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Use of a wine yeast deletion collection reveals genes that influence fermentation performance under low-nitrogen conditions

Use of a wine yeast deletion collection reveals genes that influence fermentation performance under low-nitrogen conditions
Use of a wine yeast deletion collection reveals genes that influence fermentation performance under low-nitrogen conditions

A deficiency of nitrogenous nutrients in grape juice can cause stuck and sluggish alcoholic fermentation, which has long been a problem in winemaking. Nitrogen requirements vary between wine yeast strains, and the ability of yeast to assimilate nitrogen depends on the nature and concentration of nitrogen present in the medium. In this study, a wine yeast gene deletion collection (1844 deletants in the haploid AWRI1631 background) was screened to identify genes whose deletion resulted in a reduction in the time taken to utilise all sugars when grown in a chemically defined grape juice medium supplemented with limited nitrogen (75 mg L -1 as a free amino acid mixture). Through micro-scale and laboratory-scale fermentations, 15 deletants were identified that completed fermentation in a shorter time than the wildtype (c.a. 15%-59% time reduction). This group of genes was annotated to biological processes including protein modification, transport, metabolism and ubiquitination (UBC13, MMS2, UBP7, UBI4, BRO1, TPK2, EAR1, MRP17, MFA2 and MVB12), signalling (MFA2) and amino acid metabolism (AAT2). Deletion of MFA2, encoding mating factor-a, resulted in a 55% decrease in fermentation duration. Mfa2Δ was chosen for further investigation to understand how this gene deletion conferred fermentation efficiency in limited nitrogen conditions.

Genome wide screening, Limited nitrogen, Mating a-factor, MFA2, Saccharomyces cerevisiae, Yeast deletion library
1567-1356
Peter, Josephine J.
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Watson, Tommaso L.
cd72a90b-1bec-4517-9831-7c31b958520a
Walker, Michelle E.
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Gardner, Jennifer M.
0d95188b-206d-4817-8437-e163351f6e7f
Lang, Tom A.
483fd372-b7ce-45f4-9198-461ecf47907e
Borneman, Anthony
1489572d-e8df-4476-9629-8ebd4eb2729a
Forgan, Angus
a3cc757b-faa7-4fa1-979a-c2a68ac47b87
Tran, Tina
e8859e70-63ab-44cc-adc1-d2bd84dcb8da
Jiranek, Vladimir
8e5a8dfd-f5b2-43e3-928b-11dff324abc7
Peter, Josephine J.
def5f5fe-5151-4082-9712-ca18e839ea7a
Watson, Tommaso L.
cd72a90b-1bec-4517-9831-7c31b958520a
Walker, Michelle E.
5e8a98ce-9e08-409a-99e4-a0b96a490940
Gardner, Jennifer M.
0d95188b-206d-4817-8437-e163351f6e7f
Lang, Tom A.
483fd372-b7ce-45f4-9198-461ecf47907e
Borneman, Anthony
1489572d-e8df-4476-9629-8ebd4eb2729a
Forgan, Angus
a3cc757b-faa7-4fa1-979a-c2a68ac47b87
Tran, Tina
e8859e70-63ab-44cc-adc1-d2bd84dcb8da
Jiranek, Vladimir
8e5a8dfd-f5b2-43e3-928b-11dff324abc7

Peter, Josephine J., Watson, Tommaso L., Walker, Michelle E., Gardner, Jennifer M., Lang, Tom A., Borneman, Anthony, Forgan, Angus, Tran, Tina and Jiranek, Vladimir (2018) Use of a wine yeast deletion collection reveals genes that influence fermentation performance under low-nitrogen conditions. FEMS Yeast Research, 18 (3), [foy009]. (doi:10.1093/femsyr/foy009).

Record type: Article

Abstract

A deficiency of nitrogenous nutrients in grape juice can cause stuck and sluggish alcoholic fermentation, which has long been a problem in winemaking. Nitrogen requirements vary between wine yeast strains, and the ability of yeast to assimilate nitrogen depends on the nature and concentration of nitrogen present in the medium. In this study, a wine yeast gene deletion collection (1844 deletants in the haploid AWRI1631 background) was screened to identify genes whose deletion resulted in a reduction in the time taken to utilise all sugars when grown in a chemically defined grape juice medium supplemented with limited nitrogen (75 mg L -1 as a free amino acid mixture). Through micro-scale and laboratory-scale fermentations, 15 deletants were identified that completed fermentation in a shorter time than the wildtype (c.a. 15%-59% time reduction). This group of genes was annotated to biological processes including protein modification, transport, metabolism and ubiquitination (UBC13, MMS2, UBP7, UBI4, BRO1, TPK2, EAR1, MRP17, MFA2 and MVB12), signalling (MFA2) and amino acid metabolism (AAT2). Deletion of MFA2, encoding mating factor-a, resulted in a 55% decrease in fermentation duration. Mfa2Δ was chosen for further investigation to understand how this gene deletion conferred fermentation efficiency in limited nitrogen conditions.

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More information

Published date: 1 May 2018
Additional Information: Publisher Copyright: © FEMS 2018.
Keywords: Genome wide screening, Limited nitrogen, Mating a-factor, MFA2, Saccharomyces cerevisiae, Yeast deletion library

Identifiers

Local EPrints ID: 482662
URI: http://eprints.soton.ac.uk/id/eprint/482662
ISSN: 1567-1356
PURE UUID: 49020a97-c548-4a75-979e-50fc22ee9dbe
ORCID for Vladimir Jiranek: ORCID iD orcid.org/0000-0002-9775-8963

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Date deposited: 11 Oct 2023 16:48
Last modified: 18 Mar 2024 04:12

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Contributors

Author: Josephine J. Peter
Author: Tommaso L. Watson
Author: Michelle E. Walker
Author: Jennifer M. Gardner
Author: Tom A. Lang
Author: Anthony Borneman
Author: Angus Forgan
Author: Tina Tran
Author: Vladimir Jiranek ORCID iD

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