Simultaneous Estimation of Additive and Mutational Genetic Variance in an Outbred Population of <i>Drosophila serrata</i>

McGuigan, Katrina; Aguirre, J. David; Blows, Mark W.

doi:10.1534/genetics.115.178632

Cited by 16 publications

(26 citation statements)

References 78 publications

(99 reference statements)

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“…Probably the most comparable data to ours in terms of the types of traits are from D. serrata, in which McGuigan et al (2015) report VG and VM for eight cuticular hydrocarbons and 10 wing dimensions. The median t P was 125 generations, again suggestive of substantially stronger selection against homozygotes.…”

Section: Discussionsupporting

confidence: 66%

“…Fruit flies are obligate outcrossers, so selection against new mutations occurs primarily in heterozygotes, which implies that selection against mutant homozygotes must be substantially stronger. Persistence times of heterozygous mutations affecting life history traits in Daphnia are similar to those in D. melanogaster, on the order of 40 generations (Lynch et al 1998).Probably the most comparable data to ours in terms of the types of traits are from D. serrata, in which McGuigan et al (2015) report VG and VM for eight cuticular hydrocarbons and 10 wing dimensions. The median t P was 125 generations, again suggestive of substantially stronger selection against homozygotes.…”

supporting

confidence: 72%

“…Second, when scaled relative to the trait mean, life history traits experience greater input of genetic variation from mutation than other classes of traits (Houle et al 1996;Halligan and Keightley 2009). Third, life history traits appear to be under stronger purifying selection than other classes of traits (Houle et al 1996;Lynch et al 1999;McGuigan et al 2015).A longstanding related, but unanswered, question is the relative influence of balancing selection on the maintenance of genetic variation (Dobzhansky 1955;Lewontin 1974; Charlesworth 2015). Presumably, a large fraction of mutations are unconditionally deleterious and are removed more or less efficiently by selection.…”

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confidence: 99%

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Mutation Is a Sufficient and Robust Predictor of Genetic Variation for Mitotic Spindle Traits in Caenorhabditis elegans

et al. 2016

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Different types of phenotypic traits consistently exhibit different levels of genetic variation in natural populations. There are two potential explanations: Either mutation produces genetic variation at different rates or natural selection removes or promotes genetic variation at different rates. Whether mutation or selection is of greater general importance is a longstanding unresolved question in evolutionary genetics. We report mutational variances (VM) for 19 traits related to the first mitotic cell division in Caenorhabditis elegans and compare them to the standing genetic variances (VG) for the same suite of traits in a worldwide collection C. elegans. Two robust conclusions emerge. First, the mutational process is highly repeatable: The correlation between VM in two independent sets of mutation accumulation lines is 0.9. Second, VM for a trait is a good predictor of VG for that trait: The correlation between VM and VG is 0.9. This result is predicted for a population at mutation-selection balance; it is not predicted if balancing selection plays a primary role in maintaining genetic variation.KEYWORDS mutation accumulation; mutational robustness; mutation-selection balance; mutational variance; persistence time T HE question "What are the factors that govern genetic variation in natural populations?" has been central to the field of evolutionary genetics ever since its inception (Dobzhansky 1937;Lewontin 1974Lewontin , 1997. Within a group of organisms, seemingly similar or related phenotypic traits can vary considerably, and consistently, in the extent of genetic variation in the trait. For example, in many organisms, resistance to acute heat stress is much less heritable and evolvable than resistance to acute cold stress (Hoffmann et al. 2013). If different traits in the same set of organisms have consistently different levels of genetic variation, there are two potential underlying evolutionary causes: mutation and/or selection. Traits may differ in the mutational target they present, i.e., the number and/or types of loci that potentially affect the trait, or in the rate at which those loci mutate. Traits may also differ in the average effect that mutations have on the trait; i.e., they may be differently robust to the effects of mutation. Alternatively, traits may be subject to differing strengths and/or kinds of selection.In quantitative genetics, a few empirical conclusions seem fairly certain. First, traits that are direct components of fitness-life history traits-are typically more genetically variable than other classes of traits (Houle 1992;Lynch et al. 1999). Second, when scaled relative to the trait mean, life history traits experience greater input of genetic variation from mutation than other classes of traits (Houle et al. 1996;Halligan and Keightley 2009). Third, life history traits appear to be under stronger purifying selection than other classes of traits (Houle et al. 1996;Lynch et al. 1999;McGuigan et al. 2015).A longstanding related, but unanswered, question is the relative...

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Section: Discussionsupporting

confidence: 66%

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confidence: 72%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Mutation Is a Sufficient and Robust Predictor of Genetic Variation for Mitotic Spindle Traits in Caenorhabditis elegans

et al. 2016

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“…Pleiotropy produces covariation among traits, orienting new genetic variation that arises from mutation (Houle and Fierst ; McGuigan et al. ; Hine et al. ), and standing genetic variation (Walsh and Blows ), into a smaller number of multivariate trait combinations.…”

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confidence: 99%

Cross‐sex genetic covariances limit the evolvability of wing‐shape within and among species of Drosophila

Sztepanacz

Houle

2019

Evolution

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The independent evolution of males and females is potentially constrained by both sexes inheriting the same alleles from their parents. This genetic constraint can limit the evolvability of complex traits; however, there are few studies of multivariate evolution that incorporate cross‐sex genetic covariances in their predictions. Drosophila wing‐shape has emerged as a model high‐dimensional phenotype; wing‐shape is highly evolvable in contemporary populations, and yet perplexingly stable across phylogenetic timescales. Here, we show that cross‐sex covariances in Drosophila melanogaster, given by the B‐matrix, may considerably bias wing‐shape evolution. Using random skewers, we show that B would constrain the response to antagonistic selection by 90%, on average, but would double the response to concordant selection. Both cross‐sex within‐trait and cross‐sex cross‐trait covariances determined the predicted response to antagonistic selection, but only cross‐sex within‐trait covariances facilitated the predicted response to concordant selection. Similar patterns were observed in the direction of extant sexual dimorphism in D. melanogaster, and in directions of most and least dimorphic variation across the Drosophila phylogeny. Our results highlight the importance of considering between‐sex genetic covariances when making predictions about evolution on both macro‐ and microevolutionary timescales, and may provide one more explanatory piece in the puzzle of stasis.

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The transcriptional architecture of phenotypic dimorphism

2017

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The profound differences in gene expression between the sexes are increasingly used to study the molecular basis of sexual dimorphism, sexual selection and sexual conflict. Studies of transcriptional architecture, based on comparisons of gene expression, have also been implemented for a wide variety of other intra-specific polymorphisms. These efforts are based on key assumptions regarding the relationship between transcriptional architecture, phenotypic variation and the target of selection. Some of these assumptions are better supported by available evidence than others. In all cases, the evidence is largely circumstantial, leaving considerable gaps in our understanding of the relationship between transcriptional and phenotypic dimorphism.

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Simultaneous Estimation of Additive and Mutational Genetic Variance in an Outbred Population of Drosophila serrata

Cited by 16 publications

References 78 publications

Mutation Is a Sufficient and Robust Predictor of Genetic Variation for Mitotic Spindle Traits in Caenorhabditis elegans

Mutation Is a Sufficient and Robust Predictor of Genetic Variation for Mitotic Spindle Traits in Caenorhabditis elegans

Cross‐sex genetic covariances limit the evolvability of wing‐shape within and among species of Drosophila

The transcriptional architecture of phenotypic dimorphism

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