Datasets:

jglaser
/

pdbbind_complexes

	from mpi4py import MPI
	from mpi4py.futures import MPICommExecutor

	import warnings
	from Bio.PDB import PDBParser, PPBuilder, CaPPBuilder
	from Bio.PDB.NeighborSearch import NeighborSearch
	from Bio.PDB.Selection import unfold_entities

	import numpy as np
	import dask.array as da

	from rdkit import Chem

	from spyrmsd import molecule
	from spyrmsd import graph
	import networkx as nx

	import os
	import re
	import sys

	# all punctuation
	punctuation_regex = r"""($\|$\|\.\|=\|#\|-\|\+\|\\\|\/\|:\|~\|@\|\?\|>>?\|\*\|\$\|\%[0-9]{2}\|[0-9])"""

	# tokenization regex (Schwaller)
	molecule_regex = r"""(\[[^\]]+]\|Br?\|Cl?\|N\|O\|S\|P\|F\|I\|b\|c\|n\|o\|s\|p\|$\|$\|\.\|=\|#\|-\|\+\|\\\|\/\|:\|~\|@\|\?\|>>?\|\*\|\$\|\%[0-9]{2}\|[0-9])"""

	max_seq = 2046 # = 2048 - 2 (accounting for [CLS] and [SEP])
	max_smiles = 510 # = 512 - 2
	chunk_size = '1G'

	def rot_from_two_vecs(e0_unnormalized, e1_unnormalized):
	"""Create rotation matrices from unnormalized vectors for the x and y-axes.
	This creates a rotation matrix from two vectors using Gram-Schmidt
	orthogonalization.
	Args:
	e0_unnormalized: vectors lying along x-axis of resulting rotation
	e1_unnormalized: vectors lying in xy-plane of resulting rotation
	Returns:
	Rotations resulting from Gram-Schmidt procedure.
	"""
	# Normalize the unit vector for the x-axis, e0.
	e0 = e0_unnormalized / np.linalg.norm(e0_unnormalized)

	# make e1 perpendicular to e0.
	c = np.dot(e1_unnormalized, e0)
	e1 = e1_unnormalized - c * e0
	e1 = e1 / np.linalg.norm(e1)

	# Compute e2 as cross product of e0 and e1.
	e2 = np.cross(e0, e1)

	# local to space frame
	return np.stack([e0,e1,e2]).T

	def get_local_frames(mol):
	# get the two nearest neighbors of every atom on the molecular graph
	# ties are broken using canonical ordering
	g = molecule.Molecule.from_rdkit(mol).to_graph()

	R = []
	for node in g:
	length = nx.single_source_shortest_path_length(g, node)

	neighbor_a = [n for n,l in length.items() if l==1][0]

	try:
	neighbor_b = [n for n,l in length.items() if l==1][1]
	except:
	# get next nearest neighbor
	neighbor_b = [n for n,l in length.items() if l==2][0]

	xyz = np.array(mol.GetConformer().GetAtomPosition(node))
	xyz_a = np.array(mol.GetConformer().GetAtomPosition(neighbor_a))
	xyz_b = np.array(mol.GetConformer().GetAtomPosition(neighbor_b))

	R.append(rot_from_two_vecs(xyz_a-xyz, xyz_b-xyz))

	return R

	def parse_complex(fn):
	try:
	name = os.path.basename(fn)

	# parse protein sequence and coordinates
	parser = PDBParser()
	with warnings.catch_warnings():
	warnings.simplefilter("ignore")
	structure = parser.get_structure('protein',fn+'/'+name+'_protein.pdb')

	res_frames = []

	# extract sequence, Calpha positions and local coordinate frames using the AF2 convention
	ppb = CaPPBuilder()
	seq = []
	xyz_receptor = []
	R_receptor = []
	for pp in ppb.build_peptides(structure):
	seq.append(str(pp.get_sequence()))
	xyz_receptor += [tuple(a.get_vector()) for a in pp.get_ca_list()]

	for res in pp:
	N = np.array(tuple(res['N'].get_vector()))
	C = np.array(tuple(res['C'].get_vector()))
	CA = np.array(tuple(res['CA'].get_vector()))

	R_receptor.append(rot_from_two_vecs(N-CA,C-CA).flatten().tolist())

	seq = ''.join(seq)

	# parse ligand, convert to SMILES and map atoms
	suppl = Chem.SDMolSupplier(fn+'/'+name+'_ligand.sdf')
	mol = next(suppl)

	# bring molecule atoms in canonical order (to determine local frames uniquely)
	m_neworder = tuple(zip(*sorted([(j, i) for i, j in enumerate(Chem.CanonicalRankAtoms(mol))])))[1]
	mol = Chem.RenumberAtoms(mol, m_neworder)

	# position of atoms in SMILES (not counting punctuation)
	smi = Chem.MolToSmiles(mol)
	atom_order = [int(s) for s in list(filter(None,re.sub(r'[\[\]]','',mol.GetProp("_smilesAtomOutputOrder")).split(',')))]

	# tokenize the SMILES
	tokens = list(filter(None, re.split(molecule_regex, smi)))

	# remove punctuation
	masked_tokens = [re.sub(punctuation_regex,'',s) for s in tokens]

	k = 0
	token_pos = []
	token_rot = []

	frames = get_local_frames(mol)

	for i,token in enumerate(masked_tokens):
	if token != '':
	token_pos.append(tuple(mol.GetConformer().GetAtomPosition(atom_order[k])))
	token_rot.append(frames[atom_order[k]].flatten().tolist())
	k += 1
	else:
	token_pos.append((np.nan, np.nan, np.nan))
	token_rot.append(np.eye(3).flatten().tolist())

	return name, seq, smi, xyz_receptor, token_pos, token_rot, R_receptor

	except Exception as e:
	print(e)
	return None


	if __name__ == '__main__':
	import glob

	filenames = glob.glob('data/pdbbind/v2020-other-PL/*')
	filenames.extend(glob.glob('data/pdbbind/refined-set/*'))
	filenames = sorted(filenames)
	comm = MPI.COMM_WORLD
	with MPICommExecutor(comm, root=0) as executor:
	if executor is not None:
	result = executor.map(parse_complex, filenames, chunksize=32)
	result = list(result)
	names = [r[0] for r in result if r is not None]
	seqs = [r[1] for r in result if r is not None]
	all_smiles = [r[2] for r in result if r is not None]
	all_xyz_receptor = [r[3] for r in result if r is not None]
	all_xyz_ligand = [r[4] for r in result if r is not None]
	all_rot_ligand = [r[5] for r in result if r is not None]
	all_rot_receptor = [r[6] for r in result if r is not None]

	import pandas as pd
	df = pd.DataFrame({'name': names, 'seq': seqs,
	'smiles': all_smiles,
	'receptor_xyz': all_xyz_receptor,
	'ligand_xyz': all_xyz_ligand,
	'ligand_rot': all_rot_ligand,
	'receptor_rot': all_rot_receptor})
	df.to_parquet('data/pdbbind.parquet',index=False)