Protein kinase A mediates growth-regulated expression of yeast ribosomal protein genes by modulating RAP1 transcriptional activity

The TOR kinases link nutrient sensing to cell growth

Rapamycin is an immunosuppressive natural product that inhibits the proliferation of T-cells in response to nutrients and growth factors. Rapamycin binds to the peptidyl-prolyl isomerase FKBP12 and forms protein-drug complexes that inhibit signal transduction by the TOR kinases. The FKBP12 and TOR proteins are conserved from fungi to humans, and in both organisms the TOR signaling pathway plays a role in nutrient sensing. In response to nitrogen sources or amino acids, TOR regulates both transcription and translation, enabling cells to appropriately respond to growth-promoting signals. Rapamycin is having a profound impact on clinical medicine and was approved as an immunosuppressant for transplant recipients in 1999. Ongoing clinical studies address new clinical applications for rapamycin as an antiproliferative drug for chemotherapy and invasive cardiology.

Gcn2 mediates Gcn4 activation in response to glucose stimulation or UV radiation not via GCN4 translation

In mammalian cells transcription factors of the AP-1 family are activated by either stress signals such as UV radiation, or mitogenic signals such as growth factors. Here we show that a similar situation exists in the yeast Saccharomyces cerevisiae. The AP-1 transcriptional activator Gcn4, known to be activated by stress signals such as UV radiation and amino acids starvation, is also induced by growth stimulation such as glucose. We show that glucose-dependent Gcn4 activation is mediated through the Ras/cAMP pathway. This pathway is also responsible for UV-dependent Gcn4 activation but is not involved in Gcn4 activation by amino acid starvation. Thus, the unusual phenomenon of activation of mitogenic pathways and AP-1 factors by contradictory stimuli through Ras is conserved from yeast to mammals. We also show that activation of Gcn4 by glucose and UV requires Gcn2 activity. However, in contrast to its role in amino acid starvation, Gcn2 does not increase eIF2alpha phosphorylation or translation of GCN4 mRNA in response to glucose or UV. These findings suggest a novel mechanism of action for Gcn2. The finding that Gcn4 is activated in response to glucose via the Ras/cAMP pathway suggests that this cascade coordinates glucose metabolism with amino acids and purine biosynthesis and thereby ensures availability of both energy and essential building blocks for continuation of the cell cycle.

The yeast glycerol 3-phosphatases Gpp1p and Gpp2p are required for glycerol biosynthesis and differentially involved in the cellular responses to osmotic, anaerobic, and oxidative stress

We have characterized the strongly homologous GPP1/RHR2 and GPP2/HOR2 genes, encoding isoforms of glycerol 3-phosphatase. Mutants lacking both GPP1 and GPP2 are devoid of glycerol 3-phosphatase activity and produce only a small amount of glycerol, confirming the essential role for this enzyme in glycerol biosynthesis. Overproduction of Gpp1p and Gpp2p did not significantly enhance glycerol production, indicating that glycerol phosphatase is not rate-limiting for glycerol production. Previous studies have shown that expression of both GPP1 and GPP2 is induced under hyperosmotic stress and that induction partially depends on the HOG (high osmolarity glycerol) pathway. We here show that expression of GPP1 is strongly decreased in strains having low protein kinase A activity, although it is still responsive to osmotic stress. The gpp1Delta/gpp2Delta double mutant is hypersensitive to high osmolarity, whereas the single mutants remain unaffected, indicating GPP1 and GPP2 substitute well for each other. Transfer to anaerobic conditions does not affect expression of GPP2, whereas GPP1 is transiently induced, and mutants lacking GPP1 show poor anaerobic growth. All gpp mutants show increased levels of glycerol 3-phosphate, which is especially pronounced when gpp1Delta and gpp1Delta/gpp2Delta mutants are transferred to anaerobic conditions. The addition of acetaldehyde, a strong oxidizer of NADH, leads to decreased glycerol 3-phosphate levels and restored anaerobic growth of the gpp1Delta/gpp2Delta mutant, indicating that the anaerobic accumulation of NADH causes glycerol 3-phosphate to reach growth-inhibiting levels. We also found the gpp1Delta/gpp2Delta mutant is hypersensitive to the superoxide anion generator, paraquat. Consistent with a role for glycerol 3-phosphatase in protection against oxidative stress, expression of GPP2 is induced in the presence of paraquat. This induction was only marginally affected by the general stress-response transcriptional factors Msn2p/4p or protein kinase A activity. We conclude that glycerol metabolism plays multiple roles in yeast adaptation to altered growth conditions, explaining the complex regulation of glycerol biosynthesis genes.

