Deep-sea ostracod faunal dynamics in a marginal sea: biotic response to oxygen variability and mid-Pleistocene global changes

Huang, Huai-Hsuan May; Yasuhara, Moriaki; Iwatani, Hokuto; Yamaguchi, Tatsuhiko; Yamada, Keigo; Mamo, Briony

doi:10.1017/pab.2018.37

Cited by 14 publications

(9 citation statements)

References 65 publications

(114 reference statements)

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“…In deeper waters (>900 m), the abundance and diversity of ostracods are lower than in the intermediate water depths. Nevertheless, statistical analyses also show that oxygen variability was important in controlling deeper-water faunal changes (Huang et al, 2018b;Yamaguchi et al, 2017). Other major taxonomic groups, such as the foraminifera and radiolarians, show consistent patterns in that the anoxic conditions resulted in their absence from the deep-sea fauna (Gallagher et al, 2018;Itaki et al, 2004).…”

Section: Biological Impacts Of Deoxygenation On Benthic Faunamentioning

confidence: 85%

System controls of coastal and open ocean oxygen depletion

Pitcher

Aguirre-Velarde

Breitburg

et al. 2021

Progress in Oceanography

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The epoch of the Anthropocene, a period during which human activity has been the dominant influence on climate and the environment, has witnessed a decline in oxygen concentrations and an expansion of oxygendepleted environments in both coastal and open ocean systems since the middle of the 20th century. This paper provides a review of system-specific drivers of low oxygen in a range of case studies representing marine systems in the open ocean, on continental shelves, in enclosed seas and in the coastal environment. Identification of similar and contrasting responses within and across system types and corresponding oxygen regimes is shown to be informative both in understanding and isolating key controlling processes and provides a sound basis for predicting change under anticipated future conditions. Case studies were selected to achieve a balance in system diversity and global coverage. Each case study describes system attributes, including the present-day oxygen environment and known trends in oxygen concentrations over time. Central to each case study is the identification of the physical and biogeochemical processes that determine oxygen concentrations through the tradeoff between ventilation and respiration. Spatial distributions of oxygen and time series of oxygen data provide the opportunity to identify trends in oxygen availability and have allowed various drivers of low oxygen to be distinguished through correlative and causative relationships. Deoxygenation results from a complex interplay of hydrographic and biogeochemical processes and the superposition of these processes, some additive and others subtractive, makes attribution to any particular driver challenging. System-specific models are therefore required to achieve a quantitative understanding of these processes and of the feedbacks between processes at varying scales.

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Section: Biological Impacts Of Deoxygenation On Benthic Faunamentioning

confidence: 85%

System controls of coastal and open ocean oxygen depletion

Pitcher

Aguirre-Velarde

Breitburg

et al. 2021

Progress in Oceanography

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“…However, after the MBE warm-adapted taxa went extinct regionally in the Arctic, with shrinking distributions to the south (DeNinno et al, 2015;Cronin et al, 2017). In the Sea of Japan, endemic cool water species replaced circumpolar species after the MBE, and many circumpolar species went extinct regionally (Ozawa and Kamiya, 2005;Cronin and Ikeya, 1987;Huang et al, 2018Huang et al, , 2019. In sum, when orbital cyclicity is consistent, microfossil species seem to show evidence of repeated community assembly that matches prevailing conditions, indicating that community assembly may be deterministic.…”

Section: Biotic Dynamics On Millennial Timescalesmentioning

confidence: 95%

“…Temperature likely controls biodiversity because fewer species can physiologically tolerate conditions in colder places than in warmer places on these ecological timescales (Currie et al, 2004;. Changes in the dominant mode of orbital cyclicity can, by contrast, permanently disturb marine ecosystems (Hayward et al, 2007;DeNinno et al, 2015;Cronin et al, 2017;Huang et al, 2018Huang et al, , 2019, such as during the transition from 41,000-to 100,000-year cycles in the Mid-Pleistocene Transition (MPT) and the Mid-Brunhes Event (MBE). For example, deep-sea benthic foraminifera show a prominent global extinction event during the MPT (Hayward et al, 2007).…”

Section: Biotic Dynamics On Millennial Timescalesmentioning

confidence: 99%

Time Machine Biology: Cross-Timescale Integration of Ecology, Evolution, and Oceanography

Yasuhara¹,

Huang²,

Hull³

et al. 2020

Oceanog

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“…The Sea of Japan is geographically isolated and has an abnormally high level of dissolved oxygen in its deeper parts; however, its bottom-water oxygen level has declined up to 8-10% in the past three decades (Elsner et al 2013;Huang et al 2019;Huang et al 2018). The abyssal depths of the Sea of Japan were formed in the Cenozoic as a caldera of the mainland (Malyutina and Brandt 2013).…”

Section: Sea Of Japanmentioning

confidence: 99%

Biogeographic Atlas of the Deep NW Pacific Fauna

Saeedi¹,

Brandt²

2020

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We would like to thank the captains and crews of RVs 'Akademik M.A. Lavrentyev' and 'Sonne' , student helpers, and anyone else who contributed to sample management and sorting the specimens. Special thanks to Mark Costello for his advice and Marianna Simões for her help in this book project. A very special thanks to James Reimer for editing and English proofreading of this chapter and to Rachel Downey for English proofreading most of the chapters of this book.

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Deep-sea ostracod faunal dynamics in a marginal sea: biotic response to oxygen variability and mid-Pleistocene global changes

Cited by 14 publications

References 65 publications

System controls of coastal and open ocean oxygen depletion

System controls of coastal and open ocean oxygen depletion

Time Machine Biology: Cross-Timescale Integration of Ecology, Evolution, and Oceanography

Biogeographic Atlas of the Deep NW Pacific Fauna

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