A genomic assessment of the marine-speciation paradox within the toothed whale superfamily Delphinoidea

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A genomic assessment of the marine-speciation paradox within the toothed whale superfamily Delphinoidea. / Westbury, Michael V.; Cabrera, Andrea A.; Rey-Iglesia, Alba; De Cahsan, Binia; Duchêne, David A.; Hartmann, Stefanie; Lorenzen, Eline D.

In: Molecular Ecology, Vol. 32, No. 17, 2023, p. 4829-4843.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Westbury, MV, Cabrera, AA, Rey-Iglesia, A, De Cahsan, B, Duchêne, DA, Hartmann, S & Lorenzen, ED 2023, 'A genomic assessment of the marine-speciation paradox within the toothed whale superfamily Delphinoidea', Molecular Ecology, vol. 32, no. 17, pp. 4829-4843. https://doi.org/10.1111/mec.17069

APA

Westbury, M. V., Cabrera, A. A., Rey-Iglesia, A., De Cahsan, B., Duchêne, D. A., Hartmann, S., & Lorenzen, E. D. (2023). A genomic assessment of the marine-speciation paradox within the toothed whale superfamily Delphinoidea. Molecular Ecology, 32(17), 4829-4843. https://doi.org/10.1111/mec.17069

Vancouver

Westbury MV, Cabrera AA, Rey-Iglesia A, De Cahsan B, Duchêne DA, Hartmann S et al. A genomic assessment of the marine-speciation paradox within the toothed whale superfamily Delphinoidea. Molecular Ecology. 2023;32(17):4829-4843. https://doi.org/10.1111/mec.17069

Author

Westbury, Michael V. ; Cabrera, Andrea A. ; Rey-Iglesia, Alba ; De Cahsan, Binia ; Duchêne, David A. ; Hartmann, Stefanie ; Lorenzen, Eline D. / A genomic assessment of the marine-speciation paradox within the toothed whale superfamily Delphinoidea. In: Molecular Ecology. 2023 ; Vol. 32, No. 17. pp. 4829-4843.

Bibtex

@article{974f9db2da894bf9a521e0f0dc4cb931,
title = "A genomic assessment of the marine-speciation paradox within the toothed whale superfamily Delphinoidea",
abstract = "The impact of post-divergence gene flow in speciation has been documented across a range of taxa in recent years, and may have been especially widespread in highly mobile, wide-ranging marine species, such as cetaceans. Here, we studied individual genomes from nine species across the three families of the toothed whale superfamily Delphinoidea (Delphinidae, Phocoenidae and Monodontidae). To investigate the role of post-divergence gene flow in the speciation process, we used a multifaceted approach, including (i) phylogenomics, (ii) the distribution of shared derived alleles and (iii) demographic inference. We found the divergence of lineages within Delphinoidea did not follow a process of pure bifurcation, but was much more complex. Sliding-window phylogenomics reveal a high prevalence of discordant topologies within the superfamily, with further analyses indicating these discordances arose due to both incomplete lineage sorting and gene flow. D-statistics and f-branch analyses supported gene flow between members of Delphinoidea, with the vast majority of gene flow occurring as ancient interfamilial events. Demographic analyses provided evidence that introgressive gene flow has likely ceased between all species pairs tested, despite reports of contemporary interspecific hybrids. Our study provides the first steps towards resolving the large complexity of speciation within Delphinoidea; we reveal the prevalence of ancient interfamilial gene flow events prior to the diversification of each family, and suggest that contemporary hybridisation events may be disadvantageous, as hybrid individuals do not appear to contribute to the parental species' gene pools.",
keywords = "genomics, hybridization, mammals, molecular evolution, speciation",
author = "Westbury, {Michael V.} and Cabrera, {Andrea A.} and Alba Rey-Iglesia and Binia De Cahsan and Duch{\^e}ne, {David A.} and Stefanie Hartmann and Lorenzen, {Eline D.}",
note = "Publisher Copyright: {\textcopyright} 2023 The Authors. Molecular Ecology published by John Wiley & Sons Ltd.",
year = "2023",
doi = "10.1111/mec.17069",
language = "English",
volume = "32",
pages = "4829--4843",
journal = "Molecular Ecology",
issn = "0962-1083",
publisher = "Wiley-Blackwell",
number = "17",

}

RIS

TY - JOUR

T1 - A genomic assessment of the marine-speciation paradox within the toothed whale superfamily Delphinoidea

AU - Westbury, Michael V.

