Coral reef fish

Coral reef fish are fish which live amongst or in close relation to coral reefs. Coral reefs form complex ecosystems with tremendous biodiversity. Among the myriad inhabitants, the fish stand out as colourful and interesting to watch. Hundreds of species can exist in a small area of a healthy reef, many of them hidden or well camouflaged. Reef fish have developed many ingenious specialisations adapted to survival on the reefs.

The fish that inhabit coral reefs are numerous and diverse

Coral reefs occupy less than 1% of the surface area of the world oceans, but provide a home for 25% of all marine fish species. Reef habitats are a sharp contrast to the open water habitats that make up the other 99% of the world oceans.

However, loss and degradation of coral reef habitat, increasing pollution, and overfishing including the use of destructive fishing practices, are threatening the survival of the coral reefs and the associated reef fish.

Overview

In the foreground is an orange-lined triggerfish displaying spines. Triggerfish have mouths that crush shells. Orange-lined triggerfish are particularly aggressive. The black and white fish are three-stripe damselfish and the unstriped fish are blue-green chromis damselfish. If the triggerfish attacks, the damselfish will hide in the nearby cauliflower coral. If the triggerfish wants to hide, it will squeeze into a coral crevice and lock itself in place with its spines.

Coral reefs are the result of millions of years of coevolution among algae, invertebrates and fish. They have become crowded and complex environments, and the fish have evolved many ingenious ways of surviving.[1] Most fishes found on coral reefs are ray-finned fishes, known for the characteristic sharp, bony rays and spines in their fins.[1] These spines provide formidable defences, and when erected they can usually be locked in place or are venomous. Many reef fish have also evolved cryptic coloration to confuse predators.[2]

Reef fish have also evolved complex adaptive behaviours. Small reef fish get protection from predators by hiding in reef crevices or by shoaling and schooling. Many reef fish confine themselves to one small neighbourhood where every hiding place is known and can be immediately accessed. Others cruise the reefs for food in shoals, but return to a known area to hide when they are inactive. Resting small fish are still vulnerable to attack by crevice predators, so many fish, such as triggerfish, squeeze into a small hiding place and wedge themselves by erecting their spines.[2]

As an example of the adaptations made by reef fish, the yellow tang is a herbivore which feeds on benthic turf algae. They also provide cleaner services to marine turtles, by removing algal growth from their shells. They do not tolerate other fish with the same colour or shape. When alarmed, the usually placid yellow tang can erect spines in its tail and slash at its opponent with rapid sideways movements.

Diversity and distribution

Distribution of coral reefs

Coral reefs contain the most diverse fish assemblages to be found anywhere on earth, with perhaps as many as 6,000–8,000 species dwelling within coral reef ecosystems of the world's oceans.[3]

The mechanisms that first led to, and continue to maintain, such concentrations of fish species on coral reefs has been widely debated over the last 50 years. While many reasons have been proposed, there is no general scientific consensus on which of these is the most influential, but it seems likely that a number of factors contribute. These include the rich habitat complexity and diversity inherent in coral reef ecosystems,[4][5] the wide variety and temporal availability of food resources available to coral reef fishes,[6] a host of pre and post-larval settlement processes,[7] and as yet unresolved interactions between all these factors. The wealth of fishes on reefs is filled by tiny, bottom-dwelling reef fishes.[8]

There are two major regions of coral reef development recognized; the Indo-Pacific (which includes the Pacific and Indian Oceans as well as the Red Sea), and the tropical western Atlantic (also known as the "wider" or "greater" Caribbean). Each of these two regions contains its own unique coral reef fish fauna with no natural overlap in species. Of the two regions, the richest by far in terms of reef fish diversity is the Indo-Pacific where there are an estimated 4,000–5,000 species of fishes associated with coral reef habitats. Another 500–700 species can be found in the greater Caribbean region.[3]

Reef fish adaptations

Contrast between coral reef and open water fishes
Many reef fish, like this queen angelfish, have a body flattened like a pancake, with pectoral and pelvic fins that act with the flattened body to maximize manoeuvrability.
In contrast, open water fish like this Atlantic bluefin tuna, are usually streamlined for straightline speed, with a deeply forked tail and a smooth body shaped like a spindle tapered at both ends. They are countershaded with silvery colours.

Body shape

Most reef fishes have body shapes that are different from open water fishes. Open water fish are usually built for speed in the open sea, streamlined like torpedoes to minimise friction as they move through the water. Reef fish are operating in the relatively confined spaces and complex underwater landscapes of coral reefs. For this manoeuvrability is more important than straight line speed, so coral reef fish have developed bodies which optimize their ability to dart and change direction. They outwit predators by dodging into fissures in the reef or playing hide and seek around coral heads.[14]

Many reef fish, such as butterflyfish and angelfishes, have evolved bodies which are deep and laterally compressed like a pancake. Their pelvic and pectoral fins are designed differently, so they act together with the flattened body to optimise manoeuvrability.[14]

Colouration

The psychedelic Synchiropus splendidus is one of only two animal species known to have blue colouring because of cellular pigment.[15]
The well camouflaged striated frogfish, a species of anglerfish, is an ambush predator.
Clown triggerfish. The colouration of triggerfish fade into drabness when they sleep or are being submissive, and return to vividness when they are not threatened.

