Sone, K.; Ito, T.; Yamada, C.; Kashima, T.; Miyanaga, A.; Ohkama-Ohtsu, N.; Fushinobu, S.

{gamma}-Glutamyl peptidase 1 (GGP1) plays a dual role in primary and secondary sulfur metabolism in Arabidopsis thaliana. During glutathione (GSH) turnover, GGP1 hydrolyzes the isopeptide bond of GSH to degrade the tripeptide into Glu and Cys-Gly. During glucosinolate and camalexin biosynthesis, GGP1 processes GSH conjugates, which have a large substituent at the thiol side chain, by hydrolyzing the same isopeptide bond of {gamma}-Glu. In the present study, we determined the crystal structures of the following GGP1 forms: ligand-free, Glu complex, covalent {gamma}-Glu intermediate, and disulfide-linked S-S inactive forms. The intermediate structure, in which {gamma}-Glu is covalently linked to the nucleophile C100, was trapped by mutating the catalytic His to Asn (H192N). In the Glu complex and {gamma}-Glu intermediate structures, Glu bound to the S1 subsite is extensively recognized by several hydrogen bonds. The substrate recognition of the Cys-Gly moiety at the S1\' and S2\' subsites was revealed by modeling GSH in the active site. Mutational analysis indicated that R206 plays an important role in substrate binding by forming a salt bridge with Gly at the S2\' subsite. An open pocket is present beyond the thiol side chain of Cys in the S1\' subsite, which contributed to the dual activity of GGP1 toward GSH and GSH conjugates. The S-S inactive structure was obtained by soaking GGP1 crystals in Cys-Gly, and the catalytic cysteine (C100) partially formed a disulfide bond with a neighboring C154 residue. The partial inactivation of GGP1 in the presence of a pro-oxidant (Cys-Gly) has revealed its possible role in oxidative stress regulation in Arabidopsis.