Persistent Gene Flow Suggests an Absence of Reproductive Isolation in an African Antelope Speciation Model

Xi Wang; Casper-Emil Tingskov Pedersen; Georgios Athanasiadis; Genís Garcia-Erill; Kristian Hanghøj; Laura D Bertola; Malthe Sebro Rasmussen; Mikkel Schubert; Xiaodong Liu; Zilong Li; Long Lin; Renzo F Balboa; Emil Jørsboe; Casia Nursyifa; Shanlin Liu; Vincent Muwanika; Charles Masembe; Lei Chen; Wen Wang; Ida Moltke; Hans R Siegismund; Anders Albrechtsen; Rasmus Heller

doi:10.1093/sysbio/syae037

Persistent Gene Flow Suggests an Absence of Reproductive Isolation in an African Antelope Speciation Model

Xi Wang, Casper-Emil Tingskov Pedersen, Georgios Athanasiadis, Genís Garcia-Erill, Kristian Hanghøj, Laura D Bertola, Malthe Sebro Rasmussen, Mikkel Schubert, Xiaodong Liu, Zilong Li, Long Lin, Renzo F Balboa, Emil Jørsboe, Casia Nursyifa, Shanlin Liu, Vincent Muwanika, Charles Masembe, Lei Chen, Wen Wang, Ida MoltkeHans R Siegismund, Anders Albrechtsen^*, Rasmus Heller^*

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

African antelope diversity is a globally unique vestige of a much richer world-wide Pleistocene megafauna. Despite this, the evolutionary processes leading to the prolific radiation of African antelopes are not well understood. Here, we sequenced 145 whole genomes from both subspecies of the waterbuck (Kobus ellipsiprymnus), an African antelope believed to be in the process of speciation. We investigated genetic structure and population divergence and found evidence of a mid-Pleistocene separation on either side of the eastern Great Rift Valley, consistent with vicariance caused by a rain shadow along the so-called “Kingdon’s Line.” However, we also found pervasive evidence of both recent and widespread historical gene flow across the Rift Valley barrier. By inferring the genome-wide landscape of variation among subspecies, we found 14 genomic regions of elevated differentiation, including a locus that may be related to each subspecies’ distinctive coat pigmentation pattern. We investigated these regions as candidate speciation islands. However, we observed no significant reduction in gene flow in these regions, nor any indications of selection against hybrids. Altogether, these results suggest a pattern whereby climatically driven vicariance is the most important process driving the African antelope radiation and suggest that reproductive isolation may not set in until very late in the divergence process. This has a significant impact on taxonomic inference, as many taxa will be in a gray area of ambiguous systematic status, possibly explaining why it has been hard to achieve consensus regarding the species status of many African antelopes. Our analyses demonstrate how population genetics based on low-depth whole genome sequencing can provide new insights that can help resolve how far lineages have gone along the path to speciation.

Original language	English
Journal	Systematic Biology
Volume	73
Issue number	6
Pages (from-to)	979–994
Number of pages	16
ISSN	1063-5157
DOIs	https://doi.org/10.1093/sysbio/syae037
Publication status	Published - 2024

Bibliographical note

Funding Information:
We thank Amal al-Chaer for her laboratory work on extracting DNA from the tissue samples. Wildlife authorities from Ghana, Uganda, Kenya, Tanzania, and Zambia are thanked for their support and permissions. Peter Arctander is thanked for his huge efforts towards sample collection. Three anonymous reviewers, the Associate Editor and the Editor are thanked for their helpful comments and suggestions, which improved the paper. XW, LDB and RH were supported by an European Research Council Starting Grant (No. 853442), and RH was furthermore supported by a Carlsberg Foundation Young Researcher grant (CF21-0497).

Publisher Copyright:
© 2024 The Author(s).

