Project description:Two nutrient sensing and regulatory pathways, the general amino acid control (GAAC) and the target of rapamycin (TOR), control yeast growth and metabolism in response to changes in nutrient availability. Starvation for amino acids activates the GAAC pathway, involving Gcn2p phosphorylation of eIF2 and preferential translation of GCN4, a transcription activator of genes involved in amino acid metabolism. TOR senses nitrogen availability and regulates gene expression through transcription factors, such as Gln3p. We used microarray analyses to address the integration of the GAAC and TOR pathways in directing the yeast transcriptome in response to amino acid starvation and rapamycin treatment. Of the ~2500 genes whose expression was changed by 2-fold or greater, Gcn4p and Gln3p were required for 542 and 657 genes, respectively. While Gcn4p activates a common core of 57 genes in response to amino acid starvation or rapamycin treatment, the different stress arrangements allow for variations in Gcn4p-directed transcription. With few exceptions, genes requiring Gcn2p eIF2 kinase for induced expression also required Gcn4p, emphasizing the role of Gcn2p as an upstream activator of Gcn4p-directed transcription. There is also significant coordination between the GAAC and TOR pathways, with Gcn4p being required for activation of more genes during rapamycin treatment than Gln3p. Importantly, TOR regulates the GAAC-directed transcription of genes required for assimilation of nitrogen sources, such as γ-amino-butyric acid. Therefore, yeast has integrated gene expression responses to amino acid abundance and nitrogen source quality through the control of Gcn2p phosphorylation of eIF2 and GCN4 translation. Keywords: gene expression In this study, we carried out microarray analyses in a collection of yeast strains deleted for GCN2, GCN4, and GLN3, individually or in combinations, to explore the importance of the TOR and GAAC pathways in directing the transcriptome in response to amino acid starvation and rapamycin treatment.

Project description:Rheb, a ras-like small GTPase conserved from human to yeast, controls Tor kinase and plays a central role in regulation of cell growth depending on extracellular conditions. Fission yeast Rheb regulates amino acid uptake as well as response to nitrogen starvation. In this study we generated two mutants of Rheb, rhb1-DA4 and rhb1-DA8, and characterized them genetically. V17A mutation within the G1 box defined for the ras-like GTPases was responsible for rhb1-DA4, and Q52R I76F within the switch II domain for rhb1-DA8. In fission yeast, two events, induction of a meiosis initiating gene mei2+ and cell division without cell growth, are a typical response to nitrogen starvation. Under nitrogen-rich conditions, Rheb stimulates Tor kinase, which, in turn, suppresses the response to nitrogen starvation. While amino acid uptake was prevented by both rhb1-DA4 and rhb1-DA8 in a dominant fashion, the response to nitrogen starvation was prevented only by rhb1-DA4. rhb1-DA8 thereby allowed genetic dissection of the Rheb-dependent signaling cascade. We postulate that Rheb in fission may have two downstream elements, Tor kinase for regulation of the response to nitrogen starvation and the other element for regulation of amino acid uptake.

Project description:The transcriptional data from an integrative analysis of transcriptional and metabolic stress responses that provides a more complete understanding of the mechanisms by which genetic regulatory circuits mediate metabolic phenotype. Experiment Overall Design: Our investigation disrupts native transcriptional control of amino acid biosynthesis via the Gcn4p- mediated transcriptional stress response. Specifically, genetic perturbation of transcriptional regulator Gcn4p in a stress condition is achieved via wild-type S288C and gcn4-delta strains in a pH-controlled chemostat environment in which a titrated inhibitor creates near histidine starvation and glucose supply limits growth to a pre-defined rate (0.10 hr^-1). The gene expression chip titles indicate the condition.

Project description:Rheb, a ras-like small GTPase conserved from human to yeast, controls Tor kinase and plays a central role in regulation of cell growth depending on extracellular conditions. Fission yeast Rheb regulates amino acid uptake as well as response to nitrogen starvation. In this study we generated two mutants of Rheb, rhb1-DA4 and rhb1-DA8, and characterized them genetically. V17A mutation within the G1 box defined for the ras-like GTPases was responsible for rhb1-DA4, and Q52R I76F within the switch II domain for rhb1-DA8. In fission yeast, two events, induction of a meiosis initiating gene mei2+ and cell division without cell growth, are a typical response to nitrogen starvation. Under nitrogen-rich conditions, Rheb stimulates Tor kinase, which, in turn, suppresses the response to nitrogen starvation. While amino acid uptake was prevented by both rhb1-DA4 and rhb1-DA8 in a dominant fashion, the response to nitrogen starvation was prevented only by rhb1-DA4. rhb1-DA8 thereby allowed genetic dissection of the Rheb-dependent signaling cascade. We postulate that Rheb in fission may have two downstream elements, Tor kinase for regulation of the response to nitrogen starvation and the other element for regulation of amino acid uptake. Gene expression profile under nitrogen starvation in fission yeast. Type of experiment: Comparing between vegetatively-growing control cells and cells 3 hrs after nitrogen starvation. Experimental factor: Gene expression profile after nitrogen starvation in the rhb1-D4 or rhb1-D8 cells. Quality control steps taken: All experiments were repeated more than twice except for the tsc2D which was previously reported. Keywards: Nitrogen starvation, rhb1-D4, rhb1-D8

