Sex chromosomes have evolved repeatedly across eukaryotes. The emergence of a sex-determining (SD) locus is expected to progressively restrict recombination, driving convergent molecular differentiation. However, evidence from taxa like teleost fishes, representing over half of vertebrate species with unmatched diversity in SD systems, challenges this model. Teleost sex chromosomes are often difficult to detect as they experience frequent turnovers, resetting the differentiation process. Nothobranchius killifishes, which include the XY system shared by N. furzeri and N. kadleci and X1X2Y systems in six other species, offer a valuable model to study sex chromosome turnovers. We characterised X1X2Y systems in five killifish species and found that sex chromosomes evolved at least four times independently. Sex-determining regions resided near centromeres or predicted chromosome rearrangement breakpoints in N. brieni and N. guentheri, suggesting recombination cold spots may facilitate sex chromosome evolution. Chromosomes representing the XY system in N. furzeri/N. kadleci were sex-linked also in the outgroup Fundulosoma thierryi, with several genes, including gdf6, residing in the region of differentiation. Although the X1X2Y systems of N. guentheri, N. lourensi (both Coastal clade), and N. brieni (Kalahari clade) involved different chromosomes, they shared a potential SD region. We uncovered two sex-linked evolutionary strata of distinct age in N. guentheri. However, its potential SD gene amhr2 was located in the younger stratum and is hence unlikely to be the ancestral SD gene in this lineage. Our findings suggest recombination landscapes shape sex chromosome turnover and that certain synteny blocks are repeatedly co-opted as sex chromosomes in killifishes.

• Keywords
• bacterial artificial chromosome, chromosome fusion, pool‐seq, recombination suppression, sex chromosome differentiation, zoo‐FISH,
• MeSH
• Killifishes * genetics   MeSH
• Phylogeny MeSH
• Evolution, Molecular * MeSH
• Sex Chromosomes * genetics   MeSH
• Sex Determination Processes * genetics   MeSH
• Recombination, Genetic MeSH
• Animals MeSH
• Check Tag
• Male MeSH
• Female MeSH
• Animals MeSH
• Publication type
• Journal Article MeSH

Satellite DNA (satDNA) is a rapidly evolving class of tandem repeats, with some monomers being involved in centromere organization and function. To identify repeats associated with (peri)centromeric regions, we investigated satDNA across Southern and Coastal clades of African annual killifishes of the genus Nothobranchius. Molecular cytogenetic and bioinformatic analyses revealed that two previously identified satellites, designated here as NkadSat01-77 and NfurSat01-348, are associated with (peri)centromeres only in one lineage of the Southern clade. NfurSat01-348 was, however, additionally detected outside centromeres in three members of the Coastal clade. We also identified a novel satDNA, NrubSat01-48, associated with (peri)centromeres in N. foerschi, N. guentheri, and N. rubripinnis. Our findings revealed fast turnover of satDNA associated with (peri)centromeres and different trends in their evolution in two clades of the genus Nothobranchius.

• Keywords
• Centromere drive, Constitutive heterochromatin, RepeatExplorer, Repetitive sequences, satDNA,
• MeSH
• Centromere genetics   MeSH
• Killifishes * genetics   MeSH
• Fundulidae * genetics   MeSH
• Evolution, Molecular MeSH
• DNA, Satellite MeSH
• Animals MeSH
• Check Tag
• Animals MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Names of Substances
• DNA, Satellite MeSH

A vast body of studies is available that describe age-dependent gene expression in relation to aging in a number of different model species. These data were obtained from animals kept in conditions with reduced environmental challenges, abundant food, and deprivation of natural sensory stimulation. Here, we compared wild- and captive aging in the short-lived turquoise killifish (Nothobranchius furzeri). These fish inhabit temporary ponds in the African savannah. When the ponds are flooded, eggs hatch synchronously, enabling a precise timing of their individual and population age. We collected the brains of wild fish of different ages and quantified the global age-dependent regulation of transcripts using RNAseq. A major difference between captive and wild populations is that wild populations had unlimited access to food and hence grew to larger sizes and reached asymptotic size more rapidly, enabling the analysis of age-dependent gene expression without the confounding effect of adult brain growth. We found that the majority of differentially expressed genes show the same direction of regulation in wild and captive populations. However, a number of genes were regulated in opposite direction. Genes downregulated in the wild and upregulated in captivity were enriched for terms related to neuronal communication. Genes upregulated in the wild and downregulated in captive conditions were enriched in terms related to DNA replication. Finally, the rate of age-dependent gene regulation was higher in wild animals, suggesting a phenomenon of accelerated aging.

• Keywords
• Nothobranchius furzeri, RNAseq, brain aging, gene expression, killifish,
• MeSH
• Cyprinodontiformes * genetics   MeSH
• Animals, Wild genetics   MeSH
• Fundulidae * genetics   MeSH
• Brain MeSH
• Aging genetics   MeSH
• Animals MeSH
• Check Tag
• Animals MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH