Abstract
There is increasing evidence for frequent turnover in sex chromosomes in vertebrates. Yet experimental systems suitable for tracing the detailed process of turnover are rare. In theory, homologous turnover is possible if the new sex-determining locus is established on the existing sex-chromosome. However, there is no empirical evidence for such an event. The genus Takifugu includes fugu (Takifugu rubripes) and its two closely-related species whose sex is most likely determined by a SNP at the Amhr2 locus. In these species, males are heterozygous, with G and C alleles at the SNP site, while females are homozygous for the C allele. To determine if a shift in the sex-determining locus occurred in another member of this genus, we used genetic mapping to characterize the sex-chromosome systems of Takifugu niphobles. We found that the G allele of Amhr2 is absent in T. niphobles. Nevertheless, our initial mapping suggests a linkage between the phenotypic sex and the chromosome 19, which harbors the Amhr2 locus. Subsequent high-resolution analysis using a sex-reversed fish demonstrated that the sex-determining locus maps to the proximal end of chromosome 19, far from the Amhr2 locus. Thus, it is likely that homologous turnover involving these species has occurred. The data also showed that there is a male-specific reduction of recombination around the sex-determining locus. Nevertheless, no evidence for sex-chromosome differentiation was detected: the reduced recombination depended on phenotypic sex rather than genotypic sex; no X- or Y-specific maker was obtained; the YY individual was viable. Furthermore, fine-scale mapping narrowed down the new sex-determining locus to the interval corresponding to approximately 300-kb of sequence in the fugu genome. Thus, T. niphobles is determined to have a young and small sex-determining region that is suitable for studying an early phase of sex-chromosome evolution and the mechanisms underlying turnover of sex chromosome.
Highlights
The sex chromosome and the sex-determining gene within have been maintained in therian mammals and birds for more than one hundred million years [1,2]
Kamiya et al [26] have suggested that a missense single-nucleotide polymorphism (SNP) at the Amhr2 locus (SNP7271) is most likely to act as the sex-determining switch in fugu (T. rubripes) and its two closely-related species, T. poecilonotus and T. pardalis
In order to determine if another closely-related species of fugu, T. niphobles, shares the same mechanism for determining its sex, we compared the partial genomic sequences of the Amhr2 gene between female (n = 7) and male (n = 8) T. niphobles, and compared them to the sequences from the corresponding sex in fugu, T. poecilonotus and T. pardalis
Summary
The sex chromosome and the sex-determining gene within have been maintained in therian mammals and birds for more than one hundred million years [1,2] Such stability and conservation of sex-determining system across a wide range of taxa is not universal in vertebrates. Teleost fishes are a useful group of animals to investigate the process of sex-chromosome turnover and evolution of new sexdetermining genes because different sex-determination mechanisms exist in closely related species [21,22], and the master sex-determining genes (or strong candidate genes) have been identified in some of these groups [23,24,25,26,27,28,29,30]. We conclude that T. niphobles has a sexdetermining locus that is distinct from that in fugu and its two closely related species, despite having sex chromosomes that are homologous in these species
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