Your search keyword '"Svardal, Hannes"' showing total 10 results

1. Mapping epigenetic divergence in the massive radiation of Lake Malawi cichlid fishes.

Author

Vernaz G, Malinsky M, Svardal H, Du M, Tyers AM, Santos ME, Durbin R, Genner MJ, Turner GF, and Miska EA

Subjects

Animals, DNA Transposable Elements, Epigenome, Gene Expression, Genomics, Lakes, Liver, Malawi, Sequence Analysis, DNA, Species Specificity, Chromosome Mapping, Cichlids genetics, Epigenesis, Genetic, Evolution, Molecular

Abstract

Epigenetic variation modulates gene expression and can be heritable. However, knowledge of the contribution of epigenetic divergence to adaptive diversification in nature remains limited. The massive evolutionary radiation of Lake Malawi cichlid fishes displaying extensive phenotypic diversity despite extremely low sequence divergence is an excellent system to study the epigenomic contribution to adaptation. Here, we present a comparative genome-wide methylome and transcriptome study, focussing on liver and muscle tissues in phenotypically divergent cichlid species. In both tissues we find substantial methylome divergence among species. Differentially methylated regions (DMR), enriched in evolutionary young transposons, are associated with transcription changes of ecologically-relevant genes related to energy expenditure and lipid metabolism, pointing to a link between dietary ecology and methylome divergence. Unexpectedly, half of all species-specific DMRs are shared across tissues and are enriched in developmental genes, likely reflecting distinct epigenetic developmental programmes. Our study reveals substantial methylome divergence in closely-related cichlid fishes and represents a resource to study the role of epigenetics in species diversification., (© 2021. Crown.)

Published

2021

2. Genetic Variation and Hybridization in Evolutionary Radiations of Cichlid Fishes.

Author

Svardal H, Salzburger W, and Malinsky M

Subjects

Animals, Cichlids classification, Genome, Phylogeny, Biological Evolution, Cichlids genetics, Genetic Variation, Hybridization, Genetic

Abstract

Evolutionary radiations are responsible for much of the variation in biodiversity across taxa. Cichlid fishes are well known for spectacular evolutionary radiations, as they have repeatedly evolved into large and phenotypically diverse arrays of species. Cichlid genomes carry signatures of past events and, at the same time, are the substrate for ongoing evolution. We survey genome-wide data and the available literature covering 438 cichlid populations (412 species) across multiple radiations to synthesize information about patterns and sharing of genetic variation. Nucleotide diversity within species is low in cichlids, with 92% of surveyed populations having less diversity than the median value found in other vertebrates. Divergence within radiations is also low, and a large proportion of variation is shared among species due to incomplete lineage sorting and widespread hybridization. Population genetics therefore provides a suitable conceptual framework for evolutionary genomic studies of cichlid radiations. We focus in detail on the roles of hybridization in shaping the patterns of genetic variation and in promoting cichlid diversification.

Published

2021

3. Ancestral Hybridization Facilitated Species Diversification in the Lake Malawi Cichlid Fish Adaptive Radiation.

Author

Svardal H, Quah FX, Malinsky M, Ngatunga BP, Miska EA, Salzburger W, Genner MJ, Turner GF, and Durbin R

Subjects

Animals, Gene Flow, Haplotypes, Lakes, Malawi, Polymorphism, Genetic, Adaptation, Biological genetics, Cichlids genetics, Genetic Speciation, Hybridization, Genetic

Abstract

The adaptive radiation of cichlid fishes in East African Lake Malawi encompasses over 500 species that are believed to have evolved within the last 800,000 years from a common founder population. It has been proposed that hybridization between ancestral lineages can provide the genetic raw material to fuel such exceptionally high diversification rates, and evidence for this has recently been presented for the Lake Victoria region cichlid superflock. Here, we report that Lake Malawi cichlid genomes also show evidence of hybridization between two lineages that split 3-4 Ma, today represented by Lake Victoria cichlids and the riverine Astatotilapia sp. "ruaha blue." The two ancestries in Malawi cichlid genomes are present in large blocks of several kilobases, but there is little variation in this pattern between Malawi cichlid species, suggesting that the large-scale mosaic structure of the genomes was largely established prior to the radiation. Nevertheless, tens of thousands of polymorphic variants apparently derived from the hybridization are interspersed in the genomes. These loci show a striking excess of differentiation across ecological subgroups in the Lake Malawi cichlid assemblage, and parental alleles sort differentially into benthic and pelagic Malawi cichlid lineages, consistent with strong differential selection on these loci during species divergence. Furthermore, these loci are enriched for genes involved in immune response and vision, including opsin genes previously identified as important for speciation. Our results reinforce the role of ancestral hybridization in explosive diversification by demonstrating its significance in one of the largest recent vertebrate adaptive radiations., (© The Author(s) 2019. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2020

