Anglerfish

"Esca" redirects here. For the grapevine disease, see Esca (grape).

Angler fish
Humpback anglerfish, Melanocetus johnsonii
Scientific classification
Kingdom:	Animalia
Phylum:	Chordata
Class:	Actinopterygii
Subclass:	Neopterygii
Infraclass:	Teleostei
Order:	Lophiiformes Garman, 1899

(A) Centrophryne spinulosa, 136 mm SL
(B) Cryptopsaras couesii, 34.5 mm SL
(C) Himantolophus appelii, 124 mm SL
(D) Diceratias trilobus, 86 mm SL
(E) Bufoceratias wedli, 96 mm SL
(F) Bufoceratias shaoi, 101 mm SL
(G) Melanocetus eustales, 93 mm SL
(H) Lasiognathus amphirhamphus, 157 mm SL
(I) Thaumatichthys binghami, 83 mm SL
(J) Chaenophryne quasiramifera, 157 mm SL.

Anglerfishes are members of the teleost order Lophiiformes /ˌlɒfiːəˈfɔːrmiːz/.^[1] They are bony fishes named for their characteristic mode of predation, in which a fleshy growth from the fish's head (the esca or illicium) acts as a lure.

Anglerfish are also notable for extreme sexual dimorphism seen in the suborder Ceratioidei, and sexual parasitism of male anglerfish. In these species, males may be hundreds to thousands of times smaller than females.^[2]

Anglerfish occur worldwide. Some are pelagic while others are benthic; some live in the deep sea (e.g., Ceratiidae) while others on the continental shelf (e.g., the frogfishes Antennariidae and the monkfish/goosefish Lophiidae). Pelagic forms are most laterally compressed whereas the benthic forms are often extremely dorsoventrally compressed (depressed) often with large upward pointing mouths.

Evolution

A mitochondrial genome phylogenetic study suggested that anglerfishes are diversified in a short period of the early to mid Cretaceous, between 130 and 100 million years ago.^[3]

Ranging in color from dark gray to dark brown, these carnivores have huge heads that bear enormous, crescent-shaped mouth full of long, fang-like teeth angled inward for efficient prey grabbing. Their length can vary from 8 in (20 cm) to over 3 ft (1 m) with weight of up to 100 pounds (50 kg).^[4]

Classification

FishBase,^[1] Nelson,leedle ^[5] and Pietsch^[2] list eighteen families, but ITIS^[6] lists only sixteen. The following taxa have been arranged to show their evolutionary relationships.^[2]

• Suborder Lophioidei
  • Lophiidae (goosefishes or monkfishes)
• Suborder Antennarioidei
  • Antennariidae (frogfishes)
  • Tetrabrachiidae (four-armed frogfishes)^[7]
  • Brachionichthyidae (handfishes)
  • Lophichthyidae (Boschma's frogfish — monotypic)^[7]
• Suborder Chaunacoidei
  • Chaunacidae (sea toads)
• Suborder Ogcocephaloidei
  • Ogcocephalidae (batfishes)
• Suborder Ceratioidei (deepsea families)^[2]
  • Centrophrynidae (prickly seadevils — monotypic)
  • Ceratiidae (warty seadevils)
  • Himantolophidae (footballfishes)
  • Diceratiidae (doublespine seadevils)
  • Melanocetidae (black seadevils)
  • Thaumatichthyidae (wolf-trap seadevils)
  • Oneirodidae (dreamers)
  • Caulophrynidae (fanfin seadevils)
  • Neoceratiidae (needlebeard seadevil — monotypic)
  • Gigantactinidae (whipnose seadevils)
  • Linophrynidae (leftvent seadevils)

Anatomy

Most adult female ceratioid anglerfish have a luminescent organ called the esca at the tip of a modified dorsal ray. It has been hypothesized that the organ serves the obvious purpose of luring prey in dark deep-sea environments, but also serves to call male attention to the female to facilitate mating. The source of luminescence is symbiotic bacteria that dwell in and around the esca. In some species, the bacteria recruited to the esca are incapable of luminescence independent of the anglerfish, suggesting that they have developed a symbiotic relationship and that the bacteria are unable to synthesize all of the chemicals necessary for luminescence. They depend on the fish to make up the difference. Electron microscopy of these bacteria in some species reveals that they are Gram-negative rods that lack capsules, spores, or flagella. They have double-layered cell walls and mesosomes.^[8]

In most species, a wide mouth extends all around the anterior circumference of the head, and bands of inwardly-inclined teeth line both jaws. The teeth can be depressed so as to offer no impediment to an object gliding towards the stomach but prevent its escape from the mouth. The anglerfish is able to distend both its jaw and its stomach, since its bones are thin and flexible, to enormous size, allowing it to swallow prey up to twice as large as its entire body.

