Vacuolar morphology of Saccharomyces cerevisiae during the process of wine making and Japanese sake brewing

Although ethanol and osmotic stress affect the vacuolar morphology of Saccharomyces cerevisiae, little information is available about changes in vacuolar morphology during the processes of wine making and Japanese sake (rice wine) brewing. Here, we elucidated changes in the morphology of yeast vacuoles using Zrc1p-GFP, a vacuolar membrane protein, so as to better understand yeast physiology during the brewing process. Wine yeast cells (OC-2 and EC1118) contained highly fragmented vacuoles in the sake mash (moromi) as well as in the grape must. Although sake yeast cells (Kyokai no. 9 and no. 10) also contained highly fragmented vacuoles during the wine-making process, they showed quite a distinct vacuolar morphology during sake brewing. Since the environment surrounding sake yeast cells in the sake mash did not differ much from that surrounding wine yeast cells, the difference in vacuolar morphology during sake brewing between wine yeast and sake yeast was likely caused by innate characters.     

Effect of L-proline on sake brewing and ethanol stress in Saccharomyces cerevisiae

During the fermentation of sake, cells of Saccharomyces cerevisiae are exposed to high concentrations of ethanol, thereby damaging the cell membrane and functional proteins. L-proline protects yeast cells from damage caused by freezing or oxidative stress. In this study, we evaluated the role of intracellular L-proline in cells of S. cerevisiae grown under ethanol stress. An L-proline-accumulating laboratory strain carries a mutant allele of PRO1, pro1(D154N), which encodes the Asp154Asn mutant gamma-glutamyl kinase. This mutation increases the activity of gamma-glutamyl kinase and gamma-glutamyl phosphate reductase, which catalyze the first two steps of L-proline synthesis and which together may form a complex in vivo. When cultured in liquid medium in the presence of 9% and 18% ethanol under static conditions, the cell viability of the L-proline-accumulating laboratory strain is greater than the cell viability of the parent strain. This result suggests that intracellular accumulation of L-proline may confer tolerance to ethanol stress. We constructed a novel sake yeast strain by disrupting the PUT1 gene, which is required for L-proline utilization, and replacing the wild-type PRO1 allele with the pro1(D154N) allele. The resultant strain accumulated L-proline and was more tolerant to ethanol stress than was the control strain. We used the strain that could accumulate L-proline to brew sake containing five times more L-proline than what is found in sake brewed with the control strain, without affecting the fermentation profiles.     

Formation of cytoplasmic P-bodies in sake yeast during Japanese sake brewing and wine making

Recent studies have revealed that cytoplasmic processing bodies (P-bodies) play important roles in the control of eukaryotic gene expression in response to stress. Since the formation of P-bodies is in dynamic competition with translation, the status of translation is reflected in the assembly and disassembly of P-bodies in eukaryotic cells. During the brewing of Japanese sake and the making of wine, yeast cells are exposed to stress caused by increases in the concentration of ethanol. Here we found that ethanol stress enhances the formation of P-bodies in yeast cells in SD medium. In the wine-making process, P-body formation was also enhanced as alcoholic fermentation proceeded, but the formation of P-bodies was not simply affected by the ethanol concentration in the sake mash. These findings suggest differences in the rate of translation and the cytoplasmic mRNA flux during the sake brewing and wine making processes.     

Characterization of the export of bulk poly(A)+ mRNA in Saccharomyces cerevisiae during the wine-making process

Ethanol stress affects the nuclear export of mRNA similarly to heat shock in Saccharomyces cerevisiae. However, we have little information about mRNA transport in actual alcoholic fermentation. Here we characterized the transport of mRNA during wine making and found that bulk poly(A)+ mRNA accumulated in the nucleus as fermentation progressed.     

Characterization and localization of the sporulation glucoamylase of Saccharomyces cerevisiae

Glucoamylase (SGA) was purified approximately 250-fold from sporulating Saccharomyces cerevisiae cells. The partially purified enzyme was active against glycogen, starch, maltotriose and maltose. It exhibited maximum catalytic activity against glycogen at pH 5.5. The enzyme appears to be glycosylated, because it bound to lentil-lectin Sepharose. SGA was expressed in vegetatively growing cells under the control of the GAL1 promoter, and the cellular location of the enzymatic activity determined by fractionation techniques. SGA was preferentially recovered in fractions which were enriched for the vacuolar hydrolases, carboxypeptidase Y and alpha-mannosidase.     

