Structural and functional characterization of peptidyl-tRNA hydrolase from Klebsiella pneumoniae.

Klebsiella pneumoniae is a member of the ESKAPE panel of pathogens that are top priority to tackle AMR. Bacterial peptidyl tRNA hydrolase (Pth), an essential, ubiquitous enzyme, hydrolyzes the peptidyl-tRNAs that accumulate in the cytoplasm because of premature termination of translation. Pth cleaves the ester bond between 2' or 3' hydroxyl of the ribose in the tRNA and C-terminal carboxylate of the peptide, thereby making free tRNA available for repeated cycles of protein synthesis and preventing cell death by alleviating tRNA starvation. Pth structures have been determined in peptide-bound or peptide-free states. In peptide-bound state, highly conserved residues F67, N69 and N115 adopt a conformation that is conducive to their interaction with peptide moiety of the substrate. While, in peptide-free state, these residues move away from the catalytic center, perhaps, in order to facilitate release of hydrolysed peptide. Here, we present a novel X-ray crystal structure of Pth from Klebsiella pneumoniae (KpPth), at 1.89 Å resolution, in which out of the two molecules in the asymmetric unit, one reflects the peptide-bound while the other reflects peptide-free conformation of the conserved catalytic site residues. Each molecule of the protein has canonical structure with seven stranded ß-sheet structure surrounded by six α-helices. MD simulations indicate that both the forms converge over 500 ns simulation to structures with wider opening of the crevice at peptide-binding end. In solution, KpPth is monomeric and its 2D-HSQC spectrum displays a single set of well dispersed peaks. Further, KpPth was demonstrated to be enzymatically active on BODIPY-Lys-tRNALys3.

Role of methionine 71 in substrate recognition and structural integrity of bacterial peptidyl-tRNA hydrolase.

BACKGROUND: Bacterial peptidyl-tRNA hydrolase (Pth) is an essential enzyme that alleviates tRNA starvation by recycling prematurely dissociated peptidyl-tRNAs. The specificity of Pth for N-blocked-aminoacyl-tRNA has been proposed to be contingent upon conserved residue N14 forming a hydrogen bond with the carbonyl of the first peptide bond in the substrate. M71 is involved in forming a conserved hydrogen bond with N14. Other interactions facilitating this recognition are not known. METHODS: The structure, dynamics, and stability of the M71A mutant of Pth from Vibrio cholerae (VcPth) were characterized by X-ray crystallography, NMR spectroscopy, MD simulations and DSC. RESULTS: Crystal structure of M71A mutant was determined. In the structure, the dimer interface is formed by the insertion of six C-terminal residues of one molecule into the active site of another molecule. The side-chain amide of N14 was hydrogen bonded to the carbonyl of the last peptide bond formed between residues A196 and E197, and also to A71. The CSP profile of mutation was similar to that observed for the N14D mutant. M71A mutation lowered the thermal stability of the protein. CONCLUSION: Our results indicate that the interactions of M71 with N14 and H24 play an important role in optimal positioning of their side-chains relative to the peptidyl-tRNA substrate. Overall, these interactions of M71 are important for the activity, stability, and compactness of the protein. SIGNIFICANCE: The work presented provides original and new structural and dynamics information that significantly enhances our understanding of the network of interactions that govern this enzyme's activity and selectivity.