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Deep-sea fish

August 26, 2023

Deep-sea fish are fish that live in the darkness below the sunlit surface waters, that is below the epipelagic or photic zone of the sea. The lanternfish is, by far, the most common deep-sea fish. Other deep sea fishes include the flashlight fish, cookiecutter shark, bristlemouths, anglerfish, viperfish, and some species of eelpout.

Humpback anglerfish

Only about 2% of known marine species inhabit the pelagic environment. This means that they live in the water column as opposed to the benthic organisms that live in or on the sea floor.[1] Deep-sea organisms generally inhabit bathypelagic (1000–4000 m deep) and abyssopelagic (4000–6000 m deep) zones. However, characteristics of deep-sea organisms, such as bioluminescence can be seen in the mesopelagic (200–1000 m deep) zone as well. The mesopelagic zone is the disphotic zone, meaning light there is minimal but still measurable. The oxygen minimum layer exists somewhere between a depth of 700 m and 1000 m deep depending on the place in the ocean. This area is also where nutrients are most abundant. The bathypelagic and abyssopelagic zones are aphotic, meaning that no light penetrates this area of the ocean. These zones make up about 75% of the inhabitable ocean space.[2]

The epipelagic zone (0–200 m) is the area where light penetrates the water and photosynthesis occurs. This is also known as the photic zone. Because this typically extends only a few hundred meters below the water, the deep sea, about 90% of the ocean volume, is in darkness. The deep sea is also an extremely hostile environment, with temperatures that rarely exceed 3 °C (37 °F) and fall as low as −1.8 °C (29 °F) (with the exception of hydrothermal vent ecosystems that can exceed 350 °C, or 662 °F), low oxygen levels, and pressures between 20 and 1000 atm (between 2 and 100 MPa).[3]

Environment Edit

 
Scale diagram of the layers of the pelagic zone

In the deep ocean, the waters extend far below the epipelagic zone, and support very different types of pelagic fishes adapted to living in these deeper zones.[4] In deep water, marine snow is a continuous shower of mostly organic detritus falling from the upper layers of the water column. Its origin lies in activities within the productive photic zone. Marine snow includes dead or dying plankton, protists (diatoms), fecal matter, sand, soot and other inorganic dust. The "snowflakes" grow over time and may reach several centimetres in diameter, travelling for weeks before reaching the ocean floor. However, most organic components of marine snow are consumed by microbes, zooplankton and other filter-feeding animals within the first 1000 m of their journey, that is, within the epipelagic zone. In this way marine snow may be considered the foundation of deep-sea mesopelagic and benthic ecosystems: As sunlight cannot reach them, deep-sea organisms rely heavily on marine snow as an energy source. Since there is no light in the deep sea (aphotic), there is a lack of primary producers. Therefore, most organisms in the bathypelagic rely on the marine snow from regions higher in the vertical column.

Some deep-sea pelagic groups, such as the lanternfish, ridgehead, marine hatchetfish, and lightfish families are sometimes termed pseudoceanic because, rather than having an even distribution in open water, they occur in significantly higher abundances around structural oases, notably seamounts and over continental slopes. The phenomenon is explained by the likewise abundance of prey species which are also attracted to the structures.

Hydrostatic pressure increases by 1 atm for every 10 m in depth.[5] Deep-sea organisms have the same pressure within their bodies as is exerted on them from the outside, so they are not crushed by the extreme pressure. Their high internal pressure, however, results in the reduced fluidity of their membranes because molecules are squeezed together. Fluidity in cell membranes increases efficiency of biological functions, most importantly the production of proteins, so organisms have adapted to this circumstance by increasing the proportion of unsaturated fatty acids in the lipids of the cell membranes.[6] In addition to differences in internal pressure, these organisms have developed a different balance between their metabolic reactions from those organisms that live in the epipelagic zone. David Wharton, author of Life at the Limits: Organisms in Extreme Environments, notes "Biochemical reactions are accompanied by changes in volume. If a reaction results in an increase in volume, it will be inhibited by pressure, whereas, if it is associated with a decrease in volume, it will be enhanced".[7] This means that their metabolic processes must ultimately decrease the volume of the organism to some degree.

 
Humans seldom encounter frilled sharks alive, so they pose little danger (though scientists have accidentally cut themselves examining their teeth).[8]

Most fish that have evolved in this harsh environment are not capable of surviving in laboratory conditions, and attempts to keep them in captivity have led to their deaths. Deep-sea organisms contain gas-filled spaces (vacuoles). Gas is compressed under high pressure and expands under low pressure. Because of this, these organisms have been known to blow up if they come to the surface.[7]

Characteristics Edit

 
An annotated diagram of the basic external features of an abyssal grenadier and standard length measurements.
Rhinochimera atlantica
 
Gigantactis is a deep-sea fish with a dorsal fin whose first filament has become very long and is tipped with a bioluminescent photophore lure.
 
Pelican eel
 
Bigeye tuna cruise the epipelagic zone at night and the mesopelagic zone during the day

The fish of the deep-sea have evolved various adaptations to survive in this region. Since many of these fish live in regions where there is no natural illumination, they cannot rely solely on their eyesight for locating prey and mates and avoiding predators; deep-sea fish have evolved appropriately to the extreme sub-photic region in which they live. Many of these organisms are blind and rely on their other senses, such as sensitivities to changes in local pressure and smell, to catch their food and avoid being caught. Those that aren't blind have large and sensitive eyes that can use bioluminescent light. These eyes can be as much as 100 times more sensitive to light than human eyes. Rhodopsin (Rh1) is a protein found in the eye’s rod cells that helps animals see in dim light. While most vertebrates usually have one Rh1 opsin gene, some deep sea fish have several Rh1 genes, and one species, the silver spinyfin (Diretmus argenteus), has 38.[9] This proliferation of Rh1 genes may help deep sea fish to see in the depths of the ocean. Also, to avoid predation, many species are dark to blend in with their environment.[10]

Many deep-sea fish are bioluminescent, with extremely large eyes adapted to the dark. Bioluminescent organisms are capable of producing light biologically through the agitation of molecules of luciferin, which then produce light. This process must be done in the presence of oxygen. These organisms are common in the mesopelagic region and below (200 m and below). More than 50% of deep-sea fish, as well as some species of shrimp and squid, are capable of bioluminescence. About 80% of these organisms have photophores – light producing glandular cells that contain luminous bacteria bordered by dark colourings. Some of these photophores contain lenses, much like those in the eyes of humans, which can intensify or lessen the emanation of light. The ability to produce light only requires 1% of the organism's energy and has many purposes: It is used to search for food and attract prey, like the anglerfish; claim territory through patrol; communicate and find a mate, and distract or temporarily blind predators to escape. Also, in the mesopelagic where some light still penetrates, some organisms camouflage themselves from predators below them by illuminating their bellies to match the colour and intensity of light from above so that no shadow is cast. This tactic is known as counter-illumination.[11]

The lifecycle of deep-sea fish can be exclusively deep water although some species are born in shallower water and sink upon maturation. Regardless of the depth where eggs and larvae reside, they are typically pelagic. This planktonic — drifting — lifestyle requires neutral buoyancy. In order to maintain this, the eggs and larvae often contain oil droplets in their plasma.[12] When these organisms are in their fully matured state they need other adaptations to maintain their positions in the water column. In general, water's density causes upthrust — the aspect of buoyancy that makes organisms float. To counteract this, the density of an organism must be greater than that of the surrounding water. Most animal tissues are denser than water, so they must find an equilibrium to make them float.[13] Many organisms develop swim bladders (gas cavities) to stay afloat, but because of the high pressure of their environment, deep-sea fishes usually do not have this organ. Instead they exhibit structures similar to hydrofoils in order to provide hydrodynamic lift. It has also been found that the deeper a fish lives, the more jelly-like its flesh and the more minimal its bone structure. They reduce their tissue density through high fat content, reduction of skeletal weight — accomplished through reductions of size, thickness and mineral content — and water accumulation[14] makes them slower and less agile than surface fish.

