aboutsummaryrefslogtreecommitdiff
diff options
context:
space:
mode:
authordeepsource-autofix[bot] <62050782+deepsource-autofix[bot]@users.noreply.github.com>2020-07-07 14:55:17 +0000
committerGitHub <noreply@github.com>2020-07-07 14:55:17 +0000
commit0d135d611506e81d322596c7827b08bbfd3b7c08 (patch)
treea281b8e1f140ad3de77d818747fce03bcfa5b77b
parent7059ee2a4ced23e467741cc846eb185886ffca38 (diff)
Format code with Blackdeepsource-transform-b65b5545
-rw-r--r--plip/basic/config.py606
-rw-r--r--plip/basic/logger.py8
-rw-r--r--plip/basic/parallel.py6
-rw-r--r--plip/basic/remote.py132
-rw-r--r--plip/basic/supplemental.py156
-rw-r--r--plip/exchange/json.py2
-rw-r--r--plip/exchange/report.py786
-rw-r--r--plip/exchange/webservices.py40
-rw-r--r--plip/exchange/xml.py349
-rw-r--r--plip/plipcmd.py410
-rw-r--r--plip/structure/detection.py659
-rw-r--r--plip/structure/preparation.py1828
-rw-r--r--plip/test/test_basic_functions.py39
-rw-r--r--plip/test/test_command_line.py26
-rw-r--r--plip/test/test_hydrogen_bonds.py16
-rw-r--r--plip/test/test_literature_validated.py264
-rw-r--r--plip/test/test_metal_coordination.py66
-rw-r--r--plip/test/test_pi_stacking.py10
-rw-r--r--plip/test/test_remote_services.py18
-rw-r--r--plip/test/test_water_bridges.py8
-rw-r--r--plip/test/test_xml_parser.py56
-rw-r--r--plip/visualization/chimera.py84
-rw-r--r--plip/visualization/pymol.py618
-rw-r--r--plip/visualization/visualize.py62
-rw-r--r--scripts/get-best.py17
-rw-r--r--scripts/get_dock_score.py20
-rw-r--r--scripts/makeReport.py193
-rw-r--r--scripts/quick-ligand-protein.py69
28 files changed, 4631 insertions, 1917 deletions
diff --git a/plip/basic/config.py b/plip/basic/config.py
index a7468cf..3770d44 100644
--- a/plip/basic/config.py
+++ b/plip/basic/config.py
@@ -1,5 +1,5 @@
-__version__ = '2.1.0-beta'
-__maintainer__ = 'PharmAI GmbH (2020) - www.pharm.ai - hello@pharm.ai'
+__version__ = "2.1.0-beta"
+__maintainer__ = "PharmAI GmbH (2020) - www.pharm.ai - hello@pharm.ai"
import logging
@@ -14,8 +14,8 @@ PICS = False
PYMOL = False
STDOUT = False
RAWSTRING = False # use raw strings for input / output
-OUTPATH = './'
-BASEPATH = './'
+OUTPATH = "./"
+BASEPATH = "./"
BREAKCOMPOSITE = False # Break up composite ligands with covalent bonds
ALTLOC = False # Consider alternate locations
PLUGIN_MODE = False # Special mode for PLIP in Plugins (e.g. PyMOL)
@@ -34,27 +34,45 @@ NOHYDRO = False # Do not add hydrogen bonds (in case already present in the str
# Thresholds for detection (global variables)
BS_DIST = 7.5 # Determines maximum distance to include binding site residues
-AROMATIC_PLANARITY = 5.0 # Determines allowed deviation from planarity in aromatic rings
+AROMATIC_PLANARITY = (
+ 5.0 # Determines allowed deviation from planarity in aromatic rings
+)
MIN_DIST = 0.5 # Minimum distance for all distance thresholds
# Some distance thresholds were extended (max. 1.0A) if too restrictive too account for low-quality structures
HYDROPH_DIST_MAX = 4.0 # Distance cutoff for detection of hydrophobic contacts
HBOND_DIST_MAX = 4.1 # Max. distance between hydrogen bond donor and acceptor (Hubbard & Haider, 2001) + 0.6 A
-HBOND_DON_ANGLE_MIN = 100 # Min. angle at the hydrogen bond donor (Hubbard & Haider, 2001) + 10
-PISTACK_DIST_MAX = 5.5 # Max. distance for parallel or offset pistacking (McGaughey, 1998)
-PISTACK_ANG_DEV = 30 # Max. Deviation from parallel or perpendicular orientation (in degrees)
+HBOND_DON_ANGLE_MIN = (
+ 100 # Min. angle at the hydrogen bond donor (Hubbard & Haider, 2001) + 10
+)
+PISTACK_DIST_MAX = (
+ 5.5 # Max. distance for parallel or offset pistacking (McGaughey, 1998)
+)
+PISTACK_ANG_DEV = (
+ 30 # Max. Deviation from parallel or perpendicular orientation (in degrees)
+)
PISTACK_OFFSET_MAX = 2.0 # Maximum offset of the two rings (corresponds to the radius of benzene + 0.5 A)
PICATION_DIST_MAX = 6.0 # Max. distance between charged atom and aromatic ring center (Gallivan and Dougherty, 1999)
SALTBRIDGE_DIST_MAX = 5.5 # Max. distance between centers of charge for salt bridges (Barlow and Thornton, 1983) + 1.5
HALOGEN_DIST_MAX = 4.0 # Max. distance between oxy. and halogen (Halogen bonds in biological molecules., Auffinger)+0.5
-HALOGEN_ACC_ANGLE = 120 # Optimal acceptor angle (Halogen bonds in biological molecules., Auffinger)
-HALOGEN_DON_ANGLE = 165 # Optimal donor angle (Halogen bonds in biological molecules., Auffinger)
+HALOGEN_ACC_ANGLE = (
+ 120 # Optimal acceptor angle (Halogen bonds in biological molecules., Auffinger)
+)
+HALOGEN_DON_ANGLE = (
+ 165 # Optimal donor angle (Halogen bonds in biological molecules., Auffinger)
+)
HALOGEN_ANGLE_DEV = 30 # Max. deviation from optimal angle
-WATER_BRIDGE_MINDIST = 2.5 # Min. distance between water oxygen and polar atom (Jiang et al., 2005) -0.1
-WATER_BRIDGE_MAXDIST = 4.1 # Max. distance between water oxygen and polar atom (Jiang et al., 2005) +0.5
+WATER_BRIDGE_MINDIST = (
+ 2.5 # Min. distance between water oxygen and polar atom (Jiang et al., 2005) -0.1
+)
+WATER_BRIDGE_MAXDIST = (
+ 4.1 # Max. distance between water oxygen and polar atom (Jiang et al., 2005) +0.5
+)
WATER_BRIDGE_OMEGA_MIN = 71 # Min. angle between acceptor, water oxygen and donor hydrogen (Jiang et al., 2005) - 9
WATER_BRIDGE_OMEGA_MAX = 140 # Max. angle between acceptor, water oxygen and donor hydrogen (Jiang et al., 2005)
WATER_BRIDGE_THETA_MIN = 100 # Min. angle between water oxygen, donor hydrogen and donor atom (Jiang et al., 2005)
-METAL_DIST_MAX = 3.0 # Max. distance between metal ion and interacting atom (Harding, 2001)
+METAL_DIST_MAX = (
+ 3.0 # Max. distance between metal ion and interacting atom (Harding, 2001)
+)
# Other thresholds
MAX_COMPOSITE_LENGTH = 200 # Filter out ligands with more than 200 fragments
@@ -64,8 +82,8 @@ MAX_COMPOSITE_LENGTH = 200 # Filter out ligands with more than 200 fragments
#########
# Names of RNA and DNA residues to be considered (detection by name)
-RNA = ['U', 'A', 'C', 'G']
-DNA = ['DT', 'DA', 'DC', 'DG']
+RNA = ["U", "A", "C", "G"]
+DNA = ["DT", "DA", "DC", "DG"]
#############
# Whitelist #
@@ -73,49 +91,535 @@ DNA = ['DT', 'DA', 'DC', 'DG']
# Metal cations which can be complexed
-METAL_IONS = ['CA', 'CO', 'MG', 'MN', 'FE', 'CU', 'ZN', 'FE2', 'FE3', 'FE4', 'LI', 'NA', 'K', 'RB', 'SR', 'CS', 'BA',
- 'CR', 'NI', 'FE1', 'NI', 'RU', 'RU1', 'RH', 'RH1', 'PD', 'AG', 'CD', 'LA', 'W', 'W1', 'OS', 'IR', 'PT',
- 'PT1', 'AU', 'HG', 'CE', 'PR', 'SM', 'EU', 'GD', 'TB', 'YB', 'LU', 'AL', 'GA', 'IN', 'SB', 'TL', 'PB']
+METAL_IONS = [
+ "CA",
+ "CO",
+ "MG",
+ "MN",
+ "FE",
+ "CU",
+ "ZN",
+ "FE2",
+ "FE3",
+ "FE4",
+ "LI",
+ "NA",
+ "K",
+ "RB",
+ "SR",
+ "CS",
+ "BA",
+ "CR",
+ "NI",
+ "FE1",
+ "NI",
+ "RU",
+ "RU1",
+ "RH",
+ "RH1",
+ "PD",
+ "AG",
+ "CD",
+ "LA",
+ "W",
+ "W1",
+ "OS",
+ "IR",
+ "PT",
+ "PT1",
+ "AU",
+ "HG",
+ "CE",
+ "PR",
+ "SM",
+ "EU",
+ "GD",
+ "TB",
+ "YB",
+ "LU",
+ "AL",
+ "GA",
+ "IN",
+ "SB",
+ "TL",
+ "PB",
+]
##############
# Blacklists #
##############
# Other Ions/Atoms (not yet supported)
-anions = ['CL', 'IOD', 'BR']
-other = ['MO', 'RE', 'HO']
+anions = ["CL", "IOD", "BR"]
+other = ["MO", "RE", "HO"]
UNSUPPORTED = anions + other
# BioLiP list of suspicious ligands from http://zhanglab.ccmb.med.umich.edu/BioLiP/ligand_list (2014-07-10)
# Add ligands here to get warnings for possible artifacts.
-biolip_list = ['ACE', 'HEX', 'TMA', 'SOH', 'P25', 'CCN', 'PR', 'PTN', 'NO3', 'TCN', 'BU1', 'BCN', 'CB3', 'HCS', 'NBN',
- 'SO2', 'MO6', 'MOH', 'CAC', 'MLT', 'KR', '6PH', 'MOS', 'UNL', 'MO3', 'SR', 'CD3', 'PB', 'ACM', 'LUT',
- 'PMS', 'OF3', 'SCN', 'DHB', 'E4N', '13P', '3PG', 'CYC', 'NC', 'BEN', 'NAO', 'PHQ', 'EPE', 'BME', 'TB',
- 'ETE', 'EU', 'OES', 'EAP', 'ETX', 'BEZ', '5AD', 'OC2', 'OLA', 'GD3', 'CIT', 'DVT', 'OC6', 'MW1', 'OC3',
- 'SRT', 'LCO', 'BNZ', 'PPV', 'STE', 'PEG', 'RU', 'PGE', 'MPO', 'B3P', 'OGA', 'IPA', 'LU', 'EDO', 'MAC',
- '9PE', 'IPH', 'MBN', 'C1O', '1PE', 'YF3', 'PEF', 'GD', '8PE', 'DKA', 'RB', 'YB', 'GGD', 'SE4', 'LHG',
- 'SMO', 'DGD', 'CMO', 'MLI', 'MW2', 'DTT', 'DOD', '7PH', 'PBM', 'AU', 'FOR', 'PSC', 'TG1', 'KAI', '1PG',
- 'DGA', 'IR', 'PE4', 'VO4', 'ACN', 'AG', 'MO4', 'OCL', '6UL', 'CHT', 'RHD', 'CPS', 'IR3', 'OC4', 'MTE',
- 'HGC', 'CR', 'PC1', 'HC4', 'TEA', 'BOG', 'PEO', 'PE5', '144', 'IUM', 'LMG', 'SQU', 'MMC', 'GOL', 'NVP',
- 'AU3', '3PH', 'PT4', 'PGO', 'ICT', 'OCM', 'BCR', 'PG4', 'L4P', 'OPC', 'OXM', 'SQD', 'PQ9', 'BAM', 'PI',
- 'PL9', 'P6G', 'IRI', '15P', 'MAE', 'MBO', 'FMT', 'L1P', 'DUD', 'PGV', 'CD1', 'P33', 'DTU', 'XAT', 'CD',
- 'THE', 'U1', 'NA', 'MW3', 'BHG', 'Y1', 'OCT', 'BET', 'MPD', 'HTO', 'IBM', 'D01', 'HAI', 'HED', 'CAD',
- 'CUZ', 'TLA', 'SO4', 'OC5', 'ETF', 'MRD', 'PT', 'PHB', 'URE', 'MLA', 'TGL', 'PLM', 'NET', 'LAC', 'AUC',
- 'UNX', 'GA', 'DMS', 'MO2', 'LA', 'NI', 'TE', 'THJ', 'NHE', 'HAE', 'MO1', 'DAO', '3PE', 'LMU', 'DHJ',
- 'FLC', 'SAL', 'GAI', 'ORO', 'HEZ', 'TAM', 'TRA', 'NEX', 'CXS', 'LCP', 'HOH', 'OCN', 'PER', 'ACY', 'MH2',
- 'ARS', '12P', 'L3P', 'PUT', 'IN', 'CS', 'NAW', 'SB', 'GUN', 'SX', 'CON', 'C2O', 'EMC', 'BO4', 'BNG',
- 'MN5', '__O', 'K', 'CYN', 'H2S', 'MH3', 'YT3', 'P22', 'KO4', '1AG', 'CE', 'IPL', 'PG6', 'MO5', 'F09',
- 'HO', 'AL', 'TRS', 'EOH', 'GCP', 'MSE', 'AKR', 'NCO', 'PO4', 'L2P', 'LDA', 'SIN', 'DMI', 'SM', 'DTD',
- 'SGM', 'DIO', 'PPI', 'DDQ', 'DPO', 'HCA', 'CO5', 'PD', 'OS', 'OH', 'NA6', 'NAG', 'W', 'ENC', 'NA5',
- 'LI1', 'P4C', 'GLV', 'DMF', 'ACT', 'BTB', '6PL', 'BGL', 'OF1', 'N8E', 'LMT', 'THM', 'EU3', 'PGR', 'NA2',
- 'FOL', '543', '_CP', 'PEK', 'NSP', 'PEE', 'OCO', 'CHD', 'CO2', 'TBU', 'UMQ', 'MES', 'NH4', 'CD5', 'HTG',
- 'DEP', 'OC1', 'KDO', '2PE', 'PE3', 'IOD', 'NDG', 'CL', 'HG', 'F', 'XE', 'TL', 'BA', 'LI', 'BR', 'TAU',
- 'TCA', 'SPD', 'SPM', 'SAR', 'SUC', 'PAM', 'SPH', 'BE7', 'P4G', 'OLC', 'OLB', 'LFA', 'D10', 'D12', 'DD9',
- 'HP6', 'R16', 'PX4', 'TRD', 'UND', 'FTT', 'MYR', 'RG1', 'IMD', 'DMN', 'KEN', 'C14', 'UPL', 'CMJ', 'ULI',
- 'MYS', 'TWT', 'M2M', 'P15', 'PG0', 'PEU', 'AE3', 'TOE', 'ME2', 'PE8', '6JZ', '7PE', 'P3G', '7PG', 'PG5',
- '16P', 'XPE', 'PGF', 'AE4', '7E8', '7E9', 'MVC', 'TAR', 'DMR', 'LMR', 'NER', '02U', 'NGZ', 'LXB', 'A2G',
- 'BM3', 'NAA', 'NGA', 'LXZ', 'PX6', 'PA8', 'LPP', 'PX2', 'MYY', 'PX8', 'PD7', 'XP4', 'XPA', 'PEV', '6PE',
- 'PEX', 'PEH', 'PTY', 'YB2', 'PGT', 'CN3', 'AGA', 'DGG', 'CD4', 'CN6', 'CDL', 'PG8', 'MGE', 'DTV', 'L44',
- 'L2C', '4AG', 'B3H', '1EM', 'DDR', 'I42', 'CNS', 'PC7', 'HGP', 'PC8', 'HGX', 'LIO', 'PLD', 'PC2', 'PCF',
- 'MC3', 'P1O', 'PLC', 'PC6', 'HSH', 'BXC', 'HSG', 'DPG', '2DP', 'POV', 'PCW', 'GVT', 'CE9', 'CXE', 'C10',
- 'CE1', 'SPJ', 'SPZ', 'SPK', 'SPW', 'HT3', 'HTH', '2OP', '3NI', 'BO3', 'DET', 'D1D', 'SWE', 'SOG']
+biolip_list = [
+ "ACE",
+ "HEX",
+ "TMA",
+ "SOH",
+ "P25",
+ "CCN",
+ "PR",
+ "PTN",
+ "NO3",
+ "TCN",
+ "BU1",
+ "BCN",
+ "CB3",
+ "HCS",
+ "NBN",
+ "SO2",
+ "MO6",
+ "MOH",
+ "CAC",
+ "MLT",
+ "KR",
+ "6PH",
+ "MOS",
+ "UNL",
+ "MO3",
+ "SR",
+ "CD3",
+ "PB",
+ "ACM",
+ "LUT",
+ "PMS",
+ "OF3",
+ "SCN",
+ "DHB",
+ "E4N",
+ "13P",
+ "3PG",
+ "CYC",
+ "NC",
+ "BEN",
+ "NAO",
+ "PHQ",
+ "EPE",
+ "BME",
+ "TB",
+ "ETE",
+ "EU",
+ "OES",
+ "EAP",
+ "ETX",
+ "BEZ",
+ "5AD",
+ "OC2",
+ "OLA",
+ "GD3",
+ "CIT",
+ "DVT",
+ "OC6",
+ "MW1",
+ "OC3",
+ "SRT",
+ "LCO",
+ "BNZ",
+ "PPV",
+ "STE",
+ "PEG",
+ "RU",
+ "PGE",
+ "MPO",
+ "B3P",
+ "OGA",
+ "IPA",
+ "LU",
+ "EDO",
+ "MAC",
+ "9PE",
+ "IPH",
+ "MBN",
+ "C1O",
+ "1PE",
+ "YF3",
+ "PEF",
+ "GD",
+ "8PE",
+ "DKA",
+ "RB",
+ "YB",
+ "GGD",
+ "SE4",
+ "LHG",
+ "SMO",
+ "DGD",
+ "CMO",
+ "MLI",
+ "MW2",
+ "DTT",
+ "DOD",
+ "7PH",
+ "PBM",
+ "AU",
+ "FOR",
+ "PSC",
+ "TG1",
+ "KAI",
+ "1PG",
+ "DGA",
+ "IR",
+ "PE4",
+ "VO4",
+ "ACN",
+ "AG",
+ "MO4",
+ "OCL",
+ "6UL",
+ "CHT",
+ "RHD",
+ "CPS",
+ "IR3",
+ "OC4",
+ "MTE",
+ "HGC",
+ "CR",
+ "PC1",
+ "HC4",
+ "TEA",
+ "BOG",
+ "PEO",
+ "PE5",
+ "144",
+ "IUM",
+ "LMG",
+ "SQU",
+ "MMC",
+ "GOL",
+ "NVP",
+ "AU3",
+ "3PH",
+ "PT4",
+ "PGO",
+ "ICT",
+ "OCM",
+ "BCR",
+ "PG4",
+ "L4P",
+ "OPC",
+ "OXM",
+ "SQD",
+ "PQ9",
+ "BAM",
+ "PI",
+ "PL9",
+ "P6G",
+ "IRI",
+ "15P",
+ "MAE",
+ "MBO",
+ "FMT",
+ "L1P",
+ "DUD",
+ "PGV",
+ "CD1",
+ "P33",
+ "DTU",
+ "XAT",
+ "CD",
+ "THE",
+ "U1",
+ "NA",
+ "MW3",
+ "BHG",
+ "Y1",
+ "OCT",
+ "BET",
+ "MPD",
+ "HTO",
+ "IBM",
+ "D01",
+ "HAI",
+ "HED",
+ "CAD",
+ "CUZ",
+ "TLA",
+ "SO4",
+ "OC5",
+ "ETF",
+ "MRD",
+ "PT",
+ "PHB",
+ "URE",
+ "MLA",
+ "TGL",
+ "PLM",
+ "NET",
+ "LAC",
+ "AUC",
+ "UNX",
+ "GA",
+ "DMS",
+ "MO2",
+ "LA",
+ "NI",
+ "TE",
+ "THJ",
+ "NHE",
+ "HAE",
+ "MO1",
+ "DAO",
+ "3PE",
+ "LMU",
+ "DHJ",
+ "FLC",
+ "SAL",
+ "GAI",
+ "ORO",
+ "HEZ",
+ "TAM",
+ "TRA",
+ "NEX",
+ "CXS",
+ "LCP",
+ "HOH",
+ "OCN",
+ "PER",
+ "ACY",
+ "MH2",
+ "ARS",
+ "12P",
+ "L3P",
+ "PUT",
+ "IN",
+ "CS",
+ "NAW",
+ "SB",
+ "GUN",
+ "SX",
+ "CON",
+ "C2O",
+ "EMC",
+ "BO4",
+ "BNG",
+ "MN5",
+ "__O",
+ "K",
+ "CYN",
+ "H2S",
+ "MH3",
+ "YT3",
+ "P22",
+ "KO4",
+ "1AG",
+ "CE",
+ "IPL",
+ "PG6",
+ "MO5",
+ "F09",
+ "HO",
+ "AL",
+ "TRS",
+ "EOH",
+ "GCP",
+ "MSE",
+ "AKR",
+ "NCO",
+ "PO4",
+ "L2P",
+ "LDA",
+ "SIN",
+ "DMI",
+ "SM",
+ "DTD",
+ "SGM",
+ "DIO",
+ "PPI",
+ "DDQ",
+ "DPO",
+ "HCA",
+ "CO5",
+ "PD",
+ "OS",
+ "OH",
+ "NA6",
+ "NAG",
+ "W",
+ "ENC",
+ "NA5",
+ "LI1",
+ "P4C",
+ "GLV",
+ "DMF",
+ "ACT",
+ "BTB",
+ "6PL",
+ "BGL",
+ "OF1",
+ "N8E",
+ "LMT",
+ "THM",
+ "EU3",
+ "PGR",
+ "NA2",
+ "FOL",
+ "543",
+ "_CP",
+ "PEK",
+ "NSP",
+ "PEE",
+ "OCO",
+ "CHD",
+ "CO2",
+ "TBU",
+ "UMQ",
+ "MES",
+ "NH4",
+ "CD5",
+ "HTG",
+ "DEP",
+ "OC1",
+ "KDO",
+ "2PE",
+ "PE3",
+ "IOD",
+ "NDG",
+ "CL",
+ "HG",
+ "F",
+ "XE",
+ "TL",
+ "BA",
+ "LI",
+ "BR",
+ "TAU",
+ "TCA",
+ "SPD",
+ "SPM",
+ "SAR",
+ "SUC",
+ "PAM",
+ "SPH",
+ "BE7",
+ "P4G",
+ "OLC",
+ "OLB",
+ "LFA",
+ "D10",
+ "D12",
+ "DD9",
+ "HP6",
+ "R16",
+ "PX4",
+ "TRD",
+ "UND",
+ "FTT",
+ "MYR",
+ "RG1",
+ "IMD",
+ "DMN",
+ "KEN",
+ "C14",
+ "UPL",
+ "CMJ",
+ "ULI",
+ "MYS",
+ "TWT",
+ "M2M",
+ "P15",
+ "PG0",
+ "PEU",
+ "AE3",
+ "TOE",
+ "ME2",
+ "PE8",
+ "6JZ",
+ "7PE",
+ "P3G",
+ "7PG",
+ "PG5",
+ "16P",
+ "XPE",
+ "PGF",
+ "AE4",
+ "7E8",
+ "7E9",
+ "MVC",
+ "TAR",
+ "DMR",
+ "LMR",
+ "NER",
+ "02U",
+ "NGZ",
+ "LXB",
+ "A2G",
+ "BM3",
+ "NAA",
+ "NGA",
+ "LXZ",
+ "PX6",
+ "PA8",
+ "LPP",
+ "PX2",
+ "MYY",
+ "PX8",
+ "PD7",
+ "XP4",
+ "XPA",
+ "PEV",
+ "6PE",
+ "PEX",
+ "PEH",
+ "PTY",
+ "YB2",
+ "PGT",
+ "CN3",
+ "AGA",
+ "DGG",
+ "CD4",
+ "CN6",
+ "CDL",
+ "PG8",
+ "MGE",
+ "DTV",
+ "L44",
+ "L2C",
+ "4AG",
+ "B3H",
+ "1EM",
+ "DDR",
+ "I42",
+ "CNS",
+ "PC7",
+ "HGP",
+ "PC8",
+ "HGX",
+ "LIO",
+ "PLD",
+ "PC2",
+ "PCF",
+ "MC3",
+ "P1O",
+ "PLC",
+ "PC6",
+ "HSH",
+ "BXC",
+ "HSG",
+ "DPG",
+ "2DP",
+ "POV",
+ "PCW",
+ "GVT",
+ "CE9",
+ "CXE",
+ "C10",
+ "CE1",
+ "SPJ",
+ "SPZ",
+ "SPK",
+ "SPW",
+ "HT3",
+ "HTH",
+ "2OP",
+ "3NI",
+ "BO3",
+ "DET",
+ "D1D",
+ "SWE",
+ "SOG",
+]
diff --git a/plip/basic/logger.py b/plip/basic/logger.py
index ca65411..f15650e 100644
--- a/plip/basic/logger.py
+++ b/plip/basic/logger.py
@@ -8,14 +8,16 @@ def get_logger():
"""
frame = inspect.stack()[1]
module_name = inspect.getmodule(frame[0]).__name__
- if module_name != '__main__':
+ if module_name != "__main__":
logger = logging.getLogger(module_name)
if not logger.parent.handlers:
ch = logging.StreamHandler()
- formatter = logging.Formatter('%(asctime)s [%(levelname)s] [%(filename)s:%(lineno)d] %(name)s: %(message)s')
+ formatter = logging.Formatter(
+ "%(asctime)s [%(levelname)s] [%(filename)s:%(lineno)d] %(name)s: %(message)s"
+ )
ch.setFormatter(formatter)
logger.parent.addHandler(ch)
else:
- logger = logging.getLogger('plip')
+ logger = logging.getLogger("plip")
return logger
diff --git a/plip/basic/parallel.py b/plip/basic/parallel.py
index 1f71943..cd0b93b 100644
--- a/plip/basic/parallel.py
+++ b/plip/basic/parallel.py
@@ -34,9 +34,9 @@ def parallel_fn(f):
def simple_parallel(func, sequence, **args):
""" f takes an element of sequence as input and the keyword args in **args"""
- if 'processes' in args:
- processes = args.get('processes')
- del args['processes']
+ if "processes" in args:
+ processes = args.get("processes")
+ del args["processes"]
else:
processes = multiprocessing.cpu_count()
diff --git a/plip/basic/remote.py b/plip/basic/remote.py
index 0c67f6f..18de4b7 100644
--- a/plip/basic/remote.py
+++ b/plip/basic/remote.py
@@ -1,14 +1,23 @@
from collections import namedtuple
-hbonds_info = namedtuple('hbonds_info', 'ldon_id lig_don_id prot_acc_id pdon_id prot_don_id lig_acc_id')
-hydrophobic_info = namedtuple('hydrophobic_info', 'bs_ids lig_ids pairs_ids')
-halogen_info = namedtuple('halogen_info', 'don_id acc_id')
-pistack_info = namedtuple('pistack_info', 'proteinring_atoms, proteinring_center ligandring_atoms '
- 'ligandring_center type')
-pication_info = namedtuple('pication_info', 'ring_center charge_center ring_atoms charge_atoms, protcharged')
-sbridge_info = namedtuple('sbridge_info', 'positive_atoms negative_atoms positive_center negative_center protispos')
-wbridge_info = namedtuple('wbridge_info', 'don_id acc_id water_id protisdon')
-metal_info = namedtuple('metal_info', 'metal_id, target_id location')
+hbonds_info = namedtuple(
+ "hbonds_info", "ldon_id lig_don_id prot_acc_id pdon_id prot_don_id lig_acc_id"
+)
+hydrophobic_info = namedtuple("hydrophobic_info", "bs_ids lig_ids pairs_ids")
+halogen_info = namedtuple("halogen_info", "don_id acc_id")
+pistack_info = namedtuple(
+ "pistack_info",
+ "proteinring_atoms, proteinring_center ligandring_atoms " "ligandring_center type",
+)
+pication_info = namedtuple(
+ "pication_info", "ring_center charge_center ring_atoms charge_atoms, protcharged"
+)
+sbridge_info = namedtuple(
+ "sbridge_info",
+ "positive_atoms negative_atoms positive_center negative_center protispos",
+)
+wbridge_info = namedtuple("wbridge_info", "don_id acc_id water_id protisdon")
+metal_info = namedtuple("metal_info", "metal_id, target_id location")
class VisualizerData:
@@ -21,7 +30,7 @@ class VisualizerData:
# General Information
self.lig_members = sorted(pli.ligand.members)
- self.sourcefile = pcomp.sourcefiles['pdbcomplex']
+ self.sourcefile = pcomp.sourcefiles["pdbcomplex"]
self.corrected_pdb = pcomp.corrected_pdb
self.pdbid = mol.pymol_name
self.hetid = ligand.hetid
@@ -39,57 +48,88 @@ class VisualizerData:
# Hydrophobic Contacts
# Contains IDs of contributing binding site, ligand atoms and the pairings
- hydroph_pairs_id = [(h.bsatom_orig_idx, h.ligatom_orig_idx) for h in pli.hydrophobic_contacts]
- self.hydrophobic_contacts = hydrophobic_info(bs_ids=[hp[0] for hp in hydroph_pairs_id],
- lig_ids=[hp[1] for hp in hydroph_pairs_id],
- pairs_ids=hydroph_pairs_id)
+ hydroph_pairs_id = [
+ (h.bsatom_orig_idx, h.ligatom_orig_idx) for h in pli.hydrophobic_contacts
+ ]
+ self.hydrophobic_contacts = hydrophobic_info(
+ bs_ids=[hp[0] for hp in hydroph_pairs_id],
+ lig_ids=[hp[1] for hp in hydroph_pairs_id],
+ pairs_ids=hydroph_pairs_id,
+ )
# Hydrogen Bonds
# #@todo Don't use indices, simplify this code here
hbonds_ldon, hbonds_pdon = pli.hbonds_ldon, pli.hbonds_pdon
hbonds_ldon_id = [(hb.a_orig_idx, hb.d_orig_idx) for hb in hbonds_ldon]
hbonds_pdon_id = [(hb.a_orig_idx, hb.d_orig_idx) for hb in hbonds_pdon]
- self.hbonds = hbonds_info(ldon_id=[(hb.a_orig_idx, hb.d_orig_idx) for hb in hbonds_ldon],
- lig_don_id=[hb[1] for hb in hbonds_ldon_id],
- prot_acc_id=[hb[0] for hb in hbonds_ldon_id],
- pdon_id=[(hb.a_orig_idx, hb.d_orig_idx) for hb in hbonds_pdon],
- prot_don_id=[hb[1] for hb in hbonds_pdon_id],
- lig_acc_id=[hb[0] for hb in hbonds_pdon_id])
+ self.hbonds = hbonds_info(
+ ldon_id=[(hb.a_orig_idx, hb.d_orig_idx) for hb in hbonds_ldon],
+ lig_don_id=[hb[1] for hb in hbonds_ldon_id],
+ prot_acc_id=[hb[0] for hb in hbonds_ldon_id],
+ pdon_id=[(hb.a_orig_idx, hb.d_orig_idx) for hb in hbonds_pdon],
+ prot_don_id=[hb[1] for hb in hbonds_pdon_id],
+ lig_acc_id=[hb[0] for hb in hbonds_pdon_id],
+ )
# Halogen Bonds
- self.halogen_bonds = [halogen_info(don_id=h.don_orig_idx, acc_id=h.acc_orig_idx)
- for h in pli.halogen_bonds]
+ self.halogen_bonds = [
+ halogen_info(don_id=h.don_orig_idx, acc_id=h.acc_orig_idx)
+ for h in pli.halogen_bonds
+ ]
# Pistacking
- self.pistacking = [pistack_info(proteinring_atoms=pistack.proteinring.atoms_orig_idx,
- proteinring_center=pistack.proteinring.center,
- ligandring_atoms=pistack.ligandring.atoms_orig_idx,
- ligandring_center=pistack.ligandring.center,
- type=pistack.type) for pistack in pli.pistacking]
+ self.pistacking = [
+ pistack_info(
+ proteinring_atoms=pistack.proteinring.atoms_orig_idx,
+ proteinring_center=pistack.proteinring.center,
+ ligandring_atoms=pistack.ligandring.atoms_orig_idx,
+ ligandring_center=pistack.ligandring.center,
+ type=pistack.type,
+ )
+ for pistack in pli.pistacking
+ ]
# Pi-cation interactions
- self.pication = [pication_info(ring_center=picat.ring.center,
- charge_center=picat.charge.center,
- ring_atoms=picat.ring.atoms_orig_idx,
- charge_atoms=picat.charge.atoms_orig_idx,
- protcharged=picat.protcharged)
- for picat in pli.pication_paro + pli.pication_laro]
+ self.pication = [
+ pication_info(
+ ring_center=picat.ring.center,
+ charge_center=picat.charge.center,
+ ring_atoms=picat.ring.atoms_orig_idx,
+ charge_atoms=picat.charge.atoms_orig_idx,
+ protcharged=picat.protcharged,
+ )
+ for picat in pli.pication_paro + pli.pication_laro
+ ]
# Salt Bridges
- self.saltbridges = [sbridge_info(positive_atoms=sbridge.positive.atoms_orig_idx,
- negative_atoms=sbridge.negative.atoms_orig_idx,
- positive_center=sbridge.positive.center,
- negative_center=sbridge.negative.center,
- protispos=sbridge.protispos)
- for sbridge in pli.saltbridge_lneg + pli.saltbridge_pneg]
+ self.saltbridges = [
+ sbridge_info(
+ positive_atoms=sbridge.positive.atoms_orig_idx,
+ negative_atoms=sbridge.negative.atoms_orig_idx,
+ positive_center=sbridge.positive.center,
+ negative_center=sbridge.negative.center,
+ protispos=sbridge.protispos,
+ )
+ for sbridge in pli.saltbridge_lneg + pli.saltbridge_pneg
+ ]
# Water Bridgese('wbridge_info', 'don_id acc_id water_id protisdon')
- self.waterbridges = [wbridge_info(don_id=wbridge.d_orig_idx,
- acc_id=wbridge.a_orig_idx,
- water_id=wbridge.water_orig_idx,
- protisdon=wbridge.protisdon) for wbridge in pli.water_bridges]
+ self.waterbridges = [
+ wbridge_info(
+ don_id=wbridge.d_orig_idx,
+ acc_id=wbridge.a_orig_idx,
+ water_id=wbridge.water_orig_idx,
+ protisdon=wbridge.protisdon,
+ )
+ for wbridge in pli.water_bridges
+ ]
# Metal Complexes
- self.metal_complexes = [metal_info(metal_id=metalc.metal_orig_idx,
- target_id=metalc.target_orig_idx,
- location=metalc.location) for metalc in pli.metal_complexes]
+ self.metal_complexes = [
+ metal_info(
+ metal_id=metalc.metal_orig_idx,
+ target_id=metalc.target_orig_idx,
+ location=metalc.location,
+ )
+ for metalc in pli.metal_complexes
+ ]
diff --git a/plip/basic/supplemental.py b/plip/basic/supplemental.py
index 6b3ef7b..7164497 100644
--- a/plip/basic/supplemental.py
+++ b/plip/basic/supplemental.py
@@ -18,22 +18,24 @@ from plip.basic import config, logger
logger = logger.get_logger()
# Windows and MacOS
-if os.name != 'nt' and platform.system() != 'Darwin': # Resource module not available for Windows
+if (
+ os.name != "nt" and platform.system() != "Darwin"
+): # Resource module not available for Windows
import resource
# Settings
-np.seterr(all='ignore') # No runtime warnings
+np.seterr(all="ignore") # No runtime warnings
def tmpfile(prefix, direc):
"""Returns the path to a newly created temporary file."""
- return tempfile.mktemp(prefix=prefix, suffix='.pdb', dir=direc)
+ return tempfile.mktemp(prefix=prefix, suffix=".pdb", dir=direc)
def is_lig(hetid):
"""Checks if a PDB compound can be excluded as a small molecule ligand"""
h = hetid.upper()
- return not (h == 'HOH' or h in config.UNSUPPORTED)
+ return not (h == "HOH" or h in config.UNSUPPORTED)
def extract_pdbid(string):
@@ -48,19 +50,25 @@ def extract_pdbid(string):
def whichrestype(atom):
"""Returns the residue name of an Pybel or OpenBabel atom."""
- atom = atom if not isinstance(atom, Atom) else atom.OBAtom # Convert to OpenBabel Atom
+ atom = (
+ atom if not isinstance(atom, Atom) else atom.OBAtom
+ ) # Convert to OpenBabel Atom
return atom.GetResidue().GetName() if atom.GetResidue() is not None else None
def whichresnumber(atom):
"""Returns the residue number of an Pybel or OpenBabel atom (numbering as in original PDB file)."""
- atom = atom if not isinstance(atom, Atom) else atom.OBAtom # Convert to OpenBabel Atom
+ atom = (
+ atom if not isinstance(atom, Atom) else atom.OBAtom
+ ) # Convert to OpenBabel Atom
return atom.GetResidue().GetNum() if atom.GetResidue() is not None else None
def whichchain(atom):
"""Returns the residue number of an PyBel or OpenBabel atom."""
- atom = atom if not isinstance(atom, Atom) else atom.OBAtom # Convert to OpenBabel Atom
+ atom = (
+ atom if not isinstance(atom, Atom) else atom.OBAtom
+ ) # Convert to OpenBabel Atom
return atom.GetResidue().GetChain() if atom.GetResidue() is not None else None
@@ -82,7 +90,11 @@ def vector(p1, p2):
:param p2: coordinates of point p2
:returns : numpy array with vector coordinates
"""
- return None if len(p1) != len(p2) else np.array([p2[i] - p1[i] for i in range(len(p1))])
+ return (
+ None
+ if len(p1) != len(p2)
+ else np.array([p2[i] - p1[i] for i in range(len(p1))])
+ )
def vecangle(v1, v2, deg=True):
@@ -97,7 +109,7 @@ def vecangle(v1, v2, deg=True):
dm = np.dot(v1, v2)
cm = np.linalg.norm(v1) * np.linalg.norm(v2)
angle = np.arccos(dm / cm) # Round here to prevent floating point errors
- return np.degrees([angle, ])[0] if deg else angle
+ return np.degrees([angle,])[0] if deg else angle
def normalize_vector(v):
@@ -114,7 +126,12 @@ def centroid(coo):
:param coo: Array of coordinate arrays
:returns : centroid coordinates as list
"""
- return list(map(np.mean, (([c[0] for c in coo]), ([c[1] for c in coo]), ([c[2] for c in coo]))))
+ return list(
+ map(
+ np.mean,
+ (([c[0] for c in coo]), ([c[1] for c in coo]), ([c[2] for c in coo])),
+ )
+ )
def projection(pnormal1, ppoint, tpoint):
@@ -150,11 +167,15 @@ def cluster_doubles(double_list):
if a in location and b in location:
if location[a] != location[b]:
if location[a] < location[b]:
- clusters[location[a]] = clusters[location[a]].union(clusters[location[b]]) # Merge clusters
- clusters = clusters[:location[b]] + clusters[location[b] + 1:]
+ clusters[location[a]] = clusters[location[a]].union(
+ clusters[location[b]]
+ ) # Merge clusters
+ clusters = clusters[: location[b]] + clusters[location[b] + 1 :]
else:
- clusters[location[b]] = clusters[location[b]].union(clusters[location[a]]) # Merge clusters
- clusters = clusters[:location[a]] + clusters[location[a] + 1:]
+ clusters[location[b]] = clusters[location[b]].union(
+ clusters[location[a]]
+ ) # Merge clusters
+ clusters = clusters[: location[a]] + clusters[location[a] + 1 :]
# Rebuild index of locations for each element as they have changed now
location = {}
for i, cluster in enumerate(clusters):
@@ -181,9 +202,10 @@ def cluster_doubles(double_list):
# File operations
#################
+
def tilde_expansion(folder_path):
"""Tilde expansion, i.e. converts '~' in paths into <value of $HOME>."""
- return os.path.expanduser(folder_path) if '~' in folder_path else folder_path
+ return os.path.expanduser(folder_path) if "~" in folder_path else folder_path
def folder_exists(folder_path):
@@ -194,14 +216,21 @@ def folder_exists(folder_path):
def create_folder_if_not_exists(folder_path):
"""Creates a folder if it does not exists."""
folder_path = tilde_expansion(folder_path)
- folder_path = "".join([folder_path, '/']) if not folder_path[-1] == '/' else folder_path
+ folder_path = (
+ "".join([folder_path, "/"]) if not folder_path[-1] == "/" else folder_path
+ )
direc = os.path.dirname(folder_path)
if not folder_exists(direc):
os.makedirs(direc)
def cmd_exists(c):
- return subprocess.call("type " + c, shell=True, stdout=subprocess.PIPE, stderr=subprocess.PIPE) == 0
+ return (
+ subprocess.call(
+ "type " + c, shell=True, stdout=subprocess.PIPE, stderr=subprocess.PIPE
+ )
+ == 0
+ )
################
@@ -212,20 +241,22 @@ def cmd_exists(c):
def initialize_pymol(options):
"""Initializes PyMOL"""
import pymol
+
# Pass standard arguments of function to prevent PyMOL from printing out PDB headers (workaround)
- pymol.finish_launching(args=['pymol', options, '-K'])
+ pymol.finish_launching(args=["pymol", options, "-K"])
pymol.cmd.reinitialize()
-def start_pymol(quiet=False, options='-p', run=False):
+def start_pymol(quiet=False, options="-p", run=False):
"""Starts up PyMOL and sets general options. Quiet mode suppresses all PyMOL output.
Command line options can be passed as the second argument."""
import pymol
- pymol.pymol_argv = ['pymol', '%s' % options] + sys.argv[1:]
+
+ pymol.pymol_argv = ["pymol", "%s" % options] + sys.argv[1:]
if run:
initialize_pymol(options)
if quiet:
- pymol.cmd.feedback('disable', 'all', 'everything')
+ pymol.cmd.feedback("disable", "all", "everything")
def nucleotide_linkage(residues):
@@ -235,7 +266,7 @@ def nucleotide_linkage(residues):
#######################################
# Basic support for RNA/DNA as ligand #
#######################################
- nucleotides = ['A', 'C', 'T', 'G', 'U', 'DA', 'DC', 'DT', 'DG', 'DU']
+ nucleotides = ["A", "C", "T", "G", "U", "DA", "DC", "DT", "DG", "DU"]
dna_rna = {} # Dictionary of DNA/RNA residues by chain
covlinkage = namedtuple("covlinkage", "id1 chain1 pos1 conf1 id2 chain2 pos2 conf2")
# Create missing covlinkage entries for DNA/RNA
@@ -243,7 +274,9 @@ def nucleotide_linkage(residues):
resname, chain, pos = ligand
if resname in nucleotides:
if chain not in dna_rna:
- dna_rna[chain] = [(resname, pos), ]
+ dna_rna[chain] = [
+ (resname, pos),
+ ]
else:
dna_rna[chain].append((resname, pos))
for chain in dna_rna:
@@ -253,8 +286,16 @@ def nucleotide_linkage(residues):
name, pos = nucleotide
nextnucleotide = nuc_list[i + 1]
nextname, nextpos = nextnucleotide
- newlink = covlinkage(id1=name, chain1=chain, pos1=pos, conf1='',
- id2=nextname, chain2=chain, pos2=nextpos, conf2='')
+ newlink = covlinkage(
+ id1=name,
+ chain1=chain,
+ pos1=pos,
+ conf1="",
+ id2=nextname,
+ chain2=chain,
+ pos2=nextpos,
+ conf2="",
+ )
nuc_covalent.append(newlink)
return nuc_covalent
@@ -273,7 +314,12 @@ def ring_is_planar(ring, r_atoms):
# Given all normals of ring atoms and their neighbors, the angle between any has to be 5.0 deg or less
for n1, n2 in itertools.product(normals, repeat=2):
arom_angle = vecangle(n1, n2)
- if all([arom_angle > config.AROMATIC_PLANARITY, arom_angle < 180.0 - config.AROMATIC_PLANARITY]):
+ if all(
+ [
+ arom_angle > config.AROMATIC_PLANARITY,
+ arom_angle < 180.0 - config.AROMATIC_PLANARITY,
+ ]
+ ):
return False
return True
@@ -282,21 +328,21 @@ def classify_by_name(names):
"""Classify a (composite) ligand by the HETID(s)"""
if len(names) > 3: # Polymer
if len(set(config.RNA).intersection(set(names))) != 0:
- ligtype = 'RNA'
+ ligtype = "RNA"
elif len(set(config.DNA).intersection(set(names))) != 0:
- ligtype = 'DNA'
+ ligtype = "DNA"
else:
ligtype = "POLYMER"
else:
- ligtype = 'SMALLMOLECULE'
+ ligtype = "SMALLMOLECULE"
for name in names:
if name in config.METAL_IONS:
if len(names) == 1:
- ligtype = 'ION'
+ ligtype = "ION"
else:
if "ION" not in ligtype:
- ligtype += '+ION'
+ ligtype += "+ION"
return ligtype
@@ -323,7 +369,7 @@ def get_isomorphisms(reference, lig):
isomorphs = pybel.ob.vpairUIntUInt()
mappr.MapFirst(lig.OBMol, isomorphs)
isomorphs = [isomorphs]
- logger.debug(f'number of isomorphisms: {len(isomorphs)}')
+ logger.debug(f"number of isomorphisms: {len(isomorphs)}")
# @todo Check which isomorphism to take
return isomorphs
@@ -340,15 +386,17 @@ def canonicalize(lig, preserve_bond_order=False):
bond.SetBondOrder(1)
lig.DeleteData(pybel.ob.StereoData)
lig = pybel.Molecule(lig)
- testcan = lig.write(format='can')
+ testcan = lig.write(format="can")
try:
- pybel.readstring('can', testcan)
- reference = pybel.readstring('can', testcan)
+ pybel.readstring("can", testcan)
+ reference = pybel.readstring("can", testcan)
except IOError:
- testcan, reference = '', ''
- if testcan != '':
+ testcan, reference = "", ""
+ if testcan != "":
reference.removeh()
- isomorphs = get_isomorphisms(reference, lig) # isomorphs now holds all isomorphisms within the molecule
+ isomorphs = get_isomorphisms(
+ reference, lig
+ ) # isomorphs now holds all isomorphisms within the molecule
if not len(isomorphs) == 0:
smi_dict = {}
smi_to_can = isomorphs[0]
@@ -365,7 +413,9 @@ def int32_to_negative(int32):
32 bit integer and returns the actual number.
"""
dct = {}
- if int32 == 4294967295: # Special case in some structures (note, this is just a workaround)
+ if (
+ int32 == 4294967295
+ ): # Special case in some structures (note, this is just a workaround)
return -1
for i in range(-1000, -1):
dct[np.uint32(i)] = i
@@ -378,7 +428,7 @@ def int32_to_negative(int32):
def read_pdb(pdbfname, as_string=False):
"""Reads a given PDB file and returns a Pybel Molecule."""
pybel.ob.obErrorLog.StopLogging() # Suppress all OpenBabel warnings
- if os.name != 'nt': # Resource module not available for Windows
+ if os.name != "nt": # Resource module not available for Windows
maxsize = resource.getrlimit(resource.RLIMIT_STACK)[-1]
resource.setrlimit(resource.RLIMIT_STACK, (min(2 ** 28, maxsize), maxsize))
sys.setrecursionlimit(10 ** 5) # increase Python recursion limit
@@ -387,48 +437,50 @@ def read_pdb(pdbfname, as_string=False):
def read(fil):
"""Returns a file handler and detects gzipped files."""
- if os.path.splitext(fil)[-1] == '.gz':
- return gzip.open(fil, 'rb')
- elif os.path.splitext(fil)[-1] == '.zip':
- zf = zipfile.ZipFile(fil, 'r')
+ if os.path.splitext(fil)[-1] == ".gz":
+ return gzip.open(fil, "rb")
+ elif os.path.splitext(fil)[-1] == ".zip":
+ zf = zipfile.ZipFile(fil, "r")
return zf.open(zf.infolist()[0].filename)
else:
- return open(fil, 'r')
+ return open(fil, "r")
def readmol(path, as_string=False):
"""Reads the given molecule file and returns the corresponding Pybel molecule as well as the input file type.
In contrast to the standard Pybel implementation, the file is closed properly."""
- supported_formats = ['pdb']
+ supported_formats = ["pdb"]
# Fix for Windows-generated files: Remove carriage return characters
if "\r" in path and as_string:
- path = path.replace('\r', '')
+ path = path.replace("\r", "")
for sformat in supported_formats:
obc = pybel.ob.OBConversion()
obc.SetInFormat(sformat)
- logger.debug(f'detected {sformat} as format, trying to read file with OpenBabel')
+ logger.debug(
+ f"detected {sformat} as format, trying to read file with OpenBabel"
+ )
# Read molecules with single bond information
if as_string:
try:
mymol = pybel.readstring(sformat, path)
except IOError:
- logger.error('no valid file format provided')
+ logger.error("no valid file format provided")
sys.exit(1)
else:
read_file = pybel.readfile(format=sformat, filename=path, opt={"s": None})
try:
mymol = next(read_file)
except StopIteration:
- logger.error('file contains no valid molecules')
+ logger.error("file contains no valid molecules")
sys.exit(1)
- logger.debug('molecule successfully read')
+ logger.debug("molecule successfully read")
# Assign multiple bonds
mymol.OBMol.PerceiveBondOrders()
return mymol, sformat
- logger.error('no valid file format provided')
+ logger.error("no valid file format provided")
sys.exit(1)
diff --git a/plip/exchange/json.py b/plip/exchange/json.py
index 5c7ad5c..14febda 100644
--- a/plip/exchange/json.py
+++ b/plip/exchange/json.py
@@ -1 +1 @@
-# place holder for module to add Json support \ No newline at end of file
+# place holder for module to add Json support
diff --git a/plip/exchange/report.py b/plip/exchange/report.py
index a559bf8..edca1f1 100644
--- a/plip/exchange/report.py
+++ b/plip/exchange/report.py
@@ -11,7 +11,7 @@ from plip.structure.preparation import PDBComplex
class StructureReport:
"""Creates reports (xml or txt) for one structure/"""
- def __init__(self, mol: PDBComplex, outputprefix: str = 'report'):
+ def __init__(self, mol: PDBComplex, outputprefix: str = "report"):
self.mol = mol
self.excluded = self.mol.excluded
self.xmlreport = self.construct_xml_tree()
@@ -22,57 +22,75 @@ class StructureReport:
def construct_xml_tree(self):
"""Construct the basic XML tree"""
- report = et.Element('report')
- plipversion = et.SubElement(report, 'plipversion')
+ report = et.Element("report")
+ plipversion = et.SubElement(report, "plipversion")
plipversion.text = __version__
- date_of_creation = et.SubElement(report, 'date_of_creation')
+ date_of_creation = et.SubElement(report, "date_of_creation")
date_of_creation.text = time.strftime("%Y/%m/%d")
- citation_information = et.SubElement(report, 'citation_information')
- citation_information.text = "Salentin,S. et al. PLIP: fully automated protein-ligand interaction profiler. " \
- "Nucl. Acids Res. (1 July 2015) 43 (W1): W443-W447. doi: 10.1093/nar/gkv315"
+ citation_information = et.SubElement(report, "citation_information")
+ citation_information.text = (
+ "Salentin,S. et al. PLIP: fully automated protein-ligand interaction profiler. "
+ "Nucl. Acids Res. (1 July 2015) 43 (W1): W443-W447. doi: 10.1093/nar/gkv315"
+ )
- maintainer_information = et.SubElement(report, 'maintainer_information')
+ maintainer_information = et.SubElement(report, "maintainer_information")
maintainer_information.text = config.__maintainer__
- mode = et.SubElement(report, 'mode')
+ mode = et.SubElement(report, "mode")
if config.DNARECEPTOR:
- mode.text = 'dna_receptor'
+ mode.text = "dna_receptor"
else:
- mode.text = 'default'
- pdbid = et.SubElement(report, 'pdbid')
+ mode.text = "default"
+ pdbid = et.SubElement(report, "pdbid")
pdbid.text = self.mol.pymol_name.upper()
- filetype = et.SubElement(report, 'filetype')
+ filetype = et.SubElement(report, "filetype")
filetype.text = self.mol.filetype.upper()
- pdbfile = et.SubElement(report, 'pdbfile')
- pdbfile.text = self.mol.sourcefiles['pdbcomplex']
- pdbfixes = et.SubElement(report, 'pdbfixes')
- pdbfixes.text = str(self.mol.information['pdbfixes'])
- filename = et.SubElement(report, 'filename')
- filename.text = str(self.mol.sourcefiles.get('filename') or None)
- exligs = et.SubElement(report, 'excluded_ligands')
+ pdbfile = et.SubElement(report, "pdbfile")
+ pdbfile.text = self.mol.sourcefiles["pdbcomplex"]
+ pdbfixes = et.SubElement(report, "pdbfixes")
+ pdbfixes.text = str(self.mol.information["pdbfixes"])
+ filename = et.SubElement(report, "filename")
+ filename.text = str(self.mol.sourcefiles.get("filename") or None)
+ exligs = et.SubElement(report, "excluded_ligands")
for i, exlig in enumerate(self.excluded):
- e = et.SubElement(exligs, 'excluded_ligand', id=str(i + 1))
+ e = et.SubElement(exligs, "excluded_ligand", id=str(i + 1))
e.text = exlig
- covalent = et.SubElement(report, 'covlinkages')
+ covalent = et.SubElement(report, "covlinkages")
for i, covlinkage in enumerate(self.mol.covalent):
- e = et.SubElement(covalent, 'covlinkage', id=str(i + 1))
- f1 = et.SubElement(e, 'res1')
- f2 = et.SubElement(e, 'res2')
- f1.text = ":".join([covlinkage.id1, covlinkage.chain1, str(covlinkage.pos1)])
- f2.text = ":".join([covlinkage.id2, covlinkage.chain2, str(covlinkage.pos2)])
+ e = et.SubElement(covalent, "covlinkage", id=str(i + 1))
+ f1 = et.SubElement(e, "res1")
+ f2 = et.SubElement(e, "res2")
+ f1.text = ":".join(
+ [covlinkage.id1, covlinkage.chain1, str(covlinkage.pos1)]
+ )
+ f2.text = ":".join(
+ [covlinkage.id2, covlinkage.chain2, str(covlinkage.pos2)]
+ )
return report
def construct_txt_file(self):
"""Construct the header of the txt file"""
- textlines = ['Prediction of noncovalent interactions for PDB structure %s' % self.mol.pymol_name.upper(), ]
+ textlines = [
+ "Prediction of noncovalent interactions for PDB structure %s"
+ % self.mol.pymol_name.upper(),
+ ]
textlines.append("=" * len(textlines[0]))
- textlines.append('Created on %s using PLIP v%s\n' % (time.strftime("%Y/%m/%d"), __version__))
- textlines.append('If you are using PLIP in your work, please cite:')
- textlines.append('Salentin,S. et al. PLIP: fully automated protein-ligand interaction profiler.')
