A combination of sexual and ecological divergence contributes to rearrangement spread during initial stages of speciation

Chromosomal rearrangements between sympatric species often contain multiple loci contributing to assortative mating, local adaptation and hybrid sterility. When and how these associations arise during the process of speciation remains a subject of debate. Here, we address the relative roles of local...

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Published inMolecular ecology Vol. 26; no. 8; pp. 2331 - 2347
Main Authors Kozak, Genevieve M., Wadsworth, Crista B., Kahne, Shoshanna C., Bogdanowicz, Steven M., Harrison, Richard G., Coates, Brad S., Dopman, Erik B.
Format Journal Article
LanguageEnglish
Published England Blackwell Publishing Ltd 01.04.2017
Subjects
Adaptation, Physiological
Animals
assortative mating
chromosomal rearrangements
chromosome aberrations
Chromosome Mapping
Ecological adaptation
ecological speciation
Ecotype
Ecotypes
evolution
Female
Gene loci
Gene mapping
Gene Rearrangement
genes
Genetic Speciation
Genetics, Population
hybrids
inversions
loci
Male
moths
Moths - genetics
North America
olfactory receptors
Ostrinia nubilalis
Pedigree
pheromone
Quantitative Trait Loci
Recombination, Genetic
reproductive isolation
Seasons
Sex Attractants - genetics
sex pheromones
Speciation
Sympatry
univoltine habit
Z chromosome
reproductive isolation
pheromone
chromosomal rearrangements
ecological speciation
assortative mating
inversions
Online AccessGet full text
ISSN0962-1083
1365-294X
1365-294X
DOI10.1111/mec.14036

