Evolutionary innovations in Antarctic brittle stars linked to glacial refugia

The drivers behind evolutionary innovations such as contrasting life histories and morphological change are central questions of evolutionary biology. However, the environmental and ecological contexts linked to evolutionary innovations are generally unclear. During the Pleistocene glacial cycles, g...

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Main Authors:	SCY Lau, Jan Strugnell, CJ Sands, CNS Silva, NG Wilson
Format:	Other Non-Article Part of Journal/Newspaper
Language:	unknown
Published:	2022
Subjects:	Uncategorized Science & Technology Life Sciences & Biomedicine Ecology Evolutionary Biology Environmental Sciences & Ecology contrasting life histories evolutionary innovation glacial refugia morphological innovation population genetics SOUTHERN-OCEAN ECHINODERMATA-OPHIUROIDEA GENETIC-STRUCTURE MITOCHONDRIAL LINEAGES SPECIES DELIMITATION POPULATION-GENETICS CIRCUMPOLAR CURRENT CRYPTIC SPECIATION SEA BIODIVERSITY Antarctic Prydz Bay Scotia Sea Southern Ocean The Antarctic Antarc*
Online Access:	https://doi.org/10.26181/18516281.v1 https://figshare.com/articles/journal_contribution/Evolutionary_innovations_in_Antarctic_brittle_stars_linked_to_glacial_refugia/18516281

