Zschokkella

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Zschokkella
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Kingdom: Animalia
Phylum: Cnidaria
Class: Myxosporea
Order: Bivalvulida
Family: Myxidiidae
Genus: Zschokkella
Auerbach, 1909

Zschokkella are identified as parasitic organisms from the family Myxidiidae of the suborder Variisporina. [1] This genus of Myxozoa tend to inhabit common areas of their host and can be found around the globe in both marine to freshwater habitats. Zschokkella also have spore shapes and host specific parasitism that differentiates it from other Myxidiidae.

Contents

Genus description

Zschokkella have features that differentiate it from other genera in Variisporina. One is that the genus seems exclusive to only infecting the host at a family level. [2] It is suggested that due to their widespread nature, Zschokkella may parasitize on different host families based on the region or conditions they live in. Zschokkella are also able to alternate between their hosts given their morphologies. [3] They are identified by their striations and spore size which vary between species.

Zschokkella are coelozoic, meaning they inhabit a part or parts of another organisms body. [2] In this case, most Zschokkella inhabit parts of the excretory system in fish.

About 97 species of Zschokkella have been identified with a few species remaining unclassified. [4] [1]

Reproduction

Zschokkella reproduce via sporogenesis. They start their lives as sporoplasms, a group of protoplasts forming the spore, that is then injected into or on the host. From sporoplasms, Zschokkella develop into trophozoites as they feed on the host. [4] In this stage, they can develop to be either diasporic or polysporic. This means that, from the plasmodia, they are able to produce around 2-12 or more mature spores. [5] [6] [7] Spores are released into the waters and latch on to fish, eventually making their way through the excretory system of the host whilst parasitizing from them and developing into new mature spores.

Spore morphology

Between species of Zschokkella, there are differences in spore morphologies. [8]

Most spores in their earlier stages are described as ellipsoidal from the sutural viewpoint and semicircular from the valvular viewpoint. [4] Along the ends of the spores are a rounded edge. The valves of the shells are described as either smooth or having ridges, depending on the species. [4] The sutures along the spores can be either straight, sinuous, or curved. In the spores, there are commonly two polar capsules, one on each side of the spore, both in a spherical shape. [9] The sporoplasm which infects the host are binucleate: each cell or protoplast of the sporoplasm contains two nuclei. [4] At maturation, spores can become elongated, spherical, reniform or other shapes depending on species. [4] Other features such as spore size, the number of sutures on a spore, and the shape of the polar capsules also vary between species of Zschokkella.

Common areas of infection

Fish are the most common hosts for Zschokkella. The area infected is dependent on the species of Zschokkella parasitizing on the fish. Most species of Zschokkella live in the gallbladder of fish. [10] Some species live in the kidneys or renal tubules of fish while others live in the urinary tract and ureters of fish. [5] Researchers found this as they identified Zschokkella in the urine and bile of fish.

Related Research Articles

<span class="mw-page-title-main">Myxozoa</span> Group of marine parasites

Myxozoa is a subphylum of aquatic cnidarian animals – all obligate parasites. It contains the smallest animals ever known to have lived. Over 2,180 species have been described and some estimates have suggested at least 30,000 undiscovered species. Many have a two-host lifecycle, involving a fish and an annelid worm or a bryozoan. The average size of a myxosporean spore usually ranges from 10 μm to 20 μm, whereas that of a malacosporean spore can be up to 2 mm. Myxozoans can live in both freshwater and marine habitats.

<span class="mw-page-title-main">Myxosporea</span> Class of cnidarians comprising microscopic parasites

Myxosporea is a class of microscopic animals, all of whom are parasites. They belong to the Myxozoa clade within Cnidaria. They have a complex life cycle that comprises vegetative forms in two hosts—one an aquatic invertebrate and the other an ectothermic vertebrate, usually a fish. Each parasitized host releases a different type of spore. The two forms of spore are so different that until relatively recently they were treated as belonging to different classes within the Myxozoa.

The term polar filament may refer to either of two analogous structures used for host invasion by different groups of parasites: Myxozoa (Metazoa) and Microsporidia (Fungi), respectively.

Kudoa thyrsites is a myxosporean parasite of marine fishes. It has a worldwide distribution, and infects a wide range of host species. This parasite is responsible for causing economic losses to the fisheries sector, by causing post-mortem "myoliquefaction", a softening of the flesh to such an extent that the fish becomes unmarketable. It is not infective to humans.

Ellobiopsis is a genus of unicellular, ectoparasitic eukaryotes causing disease in crustaceans. This genus is widespread and has been found infecting copepods from both marine and freshwater ecosystems. parasitism has been seen to interfere with fertility in both sexes of copepods.

<i>Kudoa</i> Genus of marine parasites

Kudoa is a genus of Myxozoa and the only genus recognized within the monotypic family Kudoidae. There are approximately 100 species of Kudoa all of which parasitize on marine and estuarine fish. Kudoa are most commonly known and studied for the negative effects the genus has on commercial fishing and aquaculture industries.

Gadimyxa atlantica is a species of parasitic myxozoan. Together with G. arctica and G. sphaerica, they infect Gadus morhua and Arctogadus glacialis by developing coelozoically in bisporic plasmodia in their urinary systems. These 3 species' spores exhibit two morphological forms: wide and subspherical, being both types bilaterally symmetrical along the suture line. The wide spores have a mean width ranging from 7.5-10μm, respectively, while the subspherical ones range from 5.3-8μm in mean width. The subspherical forms of Gadimyxa are similar to Ortholinea, differing in the development of the spores and in the arrangement of the polar capsules. Polychaetes Spirorbisspecies act as invertebrate hosts of G. atlantica.

