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Schistocephalus solidus (Müller 1776) Steenstrup 1857

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Animal / parasite / ectoparasite
plerocercoid of Schistocephalus solidus ectoparasitises distended body cavity of Gasterosteus aculeatus

Animal / parasite / ectoparasite
adult of Schistocephalus solidus ectoparasitises gut of Laridae

Animal / parasite / ectoparasite
adult of Schistocephalus solidus ectoparasitises gut of Podiceps

Animal / parasite / ectoparasite
procercoid of Schistocephalus solidus ectoparasitises body cavity of Cyclops

Animal / parasite / ectoparasite
procercoid of Schistocephalus solidus ectoparasitises body cavity of Cyclops strenuus

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Basic biology of Schistocephalus solidus

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Schistocephalus solidus

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Schistocephalus solidus is a tapeworm of fish, fish-eating birds and rodents. This hermaphroditic parasite belongs to the Eucestoda subclass, of class Cestoda. This species has been used to demonstrate that cross-fertilization produces a higher infective success rate than self-fertilization.[2][3]

Life cycle

Life cycle of Schistocephalus solidus

It parasitizes fish and fish-eating water birds. The fish-eating water bird is the definitive host, and reproduction occurs in the bird's intestine. Eggs of the tapeworm are passed with the bird's feces and hatch in the water, where the first larval stage, the coracidium, is produced. The coracidium is then ingested by the first intermediate host, a cyclopoid copepod (e.g. Macrocyclops albidus). The second larval stage then subsequently develops in the tissue of this host. Within one to two weeks, the infected copepod is ingested by the second intermediate host, the three-spined stickleback, Gasterosteus aculeatus. The third larval stage, the plerocercoid, grows in the abdomen of the fish. When the fish is eaten by a bird, the larvae mature and adults start to produce eggs within two days. Reproduction takes place within one to two weeks, after which the parasite dies.[4]

Ecology

Prevalence — the proportion of host population infected — in naturally infected populations of the first intermediate hosts is likely low.[5] Conversely, in populations where Schistocephalus solidus infects the second intermediate host (three-spined stickleback) it can reach high prevalence, up to 93% in both European and North American populations [6][7]

The growth of S. solidus in the second intermediate host is largely dependent upon the environmental temperatures. At an increase of temperature from 15 °C to 20 °C the growth of S. solidus can grow four times as fast. At the same time, the growth rate of the stickleback is significantly reduced.[8]

Reproduction

Reproduction of S. solidus in the definitive bird host in which it resides for a maximum of two weeks.[4] Because adult worms are hermaphroditic eggs can be fertilised in three different ways; (1) self-fertilization (2) breeding with a sibling (3) breeding with an unrelated individual.[3] In most species outbreeding (mating with an unrelated individual) would be preferred,[9] but advantages and disadvantages of each of these breeding strategies have been argued.[10] In short, self-fertilization is advantageous when no mating partners are around, but might lead to inbreeding depression—the reduced fitness of offspring because of the unmasking of deleterious recessive alleles due to the breeding of closely related individuals. Similarly, breeding with a sibling, also known as incestuous mating, also shares some of the same disadvantages as self-fertilization does—inbreeding depression and lack of genetic variation. But incestuous mating is advantageous because it helps maintain gene complexes within the family which may be important for local adaptation. Breeding with unrelated individuals might seem to be most advantageous choice of mating because it increases genetic variation and avoids inbreeding depression, but it could be more time-consuming as partners might not always be available.[3]

In Schistocephalus solidus inbreeding is indeed disadvantageous, as mating between siblings generally produce a 3.5 times reduction in hatching success of the eggs produced from these matings compared to mating with unrelated individuals.[2][10] Outcrossing also increases the chances of infecting the second intermediate host.[11] However, there is also a preference to pair with larger mates, and to avoid very small mates.[12] The later means that self-fertilisation can also occur when potential partners are available. Under some circumstances, there could exist a significant advantage for incestuous mating, despite inbreeding depression.[13] In species where there is low parental investment and sexual encounters are rare and sequential, incestuous breeding is indirectly beneficial. If the prospective mates are related there is an increase mutual interest in finding a resolution with respect to playing the unpreferred sexual role. With less time allotted to conflicting over sexual roles and dominating one another, procreation is more cost-effective. Under these conditions, the greater effectiveness of inbreeding prevails over the detriment of incestuous mating and evolutionarily select for a preference for related mates.[13]

Infectivity

Corracidia are more infective to male copepods than to female copepods.[14] This has been suggested to be due to the negative impacts sex hormones such as testosterone can have on the immune system.