Due to the poor level of photosynthetic light reaching deep-sea environments, most fish need to rely on organic matter sinking from higher levels, or, in rare cases, hydrothermal vents for nutrients. This makes the deep-sea much poorer in productivity than shallower regions. Also, animals in the pelagic environment are sparse and food doesn't come along frequently. Because of this, organisms need adaptations that allow them to survive. Some have long feelers to help them locate prey or attract mates in the pitch black of the deep ocean. The deep-sea angler fish in particular has a long fishing-rod-like adaptation protruding from its face, on the end of which is a bioluminescent piece of skin that wriggles like a worm to lure its prey. Some must consume other fish that are the same size or larger than them and they need adaptations to help digest them efficiently. Great sharp teeth, hinged jaws, disproportionately large mouths, and expandable bodies are a few of the characteristics that deep-sea fishes have for this purpose.[10] The gulper eel is one example of an organism that displays these characteristics.

Fish in the different pelagic and deep water benthic zones are physically structured, and behave in ways, that differ markedly from each other. Groups of coexisting species within each zone all seem to operate in similar ways, such as the small mesopelagic vertically migrating plankton-feeders, the bathypelagic anglerfishes, and the deep water benthic rattails.[15]

Ray finned species, with spiny fins, are rare among deep sea fishes, which suggests that deep sea fish are ancient and so well adapted to their environment that invasions by more modern fishes have been unsuccessful.[16] The few ray fins that do exist are mainly in the Beryciformes and Lampriformes, which are also ancient forms. Most deep sea pelagic fishes belong to their own orders, suggesting a long evolution in deep sea environments. In contrast, deep water benthic species, are in orders that include many related shallow water fishes.[17]

Mesopelagic fish Edit

Mesopelagic fish
 
Most mesopelagic fishes are small filter feeders which ascend at night to feed in the nutrient rich waters of the epipelagic zone. During the day, they return to the dark, cold, oxygen deficient waters of the mesopelagic where they are relatively safe from predators. Lanternfish account for as much as 65% of all deep sea fish biomass and are largely responsible for the deep scattering layer of the world's oceans.
 
Most of the rest of the mesopelagic fishes are ambush predators, like this sabertooth fish which uses its telescopic, upward-pointing eyes to pick out prey silhouetted against the gloom above. Their recurved teeth prevent a captured fish from backing out.
 
The Antarctic toothfish have large, upward looking eyes, adapted to detecting the silhouettes of prey fish[20]
 
The barreleye has barrel-shaped, tubular eyes which are generally directed upwards but can be swivelled forward[21]
 
The telescopefish has large, forward-pointing telescoping eyes with large lenses[22]

Below the epipelagic zone, conditions change rapidly. Between 200 m and about 1000 m, light continues to fade until there is almost none. Temperatures fall through a thermocline to temperatures between 3.9 °C (39 °F) and 7.8 °C (46 °F). This is the twilight or mesopelagic zone. Pressure continues to increase, at the rate of one atm every 10 m, while nutrient concentrations fall, along with dissolved oxygen and the rate at which the water circulates.[4]

Sonar operators, using the newly developed sonar technology during World War II, were puzzled by what appeared to be a false sea floor 300–500 m deep at day, and less deep at night. This turned out to be due to millions of marine organisms, most particularly small mesopelagic fish, with swim bladders that reflected the sonar. These organisms migrate up into shallower water at dusk to feed on plankton. The layer is deeper when the moon is out, and can become shallower when clouds pass over the moon. This phenomenon has come to be known as the deep scattering layer.[23]

Most mesopelagic fish make daily vertical migrations, moving at night into the epipelagic zone, often following similar migrations of zooplankton, and returning to the depths for safety during the day.[4][24] These vertical migrations often occur over large vertical distances, and are undertaken with the assistance of a swim bladder.[16] The swim bladder is inflated when the fish wants to move up, and, given the high pressures in the messoplegic zone, this requires significant energy. As the fish ascends, the pressure in the swim bladder must adjust to prevent it from bursting. When the fish wants to return to the depths, the swim bladder is deflated.[25] Some mesopelagic fishes make daily migrations through the thermocline, where the temperature changes between 50 °F (10 °C) and 69 °F (20 °C), thus displaying considerable tolerances for temperature change.[26]

These fish have muscular bodies, ossified bones, scales, well developed gills and central nervous systems, and large hearts and kidneys. Mesopelagic plankton feeders have small mouths with fine gill rakers, while the piscivores have larger mouths and coarser gill rakers.[4]

Mesopelagic fish are adapted for an active life under low light conditions. Most of them are visual predators with large eyes. Some of the deeper water fish have tubular eyes with big lenses and only rod cells that look upwards. These give binocular vision and great sensitivity to small light signals.[4] This adaptation gives improved terminal vision at the expense of lateral vision, and allows the predator to pick out squid, cuttlefish, and smaller fish that are silhouetted against the gloom above them.

Mesopelagic fish usually lack defensive spines, and use colour to camouflage themselves from other fish. Ambush predators are dark, black or red. Since the longer, red, wavelengths of light do not reach the deep sea, red effectively functions the same as black. Migratory forms use countershaded silvery colours. On their bellies, they often display photophores producing low grade light. For a predator from below, looking upwards, this bioluminescence camouflages the silhouette of the fish. However, some of these predators have yellow lenses that filter the (red deficient) ambient light, leaving the bioluminescence visible.[27]

The brownsnout spookfish, a species of barreleye, is the only vertebrate known to employ a mirror, as opposed to a lens, to focus an image in its eyes.[28][29]

Sampling by deep trawling indicates that lanternfish account for as much as 65% of all deep-sea fish biomass.[30] Indeed, lanternfish are among the most widely distributed, populous, and diverse of all vertebrates, playing an important ecological role as prey for larger organisms. The estimated global biomass of lanternfish is 550–660 million tonnes, several times the entire world fisheries catch. Lanternfish also account for much of the biomass responsible for the deep scattering layer of the world's oceans.[31]

Bigeye tuna are an epipelagic/mesopelagic species that eats other fish. Satellite tagging has shown that bigeye tuna often spend prolonged periods cruising deep below the surface during the daytime, sometimes making dives as deep as 500 m. These movements are thought to be in response to the vertical migrations of prey organisms in the deep scattering layer.

  •  

    The stoplight loosejaw has a lower jaw one-quarter as long as its body. The jaw has no floor and is attached only by a hinge and a modified tongue bone. Large fang-like teeth in the front are followed by many small barbed teeth.[32][33]

  •  

    The stoplight loosejaw is also one of the few fishes that produce red bioluminescence. As most of their prey cannot perceive red light, this allows it to hunt with an essentially invisible beam of light.[32]

  •  

    Long-snouted lancetfish. Lancetfish are ambush predators which spend all their time in the mesopelagic zone. They are among the largest mesopelagic fishes (up to 2 m).[34]

  •  

    The daggertooth paralyses other mesopelagic fish when it bites them with its dagger-like teeth[35]

Bathypelagic fish Edit

Bathypelagic fish
 
The humpback anglerfish is a bathypelagic ambush predator, which attracts prey with a bioluminescent lure. It can ingest prey larger than itself, which it swallows with an inrush of water when it opens its mouth.[36]
 
Many bristlemouth species, such as the "spark anglemouth" above,[37] are also bathypelagic ambush predators which can swallow prey larger than themselves. They are among the most abundant of all vertebrate families.[37]
 
Young, red flabby whalefish make nightly vertical migrations into the lower mesopelagic zone to feed on copepods. When males make the transition to adults, they develop a massive liver, and then their jaws fuse shut. They no longer eat, but continue to metabolise the energy stored in their liver.[38][39]
 
The Sloane's viperfish can make nightly migrations from bathypelagic depths to near surface waters.[40]
 
The widespread fangtooth has the largest teeth of any fish, proportionate to body size.[41] Despite their ferocious appearance, bathypelagic fish are usually weakly muscled and too small to represent any threat to humans.

