fbpx
Wikipedia

Apicomplexa

February 16, 2024

The Apicomplexa (also called Apicomplexia; single: apicomplexan) are organisms of a large phylum of mainly parasitic alveolates. Most possess a unique form of organelle structure that comprises a type of (non-photosynthetic) plastid called an apicoplast—with an apical complex membrane. The organelle's apical shape (e.g., Ceratium furca) is an adaptation that the apicomplexan applies in penetrating a host cell.

Apicomplexa
Scientific classification
Domain: Eukaryota
Clade: Diaphoretickes
Clade: TSAR
Clade: SAR
Clade: Alveolata
Phylum: Apicomplexa
Levine, 1970[1][2]
Classes & Subclasses Perkins, 2000

The Apicomplexa are unicellular and spore-forming. Most are obligate endoparasites of animals,[3] except Nephromyces, a symbiont in marine animals, originally classified as a chytrid fungus,[4] and the Chromerida, some of which are photosynthetic partners of corals. Motile structures such as flagella or pseudopods are present only in certain gamete stages.

The Apicomplexa are a diverse group that includes organisms such as the coccidia, gregarines, piroplasms, haemogregarines, and plasmodia. Diseases caused by Apicomplexa include:

The name Apicomplexa derives from two Latin words—apex (top) and complexus (infolds)—for the set of organelles in the sporozoite. The Apicomplexa comprise the bulk of what used to be called the Sporozoa, a group of parasitic protozoans, in general without flagella, cilia, or pseudopods. Most of the Apicomplexa are motile, however, with a gliding mechanism[5] that uses adhesions and small static myosin motors.[6] The other main lines were the Ascetosporea (a group of Rhizaria), the Myxozoa (highly derived cnidarian animals), and the Microsporidia (derived from fungi). Sometimes, the name Sporozoa is taken as a synonym for the Apicomplexa, or occasionally as a subset.

Description edit

 
Apicomplexan structure[7]
 
Some cell types: ookinete, sporozoite, merozoite

The phylum Apicomplexa contains all eukaryotes with a group of structures and organelles collectively termed the apical complex.[8] This complex consists of structural components and secretory organelles required for invasion of host cells during the parasitic stages of the Apicomplexan life cycle.[8] Apicomplexa have complex life cycles, involving several stages and typically undergoing both asexual and sexual replication.[8] All Apicomplexa are obligate parasites for some portion of their life cycle, with some parasitizing two separate hosts for their asexual and sexual stages.[8]

Besides the conserved apical complex, Apicomplexa are morphologically diverse. Different organisms within Apicomplexa, as well as different life stages for a given apicomplexan, can vary substantially in size, shape, and subcellular structure.[8] Like other eukaryotes, Apicomplexa have a nucleus, endoplasmic reticulum and Golgi complex.[8] Apicomplexa generally have a single mitochondrion, as well as another endosymbiont-derived organelle called the apicoplast which maintains a separate 35 kilobase circular genome (with the exception of Cryptosporidium species and Gregarina niphandrodes which lack an apicoplast).[8]

All members of this phylum have an infectious stage—the sporozoite—which possesses three distinct structures in an apical complex. The apical complex consists of a set of spirally arranged microtubules (the conoid), a secretory body (the rhoptry) and one or more polar rings. Additional slender electron-dense secretory bodies (micronemes) surrounded by one or two polar rings may also be present. This structure gives the phylum its name. A further group of spherical organelles is distributed throughout the cell rather than being localized at the apical complex and are known as the dense granules. These typically have a mean diameter around 0.7 μm. Secretion of the dense-granule content takes place after parasite invasion and localization within the parasitophorous vacuole and persists for several minutes.[citation needed]

  • Flagella are found only in the motile gamete. These are posteriorly directed and vary in number (usually one to three).
  • Basal bodies are present. Although hemosporidians and piroplasmids have normal triplets of microtubules in their basal bodies, coccidians and gregarines have nine singlets.
  • The mitochondria have tubular cristae.
  • Centrioles, chloroplasts, ejectile organelles, and inclusions are absent.
  • The cell is surrounded by a pellicle of three membrane layers (the alveolar structure) penetrated by micropores.

Replication:

  • Mitosis is usually closed, with an intranuclear spindle; in some species, it is open at the poles.
  • Cell division is usually by schizogony.
  • Meiosis occurs in the zygote.

Mobility:

Apicomplexans have a unique gliding capability which enables them to cross through tissues and enter and leave their host cells. This gliding ability is made possible by the use of adhesions and small static myosin motors.[9]

Other features common to this phylum are a lack of cilia, sexual reproduction, use of micropores for feeding, and the production of oocysts containing sporozoites as the infective form.

Transposons appear to be rare in this phylum, but have been identified in the genera Ascogregarina and Eimeria.[10]

Life cycle edit

Further information: Apicomplexa lifecycle stages
 
Generic lifecycle of an Apicomplexan: 1-zygote (cyst), 2-sporozoites, 3-merozoites, 4-gametocytes

Most members have a complex lifecycle, involving both asexual and sexual reproduction. Typically, a host is infected via an active invasion by the parasites (similar to entosis), which divide to produce sporozoites that enter its cells. Eventually, the cells burst, releasing merozoites, which infect new cells. This may occur several times, until gamonts are produced, forming gametes that fuse to create new cysts. Many variations occur on this basic pattern, however, and many Apicomplexa have more than one host.[citation needed]

The apical complex includes vesicles called rhoptries and micronemes, which open at the anterior of the cell. These secrete enzymes that allow the parasite to enter other cells. The tip is surrounded by a band of microtubules, called the polar ring, and among the Conoidasida is also a funnel of tubulin proteins called the conoid.[11] Over the rest of the cell, except for a diminished mouth called the micropore, the membrane is supported by vesicles called alveoli, forming a semirigid pellicle.[12]

The presence of alveoli and other traits place the Apicomplexa among a group called the alveolates. Several related flagellates, such as Perkinsus and Colpodella, have structures similar to the polar ring and were formerly included here, but most appear to be closer relatives of the dinoflagellates. They are probably similar to the common ancestor of the two groups.[12]

Another similarity is that many apicomplexan cells contain a single plastid, called the apicoplast, surrounded by either three or four membranes. Its functions are thought to include tasks such as lipid and heme biosynthesis, and it appears to be necessary for survival. In general, plastids are considered to have a common origin with the chloroplasts of dinoflagellates, and evidence points to an origin from red algae rather than green.[13][14]

Subgroups edit

Within this phylum are four groups — coccidians, gregarines, haemosporidians (or haematozoans, including in addition piroplasms), and marosporidians. The coccidians and haematozoans appear to be relatively closely related.[15]

Perkinsus , while once considered a member of the Apicomplexa, has been moved to a new phylum — Perkinsozoa.[16]

Gregarines edit

 
Trophozoite of a gregarine
Main article: Gregarinasina

The gregarines are generally parasites of annelids, arthropods, and molluscs. They are often found in the guts of their hosts, but may invade the other tissues. In the typical gregarine lifecycle, a trophozoite develops within a host cell into a schizont. This then divides into a number of merozoites by schizogony. The merozoites are released by lysing the host cell, which in turn invade other cells. At some point in the apicomplexan lifecycle, gametocytes are formed. These are released by lysis of the host cells, which group together. Each gametocyte forms multiple gametes. The gametes fuse with another to form oocysts. The oocysts leave the host to be taken up by a new host.[17]

Coccidians edit

 
Dividing Toxoplasma gondii (Coccidia) parasites
Main article: Coccidia

In general, coccidians are parasites of vertebrates. Like gregarines, they are commonly parasites of the epithelial cells of the gut, but may infect other tissues.

