Fact-checked by Grok 2 weeks ago

Scyphozoa

Scyphozoa is a class of marine invertebrates within the phylum , commonly known as true , characterized by their dominant medusoid form featuring a bell-shaped body composed primarily of thick —a jelly-like substance that makes up about 97% —surrounded by a thin epidermis and gastrodermis, along with tentacles armed with stinging nematocysts for prey capture. These organisms exhibit radial symmetry and lack organs such as a , eyes, or , with body sizes ranging from a few millimeters to over 2 meters in diameter, and some species like Cyanea capillata possessing tentacles up to 36.5 meters long. Taxonomically, Scyphozoa encompasses three orders—Coronatae, , and —comprising approximately 20 families, 60 genera, and about 200 species, with the free-swimming medusae predominant. They are distributed worldwide in all oceans, from tropical to polar regions, predominantly in shallow coastal (neritic) waters but extending to depths of up to 4,600 meters in some species, and are exclusively marine with no freshwater representatives. The of scyphozoans typically alternates between a sessile stage (scyphistoma), which is small and tentacled, and a free-swimming stage, involving larval , ephyra (juvenile ), and adult phases, with occurring both sexually via eggs and sperm and asexually through budding or strobilation. Some species, such as those in , feature fused oral arms instead of marginal tentacles, and certain taxa like harbor symbiotic algae for nutrition. Ecologically, scyphozoans are carnivorous predators that feed on , fish eggs, and small using their nematocysts, serving as prey for larger marine animals like and sea turtles, while their periodic blooms—such as those observed in the Mediterranean during the —can disrupt fisheries, tourism, and ecosystems by clogging nets and reducing biodiversity. Notable species include the common moon jelly often seen in coastal waters.

Taxonomy and phylogeny

Classification

Scyphozoa is a class within the phylum and subphylum , encompassing true jellyfishes characterized by a dominant stage in their . The class is divided into three extant orders: Coronatae (crown jellyfishes), (semaphore jellyfishes), and (rhizostome jellyfishes), which together comprise approximately 24 families, 71 genera, and over 220 recognized species worldwide. Estimates suggest the total diversity could reach up to 400 species when accounting for undescribed taxa, particularly in understudied deep-sea and tropical regions. Taxonomic classification within Scyphozoa relies on a combination of morphological traits and molecular data. Key criteria include the structure of the medusa, such as the arrangement of tentacles, oral arms, and the presence or absence of a velum, alongside polyp morphology where applicable. Molecular phylogenetics, utilizing markers like 18S rRNA and mitochondrial genes (e.g., COI and 16S), has refined these distinctions by resolving cryptic species and clarifying ordinal relationships. Prominent families include , which contains the moon jellyfish genus Aurelia known for its cosmopolitan distribution, and Rhizostomatidae, featuring the barrel jellyfish with fused oral arms. Other notable families are Cyaneidae (e.g., genus Cyanea) in and Atorellidae in Coronatae, often deep-sea dwellers. Recent integrative taxonomy studies have expanded the known diversity. For instance, a 2024 analysis combining morphological examination and phylogenetic sequencing identified Cyanea altafissura sp. nov., a new semaeostome species from the Gulf of Guinea, distinguished by unique lappet morphology and genetic divergence from congeners. Similarly, in 2025, Aurelia profunda was described from the Gulf of Mexico based on medusa and ephyra traits, highlighting cryptic speciation within Ulmaridae through COI barcoding. Additionally, in May 2025, Phyllorhiza yurena sp. nov. was described from the East China Sea, a new rhizostome distinguished by its morphological traits and genetic markers. Post-2020 revisions have incorporated (eDNA) metabarcoding to uncover hidden . A 2025 study in the Xisha Islands of the used eDNA to detect Scyphozoa among 188 operational taxonomic units of Scyphozoa, , and , revealing distribution patterns for underrepresented orders like Coronatae and confirming the presence of undescribed rhizostomes in ecosystems. These advances underscore the role of genomic tools in updating Scyphozoa amid ongoing discoveries.

Evolutionary history

The fossil record of Scyphozoa is sparse due to their soft-bodied nature, but scyphozoan-like medusoids appear in the early , with Burgessomedusa phasmiformis from the middle Cambrian representing the oldest unequivocal macroscopic free-swimming medusa, dated to approximately 508 million years ago. Earlier fossils, such as microscopic medusozoans with radial symmetry from the Fortunian stage, suggest precursors to scyphozoan forms, including biradial and hexaradial structures reported in 2018 studies from . By the , medusoid fossils become more diverse, with impressions in marginal marine dolostones indicating semaeostome or rhizostome-like scyphozoans. The extinct order , often classified within Scyphozoa, spans from the terminal to the and is considered a possible ancestral group due to its fourfold symmetry and phosphatic exoskeleton homologous to scyphozoan structures, with the oldest known specimen, Paraconularia ediacara, from Brazilian strata around 541 million years ago. Phylogenetically, Scyphozoa occupies a position within the phylum as part of the monophyletic clade, which diverged from early in cnidarian evolution during the . Within , Scyphozoa forms a clade with and Cubozoa that is sister to , as supported by phylogenomic analyses of nuclear and mitochondrial genes across 29 cnidarian species, showing strong bootstrap support (100%) for this topology. Molecular evidence from mitogenomes further confirms the divergence of Scyphozoa from and Cubozoa, with Scyphozoa and Cubozoa sharing a closer relationship within the non- medusozoans, based on comparisons of 266 complete cnidarian mitochondrial genomes. Comparative genetics in Aurelia species highlights how geological barriers, such as the historical closure of the precursor, shaped pre-anthropogenic divergences, with Mediterranean and populations showing distinct lineages predating human influences. Key evolutionary adaptations in Scyphozoa include the dominance of the stage over the , a reversal from the -dominant life cycle in , enabling greater dispersal in planktonic environments through the development of a gelatinous bell. Pulsation of the bell margin, driven by epithelial striated muscles, evolved as the primary mechanism, allowing rhythmic contractions for propulsion and vertical migration, as evidenced by biomechanical studies of fossil and extant forms. Nematocysts, the stinging cells characteristic of , underwent specialization in Scyphozoa for predation, with diverse types in tentacles and bell margins facilitating capture of , building on ancestral cnidarian designs from the . The transition from to via strobilation represents a pivotal , involving hormonal and transverse to produce ephyrae, which enhanced reproductive output and ecological success in marine habitats. Recent genetic insights reveal anthropogenic influences on Scyphozoa evolution, particularly Lessepsian migrations through the since , which have facilitated invasions but not always ; for instance, genomic analyses of Aurelia show that populations are more closely related to Pacific lineages than to Mediterranean ones, indicating no recent inter-sea migration and instead highlighting ongoing evolutionary isolation. This 2021 study, using whole-genome sequencing of multiple scyphozoan , underscores how human-altered pathways interact with ancient geological barriers to drive contemporary diversification.