Remodeling of yeast genome expression in response to environmental changes

We used genome-wide expression analysis to explore how gene expression in Saccharomyces cerevisiae is remodeled in response to various changes in extracellular environment, including changes in temperature, oxidation, nutrients, pH, and osmolarity. The results demonstrate that more than half of the genome is involved in various responses to environmental change and identify the global set of genes induced and repressed by each condition. These data implicate a substantial number of previously uncharacterized genes in these responses and reveal a signature common to environmental responses that involves approximately 10% of yeast genes. The results of expression analysis with MSN2/MSN4 mutants support the model that the Msn2/Msn4 activators induce the common response to environmental change. These results provide a global description of the transcriptional response to environmental change and extend our understanding of the role of activators in effecting this response.

Genomic expression programs in the response of yeast cells to environmental changes

We explored genomic expression patterns in the yeast Saccharomyces cerevisiae responding to diverse environmental transitions. DNA microarrays were used to measure changes in transcript levels over time for almost every yeast gene, as cells responded to temperature shocks, hydrogen peroxide, the superoxide-generating drug menadione, the sulfhydryl-oxidizing agent diamide, the disulfide-reducing agent dithiothreitol, hyper- and hypo-osmotic shock, amino acid starvation, nitrogen source depletion, and progression into stationary phase. A large set of genes (approximately 900) showed a similar drastic response to almost all of these environmental changes. Additional features of the genomic responses were specialized for specific conditions. Promoter analysis and subsequent characterization of the responses of mutant strains implicated the transcription factors Yap1p, as well as Msn2p and Msn4p, in mediating specific features of the transcriptional response, while the identification of novel sequence elements provided clues to novel regulators. Physiological themes in the genomic responses to specific environmental stresses provided insights into the effects of those stresses on the cell.

Coordinate regulation of yeast ribosomal protein genes is associated with targeted recruitment of Esa1 histone acetylase

The Esa1-containing NuA4 histone acetylase complex can interact with activation domains in vitro and stimulate transcription on reconstituted chromatin templates. In yeast cells, Esa1 is targeted to a small subset of promoters in an activator-specific manner. Esa1 is specifically recruited to ribosomal protein (RP) promoters, and this recruitment appears to require binding by Rap1 or Abf1. Esa1 is important for RP transcription, and Esa1 recruitment to RP promoters correlates with coordinate regulation of RP genes in response to growth stimuli. However, following Esa1 depletion, H4 acetylation decreases dramatically at many loci, but transcription is not generally affected. Therefore, the transcription-associated targeted recruitment of Esa1 to RP promoters occurs in a background of more global nontargeted acetylation that is itself not required for transcription.

Identification and transcription control of fission yeast genes repressed by an ammonium starvation growth arrest

In fission yeast Schizosaccharomyces pombe, ammonium starvation induces a growth arrest, a cell cycle exit in G(1) and a further switch to meiosis. This process is regulated by the cAMP-dependent protein kinase and the Wis1-dependent MAP kinase cascade, and downstream transcription factors. In order to understand how cells adapt their genetic programme to the switch from mitotic cycling to starvation, a differential transcript analysis comparing mRNA from exponentially growing and ammonium-starved cells was performed. Genes repressed by this stimulus mainly concern cell growth, i.e. protein synthesis and global metabolism. Comparison of the expression of two of them, the ribosomal proteins Rps6 and TCTP, in many different growing conditions, evidenced a strong correlation, suggesting that their transcriptions are coordinately regulated. Nevertheless, by repeating the ammonium starvation on strains constitutively activated for the PKA pathway (Deltacgs1), or unable to activate the Wis1-dependent MAP kinase pathway (Deltawis1), or with both characteristics (Deltacgs1+Deltawis1), the transcriptional inhibition was found to be governed either by the PKA pathway, or by the Wis1 pathway, or by both. These results suggest that during the switch from exponential growth to ammonium starvation, cell homeostasis is maintained by downregulating the transcription of the most expressed genes by a PKA and a Wis1-dependent process. Accession Nos for the S30 and L14 ribosomal protein cDNA sequences are AJ2731 and AJ2732, respectively.