Coral reef fishes exhibit a huge variety of dazzling and sometimes bizarre colours and patterns. This is in marked contrasts to open water fishes which are usually countershaded with silvery colours.

The patterns have different functions. Sometimes they camouflage the fish when the fish rests in places with the right background. Colouration can also be used to help species recognition during mating. Some unmistakable contrasting patterns are used to warn predators that the fish has venomous spines or poisonous flesh.[14]

The foureye butterflyfish gets its name from a large dark spot on the rear portion of each side of the body. This spot is surrounded by a brilliant white ring, resembling an eyespot. A black vertical bar on the head runs through the true eye, making it hard to see.[16] This can result in a predator thinking the fish is bigger than it is, and confusing the back end with the front end. The butterflyfish's first instinct when threatened is to flee, putting the false eyespot closer to the predator than the head. Most predators aim for the eyes, and this false eyespot tricks the predator into believing that the fish will flee tail first. When escape is not possible, the butterflyfish will sometimes turn to face its aggressor, head lowered and spines fully erect, like a bull about to charge. This may serve to intimidate the other animal or may remind the predator that the butterflyfish is too spiny to make a comfortable meal.

The psychedelic Synchiropus splendidus (right) is not easily seen due to its bottom-feeding habit and its small size, reaching only about 6 cm. It feeds primarily on small crustaceans and other invertebrates, and is popular in the aquarium trade.

Just as some prey species evolved cryptic colouration and patterns to help avoid predators, some ambush predators evolved camouflage that lets them ambush their prey. The tasseled scorpionfish is an ambush predator that looks like part of a sea floor encrusted with coral and algae. It lies in wait on the sea floor for crustaceans and small fish, such as gobies, to pass by.[17] Another ambush predator is the striated frogfish (right). They lie on the bottom and wave a conspicuous worm-like lure strategically attached above their mouth. Normally about 10 cm (4 in) long, they can also inflate themselves like puffers.[18][19]

Gobies avoid predators by tucking themselves into coral crevices or partly burying themselves in sand. They continually scan for predators with eyes that swivel independently. The camouflage of the tasseled scorpionfish can prevent gobies from seeing them until it's too late.[17]

The clown triggerfish has strong jaws for crushing and eating sea urchins, crustaceans and hard-shell molluscs. Its ventral (lower) surface has large, white spots on a dark background, and its dorsal (upper) surface has black spots on yellow.[20] This is a form of countershading: from below, the white spots look like the lighted surface of the water above; and from above, the fish blends more with the coral reef below. The brightly painted yellow mouth may deter potential predators.[21]

Feeding strategies

Many reef fish species have evolved different feeding strategies accompanied by specialized mouths, jaws and teeth particularly suited to deal with their primary food sources found in coral reef ecosystems. Some species even shift their dietary habits and distributions as they mature.[22] This is not surprising, given the huge variety in the types of prey on offer around coral reefs.[14]

For example, the primary food source of butterflyfishes are the coral polyps themselves or the appendages of polychaetes and other small invertebrate animals. Their mouths protrude like forceps, and are equipped with fine teeth that allow them to nip off such exposed body parts of their prey. Parrotfishes eat algae growing on reef surfaces, utilizing mouths like beaks well adapted to scrape off their food. Other fish, like snapper, are generalized feeders with more standard jaw and mouth structures that allow them to forage on a wide range of animal prey types, including small fishes and invertebrates.[14]

Generalized carnivores

Red snapper, are generalized reef feeders with standard jaw and mouth structures that allow them to eat almost anything, though they prefer small fish and crustaceans.

Carnivores are the most diverse of feeding types among coral reef fishes. There are many more carnivore species on the reefs than herbivores. Competition among carnivores is intense, resulting in a treacherous environment for their prey. Hungry predators lurk in ambush or patrol every part of the reef, night and day.[23]

Some fishes associated with reefs are generalized carnivores that feed on a variety of animal prey. These typically have large mouths that can be rapidly expanded, thereby drawing in nearby water and any unfortunate animals contained within the inhaled water mass. The water is then expelled through the gills with the mouth closed, thereby trapping the helpless prey[14] For example, the bluestripe snapper has a varied diet, feeding on fishes, shrimps, crabs, stomatopods, cephalopods and planktonic crustaceans, as well as plant and algae material. Diet varies with age, location and the prevalent prey items locally.[24]

Goatfish are tireless benthic feeders, using a pair of long chemosensory barbels (whiskers) protruding from their chins to rifle through the sediments in search of a meal. Like goats, they seek anything edible: worms, crustaceans, molluscs and other small invertebrates are staples.[25] The yellowfin goatfish (Mulloidichthys vanicolensis) often schools with the blue-striped snapper. The yellowfins change their colouration to match that of the snapper. Presumably this is for predator protection, since goatfish are a more preferred prey than bluestripe snapper. By night the schools disperse and individual goatfish head their separate ways to loot the sands. Other nocturnal feeders shadow the active goatfish, waiting patiently for overlooked morsels.

