The 1.5-A Structure of Chryseobacterium Meningosepticum Zinc Beta-lactamase in Complex with the Inhibitor, D-captopril

Overview

Journal J Biol Chem

Specialty Biochemistry

Date 2003 Apr 10

PMID 12684522

Citations 42

Authors

Isabel Garcia-Saez

Julie Hopkins

Cyril Papamicael

Nicola Franceschini

Gianfranco Amicosante

Gian Maria Rossolini

Moreno Galleni

Jean-Marie Frere

Otto Dideberg

Affiliations

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Abstract

The crystal structure of the class-B beta-lactamase, BlaB, from the pathogenic bacterium, Chryseobacterium meningosepticum, in complex with the inhibitor, d-captopril, has been solved at 1.5-A resolution. The enzyme has the typical alphabeta/betaalpha metallo-beta-lactamase fold and the characteristic two metal binding sites of members of the subclass B1, in which two Zn2+ ions were identified. d-Captopril, a diastereoisomer of the commercial drug, captopril, acts as an inhibitor by displacing the catalytic hydroxyl ion required for antibiotic hydrolysis and intercalating its sulfhydryl group between the two Zn2+ ions. Interestingly, d-captopril is located on one side of the active site cleft. The x-ray structure of the complex of the closely related enzyme, IMP-1, with a mercaptocarboxylate inhibitor, which also contains a sulfhydryl group bound to the two Zn2+ ions, shows the ligand to be located on the opposite side of the active site cleft. A molecule generated by fusion of these two inhibitors would cover the entire cleft, suggesting an interesting approach to the design of highly specific inhibitors.

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