Abstract
Chromosomal inversion polymorphisms have been linked to the evolution of phenotypic variation, environmental adaptation, and speciation. The genome of the white-throated sparrow (Zonotrichia albicollis) contains two exceptionally large chromosomal polymorphisms. The rearrangement on the 2nd chromosome (ZAL2/2(m)) has been the subject of considerable study and is linked to both plumage morph and alternative reproductive strategies. Using extensive genomic and transcriptomic resources, we molecularly characterised the other polymorphism, which is on the 3rd chromosome (ZAL3/3(a)). We estimate that the ZAL3 polymorphism is larger than the ZAL2 polymorphism, capturing nearly 1000 genes. Sequence divergence between ZAL3 and ZAL3(a) is approximately half that of ZAL2/2(m), suggesting that ZAL3/3(a) evolved in the context of the ZAL2/2(m) rearrangement. We found evidence of reduced genetic diversity inside the rearranged region on ZAL3, sequence divergence between ZAL3 and ZAL3(a), and notable gene expression differences and allelic bias between the two haplotypes. We did not, however, find evidence consistent with widespread degeneration of ZAL3. We identified a region inside the rearrangement that shows evidence of balancing selection, consistent with hypotheses that such divergent haplotypes may evolve within non-recombining polymorphisms. Using a newly developed PCR-based genotyping assay for the ZAL3 polymorphism, we genotyped 972 archived samples. We found that ZAL3/3 homozygotes are rare (1.2% of the population), but at the population level the arrangement is in Hardy-Weinberg equilibrium. We report here that rare ZAL3/3 homozygotes are in poorer body condition. Together, our observations of this young inversion polymorphism indicate that reduced genetic diversity, reduced selection efficacy, and the accumulation of adaptive alleles can occur before detectable genetic degeneration.