Alcyonacea
Alcyonacea are a species of sessile colonial cnidarians that are found throughout the oceans of the world, especially in the deep sea, polar waters, tropics and subtropics. Whilst not in a strict taxonomic sense, Alcyonacea are commonly known as "soft corals" (Octocorallia) that are quite different from "true" corals (Scleractinia). The term “soft coral” generally applies to organisms in the two orders Pennatulacea and Alcyonacea with their polyps embedded within a fleshy mass of coenenchymal tissue.[2] Consequently, the term “gorgonian coral” is commonly handed to multiple species in the order Alcyonacea that produce a mineralized skeletal axis (or axial-like layer) composed of calcite and the proteinaceous material gorgonin only and corresponds to only one of several families within the formally accepted taxon Gorgoniidae (Scleractinia). These can be found in order Malacalcyonacea (taxonomic synonyms of include (unnacepted): Alcyoniina, Holaxonia, Protoalcyonaria, Scleraxonia, and Stolonifera.[3] They are sessile colonial cnidarians that are found throughout the oceans of the world, especially in the deep sea, polar waters, tropics and subtropics. Common names for subsets of this order are sea fans and sea whips; others are similar to the sea pens of related order Pennatulacea. Individual tiny polyps form colonies that are normally erect, flattened, branching, and reminiscent of a fan. Others may be whiplike, bushy, or even encrusting.[4] A colony can be several feet high and across, but only a few inches thick. They may be brightly coloured, often purple, red, or yellow. Photosynthetic gorgonians can be successfully kept in captive aquaria.
Soft coral | |
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Cladiella sp. | |
Scientific classification | |
Domain: | Eukaryota |
Kingdom: | Animalia |
Phylum: | Cnidaria |
Class: | Octocorallia |
Order: | Alcyonacea Lamouroux, 1812 [1] |
Suborders | |
See text | |
Synonyms | |
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About 500 different species of gorgonians are found in the oceans of the world, but they are particularly abundant in the shallow waters of the Western Atlantic, including Florida, Bermuda, and the West Indies.[5]
Anatomy
The structure of a gorgonian colony varies. In the suborder Holaxonia, skeletons are formed from a flexible, horny substance called gorgonin. The suborder Scleraxonia species are supported by a skeleton of tightly grouped calcareous spicules. Also, some species encrust like coral.[6]
Measurements of the gorgonin and calcite within several long-lived species of gorgonians can be useful in paleoclimatology and paleoceanography, as their skeletal growth rate and composition are highly correlated with seasonal and climatic variation.[7][8][9]
Features
Soft corals contain minute, spiny skeletal elements called sclerites, useful in species identification. Sclerites give these corals some degree of support and give their flesh a spiky, grainy texture that deters predators. In the past, soft corals were thought to be unable to lay new foundations for future corals, but recent findings suggest that colonies of the leather-coral genus Sinularia are able to cement sclerites and consolidate them at their base into alcyonarian spiculite,[10] thus making them reef builders.
Unlike stony corals, most soft corals thrive in nutrient-rich waters with less intense light. Almost all use symbiotic photosynthetic zooxanthella as a major energy source. However, most readily eat any free-floating food, such as zooplankton, out of the water column. They are integral members of the reef ecosystem and provide habitat for fish, snails, algae, and a diversity of other marine species.
Despite being dominated by "soft corals", the order Alcyonacea now contains all species known as "gorgonian corals", that produce a hard skeleton made from gorgonin, a protein unique to the group that makes their skeletons quite different from "true" corals (Scleractinia). These "gorgonion corals" can be found in suborders Holaxonia, Scleraxonia, and Stolonifera.
Many soft corals are easily collected in the wild for the reef aquarium hobby, as small cuttings are less prone to infection or damage during shipping than stony corals. Nevertheless, home-grown specimens tend to be more adaptable to aquarium life and help conserve wild reefs. Soft corals grow quickly in captivity and are easily divided into new individuals, and so those grown by aquaculture are often hardier and less expensive than imported corals from the wild.
Ecology
Each gorgonian polyp has eight tentacles, which catch plankton and particulate matter for consumption. This process, called filter feeding, is facilitated when the "fan" is oriented across the prevailing current to maximise water flow to the gorgonian, hence food supply.
Some gorgonians contain algae, or zooxanthellae. This symbiotic relationship assists in giving the gorgonian nutrition by photosynthesis. Gorgonians possessing zooxanthellae are usually characterized by brownish polyps.
Gorgonians are found primarily in shallow waters, though some have been found at depths of several thousand feet.[4][6] The size, shape, and appearance of gorgonians can be correlated with their location. The more fan-shaped and flexible gorgonians tend to populate shallower areas with strong currents, while the taller, thinner, and stiffer gorgonians can be found in deeper, calmer waters.[4]
Other fauna, such as hydrozoa, bryozoa, and brittle stars, are known to dwell within the branches of gorgonian colonies.[11] The pygmy seahorse not only makes certain species of gorgonians its home, but also closely resembles its host, thus is well camouflaged.[12] Two species of pygmy seahorse, Hippocampus bargibanti and Hippocampus denise, are obligate residents on gorgonians. H. bargibanti is limited to two species in the single genus Muricella.