Keywords

Admixture
islands of differentiation
speciation genomics
waterbuck
Waterbuck

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Cite this

Wang, X., Pedersen, C.-E. T., Athanasiadis, G., Garcia-Erill, G., Hanghøj, K., Bertola, L. D., Rasmussen, M. S., Schubert, M., Liu, X., Li, Z., Lin, L., Balboa, R. F., Jørsboe, E., Nursyifa, C., Liu, S., Muwanika, V., Masembe, C., Chen, L., Wang, W., ... Heller, R. (2024). Persistent Gene Flow Suggests an Absence of Reproductive Isolation in an African Antelope Speciation Model. Systematic Biology, 73(6), 979–994. https://doi.org/10.1093/sysbio/syae037

Wang, X, Pedersen, C-ET, Athanasiadis, G, Garcia-Erill, G , Hanghøj, K, Bertola, LD, Rasmussen, MS , Schubert, M , Liu, X , Li, Z, Lin, L, Balboa, RF , Jørsboe, E , Nursyifa, C, Liu, S, Muwanika, V, Masembe, C, Chen, L, Wang, W, Moltke, I , Siegismund, HR , Albrechtsen, A & Heller, R 2024, 'Persistent Gene Flow Suggests an Absence of Reproductive Isolation in an African Antelope Speciation Model', Systematic Biology, vol. 73, no. 6, pp. 979–994. https://doi.org/10.1093/sysbio/syae037

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abstract = "African antelope diversity is a globally unique vestige of a much richer world-wide Pleistocene megafauna. Despite this, the evolutionary processes leading to the prolific radiation of African antelopes are not well understood. Here, we sequenced 145 whole genomes from both subspecies of the waterbuck (Kobus ellipsiprymnus), an African antelope believed to be in the process of speciation. We investigated genetic structure and population divergence and found evidence of a mid-Pleistocene separation on either side of the eastern Great Rift Valley, consistent with vicariance caused by a rain shadow along the so-called “Kingdon{\textquoteright}s Line.” However, we also found pervasive evidence of both recent and widespread historical gene flow across the Rift Valley barrier. By inferring the genome-wide landscape of variation among subspecies, we found 14 genomic regions of elevated differentiation, including a locus that may be related to each subspecies{\textquoteright} distinctive coat pigmentation pattern. We investigated these regions as candidate speciation islands. However, we observed no significant reduction in gene flow in these regions, nor any indications of selection against hybrids. Altogether, these results suggest a pattern whereby climatically driven vicariance is the most important process driving the African antelope radiation and suggest that reproductive isolation may not set in until very late in the divergence process. This has a significant impact on taxonomic inference, as many taxa will be in a gray area of ambiguous systematic status, possibly explaining why it has been hard to achieve consensus regarding the species status of many African antelopes. Our analyses demonstrate how population genetics based on low-depth whole genome sequencing can provide new insights that can help resolve how far lineages have gone along the path to speciation.",

keywords = "Admixture, islands of differentiation, speciation genomics, waterbuck, Waterbuck",

author = "Xi Wang and Pedersen, {Casper-Emil Tingskov} and Georgios Athanasiadis and Gen{\'i}s Garcia-Erill and Kristian Hangh{\o}j and Bertola, {Laura D} and Rasmussen, {Malthe Sebro} and Mikkel Schubert and Xiaodong Liu and Zilong Li and Long Lin and Balboa, {Renzo F} and Emil J{\o}rsboe and Casia Nursyifa and Shanlin Liu and Vincent Muwanika and Charles Masembe and Lei Chen and Wen Wang and Ida Moltke and Siegismund, {Hans R} and Anders Albrechtsen and Rasmus Heller",

note = "Funding Information: We thank Amal al-Chaer for her laboratory work on extracting DNA from the tissue samples. Wildlife authorities from Ghana, Uganda, Kenya, Tanzania, and Zambia are thanked for their support and permissions. Peter Arctander is thanked for his huge efforts towards sample collection. Three anonymous reviewers, the Associate Editor and the Editor are thanked for their helpful comments and suggestions, which improved the paper. XW, LDB and RH were supported by an European Research Council Starting Grant (No. 853442), and RH was furthermore supported by a Carlsberg Foundation Young Researcher grant (CF21-0497). Publisher Copyright: {\textcopyright} 2024 The Author(s).",

year = "2024",

doi = "10.1093/sysbio/syae037",

language = "English",

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T1 - Persistent Gene Flow Suggests an Absence of Reproductive Isolation in an African Antelope Speciation Model

