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低温锻炼技术被广泛地应用到实际活性干酵母的活化过程中,该文以普通酿酒酵母和经低温锻炼的酿酒酵母BH8为实验材料分别对葡萄汁进行发酵实验。实验结果表明,在13 ℃的低温发酵条件下,经过低温锻炼的酿酒酵母与对照相比发酵时间缩短2 d,发酵效率提高了7.41%;最大活菌数增加了8.33%;残糖量降低了16.28%;乙醇含量增加了4.04%;乙酸含量降低了6.70%。然而其甘油、海藻糖和琥珀酸的含量却低于对照组,这很可能是由于酿酒酵母在低温锻炼过程中已经产生了抗低温胁迫的原因。 相似文献
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MIGUEL de BARROS LOPES ATA -ur-REHMAN HOLGER GOCKOWIAK ANTHONY J. HEINRICH PETER LANGRIDGE PAUL A. HENSCHKE 《Australian Journal of Grape and Wine Research》2000,6(3):208-215
Wine yeasts efficiently convert sugar into ethanol. The possibility of diverting some of the sugar into compounds other than ethanol by using molecular genetic methods was tested. Over-expression of the yeast glycerol 3-phosphate dehydrogenase gene ( GPD2 ) in a laboratory strain of Saccharomyces cerevisiae led to an approximate two-fold increase in the extracellular glycerol concentration. In the medium fermented with the modified strain, acetic acid concentration also increased approximately two-fold when respiration was blocked. A strain deleted for the GPD2 gene had the opposite phenotype, producing lower amounts of glycerol and acetic acid, with the latter compound only reduced during non-respiratory growth. A commercial wine yeast over-expressing GPD2 produced 16.5 g/L glycerol in a wine fermentation, compared to 7.9 g/L obtained with the parent strain. As seen for the laboratory strain, acetic acid concentrations were also increased when using the genetically modified wine yeast. A panel of wine judges confirmed the increase in volatile acidity of these wines. The altered glycerol biosynthetic pathway sequestered carbon from glycolysis and reduced the production of ethanol by 6 g/L. 相似文献
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Raspberry wine fermentation with suspended and immobilized yeast cells of two strains of Saccharomyces cerevisiae 下载免费PDF全文
Radovan Djordjević Brian Gibson Mari Sandell Gustavo M. de Billerbeck Branko Bugarski Ida leskošek‐Čukalović Jovana Vunduk Ninoslav Nikićević Viktor Nedović 《Yeast (Chichester, England)》2015,32(1):271-279
The objectives of this study were to assess the differences in fermentative behaviour of two different strains of Saccharomyces cerevisiae (EC1118 and RC212) and to determine the differences in composition and sensory properties of raspberry wines fermented with immobilized and suspended yeast cells of both strains at 15 °C. Analyses of aroma compounds, glycerol, acetic acid and ethanol, as well as the kinetics of fermentation and a sensory evaluation of the wines, were performed. All fermentations with immobilized yeast cells had a shorter lag phase and faster utilization of sugars and ethanol production than those fermented with suspended cells. Slower fermentation kinetics were observed in all the samples that were fermented with strain RC212 (suspended and immobilized) than in samples fermented with strain EC1118. Significantly higher amounts of acetic acid were detected in all samples fermented with strain RC212 than in those fermented with strain EC1118 (0.282 and 0.602 g/l, respectively). Slightly higher amounts of glycerol were observed in samples fermented with strain EC1118 than in those fermented with strain RC212. Copyright © 2014 John Wiley & Sons, Ltd. 相似文献
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利用耐高渗透压酵母以糖蜜为原料生产甘油 总被引:2,自引:0,他引:2
通过一般发酵法得到的乙醇产品在发酵醪中大致产生 13g/L甘油。这个产量不适宜开发利用 ,利用耐高渗透压酵母 (Hollandia、Fleischmann)通过调整发酵条件例如渗透压 (水的活度 )、pH、温度、酵母接种量生成甘油。结果表明 ,在发酵条件为 3 9 9°bx、pH8 7、3 8℃、接种量 12 0× 10 6 个 /mL ,甘油产量可提高到 5 6g/L。此技术的应用会给发酵法生产乙醇的工厂带来巨大的经济效益 相似文献
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Effects of altering fermentation parameters on glycerol and bioethanol production from cane molasses
Cate N Munene Willem H Kampen Henry Njapau 《Journal of the science of food and agriculture》2002,82(3):309-314
