Cytochrome P450 Site of Metabolism Prediction from 2D Topological Fingerprints Using GPU Accelerated Probabilistic Classifiers

Overview

Journal J Cheminform

Publisher Biomed Central

Specialty Chemistry

Date 2014 Jun 25

PMID 24959208

Citations 10

Authors

Jonathan D Tyzack

Hamse Y Mussa

Mark J Williamson

Johannes Kirchmair

Robert C Glen

Affiliations

Soon will be listed here.

Abstract

Background: The prediction of sites and products of metabolism in xenobiotic compounds is key to the development of new chemical entities, where screening potential metabolites for toxicity or unwanted side-effects is of crucial importance. In this work 2D topological fingerprints are used to encode atomic sites and three probabilistic machine learning methods are applied: Parzen-Rosenblatt Window (PRW), Naive Bayesian (NB) and a novel approach called RASCAL (Random Attribute Subsampling Classification ALgorithm). These are implemented by randomly subsampling descriptor space to alleviate the problem often suffered by data mining methods of having to exactly match fingerprints, and in the case of PRW by measuring a distance between feature vectors rather than exact matching. The classifiers have been implemented in CUDA/C++ to exploit the parallel architecture of graphical processing units (GPUs) and is freely available in a public repository.

Results: It is shown that for PRW a SoM (Site of Metabolism) is identified in the top two predictions for 85%, 91% and 88% of the CYP 3A4, 2D6 and 2C9 data sets respectively, with RASCAL giving similar performance of 83%, 91% and 88%, respectively. These results put PRW and RASCAL performance ahead of NB which gave a much lower classification performance of 51%, 73% and 74%, respectively.

Conclusions: 2D topological fingerprints calculated to a bond depth of 4-6 contain sufficient information to allow the identification of SoMs using classifiers based on relatively small data sets. Thus, the machine learning methods outlined in this paper are conceptually simpler and more efficient than other methods tested and the use of simple topological descriptors derived from 2D structure give results competitive with other approaches using more expensive quantum chemical descriptors. The descriptor space subsampling approach and ensemble methodology allow the methods to be applied to molecules more distant from the training data where data mining would be more likely to fail due to the lack of common fingerprints. The RASCAL algorithm is shown to give equivalent classification performance to PRW but at lower computational expense allowing it to be applied more efficiently in the ensemble scheme.

Citing Articles

Prediction of UGT-mediated Metabolism Using the Manually Curated MetaQSAR Database.

Mazzolari A, Afzal A, Pedretti A, Testa B, Vistoli G, Bender A ACS Med Chem Lett. 2019; 10(4):633-638.

PMID: 30996809 PMC: 6466832. DOI: 10.1021/acsmedchemlett.8b00603.

Computational methods and tools to predict cytochrome P450 metabolism for drug discovery.

Tyzack J, Kirchmair J Chem Biol Drug Des. 2018; 93(4):377-386.

PMID: 30471192 PMC: 6590657. DOI: 10.1111/cbdd.13445.

QNA-Based Prediction of Sites of Metabolism.

Tarasova O, Rudik A, Dmitriev A, Lagunin A, Filimonov D, Poroikov V Molecules. 2017; 22(12).

PMID: 29194399 PMC: 6149875. DOI: 10.3390/molecules22122123.

G.A.M.E.: GPU-accelerated mixture elucidator.

Schurz A, Su B, Tu Y, Lu T, Lin O, Tseng Y J Cheminform. 2017; 9(1):50.

PMID: 29086161 PMC: 5602814. DOI: 10.1186/s13321-017-0238-7.

Predicting the Metabolic Sites by Flavin-Containing Monooxygenase on Drug Molecules Using SVM Classification on Computed Quantum Mechanics and Circular Fingerprints Molecular Descriptors.

Fu C, Lin T PLoS One. 2017; 12(1):e0169910.

PMID: 28072829 PMC: 5224990. DOI: 10.1371/journal.pone.0169910.

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