Showing papers in "Yeast in 1992"

Effect of benzoic acid on metabolic fluxes in yeasts: A continuous‐culture study on the regulation of respiration and alcoholic fermentation

Abstract: Addition of benzoate to the medium reservoir of glucose-limited chemostat cultures of Saccharomyces cerevisiae CBS 8066 growing at a dilution rate (D) of 0.10 h-1 resulted in a decrease in the biomass yield, and an increase in the specific oxygen uptake rate (qO2) from 2.5 to as high as 19.5 mmol g-1 h-1. Above a critical concentration, the presence of benzoate led to alcoholic fermentation and a reduction in qO2 to 13 mmol g-1 h-1. The stimulatory effect of benzoate on respiration was dependent on the dilution rate: at high dilution rates respiration was not enhanced by benzoate. Cells could only gradually adapt to growth in the presence of benzoate: a pulse of benzoate given directly to the culture resulted in wash-out. As the presence of benzoate in cultures growing at low dilution rates resulted in large changes in the catabolic glucose flux, it was of interest to study the effect of benzoate on the residual glucose concentration in the fermenter as well as on the level of some selected enzymes. At D = 0.10 h-1, the residual glucose concentration increased proportionally with increasing benzoate concentration. This suggests that modulation of the glucose flux mainly occurs via a change in the extracellular glucose concentration rather than by synthesis of an additional amount of carriers. Also various intracellular enzyme levels were not positively correlated with the rate of respiration. A notable exception was citrate synthase: its level increased with increasing respiration rate. Growth of S. cerevisiae in ethanol-limited cultures in the presence of benzoate also led to very high qO2 levels of 19-21 mmol g-1 h-1. During growth on glucose as well as on ethanol, the presence of benzoate coincided with an increase in the mitochondrial volume up to one quarter of the total cellular volume. Also with the Crabtree-negative yeasts Candida utilis, Kluyveromyces marxianus and Hansenula polymorpha, growth in the presence of benzoate resulted in an increase in qO2 and, at high concentrations of benzoate, in aerobic fermentation. In contrast to S. cerevisiae, the highest qO2 of these yeasts when growing at D = 0.10 h-1 in the presence of benzoate was equal to, or lower than the qO2 attainable at mu(max) without benzoate. Enzyme activities that were repressed by glucose in S. cerevisiae also declined in K. marxianus when the glucose flux was increased by the presence of benzoate.(ABSTRACT TRUNCATED AT 400 WORDS)

Foreign gene expression in yeast: a review.

Abstract: 0749-503X/92/060423-66 $38.00

A rapid method for localized mutagenesis of yeast genes

Abstract: We have developed a simple procedure for the localized mutagenesis of yeast genes. In this technique the region of interest is first amplified under mutagenic polymerase chain reaction (PCR) conditions. Cotransformation of the PCR product with a gapped plasmid containing homology to both ends of the PCR product allows in vivo recombination to repair the gap with the mutagenized DNA. This procedure is efficient, allows targeting of specific regions for mutagenesis, and requires no subcloning steps in Escherichia coli.

Development of the yeast Pichia pastoris as a model organism for a genetic and molecular analysis of peroxisome assembly

Abstract: We describe the isolation of mutants of the yeast Pichia pastoris that are deficient in peroxisome assembly (pas). These mutants of P. pastoris can be identified solely by their inability to grow on methanol and oleic acid, the utilization of which requires peroxisomal enzymes, and are defined by the absence of normal peroxisomes as judged by electron microscopy and biochemical fractionation experiments. These mutants are the result of genetic defects at single loci and represent at least eight different complementation groups. The isolation of pas mutants of P. pastoris by a simple screen for mutants unable to use methanol and oleic acid represents a significantly more efficient method for identification of pas mutants than is possible in other organisms. To exploit this advantage fully we also developed new reagents for the genetic and molecular manipulation of P. pastoris. These include a set of auxotropic strains with an essentialiy wild type genetic background, plasmids that act as Escherichia coli–P. pastoris shuttle vectors, and genomic DNA libraries for isolation of P. pastoris genes by functional complementation of mutants or by nucleic acid hybridization. The availability of numerous pas mutants and the reagents necessary for their molecular analysis should lead to the isolation and characterization of genes involved in peroxisome assembly.

