False cleanerfish

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False cleanerfish
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Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Chordata
Class: Actinopterygii
Order: Blenniiformes
Family: Blenniidae
Genus: Aspidontus
Species:
A. taeniatus
Binomial name
Aspidontus taeniatus
Quoy & Gaimard, 1834

The false cleanerfish (Aspidontus taeniatus) is a species of combtooth blenny, a mimic that copies both the dance and appearance of Labroides dimidiatus (the bluestreak cleaner wrasse), a similarly colored species of cleaner wrasse. It likely mimics that species to avoid predation, [2] as well as to occasionally bite the fins of its victims rather than consume parasites. [3] [4] Most veiled attacks occur on juvenile fish, as adults that have been attacked in the past may avoid or even attack A. taeniatus. [5]

Contents

It is indigenous to coral reef habitats in the Indo-Pacific.

Mimicry

Appearance

The false cleanerfish primarily lives in coral reef margins among the cleaning stations of the bluestreak cleaner wrasse (Labroides dimidiatus), [2] and are usually seen near locations of one or more L. dimidiatus. [6] With its territory primarily overlapping with its model fish, the false cleanerfish mimics both the appearance and occasionally the behavior of said fish. Though A. taeniatus is typically known to exhibit the characteristic black stripe and blue body and general body shape and structure of L. dimidiatus, [5] some individuals have been witnessed to mimic the appearance of other reef fish, as well as atypically colored cleaner wrasses that live in the same territory. [5] [7]

Juvenile A. taeniatus fish match the appearance of juvenile L. dimidiatus (black body, blue dorsal stripe), and continue to match the coloration of cleaner wrasses of the same size throughout growth. [5] [6] It is not known whether the false cleanerfish adopts a permanent color pattern or if it alters its coloration to mimic the appearance of neighboring cleaner wrasses.

One major difference in appearance between the false cleanerfish and its model is the location of the mouth. A. taeniatus has an underslung mouth, whereas L. dimidiatus has its mouth in the terminal position. [6] Additionally, the false cleanerfish has a small set of teeth on the upper mandible, as well as enormous canines that protrude from its lower jaw and fit into sockets laterally on the roof of its mouth. [6]

Cheating behaviour

The false cleanerfish has been observed to mimic the unusual "dance" of the bluestreak cleaner wrasse by spreading its caudal fin and oscillating its posterior end up and down. [3] By doing so, the false cleanerfish elicits the same posing behavior in client fish, similarly to L. dimidiatus. [2] [3] Occasionally, however, rather than feeding on ectoparasites like the cleaner wrasse, the false cleanerfish will attack and attempt (and sometimes succeed) at tearing away portions of fin from the client fish. [2] [3] [7] [8] This typically occurs and is most successful with juvenile client fish, [6] as adults have been evidenced to avoid or even indiscriminately attack cleanerfish, suggesting adult client fish remember being attacked. [9] Also, evidence indicates adult fish are able to distinguish between L. dimidiatus and A. taeniatus, and thus avoid it altogether. [5] [6] [7]

Evolutionary basis

Though A. taeniatus mimics L. dimidiatus in color, morphology, and mode of swimming, the false cleanerfish cheats much less often than initially reported. [2] The stomach contents of A. taeniatus consist primarily of the demersal eggs of fishes and the tentacles of tube worms, [2] [6] with a relatively small portion of fish fins, or ectoparasites [10] —the primary stomach contents of L. dimidiatus. Additionally, close observation of A. taeniatus has shown them to only attack posing clients at a rate of about 20%. [2]

The primary reason for the false cleanerfish's mimicry is suggested to be not to cheat and feed on the flesh of client fish, but to avoid predation by those fish that do not prey on L. dimidiatus. [2] Aggressive mimicry typically results in the complete consumption of prey by a mimic predator (such as anglerfish), or partial consumption of prey by an unattractive mimic. [2] In both cases, the host fish can rarely or never learn the disguise of the mimic; the fact that A. taeniatus can be easily identified by client fish helps to dispel the notion that it is primarily an aggressive mimic. [9] Groupers raised in captivity do not attack L. dimidiatus, while they do consume all other noncleanerfish on sight. [11] Furthermore, false cleanerfish inflict a higher cost on their models and cleaning stations when cheating, as client fish are more likely to behave aggressively or avoid cleaning stations altogether if they are consistently attacked. [12]

