Atlantic-wide connectivity of Ascension Island green turtles revealed by finer-scale mitochondrial DNA markers

Coveney, Sophia; Jiménez-Guri, Eva; Ball, Samantha; Mianseko, Nathalie; Broderick, Annette C.; Godley, Brendan J.; Hancock, Joana M.; Pereira, Welton Quirino; Regalla, Aissa; Rocha, Rita Gomes; Senhoury, Cheibani; Thoisy, Benoit de; Tilley, Dominic; Vargas, Sarah Maria; Weber, Sam B.; Patrício, Ana Rita

doi:10.1007/s10592-025-01720-3

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Atlantic-wide connectivity of Ascension Island green turtles revealed by finer-scale mitochondrial DNA markers

Sophia Coveney, Eva Jiménez-Guri

, Samantha Ball

, Nathalie Mianseko, Annette C. Broderick

, Brendan J. Godley

, Joana M. Hancock

, Welton Quirino Pereira, Aissa Regalla

, Rita Gomes Rocha

, Cheibani Senhoury, Benoit de Thoisy

, Dominic Tilley

, Sarah Maria Vargas

, Sam B. Weber

, Ana Rita Patrício

Conservation Genetics

Swansea University Author: Sophia Coveney

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DOI (Published version): 10.1007/s10592-025-01720-3

Abstract

Marine turtles undertake long migrations across different geographies and habitats, exposing them to a wide range of threats throughout their lifespan. Analysing population structure and connectivity is key to informing effective conservation management. We expand knowledge of Atlantic-wide connecti...

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Published in:	Conservation Genetics
ISSN:	1566-0621 1572-9737
Published:	Springer Science and Business Media LLC 2025
Online Access:	Check full text
URI:	https://cronfa.swan.ac.uk/Record/cronfa70122