Genetic homology between Saccharomyces cerevisiae and its sibling species S. paradoxus and S. bayanus: electrophoretic karyotypes.

Abstract: Chromosomal DNAs of many monosporic strains of the biological species Saccharomyces cerevisiae, S. paradoxus and S. bayanus were analysed using contour-clamped homogeneous electric field electrophgoresis. SSouthern blot hybridization with eight cloned S. cerevisiae genes (ADC1, CUP1, GAL4, LEU2, rDNA, SUC2, TRP1 and URA3) assigned to different chromosomes was used to study homology and chromosomal location of the genes three sibiling species. A comparative study of Ty1, Ty2 and telomere-associated Y' sequences having multiple chromosomal location was also done. Chromosome length polymorphism was found in cultured strains of S. cerevisiae. Wild S. cerevisiae and S. paradoxus strains yielded chromosome banding patterns very similar to each other, The karyotype pattern of S. bayanus was readily distinguishable from that of S. cerevisiae and S. paradoxus. Southern blot analysis revealed a low degree of homology between the S. cerevisiae genes studied and the corresponding S. paradoxus and S. bayanus genes. The number of chromosomes appears to be 16 in all three species.

DIT101 (CSD2, CAL1), a cell cycle-regulated yeast gene required for synthesis of chitin in cell walls and chitosan in spore walls.

Abstract: A mutant screen has been designed to isolate mutants in Saccharomyces cerevisiae deficient in spore wall dityrosine. As shown by electron microscopy, most of the mutant spores lacked only the outermost, dityrosine-rich layer of the spore wall. Mutant dit101, however, was additionally lacking the chitosan layer of the spore wall. Chemical measurements showed that this mutant does not synthesize chitosan during sporulation. The mutant spores were viable but sensitive to lytic enzymes (glusulase or zymolyase). Unlike most of the dit-mutants, dit101 did show a distinctive phenotype in vegetative cells: they grew normally but contained very little chitin and were therefore resistant to the toxic chitin-binding dye, Calcofluor White. The cells showed barely detectable staining of the walls with Calcofluor White or primulin. The decrease in the amount of chitin in vegetative cells and the absence of chitosan in spores suggested that the mutant dit101 could be defective in a chitin synthase. Indeed, a genomic yeast clone harboring the gene, CSD2, sharing significant sequence similarity with yeast chitin synthases I and II (C. E. Bulawa (1992), Mol. Cell. Biol. 12, 1764-1776), complemented our mutant and was shown to correspond to the chromosomal locus of dit101. Thus, the mutations dit101 and csd2 (and probably also call; M. H. Valdivieso et al., (1991), J. Cell Biol. 114, 101-109) were shown to be allelic. The gene was mapped to chromosome II and was located about 3 kb distal of GAL1. Using this DNA clone, a transcript of about 3500-4000 nucleotides was detected. Comparing RNA isolated from vegetative cells and from sporulating cells at different times throughout the sporulation process, no significant differences in DIT101 transcript levels could be detected indicating absence of sporulation-specific transcriptional regulation. However, the amount of DIT101 transcript changed significantly at different stages of the mitotic cell cycle, peaking after septum formation, but before cytokinesis. As most of the chitin synthesis of vegetative cells occurs at this stage of the cell division cycle, chitin synthesis mediated by DIT101 could be primarily regulated at the level of transcription in vegetatively growing cells.

Molecular cloning of CIF1, a yeast gene necessary for growth on glucose

Abstract: The cif1 mutation of Saccharomyces cerevisiae (Navon et al., Biochemistry 18, 4487-4499, 1979) causes inability to grow on glucose and absence of catabolite inactivation. We have cloned the CIF1 gene by complementation of function and located it in a 2.75 kb SphI-BstEII fragment situated at ca. 18 kb centromere distal of LYS2 and ca. 80 kb centromere proximal of TYR1 on chromosome II. Southern analysis demonstrated that CIF1 is present in a single copy in the yeast genome. Northern analysis revealed that the corresponding mRNA of 1.8 kb is more abundant in cells grown on galactose than in those grown on glucose. A protein of ca. 54 kDa was predicted from the open reading frame in the sequenced fragment. In strains carrying the cif1 mutation the intracellular concentration of ATP decreased immediately after addition of glucose while the intracellular concentration of cAMP did not increase. cAMP concentration increased in response to galactose or 2,4-dinitrophenol. Disruption of BCY1 or overexpression of CDC25 in a cif1 background did not restore growth on glucose, suggesting that the absence of cAMP signal is not the primary cause of lack of growth on glucose. Complementation tests showed that cif1 is not allelic to fdp1 although the two genes seem to be functionally related.

