Evaluation of the potential of commercial non-Saccharomyces yeast strains of Torulaspora delbrueckii and Lachancea thermotolerans in beer fermentation

This work evaluated the potential of three commercial non-Saccharomyces yeast strains Torulaspora delbrueckii (Biodiva and Prelude) and Lachancea thermotolerans (Concerto) for beer fermentation. The fermentation performance, volatile and non-volatile profiles were compared. Growth behaviours of all three yeast strains exhibited similar trends during the initial fermentation phase although a marked population decline was detected in strains Prelude and Concerto, which also showed a rapid utilisation of maltose, while strain Biodiva was unable to consume maltose and consumed lesser amounts of amino acids. Additionally, terpenoids inherently absent in the wort such as β-caryophyllene and geranyl acetone were produced in all beers, significantly higher in beers fermented with strain Prelude. For volatile profiles, Prelude and Concerto produced more ethanol and significantly higher amounts of acetate esters and long-chained ethyl esters. Strain Biodiva, on the other hand, produced higher amounts of isoamyl alcohol and ethyl butanoate.     

Altered Patterns of Maltose and Glucose Fermentation by Brewing and Wine Yeasts Influenced by the Complexity of Nitrogen Source

Maltose and glucose fermentations by industrial brewing and wine yeasts strains were strongly affected by the structural complexity of the nitrogen source. In this study, four Saccharomyces cerevisiae strains, two brewing and two wine yeasts, were grown in a medium containing maltose or glucose supplemented with a nitrogen source varying from a single ammonium salt (ammonium sulfate) to free amino acids (casamino acids) and peptides (peptone). Diauxie was observed at low sugar concentration for brewing and wine strains, independent of nitrogen supplementation, and the type of sugar. At high sugar concentrations altered patterns of sugar fermentation were observed, and biomass accumulation and ethanol production depended on the nature of the nitrogen source and were different for brewing and wine strains. In maltose, high biomass production was observed under peptone and casamino acids for the brewing and wine strains, however efficient maltose utilization and high ethanol production was only observed in the presence of casamino acids for one brewing and one wine strain studied. Conversely, peptone and casamino acids induced higher biomass and ethanol production for the two other brewing and wine strains studied. With glucose, in general, peptone induced higher fermentation performance for all strains, and one brewing and wine strain produced the same amount of ethanol with peptone and casamino acids supplementation. Ammonium salts always induced poor yeast performance. The results described in this paper suggest that the complex nitrogen composition of the cultivation medium may create conditions resembling those responsible for inducing sluggish/stuck fermentation, and indicate that the kind and concentration of sugar, the complexity of nitrogen source and the yeast genetic background influence optimal industrial yeast fermentation performance.     

Influence of fermentation temperature on volatile thiols concentrations in Sauvignon blanc wines

The effect of Saccharomyces cerevisiae strains on the amount of 4-mercapto-4-methylpentan-2-one, a major varietal aroma of Sauvignon blanc wines, was demonstrated by previous research work. However, the influence of different alcoholic fermentation parameters on the levels of volatile thiols (4-mercapto-4-methylpentan-2-one, 3-mercaptohexan-1-ol and 3-mercaptohexyl acetate) in wines has not yet been investigated. The impact of fermentation temperature on the final amount of volatiles thiols and on some other analytical parameters (ethanol, total acidity, residual sugars, volatile acidity) was determined in a model medium and in grape juice. Interaction between fermentation temperature and yeast strain was also tested. The fermentation temperature influenced the amount of volatile thiols irrespective of the yeast strain used. The final levels of 4MMP and 3MH in model medium and in wines were higher when the alcoholic fermentation is conducted at 20 degrees C than at 13 degrees C. The 3MHA, which was correlated with the amount of 3MH determined in wines, was also higher when the alcoholic fermentation was conducted at 20 degrees C. From a technological point of view, the choice of yeast strain and fermentation temperature has a decisive influence on the concentrations of the varietal aromas of Sauvignon blanc wines.     

