Flocculence of Saccharomyces cerevisiae cells is induced by nutrient limitation, with cell surface hydrophobicity as a major determinant.

Initiation of flocculation ability of Saccharomyces cerevisiae MPY1 cells was observed at the moment the cells stop dividing because of nitrogen limitation. A shift in concentration of the limiting nutrient resulted in a corresponding shift in cell division and initiation of flocculence. Other limitations also led to initiation of flocculence, with magnesium limitation as the exception. Magnesium-limited S. cerevisiae cells did not flocculate at any stage of growth. Cell surface hydrophobicity was found to be strongly correlated with the ability of the yeast cells to flocculate. Hydrophobicity sharply increased at the end of the logarithmic growth phase, shortly before initiation of flocculation ability. Treatments of cells which resulted in a decrease in hydrophobicity also yielded a decrease in flocculation ability. Similarly, the presence of polycations increased both hydrophobicity and the ability to flocculate. Magnesium-limited cells were found to be strongly affected in cell surface hydrophobicity. A proteinaceous cell surface factor(s) was identified as a flocculin. This heat-stable component had a strong emulsifying activity, and appears to be involved in both cell surface hydrophobicity and in flocculation ability of the yeast cells.     

On the Mechanism of Brewer’s Yeast Flocculation

Brewer’s yeast appears to flocculate or disperse reversibly in response to the environmental conditions. The yeast and its solubilized cell surface substance show flocculation-dispersion changes according to pH, sugar concentration and flocculation inducing substances. Top fermentative yeasts do not show such a response to the surrounding conditions. Cell surfaces of bottom fermentative yeasts increase in hydrophobicity during a shift from fermentation starting conditions (dispersion of yeast) (high sugar concentration, pH 5.5) to ending conditions ( flocculation) (no sugar, pH 4.2), but this hydrophobicity increase was not seen in the case of top fermentative yeast cells. The contributions of hydrophobic interaction and ionic bonds to flocculence of the yeast were discussed.     

Yeast flocculation: factors affecting the measurement of flocculence

The physical meaning of the residual absorbance of a yeast suspension after flocculation and settling has been investigated. Starting with a dispersed suspension, agitation accelerates flocculation by increasing the probability of collision between particles. As flocculation advances, agitation also breaks the flocs. A stationary state is reached when flocculence (tendency to flocculate) is counterpoised by agitation. If the intensity of agitation is maintained constant, the free cell concentration reflects the flocculence, provided the stationary state is reached. The residual absorbance, determined after settling of the flocs, is a measure of the free cell concentration and represents an adequate parameter to characterize yeast flocculence.     

On-line measurement and analysis of yeast flocculation

The ability of yeast to flocculate is important in different separation processes, especially in the beer industry. Because of the regulation purposes, there is a need for online monitoring. With the presented measuring set-up, consisting of a peristaltic pump, a photometer, and a computer, it is possible to determine the onset of flocculation as well as to follow flocculation intensity and the concentration of nonflocculated cells. It was found that for the yeast strain Saccharomyces cerevisiae ZIM 198 the decrease of nonflocculated cells (after flocculation has occurred) during the exponential growth can be described by an exponential equation for the first-order process, whereas the increase of free cells due to dispersion of the flocs during the stationary phase follows the form of the growth curve. It was also demonstrated that the absorbency profiles of yeast sedimentation can be described by the second-order equation suggested by Stradford and Keenan for the decrease of cell concentration during sedimentation. (c) 1997 John Wiley & Sons, Inc.     

Unusual flocculation characteristics of the yeast Candida famata (Debaryomyces hansenii)

Candida famata NCYC 576 cells aggregated throughout growth in YEPD. Aggregates were dispersed by Pronase E, EDTA or specific sugars. EDTA-dispersed cells reaggregated after calcium ion addition. Unlike Saccharomyces cerevisiae, C. famata cells lost the ability to flocculate with repeated EDTA washings. These cells regained flocculation when resuspended in the first washing solution after calcium addition. Candida famata NCYC 576 aggregation is consistent with lectin-mediated yeast flocculation, where lectins are not surface-anchored, as in S. cerevisiae but attached to cells only by lectin action.     