Cloning and disruption of a gene required for growth on acetate but not on ethanol: the acetyl-coenzyme A synthetase gene of Saccharomyces cerevisiae.

Abstract: A DNA fragment of Saccharomyces cerevisiae with high homology to the acetyl-coenzyme A (acetyl-CoA) synthetase genes of Aspergillus nidulans and Neurospora crassa has been cloned, sequenced and mapped to chromosome I. It contains an open reading frame of 2139 nucleotides, encoding a predicted gene product of 79.2 kDa. In contrast to its ascomycete homologs, there are no introns in the coding sequence. The first ATG codon of the open reading frame is in an unusual context for a translational start site, while the next ATG, 24 codons downstream, is in a more conventional context. Possible implications of two alternative translational start sites for the cellular localization of the enzyme are discussed. A stable mutant of this gene, obtained by the gene disruption technique, had the same low basal activity of acetyl-CoA synthetase as wild-type cells when grown on glucose but completely lacked the strong increase in activity upon entering the stationary phase, providing direct proof that the gene encodes an inducible acetyl-CoA synthetase (ACS1) of yeast. As expected, the mutant was unable to grow on acetate as sole carbon source. Nevertheless, it showed normal induction of isocitrate lyase on acetate media, indicating that activity of acetyl-CoA synthetase is dispensable for induction of the glyoxylate cycle in S. cerevisiae. Surprisingly, disruption of the ACS1 gene did not affect growth on media containing ethanol as the sole carbon source, demonstrating that there are alternative pathways leading to acetyl-CoA under these conditions.

Control of peroxisome proliferation in Saccharomyces cerevisiae by ADR1, SNF1 (CAT1, CCR1) and SNF4 (CAT3).

Abstract: The Saccharomyces cerevisiae ADR1 gene has recently been demonstrated to control transcription of several genes encoding peroxisomal proteins or proteins necessary for peroxisome formation. Therefore, the effect of two other genes (SNF1 (CAT1, CCR1) and SNF4 (CAT3)) known to control derepression of glucose-repressible genes was studied. Levels of transcripts of genes encoding catalase A, fatty acid beta-oxidation enzymes and of the PAS1 gene are reduced in snf1 and snf4 mutants on ethanol as well as on oleic acid medium. By immunogold labelling with an antibody directed against peroxisomal thiolase, clusters of peroxisomes were detected in wild-type cells, whereas smaller single peroxisomes were observed in adr1 mutant cells. Results of immunofluorescence experiments are consistent with these observations. No peroxisomes were detected in snf1 and snf4 mutants by immunogold labelling as well as by immunofluorescence.

Yeast flocculation: reconciliation of physiological and genetic viewpoints.

Abstract: Yeast flocculation results from surface expression of specific proteins (lectins). Two flocculation phenotypes were suggested by physiological and biochemical tests, whereas genetic data suggested a larger number of mechanisms of flocculation. After reviewing the biochemistry, physiology and genetics of flocculation, a new hypothesis combining the data available from these different sources, is proposed. Flocculation results when lectins present on flocculent cell walls bind to sugar residues of neighbouring cell walls. These sugar receptors are intrinsic to the mannan comprising cell walls of Saccharomyces cerevisiae. Two lectin phenotypes were revealed by sugar inhibition studies. The gluco- and mannospecific NewFlo phenotype is not, as yet, found in genetically defined strains. Mannospecific flocculation (Flo1 phenotype) is found in strains containing the genes FLO1, FLO5 and FLO8. This phenotype is also found following mutation of the TUP1 or CYC8 loci, in previously non-flocculent strains. It is therefore proposed that the structural gene for mannospecific flocculation is common or possibly ubiquitous in non-flocculent strains and in consequence, FLO1, FLO5 and FLO8 are probably regulatory genes, exerting positive control over the structural gene. Flocculation expression requires lectin secretion to the cell surface. Many of the observed 'suppressions' of flocculation may be due to mutations of the secretory process, involved in transporting structural proteins to the cell wall. The possible involvement of killer L double-stranded RNA with flocculation is suggested, given the lectin properties of viral coat proteins and an association between L double-stranded RNA and the Flo1 phenotype.

