Ethanol-Independent Biofilm Formation by a Flor Wine Yeast Strain of Saccharomyces cerevisiae

Flor strains of Saccharomyces cerevisiae form a biofilm on the surface of wine at the end of fermentation, when sugar is depleted and growth on ethanol becomes dependent on oxygen. Here, we report greater biofilm formation on glycerol and ethyl acetate and inconsistent formation on succinic, lactic, and acetic acids.Flor or velum formation by certain wine strains of Saccharomyces cerevisiae (flor strains) is a form of cellular aggregation observed as an air-liquid interfacial biofilm at the end of the alcoholic fermentation. Formation of the biofilm appears to be an adaptive mechanism because it ensures access to oxygen and therefore permits continued growth on nonfermentable ethanol. In general, nonbuoyant cells cease growth at the end of completed wine fermentations not for lack of carbon but for lack of oxygen. Biofilm cells have been found to have an elevated and/or altered lipid content and increased surface hydrophobicity (3, 5, 8, 9, 11). While both Hsp12, a small heat shock protein (13), and Muc1 (also known as Flo11), a hydrophobic cell wall mannoprotein (4, 6), have been shown to be required for the flor biofilm (10, 12, 14), other genetic or environmental requirements, other than an absence of glucose and the presence of ethanol and oxygen, have not been demonstrated. Here, we asked whether flor formation could be induced during growth on nonfermentable substrates other than ethanol. On the basis of dry weight of biofilm formed per mg of available carbon, the best carbon sources were found to be glycerol, ethyl acetate, and ethanol, in descending order. While subsurface growth occurred on acetic, dl-lactic, and succinic acids, an air-liquid interfacial biofilm did not always form. Microarray analysis of cells shifted from growth on glucose to growth on ethanol did not detect significant changes in expression of known biofilm formation-associated genes.     

Construction of a Stable alpha-Galactosidase-Producing Baker's Yeast Strain

Molasses is widely used as a substrate for commercial yeast production. The complete hydrolysis of raffinose, which is present in beet molasses, by Saccharomyces strains requires the secretion of alpha-galactosidase, in addition to the secretion of invertase. Raffinose is not completely utilized by commercially available yeast strains used for baking, which are Mel. In this study we integrated the yeast MEL1 gene, which codes for alpha-galactosidase, into a commercial mel baker's yeast strain. The Mel phenotype of the new strain was stable. The MEL1 gene was expressed when the new Mel baker's yeast was grown in molasses medium under conditions similar to those used for baker's yeast production at commercial factories. The alpha-galactosidase produced by this novel baker's yeast strain hydrolyzed all the melibiose that normally accumulates in the growth medium. As a consequence, additional carbohydrate was available to the yeasts for growth. The new strain also produced considerably more alpha-galactosidase than did a wild-type Mel strain and may prove useful for commercial production of alpha-galactosidase.     

植酸酶酵母工程菌的构建*

从无花果曲霉(Aspergillus ficuum)3．4322中用RT-PCR方法扩增出一条约1．4kb的特异性条带,DNA序列测定表明,目的片段为不含信号肽的植酸酶编码序列,全长1347bp。无花果曲霉(Aspergillus ficuum)3．4322phyA基因序列已在GenBank注册(注册号为：AF537344)。将该基因克隆到酵母表达载体pYES2中,构建成不带信号肽phyA基因的重组表达载体pYPA2。用醋酸锂法将pYPA2转进urd缺陷型的酿酒酵母(s．oeraisiae INVSc1),筛选获得含植酸酶基因的酵母转化子。经半乳糖诱导表达后,用磷钼蓝显色(AMES)法对酵母菌体进行酶活测定,测出了明显的植酸酶活性,pYPA2胞内植酸酶活性约11．55IU／mL,表明无花果曲霉(Aspergillus ficuum)3．4322phyA基因能在酿酒酵母中表达。     

Toxins of a Wild Candida Killer Yeast with a Novel Killer Property

The killer toxic substance of Candida SW-55 was separated into two components, I and II, by CM-Sepharose CL-6B column chromatography. They were purified 20 700-fold and 11 100-fold from the culture filtrate of SW-55, respectively. Each purified toxin gave a marked glycoprotein band with molecular mass of 36 kDa on SDS/polyacrylamide gel electrophoresis. Toxins I and II had almost the same isoelectric points, 3.4~3.7 and 3.3~3.8, respectively. Toxin I had strong killer activity against Saccharomyces cerevisiae, Candida glabrata, Hansenula anomala, and Rhodotorula rubra (MIC 0.2~0.3μg/ml), and moderate activity against Kluyveromyces lactis (MIC 2.5μg/ml) and Pichia membranaefaciens (MIC 0.6 μg/ml) but bacteria, fungi, and the other yeasts tested were not affected by toxin I even at the high concentration of 20 μg/ml. Toxin II turned out to be less active than toxin I and the MIC for S. cerevisiae Epernay was 0.4~0.5μg/ml.     