Repression and induction of flocculation interactions in Saccharomyces cerevisiae.

The biological control of flocculation interactions by factors related to growth under different conditions of aeration was documented with a new assay for flocculence. The degree of flocculence expressed in a genetically defined Saccharomyces cerevisiae strain (FLO1/FLO1 ade1/ade1) remained constant during aerobic growth but varied with aeration. Flocculence was repressed in anaerobically growing cells but was induced in stationary cells or cells returned to aerobic growth. Repression was correlated with the selective inactivation of cell surface lectin-like components. The changes in flocculence were accompanied by changes in 16 extractable proteins separated by electrophoresis; however, a clear correlation between specific protein bands and flocculence could not be established. The study clearly demonstrated that the phenotypic expression of FLO1 could be reproducibly manipulated for experimental purposes by aeration alone.     

The impact of brewing yeast cell age on fermentation performance,attenuation and flocculation

Individual cells of the yeast Saccharomyces cerevisiae exhibit a finite replicative lifespan, which is widely believed to be a function of the number of divisions undertaken. As a consequence of ageing, yeast cells undergo constant modifications in terms of physiology, morphology and gene expression. Such characteristics play an important role in the performance of yeast during alcoholic beverage production, influencing sugar uptake, alcohol and flavour production and also the flocculation properties of the yeast strain. However, although yeast fermentation performance is strongly influenced by the condition of the yeast culture employed, until recently cell age has not been considered to be important to the process. In order to ascertain the effect of replicative cell age on fermentation performance, age synchronised populations of a lager strain were prepared using sedimentation through sucrose gradients. Each age fraction was analysed for the ability to utilise fermentable sugars and the capacity to flocculate. In addition cell wall properties associated with flocculation were determined for cells within each age fraction. Aged cells were observed to ferment more efficiently and at a higher rate than mixed aged or virgin cell cultures. Additionally, the flocculation potential and cell surface hydrophobicity of cells was observed to increase in conjunction with cell age. The mechanism of ageing and senescence in brewing yeast is a complex process, however here we demonstrate the impact of yeast cell ageing on fermentation performance.     

Characterization of non-flocculent cells isolated from a culture of flocculent Saccharomyces cerevisiae NCYC 1001

During cultivation of a flocculent yeast, Saccharomyces cerevisiae 1001, two cell fractions, flocs and free cells, appeared in the medium. Free cells contained cells with a normal ability to flocculate, less flocculent cells and not-flocculent cells. When the non-flocculent cells and not-flocculent cells. When the non-flocculent cell fraction from the postexponential phase of growth was collected and used as an inoculum, the culture showed synchronous growth. The floc forming ability of the yeast cells from this culture increased gradually with the number of divisions.     

Dependence of sulphate uptake by Anacystis nidulans on energy,on osmotic shock and on sulphate starvation

Effects of treatments with proteolytic enzymes and protein-modifying reagents on flocculation of brewer's yeast IFO 2018 were investigated. The floc-forming ability of the yeast cells was irreversibly eliminated by treatment with papain, trypsin, chymotrypsin or pepsin, indicating that certain proteins on the cell surface participate in the yeast flocculation. Chemical modification with reagents, known to act on disulfide bridges, carboxyl and/or phosphate groups, phenolic groups, amino groups, and imidazole groups, also destroyed the ability to flocculate, although in some cases a high concentration (8 M) of urea was necessary in addition to protein-modifying reagents. Thus, it is suggested strongly that these functional groups of amino acid residues of the proteins are essential for the floc-forming ability of brewer's yeast cells.Abbreviations Used CMA buffer 0.20 M Na-acetate buffer (pH 4.5) containing 0.009 M CaCl₂ and 0.004 M MgSO₄ - S.P. sedimentation percentage (see text) - SH sulfhydryl     

Natural transformation of Streptococcus crista

Abstract Most brewing strains of Saccharomyces cerevisiae flocculate following growth in beer wort. However, many do not flocculate in laboratory culture media, because their initial pH and buffering capacity do not correspond to the pH range within which these yeasts flocculate. Many, though not all, NewFlo phenotype brewing yeasts flocculate within a narrow pH range only; this is indicative of the existence of more than one NewFlo flocculation phenotype. Such strains may be flocculated by small alterations of pH to within the flocculation range. Induction of flocculation by pH change may be used to separate cells from media at any stage during fermentation.     

