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Appl Environ Microbiol


Title:Volatile Aroma Compound Production Is Affected by Growth Rate in S. cerevisiae
Author(s):Visinoni F; Zhang P; Hollywood KA; Carlin S; Vrhovsek U; Winterburn J; Delneri D;
Address:"Manchester Institute of Biotechnology, University of Manchestergrid.5379.8, Manchester, United Kingdom. Foundation Edmund Mach, San Michele all' Adige, Trento, Italy. Department of Chemical Engineering, The University of Manchester, grid.5379.8Manchester, United Kingdom"
Journal Title:Appl Environ Microbiol
Year:2022
Volume:20221115
Issue:23
Page Number:e0150922 -
DOI: 10.1128/aem.01509-22
ISSN/ISBN:1098-5336 (Electronic) 0099-2240 (Print) 0099-2240 (Linking)
Abstract:"The initial growth rate of a yeast strain is a key parameter in the production of fermented beverages. Fast growth is linked with higher fermentative capacity and results in less slow and stuck fermentations unable to reach the expected final gravity. As concentrations of metabolites are in a constant state of flux, quantitative data on how growth rate affects the production of aromatic compounds becomes an important factor for brewers. Chemostats allow to set and keep a specific dilution rate throughout the fermentation and are ideal system to study the effect of growth on aroma production. In this study, we ran chemostats alongside batch and fed-batch cultures, compared volatile profiles detected at different growth rates, and identified those affected by the different feeding profiles. Specifically, we quantified six abundant aroma compounds produced in anaerobic glucose-limited continuous cultivations of S. cerevisiae at different dilution rates. We found that volatile production was affected by the growth rate in four out of six compounds assayed, with higher alcohols and esters following opposite trends. Batch and fed-batch fermentations were devised to study the extent by which the final concentration of volatile compounds is influenced by glucose availability. Compared with the batch system, fed-batch fermentations, where the yeast growth was artificially limited by a slow constant release of nutrients in the media, resulted in a significant increase in concentration of higher alcohols, mirroring the results obtained in continuous fermentations. This study paves the way to further process development optimization for the production of fermented beverages. IMPORTANCE The production of fermentation beverages will need to quickly adapt to changes in both the climate and customer demands, requiring the development of new strains and processes. Breakthroughs in the field are hindered by the limited knowledge on the interplay between physiology and aroma compound production in yeast. No quantitative data on how growth rate affects aroma profile is available in the literature to guide optimization of the complex flavors in fermented beverages. In this study, we exploited the chemostat system, alongside with batch and fed-batch cultures, to compare volatile profiles at different growth rates. We identified the aromatic compounds affected by the different feeding profiles and nutrient limitations. Moreover, we uncovered the correlation between yeast growth, esters, and higher alcohols production. This study showcases the potential of the application of feeding profiles for the manipulation of aroma in the craft beverage industry"
Keywords:*Saccharomyces cerevisiae/metabolism Odorants Fermentation Batch Cell Culture Techniques Alcohols/metabolism Glucose/metabolism *Volatile Organic Compounds/metabolism aromatic compounds chemostat cultures yeast;
Notes:"MedlineVisinoni, Federico Zhang, Penghan Hollywood, Katherine A Carlin, Silvia Vrhovsek, Urska Winterburn, James Delneri, Daniela eng BB/M017702/1/BB_/Biotechnology and Biological Sciences Research Council/United Kingdom BB/R013497/1/BB_/Biotechnology and Biological Sciences Research Council/United Kingdom Research Support, Non-U.S. Gov't 2022/11/16 Appl Environ Microbiol. 2022 Dec 13; 88(23):e0150922. doi: 10.1128/aem.01509-22. Epub 2022 Nov 15"

 
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