Gaseous environments modify physiology in the brewing yeast Saccharomyces cerevisiae during batch alcoholic fermentation

Aims:  To investigate the impact of different gaseous atmospheres on different physiological parameters in the brewing yeast Saccharomyces cerevisiae BRAS291 during batch fermentation.
Methods and Results:  Yeasts were cultivated on a defined medium with a continuous sparging of hydrogen, helium and oxygen or without gas, permitting to obtain three values of external redox. High differences were observed concerning viable cell number, size and metabolites produced during the cultures. The ethanol yields were diminished whereas glycerol, succinate, acetoin, acetate and acetaldehyde yields were enhanced significantly. Moreover, we observed major changes in the intracellular NADH/NAD⁺ and GSH/GSSG ratio.
Conclusions:  The use of gas led to drastic changes in the cell size, primary energy metabolism and internal redox balance and E _h . These changes were different depending on the gas applied throughout the culture.
Significance and Impact of the Study:  For the first time, our study describes the influence of various gases on the physiology of the brewing yeast S. cerevisiae . These influences concern mainly yeast growth, cell structure, carbon and redox metabolisms. This work may have important implications in alcohol-related industries, where different strategies are currently developed to control better the production of metabolites with a particular attention to glycerol and ethanol.     

The NES-Crm1p export pathway is not a major mRNA export route in Saccharomyces cerevisiae.

Nuclear export signal (NES)-containing proteins are recognized by the NES receptor CRM1/Crm1p (also called exportin 1/Xpo1p). In vertebrates and Schizosaccharomyces pombe, the toxin leptomycin B (LMB) inhibits CRM1-mediated export by interacting directly with CRM1 and disrupting the trimeric Ran-GTP-CRM1-NES export complex. In Saccharomyces cerevisiae, LMB is not toxic and is apparently unable to interact with Crm1p. A second difference between the systems is that LMB has no effect on mRNA export in vertebrate systems, whereas there is evidence that S.cerevisiae Crm1p plays a role in mRNA export. Here we show that a single amino acid change converts S. cerevisiae Crm1p from being LMB insensitive to fully LMB sensitive, indicating that Crm1p is the only relevant LMB target. This new strain has no phenotype, but LMB has a rapid and potent inhibitory effect on NES-mediated export. In situ hybridization assays show that LMB also causes nuclear accumulation of poly(A)+ RNA but with a significant delay compared with the effect on NES-mediated export. Biochemical assays indicate little or no LMB effect on cytoplasmic protein synthesis, indicating that the NES-Crm1p pathway is not a major mRNA export route in S.cerevisiae. We conclude that Crm1p structure and function is conserved from S.cerevisiae to man.     

清酒酵母与酿酒醇母原生质体融合的研究

清酒酵母（ＳａｃｃｈａｒｏｍｙｃｅｓｓａｋｅＹａｂｅ）是日本清酒的生产菌株．耐酒精能力强;Ｋ氏酿酒酵母（ＳａｃｃｈａｒｏｍｙｃｅｓｃｅｒｅｖｉｓｉａｅＫ）是酒精生产的常用菌株,发酵力强。本文应用原生质体融合技术进行了二菌株原生质体融合的研究。通过硫酸二乙酯（ＤＥＳ）诱变得到营养缺隐型菌株Ｑ（ａｒｇ－）和Ｋ（ｌｙｓ－,ρ－）,其融合率为１．２５×１０－５。检出的融合子其酒精发酵特性、细胞形态、体积大小都不同于双亲菌株。比较了在２８℃培养条件下,出发余株清酒酵母,Ｋ氏酿酒酵母和融合子Ｆ１、Ｆ２的发酵速度曲线、乙醇产量和酒精耐量等,得到一株在２８℃培养条件下,乙醇产量为７．４％（Ｖ／Ｖ）,酒精耐量为１５％的融合株Ｆ１。     

Direct mating between diploid sake strains of Saccharomyces cerevisiae

Various auxotrophic mutants of diploid heterothallic Japanese sake strains of Saccharomyces cerevisiae were utilized for selecting mating-competent diploid isolates. The auxotrophic mutants were exposed to ultraviolet (UV) irradiation and crossed with laboratory haploid tester strains carrying complementary auxotrophic markers. Zygotes were then selected on minimal medium. Sake strains exhibiting a MATa or MATα mating type were easily obtained at high frequency without prior sporulation, suggesting that the UV irradiation induced homozygosity at the MAT locus. Flow cytometric analysis of a hybrid showed a twofold higher DNA content than the sake diploid parent, consistent with tetraploidy. By crossing strains of opposite mating type in all possible combinations, a number of hybrids were constructed. Hybrids formed in crosses between traditional sake strains and between a natural nonhaploid isolate and traditional sake strains displayed equivalent fermentation ability without any apparent defects and produced comparable or improved sake. Isolation of mating-competent auxotrophic mutants directly from industrial yeast strains allows crossbreeding to construct polyploids suitable for industrial use without dependence on sporulation.     

Critical importance of phytase for yeast growth and alcohol fermentation in Japanese sake brewing

The high phytase producing mutant of Aspergillus oryzae (KL-38) previously isolated was employed for koji making, and the produced koji rice then supplied for sake brewing. The alcohol fermentation was improved compared to that with the parent strain (A. oryzae BP-1). The effects of two phytase isozymes (Phy I and Phy II) produced by A. oryzae on yeast growth and inorganic phosphate liberation were investigated using a synthetic medium containing phytic acid as a sole phosphate source. Yeast growth and the liberation of inorganic phosphate were both enhanced by the combination of Phy I and Phy II at a ratio of 1 to 3, which was compatible with the production ratio in KL-38. Based on these results, phytase plays important role in sake brewing, and that the maximum inorganic phosphate liberation from phytic acid can be obtained by a suitable combination of Phy I and Phy II.     

