Thu. Dec 26th, 2024

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TEXAS: One of the largest animal groups on the planet, the deep sea, is still mostly unknown to us. However, it already faces an increasing number of environmental stresses brought on by humans.
In the scientific journal Nature Communications, a recent study headed by scientists at the GEOMAR Helmholtz Centre for Ocean Research Kiel offers the first insights into the stress response of a deep pelagic jellyfish to ocean warming and sediment plumes caused by deep-sea mining.
The environmental disruption brought on by the commercial mining of mineral resources on the seafloor is one specific and potentially significant environmental stressor for animals in the deep ocean. In addition to targeting seafloor minerals, mining activities will also disrupt and pump up fine silt off the seafloor, creating plumes, or suspended sediment “clouds,” along the seafloor.
The gathered silt must be released back into the water column while on board the ship. These kinds of sediment plumes can spread out over tens or even hundreds of kilometres in the water column because there are currently no rules dictating the minimum depth at which the silt must be released.
Therefore, animal communities in the midwater, or above-the-floor water column, would also be impacted by deep-sea mining. Animals living in the midwater are predicted to be extremely vulnerable to sediment plumes caused by mining because there is typically minimal silt in this area.
This is concerning as Dr Helena Hauss, co-first author of the study and Research Director of Marine Ecology at Norwegian Research Centre (NORCE), explained “The midwater is crucial for the global ocean’s capacity to store carbon, but also its inhabitants are the main food source for many fish, squid, and marine mammal species and therefore resemble a critical link in the marine food web. They have evolved under much more stable conditions compared to surface-dwelling animals, under a constant scarcity of food, and are therefore potentially more susceptible to changing conditions in their environment.”
Dr Henk-Jan Hoving, senior author and group leader of the Deep Sea Ecology group at GEOMAR, added, “Midwater species are often fragile, gelatinous and sometimes giant organisms, with low metabolic rates that are difficult to observe in their natural environment and to perform experiments on. Their physical fragility may make them particularly vulnerable to environmental disturbance. At the same we have only scratched the surface when it comes to exploring the midwater and most biodiversity still remains unknown, as well as their function in the ecosystem, and their tolerance to change.”
Despite the importance of midwater ecosystems on a global scale, little research has so far focussed on species-specific responses of midwater animals to environmental stressors.
This is the gap that the researchers set out to fill in the recently published study. For the first time, the authors of the study investigated the stress response of a midwater organism, the helmet jellyfish (owing to its hat-like shape) to simulated sediment plumes.
“Since determining ‘stress’ in a jellyfish is not a straightforward process, we investigated their response from multiple angles and combined insights gained from their physiology, gene expression and the microbial symbionts on the jellyfish’s exterior”, explained Vanessa Stenvers, co-first author of the study and doctoral candidate at GEOMAR and the Smithsonian Institution.
The strongest visual effect of suspended sediment was the aggregation of sediment particles on the jellyfish after just ~1.5 hours of incubation, to which the jellyfish started to produce excess mucus that slowly sloughed off.
“While mucus helped jellyfish maintain a stable microbiome, continuous mucus production is an energetically costly response and can demand a substantial portion of the total energy budget of an animal”, added Stenvers.
Additionally, jellyfish showed marked expression of genes related to respiration, innate immunity and wound repair in the highest sediment treatments, further signalling stress. Whether jellyfish can recover after exposure remains the subject of further research, as a comprehensive understanding of ecosystem responses to stressors will take time.
The team further emphasizes that suspended sediment induced a more severe response in helmet jellyfish than a four-degree rise in sea water temperature.
Current climate projections assume that sea temperatures will rise by one degree in the next 84 years, while a rise of four degrees is only predicted in the most extreme global warming scenarios. The authors are concerned that stressors leading to increased energy expenditure, as they observed for the helmet jellyfish, will have to be met with increased food intake. Since food in the deep sea is generally scarce, this could ultimately lead to starvation.
Although more data from different midwater species are needed to better understand the environmental impacts of deep-sea mining, the stress response in helmet jellyfish may be representative of other gelatinous animals.
Gelatinous animals, characterized by high water content and jelly-like tissues, are an abundant component of deep-sea ecosystems, represented across the tree of Life. Based on their overall findings, the researchers urge caution with regard to deep-sea mining, as many of the deep ocean’s important ecosystem services could be compromised.
Professor Andrew K. Sweetman, co-author from the Scottish Association for Marine Science, concluded, “With deep-sea mining possibly starting in the next decade, which has the potential to disturb nearby water column habitats as well as the seafloor, understanding the combined effects of mining and ocean warming is essential.”
The team hopes that their study, which provides a first glimpse into what some of the possible impacts may be in the midwater zone, will be taken into account by mining companies and the International Seabed Authority (ISA) to develop mining strategies that reduce the environmental damage as much as possible.



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