Template-based structure prediction and molecular dynamics simulation study of two mammalian Aspartyl-tRNA synthetases

Molecular dynamics simulations of cognate and non-cognate AspRS-tRNAAsp complexes

Aspartyl tRNA synthetase (AspRS), one of the 20 aminoacyl-tRNA synthetases, plays an important role in protein synthesis by catalyzing the aminoacylation reaction and synthesises Aspartyl-tRNA (tRNA^Asp). A typical three-dimensional structure of AspRS comprises three distinct domains for the recognition of cognate tRNA and catalysis, namely, anti-codon binding domain/N-terminal domain, hinge domain and catalytic domain through their interactions with anti-codon loop, D-stem and acceptor arm of cognate tRNA, respectively. In this work, we have studied the structural characteristics of each domain of AspRS to understand the recognition mechanism of tRNA^Asp using molecular dynamics simulations. The dynamics of AspRS-tRNA^Asp complexes from E.coli (cognate and non-cognate), S.cerevisiae (cognate) and T.thermophilus (non-cognate) were compared to understand the differences in recognition of cognate and non-cognate tRNAs. Our results explain that the conformational changes associated with the recognition of tRNA occur only in the cognate complexes. Among the cognate complexes, the conformational changes in yeast AspRS are highly controlled during tRNA^Asp recognition than that of in the E. coli AspRS. Moreover, the functional motions required for the tRNA recognition are observed only in the cognate complexes, and the conformational changes in AspRS and their recognition of tRNA^Asp are organism specific.Communicated by Ramaswamy H. Sarma.

MD Simulations of tRNA and Aminoacyl-tRNA Synthetases: Dynamics, Folding, Binding, and Allostery

While tRNA and aminoacyl-tRNA synthetases are classes of biomolecules that have been extensively studied for decades, the finer details of how they carry out their fundamental biological functions in protein synthesis remain a challenge. Recent molecular dynamics (MD) simulations are verifying experimental observations and providing new insight that cannot be addressed from experiments alone. Throughout the review, we briefly discuss important historical events to provide a context for how far the field has progressed over the past few decades. We then review the background of tRNA molecules, aminoacyl-tRNA synthetases, and current state of the art MD simulation techniques for those who may be unfamiliar with any of those fields. Recent MD simulations of tRNA dynamics and folding and of aminoacyl-tRNA synthetase dynamics and mechanistic characterizations are discussed. We highlight the recent successes and discuss how important questions can be addressed using current MD simulations techniques. We also outline several natural next steps for computational studies of AARS:tRNA complexes.