Moray eels and coral groupers (Plectropomus pessuliferus) are known to cooperate with each other when hunting.[26] Grouper are protogynous hermaphrodites, who school in harems that can vary greatly in size according to the population size and reef habitat.[27] When no male is available, in each school the largest female shifts sex to male. If the final male disappears, changes to the largest female occur, with male behavior occurring within several hours and sperm production occurring within ten days.[28]

Specialised carnivores

Large schools of forage fish, such as surgeonfish and cardinalfish, move around the reef feeding on tiny zooplankton. The forage fish are, in turn, eaten by larger fish, such as the bigeye trevally. Fish receive many benefits from schooling behaviour, including defence against predators through better predator detection, since each fish is on the lookout. Schooling fish have developed remarkable displays of precise choreography which confuse and evade predators. For this they have evolved special pressure sensors along their sides, called lateral lines, that let them feel each other's movements and stay synchronized.[17]

Bigeye trevally also form schools. They are swift predators who patrol the reef in hunting packs. When they find a school of forage fish, such as cardinalfish, they surround them and herd them close to the reef. This panics the prey fish, and their schooling becomes chaotic, leaving them open to attack by the trevally.[17]

The titan triggerfish can move relatively large rocks when feeding and is often followed by smaller fishes that feed on leftovers. They also use a jet of water to uncover sand dollars buried in sand.

Barracuda are ferocious predators on other fishes, with razor-sharp conical teeth which make it easy for them to rip their prey to shreds. Barracuda patrol the outer reef in large schools, and are extremely fast swimmers with streamlined, torpedo-shaped bodies.[17]

Porcupinefish are medium to large sized, and are usually found swimming among or near coral reefs. They inflate their body by swallowing water, reducing potential predators to those with much bigger mouths.

External image
Giant moray with cleaner wrasses
Porcupinefish with cleaner wrasses

Fish can not groom themselves. Some fish specialise as cleaner fish, and establish cleaning stations where other fish can come to have their parasites nibbled away. The "resident fish doctor and dentist on the reef is the bluestreak cleaner wrasse".[23] The bluestreak is marked with a conspicuous bright blue stripe and behaves in a stereotypical way which attracts larger fish to its cleaning station. As the bluestreak snacks on the parasites it gently tickles its client. This seems to bring the larger fish back again for regular servicing.[23]

The reef lizardfish secretes a mucus coating which reduces drag when they swim and also protects it from some parasites. But other parasites find the mucus itself good to eat. So lizardfish visit the cleaner wrasse, which clean the parasites from the skin, gills and mouth.[23]

Herbivores

Surgeonfish are among the most common of coral reef herbivores, often feeding in shoals. This may be a mechanism for overwhelming the highly aggressive defence responses of small territorial damselfishes that vigorously guard small patches of algae on coral reefs.[29]

Herbivores feed on plants. The four largest groups of coral reef fishes that feed on plants are the parrotfishes, damselfishes, rabbitfishes, and surgeonfishes. All feed primarily on microscopic and macroscopic algae growing on or near coral reefs.

Algae can drape reefs in kaleidoscopes of colours and shapes. Algae are primary producers, which means they are plants synthesising food directly from solar energy and carbon dioxide and other simple nutrient molecules. Without algae, everything on the reef would die. One important algal group, the bottom dwelling (benthic) algae, grows over dead coral and other inert surfaces, and provides grazing fields for herbivores such as parrotfish.[17]

Parrotfish are named for their parrot-like beaks and bright colours. They are large herbivores that graze on the algae that grows on hard dead corals. Equipped with two pairs of crushing jaws and their beaks, they pulverize chunks of algae-coated coral, digesting the algae and excreting the coral as fine sand.[17]

Smaller parrotfish are relatively defenceless herbivores, poorly defended against predators like barracuda. They have evolved to find protection by schooling, sometimes with other species like shoaling rabbitfish. Spinefoot rabbitfish are named for their defensive venomous spines, and they are seldom attacked by predators. Spines are a last-ditch defence. It is better to avoid predator detection in the first place, and avoid being thrust into risky spine-to-fang battles. So rabbitfish have also evolved skilful colour changing abilities.[23]

Damselfish are a group of species that feed on zooplankton and algae, and are an important reef forage fish for larger predators. They are small, typically five centimetres (two inches) long. Many species are aggressive towards other fishes which also graze on algae, such as surgeonfish. Surgeonfish sometimes use schooling as a countermeasure to defensive attacks by solitary damselfish.[29]

Symbiosis

A hawkfish, safely perched on Acropora, surveys its surroundings

Symbiosis refers to two species that have a close relationship with each other. The relationship can be mutualistic, when both species benefit from the relationship, commensalistic, when one species benefits and the other is unaffected, and parasitistic, when one species benefits, and the other is harmed.