Cell Surface Galactosylation Is Essential for Nonsexual Flocculation in Schizosaccharomyces pombe

We have isolated fission yeast mutants that constitutively flocculate upon growth in liquid media. One of these mutants, the gsf1 mutant, was found to cause dominant, nonsexual, and calcium-dependent aggregation of cells into flocs. Its flocculation was inhibited by the addition of galactose but was not affected by the addition of mannose or glucose, unlike Saccharomyces cerevisiae FLO mutants. The gsf1 mutant coflocculated with Schizosaccharomyces pombe wild-type cells, while no coflocculation was found with galactose-deficient (gms1Δ) cells. Moreover, flocculation of the gsf1 mutant was also inhibited by addition of cell wall galactomannan from wild-type cells but not from gms1Δ cells. These results suggested that galactose residues in the cell wall glycoproteins may be receptors of gsf1-mediated flocculation, and therefore cell surface galactosylation is required for nonsexual flocculation in S. pombe.     

Carbohydrate carbon sources induce loss of flocculation of an ale-brewing yeast strain

AIMS: To identify the nutrients that can trigger the loss of flocculation under growth conditions in an ale-brewing strain, Saccharomyces cerevisiae NCYC 1195. METHODS AND RESULTS: Flocculation was evaluated using the method of Soares, E.V. and Vroman, A. [Journal of Applied Microbiology (2003) 95, 325]. Yeast growth with metabolizable carbon sources (glucose, fructose, galactose, maltose or sucrose) at 2% (w/v), induced the loss of flocculation in yeast that had previously been allowed to flocculate. The yeast remained flocculent when transferred to a medium containing the required nutrients for yeast growth and a sole nonmetabolizable carbon source (lactose). Transfer of flocculent yeast into a growth medium with ethanol (4% v/v), as the sole carbon source did not induce the loss of flocculation. Even the addition of glucose (2% w/v) or glucose and antimycin A (0.1 mg l(-1)) to this culture did not bring about loss of flocculation. Cycloheximide addition (15 mg l(-1)) to glucose-growing cells stopped flocculation loss. CONCLUSIONS: Carbohydrates were the nutrients responsible for stimulating the loss of flocculation in flocculent yeast cells transferred to growing conditions. The glucose-induced loss of flocculation required de novo protein synthesis. Ethanol prevented glucose-induced loss of flocculation. This protective effect of ethanol was independent of the respiratory function of the yeast. SIGNIFICANCE AND IMPACT OF THE STUDY: This work contributes to the elucidation of the role of nutrients in the control of the flocculation cycle in NewFlo phenotype yeast strains.     

Flocculation in ale brewing strains of <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>: re-evaluation of the role of cell surface charge and hydrophobicity

Flocculation is an eco-friendly process of cell separation, which has been traditionally exploited by the brewing industry. Cell surface charge (CSC), cell surface hydrophobicity (CSH) and the presence of active flocculins, during the growth of two (NCYC 1195 and NCYC 1214) ale brewing flocculent strains, belonging to the NewFlo phenotype, were examined. Ale strains, in exponential phase of growth, were not flocculent and did not present active flocculent lectins on the cell surface; in contrast, the same strains, in stationary phase of growth, were highly flocculent (>98%) and presented a hydrophobicity of approximately three to seven times higher than in exponential phase. No relationship between growth phase, flocculation and CSC was observed. For comparative purposes, a constitutively flocculent strain (S646-1B) and its isogenic non-flocculent strain (S646-8D) were also used. The treatment of ale brewing and S646-1B strains with pronase E originated a loss of flocculation and a strong reduction of CSH; S646-1B pronase E-treated cells displayed a similar CSH as the non-treated S646-8D cells. The treatment of the S646-8D strain with protease did not reduce CSH. In conclusion, the increase of CSH observed at the onset of flocculation of ale strains is a consequence of the presence of flocculins on the yeast cell surface and not the cause of yeast flocculation. CSH and CSC play a minor role in the auto-aggregation of the ale strains since the degree of flocculation is defined, primarily, by the presence of active flocculins on the yeast cell wall.     

