Alveolate: Difference between revisions

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Colponemida is not incertae sedis
That might be what the word means as a general adjective, but these area _alveolates_, distinguished by the presence of alveoli, and thus alveolate in fact means alveoli-bearing and not pitted as it would if you were describing plants or mushrooms. These have sacs, they're sac-bearing. A better thing to do would be to do (from Latin alveolatus, meaing sac-bearing) but I don't know how to do that nicely, so if anyone is mad at this please do that instead of reverting since this is just incorrect.
 
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| subdivision_ranks = Phyla and orders
| subdivision_ranks = Phyla and orders
| subdivision = * [[Ciliate|Ciliophora]]
| subdivision = * [[Ciliate|Ciliophora]]
* [[Colponemid]]a
* "[[Colponemid]]a"
* '''[[Myzozoa]]'''
* '''[[Myzozoa]]'''
** [[Apicomplexa]]
** [[Apicomplexa]]
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}}
}}


The '''alveolates''' (meaning "pitted like a honeycomb")<ref>{{cite web |url=http://www.memidex.com/alveolate |title=alveolate |work=Memidex (WordNet) Dictionary/Thesaurus |access-date=2011-01-26 |archive-url=https://web.archive.org/web/20160411233722/http://www.memidex.com/alveolate |archive-date=2016-04-11 |url-status=dead }}</ref> are a group of [[protist]]s, considered a major unranked [[clade]]<ref name="Adl2012">{{cite journal | last1 = Adl | first1 = S.M. | display-authors = etal  | year = 2012 | title = The revised classification of eukaryotes | journal = Journal of Eukaryotic Microbiology | volume = 59 | issue = 5| pages = 429–514 | doi=10.1111/j.1550-7408.2012.00644.x | pmid=23020233 | pmc=3483872}}</ref> or [[Phylum|superphylum]]<ref name="Ruggiero15">{{cite journal |vauthors=Ruggiero MA, Gordon DP, Orrell TM, Bailly N, Bourgoin T, Brusca RC, Cavalier-Smith T, Guiry MD, Kirk PM |title=A higher level classification of all living organisms |journal=PLOS ONE |volume=10 |issue=4 |pages=e0119248 |year=2015 |pmid=25923521 |pmc=4418965 |doi=10.1371/journal.pone.0119248 |bibcode=2015PLoSO..1019248R |doi-access=free }}</ref> within [[Eukaryote|Eukaryota]]. They are currently grouped with the [[Stramenopile]]s and [[Rhizaria]] among the protists with tubulocristate mitochondria into the [[SAR supergroup|SAR]] [[Supergroup (biology)|supergroup]].
The '''alveolates''' are a group of [[protist]]s, considered a major unranked [[clade]]<ref name="Adl2012">{{cite journal | last1 = Adl | first1 = S.M. | display-authors = etal  | year = 2012 | title = The revised classification of eukaryotes | journal = Journal of Eukaryotic Microbiology | volume = 59 | issue = 5| pages = 429–514 | doi=10.1111/j.1550-7408.2012.00644.x | pmid=23020233 | pmc=3483872}}</ref> or [[Phylum|superphylum]]<ref name="Ruggiero15">{{cite journal |vauthors=Ruggiero MA, Gordon DP, Orrell TM, Bailly N, Bourgoin T, Brusca RC, Cavalier-Smith T, Guiry MD, Kirk PM |title=A higher level classification of all living organisms |journal=PLOS ONE |volume=10 |issue=4 |article-number=e0119248 |year=2015 |pmid=25923521 |pmc=4418965 |doi=10.1371/journal.pone.0119248 |bibcode=2015PLoSO..1019248R |doi-access=free }}</ref> within [[Eukaryote|Eukaryota]]. They are currently grouped with the [[Stramenopile]]s and [[Rhizaria]] among the protists with tubulocristate mitochondria into the [[SAR supergroup]].