Viruses

Schistocephalus solidus itself a parasite, can also get infected by parasites (known as hyperparasites), including viruses.[15] These viruses are likely to affect the evolution of the virulence and broader interactions of S. solidus with its hosts.[15][16]

Host manipulation

The Schistocephalus solidus parasite is capable of host manipulation in both intermediate hosts, the copepod and the three-spined stickleback.

First intermediate host

In the copepod host, it is able to suppress activity while uninfective to the stickleback host.[17] This reduces the likelihood of the copepod host being consumed and consequently unsuccessful transmission of the parasite.[18] Once the parasite becomes infective, after approximately two weeks, activity increases[17] and, as a consequence, the risk of consumption by three-spined sticklebacks increases.[19] However, when multiple, non-simultaneous infections by S. solidus occur, host manipulation is orchestrated by the first infecting parasite. This increases the risk of premature consumption of the subsequent infections by the fish host.[20] Consistent differences in manipulation are seen between parasite genotypes [21] and populations.[22] Differences in host genotypes are maintained after infections, but less pronounced.[21]

Second intermediate host

In the fish host, host manipulation induces more risk taking behaviour like positive geotaxis[23] and negative thigmotaxis.[24] This change in behaviour is unlikely to be caused solely by the mechanical presence of the parasite. Phenotype modification, through injecting silicon "parasites", with densities and sizes similar to infective plerocercoids (~150 mg) did not alter behaviour.[24] Physiologically, S. solidus is a parasite that inhibits egg production in female three-spined sticklebacks in European populations,[6] but not in Alaskan populations where only egg mass is reduced.[7][25] The egg mass of fish was correlated to the parasite index, which indicates that the reduction in egg mass is a non-adaptive side effect of parasite infection.

Model species

Schistocephalus solidus is effectively used a model species for studying the evolutionary dynamics of host-parasite interactions.[26][27] More recently, it was proposed a model to study host-parasite-microbe interactions[28]

in vitro breeding

The option to breed S. solidus in the laboratory [29] makes them a useful model for studying host-parasite interactions.[26] For 'culturing' of the worm progenetic plerocercoids are dissected from the stickleback host. The worm can then be incubated in a dialysis tube embedded in culture medium and kept at 40 °C.[29] These worms are then ideally incubated in pairs of similar size to maximise outcrossing and egg hatching.[12] Optionally, large S. solidus worms can also be cut into smaller pieces and incubated separately.[30]

