The URE2 protein regulates nitrogen catabolic gene expression through the GATAA-containing UASNTR element in Saccharomyces cerevisiae.

Many of the gene products that participate in nitrogen metabolism are sensitive to nitrogen catabolite repression (NCR), i.e., their expression is decreased to low levels when readily used nitrogen sources such as asparagine are provided. Previous work has shown this NCR sensitivity requires the cis-acting UASNTR element and trans-acting GLN3. Here, we extend the analysis to include the response of their expression to deletion of the URE2 locus. The expression of these nitrogen catabolic genes becomes, to various degrees, NCR insensitive in the ure2 deletion. This response is shown to be mediated through the GATAA-containing UASNTR element and supports the current idea that the NCR regulatory circuit involves the following steps: environmental signal-->URE2-->GLN3-->UASNTR operation-->NCR-sensitive gene expression. The various responses of the nitrogen catabolic genes' expression to deletion of the URE2 locus also indicate that not all NCR is mediated through URE2.     

The Saccharomyces cerevisiae checkpoint gene BUB1 encodes a novel protein kinase.

Normal cell multiplication requires that the events of mitosis occur in a carefully ordered fashion. Cells employ checkpoints to prevent cycle progression until some prerequisite step has been completed. To explore the mechanisms of checkpoint enforcement, we previously screened for mutants of Saccharomyces cerevisiae which are unable to recover from a transient treatment with a benzimidazole-related microtubule inhibitor because they fail to inhibit subsequent cell cycle steps. Two of the identified genes, BUB2 and BUB3, have been cloned and described (M. A. Hoyt, L. Totis, and B. T. Roberts, Cell 66:507-517, 1991). Here we present the characterization of the BUB1 gene and its product. Genetic evidence was obtained suggesting that Bub1 and Bub3 are mutually dependent for function, and immunoprecipitation experiments demonstrated a physical association between the two. Sequence analysis of BUB1 revealed a domain with similarity to protein kinases. In vitro experiments confirmed that Bub1 possesses kinase activity; Bub1 was able to autophosphorylate and to catalyze phosphorylation of Bub3. In addition, overproduced Bub1 was found to localize to the cell nucleus.     

Candida albicans HEX1 gene, a reporter of gene expression in Saccharomyces cerevisiae

A nonapeptide from IL-1β has been reported to be an immunostimulant and adjuvant. To investigate the possibility of enhancing the immunogenicity of recombinant antigens delivered by live-attenuated Salmonella strains, we inserted an oligonucleotide coding for the nonapeptide from murine IL-1β into the genes of three model proteins: LamB, MalE, and flagellin. The hybrid proteins were expressed and delivered in vivo by Salmonella aroA strains, and serum antibody responses were analyzed. The results showed that the nonapeptide induced an increase in the immune response against Salmonella-delivered flagellin, measured on day 28 post-immunization. However, the adjuvant effect was lost by day 42. In no case was an adjuvant effect detected for Salmonella-delivered LamB or MalE. Thus, by comparing the immune responses raised by purified MalE with and without the peptide, we investigated whether the insertion of the peptide affected the immunogenicity of the protein itself. Also in this case, a modest adjuvant effect was shown only after primary immunization and when very low doses of antigen were used. In conclusion, the immunomodulatory properties of the IL-1β peptide can also be detected when it is delivered in vivo by Salmonella; however, the effect is modest and antigen-dependent. Received: 30 May 1997 / Accepted: 15 September 1997     

The ROX3 gene encodes an essential nuclear protein involved in CYC7 gene expression in Saccharomyces cerevisiae.

The ROX3 gene was identified during a hunt for mutants with increased expression of the heme-regulated CYC7 gene, which encodes the minor species of cytochrome c in the yeast Saccharomyces cerevisiae. The rox3 mutants caused a 10-fold increase in CYC7 expression both in the presence and absence of heme, had slightly increased anaerobic expression of the heme-activated CYC1 gene, and caused decreases in the anaerobic expression of the heme-repressed ANB1 gene and the aerobic expression of its heme-induced homolog. The wild-type ROX3 gene was cloned, and the sequence indicated that it encodes a 220-amino-acid protein. This protein is essential; deletion of the coding sequence was lethal. The coding sequence for beta-galactosidase was fused to the 3' end of the ROX3 coding sequence, and the fusion product was found to be localized in the nucleus, strongly suggesting that the wild-type protein carries out a nuclear function. Mutations in the rox3 gene showed an interesting pattern of intragenic complementation. A deletion of the 5' coding region complemented a nonsense mutation at codon 128 but could not prevent the lethality of the null mutation. These results suggest that the amino-terminal domain is required for an essential function, while the carboxy-terminal domain can be supplied in trans to achieve the wild-type expression of CYC7. Finally, RNA blots demonstrated that the ROX3 mRNA was expressed at higher levels anaerobically but was not subject to heme repression. The nuclear localization and the lack of viability of null mutants suggest that the ROX3 protein is a general regulatory factor.     

