RT Journal Article SR Electronic T1 Recombination Suppression is Unlikely to Contribute to Speciation in Sympatric Heliconius Butterflies JF bioRxiv FD Cold Spring Harbor Laboratory SP 083931 DO 10.1101/083931 A1 John W. Davey A1 Sarah L. Barker A1 Pasi M. Rastas A1 Ana Pinharanda A1 Simon H. Martin A1 Richard Durbin A1 Richard M. Merrill A1 Chris D. Jiggins YR 2016 UL http://biorxiv.org/content/early/2016/10/27/083931.abstract AB Mechanisms that suppress recombination are known to help maintain species barriers by preventing the breakup of co-adapted gene combinations. The sympatric butterfly species H. melpomene and H. cydno are separated by many strong barriers, but the species still hybridise infrequently in the wild, with around 40% of the genome influenced by introgression. We tested the hypothesis that genetic barriers between the species are reinforced by inversions or other mechanisms to reduce between-species recombination rate. We constructed fine-scale recombination maps for Panamanian populations of both species and hybrids to directly measure recombination rate between these species, and generated long sequence reads to detect inversions. We find no evidence for a systematic reduction in recombination rates in F1 hybrids, and also no evidence for inversions longer than 50 kb that might be involved in generating or maintaining species barriers. This suggests that mechanisms leading to global or local reduction in recombination do not play a significant role in the maintenance of species barriers between H. melpomene and H. cydno.Author Summary It is now possible to study the process of species formation by sequencing the genomes of multiple closely related species. Heliconius melpomene and Heliconius cydno are two butterfly species that have diverged over the past 2 million years and have different colour patterns, mate preferences and host plants. However, they still hybridise infrequently in the wild and exchange large parts of their genomes. Typically, when genomes are exchanged, chromosomes are recombined and gene combinations are broken up, preventing species from forming. Theory predicts that gene variants that define species might be linked together because of structural differences in their genomes, such as inverted pieces of chromosomes that will not be broken up when the species hybridise. However, in this paper, we use deep sequencing of large crosses of butterflies to show that there are no long chromosome regions that are not broken up during hybridisation, and no long chromosome inversions anywhere between the two genomes. This suggests that hybridisation is rare enough and mate preference is strong enough that inversions are not necessary to maintain the species barrier.