Below the mesopelagic zone it is pitch dark. This is the midnight (or bathypelagic zone), extending from 1000 m to the bottom deep water benthic zone. If the water is exceptionally deep, the pelagic zone below 4000 m is sometimes called the lower midnight (or abyssopelagic zone). Temperatures in this zone range from 1 to 4 degrees celsius and is completely aphotic.

Conditions are somewhat uniform throughout these zones; the darkness is complete, the pressure is crushing, and temperatures, nutrients and dissolved oxygen levels are all low.[4]

Bathypelagic fish have special adaptations to cope with these conditions – they have slow metabolisms and unspecialized diets, being willing to eat anything that comes along. They prefer to sit and wait for food rather than waste energy searching for it. The behaviour of bathypelagic fish can be contrasted with the behaviour of mesopelagic fish. Mesopelagic fish are often highly mobile, whereas bathypelagic fish are almost all lie-in-wait predators, normally expending little energy in movement.[42]

The dominant bathypelagic fishes are small bristlemouth and anglerfish; fangtooth, viperfish, daggertooth and barracudina are also common. These fishes are small, many about 10 cm long, and not many longer than 25 cm. They spend most of their time waiting patiently in the water column for prey to appear or to be lured by their phosphors. What little energy is available in the bathypelagic zone filters from above in the form of detritus, faecal material, and the occasional invertebrate or mesopelagic fish.[42] About 20 per cent of the food that has its origins in the epipelagic zone falls down to the mesopelagic zone,[23] but only about 5 per cent filters down to the bathypelagic zone.[36]

Bathypelagic fish are sedentary, adapted to outputting minimum energy in a habitat with very little food or available energy, not even sunlight, only bioluminescence. Their bodies are elongated with weak, watery muscles and skeletal structures. Since so much of the fish is water, they are not compressed by the great pressures at these depths. They often have extensible, hinged jaws with recurved teeth. They are slimy, without scales. The central nervous system is confined to the lateral line and olfactory systems, the eyes are small and may not function, and gills, kidneys and hearts, and swim bladders are small or missing.[36][43]

These are the same features found in fish larvae, which suggests that during their evolution, bathypelagic fish have acquired these features through neoteny. As with larvae, these features allow the fish to remain suspended in the water with little expenditure of energy.[44]

Despite their ferocious appearance, these beasts of the deep are mostly miniature fish with weak muscles, and are too small to represent any threat to humans.

The swim bladders of deep sea fish are either absent or scarcely operational, and bathypelagic fish do not normally undertake vertical migrations. Filling bladders at such great pressures incurs huge energy costs. Some deep sea fishes have swim bladders which function while they are young and inhabit the upper epipelagic zone, but they wither or fill with fat when the fish move down to their adult habitat.[45]

The most important sensory systems are usually the inner ear, which responds to sound, and the lateral line, which responds to changes in water pressure. The olfactory system can also be important for males who find females by smell.[46] Bathypelagic fish are black, or sometimes red, with few photophores. When photophores are used, it is usually to entice prey or attract a mate. Because food is so scarce, bathypelagic predators are not selective in their feeding habits, but grab whatever comes close enough. They accomplish this by having a large mouth with sharp teeth for grabbing large prey and overlapping gill rakers which prevent small prey that have been swallowed from escaping.[43]

It is not easy finding a mate in this zone. Some species depend on bioluminescence, where bioluminescent patterns are unique to specific species. Others are hermaphrodites, which doubles their chances of producing both eggs and sperm when an encounter occurs.[36] The female anglerfish releases pheromones to attract tiny males. When a male finds her, he bites on to her and never lets go. When a male of the anglerfish species Haplophryne mollis bites into the skin of a female, he releases an enzyme that digests the skin of his mouth and her body, fusing the pair to the point where the two circulatory systems join up. The male then atrophies into nothing more than a pair of gonads. This extreme sexual dimorphism ensures that, when the female is ready to spawn, she has a mate immediately available.[47]

Many forms other than fish live in the bathypelagic zone, such as squid, large whales, octopuses, sponges, brachiopods, sea stars, and echinoids, but this zone is difficult for fish to live in.

  •  

    The pelican eel uses its large mouth like a net by opening its jaws and swimming towards prey. It has a luminescent organ at the tip of its tail to attract prey.

  •  

    The black swallower, with its distensible stomach, is notable for its ability to swallow, whole, bony fishes ten times its mass.[48][49]

  •  

    Female Haplophryne mollis anglerfish trailing attached males which have atrophied into a pair of gonads, for use when the female is ready to spawn.

Adaptation to high pressure Edit

As a fish moves deeper into the sea, the weight of the water overhead exerts increasing hydrostatic pressure on the fish. This increased pressure amounts to about one atm for every 10 m in depth. For a fish at the bottom of the bathypelagic zone, this pressure amounts to about 400 atm (nearly 6000 pounds per square inch).[50]

Deep sea organisms possess adaptations at cellular and physiological levels that allow them to survive in environments of great pressure. Not having these adaptations limits the depths at which shallow-water species can operate. High levels of external pressure affects how metabolic processes and biochemical reactions proceed. The equilibrium of many chemical reactions is disturbed by pressure, and pressure can inhibit processes which result in an increase in volume. Water, a key component in many biological processes, is very susceptible to volume changes, mainly because constituents of cellular fluid have an effect on water structure. Thus, enzymatic reactions that induce changes in water organization effectively change the system's volume.[51] Proteins responsible for catalyzing reactions are typically held together by weak bonds and the reactions usually involve volume increases.[52]

Species that can tolerate these depths have evolved changes in their protein structure and reaction criteria to withstand pressure, in order to perform reactions in these conditions. In high pressure environments, bilayer cellular membranes experience a loss of fluidity. Deep-sea cellular membranes favor phospholipid bilayers with a higher proportion of unsaturated fatty acids, which induce a higher fluidity than their sea-level counterparts.

 
The rattail Coryphaenoides armatus (abyssal grenadier) on the Davidson Seamount at 2253 m depth.

Deep sea species exhibit lower changes of entropy and enthalpy compared to surface level organisms, since a high pressure and low temperature environment favors negative enthalpy changes and reduced dependence on entropy-driven reactions. From a structural standpoint, globular proteins of deep sea fish due to the tertiary structure of G-actin are relatively rigid compared to those of surface level fish.[51] The fact that proteins in deep sea fish are structurally different from surface fish is apparent from the observation that actin from the muscle fibers of deep sea fish are extremely heat resistant; an observation similar to what is found in lizards. These proteins are structurally strengthened by modification of the bonds in the tertiary structure of the protein which also happens to induce high levels of thermal stability.[52] Proteins are structurally strengthened to resist pressure by modification of bonds in the tertiary structure.[52] Therefore, high levels of hydrostatic pressure, similar to high body temperatures of thermophilic desert reptiles, favor rigid protein structures.

Na+/K+ -ATPase is a lipoprotein enzyme that plays a prominent role in osmoregulation and is heavily influenced by hydrostatic pressure. The inhibition of Na+/K+ -ATPase is due to increased compression due to pressure. The rate-limiting step of the Na+/K+ -ATPase reaction induces an expansion in the bilayer surrounding the protein, and therefore an increase in volume. An increase in volume makes Na+/K+ -ATPase reactivity susceptible to higher pressures. Even though the Na+/K+ -ATPase activity per gram of gill tissue is lower for deep sea fishes, the Na+/K+ -ATPases of deep sea fishes exhibit a much higher tolerance of hydrostatic pressure compared to their shallow-water counterparts. This is exemplified between the species C. acrolepis (around 2000 m deep) and its hadalpelagic counterpart C. armatus (around 4000 m deep), where the Na+/K+ -ATPases of C. armatus are much less sensitive to pressure. This resistance to pressure can be explained by adaptations in the protein and lipid moieties of Na+/K+ -ATPase.[53]

Lanternfish Edit

Main article: Lanternfish
 
Lantern fish

Sampling via deep trawling indicates that lanternfish account for as much as 65% of all deep-sea fish biomass.[30] Indeed, lanternfish are among the most widely distributed, populous, and diverse of all vertebrates, playing an important ecological role as prey for larger organisms. With an estimated global biomass of 550–660 million metric tons, several times the entire world fisheries catch, lanternfish also account for much of the biomass responsible for the deep scattering layer of the world's oceans. In the Southern Ocean, Myctophids provide an alternative food resource to krill for predators such as squid and the king penguin. Although these fish are plentiful and prolific, currently only a few commercial lanternfish fisheries exist: these include limited operations off South Africa, in the sub-Antarctic, and in the Gulf of Oman.