Isolation of new temperature-sensitive mutants of Saccharomyces cerevisiae deficient in mannose outer chain elongation.

Abstract: We have isolated two temperature-sensitive Saccharomyces cerevisiae mutants which exhibit a deficiency in mannose outer chain elongation of asparagine-linked oligosaccharide. The size of yeast glycoprotein, secretory form of invertase, of one mutant (och1) was slightly larger than that of the sec18 mutant at the non-permissive temperature, while that of the other mutant (och2) was almost the same as that of the sec18 mutant. Unlike sec mutants, the och mutants were not deficient in secretion of invertase. The och1 mutant showed a 2+:2- cosegregation with regard to the temperature sensitivity and mannose outer chain deficiency, suggesting that a single gene designated as OCH1 is responsible for these two phenotypes. The och1 mutant stopped its growth at the early stage of bud formation and rapidly lost its viability at the non-permissive temperature. The och1 mutation was mapped near the ole1 on the left arm of chromosome VII. The och1 mutant cells accumulated the external invertase containing a large amount of core-like oligosaccharides (Man9-10GlcNAc2) and a small amount of high mannose oligosaccharides (greater than Man50GlcNAc2) at the non-permissive temperature. Production of the active form of human tissue-type plasminogen activator was increased in the och1 mutant compared with the parental strain, suggesting the potential advantage of this mutant for the production of mammalian-type glycoproteins which lack mannose outer chains in yeast.

Architectural features of pre-mRNA introns in the fission yeast Schizosaccharomyces pombe.

Abstract: The architectural features of 73 introns found in 36 genes of the fission yeast Schizosaccharomyces pombe have been compiled and tabulated. The introns from S. pombe can be grouped into two size classes. Intron features are discussed in comparison to intron features of Saccharomyces cerevisiae and other eukaryotes. The results indicate that S. pombe displays quite different architectural features than the budding yeast S. cerevisiae. However, particularly in the 3' region, S. pombe introns also appear to differ from mammalian introns.

Genetic and molecular analysis of DNA43 and DNA52: two new cell-cycle genes in Saccharomyces cerevisiae.

Abstract: Two Saccharomyces cerevisiae genes previously unknown to be required for DNA synthesis have been identified by screening a collection of temperature-sensitive mutants. The effects of mutations in DNA43 and DNA52 on the rate of S phase DNA synthesis were detected by monitoring DNA synthesis in synchronous populations that were obtained by isopycnic density centrifugation. dna43-1 and dna52-1 cells undergo cell-cycle arrest at the restrictive temperature (37 degrees C), exhibiting a large-budded terminal phenotype; the nuclei of arrested cells are located at the neck of the bud and have failed to undergo DNA replication. These phenotypes suggest that DNA43 and DNA52 are required for entry into or completion of S phase. DNA43 and DNA52 were cloned by their abilities to suppress the temperature-sensitive lethal phenotypes of dna43-1 and dna52-1 cells, respectively. DNA sequence analysis suggested that DNA43 and DNA52 encode proteins of 59.6 and 80.6 kDa, respectively. Both DNA43 and DNA52 are essential for viability and genetic mapping experiments indicate that they represent previously unidentified genes: DNA43 is located on chromosome IX, 32 cM distal from his5 and DNA52 is located on chromosome IV, 0.9 cM from cdc34.

Parameters affecting the frequencies of transformation and co-transformation with synthetic oligonucleotides in yeast.

