A community computational challenge to predict the activity of pairs of compounds

NCI-DREAM Community; Mukesh Bansal; Jichen Yang; Charles Karan; Michael P. Menden; James C. Costello; Hao Tang; Guanghua Xiao; Jun Li; Jeffrey D. Allen; Rui Zhong; Beibei Chen; Minsoo Kim; Tao Wang; Laura M. Heiser; Ronald Realubit; Michela Mattioli; Mariano J. Alvarez; Yao Shen; Daniel Gallahan; Dinah S. Singer; Julio Sáez-Rodríguez; Yang Xie; Gustavo Stolovitzky; Andrea Califano

doi:10.1038/nbt.3052

A community computational challenge to predict the activity of pairs of compounds

NCI-DREAM Community(Columbia University), Mukesh Bansal(Columbia University), Jichen Yang(High Throughput Biology (United States)), Charles Karan(European Bioinformatics Institute), Michael P. Menden(Boston University), James C. Costello(Howard Hughes Medical Institute), Hao Tang(The University of Texas Southwestern Medical Center), Guanghua Xiao(The University of Texas Southwestern Medical Center), Jun Li(The University of Texas Southwestern Medical Center), Jeffrey D. Allen(The University of Texas Southwestern Medical Center), Rui Zhong(The University of Texas Southwestern Medical Center), Beibei Chen(The University of Texas Southwestern Medical Center), Minsoo Kim(The University of Texas Southwestern Medical Center), Tao Wang(Oregon Health & Science University), Laura M. Heiser(Oregon Health & Science University), Ronald Realubit(Italian Institute of Technology), Michela Mattioli(Italian Institute of Technology), Mariano J. Alvarez(Columbia University), Yao Shen(National Cancer Institute), Daniel Gallahan(National Cancer Institute), Dinah S. Singer(European Bioinformatics Institute), Julio Sáez-Rodríguez(European Bioinformatics Institute), Yang Xie(IBM (United States)), Gustavo Stolovitzky(IBM (United States)), Andrea Califano(Columbia University)

Nature Biotechnology

November 17, 2014

10.1038/nbt.3052

Cited by 338Open Access

Full Text

Abstract

Recent therapeutic successes have renewed interest in drug combinations, but experimental screening approaches are costly and often identify only small numbers of synergistic combinations. The DREAM consortium launched an open challenge to foster the development of in silico methods to computationally rank 91 compound pairs, from the most synergistic to the most antagonistic, based on gene-expression profiles of human B cells treated with individual compounds at multiple time points and concentrations. Using scoring metrics based on experimental dose-response curves, we assessed 32 methods (31 community-generated approaches and SynGen), four of which performed significantly better than random guessing. We highlight similarities between the methods. Although the accuracy of predictions was not optimal, we find that computational prediction of compound-pair activity is possible, and that community challenges can be useful to advance the field of in silico compound-synergy prediction.

Related Papers

No related papers found

Powered by citation graph analysis