Abstract
ABSTRACTβ-Lactamase-mediated resistance is a growing threat to the continued use of β-lactam antibiotics. The use of the β-lactam-based serine-β-lactamase (SBL) inhibitors clavulanic acid, sulbactam, and tazobactam and, more recently, the non-β-lactam inhibitor avibactam has extended the utility of β-lactams against bacterial infections demonstrating resistance via these enzymes. These molecules are, however, ineffective against the metallo-β-lactamases (MBLs), which catalyze their hydrolysis. To date, there are no clinically available metallo-β-lactamase inhibitors. Coproduction of MBLs and SBLs in resistant infections is thus of major clinical concern. The development of “dual-action” inhibitors, targeting both SBLs and MBLs, is of interest, but this is considered difficult to achieve due to the structural and mechanistic differences between the two enzyme classes. We recently reported evidence that cyclic boronates can inhibit both serine- and metallo-β-lactamases. Here we report that cyclic boronates are able to inhibit all four classes of β-lactamase, including the class A extended spectrum β-lactamase CTX-M-15, the class C enzyme AmpC from Pseudomonas aeruginosa, and class D OXA enzymes with carbapenem-hydrolyzing capabilities. We demonstrate that cyclic boronates can potentiate the use of β-lactams against Gram-negative clinical isolates expressing a variety of β-lactamases. Comparison of a crystal structure of a CTX-M-15:cyclic boronate complex with structures of cyclic boronates complexed with other β-lactamases reveals remarkable conservation of the small-molecule binding mode, supporting our proposal that these molecules work by mimicking the common tetrahedral anionic intermediate present in both serine- and metallo-β-lactamase catalysis.
Highlights
ABSTRACT -Lactamase-mediated resistance is a growing threat to the continued use of -lactam antibiotics
We show that cyclic boronates are able to inhibit all classes of -lactamase, including the class A extended-spectrum SBLs (ESBLs) CTX-M-15, the class C enzyme AmpC from Pseudomonas aeruginosa, and two carbapenem-hydrolyzing OXA variants, OXA-23 and OXA-48
Neither cyclic boronate 1 nor 2 was able to achieve potency comparable with the lowest IC50s exhibited by avibactam and BLI-489 against the OXA enzymes, with IC50s for cyclic boronate 1 being around 10- to 20-fold higher and those for cyclic boronate 2 being around 100- to 200-fold higher
Summary
ABSTRACT -Lactamase-mediated resistance is a growing threat to the continued use of -lactam antibiotics. Inhibitors of the SBLs include the -lactams clavulanic acid (CLAV), sulbactam (SUL), and tazobactam (TAZ), which are active against class A -lactamases [2, 13, 14], and the recently introduced non-lactam -lactamase inhibitor avibactam, which has a broader spectrum of SBL inhibition activity [15, 16] These inhibitors have increased the efficacy of -lactam antibiotics against SBL-mediated resistance in bacteria, but they are inactive against the Zn(II)dependent class B metallo--lactamases (MBLs), which constitute a structural and mechanistically distinct family of enzymes and exhibit considerable heterogeneity, even among themselves [17]. We show that cyclic boronates are able to inhibit all classes of -lactamase, including the class A ESBL CTX-M-15, the class C enzyme AmpC from Pseudomonas aeruginosa, and two carbapenem-hydrolyzing OXA variants, OXA-23 and OXA-48 These cyclic boronates are effective in inhibiting the growth of clinical Gram-negative bacterial strains expressing multiple -lactamases. Crystallographic analysis of a cyclic boronate complexed with CTX-M-15 supports the proposal that the cyclic boronates closely mimic the first tetrahedral intermediate in bicyclic -lactam hydrolysis
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