The coccidian lifecycle involves merogony, gametogony, and sporogony. While similar to that of the gregarines it differs in zygote formation. Some trophozoites enlarge and become macrogamete, whereas others divide repeatedly to form microgametes (anisogamy). The microgametes are motile and must reach the macrogamete to fertilize it. The fertilized macrogamete forms a zygote that in its turn forms an oocyst that is normally released from the body. Syzygy, when it occurs, involves markedly anisogamous gametes. The lifecycle is typically haploid, with the only diploid stage occurring in the zygote, which is normally short-lived.[18]

The main difference between the coccidians and the gregarines is in the gamonts. In the coccidia, these are small, intracellular, and without epimerites or mucrons. In the gregarines, these are large, extracellular, and possess epimerites or mucrons. A second difference between the coccidia and the gregarines also lies in the gamonts. In the coccidians, a single gamont becomes a macrogametocyte, whereas in the gregarines, the gamonts give rise to multiple gametocytes.[19]

Haemosporidia edit

 
Trophozoites of the Plasmodium vivax (Haemosporidia) parasite among human red blood cells
Main article: Haemosporida

The Haemosporidia have more complex lifecycles that alternate between an arthropod and a vertebrate host. The trophozoite parasitises erythrocytes or other tissues in the vertebrate host. Microgametes and macrogametes are always found in the blood. The gametes are taken up by the insect vector during a blood meal. The microgametes migrate within the gut of the insect vector and fuse with the macrogametes. The fertilized macrogamete now becomes an ookinete, which penetrates the body of the vector. The ookinete then transforms into an oocyst and divides initially by meiosis and then by mitosis (haplontic lifecycle) to give rise to the sporozoites. The sporozoites escape from the oocyst and migrate within the body of the vector to the salivary glands where they are injected into the new vertebrate host when the insect vector feeds again.[20]

Marosporida edit

The class Marosporida Mathur, Kristmundsson, Gestal, Freeman, and Keeling 2020 is a newly recognized lineage of apicomplexans that is sister to the Coccidia and Hematozoa. It is defined as a phylogenetic clade containing Aggregata octopiana Frenzel 1885, Merocystis kathae Dakin, 1911 (both Aggregatidae, originally coccidians), Rhytidocystis sp. 1 and Rhytidocystis sp. 2 Janouškovec et al. 2019 (Rhytidocystidae Levine, 1979, originally coccidians, Agamococcidiorida), and Margolisiella islandica Kristmundsson et al. 2011 (closely related to Rhytidocystidae). Marosporida infect marine invertebrates. Members of this clade retain plastid genomes and the canonical apicomplexan plastid metabolism. However, marosporidians have the most reduced apicoplast genomes sequenced to date, lack canonical plastidial RNA polymerase and so provide new insights into reductive organelle evolution.[15]

Ecology and distribution edit

 
Two tachyzoites of Toxoplasma gondii, transmission electron microscopy

Many of the apicomplexan parasites are important pathogens of humans and domestic animals. In contrast to bacterial pathogens, these apicomplexan parasites are eukaryotic and share many metabolic pathways with their animal hosts. This makes therapeutic target development extremely difficult – a drug that harms an apicomplexan parasite is also likely to harm its human host. At present, no effective vaccines are available for most diseases caused by these parasites. Biomedical research on these parasites is challenging because it is often difficult, if not impossible, to maintain live parasite cultures in the laboratory and to genetically manipulate these organisms. In recent years, several of the apicomplexan species have been selected for genome sequencing. The availability of genome sequences provides a new opportunity for scientists to learn more about the evolution and biochemical capacity of these parasites. The predominant source of this genomic information is the EuPathDB[21] family of websites, which currently provides specialised services for Plasmodium species (PlasmoDB),[22][23] coccidians (ToxoDB),[24][25] piroplasms (PiroplasmaDB),[26] and Cryptosporidium species (CryptoDB).[27][28] One possible target for drugs is the plastid, and in fact existing drugs such as tetracyclines, which are effective against apicomplexans, seem to operate against the plastid.[29]

Many Coccidiomorpha have an intermediate host, as well as a primary host, and the evolution of hosts proceeded in different ways and at different times in these groups. For some coccidiomorphs, the original host has become the intermediate host, whereas in others it has become the definitive host. In the genera Aggregata, Atoxoplasma, Cystoisospora, Schellackia, and Toxoplasma, the original is now definitive, whereas in Akiba, Babesiosoma, Babesia, Haemogregarina, Haemoproteus, Hepatozoon, Karyolysus, Leucocytozoon, Plasmodium, Sarcocystis, and Theileria, the original hosts are now intermediate.

Similar strategies to increase the likelihood of transmission have evolved in multiple genera. Polyenergid oocysts and tissue cysts are found in representatives of the orders Protococcidiorida and Eimeriida. Hypnozoites are found in Karyolysus lacerate and most species of Plasmodium; transovarial transmission of parasites occurs in lifecycles of Karyolysus and Babesia.

Horizontal gene transfer appears to have occurred early on in this phylum's evolution with the transfer of a histone H4 lysine 20 (H4K20) modifier, KMT5A (Set8), from an animal host to the ancestor of apicomplexans.[30] A second gene—H3K36 methyltransferase (Ashr3 in plants)—may have also been horizontally transferred.[12]

Blood-borne genera edit

Within the Apicomplexa are three suborders of parasites:[12]

Within the Adelorina are species that infect invertebrates and others that infect vertebrates. The Eimeriorina—the largest suborder in this phylum—the lifecycle involves both sexual and asexual stages. The asexual stages reproduce by schizogony. The male gametocyte produces a large number of gametes and the zygote gives rise to an oocyst, which is the infective stage. The majority are monoxenous (infect one host only), but a few are heteroxenous (lifecycle involves two or more hosts).

The number of families in this later suborder is debated, with the number of families being between one and 20 depending on the authority and the number of genera being between 19 and 25.

Taxonomy edit

Further information: wikispecies:Apicomplexa

History edit

The first Apicomplexa protozoan was seen by Antonie van Leeuwenhoek, who in 1674 saw probably oocysts of Eimeria stiedae in the gall bladder of a rabbit. The first species of the phylum to be described, Gregarina ovata in earwigs intestines, was named by Dufour in 1828. He thought that they were a peculiar group related to the trematodes, at that time included in Vermes.[31] Since then, many more have been identified and named. During 1826–1850, 41 species and six genera of Apicomplexa were named. In 1951–1975, 1873 new species and 83 new genera were added.[31]

The older taxon Sporozoa, included in Protozoa, was created by Leuckart in 1879[32] and adopted by Bütschli in 1880.[33] Through history, it grouped with the current Apicomplexa many unrelated groups. For example, Kudo (1954) included in the Sporozoa species of the Ascetosporea (Rhizaria), Microsporidia (Fungi), Myxozoa (Animalia), and Helicosporidium (Chlorophyta), while Zierdt (1978) included the genus Blastocystis (Stramenopiles).[34] Dermocystidium was also thought to be sporozoan. Not all of these groups had spores, but all were parasitic.[31] However, other parasitic or symbiotic unicellular organisms were included too in protozoan groups outside Sporozoa (Flagellata, Ciliophora and Sarcodina), if they had flagella (e.g., many Kinetoplastida, Retortamonadida, Diplomonadida, Trichomonadida, Hypermastigida), cilia (e.g., Balantidium) or pseudopods (e.g., Entamoeba, Acanthamoeba, Naegleria). If they had cell walls, they also could be included in plant kingdom between bacteria or yeasts.

Sporozoa is no longer regarded as biologically valid and its use is discouraged,[35] although some authors still use it as a synonym for the Apicomplexa. More recently, other groups were excluded from Apicomplexa, e.g., Perkinsus and Colpodella (now in Protalveolata).

The field of classifying Apicomplexa is in flux and classification has changed throughout the years since it was formally named in 1970.[1]

By 1987, a comprehensive survey of the phylum was completed: in all, 4516 species and 339 genera had been named. They consisted of:[36][31]

Although considerable revision of this phylum has been done (the order Haemosporidia now has 17 genera rather than 9), these numbers are probably still approximately correct.[37]

Jacques Euzéby (1988) edit

Jacques Euzéby in 1988[38] created a new class Haemosporidiasina by merging subclass Piroplasmasina and suborder Haemospororina.

The division into Achromatorida and Chromatorida, although proposed on morphological grounds, may have a biological basis, as the ability to store haemozoin appears to have evolved only once.[39]

Roberts and Janovy (1996) edit

Roberts and Janovy in 1996 divided the phylum into the following subclasses and suborders (omitting classes and orders):[40]

These form the following five taxonomic groups:

  1. The gregarines are, in general, one-host parasites of invertebrates.
  2. The adeleorins are one-host parasites of invertebrates or vertebrates, or two-host parasites that alternately infect haematophagous (blood-feeding) invertebrates and the blood of vertebrates.
  3. The eimeriorins are a diverse group that includes one host species of invertebrates, two-host species of invertebrates, one-host species of vertebrates and two-host species of vertebrates. The eimeriorins are frequently called the coccidia. This term is often used to include the adeleorins.
  4. Haemospororins, often known as the malaria parasites, are two-host Apicomplexa that parasitize blood-feeding dipteran flies and the blood of various tetrapod vertebrates.
  5. Piroplasms where all the species included are two-host parasites infecting ticks and vertebrates.

