Use of high-ethanol-resistant yeast isolates from Nigerian palm wine in lager beer brewing

High-ethanol-resistant yeasts, characterized as Saccharomyces sp., were isolated from Nigerian palm wine with added sucrose for high gravity brewing. The yeast isolates that survived the highest ethanol production were used to ferment brewery wort and produced 8.2 to 8.5% (v/v) ethanol; values almost double that of the control yeast from a local brewery.     

Dynamic genome-scale modeling of Saccharomyces cerevisiae unravels mechanisms for ester formation during alcoholic fermentation

Fermentation employing Saccharomyces cerevisiae has produced alcoholic beverages and bread for millennia. More recently, S. cerevisiae has been used to manufacture specific metabolites for the food, pharmaceutical, and cosmetic industries. Among the most important of these metabolites are compounds associated with desirable aromas and flavors, including higher alcohols and esters. Although the physiology of yeast has been well-studied, its metabolic modulation leading to aroma production in relevant industrial scenarios such as winemaking is still unclear. Here we ask what are the underlying metabolic mechanisms that explain the conserved and varying behavior of different yeasts regarding aroma formation under enological conditions? We employed dynamic flux balance analysis (dFBA) to answer this key question using the latest genome-scale metabolic model (GEM) of S. cerevisiae. The model revealed several conserved mechanisms among wine yeasts, for example, acetate ester formation is dependent on intracellular metabolic acetyl-CoA/CoA levels, and the formation of ethyl esters facilitates the removal of toxic fatty acids from cells using CoA. Species-specific mechanisms were also found, such as a preference for the shikimate pathway leading to more 2-phenylethanol production in the Opale strain as well as strain behavior varying notably during the carbohydrate accumulation phase and carbohydrate accumulation inducing redox restrictions during a later cell growth phase for strain Uvaferm. In conclusion, our new metabolic model of yeast under enological conditions revealed key metabolic mechanisms in wine yeasts, which will aid future research strategies to optimize their behavior in industrial settings.     

定点突变提高解淀粉芽孢杆菌JP-21脲酶应用特性

氨基甲酸乙酯(Ethylcarbamate,EC)是一种存在于发酵食品和酒精饮料中的可致癌物,过量摄入可能会影响人体健康。酶法降解是减少发酵食品中氨基甲酸乙酯及其前体尿素含量的有效方法之一。脲酶具有氨基甲酸乙酯水解酶和尿素酶两种活性,因此在减少发酵食品中氨基甲酸乙酯及其前体尿素方面具有良好的应用前景。目前脲酶降解发酵酒精饮料中氨基甲酸乙酯面临的主要问题是脲酶对氨基甲酸乙酯的催化活性及亲和力较低,因而其降解效果不理想。文中成功在大肠杆菌Escherichia coli中表达了来源于解淀粉芽孢杆菌Bacillus amyloliquefaciens JP-21的脲酶,表达水平为尿素酶3 291.74 U/L,氨基甲酸乙酯水解酶227.26 U/L。通过模拟脲酶中催化亚基UreC与氨基甲酸乙酯对接的结构,确定了M326和M374这两个影响酶与底物结合的位点。采用点饱和突变获得了3株氨基甲酸乙酯水解酶活性提高的突变体M374A、M374T和M326V,以EC为底物时的Km分别为101.84mmol/L、129.49 mmol/L和121.67 mmol/L,比野生型分别降低了37.47%–50.82%。突变体可以降解黄酒中97%的尿素,M374T对黄酒中EC的降解效果最好,可将黄酒中EC从513.90μg/L降至393.57μg/L,降解率是野生脲酶的1.97倍。研究结果对今后改造脲酶催化特性和改善其应用特性具有重要意义,可为开发减控发酵食品中的微生物代谢氨(胺)类危害物策略提供参考。     

赤霞珠葡萄果实苹果酸生物合成关键转录因子的筛选与鉴定

该研究以宁夏贺兰山东麓酿酒葡萄种植区栽培面积最大的‘赤霞珠’为材料,在前期完成从果实形成至成熟不同发育时期的转录组测序以及关键有机酸含量测定基础上,进一步通过转录因子结合位点预测、差异表达基因分析、加权基因共表达网络关联分析(WGCNA),逐步筛选出与‘赤霞珠’果实苹果酸生物合成相关功能基因特异结合的、影响苹果酸生物合成的相应转录因子,并对其进行qRT PCR验证,以揭示这些关键功能基因及其关键转录因子在葡萄不同种植区、果实不同发育时期存在的相互调控作用机制,为以后培育优质酿酒葡萄提供新的理论依据与思路。结果表明：(1)GC/MS分析发现, ‘赤霞珠’果实在4个发育时期的延胡索酸和苹果酸含量变化趋势基本一致,两种酸含量均从果实硬果期到绿果期逐步升至最高(3.63和626.53 μg/g),之后缓慢下降,经转色期到成熟期后逐渐降至最低(2.14和244.26 μg/g),而草酰乙酸的变化趋势却相反,在硬果期含量最高(315.54 μg/g),经绿果期、转色期到成熟期逐渐降至最低值(126.11 μg/g)。(2)‘赤霞珠’果实发育时期样本转录组测序共获得可能与苹果酸生物合成途径12种功能基因结合的转录因子6 411个,其中延胡索酸水化酶(FH)的3个功能基因有86个转录因子,苹果酸脱氢酶(MDH)的10个功能基因有717个转录因子。(3)转录组测序数据及其与有机酸含量WGCNA关联结果的Veen分析确定了‘赤霞珠’果实成熟过程中与苹果酸生物合成相关度最高的3个FH基因(VIT_14s0060g01700、VIT_13s0019g03330、VIT_07s0005g00880)、2个MDH基因(VIT_10s0003g01000、VIT_13s0019g05250)及相应的18个关键转录因子。(4)qRT PCR验证及相关性分析表明, FH基因VIT_13s0019g03330与其转录因子VIT_01s0011g06200、VIT_08s0056g01230以及MDH基因VIT_13s0019g05250与其转录因子VIT_06s0004g04960、VIT_10s0003g02070的表达水平与苹果酸的积累存在显著正相关关系,推测这4个关键转录因子可能通过调控功能基因的转录,综合影响‘赤霞珠’果实苹果酸的生物合成。     

