Abstract
In Escherichia coli, the peptidoglycan cell wall is synthesized by bifunctional penicillin-binding proteins such as PBP1b that have both transpeptidase and transglycosylase activities. The PBP1b transpeptidase domain is a major target of β-lactams, and therefore it is important to attain a detailed understanding of its inhibition. The peptidoglycan glycosyltransferase domain of PBP1b is also considered an excellent antibiotic target yet is not exploited by any clinically approved antibacterials. Herein, we adapt a pyrophosphate sensor assay to monitor PBP1b-catalyzed glycosyltransfer and present an improved crystallographic model for inhibition of the PBP1b glycosyltransferase domain by the potent substrate analog moenomycin. We elucidate the structure of a previously disordered region in the glycosyltransferase active site and discuss its implications with regards to peptidoglycan polymerization. Furthermore, we solve the crystal structures of E. coli PBP1b bound to multiple different β-lactams in the transpeptidase active site and complement these data with gel-based competition assays to provide a detailed structural understanding of its inhibition. Taken together, these biochemical and structural data allow us to propose new insights into inhibition of both enzymatic domains in PBP1b.
Highlights
In Escherichia coli, the peptidoglycan cell wall is synthesized by bifunctional penicillin-binding proteins such as PBP1b that have both transpeptidase and transglycosylase activities
E. coli PBP1b consists of five domains: (i) a transmembrane (TM) ␣-helix at the N terminus; (ii) a UvrB domain 2 homolog (UB2H) domain, which is unique to PBP1b and presumably interacts with periplasmic binding partners including the outer membrane-tethered regulatory protein LpoB [1, 3,4,5]; (iii) a membrane-associated GTase domain; (iv) a linker region connecting the GTase and TPase domains; and (v) a C-terminal TPase domain (Fig. 1)
PBP1b Glycosyltransferase Pyrophosphate Sensor Assay—A major advance in peptidoglycan GTase assays came from the development of a continuous kinetic assay using fluorescent dansyl lipid II [18]
Summary
PBP1b Glycosyltransferase Pyrophosphate Sensor Assay—A major advance in peptidoglycan GTase assays came from the development of a continuous kinetic assay using fluorescent dansyl lipid II (i.e. the ⑀-amino group at the position 3 of the stem peptide is covalently modified with a dansyl group) [18] In this assay, polymerization of dansyl-lipid II followed by polymer digestion with a muramidase results in a decrease in fluorescence of the dansyl-muropeptides caused by the removal of the lipid moiety during polymerization [19]. The pyrophosphate sensor assay provides a convenient alternative assay that has the advantage of utilizing the natural substrate without the need for fluorescent derivatization or coupled enzymes This assay should be generally transferable to other peptidoglycan GTases and provides a robust system to study the effect of activators and inhibitors in the future.
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