Influence of addition of insoluble solids,different yeast strains and pectinesterase enzyme on the quality of apple wine

Rate of fermentation and physico‐chemical characteristics of apple wines, owing to the addition of different yeast strains, insoluble solids and pectinesterase enzyme, were examined. The highest rates of fermentation and ethanol production were found in the wine fermented by yeast strain UCD 505, while strain UCD 595 gave the smallest amount of methanol. The addition of insoluble solids to the apple juice significantly increased the levels of methanol, vitamin C, amyl alcohol, total volatiles, rate of fermentation, tannins, colour units, Mn and Zn. Addition of insoluble solids decreased pH, titrable acidity, ethanol, total sugars, total esters, and K, Mg, Ca, Cu and Fe content of the wine. Addition of pectinesterase enzyme significantly increased all the parameters examined except for pH, vitamin C, total esters, Mn and Mg content. Application of cluster analysis to the results of rate of fermentation, reducing sugars, volatile acidity and ethanol showed that the influence of the yeast strains was more than the influence of insoluble solids or pectinesterase enzyme addition. Consideration of more parameters showed that there was a clear interaction between the yeast strain, insoluble solids and the pectinesterase enzyme. Addition of insoluble solids to the must led to the production of some undesirable quality characteristics. In contrast, specific yeast strains and enzyme addition improved various physico‐chemical characteristics of the wine. Pre‐settled or clarified juice was preferred to produce a quality apple wine. Copyright © 2013 The Institute of Brewing & Distilling     

Fermentation properties of a wine yeast over-expressing the Saccharomyces cerevisiae glycerol 3-phosphate dehydrogenase gene (GPD2)

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.     

Effect of Sugar Catabolite Repression in Correlation with the Structural Complexity of the Nitrogen Source on Yeast Growth and Fermentation

Biomass and ethanol production by industrial Saccharomyces cerevisiae strains were strongly affected by the structural complexity of the nitrogen source during fermentation in media containing galactose, and supplemented with a nitrogen source varying from a single ammonium salt (ammonium sulfate) to free amino acids (casamino acids) and peptides (peptone). Diauxie was observed at low galactose concentrations independent of nitrogen supplementation. At high sugar concentrations altered patterns of galactose utilisation were observed. Biomass accumulation and ethanol production depended on the nature of the nitrogen source and were different for baking and brewing ale and lager strains. Baking yeast showed improved galactose fermentation performance in the medium supplemented with casamino acids. High biomass production was observed with peptone and casamino acids for the ale brewing strain, however high ethanol production was observed only in the presence of casamino acids. Conversely, peptone was the nitrogen supplement that induced higher biomass and ethanol production for the lager brewing strain. Ammonium salts always induced poor yeast performance. The results with galactose differed from those obtained with glucose and maltose which indicated that supplementation with a nitrogen source in the peptide form (peptone) was more positive for yeast metabolism, suggesting that sugar catabolite repression has a central role in yeast performance in a medium containing nitrogen sources with differing levels of structural complexity.     

Nitrogen metabolism in chardonnay musts inoculated with killer strains of Saccharomyces cerevisiae

This paper examines the evolution of nitrogen compounds during alcoholic fermentation in chardonnay musts inoculated with killer strains of Saccharomyces cerevisiae (ICV D47 and ICV K1M). The results are compared with those obtained from chardonnay must fermented with indigenous yeasts (control sample). The total quantity of nitrogen assimilated, as well as the kinetics of utilization of ammonium ion and amino acids, was different depending on the yeast responsible for the fermentation. In the must inoculated with strain K1M, the nitrogen compounds were consumed more quickly and in greater quantity than in the must inoculated with strain D47. In the uninoculated must, the ammonium ion was not completely consumed, the consumption of amino acids was scant, the fermentation was slow, and the resulting wine had a high volatile acidity. Independently of the yeast used, in all the samples a preference was observed in the consumption of amino acids found in proteins over the amino acids not found in proteins and proline.     

Impact of mixed Torulaspora delbrueckii-Saccharomyces cerevisiae culture on high-sugar fermentation

Conventional wine yeasts produce high concentrations of volatile acidity, mainly acetic acid, during high-sugar fermentation. This alcoholic fermentation by-product is highly detrimental to wine quality and, in some cases, levels may even exceed legal limits. In this study, a non-conventional species, Torulaspora delbrueckii, was used, in pure cultures and mixed with Saccharomyces cerevisiae yeast, to ferment botrytized musts. Fermentation rate, biomass growth, and the formation of volatile acidity, acetaldehyde, and glycerol were considered. This study demonstrated that T. delbrueckii, often described as a low acetic producer under standard conditions, retained this quality even in a high-sugar medium. Unlike S. cerevisiae, this species did not respond to the hyper-osmotic medium by increasing acetic production as soon as it is inoculated into the must. Nevertheless, this yeast produced low ethanol and biomass yields, and the fermentation was sluggish. As a result, T. delbrueckii fermentations do not reach the required ethanol content (14%vol.), although this species can survive at this concentration. A mixed culture of T. delbrueckii and S. cerevisiae was the best combination for improving the analytical profile of sweet wine, particularly volatile acidity and acetaldehyde production. A mixed T. delbrueckii/S. cerevisiae culture at a 20:1 ratio produced 53% less in volatile acidity and 60% less acetaldehyde than a pure culture of S. cerevisiae. Inoculating S. cerevisiae after 5 days' fermentation by T. delbrueckii had less effect on volatile acidity and acetaldehyde production and resulted in stuck fermentation. These results contribute to a better understanding of the behaviour of non-Saccharomyces and their potential application in wine industry.     

