A Global Biogeographic Classification of the Mesopelagic Zone

Tracey Sutton; Malcolm R. Clark; Daniel C. Dunn; Patrick N. Halpin; Alex D. Rogers; John Guinotte; Steven J. Bograd; Martin V. Angel; Jose Angel A. Perez; Karen Wishner; Richard L. Haedrich; Dhugal Lindsay; Jeffrey C. Drazen; Alexander Vereshchaka; Uwe Piatkowski; Telmo Morato; Katarzyna Blachowiak-Samolyk; Bruce H. Robison; Kristina Gjerde; Annelies Pierrot-Bults; Patricio Bernal; Gabriel Reygondeau; Mikko Heino

doi:10.1016/j.dsr.2017.05.006

A Global Biogeographic Classification of the Mesopelagic Zone

Tracey Sutton
, Malcolm R. Clark
, Daniel C. Dunn
, Patrick N. Halpin
, Alex D. Rogers
, John Guinotte
, Steven J. Bograd
, Martin V. Angel
, Jose Angel A. Perez
, Karen Wishner
, Richard L. Haedrich
, Dhugal Lindsay
, Jeffrey C. Drazen
, Alexander Vereshchaka
, Uwe Piatkowski
, Telmo Morato
, Katarzyna Blachowiak-Samolyk
, Bruce H. Robison
, Kristina Gjerde
, Annelies Pierrot-Bults

Patricio Bernal, Gabriel Reygondeau, Mikko Heino

Department of Marine and Environmental Sciences

Research output: Contribution to journal › Article › peer-review

Abstract

We have developed a global biogeographic classification of the mesopelagic zone to reflect the regional scales over which the ocean interior varies in terms of biodiversity and function. An integrated approach was necessary, as global gaps in information and variable sampling methods preclude strictly statistical approaches. A panel combining expertise in oceanography, geospatial mapping, and deep-sea biology convened to collate expert opinion on the distributional patterns of pelagic fauna relative to environmental proxies (temperature, salinity, and dissolved oxygen at mesopelagic depths). An iterative Delphi Method integrating additional biological and physical data was used to classify biogeographic ecoregions and to identify the location of ecoregion boundaries or inter-regions gradients. We define 33 global mesopelagic ecoregions. Of these, 20 are oceanic while 13 are ‘distant neritic.’ While each is driven by a complex of controlling factors, the putative primary driver of each ecoregion was identified. While work remains to be done to produce a comprehensive and robust mesopelagic biogeography (i.e., reflecting temporal variation), we believe that the classification set forth in this study will prove to be a useful and timely input to policy planning and management for conservation of deep-pelagic marine resources. In particular, it gives an indication of the spatial scale at which faunal communities are expected to be broadly similar in composition, and hence can inform application of ecosystem-based management approaches, marine spatial planning and the distribution and spacing of networks of representative protected areas.

Original language	American English
Pages (from-to)	85-102
Number of pages	18
Journal	Deep Sea Research Part I: Oceanographic Research Papers
Volume	126
DOIs	https://doi.org/10.1016/j.dsr.2017.05.006
State	Published - Aug 1 2017

Bibliographical note

Publisher Copyright:
© 2017 The Authors

Funding

Funders	Funder number
Natural Environment Research Council	NE/F005504/1

ASJC Scopus Subject Areas

Aquatic Science
Oceanography

Keywords

Biodiversity
Biogeographical ecoregions
Gyres
Oceanic biomes
Oxygen minimum zones
Upwelling

Disciplines

Marine Biology
Oceanography and Atmospheric Sciences and Meteorology

Access to Document

10.1016/j.dsr.2017.05.006License: CC BY

A Global Biogeographic Classification of the Mesopelagic ZoneFinal published version, 1.15 MBLicense: CC BY

