Metabolism of Schizosaccharomyces pombe under reduced osmotic stress conditions afforded by fed-batch alcoholic fermentation of white grape must.

Strains of Schizosaccharomyces pombe are being increasingly investigated with regards to their grape winemaking potential either in combination with the typical production yeast, Saccharomyces cerevisiae, or in monoseptic fermentations. Their ethanol tolerance and ability to degrade L-malic acid is oenologically convenient but contrasts with the comparatively high acetic acid and acetaldehyde formation potential which is considered undesirable, especially in white winemaking. The purpose of this work was to investigate the performance of a selected S. pombe strain in monoseptic femerntations of white grape must. Traditional batch fermentations were compared with an innovative and automated fed-batch fermentation technique were sugar concentrations are kept low during fermentations to decrease sugar induced osmotic stress. Because of its known effect on growth and ethanol tolerance, the effect of Mg was also tested. While Mg supplementation was not shown to significantly influence residual values of sugars, ethanol, glycerol, organic acids and acetaldehyde, the application of the fed-batch technique led to a fundamental change in yeast physiology. While glycerol values were only slightly reduced, the fed-batch approach allowed obtaining wines devoid of acetic acid whose levels were considerable in wines produced by the traditional batch technique (0.6 g/L). The work demonstrates that the acetic acid metabolism of S. pombe is associated to sugar induced osmotic stress such as for S. cerevisiae, too, and may be controlled by application of suitable fermentation techniques for winemaking.

Characterization of the response to low pH of Lactobacillus casei ΔRR12, a mutant strain with low D-alanylation activity and sensitivity to low pH.

AIMS: To identify the differences that account for the acid sensitivity of Lactobacillus casei ΔRR12. RR12 controls the expression of the dlt operon, and its inactivation leads to a diminished teichoic acid D-alanylation activity. To this end, a comparison of its response of ΔRR12 to low pH with the parental strain Lact. casei BL23 was carried out. METHODS AND RESULTS: The ability to induce an acid tolerance response (ATR), fatty acid (FA) composition and proteome changes induced in both strains in response to acid were investigated. Results obtained showed that both strains induce a growth-phase-dependent ATR. However, significant differences in the content of FAs and membrane-associated proteins were detected. CONCLUSIONS: The greater abundance of cytoplasmic proteins in the membrane fraction of the mutant strain ΔRR12 suggests an increased permeability of the cell membrane in this strain. SIGNIFICANCE AND IMPACT OF THE STUDY: The analysis of the response to low pH of strain ΔRR12 indicated that the inactivation of TCS12 affected the content of FAs and proteins associated to the cell envelope. Increased abundance of cytoplasmic proteins suggested that low alanylation of teichoic acids affected the permeability of the cell membrane and possibly accounts for the acid sensitivity of strain ΔRR12.

Functional analysis to identify genes in wine yeast adaptation to low-temperature fermentation.

AIMS: To identify genes and proteins involved in adaptation to low-temperature fermentations in a commercial wine yeast. METHODS AND RESULTS: Nine proteins were identified as representing the most significant changes in proteomic maps during the first 24 h of fermentation at low (13°C) and standard temperature (25°C). These proteins were mainly involved in stress response and in glucose and nitrogen metabolism. Transcription analysis of the genes encoding most of these proteins within the same time frame of wine fermentation presented a good correlation with proteomic data. Knockout and overexpressing strains of some of these genes were constructed and tested to evaluate their ability to start the fermentation process. The strain overexpressing ILV5 improved its fermentation activity in the first hours of fermentation. This strain showed a quicker process of mitochondrial degeneration, an altered intracellular amino acid profile and laxer nitrogen catabolite repression regulation. CONCLUSIONS: The proteomic and transcriptomic analysis is useful to detect key molecular adaptation mechanisms of biotechnological interest for industrial processes. ILV5 gene seems to be important in wine yeast adaptation to low-temperature fermentation. SIGNIFICANCE AND IMPACT OF THE STUDY: This study provides information that might help improve the future performance of wine yeast, either by genetic modification or by adaptation during industrial production.

