A new disruption vector (pDHO) to obtain heterothallic strains from both Saccharomyces cerevisiae and Saccharomyces pastorianus

Yeasts are responsible for several traits in fermented beverages, including wine and beer, and their genetic manipulation is often necessary to improve the quality of the fermentation product. Improvement of wild-type strains of Saccharomyces cerevisiae and Saccharomyces pastorianus is difficult due to their homothallic character and variable ploidy level. Homothallism is determined by the HO gene in S. cerevisiae and the Sc-HO gene in S. pastorianus. In this work, we describe the construction of an HO disruption vector (pDHO) containing an HO disruption cassette and discuss its use in generating heterothallic yeast strains from homothallic Saccharomyces species.     

Saccharomyces cerevisiae protein phosphatase 2A performs an essential cellular function and is encoded by two genes.

Two genes (PPH21 and PPH22) encoding the yeast homologues of protein serine-threonine phosphatase 2A have been cloned from a Saccharomyces cerevisiae genomic library using a rabbit protein phosphatase 2A cDNA as a hybridization probe. The PPH genes are genetically linked on chromosome IV and are predicted to encode polypeptides each with 74% amino acid sequence identity to rabbit type 2A protein phosphatase, indicating once again the extraordinarily high degree of sequence conservation shown by protein-phosphatases from different species. The two PPH genes show less than 10% amino acid sequence divergence from each other and while disruption of either PPH gene alone is without any major effect, the double disruption is lethal. This indicates that protein phosphatase 2A activity is an essential cellular function in yeast. Measurement of type 2A protein phosphatase activity in yeast strains lacking one or other of the genes indicates that they account for most, if not all, protein phosphatase 2A activity in the cell.     

Comparative molecular-genetic analysis of the beta-fructosidases in yeast Saccharomyces

To infer the molecular evolution of polymeric beta-fructosidase SUC genes of the yeast Saccharomyces, we have cloned and sequenced a new SUC gene from S. cariocanus and determined the sequence similarity of beta-fructosidases within the genus Saccharomyces. The proteins of Saccharomyces cerevisiae and its five sibling species (S. bayanus, S. cariocanus, S. kudriavzevii, S. mikatae, S. paradoxus) have high degree of identity - 90-97%. The invertase of S. bayanus is the most divergent among the proteins studied. The data obtained indicated that the yeast invertases are highly conservative. In the coding regions of the SUC genes the pyrimidine transitions were the most abundant event due to silent changes mainly in the third codon position. There is only one, probably, non-telomeric SUC gene in each of the Saccharomyces species. In S. cerevisiae, S. bayanus, S. kudriavzevii, S. mikatae and S. paradoxus the SUC gene have been mapped on chromosome IX, whereas in S. cariocanus this gene is located in chromosone XV, in the position of translocation.     

pSH-CUP重组质粒的构建及面包酵母酸性海藻糖 酶基因的敲除

设计含有与面包酵母(Saccharomyces cerevisiae BY-6)编码酸性海藻糖酶ATH基因内部部分序列同源的长引物,以质粒pUG6为模板进行PCR构建带有Cre/loxP系统的敲除单元,转化面包酵母获得G418阳性克隆.将铜抗性基因(cuP1-MT1)导入Cre重组酶表达质粒pSH47,得到重组质粒pSH-CUZ,并转化阳性克隆,以铜抗性筛选面包酵母转化子.半乳糖诱导表达Cre酶切除Kanr基因.重组质粒pSH-CUP的构建,不仅解决了酵母转化子筛选标记问题和非酵母基因的引入,而且使LoxP-kanMX-loxP基因敲除体系在进行真核生物基因敲除时更加方便可行.     

Improved method for the PCR-based gene disruption in Saccharomyces cerevisiae

The PCR-based gene disruption strategy originally devised by Baudin et al. is widely used for gene targeting in Saccharomyces cerevisiae. An advantage of this strategy is its simplicity in making targeting constructs. The efficiencies of the targeted disruption are highly variable from locus to locus, however, and often very low. In this report, a method for improving the gene deletion efficiency is described.     

Cloning and characterization of the MAL11 gene encoding a high-affinity maltose transporter from Torulaspora delbrueckii

The transport and regulation of maltose utilization by Torulaspora delbrueckii, one of the most abundant non-Saccharomyces species present in home-made corn and rye bread dough, has been investigated. A DNA fragment containing the MAL11 gene from T. delbrueckii (TdMAL11) was isolated by complementation cloning in Saccharomyces cerevisiae. DNA sequence analysis revealed the presence of an open reading frame (ORF) of 1884 bp, encoding a 627-amino acid membrane protein, which displays high homology to other yeast maltose transporters. Upstream of TdMAL11, the DNA insert contained a partial ORF (TdMAL12) on the opposite strand, which showed high similarity to the S. cerevisiae MAL12 gene. Sequence analysis, Northern blot and transport measurements indicated that TdMAL11 expression is regulated by the carbon source. Attempts to disrupt TdMAL11 revealed the presence of two functional MAL loci. Disruption of a single copy decreased the V(max) of maltose transport, but not the K(m), whereas the double disruption abolished the uptake of this sugar in T. delbrueckii.     