Cite this

Sutton, T., Clark, M. R., Dunn, D. C., Halpin, P. N., Rogers, A. D., Guinotte, J., Bograd, S. J., Angel, M. V., Perez, J. A. A., Wishner, K., Haedrich, R. L., Lindsay, D., Drazen, J. C., Vereshchaka, A., Piatkowski, U., Morato, T., Blachowiak-Samolyk, K., Robison, B. H., Gjerde, K., ... Heino, M. (2017). A Global Biogeographic Classification of the Mesopelagic Zone. Deep Sea Research Part I: Oceanographic Research Papers, 126, 85-102. https://doi.org/10.1016/j.dsr.2017.05.006

Sutton, T, Clark, MR, Dunn, DC, Halpin, PN, Rogers, AD, Guinotte, J, Bograd, SJ, Angel, MV, Perez, JAA, Wishner, K, Haedrich, RL, Lindsay, D, Drazen, JC, Vereshchaka, A, Piatkowski, U, Morato, T, Blachowiak-Samolyk, K, Robison, BH, Gjerde, K, Pierrot-Bults, A, Bernal, P, Reygondeau, G & Heino, M 2017, 'A Global Biogeographic Classification of the Mesopelagic Zone', Deep Sea Research Part I: Oceanographic Research Papers, vol. 126, pp. 85-102. https://doi.org/10.1016/j.dsr.2017.05.006

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title = "A Global Biogeographic Classification of the Mesopelagic Zone",

abstract = " We have developed a global biogeographic classification of the mesopelagic zone to reflect the regional scales over which the ocean interior varies in terms of biodiversity and function. An integrated approach was necessary, as global gaps in information and variable sampling methods preclude strictly statistical approaches. A panel combining expertise in oceanography, geospatial mapping, and deep-sea biology convened to collate expert opinion on the distributional patterns of pelagic fauna relative to environmental proxies (temperature, salinity, and dissolved oxygen at mesopelagic depths). An iterative Delphi Method integrating additional biological and physical data was used to classify biogeographic ecoregions and to identify the location of ecoregion boundaries or inter-regions gradients. We define 33 global mesopelagic ecoregions. Of these, 20 are oceanic while 13 are {\textquoteleft}distant neritic.{\textquoteright} While each is driven by a complex of controlling factors, the putative primary driver of each ecoregion was identified. While work remains to be done to produce a comprehensive and robust mesopelagic biogeography (i.e., reflecting temporal variation), we believe that the classification set forth in this study will prove to be a useful and timely input to policy planning and management for conservation of deep-pelagic marine resources. In particular, it gives an indication of the spatial scale at which faunal communities are expected to be broadly similar in composition, and hence can inform application of ecosystem-based management approaches, marine spatial planning and the distribution and spacing of networks of representative protected areas.",

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author = "Tracey Sutton and Clark, \{Malcolm R.\} and Dunn, \{Daniel C.\} and Halpin, \{Patrick N.\} and Rogers, \{Alex D.\} and John Guinotte and Bograd, \{Steven J.\} and Angel, \{Martin V.\} and Perez, \{Jose Angel A.\} and Karen Wishner and Haedrich, \{Richard L.\} and Dhugal Lindsay and Drazen, \{Jeffrey C.\} and Alexander Vereshchaka and Uwe Piatkowski and Telmo Morato and Katarzyna Blachowiak-Samolyk and Robison, \{Bruce H.\} and Kristina Gjerde and Annelies Pierrot-Bults and Patricio Bernal and Gabriel Reygondeau and Mikko Heino",

note = "Publisher Copyright: {\textcopyright} 2017 The Authors",

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month = aug,

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doi = "10.1016/j.dsr.2017.05.006",

language = "American English",

volume = "126",

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AU - Sutton, Tracey

AU - Clark, Malcolm R.

AU - Dunn, Daniel C.

AU - Halpin, Patrick N.

AU - Rogers, Alex D.

AU - Guinotte, John

AU - Bograd, Steven J.

AU - Angel, Martin V.

AU - Perez, Jose Angel A.

AU - Wishner, Karen

AU - Haedrich, Richard L.

