Exemplo n.º 1
0
def rebuild_c_terminal(complex: oechem.OEGraphMol) -> oechem.OEGraphMol:
    # Delete and rebuild C-terminal residue because Spruce causes issues with this
    # See: 6m2n 6lze
    pred = oechem.OEIsCTerminalAtom()
    for atom in complex.GetAtoms():
        if pred(atom):
            for nbor in atom.GetAtoms():
                if oechem.OEGetPDBAtomIndex(nbor) == oechem.OEPDBAtomName_O:
                    complex.DeleteAtom(nbor)
    return complex
Exemplo n.º 2
0
def _OEFixConnectionNH(protein):
    """
    Temporary fix, thanks to Jesper!
    """
    for atom in protein.GetAtoms(
            oechem.OEAndAtom(oespruce.OEIsModeledAtom(),
                             oechem.OEIsNitrogen())):
        if oechem.OEGetPDBAtomIndex(atom) == oechem.OEPDBAtomName_N:
            expected_h_count = 1
            if oechem.OEGetResidueIndex(atom) == oechem.OEResidueIndex_PRO:
                expected_h_count = 0
            if atom.GetTotalHCount() != expected_h_count:
                oechem.OESuppressHydrogens(atom)
                atom.SetImplicitHCount(1)
                oechem.OEAddExplicitHydrogens(protein, atom)
                for nbr in atom.GetAtoms(oechem.OEIsHydrogen()):
                    oechem.OESet3DHydrogenGeom(protein, nbr)
Exemplo n.º 3
0
def prepare_receptor(complex_pdb_filename, output_basepath, dimer=False):
    """
    Parameters
    ----------
    complex_pdb_filename : str
        The complex PDB file to read in
    output_basepath : str
        Base path for output
    dimer : bool, optional, default=False
        If True, generate the dimer as the biological unit
    """
    import os
    basepath, filename = os.path.split(complex_pdb_filename)
    prefix, extension = os.path.splitext(filename)
    prefix = os.path.join(output_basepath, prefix)

    # Check if receptor already exists
    receptor_filename = f'{prefix}-receptor.oeb.gz'
    thiolate_receptor_filename = f'{prefix}-receptor-thiolate.oeb.gz'
    if os.path.exists(receptor_filename) and os.path.exists(
            thiolate_receptor_filename):
        return

    # Read in PDB file
    pdbfile_lines = [
        line for line in open(complex_pdb_filename, 'r') if 'UNK' not in line
    ]

    # If monomer is specified, drop crystal symmetry lines
    if not dimer:
        pdbfile_lines = [
            line for line in pdbfile_lines if 'REMARK 350' not in line
        ]

    # Reconstruct PDBFile contents
    pdbfile_contents = ''.join(pdbfile_lines)

    # Read the receptor and identify design units
    from openeye import oespruce, oechem
    from tempfile import NamedTemporaryFile
    with NamedTemporaryFile(delete=False, mode='wt', suffix='.pdb') as pdbfile:
        pdbfile.write(pdbfile_contents)
        pdbfile.close()
        complex = read_pdb_file(pdbfile.name)
        # TODO: Clean up

    #print('Identifying design units...')
    design_units = list(oespruce.OEMakeDesignUnits(complex))
    if len(design_units) == 1:
        design_unit = design_units[0]
    elif len(design_units) > 1:
        #print('More than one design unit found---using first one')
        design_unit = design_units[0]
    elif len(design_units) == 0:
        raise Exception(f' * No design units found for {complex_pdb_filename}')

    # Prepare the receptor
    #print('Preparing receptor...')
    from openeye import oedocking
    protein = oechem.OEGraphMol()
    design_unit.GetProtein(protein)
    ligand = oechem.OEGraphMol()
    design_unit.GetLigand(ligand)

    receptor = oechem.OEGraphMol()
    oedocking.OEMakeReceptor(receptor, protein, ligand)
    oedocking.OEWriteReceptorFile(receptor, receptor_filename)

    with oechem.oemolostream(f'{prefix}-protein.pdb') as ofs:
        oechem.OEWriteMolecule(ofs, protein)
    with oechem.oemolostream(f'{prefix}-ligand.mol2') as ofs:
        oechem.OEWriteMolecule(ofs, ligand)
    with oechem.oemolostream(f'{prefix}-ligand.pdb') as ofs:
        oechem.OEWriteMolecule(ofs, ligand)
    with oechem.oemolostream(f'{prefix}-ligand.sdf') as ofs:
        oechem.OEWriteMolecule(ofs, ligand)

