Nutrient Signaling via the TORC1-Greatwall-PP2AB55δ Pathway Is Responsible for the High Initial Rates of Alcoholic Fermentation in Sake Yeast Strains of Saccharomyces cerevisiae.

Saccharomyces cerevisiae sake yeast strain Kyokai no. 7 (K7) and its relatives carry a homozygous loss-of-function mutation in the RIM15 gene, which encodes a Greatwall family protein kinase. Disruption of RIM15 in nonsake yeast strains leads to improved alcoholic fermentation, indicating that the defect in Rim15p is associated with the enhanced fermentation performance of sake yeast cells. In order to understand how Rim15p mediates fermentation control, we here focused on target-of-rapamycin protein kinase complex 1 (TORC1) and protein phosphatase 2A with the B55δ regulatory subunit (PP2AB55δ), complexes that are known to act upstream and downstream of Rim15p, respectively. Several lines of evidence, including our previous transcriptomic analysis data, suggested enhanced TORC1 signaling in sake yeast cells during sake fermentation. Fermentation tests of the TORC1-related mutants using a laboratory strain revealed that TORC1 signaling positively regulates the initial fermentation rate in a Rim15p-dependent manner. Deletion of the CDC55 gene, encoding B55δ, abolished the high fermentation performance of Rim15p-deficient laboratory yeast and sake yeast cells, indicating that PP2AB55δ mediates the fermentation control by TORC1 and Rim15p. The TORC1-Greatwall-PP2AB55δ pathway similarly affected the fermentation rate in the fission yeast Schizosaccharomyces pombe, strongly suggesting that the evolutionarily conserved pathway governs alcoholic fermentation in yeasts. It is likely that elevated PP2AB55δ activity accounts for the high fermentation performance of sake yeast cells. Heterozygous loss-of-function mutations in CDC55 found in K7-related sake strains may indicate that the Rim15p-deficient phenotypes are disadvantageous to cell survival.IMPORTANCE The biochemical processes and enzymes responsible for glycolysis and alcoholic fermentation by the yeast S. cerevisiae have long been the subject of scientific research. Nevertheless, the factors determining fermentation performance in vivo are not fully understood. As a result, the industrial breeding of yeast strains has required empirical characterization of fermentation by screening numerous mutants through laborious fermentation tests. To establish a rational and efficient breeding strategy, key regulators of alcoholic fermentation need to be identified. In the present study, we focused on how sake yeast strains of S. cerevisiae have acquired high alcoholic fermentation performance. Our findings provide a rational molecular basis to design yeast strains with optimal fermentation performance for production of alcoholic beverages and bioethanol. In addition, as the evolutionarily conserved TORC1-Greatwall-PP2AB55δ pathway plays a major role in the glycolytic control, our work may contribute to research on carbohydrate metabolism in higher eukaryotes.

Mutations in rice (Oryza sativa) heavy metal ATPase 2 (OsHMA2) restrict the translocation of zinc and cadmium.

Widespread soil contamination with heavy metals has fostered the need for plant breeders to develop new crops that do not accumulate heavy metals. Metal-transporting transmembrane proteins that transport heavy metals across the plant plasma membrane are key targets for developing these new crops. Oryza sativa heavy metal ATPase 3 (OsHMA3) is known to be a useful gene for limiting cadmium (Cd) accumulation in rice. OsHMA2 is a close homolog of OsHMA3, but the function of OsHMA2 is unknown. To gain insight into the function of OsHMA2, we analyzed three Tos17 insertion mutants. The translocation ratios of zinc (Zn) and Cd were clearly lower in all mutants than in the wild type, suggesting that OsHMA2 is a major transporter of Zn and Cd from roots to shoots. By comparing each allele in the OsHMA2 protein structure and measuring the Cd translocation ratio, we identified the C-terminal region as essential for Cd translocation into shoots. Two alleles were identified as good material for breeding rice that does not contain Cd in the grain but does contain some Zn, and that grows normally.

OsHMA3, a P1B-type of ATPase affects root-to-shoot cadmium translocation in rice by mediating efflux into vacuoles.