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spelling	2025-10-06T13:16:54.0345005 v2 70122 2025-08-07 Atlantic-wide connectivity of Ascension Island green turtles revealed by finer-scale mitochondrial DNA markers d1d2ee71208adad26732e182016973e3 Sophia Coveney Sophia Coveney true false 2025-08-07 BGPS Marine turtles undertake long migrations across different geographies and habitats, exposing them to a wide range of threats throughout their lifespan. Analysing population structure and connectivity is key to informing effective conservation management. We expand knowledge of Atlantic-wide connectivity of green turtles (Chelonia mydas) by characterising the genetic structure of the Ascension Island nesting population, one of the largest in the Atlantic Ocean, and carrying out Atlantic population structure and mixed stock analyses using high-resolution genetic markers. We amplified a ~ 738 bp fragment (extended D-loop) and a highly polymorphic mitochondrial short tandem repeat (mtSTR) fragment of the mitochondrial DNA control region, designating haplotypes based on (1) extended D-loop and (2) the extended D-loop and mtSTR combined. Overall, 11 extended D-loop and 33 combined haplotypes were found, the dominant haplotypes being CM-A8.1 and CM-A8.1/7-12-4-4. Population structure analysis found three main genetic groups: Northwest Atlantic, Northern South America, and South and East Atlantic. Mixed stock analyses indicate Ascension Island as a major source for juvenile foraging aggregations in the Southwest Atlantic (34–55%) and Central Africa (18–78%), with some contribution to West Africa (3–20%). Green turtles are vulnerable to fishery bycatch in the coastal waters of the South and East Atlantic. Our study underlines how improving sample sizes of Atlantic mtSTR haplotypes could further elucidate green turtle connectivity across threatened regions. We urge international collaboration to minimise mtSTR data gaps, in order to enhance connectivity assessments and improve conservation measures between countries that share populations. Journal Article Conservation Genetics 0 Springer Science and Business Media LLC 1566-0621 1572-9737 mtDNA; Chelonia mydas; mtSTR; Population genetics; Mixed stock analysis; Sea turtles 22 8 2025 2025-08-22 10.1007/s10592-025-01720-3 COLLEGE NANME Biosciences Geography and Physics School COLLEGE CODE BGPS Swansea University SU Library paid the OA fee (TA Institutional Deal) Fundação Renova (Technical-Scientific Cooperation Agreement n◦ 30/2018 with FEST - Brazil); Fundação do Estado do Espírito Santo, Brazil (Scholarship #143/2022); Fundação para a Ciência e a Tecnologia (2022-00505.CEECIND, 2023.07021.CEECIND/CP2831/CT0012); Natural Environment Research Council (NE/L009501/1). 2025-10-06T13:16:54.0345005 2025-08-07T10:16:54.9774181 Faculty of Science and Engineering School of Biosciences, Geography and Physics - Biosciences Sophia Coveney 1 Eva Jiménez-Guri 0000-0002-9592-1077 2 Samantha Ball 0000-0002-5147-7111 3 Nathalie Mianseko 4 Annette C. Broderick 0000-0003-1444-1782 5 Brendan J. Godley 0000-0003-3845-0034 6 Joana M. Hancock 0000-0002-6171-8273 7 Welton Quirino Pereira 8 Aissa Regalla 0000-0003-1522-8211 9 Rita Gomes Rocha 0000-0002-4410-3648 10 Cheibani Senhoury 11 Benoit de Thoisy 0000-0002-8420-5112 12 Dominic Tilley 0000-0002-5427-191x 13 Sarah Maria Vargas 0000-0002-8042-7295 14 Sam B. Weber 0000-0003-1447-4082 15 Ana Rita Patrício 0000-0003-4963-2343 16 70122__35257__78a247bc1843403bb2fdee36e1fc1576.pdf 70122.VoR.pdf 2025-10-06T12:19:27.4088963 Output 2537757 application/pdf Version of Record true © The Author(s) 2025. This article is licensed under a Creative Commons Attribution 4.0 International License. true eng http://creativecommons.org/licenses/by/4.0/
title	Atlantic-wide connectivity of Ascension Island green turtles revealed by finer-scale mitochondrial DNA markers
spellingShingle	Atlantic-wide connectivity of Ascension Island green turtles revealed by finer-scale mitochondrial DNA markers Sophia Coveney
title_short	Atlantic-wide connectivity of Ascension Island green turtles revealed by finer-scale mitochondrial DNA markers
title_full	Atlantic-wide connectivity of Ascension Island green turtles revealed by finer-scale mitochondrial DNA markers
title_fullStr	Atlantic-wide connectivity of Ascension Island green turtles revealed by finer-scale mitochondrial DNA markers
title_full_unstemmed	Atlantic-wide connectivity of Ascension Island green turtles revealed by finer-scale mitochondrial DNA markers
title_sort	Atlantic-wide connectivity of Ascension Island green turtles revealed by finer-scale mitochondrial DNA markers
author_id_str_mv	d1d2ee71208adad26732e182016973e3
author_id_fullname_str_mv	d1d2ee71208adad26732e182016973e3_***_Sophia Coveney
author	Sophia Coveney
author2	Sophia Coveney Eva Jiménez-Guri Samantha Ball Nathalie Mianseko Annette C. Broderick Brendan J. Godley Joana M. Hancock Welton Quirino Pereira Aissa Regalla Rita Gomes Rocha Cheibani Senhoury Benoit de Thoisy Dominic Tilley Sarah Maria Vargas Sam B. Weber Ana Rita Patrício
format	Journal article
container_title	Conservation Genetics
container_volume	0
publishDate	2025
institution	Swansea University
issn	1566-0621 1572-9737
doi_str_mv	10.1007/s10592-025-01720-3
publisher	Springer Science and Business Media LLC
college_str	Faculty of Science and Engineering
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hierarchy_top_title	Faculty of Science and Engineering
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department_str	School of Biosciences, Geography and Physics - Biosciences{{{_:::_}}}Faculty of Science and Engineering{{{_:::_}}}School of Biosciences, Geography and Physics - Biosciences
document_store_str	1
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description	Marine turtles undertake long migrations across different geographies and habitats, exposing them to a wide range of threats throughout their lifespan. Analysing population structure and connectivity is key to informing effective conservation management. We expand knowledge of Atlantic-wide connectivity of green turtles (Chelonia mydas) by characterising the genetic structure of the Ascension Island nesting population, one of the largest in the Atlantic Ocean, and carrying out Atlantic population structure and mixed stock analyses using high-resolution genetic markers. We amplified a ~ 738 bp fragment (extended D-loop) and a highly polymorphic mitochondrial short tandem repeat (mtSTR) fragment of the mitochondrial DNA control region, designating haplotypes based on (1) extended D-loop and (2) the extended D-loop and mtSTR combined. Overall, 11 extended D-loop and 33 combined haplotypes were found, the dominant haplotypes being CM-A8.1 and CM-A8.1/7-12-4-4. Population structure analysis found three main genetic groups: Northwest Atlantic, Northern South America, and South and East Atlantic. Mixed stock analyses indicate Ascension Island as a major source for juvenile foraging aggregations in the Southwest Atlantic (34–55%) and Central Africa (18–78%), with some contribution to West Africa (3–20%). Green turtles are vulnerable to fishery bycatch in the coastal waters of the South and East Atlantic. Our study underlines how improving sample sizes of Atlantic mtSTR haplotypes could further elucidate green turtle connectivity across threatened regions. We urge international collaboration to minimise mtSTR data gaps, in order to enhance connectivity assessments and improve conservation measures between countries that share populations.
published_date	2025-08-22T05:30:02Z
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Atlantic-wide connectivity of Ascension Island green turtles revealed by finer-scale mitochondrial DNA markers

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