2006
DOI: 10.1080/09670260600961080
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Did the peridinin plastid evolve through tertiary endosymbiosis? A hypothesis

Abstract: Most photosynthetic dinoflagellates harbour the peridinin plastid. This plastid is surrounded by three membranes and its characteristic pigments are chlorophyll c and the carotenoid peridinin. The evolutionary origin of this peculiar plastid remains controversial and is hotly debated. On the recently published tree of concatenated plastid-encoded proteins, dinoflagellates emerge from within the Chromista (clade containing cryptophytes, heterokonts, and haptophytes) and cluster specifically with Heterokonta. Th… Show more

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Cited by 41 publications
(26 citation statements)
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“…The outermost (third) membrane of euglenoid plastids has the ability to fuse with vesicles budding from Golgi apparatus containing chloroplast precursor proteins (Sulli et al 1999), suggesting that it is homologous with the former phagosomal membrane and that algal plasma membrane has been lost (Cavalier-Smith 1999. Alternatively, myzocytic engulfment of algal chloroplasts (acquisition of algal cytoplasm with chloroplasts but not the whole algal cell; see Gibbs 1978;Tengs et al 2000;Bodył 2005;Bodył and Moszczyński 2006) by the ancestor of plastid-bearing euglenids may have resulted directly in plastids bounded by three membranes without any need to infer subsequent membrane loss.…”
Section: Origin Of Chlorarachnean and Euglenoid Plastidsmentioning
confidence: 97%
“…The outermost (third) membrane of euglenoid plastids has the ability to fuse with vesicles budding from Golgi apparatus containing chloroplast precursor proteins (Sulli et al 1999), suggesting that it is homologous with the former phagosomal membrane and that algal plasma membrane has been lost (Cavalier-Smith 1999. Alternatively, myzocytic engulfment of algal chloroplasts (acquisition of algal cytoplasm with chloroplasts but not the whole algal cell; see Gibbs 1978;Tengs et al 2000;Bodył 2005;Bodył and Moszczyński 2006) by the ancestor of plastid-bearing euglenids may have resulted directly in plastids bounded by three membranes without any need to infer subsequent membrane loss.…”
Section: Origin Of Chlorarachnean and Euglenoid Plastidsmentioning
confidence: 97%
“…The alternative view is that subsequent to a single red algal secondary endosymbiosis, perhaps in an ancestor of cryptophyte algae, one or more cryptic 'tertiary' endosymbiotic events served to spread this red algal-derived plastid further afield (e.g., [101][102][103][104]). This model takes into account discrepancies between the host-and organelle-associated features of the organisms in question, including the relative strength of phylogenetic signals in their nuclear, mitochondrial and plastid genomes [105].…”
Section: Eukaryotic Photosynthesis: Origin and Spreadmentioning
confidence: 98%
“…Their secondary plastid, called the peridinin plastid, is distinguished by the pigment peridinin and by three bounding membranes rather than the four common to most secondary plastids (see Falkowski et al 2004;Yoon et al 2005 for a review). However, other hypotheses suggest that the peridinin plastid evolved from a heterokont alga through a tertiary endosymbiosis (Body" and Moszczyń ski 2006). Dinoflagellates are unique among eukaryotic algae in that they have taken the process of endosymbiosis one step further, since in several independent lineages the peridinin plastid has been replaced either with a successive secondary plastid or with a plastid from another secondary alga, resulting in tertiary plastids.…”
Section: Introductionmentioning
confidence: 99%