Speisky Hernán, Gómez Maritza, Burgos-Bravo Francesca, López-Alarcón Camilo, Jullian Carolina, Olea-Azar Claudio, Aliaga Margarita E
Nutrition and Food Technology Institute, University of Chile, Santiago, Chile.
Bioorg Med Chem. 2009 Mar 1;17(5):1803-10. doi: 10.1016/j.bmc.2009.01.069. Epub 2009 Feb 4.
The interaction between Cu(2+) ions and GSH molecules leads to the swift formation of the physiologically occurring Cu(I)-GSH complex. Recently, we reported that this complex is able to reduce molecular oxygen into superoxide in a reversible reaction. In the present study, by means of fluorescence, luminescence, EPR and NMR techniques, we investigated the superoxide-generating capacity of the Cu(I)-GSH complex, demonstrated the occurrence and characterized the chemical nature of the oxidized complex which is formed upon removing of superoxide radicals from the former reaction, and addressed some of the redox consequences associated with the interaction between the Cu(I)-GSH complex, its oxidized complex form, and an in-excess of GSH molecules. The interaction between Cu(I)-GSH and added GSH molecules led to an substantial exacerbation of the ability of the former to generate superoxide anions. Removal of superoxide from a solution containing the Cu(I)-GSH complex, by addition of Tempol, led to the formation and accumulation of Cu(II)-GSSG. Interaction between the latter complex and GSH molecules permitted the re-generation of the Cu(I)-GSH complex and led to a concomitant recovery of its superoxide-generating capacity. Some of the potential redox and biological implications arising from these interactions are discussed.
铜离子(Cu(2+))与谷胱甘肽(GSH)分子之间的相互作用会迅速形成生理上存在的Cu(I)-[GSH]₂复合物。最近,我们报道了这种复合物能够在一个可逆反应中将分子氧还原为超氧化物。在本研究中,我们借助荧光、发光、电子顺磁共振(EPR)和核磁共振(NMR)技术,研究了Cu(I)-[GSH]₂复合物产生超氧化物的能力,证实了从前述反应中去除超氧自由基后形成的氧化复合物的存在并对其化学性质进行了表征,还探讨了与Cu(I)-[GSH]₂复合物、其氧化复合物形式以及过量的GSH分子之间相互作用相关的一些氧化还原后果。Cu(I)-[GSH]₂与添加的GSH分子之间的相互作用导致前者产生超氧阴离子的能力大幅增强。通过添加Tempol从含有Cu(I)-[GSH]₂复合物的溶液中去除超氧化物,会导致Cu(II)-GSSG的形成和积累。后一种复合物与GSH分子之间的相互作用使得Cu(I)-[GSH]₂复合物得以再生,并使其产生超氧化物的能力随之恢复。本文讨论了这些相互作用产生的一些潜在氧化还原和生物学意义。