Morphology

Body structure

Scyphozoans display a dimorphic consisting of the and stages, both characterized by radial and diploblastic tissue organization with an outer and inner gastrodermis separated by . The , the dominant stage in Coronatae, , and , is typically free-floating and features an umbrella-shaped bell that propels the animal through pulsations, with the convex exumbrella surface facing upward and the concave subumbrella forming the interior cavity. In contrast, exhibit a sessile medusoid form, goblet- or trumpet-shaped, attached to substrates by a basal or stalk, with a (reduced umbrella) bearing eight short arms tipped with clusters of tentacles, lacking a propulsive bell. The stage, in contrast, is a sessile, tubular form attached to substrates, resembling a hydroid with a basal disk for , a cylindrical column, and an oral crown of tentacles. This overall structure lacks hard skeletal elements or complex organs, relying instead on hydrostatic mechanisms for support and movement. A prominent feature of scyphozoan is the , a gelatinous matrix containing scattered amoeboid cells, composed primarily of water, mucopolysaccharides, and salts, which accounts for about 95% of the medusa's wet mass and enables without rigid support. The bell includes four to eight oral arms extending from the central manubrium, which houses the mouth leading to a gastrovascular cavity divided into four radial canals and gastric pockets lined with gastric filaments for nutrient absorption. Cnidocytes containing nematocysts are embedded in the of tentacles, oral arms, and bell margins, serving as defensive and capture mechanisms through harpoon-like discharge. In the , the gastrovascular cavity is simpler, with nematocysts concentrated around the oral tentacles for passive prey entrapment. Structural variations occur across scyphozoan orders, reflecting adaptations to diverse habitats. In the Coronatae, the bell features a deep coronal groove resembling a that divides the subumbrella into chambers, aiding in controlled descent in deep waters. The Rhizostomeae, conversely, lack marginal , compensating with highly branched oral arms that bear numerous secondary mouths and nematocyst batteries for enhanced feeding efficiency. , the most diverse order, typically possess prominent marginal and a simple bell structure. are small (typically under 10 cm tall), with a stalk-like for attachment to hard substrates in cold, shallow waters, a flattened or invaginated with eight arms each ending in clusters, and a simpler gastrovascular system. Scyphozoan size varies widely, from small medusae measuring a few centimeters in diameter, such as those in the order , to giants like Cyanea capillata, which can reach a bell of over 2 meters and tentacles extending up to 40 meters. stages are generally smaller, ranging from millimeters to a few centimeters in height, adapted for benthic attachment.

Sensory and nervous system

The nervous system of scyphozoans is characterized by a diffuse distributed throughout the bell, tentacles, and oral arms, lacking a centralized or distinct . This consists of interconnected neurons that facilitate basic coordination and signal propagation across the body, with two primary nets often distinguished: a motor nerve net associated with musculature for contraction and a net for environmental input. In medusae, coordination is enhanced by rhopalial ganglia located in the sensory structures called rhopalia, which integrate signals and relay them via the nerve nets without direct interconnections between rhopalia. Sensory structures in scyphozoans are primarily concentrated in the rhopalia positioned around the bell margin (or calyx in Stauromedusae), serving as multifunctional organs for environmental perception, with numbers typically in multiples of four (4-16). Each rhopalium typically includes statocysts containing statoliths for detecting gravity and orientation, ocelli for light detection, and mechanoreceptors such as ciliated cells and touch plates for sensing water movement and pressure. In some taxa, like rhizostomes, rhopalia feature marginal clubs with additional chemoreceptors for detecting dissolved substances, while mechanoreceptors and potential chemosensors are also dispersed across the body surface via the diffuse nerve net. These sensory and neural components enable reflexive behaviors essential for survival, such as the rhythmic pulsation of the bell controlled by pacemaker regions within the motor nerve net, which generate coordinated contractions for propulsion at rates typically around 1-2 pulses per second in species like Aurelia aurita. Phototaxis is mediated by ocelli, with Aurelia exhibiting negative phototaxis by orienting away from light sources to avoid surface waters during daylight, while statocysts and mechanoreceptors facilitate rheotaxis, allowing countercurrent swimming against flows to maintain position in blooms. Such responses are strictly reflexive, lacking evidence of complex learning or memory, and rely on direct sensory-motor linkages without higher processing.

