Ethanol production and maximum cell growth are highly correlated with membrane lipid composition during fermentation as determined by lipidomic analysis of 22 saccharomyces cerevisiae strains
Ethanol production and maximum cell growth are highly correlated with membrane lipid composition during fermentation as determined by lipidomic analysis of 22 saccharomyces cerevisiae strains
Optimizing ethanol yield during fermentation is important for efficient production of fuel alcohol, as well as wine and other alcoholic beverages. However, increasing ethanol concentrations during fermentation can create problems that result in arrested or sluggish sugar-to-ethanol conversion. The fundamental cellular basis for these problem fermentations, however, is not well understood. Small-scale fermentations were performed in a synthetic grape must using 22 industrial Saccharomyces cerevisiae strains (primarily wine strains) with various degrees of ethanol tolerance to assess the correlation between lipid composition and fermentation kinetic parameters. Lipids were extracted at several fermentation time points representing different growth phases of the yeast to quantitatively analyze phospholipids and ergosterol utilizing atmospheric pressure ionization-mass spectrometry methods. Lipid profiling of individual fermentations indicated that yeast lipid class profiles do not shift dramatically in composition over the course of fermentation. Multivariate statistical analysis of the data was performed using partial least-squares linear regression modeling to correlate lipid composition data with fermentation kinetic data. The results indicate a strong correlation (R2=0.91) between the overall lipid composition and the final ethanol concentration (wt/wt), an indicator of strain ethanol tolerance. One potential component of ethanol tolerance, the maximum yeast cell concentration, was also found to be a strong function of lipid composition (R2=0.97). Specifically, strains unable to complete fermentation were associated with high phosphatidylinositol levels early in fermentation. Yeast strains that achieved the highest cell densities and ethanol concentrations were positively correlated with phosphatidylcholine species similar to those known to decrease the perturbing effects of ethanol in model membrane systems.
91-104
Henderson, Clark M.
bb0fb4ed-1306-4390-b2e3-d6830d08d886
Lozada-Contreras, Michelle
40c46f6c-e1f5-4c7d-a16e-37329a5cf657
Jiranek, Vladimir
8e5a8dfd-f5b2-43e3-928b-11dff324abc7
Longo, Marjorie L.
9d3f3726-a0a0-43cd-80d7-af58802eb2ef
Block, David E.
811b28a7-13ec-4867-8407-6c7e3c552aa5
January 2013
Henderson, Clark M.
bb0fb4ed-1306-4390-b2e3-d6830d08d886
Lozada-Contreras, Michelle
40c46f6c-e1f5-4c7d-a16e-37329a5cf657
Jiranek, Vladimir
8e5a8dfd-f5b2-43e3-928b-11dff324abc7
Longo, Marjorie L.
9d3f3726-a0a0-43cd-80d7-af58802eb2ef
Block, David E.
811b28a7-13ec-4867-8407-6c7e3c552aa5
Henderson, Clark M., Lozada-Contreras, Michelle, Jiranek, Vladimir, Longo, Marjorie L. and Block, David E.
(2013)
Ethanol production and maximum cell growth are highly correlated with membrane lipid composition during fermentation as determined by lipidomic analysis of 22 saccharomyces cerevisiae strains.
Applied and Environmental Microbiology, 79 (1), .
(doi:10.1128/AEM.02670-12).
Abstract
Optimizing ethanol yield during fermentation is important for efficient production of fuel alcohol, as well as wine and other alcoholic beverages. However, increasing ethanol concentrations during fermentation can create problems that result in arrested or sluggish sugar-to-ethanol conversion. The fundamental cellular basis for these problem fermentations, however, is not well understood. Small-scale fermentations were performed in a synthetic grape must using 22 industrial Saccharomyces cerevisiae strains (primarily wine strains) with various degrees of ethanol tolerance to assess the correlation between lipid composition and fermentation kinetic parameters. Lipids were extracted at several fermentation time points representing different growth phases of the yeast to quantitatively analyze phospholipids and ergosterol utilizing atmospheric pressure ionization-mass spectrometry methods. Lipid profiling of individual fermentations indicated that yeast lipid class profiles do not shift dramatically in composition over the course of fermentation. Multivariate statistical analysis of the data was performed using partial least-squares linear regression modeling to correlate lipid composition data with fermentation kinetic data. The results indicate a strong correlation (R2=0.91) between the overall lipid composition and the final ethanol concentration (wt/wt), an indicator of strain ethanol tolerance. One potential component of ethanol tolerance, the maximum yeast cell concentration, was also found to be a strong function of lipid composition (R2=0.97). Specifically, strains unable to complete fermentation were associated with high phosphatidylinositol levels early in fermentation. Yeast strains that achieved the highest cell densities and ethanol concentrations were positively correlated with phosphatidylcholine species similar to those known to decrease the perturbing effects of ethanol in model membrane systems.
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Published date: January 2013
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Local EPrints ID: 482597
URI: http://eprints.soton.ac.uk/id/eprint/482597
ISSN: 0099-2240
PURE UUID: 67abfd1d-1bda-4e35-b206-0c7409ae4aca
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Date deposited: 10 Oct 2023 17:00
Last modified: 18 Mar 2024 04:12
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Author:
Clark M. Henderson
Author:
Michelle Lozada-Contreras
Author:
Vladimir Jiranek
Author:
Marjorie L. Longo
Author:
David E. Block
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