Nomura's jellyfish

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Nomura's jellyfish
Nemopilema nomurai1.jpg
Nemopilema nomurai in the Kaiyūkan-aquarium of Ōsaka
Nomurajelly.svg
Size comparison of a Nomura's jellyfish next to a diver
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Cnidaria
Class: Scyphozoa
Order: Rhizostomeae
Family: Rhizostomatidae
Genus: Nemopilema
Kishinouye, 1922
Species:
N. nomurai
Binomial name
Nemopilema nomurai
(Kishinouye, 1922)
Synonyms
  • Stomolophus nomurai

Nomura's jellyfish (エチゼンクラゲ, echizen kurage, Nemopilema nomurai) is a very large rhizostome jellyfish, in the same size class as the lion's mane jellyfish, the largest cnidarian in the world. It is edible but not considered high quality. [1] It is the only species in the monotypic genus Nemopilema. Commonly found in the waters of East Asia, and can negatively effect fisheries due to their large size and quantity. As a form of combating the large blooms, recent studies attempt to find new uses for the large jellyfish such as studying its venom for medical applications.

Contents

Description

A Nomura jellyfish at Little Munsom Island, Jeju-do, South Korea Nomura jellyfish 2009 Korea a.jpg
A Nomura jellyfish at Little Munsom Island, Jeju-do, South Korea

Nemopilema nomurai can grow up to 2 m (6 ft 7 in) in diameter and weigh up to 200 kg (440 lb), the diameter when fully grown is slightly greater than the height of an average human. [2] The species was named in tribute to Mr. Kan'ichi Nomura (C18–C19), Director General of the Fukui Prefectural Fisheries Experimental Station, who in early December 1921 sent a specimen in a 72-litre (16 imp gal; 19 US gal) wooden tank to Professor Kishinouye, who found that it was unknown and dedicated time to study the living specimens. [3]

Nemopilema nomurai caught around Tsushima and the Iki Islands have a translucent whitish body, with pinkish or reddish capulets and oral arms, and transparent immature gonads. Jellyfish have two main types of muscle: epitheliomuscular cells and striated muscle cells. Researchers found that gene families that are closely associated with striated muscle were expressed in the bell portion of the jellyfish, providing evidence that striated muscle plays a significant role in jellyfish motility. [4]

Distribution

Nomura's jellyfish reside primarily in the waters between China and Japan, primarily centralized in the Yellow Sea and East China Sea. [5] Population blooms appeared to be increasing with frequency in the time period of 1989–2009. [6] Possible reasons for the population increase in Nomura's Jellyfish include climate change, overfishing, and coastal modification adding substrate for asexually producing polyps. [5]

Life cycle

The life cycle of Nemopilema nomurai is very similar to that of other rhizostomes. Nomura’s jellyfish are normally found in the Yellow Sea and populations are generally maintained there year round. During June and July, changes in the water salinity lead to the expatriation of larval stage jellyfish via the Tsushima strait. In 2005 the largest blooms were in late October. [5] It is noted that this species of jellyfish in six months can grow from the size of a grain of rice to greater than 6 ft (1.8 m) wide. [7]

Ecology

Example of a jellyfish bloom Water-jellyfish.jpg
Example of a jellyfish bloom

This species of jellyfish feeds mostly on zooplankton in all stages of life, feeding on larger fish as they grow larger. Their only predators consist of swordfish, tuna, sunfish, leatherback turtles, and humans. [7]

Jellyfish Blooms

While jellyfish blooms have been documented in the Sea of Japan since the writing of their first history book, the blooms of Nemopilema nomurai have been more recent. Since the beginning of the 20th century the instances of N. nomurai explosive blooms have been on the increase, a fact not helped by their size — being one of the largest species of jellyfish recorded. [5] The largest N. nomurai blooms have been documented between the years of 2002 - 2003, during the time in which these blooms took place it was observed that the fishing industry was affected negatively. [8] The effects of the blooms can be seen in an event that took place in 2009, when a 10 tonnes (11 tons) fishing trawler, the Diasan Shinsho-maru, capsized off Chiba on Tokyo Bay as its three-man crew tried to haul in a net containing dozens of Nomura's jellyfish; the three were rescued by another trawler. [9] [10]

Envenomations

Severe envenomations are becoming more common than ever. Victims of a sting from the N. Nomurai jellyfish may present symptoms of itching, swelling, acute pain, local erythrosis, and inflammation; in severe cases, the envenomations can cause death. [11] Recent research has also revealed that the myotoxicity caused by the presence of Nemopilema nomurai nematocyst venom (NnNV) in the body, which leads to Oedematogenic effects on the victims skin as well as resulting in the necrosis of the muscle tissue in some cases can be prohibited by metalloproteinase inhibitors such as Batimastat (BMT) and Ethylenediaminetetraacetic acid (EDTA). [12] [13] The nematocyst venom of the N. nomurai is composed of complex, toxic mixtures of proteins. Further research is in progress to determine the key factors within these protein mixtures, which could predict specific symptoms from the venom and aid in treatment. Using experimental omics-based approaches, research has revealed different sting related proteins and enzymatic components such as metalloproteinase and phospholipase A2s, as well as differences in hemolytic activity. [14] However, research has yet to provide a correlation between these components and symptoms of the envenomation.

