Reaction of Adenosylcobalamin-Dependent Glutamate Mutase with 2-Thiolglutarate

Abstract

We have investigated the reaction of glutamate mutase with the glutamate analogue, 2-thiolglutarate. In the standard assay, 2-thiolglutarate behaves as a competitive inhibitor with a K_i of 0.05 mM. However, rather than simply binding inertly at the active site, 2-thiolglutarate elicits cobalt−carbon bond homolysis and the formation of 5‘-deoxyadenosine. The enzyme exhibits a complicated EPR spectrum in the presence of 2-thiolglutarate that is markedly different from any previously observed with the enzyme. The spectrum was simulated well by assuming that it arises from electron−electron spin coupling between a thioglycolyl radical and low-spin Co²⁺ in cob(II)alamin. Analysis of the zero-field splitting parameters obtained from the simulations places the organic radical ∼10 Å from the cobalt and at a tilt angle of ∼70° to the normal of the corrin ring. This orientation is in good agreement with that expected from the crystal structure of glutamate mutase complexed with the substrate. 2-Thiolglutarate appears to react in a manner analogous to that of glutamate by first forming a thiolglutaryl radical at C-4 that then undergoes fragmentation to produce acrylate and the sulfur-stabilized thioglycolyl radical. The thioglycolyl radical accumulates on the enzyme, suggesting it is too stable to undergo further steps in the mechanism at a detectable rate.