AU - Lindsay, Dhugal

AU - Drazen, Jeffrey C.

AU - Vereshchaka, Alexander

AU - Piatkowski, Uwe

AU - Morato, Telmo

AU - Blachowiak-Samolyk, Katarzyna

AU - Robison, Bruce H.

AU - Gjerde, Kristina

AU - Pierrot-Bults, Annelies

AU - Bernal, Patricio

AU - Reygondeau, Gabriel

AU - Heino, Mikko

PY - 2017/8/1

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N2 - We have developed a global biogeographic classification of the mesopelagic zone to reflect the regional scales over which the ocean interior varies in terms of biodiversity and function. An integrated approach was necessary, as global gaps in information and variable sampling methods preclude strictly statistical approaches. A panel combining expertise in oceanography, geospatial mapping, and deep-sea biology convened to collate expert opinion on the distributional patterns of pelagic fauna relative to environmental proxies (temperature, salinity, and dissolved oxygen at mesopelagic depths). An iterative Delphi Method integrating additional biological and physical data was used to classify biogeographic ecoregions and to identify the location of ecoregion boundaries or inter-regions gradients. We define 33 global mesopelagic ecoregions. Of these, 20 are oceanic while 13 are ‘distant neritic.’ While each is driven by a complex of controlling factors, the putative primary driver of each ecoregion was identified. While work remains to be done to produce a comprehensive and robust mesopelagic biogeography (i.e., reflecting temporal variation), we believe that the classification set forth in this study will prove to be a useful and timely input to policy planning and management for conservation of deep-pelagic marine resources. In particular, it gives an indication of the spatial scale at which faunal communities are expected to be broadly similar in composition, and hence can inform application of ecosystem-based management approaches, marine spatial planning and the distribution and spacing of networks of representative protected areas.

AB - We have developed a global biogeographic classification of the mesopelagic zone to reflect the regional scales over which the ocean interior varies in terms of biodiversity and function. An integrated approach was necessary, as global gaps in information and variable sampling methods preclude strictly statistical approaches. A panel combining expertise in oceanography, geospatial mapping, and deep-sea biology convened to collate expert opinion on the distributional patterns of pelagic fauna relative to environmental proxies (temperature, salinity, and dissolved oxygen at mesopelagic depths). An iterative Delphi Method integrating additional biological and physical data was used to classify biogeographic ecoregions and to identify the location of ecoregion boundaries or inter-regions gradients. We define 33 global mesopelagic ecoregions. Of these, 20 are oceanic while 13 are ‘distant neritic.’ While each is driven by a complex of controlling factors, the putative primary driver of each ecoregion was identified. While work remains to be done to produce a comprehensive and robust mesopelagic biogeography (i.e., reflecting temporal variation), we believe that the classification set forth in this study will prove to be a useful and timely input to policy planning and management for conservation of deep-pelagic marine resources. In particular, it gives an indication of the spatial scale at which faunal communities are expected to be broadly similar in composition, and hence can inform application of ecosystem-based management approaches, marine spatial planning and the distribution and spacing of networks of representative protected areas.

KW - Biodiversity

KW - Biogeographical ecoregions

KW - Gyres

KW - Oceanic biomes

KW - Oxygen minimum zones

KW - Upwelling

UR - https://nsuworks.nova.edu/occ_facarticles/813

UR - https://www.scopus.com/pages/publications/85020421877

UR - https://www.scopus.com/pages/publications/85020421877#tab=citedBy

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DO - 10.1016/j.dsr.2017.05.006

M3 - Article

SN - 0967-0637

VL - 126

SP - 85

EP - 102

JO - Deep Sea Research Part I: Oceanographic Research Papers

JF - Deep Sea Research Part I: Oceanographic Research Papers

ER -

A Global Biogeographic Classification of the Mesopelagic Zone

Abstract

Bibliographical note

Funding

ASJC Scopus Subject Areas

Keywords

Disciplines

Access to Document

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