Project description:This SuperSeries is composed of the following subset Series: GSE33097: Deletion mutant analysis of established glucose signaling and metabolic pathway members in Saccharomyces cerevisiae. GSE33098: Glucose-depletion time-course experiment in Saccharomyces cerevisiae wild-type cells. Refer to individual Series

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.

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: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:Comparison of the transcriptomes of Saccharomyces cerevisiae wild type FY23 and a PDE2 deletion mutant DJ28. Keywords = PDE2 Keywords = Ras/cAMP pathway Keywords: other

Project description:Comparison of the transcriptomes of Saccharomyces cerevisiae wild type FY23 and a PDE2 deletion mutant DJ28. Keywords = PDE2 Keywords = Ras/cAMP pathway

Project description:To gather more in-depth knowledge of the Mtl1p mechanosensor's role in Saccharomyces cerevisiae metabolism, we conducted a comparative metabolomic analysis of two Saccharomyces cerevisiae strains: the wild type and mtl1Δ, which carries a deletion of the mechanosensor Mtl1p. Both strains were grown under normal conditions at 27°C. The most significant metabolic changes between these strains were related to amino acid metabolism, purine metabolism, and carboxylic acid metabolism.

Project description:To gather more in-depth knowledge of the Mtl1p mechanosensor's role in Saccharomyces cerevisiae metabolism, we conducted a comparative metabolomic analysis of two Saccharomyces cerevisiae strains: the wild type and mtl1Δ, which carries a deletion of the mechanosensor Mtl1p. Both strains were grown under normal conditions at 27°C. The most significant metabolic changes between these strains were related to amino acid metabolism, purine metabolism, and carboxylic acid metabolism.

Project description:Most available knowledge on fungal arginine metabolism is derived from studies on Saccharomyces cerevisiae, in which arginine catabolism is initiated by releasing urea via the arginase reaction. Orthologs of the S. cerevisiae genes encoding the first three enzymes in the arginase pathway were cloned from Kluyveromyces lactis and shown to functionally complement the corresponding deletion in S. cerevisiae. Surprisingly, deletion of the single K. lactis arginase gene KlCAR1 did not completely abolish growth on arginine as nitrogen source. Growth rate of mutant strongly increased during serial transfer in shake-flask cultures. A combination of RNAseq-based transcriptome analysis and 13C-15N-based flux analysis was used to elucidate the arginase-independent pathway. Isotopic 13C15N-enrichment in ?-aminobutyrate revealed succinate as the entry point in the TCA cycle of the alternative pathway. Transcript analysis combined with enzyme activity measurements indicated increased expression in the Klcar1? mutant of a guanidinobutyrase (EC.3.5.3.7), an enzyme not previously demonstrated in fungi. Expression of the K. lactis KLLA0F27995g (renamed KlGBU1) encoding guanidinobutyrase enabled S. cerevisiae to use guanidinobutyrate as sole nitrogen source and its deletion in K. lactis almost completely abolish growth on this nitrogen source. Phylogenetic analysis suggests that this enzyme activity is widespread in fungi. The goal of the present study was to characterize arginine catabolism in K. lactis. To this end, CAR1, CAR2 and PRO3 orthologs in K. lactis were identified and functionally analysed by deletion, expression in S. cerevisiae and enzyme activity assays. Since deletion of the arginase gene in K. lactis was found not to completely abolish growth on arginine as a sole nitrogen source, the alternative pathway for arginine catabolism operating in this yeast was studied by a combination of transcriptome analysis, 13C and 15N isotope-based flux analysis and enzyme activity assays in cell extracts. To investigate arginine metabolism in the arginase-negative K. lactis strain, strains GG1632 (Klku80? KlCAR1 reference strain) and IMS0367 (Klcar1? Arg+) were grown in aerobic bioreactor batch cultures on glucose chemically defined medium with arginine as sole nitrogen source. RNA sequencing of samples taken during the exponential phase of growth on glucose-arginine media of the reference strain G1631 and the arginase less strain IMS0367 were compared resulting in the characterization of a new function.

Project description:To determine the roles of histone acetyltransferase Gcn5 and histone deacetylase Hda1 in regulating metabolic reprogramming during glucose starvation in Saccharomyces cerevisiae cells. The transcriptome of wild-type, gcn5Δ, hda1Δ, and gcn5Δhda1Δ cells grown at both glucose-replete (exponential phase) and glucose-starved (early PDS (post-diauxic shift) phase) conditions were determined.