Astrangia poculata

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Astrangia poculata
Astrangia danae.jpeg
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Cnidaria
Class: Hexacorallia
Order: Scleractinia
Family: Rhizangiidae
Genus: Astrangia
Species:
A. poculata
Binomial name
Astrangia poculata
(Ellis & Solander, 1786) [2]
Synonyms [2]
List
  • Astrangia astreiformis Milne Edwards & Haime, 1849
  • Astrangia danae Milne Edwards & Haime, 1849
  • Astrangia danae Agassiz, 1850
  • Astrangia edwardsii Verrill, 1866
  • Astrangia michelinii Milne Edwards & Haime, 1848
  • Madrepora poculata Ellis & Solander, 1786

Astrangia poculata, the northern star coral or northern cup coral, is a species of non-reefbuilding stony coral in the family Rhizangiidae. [3] It is native to shallow water in the western Atlantic Ocean and the Caribbean Sea. It is also found on the western coast of Africa. The International Union for Conservation of Nature lists this coral as being of "least concern". [1] Astrangia poculata is an emerging model organism for corals because it harbors a facultative photosymbiosis, is a calcifying coral, and has a large geographic range. [4] Research on this emerging model system is showcased annually by the Astrangia Research Working Group, collaboratively hosted by Roger Williams University, Boston University, and Southern Connecticut State University [5]

Contents

Description

Astrangia poculata grows in small clumps that are up to 5 cm (2 in) across. The individual polyps are large and sit in stony cups known as corallites. The polyps are translucent and the colony has a furry appearance when they are expanded. In warm water and with high levels of light, this coral often houses photosynthesizing symbiotic protists known as zooxanthellae in its tissues, and then the coral appears brown. In cooler, or low-light conditions, the zooxanthellae may no longer be beneficial to the coral and may be expelled, and then the coral appears pale in colour. It can be confused with the southern cup coral (Astrangia solitaria), but that species has a more southerly distribution, is generally brown, may be solitary, has larger corallites 4 mm (0.16 in) wide with 36 septa (stony ridges), [6] and does not contain zooxanthellae. [7]

Distribution and habitat

Astrangia poculata is native to the western Atlantic Ocean and Caribbean Sea where its range extends from Cape Cod in Massachusetts to the Gulf of Mexico. [8] It also occurs on the western coast of Africa. It occurs in encrusting clumps on rocks and is common under ledges and boulders, on pilings and on wrecks. It also occurs in deep water and detached clumps sometimes get washed up on shore. [1] [6]

Biology

Reproduction of Astrangia poculata takes place during the summer when eggs and sperm are liberated into the water column and fertilisation takes place. The embryos hatch into planula larvae which drift with the plankton before settling to the seabed and undergoing metamorphosis into polyps. [6] Among zooxanthelate organisms, A. poculata is one of the few to have been studied with regard to the acquisition of zooxanthellae. It was found that there was no routine transfer of these symbionts from parent to offspring. [9]

The polyps spread their tentacles to feed, gathering plankton and other food particles from the water passing by. The colony grows by budding, and in favourable conditions, the clump can grow at the rate of one new polyp every three days. In colder conditions it may stop growing and the coenosarc (soft tissues) may die back to some extent [10] or lose symbionts via expulsion, [11] rendering the stony skeleton prone to being fouled by other organisms [6] and undergoing a winter quiescence. [12] The base often hosts various boring or burrowing commensal invertebrates. [13] Both temperature and symbiosis are known to influence the condition of the coral host, specifically with regards to wound-healing ability, [14] [15] but it is primarily season that drives microbiome structure in Rhode Island populations of the coral. [16]

Astrangia poculata coral from Ft Wetherill, Rhode Island demonstrating facultative symbiosis Astrangia poculata coral from Ft Wetherill, Rhode Island demonstrating facultative symbiosis.jpg
Astrangia poculata coral from Ft Wetherill, Rhode Island demonstrating facultative symbiosis

Related Research Articles

<span class="mw-page-title-main">Coral</span> Marine invertebrates of the class Anthozoa

Corals are colonial marine invertebrates within the class Anthozoa of the phylum Cnidaria. They typically form compact colonies of many identical individual polyps. Coral species include the important reef builders that inhabit tropical oceans and secrete calcium carbonate to form a hard skeleton.

<span class="mw-page-title-main">Scleractinia</span> Order of Hexacorallia which produce a massive stony skeleton

Scleractinia, also called stony corals or hard corals, are marine animals in the phylum Cnidaria that build themselves a hard skeleton. The individual animals are known as polyps and have a cylindrical body crowned by an oral disc in which a mouth is fringed with tentacles. Although some species are solitary, most are colonial. The founding polyp settles and starts to secrete calcium carbonate to protect its soft body. Solitary corals can be as much as 25 cm (10 in) across but in colonial species the polyps are usually only a few millimetres in diameter. These polyps reproduce asexually by budding, but remain attached to each other, forming a multi-polyp colony of clones with a common skeleton, which may be up to several metres in diameter or height according to species.

<span class="mw-page-title-main">Ivory bush coral</span> Species of cnidarian

Oculina varicosa, or the ivory bush coral, is a scleractinian deep-water coral primarily found at depths of 70-100m, and ranges from Bermuda and Cape Hatteras to the Gulf of Mexico and the Caribbean. Oculina varicosa flourishes at the Oculina Bank off the east coast of Florida, where coral thickets house a variety of marine organisms. The U.S. National Marine Fisheries Service considers Oculina a genus of concern, due to the threat of rapid ocean warming. Species of concern are those species about which the U.S. Government's National Oceanic and Atmospheric Administration (NOAA), National Marine Fisheries Service, has some concerns regarding status and threats, but for which insufficient information is available to indicate a need to list the species under the U.S. Endangered Species Act (ESA). While Oculina is considered a more robust genus in comparison to tropical corals, rising ocean temperatures continue to threaten coral health across the planet.

<i>Pocillopora</i> Genus of corals

Pocillopora is a genus of stony corals in the family Pocilloporidae occurring in the Pacific and Indian Oceans. They are commonly called cauliflower corals and brush corals.

<i>Galaxea fascicularis</i> Species of coral

Galaxea fascicularis is a species of colonial stony coral in the family Euphylliidae, commonly known as octopus coral, fluorescence grass coral, galaxy coral among various vernacular names.

<i>Pseudodiploria clivosa</i> Species of coral

Pseudodiploria clivosa, the knobby brain coral, is a colonial species of stony coral in the family Mussidae. It occurs in shallow water in the West Atlantic Ocean and Caribbean Sea.

<i>Cynarina lacrymalis</i> Species of coral

Cynarina lacrymalis is a species of stony coral in the family Lobophylliidae. It is variously known as the flat cup coral, solitary cup coral, button coral, doughnut coral, or cat's eye coral. It is found in the western Indo-Pacific Ocean and is sometimes kept in reef aquaria.

<i>Pocillopora verrucosa</i> Species of coral

Pocillopora verrucosa, commonly known as cauliflower coral, rasp coral, or knob-horned coral, is a species of stony coral in the family Pocilloporidae. It is native to tropical and subtropical parts of the Indian and Pacific Oceans.

<i>Orbicella faveolata</i> Species of coral

Orbicella faveolata, commonly known as mountainous star coral, is a colonial stony coral in the family Merulinidae. Orbicella faveolata is native to the coral coast of the Caribbean Sea and the Gulf of Mexico and is listed as "endangered" by the International Union for Conservation of Nature. O. faveolata was formerly known as Montastraea faveolata.

<i>Astrangia</i> Genus of corals

Astrangia is a genus of stony corals in the family Rhizangiidae. Members of this genus are non-reef building corals and are found in the Atlantic and Indo-Pacific Oceans. They are solitary corals with large polyps and are found in clumps. They reproduce from stolons. The corallites are small with simple toothed septa.

Astrangia solitaria, the dwarf cup coral or southern cup coral, is a species of stony coral in the family Rhizangiidae. It is native to shallow water in the western Atlantic Ocean and the Caribbean Sea.

