fbpx
Wikipedia

Deep sea

January 31, 2023

For the film, see Deep Sea 3D.

The deep sea is broadly defined as the ocean depth where light begins to fade, at an approximate depth of 200 metres (656 feet) or the point of transition from continental shelves to continental slopes.[1][2] Conditions within the deep sea are a combination of low temperatures, darkness and high pressure[3] The deep sea is considered the least explored Earth biome, with the extreme conditions making the environment difficult to access and explore.[4]

Schematic representation of pelagic and benthic zones.

Organisms living within the deep sea have a variety of adaptations to survive in these conditions.[5] Organisms can survive in the deep sea through a number of feeding methods including scavenging, predation and filtration, with a number of organisms surviving by feeding on marine snow.[6] Marine snow is organic material that has fallen from upper waters into the deep sea.[7]

In 1960, the bathyscaphe Trieste descended to the bottom of the Mariana Trench near Guam, at 10,911 m (35,797 ft; 6.780 mi), the deepest known spot in any ocean. If Mount Everest (8,848 m or 29,029 ft or 5.498 mi) were submerged there, its peak would be more than 2 km (1.2 mi) beneath the surface. After the Trieste was retired, the Japanese remote-operated vehicle (ROV) Kaikō was the only vessel capable of reaching this depth until it was lost at sea in 2003.[8] In May and June 2009, the hybrid-ROV Nereus returned to the Challenger Deep for a series of three dives to depths exceeding 10,900 m (35,800 ft; 6.8 mi).

Environmental characteristics

Light

Natural light does not penetrate the deep ocean, with the exception of the upper parts of the mesopelagic. Since photosynthesis is not possible, plants and phytoplankton cannot live in this zone, and as these are the primary producers of almost all of earth's ecosystems, life in this area of the ocean must depend on energy sources from elsewhere. Except for the areas close to the hydrothermal vents, this energy comes from organic material drifting down from the photic zone. The sinking organic material is composed of algal particulates, detritus, and other forms of biological waste, which is collectively referred to as marine snow.[citation needed]

Pressure

Because pressure in the ocean increases by about 1 atmosphere for every 10 meters of depth, the amount of pressure experienced by many marine organisms is extreme. Until recent years, the scientific community lacked detailed information about the effects of pressure on most deep sea organisms because the specimens encountered arrived at the surface dead or dying and weren't observable at the pressures at which they lived. With the advent of traps that incorporate a special pressure-maintaining chamber, undamaged larger metazoan animals have been retrieved from the deep sea in good condition.[citation needed]

Salinity

Salinity is remarkably constant throughout the deep sea, at about 35 parts per thousand.[9] There are some minor differences in salinity, but none that are ecologically significant, except in the Mediterranean and Red Seas.

Temperature

The two areas of greatest temperature gradient in the oceans are the transition zone between the surface waters and the deep waters, the thermocline, and the transition between the deep-sea floor and the hot water flows at the hydrothermal vents. Thermoclines vary in thickness from a few hundred meters to nearly a thousand meters. Below the thermocline, the water mass of the deep ocean is cold and far more homogeneous. Thermoclines are strongest in the tropics, where the temperature of the epipelagic zone is usually above 20 °C. From the base of the epipelagic, the temperature drops over several hundred meters to 5 or 6 °C at 1,000 meters. It continues to decrease to the bottom, but the rate is much slower. The cold water stems from sinking heavy surface water in the polar regions.[9]

At any given depth, the temperature is practically unvarying over long periods of time, without seasonal changes and with very little interannual variability. No other habitat on earth has such a constant temperature.[10]

In hydrothermal vents the temperature of the water as it emerges from the "black smoker" chimneys may be as high as 400 °C (it is kept from boiling by the high hydrostatic pressure) while within a few meters it may be back down to 2 to 4 °C.[11]

Biology

Main article: Deep sea community

Regions below the epipelagic are divided into further zones, beginning with the bathyal zone (also considered the continental slope) which spans from 200 to 3000 meters [12] below sea level and is essentially transitional, containing elements from both the shelf above and the abyss below.[13] Below this zone, the deep sea consists of the abyssal zone which occurs between the ocean depths of 3000 and 6000 metres [14] and the hadal zone (6000 - 11,000 meters).[15][16] Food consists of falling organic matter known as 'marine snow' and carcasses derived from the productive zone above, and is scarce both in terms of spatial and temporal distribution.[17]

Instead of relying on gas for their buoyancy, many deep-sea species have jelly-like flesh consisting mostly of glycosaminoglycans, which provides them with very low density. It is also common among deep water squid to combine the gelatinous tissue with a flotation chamber filled with a coelomic fluid made up of the metabolic waste product ammonium chloride, which is lighter than the surrounding water.[citation needed]

The midwater fish have special adaptations to cope with these conditions—they are small, usually being under 25 centimetres (10 in); they have slow metabolisms and unspecialized diets, preferring to sit and wait for food rather than waste energy searching for it. They have elongated bodies with weak, watery muscles and skeletal structures. They often have extendable, hinged jaws with recurved teeth. Because of the sparse distribution and lack of light, finding a partner with which to breed is difficult, and many organisms are hermaphroditic.[citation needed]

Because light is so scarce, fish often have larger than normal, tubular eyes with only rod cells. [18][19] Their upward field of vision allows them to seek out the silhouette of possible prey.[20] Prey fish however also have adaptations to cope with predation. These adaptations are mainly concerned with reduction of silhouettes, a form of camouflage. The two main methods by which this is achieved are reduction in the area of their shadow by lateral compression of the body,[21] and counter illumination via bioluminescence. [22][19] This is achieved by production of light from ventral photophores, which tend to produce such light intensity to render the underside of the fish of similar appearance to the background light. For more sensitive vision in low light, some fish have a retroreflector behind the retina.[23] Flashlight fish have this plus photophores, which combination they use to detect eyeshine in other fish (see tapetum lucidum).[24][25]

Organisms in the deep sea are almost entirely reliant upon sinking living and dead organic matter which falls at approximately 100 meters per day.[26] In addition, only about 1 to 3% of the production from the surface reaches the sea bed mostly in the form of marine snow. Larger food falls, such as whale carcasses, also occur and studies have shown that these may happen more often than currently believed. There are many scavengers that feed primarily or entirely upon large food falls and the distance between whale carcasses is estimated to only be 8 kilometers.[27] In addition, there are a number of filter feeders that feed upon organic particles using tentacles, such as Freyella elegans.[28]