Project description:Transcriptional regulation of branched-chain amino acid metabolism in Saccharomyces cerevisiae involves two key regulator proteins, Leu3p and Gcn4p. Leu3p is a pathway-specific regulator, known to regulate six genes involved in branched-chain amino acid metabolism and one gene in nitrogen assimilation. Gcn4p is a global regulator, involved in the general response to amino acid and purine starvation. To investigate the contribution of Leu3p in regulation of gene expression, a leu3D strain was compared to an isogenic reference strain using DNA-microarray analysis. This comparison was performed for both glucose-grown, ammonium-limited and ethanol-limited, ammonium-excess chemostat cultures. In ethanol-limited cultures, absence of Leu3p led to reduced transcript levels of six of the seven established Leu3p target genes, but did not affect key physiological parameters. In ammonium-limited cultures, absence of Leu3p caused a drastic decrease in storage carbohydrate content. mRNA levels of genes involved in storage carbohydrate metabolism were also found reduced. Under N-limited conditions, the leu3D genotype elicited an amino-acid starvation response, leading to increased transcript levels of many amino acid biosynthesis genes. By combining the transcriptome data with data from earlier studies that measured DNA binding of Leu3p both in vitro and in vivo, BAT1, GAT1 and OAC1 were identified as additional Leu3p-regulated genes. This study demonstrates that unravelling of transcriptional regulation networks should preferably include several cultivation conditions and requires a combination of experimental approaches.

Project description:In Saccharomyces cerevisiae, the Gcn2p kinase controls a gene expression program in response to nutrient deprivation. Upon amino acid deprivation Gcn2p phosphorylates the translation initiation factor 2a subunit (eIF2a). Phosphorylation of eIF2a transiently inhibits translation initiation, and favours selective translation of the GCN4 transcription factor mRNA. High levels of Gcn4p then activate the expression of genes encoding amino acid biosynthesis pathways. Besides nutrient deprivation, Gcn2p can also be activated by other stresses such as DNA damage. Previous studies in our lab suggested that Gcn2p regulated other cellular pathways apart from translation initiation. To gain insights into these new regulatory roles of Gcn2p, we generated a strain called (GCN2c) expressing a constitutively active Gcn2p kinase mutant. In the GCN2c strain, phosphorylation of eIF2a and translation of a GCN4-lacz reporter was constitutively high in the absence of amino acid starvation. We investigated the transcriptional profile of the GCN2c mutant strain by cDNA microarrays. As expected, numerous amino acid biosynthetic genes were upregulated, being dependent of Gcn4p. Most interestingly, expression of genes encoding proteins involved in DNA replication/repair was decreased, suggesting that Gcn2p could regulate cell cycle progression from G1 to S phase. Accordingly, the Gcn2c strain exhibited, i) slow growth, ii) a delayed entry into S phase, and iii) hypersensitivity to hydroxyurea. In addition, MMS treatment induced a G1 checkpoint and a growth defect which was dependent on Gcn2p and Gcn3p. Considering that MMS delays cell cycle progression by generating DNA lesions, the findings suggest that DNA damage induces a G1/S checkpoint by a novel pathway involving the protein kinase Gcn2p. Keywords: mutant analysis

Project description:Transcriptional regulation of branched-chain amino acid metabolism in Saccharomyces cerevisiae involves two key regulator proteins, Leu3p and Gcn4p. Leu3p is a pathway-specific regulator, known to regulate six genes involved in branched-chain amino acid metabolism and one gene in nitrogen assimilation. Gcn4p is a global regulator, involved in the general response to amino acid and purine starvation. To investigate the contribution of Leu3p in regulation of gene expression, a leu3D strain was compared to an isogenic reference strain using DNA-microarray analysis. This comparison was performed for both glucose-grown, ammonium-limited and ethanol-limited, ammonium-excess chemostat cultures. In ethanol-limited cultures, absence of Leu3p led to reduced transcript levels of six of the seven established Leu3p target genes, but did not affect key physiological parameters. In ammonium-limited cultures, absence of Leu3p caused a drastic decrease in storage carbohydrate content. mRNA levels of genes involved in storage carbohydrate metabolism were also found reduced. Under N-limited conditions, the leu3D genotype elicited an amino-acid starvation response, leading to increased transcript levels of many amino acid biosynthesis genes. By combining the transcriptome data with data from earlier studies that measured DNA binding of Leu3p both in vitro and in vivo, BAT1, GAT1 and OAC1 were identified as additional Leu3p-regulated genes. This study demonstrates that unravelling of transcriptional regulation networks should preferably include several cultivation conditions and requires a combination of experimental approaches. Keywords: ordered

