Relationships between trehalose metabolism and maltose utilization in Saccharomyces cerevisiae

Summary A pattern of active accumulation of trehalose during growth on glucose medium, TAC(+) phenotype, is controlled by a polymeric series of maltose fermentation (MAL) genes. An essential requirement for expression of the TAC(+) phenotype is that the MAL gene be in the constitutive state, MAL ^c. Mutation of a constitutive MAL allele to a maltose- inducible or nonfermenting (mal) state, alters the pattern of trehalose metabolism so that little or no trehalose accumulation occurs during growth on glucose medium. The TAC(+) phenotype is obtained in MAL ^c strains whether or not -glucosidase formation is sensitive or resistant to carbon catabolite repression. However, trehalose accumulation is sensitive to glucose levels even in MAL ^c strains in which -glucosidase formation is insensitive to catabolite repression. The effects of constitutive MAL genes on trehalose accumulation cannot be accounted for by an increase in trehalose-6 phosphate synthase or a decrease in trehalase as determined in vitro. A mechanism is proposed in which the gene-product of a MAL gene serves as a common positive regulator for expression of four genes coding respectively for maltose permease, maltase, -methylglucosidase and a component of the trehalose accumulation system.Paper I appeared in Cell. and Molec. Biology 25: 345–354, 1979     

MAL63 codes for a positive regulator of maltose fermentation in Saccharomyces cerevisiae

Summary Genetic analysis of the MAL6 locus has previously yielded mal6 mutants which fall into a single complementation group and which are noninducible for maltase and maltose permease. However, the strains used in these studies contained additional partially functional copies of MAL1 (referred to as MAL1g) and MAL3 (referred to as MAL3g). Using a strain lacking MALg genes, we have isolated two classes of mutants and these classes correspond to mutations in MAL63 and MAL61, two genes of the MAL6 complex. Disruptions of MAL63 are noninducible for maltase and maltose permease and for their corresponding mRNAs. The mal6 mutants are shown to map to MAL63 Inducer exclusion as a cause of the noninducible phenotype of the mal63 mutations has been eliminated by constructing a ma163 mutant in a strain constitutive for maltose permease; the strain remains noninducible. These results rigorously demonstrate that MAL63 is a regulatory gene which plays a positive role in the regulation of maltose fermentation.     

A method to sharply delimit a yeast nuclear gene in a cloned DNA fragment

Summary We have developped a procedure to delimit the boundaries of a cloned gene carried on a DNA fragment as large as 4 to 5 kilobases. The method consists in the following. Two series of limit digest products generated with a tetranucleotide recognition sequence endonuclease and originating from either of the two ends of this DNA segment are tested for their complementing capacity by yeast transformation. The gene is then delimited by the overlap of the two shortest complementing fragments.     

High frequency recombination and the expression of genes cloned on chimeric yeast plasmids: Identification of a fragment of 2-μm circle essential for transformation

Summary We have carried out experiments aimed at explaining the observed variations in transformation frequencies when Saccharomyces cerevisiae or Saccharomyces carlbergensis are transformed with chimeric plasmids that contain one of 4 possible EcoRI fragments of the yeast 2-m circle. These plasmids fall into 2 classes when used to transform 2 different yeast his3 auxotrophs, one (strain LL20) harbours indigenous 2-m circle, and the other (strain YF233) is devoid of this plasmid. Hybrid plasmids containing either the 2.4 mega-dalton (mD) R-form EcoRI fragment (pYF88) or the l.4 mD L-form EcoRI fragment (pYF177) of 2-m circle transform either of the two hosts at a high frequency (50,000 colonies per Mg in LL20 and 10,000 colonies per g in YF233). Hybrid plasmids containing the 1.5 mD R-form EcoRI fragment (pYF87) or the 2.5 mD L-form EcoRI fragment (pYF178) of the 2-m circle transform LL20 at a reduced frequency (6,000–16,000 colonies per g) and YF233 at extremely low frequencies (1–5 colonies per g). All plasmids retrieved from strain YF233 that had been transformed with pYF88 or pYF177 were identical to the original transforming plasmid. Of the plasmids retrieved from strain LL20 that had been transformed with pYF87 and pYF178, approximately half had acquired an extra copy of the 2-m circle. Of the plasmids retrieved from strain LL20 that had been transformed with pYF88 and pYF177, an average of only approximately 13% had acquired an extra copy of 2-m circle. Taken together, these observations indicate that the transformation of yeast by a plasmid lacking the ability to replicate (pYF87 and pYF1780) occurs by the recombinational acquisition of 1 copy of the host 2-m circle, which serves to supply the incoming plasmid with missing essential sequences. A comparison of 2-m circle DNA fragments carried by pYF88 and pYF177 indicates that the region of 2-m circle required for high frequency transformation is a 1.2 mD segment that is common to the 2.4 mD R-form and 1.4 ml) L-form EcoRI fragments. This region extends from the EcoRI cut site adjacent to the PstI site, through to the end of the inverted repeat. However, the inverted repeat sequence alone is not sufficient to bestow high frequency transformation of yeast.     

