Quality control method based on quartz crystal microbalance and WGA for flour milled from germinated wheat

Plasma membrane is the initial sensor of different stress conditions and its composition is modified with response to environmental changes. In the present study, we have modified the lipid composition of the membrane by growing Saccharomyces cerevisiae in the presence of different fatty acids and ergosterol. All supplemented fatty acids were incorporated into the cell and this incorporation produced significant changes in the lipid composition. The incubation with ergosterol also modified the lipid composition of the cells; however, these cells presented a strong reduction in the content of this sterol. The different cellular lipid composition has been related to viability and fermentation performance at low temperature (13 °C). The cells incubated with palmitoleic acid (C16:1) showed higher viability and significant reduction in the fermentation length. These cells presented higher C16:1 and ergosterol content, shorter chain length of the fatty acids and higher ratio of sterols/phospholipids. Therefore redesigning the composition of cellular membranes during industrial yeast propagation seems to be a promising strategy for improving fermentation performance in the winery.     

Effect of Initial PH on Growth Characteristics and Fermentation Properties of Saccharomyces cerevisiae

As the core microorganism of wine making, Saccharomyces cerevisiae encounter low pH stress at the beginning of fermentation. Effect of initial pH (4.50, 3.00, 2.75, 2.50) on growth and fermentation performance of 3 S. cerevisiae strains Freddo, BH8, Nº.7303, different tolerance at low pH, chosen from 12 strains, was studied. The values of yeast growth (OD₆₀₀, colony forming units, cell dry weight), fermentation efficiency (accumulated mass loss, change of total sugar concentration), and fermentation products (ethanol, glycerol, acetic acid, and l ‐succinic acid) at different pH stress were measured. The results showed that the initial pH of must was a vital factor influencing yeast growth and alcoholic fermentation. Among the 3 strains, strain Freddo and BH8 were more tolerant than Nº.7303, so they were affected slighter than the latter. Among the 4 pH values, all the 3 strains showed adaptation even at pH 2.50; pH 2.75 and 2.50 had more vital effect on yeast growth and fermentation products in contrast with pH 4.50 and 3.00. In general, low initial pH showed the properties of prolonging yeast lag phase, affecting accumulated mass loss, changing the consumption rate of total sugar, increasing final content of acetic acid and glycerol, and decreasing final content of ethanol and l ‐ succinic acid, except some special cases. Based on this study, the effect of low pH on wine products would be better understood and the tolerance mechanism of low pH of S. cerevisiae could be better explored in future.     

Oleic acid and ergosterol supplementation mitigates oxidative stress in wine strains of Saccharomyces cerevisiae

During fermentation of high-sugar-containing medium lacking lipid nutrients, wine yeasts undergo oxidative stress and oxidative damage to cell membranes and proteins. Considering that cell membranes are important stress sensors, and that under hypoxic conditions wine yeasts modulate cell membranes composition by incorporating lipids available in the growth medium, in the present work, the effects of lipid nutrition on wine yeast oxidative stress response were evaluated on two strains of Saccharomyces cerevisiae. Biomarkers of oxidative stress, oxidative damage and antioxidant response were evaluated together with viability and acetic acid production during fermentation of a synthetic must lacking lipid nutrients as compared to added oleic acid and ergosterol. The results show that the availability of lipid nutrients causes a significant reduction in the intracellular content of reactive oxygen species and in the oxidative damage to membranes and proteins, as indicated by flow cytometry of cells stained with dihydroethidum (DHE) and propidium iodide (PI) and by Western blot of protein carbonyls. Accordingly, lipid nutrients feeding results in the increase in cell viability and superoxide activity, and the reduction in trehalose accumulation, proteinase A activity and production of acetic acid. In summary, these results are compatible with the hypothesis that the supplementation of lipid nutrients mitigates oxidative stress and oxidative damage in wine strains of S. cerevisiae during growth under unfavourable conditions.     

