Disease-associated mutations disrupt functionally important regions of intrinsic protein disorder

The effects of disease mutations on protein structure and function have been extensively investigated, and many predictors of the functional impact of single amino acid substitutions are publicly available. The majority of these predictors are based on protein structure and evolutionary conservation...

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Bibliographic Details
Published in:PLoS computational biology 2012-10, Vol.8 (10), p.e1002709-e1002709
Main Authors: Vacic, Vladimir, Markwick, Phineus R L, Oldfield, Christopher J, Zhao, Xiaoyue, Haynes, Chad, Uversky, Vladimir N, Iakoucheva, Lilia M
Format: Article
Language:English
Subjects:
Arginine - genetics
Biology
Cluster Analysis
Computational Biology
Disease
Disease - genetics
Entropy
Gene mutations
Health aspects
Humans
Models, Genetic
Molecular Dynamics Simulation
Mutation
Physiological aspects
Protein Conformation
Proteins
Proteins - chemistry
Proteins - genetics
Proteins - metabolism
Proteomics
Sequence Analysis, DNA
Studies
Transcription Factors
Tumor Suppressor Proteins
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Summary:The effects of disease mutations on protein structure and function have been extensively investigated, and many predictors of the functional impact of single amino acid substitutions are publicly available. The majority of these predictors are based on protein structure and evolutionary conservation, following the assumption that disease mutations predominantly affect folded and conserved protein regions. However, the prevalence of the intrinsically disordered proteins (IDPs) and regions (IDRs) in the human proteome together with their lack of fixed structure and low sequence conservation raise a question about the impact of disease mutations in IDRs. Here, we investigate annotated missense disease mutations and show that 21.7% of them are located within such intrinsically disordered regions. We further demonstrate that 20% of disease mutations in IDRs cause local disorder-to-order transitions, which represents a 1.7-2.7 fold increase compared to annotated polymorphisms and neutral evolutionary substitutions, respectively. Secondary structure predictions show elevated rates of transition from helices and strands into loops and vice versa in the disease mutations dataset. Disease disorder-to-order mutations also influence predicted molecular recognition features (MoRFs) more often than the control mutations. The repertoire of disorder-to-order transition mutations is limited, with five most frequent mutations (R→W, R→C, E→K, R→H, R→Q) collectively accounting for 44% of all deleterious disorder-to-order transitions. As a proof of concept, we performed accelerated molecular dynamics simulations on a deleterious disorder-to-order transition mutation of tumor protein p63 and, in agreement with our predictions, observed an increased α-helical propensity of the region harboring the mutation. Our findings highlight the importance of mutations in IDRs and refine the traditional structure-centric view of disease mutations. The results of this study offer a new perspective on the role of mutations in disease, with implications for improving predictors of the functional impact of missense mutations.
ISSN:1553-7358
1553-734X
1553-7358
DOI:10.1371/journal.pcbi.1002709