Global Connectivity of Southern Ocean Ecosystems

Murphy, Eugene J.; Johnston, Nadine M.; Hofmann, Eileen E.; Phillips, Richard A.; Jackson, Jennifer A.; Constable, Andrew J.; Henley, Sian F.; Melbourne‐Thomas, Jessica; Trebilco, Rowan; Cavanagh, Rachel D.; Tarling, Geraint A.; Saunders, Ryan A.; Barnes, David K. A.; Costa, Daniel P.; Corney, Stuart; Fraser, Ceridwen I.; Höfer, Juan; Hughes, Kevin A.; Sands, Chester J.; Thorpe, Sally; Trathan, Philip N.; Xavier, José C.

doi:10.3389/fevo.2021.624451

Cited by 29 publications

(23 citation statements)

References 336 publications

(494 reference statements)

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“…Although ocean basin connectivity is rather high at the scale of our study (Jönsson & Watson, 2016), dispersal by marine currents and mesoscale processes are known to impact plankton community structure (Richter et al, 2020; Sommeria-Klein et al, 2021). For instance, the Antarctic Polar Front seems to be the main delimiter between regions 3 and 4, which coincides with the view that it imposes a strong physical barrier on passively drifting zooplankton (Murphy et al, 2021). Yet, recent evidence showed that many epipelagic plankton can cross Southern Ocean fronts thanks to the very dynamic meandering eddies (Murphy et al, 2021), which could explain the deviations of the region 4 boundaries from the Antarctic Polar Front.…”

Section: Discussionsupporting

confidence: 79%

“…For instance, the Antarctic Polar Front seems to be the main delimiter between regions 3 and 4, which coincides with the view that it imposes a strong physical barrier on passively drifting zooplankton (Murphy et al, 2021). Yet, recent evidence showed that many epipelagic plankton can cross Southern Ocean fronts thanks to the very dynamic meandering eddies (Murphy et al, 2021), which could explain the deviations of the region 4 boundaries from the Antarctic Polar Front. Therefore, the gradient in community trait expression separating regions 3 and 4 may also stem from the latitudinal gradient in temperature and biogeochemical conditions that select species and their traits based on physiological and metabolic constraints.…”

Section: Discussionsupporting

confidence: 79%

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Copepod functional traits and groups show divergent biogeographies in the global ocean

Benedetti

Wydler

Vogt

2022

Preprint

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Aim: To define global zooplankton functional groups (FGs) and to estimate their environmental niche and habitat distribution. We model the spatial patterns of copepod FGs habitat and identify regions sharing similar functional trait expression at the community level. Taxon: Marine planktonic Neocopepoda. Location: Global ocean. Methods: Factor analysis on mixed data and hierarchical clustering were used to identify copepod FGs based on five species-level functional traits. An ensemble of species distribution models was used to estimate the environmental niches of the modelled species, project the mean annual habitat suitability of the FGs, and to estimate the community weighted mean values of the traits studied. Ocean regions were defined based on their community-level mean trait expression using a principal component analysis and hierarchical clustering. Results: Eleven global copepod FGs were identified. They displayed contrasting latitudinal patterns in mean annual habitat suitability that could be explained by differences in environmental niche preferences: two FGs were associated with polar conditions, one followed the global temperature gradient, five were associated with tropical oligotrophic gyres, and the remaining three with boundary currents and counter currents. Four main regions of varying community weighted mean trait values emerged: the Southern Ocean, the northern and southern high latitudes, the tropical gyres, and the boundary currents and upwelling systems. Conclusions: We build on an exhaustive species trait dataset to put forward novel FGs that will improve the representation of zooplankton in global marine ecosystem models. Our results contribute to our understanding of the spatial patterns and drivers of marine plankton trait biogeography and will serve as a basis for studying the links between zooplankton biodiversity and ecosystem functioning and how they might evolve in the context of climate change.

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Section: Discussionsupporting

confidence: 79%

Section: Discussionsupporting

confidence: 79%

Copepod functional traits and groups show divergent biogeographies in the global ocean

Benedetti

Wydler

Vogt

2022

Preprint

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“…Managing greenhouse gas emissions is the primary way that these changes in the Earth System can be moderated (IPCC, 2018). Changes in polar regions impact people the world over, not just from the perspective of physics and tangible services from within the region (Meredith et al, 2019;Cavanagh et al, 2021) but also from more distant biological and human connections with the regions (Murphy et al, 2021;Roberts et al, 2021). Adaptation may attenuate impacts of climate change to socioecological systems in the near term (see Simpson et al, 2021) but cannot protect the fundamental nature of cold-and icedependent marine ecosystems, which are projected to experience rapid and irreversible loss over the next century under high (and possibly moderate) emission scenarios.…”

Section: Policy Relevant Climate Assessmentsmentioning

confidence: 99%

Climate Change Impacts on Polar Marine Ecosystems: Toward Robust Approaches for Managing Risks and Uncertainties

Ottersen¹,

Constable²,

Hollowed³

et al. 2022

Front. Clim.