- textlines.append('Nucl. Acids Res. (1 July 2015) 43 (W1): W443-W447. doi: 10.1093/nar/gkv315\n')
+ textlines.append(
+ "Created on %s using PLIP v%s\n" % (time.strftime("%Y/%m/%d"), __version__)
+ )
+ textlines.append("If you are using PLIP in your work, please cite:")
+ textlines.append(
+ "Salentin,S. et al. PLIP: fully automated protein-ligand interaction profiler."
+ )
+ textlines.append(
+ "Nucl. Acids Res. (1 July 2015) 43 (W1): W443-W447. doi: 10.1093/nar/gkv315\n"
+ )
if len(self.excluded) != 0:
- textlines.append('Excluded molecules as ligands: %s\n' % ','.join([lig for lig in self.excluded]))
+ textlines.append(
+ "Excluded molecules as ligands: %s\n"
+ % ",".join([lig for lig in self.excluded])
+ )
if config.DNARECEPTOR:
- textlines.append('DNA/RNA in structure was chosen as the receptor part.\n')
+ textlines.append("DNA/RNA in structure was chosen as the receptor part.\n")
return textlines
def get_bindingsite_data(self):
@@ -80,21 +98,24 @@ class StructureReport:
for i, site in enumerate(sorted(self.mol.interaction_sets)):
s = self.mol.interaction_sets[site]
bindingsite = BindingSiteReport(s).generate_xml()
- bindingsite.set('id', str(i + 1))
- bindingsite.set('has_interactions', 'False')
+ bindingsite.set("id", str(i + 1))
+ bindingsite.set("has_interactions", "False")
self.xmlreport.insert(i + 1, bindingsite)
for itype in BindingSiteReport(s).generate_txt():
self.txtreport.append(itype)
if not s.no_interactions:
- bindingsite.set('has_interactions', 'True')
+ bindingsite.set("has_interactions", "True")
else:
- self.txtreport.append('No interactions detected.')
+ self.txtreport.append("No interactions detected.")
def write_xml(self, as_string=False):
"""Write the XML report"""
if not as_string:
- et.ElementTree(self.xmlreport).write('{}/{}.xml'.format(self.outpath, self.outputprefix), pretty_print=True,
- xml_declaration=True)
+ et.ElementTree(self.xmlreport).write(
+ "{}/{}.xml".format(self.outpath, self.outputprefix),
+ pretty_print=True,
+ xml_declaration=True,
+ )
else:
output = et.tostring(self.xmlreport, pretty_print=True)
if config.RAWSTRING:
@@ -104,10 +125,10 @@ class StructureReport:
def write_txt(self, as_string=False):
"""Write the TXT report"""
if not as_string:
- with open('{}/{}.txt'.format(self.outpath, self.outputprefix), 'w') as f:
- [f.write(textline + '\n') for textline in self.txtreport]
+ with open("{}/{}.txt".format(self.outpath, self.outputprefix), "w") as f:
+ [f.write(textline + "\n") for textline in self.txtreport]
else:
- output = '\n'.join(self.txtreport)
+ output = "\n".join(self.txtreport)
if config.RAWSTRING:
output = repr(output)
print(output)
@@ -126,7 +147,9 @@ class BindingSiteReport:
self.ligand = self.complex.ligand
self.bindingsite = self.complex.bindingsite
self.output_path = self.complex.output_path
- self.bsid = ':'.join([self.ligand.hetid, self.ligand.chain, str(self.ligand.position)])
+ self.bsid = ":".join(
+ [self.ligand.hetid, self.ligand.chain, str(self.ligand.position)]
+ )
self.longname = self.ligand.longname
self.ligtype = self.ligand.type
self.bs_res = self.bindingsite.bs_res
@@ -141,163 +164,408 @@ class BindingSiteReport:
############################
self.hydrophobic_features = (
- 'RESNR', 'RESTYPE', 'RESCHAIN', 'RESNR_LIG', 'RESTYPE_LIG', 'RESCHAIN_LIG', 'DIST', 'LIGCARBONIDX',
- 'PROTCARBONIDX', 'LIGCOO',
- 'PROTCOO')
+ "RESNR",
+ "RESTYPE",
+ "RESCHAIN",
+ "RESNR_LIG",
+ "RESTYPE_LIG",
+ "RESCHAIN_LIG",
+ "DIST",
+ "LIGCARBONIDX",
+ "PROTCARBONIDX",
+ "LIGCOO",
+ "PROTCOO",
+ )
self.hydrophobic_info = []
for hydroph in self.complex.hydrophobic_contacts:
- self.hydrophobic_info.append((hydroph.resnr, hydroph.restype, hydroph.reschain, hydroph.resnr_l,
- hydroph.restype_l, hydroph.reschain_l, '%.2f' % hydroph.distance,
- hydroph.ligatom_orig_idx, hydroph.bsatom_orig_idx, hydroph.ligatom.coords,
- hydroph.bsatom.coords))
+ self.hydrophobic_info.append(
+ (
+ hydroph.resnr,
+ hydroph.restype,
+ hydroph.reschain,
+ hydroph.resnr_l,
+ hydroph.restype_l,
+ hydroph.reschain_l,
+ "%.2f" % hydroph.distance,
+ hydroph.ligatom_orig_idx,
+ hydroph.bsatom_orig_idx,
+ hydroph.ligatom.coords,
+ hydroph.bsatom.coords,
+ )
+ )
##################
# HYDROGEN BONDS #
##################
self.hbond_features = (
- 'RESNR', 'RESTYPE', 'RESCHAIN', 'RESNR_LIG', 'RESTYPE_LIG', 'RESCHAIN_LIG', 'SIDECHAIN', 'DIST_H-A',
- 'DIST_D-A',
- 'DON_ANGLE',
- 'PROTISDON', 'DONORIDX', 'DONORTYPE', 'ACCEPTORIDX', 'ACCEPTORTYPE', 'LIGCOO', 'PROTCOO')
+ "RESNR",
+ "RESTYPE",
+ "RESCHAIN",
+ "RESNR_LIG",
+ "RESTYPE_LIG",
+ "RESCHAIN_LIG",
+ "SIDECHAIN",
+ "DIST_H-A",
+ "DIST_D-A",
+ "DON_ANGLE",
+ "PROTISDON",
+ "DONORIDX",
+ "DONORTYPE",
+ "ACCEPTORIDX",
+ "ACCEPTORTYPE",
+ "LIGCOO",
+ "PROTCOO",
+ )
self.hbond_info = []
for hbond in self.complex.hbonds_pdon + self.complex.hbonds_ldon:
- ligatom, protatom = (hbond.a, hbond.d) if hbond.protisdon else (hbond.d, hbond.a)
- self.hbond_info.append((hbond.resnr, hbond.restype, hbond.reschain, hbond.resnr_l, hbond.restype_l,
- hbond.reschain_l, hbond.sidechain,
- '%.2f' % hbond.distance_ah, '%.2f' % hbond.distance_ad, '%.2f' % hbond.angle,
- hbond.protisdon, hbond.d_orig_idx, hbond.dtype, hbond.a_orig_idx, hbond.atype,
- ligatom.coords, protatom.coords))
+ ligatom, protatom = (
+ (hbond.a, hbond.d) if hbond.protisdon else (hbond.d, hbond.a)
+ )
+ self.hbond_info.append(
+ (
+ hbond.resnr,
+ hbond.restype,
+ hbond.reschain,
+ hbond.resnr_l,
+ hbond.restype_l,
+ hbond.reschain_l,
+ hbond.sidechain,
+ "%.2f" % hbond.distance_ah,
+ "%.2f" % hbond.distance_ad,
+ "%.2f" % hbond.angle,
+ hbond.protisdon,
+ hbond.d_orig_idx,
+ hbond.dtype,
+ hbond.a_orig_idx,
+ hbond.atype,
+ ligatom.coords,
+ protatom.coords,
+ )
+ )
#################
# WATER-BRIDGES #
#################
self.waterbridge_features = (
- 'RESNR', 'RESTYPE', 'RESCHAIN', 'RESNR_LIG', 'RESTYPE_LIG', 'RESCHAIN_LIG', 'DIST_A-W', 'DIST_D-W',
- 'DON_ANGLE',
- 'WATER_ANGLE',
- 'PROTISDON', 'DONOR_IDX', 'DONORTYPE', 'ACCEPTOR_IDX', 'ACCEPTORTYPE', 'WATER_IDX',
- 'LIGCOO', 'PROTCOO', 'WATERCOO')
+ "RESNR",
+ "RESTYPE",
+ "RESCHAIN",
+ "RESNR_LIG",
+ "RESTYPE_LIG",
+ "RESCHAIN_LIG",
+ "DIST_A-W",
+ "DIST_D-W",
+ "DON_ANGLE",
+ "WATER_ANGLE",
+ "PROTISDON",
+ "DONOR_IDX",
+ "DONORTYPE",
+ "ACCEPTOR_IDX",
+ "ACCEPTORTYPE",
+ "WATER_IDX",
+ "LIGCOO",
+ "PROTCOO",
+ "WATERCOO",
+ )
# The coordinate format is an exception here, since the interaction is not only between ligand and protein
self.waterbridge_info = []
for wbridge in self.complex.water_bridges:
- lig, prot = (wbridge.a, wbridge.d) if wbridge.protisdon else (wbridge.d, wbridge.a)
- self.waterbridge_info.append((wbridge.resnr, wbridge.restype, wbridge.reschain, wbridge.resnr_l,
- wbridge.restype_l, wbridge.reschain_l,
- '%.2f' % wbridge.distance_aw, '%.2f' % wbridge.distance_dw,
- '%.2f' % wbridge.d_angle, '%.2f' % wbridge.w_angle, wbridge.protisdon,
- wbridge.d_orig_idx, wbridge.dtype, wbridge.a_orig_idx, wbridge.atype,
- wbridge.water_orig_idx, lig.coords, prot.coords, wbridge.water.coords))
+ lig, prot = (
+ (wbridge.a, wbridge.d) if wbridge.protisdon else (wbridge.d, wbridge.a)
+ )
+ self.waterbridge_info.append(
+ (
+ wbridge.resnr,
+ wbridge.restype,
+ wbridge.reschain,
+ wbridge.resnr_l,
+ wbridge.restype_l,
+ wbridge.reschain_l,
+ "%.2f" % wbridge.distance_aw,
+ "%.2f" % wbridge.distance_dw,
+ "%.2f" % wbridge.d_angle,
+ "%.2f" % wbridge.w_angle,
+ wbridge.protisdon,
+ wbridge.d_orig_idx,
+ wbridge.dtype,
+ wbridge.a_orig_idx,
+ wbridge.atype,
+ wbridge.water_orig_idx,
+ lig.coords,
+ prot.coords,
+ wbridge.water.coords,
+ )
+ )
################
# SALT BRIDGES #
################
self.saltbridge_features = (
- 'RESNR', 'RESTYPE', 'RESCHAIN', 'RESNR_LIG', 'RESTYPE_LIG', 'RESCHAIN_LIG', 'DIST', 'PROTISPOS',
- 'LIG_GROUP',
- 'LIG_IDX_LIST',
- 'LIGCOO', 'PROTCOO')
+ "RESNR",
+ "RESTYPE",
+ "RESCHAIN",
+ "RESNR_LIG",
+ "RESTYPE_LIG",
+ "RESCHAIN_LIG",
+ "DIST",
+ "PROTISPOS",
+ "LIG_GROUP",
+ "LIG_IDX_LIST",
+ "LIGCOO",
+ "PROTCOO",
+ )
self.saltbridge_info = []
for sb in self.complex.saltbridge_lneg + self.complex.saltbridge_pneg:
if sb.protispos:
- group, ids = sb.negative.fgroup, [str(x) for x in sb.negative.atoms_orig_idx]
- self.saltbridge_info.append((sb.resnr, sb.restype, sb.reschain, sb.resnr_l, sb.restype_l, sb.reschain_l,
- '%.2f' % sb.distance, sb.protispos,
- group.capitalize(), ",".join(ids),
- tuple(sb.negative.center), tuple(sb.positive.center)))
+ group, ids = (
+ sb.negative.fgroup,
+ [str(x) for x in sb.negative.atoms_orig_idx],
+ )
+ self.saltbridge_info.append(
+ (
+ sb.resnr,
+ sb.restype,
+ sb.reschain,
+ sb.resnr_l,
+ sb.restype_l,
+ sb.reschain_l,
+ "%.2f" % sb.distance,
+ sb.protispos,
+ group.capitalize(),
+ ",".join(ids),
+ tuple(sb.negative.center),
+ tuple(sb.positive.center),
+ )
+ )
else:
- group, ids = sb.positive.fgroup, [str(x) for x in sb.positive.atoms_orig_idx]
- self.saltbridge_info.append((sb.resnr, sb.restype, sb.reschain, sb.resnr_l, sb.restype_l, sb.reschain_l,
- '%.2f' % sb.distance, sb.protispos,
- group.capitalize(), ",".join(ids),
- tuple(sb.positive.center), tuple(sb.negative.center)))
+ group, ids = (
+ sb.positive.fgroup,
+ [str(x) for x in sb.positive.atoms_orig_idx],
+ )
+ self.saltbridge_info.append(
+ (
+ sb.resnr,
+ sb.restype,
+ sb.reschain,
+ sb.resnr_l,
+ sb.restype_l,
+ sb.reschain_l,
+ "%.2f" % sb.distance,
+ sb.protispos,
+ group.capitalize(),
+ ",".join(ids),
+ tuple(sb.positive.center),
+ tuple(sb.negative.center),
+ )
+ )
###############
# PI-STACKING #
###############
self.pistacking_features = (
- 'RESNR', 'RESTYPE', 'RESCHAIN', 'RESNR_LIG', 'RESTYPE_LIG', 'RESCHAIN_LIG', 'CENTDIST', 'ANGLE', 'OFFSET',
- 'TYPE',
- 'LIG_IDX_LIST', 'LIGCOO', 'PROTCOO')
+ "RESNR",
+ "RESTYPE",
+ "RESCHAIN",
+ "RESNR_LIG",
+ "RESTYPE_LIG",
+ "RESCHAIN_LIG",
+ "CENTDIST",
+ "ANGLE",
+ "OFFSET",
+ "TYPE",
+ "LIG_IDX_LIST",
+ "LIGCOO",
+ "PROTCOO",
+ )
self.pistacking_info = []
for stack in self.complex.pistacking:
ids = [str(x) for x in stack.ligandring.atoms_orig_idx]
- self.pistacking_info.append((stack.resnr, stack.restype, stack.reschain, stack.resnr_l, stack.restype_l,
- stack.reschain_l, '%.2f' % stack.distance,
- '%.2f' % stack.angle, '%.2f' % stack.offset, stack.type, ",".join(ids),
- tuple(stack.ligandring.center), tuple(stack.proteinring.center)))
+ self.pistacking_info.append(
+ (
+ stack.resnr,
+ stack.restype,
+ stack.reschain,
+ stack.resnr_l,
+ stack.restype_l,
+ stack.reschain_l,
+ "%.2f" % stack.distance,
+ "%.2f" % stack.angle,
+ "%.2f" % stack.offset,
+ stack.type,
+ ",".join(ids),
+ tuple(stack.ligandring.center),
+ tuple(stack.proteinring.center),
+ )
+ )
##########################
# PI-CATION INTERACTIONS #
##########################
self.pication_features = (
- 'RESNR', 'RESTYPE', 'RESCHAIN', 'RESNR_LIG', 'RESTYPE_LIG', 'RESCHAIN_LIG', 'DIST', 'OFFSET', 'PROTCHARGED',
- 'LIG_GROUP',
- 'LIG_IDX_LIST', 'LIGCOO', 'PROTCOO')
+ "RESNR",
+ "RESTYPE",
+ "RESCHAIN",
+ "RESNR_LIG",
+ "RESTYPE_LIG",
+ "RESCHAIN_LIG",
+ "DIST",
+ "OFFSET",
+ "PROTCHARGED",
+ "LIG_GROUP",
+ "LIG_IDX_LIST",
+ "LIGCOO",
+ "PROTCOO",
+ )
self.pication_info = []
for picat in self.complex.pication_laro + self.complex.pication_paro:
if picat.protcharged:
ids = [str(x) for x in picat.ring.atoms_orig_idx]
- group = 'Aromatic'
- self.pication_info.append((picat.resnr, picat.restype, picat.reschain, picat.resnr_l, picat.restype_l,
- picat.reschain_l, '%.2f' % picat.distance,
- '%.2f' % picat.offset, picat.protcharged, group, ",".join(ids),
- tuple(picat.ring.center), tuple(picat.charge.center)))
+ group = "Aromatic"
+ self.pication_info.append(
+ (
+ picat.resnr,
+ picat.restype,
+ picat.reschain,
+ picat.resnr_l,
+ picat.restype_l,
+ picat.reschain_l,
+ "%.2f" % picat.distance,
+ "%.2f" % picat.offset,
+ picat.protcharged,
+ group,
+ ",".join(ids),
+ tuple(picat.ring.center),
+ tuple(picat.charge.center),
+ )
+ )
else:
ids = [str(x) for x in picat.charge.atoms_orig_idx]
group = picat.charge.fgroup
- self.pication_info.append((picat.resnr, picat.restype, picat.reschain, picat.resnr_l, picat.restype_l,
- picat.reschain_l, '%.2f' % picat.distance,
- '%.2f' % picat.offset, picat.protcharged, group, ",".join(ids),
- tuple(picat.charge.center), tuple(picat.ring.center)))
+ self.pication_info.append(
+ (
+ picat.resnr,
+ picat.restype,
+ picat.reschain,
+ picat.resnr_l,
+ picat.restype_l,
+ picat.reschain_l,
+ "%.2f" % picat.distance,
+ "%.2f" % picat.offset,
+ picat.protcharged,
+ group,
+ ",".join(ids),
+ tuple(picat.charge.center),
+ tuple(picat.ring.center),
+ )
+ )
#################
# HALOGEN BONDS #
#################
self.halogen_features = (
- 'RESNR', 'RESTYPE', 'RESCHAIN', 'RESNR_LIG', 'RESTYPE_LIG', 'RESCHAIN_LIG', 'SIDECHAIN', 'DIST',
- 'DON_ANGLE',
- 'ACC_ANGLE',
- 'DON_IDX', 'DONORTYPE', 'ACC_IDX', 'ACCEPTORTYPE', 'LIGCOO', 'PROTCOO')
+ "RESNR",
+ "RESTYPE",
+ "RESCHAIN",
+ "RESNR_LIG",
+ "RESTYPE_LIG",
+ "RESCHAIN_LIG",
+ "SIDECHAIN",
+ "DIST",
+ "DON_ANGLE",
+ "ACC_ANGLE",
+ "DON_IDX",
+ "DONORTYPE",
+ "ACC_IDX",
+ "ACCEPTORTYPE",
+ "LIGCOO",
+ "PROTCOO",
+ )
self.halogen_info = []
for halogen in self.complex.halogen_bonds:
- self.halogen_info.append((halogen.resnr, halogen.restype, halogen.reschain, halogen.resnr_l,
- halogen.restype_l, halogen.reschain_l, halogen.sidechain,
- '%.2f' % halogen.distance, '%.2f' % halogen.don_angle, '%.2f' % halogen.acc_angle,
- halogen.don_orig_idx, halogen.donortype,
- halogen.acc_orig_idx, halogen.acctype,
- halogen.acc.o.coords, halogen.don.x.coords))
+ self.halogen_info.append(
+ (
+ halogen.resnr,
+ halogen.restype,
+ halogen.reschain,
+ halogen.resnr_l,
+ halogen.restype_l,
+ halogen.reschain_l,
+ halogen.sidechain,
+ "%.2f" % halogen.distance,
+ "%.2f" % halogen.don_angle,
+ "%.2f" % halogen.acc_angle,
+ halogen.don_orig_idx,
+ halogen.donortype,
+ halogen.acc_orig_idx,
+ halogen.acctype,
+ halogen.acc.o.coords,
+ halogen.don.x.coords,
+ )
+ )
###################
# METAL COMPLEXES #
###################
self.metal_features = (
- 'RESNR', 'RESTYPE', 'RESCHAIN', 'RESNR_LIG', 'RESTYPE_LIG', 'RESCHAIN_LIG', 'METAL_IDX', 'METAL_TYPE',
- 'TARGET_IDX', 'TARGET_TYPE',
- 'COORDINATION', 'DIST', 'LOCATION', 'RMS', 'GEOMETRY', 'COMPLEXNUM', 'METALCOO',
- 'TARGETCOO')
+ "RESNR",
+ "RESTYPE",
+ "RESCHAIN",
+ "RESNR_LIG",
+ "RESTYPE_LIG",
+ "RESCHAIN_LIG",
+ "METAL_IDX",
+ "METAL_TYPE",
+ "TARGET_IDX",
+ "TARGET_TYPE",
+ "COORDINATION",
+ "DIST",
+ "LOCATION",
+ "RMS",
+ "GEOMETRY",
+ "COMPLEXNUM",
+ "METALCOO",
+ "TARGETCOO",
+ )
self.metal_info = []
# Coordinate format here is non-standard since the interaction partner can be either ligand or protein
for m in self.complex.metal_complexes:
self.metal_info.append(
- (m.resnr, m.restype, m.reschain, m.resnr_l, m.restype_l, m.reschain_l, m.metal_orig_idx, m.metal_type,
- m.target_orig_idx, m.target_type, m.coordination_num, '%.2f' % m.distance,
- m.location, '%.2f' % m.rms, m.geometry, str(m.complexnum), m.metal.coords,
- m.target.atom.coords))
+ (
+ m.resnr,
+ m.restype,
+ m.reschain,
+ m.resnr_l,
+ m.restype_l,
+ m.reschain_l,
+ m.metal_orig_idx,
+ m.metal_type,
+ m.target_orig_idx,
+ m.target_type,
+ m.coordination_num,
+ "%.2f" % m.distance,
+ m.location,
+ "%.2f" % m.rms,
+ m.geometry,
+ str(m.complexnum),
+ m.metal.coords,
+ m.target.atom.coords,
+ )
+ )
def write_section(self, name, features, info, f):
"""Provides formatting for one section (e.g. hydrogen bonds)"""
if not len(info) == 0:
- f.write('\n\n### %s ###\n' % name)
- f.write('%s\n' % '\t'.join(features))
+ f.write("\n\n### %s ###\n" % name)
+ f.write("%s\n" % "\t".join(features))
for line in info:
- f.write('%s\n' % '\t'.join(map(str, line)))
+ f.write("%s\n" % "\t".join(map(str, line)))
def rst_table(self, array):
"""Given an array, the function formats and returns and table in rST format."""
@@ -309,62 +577,77 @@ class BindingSiteReport:
cell_dict[j] = []
cell_dict[j].append(val)
for item in cell_dict:
- cell_dict[item] = max([len(x) for x in cell_dict[item]]) + 1 # Contains adapted width for each column
+ cell_dict[item] = (
+ max([len(x) for x in cell_dict[item]]) + 1
+ ) # Contains adapted width for each column
# Format top line
num_cols = len(array[0])
- form = '+'
+ form = "+"
for col in range(num_cols):
- form += (cell_dict[col] + 1) * '-'
- form += '+'
- form += '\n'
+ form += (cell_dict[col] + 1) * "-"
+ form += "+"
+ form += "\n"
# Format values
for i, row in enumerate(array):
- form += '| '
+ form += "| "
for j, val in enumerate(row):
cell_width = cell_dict[j]
- form += str(val) + (cell_width - len(val)) * ' ' + '| '
+ form += str(val) + (cell_width - len(val)) * " " + "| "
form.rstrip()
- form += '\n'
+ form += "\n"
# Seperation lines
- form += '+'
+ form += "+"
if i == 0:
- sign = '='
+ sign = "="
else:
- sign = '-'
+ sign = "-"
for col in range(num_cols):
form += (cell_dict[col] + 1) * sign
- form += '+'
- form += '\n'
+ form += "+"
+ form += "\n"
return form
def generate_txt(self):
"""Generates an flat text report for a single binding site"""
txt = []
- titletext = '%s (%s) - %s' % (self.bsid, self.longname, self.ligtype)
+ titletext = "%s (%s) - %s" % (self.bsid, self.longname, self.ligtype)
txt.append(titletext)
for i, member in enumerate(self.lig_members[1:]):
- txt.append(' + %s' % ":".join(str(element) for element in member))
+ txt.append(" + %s" % ":".join(str(element) for element in member))
txt.append("-" * len(titletext))
- txt.append("Interacting chain(s): %s\n" % ','.join([chain for chain in self.interacting_chains]))
- for section in [['Hydrophobic Interactions', self.hydrophobic_features, self.hydrophobic_info],
- ['Hydrogen Bonds', self.hbond_features, self.hbond_info],
- ['Water Bridges', self.waterbridge_features, self.waterbridge_info],
- ['Salt Bridges', self.saltbridge_features, self.saltbridge_info],
- ['pi-Stacking', self.pistacking_features, self.pistacking_info],
- ['pi-Cation Interactions', self.pication_features, self.pication_info],
- ['Halogen Bonds', self.halogen_features, self.halogen_info],
- ['Metal Complexes', self.metal_features, self.metal_info]]:
+ txt.append(
+ "Interacting chain(s): %s\n"
+ % ",".join([chain for chain in self.interacting_chains])
+ )
+ for section in [
+ [
+ "Hydrophobic Interactions",
+ self.hydrophobic_features,
+ self.hydrophobic_info,
+ ],
+ ["Hydrogen Bonds", self.hbond_features, self.hbond_info],
+ ["Water Bridges", self.waterbridge_features, self.waterbridge_info],
+ ["Salt Bridges", self.saltbridge_features, self.saltbridge_info],
+ ["pi-Stacking", self.pistacking_features, self.pistacking_info],
+ ["pi-Cation Interactions", self.pication_features, self.pication_info],
+ ["Halogen Bonds", self.halogen_features, self.halogen_info],
+ ["Metal Complexes", self.metal_features, self.metal_info],
+ ]:
iname, features, interaction_information = section
# Sort results first by res number, then by distance and finally ligand coordinates to get a unique order
- interaction_information = sorted(interaction_information, key=itemgetter(0, 2, -2))
+ interaction_information = sorted(
+ interaction_information, key=itemgetter(0, 2, -2)
+ )
if not len(interaction_information) == 0:
- txt.append('\n**%s**' % iname)
- table = [features, ]
+ txt.append("\n**%s**" % iname)
+ table = [
+ features,
+ ]
for single_contact in interaction_information:
values = []
for x in single_contact:
@@ -376,122 +659,185 @@ class BindingSiteReport:
values.append(str(x))
table.append(values)
txt.append(self.rst_table(table))
- txt.append('\n')
+ txt.append("\n")
return txt
def generate_xml(self):
"""Generates an XML-formatted report for a single binding site"""
- report = et.Element('bindingsite')
- identifiers = et.SubElement(report, 'identifiers')
- longname = et.SubElement(identifiers, 'longname')
- ligtype = et.SubElement(identifiers, 'ligtype')
- hetid = et.SubElement(identifiers, 'hetid')
- chain = et.SubElement(identifiers, 'chain')
- position = et.SubElement(identifiers, 'position')
- composite = et.SubElement(identifiers, 'composite')
- members = et.SubElement(identifiers, 'members')
- smiles = et.SubElement(identifiers, 'smiles')
- inchikey = et.SubElement(identifiers, 'inchikey')
+ report = et.Element("bindingsite")
+ identifiers = et.SubElement(report, "identifiers")
+ longname = et.SubElement(identifiers, "longname")
+ ligtype = et.SubElement(identifiers, "ligtype")
+ hetid = et.SubElement(identifiers, "hetid")
+ chain = et.SubElement(identifiers, "chain")
+ position = et.SubElement(identifiers, "position")
+ composite = et.SubElement(identifiers, "composite")
+ members = et.SubElement(identifiers, "members")
+ smiles = et.SubElement(identifiers, "smiles")
+ inchikey = et.SubElement(identifiers, "inchikey")
# Ligand properties. Number of (unpaired) functional atoms and rings.
- lig_properties = et.SubElement(report, 'lig_properties')
- num_heavy_atoms = et.SubElement(lig_properties, 'num_heavy_atoms')
- num_hbd = et.SubElement(lig_properties, 'num_hbd')
+ lig_properties = et.SubElement(report, "lig_properties")
+ num_heavy_atoms = et.SubElement(lig_properties, "num_heavy_atoms")
+ num_hbd = et.SubElement(lig_properties, "num_hbd")
num_hbd.text = str(self.ligand.num_hbd)
- num_unpaired_hbd = et.SubElement(lig_properties, 'num_unpaired_hbd')
+ num_unpaired_hbd = et.SubElement(lig_properties, "num_unpaired_hbd")
num_unpaired_hbd.text = str(self.complex.num_unpaired_hbd)
- num_hba = et.SubElement(lig_properties, 'num_hba')
+ num_hba = et.SubElement(lig_properties, "num_hba")
num_hba.text = str(self.ligand.num_hba)
- num_unpaired_hba = et.SubElement(lig_properties, 'num_unpaired_hba')
+ num_unpaired_hba = et.SubElement(lig_properties, "num_unpaired_hba")
num_unpaired_hba.text = str(self.complex.num_unpaired_hba)
- num_hal = et.SubElement(lig_properties, 'num_hal')
+ num_hal = et.SubElement(lig_properties, "num_hal")
num_hal.text = str(self.ligand.num_hal)
- num_unpaired_hal = et.SubElement(lig_properties, 'num_unpaired_hal')
+ num_unpaired_hal = et.SubElement(lig_properties, "num_unpaired_hal")
num_unpaired_hal.text = str(self.complex.num_unpaired_hal)
- num_aromatic_rings = et.SubElement(lig_properties, 'num_aromatic_rings')
+ num_aromatic_rings = et.SubElement(lig_properties, "num_aromatic_rings")
num_aromatic_rings.text = str(self.ligand.num_rings)
- num_rot_bonds = et.SubElement(lig_properties, 'num_rotatable_bonds')
+ num_rot_bonds = et.SubElement(lig_properties, "num_rotatable_bonds")
num_rot_bonds.text = str(self.ligand.num_rot_bonds)
- molweight = et.SubElement(lig_properties, 'molweight')
+ molweight = et.SubElement(lig_properties, "molweight")
molweight.text = str(self.ligand.molweight)
- logp = et.SubElement(lig_properties, 'logp')
+ logp = et.SubElement(lig_properties, "logp")
logp.text = str(self.ligand.logp)
- ichains = et.SubElement(report, 'interacting_chains')
- bsresidues = et.SubElement(report, 'bs_residues')
+ ichains = et.SubElement(report, "interacting_chains")
+ bsresidues = et.SubElement(report, "bs_residues")
for i, ichain in enumerate(self.interacting_chains):
- c = et.SubElement(ichains, 'interacting_chain', id=str(i + 1))
+ c = et.SubElement(ichains, "interacting_chain", id=str(i + 1))
c.text = ichain
for i, bsres in enumerate(self.bs_res):
- contact = 'True' if bsres in self.bs_res_interacting else 'False'
- distance = '%.1f' % self.min_dist[bsres][0]
+ contact = "True" if bsres in self.bs_res_interacting else "False"
+ distance = "%.1f" % self.min_dist[bsres][0]
aatype = self.min_dist[bsres][1]
- c = et.SubElement(bsresidues, 'bs_residue', id=str(i + 1), contact=contact, min_dist=distance, aa=aatype)
+ c = et.SubElement(
+ bsresidues,
+ "bs_residue",
+ id=str(i + 1),
+ contact=contact,
+ min_dist=distance,
+ aa=aatype,
+ )
c.text = bsres
- hetid.text, chain.text, position.text = self.ligand.hetid, self.ligand.chain, str(self.ligand.position)
- composite.text = 'True' if len(self.lig_members) > 1 else 'False'
+ hetid.text, chain.text, position.text = (
+ self.ligand.hetid,
+ self.ligand.chain,
+ str(self.ligand.position),
+ )
+ composite.text = "True" if len(self.lig_members) > 1 else "False"
longname.text = self.longname
ligtype.text = self.ligtype
smiles.text = self.ligand.smiles
inchikey.text = self.ligand.inchikey
- num_heavy_atoms.text = str(self.ligand.heavy_atoms) # Number of heavy atoms in ligand
+ num_heavy_atoms.text = str(
+ self.ligand.heavy_atoms
+ ) # Number of heavy atoms in ligand
for i, member in enumerate(self.lig_members):
bsid = ":".join(str(element) for element in member)
- m = et.SubElement(members, 'member', id=str(i + 1))
+ m = et.SubElement(members, "member", id=str(i + 1))
m.text = bsid
- interactions = et.SubElement(report, 'interactions')
+ interactions = et.SubElement(report, "interactions")
def format_interactions(element_name, features, interaction_information):
"""Returns a formatted element with interaction information."""
interaction = et.Element(element_name)
# Sort results first by res number, then by distance and finally ligand coordinates to get a unique order
- interaction_information = sorted(interaction_information, key=itemgetter(0, 2, -2))
+ interaction_information = sorted(
+ interaction_information, key=itemgetter(0, 2, -2)
+ )
for j, single_contact in enumerate(interaction_information):
- if not element_name == 'metal_complexes':
- new_contact = et.SubElement(interaction, element_name[:-1], id=str(j + 1))
+ if not element_name == "metal_complexes":
+ new_contact = et.SubElement(
+ interaction, element_name[:-1], id=str(j + 1)
+ )
else: # Metal Complex[es]
- new_contact = et.SubElement(interaction, element_name[:-2], id=str(j + 1))
+ new_contact = et.SubElement(
+ interaction, element_name[:-2], id=str(j + 1)
+ )
for i, feature in enumerate(single_contact):
# Just assign the value unless it's an atom list, use subelements in this case
- if features[i] == 'LIG_IDX_LIST':
+ if features[i] == "LIG_IDX_LIST":
feat = et.SubElement(new_contact, features[i].lower())
- for k, atm_idx in enumerate(feature.split(',')):
- idx = et.SubElement(feat, 'idx', id=str(k + 1))
+ for k, atm_idx in enumerate(feature.split(",")):
+ idx = et.SubElement(feat, "idx", id=str(k + 1))
idx.text = str(atm_idx)
- elif features[i].endswith('COO'):
+ elif features[i].endswith("COO"):
feat = et.SubElement(new_contact, features[i].lower())
xc, yc, zc = feature
- xcoo = et.SubElement(feat, 'x')
- xcoo.text = '%.3f' % xc
- ycoo = et.SubElement(feat, 'y')
- ycoo.text = '%.3f' % yc
- zcoo = et.SubElement(feat, 'z')
- zcoo.text = '%.3f' % zc
+ xcoo = et.SubElement(feat, "x")
+ xcoo.text = "%.3f" % xc
+ ycoo = et.SubElement(feat, "y")
+ ycoo.text = "%.3f" % yc
+ zcoo = et.SubElement(feat, "z")
+ zcoo.text = "%.3f" % zc
else:
feat = et.SubElement(new_contact, features[i].lower())
feat.text = str(feature)
return interaction
- interactions.append(format_interactions('hydrophobic_interactions', self.hydrophobic_features,
- self.hydrophobic_info))
- interactions.append(format_interactions('hydrogen_bonds', self.hbond_features, self.hbond_info))
- interactions.append(format_interactions('water_bridges', self.waterbridge_features, self.waterbridge_info))
- interactions.append(format_interactions('salt_bridges', self.saltbridge_features, self.saltbridge_info))
- interactions.append(format_interactions('pi_stacks', self.pistacking_features, self.pistacking_info))
- interactions.append(format_interactions('pi_cation_interactions', self.pication_features, self.pication_info))
- interactions.append(format_interactions('halogen_bonds', self.halogen_features, self.halogen_info))
- interactions.append(format_interactions('metal_complexes', self.metal_features, self.metal_info))
+ interactions.append(
+ format_interactions(
+ "hydrophobic_interactions",
+ self.hydrophobic_features,
+ self.hydrophobic_info,
+ )
+ )
+ interactions.append(
+ format_interactions("hydrogen_bonds", self.hbond_features, self.hbond_info)
+ )
+ interactions.append(
+ format_interactions(
+ "water_bridges", self.waterbridge_features, self.waterbridge_info
+ )
+ )
+ interactions.append(
+ format_interactions(
+ "salt_bridges", self.saltbridge_features, self.saltbridge_info
+ )
+ )
+ interactions.append(
+ format_interactions(
+ "pi_stacks", self.pistacking_features, self.pistacking_info
+ )
+ )
+ interactions.append(
+ format_interactions(
+ "pi_cation_interactions", self.pication_features, self.pication_info
+ )
+ )
+ interactions.append(
+ format_interactions(
+ "halogen_bonds", self.halogen_features, self.halogen_info
+ )
+ )
+ interactions.append(
+ format_interactions("metal_complexes", self.metal_features, self.metal_info)
+ )
# Mappings
- mappings = et.SubElement(report, 'mappings')
- smiles_to_pdb = et.SubElement(mappings, 'smiles_to_pdb') # SMILES numbering to PDB file numbering (atoms)
- bsid = ':'.join([self.ligand.hetid, self.ligand.chain, str(self.ligand.position)])
+ mappings = et.SubElement(report, "mappings")
+ smiles_to_pdb = et.SubElement(
+ mappings, "smiles_to_pdb"
+ ) # SMILES numbering to PDB file numbering (atoms)
+ bsid = ":".join(
+ [self.ligand.hetid, self.ligand.chain, str(self.ligand.position)]
+ )
if self.ligand.atomorder is not None:
- smiles_to_pdb_map = [(key, self.ligand.Mapper.mapid(self.ligand.can_to_pdb[key],
- mtype='protein', bsid=bsid)) for key in
- self.ligand.can_to_pdb]
- smiles_to_pdb.text = ','.join([str(mapping[0]) + ':' + str(mapping[1]) for mapping in smiles_to_pdb_map])
+ smiles_to_pdb_map = [
+ (
+ key,
+ self.ligand.Mapper.mapid(
+ self.ligand.can_to_pdb[key], mtype="protein", bsid=bsid
+ ),
+ )
+ for key in self.ligand.can_to_pdb
+ ]
+ smiles_to_pdb.text = ",".join(
+ [
+ str(mapping[0]) + ":" + str(mapping[1])
+ for mapping in smiles_to_pdb_map
+ ]
+ )
else:
- smiles_to_pdb.text = ''
+ smiles_to_pdb.text = ""
return report
diff --git a/plip/exchange/webservices.py b/plip/exchange/webservices.py
index 0c8cd3e..61cb6f5 100644
--- a/plip/exchange/webservices.py
+++ b/plip/exchange/webservices.py
@@ -11,44 +11,50 @@ logger = logger.get_logger()
def check_pdb_status(pdbid):
"""Returns the status and up-to-date entry in the PDB for a given PDB ID"""
- url = 'http://www.rcsb.org/pdb/rest/idStatus?structureId=%s' % pdbid
+ url = "http://www.rcsb.org/pdb/rest/idStatus?structureId=%s" % pdbid
xmlf = urlopen(url)
xml = et.parse(xmlf)
xmlf.close()
status = None
current_pdbid = pdbid
- for df in xml.xpath('//record'):
- status = df.attrib['status'] # Status of an entry can be either 'UNKWOWN', 'OBSOLETE', or 'CURRENT'
- if status == 'OBSOLETE':
- current_pdbid = df.attrib['replacedBy'] # Contains the up-to-date PDB ID for obsolete entries
+ for df in xml.xpath("//record"):
+ status = df.attrib[
+ "status"
+ ] # Status of an entry can be either 'UNKWOWN', 'OBSOLETE', or 'CURRENT'
+ if status == "OBSOLETE":
+ current_pdbid = df.attrib[
+ "replacedBy"
+ ] # Contains the up-to-date PDB ID for obsolete entries
return [status, current_pdbid.lower()]
def fetch_pdb(pdbid):
"""Get the newest entry from the RCSB server for the given PDB ID. Exits with '1' if PDB ID is invalid."""
pdbid = pdbid.lower()
- logger.info(f'checking status of PDB-ID {pdbid}')
+ logger.info(f"checking status of PDB-ID {pdbid}")
state, current_entry = check_pdb_status(pdbid) # Get state and current PDB ID
- if state == 'OBSOLETE':
- logger.info(f'entry is obsolete, getting {current_entry} instead')
- elif state == 'CURRENT':
- logger.info('entry is up-to-date')
- elif state == 'UNKNOWN':
- logger.error('invalid PDB-ID (entry does not exist on PDB server)')
+ if state == "OBSOLETE":
+ logger.info(f"entry is obsolete, getting {current_entry} instead")
+ elif state == "CURRENT":
+ logger.info("entry is up-to-date")
+ elif state == "UNKNOWN":
+ logger.error("invalid PDB-ID (entry does not exist on PDB server)")
sys.exit(1)
- logger.info('downloading file from PDB')
+ logger.info("downloading file from PDB")
# get URL for current entry
# @todo needs update to react properly on response codes of RCSB servers
- pdburl = f'http://www.rcsb.org/pdb/files/{current_entry}.pdb'
+ pdburl = f"http://www.rcsb.org/pdb/files/{current_entry}.pdb"
try:
pdbfile = urlopen(pdburl).read().decode()
# If no PDB file is available, a text is now shown with "We're sorry, but ..."
# Could previously be distinguished by an HTTP error
- if 'sorry' in pdbfile:
- logger.error('no file in PDB format available from wwPDB for the given PDB ID.')
+ if "sorry" in pdbfile:
+ logger.error(
+ "no file in PDB format available from wwPDB for the given PDB ID."
+ )
sys.exit(1)
except HTTPError:
- logger.error('no file in PDB format available from wwPDB for the given PDB ID')
+ logger.error("no file in PDB format available from wwPDB for the given PDB ID")
sys.exit(1)
return [pdbfile, current_entry]
diff --git a/plip/exchange/xml.py b/plip/exchange/xml.py
index a5eee21..92399c2 100644
--- a/plip/exchange/xml.py
+++ b/plip/exchange/xml.py
@@ -8,16 +8,16 @@ class XMLStorage:
def getdata(self, tree, location, force_string=False):
"""Gets XML data from a specific element and handles types."""
- found = tree.xpath('%s/text()' % location)
+ found = tree.xpath("%s/text()" % location)
if not found:
return None
else:
data = found[0]
if force_string:
return data
- if data == 'True':
+ if data == "True":
return True
- elif data == 'False':
+ elif data == "False":
return False
else:
try:
@@ -31,22 +31,26 @@ class XMLStorage:
def getcoordinates(self, tree, location):
"""Gets coordinates from a specific element in PLIP XML"""
- return tuple(float(x) for x in tree.xpath('.//%s/*/text()' % location))
+ return tuple(float(x) for x in tree.xpath(".//%s/*/text()" % location))
class Interaction(XMLStorage):
"""Stores information on a specific interaction type"""
def __init__(self, interaction_part):
- self.id = interaction_part.get('id')
- self.resnr = self.getdata(interaction_part, 'resnr')
- self.restype = self.getdata(interaction_part, 'restype', force_string=True)
- self.reschain = self.getdata(interaction_part, 'reschain', force_string=True)
- self.resnr_lig = self.getdata(interaction_part, 'resnr_lig')
- self.restype_lig = self.getdata(interaction_part, 'restype_lig', force_string=True)
- self.reschain_lig = self.getdata(interaction_part, 'reschain_lig', force_string=True)
- self.ligcoo = self.getcoordinates(interaction_part, 'ligcoo')
- self.protcoo = self.getcoordinates(interaction_part, 'protcoo')
+ self.id = interaction_part.get("id")
+ self.resnr = self.getdata(interaction_part, "resnr")
+ self.restype = self.getdata(interaction_part, "restype", force_string=True)
+ self.reschain = self.getdata(interaction_part, "reschain", force_string=True)
+ self.resnr_lig = self.getdata(interaction_part, "resnr_lig")
+ self.restype_lig = self.getdata(
+ interaction_part, "restype_lig", force_string=True
+ )
+ self.reschain_lig = self.getdata(
+ interaction_part, "reschain_lig", force_string=True
+ )
+ self.ligcoo = self.getcoordinates(interaction_part, "ligcoo")
+ self.protcoo = self.getcoordinates(interaction_part, "protcoo")
class HydrophobicInteraction(Interaction):
@@ -54,9 +58,9 @@ class HydrophobicInteraction(Interaction):
def __init__(self, hydrophobic_part):
Interaction.__init__(self, hydrophobic_part)
- self.dist = self.getdata(hydrophobic_part, 'dist')
- self.ligcarbonidx = self.getdata(hydrophobic_part, 'ligcarbonidx')
- self.protcarbonidx = self.getdata(hydrophobic_part, 'protcarbonidx')
+ self.dist = self.getdata(hydrophobic_part, "dist")
+ self.ligcarbonidx = self.getdata(hydrophobic_part, "ligcarbonidx")
+ self.protcarbonidx = self.getdata(hydrophobic_part, "protcarbonidx")
class HydrogenBond(Interaction):
@@ -64,17 +68,17 @@ class HydrogenBond(Interaction):
def __init__(self, hbond_part):
Interaction.__init__(self, hbond_part)
- self.sidechain = self.getdata(hbond_part, 'sidechain')
- self.dist_h_a = self.getdata(hbond_part, 'dist_h-a')
- self.dist_d_a = self.getdata(hbond_part, 'dist_d-a')
+ self.sidechain = self.getdata(hbond_part, "sidechain")
+ self.dist_h_a = self.getdata(hbond_part, "dist_h-a")
+ self.dist_d_a = self.getdata(hbond_part, "dist_d-a")
self.dist = self.dist_d_a
- self.don_angle = self.getdata(hbond_part, 'don_angle')
- self.protisdon = self.getdata(hbond_part, 'protisdon')
- self.donoridx = self.getdata(hbond_part, 'donoridx')
- self.acceptoridx = self.getdata(hbond_part, 'acceptoridx')
- self.donortype = self.getdata(hbond_part, 'donortype', force_string=True)
- self.acceptortype = self.getdata(hbond_part, 'acceptortype', force_string=True)
+ self.don_angle = self.getdata(hbond_part, "don_angle")
+ self.protisdon = self.getdata(hbond_part, "protisdon")
+ self.donoridx = self.getdata(hbond_part, "donoridx")
+ self.acceptoridx = self.getdata(hbond_part, "acceptoridx")
+ self.donortype = self.getdata(hbond_part, "donortype", force_string=True)
+ self.acceptortype = self.getdata(hbond_part, "acceptortype", force_string=True)
class WaterBridge(Interaction):
@@ -82,19 +86,21 @@ class WaterBridge(Interaction):
def __init__(self, wbridge_part):
Interaction.__init__(self, wbridge_part)
- self.dist_a_w = self.getdata(wbridge_part, 'dist_a-w')
- self.dist_d_w = self.getdata(wbridge_part, 'dist_d-w')
- self.don_angle = self.getdata(wbridge_part, 'don_angle')
- self.water_angle = self.getdata(wbridge_part, 'water_angle')
- self.protisdon = self.getdata(wbridge_part, 'protisdon')
+ self.dist_a_w = self.getdata(wbridge_part, "dist_a-w")
+ self.dist_d_w = self.getdata(wbridge_part, "dist_d-w")
+ self.don_angle = self.getdata(wbridge_part, "don_angle")
+ self.water_angle = self.getdata(wbridge_part, "water_angle")
+ self.protisdon = self.getdata(wbridge_part, "protisdon")
self.dist = self.dist_a_w if self.protisdon else self.dist_d_w
- self.donor_idx = self.getdata(wbridge_part, 'donor_idx')
- self.acceptor_idx = self.getdata(wbridge_part, 'acceptor_idx')
- self.donortype = self.getdata(wbridge_part, 'donortype', force_string=True)
- self.acceptortype = self.getdata(wbridge_part, 'acceptortype', force_string=True)
- self.water_idx = self.getdata(wbridge_part, 'water_idx')
- self.watercoo = self.getcoordinates(wbridge_part, 'watercoo')
+ self.donor_idx = self.getdata(wbridge_part, "donor_idx")
+ self.acceptor_idx = self.getdata(wbridge_part, "acceptor_idx")
+ self.donortype = self.getdata(wbridge_part, "donortype", force_string=True)
+ self.acceptortype = self.getdata(
+ wbridge_part, "acceptortype", force_string=True
+ )
+ self.water_idx = self.getdata(wbridge_part, "water_idx")
+ self.watercoo = self.getcoordinates(wbridge_part, "watercoo")
class SaltBridge(Interaction):
@@ -102,11 +108,12 @@ class SaltBridge(Interaction):
def __init__(self, sbridge_part):
Interaction.__init__(self, sbridge_part)
- self.dist = self.getdata(sbridge_part, 'dist')
- self.protispos = self.getdata(sbridge_part, 'protispos')
- self.lig_group = self.getdata(sbridge_part, 'lig_group', force_string=True)
- self.lig_idx_list = [int(tagpart.text) for tagpart in
- sbridge_part.xpath('lig_idx_list/idx')]
+ self.dist = self.getdata(sbridge_part, "dist")
+ self.protispos = self.getdata(sbridge_part, "protispos")
+ self.lig_group = self.getdata(sbridge_part, "lig_group", force_string=True)
+ self.lig_idx_list = [
+ int(tagpart.text) for tagpart in sbridge_part.xpath("lig_idx_list/idx")
+ ]
class PiStacking(Interaction):
@@ -114,13 +121,14 @@ class PiStacking(Interaction):
def __init__(self, pistack_part):
Interaction.__init__(self, pistack_part)
- self.centdist = self.getdata(pistack_part, 'centdist')
+ self.centdist = self.getdata(pistack_part, "centdist")
self.dist = self.centdist
- self.angle = self.getdata(pistack_part, 'angle')
- self.offset = self.getdata(pistack_part, 'offset')
- self.type = self.getdata(pistack_part, 'type')
- self.lig_idx_list = [int(tagpart.text) for tagpart in
- pistack_part.xpath('lig_idx_list/idx')]
+ self.angle = self.getdata(pistack_part, "angle")
+ self.offset = self.getdata(pistack_part, "offset")
+ self.type = self.getdata(pistack_part, "type")
+ self.lig_idx_list = [
+ int(tagpart.text) for tagpart in pistack_part.xpath("lig_idx_list/idx")
+ ]
class PiCation(Interaction):
@@ -128,11 +136,13 @@ class PiCation(Interaction):
def __init__(self, pication_part):
Interaction.__init__(self, pication_part)
- self.dist = self.getdata(pication_part, 'dist')
- self.offset = self.getdata(pication_part, 'offset')
- self.protcharged = self.getdata(pication_part, 'protcharged')
- self.lig_group = self.getdata(pication_part, 'lig_group')
- self.lig_idx_list = [int(tag.text) for tag in pication_part.xpath('.//lig_idx_list/idx')]
+ self.dist = self.getdata(pication_part, "dist")
+ self.offset = self.getdata(pication_part, "offset")
+ self.protcharged = self.getdata(pication_part, "protcharged")
+ self.lig_group = self.getdata(pication_part, "lig_group")
+ self.lig_idx_list = [
+ int(tag.text) for tag in pication_part.xpath(".//lig_idx_list/idx")
+ ]
class HalogenBond(Interaction):
@@ -140,14 +150,16 @@ class HalogenBond(Interaction):
def __init__(self, halogen_part):
Interaction.__init__(self, halogen_part)
- self.dist = self.getdata(halogen_part, 'dist')
- self.don_angle = self.getdata(halogen_part, 'don_angle')
- self.acc_angle = self.getdata(halogen_part, 'acc_angle')
- self.donortype = self.getdata(halogen_part, 'donortype', force_string=True)
- self.acceptortype = self.getdata(halogen_part, 'acceptortype', force_string=True)
- self.don_idx = self.getdata(halogen_part, 'don_idx')
- self.acc_idx = self.getdata(halogen_part, 'acc_idx')
- self.sidechain = self.getdata(halogen_part, 'sidechain')
+ self.dist = self.getdata(halogen_part, "dist")
+ self.don_angle = self.getdata(halogen_part, "don_angle")
+ self.acc_angle = self.getdata(halogen_part, "acc_angle")
+ self.donortype = self.getdata(halogen_part, "donortype", force_string=True)
+ self.acceptortype = self.getdata(
+ halogen_part, "acceptortype", force_string=True
+ )
+ self.don_idx = self.getdata(halogen_part, "don_idx")
+ self.acc_idx = self.getdata(halogen_part, "acc_idx")
+ self.sidechain = self.getdata(halogen_part, "sidechain")
class MetalComplex(Interaction):
@@ -155,18 +167,22 @@ class MetalComplex(Interaction):
def __init__(self, metalcomplex_part):
Interaction.__init__(self, metalcomplex_part)
- self.metal_idx = self.getdata(metalcomplex_part, 'metal_idx')
- self.metal_type = self.getdata(metalcomplex_part, 'metal_type', force_string=True)
- self.target_idx = self.getdata(metalcomplex_part, 'target_idx')
- self.target_type = self.getdata(metalcomplex_part, 'target_type', force_string=True)
- self.coordination = self.getdata(metalcomplex_part, 'coordination')
- self.dist = self.getdata(metalcomplex_part, 'dist')
- self.location = self.getdata(metalcomplex_part, 'location', force_string=True)
- self.rms = self.getdata(metalcomplex_part, 'rms')
- self.geometry = self.getdata(metalcomplex_part, 'geometry', force_string=True)
- self.complexnum = self.getdata(metalcomplex_part, 'complexnum')
- self.targetcoo = self.getcoordinates(metalcomplex_part, 'targetcoo')
- self.metalcoo = self.getcoordinates(metalcomplex_part, 'metalcoo')
+ self.metal_idx = self.getdata(metalcomplex_part, "metal_idx")
+ self.metal_type = self.getdata(
+ metalcomplex_part, "metal_type", force_string=True
+ )
+ self.target_idx = self.getdata(metalcomplex_part, "target_idx")
+ self.target_type = self.getdata(
+ metalcomplex_part, "target_type", force_string=True
+ )
+ self.coordination = self.getdata(metalcomplex_part, "coordination")
+ self.dist = self.getdata(metalcomplex_part, "dist")
+ self.location = self.getdata(metalcomplex_part, "location", force_string=True)
+ self.rms = self.getdata(metalcomplex_part, "rms")
+ self.geometry = self.getdata(metalcomplex_part, "geometry", force_string=True)
+ self.complexnum = self.getdata(metalcomplex_part, "complexnum")
+ self.targetcoo = self.getcoordinates(metalcomplex_part, "targetcoo")
+ self.metalcoo = self.getcoordinates(metalcomplex_part, "metalcoo")
class BSite(XMLStorage):
@@ -175,63 +191,107 @@ class BSite(XMLStorage):
def __init__(self, bindingsite, pdbid):
self.bindingsite = bindingsite
self.pdbid = pdbid
- self.bsid = ":".join(bindingsite.xpath('identifiers/*/text()')[2:5])
+ self.bsid = ":".join(bindingsite.xpath("identifiers/*/text()")[2:5])
self.uniqueid = ":".join([self.pdbid, self.bsid])
- self.hetid = self.getdata(bindingsite, 'identifiers/hetid', force_string=True)
- self.longname = self.getdata(bindingsite, 'identifiers/longname', force_string=True)
- self.ligtype = self.getdata(bindingsite, 'identifiers/ligtype', force_string=True)
- self.smiles = self.getdata(bindingsite, 'identifiers/smiles', force_string=True)
- self.inchikey = self.getdata(bindingsite, 'identifiers/inchikey', force_string=True)
- self.position = self.getdata(bindingsite, 'identifiers/position')
- self.chain = self.getdata(bindingsite, 'identifiers/chain', force_string=True)
+ self.hetid = self.getdata(bindingsite, "identifiers/hetid", force_string=True)
+ self.longname = self.getdata(
+ bindingsite, "identifiers/longname", force_string=True
+ )
+ self.ligtype = self.getdata(
+ bindingsite, "identifiers/ligtype", force_string=True
+ )
+ self.smiles = self.getdata(bindingsite, "identifiers/smiles", force_string=True)
+ self.inchikey = self.getdata(
+ bindingsite, "identifiers/inchikey", force_string=True
+ )
+ self.position = self.getdata(bindingsite, "identifiers/position")
+ self.chain = self.getdata(bindingsite, "identifiers/chain", force_string=True)
# Information on binding site members
self.members = []
- for member in bindingsite.xpath('identifiers/members/member'):
- self.members += member.xpath('text()')
+ for member in bindingsite.xpath("identifiers/members/member"):
+ self.members += member.xpath("text()")
- self.composite = self.getdata(bindingsite, 'identifiers/composite')
+ self.composite = self.getdata(bindingsite, "identifiers/composite")
# Ligand Properties
- self.heavy_atoms = self.getdata(bindingsite, 'lig_properties/num_heavy_atoms')
- self.hbd = self.getdata(bindingsite, 'lig_properties/num_hbd')
- self.unpaired_hbd = self.getdata(bindingsite, 'lig_properties/num_unpaired_hbd')
- self.hba = self.getdata(bindingsite, 'lig_properties/num_hba')
- self.unpaired_hba = self.getdata(bindingsite, 'lig_properties/num_unpaired_hba')
- self.hal = self.getdata(bindingsite, 'lig_properties/num_hal')
- self.unpaired_hal = self.getdata(bindingsite, 'lig_properties/num_unpaired_hal')
- self.molweight = self.getdata(bindingsite, 'lig_properties/molweight')
- self.logp = self.getdata(bindingsite, 'lig_properties/logp')
- self.rotatable_bonds = self.getdata(bindingsite, 'lig_properties/num_rotatable_bonds')
- self.rings = self.getdata(bindingsite, 'lig_properties/num_aromatic_rings')
+ self.heavy_atoms = self.getdata(bindingsite, "lig_properties/num_heavy_atoms")
+ self.hbd = self.getdata(bindingsite, "lig_properties/num_hbd")
+ self.unpaired_hbd = self.getdata(bindingsite, "lig_properties/num_unpaired_hbd")
+ self.hba = self.getdata(bindingsite, "lig_properties/num_hba")
+ self.unpaired_hba = self.getdata(bindingsite, "lig_properties/num_unpaired_hba")
+ self.hal = self.getdata(bindingsite, "lig_properties/num_hal")
+ self.unpaired_hal = self.getdata(bindingsite, "lig_properties/num_unpaired_hal")
+ self.molweight = self.getdata(bindingsite, "lig_properties/molweight")
+ self.logp = self.getdata(bindingsite, "lig_properties/logp")
+ self.rotatable_bonds = self.getdata(
+ bindingsite, "lig_properties/num_rotatable_bonds"
+ )
+ self.rings = self.getdata(bindingsite, "lig_properties/num_aromatic_rings")
# Binding Site residues
self.bs_res = []
- for tagpart in bindingsite.xpath('bs_residues/bs_residue'):
+ for tagpart in bindingsite.xpath("bs_residues/bs_residue"):
resnumber, reschain = tagpart.text[:-1], tagpart.text[-1]
- aa, contact, min_dist = tagpart.get('aa'), tagpart.get('contact'), tagpart.get('min_dist')
- new_bs_res = {'resnr': int(resnumber), 'reschain': reschain, 'aa': aa,
- 'contact': True if contact == 'True' else False, 'min_dist': float(min_dist)}
+ aa, contact, min_dist = (
+ tagpart.get("aa"),
+ tagpart.get("contact"),
+ tagpart.get("min_dist"),
+ )
+ new_bs_res = {
+ "resnr": int(resnumber),
+ "reschain": reschain,
+ "aa": aa,
+ "contact": True if contact == "True" else False,
+ "min_dist": float(min_dist),
+ }
self.bs_res.append(new_bs_res)
# Interacting chains
self.interacting_chains = []
- for chain in bindingsite.xpath('interacting_chains/interacting_chain'):
- self.interacting_chains += chain.xpath('text()')
+ for chain in bindingsite.xpath("interacting_chains/interacting_chain"):
+ self.interacting_chains += chain.xpath("text()")
# Interactions
- interactions = bindingsite.xpath('interactions')[0]
- self.hydrophobics = [HydrophobicInteraction(x) for x in
- interactions.xpath('hydrophobic_interactions/hydrophobic_interaction')]
- self.hbonds = [HydrogenBond(x) for x in interactions.xpath('hydrogen_bonds/hydrogen_bond')]
- self.wbridges = [WaterBridge(x) for x in interactions.xpath('water_bridges/water_bridge')]
- self.sbridges = [SaltBridge(x) for x in interactions.xpath('salt_bridges/salt_bridge')]
- self.pi_stacks = [PiStacking(x) for x in interactions.xpath('pi_stacks/pi_stack')]
- self.pi_cations = [PiCation(x) for x in interactions.xpath('pi_cation_interactions/pi_cation_interaction')]
- self.halogens = [HalogenBond(x) for x in interactions.xpath('halogen_bonds/halogen_bond')]
- self.metal_complexes = [MetalComplex(x) for x in interactions.xpath('metal_complexes/metal_complex')]
- self.num_contacts = len(self.hydrophobics) + len(self.hbonds) + len(self.wbridges) + len(self.sbridges) + \
- len(self.pi_stacks) + len(self.pi_cations) + len(self.halogens) + len(self.metal_complexes)
+ interactions = bindingsite.xpath("interactions")[0]
+ self.hydrophobics = [
+ HydrophobicInteraction(x)
+ for x in interactions.xpath(
+ "hydrophobic_interactions/hydrophobic_interaction"
+ )
+ ]
+ self.hbonds = [
+ HydrogenBond(x) for x in interactions.xpath("hydrogen_bonds/hydrogen_bond")
+ ]
+ self.wbridges = [
+ WaterBridge(x) for x in interactions.xpath("water_bridges/water_bridge")
+ ]
+ self.sbridges = [
+ SaltBridge(x) for x in interactions.xpath("salt_bridges/salt_bridge")
+ ]
+ self.pi_stacks = [
+ PiStacking(x) for x in interactions.xpath("pi_stacks/pi_stack")
+ ]
+ self.pi_cations = [
+ PiCation(x)
+ for x in interactions.xpath("pi_cation_interactions/pi_cation_interaction")
+ ]
+ self.halogens = [
+ HalogenBond(x) for x in interactions.xpath("halogen_bonds/halogen_bond")
+ ]
+ self.metal_complexes = [
+ MetalComplex(x) for x in interactions.xpath("metal_complexes/metal_complex")
+ ]
+ self.num_contacts = (
+ len(self.hydrophobics)
+ + len(self.hbonds)
+ + len(self.wbridges)
+ + len(self.sbridges)
+ + len(self.pi_stacks)
+ + len(self.pi_cations)
+ + len(self.halogens)
+ + len(self.metal_complexes)
+ )
self.has_interactions = self.num_contacts > 0
self.get_atom_mapping()
@@ -240,25 +300,45 @@ class BSite(XMLStorage):
def get_atom_mapping(self):
"""Parses the ligand atom mapping."""
