Cassiopea Literature
Article Name | Year | Author | Location where jellies were collected | Type of publication | Study | Species studied | Species ID method | Search Engine | ||||||||||
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On a new species of Cassiopea from Jamaica | 1892 | Bigelow, R..P. | Jamaica | Memoir | species description, anatomy, taxonomy | xamachana | morphology | N/A | ||||||||||
The anatomy and development of Cassiopea xamachana | 1900 | Bigelow, R..P. | Port Henderson, Jamaica | Memoir | development, anatomy | xamachana | morphology | N/A | ||||||||||
Nerve conduction, and other reactions in Cassiopea | 1916 | ALFRED GOLDSBOROUGH MAYER | Florida | paper | physiology | xamachana | morphology | web of science | ||||||||||
The influence of the marginal sense organs on the rate of regeneration in Cassiopea xamachana | 1916 | Cary, L. | Ft. Jefferson, Dry Tortugas, Florida | paper | regeneration, development, physiology | xamachana | morphology | SC | ||||||||||
FURTHER STUDIES OF NERVE CONDUCTION IN CASSIOPEA | 1917 | Alfred Mayer | UNKNOWN | Memoir | nerves, physiology | sp | morphology | other | ||||||||||
The development of Cassiopea andromeda | 1960 | Gohar, Eisawy | UNKNOWN | Memoir | development, developmental biology | andromeda | morphology | other | ||||||||||
Caribbean Scyphomedusae of the Genus Cassiopea | 1968 | Hummelinck | multiple | paper | species description, anatomy, taxonomy | xamachana, andromeda, frondosa | morphology | other | ||||||||||
Caribbean scyphomedusae of the genus cassiopea | 1968 | Wagenaar | multiple | Book chapter | survey, geography | xamachana and frondosa | morphology | web of science | ||||||||||
Cyclopoid copepod assoaciated with a medusa in puerto rico | 1969 | Humes | La Parguera, Puerto Rico | paper | association, copepods | xamachana | morphology | web of science | ||||||||||
Normal and experimentally modified development of buds in Cassiopea (Phylum Coelenterata; Class Schyphozoa) | 1971 | Curtis, S., and Cowden, R. R. | Big Pine Key, Florida | paper | development, life cycle, asexual repro | sp | morphology | other | ||||||||||
Some aspects of regeneration in the scyphistoma of Cassiopea (Class Scyphozoa) as revealed by the use of antimetabolites and microspectrophotometry | 1974 | Curtis, S., and Cowden, R. R. | Big Pine Key, Florida | paper | life cycle, development, antimetabolites | sp | morphology | other | ||||||||||
Productivity and organic consumption in Cassiopea and Condylactus | 1975 | Cates | Florida Keys | paper | zooxanthellae, nutrient uptake, organic matter | sp | morphology | web of science | ||||||||||
Strobilation, Budding and Initiation of Scyphistoma Morphogenesis in the Rhizostome Cassiopea andromeda (Cnidaria: Scyphozoa) | 1978 | Hofmann, Neumann and Henne | Aquazoo Löbbecke Museum Dusseldorf, Germany | paper | life cycle, development, zooxanthellae | andromeda | morphology | web of science | ||||||||||
Bacterial Induction of Settlement and Metamorphosis in the Planula Larvae of Cassiopea andromeda (Cnidaria: Scyphozoa, Rhizostomeae) | 1979 | Neumann | Florida Keys | paper | life cycle, development, zooxanthellae | andromeda | morphology | web of science | ||||||||||
Carbon metabolism and strobilation in Cassiopea Andromeda (Cnidaria: Scyphozoa): Significance of Endosymbiotic dinoflagellates | 1981 | Hofmann and Kremer | lab-reared | paper | development, metabolism and zooxanthallae | andromeda | morphology | Web of science | ||||||||||
Selectivity in phagocytosis and persistence of symbiotic algae by the scyphistoma stage of the jellyfish Cassiopea xamachana | 1983 | Colley, N. J., and Trench, R. K. | Florida | paper | macromoplecules, celullar, symbiosis | xamachana | morphology | web of science | ||||||||||
A New Dondice (opisthobranchia;favorinidae) predator of Cassiopea in southwest Puerto Rico | 1985 | Brandon and Cutress | La Parguera, Puerto Rico | paper | nudibranch, predation, description | xamachana | morphology | scholar google | ||||||||||
Ammonia induces metamorphosis of the oral half of buds into polyp heads in the scyphozoan Cassiopea | 1987 | Berking and Schüle | lab-reared | paper | development, metamorphosis, ammonia | andromeda | morphology | scholar google | ||||||||||
An Unusual blue mesogleal protein from the mangrove jellyfish Cassiopea xamachana | 1987 | Blanquet and Phelan | Marine Specimens Unltd, Summerland Key, FL | paper | blue mesogleal protein, molecular | xamachana | morphology | web of science | ||||||||||
Requirement of exogenous inducers for metamorphosis of axenic larvae and buds of Cassiopea andromeda (Cnidaria: Scyphozoa) | 1987 | Fitt, Hofmann, Wolk and Rahat | Israel | paper | development, life cycle, asexual repro | andromeda | morphology | web of science | ||||||||||
Induction of Metamorphosis in the Symbiotic Scyphozoan Cassiopea andromeda: Role of Marine Bacteria and of Biochemicals | 1987 | Hofmann and Brand | Israel | paper | development, metamorphosis, asexual repro | andromeda | morphology | scholar google | ||||||||||
Bud formation and metamorphosis in Cassiopea andromeda (Cnidaria: Scyphozoa): a developmental and ustrastructural study | 1990 | Hofmann and Honegger | Aquazoo Löbbecke Museum Dusseldorf, Germany | paper | development, life cycle, asexual repro | andromeda | morphology | web of science | ||||||||||
Bud formation in the scyphozoan Cassiopea andromeda: epithelial dynamics and fate map (Coelenterate Biology Book) | 1991 | Hofmann and Gottieb | lab-reared | Book chapter | development, developmental biology | andromeda | morphology | web of science | ||||||||||
Development of Planuloid Buds of Cassiopea xamachana (Cnidaria: Scyphozoa) | 1992 | Van Lieshout and Martin | lab-reared | paper | development, life cycle, asexual repro | xamachana | morphology | web of science | ||||||||||
Check points in the life cycle of cassiopea control of metagenesis and metamorphosis in a tropical jellyfish | 1996 | Hofmann, Fitt and Fleck | none | paper | experimental data review, development and metagenesis triggers in vitro | spp | morphology | web of science | ||||||||||
The role of temperature in survival of the polyp stage of the tropical rhizostome jellyfish Cassiopea xamachana | 1998 | Fitt and Costley | Florida Keys | paper | zooxanthellae uptake, development | xamachana | morphology | scholar google | ||||||||||
Chemical fate of a metamorphic inducer in larvae-like buds of the Cnidarian Cassiopea andromeda | 1998 | Fleck, J. | lab-reared | paper | polyp, development, metamorphosis, buds, larvae, chemical cue | andromeda | morphology | scholar google | ||||||||||
Production, respiration, and photophysiology of the mangrove jellyfish Cassiopea xamachana symbiotic with zooxanthellae: effect of jellyfish size and season | 1998 | Verde and McCloskey | Florida Keys | paper | carbon budget, chlorophyll levels, function of size and seasonality | xamachana | morphology | scholar google | ||||||||||
