Distribution and Species Richness of Benthic Polychaeta and Sipuncula in the Northwestern Pacific
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Published:2023-04-14
Issue:4
Volume:15
Page:557
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ISSN:1424-2818
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Container-title:Diversity
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language:en
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Short-container-title:Diversity
Author:
Kohlenbach Katharina12, Knauber Henry12, Brandt Angelika12, Saeedi Hanieh2
Affiliation:
1. Department of Biological Sciences, Institute for Ecology, Diversity and Evolution, Goethe University Frankfurt, 60438 Frankfurt am Main, Germany 2. Senckenberg Research Institute and Natural History Museum, Department of Marine Zoology, 60325 Frankfurt am Main, Germany
Abstract
Polychaeta and Sipuncula are abundant inhabitants of benthic marine habitats and have been increasingly sampled in the Northwest Pacific (NWP). However, polychaete and sipunculan species richness, composition, and distribution patterns still require further investigation, despite previous studies due to increasing deep-sea data flow. Using occurrence records for Polychaeta and Sipuncula from the Ocean Biodiversity Information System (OBIS) and the Global Biodiversity Information Facility (GBIF), we analyzed sampling effort (the number of distribution records), alpha (the number of species per 700,000 km2 hexagon cells) and gamma (the number of species per 5° latitudinal band) species diversity, and estimated species richness along latitudinal and bathymetric gradients. The species richness estimations were also correlated with multiple environmental and topographic variables, including depth, temperature, dissolved oxygen, chlorophyll, primary production, phytoplankton, current velocity, light, iron, nitrate, phosphate, silicate, and salinity. The dataset included over 30,000 distribution records belonging to polychaete (31,114 records, 98%) and sipunculan (690 records, 2%) species. Half of the distribution records were reported at a species level. The area around the island of Hainan and South Korea showed the highest alpha species richness (the number of species per 700,000 km2 hexagon cell), yet the estimated species richness (ES50) indicated that there might be many unknown, unsampled, or non-digitized species throughout the whole NWP. Correspondingly, most distribution records (sampling effort) and gamma species richness were found between latitudes 20 and 40° and decreased towards higher latitudes. Sipuncula were reported relatively more frequently from the deep sea than Polychaeta (62.8% vs. 12%). Overall, the number of species and records decreased with increasing depth, with a peak at about 5000 m. The alpha species richness had the strongest positive correlations with temperature, chlorophyll, primary production, and phytoplankton concentration. Here, we provide an overview of the species richness and distribution of Polychaeta in comparison with Sipuncula in the NWP, in both shallow and deep environments. This study demonstrates where further sampling efforts are needed to fill our knowledge gaps on annelids’ distribution and diversity along the NWP. This could improve the analyses of the distribution and diversity of annelids to better understand the current environmental drivers of biodiversity, as well as predicting potential future drivers. The outcome of the environmental correlation provides thus valuable knowledge for predicting the future impacts of global warming on potential distribution shifts of annelids into new environments such as the Arctic Sea, possibly resulting in biological invasions.
Funder
Federal Ministry of Education and Research
Subject
Nature and Landscape Conservation,Agricultural and Biological Sciences (miscellaneous),Ecological Modeling,Ecology
Reference114 articles.
1. Birstein, J.A. (1963). Deep Water Isopods (Crustacea, Isopoda) of the North-Western Part of the Pacific Ocean, Indian National Scientific Documentation Centre. 2. Brandt, A. (2021, November 04). RV Sonne SO-250 Cruise Report/Fahrtbericht. SO-250 KuramBio II (Kuril Kamchatka Biodiversity Studies) Tomakomai—Yokohama, Japan, 16.08.–26.09.2016. Available online: http://tristan.cordier.free.fr/files/SO250_KuramBio%20II_20161014.pdf. 3. Biodiversity and biogeography of the abyssal and hadal Kuril-Kamchatka trench and adjacent NW Pacific deep-sea regions;Brandt;Prog. Oceanogr.,2020 4. Brandt, A., and Malyutina, M. (2021, November 04). The German-Russian Deep-Sea Expedition KuramBio (Kuril Kamchatka Biodiversity Studies) to the Kuril Kamchatka Trench and Abyssal Plain on Board of the R/V Sonne, 223rd Expedition (21 July–7 September 2012). Available online: https://www.researchgate.net/publication/298305628_The_German-Russian_deep-sea_expedition_KuramBio_Kurile_Kamchatka_Biodiversity_Study_to_the_Kurile_Kamchatka_Trench_and_abyssal_plain_on_board_of_the_RV_Sonne_223rd_Expedition_July_21th_-_September_7th. 5. Brandt, A., Malyutina, M., Majorova, N., Bashmanov, A., Brenke, N., Chizhova, T., Elsner, N., Golovan, O., Göcke, C., and Kaplunenko, D. (2021, November 04). The Russian-German Deep-Sea Expedition (SoJaBio) to the Sea of Japan Onboard of the R/V Akademik Lavrentyev. 51st Cruise, 11 August–5 September 2010, The Cruise Report. Available online: https://www.researchgate.net/publication/298305568_The_Russian-German_deep-sea_expedition_SoJaBio_to_the_Sea_of_Japan_onboard_of_the_RV_Akademik_Lavrentyev_51st_Cruise_August_11th_-_September_5th_2010_The_Cruise_Report.
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