Your search keyword '"Freiburger, Lee A."' showing total 2 results

1. Substrate-dependent switching of the allosteric binding mechanism of a dimeric enzyme.

Author

Freiburger, Lee, Miletti, Teresa, Zhu, Siqi, Baettig, Oliver, Berghuis, Albert, Auclair, Karine, and Mittermaier, Anthony

Subjects

*ENZYMES, *LIGANDS (Biochemistry), *MOLECULAR interactions, *MOLECULAR conformation, *ALLOSTERIC regulation

Abstract

Enzyme activity is commonly controlled by allostery, where ligand binding at one site alters the activities of distant sites. Classical explanations for multisubunit proteins involve conformational transitions that are fundamentally deterministic. For example, in the Monod-Wyman-Changeaux (MWC) paradigm, conformational transitions occur simultaneously in all subunits. In the Koshland-Nemethy-Filmer (KNF) paradigm, conformational transitions only occur in ligand-bound subunits. In contrast, recent models predict conformational changes that are governed by probabilities rather than absolute rules. To better understand allostery at the molecular level, we applied a recently developed spectroscopic and calorimetric method to the interactions of a dimeric enzyme with two different ligands. We found that conformational transitions appear MWC-like for a ligand that binds at the dimer interface and KNF-like for a distal ligand. These results provide strong experimental support for probabilistic allosteric theory predictions that an enzyme can exhibit a mixture of MWC and KNF character, with the balance partly governed by subunit interface energies. [ABSTRACT FROM AUTHOR]

Published

2014

2. Kinetic and Structural Analysis of Bisubstrate Inhibition of the Salmonella enterica Aminoglycoside 6'-N-AcetyItransferase.

Author

Magalhães, Maria L. B., Vetting, Matthew W., Feng Gao, Freiburger, Lee, Auclair, Karine, and Blanchard, John S.

Subjects

*SALMONELLA enteritidis, *ENZYMES, *AMINOGLYCOSIDES, *ACETYLATION, *ANTIBIOTICS, *PHOSPHORYLATION

Abstract

Aminoglycosides are antibacterial compounds that act by binding to the A site of the small 30S bacterial ribosomal subunit and inhibiting protein translation. Clinical resistance to aminoglycosides is generally the result of the expression of enzymes that covalently modify the antibiotic, including phosphorylation, adenylylation, and acetylation. Bisubstrate analogs for the aminoglycoside N-acetyl- transferases are nanomolar inhibitors of Enterococcus faecium AAC(6')-Ii. However, in the case of the Salmonella enterica aac(6')-Iy-encoded aminoglycoside N-acetyltransferase, we demonstrate that a series of bisubstrate analogs are only micromolar inhibitors. In contrast to studies with AAC(6')-Ii, the inhibition constants toward AAC(6')-Iy are essentially independent of both the identity of the aminoglycoside component of the bisubstrate and the number of carbon atoms that are used to link the CoA and aminoglycoside components. The patterns of inhibition suggest that the CoA portion of the bisubstrate analog can bind to the enzyme-aminoglycoside substrate complex and that the aminoglycoside portion can bind to the enzyme-CoA product complex. However, at the high concentrations of bisubstrate analog used in crystallization experiments, we could crystallize and solve the three-dimensional structure of the enzyme-bisubstrate complex. The structure reveals that both the CoA and aminoglycoside portions bind in essentially the same positions as those previously observed for the enzyme-C0A-ribostamycin complex, with only a modest adjustment to accommodate the "linker". These results are compared to previous studies of the interaction of similar bisubstrate analogs with other aminoglycoside N-acetyltransferases. [ABSTRACT FROM AUTHOR]

Published

2008