Genetic engineering of a sake yeast producing no urea by successive disruption of arginase gene

Urea is reported to be a main precursor of ethyl carbamate (ECA), which is suspected to be a carcinogen, in wine and sake. In order to minimize production of urea, arginase-deficient mutants (delta car1/delta car1) were constructed from a diploid sake yeast, Kyokai no. 9, by successive disruption of the two copies of the CAR1 gene. First, the yeast strain was transformed with plasmid pCAT2 (delta car1 SMR1), and strains heterozygous for CAR1 gene were isolated on sulfometuron methyl plates. Successively, the other CAR1 gene was disrupted by transformation with plasmid pCAT1 (delta car1 G418r) and the resulting car1 mutants were isolated on a G418 plate. Arginase assay of the total cell lysate of the mutants showed that 70% of transformants isolated on G418 plates had no detectable enzyme activity, possibly as a result of the disruption of the two copies of the CAR1 gene. Further genomic Southern analysis confirmed this result. We could brew sake containing no urea with the delta car1/delta car1 homozygous mutant. It is of additional interest that no ECA was detected in the resulting sake, even after storage for 5 months at 30 degrees C. This molecular biological study suggests that ECA in sake originates mainly from urea that is produced by the arginase.     

Contribution of the fermenting yeast strain to ethyl carbamate generation in stone fruit spirits

Fermented fruit and beverages frequently contain ethyl carbamate (EC), a potentially carcinogenic compound that can be formed by the reaction of urea with ethanol. Both are produced by the yeast Saccharomyces cerevisiae with ethanol as the major end product of hexose fermentation and urea as a by-product in arginine catabolism. In spirit production, EC can also be derived from cyanide introduced by stone fruit. To determine the relative contribution of yeast metabolism to EC production, we genetically engineered a diploid laboratory strain to reduce the arginase activity, thus blocking the pathway to urea production. For this purpose, strains with either a heterozygous CAR1/car1 deletion or a homozygous defect (car1/car1) were constructed. These strains were compared to the parental wild type and to an industrial yeast strain in cherry mash fermentations and spirit production. The strain with the homozygous car1 deletion showed a significant reduction of EC in the final spirits in comparison to the non-engineered controls. Nevertheless, using this strain for fermentation of stoneless cherry mashes did not completely impede EC formation. This indicates another, as yet unidentified, source for this compound.     

Genetic engineering of a sake yeast producing no urea by successive disruption of arginase gene.

Urea is reported to be a main precursor of ethyl carbamate (ECA), which is suspected to be a carcinogen, in wine and sake. In order to minimize production of urea, arginase-deficient mutants (delta car1/delta car1) were constructed from a diploid sake yeast, Kyokai no. 9, by successive disruption of the two copies of the CAR1 gene. First, the yeast strain was transformed with plasmid pCAT2 (delta car1 SMR1), and strains heterozygous for CAR1 gene were isolated on sulfometuron methyl plates. Successively, the other CAR1 gene was disrupted by transformation with plasmid pCAT1 (delta car1 G418r) and the resulting car1 mutants were isolated on a G418 plate. Arginase assay of the total cell lysate of the mutants showed that 70% of transformants isolated on G418 plates had no detectable enzyme activity, possibly as a result of the disruption of the two copies of the CAR1 gene. Further genomic Southern analysis confirmed this result. We could brew sake containing no urea with the delta car1/delta car1 homozygous mutant. It is of additional interest that no ECA was detected in the resulting sake, even after storage for 5 months at 30 degrees C. This molecular biological study suggests that ECA in sake originates mainly from urea that is produced by the arginase.     

