Aurelia coerulea

Aurelia coerulea is a species from genus Aurelia (also known as moon jellyfish).

Aurelia coerulea
Scientific classification
Kingdom: Animalia
Phylum: Cnidaria
Class: Scyphozoa
Order: Semaeostomeae
Family: Ulmaridae
Genus: Aurelia
Species:
A. coerulea
Binomial name
Aurelia coerulea
von Lendenfeld, 1884

This species is native to Japan,[1] and they can also be found in coastal areas of China, Korea, California, the Mediterranean and other temperate seas.[2][3][4][5][6][7][1][8][9][10][11] They are particularly abundant in artificial habitats and sheltered regions.[2][3] They have a very high reproductive rate which can sequentially cause the blooming event.[12][4][5][13][8][10][11] A.coerulea blooming causes problems such as impairing fisheries, clogging the nuclear power plants and disrupting the local zooplankton abundance.[12][4][5][13][8][10][11] The chemical compounds they secrete for self-defense mechanism can be used for pharmaceutical purposes.[3][7]

Habitat

A.coerulea are mainly distributed in culture ponds, artificial reefs, lagoons, marinas, and other cold and shady artificial constructions for settlement and proliferation.[2][3] They are weak swimmers so those structures can protect the polyps from being washed away.[2] Hypoxia in coastal waters induces stress and disrupts life cycles of the benthic organisms, but A.coerulea polyps are more tolerant than some other competitors under low dissolved oxygen level, so their population increase while others left due to stress.[12] A.coerulea like ambient temperature, disrupted temperature and salinity will bring detrimental effects to them.[4][5][13][11]

Blooming

It has been reported that blooming of the A.coerulea medusae clogged cooling water intakes and increased shut down frequency of nuclear power plants.[8] Also, blooming occur in eutrophic embayments disrupts the local zooplankton abundance.[10] Planktonic ciliates are abundant in eutrophic embayments, the A.coerulea polyp and ephyra actively devour and assimilate ciliates until medusa stage, medusa then prey on mesozooplankton and macrozooplankton.[10] The ephyra can tolerate long period of starvation and grow to medusa in spring with better food conditions.[10] The high abundance of medusae decreases mesozooplankton and macrozooplankton but increases microzooplankton population, which will later become the food source for A.coerulea polyps, resulting in another bloom as a cycle.[10]

Life cycle

A.coerulea has two life cycles, the metagenetic life cycle and direct development life cycle, it can alternate life cycle strategies based on environmental conditions.[6]

In metagenetic life cycle, the A.coerulea planula turns into polyp then attach to substrates for up to half a year till strobilation.[6] Under warm condition, the polyps will reproduce asexually, under cold condition, the polyps will grow then strobilate.[6] Some disadvantages of this life cycle is that the polyps have to compete for space and beware of predation.[6]

In direct development life cycle, A.coerulea planula turns into ephyra, ephyra stage has longer longevity and higher chance to find substrates to settle down.[6] While this stage has low mortality but their population growth is lower as compared to the other life cycle.[6]

Potential uses

A.coerulea lives in bacteria rich habitat, it secretes phenolic compound, which is known for its antioxidant property in nature.[3] Also it has been reported that it shows lysozyme-like activity in its oral arms, umbrella tissues and mucus.[3] Those unique mechanisms can be contributing to their self-defense system against bacteria.[3] Extraction of those compounds can be used for biotechnological and pharmaceutical purposes.[3]