    # Filter out UNK from PDB files (which have covalent adducts)
    pdbfile_lines = [
        line for line in open(f'{prefix}-protein.pdb', 'r')
        if 'UNK' not in line
    ]
    with open(f'{prefix}-protein.pdb', 'wt') as outfile:
        outfile.write(''.join(pdbfile_lines))

    # Adjust protonation state of CYS145 to generate thiolate form
    #print('Deprotonating CYS145...')
    pred = oechem.OEAtomMatchResidue(["CYS:145: :A"])
    for atom in protein.GetAtoms(pred):
        if oechem.OEGetPDBAtomIndex(atom) == oechem.OEPDBAtomName_SG:
            oechem.OESuppressHydrogens(atom)
            atom.SetFormalCharge(-1)
            atom.SetImplicitHCount(0)
    # Adjust protonation states
    #print('Re-optimizing hydrogen positions...')
    place_hydrogens_opts = oechem.OEPlaceHydrogensOptions()
    place_hydrogens_opts.SetBypassPredicate(pred)
    protonate_opts = oespruce.OEProtonateDesignUnitOptions(
        place_hydrogens_opts)
    success = oespruce.OEProtonateDesignUnit(design_unit, protonate_opts)
    design_unit.GetProtein(protein)

    # Old hacky way to adjust protonation states
    #opts = oechem.OEPlaceHydrogensOptions()
    #opts.SetBypassPredicate(pred)
    #describe = oechem.OEPlaceHydrogensDetails()
    #success = oechem.OEPlaceHydrogens(protein, describe, opts)
    #if success:
    #    oechem.OEUpdateDesignUnit(design_unit, protein, oechem.OEDesignUnitComponents_Protein)

    # Write thiolate form of receptor
    receptor = oechem.OEGraphMol()
    oedocking.OEMakeReceptor(receptor, protein, ligand)
    oedocking.OEWriteReceptorFile(receptor, thiolate_receptor_filename)

    with oechem.oemolostream(f'{prefix}-protein-thiolate.pdb') as ofs:
        oechem.OEWriteMolecule(ofs, protein)

    # Filter out UNK from PDB files (which have covalent adducts)
    pdbfile_lines = [
        line for line in open(f'{prefix}-protein-thiolate.pdb', 'r')
        if 'UNK' not in line
    ]
    with open(f'{prefix}-protein-thiolate.pdb', 'wt') as outfile:
        outfile.write(''.join(pdbfile_lines))
def prepare_receptor(complex_pdb_filename,
                     output_basepath,
                     dimer=False,
                     retain_water=False):
    """
    Parameters
    ----------
    complex_pdb_filename : str
        The complex PDB file to read in
    output_basepath : str
        Base path for output
    dimer : bool, optional, default=False
        If True, generate the dimer as the biological unit
    retain_water : bool, optional, default=False
        If True, will retain waters
    """
    # Check whether this is a diamond SARS-CoV-2 Mpro structure or not
    import re
    is_diamond_structure = (re.search('-x\d+_', complex_pdb_filename)
                            is not None)

    import os
    basepath, filename = os.path.split(complex_pdb_filename)
    prefix, extension = os.path.splitext(filename)
    prefix = os.path.join(output_basepath, prefix)

    # Check if receptor already exists
    receptor_filename = f'{prefix}-receptor.oeb.gz'
    thiolate_receptor_filename = f'{prefix}-receptor-thiolate.oeb.gz'
    if os.path.exists(receptor_filename) and os.path.exists(
            thiolate_receptor_filename):
        return

    # Read in PDB file, skipping UNK atoms (left over from processing covalent ligands)
    pdbfile_lines = [
        line for line in open(complex_pdb_filename, 'r') if 'UNK' not in line
    ]

    # Check if biological symmetry header is present
    has_biological_symmetry_header = False
    for line in pdbfile_lines:
        if 'REMARK 350' in line:
            has_biological_symmetry_header = True
            break

    # Prepend REMARK 350 (biological symmetry) header lines for Mpro (from 5RGG) if not present
    if is_diamond_structure and (not has_biological_symmetry_header):
        pdbfile_lines = [
            line + '\n' for line in BIOLOGICAL_SYMMETRY_HEADER.split('\n')
        ] + pdbfile_lines

    # If monomer is specified, drop crystal symmetry lines
    if not dimer:
        pdbfile_lines = [
            line for line in pdbfile_lines if 'REMARK 350' not in line
        ]