The wide-ranging phenotypes of ergosterol biosynthesis mutants,and implications for microbial cell factories

Yeast strains have been used extensively as robust microbial cell factories for the production of bulk and fine chemicals, including biofuels (bioethanol), complex pharmaceuticals (antimalarial drug artemisinin and opioid pain killers), flavours, and fragrances (vanillin, nootkatone, and resveratrol). In many cases, it is of benefit to suppress or modify ergosterol biosynthesis during strain engineering, for example, to increase thermotolerance or to increase metabolic flux through an alternate pathway. However, the impact of modifying ergosterol biosynthesis on engineered strains is discussed sparsely in literature, and little attention has been paid to the implications of these modifications on the general health and well-being of yeast. Importantly, yeast with modified sterol content exhibit a wide range of phenotypes, including altered organization and dynamics of plasma membrane, altered susceptibility to chemical treatment, increased tolerance to high temperatures, and reduced tolerance to other stresses such as high ethanol, salt, and solute concentrations. Here, we review the wide-ranging phenotypes of viable Saccharomyces cerevisiae strains with altered sterol content and discuss the implications of these for yeast as microbial cell factories.     

Microbial succession and metabolite changes during the fermentation of Chinese light aroma‐style liquor

A combination of culture‐dependent and culture‐independent methods and SPME–GC–MS were used to monitor changes of bacterial and yeast communities, and flavour compounds during the fermentation process of Chinese light aroma‐style liquor. Bacillus and Lactobacillus were the main bacterial genera. Pichia anomala, Saccharomyces cerevisiae and Issatchenkia orientalis were the dominant yeast species. There was a close relationship between fermentation time and the shift of microbial community. Compared with the microbiota in the fermentation of other style liquors, higher bacterial diversity and different non‐Saccharomyces composition led to a variety of metabolites. Metabolite analysis showed that esters, acids, alcohols, aromatic compounds and phenols were the main flavour components and most of them were synthesised in the latter phase of fermentation. Principal component analysis further demonstrated that Bacillus and yeast were the most influential microorganisms in the first 10 days of fermentation, and lactic acid bacteria predominated in the later phase. Lactic acid bacteria regulated the composition of other bacteria and yeast, and synthesised flavour compounds to affect the organoleptic properties of liquor. S. cerevisiae and P. anomala were two important yeast species responsible for the characteristic aroma of liquor. These results present a comprehensive understanding of microbial interaction and potential starter cultures to produce desirable liquor quality. © 2018 The Institute of Brewing & Distilling     

Cellular mechanism for the improvement of multiple stress tolerance in brewer's yeast by potassium ion supplementation

The ethanol fermentation efficiency was affected by multiple stress tolerance of yeast during brewing and bioethanol industry. The effect of KCl on the multiple stress tolerance of yeast cells was examined. Results showed that KCl addition significantly enhanced the tolerance of yeast cells to osmotic and ethanol stress, which correlated with the decreased membrane permeability, the increased intracellular ergosterol and ATP content, and the improved activity of complex II and complex III in yeast cells. Biomass and viability of yeast cells under osmotic and ethanol stress were increased significantly by KCl addition. Supplementation of 4 and 10 g L⁻¹ KCl exhibited the best promotion activity for yeast cells present in medium with 500 g L⁻¹ sucrose and 10% (v v⁻¹) ethanol, respectively. These results suggested that exogenous potassium addition might be an effective strategy to improve yeast tolerance and fermentation efficiency during industrial very-high-gravity (VHG) fermentation.     

Effect of growth temperature on yeast lipid composition and alcoholic fermentation at low temperature

The loss of viability of wine yeast strains due to low-temperature fermentations could be overcome by increasing their stress tolerance and adaptability. Changes in membrane lipid composition are one of the first responses to cold stress. The aim of this study was to analyze the various adaptation mechanisms to low temperatures by comparing the better adapted Saccharomyces species. The viability, vitality, fermentation capacity, and lipid composition of different Saccharomyces species (S. cerevisiae, S. bayanus, S. uvarum, and a hybrid S. cerevisiae/S. uvarum) with different fermentative origins (wine, beer, and baker’s strains together with a laboratory strain) were compared after culturing at low (13 °C) and optimal (25 °C) temperatures. In spite of specific responses of the different strains/species, the results showed that at low temperature, the medium-chain fatty acid and the triacylglyceride content increased, whereas the phosphatidic acid content and the phosphatidylcholine/phosphatidylethanolamine ratio decreased. Only the laboratory strain was not able to ferment the sugars, and after growing at both temperatures, its lipid composition was very different from that of the other strains. The hybrid strain showed the highest sugar consumption at 13 °C and the best vitality whatever the preculture temperature used. The rest of the species needed a preadaptation at low temperature involving a change in their lipid composition to improve their fermentation rate at 13 °C.     