<i>Turbinaria reniformis</i> Species of coral

Turbinaria reniformis, commonly known as yellow scroll coral, is a species of colonial stony coral in the family Dendrophylliidae. It is native to the Indo-Pacific region. The International Union for Conservation of Nature has rated its conservation status as being "vulnerable".

<i>Seriatopora hystrix</i> Species of coral

Seriatopora hystrix is a species of colonial stony coral in the family Pocilloporidae. It forms a branching clump and is commonly known as thin birdsnest coral. It grows in shallow water on fore-reef slopes or in sheltered lagoons, the type locality being the Red Sea. It is native to East Africa, the Red Sea and the western Indo-Pacific region. It is a common species and the International Union for Conservation of Nature has assessed its conservation status as being of "least concern".

<i>Coelastrea aspera</i> Species of stony coral

Coelastrea aspera is a species of stony coral in the family Merulinidae. It is a colonial species native to the Indo-Pacific region where it occurs in shallow water. It was first described by the American zoologist Addison Emery Verrill in 1866 as Goniastrea aspera but it has since been determined that it should be in a different genus and its scientific name has been changed to Coelastrea aspera. This is a common species throughout much of its wide range and the International Union for Conservation of Nature has rated its conservation status as being of "least concern".

<i>Favites complanata</i> Species of coral

Favites complanata is a species of stony coral in the family Merulinidae, sometimes known as the larger star coral. It is native to the Indo-Pacific region and its range extends from the Red Sea and Indian Ocean to the western and central Pacific Ocean. This is an uncommon species of coral and seems to be decreasing in abundance, and the International Union for Conservation of Nature has rated its conservation status as being "near threatened".

<span class="mw-page-title-main">Holobiont</span> Host and associated species living as a discrete ecological unit

A holobiont is an assemblage of a host and the many other species living in or around it, which together form a discrete ecological unit through symbiosis, though there is controversy over this discreteness. The components of a holobiont are individual species or bionts, while the combined genome of all bionts is the hologenome. The holobiont concept was initially introduced by the German theoretical biologist Adolf Meyer-Abich in 1943, and then apparently independently by Dr. Lynn Margulis in her 1991 book Symbiosis as a Source of Evolutionary Innovation. The concept has evolved since the original formulations. Holobionts include the host, virome, microbiome, and any other organisms which contribute in some way to the functioning of the whole. Well-studied holobionts include reef-building corals and humans.

<i>Heterocyathus</i> Genus of coral

Heterocyathus is a genus of coral of the family Caryophylliidae.

<span class="mw-page-title-main">Marine microbiome</span>

All animals on Earth form associations with microorganisms, including protists, bacteria, archaea, fungi, and viruses. In the ocean, animal–microbial relationships were historically explored in single host–symbiont systems. However, new explorations into the diversity of marine microorganisms associating with diverse marine animal hosts is moving the field into studies that address interactions between the animal host and a more multi-member microbiome. The potential for microbiomes to influence the health, physiology, behavior, and ecology of marine animals could alter current understandings of how marine animals adapt to change, and especially the growing climate-related and anthropogenic-induced changes already impacting the ocean environment.

<i>Oculina arbuscula</i>

Oculina arbuscula is a branching temperate coral found along the east coast of the United States from Florida to North Carolina. It has a facultative symbiosis with microalgae of the family Symbiodiniaceae. Unlike tropical corals, O. arbuscula can survive without its algal endosymbionts by switching to a predominantly heterotrophic feeding strategy. Symbiotic colonies are typically found in shallower waters due to light availability, whereas aposymbiotic or mixed colonies are found as deep as 200m. The ability of O. arbuscula to exist in different symbiotic states makes it a good model system for studying the cnidarian-dinoflagellate symbiosis.