Life cycle

Reproduction

Scyphozoa exhibit both and , with the stage primarily responsible for sexual processes and the stage for asexual propagation. is gonochoristic, featuring separate male and female individuals, where gonads develop from the endodermal tissue of the bell or along mesenteries in the gastric cavity. In males, spermatocysts produce , while females develop oocytes in ovaries; gametes are released into the water through the . Fertilization is typically external but can be internal in some species, with females often ingesting and brooding on their oral arms before release. This process results in larvae, which settle to form . Asexual reproduction occurs mainly in the polyp (scyphistoma) stage and enables population persistence and expansion. Polyps reproduce by , producing genetically identical clones through mechanisms such as direct budding, stolonal budding, or podocyst formation, where resistant cysts form under adverse conditions to survive stress. , a form of transverse , follows, in which the polyp segments into a stack of discs (strobila) that detach as free-swimming ephyrae, the juvenile . For example, in Aurelia spp., strobilation yields multiple ephyrae per polyp, amplifying medusa production. Environmental factors, particularly temperature and photoperiod, regulate reproductive timing. Sexual spawning in medusae is often triggered by rising temperatures and seasonal photoperiod changes, with temperate species like exhibiting peaks in spring and summer when water warms above 15–20°C. Asexual strobilation in polyps, conversely, is induced by cooling temperatures (e.g., a drop to 14°C in Aurelia coerulea) combined with short photoperiods mimicking winter-spring transitions, optimizing ephyra release for favorable growth conditions. Food availability also modulates budding rates, with nutrient scarcity favoring podocyst production over active . Hermaphroditism is rare in Scyphozoa, with most taxa maintaining strict ; however, has been observed in some , where individuals can switch sexes during their .

In most Scyphozoa, the involves a complex metagenetic characterized by between a sexually reproducing phase and an asexually reproducing phase, with the typically dominating in terms of biomass and ecological impact. However, in the order , the develops directly into a sessile stauromedusa without a free-living stage, and some holopelagic species like Periphylla periphylla also show direct development from to juvenile . This cycle begins post-fertilization with the development of a free-swimming, ciliated from the . The , measuring approximately 0.2–1 mm in length, swims actively using cilia for several days to weeks before settling on a suitable , such as rocks or bivalve shells, where it undergoes into the sessile scyphistoma . and initial typically occur within 4 days to 2 weeks, completing in about 3 days at temperatures of 20–22°C, marking the transition from pelagic to benthic life. The scyphistoma , a cylindrical, tentaculate form attached by its aboral end, grows through , producing clones that can form colonies under favorable conditions. This stage persists for months to years, depending on environmental factors, during which the polyp feeds on and accumulates . Under specific cues, such as decreasing temperatures (e.g., 12–18°C in temperate ) or changes in photoperiod and , the polyp undergoes strobilation, transforming into a strobila—a segmented, stacked-disc where transverse constrictions form multiple ephyrae precursors. Strobilation is a key metamorphic process triggered by these abiotic signals, enabling rapid population expansion through . Each ephyra, a small (about 0.3–1 diameter), star-shaped juvenile , is released from the strobila and swims freely using ciliary motion and early pulsations of its developing bell. Over weeks to months, the ephyra into an adult through ontogenetic changes, including bell expansion, development of a continuous margin, elongation of tentacles and oral arms, and refinement of the rhopalial structures for sensory and functions. In species like Aurelia sp.1, ephyrae reach juvenile medusa size in approximately 10 days post-release, achieving in 2–6 months at around 18°C, though rates vary with , availability, and species—faster in warmer waters (e.g., 20–26°C for tropical forms like ). This progression emphasizes the medusa's role as the dispersive, reproductive phase, completing the cycle upon release.

Distribution and habitat

Global distribution

Scyphozoa exhibit a across all marine environments worldwide, inhabiting oceans from tropical to polar regions. The class is particularly diverse in the , recognized as a hotspot for scyphozoan , where numerous thrive in coastal and open-water habitats. In polar areas, such as Cyanea capillata dominate in the , extending into waters of the northern Atlantic and Pacific, while in the , deep-water forms like gigantea occur in coastal and shelf regions. Tropical and subtropical waters, including the , support blooms of such as Rhopilema nomadica, which has become prominent in the eastern basin. Most scyphozoan species are primarily epipelagic, occupying the upper 200 meters of the where they form the dominant component of communities. However, certain taxa like the are benthic, attaching to substrates such as and rocks in coastal zones rather than drifting pelagically. Recent (eDNA) metabarcoding studies have uncovered previously undetected diversity in remote areas, such as the Xisha Islands in the , highlighting hidden biogeographic patterns in coral reef-associated scyphozoans. Patterns of endemism and invasions shape scyphozoan distributions, with many species native to specific basins but expanding ranges through human-mediated vectors. For instance, the rhizostome Rhopilema nomadica was introduced to the via the as a Lessepsian migrant, establishing populations in the eastern . Genetic analyses confirm its origins and rapid colonization following canal transit. Range expansions are often facilitated by shipping, which transports polyps or ephyrae in ballast water, enabling species like Phyllorhiza punctata to invade new coastal regions from the to the Atlantic. Representative examples illustrate regional biogeography: in coastal Asia, rhizostome species such as Nemopilema nomurai and Rhopilema esculentum are abundant along the East China Sea and Yellow Sea shelves, supporting commercial fisheries. In the temperate Atlantic, semaeostome taxa like Aurelia aurita and Chrysaora hysoscella prevail in shelf waters from the Bay of Biscay to the North Sea, influencing local plankton dynamics.