Perkins (2000) edit

 

Perkins et al. proposed the following scheme.[41] It is outdated as the Perkinsidae have since been recognised as a sister group to the dinoflagellates rather that the Apicomplexia:

Macrogamete and microgamete develop separately. Syzygy does not occur. Ookinete has a conoid. Sporozoites have three walls. Heteroxenous: alternates between vertebrate host (in which merogony occurs) and invertebrate host (in which sporogony occurs). Usually blood parasites, transmitted by blood-sucking insects.
  • Order Perkinsorida

The name Protospiromonadida has been proposed for the common ancestor of the Gregarinomorpha and Coccidiomorpha.[42]

Another group of organisms that belong in this taxon are the corallicolids.[43] These are found in coral reef gastric cavities. Their relationship to the others in this phylum has yet to be established.

Another genus has been identified - Nephromyces - which appears to be a sister taxon to the Hematozoa.[44] This genus is found in the renal sac of molgulid ascidian tunicates.

Evolution edit

Further information: Alveolate § Phylogeny

Members of this phylum, except for the photosynthetic chromerids,[45] are parasitic and evolved from a free-living ancestor. This lifestyle is presumed to have evolved at the time of the divergence of dinoflagellates and apicomplexans.[46][47] Further evolution of this phylum has been estimated to have occurred about 800 million years ago.[48] The oldest extant clade is thought to be the archigregarines.[46]

These phylogenetic relations have rarely been studied at the subclass level. The Haemosporidia are related to the gregarines, and the piroplasms and coccidians are sister groups.[49] The Haemosporidia and the Piroplasma appear to be sister clades, and are more closely related to the coccidians than to the gregarines.[10] Marosporida is a sister group to Coccidiomorphea.[15]

Myzozoa
Apicomplexa s.l.

Squirmida (Digyalum, Filipodium, Platyproteum)

Chrompodellids/Apicomonadea
Apicomplexa s.s.
Gregarines s.l.

Cryptosporidium

Gregarines s.s.

Marosporida

Aggregatidae (Aggregata, Merocystis)

Margolisiella

Rhytidocystidae (Rhytidocystis)

Coccidiomorphea
Coccidia

Hemogregarines

Coccidia with a single host (Eimeria, Isospora, Cyclospora)

Cyst-forming coccidia (Toxoplasma, Sarcocystis, Frenkellia)

Hematozoa

Piroplasms (Babesia, Theileria)

Hemosporidia (Plasmodium, Leucocytozoon)

Dinoflagellates & Perkinsozoa

Janouškovec et al 2015 presents a somewhat different phylogeny, supporting the work of others showing multiple events of plastids losing photosynthesis. More importantly this work provides the first phylogenetic evidence that there have also been multiple events of plastids becoming genome-free.[50]

