Abstract
Molecular recognition between the aminoacyl-tRNA synthetase enzymes and their cognate amino acid ligands is essential for the faithful translation of the genetic code. In aspartyl-tRNA synthetase (AspRS), the co-substrate ATP binds preferentially with three associated Mg2+ cations in an unusual, bent geometry. The Mg2+ cations play a structural role and are thought to also participate catalytically in the enzyme reaction. Co-binding of the ATP x Mg3(2+) complex was shown recently to increase the Asp/Asn binding free energy difference, indicating that amino acid discrimination is substrate-assisted. Here, we used molecular dynamics free energy simulations and continuum electrostatic calculations to resolve two related questions. First, we showed that if one of the Mg2+ cations is removed, the Asp/Asn binding specificity is strongly reduced. Second, we computed the relative stabilities of the three-cation complex and the 2-cation complexes. We found that the 3-cation complex is overwhelmingly favored at ordinary magnesium concentrations, so that the protein is protected against the 2-cation state. In the homologous LysRS, the 3-cation complex was also strongly favored, but the third cation did not affect Lys binding. In tRNA-bound AspRS, the single remaining Mg2+ cation strongly favored the Asp-adenylate substrate relative to Asn-adenylate. Thus, in addition to their structural and catalytic roles, the Mg2+ cations contribute to specificity in AspRS through long range electrostatic interactions with the Asp side chain in both the pre- and post-adenylation states.
Highlights
Specific molecular association is fundamental to many biochemical processes and is frequently used to transfer energy or information
We find that ATP binding in a completely bent conformation with three associated Mg2ϩ cations is a characteristic property of class II Aminoacyl-tRNA synthetases (aaRSs)
We report the calculations to compare AspAMP and AsnAMP binding to AspRS1⁄7tRNA in the presence of one or no co-bound Mg2ϩ cations
Summary
The specificity of Asp binding to AspRS is governed by the binding free energy difference between the cognate Asp and competitor ligands This difference can be obtained from molecular dynamics free energy simulations (MDFE), which have matured enormously in recent years and have been used to study several aaRSs. Extensive studies [33,34,35] show that when the AspRS binding pocket is in the “open” state (open flipping loop), there is an enormous preference for Asp over Asn, thanks to a network of electrostatic interactions in the active site. The present article focuses on the precise stability of the ATP-associated Mg2ϩ cations in the AspRS structure and their role in the thermodynamics of Asp and Asn binding. We find that ATP binding in a completely bent conformation with three associated Mg2ϩ cations is a characteristic property of class II aaRSs
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