The occurrence of killer,sensitive, and neutral yeasts in Brazilian Riesling Italico grape must and the effect of neutral strains on killing behaviour

 The occurrence of killer toxins amongst yeasts in Brazilian Riesling Italico grape must was investigated by using the sensitive strain EMBRAPA-26B as a reference strain at 18°C and 28°C. From a total of 85 previously isolated yeasts, 21 strains showed ability to kill the sensitive strain on unbuffered grape must/agar (MA-MB) and 0.1 M citrate/phosphate-buffered yeast extract/peptone/dextrose/agar (YEPD-MB) media both supplemented with 30 mg/l methylene blue. The killer activity of only four yeasts depended on the incubation temperature rather than the medium used. At 28°C, the strains 11B and 53B were not able to show killer action. On the other hand, strains 49B and 84B did not kill the sensitive yeast at 18°C. The killer strain EMBRAPA-91B and a commercial wine killer yeast K-1 were employed to examine the sensitivity of the isolated yeasts on YEPD-MB and MA-MB at 18°C. The sensitivity and neutral characteristics of yeasts were shown to be dependent on the medium and the killer strain. Interactions, including K^- R^-, K^- R⁺ and K⁺ R⁺ strains, simultaneously, have revealed that some K^-R⁺ strains appear to protect the K^- R^- strain against the killer toxin. Sensitive dead cells, although to a less extent, also exhibited similar protection. Kinetic studies have shown that the maximum specific growth rates were higher for the 20B YEPD-MB-sensitive strain (μ_max=0.517 h^-1) than for both the 91B (μ_max=0.428 h^-1) and K-1 (μ_max= 0.466 h^-1) killer strains. The protective capacity of neutral or sensitive cells that contaminate a fermentation, as well as the higher maximum specific growth rate of sensitive yeasts, besides other factors, may preclude the dominance of a killer strain. This protective capacity may also reduce the risk of a sensitive inoculum being killed by wild-type killer yeasts in open non-sterile fermentation. Received: 3 November 1995/Received revision: 11 March 1996/Accepted: 15 April 1996     

Scent of a killer: How could killer yeast boost its dispersal?

Vector‐borne parasites often manipulate hosts to attract uninfected vectors. For example, parasites causing malaria alter host odor to attract mosquitoes. Here, we discuss the ecology and evolution of fruit‐colonizing yeast in a tripartite symbiosis—the so‐called “killer yeast” system. “Killer yeast” consists of Saccharomyces cerevisiae yeast hosting two double‐stranded RNA viruses (M satellite dsRNAs, L‐A dsRNA helper virus). When both dsRNA viruses occur in a yeast cell, the yeast converts to lethal toxin‑producing “killer yeast” phenotype that kills uninfected yeasts. Yeasts on ephemeral fruits attract insect vectors to colonize new habitats. As the viruses have no extracellular stage, they depend on the same insect vectors as yeast for their dispersal. Viruses also benefit from yeast dispersal as this promotes yeast to reproduce sexually, which is how viruses can transmit to uninfected yeast strains. We tested whether insect vectors are more attracted to killer yeasts than to non‑killer yeasts. In our field experiment, we found that killer yeasts were more attractive to Drosophila than non‐killer yeasts. This suggests that vectors foraging on yeast are more likely to transmit yeast with a killer phenotype, allowing the viruses to colonize those uninfected yeast strains that engage in sexual reproduction with the killer yeast. Beyond insights into the basic ecology of the killer yeast system, our results suggest that viruses could increase transmission success by manipulating the insect vectors of their host.     

Mutant isolation of non-urea producing sake yeast by positive selection

Urea is reported to be a main precursor in wine and sake (Japanese rice wine) of ethyl carbamate (ECA), a suspected carcinogen. We constructed an arginase-deficient mutant (Δcar1/Δcar1) from a diploid sake yeast, Kyokai no. 9, using a gene disruption method (Kitamoto, K. et al., Appl. Environ. Microbiol., 57, 301, 1991). The car1 mutant thus constructed enabled us to brew sake containing no urea or ECA. In spite of their superior characteristics, industrial use of mutants for sake brewing has so far been difficult because guidelines for recombinant DNA utilization in the food and beverages industry have not yet been established. Using the genetically engineered car1 mutant, we have developed a new medium for the positive selection of car1 mutants. Many arginase-deficient mutants could be easily isolated from not only a laboratory haploid strain (X2180-1A), but also sake yeasts (Kyokai no. 9 and Kyokai no 10) and wine yeasts (Geisenheim 74 and Eperney). Sake with no urea could be brewed using the car1 mutants, and no ECA was detected in the resulting sake even after heat treatment (hi-ire) and storage.     