Gorgonians produce unusual organic compounds in their tissues, particularly diterpenes, and some of these are important candidates for new drugs.[13] These compounds may be part of the chemical defenses produced by gorgonians to render their tissue distasteful to potential predators.[14] Bottlenose dolphins in the Red Sea have been observed swimming against these tissues, in what is thought to be an attempt to take advantage of the antimicrobial qualities of diterpenes.[15] Despite these chemical defenses, the tissues of gorgonians are prey for flamingo tongue snails of the genus Cyphoma, nudibranchs, the fireworm Hermodice spp., and their polyps are food for butterflyfishes.[16] Amongst the nudibranchs which feed on soft corals and sea fans are the Tritoniidae and the genus Phyllodesmium which specialises in eating Xenia species.[17]
Suborders and families
The World Register of Marine Species lists these suborders and families:[18]
- suborder Alcyoniina
- family Acrophytidae McFadden & Ofwegen, 2017
- family Alcyoniidae Lamouroux, 1812
- family Aquaumbridae Breedy, van Ofwegen & Vargas, 2012
- family Corymbophytidae McFadden & Ofwegen, 2017
- family Leptophytidae McFadden & Ofwegen, 2017
- family Nephtheidae Gray, 1862
- family Nidaliidae Gray, 1869
- family Paralcyoniidae Gray, 1869
- family Xeniidae Ehrenberg, 1828
- suborder Calcaxonia
- family Chrysogorgiidae Verrill, 1883
- family Ellisellidae Gray, 1859
- family Ifalukellidae Bayer, 1955
- family Isididae Lamouroux, 1812
- family Primnoidae Milne Edwards, 1857
- suborder Holaxonia
- family Acanthogorgiidae Gray, 1859
- family Dendrobrachiidae Brook, 1889
- family Gorgoniidae Lamouroux, 1812
- family Keroeididae Kinoshita, 1910
- family Plexauridae Gray, 1859
- suborder Protoalcyonaria
- family Taiaroidae Bayer & Muzik, 1976
- suborder Scleraxonia
- family Anthothelidae Broch, 1916
- family Briareidae Gray, 1859
- family Coralliidae Lamouroux, 1812
- family Melithaeidae Gray, 1870
- family Paragorgiidae Kükenthal, 1916
- family Parisididae Aurivillius, 1931
- family Spongiodermidae Wright & Studer, 1889
- family Subergorgiidae Gray, 1859
- family Victorgorgiidae Moore, Alderslade & Miller, 2017
- suborder Stolonifera
- family Acrossotidae Bourne, 1914
- family Arulidae McFadden & van Ofwegen, 2012
- family Clavulariidae Hickson, 1894
- family Coelogorgiidae Bourne, 1900
- family Cornulariidae Dana, 1846
- family Pseudogorgiidae Utinomi & Harada, 1973
- family Tubiporidae Ehrenberg, 1828
- family Acanthoaxiidae van Ofwegen & McFadden, 2010
- family Haimeidae Wright, 1865
- family Paramuriceidae Bayer, 1956
- family Parasphaerascleridae McFadden & van Ofwegen, 2013
- family Viguieriotidae
- Alcyonium acaule, an alcyoniid
- Dendronephthya hemprichi, a nephtheid
- Siphonogorgia godeffroyi, a nidaliid
- Maasella edwardsi, a paralcyoniid
- Heteroxenia fuscescens, a xeniid
- Iridigorgia sp., a chrysogorgiid
- Ellisella sp., an ellisellid
- Isidella tentaculum, an isidid
- Plumarella pellucida, a primnoid
- Muricella sp., an acanthogorgiid
- Gorgonia ventalina, a gorgoniid
- Paramuricea clavata, a paramuriceid
- Muricea elongata, a plexaurid
- Anthothela grandiflora, an anthothelid
- Briareum sp., a briareid
- Corallium rubrum, a coralliid
- Acabaria splendens, a melithaeid
- Paragorgia arborea, a paragorgiid
- Annella mollis, a subergorgiid
- Clavularia viridis, a clavulariid
- Cornularia cornucopiae, a cornulariid
- Tubipora musica, Tubiporidae
References
- van Ofwegen, L. (2011). "Alcyonacea Lamouroux, 1812". WoRMS. World Register of Marine Species. Retrieved 15 December 2011.