==Characteristics==
==Characteristics==
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[[File:EM alveoli ciliate paramecium putrinum.jpg|600px|thumb|center|Transmission electron micrograph of a thin section of the surface of the ciliate ''[[Paramecium]] putrinum'', showing the alveoli (red arrows) under the cell surface]]
[[File:EM alveoli ciliate paramecium putrinum.jpg|600px|thumb|center|Transmission electron micrograph of a thin section of the surface of the ciliate ''[[Paramecium]] putrinum'', showing the alveoli (red arrows) under the cell surface]]


Almost all sequenced mitochondrial genomes of ciliates and apicomplexa are linear.<ref name="Barth2011">{{Cite journal |last1=Barth |first1=D |last2=Berendonk |first2=TU |year=2011 |title=The mitochondrial genome sequence of the ciliate ''Paramecium caudatum'' reveals a shift in nucleotide composition and codon usage within the genus ''Paramecium'' |journal=BMC Genomics |volume=12 |page=272 |doi=10.1186/1471-2164-12-272 |pmc=3118789 |pmid=21627782 |doi-access=free}}</ref> The mitochondria almost all carry [[mtDNA]] of their own but with greatly reduced genome sizes. Exceptions are ''[[Cryptosporidium]]'' which are left with only a [[mitosome]], the circular mitochondrial genomes of ''[[Acavomonas]]'' and ''[[Babesia microti]]'',<ref name="Obornik-Lukes-2015">{{Cite journal |last1=Oborník |first1=Miroslav |last2=Lukeš |first2=Julius |date=2015-10-15 |title=The Organellar Genomes of Chromera and Vitrella, the Phototrophic Relatives of Apicomplexan Parasites |url=https://www.annualreviews.org/content/journals/10.1146/annurev-micro-091014-104449 |journal=Annual Review of Microbiology |volume=69 |pages=129–144 |doi=10.1146/annurev-micro-091014-104449 |issn=0066-4227 |pmid=26092225 |access-date=2024-04-15|url-access=subscription }}</ref><ref name="Cornillot2012">{{Cite journal |vauthors=Cornillot E, Hadj-Kaddour K, Dassouli A, Noel B, Ranwez V, Vacherie B, Augagneur Y, Brès V, Duclos A, Randazzo S, Carcy B, Debierre-Grockiego F, Delbecq S, Moubri-Ménage K, Shams-Eldin H, Usmani-Brown S, Bringaud F, Wincker P, Vivarès CP, Schwarz RT, Schetters TP, Krause PJ, Gorenflot A, Berry V, Barbe V, Ben Mamoun C |year=2012 |title=Sequencing of the smallest Apicomplexan genome from the human pathogen ''Babesia microti'' |journal=Nucleic Acids Res. |volume=40 |issue=18 |pages=9102–14 |doi=10.1093/nar/gks700 |pmc=3467087 |pmid=22833609}}</ref> and ''[[Toxoplasma]]'''s highly fragmented mitochondrial genome, consisting of 21 sequence blocks which recombine to produce longer segments.<ref>{{Cite journal |last1=Namasivayam |first1=Sivaranjani |last2=Baptista |first2=Rodrigo P. |last3=Xiao |first3=Wenyuan |last4=Hall |first4=Erica M. |last5=Doggett |first5=Joseph S. |last6=Troell |first6=Karin |last7=Kissinger |first7=Jessica C. |date=May 2021 |title=A novel fragmented mitochondrial genome in the protist pathogen Toxoplasma gondii and related tissue coccidia |journal=Genome Research |volume=31 |issue=5 |pages=852–865 |doi=10.1101/gr.266403.120 |pmc=8092004 |pmid=33906963}}</ref><ref>{{Cite journal |last1=Namasivayam |first1=Sivaranjani |last2=Sun |first2=Cheng |last3=Bah |first3=Assiatu B. |last4=Oberstaller |first4=Jenna |last5=Pierre-Louis |first5=Edwin |last6=Etheridge |first6=Ronald Drew |last7=Feschotte |first7=Cedric |last8=Pritham |first8=Ellen J. |last9=Kissinger |first9=Jessica C. |date=2023-11-07 |title=Massive invasion of organellar DNA drives nuclear genome evolution in Toxoplasma |journal=Proceedings of the National Academy of Sciences |volume=120 |issue=45 |pages=–2308569120 |bibcode=2023PNAS..12008569N |doi=10.1073/pnas.2308569120 |pmc=10636329 |pmid=37917792 }}</ref>