Marine bacteriophages play an important role in cycling nutrients in deep sea sediments. They are extremely abundant (between 5×1012 and 1×1013 phages per square meter) in sediments around the world.[29]

Despite being so isolated deep sea organisms have still been harmed by human interaction with the oceans. The London Convention[30] aims to protect the marine environment from dumping of wastes such as sewage sludge[31] and radioactive waste. A study found that at one region there had been a decrease in deep sea coral from 2007 to 2011, with the decrease being attributed to global warming and ocean acidification, and biodiversity estimated as being at the lowest levels in 58 years.[32] Ocean acidification is particularly harmful to deep sea corals because they are made of aragonite, an easily soluble carbonate, and because they are particularly slow growing and will take years to recover.[33] Deep sea trawling is also harming the biodiversity by destroying deep sea habitats which can take years to form.[34] Another human activity that has altered deep sea biology is mining. One study found that at one mining site fish populations had decreased at six months and at three years, and that after twenty six years populations had returned to the same levels as prior to the disturbance.[35]

Chemosynthesis

There are a number of species that do not primarily rely upon dissolved organic matter for their food. These species and communities are found at hydrothermal vents at sea-floor spreading zones.[36][37] One example is the symbiotic relationship between the tube worm Riftia and chemosynthetic bacteria.[38] It is this chemosynthesis that supports the complex communities that can be found around hydrothermal vents. These complex communities are one of the few ecosystems on the planet that do not rely upon sunlight for their supply of energy.[39]

Adaptation to hydrostatic pressure

Deep sea fish have different adaptations in their proteins, anatomical structures, and metabolic systems to survive in the Deep sea, where the inhabitants have to withstand great amount of hydrostatic pressure. While other factors like food availability and predator avoidance are important, the deep-sea organisms must have the ability to maintain well-regulated metabolic system in the face of high pressures. [40] In order to adjust for the extreme environment, these organisms have developed unique characteristics.

Proteins are affected greatly by the elevated hydrostatic pressure, as they undergo changes in water organization during hydration and dehydration reactions of the binding events. This is due to the fact that most enzyme-ligand interactions form through charged or polar non-charge interactions. Because hydrostatic pressure affects both protein folding and assembly and enzymatic activity, the deep sea species must undergo physiological and structural adaptations to preserve protein functionality against pressure.[40][41]

Actin is a protein that is essential for different cellular functions. The α-actin serves as a main component for muscle fiber, and it is highly conserved across numerous different species. Some Deep-sea fish developed pressure tolerance through the change in mechanism of their α-actin. In some species that live in depths greater than 5000m, C.armatus and C.yaquinae have specific substitutions on the active sites of α-Actin, which serves as the main component of muscle fiber.[42] These specific substitutions, Q137K and V54A from C.armatus or I67P from C.yaquinae are predicted to have importance in pressure tolerance.[42] Substitution in the active sites of actin result in significant changes in the salt bridge patterns of the protein, which allows for better stabilization in ATP binding and sub unit arrangement, confirmed by the free energy analysis and molecular dynamics simulation.[43] It was found that deep sea fish have more salt bridges in their actins compared to fish inhabiting the upper zones of the sea.[42]

In relations to protein substitution, specific osmolytes were found to be abundant in deep sea fish under high hydrostatic pressure. For certain chondrichtyans, it was found that Trimethylamine N-oxide (TMAO) increased with depth, replacing other osmolytes and urea.[44] Due to the ability of TMAO being able to protect proteins from high hydrostatic pressure destabilizing proteins, the osmolyte adjustment serves are an important adaptation for deep sea fish to withstand high hydrostatic pressure.

Deep-sea organisms possess molecular adaptations to survive and thrive in the deep oceans. Mariana hadal snailfish developed modification in the Osteocalcin(burlap) gene, where premature termination of the gene was found.[41] Osteocalcin gene regulates bone development and tissue mineralization, and the frameshift mutation seems to have resulted in the open skull and cartilage-based bone formation.[41] Due to high hydrostatic pressure in the deep sea, closed skulls that organisms living on the surface develop cannot withstand the enforcing stress. Similarly, common bone developments seen in surface vertebrates cannot maintain their structural integrity under constant high pressure.[41]

Exploration

Main article: Deep-sea exploration

It has been suggested that more is known about the Moon than the deepest parts of the ocean.[45] This is a common misconception based on a 1953 statement by George E.R. Deacon published in the Journal of Navigation, and largely refers to the scarce amount of seafloor bathymetry available at the time.[46] The similar idea that more people have stood on the moon than have been to the deepest part of the ocean is likewise problematic.[46]

Describing the operation and use of an autonomous lander (RV Kaharoa) in deep-sea research; the fish seen is the abyssal grenadier (Coryphaenoides armatus).

Still the deep-sea remains one of the least explored regions on planet Earth.[47] Pressures even in the mesopelagic become too great for traditional exploration methods, demanding alternative approaches for deep-sea research. Baited camera stations, small manned submersibles, and ROVs (remotely operated vehicles) are three methods utilized to explore the ocean's depths. Because of the difficulty and cost of exploring this zone, current knowledge is limited. Pressure increases at approximately one atmosphere for every 10 meters meaning that some areas of the deep sea can reach pressures of above 1,000 atmospheres. This not only makes great depths very difficult to reach without mechanical aids, but also provides a significant difficulty when attempting to study any organisms that may live in these areas as their cell chemistry will be adapted to such vast pressures.

