Structure of the yeast F
            <sub>1</sub>
            F
            <sub>o</sub>
            -ATP synthase dimer and its role in shaping the mitochondrial cristae

Davies, Karen M.; Anselmi, Claudio; Wittig, Ilka; Faraldo‐Gómez, José D.; Kühlbrandt, Werner

doi:10.1073/pnas.1204593109

Cited by 427 publications

(540 citation statements)

References 51 publications

(79 reference statements)

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“…We have shown previously that the formation of inner-membrane cristae depends on the presence of ATP synthase dimers (6). Computer simulations indicate that the dimers induce membrane curvature, and not that, conversely, membrane curvature induces dimer formation (6).…”

Section: Resultsmentioning

confidence: 99%

“…Computer simulations indicate that the dimers induce membrane curvature, and not that, conversely, membrane curvature induces dimer formation (6). Yeast mutants in which the dimerspecific ATP synthase subunits e or g were knocked out lacked ATP synthase dimers, dimer rows, and lamellar cristae.…”

Section: Resultsmentioning

confidence: 99%

“…Each particle was connected to the membrane by a 4-nm stalk. Subtomogram averaging of the same particle pairs in yeast (6) and other organisms (1) has shown that they are dimers of the mitochondrial ATP synthase. Dimer rows were always present along the highly curved cristae tips in the partly lamellar morphology (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…The inner mitochondrial membrane is highly folded into cristae (1)(2)(3), which contain the bulk of the respiratory chain complexes and the mitochondrial F 1 F o ATP synthase (4,5). At the cristae ridges, the ATP synthase self-assembles into long rows of dimers, which maintain a high local membrane curvature and normal cristae architecture (1,6,7). Respiratory chain complexes at either side of the dimer rows (1) pump protons from the mitochondrial matrix into the cristae space.…”

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confidence: 99%

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Age-dependent dissociation of ATP synthase dimers and loss of inner-membrane cristae in mitochondria

Daum

Walter

Horst

et al. 2013

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

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Aging is one of the most fundamental, yet least understood biological processes that affect all forms of eukaryotic life. Mitochondria are intimately involved in aging, but the underlying molecular mechanisms are largely unknown. Electron cryotomography of whole mitochondria from the aging model organism Podospora anserina revealed profound age-dependent changes in membrane architecture. With increasing age, the typical cristae disappear and the inner membrane vesiculates. The ATP synthase dimers that form rows at the cristae tips dissociate into monomers in inner-membrane vesicles, and the membrane curvature at the ATP synthase inverts. Dissociation of the ATP synthase dimer may involve the peptidyl prolyl isomerase cyclophilin D. Finally, the outer membrane ruptures near large contact-site complexes, releasing apoptogens into the cytoplasm. Inner-membrane vesiculation and dissociation of ATP synthase dimers would impair the ability of mitochondria to supply the cell with sufficient ATP to maintain essential cellular functions.subtomogram averaging | cell death

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

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Age-dependent dissociation of ATP synthase dimers and loss of inner-membrane cristae in mitochondria

Daum

Walter

Horst

et al. 2013

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

Self Cite

206

195

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“…The dimeric nature of ATP synthase is now largely acknowledged in many organisms, and in mammals and yeasts, the dimer has a molecular mass of ~1.2 MDa and is thought also to be responsible for shaping mitochondrial cristae (Davies et al, 2012;Velours and Arselin, 2000;Walker et al, 1991). Beyond mammals, fungi and flowering plants, the first organism where an unusual structure and subunit composition of the mitochondrial ATP synthase was found was the green alga C. reinhardtii and its colourless relative Polytomella sp.…”