Environmental tolerances

Scyphozoans exhibit broad environmental tolerances that enable them to inhabit diverse marine environments, primarily as eurythermal organisms capable of surviving temperatures from approximately 5°C to 30°C across their life stages. Polyps and medusae of species like Aurelia aurita thrive within 15–25°C, with growth rates peaking in this range, while extreme lows or highs can induce or stress responses such as formation in polyps. A 2025 study on Sanderia malayensis ephyrae demonstrated optimal survival and growth at 20–25°C, where feeding efficiency and bell diameter expansion were maximized compared to lower temperatures around 15°C. Rising temperatures due to are shifting , advancing strobilation and favoring bloom formation in temperate regions by aligning reproductive cycles with warmer conditions. Salinity tolerances in Scyphozoa are generally confined to conditions of 25–35 practical units (psu), reflecting their osmoconforming where internal fluids approximate concentrations. Some species, such as Catostylus tagi, extend into brackish waters, with planulae surviving 15–25 psu and polyps developing faster at higher salinities within this range. occurs via mesogleal cells in the matrix, which facilitate through specialized channels to maintain cellular integrity under fluctuating salinities. The 2025 S. malayensis investigation revealed interactive effects of (20–35 psu) and temperature, where ephyrae survival dropped below 20 psu at 24°C but remained high at 30 psu across 20–25°C, underscoring combined impacts on feeding and growth. Beyond temperature and , scyphozoans display notable tolerance attributable to their low metabolic rates and intragel oxygen reserves in the , allowing medusae like Aurelia sp.1 to endure prolonged low-oxygen conditions without significant physiological disruption. Polyps further enhance resilience through under hypoxic stress, sustaining populations in oxygen-depleted benthic zones. Regarding , scyphozoans show varying sensitivity to acidification from elevated CO₂, with medusae often more vulnerable than polyps under projected conditions (pH ~7.5). Experimental data from recent studies indicate that while individual tolerances support wide distributions, synergistic stressors like warming and low can elevate mortality and reduce feeding rates by up to 50% in ephyrae.

Ecology

Feeding and predation

Scyphozoan jellyfish are primarily planktivorous predators, consuming such as , copepod nauplii, rotifers, and fish eggs, as well as occasional microplankton like when larger prey is scarce. These species exhibit non-selective feeding, capturing prey in proportions roughly matching environmental availability, though some positive selection occurs for items like and fish eggs during peak seasons. In dense blooms, cannibalistic interactions can arise, particularly among ephyrae or smaller individuals, where polyps or early medusae consume conspecific planulae or juveniles. Prey capture relies on tentacles and oral arms equipped with nematocysts, specialized stinging cells that discharge upon tactile contact to immobilize victims. Bell pulsations generate feeding currents and vortices that draw plankton toward the subumbrella, increasing encounter rates with tentacles near the bell margin, where most captures occur during the contraction phase. Paralyzed prey is then transported by contracting tentacles or oral arms to the gastric cavity, where gastric filaments secrete enzymes for extracellular digestion, breaking down tissues into absorbable nutrients. Daily ingestion rates vary with prey density and temperature; for example, in Aurelia coerulea polyps, carbon-specific rates average 0.13 μg C μg C⁻¹ d⁻¹ but can reach 0.43 μg C μg C⁻¹ d⁻¹ in warmer conditions with abundant zooplankton, equivalent to substantial biomass turnover in small individuals. In medusae like Stomolophus meleagris, rations range from 20 to 100 mg C medusa⁻¹ day⁻¹, depending on size and prey type. Scyphozoans occupy a mid-level carnivorous trophic position (typically TL 2.5–2.8), channeling energy from primary and secondary consumers to higher predators while exerting top-down control on communities. They serve as key prey for marine vertebrates, including leatherback sea turtles (Dermochelys coriacea), (Mola mola), and various fishes, which consume them opportunistically during blooms. To counter predation, scyphozoans employ rapid, strong bell contractions for , enabling escape swims that differ in intensity from routine pulsing. Additionally, they contribute to nutrient cycling by excreting and dissolved rich in , , and carbon, which stimulates bacterioplankton growth and regenerates inorganic nutrients for primary producers.

Symbiotic relationships

Scyphozoa, the true jellyfishes, harbor diverse microbial communities on their surfaces and within their tissues, forming symbiotic associations that influence host and . Bacterial microbiomes associated with scyphozoan medusae exhibit lower diversity compared to surrounding and show specialization across taxa, life stages, and body regions such as the mucus layer and gastric cavity. These communities, dominated by groups like (e.g., ) and (e.g., Rhodobacteraceae), may facilitate digestion, nutrient provision, and defense through antimicrobial compounds. A 2025 study on blooms of Rhopilema nomadica in the revealed temporal shifts in microbial composition during bloom progression, with distinct patterns in oral arms, bells, and surrounding ; these shifts correlated with environmental changes like temperature and nutrient levels, suggesting dynamic symbiotic responses to bloom dynamics. Commensal relationships are common in Scyphozoa, where various utilize as mobile habitats without apparent harm to . Juvenile fishes, comprising over 95% of symbiotic associates in species like Stomolophus meleagris, shelter within the bell or oral arms for protection from predators while feeding on prey captured by the jellyfish. Invertebrates such as hyperiid amphipods also form commensal bonds; for instance, Themisto australis clings to the subumbrella of Cyanea capillata, using the jellyfish for transport and refuge while reproducing in the sheltered environment. These associations enhance the survival and reproductive success of the commensals in the open ocean. Parasitic interactions significantly impact scyphozoan , particularly . Helminths, including digenean trematodes and cestodes, infect medusae as , with high indicating their integration into parasite life cycles. Protozoans, such as parasitic dinoflagellates and , also target Scyphozoa, often residing in reproductive tissues. In Aurelia species, parasitism by metazoans like nematodes and protozoans reduces oocyte production, gonad size, and overall , leading to smaller bell diameters and altered patterns that compromise . Mutualistic symbioses in Scyphozoa are rare but notable in certain taxa, involving photosynthetic algae that provide nutritional benefits. In upside-down jellyfishes like Cassiopea spp., endosymbiotic dinoflagellates (Symbiodinium) engage in nutrient exchange, transferring photosynthetically fixed organic carbon to the host while receiving inorganic nutrients in return, which fuels host metabolism and supports anabolic processes. This symbiosis can supply up to 70% of the host's energy needs and enhances resilience during environmental stress, such as nutrient limitation or temperature fluctuations, by improving long-term survival of autonomous stinging structures like cassiosomes.