4. Whole-genome sequences of Malawi cichlids reveal multiple radiations interconnected by gene flow.

Author

Malinsky M, Svardal H, Tyers AM, Miska EA, Genner MJ, Turner GF, and Durbin R

Subjects

Animals, Genetic Variation, Lakes, Malawi, Phylogeny, Tanzania, Whole Genome Sequencing, Biological Evolution, Cichlids genetics, Gene Flow, Genome

Abstract

The hundreds of cichlid fish species in Lake Malawi constitute the most extensive recent vertebrate adaptive radiation. Here we characterize its genomic diversity by sequencing 134 individuals covering 73 species across all major lineages. The average sequence divergence between species pairs is only 0.1-0.25%. These divergence values overlap diversity within species, with 82% of heterozygosity shared between species. Phylogenetic analyses suggest that diversification initially proceeded by serial branching from a generalist Astatotilapia-like ancestor. However, no single species tree adequately represents all species relationships, with evidence for substantial gene flow at multiple times. Common signatures of selection on visual and oxygen transport genes shared by distantly related deep-water species point to both adaptive introgression and independent selection. These findings enhance our understanding of genomic processes underlying rapid species diversification, and provide a platform for future genetic analysis of the Malawi radiation.

Published

2018

5. Phylogenomics of trophically diverse cichlids disentangles processes driving adaptive radiation and repeated trophic transitions.

Author

Singh, Pooja, Irisarri, Iker, Torres‐Dowdall, Julián, Thallinger, Gerhard G., Svardal, Hannes, Lemmon, Emily Moriarty, Lemmon, Alan R., Koblmüller, Stephan, Meyer, Axel, and Sturmbauer, Christian

Subjects

ADAPTIVE radiation, CICHLIDS, SYMPATRIC speciation, DEGREES of freedom, GRAZING

Abstract

Cichlid fishes of the tribe Tropheini are a striking case of adaptive radiation, exemplifying multiple trophic transitions between herbivory and carnivory occurring in sympatry with other established cichlid lineages. Tropheini evolved highly specialized eco‐morphologies to exploit similar trophic niches in different ways repeatedly and rapidly. To better understand the evolutionary history and trophic adaptations of this lineage, we generated a dataset of 532 targeted loci from 21 out of the 22 described Tropheini species. We resolved the Tropheini into seven monophyletic genera and discovered one to be polyphyletic. The polyphyletic genus, Petrochromis, represents three convergent origins of the algae grazing trophic specialization. This repeated evolution of grazing may have been facilitated by adaptive introgression as we found evidence for gene flow among algae grazing genera. We also found evidence of gene flow among algae browsing genera, but gene flow was restricted between herbivorous and carnivorous genera. Furthermore, we observed no evidence supporting a hybrid origin of this radiation. Our molecular evolutionary analyses suggest that opsin genes likely evolved in response to selection pressures associated with trophic ecology in the Tropheini. We found surprisingly little evidence of positive selection in coding regions of jaw‐shaping genes in this trophically diverse lineage. This suggests low degrees of freedom for further change in these genes, and possibly a larger role for regulatory variation in driving jaw adaptations. Our study emphasizes Tropheini cichlids as an important model for studying the evolution of trophic specialization and its role in speciation. [ABSTRACT FROM AUTHOR]

Published

2022

6. Ancestral Hybridization Facilitated Species Diversification in the Lake Malawi Cichlid Fish Adaptive Radiation

Author

Svardal, Hannes, Quah, Fu Xiang, Malinsky, Milan, Ngatunga, Benjamin P, Miska, Eric A, Salzburger, Walter, Genner, Martin J, Turner, George F, and Durbin, Richard

Subjects

Gene Flow, Malawi, Polymorphism, Genetic, hybrid swarm, Genetic Speciation, Adaptation, Biological, Cichlids, cichlid fish, Lakes, Haplotypes, parasitic diseases, Animals, Hybridization, Genetic, 14. Life underwater, adaptive radiation, human activities