    # Filter out waters
    if not retain_water:
        pdbfile_lines = [line for line in pdbfile_lines if 'HOH' not in line]

    # Filter out LINK records to covalent inhibitors so we can model non-covalent complex
    pdbfile_lines = [line for line in pdbfile_lines if 'LINK' not in line]

    # Reconstruct PDBFile contents
    pdbfile_contents = ''.join(pdbfile_lines)

    # Append SEQRES to all structures if they do not have it
    seqres = """\
SEQRES   1 A  306  SER GLY PHE ARG LYS MET ALA PHE PRO SER GLY LYS VAL
SEQRES   2 A  306  GLU GLY CYS MET VAL GLN VAL THR CYS GLY THR THR THR
SEQRES   3 A  306  LEU ASN GLY LEU TRP LEU ASP ASP VAL VAL TYR CYS PRO
SEQRES   4 A  306  ARG HIS VAL ILE CYS THR SER GLU ASP MET LEU ASN PRO
SEQRES   5 A  306  ASN TYR GLU ASP LEU LEU ILE ARG LYS SER ASN HIS ASN
SEQRES   6 A  306  PHE LEU VAL GLN ALA GLY ASN VAL GLN LEU ARG VAL ILE
SEQRES   7 A  306  GLY HIS SER MET GLN ASN CYS VAL LEU LYS LEU LYS VAL
SEQRES   8 A  306  ASP THR ALA ASN PRO LYS THR PRO LYS TYR LYS PHE VAL
SEQRES   9 A  306  ARG ILE GLN PRO GLY GLN THR PHE SER VAL LEU ALA CYS
SEQRES  10 A  306  TYR ASN GLY SER PRO SER GLY VAL TYR GLN CYS ALA MET
SEQRES  11 A  306  ARG PRO ASN PHE THR ILE LYS GLY SER PHE LEU ASN GLY
SEQRES  12 A  306  SER CYS GLY SER VAL GLY PHE ASN ILE ASP TYR ASP CYS
SEQRES  13 A  306  VAL SER PHE CYS TYR MET HIS HIS MET GLU LEU PRO THR
SEQRES  14 A  306  GLY VAL HIS ALA GLY THR ASP LEU GLU GLY ASN PHE TYR
SEQRES  15 A  306  GLY PRO PHE VAL ASP ARG GLN THR ALA GLN ALA ALA GLY
SEQRES  16 A  306  THR ASP THR THR ILE THR VAL ASN VAL LEU ALA TRP LEU
SEQRES  17 A  306  TYR ALA ALA VAL ILE ASN GLY ASP ARG TRP PHE LEU ASN
SEQRES  18 A  306  ARG PHE THR THR THR LEU ASN ASP PHE ASN LEU VAL ALA
SEQRES  19 A  306  MET LYS TYR ASN TYR GLU PRO LEU THR GLN ASP HIS VAL
SEQRES  20 A  306  ASP ILE LEU GLY PRO LEU SER ALA GLN THR GLY ILE ALA
SEQRES  21 A  306  VAL LEU ASP MET CYS ALA SER LEU LYS GLU LEU LEU GLN
SEQRES  22 A  306  ASN GLY MET ASN GLY ARG THR ILE LEU GLY SER ALA LEU
SEQRES  23 A  306  LEU GLU ASP GLU PHE THR PRO PHE ASP VAL VAL ARG GLN
SEQRES  24 A  306  CYS SER GLY VAL THR PHE GLN
"""
    has_seqres = 'SEQRES' in pdbfile_contents
    if not has_seqres:
        #print('Adding SEQRES')
        pdbfile_contents = seqres + pdbfile_contents

    # Read the receptor and identify design units
    from openeye import oespruce, oechem
    from tempfile import NamedTemporaryFile
    with NamedTemporaryFile(delete=False, mode='wt', suffix='.pdb') as pdbfile:
        pdbfile.write(pdbfile_contents)
        pdbfile.close()
        complex = read_pdb_file(pdbfile.name)
        # TODO: Clean up

    # Strip protons from structure to allow SpruceTK to add these back
    # See: 6wnp, 6wtj, 6wtk, 6xb2, 6xqs, 6xqt, 6xqu, 6m2n
    #print('Suppressing hydrogens')
    #print(f' Initial: {sum([1 for atom in complex.GetAtoms()])} atoms')
    for atom in complex.GetAtoms():
        if atom.GetAtomicNum() > 1:
            oechem.OESuppressHydrogens(atom)
    #print(f' Final: {sum([1 for atom in complex.GetAtoms()])} atoms')

