CLG1, a new cyclin-like gene of Saccharomyces cerevisiae

A region of chromosome VII adjacent to SKI8 has a 453 amino acid open reading frame whose sequence has significant similarity to that of HCS26, a G1 cyclin. A disruption mutation of this open reading frame has no apparent phenotype under the conditions tested. ORFD, an open reading frame adjacent to the CDC48 gene, is even more similar to HCS26.     

Sequence of the sup61-RAD18 region on chromosome III of Saccharomyces cerevisiae.

A 7965 bp DNA segment from the right arm of chromosome III of Saccharomyces cerevisiae, encompassing the sup61 and RAD18 genes, was sequenced. Four new open reading frames were found in this DNA fragment. One of them, YCR103, is 51% homologous with the G10 gene product of Xenopus laevis.     

A set of genetically diverged Saccharomyces cerevisiae strains with markerless deletions of multiple auxotrophic genes

Genome analysis of over 70 Saccharomyces strains revealed the existence of five groups of genetically diverged S. cerevisiae wild‐type isolates, which feature distinct genetic backgrounds and reflect the natural diversity existing among the species. The strains originated from different geographical and ecological niches (Malaysian, West African, North American, Wine/European and Sake) and represent clean, non‐mosaic lineages of S. cerevisiae, meaning that their genomes differ essentially by monomorphic and private SNPs. In this study, one representative strain for each of the five S. cerevisiae clean lineages was selected and mutated for several auxotroph genes by clean markerless deletions, so that all dominant markers remained available for further genetic manipulations. A set of 50 strains was assembled, including eight haploid and two diploid strains for each lineage. These strains carry different combinations of leu2?0, lys2?0, met15?0, ura3?0 and/or ura3?::KanMX‐barcoded deletions with marker configurations resembling that of the BY series, which will allow large‐scale crossing with existing deletion collections. This new set of genetically tractable strains provides a powerful tool kit to explore the impact of natural variation on complex biological processes. Copyright © 2013 John Wiley & Sons, Ltd.     

Disruption of seven hypothetical aryl alcohol dehydrogenase genes from Saccharomyces cerevisiae and construction of a multiple knock-out strain

By in silicio analysis, we have discovered that there are seven open reading frames (ORFs) in Saccharomyces cerevisiae whose protein products show a high degree of amino acid sequence similarity to the aryl alcohol dehydrogenase (AAD) of the lignin-degrading fungus Phanerochaete chrysosporium. Yeast cultures grown to stationary phase display a significant aryl alcohol dehydrogenase activity by degrading aromatic aldehydes to the corresponding alcohols. To study the biochemical and the biological role of each of the AAD genes, a series of mutant strains carrying deletion of one or more of the AAD-coding sequences was constructed by PCR-mediated gene replacement, using the readily selectable marker kanMX. The correct targeting of the PCR-generated disruption cassette into the genomic locus was verified by analytical PCR and by pulse-field gel electrophoresis (PFGE) followed by Southern blot analysis. Double, triple and quadruple mutant strains were obtained by classical genetic methods, while the construction of the quintuple, sextuple and septuple mutants was achieved by using the marker URA3 from Kluyveromyces lactis, HIS3 from Schizosaccharomyces pombe and TRP1 from S. cerevisiae. None of the knock-out strains revealed any mutant phenotype when tested for the degradation of aromatic aldehydes using both spectrophotometry and high performance liquid chromatography (HPLC). Specific tests for changes in the ergosterol and phospholipids profiles did not reveal any mutant phenotype and mating and sporulation efficiencies were not affected in the septuple deletant. Compared to the wild-type strain, the septuple deletant showed an increased resistance to the anisaldehyde, but there is a possibility that the nutritional markers used for gene replacement are causing this effect.     

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

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.     