CONTROLLED PRODUCTION OF CIDER BY INDUCTION OF ALCOHOLIC FERMENTATION AND MALOLACTIC CONVERSION

Characterization experiments involving lactic bacteria allowed a strain of Leuconostoc oenos to be selected in terms of growth capacity at variable pH, temperature, ethanol and sulphite concentrations, malic to lactic conversion yield, acetic acid uptake and dextran production capacity. Cider was produced under controlled conditions where the effect of Kloeckera apiculata yeasts on the development of Saccharomyces cerevisiae and production of major non-volatile compounds influencing end product quality was studied. The apiculate yeast was found to produce large amounts of acetic acid and use the other organic acids; also, it hindered fermentation to a certain extent. A study of the effect of the inoculation time with L oenos as an inducer of malolactic fermentation revealed sequential inoculation of the lactic bacterium once most major sugars in the must had been depleted to be the most favourable. Using yeast cell walls boosted fermentation development, as well as degradation of malic acid and synthesis of succinic and acetic acid.     

The effect of ethanol and specific growth rate on the lipid content and composition of Saccharomyces cerevisiae grown anaerobically in a chemostat

The effects of produced ethanol and specific growth rate on the lipid content and composition of Saccharomyces cerevisiae CBS 2806 were studied using anaerobic chemostat cultures. The cells adapted to increased concentrations of produced ethanol by increasing the proportion of ergosterol at the expense of lanosterol, by increasing the proportion of phosphatidylinositol at the expense of phosphatidylcholine, and by increasing the amount of C_18:0 fatty acids in total phospholipids at the expense of C_16:0 fatty acids. The produced ethanol had no effect on the phospholipid content nor on the proportion of unsaturated fatty acids in the phospholipids. The specific growth rate had no effect on the phospholipid content, the sterol composition, the phospholipid composition, the fatty acid composition of total phospholipids, or on the proportion of unsaturated fatty acids in the phospholipids of S. cerevisiae. It was not possible to separate the effects of produced ethanol and growth rate on the ergosterol content of the chemostat-grown S. cerevisiae cells.     

Determinants of flocculence of brewer's yeast during fermentation in wort

Ability of Saccharomyces cerevisiae MPY3 cells to flocculate during fermentation in wort was found to be triggered after growth limitation by oxygen shortage and to coincide with a sharp increase in cell surface hydrophobicity of the cells. Presence of oxygen in the pitching wort influenced final cell number, flocculence of the cells and cell surface hydrophobicity. Flocculation ability of cells grown in air-depleted pitching wort was hampered, concomitant with a decrease in final cell number and in final cell surface hydrophobicity. Addition of ergosterol and Tween 80 to air-depleted wort restored normal growth of the cells as well as flocculation ability and the increase in cell surface hydrophobicity. The same parameters increased in value after addition of ergosterol and Tween 80 to a fermentation with air-saturated pitching wort. Hydrophobicity of a non-flocculent mutant of S. cerevisiae strain MPY3, fermenting in air-saturated pitching wort, did not increase at cell division arrest. These results support the hypothesis that cell surface hydrophobicity is a major determinant for yeast cells to become flocculent, and suggest that shortage of sterols and unsaturated fatty acids precedes flocculence under brewing conditions.     

SELECTION AND BIOCHEMICAL CHARACTERISATION OF SACCHAROMYCES CEREVISIAE AND KLOECKERA APICULATA STRAINS ISOLATED FROM SPANISH CIDER

The behaviour of different strains of Saccharomyces cerevisiae and Kloeckera apiculata in apple juice fermentation was studied. Ethanol production was higher for Saccharomyces strains while residual sugars and ethyl acetate content was higher for Kloeckera strains. Kl. apiculata fermented products showed the lowest amount of higher alcohols and the lowest content in organic acids with the exception of acetic acid, so this yeast produced an increment in volatile acidity. On the basis of ethyl acetate, hydrogen sulfide, and acetic acid production, fermentative ability, potassium metabisulfite resistance and sporulation percentage, one strain from Sacch. cerevisiae could be employed as starter for making cider.     

