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Lankesterella (Apicomplexa)

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Lankesterella
Scientific classification
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Genus:
Lankesterella
Species

Lankesterella alencari
Lankesterella baznosanui
Lankesterella bufonis
Lankesterella hylae
Lankesterella millani
Lankesterella minima
Lankesterella valsainensis
Lankesterella macrovacuolata
Lankesterella vacuolata
Lankesterella petiti[1]
Lankesterella poeppigii
Lankesterella tritonis

Lankesterella is a genus in the phylum Apicomplexa. Species in this genus infect amphibians, reptiles[2] and birds.[3]

The type species is Lankesterella minima.

History

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This genus was created by Labbe in 1899.

This genus is more commonly known as Atoxoplasma, it is a genus of parasitic alveolates in the phylum Apicomplexa. Atoxoplasma species in passerines are a group of organisms with intestinal and extraintestinal forms that can cause significant morbidity and mortality but are not transmissible by syringe.

These genera were united by Lainson in 1959. They were separated again by Levin in 1982. More commonly known as Atoxoplasma, it is a genus of parasitic alveolates in the phylum Apicomplexa.[4] Apicomplexans are obligate intracellular parasites that typically invade blood cells. They have a distinct feature called the apical complex which helps in the penetration of the parasite into the host cell. Atoxoplasma sp. in passerines is a group of organisms with intestinal and extraintestinal forms that can cause significant morbidity and mortality.[5] This latter name was coined by Garnham in 1950 for a group of parasites resembling Toxoplasma. Recent molecular studies revealed that some of the avian parasites which were initially thought to be Hepatozoon species were actually found to be closely related to the amphibian parasite Lankesterella minima. The apicomplexan genera Lankesterella and Schellackia were largely believed to form a monophyletic clade within the family Lankesterellidae. However, phylogenetic analyses revealed they have an independent evolutionary origin.[6] Morphological identification is clearly not enough due to the many errors that occur in identification and hence the need for DNA barcoding for precise identification of the target species.[7]

Description

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Lankesterella are extra-intestinal coccidia that invades the host blood. Criteria for the specific differentiation of Lankesterella are limited due to the fact that they are much similar in morphology with other apicomplexans such as Isosporas and hepatazoons. The most commonly described stages are the sporozoites found in the peripheral blood erythrocytes. Despite considerable structural divergences that have been observed among the sporozoite shapes, a system for taxonomic differentiation has not been developed. Descriptions of the stages developing in the viscera are less available as they require necropsy of the host. Lankesterella species are commonly known in amphibians and reptiles, but in recent times it has been found to also infect avian species. The oocysts usually contain more than 32 sporozoites. There are no sporocysts.

Life cycle

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In the species that infect amphibians, the vectors are leeches. However, the lifecycle in avian species is still unknown since they have similar blood stages to other related apicomplexans such as hepatozoons and isosporas.

The fact that Lankesterella and Schellackia is nested within the same paraphyletic Eimeriidae makes the lifecycle of these parasites to be considered as an evolutionary novelty. Transmission is by a blood-sucking vector that exerts a mechanical role in the transmission between hosts. The infective stages of the parasite remain completely dormant in the vectors without any development.[8] Transmission in amphibians and reptiles occurs by blood-sucking arthropods such as leeches (intermediate hosts) or through the consumption of another definitive host (a snake eating an infected rat)[9] and transmission is avian species is still unknown. This uncertainty is due to the fact that further investigations into the life cycle and the use of molecular tools for the identification of different species remain important in order to better understand the biology of the lankesterella species.[10]


The sporozoites invade macrophages or endothelial cells. After development there, they invade circulating blood cells. The sporozoites may also invade liver parenchyma or tissue macrophages. A quite distinct feature of the parasite is that it invades the leukocytes in birds and erythrocytes in amphibians and reptiles

Host records

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Vertebrate

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Parasite species unknown

Vector

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Synonyms

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  • L. garnhami - L. serini
  • L. kabeeni - L. vacuolata,L. macrovacuolata

