Remora

This article is about the remora family. For the genus, see Remora (genus). For the rescue vehicle, see Australian Submarine Rescue Vehicle Remora.
Remora
Common remora, Remora remora
Scientific classification
Kingdom: Animalia
Phylum: Chordata
Class: Actinopterygii
Order: Perciformes
Suborder: Percoidei
Superfamily: Percoidea
Family: Echeneidae
Rafinesque, 1810
Genera
Synonyms

Echeneididae

The remoras (remora pronounced /rəˈmɔːrə/ or /ˈrɛmərə/), sometimes called suckerfish, are a family (Echeneidae) of ray-finned fish in the order Perciformes.[1][2] They grow to 7–75 cm (2.8 in–2 ft 5.5 in) long, and their distinctive first dorsal fins take the form of a modified oval, sucker-like organ with slat-like structures that open and close to create suction and take a firm hold against the skin of larger marine animals.[3] By sliding backward, the remora can increase the suction, or it can release itself by swimming forward. Remoras sometimes attach to small boats. They swim well on their own, with a sinuous, or curved, motion.

Characteristics

Remoras have their front dorsal fins modified into large suckers with which they cling onto a host animal such as a whale, turtle, shark or ray. It is probably a commensal arrangement as the remora can move around on the host, removing ectoparasites and loose flakes of skin, while benefiting from the protection provided by the host, and the constant flow of water across its gills.[4] Although it was initially believed that remoras fed off particulate matter from the host's meals, this has been shown a falsehood, in reality their diets are primarily composed of host feces instead.[5]

Habitat

Some remoras, such as this Echeneis naucrates, may attach themselves to scuba divers.

Remoras are primarily tropical open-ocean dwellers, occasionally found in temperate or coastal waters if they have attached to large fish that have wandered into these areas. In the mid-Atlantic, spawning usually takes place in June and July; in the Mediterranean, it occurs in August and September. The sucking disc begins to show when the young fish are about 1 cm (0.4 in) long. When the remora reaches about 3 cm (1.2 in), the disc is fully formed and the remora can then attach to other animals. The remora's lower jaw projects beyond the upper, and the animal lacks a swim bladder.[1]

Some remoras associate primarily with specific host species. They are commonly found attached to sharks, manta rays, whales, turtles, and dugongs (hence the common names "sharksucker" and "whalesucker"). Smaller remoras also fasten onto fish such as tuna and swordfish, and some small remoras travel in the mouths or gills of large manta rays, ocean sunfish, swordfish and sailfish.

The relationship between a remora and its host is most often taken to be one of commensalism, specifically phoresy. Though it was originally thought that the host to which it attaches for transport gains nothing from the relationship, research[6] indicates that hosts also benefit, given that remoras feed on parasites (such as copepods) and clean sloughing epidermal tissue as well as ingesting scraps of food, feces, and small nekton and zooplankton. The remora benefits by using the host as transport and protection, and also feeds on materials dropped by the host. Controversy surrounds whether a remora's diet is primarily leftover fragments, or the feces of the host. In some species (Echeneis naucrates and E. neucratoides), consumption of host feces is strongly indicated in gut dissections. For other species, such as those found in a host's mouth, scavenging of leftovers is more likely. On rare and even more rarely filmed occasions, such as the 2010 episode of Shark Week known as "Shark City", remoras that associate with sharks may end up as their prey as was the case with a Lemon shark consuming a remora after noticing the remora attempting to adhere to it.

Physiology

Research into the physiology of the remora has been of significant benefit to the understanding of ventilation costs in fish.

Remoras, like many other fishes, have two different modes of ventilation. Ram ventilation[7] is the process in which at higher speeds, the remora uses the force of the water moving past it to create movement of fluid in the gills. Alternatively, at lower speeds the remora will use a form of active ventilation,[7] in which the fish actively moves fluid through its gills. In order to use active ventilation, a fish must actively use energy to move the fluid; however, determining this energy cost is normally complicated due to the movement of the fish when using either method. As a result, the remora has proved invaluable in finding this cost difference, (since they will stick to a shark or tube, and hence remain stationary despite the movement or lack thereof of water.) Experimental data from studies on Remora found that the associated cost for active ventilation created a 3.7–5.1% increased energy consumption in order to maintain the same quantity of fluid flow the fish obtained by using ram ventilation.[8]

Other research into the remora's physiology came about as a result of studies across multiple taxa, or using the remora as an out-group for certain evolutionary studies. Concerning the latter case, remoras were used as an outgroup when investigating tetrodotoxin resistance in remoras, pufferfish, and related species, finding remoras (specifically Echeneis naucrates) had a resistance of 6.1–5.5×108 M.[9]

