The nature of the toxic compounds produced by Saccharomyces cerevisiae CCMI 885 that induce the early death of Hanseniaspora guilliermondii during mixed fermentations, as well as their ability to ...inhibit the growth of other non-Saccharomyces wine-related strains, was investigated. The killing effect of mixed supernatants towards H. guilliermondii was inactivated by protease treatments, thus revealing the proteinaceous nature of the toxic compounds. Analysis of the protein pattern of mixed supernatants on Tricine SDS-PAGE showed that this S. cerevisiae strain secretes peptides (<10 kDa), which were detected only when death of H. guilliermondii was already established. Death-inducing supernatants were ultrafiltrated by 10 and 2 kDa membranes, respectively, and the inhibitory effect of those permeates were tested in H. guilliermondii cultures. Results indicated that the (2-10) kDa protein fraction of those supernatants seemed to contain antimicrobial peptides active against H. guilliermondii. Thus, the (2-10) kDa protein fraction was concentrated and its inhibitory effect tested against strains of Kluyveromyces marxianus, Kluyveromyces thermotolerans, Torulaspora delbrueckii and H. guilliermondii. Under the growth conditions used for these tests, the (2-10) kDa protein fraction of S. cerevisiae CCMI 885 supernatants exhibited a fungistatic effect against all the strains and a fungicidal effect against K. marxianus.
Winemaking, brewing and baking are some of the oldest biotechnological processes. In all of them, alcoholic fermentation is the main biotransformation and Saccharomyces cerevisiae the primary ...microorganism. Although a wide variety of microbial species may participate in alcoholic fermentation and contribute to the sensory properties of end-products, the yeast S. cerevisiae invariably dominates the final stages of fermentation. The ability of S. cerevisiae to outcompete other microbial species during alcoholic fermentation processes, such as winemaking, has traditionally been ascribed to its high fermentative power and capacity to withstand the harsh environmental conditions, i.e. high levels of ethanol and organic acids, low pH values, scarce oxygen availability and depletion of certain nutrients. However, in recent years, several studies have raised evidence that S. cerevisiae, beyond its remarkable fitness for alcoholic fermentation, also uses defensive strategies mediated by different mechanisms, such as cell-to-cell contact and secretion of antimicrobial peptides, to combat other microorganisms. In this paper, we review the main physiological features underlying the special aptitude of S. cerevisiae for alcoholic fermentation and discuss the role of microbial interactions in its dominance during alcoholic fermentation, as well as its relevance for winemaking.
Real-time detection of microorganisms involved in complex microbial process, such as wine fermentations, and evaluation of their physiological state is crucial to predict whether or not those ...microbial species will be able to impact the final product. In the present work we used a direct live/dead staining (LDS) procedure combined with fluorescence in situ hybridization (FISH) to simultaneously assess the identity and viability of Saccharomyces cerevisiae (Sc) and Hanseniaspora guilliermondii (Hg) during fermentations performed with single and mixed cultures. The population evolution of both yeasts was determined by plating and by LDS combined with species-specific FISH-probes labeled with Fluorescein. Since the FISH method involves the permeabilization of the cell membrane prior to hybridization and that it may influence the free diffusion of PI in and out of the cells, we optimized the concentration of this dye (0.5μg of PI per 106 cells) for minimal diffusion (less than 2%). Fluorescent cells were enumerated by hemocytometry and flow cytometry. Results showed that the survival rate of Sc during mixed cultures was high throughout the entire process (60% of viable cells at the 9th day), while Hg began to die off at the 2nd day, exhibited 98% of dead cells at the 3rd day (45g/l of ethanol) and became completely unculturable at the 4th day. However, under single culture fermentation the survival rate and culturability of Hg decreased at a much slower pace, exhibiting at the 7th day (67g/l of ethanol) 8.7×104CFU/ml and 85% of dead cells. Thus, our work demonstrated that the LDS–FISH method is able to simultaneously assess the viability and identity of these wine-related yeast species during alcoholic fermentation in a fast and reliable way. In order to validate PI-staining as a viability marker during alcoholic fermentation, we evaluated the effect of ethanol on the membrane permeability of Sc and Hg cells, as well as their capacity to recover membrane integrity after being exposed to different levels of ethanol (1%, 6%, 10%, 12% v/v). Results showed that while Sc cells were able to recover membrane integrity after ethanol exposure, Hg cells were not. However, under alcoholic fermentation Sc cells didn't recover membrane integrity after the mid-term (4–5days) of alcoholic fermentation.
► S. cerevisiae showed high survival rates throughout alcoholic fermentation. ► Sublethally-injured S. cerevisiae cells recovered membrane integrity after ethanol exposure. ► LDS–FISH coupled with flow cytometry is a high throughput method suitable for microbial control.
