An ancestral bacterial division system is widespread in eukaryotic mitochondria

Leger, Michelle M.; Petrů, Markéta; Žárský, Vojtěch; Eme, Laura; Vlček, Čestmı́r; Harding, Tommy; Lang, B. Franz; Eliáš, Marek; Doležal, Pavel; Roger, Andrew J.

doi:10.1073/pnas.1421392112

Cited by 70 publications

(60 citation statements)

References 89 publications

(62 reference statements)

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“…The most widespread eukaryotic organelle with bacterial ancestry is the mitochondrion. An extensive set of organellar functions are clearly of direct ancestry from α-proteobacteria, including organelle maintenance and replication (Leger et al, 2015), much of aerobic energy metabolism (Müller et al, 2012, as well as others) and even some recent surprises about organelle morphology, such as the mitochondrial contact site (MICOS) complex that is responsible for cristae formation (Muñoz-Gómez et al, 2016). The α-proteobacterial contribution can also be seen in other processes, such as in Fe-S cluster formation (Barberà et al, 2010), β-oxidation of fatty acids (Bolte et al, 2015), the glycine cleavage system (Nývltová et al, 2015) and hemebiosynthesis (Cenci et al, 2016).…”

Section: Towards Revealing the Prokaryotic Origins Of Eukaryotic Cellmentioning

confidence: 99%

The changing view of eukaryogenesis – fossils, cells, lineages and how they all come together

Dacks

Field

Buick

et al. 2016

Journal of Cell Science

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Eukaryogenesis -the emergence of eukaryotic cells -represents a pivotal evolutionary event. With a fundamentally more complex cellular plan compared to prokaryotes, eukaryotes are major contributors to most aspects of life on Earth. For decades, we have understood that eukaryotic origins lie within both the Archaea domain and α-Proteobacteria. However, it is much less clear when, and from which precise ancestors, eukaryotes originated, or the order of emergence of distinctive eukaryotic cellular features. Many competing models for eukaryogenesis have been proposed, but until recently, the absence of discriminatory data meant that a consensus was elusive. Recent advances in paleogeology, phylogenetics, cell biology and microbial diversity, particularly the discovery of the 'Candidatus Lokiarcheaota' phylum, are now providing new insights into these aspects of eukaryogenesis. The new data have allowed the time frame during which eukaryogenesis occurred to be finessed, a more precise identification of the contributing lineages and the biological features of the contributors to be clarified. Considerable advances have now been used to pinpoint the prokaryotic origins of key eukaryotic cellular processes, such as intracellular compartmentalisation, with major implications for models of eukaryogenesis.

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Section: Towards Revealing the Prokaryotic Origins Of Eukaryotic Cellmentioning

confidence: 99%

The changing view of eukaryogenesis – fossils, cells, lineages and how they all come together

Dacks

Field

Buick

et al. 2016

Journal of Cell Science

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“…The bacterial divisome complex, which is built around the polymers of a tubulin ortholog, the GTPase FtsZ, has been entirely replaced in the mitochondria of many eukaryote lineages by proteins of the dynamin superfamily [17]; yet, eukaryotes that have preserved the original FtsZ-based machinery can still be found in all eukaryotic supergroups [18, 19]. …”

Section: Introductionmentioning

confidence: 99%

Giardia intestinalis mitosomes undergo synchronized fission but not fusion and are constitutively associated with the endoplasmic reticulum

