Coupling large-spatial scale larval dispersal modelling with barcoding to refine the amphi-Atlantic connectivity hypothesis in deep-sea seep mussels

Portanier, Elodie; Nicolle, Amandine; Rath, Willi; Monnet, Lorraine; Goff, Grégoire Le; Port, Anne-Sophie Le; Daguin‐Thiébaut, Claire; Morrison, Cheryl L.; Ravara, Ascensão; Betters, Melissa; Young, Craig M.; Dover, Cindy Lee Van; Biastoch, Arne; Thiébaut, Éric; Jollivet, Didier

doi:10.3389/fmars.2023.1122124

Cited by 3 publications

(1 citation statement)

References 147 publications

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“…Genetic connectivity is essential in maintaining diversity and promoting the evolution of marine organisms, and depends on factors such as dispersal ability, reproductive traits, seafloor topology, and environmental conditions (Blanchard & Gollner, 2022;Brunner et al, 2023;De Wit et al, 2023;Faria et al, 2021;Ingels et al, 2023;Mouchi et al, 2023;Pereira et al, 2023;Plouviez et al, 2013Plouviez et al, , 2019Portanier et al, 2023;Virtanen et al, 2020;Yahagi et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Highly structured populations of copepods at risk to deep‐sea mining: Integration of genomic data with demogenetic and biophysical modelling

Diaz‐Recio Lorenzo,

Tran Lu Y,

Brunner

et al. 2024

Molecular Ecology

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Copepoda is the most abundant taxon in deep‐sea hydrothermal vents, where hard substrate is available. Despite the increasing interest in seafloor massive sulphides exploitation, there have been no population genomic studies conducted on vent meiofauna, which are known to contribute over 50% to metazoan biodiversity at vents. To bridge this knowledge gap, restriction‐site‐associated DNA sequencing, specifically 2b‐RADseq, was used to retrieve thousands of genome‐wide single‐nucleotide polymorphisms (SNPs) from abundant populations of the vent‐obligate copepod Stygiopontius lauensis from the Lau Basin. SNPs were used to investigate population structure, demographic histories and genotype–environment associations at a basin scale. Genetic analyses also helped to evaluate the suitability of tailored larval dispersal models and the parameterization of life‐history traits that better fit the population patterns observed in the genomic dataset for the target organism. Highly structured populations were observed on both spatial and temporal scales, with divergence of populations between the north, mid, and south of the basin estimated to have occurred after the creation of the major transform fault dividing the Australian and the Niuafo'ou tectonic plate (350 kya), with relatively recent secondary contact events (<20 kya). Larval dispersal models were able to predict the high levels of structure and the highly asymmetric northward low‐level gene flow observed in the genomic data. These results differ from most studies conducted on megafauna in the region, elucidating the need to incorporate smaller size when considering site prospecting for deep‐sea exploitation of seafloor massive sulphides, and the creation of area‐based management tools to protect areas at risk of local extinction, should mining occur.

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Section: Introductionmentioning

confidence: 99%

Highly structured populations of copepods at risk to deep‐sea mining: Integration of genomic data with demogenetic and biophysical modelling

Diaz‐Recio Lorenzo,

Tran Lu Y,

Brunner

et al. 2024

Molecular Ecology

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Methane seeps on the U.S. Atlantic margin: An updated inventory and interpretative framework

Ruppel,

Skarke,

Miller

et al. 2024

Marine Geology

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Genetic connectivity and isotopic niches of alvinocaridid shrimps from chemosynthetic habitats in Aotearoa/New Zealand, with a new Alvinocaris species

Methou,

Ogawa,

Nomaki

et al. 2024

Mar. Ecol. Prog. Ser.

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Chemosynthetic ecosystems off Aotearoa/New Zealand comprise both hydrothermal vents on the Kermadec Arc and methane seeps on the Hikurangi Margin which host rich communities of specialized fauna including 4 alvinocaridid shrimp species. The systematic positions of these New Zealand alvinocaridid shrimps have not been studied using genetic tools and little is known about their habitat use and feeding habits. Here, we re-evaluate the taxonomy of alvinocaridid shrimps from New Zealand using genetic barcoding and characterize their connectivity and isotopic niches across 8 localities. We describe a new species, Alvinocaris webberi sp. nov., previously confused with A. longirostris. We also show that A. alexander and A. chelys are junior synonyms of A. dissimilis, revealing a high genetic connectivity across hydrothermal vents and methane seeps from Japan to New Zealand, greatly extending its range. Finally, we find clear niche separation in co-occurring alvinocaridid shrimps, suggesting different diets and/or habitat use. Nevertheless, all species rely on chemosynthetic resources, regardless of the habitat depth, which ranges from 380 to 1650 m.

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Coupling large-spatial scale larval dispersal modelling with barcoding to refine the amphi-Atlantic connectivity hypothesis in deep-sea seep mussels

Cited by 3 publications

References 147 publications

Highly structured populations of copepods at risk to deep‐sea mining: Integration of genomic data with demogenetic and biophysical modelling

Highly structured populations of copepods at risk to deep‐sea mining: Integration of genomic data with demogenetic and biophysical modelling

Methane seeps on the U.S. Atlantic margin: An updated inventory and interpretative framework

Genetic connectivity and isotopic niches of alvinocaridid shrimps from chemosynthetic habitats in Aotearoa/New Zealand, with a new Alvinocaris species

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