Use for fishing

Some cultures use remoras to catch turtles. A cord or rope is fastened to the remora's tail, and when a turtle is sighted, the fish is released from the boat; it usually heads directly for the turtle and fastens itself to the turtle's shell, and then both remora and turtle are hauled in. Smaller turtles can be pulled completely into the boat by this method, while larger ones are hauled within harpooning range. This practice has been reported throughout the Indian Ocean, especially from eastern Africa near Zanzibar and Mozambique,[10] and from northern Australia near Cape York and Torres Strait.[11][12]

Similar reports come from Japan and from the Americas. Some of the first records of the "fishing fish" in the Western literature come from the accounts of the second voyage of Christopher Columbus. However, Leo Wiener considers the Columbus accounts to be apocryphal: what was taken for accounts of the Americas may have been, in fact, notes Columbus derived from accounts of the East Indies, his desired destination.[13]

Mythology

See also: Echeneis

In ancient times, the remora was believed to stop a ship from sailing. In Latin, remora means "delay", while the genus name Echeneis comes from Greek εχειν, echein ("to hold") and ναυς, naus ("a ship"). In a notable account by Pliny the Elder, the remora is blamed for the defeat of Mark Antony at the Battle of Actium and, indirectly, for the death of Caligula.[14] A modern version of the story is given by Jorge Luis Borges in Book of Imaginary Beings (1957).

Because of the shape of the jaws, appearance of the sucker, and coloration of the remora, it sometimes appears to be swimming upside down. This probably led to the older common name reversus, although this might also derive from the fact that the remora frequently attaches itself to the tops of manta rays or other fish, so that the remora is upside down while attached.

Timeline

Quaternary Neogene Paleogene Holocene Pleist. Miocene Oligocene Eocene Paleocene Echeneis Quaternary Neogene Paleogene Holocene Pleist. Miocene Oligocene Eocene Paleocene

See also

References

  1. 1 2 Froese, Rainer, and Daniel Pauly, eds. (2013). "Echeneidae" in FishBase. April 2013 version.
  2. "Echeneidae". Integrated Taxonomic Information System. Retrieved 20 March 2006.
  3. "Sharksucker fish's strange disc explained". Natural History Museum. 28 January 2013. Archived from the original on 1 February 2013. Retrieved 5 February 2013.
  4. Jackson, John (30 November 2012). "How does the Remora develop its sucker?". National History Museum. Retrieved 2 January 2016.
  5. Williams, E. H.; Mignucci-Giannoni, A. A.; Bunkley-Williams, L.; Bonde, R. K.; Self-Sullivan, C.; Preen, A.; Cockcroft, V. G. (2003). "Echeneid-sirenian associations, with information on sharksucker diet". Journal of Fish Biology. 63 (5): 1176. doi:10.1046/j.1095-8649.2003.00236.x.
  6. Cressey, R.; Lachner, E. (1970). "The parasitic copepod diet and life history of diskfishes (Echeneidae)". Copeia. 1970 (2): 310–318. doi:10.2307/1441652. JSTOR 1441652.
  7. 1 2 Willmer, Pat; Stone, Graham; Johnston, Ian (2009-03-12). Environmental Physiology of Animals. John Wiley & Sons. ISBN 9781444309225.
  8. Steffensen, J. F.; Lomholt, J. P. (1983-03-01). "Energetic cost of active branchial ventilation in the sharksucker, Echeneis naucrates". Journal of Experimental Biology. 103 (1): 185–192. ISSN 0022-0949. PMID 6854201.
  9. Kidokoro, Yoshiaki; Grinnell, Alan D.; Eaton, Douglas C. (1974). "Tetrodotoxin sensitivity of muscle action potentials in pufferfishes and related fishes". Journal of Comparative Physiology. 89: 59. doi:10.1007/BF00696163.
  10. Gudger, E. W. (1919). "On the Use of the Sucking-Fish for Catching Fish and Turtles: Studies in Echeneis or Remora, II., Part 1.". The American Naturalist. 53 (627): 289–311. doi:10.1086/279716. JSTOR 2455925.
  11. Gudger, E. W. (1919). "On the Use of the Sucking-Fish for Catching Fish and Turtles: Studies in Echeneis or Remora, II., Part 2". The American Naturalist. 53 (628): 446–467. doi:10.1086/279724. JSTOR 2456185.
  12. MacGillivray, John (1852). Narrative of the Voyage of H.M.S. Rattlesnake, Commanded By the Late Captain Owen Stanley, R.N., F.R.S. Etc. During the Years 1846–1850. 2. London: Lords Commissioners of the Admiralty. (Dr. Gudger's accounts are more authoritative, but this source is noted as an early account that Gudger appears to have missed.)
  13. Wiener, Leo (1921). "Once more the sucking-fish". The American Naturalist. 55 (637): 165–174. doi:10.1086/279802. JSTOR 2456418.
  14. Pliny the Elder. "Book 32, Chapter 1". Natural History. (cited in Gudger, E. W. (1930). "Some old time figures of the shipholder, Echeneis or Remora, holding the ship". Isis. 13 (2): 340–352. doi:10.1086/346461. JSTOR 224651.)
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