The Production of a Yeast Killer Factor in the Chemostat and the Effects of Killer Yeasts in Mixed Continuous Culture with a Sensitive Strain

In batch culture in a complex medium the killer yeasts NCYC 738 and NCYC 235 gave maximal killer activity when grown in the pH ranges 4·2–4·4 and 4·6–4·8 respectively. Incubation of culture filtrates of NCYC 738 for 10 h at 25 °C or 2 h at 29 °C resulted in a 50% reduction in activity. The addition of bovine serum albumin or gelatine to a complex medium stabilized killer activity. In a defined medium the addition of yeast extract stimulated the production of killer activity. When killer yeast NCYC 738 was grown in a chemostat, killer activity was influenced by temperature, pH and the rate at which the culture was stirred. The production of killer activity was growth-linked and increased as dilution rate was raised to a maximum of 0·15 h"1. Steady state continuous cultures of the sensitive strain, NCYC 1006, were contaminated deliberately with either killer or killer-cured strains. During the first 30 h cultivation, the cell concentration of both strains increased. Subsequently the sensitive strain was displaced from the culture. When killer-cured NCYC 738 was added, the rate of displacement was proportional to the culture temperature. However, with killer NCYC 738 increase of temperature reduced the rate of displacement. When killer NCYC 235 was employed, a lowering of pH decreased the rate of displacement but had no effect when killer-cured NCYC 235 was used.     

Growth and Fermentation Characteristics of a Strain of the Wine Yeast Kluyveromyces thermotolerans Isolated in Greece

Summary During the single culture fermentation of grape must K. thermotolerans, strain TH941, isolated in a wine-producing region in northern Greece, reached a very high cell concentration of 8.4 log (c.f.u ml⁻¹), followed by a rapid decline of the viable cells. The yeast produced 9.6 g L-lactic acid l⁻¹ during the growth phase, 7.58% v/v of ethanol and showed a limited degradation of L-malic acid as well as a low production of volatile acidity. In the presence of 3% v/v and 6% v/v of ethanol the K. thermotolerans isolate was able to grow. At 9% v/v of ethanol it could not grow but showed no loss of viability for 10 days.     

Effects of Yeast Killer Factor on Sensitive Cells

The toxic factor secreted by killer strains of yeast and its effects on sensitive strains have been explored in detail.     

酵母亚细胞结构分离效率评估菌株的构建 *

背景: 真核细胞依赖其亚细胞结构高效地完成复杂的生化反应。尽管目前有一些亚细胞结构分离技术,但却缺乏评估这些分离技术的简单、有效方法。目的: 构建可以用来检测亚细胞结构分离效率的酿酒酵母菌株。方法: 通过传统的分子生物学与细胞生物学方法以酿酒酵母为背景构建了亚细胞结构分离效率评估菌株,并进行可行性检测。首先,将酵母各细胞器、自噬体及质膜的标记蛋白进行分组,用不同的蛋白标签分别标记每组蛋白。然后,以标记蛋白-GFP/RFP作为对照组通过免疫荧光法检测蛋白标签对标记蛋白的亚细胞定位是否有影响。最后,通过非连续性密度梯度离心验证该检测菌株能否用来检测亚细胞结构的分离效率。结果: 成功构建了酵母亚细胞结构分离效率评估菌株,该菌株标记了大多数酵母细胞亚细胞结构。挂标签的标记蛋白仍然定位在各自标记蛋白对应的亚细胞结构。非连续性密度梯度离心后,酵母各个亚细胞结构的标记蛋白均可以被检测到。结论: 该酵母亚细胞结构分离效率评估菌株是检测各亚细胞结构分离结果的方便工具,对今后酿酒酵母细胞生物学的研究有潜在的应用价值。     