Cloning,Sequencing and Expression of a Full-Length cDNA Copy of the M1 Double-Stranded RNA Virus from the Yeast,Saccharomyces cerevisiae

Strains of the budding yeast, Saccharomyces cerevisiae, may contain one or more cytoplasmic viruses with double-stranded RNA (dsRNA) genomes. The killer phenomenon in yeast, in which one cell secretes a killer toxin that is lethal to another cell, is dependent upon the presence of the L-A and M1 dsRNA viruses. The L-A viral genome encodes proteins for the viral capsid, and for synthesis and encapsidation of single-stranded RNA replication cycle intermediates. The M1 virus depends upon the L-A-encoded proteins for its capsid and for the replication of its killer-toxin-encoding genome. A full-length cDNA clone of an M1 genome has been made from a single dsRNA molecule and shown to encode functional killer and killer-immunity functions. The sequence of the clone indicates minor differences from previously published sequences of parts of the M1 genome and of the complete genome of S14 (an internal deletion derivative of M1) but no unreported amino acid variants and no changes in putative secondary structures of the single-stranded RNA. A 118-nucleotide contiguous segment of the M1 genome has not previously been reported; 92 of those nucleotides comprise a segment of A nucleotides in the AU-rich bubble that follows the toxin-encoding reading frame. The GenBank Accession Number for the sequence is U78817; the locus is SCU78817. © 1997 John Wiley & Sons, Ltd.     

Quantitative trait locus for calving traits on Bos taurus autosome 18 in Holstein cattle is embedded in a complex genomic region

Although the quantitative trait locus (QTL) on chromosome 18 (BTA18) associated with paternal calving ease and stillbirth in Holstein Friesian cattle and its cross has been known for over 20 years, to our knowledge, the exact causal genetic sequence has yet escaped identification. The aim of this study was to re-examine the region of the published QTL on BTA18 and to investigate the possible reasons behind this elusiveness. For this purpose, we carried out a combined linkage disequilibrium and linkage analysis using genotyping data of 2,697 German Holstein Friesian (HF) animals and subsequent whole-genome sequencing (WGS) data analyses and genome assembly of HF samples. We confirmed the known QTL in the 95% confidence interval of 1.089 Mbp between 58.34 and 59.43 Mbp on BTA18. Additionally, these 4 SNPs in the near-perfect linkage disequilibrium with the QTL haplotype were identified: rs381577268 (on 57,816,137 bp, C/T), rs381878735 (on 59,574,329 bp, A/T), rs464221818 (on 59,329,176 bp, C/T), and rs472502785 (on 59,345,689 bp, T/C). Search for the causal mutation using short and long-read sequences, and methylation data of the BTA18 QTL region did not reveal any candidates though. The assembly showed problems in the region, as well as an abundance of segmental duplications within and around the region. Taking the QTL of BTA18 in Holstein cattle as an example, the data presented in this study comprehensively characterize the genomic features that could also be relevant for other such elusive QTL in various other cattle breeds and livestock species as well.     

The product of the KIN1 locus in Saccharomyces cerevisiae is a serine/threonine-specific protein kinase.

The catalytic domain (30 kDa) of all protein kinases can be aligned for maximum homology, thereby revealing both invariant and highly conserved residues. The KIN1 locus from Saccharomyces cerevisiae was isolated by hybridization to a degenerate oligonucleotide encoding the conserved protein kinase domain, DVWSFG. The predicted amino acid sequence revealed significant homology to the catalytic domain of protein kinases. Using antibodies raised against a bacterial LacZ/KIN1 fusion protein, we have identified by immunoprecipitation the yeast KIN1 gene product as a 145,000 dalton protein (p145KIN1). In exponentially growing yeast cells, the KIN1 protein is phosphorylated primarily on serine residues. The gene product of KIN1 was shown to be a serine/threonine-specific protein kinase in immune complexes, as determined by the transfer of label from [gamma-32P]ATP to either pp145KIN1 or to an exogenously added substrate, alpha-casein. The optimal metal ion concentration in this assay was 20 mM-MnCl2. Subsequent phosphoamino acid analysis of the radiolabelled product, pp145KIN1, demonstrated that this autophosphorylation was specific for serine/threonine residues. There is no apparent difference between wild-type cells and cells containing a disrupted KIN1 gene. The biochemical characterization of protein kinases in simple eukaryotes such as yeast will aid us in determining the role of phosphorylation in cellular growth and physiology.     