Endangered species Edit

A 2006 study by Canadian scientists has found five species of deep-sea fish – blue hake, spiny eel – to be on the verge of extinction due to the shift of commercial fishing from continental shelves to the slopes of the continental shelves, down to depths of 1600 m. The slow reproduction of these fish – they reach sexual maturity at about the same age as human beings – is one of the main reasons that they cannot recover from the excessive fishing.[54]

See also Edit

Citations Edit

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  3. ^ Trujillo & Thurman 2011, pp. 457, 460.
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  5. ^ Wharton 2002, pp. 198.
  6. ^ Wharton 2002, pp. 199, 201–202.
  7. ^ a b Wharton 2002, pp. 199.
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  9. ^ Musilova, Zuzana; Cortesi, Fabio; Matschiner, Michael; Davies, Wayne; Patel, Jagdish; Stieb, Sara; de Busserolles, Fanny; Malmstrøm, Martin; Tørresen, Ole; Brown, Celeste; Mountford, Jessica; Hanel, Reinhold; Stenkamp, Deborah; Jakobsen, Kjetill; Carleton, Karen; Jentoft, Sissel; Marshall, Justin; Salzburger, Walter (2019). "Vision using multiple distinct rod opsins in deep-sea fishes". Science. American Association for the Advancement of Science. 364 (6440): 588–592. Bibcode:2019Sci...364..588M. doi:10.1126/science.aav4632. PMC 6628886. PMID 31073066.
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  42. ^ a b Moyle & Cech 2004, pp. 594.
  43. ^ a b Moyle & Cech 2004, pp. 587.
  44. ^ Marshall (1984) "Progenetic tendencies in deep-sea fishes", pp. 91-101 in Potts GW and Wootton RJ (eds.) (1984) Fish reproduction: strategies and tactics Fisheries Society of the British Isles.
  45. ^ Horn MH (1970). "The swim bladder as a juvenile organ in stromateoid fishes". Breviora. 359: 1–9.
  46. ^ Jumper GY, Bair RC (1991). "Location by olfaction: a model and application to the mating problem in the deep-sea Hatchetfish Argyropelecus hemigymnus". The American Naturalist. 138 (6): 1431–58. doi:10.1086/285295. JSTOR 2462555. S2CID 84386858.
  47. ^ Theodore W. Pietsch (1975). "Precocious sexual parasitism in the deep sea ceratioid anglerfish, Cryptopsaras couesi Gill". Nature. 256 (5512): 38–40. Bibcode:1975Natur.256...38P. doi:10.1038/256038a0. S2CID 4226567.
  48. ^ Jordan, D.S. (1905). A Guide to the Study of Fishes. H. Holt and Company.
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References Edit

  • Hochachka, Peter W.; Somero, George N. (1984). Biochemical Adaptation. Princeton University Press. JSTOR j.ctt7zv9d4.
  • Moyle, P. B.; Cech, J. J. (2004). Fishes, An Introduction to Ichthyology (5 ed.). Benjamin Cummings. ISBN 9780131008472.
  • Paxton, J. R.; Eschmeyer, W. N., eds. (1998). Encyclopedia of Fishes. San Diego: Academic Press. ISBN 0125476655.
  • Priede, Imants G., ed. (2017). "Adaptations to the Deep Sea". Deep-Sea Fishes: Biology, Diversity, Ecology and Fisheries. Cambridge: Cambridge University Press. pp. 87–138. doi:10.1017/9781316018330.004. ISBN 9781316018330.
  • Randall, David J.; Farrell, Anthony Peter (1997). Deep-sea Fishes. San Diego: Academic. ISBN 9780123504401.
  • Trujillo, Alan P.; Thurman, Harold V. (2011). Essentials of Oceanography (10 ed.). Boston: Prentice Hall. ISBN 9780321668127.
  • Wharton, David (2002). Life at the Limits: Organisms in Extreme Environments. Cambridge: Cambridge University Press. p. 198. ISBN 9780521782128.

Further reading Edit

  • Gordon J. D. M. (2001) "Deep-sea fishes" In: John H. Steele, Steve A. Thorpe, Karl K. Turekian (eds.) Elements of Physical Oceanography, pages 227–233, Academic Press. ISBN 9780123757241.
  • Hoar W. S., Randall D. J. and Farrell A. P. (eds.) (1997) Deep-Sea Fishes, Academic Press. ISBN 9780080585406.
  • Shotton, Ross (1995) "Deepwater fisheries" In: Review of the state of world marine fishery resources, FAO Fisheries technical paper 457, FAO, Rome. ISBN 92-5-105267-0.
  • Tandstad M., Shotton R., Sanders J. and Carocci F. (2011) "Deep-sea Fisheries" In: Review of the state of world marine fishery resources, pages 265–278, FAO Fisheries technical paper 569, FAO, Rome. ISBN 978-92-5-107023-9.

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  Creatures and Fish of the Deep Ocean – National Geographic documentary