Abstract

The adaptive radiation of cichlid fishes in East African Lake Malawi encompasses over 500 species that are believed to have evolved within the last 800,000 years from a common founder population. It has been proposed that hybridization between ancestral lineages can provide the genetic raw material to fuel such exceptionally high diversification rates, and evidence for this has recently been presented for the Lake Victoria region cichlid superflock. Here, we report that Lake Malawi cichlid genomes also show evidence of hybridization between two lineages that split 3-4 Ma, today represented by Lake Victoria cichlids and the riverine Astatotilapia sp. "ruaha blue." The two ancestries in Malawi cichlid genomes are present in large blocks of several kilobases, but there is little variation in this pattern between Malawi cichlid species, suggesting that the large-scale mosaic structure of the genomes was largely established prior to the radiation. Nevertheless, tens of thousands of polymorphic variants apparently derived from the hybridization are interspersed in the genomes. These loci show a striking excess of differentiation across ecological subgroups in the Lake Malawi cichlid assemblage, and parental alleles sort differentially into benthic and pelagic Malawi cichlid lineages, consistent with strong differential selection on these loci during species divergence. Furthermore, these loci are enriched for genes involved in immune response and vision, including opsin genes previously identified as important for speciation. Our results reinforce the role of ancestral hybridization in explosive diversification by demonstrating its significance in one of the largest recent vertebrate adaptive radiations.

7. Mapping epigenetic divergence in the massive radiation of Lake Malawi cichlid fishes

Author

Vernaz, Grégoire, Malinsky, Milan, Svardal, Hannes, Du, Mingliu, Tyers, Alexandra M, Santos, M Emília, Durbin, Richard, Genner, Martin J, Turner, George F, and Miska, Eric A

Subjects

Malawi, Chromosome Mapping, Gene Expression, Cichlids, Genomics, Sequence Analysis, DNA, Epigenesis, Genetic, Evolution, Molecular, Epigenome, Lakes, Liver, Species Specificity, DNA Transposable Elements, Animals, 14. Life underwater

Abstract

Epigenetic variation modulates gene expression and can be heritable. However, knowledge of the contribution of epigenetic divergence to adaptive diversification in nature remains limited. The massive evolutionary radiation of Lake Malawi cichlid fishes displaying extensive phenotypic diversity despite extremely low sequence divergence is an excellent system to study the epigenomic contribution to adaptation. Here, we present a comparative genome-wide methylome and transcriptome study, focussing on liver and muscle tissues in phenotypically divergent cichlid species. In both tissues we find substantial methylome divergence among species. Differentially methylated regions (DMR), enriched in evolutionary young transposons, are associated with transcription changes of ecologically-relevant genes related to energy expenditure and lipid metabolism, pointing to a link between dietary ecology and methylome divergence. Unexpectedly, half of all species-specific DMRs are shared across tissues and are enriched in developmental genes, likely reflecting distinct epigenetic developmental programmes. Our study reveals substantial methylome divergence in closely-related cichlid fishes and represents a resource to study the role of epigenetics in species diversification.

8. Whole-genome sequences of Malawi cichlids reveal multiple radiations interconnected by gene flow

Author

Malinsky, Milan, Svardal, Hannes, Tyers, Alexandra M, Miska, Eric A, Genner, Martin J, Turner, George F, and Durbin, Richard

Subjects

Gene Flow, Lakes, Malawi, Genome, Whole Genome Sequencing, Animals, Genetic Variation, 14. Life underwater, Cichlids, Biological Evolution, Tanzania, Phylogeny

Abstract

The hundreds of cichlid fish species in Lake Malawi constitute the most extensive recent vertebrate adaptive radiation. Here we characterize its genomic diversity by sequencing 134 individuals covering 73 species across all major lineages. The average sequence divergence between species pairs is only 0.1-0.25%. These divergence values overlap diversity within species, with 82% of heterozygosity shared between species. Phylogenetic analyses suggest that diversification initially proceeded by serial branching from a generalist Astatotilapia-like ancestor. However, no single species tree adequately represents all species relationships, with evidence for substantial gene flow at multiple times. Common signatures of selection on visual and oxygen transport genes shared by distantly related deep-water species point to both adaptive introgression and independent selection. These findings enhance our understanding of genomic processes underlying rapid species diversification, and provide a platform for future genetic analysis of the Malawi radiation.

