Repetitive DNA represents an important driver of sex chromosome differentiation. Yet, repetitive sequences tend to be misrepresented or overlooked in genomic studies. We analysed repetitive DNA landscape of sex chromosomes in several populations of a turquoise killifish Nothobranchius furzeri and its sister species N. kadleci (Teleostei: Nothobranchiidae), representatives of African annual killifishes with high rate of karyotype and sex chromosome evolution. We combined bioinformatic analyses of repeatome with molecular cytogenetic techniques such as comparative genomic hybridization, fluorescence in situ hybridization with satellite sequences, genes for ribosomal RNAs (rDNA) and bacterial artificial chromosomes (BACs) and immunostaining of SYCP3 and MLH1 proteins, which marked lateral elements of synaptonemal complexes and recombination sites, respectively. We revealed that N. furzeri and N. kadleci share the XY sex chromosome system, which is thus much older than previously assumed. Sex chromosomes are mostly heteromorphic as evidenced by distinct distribution of satellite DNAs and major rDNA. Yet, the heteromorphic XY sex chromosomes pair almost exclusively regularly in meiosis, which implies synaptic adjustment. Physical mapping of BACs identified inversions on Y chromosomes of the N. kadleci populations, akin to the pattern previously reported in N. furzeri. Yet, repetitive DNA landscape of X and Y sex chromosomes either diverged in parallel in populations of both species or it evolved in their common ancestor and thus predates the inversions. The observed differentiation via repeat repatterning thus cannot be explained by the classical sexually antagonistic model. Rather, we hypothesized that relaxed meiotic drive and recombination reduced by neutral processes could drive changes in repeatome and secondary inversions could be maintained by sexually antagonistic regulatory effects resulting from early evolution of dosage compensation..
Satellite DNA (satDNA) is rapidly evolving class of tandem repeats with some motifs being involved in centromere organization and function. Rapid co-evolution of centromeric satDNA and associated proteins has been mostly attributed to the so-called centromere drive. To identify repeats associated with centromeric regions and test for the role of meiotic drive in their evolution, we investigated satDNA across Southern and Coastal clades of African annual killifishes of the genus Nothobranchius. C-banding showed expansion of (peri)centromeric heterochromatin regions in the Southern-clade killifishes. Molecular cytogenetic and bioinformatic analyses further revealed that two previously identified satellites, Nfu-SatA and Nfu-SatB, are associated with centromeres only in one lineage of the Southern clade. Nfu-SatB was, however, detected outside centromeres also in other members of the Coastal clade, which is consistent with the "library" hypothesis of satDNA evolution. We also identified a novel satDNA, Cl-36, associated with (peri)centromeres in N. foerschi, N. guentheri and N. rubripinnis from the Coastal clade. Our findings could be explained by centromere drive shaping karyotype change and centromeric repeat turnover in Nothobranchius species with possible reversal of spindle polarity within the Southern clade.
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