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MCSM-LIG: QUANTIFYING THE EFFECTS OF MUTATIONS ON PROTEIN-SMALL MOLECULE AFFINITY IN GENETIC DISEASE AND EMERGENCE OF DRUG RESISTANCE.
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University of Cambridge. Sanger Building. Department of Biochemistry. Cambridge, CB, UK/ Fundação Oswaldo Cruz. Centro de Pesquisas René Rachou. Belo Horizonte, MG, Brazil
University of Cambridge. Sanger Building. Department of Biochemistry. Cambridge, CB, UK
University of Cambridge. Sanger Building. Department of Biochemistry. Cambridge, CB, UK
University of Cambridge. Sanger Building. Department of Biochemistry. Cambridge, CB, UK
University of Cambridge. Sanger Building. Department of Biochemistry. Cambridge, CB, UK
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The ability to predict how a mutation affects ligand binding is an essential step in understanding, anticipating and improving the design of new treatments for drug resistance, and in understanding genetic diseases. Here we present mCSM-lig, a structure-guided computational approach for quantifying the effects of single-point missense mutations on affinities of small molecules for proteins. mCSM-lig uses graph-based signatures to represent the wild-type environment of mutations, and small-molecule chemical features and changes in protein stability as evidence to train a predictive model using a representative set of protein-ligand complexes from the Platinum database. We show our method provides a very good correlation with experimental data (up to ρ = 0.67) and is effective in predicting a range of chemotherapeutic, antiviral and antibiotic resistance mutations, providing useful insights for genotypic screening and to guide drug development. mCSM-lig also provides insights into understanding Mendelian disease mutations and as a tool for guiding protein design. mCSM-lig is freely available as a web server at http://structure.bioc.cam.ac.uk/mcsm_lig.
HERZIG, Volker et al. Molecular basis of the remarkable species selectivity of an insecticidal sodium channel toxin from the African spider Augacephalus ezendami. Scientific Reports 6, Art. 29538, 2016
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