References

  1. ^ "Schistocephalus solidus". Global Biodiversity Information Facility.
  2. ^ a b Christen M; Kurtz J; Milinski M (2002). "Outcrossing increases infection success and competitive ability: experimental evidence from a hermaphrodite parasite". Evolution. 56 (11): 2243–51. doi:10.1554/0014-3820(2002)056[2243:oiisac]2.0.co;2. PMID 12487354. S2CID 20906916.
  3. ^ a b c Schjørring, Solveig (2004). "Delayed selfing in relation to the availability of a mating partner in the cestode Schistocephalus solidus". Evolution. 58 (11): 2591–2596. doi:10.1554/04-270. PMID 15612301. S2CID 198155264.
  4. ^ a b Dubinina, Mariia Nikolaevna (1980). Tapeworms (Cestoda, Ligulidae) of the fauna of the USSR.
  5. ^ Zander, C. D.; Groenewold, S.; Strohbach, U. (1994). "Parasite transfer from crustacean to fish hosts in the Lübeck Bight, SW Baltic Sea". Helgoländer Meeresuntersuchungen. 48 (1): 89–105. Bibcode:1994HM.....48...89Z. doi:10.1007/BF02366204.
  6. ^ a b McPhail, J. D.; Peacock, S. D. (1983). "Some effects of the Cestode (Schistocephalus solidus) on reproduction in the threespine stickleback (Gasterosteus aculeatus), evolutionary aspects of a host-parasite interaction". Canadian Journal of Zoology. 61 (4): 901–908. doi:10.1139/z83-118.
  7. ^ a b Heins, David C; Singer, Scarlet S; Baker, John A (1999). "Virulence of the cestode Schistocephalus solidus and reproduction in infected threespine stickleback, Gasterosteus aculeatus". Canadian Journal of Zoology. 77 (12): 1967–1974. doi:10.1139/z99-180.
  8. ^ Macnab, Vicki; Barber, Iain (2012). "Some (worms) like it hot: fish parasites grow faster in warmer water, and alter host thermal preferences". Global Change Biology. 18 (5): 1540–1548. Bibcode:2012GCBio..18.1540M. doi:10.1111/j.1365-2486.2011.02595.x. S2CID 86103632.
  9. ^ Galvani, Alison P.; Coleman, Ronald M.; Ferguson, Neil M. (2003). "The maintenance of sex in parasites". Proceedings of the Royal Society of London. Series B: Biological Sciences. 270 (1510): 19–28. doi:10.1098/rspb.2002.2182. PMC 1691212. PMID 12590767.
  10. ^ a b Schjørring, Solveig; Jäger, Ilonka (2007). "Incestuous mate preference by a simultaneous hermaphrodite with strong inbreeding depression". Evolution. 61 (2): 423–430. doi:10.1111/j.1558-5646.2007.00028.x. PMID 17348951. S2CID 2396487.
  11. ^ Christen, M.; Milinski, M. (2003). "The consequences of self-fertilization and outcrossing of the cestode Schistocephalus solidus in its second intermediate host". Parasitology. 126 (4): 369–378. doi:10.1017/s0031182003002956. PMID 12741516. S2CID 21430425.
  12. ^ a b Lüscher, A.; Wedekind, C. (2002). "Size-dependent discrimination of mating partners in the simultaneous hermaphroditic cestode Schistocephalus solidus". Behavioral Ecology. 13 (2): 254–259. doi:10.1093/beheco/13.2.254.
  13. ^ a b Kokko, Hanna; Ots, Indrek (2006). "When not to avoid inbreeding". Evolution. 60 (3): 467–475. doi:10.1111/j.0014-3820.2006.tb01128.x. PMID 16637492.
  14. ^ Wedekind, Claus; Jakobsen, Per J. (1998). "Male-Biased Susceptibility to Helminth Infection: An Experimental Test with a Copepod". Oikos. 81 (3): 458. doi:10.2307/3546767. JSTOR 3546767.
  15. ^ a b Hahn, Megan A.; Rosario, Karyna; Lucas, Pierrick; Dheilly, Nolwenn M. (2020). "Characterization of viruses in a tapeworm: phylogenetic position, vertical transmission, and transmission to the parasitized host". The ISME Journal. 14 (7): 1755–1767. doi:10.1038/s41396-020-0642-2. PMC 7305300. PMID 32286546.
  16. ^ Dheilly, Nolwenn M.; Poulin, Robert; Thomas, Frédéric (2015). "Biological warfare: Microorganisms as drivers of host–parasite interactions". Infection, Genetics and Evolution. 34: 251–259. doi:10.1016/j.meegid.2015.05.027. PMID 26026593.
  17. ^ a b Hammerschmidt, Katrin; Koch, Kamilla; Milinski, Manfred; Chubb, James C.; Parker, Geoff A. (2009). "When to go: optimization of host switching in parasites with complex life cycles". Evolution. 63 (8): 1976–1986. doi:10.1111/j.1558-5646.2009.00687.x. PMID 19453381.
