<i>Saccharomyces cerevisiae FLO1</i>Gene Demonstrates Genetic Linkage to Increased Fermentation Rate at Low Temperatures

Deed, Rebecca C.; Fedrizzi, Bruno; Gardner, Richard C.

doi:10.1534/g3.116.037630

Cited by 10 publications

(36 citation statements)

References 85 publications

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“…The genomic context of the laboratory strain could have contributed to this finding; by evolving a strain with a nonsense mutation in flocculation transcription factor Flo8, we were functionally screening for bypass suppressors. A different genetic background might be more likely to reveal different favored adaptations for both flocculation and multicellular phenotypes, and recent work has demonstrated the important role of background in FLO1 performance during fermentation (Deed et al 2017). Despite the constraint provided by strain background, our findings are in keeping with other work in eukaryotes demonstrating favored adaptive responses, not just in the clear relationships between nutrient limitation and the amplification of nutrient transporters (Brown, Todd, and Rosenzweig 1998;Gresham et al 2008), but also in response to stress treatments.…”

Section: Discussionsupporting

confidence: 88%

Experimental evolution reveals favored adaptive routes to cell aggregation in yeast

Hope

Amorosi

Miller

et al. 2016

Preprint

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Yeast flocculation is a community-building cell aggregation trait that is an important mechanism of stress resistance and a useful phenotype for brewers; however, it is also a nuisance in many industrial processes, in clinical settings, and in the laboratory. Chemostat-based evolution experiments are impaired by inadvertent selection for aggregation, which we observe in 35% of populations. These populations provide a testing ground for understanding the breadth of genetic mechanisms Saccharomyces cerevisiae uses to flocculate, and which of those mechanisms provide the biggest adaptive advantages. In this study, we employed experimental evolution as a tool to ask whether one or many routes to flocculation are favored, and to engineer a strain with reduced flocculation potential. Using a combination of whole genome sequencing and bulk segregant analysis, we identified causal mutations in 23 independent clones that had evolved cell aggregation during hundreds of generations of chemostat growth. In 12 of those clones, we identified a transposable element insertion in the promoter region of known flocculation gene FLO1, and, in an additional five clones, we recovered loss-of-function mutations in transcriptional repressor TUP1, which regulates FLO1 and other related genes. Other causal mutations were found in genes that have not been previously connected to flocculation. Evolving a flo1 deletion strain revealed that this single deletion reduces flocculation occurrences to 3%, and demonstrated the efficacy of using experimental evolution as a tool to identify and eliminate the primary adaptive routes for undesirable traits.

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Section: Discussionsupporting

confidence: 88%

Experimental evolution reveals favored adaptive routes to cell aggregation in yeast

Hope

Amorosi

Miller

et al. 2016

Preprint

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“…Eight milliliter micro-vinifications were performed in 13 mL ventilation-cap polypropylene tubes, with orbital shaking at 100 rpm. 31,32 Tube lids were perforated with a 0.5 mm 2 pinhole to allow for CO 2 release. The musts were inoculated using 1 × 10 6 mL −1 cells from overnight cultures as above and un-inoculated control samples were included to control for DMS formed chemically and independent of yeast.…”

Section: Yeast Growth Assay Conditionsmentioning

confidence: 99%

“…blanc juice and wine were only 2.57% and 2.67%. The recoveries obtained with this method were also evaluated with the same Sauvignon blanc juice and wine at three different concentrations (31,310, 779 μg L −1 ) in duplicate. Recoveries in juice ranged from 101% to 106%, and the wine recoveries varied between 99% and 101%.…”

Section: Quantitation Of Dms Using Headspace Solid-phase Micro-extracmentioning

confidence: 99%

A new analytical method to measure S‐methyl‐l‐methionine in grape juice reveals the influence of yeast on dimethyl sulfide production during fermentation

