Cancer missense mutations alter binding properties of proteins and their interaction networks

Many studies have shown that missense mutations might play an important role in carcinogenesis. However, the extent to which cancer mutations might affect biomolecular interactions remains unclear. Here, we map glioblastoma missense mutations on the human protein interactome, model the structures of...

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Veröffentlicht in:	PloS one 2013-06, Vol.8 (6), p.e66273
Hauptverfasser:	Nishi, Hafumi, Tyagi, Manoj, Teng, Shaolei, Shoemaker, Benjamin A, Hashimoto, Kosuke, Alexov, Emil, Wuchty, Stefan, Panchenko, Anna R
Format:	Artikel
Sprache:	eng
Schlagworte:	Acids Amino acid sequence Amino acids Analysis Artificial Intelligence Binding Sites Bioinformatics Biology Biomarkers Biophysics Biotechnology Brain cancer Cancer Carcinogenesis Carcinogens Chemical properties DNA-Binding Proteins - chemistry DNA-Binding Proteins - genetics DNA-Binding Proteins - metabolism Energy (Physics) Genes Genomes Glioblastoma Glioblastoma - genetics Glioblastoma - metabolism Gliomas Humans Interfaces Medicine Missense mutation Models, Biological Mutation Mutation, Missense National libraries Nervous system Network analysis Nucleic acids Phenotype Physicochemical properties Protein Binding Protein Interaction Domains and Motifs - genetics Protein Interaction Maps Protein Stability Proteins Thermodynamics Transduction Turnover rate
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creator	Nishi, Hafumi Tyagi, Manoj Teng, Shaolei Shoemaker, Benjamin A Hashimoto, Kosuke Alexov, Emil Wuchty, Stefan Panchenko, Anna R
description	Many studies have shown that missense mutations might play an important role in carcinogenesis. However, the extent to which cancer mutations might affect biomolecular interactions remains unclear. Here, we map glioblastoma missense mutations on the human protein interactome, model the structures of affected protein complexes and decipher the effect of mutations on protein-protein, protein-nucleic acid and protein-ion binding interfaces. Although some missense mutations over-stabilize protein complexes, we found that the overall effect of mutations is destabilizing, mostly affecting the electrostatic component of binding energy. We also showed that mutations on interfaces resulted in more drastic changes of amino acid physico-chemical properties than mutations occurring outside the interfaces. Analysis of glioblastoma mutations on interfaces allowed us to stratify cancer-related interactions, identify potential driver genes, and propose two dozen additional cancer biomarkers, including those specific to functions of the nervous system. Such an analysis also offered insight into the molecular mechanism of the phenotypic outcomes of mutations, including effects on complex stability, activity, binding and turnover rate. As a result of mutated protein and gene network analysis, we observed that interactions of proteins with mutations mapped on interfaces had higher bottleneck properties compared to interactions with mutations elsewhere on the protein or unaffected interactions. Such observations suggest that genes with mutations directly affecting protein binding properties are preferably located in central network positions and may influence critical nodes and edges in signal transduction networks.
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subjects	Acids Amino acid sequence Amino acids Analysis Artificial Intelligence Binding Sites Bioinformatics Biology Biomarkers Biophysics Biotechnology Brain cancer Cancer Carcinogenesis Carcinogens Chemical properties DNA-Binding Proteins - chemistry DNA-Binding Proteins - genetics DNA-Binding Proteins - metabolism Energy (Physics) Genes Genomes Glioblastoma Glioblastoma - genetics Glioblastoma - metabolism Gliomas Humans Interfaces Medicine Missense mutation Models, Biological Mutation Mutation, Missense National libraries Nervous system Network analysis Nucleic acids Phenotype Physicochemical properties Protein Binding Protein Interaction Domains and Motifs - genetics Protein Interaction Maps Protein Stability Proteins Thermodynamics Transduction Turnover rate
title	Cancer missense mutations alter binding properties of proteins and their interaction networks
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