Abstract: Factors influencing the direct transformation of the yeast Saccharomyces cerevisiae with synthetic oligonucleotides were investigated by selecting for cyc1 transformants that contained at least partially functional iso-1-cytochrome c. Approximately 3 x 10(4) transformants, constituting 0.1% of the cells, were obtained by using 1 mg of oligonucleotide in the reaction mixture. Carrier, such as heterogeneous oligonucleotides, enhanced transformation frequencies. Transformation frequencies were dramatically reduced if the oligonucleotides had a large number of mismatches or had terminally located mismatches. Transformation with oligonucleotides, but not with linearized double-strand plasmid, was efficient in a rad52- strain, suggesting that the pathway for transformation with oligonucleotides is different from that with linearized double-strand plasmid. We describe a procedure of co-transformation with two oligonucleotides, one correcting the cyc1 defect of the target allele in the host strain, and the other producing a desired amino acid alteration elsewhere in the iso-1-cytochrome c molecule; approximately 20% of the transformants obtained by co-transformation contained these desired second alterations.

Yeast flocculation: receptor definition by mnn mutants and concanavalin A.

Abstract: Yeast flocculation involves the binding of surface lectins on flocculent yeasts, to carbohydrate receptors present as constituents of yeast cell walls. Receptors were investigated by coflocculation of flocculent strains of Saccharomyces cerevisiae, of both Flo 1 and NewFlo phenotypes, to known mnn mutants which vary in the wall mannan structure. Strong coflocculation was found with mnn1, mnn4, mnn9 and control strains, while very little coflocculation was found with mnn2 and mnn5 strains. In contrast, aggregation of these mutants by concanavalin A, a lectin with similar sugar inhibition to NewFlo phenotype flocculation, showed strong aggregation of mnn1, mnn4 and mnn5 strains and poor aggregation of mnn2 and mnn9 strains. The mmn mutant data suggested that flocculation receptors were the outer-chain mannan side-branches, two or three mannose residues in length, confirming an earlier theory based on sugar inhibition data. The similarities and differences between flocculation and concanavalin A aggregation are discussed.

Rag−mutations involved in glucose metabolism in yeast: Isolation and genetic characterization

Abstract: Some natural isolates and many laboratory strains of the yeast Kluyveromyces lactis cannot grow on glucose when respiration is inhibited by antimycin A. The ability or inability to grow on glucose in the absence of mitochondrial respiration has been called Rag+ or Rag− phenotype (resistance to antimycin on glucose, respectively). Rag− strains, unable to grow on glucose in the presence of the respiratory drug, behave as if they were defective in fermentation. The Rag phenotype was first found to be determined by variant alleles of either of the two nuclear genes, RAG1 and RAG2, which code for a low-affinity glucose transport protein and for phosphoglucose isomerase, respectively. These findings suggested that the Rag− phenotype can be used to obtain mutations of genes involved in glucose metabolism in K. lactis. We thus looked for other Rag− mutants. Seventy-four mutants were isolated and genetically characterized. All of the mutations were nuclear recessive alleles, defining 11 new complementation groups, which we designate rag3 through rag13.

Identification of RAD16, a yeast excision repair gene homologous to the recombinational repair gene RAD54 and to the SNF2 gene involved in transcriptional activation.

Abstract: The RAD54 gene of Saccharomyces cerevisiae is involved in the recombinational repair of DNA damage. The predicted amino acid sequence of the RAD54 protein shows significant homologies with the yeast SNF2 protein, which is required for the transcriptional activation of a number of diversely regulated genes. These proteins are 31% identical in a 492-amino acid region that includes presumed nucleotide and Mg2+ binding sites. We noted previously that the SNF2 protein also shares homology with a partial open reading frame (ORF) that was reported with the sequence of an adjacent gene. This ORF also shares homology with the RAD54 protein. To test whether this ORF is involved in transcriptional activation or DNA repair, yeast strains deleted for part of it have been isolated. These strains do not show a Snf-like phenotype, but they are UV sensitive. This gene has been identified as RAD16, a gene involved in the excision repair of DNA damage. Analysis of the rad16 deletion mutations indicates that RAD16 encodes a non-essential function and is not absolutely required for excision repair. Outside the region of homology to RAD54 and SNF2, the predicted RAD16 protein contains a novel cysteine-rich motif that may bind zinc and that has been found recently in eleven other proteins, including the yeast RAD18 protein. The homologies between RAD16, RAD54 and SNF2 are also shared by several additional, recently isolated yeast and Drosophila genes.

