Genetic Improvement of Wine Yeast

One of the most prominent consequences of global climate warming for the wine industry is a clear increase of the sugar content in grapes, and thus the alcohol level in wines. Among the several approaches to address this important issue, this review focuses on biotechnological solutions, mostly relying on the selection and improvement of wine yeast strains for reduced ethanol yields. Other possibilities are also presented. Researchers are resorting to both S. cerevisiae and alternative wine yeast species for the lowering of alcohol yields. In addition to the use of selected strains under more or less standard fermentation conditions, aerobic fermentation is increasingly being explored for this purpose. Genetic improvement is also playing a role in the development of biotechnological tools to counter the increase in the wine alcohol levels. The use of recombinant wine yeasts is restricted to research, but its contribution to the advancement of the field is still relevant. Furthermore, genetic improvement by non-GMO approaches is providing some interesting results, and will probably result in the development of commercial yeast strains with a lower alcohol yield in the near future. The optimization of fermentation processes using natural isolates is, anyway, the most probable source of advancement in the short term for the production of wines with lower alcohol contents.

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A Saccharomyces cerevisiae wine yeast strain overproducing mannoproteins selected through classical genetic methods

OENO One ◽

10.20870/oeno-one.2010.44.4.1475 ◽

2010 ◽

Vol 44 (4) ◽

pp. 243 ◽

Cited By ~ 2

Author(s):

Daniel González-Ramos ◽

A. Muñoz ◽

Anne Ortiz-Julien ◽

Antonio Tomás Palacios ◽

José María Heras ◽

...

Keyword(s):

Cell Wall ◽

Mutant Strain ◽

Concanavalin A ◽

Yeast Strain ◽

Genetic Improvement ◽

Wine Yeast ◽

Red Wines ◽

Uv Mutagenesis ◽

Yeast Strains ◽

Wine Yeast Strain

Aims: Developing, by classical genetic methods, new wine yeast strains showing improved release of mannoproteins during wine fermentation, as well as suitable selection procedures for this purpose. These strains would be useful to improve quality characters associated to wine mannoprotein content.Methods and results: UV mutagenesis was used for genetic improvement of the industrial wine yeast strain ADY1. Cell wall-related phenotypes were used as primary selection criteria; an additional screening procedure was developed based on the detection of the released mannoproteins by hybridization with peroxidase-labeled Concanavalin A. Mannoprotein overproduction was assessed in laboratory media as well as in grapevine juice. One mutant strain, renamed HPS, was selected using these criteria. HPS showed increased mannoprotein release in different culture media, including natural must. Moreover, white wines fermented with this improved strain were less susceptible to protein haze than equivalent wines fermented with the original ADY1 strain. Red wines fermented with the mutant strain were also polysaccharide-enriched as compared to the original one.Conclusion: No clear correlation between a specific cell wall-related phenotype, or a combination of them, and improved release of polysaccharides by yeast random mutants could be established, and not all strains identified by in vitro assays as mannoprotein overproducing mutants were found positive for mannoprotein release in industrial conditions. Nevertheless, UV mutagenesis, combined with Concanavalin A detection, seems to be a viable way to improve mannoprotein release by industrial wine yeast strains.Significance and impact of the study: This study is one of the few recent reports on genetic improvement of wine yeast strains by non-recombinant genetic tools. It shows that mannoprotein release can be genetically improved and, for the first time, describes a successful selection procedure for such a complex character. These strains are potentially useful for the improvement of mannoprotein-related characters of white and red wines.

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