Mechanisms of yeast flocculation: comparison of top- and bottom-fermenting strains.

The flocculation of two brewing yeast strains, top-fermenting strain Saccharomyces cerevisiae MUCL 38485 and bottom-fermenting strain Saccharomyces carlsbergensis MUCL 28285, has been investigated by means of a turbidimetric test. The two strains showed different electrical properties, a different hydrophobicity, and a different surface chemical composition. They flocculated according to completely different mechanisms; however, no correlation between the cell physicochemical properties and the onset of flocculation was found for either strain. Flocculation of the bottom strain was governed by a lectin-mediated mechanism. It was inhibited by mannose and some other sugars, required calcium specifically, occurred in a narrow pH range different from the isoelectric point, and was not influenced by ethanol. The onset of flocculation at the end of the exponential phase was controlled both by the appearance of "active" lectins at the cell surface and by the decrease in sugar concentration in the solution. Flocculation of the top strain was not inhibited by mannose, did not require the addition of calcium, and took place at the cell isoelectric point. Low concentrations of ethanol broadened the pH range in which the cells flocculated, and flocculation was favored by an increase of ionic strength. Adsorbed ethanol may induce flocculation by reducing the electrostatic repulsion between cells, by decreasing steric stabilization, and/or by allowing the protrusion of polymer chains into the liquid phase. The onset of flocculation was controlled by both a change of the cell surface and an increase in ethanol concentration. The only evidence for an adhesin-mediated mechanism was the specific requirement for a small amount of calcium.     

絮凝特性对自絮凝颗粒酵母耐酒精能力的影响及作用机制

首次报道絮凝特性提高酵母菌耐酒精能力的现象及其机制。融合株SPSC与其两亲本粟酒裂殖酵母变异株和酿酒酵母变异株于 30℃经 18% (V/V)酒精冲击 7h的存活率分别为 52%、37%和 9%。细胞膜磷脂脂肪酸组成分析表明 ,两絮凝酵母 (融合株SPSC和粟酒裂殖酵母变异株 )的棕榈酸含量均约为非絮凝酵母 (酿酒酵母变异株 )的两倍 ,而棕榈油酸和油酸的含量明显低于后者。研究表明 ,当两絮凝酵母在培养中由于柠檬酸钠的作用 (抑制絮凝体的形成 )而以游离细胞生长存在时 ,其细胞膜磷脂棕榈酸含量显著下降 ,而棕榈油酸和油酸的含量明显增加 ,结果细胞膜磷脂脂肪酸组成特点与酿酒酵母变异株相似 ;而且实验表明 ,絮凝特性的消失伴随菌体耐酒精能力的急剧下降 ,变得与酿酒酵母变异株的水平相当。这些结果提示两絮凝酵母具有较强的耐酒精能力与其细胞膜磷脂脂肪酸组成中含有更高比例的棕榈酸有关。     

