Project description:Yeast replicative aging is a process resembling replicative aging in mammalian cells. During aging, wild type haploid yeast cells enlarge, become sterile, and undergo nucleolar enlargement and fragmentation; we sought gene expression changes during the time of these phenotypic changes. Gene expression studied via microarrays and qPCR has shown reproducible, statistically significant changes in mRNA of genes at 12 and 18-20 generations. Our findings support previously described changes towards aerobic metabolism, decreased ribosome gene expression, and a partial Environmental Stress Response. Our novel findings include a pseudo-stationary phase, down-regulation of methylation-related metabolism, increased Nucleotide Excision Repair related mRNA, and a strong up-regulation of many of the regulatory subunits of protein phosphatase I (Glc7). These findings are correlated with aging changes in higher organisms as well as with the known involvement of protein phosphorylation states during yeast aging. J Gerontol, Jan, 2008, vol 63A, no. 1. Keywords: aging time course

Project description:Paired-end, ribosome depleted, total RNA Sequencing

Project description:we carried out a systematic and quantitative investigation of yeast aging with single-cell resolution through transcriptomic sequencing. We optimized a single-cell RNA sequencing (scRNA-seq) protocol to quantitatively study the whole transcriptome profiles of single yeast cells at different ages, finding increased cell-to-cell transcriptional variability during aging. The single-cell transcriptome analysis also highlighted key biological processes or cellular components, including oxidation-reduction process, oxidative stress response (OSR), translation, ribosome biogenesis and mitochondrion that underlie aging in yeast. We uncovered a molecular marker of FIT3, indicating the early heterogeneity during aging in yeast. We also analyzed the regulation of transcription factors and further characterized the distinctive temporal regulation of the OSR by YAP1 and proteasome activity by RPN4 during aging in yeast. Overall, our data profoundly reveal early heterogeneity during aging in yeast and shed light on the aging dynamics at the single cell level.

Project description:Ribosome profiling of budding yeast Saccharomyces cerevisiae in eEF3 depleted conditions

Project description:Penicillium sp. grown on PDB SPE-depleted media, for successive generations

Project description:AB SOLID sequencing of ribosome-depleted RNA from S. Cerevisiae, S. Paradoxus, S. Mikatae, and S. Bayanus These four yeast species were grown in complete media and total RNA was sequenced.

Project description:Total ribosome-depleted RNA sequencing was performed on the left cardiac ventricle, skeletal muscle (quadriceps femoris), and kidney of young adult (16.5 wk) and early aging (86 wk) C57BL/6J mice.

Project description:AB SOLID sequencing of ribosome-depleted RNA from S. Cerevisiae, S. Paradoxus, S. Mikatae, and S. Bayanus These four yeast species were grown in complete media and total RNA was sequenced. Cross-Species Gene Expression using RNA-Seq Data was examined. Eight samples examined: two biological replicates of each species

Project description:Inducible expression of transcription factor Sp1 in hematopoietic baf-3 cells

Project description:Protein synthesis is strictly regulated during replicative aging in yeast, but global translational regulation during replicative aging is poorly characterized. To conduct ribosomal profiling during replicative aging, we collected a large number of dividing aged cells using a miniature chemostat aging device. Translational efficiency, defined as the number of ribosome footprints normalized to transcript abundance, was compared between young and aged cells for each gene. We identified more than 700 genes with changes greater than twofold during replicative aging. Increased translational efficiency was observed in genes involved in DNA repair and chromosome organization. Decreased translational efficiency was observed in genes encoding ribosome components, transposon Ty1 and Ty2 genes, transcription factor HAC1 genes associated with the unfolded protein response, genes involved in cell wall synthesis and assembly, and ammonium permease genes. Our results provide a global view of translational regulation during replicative aging, in which the pathways involved in various cell functions are translationally regulated and cause diverse phenotypic changes.