Human significance

Commercial exploitation

Scyphozoa, particularly species in the order such as Nemopilema nomurai, are commercially harvested for human consumption in , where they are processed into jellyfish salad and other delicacies after salting and drying. leads global production, with annual harvests reaching approximately 200,000 tons as of 2024, primarily from coastal waters like the and Bohai Bay. Beyond food, collagen extracted from Scyphozoa species is utilized in and pharmaceuticals for its and regenerative properties, serving as a base for wound dressings and anti-aging products. In traditional East Asian , particularly Chinese practices, dried preparations are employed for their purported cooling and detoxifying effects, treating conditions like and digestive issues. Aquaculture efforts focus on culturing Scyphozoa polyps to produce medusae for food, bait in fisheries, or research purposes, with techniques involving controlled strobilation in tanks to generate ephyrae. However, challenges persist due to the unpredictability of natural blooms, which complicates scaling production and synchronizing with market demands. Jellyfish harvesting has intensified since the 1990s, driven by overfishing of finfish stocks that reduced competition and increased jellyfish abundance, prompting fisheries to shift toward this alternative resource.

Ecological and economic impacts

Scyphozoan jellyfish blooms are driven by multiple anthropogenic factors, including from nutrient runoff, that reduces competition from fish predators, and climate change-induced warming that favors jellyfish reproduction and survival. These blooms exhibit high unpredictability due to complex interactions among environmental stressors and intrinsic , complicating forecasting efforts. In regions like , blooms of nine scyphozoan species pose significant threats to marine by damaging fish cages and to coastal through beach closures and swimmer deterrents. Ecologically, jellyfish blooms deplete prey populations by voraciously consuming zooplankton, fish larvae, and small fish, which disrupts food webs and reduces recruitment for commercially important species. Decomposing jellyfish carcasses exacerbate oxygen depletion in bottom waters, contributing to hypoxic dead zones that further harm benthic biodiversity and fish assemblages. In invaded areas like the , blooms of have induced biodiversity shifts by altering communities and facilitating regime changes in the ecosystem, often following and introductions. Economically, jellyfish blooms inflict substantial costs on fisheries by clogging nets and reducing catches; for instance, in the Northern Adriatic, losses from diminished yields exceed €8 million annually for fleets. Power plant operations face disruptions from intake blockages, as seen in where blooms have halted cooling systems. Health risks from stings add further burdens, with severe envenomations causing medical treatments and economic losses, such as Australia's 2002 Irukandji outbreak costing millions in healthcare and productivity. Management strategies include monitoring via (eDNA) to detect early bloom signals with high sensitivity, enabling proactive responses in coastal zones. Mitigation efforts employ physical barriers, such as fine-mesh nets around sites and power plant intakes, to reduce ingress and minimize operational downtime.

