Abstract
Chloroplasts (plastids) and mitochondria evolved from endosymbiotic bacteria. These organelles perform vital functions in photosynthetic eukaryotes, such as harvesting and converting energy for use in biological processes. Consistent with their evolutionary origins, plastids and mitochondria proliferate by the binary fission of pre-existing organelles. Here, I review the structures and functions of the supramolecular machineries driving plastid and mitochondrial division, which were discovered and first studied in the primitive red alga Cyanidioschyzon merolae. In the past decade, intact division machineries have been isolated from plastids and mitochondria and examined to investigate their underlying structure and molecular mechanisms. A series of studies has elucidated how these division machineries assemble and transform during the fission of these organelles, and which of the component proteins generate the motive force for their contraction. Plastid- and mitochondrial-division machineries have important similarities in their structures and mechanisms despite sharing no component proteins, implying that these division machineries evolved in parallel. The establishment of these division machineries might have enabled the host eukaryotic ancestor to permanently retain these endosymbiotic organelles by regulating their binary fission and the equal distribution of resources to daughter cells. These findings provide key insights into the establishment of endosymbiotic organelles and have opened new avenues of research into their evolution and mechanisms of proliferation.
Highlights
Chloroplasts generate organic molecules and oxygen by photosynthesis (Jarvis and López-Juez 2013), a process which, over the past billion years, resulted in the greening of the Earth
These organelles are not produced de novo; their proliferation involves the binary division of pre-existing organelles; this division is carried out by specialized ring structures known as the plastid division machinery and the mitochondrial division machinery
The proteins responsible for the assembly of the PD and mediated EOD ring (MD ring) have not been fully elucidated, our recent studies in the unicellular alga Cyanidioschyzon merolae revealed that the glycosyltransferase proteins PLASTIDDIVIDING RING1 (PDR1) and MITOCHONDRIONDIVIDING RING1 (MDR1) are involved in the assembly of the PD and MD rings, respectively (Yoshida et al 2010, 2017)
Summary
Chloroplasts generate organic molecules and oxygen by photosynthesis (Jarvis and López-Juez 2013), a process which, over the past billion years, resulted in the greening of the Earth. The dynamin ring is a disconnected ring-like structure formed of a dynamin superfamily member protein on the cytosolic surface of the outer envelope membrane at the organelle division site (Miyagishima et al 2003a; Osteryoung and Nunnari 2003).
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