125409-88-3Relevant articles and documents
Ring addition of the α-amino group of glutathione increases the reactivity of benzoquinone thioethers
Alt, Carmen,Eyer, Peter
, p. 1223 - 1233 (1998)
2-(Glutathion-S-yl)-1,4-benzoquinone was found to be remarkably unstable in phosphate butter (pH 7.4) even in the absence of oxygen. Intramolecular addition of the α-amino group of the glutamate residue to the quinone ring yielded ultimately 2,3-(glutathion-N,S-yl)-1,4-benzoquinone and 2,6- (glutathion-N,S-yl)-1,4-benzoquinone in a 3:1 ratio along with 2-(glutathion- S-yl)-1,4-hydroquinone. Kinetic studies indicated that the cyclization reactions proceeded at a rate k1 of 0.093 min-1, while intermolecular reactions followed a second-order kinetics with a k2 of 94 M-1 min-1 (pH 7.4, 37 °C), resulting in multiple polymerization products. Both intramolecular amino adducts of 2-(glutathion-S-yl)-1;4-benzoquinone are prone to hydrolysis, leading to the insertion of an additional OH group in the ring. These S-substituted trihydroxybenzene derivatives are particularly susceptible to autoxidation. The model compound 6-(N-acetylcystein-S-yl)-2- hydroxy-1,4-hydroquinone was shown to form readily two atropoisomeric biphenyls upon autoxidation: 2,4'-bis(N-acetylcystein-S-yl)-2',3,3',4,6,6'- hexahydroxybiphenyl, indicating C-C coupling, presumably via semiquinone radical intermediates. Thus, the sequence of glutathione S-addition, followed by oxidation, N-addition, oxidation, an 1 hydrolysis, constitutes a novel and very effective activation pathway of quinones for eliciting oxidative stress. These data underline the fact that glutathione conjugates of autoxidizable aromatics are no obligatory stable end products of a detoxication reaction. The possible toxicological impacts of intra- and intermolecular addition reactions of quinoid thiol conjugates are discussed.
Alkylation of cytochrome c by (glutathion-S-yl)-1,4-benzoquinone and iodoacetamide demonstrates compound-dependent site specificity
Person, Maria D.,Mason, Daniel E.,Liebler, Daniel C.,Monks, Terrence J.,Lau, Serrine S.
, p. 41 - 50 (2005)
The reaction of cytochrome c with the electrophilic compounds (glutathion-S-yl)-1,4-benzoquinone (GSBQ) and iodoacetamide was studied using mass spectrometry. GSBQ is a nephrotoxic quinol-thioether metabolite of benzoquinone, while iodoacetamide is an alkylating agent targeting cysteine thiols. Both chemicals formed covalent adducts with cytochrome c. GSBQ formed adducts with cytochrome c at pH 6 on several histidine and lysine residues. At a pH > 7, the initial product rearranged to a disubstituted cyclic quinone species preferentially found at two sites on the protein, Lys25-Lys27 and Lys86-Lys87, via quinol amine linkages. These two sites were previously determined to be the targets of benzoquinone adduct formation [Person et al. (2003) Chem. Res. Toxicol. 16, 598-608]. Cyclic reaction products are preferentially formed at two sites on the protein because of the presence of multiple basic residues in a conformationally flexible region whereas noncyclic products bind to a broad spectrum of available lysine and histidine nucleophiles. Iodoacetamide was a less selective alkylating agent able to form adducts on the majority of the nucleophilic sites of the protein. MS/MS spectra were used to identify signature ions for GSBQ-adducted peptides from the characteristic fragmentation patterns. Neutral losses of the 129 Da γ-glutamate residue and of the 273 Da glutathione moiety were found in both cysteine thiol- and lysine amine-linked GSBQ adduct MS/MS. Characteristic fragment ions were used in conjunction with the scoring algorithm for spectral analysis to search for adducted species present at low levels in the sample, and the analysis is applicable generally to detection of glutathione conjugates by MS/MS. Parallel analysis using matrix-assisted laser desorption/ionization-MS to compare spectra of control and treated samples allowed identification of peptide adducts formed by direct addition of GSBQ and by the subsequent loss of the glutathione moiety in a pH-dependent cyclization reaction.