Increased astaxanthin production by a Phaffia rhodozyma mutant grown on date juice from Yucca fillifera

The wild strain and the astaxanthin-overproducing mutant strain 25–2 of Phaffia rhodozyma were analyzed in order to assess their ability to grow and synthesize astaxanthin in a minimal medium composed of g L⁻¹: KH₂PO₄ 2.0; MgSO₄ 0.5; CaCl₂ 0.1; urea 1.0 and supplemented with date juice of Yucca fillifera as a carbon source (yuca medium). The highest astaxanthin production (6170 μg L⁻¹) was obtained at 22.5 g L⁻¹ of reducing sugars. The addition of yeast extract to the yuca medium at concentrations of 0.5–3.0 g L⁻¹ inhibited astaxanthin synthesis. The yuca medium supported a higher production of astaxanthin, 2.5-fold more than that observed in the YM medium. Journal of Industrial Microbiology & Biotechnology (2000) 24, 187–190. Received 14 July 1999/ Accepted in revised form 02 December 1999     

The Awa1 gene is required for the foam-forming phenotype and cell surface hydrophobicity of sake yeast

Sake, a traditional alcoholic beverage in Japan, is brewed with sake yeasts, which are classified as Saccharomyces cerevisiae. Almost all sake yeasts form a thick foam layer on sake mash during the fermentation process because of their cell surface hydrophobicity, which increases the cells' affinity for bubbles. To reduce the amount of foam, nonfoaming mutants were bred from foaming sake yeasts. Nonfoaming mutants have hydrophilic cell surfaces and no affinity for bubbles. We have cloned a gene from a foam-forming sake yeast that confers foaming ability to a nonfoaming mutant. This gene was named AWA1 and structures of the gene and its product were analyzed. The N- and C-terminal regions of Awa1p have the characteristic sequences of a glycosylphosphatidylinositol anchor protein. The entire protein is rich in serine and threonine residues and has a lot of repetitive sequences. These results suggest that Awa1p is localized in the cell wall. This was confirmed by immunofluorescence microscopy and Western blotting analysis using hemagglutinin-tagged Awa1p. Moreover, an awa1 disruptant of sake yeast was hydrophilic and showed a nonfoaming phenotype in sake mash. We conclude that Awa1p is a cell wall protein and is required for the foam-forming phenotype and the cell surface hydrophobicity of sake yeast.     

A comparison of the killer character in different yeasts and its classification

The interactions between 20 killer yeasts of various genera and species were examined. Ten distinct groups were recognised with respect to killer activity and 10 distinct groups with respect to resistance to killer action. Using both killing and resistance phenotypes, 13 classes of killer yeast were found. With the exception of Torulopsis glabrata NCYC 388, non-Saccharomyces strains of yeast were not killed by a member of the genus Saccharomyces.The killer character of the 3 killing groups of Saccharomyces identified could be cured by treatment with cycloheximide or incubation at elevated temperature and the effectiveness of these procedures was indicative of the category of killer yeast examined. Killer yeasts not belonging to the genus Saccharomyces could not be cured of their activity. Double-stranded ribonucleic acids were extracted only from Saccharomyces spp. and the molecular weights of the species present were a function of the killer class to which a strain belonged.By an analysis of the effects of proteolytic enzymes, temperature and pH on killer activity and by gel chromatography of crude preparations of killer factors, the toxins of different killer classes were shown to be biochemically distinct. However all toxins had certain properties in common consistent with there being a protein component essential to killer action.     

Serological study of yeast killer toxins by monoclonal antibodies

Yeast killer toxins coded by determined and undetermined killer plasmids or presumptive nuclear gene(s) in various genera (Saccharomyces, Kluyveromyces, Pichia and Candida) have been serologically investigated by a monoclonal antibody (KT4), produced against the yeast killer toxin of Pichia (Hansenula) anomala UCSC 25F. Double immunodiffusion with the killer toxins as antigens and indirect immunofluorescence on whole cells of the corresponding killer yeast have been used. In both the serological procedures, monoclonal antibody KT4 proved to be reacting only with the killer toxins and the whole cells of yeasts belonging to the genus Pichia.     