Almost all sequenced mitochondrial genomes of ciliates and apicomplexa are linear.<ref name="Barth2011">{{Cite journal |last1=Barth |first1=D |last2=Berendonk |first2=TU |year=2011 |title=The mitochondrial genome sequence of the ciliate ''Paramecium caudatum'' reveals a shift in nucleotide composition and codon usage within the genus ''Paramecium'' |journal=BMC Genomics |volume=12 |article-number=272 |doi=10.1186/1471-2164-12-272 |pmc=3118789 |pmid=21627782 |doi-access=free}}</ref> The mitochondria almost all carry [[mtDNA]] of their own but with greatly reduced genome sizes. Exceptions are ''[[Cryptosporidium]]'' which are left with only a [[mitosome]], the circular mitochondrial genomes of ''[[Acavomonas]]'' and ''[[Babesia microti]]'',<ref name="Obornik-Lukes-2015">{{Cite journal |last1=Oborník |first1=Miroslav |last2=Lukeš |first2=Julius |date=2015-10-15 |title=The Organellar Genomes of Chromera and Vitrella, the Phototrophic Relatives of Apicomplexan Parasites |url=https://www.annualreviews.org/content/journals/10.1146/annurev-micro-091014-104449 |journal=Annual Review of Microbiology |volume=69 |pages=129–144 |doi=10.1146/annurev-micro-091014-104449 |issn=0066-4227 |pmid=26092225 |access-date=2024-04-15|url-access=subscription }}</ref><ref name="Cornillot2012">{{Cite journal |vauthors=Cornillot E, Hadj-Kaddour K, Dassouli A, Noel B, Ranwez V, Vacherie B, Augagneur Y, Brès V, Duclos A, Randazzo S, Carcy B, Debierre-Grockiego F, Delbecq S, Moubri-Ménage K, Shams-Eldin H, Usmani-Brown S, Bringaud F, Wincker P, Vivarès CP, Schwarz RT, Schetters TP, Krause PJ, Gorenflot A, Berry V, Barbe V, Ben Mamoun C |year=2012 |title=Sequencing of the smallest Apicomplexan genome from the human pathogen ''Babesia microti'' |journal=Nucleic Acids Res. |volume=40 |issue=18 |pages=9102–14 |doi=10.1093/nar/gks700 |pmc=3467087 |pmid=22833609}}</ref> and ''[[Toxoplasma]]''<nowiki/>'s highly fragmented mitochondrial genome, consisting of 21 sequence blocks which recombine to produce longer segments.<ref>{{Cite journal |last1=Namasivayam |first1=Sivaranjani |last2=Baptista |first2=Rodrigo P. |last3=Xiao |first3=Wenyuan |last4=Hall |first4=Erica M. |last5=Doggett |first5=Joseph S. |last6=Troell |first6=Karin |last7=Kissinger |first7=Jessica C. |date=May 2021 |title=A novel fragmented mitochondrial genome in the protist pathogen Toxoplasma gondii and related tissue coccidia |journal=Genome Research |volume=31 |issue=5 |pages=852–865 |doi=10.1101/gr.266403.120 |pmc=8092004 |pmid=33906963}}</ref><ref>{{Cite journal |last1=Namasivayam |first1=Sivaranjani |last2=Sun |first2=Cheng |last3=Bah |first3=Assiatu B. |last4=Oberstaller |first4=Jenna |last5=Pierre-Louis |first5=Edwin |last6=Etheridge |first6=Ronald Drew |last7=Feschotte |first7=Cedric |last8=Pritham |first8=Ellen J. |last9=Kissinger |first9=Jessica C. |date=2023-11-07 |title=Massive invasion of organellar DNA drives nuclear genome evolution in Toxoplasma |journal=Proceedings of the National Academy of Sciences |volume=120 |issue=45 |pages=–2308569120 |bibcode=2023PNAS..12008569N |doi=10.1073/pnas.2308569120 |doi-access=free |pmc=10636329 |pmid=37917792 }}</ref>


