Abstract
Sex chromosomes can evolve when recombination is halted between a pair of chromosomes, and this can lead to degeneration of the sex-limited chromosome. In the early stages of differentiation sex chromosomes are homomorphic, and even though homomorphic sex chromosomes are very common throughout animals and plants, we know little about the evolutionary forces shaping these types of sex chromosomes. We used DNA- and RNA-Seq data from females and males to explore the sex chromosomes in the female heterogametic willow, Salix viminalis, a species with ancient dioecy but with homomorphic sex chromosomes. We detected no major sex differences in read coverage in the sex determination (SD) region, indicating that the W region has not significantly degenerated. However, single nucleotide polymorphism densities in the SD region are higher in females compared with males, indicating very recent recombination suppression, followed by the accumulation of sex-specific single nucleotide polymorphisms. Interestingly, we identified two female-specific scaffolds that likely represent W-chromosome-specific sequence. We show that genes located in the SD region display a mild excess of male-biased expression in sex-specific tissue, and we use allele-specific gene expression analysis to show that this is the result of masculinization of expression on the Z chromosome rather than degeneration of female-expression on the W chromosome. Together, our results demonstrate that insertion of small DNA fragments and accumulation of sex-biased gene expression can occur before the detectable decay of the sex-limited chromosome.
Highlights
Sex chromosomes are typically thought to diverge as recombination is suppressed between a homologous pair of chromosomes following the acquisition of a sex determination (SD) genetic factor and nearby genes with alleles of sex-specific effects (Bull 1983; Bergero and Charlesworth 2009; Qiu, et al 2013; Charlesworth 2016; Tennessen, et al 2016)
We sequenced the genomes of two females (ZW) and two males (ZZ) of the female heterogametic willow S. viminalis to approximately 30x coverage
In order to further characterize the evolution of the sex chromosomes and the SD region, we used genome coverage in females versus males to assess the degree of sequence differentiation between the sex chromosomes
Summary
Sex chromosomes are typically thought to diverge as recombination is suppressed between a homologous pair of chromosomes following the acquisition of a sex determination (SD) genetic factor and nearby genes with alleles of sex-specific effects (Bull 1983; Bergero and Charlesworth 2009; Qiu, et al 2013; Charlesworth 2016; Tennessen, et al 2016). Sex determination is extraordinarily dynamic, and closely related species have different SD loci due to rapid and repeated turnover of sex chromosomes across short evolutionary timescales (Phillips, et al 2001; Miura 2008; Mank and Avise 2009). These turnover events, which are remarkably common in plants and animals (Bachtrog, et al 2014; Vicoso and Bachtrog 2015), initialize the evolution of novel sex chromosomes and provide a unique possibility for the analysis of the initial steps of sex chromosome evolution
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