# Atom mappings
- smiles_to_pdb_mapping = self.bindingsite.xpath('mappings/smiles_to_pdb/text()')
+ smiles_to_pdb_mapping = self.bindingsite.xpath("mappings/smiles_to_pdb/text()")
if not smiles_to_pdb_mapping:
- self.mappings = {'smiles_to_pdb': None, 'pdb_to_smiles': None}
+ self.mappings = {"smiles_to_pdb": None, "pdb_to_smiles": None}
else:
- smiles_to_pdb_mapping = {int(y[0]): int(y[1]) for y in [x.split(':')
- for x in smiles_to_pdb_mapping[0].split(',')]}
- self.mappings = {'smiles_to_pdb': smiles_to_pdb_mapping}
- self.mappings['pdb_to_smiles'] = {v: k for k, v in self.mappings['smiles_to_pdb'].items()}
+ smiles_to_pdb_mapping = {
+ int(y[0]): int(y[1])
+ for y in [x.split(":") for x in smiles_to_pdb_mapping[0].split(",")]
+ }
+ self.mappings = {"smiles_to_pdb": smiles_to_pdb_mapping}
+ self.mappings["pdb_to_smiles"] = {
+ v: k for k, v in self.mappings["smiles_to_pdb"].items()
+ }
def get_counts(self):
"""counts the interaction types and backbone hydrogen bonding in a binding site"""
hbondsback = len([hb for hb in self.hbonds if not hb.sidechain])
- counts = {'hydrophobics': len(self.hydrophobics), 'hbonds': len(self.hbonds),
- 'wbridges': len(self.wbridges), 'sbridges': len(self.sbridges), 'pistacks': len(self.pi_stacks),
- 'pications': len(self.pi_cations), 'halogens': len(self.halogens), 'metal': len(self.metal_complexes),
- 'hbond_back': hbondsback, 'hbond_nonback': (len(self.hbonds) - hbondsback)}
- counts['total'] = counts['hydrophobics'] + counts['hbonds'] + counts['wbridges'] + \
- counts['sbridges'] + counts['pistacks'] + counts['pications'] + counts['halogens'] + counts['metal']
+ counts = {
+ "hydrophobics": len(self.hydrophobics),
+ "hbonds": len(self.hbonds),
+ "wbridges": len(self.wbridges),
+ "sbridges": len(self.sbridges),
+ "pistacks": len(self.pi_stacks),
+ "pications": len(self.pi_cations),
+ "halogens": len(self.halogens),
+ "metal": len(self.metal_complexes),
+ "hbond_back": hbondsback,
+ "hbond_nonback": (len(self.hbonds) - hbondsback),
+ }
+ counts["total"] = (
+ counts["hydrophobics"]
+ + counts["hbonds"]
+ + counts["wbridges"]
+ + counts["sbridges"]
+ + counts["pistacks"]
+ + counts["pications"]
+ + counts["halogens"]
+ + counts["metal"]
+ )
return counts
@@ -269,17 +349,22 @@ class PlipXML(XMLStorage):
self.load_data(xmlfile)
# Parse general information
- self.version = self.getdata(self.doc, '/report/plipversion/')
- self.pdbid = self.getdata(self.doc, '/report/pdbid', force_string=True)
- self.filetype = self.getdata(self.doc, '/report/filetype')
- self.fixed = self.getdata(self.doc, '/report/pdbfixes/')
- self.filename = self.getdata(self.doc, '/report/filename')
- self.excluded = self.doc.xpath('/report/excluded_ligands/excluded_ligand/text()')
+ self.version = self.getdata(self.doc, "/report/plipversion/")
+ self.pdbid = self.getdata(self.doc, "/report/pdbid", force_string=True)
+ self.filetype = self.getdata(self.doc, "/report/filetype")
+ self.fixed = self.getdata(self.doc, "/report/pdbfixes/")
+ self.filename = self.getdata(self.doc, "/report/filename")
+ self.excluded = self.doc.xpath(
+ "/report/excluded_ligands/excluded_ligand/text()"
+ )
# Parse binding site information
- self.bsites = {BSite(bs, self.pdbid).bsid: BSite(bs, self.pdbid) for bs in self.doc.xpath('//bindingsite')}
+ self.bsites = {
+ BSite(bs, self.pdbid).bsid: BSite(bs, self.pdbid)
+ for bs in self.doc.xpath("//bindingsite")
+ }
self.num_bsites = len(self.bsites)
def load_data(self, xmlfile):
"""Loads/parses an XML file and saves it as a tree if successful."""
- self.doc = etree.parse(xmlfile) \ No newline at end of file
+ self.doc = etree.parse(xmlfile)
diff --git a/plip/plipcmd.py b/plip/plipcmd.py
index e4c0815..b590d09 100644
--- a/plip/plipcmd.py
+++ b/plip/plipcmd.py
@@ -25,12 +25,14 @@ from plip.exchange.webservices import fetch_pdb
from plip.structure.preparation import create_folder_if_not_exists, extract_pdbid
from plip.structure.preparation import tilde_expansion, PDBComplex
-description = f"The Protein-Ligand Interaction Profiler (PLIP) {__version__}" \
- "is a command-line based tool to analyze interactions in a protein-ligand complex. " \
- "If you are using PLIP in your work, please cite: " \
- "Salentin,S. et al. PLIP: fully automated protein-ligand interaction profiler. " \
- "Nucl. Acids Res. (1 July 2015) 43 (W1): W443-W447. doi:10.1093/nar/gkv315" \
- f"Supported and maintained by: {config.__maintainer__}"
+description = (
+ f"The Protein-Ligand Interaction Profiler (PLIP) {__version__}"
+ "is a command-line based tool to analyze interactions in a protein-ligand complex. "
+ "If you are using PLIP in your work, please cite: "
+ "Salentin,S. et al. PLIP: fully automated protein-ligand interaction profiler. "
+ "Nucl. Acids Res. (1 July 2015) 43 (W1): W443-W447. doi:10.1093/nar/gkv315"
+ f"Supported and maintained by: {config.__maintainer__}"
+)
def threshold_limiter(aparser, arg):
@@ -40,13 +42,13 @@ def threshold_limiter(aparser, arg):
return arg
-def process_pdb(pdbfile, outpath, as_string=False, outputprefix='report'):
+def process_pdb(pdbfile, outpath, as_string=False, outputprefix="report"):
"""Analysis of a single PDB file. Can generate textual reports XML, PyMOL session files and images as output."""
if not as_string:
- pdb_file_name = pdbfile.split('/')[-1]
- startmessage = f'starting analysis of {pdb_file_name}'
+ pdb_file_name = pdbfile.split("/")[-1]
+ startmessage = f"starting analysis of {pdb_file_name}"
else:
- startmessage = 'starting analysis from STDIN'
+ startmessage = "starting analysis from STDIN"
logger.info(startmessage)
mol = PDBComplex()
mol.output_path = outpath
@@ -68,10 +70,16 @@ def process_pdb(pdbfile, outpath, as_string=False, outputprefix='report'):
if config.PYMOL or config.PICS:
from plip.visualization.visualize import visualize_in_pymol
- complexes = [VisualizerData(mol, site) for site in sorted(mol.interaction_sets)
- if not len(mol.interaction_sets[site].interacting_res) == 0]
+
+ complexes = [
+ VisualizerData(mol, site)
+ for site in sorted(mol.interaction_sets)
+ if not len(mol.interaction_sets[site].interacting_res) == 0
+ ]
if config.MAXTHREADS > 1:
- logger.info(f'generating visualizations in parallel on {config.MAXTHREADS} cores')
+ logger.info(
+ f"generating visualizations in parallel on {config.MAXTHREADS} cores"
+ )
parfn = parallel_fn(visualize_in_pymol)
parfn(complexes, processes=config.MAXTHREADS)
else:
@@ -89,19 +97,22 @@ def download_structure(inputpdbid):
Checks for validity of ID and handles error while downloading.
Returns the path of the downloaded file."""
try:
- if len(inputpdbid) != 4 or extract_pdbid(inputpdbid.lower()) == 'UnknownProtein':
- logger.error(f'invalid PDB-ID (wrong format): {inputpdbid}')
+ if (
+ len(inputpdbid) != 4
+ or extract_pdbid(inputpdbid.lower()) == "UnknownProtein"
+ ):
+ logger.error(f"invalid PDB-ID (wrong format): {inputpdbid}")
sys.exit(1)
pdbfile, pdbid = fetch_pdb(inputpdbid.lower())
- pdbpath = tilde_expansion('%s/%s.pdb' % (config.BASEPATH.rstrip('/'), pdbid))
+ pdbpath = tilde_expansion("%s/%s.pdb" % (config.BASEPATH.rstrip("/"), pdbid))
create_folder_if_not_exists(config.BASEPATH)
- with open(pdbpath, 'w') as g:
+ with open(pdbpath, "w") as g:
g.write(pdbfile)
- logger.info(f'file downloaded as {pdbpath}')
+ logger.info(f"file downloaded as {pdbpath}")
return pdbpath, pdbid
except ValueError: # Invalid PDB ID, cannot fetch from RCBS server
- logger.error(f'PDB-ID does not exist: {inputpdbid}')
+ logger.error(f"PDB-ID does not exist: {inputpdbid}")
sys.exit(1)
@@ -111,9 +122,9 @@ def remove_duplicates(slist):
unique = list(set(slist))
difference = len(slist) - len(unique)
if difference == 1:
- logger.info('removed one duplicate entry from input list')
+ logger.info("removed one duplicate entry from input list")
if difference > 1:
- logger.info(f'Removed {difference} duplicate entries from input list')
+ logger.info(f"Removed {difference} duplicate entries from input list")
return unique
@@ -122,9 +133,9 @@ def run_analysis(inputstructs, inputpdbids):
pdbid, pdbpath = None, None
# @todo For multiprocessing, implement better stacktracing for errors
# Print title and version
- logger.info(f'Protein-Ligand Interaction Profiler (PLIP) {__version__}')
- logger.info(f'brought to you by: {config.__maintainer__}')
- logger.info(f'please cite: https://www.doi.org/10.1093/nar/gkv315')
+ logger.info(f"Protein-Ligand Interaction Profiler (PLIP) {__version__}")
+ logger.info(f"brought to you by: {config.__maintainer__}")
+ logger.info(f"please cite: https://www.doi.org/10.1093/nar/gkv315")
output_prefix = config.OUTPUTFILENAME
if inputstructs is not None: # Process PDB file(s)
@@ -132,114 +143,258 @@ def run_analysis(inputstructs, inputpdbids):
inputstructs = remove_duplicates(inputstructs)
read_from_stdin = False
for inputstruct in inputstructs:
- if inputstruct == '-':
+ if inputstruct == "-":
inputstruct = sys.stdin.read()
read_from_stdin = True
if config.RAWSTRING:
if sys.version_info < (3,):
- inputstruct = bytes(inputstruct).decode('unicode_escape')
+ inputstruct = bytes(inputstruct).decode("unicode_escape")
else:
- inputstruct = bytes(inputstruct, 'utf8').decode('unicode_escape')
+ inputstruct = bytes(inputstruct, "utf8").decode(
+ "unicode_escape"
+ )
else:
if os.path.getsize(inputstruct) == 0:
- logger.error('empty PDB file')
+ logger.error("empty PDB file")
sys.exit(1)
if num_structures > 1:
- basename = inputstruct.split('.')[-2].split('/')[-1]
- config.OUTPATH = '/'.join([config.BASEPATH, basename])
- output_prefix = 'report'
- process_pdb(inputstruct, config.OUTPATH, as_string=read_from_stdin, outputprefix=output_prefix)
+ basename = inputstruct.split(".")[-2].split("/")[-1]
+ config.OUTPATH = "/".join([config.BASEPATH, basename])
+ output_prefix = "report"
+ process_pdb(
+ inputstruct,
+ config.OUTPATH,
+ as_string=read_from_stdin,
+ outputprefix=output_prefix,
+ )
else: # Try to fetch the current PDB structure(s) directly from the RCBS server
num_pdbids = len(inputpdbids)
inputpdbids = remove_duplicates(inputpdbids)
for inputpdbid in inputpdbids:
pdbpath, pdbid = download_structure(inputpdbid)
if num_pdbids > 1:
- config.OUTPATH = '/'.join([config.BASEPATH, pdbid[1:3].upper(), pdbid.upper()])
- output_prefix = 'report'
+ config.OUTPATH = "/".join(
+ [config.BASEPATH, pdbid[1:3].upper(), pdbid.upper()]
+ )
+ output_prefix = "report"
process_pdb(pdbpath, config.OUTPATH, outputprefix=output_prefix)
if (pdbid is not None or inputstructs is not None) and config.BASEPATH is not None:
- if config.BASEPATH in ['.', './']:
- logger.info('finished analysis, find the result files in the working directory')
+ if config.BASEPATH in [".", "./"]:
+ logger.info(
+ "finished analysis, find the result files in the working directory"
+ )
else:
- logger.info(f'finished analysis, find the result files in {config.BASEPATH}')
+ logger.info(
+ f"finished analysis, find the result files in {config.BASEPATH}"
+ )
-if __name__ == '__main__':
+if __name__ == "__main__":
"""Parse command line arguments and start main script for analysis."""
parser = ArgumentParser(prog="PLIP", description=description)
- pdbstructure = parser.add_mutually_exclusive_group(required=True) # Needs either PDB ID or file
+ pdbstructure = parser.add_mutually_exclusive_group(
+ required=True
+ ) # Needs either PDB ID or file
# '-' as file name reads from stdin
- pdbstructure.add_argument("-f", "--file", dest="input", nargs="+", help="Set input file, '-' reads from stdin")
+ pdbstructure.add_argument(
+ "-f",
+ "--file",
+ dest="input",
+ nargs="+",
+ help="Set input file, '-' reads from stdin",
+ )
pdbstructure.add_argument("-i", "--input", dest="pdbid", nargs="+")
- outputgroup = parser.add_mutually_exclusive_group(required=False) # Needs either outpath or stdout
+ outputgroup = parser.add_mutually_exclusive_group(
+ required=False
+ ) # Needs either outpath or stdout
outputgroup.add_argument("-o", "--out", dest="outpath", default="./")
- outputgroup.add_argument("-O", "--stdout", dest="stdout", action="store_true", default=False,
- help="Write to stdout instead of file")
- parser.add_argument("--rawstring", dest="use_raw_string", default=False, action="store_true",
- help="Use Python raw strings for stdout and stdin")
- parser.add_argument("-v", "--verbose", dest="verbose", default=False, help="Turn on verbose mode",
- action="store_true")
- parser.add_argument("-q", "--quiet", dest="quiet", default=False, help="Turn on quiet mode", action="store_true")
- parser.add_argument("-s", "--silent", dest="silent", default=False, help="Turn on silent mode", action="store_true")
- parser.add_argument("-p", "--pics", dest="pics", default=False, help="Additional pictures", action="store_true")
- parser.add_argument("-x", "--xml", dest="xml", default=False, help="Generate report file in XML format",
- action="store_true")
- parser.add_argument("-t", "--txt", dest="txt", default=False, help="Generate report file in TXT (RST) format",
- action="store_true")
- parser.add_argument("-y", "--pymol", dest="pymol", default=False, help="Additional PyMOL session files",
- action="store_true")
- parser.add_argument("--maxthreads", dest="maxthreads", default=multiprocessing.cpu_count(),
- help="Set maximum number of main threads (number of binding sites processed simultaneously)."
- "If not set, PLIP uses all available CPUs if possible.",
- type=int)
- parser.add_argument("--breakcomposite", dest="breakcomposite", default=False,
- help="Don't combine ligand fragments with covalent bonds but treat them as single ligands for the analysis.",
- action="store_true")
- parser.add_argument("--altlocation", dest="altlocation", default=False,
- help="Also consider alternate locations for atoms (e.g. alternate conformations).",
- action="store_true")
- parser.add_argument("--nofix", dest="nofix", default=False,
- help="Turns off fixing of PDB files.",
- action="store_true")
- parser.add_argument("--nofixfile", dest="nofixfile", default=False,
- help="Turns off writing files for fixed PDB files.",
- action="store_true")
- parser.add_argument("--nopdbcanmap", dest="nopdbcanmap", default=False,
- help="Turns off calculation of mapping between canonical and PDB atom order for ligands.",
- action="store_true")
- parser.add_argument("--dnareceptor", dest="dnareceptor", default=False,
- help="Uses the DNA instead of the protein as a receptor for interactions.",
- action="store_true")
- parser.add_argument("--name", dest="outputfilename", default="report",
- help="Set a filename for the report TXT and XML files. Will only work when processing single structures.")
- ligandtype = parser.add_mutually_exclusive_group() # Either peptide/inter or intra mode
- ligandtype.add_argument("--peptides", "--inter", dest="peptides", default=[],
- help="Allows to define one or multiple chains as peptide ligands or to detect inter-chain contacts",
- nargs="+")
- ligandtype.add_argument("--intra", dest="intra", help="Allows to define one chain to analyze intra-chain contacts.")
- parser.add_argument("--keepmod", dest="keepmod", default=False,
- help="Keep modified residues as ligands",
- action="store_true")
- parser.add_argument("--nohydro", dest="nohydro", default=False,
- help="Do not add polar hydrogens in case your structure already contains hydrogens.",
- action="store_true")
+ outputgroup.add_argument(
+ "-O",
+ "--stdout",
+ dest="stdout",
+ action="store_true",
+ default=False,
+ help="Write to stdout instead of file",
+ )
+ parser.add_argument(
+ "--rawstring",
+ dest="use_raw_string",
+ default=False,
+ action="store_true",
+ help="Use Python raw strings for stdout and stdin",
+ )
+ parser.add_argument(
+ "-v",
+ "--verbose",
+ dest="verbose",
+ default=False,
+ help="Turn on verbose mode",
+ action="store_true",
+ )
+ parser.add_argument(
+ "-q",
+ "--quiet",
+ dest="quiet",
+ default=False,
+ help="Turn on quiet mode",
+ action="store_true",
+ )
+ parser.add_argument(
+ "-s",
+ "--silent",
+ dest="silent",
+ default=False,
+ help="Turn on silent mode",
+ action="store_true",
+ )
+ parser.add_argument(
+ "-p",
+ "--pics",
+ dest="pics",
+ default=False,
+ help="Additional pictures",
+ action="store_true",
+ )
+ parser.add_argument(
+ "-x",
+ "--xml",
+ dest="xml",
+ default=False,
+ help="Generate report file in XML format",
+ action="store_true",
+ )
+ parser.add_argument(
+ "-t",
+ "--txt",
+ dest="txt",
+ default=False,
+ help="Generate report file in TXT (RST) format",
+ action="store_true",
+ )
+ parser.add_argument(
+ "-y",
+ "--pymol",
+ dest="pymol",
+ default=False,
+ help="Additional PyMOL session files",
+ action="store_true",
+ )
+ parser.add_argument(
+ "--maxthreads",
+ dest="maxthreads",
+ default=multiprocessing.cpu_count(),
+ help="Set maximum number of main threads (number of binding sites processed simultaneously)."
+ "If not set, PLIP uses all available CPUs if possible.",
+ type=int,
+ )
+ parser.add_argument(
+ "--breakcomposite",
+ dest="breakcomposite",
+ default=False,
+ help="Don't combine ligand fragments with covalent bonds but treat them as single ligands for the analysis.",
+ action="store_true",
+ )
+ parser.add_argument(
+ "--altlocation",
+ dest="altlocation",
+ default=False,
+ help="Also consider alternate locations for atoms (e.g. alternate conformations).",
+ action="store_true",
+ )
+ parser.add_argument(
+ "--nofix",
+ dest="nofix",
+ default=False,
+ help="Turns off fixing of PDB files.",
+ action="store_true",
+ )
+ parser.add_argument(
+ "--nofixfile",
+ dest="nofixfile",
+ default=False,
+ help="Turns off writing files for fixed PDB files.",
+ action="store_true",
+ )
+ parser.add_argument(
+ "--nopdbcanmap",
+ dest="nopdbcanmap",
+ default=False,
+ help="Turns off calculation of mapping between canonical and PDB atom order for ligands.",
+ action="store_true",
+ )
+ parser.add_argument(
+ "--dnareceptor",
+ dest="dnareceptor",
+ default=False,
+ help="Uses the DNA instead of the protein as a receptor for interactions.",
+ action="store_true",
+ )
+ parser.add_argument(
+ "--name",
+ dest="outputfilename",
+ default="report",
+ help="Set a filename for the report TXT and XML files. Will only work when processing single structures.",
+ )
+ ligandtype = (
+ parser.add_mutually_exclusive_group()
+ ) # Either peptide/inter or intra mode
+ ligandtype.add_argument(
+ "--peptides",
+ "--inter",
+ dest="peptides",
+ default=[],
+ help="Allows to define one or multiple chains as peptide ligands or to detect inter-chain contacts",
+ nargs="+",
+ )
+ ligandtype.add_argument(
+ "--intra",
+ dest="intra",
+ help="Allows to define one chain to analyze intra-chain contacts.",
+ )
+ parser.add_argument(
+ "--keepmod",
+ dest="keepmod",
+ default=False,
+ help="Keep modified residues as ligands",
+ action="store_true",
+ )
+ parser.add_argument(
+ "--nohydro",
+ dest="nohydro",
+ default=False,
+ help="Do not add polar hydrogens in case your structure already contains hydrogens.",
+ action="store_true",
+ )
# Optional threshold arguments, not shown in help
- thr = namedtuple('threshold', 'name type')
- thresholds = [thr(name='aromatic_planarity', type='angle'),
- thr(name='hydroph_dist_max', type='distance'), thr(name='hbond_dist_max', type='distance'),
- thr(name='hbond_don_angle_min', type='angle'), thr(name='pistack_dist_max', type='distance'),
- thr(name='pistack_ang_dev', type='other'), thr(name='pistack_offset_max', type='distance'),
- thr(name='pication_dist_max', type='distance'), thr(name='saltbridge_dist_max', type='distance'),
- thr(name='halogen_dist_max', type='distance'), thr(name='halogen_acc_angle', type='angle'),
- thr(name='halogen_don_angle', type='angle'), thr(name='halogen_angle_dev', type='other'),
- thr(name='water_bridge_mindist', type='distance'), thr(name='water_bridge_maxdist', type='distance'),
- thr(name='water_bridge_omega_min', type='angle'), thr(name='water_bridge_omega_max', type='angle'),
- thr(name='water_bridge_theta_min', type='angle')]
+ thr = namedtuple("threshold", "name type")
+ thresholds = [
+ thr(name="aromatic_planarity", type="angle"),
+ thr(name="hydroph_dist_max", type="distance"),
+ thr(name="hbond_dist_max", type="distance"),
+ thr(name="hbond_don_angle_min", type="angle"),
+ thr(name="pistack_dist_max", type="distance"),
+ thr(name="pistack_ang_dev", type="other"),
+ thr(name="pistack_offset_max", type="distance"),
+ thr(name="pication_dist_max", type="distance"),
+ thr(name="saltbridge_dist_max", type="distance"),
+ thr(name="halogen_dist_max", type="distance"),
+ thr(name="halogen_acc_angle", type="angle"),
+ thr(name="halogen_don_angle", type="angle"),
+ thr(name="halogen_angle_dev", type="other"),
+ thr(name="water_bridge_mindist", type="distance"),
+ thr(name="water_bridge_maxdist", type="distance"),
+ thr(name="water_bridge_omega_min", type="angle"),
+ thr(name="water_bridge_omega_max", type="angle"),
+ thr(name="water_bridge_theta_min", type="angle"),
+ ]
for t in thresholds:
- parser.add_argument('--%s' % t.name, dest=t.name, type=lambda val: threshold_limiter(parser, val),
- help=argparse.SUPPRESS)
+ parser.add_argument(
+ "--%s" % t.name,
+ dest=t.name,
+ type=lambda val: threshold_limiter(parser, val),
+ help=argparse.SUPPRESS,
+ )
arguments = parser.parse_args()
@@ -264,8 +419,11 @@ if __name__ == '__main__':
config.STDOUT = arguments.stdout
config.RAWSTRING = arguments.use_raw_string
config.OUTPATH = arguments.outpath
- config.OUTPATH = tilde_expansion("".join([config.OUTPATH, '/'])
- if not config.OUTPATH.endswith('/') else config.OUTPATH)
+ config.OUTPATH = tilde_expansion(
+ "".join([config.OUTPATH, "/"])
+ if not config.OUTPATH.endswith("/")
+ else config.OUTPATH
+ )
config.BASEPATH = config.OUTPATH # Used for batch processing
config.BREAKCOMPOSITE = arguments.breakcomposite
config.ALTLOC = arguments.altlocation
@@ -283,28 +441,46 @@ if __name__ == '__main__':
try:
import pymol
except ImportError:
- logger.error('PyMOL is required for the --pics and --pymol option')
+ logger.error("PyMOL is required for the --pics and --pymol option")
sys.exit(1)
# Assign values to global thresholds
for t in thresholds:
tvalue = getattr(arguments, t.name)
if tvalue is not None:
- if t.type == 'angle' and not 0 < tvalue < 180: # Check value for angle thresholds
- parser.error("Threshold for angles need to have values within 0 and 180.")
- if t.type == 'distance':
+ if (
+ t.type == "angle" and not 0 < tvalue < 180
+ ): # Check value for angle thresholds
+ parser.error(
+ "Threshold for angles need to have values within 0 and 180."
+ )
+ if t.type == "distance":
if tvalue > 10: # Check value for angle thresholds
- parser.error("Threshold for distances must not be larger than 10 Angstrom.")
- elif tvalue > config.BS_DIST + 1: # Dynamically adapt the search space for binding site residues
+ parser.error(
+ "Threshold for distances must not be larger than 10 Angstrom."
+ )
+ elif (
+ tvalue > config.BS_DIST + 1
+ ): # Dynamically adapt the search space for binding site residues
config.BS_DIST = tvalue + 1
setattr(config, t.name.upper(), tvalue)
# Check additional conditions for interdependent thresholds
if not config.HALOGEN_ACC_ANGLE > config.HALOGEN_ANGLE_DEV:
- parser.error("The halogen acceptor angle has to be larger than the halogen angle deviation.")
+ parser.error(
+ "The halogen acceptor angle has to be larger than the halogen angle deviation."
+ )
if not config.HALOGEN_DON_ANGLE > config.HALOGEN_ANGLE_DEV:
- parser.error("The halogen donor angle has to be larger than the halogen angle deviation.")
+ parser.error(
+ "The halogen donor angle has to be larger than the halogen angle deviation."
+ )
if not config.WATER_BRIDGE_MINDIST < config.WATER_BRIDGE_MAXDIST:
- parser.error("The water bridge minimum distance has to be smaller than the water bridge maximum distance.")
+ parser.error(
+ "The water bridge minimum distance has to be smaller than the water bridge maximum distance."
+ )
if not config.WATER_BRIDGE_OMEGA_MIN < config.WATER_BRIDGE_OMEGA_MAX:
- parser.error("The water bridge omega minimum angle has to be smaller than the water bridge omega maximum angle")
- expanded_path = tilde_expansion(arguments.input) if arguments.input is not None else None
+ parser.error(
+ "The water bridge omega minimum angle has to be smaller than the water bridge omega maximum angle"
+ )
+ expanded_path = (
+ tilde_expansion(arguments.input) if arguments.input is not None else None
+ )
run_analysis(expanded_path, arguments.pdbid) # Start main script
diff --git a/plip/structure/detection.py b/plip/structure/detection.py
index 71fec63..6a2eeb7 100644
--- a/plip/structure/detection.py
+++ b/plip/structure/detection.py
@@ -11,25 +11,30 @@ from plip.basic.supplemental import whichresnumber, whichrestype, whichchain
logger = logger.get_logger()
+
def filter_contacts(pairings):
"""Filter interactions by two criteria:
1. No interactions between the same residue (important for intra mode).
2. No duplicate interactions (A with B and B with A, also important for intra mode)."""
if not config.INTRA:
return pairings
- filtered1_pairings = [p for p in pairings if (p.resnr, p.reschain) != (p.resnr_l, p.reschain_l)]
+ filtered1_pairings = [
+ p for p in pairings if (p.resnr, p.reschain) != (p.resnr_l, p.reschain_l)
+ ]
already_considered = []
filtered2_pairings = []
for contact in filtered1_pairings:
try:
- dist = 'D{}'.format(round(contact.distance, 2))
+ dist = "D{}".format(round(contact.distance, 2))
except AttributeError:
try:
- dist = 'D{}'.format(round(contact.distance_ah, 2))
+ dist = "D{}".format(round(contact.distance_ah, 2))
except AttributeError:
- dist = 'D{}'.format(round(contact.distance_aw, 2))
- res1, res2 = ''.join([str(contact.resnr), contact.reschain]), ''.join(
- [str(contact.resnr_l), contact.reschain_l])
+ dist = "D{}".format(round(contact.distance_aw, 2))
+ res1, res2 = (
+ "".join([str(contact.resnr), contact.reschain]),
+ "".join([str(contact.resnr_l), contact.reschain_l]),
+ )
data = {res1, res2, dist}
if data not in already_considered:
filtered2_pairings.append(contact)
@@ -41,12 +46,16 @@ def filter_contacts(pairings):
# FUNCTIONS FOR DETECTION OF SPECIFIC INTERACTIONS
##################################################
+
def hydrophobic_interactions(atom_set_a, atom_set_b):
"""Detection of hydrophobic pliprofiler between atom_set_a (binding site) and atom_set_b (ligand).
Definition: All pairs of qualified carbon atoms within a distance of HYDROPH_DIST_MAX
"""
- data = namedtuple('hydroph_interaction', 'bsatom bsatom_orig_idx ligatom ligatom_orig_idx '
- 'distance restype resnr reschain restype_l, resnr_l, reschain_l')
+ data = namedtuple(
+ "hydroph_interaction",
+ "bsatom bsatom_orig_idx ligatom ligatom_orig_idx "
+ "distance restype resnr reschain restype_l, resnr_l, reschain_l",
+ )
pairings = []
for a, b in itertools.product(atom_set_a, atom_set_b):
if a.orig_idx == b.orig_idx:
@@ -54,12 +63,29 @@ def hydrophobic_interactions(atom_set_a, atom_set_b):
e = euclidean3d(a.atom.coords, b.atom.coords)
if not config.MIN_DIST < e < config.HYDROPH_DIST_MAX:
continue
- restype, resnr, reschain = whichrestype(a.atom), whichresnumber(a.atom), whichchain(a.atom)
- restype_l, resnr_l, reschain_l = whichrestype(b.orig_atom), whichresnumber(b.orig_atom), whichchain(b.orig_atom)
- contact = data(bsatom=a.atom, bsatom_orig_idx=a.orig_idx, ligatom=b.atom, ligatom_orig_idx=b.orig_idx,
- distance=e, restype=restype, resnr=resnr,
- reschain=reschain, restype_l=restype_l,
- resnr_l=resnr_l, reschain_l=reschain_l)
+ restype, resnr, reschain = (
+ whichrestype(a.atom),
+ whichresnumber(a.atom),
+ whichchain(a.atom),
+ )
+ restype_l, resnr_l, reschain_l = (
+ whichrestype(b.orig_atom),
+ whichresnumber(b.orig_atom),
+ whichchain(b.orig_atom),
+ )
+ contact = data(
+ bsatom=a.atom,
+ bsatom_orig_idx=a.orig_idx,
+ ligatom=b.atom,
+ ligatom_orig_idx=b.orig_idx,
+ distance=e,
+ restype=restype,
+ resnr=resnr,
+ reschain=reschain,
+ restype_l=restype_l,
+ resnr_l=resnr_l,
+ reschain_l=reschain_l,
+ )
pairings.append(contact)
return filter_contacts(pairings)
@@ -70,43 +96,79 @@ def hbonds(acceptors, donor_pairs, protisdon, typ):
donor hydrogens and acceptor showing a distance within HBOND DIST MIN and HBOND DIST MAX
and donor angles above HBOND_DON_ANGLE_MIN
"""
- data = namedtuple('hbond', 'a a_orig_idx d d_orig_idx h distance_ah distance_ad angle type protisdon resnr '
- 'restype reschain resnr_l restype_l reschain_l sidechain atype dtype')
+ data = namedtuple(
+ "hbond",
+ "a a_orig_idx d d_orig_idx h distance_ah distance_ad angle type protisdon resnr "
+ "restype reschain resnr_l restype_l reschain_l sidechain atype dtype",
+ )
pairings = []
for acc, don in itertools.product(acceptors, donor_pairs):
- if not typ == 'strong':
+ if not typ == "strong":
continue
# Regular (strong) hydrogen bonds
dist_ah = euclidean3d(acc.a.coords, don.h.coords)
dist_ad = euclidean3d(acc.a.coords, don.d.coords)
if not config.MIN_DIST < dist_ad < config.HBOND_DIST_MAX:
continue
- vec1, vec2 = vector(don.h.coords, don.d.coords), vector(don.h.coords, acc.a.coords)
+ vec1, vec2 = (
+ vector(don.h.coords, don.d.coords),
+ vector(don.h.coords, acc.a.coords),
+ )
v = vecangle(vec1, vec2)
if not v > config.HBOND_DON_ANGLE_MIN:
continue
protatom = don.d.OBAtom if protisdon else acc.a.OBAtom
ligatom = don.d.OBAtom if not protisdon else acc.a.OBAtom
- is_sidechain_hbond = protatom.GetResidue().GetAtomProperty(protatom, 8) # Check if sidechain atom
+ is_sidechain_hbond = protatom.GetResidue().GetAtomProperty(
+ protatom, 8
+ ) # Check if sidechain atom
resnr = whichresnumber(don.d) if protisdon else whichresnumber(acc.a)
- resnr_l = whichresnumber(acc.a_orig_atom) if protisdon else whichresnumber(don.d_orig_atom)
+ resnr_l = (
+ whichresnumber(acc.a_orig_atom)
+ if protisdon
+ else whichresnumber(don.d_orig_atom)
+ )
restype = whichrestype(don.d) if protisdon else whichrestype(acc.a)
- restype_l = whichrestype(acc.a_orig_atom) if protisdon else whichrestype(don.d_orig_atom)
+ restype_l = (
+ whichrestype(acc.a_orig_atom)
+ if protisdon
+ else whichrestype(don.d_orig_atom)
+ )
reschain = whichchain(don.d) if protisdon else whichchain(acc.a)
- rechain_l = whichchain(acc.a_orig_atom) if protisdon else whichchain(don.d_orig_atom)
+ rechain_l = (
+ whichchain(acc.a_orig_atom) if protisdon else whichchain(don.d_orig_atom)
+ )
# Next line prevents H-Bonds within amino acids in intermolecular interactions
if config.INTRA is not None and whichresnumber(don.d) == whichresnumber(acc.a):
continue
# Next line prevents backbone-backbone H-Bonds
- if config.INTRA is not None and protatom.GetResidue().GetAtomProperty(protatom,
- 8) and ligatom.GetResidue().GetAtomProperty(
- ligatom, 8):
+ if (
+ config.INTRA is not None
+ and protatom.GetResidue().GetAtomProperty(protatom, 8)
+ and ligatom.GetResidue().GetAtomProperty(ligatom, 8)
+ ):
continue
- contact = data(a=acc.a, a_orig_idx=acc.a_orig_idx, d=don.d, d_orig_idx=don.d_orig_idx, h=don.h,
- distance_ah=dist_ah, distance_ad=dist_ad, angle=v, type=typ, protisdon=protisdon,
- resnr=resnr, restype=restype, reschain=reschain, resnr_l=resnr_l,
- restype_l=restype_l, reschain_l=rechain_l, sidechain=is_sidechain_hbond,
- atype=acc.a.type, dtype=don.d.type)
+ contact = data(
+ a=acc.a,
+ a_orig_idx=acc.a_orig_idx,
+ d=don.d,
+ d_orig_idx=don.d_orig_idx,
+ h=don.h,
+ distance_ah=dist_ah,
+ distance_ad=dist_ad,
+ angle=v,
+ type=typ,
+ protisdon=protisdon,
+ resnr=resnr,
+ restype=restype,
+ reschain=reschain,
+ resnr_l=resnr_l,
+ restype_l=restype_l,
+ reschain_l=rechain_l,
+ sidechain=is_sidechain_hbond,
+ atype=acc.a.type,
+ dtype=don.d.type,
+ )
pairings.append(contact)
return filter_contacts(pairings)
@@ -114,14 +176,17 @@ def hbonds(acceptors, donor_pairs, protisdon, typ):
def pistacking(rings_bs, rings_lig):
"""Return all pi-stackings between the given aromatic ring systems in receptor and ligand."""
data = namedtuple(
- 'pistack',
- 'proteinring ligandring distance angle offset type restype resnr reschain restype_l resnr_l reschain_l')
+ "pistack",
+ "proteinring ligandring distance angle offset type restype resnr reschain restype_l resnr_l reschain_l",
+ )
pairings = []
for r, l in itertools.product(rings_bs, rings_lig):
# DISTANCE AND RING ANGLE CALCULATION
d = euclidean3d(r.center, l.center)
b = vecangle(r.normal, l.normal)
- a = min(b, 180 - b if not 180 - b < 0 else b) # Smallest of two angles, depending on direction of normal
+ a = min(
+ b, 180 - b if not 180 - b < 0 else b
+ ) # Smallest of two angles, depending on direction of normal
# RING CENTER OFFSET CALCULATION (project each ring center into the other ring)
proj1 = projection(l.normal, l.center, r.center)
@@ -129,24 +194,45 @@ def pistacking(rings_bs, rings_lig):
offset = min(euclidean3d(proj1, l.center), euclidean3d(proj2, r.center))
# RECEPTOR DATA
- resnr, restype, reschain = whichresnumber(r.atoms[0]), whichrestype(r.atoms[0]), whichchain(r.atoms[0])
- resnr_l, restype_l, reschain_l = whichresnumber(l.orig_atoms[0]), whichrestype(
- l.orig_atoms[0]), whichchain(l.orig_atoms[0])
+ resnr, restype, reschain = (
+ whichresnumber(r.atoms[0]),
+ whichrestype(r.atoms[0]),
+ whichchain(r.atoms[0]),
+ )
+ resnr_l, restype_l, reschain_l = (
+ whichresnumber(l.orig_atoms[0]),
+ whichrestype(l.orig_atoms[0]),
+ whichchain(l.orig_atoms[0]),
+ )
# SELECTION BY DISTANCE, ANGLE AND OFFSET
passed = False
if not config.MIN_DIST < d < config.PISTACK_DIST_MAX:
continue
if 0 < a < config.PISTACK_ANG_DEV and offset < config.PISTACK_OFFSET_MAX:
- ptype = 'P'
+ ptype = "P"
passed = True
- if 90 - config.PISTACK_ANG_DEV < a < 90 + config.PISTACK_ANG_DEV and offset < config.PISTACK_OFFSET_MAX:
- ptype = 'T'
+ if (
+ 90 - config.PISTACK_ANG_DEV < a < 90 + config.PISTACK_ANG_DEV
+ and offset < config.PISTACK_OFFSET_MAX
+ ):
+ ptype = "T"
passed = True
if passed:
- contact = data(proteinring=r, ligandring=l, distance=d, angle=a, offset=offset,
- type=ptype, resnr=resnr, restype=restype, reschain=reschain,
- resnr_l=resnr_l, restype_l=restype_l, reschain_l=reschain_l)
+ contact = data(
+ proteinring=r,
+ ligandring=l,
+ distance=d,
+ angle=a,
+ offset=offset,
+ type=ptype,
+ resnr=resnr,
+ restype=restype,
+ reschain=reschain,
+ resnr_l=resnr_l,
+ restype_l=restype_l,
+ reschain_l=reschain_l,
+ )
pairings.append(contact)
return filter_contacts(pairings)
@@ -156,7 +242,9 @@ def pication(rings, pos_charged, protcharged):
For tertiary and quaternary amines, check also the angle between the ring and the nitrogen.