==History==
==History==
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==Classification==
==Classification==
Alveolata include around nine major and minor groups. They are diverse in form, and are known to be related by various ultrastructural and genetic similarities:<ref name=Tikhonenkov14>{{cite journal | doi = 10.1371/journal.pone.0095467 | pmid=24740116 | pmc=3989336 | volume=9 | issue=4 | title=Description of ''Colponema vietnamica'' sp.n. and ''Acavomonas peruviana'' n. gen. n. sp., two new alveolate phyla (Colponemidia nom. nov. and Acavomonidia nom. nov.) and their contributions to reconstructing the ancestral state of alveolates and eukaryotes | year=2014 | journal=PLOS ONE | pages=e95467 | last1 = Tikhonenkov | first1 = DV | last2 = Janouškovec | first2 = J | last3 = Mylnikov | first3 = AP | last4 = Mikhailov | first4 = KV | last5 = Simdyanov | first5 = TG | last6 = Aleoshin | first6 = VV | last7 = Keeling | first7 = PJ| bibcode=2014PLoSO...995467T | doi-access=free }}</ref>
Alveolata include around nine major and minor groups. They are diverse in form, and are known to be related by various ultrastructural and genetic similarities:<ref name=Tikhonenkov14>{{cite journal | doi = 10.1371/journal.pone.0095467 | pmid=24740116 | pmc=3989336 | volume=9 | issue=4 | title=Description of ''Colponema vietnamica'' sp.n. and ''Acavomonas peruviana'' n. gen. n. sp., two new alveolate phyla (Colponemidia nom. nov. and Acavomonidia nom. nov.) and their contributions to reconstructing the ancestral state of alveolates and eukaryotes | year=2014 | journal=PLOS ONE | article-number=e95467 | last1 = Tikhonenkov | first1 = DV | last2 = Janouškovec | first2 = J | last3 = Mylnikov | first3 = AP | last4 = Mikhailov | first4 = KV | last5 = Simdyanov | first5 = TG | last6 = Aleoshin | first6 = VV | last7 = Keeling | first7 = PJ| bibcode=2014PLoSO...995467T | doi-access=free }}</ref>


*[[Ciliate]]s – very common protozoa with many short [[cilium|cilia]] arranged in rows, and two nuclei
*[[Ciliate]]s – very common protozoa with many short [[cilium|cilia]] arranged in rows, and two nuclei
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The Acavomonidia and Colponemidia were previously grouped together as colponemids, a taxon now split because each has a distinctive organization or [[ultrastructural identity]]. The Acavomonidia are closer to the dinoflagellate/perkinsid group than the Colponemidia are.<ref name=Tikhonenkov14/> As such, the informal term "colponemids", as it stands currently, covers two non-sister groups within Alveolata: the Acavomonidia and the Colponemidia.<ref name=Tikhonenkov14/>
The Acavomonidia and Colponemidia were previously grouped together as colponemids, a taxon now split because each has a distinctive organization or [[ultrastructural identity]]. The Acavomonidia are closer to the dinoflagellate/perkinsid group than the Colponemidia are.<ref name=Tikhonenkov14/> As such, the informal term "colponemids", as it stands currently, covers two non-sister groups within Alveolata: the Acavomonidia and the Colponemidia.<ref name=Tikhonenkov14/>