酿酒酵母蔗糖关键代谢途径基因的敲除及其生长特性的变化分析

该研究以酿酒酵母（Sacchromyces cerevisiae）IMX581为出发菌株,利用Crispr-Cas9基因编辑的方法敲除其蔗糖消耗途径中的蔗糖转化酶基因Suc2和麦芽糖酶基因MAL32、MAL12、MAL22,构建工程菌株IMX581△Suc2和IMX581△Suc2△MAL32△MAL12△MAL22,并对其生长特性及蔗糖消耗情况进行分析。结果表明,当初始OD600 nm值为0.1时,菌株IMX581△Suc2在以蔗糖为唯一碳源的培养基上仍然可以生长,但培养56 h时,生物量是出发菌株IMX581的52%,而菌株IMX581△Suc2△MAL32△MAL12△MAL22几乎不生长。当初始OD600 nm值为0.1、5.0及10.0时,菌株IMX581△Suc2和IMX581△Suc2△MAL32△MAL12△MAL22培养72 h后,蔗糖的消耗率较出发菌株IMX581均显著下降,分别为28.5%、35.5%、38.5%和7.0%、18.4%、22.5%。因此,成功构建了显著降低蔗糖消耗的菌株IMX581△Suc2△MAL32△MAL12△MAL22,为研究酿酒酵母对蔗糖的利用及调控提供了参考。     

Screening and characterization of transposon-insertion mutants in a pseudohyphal strain of Saccharomyces cerevisiae

Strains of Saccharomyces cerevisiae with sigma1278b background are widely used for elucidation of pseudohyphal differentiation and signal transduction. However, information and resources on the strains are limited compared to the S288C strains. To facilitate functional analysis of strains with sigma1278b background, mutant strains were generated by using a mini-transposon3-3 x HA/LacZ (mTn3)-mutagenized library. Mutants with mTn3 insertions were screened for expression of beta-galactosidase activity under nitrogen starvation and the insertion sites were identified. One hundred and five heterozygous diploid strains were selected and subjected to tetrad analysis. Insertion of mTn3 in 11 genes was lethal in the strain, including three genes, HAC1, TPS1 and UME6, which are non-essential genes according to the Saccharomyces Genome Database. Viable haploid strains with mTn3 insertions were examined for invasive growth, which is a differentiation process in haploid strains including agar penetration on rich medium, and cell morphology during invasive growth. We also examined homozygous diploid strains with mTn3-insertions for filamentous growth and sporulation.     

低温等离子体处理对PET膜性能的影响

选用低温等离子体处理对PET膜进行表面改性.通过扫描电镜、XPS、表面接触角以及表面自由能分析,测试表征了等离子体处理前后膜表面物理形貌结构、化学组分构成以及表面性能的变化情况.研究结果表明,等离子体处理对PET膜产生刻蚀作用,等离子体处理后的样品表面氧/碳、氮/碳含量比有所增加,膜表含氧极性基团如C—O/C—N、C O、C O—O等的含量增加,膜表亲水性有明显改善,表面自由能明显提高.     

The determinants of heat-shock element-directed lacZ expression in Saccharomyces cerevisiae.

Heat-shock induction of heat-shock protein genes is due to a specific promoter element (the heat-shock element, HSE). This study used lacZ under HSE control (HSE-lacZ) to characterize HSE activity in Saccharomyces cerevisiae cells of different physiological states and differing genetic backgrounds. In batch fermentations HSE-lacZ induction by heat shock was maximal in exponential growth, and showed marked decline with the approach to stationary phase. Expression in the absence of heat shock was unaffected by growth phase, indicating that the growth-dependent expression of many yeast heat-shock genes uses promoter elements in addition to the HSE. Heat-induced expression was strongly influenced by the temperature at which cultures were grown. While basal, uninduced expression was constant during growth at different temperatures to 30 degrees C, induction by transfer to 39 degrees C was reduced by increases in growth temperature as low as 18-24 degrees C. Maximal HSE-lacZ induction (30- to 50-fold) was in cultures grown at low temperatures (18-24 degrees C), then heat shocked at 39 degrees C. Ethanol was a poor inducer. Mutations having little effect on HSE-lacZ expression included a respiratory petite; ubi4 (which inactivates the poly-ubiquitin gene); also ubc4 and ubc5 (which each inactivate one of the ubiquitin ligases involved in degradation of aberrant protein). pep4-3 increased both basal and induced beta-galactosidase about two-fold, probably because of slower turnover of this enzyme in pep4-3 strains.     

