The structural genes of internal invertases in Saccharomyces cerevisiae.

Summary Polyacrylamide gel electrophoresis (without SDS) of invertases from strains each carrying only one of the five known SUC-genes revealed differences in mobility of the internal enzymes. SUC1 invertase moved distinctly slower than the invertases formed in the presence of genes SUC2 to SUC5. Three bands of internal invertase activity were found in diploids carrying both SUC1 (slow invertase) and one of the other SUC-genes (fast invertases). Tetrad analysis of such diploids yielded haploids which showed the same three bands if they carried SUC1 in combination with another SUC gene. A gene dosage effect was observed in relation to invertase activity in haploid strains with only gene SUC1 or only SUC4 on one hand, and both genes on the other hand. A sucrose non-fermenting and invertase negative strain with mutant allele suc3-3 of gene SUC3 (fast invertase) was crossed with SUC1. The heterozygous diploid and the recombinant haploids (SUC1 suc3-3) showed two bands in the region of the internal invertase: a slow SUC1 band and a second band corresponding to the intermediate band of SUC1-SUC3 strains. The intermediate band in SUC1 suc3-3 strains is considered as a hybrid consisting of an active SUC1-monomer and an inactive suc3-mutant monomer. Formation of such hybrid bands was taken as evidence for the structural nature of SUC-genes.     

Regulation of nuclear genes encoding mitochondrial proteins in Saccharomyces cerevisiae.

Selection for mutants which release glucose repression of the CYB2 gene was used to identify genes which regulate repression of mitochondrial biogenesis. We have identified two of these as the previously described GRR1/CAT80 and ROX3 genes. Mutations in these genes not only release glucose repression of CYB2 but also generally release respiration of the mutants from glucose repression. In addition, both mutants are partially defective in CYB2 expression when grown on nonfermentable carbon sources, indicating a positive regulatory role as well. ROX3 was cloned by complementation of a glucose-inducible flocculating phenotype of an amber mutant and has been mapped as a new leftmost marker on chromosome 2. The ROX3 mutant has only a modest defect in glucose repression of GAL1 but is substantially compromised in galactose induction of GAL1 expression. This mutant also has increased SUC2 expression on nonrepressing carbon sources. We have also characterized the regulation of CYB2 in strains carrying null mutation in two other glucose repression genes, HXK2 and SSN6, and show that HXK2 is a negative regulator of CYB2, whereas SSN6 appears to be a positive effector of CYB2 expression.     

Suppression of Escherichia coli alkB mutants by Saccharomyces cerevisiae genes.

The alkB gene is one of a group of alkylation-inducible genes in Escherichia coli, and its product protects cells from SN2-type alkylating agents such as methyl methanesulfonate (MMS). However, the precise biochemical function of the AlkB protein remains unknown. Here, we describe the cloning, sequencing, and characterization of three Saccharomyces cerevisiae genes (YFW1, YFW12, and YFW16) that functionally complement E. coli alkB mutant cells. DNA sequence analysis showed that none of the three gene products have any amino acid sequence homology with the AlkB protein. The YFW1 and YFW12 proteins are highly serine and threonine rich, and YFW1 contains a stretch of 28 hydrophobic residues, indicating that it may be a membrane protein. The YFW16 gene turned out to be allelic with the S. cerevisiae STE11 gene. STE11 is a protein kinase known to be involved in pheromone signal transduction in S. cerevisiae; however, the kinase activity is not required for MMS resistance because mutant STE11 proteins lacking kinase activity could still complement E. coli alkB mutants. Despite the fact that YFW1, YFW12, and YFW16/STE11 each confer substantial MMS resistance upon E. coli alkB cells, S. cerevisiae null mutants for each gene were not MMS sensitive. Whether these three genes provide alkylation resistance in E. coli via an alkB-like mechanism remains to be determined, but protection appears to be specific for AlkB-deficient E. coli because none of the genes protect other alkylation-sensitive E. coli strains from killing by MMS.     

