""" return _pyChiNn_(mol, 4) Chi0v = lambda x: rdMolDescriptors.CalcChi0v(x) Chi0v.version = rdMolDescriptors._CalcChi0v_version Chi1v = lambda x: rdMolDescriptors.CalcChi1v(x) Chi1v.version = rdMolDescriptors._CalcChi1v_version Chi2v = lambda x: rdMolDescriptors.CalcChi2v(x) Chi2v.version = rdMolDescriptors._CalcChi2v_version Chi3v = lambda x: rdMolDescriptors.CalcChi3v(x) Chi3v.version = rdMolDescriptors._CalcChi3v_version Chi4v = lambda x: rdMolDescriptors.CalcChi4v(x) Chi4v.version = rdMolDescriptors._CalcChi4v_version ChiNv_ = lambda x, y: rdMolDescriptors.CalcChiNv(x, y) ChiNv_.version = rdMolDescriptors._CalcChiNv_version Chi0n = lambda x: rdMolDescriptors.CalcChi0n(x) Chi0n.version = rdMolDescriptors._CalcChi0n_version Chi1n = lambda x: rdMolDescriptors.CalcChi1n(x) Chi1n.version = rdMolDescriptors._CalcChi1n_version Chi2n = lambda x: rdMolDescriptors.CalcChi2n(x) Chi2n.version = rdMolDescriptors._CalcChi2n_version Chi3n = lambda x: rdMolDescriptors.CalcChi3n(x) Chi3n.version = rdMolDescriptors._CalcChi3n_version Chi4n = lambda x: rdMolDescriptors.CalcChi4n(x) Chi4n.version = rdMolDescriptors._CalcChi4n_version ChiNn_ = lambda x, y: rdMolDescriptors.CalcChiNn(x, y) ChiNn_.version = rdMolDescriptors._CalcChiNn_version
def get_fingerprint(SMILES=None, E_BIND=None): """ PRE: Takes in a MOLECULE as a SMILES POST: Prints its finger prints as two list, the first contains the names, the second contains the fingerprints """ def get_atoms_coords(RDKIT_BLOCK): """Takes as input an RDKIT BLOCK and returns a list of atoms with a numpy array containing the coordinates""" RDKIT_BLOCK = RDKIT_BLOCK.split('\n') atm_number = int(RDKIT_BLOCK[3][:3]) RDKIT_BLOCK = [x.split() for x in RDKIT_BLOCK] atm_list = [] coords_array = np.zeros([atm_number, 3], dtype=float) for i, line in enumerate(RDKIT_BLOCK[4:4 + atm_number]): coords_atm = line atm_list.append(coords_atm[3]) coords_array[i, :] = coords_atm[:3] return atm_list, coords_array def get_atom_types(mol): """ PRE: Takes in the mol POST: Returns a dictionary with the atom types and numbers """ atom_types = {} for atom in mol.GetAtoms(): symbol = atom.GetSymbol() if symbol in atom_types: atom_types[symbol] += 1 else: atom_types[symbol] = 1 return atom_types def AreRingFused(mol): """ PRE : Takes in a mol rdkit POST : Returns the max number of fused rings. That is the maximum number of rings any atom belongs to """ rings = Chem.GetSymmSSSR(mol) ring_dic = {} for ring in rings: for atom in list(ring): if atom in ring_dic: ring_dic[atom] += 1 else: ring_dic[atom] = 1 if ring_dic.values() == []: return 0 else: return max(ring_dic.values()) def getVolume(mol, atom_types): """ PRE: Takes in a mol with HYDROGENS ADDED POST: Returns its volume computed as a linear combination of the contribution of the vdW volumes """ index_of_vols = {'H': 7.24, 'C': 20.58, 'N': 15.60, 'O': 14.71, 'F': 13.31, 'Cl': 22.45, 'Br': 26.52, 'I': 32.52, 'P': 24.43, 'S': 24.43, 'As': 26.52, 'B': 40.48, 'Si': 38.79, 'Se': 28.73, 'Te': 36.62} gross_volume = 0 # for sym in atom_types: # gross_volume += atom_types[sym] * index_of_vols[sym] bonds = mol.GetNumBonds() rings = Chem.GetSymmSSSR(mol) # print 'aromatic ring count is ',descriptors.CalcNumAromaticRings(mol) # print 'aliphatic ring count is ',descriptors.CalcNumAliphaticRings(mol) ra = 0 largest_ra = 0 rna = 0 largest_rna = 0 for ringId in range(len(rings)): if isRingAromatic(mol, tuple(rings[ringId])): ra += 1 if largest_ra < len(rings[ringId]): largest_ra = len(rings[ringId]) else: rna += 1 if largest_rna < len(rings[ringId]): largest_rna = len(rings[ringId]) # volume = gross_volume - 5.92 * bonds - 14.7 * ra - 3.8 * rna try: AllChem.EmbedMolecule(mol) AllChem.MMFFOptimizeMolecule(mol) volume = AllChem.ComputeMolVolume(mol) except: raise ValueError("Can't build the molecule") return volume, ra, rna, largest_ra, largest_rna def isRingAromatic(mol, ring): """ PRE: Takes in a mol and a ring given as a tuple of atom id POST: Returns TRUE is all the atoms inside the ring are aromatic and FALSE otherwise """ aromatic = True for ids in ring: if mol.GetAtomWithIdx(ids).GetIsAromatic(): # print ids pass else: aromatic = False break return aromatic mol = SMILES features = [ 'atomNbr', 'Volume', 'NAtom', 'OAtom', 'SAtom', 'PAtom', 'ClAtom', 'BrAtom', 'FAtom', 'IAtom', 'AromaticRingNumber', 'LargestAromaticRingAtomNbr', 'NonAromaticRingNumber', 'LargestNonAromaticRingAtomNbr', 'MaxNbrFusedRings', 'SurfaceArea', 'Charge', # 'MinRadiusOfCylinder', # 'RadiusOfCylinderBestConf', 'NitroNbr', 'AlcoholNbr', 'KetoneNbr', 'NitrileNbr', 'ThiolNbr', 'Phenol_likeNbr', 'EsterNbr', 'SulfideNbr', 'CarboxilicAcidNbr', 'EtherNbr', 'AmideNbr', 'AnilineNbr', 'PrimaryAmineNbr', 'SecondaryAmineNbr', 'RotableBondNum', 'HBondDonor', 'HBondAcceptor', 'MolLogP', 'MolMR' ] for i in range(6): features.append('Chi{}v'.format(i + 1)) features.append('Chi{}n'.format(i + 1)) if i < 3: features.append('Kappa{}'.format(i + 1)) feature_dic = dict.fromkeys(features) if mol == None: return sorted(feature_dic.keys()) mol = Chem.MolFromSmiles(SMILES) mol = Chem.AddHs(mol) feature_dic['RotableBondNum'] = descriptors.CalcNumRotatableBonds(mol) for i in range(6): feature_dic['Chi{}v'.format(i + 1)] = descriptors.CalcChiNv(mol, i + 1) feature_dic['Chi{}n'.format(i + 1)] = descriptors.CalcChiNn(mol, i + 1) feature_dic['Kappa1'] = descriptors.CalcKappa1(mol) feature_dic['Kappa2'] = descriptors.CalcKappa2(mol) feature_dic['Kappa3'] = descriptors.CalcKappa3(mol) feature_dic['HBondAcceptor'] = descriptors.CalcNumHBA(mol) feature_dic['HBondDonor'] = descriptors.CalcNumHBD(mol) CrippenDescriptors = descriptors.CalcCrippenDescriptors(mol) feature_dic['MolLogP'] = CrippenDescriptors[0] feature_dic['MolMR'] = CrippenDescriptors[1] atom_types = get_atom_types(mol) for feat, symbol in zip(['NAtom', 'OAtom', 'SAtom', 'PAtom', 'ClAtom', 'BrAtom', 'FAtom', 'IAtom'], ['N', 'O', 'S', 'P', 'Cl', 'Br', 'F', 'I']): if symbol in atom_types: feature_dic[feat] = atom_types[symbol] else: feature_dic[feat] = 0 feature_dic['atomNbr'] = mol.GetNumHeavyAtoms() feature_dic['Volume'], feature_dic['AromaticRingNumber'], feature_dic['NonAromaticRingNumber'], feature_dic[ 'LargestAromaticRingAtomNbr'], feature_dic['LargestNonAromaticRingAtomNbr'] = getVolume(mol, atom_types) feature_dic['MaxNbrFusedRings'] = AreRingFused(mol) feature_dic['SurfaceArea'] = descriptors.CalcTPSA(mol) feature_dic['Charge'] = Chem.GetFormalCharge(mol) funct_dic = { '[$([NX3](=O)=O),$([NX3+](=O)[O-])][!#8]': 'NitroNbr', '[#6][OX2H]': 'AlcoholNbr', '[NX1]#[CX2]': 'NitrileNbr', '[#6][CX3](=O)[#6]': 'KetoneNbr', '[#16X2H]': 'ThiolNbr', "[OX2H][cX3][c]": 'Phenol_likeNbr', '[#6][CX3](=O)[OX2H0][#6]': 'EsterNbr', '[#16X2H0]': 'SulfideNbr', '[CX3](=O)[OX2H1]': 'CarboxilicAcidNbr', '[OD2]([#6])[#6]': 'EtherNbr', # '[NX3][CX3](=[OX1])[#6]':'AmideNbr', '[#7X3][#6X3](=[OX1])[#6]': 'AmideNbr', '[NX3][cc]': 'AnilineNbr', '[NX3H2;!$(NC=O)]': 'PrimaryAmineNbr', '[NX3H1;!$(NC=O)]': 'SecondaryAmineNbr'} for funct in funct_dic: patt = Chem.MolFromSmarts(funct) feature_dic[funct_dic[funct]] = len(mol.GetSubstructMatches(patt)) # names, coords = get_atoms_coords(Chem.MolToMolBlock(mol)) # feature_dic['MinRadiusOfCylinder'] = returnCircleAsTuple(coords[:,1:])[2] # feature_dic['MinRadiusOfCylinder'] = RADIUS[0] # feature_dic['RadiusOfCylinderBestConf'] = RADIUS[1] values = [] for key in sorted(feature_dic.keys()): values.append(feature_dic[key]) # print key, feature_dic[key] return values