Biogeography and connectivity across habitat types and geographical scales in Pacific abyssal scavenging amphipods
Biogeography and connectivity across habitat types and geographical scales in Pacific abyssal scavenging amphipods
Recently, there has been a resurgent interest in the exploration of deep-sea mineral deposits, particularly polymetallic nodules in the Clarion-Clipperton Zone (CCZ), central Pacific. Accurate environmental impact assessment is critical to the effective management of a new industry and depends on a sound understanding of species taxonomy, biogeography, and connectivity across a range of scales. Connectivity is a particularly important parameter in determining ecosystem resilience, as it helps to define the ability of a system to recover post-impact. Scavenging amphipods in the superfamilies Alicelloidea Lowry and De Broyer, 2008 and Lysianassoidea Dana, 1849 contribute to a unique and abundant scavenging community in abyssal ecosystems. They are relatively easy to sample and in recent years have become the target of several molecular and taxonomic studies, but are poorly studied in the CCZ. Here, a molecular approach is used to identify and delimit species, and to investigate evolutionary relationships of scavenging amphipods from both abyssal plain and deep (>3000 m) seamount habitats in three APEIs (Areas of Particular Environmental Interest, i.e., designated conservation areas) in the western CCZ. A total of 17 different morphospecies of scavenging amphipods were identified, which include at least 30 genetic species delimited by a fragment of the cytochrome c oxidase subunit I (COI) barcode gene. The scavenging communities sampled in the western CCZ included the most common species (Abyssorchomene gerulicorbis (Shulenberger and Barnard, 1976), A. chevreuxi (Stebbing, 1906), Paralicella caperesca Shulenberger and Barnard, 1976, and P. tenuipes Chevreux, 1908) reported for other ocean basins. Only four morphospecies, representing five genetic species, were shared between APEIs 1, 4, and 7. The two abyssal plain sites at APEIs 4 and 7 were dominated by two and three of the most common scavenging species, respectively, while the APEI 1 seamount site was dominated by two species potentially new to science that appeared to be endemic to the site. The presence of common species in all sites and high genetic diversity, yet little geographic structuring, indicate connectivity over evolutionary time scales between the areas, which span about 1500 km. Similar to recent studies, the differences in amphipod assemblages found between the seamount and abyssal sites suggest that ecological conditions on seamounts generate distinct community compositions.
biodiversity, Clarion-Clipperton Zone, connectivity, deep-sea mining, scavenging amphipods, seamount
Bribiesca-Contreras, Guadalupe
feb06280-2c3f-44de-a356-19e8de31e533
Dahlgren, Thomas G.
35e04ba6-303d-44d0-ae60-f434977dc0ff
Horton, Tammy
c4b41665-f0bc-4f0f-a7af-b2b9afc02e34
Drazen, Jeffrey C.
554a715d-e0da-4732-9503-8de5b00da6af
Drennan, Regan
f810f4e7-de45-4174-9fbc-d3f8062c9c41
Jones, Daniel O.B.
44fc07b3-5fb7-4bf5-9cec-78c78022613a
Leitner, Astrid B.
e634869b-adbb-42da-a2cb-811de2144377
McQuaid, Kirsty A.
b035a507-db1a-44d8-a102-bbc87e0741e1
Smith, Craig R.
a99f491d-b292-47c1-9f16-3cde8f85bc0d
Taboada, Sergio
75d9eb42-4801-4232-ab77-bc686f22e0e1
Wiklund, Helena
7c228af0-33a8-471f-b0f8-bc1e558cf8ed
Glover, Adrian G.
91192a3a-fc25-4c1f-b062-2e4da183272e
27 July 2021
Bribiesca-Contreras, Guadalupe
feb06280-2c3f-44de-a356-19e8de31e533
Dahlgren, Thomas G.
35e04ba6-303d-44d0-ae60-f434977dc0ff
Horton, Tammy
c4b41665-f0bc-4f0f-a7af-b2b9afc02e34
Drazen, Jeffrey C.
554a715d-e0da-4732-9503-8de5b00da6af
Drennan, Regan
f810f4e7-de45-4174-9fbc-d3f8062c9c41
Jones, Daniel O.B.
44fc07b3-5fb7-4bf5-9cec-78c78022613a
Leitner, Astrid B.
e634869b-adbb-42da-a2cb-811de2144377
McQuaid, Kirsty A.
b035a507-db1a-44d8-a102-bbc87e0741e1
Smith, Craig R.
a99f491d-b292-47c1-9f16-3cde8f85bc0d
Taboada, Sergio
75d9eb42-4801-4232-ab77-bc686f22e0e1
Wiklund, Helena
7c228af0-33a8-471f-b0f8-bc1e558cf8ed
Glover, Adrian G.
91192a3a-fc25-4c1f-b062-2e4da183272e
Bribiesca-Contreras, Guadalupe, Dahlgren, Thomas G., Horton, Tammy, Drazen, Jeffrey C., Drennan, Regan, Jones, Daniel O.B., Leitner, Astrid B., McQuaid, Kirsty A., Smith, Craig R., Taboada, Sergio, Wiklund, Helena and Glover, Adrian G.