An example of commensalism occurs between the hawkfish and fire coral. Thanks to their large, skinless pectoral fins, hawkfish can perch on fire corals without harm. Fire corals are not true corals, but are hydrozoans possessing stinging cells called nematocysts which would normally prevent close contact. The protection fire corals offer hawkfish means the hawkfish has the high ground of the reef, and can safely survey its surroundings like a hawk. Hawkfish usually stay motionless, but dart out and grab crustaceans and other small invertebrates as they pass by. They are mostly solitary, although some species form pairs and share a head of coral.

A more bizarre example of commensalism occurs between the slim, eel-shaped pinhead pearlfish and a particular species of sea cucumber. The pearlfish enters the sea cucumber through its anus, and spends the day safely protected inside the seacucumbers alimentary tract. At night it emerges the same way and feeds on small crustaceans.[30]

External images
Perlfish emerging from a sea cucumber
Clownfish swimming among coral

Sea anemones are common on reefs. The tentacles of sea anemones bristle with tiny harpoons (nematocysts) primed with toxins, and are an effective deterrent against most predators. However, saddle butterflyfish, which are up to 30 cm (12 in) long, have developed a resistance to these toxins. Saddle butterflyfish usually flutter gently rather than swim. However, in the presence of their preferred food, sea anemones, this gentleness disappears, and the butterflyfish dash in and out, ripping off the anemone tentacles.[17]

Monogenean parasites of the genus Pseudorhabdosynochus (arrows) on the gill filament of a grouper.

There is a mutualistic relationship between sea anemones and clownfish. This gives the sea anemones a second line of defence. They are guarded by fiercely territorial clownfish, who are also immune to the anemone toxins. To get their meal, butterflyfish must get past these protective clownfish who, although smaller, are not intimidated. An anemone without its clownfish will quickly be eaten by butterflyfish.[17] In return, the anemones provide the clownfish protection from their predators, who are not immune to anemone stings. As a further benefit to the anemone, waste ammonia from the clownfish feed symbiotic algae found in the anemone's tentacles.[31][32]

As with all fish, coral reef fish harbour parasites.[33] Since coral reef fish are characterized by high biodiversity, parasites of coral reef fish show tremendous variety. Parasites of coral reef fish include nematodes, Platyhelminthes (cestodes, digeneans, and monogeneans), leeches, parasitic crustaceans such as isopods and copepods,[34][35][36] and various microorganisms such as myxosporidia and microsporidia. Some of these fish parasites have heteroxenous life cycles (i.e. they have several hosts) among which sharks (certain cestodes) or molluscs (digeneans). The high biodiversity of coral reefs increases the complexity of the interactions between parasites and their various and numerous hosts. Numerical estimates of parasite biodiversity have shown that certain coral fish species have up to 30 species of parasites.[33][34] [35][36] The mean number of parasites per fish species is about ten.[34][35][36] This has a consequence in term of co-extinction. Results obtained for the coral reef fish of New Caledonia suggest that extinction of a coral reef fish species of average size would eventually result in the co-extinction of at least ten species of parasites.[36]

Toxicity

Head-on view of the venomous lionfish[37]

Many reef fish are toxic. Toxic fish are fish which contain strong toxins in their bodies. There is a distinction between poisonous fish and venomous fish. Both types of fish contain strong toxins, but the difference is in the way the toxin is delivered. Venomous fish deliver their toxins (called venom) by biting, stinging, or stabbing, causing an envenomation. Venomous fish don't necessarily cause poisoning if they are eaten, since the venom is often destroyed in the digestive system. By contrast, poisonous fish contain strong toxins which are not destroyed by the digestive system. This makes them poisonous to eat.[38]

Venomous fish carry their venom in venom glands and use various delivery systems, such as spines or sharp fins, barbs or spikes, and fangs. Venomous fish tend to be either very visible, using flamboyant colours to warn enemies, or skilfully camouflaged and maybe buried in the sand. Apart from the defence or hunting value, venom might have value for bottom dwelling fish by killing the bacteria that try to invade their skin. Few of these venoms have been studied. They are a yet to be tapped resource for bioprospecting to find drugs with medical uses.[39]

The most venomous known fish is the reef stonefish.[40][41] It has a remarkable ability to camouflage itself amongst rocks. It is an ambush predator that sits on the bottom waiting for prey to come close. It does not swim away if disturbed, but erects 13 venomous spines along its back. For defence, it can shoot venom from each or all of these spines. Each spine is like a hypodermic needle, delivering the venom from two sacs attached to the spine. The stonefish has control over whether to shoot its venom, and does so when provoked or frightened.[39] The venom results in severe pain, paralysis and tissue death, and can be fatal if not treated. Despite its formidable defence, the stonefish does have predators. Some bottom feeding rays and sharks with crushing teeth feed on them, as does the Stokes' seasnake[42]

