Kudoa thyrsites

Kudoa thyrsites is a myxosporean parasite of marine fishes . It has a worldwide distribution, and a wide range of host species. This parasite is responsible for causing economic losses to the fisheries sector, by causing post-mortem “myolefaction”, to become a marketable fish. It is not infective to humans.

Taxonomy

The spores of K. thyrsites are stellate in shape, with 4 valves and 4 polar capsules . Upon infection by the actinosporean stage the sporoplasm migrates to a fiber muscle where it forms a pseudocyst . These pseudocysts are the developing spore stages. Comparison of 18S rDNA sequences of Kudo species and other myxozoan species to determine their relationships. They show that Kudoa species are distinct from other analyzed myxozoans ( Myxidium sp., Myxobolus sp., And Henneguya zschokkei ) [1] .Kudoa thyrsites is an interesting member of this group, which is one of the most influential species in the world (Table 1).

Pathology

Members of the genus Kudoa Primarily infected muscle tissue of marine fishes, Where They form nodules or pseudocysts Containing a great number of individual spores. In lighter infections, these pseudocysts are isolated from the fish’s immune system within the muscle fiber. More intense infections can result in severe inflammation surrounding infected muscle fibers [2] . They are associated with post-mortem degeneration of the tissue. This enzyme is most likely a result of proteolytic enzymes by the parasite [3] . This causes losses to both aquacultureoperations, for instance, where salmon are being rearranged in “sea-pens”, and to capture fisheries . Losses are live both, through the degradation of fish products, and Indirectly, through the perception of the consumer That fish from a Particular area are of a lower quality. The intensity of K. thyrsites infection is positively correlated with the severity of flesh softening in Atlantic salmon fillets [4] . Softening of flesh has been reported, while lightly infected girls showed no softening. Prevention and / or control of K. thyrsitesinfections is problematic especially in open water netpens. Currently there are no available treatments. One approach to control may be the life cycle in some way minimizing the likelihood of infection.

Table 1. Distribution and species infected by Kudoa thyrsites
leasing Species Common name
North America Merluccius productus Pacific hake
Oncorhynchus spp. Pacific salmon
Icelinus filamentosus Threadfin sculpin
Ophiodon elongatus lingcod
Aulorhynchus flavidus Tube-snout
Salmo salar Atlantic Salmon
Reinhardtius stomias Arrowtooth Flounder
Eopsetta jordani Petrale sole
Hippoglossus stenolepis Pacific halibut
Microstomus pacificus Dover sole
Lepidopsetta bilineatus Rock sole
Platichthys stellatus Starry flounder
Parophrys vetula English sole
Theragra chalcogramma Alaskan pollock
Merluccius capensis Cape hake
australia Engraulis australis Australian anchovy
Engraulis japonicus Japanese anchovy
Sardinella lemuru Bali sardinella
Sardinops neopilchardus Australian pilchard
Spratelloides delicatulus Blue sprat
Coryphaena hippurus Mahi Mahi
South Africa Sardinops ocellatus South African pilchard
Thyrsites atun Snoek
chile Paralichthys adspersus Fine flounder
japan Cypselurus sp. Flying fish
ireland Salmo salar Atlantic Salmon
Clupea harengus Herring
Spain Salmo salar Atlantic Salmon
United Kingdom Scomber scomber mackerel
Salmo trutta Brown trout

Life cycle

The myxosporeans have been shown to have more complex life cycles than one host. Usually a fish and an oligochaete or polychaete worm, and in one case a bryozoan . The life cycle of K. thyrsites is poorly understood. It has been hypothesized that K. thyrsites has an indirect life cycle involving some marine invertebrate. Experiments have shown direct transmission of myxosporean marine Myxidium leei in sea ​​bream [5] . However, direct transmission of K. thyrsites failed when native fish were fed fresh myxospores [6] . If K. thyrsites does not have an indirect life cycle, the intermediate host has yet to be identified.

References

  1. ^ Hervio, DML, Kent, ML, Khattra, J., Sakanari, J., Yokoyama, H. Devlin, RH (1997). “Taxonomy of Kudoa species (Myxosporea), using a small-subunit ribosomal DNA”. Canadian Journal of Zoology . 75 (12): 2112-2119. doi: 10.1139 / z97-846 .
  2. ^ Kent, ML; TT Poppe (1988). “Diseases of netpen-reared salmonid fishes”. Pacific Biological Station, Nanaimo, BC. : 293pp.
  3. ^ Tsuyuki, H., Williscroft, SN, Kabata, Z., Whitaker, DJ (1982). “The relationship between acid and neutral protease and the incidence of soft tissue in the muscle tissue of Pacific hake ( Merluccius productus ) infected withKudoa paniformis and / or K. thyrsitis . Canadian Technical Report on Fisheries and Aquatic Sciences . 1130 : 39 pp.
  4. ^ St-Hilaire, S., Hill, M., Kent, ML, Whitaker, DJ, Ribble, C. (1997). “A comparative study of muscle texture and intensity of Kudoa thyrsites infection in farm-reared Salmon Atlantic Salmon Salmon on the Pacific Coast of Canada”. Diseases of Aquatic Organisms . 31 : 221-225. doi : 10.3354 / dao031221 .
  5. ^ Diamond, A. (1997). “Fish-to-fish transmission of a marine myxosporean”. Diseases of Aquatic Organisms . 30 : 99-105. doi : 10.3354 / dao030099 .
  6. ^ Moran, JDW, Whitaker, DJ, Kent, ML (1999). “Natural and laboratory transmission of the marine myxosporean parasite Kudoa thyrsites (Gilchrist, 1924) to Atlantic salmon ( Salmo salar )”. Journal of Aquatic Animal Health11 (2): 110-115. doi : 10.1577 / 1548-8667 (1999) 011 <0110: NALTOT> 2.0.CO; 2 . ISSN  1548-8667 .

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