Development of a strain of Hansenula polymorpha for the efficient expression of guar α-galactosidase

Abstract: A strain of the methylotrophic yeast Hansenula polymorpha, A16, has been developed that expresses the guar alpha-galactosidase gene to 22.4 mg/g dry cell weight in chemostat cultures at a dilution rate of 0.1 h(-1). This corresponds to more than 13.1% of soluble cell protein, of which 56-62% is secreted into the medium. The alpha-galactosidase gene was flanked by the promoter and terminator sequences of the H.polymorpha mox gene, which can direct expression of the mox gene itself more than 30% of total cell protein under methanol growth. The expression cassette (pUR3510) based on the Saccharomyces cerevisiae plasmid, YEp13, was integrated into the genome. Such transformants were stable in chemostat cultures and exhibited 100% stability for both alpha-galactosidase+ and leu+ phenotypes. Chemostat cultures produced higher levels of alpha-galactosidase with higher specific productivities expressed as mg alpha-galactosidase g(-1) h(-1) compared to batch cultures.

Transport of malic acid in the yeast Schizosaccharomyces pombe: evidence for a proton-dicarboxylate symport

Abstract: The transport system for malic acid present in Schizosaccharomyces pombe cells, growing in batch culture on several corbon sources, has been studied. It was found that the diarboxylic acid crrier of S. Pombe is a proton-dicarboxylate symporter that allows transport and accumulation as a function of ΔpH with the following kenetic parameters at pH 5·0: Vmax = 0·01 nmol of total malic acids −1 mg (dry weight) of cells, −1and Km = 0·1mM total malica acid uptake (pH 5·0) was accompanied by desappearance of extracellular protons, the uptake rates of which followed Michaelis-Menten kinetics as a function of the acid conscentration. The Km values, calculated as the concentrations either of anions or of undissociated acid, at various extracellular pH values, pointed to the monoanionic form as the transported species. Furthermore, accumulated free acid suffered rapid efflux after the addition of the portonophore carbonyl cyanid m-chlorophenyl hydrazone. These results suggested that the transport system was a dicarboxylateproton symporter. Growth of cells in a medium wiht glucose (up to 14%, w/v) and malic acid (1·5%, w/v) also resulted in proton-dicarboxylate activity, suggesting that the system, besides being constitutive, was still active at high glucose concentratons. The following dicarboxylic acids acted as competitive inhibitors of malic acid transport at pH 5·0: D- malic acid, succinic acid, fumaria acid oxaloacetic acid, α-Ketoglutaric acid, maleic acid, maleic and malonic acid. In addition all of these dicarboxylic acids induced proton movements that followed Michaelis–Menten kinetics. It was concluded that the malic negatively charged form (probably the monoanionic form) was transported by a proton-symport mechanism and that the carrier appeared to be a common ‘dicarboxylat transport sysmem’. The undissociated acid entered the cells slowly by simple diffusion.

The small heat-shock protein Hsp26 of Saccharomyces cerevisiae assembles into a high molecular weight aggregate.

Abstract: Hsp26 is one of the major small heat-shock proteins (Hsp) of the yeast Saccharomyces cerevisiae, yet its cellular role remains to be discovered To examine the cellular consequences of overexpression of Hsp26, the gene encoding this protein (HSP26) was overexpressed from a multicopy plasmid using either its own promoter or by coupling it to the efficient constitutive PGK promoter The PGK promoter provided the opportunity to overexpress Hsp26 under non-stress conditions and such high level synthesis, prior to a lethal heat shock (50 degrees C), gave a small but reproducible elevation in thermotolerance In transformed strains overexpressing Hsp26 under either stressed or non-stress conditions, the Hsp26 polypeptide was recovered almost exclusively as a high molecular weight aggregate This high molecular weight aggregate (or heat-shock granule; HSG) was purified by differential centrifugation and sucrose gradient density centrifugation and shown, by electron microscopic analysis, to be of a uniform size (15-25 nm diameter) Analysis of the purified HSG demonstrated that it had a molecular weight of 550 kDa, yet contained no other integral polypeptides or other macromolecules

RHO gene products, putative small GTP-binding proteins, are important for activation of the CAL1/CDC43 gene product, a protein geranylgeranyltransferase in Saccharomyces cerevisiae.