See also

References

  1. ^ Tyler, P. A. (2003). In Ecosystems of the World 28, Ecosystems of the Deep Sea. Amsterdam: Elsevier. pp. 1–3.
  2. ^ "What is the "deep" ocean? : Ocean Exploration Facts: NOAA Office of Ocean Exploration and Research". oceanexplorer.noaa.gov. Retrieved 2022-09-29.
  3. ^ Paulus, Eva (2021). "Shedding Light on Deep-Sea Biodiversity—A Highly Vulnerable Habitat in the Face of Anthropogenic Change". Frontiers in Marine Science. 8. doi:10.3389/fmars.2021.667048. ISSN 2296-7745.
  4. ^ Danovaro, Roberto; Corinaldesi, Cinzia; Dell’Anno, Antonio; Snelgrove, Paul V. R. (2017-06-05). "The deep-sea under global change". Current Biology. 27 (11): R461–R465. doi:10.1016/j.cub.2017.02.046. ISSN 0960-9822. PMID 28586679. S2CID 20785268.
  5. ^ Brown, Alastair; Thatje, Sven (2013). "Explaining bathymetric diversity patterns in marine benthic invertebrates and demersal fishes: physiological contributions to adaptation of life at depth". Biological Reviews. 89 (2): 406–426. doi:10.1111/brv.12061. ISSN 1464-7931. PMC 4158864. PMID 24118851.
  6. ^ Higgs, Nicholas D.; Gates, Andrew R.; Jones, Daniel O. B. (2014-05-07). "Fish Food in the Deep Sea: Revisiting the Role of Large Food-Falls". PLOS ONE. 9 (5): e96016. Bibcode:2014PLoSO...996016H. doi:10.1371/journal.pone.0096016. ISSN 1932-6203. PMC 4013046. PMID 24804731.
  7. ^ US Department of Commerce, National Oceanic and Atmospheric Administration. "What is marine snow?". oceanservice.noaa.gov. Retrieved 2022-09-29.
  8. ^ Horstman, Mark (2003-07-09). "Hope floats for lost deep-sea explorer". www.abc.net.au. from the original on 2010-09-27. Retrieved 2021-05-07.
  9. ^ a b Claus Detlefsen. "About the Marianas" (in Danish) Ingeniøren / Geological Survey of Denmark and Greenland, 2 November 2013. Accessed: 2 November 2013.
  10. ^ MarineBio (2018-06-17). "The Deep Sea". MarineBio Conservation Society. Retrieved 2020-08-07.
  11. ^ Nybakken, James W. Marine Biology: An Ecological Approach. Fifth Edition. Benjamin Cummings, 2001. p. 136 - 141.
  12. ^ Levin, Lisa A.; Dayton, Paul K. (1 November 2009). "Ecological theory and continental margins: where shallow meets deep". Trends in Ecology & Evolution. 24 (11): 606–617. doi:10.1016/j.tree.2009.04.012. ISSN 0169-5347. PMID 19692143. Retrieved 29 September 2022.
  13. ^ Gage, John D.; Tyler, Paul A. (18 April 1991). Deep-Sea Biology: A Natural History of Organisms at the Deep-Sea Floor. Cambridge University Press. ISBN 978-0-521-33431-0. Retrieved 29 September 2022.
  14. ^ Smith, Craig R.; De Leo, Fabio C.; Bernardino, Angelo F.; Sweetman, Andrew K.; Arbizu, Pedro Martinez (1 September 2008). "Abyssal food limitation, ecosystem structure and climate change". Trends in Ecology & Evolution. 23 (9): 518–528. doi:10.1016/j.tree.2008.05.002. ISSN 0169-5347. PMID 18584909. Retrieved 29 September 2022.
  15. ^ Jamieson, Alan J.; Fujii, Toyonobu; Mayor, Daniel J.; Solan, Martin; Priede, Imants G. (1 March 2010). "Hadal trenches: the ecology of the deepest places on Earth". Trends in Ecology & Evolution. 25 (3): 190–197. doi:10.1016/j.tree.2009.09.009. ISSN 0169-5347. PMID 19846236. Retrieved 29 September 2022.
  16. ^ Jamieson, Alan J.; Stewart, Heather A.; Weston, Johanna N. J.; Lahey, Patrick; Vescovo, Victor L. (2022). "Hadal Biodiversity, Habitats and Potential Chemosynthesis in the Java Trench, Eastern Indian Ocean". Frontiers in Marine Science. 9. doi:10.3389/fmars.2022.856992.
  17. ^ Robison, Bruce H.; Reisenbichler, Kim R.; Sherlock, Rob E. (2005-06-10). "Giant Larvacean Houses: Rapid Carbon Transport to the Deep Sea Floor". Science. 308 (5728): 1609–1611. Bibcode:2005Sci...308.1609R. doi:10.1126/science.1109104. ISSN 0036-8075. PMID 15947183. S2CID 730130.
  18. ^ Lupše, Nik; Cortesi, Fabio; Freese, Marko; Marohn, Lasse; Pohlmann, Jan-Dag; Wysujack, Klaus; Hanel, Reinhold; Musilova, Zuzana (9 December 2021). "Visual Gene Expression Reveals a cone-to-rod Developmental Progression in Deep-Sea Fishes". Molecular Biology and Evolution. 38 (12): 5664–5677. doi:10.1093/molbev/msab281. PMC 8662630. PMID 34562090. Retrieved 29 September 2022.
  19. ^ a b Warrant, Eric J.; Locket, N. Adam (August 2004). "Vision in the deep sea". Biological Reviews. 79 (3): 671–712. doi:10.1017/S1464793103006420. ISSN 1469-185X. PMID 15366767. S2CID 34907805.
  20. ^ Collin, Shaun P.; Chapuis, Lucille; Michiels, Nico K. (2019). "Impacts of (extreme) depth on life in the deep-sea". Marine Extremes. Routledge. pp. 197–216. doi:10.4324/9780429491023-12. ISBN 9780429491023. S2CID 133939260. Retrieved 29 September 2022.
  21. ^ Hoving, Henk‐Jan T.; Freitas, Rui (February 2022). "Pelagic observations of the midwater scorpionfish Ectreposebastes imus (Setarchidae) suggests a role in trophic coupling between deep‐sea habitats". Journal of Fish Biology. 100 (2): 586–589. doi:10.1111/jfb.14944. PMID 34751439. S2CID 243863469. Retrieved 29 September 2022.
  22. ^ Davis, Alexander L.; Sutton, Tracey T.; Kier, William M.; Johnsen, Sönke (10 June 2020). "Evidence that eye-facing photophores serve as a reference for counterillumination in an order of deep-sea fishes". Proceedings of the Royal Society B: Biological Sciences. 287 (1928): 20192918. doi:10.1098/rspb.2019.2918. PMC 7341941. PMID 32517614.
  23. ^ Palmer, Benjamin A.; Gur, Dvir; Weiner, Steve; Addadi, Lia; Oron, Dan (October 2018). "The Organic Crystalline Materials of Vision: Structure-Function Considerations from the Nanometer to the Millimeter Scale". Advanced Materials. 30 (41): 1800006. doi:10.1002/adma.201800006. PMID 29888511. S2CID 47005095. Retrieved 29 September 2022.