9. Ancestral Hybridization Facilitated Species Diversification in the Lake Malawi Cichlid Fish Adaptive Radiation

Author

Walter Salzburger, George F. Turner, Benjamin P. Ngatunga, Martin J. Genner, Richard Durbin, Eric A. Miska, Hannes Svardal, Fu Xiang Quah, Milan Malinsky, Svardal, Hannes [0000-0001-7866-7313], Quah, Fu Xiang [0000-0002-4616-5324], Miska, Eric [0000-0002-4450-576X], Durbin, Richard [0000-0002-9130-1006], and Apollo - University of Cambridge Repository

Subjects

Gene Flow, 0106 biological sciences, Malawi, hybrid swarm, Genetic Speciation, media_common.quotation_subject, Adaptation, Biological, Genome, 010603 evolutionary biology, 01 natural sciences, Gene flow, 03 medical and health sciences, Cichlid, Adaptive radiation, biology.animal, parasitic diseases, Genetics, Animals, 14. Life underwater, Hybrid swarm, Biology, Molecular Biology, Discoveries, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, media_common, 0303 health sciences, Polymorphism, Genetic, biology, Vertebrate, Pelagic zone, Cichlids, biology.organism_classification, cichlid fish, Chemistry, Lakes, Speciation, Astatotilapia, Haplotypes, Evolutionary biology, Hybridization, Genetic, Human medicine, gene flow, adaptive radiation, human activities, Founder effect

Abstract

The adaptive radiation of cichlid fishes in East Afrian Lake Malawi encompasses over 500 species that are believed to have evolved within the last 800 thousand years from a common founder population. It has been proposed that hybridisation between ancestral lineages can provide the genetic raw material to fuel such exceptionally high diversification rates, and evidence for this has recently been presented for the Lake Victoria Region cichlid superflock. Here we report that Lake Malawi cichlid genomes also show evidence of hybridisation between two lineages that split 3-4 million years ago, today represented by Lake Victoria cichlids and the riverine Astatotilapia sp. ‘ruaha blue’. The two ancestries in Malawi cichlid genomes are present in large blocks of several kilobases, but there is little variation in this pattern between Malawi cichlid species, suggesting that the large-scale mosaic structure of the genomes was largely established prior to the radiation. Nevertheless, tens of thousands of polymorphic variants apparently derived from the hybridisation are interspersed in the genomes. These loci show a striking excess of differentiation across ecological subgroups in the Lake Malawi cichlid assemblage, and parental alleles sort differentially into benthic and pelagic Malawi cichlid lineages, consistent with strong differential selection on these loci during species divergence. Furthermore, these loci are enriched for genes involved in immune response and vision, including opsin genes previously identified as important for speciation. Our results reinforce the role of ancestral hybridisation in explosive diversification by demonstrating its significance in one of the largest recent vertebrate adaptive radiations.

Published

2019

10. Whole-genome sequences of Malawi cichlids reveal multiple radiations interconnected by gene flow

Author

Eric A. Miska, Martin J. Genner, George F. Turner, Hannes Svardal, Alexandra M. Tyers, Milan Malinsky, Richard Durbin, Malinsky, Milan [0000-0002-1462-6317], Svardal, Hannes [0000-0001-7866-7313], Miska, Eric A [0000-0002-4450-576X], Durbin, Richard [0000-0002-9130-1006], and Apollo - University of Cambridge Repository

Subjects

0106 biological sciences, 0301 basic medicine, Gene Flow, Malawi, Introgression, Generalist and specialist species, 010603 evolutionary biology, 01 natural sciences, Tanzania, Article, Gene flow, 03 medical and health sciences, Cichlid, biology.animal, Adaptive radiation, Animals, 14. Life underwater, Biology, Ecology, Evolution, Behavior and Systematics, Phylogeny, 030304 developmental biology, Genetics, 0303 health sciences, Genome, Ecology, biology, Phylogenetic tree, Whole Genome Sequencing, Oxygen transport, Vertebrate, Genetic Variation, Cichlids, biology.organism_classification, Biological Evolution, Chemistry, Lakes, 030104 developmental biology, Evolutionary biology

Abstract

The hundreds of cichlid fish species in Lake Malawi constitute the most extensive recent vertebrate adaptive radiation. Here we characterize its genomic diversity by sequencing 134 individuals covering 73 species across all major lineages. Average sequence divergence between species pairs is only 0.1-0.25%. These divergence values overlap diversity within species, with 82% of heterozygosity shared between species. Phylogenetic analyses suggest that diversification initially proceeded by serial branching from a generalistAstatotilapia-likeancestor. However, no single species tree adequately represents all species relationships, with evidence for substantial gene flow at multiple times. Common signatures of selection on visual and oxygen transport genes shared by distantly related deep water species point to both adaptive introgression and independent selection. These findings enhance our understanding of genomic processes underlying rapid species diversification, and provide a platform for future genetic analysis of the Malawi radiation.One Sentence Summary: The genomes of 73 cichlid fish species from Lake Malawi uncover evolutionary processes underlying a large adaptive evolutionary radiation.

Published

2018