Vitality enhancement of the rehydrated active dry wine yeast.

In winemaking, spontaneous grape must fermentations have been replaced by inoculation of commercial active dry wine yeast (ADWY). Yeast rehydration is the key to avoiding stuck and sluggish fermentations. Despite the importance of this step, not enough is known about what this process implies for winemaking as a whole or about what kind of practices could help to improve it. The main aim of this study is to determine the best yeast rehydration conditions for ensuring good cell viability and vitality before inoculation into the must. The experimental rehydration media in this study can be divided into four groups: carbon and nitrogen compounds, metallic ions, oxidant and antioxidant agents, and membrane fluidity agents. We studied the biochemical and biophysical behaviour of ADWY after rehydration in the various media under oenological conditions, i.e. incubation at 37 degrees C for 30 min. The viability of rehydrated yeast cells was evaluated by plating, and assessed by fluorescence microscopy and flow cytometry. The vitality of rehydrated cells was estimated by indirect impedance. The rehydrating solution complemented with magnesium provided the best vitality rate because the time taken to reach the activity threshold was cut by two thirds. This improvement was also illustrated by the less time needed to stop the leakage of intracellular compounds during the rehydration process.

Application of molecular methods for the differentiation of acetic acid bacteria in a red wine fermentation.

AIMS: To apply rapid and reliable molecular techniques for typing acetic acid bacteria and studying their population dynamics during wine-making processes. METHODS AND RESULTS: We tested the usefulness of the Enterobacterial Repetitive Intergenic Consensus-PCR (ERIC-PCR) and Repetitive Extragenic Palindromic-PCR (REP-PCR) techniques with reference strains of most of the species of acetic acid bacteria. We obtained exclusive patterns for each strain with the ERIC-PCR technique, proving the utility for characterizing below species level. REP-PCR technique was not as adequate for this purpose because some strains yielded identical fingerprint. One hundred twenty isolates from a commercial red wine fermentation were fingerprinted using both techniques. We detected a high degree of strain diversity in the first stage of fermentation that decreased throughout the process. However, several strains and species were dominant in the alcoholic fermentation phases. The identification of different strains or genotypes at the species level was carried out by restriction analysis of the 16S ribosomal DNA gene. Gluconobacter oxydans dominated the fresh must, while Acetobacter aceti was the only isolated species at the end of the process. Gluconacetobacter hansenii and G. liquefaciens were also isolated in significant numbers at the beginning of fermentation. CONCLUSIONS: ERIC-PCR and REP-PCR techniques proved useful for characterizing strains of acetic acid bacteria. SIGNIFICANCE AND IMPACT OF THE STUDY: The availability of molecular techniques for a fast and reliable genotypic characterization should increase our knowledge of the ecology of acetic acid bacteria and determine more accurately their growth behaviour during various stages of vinification.

Effect of phenolic compounds on the co-metabolism of citric acid and sugars by Oenococcus oeni from wine.

AIMS: The goal of this study was to examine the growth of Oenococcus oeni in the presence of phenolic compounds under wine conditions and to see how these compounds affect bacterial metabolism. METHODS AND RESULTS: Phenolic compounds have been added to a basal medium that simulates the composition of wine. Fifty milligrams per litre or more of phenolic compounds stimulated bacterial growth. Oenococcus oeni seemed to use citric acid and trehalose, if they were present, before glucose and fructose. Citrate was completely exhausted in three days and the yield of acetate was higher when phenolic compounds were present. CONCLUSIONS: Phenolic compounds reduced the rate of sugar consumption and enhanced citric acid consumption, increasing the yield of acetic acid. SIGNIFICANCE AND IMPACT OF THE STUDY: This study allows a better knowledge of co-metabolism of citric acid and sugars by O. oeni in the presence of phenolic compounds of wine.

Lactobacillic acid accumulation in the plasma membrane of Oenococcus oeni: a response to ethanol stress?

