Improving Industrially Relevant Phenotypic Traits by Engineering Chromosome Copy Number in Saccharomyces pastorianus

Vries, Arthur R. Gorter de; Knibbe, Ewout; Roosmalen, Roderick van; Broek, Marcel van den; Cortés, Pilar de la Torre; O'Herne, Stephanie F; Vijverberg, Pascal A; Masoudi, Anissa el; Brouwers, Nick; Pronk, Jack T.; Daran, Jean‐Marc

doi:10.3389/fgene.2020.00518

Cited by 12 publications

(8 citation statements)

References 68 publications

(88 reference statements)

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“…The latter include ploidy changes, aneuploidies/chromosome copy number variations (CCNVs), loss of heterozygosity (LOH), gross chromosomal rearrangements (GCRs), and mitotic crossing overs (Peter et al, 2018; van den Broek et al, 2015; Zhu et al, 2016). These phenomena can alter their industrial performance and may happen very rapidly (Gorter de Vries et al, 2020; Kadowaki et al, 2017; Large et al, 2020; Morard et al, 2019, 2020; Zhang et al, 2016). Along with point mutations, these GSV events result in clonal populations gradually accumulating differences in various traits, leading to clonal heterogeneity, clonal interference (competition among isogenic asexual lineages), and hence the emergence of so‐called subclonal lineages, reminiscent of the experimental evolution setups conducted with laboratory strains (Blundell et al, 2018; Lang et al, 2011; Large et al, 2020; Payen et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

How to characterize a strain? Clonal heterogeneity in industrial Saccharomyces influences both phenotypes and heterogeneity in phenotypes

Rácz

Mukhtar

Imre

et al. 2021

Yeast

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Populations of microbes are constantly evolving heterogeneity that selection acts upon, yet heterogeneity is nontrivial to assess methodologically. The necessary practice of isolating single‐cell colonies and thus subclone lineages for establishing, transferring, and using a strain results in single‐cell bottlenecks with a generally neglected effect on the characteristics of the strain itself. Here, we present evidence that various subclone lineages for industrial yeasts sequenced for recent genomic studies show considerable differences, ranging from loss of heterozygosity to aneuploidies. Subsequently, we assessed whether phenotypic heterogeneity is also observable in industrial yeast, by individually testing subclone lineages obtained from products. Phenotyping of industrial yeast samples and their newly isolated subclones showed that single‐cell bottlenecks during isolation can indeed considerably influence the observable phenotype. Next, we decoupled fitness distributions on the level of individual cells from clonal interference by plating single‐cell colonies and quantifying colony area distributions. We describe and apply an approach using statistical modeling to compare the heterogeneity in phenotypes across samples and subclone lineages. One strain was further used to show how individual subclonal lineages are remarkably different not just in phenotype but also in the level of heterogeneity in phenotype. With these observations, we call attention to the fact that choosing an initial clonal lineage from an industrial yeast strain may vastly influence downstream performances and observations on karyotype, on phenotype, and also on heterogeneity.

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Section: Introductionmentioning

confidence: 99%

How to characterize a strain? Clonal heterogeneity in industrial Saccharomyces influences both phenotypes and heterogeneity in phenotypes

Rácz

Mukhtar

Imre

et al. 2021

Yeast

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show abstract

“…In fact, in the strains sequenced to the date, aneuploidy is found in industrial strains that are often polyploid [51–53], which is also the case for allopolyploids of the genus, suggesting a link between genome stability, aneuploidy and hybridization in domestication. Furthermore, large difference of aneuploidy in a population has been coupled with phenotypic diversity, ultimately facilitating large phenotypic leaps [54, 55]. In general, it has been revealed that the genome structure is much less stable than what was classically thought, with increasing evidence that it could be an important aspect of evolution and domestication.…”

