Project description:To understand the organisation of the glucose regulatory system, we analysed 91 deletion mutants of established glucose signalling and metabolic pathway members in Saccharomyces cerevisiae by DNA microarrays. These deletion mutants do not induce pathway-specific transcriptional responses reflecting the tight interconnection between pathways of the glucose regulatory system. Instead, one main transcriptional response is discerned, which varies in direction to mimic either a high or a low glucose response. The study reveals both known and unknown relationships within and between individual pathways and their members. Metabolic components of the glucose regulatory system are most frequently affected at the transcriptional level. A new network approach is applied that exposes the hierarchical organisation of the glucose regulatory system. Tps2 and Tsl1, two enzymes involved in trehalose biosynthesis, are predicted to be the most downstream transcriptional components. This prediction is further validated by epistasis analysis of Tps2 double mutants. Taken together, this suggests that changes in perceived glucose levels ultimately lead to a shift in trehalose biosynthesis. RNA isolated from a large amount of wt yeast from a single culture was used as a common reference. This common reference was used for each separate hybridization and used in the statistical analysis to obtain an average expression-profile for each deletion mutant relative to the wt. Two independent cultures were hybridized on two separate microarrays. For the first hybridization the Cy5 (red) labeled cRNA from the deletion mutant is hybridized together with the Cy3 (green) labeled cRNA from the common reference. For the replicate hybridization, the labels are swapped. Each gene is represented twice on the microarray, resulting in four measurements per mutant. Up to five deletion strains were grown on a single day. Wt cultures were grown parallel to the deletion mutants to assess day-to-day variance.

Project description:In Saccharomyces cerevisiae, glycogen and trehalose are important reserve carbohydrates that accumulate under nutrient limitation in batch cultures. An inherent draw-back of batch studies is that specific growth rate and substrate and product concentrations are variable over time and between cultures. The aim of this present study was to identify the nutritional requirements associated with high accumulation of reserve carbohydrates at a fixed specific growth rate (0.10 h-1) in anaerobic chemostat cultures that were limited by one of five different nutrients (carbon, nitrogen, sulfur, phosphorus or zinc). Reserve carbohydrates accumulation is not a general response to nutrient limitation. Over the conditions tested, accumulation occurs essentially under nitrogen (and to a lesser extent carbon) limited conditions. This was confirmed by the transcriptional profile of the genes involved in trehalose biosynthesis. We show that the transcriptional induction of both glycogen and trehalose biosynthesis genes was to a large extent driven by the regulator Msn2/4. However, the main regulatory control of glycogen biosynthesis was post-translational. Under nitrogen limitation, the ratio of glycogen synthase over glycogen phosphorylase increased up to eight-fold, thus enabling an increased flux towards glycogen biosynthesis. Experiment Overall Design: We studied this in anaerobic chemostat cultures at a dilution rate of 0.10 h-1 where growth was limited by five different nutrients (carbon, nitrogen, sulfur, phosphorus or zinc limitations). In addition, we studied the expression of these pathways at transcriptional and post-transcriptional levels and assessed the role of Msn2/4 in mediating transcriptional induction of glycogen and trehalose genes in the absence of stress.

Project description:In Saccharomyces cerevisiae, glycogen and trehalose are important reserve carbohydrates that accumulate under nutrient limitation in batch cultures. An inherent draw-back of batch studies is that specific growth rate and substrate and product concentrations are variable over time and between cultures. The aim of this present study was to identify the nutritional requirements associated with high accumulation of reserve carbohydrates at a fixed specific growth rate (0.10 h-1) in anaerobic chemostat cultures that were limited by one of five different nutrients (carbon, nitrogen, sulfur, phosphorus or zinc). Reserve carbohydrates accumulation is not a general response to nutrient limitation. Over the conditions tested, accumulation occurs essentially under nitrogen (and to a lesser extent carbon) limited conditions. This was confirmed by the transcriptional profile of the genes involved in trehalose biosynthesis. We show that the transcriptional induction of both glycogen and trehalose biosynthesis genes was to a large extent driven by the regulator Msn2/4. However, the main regulatory control of glycogen biosynthesis was post-translational. Under nitrogen limitation, the ratio of glycogen synthase over glycogen phosphorylase increased up to eight-fold, thus enabling an increased flux towards glycogen biosynthesis.

Project description:Deletion mutants of all established glucose signalling and some metabolic pathway members have been analyzed by expression profiling. Tps2 double mutants are profiled to verify the prediction that Tps2 is one of the most downstream transcriptional components.