It is known that ethanol strongly interferes with the development and activity of lactic acid bacteria in wine. In this work, it was observed that membrane composition was dependent of ethanol concentration and cell physiological state. The protein electrophoretic profile was modified in the membranes of Oenococcus oeni cultured in presence of 8 and 10% ethanol. Concerning the membrane lipid composition, it was observed that O. oeni maintained a high level of phospholipid biosynthesis via the relative increased biosynthesis of phosphoethanolamine and sphingomyelin in presence of ethanol. On the other hand, ethanol induced an increase in the membrane lactobacillic acid percentage at the expense of cis-vaccenic acid. This increased synthesis of lactobacillic acid appears as the more significant change induced by ethanol in O. oeni membrane. The increase of lactobacillic acid in the membrane of O. oeni clearly appears as a factor that provides protection against the toxic effect of ethanol, balancing the increase of membrane fluidity normally attributed to ethanol. The results presented in this paper constitute evidence that lactobacillic acid may have a part in the survival and or adaptive mechanisms developed by O. oeni under culture adverse conditions, allowing these bacteria to maintain their activity in the presence of ethanol, namely performing malolactic fermentation in wine.

Yeast population dynamics in spontaneous fermentations: comparison between two different wine-producing areas over a period of three years.

Yeast ecology, biogeography and biodiversity are important and interesting topics of research. The population dynamics of yeasts in several cellars of two Spanish wine-producing regions was analysed for three consecutive years (1996 to 1998). No yeast starter cultures had been used in these wineries which therefore provided an ideal winemaking environment to investigate the dynamics of grape-related indigenous yeast populations. Non-Saccharomyces yeast species were identified by RFLPs of their rDNA, while Saccharomyces species and strains were identified by RFLPs of their mtDNA. This study confirmed the findings of other reports that non-Saccharomyces species were limited to the early stages of fermentation whilst Saccharomyces dominated towards the end of the alcoholic fermentation. However, significant differences were found with previous studies, such as the survival of non-Saccharomyces species in stages with high alcohol content and a large variability of Saccharomyces strains (a total of 112, all of them identified as Saccharomyces cerevisiae) with no clear predominance of any strain throughout all the fermentation, probably related to the absence of killer phenotype and lack of previous inoculation with commercial strains.

Identification of acetic acid bacteria by restriction fragment length polymorphism analysis of a PCR-amplified fragment of the gene coding for 16S rRNA.

Acetic acid bacteria (AAB) irreversibly spoil wines and represent a serious problem. Limited studies on the ecology of AAB during winemaking have been done due to the lack of rapid and precise techniques for their identification. RFLP analysis of PCR-amplified fragment of 16S rDNA was performed on AAB reference strains. The amplified rDNAs were approximately 870-bp long for all AAB species while no amplicons were detected for lactic acid bacteria and yeasts. Out of the four restriction enzymes tested, TaqI was the most efficient one and divided the studied AAB into six groups. However, complete differentiation among collection strains of Acetobacter pasteurianus and Gluconoacetobacter hansenii was not possible.

Influence of phenolic compounds on the physiology of Oenococcus oeni from wine.

This study shows that the growth of Oenococcus oeni CECT 4100 in a synthetic medium is affected by phenolic compounds in different ways, depending on their type and concentration. Generally they have no effects at low concentrations, but hydroxycinnamic acids are inhibitory at high concentrations. Malolactic fermentation was stimulated in the presence of catechin and quercetin, but increasingly delayed with increasing amounts of p-coumaric acid. Gallic acid appeared to delay or inhibit the formation of acetic acid from citric acid. This could lead to a better control of malolactic fermentation and suppress the increase in volatile acidity, which is undesirable in the wine-making process.

Effect of triazole fungicides on lipid metabolism of Saccharomyces cerevisiae.

The triazole fungicide (Flusilazole) modified the sterol content of Saccharomyces cerevisiae. The plasma membrane fluidity was altered by the presence of methyl sterol which increased with the flusilazole concentration. On the other hand, the short free fatty acids (C6 to C14) and the unsaturated free fatty acids increased in the cells, while the short free fatty acids decreased in the medium.