Spoilage yeasts from Patagonian cellars: characterization and potential biocontrol based on killer interactions

Indigenous yeasts associated with surfaces in three North Patagonian cellars were isolated by means of selective media developed for the isolation of Dekkera/Brettanomyces yeasts; 81 isolates were identified as belonging to Candida boidinii (16%), Hanseniaspora uvarum (38%), Pichia guilliermondii (3%), Saccharomyces cerevisiae (1%), Geotrichum silvicola (16%) and the new yeast species Candida patagonica (26%). No Dekkera/Brettanomyces isolate was obtained, however, 41 isolates (51% of the total isolates) produced some enologically undesirable features under laboratory conditions including the production of 4-ethylphenol and 4-vinylphenol, observed in the Candida boidinii and Pichia guilliermondii isolates. The sensitivity of the 41 spoilage isolates and seven Brettanomyces bruxellensis collection strains was evaluated against a panel of 55 indigenous and ten reference killer yeasts. Killer cultures belonging to Pichia anomala and Kluyveromyces lactis species showed the broadest killer spectrum against spoilage yeasts, including Dekkera bruxellensis collection strains. These killer isolates could be good candidates for use in biocontrol of regionally relevant spoilage yeasts.     

Influence of killer strains of Saccharomyces cerevisiae on wine fermentation

The effect of killer strains of Saccharomyces cerevisiae on the growth of sensitive strains during must fermentation was studied by using a new method to monitor yeast populations. The capability of killer yeast strains to eliminate sensitive strains depends on the initial proportion of killer yeasts, the susceptibility of sensitive strains, and the treatment of the must. In sterile filtered must, an initial proportion of 2-6% of killer yeasts was responsible for protracted fermentation and suppression of isogenic sensitive strains. A more variable initial proportion was needed to get the same effect with non-isogenic strains. The suspended solids that remain in the must after cold-settling decreased killer toxin effect. The addition of bentonite to the must avoided protracted fermentation and the suppression of sensitive strains; however, the addition of yeast dietary nutrients with yeast cell walls did not, although it decreased fermentation lag.     

History,lineage and phenotypic differentiation of sake yeast

ABSTRACT

Sake yeast was first isolated as a single yeast strain, Saccharomyces sake, during the Meiji era. Yeast strains suitable for sake fermentation were subsequently isolated from sake brewers and distributed as Kyokai yeast strains. Sake yeast strains that produce characteristic flavors have been bred in response to various market demands and individual preferences. Interestingly, both genetic and morphological studies have indicated that sake yeast used during the Meiji era differs from new sake yeasts derived from Kyokai Strain No. 7 lineage. Here, we discuss the history of sake yeast breeding, from the discovery of sake yeast to the present day, to highlight the achievements of great Japanese scientists and engineers.     

The costs and benefits of killer toxin production by the yeast Pichia kluyveri

Numerous yeast species in many genera are able to produce and excrete extracellular toxic proteins (mycocins) that can kill other specific sensitive yeasts. Natural distributions of killer yeasts suggest that they may be important in maintaining community composition and provide a benefit to the toxin producing cells. The fact that not all yeasts are killers and that polymorphisms exist within some killer species suggests there may be a cost associated with killer toxin production. This study focuses on the costs and benefits associated with toxin production by the yeast Pichia kluyveri. Strains differing in their ability to kill were obtained by tetrad dissection. One parent strain produced spores that exhibited a trade-off between killing ability and intrinsic growth rate. A killer clone from this strain was able to maintain a higher proportion of cells than a non-killer when grown with the same sensitive yeast under laboratory-simulated natural conditions. On the other hand, when grown with a yeast not sensitive to Pichia kluyveri toxin, the non-killer maintained a higher proportion of the total community than did the killer clone. The data support the hypothesis that there are both costs and benefits to producing killer toxin, and based on this, selection may favor different phenotypes in different conditions.     

Differential killer sensitivity as a tool for fingerprinting wine-yeast strains ofSaccharomyces cerevisiae

The extreme variability of the killer phenomenon in nature, expressed differently in different strains of the same yeast species, embodies an exceptional potential for the discrimination of yeasts at the strain level. Killer-sensitive relationships between a killer reference panel of 24 yeasts belonging to 13 species of six genera, and different industrial wine-starters ofSaccharomyces cerevisiae can be used profitably for a rapid and simple fingerprinting procedure.     

