Article

Supergene Evolution Triggered by the Introgression of a Chromosomal Inversion

Details

Citation

Jay P, Whibley A, Frézal L, Rodríguez de Cara MÁ, Nowell RW, Mallet J, Dasmahapatra KK & Joron M (2018) Supergene Evolution Triggered by the Introgression of a Chromosomal Inversion. Current Biology, 28 (11), pp. 1839-1845.e3. https://doi.org/10.1016/j.cub.2018.04.072

Abstract
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. 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. However, the mechanism governing the formation of supergenes is not well understood and poses the paradox of establishing divergent functional haplotypes in the face of recombination. 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 involving the introgression of a chromosomal rearrangement is likely to be a common feature of complex structural polymorphisms associated with the coexistence of distinct adaptive syndromes. This shows that the reticulation of genealogies may have a powerful influence on the evolution of genetic architectures in nature.

Keywords
chromosomal inversion; supergene; introgression; Heliconius; phylogenomic; genomic; mimicry; gene flow; hybridization

Journal
Current Biology: Volume 28, Issue 11

StatusPublished
FundersThe Agence Nationale de la Recherche / French National Research Agency (ANR)
Publication date04/06/2018
Publication date online24/05/2018
Date accepted by journal18/04/2018
PublisherElsevier BV
ISSN0960-9822
eISSN1879-0445

People (1)

Dr Reuben Nowell

Dr Reuben Nowell

Lecturer in Animal Evolutionary Biology, Biological and Environmental Sciences