  24. ^ Hellinger, Jens; Jägers, Peter; Donner, Marcel; Sutt, Franziska; Mark, Melanie D.; Senen, Budiono; Tollrian, Ralph; Herlitze, Stefan (2017-02-08). De, Abhijit (ed.). "The Flashlight Fish Anomalops katoptron Uses Bioluminescent Light to Detect Prey in the Dark". PLOS ONE. 12 (2): e0170489. Bibcode:2017PLoSO..1270489H. doi:10.1371/journal.pone.0170489. ISSN 1932-6203. PMC 5298212. PMID 28178297.
  25. ^ Cavallaro, Mauro; Guerrera, Maria Cristina; Abbate, Francesco; Levanti, Maria Beatrice; Laurà, Rosaria; Ammendolia, Giovanni; Malara, Danilo; Stipa, Maria Giulia; Battaglia, Pietro (October 2021). "Morphological, ultrastructural and immunohistochemical study on the skin ventral photophores of Diaphus holti Tåning, 1918 (Family: Myctophidae)". Acta Zoologica. 102 (4): 405–411. doi:10.1111/azo.12348. ISSN 0001-7272. S2CID 225368866.
  26. ^ "Marine Snow and Fecal Pellets". Oceanus Magazine.
  27. ^ R. N. Gibson, Harold (CON) Barnes, R. J. A. Atkinson, Oceanography and Marine Biology, An Annual Review. 2007. Volume 41. Published by CRC Press, 2004 ISBN 0-415-25463-9, ISBN 978-0-415-25463-2
  28. ^ "Discover - Natural History Museum". www.nhm.ac.uk.
  29. ^ Danovaro, Roberto; Antonio Dell'Anno; Cinzia Corinaldesi; Mirko Magagnini; Rachel Noble; Christian Tamburini; Markus Weinbauer (2008-08-28). "Major viral impact on the functioning of benthic deep-sea ecosystems". Nature. 454 (7208): 1084–1087. Bibcode:2008Natur.454.1084D. doi:10.1038/nature07268. PMID 18756250. S2CID 4331430.
  30. ^ . International Maritime Organization. Archived from the original on 3 March 2019. Retrieved 24 March 2020.
  31. ^ Snelgrove, Paul; Grassle, Fred (1995-01-01). "What of the deep sea's future diversity?". Oceanus. 38 (2). Retrieved 24 March 2020.
  32. ^ Zimmerman, Alexander N.; Johnson, Claudia C.; Bussberg, Nicholas W.; Dalkilic, Mehmet M. (April 2020). "Stability and decline in deep-sea coral biodiversity, Gulf of Mexico and US West Atlantic". Coral Reefs. 39 (2): 345–359. doi:10.1007/s00338-020-01896-9. S2CID 210975434.
  33. ^ Ruttimann, Jacqueline (2006-08-31). "Oceanography: sick seas". Nature. 442 (7106): 978–80. Bibcode:2006Natur.442..978R. doi:10.1038/442978a. PMID 16943816. S2CID 4332965.
  34. ^ Koslow, Tony (2011-11-20). "The silent deep: the discovery, ecology & conservation of the deep sea". Pacific Ecologist. 20.
  35. ^ Drazen, Jeffery; Leitner, Astrid; Morningstar, Sage; Marcon, Yann; Greinert, Jens; Purser, Auntun (2019-01-01). "Observations of deep-sea fishes and mobile scavengers from the abyssal DISCOL experimental mining area". Biogeosciences. 16 (16): 3133–3146. Bibcode:2019BGeo...16.3133D. doi:10.5194/bg-16-3133-2019. ProQuest 2276806480.
  36. ^ Dover, Cindy Van (2000-03-26). The Ecology of Deep-Sea Hydrothermal Vents. ISBN 978-0-691-04929-8.
  37. ^ Martin, William; Baross, John; Kelley, Deborah; Russell, Michael J. (November 2008). "Hydrothermal vents and the origin of life". Nature Reviews Microbiology. 6 (11): 805–814. doi:10.1038/nrmicro1991. ISSN 1740-1534. PMID 18820700. S2CID 1709272.
  38. ^ Cavanaugh, F. J. Stewart and C. M. (2006). "Symbiosis of Thioautotrophic Bacteria with Riftia pachyptila | EndNote Click". Progress in Molecular and Subcellular Biology. 41: 197–225. doi:10.1007/3-540-28221-1_10. PMID 16623395. Retrieved 2022-09-29.
  39. ^ HW Jannasch. 1985. The Chemosynthetic Support of Life and the Microbial Diversity at Deep-Sea Hydrothermal Vents. Proceedings of the Royal Society of London. Series B, Biological Sciences, Vol. 225, No. 1240 (Sep. 23, 1985), pp. 277-297
  40. ^ a b "Chapter Twelve. Adaptations to the Deep Sea", Biochemical Adaptation, Princeton University Press, pp. 450–495, 1984-12-31, doi:10.1515/9781400855414.450, ISBN 978-1-4008-5541-4, retrieved 2020-11-02
  41. ^ a b c d Wang, Kun; Shen, Yanjun; Yang, Yongzhi; Gan, Xiaoni; Liu, Guichun; Hu, Kuang; Li, Yongxin; Gao, Zhaoming; Zhu, Li; Yan, Guoyong; He, Lisheng (May 2019). "Morphology and genome of a snailfish from the Mariana Trench provide insights into deep-sea adaptation". Nature Ecology & Evolution. 3 (5): 823–833. doi:10.1038/s41559-019-0864-8. ISSN 2397-334X. PMID 30988486.
  42. ^ a b c Wakai, Nobuhiko; Takemura, Kazuhiro; Morita, Takami; Kitao, Akio (2014-01-20). "Mechanism of Deep-Sea Fish α-Actin Pressure Tolerance Investigated by Molecular Dynamics Simulations". PLOS ONE. 9 (1): e85852. Bibcode:2014PLoSO...985852W. doi:10.1371/journal.pone.0085852. ISSN 1932-6203. PMC 3896411. PMID 24465747.
  43. ^ Hata, Hiroaki; Nishiyama, Masayoshi; Kitao, Akio (2020-02-01). "Molecular dynamics simulation of proteins under high pressure: Structure, function and thermodynamics". Biochimica et Biophysica Acta (BBA) - General Subjects. Novel measurement techniques for visualizing 'live' protein molecules. 1864 (2): 129395. doi:10.1016/j.bbagen.2019.07.004. ISSN 0304-4165. PMID 31302180. S2CID 196613044.
  44. ^ Yancey, Paul H.; Speers-Roesch, Ben; Atchinson, Sheila; Reist, James D.; Majewski, Andrew R.; Treberg, Jason R. (2017-11-27). "Osmolyte Adjustments as a Pressure Adaptation in Deep-Sea Chondrichthyan Fishes: An Intraspecific Test in Arctic Skates (Amblyraja hyperborea) along a Depth Gradient". Physiological and Biochemical Zoology. 91 (2): 788–796. doi:10.1086/696157. ISSN 1522-2152. PMID 29315031. S2CID 26847773.
  45. ^ Tim Flannery, Where Wonders Await Us. New York Review of Books, December 2007
  46. ^ a b Jamieson, Alan J; Singleman, Glenn; Linley, Thomas D; Casey, Susan (2020-12-21). "Fear and loathing of the deep ocean: why don't people care about the deep sea?". ICES Journal of Marine Science. 78 (3): 797–809. doi:10.1093/icesjms/fsaa234. ISSN 1054-3139.
  47. ^ Briand, F.; Snelgrove, P. (2003). "Mare Incognitum? An overview". CIESM Workshop Monographs. 23: 5–27.[1]

