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Opah

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(Redirected from Lampridae)

Opah
Temporal range: Late Miocene–present [1]
Lampris guttatus
Scientific classification Edit this classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Actinopterygii
Order: Lampriformes
Family: Lampridae
Gill, 1862
Genus: Lampris
Retzius, 1799
Species

See text

Opahs, also commonly known as moonfish, sunfish, cowfish (not to be confused with Molidae), kingfish, and redfin ocean pan are large, colorful, deep-bodied pelagic lampriform fishes comprising the small family Lampridae (also spelled Lamprididae).

The family comprises two genera: Lampris (from Ancient Greek λαμπρός (lamprós) 'brilliant, clear') and the monotypic Megalampris[2] (known only from fossil remains). The extinct family, Turkmenidae, from the Paleogene of Central Asia, is closely related, though much smaller.

In 2015, Lampris guttatus was discovered to have near-whole-body endothermy[3][4][5] in which the entire core of the body is maintained at around 5 °C above the surrounding water. This is unique among fish as most fish are entirely cold blooded or are capable of warming only some parts of their bodies.

Species

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Two living species were traditionally recognized, but a taxonomic review in 2018 found that more should be recognized (the result of splitting L. guttatus into several species, each with a more restricted geographic range), bringing the total to six.[6] The six species of Lampris have mostly non-overlapping geographical ranges, and can be recognized based on body shape and coloration pattern.[6]

Extinct species

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Description

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Lampris guttatus

Opahs are deeply keeled, compressed, discoid fish with conspicuous coloration: the body is a deep red-orange grading to rosy on the belly, with white spots covering the flanks. Both the median and paired fins are a bright vermilion. The large eyes stand out, as well, ringed with golden yellow. The body is covered in minute cycloid scales and its silvery, iridescent guanine coating is easily abraded.

Opahs closely resemble in shape the unrelated butterfish (family Stromateidae). Both have falcated (curved) pectoral fins and forked, emarginated (notched) caudal fins. Aside from being significantly larger than butterfish, opahs have enlarged, falcated pelvic fins with about 14 to 17 rays, which distinguish them from superficially similar carangids—positioned thoracically; adult butterfish lack pelvic fins. The pectorals of opahs are also inserted (more or less) horizontally rather than vertically. The anterior portion of an opah's single dorsal fin (with about 50–55 rays) is greatly elongated, also in a falcated profile similar to the pelvic fins. The anal fin (around 34 to 41 rays) is about as high and as long as the shorter portion of the dorsal fin, and both fins have corresponding grooves into which they can be depressed.

The snout is pointed and the mouth small, toothless, and terminal. The lateral line forms a high arch over the pectoral fins before sweeping down to the caudal peduncle. The larger species, Lampris guttatus, may reach a total length of 2 m (6.6 ft) and a weight of 270 kg (600 lb). The lesser-known Lampris immaculatus reaches a recorded total length of just 1.1 m (3.6 ft).

Endothermy

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Skeleton

The opah is the only fish known to exhibit whole body endothermy where all the internal organs are kept at a higher temperature than the surrounding water.[3] This feature allows opahs to maintain an active lifestyle in the cold waters they inhabit.[5] Unlike birds and mammals, the opah is not a homeotherm despite being an endotherm: while its body temperature is raised above the surrounding water temperature, it still varies with the external temperature and is not held constant.[8] In addition to whole body endothermy, the opah also exhibits regional endothermy by raising the temperature of its brain and eyes above that of the rest of the body.[8] Regional endothermy also arose by convergent evolution in tuna, lamnid sharks and billfishes where the swimming muscles and cranial organs are maintained at an elevated temperature compared to the surrounding water.

The large muscles powering the pectoral fins generate most of the heat in the opah. In addition to the heat they generate while moving, these muscles have special regions that can generate additional heat without contracting.[9] The opah has a thick layer of fat that insulates its internal organs and cranium from the surrounding water. However, fat alone is insufficient to retain heat within a fish's body. The gills are the main point of heat loss in fishes as this is where blood from the entire body must continuously be brought in close contact with the surrounding water. Opahs prevent heat loss through their gills using a special structure in the gill blood vessels called the rete mirabile. The rete mirabile is a dense network of blood vessels where the warm blood flowing from the heart to the gills transfers its heat to the cold blood returning from the gills. Hence, the rete mirabile prevents warm blood from coming in contact with the cold water (and losing its heat) and also ensures that the blood returning to the internal organs is warmed up to body temperature. Within the rete, the warm and cold blood flow past each other in opposite directions through thin vessels to maximise the heat transferred. This mechanism is called a counter-current heat exchanger.

