Vasni Zavaleta, Laura Pérez-Través, Luis A Saona, Carlos A Villarroel, Amparo Querol, Francisco A Cubillos
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Polyploid hybrids were generated through a spontaneous diploid hybridization technique (rare-mating), revealing a prevalence of triploids and diploids over tetraploids. Despite the absence of heterosis in fermentative capacity, hybrids displayed phenotypic variability, notably influenced by maltotriose consumption. Interestingly, ploidy levels did not significantly correlate with fermentative capacity, although triploids exhibited greater phenotypic variability. The <i>S. cerevisiae</i> parental lineages primarily influenced volatile compound profiles, with significant differences in aroma production. Interestingly, hybrids emerging from the Beer <i>S. cerevisiae</i> parental lineages exhibited a volatile compound profile resembling the corresponding <i>S. eubayanus</i> parent. This pattern may result from the dominant inheritance of the <i>S. eubayanus</i> aroma profile, as suggested by the over-expression of genes related to alcohol metabolism and acetate synthesis in hybrids including the Beer <i>S. cerevisiae</i> lineage. Our findings suggest complex interactions between parental lineages and hybridization outcomes, highlighting the potential for creating yeasts with distinct brewing traits through hybridization strategies.</p><p><strong>Importance: </strong>Our study investigates the principles of lager yeast hybridization between <i>Saccharomyces cerevisiae</i> and <i>Saccharomyces eubayanus</i>. This process gave rise to the lager yeast <i>Saccharomyces pastorianus</i>. By examining how these novel hybrids perform during fermentation and the aromas they produce, we uncover the genetic bases of brewing trait inheritance. We successfully generated polyploid hybrids using diverse strains and lineages from both parent species, predominantly triploids and diploids. Although these hybrids did not show improved fermentation capacity, they exhibited varied traits, especially in utilizing maltotriose, a key sugar in brewing. Remarkably, the aroma profiles of these hybrids were primarily influenced by the <i>S. cerevisiae</i> parent, with Beer lineage hybrids adopting aroma characteristics from their <i>S. eubayanus</i> parent. These insights reveal the complex genetic interactions in hybrid yeasts, opening new possibilities for crafting unique brewing yeasts with desirable traits.</p>","PeriodicalId":18819,"journal":{"name":"mSystems","volume":" ","pages":"e0076224"},"PeriodicalIF":5.0000,"publicationDate":"2024-11-12","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Understanding brewing trait inheritance in <i>de novo</i> Lager yeast hybrids.\",\"authors\":\"Vasni Zavaleta, Laura Pérez-Través, Luis A Saona, Carlos A Villarroel, Amparo Querol, Francisco A Cubillos\",\"doi\":\"10.1128/msystems.00762-24\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Hybridization between <i>Saccharomyces cerevisiae</i> and <i>Saccharomyces eubayanus</i> resulted in the emergence of <i>S. pastorianus</i>, a crucial yeast for lager fermentation. However, our understanding of hybridization success and hybrid vigor between these two species remains limited due to the scarcity of <i>S. eubayanus</i> parental strains. Here, we explore hybridization success and the impact of hybridization on fermentation performance and volatile compound profiles in newly formed lager hybrids. By selecting parental candidates spanning a diverse array of lineages from both species, we reveal that the Beer and PB-2 lineages exhibit high rates of hybridization success in <i>S. cerevisiae</i> and <i>S. eubayanus</i>, respectively. Polyploid hybrids were generated through a spontaneous diploid hybridization technique (rare-mating), revealing a prevalence of triploids and diploids over tetraploids. Despite the absence of heterosis in fermentative capacity, hybrids displayed phenotypic variability, notably influenced by maltotriose consumption. Interestingly, ploidy levels did not significantly correlate with fermentative capacity, although triploids exhibited greater phenotypic variability. The <i>S. cerevisiae</i> parental lineages primarily influenced volatile compound profiles, with significant differences in aroma production. Interestingly, hybrids emerging from the Beer <i>S. cerevisiae</i> parental lineages exhibited a volatile compound profile resembling the corresponding <i>S. eubayanus</i> parent. This pattern may result from the dominant inheritance of the <i>S. eubayanus</i> aroma profile, as suggested by the over-expression of genes related to alcohol metabolism and acetate synthesis in hybrids including the Beer <i>S. cerevisiae</i> lineage. Our findings suggest complex interactions between parental lineages and hybridization outcomes, highlighting the potential for creating yeasts with distinct brewing traits through hybridization strategies.</p><p><strong>Importance: </strong>Our study investigates the principles of lager yeast hybridization between <i>Saccharomyces cerevisiae</i> and <i>Saccharomyces eubayanus</i>. This process gave rise to the lager yeast <i>Saccharomyces pastorianus</i>. By examining how these novel hybrids perform during fermentation and the aromas they produce, we uncover the genetic bases of brewing trait inheritance. We successfully generated polyploid hybrids using diverse strains and lineages from both parent species, predominantly triploids and diploids. Although these hybrids did not show improved fermentation capacity, they exhibited varied traits, especially in utilizing maltotriose, a key sugar in brewing. Remarkably, the aroma profiles of these hybrids were primarily influenced by the <i>S. cerevisiae</i> parent, with Beer lineage hybrids adopting aroma characteristics from their <i>S. eubayanus</i> parent. 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引用次数: 0