Nutritional control of nucleocytoplasmic localization of cAMP-dependent protein kinase catalytic and regulatory subunits in Saccharomyces cerevisiae

In budding yeast, cAMP-dependent protein kinase (PKA) plays a central role in the nutritional control of metabolism, cell cycle, and transcription. This study shows that both the regulatory subunit Bcy1p and the catalytic subunit Tpk1p associated with it are predominantly localized in the nucleus of rapidly growing cells. Activation of nuclear PKA by cAMP leads to fast entry of a significant part of Tpk1p into the cytoplasm, while the regulatory subunit remains nuclear. In contrast to rapidly proliferating cells, both Bcy1p and Tpk1p are distributed over nucleus and cytoplasm in cells growing on a nonfermentable carbon source or in stationary phase cells. These results demonstrate that at least two different mechanisms determine the subcellular localization of PKA; cAMP controls the localization of Tpk1p, and the carbon source determines that of Bcy1p. The N-terminal domain of Bcy1p serves to target it properly during logarithmic and stationary phase. Studies with Bcy1p mutant versions unable to concentrate in the nucleus revealed that cells producing them are less viable in stationary phase than wild type cells, display delayed reproliferation following transfer to fresh growth medium, and, as diploids, exhibit reduced efficiency of sporulation.

Selection of genes repressed by cAMP that are induced by nutritional limitation in Saccharomyces cerevisiae

DNA-lacZ fusion libraries of yeast Saccharomyces cerevisiae were used to select genes coordinately regulated by the Ras-cAMP-cAPK signalling pathway. Sixteen new genes (AGP1, APE2, APE3, FPS1, GUT2, MDH2, PLB2, PYK2, RNR3, SUR1, UGA1, YHR033w, YBR006w, YHR143w, YMR086w and YOR173w) were found to be repressed by cAMP. Most of these genes encode for metabolic enzymes and are induced by nutritional limitations. These common properties suggest a role of this pathway in the metabolic adjustment of the cell to nutritional variations. The induction of 10 of these genes is reduced in the msn2,msn4 double mutant, which emphasizes the role of the Msn2/4p transcriptional activators in mediating the Ras-cAMP-cAPK signalling pathway. The Msn2p/Msn4p-independent expression of the six other genes suggests the existence of other regulatory systems under the control of this pathway.

The economics of ribosome biosynthesis in yeast

In a rapidly growing yeast cell, 60% of total transcription is devoted to ribosomal RNA, and 50% of RNA polymerase II transcription and 90% of mRNA splicing are devoted to ribosomal proteins (RPs). Coordinate regulation of the approximately 150 rRNA genes and 137 RP genes that make such prodigious use of resources is essential for the economy of the cell. This is entrusted to a number of signal transduction pathways that can abruptly induce or silence the ribosomal genes, leading to major implications for the expression of other genes as well.

Molecular mechanism of the multiple regulation of the Saccharomyces cerevisiae ATF1 gene encoding alcohol acetyltransferase

The ATF1 gene encodes an alcohol acetyl transferase (AATase), that catalyses the synthesis of acetate esters from acetyl CoA and several kinds of alcohols. ATF1 transcription is negatively regulated by unsaturated fatty acids and oxygen. A series of analyses of the ATF1 promoter identified an 18 bp element essential for transcriptional activation. Ligation of the 18 bp element into a plasmid carrying the CYC1 promoter deleted UAS-activated transcription and conferred transcriptional repression by unsaturated fatty acids. The 18 bp element contains a binding sequence for Rap1p, which is a transcriptional repressor and activator. In vitro binding studies showed that Rap1p binds to the 18 bp element essential for transcriptional activation. The results of internal deletion studies of the promoter region suggested that there was also a region responsible for ATF1 oxygen regulation. This region contained the consensus binding sequence for the hypoxic repressor Rox1p. In vitro binding studies showed that Rox1p binds to the region responsible for oxygen regulation. To investigate the effect of the hypoxic repressor complex on transcription, ATF1 expression was measured in rox1, tup1 and ssn6 disruptant strains. It was found that rox1, tup1 and ssn6 disruption caused elevated expression of ATF1 under aerobic conditions. Thus, the activation of ATF1 transcription is dependent on Rap1p, and the Rox1p-Tup1p-Ssn6p hypoxic repressor complex is responsible for repression by oxygen. Furthermore, a study of ATF1 expression in a sch9 null mutant suggested that the Sch9p protein kinase is involved in ATF1 trancriptional activation.

TOR kinase homologs function in a signal transduction pathway that is conserved from yeast to mammals

Rapamycin is a natural product with potent antifungal and immunosuppressive activities. Rapamycin binds to the FKBP12 prolyl isomerase, and the resulting protein-drug complex inhibits the TOR kinase homologs. Both the FKBP12 and the TOR proteins are highly conserved from yeast to man, and genetic and biochemical studies reveal that these proteins are the targets of rapamycin in vivo. Treatment of yeast or mammalian cells with rapamycin inhibits translational initiation of a subset of mRNAs and dramatically represses ribosomal mRNA and tRNA transcription. Furthermore, rapamycin exposure blocks cell cycle progression in the early G1 phase of the cell cycle, driving cells into a G0 state and, ultimately, triggering autophagy. Recent findings reveal that the upstream factors regulating the TOR signaling cascade are involved in detecting amino acids, nutrients, or growth factors. These findings indicate that the TOR proteins function in a signal transduction pathway that coordinates nutritional and mitogenic signals to control protein biosynthesis and degradation.