    # Delete and rebuild C-terminal residue because Spruce causes issues with this
    # See: 6m2n 6lze
    #print('Deleting C-terminal residue O')
    pred = oechem.OEIsCTerminalAtom()
    for atom in complex.GetAtoms():
        if pred(atom):
            for nbor in atom.GetAtoms():
                if oechem.OEGetPDBAtomIndex(nbor) == oechem.OEPDBAtomName_O:
                    complex.DeleteAtom(nbor)

    #pred = oechem.OEAtomMatchResidue(["GLN:306:.*:.*:.*"])
    #for atom in complex.GetAtoms(pred):
    #    if oechem.OEGetPDBAtomIndex(atom) == oechem.OEPDBAtomName_O:
    #        print('Deleting O')
    #        complex.DeleteAtom(atom)

    #het = oespruce.OEHeterogenMetadata()
    #het.SetTitle("LIG")  # real ligand 3 letter code
    #het.SetID("CovMoonShot1234")  # in case you have corporate IDs
    #het.SetType(oespruce.OEHeterogenType_Ligand)
    #   mdata.AddHeterogenMetadata(het)

    #print('Identifying design units...')
    # Produce zero design units if we fail to protonate

    # Log warnings
    errfs = oechem.oeosstream(
    )  # create a stream that writes internally to a stream
    oechem.OEThrow.SetOutputStream(errfs)
    oechem.OEThrow.Clear()
    oechem.OEThrow.SetLevel(
        oechem.OEErrorLevel_Verbose)  # capture verbose error output

    opts = oespruce.OEMakeDesignUnitOptions()
    #print(f'ligand atoms: min {opts.GetSplitOptions().GetMinLigAtoms()}, max {opts.GetSplitOptions().GetMaxLigAtoms()}')
    opts.GetSplitOptions().SetMinLigAtoms(
        7)  # minimum fragment size (in heavy atoms)

    mdata = oespruce.OEStructureMetadata()
    opts.GetPrepOptions().SetStrictProtonationMode(True)

    # Both N- and C-termini should be zwitterionic
    # Mpro cleaves its own N- and C-termini
    # See https://www.pnas.org/content/113/46/12997
    opts.GetPrepOptions().GetBuildOptions().SetCapNTermini(False)
    opts.GetPrepOptions().GetBuildOptions().SetCapCTermini(False)
    # Don't allow truncation of termini, since force fields don't have parameters for this
    opts.GetPrepOptions().GetBuildOptions().GetCapBuilderOptions(
    ).SetAllowTruncate(False)
    # Build loops and sidechains
    opts.GetPrepOptions().GetBuildOptions().SetBuildLoops(True)
    opts.GetPrepOptions().GetBuildOptions().SetBuildSidechains(True)

    # Don't flip Gln189
    #pred = oechem.OEAtomMatchResidue(["GLN:189: :A"])
    pred = oechem.OEAtomMatchResidue(["GLN:189:.*:.*:.*"])
    protonate_opts = opts.GetPrepOptions().GetProtonateOptions()
    place_hydrogens_opts = protonate_opts.GetPlaceHydrogensOptions()
    #place_hydrogens_opts.SetBypassPredicate(pred)
    place_hydrogens_opts.SetNoFlipPredicate(pred)
    #protonate_opts = oespruce.OEProtonateDesignUnitOptions(place_hydrogens_opts)
    #opts.GetPrepOptions().SetProtonateOptions(protonate_options);

    # Make design units
    design_units = list(oespruce.OEMakeDesignUnits(complex, mdata, opts))

    # Restore error stream
    oechem.OEThrow.SetOutputStream(oechem.oeerr)

    # Capture the warnings to a string
    warnings = errfs.str().decode("utf-8")

    if len(design_units) >= 1:
        design_unit = design_units[0]
        print('')
        print('')
        print(f'{complex_pdb_filename} : SUCCESS')
        print(warnings)
    elif len(design_units) == 0:
        print('')
        print('')
        print(f'{complex_pdb_filename} : FAILURE')
        print(warnings)
        msg = f'No design units found for {complex_pdb_filename}\n'
        msg += warnings
        msg += '\n'
        raise Exception(msg)

