Aims: To test indigenous Saccharomyces cerevisiae as starters to produce cachaça in large‐scale in a traditional distillery, establishing the period in which, each strain predominates in the vats, chemical composition and sensory attributes of the beverage, and to compare these data with vats prepared by spontaneous fermentation.
Methods and Results: Strains were evaluated for kinetic fermentation parameters, permanence in vats, volatile compound production, and sensory attributes for the cachaças produced. In general the vats in which starter strains were used, no difference in restriction mitochondrial DNA (mtDNA) profiles of isolates was observed. In the vats in which spontaneous fermentation occurred, different mtDNA restriction profiles were observed. Most of the non‐Saccharomyces species isolated could be regarded as contaminants of fermentation. All cachaças produced, despite being recently distilled and with differences in their chemical composition, were well accepted by the judges.
Conclusions: It was possible to detect the differences in the fermentation capacities of S. cerevisiae strains, in their relative abundances at different time periods, and in the chemical compositions and sensory attributes of the resulting beverages.
Significance and Impact of the Study: The indigenous strains utilized to prepare cachaça have shown potential to be used as starters of this traditional fermentation process.
Nine indigenous cachaça Saccharomyces cerevisiae strains and one wine strain were compared for their trehalose metabolism characteristics under non-lethal (40 degrees C) and lethal (52 degrees C) heat shock, ethanol shock and combined heat and ethanol stresses. The yeast protection mechanism was studied through trehalose concentration, neutral trehalase activity and expression of heat shock proteins Hsp70 and Hsp104. All isolates were able to accumulate trehalose and activate neutral trehalase under stress conditions. No correlation was found between trehalose levels and neutral trehalase activity under heat or ethanol shock. However, when these stresses were combined, a positive relationship was found. After pre-treatment at 40 degrees C for 60 min, and heat shock at 52 degrees C for 8 min, eight strains maintained their trehalose levels and nine strains improved their resistance against lethal heat shock. Among the investigated stresses, heat treatment induced the highest level of trehalose and combined heat and ethanol stresses activated the neutral trehalase most effectively. Hsp70 and Hsp104 were expressed by all strains at 40 degrees C and all of them survived this temperature although a decrease in cell viability was observed at 52 degrees C. The stress imposed by more than 5% ethanol (v/v) represented the best condition to differentiate strains based on trehalose levels and neutral trehalase activity. The investigated S. cerevisiae strains exhibited different characteristics of trehalose metabolism, which could be an important tool to select strains for the cachaça fermentation process.
During the production of traditional cachaça (alembic´s cachaça), contamination of the fermented must is one of the factors leading to economic losses in the beverage manufacturing industry. The diversity of bacterial populations and the role of these microorganisms during the cachaça production process are still poorly understood in Brazil. In our work, the fermentation process was followed in two distilleries located in the state of Minas Gerais. The objective of this work was to identify the populations of lactic acid bacteria present during cachaça fermentation using physiological and molecular methods. Lactic acid bacteria were isolated in high frequencies during all of the fermentative processes, and Lactobacillus plantarum and L.casei were the most prevalent species. Other lactic acid bacteria were found in minor frequencies, such as L. ferintoshensis, L. fermentum, L. jensenii, L. murinus, Lactococcus lactis, Enterococcus sp. and Weissella confusa. These bacteria could contribute to the increase of volatile acidity levels or to the production of compounds that could influence the taste and aroma of the beverage.
Six Saccharomyces cerevisiae strains from cachaça fermentation were characterized for biomass, ethanol, glycerol, and acetic acid yields, as well as productivity. Three strains presenting the best fermentation parameters were selected for cachaça production. The experiments were carried out in an industrial distillery that distills this beverage in a stainless steel column, and in a traditional distillery that uses copper alembic for distillation. The permanence of the selected strains was studied by restriction fragment analysis of mitochondrial DNA. Strains UFMG-A1007 and UFMG-A2097 were prevalent in the vats during the 5 days of the fermentation period. Non-Saccharomyces strains were isolated during the entire fermentation period. In general, the cachaças produced in the stainless steel column had the highest concentrations of volatile acidity, acetaldehyde, esters, and higher alcohols. Both cachaças did not differ statistically in aroma, taste, and overall impression. The use of these indigenous S. cerevisiae strains as starter ferment could improve the sensory attributes of both industrial and traditional cachaças.
Fermentation-induced loss of stress resistance in yeast is an important phenotype from an industrial point of view. It hampers optimal use of frozen dough applications as well as high gravity brewing fermentations because these applications require stress-tolerant yeast strains during active fermentation. Different mutants (e.g. fil1, an adenylate cyclase mutant CYR1lys1682) that are affected in this loss of stress resistance have been isolated, but so far the identification of the target genes important for the increased tolerance has failed. Previously we have shown that neither trehalose nor Hsp104 nor STRE-controlled genes are involved in the higher stress tolerance of the fil1 mutant. The contribution of other putative downstream factors of the PKA pathway was investigated and here we show that the small heat-shock protein Hsp26 is required for the high heat stress tolerance of the fil1 mutant, both in stationary phase cells as well as during active fermentation.
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