Generation of disruption cassettes in vivo using a PCR product and Saccharomyces cerevisiae

A method to obtain disruption cassettes based on the homologous recombination in Saccharomyces cerevisiae is described. The disruption marker is amplified by PCR using oligonucleotides containing 50 bp homologous to the disruptable gene and 20 bp from the marker. The PCR product is cotransformed into yeast with a plasmid containing the gene. After recombination, a plasmid that carries the disruption cassette for the gene is produced.     

Trehalose-6-P synthase is dispensable for growth on glucose but not for spore germination in Schizosaccharomyces pombe.

Trehalose-6-P inhibits hexokinases in Saccharomyces cerevisiae (M. A. Blázquez, R. Lagunas, C. Gancedo, and J. M. Gancedo, FEBS Lett. 329:51-54, 1993), and disruption of the TPS1 gene (formerly named CIF1 or FDP1) encoding trehalose-6-P synthase prevents growth in glucose. We have found that the hexokinase from Schizosaccharomyces pombe is not inhibited by trehalose-6-P even at a concentration of 3 mM. The highest internal concentration of trehalose-6-P that we measured in S. pombe was 0.75 mM after heat shock. We have isolated from S. pombe the tps1+ gene, which is homologous to the Saccharomyces cerevisiae TPS1 gene. The DNA sequence from tps1+ predicts a protein of 479 amino acids with 65% identity with the protein of S. cerevisiae. The tps1+ gene expressed from its own promoter could complement the lack of trehalose-6-P synthase in S. cerevisiae tps1 mutants. The TPS1 gene from S. cerevisiae could also restore trehalose synthesis in S. pombe tps1 mutants. A chromosomal disruption of the tps1+ gene in S. pombe did not have a noticeable effect on growth in glucose, in contrast with the disruption of TPS1 in S. cerevisiae. However, the disruption prevented germination of spores carrying it. The level of an RNA hybridizing with an internal probe of the tps1+ gene reached a maximum after 20 min of heat shock treatment. The results presented support the idea that trehalose-6-P plays a role in the control of glycolysis in S. cerevisiae but not in S. pombe and show that the trehalose pathway has different roles in the two yeast species.     

Evidence for divergent evolution of growth temperature preference in sympatric Saccharomyces species

The genus Saccharomyces currently includes eight species in addition to the model yeast Saccharomyces cerevisiae, most of which can be consistently isolated from tree bark and soil. We recently found sympatric pairs of Saccharomyces species, composed of one cryotolerant and one thermotolerant species in oak bark samples of various geographic origins. In order to contribute to explain the occurrence in sympatry of Saccharomyces species, we screened Saccharomyces genomic data for protein divergence that might be correlated to distinct growth temperature preferences of the species, using the dN/dS ratio as a measure of protein evolution rates and pair-wise species comparisons. In addition to proteins previously implicated in growth at suboptimal temperatures, we found that glycolytic enzymes were among the proteins exhibiting higher than expected divergence when one cryotolerant and one thermotolerant species are compared. By measuring glycolytic fluxes and glycolytic enzymatic activities in different species and at different temperatures, we subsequently show that the unusual divergence of glycolytic genes may be related to divergent evolution of the glycolytic pathway aligning its performance to the growth temperature profiles of the different species. In general, our results support the view that growth temperature preference is a trait that may have undergone divergent selection in the course of ecological speciation in Saccharomyces.     

Disruption of individual members of Arabidopsis syntaxin gene families indicates each has essential functions

Syntaxins are a large group of proteins found in all eukaryotes involved in the fusion of transport vesicles to target membranes. Twenty-four syntaxins grouped into 10 gene families are found in the model plant Arabidopsis thaliana, each group containing one to five paralogous members. The Arabidopsis SYP2 and SYP4 gene families contain three members each that share 60 to 80% protein sequence identity. Gene disruptions of the yeast (Saccharomyces cerevisiae) orthologs of the SYP2 and SYP4 gene families (Pep12p and Tlg2p, respectively) indicate that these syntaxins are not essential for growth in yeast. However, we have isolated and characterized gene disruptions in two genes from each family, finding that disruption of individual syntaxins from these families is lethal in the male gametophyte of Arabidopsis. Complementation of the syp21-1 gene disruption with its cognate transgene indicated that the lethality is linked to the loss of the single syntaxin gene. Thus, it is clear that each syntaxin in the SYP2 and SYP4 families serves an essential nonredundant function.     