Section: Introductionmentioning

confidence: 99%

Genomic instability in an interspecific hybrid of the genus Saccharomyces: a matter of adaptability

et al. 2020

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Ancient events of polyploidy have been linked to huge evolutionary leaps in the tree of life, while increasing evidence shows that newly established polyploids have adaptive advantages in certain stress conditions compared to their relatives with a lower ploidy. The genus Saccharomyces is a good model for studying such events, as it contains an ancient whole-genome duplication event and many sequenced Saccharomyces cerevisiae are, evolutionary speaking, newly formed polyploids. Many polyploids have unstable genomes and go through large genome erosions; however, it is still unknown what mechanisms govern this reduction. Here, we sequenced and studied the natural S. cerevisiae × Saccharomyces kudriavzevii hybrid strain, VIN7, which was selected for its commercial use in the wine industry. The most singular observation is that its nuclear genome is highly unstable and drastic genomic alterations were observed in only a few generations, leading to a widening of its phenotypic landscape. To better understand what leads to the loss of certain chromosomes in the VIN7 cell population, we looked for genetic features of the genes, such as physical interactions, complex formation, epistatic interactions and stress responding genes, which could have beneficial or detrimental effects on the cell if their dosage is altered by a chromosomal copy number variation. The three chromosomes lost in our VIN7 population showed different patterns, indicating that multiple factors could explain the mechanisms behind the chromosomal loss. However, one common feature for two out of the three chromosomes is that they are among the smallest ones. We hypothesize that small chromosomes alter their copy numbers more frequently as a low number of genes is affected, meaning that it is a by-product of genome instability, which might be the chief driving force of the adaptability and genome architecture of this hybrid.

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“…For example, genome diversity of lager yeast strains is thought to be limited due to an evolutionary bottleneck that occurred during the industrialization of lager beer production ( Gallone et al 2019 ). However, extra-variation and innovation in the lager beer industry could be achieved by screening for different ploidy levels yeasts in available collections or by artificially increasing the number of chromosome copies by genetic modification, physical or chemical treatments ( Gorter de Vries et al 2017 , 2020 ).…”

Section: Discussionmentioning

confidence: 99%

Long-insert clone experimental evidence for assembly improvement and chimeric chromosomes detection in an allopentaploid beer yeast

Gómez-Muñoz

García-Ortega

Montalvo-Arredondo

et al. 2021

G3 Genes|Genomes|Genetics

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Lager beer is made with the hybrid Saccharomyces pastorianus. Many publicly available S. pastorianus genome assemblies are highly fragmented due to the difficulties of assembling hybrid genomes, such as the presence of homeologous chromosomes from both parental types, and translocations between them. To improve the assembly of a previously sequenced lager yeast hybrid Saccharomyces sp. 790, and elucidate its genome structure, we proposed the use of alternative experimental evidence. We determined the phylogenetic position of Saccharomyces sp. 790 and established it as S. pastorianus 790. Then, we obtained from this yeast a bacterial artificial chromosome (BAC) genomic library with its BAC-end sequences (BESs). To analyze this data, we developed a pipeline (applicable to other assemblies) that classifies BESs pairs alignments according to their orientation. For the case of S. pastorianus 790, paired-end BESs alignments validated parts of the assembly and unpaired-end ones suggested contig joins or misassemblies. Importantly, the BACs library was preserved and used for verification experiments. Unpaired-end alignments were used to upgrade the previous assembly, and provided an improved detection of translocations. With this, we proposed a genome structure of S. pastorianus 790, which was similar to that of other lager yeasts; however, when we estimated chromosome copy number and experimentally measured its genome size, we discovered that one key difference is the outstanding S. pastorianus 790 ploidy level (allopentaploid). Altogether, our results show the value of combining bioinformatic analyses with experimental data such as long-insert clone information to improve a short-read assembly of a hybrid genome.

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Improving Industrially Relevant Phenotypic Traits by Engineering Chromosome Copy Number in Saccharomyces pastorianus

Cited by 12 publications

References 68 publications

How to characterize a strain? Clonal heterogeneity in industrial Saccharomyces influences both phenotypes and heterogeneity in phenotypes

How to characterize a strain? Clonal heterogeneity in industrial Saccharomyces influences both phenotypes and heterogeneity in phenotypes

Genomic instability in an interspecific hybrid of the genus Saccharomyces: a matter of adaptability

Long-insert clone experimental evidence for assembly improvement and chimeric chromosomes detection in an allopentaploid beer yeast

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