Behavior

Swimming and energy conservation

Many anglerfish species are deep-sea dwellers, which poses a challenge to ecologists that hope to study and observe the fish. Anglerfish morphology reflects the value of energy conservation for these organisms which often live in extremely prey-scarce environments.^[9] Some researchers suggest that this is why many ceratioids minimize their energy use by remaining lethargic and using a lie-and-wait hunting strategy.^[10] Anglerfish are particularly well suited to conserve energy because they are able to hunt and forage while remaining lethargic, devoting just 2% of energy intake to swimming.

In one rare ROV observation of an in-situ anglerfish, researchers observed several rapid swimming and avoidance behaviors. In 74% of the video footage, the fish was observed passively drifting. Occasionally, it would also exhibit rapid burst swimming. While drifting, the fish weakly beat its pectoral fins in a behavior known as sculling.^[10] The sculling behavior observed is suggested as necessary to keep the fish in a neutral position in the water and to counteract any displacing currents.^[11] The bursts of fast swimming typically last less that five seconds. The swimming behavior in this video is similar to that seen in other in-situ footage of a ceratioid anglerfish.^[10]

Another in-situ observation of three different whipnose anglerfish showed unusual upside-down swimming behavior. Fish were observed floating upside-down completely motionless with the illicium hanging down stiffly in a slight arch in front of the fish. Notably, the illicium was hanging over small visible burrows. The observers suggest that this is one effort to entice prey and is another example of low energy opportunistic foraging and predation. When the ROV approached the fish, they exhibited burst swimming, still upside-down.^[12]

Predationwnjfnaerkgjerlkbnselkbtnejk

Skeleton of the angler fish, Lophius piscatorius. The first spine of the dorsal fin of the anglerfish acts as a fishing rod with a lure.

The name "anglerfish" derives from the species' characteristic method of predation. Anglerfish typically have at least one long filament sprouting from the middle of their heads, termed the illicium. The illicium are the detached and modified first three spines of the anterior dorsal fin. In most anglerfish species, the longest filament is the first. This first spine protrudes above the fish's eyes and terminates in an irregular growth of flesh (the esca), and can move in all directions. Anglerfish can wiggle the esca to make it resemble a prey animal, which lures the anglerfish's prey close enough for the anglerfish to devour them whole. The jaws reflexively shut upon contact to the tentacle.

Some deep-sea anglerfish of the bathypelagic zone emit light from their escas to attract prey. This bioluminescence is a result of symbiosis with bacteria. Although the mechanism by which they are harnessed by ceratioids is unknown, the bacteria have been speculated to enter the esca from the seawater through small pores. Once within the esca, they can multiply until their density is such that their collective glow is very bright.^[13]

Because anglerfish are opportunistic foragers, they show a range of preferred prey with fish at the extremes of the size spectrum, whilst showing increased selectivity for certain prey. One study examining the stomach contents of threadfin anglerfish off the Pacific coast of Central America found that these fish primarily ate two categories of benthic prey: crustaceans and teleost fish. The most frequent prey were pandalid shrimp. Interestingly, 52% of the stomachs examined were empty, supporting the observations that anglerfish are low energy consumers.^[14]

Reproduction

Linophrynidae: Haplophryne mollis. Female anglerfish with atrophied males attached.

Antennariidae: striated frogfish, Antennarius striatus

Some anglerfish, like those of the Ceratioid group (Ceratiidae, or sea devils), employ an unusual mating method. Because individuals are locally rare, encounters are also very rare. Therefore, finding a mate is problematic. When scientists first started capturing ceratioid anglerfish, they noticed that all of the specimens were female. These individuals were a few centimetres in size and almost all of them had what appeared to be parasites attached to them. It turned out that these "parasites" were highly reduced male ceratioids. This indicates that anglerfish use a polyandrous mating system.

In certain ceratioids, parasitic reproduction is required. Free living males and non-parasitized females in these species never have fully developed gonads. Thus, males never mature without parasitizing a female and die if they are unable to find one.^[2] At birth, male ceratioids are already equipped with extremely well-developed olfactory organs^[15] that detect scents in the water. Males of some species also develop large, highly specialized eyes that may aid in identifying mates in dark environments. The male ceratioid lives solely to find and mate with a female. They are significantly smaller than a female angler fish, and may have trouble finding food in the deep sea. Furthermore, the growth of the alimentary canals of some males becomes stunted, preventing them from feeding. Some taxa have jaw apparatus that are never suitable or effective for prey capture.^[15] These features necessitate that the male quickly find a female anglerfish to prevent death. The sensitive olfactory organs help the male to detect the pheromones that signal the proximity of a female anglerfish.

