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Free keywords:
Databases, Genetic; Humans; Models, Genetic; Models, Molecular; Molecular Sequence Annotation; Molecular Structure; Mutation, Missense/*genetics; Neoplasms/*genetics/*pathology; Oncogene Proteins/*chemistry/*genetics; Polymorphism, Single Nucleotide/genetics; Protein Stability; Tumor Suppressor Proteins/*chemistry/*genetics
Abstract:
BACKGROUND: Current large-scale cancer sequencing projects have identified large numbers of somatic mutations covering an increasing number of different cancer tissues and patients. However, the characterization of these mutations at the structural and functional level remains a challenge. RESULTS: We present results from an analysis of the structural impact of frequent missense cancer mutations using an automated method. We find that inactivation of tumor suppressors in cancer correlates frequently with destabilizing mutations preferably in the core of the protein, while enhanced activity of oncogenes is often linked to specific mutations at functional sites. Furthermore, our results show that this alteration of oncogenic activity is often associated with mutations at ATP or GTP binding sites. CONCLUSIONS: With our findings we can confirm and statistically validate the hypotheses for the gain-of-function and loss-of-function mechanisms of oncogenes and tumor suppressors, respectively. We show that the distinct mutational patterns can potentially be used to pre-classify newly identified cancer-associated genes with yet unknown function.
