Influence of Water Masses on the Biodiversity and Biogeography of Deep-Sea Benthic Ecosystems in the North Atlantic
|Author(s)||Puerta Patricia1, Johnson Clare2, Carreiro-Silva Marina3, Henry Lea-Anne4, Kenchington Ellen5, Morato Telmo3, Kazanidis Georgios4, Luis Rueda Jose6, Urra Javier6, Ross Steve7, Wei Chih-Lin8, Manuel Gonzalez-Irusta Jose9, Arnaud-Haond Sophie10, Orejas Covadonga1|
|Affiliation(s)||1 : Inst Espanol Oceanog, Ctr Oceanog Baleares, Palma De Mallorca, Spain.
2 : Scottish Assoc Marine Sci, Oban, Argyll, Scotland.
3 : Univ Acores, Inst Mar, Ctr OKEANOS, Horta, Portugal.
4 : Univ Edinburgh, Sch GeoSci, Edinburgh, Midlothian, Scotland.
5 : Bedford Inst Oceanog, Dept Fisheries & Oceans, Dartmouth, NS, Canada.
6 : Ctr Oceanog Malaga, Inst Espanol Oceanog, Fuengirola, Spain.
7 : Univ North Carolina Wilmington, Ctr Marine Sci, Wilmington, NC USA.
8 : Natl Taiwan Univ, Inst Oceanog, Taipei, Taiwan.
9 : Inst Espanol Oceanog, Ctr Oceanog Santander, Santander, Spain.
10 : Univ Montpellier, IFREMER, CNRS, MARBEC,IRD, Sete, France.
|Source||Frontiers In Marine Science (2296-7745) (Frontiers Media Sa), 2020-04 , Vol. 7 , N. 239 , P. 25p.|
|WOS© Times Cited||4|
|Keyword(s)||North Atlantic, deep-sea, biodiversity, biogeography, water masses, vulnerable marine ecosystems|
Circulation patterns in the North Atlantic Ocean have changed and re-organized multiple times over millions of years, influencing the biodiversity, distribution, and connectivity patterns of deep-sea species and ecosystems. In this study, we review the effects of the water mass properties (temperature, salinity, food supply, carbonate chemistry, and oxygen) on deep-sea benthic megafauna (from species to community level) and discussed in future scenarios of climate change. We focus on the key oceanic controls on deep-sea megafauna biodiversity and biogeography patterns. We place particular attention on cold-water corals and sponges, as these are ecosystem-engineering organisms that constitute vulnerable marine ecosystems (VME) with high associated biodiversity. Besides documenting the current state of the knowledge on this topic, a future scenario for water mass properties in the deep North Atlantic basin was predicted. The pace and severity of climate change in the deep-sea will vary across regions. However, predicted water mass properties showed that all regions in the North Atlantic will be exposed to multiple stressors by 2100, experiencing at least one critical change in water temperature (+2 degrees C), organic carbon fluxes (reduced up to 50%), ocean acidification (pH reduced up to 0.3), aragonite saturation horizon (shoaling above 1000 m) and/or reduction in dissolved oxygen (> 5%). The northernmost regions of the North Atlantic will suffer the greatest impacts. Warmer and more acidic oceans will drastically reduce the suitable habitat for ecosystem-engineers, with severe consequences such as declines in population densities, even compromising their long-term survival, loss of biodiversity and reduced biogeographic distribution that might compromise connectivity at large scales. These effects can be aggravated by reductions in carbon fluxes, particularly in areas where food availability is already limited. Declines in benthic biomass and biodiversity will diminish ecosystem services such as habitat provision, nutrient cycling, etc. This study shows that the deep-sea VME affected by contemporary anthropogenic impacts and with the ongoing climate change impacts are unlikely to withstand additional pressures from more intrusive human activities. This study serves also as a warning to protect these ecosystems through regulations and by tempering the ongoing socio-political drivers for increasing exploitation of marine resources.