Fermentative capacity of Kluyveromyces marxianus and Saccharomyces cerevisiae after oxidative stress

Volatile compound production during alcoholic fermentation has been studied in the production of many beverages. Temperature, yeast strain, nutrients and pH have been identified as important factors in the production of volatile compounds. In addition, other factors could influence this production during the fermentation process as well. Oxidative stress could occur during yeast biomass production because oxygen is an essential nutrient that is added to the growth medium. The fermentation parameters and the volatile compound production of one Saccharomyces cerevisiae strain (MC4) and two Kluyveromyces marxianus strains (OFF1 and SLP1) were evaluated in relation to fermentation parameters after oxidative stress induced by hydrogen peroxide or menadione. These yeasts were compared with S. cerevisiae W303–1A and showed significant differences in ethanol production, ethanol yield and maximum ethanol production rate. K. marxianus (OFF1) showed better fermentative capacity after oxidative stress. The higher alcohol production decreased after oxidative stress by >35% after 72 h fermentation time, and the amyl alcohol decreased at a higher level (>60%); however, the isobutanol production increased after oxidative stress between 1.5 and 4 times. The yeasts produced significant concentrations of esters however ethyl lactate, ethyl caprylate and the ethyl caproate were not detected in the control fermentation, while in the stress fermentation they accounted for up to 3 mg/L. These results demonstrate that oxidative stress can play an important role in the final aroma profile; but it is necessary to guarantee adequate yeast growth to obtain the volatile compounds desired. Copyright © 2017 The Institute of Brewing & Distilling     

YEAST STRAIN AND KINETIC ASPECTS OF THE FORMATION OF FLAVOUR COMPONENTS IN CIDER

An apple juice was fermented at 8°C using twelve strains of Saccharomyces uvarum. Glucose, fructose, malic and L-lactic acids, isobutanol, 2,3 butanediol, isoamyl alcohol, ethyl acetate and titratable acidity were determined and monitored in the course of fermentation. It was observed that yeast strains differed from one another mainly in fermentation rates. When components were determined in ciders of the same remaining fructose concentration, rather than after the same fermentation time, the only significant effect of the yeast strain was on the amounts of glucose and ethanol in sweeter cider (fructose 34 g/litre), or on the amounts of glucose, acetic acid, isobutanol and amyl alcohols in dryer ciders (fructose 17 g/litre). A sensory analysis showed that standard deviations of concentrations of remaining or formed components in ciders fermented by different yeast strains, was sufficient to be detected by the taste panel. Added glucose in this range of concentration (1.5 g/litre) in cider reduced the perception of sourness while the addition of acetic acid (0.3 g/litre) reduced the perception of the scented flavour. Added Isobutnol (6 mg/litre) reduced the perception of sweetness. No significant effect of added isoamyl alcohol (30 mg/litre) could be detected. Chemical determinations were correlated by means of regression equations derived from earlier work with some organoleptic characteristics. No anticipated effect of the yeast strain could be detected on any studied flavour characteristic. It is concluded that in ciders of the same attenuation, the effect if it does exist, of the S.uvarum strain isolated from ciders, must be low.     

Influence of assimilable nitrogen on volatile acidity production by Saccharomyces cerevisiae during high sugar fermentation

We analyzed the variability of volatile acidity and glycerol production by Saccharomyces cerevisiae on a large sample of high sugar musts. The production of volatile acidity was inversely correlated with the maximum cell population and the assimilable nitrogen concentration. The higher the nitrogen concentration, the less volatile acidity was produced. An approach to minimize volatile acidity production during high sugar fermentations by adjustment of assimilable nitrogen in musts was investigated in terms of both quantity and addition time. It was found that the optimal nitrogen concentration in the must is 190 mgN.l(-1). The best moment for nitrogen addition was at the beginning of fermentation. Addition at the end of the growth phase had less effect on volatile acidity reduction. We suggest that by stimulating cell growth, nitrogen addition provides NADH in the redox-equilibrating process, which in turn reduces volatile acidity formation.     