August 26, 2023
deep, fish, fish, that, live, darkness, below, sunlit, surface, waters, that, below, epipelagic, photic, zone, lanternfish, most, common, deep, fish, other, deep, fishes, include, flashlight, fish, cookiecutter, shark, bristlemouths, anglerfish, viperfish, som. Deep sea fish are fish that live in the darkness below the sunlit surface waters that is below the epipelagic or photic zone of the sea The lanternfish is by far the most common deep sea fish Other deep sea fishes include the flashlight fish cookiecutter shark bristlemouths anglerfish viperfish and some species of eelpout Humpback anglerfishOnly about 2 of known marine species inhabit the pelagic environment This means that they live in the water column as opposed to the benthic organisms that live in or on the sea floor 1 Deep sea organisms generally inhabit bathypelagic 1000 4000 m deep and abyssopelagic 4000 6000 m deep zones However characteristics of deep sea organisms such as bioluminescence can be seen in the mesopelagic 200 1000 m deep zone as well The mesopelagic zone is the disphotic zone meaning light there is minimal but still measurable The oxygen minimum layer exists somewhere between a depth of 700 m and 1000 m deep depending on the place in the ocean This area is also where nutrients are most abundant The bathypelagic and abyssopelagic zones are aphotic meaning that no light penetrates this area of the ocean These zones make up about 75 of the inhabitable ocean space 2 The epipelagic zone 0 200 m is the area where light penetrates the water and photosynthesis occurs This is also known as the photic zone Because this typically extends only a few hundred meters below the water the deep sea about 90 of the ocean volume is in darkness The deep sea is also an extremely hostile environment with temperatures that rarely exceed 3 C 37 F and fall as low as 1 8 C 29 F with the exception of hydrothermal vent ecosystems that can exceed 350 C or 662 F low oxygen levels and pressures between 20 and 1000 atm between 2 and 100 MPa 3 Contents 1 Environment 2 Characteristics 3 Mesopelagic fish 4 Bathypelagic fish 5 Adaptation to high pressure 6 Lanternfish 7 Endangered species 8 See also 9 Citations 10 References 11 Further reading 12 External linksEnvironment Edit Scale diagram of the layers of the pelagic zoneIn the deep ocean the waters extend far below the epipelagic zone and support very different types of pelagic fishes adapted to living in these deeper zones 4 In deep water marine snow is a continuous shower of mostly organic detritus falling from the upper layers of the water column Its origin lies in activities within the productive photic zone Marine snow includes dead or dying plankton protists diatoms fecal matter sand soot and other inorganic dust The snowflakes grow over time and may reach several centimetres in diameter travelling for weeks before reaching the ocean floor However most organic components of marine snow are consumed by microbes zooplankton and other filter feeding animals within the first 1000 m of their journey that is within the epipelagic zone In this way marine snow may be considered the foundation of deep sea mesopelagic and benthic ecosystems As sunlight cannot reach them deep sea organisms rely heavily on marine snow as an energy source Since there is no light in the deep sea aphotic there is a lack of primary producers Therefore most organisms in the bathypelagic rely on the marine snow from regions higher in the vertical column Some deep sea pelagic groups such as the lanternfish ridgehead marine hatchetfish and lightfish families are sometimes termed pseudoceanic because rather than having an even distribution in open water they occur in significantly higher abundances around structural oases notably seamounts and over continental slopes The phenomenon is explained by the likewise abundance of prey species which are also attracted to the structures Hydrostatic pressure increases by 1 atm for every 10 m in depth 5 Deep sea organisms have the same pressure within their bodies as is exerted on them from the outside so they are not crushed by the extreme pressure Their high internal pressure however results in the reduced fluidity of their membranes because molecules are squeezed together Fluidity in cell membranes increases efficiency of biological functions most importantly the production of proteins so organisms have adapted to this circumstance by increasing the proportion of unsaturated fatty acids in the lipids of the cell membranes 6 In addition to differences in internal pressure these organisms have developed a different balance between their metabolic reactions from those organisms that live in the epipelagic zone David Wharton author of Life at the Limits Organisms in Extreme Environments notes Biochemical reactions are accompanied by changes in volume If a reaction results in an increase in volume it will be inhibited by pressure whereas if it is associated with a decrease in volume it will be enhanced 7 This means that their metabolic processes must ultimately decrease the volume of the organism to some degree Humans seldom encounter frilled sharks alive so they pose little danger though scientists have accidentally cut themselves examining their teeth 8 Most fish that have evolved in this harsh environment are not capable of surviving in laboratory conditions and attempts to keep them in captivity have led to their deaths Deep sea organisms contain gas filled spaces vacuoles Gas is compressed under high pressure and expands under low pressure Because of this these organisms have been known to blow up if they come to the surface 7 Characteristics Edit An annotated diagram of the basic external features of an abyssal grenadier and standard length measurements source source source source source source source source Rhinochimera atlantica Gigantactis is a deep sea fish with a dorsal fin whose first filament has become very long and is tipped with a bioluminescent photophore lure Pelican eel Bigeye tuna cruise the epipelagic zone at night and the mesopelagic zone during the dayThe fish of the deep sea have evolved various adaptations to survive in this region Since many of these fish live in regions where there is no natural illumination they cannot rely solely on their eyesight for locating prey and mates and avoiding predators deep sea fish have evolved appropriately to the extreme sub photic region in which they live Many of these organisms are blind and rely on their other senses such as sensitivities to changes in local pressure and smell to catch their food and avoid being caught Those that aren t blind have large and sensitive eyes that can use bioluminescent light These eyes can be as much as 100 times more sensitive to light than human eyes Rhodopsin Rh1 is a protein found in the eye s rod cells that helps animals see in dim light While most vertebrates usually have one Rh1 opsin gene some deep sea fish have several Rh1 genes and one species the silver spinyfin Diretmus argenteus has 38 9 This proliferation of Rh1 genes may help deep sea fish to see in the depths of the ocean Also to avoid predation many species are dark to blend in with their environment 10 Many deep sea fish are bioluminescent with extremely large eyes adapted to the dark Bioluminescent organisms are capable of producing light biologically through the agitation of molecules of luciferin which then produce light This process must be done in the presence of oxygen These organisms are common in the mesopelagic region and below 200 m and below More than 50 of deep sea fish as well as some species of shrimp and squid are capable of bioluminescence About 80 of these organisms have photophores light producing glandular cells that contain luminous bacteria bordered by dark colourings Some of these photophores contain lenses much like those in the eyes of humans which can intensify or lessen the emanation of light The ability to produce light only requires 1 of the organism s energy and has many purposes It is used to search for food and attract prey like the anglerfish claim territory through patrol communicate and find a mate and distract or temporarily blind predators to escape Also in the mesopelagic where some light still penetrates some organisms camouflage themselves from predators below them by illuminating their bellies to match the colour and intensity of light from above so that no shadow is cast This tactic is known as counter illumination 11 The lifecycle of deep sea fish can be exclusively deep water although some species are born in shallower water and sink upon maturation Regardless of the depth where eggs and larvae reside they are typically pelagic This planktonic drifting lifestyle requires neutral buoyancy In order to maintain this the eggs and larvae often contain oil droplets in their plasma 12 When these organisms are in their fully matured state they need other adaptations to maintain their positions in the water column In general water s density causes upthrust the aspect of buoyancy that makes organisms float To counteract this the density of an organism must be greater than that of the surrounding water Most animal tissues are denser than water so they must find an equilibrium to make them float 13 Many organisms develop swim bladders gas cavities to stay afloat but because of the high pressure of their environment deep sea fishes usually do not have this organ Instead they exhibit structures similar to hydrofoils in order to provide hydrodynamic lift It has also been found that the deeper a fish lives the more jelly like its flesh and the more minimal its bone structure They