A Pseudohypervalent Sulfur Intermediate as an Oxidative Protective Mechanism in the Archaea Peroxiredoxin Enzyme ApTPx.

Peroxiredoxins (Prxs) are a ubiquitous class of enzymes that have central roles in a number of important physiological processes. Using a multiscale computational approach, we have investigated the mechanism by which the active-site cysteine (Cys50) in the typical 2-Cys Prx from Archaea (ApTPx) is oxidized by H2O2 to sulfenic acid. In addition, its further oxidation to give a sulfinic acid and its possible alternate intramolecular reaction to form an experimentally proposed hypervalent sulfurane were examined. Oxidation of Cys50 by H2O2 to give the sulfenic acid intermediate occurs in one step with a barrier of 82.1 kJ mol-1. A two-step pathway is proposed with a very low barrier of 16.5 kJ mol-1 by which it can subsequently react with an adjacent histidyl (His42) to form the pseudohypervalent sulfurane. This pathway also involves an adjacent aspartyl (Asp45), which helps alternate the protonation state of His42. The sulfurane's Cys50S···NδHis42 interaction was characterized using QTAIM, NCI, and NBO analyses and found to be a noncovalent interaction. Notably, this bond helps orient the Cys50SOH moiety such that it is less susceptible to oxidation by H2O2 to sulfinic acid. Significantly, sulfurane formation is energetically favored to further H2O2 oxidation of Cys50SOH to a sulfinic acid, providing a mechanism by which the active-site Cys50 is protected against overoxidation.

Substrate-Assisted and Enzymatic Pretransfer Editing of Nonstandard Amino Acids by Methionyl-tRNA Synthetase.

Aminoacyl-tRNA synthetases (aaRSs) are central to a number of physiological processes, including protein biosynthesis. In particular, they activate and then transfer their corresponding amino acid to the cognate tRNA. This is achieved with a generally remarkably high fidelity by editing against incorrect standard and nonstandard amino acids. Using docking, molecular dynamics (MD), and hybrid quantum mechanical/molecular mechanics methods, we have investigated mechanisms by which methionyl-tRNA synthetase (MetRS) may edit against the highly toxic, noncognate, amino acids homocysteine (Hcy) and its oxygen analogue, homoserine (Hse). Substrate-assisted editing of Hcy-AMP in which its own phosphate acts as the mechanistic base occurs with a rate-limiting barrier of 98.2 kJ mol(-1). This step corresponds to nucleophilic attack of the Hcy side-chain sulfur at its own carbonyl carbon (CCarb). In contrast, a new possible editing mechanism is identified in which an active site aspartate (Asp259) acts as the base. The rate-limiting step is now rotation about the substrate's aminoacyl Cß-Cγ bond with a barrier of 27.5 kJ mol(-1), while for Hse-AMP, the rate-limiting step is cleavage of the CCarb-OP bond with a barrier of 30.9 kJ mol(-1). A similarly positioned aspartate or glutamate also occurs in the homologous enzymes LeuRS, IleRS, and ValRS, which also discriminate against Hcy. Docking and MD studies suggest that at least in the case of LeuRS and ValRS, a similar editing mechanism may be possible.