- Bayer, F. M. (1961). The shallow-water Octocorallia of the West Indian region. Studies on the Fauna of Curaçao and other Caribbean Islands, 12(1), 1-373.; Córdova-Isaza, A., Jiménez-Mármol, S., Guerra, Y., & Salas-Sarduy, E. (2023). Enzyme Inhibitors from Gorgonians and Soft Corals. Marine Drugs, 21(2), 104. https://doi.org/10.3390/md21020104; Raimundo, I., Silva, S., Costa, R., & Keller-Costa, T. (2018). Bioactive Secondary Metabolites from Octocoral-Associated Microbes—New Chances for Blue Growth. Marine Drugs, 16(12), 485. https://doi.org/10.3390/md16120485
- Daly, M., M.R. Brugler, P. Cartwright, A.G. Collins, M.N. Dawson, D.G. Fautin, S.C. France, C.S. McFadden, D.M. Opresko, E. Rodriquez, S.L. Romano, J.L. Stake. (2007). The phylum Cnidaria: A review of phylogenetic patterns and diversity 300 years after Linnaeus. Zootaxa. (1668): 127–182., available online at http://www.mapress.com/zootaxa/2007f/zt01668p182.pdf; McFadden, C.S.; van Ofwegen, L.P.; Quattrini, A.M. (2022) Revisionary systematics of Octocorallia (Cnidaria: Anthozoa) guided by phylogenomics. Bulletin of the Society of Systematic Biologists. 1(3), 8735, pp. 1-79. Available online at https://ssbbulletin.org/index.php/bssb/article/view/8735 page(s): 21; Schoch CL, et al. NCBI Taxonomy: a comprehensive update on curation, resources and tools. Database (Oxford). 2020: baaa062. PubMed: 32761142 PMC: PMC7408187.
- Borneman, Eric H. (2001). Aquarium Corals: Selection, Husbandry, and Natural History. Neptune City, NJ: T.F.H. Publications. p. 464. ISBN 1-890087-47-5.
- "Sea Fan". University of Delaware Graduate College of Marine Studies. Archived from the original on 17 April 2006. Retrieved 23 September 2007.
- Goldstein, Robert J. (1997). Marine Reef Aquarium Handbook. Barron's Educational Series, Inc. p. 198. ISBN 0-8120-9598-7.
- Heikoop, J.M.; M.J. Risk; C.K. Shearer; V. Atudorei (March 2002). "Potential climate signals from the deep-sea gorgonian coral Primnoa resedaeformis". Hydrobiologia. 471 (1–3): 117–124. doi:10.1023/A:1016505421115. S2CID 7432164.
- Sherwood, Owen A.; Jeffrey M. Heikoop; Daniel J. Sinclair; David B. Scott; Michael J. Risk; Chip Shearer; Kumiko Azetsu-Scott (2005). Cold-Water Corals and Ecosystems. Erlangen Earth Conference Series. Springer Berlin Heidelberg. pp. 1061–1079. doi:10.1007/3-540-27673-4. ISBN 978-3-540-24136-2.
- Bond, Zoë A.; Anne L. Cohen; Struan R. Smith; William J. Jenkins (31 August 2005). "Growth and composition of high-Mg calcite in the skeleton of a Bermudian gorgonian (Plexaurella dichotoma): Potential for paleothermometry". Geochemistry, Geophysics, Geosystems. 6 (8): Q08010. Bibcode:2005GGG.....6.8010B. doi:10.1029/2005GC000911. hdl:1912/396. S2CID 128703481.
- Kenji Konishi, "Alcyonarian spiculite: the limestone of soft corals", 1981; M.-S. Jeng, H.-D. Huang, C.-F. Dai, Y.-C. Hsiao and Y. Benayahu. (15 May 2011), "Sclerite calcification and reef-building in the fleshy octocoral genus Sinularia (Octocorallia: Alcyonacea)", Earth and Environmental Science, Coral Reefs doi:10.1007/s00338-011-0765-z.
- Haywood, Martyn; Sue Wells (1989). The Manual of Marine Invertebrates. Morris Plains, NJ: Tetra Press:Salamander Books Ltd. p. 208. ISBN 3-89356-033-5.
- Agbayani, Eli (5 June 2007). "Hippocampus bargibanti, Pygmy seahorse". FishBase. Retrieved 22 September 2007.
- Berrue, F; Kerr, RG (2009). "Diterpenes from gorgonian corals". Natural Product Reports. 26 (5): 681–710. doi:10.1039/b821918b. PMID 19387501.
- O'Neal, W; Pawlik, JR (2002). "A reappraisal of the chemical and physical defenses of Caribbean gorgonian corals against predatory fishes". Marine Ecology Progress Series. 240: 117–126. Bibcode:2002MEPS..240..117O. doi:10.3354/meps240117.
- Attenborough, David (12 November 2017). ""Coral Reefs"". Blue Planet II. Episode 3. BBC One.
- Pawlik, JR; et al. (1987). "Patterns of chemical defense among Caribbean gorgonian corals - A preliminary survey". Journal of Experimental Marine Biology and Ecology. 108: 55–66. doi:10.1016/0022-0981(87)90130-4.
- García-Matucheski, S. and Muniain, C. (2011). Predation by the nudibranch Tritonia odhneri (Opisthobranchia:Tritoniidae) on octocorals from the South Atlantic Ocean. Marine Biodiversity, 41(2), 287–297.
- "WoRMS - World Register of Marine Species - Alcyonacea". marinespecies.org. Retrieved 22 March 2018.
External links
- The Marine Fauna Gallery of Norway
- AnimalDiversity
- Gorgonian Corals Archived 6 June 2010 at the Wayback Machine