A Saccharomyces cerevisiae G-protein coupled receptor, Gpr1, is specifically required for glucose activation of the cAMP pathway during the transition to growth on glucose

In the yeast Saccharomyces cerevisiae the accumulation of cAMP is controlled by an elaborate pathway. Only two triggers of the Ras adenylate cyclase pathway are known. Intracellular acidification induces a Ras-mediated long-lasting cAMP increase. Addition of glucose to cells grown on a non-fermentable carbon source or to stationary-phase cells triggers a transient burst in the intracellular cAMP level. This glucose-induced cAMP signal is dependent on the G alpha-protein Gpa2. We show that the G-protein coupled receptor (GPCR) Gpr1 interacts with Gpa2 and is required for stimulation of cAMP synthesis by glucose. Gpr1 displays sequence homology to GPCRs of higher organisms. The absence of Gpr1 is rescued by the constitutively activated Gpa2Val-132 allele. In addition, we isolated a mutant allele of GPR1, named fil2, in a screen for mutants deficient in glucose-induced loss of heat resistance, which is consistent with its lack of glucose-induced cAMP activation. Apparently, Gpr1 together with Gpa2 constitute a glucose-sensing system for activation of the cAMP pathway. Deletion of Gpr1 and/or Gpa2 affected cAPK-controlled features (levels of trehalose, glycogen, heat resistance, expression of STRE-controlled genes and ribosomal protein genes) specifically during the transition to growth on glucose. Hence, an alternative glucose-sensing system must signal glucose availability for the Sch9-dependent pathway during growth on glucose. This appears to be the first example of a GPCR system activated by a nutrient in eukaryotic cells. Hence, a subfamily of GPCRs might be involved in nutrient sensing.

A gene coding for a ribosomal protein L41 in cycloheximide-resistant ribosomes has a promoter which is upregulated under the growth-inhibitory conditions in yeast, Candida maltosa

We previously found by using yeast, Candida maltosa, that cycloheximide (CYH) sensitivity of ribosomes is dependent on the 56th amino acid residues of a ribosomal protein, L413 (proline in sensitive and glutamine in resistant ribosomes). We also revealed that in this yeast, which has both L41-P type and L41-Q type genes, the expression of the latter type genes is induced by the addition of CYH in the medium to make the cells inducibly resistant to CYH. In this paper, we analyzed the promoter region of L41-Q2a, one of the CYH-inducible L41-Q type genes and found two elements required for the induction of expression: one was a GCRE (Gcn4p-responsive element of Saccharomyces cerevisiae)-like element and the other was a GT-rich element. This promoter region was also required for its expression under some other growth inhibitory conditions. Furthermore, it was suggested that Q-type ribosomes synthesized under these conditions are more resistant to these inhibitory conditions.

Protein kinase C enables the regulatory circuit that connects membrane synthesis to ribosome synthesis in Saccharomyces cerevisiae

The balanced growth of a cell requires the integration of major systems such as DNA replication, membrane biosynthesis, and ribosome formation. An example of such integration is evident from our recent finding that, in Saccharomyces cerevisiae, any failure in the secretory pathway leads to severe repression of transcription of both rRNA and ribosomal protein genes. We have attempted to determine the regulatory circuit(s) that connects the secretory pathway with the transcription of ribosomal genes. Experiments show that repression does not occur through the circuit that responds to misfolded proteins in the endoplasmic reticulum, nor does it occur through circuits known to regulate ribosome synthesis, e.g. the stringent response, or the cAMP pathway. Rather, it appears to depend on a stress response at the plasma membrane that is transduced through protein kinase C (PKC). Deletion of PKC1 relieves the repression of both ribosomal protein and rRNA genes that occurs in response to a defect in the secretory pathway. We propose that failure of the secretory pathway prevents the synthesis of new plasma membrane. As protein synthesis continues, stress develops in the plasma membrane. This stress is monitored by Pkc1p, which initiates a signal transduction pathway that leads to repression of transcription of the rRNA and ribosomal protein genes. The importance of the transcription of the 137 ribosomal protein genes to the economy of the cell is apparent from the existence of at least three distinct pathways that can effect the repression of this set of genes.