Current bioethanol production processes do not produce more than approximately 13 g l?1 glycerol at a purity of 11% total solids in the fermented mash. Such quantities are not sufficiently high for economic exploitation unless very‐large‐capacity plants are involved. It was envisaged that the ratio of glycerol to bioethanol could be altered in favour of glycerol by adjusting such fermentation parameters as osmotic pressure (water activity), pH, temperature and yeast cell inoculum. At 39.9 ° brix, pH 8.7, 38 °C, 90.7 atm and 120 × 106 yeast cells ml?1, glycerol formation in fermented mash increased to 56 g l?1 at a purity of 14% total solids. The potential for high glycerol production, hence higher revenue, has been demonstrated. Adoption of this technology could have a significant positive economic impact on existing or new biomass‐to‐ethanol plants. © 2002 Society of Chemical Industry 相似文献
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Eglinton JM Heinrich AJ Pollnitz AP Langridge P Henschke PA de Barros Lopes M 《Yeast (Chichester, England)》2002,19(4):295-301
Glycerol is a major fermentation product of Saccharomyces cerevisiae that contributes to the sensory character of wine. Diverting sugar to glycerol overproduction and away from ethanol production by overexpressing the glycerol 3-phosphate dehydrogenase gene,GPD2, caused S. cerevisiae to produce more than twice as much acetic acid as the wild-type strain (S288C background) in anaerobic cell culture. Deletion of the aldehyde dehydrogenase gene, ALD6, in wild-type and GPD2 overexpressing strains (GPD2-OP) decreased acetic acid production by three- and four-fold, respectively. In conjunction with reduced acetic acid production, the GPD2-OP ald6Delta strain produced more glycerol and less ethanol than the wild-type. The growth rate and fermentation rate were similar for the modified and wild-type strains, although the fermentation rate for the GPD2 ald6Delta strain was slightly less than that of the other strains from 24h onwards. Analysis of the metabolome of the mutants revealed that genetic modification affected the production of some secondary metabolites of fermentation, including acids, esters, aldehydes and higher alcohols, many of which are flavour-active in wine. Modification of GPD2 and ALD6 expression represents an effective strategy to increase the glycerol and decrease the ethanol concentration during fermentation, and alters the chemical composition of the medium such that, potentially, novel flavour diversity is possible. The implications for the use of these modifications in commercial wine production require further investigation in wine yeast strains. 相似文献
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A gut2 mutant of Saccharomyces cerevisiae is deficient in the mitochondrial glycerol 3-phosphate dehydrogenase and hence cannot utilize glycerol. Upon transformation of a gut2 mutant strain with a low-copy yeast genomic library, hybrid plasmids were isolated which complemented the gut2 mutation. The nucleotide sequence of a 3·2 kb PstI-XhoI fragment complementing a gut2 mutant strain is presented. The fragment reveals an open reading frame (ORF) encoding a polypeptide with a predicted molecular weight of 68·8 kDa. Disruption of the ORF leads to a glycerol non-utilizing phenotype. A putative flavin-binding domain, located at the amino terminus, was identified by comparison with the amino acid sequences of other flavoproteins. The cloned gene has been mapped both physically and genetically to the left arm of chromosome IX, where the original gut2 mutation also maps. We conclude that the presented ORF is the GUT2 gene and propose that it is the structural gene for the mitochondrial glycerol 3-phosphate dehydrogenase. 相似文献
