Project description:Ribosome profiling upon glucose starvation in S. cerevisiae

Project description:Cultivation methods used to investigate microbial calorie restriction often result in carbon and energy starvation. This study aims to dissect cellular responses to calorie restriction and starvation in Saccharomyces cerevisiae by using retentostat cultivation. In retentostats, cells are continuously supplied with a small, constant carbon and energy supply, sufficient for maintenance of cellular viability and integrity but insufficient for growth. When glucose-limited retentostats cultivated under extreme calorie restriction were subjected to glucose starvation, calorie-restricted and glucose-starved cells were found to share characteristics such as increased heat-shock tolerance and expression of quiescence-related genes. However, they also displayed strikingly different features. While calorie-restricted yeast cultures remained metabolically active and viable for prolonged periods of time, glucose starvation resulted in rapid consumption of reserve carbohydrates, population heterogeneity due to appearance of senescent cells and, ultimately, loss of viability. Moreover, during starvation, calculated rates of ATP synthesis from storage carbohydrates were 2-3 orders of magnitude lower than steady-state ATP-turnover rates calculated under extreme calorie restriction in retentostats. Stringent reduction of ATP turnover during glucose starvation was accompanied by a strong down-regulation of genes involved in protein synthesis. These results demonstrate that extreme calorie restriction and carbon starvation represent different physiological states in S. cerevisiae.

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:Alkaline pH stress invokes in S. cerevisiae a potent and fast transcriptional response that includes many genes repressed by glucose. Certain mutants in the glucose-sensing and response pathways, such as those lacking the Snf1 kinase, are sensitive to alkalinization. We show that addition of glucose to the medium improves growth of wild type cells at high pH, fully abolish the snf1 alkali-sensitive phenotype and attenuates high pH-induced Snf1 phosphorylation at Thr210. The elm1 mutant, lacking one of the three upstream Snf1 kinases (tos3, elm1 and sak1), is markedly alkali sensitive, whereas the phenotype of the tos3 elm1 sak1 strain is even stronger than that of snf1 cells and it is not fully rescued by glucose supplementation. DNA microarray analysis reveals that about 75% of genes induced at short term by high pH are also induced by glucose scarcity. Snf1 mediates, in full or in part, the activation of a significant subset (38%) of short-term alkali-induced genes, including those coding high-affinity hexose transporters and phosphorylating enzymes. Induction of genes encoding enzymes involved in glycogen (but not trehalose) metabolism is largely dependent of the presence of Snf1. Therefore, the function of Snf1 in adaptation to glucose scarcity appears crucial for alkaline pH tolerance. Incorporation of micromolar amounts of iron and copper to a glucose-supplemented medium result in an additive effect and allows near normal growth at high pH, thus indicating that these three nutrients are key limiting factors for growth in an alkaline environment.

Project description:Tda1 in Saccharomyces cerevisiae is a protein kinase that is activated in response to glucose starvation. However, how it is activated has not been investigated for a long time. In this analysis, yeast cells were grown in high (2%) or low (0.05%) glucose medium, and the lysate were subjected to immunoprecipitation of Tda1-3xHA with an anti HA antibody. Proteins in the immnoprecipitated fractions were digested and peptides were analyzed by MS/MS.

Project description:Cultivation methods used to investigate microbial calorie restriction often result in carbon and energy starvation. This study aims to dissect cellular responses to calorie restriction and starvation in Saccharomyces cerevisiae by using retentostat cultivation. In retentostats, cells are continuously supplied with a small, constant carbon and energy supply, sufficient for maintenance of cellular viability and integrity but insufficient for growth. When glucose-limited retentostats cultivated under extreme calorie restriction were subjected to glucose starvation, calorie-restricted and glucose-starved cells were found to share characteristics such as increased heat-shock tolerance and expression of quiescence-related genes. However, they also displayed strikingly different features. While calorie-restricted yeast cultures remained metabolically active and viable for prolonged periods of time, glucose starvation resulted in rapid consumption of reserve carbohydrates, population heterogeneity due to appearance of senescent cells and, ultimately, loss of viability. Moreover, during starvation, calculated rates of ATP synthesis from storage carbohydrates were 2-3 orders of magnitude lower than steady-state ATP-turnover rates calculated under extreme calorie restriction in retentostats. Stringent reduction of ATP turnover during glucose starvation was accompanied by a strong down-regulation of genes involved in protein synthesis. These results demonstrate that extreme calorie restriction and carbon starvation represent different physiological states in S. cerevisiae. The yeast was first grown for 14 days under extreme calorie restriction in anaerobic, glucose-limited retentostats (Boender et al., 2009, Appl.Environ.Microbiol., 75: 5607-5614.). Subsequently, starvation was started by terminating the glucose feed. Yeast transcriptional reprogramming in response to calorie restriction and starvation was monitored by microarray analysis. Independent duplicate retentostat cultures, and subsequently starvation, were sampled for transcriptome analysis using Affymetrix microarrays. One time-point was sampled during calorie restriction (T0) and four time points were sampled during the starvation phase 10, 30, 60 and 120 minutes after switching of the feed, resulting in a dataset of 10 arrays.