AU - Wang, Xi

AU - Pedersen, Casper-Emil Tingskov

AU - Athanasiadis, Georgios

AU - Garcia-Erill, Genís

AU - Hanghøj, Kristian

AU - Bertola, Laura D

AU - Rasmussen, Malthe Sebro

AU - Schubert, Mikkel

AU - Liu, Xiaodong

AU - Li, Zilong

AU - Lin, Long

AU - Balboa, Renzo F

AU - Jørsboe, Emil

AU - Nursyifa, Casia

AU - Liu, Shanlin

AU - Muwanika, Vincent

AU - Masembe, Charles

AU - Chen, Lei

AU - Wang, Wen

AU - Moltke, Ida

AU - Siegismund, Hans R

AU - Albrechtsen, Anders

AU - Heller, Rasmus

N1 - Funding Information: We thank Amal al-Chaer for her laboratory work on extracting DNA from the tissue samples. Wildlife authorities from Ghana, Uganda, Kenya, Tanzania, and Zambia are thanked for their support and permissions. Peter Arctander is thanked for his huge efforts towards sample collection. Three anonymous reviewers, the Associate Editor and the Editor are thanked for their helpful comments and suggestions, which improved the paper. XW, LDB and RH were supported by an European Research Council Starting Grant (No. 853442), and RH was furthermore supported by a Carlsberg Foundation Young Researcher grant (CF21-0497). Publisher Copyright: © 2024 The Author(s).

PY - 2024

Y1 - 2024

N2 - African antelope diversity is a globally unique vestige of a much richer world-wide Pleistocene megafauna. Despite this, the evolutionary processes leading to the prolific radiation of African antelopes are not well understood. Here, we sequenced 145 whole genomes from both subspecies of the waterbuck (Kobus ellipsiprymnus), an African antelope believed to be in the process of speciation. We investigated genetic structure and population divergence and found evidence of a mid-Pleistocene separation on either side of the eastern Great Rift Valley, consistent with vicariance caused by a rain shadow along the so-called “Kingdon’s Line.” However, we also found pervasive evidence of both recent and widespread historical gene flow across the Rift Valley barrier. By inferring the genome-wide landscape of variation among subspecies, we found 14 genomic regions of elevated differentiation, including a locus that may be related to each subspecies’ distinctive coat pigmentation pattern. We investigated these regions as candidate speciation islands. However, we observed no significant reduction in gene flow in these regions, nor any indications of selection against hybrids. Altogether, these results suggest a pattern whereby climatically driven vicariance is the most important process driving the African antelope radiation and suggest that reproductive isolation may not set in until very late in the divergence process. This has a significant impact on taxonomic inference, as many taxa will be in a gray area of ambiguous systematic status, possibly explaining why it has been hard to achieve consensus regarding the species status of many African antelopes. Our analyses demonstrate how population genetics based on low-depth whole genome sequencing can provide new insights that can help resolve how far lineages have gone along the path to speciation.

AB - African antelope diversity is a globally unique vestige of a much richer world-wide Pleistocene megafauna. Despite this, the evolutionary processes leading to the prolific radiation of African antelopes are not well understood. Here, we sequenced 145 whole genomes from both subspecies of the waterbuck (Kobus ellipsiprymnus), an African antelope believed to be in the process of speciation. We investigated genetic structure and population divergence and found evidence of a mid-Pleistocene separation on either side of the eastern Great Rift Valley, consistent with vicariance caused by a rain shadow along the so-called “Kingdon’s Line.” However, we also found pervasive evidence of both recent and widespread historical gene flow across the Rift Valley barrier. By inferring the genome-wide landscape of variation among subspecies, we found 14 genomic regions of elevated differentiation, including a locus that may be related to each subspecies’ distinctive coat pigmentation pattern. We investigated these regions as candidate speciation islands. However, we observed no significant reduction in gene flow in these regions, nor any indications of selection against hybrids. Altogether, these results suggest a pattern whereby climatically driven vicariance is the most important process driving the African antelope radiation and suggest that reproductive isolation may not set in until very late in the divergence process. This has a significant impact on taxonomic inference, as many taxa will be in a gray area of ambiguous systematic status, possibly explaining why it has been hard to achieve consensus regarding the species status of many African antelopes. Our analyses demonstrate how population genetics based on low-depth whole genome sequencing can provide new insights that can help resolve how far lineages have gone along the path to speciation.

KW - Admixture

KW - islands of differentiation

KW - speciation genomics

KW - waterbuck

KW - Waterbuck

U2 - 10.1093/sysbio/syae037

DO - 10.1093/sysbio/syae037

M3 - Journal article

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SN - 1063-5157

VL - 73

SP - 979

EP - 994

JO - Systematic Biology

JF - Systematic Biology

IS - 6

ER -