Litcius/Paper detail

Natural variants modify Klebsiella pneumoniae carbapenemase (KPC) acyl–enzyme conformational dynamics to extend antibiotic resistance

Catherine L. Tooke, Philip Hinchliffe, Robert A. Bonomo, Christopher J. Schofield, Adrian J. Mulholland, James Spencer

2020Journal of Biological Chemistry49 citationsDOIOpen Access PDF

Abstract

values. High-resolution crystal structures of ESOC acyl-enzyme complexes with deacylation-deficient (E166Q) KPC-2 and KPC-4 mutants show that ceftazidime acylation causes rearrangement of three loops; the Ω, 240, and 270 loops, which border the active site. However, these rearrangements are less pronounced in the KPC-4 than the KPC-2 ceftazidime acyl-enzyme and are not observed in the KPC-2:cefotaxime acyl-enzyme. Molecular dynamics simulations of KPC:ceftazidime acyl-enyzmes reveal that the deacylation general base E166, located on the Ω loop, adopts two distinct conformations in KPC-2, either pointing "in" or "out" of the active site; with only the "in" form compatible with deacylation. The "out" conformation was not sampled in the KPC-4 acyl-enzyme, indicating that efficient ESOC breakdown is dependent upon the ordering and conformation of the KPC Ω loop. The results explain how point mutations expand the activity spectrum of the clinically important KPC SBLs to include ESOCs through their effects on the conformational dynamics of the acyl-enzyme intermediate.

Topics & Concepts

Klebsiella pneumoniaeMicrobiologyAntibioticsEnzymeAntibiotic resistanceBiologyChemistryEscherichia coliBiochemistryGeneAntibiotic Resistance in BacteriaMicrobial Natural Products and BiosynthesisBerberine and alkaloids research