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CReM - chemically reasonable mutations

CReM is an open-source Python framework to generate chemical structures using a fragment-based approach.

The main idea behind is similar to matched molecular pairs considering context that fragments in the identical context are interchangeable. Therefore, one can create a database of interchangeable fragments and use it for generation of chemically valid structures.

Features:

  1. Generation of a custom fragment database
  2. Three modes of structure generation: MUTATE, GROW, LINK
  3. Context radius to consider for replacement
  4. Fragment size to replace and the size of a replacing fragment
  5. Protection of atoms from modification (e.g. scaffold protection)
  6. Replacements with fragments occurred in a fragment database with certain minimal frequency
  7. Make randomly chosen replacements up to the specified number

Limitations and known issues

  1. New ring systems cannot be constructed from fragments, thus representativeness of ring systems in generated structures depends on a used fragment database. We are working on that issue.
  2. Very large molecules will not be processed by CReM. If a molecule has more than 30 non-ring single bonds it will not be MUTATED. If a molecule has more than 100 hydrogen atoms it will not be processed by GROW and LINK.
  3. Canonicalisation of contexts depends on RDKit SMILES representation. Thus, changing in RDKit SMILES representation may affect fragment databases and make impossible to use a database prepared with previous RDKit version from code running under later RDKit versions.

Documentation

https://crem.readthedocs.io/en/latest/

Web app

To play with a tool online.
https://crem.imtm.cz/

Installation

Several command line utilities will be installed to create fragment databases and crem module will become available in Python imports to generate structures.

From pypi package

pip install crem

Manually from repository

git clone https://github.com/DrrDom/crem
cd crem
python3 setup.py sdist bdist_wheel
pip install dist/crem-0.1-py3-none-any.whl

Uninstall

pip uninstall crem

Dependencies

crem requires rdkit>=2017.09. To run the guacamol test guacamol should be installed.

Generation of a fragment database

This step is required if you want to generate a custom fragment database. You can download precompiled databases obtained by fragmentation of the whole ChEMBL by links provided on this page - http://www.qsar4u.com/pages/crem.php.

For convenience there is the bash script crem_create_frag_db.sh which includes all steps below. It takes three positional arguments: input file with SMILES, output directory where intermediate files and a final database will be stored and number of CPUs to use (this is optional, default value is 1).

crem_create_frag_db.sh input.smi fragdb_dir 32

Fragmentation of input structures:

fragmentation -i input.smi -o frags.txt -c 32 -v

Convert fragments to standardized representation of a core and a context of a given radius:

frag_to_env -i frags.txt -o r3.txt -r 3 -c 32 -v

Remove duplicated lines in the output file and count frequency of occurrence of fragemnt-context pairs. These (sort and uniq) are bash utilities but since Win10 is Linux-friendly that should not be a big issue for Win users to execute them

sort r3.txt | uniq -c > r3_c.txt

Create DB and import the file to a database table

env_to_db -i r3_c.txt -o fragments.db -r 3 -c -v

Last three steps should be executed for each radius. All tables can be stored in the same database.

Structure generation

Import necessary functions from the main module

from crem.crem import mutate_mol, grow_mol, link_mols
from rdkit import Chem

Create a molecute and mutate it. Only one heavy atom will be substituted. Default radius is 3.

m = Chem.MolFromSmiles('c1cc(OC)ccc1C')  # methoxytoluene
mols = list(mutate_mol(m, db_name='replacements.db', max_size=1))

output example

['CCc1ccc(C)cc1',
 'CC#Cc1ccc(C)cc1',
 'C=C(C)c1ccc(C)cc1',
 'CCCc1ccc(C)cc1',
 'CC=Cc1ccc(C)cc1',
 'CCCCc1ccc(C)cc1',
 'CCCOc1ccc(C)cc1',
 'CNCCc1ccc(C)cc1',
 'COCCc1ccc(C)cc1',
 ...
 'Cc1ccc(C(C)(C)C)cc1']

Add hydrogens to the molecule to mutate hydrogens as well

mols = list(mutate_mol(Chem.AddHs(m), db_name='replacements.db', max_size=1))

output

['CCc1ccc(C)cc1',
 'CC#Cc1ccc(C)cc1',
 'C=C(C)c1ccc(C)cc1',
 'CCCc1ccc(C)cc1',
 'Cc1ccc(C(C)C)cc1',
 'CC=Cc1ccc(C)cc1',
 ...
 'COc1ccc(C)cc1C',
 'C=Cc1cc(C)ccc1OC',
 'COc1ccc(C)cc1Cl',
 'COc1ccc(C)cc1CCl']