Carbon regulation of ribosomal genes in Neurospora crassa occurs by a mechanism which does not require Cre-1, the homologue of the Aspergillus carbon catabolite repressor, CreA

Transcription of the ribosomal protein and 40S rRNA genes is coordinately regulated during steady state growth and carbon shifts in Neurospora crassa. Recognition sequences for the Aspergillus nidulans carbon catabolite repressor, CreA, overlap transcriptional elements of a 40S rRNA gene and the crp-2 ribosomal protein gene. They also occur in similar locations in the promoters of several other ribosomal protein genes. Substitutions encompassing the -74 and -167 CreA consensus sequences in the crp-2 promoter result in a decrease in transcription. A cDNA encoding the N. crassa homologue of CreA was cloned and designated Cre-1. The Cre-1 protein is 45% identical to CreA from A. nidulans. Cre-1 protein produced in Escherichia coli binds to the CreA sites in the promoters of the 40S rRNA and crp-2 genes. An amino acid change from histidine (92) to threonine changed the Cre-1 binding specificity from (5'G/CC/TGGG/AG3') to (5'G/CC/TGGCG3'). Base substitutions in the Cre-1 binding sites of the crp-2 promoter disrupted binding of wildtype Cre-1 in vitro but had no effect on transcription during steady state growth or carbon shifts, indicating that regulation of ribosomal genes by carbon source is not mediated by Cre-1, but via different proteins binding the Cre-1 sites and the Dde boxes.

Role of RAS2 in recovery from chronic stress: effect on yeast life span

The replicative life span of Saccharomyces cerevisiae was previously shown to be modulated by the homologous signal transducers Ras1p and Ras2p in a reciprocal manner. We have used thermal stress as a life span modulator in order to uncover functional differences between the RAS genes that may contribute to their divergent effects on life span. Chronic exposure of cells throughout life to recurring heat shocks at sublethal temperatures decreased their replicative life span. ras2 mutants, however, suffered the largest decrease compared to wild-type and ras1 mutant cells. The decrease was correlated with a substantial delay in resumption of budding upon recovery from these heat shocks, indicating an impaired renewal of cell cycling. Detailed analysis of gene expression showed that, during recovery, ras2 mutants were selectively impaired in down-regulation of stress-responsive genes and up-regulation of growth-promoting genes. Our results suggest that one of the functions of RAS2 in maintaining life span, for which RAS1 does not substitute, is to ensure renewal of growth and cell division after bouts of stress that cells encounter during their life. This activity of RAS2 is effected by the cyclic AMP pathway. Overexpression of RAS2, but not RAS2(ser42) which is deficient in the activation of adenylate cyclase, completely reversed the effect of chronic stress on life span. Thus, RAS2 is limiting for longevity in the face of chronic stress. Since RAS2 is known to down-regulate stress responses, this demonstrates that for longevity the ability to recover from stress is at least as important as the ability to mount a stress response.

Specialized Rap1p/Gcr1p transcriptional activation through Gcr1p DNA contacts requires Gcr2p, as does hyperphosphorylation of Gcr1p

The multifunctional regulatory factor Rap1p of Saccharomyces cerevisiae accomplishes one of its tasks, transcriptional activation, by complexing with Gcr1p. An unusual feature of this heteromeric complex is its apparent capacity to contact simultaneously two adjacent DNA elements (UASRPG and the CT box, bound specifically by Rap1p and Gcr1p, respectively). The complex can activate transcription through isolated UASRPG but not CT elements. In promoters that contain both DNA signals its activity is enhanced, provided the helical spacing between the two elements is appropriate; this suggests that at least transient DNA loop formation is involved. We show here that this CT box-dependent augmentation of Rap1p/Gcr1p activation requires the presence of a third protein Gcr2p; the Gcr2- growth defect appears to result from a genome-wide loss of the CT box effect. Interestingly, a hyperphosphorylated form of Gcr1p disappears in delta gcr2 cells but reappears if they harbor a doubly point-mutated GCR1 allele that bypasses the Gcr2- growth defect. Gcr2p therefore appears to induce a conformation change in Gcr1p and/or stimulate its hyperphosphorylation; one or both of these effects can be mimicked in the absence of GCR2 by mutation of GCR1. This improved view of Rap1p/Gcr1p/Gcr2p function reveals a new aspect of eukaryotic gene regulation: modification of an upstream activator, accompanied by at least transient DNA loop formation, mediates its improved capacity to activate transcription.