However, there is evidence of geographical variation on the benefits obtained by the mimicry: whereas in the Red Sea and the Great Barrier Reef foraging on tube worms or substrate was more common than attacks by mimics, in French Polynesia and Indonesia false cleanerfish (especially juveniles) fed on client fish tissue more commonly than other food sources. [4] An alternate reason for the mimicry behavior of A. taeniatus is to deceive egg-caring fishes so to more easily gain access to their eggs; however, little evidence favors this possibility. [2]

The evolution of A. taeniatus to mimic L. dimidiatus has been used as evidence for the strong selection of client fish that do not attack their cleaners, or cheat and consume their cleaners after cleaning. [13] Furthermore, the behavior of A. taeniatus mimicking L. dimidiatus in a largely nonaggressive way supports the hypothesis of the evolution of reciprocally altruistic behavior. [13]

Related Research Articles

<span class="mw-page-title-main">Mimicry</span> Evolutionary strategy

In evolutionary biology, mimicry is an evolved resemblance between an organism and another object, often an organism of another species. Mimicry may evolve between different species, or between individuals of the same species. In the simplest case, as in Batesian mimicry, a mimic resembles a model, so as to deceive a dupe, all three being of different species. A Batesian mimic, such as a hoverfly, is harmless, while its model, such as a wasp, is harmful, and is avoided by the dupe, such as an insect-eating bird. Birds hunt by sight, so the mimicry in that case is visual, but in other cases mimicry may make use of any of the senses. Most types of mimicry, including Batesian, are deceptive, as the mimics are not harmful, but Müllerian mimicry, where different harmful species resemble each other, is honest, as when species of wasps and of bees all have genuinely aposematic warning coloration. More complex types may be bipolar, involving only two species, such as when the model and the dupe are the same; this occurs for example in aggressive mimicry, where a predator in wolf-in-sheep's-clothing style resembles its prey, allowing it to hunt undetected. Mimicry is not limited to animals; in Pouyannian mimicry, an orchid flower is the mimic, resembling a female bee, its model; the dupe is the male bee of the same species, which tries to copulate with the flower, enabling it to transfer pollen, so the mimicry is again bipolar. In automimicry, another bipolar system, model and mimic are the same, as when blue lycaenid butterflies have 'tails' or eyespots on their wings that mimic their own heads, misdirecting predator dupes to strike harmlessly. Many other types of mimicry exist.

<span class="mw-page-title-main">Wrasse</span> Family of ray-finned fishes

The wrasses are a family, Labridae, of marine ray-finned fish, many of which are brightly colored. The family is large and diverse, with over 600 species in 81 genera, which are divided into nine subgroups or tribes. They are typically small, most of them less than 20 cm (7.9 in) long, although the largest, the humphead wrasse, can measure up to 2.5 m (8.2 ft). They are efficient carnivores, feeding on a wide range of small invertebrates. Many smaller wrasses follow the feeding trails of larger fish, picking up invertebrates disturbed by their passing. Juveniles of some representatives of the genera Bodianus, Epibulus, Cirrhilabrus, Oxycheilinus, and Paracheilinus hide among the tentacles of the free-living mushroom corals and Heliofungia actiniformis.

<span class="mw-page-title-main">Blenniiformes</span> Order of fishes

Blenny is a common name for many types of fish, including several families of percomorph marine, brackish, and some freshwater fish sharing similar morphology and behaviour. Six families are considered "true blennies", grouped under the order Blenniiformes; its members are referred to as blenniiformids. About 151 genera and nearly 900 species have been described within the order. The order was formerly classified as a suborder of the Perciformes but the 5th Edition of Fishes of the World divided the Perciformes into a number of new orders and the Blenniiformes were placed in the percomorph clade Ovalentaria alongside the such taxa as Cichliformes, Mugiliformes and Gobiesociformes.