et al. 2019

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BACKGROUND Dimethyl sulfide (DMS) is a small sulfur‐containing impact odorant, imparting distinctive positive and / or negative characters to food and beverages. In white wine, the presence of DMS at perception threshold is considered to be a fault, contributing strong odors reminiscent of asparagus, cooked cabbage, and creamed corn. The source of DMS in wine has long been associated with S‐methyl‐l‐methionine (SMM), a derivative of the amino acid methionine, which is thought to break down into DMS through chemical degradation, particularly during wine ageing. RESULTS We developed and validated a new liquid chromatography–tandem mass spectrometry (LC–MS/MS) method with a stable isotope dilution assay (SIDA) to measure SMM in grape juice and wine. The application of this new method for quantitating SMM, followed by the quantitation of DMS using headspace‐solid phase micro‐extraction coupled with gas chromatography–mass spectrometry (HS‐SPME/GC–MS), confirmed that DMS can be produced in wine via the chemical breakdown of SMM to DMS, with greater degradation observed at 28 °C than at 14 °C. Further investigation into the role of grape juice and yeast strain on DMS formation revealed that the DMS produced from three different Sauvignon blanc grape juices, either from the SMM naturally present or SMM spiked at 50 mmol L−1, was modulated depending on each of the four strains of Saccharomyces cerevisiae wine yeast used for fermentation. CONCLUSION This study confirms the existence of a chemical pathway to the formation of DMS and reveals a yeast‐mediated mechanism towards the formation of DMS from SMM during alcoholic fermentation. © 2019 Society of Chemical Industry

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“…VII and one on Chr. XIII, that were signi cantly linked to fermentative lag [22]. Linkage analysis was performed on a set of 119/121 completely mapped (> 99% of the genome) F 1 progeny from a cross between haploid strains BY4716 and RM11-1a constructed by Brem et al [23].…”

Section: Introductionmentioning

confidence: 99%

“…This previous identi cation of chromosomal regions linked to lag phase duration provides an excellent opportunity to investigate the causative genes using a controlled and reproducible fermentation medium, such as synthetic grape medium (SGM). Since single reciprocal hemizygosity analysis (RHA) was not feasible for 44 different genes, we rst aimed to test the lag duration of BY4743 single deletants of each candidate ORF identi ed in Deed et al [22]. Those demonstrating variation in lag time compared to the BY4743 reference strain would be deleted in haploids RM11-1a and S288C, followed by the construction of RHA hybrids.…”

Section: Introductionmentioning

confidence: 99%

The CGI121 gene from Saccharomyces cerevisiae demonstrates genetic linkage to increased lag time under enological conditions

Li¹,

Deed²

2020

Preprint

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Background In winemaking, it is standard practice to ferment white wines at low temperatures (10–18 ºC). However, low temperatures increase the fermentation duration and risk of problem ferments, which can lead to significant costs. The length of the lag period at fermentation initiation is one parameter that is heavily impacted by low temperatures. Therefore, the identification of Saccharomyces cerevisiae genes with an impact on fermentation kinetics, such as lag time, is of interest for winemaking. Results We selected a set of 28 S. cerevisiae BY4743 single deletants based on a prior list of candidate open reading frames (ORFs) mapped to quantitative trait loci (QTLs) on chromosomes VII and XIII influencing the duration of fermentative lag time by bulk segregant analysis. Five out of 28 BY4743 deletants, Δapt1, Δcgi121, Δclb6, Δrps17a, and Δvma21, differed significantly in their fermentative lag phase duration compared to BY4743 in synthetic grape medium (SGM) at 15 ºC, over 72 h. Fermentation at 12.5 ºC for 528 h, to show a greater resolution of the lag times, identified the inability of BY4743 Δapt1 to initiate fermentation and confirmed the significantly longer lag times of the BY4743 Δcgi121, Δrps17a, and Δvma21 deletants. The three candidate ORFs were deleted in S. cerevisiae RM11-1a and S288C to perform single reciprocal hemizygosity analysis (RHA). RHA hybrids and single deletants of RM11-1a and S288C were fermented at 12.5 ºC in SGM. Lag time measurements confirmed genetic linkage of CGI121 on chromosome XIII, encoding a component of the EKC/KEOPS complex, to fermentative lag phase. Nucleotide sequences of RM11-1a and S288C CGI121 alleles differed by only one synonymous nucleotide suggesting that codon bias or positional effects might be responsible for the impact of this gene on lag phase duration. Conclusion This research demonstrates a new role of CGI121 in fermentative lag time in S. cerevisiae during fermentation and highlights the applicability of QTL analysis for investigating complex phenotypic traits in yeast, such as fermentation kinetics.

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Saccharomyces cerevisiae FLO1Gene Demonstrates Genetic Linkage to Increased Fermentation Rate at Low Temperatures

Cited by 10 publications

References 85 publications

Experimental evolution reveals favored adaptive routes to cell aggregation in yeast

Experimental evolution reveals favored adaptive routes to cell aggregation in yeast

A new analytical method to measure S‐methyl‐l‐methionine in grape juice reveals the influence of yeast on dimethyl sulfide production during fermentation

The CGI121 gene from Saccharomyces cerevisiae demonstrates genetic linkage to increased lag time under enological conditions

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