Flocculation onset in Saccharomyces cerevisiae: the role of nutrients

AIMS: To examine the role of the nutrients on the onset of flocculation in an ale-brewing strain, Saccharomyces cerevisiae NCYC 1195. METHODS AND RESULTS: Flocculation was evaluated using the method of Soares, E.V. and Vroman, A. [Journal of Applied Microbiology (2003) 95, 325]. For cells grown in chemically defined medium (yeast nitrogen base with glucose) or in rich medium (containing yeast extract, peptone and fermentable sugars: fructose or maltose), the onset of flocculation occurred after the end of exponential respiro-fermentative phase of growth being coincident with the attainment of the lower level of carbon source in the culture medium. Cells, in exponential respiro-fermentative phase of growth, transferred to a glucose-containing medium without nitrogen source, developed a flocculent phenotype, while these carbon source starved cells, in the presence of all other nutrients that support growth, did not flocculate. In addition, cells in exponential phase of growth, under catabolite repression, when transferred to a medium containing 0.2% (w/v) of fermentable sugar (fructose or maltose) or 2% (v/v) ethanol, showed a rapid triggering of flocculation, while when incubated in 2% (v/v) glycerol did not develop a flocculent phenotype. CONCLUSIONS: The onset of flocculation occurs when a low sugar and/or nitrogen concentration is reached in culture media. The triggering of flocculation is an energetic dependent process influenced by the carbon source metabolism. The presence of external nitrogen source is not necessary for developing a flocculent phenotype. SIGNIFICANCE AND IMPACT OF THE STUDY: This work contributes to the elucidation of the role of nutrients on the onset of flocculation in NewFlo phenotype yeast strains. This information might be useful to the brewing industry, in the control of yeast flocculation, as the time when the onset of flocculation occurs can determine the fermentation performance and the beer quality.     

Mutational Analysis of Morphologic Differentiation in Saccharomyces Cerevisiae

A genetic analysis was undertaken to investigate the mechanisms controlling cellular morphogenesis in Saccharomyces cerevisiae. Sixty mutant strains exhibiting abnormally elongated cell morphology were isolated. The cell elongation phenotype in at least 26 of the strains resulted from a single recessive mutation. These mutations, designated generically elm (elongated morphology), defined 14 genes; two of these corresponded to the previously described genes GRR1 and CDC12. Genetic interactions between mutant alleles suggest that several ELM genes play roles in the same physiological process. The cell and colony morphology and growth properties of many elm mutant strains are similar to those of wild-type yeast strains after differentiation in response to nitrogen limitation into the pseudohyphal form. Each elm mutation resulted in multiple characteristics of pseudohyphal cells, including elongated cell shape, delay in cell separation, simultaneous budding of mother and daughter cells, a unipolar budding pattern, and/or the ability to grow invasively beneath the agar surface. Mutations in 11 of the 14 ELM gene loci potentiated pseudohyphal differentiation in nitrogen-limited medium. Thus, a subset of the ELM genes are likely to affect control or execution of a defined morphologic differentiation pathway in S. cerevisiae.     

Cell adsorption control by culture conditions

Summary Phosphate supply to growingCorynebacterium glutamicum (i.e. their phosphorus content) was found to have a distinct influence on cell wall properties, resulting in a variation of flocculation and adsorption behaviour of the bacteria. Cells saturated with phosphate are hydrophobic and show a high tendency to flocculate and to adsorb on treated glass surfaces due to hydrophobic interactions. Phosphate depletion of the cells leads to a more hydrophilic surface character and a comparatively low ability to flocculate and to adhere. The net surface charge ofC. glutamicum is not much affected by their phosphorus content. As phosphate depletion (down to a phosphorus content of about 20% of the saturation value) was shown to have no influence on growth rate and on specific 1-leucine productivity, the inducible variation of the surface properties ofC. glutamicum can be exploited to control a continuous reactor with adsorbed cells.     

Chemical modifications of the cell-surface components of Lactobacillus fermentum FTPT 1405 and their effect on the flocculation of Saccharomyces cerevisiae

The effect of treatment of Lactobacillus fermentum with several protein- and carbohydrate-modifying reagents on the bacterium's ability to flocculate Saccharomyces cerevisiae was investigated. The proteinaceous nature of the cell-surface components of L. fermentum which are responsible for floc formation was confirmed by inactivation of floc formation following photo-irradiation, with Methylene Blue or Rose Bengal as sensitizer, or acylation with acetic anhydride, maleic anhydride or acetylimidazole, and by the reaction of the components with nitrous acid, I₂ and performic acid.The phenolic hydroxyl group of tyrosine and the indole group of tryptophan appear essential for flocculation. Proteinaceous components of the yeast cell surface and carbohydrate components on the bacterial cell surface were not required for flocculation but carbohydrate residues on the yeast surface were essential.