Jump to content

Cardiocephaloides longicollis

From Wikipedia, the free encyclopedia

This is an old revision of this page, as edited by CommonsDelinker (talk | contribs) at 03:08, 14 December 2016 (Removing "Life_cycle_of_Cardiocephaloides_longicollis.jpg", it has been deleted from Commons by Didym because: per c:Commons:Deletion requests/Files uploaded by ScienceGator.). The present address (URL) is a permanent link to this revision, which may differ significantly from the current revision.

Cardiocephaloides longicollis
Scientific classification
Kingdom:
Phylum:
Class:
Order:
Family:
Genus:
Species:

The life cycle of C.longicollis is asexual as well as complex. Its asexual stage resides in the body of whelks where it replicates many times, and eventually its eggs are dispersed in the water through feces. C.longicollis begin their early life as free swimming miracidia larvae in the water. They go on to infect snails (intermediate host), and a variety of fishes, usually second intermediate host, in the form of a cercariae. While C.longicollis has previously been recorded in 19 fish species, researchers have found 12 other species which are viable hosts for C.longicollis making for a grand total of 31 aquatic species. The final host for this parasite are the gulls that eat the infected fish in which the parasite has formed cysts in.

Life Cycle

The asexual life cycle of C. longicollis is complex which involves carnivorous scavenging whelks, a variety of fish, and gulls. The asexual stages of C. longicollis reside in the body of whelks where it replicates many times, producing a stream of swimming larvae call cercariae. The cercariae then go in the water to infect a variety of different fish. While C. longicollis has previously been recorded in 19 fish species, researchers have found 12 other species which are also viable hosts for C. longicollis, making for a grand total of 31 aquatic species. The final host for this parasite are gulls, when they eat the fluke that reside in parasitised fish. [1]


Host

The occurrence of C. longicollis was restricted to 3 species of Nassaridae, N. corniculum, N. reticulatus and N. neritea. Data demonstrate that C. longicollis has a much wider host spectrum in the second intermediate host, by recently adding 12 new host records: Diplodus sargus, D. dentex, Spicara maena, Spondyliosoma cantharus, Pagellus acarne, Pagellus erythrinus, Pagellus bogaraveo, Oblada melanura, Zosterisessor ophiocephalus, Coris julis, C. chromis, Serranus scriba. The Sparidae, Gobiidae and Labriidae are previously recorded host families and the Pomacentridae and Serranidae as new host families, resulting in a total of 31 fish host species from nine fish families.[2]

Transmission by Human Intervention

The parasite, C. longicollis, infections fish that hang around near the sea floor or near the coast, also in shallow lagoon which is significantly higher. This is probably because they are in close proximity to the whelks which are sources of infection. Fish that are around ≤14 cm in length are usually infected with the parasite. The fish in those size range have on average of 73 larvae in their brain. Interestingly, one fish has been recorded to have 220 parasites in its brain.

These larger fish live in deeper waters which are out of the gulls' reach, so regardless of their heavy larval fluke load, gulls can't get to them. Those parasites are at a dead end, where they are destined to die or end up in the stomach of another predator which is not a gull. Human intervention are the reason infection is reoccurring. As many as 31 species of fish can be infected with C. longicollis which are targeted by commercial fishing operations, or end up as by-catch. Many of those by-catch fishes are loaded with parasites and discarded at the port. This pile of of parasite-laden fish present opportunistic gulls with a rich and accessible feast. Thus contributing to the transmission. [3][4]


References

  1. ^ Leung, T. (2016, November 26). Cardiocephaloides longicollis. Retrieved November 1, 2016.
  2. ^ Born-Torrijos, A., Poulin, R., Perez-del-Olmo, A., Culurgioni, J., Raga, J. A., & Holzer, A. S. (2016, June 16). An optimised multi-host trematode life cycle: Fishery discards enhance trophic parasite transmission to scavenging birds. Nternational Journal for Parasitology, 46(745), 753rd ser., 1-9. Retrieved November 30, 2016, from http://www.otago.ac.nz/parasitegroup/PDF papers/Born-Torrijosetal2016-IJP.pdf
  3. ^ Prévot, G., Bartoli, P., 1980. Démonstration de l’existence d’un cycle marin chez les Strigeides: Cardiocephalus longicollis Szidat, 1928 (Trematoda: Strigeidae). Ann. Parasitol. Hum. Comp. 55, 407–425.
  4. ^ Born-Torrijos, A., Poulin, R., Perez-del-Olmo, A., Culurgioni, J., Raga, J. A., & Holzer, A. S. (2016, June 16). An optimised multi-host trematode life cycle: Fishery discards enhance trophic parasite transmission to scavenging birds. Nternational Journal for Parasitology, 46(745), 753rd ser., 1-9. Retrieved November 30, 2016, from http://www.otago.ac.nz/parasitegroup/PDF papers/Born-Torrijosetal2016-IJP.pdf
  1. Born-Torrijos, A., Poulin, R., Perez-del-Olmo, A., Culurgioni, J., Raga, J. A., & Holzer, A. S. (2016, June 16). An optimised multi-host trematode life cycle: Fishery discards enhance trophic parasite transmission to scavenging birds. Nternational Journal for Parasitology, 46(745), 753rd ser., 1-9. Retrieved November 30, 2016, from http://www.otago.ac.nz/parasitegroup/PDF papers/Born-Torrijosetal2016-IJP.pdf
  2. Prévot, G., Bartoli, P., 1980. Démonstration de l’existence d’un cycle marin chez les Strigeides: Cardiocephalus longicollis Szidat, 1928 (Trematoda: Strigeidae). Ann. Parasitol. Hum. Comp. 55, 407–425.
  3. Leung, T. (2016, November 26). Cardiocephaloides longicollis. Retrieved November 1, 2016.