reduce their tissue density through high fat content reduction of skeletal weight accomplished through reductions of size thickness and mineral content and water accumulation 14 makes them slower and less agile than surface fish Due to the poor level of photosynthetic light reaching deep sea environments most fish need to rely on organic matter sinking from higher levels or in rare cases hydrothermal vents for nutrients This makes the deep sea much poorer in productivity than shallower regions Also animals in the pelagic environment are sparse and food doesn t come along frequently Because of this organisms need adaptations that allow them to survive Some have long feelers to help them locate prey or attract mates in the pitch black of the deep ocean The deep sea angler fish in particular has a long fishing rod like adaptation protruding from its face on the end of which is a bioluminescent piece of skin that wriggles like a worm to lure its prey Some must consume other fish that are the same size or larger than them and they need adaptations to help digest them efficiently Great sharp teeth hinged jaws disproportionately large mouths and expandable bodies are a few of the characteristics that deep sea fishes have for this purpose 10 The gulper eel is one example of an organism that displays these characteristics Fish in the different pelagic and deep water benthic zones are physically structured and behave in ways that differ markedly from each other Groups of coexisting species within each zone all seem to operate in similar ways such as the small mesopelagic vertically migrating plankton feeders the bathypelagic anglerfishes and the deep water benthic rattails 15 Ray finned species with spiny fins are rare among deep sea fishes which suggests that deep sea fish are ancient and so well adapted to their environment that invasions by more modern fishes have been unsuccessful 16 The few ray fins that do exist are mainly in the Beryciformes and Lampriformes which are also ancient forms Most deep sea pelagic fishes belong to their own orders suggesting a long evolution in deep sea environments In contrast deep water benthic species are in orders that include many related shallow water fishes 17 Species by pelagic zoneMany species move daily between zones in vertical migrations In this table they are listed in the middle or deeper zone where they are regularly found Zone Species and species groups include Epipelagic 18 mackerel requiem and whale sharks clupeiforms herring anchovy Salmonidae salmon atheriniforms flyingfishes halfbeaks sauries perciforms jacks dolphinfish pomfrets barracudas tunas billfish Mesopelagic Lanternfish opah longnose lancetfish barreleye ridgehead sabretooth stoplight loosejaw marine hatchetfish 19 Bathypelagic Principally bristlemouth and anglerfish Also fangtooth viperfish black swallower telescopefish hammerjaw daggertooth barracudina black scabbardfish bobtail snipe eel unicorn crestfish pelican eel flabby whalefish Benthopelagic 18 Rattail and brotula are particularly abundant Benthic Flatfish hagfish eelpout greeneye eel stingray lumpfish and batfish 18 Comparative structure of pelagic fishesEpipelagic Mesopelagic Bathypelagic deep sea benthicmuscles muscular bodies ossified bones scales well developed gills and central nervous systems and large hearts and kidneys poorly developed flabbyskeleton strong ossified bones weak minimal ossificationscales yes nonenervous systems well developed lateral line and olfactory onlyeyes large and sensitive small and may not function variable well developed to absent photophores absent common common usually absentgills well developedkidneys large smallheart large smallswim bladder vertically migratory fish have swim bladders reduced or absent variable well developed to absent size usually under 25 cm variable species greater than one meter are not uncommonMesopelagic fish EditMesopelagic fish Most mesopelagic fishes are small filter feeders which ascend at night to feed in the nutrient rich waters of the epipelagic zone During the day they return to the dark cold oxygen deficient waters of the mesopelagic where they are relatively safe from predators Lanternfish account for as much as 65 of all deep sea fish biomass and are largely responsible for the deep scattering layer of the world s oceans Most of the rest of the mesopelagic fishes are ambush predators like this sabertooth fish which uses its telescopic upward pointing eyes to pick out prey silhouetted against the gloom above Their recurved teeth prevent a captured fish from backing out The Antarctic toothfish have large upward looking eyes adapted to detecting the silhouettes of prey fish 20 The barreleye has barrel shaped tubular eyes which are generally directed upwards but can be swivelled forward 21 The telescopefish has large forward pointing telescoping eyes with large lenses 22 Below the epipelagic zone conditions change rapidly Between 200 m and about 1000 m light continues to fade until there is almost none Temperatures fall through a thermocline to temperatures between 3 9 C 39 F and 7 8 C 46 F This is the twilight or mesopelagic zone Pressure continues to increase at the rate of one atm every 10 m while nutrient concentrations fall along with dissolved oxygen and the rate at which the water circulates 4 Sonar operators using the newly developed sonar technology during World War II were puzzled by what appeared to be a false sea floor 300 500 m deep at day and less deep at night This turned out to be due to millions of marine organisms most particularly small mesopelagic fish with swim bladders that reflected the sonar These organisms migrate up into shallower water at dusk to feed on plankton The layer is deeper when the moon is out and can become shallower when clouds pass over the moon This phenomenon has come to be known as the deep scattering layer 23 Most mesopelagic fish make daily vertical migrations moving at night into the epipelagic zone often following similar migrations of zooplankton and returning to the depths for safety during the day 4 24 These vertical migrations often occur over large vertical distances and are undertaken with the assistance of a swim bladder 16 The swim bladder is inflated when the fish wants to move up and given the high pressures in the messoplegic zone this requires significant energy As the fish ascends the pressure in the swim bladder must adjust to prevent it from bursting When the fish wants to return to the depths the swim bladder is deflated 25 Some mesopelagic fishes make daily migrations through the thermocline where the temperature changes between 50 F 10 C and 69 F 20 C thus displaying considerable tolerances for temperature change 26 These fish have muscular bodies ossified bones scales well developed gills and central nervous systems and large hearts and kidneys Mesopelagic plankton feeders have small mouths with fine gill rakers while the piscivores have larger mouths and coarser gill rakers 4 Mesopelagic fish are adapted for an active life under low light conditions Most of them are visual predators with large eyes Some of the deeper water fish have tubular eyes with big lenses and only rod cells that look upwards These give binocular vision and great sensitivity to small light signals 4 This adaptation gives improved terminal vision at the expense of lateral vision and allows the predator to pick out squid cuttlefish and smaller fish that are silhouetted against the gloom above them Mesopelagic fish usually lack defensive spines and use colour to camouflage themselves from other fish Ambush predators are dark black or red Since the longer red wavelengths of light do not reach the deep sea red effectively functions the same as black Migratory forms use countershaded silvery colours On their bellies they often display photophores producing low grade light For a predator from below looking upwards this bioluminescence camouflages the silhouette of the fish However some of these predators have yellow lenses that filter the red deficient ambient light leaving the bioluminescence visible 27 The brownsnout spookfish a species of barreleye is the only vertebrate known to employ a mirror as opposed to a lens to focus an image in its eyes 28 29 Sampling by deep trawling indicates that lanternfish account for as much as 65 of all deep sea fish biomass 30 Indeed lanternfish are among the most widely distributed populous and diverse of all vertebrates playing an important ecological role as prey for larger organisms The estimated global biomass of lanternfish is 550 660 million tonnes several times the entire world fisheries catch Lanternfish also account for much of the biomass responsible for the deep scattering layer of the world s oceans 31 Bigeye tuna are an epipelagic mesopelagic species that eats other fish Satellite tagging has shown that bigeye tuna often spend prolonged periods cruising deep below the surface during the daytime sometimes making dives as deep as 500 m These movements are thought to be in response to the vertical migrations of prey organisms in the deep scattering layer The stoplight loosejaw has a lower jaw one quarter as long as its body The jaw has no floor and is attached only by a hinge and a modified tongue bone Large fang like teeth in the front are followed by many small barbed teeth 32 33 The stoplight loosejaw is also one of the few fishes that produce red bioluminescence As most of their prey cannot perceive red light this allows it to hunt with an essentially invisible beam of light 32 Long snouted lancetfish Lancetfish are ambush predators which spend all their time in the