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Miracidium

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The miracidium is the second stage in the life cycle of trematodes. When trematode eggs are laid and come into contact with fresh water, they hatch and release miracidium. In this phase, miracidia are ciliated and free-swimming. This stage is completed upon coming in contact with, and entering into, a suitable intermediate host for the purposes of asexual reproduction.[1] Many different species of Trematoda exist, expressing some variation in the physiology and appearance of the miracidia. The various trematode species implement similar strategies to increase their chances of locating and colonizing a new host.

Anatomy

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Hirundinella ventricosa

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The trematode Hirundinella ventricosa releases eggs in strings. Each egg contains a single miracidium, while the string contains living spermatozoa. Miracidia have cilia that are only present in the upper portion of the body near an apical gland with 12 hook-like spines in the opening.[2]

Echinostoma paraensei

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Miracidia usually need to enter a Mollusca host before they can start growing and begin reproduction, however certain species can use other animals as intermediate or main hosts. Echinostoma paraensei miracidia have 18 plates along the outside of their body.[3]

Even when about to hatch, their eggs show no signs of specialization such as projection or spine-like structure. They have elongated bodies with one intraepidermal ridge in the anterior row. They display a single "excretory vesicle".[4]

The miracidia are oval-shaped and their body is almost entirely covered in cilia except for the most anterior portions, taken up by "apical papilla". The miracidia have four papillae on each side, which contain sensory hairs. They each have an apical gland that leads to the apical papilla. They have four rows of epidermal plates, with row two made up of eight plates, while the other three rows each have six. Their eyespots are dark brown and shaped like an inverted capital letter L, located between the first and second row of plates. A single "large cephalic ganglion" along with several smaller nuclei, make up the nervous system.[5]

Physiology

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Miracidia do not feed. Their sole purpose is to locate and colonize a host. The ability and efficiency of miracidia to find a host is a crucial factor in the growth and success of later life stages.

Schistosome miracidia follow a three-phase process when searching for a host. In phase one, the miracidia use light gravity stimuli to concentrate in areas that are likely attractive to snail hosts. The second phase consists of randomly moving around. In phase three miracidia begin approaching their host target and preparing to penetrate it.[6]

Chemosensitivity plays a large role in the search for a host, but it is not specific enough to find only those species that are suitable hosts.[6] Carbohydrates along the surface of the miracidia interact with the lectins produced by gastropods. The organization and number of these carbohydrates shift as the miracidia begin their transition to the next step in their development. Certain carbohydrates are bound all over the body of the sporocyst stage but have only been found to be present on the "intercellular ridges" of the miracidia.[7]

Three glands assist them in this process. They use glandular secretions that collect in an indented area of the papilla, as a means of both sticking to the host they are attempting to invade, and breaking down the cells on the outside of the host organism to gain entry into it.

Once inside a host, germ cells begin to form and then replicate into germ balls. Each of the germ balls grows and eventually becomes the next step in the life cycle, the sporocyst.[8]

References

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  1. ^ Nikander, Sven; Näreaho, Anu; Saari, Seppo (2019). Canine Parasites and Parasitic Diseases. Academic Press. pp. 34–35. ISBN 9780128141120. Retrieved 25 May 2021.
  2. ^ Meenakshi, Murugesh; Madhavi, R. (1990). "Egg and Miracidium of Hirudinella Ventricosa (Trematoda: Hirudinellidae)". The Journal of Parasitology. 76 (5): 748–749. doi:10.2307/3282998. JSTOR 3282998. PMID 2213424. Retrieved 14 March 2021.
  3. ^ Pinheiro, Jairo; Maldonado, Arnaldo (2004). "Light and scanning electron microscopy of the miracidium of Echinostoma paraensei (Trematoda, Echinostomatidae)". Veterinary Parasitology. 121 (3–4): 265–275. doi:10.1016/j.vetpar.2004.02.019. PMID 15135866. Retrieved 14 March 2021.
  4. ^ Pinheiro, J.; Franco-Acuña, D.; Oliveira-Menezes, A.; Brandolini, S.V.P.B.; Adnet, F.A.O.; Lopes Torres, E.J.; Miranda, F.J.B.; Souza, W. De.; Damatta, R.A. (2015-09-01). "Additional study of the morphology of eggs and miracidia of Eurytrema coelomaticum (Trematoda)". Helminthologia. 52 (3): 244–251. doi:10.1515/helmin-2015-0039. S2CID 90946928. Retrieved 3 March 2021.
  5. ^ Diaz, M.T.; Hernández, L.E.; Bashirullah, A.K. (June 2002). "Experimental life cycle of Philophthalmus gralli (Thematoda: Philophthalmidae) in Venezuela". Revista de Biología Tropical. 50 (2): 629–641. PMID 12298291. Retrieved 3 March 2021.
  6. ^ a b Christensen, N (December 1980). "A review of the influence of host- and parasite-related factors and environmental conditions on the host-finding capacity of the trematode miracidium". Acta Tropica. 37 (4): 303–318. doi:10.5169/seals-312667. PMID 6110321. Retrieved 2 March 2021.
  7. ^ Georgieva, Katya; Georgieva, Simona; Mizinska, Yana; Stoitsova, Stoyanka (March 2012). "Fasciola hepatica miracidia: Lectin binding and stimulation of in vitro miracidium-to-sporocyst transformation". Acta Parasitologica. 57 (1): 46–52. doi:10.2478/s11686-012-0007-8. PMID 22807013. S2CID 255346391. Retrieved 2 March 2021.
  8. ^ Bogitsh, Burton; Carter, Clint; Oeltmann, Thomas (July 11, 2018). Human Parasitology (Fifth ed.). Academic Press. pp. 149–174. ISBN 978-0-12-813712-3. Retrieved 2 March 2021.