Characterization and regulation of the genes encoding ribosomal proteins L39 and S7 of the human pathogen Candida albicans

Genes encoding the Candida albicans ribosomal proteins L39 and S7 (RPL39, RPS7) were isolated and sequenced. From RPL39 cDNA a single intron interrupting the fifth codon in the genomic sequence could be deduced. Two homologous RPL39 genes in Saccharomyces cerevisiae contain a single intron in a conserved position. In contrast, C. albicans RPS7 was found to lack an intron, while both S. cerevisiae homologs are interrupted by single introns. The deduced L39 and S7 proteins contained 67% and 83% identical residues compared to the S. cerevisiae homologs. During hyphal induction the RPL39, RPS7 and RPL29 transcript levels increased three- to six-fold relative to ribosomal RNA, while ACT1 and RPS33 control transcripts were not regulated extensively. As suggested by unaltered transcript stabilities during hyphal induction, this regulation occurs on the transcriptional level; a conserved 18 bp palindromic sequence (5'-TTAGGGCTATAGCCCTAA-3'), which is present in the promoter regions of the RPL39 and RPS7 genes, may be involved in regulation.

The Sch9 protein kinase in the yeast Saccharomyces cerevisiae controls cAPK activity and is required for nitrogen activation of the fermentable-growth-medium-induced (FGM) pathway

In cells of the yeast Saccharomyces cerevisiae, trehalase activation, repression of CTT1 (catalase), SSA3 (Hsp70) and other STRE-controlled genes, feedback inhibition of cAMP synthesis and to some extent induction of ribosomal protein genes is controlled by the Ras-adenylate cyclase pathway and by the fermentable-growth-medium-induced pathway (FGM pathway). When derepressed cells are shifted from a non-fermentable carbon source to glucose, the Ras-adenylate cyclase pathway is transiently activated while the FGM pathway triggers a more lasting activation of the same targets when the cells become glucose-repressed. Activation of the FGM pathway is not mediated by cAMP but requires catalytic activity of cAMP-dependent protein kinase (cAPK; Tpk1, 2 or 3). This study shows that elimination of Sch9, a protein kinase with homology to the catalytic subunits of cAPK, affects all target systems in derepressed cells in a way consistent with higher activity of cAPK in vivo. In vitro measurements with trehalase and kemptide as substrates confirmed that elimination of sch9 enhances cAPK activity about two- to threefold, in both the absence and presence of cAMP. In vivo it similarly affected the basal and final level but not the extent of the glucose-induced responses in derepressed cells. The reduction in growth rate caused by deletion of SCH9 is unlikely to be responsible for the increase in cAPK activity since reduction of growth rate generally leads to lower cAPK activity in yeast. On the other hand, deletion of SCH9 abolished the responses of the protein kinase A targets in glucose-repressed cells. Re-addition of nitrogen to cells starved for nitrogen in the presence of glucose failed to trigger activation of trehalase, caused strongly reduced and aberrant repression of CTT1 and SSA3, and failed to induce the upshift in RPL25 expression. From these results three conclusions can be drawn: (1) Sch9 either directly or indirectly reduces the activity of protein kinase A; (2) Sch9 is not required for glucose-induced activation of the Ras-adenylate cyclase pathway; and (3) Sch9 is required for nitrogen-induced activation of the FGM pathway. The latter indicates that Sch9 might be the target of the FGM pathway rather than cAPK itself.

RIC1, a novel gene required for ribosome synthesis in Saccharomyces cerevisiae

We isolated a temperature-sensitive mutant of Saccharomyces cerevisiae in which transcription both of ribosomal protein genes and of ribosomal RNA is defective at the non-permissive temperature. Temperature-sensitivity for growth is recessive and segregates 2:2. The wild type gene, termed RIC1 (for ribosome control) was cloned by complementation of the temperature-sensitive phenotype from a genomic DNA library based on the CEN plasmid. RIC1 encodes a protein of 1056 amino acid (aa) residues including a putative nuclear localization sequence. Data base searches revealed that RIC1 is a novel gene and predicted aa sequence share some sequence similarity with viral transcriptional regulatory proteins.

