Role of Y94 in Proton and Hydride Transfers Catalyzed by Thymidylate Synthase

Labelled Comp Radiopharmac

2005

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Section: Synthesis Of R-mentioning

confidence: 99%

Microscale synthesis of isotopically labeled 6R‐N⁵, N¹⁰ methylene‐5, 6, 7, 8‐tetrahydrofolate

Hong

Labelled Comp Radiopharmac

2005

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“…There are several experimental methods that attempt to assess the nature of individual chemical steps: for instance, measurement of single-turnover rates as a function of pH (Fierke, Johnson, & Benkovic, 1987), or measurement of KIE obs as function of substrate concentration (Hong, Maley, & Kohen, 2007). Measuring single-turnover rates can dramatically reduce the kinetic complexity by reducing the number of microscopic steps involved in the measurement, but as the initiation of the reaction involves substrate binding, and there is still a C > 0 that results from protonation changes and the conformational steps that follow that substrate binding, and of course from the chemical steps other than the one under study, in systems catalyzing sequential chemical conversions (e.g., see TSase below).…”

Section: The Northrop Methodsmentioning

confidence: 99%

Examinations of the Chemical Step in Enzyme Catalysis

Singh

Islam

2016

Methods in Enzymology

Advances in computational and experimental methods in enzymology have aided comprehension of enzyme-catalyzed chemical reactions. The main difficulty in comparing computational findings to rate measurements is that the first examines a single energy barrier while the second frequently reflects a combination of many microscopic barriers. We present here intrinsic kinetic isotope effects and their temperature dependence as a useful experimental probe of a single chemical step in a complex kinetic cascade. Computational predictions are tested by this method for two model enzymes: dihydrofolate reductase (DHFR) and thymidylate synthase (TSase). The description highlights the significance of collaboration between experimentalists and theoreticians to develop a better understanding of enzyme-catalyzed chemical conversions.

“…Furthermore, the reaction catalyzed by Ec TSase is ordered with dUMP binding followed by CH 2 H 4 F to form a productive Michaelis complex. 33 Consequently, binding of the bi-substrate adduct ( Int-B ) to the predominant conformation of the free TSase in solution is a relatively rare event. Binding of Int-B must be accompanied by a slow conformational change of the active site and Int-B itself (i.e., “induced-fit”).…”

mentioning

confidence: 99%

Noncovalent Intermediate of Thymidylate Synthase: Fact or Fiction?

Kholodar

2016

J. Am. Chem. Soc.

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Thymidylate synthase is an attractive target for antibiotic and anticancer drugs due to its essential role in the de novo biosynthesis of the DNA nucleotide thymine. The enzymatic reaction is initiated by a nucleophilic activation of the substrate via formation of a covalent bond to an active site cysteine. The traditionally accepted mechanism is then followed by a series of covalently-bound intermediates, where that bond is only cleaved upon product release. Recent computational and experimental studies suggest that the covalent bond between the protein and substrate is actually quite labile. Importantly, these findings predict the existence of a non-covalently bound bi-substrate intermediate, not previously anticipated, which could be the target of a novel class of drugs inhibiting DNA biosynthesis. Here we report the synthesis of the proposed intermediate and findings supporting its chemical and kinetic competence. These findings substantiate the predicted non-traditional mechanism and the potential of this intermediate as a new drug lead.