External links

 
Scholia has a topic profile for Deep sea.
  • Deep Sea Foraminifera – Deep Sea Foraminifera from 4400 meters depth, Antarctica - an image gallery and description of hundreds of specimens
  • Deep Ocean Exploration on the Smithsonian Ocean Portal
  • Deep-Sea Creatures Facts and images from the deepest parts of the ocean
  • How Deep Is The Ocean 2016-06-15 at the Wayback Machine Facts and infographic on ocean depth

January 31, 2023
deep, film, deep, deep, broadly, defined, ocean, depth, where, light, begins, fade, approximate, depth, metres, feet, point, transition, from, continental, shelves, continental, slopes, conditions, within, deep, combination, temperatures, darkness, high, press. For the film see Deep Sea 3D The deep sea is broadly defined as the ocean depth where light begins to fade at an approximate depth of 200 metres 656 feet or the point of transition from continental shelves to continental slopes 1 2 Conditions within the deep sea are a combination of low temperatures darkness and high pressure 3 The deep sea is considered the least explored Earth biome with the extreme conditions making the environment difficult to access and explore 4 Schematic representation of pelagic and benthic zones Organisms living within the deep sea have a variety of adaptations to survive in these conditions 5 Organisms can survive in the deep sea through a number of feeding methods including scavenging predation and filtration with a number of organisms surviving by feeding on marine snow 6 Marine snow is organic material that has fallen from upper waters into the deep sea 7 In 1960 the bathyscaphe Trieste descended to the bottom of the Mariana Trench near Guam at 10 911 m 35 797 ft 6 780 mi the deepest known spot in any ocean If Mount Everest 8 848 m or 29 029 ft or 5 498 mi were submerged there its peak would be more than 2 km 1 2 mi beneath the surface After the Trieste was retired the Japanese remote operated vehicle ROV Kaikō was the only vessel capable of reaching this depth until it was lost at sea in 2003 8 In May and June 2009 the hybrid ROV Nereus returned to the Challenger Deep for a series of three dives to depths exceeding 10 900 m 35 800 ft 6 8 mi Contents 1 Environmental characteristics 1 1 Light 1 2 Pressure 1 3 Salinity 1 4 Temperature 2 Biology 2 1 Chemosynthesis 2 2 Adaptation to hydrostatic pressure 3 Exploration 4 See also 5 References 6 External linksEnvironmental characteristics EditLight Edit Natural light does not penetrate the deep ocean with the exception of the upper parts of the mesopelagic Since photosynthesis is not possible plants and phytoplankton cannot live in this zone and as these are the primary producers of almost all of earth s ecosystems life in this area of the ocean must depend on energy sources from elsewhere Except for the areas close to the hydrothermal vents this energy comes from organic material drifting down from the photic zone The sinking organic material is composed of algal particulates detritus and other forms of biological waste which is collectively referred to as marine snow citation needed Pressure Edit Because pressure in the ocean increases by about 1 atmosphere for every 10 meters of depth the amount of pressure experienced by many marine organisms is extreme Until recent years the scientific community lacked detailed information about the effects of pressure on most deep sea organisms because the specimens encountered arrived at the surface dead or dying and weren t observable at the pressures at which they lived With the advent of traps that incorporate a special pressure maintaining chamber undamaged larger metazoan animals have been retrieved from the deep sea in good condition citation needed Salinity Edit Salinity is remarkably constant throughout the deep sea at about 35 parts per thousand 9 There are some minor differences in salinity but none that are ecologically significant except in the Mediterranean and Red Seas Temperature Edit The two areas of greatest temperature gradient in the oceans are the transition zone between the surface waters and the deep waters the thermocline and the transition between the deep sea floor and the hot water flows at the hydrothermal vents Thermoclines vary in thickness from a few hundred meters to nearly a thousand meters Below the thermocline the water mass of the deep ocean is cold and far more homogeneous Thermoclines are strongest in the tropics where the temperature of the epipelagic zone is usually above 20 C From the base of the epipelagic the temperature drops over several hundred meters to 5 or 6 C at 1 000 meters It continues to decrease to the bottom but the rate is much slower The cold water stems from sinking heavy surface water in the polar regions 9 At any given depth the temperature is practically unvarying over long periods of time without seasonal changes and with very little interannual variability No other habitat on earth has such a constant temperature 10 In hydrothermal vents the temperature of the water as it emerges from the black smoker chimneys may be as high as 400 C it is kept from boiling by the high hydrostatic pressure while within a few meters it may be back down to 2 to 4 C 11 Biology EditMain article Deep sea community Regions below the epipelagic are divided into further zones beginning with the bathyal zone also considered the continental slope which spans from 200 to 3000 meters 12 below sea level and is essentially transitional containing elements from both the shelf above and the abyss below 13 Below this zone the deep sea consists of the abyssal zone which occurs between the ocean depths of 3000 and 6000 metres 14 and the hadal zone 6000 11 000 meters 15 16 Food consists of falling organic matter known as marine snow and carcasses derived from the productive zone above and is scarce both in terms of spatial and temporal distribution 17 Instead of relying on gas for their buoyancy many deep sea species have jelly like flesh consisting mostly of glycosaminoglycans which provides them with very low density It is also common among deep water squid to combine the gelatinous tissue with a flotation chamber filled with a coelomic fluid made up of the metabolic waste product ammonium chloride which is lighter than the surrounding water citation needed The midwater fish have special adaptations to cope with these conditions they are small usually being under 25 centimetres 10 in they have slow metabolisms and unspecialized diets preferring to sit and wait for food rather than waste