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Abstract Chromosomal rearrangements between sympatric species often contain multiple loci contributing to assortative mating, local adaptation and hybrid sterility. When and how these associations arise during the process of speciation remains a subject of debate. Here, we address the relative roles of local adaptation and assortative mating on the dynamics of rearrangement evolution by studying how a rearrangement covaries with sexual and ecological trait divergence within a species. Previously, a chromosomal rearrangement that suppresses recombination on the Z (sex) chromosome was identified in European corn borer moths (Ostrinia nubilalis). We further characterize this recombination suppressor and explore its association with variation in sex pheromone communication and seasonal ecological adaptation in pairs of populations that are divergent in one or both of these characteristics. Direct estimates of recombination suppression in pedigree mapping families indicated that more than 39% of the Z chromosome (encompassing up to ~10 megabases and ~300 genes) resides within a nonrecombining unit, including pheromone olfactory receptor genes and a major quantitative trait locus that contributes to ecotype differences (Pdd). Combining direct and indirect estimates of recombination suppression, we found that the rearrangement was occasionally present between sexually isolated strains (E vs. Z) and between divergent ecotypes (univoltine vs. bivoltine). However, it was only consistently present when populations differed in both sexual and ecological traits. Our results suggest that independent of the forces that drove the initial establishment of the rearrangement, a combination of sexual and ecological divergence is required for rearrangement spread during speciation.
AbstractList Chromosomal rearrangements between sympatric species often contain multiple loci contributing to assortative mating, local adaptation and hybrid sterility. When and how these associations arise during the process of speciation remains a subject of debate. Here, we address the relative roles of local adaptation and assortative mating on the dynamics of rearrangement evolution by studying how a rearrangement covaries with sexual and ecological trait divergence within a species. Previously, a chromosomal rearrangement that suppresses recombination on the Z (sex) chromosome was identified in European corn borer moths (Ostrinia nubilalis). We further characterize this recombination suppressor and explore its association with variation in sex pheromone communication and seasonal ecological adaptation in pairs of populations that are divergent in one or both of these characteristics. Direct estimates of recombination suppression in pedigree mapping families indicated that more than 39% of the Z chromosome (encompassing up to ~10 megabases and ~300 genes) resides within a nonrecombining unit, including pheromone olfactory receptor genes and a major quantitative trait locus that contributes to ecotype differences (Pdd). Combining direct and indirect estimates of recombination suppression, we found that the rearrangement was occasionally present between sexually isolated strains (E vs. Z) and between divergent ecotypes (univoltine vs. bivoltine). However, it was only consistently present when populations differed in both sexual and ecological traits. Our results suggest that independent of the forces that drove the initial establishment of the rearrangement, a combination of sexual and ecological divergence is required for rearrangement spread during speciation.
Chromosomal rearrangements between sympatric species often contain multiple loci contributing to assortative mating, local adaptation and hybrid sterility. When and how these associations arise during the process of speciation remains a subject of debate. Here, we address the relative roles of local adaptation and assortative mating on the dynamics of rearrangement evolution by studying how a rearrangement covaries with sexual and ecological trait divergence within a species. Previously, a chromosomal rearrangement that suppresses recombination on the Z (sex) chromosome was identified in European corn borer moths ( Ostrinia nubilalis ). We further characterize this recombination suppressor and explore its association with variation in sex pheromone communication and seasonal ecological adaptation in pairs of populations that are divergent in one or both of these characteristics. Direct estimates of recombination suppression in pedigree mapping families indicated that more than 39% of the Z chromosome (encompassing up to ~10 megabases and ~300 genes) resides within a nonrecombining unit, including pheromone olfactory receptor genes and a major quantitative trait locus that contributes to ecotype differences ( Pdd ). Combining direct and indirect estimates of recombination suppression, we found that the rearrangement was occasionally present between sexually isolated strains (E vs. Z) and between divergent ecotypes (univoltine vs. bivoltine). However, it was only consistently present when populations differed in both sexual and ecological traits. Our results suggest that independent of the forces that drove the initial establishment of the rearrangement, a combination of sexual and ecological divergence is required for rearrangement spread during speciation.
Chromosomal rearrangements between sympatric species often contain multiple loci contributing to assortative mating, local adaptation and hybrid sterility. When and how these associations arise during the process of speciation remains a subject of debate. Here, we address the relative roles of local adaptation and assortative mating on the dynamics of rearrangement evolution by studying how a rearrangement covaries with sexual and ecological trait divergence within a species. Previously, a chromosomal rearrangement that suppresses recombination on the Z (sex) chromosome was identified in European corn borer moths (Ostrinia nubilalis). We further characterize this recombination suppressor and explore its association with variation in sex pheromone communication and seasonal ecological adaptation in pairs of populations that are divergent in one or both of these characteristics. Direct estimates of recombination suppression in pedigree mapping families indicated that more than 39% of the Z chromosome (encompassing up to ~10 megabases and ~300 genes) resides within a nonrecombining unit, including pheromone olfactory receptor genes and a major quantitative trait locus that contributes to ecotype differences (Pdd). Combining direct and indirect estimates of recombination suppression, we found that the rearrangement was occasionally present between sexually isolated strains (E vs. Z) and between divergent ecotypes (univoltine vs. bivoltine). However, it was only consistently present when populations differed in both sexual and ecological traits. Our results suggest that independent of the forces that drove the initial establishment of the rearrangement, a combination of sexual and ecological divergence is required for rearrangement spread during speciation.Chromosomal rearrangements between sympatric species often contain multiple loci contributing to assortative mating, local adaptation and hybrid sterility. When and how these associations arise during the process of speciation remains a subject of debate. Here, we address the relative roles of local adaptation and assortative mating on the dynamics of rearrangement evolution by studying how a rearrangement covaries with sexual and ecological trait divergence within a species. Previously, a chromosomal rearrangement that suppresses recombination on the Z (sex) chromosome was identified in European corn borer moths (Ostrinia nubilalis). We further characterize this recombination suppressor and explore its association with variation in sex pheromone communication and seasonal ecological adaptation in pairs of populations that are divergent in one or both of these characteristics. Direct estimates of recombination suppression in pedigree mapping families indicated that more than 39% of the Z chromosome (encompassing up to ~10 megabases and ~300 genes) resides within a nonrecombining unit, including pheromone olfactory receptor genes and a major quantitative trait locus that contributes to ecotype differences (Pdd). Combining direct and indirect estimates of recombination suppression, we found that the rearrangement was occasionally present between sexually isolated strains (E vs. Z) and between divergent ecotypes (univoltine vs. bivoltine). However, it was only consistently present when populations differed in both sexual and ecological traits. Our results suggest that independent of the forces that drove the initial establishment of the rearrangement, a combination of sexual and ecological divergence is required for rearrangement spread during speciation.
Author Wadsworth, Crista B.
Coates, Brad S.
Dopman, Erik B.
Kahne, Shoshanna C.
Bogdanowicz, Steven M.
Harrison, Richard G.
Kozak, Genevieve M.
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Issue 8
Keywords reproductive isolation
pheromone
chromosomal rearrangements
ecological speciation
assortative mating
inversions
Language English
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2012; 67
2011; 29
2011; 286
2009; 25
1973; 74
1977; 47
1976; 108
2011a; 6
2006; 16
2015; 11
2009
2008
2013a; 3
1978; 110
2005
2004
2002
2011; 104
2015; 28
1991; 20
2016
2009; 7
2001a; 55
2008; 211
2012; 7
2012; 4
2012; 9
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Snippet Chromosomal rearrangements between sympatric species often contain multiple loci contributing to assortative mating, local adaptation and hybrid sterility....
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SubjectTerms Adaptation, Physiological
Animals
assortative mating
chromosomal rearrangements
chromosome aberrations
Chromosome Mapping
Ecological adaptation
ecological speciation
Ecotype
Ecotypes
evolution
Female
Gene loci
Gene mapping
Gene Rearrangement
genes
Genetic Speciation
Genetics, Population
hybrids
inversions
loci
Male
moths
Moths - genetics
North America
olfactory receptors
Ostrinia nubilalis
Pedigree
pheromone
Quantitative Trait Loci
Recombination, Genetic
reproductive isolation
Seasons
Sex Attractants - genetics
sex pheromones
Speciation
Sympatry
univoltine habit
Z chromosome
Title A combination of sexual and ecological divergence contributes to rearrangement spread during initial stages of speciation
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fmec.14036
https://www.ncbi.nlm.nih.gov/pubmed/28141898
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Volume 26
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