Traditionally, it was assumed that non-Saccharomyces (NS) yeasts could only survive in the early stages of alcoholic fermentations. However, recent studies applying culture-independent methods have ...shown that NS populations persist throughout the fermentation process. The aim of the present work was to analyze and quantify Saccharomyces cerevisiae (Sc) and Hanseniaspora guilliermondii (Hg) populations during alcoholic fermentations by plating and culture-independent methods, such as fluorescence in situ hybridization (FISH) and quantitative PCR (QPCR). Species-specific FISH probes labeled with fluorescein (FITC) were used to directly hybridize Sc and Hg cells from single and mixed cultures that were enumerated by epifluorescence microscopy and flow cytometry. Static and agitated fermentations were performed in synthetic grape juice and cell density as well as sugar consumption and ethanol production were determined throughout fermentations. Cell density values obtained by FISH and QPCR revealed the presence of high populations (107–108 cells/ml) of Sc and Hg throughout fermentations. Plate counts of both species did not show significant differences with culture-independent results in pure cultures. However, during mixed fermentations Hg lost its culturability after 4–6 days, while Sc remained culturable (about 108 cells/ml) throughout the entire fermentation (up to 10 days). The rRNA content of cells during mixed fermentations was also analyzed by flow cytometry in combination with FISH probes. The fluorescence intensity conferred by the species-specific FISH probes was considerably lower for Hg than for Sc. Moreover, the rRNA content of Hg cells, conversely to Sc cells, remained almost unchanged after boiling, which showed that rRNA stability is species-dependent.
► Culture-independent methods (FISH and QPCR) to monitor Sc and Hg populations. ► Flow cytometry in combination with FISH probes to quantify the rRNA content of cells. ► The cellular density of Hg was much lower as determined by plating or by both FISH and QPCR. ► The stability of the rRNA of boiled cells showed to be species-dependent.
To analyse the yeast population diversity during wine fermentations, specific fluorescein-labelled oligonucleotide probes targeted to the D1/D2 region of the 26S rRNA of different yeast species known ...to occur frequently in this environment were designed and tested with reference strains. The probes were then used to identify wine must isolates and to follow, in combination with plate counts, the evolution of yeast populations in two winery fermentations of white and red grape musts. In both cases, a high diversity of non-
Saccharomyces yeast species was detected, including
Candida stellata,
Hanseniaspora uvarum,
H. guilliermondii,
Kluyveromyces marxianus,
K. thermotolerans and
Torulaspora delbrueckii. Some of these species (e.g.,
K. marxianus,
K. thermotolerans and
T. delbrueckii) were present in significant amounts during the tumultuous fermentation stage, despite the predominance of
Saccharomyces cerevisiae cells following the inoculation of the wine musts with a starter strain. To further clarify the yeast population dynamics at the late phase of the fermentations, and because winery conditions do not allow a reliable control of experimental variables, strains isolated from the industrial musts were used to conduct two laboratory microvinifications in synthetic grape juice, using different ratios of
S. cerevisiae/non-
Saccharomyces in the inocula. Under these conditions, the results were similar to those obtained in the winery, showing a yeast profile with mixed species throughout the first fermentation stage, i.e. until about 40–50% of the total sugar was consumed. Non-
Saccharomyces yeasts were outgrown by
S. cerevisiae only after ethanol reached concentrations around 4–5% (
v
/
v), which argues in favour of a potential important role of non-
Saccharomyces in the final organoleptic characteristics of the wine.
The industrial use of starter cultures containing a consortium of different strains from the same species is nowadays seen as a possible strategy to enhance the organoleptic complexity of wines. To ...assess the relative contribution of each strain to the final product it is essential to quantify population evolution during the wine fermentation process, which requires strain-specific methods to identify and differentiate each strain. In the present study, a molecular method based on analysis of the polymorphisms exhibited by the PCR-amplification of the delta regions of three Saccharomyces cerevisiae strains was developed. A set of three pairs of primers (delta1-delta2, delta12-delta2, delta12-delta21) was used for each strain, and analysis of the resulting polymorphism patterns showed that the delta12-delta2 primer pair exhibited the highest resolution and discriminatory power. Thus, this pair of primers was selected to monitor the population evolution of a laboratory-scale wine fermentation performed in synthetic grape juice that was inoculated with similar amounts of each strain. The results showed that all strains grew together during the exponential growth phase (2-3 days) and maintained high cell density values (10⁶-10⁷ cfu ml⁻¹) throughout the stationary growth phase without significantly changing their relative population proportion, thus indicating that each strain can influence the chemical composition and final flavor of wine, albeit at different levels. This study also showed that PCR-amplification of DNA delta sequences of S. cerevisiae strains is a reproducible, strain-specific and simple method that can be used successfully to monitor yeast strain population dynamics during wine fermentations.