Unlike the stonefish which can shoot venom, the lionfish can only release venom when something strikes its spines. Although not native to the US coast, lionfish have appeared around Florida and have spread up the coast to New York. They are attractive aquarium fish, sometimes used to stock ponds, and may have been washed into the sea during a hurricane. Lionfish can aggressively dart at scuba divers and attempt to puncture the facemask with their venomous spines.[39]

The spotted trunkfish is a reef fish which secretes a colourless ciguatera toxin from glands on its skin when touched. The toxin is only dangerous when ingested, so there's no immediate harm to divers. However, predators as large as nurse sharks can die as a result of eating a trunkfish.[44] Ciguatera toxins appear to accumulate in top predators of coral reefs. Many of the Caribbean groupers and the barracuda for example may contain enough of this toxin to cause severe symptoms in humans who eat them. What makes the situation particularly dangerous is that such species may be toxic only at certain sizes or locations, making it difficult to know whether or when they are or are not safe to eat. In some locations this leads to many cases of ciguatera poisoning among tropical islanders.[45]

The stargazer buries itself in sand and can deliver electric shocks as well as venom. It is a delicacy in some cultures (the venom is destroyed when it is cooked), and can be found for sale in some fish markets with the electric organ removed. They have been called "the meanest things in creation".[39]

The giant moray is a reef fish at the top of the food chain. Like many other apex reef fish, it is likely to cause ciguatera poisoning if eaten.[46][47] Outbreaks of ciguatera poisoning in the 11th to 15th centuries from large, carnivorous reef fish, caused by harmful algal blooms, could be a reason why Polynesians migrated to Easter Island, New Zealand, and possibly Hawaii.[48][49]

Reef sharks and rays

The whitetip reef shark almost exclusively inhabits coral reefs.

whitetip, blacktip and grey reef sharks dominate the ecosystems of coral reefs in the Indo-Pacific. Coral reefs in the western Atlantic Ocean are dominated by the Caribbean reef shark. These sharks, all species of requiem shark, all have the robust, streamlined bodies typical of the requiem shark. As fast-swimming, agile predators, they feed primarily on free-swimming bony fishes and cephalopods. Other species of reef sharks include the Galapagos shark, the tawny nurse shark and hammerheads.

The whitetip reef shark is a small shark usually less than 1.6 m (5.2 ft) in length. It is found almost exclusively around coral reefs where it can be encountered around coral heads and ledges with high vertical relief, or over sandy flats, in lagoons, or near drop-offs to deeper water.[50] Whitetips prefer very clear water and rarely swim far from the bottom.[51] They spend most of the daytime resting inside caves. Unlike other requiem sharks, which usually rely on ram ventilation and must constantly swim to breathe, these sharks can pump water over their gills and lie still on the bottom. They have slender, lithe bodies, which allow them to wriggle into crevices and holes and extract prey inaccessible to other reef sharks. On the other hand, they are rather clumsy when attempting to take food suspended in open water.[51]

Whitetip reef sharks spend much of the day lying still on the bottom

Whitetip reef sharks do not frequent very shallow water like the blacktip reef shark, nor the outer reef like the grey reef shark.[52] They generally remain within a highly localized area. An individual shark may use the same cave for months to years. The daytime home range of a whitetip reef shark is limited to about 0.05 km2 (0.019 sq mi); at night this range increases to 1 km2 (0.39 sq mi).[53]

The whitetip reef shark is highly responsive to olfactory, acoustic, and electrical cues given off by potential prey. Its visual system is attuned more to movement and/or contrast than to object details.[50][54][55] It is especially sensitive to natural and artificial low-frequency sounds in the 25–100 Hz range, which evoke struggling fish.[53] Whitetips hunt primarily at night, when many fishes are asleep and easily taken. After dusk, a group of sharks may target the same prey item, covering every exit route from a particular coral head. Each shark hunts for itself and in competition with the others in its group.[50] They feed mainly on bony fishes, including eels, squirrelfishes, snappers, damselfishes, parrotfishes, surgeonfishes, triggerfishes, and goatfishes, as well as octopus, spiny lobsters, and crabs.[52] Important predators of the whitetip reef shark include tiger sharks and Galapagos sharks.

Adult blacktip reef sharks often patrol reef ledges

The blacktip reef shark is typically about 1.6 m (5.2 ft) long. It is usually found over reef ledges and sandy flats, though it can also enter brackish and freshwater environments. This species likes shallow water, while the whitetip and the grey reef shark are prefer deeper water. Younger sharks favour shallow sandy flats, and older sharks spend more time around reef ledges and near reef drop-offs. Blacktip reef sharks are strongly attached to their own area, where they may remain for up to several years.[56] A tracking study off Palmyra Atoll in the central Pacific has found that the blacktip reef shark had a home range of about 0.55 km2 (0.21 sq mi), among the smallest of any shark species. The size and location of the range does not change with time of day. The blacktip reef shark swims alone or in small groups. Large social aggregations have also been observed.[52][57] They are active predators of small bony fishes, cephalopods, and crustaceans, and also feed on sea snakes and seabirds.[52] Blacktip reef sharks are preyed on by groupers, grey reef sharks, tiger sharks, and members of their own species. At Palmyra Atoll, adult blacktip reef sharks avoid patrolling tiger sharks by staying out of the central, deeper lagoon.[58]

