Abstract

Phage lysins are a source of novel antimicrobials to tackle the bacterial antibiotic-resistance crisis. The engineering of phage lysins is being explored as a game-changing technological strategy to introduce a more precise approach in the way in which antimicrobial therapy is applied. Such engineering efforts will benefit from a better understanding of lysin structure and function. In this work, the antimicrobial activity of the endolysin from Pseudomonas aeruginosa phage JG004, termed Pae87, has been characterized. This lysin had previously been identified as an antimicrobial agent candidate that is able to interact with the Gram-negative surface and disrupt it. Further evidence is provided here based on a structural and biochemical study. A high-resolution crystal structure of Pae87 complexed with a peptidoglycan fragment showed a separate substrate-binding region within the catalytic domain, 18 Å away from the catalytic site and located on the opposite side of the lysin molecule. This substrate-binding region was conserved among phylogenetically related lysins lacking an additional cell-wall-binding domain, but not among those containing such a module. Two glutamic acids were identified to be relevant for the peptidoglycan-degradation activity, although the antimicrobial activity of Pae87 was seemingly unrelated. Incontrast, an antimicrobial peptide-like region within the Pae87 C-terminus, named P87, was found to be able to actively disturb the outer membrane and display antibacterial activity by itself. Therefore, an antimicrobial mechanism for Pae87 is proposed in which the P87 peptide plays the role of binding to the outer membrane and disrupting the cell-wall function, either with or without the participation of the catalytic activity of Pae87.

Highlights

  • Antibiotic resistance is becoming one of the most serious threats to public health worldwide, as the number of multiresistant bacterial strains is growing progressively

  • In the subset of SLYS that comprises just those entries bearing at least a Muramidase catalytic domain, hereafter termed SMUR, the length distribution contains two subpopulations (Fig. 1f ) that can be related to the presence or absence of a cell-wall-binding domain (CWBD), which is usually located at the N-terminus (Figs. 1g and 1h). 54.3% of the lysins in SMUR contained two predicted domains while the rest are thought to be monomodular, as is Pae87 itself

  • This structure provided a basis to propose the presence of a substrate-binding subdomain within the catalytic domain of Pae87

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Summary

Introduction

Antibiotic resistance is becoming one of the most serious threats to public health worldwide, as the number of multiresistant bacterial strains is growing progressively. Lysins are highly evolved enzymes produced by phages at the end of the lytic infection cycle to degrade the bacterial peptidoglycan, leading to cell lysis and phage progeny release. This mechanism relies on adding the purified enzyme exogenously (‘lysis from without’) and provokes the rapid degradation of the substrate (the peptidoglycan) and the lysis and death of susceptible bacteria, including multi-drug-resistant strains. Lysins have demonstrated several advantages over standard antibiotics, including (i) rapid killing activity against both stationary- and exponential-phase bacteria, practically within a few minutes of contact with the peptidoglycan substrate, (ii) effectiveness against multi-drug-resistant bacteria, (iii) specificity to the target pathogen, especially against Gram-positive bacteria, which allows the preservation of the normal microbiota, (iv) a seemingly very unlikely appearance of resistance, probably due to the conservation of its substrate, the peptidoglycan, (v) synergistic effects with other lysins or antibiotics and (vi) efficient lethal activity against colonizing pathogens growing on mucosal surfaces and/or in biofilms (Pastagia et al, 2013)

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