• The cadmium (Cd) over-accumulating rice (Oryza sativa) cv Cho-Ko-Koku was previously shown to have an enhanced rate of root-to-shoot Cd translocation. This trait is controlled by a single recessive allele located at qCdT7. • In this study, using positional cloning and transgenic strategies, heavy metal ATPase 3 (OsHMA3) was identified as the gene that controls root-to-shoot Cd translocation rates. The subcellular localization and Cd-transporting activity of the gene products were also investigated. • The allele of OsHMA3 that confers high root-to-shoot Cd translocation rates (OsHMA3mc) encodes a defective P(1B) -ATPase transporter. OsHMA3 fused to green fluorescent protein was localized to vacuolar membranes in plants and yeast. An OsHMA3 transgene complemented Cd sensitivity in a yeast mutant that lacks the ability to transport Cd into vacuoles. By contrast, OsHMA3mc did not complement the Cd sensitivity of this yeast mutant, indicating that the OsHMA3mc transport function was lost. • We propose that the root cell cytoplasm of Cd-overaccumulating rice plants has more Cd available for loading into the xylem as a result of the lack of OsHMA3-mediated transportation of Cd to the vacuoles. This defect results in Cd translocation to the shoots in higher concentrations. These data demonstrate the importance of vacuolar sequestration for Cd accumulation in rice.

Hsp104 contributes to freeze-thaw tolerance by maintaining proteasomal activity in a spore clone isolated from Shirakami kodama yeast.

The supply of oven-fresh bakery products to consumers has been improved by frozen dough technology; however, freeze-thaw stress decreases the activity of yeast cells. To breed better baker's yeasts for frozen dough, it is important to understand the factors affecting freeze-thaw stress tolerance in baker's yeast. We analyzed the stress response in IB1411, a spore clone from Saccharomyces cerevisiae Shirakami kodama yeast, with an exceptionally high tolerance to freeze-thaw stress. Genes encoding trehalose-6-phosphate synthase (TPS1), catalase (CTT1), and disaggregase (HSP104) were highly expressed in IB1411 cells even under conditions of non-stress. The expression of Hsp104 protein was also higher in IB1411 cells even under non-stress conditions. Deletion of HSP104 (hsp104Δ) in IB1411 cells reduced the activity of the ubiquitin-proteasome system (UPS). By monitoring the accumulation of aggregated proteins using the ΔssCPY*-GFP fusion protein under freeze-thaw stress or treatment with proteasomal inhibitor, we found that IB1411 cells resolved aggregated proteins faster than the hsp104Δ strain. Thus, Hsp104 seems to contribute to freeze-thaw tolerance by maintaining UPS activity via the disaggregation of aggregated proteins. Lastly, we found that the IB1411 cells maintained high leavening ability in frozen dough as compared with the parental strain, Shirakami kodama yeast, and thus will be useful for making bread.

Oxidative stress tolerance of a spore clone isolated from Shirakami kodama yeast depends on altered regulation of Msn2 leading to enhanced expression of ROS-degrading enzymes.

We analyzed the stress response in a spore clone from Shirakami kodama yeast, Saccharomyces cerevisiae, with an exceptional high tolerance to oxidative stress. The levels of reactive oxygen species (ROS) in this clone were very low, whereas the genes for superoxide dismutase (SOD2) and catalase (CTT1) were highly expressed and those enzymes also had high activities even under non-stress conditions. Both genes are regulated by general stress-responsive transcription factors Msn2 and Msn4, and Yap1, a transcription factor required for oxidative stress tolerance, and the removal of Msn2 or Yap1 caused a significant decrease in CTT1-expression. Under non-stress conditions, Msn2 was ~3.6-fold more abundant in the nucleus of the spore clone compared with a laboratory strain, whereas the nuclear abundance of Yap1 remained unchanged. Thus, a high tolerance to oxidative stress in this spore clone results from a high expression of ROS-degrading enzymes by the abundant accumulation of Msn2 in the nucleus. We found that oxidative stress caused by the presence of furfural did not impair fermentation by this strain, which could make it attractive for ethanol production from lignocellulosic biomass.

TORC1 activity is partially reduced under nitrogen starvation conditions in sake yeast Kyokai no. 7, Saccharomyces cerevisiae.

Industrial yeasts are generally unable to sporulate but treatment with the immunosuppressive drug rapamycin restores this ability in a sake yeast strain Kyokai no. 7 (K7), Saccharomyces cerevisiae. This finding suggests that TORC1 is active under sporulation conditions. Here, using a reporter gene assay, Northern and Western blots, we tried to gain insight into how TORC1 function under nitrogen starvation conditions in K7 cells. Similarly to a laboratory strain, RPS26A transcription was repressed and Npr1 was dephosphorylated in K7 cells, indicative of the expected loss of TORC1 function under nitrogen starvation. The expression of nitrogen catabolite repression-sensitive genes, however, was not induced, the level of Cln3 remained constant, and autophagy was more slowly induced than in a laboratory strain, all suggestive of active TORC1. We conclude that TORC1 activity is partially reduced under nitrogen starvation conditions in K7 cells.

Efficient selection of hybrids by protoplast fusion using drug resistance markers and reporter genes in Saccharomyces cerevisiae.

