The role of MT (metallothionein) gene expression was investigated in rotenone-treated HeLa cells to induce a deficiency of NADH:ubiquinone oxidoreductase (complex I). Complex I deficiency leads to a diversity of cellular consequences, including production of ROS (reactive oxygen species) and apoptosis. HeLa cells were titrated with rotenone, resulting in dose-dependent decrease in complex I activity and elevated ROS production at activities lower than 33%. Expression of MT2A (MT isoform 2A), but not MT1A or MT1B RNA, was significantly inducible by rotenone (up to 7-fold), t-BHP (t-butyl hydroperoxide; 5-fold) and CdCl2 (50-fold), but not ZnCl2. Myxothiazol treatment did not elevate either ROS or MT2A levels, which supports a ROS-related mechanism for rotenone-induced MT2A expression. To evaluate the role of MT2A expression, MT2A and MT1B were overexpressed in HeLa cells and treated with rotenone. Compared with control and MT1B-overexpressing cells, ROS production was significantly lower and cell viability higher in MT2A-overexpressing HeLa cells when ROS production was enhanced by treatment with t-BHP. Mitochondrial membrane potential was noticeably less reduced in both MT-overexpressing cell lines. MT2A overexpression in rotenone-treated cells also significantly reduced or delayed apoptosis induction, as measured by caspase 3/7 activity and cytosolic nucleosome enrichment. We conclude that MT2A offers significant protection against the main death-causing consequences of rotenone-induced complex I deficiency in HeLa cells. Our results are in support of the protective role against oxidative stress ascribed to MTs and provide evidence that MT2A expression may be a beneficial downstream adaptive response in complex I-deficient cells.
Mitochondrial oxidative phosphorylation deficiency is accompanied by various down-stream, adaptive responses which play a key role in the varied phenotypes observed when mitochondrial dysfunction occurs. These responses are often accompanied by the induction of genes involved in defense mechanisms against oxidative stress. Among these responses, metallothioneins (MTs) has been identified to be responsive to mitochondrial dysfunction. MTs, which are expressed in four different isoforms, are small, cysteine rich, metal binding proteins that have been associated with a protective effect in cells under numerous diseased and stressed states. Their diverse functionality and protective roles can be ascribed to their three basic abilities or primary functions which are metal homeostasis, heavy metal detoxification and free radical scavenging. The involvement of MTs with numerous cellular processes, organelles and cells has received much attention while notice of their involvement with the function of mitochondria has been lacking. It is believed that MTs promote the survival of mitochondrial dysfunctional cells by acting as highly efficient reducing elements against the damaging properties of reactive oxygen species (ROS) and by limiting apoptosis. In addition to their role in mitochondrial disease, convincing evidence exist, albeit with conflicting results, of its involvement in some key functions of the mitochondrion, including redox modulation, metal homeostasis and enzyme and transcription factor regulation.
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