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The Polar Regions chapter of the Intergovernmental Panel on Climate Change's Special Report on the Ocean and Cryosphere in a Changing Climate (SROCC) provides a comprehensive assessment of climate change impacts on polar marine ecosystems and associated consequences for humans. It also includes identification of confidence for major findings based on agreement across studies and weight of evidence. Sources of uncertainty, from the extent of available datasets, to resolution of projection models, to the complexity and understanding of underlying social-ecological linkages and dynamics, can influence confidence. Here we, marine ecosystem scientists all having experience as lead authors of IPCC reports, examine the evolution of confidence in observed and projected climate-linked changes in polar ecosystems since SROCC. Further synthesis of literature on polar marine ecosystems has been undertaken, especially within IPCC's Sixth Assessment Report (AR6) Working Group II; for the Southern Ocean also the Marine Ecosystem Assessment for the Southern Ocean (MEASO). These publications incorporate new scientific findings that address some of the knowledge gaps identified in SROCC. While knowledge gaps have been narrowed, we still find that polar region assessments reflect pronounced geographical skewness in knowledge regarding the responses of marine life to changing climate and associated literature. There is also an imbalance in scientific focus; especially research in Antarctica is dominated by physical oceanography and cryosphere science with highly fragmented approaches and only short-term funding to ecology. There are clear indications that the scientific community has made substantial progress in its ability to project ecosystem responses to future climate change through the development of coupled biophysical models of the region facilitated by increased computer power allowing for improved resolution in space and time. Lastly, we point forward—providing recommendations for future advances for IPCC assessments.

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“…In addition to the perturbations that have already impacted the Southern Ocean, major changes in its habitats and ecosystems are expected over the coming years in response to increased pressures from a range of global (see Morley et al, 2020) and local environmental drivers (see Grant et al, 2021), the majority of which have an anthropogenic component (Murphy et al, 2007b;Rogers et al, 2007;Clarke et al, 2012;Constable et al, 2014b;Gutt et al, 2015;Chown and Brooks, 2019;Kennicutt et al, 2019). Owing to the extensive physical, biogeochemical, and ecological connectivity between Southern Ocean ecosystems and the global ocean, future changes in the structure and functioning of these ecosystems will also have consequences throughout the Earth System (Henley et al, 2020;Murphy et al, 2021). To predict how Southern Ocean ecosystems will respond to global change and the implications for regional and Earth System functioning and decision-making, assessments of the sensitivity of Southern Ocean zooplankton to changes in these drivers are necessary (Constable et al, 2014a,b).…”

Section: Introductionmentioning

confidence: 99%

Status, Change, and Futures of Zooplankton in the Southern Ocean

et al. 2022

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In the Southern Ocean, several zooplankton taxonomic groups, euphausiids, copepods, salps and pteropods, are notable because of their biomass and abundance and their roles in maintaining food webs and ecosystem structure and function, including the provision of globally important ecosystem services. These groups are consumers of microbes, primary and secondary producers, and are prey for fishes, cephalopods, seabirds, and marine mammals. In providing the link between microbes, primary production, and higher trophic levels these taxa influence energy flows, biological production and biomass, biogeochemical cycles, carbon flux and food web interactions thereby modulating the structure and functioning of ecosystems. Additionally, Antarctic krill (Euphausia superba) and various fish species are harvested by international fisheries. Global and local drivers of change are expected to affect the dynamics of key zooplankton species, which may have potentially profound and wide-ranging implications for Southern Ocean ecosystems and the services they provide. Here we assess the current understanding of the dominant metazoan zooplankton within the Southern Ocean, including Antarctic krill and other key euphausiid, copepod, salp and pteropod species. We provide a systematic overview of observed and potential future responses of these taxa to a changing Southern Ocean and the functional relationships by which drivers may impact them. To support future ecosystem assessments and conservation and management strategies, we also identify priorities for Southern Ocean zooplankton research.

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Global Connectivity of Southern Ocean Ecosystems

Cited by 29 publications

References 336 publications

Copepod functional traits and groups show divergent biogeographies in the global ocean

Copepod functional traits and groups show divergent biogeographies in the global ocean

Climate Change Impacts on Polar Marine Ecosystems: Toward Robust Approaches for Managing Risks and Uncertainties

Status, Change, and Futures of Zooplankton in the Southern Ocean

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