Literature DB >> 16981688

Structure of coenzyme A-disulfide reductase from Staphylococcus aureus at 1.54 A resolution.

T Conn Mallett1, Jamie R Wallen, P Andrew Karplus, Hiroaki Sakai, Tomitake Tsukihara, Al Claiborne.   

Abstract

Coenzyme A (CoASH) replaces glutathione as the major low molecular weight thiol in Staphylococcus aureus; it is maintained in the reduced state by coenzyme A-disulfide reductase (CoADR), a homodimeric enzyme similar to NADH peroxidase but containing a novel Cys43-SSCoA redox center. The crystal structure of S. aureus CoADR has been solved using multiwavelength anomalous dispersion data and refined at a resolution of 1.54 A. The resulting electron density maps define the Cys43-SSCoA disulfide conformation, with Cys43-S(gamma) located at the flavin si face, 3.2 A from FAD-C4aF, and the CoAS- moiety lying in an extended conformation within a cleft at the dimer interface. A well-ordered chloride ion is positioned adjacent to the Cys43-SSCoA disulfide and receives a hydrogen bond from Tyr361'-OH of the complementary subunit, suggesting a role for Tyr361' as an acid-base catalyst during the reduction of CoAS-disulfide. Tyr419'-OH is located 3.2 A from Tyr361'-OH as well and, based on its conservation in known functional CoADRs, also appears to be important for activity. Identification of residues involved in recognition of the CoAS-disulfide substrate and in formation and stabilization of the Cys43-SSCoA redox center has allowed development of a CoAS-binding motif. Bioinformatics analyses indicate that CoADR enzymes are broadly distributed in both bacterial and archaeal kingdoms, suggesting an even broader significance for the CoASH/CoAS-disulfide redox system in prokaryotic thiol/disulfide homeostasis.

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Year:  2006        PMID: 16981688      PMCID: PMC2525802          DOI: 10.1021/bi061139a

Source DB:  PubMed          Journal:  Biochemistry        ISSN: 0006-2960            Impact factor:   3.162


  56 in total

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Authors:  G J Kleywegt; T A Jones
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