Diversity and Postzygotic Evolution of the Mitochondrial Genome in Hybrids of Saccharomyces Species Isolated by Double Sterility Barrier

Szabó, Ágnes; Antunovics, Zsuzsa; Karanyicz, Edina; Sipiczki, Matthias

doi:10.3389/fmicb.2020.00838

Cited by 7 publications

(7 citation statements)

References 109 publications

(207 reference statements)

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“…As observed in previous studies on allotetraploid yeast (Greig et al, 2002;Sebastiani et al, 2002;Antunovics et al, 2005;Pfliegler et al, 2012;Karanyicz et al, 2017;Szabó et al, 2020;Naseeb et al, 2021) there appeared to be no post-zygotic barrier to reproduction with the F1 hybrid investigated here. The ability to produce viable spores among the F1 spore clones was also limited to tetraploid strains (via endomitosis (Sebastiani et al, 2002) or, as is most likely the case here, self-fertilization of homo-or hemizygous diploid spores).…”

Section: Discussionsupporting

confidence: 86%

Lager Yeast Design Through Meiotic Segregation of a Saccharomyces cerevisiae × Saccharomyces eubayanus Hybrid

Krogerus

Magalhães

Castillo

et al. 2021

Front. Fungal Biol.

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Yeasts in the lager brewing group are closely related and consequently do not exhibit significant genetic variability. Here, an artificial Saccharomyces cerevisiae × Saccharomyces eubayanus tetraploid interspecies hybrid was created by rare mating, and its ability to sporulate and produce viable gametes was exploited to generate phenotypic diversity. Four spore clones obtained from a single ascus were isolated, and their brewing-relevant phenotypes were assessed. These F1 spore clones were found to differ with respect to fermentation performance under lager brewing conditions (15°C, 15 °Plato), production of volatile aroma compounds, flocculation potential and temperature tolerance. One spore clone, selected for its rapid fermentation and acetate ester production was sporulated to produce an F2 generation, again comprised of four spore clones from a single ascus. Again, phenotypic diversity was introduced. In two of these F2 clones, the fermentation performance was maintained and acetate ester production was improved relative to the F1 parent and the original hybrid strain. Strains also performed well in comparison to a commercial lager yeast strain. Spore clones varied in ploidy and chromosome copy numbers, and faster wort fermentation was observed in strains with a higher ploidy. An F2 spore clone was also subjected to 10 consecutive wort fermentations, and single cells were isolated from the resulting yeast slurry. These isolates also exhibited variable fermentation performance and chromosome copy numbers, highlighting the instability of polyploid interspecific hybrids. These results demonstrate the value of this natural approach to increase the phenotypic diversity of lager brewing yeast strains.

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Section: Discussionsupporting

confidence: 86%

Lager Yeast Design Through Meiotic Segregation of a Saccharomyces cerevisiae × Saccharomyces eubayanus Hybrid

Krogerus

Magalhães

Castillo

et al. 2021

Front. Fungal Biol.

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“…Mitochondrial-nuclear interactions have been reported as having a major role in phenotypic variation both in intra-species and inter-species yeast hybrids (E. P. Baker et al 2019; Chou et al 2010; Hewitt et al 2020; Hsu and Chou 2017; Lee et al 2008; X. C. Li et al 2019; Paliwal et al 2014), affecting respiration (Albertin et al 2013) fermentation properties (Hewitt et al 2020; Solieri et al 2008), progeny fitness (Zeyl et al 2005; Zeyl 2006), reproductive isolation (Chou and Leu 2010; Lee et al 2008; Szabo et al 2020) and nuclear transcription (Hewitt et al 2020). Studies on inter-species yeast hybrids in the lab have shown a correlation between the origin of the mitochondrial genome and the higher stability of one of the nuclear genomes (Antunovics et al 2005; Karanyicz et al 2017; Peris et al 2020).…”

Section: Resultsmentioning

confidence: 99%

“…Among these, SKO1, a basic leucine zipper transcription factor, mapped in S. eubayanus alleles of Sc/Sem segregants, has been described having a major role in mediating HOG pathway-dependent osmotic regulation (Rep et al 2001). (Albertin et al 2013) fermentation properties (Hewitt et al 2020;Solieri et al 2008), progeny fitness (Zeyl et al 2005;Zeyl 2006), reproductive isolation (Chou and Leu 2010;Lee et al 2008;Szabo et al 2020) and nuclear transcription (Hewitt et al 2020). Studies on interspecies yeast hybrids in the lab have shown a correlation between the origin of the mitochondrial genome and the higher stability of one of the nuclear genomes (Antunovics et al 2005;Karanyicz et al 2017;Peris et al 2020).…”