References

  1. 1 2 3 Aronson, R.; Bruckner, A.; Moore, J.; Precht, B.; E. Weil (2008). "Astrangia poculata". IUCN Red List of Threatened Species . 2008: e.T133446A3749524. doi: 10.2305/IUCN.UK.2008.RLTS.T133446A3749524.en . Retrieved 20 November 2021.
  2. 1 2 Cairns, Stephen (2013). "Astrangia poculata (Ellis & Solander, 1786)". WoRMS. World Register of Marine Species . Retrieved 2015-02-08.
  3. Peters, E.C., Cairns, S.D., Pilson, M.E., Wells, J.W., Jaap, W.C., Lang, J.C., Vasleski, C.E. and St Pierre Gollahon, L., 1988. Nomenclature and biology of Astrangia poculata (= A. danae,= A. astreiformis)(Cnidaria: Anthozoa).
  4. "The Astrangia Working Group". The Astrangia Working Group. Retrieved December 5, 2019.
  5. "The Astrangia Working Group". The Astrangia Working Group. Retrieved 5 December 2019.
  6. 1 2 3 4 Sweat, L.H. (2012-12-28). "Astrangia poculata: Northern cup coral". Smithsonian Marine Station at Fort Pierce. Retrieved 2015-02-08.
  7. Cairns, Stephen (2013). "Astrangia solitaria (Lesueur, 1817)". WoRMS. World Register of Marine Species . Retrieved 2015-02-09.
  8. Dimond J.L., Kerwin A.H., Rotjan R., Sharp K., Stewart F.J., Thornhill D.J. (2013). "A simple temperature-based model predicts the upper latitudinal limit of the temperate coral Astrangia poculata". Coral Reefs. 32 (2): 401–409. Bibcode:2013CorRe..32..401D. doi:10.1007/s00338-012-0983-z. S2CID   18840399.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  9. Davy, Simon K.; Turner, John R. (2003). "Early Development and Acquisition of Zooxanthellae in the Temperate Symbiotic Sea Anemone Anthopleura ballii (Cocks)". The Biological Bulletin. 295 (1): 66–72. doi:10.2307/1543446. JSTOR   1543446. PMID   12917223. S2CID   1733891.
  10. Dimond J., Carrington E. (2007). "Temporal variation in the symbiosis and growth of the temperate scleractinian coral Astrangia poculata". Marine Ecology Progress Series. 348: 161–172. Bibcode:2007MEPS..348..161D. doi: 10.3354/meps07050 .
  11. Dimond, J. and Carrington, E., 2008 Symbiosis regulation in a facultatively symbiotic temperate coral: zooxanthellae division and expulsion Coral Reefs, 27(3), pp.601-604
  12. Grace, S., 2017. Winter Quiescence, Growth Rate, and the Release from Competition in the Temperate Scleractinian Coral Astrangia poculata (Ellis & Solander 1786). Northeastern Naturalist, 24(sp7), pp.B119-B134.
  13. Jacques, T.G.; Pilson, M.E.Q. (1980). "Experimental ecology of the temperate scleractinian coral Astrangia danae I. Partition of respiration, photosynthesis and calcification between host and symbionts". Marine Biology. 60 (2–3): 167–178. doi:10.1007/BF00389160. S2CID   84942034.
  14. DeFilippo L., Burmester E.M., Kaufman L., Rotjan R.D. (2016). "Patterns of surface lesion recovery in the Northern Star Coral, Astrangia poculata". Journal of Experimental Marine Biology and Ecology. 481: 15–24. doi:10.1016/j.jembe.2016.03.016.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  15. Burmester, E.M., Finnerty, J.R., Kaufman, L. and Rotjan, R.D., 2017 Temperature and symbiosis affect lesion recovery in experimentally wounded, facultatively symbiotic temperate corals Marine Ecology Progress Series, 570, pp.87-99
  16. Sharp K.H., Pratte Z.A., Kerwin A.H., Rotjan R.D., Stewart F.J. (2017). "Season, but not symbiont state, drives microbiome structure in the temperate coral Astrangia poculata". Microbiome. 5 (1): 120. doi: 10.1186/s40168-017-0329-8 . PMC   5603060 . PMID   28915923.{{cite journal}}: CS1 maint: multiple names: authors list (link)
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