Degrading mangrove leaves of Rhizophora mangle Linne provide a natural cue for settlement and metamorphosis of the upside down jellyfish Cassiopea xamachana Bigelow | 1999 | Fleck and Fitt | Florida Keys | paper | development, life cycle, asexual repro | xamachana | morphology | scholar google | ||||||||||
A proline-rich originating from decomposing mangrove leaves is one natural metamorphic cue of the tropical jellyfish cassiopea xamachana | 1999 | Fleck Fitt Hanh | Florida Keys | paper | development, life cycle, asexual repro | xamachana | morphology | scholar google | ||||||||||
Cassiopea xamachana as a bioindicator of dissolved inorganic Phosphates in seawater | 2000 | Brian Todd, William Fitt | Florida Keys | thesis | DIP, levels, phosphate uptake, bioindicator | xamachana | morphology | web of science | ||||||||||
Management of jellyfish fisheries, with special reference to the Order Rhizostomeae | 2000 | Kingsford, Pitt, Gillanders | multiple | manual, paper | fisheries, management | andromeda | morphology | research gate | ||||||||||
Pelagic coelenterates and eutrophication: a review | 2001 | Arai | Review | review | eutrophication, review, jellyfish | review | review | scholar google | ||||||||||
A comparison of the toxinological characteristics of two Cassiopea and Aurelia species | 2001 | Radwan, Burnett, Bloom Coliano Eldefrawi Erdely Arelian Torres and Heimer-dela Cotera | Qusier, Egypt; Harbour Island, Bahamas; Chesapeake Bay, MD-VA | paper | toxicology, venom comparison, cnidom | xamachana and andromeda | morphology | scholar google | ||||||||||
Hermaphroditism, gonochorism, and asexual reproduction in Cassiopea sp—an immigrant in the islands of Hawai’i | 2002 | Hofmann and Hadfield | Oahu, Hawaii | paper | development, metamorphosis, asexual repro | sp | morphology | scholar google | ||||||||||
Some toxicological characteristics ofthree venomous soft corals from the Red Sea | 2002 | Radwan, Aboul-Dahab, Burnett | Red Sea | paper | Soft coral; Toxins; Venoms; Anthozoa; Nephthea; Dendronephthya; Heteroxenia fuscescens; Nematocyst; Red Sea | xamachana | morphology | web of science | ||||||||||
Variation in Host-Symbiont Compatibility Among Cassiopea- Algal Symbioses | 2003 | Adrianne Joy Sloan | Florida Keys | dissertation | symbiodinium, zooxanthallae, development, life cycle | xamachana | morphology | web of science | ||||||||||
Location and Quantification of Carbonic Anhydrase Activity in the Symbiotic Scuphozan Cassiopea xamachana | 2003 | Estes, Kempf, Henry | Marathon Key, Florida | paper | carbon chemistry, zooxanthellae, bleaching | xamachana | morphology | web of science | ||||||||||
An endogenous peptide is involved in internal control of metamorphosis in the marine invertebrate Cassiopea xamachana (Cnidaria : Scyphozoa) | 2003 | Thieme and Hofmann | Florida Keys | paper | cassiopea, metamorphosis, active peptide | xamachana | morphology | web of science | ||||||||||
Control of head morphogenesis in an invertebrate asexually produced larva-like bud (Cassiopea andromeda; Cnidaria: Scyphozoa) | 2003 | Thieme and Hofmann | lab-reared | paper | development, life cycle, asexual repro | andromeda | morphology | web of science | ||||||||||
Global phylogeography of Cassiopea (Scyphozoa: Rhizostomeae): molecular evidence for cryptic species and multiple invasions of the Hawaiian Islands | 2004 | Holland, Dawson, Crow, Hofmann | Hawaii Islands | paper | DNA Barcoding, phylogenetics | andromeda | molecular | scholar google | ||||||||||
Toxicity and mAChRs binding activity of Cassiopea xamachana venom from Puerto Rican coasts | 2005 | Radwan, Roman, Baksi, Burnett | Puerto Rico | paper | toxicology, venom comparison, cnidom | xamachana | morphology | web of science | ||||||||||
A new record of an alien jellyfish from the Levantine coast of Turkey – Cassiopea andromeda (Forsskål, 1775) (Cnidaria: Scyphozoa:Rhizostomea) | 2006 | Çevik, C. | Turkey | paper | Cassiopea andromeda, Scyphozoa, Levant Sea, Turkey, Iskenderun Bay, alien species | andromeda | scholar google | |||||||||||
Associations between metals and the blue mesogleal protein of Cassiopea xamachana | 2006 | Pnelan, Matta, Reyes, Fernando, Boykins and Blanquet | La Parguera Puerto Rico | paper | blue mesogleal protein, metals, molecular | xamachana | morphology | web of science | ||||||||||
Natural infections of aposymbiotic Cassiopea xamachana scyphistomae from environmental pools of Symbiodinium | 2006 | Thornhill, Daniel, LaJeunesse, Schmidt, Fitt | Florida Bay | paper | zooxanthellae, infection, symbiosis | xamachana | morphology | web of science | ||||||||||
Patterns of inorganic phosphate uptake in Cassiopea xamachana: A bioindicator species | 2006 | Todd, Thornhill and Fitt | Florida Keys | paper | different DIP uptake by symbionts and jellies, | xamachana | morphology | scholar google | ||||||||||
Effects of bleaching and nutrient supplementation on wet weight in the jellyfish Cassiopea xamachana (Bigelow) (Cnidaria: Scyphozoa) | 2008 | McGill and Pomory | Florida Keys | paper | bleaching, POM/DOM, nutrient | xamachana | morphology | scholar google | ||||||||||
A review and synthesis on the systematics and evolution of jellyfish blooms: advantageous aggregations and adaptive assemblages | 2009 | Hammer and Dawson | Review | review | jellyfish blooms, evolution, adaptations, review | andromeda | molecular | scholar google | ||||||||||
Light intensity influences the production and translocation of fatty acids by zooxanthellae in the jellyfish Cassiopea sp | 2009 | Mortillaro, Pitt, Lee and Meziane | Queensland, Australia | paper | zooxanthellae, fatty acids, symbiosis | sp | morphology | scholar google | ||||||||||
Prediction, Location, Collection and Transport of Jellyfish (Cnidaria) and Their Polyps | 2009 | Pierce | Review | review | prediction, review of jellies in general and polyps | review | review | Science Direct | ||||||||||
Oxygen and nutrient dynamics of the upside down jellyfish (Cassiopea sp) and its influence on benthic nutrient exchanges and primary production | 2009 | Welsh, Dunn and Meziane | Queensland, Australia | paper | nutrient dynamics, exchanges, primary production | sp | morphology | web of science | ||||||||||
Enhanced pore-water nutrient fluxes by the upside-down jellyfish Cassiopea sp in a Red Sea coral reef | 2010 | Jantzen, Wild, Rasheed, El-Zibdah, Ritcher | Gulf of Aqaba | paper | pore-water benthic fluxes, nutrient uptake, photosynthesis performance and respiration, | sp | morphology | scholar google | ||||||||||