Similar upstream regulatory elements of genes that encode the two largest subunits of RNA polymerase II in Saccharomyces cerevisiae

We have determined the location of cis-acting elements that are important for the expression of RPO21 and RPO22, genes that encode the two largest subunits of RNA polymerase II (RNAPII) in Saccharomyces cerevisiae. A series of 5'-end deletions and nucleotide substitutions in the upstream regions of RPO21 and RPO22 were tested for their effect on the expression of lacZ fusions of these genes. Deletion of sequences from -723 to -693 in RPO21, which disrupted two Reb1p-binding sites and an Abf1p-binding site, resulted in a 10-fold decrease in expression. A T-rich region downstream of these sites was also important for expression. Deletion of sequences from -437 to -392 in the RPO22-upstream, which resulted in a 30-fold decrease in expression, indicated that the Reb1p- and Abf1p-binding sites in this region were important for RPO22 expression, as was a T-rich sequence immediately downstream of these sites. The RPO21 and RPO22 upstream regions were capable of interacting in vitro (gel-mobility-shift assays) with Reb1p and Abf1p. The similarities in the type and organization of elements in the upstream regions of RPO21 and RPO22 suggest that expression of these genes may be regulated coordinately.

High cAMP levels antagonize the reprogramming of gene expression that occurs at the diauxic shift in Saccharomyces cerevisiae

In order to analyse the involvement of the cAMP pathway in the regulation of gene expression in Saccharomyces cerevisiae, we have examined the effect of cAMP on protein synthesis by using two-dimensional gel electrophoresis. cAMP had only a minor effect on the protein pattern of cells growing exponentially on glucose. However, it interfered with the changes in gene expression normally occurring upon glucose exhaustion in yeast cultures, maintaining a protein pattern typical of cells growing on glucose. This effect was accompanied by a delay before growth recovery on ethanol. We propose a model in which the cAMP-signalling pathway has a role in the maintenance of gene expression, rather than in the determination of a specific programme. A decrease of cAMP would then be required for metabolic transitions such as the diauxic phase.

Differential response to UV stress and DNA damage during the yeast replicative life span

The yeast Saccharomyces cerevisiae is mortal. Before they die, individual yeasts bud repeatedly producing a finite number of progeny, which have the capacity for a full life span. A feature of aging in many species is the waning of resistance to stress. To determine whether this is the case in yeast, we have examined the survival (viability) of age-synchronized populations of yeasts of various ages, spanning youth, midlife, and old age, after irradiation with ultraviolet light (UV). Resistance to UV was biphasic. There was an increase through midlife, followed by a precipitous decline. For comparison, another mutagenic agent, ethyl methanesulfonate (EMS), was tested in the same way. The response was very different. A uniphase decrease in resistance to this DNA-alkylating agent was found with a plateau later in life. The results argue that the increase in resistance to UV with age is an active process and not simply a monotonic age change. RAS2 is among the genes that determine yeast longevity. This gene is preferentially expressed in young cells and has a life span-extending effect on yeasts. One known function of RAS2 is to mount a protective response to irradiation by UV, which occurs independently of DNA damage. The distinction between UV and EMS found here is consistent with the notion that resistance to UV plays a role in yeast longevity in a manner not related to DNA damage. Furthermore, it suggests that RAS2 may participate in this response. We have found that RAS2 expression and UV resistance coincide in middle-aged yeasts bolstering this possibility. These data and the eclipse in activity of several longevity determining genes at midlife in yeasts also raise the possibility that active life maintenance processes function through this period, after which the organism operates on any remaining reserves until death.

Molecular and genetic analysis of the toxic effect of RAP1 overexpression in yeast

Rap1p is a context-dependent regulatory protein in yeast that functions as a transcriptional activator of many essential genes, including those encoding ribosomal proteins and glycolytic enzymes. Rap1p also participates in transcriptional silencing at HM mating-type loci and telomeres. Overexpression of RAP1 strongly inhibits cell growth, perhaps by interfering with essential transcriptional activation functions within the cell. Here we report a molecular and genetic analysis of the toxic effect of RAP1 overexpression. We show that toxicity does not require the previously defined Rap1p activation and silencing domains, but instead is dependent upon the DNA-binding domain and an adjacent region of unknown function. Point mutations were identified in the DNA-binding domain that relieve the toxic effect of overexpression. Two of these mutations can complement a RAP1 deletion yet cause growth defects and altered DNA-binding properties in vitro. However, a small deletion of the adjacent (downstream) region that abolishes overexpression toxicity has, by itself, no apparent effect on growth or DNA binding. SKO1/ACR1, which encodes a CREB-like repressor protein in yeast, was isolated as a high copy suppressor of the toxicity caused by RAP1 overexpression. Models related to the regulation of Rap1p activity are discussed.