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A general procedure is described for determining the chromosomal constitution of industrial strains of Saccharomyces cerevisiae based on analysis of segregation frequencies for input markers among random spore progeny of industrial-laboratory strain hybrids. The multiply auxotrophic haploid testers used carried a dominant erythromycin-resistance marker, allowing hybrids to be selected in mass matings with spores produced by the wild-type industrial strains. Analysis of a number of independent crosses between the haploid testers and an unselected population of spores of each wine strain distinguished between disomic, trisomic and tetrasomic chromosomal complements in the parents. Possible explanations for a significant class of aberrant segregation frequencies are discussed. Results of the analysis indicate that UCD Enology 522 (Montrachet) is diploid and possibly trisomic for chromosome VII; 522X is diploid; UCD Enology 505 (California Champagne) is disomic for chromosome XVI, trisomic for chromosomes I, II, III, VI, VIII, IX, X, XII, XV, tetrasomic for chromosomes IV, XI, XIII, XIV and either trisomic or tetrasomic for chromosomes V and VII; and that UCD Enology 595 (Pasteur Champagne) is disomic for chromosomes I, II, III, IX, XVI, trisomic for chromosomes IV, VI, X, XII, XIV, XV, tetrasomic for chromosomes V, VIII, XI, XIII and either disomic or tetrasomic for chromosome VII. 相似文献
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Malo-ethanolic fermentation in grape must by recombinant strains of Saccharomyces cerevisiae. 总被引:1,自引:0,他引:1
H Volschenk M Viljoen-Bloom R E Subden H J van Vuuren 《Yeast (Chichester, England)》2001,18(10):963-970
Recombinant strains of Saccharomyces cerevisiae with the ability to reduce wine acidity could have a significant influence on the future production of quality wines, especially in cool climate regions. L-Malic acid and L-tartaric acid contribute largely to the acid content of grapes and wine. The wine yeast S. cerevisiae is unable to effectively degrade L-malic acid, whereas the fission yeast Schizosaccharomyces pombe efficiently degrades high concentrations of L-malic acid by means of a malo-ethanolic fermentation. However, strains of Sz. pombe are not suitable for vinification due to the production of undesirable off-flavours. Heterologous expression of the Sz. pombe malate permease (mae1) and malic enzyme (mae2) genes on plasmids in S. cerevisiae resulted in a recombinant strain of S. cerevisiae that efficiently degraded up to 8 g/l L-malic acid in synthetic grape must and 6.75 g/l L-malic acid in Chardonnay grape must. Furthermore, a strain of S. cerevisiae containing the mae1 and mae2 genes integrated in the genome efficiently degraded 5 g/l of L-malic acid in synthetic and Chenin Blanc grape musts. Furthermore, the malo-alcoholic strains produced higher levels of ethanol during fermentation, which is important for the production of distilled beverages. 相似文献
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This study investigated the competition and potential hybrid generation between the species Saccharomyces cerevisiae and S. kudriavzevii in a wine-model environment. Our main goal was to understand why S. kudriavzevii has not been found in wine fermentations whilst their hybrids are present. Auxotrophic mutants (Ura(-) and Lys(-)) were used to favour the selection of hybrids and to specifically differentiate the two species in mixed fermentations carried out at different temperatures (17 °C, 24 °C and 31 °C). Both yeasts showed a reduction in their maximum specific growth rates in mixed fermentations, indicating a clear antagonistic effect between the two microorganisms. Temperature played an important role in this competition. In this way, S. kudriavzevii was less affected at 17 °C, but S. cerevisiae was clearly the best competitor at 31 °C, preventing the growth of S. kudriavzevii. Population levels of S. kudriavzevii always significantly decreased in the presence of S. cerevisiae. Ethanol was measured throughout the fermentations and in all cases S. kudriavzevii growth was arrested when ethanol levels were < 5 g/l, indicating that this compound did not influence the competitive exclusion of S. kudriavzevii. Killer factors were also discarded due to the K(-) R(-) phenotype of both strains. Finally, no prototrophic interspecific hybrids were isolated in small-scale fermentations at any temperature assayed. Our results show that the lack of competitiveness exhibited by S. kudriavzevii, especially at high temperatures, explains the absence of this species in wine fermentations, suggesting that natural S. cerevisiae × S. kudriavzevii hybrids most likely originated in wild environments rather than in industrial fermentations. 相似文献