Spatial distribution of the upside-down jellyWsh Cassiopea sp within fringing coral reef environments of the Northern Red Sea: implications for its life cycle | 2010 | Niggl and Wild | Northern Red Sea, Gulf of Aqaba, Jordan | paper | spatial survey, different habitats, bioindicator, habitat selection, field ecology | sp | morphology | scholar google | ||||||||||
Organic matter release by the benthic upside-down jellyfish Cassiopea sp fuels pelagic food webs in coral reefs | 2010 | Niggl, Nauman, Struck, Manasrah and Wild | Gulf of Aqaba | paper | quantify organic matter release if Cassiopea and if this is transferred to planktonic microbes and zooplankton | sp | morphology | scholar google | ||||||||||
Comparison of telomere length among different life cycle stages of the jellyfish Cassiopea andromeda | 2010 | Ojimi and Hidaka | Enoshima Aquarium- Japan | paper | genetics | andromeda | molecular | web of science | ||||||||||
Identification key for young ephyrae: a first step for early detection of jellyfish blooms | 2010 | Pohl and Jarms | museum/lab-reared | Book chapter | development, structures | none | review | web of science | ||||||||||
Trace element accumulation in Cassiopea sp (Scyphozoa) from urban marine environments in Australia | 2010 | Templeman and Kignsford | Australia | paper | biomonitor, trace metals, urban, anthropogenic impact, bioindicator | sp | morphology | web of science | ||||||||||
A numerical study of the effects of bell pulsation dynamics and oral arms on the exchange currents generated by the upside-down jellyfish Cassiopea xamachana | 2011 | Hamlet, Santhanakrishnan and Miller | lab-reared | paper | mathematical model, experimental, flow, fluid dynamics | xamachana | morphology | scholar google | ||||||||||
Primer regustro de dondice parguerencis para Venezuela | 2011 | Mariño, Farfán and Caballer | venezuela | paper | nudibranch, predation, description | xamachana | morphology | Science Direct | ||||||||||
Effects of anthropogenic disturbance on the abundance and size of epibenthic jellyfish Cassiopea spp. | 2011 | Stoner, Layman, Yeager, Hassett | Abaco, Bahamas | paper | coastal pollution, human populations, bioindicator | spp | morphology | scholar google | ||||||||||
Feeding Currents of the Upside Down Jellyfish in the Presence of Background Flow | 2012 | Hamlet and Miller | Carolina Biological Supply Company (Burlington, NC) and Gulf Specimen Marine Laboratories, Inc. (Panacea, FL) | paper | fluid dynamics, flow, feeding | spp | morphology | web of science | ||||||||||
Flow structure and transport characteristics of feeding and exchange currents generated by upside-down Cassiopea jellyfish | 2012 | Santhanakrishnan, Dollinger, Hamlet, Colin and Miller | Gulf specimen marine lab, Florida Carolina Biological Supply, North Carolina New England Aquarium Boston, Massachussets | paper | fluid dynamics, physics | xamachana and frondosa | morphology | web of science | ||||||||||
The utility of statoliths and bell size to elucidate age and condition of a scyphomedusa (Cassiopea sp) | 2013 | Hopf and Kingsford | Marine and Aquaculture Research Facilities Unit at James Cook University, Townsville | paper | statolith, proxies to age medusae (in this case Cassiopea) | xamachana | morphology | Science Direct | ||||||||||
Anti-inflammatory activity of pure upside down jellyfish Cassiopea xamachana (Bigelow, 1900) on male sprague dawley rats. | 2013 | Gorgonio, Go | unkown | thesis | antiinflamatory, medical | xamachana | morphology | web of science | ||||||||||
Human driven benthic jellyfish blooms: Causes and Consequences for coastal marine ecosystems | 2014 | Elizabeth Stoner | Abaco, Bahamas | dissertation | bioindicator, field ecology, human impact | sp | morphology | web of science | ||||||||||
Variation in symbiont uptake in the early ontogeny of the upside-down jellyfish, Cassiopea spp. | 2014 | Mellas, Mcllroy, fitt and coffroth | Florida Keys, Monterey Bay Aquarium | paper | symbiont uptake, development | xamachana and ornata | morphology | Science Direct | ||||||||||
Asexual reproduction strategies and blooming potential in Scyphozoa | 2014 | Schiariti, Morandini, Jarms, Paes, Franke and Miazan | lab-reared | paper | development, reproduction | sp | morphology | web of science | ||||||||||
Effects of Epibenthic Jellyfish, Cassiopea spp., on Faunal Community Composition of Bahamian Seagrass Beds | 2014 | Stoner, Yeager and Layman | Abaco, Bahamas | paper | ecology, community composition | spp | morphology | scholar google | ||||||||||
Modification of a seagrass community by benthic jellyfish blooms and nutrient enrichment | 2014 | Stoner, Yeager, Sweatman, Sebilian and Layman | Abaco, Bahamas | paper | ecology, anthropogenic nutrient enrichment (via fertilizer additions), proliferations | sp | morphology | scholar google | ||||||||||
Temperature-driven asexual reproduction and strobilation in three scyphozoan jellyfish polyps | 2014 | Treible and Condon | lab-reared | paper | strobilation, temp influence, development comparison b/w scyphomedusae, ocean acidification | sp | morphology | scholar google | ||||||||||
Revised descriptions of the nematocysts and the asexual reproduction modes of the scyphozoan jellyfish Cassiopea andromeda (Forska°l, 1775) | 2015 | Heins, Glatzel and Holst | Red Sea, North Sea | paper | development, nematocysts and asexual repro | andromeda | morphology | web of science | ||||||||||
Bristle worm attack: benthic jellyfish are not trophic dead ends | 2015 | Stoner and Layman | Abaco, Bahamas | Research Note | predation of cassiopea | spp | morphology | scholar google | ||||||||||
Fine-scale detection of pollutants by a benthic marine jellyfish | 2016 | Epstein, Templeman and Kingsford | Queensland, Australia | paper | trace metals, bioaccumulation, pollution | maremetens | morphology | web of science | ||||||||||
Symbiont carbon and nitrogen assimilation in the Cassiopea–Symbiodinium mutualism | 2016 | Freeman, Stoner, Easson, Matterson, Baker | Panamá | paper | C,N assimilations in tissue under light and dark conditions; nutrient dynamics | xamachana | morphology | web of science | ||||||||||
Spatiotemporal distribution, abundance, and species–environment relationships of Scyphozoa (Cnidaria) species in Hisarönü, Marmaris, and Fethiye bays (Muğla, Turkey) | 2016 | GÜLŞAHİN, TARKAN, TARKAN | Turkey | paper | spatiotemporal distribution, abundance, species-environment relationship | andromeda | morphology | web of science | ||||||||||
First Records of the Invasive “Upside-down Jellyfish”, Cassiopea (Cnidaria: Scyphozoa: Rhizostomeae: Cassiopeidae), from Coastal Lakes of New South Wales, Australia | 2016 | Keable and Ahyong | Australia | paper | invasive species, cassiopea bloom | ndrosia | morphology | web of science | ||||||||||