Project description:To investigate the glucose regulatory system in Saccharomyces cerevisiae, we conducted a time-course in which glucose-depleted wildtype (WT) cells were inoculated into fresh media (SC, 2% glucose). Their subsequent transcriptional output was monitored over a period of five hours by DNA microarrays: samples for gene expression profiling were taken immediately after, as well as 3, 7.5, 15, 30, 60, 110, 150, and 300 minutes after inoculation into fresh medium. Transcripts upregulated are involved in translational processes such as the GO biological processes “ribosome biogenesis” and “ribosome localization”. Transcripts downregulated are enriched for the GO biological processes “cellular respiration” and various metabolism related processes. The time-course was used to verify the physiological relevance of gene expression profiles determined for individual deletions of glucose regulatory system components. Importantly, transcripts up- or downregulated in WT cells upon the addition of glucose are similarly up- or downregulated in deletion mutants that each lack a component of the glucose regulatory system.

Project description:Exploring molecular details of carbon utilization trade-offs in galactose-evolved yeast Adaptively evolved yeast mutants on galactose for around 400 generations showed diminished growth and carbon uptake rates on glucose. Genome-scale approaches were applied to characterize the molecular genetic basis of these trade-offs in carbon source utilization. Engineered mutants showing trade-offs in a specific carbon uptake rate between both carbons were used as controls. The transcriptional responses of the evolved mutants were almost identical during growth on both carbon sources. These carbon-independent conserved patterns were clearly observed in specific pathways and genes. Up-regulation of PGM2, a confirmed beneficial genetic change for improving galactose utilization was preserved on both carbons. In addition, HXK1, GLK1 and genes involved in reserve carbohydrate metabolism were up-regulated, while HXK2 was down-regulated. Genes that have a transcription factor binding site for Gis1p, Rph1p, Msn2/4p and Nrg1p were up-regulated. These results indicated changes in the metabolic pathways involved in metabolism of both carbons and in nutrient signaling pathway. The concentration profile of trehalose and glycogen supported these findings. Mutations in RAS2 and ERG5 genes were selected because of their beneficial and neutral effect on galactose utilization, respectively in our previous study. Site-directed mutants containing galactose-beneficial mutations in RAS2 only resulted in a significant decrease in glucose utilization. Integration of all these analyses clearly suggest an antagonistic pleiotropic trade-off in carbon source utilization caused by changes in regulatory region, and we hereby demonstrate how systems biology can be used to gain insight into evolutionary processes at the molecular level. Yeast galactose evolved mutants having improved galactose availability were grown on aerobic batch with glucose as carbon source

Project description:transcriptional reponse of yeast glucose sensing pathway mutants to glucose addition

Project description:We propose a carbon source dependent genetic regulatory network for the budding yeast Saccharomyces cerevisiae, derived from quantitative proteomic analyses integrated with bioinformatics knowledge of regulatory pathways and protein interactions. The proposed network, comprising 1247 transcription factor interactions and 126 chaperone interactions, defines the proteome shift in the cell when growing under different carbon sources. We used a label-free proteomics strategy to quantify alterations in protein abundance for S. cerevisiae when grown on minimal media using glucose, galactose, maltose and trehalose as sole carbon sources.

Project description:The Hippo pathway and its nuclear effector Yap regulate organ size and cancer formation. While many modulators of Hippo activity have been identified, little is known about how Yap target genes mediate these growth effects. Here, we show that defects in hepatic progenitor potential and liver growth in yap-/- mutant zebrafish are caused by impaired glucose transport and nucleotide biosynthesis: transcriptomic and metabolomic analyses reveal that Yap directly regulates expression of glucose transporter glut1, causing decreased glycolytic flux into anabolic nucleotide biosynthesis in yap-/- mutants and impaired glucose tolerance in adults. Nucleotide supplementation improved Yap-deficient phenotypes, indicating functional importance of glucose-fuelled nucleotide biosynthesis. Yap-regulated Glut1 expression and glucose uptake are conserved in mammals. Our results identify Glut1 as a direct Yap target enhancing glucose uptake and utilization for anabolic nucleotide biosynthesis, which are required for organ growth. Our findings demonstrate the central role of Hippo signalling in metabolic homeostasis

Project description:The implementation of a cost-effective lignocellulosic ethanol production requires developing efficient high gravity processes (i.e. working at high substrate concentrations). During the fermentation processes, the presence of high concentration of insoluble solids leads to lower glucose consumption rates, reduced ethanol volumetric productivities, and the accumulation of intracellular reactive oxygen species (ROS). Major repressed biological processes include cell cycle progression, trehalose and glycogen biosynthesis, DNA repair mechanisms, and certain genes involved in the general cell stress response. On the other hand, genes related to the glutathione, thioredoxin and methionine scavenging systems are induced.