References
  1. Frolova, Alexandra, and Maria P. Miglietta. "Insights on Bloom Forming Jellyfish (Class: Scyphozoa) in the Gulf of Mexico: Environmental Tolerance Ranges and Limits Suggest Differences in Habitat Preference and Resistance to Climate Change among Congeners." Frontiers in Marine Science, 2020. ProQuest, https://login.pallas2.tcl.sc.edu/login?url=https://www.proquest.com/scholarly-journals/insights-on-bloom-forming-jellyfish-class/docview/2359779007/se-2, doi:http://dx.doi.org/10.3389/fmars.2020.00093.
  2. Dong, Zhijun, et al. "Artificial Reefs for Sea Cucumber Aquaculture Confirmed as Settlement Substrates of the Moon Jellyfish 0RW1S34RfeSDcfkexd09rT2Aurelia Coerulea1RW1S34RfeSDcfkexd09rT2." Hydrobiologia, vol. 818, no. 1, 2018, pp. 223-234. ProQuest, https://login.pallas2.tcl.sc.edu/login?url=https://www.proquest.com/scholarly-journals/artificial-reefs-sea-cucumber-aquaculture/docview/2024252471/se-2, doi:http://dx.doi.org/10.1007/s10750-018-3615-y.
  3. Stabili, Loredana, et al. "Jellyfish Bioprospecting in the Mediterranean Sea: Antioxidant and Lysozyme-Like Activities from 0RW1S34RfeSDcfkexd09rT2Aurelia Coerulea1RW1S34RfeSDcfkexd09rT2 (Cnidaria, Scyphozoa) Extracts." Marine Drugs, vol. 19, no. 11, 2021, pp. 619. ProQuest, https://login.pallas2.tcl.sc.edu/login?url=https://www.proquest.com/scholarly-journals/jellyfish-bioprospecting-mediterranean-sea/docview/2602139589/se-2, doi:http://dx.doi.org/10.3390/md19110619.
  4. Marques, Raquel, et al. "Dynamics and Asexual Reproduction of the Jellyfish 0RW1S34RfeSDcfkexd09rT2Aurelia Coerulea1RW1S34RfeSDcfkexd09rT2 Benthic Life Stage in the Thau Lagoon (Northwestern Mediterranean)." Marine Biology, vol. 166, no. 6, 2019, pp. 1-14. ProQuest, https://login.pallas2.tcl.sc.edu/login?url=https://www.proquest.com/scholarly-journals/dynamics-asexual-reproduction-jellyfish-i-aurelia/docview/2222455095/se-2?accountid=13965, doi:http://dx.doi.org/10.1007/s00227-019-3522-4.
  5. Sun-Hee, Lee, et al. "Contrasting Effects of Regional and Local Climate on the Interannual Variability and Phenology of the Scyphozoan, 0RW1S34RfeSDcfkexd09rT2Aurelia Coerulea1RW1S34RfeSDcfkexd09rT2 and 0RW1S34RfeSDcfkexd09rT2Nemopilema Nomurai1RW1S34RfeSDcfkexd09rT2 in the Korean Peninsula." Diversity, vol. 13, no. 5, 2021, pp. 214. ProQuest, https://login.pallas2.tcl.sc.edu/login?url=https://www.proquest.com/scholarly-journals/contrasting-effects-regional-local-climate-on/docview/2532327191/se-2, doi:http://dx.doi.org/10.3390/d13050214.
  6. Suzuki, Kentaro S., et al. "Seasonal Alternation of the Ontogenetic Development of the Moon Jellyfish Aurelia Coerulea in Maizuru Bay, Japan." PLoS One, vol. 14, no. 11, 2019. ProQuest, https://login.pallas2.tcl.sc.edu/login?url=https://www.proquest.com/scholarly-journals/seasonal-alternation-ontogenetic-development-moon/docview/2316770006/se-2, doi:http://dx.doi.org/10.1371/journal.pone.0225513.
  7. Liu, Wenwen, et al. "Stress-Induced Mucus Secretion and its Composition by a Combination of Proteomics and Metabolomics of the Jellyfish Aurelia Coerulea." Marine Drugs, vol. 16, no. 9, 2018. ProQuest, https://login.pallas2.tcl.sc.edu/login?url=https://www.proquest.com/scholarly-journals/stress-induced-mucus-secretion-composition/docview/2125111989/se-2, doi:http://dx.doi.org/10.3390/md16090341.
  8. Feng, Song, et al. “Strobilation of Three Scyphozoans (Aurelia Coelurea, Nemopilema Nomurai, and Rhopilema Esculentum) in the Field at Jiaozhou Bay, China.” Marine Ecology Progress Series, vol. 591, Inter-Research Science Center, 2018, pp. 141–53, https://www.jstor.org/stable/26502942.
  9. Yoseph Seo, Jinho Chae & Jang-Seu Ki (2020) The complete mitochondrial genome of the jellyfish Aurelia coerulea (Cnidaria and Scyphozoa) with phylogenetic analysis, Mitochondrial DNA Part B, 5:2, 1929-1930, DOI: 10.1080/23802359.2020.1749155
  10. Kamiyama, T. Planktonic ciliates as food for the scyphozoan Aurelia coerulea: feeding and growth responses of ephyra and metephyra stages. J Oceanogr 74, 53–63 (2018). https://doi-org.pallas2.tcl.sc.edu/10.1007/s10872-017-0438-9
  11. Zhijun Dong, Tingting Sun. Combined effects of ocean acidification and temperature on planula larvae of the moon jellyfish Aurelia coerulea, Marine Environmental Research, Volume 139, 2018, Pages 144-150, ISSN 0141-1136, https://doi.org/10.1016/j.marenvres.2018.05.015.
  12. Jin, Hongsung, et al. "Dissolved Oxygen-and Temperature-Dependent Simulation of the Population Dynamics of Moon Jellyfish (0RW1S34RfeSDcfkexd09rT2Aurelia Coerulea1RW1S34RfeSDcfkexd09rT2) Polyps." Diversity, vol. 13, no. 5, 2021, pp. 184. ProQuest, https://login.pallas2.tcl.sc.edu/login?url=https://www.proquest.com/scholarly-journals/dissolved-oxygen-temperature-dependent-simulation/docview/2532336007/se-2, doi:http://dx.doi.org/10.3390/d13050184.
  13. Dong, Zhijun, et al. “Effects of Salinity and Temperature on the Recruitment of Aurelia Coerulea Planulae.” Marine Biology Research, vol. 14, no. 5, June 2018, pp. 454–61. EBSCOhost, doi-org.pallas2.tcl.sc.edu/10.1080/17451000.2018.1459725.


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