Variations of internal pH in typical Italian sourdough yeasts during co-fermentation with lactobacilli

The effects of organic acids (lactic and acetic) and extracellular pH (pHex) on the intracellular pH (pHi) of Saccharomyces cerevisiae and Candida milleri during co-fermentation with lactobacilli were investigated by using Fluorescence-Ratio-Imaging-Microscopy (FRIM). Yeasts were grown in a system that partially mimics sourdough composition, using individual fermentation and combinations with lactic acid bacteria. Fermentations were carried out at 25 °C for 22 h at an initial pH of 5.3. The two yeast species grew equally well during the co-fermentations with lactobacilli. Our results reveal large differences in pHi values between the two yeast species, primarily in relation with pHex changes, while the concentration of organic acids did not seem to affect the pHi. Moreover, the pHi of S. cerevisiae seemed to be affected by maltose consumption. The pH gradient (difference between internal and external pH) of S. cerevisiae remained rather constant, ranging from 2.0 to 2.5. C. milleri instead exhibited a higher pHi, that remained constant throughout the experiments and was unaffected by pHex and/or sugar consumption. Thus, the pH gradient of C. milleri varied much more than that of S. cerevisiae, ranging from 2.3 to 3.8. Our results suggest that the two yeast species have different pHi regulation mechanisms.     

Relationship between ethanol tolerance, H+ -ATPase activity and the lipid composition of the plasma membrane in different wine yeast strains

Ethanol tolerance, ATPase activity and the lipid composition of the plasma membrane to study potential relationship among them were examined in five different wine yeast strains. Yeast cells were subjected to ethanol stress (4% v/v). Principal component analysis of the results revealed that the wine yeasts studied can be distinguished in terms of ATPase activity and oleic acid (C18:1), and palmitoleic acid (C16:1), in plasma membrane. Multiple regression analysis was used to identify a potential influence of some components of the plasma membrane on ethanol tolerance and ATPase activity. Based on the results, the ergosterol, oleic acid and palmitoleic acid are highly correlated with ATPase activity and ethanol tolerance. Ethanol tolerance and the ATPase activity of the plasma membrane were correlated at the 96.64% level with the oleic acid and ergosterol in plasma membrane. The Saccharomyces cerevisiae var. capensis flor yeast strain, which exhibited the highest ergosterol concentration in plasma membrane when grown in the presence of 4% v/v ethanol, was found to be the most ethanol-tolerant.     

Development of a “Stress Model” Fermentation System for Fuel Ethanol Yeast Strains

During industrial scale fuel ethanol fermentations, yeast encounters a multitude of stress factors that impose constraints on growth and fermentative metabolism. These stresses include high sugar concentration, elevated temperature, high ethanol concentrations, low external pH and the weak organic acids lactic and acetic. Yeast strains which are tolerant to these stresses and able to synthesize high ethanol concentrations in their presence would be most desirable for use in industrial scale fuel ethanol production. In this study, a “stress model” fermentation system was developed as a tool to screen candidate yeast strains for relative stress resistance. The stress model was designed on the basis that the degree of ethanol produced by a particular strain would be indicative of the stress resistance of that particular strain. Eight strains of Saccharomyces cerevisiae, each with different backgrounds and fermentative capabilities, were screened for relative stress resistance using the stress model. The results obtained indicate that the sum of the stress factors in the stress model exceeded the tolerance level of most of the strains screened (approximately 40%). Two strains in particular, J006 and A007, displayed superior fermentative performance and produced significantly (P > 0.01) higher final ethanol concentrations when compared to the other strains.     

Changes in the Lipid Composition of Saccharomyces cerevisiae Race Capensis (G-1) During Alcoholic Fermentation and Flor Film Formation

The cellular lipid composition of one flor-forming strain of Saccharomyces cerevisiae during fermentation and the subsequent period of film formation with different oxygen levels was studied. Irrespective of fermentation conditions, only those yeasts which came into contact with oxygen after fermentation formed a flor film. After the fermentation, these yeasts entered an adaptation phase in which the percentage of oleic acid increased considerably at the expense of other long-chain fatty acids. Their phospholipid contents remained high, as well as the unsaturation index of their fatty acids and the ergosterol/phospholipids ratio was maintained below 1. These changes allowed an increased viability of yeasts in the wine of up to 80% and the acquisition of sufficient hydrophobicity and floatability to reach the surface and form flor film.     

