Divergence and Functional Degradation of a Sex Chromosome-like Supergene

Tuttle, Elaina M.; Bergland, Alan O.; Korody, Marisa L.; Brewer, Michael S.; Newhouse, Daniel J.; Minx, Patrick; Stager, Maria; Betuel, Adam M.; Cheviron, Zachary A.; Warren, Wesley C.; Gonser, Rusty A.; Balakrishnan, Christopher N.

doi:10.1016/j.cub.2015.11.069

Cited by 288 publications

(435 citation statements)

References 36 publications

Supporting

Mentioning

416

Contrasting

Unclassified

Order By: Relevance

“…Mimicry polymorphism in H. numata is controlled by a supergene characterized by distinct chromosomal inversions maintaining the different haplotypes underlying the various wing patterns (14). As documented in an increasing number of cases, inversions may be associated with deleterious effects, either through the disruption of gene regulation by the breakpoints or due to deleterious mutations present within the segment at the time of the inversion, causing reduced fitness in homozygotes (27,(38)(39)(40). By minimizing the frequency of homozygotes for the inversion in offspring, disassortative mating protects from the deleterious effects associated with the inversions.…”

Section: Resultsmentioning

confidence: 99%

“…Mate preference generally causes positive assortative mating between individuals with the same phenotype and may reinforce local monomorphism in the warning signal. However, sexual preferences may maintain color polymorphism through a preference for rare phenotypes (24) or from disassortative mating [i.e., between individuals of different phenotypes (25)(26)(27)], generating negative FDS (3). Indeed, under disassortative mating, individuals with a rarer phenotype enjoy increased reproductive success because a larger proportion of the population will prefer them.…”

mentioning

confidence: 99%

See 1 more Smart Citation

Polymorphism at a mimicry supergene maintained by opposing frequency-dependent selection pressures

Chouteau

Llaurens

Piron‐Prunier

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

105

View full text Add to dashboard Cite

Explaining the maintenance of adaptive diversity within populations is a long-standing goal in evolutionary biology, with important implications for conservation, medicine, and agriculture. Adaptation often leads to the fixation of beneficial alleles, and therefore it erodes local diversity so that understanding the coexistence of multiple adaptive phenotypes requires deciphering the ecological mechanisms that determine their respective benefits. Here, we show how antagonistic frequency-dependent selection (FDS), generated by natural and sexual selection acting on the same trait, maintains mimicry polymorphism in the toxic butterfly Heliconius numata. Positive FDS imposed by predators on mimetic signals favors the fixation of the most abundant and best-protected wing-pattern morph, thereby limiting polymorphism. However, by using mate-choice experiments, we reveal disassortative mate preferences of the different wing-pattern morphs. The resulting negative FDS on wing-pattern alleles is consistent with the excess of heterozygote genotypes at the supergene locus controlling wing-pattern variation in natural populations of H. numata. The combined effect of positive and negative FDS on visual signals is sufficient to maintain a diversity of morphs displaying accurate mimicry with other local prey, although some of the forms only provide moderate protection against predators. Our findings help understand how alternative adaptive phenotypes can be maintained within populations and emphasize the need to investigate interactions between selective pressures in other cases of puzzling adaptive polymorphism.disassortative mating | selection conflicts | Müllerian mimicry | aposematism | warning signals

show abstract

Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

Polymorphism at a mimicry supergene maintained by opposing frequency-dependent selection pressures

Chouteau

Llaurens

Piron‐Prunier

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

105

View full text Add to dashboard Cite

show abstract

“…Examples include floral heteromorphy determining alternative pollination strategies 10 , butterfly mimicry of alternative wing-pattern and behaviours of toxic models 3,11,12 , contrasting mating tactics in several birds 13,14 , and alternative social organization in ant colonies 4 . In most documented cases, the maintenance of character associations is mediated by polymorphic rearrangements, such as inversions, which suppress local recombination and allow the differentiated supergene alleles to persist 2,4,5,10,13 . However, the build-up of differentiated haplotypes from initially recombining loci is poorly understood 1,6 .…”