Project description:We show that the sensitivity of tsc mutant cells to rapamycin is mediated by TORC1 and can be suppressed by overexpression of the 2-oxoglutarate-Fe(II) dependent oxygenase, Isp7. We show that Isp7 is a novel regulator of amino acids uptake that acts via regulation of gene expression, both upstream and downstream of TOR signaling. suppressed by overexpression of the putative 2-oxoglutarate-Fe(II) dependent oxygenase, Isp7. We show that Isp7 is a novel master regulator of amino acids uptake that acts via regulation of gene expression, both upstream and downstream of TOR signaling. TOR proteins reside in two distinct complexes, TOR complex 1 and 2 (TORC1 and TORC2) that are central for the regulation of cellular growth, proliferation and survival. TOR is also the target for the immunosuppressive and anti-cancer drug rapamycin. In Schizosaccharaomyces pombe, disruption of the TSC complex, mutations in which can lead to the Tuberous Sclerosis syndrome in humans, results in a rapamycin sensitive phenotype under poor nitrogen conditions. We show here that the sensitivity to rapamycin is mediated via inhibition of TORC1 and suppressed by overexpression of isp7+, a member of the family of 2-oxoglutarate-Fe(II) dependent oxygenases. The transcript level of isp7+ is negatively regulated by TORC1 but positively regulated by TORC2. Yet, we find extensive similarity between the transcriptome of cells disrupted for isp7+ and cells mutated in the catalytic subunit of TORC1. Moreover, Isp7 regulates amino acid permease expression similarly to TORC1 and in contrast to TORC2. Overexpression of isp7+ induces TORC1-dependent phosphorylation of ribosomal protein Rps6, while inhibiting TORC2-dependent phosphorylation and activation of the AGC-like kinase Gad8. Taken together, our findings suggest a central role for Isp7 in amino acid homeostasis and the presence of isp7+-dependent regulatory loops that affect both TORC1 and TORC2. 6 Samples (arrays) were performed. We generated pairwise comparison between DISP7 and WT, using Partek Genomics Suite. Genes with p≤5%[FDR] and a fold-change difference of ≥2\1.5 or <-2\-1.5 were selected.

Project description:We show that the sensitivity of tsc mutant cells to rapamycin is mediated by TORC1 and can be suppressed by overexpression of the 2-oxoglutarate-Fe(II) dependent oxygenase, Isp7. We show that Isp7 is a novel regulator of amino acids uptake that acts via regulation of gene expression, both upstream and downstream of TOR signaling. suppressed by overexpression of the putative 2-oxoglutarate-Fe(II) dependent oxygenase, Isp7. We show that Isp7 is a novel master regulator of amino acids uptake that acts via regulation of gene expression, both upstream and downstream of TOR signaling. TOR proteins reside in two distinct complexes, TOR complex 1 and 2 (TORC1 and TORC2) that are central for the regulation of cellular growth, proliferation and survival. TOR is also the target for the immunosuppressive and anti-cancer drug rapamycin. In Schizosaccharaomyces pombe, disruption of the TSC complex, mutations in which can lead to the Tuberous Sclerosis syndrome in humans, results in a rapamycin sensitive phenotype under poor nitrogen conditions. We show here that the sensitivity to rapamycin is mediated via inhibition of TORC1 and suppressed by overexpression of isp7+, a member of the family of 2-oxoglutarate-Fe(II) dependent oxygenases. The transcript level of isp7+ is negatively regulated by TORC1 but positively regulated by TORC2. Yet, we find extensive similarity between the transcriptome of cells disrupted for isp7+ and cells mutated in the catalytic subunit of TORC1. Moreover, Isp7 regulates amino acid permease expression similarly to TORC1 and in contrast to TORC2. Overexpression of isp7+ induces TORC1-dependent phosphorylation of ribosomal protein Rps6, while inhibiting TORC2-dependent phosphorylation and activation of the AGC-like kinase Gad8. Taken together, our findings suggest a central role for Isp7 in amino acid homeostasis and the presence of isp7+-dependent regulatory loops that affect both TORC1 and TORC2.

Project description:To investigate the role of transcriptional factors Gcn4, Leu3, Gat1 and Met31 in the response to 3AT-induced amino acid starvation, we performed time-course microarray studies of wild-type, single deletion and double deletion strains. The analyses provide insight into a complex regulatory response involving at least four transcription factors. Yeast Saccharomyces Cerevisiae BY4741 wild-type and deletion strains were collected at various time points after 3AT induced amino acid starvation.