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Introgression between species has the potential to shape evolutionary trajectories in important ways, but uncovering complex introgression dynamics has only recently been made possible by advances in genomics. Warblers of the avian family Parulidae exemplify rapid diversification and sexual trait divergence, and we endeavored to study historical introgression in the family. We sequenced multiple genomes of nearly every species, constructed a phylogeny for the family, and investigated gene flow across the genome and at genes known for controlling feather color. We found that DNA haplotypes including the geneBCO2, which encodes an enzyme that degrades yellow carotenoids, have spread among genera multiple times—fromVermivoratoGeothlypisand fromLeiothlypisto multipleCardellinaandSetophagaspecies. Patterns of inheritance in the latter case point to introgression that occurred 0.5 to 2 million years ago, and the shared haplotype among recipient species is less than 100 nucleotides long. Separately, we found evidence of introgression from redCardellinaspecies to both of the two redMyioborusspecies atBDH1Land from one redMyioborusspecies to the other atCYP2J19; both are key genes in the pathway that converts yellow carotenoids to red ketocarotenoids. Our results show that introgression is a common mechanism for the evolution of colorful plumage in parulid warblers and hint at complex histories of gene flow behind some of the Western Hemisphere’s most colorful birds. 

Abstract Studying how genetic variation is structured across space, and how it relates to divergence in phenotypic traits relevant to reproductive isolation, is important for our overall understanding of the speciation process. We used reduced-representation genomic data (ddRAD-seq) to examine patterns of genetic variation across the full distribution of an Andean warbler species complex (Myioborus ornatus–melanocephalus), which includes a known hybrid zone between two strikingly different plumage forms. Genetic structure largely reflects geographic variation in head plumage, some of which corresponds to major topographic barriers in the Andes. We also found evidence of isolation by distance shaping genetic patterns across the group’s broad latitudinal range. We found thatchrysopsandbairdi, two taxa with marked plumage differences that have a known hybrid zone, were characterized by low overall genetic divergence. Based on our cline analyses of both plumage and genomic hybrid indices, this hybrid zone extends for approximately 250 km, where advanced generation hybrids are likely most common. We also identified a slight difference in the centers of the plumage and genomic clines, potentially suggesting the asymmetric introgression ofchrysops-like plumage traits. By studying genetic variation in a phenotypically complex group distributed across a topographically complex area, which includes a hybrid zone, we were able to show how both geographic features and potentially sexually selected plumage traits may play a role in species formation in tropical mountains 

Genomic data can provide valuable insights into the evolutionary history of rapidly diversifying groups and the genetic basis of phenotypic differences among lineages. We used whole-genome sequencing of the warbler genus Myioborus to investigate dynamics of its recent diversification in Neotropical mountains. We found that mitochondrial and UCE phylogenies are mostly, but not fully, concordant, and we found phylogenetic support for a pattern of north-to-south and low-to-high elevation colonization in the genus. Within the ornatus-melanocephalus complex, which showed topological incongruence between our phylogenies, we found that genetic structure generally coincides with geographic variation in plumage, although three subspecies with striking plumage differences exhibit low mitochondrial divergence. The hybridizing taxa M. o. chrysops and M. m. bairdi show very shallow genomic differentiation, with marked peaks of divergence. Most of these are shared with other parulid warbler pairs, pointing to broad genomic features, like recombination rate, as the processes shaping these regions. However, other highly differentiated regions were unique to Myioborus, including one containing the gene CCDC91, which is associated with melanin-based plumage differences in several other birds. Lastly, we found higher levels of differentiation on the Z chromosome relative to autosomes, including two putative chromosomal inversions. Together, these results highlight the interplay of deep ancestral divergence, recent hybridization, and shared genomic architecture in shaping the evolution of phenotypic and genomic diversity within Myioborus. 

Bachman’s warbler (Vermivora bachmanii)—last sighted in 1988—is one of the only North American passerines to recently go extinct. Given extensive ongoing hybridization of its two extant congeners—the bluewinged warbler (V. cyanoptera) and golden-winged warbler (V. chrysoptera)—and shared patterns of plumage variation between Bachman’s warbler and hybrids between those extant species, it has been suggested that Bachman’s warbler might have also had a component of hybrid ancestry. Here, we use historic DNA (hDNA) and whole genomes of Bachman’s warblers collected at the turn of the 20th century to address this. We combine these data with the two extant Vermivora species to examine patterns of population differentiation, inbreeding, and gene flow. In contrast to the admixture hypothesis, the genomic evidence is consistent with V. bachmanii having been a highly divergent, reproductively isolated species, with no evidence of introgression. We show that these three species have similar levels of runs of homozygosity (ROH), consistent with effects of a small long-term effective population size or population bottlenecks, with one V. bachmanii outlier showing numerous long ROH and a FROH greater than 5%. We also found—using population branch statistic estimates—previously undocumented evidence of lineage-specific evolution in V. chrysoptera near a pigmentation gene candidate, CORIN, which is a known modifier of ASIP, which is in turn involved in melanic throat and mask coloration in this family of birds. Together, these genomic results also highlight how natural history collections are such invaluable repositories of information about extant and extinct species.