AU - Cabrera, Andrea A.

AU - Rey-Iglesia, Alba

AU - De Cahsan, Binia

AU - Duchêne, David A.

AU - Hartmann, Stefanie

AU - Lorenzen, Eline D.

N1 - Publisher Copyright: © 2023 The Authors. Molecular Ecology published by John Wiley & Sons Ltd.

PY - 2023

Y1 - 2023

N2 - The impact of post-divergence gene flow in speciation has been documented across a range of taxa in recent years, and may have been especially widespread in highly mobile, wide-ranging marine species, such as cetaceans. Here, we studied individual genomes from nine species across the three families of the toothed whale superfamily Delphinoidea (Delphinidae, Phocoenidae and Monodontidae). To investigate the role of post-divergence gene flow in the speciation process, we used a multifaceted approach, including (i) phylogenomics, (ii) the distribution of shared derived alleles and (iii) demographic inference. We found the divergence of lineages within Delphinoidea did not follow a process of pure bifurcation, but was much more complex. Sliding-window phylogenomics reveal a high prevalence of discordant topologies within the superfamily, with further analyses indicating these discordances arose due to both incomplete lineage sorting and gene flow. D-statistics and f-branch analyses supported gene flow between members of Delphinoidea, with the vast majority of gene flow occurring as ancient interfamilial events. Demographic analyses provided evidence that introgressive gene flow has likely ceased between all species pairs tested, despite reports of contemporary interspecific hybrids. Our study provides the first steps towards resolving the large complexity of speciation within Delphinoidea; we reveal the prevalence of ancient interfamilial gene flow events prior to the diversification of each family, and suggest that contemporary hybridisation events may be disadvantageous, as hybrid individuals do not appear to contribute to the parental species' gene pools.

AB - The impact of post-divergence gene flow in speciation has been documented across a range of taxa in recent years, and may have been especially widespread in highly mobile, wide-ranging marine species, such as cetaceans. Here, we studied individual genomes from nine species across the three families of the toothed whale superfamily Delphinoidea (Delphinidae, Phocoenidae and Monodontidae). To investigate the role of post-divergence gene flow in the speciation process, we used a multifaceted approach, including (i) phylogenomics, (ii) the distribution of shared derived alleles and (iii) demographic inference. We found the divergence of lineages within Delphinoidea did not follow a process of pure bifurcation, but was much more complex. Sliding-window phylogenomics reveal a high prevalence of discordant topologies within the superfamily, with further analyses indicating these discordances arose due to both incomplete lineage sorting and gene flow. D-statistics and f-branch analyses supported gene flow between members of Delphinoidea, with the vast majority of gene flow occurring as ancient interfamilial events. Demographic analyses provided evidence that introgressive gene flow has likely ceased between all species pairs tested, despite reports of contemporary interspecific hybrids. Our study provides the first steps towards resolving the large complexity of speciation within Delphinoidea; we reveal the prevalence of ancient interfamilial gene flow events prior to the diversification of each family, and suggest that contemporary hybridisation events may be disadvantageous, as hybrid individuals do not appear to contribute to the parental species' gene pools.

KW - genomics

KW - hybridization

KW - mammals

KW - molecular evolution

KW - speciation

U2 - 10.1111/mec.17069

DO - 10.1111/mec.17069

M3 - Journal article

C2 - 37448145

AN - SCOPUS:85165142555

VL - 32

SP - 4829

EP - 4843

JO - Molecular Ecology

JF - Molecular Ecology

SN - 0962-1083

IS - 17

ER -

ID: 361692719