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MECHANISMS OF ENZYMIC AND HYDRIDE TRANSFERS

$377,517R01FY2006GMNIH

Brandeis University, Waltham MA

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Abstract

DESCRIPTION (provided by applicant): The objective of this project is to use X-ray crystallography, computer simulations, site-directed mutagenesis and kinetic measurements to determine what structural features in an enzyme active site promote efficient catalysis of hydrogen ion transfer. Transfer of a hydrogen, usually in the form of either a proton or a hydride ion is the most common chemical reaction in biology, and is also perhaps the simplest, yet it is not always an easy reaction to carry out rapidly. When the donor and acceptor atoms are unactivated carbons or oxygens, the uncatalyzed reactions are very slow, because the -C-H and -O-H groups are not very acidic (both typically have pKa values near 20). Yet enzymes are able to accelerate the transfer of H+ and H- from -C-H and -O-H by more than 15 orders of magnitude in some cases, achieving turnover numbers exceeding 1000 per second. Establishing how enzymes activate substrates, cofactors and their own catalytic groups to effect such catalysis is the goal of this project. We have selected several model systems for study. For proton transfer catalysis: mutarotase (GalM), which catalyses both ring opening and proton transfer; and ketosteroid isomerase (KSI), which utilizes a prototypical acid/base mechanism. For hydride transfer: xylose isomerase (XyI), which catalyzes sugar ring opening followed by metal-mediated 1,2-hydride transfer and dihydrofolate reductase (DHFR), where the hydride donor is NAD. For mutarotase and KSI our aim is to understand how the enzymes increase the basicity of the catalytic base and lower the pKa of the carbon acid and how the transition states are stabilized. For XyI, we aim to learn how the two metal ions in the active site cooperate to promote hydride transfer and how the ring-opening reaction is catalyzed. For DHFR we are studying the orientation and distance requirements for hydride donor and substrate positioning, and the possible role of coenzyme and substrate strain. The protic environment in the active sites and the role of protein dynamics in catalysis are also being probed for all these enzymes computationally and by ultra-high resolution (beyond approximately IA resolution) X-ray diffraction.

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