酵母基因中断技术

酵母基因中断技术是研究酵母基因功能的重要手段，自80年代初诞生以来经历了不断的改进和发展.PCR介导的酵母基因中断技术，大大简化了操作，实现了酵母基因的精确缺失；酵母基因的多重中断技术，可在酵母内实现多个基因的中断；可进行大规模基因中断和功能分析的酵母基因中断技术，适应了在酵母全基因组测序完成的情况下进行功能基因组学研究的要求.酵母基因中断技术对人类基因功能研究也有很大启示作用.     

Transformation in fungi.

Transformation with exogenous deoxyribonucleic acid (DNA) now appears to be possible with all fungal species, or at least all that can be grown in culture. This field of research is at present dominated by Saccharomyces cerevisiae and two filamentous members of the class Ascomycetes, Aspergillus nidulans and Neurospora crassa, with substantial contributions also from fission yeast (Schizosaccharomyces pombe) and another filamentous member of the class Ascomycetes, Podospora anserina. However, transformation has been demonstrated, and will no doubt be extensively used, in representatives of most of the main fungal classes, including Phycomycetes, Basidiomycetes (the order Agaricales and Ustilago species), and a number of the Fungi Imperfecti. The list includes a number of plant pathogens, and transformation is likely to become important in the analysis of the molecular basis of pathogenicity. Transformation may be maintained either by using an autonomously replicating plasmid as a vehicle for the transforming DNA or through integration of the DNA into the chromosomes. In S. cerevisiae and other yeasts, a variety of autonomously replicating plasmids have been used successfully, some of them designed for use as shuttle vectors for Escherichia coli as well as for yeast transformation. Suitable plasmids are not yet available for use in filamentous fungi, in which stable transformation is dependent on chromosomal integration. In Saccharomyces cerevisiae, integration of transforming DNA is virtually always by homology; in filamentous fungi, in contrast, it occurs just as frequently at nonhomologous (ectopic) chromosomal sites. The main importance of transformation in fungi at present is in connection with gene cloning and the analysis of gene function. The most advanced work is being done with S. cerevisiae, in which the virtual restriction of stable DNA integration to homologous chromosome loci enables gene disruption and gene replacement to be carried out with greater precision and efficiency than is possible in other species that show a high proportion of DNA integration events at nonhomologous (ectopic) sites. With a little more trouble, however, the methodology pioneered for S. cerevisiae can be applied to other fungi too. Transformation of fungi with DNA constructs designed for high gene expression and efficient secretion of gene products appears to have great commercial potential.     

SAM1, the structural gene for one of the S-adenosylmethionine synthetases in Saccharomyces cerevisiae. Sequence and expression

Saccharomyces cerevisiae contains two genes, SAM1 and SAM2, encoding functional S-adenosylmethionine synthetases. The gene SAM1 was isolated by functional complementation of a double mutant of S. cerevisiae, and its identity was confirmed by gene disruption. The cloned gene was used to probe wild type chromosomal DNA, and two regions hybridizing with SAM1 were found, one of which is the SAM1 region. The DNA sequence of SAM1 is reported. The translation product shows a high homology with the one deduced from the sequence of the MetK gene encoding the SAM synthetase of Escherichia coli.     

Transformation in fungi.

Transformation with exogenous deoxyribonucleic acid (DNA) now appears to be possible with all fungal species, or at least all that can be grown in culture. This field of research is at present dominated by Saccharomyces cerevisiae and two filamentous members of the class Ascomycetes, Aspergillus nidulans and Neurospora crassa, with substantial contributions also from fission yeast (Schizosaccharomyces pombe) and another filamentous member of the class Ascomycetes, Podospora anserina. However, transformation has been demonstrated, and will no doubt be extensively used, in representatives of most of the main fungal classes, including Phycomycetes, Basidiomycetes (the order Agaricales and Ustilago species), and a number of the Fungi Imperfecti. The list includes a number of plant pathogens, and transformation is likely to become important in the analysis of the molecular basis of pathogenicity. Transformation may be maintained either by using an autonomously replicating plasmid as a vehicle for the transforming DNA or through integration of the DNA into the chromosomes. In S. cerevisiae and other yeasts, a variety of autonomously replicating plasmids have been used successfully, some of them designed for use as shuttle vectors for Escherichia coli as well as for yeast transformation. Suitable plasmids are not yet available for use in filamentous fungi, in which stable transformation is dependent on chromosomal integration. In Saccharomyces cerevisiae, integration of transforming DNA is virtually always by homology; in filamentous fungi, in contrast, it occurs just as frequently at nonhomologous (ectopic) chromosomal sites. The main importance of transformation in fungi at present is in connection with gene cloning and the analysis of gene function. The most advanced work is being done with S. cerevisiae, in which the virtual restriction of stable DNA integration to homologous chromosome loci enables gene disruption and gene replacement to be carried out with greater precision and efficiency than is possible in other species that show a high proportion of DNA integration events at nonhomologous (ectopic) sites. With a little more trouble, however, the methodology pioneered for S. cerevisiae can be applied to other fungi too. Transformation of fungi with DNA constructs designed for high gene expression and efficient secretion of gene products appears to have great commercial potential.     

