Deep Convergence, Shared Ancestry, and Evolutionary Novelty in the Genetic Architecture of Heliconius Mimicry.

Jake Morris,Kanchon K Dasmahapatra,Simon H Martin,Camilo Salazar,Steven M Van Belleghem,Chris D Jiggins,Joseph J Hanly

doi:10.1534/genetics.120.303611

Jake Morris, Kanchon K Dasmahapatra + Show 5 more

Open Access

https://doi.org/10.1534/genetics.120.303611

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Abstract

Convergent evolution can occur through different genetic mechanisms in different species. It is now clear that convergence at the genetic level is also widespread, and can be caused by either (i) parallel genetic evolution, where independently evolved convergent mutations arise in different populations or species, or (ii) collateral evolution in which shared ancestry results from either ancestral polymorphism or introgression among taxa. The adaptive radiation of Heliconius butterflies shows color pattern variation within species, as well as mimetic convergence between species. Using comparisons from across multiple hybrid zones, we use signals of shared ancestry to identify and refine multiple putative regulatory elements in Heliconius melpomene and its comimics, Heliconius elevatus and Heliconius besckei, around three known major color patterning genes: optix, WntA, and cortex While we find that convergence between H. melpomene and H. elevatus is caused by a complex history of collateral evolution via introgression in the Amazon, convergence between these species in the Guianas appears to have evolved independently. Thus, we find adaptive convergent genetic evolution to be a key driver of regulatory changes that lead to rapid phenotypic changes. Furthermore, we uncover evidence of parallel genetic evolution at some loci around optix and WntA in H. melpomene and its distant comimic Heliconius erato Ultimately, we show that all three of convergence, conservation, and novelty underlie the modular architecture of Heliconius color pattern mimicry.

Highlights

CONVERGENT evolution is a natural experiment in repeated evolution of similar traits, and offers unique insights into the evolutionary process (Blount et al 2018)
We identify a 1.5 kb locus that we putatively delimit as the optix band region, as well as two loci at WntA that are associated with the full black discal forewing phenotype that H. elevatus shares with these H. melpomene races rather than the broken black of its sister species H. pardalinus
We have investigated the contributions of three genetic modes of evolution to explain convergent wing color pattern phenotypes found in Heliconius butterflies (H. melpomene, H. elevatus, H. besckei, and H. erato)

Summary

Introduction

CONVERGENT evolution is a natural experiment in repeated evolution of similar traits, and offers unique insights into the evolutionary process (Blount et al 2018). We use phylogenetic analysis across multiple hybrid zone comparisons to delimit narrow regions of the genome associated with color pattern elements due to shared ancestry (either from introgression or ancestral polymorphism) We do this by identifying genomic regions that show genotype-by-phenotype associations and particular phylogenetic histories consistent with controlling specific wing color pattern phenotypes. This allows us for the first time to look at the mechanism of convergence between Guianese H. melpomene and H. elevatus. We propose that these narrow regions are putative modular regulatory elements, with each controlling a specific wing pattern phenotype. We investigate the homology and conservation of these regulatory elements between H. melpomene and H. erato, as well as across other Lepidoptera species

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