The Apicomplexa and dinoflagellates may be more closely related to each other than to the ciliates.  Both have [[plastid]]s, and most share a bundle or cone of [[microtubule]]s at the top of the cell.  In apicomplexans this forms part of a complex used to enter host cells, while in some colorless dinoflagellates it forms a peduncle used to ingest prey.  Various other genera are closely related to these two groups, mostly flagellates with a similar apical structure.  These include free-living members in ''[[Oxyrrhis]]'' and ''[[Colponema]]'', and parasites in ''[[Perkinsus marinus|Perkinsus]]'',<ref name=Zhang2011>{{cite journal | last1 = Zhang | first1 = H | last2 = Campbell | first2 = DA | last3 = Sturm | first3 = NR | last4 = Dungan | first4 = CF | last5 = Lin | first5 = S | year = 2011 | title = Spliced leader RNAs, mitochondrial gene frameshifts and multi-protein phylogeny expand support for the genus ''Perkinsus'' as a unique group of Alveolates | journal = PLOS ONE | volume = 6 | issue = 5| page = e19933 | doi=10.1371/journal.pone.0019933 | pmid=21629701 | pmc=3101222| bibcode = 2011PLoSO...619933Z | doi-access = free }}</ref> ''[[Parvilucifera]]'', ''[[Rastrimonas]]'' and the [[ellobiopsid]]s.  In 2001, direct amplification of the [[rRNA]] gene in marine [[picoplankton]] samples revealed the presence of two novel alveolate lineages, called group I and II.<ref>{{cite journal |vauthors=López-García P, Rodríguez-Valera F, Pedrós-Alió C, Moreira D |title=Unexpected diversity of small eukaryotes in deep-sea Antarctic plankton |journal=Nature |volume=409 |issue=6820 |pages=603–7 |year=2001 |pmid=11214316 |doi=10.1038/35054537 |bibcode=2001Natur.409..603L |s2cid=11550698 }}</ref><ref>{{cite journal |vauthors=Moon-van der Staay SY, De Wachter R, Vaulot D |title=Oceanic 18S rDNA sequences from picoplankton reveal unsuspected eukaryotic diversity |journal=Nature |volume=409 |issue=6820 |pages=607–10 |year=2001 |pmid=11214317 |doi=10.1038/35054541 |bibcode=2001Natur.409..607M |s2cid=4362835 }}</ref>  Group I has no cultivated relatives, while group II is related to the dinoflagellate parasite ''[[Amoebophrya]]'', which was classified until now in the [[Syndiniales]] dinoflagellate order.
The Apicomplexa and dinoflagellates may be more closely related to each other than to the ciliates.  Both have [[plastid]]s, and most share a bundle or cone of [[microtubule]]s at the top of the cell.  In apicomplexans this forms part of a complex used to enter host cells, while in some colorless dinoflagellates it forms a peduncle used to ingest prey.  Various other genera are closely related to these two groups, mostly flagellates with a similar apical structure.  These include free-living members in ''[[Oxyrrhis]]'' and ''[[Colponema]]'', and parasites in ''[[Perkinsus marinus|Perkinsus]]'',<ref name=Zhang2011>{{cite journal | last1 = Zhang | first1 = H | last2 = Campbell | first2 = DA | last3 = Sturm | first3 = NR | last4 = Dungan | first4 = CF | last5 = Lin | first5 = S | year = 2011 | title = Spliced leader RNAs, mitochondrial gene frameshifts and multi-protein phylogeny expand support for the genus ''Perkinsus'' as a unique group of Alveolates | journal = PLOS ONE | volume = 6 | issue = 5| article-number = e19933 | doi=10.1371/journal.pone.0019933 | pmid=21629701 | pmc=3101222| bibcode = 2011PLoSO...619933Z | doi-access = free }}</ref> ''[[Parvilucifera]]'', ''[[Rastrimonas]]'' and the [[ellobiopsid]]s.  In 2001, direct amplification of the [[rRNA]] gene in marine [[picoplankton]] samples revealed the presence of two novel alveolate lineages, called group I and II.<ref>{{cite journal |vauthors=López-García P, Rodríguez-Valera F, Pedrós-Alió C, Moreira D |title=Unexpected diversity of small eukaryotes in deep-sea Antarctic plankton |journal=Nature |volume=409 |issue=6820 |pages=603–7 |year=2001 |pmid=11214316 |doi=10.1038/35054537 |bibcode=2001Natur.409..603L |s2cid=11550698 }}</ref><ref>{{cite journal |vauthors=Moon-van der Staay SY, De Wachter R, Vaulot D |title=Oceanic 18S rDNA sequences from picoplankton reveal unsuspected eukaryotic diversity |journal=Nature |volume=409 |issue=6820 |pages=607–10 |year=2001 |pmid=11214317 |doi=10.1038/35054541 |bibcode=2001Natur.409..607M |s2cid=4362835 }}</ref>  Group I has no cultivated relatives, while group II is related to the dinoflagellate parasite ''[[Amoebophrya]]'', which was classified until now in the [[Syndiniales]] dinoflagellate order.