However, the methods by which anglerfish locate mates are variable. Some species have minute eyes unfit for identifying females visually, while others have underdeveloped nostrils, making it unlikely that they effectively find females using olfaction.^[2] When a male finds a female, he bites into her skin, and releases an enzyme that digests the skin of his mouth and her body, fusing the pair down to the blood-vessel level.^[15] The male becomes dependent on the female host for survival by receiving nutrients via their shared circulatory system, and provides sperm to the female in return. After fusing, males increase in volume and become much larger relative to free-living males of the species. They live and remain reproductively functional as long as the female lives and can take part in multiple spawnings.^[2] This extreme sexual dimorphism ensures that, when the female is ready to spawn, she has a mate immediately available.^[16] Multiple males can be incorporated into a single individual female with up to eight males in some species, though some taxa appear to have a one male per female rule.^[2]

Parasitism is not the only method of reproduction in anglerfish. In fact, many families and genera including Melanocetidae, Himantolophidae, Diceratiidae, and Gigantactinidae show no evidence of male parasitism.^[17] Females in some of these species contain large, developed ovaries and free-living males have large testes suggesting that these sexually mature individuals may spawn during a temporary sexual attachment that does not involve fusion of tissue. Males in these species also have well-toothed jaws that are far more effective in hunting than those seen in parasitic species.^[17]

Finally, some researchers suggest that sexual parasitism may be an optional strategy in some species of anglerfish.^[2] In the oneirodid genera, females have been reported in Leptacanthichthys and Bertella, which were parasitized, and others which were not but still developed fully functional gonads.^[18] One theory suggests that males will attach to females regardless of their own reproductive development if the female is not sexually mature, but when both male and female are mature, they will spawn then separate.^[2]

One explanation for the evolution of sexual parasitism is as follows. The relative low density of females in deep-sea environments leaves little opportunity for mate choice among anglerfish. Females remain large to accommodate fecundity, as is evidenced by their large ovaries and eggs. Males would be expected to shrink to reduce metabolic costs in resource poor environments and would develop highly specialized female finding abilities. If a male manages to find a female parasitic attachment then it is ultimately more likely to improve lifetime fitness relative to free-living, particularly when the prospect of finding future mates is poor. An additional advantage to parasitism is that the male’s sperm can be used in multiple fertilizations, as he stays always available to the female for mating. Higher densities of male-female encounters might correlate with species that demonstrate facultative parasitism or simply use a more traditional temporary contact mating.^[19]

The spawn of the anglerfish of the genus Lophius consists of a thin sheet of transparent gelatinous material 25 cm wide and greater than 10 metres long.^[20] The eggs in this sheet are in a single layer, each in its own cavity. The spawn is free in the sea. The larvae are free-swimming and have the pelvic fins elongated into filaments. Such an egg sheet is rare among fish.

Threats

Northwest European Lophius spp. are listed by the ICES as "outside safe biological limits."^[21] Additionally, anglerfish are known to occasionally rise to the surface during El Niño, leaving large groups of dead anglerfish floating on surface.^[21]

In 2010, Greenpeace International added the American angler (Lophius americanus), the angler (Lophius piscatorius) and the black-bellied angler (Lophius budegassa) to its seafood red list. The Greenpeace International seafood red list is a list of fish commonly sold worldwide which have a very high likelihood of being sourced from unsustainable fisheries.^[22]

Human consumption

One family, Lophiidae, is of commercial interest with fisheries found in north-western Europe, eastern North America, Africa and the Far East. In Europe and North America, the tail meat of fish of the genus Lophius, known as monkfish or goosefish (North America), is widely used in cooking, and is often compared to lobster tail in taste and texture. In Asia, especially Korea and Japan, it is a delicacy.^[23]