Effects of spontaneous and inoculated fermentation on the volatile profile of lychee (Litchi chinensis Sonn) fermented beverages

The aim of this study was to evaluate the contribution of yeast to the volatile profile of beverages obtained by the fermentation of lychee must through inoculated (Saccharomyces cerevisiae strains UFLA CA116 , UFLA CA1183 and UFLA CA1174 ) and spontaneous fermentation. Higher alcohols and esters were the primary volatiles detected by SPME/GC–MS. A Principal Component Analysis indicated similarities between UFLA CA116 and UFLA CA1183 and between UFLA CA1174 and spontaneous fermentation. Changing the yeast strain used in the fermentation process has the potential to modulate the volatile profile of fermented beverages. The beverage produced by the inoculation of yeast CA1183 showed the most complex aroma profile compared to the other beverages.     

Sucrose Fermentation by Brazilian Ethanol Production Yeasts in Media Containing Structurally Complex Nitrogen Sources

Four Saccharomyces cerevisiae Brazilian industrial ethanol production strains were grown, under shaken and static conditions, in media containing 22% (w/v) sucrose supplemented with nitrogen sources varying from a single ammonium salt (ammonium sulfate) to free amino acids (casamino acids) and peptides (peptone). Sucrose fermentations by Brazilian industrial ethanol production yeasts strains were strongly affected by both the structural complexity of the nitrogen source and the availability of oxygen. Data suggest that yeast strains vary in their response to the nitrogen source's complex structure and to oxygen availability. In addition, the amount of trehalose produced could be correlated with the fermentation performance of the different yeasts, suggesting that efficient fuel ethanol production depends on finding conditions which are appropriate for a particular strain, considering demand and dependence on available nitrogen sources in the fermentation medium.     

优良本土酿酒酵母的酿酒特性及产香能力初析

酿酒酵母产生的多种挥发性物质影响葡萄酒的香气风格,筛选本土酿酒酵母对改善葡萄酒同质化有积极作用.以13株不同来源的酿酒酵母和1株商业对照为试验菌株,对供试酵母的酒精耐受性、嗜杀性、产硫化氢能力及生长曲线进行了测定.随后在模拟汁中探究酵母的发酵特性,用固相微萃取-气相色谱/质谱(solid-phase microextr...     

The effects of copper and high sugar concentrations on growth, fermentation efficiency and volatile acidity production of different commercial wine yeast strains

The effect of high sugar concentrations or the presence of copper residues on fermentation efficiency and volatile acid (VA) production were examined for selected commercial wine yeast strains. Fermentation rate as measured by accumulated mass loss appeared to be least affected by high sugar concentrations during the first few days of fermentation for strains VIN13, WE14, N96 and RJ11. It was, however, only fermentations using VIN13, WE372, N96 and L2056 that contained less than 11 g/L fructose after 21 days. VIN13 and RJ11 produced the lowest VA in the 21^o, 25^o and 28^oBrix musts. Fermentation efficiency of six strains was also studied in must containing 0.25 mM Cu²⁺. Results indicated that strains NT50, Collection Cépage Cabernet (CC) and D80 were not significantly affected, whereas VIN13, NT112 and RJ11 contained significantly more glucose and fructose after fermentation in the must containing copper. Copper addition also increased VA production, with strains RJ11 and NT50 being the most affected.     

Disruption of ubiquitin-related genes in laboratory yeast strains enhances ethanol production during sake brewing

Sake yeast can produce high levels of ethanol in concentrated rice mash. While both sake and laboratory yeast strains belong to the species Saccharomyces cerevisiae, the laboratory strains produce much less ethanol. This disparity in fermentation activity may be due to the strains' different responses to environmental stresses, including ethanol accumulation. To obtain more insight into the stress response of yeast cells under sake brewing conditions, we carried out small-scale sake brewing tests using laboratory yeast strains disrupted in specific stress-related genes. Surprisingly, yeast strains with disrupted ubiquitin-related genes produced more ethanol than the parental strain during sake brewing. The elevated fermentation ability conferred by disruption of the ubiquitin-coding gene UBI4 was confined to laboratory strains, and the ubi4 disruptant of a sake yeast strain did not demonstrate a comparable increase in ethanol production. These findings suggest different roles for ubiquitin in sake and laboratory yeast strains.     