Isolation of the yeast INO4 gene,a positive regulator of phospholipid biosynthesis

Summary Yeast ino4 mutants are auxotrophic for the phospholipid precursor inositol and have pleiotropic defects in phospholipid synthesis. The mutants are unable to derepress the cytoplasmic enzyme, inositol-1-phosphate synthase and they exhibit reduced synthesis of methylated phospholipids, particularly phosphatidylcholine. The INO4 gene is believed to encode a positive regulator involved in coordinate control of phospholipid synthesis. In the present study, we report the isolation of two clones containing the INO4 gene. The clones share a region of homology and were mapped to the INO4 locus. Southern blot analysis revealed that the cloned DNA contained both unique and repetitive DNA.     

Relationships between trehalose metabolism and maltose utilization in Saccharomyces cerevisiae

Summary A specific deficiency in UDPG-linked trehalose-6-phosphate synthase in the yeast, Saccharomyces cerevisiae has been associated with a single nuclear gene, sst1. Strains bearing this abnormal allele lacked the capacity to accumulate trehalose during growth on glucose or galactose medium or when incubated with glucose in nonproliferating conditions. However, sst1 strains still exhibited trehalose accumulation during growth on maltose medium, provided they contained a gene for maltose fermentation (MAL gene). Introduction of a constitutive MAL ^c gene into an sst1 strain rendered the strain capable of accumulating trehalose during growth on glucose medium, but did not restore the normal capacity to convert glucose to trehalose in nonproliferating conditions. Different systems, I and II, of trehalose accumulation are proposed. System I would require the UPDG-linked synthase, whereas system II, which is normally specific for maltose, would utilize a different enzyme. It is unlikely that system II produces trehalose by trans-glucosylation, since it converted glucose to trehalose in MAL ^c sst1 strains. The results indicate that maltose specifically induces the production of the MAL gene-product, which, in turn, would stimulate the formation (or activation) of system II.     

Suppressible alleles in a wide domain regulatory gene in Aspergillus nidulans

Summary The areA gene of Aspergillus nidulans is a one of the better studied eukaryotic wide domain regulatory genes, necessary for the expression of most structural genes involved in the utilization of a wide variety of nitrogen sources (Arst and Cove 1973; Arst 1983). Here we report the isolation and properties of areA alleles suppressible by translational suppressors (Roberts et al. 1979). Thus we show formally that the areA gene specifies a protein rather than an RNA product and we show that it is possible to generate by external suppression areA gene products with modified properties.     

Isolation of a Chlamydomonas reinhardtii telomer by functional complementation in yeast

We attempted to determine whether Chlamydomonas reinhardtii telomeres, which do not form G-quartet structures readily in vitro, are able to nucleate telomere addition in Saccharomyces cerevisiae. Restricted C. reinhardtii genomic DNA was ligated to a linear S. cerevisiae vector lacking a telomere. A C. reinhardtii telomere ligated to this unprotected end allowed vector replication as a linear DNA molecule in S. cerevisiae. DNA sequencing revealed common [T₄AG₃]_n and variant T₆AG₃ and T₅AG₃ C. reinhardtii telomere repeats capped by S. cerevisiae telomere repeat units. The recognition of a C. reinhardtii telomere by the telomere maintenance machinery of S. cerevisiae is consistent with a common theme for telomere structure in organisms with divergent telomere repeats.     