mesopelagic zone They are among the largest mesopelagic fishes up to 2 m 34 The daggertooth paralyses other mesopelagic fish when it bites them with its dagger like teeth 35 Bathypelagic fish EditBathypelagic fish The humpback anglerfish is a bathypelagic ambush predator which attracts prey with a bioluminescent lure It can ingest prey larger than itself which it swallows with an inrush of water when it opens its mouth 36 Many bristlemouth species such as the spark anglemouth above 37 are also bathypelagic ambush predators which can swallow prey larger than themselves They are among the most abundant of all vertebrate families 37 Young red flabby whalefish make nightly vertical migrations into the lower mesopelagic zone to feed on copepods When males make the transition to adults they develop a massive liver and then their jaws fuse shut They no longer eat but continue to metabolise the energy stored in their liver 38 39 The Sloane s viperfish can make nightly migrations from bathypelagic depths to near surface waters 40 The widespread fangtooth has the largest teeth of any fish proportionate to body size 41 Despite their ferocious appearance bathypelagic fish are usually weakly muscled and too small to represent any threat to humans Below the mesopelagic zone it is pitch dark This is the midnight or bathypelagic zone extending from 1000 m to the bottom deep water benthic zone If the water is exceptionally deep the pelagic zone below 4000 m is sometimes called the lower midnight or abyssopelagic zone Temperatures in this zone range from 1 to 4 degrees celsius and is completely aphotic Conditions are somewhat uniform throughout these zones the darkness is complete the pressure is crushing and temperatures nutrients and dissolved oxygen levels are all low 4 Bathypelagic fish have special adaptations to cope with these conditions they have slow metabolisms and unspecialized diets being willing to eat anything that comes along They prefer to sit and wait for food rather than waste energy searching for it The behaviour of bathypelagic fish can be contrasted with the behaviour of mesopelagic fish Mesopelagic fish are often highly mobile whereas bathypelagic fish are almost all lie in wait predators normally expending little energy in movement 42 The dominant bathypelagic fishes are small bristlemouth and anglerfish fangtooth viperfish daggertooth and barracudina are also common These fishes are small many about 10 cm long and not many longer than 25 cm They spend most of their time waiting patiently in the water column for prey to appear or to be lured by their phosphors What little energy is available in the bathypelagic zone filters from above in the form of detritus faecal material and the occasional invertebrate or mesopelagic fish 42 About 20 per cent of the food that has its origins in the epipelagic zone falls down to the mesopelagic zone 23 but only about 5 per cent filters down to the bathypelagic zone 36 Bathypelagic fish are sedentary adapted to outputting minimum energy in a habitat with very little food or available energy not even sunlight only bioluminescence Their bodies are elongated with weak watery muscles and skeletal structures Since so much of the fish is water they are not compressed by the great pressures at these depths They often have extensible hinged jaws with recurved teeth They are slimy without scales The central nervous system is confined to the lateral line and olfactory systems the eyes are small and may not function and gills kidneys and hearts and swim bladders are small or missing 36 43 These are the same features found in fish larvae which suggests that during their evolution bathypelagic fish have acquired these features through neoteny As with larvae these features allow the fish to remain suspended in the water with little expenditure of energy 44 Despite their ferocious appearance these beasts of the deep are mostly miniature fish with weak muscles and are too small to represent any threat to humans The swim bladders of deep sea fish are either absent or scarcely operational and bathypelagic fish do not normally undertake vertical migrations Filling bladders at such great pressures incurs huge energy costs Some deep sea fishes have swim bladders which function while they are young and inhabit the upper epipelagic zone but they wither or fill with fat when the fish move down to their adult habitat 45 The most important sensory systems are usually the inner ear which responds to sound and the lateral line which responds to changes in water pressure The olfactory system can also be important for males who find females by smell 46 Bathypelagic fish are black or sometimes red with few photophores When photophores are used it is usually to entice prey or attract a mate Because food is so scarce bathypelagic predators are not selective in their feeding habits but grab whatever comes close enough They accomplish this by having a large mouth with sharp teeth for grabbing large prey and overlapping gill rakers which prevent small prey that have been swallowed from escaping 43 It is not easy finding a mate in this zone Some species depend on bioluminescence where bioluminescent patterns are unique to specific species Others are hermaphrodites which doubles their chances of producing both eggs and sperm when an encounter occurs 36 The female anglerfish releases pheromones to attract tiny males When a male finds her he bites on to her and never lets go When a male of the anglerfish species Haplophryne mollis bites into the skin of a female he releases an enzyme that digests the skin of his mouth and her body fusing the pair to the point where the two circulatory systems join up The male then atrophies into nothing more than a pair of gonads This extreme sexual dimorphism ensures that when the female is ready to spawn she has a mate immediately available 47 Many forms other than fish live in the bathypelagic zone such as squid large whales octopuses sponges brachiopods sea stars and echinoids but this zone is difficult for fish to live in The pelican eel uses its large mouth like a net by opening its jaws and swimming towards prey It has a luminescent organ at the tip of its tail to attract prey The black swallower with its distensible stomach is notable for its ability to swallow whole bony fishes ten times its mass 48 49 Female Haplophryne mollis anglerfish trailing attached males which have atrophied into a pair of gonads for use when the female is ready to spawn Adaptation to high pressure EditAs a fish moves deeper into the sea the weight of the water overhead exerts increasing hydrostatic pressure on the fish This increased pressure amounts to about one atm for every 10 m in depth For a fish at the bottom of the bathypelagic zone this pressure amounts to about 400 atm nearly 6000 pounds per square inch 50 Deep sea organisms possess adaptations at cellular and physiological levels that allow them to survive in environments of great pressure Not having these adaptations limits the depths at which shallow water species can operate High levels of external pressure affects how metabolic processes and biochemical reactions proceed The equilibrium of many chemical reactions is disturbed by pressure and pressure can inhibit processes which result in an increase in volume Water a key component in many biological processes is very susceptible to volume changes mainly because constituents of cellular fluid have an effect on water structure Thus enzymatic reactions that induce changes in water organization effectively change the system s volume 51 Proteins responsible for catalyzing reactions are typically held together by weak bonds and the reactions usually involve volume increases 52 Species that can tolerate these depths have evolved changes in their protein structure and reaction criteria to withstand pressure in order to perform reactions in these conditions In high pressure environments bilayer cellular membranes experience a loss of fluidity Deep sea cellular membranes favor phospholipid bilayers with a higher proportion of unsaturated fatty acids which induce a higher fluidity than their sea level counterparts The rattail Coryphaenoides armatus abyssal grenadier on the Davidson Seamount at 2253 m depth Deep sea species exhibit lower changes of entropy and enthalpy compared to surface level organisms since a high pressure and low temperature environment favors negative enthalpy changes and reduced dependence on entropy driven reactions From a structural standpoint globular proteins of deep sea fish due to the tertiary structure of G actin are relatively rigid compared to those of surface level fish 51 The fact that proteins in deep sea fish are structurally different from surface fish is apparent from the observation that actin from the muscle fibers of deep sea fish are extremely heat resistant an observation similar to what is found in lizards These proteins are structurally strengthened by modification of the bonds in the tertiary structure of the protein which also happens to induce high levels of thermal stability 52 Proteins are structurally strengthened to resist pressure by modification of bonds in the tertiary structure 52 Therefore high levels of hydrostatic pressure similar to high body temperatures of thermophilic desert reptiles favor rigid protein structures Na K ATPase is a lipoprotein enzyme that plays a prominent role in osmoregulation and is heavily influenced by hydrostatic pressure The inhibition of Na K ATPase is due to increased compression due to pressure The rate limiting step of the Na K ATPase reaction induces an expansion in the bilayer