(2021)
Biogeography and connectivity across habitat types and geographical scales in Pacific abyssal scavenging amphipods.
Frontiers in Marine Science, 8, [705237].
(doi:10.3389/fmars.2021.705237).
Abstract
Recently, there has been a resurgent interest in the exploration of deep-sea mineral deposits, particularly polymetallic nodules in the Clarion-Clipperton Zone (CCZ), central Pacific. Accurate environmental impact assessment is critical to the effective management of a new industry and depends on a sound understanding of species taxonomy, biogeography, and connectivity across a range of scales. Connectivity is a particularly important parameter in determining ecosystem resilience, as it helps to define the ability of a system to recover post-impact. Scavenging amphipods in the superfamilies Alicelloidea Lowry and De Broyer, 2008 and Lysianassoidea Dana, 1849 contribute to a unique and abundant scavenging community in abyssal ecosystems. They are relatively easy to sample and in recent years have become the target of several molecular and taxonomic studies, but are poorly studied in the CCZ. Here, a molecular approach is used to identify and delimit species, and to investigate evolutionary relationships of scavenging amphipods from both abyssal plain and deep (>3000 m) seamount habitats in three APEIs (Areas of Particular Environmental Interest, i.e., designated conservation areas) in the western CCZ. A total of 17 different morphospecies of scavenging amphipods were identified, which include at least 30 genetic species delimited by a fragment of the cytochrome c oxidase subunit I (COI) barcode gene. The scavenging communities sampled in the western CCZ included the most common species (Abyssorchomene gerulicorbis (Shulenberger and Barnard, 1976), A. chevreuxi (Stebbing, 1906), Paralicella caperesca Shulenberger and Barnard, 1976, and P. tenuipes Chevreux, 1908) reported for other ocean basins. Only four morphospecies, representing five genetic species, were shared between APEIs 1, 4, and 7. The two abyssal plain sites at APEIs 4 and 7 were dominated by two and three of the most common scavenging species, respectively, while the APEI 1 seamount site was dominated by two species potentially new to science that appeared to be endemic to the site. The presence of common species in all sites and high genetic diversity, yet little geographic structuring, indicate connectivity over evolutionary time scales between the areas, which span about 1500 km. Similar to recent studies, the differences in amphipod assemblages found between the seamount and abyssal sites suggest that ecological conditions on seamounts generate distinct community compositions.
Text
fmars-08-705237
- Version of Record
More information
Published date: 27 July 2021
Additional Information:
Funding Information:
We thank the masters, crew and technical support staff on the R/V Kilo Moana and ROV Luukai for their expertise in collecting samples. We thank the primary funder, the Gordon and Betty Moore Foundation grant no. 5596 and NOAA Office of Ocean Exploration (grant #NA17OAR0110209). We also acknowledge funding from UK Seabed Resources, the UK Natural Environment Research Council grant numbers NE/T003537/1 and NE/T002913/1, and The Norwegian Research Council (JPIO Mining Impact 2). We also acknowledge Dr. Lauren Hughes and Muriel Rabone (NHM) for curatorial support, and Elena Luigli (NHM) and Claire Griffin (NHM) for lab support. This is a contribution from SOEST, University of Hawai?i at M?noa.
Funding Information:
We thank the masters, crew and technical support staff on the R/V Kilo Moana and ROV Luukai for their expertise in collecting samples. We thank the primary funder, the Gordon and Betty Moore Foundation grant no. 5596 and NOAA Office of Ocean Exploration (grant #NA17OAR0110209). We also acknowledge funding from UK Seabed Resources, the UK Natural Environment Research Council grant numbers NE/T003537/1 and NE/T002913/1, and The Norwegian Research Council (JPIO Mining Impact 2). We also acknowledge Dr. Lauren Hughes and Muriel Rabone (NHM) for curatorial support, and Elena Luigli (NHM) and Claire Griffin (NHM) for lab support. This is a contribution from SOEST, University of Hawai‘i at Ma¯noa.
Publisher Copyright:
© Copyright © 2021 Bribiesca-Contreras, Dahlgren, Horton, Drazen, Drennan, Jones, Leitner, McQuaid, Smith, Taboada, Wiklund and Glover.
Copyright:
Copyright 2021 Elsevier B.V., All rights reserved.
Keywords:
biodiversity, Clarion-Clipperton Zone, connectivity, deep-sea mining, scavenging amphipods, seamount
Identifiers
Local EPrints ID: 452139
URI: http://eprints.soton.ac.uk/id/eprint/452139
ISSN: 2296-7745
PURE UUID: 928a8a44-7f76-452a-8329-a9675c536b6a
Catalogue record
Date deposited: 25 Nov 2021 17:58
Last modified: 18 Mar 2024 03:53
Export record
Altmetrics
Contributors
Author:
Guadalupe Bribiesca-Contreras
Author:
Thomas G. Dahlgren
Author:
Tammy Horton
Author:
Jeffrey C. Drazen
Author:
Daniel O.B. Jones
Author:
Astrid B. Leitner
Author:
Kirsty A. McQuaid
Author:
Craig R. Smith
Author:
Sergio Taboada
Author:
Helena Wiklund
Author:
Adrian G. Glover
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics