Zinc is a metal which is a cofactor in many enzymes and a structural element in zinc finger motifs those are important in relation between DNA and regulator proteins. Little is known about uptake, distribution, toxicity and detoxification of zinc ions in cells. In this study, zinc toxicity and detoxification levels have been compared in wild type and Cu/Zn superoxide dismutase mutant (sod1Delta) cells of the fission yeast Schizosaccharomyces pombe. We evaluated the toxic levels of zinc, total zinc content, lipid peroxidation levels and catalase activities for both strains which were grown in medium containing different concentrations of zinc. sod1Delta mutant showed important growth retardation and has higher lipid peroxidation and catalase activities than wild type. Cu/Zn superoxide dismutase (SOD1) activity of wild type cells was markedly increased when they were treated with elevated levels of zinc. SOD1 mRNA level also significantly increased when the cells treated with higher concentrations of zinc. These results indicate that the mutant cells were more sensitive to zinc stress and seemed to have more oxidative intracellular environment than wild type cells. Our results support the idea that superoxide dismutase is an important factor for zinc detoxification in eukaryotes.
Cu,Zn superoxide dismutase (SOD1) is an antioxidant enzyme that catalyzes the removal of superoxide radicals generated in various biological oxidations. Amyotrophic lateral sclerosis (ALS) is one of the most common neurodegenerative disorders, occurring in families (FALS) and sporadically (SALS). FALS and SALS are distinguishable genetically but not clinically. More than 100 point mutations in the human SOD 1 gene have been identified that cause FALS. In order to determine the effects of mutant SOD protein, we first cloned wild-type and A4V mutant human SOD1 into Schizosaccharomyces pombe. This study shows viabilities and some antioxidant properties including SOD, catalase, proteasomal activity, and protein carbonyl levels of transformants in SOD1 deleted strain (MN415); and its parental strain (JY741) at different stress conditions. There was no more oxidative damage in the human mutant SOD carrying the transformant strain compared with other strains. These results may help to explain whether ALS progresses as a consequence of cellular oxidative damage.
The anti-aging properties of metformin used for the treatment of type 2 diabetes mellitus have been studied extensively but there is more to discover regarding underlying mechanisms. Here we show that metformin significantly prolongs the chronological lifespan (CLS) of Schizosaccharomyces pombe through mechanisms similar to those observed in mammalian cells and other model organisms. While the presence of metformin in the medium caused an increase in carbohydrate consumption and ATP production, it reduced reactive oxygen species production and alleviate oxidative damage parameters such as lipid peroxidation and carbonylated proteins. We also tested whether the effect of metformin changed with the time it was added to the medium and observed that the lifespan-prolonging effect of metformin was related to the glucose concentration in the medium and did not prolong lifespan when added after glucose was completely depleted in the medium. On the other hand, cells inoculated in glucose-free medium containing metformin also showed extended lifespan suggesting that mechanisms other than that solely depend on glucose availability may be involved in extending the lifespan. These results suggest that metformin prolongs lifespan especially affecting energy metabolism and stress resistance capacity and that fission yeast can be effectively used when investigating the anti-aging mechanisms of metformin.
ABSTRACT. Because of its specific electrochemical properties, copper is an essential heavy metal for living organisms. As with other heavy metals, high levels can provoke damage. We examined gene expression under copper stress in wild-type fission yeast (Schizosaccharomyces pombe) through differential display. After the EC 50 concentration of CuSO 4 was determined as 50 µM, total RNA was isolated from cells treated or not with copper. The expression level of SPCC1682.13, ppk1, SPBC2F12.05c, and adg2 genes increased significantly under copper stress. Considering the functions of these genes are related to the cell cycle, cell division and chromosome dynamics, we hypothesize that retardation of the cell cycle under copper stress is relevant to the events that depend on the functions of these genes.
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