Some studies suggested the [[Ascetosporea|haplosporid]]s, mostly parasites of marine invertebrates, might belong here, but they lack alveoli and are now placed among the [[Cercozoa]].
Some studies suggested the [[Ascetosporea|haplosporid]]s, mostly parasites of marine invertebrates, might belong here, but they lack alveoli and are now placed among the [[Cercozoa]].


The ellobiopsids are of uncertain relation within the alveolates. Silberman et al 2004 establish that the ''[[Thalassomyces]]'' genus of ellobiopsids are alveolates using [[phylogenetic]] analysis, however {{as of|2016|lc=yes}} no more certainty exists on their place.<ref name="Hoppenrath-2016">{{cite journal | last=Hoppenrath | first=Mona | title=Dinoflagellate taxonomy — a review and proposal of a revised classification | journal=[[Marine Biodiversity]] | publisher=[[Senckenberg Institute]] ([[Springer Science+Business Media|Springer]]) | volume=47 | issue=2 | date=2016-04-29 | issn=1867-1616 | doi=10.1007/s12526-016-0471-8 | pages=381–403| s2cid=42100119 }}</ref><ref name="Taylor-2004">{{cite journal | last=Taylor | first=F. J. R. "Max" | title=Illumination or confusion? Dinoflagellate molecular phylogenetic data viewed from a primarily morphological standpoint | journal=[[Phycological Research]] | publisher=[[Japanese Society of Phycology]] ([[Wiley Publishing|Wiley]]) | volume=52 | issue=4 | year=2004 | issn=1322-0829 | doi=10.1111/j.1440-183.2004.00360.x | pages=308–324| s2cid=86797666 }}</ref>
The ellobiopsids are of uncertain relation within the alveolates. Silberman et al 2004 establish that the ''[[Thalassomyces]]'' genus of ellobiopsids are alveolates using [[phylogenetic]] analysis, however {{as of|2016|lc=yes}} no more certainty exists on their place.<ref name="Hoppenrath-2016">{{cite journal | last=Hoppenrath | first=Mona | title=Dinoflagellate taxonomy — a review and proposal of a revised classification | journal=[[Marine Biodiversity]] | publisher=[[Senckenberg Institute]] ([[Springer Science+Business Media|Springer]]) | volume=47 | issue=2 | date=2016-04-29 | issn=1867-1616 | doi=10.1007/s12526-016-0471-8 | pages=381–403| s2cid=42100119 }}</ref><ref name="Taylor-2004">{{cite journal | last=Taylor | first=F. J. R. "Max" | title=Illumination or confusion? Dinoflagellate molecular phylogenetic data viewed from a primarily morphological standpoint | journal=[[Phycological Research]] | publisher=[[Japanese Society of Phycology]] ([[Wiley Publishing|Wiley]]) | volume=52 | issue=4 | year=2004 | issn=1322-0829 | doi=10.1111/j.1440-183.2004.00360.x | pages=308–324| bibcode=2004PhycR..52..308T | s2cid=86797666 }}</ref>


===Phylogeny===
===Phylogeny===

Latest revision as of 16:28, 28 October 2025

Template:Short description Template:Cs1 config Template:Automatic taxobox

The alveolates are a group of protists, considered a major unranked clade[1] or superphylum[2] within Eukaryota. They are currently grouped with the Stramenopiles and Rhizaria among the protists with tubulocristate mitochondria into the SAR supergroup.

Characteristics

The most notable shared characteristic is the presence of cortical (near the surface) alveoli (sacs). These are flattened vesicles (sacs) arranged as a layer just under the membrane and supporting it, typically contributing to a flexible pellicle (thin skin). In armored dinoflagellates they may contain stiff plates. Alveolates have mitochondria with tubular cristae (invaginations), and cells often have pore-like intrusions through the cell surface. The group contains free-living and parasitic organisms, predatory flagellates, and photosynthetic organisms.