Grow molecule. Only hydrogens will be replaced. Hydrogens should not be added explicitly.

mols = list(grow_mol(m, db_name='replacements.db'))

output

['COc1ccc(C)c(Br)c1',
 'COc1ccc(C)c(C)c1',
 'COc1ccc(C)c(Cl)c1',
 'COc1ccc(C)c(OC)c1',
 'COc1ccc(C)c(N)c1',
 ...
 'COc1ccc(CCN)cc1']

Create the second molecule and link it to toluene

m2 = Chem.MolFromSmiles('NCC(=O)O')  # glycine
mols = list(link_mols(m, m2, db_name='replacements.db'))

output

['Cc1ccc(OCC(=O)NCC(=O)O)cc1',
 'Cc1ccc(OCCOC(=O)CN)cc1',
 'COc1ccc(CC(=N)NCC(=O)O)cc1',
 'COc1ccc(CC(=O)NCC(=O)O)cc1',
 'COc1ccc(CC(=S)NCC(=O)O)cc1',
 'COc1ccc(CCOC(=O)CN)cc1']

You can vary the size of a linker and specify the distance between two attachment points in a linking fragment. There are many other arguments available in these functions, look at their docstrings for details.

Additional filters to control fragments chosen for replacing

An example of a filtering function which will keep only fragments containing a specific atom to be chosen for replacing.

from collections import defaultdict
from functools import partial
from rdkit import Chem

def filter_function(row_ids, cur, radius, atom_number):

    """
    The first three arguments should be always the same as shown in the example. These parameters will be passed to a function from a main function, e.g. from mutate_mol. All other arguments are user-defined. The function should return the list of row ids of fragments which will be used for replacing. 

    :param row_id: a list of row ids from CReM database of those fragments which satisfy other selection criteria
    :param cur: cursor of CReM database
    :param radius: radius of a context 
    :param atom_number: an atomic number, fragments with this number will be discarded
    :return list of remaining row ids
    """

    # this part may be kept intact, it collects from DB SMILES of fragments with given row ids
    # since fragments may occur multiple times (due to different contexts) the results are collected in a dict
    if not row_ids:
        return []
    batch_size = 32000  # SQLite has a limit on a number of passed values to a query
    row_ids = list(row_ids)
    smis = defaultdict(list)  # {smi_1: [rowid_1, rowid_5, ...], ...}
    for start in range(0, len(row_ids), batch_size):
        batch = row_ids[start:start + batch_size]
        sql = f"SELECT rowid, core_smi FROM radius{radius} WHERE rowid IN ({','.join('?' * len(batch))})"
        for i, smi in cur.execute(sql, batch).fetchall():
            smis[smi].append(i)

    output_row_ids = []
    for smi, ids in smis.items():
        for a in Chem.MolFromSmiles(smi).GetAtoms():
            if a.GetAtomicNum() == atom_number:
                output_row_ids.extend(ids)
    return output_row_ids

# only F-containing fragments will be chosen for replacing
mol = Chem.MolFromSmiles('c1ccccc1C')
mols = mutate_mol(mol, db_name='replacements.db', filter_func=partial(filter_function, atom_number=9), max_size=1, max_inc=3)

output

['Fc1ccccc1', 
 'FC(F)(F)c1ccccc1',
 'FC(F)Oc1ccccc1',
 'FC(F)Sc1ccccc1']
Custom sampling of randomly chosen fragments

If not all possible derivatives are necessary to generate a user may limit the number of returned compounds by max_replacements argument which enable uniform sampling of a desired number of molecules. To enable custom sampling and bias selection to more desired chemotypes there is an argument sample_func which takes a function implementing the selection. This function should take four necessary arguments: row_ids (list or set of row_ids from the fragment database), cursor of that fragment database, radius (int) and the number of returned items (int). An example of such a function is implemented in utils module and showed below. Other biases can be introduced via this option. Please not, using of complex sampling functions may slow down structure generation.

def sample_csp3(row_ids, cur, radius, n):
    """
    Performs random selection of fragments proportionally to a squared fraction of sp3 carbon atoms.
    :param row_ids: the list of row ids of fragments to consider
    :param cur: cursor to the fragment database
    :param radius: context radius
    :param n: the number of fragments to select
    :return: the list of row ids of selected fragments
    """
    d = defaultdict(list)
    for rowid, core_smi, _, _ in _get_replacements(cur, radius, row_ids):
        d[core_smi].append(rowid)
    smis = list(d.keys())
    values = [rdMolDescriptors.CalcFractionCSP3(Chem.MolFromSmiles(smi)) ** 2 for smi in smis]
    values = [v + 1e-8 for v in values]
    values = np.array(values) / sum(values)
    selected_smiles = np.random.choice(smis, n, replace=False, p=values).tolist()
    ids = []
    for smi in selected_smiles:
        ids.extend(d[smi])
    ids = random.sample(ids, n)
    return ids

