Parrotfish Explained

Parrotfish are a group of fish species traditionally regarded as a family (Scaridae), but now often treated as a subfamily (Scarinae) or tribe (Scarini) of the wrasses (Labridae). With roughly 95 species, this group's largest species richness is in the Indo-Pacific. They are found in coral reefs, rocky coasts, and seagrass beds, and can play a significant role in bioerosion.

Description

Parrotfish are named for their dentition,[1] which is distinct from other fish, including other labrids. Their numerous teeth are arranged in a tightly packed mosaic on the external surface of their jaw bones, forming a parrot-like beak with which they rasp algae from coral and other rocky substrates (which contributes to the process of bioerosion).

Maximum sizes vary within the group, with the majority of species reaching 30cm-50cmcm (10inches-20inchescm) in length. However, a few species reach lengths in excess of 1m (03feet), and the green humphead parrotfish can reach up to 1.3m (04.3feet). The smallest species is the bluelip parrotfish (Cryptotomus roseus), which has a maximum size of 13cm (05inches).[2]

Mucus

Some parrotfish species, including the queen parrotfish (Scarus vetula), secrete a mucus cocoon, particularly at night.[3] Prior to going to sleep, some species extrude mucus from their mouths, forming a protective cocoon that envelops the fish, presumably hiding its scent from potential predators.[4] This mucus envelope may also act as an early warning system, allowing the parrotfish to flee when it detects predators such as moray eels disturbing the membrane. The skin itself is covered in another mucous substance which may have antioxidant properties helpful in repairing bodily damage,[3] or repelling parasites, in addition to providing protection from UV light.[3]

Feeding

Most parrotfish species are herbivores, feeding mainly on epilithic algae.[5] [6] [7] A wide range of other small organisms are sometimes eaten, including invertebrates (sessile and benthic species, as well as zooplankton), bacteria and detritus.[8] A few mostly larger species such as the green humphead parrotfish (Bolbometopon muricatum) feed extensively on living coral (polyps).[6] [7] None of these are exclusive corallivores, but polyps can make up as much as half their diet[7] or even more in the green humphead parrotfish.[5] Overall it has been estimated that fewer than one percent of parrotfish bites involve live corals and all except the green humphead parrotfish prefer algae-covered surfaces over live corals.[7] Nevertheless, when they do eat coral polyps, localized coral death can occur.[7] Their feeding activity is important for the production and distribution of coral sands in the reef biome, and can prevent algal overgrowth of the reef structure. The teeth grow continuously, replacing material worn away by feeding. Whether they feed on coral, rock or seagrasses, the substrate is ground up between the pharyngeal teeth.[7] [9] After they digest the edible portions from the rock, they excrete it as sand, helping create small islands and the sandy beaches. The humphead parrotfish can produce 90kg (200lb) of sand each year. Or, on average (as there are so many variables i.e. size/species/location/depth etc.), almost 250g per parrotfish per day. While feeding, parrotfish must be cognizant of predation by one of their main predators, the lemon shark.[10] On Caribbean coral reefs, parrotfish are important consumers of sponges.[11] An indirect effect of parrotfish grazing on sponges is the protection of reef-building corals that would otherwise be overgrown by fast-growing sponge species.[12] [13]

Analysis of parrotfish feeding biology describes three functional groups: excavators, scrapers and browsers.[5] Excavators have larger, stronger jaws that can gouge the substrate,[14] leaving visible scars on the surface. Scrapers have less powerful jaws that can but infrequently do leave visible scraping scars on the substrate. Some of these may also feed on sand instead of hard surfaces. Browsers mainly feed on seagrasses and their epiphytes. Mature excavating species include Bolbometopon muricatum, Cetoscarus, Chlorurus and Sparisoma viride. These excavating species all feed as scrapers in early juvenile stages, but Hipposcarus and Scarus, which also feed as scrapers in early juvenile stages, retain the scraping feeding mode as adults. Browsing species are found in the genera Calotomus, Cryptotomus, Leptoscarus, Nicholsina and Sparisoma. Feeding modes reflect habitat preferences, with browsers chiefly living in the grassy seabed, and excavators and scrapers on coral reefs.[15]

Recently, the microphage feeding hypothesis challenged the prevailing paradigm of parrotfish as algal consumers by proposing that:

Microscopy and molecular barcoding of coral reef substrate bitten by scraping and excavating parrotfish suggest that coral reef cyanobacteria from the order Nostocales are important in the feeding of these parrotfish.[16] Additional microscopy and molecular barcoding research indicates that some parrotfish may ingest microscopic biota associated with endolithic sponges.[17]