Reduced salinity increases susceptibility of zooxanthellate jellyfish to herbicide toxicity during a simulated rainfall event | 2016 | Klein, Pitt and Carroll | Australia | paper | zooxanthellae, nutrient pollution | sp | morphology | web of science | ||||||||||
Surviving but not thriving: inconsistent responses of zooxanthellate jellyfish polyps to ocean warming and future UV-B scenarios | 2016 | Klein, Pitt and Carroll | Queensland, Australia | scientific report | zooxanthellae uptake, development | sp | morphology | web of science | ||||||||||
Cassiopea and its zooxanthellae (The Cnidaria: Past, Present, Future) | 2016 | lampert | none | Book chapter | review-like structure of Cassiopea and zooxanthellae | sp | morphology | web of science | ||||||||||
All non-indigenous species were introduced recently? The case study of Cassiopea (Cnidaria: Scyphozoa) in Brazilian waters | 2016 | Morandini, Stampar, Maronna and Silveira | Brazil | paper | invasive species, cassiopea bloom, dna barcoding COI | andromeda | molecular | web of science | ||||||||||
Comparison of zooxanthellae densities from upside-down jellyfish, Cassiopea xamachana, across coastal habitats of The Bahamas | 2016 | Stoner, Sebilian and Layman | Abaco, Bahamas | Research Note | field ecology | xamachana | morphology | web of science | ||||||||||
Cellular respiration, oxygen consumption and trade offs of the jellyfish Cassiopea sp In response to temperature change | 2017 | Ajbour Zimmer and Hunzmann | Bremen, Germany | paper | metabolism, stressors | sp | morphology | web of science | ||||||||||
Phylogenetic relationships and morphological variations of upside-down jellyfishes, Cassiopea spp. inhabiting Palau Islands | 2017 | Arai, Gotoh, Yokoyama, Sato, Okuizumi and Hanzawa | Japan; 5 marine lakes and Kamo aquarium | paper | phylogenetics, phenotipic plasticity | spp | both | research gate | ||||||||||
Indomethacin reproducibly induces metamorphosis in Cassiopea xamachana scyphistomae | 2017 | Cabrales-Arellano, Islas-Flores, Thomé and Villanueva | Mexico | paper | development, nematocysts and asexual repro | xamachana | morphology | scholar google | ||||||||||
The effect of water acidification on zooxanthellae density in upside-down jellyfish, Cassiopea spp | 2017 | Chelsea Gail Weeks | John G. Shedd Aquarium- Chicago Illinois | thesis | ocean acidification, polyps, cassiopea, zooxanthellae density, growth | spp | morphology | web of science | ||||||||||
Hematological parameters on the effect of thejellyfish venom Cassiopea andromeda in animal models | 2017 | Nabipour, Mohebbi, Vatanpour, Vazirizadeh | Iran | paper | venom, toxicology, | andromeda | morphology | scholar google | ||||||||||
The Jellyfish Cassiopea Exhibits a Sleep-like State | 2017 | Nath, Bedbrook, Abrams, Basinger, Bois, Prober, Stemberg, Gradinaru, Goentoro | Florida Keys | scientific report | behavior, genomics, sleep | spp | morphology | scholar google | ||||||||||
Herbicide effects on the growth and photosynthetic efficiency of Cassiopea maremetens | 2017 | Rowen, Templeman and Kingsford | Queensland, Australia | paper | zooxanthellae, herbicide, anthropogenic impact | maremetens | morphology | scholar google | ||||||||||
Metabolic and oxidative stress responses of the jellyfish Cassiopea to pollution in the Gulf of Aqaba, Jordan | 2018 | Aljbour, Al-Horani and Kunzmann | Gulf of Aqaba | paper | metabolism, stressors | sp | morphology | scholar google | ||||||||||
Back with a bang – an unexpected massive bloom of Cassiopea andromeda (Forskaal, 1775) in the Maltese Islands, nine years after its first appearance | 2018 | Deidun, Gauci, Sciberras and Piraino | Mediterranean; Italy | short communication | bloom, field counts, field ecology | andromeda | morphology | web of science | ||||||||||
Acetylcholinesterase inhibitory activity of a neurosteroidal alkaloid from the upside-down jellyfish Cassiopea andromeda venom | 2018 | Mohebbi, G; Nabipour, I; Vazirizadeh, A; Vatanpour, H; Farrokhnia, M; Maryamabadi, A; Bargahi, A | Nayban Bay, Iran | paper | biochemistry, neuroscience, cell biology | andromeda | morphology | Web of science | ||||||||||
Acquisition and proliferation of algal symbionts in bleached polyps of the upside-down jellyfish, Cassiopea xamachana | 2018 | Newkirk, Frazer and Martindale | Florida Keys | paper | polyp bleaching, symbionts, development | xamachana | morphology | web of science | ||||||||||
Upside-Down but Headed in the Right Direction: Review of the Highly Versatile Cassiopea xamachana System | 2018 | Ohdera et al. | Review | review | symbiosis, embryology, climate ecology, genomes, transcriptomes | xamachana | review | web of science | ||||||||||
Contrasting Antibacterial Capabilities of the Surface Mucus Layer From Three Symbiotic Cnidarians | 2018 | Rivera-Ortega and Thomé | Puerto Morelos, México | paper | medicine, antibacterial capacity | xamachana | morphology | web of science | ||||||||||
Experimental effects of multiple thermal stress events on a chlorophyll-a content and size of Cassiopea andromeda and the role of heterotrophic feeding and Symbiodinium concentration | 2018 | Thomás Nei Soto Banha | Brazil | dissertation | thermal stress, zooxanthellae, photosynthesis | andromeda | morphology | web of science | ||||||||||
Metabolic and oxidative stress responses of the jellyfish Cassiopea spto changes in seawater temperature | 2019 | Aljbour, Zimmer, Horani and Kunzmann | MAREE facilities at the Leibniz-Zentrum für Marine Tropenforschung | paper | metabolism, stressors | sp | morphology | scholar google | ||||||||||
Review of the diversity, traits, and ecology of zooxanthellate jellyfishes | 2019 | Djeghri, Pondaven, Stibor and Dawson | none | review | diversity, ecology, zooxanthellae | review | review | web of science | ||||||||||
Regenerative Capacity of the Upside-down Jellyfish Cassiopea xamachana | 2019 | Gamero-Mora, Hakbauer, Bartsch, Stampar, Morandini | Brazil and Florida | paper | regeneration, development | xamachana | molecular | research gate | ||||||||||
Corrigendum: Night-Time Temperature Reprieves Enhance the Thermal Tolerance of a Symbiotic Cnidarian | 2019 | Klein, Pitt, Lucas, Hung, Schmidt-Roach, Aranda and Duarte | Red Sea | paper | correction paper | none | none | web of science | ||||||||||
Night-Time Temperature Reprieves Enhance the Thermal Tolerance of a Symbiotic Cnidarian | 2019 | Klein, Pitt, Lucas, Hung, Schmidt-Roach, Aranda and Duarte | Red Sea | paper | climate change, diel variability | sp | morphology | web of science | ||||||||||
Box, stalked, and upside-down? Draft genomes from diverse jellyfish (Cnidaria, Acraspeda) lineages: Alatina alata (Cubozoa), Calvadosia cruxmelitensis (Staurozoa), and Cassiopea xamachana (Scyphozoa | 2019 | Ohdera, Ames, Dikow, Kayal, Chiodin, Busby, La, Pirro, Collins, Medina and Ryan | lab-reared | Research Note | genomics, phylogeny | xamachana | molecular | web of science | ||||||||||