Section: Phenotypic Diversity Of Tetraploid Hybrids Is Underpinned Bymentioning

confidence: 99%

Restoring fertility in yeast hybrids: breeding and quantitative genetics of beneficial traits

Naseeb

Visinoni

et al. 2021

Preprint

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Hybrids species can harbour a combination of beneficial traits from each parent and may exhibit hybrid vigour, more readily adapting to new harsher environments. Inter-species hybrids are also sterile and therefore an evolutionary dead-end unless fertility is restored, usually via auto-polyploidisation events. In the Saccharomyces genus, hybrids are readily found in nature and in industrial settings, where they have adapted to severe fermentative conditions. Due to their hybrid sterility, the development of new commercial yeast strains has so far been primarily conducted via selection methods rather than breeding. In this study, we overcame infertility by creating tetraploid intermediates of Saccharomyces inter-species hybrids, to allow continuous multigenerational breeding. We incorporated nuclear and mitochondrial genetic diversity within each parental species, allowing for quantitative genetic analysis of traits exhibited by the hybrids, and for nuclear-mitochondrial interactions to be assessed. Using pooled F12 generation segregants of different hybrids with extreme phenotype distributions, we identified QTLs for tolerance to high and low temperatures, high sugar concentration, high ethanol concentration, and acetic acid levels. We identified QTLs that are species specific, that are shared between species, as well as hybrid specific, where the variants do not exhibit phenotypic differences in the original parental species. Moreover, we could distinguish between mitochondria-type dependent and independent traits. This study tackles the complexity of the genetic interactions and traits in hybrid species, bringing hybrids into the realm of full genetic analysis of diploid species, and paves the road for the biotechnological exploitation of yeast biodiversity.

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“…The hybrids usually had parental mitotypes or, less frequently, recombinant mitotypes (e.g. 16,[30][31][32][33][34] ). In this study both types of hybrids were homoplasmic.…”

Section: Discussionmentioning

confidence: 99%

Synthetic two-species allodiploid and three-species allotetraploid Saccharomyces hybrids with euploid (complete) parental subgenomes

Antunovics

Szabó

Heistinger

et al. 2023

Sci Rep

Self Cite

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Combination of the genomes of Saccharomyces species has great potential for the construction of new industrial strains as well as for the study of the process of speciation. However, these species are reproductively isolated by a double sterility barrier. The first barrier is mainly due to the failure of the chromosomes to pair in allodiploid meiosis. The second barrier ensures that the hybrid remains sterile even after genome duplication, an event that can restore fertility in plant interspecies hybrids. The latter is attributable to the autodiploidisation of the allotetraploid meiosis that results in sterile allodiploid spores (return to the first barrier). Occasionally, mating-competent alloaneuploid spores arise by malsegregation of MAT-carrying chromosomes. These can mate with cells of a third species resulting in aneuploid zygotes having at least one incomplete subgenome. Here we report on the construction of euploid three-species hybrids by making use of “rare mating” between a sterile S. kudriavzevii x S. uvarum allodiploid hybrid and a diploid S. cerevisiae strain. The hybrids have allotetraploid 2nScnSk nSu genomes consisting of complete sets of parental chromosomes. This is the first report on the production of euploid three-species Saccharomyces hybrids by natural mating, without genetic manipulation. The hybrids provide possibilities for studying the interactions of three allospecific genomes and their orthologous genes present in the same cell.

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Diversity and Postzygotic Evolution of the Mitochondrial Genome in Hybrids of Saccharomyces Species Isolated by Double Sterility Barrier

Cited by 7 publications

References 109 publications

Lager Yeast Design Through Meiotic Segregation of a Saccharomyces cerevisiae × Saccharomyces eubayanus Hybrid

Lager Yeast Design Through Meiotic Segregation of a Saccharomyces cerevisiae × Saccharomyces eubayanus Hybrid

Restoring fertility in yeast hybrids: breeding and quantitative genetics of beneficial traits

Synthetic two-species allodiploid and three-species allotetraploid Saccharomyces hybrids with euploid (complete) parental subgenomes

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