Coral reef drop-offs are a favoured habitat for grey reef sharks

Grey reef sharks are usually less than 1.9 metres (6.2 ft) long.[52] Despite their moderate size, grey reef sharks actively expel most other shark species from favored habitats.[59] In areas where this species co-exists with the blacktip reef shark, the latter species occupy the shallow flats while the grey reef sharks stay in deeper water.[52] Many grey reef sharks have a home range on a specific area of the reef, to which they continually return. However, they are social rather than territorial. During the day, these sharks often form groups of 5–20 individuals near coral-reef drop-offs, splitting up in the evening as the sharks begin to hunt. They are found over continental and insular shelves, preferring the leeward (away from the direction of the current) sides of coral reefs with clear water and rugged topography. They are frequently found near the drop-offs at the outer edges of the reef, and less commonly within lagoons. On occasion, this shark may venture several kilometers out into the open ocean.[52][60]

Shark researcher Leonard Compagno comments on the relationship between the three species.

"[The grey reef shark] ...shows microhabitat separation from the blacktip reef sharks; around islands where both species occur, the blacktip occupies shallow flats, while the grey reef shark is usually found in deeper areas, but where the blacktip is absent, the grey reef shark is commonly found on the flats... [The grey reef shark] complements the whitetip shark as it is far more adapt at catching off-bottom fish than the whitetip, but the later is far more competent in extracting prey from crevices and holes in reefs."[52]

A Caribbean reef shark cruises a coral reef in the Bahamas.

The Caribbean reef shark is up to 3 metres (10 ft) long, one of the largest apex predators in the reef ecosystem. Like the whitetip reef shark, they have been documented resting motionless on the sea bottom or inside caves - unusual behaviour for requiem sharks. Caribbean reef sharks play a major role in shaping Caribbean reef communities. They are more active at night, with no evidence of seasonal changes in activity or migration. Juveniles tend to remain in a localized area throughout the year, while adults range over a wider area.[61] The Caribbean reef shark feeds on a wide variety of reef-dwelling bony fishes and cephalopods, as well as some elasmobranchs such as eagle rays and yellow stingrays .[62] Young sharks feed on small fishes, shrimps, and crabs.[53] In turn, young sharks are preyed on by larger sharks such as the tiger shark and the bull shark.

See also

  • Anthiinae
  • List of marine aquarium fish species – most of these fish are coral reef fish
  • List of reef fish of the Red Sea

