Biological and environmental rhythms in (dark) deep-sea hydrothermal ecosystems

Cuvelier, Daphné; Legendre, Pierre; Laës-Huon, Agathe; Sarradin, Pierre‐Marie; Sarrazin, Jozée

doi:10.5194/bg-14-2955-2017

Cited by 29 publications

(27 citation statements)

References 53 publications

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“…Surface tides supply much of the mechanical energy required to generate internal tides, as they move stratified water up and down mid-ocean ridges and seamounts, thus producing waves in the ocean's interior. Internal waves, produced at a tidal frequency, are primary drivers of deep-sea mixing processes (Vic et al, 2019) that modulate the behavior of deep-sea organisms Cuvelier et al, 2017).…”

Section: The Deep-sea Ecosystems: a Symphony Of Cycles And Rhythms Environmental Cycles And Episodic Signalsmentioning

confidence: 99%

Integrating Diel Vertical Migrations of Bioluminescent Deep Scattering Layers Into Monitoring Programs

et al. 2021

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The deep sea (i.e., >200 m depth) is a highly dynamic environment where benthic ecosystems are functionally and ecologically connected with the overlying water column and the surface. In the aphotic deep sea, organisms rely on external signals to synchronize their biological clocks. Apart from responding to cyclic hydrodynamic patterns and periodic fluctuations of variables such as temperature, salinity, phytopigments, and oxygen concentration, the arrival of migrators at depth on a 24-h basis (described as Diel Vertical Migrations; DVMs), and from well-lit surface and shallower waters, could represent a major response to a solar-based synchronization between the photic and aphotic realms. In addition to triggering the rhythmic behavioral responses of benthic species, DVMs supply food to deep seafloor communities through the active downward transport of carbon and nutrients. Bioluminescent species of the migrating deep scattering layers play a not yet quantified (but likely important) role in the benthopelagic coupling, raising the need to integrate the efficient detection and quantification of bioluminescence into large-scale monitoring programs. Here, we provide evidence in support of the benefits for quantifying and continuously monitoring bioluminescence in the deep sea. In particular, we recommend the integration of bioluminescence studies into long-term monitoring programs facilitated by deep-sea neutrino telescopes, which offer photon counting capability. Their Photo-Multiplier Tubes and other advanced optical sensors installed in neutrino telescope infrastructures can boost the study of bioluminescent DVMs in concert with acoustic backscatter and video imagery from ultra-low-light cameras. Such integration will enhance our ability to monitor proxies for the mass and energy transfer from the upper ocean into the deep-sea Benthic Boundary Layer (BBL), a key feature of the ocean biological pump and crucial for monitoring the effects of climate-change. In addition, it will allow for investigating the role of deep scattering DVMs in the behavioral responses, abundance and structure of deep-sea benthic communities. The proposed approach may represent a new frontier for the study and discovery of new, taxon-specific bioluminescence capabilities. It will thus help to expand our knowledge of poorly described deep-sea biodiversity inventories and further elucidate the connectivity between pelagic and benthic compartments in the deep-sea.

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Section: The Deep-sea Ecosystems: a Symphony Of Cycles And Rhythms Environmental Cycles And Episodic Signalsmentioning

confidence: 99%

Integrating Diel Vertical Migrations of Bioluminescent Deep Scattering Layers Into Monitoring Programs

et al. 2021

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“…Such platforms are open windows of the continental margin, from coastal areas to abyssal plains, to remotely study in real time life activity and its responses to environmental changes . For example, on Earth, compacted versions of these observatories have been successfully deployed in the deep sea close to hydrothermal vents, with cable-to-shore or in a stand-alone (i.e., moored) fashion, enabling a remote and long-lasting monitoring of biological components and en-vironmental variables at hydrothermal vent sites (e.g., Colaço et al, 2011;Cuvelier et al, 2017). On Enceladus, these types of platforms may provide long-lasting Eulerian measurements of the exo-oceanic proximal water mass characteristics, alerting scientists in the case of detection of any relevant transient object.…”

Section: Observatoriesmentioning

confidence: 99%

Exo-Ocean Exploration with Deep-Sea Sensor and Platform Technologies

et al. 2020

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“…For example, trace metal sensors could be integrated with existing ocean observing assets, such as the long-term time sampling program in Saanich Inlet (BC, Canada), a low-oxygen fjord, with monthly monitoring measurements, and a VENUS cabled observatory (Ocean Networks Canada). The implementation of such systems should be easily accomplished as it has already been performed on one of the deepest parts of the Ocean Networks Canada (Grotto Hydrothermal Vent, Endeavour Field, 2186 m) from 2011 and 2013 to collect iron concentrations (CHEMINI in situ analyzer) and to link them to the chemosynthetic environment and its related fauna (Cuvelier et al, 2014(Cuvelier et al, , 2017.…”

Section: Time Seriesmentioning

confidence: 99%

Developing Autonomous Observing Systems for Micronutrient Trace Metals

et al. 2019

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Grand et al. Autonomous Micronutrient Metal Observing Systems technologies to in situ applications; and (4) develop a community-led standardized protocol to demonstrate the endurance and comparability of in situ sensor data with established techniques. Such a vision will be best served through ongoing collaborations between trace metal geochemists, analytical chemists, the engineering community, and commercial partners, which will accelerate the delivery of new technologies for in situ metal sensing in the decade following OceanObs'19.

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Biological and environmental rhythms in (dark) deep-sea hydrothermal ecosystems

Cited by 29 publications

References 53 publications

Integrating Diel Vertical Migrations of Bioluminescent Deep Scattering Layers Into Monitoring Programs

Integrating Diel Vertical Migrations of Bioluminescent Deep Scattering Layers Into Monitoring Programs

Exo-Ocean Exploration with Deep-Sea Sensor and Platform Technologies

Developing Autonomous Observing Systems for Micronutrient Trace Metals

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