A model for oxidative modification of glutamine synthetase, based on crystal structures of mutant H269N and the oxidized enzyme.

Abstract

Proteolytic degradation of glutamine synthetase (GS) in Escherichia coli is known to follow "marking" by oxidative modification. At an early stage of the degradative pathway, oxidation of His 269 and Arg 344 abolishes GS enzymatic activity. We propose a mechanism for the early stage of oxidative inactivation of GS on the basis of the crystal structure of H269N and tryptophan fluorescence spectra of H269N and H269NR344Q: (1) Oxidation of Arg 344, adjacent to the n2 metal ion site, decreases ATP binding. (2) Oxidation of His 269 to Asn destroys the n2 site, consistent with the function of His 269 as a ligand for the n2 metal. (3) Loss of Mn2+ at the n2 site destroys the integrity of the ATP binding site. (4) Destruction of the ATP site results in the observed low enzymatic activity of H269N and H269NR344Q. During later stages of oxidative modification, the n1 metal ion site is destroyed and the active site of the enzyme becomes flexible as suggested by X-ray data collected from an oxidized crystal of GS. Thus, studies of mutant and oxidized enzymes confirm that there are at least two stages of oxidative modification of GS. These studies suggest that the early modification occurs at the n2 metal ion site, eliminating enzyme activity, and the later modification occurs at the n1 metal ion site, relaxing the GS structure, perhaps enabling proteolytic degradation. These studies also illuminate the differing roles of the two bound metal ions: the tightly bound n1 ion enhances the stability of the catalytically active conformation, and the less tightly bound n2 ion participates in ATP binding.