Notes

  1. Moyle and Cech, 2003, p. 555.
  2. Moyle and Cech, 2003, p. 561.
  3. Liske and Myers, 2001.
  4. Analysis of the influence of substrate variables on coral reef fish communities. Luckhurst, B.E. and K. Luckhurst, 1978.
  5. Similarity and Diversity Among Coral Reef Fish Communities: A Comparison between Tropical Western Atlantic (Virgin Islands) and Tropical Central Pacific (Marshall Islands) Patch Reefs. Gladfelter et al. 1980
  6. Food Habits of Reef Fishes of the West Indies, Randall, J.E. 1967
  7. Coral Reef Fish Ecology, Buchheim, J.
  8. Tiny fishes fuel life on coral reefs typically evoke clear, turquoise waters and a staggering number of colourful fishes. But what supports such an abundance of life? by Amit Malewar. Published on May 24, 2019
  9. Depczynski, Martial; Bellwood, David R (2005), "Shortest recorded vertebrate lifespan found in a coral reef fish", Current Biology, 15 (8): R288-9, doi:10.1016/j.cub.2005.04.016, PMID 15854891, S2CID 22684907
  10. Guinness Book of World Records (2009)
  11. Froese, Rainer, and Daniel Pauly, eds. (2009). "Batrachoididae" in FishBase. September 2009 version.
  12. Froese, Rainer; Pauly, Daniel (eds.) (2009). "Opsanus beta" in FishBase. September 2009 version.
  13. Moyle and Cech 2003, pp. 4.
  14. Alevizon WS (1994) "Pisces Guide to Caribbean Reef Ecology" Gulf Publishing Company ISBN 1-55992-077-7
  15. Goda, M.; R. Fujii (2009). "Blue Chromatophores in Two Species of Callionymid Fish". Zoological Science. 12 (6): 811–813. doi:10.2108/zsj.12.811. S2CID 86385679.
  16. FishBaseFroese, Rainer; Pauly, Daniel (eds.) (2009). "Chaetodon capistratus" in FishBase. July 2009 version.
  17. Coral Reef Connections: Predators and Prey US Public Broadcasting Service. Retrieved 16 January 2010.
  18. Froese, Rainer; Pauly, Daniel (eds.) (2010). "Antennarius striatus" in FishBase. January 2010 version.
  19. Antennarius striatus www.frogfish.ch.
  20. Froese, Rainer; Pauly, Daniel (eds.) (2010). "Balistoides conspicillum" in FishBase. January 2010 version.
  21. Dakin, Nick (1992). The Macmillan book of the Marine Aquarium. New York: Macmillan Publishing Company. pp. 177. ISBN 0-02-897108-6.
  22. Clark, Nicholas; Russ, G (2012). "Ontogenetic shifts in the habitat associations of butterflyfishes (F. Chaetodontidae)". Environmental Biology of Fishes. 94 (4): 579–590. doi:10.1007/s10641-011-9964-2. S2CID 18103407.
  23. Coral Reef Connections: Partners US Public Broadcasting Service. Retrieved 16 January 2010.
  24. Allen, G.R. (1985). FAO Species Catalogue Vol. 6: Snappers of the World; An Annotated and Illustrated Catalogue of Lutjanid Species Known to Date. Rome: FAO. p. 207. ISBN 92-5-102321-2.
  25. Johnson, G.D.; Gill, A.C. (1998). Paxton, J.R.; Eschmeyer, W.N. (eds.). Encyclopedia of Fishes. San Diego: Academic Press. p. 186. ISBN 0-12-547665-5.
  26. Bshary, Redouan; Hohner, Andrea; Ait-el-Djoudi, Karim; Fricke, Hans (2006). "Interspecific Communicative and Coordinated Hunting between Groupers and Giant Moray Eels in the Red Sea". PLOS Biology. 4 (12): e431. doi:10.1371/journal.pbio.0040431. PMC 1750927. PMID 17147471.
  27. Kline, R.J. (2010) "Hormonal correlates of coloration and sexual change in the hermaphroditic grouper, Epinephelus adscensionis". Doctoral dissertation, University of Texas at Austin. PDF.
  28. "SEX CHANGE IN FISH FOUND COMMON." The New York Times. December 4, 1984. Retrieved on December 26, 2011.
  29. Mixed schooling and its possible significance in a tropical western Atlantic parrotfish and surgeonfish. WS Alevizon, Copeia 1976:797–798.
  30. Pearlfish (2010). In Encyclopædia Britannica. Retrieved January 30, 2010.
  31. Porat, D.; Chadwick-Furman, N. E. (2004). "Effects of anemonefish on giant sea anemones: expansion behavior, growth, and survival". Hydrobiologia. 530 (1–3): 513–520. doi:10.1007/s10750-004-2688-y. S2CID 2251533.
  32. Porat, D.; Chadwick-Furman, N. E. (2005). "Effects of anemonefish on giant sea anemones: ammonium uptake, zooxanthella content and tissue regeneration". Mar. Freshw. Behav. Phys. 38: 43–51. doi:10.1080/10236240500057929. S2CID 53051081.
  33. Justine, J.-L. 2010: Parasites of coral reef fish: how much do we know? With a bibliography of fish parasites in New Caledonia. Belgian Journal of Zoology, 140 (Suppl.), 155–190. Free PDF Archived 2016-03-07 at the Wayback Machine
  34. Justine, J-L.; Beveridge, I.; Boxshall, GA.; Bray, RA.; Moravec, F.; Trilles, JP.; Whittington, ID. (November 2010). "An annotated list of parasites (Isopoda, Copepoda, Monogenea, Digenea, Cestoda and Nematoda) collected in groupers (Serranidae, Epinephelinae) in New Caledonia emphasizes parasite biodiversity in coral reef fish". Folia Parasitol (Praha). 57 (4): 237–62. doi:10.14411/fp.2010.032. PMID 21344838. Free PDF
  35. Justine, J.-L.; Beveridge, I.; Boxshall, G. A.; Bray, R. A.; Moravec, F.; Whittington, I. D. (2010). "An annotated list of fish parasites (Copepoda, Monogenea, Digenea, Cestoda and Nematoda) collected from Emperors and Emperor Bream (Lethrinidae) in New Caledonia further highlights parasite biodiversity estimates on coral reef fish" (PDF). Zootaxa. 2691: 1–40. doi:10.11646/zootaxa.2691.1.1.