mentioning

confidence: 99%

Supergene evolution triggered by the introgression of a chromosomal inversion

Jay

Whibley

Frézal

et al. 2017

Preprint

View full text Add to dashboard Cite

Supergenes are groups of tightly linked loci whose variation is inherited as a single Mendelian locus and are a common genetic architecture for complex traits under balancing selection 1 . Supergene alleles are long-range haplotypes with numerous mutations underlying distinct adaptive strategies, often maintained in linkage disequilibrium through the suppression of recombination by chromosomal rearrangements [2][3][4][5] . However, the mechanism governing the formation of supergenes is not well understood, and poses the paradox of establishing divergent functional haplotypes in face of recombination 1,6 . Here, we show that the formation of the supergene alleles encoding mimicry polymorphism in the butterfly Heliconius numata is associated with the introgression of a divergent, inverted chromosomal segment. Haplotype divergence and linkage disequilibrium indicate that supergene alleles, each allowing precise wing-pattern resemblance to distinct butterfly models, originate from over a million years of independent chromosomal evolution in separate lineages. These "superalleles" have evolved from a chromosomal inversion captured by introgression and maintained in balanced polymorphism, triggering supergene inheritance. This mode of evolution is likely to be a common feature of complex structural polymorphisms associated with the coexistence of distinct adaptive syndromes, and shows that the reticulation of genealogies may have a powerful influence on the evolution of genetic architectures in nature.How new beneficial traits which require more than one novel mutation emerge in natural populations is a long-standing question in biology [7][8][9] . Supergenes control alternative adaptive strategies that require the association of multiple co-adapted characters, and have evolved repeatedly in many taxa under balancing selection. Examples include floral heteromorphy determining alternative pollination strategies 10

show abstract

“…We also predicted that under strong drift, deleterious mutations would accumulate and impair normal levels of gene expression. Such patterns have been observed in situations where recombination is suppressed (e.g., neo sex chromosomes: Bachtrog 2006; "supergenes": Tuttle et al 2016). In this case, Timor zebra finch alleles would show a tendency to be underexpressed relative to the Australian allele in heterozygous hybrids.…”

Section: Discussionmentioning

confidence: 90%

Gene Regulatory Evolution During Speciation in a Songbird

Balakrishnan

Davidson

2015

Preprint

View full text Add to dashboard Cite

Over the last decade, tremendous progress has been made toward a comparative understanding of gene regulatory evolution. However, we know little about how gene regulation evolves in birds, and how divergent genomes interact in their hybrids. Because of the unique features of birds -female heterogamety, a highly conserved karyotype, and the slow evolution of reproductive incompatibilities -an understanding of regulatory evolution in birds is critical to a comprehensive understanding of regulatory evolution and its implications for speciation. Using a novel complement of analyses of replicated RNA-seq libraries, we demonstrate abundant divergence in brain gene expression between zebra finch (Taeniopygia guttata) subspecies. By comparing parental populations and their F1 hybrids, we also show that gene misexpression is relatively rare among brain-expressed transcripts in male birds. If this pattern is consistent across tissues and sexes, it may partially explain the slow buildup of postzygotic reproductive isolation observed in birds relative to other taxa. Although we expected that the action of genetic drift on the islanddwelling zebra finch subspecies would be manifested in a higher rate of trans regulatory divergence, we found that most divergence was in cis regulation, following a pattern commonly observed in other taxa. Thus, our study highlights both unique and shared features of avian regulatory evolution. KEYWORDS

show abstract

Divergence and Functional Degradation of a Sex Chromosome-like Supergene

Cited by 288 publications

References 36 publications

Polymorphism at a mimicry supergene maintained by opposing frequency-dependent selection pressures

Polymorphism at a mimicry supergene maintained by opposing frequency-dependent selection pressures

Supergene evolution triggered by the introgression of a chromosomal inversion

Gene Regulatory Evolution During Speciation in a Songbird

Contact Info

Product

Resources

About