energy searching for it They have elongated bodies with weak watery muscles and skeletal structures They often have extendable hinged jaws with recurved teeth Because of the sparse distribution and lack of light finding a partner with which to breed is difficult and many organisms are hermaphroditic citation needed Because light is so scarce fish often have larger than normal tubular eyes with only rod cells 18 19 Their upward field of vision allows them to seek out the silhouette of possible prey 20 Prey fish however also have adaptations to cope with predation These adaptations are mainly concerned with reduction of silhouettes a form of camouflage The two main methods by which this is achieved are reduction in the area of their shadow by lateral compression of the body 21 and counter illumination via bioluminescence 22 19 This is achieved by production of light from ventral photophores which tend to produce such light intensity to render the underside of the fish of similar appearance to the background light For more sensitive vision in low light some fish have a retroreflector behind the retina 23 Flashlight fish have this plus photophores which combination they use to detect eyeshine in other fish see tapetum lucidum 24 25 Organisms in the deep sea are almost entirely reliant upon sinking living and dead organic matter which falls at approximately 100 meters per day 26 In addition only about 1 to 3 of the production from the surface reaches the sea bed mostly in the form of marine snow Larger food falls such as whale carcasses also occur and studies have shown that these may happen more often than currently believed There are many scavengers that feed primarily or entirely upon large food falls and the distance between whale carcasses is estimated to only be 8 kilometers 27 In addition there are a number of filter feeders that feed upon organic particles using tentacles such as Freyella elegans 28 Marine bacteriophages play an important role in cycling nutrients in deep sea sediments They are extremely abundant between 5 1012 and 1 1013 phages per square meter in sediments around the world 29 Despite being so isolated deep sea organisms have still been harmed by human interaction with the oceans The London Convention 30 aims to protect the marine environment from dumping of wastes such as sewage sludge 31 and radioactive waste A study found that at one region there had been a decrease in deep sea coral from 2007 to 2011 with the decrease being attributed to global warming and ocean acidification and biodiversity estimated as being at the lowest levels in 58 years 32 Ocean acidification is particularly harmful to deep sea corals because they are made of aragonite an easily soluble carbonate and because they are particularly slow growing and will take years to recover 33 Deep sea trawling is also harming the biodiversity by destroying deep sea habitats which can take years to form 34 Another human activity that has altered deep sea biology is mining One study found that at one mining site fish populations had decreased at six months and at three years and that after twenty six years populations had returned to the same levels as prior to the disturbance 35 Chemosynthesis Edit There are a number of species that do not primarily rely upon dissolved organic matter for their food These species and communities are found at hydrothermal vents at sea floor spreading zones 36 37 One example is the symbiotic relationship between the tube worm Riftia and chemosynthetic bacteria 38 It is this chemosynthesis that supports the complex communities that can be found around hydrothermal vents These complex communities are one of the few ecosystems on the planet that do not rely upon sunlight for their supply of energy 39 Adaptation to hydrostatic pressure Edit Deep sea fish have different adaptations in their proteins anatomical structures and metabolic systems to survive in the Deep sea where the inhabitants have to withstand great amount of hydrostatic pressure While other factors like food availability and predator avoidance are important the deep sea organisms must have the ability to maintain well regulated metabolic system in the face of high pressures 40 In order to adjust for the extreme environment these organisms have developed unique characteristics Proteins are affected greatly by the elevated hydrostatic pressure as they undergo changes in water organization during hydration and dehydration reactions of the binding events This is due to the fact that most enzyme ligand interactions form through charged or polar non charge interactions Because hydrostatic pressure affects both protein folding and assembly and enzymatic activity the deep sea species must undergo physiological and structural adaptations to preserve protein functionality against pressure 40 41 Actin is a protein that is essential for different cellular functions The a actin serves as a main component for muscle fiber and it is highly conserved across numerous different species Some Deep sea fish developed pressure tolerance through the change in mechanism of their a actin In some species that live in depths greater than 5000m C armatus and C yaquinae have specific substitutions on the active sites of a Actin which serves as the main component of muscle fiber 42 These specific substitutions Q137K and V54A from C armatus or I67P from C yaquinae are predicted to have importance in pressure tolerance 42 Substitution in the active sites of actin result in significant changes in the salt bridge patterns of the protein which allows for better stabilization in ATP binding and sub unit arrangement confirmed by the free energy analysis and molecular dynamics simulation 43 It was found that deep sea fish have more salt bridges in their actins compared to fish inhabiting the upper zones of the sea 42 In relations to protein substitution specific osmolytes were found to be abundant in deep sea fish under high hydrostatic pressure For certain chondrichtyans it was found that Trimethylamine N oxide TMAO increased with depth replacing other osmolytes and urea 44 Due to the ability of TMAO being able to protect proteins from high hydrostatic pressure destabilizing proteins the osmolyte adjustment serves are an important adaptation for deep sea fish to withstand high hydrostatic pressure Deep sea organisms possess molecular adaptations to survive and thrive in the deep oceans Mariana hadal snailfish developed modification in the Osteocalcin burlap gene where premature termination