Molecular identity of the non-indigenous Cassiopea sp from Palermo Harbour (central Mediterranean Sea) | 2019 | Perzia, Sinopoli and Castriota | Mediterranean; Italy | paper | DNA Barcoding, molecular | sp | morphology | web of science | ||||||||||
Does seawater acidification affect zooxanthellae density and health in the invasive upside‐down jellyfish, Cassiopea spp.? | 2019 | weeks, Meaghe, Willink, McCravy | John G. Shedd Aquarium in Chicago | paper | zooxanthellae, OA | sp | morphology | scholar google | ||||||||||
Cassiosomes are stinging cell structures in the mucus of cassiopea | 2020 | Ames et al. | Florida Keys | paper | chemistry, toxicology | xamachana | morphology | web of science | ||||||||||
Juvenile Cassiopea andromeda medusae are resistant to multiple thermal stress events | 2020 | Banha et al. | Brazilian coast | paper | development, life cycle, thermal | andromeda | molecular | web of science | ||||||||||
Cell-free scaffold from jellyfish Cassiopea andromeda (Cnidaria; Scyphozoa) for skin tissue engineering | 2020 | Cervantes et al. | Yucatán, Mexico | paper | biomedical, skin engineering | andromeda | morphology | scholar google | ||||||||||
Modulatory Activities of Plant Extracts on Jellyfish Cytotoxicity | 2020 | Cornara et al. | Aquarium of Genova, Italy | paper | plant medicine, venom, remedy for skil injuries | andromeda | morphology | web of science | ||||||||||
Studies on the cholinesterases inhibiting compounds from the Cassiopea andromeda venom | 2020 | Darabi et al. | Nayband-ba, Iran | paper | venom, toxicology, medicine | andromeda | morphology | web of science | ||||||||||
δ13C, δ15N, and C:N ratios as nutrition indicators of zooxanthellate jellyfishes: insights from an experimental approach | 2020 | Djeghri, Stibor, Lebeau and Pondaven | Aquarium (Trocadéro Aquarium- Paris, France) | paper | bioindicator, human impact | sp | morphology | web of science | ||||||||||
Jelly surge in the Mediterranean Sea: threat or opportunity? | 2020 | Gravili | Review | review | climate change, mediterranean sea, invasive species | review | review | web of science | ||||||||||
Evidence of microplastics from benthic jellyfish (Cassiopea xamachana) in Florida estuaries | 2020 | Iliff, Wilczek, Harris, Bouldin and Stoner | Florida; Florida Keys, Sarasota Bay and Jupiter | paper | microplastics, bioindicator | xamachana | morphology | Science Direct | ||||||||||
Is phenotypic plasticity determined by temperature and fluid regime in filter-feeding gelatinous organisms? | 2020 | Jordano, Morandini and Nagata | Cabo Frio, Brazil | paper | phenotypic plasticity, biomechanics, filtration | andromeda | morphology | web of science | ||||||||||
Risk screening of the potential invasiveness of non-native jellyfishes in the Mediterranean Sea | 2020 | Killi, Tarkan, Kozic, Copp, Davidson and Vilizzi | Mediterranean | paper | risk assesment, ecology, invasive speciess | spp | both | web of science | ||||||||||
First record of upside-down jellyfish Cassiopea andromeda (Forskål, 1775) (Cnidaria: Scyphozoa: Rhizostomeae: Cassiopeidae) from Sri Lanka | 2020 | Krishan D. Karunarathne, Shanika M. Liyanaarachchi and M.D.S.T. de Croos | Sri Lanka, India | paper | report, morphology | andromeda | morphology | scholar google | ||||||||||
Amoebocytes facilitate efficient carbon and nitrogen assimilation in the Cassiopea-Symbiodiniaceae symbiosis | 2020 | Lyndby et al. | DeJong Marinelife (Netherlands) | paper | Cassiopea, photosynthesis, stable isotope labelling, nutrients, electron microscopy, NanoSIMS | sp | morphology | web of science | ||||||||||
Detecting effects of herbicide runoff: The use of Cassiopea maremetens as a biomonitor to hexazinone | 2020 | McKenzie, Templeman, Kingsford | Queensland, Australia | paper | biomonitor, herbicide, bioindicator | maremetens | morphology | web of science | ||||||||||
Adaptation to Bleaching: Are Thermotolerant Symbiodiniaceae Strains More Successful Than Other strains Under Elevated Temperatures in a Model Symbiotic Cnidarian? | 2020 | Newkirk, Frazer, Martindale and Schnitzler | Florida Keys | paper | symbiodinium, zooxanthallae, development, life cycle | xamachana | morphology | web of science | ||||||||||
The puzzling occurrence of the upside-down jellyfish Cassiopea (Cnidaria: Scyphozoa) along the Brazilian coast: a result of several invasion events? | 2020 | Stampar et al. | Brazil | paper | species, jellyfish bloom, medusa, non-native species | andromeda, frondosa, ornata, xamachana | molecular | web of science | ||||||||||
Assessment of scyphozoan diversity, distribution and blooms: Implications of jellyfish outbreaks to the environment and human welfare in Malaysia | 2020 | Syazwan, et al. | Malaysia | paper | distribution, habitat, report | andromeda, sp | morphology | web of science | ||||||||||
Ecologia populacional da medusa exótica Cassiopea andromeda Forskâl, 1775 (Cnidaria: Scyphozoa) em uma fazenda de camarão e em ambiente de manguezal no Nordeste do Brasil | 2020 | Thé, Morandini | Brazil | dissertation | bioindicator, field ecology, human impact, fisheries, density, habitat, DNA Barcoding COI | andromeda | molecular | scholar google | ||||||||||
Size and density of upside-down jellyfish, Cassiopea sp, and their impact on benthic fluxes in a Caribbean lagoon | 2020 | Zarnoch, Hossain, Fusco, Alldred, Hoellein and Perdikaris | Barbuda | paper | ecology | sp | morphology | scholar google | ||||||||||
Fieldable Environmental DNA Sequencing to Assess Jellyfish Biodiversity in Nearshore Waters of the Florida Keys, United States | 2021 | Ames, Ohdera, Colston, Collins, Fitt, Morandini, Erickson, Vora | Florida Keys | paper | edna, jellyfish biodiversity, DNA, barcoding, metabarcoding | xamachana, andromeda frondosa | molecular | web of science | ||||||||||
The internal microenvironment of symbiotic jellyfish Cassiopea sp. from the Red Sea | 2021 | Arossa et al. | King Abdullah Economic City Lagoon, Red Sea | paper | symbiont, photosynthesis, symbiodinium, oxygen, pH | sp | morphology | web of science | ||||||||||
Symbiotic microalgae do not increase susceptibility of zooxanthellate medusae (Cassiopea xamachana) to herbicides | 2021 | Carolina Olguín-Jacobson, Kylie A. Pitt | Sea World; Gold Coast, Australia | paper | herbiciddes effect on zooxanthellae, symbionts, atrazine | xamachana | morphology | scholar google | ||||||||||
New Alien Mediterranean Biodiversity Records (November 2021) | 2021 | Crocetta, et al. | Mediterranean (Lybia) | paper | biodiversity, report, | andromeda | morphology | web of science | ||||||||||