  36. Justine, J-L.; Beveridge, I.; Boxshall, GA.; Bray, RA.; Miller, TL.; Moravec, F.; Trilles, JP.; Whittington, ID. (2012). "An annotated list of fish parasites (Isopoda, Copepoda, Monogenea, Digenea, Cestoda, Nematoda) collected from Snappers and Bream (Lutjanidae, Nemipteridae, Caesionidae) in New Caledonia confirms high parasite biodiversity on coral reef fish". Aquat Biosyst. 8 (1): 22. doi:10.1186/2046-9063-8-22. PMC 3507714. PMID 22947621.
  37. Froese, Rainer; Pauly, Daniel (eds.) (2009). "Pterois volitans" in FishBase. July 2009 version.
  38. Poisonous vs. Venomous fish: What's the difference? Archived 2009-10-30 at the Wayback Machine Reef Biosearch. Retrieved 17 July 2009.
  39. Grady, Denise Venom Runs Thick in Fish Families, Researchers Learn The New York Times 22 August 2006.
  40. Froese, Rainer; Pauly, Daniel (eds.) (2009). "Synanceja verrucosa" in FishBase. July 2009 version.
  41. "The Stonefish – The Deadliest Fish in The World", Virginia Wells, Petplace.com.
  42. Reef Stonefish, Synanceia verrucosa (Bloch & Schneider, 1801) Australian Museum. Retrieved 21 July 2009.
  43. Froese, Rainer; Pauly, Daniel (eds.) (2009). "Uranoscopus sulphureus" in FishBase. July 2009 version.
  44. Froese, Rainer; Pauly, Daniel (eds.) (2009). "Lactophrys bicaudalis" in FishBase. July 2009 version.
  45. Ciguatera Archived 2010-02-04 at the Wayback Machine. "Rosenstiel School of Marine and Atmospheric Science, Univ. of Miami"
  46. Lieske, E. and Myers, R.F. (2004) Coral reef guide; Red Sea London, HarperCollins ISBN 0-00-715986-2
  47. Froese, Rainer; Pauly, Daniel (eds.) (2009). "Gymnothorax javanicus" in FishBase. July 2009 version.
  48. Rongo, T; Bush, M; van Woesik, R (2009). "Did ciguatera prompt the late Holocene Polynesian voyages of discovery?". Journal of Biogeography. 36 (8): 1423–1432. doi:10.1111/j.1365-2699.2009.02139.x.
  49. Voyages of discovery or necessity? Fish poisoning may be why Polynesians left paradise PhysOrg.com, 18 May 2009.
  50. Hobson, E.S. (1963). "Feeding Behavior in Three Species of Sharks". Pacific Science. 17: 171–194.
  51. Randall, J.E. (1977). "Contribution to the Biology of the Whitetip Reef Shark (Triaenodon obesus)". Pacific Science. 31 (2): 143–164.
  52. Compagno, L.J.V. (1984). Sharks of the World: An Annotated and Illustrated Catalogue of Shark Species Known to Date. Rome: Food and Agricultural Organization. pp. 459–461. ISBN 92-5-101384-5.
  53. Martin, R.A. Caribbean Reef Shark. ReefQuest Centre for Shark Research. Retrieved on February 14, 2009.
  54. Nelson, D.R. and R.H. Johnson. (1970). Acoustic studies on sharks: Rangiroa Atoll, July 1969. ONR Technical Report 2, No. N00014-68-C-0138.
  55. Yano, K.; H. Mori; K. Minamikawa; S. Ueno; S. Uchida; K. Nagai; M. Toda & M. Masuda (June 2000). "Behavioral response of sharks to electric stimulation". Bulletin of Seikai National Fisheries Research Institute. 78: 13–30.
  56. Papastamatiou, Y.P.; J.E. Caselle; A.M. Friedlander & C.G. Lowe (16 September 2009). "Distribution, size frequency, and sex ratios of blacktip reef sharks Carcharhinus melanopterus at Palmyra Atoll: a predator-dominated ecosystem". Journal of Fish Biology. 75 (3): 647–654. doi:10.1111/j.1095-8649.2009.02329.x. PMID 20738562.
  57. Springer, S. (1967), "Social organization of shark populations", in Gilbert, P.W.; R.F. Mathewson; D.P. Rail (eds.), Sharks, Skates, and Rays, Baltimore: Johns Hopkins Press, pp. 149–174
  58. Papastamatiou, Y.P.; C.G. Lowe; J.E. Caselle & A.M. Friedlander (April 2009). "Scale-dependent effects of habitat on movements and path structure of reef sharks at a predator-dominated atoll". Ecology. 90 (4): 996–1008. doi:10.1890/08-0491.1. PMID 19449694.
  59. Martin, R.A. (March 2007). "A review of shark agonistic displays: comparison of display features and implications for shark-human interactions". Marine and Freshwater Behaviour and Physiology. 40 (1): 3–34. doi:10.1080/10236240601154872.
  60. Papastamatiou, Y.P.; Wetherbee, B.M.; Lowe, C.G. & Crow, G.L. (2006). "Distribution and diet of four species of carcharhinid shark in the Hawaiian Islands: evidence for resource partitioning and competitive exclusion". Marine Ecology Progress Series. 320: 239–251. Bibcode:2006MEPS..320..239P. doi:10.3354/meps320239.
  61. Garla, R.C.; Chapman, D.D.; Wetherbee, B.M. & Shivji, M. (2006). "Movement patterns of young Caribbean reef sharks, Carcharhinus perezi, at Fernando de Noronha Archipelago, Brazil: the potential of marine protected areas for conservation of a nursery ground". Marine Biology. 149 (2): 189–199. doi:10.1007/s00227-005-0201-4. S2CID 85922851.
  62. Rosa, R.S.; Mancini, P.; Caldas, J.P. & Graham, R.T. (2006). "Carcharhinus perezi". IUCN Red List of Threatened Species. 2006: e.T60217A12323052. doi:10.2305/IUCN.UK.2006.RLTS.T60217A12323052.en.

References

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.