"""
data = namedtuple(
- 'pication', 'ring charge distance offset type restype resnr reschain restype_l resnr_l reschain_l protcharged')
+ "pication",
+ "ring charge distance offset type restype resnr reschain restype_l resnr_l reschain_l protcharged",
+ )
pairings = []
if len(rings) == 0 or len(pos_charged) == 0:
return pairings
@@ -167,38 +255,92 @@ def pication(rings, pos_charged, protcharged):
# Project the center of charge into the ring and measure distance to ring center
proj = projection(ring.normal, ring.center, p.center)
offset = euclidean3d(proj, ring.center)
- if not config.MIN_DIST < d < config.PICATION_DIST_MAX or not offset < config.PISTACK_OFFSET_MAX:
+ if (
+ not config.MIN_DIST < d < config.PICATION_DIST_MAX
+ or not offset < config.PISTACK_OFFSET_MAX
+ ):
continue
- if type(p).__name__ == 'lcharge' and p.fgroup == 'tertamine':
+ if type(p).__name__ == "lcharge" and p.fgroup == "tertamine":
# Special case here if the ligand has a tertiary amine, check an additional angle
# Otherwise, we might have have a pi-cation interaction 'through' the ligand
- n_atoms = [a_neighbor for a_neighbor in OBAtomAtomIter(p.atoms[0].OBAtom)]
+ n_atoms = [
+ a_neighbor for a_neighbor in OBAtomAtomIter(p.atoms[0].OBAtom)
+ ]
n_atoms_coords = [(a.x(), a.y(), a.z()) for a in n_atoms]
- amine_normal = np.cross(vector(n_atoms_coords[0], n_atoms_coords[1]),
- vector(n_atoms_coords[2], n_atoms_coords[0]))
+ amine_normal = np.cross(
+ vector(n_atoms_coords[0], n_atoms_coords[1]),
+ vector(n_atoms_coords[2], n_atoms_coords[0]),
+ )
b = vecangle(ring.normal, amine_normal)
# Smallest of two angles, depending on direction of normal
a = min(b, 180 - b if not 180 - b < 0 else b)
if not a > 30.0:
- resnr, restype = whichresnumber(ring.atoms[0]), whichrestype(ring.atoms[0])
+ resnr, restype = (
+ whichresnumber(ring.atoms[0]),
+ whichrestype(ring.atoms[0]),
+ )
reschain = whichchain(ring.atoms[0])
- resnr_l, restype_l = whichresnumber(p.orig_atoms[0]), whichrestype(p.orig_atoms[0])
+ resnr_l, restype_l = (
+ whichresnumber(p.orig_atoms[0]),
+ whichrestype(p.orig_atoms[0]),
+ )
reschain_l = whichchain(p.orig_atoms[0])
- contact = data(ring=ring, charge=p, distance=d, offset=offset, type='regular',
- restype=restype, resnr=resnr, reschain=reschain,
- restype_l=restype_l, resnr_l=resnr_l, reschain_l=reschain_l,
- protcharged=protcharged)
+ contact = data(
+ ring=ring,
+ charge=p,
+ distance=d,
+ offset=offset,
+ type="regular",
+ restype=restype,
+ resnr=resnr,
+ reschain=reschain,
+ restype_l=restype_l,
+ resnr_l=resnr_l,
+ reschain_l=reschain_l,
+ protcharged=protcharged,
+ )
pairings.append(contact)
break
- resnr = whichresnumber(p.atoms[0]) if protcharged else whichresnumber(ring.atoms[0])
- resnr_l = whichresnumber(ring.orig_atoms[0]) if protcharged else whichresnumber(p.orig_atoms[0])
- restype = whichrestype(p.atoms[0]) if protcharged else whichrestype(ring.atoms[0])
- restype_l = whichrestype(ring.orig_atoms[0]) if protcharged else whichrestype(p.orig_atoms[0])
- reschain = whichchain(p.atoms[0]) if protcharged else whichchain(ring.atoms[0])
- reschain_l = whichchain(ring.orig_atoms[0]) if protcharged else whichchain(p.orig_atoms[0])
- contact = data(ring=ring, charge=p, distance=d, offset=offset, type='regular', restype=restype,
- resnr=resnr, reschain=reschain, restype_l=restype_l, resnr_l=resnr_l,
- reschain_l=reschain_l, protcharged=protcharged)
+ resnr = (
+ whichresnumber(p.atoms[0])
+ if protcharged
+ else whichresnumber(ring.atoms[0])
+ )
+ resnr_l = (
+ whichresnumber(ring.orig_atoms[0])
+ if protcharged
+ else whichresnumber(p.orig_atoms[0])
+ )
+ restype = (
+ whichrestype(p.atoms[0]) if protcharged else whichrestype(ring.atoms[0])
+ )
+ restype_l = (
+ whichrestype(ring.orig_atoms[0])
+ if protcharged
+ else whichrestype(p.orig_atoms[0])
+ )
+ reschain = (
+ whichchain(p.atoms[0]) if protcharged else whichchain(ring.atoms[0])
+ )
+ reschain_l = (
+ whichchain(ring.orig_atoms[0])
+ if protcharged
+ else whichchain(p.orig_atoms[0])
+ )
+ contact = data(
+ ring=ring,
+ charge=p,
+ distance=d,
+ offset=offset,
+ type="regular",
+ restype=restype,
+ resnr=resnr,
+ reschain=reschain,
+ restype_l=restype_l,
+ resnr_l=resnr_l,
+ reschain_l=reschain_l,
+ protcharged=protcharged,
+ )
pairings.append(contact)
return filter_contacts(pairings)
@@ -206,59 +348,124 @@ def pication(rings, pos_charged, protcharged):
def saltbridge(poscenter, negcenter, protispos):
"""Detect all salt bridges (pliprofiler between centers of positive and negative charge)"""
data = namedtuple(
- 'saltbridge', 'positive negative distance protispos resnr restype reschain resnr_l restype_l reschain_l')
+ "saltbridge",
+ "positive negative distance protispos resnr restype reschain resnr_l restype_l reschain_l",
+ )
pairings = []
for pc, nc in itertools.product(poscenter, negcenter):
- if not config.MIN_DIST < euclidean3d(pc.center, nc.center) < config.SALTBRIDGE_DIST_MAX:
+ if (
+ not config.MIN_DIST
+ < euclidean3d(pc.center, nc.center)
+ < config.SALTBRIDGE_DIST_MAX
+ ):
continue
resnr = pc.resnr if protispos else nc.resnr
- resnr_l = whichresnumber(nc.orig_atoms[0]) if protispos else whichresnumber(pc.orig_atoms[0])
+ resnr_l = (
+ whichresnumber(nc.orig_atoms[0])
+ if protispos
+ else whichresnumber(pc.orig_atoms[0])
+ )
restype = pc.restype if protispos else nc.restype
- restype_l = whichrestype(nc.orig_atoms[0]) if protispos else whichrestype(pc.orig_atoms[0])
+ restype_l = (
+ whichrestype(nc.orig_atoms[0])
+ if protispos
+ else whichrestype(pc.orig_atoms[0])
+ )
reschain = pc.reschain if protispos else nc.reschain
- reschain_l = whichchain(nc.orig_atoms[0]) if protispos else whichchain(pc.orig_atoms[0])
- contact = data(positive=pc, negative=nc, distance=euclidean3d(pc.center, nc.center), protispos=protispos,
- resnr=resnr, restype=restype, reschain=reschain, resnr_l=resnr_l, restype_l=restype_l,
- reschain_l=reschain_l)
+ reschain_l = (
+ whichchain(nc.orig_atoms[0]) if protispos else whichchain(pc.orig_atoms[0])
+ )
+ contact = data(
+ positive=pc,
+ negative=nc,
+ distance=euclidean3d(pc.center, nc.center),
+ protispos=protispos,
+ resnr=resnr,
+ restype=restype,
+ reschain=reschain,
+ resnr_l=resnr_l,
+ restype_l=restype_l,
+ reschain_l=reschain_l,
+ )
pairings.append(contact)
return filter_contacts(pairings)
def halogen(acceptor, donor):
"""Detect all halogen bonds of the type Y-O...X-C"""
- data = namedtuple('halogenbond', 'acc acc_orig_idx don don_orig_idx distance don_angle acc_angle restype '
- 'resnr reschain restype_l resnr_l reschain_l donortype acctype sidechain')
+ data = namedtuple(
+ "halogenbond",
+ "acc acc_orig_idx don don_orig_idx distance don_angle acc_angle restype "
+ "resnr reschain restype_l resnr_l reschain_l donortype acctype sidechain",
+ )
pairings = []
for acc, don in itertools.product(acceptor, donor):
dist = euclidean3d(acc.o.coords, don.x.coords)
if not config.MIN_DIST < dist < config.HALOGEN_DIST_MAX:
continue
- vec1, vec2 = vector(acc.o.coords, acc.y.coords), vector(acc.o.coords, don.x.coords)
- vec3, vec4 = vector(don.x.coords, acc.o.coords), vector(don.x.coords, don.c.coords)
+ vec1, vec2 = (
+ vector(acc.o.coords, acc.y.coords),
+ vector(acc.o.coords, don.x.coords),
+ )
+ vec3, vec4 = (
+ vector(don.x.coords, acc.o.coords),
+ vector(don.x.coords, don.c.coords),
+ )
acc_angle, don_angle = vecangle(vec1, vec2), vecangle(vec3, vec4)
- is_sidechain_hal = acc.o.OBAtom.GetResidue().GetAtomProperty(acc.o.OBAtom, 8) # Check if sidechain atom
- if not config.HALOGEN_ACC_ANGLE - config.HALOGEN_ANGLE_DEV < acc_angle \
- < config.HALOGEN_ACC_ANGLE + config.HALOGEN_ANGLE_DEV:
+ is_sidechain_hal = acc.o.OBAtom.GetResidue().GetAtomProperty(
+ acc.o.OBAtom, 8
+ ) # Check if sidechain atom
+ if (
+ not config.HALOGEN_ACC_ANGLE - config.HALOGEN_ANGLE_DEV
+ < acc_angle
+ < config.HALOGEN_ACC_ANGLE + config.HALOGEN_ANGLE_DEV
+ ):
continue
- if not config.HALOGEN_DON_ANGLE - config.HALOGEN_ANGLE_DEV < don_angle \
- < config.HALOGEN_DON_ANGLE + config.HALOGEN_ANGLE_DEV:
+ if (
+ not config.HALOGEN_DON_ANGLE - config.HALOGEN_ANGLE_DEV
+ < don_angle
+ < config.HALOGEN_DON_ANGLE + config.HALOGEN_ANGLE_DEV
+ ):
continue
- restype, reschain, resnr = whichrestype(acc.o), whichchain(acc.o), whichresnumber(acc.o)
- restype_l, reschain_l, resnr_l = whichrestype(don.orig_x), whichchain(don.orig_x), whichresnumber(don.orig_x)
- contact = data(acc=acc, acc_orig_idx=acc.o_orig_idx, don=don, don_orig_idx=don.x_orig_idx,
- distance=dist, don_angle=don_angle, acc_angle=acc_angle,
- restype=restype, resnr=resnr,
- reschain=reschain, restype_l=restype_l,
- reschain_l=reschain_l, resnr_l=resnr_l, donortype=don.x.OBAtom.GetType(), acctype=acc.o.type,
- sidechain=is_sidechain_hal)
+ restype, reschain, resnr = (
+ whichrestype(acc.o),
+ whichchain(acc.o),
+ whichresnumber(acc.o),
+ )
+ restype_l, reschain_l, resnr_l = (
+ whichrestype(don.orig_x),
+ whichchain(don.orig_x),
+ whichresnumber(don.orig_x),
+ )
+ contact = data(
+ acc=acc,
+ acc_orig_idx=acc.o_orig_idx,
+ don=don,
+ don_orig_idx=don.x_orig_idx,
+ distance=dist,
+ don_angle=don_angle,
+ acc_angle=acc_angle,
+ restype=restype,
+ resnr=resnr,
+ reschain=reschain,
+ restype_l=restype_l,
+ reschain_l=reschain_l,
+ resnr_l=resnr_l,
+ donortype=don.x.OBAtom.GetType(),
+ acctype=acc.o.type,
+ sidechain=is_sidechain_hal,
+ )
pairings.append(contact)
return filter_contacts(pairings)
def water_bridges(bs_hba, lig_hba, bs_hbd, lig_hbd, water):
"""Find water-bridged hydrogen bonds between ligand and protein. For now only considers bridged of first degree."""
- data = namedtuple('waterbridge', 'a a_orig_idx atype d d_orig_idx dtype h water water_orig_idx distance_aw '
- 'distance_dw d_angle w_angle type resnr restype reschain resnr_l restype_l reschain_l protisdon')
+ data = namedtuple(
+ "waterbridge",
+ "a a_orig_idx atype d d_orig_idx dtype h water water_orig_idx distance_aw "
+ "distance_dw d_angle w_angle type resnr restype reschain resnr_l restype_l reschain_l protisdon",
+ )
pairings = []
# First find all acceptor-water pairs with distance within d
# and all donor-water pairs with distance within d and angle greater theta
@@ -274,15 +481,25 @@ def water_bridges(bs_hba, lig_hba, bs_hbd, lig_hbd, water):
prot_aw.append((acc2, w, dist))
for don1 in lig_hbd:
dist = euclidean3d(don1.d.coords, w.oxy.coords)
- d_angle = vecangle(vector(don1.h.coords, don1.d.coords), vector(don1.h.coords, w.oxy.coords))
- if config.WATER_BRIDGE_MINDIST <= dist <= config.WATER_BRIDGE_MAXDIST \
- and d_angle > config.WATER_BRIDGE_THETA_MIN:
+ d_angle = vecangle(
+ vector(don1.h.coords, don1.d.coords),
+ vector(don1.h.coords, w.oxy.coords),
+ )
+ if (
+ config.WATER_BRIDGE_MINDIST <= dist <= config.WATER_BRIDGE_MAXDIST
+ and d_angle > config.WATER_BRIDGE_THETA_MIN
+ ):
lig_dw.append((don1, w, dist, d_angle))
for don2 in bs_hbd:
dist = euclidean3d(don2.d.coords, w.oxy.coords)
- d_angle = vecangle(vector(don2.h.coords, don2.d.coords), vector(don2.h.coords, w.oxy.coords))
- if config.WATER_BRIDGE_MINDIST <= dist <= config.WATER_BRIDGE_MAXDIST \
- and d_angle > config.WATER_BRIDGE_THETA_MIN:
+ d_angle = vecangle(
+ vector(don2.h.coords, don2.d.coords),
+ vector(don2.h.coords, w.oxy.coords),
+ )
+ if (
+ config.WATER_BRIDGE_MINDIST <= dist <= config.WATER_BRIDGE_MAXDIST
+ and d_angle > config.WATER_BRIDGE_THETA_MIN
+ ):
prot_hw.append((don2, w, dist, d_angle))
for l, p in itertools.product(lig_aw, prot_hw):
@@ -291,17 +508,44 @@ def water_bridges(bs_hba, lig_hba, bs_hbd, lig_hbd, water):
if not wl.oxy == wd.oxy:
continue
# Same water molecule and angle within omega
- w_angle = vecangle(vector(acc.a.coords, wl.oxy.coords), vector(wl.oxy.coords, don.h.coords))
+ w_angle = vecangle(
+ vector(acc.a.coords, wl.oxy.coords), vector(wl.oxy.coords, don.h.coords)
+ )
if not config.WATER_BRIDGE_OMEGA_MIN < w_angle < config.WATER_BRIDGE_OMEGA_MAX:
continue
- resnr, reschain, restype = whichresnumber(don.d), whichchain(don.d), whichrestype(don.d)
- resnr_l, reschain_l, restype_l = whichresnumber(acc.a_orig_atom), whichchain(
- acc.a_orig_atom), whichrestype(acc.a_orig_atom)
- contact = data(a=acc.a, a_orig_idx=acc.a_orig_idx, atype=acc.a.type, d=don.d, d_orig_idx=don.d_orig_idx,
- dtype=don.d.type, h=don.h, water=wl.oxy, water_orig_idx=wl.oxy_orig_idx,
- distance_aw=distance_aw, distance_dw=distance_dw, d_angle=d_angle, w_angle=w_angle,
- type='first_deg', resnr=resnr, restype=restype,
- reschain=reschain, restype_l=restype_l, resnr_l=resnr_l, reschain_l=reschain_l, protisdon=True)
+ resnr, reschain, restype = (
+ whichresnumber(don.d),
+ whichchain(don.d),
+ whichrestype(don.d),
+ )
+ resnr_l, reschain_l, restype_l = (
+ whichresnumber(acc.a_orig_atom),
+ whichchain(acc.a_orig_atom),
+ whichrestype(acc.a_orig_atom),
+ )
+ contact = data(
+ a=acc.a,
+ a_orig_idx=acc.a_orig_idx,
+ atype=acc.a.type,
+ d=don.d,
+ d_orig_idx=don.d_orig_idx,
+ dtype=don.d.type,
+ h=don.h,
+ water=wl.oxy,
+ water_orig_idx=wl.oxy_orig_idx,
+ distance_aw=distance_aw,
+ distance_dw=distance_dw,
+ d_angle=d_angle,
+ w_angle=w_angle,
+ type="first_deg",
+ resnr=resnr,
+ restype=restype,
+ reschain=reschain,
+ restype_l=restype_l,
+ resnr_l=resnr_l,
+ reschain_l=reschain_l,
+ protisdon=True,
+ )
pairings.append(contact)
for p, l in itertools.product(prot_aw, lig_dw):
acc, wl, distance_aw = p
@@ -309,38 +553,71 @@ def water_bridges(bs_hba, lig_hba, bs_hbd, lig_hbd, water):
if not wl.oxy == wd.oxy:
continue
# Same water molecule and angle within omega
- w_angle = vecangle(vector(acc.a.coords, wl.oxy.coords), vector(wl.oxy.coords, don.h.coords))
+ w_angle = vecangle(
+ vector(acc.a.coords, wl.oxy.coords), vector(wl.oxy.coords, don.h.coords)
+ )
if not config.WATER_BRIDGE_OMEGA_MIN < w_angle < config.WATER_BRIDGE_OMEGA_MAX:
continue
- resnr, reschain, restype = whichresnumber(acc.a), whichchain(acc.a), whichrestype(acc.a)
- resnr_l, reschain_l, restype_l = whichresnumber(don.d_orig_atom), whichchain(
- don.d_orig_atom), whichrestype(don.d_orig_atom)
- contact = data(a=acc.a, a_orig_idx=acc.a_orig_idx, atype=acc.a.type, d=don.d, d_orig_idx=don.d_orig_idx,
- dtype=don.d.type, h=don.h, water=wl.oxy, water_orig_idx=wl.oxy_orig_idx,
- distance_aw=distance_aw, distance_dw=distance_dw,
- d_angle=d_angle, w_angle=w_angle, type='first_deg', resnr=resnr,
- restype=restype, reschain=reschain,
- restype_l=restype_l, reschain_l=reschain_l, resnr_l=resnr_l, protisdon=False)
+ resnr, reschain, restype = (
+ whichresnumber(acc.a),
+ whichchain(acc.a),
+ whichrestype(acc.a),
+ )
+ resnr_l, reschain_l, restype_l = (
+ whichresnumber(don.d_orig_atom),
+ whichchain(don.d_orig_atom),
+ whichrestype(don.d_orig_atom),
+ )
+ contact = data(
+ a=acc.a,
+ a_orig_idx=acc.a_orig_idx,
+ atype=acc.a.type,
+ d=don.d,
+ d_orig_idx=don.d_orig_idx,
+ dtype=don.d.type,
+ h=don.h,
+ water=wl.oxy,
+ water_orig_idx=wl.oxy_orig_idx,
+ distance_aw=distance_aw,
+ distance_dw=distance_dw,
+ d_angle=d_angle,
+ w_angle=w_angle,
+ type="first_deg",
+ resnr=resnr,
+ restype=restype,
+ reschain=reschain,
+ restype_l=restype_l,
+ reschain_l=reschain_l,
+ resnr_l=resnr_l,
+ protisdon=False,
+ )
pairings.append(contact)
return filter_contacts(pairings)
def metal_complexation(metals, metal_binding_lig, metal_binding_bs):
"""Find all metal complexes between metals and appropriate groups in both protein and ligand, as well as water"""
- data = namedtuple('metal_complex', 'metal metal_orig_idx metal_type target target_orig_idx target_type '
- 'coordination_num distance resnr restype '
- 'reschain restype_l reschain_l resnr_l location rms, geometry num_partners complexnum')
+ data = namedtuple(
+ "metal_complex",
+ "metal metal_orig_idx metal_type target target_orig_idx target_type "
+ "coordination_num distance resnr restype "
+ "reschain restype_l reschain_l resnr_l location rms, geometry num_partners complexnum",
+ )
pairings_dict = {}
pairings = []
# #@todo Refactor
metal_to_id = {}
metal_to_orig_atom = {}
- for metal, target in itertools.product(metals, metal_binding_lig + metal_binding_bs):
+ for metal, target in itertools.product(
+ metals, metal_binding_lig + metal_binding_bs
+ ):
distance = euclidean3d(metal.m.coords, target.atom.coords)
if not distance < config.METAL_DIST_MAX:
continue
if metal.m not in pairings_dict:
- pairings_dict[metal.m] = [(target, distance), ]
+ pairings_dict[metal.m] = [
+ (target, distance),
+ ]
metal_to_id[metal.m] = metal.m_orig_idx
metal_to_orig_atom[metal.m] = metal.orig_m
else:
@@ -354,24 +631,32 @@ def metal_complexation(metals, metal_binding_lig, metal_binding_bs):
vectors_dict = defaultdict(list)
for contact_pair in contact_pairs:
target, distance = contact_pair
- vectors_dict[target.atom.idx].append(vector(metal.coords, target.atom.coords))
+ vectors_dict[target.atom.idx].append(
+ vector(metal.coords, target.atom.coords)
+ )
# Listing of coordination numbers and their geometries
- configs = {2: ['linear', ],
- 3: ['trigonal.planar', 'trigonal.pyramidal'],
- 4: ['tetrahedral', 'square.planar'],
- 5: ['trigonal.bipyramidal', 'square.pyramidal'],
- 6: ['octahedral', ]}
+ configs = {
+ 2: ["linear",],
+ 3: ["trigonal.planar", "trigonal.pyramidal"],
+ 4: ["tetrahedral", "square.planar"],
+ 5: ["trigonal.bipyramidal", "square.pyramidal"],
+ 6: ["octahedral",],
+ }
# Angle signatures for each geometry (as seen from each target atom)
- ideal_angles = {'linear': [[180.0]] * 2,
- 'trigonal.planar': [[120.0, 120.0]] * 3,
- 'trigonal.pyramidal': [[109.5, 109.5]] * 3,
- 'tetrahedral': [[109.5, 109.5, 109.5, 109.5]] * 4,
- 'square.planar': [[90.0, 90.0, 90.0, 90.0]] * 4,
- 'trigonal.bipyramidal': [[120.0, 120.0, 90.0, 90.0]] * 3 + [[90.0, 90.0, 90.0, 180.0]] * 2,
- 'square.pyramidal': [[90.0, 90.0, 90.0, 180.0]] * 4 + [[90.0, 90.0, 90.0, 90.0]],
- 'octahedral': [[90.0, 90.0, 90.0, 90.0, 180.0]] * 6}
+ ideal_angles = {
+ "linear": [[180.0]] * 2,
+ "trigonal.planar": [[120.0, 120.0]] * 3,
+ "trigonal.pyramidal": [[109.5, 109.5]] * 3,
+ "tetrahedral": [[109.5, 109.5, 109.5, 109.5]] * 4,
+ "square.planar": [[90.0, 90.0, 90.0, 90.0]] * 4,
+ "trigonal.bipyramidal": [[120.0, 120.0, 90.0, 90.0]] * 3
+ + [[90.0, 90.0, 90.0, 180.0]] * 2,
+ "square.pyramidal": [[90.0, 90.0, 90.0, 180.0]] * 4
+ + [[90.0, 90.0, 90.0, 90.0]],
+ "octahedral": [[90.0, 90.0, 90.0, 90.0, 180.0]] * 6,
+ }
angles_dict = {}
for target in vectors_dict:
@@ -380,27 +665,40 @@ def metal_complexation(metals, metal_binding_lig, metal_binding_bs):
for t in vectors_dict:
if not t == target:
[other_vectors.append(x) for x in vectors_dict[t]]
- angles = [vecangle(pair[0], pair[1]) for pair in itertools.product(cur_vector, other_vectors)]
+ angles = [
+ vecangle(pair[0], pair[1])
+ for pair in itertools.product(cur_vector, other_vectors)
+ ]
angles_dict[target] = angles
all_total = [] # Record fit information for each geometry tested
- gdata = namedtuple('gdata', 'geometry rms coordination excluded diff_targets') # Geometry Data
+ gdata = namedtuple(
+ "gdata", "geometry rms coordination excluded diff_targets"
+ ) # Geometry Data
# Can't specify geometry with only one target
if num_targets == 1:
- final_geom = 'NA'
+ final_geom = "NA"
final_coo = 1
excluded = []
rms = 0.0
else:
- for coo in sorted(configs, reverse=True): # Start with highest coordination number
+ for coo in sorted(
+ configs, reverse=True
+ ): # Start with highest coordination number
geometries = configs[coo]
for geometry in geometries:
- signature = ideal_angles[geometry] # Set of ideal angles for geometry, from each perspective
+ signature = ideal_angles[
+ geometry
+ ] # Set of ideal angles for geometry, from each perspective
geometry_total = 0
- geometry_scores = [] # All scores for one geometry (from all subsignatures)
+ geometry_scores = (
+ []
+ ) # All scores for one geometry (from all subsignatures)
used_up_targets = [] # Use each target just once for a subsignature
not_used = []
- coo_diff = num_targets - coo # How many more observed targets are there?
+ coo_diff = (
+ num_targets - coo
+ ) # How many more observed targets are there?
# Find best match for each subsignature
for subsignature in signature: # Ideal angles from one perspective
@@ -409,7 +707,9 @@ def metal_complexation(metals, metal_binding_lig, metal_binding_bs):
for k, target in enumerate(angles_dict):
if target not in used_up_targets:
- observed_angles = angles_dict[target] # Observed angles from perspective of one target
+ observed_angles = angles_dict[
+ target
+ ] # Observed angles from perspective of one target
single_target_scores = []
used_up_observed_angles = []
for i, ideal_angle in enumerate(subsignature):
@@ -426,7 +726,9 @@ def metal_complexation(metals, metal_binding_lig, metal_binding_bs):
used_up_observed_angles.append(best_match)
single_target_scores.append(best_match_diff)
# Calculate RMS for target angles
- target_total = sum([x ** 2 for x in single_target_scores]) ** 0.5 # Tot. score targ/sig
+ target_total = (
+ sum([x ** 2 for x in single_target_scores]) ** 0.5
+ ) # Tot. score targ/sig
if target_total < best_target_score:
best_target_score = target_total
best_target = target
@@ -436,9 +738,20 @@ def metal_complexation(metals, metal_binding_lig, metal_binding_bs):
# Total score is mean of RMS values
geometry_total = np.mean(geometry_scores)
# Record the targets not used for excluding them when deciding for a final geometry
- [not_used.append(target) for target in angles_dict if target not in used_up_targets]
- all_total.append(gdata(geometry=geometry, rms=geometry_total, coordination=coo,
- excluded=not_used, diff_targets=coo_diff))
+ [
+ not_used.append(target)
+ for target in angles_dict
+ if target not in used_up_targets
+ ]
+ all_total.append(
+ gdata(
+ geometry=geometry,
+ rms=geometry_total,
+ coordination=coo,
+ excluded=not_used,
+ diff_targets=coo_diff,
+ )
+ )
# Make a decision here. Starting with the geometry with lowest difference in ideal and observed partners ...
# Check if the difference between the RMS to the next best solution is not larger than 0.5
@@ -449,31 +762,59 @@ def metal_complexation(metals, metal_binding_lig, metal_binding_bs):
this_rms, next_rms = total.rms, next_total.rms
diff_to_next = next_rms - this_rms
if diff_to_next > 0.5:
- final_geom, final_coo, rms, excluded = total.geometry, total.coordination, total.rms, total.excluded
+ final_geom, final_coo, rms, excluded = (
+ total.geometry,
+ total.coordination,
+ total.rms,
+ total.excluded,
+ )
break
elif next_total.rms < 3.5:
- final_geom, final_coo, = next_total.geometry, next_total.coordination
+ final_geom, final_coo, = (
+ next_total.geometry,
+ next_total.coordination,
+ )
rms, excluded = next_total.rms, next_total.excluded
break
elif i == len(all_total) - 2:
- final_geom, final_coo, rms, excluded = "NA", "NA", float('nan'), []
+ final_geom, final_coo, rms, excluded = "NA", "NA", float("nan"), []
break
# Record all contact pairing, excluding those with targets superfluous for chosen geometry
- only_water = set([x[0].location for x in contact_pairs]) == {'water'}
+ only_water = set([x[0].location for x in contact_pairs]) == {"water"}
if not only_water: # No complex if just with water as targets
- logger.info(f'metal ion {metal.type} complexed with {final_geom} geometry (coo. number {final_coo}/ {num_targets} observed)')
+ logger.info(
+ f"metal ion {metal.type} complexed with {final_geom} geometry (coo. number {final_coo}/ {num_targets} observed)"
+ )
for contact_pair in contact_pairs:
target, distance = contact_pair
if target.atom.idx not in excluded:
metal_orig_atom = metal_to_orig_atom[metal]
- restype_l, reschain_l, resnr_l = whichrestype(metal_orig_atom), whichchain(
- metal_orig_atom), whichresnumber(metal_orig_atom)
- contact = data(metal=metal, metal_orig_idx=metal_to_id[metal], metal_type=metal.type,
- target=target, target_orig_idx=target.atom_orig_idx, target_type=target.type,
- coordination_num=final_coo, distance=distance, resnr=target.resnr,
- restype=target.restype, reschain=target.reschain, location=target.location,
- rms=rms, geometry=final_geom, num_partners=num_targets, complexnum=cnum + 1,
- resnr_l=resnr_l, restype_l=restype_l, reschain_l=reschain_l)
+ restype_l, reschain_l, resnr_l = (
+ whichrestype(metal_orig_atom),
+ whichchain(metal_orig_atom),
+ whichresnumber(metal_orig_atom),
+ )
+ contact = data(
+ metal=metal,
+ metal_orig_idx=metal_to_id[metal],
+ metal_type=metal.type,
+ target=target,
+ target_orig_idx=target.atom_orig_idx,
+ target_type=target.type,
+ coordination_num=final_coo,
+ distance=distance,
+ resnr=target.resnr,
+ restype=target.restype,
+ reschain=target.reschain,
+ location=target.location,
+ rms=rms,
+ geometry=final_geom,
+ num_partners=num_targets,
+ complexnum=cnum + 1,
+ resnr_l=resnr_l,
+ restype_l=restype_l,
+ reschain_l=reschain_l,
+ )
pairings.append(contact)
return filter_contacts(pairings)
diff --git a/plip/structure/preparation.py b/plip/structure/preparation.py
index 6b63d63..6b4f04d 100644
--- a/plip/structure/preparation.py
+++ b/plip/structure/preparation.py
@@ -10,12 +10,39 @@ from openbabel import pybel
from plip.basic import config, logger
from plip.basic.supplemental import centroid, tilde_expansion, tmpfile, classify_by_name
-from plip.basic.supplemental import cluster_doubles, is_lig, normalize_vector, vector, ring_is_planar
-from plip.basic.supplemental import extract_pdbid, read_pdb, create_folder_if_not_exists, canonicalize
+from plip.basic.supplemental import (
+ cluster_doubles,
+ is_lig,
+ normalize_vector,
+ vector,
+ ring_is_planar,
+)
+from plip.basic.supplemental import (
+ extract_pdbid,
+ read_pdb,
+ create_folder_if_not_exists,
+ canonicalize,
+)
from plip.basic.supplemental import read, nucleotide_linkage, sort_members_by_importance
-from plip.basic.supplemental import whichchain, whichrestype, whichresnumber, euclidean3d, int32_to_negative
-from plip.structure.detection import halogen, pication, water_bridges, metal_complexation
-from plip.structure.detection import hydrophobic_interactions, pistacking, hbonds, saltbridge
+from plip.basic.supplemental import (
+ whichchain,
+ whichrestype,
+ whichresnumber,
+ euclidean3d,
+ int32_to_negative,
+)
+from plip.structure.detection import (
+ halogen,
+ pication,
+ water_bridges,
+ metal_complexation,
+)
+from plip.structure.detection import (
+ hydrophobic_interactions,
+ pistacking,
+ hbonds,
+ saltbridge,
+)
logger = logger.get_logger()
@@ -25,8 +52,16 @@ class PDBParser:
self.as_string = as_string
self.pdbpath = pdbpath
self.num_fixed_lines = 0
- self.covlinkage = namedtuple("covlinkage", "id1 chain1 pos1 conf1 id2 chain2 pos2 conf2")
- self.proteinmap, self.modres, self.covalent, self.altconformations, self.corrected_pdb = self.parse_pdb()
+ self.covlinkage = namedtuple(
+ "covlinkage", "id1 chain1 pos1 conf1 id2 chain2 pos2 conf2"
+ )
+ (
+ self.proteinmap,
+ self.modres,
+ self.covalent,
+ self.altconformations,
+ self.corrected_pdb,
+ ) = self.parse_pdb()
def parse_pdb(self):
"""Extracts additional information from PDB files.
@@ -38,7 +73,9 @@ class PDBParser:
IV. Alternative conformations
"""
if self.as_string:
- fil = self.pdbpath.rstrip('\n').split('\n') # Removing trailing newline character
+ fil = self.pdbpath.rstrip("\n").split(
+ "\n"
+ ) # Removing trailing newline character
else:
f = read(self.pdbpath)
fil = f.readlines()
@@ -57,19 +94,23 @@ class PDBParser:
lastnum = 0 # Atom numbering (has to be consecutive)
other_models = False
for line in fil:
- if not other_models: # Only consider the first model in an NRM structure
+ if (
+ not other_models
+ ): # Only consider the first model in an NRM structure
corrected_line, newnum = self.fix_pdbline(line, lastnum)
if corrected_line is not None:
- if corrected_line.startswith('MODEL'):
+ if corrected_line.startswith("MODEL"):
try: # Get number of MODEL (1,2,3)
model_num = int(corrected_line[10:14])
if model_num > 1: # MODEL 2,3,4 etc.
other_models = True
except ValueError:
- logger.debug(f'ignoring invalid MODEL entry: {corrected_line}')
+ logger.debug(
+ f"ignoring invalid MODEL entry: {corrected_line}"
+ )
corrected_lines.append(corrected_line)
lastnum = newnum
- corrected_pdb = ''.join(corrected_lines)
+ corrected_pdb = "".join(corrected_lines)
else:
corrected_pdb = self.pdbpath
corrected_lines = fil
@@ -81,8 +122,8 @@ class PDBParser:
if line.startswith(("ATOM", "HETATM")):
# Retrieve alternate conformations
atomid, location = int(line[6:11]), line[16]
- location = 'A' if location == ' ' else location
- if location != 'A':
+ location = "A" if location == " " else location
+ if location != "A":
alt.append(atomid)
if not previous_ter:
@@ -107,12 +148,18 @@ class PDBParser:
def fix_pdbline(self, pdbline, lastnum):
"""Fix a PDB line if information is missing."""
pdbqt_conversion = {
- "HD": "H", "HS": "H", "NA": "N",
- "NS": "N", "OA": "O", "OS": "O", "SA": "S"}
+ "HD": "H",
+ "HS": "H",
+ "NA": "N",
+ "NS": "N",
+ "OA": "O",
+ "OS": "O",
+ "SA": "S",
+ }
fixed = False
new_num = 0
forbidden_characters = "[^a-zA-Z0-9_]"
- pdbline = pdbline.strip('\n')
+ pdbline = pdbline.strip("\n")
# Some MD / Docking tools produce empty lines, leading to segfaults
if len(pdbline.strip()) == 0:
self.num_fixed_lines += 1
@@ -121,9 +168,9 @@ class PDBParser:
self.num_fixed_lines += 1
return None, lastnum
# TER Entries also have continuing numbering, consider them as well
- if pdbline.startswith('TER'):
+ if pdbline.startswith("TER"):
new_num = lastnum + 1
- if pdbline.startswith('ATOM'):
+ if pdbline.startswith("ATOM"):
new_num = lastnum + 1
current_num = int(pdbline[6:11])
resnum = pdbline[22:27].strip()
@@ -132,73 +179,107 @@ class PDBParser:
try:
int(resnum)
except ValueError:
- pdbline = pdbline[:22] + ' 0 ' + pdbline[27:]
+ pdbline = pdbline[:22] + " 0 " + pdbline[27:]
fixed = True
# Invalid characters in residue name
if re.match(forbidden_characters, resname.strip()):
- pdbline = pdbline[:17] + 'UNK ' + pdbline[21:]
+ pdbline = pdbline[:17] + "UNK " + pdbline[21:]
fixed = True
if lastnum + 1 != current_num:
- pdbline = pdbline[:6] + (5 - len(str(new_num))) * ' ' + str(new_num) + ' ' + pdbline[12:]
+ pdbline = (
+ pdbline[:6]
+ + (5 - len(str(new_num))) * " "
+ + str(new_num)
+ + " "
+ + pdbline[12:]
+ )
fixed = True
# No chain assigned
- if pdbline[21] == ' ':
- pdbline = pdbline[:21] + 'A' + pdbline[22:]
+ if pdbline[21] == " ":
+ pdbline = pdbline[:21] + "A" + pdbline[22:]
fixed = True
- if pdbline.endswith('H'):
+ if pdbline.endswith("H"):
self.num_fixed_lines += 1
return None, lastnum
# Sometimes, converted PDB structures contain PDBQT atom types. Fix that.
for pdbqttype in pdbqt_conversion:
if pdbline.strip().endswith(pdbqttype):
- pdbline = pdbline.strip()[:-2] + ' ' + pdbqt_conversion[pdbqttype] + '\n'
+ pdbline = (
+ pdbline.strip()[:-2] + " " + pdbqt_conversion[pdbqttype] + "\n"
+ )
self.num_fixed_lines += 1
- if pdbline.startswith('HETATM'):
+ if pdbline.startswith("HETATM"):
new_num = lastnum + 1
try:
current_num = int(pdbline[6:11])
except ValueError:
current_num = None
- logger.debug(f'invalid HETATM entry: {pdbline}')
+ logger.debug(f"invalid HETATM entry: {pdbline}")
if lastnum + 1 != current_num:
- pdbline = pdbline[:6] + (5 - len(str(new_num))) * ' ' + str(new_num) + ' ' + pdbline[12:]
+ pdbline = (
+ pdbline[:6]
+ + (5 - len(str(new_num))) * " "
+ + str(new_num)
+ + " "
+ + pdbline[12:]
+ )
fixed = True
# No chain assigned or number assigned as chain
- if pdbline[21] == ' ':
- pdbline = pdbline[:21] + 'Z' + pdbline[22:]
+ if pdbline[21] == " ":
+ pdbline = pdbline[:21] + "Z" + pdbline[22:]
fixed = True
# No residue number assigned
- if pdbline[23:26] == ' ':
- pdbline = pdbline[:23] + '999' + pdbline[26:]
+ if pdbline[23:26] == " ":
+ pdbline = pdbline[:23] + "999" + pdbline[26:]
fixed = True
# Non-standard Ligand Names
ligname = pdbline[17:21].strip()
if len(ligname) > 3:
- pdbline = pdbline[:17] + ligname[:3] + ' ' + pdbline[21:]
+ pdbline = pdbline[:17] + ligname[:3] + " " + pdbline[21:]
fixed = True
if re.match(forbidden_characters, ligname.strip()):
- pdbline = pdbline[:17] + 'LIG ' + pdbline[21:]
+ pdbline = pdbline[:17] + "LIG " + pdbline[21:]
fixed = True
if len(ligname.strip()) == 0:
- pdbline = pdbline[:17] + 'LIG ' + pdbline[21:]
+ pdbline = pdbline[:17] + "LIG " + pdbline[21:]
fixed = True
- if pdbline.endswith('H'):
+ if pdbline.endswith("H"):
self.num_fixed_lines += 1
return None, lastnum
# Sometimes, converted PDB structures contain PDBQT atom types. Fix that.
for pdbqttype in pdbqt_conversion:
if pdbline.strip().endswith(pdbqttype):
- pdbline = pdbline.strip()[:-2] + ' ' + pdbqt_conversion[pdbqttype] + ' '
+ pdbline = (
+ pdbline.strip()[:-2] + " " + pdbqt_conversion[pdbqttype] + " "
+ )
self.num_fixed_lines += 1
self.num_fixed_lines += 1 if fixed else 0
- return pdbline + '\n', max(new_num, lastnum)
+ return pdbline + "\n", max(new_num, lastnum)
def get_linkage(self, line):
"""Get the linkage information from a LINK entry PDB line."""
- conf1, id1, chain1, pos1 = line[16].strip(), line[17:20].strip(), line[21].strip(), int(line[22:26])
- conf2, id2, chain2, pos2 = line[46].strip(), line[47:50].strip(), line[51].strip(), int(line[52:56])
- return self.covlinkage(id1=id1, chain1=chain1, pos1=pos1, conf1=conf1,
- id2=id2, chain2=chain2, pos2=pos2, conf2=conf2)
+ conf1, id1, chain1, pos1 = (
+ line[16].strip(),
+ line[17:20].strip(),
+ line[21].strip(),
+ int(line[22:26]),
+ )
+ conf2, id2, chain2, pos2 = (
+ line[46].strip(),
+ line[47:50].strip(),
+ line[51].strip(),
+ int(line[52:56]),
+ )
+ return self.covlinkage(
+ id1=id1,
+ chain1=chain1,
+ pos1=pos1,
+ conf1=conf1,
+ id2=id2,
+ chain2=chain2,
+ pos2=pos2,
+ conf2=conf2,
+ )
class LigandFinder:
@@ -212,15 +293,20 @@ class LigandFinder:
self.covalent = covalent
self.mapper = mapper
self.ligands = self.getligs()
- self.excluded = sorted(list(self.lignames_all.difference(set(self.lignames_kept))))
+ self.excluded = sorted(
+ list(self.lignames_all.difference(set(self.lignames_kept)))
+ )
def getpeptides(self, chain):
"""If peptide ligand chains are defined via the command line options,
try to extract the underlying ligand formed by all residues in the
given chain without water
"""
- all_from_chain = [o for o in pybel.ob.OBResidueIter(
- self.proteincomplex.OBMol) if o.GetChain() == chain] # All residues from chain
+ all_from_chain = [
+ o
+ for o in pybel.ob.OBResidueIter(self.proteincomplex.OBMol)
+ if o.GetChain() == chain
+ ] # All residues from chain
if len(all_from_chain) == 0:
return None
else:
@@ -240,7 +326,9 @@ class LigandFinder:
# Filter for ligands using lists
ligand_residues, self.lignames_all, self.water = self.filter_for_ligands()
- all_res_dict = {(a.GetName(), a.GetChain(), a.GetNum()): a for a in ligand_residues}
+ all_res_dict = {
+ (a.GetName(), a.GetChain(), a.GetNum()): a for a in ligand_residues
+ }
self.lignames_kept = list(set([a.GetName() for a in ligand_residues]))
if not config.BREAKCOMPOSITE:
@@ -249,22 +337,35 @@ class LigandFinder:
# Find fragment linked by covalent bonds
res_kmers = self.identify_kmers(all_res_dict)
else:
- res_kmers = [[a, ] for a in ligand_residues]
- logger.debug(f'{len(res_kmers)} ligand kmer(s) detected for closer inspection')
- for kmer in res_kmers: # iterate over all ligands and extract molecules + information
+ res_kmers = [[a,] for a in ligand_residues]
+ logger.debug(
+ f"{len(res_kmers)} ligand kmer(s) detected for closer inspection"
+ )
+ for (
+ kmer
+ ) in (
+ res_kmers
+ ): # iterate over all ligands and extract molecules + information
if len(kmer) > config.MAX_COMPOSITE_LENGTH:
logger.debug(
- f'ligand kmer(s) filtered out with a length of {len(kmer)} fragments ({config.MAX_COMPOSITE_LENGTH} allowed)')
+ f"ligand kmer(s) filtered out with a length of {len(kmer)} fragments ({config.MAX_COMPOSITE_LENGTH} allowed)"
+ )
else:
ligands.append(self.extract_ligand(kmer))
else:
# Extract peptides from given chains
- self.water = [o for o in pybel.ob.OBResidueIter(self.proteincomplex.OBMol) if o.GetResidueProperty(9)]
+ self.water = [
+ o
+ for o in pybel.ob.OBResidueIter(self.proteincomplex.OBMol)
+ if o.GetResidueProperty(9)
+ ]
if config.PEPTIDES:
peptide_ligands = [self.getpeptides(chain) for chain in config.PEPTIDES]
elif config.INTRA is not None:
- peptide_ligands = [self.getpeptides(config.INTRA), ]
+ peptide_ligands = [
+ self.getpeptides(config.INTRA),
+ ]
ligands = [p for p in peptide_ligands if p is not None]
self.covalent, self.lignames_kept, self.lignames_all = [], [], set()
@@ -273,35 +374,53 @@ class LigandFinder:
def extract_ligand(self, kmer):
"""Extract the ligand by copying atoms and bonds and assign all information necessary for later steps."""
- data = namedtuple('ligand', 'mol hetid chain position water members longname type atomorder can_to_pdb')
- members = [(res.GetName(), res.GetChain(), int32_to_negative(res.GetNum())) for res in kmer]
+ data = namedtuple(
+ "ligand",
+ "mol hetid chain position water members longname type atomorder can_to_pdb",
+ )
+ members = [
+ (res.GetName(), res.GetChain(), int32_to_negative(res.GetNum()))
+ for res in kmer
+ ]
members = sort_members_by_importance(members)
rname, rchain, rnum = members[0]
- logger.debug(f'finalizing extraction for ligand {rname}:{rchain}:{rnum} with {len(kmer)} elements')
+ logger.debug(
+ f"finalizing extraction for ligand {rname}:{rchain}:{rnum} with {len(kmer)} elements"
+ )
names = [x[0] for x in members]
- longname = '-'.join([x[0] for x in members])
+ longname = "-".join([x[0] for x in members])
if config.PEPTIDES:
- ligtype = 'PEPTIDE'
+ ligtype = "PEPTIDE"
elif config.INTRA is not None:
- ligtype = 'INTRA'
+ ligtype = "INTRA"
else:
# Classify a ligand by its HETID(s)
ligtype = classify_by_name(names)
- logger.debug(f'ligand classified as {ligtype}')
+ logger.debug(f"ligand classified as {ligtype}")
hetatoms = set()
for obresidue in kmer:
- hetatoms_res = set([(obatom.GetIdx(), obatom) for obatom in pybel.ob.OBResidueAtomIter(obresidue)
- if obatom.GetAtomicNum() != 1])
+ hetatoms_res = set(
+ [
+ (obatom.GetIdx(), obatom)
+ for obatom in pybel.ob.OBResidueAtomIter(obresidue)
+ if obatom.GetAtomicNum() != 1
+ ]
+ )
if not config.ALTLOC:
# Remove alternative conformations (standard -> True)
- hetatoms_res = set([atm for atm in hetatoms_res
- if not self.mapper.mapid(atm[0], mtype='protein',
- to='internal') in self.altconformations])
+ hetatoms_res = set(
+ [
+ atm
+ for atm in hetatoms_res
+ if not self.mapper.mapid(atm[0], mtype="protein", to="internal")
+ in self.altconformations
+ ]
+ )
hetatoms.update(hetatoms_res)
- logger.debug(f'hetero atoms determined (n={len(hetatoms)})')
+ logger.debug(f"hetero atoms determined (n={len(hetatoms)})")
hetatoms = dict(hetatoms) # make it a dict with idx as key and OBAtom as value
lig = pybel.ob.OBMol() # new ligand mol
@@ -310,15 +429,24 @@ class LigandFinder:
idx = obatom.GetIdx()
lig.AddAtom(obatom)
# ids of all neighbours of obatom
- neighbours[idx] = set([neighbour_atom.GetIdx() for neighbour_atom
- in pybel.ob.OBAtomAtomIter(obatom)]) & set(hetatoms.keys())
- logger.debug(f'atom neighbours mapped')
+ neighbours[idx] = set(
+ [
+ neighbour_atom.GetIdx()
+ for neighbour_atom in pybel.ob.OBAtomAtomIter(obatom)
+ ]
+ ) & set(hetatoms.keys())
+ logger.debug(f"atom neighbours mapped")
##############################################################
# map the old atom idx of OBMol to the new idx of the ligand #
##############################################################
- newidx = dict(zip(hetatoms.keys(), [obatom.GetIdx() for obatom in pybel.ob.OBMolAtomIter(lig)]))
+ newidx = dict(
+ zip(
+ hetatoms.keys(),
+ [obatom.GetIdx() for obatom in pybel.ob.OBMolAtomIter(lig)],
+ )
+ )
mapold = dict(zip(newidx.values(), newidx))
# copy the bonds
for obatom in hetatoms:
@@ -328,16 +456,16 @@ class LigandFinder:
lig = pybel.Molecule(lig)
# For kmers, the representative ids are chosen (first residue of kmer)
- lig.data.update({'Name': rname, 'Chain': rchain, 'ResNr': rnum})
+ lig.data.update({"Name": rname, "Chain": rchain, "ResNr": rnum})
# Check if a negative residue number is represented as a 32 bit integer
if rnum > 10 ** 5:
rnum = int32_to_negative(rnum)
- lig.title = ':'.join((rname, rchain, str(rnum)))
+ lig.title = ":".join((rname, rchain, str(rnum)))
self.mapper.ligandmaps[lig.title] = mapold
- logger.debug('renumerated molecule generated')
+ logger.debug("renumerated molecule generated")
if not config.NOPDBCANMAP:
atomorder = canonicalize(lig)
@@ -348,9 +476,18 @@ class LigandFinder:
if atomorder is not None:
can_to_pdb = {atomorder[key - 1]: mapold[key] for key in mapold}
- ligand = data(mol=lig, hetid=rname, chain=rchain, position=rnum, water=self.water,
- members=members, longname=longname, type=ligtype, atomorder=atomorder,
- can_to_pdb=can_to_pdb)
+ ligand = data(
+ mol=lig,
+ hetid=rname,
+ chain=rchain,
+ position=rnum,
+ water=self.water,
+ members=members,
+ longname=longname,
+ type=ligtype,
+ atomorder=atomorder,
+ can_to_pdb=can_to_pdb,
+ )
return ligand
def is_het_residue(self, obres):
@@ -375,20 +512,35 @@ class LigandFinder:
def filter_for_ligands(self):
"""Given an OpenBabel Molecule, get all ligands, their names, and water"""
- candidates1 = [o for o in pybel.ob.OBResidueIter(
- self.proteincomplex.OBMol) if not o.GetResidueProperty(9) and self.is_het_residue(o)]
+ candidates1 = [
+ o
+ for o in pybel.ob.OBResidueIter(self.proteincomplex.OBMol)
+ if not o.GetResidueProperty(9) and self.is_het_residue(o)
+ ]
if config.DNARECEPTOR: # If DNA is the receptor, don't consider DNA as a ligand
- candidates1 = [res for res in candidates1 if res.GetName() not in config.DNA + config.RNA]
+ candidates1 = [
+ res
+ for res in candidates1
+ if res.GetName() not in config.DNA + config.RNA
+ ]
all_lignames = set([a.GetName() for a in candidates1])
- water = [o for o in pybel.ob.OBResidueIter(self.proteincomplex.OBMol) if o.GetResidueProperty(9)]
+ water = [
+ o
+ for o in pybel.ob.OBResidueIter(self.proteincomplex.OBMol)
+ if o.GetResidueProperty(9)
+ ]
# Filter out non-ligands
if not config.KEEPMOD: # Keep modified residues as ligands
- candidates2 = [a for a in candidates1 if is_lig(a.GetName()) and a.GetName() not in self.modresidues]
+ candidates2 = [
+ a
+ for a in candidates1
+ if is_lig(a.GetName()) and a.GetName() not in self.modresidues
+ ]
else:
candidates2 = [a for a in candidates1 if is_lig(a.GetName())]
- logger.debug(f'{len(candidates2)} ligand(s) after first filtering step')
+ logger.debug(f"{len(candidates2)} ligand(s) after first filtering step")
############################################
# Filtering by counting and artifacts list #
@@ -397,7 +549,10 @@ class LigandFinder:
unique_ligs = set(a.GetName() for a in candidates2)
for ulig in unique_ligs:
# Discard if appearing 15 times or more and is possible artifact
- if ulig in config.biolip_list and [a.GetName() for a in candidates2].count(ulig) >= 15:
+ if (
+ ulig in config.biolip_list
+ and [a.GetName() for a in candidates2].count(ulig) >= 15
+ ):
artifacts.append(ulig)
selected_ligands = [a for a in candidates2 if a.GetName() not in artifacts]
@@ -408,12 +563,19 @@ class LigandFinder:
"""Using the covalent linkage information, find out which fragments/subunits form a ligand."""
# Remove all those not considered by ligands and pairings including alternate conformations
- ligdoubles = [[(link.id1, link.chain1, link.pos1),
- (link.id2, link.chain2, link.pos2)] for link in
- [c for c in self.covalent if c.id1 in self.lignames_kept and c.id2 in self.lignames_kept
- and c.conf1 in ['A', ''] and c.conf2 in ['A', '']
- and (c.id1, c.chain1, c.pos1) in residues
- and (c.id2, c.chain2, c.pos2) in residues]]
+ ligdoubles = [
+ [(link.id1, link.chain1, link.pos1), (link.id2, link.chain2, link.pos2)]
+ for link in [
+ c
+ for c in self.covalent
+ if c.id1 in self.lignames_kept
+ and c.id2 in self.lignames_kept
+ and c.conf1 in ["A", ""]
+ and c.conf2 in ["A", ""]
+ and (c.id1, c.chain1, c.pos1) in residues
+ and (c.id2, c.chain2, c.pos2) in residues
+ ]
+ ]
kmers = cluster_doubles(ligdoubles)
if not kmers: # No ligand kmers, just normal independent ligands
return [[residues[res]] for res in residues]
@@ -429,7 +591,9 @@ class LigandFinder:
in_kmer.append((res.GetName(), res.GetChain(), res.GetNum()))
for res in residues:
if res not in in_kmer:
- newres = [residues[res], ]
+ newres = [
+ residues[res],
+ ]
res_kmers.append(newres)
return res_kmers
@@ -438,26 +602,32 @@ class Mapper:
"""Provides functions for mapping atom IDs in the correct way"""
def __init__(self):
- self.proteinmap = None # Map internal atom IDs of protein residues to original PDB Atom IDs
- self.ligandmaps = {} # Map IDs of new ligand molecules to internal IDs (or PDB IDs?)
+ self.proteinmap = (
+ None # Map internal atom IDs of protein residues to original PDB Atom IDs
+ )
+ self.ligandmaps = (
+ {}
+ ) # Map IDs of new ligand molecules to internal IDs (or PDB IDs?)
self.original_structure = None
- def mapid(self, idx, mtype, bsid=None, to='original'): # Mapping to original IDs is standard for ligands
- if mtype == 'reversed': # Needed to map internal ID back to original protein ID
+ def mapid(
+ self, idx, mtype, bsid=None, to="original"
+ ): # Mapping to original IDs is standard for ligands
+ if mtype == "reversed": # Needed to map internal ID back to original protein ID
return self.reversed_proteinmap[idx]
- if mtype == 'protein':
+ if mtype == "protein":
return self.proteinmap[idx]
- elif mtype == 'ligand':
- if to == 'internal':
+ elif mtype == "ligand":
+ if to == "internal":
return self.ligandmaps[bsid][idx]
- elif to == 'original':
+ elif to == "original":
return self.proteinmap[self.ligandmaps[bsid][idx]]
def id_to_atom(self, idx):
"""Returns the atom for a given original ligand ID.
To do this, the ID is mapped to the protein first and then the atom returned.