Thioredoxin genes in Saccharomyces cerevisiae: map positions of TRX1 and TRX2.

The two genes encoding thioredoxins in Saccharomyces cerevisiae, TRX1 and TRX2, map to chromosome XII and VII, respectively. From the DNA sequence of the intragenic region TRX1 is 500 bp downstream of PDC1. Tetrad analysis places TRX2 1.1 cM from ADE3, while a physical map of this region positions TRX2 4.5 kb downstream of ADE3. The mapping of TRX1 adjacent to PDC1 clarifies previous results (Muller, E. G. D. J. Biol. Chem. 266, 9194-9202, 1991) that suggested a third thioredoxin gene.     

Analysis of β-glucans and chitin in a Saccharomyces cerevisiae cell wall mutant using high-performance liquid chromatography

We have previously shown that mutations in the yeast KNR4 gene resulted in pleiotropic cell wall defects, including resistance to killer 9 toxin, elevated osmotic sensitivity to SDS and increased resistance to zymolyase, a (1→3)-β-glucanase. In this report, we further demonstrated that knr4 mutant cells were more permeable to a chromogenic substrate, X-GAL, suggesting that the mutant cell walls were leakier to certain non-permeable molecules. To determine if these defects resulted from structural changes in the cell walls, we analysed the alkali-insoluble cell wall components using HPLC assays developed for this purpose. Comparative analysis using four isogenic strains from a ‘knr4 disrupted’ tetrad demonstrated that mutant cell walls contained much less (1→3)-β-glucan and (1→6)-β-glucan; however, the level of chitin, a minor cell wall component, was found to be five times higher in the mutant strains compared to the wild-type strains. The data suggested that the knr4 mutant cell walls were dramatically weakened, which may explain the pleiotropic cell wall defects.     

The GDI1 genes from Kluyveromyces lactis and Pichia pastoris: cloning and functional expression in Saccharomyces cerevisiae

The nucleotide sequences of 2.8 kb and 2.9 kb fragments containing the Kluyveromyces lactis and Pichia pastoris GDI1 genes, respectively, were determined. K. lactis GDI1 was found during sequencing of a genomic library clone, whereas the P. pastoris GDI1 was obtained from a genomic library by complementing a Saccharomyces cerevisiae sec19‐1 mutant strain. The sequenced DNA fragments contain open reading frames of 1338 bp (K.lactis) and 1344 bp (P. pastoris), coding for polypeptides of 445 and 447 residues, respectively. Both sequences fully complement the S. cerevisiae sec19‐1 mutation. They have high degrees of homology with known GDP dissociation inhibitors from yeast species and other eukaryotes. The GenBank Accession Nos of the sequences are AF255332 (K.lactis GDI1) and AY007574 (P. pastoris GDI1). Copyright © 2001 John Wiley & Sons, Ltd.     

Associating protein activities with their genes: rapid identification of a gene encoding a methylglyoxal reductase in the yeast Saccharomyces cerevisiae

Methylglyoxal is associated with a broad spectrum of biological effects, including cytostatic and cytotoxic activities. It is detoxified by the glyoxylase system or by its reduction to lactaldehyde by methylglyoxal reductase. We show that methylglyoxal reductase (NADPH-dependent) is encoded by GRE2 (YOL151w). We associated this activity with its gene by partially purifying the enzyme and identifying by MALDI-TOF the proteins in candidate bands on SDS-PAGE gels whose relative intensities correlated with specific activity through three purification steps. The candidate proteins were then purified using a glutathione-S-transferase tag that was fused to them, and tested for methylglyoxal reductase activity. The advantage of this approach is that only modest protein purification is required. Our approach should be useful for identifying many of the genes that encode the metabolic pathway enzymes that have not been associated with a gene (about 275 in S. cerevisiae, by our estimate).