Karyotype Rearrangements in a Wine Yeast Strain by rad52-Dependent and rad52-Independent Mechanisms

Yeast strains isolated from the wild may undergo karyotype changes during vegetative growth, a characteristic that compromises their utility in genetic improvement projects for industrial purposes. Karyotype instability is a dominant trait, segregating among meiotic derivatives as if it depended upon only a few genetic elements. We show that disrupting the RAD52 gene in a hypervariable strain partially stabilizes its karyotype. Specifically, RAD52 disruption eliminated recombination at telomeric and subtelomeric sequences, had no influence on ribosomal DNA rearrangement rates, and reduced to 30% the rate of changes in chromosomal size. Thus, there are at least three mechanisms related to karyotype instability in wild yeast strains, two of them not requiring RAD52-mediated homologous recombination. When utilized for a standard sparkling-wine second fermentation, Δrad52 strains retained the enological properties of the parental strain, specifically its vigorous fermentation capability. These data increase our understanding of the mechanisms of karyotype instability in yeast strains isolated from the wild and illustrate the feasibility and limitations of genetic remediation to increase the suitability of natural strains for industrial processes.     

Occurrence and Growth of Killer Yeasts during Wine Fermentation

Sixteen wine fermentations were examined for the presence of killer yeasts. Killer property and sensitivity to killer action were found in isolates of Saccharomyces cerevisiae but not in isolates of Kloeckera, Candida, Hansenula, and Torulaspora spp. Several killer and killer-sensitive strains of S. cerevisiae were differentiated by colony morphology, and this property was used to monitor their growth kinetics in mixed cultures in grape juice. Killer-sensitive strains died off within 24 to 48 h during mixed-strain fermentation. Killer action was demonstrated at pH 3.0 and pH 3.5 and over the range of 15 to 25°C but depended on the proportion of killer to killer-sensitive cells at the commencement of fermentation. The dominance of killer strains in mixed-strain fermentations was reflected in the production of ethanol, acetic acid, and glycerol.     

葡萄酒中酵母菌高产甘油的研究进展

甘油是酵母菌酒精发酵过程中的副产物,甘油作为非挥发性物质,对葡萄酒的香气没有贡献,但是其黏性和甜味,可使葡萄酒具有圆润、柔滑、甘甜、肥硕、更易入口的特性,也可用于平衡酒中的酸感,增加口感复杂性,是高品质果酒的重要成分。近年来,国内外对高产甘油酵母的研究日益增多,着重于提高葡萄酒中酵母发酵生产甘油的能力。     

葡萄酒工业酵母生孢特性研究

孢子是单倍体配子,由于具有遗传型与表现型相一致的优点,是遗传学上常用的材料。用工业化葡萄酒活性干酵母进行生孢试验,结果表明,供试8支菌种均可生孢,但生孢率与孢子形态相差较大。其中,17#生孢最强,30#、29#、27#次之,28#、18#、26#渐弱,32#生孢最弱。子囊多为圆形大细胞,孢子多为球形或卵圆形,子囊内一般含2~4个孢子,但29#中可见5~6个孢子。     

Effect of a Killer Toxin of Yeast on Eucaryotic Systems

The Saccharomyces cerevisiae killer toxin KT 28, which inhibits sensitive yeasts, was shown to have no effect on several pathogenic fungi or on the protozoan Trichomonas vaginalis. At concentrations of about 0.1 mg/ml, a partial inhibition of the skin pathogenic fungi Trichophyton rubrum and Microsporum canis was observed at pH 6.5. No pharmacological activity was detected in various tests with several animal organs.     

原生质体融合构建葡萄酒降酸酵母的研究

对葡萄酒酵母1450(Chxs、Ampr)和酒酒球菌SD-2a(Chxr、Amps)的原生质体制备方法进行了研究,并采用PEG和Ca2 促融的方法进行了两菌株的跨界原生质体融合。利用放线菌酮 氨苄青霉素对融合子进行初筛,再经发酵试验复筛,从117株融合子中筛选出1株在酒精发酵的同时降解苹果酸能力强的融合子F-20,在连续传代10次后,其遗传性状稳定。融合子F-20的酒精发酵能力接近葡萄酒酵母1450,同时能够降解66%左右的苹果酸。     