"""
- mapped_idx = self.mapid(idx, 'reversed')
+ mapped_idx = self.mapid(idx, "reversed")
return pybel.Atom(self.original_structure.GetAtom(mapped_idx))
@@ -476,10 +646,15 @@ class Mol:
def hydrophobic_atoms(self, all_atoms):
"""Select all carbon atoms which have only carbons and/or hydrogens as direct neighbors."""
atom_set = []
- data = namedtuple('hydrophobic', 'atom orig_atom orig_idx')
- atm = [a for a in all_atoms if a.atomicnum == 6 and set([natom.GetAtomicNum() for natom
- in pybel.ob.OBAtomAtomIter(a.OBAtom)]).issubset(
- {1, 6})]
+ data = namedtuple("hydrophobic", "atom orig_atom orig_idx")
+ atm = [
+ a
+ for a in all_atoms
+ if a.atomicnum == 6
+ and set(
+ [natom.GetAtomicNum() for natom in pybel.ob.OBAtomAtomIter(a.OBAtom)]
+ ).issubset({1, 6})
+ ]
for atom in atm:
orig_idx = self.Mapper.mapid(atom.idx, mtype=self.mtype, bsid=self.bsid)
orig_atom = self.Mapper.id_to_atom(orig_idx)
@@ -489,45 +664,88 @@ class Mol:
def find_hba(self, all_atoms):
"""Find all possible hydrogen bond acceptors"""
- data = namedtuple('hbondacceptor', 'a a_orig_atom a_orig_idx type')
+ data = namedtuple("hbondacceptor", "a a_orig_atom a_orig_idx type")
a_set = []
for atom in filter(lambda at: at.OBAtom.IsHbondAcceptor(), all_atoms):
- if atom.atomicnum not in [9, 17, 35, 53] and atom.idx not in self.altconf: # Exclude halogen atoms
- a_orig_idx = self.Mapper.mapid(atom.idx, mtype=self.mtype, bsid=self.bsid)
+ if (
+ atom.atomicnum not in [9, 17, 35, 53] and atom.idx not in self.altconf
+ ): # Exclude halogen atoms
+ a_orig_idx = self.Mapper.mapid(
+ atom.idx, mtype=self.mtype, bsid=self.bsid
+ )
a_orig_atom = self.Mapper.id_to_atom(a_orig_idx)
- a_set.append(data(a=atom, a_orig_atom=a_orig_atom, a_orig_idx=a_orig_idx, type='regular'))
+ a_set.append(
+ data(
+ a=atom,
+ a_orig_atom=a_orig_atom,
+ a_orig_idx=a_orig_idx,
+ type="regular",
+ )
+ )
a_set = sorted(a_set, key=lambda x: x.a_orig_idx)
return a_set
def find_hbd(self, all_atoms, hydroph_atoms):
"""Find all possible strong and weak hydrogen bonds donors (all hydrophobic C-H pairings)"""
donor_pairs = []
- data = namedtuple('hbonddonor', 'd d_orig_atom d_orig_idx h type')
- for donor in [a for a in all_atoms if a.OBAtom.IsHbondDonor() and a.idx not in self.altconf]:
+ data = namedtuple("hbonddonor", "d d_orig_atom d_orig_idx h type")
+ for donor in [
+ a
+ for a in all_atoms
+ if a.OBAtom.IsHbondDonor() and a.idx not in self.altconf
+ ]:
in_ring = False
if not in_ring:
- for adj_atom in [a for a in pybel.ob.OBAtomAtomIter(donor.OBAtom) if a.IsHbondDonorH()]:
- d_orig_idx = self.Mapper.mapid(donor.idx, mtype=self.mtype, bsid=self.bsid)
+ for adj_atom in [
+ a
+ for a in pybel.ob.OBAtomAtomIter(donor.OBAtom)
+ if a.IsHbondDonorH()
+ ]:
+ d_orig_idx = self.Mapper.mapid(
+ donor.idx, mtype=self.mtype, bsid=self.bsid
+ )
d_orig_atom = self.Mapper.id_to_atom(d_orig_idx)
- donor_pairs.append(data(d=donor, d_orig_atom=d_orig_atom, d_orig_idx=d_orig_idx,
- h=pybel.Atom(adj_atom), type='regular'))
+ donor_pairs.append(
+ data(
+ d=donor,
+ d_orig_atom=d_orig_atom,
+ d_orig_idx=d_orig_idx,
+ h=pybel.Atom(adj_atom),
+ type="regular",
+ )
+ )
for carbon in hydroph_atoms:
- for adj_atom in [a for a in pybel.ob.OBAtomAtomIter(carbon.atom.OBAtom) if a.GetAtomicNum() == 1]:
- d_orig_idx = self.Mapper.mapid(carbon.atom.idx, mtype=self.mtype, bsid=self.bsid)
+ for adj_atom in [
+ a
+ for a in pybel.ob.OBAtomAtomIter(carbon.atom.OBAtom)
+ if a.GetAtomicNum() == 1
+ ]:
+ d_orig_idx = self.Mapper.mapid(
+ carbon.atom.idx, mtype=self.mtype, bsid=self.bsid
+ )
d_orig_atom = self.Mapper.id_to_atom(d_orig_idx)
- donor_pairs.append(data(d=carbon, d_orig_atom=d_orig_atom,
- d_orig_idx=d_orig_idx, h=pybel.Atom(adj_atom), type='weak'))
+ donor_pairs.append(
+ data(
+ d=carbon,
+ d_orig_atom=d_orig_atom,
+ d_orig_idx=d_orig_idx,
+ h=pybel.Atom(adj_atom),
+ type="weak",
+ )
+ )
donor_pairs = sorted(donor_pairs, key=lambda x: (x.d_orig_idx, x.h.idx))
return donor_pairs
def find_rings(self, mol, all_atoms):
"""Find rings and return only aromatic.
Rings have to be sufficiently planar OR be detected by OpenBabel as aromatic."""
- data = namedtuple('aromatic_ring', 'atoms orig_atoms atoms_orig_idx normal obj center type')
+ data = namedtuple(
+ "aromatic_ring", "atoms orig_atoms atoms_orig_idx normal obj center type"
+ )
rings = []
- aromatic_amino = ['TYR', 'TRP', 'HIS', 'PHE']
+ aromatic_amino = ["TYR", "TRP", "HIS", "PHE"]
ring_candidates = mol.OBMol.GetSSSR()
- logger.debug(f'number of aromatic ring candidates: {len(ring_candidates)}')
+ logger.debug(f"number of aromatic ring candidates: {len(ring_candidates)}")
# Check here first for ligand rings not being detected as aromatic by Babel and check for planarity
for ring in ring_candidates:
r_atoms = [a for a in all_atoms if ring.IsMember(a.OBAtom)]
@@ -535,28 +753,42 @@ class Mol:
if 4 < len(r_atoms) <= 6:
res = list(set([whichrestype(a) for a in r_atoms]))
# re-sort ring atoms for only ligands, because HETATM numbering is not canonical in OpenBabel
- if res[0] == 'UNL':
- ligand_orig_idx = [self.Mapper.ligandmaps[self.bsid][a.idx] for a in r_atoms]
+ if res[0] == "UNL":
+ ligand_orig_idx = [
+ self.Mapper.ligandmaps[self.bsid][a.idx] for a in r_atoms
+ ]
sort_order = np.argsort(np.array(ligand_orig_idx))
r_atoms = [r_atoms[i] for i in sort_order]
- if ring.IsAromatic() or res[0] in aromatic_amino or ring_is_planar(ring, r_atoms):
+ if (
+ ring.IsAromatic()
+ or res[0] in aromatic_amino
+ or ring_is_planar(ring, r_atoms)
+ ):
# Causes segfault with OpenBabel 2.3.2, so deactivated
# typ = ring.GetType() if not ring.GetType() == '' else 'unknown'
# Alternative typing
- ring_type = '%s-membered' % len(r_atoms)
- ring_atms = [r_atoms[a].coords for a in [0, 2, 4]] # Probe atoms for normals, assuming planarity
+ ring_type = "%s-membered" % len(r_atoms)
+ ring_atms = [
+ r_atoms[a].coords for a in [0, 2, 4]
+ ] # Probe atoms for normals, assuming planarity
ringv1 = vector(ring_atms[0], ring_atms[1])
ringv2 = vector(ring_atms[2], ring_atms[0])
- atoms_orig_idx = [self.Mapper.mapid(r_atom.idx, mtype=self.mtype,
- bsid=self.bsid) for r_atom in r_atoms]
+ atoms_orig_idx = [
+ self.Mapper.mapid(r_atom.idx, mtype=self.mtype, bsid=self.bsid)
+ for r_atom in r_atoms
+ ]
orig_atoms = [self.Mapper.id_to_atom(idx) for idx in atoms_orig_idx]
- rings.append(data(atoms=r_atoms,
- orig_atoms=orig_atoms,
- atoms_orig_idx=atoms_orig_idx,
- normal=normalize_vector(np.cross(ringv1, ringv2)),
- obj=ring,
- center=centroid([ra.coords for ra in r_atoms]),
- type=ring_type))
+ rings.append(
+ data(
+ atoms=r_atoms,
+ orig_atoms=orig_atoms,
+ atoms_orig_idx=atoms_orig_idx,
+ normal=normalize_vector(np.cross(ringv1, ringv2)),
+ obj=ring,
+ center=centroid([ra.coords for ra in r_atoms]),
+ type=ring_type,
+ )
+ )
return rings
def get_hydrophobic_atoms(self):
@@ -566,16 +798,24 @@ class Mol:
return self.hbond_acc_atoms
def get_hbd(self):
- return [don_pair for don_pair in self.hbond_don_atom_pairs if don_pair.type == 'regular']
+ return [
+ don_pair
+ for don_pair in self.hbond_don_atom_pairs
+ if don_pair.type == "regular"
+ ]
def get_weak_hbd(self):
- return [don_pair for don_pair in self.hbond_don_atom_pairs if don_pair.type == 'weak']
+ return [
+ don_pair
+ for don_pair in self.hbond_don_atom_pairs
+ if don_pair.type == "weak"
+ ]
def get_pos_charged(self):
- return [charge for charge in self.charged if charge.type == 'positive']
+ return [charge for charge in self.charged if charge.type == "positive"]
def get_neg_charged(self):
- return [charge for charge in self.charged if charge.type == 'negative']
+ return [charge for charge in self.charged if charge.type == "negative"]
class PLInteraction:
@@ -592,65 +832,135 @@ class PLInteraction:
self.altconf = protcomplex.altconf
# #@todo Refactor code to combine different directionality
- self.saltbridge_lneg = saltbridge(self.bindingsite.get_pos_charged(), self.ligand.get_neg_charged(), True)
- self.saltbridge_pneg = saltbridge(self.ligand.get_pos_charged(), self.bindingsite.get_neg_charged(), False)
-
- self.all_hbonds_ldon = hbonds(self.bindingsite.get_hba(),
- self.ligand.get_hbd(), False, 'strong')
- self.all_hbonds_pdon = hbonds(self.ligand.get_hba(),
- self.bindingsite.get_hbd(), True, 'strong')
-
- self.hbonds_ldon = self.refine_hbonds_ldon(self.all_hbonds_ldon, self.saltbridge_lneg,
- self.saltbridge_pneg)
- self.hbonds_pdon = self.refine_hbonds_pdon(self.all_hbonds_pdon, self.saltbridge_lneg,
- self.saltbridge_pneg)
+ self.saltbridge_lneg = saltbridge(
+ self.bindingsite.get_pos_charged(), self.ligand.get_neg_charged(), True
+ )
+ self.saltbridge_pneg = saltbridge(
+ self.ligand.get_pos_charged(), self.bindingsite.get_neg_charged(), False
+ )
+
+ self.all_hbonds_ldon = hbonds(
+ self.bindingsite.get_hba(), self.ligand.get_hbd(), False, "strong"
+ )
+ self.all_hbonds_pdon = hbonds(
+ self.ligand.get_hba(), self.bindingsite.get_hbd(), True, "strong"
+ )
+
+ self.hbonds_ldon = self.refine_hbonds_ldon(
+ self.all_hbonds_ldon, self.saltbridge_lneg, self.saltbridge_pneg
+ )
+ self.hbonds_pdon = self.refine_hbonds_pdon(
+ self.all_hbonds_pdon, self.saltbridge_lneg, self.saltbridge_pneg
+ )
self.pistacking = pistacking(self.bindingsite.rings, self.ligand.rings)
- self.all_pi_cation_laro = pication(self.ligand.rings, self.bindingsite.get_pos_charged(), True)
- self.pication_paro = pication(self.bindingsite.rings, self.ligand.get_pos_charged(), False)
-
- self.pication_laro = self.refine_pi_cation_laro(self.all_pi_cation_laro, self.pistacking)
-
- self.all_hydrophobic_contacts = hydrophobic_interactions(self.bindingsite.get_hydrophobic_atoms(),
- self.ligand.get_hydrophobic_atoms())
- self.hydrophobic_contacts = self.refine_hydrophobic(self.all_hydrophobic_contacts, self.pistacking)
- self.halogen_bonds = halogen(self.bindingsite.halogenbond_acc, self.ligand.halogenbond_don)
- self.water_bridges = water_bridges(self.bindingsite.get_hba(), self.ligand.get_hba(),
- self.bindingsite.get_hbd(), self.ligand.get_hbd(),
- self.ligand.water)
-
- self.water_bridges = self.refine_water_bridges(self.water_bridges, self.hbonds_ldon, self.hbonds_pdon)
-
- self.metal_complexes = metal_complexation(self.ligand.metals, self.ligand.metal_binding,
- self.bindingsite.metal_binding)
+ self.all_pi_cation_laro = pication(
+ self.ligand.rings, self.bindingsite.get_pos_charged(), True
+ )
+ self.pication_paro = pication(
+ self.bindingsite.rings, self.ligand.get_pos_charged(), False
+ )
+
+ self.pication_laro = self.refine_pi_cation_laro(
+ self.all_pi_cation_laro, self.pistacking
+ )
+
+ self.all_hydrophobic_contacts = hydrophobic_interactions(
+ self.bindingsite.get_hydrophobic_atoms(),
+ self.ligand.get_hydrophobic_atoms(),
+ )
+ self.hydrophobic_contacts = self.refine_hydrophobic(
+ self.all_hydrophobic_contacts, self.pistacking
+ )
+ self.halogen_bonds = halogen(
+ self.bindingsite.halogenbond_acc, self.ligand.halogenbond_don
+ )
+ self.water_bridges = water_bridges(
+ self.bindingsite.get_hba(),
+ self.ligand.get_hba(),
+ self.bindingsite.get_hbd(),
+ self.ligand.get_hbd(),
+ self.ligand.water,
+ )
+
+ self.water_bridges = self.refine_water_bridges(
+ self.water_bridges, self.hbonds_ldon, self.hbonds_pdon
+ )
+
+ self.metal_complexes = metal_complexation(
+ self.ligand.metals,
+ self.ligand.metal_binding,
+ self.bindingsite.metal_binding,
+ )
self.all_itypes = self.saltbridge_lneg + self.saltbridge_pneg + self.hbonds_pdon
- self.all_itypes = self.all_itypes + self.hbonds_ldon + self.pistacking + self.pication_laro + self.pication_paro
- self.all_itypes = self.all_itypes + self.hydrophobic_contacts + self.halogen_bonds + self.water_bridges
+ self.all_itypes = (
+ self.all_itypes
+ + self.hbonds_ldon
+ + self.pistacking
+ + self.pication_laro
+ + self.pication_paro
+ )
+ self.all_itypes = (
+ self.all_itypes
+ + self.hydrophobic_contacts
+ + self.halogen_bonds
+ + self.water_bridges
+ )
self.all_itypes = self.all_itypes + self.metal_complexes
self.no_interactions = all(len(i) == 0 for i in self.all_itypes)
- self.unpaired_hba, self.unpaired_hbd, self.unpaired_hal = self.find_unpaired_ligand()
- self.unpaired_hba_orig_idx = [self.Mapper.mapid(atom.idx, mtype='ligand', bsid=self.ligand.bsid)
- for atom in self.unpaired_hba]
- self.unpaired_hbd_orig_idx = [self.Mapper.mapid(atom.idx, mtype='ligand', bsid=self.ligand.bsid)
- for atom in self.unpaired_hbd]
- self.unpaired_hal_orig_idx = [self.Mapper.mapid(atom.idx, mtype='ligand', bsid=self.ligand.bsid)
- for atom in self.unpaired_hal]
- self.num_unpaired_hba, self.num_unpaired_hbd = len(self.unpaired_hba), len(self.unpaired_hbd)
+ (
+ self.unpaired_hba,
+ self.unpaired_hbd,
+ self.unpaired_hal,
+ ) = self.find_unpaired_ligand()
+ self.unpaired_hba_orig_idx = [
+ self.Mapper.mapid(atom.idx, mtype="ligand", bsid=self.ligand.bsid)
+ for atom in self.unpaired_hba
+ ]
+ self.unpaired_hbd_orig_idx = [
+ self.Mapper.mapid(atom.idx, mtype="ligand", bsid=self.ligand.bsid)
+ for atom in self.unpaired_hbd
+ ]
+ self.unpaired_hal_orig_idx = [
+ self.Mapper.mapid(atom.idx, mtype="ligand", bsid=self.ligand.bsid)
+ for atom in self.unpaired_hal
+ ]
+ self.num_unpaired_hba, self.num_unpaired_hbd = (
+ len(self.unpaired_hba),
+ len(self.unpaired_hbd),
+ )
self.num_unpaired_hal = len(self.unpaired_hal)
# Exclude empty chains (coming from ligand as a target, from metal complexes)
- self.interacting_chains = sorted(list(set([i.reschain for i in self.all_itypes
- if i.reschain not in [' ', None]])))
+ self.interacting_chains = sorted(
+ list(
+ set(
+ [
+ i.reschain
+ for i in self.all_itypes
+ if i.reschain not in [" ", None]
+ ]
+ )
+ )
+ )
# Get all interacting residues, excluding ligand and water molecules
- self.interacting_res = list(set([''.join([str(i.resnr), str(i.reschain)]) for i in self.all_itypes
- if i.restype not in ['LIG', 'HOH']]))
+ self.interacting_res = list(
+ set(
+ [
+ "".join([str(i.resnr), str(i.reschain)])
+ for i in self.all_itypes
+ if i.restype not in ["LIG", "HOH"]
+ ]
+ )
+ )
if len(self.interacting_res) != 0:
logger.info(
- f'ligand interacts with {len(self.interacting_res)} binding site residue(s) in chain(s) {self.interacting_chains}')
+ f"ligand interacts with {len(self.interacting_res)} binding site residue(s) in chain(s) {self.interacting_chains}"
+ )
interactions_list = []
num_saltbridges = len(self.saltbridge_lneg + self.saltbridge_pneg)
num_hbonds = len(self.hbonds_ldon + self.hbonds_pdon)
@@ -659,34 +969,49 @@ class PLInteraction:
num_halogen = len(self.halogen_bonds)
num_waterbridges = len(self.water_bridges)
if num_saltbridges != 0:
- interactions_list.append('%i salt bridge(s)' % num_saltbridges)
+ interactions_list.append("%i salt bridge(s)" % num_saltbridges)
if num_hbonds != 0:
- interactions_list.append('%i hydrogen bond(s)' % num_hbonds)
+ interactions_list.append("%i hydrogen bond(s)" % num_hbonds)
if num_pication != 0:
- interactions_list.append('%i pi-cation interaction(s)' % num_pication)
+ interactions_list.append("%i pi-cation interaction(s)" % num_pication)
if num_pistack != 0:
- interactions_list.append('%i pi-stacking(s)' % num_pistack)
+ interactions_list.append("%i pi-stacking(s)" % num_pistack)
if num_halogen != 0:
- interactions_list.append('%i halogen bond(s)' % num_halogen)
+ interactions_list.append("%i halogen bond(s)" % num_halogen)
if num_waterbridges != 0:
- interactions_list.append('%i water bridge(s)' % num_waterbridges)
+ interactions_list.append("%i water bridge(s)" % num_waterbridges)
if not len(interactions_list) == 0:
- logger.info(f'complex uses {interactions_list}')
+ logger.info(f"complex uses {interactions_list}")
else:
- logger.info('no interactions for this ligand')
+ logger.info("no interactions for this ligand")
def find_unpaired_ligand(self):
"""Identify unpaired functional in groups in ligands, involving H-Bond donors, acceptors, halogen bond donors.
"""
unpaired_hba, unpaired_hbd, unpaired_hal = [], [], []
# Unpaired hydrogen bond acceptors/donors in ligand (not used for hydrogen bonds/water, salt bridges/mcomplex)
- involved_atoms = [hbond.a.idx for hbond in self.hbonds_pdon] + [hbond.d.idx for hbond in self.hbonds_ldon]
- [[involved_atoms.append(atom.idx) for atom in sb.negative.atoms] for sb in self.saltbridge_lneg]
- [[involved_atoms.append(atom.idx) for atom in sb.positive.atoms] for sb in self.saltbridge_pneg]
+ involved_atoms = [hbond.a.idx for hbond in self.hbonds_pdon] + [
+ hbond.d.idx for hbond in self.hbonds_ldon
+ ]
+ [
+ [involved_atoms.append(atom.idx) for atom in sb.negative.atoms]
+ for sb in self.saltbridge_lneg
+ ]
+ [
+ [involved_atoms.append(atom.idx) for atom in sb.positive.atoms]
+ for sb in self.saltbridge_pneg
+ ]
[involved_atoms.append(wb.a.idx) for wb in self.water_bridges if wb.protisdon]
- [involved_atoms.append(wb.d.idx) for wb in self.water_bridges if not wb.protisdon]
- [involved_atoms.append(mcomplex.target.atom.idx) for mcomplex in self.metal_complexes
- if mcomplex.location == 'ligand']
+ [
+ involved_atoms.append(wb.d.idx)
+ for wb in self.water_bridges
+ if not wb.protisdon
+ ]
+ [
+ involved_atoms.append(mcomplex.target.atom.idx)
+ for mcomplex in self.metal_complexes
+ if mcomplex.location == "ligand"
+ ]
for atom in [hba.a for hba in self.ligand.get_hba()]:
if atom.idx not in involved_atoms:
unpaired_hba.append(atom)
@@ -708,7 +1033,10 @@ class PLInteraction:
# 1. Rings interacting via stacking can't have additional hydrophobic contacts between each other.
for pistack, h in itertools.product(pistacks, all_h):
h1, h2 = h.bsatom.idx, h.ligatom.idx
- brs, lrs = [p1.idx for p1 in pistack.proteinring.atoms], [p2.idx for p2 in pistack.ligandring.atoms]
+ brs, lrs = (
+ [p1.idx for p1 in pistack.proteinring.atoms],
+ [p2.idx for p2 in pistack.ligandring.atoms],
+ )
if h1 in brs and h2 in lrs:
sel[(h1, h2)] = "EXCLUDE"
hydroph = [h for h in all_h if not (h.bsatom.idx, h.ligatom.idx) in sel]
@@ -727,7 +1055,9 @@ class PLInteraction:
# 3. If a protein atom interacts with several neighboring ligand atoms, just keep the one with the closest dist
for h in hydroph:
if h.bsatom.idx not in bsclust:
- bsclust[h.bsatom.idx] = [h, ]
+ bsclust[h.bsatom.idx] = [
+ h,
+ ]
else:
bsclust[h.bsatom.idx].append(h)
@@ -753,10 +1083,12 @@ class PLInteraction:
tuples = list(set(tuples))
tuples = sorted(tuples, key=itemgetter(1))
- clusters = cluster_doubles(tuples) # Cluster connected atoms (i.e. find hydrophobic patches)
+ clusters = cluster_doubles(
+ tuples
+ ) # Cluster connected atoms (i.e. find hydrophobic patches)
for cluster in clusters:
- min_dist = float('inf')
+ min_dist = float("inf")
min_h = None
for atm_idx in cluster:
h = idx_to_h[atm_idx]
@@ -766,7 +1098,9 @@ class PLInteraction:
hydroph_final.append(min_h)
before, reduced = len(all_h), len(hydroph_final)
if not before == 0 and not before == reduced:
- logger.info(f'reduced number of hydrophobic contacts from {before} to {reduced}')
+ logger.info(
+ f"reduced number of hydrophobic contacts from {before} to {reduced}"
+ )
return hydroph_final
def refine_hbonds_ldon(self, all_hbonds, salt_lneg, salt_pneg):
@@ -775,11 +1109,17 @@ class PLInteraction:
for hbond in all_hbonds:
i_set[hbond] = False
for salt in salt_pneg:
- protidx, ligidx = [at.idx for at in salt.negative.atoms], [at.idx for at in salt.positive.atoms]
+ protidx, ligidx = (
+ [at.idx for at in salt.negative.atoms],
+ [at.idx for at in salt.positive.atoms],
+ )
if hbond.d.idx in ligidx and hbond.a.idx in protidx:
i_set[hbond] = True
for salt in salt_lneg:
- protidx, ligidx = [at.idx for at in salt.positive.atoms], [at.idx for at in salt.negative.atoms]
+ protidx, ligidx = (
+ [at.idx for at in salt.positive.atoms],
+ [at.idx for at in salt.negative.atoms],
+ )
if hbond.d.idx in ligidx and hbond.a.idx in protidx:
i_set[hbond] = True
@@ -802,11 +1142,17 @@ class PLInteraction:
for hbond in all_hbonds:
i_set[hbond] = False
for salt in salt_lneg:
- protidx, ligidx = [at.idx for at in salt.positive.atoms], [at.idx for at in salt.negative.atoms]
+ protidx, ligidx = (
+ [at.idx for at in salt.positive.atoms],
+ [at.idx for at in salt.negative.atoms],
+ )
if hbond.a.idx in ligidx and hbond.d.idx in protidx:
i_set[hbond] = True
for salt in salt_pneg:
- protidx, ligidx = [at.idx for at in salt.negative.atoms], [at.idx for at in salt.positive.atoms]
+ protidx, ligidx = (
+ [at.idx for at in salt.negative.atoms],
+ [at.idx for at in salt.positive.atoms],
+ )
if hbond.a.idx in ligidx and hbond.d.idx in protidx:
i_set[hbond] = True
@@ -830,7 +1176,10 @@ class PLInteraction:
for picat in all_picat:
exclude = False
for stack in stacks:
- if whichrestype(stack.proteinring.atoms[0]) == 'HIS' and picat.ring.obj == stack.ligandring.obj:
+ if (
+ whichrestype(stack.proteinring.atoms[0]) == "HIS"
+ and picat.ring.obj == stack.ligandring.obj
+ ):
exclude = True
if not exclude:
i_set.append(picat)
@@ -849,18 +1198,27 @@ class PLInteraction:
if (wbridge.water.idx, wbridge.a.idx) not in wb_dict:
wb_dict[(wbridge.water.idx, wbridge.a.idx)] = wbridge
else:
- if abs(omega - wb_dict[(wbridge.water.idx, wbridge.a.idx)].w_angle) < abs(omega - wbridge.w_angle):
+ if abs(
+ omega - wb_dict[(wbridge.water.idx, wbridge.a.idx)].w_angle
+ ) < abs(omega - wbridge.w_angle):
wb_dict[(wbridge.water.idx, wbridge.a.idx)] = wbridge
for wb_tuple in wb_dict:
water, acceptor = wb_tuple
if water not in wb_dict2:
- wb_dict2[water] = [(abs(omega - wb_dict[wb_tuple].w_angle), wb_dict[wb_tuple]), ]
+ wb_dict2[water] = [
+ (abs(omega - wb_dict[wb_tuple].w_angle), wb_dict[wb_tuple]),
+ ]
elif len(wb_dict2[water]) == 1:
- wb_dict2[water].append((abs(omega - wb_dict[wb_tuple].w_angle), wb_dict[wb_tuple]))
+ wb_dict2[water].append(
+ (abs(omega - wb_dict[wb_tuple].w_angle), wb_dict[wb_tuple])
+ )
wb_dict2[water] = sorted(wb_dict2[water], key=lambda x: x[0])
else:
if wb_dict2[water][1][0] < abs(omega - wb_dict[wb_tuple].w_angle):
- wb_dict2[water] = [wb_dict2[water][0], (wb_dict[wb_tuple].w_angle, wb_dict[wb_tuple])]
+ wb_dict2[water] = [
+ wb_dict2[water][0],
+ (wb_dict[wb_tuple].w_angle, wb_dict[wb_tuple]),
+ ]
filtered_wb = []
for fwbridges in wb_dict2.values():
@@ -871,12 +1229,19 @@ class PLInteraction:
class BindingSite(Mol):
def __init__(self, atoms, protcomplex, cclass, altconf, min_dist, mapper):
"""Find all relevant parts which could take part in interactions"""
- Mol.__init__(self, altconf, mapper, mtype='protein', bsid=None)
+ Mol.__init__(self, altconf, mapper, mtype="protein", bsid=None)
self.complex = cclass
self.full_mol = protcomplex
self.all_atoms = atoms
self.min_dist = min_dist # Minimum distance of bs res to ligand
- self.bs_res = list(set([''.join([str(whichresnumber(a)), whichchain(a)]) for a in self.all_atoms])) # e.g. 47A
+ self.bs_res = list(
+ set(
+ [
+ "".join([str(whichresnumber(a)), whichchain(a)])
+ for a in self.all_atoms
+ ]
+ )
+ ) # e.g. 47A
self.rings = self.find_rings(self.full_mol, self.all_atoms)
self.hydroph_atoms = self.hydrophobic_atoms(self.all_atoms)
self.hbond_acc_atoms = self.find_hba(self.all_atoms)
@@ -887,118 +1252,228 @@ class BindingSite(Mol):
def find_hal(self, atoms):
"""Look for halogen bond acceptors (Y-{O|P|N|S}, with Y=C,P,S)"""
- data = namedtuple('hal_acceptor', 'o o_orig_idx y y_orig_idx')
+ data = namedtuple("hal_acceptor", "o o_orig_idx y y_orig_idx")
a_set = []
# All oxygens, nitrogen, sulfurs with neighboring carbon, phosphor, nitrogen or sulfur
for a in [at for at in atoms if at.atomicnum in [8, 7, 16]]:
- n_atoms = [na for na in pybel.ob.OBAtomAtomIter(a.OBAtom) if na.GetAtomicNum() in [6, 7, 15, 16]]
+ n_atoms = [
+ na
+ for na in pybel.ob.OBAtomAtomIter(a.OBAtom)
+ if na.GetAtomicNum() in [6, 7, 15, 16]
+ ]
if len(n_atoms) == 1: # Proximal atom
o_orig_idx = self.Mapper.mapid(a.idx, mtype=self.mtype, bsid=self.bsid)
- y_orig_idx = self.Mapper.mapid(n_atoms[0].GetIdx(), mtype=self.mtype, bsid=self.bsid)
- a_set.append(data(o=a, o_orig_idx=o_orig_idx, y=pybel.Atom(n_atoms[0]), y_orig_idx=y_orig_idx))
+ y_orig_idx = self.Mapper.mapid(
+ n_atoms[0].GetIdx(), mtype=self.mtype, bsid=self.bsid
+ )
+ a_set.append(
+ data(
+ o=a,
+ o_orig_idx=o_orig_idx,
+ y=pybel.Atom(n_atoms[0]),
+ y_orig_idx=y_orig_idx,
+ )
+ )
return a_set
def find_charged(self, mol):
"""Looks for positive charges in arginine, histidine or lysine, for negative in aspartic and glutamic acid."""
- data = namedtuple('pcharge', 'atoms atoms_orig_idx type center restype resnr reschain')
+ data = namedtuple(
+ "pcharge", "atoms atoms_orig_idx type center restype resnr reschain"
+ )
a_set = []
# Iterate through all residue, exclude those in chains defined as peptides
- for res in [r for r in pybel.ob.OBResidueIter(mol.OBMol) if not r.GetChain() in config.PEPTIDES]:
+ for res in [
+ r
+ for r in pybel.ob.OBResidueIter(mol.OBMol)
+ if not r.GetChain() in config.PEPTIDES
+ ]:
if config.INTRA is not None:
if res.GetChain() != config.INTRA:
continue
a_contributing = []
a_contributing_orig_idx = []
- if res.GetName() in ('ARG', 'HIS', 'LYS'): # Arginine, Histidine or Lysine have charged sidechains
+ if res.GetName() in (
+ "ARG",
+ "HIS",
+ "LYS",
+ ): # Arginine, Histidine or Lysine have charged sidechains
for a in pybel.ob.OBResidueAtomIter(res):
- if a.GetType().startswith('N') and res.GetAtomProperty(a, 8) \
- and not self.Mapper.mapid(a.GetIdx(), mtype='protein') in self.altconf:
+ if (
+ a.GetType().startswith("N")
+ and res.GetAtomProperty(a, 8)
+ and not self.Mapper.mapid(a.GetIdx(), mtype="protein")
+ in self.altconf
+ ):
a_contributing.append(pybel.Atom(a))
- a_contributing_orig_idx.append(self.Mapper.mapid(a.GetIdx(), mtype='protein'))
+ a_contributing_orig_idx.append(
+ self.Mapper.mapid(a.GetIdx(), mtype="protein")
+ )
if not len(a_contributing) == 0:
- a_set.append(data(atoms=a_contributing,
- atoms_orig_idx=a_contributing_orig_idx,
- type='positive',
- center=centroid([ac.coords for ac in a_contributing]),
- restype=res.GetName(),
- resnr=res.GetNum(),
- reschain=res.GetChain()))
- if res.GetName() in ('GLU', 'ASP'): # Aspartic or Glutamic Acid
+ a_set.append(
+ data(
+ atoms=a_contributing,
+ atoms_orig_idx=a_contributing_orig_idx,
+ type="positive",
+ center=centroid([ac.coords for ac in a_contributing]),
+ restype=res.GetName(),
+ resnr=res.GetNum(),
+ reschain=res.GetChain(),
+ )
+ )
+ if res.GetName() in ("GLU", "ASP"): # Aspartic or Glutamic Acid
for a in pybel.ob.OBResidueAtomIter(res):
- if a.GetType().startswith('O') and res.GetAtomProperty(a, 8) \
- and not self.Mapper.mapid(a.GetIdx(), mtype='protein') in self.altconf:
+ if (
+ a.GetType().startswith("O")
+ and res.GetAtomProperty(a, 8)
+ and not self.Mapper.mapid(a.GetIdx(), mtype="protein")
+ in self.altconf
+ ):
a_contributing.append(pybel.Atom(a))
- a_contributing_orig_idx.append(self.Mapper.mapid(a.GetIdx(), mtype='protein'))
+ a_contributing_orig_idx.append(
+ self.Mapper.mapid(a.GetIdx(), mtype="protein")
+ )
if not len(a_contributing) == 0:
- a_set.append(data(atoms=a_contributing,
- atoms_orig_idx=a_contributing_orig_idx,
- type='negative',
- center=centroid([ac.coords for ac in a_contributing]),
- restype=res.GetName(),
- resnr=res.GetNum(),
- reschain=res.GetChain()))
+ a_set.append(
+ data(
+ atoms=a_contributing,
+ atoms_orig_idx=a_contributing_orig_idx,
+ type="negative",
+ center=centroid([ac.coords for ac in a_contributing]),
+ restype=res.GetName(),
+ resnr=res.GetNum(),
+ reschain=res.GetChain(),
+ )
+ )
return a_set
def find_metal_binding(self, mol):
"""Looks for atoms that could possibly be involved in chelating a metal ion.
This can be any main chain oxygen atom or oxygen, nitrogen and sulfur from specific amino acids"""
- data = namedtuple('metal_binding', 'atom atom_orig_idx type restype resnr reschain location')
+ data = namedtuple(
+ "metal_binding", "atom atom_orig_idx type restype resnr reschain location"
+ )
a_set = []
for res in pybel.ob.OBResidueIter(mol.OBMol):
- restype, reschain, resnr = res.GetName().upper(), res.GetChain(), res.GetNum()
- if restype in ['ASP', 'GLU', 'SER', 'THR', 'TYR']: # Look for oxygens here
+ restype, reschain, resnr = (
+ res.GetName().upper(),
+ res.GetChain(),
+ res.GetNum(),
+ )
+ if restype in ["ASP", "GLU", "SER", "THR", "TYR"]: # Look for oxygens here
for a in pybel.ob.OBResidueAtomIter(res):
- if a.GetType().startswith('O') and res.GetAtomProperty(a, 8) \
- and not self.Mapper.mapid(a.GetIdx(), mtype='protein') in self.altconf:
- atom_orig_idx = self.Mapper.mapid(a.GetIdx(), mtype=self.mtype, bsid=self.bsid)
- a_set.append(data(atom=pybel.Atom(a), atom_orig_idx=atom_orig_idx, type='O', restype=restype,
- resnr=resnr, reschain=reschain,
- location='protein.sidechain'))
- if restype == 'HIS': # Look for nitrogen here
+ if (
+ a.GetType().startswith("O")
+ and res.GetAtomProperty(a, 8)
+ and not self.Mapper.mapid(a.GetIdx(), mtype="protein")
+ in self.altconf
+ ):
+ atom_orig_idx = self.Mapper.mapid(
+ a.GetIdx(), mtype=self.mtype, bsid=self.bsid
+ )
+ a_set.append(
+ data(
+ atom=pybel.Atom(a),
+ atom_orig_idx=atom_orig_idx,
+ type="O",
+ restype=restype,
+ resnr=resnr,
+ reschain=reschain,
+ location="protein.sidechain",
+ )
+ )
+ if restype == "HIS": # Look for nitrogen here
for a in pybel.ob.OBResidueAtomIter(res):
- if a.GetType().startswith('N') and res.GetAtomProperty(a, 8) \
- and not self.Mapper.mapid(a.GetIdx(), mtype='protein') in self.altconf:
- atom_orig_idx = self.Mapper.mapid(a.GetIdx(), mtype=self.mtype, bsid=self.bsid)
- a_set.append(data(atom=pybel.Atom(a), atom_orig_idx=atom_orig_idx, type='N', restype=restype,
- resnr=resnr, reschain=reschain,
- location='protein.sidechain'))
- if restype == 'CYS': # Look for sulfur here
+ if (
+ a.GetType().startswith("N")
+ and res.GetAtomProperty(a, 8)
+ and not self.Mapper.mapid(a.GetIdx(), mtype="protein")
+ in self.altconf
+ ):
+ atom_orig_idx = self.Mapper.mapid(
+ a.GetIdx(), mtype=self.mtype, bsid=self.bsid
+ )
+ a_set.append(
+ data(
+ atom=pybel.Atom(a),
+ atom_orig_idx=atom_orig_idx,
+ type="N",
+ restype=restype,
+ resnr=resnr,
+ reschain=reschain,
+ location="protein.sidechain",
+ )
+ )
+ if restype == "CYS": # Look for sulfur here
for a in pybel.ob.OBResidueAtomIter(res):
- if a.GetType().startswith('S') and res.GetAtomProperty(a, 8) \
- and not self.Mapper.mapid(a.GetIdx(), mtype='protein') in self.altconf:
- atom_orig_idx = self.Mapper.mapid(a.GetIdx(), mtype=self.mtype, bsid=self.bsid)
- a_set.append(data(atom=pybel.Atom(a), atom_orig_idx=atom_orig_idx, type='S', restype=restype,
- resnr=resnr, reschain=reschain,
- location='protein.sidechain'))
+ if (
+ a.GetType().startswith("S")
+ and res.GetAtomProperty(a, 8)
+ and not self.Mapper.mapid(a.GetIdx(), mtype="protein")
+ in self.altconf
+ ):
+ atom_orig_idx = self.Mapper.mapid(
+ a.GetIdx(), mtype=self.mtype, bsid=self.bsid
+ )
+ a_set.append(
+ data(
+ atom=pybel.Atom(a),
+ atom_orig_idx=atom_orig_idx,
+ type="S",
+ restype=restype,
+ resnr=resnr,
+ reschain=reschain,
+ location="protein.sidechain",
+ )
+ )
for a in pybel.ob.OBResidueAtomIter(res): # All main chain oxygens
- if a.GetType().startswith('O') and res.GetAtomProperty(a, 2) \
- and not self.Mapper.mapid(a.GetIdx(), mtype='protein') in self.altconf and restype != 'HOH':
- atom_orig_idx = self.Mapper.mapid(a.GetIdx(), mtype=self.mtype, bsid=self.bsid)
- a_set.append(data(atom=pybel.Atom(a), atom_orig_idx=atom_orig_idx, type='O', restype=res.GetName(),
- resnr=res.GetNum(), reschain=res.GetChain(),
- location='protein.mainchain'))
+ if (
+ a.GetType().startswith("O")
+ and res.GetAtomProperty(a, 2)
+ and not self.Mapper.mapid(a.GetIdx(), mtype="protein")
+ in self.altconf
+ and restype != "HOH"
+ ):
+ atom_orig_idx = self.Mapper.mapid(
+ a.GetIdx(), mtype=self.mtype, bsid=self.bsid
+ )
+ a_set.append(
+ data(
+ atom=pybel.Atom(a),
+ atom_orig_idx=atom_orig_idx,
+ type="O",
+ restype=res.GetName(),
+ resnr=res.GetNum(),
+ reschain=res.GetChain(),
+ location="protein.mainchain",
+ )
+ )
return a_set
class Ligand(Mol):
def __init__(self, cclass, ligand):
altconf = cclass.altconf
- self.hetid, self.chain, self.position = ligand.hetid, ligand.chain, ligand.position
- self.bsid = ':'.join([self.hetid, self.chain, str(self.position)])
- Mol.__init__(self, altconf, cclass.Mapper, mtype='ligand', bsid=self.bsid)
+ self.hetid, self.chain, self.position = (
+ ligand.hetid,
+ ligand.chain,
+ ligand.position,
+ )
+ self.bsid = ":".join([self.hetid, self.chain, str(self.position)])
+ Mol.__init__(self, altconf, cclass.Mapper, mtype="ligand", bsid=self.bsid)
self.members = ligand.members
self.longname = ligand.longname
self.type = ligand.type
self.complex = cclass
self.molecule = ligand.mol # Pybel Molecule
- self.smiles = self.molecule.write(format='can') # SMILES String
- self.inchikey = self.molecule.write(format='inchikey')
+ self.smiles = self.molecule.write(format="can") # SMILES String
+ self.inchikey = self.molecule.write(format="inchikey")
self.can_to_pdb = ligand.can_to_pdb
if not len(self.smiles) == 0:
self.smiles = self.smiles.split()[0]
else:
- logger.warning(f'could not write SMILES for ligand {ligand}')
- self.smiles = ''
+ logger.warning(f"could not write SMILES for ligand {ligand}")
+ self.smiles = ""
self.heavy_atoms = self.molecule.OBMol.NumHvyAtoms() # Heavy atoms count
self.all_atoms = self.molecule.atoms
self.atmdict = {l.idx: l for l in self.all_atoms}
@@ -1007,9 +1482,9 @@ class Ligand(Mol):
self.hbond_acc_atoms = self.find_hba(self.all_atoms)
self.num_rings = len(self.rings)
if self.num_rings != 0:
- logger.info(f'contains {self.num_rings} aromatic ring(s)')
+ logger.info(f"contains {self.num_rings} aromatic ring(s)")
descvalues = self.molecule.calcdesc()
- self.molweight, self.logp = float(descvalues['MW']), float(descvalues['logP'])
+ self.molweight, self.logp = float(descvalues["MW"]), float(descvalues["logP"])
self.num_rot_bonds = int(self.molecule.OBMol.NumRotors())
self.atomorder = ligand.atomorder
@@ -1017,48 +1492,73 @@ class Ligand(Mol):
# Special Case for hydrogen bond acceptor identification #
##########################################################
- self.inverse_mapping = {v: k for k, v in self.Mapper.ligandmaps[self.bsid].items()}
+ self.inverse_mapping = {
+ v: k for k, v in self.Mapper.ligandmaps[self.bsid].items()
+ }
self.pdb_to_idx_mapping = {v: k for k, v in self.Mapper.proteinmap.items()}
self.hbond_don_atom_pairs = self.find_hbd(self.all_atoms, self.hydroph_atoms)
######
donor_pairs = []
- data = namedtuple('hbonddonor', 'd d_orig_atom d_orig_idx h type')
+ data = namedtuple("hbonddonor", "d d_orig_atom d_orig_idx h type")
for donor in self.all_atoms:
- pdbidx = self.Mapper.mapid(donor.idx, mtype='ligand', bsid=self.bsid, to='original')
+ pdbidx = self.Mapper.mapid(
+ donor.idx, mtype="ligand", bsid=self.bsid, to="original"
+ )
d = cclass.atoms[self.pdb_to_idx_mapping[pdbidx]]
if d.OBAtom.IsHbondDonor():
- for adj_atom in [a for a in pybel.ob.OBAtomAtomIter(d.OBAtom) if a.IsHbondDonorH()]:
+ for adj_atom in [
+ a for a in pybel.ob.OBAtomAtomIter(d.OBAtom) if a.IsHbondDonorH()
+ ]:
d_orig_atom = self.Mapper.id_to_atom(pdbidx)
- donor_pairs.append(data(d=donor, d_orig_atom=d_orig_atom, d_orig_idx=pdbidx,
- h=pybel.Atom(adj_atom), type='regular'))
+ donor_pairs.append(
+ data(
+ d=donor,
+ d_orig_atom=d_orig_atom,
+ d_orig_idx=pdbidx,
+ h=pybel.Atom(adj_atom),
+ type="regular",
+ )
+ )
self.hbond_don_atom_pairs = donor_pairs
#######
self.charged = self.find_charged(self.all_atoms)
self.centroid = centroid([a.coords for a in self.all_atoms])
- self.max_dist_to_center = max((euclidean3d(self.centroid, a.coords) for a in self.all_atoms))
+ self.max_dist_to_center = max(
+ (euclidean3d(self.centroid, a.coords) for a in self.all_atoms)
+ )
self.water = []
- data = namedtuple('water', 'oxy oxy_orig_idx')
+ data = namedtuple("water", "oxy oxy_orig_idx")
for hoh in ligand.water:
oxy = None
for at in pybel.ob.OBResidueAtomIter(hoh):
if at.GetAtomicNum() == 8 and at.GetIdx() not in self.altconf:
oxy = pybel.Atom(at)
# There are some cases where there is no oxygen in a water residue, ignore those
- if not set([at.GetAtomicNum() for at in pybel.ob.OBResidueAtomIter(hoh)]) == {1} and oxy is not None:
- if euclidean3d(self.centroid, oxy.coords) < self.max_dist_to_center + config.BS_DIST:
- oxy_orig_idx = self.Mapper.mapid(oxy.idx, mtype='protein')
+ if (
+ not set([at.GetAtomicNum() for at in pybel.ob.OBResidueAtomIter(hoh)])
+ == {1}
+ and oxy is not None
+ ):
+ if (
+ euclidean3d(self.centroid, oxy.coords)
+ < self.max_dist_to_center + config.BS_DIST
+ ):
+ oxy_orig_idx = self.Mapper.mapid(oxy.idx, mtype="protein")
self.water.append(data(oxy=oxy, oxy_orig_idx=oxy_orig_idx))
self.halogenbond_don = self.find_hal(self.all_atoms)
self.metal_binding = self.find_metal_binding(self.all_atoms, self.water)
self.metals = []
- data = namedtuple('metal', 'm orig_m m_orig_idx')
+ data = namedtuple("metal", "m orig_m m_orig_idx")
for a in [a for a in self.all_atoms if a.type.upper() in config.METAL_IONS]:
m_orig_idx = self.Mapper.mapid(a.idx, mtype=self.mtype, bsid=self.bsid)
orig_m = self.Mapper.id_to_atom(m_orig_idx)
self.metals.append(data(m=a, m_orig_idx=m_orig_idx, orig_m=orig_m))
- self.num_hba, self.num_hbd = len(self.hbond_acc_atoms), len(self.hbond_don_atom_pairs)
+ self.num_hba, self.num_hbd = (
+ len(self.hbond_acc_atoms),
+ len(self.hbond_don_atom_pairs),
+ )
self.num_hal = len(self.halogenbond_don)
def get_canonical_num(self, atomnum):
@@ -1067,41 +1567,69 @@ class Ligand(Mol):
def is_functional_group(self, atom, group):
"""Given a pybel atom, look up if it belongs to a function group"""
- n_atoms = [a_neighbor.GetAtomicNum() for a_neighbor in pybel.ob.OBAtomAtomIter(atom.OBAtom)]
+ n_atoms = [
+ a_neighbor.GetAtomicNum()
+ for a_neighbor in pybel.ob.OBAtomAtomIter(atom.OBAtom)
+ ]
- if group in ['quartamine', 'tertamine'] and atom.atomicnum == 7: # Nitrogen
+ if group in ["quartamine", "tertamine"] and atom.atomicnum == 7: # Nitrogen
# It's a nitrogen, so could be a protonated amine or quaternary ammonium
- if '1' not in n_atoms and len(n_atoms) == 4:
- return True if group == 'quartamine' else False # It's a quat. ammonium (N with 4 residues != H)
+ if "1" not in n_atoms and len(n_atoms) == 4:
+ return (
+ True if group == "quartamine" else False
+ ) # It's a quat. ammonium (N with 4 residues != H)
elif atom.OBAtom.GetHyb() == 3 and len(n_atoms) >= 3:
- return True if group == 'tertamine' else False # It's sp3-hybridized, so could pick up an hydrogen
+ return (
+ True if group == "tertamine" else False
+ ) # It's sp3-hybridized, so could pick up an hydrogen
else:
return False
- if group in ['sulfonium', 'sulfonicacid', 'sulfate'] and atom.atomicnum == 16: # Sulfur
- if '1' not in n_atoms and len(n_atoms) == 3: # It's a sulfonium (S with 3 residues != H)
- return True if group == 'sulfonium' else False
+ if (
+ group in ["sulfonium", "sulfonicacid", "sulfate"] and atom.atomicnum == 16
+ ): # Sulfur
+ if (
+ "1" not in n_atoms and len(n_atoms) == 3
+ ): # It's a sulfonium (S with 3 residues != H)
+ return True if group == "sulfonium" else False
elif n_atoms.count(8) == 3: # It's a sulfonate or sulfonic acid
- return True if group == 'sulfonicacid' else False
+ return True if group == "sulfonicacid" else False
elif n_atoms.count(8) == 4: # It's a sulfate
- return True if group == 'sulfate' else False
+ return True if group == "sulfate" else False
- if group == 'phosphate' and atom.atomicnum == 15: # Phosphor
+ if group == "phosphate" and atom.atomicnum == 15: # Phosphor
if set(n_atoms) == {8}: # It's a phosphate
return True
- if group in ['carboxylate', 'guanidine'] and atom.atomicnum == 6: # It's a carbon atom
- if n_atoms.count(8) == 2 and n_atoms.count(6) == 1: # It's a carboxylate group
- return True if group == 'carboxylate' else False
+ if (
+ group in ["carboxylate", "guanidine"] and atom.atomicnum == 6
+ ): # It's a carbon atom
+ if (
+ n_atoms.count(8) == 2 and n_atoms.count(6) == 1
+ ): # It's a carboxylate group
+ return True if group == "carboxylate" else False
elif n_atoms.count(7) == 3 and len(n_atoms) == 3: # It's a guanidine group
nitro_partners = []
for nitro in pybel.ob.OBAtomAtomIter(atom.OBAtom):
- nitro_partners.append(len([b_neighbor for b_neighbor in pybel.ob.OBAtomAtomIter(nitro)]))
- if min(nitro_partners) == 1: # One nitrogen is only connected to the carbon, can pick up a H
- return True if group == 'guanidine' else False
-
- if group == 'halocarbon' and atom.atomicnum in [9, 17, 35, 53]: # Halogen atoms
- n_atoms = [na for na in pybel.ob.OBAtomAtomIter(atom.OBAtom) if na.GetAtomicNum() == 6]
+ nitro_partners.append(
+ len(
+ [
+ b_neighbor
+ for b_neighbor in pybel.ob.OBAtomAtomIter(nitro)
+ ]
+ )
+ )
+ if (
+ min(nitro_partners) == 1
+ ): # One nitrogen is only connected to the carbon, can pick up a H
+ return True if group == "guanidine" else False
+
+ if group == "halocarbon" and atom.atomicnum in [9, 17, 35, 53]: # Halogen atoms
+ n_atoms = [
+ na
+ for na in pybel.ob.OBAtomAtomIter(atom.OBAtom)
+ if na.GetAtomicNum() == 6
+ ]
if len(n_atoms) == 1: # Halocarbon
return True
else:
@@ -1109,18 +1637,32 @@ class Ligand(Mol):
def find_hal(self, atoms):
"""Look for halogen bond donors (X-C, with X=F, Cl, Br, I)"""
- data = namedtuple('hal_donor', 'x orig_x x_orig_idx c c_orig_idx')
+ data = namedtuple("hal_donor", "x orig_x x_orig_idx c c_orig_idx")
a_set = []
for a in atoms:
- if self.is_functional_group(a, 'halocarbon'):
- n_atoms = [na for na in pybel.ob.OBAtomAtomIter(a.OBAtom) if na.GetAtomicNum() == 6]
+ if self.is_functional_group(a, "halocarbon"):
+ n_atoms = [
+ na
+ for na in pybel.ob.OBAtomAtomIter(a.OBAtom)
+ if na.GetAtomicNum() == 6
+ ]
x_orig_idx = self.Mapper.mapid(a.idx, mtype=self.mtype, bsid=self.bsid)
orig_x = self.Mapper.id_to_atom(x_orig_idx)
- c_orig_idx = [self.Mapper.mapid(na.GetIdx(), mtype=self.mtype, bsid=self.bsid) for na in n_atoms]
- a_set.append(data(x=a, orig_x=orig_x, x_orig_idx=x_orig_idx,
- c=pybel.Atom(n_atoms[0]), c_orig_idx=c_orig_idx))
+ c_orig_idx = [
+ self.Mapper.mapid(na.GetIdx(), mtype=self.mtype, bsid=self.bsid)
+ for na in n_atoms
+ ]
+ a_set.append(
+ data(
+ x=a,
+ orig_x=orig_x,
+ x_orig_idx=x_orig_idx,
+ c=pybel.Atom(n_atoms[0]),
+ c_orig_idx=c_orig_idx,
+ )
+ )
if len(a_set) != 0:
- logger.info(f'ligand contains {len(a_set)} halogen atom(s)')
+ logger.info(f"ligand contains {len(a_set)} halogen atom(s)")
return a_set
def find_charged(self, all_atoms):
@@ -1129,76 +1671,189 @@ class Ligand(Mol):
as mentioned in 'Cation-pi interactions in ligand recognition and catalysis' (Zacharias et al., 2002)).
Identify negatively charged groups in the ligand.