  18. ^ Weinreich, F.; Benesh, D. P.; Milinski, M. (2012). "Suppression of predation on the intermediate host by two trophically-transmitted parasites when uninfective". Parasitology. 140 (1): 129–135. doi:10.1017/S0031182012001266. PMID 22906915. S2CID 25700997.
  19. ^ Wedekind, C.; Milinski, M. (2009). "Do three-spined sticklebacks avoid consuming copepods, the first intermediate host of Schistocephalus solidus? — an experimental analysis of behavioural resistance" (PDF). Parasitology. 112 (4): 371–383. doi:10.1017/S0031182000066609. S2CID 83852280.
  20. ^ Hafer, Nina; Milinski, Manfred (2015). "When parasites disagree: Evidence for parasite-induced sabotage of host manipulation". Evolution. 69 (3): 611–620. doi:10.1111/evo.12612. PMC 4409835. PMID 25643621.
  21. ^ a b Benesh, Daniel P. (2019). "Tapeworm manipulation of copepod behaviour: parasite genotype has a larger effect than host genotype". Biology Letters. 15 (9): 20190495. doi:10.1098/rsbl.2019.0495. PMC 6769145. PMID 31506036.
  22. ^ Hafer, Nina (2018). "Differences between populations in host manipulation by the tapeworm Schistocephalus solidus – is there local adaptation?". Parasitology. 145 (6): 762–769. doi:10.1017/S0031182017001792. PMID 29113596.
  23. ^ Barber, Iain; Svensson, P. Andreas; Walker, Peter (2004). "Behavioural Responses to Simulated Avian Predation in Female Three Spined Sticklebacks: The Effect of Experimental Schistocephalus Solidus Infections". Behaviour. 141 (11–12): 1425–1440. doi:10.1163/1568539042948231.
  24. ^ a b Grécias, Lucie; Valentin, Julie; Aubin-Horth, Nadia (2018). "Testing the parasite mass burden effect on alteration of host behaviour in the Schistocephalus-stickleback system". The Journal of Experimental Biology. 221 (6): jeb174748. doi:10.1242/jeb.174748. PMID 29444843.
  25. ^ Heins, David C.; Baker, John A. (2003). "Reduction of egg size in natural populations of threespine stickleback infected with a cestode macroparasite". Journal of Parasitology. 89 (1): 1–6. doi:10.1645/0022-3395(2003)089[0001:ROESIN]2.0.CO;2. PMID 12659295. S2CID 24098353.
  26. ^ a b Barber, Iain (2013). "Sticklebacks as model hosts in ecological and evolutionary parasitology". Trends in Parasitology. 29 (11): 556–566. doi:10.1016/j.pt.2013.09.004. PMID 24145060.
  27. ^ Barber, I.; Scharsack, J. P. (2010). "The three-spined stickleback- Schistocephalus solidus system: an experimental model for investigating host-parasite interactions in fish". Parasitology. 137 (3): 411–424. doi:10.1017/S0031182009991466. hdl:2381/8014. PMID 19835650. S2CID 8041954.
  28. ^ Hahn, Megan A.; Dheilly, Nolwenn M. (2016). "Experimental models to study the role of microbes in host-parasite interactions". Frontiers in Microbiology. 7: 1300. doi:10.3389/fmicb.2016.01300. PMC 4993751. PMID 27602023.
  29. ^ a b Smyth, J.D.; McManus, D.P. (1989). The Physiology and Biochemistry of Cestodes. Cambridge: Cambridge University Press. doi:10.1017/CBO9780511525841. ISBN 9780511525841.
  30. ^ Weinreich, Friederike; Kalbe, Martin; Benesh, Daniel P. (2014). "Making the in vitro breeding of Schistocephalus solidus more flexible". Experimental Parasitology. 139: 1–5. doi:10.1016/j.exppara.2014.02.002. hdl:11858/00-001M-0000-0019-7F35-C. PMID 24560832.
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Schistocephalus solidus: Brief Summary

provided by wikipedia EN

Schistocephalus solidus is a tapeworm of fish, fish-eating birds and rodents. This hermaphroditic parasite belongs to the Eucestoda subclass, of class Cestoda. This species has been used to demonstrate that cross-fertilization produces a higher infective success rate than self-fertilization.

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copyright
Wikipedia authors and editors
original
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wikipedia EN