Rare Variants in Hypermutable Genes Underlie Common Morphology and Growth Traits in Wild<i>Saccharomyces paradoxus</i>

Roop, Jeremy I.; Brem, Rachel B.

doi:10.1534/genetics.113.155341

Cited by 19 publications

(17 citation statements)

References 81 publications

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“…We found that most activators in this pathway are expressed at higher levels in S. paradoxus, while inhibitors expression is higher in S. cerevisiae ( Fig 5D). Variants of one such inhibitor, Ira2, was previously reported to be involved in morphological variation in wild S. paradoxus isolates [21], supporting the notion that these expression variations could have a large phenotypic effect.…”

Section: Discussionmentioning

confidence: 60%

“…Still, evolutionary related species that express the same set of proteins differ in complex phenotypes, allowing non-motile cells to forage for nutrients [17][18][19]. By contrast, S. paradoxus (CBS432), a close relative of S. cerevisiae, becomes filamentous even in rich media [20,21]. Therefore, the two species activate distinct differentiation programs when presented with the same condition, providing a model for evolutionary recruitment.…”

Section: Introductionmentioning

confidence: 99%

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Mapping the architecture of regulatory variation provides insights into the evolution of complex traits

Lupo

Krieger

Jonas

et al. 2020

Preprint

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Background: Organisms evolve complex traits by recruiting existing programs to new contexts, referred as co-option. Within a species, single upstream regulators can trigger full differentiation programs. Distinguishing whether co-option of differentiation programs results from variation in single regulator, or in multiple genes, is key for understanding how complex traits evolve. As an experimentally accessible model for studying this question we turned to budding yeast, where a differentiation program (filamentous) is activated in S. cerevisiae only upon starvation, but used by the related species S. paradoxus also in rich conditions. Results: To define expression variations associated with species-specific activation of the filamentous program, we profiled the transcriptome of S. cerevisiae, S. paradoxus and their hybrid along two cell cycles at 5-minutes resolution. As expected in cases of co-option, expression of oscillating genes varies between the species in synchrony with their growth phenotypes and was dominated by upstream trans-variations. Focusing on regulators of filamentous growth, we identified gene-linked variations (cis) in multiple genes across regulatory layers, which propagated to affect expression of target genes, as well as binding specificities of downstream transcription factor. Unexpectedly, variations in regulators essential for S. cerevisiae filamentation were individually too weak to explain activation of this program in S. paradoxus. Conclusions: Our study reveals the complex architecture of regulatory variation associated with species-specific use of a differentiation program. Based on these results, we suggest a new model in which evolutionary co-option of complex traits is stabilized in a distributed manner through multiple weak-effect variations accumulating throughout the regulatory network.including size, growth pattern, and body morphology [2][3][4]. A compelling model is that complex traits do not evolve de-novo but emerge through recruitment (co-option) of existing gene expression program to new contexts. Evidence supporting co-option were presented in the context of morphological evolution, where major interspecies differences in the positioning of body appendages or wing patterns were linked to variations in cis-regulatory elements controlling the expression of major regulators, including homeobox transcription factors or developmental signaling proteins [5][6][7][8][9][10].Modulating the expression of single upstream regulators provides a genetic shortcut for the evolution of complex traits [11]. Complicating this view, however, is the fact that gene expression networks, such as these activating complex traits, are polygenic and include multiple activators and inhibitors that could act as drivers [12]. Further, due to the inter-connected nature of genetic circuits, variations in seemingly distant genes could propagate to influence the same phenotype [13]. This was exemplified recently in Drosophila, where expression variation in a Hox gene that correlated with morphological...