Global regulators of ribosome biosynthesis in yeast

Three abundant ubiquitous DNA-binding protein factors appear to play a major role in the control of ribosome biosynthesis in yeast. Two of these factors mediate the regulation of transcription of ribosomal protein genes (rp-genes) in yeasts. Most yeast rp-genes are under transcriptional control of Rap1p (repressor-activator protein), while a small subset of rp-genes is activated through Abf1p (ARS binding factor). The third protein, designated Reb1p (rRNA enhancer binding protein), which binds strongly to two sites located upstream of the enhancer and the promoter of the rRNA operon, respectively, appears to play a crucial role in the efficient transcription of the chromosomal rDNA. All three proteins, however, have many target sites on the yeast genome, in particular, in the upstream regions of several Pol II transcribed genes, suggesting that they play a much more general role than solely in the regulation of ribosome biosynthesis. Furthermore, some evidence has been obtained suggesting that these factors influence the chromatin structure and creat a nucleosome-free region surrounding their binding sites. Recent studies indicate that the proteins can functionally replace each other in various cases and that they act synergistically with adjacent additional DNA sequences. These data suggest that Abf1p, Rap1p, and Reb1p are primary DNA-binding proteins that serve to render adjacent cis-acting elements accessible to specific trans-acting factors.

Mutations on the DNA-binding surface of TATA-binding protein can specifically impair the response to acidic activators in vivo

The TATA-binding protein (TBP) contains a concave surface that interacts specifically with TATA promoter elements and a convex surface that mediates protein-protein interactions with general and gene-specific transcription factors. Biochemical experiments suggest that interactions between activator proteins and TBP are important in stimulating transcription by the RNA polymerase II machinery. To gain insight into the role of TBP in mediating transcriptional activation in vivo, we implemented a genetic strategy in Saccharomyces cerevisiae that involved the use of a TBP derivative with altered specificity for TATA elements. By genetically screening a set of TBP mutant libraries that were biased to the convex surface that mediates protein-protein interactions, we identified TBP derivatives that are impaired in the response to three acidic activators (Gcn4, Gal4, and Ace1) but appear normal for constitutive polymerase II transcription. A genetic complementation assay indicates that the activation-defective phenotypes reflect specific functional properties of the TBP derivatives rather than an indirect effect on transcription. Surprisingly, three of the four activation-defective mutants affect residues that directly contact DNA. Moreover, all four mutants are defective for TATA element binding, but they interact normally with an acidic activation domain and TFIIB. In addition, we show that a subset of TBP derivatives with mutations on the DNA-binding surface of TBP are also compromised in their responses to acidic activators in vivo. These observations suggest that interactions at the TBP-TATA element interface can specifically affect the response to acidic activator proteins in vivo.

RAP1: a protean regulator in yeast

The yeast protein RAP1 is a sequence-specific DNA-binding protein that binds to many promoters, to two elements that silence mating-type genes, and to [(C)1-3A]n tracts at telomeres. RAP1 is essential for cell viability and can function as either an activator or a repressor of transcription, depending upon the context of its binding site. Recent experiments suggest that its function may be determined by different sets of protein-protein interactions at promoters and silencers. At the ends of chromosomes, RAP1 plays an important role in both silencing (telomere position effect) and telomere structure.

Nutritional upshift response of ribosomal protein gene transcription in Saccharomyces cerevisiae

Switching Saccharomyces cerevisiae from non-fermentative to fermentative growth by adding glucose to a medium with glycerol as the sole carbon source, leads to a sudden increase in the rate of ribosomal protein gene transcription. By analyzing the nutritional shift response in a variety of yeast mutants and in the presence of different drugs, evidence was obtained that: (i) no de novo protein synthesis is required for this response; (ii) protein kinase A is essential, though independent of intracellular levels of cAMP, whereas protein kinase C is not involved; (iii) proper regulation of sugar phosphorylation is essential; (iv) glycolysis is required for the long term effect of the nutritional upshift; and (v) pathways leading to glucose-induced activation differ from those leading to gene repression, probably already at the level of glucose transport.

Repression of growth-regulated G1 cyclin expression by cyclic AMP in budding yeast

A yeast cell becomes committed to the cell division cycle only if it grows to a critical size and reaches a critical rate of protein synthesis. The coordination between growth and division takes place at a control step during the G1 phase of the cell cycle called Start. It relies on the G1-specific cyclins encoded by CLN1, 2 and 3, which trigger Start through the activation of the Cdc28 protein kinase. In fact, the Cln cyclins are rate-limiting for Start execution and depend on growth. Here we report that the cyclic AMP signal pathway modulates the dependency of Cln cyclins on growth. In particular, more growth is required to trigger Start because CLN1 and CLN2 are repressed by the cAMP signal, thus explaining the previously observed cAMP-dependent increase of the critical size and critical rate of protein synthesis. Cln3 is not inhibited by the cAMP pathway and counteracts this mechanism by partially mediating the growth-dependent expression of other G1 cyclins.