Ethan R Tolman, Christopher D Beatty, Aaron Goodman, Priscilla Ramchand, Tara McAllister, Kelly Reyes, Akifa Zahara, Kassandra Taveras, Vincent Wade, John Abbott, Seth Bybee, Robert Guralnick, Kathleen M Harding, Manpreet K Kohli, Paul B Frandsen, Jessica Ware, Anton Suvorov
{"title":"海拔和海洋的屏障影响了Aotearoa的Kapokapowai(欧洲目)蜻蜓的分布、扩散和多样性。","authors":"Ethan R Tolman, Christopher D Beatty, Aaron Goodman, Priscilla Ramchand, Tara McAllister, Kelly Reyes, Akifa Zahara, Kassandra Taveras, Vincent Wade, John Abbott, Seth Bybee, Robert Guralnick, Kathleen M Harding, Manpreet K Kohli, Paul B Frandsen, Jessica Ware, Anton Suvorov","doi":"10.1093/evolut/qpaf150","DOIUrl":null,"url":null,"abstract":"<p><p>Mountains and islands provide an opportunity for studying the biogeography of diversification and population fragmentation. Aotearoa (New Zealand) is an excellent location to investigate both phenomena due to alpine emergence and oceanic separation. While it would be expected that separation across oceanic and elevation gradients are major barriers to gene flow in animals, including aquatic insects, such hypotheses have not been thoroughly tested in these taxa. By integrating population genomic from subgenomic Anchored-Hybrid Enrichment sequencing, ecological niche modeling, and morphological analyses from scanning-electron microscopy, we show that tectonic uplift and oceanic vicariance are implicated in speciation and population structure in Kapokapowai (Uropetala) dragonflies. Although Te Moana o Raukawa (Cook Strait) is likely responsible for some of the genetic structure observed, speciation has not yet occurred in populations separated by the strait. We find that the altitudinal gradient across Kā Tiritiri-o-te-Moana (the Southern Alps) is not impervious, but it significantly restricts gene flow between the aforementioned species. Our data support the hypothesis of an active colonization of Kā Tiritiri-o-te-Moana by the ancestral population of Kapokapowai, followed by a recolonization of the lowlands. These findings provide key foundations for the study of lineages endemic to Aotearoa.</p>","PeriodicalId":12082,"journal":{"name":"Evolution","volume":" ","pages":"2219-2235"},"PeriodicalIF":2.6000,"publicationDate":"2025-10-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Elevational and oceanic barriers shape the distribution, dispersal, and diversity of Aotearoa's Kapokapowai (Uropetala) dragonflies.\",\"authors\":\"Ethan R Tolman, Christopher D Beatty, Aaron Goodman, Priscilla Ramchand, Tara McAllister, Kelly Reyes, Akifa Zahara, Kassandra Taveras, Vincent Wade, John Abbott, Seth Bybee, Robert Guralnick, Kathleen M Harding, Manpreet K Kohli, Paul B Frandsen, Jessica Ware, Anton Suvorov\",\"doi\":\"10.1093/evolut/qpaf150\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Mountains and islands provide an opportunity for studying the biogeography of diversification and population fragmentation. 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We find that the altitudinal gradient across Kā Tiritiri-o-te-Moana (the Southern Alps) is not impervious, but it significantly restricts gene flow between the aforementioned species. Our data support the hypothesis of an active colonization of Kā Tiritiri-o-te-Moana by the ancestral population of Kapokapowai, followed by a recolonization of the lowlands. 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Elevational and oceanic barriers shape the distribution, dispersal, and diversity of Aotearoa's Kapokapowai (Uropetala) dragonflies.
Mountains and islands provide an opportunity for studying the biogeography of diversification and population fragmentation. Aotearoa (New Zealand) is an excellent location to investigate both phenomena due to alpine emergence and oceanic separation. While it would be expected that separation across oceanic and elevation gradients are major barriers to gene flow in animals, including aquatic insects, such hypotheses have not been thoroughly tested in these taxa. By integrating population genomic from subgenomic Anchored-Hybrid Enrichment sequencing, ecological niche modeling, and morphological analyses from scanning-electron microscopy, we show that tectonic uplift and oceanic vicariance are implicated in speciation and population structure in Kapokapowai (Uropetala) dragonflies. Although Te Moana o Raukawa (Cook Strait) is likely responsible for some of the genetic structure observed, speciation has not yet occurred in populations separated by the strait. We find that the altitudinal gradient across Kā Tiritiri-o-te-Moana (the Southern Alps) is not impervious, but it significantly restricts gene flow between the aforementioned species. Our data support the hypothesis of an active colonization of Kā Tiritiri-o-te-Moana by the ancestral population of Kapokapowai, followed by a recolonization of the lowlands. These findings provide key foundations for the study of lineages endemic to Aotearoa.
期刊介绍:
Evolution, published for the Society for the Study of Evolution, is the premier publication devoted to the study of organic evolution and the integration of the various fields of science concerned with evolution. The journal presents significant and original results that extend our understanding of evolutionary phenomena and processes.