Project description:A Saccharomyces cerevisiae mutant with extended chronological life span was obtained by using an evolutionary engineering strategy, based on successive batch cultivation under gradually enhanced caloric restriction. The mutant strain SRM11 was selected which had about 50% longer life span than the reference strain. Whole-genome transcriptomic analysis of SRM11 with respect to the reference strain was performed to identify differences in gene expression levels between the two strains.

Project description:In this study, we used Saccharomyces cerevisiae to investigate the effects of GRX deletion on yeast chronological life span (CLS). Deletion of Grx1 or Grx2 shortened yeast CLS. Quantitative proteomics revealed that GRX deletion increased cellular ROS levels to activate Ras/PKA signal pathway. Our results provided new insights into mechanisms underlying aging process.

Project description:Histone modification affects life span in various organisms. The loss of Histone H3K36 methylation can shorten replicative life span in Saccharomyces cerevisiae. However, budding yeast, as a model organism for aging research, has replicative life span (RLS) and chronological life span (CLS). In this study, we showed that the loss of Histone H3K36 methylation can shorten CLS in Saccharomyces cerevisiae. We identified Ubc3/Bre1 mediates polyubiquitination of Set2 K25 and K530 at log phase and stationary phase, and Bre1 interacts with Ubc3 and Rad6 simultaneously. BRE1 knockout can stabilize Set2 protein to maintain H3K36me3 and regulate the transcription of aging related genes, such as DSE1/DSE2/SUN4/EGT2/SCW11. We also proved that Gcn5-mediated Set2 acetylation regulates Set2 protein stability and chronological aging. Altogether, our study showed that knockout of BRE1 and GCN5 regulate Set2 protein level by mediating the polyubiquitination of Set2 to influence the level of H3K36me3 and the transcription level of aging related genes enriched by H3K36me3, thereby extending the chronological life span.

Project description:Histone modification affects life span in various organisms. The loss of Histone H3K36 methylation can shorten replicative life span in Saccharomyces cerevisiae. However, budding yeast, as a model organism for aging research, has replicative life span (RLS) and chronological life span (CLS). In this study, we showed that the loss of Histone H3K36 methylation can shorten CLS in Saccharomyces cerevisiae. We identified Ubc3/Bre1 mediates polyubiquitination of Set2 K25 and K530 at log phase and stationary phase, and Bre1 interacts with Ubc3 and Rad6 simultaneously. BRE1 knockout can stabilize Set2 protein to maintain H3K36me3 and regulate the transcription of aging related genes, such as DSE1/DSE2/SUN4/EGT2/SCW11. We also proved that Gcn5-mediated Set2 acetylation regulates Set2 protein stability and chronological aging. Altogether, our study showed that knockout of BRE1 and GCN5 regulate Set2 protein level by mediating the polyubiquitination of Set2 to influence the level of H3K36me3 and the transcription level of aging related genes enriched by H3K36me3, thereby extending the chronological life span.

Project description:The three yeast mutants sch9Δ, ras2Δ, tor1Δ show extended chronological life span up to three folds. This study aims to dissect the mechanisms that lead to the yeast life span extension. Keywords: Expression comparison between wild type and long-lived yeast mutant strain

Project description:Saccharomyces cerevisiae is an excellent microorganism for industrial succinic acid production, but high succinic acid concentration will inhibit the growth of Saccharomyces cerevisiae then reduce the production of succinic acid. Through analysis the transcriptomic data of Saccharomyces cerevisiae with different genetic backgrounds under different succinic acid stress, we hope to find the response mechanism of Saccharomyces cerevisiae to succinic acid.

Project description:Investigation of whole genome gene expression changes at short (2 hours) and extended (24 hours) timepoints in wild-type Saccharomyces cerevisiae treated with 50 μM menadione during exponential growth compared to an rph1Δ strain Transient treatment with 50 μM menadione elevates mitochondrial ROS and extends chronological lifespan in yeast. Deletion of RPH1, a H3K36me3 histone demethylase, block chronological lifespan extension. This study aimed to identify Rph1p-dependent gene expression changes induced by menadione treatment that may support chronological lifespan extension. Reference: Bonawitz, N.D., Chatenay-Lapointe, M., Wearn, C.M., and Shadel, G.S. (2008). Expression of the rDNA-encoded mitochondrial protein Tar1p is stringently controlled and responds differentially to mitochondrial respiratory demand and dysfunction. Curr Genet 54, 83-94. A 24 chip study using total RNA recovered from two separate cultures each of Saccharomyces cerevisiae wild-type DBY2006 and rph1Δ. Each chip measures expression levels of 5,777 transcripts from NCBI build June 2008 with 8 probes per transcript and 3 replicate probe sets.

Project description:Investigation of whole genome gene expression changes at short (2 hours) and extended (24 hours) timepoints in wild-type Saccharomyces cerevisiae treated with 50 μM menadione during exponential growth compared to an rph1Δ strain Transient treatment with 50 μM menadione elevates mitochondrial ROS and extends chronological lifespan in yeast. Deletion of RPH1, a H3K36me3 histone demethylase, block chronological lifespan extension. This study aimed to identify Rph1p-dependent gene expression changes induced by menadione treatment that may support chronological lifespan extension. Reference: Bonawitz, N.D., Chatenay-Lapointe, M., Wearn, C.M., and Shadel, G.S. (2008). Expression of the rDNA-encoded mitochondrial protein Tar1p is stringently controlled and responds differentially to mitochondrial respiratory demand and dysfunction. Curr Genet 54, 83-94.

Project description:Industrial bioethanol production may involve a low pH environment,improving the tolerance of S. cerevisiae to a low pH environment caused by inorganic acids may be of industrial importance to control bacterial contamination, increase ethanol yield and reduce production cost. Through analysis the transcriptomic data of Saccharomyces cerevisiae with different ploidy under low pH stress, we hope to find the tolerance mechanism of Saccharomyces cerevisiae to low pH.

Project description:A propolis-resistant Saccharomyces cerevisiae mutant strain was obtained using an evolutionary engineering strategy based on successive batch cultivation under gradually increasing propolis levels. The mutant strain FD 11 was selected at a propolis concentration that the reference strain could not grow at all. Whole-genome transcriptomic analysis of FD11 was performed with respect to its reference strain to determine differences in gene expression levels between the two strains. Saccharomyces cerevisiae