of the gene was found 41 Osteocalcin gene regulates bone development and tissue mineralization and the frameshift mutation seems to have resulted in the open skull and cartilage based bone formation 41 Due to high hydrostatic pressure in the deep sea closed skulls that organisms living on the surface develop cannot withstand the enforcing stress Similarly common bone developments seen in surface vertebrates cannot maintain their structural integrity under constant high pressure 41 Exploration EditMain article Deep sea explorationIt has been suggested that more is known about the Moon than the deepest parts of the ocean 45 This is a common misconception based on a 1953 statement by George E R Deacon published in the Journal of Navigation and largely refers to the scarce amount of seafloor bathymetry available at the time 46 The similar idea that more people have stood on the moon than have been to the deepest part of the ocean is likewise problematic 46 source source source source source source source source source source source source source source Describing the operation and use of an autonomous lander RV Kaharoa in deep sea research the fish seen is the abyssal grenadier Coryphaenoides armatus Still the deep sea remains one of the least explored regions on planet Earth 47 Pressures even in the mesopelagic become too great for traditional exploration methods demanding alternative approaches for deep sea research Baited camera stations small manned submersibles and ROVs remotely operated vehicles are three methods utilized to explore the ocean s depths Because of the difficulty and cost of exploring this zone current knowledge is limited Pressure increases at approximately one atmosphere for every 10 meters meaning that some areas of the deep sea can reach pressures of above 1 000 atmospheres This not only makes great depths very difficult to reach without mechanical aids but also provides a significant difficulty when attempting to study any organisms that may live in these areas as their cell chemistry will be adapted to such vast pressures See also EditDeep sea fish Deep ocean water Cold salty water deep below the surface of Earth s oceans Submarine landslide Landslides that transport sediment across the continental shelf and into the deep ocean The Blue Planet 2001 British nature documentary television series Nepheloid layer Oceans portalReferences Edit Tyler P A 2003 In Ecosystems of the World 28 Ecosystems of the Deep Sea Amsterdam Elsevier pp 1 3 What is the deep ocean Ocean Exploration Facts NOAA Office of Ocean Exploration and Research oceanexplorer noaa gov Retrieved 2022 09 29 Paulus Eva 2021 Shedding Light on Deep Sea Biodiversity A Highly Vulnerable Habitat in the Face of Anthropogenic Change Frontiers in Marine Science 8 doi 10 3389 fmars 2021 667048 ISSN 2296 7745 Danovaro Roberto Corinaldesi Cinzia Dell Anno Antonio Snelgrove Paul V R 2017 06 05 The deep sea under global change Current Biology 27 11 R461 R465 doi 10 1016 j cub 2017 02 046 ISSN 0960 9822 PMID 28586679 S2CID 20785268 Brown Alastair Thatje Sven 2013 Explaining bathymetric diversity patterns in marine benthic invertebrates and demersal fishes physiological contributions to adaptation of life at depth Biological Reviews 89 2 406 426 doi 10 1111 brv 12061 ISSN 1464 7931 PMC 4158864 PMID 24118851 Higgs Nicholas D Gates Andrew R Jones Daniel O B 2014 05 07 Fish Food in the Deep Sea Revisiting the Role of Large Food Falls PLOS ONE 9 5 e96016 Bibcode 2014PLoSO 996016H doi 10 1371 journal pone 0096016 ISSN 1932 6203 PMC 4013046 PMID 24804731 US Department of Commerce National Oceanic and Atmospheric Administration What is marine snow oceanservice noaa gov Retrieved 2022 09 29 Horstman Mark 2003 07 09 Hope floats for lost deep sea explorer www abc net au Archived from the original on 2010 09 27 Retrieved 2021 05 07 a b Claus Detlefsen About the Marianas in Danish Ingenioren Geological Survey of Denmark and Greenland 2 November 2013 Accessed 2 November 2013 MarineBio 2018 06 17 The Deep Sea MarineBio Conservation Society Retrieved 2020 08 07 Nybakken James W Marine Biology An Ecological Approach Fifth Edition Benjamin Cummings 2001 p 136 141 Levin Lisa A Dayton Paul K 1 November 2009 Ecological theory and continental margins where shallow meets deep Trends in Ecology amp Evolution 24 11 606 617 doi 10 1016 j tree 2009 04 012 ISSN 0169 5347 PMID 19692143 Retrieved 29 September 2022 Gage John D Tyler Paul A 18 April 1991 Deep Sea Biology A Natural History of Organisms at the Deep Sea Floor Cambridge University Press ISBN 978 0 521 33431 0 Retrieved 29 September 2022 Smith Craig R De Leo Fabio C Bernardino Angelo F Sweetman Andrew K Arbizu Pedro Martinez 1 September 2008 Abyssal food limitation ecosystem structure and climate change Trends in Ecology amp Evolution 23 9 518 528 doi 10 1016 j tree 2008 05 002 ISSN 0169 5347 PMID 18584909 Retrieved 29 September 2022 Jamieson Alan J Fujii Toyonobu Mayor Daniel J Solan Martin Priede Imants G 1 March 2010 Hadal trenches the ecology of the deepest places on Earth Trends in Ecology amp Evolution 25 3 190 197 doi 10 1016 j tree 2009 09 009 ISSN 0169 5347 PMID 19846236 Retrieved 29 September 2022 Jamieson Alan J Stewart Heather A Weston Johanna N J Lahey Patrick Vescovo Victor L 2022 Hadal Biodiversity Habitats and Potential Chemosynthesis in the Java Trench Eastern Indian Ocean Frontiers in Marine Science 9 doi 10 3389 fmars 2022 856992 Robison Bruce H Reisenbichler Kim R Sherlock Rob E 2005 06 10 Giant Larvacean Houses Rapid Carbon Transport to the Deep Sea Floor Science 308 5728 1609 1611 Bibcode 2005Sci 308 1609R doi 10 1126 science 1109104 ISSN 0036 8075 PMID 15947183 S2CID 730130 Lupse Nik Cortesi Fabio Freese Marko Marohn Lasse Pohlmann Jan Dag Wysujack Klaus Hanel Reinhold Musilova Zuzana 9 December 2021 Visual Gene Expression Reveals a cone to rod Developmental Progression in Deep Sea Fishes Molecular Biology and Evolution 38 12 5664 5677 doi 10 1093 molbev msab281 PMC 8662630 PMID 34562090 Retrieved 29 September 2022 a b Warrant Eric J Locket N Adam August 2004 Vision in the deep sea Biological Reviews 79 3 671 712 doi 10 1017 S1464793103006420 ISSN 1469 185X PMID 15366767 S2CID 34907805 Collin Shaun P Chapuis Lucille Michiels Nico K 2019 Impacts of extreme depth on life in the deep sea Marine Extremes Routledge pp 197 216 doi 10 4324 9780429491023 12 ISBN 9780429491023 S2CID 133939260 Retrieved 29 September 2022 Hoving Henk Jan T Freitas Rui February 2022 Pelagic observations of the midwater scorpionfish