Timeline of genera

File:Humpback Anglerfish (Melanocetus Johnsonii).jpg

Melanocetus johnsonii

References

1. Froese, Rainer; Pauly, Daniel (eds.). "Order Lophiiformes". FishBase. February 2006 version.
2. Pietsch, Theodore W. (25 August 2005). "Dimorphism, parasitism, and sex revisited: modes of reproduction among deep-sea ceratioid anglerfishes (Teleostei: Lophiiformes)". Ichthyological Research. 52 (3): 207–236. doi:10.1007/s10228-005-0286-2. Cite error: The named reference "Pietsch" was defined multiple times with different content (see the help page).
3. Miya, M. (2010). "Evolutionary history of anglerfishes (Teleostei: Lophiiformes): a mitogenomic perspective". BMC Evolutionary Biology. 10: 58. doi:10.1186/1471-2148-10-58. PMC 2836326. PMID 20178642. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
4. "Anglerfish". deepseacreatures.org. Retrieved 17 October 2012.
5. Joseph S. Nelson. Fishes of the World. John Wiley & Sons. ISBN 0-471-54713-1.
6. "Lophiiformes". Integrated Taxonomic Information System. Retrieved 3 April 2006.
7. Boschma's frogfish and the four-armed frogfish are included in Antennariidae in ITIS.
8. O'Day, William T. (1974). Bacterial Luminescence in the Deep-Sea Anglerfish (PDF). LA: Natural History Museum of Los Angeles County.
9. Bertelsen, E. (1951). "The Ceratioid Fishes: Ontogeny, Taxonomy, Distribution and Biology" (PDF). Dana-Report. No. 39: 1–276. Retrieved 4 October 2013. {{cite journal}}: |volume= has extra text (help)
10. Luck, Daniel Garcia (4 June 2008). "Observations of a Deep-sea Ceratioid Anglerfish of the Genus Oneirodes (Lophiiformes: Oneirodidae)". Copeia. 2008 (2): 446–451. doi:10.1643/CE-07-075. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
11. Kitchell, James (1983). "Energetics". Fish Biomechanics: 312–338. {{cite journal}}: |access-date= requires |url= (help)
12. Moore, Jon A. (31 December 2001). "Upside-Down Swimming Behavior in a Whipnose Anglerfish (Teleostei: Ceratioidei: Gigantactinidae)". Copeia. 4. 2002: 1144–1146. Retrieved 4 October 2013.
13. Piper, Ross (2007), Extraordinary Animals: An Encyclopedia of Curious and Unusual Animals, Greenwood Press.
14. Espinoza, Mario (2008). "Stomach content analyses of the threadfin anglerfish Lophiodes spilurus (Lophiiformes: Lophiidae) associated with deepwater shrimp fisheries from the central Pacific of Costa Rica". Revista de Biología Tropical. 4. 56. Retrieved 4 October 2013. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
15. Gould, Stephen Jay (1983). Hen's Teeth and Horse's Toes. New York: W. W. Norton & Company. p. 30. ISBN 0-393-01716-8. ceratioid males develop gigantic nostrils...relative to body size, some ceratioids have larger nasal organs than any other vertebrate
16. Theodore W. Pietsch. "Precocious sexual parasitism in the deep sea ceratioid anglerfish, Cryptopsaras couesi Gill". Archived from the original on 28 August 2008. Retrieved 31 July 2008. {{cite web}}: Unknown parameter |deadurl= ignored (|url-status= suggested) (help)
17. Pietsch, Theodore W. (8 March 1972). "A Review of the Monotypic Deep-Sea Anglerfish Family Centrophrynidae: Taxonomy, Distribution and Osteology". Copeia. 1972 (1): 17–47. Retrieved 4 October 2013.
18. Pietsch, Theodore W. (25 August 2005). "Dimorphism, parasitism, and sex revisited: modes of reproduction among deep-sea ceratioid anglerfishes (Teleostei: Lophiiformes)". Ichthyological Research. 52 (3): 207–236. doi:10.1007/s10228-005-0286-2.
19. Miya, Masaki (1 January 2010). "Evolutionary history of anglerfishes (Teleostei: Lophiiformes): a mitogenomic perspective". BMC Evolutionary Biology. 10 (1): 58. doi:10.1186/1471-2148-10-58. {{cite journal}}: Unknown parameter |coauthors= ignored (|author= suggested) (help)
20. Prince, E. E. 1891. Notes on the development of the angler-fish (Lophius piscatorius). Ninth Annual Report of the Fishery Board for Scotland (1890), Part III: 343–348.
21. Clover, Charles (2004). The End of the Line: How overfishing is changing the world and what we eat. London: Ebury Press. ISBN 0-09-189780-7. {{cite book}}: Cite has empty unknown parameter: |coauthors= (help)
22. Greenpeace International Seafood Red list
23. "Goosefish". All the Sea. Retrieved 20 April 2012.

• Sepkoski, Jack (2002). "A compendium of fossil marine animal genera". Bulletins of American Paleontology. 364: p.560. Retrieved 17 May 2011. {{cite journal}}: |pages= has extra text (help)

 This article incorporates text from a publication now in the public domain: Chisholm, Hugh, ed. (1911). Encyclopædia Britannica (11th ed.). Cambridge University Press. {{cite encyclopedia}}: Missing or empty |title= (help)

External links

• Tree of Life web project: Lophiiformes

• Anglerfish photos

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