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Multi-model functionalization of disease-associated PTEN missense mutations identifies multiple molecular mechanisms underlying protein dysfunction.

Kathryn L PostManuel BelmadaniPayel GangulyFabian MeiliRiki DingwallTroy A McDiarmidWarren M MeyersCaitlin HerringtonBarry Paul YoungDaniel B CallaghanSanja RogicMatthew EdwardsAna NiciforovicAlessandro CauCatharine H RankinTimothy P O'ConnorShernaz X BamjiChristopher J R LoewenDouglas W AllanPaul PavlidisKurt Haas
Published in: Nature communications (2020)
Functional variomics provides the foundation for personalized medicine by linking genetic variation to disease expression, outcome and treatment, yet its utility is dependent on appropriate assays to evaluate mutation impact on protein function. To fully assess the effects of 106 missense and nonsense variants of PTEN associated with autism spectrum disorder, somatic cancer and PTEN hamartoma syndrome (PHTS), we take a deep phenotypic profiling approach using 18 assays in 5 model systems spanning diverse cellular environments ranging from molecular function to neuronal morphogenesis and behavior. Variants inducing instability occur across the protein, resulting in partial-to-complete loss-of-function (LoF), which is well correlated across models. However, assays are selectively sensitive to variants located in substrate binding and catalytic domains, which exhibit complete LoF or dominant negativity independent of effects on stability. Our results indicate that full characterization of variant impact requires assays sensitive to instability and a range of protein functions.
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