Project description:Prolyl-tRNA synthetases (ProRSs) catalyze the covalent attachment of proline onto cognate tRNAs, an indispensable step for protein synthesis in all living organisms. ProRSs are modular enzymes and the "prokaryotic-like" ProRSs are distinguished from "eukaryotic-like" ProRSs by the presence of an editing domain (INS) inserted between motifs 2 and 3 of the main catalytic domain. Earlier studies suggested the presence of coupled-domain dynamics could contribute to catalysis; however, the role that the distal, highly mobile INS domain plays in catalysis at the synthetic active site is not completely understood. In the present study, a combination of theoretical and experimental approaches has been used to elucidate the precise role of INS domain dynamics. Quantum mechanical/molecular mechanical simulations were carried out to model catalytic Pro-AMP formation by Enterococcus faecalis ProRS. The energetics of the adenylate formation by the wild-type enzyme was computed and contrasted with variants containing active site mutations, as well as a deletion mutant lacking the INS domain. The combined results revealed that two distinct types of dynamics contribute to the enzyme's catalytic power. One set of motions is intrinsic to the INS domain and leads to conformational preorganization that is essential for catalysis. A second type of motion, stemming from the electrostatic reorganization of active site residues, impacts the height and width of the energy profile and has a critical role in fine tuning the substrate orientation to facilitate reactive collisions. Thus, motions in a distal domain can preorganize the active site of an enzyme to optimize catalysis.

Project description:To ensure high fidelity in translation, many aminoacyl-tRNA synthetases, enzymes responsible for attaching specific amino acids to cognate tRNAs, require proof-reading mechanisms. Most bacterial prolyl-tRNA synthetases (ProRSs) misactivate alanine and employ a post-transfer editing mechanism to hydrolyze Ala-tRNA(Pro). This reaction occurs in a second catalytic site (INS) that is distinct from the synthetic active site. The 2'-OH of misacylated tRNA(Pro) and several conserved residues in the Escherichia coli ProRS INS domain are directly involved in Ala-tRNA(Pro) deacylation. Although mutation of the strictly conserved lysine 279 (K279) results in nearly complete loss of post-transfer editing activity, this residue does not directly participate in Ala-tRNA(Pro) hydrolysis. We hypothesized that the role of K279 is to bind the phosphate backbone of the acceptor stem of misacylated tRNA(Pro) and position it in the editing active site. To test this hypothesis, we carried out pKa, charge neutralization, and free-energy of binding calculations. Site-directed mutagenesis and kinetic studies were performed to verify the computational results. The calculations revealed a considerably higher pKa of K279 compared to an isolated lysine and showed that the protonated state of K279 is stabilized by the neighboring acidic residue. However, substitution of this acidic residue with a positively charged residue leads to a significant increase in Ala-tRNA(Pro) hydrolysis, suggesting that enhancement in positive charge density in the vicinity of K279 favors tRNA binding. A charge-swapping experiment and free energy of binding calculations support the conclusion that the positive charge at position 279 is absolutely necessary for tRNA binding in the editing active site.

Project description:Aminoacyl-tRNA synthetases (ARSs) enhance the fidelity of protein synthesis through multiple mechanisms, including hydrolysis of the adenylate and cleavage of misacylated tRNA. Alanyl-tRNA synthetase (AlaRS) limits misacylation with glycine and serine by use of a dedicated editing domain, and a mutation in this activity has been genetically linked to a mouse model of a progressive neurodegenerative disease. Using the free-standing Pyrococcus horikoshii AlaX editing domain complexed with serine as a model and both Ser-tRNA(Ala) and Ala-tRNA(Ala) as substrates, the deacylation activities of the wild type and five different Escherichia coli AlaRS editing site substitution mutants were characterized. The wild-type AlaRS editing domain deacylated Ser-tRNA(Ala) with a k(cat)/K(M) of 6.6 × 10(5) M(-1) s(-1), equivalent to a rate enhancement of 6000 over the rate of enzyme-independent deacylation but only 12.2-fold greater than the rate with Ala-tRNA(Ala). While the E664A and T567G substitutions only minimally decreased k(cat)/K(M,) Q584H, I667E, and C666A AlaRS were more compromised in activity, with decreases in k(cat)/K(M) in the range of 6-, 6.6-, and 15-fold. C666A AlaRS was 1.7-fold more active on Ala-tRNA(Ala) relative to Ser-tRNA(Ala), providing the only example of a true reversal of substrate specificity and highlighting a potential role of the coordinated zinc in editing substrate specificity. Along with the potentially serious physiological consequences of serine misincorporation, the relatively modest specificity of the AlaRS editing domain may provide a rationale for the widespread phylogenetic distribution of AlaX free-standing editing domains, thereby contributing a further mechanism to lower concentrations of misacylated tRNA(Ala).

