A common red algal origin of the apicomplexan, dinoflagellate, and heterokont plastids

Janouškovec, Jan; Horák, Aleš; Oborník, Miroslav; Lukeš, Julius; Keeling, Patrick J.

doi:10.1073/pnas.1003335107

Cited by 419 publications

(470 citation statements)

References 43 publications

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“…These photosynthetic algae are closely related to apicomplexan parasites and share various morphological and molecular characteristics with them. Former phylogenetic analysis strongly and consistently supported it; they either form two distinct lineages with V. brassicaformis more closely related to apicomplexans (Janouškovec et al 2010) or are sisters to them (Woo et al 2015). According to the present analysis, one of the apicortin paralogs in both species, Vbra_15441 from V. brassicaformis and Cvel_6797 from C. velia, is sister to apicomplexan orthologs.…”

Section: Chromerid Apicortinssupporting

confidence: 71%

Wider than Thought Phylogenetic Occurrence of Apicortin, A Characteristic Protein of Apicomplexan Parasites

Orosz

2016

J Mol Evol

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Section: Chromerid Apicortinssupporting

confidence: 71%

Wider than Thought Phylogenetic Occurrence of Apicortin, A Characteristic Protein of Apicomplexan Parasites

Orosz

2016

J Mol Evol

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“…Secondary and tertiary endosymbiosis involving both red and green algae are further responsible for the evolution of a number of additional photosynthetic eukaryotic lineages [107][108][109]. Secondary endosymbiogenetic organisms contain at least four separate genomic compartments: nucleus, mitochondrion, plastid and nucleomorph (the former nucleus of the endosymbiotic alga).…”

Section: Symbiogenesismentioning

confidence: 99%

How life changes itself: The Read–Write (RW) genome

Shapiro

2013

Physics of Life Reviews

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The genome has traditionally been treated as a Read-Only Memory (ROM) subject to change by copying errors and accidents. In this review, I propose that we need to change that perspective and understand the genome as an intricately formatted Read-Write (RW) data storage system constantly subject to cellular modifications and inscriptions. Cells operate under changing conditions and are continually modifying themselves by genome inscriptions. These inscriptions occur over three distinct time-scales (cell reproduction, multicellular development and evolutionary change) and involve a variety of different processes at each time scale (forming nucleoprotein complexes, epigenetic formatting and changes in DNA sequence structure). Research dating back to the 1930s has shown that genetic change is the result of cell-mediated processes, not simply accidents or damage to the DNA. This cell-active view of genome change applies to all scales of DNA sequence variation, from point mutations to large-scale genome rearrangements and whole genome duplications (WGDs). This conceptual change to active cell inscriptions controlling RW genome functions has profound implications for all areas of the life sciences.

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“…In spite of numerous publications, the debate continues (cf. in Green 2010;Baurian et al 2010;Deschamps and Moreira 2009;Janouškovec et al 2010;Keeling 2010;Nozaki et al 2009;Ryes-Prieto et al 2008;Stiller 2007 was one chloroplast origin, and if so, what was the most likely host, i.e., is there only one Cinderella slipper and where is the best fit? Some unambiguous structural signs of symbiotic and/or endosymbiotic events were found some years ago when Gibbs (1981) provided significant examples showing that some chloroplasts had two limiting membranes (green and red algae), others were surrounded by three membranes (euglenids, dinoflagellates), while still others had four chloroplast membranes (browns, diatoms, cryptophytes) usually with an additional set of ribosomes on the ''chloroplast endoplasmic reticulum.''…”

Section: Distribution Of Chloroplasts: Finding Cinderella's Slippermentioning

confidence: 99%

“…Nevertheless, the group has been at the center of the chloroplast dispersion controversy mostly because it has been placed as endosymbiont at the base of the chromalveolates, argued to be a monophyletic evolutionary group (Cavalier-Smith 2002;cf. Green 2010;Janouškovec et al 2010). The chromalveolates are a diverse grouping distinguished by: the presence of Chl a plus Chl c, carotenoid-type fucoxanthin or peridinin, having ciliated or flagellated hosts, and by some un-pigmented members having presumably lost a once functioning integrated chloroplast.…”

Section: Red Algal Lineagementioning

confidence: 99%

Oxygenic photosynthesis and the distribution of chloroplasts

Gantt

2010

Photosynth Res

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The integrated functioning of two photosystems (I and II) whether in cyanobacteria or in chloroplasts is the outstanding sign of a common ancestral origin. Many variations on the basic theme are currently evident in oxygenic photosynthetic organisms whether they are prokaryotes, unicellular, or multicellular. By conservative estimates, oxygenic photosynthesis has been around for at least ca. 2.2-2.7 billions years, consistent with cyanobacteria-type microfossils, biomarkers, and an atmospheric rise in oxygen to less than 1.0% of the present concentration. The presumptions of chloroplast formation by the cyanobacterial uptake into a eukaryote prior to 1.6 BYa ago are confounded by assumptions of host type(s) and potential tolerance of oxygen toxicity. The attempted dating and interrelationships of particular chloroplasts in various plant or animal lineages has relied heavily on phylogenomic analysis and evaluations that have been difficult to confirm separately. Many variations occur in algal groups, involving the type and number of accessory pigments, and the number(s) of membranes (2-4) enclosing a chloroplast, which can both help and complicate inferences made about early or late origins of chloroplasts. Integration of updated phylogenomics with physiological and cytological observations remains a special challenge, but could lead to more accurate assumptions of initial and extant endosymbiotic event(s) leading toward stable chloroplast associations.

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A common red algal origin of the apicomplexan, dinoflagellate, and heterokont plastids

Cited by 419 publications

References 43 publications

Wider than Thought Phylogenetic Occurrence of Apicortin, A Characteristic Protein of Apicomplexan Parasites

Wider than Thought Phylogenetic Occurrence of Apicortin, A Characteristic Protein of Apicomplexan Parasites

How life changes itself: The Read–Write (RW) genome

Oxygenic photosynthesis and the distribution of chloroplasts

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