Life cycle

The development of parrotfishes is complex and accompanied by a series of changes in sex and colour (polychromatism). Most species are sequential hermaphrodites, starting as females (known as the initial phase) and then changing to males (the terminal phase). In many species, for example the stoplight parrotfish (Sparisoma viride), a number of individuals develop directly to males (i.e., they do not start as females). These directly developing males usually most resemble the initial phase, and often display a different mating strategy than the terminal phase males of the same species.[18] A few species such as the Mediterranean parrotfish (S. cretense) are secondary gonochorists. This means that some females do not change sex (they remain females throughout their lives), the ones that do change from female to male do it while still immature (reproductively functioning females do not change to males) and there are no males with female-like colors (the initial phase males in other parrotfish).[19] [20] The marbled parrotfish (Leptoscarus vaigiensis) is the only species of parrotfish known not to change sex. In most species, the initial phase is dull red, brown, or grey, while the terminal phase is vividly green or blue with bright pink, orange or yellow patches. In a smaller number of species the phases are similar, and in the Mediterranean parrotfish the adult female is brightly colored, while the adult male is gray.[21] In most species, juveniles have a different color pattern from adults. Juveniles of some tropical species can alter their color temporarily to mimic other species.[22] Where the sexes and ages differ, the remarkably different phases often were first described as separate species. As a consequence early scientists recognized more than 350 parrotfish species, which is almost four times the actual number.[18]

Most tropical species form large schools when feeding and these are often grouped by size. Harems of several females presided over by a single male are normal in most species, with the males vigorously defending their position from any challenge.

As pelagic spawners, parrotfish release many tiny, buoyant eggs into the water, which become part of the plankton. The eggs float freely, settling into the coral until hatching.

The sex change in parrotfishes is accompanied by changes in circulating steroids. Females have high levels of estradiol, moderate levels of T and undetectable levels of the major fish androgen 11-ketotestosterone. During the transition from initial to terminal coloration phases, concentrations of 11-ketotestosterone rise dramatically and estrogen levels decline. If a female is injected with 11-ketotestosterone, it will cause a precocious change in gonadal, gametic and behavioural sex.

Economic importance

A commercial fishery exists for some of the larger species, particularly in the Indo-Pacific, but also for a few others like the Mediterranean parrotfish.[23] Protecting parrotfishes is proposed as a way of saving Caribbean coral reefs from being overgrown with seaweed[24] and sponges. Despite their striking colors, their feeding behavior renders them highly unsuitable for most marine aquaria.

A new study has discovered that the parrotfish is extremely important for the health of the Great Barrier Reef; it is the only one of thousands of reef fish species that regularly performs the task of scraping and cleaning inshore coral reefs.[25]

Taxonomy

Traditionally, the parrotfishes have been considered to be a family level taxon, Scaridae. Although phylogenetic and evolutionary analyses of parrotfishes are ongoing, they are now accepted to be a clade in the tribe Cheilini, and are now commonly referred to as scarine labrids (subfamily Scarinae, family Labridae). Some authorities have preferred to maintain the parrotfishes as a family-level taxon,[26] resulting in Labridae not being monophyletic (unless split into several families).

The World Register of Marine Species divides the group into two subfamilies as follows:

Some sources retain the Scaridae as a family, placing it alongside the wrasses of the family Labridae and the weed whitings Odacidae in the order Labriformes, part of the Percomorpha. They also do not support the division of the Scaridae into two subfamilies.[27]

Timeline of genera

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bar:eratop from: -65.5 till: -23.03 color:paleogene text:Paleogene from: -23.03 till: -2.588 color:neogene text:Neogene from: -2.588 till: 0 color:quaternary text:Q.

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bar:period from: -65.5 till: -55.8 color:paleocene text:Paleocene from: -55.8 till: -33.9 color:eocene text:Eocene from: -33.9 till: -23.03 color:oligocene text:Oligocene from: -23.03 till: -5.332 color:miocene text:Miocene from: -5.332 till: -2.588 color:pliocene text:Plio. from: -2.588 till: -0.0117 color:pleistocene text:Pleist. from: -0.0117 till: 0 color:holocene text:H.

bar:era from: -65.5 till: -23.03 color:paleogene text:Paleogene from: -23.03 till: -2.588 color:neogene text:Neogene from: -2.588 till: 0 color:quaternary text:Q.

