The genomic landscape of asymmetric introgression tracks chromosomal characteristics in tinamous (Aves: Tinamidae)

We use single genomes from seven tinamou species (Palaeognathae: Tinamidae) and apply a genome-architecture-aware phylogenomic approach to (1) quantify the landscape of introgression, (2) discriminate among conflicting genealogical signals in the genome, and (3) reconstruct evolutionary history. Using summary statistics and full likelihood, we detect pervasive asymmetric introgression between two sympatric Amazonian species clouding phylogenetic relationships in this group. However, these introgression results are sensitive to the assumed species tree. When assuming the Z-chromosome phylogeny as the species tree, the landscape of introgression is non-random; introgression is negatively associated with chromosome length, elevated at macrochromosome ends, and near zero for the Z-chromosome (the avian sex chromosome). A pseudo-autosomal region on the Z-chromosome, which recombines homologously with that of the W-chromosome, shows elevated introgression comparable to that of autosomes. Our results resolve the species tree of tinamous and imply a history of linked selection purging migrant alleles that are deleterious in the hybrid genome. This selection is countered in regions of the genome expected to experience elevated recombination, allowing introgressed alleles to accumulate across >20% of the genome. This work demonstrates a genome-architecture-aware approach to resolving the species tree in the face of introgression. As chromosome-level reference genomes spanning the tree of life become increasingly available, phylogenomic studies would benefit from the adoption of genome-architecture-aware approaches like ours. This is because the genomic landscapes of introgression and genealogy are largely predicted by chromosomal characteristics.