Biochemical Characterization of Cassiopea andromeda (Forsskål, 1775), Another Red Sea Jellyfish in the Western Mediterranean Sea | 2021 | De Rinaldis et al. | Palermo, Italy | paper | chemistry, antioxidant activity | andromeda | morphology | scholar google | ||||||||||
Effect of Cassiopea andromeda Venom on P15INK4b, P21 (WAF1/CIP1), P53, DNA methyltransferase 1, and Bcl-2 Genes Expression, Apoptosis Induction, and Cell Growth Inhibition in Acute Promyelocytic Leukemia NB4 Cell line | 2021 | Dehghani et al. | persian gulf | paper | Acute Leukemia, Apoptosis, Cassiopea venom, Epigenesis, Venom, medical | andromeda | morphology | web of science | ||||||||||
Benthic jellyfish dominate water mixing in mangrove ecosystems | 2021 | Durieux, Clos and Gemmell | Florida Keys | paper | fluid dynamics, flow, feeding | sp | morphology | Web of science | ||||||||||
Magnesium concentration influences size and pulse rate in the upside-down jellyfish Cassiopea andromeda | 2021 | Evans, Millar, Wolvin, Pham, LePage, Lumsden | Hagen Aqualab | paper | physiology, growth and pulsations | andromeda | morphology | web of science | ||||||||||
Different Physiology in the Jellyfish Cassiopea xamachana and C. frondosa in Florida Bay | 2021 | Fitt, Hofmann, Kemp and Ohdera | Florida Bay | paper | life cycle, development, zooxanthellae | xamachana and andromeda | morphology | web of science | ||||||||||
Rhizostomins: A Novel Pigment Family From Rhizostome Jellyfish (Cnidaria, Scyphozoa) | 2021 | Lawley, Carroll and McDougall | Sequences, NCBI | paper | blue mesogleal protein, molecular | xamachana | molecular | web of science | ||||||||||
High photosynthetic plasticity may reinforce invasiveness of upside-down zooxanthellate jellyfish in Mediterranean coastal waters | 2021 | Mammone, Ferrier-Pagés, Lavorano, Rizzo, Piranino, Rossi | lab-reared | paper | symbionts, photosynthesis, irradiance, PAR | sp | morphology | web of science | ||||||||||
Raising Awareness of the Severity of “Contactless Stings” by Cassiopea Jellyfish and Kin | 2021 | Muffett, Klompen, Collins, Ames | Caribbean, Florida, Hawaii, French Polynesia, Brazil, Panama, Ahu Dhabi and Israel | short communication | digital survey for “contactless sting” of different jellies, including Cassiopea | sp | morphology | web of science | ||||||||||
Holobiont nitrogen control and its potential for eutrophication resistance in an obligate photosymbiotic jellyfish | 2021 | Röthig, Puntin, Wong, Burian, McLeod and Baker | lab-reared | paper | nitrogen control, eutrophicantion, symbiont | xamachana | molecular | web of science | ||||||||||
The utility of jellyfish as marine biomonitors | 2021 | Templeman, McKenzie and Kignsford | Review | review | jellyfish as bioindicators | sp | review | web of science | ||||||||||
Non-indigenous upside-down jellyfish Cassiopea andromeda in shrimp farms (Brazil) | 2021 | The et al. | Brazil | paper | invasive species, cassiopea bloom, dna barcoding COI | andromeda | molecular | scholar google | ||||||||||
Phenotypic plasticity in Cassiopea ornata (Cnidaria: Scyphozoa: Rhizostomeae) suggests environmentally driven morphology | 2022 | Anthony, Heagy, Bentlage | Guam, Micronesia | paper | phenotypic plasticity, phylogenetics | ornata | Both | scholar google | ||||||||||
Assessing Magnesium Chloride as a Chemical for Immobilization of a Symbiotic Jellyfish (Cassiopea sp.) | 2022 | Arossa, Klein, Parry, Aranda and Duarte | Red Sea | paper | invertebrate, magnesium chloride, MgCl2, Cassiopea sp., cnidaria | sp | morphology | scholar google | ||||||||||
Under pressure: Cassiopea andromeda jellyfish exposed to increasing water temperature or lead, cadmium and anthropogenic gadolinium contamination | 2022 | Béziat and Kunzmann | Red Sea and Lab-reared | paper | temperature stress, bioconcentration, heavy metals, symbiodiniaceae, pollution | andromeda | morphology | scholar google | ||||||||||
Snapshot of the Distribution and Biology of Alien Jellyfish Cassiopea andromeda (Forsskål, 1775) in a Mediterranean Touristic Harbour | 2022 | Cillari et al. | Palermo, Italy | paper | non-indigenous species; upside-down jellyfish; Megabenthos Underwater Video; species distribution; stable isotopes; mixotrophic behavior | andromeda | morphology | scholar google | ||||||||||
Indoles can induce strobilation in aposymbiotic Cassiopea andromeda polyps but are associated with developmental abnormalities | 2022 | Deng, Wang, Wang, Zhao, Luo | lab-reared | paper | biochemistry, strobilation, symbiodinium | andromeda | morphology | scholar google | ||||||||||
Revealing hidden diversity among upside-down jellyfishes (Cnidaria: Scyphozoa: Rhizostomeae: Cassiopea): distinct evidence allows the change of status of a neglected variety and the description of a new species | 2022 | Gamero-Mora et al. | western pacific (Japan and Phillipines) | paper | Cassiopea, DNA barcoding, jellyfish, morphology, Pacific Ocean, phylogeny, species delimitation, taxonomy. | mayeri and culionensis | molecular | web of science, google scholar | ||||||||||
Cnidarian-Symbiodiniaceae symbiosis establishment is independent of photosynthesis | 2022 | Jinkerson et al. | Florida Keys | paper | infection, proliferation, and maintenance can proceed without photosynthesis during symbiosis establishment, but the ability to do so depends on specific host-symbiont pairs | xamachana | morphology | scholar google | ||||||||||
Scyphozoan jellyfish diversity and distribution along the north-eastern Arabian Sea, off Gujarat coast, India | 2022 | Kumawat et al. | Arabian Sea | paper | Gujarat coast, Jellyfish, North-eastern Arabian Sea, Scyphomedusae | andromeda | morphology | scholar google | ||||||||||
The mesoglea buffers the physico-chemical microenvironment of photosymbionts in the upside-down jellyfish Cassiopea sp. | 2022 | Lyndby et al. | lab-reared | pre-print | cnidaria, symbiosis, chlorophyll fluorescence, optical properties, NanoSIMS | sp | morphology | scholar google | ||||||||||
The Upside-Down Jellyfish Cassiopea xamachana as an Emerging Model System to Study Cnidarian–Algal Symbiosis | 2022 | Medina et al. | none | Book chapter | genomic, geography, lifecycle, model organism | xamachana | both | web of science | ||||||||||
Impacts of Light and Food Availability on Early Development of Cassiopea Medusae | 2022 | Muffett, KM ; Aulgur, J ; Miglietta, MP | Florida Keys | paper | Cassiopea, ephyra, zooxanthellae, medusa, development | sp | morphology | web of science | ||||||||||
Reproducible propagation technique for the symbiotic cnidarian model system Cassiopea xamachana | 2022 | Newkirk, Vadlapudi, Sadula, Arbello and Xiang | lab-reared | methods paper | Cassiopea, Cnidarian-algal, Jellyfish, Symbiosis | xamachana | morphology | scholar google | ||||||||||