We have developed a selection system for hybrids by protoplast fusion using dominant selective drug resistance markers, Tn601(903) against geneticin and AUR1-C against aureobasidin A, and reporter genes, ADH1p-PHO5-ADH1t and CLN2p-CYC1-lacZ, in Saccharomyces cerevisiae. To examine the effectiveness of this system, plasmids with each marker and reporter gene were introduced into auxotrophic sake yeasts. From the resulting transformants, eight colonies were screened by protoplast fusion in combination with the drug resistance markers and the reporter genes. Among them, seven strains were judged as hybrids between parental strains by analysis of growth on a minimal medium. This selection system was applied to wine yeasts having no genetic markers. Six strains were regarded as hybrids between parental strains by polymerase chain reaction/restriction fragment length polymorphism (PCR/RFLP) analysis of the MET2 gene and by karyotype analysis using a contour-clamped homogeneous electric field (CHEF). We propose that the plotoplast fusion using dominant selective geneticin- and aureobasidin A-resistance markers and reporter genes is useful for the selection of hybrids from wine yeasts, which are homothallic and have low sporulation ability.

Mechanism of high trehalose accumulation in a spore clone isolated from Shirakami kodama yeast.

The intracellular trehalose levels in Shirakami kodama yeast, a strain of Saccharomyces cerevisiae, isolated in 1997 from leaf mold in the Shirakami Mountains and since used as a commercial baker's yeast, are remarkably high, which presumably is related to its tolerance of freezing and drought conditions. We isolated a spore clone from Shirakami kodama yeast with about 1.7-fold higher intracellular trehalose levels than the parental strain and set out to elucidate how this spore clone can accumulate intracellular trehalose to such a high concentration. The gene for trehalose 6-phosphate synthase, TPS1, was duplicated in this spore clone. Both TPS1 genes contributed to the high level of intracellular trehalose as a 3.4-fold decrease resulted from the disruption of one of the two TPS1 genes. Both Msn2 and Msn4, which bind to stress responsive elements in the promoter region of TPS1, were required for production of high levels of trehalose. Furthermore, the neutral trehalase activity of this spore clone is about 3-fold less than that of the laboratory strain although the gene for neutral trehalase, NTH1, functioned normally. These findings indicate that two TPS1 genes and the low trehalase activity are associated with high trehalose accumulation in this spore clone. The wide range of stresses of which we found the spore clone to be tolerant makes this yeast very attractive for commercial application and for further research into the mechanisms underlying stress responses and trehalose metabolism.

Immunosuppressive drug rapamycin restores sporulation competence in industrial yeasts.

Industrial yeasts, including a sake yeast strain Kyokai no. 7 (K7), are generally unable to sporulate. Previously, we have reported that in K7 (Saccharomyces cerevisiae) cells, deletion of the G1 cyclin gene CLN3, a key activator of the cell cycle, allows the cells to induce IME1 transcription and sporulate under sporulation conditions. Here we show that treatment with the immunosuppressive drug rapamycin also restores sporulation competence in K7 cells. Moreover, sporulation was observed after rapamycin treatment in other industrial yeasts, namely bottom fermenting yeast strains and a wine yeast strain, which are not able to sporulate under normal sporulation conditions. These findings suggest that activation of TORC1 under sporulation conditions leads to sporulation incompetence in these yeasts. Thus, rapamycin treatment will be useful to restore sporulation competence in industrial yeasts.

Cln3 blocks IME1 transcription and the Ime1-Ume6 interaction to cause the sporulation incompetence in a sake yeast, Kyokai no. 7.

Industrial yeasts, including a sake yeast Kyokai no. 7 (K7), are generally unable to sporulate. In K7 (Saccharomyces cerevisiae) cells, IME1 transcription was not induced under sporulation conditions, and K7 cells partially restored sporulation ability when transformed with a multicopy plasmid bearing IME1. However, the mechanisms of sporulation incompetence in industrial yeasts are poorly understood. We demonstrated that the deletion of the G1 cyclin CLN3, a key activator of the cell cycle, allows K7 cells to induce IME1 transcription and sporulate under sporulation conditions. In K7 cells, CLN3 mRNA and protein were not down-regulated despite sporulation conditions. Moreover, using a two-hybrid assay, we found that Ime1-Ume6 interaction was promoted in Cln3-deficient K7 cells. Thus, Cln3 is involved in the mechanism underlying sporulation incompetence by inhibiting IME1 transcription and the Ime1-Ume6 interaction. Based on these findings, we hypothesize that the absence of transmission of nutrient starvation signals to CLN3 leads to sporulation incompetence in K7 cells.