优良菌种发酵葡萄酒优化条件的探讨

以诱变耐低温果酒酵母菌种YU2.28和产香酵母S15.3为发酵菌株,进行了葡萄酒发酵条件优化的试验研究.探讨了菌种生长温度、通氧量等因素,通过对菌种的生长情况和发酵醪液中总酯含量的变化分析,确定了自选酵母酿制葡萄酒的最佳技术参数,并对优化条件下发酵得到的葡萄酒进行GC/MS分析.结果显示：YU2.28和S15.3以1：3比例的混合发酵,接种量3%,调节醪液pH值为4.0,SO2添加量40 mg/L,发酵温度20℃,主发酵6 d内控制以230r/min的摇床转速进行摇瓶发酵,并进行9 h（每天1.5 h）供氧处理,后发酵30 d,酿造出的葡萄酒品质较佳,具有酒体丰盈,酒液澄清透亮,香气醇和的特征.成品酒香气成分共检测出醇类9种,酯类8种,酸类6种和少量的醛类、酮类等成分.     

Mass spectrometry in the analysis of grape and wine proteins

Wine proteins play an important role in the quality of wine, because they affect taste, clarity and stability of product. The majority of wine proteins are in the range of 20–30 kDa. Different mass spectrometry (MS) techniques have been successfully applied to study the grape and wine proteins. By liquid chromatography (LC) electrospray ionization (ESI) MS and nano-LC/MS, nine dipeptides and 80 peptides were unambiguously identified in Champagne and Sauvignon Blanc wines, respectively. Using matrix-assisted laser desorption/ionization (MALDI) time-of-flight (TOF) and surface-enhanced laser desorption/ionization TOF, the protein and peptide fingerprints in Chardonnay, Sauvignon Blanc and Muscat of Alexandria wines were determined. MALDI-TOF identified the mesocarp proteome of six Vitis grape varieties. Proteins in different grape tissue extracts were also studied. The major grape pathogenic-related proteins are chitinases and thaumatin-like proteins, which both persist through the vinification process and cause hazes and sediments in bottled wines. ESI-MS, LC/ESI-MS and MALDI-TOF analysis of these proteins in grape and wine were also used to characterize different grape varieties.     

Immobilization of Oenococcus oeni in lentikats® to develop malolactic fermentation in wines

Entrapment of Oenococcus oeni into a polymeric matrix based on polyvinyl alcohol (PVA) (Lentikats®) was successfully used to get a better development of malolactic fermentation (MLF) in wine. The incubation of immobilized cells in a nutrient medium before starting the MLF, did not improve the degradation of malic acid. In only one day, 100% of conversion of malic acid was achieved using a high concentration of immobilized cells (0.35 g gel/ml of wine with a cell‐loading of 0.25 mg cells/mg of gel). While a low concentration of 0.21 g gel/ml of wine (cell‐loading of 0.25 mg cells/mg of gel) needed 3 days to get a reduction of 40%. The entrapped cells could be reused through six cycles (runs of 3 days), retaining 75% of efficacy for the conversion of malic acid into lactic acid. The immobilized cells in PVA hydrogels gave better performance than free cells because of the increase of the alcohol toleration. Consequently, the inhibitory effect of ethanol for developing MLF could be reduced using immobilized cells into PVA hydrogels. © 2012 American Institute of Chemical Engineers Biotechnol. Prog., 2013     

Genetic diversity of Dekkera bruxellensis yeasts isolated from Australian wineries

Yeasts of the genus Dekkera and its anamorph Brettanomyces represent a significant spoilage issue for the global wine industry. Despite this, there is limited knowledge of genetic diversity and strain distribution within wine and winery-related environments. In this study, amplified fragment length polymorphism (AFLP) analysis was conducted on 244 Dekkera bruxellensis isolates from red wine made in 31 winemaking regions of Australia. The results indicated there were eight genotypes among the isolates, and three of these were commonly found across multiple winemaking regions. Analysis of 26S rRNA gene sequences provided further evidence of three common, conserved groups, whereas a phylogeny based upon the AFLP data demonstrated that the most common D. bruxellensis genotype (I) in Australian red wine was highly divergent from the D. bruxellensis type strain (CBS 74).