References

  1. [1]
    [PDF] The Classification and Distribution of the Class Scyphozoa
    Scyphozoa, or jellyfish, are a class of Cnidaria with a single sac-like body space, found in all oceans and seas, and are one of four classes of Cnidaria.
  2. [2]
    PHYLUM CNIDARIA: CLASS SCYPHOZOA
    Scyphozoa are jellyfishes, found in all oceans, with radial symmetry, tentacles, and a body wall of epidermis, mesoglea, and gastrodermis.
  3. [3]
    Purcell 2004 Scyphozoa | Request PDF - ResearchGate
    Evolution and systematics The class Scyphozoa includes four orders, 20 families, 66 genera, and about 200 species. The four orders are Stau-romedusae, the ...Missing: count | Show results with:count
  4. [4]
    (PDF) Scyphozoa - Academia.edu
    According to recent classification, a total of 186 species of scyphozoa belonging to 3 orders, 18 families and 61 genera were recorded from the world oceans.Missing: count | Show results with:count
  5. [5]
    [PDF] Multigene phylogeny of the scyphozoan jellyfish family Pelagiidae ...
    Oct 13, 2017 · A mitogenomic analysis recently challenged the placement of the order Coronatae, such as Periphylla, within Scyphozoa (Kayal et al., 2013; but ...
  6. [6]
    Scyphozoa - an overview | ScienceDirect Topics
    Three out of five families within the order Coronatae are exclusively deep-sea species. Periphylla periphylla, for example, lacks not only benthic life ...
  7. [7]
    (PDF) Integrative taxonomy reveals the presence of a new species ...
    Sep 13, 2024 · A new species of Cyanea is described from trawl samples collected in the Gulf of Guinea during 2017 and 2019. The species is a member of the ...
  8. [8]
    Aurelia profunda (Cnidaria: Scyphozoa): a new species from the ...
    Aug 1, 2025 · We describe a new species of Aurelia (Cnidaria, Scyphozoa) collected from offshore Gulf of Mexico. Two adult specimens, including one carrying ...
  9. [9]
    Scyphozoa, Hydrozoa, and Ctenophora biodiversity and distribution ...
    Apr 25, 2025 · Here, the biodiversity and spatial distribution patterns of jellyfish and their benthic relatives, from the Scyphozoa, Hydrozoa, and Ctenophora ...
  10. [10]
    Morphological and Phylogenetic Analysis of a New Jellyfish of ...
    May 29, 2025 · The study highlights the importance of combining life history observations with molecular tools for accurate jellyfish taxonomy and provides a ...
  11. [11]
    A macroscopic free-swimming medusa from the middle Cambrian ...
    Aug 2, 2023 · Here we describe Burgessomedusa phasmiformis gen. et sp. nov., the oldest unequivocal macroscopic free-swimming medusa in the fossil record.
  12. [12]
    [PDF] AN INTERMEDIATE TYPE OF MEDUSA FROM THE EARLY ... - HAL
    Coeval microscopic fossil medusozoans with biradial, hexardial or even octaradial symmetry have been also reported (Xian et al. 2018). These assumed fossil ...
  13. [13]
    [PDF] The fossil record of cnidarian medusae - Ancient Shore
    Most are likely semaeostome or rhizostome scyphozoans (Tarhan, 2008). Numerous medusae occur in Upper Ordovician marginal marine dolostones at William Lake, ...
  14. [14]
    A New Conulariid (Cnidaria, Scyphozoa) From the Terminal ...
    Jun 7, 2022 · This is the first Ediacaran body fossil showing compelling evidence of homology with a particular conulariid genus. However, unlike the periderm ...
  15. [15]
    Van Iten - ScienceDirect.com
    The fossil record of conulariids (Cnidaria, Scyphozoa) extends downward into the topmost part of the Ediacaran System, but the first appearance of diverse, ...
  16. [16]
    Phylogenomic Analyses Support Traditional Relationships within ...
    Cnidaria comprises two groups, Anthozoa and Medusozoa (Fig 2a). These clades are widely recovered in phylogenetic analyses of molecular data [5–7] (but see [8]) ...
  17. [17]
    Mitochondrial genome comparison reveals the evolution of cnidarians
    Jun 13, 2023 · Here, we collected 266 complete cnidarian mitochondrial genomes and re-evaluated the phylogenetic relationships between the major lineages.3 Results · 3.3 Mitogenome-Based... · 4 Discussion
  18. [18]
    Comparative genetics of scyphozoan species reveals the geological ...
    It is probably the most displayed Scyphozoa in aquaria. Although this genus is well studied, its taxonomic status remains unclear due to its high morphological ...<|control11|><|separator|>
  19. [19]
    Evolution and development of scyphozoan jellyfish - PubMed
    Feb 14, 2018 · Scyphozoan jellyfish have a complex life cycle with larval, polyp, and medusa stages. Metamorphosis from polyp to medusa is called strobilation ...
  20. [20]
    Muscle systems and motility of early animals highlighted by ... - eLife
    Jan 31, 2022 · In medusae, locomotion is achieved by the rhythmic pulsation of circular sheets of epithelial striated muscles located around the bell margins ...<|separator|>
  21. [21]
    Ontogenetic transitions, biomechanical trade-offs and ... - Nature
    Jun 16, 2023 · Inertial forces (Re > 100) become increasingly dominant, and the medusae begin to generate more complex flows through pulsation. Although in ...
  22. [22]
    Comparative genetics of scyphozoan species reveals the geological ...
    Jul 8, 2021 · Using genomics of the Aurelia species, we examined contemporary anthropogenic impacts with a focus on migration of scyphozoa across the Suez ...
  23. [23]
    A Functional Biology of Scyphozoa
    **Summary of Scyphozoa Body Structure and Anatomy (Arai, 1997)**
  24. [24]
    Jellyfish and Comb Jellies | Smithsonian Ocean
    The familiar body plan that looks like an upside down bell with tentacles hanging down from the inside is called the medusa. The polyp, the other cnidarian body ...Missing: orders | Show results with:orders
  25. [25]
    Do jellyfish have central nervous systems?
    Apr 15, 2011 · Scyphozoans lack any nerve-like interconnections between rhopalia, so inter-rhopalial coordination occurs via the nerve nets. Fig. 5. Fig. 5.
  26. [26]
    Development of the rhopalial nervous system in Aurelia sp.1 ...
    Another conducting system, called the diffuse nerve net (DNN), includes all non-rhopalial sensory cells and their thin neuronal processes, and this nerve net ...
  27. [27]
    What's on the mind of a jellyfish? A review of behavioural ...
    They contain what appear to be light receptors (ocelli) and gravity sensors (statocysts). Chemosensors and mechanoreceptors are spread over most of the medusa's ...Missing: organs | Show results with:organs
  28. [28]
    Current-Oriented Swimming by Jellyfish and Its Role in Bloom ...
    Feb 2, 2015 · Our results show that jellyfish can actively swim countercurrent in response to current drift, leading to significant life-history benefits.
  29. [29]
    Reproductive and environmental traits explain the variation in egg ...