    # Prepare the receptor
    #print('Preparing receptor...')
    from openeye import oedocking
    protein = oechem.OEGraphMol()
    design_unit.GetProtein(protein)
    ligand = oechem.OEGraphMol()
    design_unit.GetLigand(ligand)

    # Create receptor and other files
    receptor = oechem.OEGraphMol()
    oedocking.OEMakeReceptor(receptor, protein, ligand)
    oedocking.OEWriteReceptorFile(receptor, receptor_filename)

    with oechem.oemolostream(f'{prefix}-protein.pdb') as ofs:
        oechem.OEWriteMolecule(ofs, protein)
    with oechem.oemolostream(f'{prefix}-ligand.mol2') as ofs:
        oechem.OEWriteMolecule(ofs, ligand)
    with oechem.oemolostream(f'{prefix}-ligand.pdb') as ofs:
        oechem.OEWriteMolecule(ofs, ligand)
    with oechem.oemolostream(f'{prefix}-ligand.sdf') as ofs:
        oechem.OEWriteMolecule(ofs, ligand)

    # Filter out UNK from PDB files (which have covalent adducts)
    pdbfile_lines = [
        line for line in open(f'{prefix}-protein.pdb', 'r')
        if 'UNK' not in line
    ]
    with open(f'{prefix}-protein.pdb', 'wt') as outfile:
        outfile.write(''.join(pdbfile_lines))

    # Adjust protonation state of CYS145 to generate thiolate form
    #print('Deprotonating CYS145...') # DEBUG
    #pred = oechem.OEAtomMatchResidue(["CYS:145: :A"])
    pred = oechem.OEAtomMatchResidue(["CYS:145:.*:.*:.*"])
    place_hydrogens_opts.SetBypassPredicate(pred)
    for atom in protein.GetAtoms(pred):
        if oechem.OEGetPDBAtomIndex(atom) == oechem.OEPDBAtomName_SG:
            #print('Modifying CYS 145 SG')
            oechem.OESuppressHydrogens(atom)
            atom.SetFormalCharge(-1)
            atom.SetImplicitHCount(0)
    #print('Protonating HIS41...') # DEBUG
    #pred = oechem.OEAtomMatchResidue(["HIS:41: :A"])
    pred = oechem.OEAtomMatchResidue(["HIS:41:.*:.*:.*"])
    place_hydrogens_opts.SetBypassPredicate(pred)
    for atom in protein.GetAtoms(pred):
        if oechem.OEGetPDBAtomIndex(atom) == oechem.OEPDBAtomName_ND1:
            #print('Protonating HIS 41 ND1')
            oechem.OESuppressHydrogens(atom)  # strip hydrogens from residue
            atom.SetFormalCharge(+1)
            atom.SetImplicitHCount(1)
    # Update the design unit with the modified formal charge for CYS 145 SG
    oechem.OEUpdateDesignUnit(design_unit, protein,
                              oechem.OEDesignUnitComponents_Protein)

    # Don't flip Gln189
    #pred = oechem.OEAtomMatchResidue(["GLN:189: :A"])
    #protonate_opts = opts.GetPrepOptions().GetProtonateOptions();
    #place_hydrogens_opts = protonate_opts.GetPlaceHydrogensOptions()
    #place_hydrogens_opts.SetNoFlipPredicate(pred)

    # Adjust protonation states
    #print('Re-optimizing hydrogen positions...') # DEBUG
    #place_hydrogens_opts = oechem.OEPlaceHydrogensOptions()
    #place_hydrogens_opts.SetBypassPredicate(pred)
    #protonate_opts = oespruce.OEProtonateDesignUnitOptions(place_hydrogens_opts)
    success = oespruce.OEProtonateDesignUnit(design_unit, protonate_opts)
    design_unit.GetProtein(protein)

    # Write thiolate form of receptor
    receptor = oechem.OEGraphMol()
    oedocking.OEMakeReceptor(receptor, protein, ligand)
    oedocking.OEWriteReceptorFile(receptor, thiolate_receptor_filename)

    with oechem.oemolostream(f'{prefix}-protein-thiolate.pdb') as ofs:
        oechem.OEWriteMolecule(ofs, protein)

    # Filter out UNK from PDB files (which have covalent adducts)
    pdbfile_lines = [
        line for line in open(f'{prefix}-protein-thiolate.pdb', 'r')
        if 'UNK' not in line
    ]
    with open(f'{prefix}-protein-thiolate.pdb', 'wt') as outfile:
        outfile.write(''.join(pdbfile_lines))