Motivation: The prediction of biologically active compounds is of great importance for high-throughput screening (HTS) approaches in drug discovery and chemical genomics. Many computational methods in this area focus on measuring the structural similarities between chemical structures. However, traditional similarity measures are often too rigid or consider only global similarities between structures. The maximum common substructure (MCS) approach provides a more promising and flexible alternative for predicting bioactive compounds

Altman

Barrow

Berretti

Blower

Bunke

Burden

Carhart

Chen

Cheng

Christianini

Cone

Conte

Cordella

Dean

Deshpande

Dimitriadou

Dobson

Dumay

Engels

Garey

Girke

Gonzalez

Hagadone

Holder

James

Johnson

King

Koch

Levi

McGregor

Moriguchi

Provost

Raymond

Sheridan

Tao Jiang

Thomas Girke

Tsai

Wang

Wheeler

Willett

Wilson

Yiqun Cao

English

PubMed

MotivationThe prediction of biologically active compounds is of great importance for high-throughput screening (HTS) approaches in drug discovery and chemical genomics. Many computational methods in this area focus on measuring the structural similarities between chemical structures. However, traditional similarity measures are often too rigid or consider only global similarities between structures. The maximum common substructure (MCS) approach provides a more promising and flexible alternative for predicting bioactive compounds.ResultsIn this article, a new backtracking algorithm for MCS is proposed and compared to global similarity measurements. Our algorithm provides high flexibility in the matching process, and it is very efficient in identifying local structural similarities. To predict and cluster biologically active compounds more efficiently, the concept of basis compounds is proposed that enables researchers to easily combine the MCS-based and traditional similarity measures with modern machine learning techniques. Support vector machines (SVMs) are used to test how the MCS-based similarity measure and the basis compound vectorization method perform on two empirically tested datasets. The test results show that MCS complements the well-known atom pair descriptor-based similarity measure. By combining these two measures, our SVM-based model predicts the biological activities of chemical compounds with higher specificity and sensitivity.Supplementary informationSupplementary data are available at Bioinformatics online

Cao, Yiqun

Jiang, Tao

Girke, Thomas

eScholarship - University of California

A maximum common substructure-based algorithm for searching and predicting drug-like compounds

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A maximum common substructure-based algorithm for searching and predicting drug-like compounds

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