What makes a chloroplast? Reconstructing the establishment of photosynthetic symbioses

Dorrell, Richard G.; Howe, Christopher J.

doi:10.1242/jcs.102285

Cited by 68 publications

(70 citation statements)

References 108 publications

(157 reference statements)

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“…In such a highly divergent chloroplast system, a concerted transcriptediting and polyuridylylation pathway might correct otherwise potentially deleterious mutations in genome sequence, for example, by converting premature termination codons to coding sequence, as in the case of the K. mikimotoi psaA transcript (Dataset S2). If the fast sequence evolution observed in dinoflagellate chloroplasts is a feature of the host, the superimposition of ancestral chloroplast transcript-processing pathways on replacement chloroplasts could be an important step in the replacement, allowing the new lineage to tolerate a host environment that might otherwise prove disadvantageous (2,19).…”

Section: Discussionmentioning

confidence: 99%

“…organelle | fucoxanthin | haptophyte | poly(U) | alveolate C hloroplasts originate through endosymbiosis, in which a freeliving photosynthetic symbiont is taken up by a eukaryotic host, with processes becoming established within the host to support the biogenesis and maintenance of the symbiont (1,2). It has long been understood that many such endosymbiotic events have occurred across the eukaryotes, giving rise to a diverse array of extant chloroplast lineages (2)(3)(4).…”

mentioning

confidence: 99%

“…It has long been understood that many such endosymbiotic events have occurred across the eukaryotes, giving rise to a diverse array of extant chloroplast lineages (2)(3)(4). Genomic and phylogenetic evidence has suggested that several major chloroplast-containing lineages have replaced their original chloroplasts with others derived from a different evolutionary lineage in a process termed "serial endosymbiosis of chloroplasts" (2,5). The best-supported examples of chloroplast replacement are found within the dinoflagellate algae, within which at least three distinct chloroplast replacement events are known to have occurred (2,6,7).…”

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confidence: 99%

“…Genomic and phylogenetic evidence has suggested that several major chloroplast-containing lineages have replaced their original chloroplasts with others derived from a different evolutionary lineage in a process termed "serial endosymbiosis of chloroplasts" (2,5). The best-supported examples of chloroplast replacement are found within the dinoflagellate algae, within which at least three distinct chloroplast replacement events are known to have occurred (2,6,7). Two even more dramatic hypotheses of chloroplast replacement have recently been put forward.…”

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confidence: 99%

“…It is well understood that processes originating in the host play important roles in chloroplast biogenesis and maintenance (2,20,21). This raises the question whether processes established during an earlier chloroplast symbiosis could be retained through serial endosymbiosis and contribute to the function of the replacement chloroplast.…”

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Functional remodeling of RNA processing in replacement chloroplasts by pathways retained from their predecessors

Dorrell

Howe

2012

Proc. Natl. Acad. Sci. U.S.A.

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Chloroplasts originate through the endosymbiotic integration of a host and a photosynthetic symbiont, with processes established within the host for the biogenesis and maintenance of the nascent chloroplast. It is thought that several photosynthetic eukaryotes have replaced their original chloroplasts with others derived from different source organisms in a process termed "serial endosymbiosis of chloroplasts." However, it is not known whether replacement chloroplasts are affected by the biogenesis and maintenance pathways established to support their predecessors. Here, we investigate whether pathways established during a previous chloroplast symbiosis function in the replacement chloroplasts of the dinoflagellate alga Karenia mikimotoi. We show that chloroplast transcripts in K. mikimotoi are subject to 3′ polyuridylylation and extensive sequence editing. We confirm that these processes do not occur in free-living relatives of the replacement chloroplast lineage, but are otherwise found only in the ancestral, red algalderived chloroplasts of dinoflagellates and their closest relatives. This indicates that these unusual RNA-processing pathways have been retained from the original symbiont lineage and made use of by the replacement chloroplast. Our results constitute an addition to current theories of chloroplast evolution in which chloroplast biogenesis may be radically remodeled by pathways remaining from previous symbioses.organelle | fucoxanthin | haptophyte | poly(U) | alveolate

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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Functional remodeling of RNA processing in replacement chloroplasts by pathways retained from their predecessors

Dorrell

Howe

2012

Proc. Natl. Acad. Sci. U.S.A.

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Chloroplastic ascorbate peroxidases targeted to stroma or thylakoid membrane: The chicken or egg dilemma

et al. 2022

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Ascorbate peroxidases (APXs) are heme peroxidases that remove hydrogen peroxide in different subcellular compartments with concomitant ascorbate cycling. Here, we analysed and discussed phylogenetic and molecular features of the APX family. Ancient APX originated as a soluble stromal enzyme, and early during plant evolution, acquired both chloroplast‐targeting and mitochondrion‐targeting sequences and an alternative splicing mechanism whereby it could be expressed as a soluble or thylakoid membrane‐bound enzyme. Later, independent duplication and neofunctionalization events in some angiosperm groups resulted in individual genes encoding stromal, thylakoidal and mitochondrial isoforms. These data reaffirm the complexity of plant antioxidant defenses that allow diverse plant species to acquire new means to adapt to changing environmental conditions.

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Chloroplast Genome

Howe

2016

Encyclopedia of Life Sciences

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Chloroplasts contain a genome that is a relic of the endosymbiont that gave rise to the organelle. These genomes typically contain 100–200 genes and encode proteins important for photosynthesis and other chloroplast functions, although dinoflagellate algae have a greatly reduced and fragmented chloroplast genome. Many, but not all, nonphotosynthetic taxa retain a remnant chloroplast genome. In some organisms the chloroplast genome may be retained to allow redox‐mediated control of gene expression, whereas in others it may continue to exist because transfer of essential genes to the nucleus is no longer possible. Multiple ribonucleic acid (RNA) polymerases are involved in chloroplast transcription in land plants, and post‐transcriptional processing involving nuclear‐encoded RNA‐binding proteins also plays an important part in the expression of the chloroplast genome. Gene expression may be regulated at a number of levels, and redox poise in the organelle may be particularly important for this. Key Concepts Chloroplasts originated in the ancestor of plants and red and green algae by endosymbiotic acquisition of a cyanobacterium, and then spread to many other eukaryotic lineages. There are other examples of stable acquisition of a cyanobacterium by a nonphotosynthetic host. Chloroplast genomes are typically 100–200 kbp in size, and include a set of genes for proteins essential to photosynthesis. Other genes present in the ancestral symbiont have been lost or relocated to the nucleus. Many nonphotosynthetic organisms retain remnant chloroplasts, with genomes, reflecting the fact that photosynthesis is not the only biochemical process that takes place in the chloroplast. In many organisms, gene transfer from chloroplast to nucleus can still take place, at an unexpectedly high frequency. Establishment of the chloroplast has resulted in the development of nuclear‐encoded RNA‐binding protein families and, in land plants, additional RNA polymerases that play a central role in chloroplast gene expression. Post‐transcriptional RNA processing plays an important role in chloroplast gene expression. In photosynthetic organisms, chloroplast gene expression is closely linked to the organelle's redox poise. The chloroplast can also influence the expression of nuclear genes.

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What makes a chloroplast? Reconstructing the establishment of photosynthetic symbioses

Cited by 68 publications

References 108 publications

Functional remodeling of RNA processing in replacement chloroplasts by pathways retained from their predecessors

Functional remodeling of RNA processing in replacement chloroplasts by pathways retained from their predecessors

Chloroplastic ascorbate peroxidases targeted to stroma or thylakoid membrane: The chicken or egg dilemma

Chloroplast Genome

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