GDH3 encodes a glutamate dehydrogenase isozyme, a previously unrecognized route for glutamate biosynthesis in Saccharomyces cerevisiae.

It has been considered that the yeast Saccharomyces cerevisiae, like many other microorganisms, synthesizes glutamate through the action of NADP+-glutamate dehydrogenase (NADP+-GDH), encoded by GDH1, or through the combined action of glutamine synthetase and glutamate synthase (GOGAT), encoded by GLN1 and GLT1, respectively. A double mutant of S. cerevisiae lacking NADP+-GDH and GOGAT activities was constructed. This strain was able to grow on ammonium as the sole nitrogen source and thus to synthesize glutamate through an alternative pathway. A computer search for similarities between the GDH1 nucleotide sequence and the complete yeast genome was carried out. In addition to identifying its cognate sequence at chromosome XIV, the search found that GDH1 showed high identity with a previously recognized open reading frame (GDH3) of chromosome I. Triple mutants impaired in GDH1, GLT1, and GDH3 were obtained. These were strict glutamate auxotrophs. Our results indicate that GDH3 plays a significant physiological role, providing glutamate when GDH1 and GLT1 are impaired. This is the first example of a microorganism possessing three pathways for glutamate biosynthesis.     

The ICL1 gene from Saccharomyces cerevisiae.

The glyoxylate cycle is essential for the utilization of C2 compounds by the yeast Saccharomyces cerevisiae. Within this cycle, isocitrate lyase catalyzes one of the key reactions. We obtained mutants lacking detectable isocitrate lyase activity, screening for their inability to grow on ethanol. Genetic and biochemical analysis suggested that they carried a defect in the structural gene, ICL1. The mutants were used for the isolation of this gene and it was located on a 3.1-kb BglII-SphI DNA fragment. We then constructed a deletion-substitution mutant in the haploid yeast genome. It did not have any isocitrate lyase activity and lacked the ability to grow on ethanol as the sole carbon source. Both strands of a DNA fragment carrying the gene and its flanking regions were sequenced. An open reading frame of 1671 bp was detected, encoding a protein of 557 amino acids with a calculated molecular mass of 62515 Da. The deduced amino acid sequence shows extensive similarities to genes encoding isocitrate lyases from various organisms. Two putative cAMP-dependent protein-kinase phosphorylation sites may explain the susceptibility of the enzyme to carbon catabolite inactivation.     

Regulation of nitrogen assimilation in Saccharomyces cerevisiae: roles of the URE2 and GLN3 genes.

Mutations in the GLN3 gene prevented a normal increase in the NAD-glutamate dehydrogenase and glutamine synthetase levels in glutamate-grown Saccharomyces cerevisiae cells, whereas mutations in the URE2 gene resulted in high levels of these enzymes in glumate- and glutamine-grown cells. A ure2 gln3 double mutant had low levels of glutamate dehydrogenase and glutamine synthetase in cells grown on glutamate and glutamine; thus, gln3 mutations were epistatic to the ure2 mutations. The results suggest that the GLN3 product is capable of promoting increases in enzyme levels in the absence of a functional URE2 product and that the URE2 product antagonizes the GLN3 product. The URE2 and GLN3 genes were also found to regulate the level of arginase activity. This regulation is completely independent of the regulation of arginase by substrate induction. The activities of glutamate dehydrogenase, glutamine synthetase, and arginase were higher in cells grown on glutamate as the nitrogen source than they were in cells grown under a nitrogen-limiting condition. It had previously been shown that the levels of these enzymes can be increased by glutamine deprivation. We propose that the URE2-GLN3 system regulates enzyme synthesis, in response to glutamine and glutamate, to adjust the intracellular concentration of ammonia so as to maintain glutamine at the level required for optimal growth.