Monitoring of killer yeast populations in mixed cultures: influence of incubation temperature of microvinifications samples

Killer yeasts are frequently used to combat and prevent contamination by wild-type yeasts during wine production and they can even dominate the wine fermentation. Stuck and sluggish fermentations can be caused by an unbalanced ratio of killer to sensitive yeasts in the bioreactor, and therefore it is important to determine the proportion of both populations. The aim of this study was to provide a simple tool to monitor killer yeast populations during controlled mixed microvinifications of killer and sensitive Saccharomyces cerevisiae. Samples were periodically extracted during vinification, seeded on Petri dishes and incubated at 25 and 37?°C; the latter temperature was assayed for possible inactivation of killer toxin production. Colonies developed under the described conditions were randomly transferred to killer phenotype detection medium. Significant differences in the killer/sensitive ratio were observed between both incubation temperatures in all microvinifications. These results suggest that 37?°C seems a better option to determine the biomass of sensitive yeasts, in order to avoid underestimation of sensitive cells in the presence of killer yeasts during fermentations. Incubation at a toxin-inhibiting temperature clearly showed the real ratio of killer to sensitive cells in fermentation systems.     

Yeast killer toxins,molecular mechanisms of their action and their applications

Killer toxins secreted by some yeast strains are the proteins that kill sensitive cells of the same or related yeast genera. In recent years, many new yeast species have been found to be able to produce killer toxins against the pathogenic yeasts, especially Candida albicans. Some of the killer toxins have been purified and characterized, and the genes encoding the killer toxins have been cloned and characterized. Many new targets including different components of cell wall, plasma membrane, tRNA, DNA and others in the sensitive cells for the killer toxin action have been identified so that the new molecular mechanisms of action have been elucidated. However, it is still unknown how some of the newly discovered killer toxins kill the sensitive cells. Studies on the killer phenomenon in yeasts have provided valuable insights into a number of fundamental aspects of eukaryotic cell biology and interactions of different eukaryotic cells. Elucidation of the molecular mechanisms of their action will be helpful to develop the strategies to fight more and more harmful yeasts.     

Tel2p, a regulator of yeast telomeric length in vivo, binds to single-stranded telomeric DNA in vitro

The telomeres of the yeast Saccharomyces cerevisiae consist of a duplex region of TG_1–3 repeats that acquire a single-stranded 3’ extension of the TG_1–3 strand at the end of S-phase. The length of these repeats is kept within a defined range by regulators such as the TEL2-encoded protein (Tel2p). Here we show that Tel2p can specifically bind to single-stranded TG_1–3. Tel2p binding produced several shifted bands; however, only the slowest migrating band contained Tel2p. Methylation protection and interference experiments as well as gel shift experiments using inosine-containing probes indicated that the faster migrating bands resulted from Tel2p-mediated formation of DNA secondary structures held together by G-G interactions. Tel2p bound to single-stranded substrates that were at least 19 bases in length and contained 14 bases of TG_1–3, and also to double-stranded/single-stranded hybrid substrates with a 3’ TG_1–3 overhang. Tel2p binding to a hybrid substrate with a 24 base single-stranded TG_1–3 extension also produced a band characteristic of G-G-mediated secondary structures. These data suggest that Tel2p could regulate telomeric length by binding to the 3’ single-stranded TG_1–3 extension present at yeast telomeres. Received: 12 November 1998; in revised form: 6 April 1999 / Accepted: 13 April 1999     

Strain differentiation of pathogenic yeasts by the killer system

High sensitivity rates to the activity of killer toxins produced by 25 species of yeasts belonging to the genera Candida, Hansenula, Pichia, Rhodotorula, Saccharomyces and Trichosporon have been observed among 112 yeast isolates (25 Cryptococcus neoformans, 29 C. glabrata, 16 C. parapsilosis, 20 C. pseudotropicalis and 22 C. tropicalis). The highest sensitivity has been observed among the C. parapsilosis isolates, the lowest in C. glabrata strains. Genera Pichia and Hansenula proved to have the greatest killer activity. A killer system, formerly used for differentiating C. albicans isolates within the species, proved to be valid as epidemiological marker when applied to 112 strains of pathogenic yeasts.