See also edit

References edit

  1. ^ a b Levine ND (1970). "Taxonomy of the Sporozoa". J Parasitol. 56 (4, Sect. 2, Part 1: Supplement: Proceedings Of the Second International Congress of Parasitology): 208–9. JSTOR 3277701.
  2. ^ Levine ND (May 1971). "Uniform Terminology for the Protozoan Subphylum Apicomplexa". J Eukaryot Microbiol. 18 (2): 352–5. doi:10.1111/j.1550-7408.1971.tb03330.x.
  3. ^ Jadwiga Grabda (1991). Marine fish parasitology: an outline. VCH. p. 8. ISBN 978-0-89573-823-3.
  4. ^ Saffo M. B.; McCoy A. M.; Rieken C.; Slamovits C. H. (2010). "Nephromyces, a beneficial apicomplexan symbiont in marine animals". Proceedings of the National Academy of Sciences. 107 (37): 16190–5. Bibcode:2010PNAS..10716190S. doi:10.1073/pnas.1002335107. PMC 2941302. PMID 20736348.
  5. ^ Kappe, Stefan H.I.; et al. (January 2004). "Apicomplexan gliding motility and host cell invasion: overhauling the motor model". Trends in Parasitology. 20 (1): 13–16. CiteSeerX 10.1.1.458.5746. doi:10.1016/j.pt.2003.10.011. PMID 14700584.
  6. ^ Sibley, L.D.I. (Oct 2010). "How apicomplexan parasites move in and out of cells". Curr Opin Biotechnol. 21 (5): 592–598. doi:10.1016/j.copbio.2010.05.009. PMC 2947570. PMID 20580218.
  7. ^ Patrick J. Keeling; Yana Eglit (21 November 2023). "Openly available illustrations as tools to describe eukaryotic microbial diversity". PLOS Biology. 21 (11): e3002395. doi:10.1371/JOURNAL.PBIO.3002395. ISSN 1544-9173. PMC 10662721. PMID 37988341. Wikidata Q123558544.
  8. ^ a b c d e f g Slapeta J, Morin-Adeline V (2011). "Apicomplexa, Levine 1970". Tree of Life Web Project. Retrieved 23 January 2019.
  9. ^ Sibley, L. D. (2004-04-09). "Intracellular Parasite Invasion Strategies". Science. 304 (5668): 248–253. Bibcode:2004Sci...304..248S. doi:10.1126/science.1094717. ISSN 0036-8075. PMID 15073368. S2CID 23218754.
  10. ^ a b Templeton TJ, Enomoto S, Chen WJ, et al. (February 2010). "A genome-sequence survey for Ascogregarina taiwanensis supports evolutionary affiliation but metabolic diversity between a Gregarine and Cryptosporidium". Mol. Biol. Evol. 27 (2): 235–48. doi:10.1093/molbev/msp226. PMC 2877549. PMID 19778951.
  11. ^ Duszynski, Donald W.; Upton, Steve J.; Couch, Lee (2004-02-21). . Department of Biology, University of New Mexico, and Division of Biology, Kansas State University. Archived from the original (Online database) on 2010-12-30. Retrieved 2006-10-04.
  12. ^ a b c d Angel., Sherman (2018). Medical Parasitology. EDTECH. ISBN 978-1-83947-353-1. OCLC 1132400230.
  13. ^ Patrick J. Keeling (2004). "Diversity and evolutionary history of plastids and their hosts". American Journal of Botany. 91 (10): 1481–1493. doi:10.3732/ajb.91.10.1481. PMID 21652304.
  14. ^ Ram, Ev; Naik, R; Ganguli, M; Habib, S (July 2008). "DNA organization by the apicoplast-targeted bacterial histone-like protein of Plasmodium falciparum". Nucleic Acids Research. 36 (15): 5061–73. doi:10.1093/nar/gkn483. PMC 2528193. PMID 18663012.
  15. ^ a b c Mathur, Varsha; Kwong, Waldan K.; Husnik, Filip; Irwin, Nicholas A. T.; Kristmundsson, Árni; Gestal, Camino; Freeman, Mark; Keeling, Patrick J (18 November 2020). "Phylogenomics Identifies a New Major Subgroup of Apicomplexans, Marosporida class nov., with Extreme Apicoplast Genome Reduction". Genome Biology and Evolution. Oxford University Press. 13 (2: evaa244). doi:10.1093/gbe/evaa244. ISSN 1759-6653. PMC 7875001. PMID 33566096.
  16. ^ Norén, Fredrik; Moestrup, Øjvind; Rehnstam-Holm, Ann-Sofi (October 1999). "Parvilucifera infectans norén et moestrup gen. et sp. nov. (perkinsozoa phylum nov.): a parasitic flagellate capable of killing toxic microalgae". European Journal of Protistology. 35 (3): 233–254. doi:10.1016/S0932-4739(99)80001-7.
  17. ^ Wong, Wesley; Wenger, Edward A.; Hartl, Daniel L.; Wirth, Dyann F. (2018-01-09). "Modeling the genetic relatedness of Plasmodium falciparum parasites following meiotic recombination and cotransmission". PLOS Computational Biology. 14 (1): e1005923. Bibcode:2018PLSCB..14E5923W. doi:10.1371/journal.pcbi.1005923. ISSN 1553-7358. PMC 5777656. PMID 29315306.
  18. ^ Adl, Sina M.; Bass, David; Lane, Christopher E.; Lukeš, Julius; Schoch, Conrad L.; Smirnov, Alexey; Agatha, Sabine; Berney, Cedric; Brown, Matthew W.; Burki, Fabien; Cárdenas, Paco; Čepička, Ivan; Chistyakova, Lyudmila; Campo, Javier; Dunthorn, Micah (2019). "Revisions to the Classification, Nomenclature, and Diversity of Eukaryotes". Journal of Eukaryotic Microbiology. 66 (1): 4–119. doi:10.1111/jeu.12691. ISSN 1066-5234. PMC 6492006. PMID 30257078.
  19. ^ Cruz-Bustos, Teresa; Feix, Anna Sophia; Ruttkowski, Bärbel; Joachim, Anja (2021-10-04). "Sexual Development in Non-Human Parasitic Apicomplexa: Just Biology or Targets for Control?". Animals. 11 (10): 2891. doi:10.3390/ani11102891. ISSN 2076-2615. PMC 8532714. PMID 34679913.
  20. ^ Frischknecht, Friedrich; Matuschewski, Kai (2017-01-20). "Plasmodium Sporozoite Biology". Cold Spring Harbor Perspectives in Medicine. 7 (5): a025478. doi:10.1101/cshperspect.a025478. ISSN 2157-1422. PMC 5411682. PMID 28108531.
  21. ^ "EuPathDB". Retrieved 2012-01-02.
  22. ^ Bahl, A.; Brunk, B.; Crabtree, J.; Fraunholz, M. J.; Gajria, B.; Grant, G. R.; Ginsburg, H.; Gupta, D.; Kissinger, J. C.; Labo, P.; Li, L.; Mailman, M. D.; Milgram, A. J.; Pearson, D. S.; Roos, D. S.; Schug, J.; Stoeckert Jr, C. J.; Whetzel, P. (2003). "PlasmoDB: The Plasmodium genome resource. A database integrating experimental and computational data". Nucleic Acids Research. 31 (1): 212–215. doi:10.1093/nar/gkg081. PMC 165528. PMID 12519984.
  23. ^ "PlasmoDB". Retrieved 2012-01-02.
  24. ^ Kissinger, J. C.; Gajria, B.; Li, L.; Paulsen, I. T.; Roos, D. S. (2003). "ToxoDB: Accessing the Toxoplasma gondii genome". Nucleic Acids Research. 31 (1): 234–236. doi:10.1093/nar/gkg072. PMC 165519. PMID 12519989.
  25. ^ "ToxoDB". Retrieved 2012-01-02.
  26. ^ "PiroplasmaDB". Retrieved 2012-01-02.
  27. ^ Heiges, M.; Wang, H.; Robinson, E.; Aurrecoechea, C.; Gao, X.; Kaluskar, N.; Rhodes, P.; Wang, S.; He, C. Z.; Su, Y.; Miller, J.; Kraemer, E.; Kissinger, J. C. (2006). "CryptoDB: A Cryptosporidium bioinformatics resource update". Nucleic Acids Research. 34 (90001): D419–D422. doi:10.1093/nar/gkj078. PMC 1347441. PMID 16381902.
  28. ^ "CryptoDB". Retrieved 2012-01-02.
  29. ^ Dahl, El; Shock, Jl; Shenai, Br; Gut, J; Derisi, Jl; Rosenthal, Pj (September 2006). "Tetracyclines specifically target the apicoplast of the malaria parasite Plasmodium falciparum". Antimicrobial Agents and Chemotherapy. 50 (9): 3124–31. doi:10.1128/AAC.00394-06. PMC 1563505. PMID 16940111.
  30. ^ Kishore SP, Stiller JW, Deitsch KW (2013). "Horizontal gene transfer of epigenetic machinery and evolution of parasitism in the malaria parasite Plasmodium falciparum and other apicomplexans". BMC Evol. Biol. 13 (1): 37. Bibcode:2013BMCEE..13...37K. doi:10.1186/1471-2148-13-37. PMC 3598677. PMID 23398820.
  31. ^ a b c d Levine N. D. (1988). "Progress in taxonomy of the Apicomplexan protozoa". The Journal of Protozoology. 35 (4): 518–520. doi:10.1111/j.1550-7408.1988.tb04141.x. PMID 3143826.
  32. ^ Leuckart, R. (1879). Die menschlichen Parasiten. Vol. 1 (2nd ed.). Leipzig: Winter.
  33. ^ Bütschli, O. (1880-82). Dr. H.G. Bronn's Klassen und Ordnungen des Thier-Reichs. Erster Band: Protozoa. Abt. I, Sarkodina und Sporozoa, [1].
  34. ^ Perez-Cordon, G.; et al. (2007). "Finding of Blastocystis sp. in bivalves of the genus Donax". Rev. Peru Biol. 14 (2): 301–2. doi:10.15381/rpb.v14i2.1824.
  35. ^ "Introduction to the Apicomplexa". from the original on 20 April 2009. Retrieved 2009-05-31.
  36. ^ Levine, N.D. (1988). The protozoan phylum Apicomplexa. CRC Press. ISBN 978-0849346538.
  37. ^ Karadjian, Gregory; Hassanin, Alexandre; Saintpierre, Benjamin; Gembu Tungaluna, Guy-Crispin; Ariey, Frederic; Ayala, Francisco J.; Landau, Irene; Duval, Linda (2016-08-15). "Highly rearranged mitochondrial genome in Nycteria parasites (Haemosporidia) from bats". Proceedings of the National Academy of Sciences. 113 (35): 9834–9839. Bibcode:2016PNAS..113.9834K. doi:10.1073/pnas.1610643113. ISSN 0027-8424. PMC 5024609. PMID 27528689.
  38. ^ Euzéby, J. (1988). Apicomplexa, 2: Hémosporidioses, Fascicule 1: Plasmodiidés, Haemoproteidés "Piroplasmes" (caractères généraux). Protozoologie Médicale Comparée. Vol. 3. Fondation Marcel Merieux. ISBN 978-2901773733. OCLC 463445910.
  39. ^ Martinsen ES, Perkins SL, Schall JJ (April 2008). "A three-genome phylogeny of malaria parasites (Plasmodium and closely related genera): evolution of life-history traits and host switches". Mol. Phylogenet. Evol. 47 (1): 261–73. doi:10.1016/j.ympev.2007.11.012. PMID 18248741.
  40. ^ Roberts, L.; Janovy, J. (1996). Foundations of Parasitology (5th ed.). Dubuque IA: Wm. C. Brown. ISBN 978-0697260710. OCLC 33439613.
  41. ^ Perkins FO, Barta JR, Clopton RE, Peirce MA, Upton SJ (2000). "Phylum Apicomplexa". In Lee JJ, Leedale GF, Bradbury P (eds.). An Illustrated guide to the Protozoa : organisms traditionally referred to as protozoa, or newly discovered groups. Vol. 1 (2nd ed.). Society of Protozoologists. pp. 190–369. ISBN 978-1891276224. OCLC 704052757.
  42. ^ Krylov MV (1992). "[The origin of heteroxeny in Sporozoa]". Parazitologia (in Russian). 26 (5): 361–368. PMID 1297964.
  43. ^ Kwong, WK; Del Campo, J; Mathur, V; Vermeij, MJA; Keeling, PJ (2019). "A widespread coral-infecting apicomplexan with chlorophyll biosynthesis genes". Nature. 568 (7750): 103–107. Bibcode:2019Natur.568..103K. doi:10.1038/s41586-019-1072-z. PMID 30944491. S2CID 92996418.
  44. ^ Muñoz-Gómez SA, Durnin K, Eme L, Paight C, Lane CE, Saffo MB, Slamovits CH (2019) Nephromyces represents a diverse and novel lineage of the Apicomplexa that has retained apicoplasts. Genome Biol Evol
  45. ^ Moore RB; Oborník M; Janouskovec J; Chrudimský T; Vancová M; Green DH; Wright SW; Davies NW; et al. (February 2008). "A photosynthetic alveolate closely related to apicomplexan parasites". Nature. 451 (7181): 959–963. Bibcode:2008Natur.451..959M. doi:10.1038/nature06635. PMID 18288187. S2CID 28005870.
  46. ^ a b Kuvardina ON, Leander BS, Aleshin VV, Myl'nikov AP, Keeling PJ, Simdyanov TG (November 2002). "The phylogeny of colpodellids (Alveolata) using small subunit rRNA gene sequences suggests they are the free-living sister group to apicomplexans". J. Eukaryot. Microbiol. 49 (6): 498–504. doi:10.1111/j.1550-7408.2002.tb00235.x. PMID 12503687. S2CID 4283969.
  47. ^ Leander BS, Keeling PJ (August 2003). "Morphostasis in alveolate evolution". Trends Ecol Evol. 18 (8): 395–402. CiteSeerX 10.1.1.410.9134. doi:10.1016/S0169-5347(03)00152-6.
  48. ^ Escalante AA, Ayala FJ (June 1995). "Evolutionary origin of Plasmodium and other Apicomplexa based on rRNA genes". Proc. Natl. Acad. Sci. U.S.A. 92 (13): 5793–7. Bibcode:1995PNAS...92.5793E. doi:10.1073/pnas.92.13.5793. PMC 41587. PMID 7597031.
  49. ^ 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.
  50. ^ Smith, David Roy; Keeling, Patrick J. (2016-09-08). "Protists and the Wild, Wild West of Gene Expression: New Frontiers, Lawlessness, and Misfits". Annual Review of Microbiology. Annual Reviews. 70 (1): 161–178. doi:10.1146/annurev-micro-102215-095448. ISSN 0066-4227. PMID 27359218.

External links edit

  • Brands, S.J. (2000). . Taxon: Genus Cryptosporidium. Amsterdam, the Netherlands: Universal Taxonomic Services. Archived from the original (Website database) on 2007-09-26. Retrieved 2006-10-13.
  • "David Roos's Seminar: Biology of Apicomplexan Parasites".

February 16, 2024
apicomplexa, also, called, apicomplexia, single, apicomplexan, organisms, large, phylum, mainly, parasitic, alveolates, most, possess, unique, form, organelle, structure, that, comprises, type, photosynthetic, plastid, called, apicoplast, with, apical, complex. The Apicomplexa also called Apicomplexia single apicomplexan are organisms of a large phylum of mainly parasitic alveolates Most possess a unique form of organelle structure that comprises a type of non photosynthetic plastid called an apicoplast with an apical complex membrane The organelle s apical shape e g Ceratium furca is an adaptation that the apicomplexan applies in penetrating a host cell ApicomplexaScientific classificationDomain EukaryotaClade DiaphoretickesClade TSARClade SARClade AlveolataPhylum ApicomplexaLevine 1970 1 2 Classes amp Subclasses Perkins 2000Aconoidasida Hematozoa Conoidasida Coccidia Coccidiasina Gregarinia Gregarinasina The Apicomplexa are unicellular and spore forming Most are obligate endoparasites of animals 3 except Nephromyces a symbiont in marine animals originally classified as a chytrid fungus 4 and the Chromerida some of which are photosynthetic partners of corals Motile structures such as flagella or pseudopods are present only in certain gamete stages The Apicomplexa are a diverse group that includes organisms such as the coccidia gregarines piroplasms haemogregarines and plasmodia Diseases caused by Apicomplexa include Babesiosis Babesia Malaria Plasmodium Cryptosporidiosis Cryptosporidium parvum Cyclosporiasis Cyclospora cayetanensis Cystoisosporiasis Cystoisospora belli Toxoplasmosis Toxoplasma gondii The name Apicomplexa derives from two Latin words apex top and complexus infolds for the set of organelles in the sporozoite The Apicomplexa comprise the bulk of what used to be called the Sporozoa a group of parasitic protozoans in general without flagella cilia or pseudopods Most of the Apicomplexa are motile however with a gliding mechanism 5 that uses adhesions and small static myosin motors 6 The other main lines were the Ascetosporea a group of Rhizaria the Myxozoa highly derived cnidarian animals and the Microsporidia derived from fungi Sometimes the name Sporozoa is taken as a synonym for the Apicomplexa or occasionally as a subset Contents 1 Description 2 Life cycle 3 Subgroups 3 1 Gregarines 3 2 Coccidians 3 3 Haemosporidia 3 4 Marosporida 4 Ecology and distribution 4 1 Blood borne genera 5 Taxonomy 5 1 History 5 2 Jacques Euzeby 1988 5 3 Roberts and Janovy 1996 5 4 Perkins 2000 6 Evolution 7 See also 8 References 9 External linksDescription edit nbsp Apicomplexan structure 7 nbsp Some cell types ookinete sporozoite merozoiteThe phylum Apicomplexa contains all eukaryotes with a group of structures and organelles collectively termed the apical complex 8 This complex consists of structural components and secretory organelles required for invasion of host cells during the parasitic stages of the Apicomplexan life cycle 8 Apicomplexa have complex life cycles involving several stages and typically undergoing both asexual and sexual replication 8 All Apicomplexa are obligate parasites for some portion of their life cycle with some parasitizing two separate hosts for their asexual and sexual stages 8 Besides the conserved apical complex Apicomplexa are morphologically diverse Different organisms within Apicomplexa as well as different life stages for a given apicomplexan can vary substantially in size shape and subcellular structure 8 Like other eukaryotes Apicomplexa have a nucleus endoplasmic reticulum and Golgi complex 8 Apicomplexa generally have a single mitochondrion as well as another endosymbiont derived organelle called the apicoplast which maintains a separate 35 kilobase circular genome with the exception of Cryptosporidium species and Gregarina niphandrodes which lack an apicoplast 8 All members of this phylum have an infectious stage the sporozoite which possesses three distinct structures in an apical complex The apical complex consists of a set of spirally arranged microtubules the conoid a secretory body the rhoptry and one or more polar rings Additional slender electron dense secretory bodies micronemes surrounded by one or two polar rings may also be present This structure gives the phylum its name A further group of spherical organelles is distributed throughout the cell rather than being localized at the apical complex and are known as the dense granules These typically have a mean diameter around 0 7 mm Secretion of the dense granule content takes place after parasite invasion and localization within the parasitophorous vacuole and persists for several minutes citation needed Flagella are found only in the motile gamete These are posteriorly directed and vary in number usually one to three Basal bodies are present Although hemosporidians and piroplasmids have normal triplets of microtubules in their basal bodies coccidians and gregarines have nine singlets The mitochondria have tubular cristae Centrioles chloroplasts ejectile organelles and inclusions are absent The cell is surrounded by a pellicle of three membrane layers the alveolar structure penetrated by micropores Replication Mitosis is usually closed with an intranuclear spindle in some species it is open at the poles Cell division is usually by schizogony Meiosis occurs in the zygote Mobility Apicomplexans have a unique gliding capability which enables them to cross through tissues and enter and leave their host cells This gliding ability is made possible by the use of adhesions and small static myosin motors 9 Other features common to this phylum are a lack of cilia sexual reproduction use of micropores for feeding and the production of oocysts containing sporozoites as the infective form Transposons appear to be rare in this phylum but have been identified in the genera Ascogregarina and Eimeria 10 Life cycle editFurther information Apicomplexa lifecycle stages nbsp Generic lifecycle of an Apicomplexan 1 zygote cyst 2 sporozoites 3 merozoites 4 gametocytes Most members have a complex lifecycle involving both asexual and sexual reproduction Typically a host is infected via an active invasion by the parasites similar to entosis which divide to produce sporozoites that enter its cells Eventually the cells burst releasing merozoites which infect new cells This may occur several times until gamonts are produced forming gametes that fuse to create new cysts Many variations occur on this basic pattern however and many Apicomplexa have more than one host citation needed The apical complex includes vesicles called rhoptries and micronemes which open at the anterior of the cell These secrete enzymes that allow the parasite to enter other cells The tip is surrounded by a band of microtubules called the polar ring and among the Conoidasida is also a funnel of tubulin proteins called the conoid 11 Over the rest of the cell except for a diminished mouth called the micropore the membrane is supported by vesicles called alveoli forming a semirigid pellicle 12 The presence of alveoli and other traits place the Apicomplexa among a group called the alveolates Several related flagellates such as Perkinsus and Colpodella have structures similar to the polar ring and were formerly included here but most appear to be closer relatives of the dinoflagellates They are probably similar to the common ancestor of the two groups 12 Another similarity is that many apicomplexan cells contain a single plastid called the apicoplast surrounded by either three or four membranes Its functions are thought to include tasks such as lipid and heme biosynthesis and it appears to be necessary for survival In general plastids are considered to have a common origin with the chloroplasts of dinoflagellates and evidence points to an origin from red algae rather than green 13 14 Subgroups editWithin this phylum are four groups coccidians gregarines haemosporidians or haematozoans including in addition piroplasms and marosporidians The coccidians and haematozoans appear to be relatively closely related 15 Perkinsus while once considered a member of the Apicomplexa has been moved to a new phylum Perkinsozoa 16 Gregarines edit nbsp