Example of sample_func application. F atom is replaced and 10 derivatives is returned biased by the fraction of sp3 carbons and not.

m = Chem.MolFromSmiles('c1ccccc1F')

res = list(mutate_mol(m, 'replacements_sa2_f5.db',
                      radius=3, min_inc=0, max_inc=10, max_replacements=10,
                      replace_ids=[6]))
values = sorted(round(rdMolDescriptors.CalcFractionCSP3(Chem.MolFromSmiles(smi)), 4) for smi in res)
print(res)
print(values)

res = list(mutate_mol(m, 'replacements_sa2_f5.db',
                      radius=3, min_inc=0, max_inc=10, max_replacements=10,
                      replace_ids=[6], sample_func=sample_csp3))
values = sorted(round(rdMolDescriptors.CalcFractionCSP3(Chem.MolFromSmiles(smi)), 4) for smi in res)
print(res)
print(values)

output

# uniform sampling
['c1ccc(-c2ccc(-c3csnn3)cc2)cc1', 'c1ccc(COc2cccnc2)cc1', 'CCCc1ccc(OCc2ccccc2)cc1', 'CC(C)(O)C(=O)NCCc1ccccc1', 'CN(C)C(=O)CNC(=O)OCc1ccccc1', 'COc1ccc(-c2ccccc2)cc1C(N)=O', 'Fc1ccccc1-c1ccccc1', 'Nc1cccnc1Sc1ccccc1', 'O=C(Nc1ccc(F)c(F)c1)c1ccccc1', 'O=C(COC(=O)c1ccco1)c1ccccc1']
[0.0, 0.0, 0.0, 0.0, 0.0714, 0.0769, 0.0833, 0.25, 0.3333, 0.4167]

# sampling biased by the fraction of sp3 carbons
['c1ccc(CNCc2ccncc2)cc1', 'Cc1cccc(CSc2ccccc2)n1', 'CC(=Cc1ccccc1)CN1CCN(C)CC1', 'CC(C)N(CCOc1ccccc1)C(C)C', 'CCN(CCC#N)C(=O)Nc1ccccc1', 'CSCc1ccccc1', 'O=C(Cc1ccccc1)NCCc1ccoc1', 'O=C(CCc1ccccc1)NC1CCCCC1', 'O=C(CN1CCCC1)NCCc1ccccc1', 'O=C(CSc1ccccc1)NC1CC1']
[0.1538, 0.1538, 0.2143, 0.25, 0.3333, 0.3636, 0.4667, 0.5, 0.5333, 0.5714]

In the latter case there are molecules having the greater fraction of sp3-carbon atoms.

Iterative enumeration

For convenience there is a function enumerate_compounds in utils module (added in version 0.2.6). It performs iterative growing (scaffold decoration) or mutation (analog enumeration) of a supplied molecule. More details are in docstring of the function.

Example. Enumerate derivatives of 1-chloro-3-methylbenzene at positions 2 and 4 of the ring and at the methyl group at the same time. In this case one should choose scaffold mode, 3 iterations, specify atom ids (0-based indices) where fragments can be attached and set protect_added_frag=True to restrict enumeration only to selected positions.

from crem.utils import enumerate_compounds

mol = Chem.MolFromMolBlock("""
  Mrv1922 05242309182D          

  8  8  0  0  0  0            999 V2000
   -3.2813    1.3161    0.0000 C   0  0  0  0  0  0  0  0  0  0  0  0
   -3.9957    0.9036    0.0000 C   0  0  0  0  0  0  0  0  0  0  0  0
   -3.9957    0.0786    0.0000 C   0  0  0  0  0  0  0  0  0  0  0  0
   -3.2813   -0.3339    0.0000 C   0  0  0  0  0  0  0  0  0  0  0  0
   -2.5668    0.0786    0.0000 C   0  0  0  0  0  0  0  0  0  0  0  0
   -2.5668    0.9036    0.0000 C   0  0  0  0  0  0  0  0  0  0  0  0
   -3.2813   -1.1589    0.0000 C   0  0  0  0  0  0  0  0  0  0  0  0
   -1.8523    1.3161    0.0000 Cl  0  0  0  0  0  0  0  0  0  0  0  0
  1  2  1  0  0  0  0
  2  3  2  0  0  0  0
  3  4  1  0  0  0  0
  4  5  2  0  0  0  0
  5  6  1  0  0  0  0
  1  6  2  0  0  0  0
  4  7  1  0  0  0  0
  6  8  1  0  0  0  0
M  END
""")

