Abstract
BackgroundMutation(s) in proteins are a natural byproduct of evolution but can also cause serious diseases. Aminoacyl-tRNA synthetases (aaRSs) are indispensable components of all cellular protein translational machineries, and in humans they drive translation in both cytoplasm and mitochondria. Mutations in aaRSs have been implicated in a plethora of diseases including neurological conditions, metabolic disorders and cancer.ResultsWe have developed an algorithmic approach for genome-wide analyses of sequence substitutions that combines evolutionary, structural and functional information. This pipeline enabled us to super-annotate human aaRS mutations and analyze their linkage to health disorders. Our data suggest that in some but not all cases, aaRS mutations occur in functional and structural sectors where they can manifest their pathological effects by altering enzyme activity or causing structural instability. Further, mutations appear in both solvent exposed and buried regions of aaRSs indicating that these alterations could lead to dysfunctional enzymes resulting in abnormal protein translation routines by affecting inter-molecular interactions or by disruption of non-bonded interactions. Overall, the prevalence of mutations is much higher in mitochondrial aaRSs, and the two most often mutated aaRSs are mitochondrial glutamyl-tRNA synthetase and dual localized glycyl-tRNA synthetase. Out of 63 mutations annotated in this work, only 12 (~20%) were observed in regions that could directly affect aminoacylation activity via either binding to ATP/amino-acid, tRNA or by involvement in dimerization. Mutations in structural cores or at potential biomolecular interfaces account for ~55% mutations while remaining mutations (~25%) remain structurally un-annotated.ConclusionThis work provides a comprehensive structural framework within which most defective human aaRSs have been structurally analyzed. The methodology described here could be employed to annotate mutations in other protein families in a high-throughput manner.Electronic supplementary materialThe online version of this article (doi:10.1186/1471-2164-15-1063) contains supplementary material, which is available to authorized users.
Highlights
Mutation(s) in proteins are a natural byproduct of evolution but can cause serious diseases
We have annotated Aminoacyl-tRNA synthetases (aaRSs) mutations into four categories: (a) those likely to abrogate or disturb ligand or tRNA binding due to direct contacts with substrates/products, (b) those that are part of aaRS structural core and where a change may directly affect enzyme folding/stability, (c) those that occur at protein surfaces which will end up being interfaces during assembly of oligomers, and (d) those that do not fall into any of the above
Mutational landscape of cytoplasmic aaRSs Disease-associated mutations have been identified in four cytoplasmic aaRS enzymes so far [28]
Summary
Mutation(s) in proteins are a natural byproduct of evolution but can cause serious diseases. Aminoacyl-tRNA synthetases (aaRSs) are indispensable components of all cellular protein translational machineries, and in humans they drive translation in both cytoplasm and mitochondria. Mutations in aaRSs have been implicated in a plethora of diseases including neurological conditions, metabolic disorders and cancer. Mutation(s) in housekeeping proteins often lead to serious ailments in humans [1]. Analysis of molecular bases of mutations that lead to dysfunctional proteins is an important step towards acquiring a detailed understanding of genetic disorders. Several studies have annotated disease-causing mutations in the human genome [2,3]. Aminoacyl-tRNA synthetases (aaRSs) drive cellular protein translation by catalyzing ligation of cognate tRNA with amino-acid for use in ribosomal protein synthesis [5]. The catalytic reaction follows a two step process as follows: AA + ATP → AMP-AA + PPi AMP-AA + tRNA → tRNAAA + AMP
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