Complete and rapid regeneration of fragments from the upside-down jellyfish Cassiopea | 2022 | Ostendarp, Plewka, Flathmann, Tilstra, El-Khaled and Wild | paper | Cassiopea sp., whole body regeneration, fragmentation, umbrella tissue, oral arms, survival, specific growth rate | sp | morphology | scholar google | |||||||||||
Evaluating the effectiveness of drones for quantifying invasive upside-down jellyfish (Cassiopea sp.) in Lake Macquarie, Australia | 2022 | Rowe et al. | Australia | paper | EPIBENTHIC JELLYFISH, MOLECULAR EVIDENCE, ABUNDANCE, SCYPHOZOA, RHIZOSTOMEAE, COMMUNITY, BLOOMS, AQABA, SIZE | sp | morphology | web of science | ||||||||||
Population dynamics of the invasive upside-down jellyfish Cassiopea in Lake Macquarie: identification, seasonality, and distribution. | 2022 | Rowe, C. | Australia | dissertation | Cassiopea, Lake Macquarie, invasive, taxonomy, population dynamics, jellyfish | maremetens and xamachana | molecular | scholar google | ||||||||||
Physiological responses of the upside-down jellyfish, Cassiopea (Cnidaria: Scyphozoa: Cassiopeidae) to temperature and implications for their range expansion along the east coast of Australia | 2022 | Rowe, Keable, Ahyong and Figueira | Australia | paper | InvasiveClimate changeBell diameterPulsation rateMetabolic rate | sp | morphology | scholar google | ||||||||||
Increased nutrient availability correlates with increased growth of the benthic jellyfish Cassiopea spp. | 2022 | Stoner, Archer and Layman | Abaco, Bahamas | paper | Anthropogenic nutrients Benthic Marine food webs | spp | morphology | scholar google | ||||||||||
Severe seawater acidification causes a significant reduction in pulse rate, bell diameter, and acute deterioration in feeding apparatus in the scyphozoan medusa Cassiopeia sp. | 2022 | Thayer et al. | lab-reared (Tennessee Aquarium) | paper | Ocean acidification, Cassiopea sp., medusa, climate change, Scyphozoa, pulse rate | sp | morphology | scholar google | ||||||||||
Specific antibacterial activity against potential pathogens and re- straining of larvae settlement from a pigmented Pseudoalteromonas strain isolated from the jellyfish Cassiopea xamachana | 2022 | Thomé and Rivera-Ortega | Xcaret Park, Cancun, Mexico | paper | Commensal bacteria . Larval settlement . Extracellular vesicles . Antimicrobial . Epibionts | xamachana | morphology | scholar google | ||||||||||
Invasive upside-down jellyfish tolerate organic eutrophication and warming | 2022 | Tilstra, Arjen; El-Khaled, Yusuf C; Meier, Saskia; Wild, Christian | lab-reared | paper | DOC, respiration, pumping rate, organic matter, eutrophication and warming | sp | morphology | scholar google | ||||||||||
Sleep is required for neural network plasticity in the jellyfish Cassiopea | 2023 | Abrams, Zhang, von Emster, Lee, Zeigler, Jain, Jafri, Chen and Harland | lab-reared | pre-print | sleep, plasticity, homeostasis | xamachana | molecular | scholar google | ||||||||||
Aerobic respiration, biochemical composition, and glycolytic responses to ultraviolet radiation in jellyfish Cassiopea sp | 2023 | Aljbour, Alves, Agusti | Red Sea | paper | jellyfish, Cassiopea sp., mitochondrial respiration, pyruvate kinase, lactate dehydrogenase, energy allocation, medusae, anaerobic respiration | sp | morphology | scholar google | ||||||||||
Flow fields generated by Cassiopea contractions: the effect of oral arms on feeding flows | 2023 | Connolly, Miller | none | thesis | fluid dynamics, mathematical model, flow field, bell pulsation, contraction | none | none | scholar google | ||||||||||
The Zooxanthellate Jellyfish Holobiont Cassiopea andromeda, a Source of Soluble Bioactive Compounds | 2023 | De Domenico et al. | La Cala, Palermo, Italy | paper | jellyfish extracts, symbiosis, symbiont, zooxanthellaw, Symbiodiniaceae, antioxidant activity, pigments, bioactive compounds | andromeda | molecular | scholar google | ||||||||||
The Effect of the Persian Gulf Jellyfish (Cassiopea andromeda) Venom on the Expression of P15, P21, P53, DNMT1, and Bcl-2 in Acute Lymphoblastic Leukemia Jurkat Cells | 2023 | Dehghani et al. | Persian Gulf | paper | Acute lymphoblastic leukemia; Apoptosis; medical | andromeda | morphology | scholar google | ||||||||||
Benthic jellyfish act as suction pumps to facilitate release of interstitial porewater | 2023 | Durieux et al. | Florida Keys | short communication | Biogeochemistry, Behavioural ecology, Marine biology, Fluid dynamics | sp | morphology | scholar google | ||||||||||
Light intensity changes and UVB radiation affect peridinin content and antioxidant activity in the Cassiopea andromeda holobiont | 2023 | Kühnhold et al. | Aquarium Berlin, Leibniz Centre for Tropical Marine Research (ZMT), Bremen, Germany | paper | Light-harvesting pigments, carotenoids, endosymbiotic dinoflagellates, Symbiodiniaceae, up-side down jellyfish, ultraviolet radiation (UVR) LEDs, health-promoting ingredients, zooxanthellae. Symbiosis, new marine food | andromeda | molecular | scholar google | ||||||||||
Upside-down jellyfish as bioindicators of anthropogenic disturbances in coastal ecosystems | 2023 | López-Figueroa, N.B. | Jobos Bay, Puerto Rico | scientific report | bioindicator, field ecology, human impact | xamachana | both | scholar google | ||||||||||
Photobiology and metabolic interactions in the symbiotic jellyfish Cassiopea | 2023 | Lyndby | Aquarium, Marine Biology Section in Helsingør, University of Copenhagen, Denmark, collected from Cuba originally | dissertation | Cassiopea, photosynthesis, stable isotope labelling, nutrients, electron microscopy, NanoSIMS, symbiont | sp | morphology | scholar google | ||||||||||
The mesoglea buffers the physico-chemical microenvironment of photosymbionts in the upside-down jellyfish Cassiopea sp. | 2023 | Lyndby, Murray, Trampe, Meibom and Kühl | Aquarium, Marine Biology Section in Helsingør, University of Copenhagen, Denmark, collected from Cuba originally | paper | symbiosis, jellyfish, microenvironment, photosynthesis, respiration, light | sp | morphology | scholar google | ||||||||||
Photobiology and metabolic interactions in the symbiotic jellyfish Cassiopea | 2023 | Lyndby, Niclas Heidelberg | lab-reared | thesis | Cassiopea; photobiology; photosynthesis; metabolic interactions; metabolism; light microenvironment; physico-chemical microenvironment; NanoSIMS; microsensors | sp | morphology | scholar google | ||||||||||
Reproductive cycle and gonadal output of the Lessepsian jellyfish Cassiopea andromeda in NW Sicily (Central Mediterranean Sea) | 2023 | Mammone et al. | Palermo, Italy | paper | reproduction, gonads, histology, bloom | andromeda | morphology | scholar google | ||||||||||
The influence of photosymbiosis in Cassiopea xamachana regenerative success | 2023 | lab-reared | paper | Wound healing , Upside-down jellyfish · Cell proliferation, Regeneration, zooxanthellae, symbiosis, symbiont, Symbiodiniaceae | xamachana | molecular | scholar google | |||||||||||
