Decreased cellular permeability to H2O2 protects Saccharomyces cerevisiae cells in stationary phase against oxidative stress

The higher resistance of stationary-phase Saccharomyces cerevisiae to H2O2 when compared with exponential phase is well characterized, but the molecular mechanisms underlying it remain mostly unknown. By applying the steady-state H2O2-delivery model, we show that (a) cellular permeability to H2O2 is five times lower in stationary--than in exponential phase; (b) cell survival to H2O2 correlates with H2O2 cellular gradients for a variety of cells; and, (c) cells in stationary phase are predicted to be more susceptible to intracellular H2O2 than in exponential phase. In conclusion, limiting H2O2 diffusion into cells is a key protective mechanism against extracellular H2O2.     

酿酒酵母氧化胁迫应答反应机制

氧化胁迫是生物体面对逆境时的重要反应。在与逆境和活性氧做斗争的过程中,细胞进化出一套完整的应答调控机制,通过调节体内活性氧的代谢平衡,来保护DNA、脂质和蛋白质等免受氧化攻击。本文以酿酒酵母为例,根据近年来国内外研究的进展,围绕其在氧化胁迫应答过程中的三道保护屏障,即抗氧化物质和防御酶系统、转录调节和氧化物降解以及细胞器自噬,综述了其抗氧化代谢机理,为深入认识细胞的抗氧化应答机制奠定基础。     

The metabolic response of Saccharomyces cerevisiae to continuous heat stress

A study has been initiated to integrate molecular and physiological responses of Saccharomyces cerevisiae to heat stress conditions. We focus our research on a quantification of the energetics of the stress response. A series of continuous heat stresses was applied to exponentially growing cells of the strain X2180-1A at 28°C, by increasing the growth temperature to 37, 39, 40, 41, 42, or 43°C. Here, the results on cell growth and viability, as well as on anabolic and catabolic rates are presented. We observed a surprisingly thin line for the cells between growing, surviving, and dying, with regard to growth temperature. The heat stress showed a dual effect on catabolism: immediately after the temperature increase a strong peak was seen, after which a new, steady level was reached. In addition, the yield on glucose decreased with increasing temperature. Our results indicate that life at elevated temperatures is energetically unfavourable and a non-lethal heat stress invokes a redistribution of catabolic and anabolic fluxes.     

Variations in mRNA transcript levels of cell wall-associated genes of Saccharomyces cerevisiae following spheroplasting

A natural subgroup (that we refer to as Saccharomyces uvarum) was identified, within the heterogeneous species Saccharomyces bayanus. The typical electrophoretic karyotype, interfertility of hybrids between strains, distinctive sugar fermentation pattern, and uniform fermentation characteristics in must, indicated that this subgroup was not only highly homogeneous, but also clearly distinguishable from other species within the Saccharomyces sensu stricto group. Investigation of the S. bayanus type strain and other strains that have been classified as S. bayanus, confirmed the apparent lack of homogeneity and, in some cases, supported the hypothesis that they are natural hybrids.     

Saccharomyces cerevisiae in the stationary phase as a model organism--characterization at cellular and proteome level

The yeast Saccharomyces cerevisiae has been used as a model organism to investigate responses to different environmental stressors. The importance of their conclusions has been expanded to human cells. The experiments were done with exponentially growing cells, which do not resemble human cells. Human and other eukaryotic cells spend the greater part of their lives in a quiescent state, known as G0 corresponding to the yeast stationary phase. Providing energy, which comes from mitochondrial respiration, is also common. Thus, in the present study S. cerevisiae was used in the stationary phase for characterization at the cellular and proteome levels. At the cellular level, optical density, cell viability, glycogen content, intracellular oxidation and cell energy metabolic activity were measured, while at the proteome level, protein profiles were analyzed using two-dimensional electrophoresis. The data obtained at both levels provide better insight into quiescence program state, which still remains poorly understood. At their base, optimal time period reflecting a stable metabolic and oxidative state of the yeast was determined. Consequently, this period is the appropriate to study changes in cell oxidant status and energy metabolic activity in response to different environmental stressors.     

tRNAHis 5-methylcytidine levels increase in response to several growth arrest conditions in Saccharomyces cerevisiae

tRNAs are highly modified, each with a unique set of modifications. Several reports suggest that tRNAs are hypomodified or, in some cases, hypermodified under different growth conditions and in certain cancers. We previously demonstrated that yeast strains depleted of tRNA^His guanylyltransferase accumulate uncharged tRNA^His lacking the G₋₁ residue and subsequently accumulate additional 5-methylcytidine (m⁵C) at residues C₄₈ and C₅₀ of tRNA^His, due to the activity of the m⁵C-methyltransferase Trm4. We show here that the increase in tRNA^His m⁵C levels does not require loss of Thg1, loss of G₋₁ of tRNA^His, or cell death but is associated with growth arrest following different stress conditions. We find substantially increased tRNA^His m⁵C levels after temperature-sensitive strains are grown at nonpermissive temperature, and after wild-type strains are grown to stationary phase, starved for required amino acids, or treated with rapamycin. We observe more modest accumulations of m⁵C in tRNA^His after starvation for glucose and after starvation for uracil. In virtually all cases examined, the additional m⁵C on tRNA^His occurs while cells are fully viable, and the increase is neither due to the GCN4 pathway, nor to increased Trm4 levels. Moreover, the increased m⁵C appears specific to tRNA^His, as tRNA^Val(AAC) and tRNA^Gly(GCC) have much reduced additional m⁵C during these growth arrest conditions, although they also have C₄₈ and C₅₀ and are capable of having increased m⁵C levels. Thus, tRNA^His m⁵C levels are unusually responsive to yeast growth conditions, although the significance of this additional m⁵C remains unclear.