"""
- data = namedtuple('lcharge', 'atoms orig_atoms atoms_orig_idx type center fgroup')
+ data = namedtuple(
+ "lcharge", "atoms orig_atoms atoms_orig_idx type center fgroup"
+ )
a_set = []
for a in all_atoms:
a_orig_idx = self.Mapper.mapid(a.idx, mtype=self.mtype, bsid=self.bsid)
a_orig = self.Mapper.id_to_atom(a_orig_idx)
- if self.is_functional_group(a, 'quartamine'):
- a_set.append(data(atoms=[a, ], orig_atoms=[a_orig, ], atoms_orig_idx=[a_orig_idx, ], type='positive',
- center=list(a.coords), fgroup='quartamine'))
- elif self.is_functional_group(a, 'tertamine'):
- a_set.append(data(atoms=[a, ], orig_atoms=[a_orig, ], atoms_orig_idx=[a_orig_idx, ], type='positive',
- center=list(a.coords),
- fgroup='tertamine'))
- if self.is_functional_group(a, 'sulfonium'):
- a_set.append(data(atoms=[a, ], orig_atoms=[a_orig, ], atoms_orig_idx=[a_orig_idx, ], type='positive',
- center=list(a.coords),
- fgroup='sulfonium'))
- if self.is_functional_group(a, 'phosphate'):
- a_contributing = [a, ]
- a_contributing_orig_idx = [a_orig_idx, ]
- [a_contributing.append(pybel.Atom(neighbor)) for neighbor in pybel.ob.OBAtomAtomIter(a.OBAtom)]
- [a_contributing_orig_idx.append(self.Mapper.mapid(neighbor.idx, mtype=self.mtype, bsid=self.bsid))
- for neighbor in a_contributing]
- orig_contributing = [self.Mapper.id_to_atom(idx) for idx in a_contributing_orig_idx]
+ if self.is_functional_group(a, "quartamine"):
+ a_set.append(
+ data(
+ atoms=[a,],
+ orig_atoms=[a_orig,],
+ atoms_orig_idx=[a_orig_idx,],
+ type="positive",
+ center=list(a.coords),
+ fgroup="quartamine",
+ )
+ )
+ elif self.is_functional_group(a, "tertamine"):
a_set.append(
- data(atoms=a_contributing, orig_atoms=orig_contributing, atoms_orig_idx=a_contributing_orig_idx,
- type='negative',
- center=a.coords, fgroup='phosphate'))
- if self.is_functional_group(a, 'sulfonicacid'):
- a_contributing = [a, ]
- a_contributing_orig_idx = [a_orig_idx, ]
- [a_contributing.append(pybel.Atom(neighbor)) for neighbor in pybel.ob.OBAtomAtomIter(a.OBAtom) if
- neighbor.GetAtomicNum() == 8]
- [a_contributing_orig_idx.append(self.Mapper.mapid(neighbor.idx, mtype=self.mtype, bsid=self.bsid))
- for neighbor in a_contributing]
- orig_contributing = [self.Mapper.id_to_atom(idx) for idx in a_contributing_orig_idx]
+ data(
+ atoms=[a,],
+ orig_atoms=[a_orig,],
+ atoms_orig_idx=[a_orig_idx,],
+ type="positive",
+ center=list(a.coords),
+ fgroup="tertamine",
+ )
+ )
+ if self.is_functional_group(a, "sulfonium"):
a_set.append(
- data(atoms=a_contributing, orig_atoms=orig_contributing, atoms_orig_idx=a_contributing_orig_idx,
- type='negative',
- center=a.coords, fgroup='sulfonicacid'))
- elif self.is_functional_group(a, 'sulfate'):
- a_contributing = [a, ]
- a_contributing_orig_idx = [a_orig_idx, ]
- [a_contributing_orig_idx.append(self.Mapper.mapid(neighbor.idx, mtype=self.mtype, bsid=self.bsid))
- for neighbor in a_contributing]
- [a_contributing.append(pybel.Atom(neighbor)) for neighbor in pybel.ob.OBAtomAtomIter(a.OBAtom)]
- orig_contributing = [self.Mapper.id_to_atom(idx) for idx in a_contributing_orig_idx]
+ data(
+ atoms=[a,],
+ orig_atoms=[a_orig,],
+ atoms_orig_idx=[a_orig_idx,],
+ type="positive",
+ center=list(a.coords),
+ fgroup="sulfonium",
+ )
+ )
+ if self.is_functional_group(a, "phosphate"):
+ a_contributing = [
+ a,
+ ]
+ a_contributing_orig_idx = [
+ a_orig_idx,
+ ]
+ [
+ a_contributing.append(pybel.Atom(neighbor))
+ for neighbor in pybel.ob.OBAtomAtomIter(a.OBAtom)
+ ]
+ [
+ a_contributing_orig_idx.append(
+ self.Mapper.mapid(
+ neighbor.idx, mtype=self.mtype, bsid=self.bsid
+ )
+ )
+ for neighbor in a_contributing
+ ]
+ orig_contributing = [
+ self.Mapper.id_to_atom(idx) for idx in a_contributing_orig_idx
+ ]
a_set.append(
- data(atoms=a_contributing, orig_atoms=orig_contributing, atoms_orig_idx=a_contributing_orig_idx,
- type='negative',
- center=a.coords, fgroup='sulfate'))
- if self.is_functional_group(a, 'carboxylate'):
- a_contributing = [pybel.Atom(neighbor) for neighbor in pybel.ob.OBAtomAtomIter(a.OBAtom)
- if neighbor.GetAtomicNum() == 8]
- a_contributing_orig_idx = [self.Mapper.mapid(neighbor.idx, mtype=self.mtype, bsid=self.bsid)
- for neighbor in a_contributing]
- orig_contributing = [self.Mapper.id_to_atom(idx) for idx in a_contributing_orig_idx]
+ data(
+ atoms=a_contributing,
+ orig_atoms=orig_contributing,
+ atoms_orig_idx=a_contributing_orig_idx,
+ type="negative",
+ center=a.coords,
+ fgroup="phosphate",
+ )
+ )
+ if self.is_functional_group(a, "sulfonicacid"):
+ a_contributing = [
+ a,
+ ]
+ a_contributing_orig_idx = [
+ a_orig_idx,
+ ]
+ [
+ a_contributing.append(pybel.Atom(neighbor))
+ for neighbor in pybel.ob.OBAtomAtomIter(a.OBAtom)
+ if neighbor.GetAtomicNum() == 8
+ ]
+ [
+ a_contributing_orig_idx.append(
+ self.Mapper.mapid(
+ neighbor.idx, mtype=self.mtype, bsid=self.bsid
+ )
+ )
+ for neighbor in a_contributing
+ ]
+ orig_contributing = [
+ self.Mapper.id_to_atom(idx) for idx in a_contributing_orig_idx
+ ]
a_set.append(
- data(atoms=a_contributing, orig_atoms=orig_contributing, atoms_orig_idx=a_contributing_orig_idx,
- type='negative',
- center=centroid([a.coords for a in a_contributing]), fgroup='carboxylate'))
- elif self.is_functional_group(a, 'guanidine'):
- a_contributing = [pybel.Atom(neighbor) for neighbor in pybel.ob.OBAtomAtomIter(a.OBAtom)
- if neighbor.GetAtomicNum() == 7]
- a_contributing_orig_idx = [self.Mapper.mapid(neighbor.idx, mtype=self.mtype, bsid=self.bsid)
- for neighbor in a_contributing]
- orig_contributing = [self.Mapper.id_to_atom(idx) for idx in a_contributing_orig_idx]
+ data(
+ atoms=a_contributing,
+ orig_atoms=orig_contributing,
+ atoms_orig_idx=a_contributing_orig_idx,
+ type="negative",
+ center=a.coords,
+ fgroup="sulfonicacid",
+ )
+ )
+ elif self.is_functional_group(a, "sulfate"):
+ a_contributing = [
+ a,
+ ]
+ a_contributing_orig_idx = [
+ a_orig_idx,
+ ]
+ [
+ a_contributing_orig_idx.append(
+ self.Mapper.mapid(
+ neighbor.idx, mtype=self.mtype, bsid=self.bsid
+ )
+ )
+ for neighbor in a_contributing
+ ]
+ [
+ a_contributing.append(pybel.Atom(neighbor))
+ for neighbor in pybel.ob.OBAtomAtomIter(a.OBAtom)
+ ]
+ orig_contributing = [
+ self.Mapper.id_to_atom(idx) for idx in a_contributing_orig_idx
+ ]
a_set.append(
- data(atoms=a_contributing, orig_atoms=orig_contributing, atoms_orig_idx=a_contributing_orig_idx,
- type='positive',
- center=a.coords, fgroup='guanidine'))
+ data(
+ atoms=a_contributing,
+ orig_atoms=orig_contributing,
+ atoms_orig_idx=a_contributing_orig_idx,
+ type="negative",
+ center=a.coords,
+ fgroup="sulfate",
+ )
+ )
+ if self.is_functional_group(a, "carboxylate"):
+ a_contributing = [
+ pybel.Atom(neighbor)
+ for neighbor in pybel.ob.OBAtomAtomIter(a.OBAtom)
+ if neighbor.GetAtomicNum() == 8
+ ]
+ a_contributing_orig_idx = [
+ self.Mapper.mapid(neighbor.idx, mtype=self.mtype, bsid=self.bsid)
+ for neighbor in a_contributing
+ ]
+ orig_contributing = [
+ self.Mapper.id_to_atom(idx) for idx in a_contributing_orig_idx
+ ]
+ a_set.append(
+ data(
+ atoms=a_contributing,
+ orig_atoms=orig_contributing,
+ atoms_orig_idx=a_contributing_orig_idx,
+ type="negative",
+ center=centroid([a.coords for a in a_contributing]),
+ fgroup="carboxylate",
+ )
+ )
+ elif self.is_functional_group(a, "guanidine"):
+ a_contributing = [
+ pybel.Atom(neighbor)
+ for neighbor in pybel.ob.OBAtomAtomIter(a.OBAtom)
+ if neighbor.GetAtomicNum() == 7
+ ]
+ a_contributing_orig_idx = [
+ self.Mapper.mapid(neighbor.idx, mtype=self.mtype, bsid=self.bsid)
+ for neighbor in a_contributing
+ ]
+ orig_contributing = [
+ self.Mapper.id_to_atom(idx) for idx in a_contributing_orig_idx
+ ]
+ a_set.append(
+ data(
+ atoms=a_contributing,
+ orig_atoms=orig_contributing,
+ atoms_orig_idx=a_contributing_orig_idx,
+ type="positive",
+ center=a.coords,
+ fgroup="guanidine",
+ )
+ )
return a_set
def find_metal_binding(self, lig_atoms, water_oxygens):
@@ -1207,67 +1862,173 @@ class Ligand(Mol):
nitrogen from imidazole; sulfur from thiolate.
"""
a_set = []
- data = namedtuple('metal_binding', 'atom orig_atom atom_orig_idx type fgroup restype resnr reschain location')
+ data = namedtuple(
+ "metal_binding",
+ "atom orig_atom atom_orig_idx type fgroup restype resnr reschain location",
+ )
for oxygen in water_oxygens:
- a_set.append(data(atom=oxygen.oxy, atom_orig_idx=oxygen.oxy_orig_idx, type='O', fgroup='water',
- restype=whichrestype(oxygen.oxy), resnr=whichresnumber(oxygen.oxy),
- reschain=whichchain(oxygen.oxy), location='water',
- orig_atom=self.Mapper.id_to_atom(oxygen.oxy_orig_idx)))
+ a_set.append(
+ data(
+ atom=oxygen.oxy,
+ atom_orig_idx=oxygen.oxy_orig_idx,
+ type="O",
+ fgroup="water",
+ restype=whichrestype(oxygen.oxy),
+ resnr=whichresnumber(oxygen.oxy),
+ reschain=whichchain(oxygen.oxy),
+ location="water",
+ orig_atom=self.Mapper.id_to_atom(oxygen.oxy_orig_idx),
+ )
+ )
# #@todo Refactor code
for a in lig_atoms:
- a_orig_idx = self.Mapper.mapid(a.idx, mtype='ligand', bsid=self.bsid)
+ a_orig_idx = self.Mapper.mapid(a.idx, mtype="ligand", bsid=self.bsid)
n_atoms = pybel.ob.OBAtomAtomIter(a.OBAtom) # Neighboring atoms
# All atomic numbers of neighboring atoms
- n_atoms_atomicnum = [n.GetAtomicNum() for n in pybel.ob.OBAtomAtomIter(a.OBAtom)]
+ n_atoms_atomicnum = [
+ n.GetAtomicNum() for n in pybel.ob.OBAtomAtomIter(a.OBAtom)
+ ]
if a.atomicnum == 8: # Oxygen
- if n_atoms_atomicnum.count('1') == 1 and len(n_atoms_atomicnum) == 2: # Oxygen in alcohol (R-[O]-H)
- a_set.append(data(atom=a, atom_orig_idx=a_orig_idx, type='O', fgroup='alcohol',
- restype=self.hetid, resnr=self.position, reschain=self.chain,
- location='ligand', orig_atom=self.Mapper.id_to_atom(a_orig_idx)))
- if True in [n.IsAromatic() for n in n_atoms] and not a.OBAtom.IsAromatic(): # Phenolate oxygen
- a_set.append(data(atom=a, atom_orig_idx=a_orig_idx, type='O', fgroup='phenolate',
- restype=self.hetid, resnr=self.position, reschain=self.chain,
- location='ligand', orig_atom=self.Mapper.id_to_atom(a_orig_idx)))
+ if (
+ n_atoms_atomicnum.count("1") == 1 and len(n_atoms_atomicnum) == 2
+ ): # Oxygen in alcohol (R-[O]-H)
+ a_set.append(
+ data(
+ atom=a,
+ atom_orig_idx=a_orig_idx,
+ type="O",
+ fgroup="alcohol",
+ restype=self.hetid,
+ resnr=self.position,
+ reschain=self.chain,
+ location="ligand",
+ orig_atom=self.Mapper.id_to_atom(a_orig_idx),
+ )
+ )
+ if (
+ True in [n.IsAromatic() for n in n_atoms]
+ and not a.OBAtom.IsAromatic()
+ ): # Phenolate oxygen
+ a_set.append(
+ data(
+ atom=a,
+ atom_orig_idx=a_orig_idx,
+ type="O",
+ fgroup="phenolate",
+ restype=self.hetid,
+ resnr=self.position,
+ reschain=self.chain,
+ location="ligand",
+ orig_atom=self.Mapper.id_to_atom(a_orig_idx),
+ )
+ )
if a.atomicnum == 6: # It's a carbon atom
- if n_atoms_atomicnum.count(8) == 2 and n_atoms_atomicnum.count(6) == 1: # It's a carboxylate group
+ if (
+ n_atoms_atomicnum.count(8) == 2 and n_atoms_atomicnum.count(6) == 1
+ ): # It's a carboxylate group
for neighbor in [n for n in n_atoms if n.GetAtomicNum() == 8]:
- neighbor_orig_idx = self.Mapper.mapid(neighbor.GetIdx(), mtype='ligand', bsid=self.bsid)
- a_set.append(data(atom=pybel.Atom(neighbor), atom_orig_idx=neighbor_orig_idx, type='O',
- fgroup='carboxylate',
- restype=self.hetid,
- resnr=self.position, reschain=self.chain,
- location='ligand', orig_atom=self.Mapper.id_to_atom(a_orig_idx)))
+ neighbor_orig_idx = self.Mapper.mapid(
+ neighbor.GetIdx(), mtype="ligand", bsid=self.bsid
+ )
+ a_set.append(
+ data(
+ atom=pybel.Atom(neighbor),
+ atom_orig_idx=neighbor_orig_idx,
+ type="O",
+ fgroup="carboxylate",
+ restype=self.hetid,
+ resnr=self.position,
+ reschain=self.chain,
+ location="ligand",
+ orig_atom=self.Mapper.id_to_atom(a_orig_idx),
+ )
+ )
if a.atomicnum == 15: # It's a phosphor atom
if n_atoms_atomicnum.count(8) >= 3: # It's a phosphoryl
for neighbor in [n for n in n_atoms if n.GetAtomicNum() == 8]:
- neighbor_orig_idx = self.Mapper.mapid(neighbor.GetIdx(), mtype='ligand', bsid=self.bsid)
- a_set.append(data(atom=pybel.Atom(neighbor), atom_orig_idx=neighbor_orig_idx, type='O',
- fgroup='phosphoryl',
- restype=self.hetid,
- resnr=self.position, reschain=self.chain,
- location='ligand', orig_atom=self.Mapper.id_to_atom(a_orig_idx)))
- if n_atoms_atomicnum.count(8) == 2: # It's another phosphor-containing group #@todo (correct name?)
+ neighbor_orig_idx = self.Mapper.mapid(
+ neighbor.GetIdx(), mtype="ligand", bsid=self.bsid
+ )
+ a_set.append(
+ data(
+ atom=pybel.Atom(neighbor),
+ atom_orig_idx=neighbor_orig_idx,
+ type="O",
+ fgroup="phosphoryl",
+ restype=self.hetid,
+ resnr=self.position,
+ reschain=self.chain,
+ location="ligand",
+ orig_atom=self.Mapper.id_to_atom(a_orig_idx),
+ )
+ )
+ if (
+ n_atoms_atomicnum.count(8) == 2
+ ): # It's another phosphor-containing group #@todo (correct name?)
for neighbor in [n for n in n_atoms if n.GetAtomicNum() == 8]:
- neighbor_orig_idx = self.Mapper.mapid(neighbor.GetIdx(), mtype='ligand', bsid=self.bsid)
- a_set.append(data(atom=pybel.Atom(neighbor), atom_orig_idx=neighbor_orig_idx, type='O',
- fgroup='phosphor.other', restype=self.hetid,
- resnr=self.position,
- reschain=self.chain, location='ligand',
- orig_atom=self.Mapper.id_to_atom(a_orig_idx)))
+ neighbor_orig_idx = self.Mapper.mapid(
+ neighbor.GetIdx(), mtype="ligand", bsid=self.bsid
+ )
+ a_set.append(
+ data(
+ atom=pybel.Atom(neighbor),
+ atom_orig_idx=neighbor_orig_idx,
+ type="O",
+ fgroup="phosphor.other",
+ restype=self.hetid,
+ resnr=self.position,
+ reschain=self.chain,
+ location="ligand",
+ orig_atom=self.Mapper.id_to_atom(a_orig_idx),
+ )
+ )
if a.atomicnum == 7: # It's a nitrogen atom
if n_atoms_atomicnum.count(6) == 2: # It's imidazole/pyrrole or similar
- a_set.append(data(atom=a, atom_orig_idx=a_orig_idx, type='N', fgroup='imidazole/pyrrole',
- restype=self.hetid, resnr=self.position, reschain=self.chain,
- location='ligand', orig_atom=self.Mapper.id_to_atom(a_orig_idx)))
+ a_set.append(
+ data(
+ atom=a,
+ atom_orig_idx=a_orig_idx,
+ type="N",
+ fgroup="imidazole/pyrrole",
+ restype=self.hetid,
+ resnr=self.position,
+ reschain=self.chain,
+ location="ligand",
+ orig_atom=self.Mapper.id_to_atom(a_orig_idx),
+ )
+ )
if a.atomicnum == 16: # It's a sulfur atom
- if True in [n.IsAromatic() for n in n_atoms] and not a.OBAtom.IsAromatic(): # Thiolate
- a_set.append(data(atom=a, atom_orig_idx=a_orig_idx, type='S', fgroup='thiolate',
- restype=self.hetid, resnr=self.position, reschain=self.chain,
- location='ligand', orig_atom=self.Mapper.id_to_atom(a_orig_idx)))
+ if (
+ True in [n.IsAromatic() for n in n_atoms]
+ and not a.OBAtom.IsAromatic()
+ ): # Thiolate
+ a_set.append(
+ data(
+ atom=a,
+ atom_orig_idx=a_orig_idx,
+ type="S",
+ fgroup="thiolate",
+ restype=self.hetid,
+ resnr=self.position,
+ reschain=self.chain,
+ location="ligand",
+ orig_atom=self.Mapper.id_to_atom(a_orig_idx),
+ )
+ )
if set(n_atoms_atomicnum) == {26}: # Sulfur in Iron sulfur cluster
- a_set.append(data(atom=a, atom_orig_idx=a_orig_idx, type='S', fgroup='iron-sulfur.cluster',
- restype=self.hetid, resnr=self.position, reschain=self.chain,
- location='ligand', orig_atom=self.Mapper.id_to_atom(a_orig_idx)))
+ a_set.append(
+ data(
+ atom=a,
+ atom_orig_idx=a_orig_idx,
+ type="S",
+ fgroup="iron-sulfur.cluster",
+ restype=self.hetid,
+ resnr=self.position,
+ reschain=self.chain,
+ location="ligand",
+ orig_atom=self.Mapper.id_to_atom(a_orig_idx),
+ )
+ )
return a_set
@@ -1279,43 +2040,54 @@ class PDBComplex:
"""
def __init__(self):
- self.interaction_sets = {} # Dictionary with site identifiers as keys and object as value
+ self.interaction_sets = (
+ {}
+ ) # Dictionary with site identifiers as keys and object as value
self.protcomplex = None
self.filetype = None
self.atoms = {} # Dictionary of Pybel atoms, accessible by their idx
self.sourcefiles = {}
self.information = {}
- self.corrected_pdb = ''
+ self.corrected_pdb = ""
self._output_path = tempfile.gettempdir()
self.pymol_name = None
self.modres = set()
self.resis = []
self.altconf = [] # Atom idx of atoms with alternate conformations
- self.covalent = [] # Covalent linkages between ligands and protein residues/other ligands
+ self.covalent = (
+ []
+ ) # Covalent linkages between ligands and protein residues/other ligands
self.excluded = [] # Excluded ligands
self.Mapper = Mapper()
self.ligands = []
def __str__(self):
- formatted_lig_names = [":".join([x.hetid, x.chain, str(x.position)]) for x in self.ligands]
+ formatted_lig_names = [
+ ":".join([x.hetid, x.chain, str(x.position)]) for x in self.ligands
+ ]
return "Protein structure %s with ligands:\n" % (self.pymol_name) + "\n".join(
- [lig for lig in formatted_lig_names])
+ [lig for lig in formatted_lig_names]
+ )
def load_pdb(self, pdbpath, as_string=False):
"""Loads a pdb file with protein AND ligand(s), separates and prepares them.
If specified 'as_string', the input is a PDB string instead of a path."""
if as_string:
- self.sourcefiles['pdbcomplex.original'] = None
- self.sourcefiles['pdbcomplex'] = None
- self.sourcefiles['pdbstring'] = pdbpath
+ self.sourcefiles["pdbcomplex.original"] = None
+ self.sourcefiles["pdbcomplex"] = None
+ self.sourcefiles["pdbstring"] = pdbpath
else:
- self.sourcefiles['pdbcomplex.original'] = pdbpath
- self.sourcefiles['pdbcomplex'] = pdbpath
- self.information['pdbfixes'] = False
- pdbparser = PDBParser(pdbpath, as_string=as_string) # Parse PDB file to find errors and get additional data
+ self.sourcefiles["pdbcomplex.original"] = pdbpath
+ self.sourcefiles["pdbcomplex"] = pdbpath
+ self.information["pdbfixes"] = False
+ pdbparser = PDBParser(
+ pdbpath, as_string=as_string
+ ) # Parse PDB file to find errors and get additional data
# #@todo Refactor and rename here
self.Mapper.proteinmap = pdbparser.proteinmap
- self.Mapper.reversed_proteinmap = {v: k for k, v in self.Mapper.proteinmap.items()}
+ self.Mapper.reversed_proteinmap = {
+ v: k for k, v in self.Mapper.proteinmap.items()
+ }
self.modres = pdbparser.modres
self.covalent = pdbparser.covalent
self.altconf = pdbparser.altconformations
@@ -1323,78 +2095,103 @@ class PDBComplex:
if not config.PLUGIN_MODE:
if pdbparser.num_fixed_lines > 0:
- logger.info(f'{pdbparser.num_fixed_lines} lines automatically fixed in PDB input file')
+ logger.info(
+ f"{pdbparser.num_fixed_lines} lines automatically fixed in PDB input file"
+ )
# Save modified PDB file
if not as_string:
- basename = os.path.basename(pdbpath).split('.')[0]
+ basename = os.path.basename(pdbpath).split(".")[0]
else:
basename = "from_stdin"
- pdbpath_fixed = tmpfile(prefix='plipfixed.' + basename + '_', direc=self.output_path)
+ pdbpath_fixed = tmpfile(
+ prefix="plipfixed." + basename + "_", direc=self.output_path
+ )
create_folder_if_not_exists(self.output_path)
- self.sourcefiles['pdbcomplex'] = pdbpath_fixed
- self.corrected_pdb = re.sub(r'[^\x00-\x7F]+', ' ', self.corrected_pdb) # Strip non-unicode chars
- if not config.NOFIXFILE: # Only write to file if this option is not activated
- with open(pdbpath_fixed, 'w') as f:
+ self.sourcefiles["pdbcomplex"] = pdbpath_fixed
+ self.corrected_pdb = re.sub(
+ r"[^\x00-\x7F]+", " ", self.corrected_pdb
+ ) # Strip non-unicode chars
+ if (
+ not config.NOFIXFILE
+ ): # Only write to file if this option is not activated
+ with open(pdbpath_fixed, "w") as f:
f.write(self.corrected_pdb)
- self.information['pdbfixes'] = True
+ self.information["pdbfixes"] = True
if not as_string:
- self.sourcefiles['filename'] = os.path.basename(self.sourcefiles['pdbcomplex'])
+ self.sourcefiles["filename"] = os.path.basename(
+ self.sourcefiles["pdbcomplex"]
+ )
self.protcomplex, self.filetype = read_pdb(self.corrected_pdb, as_string=True)
# Update the model in the Mapper class instance
self.Mapper.original_structure = self.protcomplex.OBMol
- logger.info('PDB structure successfully read')
+ logger.info("PDB structure successfully read")
# Determine (temporary) PyMOL Name from Filename
- self.pymol_name = pdbpath.split('/')[-1].split('.')[0] + '-Protein'
+ self.pymol_name = pdbpath.split("/")[-1].split(".")[0] + "-Protein"
# Replace characters causing problems in PyMOL
- self.pymol_name = self.pymol_name.replace(' ', '').replace('(', '').replace(')', '').replace('-', '_')
+ self.pymol_name = (
+ self.pymol_name.replace(" ", "")
+ .replace("(", "")
+ .replace(")", "")
+ .replace("-", "_")
+ )
# But if possible, name it after PDBID in Header
- if 'HEADER' in self.protcomplex.data: # If the PDB file has a proper header
- potential_name = self.protcomplex.data['HEADER'][56:60].lower()
- if extract_pdbid(potential_name) != 'UnknownProtein':
+ if "HEADER" in self.protcomplex.data: # If the PDB file has a proper header
+ potential_name = self.protcomplex.data["HEADER"][56:60].lower()
+ if extract_pdbid(potential_name) != "UnknownProtein":
self.pymol_name = potential_name
- logger.debug(f'PyMOL name set as: {self.pymol_name}')
+ logger.debug(f"PyMOL name set as: {self.pymol_name}")
# Extract and prepare ligands
- ligandfinder = LigandFinder(self.protcomplex, self.altconf, self.modres, self.covalent, self.Mapper)
+ ligandfinder = LigandFinder(
+ self.protcomplex, self.altconf, self.modres, self.covalent, self.Mapper
+ )
self.ligands = ligandfinder.ligands
self.excluded = ligandfinder.excluded
# decide whether to add polar hydrogens
if not config.NOHYDRO:
if not as_string:
- basename = os.path.basename(pdbpath).split('.')[0]
+ basename = os.path.basename(pdbpath).split(".")[0]
else:
basename = "from_stdin"
self.protcomplex.OBMol.AddPolarHydrogens()
- output_path = os.path.join(self._output_path, f'{basename}_protonated.pdb')
- self.protcomplex.write('pdb', output_path, overwrite=True)
- logger.info(f'protonated structure written to {output_path}')
+ output_path = os.path.join(self._output_path, f"{basename}_protonated.pdb")
+ self.protcomplex.write("pdb", output_path, overwrite=True)
+ logger.info(f"protonated structure written to {output_path}")
else:
- logger.warning('no polar hydrogens will be assigned (make sure your structure contains hydrogens)')
+ logger.warning(
+ "no polar hydrogens will be assigned (make sure your structure contains hydrogens)"
+ )
for atm in self.protcomplex:
self.atoms[atm.idx] = atm
if len(self.excluded) != 0:
- logger.info(f'excluded molecules as ligands: {self.excluded}')
+ logger.info(f"excluded molecules as ligands: {self.excluded}")
if config.DNARECEPTOR:
- self.resis = [obres for obres in pybel.ob.OBResidueIter(
- self.protcomplex.OBMol) if obres.GetName() in config.DNA + config.RNA]
+ self.resis = [
+ obres
+ for obres in pybel.ob.OBResidueIter(self.protcomplex.OBMol)
+ if obres.GetName() in config.DNA + config.RNA
+ ]
else:
- self.resis = [obres for obres in pybel.ob.OBResidueIter(
- self.protcomplex.OBMol) if obres.GetResidueProperty(0)]
+ self.resis = [
+ obres
+ for obres in pybel.ob.OBResidueIter(self.protcomplex.OBMol)
+ if obres.GetResidueProperty(0)
+ ]
num_ligs = len(self.ligands)
if num_ligs == 1:
- logger.info('analyzing one ligand')
+ logger.info("analyzing one ligand")
elif num_ligs > 1:
- logger.info(f'analyzing {num_ligs} ligands')
+ logger.info(f"analyzing {num_ligs} ligands")
else:
- logger.info(f'structure contains no ligands')
+ logger.info(f"structure contains no ligands")
def analyze(self):
"""Triggers analysis of all complexes in structure"""
@@ -1406,42 +2203,66 @@ class PDBComplex:
single_sites = []
for member in ligand.members:
- single_sites.append(':'.join([str(x) for x in member]))
- site = ' + '.join(single_sites)
- site = site if not len(site) > 20 else site[:20] + '...'
- longname = ligand.longname if not len(ligand.longname) > 20 else ligand.longname[:20] + '...'
- ligtype = 'unspecified type' if ligand.type == 'UNSPECIFIED' else ligand.type
- ligtext = f'{longname} [{ligtype}] -- {site}'
- logger.info(f'processing ligand {ligtext}')
- if ligtype == 'PEPTIDE':
- logger.info(f'chain {ligand.chain} will be processed in [PEPTIDE / INTER-CHAIN] mode')
- if ligtype == 'INTRA':
- logger.info(f'chain {ligand.chain} will be processed in [INTRA-CHAIN] mode')
- any_in_biolip = len(set([x[0] for x in ligand.members]).intersection(config.biolip_list)) != 0
-
- if ligtype not in ['POLYMER', 'DNA', 'ION', 'DNA+ION', 'RNA+ION', 'SMALLMOLECULE+ION'] and any_in_biolip:
- logger.info('may be biologically irrelevant')
+ single_sites.append(":".join([str(x) for x in member]))
+ site = " + ".join(single_sites)
+ site = site if not len(site) > 20 else site[:20] + "..."
+ longname = (
+ ligand.longname
+ if not len(ligand.longname) > 20
+ else ligand.longname[:20] + "..."
+ )
+ ligtype = "unspecified type" if ligand.type == "UNSPECIFIED" else ligand.type
+ ligtext = f"{longname} [{ligtype}] -- {site}"
+ logger.info(f"processing ligand {ligtext}")
+ if ligtype == "PEPTIDE":
+ logger.info(
+ f"chain {ligand.chain} will be processed in [PEPTIDE / INTER-CHAIN] mode"
+ )
+ if ligtype == "INTRA":
+ logger.info(f"chain {ligand.chain} will be processed in [INTRA-CHAIN] mode")
+ any_in_biolip = (
+ len(set([x[0] for x in ligand.members]).intersection(config.biolip_list))
+ != 0
+ )
+
+ if (
+ ligtype
+ not in ["POLYMER", "DNA", "ION", "DNA+ION", "RNA+ION", "SMALLMOLECULE+ION"]
+ and any_in_biolip
+ ):
+ logger.info("may be biologically irrelevant")
lig_obj = Ligand(self, ligand)
cutoff = lig_obj.max_dist_to_center + config.BS_DIST
bs_res = self.extract_bs(cutoff, lig_obj.centroid, self.resis)
# Get a list of all atoms belonging to the binding site, search by idx
- bs_atoms = [self.atoms[idx] for idx in [i for i in self.atoms.keys()
- if self.atoms[i].OBAtom.GetResidue().GetIdx() in bs_res]
- if idx in self.Mapper.proteinmap and self.Mapper.mapid(idx, mtype='protein') not in self.altconf]
- if ligand.type == 'PEPTIDE':
+ bs_atoms = [
+ self.atoms[idx]
+ for idx in [
+ i
+ for i in self.atoms.keys()
+ if self.atoms[i].OBAtom.GetResidue().GetIdx() in bs_res
+ ]
+ if idx in self.Mapper.proteinmap
+ and self.Mapper.mapid(idx, mtype="protein") not in self.altconf
+ ]
+ if ligand.type == "PEPTIDE":
# If peptide, don't consider the peptide chain as part of the protein binding site
- bs_atoms = [a for a in bs_atoms if a.OBAtom.GetResidue().GetChain() != lig_obj.chain]
- if ligand.type == 'INTRA':
+ bs_atoms = [
+ a for a in bs_atoms if a.OBAtom.GetResidue().GetChain() != lig_obj.chain
+ ]
+ if ligand.type == "INTRA":
# Interactions within the chain
- bs_atoms = [a for a in bs_atoms if a.OBAtom.GetResidue().GetChain() == lig_obj.chain]
+ bs_atoms = [
+ a for a in bs_atoms if a.OBAtom.GetResidue().GetChain() == lig_obj.chain
+ ]
bs_atoms_refined = []
# Create hash with BSRES -> (MINDIST_TO_LIG, AA_TYPE)
# and refine binding site atom selection with exact threshold
min_dist = {}
for r in bs_atoms:
- bs_res_id = ''.join([str(whichresnumber(r)), whichchain(r)])
+ bs_res_id = "".join([str(whichresnumber(r)), whichchain(r)])
for l in ligand.mol.atoms:
distance = euclidean3d(r.coords, l.coords)
if bs_res_id not in min_dist:
@@ -1451,25 +2272,40 @@ class PDBComplex:
if distance <= config.BS_DIST and r not in bs_atoms_refined:
bs_atoms_refined.append(r)
num_bs_atoms = len(bs_atoms_refined)
- logger.info(f'binding site atoms in vicinity ({config.BS_DIST} A max. dist: {num_bs_atoms})')
-
- bs_obj = BindingSite(bs_atoms_refined, self.protcomplex, self, self.altconf, min_dist, self.Mapper)
+ logger.info(
+ f"binding site atoms in vicinity ({config.BS_DIST} A max. dist: {num_bs_atoms})"
+ )
+
+ bs_obj = BindingSite(
+ bs_atoms_refined,
+ self.protcomplex,
+ self,
+ self.altconf,
+ min_dist,
+ self.Mapper,
+ )
pli_obj = PLInteraction(lig_obj, bs_obj, self)
self.interaction_sets[ligand.mol.title] = pli_obj
def extract_bs(self, cutoff, ligcentroid, resis):
"""Return list of ids from residues belonging to the binding site"""
- return [obres.GetIdx() for obres in resis if self.res_belongs_to_bs(obres, cutoff, ligcentroid)]
+ return [
+ obres.GetIdx()
+ for obres in resis
+ if self.res_belongs_to_bs(obres, cutoff, ligcentroid)
+ ]
def res_belongs_to_bs(self, res, cutoff, ligcentroid):
"""Check for each residue if its centroid is within a certain distance to the ligand centroid.
Additionally checks if a residue belongs to a chain restricted by the user (e.g. by defining a peptide chain)"""
- rescentroid = centroid([(atm.x(), atm.y(), atm.z()) for atm in pybel.ob.OBResidueAtomIter(res)])
+ rescentroid = centroid(
+ [(atm.x(), atm.y(), atm.z()) for atm in pybel.ob.OBResidueAtomIter(res)]
+ )
# Check geometry
near_enough = True if euclidean3d(rescentroid, ligcentroid) < cutoff else False
# Check chain membership
restricted_chain = True if res.GetChain() in config.PEPTIDES else False
- return (near_enough and not restricted_chain)
+ return near_enough and not restricted_chain
def get_atom(self, idx):
return self.atoms[idx]
diff --git a/plip/test/test_basic_functions.py b/plip/test/test_basic_functions.py
index 7134f55..ac6a012 100644
--- a/plip/test/test_basic_functions.py
+++ b/plip/test/test_basic_functions.py
@@ -21,13 +21,17 @@ class TestLigandSupport(unittest.TestCase):
def test_dna_rna(self):
"""Test if DNA and RNA is correctly processed as ligands"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1tf6.pdb')
+ tmpmol.load_pdb("./pdb/1tf6.pdb")
# DNA ligand four times consisting of 31 parts (composite)
- self.assertEqual([len(ligand.members) for ligand in tmpmol.ligands].count(31), 4)
- for ligset in [set((x[0] for x in ligand.members)) for ligand in tmpmol.ligands]:
+ self.assertEqual(
+ [len(ligand.members) for ligand in tmpmol.ligands].count(31), 4
+ )
+ for ligset in [
+ set((x[0] for x in ligand.members)) for ligand in tmpmol.ligands
+ ]:
if len(ligset) == 4:
# DNA only contains four bases
- self.assertEqual(ligset, {'DG', 'DC', 'DA', 'DT'})
+ self.assertEqual(ligset, {"DG", "DC", "DA", "DT"})
class TestMapping(unittest.TestCase):
@@ -36,34 +40,34 @@ class TestMapping(unittest.TestCase):
def test_ids(self):
"""Test if the atom IDs are correctly mapped from internal to original PDB."""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1vsn.pdb')
- bsid = 'NFT:A:283'
+ tmpmol.load_pdb("./pdb/1vsn.pdb")
+ bsid = "NFT:A:283"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
for contact in s.hydrophobic_contacts:
- if contact.restype == 'ALA' and contact.resnr == 133:
+ if contact.restype == "ALA" and contact.resnr == 133:
self.assertEqual(contact.ligatom_orig_idx, 1636)
self.assertEqual(contact.bsatom_orig_idx, 994)
- if contact.restype == 'ASP' and contact.resnr == 61:
+ if contact.restype == "ASP" and contact.resnr == 61:
self.assertEqual(contact.ligatom_orig_idx, 1639)
self.assertEqual(contact.bsatom_orig_idx, 448)
for contact in s.hbonds_ldon + s.hbonds_pdon:
- if contact.restype == 'GLN' and contact.resnr == 19:
+ if contact.restype == "GLN" and contact.resnr == 19:
self.assertEqual(contact.a_orig_idx, 1649)
self.assertEqual(contact.d_orig_idx, 153)
- if contact.restype == 'CYS' and contact.resnr == 25:
+ if contact.restype == "CYS" and contact.resnr == 25:
self.assertEqual(contact.a_orig_idx, 1649)
self.assertEqual(contact.d_orig_idx, 183)
- if contact.restype == 'ASN' and contact.resnr == 158:
+ if contact.restype == "ASN" and contact.resnr == 158:
self.assertEqual(contact.d_orig_idx, 1629)
self.assertEqual(contact.a_orig_idx, 1199)
for contact in s.halogen_bonds:
- if contact.restype == 'TYR' and contact.resnr == 67:
+ if contact.restype == "TYR" and contact.resnr == 67:
self.assertEqual(contact.don.x_orig_idx, 1627)
self.assertEqual(contact.acc.o_orig_idx, 485)
- if contact.restype == 'LEU' and contact.resnr == 157:
+ if contact.restype == "LEU" and contact.resnr == 157:
self.assertEqual(contact.don.x_orig_idx, 1628)
self.assertEqual(contact.acc.o_orig_idx, 1191)
@@ -72,7 +76,7 @@ class GeometryTest(unittest.TestCase):
"""Tests for geometrical calculations in PLIP"""
def vector_magnitude(self, v):
- return numpy.sqrt(sum(x**2 for x in v))
+ return numpy.sqrt(sum(x ** 2 for x in v))
# noinspection PyUnusedLocal
def setUp(self):
@@ -132,4 +136,7 @@ class GeometryTest(unittest.TestCase):
def test_cluster_doubles(self):
"""Tests for mathematics.cluster_doubles"""
# Are the results correct?
- self.assertEqual(set(cluster_doubles([(1, 3), (4, 1), (5, 6), (7, 5)])), {(1, 3, 4), (5, 6, 7)})
+ self.assertEqual(
+ set(cluster_doubles([(1, 3), (4, 1), (5, 6), (7, 5)])),
+ {(1, 3, 4), (5, 6, 7)},
+ )
diff --git a/plip/test/test_command_line.py b/plip/test/test_command_line.py
index 5d8e8e5..3e27943 100644
--- a/plip/test/test_command_line.py
+++ b/plip/test/test_command_line.py
@@ -20,29 +20,39 @@ class CommandLineTest(unittest.TestCase):
def test_empty_input_file(self):
"""Input file is empty."""
- exitcode = subprocess.call(f'{sys.executable} ../plipcmd.py -f ./special/empty.pdb -o {self.tmp_dir.name}',
- shell=True)
+ exitcode = subprocess.call(
+ f"{sys.executable} ../plipcmd.py -f ./special/empty.pdb -o {self.tmp_dir.name}",
+ shell=True,
+ )
self.assertEqual(exitcode, 1)
def test_invalid_pdb_id(self):
"""A PDB ID with no valid PDB record is provided."""
- exitcode = subprocess.call(f'{sys.executable} ../plipcmd.py -i xx1x -o {self.tmp_dir.name}', shell=True)
+ exitcode = subprocess.call(
+ f"{sys.executable} ../plipcmd.py -i xx1x -o {self.tmp_dir.name}", shell=True
+ )
self.assertEqual(exitcode, 1)
def test_invalid_input_file(self):
"""A file is provided which is not a PDB file."""
- exitcode = subprocess.call(f'{sys.executable} ../plipcmd.py -f ./special/non-pdb.pdb -o {self.tmp_dir.name}',
- shell=True)
+ exitcode = subprocess.call(
+ f"{sys.executable} ../plipcmd.py -f ./special/non-pdb.pdb -o {self.tmp_dir.name}",
+ shell=True,
+ )
self.assertEqual(exitcode, 1)
def test_pdb_format_not_available(self):
"""A valid PDB ID is provided, but there is no entry in PDB format from wwPDB"""
- exitcode = subprocess.call(f'{sys.executable} ../plipcmd.py -i 4v59 -o {self.tmp_dir.name}', shell=True)
+ exitcode = subprocess.call(
+ f"{sys.executable} ../plipcmd.py -i 4v59 -o {self.tmp_dir.name}", shell=True
+ )
self.assertEqual(exitcode, 1)
def test_valid_pdb(self):
"""A PDB ID with no valid PDB record is provided."""
- exitcode = subprocess.call(f'{sys.executable} ../plipcmd.py -x -f ./pdb/1eve.pdb -o {self.tmp_dir.name}',
- shell=True)
+ exitcode = subprocess.call(
+ f"{sys.executable} ../plipcmd.py -x -f ./pdb/1eve.pdb -o {self.tmp_dir.name}",
+ shell=True,
+ )
self.assertEqual(len(os.listdir(self.tmp_dir.name)), 2)
self.assertEqual(exitcode, 0)
diff --git a/plip/test/test_hydrogen_bonds.py b/plip/test/test_hydrogen_bonds.py
index 9d68532..f673c6e 100644
--- a/plip/test/test_hydrogen_bonds.py
+++ b/plip/test/test_hydrogen_bonds.py
@@ -8,31 +8,35 @@ def characterize_complex(pdb_file: str, binding_site_id: str) -> PLInteraction:
pdb_complex = PDBComplex()
pdb_complex.load_pdb(pdb_file)
for ligand in pdb_complex.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == binding_site_id:
+ if (
+ ":".join([ligand.hetid, ligand.chain, str(ligand.position)])
+ == binding_site_id
+ ):
pdb_complex.characterize_complex(ligand)
return pdb_complex.interaction_sets[binding_site_id]
class HydrogenBondTestCase(unittest.TestCase):
-
def test_4dst_nondeterministic_protonation(self):
config.NOHYDRO = False
for i in range(0, 10):
- interactions = characterize_complex('./pdb/4dst.pdb', 'GCP:A:202')
+ interactions = characterize_complex("./pdb/4dst.pdb", "GCP:A:202")
all_hbonds = interactions.hbonds_ldon + interactions.hbonds_pdon
self.assertTrue(len(all_hbonds) == 16 or len(all_hbonds) == 17)
def test_4dst_deterministic_protonation(self):
config.NOHYDRO = True
for i in range(0, 10):
- interactions = characterize_complex('./pdb/4dst_protonated.pdb', 'GCP:A:202')
+ interactions = characterize_complex(
+ "./pdb/4dst_protonated.pdb", "GCP:A:202"
+ )
all_hbonds = interactions.hbonds_ldon + interactions.hbonds_pdon
self.assertTrue(len(all_hbonds) == 16)
def test_no_protonation(self):
config.NOHYDRO = True
- interactions1 = characterize_complex('./pdb/1x0n_state_1.pdb', 'DTF:A:174')
+ interactions1 = characterize_complex("./pdb/1x0n_state_1.pdb", "DTF:A:174")
self.assertEqual(len(interactions1.hbonds_ldon), 0)
config.NOHYDRO = False
- interactions2 = characterize_complex('./pdb/1x0n_state_1.pdb', 'DTF:A:174')
+ interactions2 = characterize_complex("./pdb/1x0n_state_1.pdb", "DTF:A:174")
self.assertEqual(len(interactions2.hbonds_ldon), 1)
diff --git a/plip/test/test_literature_validated.py b/plip/test/test_literature_validated.py
index f3f7cbc..d49dba5 100644
--- a/plip/test/test_literature_validated.py
+++ b/plip/test/test_literature_validated.py
@@ -21,10 +21,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: Chakrabarti et al. Geometry of nonbonded interactions involving planar groups in proteins. (2007)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1eve.pdb')
- bsid = 'E20:A:2001'
+ tmpmol.load_pdb("./pdb/1eve.pdb")
+ bsid = "E20:A:2001"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Aromatic stacking with Trp84 and Trp279
@@ -39,10 +39,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: Chakrabarti et al. Geometry of nonbonded interactions involving planar groups in proteins. (2007)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1h2t.pdb')
- bsid = 'GDP:Z:1151'
+ tmpmol.load_pdb("./pdb/1h2t.pdb")
+ bsid = "GDP:Z:1151"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Sandwiched pi-stacking involving Tyr20 and Tyr43
@@ -60,10 +60,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: Betzi et al. Discovery of a potential allosteric ligand binding site in CDK2 (2012)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/3pxf.pdb')
- bsids = ['2AN:A:305', '2AN:A:304']
+ tmpmol.load_pdb("./pdb/3pxf.pdb")
+ bsids = ["2AN:A:305", "2AN:A:304"]
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) in bsids:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) in bsids:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsids[0]] # 2AN:A:305
@@ -91,10 +91,10 @@ class LiteratureValidatedTest(unittest.TestCase):
from Sinorhizobium meliloti in the liganded and unliganded-closed states. (2008)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/2reg.pdb')
- bsid = 'CHT:A:1'
+ tmpmol.load_pdb("./pdb/2reg.pdb")
+ bsid = "CHT:A:1"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Cation-pi interactions with Trp43, Trp90, Trp205, and Tyr119
@@ -109,10 +109,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: Bird et al. Crystal structures of Varicella Zoster Virus Thyrimidine Kinase. (2003)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1osn.pdb')
- bsid = 'BVP:A:500'
+ tmpmol.load_pdb("./pdb/1osn.pdb")
+ bsid = "BVP:A:500"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Sandwiched pi-stacking involving Phe93 and Phe139
@@ -128,10 +128,10 @@ class LiteratureValidatedTest(unittest.TestCase):
has implications for antiviral therapy (2008)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/2w0s.pdb')
- bsid = 'BVP:B:1207' # Complex of BVDU with Magnesium Cofactor
+ tmpmol.load_pdb("./pdb/2w0s.pdb")
+ bsid = "BVP:B:1207" # Complex of BVDU with Magnesium Cofactor
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonding of Tyr101 and Arg72
@@ -152,10 +152,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: Li et al. Identification of a potent and selective non-basic cathepsin K inhibitor. (2006)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1vsn.pdb')
- bsid = 'NFT:A:283'
+ tmpmol.load_pdb("./pdb/1vsn.pdb")
+ bsid = "NFT:A:283"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonding to Gly66
@@ -167,10 +167,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: De Moliner et al. Alternative binding modes of an inhibitor to two different kinases. (2003)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1p5e.pdb')
- bsid = 'TBS:A:301'
+ tmpmol.load_pdb("./pdb/1p5e.pdb")
+ bsid = "TBS:A:301"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Halogen Bonding of Ile10 and Leu83
@@ -183,10 +183,10 @@ class LiteratureValidatedTest(unittest.TestCase):
acetylcholinesterase.. (1993)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1acj.pdb')
- bsid = 'THA:A:999'
+ tmpmol.load_pdb("./pdb/1acj.pdb")
+ bsid = "THA:A:999"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# pi-stacking interaction with Phe330 and Trp84
@@ -199,10 +199,10 @@ class LiteratureValidatedTest(unittest.TestCase):
glutamicum CgmR in Complex with Inducers and with an Operator. (2010)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/2zoz.pdb')
- bsid = 'ET:B:184'
+ tmpmol.load_pdb("./pdb/2zoz.pdb")
+ bsid = "ET:B:184"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# pi-stacking interaction with Trp63 and Phe147
@@ -219,10 +219,10 @@ class LiteratureValidatedTest(unittest.TestCase):
RNA editing ligase 1. (2004)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1xdn.pdb')
- bsid = 'ATP:A:501'
+ tmpmol.load_pdb("./pdb/1xdn.pdb")
+ bsid = "ATP:A:501"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Arg111, Ile61 (backbone), Asn92, Val88, Lys87 and Glu86#
@@ -241,10 +241,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: Peisach et al. Interaction of a Peptidomimetic Aminimide Inhibitor with Elastase. (1995)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1bma.pdb')
- bsid = '0QH:A:256'
+ tmpmol.load_pdb("./pdb/1bma.pdb")
+ bsid = "0QH:A:256"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to val224 and Gln200
@@ -265,14 +265,16 @@ class LiteratureValidatedTest(unittest.TestCase):
and Their Prodrugs As Antimalarial Agents (2004)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/4rao.pdb')
- bsid = '3L7:B:301'
+ tmpmol.load_pdb("./pdb/4rao.pdb")
+ bsid = "3L7:B:301"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Val187, Lys165, Thr141, Lys140, Gly139, Thr138, Asp137
- hbonds = {hbond.resnr for hbond in s.hbonds_pdon} # res nr 100, 68, 69 and 199 in alternative conformation,
+ hbonds = {
+ hbond.resnr for hbond in s.hbonds_pdon
+ } # res nr 100, 68, 69 and 199 in alternative conformation,
self.assertTrue({137, 138, 139, 140, 141, 165, 187}.issubset(hbonds))
# Water bridges to Asp137, Thr141, Met142, Arg199 and Gly139
# res nr 199 and 142 in alternative conformation
@@ -286,10 +288,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: Bhattacharya et al. Structural basis of HIV-1 capsid recognition by PF74 and CPSF6(2014)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/4qnb.pdb')
- bsid = '1B0:A:301'
+ tmpmol.load_pdb("./pdb/4qnb.pdb")
+ bsid = "1B0:A:301"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Asn57 and Lys70
@@ -304,10 +306,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: Zaware et al. Structural basis of HIV-1 capsid recognition by PF74 and CPSF6(2014)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/4kya.pdb')
- bsid = '1UG:E:702'
+ tmpmol.load_pdb("./pdb/4kya.pdb")
+ bsid = "1UG:E:702"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Ala609
@@ -329,10 +331,10 @@ class LiteratureValidatedTest(unittest.TestCase):
implications for ligand binding and specificity(2002)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1n7g.pdb')
- bsid = 'NDP:A:701'
+ tmpmol.load_pdb("./pdb/1n7g.pdb")
+ bsid = "NDP:A:701"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Thr37, Gly38, Gln39, Asp40, Arg60, Leu92, Asp91, Ser63, Leu92, Ala115, Ser117,
@@ -340,7 +342,9 @@ class LiteratureValidatedTest(unittest.TestCase):
# Publication give the Prediction for Asp91 as hydrogen bond, when this contains two acceptor atoms.
hbonds = {hbond.resnr for hbond in s.hbonds_pdon}
# #@todo Hbond to 128 not detected
- self.assertTrue({37, 38, 39, 40, 92, 63, 92, 115, 117, 185, 189, 215, 220}.issubset(hbonds))
+ self.assertTrue(
+ {37, 38, 39, 40, 92, 63, 92, 115, 117, 185, 189, 215, 220}.issubset(hbonds)
+ )
# Water bridges to Gly35, Thr37, Gly38, Asp40, Arg60, Arg61, Ser63, Asn66, Ser117, Tyr128, Lys189, Arg220
waterbridges = {wb.resnr for wb in s.water_bridges}
# Hydrogen bonds to 35, 37, 38, 40, 63, 117, 128, 189, 220 not detected due to prioritization
@@ -358,10 +362,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: Tsuhako et al. The design, synthesis, and biological evaluation of PIM kinase inhibitors.(2012)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/4alw.pdb')
- bsid = 'HY7:A:1308'
+ tmpmol.load_pdb("./pdb/4alw.pdb")
+ bsid = "HY7:A:1308"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Asp186
@@ -377,10 +381,10 @@ class LiteratureValidatedTest(unittest.TestCase):
for TMAO.(2013)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/3o1h.pdb')
- bsid = 'TMO:B:1'
+ tmpmol.load_pdb("./pdb/3o1h.pdb")
+ bsid = "TMO:B:1"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Trp45
@@ -396,10 +400,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: Shikha et al. Mechanism of mismatch recognition revealed by human MutSβ bound to unpaired DNA loops.(2012)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/3thy.pdb')
- bsid = 'ADP:A:935'
+ tmpmol.load_pdb("./pdb/3thy.pdb")
+ bsid = "ADP:A:935"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Saltbridge to His295 and Lys675
@@ -414,10 +418,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: Ash et al. The structure of an N11A mutant of the G-protein domain of FeoB.(2011)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/3tah.pdb')
- bsid = 'BGO:A:300'
+ tmpmol.load_pdb("./pdb/3tah.pdb")
+ bsid = "BGO:A:300"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Ala11, Lys14, Thr15, Ser16, Asp113, Met114, Ala143 and Asp113
@@ -434,10 +438,10 @@ class LiteratureValidatedTest(unittest.TestCase):
kinase CK2 inhibitors in clinical trials for the treatment of cancer (2011).