Project description:Alanyl-tRNA synthetase (AlaRS) catalyzes synthesis of Ala-tRNA(Ala) and hydrolysis of mis-acylated Ser- and Gly-tRNA(Ala) at 2 different catalytic sites. Here, we describe the monomer structures of C-terminal truncated archaeal AlaRS, with both activation and editing domains in the apo form, in complex with an Ala-AMP analog, and in a high-resolution lysine-methylated form. The structures show docking of the editing domain to the activation domain opposite from the predicted tRNA-binding surface. Thus, the editing site is positioned >35 A from the activation site, prompting us to model 2 different tRNA complexes: one binding tRNA at the activation site, and the other binding tRNA at the editing site. Interestingly, a gel-shift assay also implies the presence of 2 types of tRNA complex with different mobility. These results suggest that tRNA translocation via a canonical CCA flipping is unlikely to occur in AlaRS. The structure also demonstrated the binding of zinc in the editing site, in which the specific coordination of zinc would be facilitated by a conserved GGQ motif, implying that the editing mechanism may not be the same as in ThrRS. As Asn-194 in eubacterial AlaRS important for Ser misactivation is replaced by Thr-213 in archaeal AlaRS, a different Ser accommodation mechanism is proposed.

Project description:The accuracy of in vivo incorporation of amino acids during protein biosynthesis is controlled to a significant extent by aminoacyl-tRNA synthetases (aaRS). This paper describes the application of the HierDock computational method to study the molecular basis of amino acid binding to the Escherichia coli methionyl tRNA synthetase (MetRS). Starting with the protein structure from the MetRS cocrystal, the HierDock calculations predict the binding site of methionine in MetRS to a root mean square deviation in coordinates (CRMS) of 0.55 A for all the atoms, compared with the crystal structure. The MetRS conformation in the cocrystal structure shows good discrimination between cognate and the 19 noncognate amino acids. In addition, the calculated binding energies of a set of five methionine analogs show a good correlation (R(2) = 0.86) to the relative free energies of binding derived from the measured in vitro kinetic parameters, K(m) and k(cat). Starting with the crystal structure of MetRS without the methionine (apo-MetRS), the putative binding site of methionine was predicted. We demonstrate that even the apo-MetRS structure shows a preference for binding methionine compared with the 19 other natural amino acids. On comparing the calculated binding energies of the 20 natural amino acids for apo-MetRS with those for the cocrystal structure, we observe that the discrimination against the noncognate substrate increases dramatically in the second step of the physical binding process associated with the conformation change in the protein.

Project description:About 1 billion years ago, in a single-celled holozoan ancestor of all animals, a gene fusion of two tRNA synthetases formed the bifunctional enzyme, glutamyl-prolyl-tRNA synthetase (EPRS). We propose here that a confluence of metabolic, biochemical, and environmental factors contributed to the specific fusion of glutamyl- (ERS) and prolyl- (PRS) tRNA synthetases. To test this idea, we developed a mathematical model that centers on the precursor-product relationship of glutamic acid and proline, as well as metabolic constraints on free glutamic acid availability near the time of the fusion event. Our findings indicate that proline content increased in the proteome during the emergence of animals, thereby increasing demand for free proline. Together, these constraints contributed to a marked cellular depletion of glutamic acid and its products, with potentially catastrophic consequences. In response, an ancient organism invented an elegant solution in which genes encoding ERS and PRS fused to form EPRS, forcing coexpression of the two enzymes and preventing lethal dysregulation. The substantial evolutionary advantage of this coregulatory mechanism is evidenced by the persistence of EPRS in nearly all extant animals.