    The smallest eggs occur in Staurozoa (18–72 µm), intermediate in Cubozoa and Hydrozoa, and some of the largest in Scyphozoa (figure 1). A higher number of eggs ...
  30. [30]
    Environmental control of asexual reproduction and somatic growth ...
    A reduction of water temperature is known to trigger upregulation of one or more secreted proteins, which act as strobilation inducers in A. aurita polyps [36].
  31. [31]
    Reproductive cycle and gonadal output of the Lessepsian jellyfish ...
    Feb 14, 2023 · A combination of traits, like high fecundity, rapid sexual maturation, high reproductive output, and asexual reproduction and hermaphroditism ...Introduction · Results · Oogenesis And...
  32. [32]
    Neuromuscular development in the emerging scyphozoan model ...
    Jan 11, 2024 · Due to their shape and position, these neurons likely have sensory functions, as has been described from other cnidarian planulae (Martin and ...Missing: rheotaxis | Show results with:rheotaxis
  33. [33]
    Life Cycle Reversal in Aurelia sp.1 (Cnidaria, Scyphozoa) | PLOS One
    In this study, development patterns of Aurelia sp.1 were followed, and life cycle reversal processes of both juvenile and sexually mature medusae were recorded, ...
  34. [34]
    Ontogenetic transitions, biomechanical trade-offs and ...
    Jun 16, 2023 · Ephyrae, the early stages of scyphozoan jellyfish, possess a conserved morphology among species. However, ontogenetic transitions lead to ...
  35. [35]
    Assessment of scyphozoan diversity, distribution and blooms
    To date, scyphozoan species have been harvested in many Southeast Asian countries including Malaysia since the early 1900s for human consumption due to their ...
  36. [36]
    [PDF] Two sympatric species of Cyanea (Scyphozoa) from Arctic seas ...
    Cyanea, a genus of majestic bloom-forming scyphozoans which is widely distributed around the world, from the temperate to boreal and polar waters, and ...Missing: Antarctic | Show results with:Antarctic
  37. [37]
    Personal submersibles offer novel ecological research access to ...
    Jan 30, 2023 · We describe direct observations of the rarely encountered scyphozoan Stygiomedusa gigantea at water depths of 80–280 m in Antarctic Peninsula coastal waters.
  38. [38]
    [PDF] The invasive tropical scyphozoan Rhopilema nomadica Galil, 1990 ...
    Dec 20, 2013 · Outbreaks have been restricted thus far to the southeastern Mediterranean. Kideys and Güccü. (1995) associated these “blooms” with high.
  39. [39]
    [PDF] Biogeography of jellyfish in the North Atlantic, by traditional and ...
    Jul 15, 2015 · The jel- lynet was used to collect jellyfish in the epipelagic layer (0–. 200 m) across the whole North Atlantic Basin, during three main EURO- ...
  40. [40]
    Backdating first records of non-indigenous species in the ...
    Aug 22, 2025 · This work lists 75 cases of backdated non-indigenous species (NIS) first records in the Mediterranean Sea which constitute 7.6% of the total ...
  41. [41]
    First record and potential trophic impact of Phyllorhiza punctata ...
    In fact, shipping traffic is thought to be a primary vector for marine invasions worldwide (Bolton & Graham Citation2004). Indeed, the life history of P.
  42. [42]
    Review Jellyfish blooms in China: Dominant species, causes and ...
    We report on the distribution and increasing incidence of jellyfish blooms and their consequences in Chinese coastal seas and analyze their relationship to ...
  43. [43]
    A blooming jellyfish in the northeast Atlantic and Mediterranean
    Apr 7, 2010 · Pelagia noctiluca is a warm-temperate holoplanktonic scyphozoan and it is distributed widely from coastal to oceanic waters as far north as ...
  44. [44]
    Chrysaora | Sea Nettle, Pacific & Atlantic | Britannica
    Oct 29, 2025 · Chrysaora, genus of marine jellyfish of the class Scyphozoa (phylum Cnidaria) that is found in all temperate and tropical seas around the world.
  45. [45]
    Ecological effect of temperature on Aurelia aurita life cycle
    ... temperature range of 2.5–27.5 ° C and grow normally at temperatures between 15–25 ° C (Duan et al., 2022). Throughout the whole life cycle of A. aurita ...
  46. [46]
    https://www.tandfonline.com/doi/full/10.1080/11250003.2014.981306
  47. [47]
    Phenology of scyphozoan jellyfish in eutrophication & climate change
    The final observation is registered with SST of 11.6–26.2 °C at sizes of 15–34.2 cm (Fig. 7ef). All three jellyfish species show high plasticity, being detected ...
  48. [48]
    Environmental control of asexual reproduction and somatic growth ...
    Jun 14, 2017 · strobilation occurs after polyps are exposed to a prolonged drop in temperature. A reduction of water temperature is known to trigger ...
  49. [49]
    Catostylus tagi (Class: Scyphozoa, Order: Discomedusae, Suborder
    The results showed a high tolerance of planulae to a wide range of salinities (15‰ to 25‰), while polyp development was significantly faster at higher ...
  50. [50]
    Mesogleal cells of the jellyfish Aurelia aurita are involved ... - PubMed
    The extracellular matrix of the jellyfish Aurelia aurita (Scyphozoa, Cnidaria), known as the mesoglea, is populated by numerous mesogleal cells (Mc).
  51. [51]
    Intragel oxygen promotes hypoxia tolerance of scyphomedusae
    Gel oxygen is depleted after about 2 h in anoxia and recovers to 70% of normal after 2.5 h in normoxia. Behaviour experiments in the laboratory showed that ...
  52. [52]
    Environmental evidence that seasonal hypoxia enhances survival ...
    In a second set of experiments, survival of scyphistomae decreased only marginally under prolonged (56 days) hypoxic conditions. Numerical growth due to asexual ...
  53. [53]
    Ocean acidification causes mortality in the medusa stage of the ...
    Apr 4, 2019 · Our results show increased in mortality of C. xaymacana under 2300 ocean acidification projections (i.e. pH of 7.51). This study represents the ...
  54. [54]
    Diets and Seasonal Ingestion Rates of Aurelia coerulea (Cnidaria
    Sep 22, 2021 · Previous studies have shown that scyphozoan polyps consume a wide variety of prey, including copepods, copepod nauplii, rotifers, planula larvae ...
  55. [55]
    Seasonal variability of diet and trophic level of the gelatinous ...
    Aug 14, 2018 · This jellyfish species has been described as a non-selective predator, feeding on almost all types of zooplankton and ichthyoplankton. The ...
  56. [56]
    Asexual Reproduction and Strobilation of Sanderia malayensis ...
    Jan 21, 2021 · Temperature and food availability have been proposed as the most important environmental factors directly influencing the reproduction rate ...<|separator|>
  57. [57]
    Feeding mechanism of Pelagia noctiluca (Scyphozoa
    The oral arms are therefore involved in the: (1) transport of prey from the tentacle to the gastric cavity; (2) catching of motionless prey; (3) anchoring the ...