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/3r0t.pdb')
- bsid = 'FU9:A:338'
+ tmpmol.load_pdb("./pdb/3r0t.pdb")
+ bsid = "FU9:A:338"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Val116
@@ -462,10 +466,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Redox Potentials of DesulfoVibrio Vulgaris Flavodoxin.(2002)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1aku.pdb')
- bsid = 'FMN:A:150'
+ tmpmol.load_pdb("./pdb/1aku.pdb")
+ bsid = "FMN:A:150"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Thr59
@@ -488,10 +492,10 @@ class LiteratureValidatedTest(unittest.TestCase):
673, a potent inhibitor derived from dihydropyridophthalazinone.(2014)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/4pjt.pdb')
- bsid = '2YQ:D:1104'
+ tmpmol.load_pdb("./pdb/4pjt.pdb")
+ bsid = "2YQ:D:1104"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Gly863
@@ -506,15 +510,15 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: Presnell et al. Oxyanion-Mediated Inhibition of Serine Proteases.(1998)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1bju.pdb')
- bsid = 'GP6:A:910'
+ tmpmol.load_pdb("./pdb/1bju.pdb")
+ bsid = "GP6:A:910"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
- #@todo Publication show hydrogen bond interactions for Gly219
+ # @todo Publication show hydrogen bond interactions for Gly219
# Hydrogen bonds to Ser190, Ser195, Gly219 and Asp189
- hbonds = {hbond.resnr for hbond in s.hbonds_pdon+s.hbonds_ldon}
+ hbonds = {hbond.resnr for hbond in s.hbonds_pdon + s.hbonds_ldon}
self.assertTrue({189, 190, 195}.issubset(hbonds))
# Water bridges to Ser190 and Val227
# Water bridge to 190 not detected due to prioritization
@@ -532,10 +536,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Reference: Wilcken et al. Halogen-Enriched Fragment Libraries as Leads for Drug Rescue of Mutant p53.(2012)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/4agl.pdb')
- bsid = 'P84:A:400'
+ tmpmol.load_pdb("./pdb/4agl.pdb")
+ bsid = "P84:A:400"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Water bridges to Val147
@@ -554,10 +558,10 @@ class LiteratureValidatedTest(unittest.TestCase):
Pathway.(2007)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/2efj.pdb')
- bsid = '37T:A:502'
+ tmpmol.load_pdb("./pdb/2efj.pdb")
+ bsid = "37T:A:502"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bond to Ser237
@@ -573,10 +577,10 @@ class LiteratureValidatedTest(unittest.TestCase):
inhibitor.(2006)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/2iuz.pdb')
- bsid = 'D1H:A:1440'
+ tmpmol.load_pdb("./pdb/2iuz.pdb")
+ bsid = "D1H:A:1440"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Trp137
@@ -597,10 +601,10 @@ class LiteratureValidatedTest(unittest.TestCase):
phosphodiesterase type 5 (PDE5) inhibitors.(2011)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/3shy.pdb')
- bsid = '5FO:A:1'
+ tmpmol.load_pdb("./pdb/3shy.pdb")
+ bsid = "5FO:A:1"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Gln817
@@ -622,10 +626,10 @@ class LiteratureValidatedTest(unittest.TestCase):
substrate recognition site constructed by rearrangement of hydrogen bond network..(1998)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1ay8.pdb')
- bsid = 'PLP:A:413'
+ tmpmol.load_pdb("./pdb/1ay8.pdb")
+ bsid = "PLP:A:413"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds to Gly108, Thr109, Asn194 and Ser257
@@ -644,10 +648,10 @@ class LiteratureValidatedTest(unittest.TestCase):
evolutionary path selected by the Lewis epitope..(2014)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/4rdl.pdb')
- bsid = 'FUC:A:601'
+ tmpmol.load_pdb("./pdb/4rdl.pdb")
+ bsid = "FUC:A:601"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid] # Instead of FUC-A-604 (sugar representative)
# Water bridges to Asn395
@@ -670,18 +674,22 @@ class LiteratureValidatedTest(unittest.TestCase):
with CGP 53820, a novel pseudosymmetric inhibitor (1995)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1hii.pdb')
- bsid = 'C20:B:101'
+ tmpmol.load_pdb("./pdb/1hii.pdb")
+ bsid = "C20:B:101"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Water bridges
- waterbridges = {str(wb.resnr)+wb.reschain for wb in s.water_bridges}
- self.assertTrue({'50A', '50B'}.issubset(waterbridges)) # Bridging Ile-B50 and Ile-A50 with ligand
+ waterbridges = {str(wb.resnr) + wb.reschain for wb in s.water_bridges}
+ self.assertTrue(
+ {"50A", "50B"}.issubset(waterbridges)
+ ) # Bridging Ile-B50 and Ile-A50 with ligand
# Hydrogen bonds
- hbonds = {str(hbond.resnr)+hbond.reschain for hbond in s.hbonds_pdon+s.hbonds_ldon}
- self.assertTrue({'27A', '27B', '29A', '48A', '48B'}.issubset(hbonds))
+ hbonds = {
+ str(hbond.resnr) + hbond.reschain for hbond in s.hbonds_pdon + s.hbonds_ldon
+ }
+ self.assertTrue({"27A", "27B", "29A", "48A", "48B"}.issubset(hbonds))
# #@todo Publication mentions additional possible hydrogen bond with Asp28B
# Hydrogen bonds with Asp-A25 are reported as a salt bridge as both partners have (potential) charges
@@ -691,22 +699,28 @@ class LiteratureValidatedTest(unittest.TestCase):
Diol Inhibitors of HIV-1 Protease (1994)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1hvi.pdb')
- bsid = 'A77:A:800'
+ tmpmol.load_pdb("./pdb/1hvi.pdb")
+ bsid = "A77:A:800"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Water bridges
- waterbridges = {str(wb.resnr)+wb.reschain for wb in s.water_bridges}
+ waterbridges = {str(wb.resnr) + wb.reschain for wb in s.water_bridges}
# #@todo Water bridge with 50B not detected
- self.assertTrue({'50A'}.issubset(waterbridges)) # Bridging Ile-B50 and Ile-A50 with ligand
+ self.assertTrue(
+ {"50A"}.issubset(waterbridges)
+ ) # Bridging Ile-B50 and Ile-A50 with ligand
# pi-cation Interactions
picat = {pication.resnr for pication in s.pication_laro}
- self.assertEqual({8}, picat) # Described as weakly polar contact/stacking in paper
+ self.assertEqual(
+ {8}, picat
+ ) # Described as weakly polar contact/stacking in paper
# Hydrogen bonds
- hbonds = {str(hbond.resnr)+hbond.reschain for hbond in s.hbonds_pdon+s.hbonds_ldon}
- self.assertTrue({'25B', '27A', '27B', '48A', '48B'}.issubset(hbonds))
+ hbonds = {
+ str(hbond.resnr) + hbond.reschain for hbond in s.hbonds_pdon + s.hbonds_ldon
+ }
+ self.assertTrue({"25B", "27A", "27B", "48A", "48B"}.issubset(hbonds))
# #@todo Paper describes additional hydrogen bond with Asp25A
def test_3o7g(self):
@@ -715,16 +729,18 @@ class LiteratureValidatedTest(unittest.TestCase):
melanoma (2010)
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/3og7.pdb')
- bsid = '032:A:1'
+ tmpmol.load_pdb("./pdb/3og7.pdb")
+ bsid = "032:A:1"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrogen bonds
- hbonds = {str(hbond.resnr)+hbond.reschain for hbond in s.hbonds_pdon+s.hbonds_ldon}
+ hbonds = {
+ str(hbond.resnr) + hbond.reschain for hbond in s.hbonds_pdon + s.hbonds_ldon
+ }
# Additional hydrogen bond to residue 530A reported
- self.assertTrue({'594A'}.issubset(hbonds))
+ self.assertTrue({"594A"}.issubset(hbonds))
def test_1hpx(self):
"""
@@ -735,20 +751,22 @@ class LiteratureValidatedTest(unittest.TestCase):
For residues in the B chain, the offset is -100 (e.g. Ile 50B in the PDB structure is Ile 150 in the paper).
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1hpx.pdb')
- bsid = 'KNI:B:900'
+ tmpmol.load_pdb("./pdb/1hpx.pdb")
+ bsid = "KNI:B:900"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Hydrophobic contacts to Val82, Ile84, Ile150 as part of flap (S1, S1' sites)
- hydroph = {str(hyd.resnr)+hyd.reschain for hyd in s.all_hydrophobic_contacts}
- self.assertTrue({'82A', '84A', '50B'}.issubset(hydroph))
+ hydroph = {str(hyd.resnr) + hyd.reschain for hyd in s.all_hydrophobic_contacts}
+ self.assertTrue({"82A", "84A", "50B"}.issubset(hydroph))
# Hydrogen bonds
- hbonds = {str(hbond.resnr)+hbond.reschain for hbond in s.hbonds_ldon+s.hbonds_pdon}
+ hbonds = {
+ str(hbond.resnr) + hbond.reschain for hbond in s.hbonds_ldon + s.hbonds_pdon
+ }
# Additional hbond to 25B not detected (low angle?)
- self.assertTrue({'29B', '48B', '27B', '25A'}.issubset(hbonds))
+ self.assertTrue({"29B", "48B", "27B", "25A"}.issubset(hbonds))
# Water bridges
- waterbridges = {str(wb.resnr)+wb.reschain for wb in s.water_bridges}
+ waterbridges = {str(wb.resnr) + wb.reschain for wb in s.water_bridges}
# Waterbridge with Gly27 is detected instead of Ala28/Asp29
- self.assertTrue({'50A', '50B', '29A'}.issubset(waterbridges))
+ self.assertTrue({"50A", "50B", "29A"}.issubset(waterbridges))
diff --git a/plip/test/test_metal_coordination.py b/plip/test/test_metal_coordination.py
index 424b8df..e054735 100644
--- a/plip/test/test_metal_coordination.py
+++ b/plip/test/test_metal_coordination.py
@@ -22,19 +22,19 @@ class MetalCoordinationTest(unittest.TestCase):
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1rmd.pdb')
- bsid = 'ZN:A:119'
+ tmpmol.load_pdb("./pdb/1rmd.pdb")
+ bsid = "ZN:A:119"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Coordination by three cysteines and one histidine of the protein
metalres = [mres.restype for mres in s.metal_complexes]
- self.assertEqual(metalres.count('CYS'), 3)
- self.assertEqual(metalres.count('HIS'), 1)
+ self.assertEqual(metalres.count("CYS"), 3)
+ self.assertEqual(metalres.count("HIS"), 1)
# Zn atom with tetrahedral geometry (coordination number 4)
self.assertEqual(s.metal_complexes[0].coordination_num, 4)
- self.assertEqual(s.metal_complexes[0].geometry, 'tetrahedral')
+ self.assertEqual(s.metal_complexes[0].geometry, "tetrahedral")
def test_1rla(self):
"""Rat liver arginase, a binuclear manganese metalloenzyme (1rmd)
@@ -42,20 +42,20 @@ class MetalCoordinationTest(unittest.TestCase):
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1rla.pdb')
- bsid = 'MN:A:500'
+ tmpmol.load_pdb("./pdb/1rla.pdb")
+ bsid = "MN:A:500"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Coordination by one histidine, three aspartic acid residues, and one water molecule
metalres = [mres.restype for mres in s.metal_complexes]
- self.assertEqual(metalres.count('HIS'), 1)
- self.assertEqual(metalres.count('ASP'), 3)
- self.assertEqual(metalres.count('HOH'), 1)
+ self.assertEqual(metalres.count("HIS"), 1)
+ self.assertEqual(metalres.count("ASP"), 3)
+ self.assertEqual(metalres.count("HOH"), 1)
# Mn atom with square pyramidal geometry (coordination number 5)
self.assertEqual(s.metal_complexes[0].coordination_num, 5)
- self.assertEqual(s.metal_complexes[0].geometry, 'square.pyramidal')
+ self.assertEqual(s.metal_complexes[0].geometry, "square.pyramidal")
def test_1het(self):
"""Liver alcohol deshydrogenase (1het)
@@ -63,18 +63,18 @@ class MetalCoordinationTest(unittest.TestCase):
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1het.pdb')
- bsid = 'ZN:A:401'
+ tmpmol.load_pdb("./pdb/1het.pdb")
+ bsid = "ZN:A:401"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Coordination by four cysteines
metalres = [mres.restype + str(mres.resnr) for mres in s.metal_complexes]
- self.assertEqual(set(metalres), {'CYS97', 'CYS100', 'CYS103', 'CYS111'})
+ self.assertEqual(set(metalres), {"CYS97", "CYS100", "CYS103", "CYS111"})
# Zn atom with tetrahedral geometry (coordination number 4)
self.assertEqual(s.metal_complexes[0].coordination_num, 4)
- self.assertEqual(s.metal_complexes[0].geometry, 'tetrahedral')
+ self.assertEqual(s.metal_complexes[0].geometry, "tetrahedral")
def test_1vfy(self):
"""Phosphatidylinositol-3-phosphate binding FYVE domain of VPS27P protein (1vfy)
@@ -82,18 +82,18 @@ class MetalCoordinationTest(unittest.TestCase):
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/1vfy.pdb')
- bsid = 'ZN:A:300'
+ tmpmol.load_pdb("./pdb/1vfy.pdb")
+ bsid = "ZN:A:300"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Coordination by four cysteines
metalres = [mres.restype for mres in s.metal_complexes]
- self.assertEqual(set(metalres), {'CYS'})
+ self.assertEqual(set(metalres), {"CYS"})
# Zn atom with tetrahedral geometry (coordination number 4)
self.assertEqual(s.metal_complexes[0].coordination_num, 4)
- self.assertEqual(s.metal_complexes[0].geometry, 'tetrahedral')
+ self.assertEqual(s.metal_complexes[0].geometry, "tetrahedral")
def test_2pvb(self):
"""Pike parvalbumin binding calcium (2pvb)
@@ -101,15 +101,15 @@ class MetalCoordinationTest(unittest.TestCase):
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/2pvb.pdb')
- bsid = 'CA:A:110'
+ tmpmol.load_pdb("./pdb/2pvb.pdb")
+ bsid = "CA:A:110"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Ca atom with square pyramidal geometry (coordination number 5)
self.assertEqual(s.metal_complexes[0].coordination_num, 5)
- self.assertEqual(s.metal_complexes[0].geometry, 'square.pyramidal')
+ self.assertEqual(s.metal_complexes[0].geometry, "square.pyramidal")
def test_2q8q(self):
"""Crystal Structure of S. aureus IsdE complexed with heme (2q8q)
@@ -117,16 +117,16 @@ class MetalCoordinationTest(unittest.TestCase):
"""
tmpmol = PDBComplex()
- tmpmol.load_pdb('./pdb/2q8q.pdb')
- bsid = 'HEM:A:300'
+ tmpmol.load_pdb("./pdb/2q8q.pdb")
+ bsid = "HEM:A:300"
for ligand in tmpmol.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
+ if ":".join([ligand.hetid, ligand.chain, str(ligand.position)]) == bsid:
tmpmol.characterize_complex(ligand)
s = tmpmol.interaction_sets[bsid]
# Coordination by four nitrogens of heme itself and one additional histidine from the protein
metalres = [mres.restype for mres in s.metal_complexes]
- self.assertEqual(metalres.count('HEM'), 4)
- self.assertEqual(metalres.count('HIS'), 1)
+ self.assertEqual(metalres.count("HEM"), 4)
+ self.assertEqual(metalres.count("HIS"), 1)
# Fe atom with square pyramidal geometry (coordination number 5)
self.assertEqual(s.metal_complexes[0].coordination_num, 5)
- self.assertEqual(s.metal_complexes[0].geometry, 'square.pyramidal')
+ self.assertEqual(s.metal_complexes[0].geometry, "square.pyramidal")
diff --git a/plip/test/test_pi_stacking.py b/plip/test/test_pi_stacking.py
index bb560a3..16409ef 100644
--- a/plip/test/test_pi_stacking.py
+++ b/plip/test/test_pi_stacking.py
@@ -8,18 +8,22 @@ def characterize_complex(pdb_file: str, binding_site_id: str) -> PLInteraction:
pdb_complex = PDBComplex()
pdb_complex.load_pdb(pdb_file)
for ligand in pdb_complex.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == binding_site_id:
+ if (
+ ":".join([ligand.hetid, ligand.chain, str(ligand.position)])
+ == binding_site_id
+ ):
pdb_complex.characterize_complex(ligand)
return pdb_complex.interaction_sets[binding_site_id]
class RingDetectionTest(unittest.TestCase):
-
def test_consistent_ring_detection(self):
config.NOHYDRO = True
angles = set()
for i in range(0, 10):
- interactions = characterize_complex('./pdb/4dst_protonated.pdb', 'GCP:A:202')
+ interactions = characterize_complex(
+ "./pdb/4dst_protonated.pdb", "GCP:A:202"
+ )
angles.add(interactions.pistacking[0].angle)
self.assertTrue(len(angles) == 1)
config.NOHYDRO = False
diff --git a/plip/test/test_remote_services.py b/plip/test/test_remote_services.py
index d52bffc..9cd27b5 100644
--- a/plip/test/test_remote_services.py
+++ b/plip/test/test_remote_services.py
@@ -14,16 +14,16 @@ class TestPDB(unittest.TestCase):
def test_pdb_entry_status(self):
# 1a0v is an obsolete entry and is replaced by 1y46
- status, current_pdbid = check_pdb_status('1a0v')
- self.assertEqual(status, 'OBSOLETE')
- self.assertEqual(current_pdbid, '1y46')
+ status, current_pdbid = check_pdb_status("1a0v")
+ self.assertEqual(status, "OBSOLETE")
+ self.assertEqual(current_pdbid, "1y46")
# 1vsn is an current entry
- status, current_pdbid = check_pdb_status('1vsn')
- self.assertEqual(status, 'CURRENT')
- self.assertEqual(current_pdbid, '1vsn')
+ status, current_pdbid = check_pdb_status("1vsn")
+ self.assertEqual(status, "CURRENT")
+ self.assertEqual(current_pdbid, "1vsn")
# xxxx is not an PDB entry
- status, current_pdbid = check_pdb_status('xxxx')
- self.assertEqual(status, 'UNKNOWN')
- self.assertEqual(current_pdbid, 'xxxx')
+ status, current_pdbid = check_pdb_status("xxxx")
+ self.assertEqual(status, "UNKNOWN")
+ self.assertEqual(current_pdbid, "xxxx")
diff --git a/plip/test/test_water_bridges.py b/plip/test/test_water_bridges.py
index 24bf128..d820b59 100644
--- a/plip/test/test_water_bridges.py
+++ b/plip/test/test_water_bridges.py
@@ -7,14 +7,16 @@ def characterize_complex(pdb_file: str, binding_site_id: str) -> PLInteraction:
pdb_complex = PDBComplex()
pdb_complex.load_pdb(pdb_file)
for ligand in pdb_complex.ligands:
- if ':'.join([ligand.hetid, ligand.chain, str(ligand.position)]) == binding_site_id:
+ if (
+ ":".join([ligand.hetid, ligand.chain, str(ligand.position)])
+ == binding_site_id
+ ):
pdb_complex.characterize_complex(ligand)
return pdb_complex.interaction_sets[binding_site_id]
class WaterBridgeTest(unittest.TestCase):
-
def test_3ems(self):
- interactions = characterize_complex('./pdb/3ems.pdb', 'ARG:A:131')
+ interactions = characterize_complex("./pdb/3ems.pdb", "ARG:A:131")
water_bridges = interactions.water_bridges
self.assertEqual(len(water_bridges), 4)
diff --git a/plip/test/test_xml_parser.py b/plip/test/test_xml_parser.py
index 1f45daa..da99e50 100644
--- a/plip/test/test_xml_parser.py
+++ b/plip/test/test_xml_parser.py
@@ -13,27 +13,27 @@ class XMLParserTest(unittest.TestCase):
"""Checks if the XML parser is working correctly"""
def setUp(self):
- self.px = PlipXML('./xml/1vsn.report.xml')
- self.bsite = self.px.bsites['NFT:A:283']
- self.smiles = 'CC(C)CC(NC(c1ccc(cc1)c1ccc(cc1)S(N)(=O)=O)C(F)(F)F)C(=O)NCC=N'
+ self.px = PlipXML("./xml/1vsn.report.xml")
+ self.bsite = self.px.bsites["NFT:A:283"]
+ self.smiles = "CC(C)CC(NC(c1ccc(cc1)c1ccc(cc1)S(N)(=O)=O)C(F)(F)F)C(=O)NCC=N"
def test_general_information(self):
"""Test if general information is correctly parsed."""
- self.assertEqual(self.px.version, '1.4.2')
- self.assertEqual(self.px.pdbid, '1VSN')
+ self.assertEqual(self.px.version, "1.4.2")
+ self.assertEqual(self.px.pdbid, "1VSN")
self.assertFalse(self.px.fixed)
- self.assertEqual(self.px.filename, '1vsn.pdb')
+ self.assertEqual(self.px.filename, "1vsn.pdb")
self.assertEqual(self.px.excluded, [])
def test_bsite_information(self):
"""Test if the binding site information is correctly parsed."""
- self.assertEqual(self.bsite.pdbid, '1VSN')
- self.assertEqual(self.bsite.uniqueid, '1VSN:NFT:A:283')
- self.assertEqual(self.bsite.hetid, 'NFT')
- self.assertEqual(self.bsite.longname, 'NFT')
- self.assertEqual(self.bsite.ligtype, 'SMALLMOLECULE')
+ self.assertEqual(self.bsite.pdbid, "1VSN")
+ self.assertEqual(self.bsite.uniqueid, "1VSN:NFT:A:283")
+ self.assertEqual(self.bsite.hetid, "NFT")
+ self.assertEqual(self.bsite.longname, "NFT")
+ self.assertEqual(self.bsite.ligtype, "SMALLMOLECULE")
self.assertEqual(self.bsite.smiles, self.smiles)
- self.assertEqual(self.bsite.members, ['NFT:A:283'])
+ self.assertEqual(self.bsite.members, ["NFT:A:283"])
self.assertFalse(self.bsite.composite)
# ligand properties
@@ -50,7 +50,7 @@ class XMLParserTest(unittest.TestCase):
self.assertAlmostEqual(self.bsite.logp, 6, 0)
# Atom mappings (non-exhaustive test)
- lmap = self.bsite.mappings['pdb_to_smiles']
+ lmap = self.bsite.mappings["pdb_to_smiles"]
self.assertEqual(lmap[1625], 24)
self.assertEqual(lmap[1649], 33)
self.assertEqual(lmap[1617], 14)
@@ -59,7 +59,7 @@ class XMLParserTest(unittest.TestCase):
self.assertEqual(len(self.bsite.bs_res), 35)
# Interacting chains
- self.assertEqual(self.bsite.interacting_chains, ['A'])
+ self.assertEqual(self.bsite.interacting_chains, ["A"])
# Has Interactions?
self.assertTrue(self.bsite.has_interactions, True)
@@ -72,8 +72,8 @@ class XMLParserTest(unittest.TestCase):
hydrophobic1 = self.bsite.hydrophobics[0]
self.assertEqual(hydrophobic1.dist, 3.67)
self.assertEqual(hydrophobic1.resnr, 61)
- self.assertEqual(hydrophobic1.restype, 'ASP')
- self.assertEqual(hydrophobic1.reschain, 'A')
+ self.assertEqual(hydrophobic1.restype, "ASP")
+ self.assertEqual(hydrophobic1.reschain, "A")
self.assertEqual(hydrophobic1.ligcarbonidx, 1639)
self.assertEqual(hydrophobic1.protcarbonidx, 448)
self.assertEqual(hydrophobic1.ligcoo, (-7.395, 24.225, 6.614))
@@ -83,17 +83,17 @@ class XMLParserTest(unittest.TestCase):
self.assertEqual(len(self.bsite.hbonds), 6)
hbond1 = self.bsite.hbonds[0]
self.assertEqual(hbond1.resnr, 19)
- self.assertEqual(hbond1.restype, 'GLN')
- self.assertEqual(hbond1.reschain, 'A')
+ self.assertEqual(hbond1.restype, "GLN")
+ self.assertEqual(hbond1.reschain, "A")
self.assertTrue(hbond1.sidechain)
self.assertEqual(hbond1.dist_h_a, 2.16)
self.assertEqual(hbond1.dist_d_a, 3.11)
self.assertEqual(hbond1.don_angle, 160.05)
self.assertTrue(hbond1.protisdon)
self.assertEqual(hbond1.donoridx, 153)
- self.assertEqual(hbond1.donortype, 'Nam')
+ self.assertEqual(hbond1.donortype, "Nam")
self.assertEqual(hbond1.acceptoridx, 1649)
- self.assertEqual(hbond1.acceptortype, 'N2')
+ self.assertEqual(hbond1.acceptortype, "N2")
self.assertEqual(hbond1.ligcoo, (2.820, 18.145, 6.806))
self.assertEqual(hbond1.protcoo, (3.976, 15.409, 7.712))
@@ -101,17 +101,17 @@ class XMLParserTest(unittest.TestCase):
self.assertEqual(len(self.bsite.wbridges), 1)
wbridge1 = self.bsite.wbridges[0]
self.assertEqual(wbridge1.resnr, 159)
- self.assertEqual(wbridge1.restype, 'HIS')
- self.assertEqual(wbridge1.reschain, 'A')
+ self.assertEqual(wbridge1.restype, "HIS")
+ self.assertEqual(wbridge1.reschain, "A")
self.assertEqual(wbridge1.dist_a_w, 3.67)
self.assertEqual(wbridge1.dist_d_w, 3.13)
self.assertEqual(wbridge1.don_angle, 126.73)
self.assertEqual(wbridge1.water_angle, 116.36)
self.assertTrue(wbridge1.protisdon)
self.assertEqual(wbridge1.donor_idx, 1210)
- self.assertEqual(wbridge1.donortype, 'Nar')
+ self.assertEqual(wbridge1.donortype, "Nar")
self.assertEqual(wbridge1.acceptor_idx, 1649)
- self.assertEqual(wbridge1.acceptortype, 'N2')
+ self.assertEqual(wbridge1.acceptortype, "N2")
self.assertEqual(wbridge1.ligcoo, (2.820, 18.145, 6.806))
self.assertEqual(wbridge1.protcoo, (6.401, 19.307, 4.971))
self.assertEqual(wbridge1.watercoo, (3.860, 18.563, 3.309))
@@ -129,16 +129,16 @@ class XMLParserTest(unittest.TestCase):
self.assertEqual(len(self.bsite.halogens), 2)
hal1 = self.bsite.halogens[0]
self.assertEqual(hal1.resnr, 67)
- self.assertEqual(hal1.restype, 'TYR')
- self.assertEqual(hal1.reschain, 'A')
+ self.assertEqual(hal1.restype, "TYR")
+ self.assertEqual(hal1.reschain, "A")
self.assertTrue(hal1.sidechain)
self.assertEqual(hal1.dist, 3.37)
self.assertEqual(hal1.don_angle, 156.70)
self.assertEqual(hal1.acc_angle, 100.53)
self.assertEqual(hal1.don_idx, 1627)
- self.assertEqual(hal1.donortype, 'F')
+ self.assertEqual(hal1.donortype, "F")
self.assertEqual(hal1.acc_idx, 485)
- self.assertEqual(hal1.acceptortype, 'O3')
+ self.assertEqual(hal1.acceptortype, "O3")
self.assertEqual(hal1.ligcoo, (-1.862, 29.303, 4.507))
self.assertEqual(hal1.protcoo, (-1.005, 26.276, 3.287))
diff --git a/plip/visualization/chimera.py b/plip/visualization/chimera.py
index a37fffb..436d0e3 100644
--- a/plip/visualization/chimera.py
+++ b/plip/visualization/chimera.py
@@ -5,8 +5,8 @@ class ChimeraVisualizer:
self.chimera = chimera_module
self.tid = tid
self.uid = plcomplex.uid
- self.plipname = 'PLIP-%i' % self.tid
- self.hetid, self.chain, self.pos = self.uid.split(':')
+ self.plipname = "PLIP-%i" % self.tid
+ self.hetid, self.chain, self.pos = self.uid.split(":")
self.pos = int(self.pos)
self.colorbyname = self.chimera.colorTable.getColorByName
self.rc = self.chimera.runCommand
@@ -32,7 +32,10 @@ class ChimeraVisualizer:
self.update_model_dict()
self.rc("background solid white")
self.rc("setattr g display 0") # Hide all pseudobonds
- self.rc("~display #%i & :/isHet & ~:%s" % (self.model_dict[self.plipname], self.hetid))
+ self.rc(
+ "~display #%i & :/isHet & ~:%s"
+ % (self.model_dict[self.plipname], self.hetid)
+ )
def update_model_dict(self):
"""Updates the model dictionary"""
@@ -51,39 +54,47 @@ class ChimeraVisualizer:
def show_hydrophobic(self):
"""Visualizes hydrophobic contacts."""
- grp = self.getPseudoBondGroup("Hydrophobic Interactions-%i" % self.tid, associateWith=[self.model])
+ grp = self.getPseudoBondGroup(
+ "Hydrophobic Interactions-%i" % self.tid, associateWith=[self.model]
+ )
grp.lineType = self.chimera.Dash
grp.lineWidth = 3
- grp.color = self.colorbyname('gray')
+ grp.color = self.colorbyname("gray")
for i in self.plcomplex.hydrophobic_contacts.pairs_ids:
self.bs_res_ids.append(i[0])
def show_hbonds(self):
"""Visualizes hydrogen bonds."""
- grp = self.getPseudoBondGroup("Hydrogen Bonds-%i" % self.tid, associateWith=[self.model])
+ grp = self.getPseudoBondGroup(
+ "Hydrogen Bonds-%i" % self.tid, associateWith=[self.model]
+ )
grp.lineWidth = 3
for i in self.plcomplex.hbonds.ldon_id:
b = grp.newPseudoBond(self.atoms[i[0]], self.atoms[i[1]])
- b.color = self.colorbyname('blue')
+ b.color = self.colorbyname("blue")
self.bs_res_ids.append(i[0])
for i in self.plcomplex.hbonds.pdon_id:
b = grp.newPseudoBond(self.atoms[i[0]], self.atoms[i[1]])
- b.color = self.colorbyname('blue')
+ b.color = self.colorbyname("blue")
self.bs_res_ids.append(i[1])
def show_halogen(self):
"""Visualizes halogen bonds."""
- grp = self.getPseudoBondGroup("HalogenBonds-%i" % self.tid, associateWith=[self.model])
+ grp = self.getPseudoBondGroup(
+ "HalogenBonds-%i" % self.tid, associateWith=[self.model]
+ )
grp.lineWidth = 3
for i in self.plcomplex.halogen_bonds:
b = grp.newPseudoBond(self.atoms[i[0]], self.atoms[i[1]])
- b.color = self.colorbyname('turquoise')
+ b.color = self.colorbyname("turquoise")
self.bs_res_ids.append(i.acc_id)
def show_stacking(self):
"""Visualizes pi-stacking interactions."""
- grp = self.getPseudoBondGroup("pi-Stacking-%i" % self.tid, associateWith=[self.model])
+ grp = self.getPseudoBondGroup(
+ "pi-Stacking-%i" % self.tid, associateWith=[self.model]
+ )
grp.lineWidth = 3
grp.lineType = self.chimera.Dash
for i, stack in enumerate(self.plcomplex.pistacking):
@@ -101,13 +112,15 @@ class ChimeraVisualizer:
r.addAtom(centroid_lig)
b = grp.newPseudoBond(centroid_lig, centroid_prot)
- b.color = self.colorbyname('forest green')
+ b.color = self.colorbyname("forest green")
self.bs_res_ids += stack.proteinring_atoms
def show_cationpi(self):
"""Visualizes cation-pi interactions"""
- grp = self.getPseudoBondGroup("Cation-Pi-%i" % self.tid, associateWith=[self.model])
+ grp = self.getPseudoBondGroup(
+ "Cation-Pi-%i" % self.tid, associateWith=[self.model]
+ )
grp.lineWidth = 3
grp.lineType = self.chimera.Dash
for i, cat in enumerate(self.plcomplex.pication):
@@ -125,7 +138,7 @@ class ChimeraVisualizer:
r.addAtom(centroid)
b = grp.newPseudoBond(centroid, chargecenter)
- b.color = self.colorbyname('orange')
+ b.color = self.colorbyname("orange")
if cat.protcharged:
self.bs_res_ids += cat.charge_atoms
@@ -135,7 +148,9 @@ class ChimeraVisualizer:
def show_sbridges(self):
"""Visualizes salt bridges."""
# Salt Bridges
- grp = self.getPseudoBondGroup("Salt Bridges-%i" % self.tid, associateWith=[self.model])
+ grp = self.getPseudoBondGroup(
+ "Salt Bridges-%i" % self.tid, associateWith=[self.model]
+ )
grp.lineWidth = 3
grp.lineType = self.chimera.Dash
for i, sbridge in enumerate(self.plcomplex.saltbridges):
@@ -153,7 +168,7 @@ class ChimeraVisualizer:
r.addAtom(chargecenter2)
b = grp.newPseudoBond(chargecenter1, chargecenter2)
- b.color = self.colorbyname('yellow')
+ b.color = self.colorbyname("yellow")
if sbridge.protispos:
self.bs_res_ids += sbridge.positive_atoms
@@ -162,14 +177,20 @@ class ChimeraVisualizer:
def show_wbridges(self):
"""Visualizes water bridges"""
- grp = self.getPseudoBondGroup("Water Bridges-%i" % self.tid, associateWith=[self.model])
+ grp = self.getPseudoBondGroup(
+ "Water Bridges-%i" % self.tid, associateWith=[self.model]
+ )
grp.lineWidth = 3
for i, wbridge in enumerate(self.plcomplex.waterbridges):
- c = grp.newPseudoBond(self.atoms[wbridge.water_id], self.atoms[wbridge.acc_id])
- c.color = self.colorbyname('cornflower blue')
+ c = grp.newPseudoBond(
+ self.atoms[wbridge.water_id], self.atoms[wbridge.acc_id]
+ )
+ c.color = self.colorbyname("cornflower blue")
self.water_ids.append(wbridge.water_id)
- b = grp.newPseudoBond(self.atoms[wbridge.don_id], self.atoms[wbridge.water_id])
- b.color = self.colorbyname('cornflower blue')
+ b = grp.newPseudoBond(
+ self.atoms[wbridge.don_id], self.atoms[wbridge.water_id]
+ )
+ b.color = self.colorbyname("cornflower blue")
self.water_ids.append(wbridge.water_id)
if wbridge.protisdon:
self.bs_res_ids.append(wbridge.don_id)
@@ -178,16 +199,20 @@ class ChimeraVisualizer:
def show_metal(self):
"""Visualizes metal coordination."""
- grp = self.getPseudoBondGroup("Metal Coordination-%i" % self.tid, associateWith=[self.model])
+ grp = self.getPseudoBondGroup(
+ "Metal Coordination-%i" % self.tid, associateWith=[self.model]
+ )
grp.lineWidth = 3
for i, metal in enumerate(self.plcomplex.metal_complexes):
- c = grp.newPseudoBond(self.atoms[metal.metal_id], self.atoms[metal.target_id])
- c.color = self.colorbyname('magenta')
+ c = grp.newPseudoBond(
+ self.atoms[metal.metal_id], self.atoms[metal.target_id]
+ )
+ c.color = self.colorbyname("magenta")
- if metal.location == 'water':
+ if metal.location == "water":
self.water_ids.append(metal.target_id)
- if metal.location.startswith('protein'):
+ if metal.location.startswith("protein"):
self.bs_res_ids.append(metal.target_id)
def cleanup(self):
@@ -197,13 +222,16 @@ class ChimeraVisualizer:
# Hide all non-interacting water molecules
water_selection = []
for wid in self.water_ids:
- water_selection.append('serialNumber=%i' % wid)
+ water_selection.append("serialNumber=%i" % wid)
self.rc("~display :HOH")
self.rc("display :@/%s" % " or ".join(water_selection))
# Show all interacting binding site residues
self.rc("~display #%i & ~:/isHet" % self.model_dict[self.plipname])
- self.rc("display :%s" % ",".join([str(self.atoms[bsid].residue.id) for bsid in self.bs_res_ids]))
+ self.rc(
+ "display :%s"
+ % ",".join([str(self.atoms[bsid].residue.id) for bsid in self.bs_res_ids])
+ )
self.rc("color lightblue :HOH")
def zoom_to_ligand(self):
diff --git a/plip/visualization/pymol.py b/plip/visualization/pymol.py
index b97912a..2e1b0e3 100644
--- a/plip/visualization/pymol.py
+++ b/plip/visualization/pymol.py
@@ -7,7 +7,6 @@ from pymol import cmd
class PyMOLVisualizer:
-
def __init__(self, plcomplex):
if plcomplex is not None:
self.plcomplex = plcomplex
@@ -20,57 +19,86 @@ class PyMOLVisualizer:
def set_initial_representations(self):
"""General settings for PyMOL"""
self.standard_settings()
- cmd.set('dash_gap', 0) # Show not dashes, but lines for the pliprofiler
- cmd.set('ray_shadow', 0) # Turn on ray shadows for clearer ray-traced images
- cmd.set('cartoon_color', 'mylightblue')
+ cmd.set("dash_gap", 0) # Show not dashes, but lines for the pliprofiler
+ cmd.set("ray_shadow", 0) # Turn on ray shadows for clearer ray-traced images
+ cmd.set("cartoon_color", "mylightblue")
# Set clipping planes for full view
- cmd.clip('far', -1000)
- cmd.clip('near', 1000)
+ cmd.clip("far", -1000)
+ cmd.clip("near", 1000)
def make_initial_selections(self):
"""Make empty selections for structures and interactions"""
- for group in ['Hydrophobic-P', 'Hydrophobic-L', 'HBondDonor-P',
- 'HBondDonor-L', 'HBondAccept-P', 'HBondAccept-L',
- 'HalogenAccept', 'HalogenDonor', 'Water', 'MetalIons', 'StackRings-P',
- 'PosCharge-P', 'PosCharge-L', 'NegCharge-P', 'NegCharge-L',
- 'PiCatRing-P', 'StackRings-L', 'PiCatRing-L', 'Metal-M', 'Metal-P',
- 'Metal-W', 'Metal-L', 'Unpaired-HBA', 'Unpaired-HBD', 'Unpaired-HAL',
- 'Unpaired-RINGS']:
- cmd.select(group, 'None')
+ for group in [
+ "Hydrophobic-P",
+ "Hydrophobic-L",
+ "HBondDonor-P",
+ "HBondDonor-L",
+ "HBondAccept-P",
+ "HBondAccept-L",
+ "HalogenAccept",
+ "HalogenDonor",
+ "Water",
+ "MetalIons",
+ "StackRings-P",
+ "PosCharge-P",
+ "PosCharge-L",
+ "NegCharge-P",
+ "NegCharge-L",
+ "PiCatRing-P",
+ "StackRings-L",
+ "PiCatRing-L",
+ "Metal-M",
+ "Metal-P",
+ "Metal-W",
+ "Metal-L",
+ "Unpaired-HBA",
+ "Unpaired-HBD",
+ "Unpaired-HAL",
+ "Unpaired-RINGS",
+ ]:
+ cmd.select(group, "None")
def standard_settings(self):
"""Sets up standard settings for a nice visualization."""
- cmd.set('bg_rgb', [1.0, 1.0, 1.0]) # White background
- cmd.set('depth_cue', 0) # Turn off depth cueing (no fog)
- cmd.set('cartoon_side_chain_helper', 1) # Improve combined visualization of sticks and cartoon
- cmd.set('cartoon_fancy_helices', 1) # Nicer visualization of helices (using tapered ends)
- cmd.set('transparency_mode', 1) # Turn on multilayer transparency
- cmd.set('dash_radius', 0.05)
+ cmd.set("bg_rgb", [1.0, 1.0, 1.0]) # White background
+ cmd.set("depth_cue", 0) # Turn off depth cueing (no fog)
+ cmd.set(
+ "cartoon_side_chain_helper", 1
+ ) # Improve combined visualization of sticks and cartoon
+ cmd.set(
+ "cartoon_fancy_helices", 1
+ ) # Nicer visualization of helices (using tapered ends)
+ cmd.set("transparency_mode", 1) # Turn on multilayer transparency
+ cmd.set("dash_radius", 0.05)
self.set_custom_colorset()
def set_custom_colorset(self):
"""Defines a colorset with matching colors. Provided by Joachim."""
- cmd.set_color('myorange', '[253, 174, 97]')
- cmd.set_color('mygreen', '[171, 221, 164]')
- cmd.set_color('myred', '[215, 25, 28]')
- cmd.set_color('myblue', '[43, 131, 186]')
- cmd.set_color('mylightblue', '[158, 202, 225]')
- cmd.set_color('mylightgreen', '[229, 245, 224]')
-
- def select_by_ids(self, selname, idlist, selection_exists=False, chunksize=20, restrict=None):
+ cmd.set_color("myorange", "[253, 174, 97]")
+ cmd.set_color("mygreen", "[171, 221, 164]")
+ cmd.set_color("myred", "[215, 25, 28]")
+ cmd.set_color("myblue", "[43, 131, 186]")
+ cmd.set_color("mylightblue", "[158, 202, 225]")
+ cmd.set_color("mylightgreen", "[229, 245, 224]")
+
+ def select_by_ids(
+ self, selname, idlist, selection_exists=False, chunksize=20, restrict=None
+ ):
"""Selection with a large number of ids concatenated into a selection
list can cause buffer overflow in PyMOL. This function takes a selection
name and and list of IDs (list of integers) as input and makes a careful
step-by-step selection (packages of 20 by default)"""
idlist = list(set(idlist)) # Remove duplicates
if not selection_exists:
- cmd.select(selname, 'None') # Empty selection first
- idchunks = [idlist[i:i + chunksize] for i in range(0, len(idlist), chunksize)]
+ cmd.select(selname, "None") # Empty selection first
+ idchunks = [idlist[i : i + chunksize] for i in range(0, len(idlist), chunksize)]
for idchunk in idchunks:
- cmd.select(selname, '%s or (id %s)' % (selname, '+'.join(map(str, idchunk))))
+ cmd.select(
+ selname, "%s or (id %s)" % (selname, "+".join(map(str, idchunk)))
+ )
if restrict is not None:
- cmd.select(selname, '%s and %s' % (selname, restrict))
+ cmd.select(selname, "%s and %s" % (selname, restrict))
def object_exists(self, object_name):
"""Checks if an object exists in the open PyMOL session."""
@@ -80,40 +108,44 @@ class PyMOLVisualizer:
"""Visualizes hydrophobic contacts."""
hydroph = self.plcomplex.hydrophobic_contacts
if not len(hydroph.bs_ids) == 0:
- self.select_by_ids('Hydrophobic-P', hydroph.bs_ids, restrict=self.protname)
- self.select_by_ids('Hydrophobic-L', hydroph.lig_ids, restrict=self.ligname)
+ self.select_by_ids("Hydrophobic-P", hydroph.bs_ids, restrict=self.protname)
+ self.select_by_ids("Hydrophobic-L", hydroph.lig_ids, restrict=self.ligname)
for i in hydroph.pairs_ids:
- cmd.select('tmp_bs', 'id %i & %s' % (i[0], self.protname))
- cmd.select('tmp_lig', 'id %i & %s' % (i[1], self.ligname))
- cmd.distance('Hydrophobic', 'tmp_bs', 'tmp_lig')
- if self.object_exists('Hydrophobic'):
- cmd.set('dash_gap', 0.5, 'Hydrophobic')
- cmd.set('dash_color', 'grey50', 'Hydrophobic')
+ cmd.select("tmp_bs", "id %i & %s" % (i[0], self.protname))
+ cmd.select("tmp_lig", "id %i & %s" % (i[1], self.ligname))
+ cmd.distance("Hydrophobic", "tmp_bs", "tmp_lig")
+ if self.object_exists("Hydrophobic"):
+ cmd.set("dash_gap", 0.5, "Hydrophobic")
+ cmd.set("dash_color", "grey50", "Hydrophobic")
else:
- cmd.select('Hydrophobic-P', 'None')
+ cmd.select("Hydrophobic-P", "None")
def show_hbonds(self):
"""Visualizes hydrogen bonds."""
hbonds = self.plcomplex.hbonds
- for group in [['HBondDonor-P', hbonds.prot_don_id],
- ['HBondAccept-P', hbonds.prot_acc_id]]:
+ for group in [
+ ["HBondDonor-P", hbonds.prot_don_id],
+ ["HBondAccept-P", hbonds.prot_acc_id],
+ ]:
if not len(group[1]) == 0:
self.select_by_ids(group[0], group[1], restrict=self.protname)
- for group in [['HBondDonor-L', hbonds.lig_don_id],
- ['HBondAccept-L', hbonds.lig_acc_id]]:
+ for group in [
+ ["HBondDonor-L", hbonds.lig_don_id],
+ ["HBondAccept-L", hbonds.lig_acc_id],
+ ]:
if not len(group[1]) == 0:
self.select_by_ids(group[0], group[1], restrict=self.ligname)
for i in hbonds.ldon_id:
- cmd.select('tmp_bs', 'id %i & %s' % (i[0], self.protname))
- cmd.select('tmp_lig', 'id %i & %s' % (i[1], self.ligname))
- cmd.distance('HBonds', 'tmp_bs', 'tmp_lig')
+ cmd.select("tmp_bs", "id %i & %s" % (i[0], self.protname))
+ cmd.select("tmp_lig", "id %i & %s" % (i[1], self.ligname))
+ cmd.distance("HBonds", "tmp_bs", "tmp_lig")
for i in hbonds.pdon_id:
- cmd.select('tmp_bs', 'id %i & %s' % (i[1], self.protname))
- cmd.select('tmp_lig', 'id %i & %s' % (i[0], self.ligname))
- cmd.distance('HBonds', 'tmp_bs', 'tmp_lig')
- if self.object_exists('HBonds'):
- cmd.set('dash_color', 'blue', 'HBonds')
+ cmd.select("tmp_bs", "id %i & %s" % (i[1], self.protname))
+ cmd.select("tmp_lig", "id %i & %s" % (i[0], self.ligname))
+ cmd.distance("HBonds", "tmp_bs", "tmp_lig")
+ if self.object_exists("HBonds"):
+ cmd.set("dash_color", "blue", "HBonds")
def show_halogen(self):
"""Visualize halogen bonds."""
@@ -122,155 +154,218 @@ class PyMOLVisualizer:
for h in halogen:
all_don_x.append(h.don_id)
all_acc_o.append(h.acc_id)
- cmd.select('tmp_bs', 'id %i & %s' % (h.acc_id, self.protname))
- cmd.select('tmp_lig', 'id %i & %s' % (h.don_id, self.ligname))
+ cmd.select("tmp_bs", "id %i & %s" % (h.acc_id, self.protname))
+ cmd.select("tmp_lig", "id %i & %s" % (h.don_id, self.ligname))
- cmd.distance('HalogenBonds', 'tmp_bs', 'tmp_lig')
+ cmd.distance("HalogenBonds", "tmp_bs", "tmp_lig")
if not len(all_acc_o) == 0:
- self.select_by_ids('HalogenAccept', all_acc_o, restrict=self.protname)
- self.select_by_ids('HalogenDonor', all_don_x, restrict=self.ligname)
- if self.object_exists('HalogenBonds'):
- cmd.set('dash_color', 'greencyan', 'HalogenBonds')
+ self.select_by_ids("HalogenAccept", all_acc_o, restrict=self.protname)
+ self.select_by_ids("HalogenDonor", all_don_x, restrict=self.ligname)
+ if self.object_exists("HalogenBonds"):
+ cmd.set("dash_color", "greencyan", "HalogenBonds")
def show_stacking(self):
"""Visualize pi-stacking interactions."""
stacks = self.plcomplex.pistacking
for i, stack in enumerate(stacks):
- pires_ids = '+'.join(map(str, stack.proteinring_atoms))
- pilig_ids = '+'.join(map(str, stack.ligandring_atoms))
- cmd.select('StackRings-P', 'StackRings-P or (id %s & %s)' % (pires_ids, self.protname))
- cmd.select('StackRings-L', 'StackRings-L or (id %s & %s)' % (pilig_ids, self.ligname))
- cmd.select('StackRings-P', 'byres StackRings-P')
- cmd.show('sticks', 'StackRings-P')
-
- cmd.pseudoatom('ps-pistack-1-%i' % i, pos=stack.proteinring_center)
- cmd.pseudoatom('ps-pistack-2-%i' % i, pos=stack.ligandring_center)
- cmd.pseudoatom('Centroids-P', pos=stack.proteinring_center)
- cmd.pseudoatom('Centroids-L', pos=stack.ligandring_center)
-
- if stack.type == 'P':
- cmd.distance('PiStackingP', 'ps-pistack-1-%i' % i, 'ps-pistack-2-%i' % i)
- if stack.type == 'T':
- cmd.distance('PiStackingT', 'ps-pistack-1-%i' % i, 'ps-pistack-2-%i' % i)
- if self.object_exists('PiStackingP'):
- cmd.set('dash_color', 'green', 'PiStackingP')
- cmd.set('dash_gap', 0.3, 'PiStackingP')
- cmd.set('dash_length', 0.6, 'PiStackingP')
- if self.object_exists('PiStackingT'):
- cmd.set('dash_color', 'smudge', 'PiStackingT')
- cmd.set('dash_gap', 0.3, 'PiStackingT')
- cmd.set('dash_length', 0.6, 'PiStackingT')
+ pires_ids = "+".join(map(str, stack.proteinring_atoms))
+ pilig_ids = "+".join(map(str, stack.ligandring_atoms))
+ cmd.select(
+ "StackRings-P",
+ "StackRings-P or (id %s & %s)" % (pires_ids, self.protname),
+ )
+ cmd.select(
+ "StackRings-L",
+ "StackRings-L or (id %s & %s)" % (pilig_ids, self.ligname),
+ )
+ cmd.select("StackRings-P", "byres StackRings-P")
+ cmd.show("sticks", "StackRings-P")
+
+ cmd.pseudoatom("ps-pistack-1-%i" % i, pos=stack.proteinring_center)
+ cmd.pseudoatom("ps-pistack-2-%i" % i, pos=stack.ligandring_center)
+ cmd.pseudoatom("Centroids-P", pos=stack.proteinring_center)
+ cmd.pseudoatom("Centroids-L", pos=stack.ligandring_center)
+
+ if stack.type == "P":
+ cmd.distance(
+ "PiStackingP", "ps-pistack-1-%i" % i, "ps-pistack-2-%i" % i
+ )
+ if stack.type == "T":
+ cmd.distance(
+ "PiStackingT", "ps-pistack-1-%i" % i, "ps-pistack-2-%i" % i
+ )
+ if self.object_exists("PiStackingP"):
+ cmd.set("dash_color", "green", "PiStackingP")
+ cmd.set("dash_gap", 0.3, "PiStackingP")
+ cmd.set("dash_length", 0.6, "PiStackingP")
+ if self.object_exists("PiStackingT"):
+ cmd.set("dash_color", "smudge", "PiStackingT")
+ cmd.set("dash_gap", 0.3, "PiStackingT")
+ cmd.set("dash_length", 0.6, "PiStackingT")
def show_cationpi(self):
"""Visualize cation-pi interactions."""
for i, p in enumerate(self.plcomplex.pication):
- cmd.pseudoatom('ps-picat-1-%i' % i, pos=p.ring_center)
- cmd.pseudoatom('ps-picat-2-%i' % i, pos=p.charge_center)
+ cmd.pseudoatom("ps-picat-1-%i" % i, pos=p.ring_center)
+ cmd.pseudoatom("ps-picat-2-%i" % i, pos=p.charge_center)
if p.protcharged:
- cmd.pseudoatom('Chargecenter-P', pos=p.charge_center)
- cmd.pseudoatom('Centroids-L', pos=p.ring_center)
- pilig_ids = '+'.join(map(str, p.ring_atoms))
- cmd.select('PiCatRing-L', 'PiCatRing-L or (id %s & %s)' % (pilig_ids, self.ligname))
+ cmd.pseudoatom("Chargecenter-P", pos=p.charge_center)
+ cmd.pseudoatom("Centroids-L", pos=p.ring_center)
+ pilig_ids = "+".join(map(str, p.ring_atoms))
+ cmd.select(
+ "PiCatRing-L",
+ "PiCatRing-L or (id %s & %s)" % (pilig_ids, self.ligname),
+ )
for a in p.charge_atoms:
- cmd.select('PosCharge-P', 'PosCharge-P or (id %i & %s)' % (a, self.protname))
+ cmd.select(
+ "PosCharge-P",
+ "PosCharge-P or (id %i & %s)" % (a, self.protname),
+ )
else:
- cmd.pseudoatom('Chargecenter-L', pos=p.charge_center)
- cmd.pseudoatom('Centroids-P', pos=p.ring_center)
- pires_ids = '+'.join(map(str, p.ring_atoms))
- cmd.select('PiCatRing-P', 'PiCatRing-P or (id %s & %s)' % (pires_ids, self.protname))
+ cmd.pseudoatom("Chargecenter-L", pos=p.charge_center)
+ cmd.pseudoatom("Centroids-P", pos=p.ring_center)
+ pires_ids = "+".join(map(str, p.ring_atoms))
+ cmd.select(
+ "PiCatRing-P",
+ "PiCatRing-P or (id %s & %s)" % (pires_ids, self.protname),
+ )
for a in p.charge_atoms:
- cmd.select('PosCharge-L', 'PosCharge-L or (id %i & %s)' % (a, self.ligname))
- cmd.distance('PiCation', 'ps-picat-1-%i' % i, 'ps-picat-2-%i' % i)
- if self.object_exists('PiCation'):
- cmd.set('dash_color', 'orange', 'PiCation')
- cmd.set('dash_gap', 0.3, 'PiCation')
- cmd.set('dash_length', 0.6, 'PiCation')
+ cmd.select(
+ "PosCharge-L", "PosCharge-L or (id %i & %s)" % (a, self.ligname)
+ )
+ cmd.distance("PiCation", "ps-picat-1-%i" % i, "ps-picat-2-%i" % i)
+ if self.object_exists("PiCation"):
+ cmd.set("dash_color", "orange", "PiCation")
+ cmd.set("dash_gap", 0.3, "PiCation")
+ cmd.set("dash_length", 0.6, "PiCation")
def show_sbridges(self):
"""Visualize salt bridges."""