Further reading

External links

Notes and References

  1. Ostéologie céphalique de deux poissons perroquets (Scaridae: Teleostei) TH Monod, JC Hureau, AE Bullock - Cybium, 1994 - Société française d'ichtyologie
  2. Shah, A.K. (2016). . The Online Guide to the Animals of Trinidad and Tobago. The University of the West Indies. Accessed 11 March 2018.
  3. Cerny-Chipman, E. "Distribution of Ultraviolet-Absorbing Sunscreen Compounds Across the Body Surface of Two Species of Scaridae." DigitalCollections@SIT 2007. Accessed 2009-06-21.
  4. Langerhans, R.B. "Evolutionary consequences of predation: avoidance, escape, reproduction, and diversification. " pp. 177–220 in Elewa, A.M.T. ed. Predation in organisms: a distinct phenomenon. Heidelberg, Germany, Springer-Verlag. 2007. Accessed 2009-06-21.
  5. Bellwood. David R.. 1994-07-14. A phylogenetic study of the parrotfish family Scaridae (Pisces: Labroidea), with a revision of genera. Records of the Australian Museum, Supplement. en. 20. 1–86. 10.3853/j.0812-7387.20.1994.51. 0812-7387. free.
  6. Bellwood . D.R. . Choat . J.H. . 1990 . A functional analysis of grazing in parrotfishes (family Scaridae): the ecological implications . Environ Biol Fish . 28 . 1–4. 189–214 . 10.1007/BF00751035 . 11262999 .
  7. Bonaldo, R.M. & R.D. Rotjan (2018). The Good, the Bad, and the Ugly: Parrotfishes as Coral Predators. in Hoey, A.S. & R.M. Bonaldo, eds. Biology of Parrotfishes. CRC Press.
  8. Comeros-Raynal . Choat . Polidoro . Clements . Abesamis . Craig . Lazuardi . McIlwain . Muljadi . Myers . Nañola Jr . Pardede . Rocha . Russell . Sanciangco . Stockwell . Harwell . Carpenter . 2012 . The Likelihood of Extinction of Iconic and Dominant Herbivores and Detritivores of Coral Reefs: The Parrotfishes and Surgeonfishes . PLOS ONE . 7 . 7. e39825 . 10.1371/journal.pone.0039825 . 22808066 . 3394754 . 2012PLoSO...739825C . free .
  9. Book: Murphy, Richard C. . Coral Reefs: Cities Under The Seas . 2002 . 978-0-87850-138-0 . The Darwin Press, Inc..
  10. Book: Bright, Michael. The private life of sharks : the truth behind the myth. 2000. Stackpole Books. Mechanicsburg, PA. 978-0-8117-2875-1.
  11. Video-monitored predation by Caribbean reef fishes on an array of mangrove and reef sponges. Marine Biology. 1996. 117–123. 126. 10.1007/BF00571383. M. Dunlap. JR. Pawlik. 84799900.
  12. Chemical defenses and resource trade-offs structure sponge communities on Caribbean coral reefs. Proceedings of the National Academy of Sciences. 2014. 24567392. 4151–4156. 111. 11. 10.1073/pnas.1321626111. T-L. Loh. JR. Pawlik . 3964098. 2014PNAS..111.4151L. free.
  13. Indirect effects of overfishing on Caribbean reefs: sponges overgrow reef-building corals. Loh. TL. 2015. PeerJ. 10.7717/peerj.901. etal. 3. e901. 25945305. 4419544 . free .
  14. Price. Samantha A.. Wainwright. Peter C.. Bellwood. David R.. Kazancioglu. Erem. Collar. David C.. Near. Thomas J.. 2010-10-01. Functional Innovations and Morphological Diversification in Parrotfish. Evolution. 64. 10. 3057–3068. 10.1111/j.1558-5646.2010.01036.x. 20497217. 19070148. 1558-5646.
  15. Environmental Biology of Fishes 28: 189-214, 1990
  16. Georgina M Nicholson, Kendall D Clements, Micro-photoautotroph predation as a driver for trophic niche specialization in 12 syntopic Indo-Pacific parrotfish species, Biological Journal of the Linnean Society, Volume 139, Issue 2, June 2023, Pages 91–114, https://doi.org/10.1093/biolinnean/blad005
  17. Nicholson, G.M., Clements, K.D. A role for encrusting, endolithic sponges in the feeding of the parrotfish Scarus rubroviolaceus? Evidence of further trophic diversification in Indo-Pacific Scarini. Coral Reefs (2024). https://doi.org/10.1007/s00338-024-02482-z
  18. Bester, C. Stoplight parrotfish. Florida Museum of Natural History, Ichthyology Department. Accessed 15-12-2009
  19. de Girolamo . Scaggiante . Rasotto . 1999 . Social organization and sexual pattern in the Mediterranean parrotfish Sparisoma cretense (Teleostei: Scaridae) . Marine Biology . 135 . 2. 353–360 . 10.1007/s002270050634 . 85428235 .
  20. Sadovy . Shapiro . 1987 . Criteria for the diagnosis of hermaphroditism in fishes . Copeia . 1987 . 1. 136–156 . 10.2307/1446046 . 1446046 .
  21. Book: Debelius, H. . 1997 . Mediterranean and Atlantic Fish Guide: From Spain to Turkey - From Norway to South Africa . ConchBooks . 221 . 978-3925919541 .
  22. Cardwell JR1, Liley NR.Gen Comp Endocrinol. 1991 Jan;81(1):7-20
  23. Cardigos, F. . 2001 . Vejas . Revista Mundo Submerso . 58 . V . 48–51 . https://web.archive.org/web/20180708074412/http://www.horta.uac.pt/projectos/marov/Media/Vejas.pdf . 8 July 2018 . dead .
  24. [Rebecca Morelle|Morelle, Rebecca]
  25. Australian Geographic. Single species may be key to reef health. September 2014.
  26. Randall, J. E. (2007). Reef and Shore Fishes of the Hawaiian Islands.
  27. Book: Fishes of the World . 5th . J. S. Nelson . T. C. Grande . M. V. H. Wilson . 2016 . 429–430 . Wiley . 978-1-118-34233-6 .