Ectreposebastes imus Setarchidae suggests a role in trophic coupling between deep sea habitats Journal of Fish Biology 100 2 586 589 doi 10 1111 jfb 14944 PMID 34751439 S2CID 243863469 Retrieved 29 September 2022 Davis Alexander L Sutton Tracey T Kier William M Johnsen Sonke 10 June 2020 Evidence that eye facing photophores serve as a reference for counterillumination in an order of deep sea fishes Proceedings of the Royal Society B Biological Sciences 287 1928 20192918 doi 10 1098 rspb 2019 2918 PMC 7341941 PMID 32517614 Palmer Benjamin A Gur Dvir Weiner Steve Addadi Lia Oron Dan October 2018 The Organic Crystalline Materials of Vision Structure Function Considerations from the Nanometer to the Millimeter Scale Advanced Materials 30 41 1800006 doi 10 1002 adma 201800006 PMID 29888511 S2CID 47005095 Retrieved 29 September 2022 Hellinger Jens Jagers Peter Donner Marcel Sutt Franziska Mark Melanie D Senen Budiono Tollrian Ralph Herlitze Stefan 2017 02 08 De Abhijit ed The Flashlight Fish Anomalops katoptron Uses Bioluminescent Light to Detect Prey in the Dark PLOS ONE 12 2 e0170489 Bibcode 2017PLoSO 1270489H doi 10 1371 journal pone 0170489 ISSN 1932 6203 PMC 5298212 PMID 28178297 Cavallaro Mauro Guerrera Maria Cristina Abbate Francesco Levanti Maria Beatrice Laura Rosaria Ammendolia Giovanni Malara Danilo Stipa Maria Giulia Battaglia Pietro October 2021 Morphological ultrastructural and immunohistochemical study on the skin ventral photophores of Diaphus holti Taning 1918 Family Myctophidae Acta Zoologica 102 4 405 411 doi 10 1111 azo 12348 ISSN 0001 7272 S2CID 225368866 Marine Snow and Fecal Pellets Oceanus Magazine R N Gibson Harold CON Barnes R J A Atkinson Oceanography and Marine Biology An Annual Review 2007 Volume 41 Published by CRC Press 2004 ISBN 0 415 25463 9 ISBN 978 0 415 25463 2 Discover Natural History Museum www nhm ac uk Danovaro Roberto Antonio Dell Anno Cinzia Corinaldesi Mirko Magagnini Rachel Noble Christian Tamburini Markus Weinbauer 2008 08 28 Major viral impact on the functioning of benthic deep sea ecosystems Nature 454 7208 1084 1087 Bibcode 2008Natur 454 1084D doi 10 1038 nature07268 PMID 18756250 S2CID 4331430 London Convention International Maritime Organization Archived from the original on 3 March 2019 Retrieved 24 March 2020 Snelgrove Paul Grassle Fred 1995 01 01 What of the deep sea s future diversity Oceanus 38 2 Retrieved 24 March 2020 Zimmerman Alexander N Johnson Claudia C Bussberg Nicholas W Dalkilic Mehmet M April 2020 Stability and decline in deep sea coral biodiversity Gulf of Mexico and US West Atlantic Coral Reefs 39 2 345 359 doi 10 1007 s00338 020 01896 9 S2CID 210975434 Ruttimann Jacqueline 2006 08 31 Oceanography sick seas Nature 442 7106 978 80 Bibcode 2006Natur 442 978R doi 10 1038 442978a PMID 16943816 S2CID 4332965 Koslow Tony 2011 11 20 The silent deep the discovery ecology amp conservation of the deep sea Pacific Ecologist 20 Drazen Jeffery Leitner Astrid Morningstar Sage Marcon Yann Greinert Jens Purser Auntun 2019 01 01 Observations of deep sea fishes and mobile scavengers from the abyssal DISCOL experimental mining area Biogeosciences 16 16 3133 3146 Bibcode 2019BGeo 16 3133D doi 10 5194 bg 16 3133 2019 ProQuest 2276806480 Dover Cindy Van 2000 03 26 The Ecology of Deep Sea Hydrothermal Vents ISBN 978 0 691 04929 8 Martin William Baross John Kelley Deborah Russell Michael J November 2008 Hydrothermal vents and the origin of life Nature Reviews Microbiology 6 11 805 814 doi 10 1038 nrmicro1991 ISSN 1740 1534 PMID 18820700 S2CID 1709272 Cavanaugh F J Stewart and C M 2006 Symbiosis of Thioautotrophic Bacteria with Riftia pachyptila EndNote Click Progress in Molecular and Subcellular Biology 41 197 225 doi 10 1007 3 540 28221 1 10 PMID 16623395 Retrieved 2022 09 29 HW Jannasch 1985 The Chemosynthetic Support of Life and the Microbial Diversity at Deep Sea Hydrothermal Vents Proceedings of the Royal Society of London Series B Biological Sciences Vol 225 No 1240 Sep 23 1985 pp 277 297 a b Chapter Twelve Adaptations to the Deep Sea Biochemical Adaptation Princeton University Press pp 450 495 1984 12 31 doi 10 1515 9781400855414 450 ISBN 978 1 4008 5541 4 retrieved 2020 11 02 a b c d Wang Kun Shen Yanjun Yang Yongzhi Gan Xiaoni Liu Guichun Hu Kuang Li Yongxin Gao Zhaoming Zhu Li Yan Guoyong He Lisheng May 2019 Morphology and genome of a snailfish from the Mariana Trench provide insights into deep sea adaptation Nature Ecology amp Evolution 3 5 823 833 doi 10 1038 s41559 019 0864 8 ISSN 2397 334X PMID 30988486 a b c Wakai Nobuhiko Takemura Kazuhiro Morita Takami Kitao Akio 2014 01 20 Mechanism of Deep Sea Fish a Actin Pressure Tolerance Investigated by Molecular Dynamics Simulations PLOS ONE 9 1 e85852 Bibcode 2014PLoSO 985852W doi 10 1371 journal pone 0085852 ISSN 1932 6203 PMC 3896411 PMID 24465747 Hata Hiroaki Nishiyama Masayoshi Kitao Akio 2020 02 01 Molecular dynamics simulation of proteins under high pressure Structure function and thermodynamics Biochimica et Biophysica Acta BBA General Subjects Novel measurement techniques for visualizing live protein molecules 1864 2 129395 doi 10 1016 j bbagen 2019 07 004 ISSN 0304 4165 PMID 31302180 S2CID 196613044 Yancey Paul H Speers Roesch Ben Atchinson Sheila Reist James D Majewski Andrew R Treberg Jason R 2017 11 27 Osmolyte Adjustments as a Pressure Adaptation in Deep Sea Chondrichthyan Fishes An Intraspecific Test in Arctic Skates Amblyraja hyperborea along a Depth Gradient Physiological and Biochemical Zoology 91 2 788 796 doi 10 1086 696157 ISSN 1522 2152 PMID 29315031 S2CID 26847773 Tim Flannery Where Wonders Await Us New York Review of Books December 2007 a b Jamieson Alan J Singleman Glenn Linley Thomas D Casey Susan 2020 12 21 Fear and loathing of the deep ocean why don t people care about the deep sea ICES Journal of Marine Science 78 3 797 809 doi 10 1093 icesjms fsaa234 ISSN 1054 3139 Briand F Snelgrove P 2003 Mare Incognitum An overview CIESM Workshop Monographs 23 5 27 1 External links Edit Scholia has a topic profile for Deep sea Deep Sea Foraminifera Deep Sea Foraminifera from 4400 meters depth Antarctica an image gallery and description of hundreds of specimens Deep Ocean Exploration on the Smithsonian Ocean Portal Deep Sea Creatures Facts and images from the deepest parts of the ocean How Deep Is The Ocean Archived 2016 06 15 at the Wayback Machine Facts and infographic on ocean depth Retrieved from https en wikipedia org w index php title Deep sea amp oldid 1136096368, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.