Construction of a Stable α-Galactosidase-Producing Baker's Yeast Strain

Molasses is widely used as a substrate for commercial yeast production. The complete hydrolysis of raffinose, which is present in beet molasses, by Saccharomyces strains requires the secretion of α-galactosidase, in addition to the secretion of invertase. Raffinose is not completely utilized by commercially available yeast strains used for baking, which are Mel⁻. In this study we integrated the yeast MEL1 gene, which codes for α-galactosidase, into a commercial mel⁰ baker's yeast strain. The Mel⁺ phenotype of the new strain was stable. The MEL1 gene was expressed when the new Mel⁺ baker's yeast was grown in molasses medium under conditions similar to those used for baker's yeast production at commercial factories. The α-galactosidase produced by this novel baker's yeast strain hydrolyzed all the melibiose that normally accumulates in the growth medium. As a consequence, additional carbohydrate was available to the yeasts for growth. The new strain also produced considerably more α-galactosidase than did a wild-type Mel⁺ strain and may prove useful for commercial production of α-galactosidase.     

Determination of Growth and Glycerol Production Kinetics of a Wine Yeast Strain Saccharomyces cerevisiae Kalecik 1 in Different Substrate Media

Summary Glycerol has been known as an important by-product of wine fermentations improving the sensory quality of wine. This study was carried out with an endogenic wine yeast strain Saccharomyces cerevisiae Kalecik 1. The kinetics of growth and glycerol biosynthesis were analysed at various initial concentrations of glucose, fructose, and sucrose in a batch system. Depending on the determined values of Monod constants, glucose (K_s = 28.09 g/l) was found as the most suitable substrate for the yeast growth. Initial glucose, fructose and sucrose concentrations necessary for maximum specific yeast growth rate were determined as 175 g, 100 l, and 200 g/l, respectively. The yeast produced glycerol at very high concentrations in fructose medium. Fructose was determined as the most suitable substrate for glycerol production while the strain showed low tendency to use it for growth. S. cerevisiae Kalecik 1 could not produce glycerol below 200 g/l initial sucrose concentration. When natural white grape juice was used as fermentation medium, maximum glycerol concentration and dry weight of the yeast were determined as 9.3 g/l and 11.8 g/l, respectively.     

Yeast Diversity and Persistence in Botrytis-Affected Wine Fermentations

Culture-dependent and -independent methods were used to examine the yeast diversity present in botrytis-affected (“botrytized”) wine fermentations carried out at high (~30°C) and ambient (~20°C) temperatures. Fermentations at both temperatures possessed similar populations of Saccharomyces, Hanseniaspora, Pichia, Metschnikowia, Kluyveromyces, and Candida species. However, higher populations of non-Saccharomyces yeasts persisted in ambient-temperature fermentations, with Candida and, to a lesser extent, Kluyveromyces species remaining long after the fermentation was dominated by Saccharomyces. In general, denaturing gradient gel electrophoresis profiles of yeast ribosomal DNA or rRNA amplified from the fermentation samples correlated well with the plating data. The direct molecular methods also revealed a Hanseniaspora osmophila population not identified in the plating analysis. rRNA analysis also indicated a large population (>10⁶ cells per ml) of a nonculturable Candida strain in the high-temperature fermentation. Monoculture analysis of the Candida isolate indicated an extreme fructophilic phenotype and correlated with an increased glucose/fructose ratio in fermentations containing higher populations of Candida. Analysis of wine fermentation microbial ecology by using both culture-dependent and -independent methods reveals the complexity of yeast interactions enriched during spontaneous fermentations.     

Sugar and Alcohol Stabilization of Yeast in Sweet Wine

Secondary fermentation of sweet wine was prevented by the Delle stabilization procedure. For this procedure, advantage is taken of the inhibitory effects of high concentrations of sugar as well as of alcohol. Thus, relatively small amounts of wine spirits were added to fermenting musts to obtain stability, as compared to the conventional procedure in which larger amounts of alcohol are added and the inhibitory effect of alcohol only is considered. The Delle value is a function of the concentrations in the wine, after spirits addition, of alcohol and sugar. Delle values which gave stable wine were dependent on time of alcohol addition, on strain of wine yeast, and on composition of wine spirits. Fractional addition of spirits, concentration of SO(2), and clarity of must had little effect on the Delle value. Sensory comparison of wines especially prepared for tasting by the Delle procedure and by the conventional procedure showed the wines made by the Delle procedure to be superior in quality. Under proper storage conditions, the Delle wines were shown to be microbiologically stable and resistant to wine spoilage organisms.