File:EM alveoli ciliate paramecium putrinum.jpg
Transmission electron micrograph of a thin section of the surface of the ciliate Paramecium putrinum, showing the alveoli (red arrows) under the cell surface

Almost all sequenced mitochondrial genomes of ciliates and apicomplexa are linear.[3] The mitochondria almost all carry mtDNA of their own but with greatly reduced genome sizes. Exceptions are Cryptosporidium which are left with only a mitosome, the circular mitochondrial genomes of Acavomonas and Babesia microti,[4][5] and Toxoplasma's highly fragmented mitochondrial genome, consisting of 21 sequence blocks which recombine to produce longer segments.[6][7]

History

The relationship of apicomplexa, dinoflagellates and ciliates had been suggested during the 1980s, and this was confirmed in the early 1990s by comparisons of ribosomal RNA sequences, most notably by Gajadhar et al.[8] Cavalier-Smith introduced the formal name Alveolata in 1991,[9] although at the time he considered the grouping to be a paraphyletic assemblage. Many biologists prefer the use of the colloquial name 'alveolate'.[10]

Classification

Alveolata include around nine major and minor groups. They are diverse in form, and are known to be related by various ultrastructural and genetic similarities:[11]

The Acavomonidia and Colponemidia were previously grouped together as colponemids, a taxon now split because each has a distinctive organization or ultrastructural identity. The Acavomonidia are closer to the dinoflagellate/perkinsid group than the Colponemidia are.[11] As such, the informal term "colponemids", as it stands currently, covers two non-sister groups within Alveolata: the Acavomonidia and the Colponemidia.[11]

The Apicomplexa and dinoflagellates may be more closely related to each other than to the ciliates. Both have plastids, and most share a bundle or cone of microtubules at the top of the cell. In apicomplexans this forms part of a complex used to enter host cells, while in some colorless dinoflagellates it forms a peduncle used to ingest prey. Various other genera are closely related to these two groups, mostly flagellates with a similar apical structure. These include free-living members in Oxyrrhis and Colponema, and parasites in Perkinsus,[12] Parvilucifera, Rastrimonas and the ellobiopsids. In 2001, direct amplification of the rRNA gene in marine picoplankton samples revealed the presence of two novel alveolate lineages, called group I and II.[13][14] Group I has no cultivated relatives, while group II is related to the dinoflagellate parasite Amoebophrya, which was classified until now in the Syndiniales dinoflagellate order.

Some studies suggested the haplosporids, mostly parasites of marine invertebrates, might belong here, but they lack alveoli and are now placed among the Cercozoa.

The ellobiopsids are of uncertain relation within the alveolates. Silberman et al 2004 establish that the Thalassomyces genus of ellobiopsids are alveolates using phylogenetic analysis, however Template:As of no more certainty exists on their place.[15][16]

Phylogeny

In 2017, Thomas Cavalier-Smith described the phylogeny of the Alveolata as follows:[17]

Template:Clade

Taxonomy

Alveolata Cavalier-Smith 1991 [Alveolatobiontes]

  • Phylum Ciliophora Doflein 1901 stat. n. Copeland 1956 [Ciliata Perty 1852; Infusoria Bütschli 1887; Ciliae, Ciliozoa, Cytoidea, Eozoa, Heterocaryota, Heterokaryota]
  • Phylum Miozoa Cavalier-Smith 1987
    • Subphylum Colponemidia Tikhonenkov, Mylnikov & Keeling 2013
    • Subphylum Acavomonadia Tikhonenkov et al. 2014
    • Subphylum Myzozoa Cavalier-Smith 2004
      • Infraphylum Apicomplexa Levine 1970 emend. Adl et al. 2005
      • Infraphylum Dinozoa Cavalier-Smith 1981 emend. 2003
        • Order ?Acrocoelida Cavalier-Smith & Chao 2004
        • Order ?Rastromonadida Cavalier-Smith & Chao 2004
        • Class Squirmidea Norén 1999 stat. nov. Cavalier-Smith 2014
        • Superclass Perkinsozoa Norén et al. 1999 s.s.
          • Class Perkinsea Levine 1978 [Perkinsasida Levine 1978]
        • Superclass Dinoflagellata Butschli 1885 stat. nov. Cavalier-Smith 1999 sensu Cavalier-Smith 2013 [Dinozoa Cavalier-Smith 1981]
          • Class Pronoctilucea
          • Class Ellobiopsea Cavalier-Smith 1993 [Ellobiophyceae Loeblich III 1970; Ellobiopsida Whisler 1990]
          • Class Myzodinea Cavalier-Smith 2017
          • Class Oxyrrhea Cavalier-Smith 1987
          • Class Syndinea Chatton 1920 s.l. [Syndiniophyceae Loeblich III 1970 s.s.; Syndina Cavalier-Smith]
          • Class Endodinea Cavalier-Smith 2017
          • Class Noctiluciphyceae Fensome et al. 1993 [Noctilucae Haeckel 1866; Noctilucea Haeckel 1866 stat. nov.; Cystoflagellata Haeckel 1873 stat. nov. Butschli 1887]
          • Class Dinophyceae Pascher 1914 [Peridinea Ehrenberg 1830 stat. nov. Wettstein]