et al. 2017

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BackgroundMitochondria of opisthokonts undergo permanent fission and fusion throughout the cell cycle. Here, we investigated the dynamics of the mitosomes, the simplest forms of mitochondria, in the anaerobic protist parasite Giardia intestinalis, a member of the Excavata supergroup of eukaryotes. The mitosomes have abandoned typical mitochondrial traits such as the mitochondrial genome and aerobic respiration and their single role known to date is the formation of iron–sulfur clusters.ResultsIn live experiments, no fusion events were observed between the mitosomes in G. intestinalis. Moreover, the organelles were highly prone to becoming heterogeneous. This suggests that fusion is either much less frequent or even absent in mitosome dynamics. Unlike in mitochondria, division of the mitosomes was absolutely synchronized and limited to mitosis. The association of the nuclear and the mitosomal division persisted during the encystation of the parasite. During the segregation of the divided mitosomes, the subset of the organelles between two G. intestinalis nuclei had a prominent role. Surprisingly, the sole dynamin-related protein of the parasite seemed not to be involved in mitosomal division. However, throughout the cell cycle, mitosomes associated with the endoplasmic reticulum (ER), although none of the known ER-tethering complexes was present. Instead, the ER–mitosome interface was occupied by the lipid metabolism enzyme long-chain acyl-CoA synthetase 4.ConclusionsThis study provides the first report on the dynamics of mitosomes. We show that together with the loss of metabolic complexity of mitochondria, mitosomes of G. intestinalis have uniquely streamlined their dynamics by harmonizing their division with mitosis. We propose that this might be a strategy of G. intestinalis to maintain a stable number of organelles during cell propagation. The lack of mitosomal fusion may also be related to the secondary reduction of the organelles. However, as there are currently no reports on mitochondrial fusion in the whole Excavata supergroup, it is possible that the absence of mitochondrial fusion is an ancestral trait common to all excavates.Electronic supplementary materialThe online version of this article (doi:10.1186/s12915-017-0361-y) contains supplementary material, which is available to authorized users.

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“…Miyagishima et al (4) concluded that FtsZ2 in green plants and algae and FtsZA in red algae descended from the original single FtsZ from the cyanobacterium and that FtsZ1 and FtsZB arose by separate gene duplications. There is a similar duplication of FtsZ in the mitochondria that have kept FtsZ, one with and one without the C-terminal peptide (4,19). As in Arabidopsis, the FtsZ with the C-terminal peptide may interact with a membrane protein to tether the Z ring, whereas the one without may play a regulatory role.…”

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confidence: 98%

The Chloroplast Tubulin Homologs FtsZA and FtsZB from the Red Alga Galdieria sulphuraria Co-assemble into Dynamic Filaments

Chen

Porter

Osawa

et al. 2017

Journal of Biological Chemistry

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Edited by Velia M. FowlerFtsZ is a homolog of eukaryotic tubulin and is present in almost all bacteria and many archaea, where it is the major cytoskeletal protein in the Z ring, required for cell division. Unlike some other cell organelles of prokaryotic origin, chloroplasts have retained FtsZ as an essential component of the division machinery. However, chloroplast FtsZs have been challenging to study because they are difficult to express and purify. To this end, we have used a FATT tag expression system to produce as soluble proteins the two chloroplast FtsZs from Galdieria sulphuraria, a thermophilic red alga. GsFtsZA and GsFtsZB assembled individually in the presence of GTP, forming large bundles of protofilaments. GsFtsZA also assembled in the presence of GDP, the first member of the FtsZ/tubulin superfamily to do so. Mixtures of GsFtsZA and GsFtsZB assembled protofilament bundles and hydrolyzed GTP at a rate approximately equal to the sum of their individual rates, suggesting a random co-assembly. GsFtsZA assembly by itself in limiting GTP gave polymers that remained stable for a prolonged time. However, when GsFtsZB was added, the co-polymers disassembled with enhanced kinetics, suggesting that the GsFtsZB regulates and enhances disassembly dynamics. GsFtsZA-mts (where mts is a membrane-targeting amphipathic helix) formed Z ring-like helices when expressed in Escherichia coli. Co-expression of GsFtsZB (without an mts) gave co-assembly of both into similar helices. In summary, we provide biochemical evidence that GsFtsZA assembles as the primary scaffold of the chloroplast Z ring and that GsFtsZB co-assembly enhances polymer disassembly and dynamics.

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An ancestral bacterial division system is widespread in eukaryotic mitochondria

Cited by 70 publications

References 89 publications

The changing view of eukaryogenesis – fossils, cells, lineages and how they all come together

The changing view of eukaryogenesis – fossils, cells, lineages and how they all come together

Giardia intestinalis mitosomes undergo synchronized fission but not fusion and are constitutively associated with the endoplasmic reticulum

The Chloroplast Tubulin Homologs FtsZA and FtsZB from the Red Alga Galdieria sulphuraria Co-assemble into Dynamic Filaments

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