Project description:The goal of this study is to analyse how the gene expression in Saccharomyces cerevisiae changes in dependency on the glucose concentration. Therefore, fed batch cultivations were carried out, during which the glucose concentration was maintained stable for several hours. Samples were taken at different times during the cultivations, the RNA was isolated and hybridised on whole genome yeast microarrays. Results from cultivations with the glucose concentrations 50, 70, 100 and 500 mg/L are presented. In addition, one sample from a starvation period (0 mg/L glucose) was analysed. Keywords: Dependency on glucose concentration

Project description:Alkaline pH stress invokes in S. cerevisiae a potent and fast transcriptional response that includes many genes repressed by glucose. Certain mutants in the glucose-sensing and response pathways, such as those lacking the Snf1 kinase, are sensitive to alkalinization. We show that addition of glucose to the medium improves growth of wild type cells at high pH, fully abolish the snf1 alkali-sensitive phenotype and attenuates high pH-induced Snf1 phosphorylation at Thr210. The elm1 mutant, lacking one of the three upstream Snf1 kinases (tos3, elm1 and sak1), is markedly alkali sensitive, whereas the phenotype of the tos3 elm1 sak1 strain is even stronger than that of snf1 cells and it is not fully rescued by glucose supplementation. DNA microarray analysis reveals that about 75% of genes induced at short term by high pH are also induced by glucose scarcity. Snf1 mediates, in full or in part, the activation of a significant subset (38%) of short-term alkali-induced genes, including those coding high-affinity hexose transporters and phosphorylating enzymes. Induction of genes encoding enzymes involved in glycogen (but not trehalose) metabolism is largely dependent of the presence of Snf1. Therefore, the function of Snf1 in adaptation to glucose scarcity appears crucial for alkaline pH tolerance. Incorporation of micromolar amounts of iron and copper to a glucose-supplemented medium result in an additive effect and allows near normal growth at high pH, thus indicating that these three nutrients are key limiting factors for growth in an alkaline environment. We identified the changes in the expression profiles caused by alkalinization of the medium (pH8 vs. pH5.5 for 10 min) in several strains: wild type cells (4 chips), snf1 mutant cells (4 chips) We also identified the transcriptomic changes that occur after glucose deprivation (0.05% vs 2% for 15 min) in: wild type cells (2 chips) snf1 mutant cells (2 chips) Total: 12 chips

Project description:Ribosome profiling (Ribo-Seq) and RNA-Seq analysis of Saccharomyces cerevisiae with and without 10 minute glucose starvation to determine effects on translation.

Project description:In response to limited nitrogen and abundant carbon sources, diploid Saccharomyces cerevisiae strains undergo a filamentous transition in cell growth as part of pseudohyphal differentiation. Use of the disaccharide maltose as the principal carbon source, in contrast to the preferred nutrient monosaccharide glucose, has been shown to induce a hyper-filamentous growth phenotype in a strain deficient for GPA2 which codes for a Galpha protein component that interacts with the glucose-sensing receptor Gpr1p to regulate filamentous growth. In this report, we compare the global transcript and proteomic profiles of wild-type and Gpa2p deficient diploid yeast strains grown on both rich and nitrogen starved maltose media. We find that deletion of GPA2 results in significantly different transcript and protein profiles when switching from rich to nitrogen starvation media. The results are discussed with a focus on the genes associated with carbon utilization, or regulation thereof, and a model for the contribution of carbon sensing/metabolism-based signal transduction to pseudohyphal differentiation is proposed. Keywords: Saccharomyces cerevisiae, nitrogen starvation, maltose, pseudohyphal differentiation, yeast, expression profiling