Project description:East African cichlid fishes have diversified in an explosive fashion, but the (epi)genetic basis of the phenotypic diversity of these fishes remains largely unknown. Although transposable elements (TEs) have been associated with phenotypic variation in cichlids, little is known about their transcriptional activity and epigenetic silencing. Here, we describe dynamic patterns of TE expression in African cichlid gonads and during early development. Orthology inference revealed an expansion of piwil1 genes in Lake Malawi cichlids, likely driven by PiggyBac TEs. The expanded piwil1 copies have signatures of positive selection and retain amino acid residues essential for catalytic activity. Furthermore, the gonads of African cichlids express a Piwi-interacting RNA (piRNA) pathway that target TEs. We define the genomic sites of piRNA production in African cichlids and find divergence in closely related species, in line with fast evolution of piRNA-producing loci. Our findings suggest dynamic co-evolution of TEs and host silencing pathways in the African cichlid radiations. We propose that this co-evolution has contributed to cichlid genomic diversity.

Project description:The existence of homologies between fins and tetrapod limb skeletal parts as well as of the nature of those mechanisms underlying the transition of the former towards the latter, have been a rich source of discussion for more than a century. While the recent use of gene expression patterns to try and infer evolutionary scenarios has been a popular and successful approach, in particular the distribution of Hox transcript domains, it has failed to provide clearcut evidence as to whether fishes do have bony elements related by ancestry to tetrapod hands and feet. In tetrapods, posterior Hoxd genes transcription in digits is controlled by a well-characterized series of enhancers forming a large regulatory landscape, which has its syntenic counterpart in zebrafish. We show here that the deletion of the orthologous landscape in fishes does not affect the transcription of these genes in fin buds. Instead, it abrogates hoxd expression in the cloaca, an essential structure related to the mammalian uro-genital sinus. We also report that Hoxd gene function in the mammalian uro-genital sinus depends on enhancers located in the same regulatory landscape and thus conclude that an ancestral Hox ‘cloacal’ regulation was co-opted, in tetrapod, as a playground to subsequently accompany the evolution of both external genitals and digits regulatory landscapes, along with the emergence of these developmentally and phylogenetically related structures.

Project description:The existence of homologies between fins and tetrapod limb skeletal parts as well as of the nature of those mechanisms underlying the transition of the former towards the latter, have been a rich source of discussion for more than a century. While the recent use of gene expression patterns to try and infer evolutionary scenarios has been a popular and successful approach, in particular the distribution of Hox transcript domains, it has failed to provide clearcut evidence as to whether fishes do have bony elements related by ancestry to tetrapod hands and feet. In tetrapods, posterior Hoxd genes transcription in digits is controlled by a well-characterized series of enhancers forming a large regulatory landscape, which has its syntenic counterpart in zebrafish. We show here that the deletion of the orthologous landscape in fishes does not affect the transcription of these genes in fin buds. Instead, it abrogates hoxd expression in the cloaca, an essential structure related to the mammalian uro-genital sinus. We also report that Hoxd gene function in the mammalian uro-genital sinus depends on enhancers located in the same regulatory landscape and thus conclude that an ancestral Hox ‘cloacal’ regulation was co-opted, in tetrapod, as a playground to subsequently accompany the evolution of both external genitals and digits regulatory landscapes, along with the emergence of these developmentally and phylogenetically related structures.

Project description:Despite deep evolutionary conservation, recombination varies greatly across the genome, among individuals, sexes and populations and can be a major evolutionary force in the wild. Yet this variation in recombination and its impact on adaptively diverging populations is not well understood. To elucidate the nature and potential consequences of recombination rate variation, we characterized fine-scale recombination landscapes by combining pedigrees, functional genomics and field fitness measurements in an adaptively divergent pair of marine and freshwater threespine stickleback populations from River Tyne, Scotland. Through whole-genome sequencing of large nuclear families, we identified the genomic location of almost 50,000 crossovers and built recombination maps for 36 marine, freshwater, and hybrid individuals at 3.8 kilobase resolution. Using these maps, we quantified the factors driving variation in recombination rate: we find strong heterochiasmy between sexes (68% of the variation) but also differences among ecotypes (21.8%). Hybrids show evidence of significant recombination suppression, both in overall map length and in individual loci. We further tested and found reduced recombination rates both within single marine–freshwater adaptive loci and between loci on the same chromosome, suggestive of selection on linked ‘cassettes’. We tested theory supporting the evolution of linked selection using temporal sampling along a natural hybrid zone, and found that recombinants with shuffled alleles across loci show traits associated with reduced fitness. Our results support predictions that divergence in cis-acting recombination modifiers whose mechanisms are disrupted in hybrids, may have an important role to play in the maintenance of differences among adaptively diverging populations.