Trophozoite of a gregarineMain article Gregarinasina The gregarines are generally parasites of annelids arthropods and molluscs They are often found in the guts of their hosts but may invade the other tissues In the typical gregarine lifecycle a trophozoite develops within a host cell into a schizont This then divides into a number of merozoites by schizogony The merozoites are released by lysing the host cell which in turn invade other cells At some point in the apicomplexan lifecycle gametocytes are formed These are released by lysis of the host cells which group together Each gametocyte forms multiple gametes The gametes fuse with another to form oocysts The oocysts leave the host to be taken up by a new host 17 Coccidians edit nbsp Dividing Toxoplasma gondii Coccidia parasitesMain article Coccidia In general coccidians are parasites of vertebrates Like gregarines they are commonly parasites of the epithelial cells of the gut but may infect other tissues The coccidian lifecycle involves merogony gametogony and sporogony While similar to that of the gregarines it differs in zygote formation Some trophozoites enlarge and become macrogamete whereas others divide repeatedly to form microgametes anisogamy The microgametes are motile and must reach the macrogamete to fertilize it The fertilized macrogamete forms a zygote that in its turn forms an oocyst that is normally released from the body Syzygy when it occurs involves markedly anisogamous gametes The lifecycle is typically haploid with the only diploid stage occurring in the zygote which is normally short lived 18 The main difference between the coccidians and the gregarines is in the gamonts In the coccidia these are small intracellular and without epimerites or mucrons In the gregarines these are large extracellular and possess epimerites or mucrons A second difference between the coccidia and the gregarines also lies in the gamonts In the coccidians a single gamont becomes a macrogametocyte whereas in the gregarines the gamonts give rise to multiple gametocytes 19 Haemosporidia edit nbsp Trophozoites of the Plasmodium vivax Haemosporidia parasite among human red blood cellsMain article Haemosporida The Haemosporidia have more complex lifecycles that alternate between an arthropod and a vertebrate host The trophozoite parasitises erythrocytes or other tissues in the vertebrate host Microgametes and macrogametes are always found in the blood The gametes are taken up by the insect vector during a blood meal The microgametes migrate within the gut of the insect vector and fuse with the macrogametes The fertilized macrogamete now becomes an ookinete which penetrates the body of the vector The ookinete then transforms into an oocyst and divides initially by meiosis and then by mitosis haplontic lifecycle to give rise to the sporozoites The sporozoites escape from the oocyst and migrate within the body of the vector to the salivary glands where they are injected into the new vertebrate host when the insect vector feeds again 20 Marosporida edit The class Marosporida Mathur Kristmundsson Gestal Freeman and Keeling 2020 is a newly recognized lineage of apicomplexans that is sister to the Coccidia and Hematozoa It is defined as a phylogenetic clade containing Aggregata octopiana Frenzel 1885 Merocystis kathae Dakin 1911 both Aggregatidae originally coccidians Rhytidocystis sp 1 and Rhytidocystis sp 2 Janouskovec et al 2019 Rhytidocystidae Levine 1979 originally coccidians Agamococcidiorida and Margolisiella islandica Kristmundsson et al 2011 closely related to Rhytidocystidae Marosporida infect marine invertebrates Members of this clade retain plastid genomes and the canonical apicomplexan plastid metabolism However marosporidians have the most reduced apicoplast genomes sequenced to date lack canonical plastidial RNA polymerase and so provide new insights into reductive organelle evolution 15 Ecology and distribution edit nbsp Two tachyzoites of Toxoplasma gondii transmission electron microscopyMany of the apicomplexan parasites are important pathogens of humans and domestic animals In contrast to bacterial pathogens these apicomplexan parasites are eukaryotic and share many metabolic pathways with their animal hosts This makes therapeutic target development extremely difficult a drug that harms an apicomplexan parasite is also likely to harm its human host At present no effective vaccines are available for most diseases caused by these parasites Biomedical research on these parasites is challenging because it is often difficult if not impossible to maintain live parasite cultures in the laboratory and to genetically manipulate these organisms In recent years several of the apicomplexan species have been selected for genome sequencing The availability of genome sequences provides a new opportunity for scientists to learn more about the evolution and biochemical capacity of these parasites The predominant source of this genomic information is the EuPathDB 21 family of websites which currently provides specialised services for Plasmodium species PlasmoDB 22 23 coccidians ToxoDB 24 25 piroplasms PiroplasmaDB 26 and Cryptosporidium species CryptoDB 27 28 One possible target for drugs is the plastid and in fact existing drugs such as tetracyclines which are effective against apicomplexans seem to operate against the plastid 29 Many Coccidiomorpha have an intermediate host as well as a primary host and the evolution of hosts proceeded in different ways and at different times in these groups For some coccidiomorphs the original host has become the intermediate host whereas in others it has become the definitive host In the genera Aggregata Atoxoplasma Cystoisospora Schellackia and Toxoplasma the original is now definitive whereas in Akiba Babesiosoma Babesia Haemogregarina Haemoproteus Hepatozoon Karyolysus Leucocytozoon Plasmodium Sarcocystis and Theileria the original hosts are now intermediate Similar strategies to increase the likelihood of transmission have evolved in multiple genera Polyenergid oocysts and tissue cysts are found in representatives of the orders Protococcidiorida and Eimeriida Hypnozoites are found in Karyolysus lacerate and most species of Plasmodium transovarial transmission of parasites occurs in lifecycles of Karyolysus and Babesia Horizontal gene transfer appears to have occurred early on in this phylum s evolution with the transfer of a histone H4 lysine 20 H4K20 modifier KMT5A Set8 from an animal host to the ancestor of apicomplexans 30 A second gene H3K36 methyltransferase Ashr3 in plants may have also been horizontally transferred 12 Blood borne genera edit Within the Apicomplexa are three suborders of parasites 12 suborder Adeleorina eight genera suborder Laveraniina formerly Haemosporina all genera in this suborder suborder Eimeriorina two genera Lankesterella and Schellackia Within the Adelorina are species that infect invertebrates and others that infect vertebrates The Eimeriorina the largest suborder in this phylum the lifecycle involves both sexual and asexual stages The asexual stages reproduce by schizogony The male gametocyte produces a large number of gametes and the zygote gives rise to an oocyst which is the infective stage The majority are monoxenous infect one host only but a few are heteroxenous lifecycle involves two or more hosts The number of families in this later suborder is debated with the number of families being between one and 20 depending on the authority and the number of genera being between 19 and 25 Taxonomy editFurther information wikispecies Apicomplexa History edit The first Apicomplexa protozoan was seen by Antonie van Leeuwenhoek who in 1674 saw probably oocysts of Eimeria stiedae in the gall bladder of a rabbit The first species of the phylum to be described Gregarina ovata in earwigs intestines was named by Dufour in 1828 He thought that they were a peculiar group related to the trematodes at that time included in Vermes 31 Since then many more have been identified and named During 1826 1850 41 species and six genera of Apicomplexa were named In 1951 1975 1873 new species and 83 new genera were added 31 The older taxon Sporozoa included in Protozoa was created by Leuckart in 1879 32 and adopted by Butschli in 1880 33 Through history it grouped with the current Apicomplexa many unrelated groups For example Kudo 1954 included in the Sporozoa species of the Ascetosporea Rhizaria Microsporidia Fungi Myxozoa Animalia and Helicosporidium Chlorophyta while Zierdt 