Populations and potential association of Saccharomyces cerevisiae with lactic acid bacteria in naturally fermented Korean rice wine

The microbial populations focused on predominant yeast species and lactic acid bacteria (LAB) in 15 commercial makgeolli brands, where a fungal starter nuruk was used were examined. Viable yeast counts were obtained on yeast potato dextrose (YPD) and MRS agar containing sodium azide. MRS-C (0.1% cycloheximide supplemented) was used for selective counts of LAB. Saccharomyces cerevisiae was found to be predominant in the 15 samples tested, with an average count of 4.6×10⁷ CFU/mL. Contrary to the earlier studies, Lactobacillus plantarum and Weissella cibaria were shown as predominant LAB species with an average count of 1.7×10⁷ CFU/mL. Surprisingly, as many as 7 log viable cells/mL were present at the ethyl alcohol concentration of 6–7%. The data from real-time PCR also indicated that the yeast populations remains almost constant during the refrigerated storage of 12 days, while that of LAB decrease slightly first 9 days and increase after then, despite the overall increase in acidity. Data from the differential microbial counts suggest that yeast S. cerevisiae might be associated with 2 LAB species, L. plantarum and W. cibaria, under ethyl alcohol stress during the turbid rice wine fermentation.     

Adaptive response and tolerance to weak acids in Saccharomyces cerevisiae boulardii: a metabolomics approach

Weak acids inhibit the growth of probiotics, such as Saccharomyces boulardii. We explored the tolerance of S. boulardii to different weak acids. S. boulardii had better fermentation ability under lactic acid conditions compared with acetic and butyric acid conditions; however, the budding of S. boulardii was significantly stronger than that of Saccharomyces cerevisiae under acetic acid conditions. Although the surface structure of S. boulardii was destroyed, it produced more daughter cells. S. boulardii metabolites were also significantly different from S. cerevisiae under acidic stress. The growth of S. boulardii under weak acid conditions differed significantly from that of S. cerevisiae. S. boulardii-mediated fingerprints under weak acid conditions were identified as latent biomarkers, related to fructose and mannose metabolism, tricarboxylic acid cycle, and the glycolysis pathway. Identified biomarkers will aid in the genetic engineering of S. boulardii and other Saccharomyces strains for improved acid resistance and biomass yield.     

Changes in organic acid contents during mead wort fermentation

Organic acids contained in honey influence the fermentation rate and frequently cause mead fermentation to halt. The purpose of this study was to determine the changes that occur in a group of selected organic acids during the fermentation of mead worts and their impact on the process. Mead worts (1:2 and 1:3 (honey:water)) were fermented using Saccharomyces cerevisiae yeast of the Johannisberg-Riesling breed (?OCK 105). The worts were supplemented with diammonium hydrogen phosphate (0.4 g/l) and citric acid (0.25 g/l). During fermentation, the contents of selected carboxylic acids were determined using gas chromatography. Mead worts contain relatively high amounts of medium-chain fatty acids, which are believed to inhibit fermentation. The dominant compounds of this group are decanoic (42 mg/l), dodecanoic (31 mg/l) and octanoic (26 mg/l) acids. The experiments demonstrated that during the early days of fermentation, the main acids to form are the acetic and succinic acids, which reduce the wort pH, while the content of fatty acids drops by 70–80%. During fermentation, the amounts of the formic, hexadecanoic and octadecanoic acids also fall.     

Modulation of grape wine flavor via the sequential inoculation of Williopsis saturnus and Saccharomyces cerevisiae

The effects of the inoculum ratio of Williopsis saturnus var. saturnus NCYC22 and Saccharomyces cerevisiae var. bayanus EC-1118 at 1:200 and 1:800 on the chemical and volatile compositions of grape wine were studied in sequential fermentation. The grape juice was first inoculated with Williopsis (W.) saturnus for 9 d; thereafter, Saccharomyces (S.) cerevisiae was inoculated to continue the fermentation until d 19. The cell population of W. saturnus disappeared by d 13, with S. cerevisiae dominating until the end of the fermentation in both inoculum ratios. The changes in yeast count, pH, total soluble solids, sugars, organic acids, and amino acids were similar between the two inoculum ratios. A range of volatile compounds was formed, including alcohols, esters, fatty acids, aldehydes, and terpenes. There were significant differences between both inoculum ratios for medium-chain fatty acids (C8, C10, and C12), ethyl esters of fatty acids of C6, C10, C12, and C14 as well as isoamyl octanoate, while other volatiles were statistically the same.