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spelling	ftlatrobeunivfig:oai:figshare.com:article/18516281 2023-05-15T13:40:20+02:00 Evolutionary innovations in Antarctic brittle stars linked to glacial refugia SCY Lau Jan Strugnell CJ Sands CNS Silva NG Wilson 2022-01-17T03:45:51Z https://doi.org/10.26181/18516281.v1 https://figshare.com/articles/journal_contribution/Evolutionary_innovations_in_Antarctic_brittle_stars_linked_to_glacial_refugia/18516281 unknown doi:10.26181/18516281.v1 https://figshare.com/articles/journal_contribution/Evolutionary_innovations_in_Antarctic_brittle_stars_linked_to_glacial_refugia/18516281 CC BY 4.0 CC-BY Uncategorized Science & Technology Life Sciences & Biomedicine Ecology Evolutionary Biology Environmental Sciences & Ecology contrasting life histories evolutionary innovation glacial refugia morphological innovation population genetics SOUTHERN-OCEAN ECHINODERMATA-OPHIUROIDEA GENETIC-STRUCTURE MITOCHONDRIAL LINEAGES SPECIES DELIMITATION POPULATION-GENETICS CIRCUMPOLAR CURRENT CRYPTIC SPECIATION SEA BIODIVERSITY Text Journal contribution 2022 ftlatrobeunivfig https://doi.org/10.26181/18516281.v1 2022-01-20T00:02:53Z The drivers behind evolutionary innovations such as contrasting life histories and morphological change are central questions of evolutionary biology. However, the environmental and ecological contexts linked to evolutionary innovations are generally unclear. During the Pleistocene glacial cycles, grounded ice sheets expanded across the Southern Ocean continental shelf. Limited ice-free areas remained, and fauna were isolated from other refugial populations. Survival in Southern Ocean refugia could present opportunities for ecological adaptation and evolutionary innovation. Here, we reconstructed the phylogeographic patterns of circum-Antarctic brittle stars Ophionotus victoriae and O. hexactis with contrasting life histories (broadcasting vs brooding) and morphology (5 vs 6 arms). We examined the evolutionary relationship between the two species using cytochrome c oxidase subunit I (COI) data. COI data suggested that O. victoriae is a single species (rather than a species complex) and is closely related to O. hexactis (a separate species). Since their recent divergence in the mid-Pleistocene, O. victoriae and O. hexactis likely persisted differently throughout glacial maxima, in deep-sea and Antarctic island refugia, respectively. Genetic connectivity, within and between the Antarctic continental shelf and islands, was also observed and could be linked to the Antarctic Circumpolar Current and local oceanographic regimes. Signatures of a probable seascape corridor linking connectivity between the Scotia Sea and Prydz Bay are also highlighted. We suggest that survival in Antarctic island refugia was associated with increase in arm number and a switch from broadcast spawning to brooding in O. hexactis, and propose that it could be linked to environmental changes (such as salinity) associated with intensified interglacial-glacial cycles. Other Non-Article Part of Journal/Newspaper Antarc* Antarctic Prydz Bay Scotia Sea Southern Ocean La Trobe University (Melbourne): Figshare Antarctic Prydz Bay Scotia Sea Southern Ocean The Antarctic
institution	Open Polar
collection	La Trobe University (Melbourne): Figshare
op_collection_id	ftlatrobeunivfig
language	unknown
topic	Uncategorized Science & Technology Life Sciences & Biomedicine Ecology Evolutionary Biology Environmental Sciences & Ecology contrasting life histories evolutionary innovation glacial refugia morphological innovation population genetics SOUTHERN-OCEAN ECHINODERMATA-OPHIUROIDEA GENETIC-STRUCTURE MITOCHONDRIAL LINEAGES SPECIES DELIMITATION POPULATION-GENETICS CIRCUMPOLAR CURRENT CRYPTIC SPECIATION SEA BIODIVERSITY
spellingShingle	Uncategorized Science & Technology Life Sciences & Biomedicine Ecology Evolutionary Biology Environmental Sciences & Ecology contrasting life histories evolutionary innovation glacial refugia morphological innovation population genetics SOUTHERN-OCEAN ECHINODERMATA-OPHIUROIDEA GENETIC-STRUCTURE MITOCHONDRIAL LINEAGES SPECIES DELIMITATION POPULATION-GENETICS CIRCUMPOLAR CURRENT CRYPTIC SPECIATION SEA BIODIVERSITY SCY Lau Jan Strugnell CJ Sands CNS Silva NG Wilson Evolutionary innovations in Antarctic brittle stars linked to glacial refugia
topic_facet	Uncategorized Science & Technology Life Sciences & Biomedicine Ecology Evolutionary Biology Environmental Sciences & Ecology contrasting life histories evolutionary innovation glacial refugia morphological innovation population genetics SOUTHERN-OCEAN ECHINODERMATA-OPHIUROIDEA GENETIC-STRUCTURE MITOCHONDRIAL LINEAGES SPECIES DELIMITATION POPULATION-GENETICS CIRCUMPOLAR CURRENT CRYPTIC SPECIATION SEA BIODIVERSITY
description	The drivers behind evolutionary innovations such as contrasting life histories and morphological change are central questions of evolutionary biology. However, the environmental and ecological contexts linked to evolutionary innovations are generally unclear. During the Pleistocene glacial cycles, grounded ice sheets expanded across the Southern Ocean continental shelf. Limited ice-free areas remained, and fauna were isolated from other refugial populations. Survival in Southern Ocean refugia could present opportunities for ecological adaptation and evolutionary innovation. Here, we reconstructed the phylogeographic patterns of circum-Antarctic brittle stars Ophionotus victoriae and O. hexactis with contrasting life histories (broadcasting vs brooding) and morphology (5 vs 6 arms). We examined the evolutionary relationship between the two species using cytochrome c oxidase subunit I (COI) data. COI data suggested that O. victoriae is a single species (rather than a species complex) and is closely related to O. hexactis (a separate species). Since their recent divergence in the mid-Pleistocene, O. victoriae and O. hexactis likely persisted differently throughout glacial maxima, in deep-sea and Antarctic island refugia, respectively. Genetic connectivity, within and between the Antarctic continental shelf and islands, was also observed and could be linked to the Antarctic Circumpolar Current and local oceanographic regimes. Signatures of a probable seascape corridor linking connectivity between the Scotia Sea and Prydz Bay are also highlighted. We suggest that survival in Antarctic island refugia was associated with increase in arm number and a switch from broadcast spawning to brooding in O. hexactis, and propose that it could be linked to environmental changes (such as salinity) associated with intensified interglacial-glacial cycles.
format	Other Non-Article Part of Journal/Newspaper
author	SCY Lau Jan Strugnell CJ Sands CNS Silva NG Wilson
author_facet	SCY Lau Jan Strugnell CJ Sands CNS Silva NG Wilson
author_sort	SCY Lau
title	Evolutionary innovations in Antarctic brittle stars linked to glacial refugia
title_short	Evolutionary innovations in Antarctic brittle stars linked to glacial refugia
title_full	Evolutionary innovations in Antarctic brittle stars linked to glacial refugia
title_fullStr	Evolutionary innovations in Antarctic brittle stars linked to glacial refugia
title_full_unstemmed	Evolutionary innovations in Antarctic brittle stars linked to glacial refugia
title_sort	evolutionary innovations in antarctic brittle stars linked to glacial refugia
publishDate	2022
url	https://doi.org/10.26181/18516281.v1 https://figshare.com/articles/journal_contribution/Evolutionary_innovations_in_Antarctic_brittle_stars_linked_to_glacial_refugia/18516281
geographic	Antarctic Prydz Bay Scotia Sea Southern Ocean The Antarctic
geographic_facet	Antarctic Prydz Bay Scotia Sea Southern Ocean The Antarctic
genre	Antarc* Antarctic Prydz Bay Scotia Sea Southern Ocean
genre_facet	Antarc* Antarctic Prydz Bay Scotia Sea Southern Ocean
op_relation	doi:10.26181/18516281.v1 https://figshare.com/articles/journal_contribution/Evolutionary_innovations_in_Antarctic_brittle_stars_linked_to_glacial_refugia/18516281
op_rights	CC BY 4.0
op_rightsnorm	CC-BY
op_doi	https://doi.org/10.26181/18516281.v1
_version_	1766132485338431488

Evolutionary innovations in Antarctic brittle stars linked to glacial refugia

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