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

Binding mode between peptidyl-tRNA hydrolase and the peptidyl-A76 moiety of the substrate

Peptidyl-tRNA hydrolase (Pth) hydrolyzes the ester bond between the peptide and the tRNA of peptidyl-tRNA molecules, which are the products of aborted translation, to prevent cell death by recycling tRNA. Numerous studies have attempted to elucidate the substrate recognition mechanism of Pth. However, the binding mode of the peptidyl-A76 (3'-terminal adenosine of tRNA) moiety of the substrate to Pth, especially the A76 moiety, remains unclear. Here, we present the crystal structure of Thermus thermophilus Pth (TtPth) in complex with adenosine 5'-monophosphate (AMP), a mimic of A76. In addition, we show the crystal structure of TtPth in which the active site cleft interacts with the C-terminal three amino acid residues of a crystallographically related neighboring TtPth molecule. Superimposition of these two crystal structures reveals that the C-terminal carboxyl group of the neighboring TtPth molecule and the 3'-hydroxyl group of AMP are located in positions favorable for ester bond formation, and we present a TtPth⋅peptidyl-A76 complex model. The complex model agrees with many previous NMR and kinetic studies, and our site-directed mutagenesis studies support its validity. Based on these facts, we conclude that the complex model properly represents the interaction between Pth and the substrate in the reaction. Furthermore, structural comparisons suggest that the substrate recognition mode is conserved among bacterial Pths. This study provides insights into the molecular mechanism of the reaction and useful information to design new drugs targeting Pth.

Characterization of structure of peptidyl-tRNA hydrolase from Enterococcus faecium and its inhibition by a pyrrolinone compound

In bacteria, peptidyl-tRNA hydrolase (Pth, E.C. 3.1.1.29) is a ubiquitous and essential enzyme for preventing the accumulation of peptidyl-tRNA and sequestration of tRNA. Pth is an esterase that cleaves the ester bond between peptide and tRNA. Here, we present the crystal structure of Pth from Enterococcus faecium (EfPth) at a resolution of 1.92 Å. The two molecules in the asymmetric unit differ in the orientation of sidechain of N66, a conserved residue of the catalytic site. Enzymatic hydrolysis of substrate α-N-BODIPY-lysyl-tRNALys (BLT) by EfPth was characterized by Michaelis-Menten parameters KM 163.5 nM and Vmax 1.9 nM/s. Compounds having pyrrolinone scaffold were tested for inhibition of Pth and one compound, 1040-C, was found to have IC50 of 180 nM. Antimicrobial activity profiling was done for 1040-C. It exhibited equipotent activity against drug-susceptible and resistant S. aureus (MRSA and VRSA) and Enterococcus (VSE and VRE) with MICs 2-8 μg/mL. 1040-C synergized with gentamicin and the combination was effective against the gentamicin resistant S. aureus strain NRS-119. 1040-C was found to reduce biofilm mass of S. aureus to an extent similar to Vancomycin. In a murine model of infection, 1040-C was able to reduce bacterial load to an extent comparable to Vancomycin.

Unveiling the Druggable Landscape of Bacterial Peptidyl tRNA Hydrolase: Insights into Structure, Function, and Therapeutic Potential

Bacterial peptidyl tRNA hydrolase (Pth) or Pth1 emerges as a pivotal enzyme involved in the maintenance of cellular homeostasis by catalyzing the release of peptidyl moieties from peptidyl-tRNA molecules and the maintenance of a free pool of specific tRNAs. This enzyme is vital for bacterial cells and an emerging drug target for various bacterial infections. Understanding the enzymatic mechanisms and structural intricacies of bacterial Pth is pivotal in designing novel therapeutics to combat antibiotic resistance. This review provides a comprehensive analysis of the multifaceted roles of Pth in bacterial physiology, shedding light on its significance as a potential drug target. This article delves into the diverse functions of Pth, encompassing its involvement in ribosome rescue, the maintenance of a free tRNA pool in bacterial systems, the regulation of translation fidelity, and stress response pathways within bacterial systems. Moreover, it also explores the druggability of bacterial Pth, emphasizing its promise as a target for antibacterial agents and highlighting the challenges associated with developing specific inhibitors against this enzyme. Structural elucidation represents a cornerstone in unraveling the catalytic mechanisms and substrate recognition of Pth. This review encapsulates the current structural insights of Pth garnered through various biophysical techniques, such as X-ray crystallography and NMR spectroscopy, providing a detailed understanding of the enzyme's architecture and conformational dynamics. Additionally, biophysical aspects, including its interaction with ligands, inhibitors, and substrates, are discussed, elucidating the molecular basis of bacterial Pth's function and its potential use in drug design strategies. Through this review article, we aim to put together all the available information on bacterial Pth and emphasize its potential in advancing innovative therapeutic interventions and combating bacterial infections.

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 β-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-tRNA^Lys3.

Characterization of active/binding site residues of peptidyl-tRNA hydrolase using biophysical and computational studies

All mRNAs cannot be translated into full-length proteins due to ribosome-stalling that leads to release of peptidyl-tRNA which can be lethal for bacterial survival. The enzyme peptidyl-tRNA hydrolase (PtH) hydrolyses the ester bond between nascent peptide and tRNA of peptidyl-tRNA and rescues the cells from toxicity. PtH is an essential enzyme in bacteria and inhibiting this crucial enzyme can serve to combat bacterial diseases. But due to lack of understanding about the catalytic mechanism of PtH, its inhibitors have not been developed. In this work, we have carried out the binding studies of M. tuberculosis and E. coli PtH with the peptidyl-tRNA analogue (puromycin) using ITC, FTIR, CD experiments followed by docking and MD simulations to identify the potential active site residues that would help to design PtH inhibitors. Binding studies of puromycin with both PtH by ITC experiments demonstrate similar thermodynamic parameters and three fold difference in their K_D. CD and FTIR studies detected changes in secondary structure composition of PtH in the presence of puromycin with different degree of perturbation. Though interactions with puromycin are conserved in both proteins, modelling studies revealed that water mediated interactions in M. tb-PtH resulting in higher affinity to puromycin.