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为提高酿酒酵母的甘油产量,分别考察不同初始葡萄糖和果糖质量浓度、pH值、发酵温度及SO2添加量对酿酒酵母D254甘油产量的影响。对酿酒酵母D254不同发酵初始条件进行单因素试验,其他因素固定条件下,葡萄糖质量浓度180g/L时酵母菌体生长平稳、生长量最高;果糖质量浓度108g/L时酵母甘油产量最高;pH值为3.5更适宜酵母菌体生长和合成甘油;在发酵温度和SO2添加量的单因素试验中也分别得出适宜发酵温度为28℃和适宜SO2添加量为 20mg/L。通过单因素试验,筛选出最利于酿酒酵母D254生长和产甘油的各因素的最佳质量浓度,进行Plackett-Burman发酵条件组合试验,得到发酵条件最佳组合为:初始葡萄糖质量浓度216g/L、果糖质量浓度144g/L、发酵温度32℃、pH 3.0、SO2添加量40mg/L,此条件下,酿酒酵母D254获得最高甘油产量达655.64μmol/L。 相似文献
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This investigation deals with factors affecting the production of glycerol in Saccharomyces cerevisiae. In particular, the impact of reduced pyruvate-decarboxylase (PDC) and increased NAD-dependent glycerol-3-phosphate dehydrogenase (GPD) levels was studied. The glycerol yield was 4·7 times (a pdc mutant exhibiting 19% of normal PDC activity) and 6·5 times (a strain exhibiting 20-fold increased GPD activity resulting from overexpression of GPD1 gene) that of the wild type. In the strain carrying both enzyme activity alterations, the glycerol yield was 8·1 times higher than that of the wild type. In all cases, the substantial increase in glycerol yield was associated with a reduction in ethanol yield and a higher by-product formation. The rate of glycerol formation in the pdc mutant was, due to a slower rate of glucose catabolism, only twice that of the wild type, and was increased by GPD1 overexpression to three times that of the wild-type level. Overexpression of GPD1 in the wild-type background, however, led to a six- to seven-fold increase in the rate of glycerol formation. The experimental work clearly demonstrates the rate-limiting role of GPD in glycerol formation in S. cerevisiae. 相似文献
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以青蒿酸产量为考察指标,在50 L发酵罐中对酿酒酵母(Saccharomyces cerevisiae)工程菌1211发酵产青蒿酸的溶氧参数进行优化。在此基础上,根据Logistic方程及Luedeking-Piret方程构建酿酒酵母工程菌1211分批发酵产青蒿酸的动力学模型。结果表明,当溶氧参数为25%~30%时,青蒿酸产量最高,为(6 269.6±100.3)mg/L。青蒿酸合成与菌体生长呈现部分生长偶联型。通过Origin 9.0软件对动力学模型进行非线性拟合,发现S. cerevisiae工程菌1211的菌体繁殖生长、青蒿酸合成以及基质消耗动力学模型的拟合度R2分别达到了0.995 85、0.979 04和0.995 48,该动力学模型能够很好的描述S. cerevisiae工程菌1211分批发酵过程。该研究为青蒿酸的低成本发酵及工业化大规模发酵生产提供了理论基础。 相似文献
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Screening of the homozygous diploid yeast deletion pool of 4741 non-essential genes identified two null mutants (Deltaura7 and Deltagal6) that grew faster than the wild-type strain in medium containing 8% v/v ethanol. The survival rate of the gal6 disruptant in 10% ethanol was higher than that of the wild-type strain. On the other hand, the glucose consumption rate of the ura7 disruptant was better than that of the wild-type strain in buffer containing ethanol. Both disruptants were more resistant to zymolyase, a yeast lytic enzyme containing mainly beta-1,3-glucanase, indicating that the integrity of the cell wall became more resistance to ethanol stress. The gal6 disruptant was also more resistant to Calcofluor white, but the ura7 disruptant was more sensitive to Calcofluor white than the wild-type strain. Furthermore, the mutant strains had a higher content of oleic acid (C18 : 1) in the presence of ethanol compared to the wild-type strain, suggesting that the disruptants cope with ethanol stress not only by modifying the cell wall integrity but also the membrane fluidity. When the cells were grown in medium containing 5% ethanol at 15 degrees C, the gal6 and ura7 disruptants showed 40% and 14% increases in the glucose consumption rate, respectively. 相似文献