Development

The development of plastids among the alveolates is intriguing. Cavalier-Smith proposed the alveolates developed from a chloroplast-containing ancestor, which also gave rise to the Chromista (the chromalveolate hypothesis). Other researchers have speculated that the alveolates originally lacked plastids and possibly the dinoflagellates and Apicomplexa acquired them separately. However, it now appears that the alveolates, the dinoflagellates, the Chromerida and the heterokont algae acquired their plastids from a red alga with evidence of a common origin of this organelle in all these four clades.[18]

Evolution

A Bayesian estimate places the evolution of the alveolate group at ~Template:Ma.[19] The Alveolata consist of Myzozoa, Ciliates, and Colponemids. In other words, the term Myzozoa, meaning "to siphon the contents from prey", may be applied informally to the common ancestor of the subset of alveolates that are neither ciliates nor colponemids. Predation upon algae is an important driver in alveolate evolution, as it can provide sources for endosymbiosis of novel plastids. The term Myzozoa is therefore a handy concept for tracking the history of the alveolate phylum.

The ancestors of the alveolate group may have been photosynthetic.[20] The ancestral alveolate probably possessed a plastid. Chromerids, apicomplexans, and peridinin dinoflagellates have retained this organelle.[21] Going one step even further back, the chromerids, the peridinin dinoflagellates and the heterokont algae have been argued to possess a monophyletic plastid lineage in common, i.e. acquired their plastids from a red alga,[18] and so it seems likely that the common ancestor of alveolates and heterokonts was also photosynthetic.

In one school of thought the common ancestor of the dinoflagellates, apicomplexans, Colpodella, Chromerida, and Voromonas was a myzocytotic predator with two heterodynamic flagella, micropores, trichocysts, rhoptries, micronemes, a polar ring and a coiled open sided conoid.[22] While the common ancestor of alveolates may also have possessed some of these characteristics, it has been argued that Myzocytosis was not one of these characteristics, as ciliates ingest prey by a different mechanism.[11]

An ongoing debate concerns the number of membranes surrounding the plastid across apicomplexans and certain dinoflagellates, and the origin of these membranes. This ultrastructural character can be used to group organisms and if the character is in common, it can imply that phyla had a common photosynthetic ancestor. On the basis that apicomplexans possess a plastid surrounded by four membranes, and that peridinin dinoflagellates possess a plastid surrounded by three membranes, Petersen et al.[23] have been unable to rule out that the shared stramenopile-alveolate plastid could have been recycled multiple times in the alveolate phylum, the source being stramenopile-alveolate donors, through the mechanism of ingestion and endosymbiosis.

Ciliates are a model alveolate, having been genetically studied in great depth over the longest period of any alveolate lineage. They are unusual among eukaryotes in that reproduction involves a micronucleus and a macronucleus. Their reproduction is easily studied in the lab, and made them a model eukaryote historically. Being entirely predatory and lacking any remnant plastid, their development as a phylum illustrates how predation and autotrophy[20] are in dynamic balance and that the balance can swing one way or other at the point of origin of a new phylum from mixotrophic ancestors, causing one ability to be lost.

Epigenetics

Few algae have been studied for epigenetics.[24] Those for which epigenetic data are available include some algal alveolates.[24]

References

Template:Reflist

External links

Template:Sister project

Template:Eukaryota Template:Alveolata Template:Chromalveolate diseases Template:Taxonbar

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