mols = enumerate_compounds(mol, 'replacements_sa2.db', mode='scaffold', n_iterations=3,
                           radius=3, max_replacements=2, replace_ids=[2,4,6], protect_added_frag=True, 
                           return_smi=True)

output

['COc1c(C)cccc1Cl', 
'Cc1cc(Cl)ccc1Cl', 
'COc1ccc(Cl)c(OC)c1C', 
'COc1c(Cl)cccc1CF', 
'Cc1c(Cl)ccc(Cl)c1C', 
'CSCc1cc(Cl)ccc1Cl', 
'COc1ccc(Cl)c(OC)c1CC#N', 
'COCc1c(OC)ccc(Cl)c1OC', 
'COc1c(Cl)cccc1C(F)F', 
'COc1c(Cl)ccc(CO)c1CF', 
'Cc1c(Cl)ccc(Cl)c1CC#N', 
'Cc1c(Cl)ccc(Cl)c1CCN', 
'CSCc1c(Cl)ccc(Cl)c1C', 
'CSCc1c(Cl)ccc(Cl)c1Cl']
Multiprocessing

All functions have an argument ncores and can make mupltile replacement in one molecule in parallel. If you want to process several molecules in parallel you have to write your own code. However, the described functions are generators and cannot be used with multiprocessing module. Therefore, three complementary functions mutate_mol2, grow_mol2 and link_mols2 were created. They return the list with results and can be pickled and used with multiprocessing.Pool or other tools.

Example:

from multiprocessing import Pool
from functools import partial
from crem.crem import mutate_mol2
from rdkit import Chem

p = Pool(2)
input_smi = ['c1ccccc1N', 'NCC(=O)OC', 'NCCCO']
input_mols = [Chem.MolFromSmiles(s) for s in input_smi]

res = list(p.imap(partial(mutate_mol2, db_name='replacements.db', max_size=1), input_mols))

res would be a list of lists with SMILES of generated molecules

Bechmarks

Guacamol
task SMILES LSTM* SMILES GA* Graph GA* Graph MCTS* CReM
Celecoxib rediscovery 1.000 0.732 1.000 0.355 1.000
Troglitazone rediscovery 1.000 0.515 1.000 0.311 1.000
Thiothixene rediscovery 1.000 0.598 1.000 0.311 1.000
Aripiprazole similarity 1.000 0.834 1.000 0.380 1.000
Albuterol similarity 1.000 0.907 1.000 0.749 1.000
Mestranol similarity 1.000 0.79 1.000 0.402 1.000
C11H24 0.993 0.829 0.971 0.410 0.966
C9H10N2O2PF2Cl 0.879 0.889 0.982 0.631 0.940
Median molecules 1 0.438 0.334 0.406 0.225 0.371
Median molecules 2 0.422 0.38 0.432 0.170 0.434
Osimertinib MPO 0.907 0.886 0.953 0.784 0.995
Fexofenadine MPO 0.959 0.931 0.998 0.695 1.000
Ranolazine MPO 0.855 0.881 0.92 0.616 0.969
Perindopril MPO 0.808 0.661 0.792 0.385 0.815
Amlodipine MPO 0.894 0.722 0.894 0.533 0.902
Sitagliptin MPO 0.545 0.689 0.891 0.458 0.763
Zaleplon MPO 0.669 0.413 0.754 0.488 0.770
Valsartan SMARTS 0.978 0.552 0.990 0.04 0.994
Deco Hop 0.996 0.970 1.000 0.590 1.000
Scaffold Hop 0.998 0.885 1.000 0.478 1.000
total score 17.341 14.398 17.983 9.011 17.919

License

BSD-3

Citation

CReM: chemically reasonable mutations framework for structure generation
Pavel Polishchuk
Journal of Cheminformatics 2020, 12, (1), 28
https://doi.org/10.1186/s13321-020-00431-w

Control of Synthetic Feasibility of Compounds Generated with CReM
Pavel Polishchuk
Journal of Chemical Information and Modeling 2020, 60, 6074-6080
https://dx.doi.org/10.1021/acs.jcim.0c00792