Abstract
Peptidoglycan is an essential and highly conserved mesh structure that surrounds bacterial cells. It plays a critical role in retaining a defined cell shape, and, in the case of pathogenic Gram-positive bacteria, it lies at the interface between bacterial cells and the host organism. Intriguingly, bacteria can metabolically incorporate unnatural D-amino acids into the peptidoglycan stem peptide directly from the surrounding medium, a process mediated by penicillin binding proteins (PBPs). Metabolic peptidoglycan remodeling via unnatural D-amino acids has provided unique insights into peptidoglycan biosynthesis of live bacteria and has also served as the basis of a synthetic immunology strategy with potential therapeutic implications. A striking feature of this process is the vast promiscuity displayed by PBPs in tolerating entirely unnatural side chains. However, the chemical space and physical features of this side chain promiscuity have not been determined systematically. In this report, we designed and synthesized a library of variants displaying diverse side chains to comprehensively establish the tolerability of unnatural D-amino acids by PBPs in both Gram-positive and Gram-negative organisms. In addition, nine Bacillus subtilis PBP-null mutants were evaluated with the goal of identifying a potential primary PBP responsible for unnatural D-amino acid incorporation and gaining insights into the temporal control of PBP activity. We empirically established the scope of physical parameters that govern the metabolic incorporation of unnatural D-amino acids into bacterial peptidoglycan.
Highlights
Enzymes involved in the biosynthesis of bacterial cell walls are validated antibiotic targets, including penicillin binding proteins (PBPs)
We evaluated a set of two amino acid derivatives (D-Lys(NBD) and L-Lys(NBD)) for the ability to label the peptidoglycan of B. subtilis (Fig. 1B)
B. subtilis was chosen as our initial model organism because of its wide use in unnatural D-amino acid studies and its compatibility with genetic manipulation [35]
Summary
Enzymes involved in the biosynthesis of bacterial cell walls are validated antibiotic targets, including penicillin binding proteins (PBPs). Bacteria can metabolically incorporate unnatural D-amino acids into the peptidoglycan stem peptide directly from the surrounding medium, a process mediated by penicillin binding proteins (PBPs). PBP TP domains are tasked with cross-linking neighboring stem peptides to increase structural strength and rigidity of the peptidoglycan, a vital process for the viability of bacterial cells. Because of their essential role in the life cycle of bacteria, small molecules that inactivate PBP TPs B. subtilis mutant strains lacking PBPs reported to possess TP activity were probed with fluorescent D-amino acids
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