Abstract: Two multicopy suppressors of the cal1-1 mutation in the yeast Saccharomyces cerevisiae have been isolated and characterized. They are identical to the yeast RHO1 and RHO2 genes, which encode putative small GTP-binding proteins. Multiple copies of either RHO gene suppressed temperature-sensitive growth of the cal1-1 mutant but did not suppress the cal1 null mutant. Genetic analysis suggests that overproduction of either RHO gene product acts for activation of the CAL1 gene product.

Dosage-dependent translational suppression in yeast Saccharomyces cerevisiae

Abstract: The overexpression of SUP35 (SUP2) wild-type gene, caused by increase of its copy number, induces an omnipotent suppression similar to the phenotype of mutants for this gene. The effectt of extra-SUP35 was detected for moderate or even low copy number. Moreover, overdosage of the fragment including only the 5′-flanking region and N-terminal 100 bp of protein-coding sequence of SUP35 leads to allosuppression. Multi-SUP35 gene was also icompatible with extrachromosomal suppressor factor ψ, presumbaly because of high level of mistranslation. The suppressor effect caused by overdosage of another gene, SUP45 (SUP1), is much lower and can be detected only for one construction which is derived from high copy number plasmid. Suppression induced by extra-SUP35 and especially by extra-SUP45 is affected by the cell environment. A model predicting that the balance of gene products is a key for regulation of translational fidelity is discussed.

Flow cytometric analysis of Saccharomyces cerevisiae autolytic mutants and protoplasts.

Abstract: Simple methods, based on the technique of flow cytometry, have been developed for the phenotypic characterization of yeast autolytic mutants and for the analysis of the formation and regeneration of the yeast protoplasts. The expression of lytic mutations determined uptake of the fluorescent dye propidium iodide, which could be carefully monitored by flow cytometry. Mixed populations of lysed and viable cells were precisely quantified and sorted, and the technique was also applied to demonstrate protection from lysis of mutant cells with cell wall defects, in the presence of osmotic stabilizers. Protoplast formation and regeneration was monitored by analysing relative cell size; this was facilitated by the preparation of homogeneous protoplast preparations. The technique of flow cytometry proved superior to other conventional methods for these types of study.

The telomere-associated MAL3 locus of Saccharomyces is a tandem array of repeated genes.

Abstract: Saccharomyces strains capable of fermenting maltose contain any one of five telomere-associated MAL loci. Each MAL locus is a complex of three genes encoding the three functions required to ferment maltose: maltose permease (GENE 1), maltase (GENE 2) and the MAL trans-activator (GENE 3). All five loci have been cloned and all are highly sequence homologous over at least a 9.0 kbp region containing these GENEs (Charron et al., Genetics 122, 307-331, 1989). Our initial studies of strains carrying the MAL3 locus indicated the presence of linked, repeated MAL-homologous sequences (Michels and Needleman, Mol. Gen. Genet. 191, 225-230, 1983). Here we report our analysis of the centromere-proximal MAL3-linked sequences and show that the complete MAL3 locus spans approximately 40 kbp and consists of tandemly arrayed, partial repeats of the three GENE sequences described above. In addition, the structure of the MAL3 locus is compared to that of three partially functional alleles of MAL3. These alleles were shown to contain only MAL31 and MAL32 and their structure suggests that they resulted from MAL3 deletions removing the sequences centromere-proximal to MAL31. The amplification and rearrangement of the telomere-linked MAL3 sequences are discussed in the context of studies on other telemere-associated sequences from yeast and other species.

Sequence of a 10.7 kb segment of yeast chromosome XI identifies the APN1 and the BAF1 loci and reveals one tRNA gene and several new open reading frames including homologs to RAD2 and kinases.