Characterization of the Export of Bulk Poly(A)+ mRNA in Saccharomyces cerevisiae during the Wine-Making Process

Ethanol stress affects the nuclear export of mRNA similarly to heat shock in Saccharomyces cerevisiae. However, we have little information about mRNA transport in actual alcoholic fermentation. Here we characterized the transport of mRNA during wine making and found that bulk poly(A)⁺ mRNA accumulated in the nucleus as fermentation progressed.     

Global gene expression analysis of yeast cells during sake brewing

During the brewing of Japanese sake, Saccharomyces cerevisiae cells produce a high concentration of ethanol compared with other ethanol fermentation methods. We analyzed the gene expression profiles of yeast cells during sake brewing using DNA microarray analysis. This analysis revealed some characteristics of yeast gene expression during sake brewing and provided a scaffold for a molecular level understanding of the sake brewing process.     

Dynamical analysis of yeast protein interaction network during the sake brewing process

Proteins interact with each other for performing essential functions of an organism. They change partners to get involved in various processes at different times or locations. Studying variations of protein interactions within a specific process would help better understand the dynamic features of the protein interactions and their functions. We studied the protein interaction network of Saccharomyces cerevisiae (yeast) during the brewing of Japanese sake. In this process, yeast cells are exposed to several stresses. Analysis of protein interaction networks of yeast during this process helps to understand how protein interactions of yeast change during the sake brewing process. We used gene expression profiles of yeast cells for this purpose. Results of our experiments revealed some characteristics and behaviors of yeast hubs and non-hubs and their dynamical changes during the brewing process. We found that just a small portion of the proteins (12.8 to 21.6%) is responsible for the functional changes of the proteins in the sake brewing process. The changes in the number of edges and hubs of the yeast protein interaction networks increase in the first stages of the process and it then decreases at the final stages.     

Whole-genome sequencing of sake yeast Saccharomyces cerevisiae Kyokai no. 7

The term 'sake yeast' is generally used to indicate the Saccharomyces cerevisiae strains that possess characteristics distinct from others including the laboratory strain S288C and are well suited for sake brewery. Here, we report the draft whole-genome shotgun sequence of a commonly used diploid sake yeast strain, Kyokai no. 7 (K7). The assembled sequence of K7 was nearly identical to that of the S288C, except for several subtelomeric polymorphisms and two large inversions in K7. A survey of heterozygous bases between the homologous chromosomes revealed the presence of mosaic-like uneven distribution of heterozygosity in K7. The distribution patterns appeared to have resulted from repeated losses of heterozygosity in the ancestral lineage of K7. Analysis of genes revealed the presence of both K7-acquired and K7-lost genes, in addition to numerous others with segmentations and terminal discrepancies in comparison with those of S288C. The distribution of Ty element also largely differed in the two strains. Interestingly, two regions in chromosomes I and VII of S288C have apparently been replaced by Ty elements in K7. Sequence comparisons suggest that these gene conversions were caused by cDNA-mediated recombination of Ty elements. The present study advances our understanding of the functional and evolutionary genomics of the sake yeast.     

Genome-wide analysis of mRNA lengths in Saccharomyces cerevisiae

Background  

Although the protein-coding sequences in the Saccharomyces cerevisiae genome have been studied and annotated extensively, much less is known about the extent and characteristics of the untranslated regions of yeast mRNAs.     

Nuclear localization of aspartate transcabamoylase in Saccharomyces cerevisiae

The cytochemical technique using the in situ precipitation of orthophosphate ions liberated specifically by the aspartate carbamoyltransferase (ATCase) (EC 2.1.3.2) reaction indicated that in Saccharomyces cerevisiae this enzyme is confined to the nucleus. This observation is in accordance with the result reported by Bernhardt and Davis (1972), Proc. Natl. Acad. Sci. U. S. A. 69:1868-1872) on Neurospora crassa. The nuclear compartmentation was also observed in a mutant strain lacking proteinase B activity. This finding indicates that this proteinase is not involved in the nuclear accumulation of ATCase, and that the activity observed in the nucleus corresponds to the multifunctional form associated with the uracil path-specific carbamoylphosphate synthetase and sensitive to feedback inhibition by UTP. In a ura2 strain transformed by nonintegrated pFL1 plasmids bearing the URA2-ATCase activity encoding gene, the lead phosphate precipitate was observed predominantly in the cytoplasm. This finding enhances the reliability of the technique used by eliminating the possibility of an artifactual displacement of an originally cytoplasmic reaction product during the preparation of the material for electron microscopy. On the other hand, nuclei isolated under hypoosmotic conditions do not exhibit the ATCase activity that is recovered in the cytosolic fractions after differential centrifugation of the lysate in Percoll gradient. A release of the protein from the nuclei during the lysis step, consistent with its nucleoplasmic localization, is postulated.