Archigregarinorida

Archigregarinorida
Scientific classification
Domain: Eukaryota
(unranked): SAR
Superphylum: Alveolata
Phylum: Apicomplexa
Levine 1970
Class: Conoidasida
Levine 1988
Subclass: Gregarinasina
Dufour 1828
Order: Archigregarinorida
Grassé & Schrével 1953
Families

Exoschizonidae
Selenidioididae

The Archigregarinorida are an order of parasitic protozoa in the phylum Apicomplexa. Species in this order infect marine invertebrates — usually annelids, ascidians, hemichordates and sipunculids.

Taxonomy

This order was redefined by Levine in 1971.[1]

The order currently consists of 76 species in two families — Exoschizonidae and Selenidioididae.

The family Exoschizonidae contains one genusExoschizon — which has one species.

The family Selenidioididae has six genera: Filipodium with 3 species, Merogregarina with one species, Meroselenidium with one species, Platyproteum with one species, Selenidioides with 11 species and Veloxidium with one species.

Phylogenetics

DNA studies suggest that the archigregarines are ancestral to the other gregarines.[2] Phylogenetic analysis suggests that this group is paraphyletic and will need division.[2] The Neogregarinorida appear to be derived from the Eugregarinorida.[3]

Assuming this is correct the evolutionary order appears to be: the Archigregarinorida gave rise to the Eugregarinorida who in turn gave rise to the Neogregarinorida.

Morrison using molecular data has shown that the Haemosporidia appear to nest within the gregarines.[4]

Description

The species in this order are relatively large spindle shaped cells, compared to other apicomplexans and eukaryotes in general (some species are > 850 µm in length). Most gregarines have longitudinal epicytic folds (bundles of microtubules beneath the cell surface with nematode like bending behaviour).

Life cycle

Archigregarines are found only in marine habitats and are transmitted by the orofaecal route. Merogony, gamogony and sporogony are thought to occur in all species in this taxon.

In all species four or more sporozoites (the precise number depends on the species) equipped with an apical complex escape from the oocysts, find their way to the appropriate body cavity and penetrate host cells in their immediate environment. The sporozoites emerge within the host cell, begin to feed and develop into larger trophozoites. In some species, the sporozoites and trophozoites are capable of asexual replication — a process called schizogony or merogony. Most species however appear to lack schizogony in their lifecycles.

The intestinal trophozoites are similar in morphology to the infective sporozoites. In all species two mature trophozoites eventually pair up in a process known as (syzygy) and develop into gamonts. The gamonts are aseptate. During syzygy gamont orientation differs between species (side to side, head to tail). A gametocyst wall forms around each pair of gamonts which then begin to divide into hundreds of gametes. Zygotes are produced by the fusion of two gametes and these in turn become surrounded by an oocyst wall. Within the oocyst meiosis occurs yielding the sporozoites. Hundreds of oocysts accumulate within each gametocyst and these are released via host's faeces or via host death and decay.

References

  1. Levine ND (1971). "Taxonomy of the Archigregarinorida and Selenidiidae (Protozoa, Apicomplexa)". J Euk Micro 18 (4): 704–717. doi:10.1111/j.1550-7408.1971.tb03401.x.
  2. 1 2 Leander BS, Clopton RE, Keeling PJ (January 2003). "Phylogeny of gregarines (Apicomplexa) as inferred from small-subunit rDNA and beta-tubulin". Int. J. Syst. Evol. Microbiol. 53 (Pt 1): 345–54. doi:10.1099/ijs.0.02284-0. PMID 12656194.
  3. Leander BS (February 2008). "Marine gregarines: evolutionary prelude to the apicomplexan radiation?". Trends Parasitol. 24 (2): 60–7. doi:10.1016/j.pt.2007.11.005. PMID 18226585.
  4. Morrison DA (August 2009). "Evolution of the Apicomplexa: where are we now?". Trends Parasitol. 25 (8): 375–82. doi:10.1016/j.pt.2009.05.010. PMID 19635681.
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