Abstract: We report here the DNA sequence of a segment of chromosome XI of Saccharomyces cerevisiae extending over 10.7 kb. The sequence was determined using a double-strand sequencing strategy adapted from the random-clone strategy. The segment contains seven non-overlapping long open reading frames, YKL500, 505, 510, 513, 516, 518 and 520 and one tRNA gene. YKL505 and YKL513 are two already sequenced genes, the BAF1/ABF1 and the APN1 genes, respectively. YKL510 exhibits a strong homology to the RAD2 protein and YKL516 is presumably a protein kinase.

Isolation and sequence analysis of the gene encoding translation elongation factor 3 from Candida albicans.

Abstract: The structural gene encoding translation elongation factor 3 (EF-3) has been cloned from a Candida albicans genomic library by hybridization to a Saccharomyces cerevisiae probe containing the Saccharomyces gene, YEF3 (Sandbaken et al., 1990b). The sequences were shown to be functionally homologous to the Saccharomyces gene by three criteria: (1) a Saccharomyces strain transformed with a high copy plasmid containing CaEF3 sequences overproduces the EF-3 peptide two-fold; (2) extracts from this strain exhibit a two-fold increase in the EF-3-catalysed, ribosome-dependent ATPase activity (Kamath and Chakraburtty, 1988); and (3) the Candida gene complements a Saccharomyces null mutant. The coding region, identified by DNA sequencing, indicates that CaEF3 encodes a 1050 amino acid polypeptide having a potential molecular weight of 116,865 Da. This protein shows 77% overall identity to the Saccharomyces YEF3 gene, with a significantly greater identity (94%) concentrated in the region of the protein thought to contain the catalytic domain of EF-3 (Sandbaken et al., 1990a). The upstream non-coding region contains T-rich regions typical of many yeast genes and several potential RAP1/GRF1 elements shown to regulate expression of a number of translational genes (Mager, 1988). The data confirm a high degree of conservation for EF-3 among the two organisms.

Characterization of mutants of the yeast Yarrowia lipolytica defective in acetyl-coenzyme A synthetase.

Abstract: The expression of the glyoxylate cycle enzymes is required for growth of the yeast Yarrowia lipolytica on acetate or fatty acids as sole carbon source. Acetyl-coenzyme A, which is produced by acetyl-coenzyme A synthetase (ACS) from acetate, is needed for induction of this expression. Acetate-non-utilizing mutants of this yeast were investigated in order to identify mutants which express no or strongly reduced activity of this enzyme. Mutations in gene ICL2 exhibited the strongest effects on the activity. In icl2 mutants, lack of ACS activity resulted in a non-induced glyoxylate cycle on acetate; however, induction on fatty acids was not affected. Gene ICL2 was identified as the structural gene encoding the monomer of ACS. It is shown that a high level of ACS activity is necessary for full expression of the glyoxylate cycle enzymes. Mutations in gene ICL1, which encodes isocitrate lyase, resulted in overproduction of ACS without any growth on acetate. A new gene (GPR1 = glyoxylate pathway regulation) was detected in which trans-dominant mutations inhibit expression of ACS and the glyoxylate cycle on acetate as carbon source.

The allantoin and uracil permease gene sequences of Saccharomyces cerevisiae are nearly identical

Abstract: We have determined the structure of the allantoin permease (DAL4) gene of Saccharomyces cerevisiae. The gene patatively encodes a hydrophobic protein with a Mr of 71 755. It possesses the alternating hydrophobic–hydrophilic regions similar to those found in many other integral membrane proteins. The most striking feature of the allantoin permease component encoded by DAL4 is its striking similarity to the uracil permease component encoded by FUR4 Although data available indicate that these proteins do not share any overlap of function, their predicted protein sequences are 68% identical, 81% similar, and their DNA sequences are 70% identical. The upstream regulatory region of DAL4 contains all lof the characterized cis-acting elements previously reported for inducible allantoin pathway genes: six sequences homologous to UASNTR, the element responsible for nitrogen catabolite repression-sensitive activation of allantoin pathway gene expression, and two sequences homologous to the cis-acting element responsible for inducere-responsiveness of the allantoin pathway genes, UIS. The finding of these homologous sequences predicted to exist on the basis of DAL4's expression characteristics, supports and strengthens the suggestion that these elements mediate the functions we have we have previously ascribed to them.