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Section: Discussionmentioning

confidence: 60%

Section: Introductionmentioning

confidence: 99%

Mapping the architecture of regulatory variation provides insights into the evolution of complex traits

Lupo

Krieger

Jonas

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…The IRA2 allele of MS164 has an insertion of eight nucleotides at position 820 of 9248 nucleotides, creating a stop codon at position 880, and thus likely encoding a strongly truncated inactive protein. Although IRA2 likely constitutes the causative allele in the gene block 3 in view of the frameshift mutation and the previous reports linking IRA2 polymorphisms to differences in stress tolerance [42,[63][64][65][66][67][68], its involvement appears more complex with possible interaction with one or more neighboring genetic elements.…”

Section: Gene Block 3 Qtl4mentioning

confidence: 93%

Polygenic analysis of very high acetic acid tolerance in the yeast Saccharomyces cerevisiae reveals a complex genetic background and several new causative alleles

Stojiljkovic

Foulquié-Moreno

Thevelein

2020

Biotechnol Biofuels

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Background: High acetic acid tolerance is of major importance in industrial yeast strains used for second-generation bioethanol production, because of the high acetic acid content of lignocellulose hydrolysates. It is also important in first-generation starch hydrolysates and in sourdoughs containing significant acetic acid levels. We have previously identified snf4 E269* as a causative allele in strain MS164 obtained after whole-genome (WG) transformation and selection for improved acetic acid tolerance. Results: We have now performed polygenic analysis with the same WG transformant MS164 to identify novel causative alleles interacting with snf4 E269* to further enhance acetic acid tolerance, from a range of 0.8-1.2% acetic acid at pH 4.7, to previously unmatched levels for Saccharomyces cerevisiae. For that purpose, we crossed the WG transformant with strain 16D, a previously identified strain displaying very high acetic acid tolerance. Quantitative trait locus (QTL) mapping with pooled-segregant whole-genome sequence analysis identified four major and two minor QTLs. In addition to confirmation of snf4 E269* in QTL1, we identified six other genes linked to very high acetic acid tolerance, TRT2, MET4, IRA2 and RTG1 and a combination of MSH2 and HAL9, some of which have never been connected previously to acetic acid tolerance. Several of these genes appear to be wild-type alleles that complement defective alleles present in the other parent strain. Conclusions: The presence of several novel causative genes highlights the distinct genetic basis and the strong genetic background dependency of very high acetic acid tolerance. Our results suggest that elimination of inferior mutant alleles might be equally important for reaching very high acetic acid tolerance as introduction of rare superior alleles. The superior alleles of MET4 and RTG1 might be useful for further improvement of acetic acid tolerance in specific industrial yeast strains.

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“…Significantly, we have shown previously that IRA1/2 and MTH1 mutations can arise in the same background, and attain high frequency [46]. It is noteworthy that allelic variation at IRA1 and IRA2, which are homologs of the hypermutable human neurofibromatosis gene NF1 , results in diverse morphological and growth phenotypes in Saccharomyces paradoxus [50]. …”

Section: Resultsmentioning

confidence: 99%

The Valley-of-Death: Reciprocal sign epistasis constrains adaptive trajectories in a constant, nutrient limiting environment

et al. 2014

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The fitness landscape is a powerful metaphor for describing the relationship between genotype and phenotype for a population under selection. However, empirical data as to the topography of fitness landscapes are limited, owing to difficulties in measuring fitness for large numbers of genotypes under any condition. We previously reported a case of reciprocal sign epistasis (RSE), where two mutations individually increased yeast fitness in a glucose-limited environment, but reduced fitness when combined, suggesting the existence of two peaks on the fitness landscape. We sought to determine whether a ridge connected these peaks so that populations founded by one mutant could reach the peak created by the other, avoiding the low-fitness “Valley-of-Death” between them. Sequencing clones after 250 generations of further evolution provided no evidence for such a ridge, but did reveal many presumptive beneficial mutations, adding to a growing body of evidence that clonal interference pervades evolving microbial populations.

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Rare Variants in Hypermutable Genes Underlie Common Morphology and Growth Traits in WildSaccharomyces paradoxus

Cited by 19 publications

References 81 publications

Mapping the architecture of regulatory variation provides insights into the evolution of complex traits

Mapping the architecture of regulatory variation provides insights into the evolution of complex traits

Polygenic analysis of very high acetic acid tolerance in the yeast Saccharomyces cerevisiae reveals a complex genetic background and several new causative alleles

The Valley-of-Death: Reciprocal sign epistasis constrains adaptive trajectories in a constant, nutrient limiting environment

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