Project description:Despite deep evolutionary conservation, recombination varies greatly across the genome, among individuals, sexes and populations and can be a major evolutionary force in the wild. Yet this variation in recombination and its impact on adaptively diverging populations is not well understood. To elucidate the nature and potential consequences of recombination rate variation, we characterized fine-scale recombination landscapes by combining pedigrees, functional genomics and field fitness measurements in an adaptively divergent pair of marine and freshwater threespine stickleback populations from River Tyne, Scotland. Through whole-genome sequencing of large nuclear families, we identified the genomic location of almost 50,000 crossovers and built recombination maps for 36 marine, freshwater, and hybrid individuals at 3.8 kilobase resolution. Using these maps, we quantified the factors driving variation in recombination rate: we find strong heterochiasmy between sexes (68% of the variation) but also differences among ecotypes (21.8%). Hybrids show evidence of significant recombination suppression, both in overall map length and in individual loci. We further tested and found reduced recombination rates both within single marine–freshwater adaptive loci and between loci on the same chromosome, suggestive of selection on linked ‘cassettes’. We tested theory supporting the evolution of linked selection using temporal sampling along a natural hybrid zone, and found that recombinants with shuffled alleles across loci show traits associated with reduced fitness. Our results support predictions that divergence in cis-acting recombination modifiers whose mechanisms are disrupted in hybrids, may have an important role to play in the maintenance of differences among adaptively diverging populations.

Project description:Sex chromosome evolution in cichlid fishes

Project description:We compare fore- and mid-brain transcriptomes of reproductive males in monogamous and non-monogamous species pairs of Peromyscus mice, Microtus voles, parid songbirds, dendrobatid frogs, and Xenotilapia species of cichlid fishes. Our study provides evidence of a universal transcriptomic mechanism underlying the evolution of monogamy in vertebrates.

Project description:The Recombination Landscapes of Spiny Lizards (genus Sceloporus)

Project description:East African cichlid fishes have diversified in an explosive fashion, but the (epi)genetic basis of the phenotypic diversity of these fishes remains largely unknown. Although transposable elements (TEs) have been associated with phenotypic variation in cichlids, little is known about their transcriptional activity and epigenetic silencing. Here, we describe dynamic patterns of TE expression in African cichlid gonads and during early development. Orthology inference revealed an expansion of piwil1 genes in Lake Malawi cichlids, likely driven by PiggyBac TEs. The expanded piwil1 copies have signatures of positive selection and retain amino acid residues essential for catalytic activity. Furthermore, the gonads of African cichlids express a Piwi-interacting RNA (piRNA) pathway that target TEs. We define the genomic sites of piRNA production in African cichlids and find divergence in closely related species, in line with fast evolution of piRNA-producing loci. Our findings suggest dynamic co-evolution of TEs and host silencing pathways in the African cichlid radiations. We propose that this co-evolution has contributed to cichlid genomic diversity.

Project description:The existence of homologies between fins and tetrapod limb skeletal parts as well as of the nature of those mechanisms underlying the transition of the former towards the latter, have been a rich source of discussion for more than a century. While the recent use of gene expression patterns to try and infer evolutionary scenarios has been a popular and successful approach, in particular the distribution of Hox transcript domains, it has failed to provide clearcut evidence as to whether fishes do have bony elements related by ancestry to tetrapod hands and feet. In tetrapods, posterior Hoxd genes transcription in digits is controlled by a well-characterized series of enhancers forming a large regulatory landscape, which has its syntenic counterpart in zebrafish. We show here that the deletion of the orthologous landscape in fishes does not affect the transcription of these genes in fin buds. Instead, it abrogates hoxd expression in the cloaca, an essential structure related to the mammalian uro-genital sinus. We also report that Hoxd gene function in the mammalian uro-genital sinus depends on enhancers located in the same regulatory landscape and thus conclude that an ancestral Hox ‘cloacal’ regulation was co-opted, in tetrapod, as a playground to subsequently accompany the evolution of both external genitals and digits regulatory landscapes, along with the emergence of these developmentally and phylogenetically related structures.