Uses

Since the recent increase in blooms, research has been underway to find uses for Nomura’s jellyfish. Each year this species costs Japanese fisheries serious damage and so an economic solution may be found in converting this invasion into a resource. [5]

As food

The Japanese company Tango Jersey Dairy produces a vanilla and jellyfish ice cream using Nomura's jellyfish. [15] [16] Consuming Echizen Kurage is potentially dangerous if the toxic part is not thoroughly cleaned and cooked. [17]

Medical

One patent suggested the use of mucin of the Nomura’s jellyfish to treat joint diseases such as osteoarthritis, although clinical data are lacking. [18] Although more research in the field is required, in recent cancer related studies it has been shown that Nemopilema nomurai jellyfish venom (NnV) can inhibit Epithelial-mesenchymal transition (EMT) in HepG2 cells. [19] EMT aids in the early stages of metastasis, which is most commonly seen in cancer, and causes the cells to develop cancer like properties. [19] The study conducted showed that when cells with EMT were treated with NnV, it had a hindering effect on the EMT and the cancer like properties of the cells. [19]

Agriculture

Like many invasive species, such as the cane toad, a simple solution is to take the species and convert them into fertilizer. Another study aimed at using an aqueous methanol extract of dried medusa to inhibit the growth of weed seedlings when added to the soil. [20]

Related Research Articles

<span class="mw-page-title-main">Cnidaria</span> Aquatic animal phylum having cnydocytes

Cnidaria is a phylum under kingdom Animalia containing over 11,000 species of aquatic animals found both in fresh water and marine environments, including jellyfish, hydroids, sea anemones, corals and some of the smallest marine parasites. Their distinguishing features are a decentralized nervous system distributed throughout a gelatinous body and the presence of cnidocytes or cnidoblasts, specialized cells with ejectable flagella used mainly for envenomation and capturing prey. Their bodies consist of mesoglea, a non-living, jelly-like substance, sandwiched between two layers of epithelium that are mostly one cell thick. Cnidarians are also some of the only animals that can reproduce both sexually and asexually.

<span class="mw-page-title-main">Venom</span> Toxin secreted by an animal

Venom or zootoxin is a type of toxin produced by an animal that is actively delivered through a wound by means of a bite, sting, or similar action. The toxin is delivered through a specially evolved venom apparatus, such as fangs or a stinger, in a process called envenomation. Venom is often distinguished from poison, which is a toxin that is passively delivered by being ingested, inhaled, or absorbed through the skin, and toxungen, which is actively transferred to the external surface of another animal via a physical delivery mechanism.

<span class="mw-page-title-main">Jellyfish</span> Soft-bodied, aquatic invertebrates

Jellyfish, also known as sea jellies, are the medusa-phase of certain gelatinous members of the subphylum Medusozoa, which is a major part of the phylum Cnidaria.

<span class="mw-page-title-main">Scyphozoa</span> Class of marine cnidarians, true jellyfish

The Scyphozoa are an exclusively marine class of the phylum Cnidaria, referred to as the true jellyfish.

<span class="mw-page-title-main">Cnidocyte</span> Explosive cell containing one giant secretory organelle (cnida)

A cnidocyte is an explosive cell containing one large secretory organelle called a cnidocyst that can deliver a sting to other organisms. The presence of this cell defines the phylum Cnidaria. Cnidae are used to capture prey and as a defense against predators. A cnidocyte fires a structure that contains a toxin within the cnidocyst; this is responsible for the stings delivered by a cnidarian. Cnidocytes are single-use cells that need to be continuously replaced.

<span class="mw-page-title-main">Box jellyfish</span> Class of cnidarians distinguished by their cube-shaped medusae

Box jellyfish are cnidarian invertebrates distinguished by their box-like body. Some species of box jellyfish produce potent venom delivered by contact with their tentacles. Stings from some species, including Chironex fleckeri, Carukia barnesi, Malo kingi, and a few others, are extremely painful and often fatal to humans.

<span class="mw-page-title-main">Irukandji syndrome</span> Medical condition

Irukandji syndrome is a condition that results from envenomation by certain box jellyfish. In rare instances the sting may result in cardiac arrest and death. The most common jellyfish involved is the Carukia barnesi, a species of Irukandji jellyfish. Those stung may experience severe or even excruciating pain.

<i>Chironex fleckeri</i> Species of jellyfish

Chironex fleckeri, commonly known as the Australian box jelly, and nicknamed the sea wasp, is a species of extremely venomous box jellyfish found in coastal waters from northern Australia and New Guinea to Indonesia, Cambodia, Malaysia and Singapore, the Philippines and Vietnam. It has been described as "the most lethal jellyfish in the world", with at least 64 known deaths in Australia from 1884 to 2021.