MboI,ThaI and HinfI endonuclease cleavage maps of the yeast mitochondrial DNA

Summary MboI, HinfI and ThaI cleavage maps have been constructed for the region of the mitochondrial DNA from S. cerevisiae where transfer RNA genes are principally located. About 40 cleavage sites have been localized between the C and P genetic markers. The MboI map covers about 50% of the total mitochondrial genome. For constructing maps we have used a series of rho^– deletion mutants whose mitochondrial DNAs have a typical single deletion structure as judged by previous genetic and physical analyses. The mutant DNAs carry known transfer RNA genes and genetic markers and, therefore, the comparison between genetic and restriction maps has allowed us to localize individual transfer RNA genes within defined physical segments.Abbreviations bp base pairs - mtDNA mitochondrial DNA - tRNA transfer RNA - rRNA ribosomal RNA - ThaI formerly TacI     

Functional analysis of the yeast genome: use of two-dimensional gel electrophoresis to detect genes in randomly cloned DNA sequences

Summary Genes are overexpressed when present in yeast cells on multicopy plasmids. Taking advantage of the protein amplification which results from this overexpression, a method has been developed for large scale detection of yeast genes on randomly cloned DNA sequences. It is based on the analysis, by two-dimensional gel electrophoresis, of the proteins from yeast cells transformed with a yeast genomic DNA library constructed in a multicopy vector. We demonstrate here the applicability of this method for exploring the yeast genome. In addition, we report results which suggest that this method may also be useful for detecting regulatory genes.     

Cloning and expression on a multicopy vector of five invertase genes of Saccharomyces cerevisiae

Summary Six unlinked loci for invertase structural genes are known in the yeast Saccharomyces cerevisiae: SUC1-SUC5 and SUC7. These genes are similar in structure and expression but not identical. Different yeast strains possess none, one or several of these genes.We have isolated the genes SUC1-SUC5, subcloned them into the multicopy vector YEp24 and compared the expression of the five SUC genes in one recipient strain. SUC2 was isolated by transformation of a suc0 strain with a gene pool and complementation to sucrose fermentation. SUC4 was cloned from a minipool of chromosomal fragments which were shown to contain SUC4 by Southern hybridization. SUC1, SUC3 and SUC5 were isolated using the method of plasmid eviction. A plasmid containing regions flanking SUC4 was integrated next to these SUC genes. The plasmid together with the SUC genes were then cut out of the chromosome using an appropriate restriction endonuclease.The length of chromosomal DNA fragments containing the different SUC genes were 4.8 kb for SUC1, 5.2 kb for SUC2, 4.8 kb for SUC3, 12.8 kb for SUC4 and 17.2 kb for SUC5.Fragments containing the complete SUC genes and the sequences controlling their expression were subcloned into YEp24 and transformed into a strain without any active invertase gene. Invertase activity of transformants was measured after growth repressing (8% glucose) and derepressing (2% raffinose) conditions. As expected from results with strains carrying the individual SUC genes in a chromosomal location, the SUC genes were expressed to a different extent.Dedicated to Prof. Dr. Fritz Kaudewitz on the occasion of his 65th birthdayThis work was supported by Deutsche Forschungsgemeinschaft     

Control of the expression of the ADE2 gene of the yeast Saccharomyces cerevisiae

The ADE2 gene encodes AIR-carboxylase which catalyzes the sixth step of the purine biosynthetic pathway in Saccharomyces cerevisiae. We have analyzed the effect of deletions in the promoter region of this gene on the expression of the enzyme using a fusion of the ADE2 gene promoter to the bacterial lacZ gene. Adenine added to the growth medium repressed the expression of the fusion at the level of mRNA. The ADE2-lacZ fusion expression can be slightly activated in response to amino-acid starvation, but only in Gcn4 ⁺ strains and in an adenine-supplemented medium. In the absence of adenine in the medium ADE2 gene expression is derepressed, and neither starvation for histidine nor a gcd1 general control regulatory mutation leads to additional derepression. Our experiments indicate that the ADE2 gene of the purine biosynthetic pathway is under both specific adenine control and the general amino-acid control system. The cis-acting promoter elements mediating both modes of regulation overlap each other and are located around the proximal TGACTC sequence.     

Construction of new yeast vectors and cloning of the nif (nitrogen fixation) gene cluster of Klebsiella pneumoniae in yeast

Summary Two vectors, termed pG63.11 (7.6 Kb) and pHCG3 (9.6 Kb), suitable for yeast transformation have been constructed. The pHCG3 vector has cosmid properties. Both vectors contain a single 3.3 Kb EcoRI-HindIII fragment of yeast origin which carries the yeast URA3 gene (1.1 Kb) and the origin of replication of the 2 µm plasmid (2.2 Kb). They confer ampicillin resistance and they contain 5 unique EcoRI,HpaI,HindIII,BamHI and SalI restriction sites. Cosmid pHCG3 was used to clone the nitrogen fixation (nif) gene cluster of Klebsiella pneumoniae carried by twoHindIII fragments of 17 and 26 Kb, respectively. The resulting cosmid, termed pGPC875 (53 Kb) which conferred a Nif⁺ phenotype to Escherichia coli, was introduced in yeast by transformation. No acetylene reduction activity was detectable in the transformants. However it was shown that the entire information for nitrogen fixation can be replicated and maintained intact in yeast for more than 50 generations of growth.     