Gadimyxa sphaerica is a species of parasitic myxozoan. Together with G. arctica and G. atlantica, they infect Gadus morhua and Arctogadus glacialis by developing coelozoically in bisporic plasmodia in their urinary systems. These 3 species' spores exhibit two morphological forms: wide and subspherical, being both types bilaterally symmetrical along the suture line. The wide spores have a mean width ranging from 7.5 to 10μm, respectively, while the subspherical ones range from 5.3-8μm in mean width. The subspherical forms of Gadimyxa are similar to Ortholinea, differing in the development of the spores and in the arrangement of the polar capsules.

Gadimyxa arctica is a species of parasitic myxozoan. Together with G. atlantica and G. sphaerica, they infect Gadus morhua and Arctogadus glacialis by developing coelozoically in bisporic plasmodia in their urinary systems. These 3 species' spores exhibit two morphological forms: wide and subspherical, being both types bilaterally symmetrical along the suture line. The wide spores have a mean width ranging from 7.5-10μm, respectively, while the subspherical ones range from 5.3-8μm in mean width. The subspherical forms of Gadimyxa are similar to Ortholinea, differing in the development of the spores and in the arrangement of the polar capsules.

Ceratomyxa brayi is a species of myxosporean parasites that infect gall-bladders of serranid fishes from the Great Barrier Reef. It was first found on Cephalopholis boenak.

Ceratomyxa cutmorei is a myxosporean parasite that infects gall-bladders of serranid fishes from the Great Barrier Reef. It was first found on Epinephelus fasciatus.

Ceratomyxa gleesoni is a myxosporean parasite that infects gall-bladders of serranid fishes from the Great Barrier Reef. It was first found on Plectropomus leopardus.

Ceratomyxa hooperi is a myxosporean parasite that infects gall-bladders of serranid fishes from the Great Barrier Reef. It was first found on Epinephelus quoyanus.

Ceratomyxa nolani is a myxosporean parasite that infects gall-bladders of serranid fishes from the Great Barrier Reef. It was first found on Epinephelus quoyanus.

Ceratomyxa whippsi is a myxosporean parasite that infects gall-bladders of serranid fishes from the Great Barrier Reef. It was first found on Cephalopholis boenak.

Ceratomyxa yokoyamai is a myxosporean parasite that infects gall-bladders of serranid fishes from the Great Barrier Reef. It was first found on Epinephelus maculatus.

<i>Enteromyxum leei</i> Species of marine parasite

Enteromyxum leei is a species of myxozoan, histozoic parasite that infects the intestinal tract and sometimes associated organs, like gall bladder and liver, of several teleostean fish species. Myxozoans are microscopic metazoans, with an obligate parasitic life-style. The parasite stages of this species live in the paracelullar space between fish enterocytes. It is the causative agent of enteromyxosis, or emaciative disease, also known as "razor blade syndrome" in sparid fish. E. leei has a wide host and geographical range within marine fish, and even freshwater fish have been infected experimentally. E. leei initially emerged in the Mediterranean in the late 1980s and it is believed to have been unintentionally introduced into the Red Sea. Its pathogenicity and economic impact depend on the host species. In the gilt-head seabream, it is manifested as a chronic disease that provokes anorexia, delayed growth with weight loss, cachexia, reduced marketability and increased mortality. In other species, it has no clinical signs. In sharpsnout seabream, infection results in very high mortality rates, which have pushed fish farmers to abandon the culture of this fish species.

<i>Sphaerospora molnari</i> Species of marine parasite

Sphaerospora molnari is a microscopic endoparasite of carp in pond cultures and natural freshwater habitats in Central and Eastern Europe. In natural infections, S. molnari invades the epithelia of gills and surrounding skin regions. It then forms spores in between epithelial cells, causing sphaerosporosis, a pathological condition of the skin and gill tissues. Affected tissues show marked dystrophic changes and necrosis, causing secondary bacterial infections and resulting in osmoregulatory and respiratory failure. Mortalities can reach 100% but little is known about the overall distribution of the parasite species in European carp ponds or its economic impact on carp aquaculture.

<i>Thelohanellus kitauei</i> Parasite of carp

Thelohanellus kitauei is a myxozoan endoparasite identified as the agent of intestinal giant-cystic disease (IGCD) of common carp Cyprinus carpio. The species was first identified in Japan, in 1980 and later formally described by Egusa & Nakajima. Fan subsequently reported the parasite in China, and several other reports from carp and Koi carp in China and Korea followed. Reports referred to an intestinal infection, swelling and emaciation of fish due to blockage of the intestinal tract by giant cysts. The intestine of carp was believed to be the only infection site of T. kitauei until Zhai et al. reported large cysts of T. kitauei in the skin, with morphologically similar and molecularly identical spores. T. kitauei has been recognized as the most detrimental disease of farmed carp in Asia with around 20% of farmed carp killed annually. In 2014, the genome of T. kitauei was sequenced, and in 2016, its life cycle was found to include the oligochaete Branchiura sowerbyi. Infected oligochaete worms were first discovered in Hungary and raised concerns of the introduction of T. kitauei into European carp culture ponds, since it was believed to be endemic to Asia. However, the related disease (IGCD) has not yet been reported in Europe.

Ellipsomyxa is a genus of cnidarian that is part of the family Ceratomyxidae.

References

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