<span class="mw-page-title-main">Cleaning station</span> Location where aquatic life congregate to be cleaned

A cleaning station is a location where aquatic life congregate to be cleaned by smaller beings. Such stations exist in both freshwater and marine environments, and are used by animals including fish, sea turtles and hippos.

Cheating is a term used in behavioral ecology and ethology to describe behavior whereby organisms receive a benefit at the cost of other organisms. Cheating is common in many mutualistic and altruistic relationships. A cheater is an individual who does not cooperate but can potentially gain the benefit from others cooperating. Cheaters are also those who selfishly use common resources to maximize their individual fitness at the expense of a group. Natural selection favors cheating, but there are mechanisms to regulate it. The stress gradient hypothesis states that facilitation, cooperation or mutualism should be more common in stressful environments, while cheating, competition or parasitism are common in benign environments.

<span class="mw-page-title-main">Tasselled wobbegong</span> Species of shark

The tasselled wobbegong is a species of carpet shark in the family Orectolobidae and the only extant member of the genus Eucrossorhinus. It inhabits shallow coral reefs off northern Australia, New Guinea, and adjacent islands. Reaching 1.8 m (5.9 ft) in length, this species has a broad and flattened body and head. Its most distinctive trait is a fringe of branching dermal flaps around its head, which extends onto its chin. The fringe, along with its complex color pattern of small blotches and reticulations, enable it to camouflage itself against the reef environment.

<span class="mw-page-title-main">Cleaner fish</span> Fish that remove parasites and dead tissue from other species

Cleaner fish are fish that show a specialist feeding strategy by providing a service to other species, referred to as clients, by removing dead skin, ectoparasites, and infected tissue from the surface or gill chambers. This example of cleaning symbiosis represents mutualism and cooperation behaviour, an ecological interaction that benefits both parties involved. However, the cleaner fish may consume mucus or tissue, thus creating a form of parasitism called cheating. The client animals are typically fish of a different species, but can also be aquatic reptiles, mammals, or octopuses. A wide variety of fish including wrasse, cichlids, catfish, pipefish, lumpsuckers, and gobies display cleaning behaviors across the globe in fresh, brackish, and marine waters but specifically concentrated in the tropics due to high parasite density. Similar behaviour is found in other groups of animals, such as cleaner shrimps.

<span class="mw-page-title-main">Aggressive mimicry</span> Deceptive mimicry of a harmless species by a predator

Aggressive mimicry is a form of mimicry in which predators, parasites, or parasitoids share similar signals, using a harmless model, allowing them to avoid being correctly identified by their prey or host. Zoologists have repeatedly compared this strategy to a wolf in sheep's clothing. In its broadest sense, aggressive mimicry could include various types of exploitation, as when an orchid exploits a male insect by mimicking a sexually receptive female, but will here be restricted to forms of exploitation involving feeding. For example, indigenous Australians who dress up as and imitate kangaroos when hunting would not be considered aggressive mimics, nor would a human angler, though they are undoubtedly practising self-decoration camouflage. Treated separately is molecular mimicry, which shares some similarity; for instance a virus may mimic the molecular properties of its host, allowing it access to its cells. An alternative term, Peckhamian mimicry, has been suggested, but it is seldom used.

<span class="mw-page-title-main">Bluestreak cleaner wrasse</span> Species of fish

The bluestreak cleaner wrasse is one of several species of cleaner wrasses found on coral reefs from Eastern Africa and the Red Sea to French Polynesia. Like other cleaner wrasses, it eats parasites and dead tissue off larger fishes' skin in a mutualistic relationship that provides food and protection for the wrasse, and considerable health benefits for the other fishes. It is also notable for having potentially passed the mirror test, though this is not without controversy.

<i>Elacatinus</i> Genus of fishes

Elacatinus is a genus of small marine gobies, often known collectively as the neon gobies. Although only one species, E. oceanops, is technically the "neon goby", because of their similar appearance, other members of the genus are generally labeled neon gobies, as well. Except for a single East Pacific species, all reside in warmer parts of the West Atlantic, including the Caribbean and Gulf of Mexico. They are known for engaging in symbiosis with other marine creatures by providing them cleaning service that consists of getting rid of ectoparasites on their bodies. In return, Elacatinus species obtain their primary source of food, ectoparasites.