References

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  1. ^ Lainson, R.; Paperna, I. (1995). "Light and electron microscope study of a Lankesterella petiti n. sp., (Apicomplexa: Lankesterellidae) infecting Bufo marinus (Amphibia: Anura) in Pará, North Brazil". Parasite. 2 (3): 307–313. doi:10.1051/parasite/1995023307. ISSN 1252-607X.
  2. ^ Paperna, I.; Ogara, W. (2014). "Description and ultrastructure of Lankesterella species infecting frogs in Kenya". Parasite. 3 (4): 341–349. doi:10.1051/parasite/1996034341. ISSN 1252-607X.
  3. ^ Chagas, Carolina Romeiro Fernandes; Harl, Josef; Preikša, Vytautas; Bukauskaitė, Dovilė; Ilgūnas, Mikas; Weissenböck, Herbert; Valkiūnas, Gediminas (2021). "Lankesterella (Apicomplexa, Lankesterellidae) Blood Parasites of Passeriform Birds: Prevalence, Molecular and Morphological Characterization, with Notes on Sporozoite Persistence in Vivo and Development in Vitro". Animals. 11 (5): 1451. doi:10.3390/ANI11051451. PMC 8158525. PMID 34070187.
  4. ^ Lainson, R. (1959). "Atoxoplasma Garnham, 1950, as a synonym for Lankesterella Labbé, 1899. Its life cycle in the English sparrow ( Passer domesticus domesticus , Linn.)". The Journal of Protozoology. 6 (4): 360–371. doi:10.1111/J.1550-7408.1959.TB04385.X.
  5. ^ Schrenzel, Mark D.; Maalouf, Gabriel A.; Gaffney, Patricia M.; Tokarz, Debra; Keener, Laura L.; McClure, Diane; Griffey, Stephen; McAloose, D.; Rideout, Bruce A. (2005). "Molecular Characterization of Isosporoid Coccidia (Isospora and Atoxoplasma SPP.) in Passerine Birds". Journal of Parasitology. 91 (3): 635–647. doi:10.1645/GE-3310. PMID 16108559.
  6. ^ Megía-Palma, Rodrigo; Martínez, Javier; Merino, Santiago (2014). "Molecular characterization of haemococcidia genus Schellackia (Apicomplexa) reveals the polyphyletic origin of the family Lankesterellidae". Zoologica Scripta. 43 (3): 304–312. doi:10.1111/zsc.12050.
  7. ^ Merino, Santiago; Martínez, Javier; Martínez-de la Puente, Josué; Criado-Fornelio, Ángel; Tomás, Gustavo; Morales, Judith; Lobato, Elisa; García-Fraile, Sonia (2006). "MOLECULAR CHARACTERIZATION OF THE 18S rDNA GENE OF AN AVIAN HEPATOZOON REVEALS THAT IT IS CLOSELY RELATED TO LANKESTERELLA". Journal of Parasitology. 92 (6): 1330–1335. doi:10.1645/GE-860R.1. PMID 17304816.
  8. ^ Megía-Palma, Rodrigo; Martínez, Javier; Paranjpe, Dhanashree; d'Amico, Verónica; Aguilar, Rocío; Palacios, María Gabriela; Cooper, Robert; Ferri-Yáñez, Francisco; Sinervo, Barry; Merino, Santiago (2017). "Phylogenetic analyses reveal that Schellackia parasites (Apicomplexa) detected in American lizards are closely related to the genus Lankesterella: Is the range of Schellackia restricted to the Old World?". Parasites & Vectors. 10 (1): 470. doi:10.1186/s13071-017-2405-0. PMC 5633878. PMID 29017602.
  9. ^ Chagas, Carolina Romeiro Fernandes; Harl, Josef; Preikša, Vytautas; Bukauskaitė, Dovilė; Ilgūnas, Mikas; Weissenböck, Herbert; Valkiūnas, Gediminas (2021). "Lankesterella (Apicomplexa, Lankesterellidae) Blood Parasites of Passeriform Birds: Prevalence, Molecular and Morphological Characterization, with Notes on Sporozoite Persistence in Vivo and Development in Vitro". Animals. 11 (5): 1451. doi:10.3390/ANI11051451. PMC 8158525. PMID 34070187.
  10. ^ Smith, Todd G. (1996). "The Genus Hepatozoon (Apicomplexa: Adeleina)". The Journal of Parasitology. 82 (4): 565–585. doi:10.2307/3283781. JSTOR 3283781. PMID 8691364.