Volatile aroma and sensory analysis of black raspberry wines fermented by different yeast strains

Robus coreanus Miquel is a small berry fruit used for Korean black raspberry (KBR) wine‐making. Twelve different yeast strains were investigated by laboratory‐scale fermentation to develop a wine with a high flavour quality. Volatile aroma compounds from the wines were analysed using headspace–solid phase microextraction–gas chromatography–mass spectrometry and sensory evaluation was performed to evaluate the flavour characteristics. The volatile aroma compounds that mostly contributed to the flavour of KBR wines were those related to fruity (esters) and floral (terpenes) aromas. Fifteen out of the 67 identified volatile compounds showed higher odour activity values than other compounds in the wines, and these compounds were considered as important contributors to the final aromas of the wine. Additionally, the KBR wine fermented by the M1 yeast strain had the highest sensory preference because of higher fruity and floral aroma characters compared with other wines. In addition to the M1 strain, the other yeast strains that produced favourable sensory characteristics included Enoferm CSM, Uvaferm VRB, Lalvin ICV GRE, Lalvin ICV Opale and LevureSeche Active. Of these strains, the M1 strain produced a particularly excellent black raspberry wine, and thus could be applied for further large‐scale production of black raspberry wines. It is also expected that this work will expedite research on the production of high‐quality black raspberry wines with beneficial physicochemical properties, functionality and good sensory characteristics. Copyright © 2015 The Institute of Brewing & Distilling     

混合菌株发酵南瓜汁及其香气分析

本文研究了混合菌株发酵南瓜汁的香气物质。采用固相微萃取技术(SPME)富集、气相色谱-嗅辨-质谱(GC-O-MS)分离检测手段,结合计算机检索技术对分离化合物进行鉴定,应用色谱峰面积归一法测定各成分的相对含量。实验结果表明:新鲜南瓜和南瓜汁中分别分鉴定出58和41个香气化学成分,南瓜汁和新鲜南瓜共有的挥发性成分有19种,南瓜中含量较高的挥发性物质为己醛、3-甲基丁醛、壬醛、戊醛、庚醛、环丁醇等物质。经过乳酸菌、酵母菌和二者混合发酵南瓜汁后挥发性成分分别鉴定出51、36和45种。通过乳酸菌和酵母菌混合发酵的南瓜汁的挥发性成分主要是乙醇、异戊醇、辛酸乙酯、1-庚醇、2,3-丁二酮和异丁醇。与乳酸菌和酵母菌单独发酵的南瓜汁相比,混合发酵后挥发性成分以醇类居多;相对含量较高的香气成分种类相似,而微量特征香气成分差异较为显著。     

无花果果酒酵母的筛选及发酵性能研究

本文主要筛选适合无花果果酒发酵的酵母。从无花果果皮和无花果果酒酒渣中初步分离得到41株酵母菌,经过一级筛选得到12株产酒产香较好的菌株,经过杜氏管法筛选得到6株起酵快的优势菌株,再经过无花果浆汁发酵法筛选得到1株起酵快、产酒产香较好的酵母。再对这株菌进行耐受性测试,结果表明,酵母菌Z20对糖度、酸度、SO2以及乙醇的耐受性较好,可作为无花果酒发酵的专用酵母。     

茅台大曲中酵母的分离、鉴定及其功能初探

采用可培养方法对酱香型白酒大曲中的酵母菌进行计数和筛选,通过形态学特征、生理生化实验及酵母26S rDNA分子生物学方法鉴定酵母,并分析酵母的发酵能力和风味成分。结果表明,酱香型大曲中酵母数量为103 CFU/g;共分离鉴定6种酵母,各酵母产香能力不同,编号FBKL2.0071扣囊复膜酵母(Saccharomycopsis fibuligera)固态发酵物具有浓郁的果香味,其中以乙酸乙酯、乙酸异戊酯、苯乙醇、乙酸苯乙酯、棕榈酸乙酯含量较高。编号FBKL2.0082多株伯顿丝孢毕赤酵母(Hyphopichia burtonii)固态发酵物呈浓郁的花香味,其中以乙酸乙酯、乙酸异戊酯和苯乙醇含量较高。这两株酵母固态发酵时都能产生大量的酯类和醇类等挥发性香味物质,还有少量醛、酮、酚和烷类等物质。分离得到的酵母产酒能力不同,总体产酒能力不高。