摘要
酿酒酵母(Saccharomyces cerevisiae)和酿酒酵母(Saccharomyces eubayanus)杂交产生了酿酒酵母(S. pastorianus),它是啤酒发酵的一种重要酵母。然而,由于 S. eubayanus 亲本菌株的稀缺,我们对这两个物种之间杂交成功率和杂交活力的了解仍然有限。在此,我们探讨了杂交成功率以及杂交对新形成的拉格杂交种的发酵性能和挥发性化合物特征的影响。通过从两个物种中选择不同品系的候选亲本,我们发现啤酒品系和 PB-2 品系分别在 S. cerevisiae 和 S. eubayanus 中表现出很高的杂交成功率。通过自发二倍体杂交技术(稀有交配)产生的多倍体杂交种显示,三倍体和二倍体比四倍体更普遍。尽管在发酵能力方面没有异交现象,但杂交种表现出了表型变异性,特别是受麦芽三糖消耗量的影响。有趣的是,虽然三倍体表现出更大的表型变异性,但倍性水平与发酵能力并无明显关联。S. cerevisiae 亲本品系主要影响挥发性化合物特征,在香气产生方面存在显著差异。有趣的是,从啤酒酿造菌(S. cerevisiae)亲本品系中产生的杂交种表现出与相应的啤酒酿造菌(S. eubayanus)亲本相似的挥发性化合物特征。这种模式可能是由 S. eubayanus 香气特征的显性遗传造成的,与酒精代谢和乙酸酯合成相关的基因在包括啤酒酿造啤酒 S. cerevisiae 品系的杂交种中过度表达也说明了这一点。我们的研究结果表明,亲本品系与杂交结果之间存在复杂的相互作用,凸显了通过杂交策略创造具有独特酿造特性的酵母菌的潜力:我们的研究调查了酿酒酵母与酿酒酵母杂交的原理。这一过程产生了酿酒酵母牧酵母。通过研究这些新型杂交种在发酵过程中的表现及其产生的香气,我们揭示了酿造性状遗传的基因基础。我们利用来自两个亲本物种的不同菌株和品系,主要是三倍体和二倍体,成功地产生了多倍体杂交种。虽然这些杂交种的发酵能力没有得到提高,但它们表现出了不同的性状,尤其是在利用麦芽三糖(酿造中的一种关键糖分)方面。值得注意的是,这些杂交种的香气特征主要受 S. cerevisiae 亲本的影响,而 Beer 系杂交种则采用了其 S. eubayanus 亲本的香气特征。这些发现揭示了杂交酵母中复杂的基因相互作用,为制造具有理想性状的独特酿酒酵母提供了新的可能性。
Understanding brewing trait inheritance in de novo Lager yeast hybrids.
Hybridization between Saccharomyces cerevisiae and Saccharomyces eubayanus resulted in the emergence of S. pastorianus, a crucial yeast for lager fermentation. However, our understanding of hybridization success and hybrid vigor between these two species remains limited due to the scarcity of S. eubayanus parental strains. Here, we explore hybridization success and the impact of hybridization on fermentation performance and volatile compound profiles in newly formed lager hybrids. By selecting parental candidates spanning a diverse array of lineages from both species, we reveal that the Beer and PB-2 lineages exhibit high rates of hybridization success in S. cerevisiae and S. eubayanus, respectively. Polyploid hybrids were generated through a spontaneous diploid hybridization technique (rare-mating), revealing a prevalence of triploids and diploids over tetraploids. Despite the absence of heterosis in fermentative capacity, hybrids displayed phenotypic variability, notably influenced by maltotriose consumption. Interestingly, ploidy levels did not significantly correlate with fermentative capacity, although triploids exhibited greater phenotypic variability. The S. cerevisiae parental lineages primarily influenced volatile compound profiles, with significant differences in aroma production. Interestingly, hybrids emerging from the Beer S. cerevisiae parental lineages exhibited a volatile compound profile resembling the corresponding S. eubayanus parent. This pattern may result from the dominant inheritance of the S. eubayanus aroma profile, as suggested by the over-expression of genes related to alcohol metabolism and acetate synthesis in hybrids including the Beer S. cerevisiae lineage. Our findings suggest complex interactions between parental lineages and hybridization outcomes, highlighting the potential for creating yeasts with distinct brewing traits through hybridization strategies.
Importance: Our study investigates the principles of lager yeast hybridization between Saccharomyces cerevisiae and Saccharomyces eubayanus. This process gave rise to the lager yeast Saccharomyces pastorianus. By examining how these novel hybrids perform during fermentation and the aromas they produce, we uncover the genetic bases of brewing trait inheritance. We successfully generated polyploid hybrids using diverse strains and lineages from both parent species, predominantly triploids and diploids. Although these hybrids did not show improved fermentation capacity, they exhibited varied traits, especially in utilizing maltotriose, a key sugar in brewing. Remarkably, the aroma profiles of these hybrids were primarily influenced by the S. cerevisiae parent, with Beer lineage hybrids adopting aroma characteristics from their S. eubayanus parent. These insights reveal the complex genetic interactions in hybrid yeasts, opening new possibilities for crafting unique brewing yeasts with desirable traits.
mSystemsBiochemistry, Genetics and Molecular Biology-Biochemistry
CiteScore
10.50
自引率
3.10%
发文量
308
审稿时长
13 weeks
期刊介绍:
mSystems™ will publish preeminent work that stems from applying technologies for high-throughput analyses to achieve insights into the metabolic and regulatory systems at the scale of both the single cell and microbial communities. The scope of mSystems™ encompasses all important biological and biochemical findings drawn from analyses of large data sets, as well as new computational approaches for deriving these insights. mSystems™ will welcome submissions from researchers who focus on the microbiome, genomics, metagenomics, transcriptomics, metabolomics, proteomics, glycomics, bioinformatics, and computational microbiology. mSystems™ will provide streamlined decisions, while carrying on ASM''s tradition of rigorous peer review.