The Conformations of Virginiamycin M1 Diacetate, an Inhibitor of Guinea Pig Brain CCK-B Receptors, in Selected Solvents

The Virginiamycin M1 derivative Virginiamycin-14,16-diacetate (VM1-diAc) is not naturally occurring and must be synthesised by those wishing to study its properties. It possesses very little if any of the antibiotic capabilities of its parent compound, Virginiamycin M1. However, VM1-diAc has been reported to bind competitively to guinea pig brain cholecystokinin (CCK-B) receptors at concentrations very near that of CCK-B itself. CCK-B may bind to the CCK-B receptor as an octa- or a tetrapeptide, suggesting that a portion of the VM1-diAc molecule has a conformation very similar to the binding site of the CCKB peptide. Since the conformations of the VM1-diAc are constrained by its cyclic structure, studies of its binding to the CCK-B receptor might provide useful information about the CCK-B peptide receptor binding. To begin such a project, we report herein results of a study of the conformations of VM1-diAc dissolved in chloroform and methanol, two solvents of different polarities.

Potential for Reduction of Streptogramin A Resistance Revealed by Structural Analysis of Acetyltransferase VatA

ABSTRACTCombinations of group A and B streptogramins (i.e., dalfopristin and quinupristin) are “last-resort” antibiotics for the treatment of infections caused by Gram-positive pathogens, including methicillin-resistantStaphylococcus aureusand vancomycin-resistantEnterococcus faecium. Resistance to streptogramins has arisen via multiple mechanisms, including the deactivation of the group A component by the large family of virginiamycinO-acetyltransferase (Vat) enzymes. Despite the structural elucidation performed for the VatD acetyltransferase, which provided a general molecular framework for activity, a detailed characterization of the essential catalytic and antibiotic substrate-binding determinants in Vat enzymes is still lacking. We have determined the crystal structure ofS. aureusVatA inapo, virginiamycin M1- and acetyl-coenzyme A (CoA)-bound forms and provide an extensive mutagenesis and functional analysis of the structural determinants required for catalysis and streptogramin A recognition. Based on an updated genomic survey across the Vat enzyme family, we identified key conserved residues critical for VatA activity that are not part of theO-acetylation catalytic apparatus. Exploiting such constraints of the Vat active site may lead to the development of streptogramin A compounds that evade inactivation by Vat enzymes while retaining binding to their ribosomal target.