<span class="mw-page-title-main">Fish intelligence</span> Intellectual capacity of fish

Fish intelligence is "the resultant of the process of acquiring, storing in memory, retrieving, combining, comparing, and using in new contexts information and conceptual skills" as it applies to fish. Due to a common perception amongst researchers that Teleost fish are "primitive" compared to mammals and birds, there has been much less research into fish cognition than into those types of animals, and much remains unknown about fish cognition, though evidence of complex navigational skills such as cognitive maps is increasing.

<i>Aspidontus tractus</i> Species of fish

Aspidontus tractus is a species of combtooth blenny found in coral reefs in the western Indian Ocean. It reaches the length of 10 centimetres (3.9 in) TL. It mimics Labroides dimidiatus, the cleaner wrasse, and feeds on the fins of fish that mistake it for the cleaner wrasse. Eggs are laid in clusters below the surface.

<span class="mw-page-title-main">Bluestriped fangblenny</span> Species of fish

Plagiotremus rhinorhynchos, commonly called the bluestriped fangblenny, is a species of combtooth blenny found in coral reefs in the Pacific and Indian Ocean. This species reaches a length of 12 centimetres (4.7 in) SL. It is also known as the bluestriped blenny, bluestriped sabretooth blenny, blunt-nose blenny, cleaner mimic, tube-worm blenny or the two-stripe blenny. They hide in deserted worm tubes or other small holes.

<span class="mw-page-title-main">Cleaning symbiosis</span> Mutually beneficial association between individuals of two species

Cleaning symbiosis is a mutually beneficial association between individuals of two species, where one removes and eats parasites and other materials from the surface of the other. Cleaning symbiosis is well-known among marine fish, where some small species of cleaner fish, notably wrasses but also species in other genera, are specialised to feed almost exclusively by cleaning larger fish and other marine animals. Other cleaning symbioses exist between birds and mammals, and in other groups.

<span class="mw-page-title-main">Red-lined wrasse</span> Species of fish

The red-lined wrasse, two-spotted wrasse or biocellated wrasse, Halichoeres biocellatus, is a species of wrasse native to shallow tropical waters in the western Pacific Ocean.

<span class="mw-page-title-main">Slender grouper</span> Genus of fish

The slender grouper is a species of marine ray-finned fish, a grouper from the subfamily Epinephelinae which is part of the family Serranidae, which also includes the anthias and sea basses. It is the only species in the genus Anyperodon. It is found in the Indo-Pacific region.

<span class="mw-page-title-main">Chiseltooth wrasse</span> Species of fish

The chiseltooth wrasse is a species of marine ray-finned fish, a wrasse from the family Labridae. It is native to the Indian Ocean and the western Pacific Ocean. It is an inhabitant of coral reefs and can be found at depths from 3 to 60 m, though rarely deeper than 40 m (130 ft). This species grows to 30 cm (12 in) in total length. It is of minor importance to local commercial fisheries and can be found in the aquarium trade. P. moluccanus is the only known member of its genus.

<span class="mw-page-title-main">Hawaiian cleaner wrasse</span> Species of fish

The Hawaiian cleaner wrasse or golden cleaner wrasse, is a species of wrasse found in the waters surrounding the Hawaiian Islands. The fish is endemic to Hawaii. These cleaner fish inhabit coral reefs, setting up a territory referred to as a cleaning station. They obtain a diet of small crustacean parasites by removing them from other reef fish in a cleaning symbiosis.

<i>Labroides bicolor</i> Species of fish

Labroides bicolor is a species of wrasse endemic to the Indian Ocean and the Pacific Ocean. It is known by various names including bicolor cleanerfish, bicolor(ed) cleaner wrasse, cleaner wrasse, two-color cleaner wrasse and yellow diesel wrasse.

In evolutionary biology, mimicry in vertebrates is mimicry by a vertebrate of some model, deceiving some other animal, the dupe. Mimicry differs from camouflage as it is meant to be seen, while animals use camouflage to remain hidden. Visual, olfactory, auditory, biochemical, and behavioral modalities of mimicry have been documented in vertebrates.

References

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