Section: Complex Vmentioning

confidence: 99%

The mitochondrial respiratory chain of the secondary green alga Euglena gracilis shares many additional subunits with parasitic Trypanosomatidae

et al. 2014

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The mitochondrion is an essential organelle for the production of cellular ATP in most eukaryotic cells. It is extensively studied, including in parasitic organisms such as trypanosomes, as a potential therapeutic target. Recently, numerous additional subunits of the respiratory-chain complexes have been described in Trypanosoma brucei and Trypanosoma cruzi. Since these subunits had apparently no counterparts in other organisms, they were interpreted as potentially associated with the parasitic trypanosome lifestyle. Here we used two complementary approaches to characterise the subunit composition of respiratory complexes in Euglena gracilis, a non-parasitic secondary green alga related to trypanosomes. First, we developed a phylogenetic pipeline aimed at mining sequence databases for identifying homologs to known respiratory-complex subunits with high confidence. Second, we used MS/MS proteomics after two-dimensional separation of the respiratory complexes by Blue Native-and SDS-PAGE to both confirm in silico predictions and to identify further additional subunits. Altogether, we identified 41 subunits that are restricted to E. gracilis, T. brucei and T. cruzi, along with 48 classical subunits described in other eukaryotes (i.e. plants, mammals and fungi). This moreover demonstrates that at least half of the subunits recently reported in T. brucei and T. cruzi are actually not specific to Trypanosomatidae, but extend at least to other Euglenozoa, and that their origin and function are thus not specifically associated with the parasitic lifestyle. Furthermore, preliminary biochemical analyses suggest that some of these additional subunits underlie the peculiarities of the respiratory chain observed in Euglenozoa.Liège, february 06 th 2014Dear Editor, Please find the fully revised version of our manuscript "The mitochondrial respiratory chain of the secondary green alga Euglena gracilis shares many additional subunits with parasitic Trypanosomatidae."We are grateful to you for having encouraged us to resubmit a modified manuscript. We have addressed all the comments raised by the reviewers on our first submission. A point to point answer has been submitted along with the manuscript. Main changes are : (i) additional explanations about the phylogenic/bioinformatic strategy including some phylogenetic trees (supplemental figures 1 and 2); (ii) all data that were previously not shown (mass spectrometry data, in vivo respiratory assays) are now included in the manuscript as supplemental figures/tables.We hope that we have now significantly improved our manuscript so you'll find it suitable for publication in the special issue of Mitochondrion dedicated to "Plant Mitochondria Biology". R: Primary MS data are now given in Supplemental Table 3 for each polypeptide for which the score was > 60. (BLAST alignments, Evalues, etc.) are actually presented in the paper to support the inference that a particular E. gracilis protein is a true homolog of a given kinetoplastid protein. The most important conclusion of t...

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F‐ATP synthase and the permeability transition pore: fewer doubts, more certainties

et al. 2019

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Whether the mitochondrial permeability transition pore (PTP), also called mitochondrial megachannel (MMC), originates from the F‐ATP synthase is a matter of controversy. This hypothesis is supported both by site‐directed mutagenesis of specific residues of F‐ATP synthase affecting regulation of the PTP/MMC and by deletion of specific subunits causing dramatic changes in channel conductance. In contrast, human cells lacking an assembled F‐ATP synthase apparently display persistence of the PTP. We discuss recent data that shed new light on this controversy, supporting the conclusion that the PTP/MMC originates from a Ca2+‐dependent conformational change in F‐ATP synthase allowing its reversible transformation into a high‐conductance channel.

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Structure of the yeast F ₁ F _o -ATP synthase dimer and its role in shaping the mitochondrial cristae

Cited by 427 publications

References 51 publications

Age-dependent dissociation of ATP synthase dimers and loss of inner-membrane cristae in mitochondria

Age-dependent dissociation of ATP synthase dimers and loss of inner-membrane cristae in mitochondria

The mitochondrial respiratory chain of the secondary green alga Euglena gracilis shares many additional subunits with parasitic Trypanosomatidae

F‐ATP synthase and the permeability transition pore: fewer doubts, more certainties

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Structure of the yeast F 1 F o -ATP synthase dimer and its role in shaping the mitochondrial cristae

Cited by 427 publications

References 51 publications

Age-dependent dissociation of ATP synthase dimers and loss of inner-membrane cristae in mitochondria

Age-dependent dissociation of ATP synthase dimers and loss of inner-membrane cristae in mitochondria

The mitochondrial respiratory chain of the secondary green alga Euglena gracilis shares many additional subunits with parasitic Trypanosomatidae

F‐ATP synthase and the permeability transition pore: fewer doubts, more certainties

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Structure of the yeast F ₁ F _o -ATP synthase dimer and its role in shaping the mitochondrial cristae