  58. [58]
    [PDF] Swimming and feeding by the scyphomedusa Chrysaora ...
    While most captures occurred near the bell margin, the location of capture relative to the bell margin was in- fluenced by the phase of the pulsation cycle ...
  59. [59]
    Diet, prey selection and daily ration of Stomolophus meleagris, a ...
    The daily ration was estimated to range from 20 to 100 mg C medusa−1, depending on size of the medusa. Bivalve veligers were selected over all other kinds of ...Missing: food consumption body
  60. [60]
    mtDNA assay reveals scyphozoan predation in the Irish Sea - PMC
    Nov 29, 2017 · Jellyfish predation in the Irish Sea is not novel: sunfish and leatherback turtles are known predators [11]. However, the relative biomass ...
  61. [61]
    The importance of jellyfish–microbe interactions for biogeochemical ...
    Apr 7, 2021 · 2018). Jellyfish mucus and excreta are composed of dissolved organic nitrogen (DON), dissolved free amino acids (AAs) and dissolved organic ...
  62. [62]
    Production of dissolved organic matter and inorganic nutrients by ...
    These gelatinous zooplankton blooms can influence carbon (C) and nutrient cycling through excretion of dissolved organic matter (DOM), and inorganic nitrogen (N) ...Method · Results · Discussion<|control11|><|separator|>
  63. [63]
    Jellyfish-Associated Microbiome in the Marine Environment - MDPI
    These bacteria are known for commensalism, symbiosis, and parasitism, or are even pathogens of marine organisms. ... The WoRMS recognizes 69 genera of Scyphozoa ...
  64. [64]
    Jellyfish blooms through the microbial lens: temporal changes, cross ...
    May 9, 2025 · Our findings reveal complex relationships between jellyfish species, bloom progression, their microbial communities, and the surrounding seawater.
  65. [65]
    Floating nurseries? Scyphozoan jellyfish, their food and their ... - PeerJ
    Jun 19, 2018 · Floating nurseries? Scyphozoan jellyfish, their food and their rich symbiotic fauna in a tropical estuary. Research Article.
  66. [66]
    Commensal associations between the hyperiid amphipod, themisto ...
    Jan 22, 2009 · Commensal associations between the hyperiid amphipod, themisto australis,and the scyphozoan jellyfish, Cyanea capillata. R.H. Condon ...
  67. [67]
    (PDF) Scyphozoan jellyfish provide short-term reproductive habitat ...
    Scyphozoan jellyfish provide short-term reproductive habitat for hyperiid amphipods in a temperate near-shore environment. September 2014; Marine Ecology ...
  68. [68]
    The unpredictability of scyphozoan jellyfish blooms - Frontiers
    In this review, we focus on the current state of knowledge, uncertainties and gaps in the critical points that can strongly influence the intensity of the ...Missing: revisions | Show results with:revisions
  69. [69]
    [PDF] Symbionts of marine medusae and ctenophores
    The Diversity and Ecology of Animal Parasites. Cambridge. University Press, Cambridge, 566 pp. Cachon J, Cachon M (1987) Parasitic dinoflagellates. In: The Bi-.
  70. [70]
    Parasites alter behavior, reproductive output, and growth patterns of ...
    Aug 5, 2025 · Our results revealed that medusa behavior, morphology, and fecundity can be significantly affected by parasitism. Infected medusae were more ...Missing: protozoans | Show results with:protozoans
  71. [71]
    Symbiotic nutrient exchange enhances the long-term survival ... - NIH
    We show that organic carbon input from the dinoflagellates fuels the metabolism of the host tissue and enables anabolic nitrogen assimilation. This symbiotic ...
  72. [72]
    Life upside-down: review of ecological roles of Cassiopea (Cnidaria
    Aug 7, 2025 · This mucus serves as a significant source of nutrients for marine microorganisms, playing a crucial role in biogeochemical cycling within these ...1 Introduction · 2 Mixotrophy · 2.1 Autotrophy And...Missing: recycling | Show results with:recycling
  73. [73]
    Living Inside a Jellyfish: The Symbiosis Case Study of Host ...
    Mar 7, 2022 · In this study, we examine the algae distribution within the host body as well as, the pigment content and cell density of the symbiont.
  74. [74]
    The Natural Ecology and Stock Enhancement of the Edible Jellyfish ...
    The Chinese have commercially exploited the jellyfish along the coasts of China for over a thousand years, and the jellyfish industry has become a commercial ...
  75. [75]
    Stock enhancement of the edible jellyfish (Rhopilema esculentum ...
    Aug 6, 2025 · China has the largest jellyfish fishery yield in the world with an annual harvest of around 300 thousand tons. Liaodong Bay is the most ...
  76. [76]
    Jellyfish Collagen in the Mediterranean Spotlight - PubMed Central
    This review explores the properties of jellyfish-derived collagen, extraction techniques, and its diverse industrial applications based on the current ...
  77. [77]
    Mediterranean jellyfish as novel food: effects of thermal processing ...
    Mar 16, 2019 · Edible jellyfish harvesting and consumption is popular in China [2] ... Nemopilema nomurai, Stomolophus spp. particularly appreciated as ...
  78. [78]
    Are Jellyfish Taking Over The World? - MedCrave online
    Jun 22, 2015 · Fisheries worldwide are now producers of jellyfish, harvesting over 425,000 tonnes annually to satisfy the high Asian demand for this delicacy.
  79. [79]
    The effects of decomposing invasive jellyfish on biogeochemical ...
    Nov 14, 2020 · Jellyfish decomposition increases oxygen demand, acidification, and nutrient production, favoring heterotrophic microbes and potentially ...
  80. [80]
    Jellyfish blooms creating oceans of slime - BBC
    Apr 4, 2012 · In the last decade enormous plagues of jellyfish have been taking over the seas. And it is our fault.Missing: >100M/ | Show results with:>100M/<|separator|>
  81. [81]
    Full article: Jellyfish Impacts on Marine Aquaculture and Fisheries
    Sep 3, 2020 · Over the last 50 years there has been an increased frequency and severity of negative impacts affecting marine fishery and aquaculture sectors.
  82. [82]
    Epidemiology of jellyfish stings using the Sting Index to identify ...
    Oct 1, 2024 · In 2002, Queensland experienced a significant economic impact due to numerous Irukandji jellyfish stings, with the financial loss estimated at ...
  83. [83]
    eDNA tech tracks lethal jellyfish with CRISPR precision
    The method offers a powerful tool for early warning and preventive measures, enhancing beach safety protocols, and mitigating risks associated with jellyfish ...
  84. [84]
    Review Jellyfish mitigation for net-based fisheries - ScienceDirect.com
    Jellyfish blooms pose significant challenges to net-based fisheries, causing economic losses and operational difficulties. This study reviews existing ...Missing: power | Show results with:power