In addition to the rete mirabile in its gills, the opah also has a rete in the blood supply to its brain and eyes. This helps to trap heat in the cranium and further raise its temperature above the rest of the body. While the rete mirabile in the gills is unique to the opah,[3] the cranial rete mirabile has also evolved independently in other fishes. Unlike in billfish which have a specialised noncontractile tissue that functions as a brain heater, the opah cranium is heated by the contractions of the large eye muscles.[8]

Behavior

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Almost nothing is known of opah biology and ecology. They are presumed to live out their entire lives in the open ocean, at mesopelagic depths of 50 to 500 m, with possible forays into the bathypelagic zone. They are apparently solitary, but are known to school with tuna and other scombrids. The fish propel themselves by a lift-based labriform mode of swimming, that is, by flapping their pectoral fins. This, together with their forked caudal fins and depressible median fins, indicates they swim at constantly high speeds like tuna.

Lampris guttatus are able to maintain their eyes and brain at 2 °C warmer than their bodies, a phenomenon called cranial endothermy and one they share with sharks in the family Lamnidae, billfishes, and some tunas.[10][11] This may allow their eyes and brains to continue functioning during deep dives into water below 4 °C.[10]

Squid and euphausiids (krill) make up the bulk of the opah diet; small fish are also taken. Pop-up archival transmitting tagging operations have indicated that, aside from humans, large pelagic sharks, such as great white sharks and mako sharks, are primary predators of opah. The tetraphyllidean tapeworm, Pelichnibothrium speciosum, has been found in L. guttatus, which may be an intermediate or paratenic host.[12]

The planktonic opah larvae initially resemble those of certain ribbonfishes (Trachipteridae), but are distinguished by the former's lack of dorsal and pelvic fin ornamentation. The slender hatchlings later undergo a marked and rapid transformation from a slender to deep-bodied form; this transformation is complete by 10.6 mm standard length in L. guttatus. Opahs are believed to have a low population resilience.

References

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  1. ^ Sepkoski, Jack (2002). "A compendium of fossil marine animal genera". Bulletins of American Paleontology. 364: 560. Archived from the original on 20 February 2009. Retrieved 8 January 2008.
  2. ^ a b Gottfried, Michael D., Fordyce, R. Ewan, Rust, Seabourne. Journal of Vertebrate Paleontology. "Megalampris keyesi, A Giant Moonfish (Teleostei, Lampridiformes), from the Late Oligocene of New Zealand". pp. 544–551.
  3. ^ a b c Wegner, Nicholas C.; Snodgrass, Owyn E.; Dewar, Heidi; Hyde, John R. (15 May 2015). "Whole-body endothermy in a mesopelagic fish, the opah, Lampris guttatus". Science. 348 (6236): 786–789. doi:10.1126/science.aaa8902. ISSN 0036-8075. PMID 25977549. Retrieved 18 February 2021.
  4. ^ Pappas, Stephanie; LiveScience. "First Warm-Blooded Fish Discovered". Scientific American. Retrieved 15 May 2015.
  5. ^ a b "Warm Blood Makes Opah an Agile Predator". Fisheries Resources Division of the Southwest Fisheries Science Center of the National Oceanic and Atmospheric Administration. 12 May 2015. Retrieved 15 May 2015. "New research by NOAA Fisheries has revealed the opah, or moonfish, as the first fully warm-blooded fish that circulates heated blood throughout its body..."
  6. ^ a b c d e f g Karen E. Underkoffler; Meagan A. Luers; John R. Hyde; Matthew T. Craig (2018). "A Taxonomic Review of Lampris guttatus (Brünnich 1788) (Lampridiformes; Lampridae) with Descriptions of Three New Species". Zootaxa. 4413 (3): 551–565. doi:10.11646/zootaxa.4413.3.9. PMID 29690102.
  7. ^ David, Lore Rose. 10 January 1943. Miocene Fishes of Southern California The Society
  8. ^ a b c Runcie, Rosa M.; Dewar, Heidi; Hawn, Donald R.; Frank, Lawrence R.; Dickson, Kathryn A. (15 February 2009). "Evidence for cranial endothermy in the opah (Lampris guttatus)". Journal of Experimental Biology. 212 (4): 461–470. doi:10.1242/jeb.022814. eISSN 1477-9145. ISSN 0022-0949. PMC 2726851. PMID 19181893. Retrieved 18 February 2021.
  9. ^ Legendre, Lucas J.; Davesne, Donald (2 March 2020). "The evolution of mechanisms involved in vertebrate endothermy". Philosophical Transactions of the Royal Society B: Biological Sciences. 375 (1793): 20190136. doi:10.1098/rstb.2019.0136. PMC 7017440. Retrieved 20 February 2021.
  10. ^ a b Bray, Dianne. "Opah, Lampris guttatus". Fishes of Australia. Archived from the original on 18 May 2015. Retrieved 16 September 2014.
  11. ^ Moyle, Peter B. (2004). Fishes : an introduction to ichthyology. Cech, Joseph J. (5th ed.). Upper Saddle River, NJ: Pearson Prentice Hall. ISBN 0-13-100847-1. OCLC 52386194.
  12. ^ Scholz et al., 1998.