surrounding the protein and therefore an increase in volume An increase in volume makes Na K ATPase reactivity susceptible to higher pressures Even though the Na K ATPase activity per gram of gill tissue is lower for deep sea fishes the Na K ATPases of deep sea fishes exhibit a much higher tolerance of hydrostatic pressure compared to their shallow water counterparts This is exemplified between the species C acrolepis around 2000 m deep and its hadalpelagic counterpart C armatus around 4000 m deep where the Na K ATPases of C armatus are much less sensitive to pressure This resistance to pressure can be explained by adaptations in the protein and lipid moieties of Na K ATPase 53 Lanternfish EditMain article Lanternfish Lantern fishSampling via deep trawling indicates that lanternfish account for as much as 65 of all deep sea fish biomass 30 Indeed lanternfish are among the most widely distributed populous and diverse of all vertebrates playing an important ecological role as prey for larger organisms With an estimated global biomass of 550 660 million metric tons several times the entire world fisheries catch lanternfish also account for much of the biomass responsible for the deep scattering layer of the world s oceans In the Southern Ocean Myctophids provide an alternative food resource to krill for predators such as squid and the king penguin Although these fish are plentiful and prolific currently only a few commercial lanternfish fisheries exist these include limited operations off South Africa in the sub Antarctic and in the Gulf of Oman Endangered species EditA 2006 study by Canadian scientists has found five species of deep sea fish blue hake spiny eel to be on the verge of extinction due to the shift of commercial fishing from continental shelves to the slopes of the continental shelves down to depths of 1600 m The slow reproduction of these fish they reach sexual maturity at about the same age as human beings is one of the main reasons that they cannot recover from the excessive fishing 54 See also Edit Oceans portalCensus of Marine Life Deep ocean water Deep sea Deep sea communities Deep water fish Demersal fish Pelagic fishCitations Edit Trujillo amp Thurman 2011 pp 354 Trujillo amp Thurman 2011 pp 365 Trujillo amp Thurman 2011 pp 457 460 a b c d e f Moyle amp Cech 2004 pp 585 Wharton 2002 pp 198 Wharton 2002 pp 199 201 202 a b Wharton 2002 pp 199 Compagno L J V 1984 Sharks of the World An Annotated and Illustrated Catalogue of Shark Species Known to Date Food and Agricultural Organization of the United Nations pp 14 15 ISBN 92 5 101384 5 Musilova Zuzana Cortesi Fabio Matschiner Michael Davies Wayne Patel Jagdish Stieb Sara de Busserolles Fanny Malmstrom Martin Torresen Ole Brown Celeste Mountford Jessica Hanel Reinhold Stenkamp Deborah Jakobsen Kjetill Carleton Karen Jentoft Sissel Marshall Justin Salzburger Walter 2019 Vision using multiple distinct rod opsins in deep sea fishes Science American Association for the Advancement of Science 364 6440 588 592 Bibcode 2019Sci 364 588M doi 10 1126 science aav4632 PMC 6628886 PMID 31073066 a b Trujillo amp Thurman 2011 pp 415 Trujillo amp Thurman 2011 pp 414 5 Randall amp Farrell 1997 pp 217 Randall amp Farrell 1997 pp 195 Randall amp Farrell 1997 pp 196 225 Moyle amp Cech 2004 pp 591 a b Haedrich R L 1996 Deep water fishes evolution and adaptation in the earth s largest living spaces Journal of Fish Biology 49 sA 40 53 Moyle amp Cech 2004 pp 586 a b c Moyle amp Cech 2004 pp 571 Froese Rainer Pauly Daniel eds 2009 Argyropelecus aculeatus in FishBase August 2009 version Froese Rainer Pauly Daniel eds 2009 Dissostichus mawsoni in FishBase August 2009 version Mystery Of Deep sea Fish With Tubular Eyes And Transparent Head Solved ScienceDaily 24 February 2009 Froese Rainer Pauly Daniel eds 2010 Gigantura chuni in FishBase October 2010 version a b Ryan P Deep sea creatures The mesopelagic zone Te Ara the Encyclopedia of New Zealand Updated 21 September 2007 Bone amp Moore 2008 p 38 Douglas E L Friedl W A Pickwell G V 1976 Fishes in oxygen minimum zones blood oxygenation characteristics Science 191 4230 957 959 Bibcode 1976Sci 191 957D doi 10 1126 science 1251208 PMID 1251208 Moyle amp Cech 2004 pp 590 Munz W R A 1976 On yellow lenses in mesopelagic animals Marine Biological Association of the UK 56 4 963 976 doi 10 1017 S0025315400021019 S2CID 86353657 Wagner H J Douglas R H Frank T M Roberts N W Partridge J C 2009 A Novel Vertebrate Eye Using Both Refractive and Reflective Optics Current Biology 19 2 108 114 doi 10 1016 j cub 2008 11 061 PMID 19110427 S2CID 18680315 Smith L Jan 8 2009 Fish with four eyes can see through the deep sea gloom Times Online Times Newspapers Ltd Retrieved on March 14 2009 a b Paxton amp Eschmeyer 1998 pp 127 8 R Cornejo R Koppelmann T Sutton Deep sea fish diversity and ecology in the benthic boundary layer a b Kenaley C P 2007 Revision of the Stoplight Loosejaw Genus Malacosteus Teleostei Stomiidae Malacosteinae with Description of a New Species from the Temperate Southern Hemisphere and Indian Ocean Copeia 2007 4 886 900 doi 10 1643 0045 8511 2007 7 886 ROTSLG 2 0 CO 2 S2CID 1038874 Sutton T T 2005 Trophic ecology of the deep sea fish Malacosteus niger Pisces Stomiidae An enigmatic feeding ecology to facilitate a unique visual system Deep Sea Research Part I Oceanographic Research Papers 52 11 2065 2076 Bibcode 2005DSRI 52 2065S doi 10 1016 j dsr 2005 06 011 Moyle amp Cech 2004 pp 336 Froese Rainer Pauly Daniel eds 2010 Anotopterus pharao in FishBase April 2010 version a b c d Ryan P Deep sea creatures The bathypelagic zone Te Ara the Encyclopedia of New Zealand Updated 21 September 2007 a b Froese Rainer and Daniel Pauly eds 2009 Gonostoma in FishBase August 2009 version Connecting knowledge and people for more than 10 years Archived from the original on 9 July 2012 Scientists solve mystery 3 fish are all the same 22 January 2009 Retrieved 22 January 2009 Froese Rainer Pauly Daniel eds 2010 Chauliodus sloani in FishBase April 2010 version Froese Rainer Pauly Daniel eds 2009 Anoplogaster cornuta in FishBase August 2009 version a b Moyle amp Cech 2004 pp 594 a b Moyle amp Cech 2004 pp 587 Marshall 1984 Progenetic tendencies in deep sea fishes pp 91 101 in Potts GW and Wootton RJ eds 1984 Fish reproduction strategies and tactics Fisheries Society of the British Isles Horn MH 1970 The swim bladder as a juvenile organ in stromateoid fishes Breviora 359 1 9 Jumper GY Bair RC 1991 Location by olfaction a model and application to the mating problem in the deep sea Hatchetfish Argyropelecus hemigymnus The American Naturalist 138 6 1431 58 doi 10 1086 285295 JSTOR 2462555 S2CID 84386858 Theodore W Pietsch 1975 Precocious sexual parasitism in the deep sea ceratioid anglerfish Cryptopsaras couesi Gill Nature 256 5512 38 40 Bibcode 1975Natur 256 38P doi 10 1038 256038a0 S2CID 4226567 Jordan D S 1905 A Guide to the Study of Fishes H Holt and Company Froese Rainer Pauly Daniel eds 2009 Chiasmodon niger in FishBase August 2009 version Scott Thomas R Powell James 2018 The Universe as It Really Is Earth Space Matter and Time Columbia University Press doi 10 7312 scot18494 ISBN 978 0 231 54576 1 S2CID 125357269 a b Hochachka amp Somero 1984 a b c Priede 2017 pp 87 138 Somero G N 1992 Adaptations to High Hydrostatic Pressure Annual Review of Physiology 54 1 557 577 doi 10 1146 annurev ph 54 030192 003013 ISSN 0066 4278 PMID 1314046 Devine Jennifer A Baker Krista D Haedrich Richard L 2006 Fisheries Deep sea fishes qualify as endangered Nature 439 7072 29 Bibcode 2006Natur 439 29D doi 10 1038 439029a PMID 16397489 S2CID 4428618 References EditHochachka Peter W Somero George N 1984 Biochemical Adaptation Princeton University Press JSTOR j ctt7zv9d4 Moyle P B Cech J J 2004 Fishes An Introduction to Ichthyology 5 ed Benjamin Cummings ISBN 9780131008472 Paxton J R Eschmeyer W N eds 1998 Encyclopedia of Fishes San Diego Academic Press ISBN 0125476655 Priede Imants G ed 2017 Adaptations to the Deep Sea Deep Sea Fishes Biology Diversity Ecology and Fisheries Cambridge Cambridge University Press pp 87 138 doi 10 1017 9781316018330 004 ISBN 9781316018330 Randall David J Farrell Anthony Peter 1997 Deep sea Fishes San Diego Academic ISBN 9780123504401 Trujillo Alan P Thurman Harold V 2011 Essentials of Oceanography 10 ed Boston Prentice Hall ISBN 9780321668127 Wharton David 2002 Life at the Limits Organisms in Extreme Environments Cambridge Cambridge University Press p 198 ISBN 9780521782128 Further reading EditGordon J D M 2001 Deep sea fishes In John H Steele Steve A Thorpe Karl K Turekian eds Elements of Physical Oceanography pages 227 233 Academic Press ISBN 9780123757241 Hoar W S Randall D J and Farrell A P eds 1997 Deep Sea Fishes Academic Press ISBN 9780080585406 Shotton Ross 1995 Deepwater fisheries In Review of the state of world marine fishery resources FAO Fisheries technical paper 457 FAO Rome ISBN 92 5 105267 0 Tandstad M Shotton R Sanders J and Carocci F 2011 Deep sea Fisheries In Review of the state of world marine fishery resources pages 265 278 FAO Fisheries technical paper 569 FAO Rome ISBN 978 92 5 107023 9 External links Edit Wikimedia Commons has media related to Deep sea fish External video Creatures and Fish of the Deep Ocean National Geographic documentaryhttps www pbs org wgbh nova abyss life bestiary html http ocean nationalgeographic com ocean photos deep sea creatures Deep Sea Creatures Articles facts and images of deep sea animals Retrieved from https en wikipedia org w index php title Deep sea fish amp oldid 1171681764, wikipedia, wiki, book, books, library,

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