Chaudiere J, Courtin O, Leclaire J
Centre de Recherche Roussel-UCLAF, Romainville, France.
Arch Biochem Biophys. 1992 Jul;296(1):328-36. doi: 10.1016/0003-9861(92)90580-p.
Selenocystamine (RSe-SeR) was shown to catalyze the oxygen-mediated oxidation of excess GSH to glutathione disulfide, at neutral pH and ambient PO2. This glutathione oxidase activity required the heterolytic reduction of the diselenide bond, which produced two equivalents of the selenolate derivative selenocysteamine (RSe-), via the transient formation of a selenenylsulfide intermediate (RSe-SG). Formation of RSe- was the only reaction observed in anaerobic conditions. At ambient PO2, the kinetics and stoichiometry of GSSG production as well as that of GSH and oxygen consumptions demonstrated that RSe- performed a three-step reduction of oxygen to water. The first step was a one-electron transfer from RSe- to dioxygen, yielding superoxide and a putative selenyl radical RSe., which decayed very rapidly to RSe-SeR. In the second step, RSe- reduced superoxide to hydrogen peroxide through a much faster one-electron transfer, also associated with the decay of RSe. to RSe-SeR. The third step was a two-electron transfer from RSe- to hydrogen peroxide, again much faster than oxygen reduction, which resulted in the production of RSe-SG, presumably via a selenenic acid intermediate (RSeOH) which was trapped by excess GSH. This third step was studied on exogenous hydroperoxide in anaerobic conditions, and it could be eliminated from the glutathione oxidase cycle in the presence of excess catalase. The role of RSe- as a one- and two-electron reductant was confirmed by competitive carboxymethylation with iodoacetate. RSe- was able to rapidly reduce ferric cytochrome c to its ferrous derivative. The overall rate of catalytic glutathione oxidation was GSH concentration dependent and oxygen concentration independent. Excess glutathione reductase and NADPH increased the catalytic oxidation of GSH, probably by switching the rate-limiting step from selenylsulfide to diselenide cleavage. When GSH was substituted for dithiothreitol, it was shown to reduce RSe-SeR to RSe- in a fast and quantitative reaction, and selenocystamine behaved as a dithiothreitol oxidase, whose catalytic cycle was dependent on oxygen concentration. The oxidase cycle of glutathione was inhibited by mercaptosuccinate, while that of dithiothreitol was not affected. When mercaptosuccinate was substituted for GSH, a stable selenenylsulfide was formed. These observations suggest that electrostatic interactions affect the reductive cleavage of diselenide and selenenylsulfide linkages. This study illustrates the ease of one-electron transfers from RSe- to a variety of reducible substrates. Such free radical mechanisms may explain much of the cytotoxicity of alkylselenols, and they demonstrate that selenocystamine is a poor catalytic model of the enzyme glutathione peroxidase.
在中性pH值和环境氧分压下,硒代胱胺(RSe - SeR)可催化过量谷胱甘肽(GSH)被氧介导氧化为谷胱甘肽二硫化物(GSSG)。这种谷胱甘肽氧化酶活性需要二硒键的异裂还原,通过硒代硫醚中间体(RSe - SG)的瞬时形成,产生两当量的硒醇盐衍生物硒代半胱胺(RSe -)。在厌氧条件下,仅观察到RSe - 的形成。在环境氧分压下,GSSG生成的动力学和化学计量以及GSH和氧消耗的动力学和化学计量表明,RSe - 进行了将氧三步还原为水的过程。第一步是从RSe - 到双氧的单电子转移,生成超氧化物和假定的硒自由基RSe·,其迅速衰变为RSe - SeR。第二步,RSe - 通过快得多的单电子转移将超氧化物还原为过氧化氢,这也与RSe·衰变为RSe - SeR有关。第三步是从RSe - 到过氧化氢的双电子转移,同样比氧还原快得多,这导致了RSe - SG的产生,推测是通过被过量GSH捕获的硒酸中间体(RSeOH)。在厌氧条件下对外源氢过氧化物研究了这第三步,并且在存在过量过氧化氢酶的情况下,它可以从谷胱甘肽氧化酶循环中消除。通过与碘乙酸的竞争性羧甲基化证实了RSe - 作为单电子和双电子还原剂的作用。RSe - 能够迅速将高铁细胞色素c还原为亚铁衍生物。催化性谷胱甘肽氧化的总体速率取决于GSH浓度,而与氧浓度无关。过量的谷胱甘肽还原酶和NADPH增加了GSH的催化氧化,可能是通过将限速步骤从硒代硫醚裂解切换为二硒键裂解。当用GSH替代二硫苏糖醇时,显示它在快速定量反应中将RSe - SeR还原为RSe -,并且硒代胱胺表现为二硫苏糖醇氧化酶,并其催化循环取决于氧浓度。谷胱甘肽的氧化酶循环受到巯基琥珀酸的抑制,而二硫苏糖醇的氧化酶循环不受影响。当用巯基琥珀酸替代GSH时,形成了稳定的硒代硫醚。这些观察结果表明静电相互作用影响二硒键和硒代硫醚键的还原裂解。这项研究说明了从RSe - 到各种可还原底物的单电子转移的容易程度。这种自由基机制可能解释了烷基硒醇的许多细胞毒性,并且它们证明硒代胱胺是谷胱甘肽过氧化物酶的不良催化模型。