PCR differentiation of Saccharomyces cerevisiae from Saccharomyces bayanus/Saccharomyces pastorianus using specific primers

The aim of the present study was to design species-specific primers capable of distinguishing between Saccharomyces cerevisiae, Saccharomyces bayanus/Saccharomyces pastorianus. The 5'-specific primers were designed from the ITS-1 region (between positions 150 and 182 from the 3'-SSU end) and the 3'-specific primers were located in the LSU gene (positions 560-590 from the 5'-end of this gene). These primers were tested with different collections and wild strains of these species and the results showed that the primers were capable of distinguishing between S. cerevisiae strains and S. bayanus/S. pastorianus. Not enough sequence differences were found between S. bayanus and S. pastorianus to design specific primers for these species using this region. This method offers an effective tool for a quick differentiation of the Saccharomyces strains of the most common species involved in industrial processes.     

Conservation of the MC domains in eukaryotic termination factor eRF3

Eukaryotic translation termination employs two protein factors, eRF1 and eRF3. Proteins of the eRF3 family each consist of three domains. The N and M domains vary in different species, while the C domains are highly homologous. The MC domains of Homo sapiens eRF3a (hGSPT I), Xenopus laevis eRF3 (XSup35), and Mus musculus eRF3a (mGSPTI) and eRF3b (mGSPT2) were found to compensate for the sup35-21(ts) temperature-sensitive mutation and lethal disruption of the SUP35 gene in yeast Saccharomyces cerevisiae. At the same time, strains containing the MC domains of the eRF3 proteins from different species differed in growth rate and the efficiency of translation termination.     

The Drosophila gene 2A5 complements the defect in mitochondrial F1-ATPase assembly in yeast lacking the molecular chaperone Atp11p.

Assembly of mitochondrial F1-ATPase in Saccharomyces cerevisiae requires the molecular chaperone, Atp11p. Database searches have identified protein sequences from Schizosaccharomyces pombe and two species of Drosophila that are homologous to S. cerevisiae Atp11p. A cDNA encoding the putative Atp11p from Drosophila yakuba was shown to complement the respiratory deficient phenotype of yeast harboring an atp11::HIS3 disruption allele. Furthermore, the product of this Drosophila gene was shown to interact with the S. cerevisiae F1 beta subunit in the yeast two-hybrid assay. These results indicate that Atp11p function is conserved in higher eukaryotes.     

PCR-based gene disruption and recombinatory marker excision to produce modified industrial Saccharomyces cerevisiae without added sequences

The dominant selectable Kanr marker, which confers geneticin resistance in yeast, is extensively used for PCR based disruption of genes in functional analysis studies in laboratory strains of Saccharomyces cerevisiae. We have developed a gene disruption cassette, which incorporates the Kanr marker, and direct repeat sequences designed from the target gene to enable the deletion of the gene without the introduction of added DNA sequences. We report on the disruption of the HO gene as a test case, using the hodr-Kanr-hodr cassette. The cassette was shown to integrate at the HO locus and the Kanr marker excised by recombination between the two direct repeat sequences. The disruption/excision event resulted in the removal of one direct repeat and the coding sequence of the gene, and hence in this case loss of HO function, with the introduction of no foreign or additional sequences, including the Kanr marker. Having been derived from the target site, the remaining direct repeat sequence is native sequence in its native location. This design template has the potential to be adapted to other genes, and as such will be of advantage in instances such as the optimization of strains by recombinant DNA technology where the retention of minimal or no foreign sequences is desired.     

Soluble fumarate reductase isoenzymes from Saccharomyces cerevisiae are required for anaerobic growth

In Saccharomyces cerevisiae, the cytosolic and promitochondrial isoenzymes of fumarate reductase are encoded by the FRDS and OSM1 genes, respectively. The product of the OSM1 gene is reported to be required for growth in hypertonic medium. Simultaneous disruption of the FRDS and OSM1 genes resulted in the inability of the yeasts to grow anaerobically on glucose as a carbon source, and disruption of the OSM1 gene caused poor growth under anaerobic conditions. However, the disruption of both the FRDS and/or OSM1 genes had no effect on aerobic growth or growth under hypertonic conditions. These results suggest that the fumarate reductase isoenzymes in Saccharomyces cerevisiae are essential for anaerobic growth but not for growth under hypertonic conditions.