Glucose regulation of Saccharomyces cerevisiae cell cycle genes

Nutrient-limited Saccharomyces cerevisiae cells rapidly resume proliferative growth when transferred into glucose medium. This is preceded by a rapid increase in CLN3, BCK2, and CDC28 mRNAs encoding cell cycle regulatory proteins that promote progress through Start. We have tested the ability of mutations in known glucose signaling pathways to block glucose induction of CLN3, BCK2, and CDC28. We find that loss of the Snf3 and Rgt2 glucose sensors does not block glucose induction, nor does deletion of HXK2, encoding the hexokinase isoenzyme involved in glucose repression signaling. Rapamycin blockade of the Tor nutrient sensing pathway does not block the glucose response. Addition of 2-deoxy glucose to the medium will not substitute for glucose. These results indicate that glucose metabolism generates the signal required for induction of CLN3, BCK2, and CDC28. In support of this conclusion, we find that addition of iodoacetate, an inhibitor of the glyceraldehyde-3-phosphate dehydrogenase step in yeast glycolysis, strongly downregulates the levels CLN3, BCK2, and CDC28 mRNAs. Furthermore, mutations in PFK1 and PFK2, which encode phosphofructokinase isoforms, inhibit glucose induction of CLN3, BCK2, and CDC28. These results indicate a link between the rate of glycolysis and the expression of genes that are critical for passage through G₁.     

Six novel genes necessary for pre-mRNA splicing in Saccharomyces cerevisiae.

We have identified six new genes whose products are necessary for the splicing of nuclear pre-mRNA in the yeast Saccharomyces cerevisiae. A collection of 426 temperature-sensitive yeast strains was generated by EMS mutagenesis. These mutants were screened for pre-mRNA splicing defects by an RNA gel blot assay, using the intron- containing CRY1 and ACT1 genes as hybridization probes. We identified 20 temperature-sensitive mutants defective in pre-mRNA splicing. Twelve appear to be allelic to the previously identified prp2, prp3, prp6, prp16/prp23, prp18, prp19 or prp26 mutations that cause defects in spliceosome assembly or the first or second step of splicing. One is allelic to SNR14 encoding U4 snRNA. Six new complementation groups, prp29-prp34, were identified. Each of these mutants accumulates unspliced pre-mRNA at 37 degrees C and thus is blocked in spliceosome assembly or early steps of pre-mRNA splicing before the first cleavage and ligation reaction. The prp29 mutation is suppressed by multicopy PRP2 and displays incomplete patterns of complementation with prp2 alleles, suggesting that the PRP29 gene product may interact with that of PRP2. There are now at least 42 different gene products, including the five spliceosomal snRNAs and 37 different proteins that are necessary for pre-mRNA splicing in Saccharomyces cerevisiae. However, the number of yeast genes identifiable by this approach has not yet been exhausted.     

Multiple protein tyrosine phosphatase-encoding genes in the yeast Saccharomyces cerevisiae.

In higher eukaryotic organisms, the regulation of tyrosine phosphorylation is known to play a major role in the control of cell division. Recently, a wide variety of protein tyrosine phosphatase (PTPase)-encoding genes (PTPs) have been identified to accompany the many tyrosine kinases previously studied. However, in the yeasts, where the cell cycle has been most extensively studied, identification of the genes involved in the direct regulation of tyrosine phosphorylation has been difficult. We have identified a pair of genes in the yeast Saccharomyces cerevisiae, which we call PTP1 and PTP2, whose products are highly homologous to PTPases identified in other systems. Both genes are poorly expressed, and contain sequence elements consistent with low-abundance proteins. We have carried out an extensive genetic analysis of PTP1 and PTP2, and found that they are not essential either singly or in combination. Neither deletion nor overexpression results in any strong phenotypes in a number of assays. Deletions also do not affect the mitotic blockage caused by deletion of the MIH1 gene (encoding a positive regulator of mitosis) and induction of the heterologous Schizosaccharomyces pombe wee1+ gene (encoding a negative regulator of mitosis). Molecular analysis has shown that PTP1 and PTP2 are quite different structurally and are not especially well conserved at the amino acid sequence level. Low-stringency Southern blots indicate that yeast may contain a family of PTPase-encoding genes. These results suggest that yeast may contain other PTPase-encoding genes that overlap functionally with PTP1 and PTP2.     

Allelism of IMP1 and GAL2 genes of Saccharomyces cerevisiae.