<span class="mw-page-title-main">Irukandji jellyfish</span> Species of jellyfish

The Irukandji jellyfish are any of several similar, extremely venomous species of rare jellyfish. With a very small adult size of about a cubic centimetre, they are both the smallest and one of the most venomous jellyfish in the world. They inhabit the northern marine waters of Australia, and cost the Australian government $AUD 3 billion annually through medical costs associated with stings and tourism losses. This type of jellyfish reproduces sexually with eggs and sperm. They fire their stingers into their victim, causing a condition known in humans as Irukandji syndrome, which can be fatal and difficult to immediately recognise due to the delayed effects of the venom. There are about 16 known species of Irukandji, of which Carukia barnesi, Malo kingi, Malo maxima, Malo filipina and Malo bella are the best known.

<i>Carybdea</i> Genus of jellyfishes

Carybdea is a genus of venomous box jellyfish within the family Carybdeidae that currently consists of a total of 8 species. This genus of jellyfish are often found in warm waters around the world in waters such as the Mediterranean Sea, the Pacific Ocean, and off the coast of Africa. Their sting can cause a range of effects depending on the species. These invertebrates will go through both sexual and asexual reproduction as they transform from a polyp to medusa. Carybdea have a box-shaped bell with four tentacles and eye-like sensory structures. There are distinct physical markings that differentiate many species within the genus. While Carybdea use their venom to act as predators, they are also preyed on by turtles and various fish. They feed on plankton, invertebrates, fish, and some crustaceans.

<i>Malo</i> (jellyfish) Genus of jellyfishes

Malo is one of a genus of box jellies in the family Carybdeida in the Phylum Cnidaria. It has four known species, three of which were described by the Australian marine biologist Lisa-Ann Gershwin. The genus was discovered in 2005. Many of the species are known for their paralytic and deadly affect. Many species in the Malo genus are very small and hard to capture and study. Many species of Malo have been captured on the Western and Eastern cost of Australia. Malo appear to be solidarity jellies.

<i>Carukia barnesi</i> Species of jellyfish

Carukia barnesi is an extremely venomous jellyfish found near Australia. Stings can result in Irukandji syndrome, and this species is commonly known as Irukandji jellyfish, although this name does not distinguish it from other Irukandji jellyfish such as Malo kingi.

<span class="mw-page-title-main">Jellyfish dermatitis</span> Medical condition

Jellyfish dermatitis is a cutaneous condition caused by stings from a jellyfish.

<span class="mw-page-title-main">Jelly blubber</span> Species of jellyfish

Catostylus mosaicus is also known as the Jelly blubber or Blue blubber jellyfish. The jelly blubber is distinguishable by its color, which ranges from light blue to a dark blue or purple, and its large (250-300mm), rounded bell which pulses in a staccato rhythm. It occurs along the coastline of Eastern Australia in estuaries and shallow bays, and often blooms to high abundance.

<span class="mw-page-title-main">Jellyfish as food</span>

Some species of jellyfish are suitable for human consumption and are used as a source of food and as an ingredient in various dishes. Edible jellyfish is a seafood that is harvested and consumed in several East and Southeast Asian countries, and in some Asian countries it is considered to be a delicacy. Edible jellyfish is often processed into a dried product. Several types of foods and dishes may be prepared with edible jellyfish, including salads, sushi, noodles, and main courses. Various preparation methods exist.

<i>Chiropsoides</i> Genus of jellyfishes

Chiropsoides is a genus of box jellyfish in the family Chiropsalmidae. It is monotypic, with a single species, Chiropsoides buitendijki. The most distinct species characteristics are the shape of the gastric saccules, the pedalial canals, and the unilateral pedalial branching.

<i>Cyanea annaskala</i> Species of jellyfish

Cyanea annaskala is a species of jellyfish that was discovered in 1882 by Robert Lendlmayer von Lendenfeld.

<i>Aiptasia mutabilis</i> Species of sea anemone

Aiptasia mutabilis, also known as the Trumpet anemone, Rock anemone, and Glass anemone, is a species of anemone typically found attached to substrates in cold waters of the Atlantic Ocean. Its unique trumpet shape gives it its common name and it can grow to be 12 cm, having a column between 3 and 6 cm in size. Like many cnidarians, they rely on nematocysts for protection and to capture prey. They are not difficult to care for, and can be kept in a home aquarium, although due to their speed of reproduction, can quickly become overpopulated.

<i>Acromitus flagellatus</i> Species of cnidarian

Acromitus flagellatus is a species of jellyfish in the Catostylidae family, suborder Dactyliophorae. It was discovered in 1903 by Otto Maas in the Malay Archipelago, and is closely related to Nemopilema nomurai and Rhopilema esculentum Other species in the genus Acromitus include A. hardenbergi,A. maculosus,A. rabanchatu, and A. tankahkeei.A. flagellatus get their name from their long flagellum and their oral arms that are as about as long as the diameter of their bell, while other species in the genus, like A. hardenbergi, have oral arms that are about half the length of their bell.

References

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