Structure and regulation of the isocitrate lyase gene ICL1 from the yeast Saccharomyces cerevisiae

The ICL1 gene encoding the isocitrate lyase from Saccharomyces cerevisiae was cloned and sequenced. A reading frame of 557 amino acids showing significant similarity to isocitrate lyases from seven other species could be identified. Construction of icl1 null mutants led to growth defects on C₂ carbon sources while utilization of sugars or C₃ substrates remained unaffected. Using an ICL1-lacZ fusion integrated at the ICL1 locus, a more than 200-fold induction of -galactosidase activity was observed after growth on ethanol when compared with glucose-repressed conditions. A preliminary analysis of the ICL1 upstream region identified a 364-bp fragment necessary and sufficient for this regulatory phenotype. Sequence motifs also present in the upstream regions of co-regulated genes were found within this region.     

Mutations to constitutivity and derepression are separate and separable in a regulatory gene of Aspergillus nidulans

Summary Previous work has shown that expression of the structural genes for the enzymes of nitrate and nitrite assimilation in Aspergillus nidulans requires the products of two positively acting regulatory genes — nirA, mediating induction, and areA, mediating nitrogen metabolite repression. Here we show that, in addition to previously described mutations in nirA leading to constitutivity, other mutations can be selected in nirA leading to nitrogen metabolite derepression. These constitutivity and depression mutations in nirA are additive and separable by intragenic recombination. This suggests that the nirA gene product contains two separate domains, a co-inducer binding region, defined by constitutivity mutations, and a region interacting with the areA gene product or with initiator sites adjacent to structural genes under areA and nirA control, defined by derepression mutations. These findings might indicate a striking similarity of action between the eukaryotic regulatory gene nirA and a comparable prokaryotic regulatory gene.     

Molecular cloning of a beta-glucosidase-encoding gene from Sclerotinia sclerotiorum by expression in Escherichia coli

Summary Six Sclerotinia sclerotiorum genes previously described as being expressed specifically during the induction of cell-wall-degrading enzymes have been transferred to Escherichia coli. When tested for expression of beta-glucosidase activity using X-glu (5-bromo-4-chloro-3-indolyl-beta-d-glucopyranoside), one of of the the genes expressed a X-glu-degrading activity. The corresponding RNA size is reported.     

The ogd1 and kgd1 mutants lacking 2-oxoglutarate dehydrogenase activity in yeast are allelic and can be differentiated by the cloned amber suppressor

The activity of mitochondrial 2-oxoglutarate dehydrogenase in S. cerevisiae can be impaired either by the ogd1 or the kgd1 mutation. The OGD1 gene and two suppressor genes were isolated by complementation of the ogd1 mutant. The complementation of the kdg1 mutant by the OGD1 gene, an allelism test, and meiotic mapping, revealed that the ogd1 and kgd1 mutations are allelic. The two mutations were differentiated by the cloned suppressor gene which was able to partially complement ogd1, but not kgd1. The molecular analysis of the suppressor gene revealed its identity with the natural tRNA _CAG ^Gln gene found in the upstream region of URA10.     

Resistance to cadmium is under the control of the CAD2 gene in the yeast Saccharomyces cerevisiae

Summary A cadmium-resistant strain, X3382-3A, which is able to grow in a medium containing 0.2 mM cadmium sulfate, was picked out from our laboratory stock strains of Saccharomyces cerevisiae. The cadmium resistance of this strain is controlled by a single dominant nuclear gene, denoted as CAD2. The locus of CAD2 was mapped by gene linkage to a site 15.5 centimorgans to the right of the his7 locus on the right arm of chromosome II. The cadmium resistance of the strain carrying CAD2 was evaluated for its properties of cadmium uptake, cadmium distribution and cadmium-metallothionein formation, in comparison with those of some other strains. The results suggest that the novel type of cadmium resistance controlled by CAD2 does not involve production of a cadmiumm-metallothionein.