PTML Model of ChEMBL Compounds Assays for Vitamin Derivatives

Ricardo Santana; Robin Zuluaga; Piedad Gañán; Sonia Arrasate; Enrique Onieva Caracuel; Humbert González-Díaz

doi:10.1021/acscombsci.9b00166

PTML Model of ChEMBL Compounds Assays for Vitamin Derivatives

ACS Comb Sci. 2020 Mar 9;22(3):129-141. doi: 10.1021/acscombsci.9b00166. Epub 2020 Feb 13.

Authors

Ricardo Santana^{1

2}, Robin Zuluaga³, Piedad Gañán⁴, Sonia Arrasate⁵, Enrique Onieva Caracuel¹, Humbert González-Díaz^{5

6}

Affiliations

¹ DeustoTech-Fundación Deusto, Avda. Universidades, 24, 48007 Bilbao, Spain.
² Grupo de Investigación sobre Nuevos Materiales, Universidad Pontificia Bolivariana UPB, 050031, Medellín, Colombia.
³ Facultad de Ingeniería Agroindustrial, Universidad Pontificia Bolivariana UPB, 050031, Medellín, Colombia.
⁴ Facultad de Ingeniería Química, Universidad Pontificia Bolivariana UPB, 050031, Medellín, Colombia.
⁵ Department of Organic Chemistry II, University of Basque Country UPV/EHU, 48940, Leioa, Spain.
⁶ IKERBASQUE, Basque Foundation for Science, 48011, Bilbao, Spain.

PMID: 32011854
DOI: 10.1021/acscombsci.9b00166

Abstract

Determining the biological activity of vitamin derivatives is needed given that organic synthesis of analogs of vitamins is an active field of interest for medicinal chemistry, pharmaceuticals, and food additives. Accordingly, scientists from different disciplines perform preclinical assays (n_ij) with a considerable combination of assay conditions (c_j). Indeed, the ChEMBL platform contains a database that includes results from 36 220 different biological activity bioassays of 21 240 different vitamins and vitamin derivatives. These assays present are heterogeneous in terms of assay combinations of c_j. They are focused on >500 different biological activity parameters (c₀), >340 different targets (c₁), >6200 types of cell (c₂), >120 organisms of assay (c₃), and >60 assay strains (c₄). It includes a total of >1850 niacin assays, >1580 tretinoin assays, >1580 retinol assays, 857 ascorbic acid assays, etc. Given the complexity of this combinatorial data in terms of being assimilated by researchers, we propose to build a model by combining perturbation theory (PT) and machine learning (ML). Through this study, we propose a PTML (PT + ML) combinatorial model for ChEMBL results on biological activity of vitamins and vitamins derivatives. The linear discriminant analysis (LDA) model presented the following results for training subset a: specificity (%) = 90.38, sensitivity (%) = 87.51, and accuracy (%) = 89.89. The model showed the following results for the external validation subset: specificity (%) = 90.58, sensitivity (%) = 87.72, and accuracy (%) = 90.09. Different types of linear and nonlinear PTML models, such as logistic regression (LR), classification tree (CT), näive Bayes (NB), and random Forest (RF), were applied to contrast the capacity of prediction. The PTML-LDA model predicts with more accuracy by applying combinatorial descriptors. In addition, a PCA experiment with chemical structure descriptors allowed us to characterize the high structural diversity of the chemical space studied. In any case, PTML models using chemical structure descriptors do not improve the performance of the PTML-LDA model based on ALOGP and PSA. We can conclude that the three variable PTML-LDA model is a simplified and adaptable tool for the prediction, for different experiment combinations, the biological activity of derivative vitamins.

Keywords: ChEMBL; big data; machine learning; multitarget models; perturbation theory; vitamins.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Bayes Theorem*
Combinatorial Chemistry Techniques*
Databases, Factual
Machine Learning*
Models, Statistical*
Molecular Structure
Vitamins / chemical synthesis
Vitamins / chemistry*

Substances

Vitamins