1978 included the genus Blastocystis Stramenopiles 34 Dermocystidium was also thought to be sporozoan Not all of these groups had spores but all were parasitic 31 However other parasitic or symbiotic unicellular organisms were included too in protozoan groups outside Sporozoa Flagellata Ciliophora and Sarcodina if they had flagella e g many Kinetoplastida Retortamonadida Diplomonadida Trichomonadida Hypermastigida cilia e g Balantidium or pseudopods e g Entamoeba Acanthamoeba Naegleria If they had cell walls they also could be included in plant kingdom between bacteria or yeasts Sporozoa is no longer regarded as biologically valid and its use is discouraged 35 although some authors still use it as a synonym for the Apicomplexa More recently other groups were excluded from Apicomplexa e g Perkinsus and Colpodella now in Protalveolata The field of classifying Apicomplexa is in flux and classification has changed throughout the years since it was formally named in 1970 1 By 1987 a comprehensive survey of the phylum was completed in all 4516 species and 339 genera had been named They consisted of 36 31 Class Conoidasida Subclass Gregarinasina p p Order Eugregarinorida with 1624 named species and 231 named genera Subclass Coccidiasina p p Order Eucoccidiorida p p Suborder Adeleorina p p Group Hemogregarines with 399 species and four genera Suborder Eimeriorina with 1771 species and 43 genera Class Aconoidasida Order Haemospororida with 444 species and nine genera Order Piroplasmorida with 173 species and 20 genera Other minor groups omitted above with 105 species and 32 generaAlthough considerable revision of this phylum has been done the order Haemosporidia now has 17 genera rather than 9 these numbers are probably still approximately correct 37 Jacques Euzeby 1988 edit Jacques Euzeby in 1988 38 created a new class Haemosporidiasina by merging subclass Piroplasmasina and suborder Haemospororina Subclass Gregarinasina the gregarines Subclass Coccidiasina Suborder Adeleorina the adeleorins Suborder Eimeriorina the eimeriorins Subclass Haemosporidiasina Order Achromatorida Order ChromatoridaThe division into Achromatorida and Chromatorida although proposed on morphological grounds may have a biological basis as the ability to store haemozoin appears to have evolved only once 39 Roberts and Janovy 1996 edit Roberts and Janovy in 1996 divided the phylum into the following subclasses and suborders omitting classes and orders 40 Subclass Gregarinasina the gregarines Subclass Coccidiasina Suborder Adeleorina the adeleorins Suborder Eimeriorina the eimeriorins Suborder Haemospororina the haemospororins Subclass Piroplasmasina the piroplasms These form the following five taxonomic groups The gregarines are in general one host parasites of invertebrates The adeleorins are one host parasites of invertebrates or vertebrates or two host parasites that alternately infect haematophagous blood feeding invertebrates and the blood of vertebrates The eimeriorins are a diverse group that includes one host species of invertebrates two host species of invertebrates one host species of vertebrates and two host species of vertebrates The eimeriorins are frequently called the coccidia This term is often used to include the adeleorins Haemospororins often known as the malaria parasites are two host Apicomplexa that parasitize blood feeding dipteran flies and the blood of various tetrapod vertebrates Piroplasms where all the species included are two host parasites infecting ticks and vertebrates Perkins 2000 edit nbsp Perkins et al proposed the following scheme 41 It is outdated as the Perkinsidae have since been recognised as a sister group to the dinoflagellates rather that the Apicomplexia Class Aconoidasida Conoid present only in the ookinete of some speciesOrder HaemospororidaMacrogamete and microgamete develop separately Syzygy does not occur Ookinete has a conoid Sporozoites have three walls Heteroxenous alternates between vertebrate host in which merogony occurs and invertebrate host in which sporogony occurs Usually blood parasites transmitted by blood sucking insects Order Piroplasmorida dd dd Class Conoidasida Subclass Gregarinasina Order Archigregarinorida Order Eugregarinorida Suborder Adeleorina Suborder Eimeriorina Order Neogregarinorida Subclass Coccidiasina Order Agamococcidiorida Order Eucoccidiorida Order Ixorheorida Order Protococcidiorida Class PerkinsasidaOrder PerkinsoridaFamily Perkinsidae dd dd The name Protospiromonadida has been proposed for the common ancestor of the Gregarinomorpha and Coccidiomorpha 42 Another group of organisms that belong in this taxon are the corallicolids 43 These are found in coral reef gastric cavities Their relationship to the others in this phylum has yet to be established Another genus has been identified Nephromyces which appears to be a sister taxon to the Hematozoa 44 This genus is found in the renal sac of molgulid ascidian tunicates Evolution editFurther information Alveolate Phylogeny Members of this phylum except for the photosynthetic chromerids 45 are parasitic and evolved from a free living ancestor This lifestyle is presumed to have evolved at the time of the divergence of dinoflagellates and apicomplexans 46 47 Further evolution of this phylum has been estimated to have occurred about 800 million years ago 48 The oldest extant clade is thought to be the archigregarines 46 These phylogenetic relations have rarely been studied at the subclass level The Haemosporidia are related to the gregarines and the piroplasms and coccidians are sister groups 49 The Haemosporidia and the Piroplasma appear to be sister clades and are more closely related to the coccidians than to the gregarines 10 Marosporida is a sister group to Coccidiomorphea 15 Myzozoa Apicomplexa s l Squirmida Digyalum Filipodium Platyproteum Chrompodellids Apicomonadea Chromerida Chromera Vitrella Piridium Colpodellida Colpodella Voromonadida Alphamonas Voromonas Apicomplexa s s Gregarines s l CryptosporidiumGregarines s s Marosporida Aggregatidae Aggregata Merocystis MargolisiellaRhytidocystidae Rhytidocystis Coccidiomorphea Coccidia HemogregarinesCoccidia with a single host Eimeria Isospora Cyclospora Cyst forming coccidia Toxoplasma Sarcocystis Frenkellia Hematozoa Piroplasms Babesia Theileria Hemosporidia Plasmodium Leucocytozoon Dinoflagellates amp PerkinsozoaJanouskovec et al 2015 presents a somewhat different phylogeny supporting the work of others showing multiple events of plastids losing photosynthesis More importantly this work provides the first phylogenetic evidence that there have also been multiple events of plastids becoming genome free 50 See also editCentroconeReferences edit a b Levine ND 1970 Taxonomy of the Sporozoa J Parasitol 56 4 Sect 2 Part 1 Supplement Proceedings Of the Second International Congress of Parasitology 208 9 JSTOR 3277701 Levine ND May 1971 Uniform Terminology for the Protozoan Subphylum Apicomplexa J Eukaryot Microbiol 18 2 352 5 doi 10 1111 j 1550 7408 1971 tb03330 x Jadwiga Grabda 1991 Marine fish parasitology an outline VCH p 8 ISBN 978 0 89573 823 3 Saffo M B McCoy A M Rieken C Slamovits C H 2010 Nephromyces a beneficial apicomplexan symbiont in marine animals Proceedings of the National Academy of Sciences 107 37 16190 5 Bibcode 2010PNAS 10716190S doi 10 1073 pnas 1002335107 PMC 2941302 PMID 20736348 Kappe Stefan H I et al January 2004 Apicomplexan gliding motility and host cell invasion overhauling the motor model Trends in Parasitology 20 1 13 16 CiteSeerX 10 1 1 458 5746 doi 10 1016 j pt 2003 10 011 PMID 14700584 Sibley L D I Oct 2010 How apicomplexan parasites move in and out of cells Curr Opin Biotechnol 21 5 592 598 doi 10 1016 j copbio 2010 05 009 PMC 2947570 PMID 20580218 Patrick J Keeling Yana Eglit 21 November 2023 Openly available illustrations as tools to describe eukaryotic microbial diversity PLOS Biology 21 11 e3002395 doi 10 1371 JOURNAL PBIO 3002395 ISSN 1544 9173 PMC 10662721 PMID 37988341 Wikidata Q123558544 a b c d e f g Slapeta J Morin Adeline V 2011 Apicomplexa Levine 1970 Tree of Life Web Project Retrieved 23 January 2019 Sibley L D 2004 04 09 Intracellular Parasite Invasion Strategies Science 304 5668 248 253 Bibcode 2004Sci 304 248S doi 10 1126 science 1094717 ISSN 0036 8075 PMID 15073368 S2CID 23218754 a b Templeton TJ Enomoto S Chen WJ et al February 2010 A genome sequence survey for Ascogregarina taiwanensis supports evolutionary affiliation but metabolic diversity between a Gregarine and Cryptosporidium