for i, saltb in enumerate(self.plcomplex.saltbridges):
if saltb.protispos:
for patom in saltb.positive_atoms:
- cmd.select('PosCharge-P', 'PosCharge-P or (id %i & %s)' % (patom, self.protname))
+ cmd.select(
+ "PosCharge-P",
+ "PosCharge-P or (id %i & %s)" % (patom, self.protname),
+ )
for latom in saltb.negative_atoms:
- cmd.select('NegCharge-L', 'NegCharge-L or (id %i & %s)' % (latom, self.ligname))
- for sbgroup in [['ps-sbl-1-%i' % i, 'Chargecenter-P', saltb.positive_center],
- ['ps-sbl-2-%i' % i, 'Chargecenter-L', saltb.negative_center]]:
+ cmd.select(
+ "NegCharge-L",
+ "NegCharge-L or (id %i & %s)" % (latom, self.ligname),
+ )
+ for sbgroup in [
+ ["ps-sbl-1-%i" % i, "Chargecenter-P", saltb.positive_center],
+ ["ps-sbl-2-%i" % i, "Chargecenter-L", saltb.negative_center],
+ ]:
cmd.pseudoatom(sbgroup[0], pos=sbgroup[2])
cmd.pseudoatom(sbgroup[1], pos=sbgroup[2])
- cmd.distance('Saltbridges', 'ps-sbl-1-%i' % i, 'ps-sbl-2-%i' % i)
+ cmd.distance("Saltbridges", "ps-sbl-1-%i" % i, "ps-sbl-2-%i" % i)
else:
for patom in saltb.negative_atoms:
- cmd.select('NegCharge-P', 'NegCharge-P or (id %i & %s)' % (patom, self.protname))
+ cmd.select(
+ "NegCharge-P",
+ "NegCharge-P or (id %i & %s)" % (patom, self.protname),
+ )
for latom in saltb.positive_atoms:
- cmd.select('PosCharge-L', 'PosCharge-L or (id %i & %s)' % (latom, self.ligname))
- for sbgroup in [['ps-sbp-1-%i' % i, 'Chargecenter-P', saltb.negative_center],
- ['ps-sbp-2-%i' % i, 'Chargecenter-L', saltb.positive_center]]:
+ cmd.select(
+ "PosCharge-L",
+ "PosCharge-L or (id %i & %s)" % (latom, self.ligname),
+ )
+ for sbgroup in [
+ ["ps-sbp-1-%i" % i, "Chargecenter-P", saltb.negative_center],
+ ["ps-sbp-2-%i" % i, "Chargecenter-L", saltb.positive_center],
+ ]:
cmd.pseudoatom(sbgroup[0], pos=sbgroup[2])
cmd.pseudoatom(sbgroup[1], pos=sbgroup[2])
- cmd.distance('Saltbridges', 'ps-sbp-1-%i' % i, 'ps-sbp-2-%i' % i)
+ cmd.distance("Saltbridges", "ps-sbp-1-%i" % i, "ps-sbp-2-%i" % i)
- if self.object_exists('Saltbridges'):
- cmd.set('dash_color', 'yellow', 'Saltbridges')
- cmd.set('dash_gap', 0.5, 'Saltbridges')
+ if self.object_exists("Saltbridges"):
+ cmd.set("dash_color", "yellow", "Saltbridges")
+ cmd.set("dash_gap", 0.5, "Saltbridges")
def show_wbridges(self):
"""Visualize water bridges."""
for bridge in self.plcomplex.waterbridges:
if bridge.protisdon:
- cmd.select('HBondDonor-P', 'HBondDonor-P or (id %i & %s)' % (bridge.don_id, self.protname))
- cmd.select('HBondAccept-L', 'HBondAccept-L or (id %i & %s)' % (bridge.acc_id, self.ligname))
- cmd.select('tmp_don', 'id %i & %s' % (bridge.don_id, self.protname))
- cmd.select('tmp_acc', 'id %i & %s' % (bridge.acc_id, self.ligname))
+ cmd.select(
+ "HBondDonor-P",
+ "HBondDonor-P or (id %i & %s)" % (bridge.don_id, self.protname),
+ )
+ cmd.select(
+ "HBondAccept-L",
+ "HBondAccept-L or (id %i & %s)" % (bridge.acc_id, self.ligname),
+ )
+ cmd.select("tmp_don", "id %i & %s" % (bridge.don_id, self.protname))
+ cmd.select("tmp_acc", "id %i & %s" % (bridge.acc_id, self.ligname))
else:
- cmd.select('HBondDonor-L', 'HBondDonor-L or (id %i & %s)' % (bridge.don_id, self.ligname))
- cmd.select('HBondAccept-P', 'HBondAccept-P or (id %i & %s)' % (bridge.acc_id, self.protname))
- cmd.select('tmp_don', 'id %i & %s' % (bridge.don_id, self.ligname))
- cmd.select('tmp_acc', 'id %i & %s' % (bridge.acc_id, self.protname))
- cmd.select('Water', 'Water or (id %i & resn HOH)' % bridge.water_id)
- cmd.select('tmp_water', 'id %i & resn HOH' % bridge.water_id)
- cmd.distance('WaterBridges', 'tmp_acc', 'tmp_water')
- cmd.distance('WaterBridges', 'tmp_don', 'tmp_water')
- if self.object_exists('WaterBridges'):
- cmd.set('dash_color', 'lightblue', 'WaterBridges')
- cmd.delete('tmp_water or tmp_acc or tmp_don')
- cmd.color('lightblue', 'Water')
- cmd.show('spheres', 'Water')
+ cmd.select(
+ "HBondDonor-L",
+ "HBondDonor-L or (id %i & %s)" % (bridge.don_id, self.ligname),
+ )
+ cmd.select(
+ "HBondAccept-P",
+ "HBondAccept-P or (id %i & %s)" % (bridge.acc_id, self.protname),
+ )
+ cmd.select("tmp_don", "id %i & %s" % (bridge.don_id, self.ligname))
+ cmd.select("tmp_acc", "id %i & %s" % (bridge.acc_id, self.protname))
+ cmd.select("Water", "Water or (id %i & resn HOH)" % bridge.water_id)
+ cmd.select("tmp_water", "id %i & resn HOH" % bridge.water_id)
+ cmd.distance("WaterBridges", "tmp_acc", "tmp_water")
+ cmd.distance("WaterBridges", "tmp_don", "tmp_water")
+ if self.object_exists("WaterBridges"):
+ cmd.set("dash_color", "lightblue", "WaterBridges")
+ cmd.delete("tmp_water or tmp_acc or tmp_don")
+ cmd.color("lightblue", "Water")
+ cmd.show("spheres", "Water")
def show_metal(self):
"""Visualize metal coordination."""
metal_complexes = self.plcomplex.metal_complexes
if not len(metal_complexes) == 0:
- self.select_by_ids('Metal-M', self.metal_ids)
+ self.select_by_ids("Metal-M", self.metal_ids)
for metal_complex in metal_complexes:
- cmd.select('tmp_m', 'id %i' % metal_complex.metal_id)
- cmd.select('tmp_t', 'id %i' % metal_complex.target_id)
- if metal_complex.location == 'water':
- cmd.select('Metal-W', 'Metal-W or id %s' % metal_complex.target_id)
- if metal_complex.location.startswith('protein'):
- cmd.select('tmp_t', 'tmp_t & %s' % self.protname)
- cmd.select('Metal-P', 'Metal-P or (id %s & %s)' % (metal_complex.target_id, self.protname))
- if metal_complex.location == 'ligand':
- cmd.select('tmp_t', 'tmp_t & %s' % self.ligname)
- cmd.select('Metal-L', 'Metal-L or (id %s & %s)' % (metal_complex.target_id, self.ligname))
- cmd.distance('MetalComplexes', 'tmp_m', 'tmp_t')
- cmd.delete('tmp_m or tmp_t')
- if self.object_exists('MetalComplexes'):
- cmd.set('dash_color', 'violetpurple', 'MetalComplexes')
- cmd.set('dash_gap', 0.5, 'MetalComplexes')
+ cmd.select("tmp_m", "id %i" % metal_complex.metal_id)
+ cmd.select("tmp_t", "id %i" % metal_complex.target_id)
+ if metal_complex.location == "water":
+ cmd.select("Metal-W", "Metal-W or id %s" % metal_complex.target_id)
+ if metal_complex.location.startswith("protein"):
+ cmd.select("tmp_t", "tmp_t & %s" % self.protname)
+ cmd.select(
+ "Metal-P",
+ "Metal-P or (id %s & %s)"
+ % (metal_complex.target_id, self.protname),
+ )
+ if metal_complex.location == "ligand":
+ cmd.select("tmp_t", "tmp_t & %s" % self.ligname)
+ cmd.select(
+ "Metal-L",
+ "Metal-L or (id %s & %s)"
+ % (metal_complex.target_id, self.ligname),
+ )
+ cmd.distance("MetalComplexes", "tmp_m", "tmp_t")
+ cmd.delete("tmp_m or tmp_t")
+ if self.object_exists("MetalComplexes"):
+ cmd.set("dash_color", "violetpurple", "MetalComplexes")
+ cmd.set("dash_gap", 0.5, "MetalComplexes")
# Show water molecules for metal complexes
- cmd.show('spheres', 'Metal-W')
- cmd.color('lightblue', 'Metal-W')
+ cmd.show("spheres", "Metal-W")
+ cmd.color("lightblue", "Metal-W")
def selections_cleanup(self):
"""Cleans up non-used selections"""
if not len(self.plcomplex.unpaired_hba_idx) == 0:
- self.select_by_ids('Unpaired-HBA', self.plcomplex.unpaired_hba_idx, selection_exists=True)
+ self.select_by_ids(
+ "Unpaired-HBA", self.plcomplex.unpaired_hba_idx, selection_exists=True
+ )
if not len(self.plcomplex.unpaired_hbd_idx) == 0:
- self.select_by_ids('Unpaired-HBD', self.plcomplex.unpaired_hbd_idx, selection_exists=True)
+ self.select_by_ids(
+ "Unpaired-HBD", self.plcomplex.unpaired_hbd_idx, selection_exists=True
+ )
if not len(self.plcomplex.unpaired_hal_idx) == 0:
- self.select_by_ids('Unpaired-HAL', self.plcomplex.unpaired_hal_idx, selection_exists=True)
+ self.select_by_ids(
+ "Unpaired-HAL", self.plcomplex.unpaired_hal_idx, selection_exists=True
+ )
selections = cmd.get_names("selections")
for selection in selections:
@@ -281,38 +376,52 @@ class PyMOLVisualizer:
if empty:
cmd.delete(selection)
cmd.deselect()
- cmd.delete('tmp*')
- cmd.delete('ps-*')
+ cmd.delete("tmp*")
+ cmd.delete("ps-*")
def selections_group(self):
"""Group all selections"""
- cmd.group('Structures', '%s %s %sCartoon' % (self.protname, self.ligname, self.protname))
- cmd.group('Interactions', 'Hydrophobic HBonds HalogenBonds WaterBridges PiCation PiStackingP PiStackingT '
- 'Saltbridges MetalComplexes')
- cmd.group('Atoms', '')
- cmd.group('Atoms.Protein', 'Hydrophobic-P HBondAccept-P HBondDonor-P HalogenAccept Centroids-P PiCatRing-P '
- 'StackRings-P PosCharge-P NegCharge-P AllBSRes Chargecenter-P Metal-P')
- cmd.group('Atoms.Ligand', 'Hydrophobic-L HBondAccept-L HBondDonor-L HalogenDonor Centroids-L NegCharge-L '
- 'PosCharge-L NegCharge-L ChargeCenter-L StackRings-L PiCatRing-L Metal-L Metal-M '
- 'Unpaired-HBA Unpaired-HBD Unpaired-HAL Unpaired-RINGS')
- cmd.group('Atoms.Other', 'Water Metal-W')
- cmd.order('*', 'y')
+ cmd.group(
+ "Structures",
+ "%s %s %sCartoon" % (self.protname, self.ligname, self.protname),
+ )
+ cmd.group(
+ "Interactions",
+ "Hydrophobic HBonds HalogenBonds WaterBridges PiCation PiStackingP PiStackingT "
+ "Saltbridges MetalComplexes",
+ )
+ cmd.group("Atoms", "")
+ cmd.group(
+ "Atoms.Protein",
+ "Hydrophobic-P HBondAccept-P HBondDonor-P HalogenAccept Centroids-P PiCatRing-P "
+ "StackRings-P PosCharge-P NegCharge-P AllBSRes Chargecenter-P Metal-P",
+ )
+ cmd.group(
+ "Atoms.Ligand",
+ "Hydrophobic-L HBondAccept-L HBondDonor-L HalogenDonor Centroids-L NegCharge-L "
+ "PosCharge-L NegCharge-L ChargeCenter-L StackRings-L PiCatRing-L Metal-L Metal-M "
+ "Unpaired-HBA Unpaired-HBD Unpaired-HAL Unpaired-RINGS",
+ )
+ cmd.group("Atoms.Other", "Water Metal-W")
+ cmd.order("*", "y")
def additional_cleanup(self):
"""Cleanup of various representations"""
cmd.remove('not alt ""+A') # Remove alternate conformations
- cmd.hide('labels', 'Interactions') # Hide labels of lines
- cmd.disable('%sCartoon' % self.protname)
- cmd.hide('everything', 'hydrogens')
+ cmd.hide("labels", "Interactions") # Hide labels of lines
+ cmd.disable("%sCartoon" % self.protname)
+ cmd.hide("everything", "hydrogens")
def zoom_to_ligand(self):
"""Zoom in too ligand and its interactions."""
cmd.center(self.ligname)
cmd.orient(self.ligname)
- cmd.turn('x', 110) # If the ligand is aligned with the longest axis, aromatic rings are hidden
- if 'AllBSRes' in cmd.get_names("selections"):
- cmd.zoom('%s or AllBSRes' % self.ligname, 3)
+ cmd.turn(
+ "x", 110
+ ) # If the ligand is aligned with the longest axis, aromatic rings are hidden
+ if "AllBSRes" in cmd.get_names("selections"):
+ cmd.zoom("%s or AllBSRes" % self.ligname, 3)
else:
if self.object_exists(self.ligname):
cmd.zoom(self.ligname, 3)
@@ -320,8 +429,10 @@ class PyMOLVisualizer:
def save_session(self, outfolder, override=None):
"""Saves a PyMOL session file."""
- filename = '%s_%s' % (self.protname.upper(), "_".join(
- [self.hetid, self.plcomplex.chain, self.plcomplex.position]))
+ filename = "%s_%s" % (
+ self.protname.upper(),
+ "_".join([self.hetid, self.plcomplex.chain, self.plcomplex.position]),
+ )
if override is not None:
filename = override
cmd.save("/".join([outfolder, "%s.pse" % filename]))
@@ -331,15 +442,15 @@ class PyMOLVisualizer:
Use this function in case neither cmd.ray() or cmd.png() work.
"""
sys.stdout = sys.__stdout__
- cmd.feedback('disable', 'movie', 'everything')
+ cmd.feedback("disable", "movie", "everything")
cmd.viewport(width, height)
- cmd.zoom('visible', 1.5) # Adapt the zoom to the viewport
- cmd.set('ray_trace_frames', 1) # Frames are raytraced before saving an image.
+ cmd.zoom("visible", 1.5) # Adapt the zoom to the viewport
+ cmd.set("ray_trace_frames", 1) # Frames are raytraced before saving an image.
cmd.mpng(filepath, 1, 1) # Use batch png mode with 1 frame only
cmd.mplay() # cmd.mpng needs the animation to 'run'
cmd.refresh()
- originalfile = "".join([filepath, '0001.png'])
- newfile = "".join([filepath, '.png'])
+ originalfile = "".join([filepath, "0001.png"])
+ newfile = "".join([filepath, ".png"])
#################################################
# Wait for file for max. 1 second and rename it #
@@ -349,29 +460,56 @@ class PyMOLVisualizer:
while not os.path.isfile(originalfile) and attempts <= 10:
sleep(0.1)
attempts += 1
- if os.name == 'nt': # In Windows, make sure there is no file of the same name, cannot be overwritten as in Unix
+ if (
+ os.name == "nt"
+ ): # In Windows, make sure there is no file of the same name, cannot be overwritten as in Unix
if os.path.isfile(newfile):
os.remove(newfile)
os.rename(originalfile, newfile) # Remove frame number in filename
# Check if imagemagick is available and crop + resize the images
- if subprocess.call("type convert", shell=True, stdout=subprocess.PIPE, stderr=subprocess.PIPE) == 0:
+ if (
+ subprocess.call(
+ "type convert",
+ shell=True,
+ stdout=subprocess.PIPE,
+ stderr=subprocess.PIPE,
+ )
+ == 0
+ ):
attempts, ecode = 0, 1
# Check if file is truncated and wait if that's the case
while ecode != 0 and attempts <= 10:
- ecode = subprocess.call(['convert', newfile, '/dev/null'], stdout=open('/dev/null', 'w'),
- stderr=subprocess.STDOUT)
+ ecode = subprocess.call(
+ ["convert", newfile, "/dev/null"],
+ stdout=open("/dev/null", "w"),
+ stderr=subprocess.STDOUT,
+ )
sleep(0.1)
attempts += 1
- trim = 'convert -trim ' + newfile + ' -bordercolor White -border 20x20 ' + newfile + ';' # Trim the image
+ trim = (
+ "convert -trim "
+ + newfile
+ + " -bordercolor White -border 20x20 "
+ + newfile
+ + ";"
+ ) # Trim the image
os.system(trim)
- getwidth = 'w=`convert ' + newfile + ' -ping -format "%w" info:`;' # Get the width of the new image
- getheight = 'h=`convert ' + newfile + ' -ping -format "%h" info:`;' # Get the hight of the new image
+ getwidth = (
+ "w=`convert " + newfile + ' -ping -format "%w" info:`;'
+ ) # Get the width of the new image
+ getheight = (
+ "h=`convert " + newfile + ' -ping -format "%h" info:`;'
+ ) # Get the hight of the new image
newres = 'if [ "$w" -gt "$h" ]; then newr="${w%.*}x$w"; else newr="${h%.*}x$h"; fi;' # Set quadratic ratio
- quadratic = 'convert ' + newfile + ' -gravity center -extent "$newr" ' + newfile # Fill with whitespace
+ quadratic = (
+ "convert " + newfile + ' -gravity center -extent "$newr" ' + newfile
+ ) # Fill with whitespace
os.system(getwidth + getheight + newres + quadratic)
else:
- sys.stderr.write('Imagemagick not available. Images will not be resized or cropped.')
+ sys.stderr.write(
+ "Imagemagick not available. Images will not be resized or cropped."
+ )
def save_picture(self, outfolder, filename):
"""Saves a picture"""
@@ -380,26 +518,26 @@ class PyMOLVisualizer:
def set_fancy_ray(self):
"""Give the molecule a flat, modern look."""
- cmd.set('light_count', 6)
- cmd.set('spec_count', 1.5)
- cmd.set('shininess', 4)
- cmd.set('specular', 0.3)
- cmd.set('reflect', 1.6)
- cmd.set('ambient', 0)
- cmd.set('direct', 0)
- cmd.set('ray_shadow', 0) # Gives the molecules a flat, modern look
- cmd.set('ambient_occlusion_mode', 1)
- cmd.set('ray_opaque_background', 0) # Transparent background
+ cmd.set("light_count", 6)
+ cmd.set("spec_count", 1.5)
+ cmd.set("shininess", 4)
+ cmd.set("specular", 0.3)
+ cmd.set("reflect", 1.6)
+ cmd.set("ambient", 0)
+ cmd.set("direct", 0)
+ cmd.set("ray_shadow", 0) # Gives the molecules a flat, modern look
+ cmd.set("ambient_occlusion_mode", 1)
+ cmd.set("ray_opaque_background", 0) # Transparent background
def adapt_for_peptides(self):
"""Adapt visualization for peptide ligands and interchain contacts"""
- cmd.hide('sticks', self.ligname)
- cmd.set('cartoon_color', 'lightorange', self.ligname)
- cmd.show('cartoon', self.ligname)
- cmd.show('sticks', "byres *-L")
+ cmd.hide("sticks", self.ligname)
+ cmd.set("cartoon_color", "lightorange", self.ligname)
+ cmd.show("cartoon", self.ligname)
+ cmd.show("sticks", "byres *-L")
cmd.util.cnc(self.ligname)
- cmd.remove('%sCartoon and chain %s' % (self.protname, self.plcomplex.chain))
- cmd.set('cartoon_side_chain_helper', 0)
+ cmd.remove("%sCartoon and chain %s" % (self.protname, self.plcomplex.chain))
+ cmd.set("cartoon_side_chain_helper", 0)
def adapt_for_intra(self):
"""Adapt visualization for intra-protein interactions"""
@@ -408,43 +546,55 @@ class PyMOLVisualizer:
"""Refinements for the visualization"""
# Show sticks for all residues interacing with the ligand
- cmd.select('AllBSRes', 'byres (Hydrophobic-P or HBondDonor-P or HBondAccept-P or PosCharge-P or NegCharge-P or '
- 'StackRings-P or PiCatRing-P or HalogenAcc or Metal-P)')
- cmd.show('sticks', 'AllBSRes')
+ cmd.select(
+ "AllBSRes",
+ "byres (Hydrophobic-P or HBondDonor-P or HBondAccept-P or PosCharge-P or NegCharge-P or "
+ "StackRings-P or PiCatRing-P or HalogenAcc or Metal-P)",
+ )
+ cmd.show("sticks", "AllBSRes")
# Show spheres for the ring centroids
- cmd.hide('everything', 'centroids*')
- cmd.show('nb_spheres', 'centroids*')
+ cmd.hide("everything", "centroids*")
+ cmd.show("nb_spheres", "centroids*")
# Show spheres for centers of charge
- if self.object_exists('Chargecenter-P') or self.object_exists('Chargecenter-L'):
- cmd.hide('nonbonded', 'chargecenter*')
- cmd.show('spheres', 'chargecenter*')
- cmd.set('sphere_scale', 0.4, 'chargecenter*')
- cmd.color('yellow', 'chargecenter*')
+ if self.object_exists("Chargecenter-P") or self.object_exists("Chargecenter-L"):
+ cmd.hide("nonbonded", "chargecenter*")
+ cmd.show("spheres", "chargecenter*")
+ cmd.set("sphere_scale", 0.4, "chargecenter*")
+ cmd.color("yellow", "chargecenter*")
- cmd.set('valence', 1) # Show bond valency (e.g. double bonds)
+ cmd.set("valence", 1) # Show bond valency (e.g. double bonds)
# Optional cartoon representation of the protein
- cmd.copy('%sCartoon' % self.protname, self.protname)
- cmd.show('cartoon', '%sCartoon' % self.protname)
- cmd.show('sticks', '%sCartoon' % self.protname)
- cmd.set('stick_transparency', 1, '%sCartoon' % self.protname)
+ cmd.copy("%sCartoon" % self.protname, self.protname)
+ cmd.show("cartoon", "%sCartoon" % self.protname)
+ cmd.show("sticks", "%sCartoon" % self.protname)
+ cmd.set("stick_transparency", 1, "%sCartoon" % self.protname)
# Resize water molecules. Sometimes they are not heteroatoms HOH, but part of the protein
- cmd.set('sphere_scale', 0.2, 'resn HOH or Water') # Needs to be done here because of the copy made
- cmd.set('sphere_transparency', 0.4, '!(resn HOH or Water)')
-
- if 'Centroids*' in cmd.get_names("selections"):
- cmd.color('grey80', 'Centroids*')
- cmd.hide('spheres', '%sCartoon' % self.protname)
- cmd.hide('cartoon', '%sCartoon and resn DA+DG+DC+DU+DT+A+G+C+U+T' % self.protname) # Hide DNA/RNA Cartoon
- if self.ligname == 'SF4': # Special case for iron-sulfur clusters, can't be visualized with sticks
- cmd.show('spheres', '%s' % self.ligname)
-
- cmd.hide('everything', 'resn HOH &!Water') # Hide all non-interacting water molecules
- cmd.hide('sticks', '%s and !%s and !AllBSRes' %
- (self.protname, self.ligname)) # Hide all non-interacting residues
-
- if self.ligandtype in ['PEPTIDE', 'INTRA']:
+ cmd.set(
+ "sphere_scale", 0.2, "resn HOH or Water"
+ ) # Needs to be done here because of the copy made
+ cmd.set("sphere_transparency", 0.4, "!(resn HOH or Water)")
+
+ if "Centroids*" in cmd.get_names("selections"):
+ cmd.color("grey80", "Centroids*")
+ cmd.hide("spheres", "%sCartoon" % self.protname)
+ cmd.hide(
+ "cartoon", "%sCartoon and resn DA+DG+DC+DU+DT+A+G+C+U+T" % self.protname
+ ) # Hide DNA/RNA Cartoon
+ if (
+ self.ligname == "SF4"
+ ): # Special case for iron-sulfur clusters, can't be visualized with sticks
+ cmd.show("spheres", "%s" % self.ligname)
+
+ cmd.hide(
+ "everything", "resn HOH &!Water"
+ ) # Hide all non-interacting water molecules
+ cmd.hide(
+ "sticks", "%s and !%s and !AllBSRes" % (self.protname, self.ligname)
+ ) # Hide all non-interacting residues
+
+ if self.ligandtype in ["PEPTIDE", "INTRA"]:
self.adapt_for_peptides()
- if self.ligandtype == 'INTRA':
+ if self.ligandtype == "INTRA":
self.adapt_for_intra()
diff --git a/plip/visualization/visualize.py b/plip/visualization/visualize.py
index 4cd7a14..a551798 100644
--- a/plip/visualization/visualize.py
+++ b/plip/visualization/visualize.py
@@ -20,54 +20,63 @@ def visualize_in_pymol(plcomplex):
lig_members = plcomplex.lig_members
chain = plcomplex.chain
if config.PEPTIDES:
- vis.ligname = 'PeptideChain%s' % plcomplex.chain
+ vis.ligname = "PeptideChain%s" % plcomplex.chain
if config.INTRA is not None:
- vis.ligname = 'Intra%s' % plcomplex.chain
+ vis.ligname = "Intra%s" % plcomplex.chain
ligname = vis.ligname
hetid = plcomplex.hetid
metal_ids = plcomplex.metal_ids
- metal_ids_str = '+'.join([str(i) for i in metal_ids])
+ metal_ids_str = "+".join([str(i) for i in metal_ids])
########################
# Basic visualizations #
########################
- start_pymol(run=True, options='-pcq', quiet=not config.VERBOSE and not config.SILENT)
+ start_pymol(
+ run=True, options="-pcq", quiet=not config.VERBOSE and not config.SILENT
+ )
vis.set_initial_representations()
cmd.load(plcomplex.sourcefile)
- current_name = cmd.get_object_list(selection='(all)')[0]
- logger.debug(f'setting current_name to {current_name} and pdbid to {pdbid}')
+ current_name = cmd.get_object_list(selection="(all)")[0]
+ logger.debug(f"setting current_name to {current_name} and pdbid to {pdbid}")
cmd.set_name(current_name, pdbid)
- cmd.hide('everything', 'all')
+ cmd.hide("everything", "all")
if config.PEPTIDES:
- cmd.select(ligname, 'chain %s and not resn HOH' % plcomplex.chain)
+ cmd.select(ligname, "chain %s and not resn HOH" % plcomplex.chain)
else:
- cmd.select(ligname, 'resn %s and chain %s and resi %s*' % (hetid, chain, plcomplex.position))
- logger.debug(f'selecting ligand for PDBID {pdbid} and ligand name {ligname}')
- logger.debug(f'resn {hetid} and chain {chain} and resi {plcomplex.position}')
+ cmd.select(
+ ligname,
+ "resn %s and chain %s and resi %s*" % (hetid, chain, plcomplex.position),
+ )
+ logger.debug(f"selecting ligand for PDBID {pdbid} and ligand name {ligname}")
+ logger.debug(f"resn {hetid} and chain {chain} and resi {plcomplex.position}")
# Visualize and color metal ions if there are any
if not len(metal_ids) == 0:
vis.select_by_ids(ligname, metal_ids, selection_exists=True)
- cmd.show('spheres', 'id %s and %s' % (metal_ids_str, pdbid))
+ cmd.show("spheres", "id %s and %s" % (metal_ids_str, pdbid))
# Additionally, select all members of composite ligands
if len(lig_members) > 1:
for member in lig_members:
resid, chain, resnr = member[0], member[1], str(member[2])
- cmd.select(ligname, '%s or (resn %s and chain %s and resi %s)' % (ligname, resid, chain, resnr))
-
- cmd.show('sticks', ligname)
- cmd.color('myblue')
- cmd.color('myorange', ligname)
- cmd.util.cnc('all')
+ cmd.select(
+ ligname,
+ "%s or (resn %s and chain %s and resi %s)"
+ % (ligname, resid, chain, resnr),
+ )
+
+ cmd.show("sticks", ligname)
+ cmd.color("myblue")
+ cmd.color("myorange", ligname)
+ cmd.util.cnc("all")
if not len(metal_ids) == 0:
- cmd.color('hotpink', 'id %s' % metal_ids_str)
- cmd.hide('sticks', 'id %s' % metal_ids_str)
- cmd.set('sphere_scale', 0.3, ligname)
+ cmd.color("hotpink", "id %s" % metal_ids_str)
+ cmd.hide("sticks", "id %s" % metal_ids_str)
+ cmd.set("sphere_scale", 0.3, ligname)
cmd.deselect()
vis.make_initial_selections()
@@ -91,9 +100,9 @@ def visualize_in_pymol(plcomplex):
vis.additional_cleanup()
if config.DNARECEPTOR:
# Rename Cartoon selection to Line selection and change repr.
- cmd.set_name('%sCartoon' % plcomplex.pdbid, '%sLines' % plcomplex.pdbid)
- cmd.hide('cartoon', '%sLines' % plcomplex.pdbid)
- cmd.show('lines', '%sLines' % plcomplex.pdbid)
+ cmd.set_name("%sCartoon" % plcomplex.pdbid, "%sLines" % plcomplex.pdbid)
+ cmd.hide("cartoon", "%sLines" % plcomplex.pdbid)
+ cmd.show("lines", "%sLines" % plcomplex.pdbid)
if config.PEPTIDES:
filename = "%s_PeptideChain%s" % (pdbid.upper(), plcomplex.chain)
@@ -104,7 +113,10 @@ def visualize_in_pymol(plcomplex):
if config.PYMOL:
vis.save_session(config.OUTPATH, override=filename)
else:
- filename = '%s_%s' % (pdbid.upper(), "_".join([hetid, plcomplex.chain, plcomplex.position]))
+ filename = "%s_%s" % (
+ pdbid.upper(),
+ "_".join([hetid, plcomplex.chain, plcomplex.position]),
+ )
if config.PYMOL:
vis.save_session(config.OUTPATH)
if config.PICS:
diff --git a/scripts/get-best.py b/scripts/get-best.py
index a10c2d2..c0185e4 100644
--- a/scripts/get-best.py
+++ b/scripts/get-best.py
@@ -11,13 +11,14 @@ version = "1.0"
desc_text = "PyMol Quick Visualtion " + version
parser = argparse.ArgumentParser(description=desc_text)
-parser.add_argument("-p","--protein",help="Path to protein file")
-parser.add_argument("-l","--ligand",help="Path to ligand_out file")
+parser.add_argument("-p", "--protein", help="Path to protein file")
+parser.add_argument("-l", "--ligand", help="Path to ligand_out file")
args = parser.parse_args()
+
def li(s):
- #log.info(s)
+ # log.info(s)
None
@@ -35,10 +36,10 @@ ligand = args.ligand
session = pymol2.PyMOL()
session.start()
cmd = session.cmd
-cmd.load(protein,'pro')
-cmd.load(ligand,'lig')
-cmd.split_states('lig')
+cmd.load(protein, "pro")
+cmd.load(ligand, "lig")
+cmd.split_states("lig")
-#fname = re.sub(r'^.*?/', '', protein.replace(".pdbqt","")) + "-" + re.sub(r'^.*?/', '', ligand.replace(".pdbqt","")) + ".pdb"
+# fname = re.sub(r'^.*?/', '', protein.replace(".pdbqt","")) + "-" + re.sub(r'^.*?/', '', ligand.replace(".pdbqt","")) + ".pdb"
-cmd.save("best.pdb","pro lig_0001")
+cmd.save("best.pdb", "pro lig_0001")
diff --git a/scripts/get_dock_score.py b/scripts/get_dock_score.py
index c8b87d5..1cc0412 100644
--- a/scripts/get_dock_score.py
+++ b/scripts/get_dock_score.py
@@ -3,8 +3,8 @@
import argparse
parser = argparse.ArgumentParser(description="Get Docking Score")
-parser.add_argument("-p","--protein",help="Path to protein file")
-parser.add_argument("-l","--ligand",help="Path to ligand_out file")
+parser.add_argument("-p", "--protein", help="Path to protein file")
+parser.add_argument("-l", "--ligand", help="Path to ligand_out file")
args = parser.parse_args()
@@ -21,7 +21,13 @@ ligand = args.ligand
from os.path import basename
-print("# " + str(basename(protein)).replace(".pdbqt","") + "-" + str(basename(ligand)).replace("_out.pdbqt",""), end="\n\n")
+print(
+ "# "
+ + str(basename(protein)).replace(".pdbqt", "")
+ + "-"
+ + str(basename(ligand)).replace("_out.pdbqt", ""),
+ end="\n\n",
+)
from tabulate import tabulate
@@ -31,7 +37,7 @@ results = []
i = 1
for line in lines:
ta = []
- if line.find('REMARK VINA') == 0 and line.split()[3] != "":
+ if line.find("REMARK VINA") == 0 and line.split()[3] != "":
l = line.split()
ta.append(i)
ta.append(l[3])
@@ -41,6 +47,6 @@ for line in lines:
if ta != []:
results.append(ta)
-print("## Docking Scores",end="\n\n")
-print(tabulate(results,headers=["No.","Affinity","rmsd l.b","rmsd u.b"]))
-print("",end="\n\n")
+print("## Docking Scores", end="\n\n")
+print(tabulate(results, headers=["No.", "Affinity", "rmsd l.b", "rmsd u.b"]))
+print("", end="\n\n")
diff --git a/scripts/makeReport.py b/scripts/makeReport.py
index 79d9c70..fc53381 100644
--- a/scripts/makeReport.py
+++ b/scripts/makeReport.py
@@ -1,8 +1,8 @@
#!/usr/bin/python3
-import argparse
+import argparse
parser = argparse.ArgumentParser(description="Make Report Helper Script")
-parser.add_argument("-i","--input",help="Path to report folder")
+parser.add_argument("-i", "--input", help="Path to report folder")
args = parser.parse_args()
@@ -11,147 +11,160 @@ if args.input == None:
exit(1)
path = args.input
-#path = '/Users/navanchauhan/Desktop/nCOV-19/scripts/pymol/test/'
+# path = '/Users/navanchauhan/Desktop/nCOV-19/scripts/pymol/test/'
import untangle
from tabulate import tabulate
-#import sys
-#report = path + "report.md"
-#sys.stdout = open(report, 'w')
+# import sys
+# report = path + "report.md"
+# sys.stdout = open(report, 'w')
from os import listdir
from os.path import isfile, join
+
onlyfiles = [f for f in listdir(path) if isfile(join(path, f))]
image = ""
for x in onlyfiles:
- if '.png' in x and 'UNL' in x:
+ if ".png" in x and "UNL" in x:
image = x
import os
-fname = os.path.join(path,'report.xml')
+
+fname = os.path.join(path, "report.xml")
doc = untangle.parse(fname)
-hi, hb, wb, sb, ps, pc, hab, mc = 0,0,0,0,0,0,0,0
+hi, hb, wb, sb, ps, pc, hab, mc = 0, 0, 0, 0, 0, 0, 0, 0
indexForUNL = 0
for x in doc.report.bindingsite:
- if x.identifiers.longname.cdata == 'UNL':
+ if x.identifiers.longname.cdata == "UNL":
break
else:
indexForUNL += 1
name = doc.report.pdbid.cdata
-#print(("# " + (name.replace("_"," ")).replace("PROTEIN","")), end="\n\n")
+# print(("# " + (name.replace("_"," ")).replace("PROTEIN","")), end="\n\n")
-print("## Visualisation", end="\n\n")
-print(f'![]({image})', end="\n\n")
+print("## Visualisation", end="\n\n")
+print(f"![]({image})", end="\n\n")
print("## Interactions", end="\n\n")
fallback = 0
try:
- if doc.report.bindingsite[indexForUNL].interactions.hydrophobic_interactions.cdata == '':
+ if (
+ doc.report.bindingsite[indexForUNL].interactions.hydrophobic_interactions.cdata
+ == ""
+ ):
print("No Hydrophobic Interactions Found", end="\n\n")
else:
print("**Hydrophobic Interactions Found**", end="\n\n")
hi = 1
except AttributeError:
- fallback=1
+ fallback = 1
-if fallback==0:
- if doc.report.bindingsite[indexForUNL].interactions.hydrophobic_interactions.cdata == '':
+if fallback == 0:
+ if (
+ doc.report.bindingsite[indexForUNL].interactions.hydrophobic_interactions.cdata
+ == ""
+ ):
print("No Hydrophobic Interactions Found", end="\n\n")
else:
print("**Hydrophobic Interactions Found**", end="\n\n")
hi = 1
- if doc.report.bindingsite[indexForUNL].interactions.hydrogen_bonds.cdata == '':
+ if doc.report.bindingsite[indexForUNL].interactions.hydrogen_bonds.cdata == "":
print("No Hydrogen Bonds Found", end="\n\n")
else:
print("**Hydrogen Bonds Found**", end="\n\n")
hb = 1
- if doc.report.bindingsite[indexForUNL].interactions.water_bridges.cdata == '':
+ if doc.report.bindingsite[indexForUNL].interactions.water_bridges.cdata == "":
print("No Water Bridges Found", end="\n\n")
else:
print("**Water Bridges Found**", end="\n\n")
wb = 1
- if doc.report.bindingsite[indexForUNL].interactions.salt_bridges.cdata == '':
+ if doc.report.bindingsite[indexForUNL].interactions.salt_bridges.cdata == "":
print("No Salt Bridges Found", end="\n\n")
else:
print("**Salt Bridges Found**", end="\n\n")
sb = 1
- if doc.report.bindingsite[indexForUNL].interactions.pi_stacks.cdata == '':
+ if doc.report.bindingsite[indexForUNL].interactions.pi_stacks.cdata == "":
print("No Pi Stacks Found", end="\n\n")
else:
print("**Pi Stacks Found**", end="\n\n")
ps = 1
- if doc.report.bindingsite[indexForUNL].interactions.pi_cation_interactions.cdata == '':
+ if (
+ doc.report.bindingsite[indexForUNL].interactions.pi_cation_interactions.cdata
+ == ""
+ ):
print("No Pi Cation Interactions Found", end="\n\n")
else:
print("**Pi Cation Interactions Found**", end="\n\n")
pc = 1
- if doc.report.bindingsite[indexForUNL].interactions.halogen_bonds.cdata == '':
+ if doc.report.bindingsite[indexForUNL].interactions.halogen_bonds.cdata == "":
print("No Halogen Bonds Found", end="\n\n")
else:
print("** Halogen Bonds Found**", end="\n\n")
hab = 1
- if doc.report.bindingsite[indexForUNL].interactions.metal_complexes.cdata == '':
- print("No Metal Complexes Found", end="\n\n")
+ if doc.report.bindingsite[indexForUNL].interactions.metal_complexes.cdata == "":
+ print("No Metal Complexes Found", end="\n\n")
else:
print("**Metal Complexes Found**", end="\n\n")
mc = 1
if fallback == 1:
- if doc.report.bindingsite.interactions.hydrophobic_interactions.cdata == '':
+ if doc.report.bindingsite.interactions.hydrophobic_interactions.cdata == "":
print("No Hydrophobic Interactions Found", end="\n\n")
else:
print("**Hydrophobic Interactions Found**", end="\n\n")
hi = 1
- if doc.report.bindingsite.interactions.hydrogen_bonds.cdata == '':
+ if doc.report.bindingsite.interactions.hydrogen_bonds.cdata == "":
print("No Hydrogen Bonds Found", end="\n\n")
else:
print("**Hydrogen Bonds Found**", end="\n\n")
hb = 1
- if doc.report.bindingsite.interactions.water_bridges.cdata == '':
+ if doc.report.bindingsite.interactions.water_bridges.cdata == "":
print("No Water Bridges Found", end="\n\n")
else:
print("**Water Bridges Found**", end="\n\n")
wb = 1
- if doc.report.bindingsite.interactions.salt_bridges.cdata == '':
+ if doc.report.bindingsite.interactions.salt_bridges.cdata == "":
print("No Salt Bridges Found", end="\n\n")
else:
print("**Salt Bridges Found**", end="\n\n")
sb = 1
- if doc.report.bindingsite.interactions.pi_stacks.cdata == '':
+ if doc.report.bindingsite.interactions.pi_stacks.cdata == "":
print("No Pi Stacks Found", end="\n\n")
else:
print("**Pi Stacks Found**", end="\n\n")
ps = 1
- if doc.report.bindingsite.interactions.pi_cation_interactions.cdata == '':
+ if doc.report.bindingsite.interactions.pi_cation_interactions.cdata == "":
print("No Pi Cation Interactions Found", end="\n\n")
else:
print("**Pi Cation Interactions Found**", end="\n\n")
pc = 1
- if doc.report.bindingsite.interactions.halogen_bonds.cdata == '':
+ if doc.report.bindingsite.interactions.halogen_bonds.cdata == "":
print("No Halogen Bonds Found", end="\n\n")
else:
print("** Halogen Bonds Found**", end="\n\n")
hab = 1
- if doc.report.bindingsite.interactions.metal_complexes.cdata == '':
- print("No Metal Complexes Found", end="\n\n")
+ if doc.report.bindingsite.interactions.metal_complexes.cdata == "":
+ print("No Metal Complexes Found", end="\n\n")
else:
print("**Metal Complexes Found**", end="\n\n")
mc = 1
if fallback == 0:
if hi == 1:
- print("## Hydrophobic Interactions",end="\n\n")
+ print("## Hydrophobic Interactions", end="\n\n")
tableBody = []
- tableHeaders = ['No.','Res.','AA','Dist','Ligand Atom','Proton Atom']
+ tableHeaders = ["No.", "Res.", "AA", "Dist", "Ligand Atom", "Proton Atom"]
i = 1
- for x in doc.report.bindingsite[indexForUNL].interactions.hydrophobic_interactions.hydrophobic_interaction:
+ for x in doc.report.bindingsite[
+ indexForUNL
+ ].interactions.hydrophobic_interactions.hydrophobic_interaction:
l = []
l.append(i)
l.append(x.resnr.cdata)
@@ -164,11 +177,24 @@ if fallback == 0:
print(tabulate(tableBody, headers=tableHeaders), end="\n\n")
if hb == 1:
- print("## Hydrogen Bonds",end="\n\n")
+ print("## Hydrogen Bonds", end="\n\n")
tableBody = []
- tableHeaders = ['No.','Res.','AA','Dist H-A','Dist D-A','Don Angle','Protisdon?','Sidechain?','D. Atom','A. Atom']
+ tableHeaders = [
+ "No.",
+ "Res.",
+ "AA",
+ "Dist H-A",
+ "Dist D-A",
+ "Don Angle",
+ "Protisdon?",
+ "Sidechain?",
+ "D. Atom",
+ "A. Atom",
+ ]
i = 1
- for x in doc.report.bindingsite[indexForUNL].interactions.hydrogen_bonds.hydrogen_bond:
+ for x in doc.report.bindingsite[
+ indexForUNL
+ ].interactions.hydrogen_bonds.hydrogen_bond:
l = []
l.append(i)
l.append(x.resnr.cdata)
@@ -182,15 +208,25 @@ if fallback == 0:
l.append((x.acceptoridx.cdata + "[" + x.acceptortype.cdata + "]"))
i += 1
tableBody.append(l)
- #print(i, x.resnr.cdata, x.restype.cdata, x.dist_h_a.cdata, x.dist_d_a.cdata, x.don_angle.cdata, x.protisdon.cdata, x.sidechain.cdata, (x.donoridx.cdata + "[" + x.donortype.cdata + "]"), (x.acceptoridx.cdata + "[" + x.acceptortype.cdata + "]"))
+ # print(i, x.resnr.cdata, x.restype.cdata, x.dist_h_a.cdata, x.dist_d_a.cdata, x.don_angle.cdata, x.protisdon.cdata, x.sidechain.cdata, (x.donoridx.cdata + "[" + x.donortype.cdata + "]"), (x.acceptoridx.cdata + "[" + x.acceptortype.cdata + "]"))
print(tabulate(tableBody, headers=tableHeaders), end="\n\n")
if sb == 1:
- print("## Salt Bridges",end="\n\n")
+ print("## Salt Bridges", end="\n\n")
tableBody = []
- tableHeaders = ['Index','Residue','AA','Distance','Protein positive?','Ligand Group','Ligand Atoms']
+ tableHeaders = [
+ "Index",
+ "Residue",
+ "AA",
+ "Distance",
+ "Protein positive?",
+ "Ligand Group",
+ "Ligand Atoms",
+ ]
i = 1
- for x in doc.report.bindingsite[indexForUNL].interactions.salt_bridges.salt_bridge:
+ for x in doc.report.bindingsite[
+ indexForUNL
+ ].interactions.salt_bridges.salt_bridge:
l = []
l.append(i)
l.append(x.resnr.cdata)
@@ -206,12 +242,14 @@ if fallback == 0:
tableBody.append(l)
print(tabulate(tableBody, headers=tableHeaders), end="\n\n")
- if pc==1:
- print("## Pi Cation Interactions",end="\n\n")
+ if pc == 1:
+ print("## Pi Cation Interactions", end="\n\n")
tableBody = []
- tableHeaders = ['Index','Residue','AA','Distance','Prot charged?','Atoms']
+ tableHeaders = ["Index", "Residue", "AA", "Distance", "Prot charged?", "Atoms"]
i = 1
- for x in doc.report.bindingsite[indexForUNL].interactions.pi_cation_interactions.pi_cation_interaction:
+ for x in doc.report.bindingsite[
+ indexForUNL
+ ].interactions.pi_cation_interactions.pi_cation_interaction:
l = []
l.append(i)
l.append(x.resnr.cdata)
@@ -228,11 +266,15 @@ if fallback == 0:
print(tabulate(tableBody, headers=tableHeaders), end="\n\n")
elif fallback == 1:
if hi == 1:
- print("## Hydrophobic Interactions",end="\n\n")
+ print("## Hydrophobic Interactions", end="\n\n")
tableBody = []
- tableHeaders = ['No.','Res.','AA','Dist','Ligand Atom','Proton Atom']
+ tableHeaders = ["No.", "Res.", "AA", "Dist", "Ligand Atom", "Proton Atom"]
i = 1
- for x in doc.report.bindingsite.interactions.hydrophobic_interactions.hydrophobic_interaction:
+ for (
+ x
+ ) in (
+ doc.report.bindingsite.interactions.hydrophobic_interactions.hydrophobic_interaction
+ ):
l = []
l.append(i)
l.append(x.resnr.cdata)
@@ -245,9 +287,20 @@ elif fallback == 1:
print(tabulate(tableBody, headers=tableHeaders), end="\n\n")
if hb == 1:
- print("## Hydrogen Bonds",end="\n\n")
+ print("## Hydrogen Bonds", end="\n\n")
tableBody = []
- tableHeaders = ['No.','Res.','AA','Dist H-A','Dist D-A','Don Angle','Protisdon?','Sidechain?','D. Atom','A. Atom']
+ tableHeaders = [
+ "No.",
+ "Res.",
+ "AA",
+ "Dist H-A",
+ "Dist D-A",
+ "Don Angle",
+ "Protisdon?",
+ "Sidechain?",
+ "D. Atom",
+ "A. Atom",
+ ]
i = 1
for x in doc.report.bindingsite.interactions.hydrogen_bonds.hydrogen_bond:
l = []
@@ -263,13 +316,21 @@ elif fallback == 1:
l.append((x.acceptoridx.cdata + "[" + x.acceptortype.cdata + "]"))
i += 1
tableBody.append(l)
- #print(i, x.resnr.cdata, x.restype.cdata, x.dist_h_a.cdata, x.dist_d_a.cdata, x.don_angle.cdata, x.protisdon.cdata, x.sidechain.cdata, (x.donoridx.cdata + "[" + x.donortype.cdata + "]"), (x.acceptoridx.cdata + "[" + x.acceptortype.cdata + "]"))
+ # print(i, x.resnr.cdata, x.restype.cdata, x.dist_h_a.cdata, x.dist_d_a.cdata, x.don_angle.cdata, x.protisdon.cdata, x.sidechain.cdata, (x.donoridx.cdata + "[" + x.donortype.cdata + "]"), (x.acceptoridx.cdata + "[" + x.acceptortype.cdata + "]"))
print(tabulate(tableBody, headers=tableHeaders), end="\n\n")
if sb == 1:
- print("## Salt Bridges",end="\n\n")
+ print("## Salt Bridges", end="\n\n")
tableBody = []
- tableHeaders = ['Index','Residue','AA','Distance','Protein positive?','Ligand Group','Ligand Atoms']
+ tableHeaders = [
+ "Index",
+ "Residue",
+ "AA",
+ "Distance",
+ "Protein positive?",
+ "Ligand Group",
+ "Ligand Atoms",
+ ]
i = 1
for x in doc.report.bindingsite.interactions.salt_bridges.salt_bridge:
l = []
@@ -287,12 +348,16 @@ elif fallback == 1:
tableBody.append(l)
print(tabulate(tableBody, headers=tableHeaders), end="\n\n")
- if pc==1:
- print("## Pi Cation Interactions",end="\n\n")
+ if pc == 1:
+ print("## Pi Cation Interactions", end="\n\n")
tableBody = []
- tableHeaders = ['Index','Residue','AA','Distance','Prot charged?','Atoms']
+ tableHeaders = ["Index", "Residue", "AA", "Distance", "Prot charged?", "Atoms"]
i = 1
- for x in doc.report.bindingsite.interactions.pi_cation_interactions.pi_cation_interaction:
+ for (
+ x
+ ) in (
+ doc.report.bindingsite.interactions.pi_cation_interactions.pi_cation_interaction
+ ):
l = []
l.append(i)
l.append(x.resnr.cdata)
@@ -310,7 +375,7 @@ elif fallback == 1:
print("## Figures", end="\n\n")
-print(f'![](output-back.png)', end="\n\n")
-print(f'![](output-front.png)', end="\n\n")
-print(f'![](closeup-back.png)', end="\n\n")
-print(f'![](closeup-front.png)', end="\n\n")
+print(f"![](output-back.png)", end="\n\n")
+print(f"![](output-front.png)", end="\n\n")
+print(f"![](closeup-back.png)", end="\n\n")
+print(f"![](closeup-front.png)", end="\n\n")
diff --git a/scripts/quick-ligand-protein.py b/scripts/quick-ligand-protein.py
index faff403..e211844 100644
--- a/scripts/quick-ligand-protein.py
+++ b/scripts/quick-ligand-protein.py
@@ -1,12 +1,14 @@
#!/usr/bin/python3
import argparse
-#import logzero
-#import logging
-#from logzero import logger as log
+
+# import logzero
+# import logging
+# from logzero import logger as log
import pymol2
import time
import os
+
print(os.getcwd())
#################
@@ -17,7 +19,7 @@ startTime = time.time()
version = "1.0"
desc_text = "PyMol Quick Visualtion " + version
ligandColor = "red"
-#logzero.loglevel(logging.INFO)
+# logzero.loglevel(logging.INFO)
height = 1000
width = 800
dpi = 300
@@ -28,9 +30,9 @@ m1 = "target"
m2 = "ligand"
parser = argparse.ArgumentParser(description=desc_text)
-parser.add_argument("-p","--protein",help="Path to protein file")
-parser.add_argument("-l","--ligand",help="Path to ligand_out file")
-parser.add_argument("-c","--color",help="Color for ligand in visualisation")
+parser.add_argument("-p", "--protein", help="Path to protein file")
+parser.add_argument("-l", "--ligand", help="Path to ligand_out file")
+parser.add_argument("-c", "--color", help="Color for ligand in visualisation")
args = parser.parse_args()
@@ -47,38 +49,55 @@ protein = args.protein
print("Protein: ", protein)
ligand = args.ligand
+
def loadMol(filename, name):
print("Loading " + filename + " as " + name)
- cmd.load(filename,name)
+ cmd.load(filename, name)
+
+
def changeColor(name, colorName):
print("Changed " + name + "'s color to " + colorName)
- cmd.color(colorName,name)
+ cmd.color(colorName, name)
+
+
def orientEtZoom():
cmd.orient()
cmd.zoom()
+
+
def showSurface(name):
- cmd.show("surface",name)
+ cmd.show("surface", name)
+
+
def surfaceTransparency(amount):
- print("Changed surface transparency to " + str(amount*100) + "%")
- cmd.set("transparency",amount)
-def generatePNG(filename,height=height,width=width,dpi=dpi,ray=ray):
+ print("Changed surface transparency to " + str(amount * 100) + "%")
+ cmd.set("transparency", amount)
+
+
+def generatePNG(filename, height=height, width=width, dpi=dpi, ray=ray):
print("Generating " + filename + ".png")
- cmd.png(filename,height,width,dpi=dpi,ray=ray)
+ cmd.png(filename, height, width, dpi=dpi, ray=ray)
+
+
def flipHorizontal():
- cmd.rotate("y",180)
+ cmd.rotate("y", 180)
+
+
def zoomTo(name):
cmd.zoom(name)
+
+
def generatePictures():
- generatePNG('output-front')
+ generatePNG("output-front")
flipHorizontal()
- generatePNG('output-back')
+ generatePNG("output-back")
zoomTo(m2)
- generatePNG('closeup-back')
+ generatePNG("closeup-back")
orientEtZoom()
flipHorizontal()
zoomTo(m2)
- generatePNG('closeup-front')
-
+ generatePNG("closeup-front")
+
print("Initialising PyMol")
session = pymol2.PyMOL()
@@ -86,10 +105,10 @@ print("Starting PyMol Session")
session.start()
cmd = session.cmd
-loadMol(protein,m1)
-loadMol(ligand,m2)
-changeColor(m1,"grey60")
-changeColor(m2,ligandColor)
+loadMol(protein, m1)
+loadMol(ligand, m2)
+changeColor(m1, "grey60")
+changeColor(m2, ligandColor)
orientEtZoom()
showSurface(m1)
surfaceTransparency(0.6)
@@ -97,4 +116,4 @@ surfaceTransparency(0.6)
generatePictures()
endTime = time.time()
-print("Finished Execution in " + str(round((endTime - startTime),2)) + " seconds.")
+print("Finished Execution in " + str(round((endTime - startTime), 2)) + " seconds.")