Residual tissue magnesium concentration in jellyfish (Aurelia aurita and Cassiopea andromeda) following magnesium chloride euthanasia | 2023 | Millar et al. | University of Guelph Hagen Aqualab | paper | Aurelia aurita, Cassiopea andromeda, euthanasia, jellyfish, magnesium | andromeda | morphology | scholar google | ||||||||||
Characterization of the populations of upside-down jellyfish in Jardines de la Reina National Park, Cuba | 2023 | Morejón-Arrojo and Rdríguez-Viera | Gulf of Guacanayabo to Casilda Bay, Cuba | accepted version | Cassiopea spp, Caribbean, MPA, Density, Benthic habitat, ecology, field | andromeda, frondosa | morphology | scholar google | ||||||||||
Demystifying Cassiopea species identity in the Florida Keys: Cassiopea xamachana and Cassiopea andromeda coexist in shallow waters | 2023 | Muffet and Miglietta | Florida Keys | paper | halotypes, DNA, phylogenetics, mitochondria | xamachana, andromeda | both | scholar google | ||||||||||
Comparative Genomic Insights into Bacterial Induction of Larval Settlement and Metamorphosis in the Upside-Down Jellyfish Cassiopea | 2023 | Ohdera et al. | Key Largo, Florida | paper | Cassiopea, larval settlement, metamorphosis, Pseudoalteromonas | xamachana | molecular | scholar google | ||||||||||
Battle for the mounds: Niche competition between upside-down jellyfish and invasive seagrass | 2023 | Smulders, slikboer, christianen and vonk | Bonaire and Curaçao | scientific report | bioturbation, Cassiopea, colonization, competition, disturbance, exotic seagrass, habitat preference, Halophila stipulacea, landscape modification, patch dynamics | spp | morphology | web of science | ||||||||||
Gene Loss may have Shaped the Cnidarian and Bilaterian Hox and ParaHox Complement | 2023 | Steinworth, Martindale and Ryan | Florida Keys | paper | Hox, homeobox, cnidarian-bilaterian ancestor, Medusozoa, Cassiopea xamachana | xamachana | morphology | web of science | ||||||||||
Understanding Cassiopea andromeda (Scyphozoa) Invasiveness in Different Habitats: A Multiple Biomarker Comparison | 2023 | Thé, Mammone, et al. | Ceará State, Brazil; Acarú and Itarema | paper | biochemical tracers; lipids; carbohydrates; stable isotopes; non-indigenous species | andromeda | morphology | scholar google | ||||||||||
Host starvation and in hospite degradation of algal symbionts shape the heat stress response of the Cassiopea-Symbiodiniaceae symbiosis | 2023 | Toullec et al. | DeJong Marinelife, Netherlands | pre-print | Climate change, photosymbiosis, Cnidaria, Symbiodiniaceae, bleaching, metabolism, NanoSIMS. | andromeda | molecular | scholar google | ||||||||||
Symbiotic nutrient exchange enhances the longterm survival of cassiosomes, the autonomous stinging-cell structures of Cassiopea | 2023 | Toullec et al. | DeJong Marinelife, Netherlands | pre-print | upside-down jellyfish, symbiosis, metabolism, Rhizostomae, stable isotope labeling, cryo-SEM, NanoSIMS, cassiosomes, zooxanthellae, symbiont | andromeda | molecular | scholar google | ||||||||||
Chemical Compositions and Experimental and Computational Modeling of the Anticancer Effects of Cnidocyte Venoms of Jellyfish Cassiopea andromeda and Catostylus mosaicus on Human Adenocarcinoma A549 Cells | 2023 | Zare et al. | Persian Gulf | paper | jellyfish; apoptosis; venom; pulmonary adenocarcinoma; molecular docking | andromeda | molecular | scholar google | ||||||||||
Non-invasive investigation of themorphology and optical properties of theupside-down jellyfishCassiopeawithoptical coherence tomography | 2023 | Lyndby et al. | DeJong Marinelife, Netherlands | paper | Cnidaria, symbiosis, chlorophyll fluorescence, optical properties, NanoSIMS | sp. | morphology | scholar google |
Cassiopea species asexually reproduce as polyps through a process called budding, where evagination of tissue at the aboral region produces a motile planuloid bud. This bud swims to and settles on appropriate substrate, where it develops into a scyphistomae. To read more about this, visit our Cassiopea literature tab!
Through this process, it is possible to create “clonal” lines by isolating an aposymbiotic polyp and allowing it to bud continuously. By starting a culture with one polyp and keeping all produced buds genetically isolated, you can create a line of aposymbiotic polyps from a controlled genetic background.
Here we established polyp lines and labs who host them. They’ve agreed to list their contact information for anyone who has questions or requests for polyps. If you have questions about this list or would like to be listed as a point of contact, please Contact Us.
If you would like to request polyps from the Medina Lab, visit our Animal Request tab.
Cassiopea xamachana
Polyp Line ID | Research labs with line |
---|---|
T1A | Medina Lab Pennsylvania State University State College, PA, USA [email protected] DeGennaro Lab Florida International University Miami, FL, USA [email protected] www.degennarolab.org Baker Lab The University of Hong Kong Hong Kong, PRC [email protected] www.thelifeisotopic.com |
T1B | Medina Lab Pennsylvania State University State College, PA, USA [email protected] |
T1C | Medina Lab Pennsylvania State University State College, PA, USA [email protected] |
T1D | Medina Lab Pennsylvania State University State College, PA, USA [email protected] |
T1E | Medina Lab Pennsylvania State University State College, PA, USA [email protected] |
T1F | Medina Lab Pennsylvania State University State College, PA, USA [email protected] |
T2A | Medina Lab Pennsylvania State University State College, PA, USA [email protected] |
T2B | Medina Lab Pennsylvania State University State College, PA, USA [email protected] |
T2C | Medina Lab Pennsylvania State University State College, PA, USA [email protected] |
T2D | Medina Lab Pennsylvania State University State College, PA, USA [email protected] |
T2E | Medina Lab Pennsylvania State University State College, PA, USA [email protected] |
T2F | Medina Lab Pennsylvania State University State College, PA, USA [email protected] |
All labs listed have agreed to list their contact information for questions about and requests for polyps
G = Genome Line T = Transcriptomes Available
The Cassiopea genome browser (C. xamachana v2.0) is now live through the Joint Genome Institute Genome Portal:
The draft genome version 1.0 is available here.
Access the draft genome publication here. Citation:
Ohdera A, Ames CL, Dikow RB, Kayal E, Chiodin M, Busby B, La S, Pirro S, Collins AG, Medina M, Ryan JF. Box, stalked, and upside-down? Draft genomes from diverse jellyfish (Cnidaria, Acraspeda) lineages: Alatina alata (Cubozoa), Calvadosia cruxmelitensis (Staurozoa), and Cassiopea xamachana (Scyphozoa). GigaScience. 2019 Jul 1;8(7):giz069.