Project description:To guarantee specific tRNA and amino acid pairing, several aminoacyl-tRNA synthetases correct aminoacylation errors by deacylating or "editing" misaminoacylated tRNA. A previously developed variant of Escherichia coli tyrosyl-tRNA synthetase (iodoTyrRS) esterifies or "charges" tRNA(Tyr) with a nonnatural amino acid, 3-iodo-l-tyrosine, and with l-tyrosine less efficiently. In the present study, the editing domain of phenylalanyl-tRNA synthetase (PheRS) was transplanted into iodoTyrRS to edit tyrosyl-tRNA(Tyr) and thereby improve the overall specificity for 3-iodo-l-tyrosine. The beta-subunit fragments of the PheRSs from Pyrococcus horikoshii and two bacteria were tested for editing activity. The isolated B3/4 editing domain of the archaeal PheRS, which was exogenously added to the tyrosylation reaction with iodoTyrRS, efficiently reduced the production of tyrosyl-tRNA(Tyr). In addition, the transplantation of this domain into iodoTyrRS at the N terminus prevented tyrosyl-tRNA(Tyr) production most strongly among the tested fragments. We next transplanted this archaeal B3/4 editing domain into iodoTyrRS at several internal positions. Transplantation into the connective polypeptide in the Rossmann-fold domain generated a variant that efficiently charges tRNA(Tyr) with 3-iodo-l-tyrosine, but hardly produces tyrosyl-tRNA(Tyr). This variant, iodoTyrRS-ed, was used, together with an amber suppressor derived from tRNA(Tyr), in a wheat germ cell-free translation system and incorporated 3-iodo-l-tyrosine, but not l-tyrosine, in response to the amber codon. Thus, the editing-domain transplantation achieved unambiguous pairing between the tRNA and the nonnatural amino acid in an expanded genetic code.

Project description:Aminoacyl-tRNA synthetases activate specific amino acid substrates and attach them via an ester linkage to cognate tRNA molecules. In addition to cognate proline, prolyl-tRNA synthetase (ProRS) can activate cysteine and alanine and misacylate tRNA(Pro). Editing of the misacylated aminoacyl-tRNA is required for error-free protein synthesis. An editing domain (INS) appended to bacterial ProRS selectively hydrolyzes Ala-tRNA(Pro), whereas Cys-tRNA(Pro) is cleared by a freestanding editing domain, YbaK, through a unique mechanism involving substrate sulfhydryl chemistry. The detailed mechanism of catalysis by INS is currently unknown. To understand the alanine specificity and mechanism of catalysis by INS, we have explored several possible mechanisms of Ala-tRNA(Pro) deacylation via hybrid QM/MM calculations. Experimental studies were also performed to test the role of several residues in the INS active site as well as various substrate functional groups in catalysis. Our results support a critical role for the tRNA 2'-OH group in substrate binding and catalytic water activation. A role is also proposed for the protein's conserved GXXXP loop in transition state stabilization and for the main chain atoms of Gly261 in a proton relay that contributes substantially to catalysis.

Project description:Febrifugine, the bioactive constituent of one of the 50 fundamental herbs of traditional Chinese medicine, has been characterized for its therapeutic activity, though its molecular target has remained unknown. Febrifugine derivatives have been used to treat malaria, cancer, fibrosis and inflammatory disease. We recently demonstrated that halofuginone (HF), a widely studied derivative of febrifugine, inhibits the development of T(H)17-driven autoimmunity in a mouse model of multiple sclerosis by activating the amino acid response (AAR) pathway. Here we show that HF binds glutamyl-prolyl-tRNA synthetase (EPRS), inhibiting prolyl-tRNA synthetase activity; this inhibition is reversed by the addition of exogenous proline or EPRS. We further show that inhibition of EPRS underlies the broad bioactivities of this family of natural product derivatives. This work both explains the molecular mechanism of a promising family of therapeutics and highlights the AAR pathway as an important drug target for promoting inflammatory resolution.

Project description:The structural organization and functionality of aminoacyl-tRNA synthetases have been expanded through polypeptide additions to their core aminoacylation domain. We have identified a novel domain appended to the methionyl-tRNA synthetase (MetRS) of the intracellular pathogen Mycoplasma penetrans. Sequence analysis of this N-terminal region suggests the appended domain is an aminotransferase, which we demonstrate here. The aminotransferase domain of MpMetRS is capable of generating methionine from its α-keto acid analog, 2-keto-4-methylthiobutyrate (KMTB). The methionine thus produced can be subsequently attached to cognate tRNAMet in the MpMetRS aminoacylation domain. Genomic erosion in the Mycoplasma species has impaired many canonical biosynthetic pathways, causing them to rely on their host for numerous metabolites. It is still unclear if this bifunctional MetRS is a key part of pathogen life cycle or is a neutral consequence of the reductive evolution experienced by Mycoplasma species.