Cloning and characterization of the previously described Saccharomyces cerevisiae IMP1 gene, which was assumed to be a nuclear determinant involved in the nucleomitochondrial control of the utilization of galactose, demonstrate allelism to the GAL2 gene. Galactose metabolism does not necessarily involve the induction of the specific transport system coded by GAL2/IMP1, because a null mutant takes up galactose and grows on it. Data on galactose uptake are presented, and the dependence on ATP for constitutive and inducible galactose transport is discussed. These results can account for the inability of imp1/gal2 mutants to grow on galactose in a respiration-deficient background. Under these conditions, uptake was affected at the functional level but not at the biosynthetic level.     

Characterization of the five replication factor C genes of Saccharomyces cerevisiae.

Replication factor C (RFC) is a five-subunit DNA polymerase accessory protein that functions as a structure-specific, DNA-dependent ATPase. The ATPase function of RFC is activated by proliferating cell nuclear antigen. RFC was originally purified from human cells on the basis of its requirement for simian virus 40 DNA replication in vitro. A functionally homologous protein complex from Saccharomyces cerevisiae, called ScRFC, has been identified. Here we report the cloning, by either peptide sequencing or by sequence similarity to the human cDNAs, of the S. cerevisiae genes RFC1, RFC2, RFC3, RFC4, and RFC5. The amino acid sequences are highly similar to the sequences of the homologous human RFC 140-, 37-, 36-, 40-, and 38-kDa subunits, respectively, and also show amino acid sequence similarity to functionally homologous proteins from Escherichia coli and the phage T4 replication apparatus. All five subunits show conserved regions characteristic of ATP/GTP-binding proteins and also have a significant degree of similarity among each other. We have identified eight segments of conserved amino acid sequences that define a family of related proteins. Despite their high degree of sequence similarity, all five RFC genes are essential for cell proliferation in S. cerevisiae. RFC1 is identical to CDC44, a gene identified as a cell division cycle gene encoding a protein involved in DNA metabolism. CDC44/RFC1 is known to interact genetically with the gene encoding proliferating cell nuclear antigen, confirming previous biochemical evidence of their functional interaction in DNA replication.     

Disruption of single-copy genes encoding acidic ribosomal proteins in Saccharomyces cerevisiae.

Using the cloned genes coding for the ribosomal acidic proteins L44 and L45, constructions were made which deleted part of the coding sequence and inserted a DNA fragment at that site carrying either the URA3 or HIS3 gene. By gene disruption techniques with linearized DNA from these constructions, strains of Saccharomyces cerevisiae were obtained which lacked a functional gene for either protein L44 or protein L45. The disrupted genes in the transformants were characterized by Southern blots. The absence of the proteins was verified by electrofocusing and immunological techniques, but a compensating increase of the other acidic ribosomal proteins was not detected. The mutant lacking L44 grew at a rate identical to the parental strain in complex as well as in minimal medium. The L45-disrupted strain also grew well in both media but at a slower rate than the parental culture. A diploid strain was obtained by crossing both transformants, and by tetrad analysis it was shown that the double transformant lacking both genes is not viable. These results indicated that proteins L44 and L45 are independently dispensable for cell growth and that the ribosome is functional in the absence of either of them.     

Saccharomyces cerevisiae PAU genes are induced by anaerobiosis

Saccharomyces cerevisiae PAU genes constitute the largest multigene family in yeast, with 23 members located mainly in subtelomeric regions. The role and regulation of these genes were previously unknown. We detected PAU gene expression during alcoholic fermentation. An analysis of PAU gene regulation using PAU-lacZ fusions and Northern analyses revealed that they were regulated by anaerobiosis. PAU genes display, however, different abilities to be induced by anaerobiosis and this appears to be related to their chromosomal localization; two subtelomeric copies are more weakly inducible than an interstitial one. We show that PAU genes are negatively regulated by oxygen and repressed by haem. Examination of PAU gene expression in rox1Delta and tup1Delta strains indicates that PAU repression by oxygen is mediated by an unknown, haem-dependent pathway, which does not involve the Rox1p anaerobic repressor but requires Tup1p. Given the size of the gene family, PAU genes could be expected to be important during yeast life and some of them probably help the yeast to cope with anaerobiosis.