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Yeast genes involved in regulating cysteine uptake affect production of hydrogen sulfide from cysteine during fermentation

Yeast genes involved in regulating cysteine uptake affect production of hydrogen sulfide from cysteine during fermentation
Yeast genes involved in regulating cysteine uptake affect production of hydrogen sulfide from cysteine during fermentation

An early burst of hydrogen sulfide (H2S) produced by Saccharomyces cerevisiae during fermentation could increase varietal thiols and therefore enhance desirable tropical aromas in varieties such as Sauvignon Blanc. Here we attempted to identify genes affecting H2S formation from cysteine by screening yeast deletion libraries via a colony colour assay on media resembling grape juice. Both Δlst4 and Δlst7 formed lighter coloured colonies and produced significantly less H2S than the wild-type on high concentrations of cysteine, likely because they are unable to take up cysteine efficiently. We then examined the nine known cysteine permeases and found deletion of AGP1, GNP1 and MUP1 led to reduced production of H2S from cysteine. We further showed that deleting genes involved in the SPS-sensing pathway such as STP1 and DAL81 also reduced H2S from cysteine. Together, this study indirectly confirms that Agp1p, Gnp1p and Mup1p are the major cysteine permeases and that they are regulated by the SPS-sensing and target of rapamycin (TOR) pathways under the grape juice-like, cysteine-supplemented, fermentation conditions. The findings highlight that cysteine transportation could be a limiting factor for yeast to generate H2S from cysteine and therefore selecting wine yeasts without defects in cysteine uptake could maximise thiol production potential.

Cysteine permease, Hydrogen sulfide, Saccharomyces cerevisiae, SPS-sensing pathway, Target of rapamycin (TOR) pathway, Varietal thiols
1567-1356
1-26
Huang, Chien Wei
0d5b4c1c-21bc-4576-82c5-700903147c3f
Walker, Michelle E.
5e8a98ce-9e08-409a-99e4-a0b96a490940
Fedrizzi, Bruno
f6937102-e02d-4404-8820-bc564201822a
Gardner, Richard C.
18c00d76-dd08-49f9-b801-97c67447d5c6
Jiranek, Vladimir
8e5a8dfd-f5b2-43e3-928b-11dff324abc7
Huang, Chien Wei
0d5b4c1c-21bc-4576-82c5-700903147c3f
Walker, Michelle E.
5e8a98ce-9e08-409a-99e4-a0b96a490940
Fedrizzi, Bruno
f6937102-e02d-4404-8820-bc564201822a
Gardner, Richard C.
18c00d76-dd08-49f9-b801-97c67447d5c6
Jiranek, Vladimir
8e5a8dfd-f5b2-43e3-928b-11dff324abc7

Huang, Chien Wei, Walker, Michelle E., Fedrizzi, Bruno, Gardner, Richard C. and Jiranek, Vladimir (2017) Yeast genes involved in regulating cysteine uptake affect production of hydrogen sulfide from cysteine during fermentation. FEMS Yeast Research, 17 (5), 1-26. (doi:10.1093/femsyr/fox046).

Record type: Article

Abstract

An early burst of hydrogen sulfide (H2S) produced by Saccharomyces cerevisiae during fermentation could increase varietal thiols and therefore enhance desirable tropical aromas in varieties such as Sauvignon Blanc. Here we attempted to identify genes affecting H2S formation from cysteine by screening yeast deletion libraries via a colony colour assay on media resembling grape juice. Both Δlst4 and Δlst7 formed lighter coloured colonies and produced significantly less H2S than the wild-type on high concentrations of cysteine, likely because they are unable to take up cysteine efficiently. We then examined the nine known cysteine permeases and found deletion of AGP1, GNP1 and MUP1 led to reduced production of H2S from cysteine. We further showed that deleting genes involved in the SPS-sensing pathway such as STP1 and DAL81 also reduced H2S from cysteine. Together, this study indirectly confirms that Agp1p, Gnp1p and Mup1p are the major cysteine permeases and that they are regulated by the SPS-sensing and target of rapamycin (TOR) pathways under the grape juice-like, cysteine-supplemented, fermentation conditions. The findings highlight that cysteine transportation could be a limiting factor for yeast to generate H2S from cysteine and therefore selecting wine yeasts without defects in cysteine uptake could maximise thiol production potential.

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More information

Published date: August 2017
Keywords: Cysteine permease, Hydrogen sulfide, Saccharomyces cerevisiae, SPS-sensing pathway, Target of rapamycin (TOR) pathway, Varietal thiols

Identifiers

Local EPrints ID: 482627
URI: http://eprints.soton.ac.uk/id/eprint/482627
DOI: doi:10.1093/femsyr/fox046
ISSN: 1567-1356
PURE UUID: d238bf83-6362-44f9-b3fa-636e47b92e0f
ORCID for Vladimir Jiranek: ORCID iD orcid.org/0000-0002-9775-8963

Catalogue record

Date deposited: 10 Oct 2023 17:01
Last modified: 18 Mar 2024 04:12

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Contributors

Author: Chien Wei Huang
Author: Michelle E. Walker
Author: Bruno Fedrizzi
Author: Richard C. Gardner
Author: Vladimir Jiranek ORCID iD

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