Mol Biol Evol 27 2 235 48 doi 10 1093 molbev msp226 PMC 2877549 PMID 19778951 Duszynski Donald W Upton Steve J Couch Lee 2004 02 21 The Coccidia of the World Department of Biology University of New Mexico and Division of Biology Kansas State University Archived from the original Online database on 2010 12 30 Retrieved 2006 10 04 a b c d Angel Sherman 2018 Medical Parasitology EDTECH ISBN 978 1 83947 353 1 OCLC 1132400230 Patrick J Keeling 2004 Diversity and evolutionary history of plastids and their hosts American Journal of Botany 91 10 1481 1493 doi 10 3732 ajb 91 10 1481 PMID 21652304 Ram Ev Naik R Ganguli M Habib S July 2008 DNA organization by the apicoplast targeted bacterial histone like protein of Plasmodium falciparum Nucleic Acids Research 36 15 5061 73 doi 10 1093 nar gkn483 PMC 2528193 PMID 18663012 a b c Mathur Varsha Kwong Waldan K Husnik Filip Irwin Nicholas A T Kristmundsson Arni Gestal Camino Freeman Mark Keeling Patrick J 18 November 2020 Phylogenomics Identifies a New Major Subgroup of Apicomplexans Marosporida class nov with Extreme Apicoplast Genome Reduction Genome Biology and Evolution Oxford University Press 13 2 evaa244 doi 10 1093 gbe evaa244 ISSN 1759 6653 PMC 7875001 PMID 33566096 Noren Fredrik Moestrup Ojvind Rehnstam Holm Ann Sofi October 1999 Parvilucifera infectans noren et moestrup gen et sp nov perkinsozoa phylum nov a parasitic flagellate capable of killing toxic microalgae European Journal of Protistology 35 3 233 254 doi 10 1016 S0932 4739 99 80001 7 Wong Wesley Wenger Edward A Hartl Daniel L Wirth Dyann F 2018 01 09 Modeling the genetic relatedness of Plasmodium falciparum parasites following meiotic recombination and cotransmission PLOS Computational Biology 14 1 e1005923 Bibcode 2018PLSCB 14E5923W doi 10 1371 journal pcbi 1005923 ISSN 1553 7358 PMC 5777656 PMID 29315306 Adl Sina M Bass David Lane Christopher E Lukes Julius Schoch Conrad L Smirnov Alexey Agatha Sabine Berney Cedric Brown Matthew W Burki Fabien Cardenas Paco Cepicka Ivan Chistyakova Lyudmila Campo Javier Dunthorn Micah 2019 Revisions to the Classification Nomenclature and Diversity of Eukaryotes Journal of Eukaryotic Microbiology 66 1 4 119 doi 10 1111 jeu 12691 ISSN 1066 5234 PMC 6492006 PMID 30257078 Cruz Bustos Teresa Feix Anna Sophia Ruttkowski Barbel Joachim Anja 2021 10 04 Sexual Development in Non Human Parasitic Apicomplexa Just Biology or Targets for Control Animals 11 10 2891 doi 10 3390 ani11102891 ISSN 2076 2615 PMC 8532714 PMID 34679913 Frischknecht Friedrich Matuschewski Kai 2017 01 20 Plasmodium Sporozoite Biology Cold Spring Harbor Perspectives in Medicine 7 5 a025478 doi 10 1101 cshperspect a025478 ISSN 2157 1422 PMC 5411682 PMID 28108531 EuPathDB Retrieved 2012 01 02 Bahl A Brunk B Crabtree J Fraunholz M J Gajria B Grant G R Ginsburg H Gupta D Kissinger J C Labo P Li L Mailman M D Milgram A J Pearson D S Roos D S Schug J Stoeckert Jr C J Whetzel P 2003 PlasmoDB The Plasmodium genome resource A database integrating experimental and computational data Nucleic Acids Research 31 1 212 215 doi 10 1093 nar gkg081 PMC 165528 PMID 12519984 PlasmoDB Retrieved 2012 01 02 Kissinger J C Gajria B Li L Paulsen I T Roos D S 2003 ToxoDB Accessing the Toxoplasma gondii genome Nucleic Acids Research 31 1 234 236 doi 10 1093 nar gkg072 PMC 165519 PMID 12519989 ToxoDB Retrieved 2012 01 02 PiroplasmaDB Retrieved 2012 01 02 Heiges M Wang H Robinson E Aurrecoechea C Gao X Kaluskar N Rhodes P Wang S He C Z Su Y Miller J Kraemer E Kissinger J C 2006 CryptoDB A Cryptosporidium bioinformatics resource update Nucleic Acids Research 34 90001 D419 D422 doi 10 1093 nar gkj078 PMC 1347441 PMID 16381902 CryptoDB Retrieved 2012 01 02 Dahl El Shock Jl Shenai Br Gut J Derisi Jl Rosenthal Pj September 2006 Tetracyclines specifically target the apicoplast of the malaria parasite Plasmodium falciparum Antimicrobial Agents and Chemotherapy 50 9 3124 31 doi 10 1128 AAC 00394 06 PMC 1563505 PMID 16940111 Kishore SP Stiller JW Deitsch KW 2013 Horizontal gene transfer of epigenetic machinery and evolution of parasitism in the malaria parasite Plasmodium falciparum and other apicomplexans BMC Evol Biol 13 1 37 Bibcode 2013BMCEE 13 37K doi 10 1186 1471 2148 13 37 PMC 3598677 PMID 23398820 a b c d Levine N D 1988 Progress in taxonomy of the Apicomplexan protozoa The Journal of Protozoology 35 4 518 520 doi 10 1111 j 1550 7408 1988 tb04141 x PMID 3143826 Leuckart R 1879 Die menschlichen Parasiten Vol 1 2nd ed Leipzig Winter Butschli O 1880 82 Dr H G Bronn s Klassen und Ordnungen des Thier Reichs Erster Band Protozoa Abt I Sarkodina und Sporozoa 1 Perez Cordon G et al 2007 Finding of Blastocystis sp in bivalves of the genus Donax Rev Peru Biol 14 2 301 2 doi 10 15381 rpb v14i2 1824 Introduction to the Apicomplexa Archived from the original on 20 April 2009 Retrieved 2009 05 31 Levine N D 1988 The protozoan phylum Apicomplexa CRC Press ISBN 978 0849346538 Karadjian Gregory Hassanin Alexandre Saintpierre Benjamin Gembu Tungaluna Guy Crispin Ariey Frederic Ayala Francisco J Landau Irene Duval Linda 2016 08 15 Highly rearranged mitochondrial genome in Nycteria parasites Haemosporidia from bats Proceedings of the National Academy of Sciences 113 35 9834 9839 Bibcode 2016PNAS 113 9834K doi 10 1073 pnas 1610643113 ISSN 0027 8424 PMC 5024609 PMID 27528689 Euzeby J 1988 Apicomplexa 2 Hemosporidioses Fascicule 1 Plasmodiides Haemoproteides Piroplasmes caracteres generaux Protozoologie Medicale Comparee Vol 3 Fondation Marcel Merieux ISBN 978 2901773733 OCLC 463445910 Martinsen ES Perkins SL Schall JJ April 2008 A three genome phylogeny of malaria parasites Plasmodium and closely related genera evolution of life history traits and host switches Mol Phylogenet Evol 47 1 261 73 doi 10 1016 j ympev 2007 11 012 PMID 18248741 Roberts L Janovy J 1996 Foundations of Parasitology 5th ed Dubuque IA Wm C Brown ISBN 978 0697260710 OCLC 33439613 Perkins FO Barta JR Clopton RE Peirce MA Upton SJ 2000 Phylum Apicomplexa In Lee JJ Leedale GF Bradbury P eds An Illustrated guide to the Protozoa organisms traditionally referred to as protozoa or newly discovered groups Vol 1 2nd ed Society of Protozoologists pp 190 369 ISBN 978 1891276224 OCLC 704052757 Krylov MV 1992 The origin of heteroxeny in Sporozoa Parazitologia in Russian 26 5 361 368 PMID 1297964 Kwong WK Del Campo J Mathur V Vermeij MJA Keeling PJ 2019 A widespread coral infecting apicomplexan with chlorophyll biosynthesis genes Nature 568 7750 103 107 Bibcode 2019Natur 568 103K doi 10 1038 s41586 019 1072 z PMID 30944491 S2CID 92996418 Munoz Gomez SA Durnin K Eme L Paight C Lane CE Saffo MB Slamovits CH 2019 Nephromyces represents a diverse and novel lineage of the Apicomplexa that has retained apicoplasts Genome Biol Evol Moore RB Obornik M Janouskovec J Chrudimsky T Vancova M Green DH Wright SW Davies NW et al February 2008 A photosynthetic alveolate closely related to apicomplexan parasites Nature 451 7181 959 963 Bibcode 2008Natur 451 959M doi 10 1038 nature06635 PMID 18288187 S2CID 28005870 a b Kuvardina ON Leander BS Aleshin VV Myl nikov AP Keeling PJ Simdyanov TG November 2002 The phylogeny of colpodellids Alveolata using small subunit rRNA gene sequences suggests they are the free living sister group to apicomplexans J Eukaryot Microbiol 49 6 498 504 doi 10 1111 j 1550 7408 2002 tb00235 x PMID 12503687 S2CID 4283969 Leander BS Keeling PJ August 2003 Morphostasis in alveolate evolution Trends Ecol Evol 18 8 395 402 CiteSeerX 10 1 1 410 9134 doi 10 1016 S0169 5347 03 00152 6 Escalante AA Ayala FJ June 1995 Evolutionary origin of Plasmodium and other Apicomplexa based on rRNA genes Proc Natl Acad Sci U S A 92 13 5793 7 Bibcode 1995PNAS 92 5793E doi 10 1073 pnas 92 13 5793 PMC 41587 PMID 7597031 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 Smith David Roy Keeling Patrick J 2016 09 08 Protists and the Wild Wild West of Gene Expression New Frontiers Lawlessness and Misfits Annual Review of Microbiology Annual Reviews 70 1 161 178 doi 10 1146 annurev micro 102215 095448 ISSN 0066 4227 PMID 27359218 External links editBrands S J 2000 The Taxonomicon amp Systema Naturae Taxon Genus Cryptosporidium Amsterdam the Netherlands Universal Taxonomic Services Archived from the original Website database on 2007 09 26 Retrieved 2006 10 13 David Roos s Seminar Biology of Apicomplexan Parasites Portal nbsp Biology Retrieved from https en wikipedia org w index php title Apicomplexa amp oldid 1205680501, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.