Carsten Bornhövd scite author profile

The inner membrane of mitochondria is organized in two morphologically distinct domains, the inner boundary membrane (IBM) and the cristae membrane (CM), which are connected by narrow, tubular cristae junctions. The protein composition of these domains, their dynamics, and their biogenesis and maintenance are poorly understood at the molecular level. We have used quantitative immunoelectron microscopy to determine the distribution of a collection of representative proteins in yeast mitochondria belonging to seven major processes: oxidative phosphorylation, protein translocation, metabolite exchange, mitochondrial morphology, protein translation, iron–sulfur biogenesis, and protein degradation. We show that proteins are distributed in an uneven, yet not exclusive, manner between IBM and CM. The individual distributions reflect the physiological functions of proteins. Moreover, proteins can redistribute between the domains upon changes of the physiological state of the cell. Impairing assembly of complex III affects the distribution of partially assembled subunits. We propose a model for the generation of this dynamic subcompartmentalization of the mitochondrial inner membrane.

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Processing of Mgm1 by the Rhomboid-type Protease Pcp1 Is Required for Maintenance of Mitochondrial Morphology and of Mitochondrial DNA

Herlan¹,

Vogel

Bornhövd³

et al. 2003

Journal of Biological Chemistry

340

317

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press). Mgm1 and its orthologs exist in two forms of different lengths. To obtain new insights into their biogenesis and function, we have characterized these isoforms. The large isoform (l-Mgm1) contains an N-terminal putative transmembrane segment that is absent in the short isoform (sMgm1). The large isoform is an integral inner membrane protein facing the intermembrane space. Furthermore, the conversion of l-Mgm1 into s-Mgm1 was found to be dependent on Pcp1 (Mdm37/YGR101w) a recently identified component essential for wild type mitochondrial morphology. Pcp1 is a homolog of Rhomboid, a serine protease known to be involved in intercellular signaling in Drosophila melanogaster, suggesting a function of Pcp1 in the proteolytic maturation process of Mgm1. Expression of s-Mgm1 can partially complement the ⌬pcp1 phenotype. Expression of both isoforms but not of either isoform alone was able to partially complement the ⌬mgm1 phenotype. Therefore, processing of l-Mgm1 by Pcp1 and the presence of both isoforms of Mgm1 appear crucial for wild type mitochondrial morphology and maintenance of mitochondrial DNA.Mitochondria are dynamic structures. Their overall morphology and the shape of the inner membrane are highly variable (5). This is exemplified by a wide variety of mitochondrial ultrastructures observed in different organisms and tissues and by the dependence of these structures on the metabolic and genetic state of the cell. Mitochondrial dynamics has recently gained increasing attention, and quite a number of proteins affecting this structural diversity have been identified. Still, our understanding of the underlying molecular events is rather incomplete. Fusion and fission of mitochondrial membranes are processes that have to be balanced in order to maintain mitochondrial morphology (6). For example, when fusion of mitochondria is abolished, fission can still continue, and consequently mitochondria get progressively fragmented (reviewed in Ref. 7). The roles of a number of proteins such as the GTPase Fzo1 (8) and the dynamin-like GTPase Dnm1 (9) in fusion and fission are known. Less clear is the role of the mitochondrial dynamin-like protein Mgm1, which is another component essential for maintaining mitochondrial morphology in Saccharomyces cerevisiae.

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The Nfs1 interacting protein Isd11 has an essential role in Fe/S cluster biogenesis in mitochondria

Adam

Bornhövd

Prokisch³

et al. 2005

EMBO J

210

233

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Formation of iron/sulfur (Fe/S) clusters, protein translocation and protein folding are essential processes in the mitochondria of Saccharomyces cerevisiae. In a systematic approach to characterize essential proteins involved in these processes, we identified a novel essential protein of the mitochondrial matrix, which is highly conserved from yeast to human and which we termed Isd11. Depletion of Isd11 caused a strong reduction in the levels of the Fe/S proteins aconitase and the Rieske protein, and a massive decrease in the enzymatic activities of aconitase and succinate dehydrogenase. Incorporation of iron into the Fe/S protein Leu1 and formation of the Fe/S cluster containing holoform of the mitochondrial ferredoxin Yah1 were inhibited in the absence of Isd11. This strongly suggests that Isd11 is required for the assembly of Fe/S proteins. We show that Isd11 forms a stable complex with Nfs1, the cysteine desulfurase of the mitochondrial machinery for Fe/S cluster assembly. In the absence of Isd11, Nfs1 is prone to aggregation. We propose that Isd11 acts together with Nfs1 in an early step in the biogenesis of Fe/S proteins.

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Alternative topogenesis of Mgm1 and mitochondrial morphology depend on ATP and a functional import motor

et al. 2004

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Mitochondrial morphology and inheritance of mitochondrial DNA in yeast depend on the dynamin-like GTPase Mgm1. It is present in two isoforms in the intermembrane space of mitochondria both of which are required for Mgm1 function. Limited proteolysis of the large isoform by the mitochondrial rhomboid protease Pcp1/Rbd1 generates the short isoform of Mgm1 but how this is regulated is unclear. We show that near its NH2 terminus Mgm1 contains two conserved hydrophobic segments of which the more COOH-terminal one is cleaved by Pcp1. Changing the hydrophobicity of the NH2-terminal segment modulated the ratio of the isoforms and led to fragmentation of mitochondria. Formation of the short isoform of Mgm1 and mitochondrial morphology further depend on a functional protein import motor and on the ATP level in the matrix. Our data show that a novel pathway, to which we refer as alternative topogenesis, represents a key regulatory mechanism ensuring the balanced formation of both Mgm1 isoforms. Through this process the mitochondrial ATP level might control mitochondrial morphology.

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Mitochondrial Membrane Potential Is Dependent on the Oligomeric State of F1F0-ATP Synthase Supracomplexes

Bornhövd

Vogel

Neupert

et al. 2006

Journal of Biological Chemistry

133

113

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The F 1 F 0 -ATP synthase in mitochondria, in addition to its function in energy transduction, has a structural role in determining cristae morphology. This depends on its ability to form dimeric and higher oligomeric supracomplexes. Here we show that mutants of the dimer-specific subunits e and g, which destabilize dimeric and oligomeric F 1 F 0 -ATP synthase supracomplexes, have a decreased mitochondrial membrane potential ⌬⌿. The degree of destabilization correlated with the reduction of the membrane potential. The enzymatic activities of F 1 F 0 -ATP synthase and cytochrome c oxidase, maximal respiration rate, coupling of oxidative phosphorylation, and tubular mitochondrial morphology were not affected or only to a minor extent. In mutants lacking one or two coiled-coil domains of subunit e, the reduction of the mitochondrial membrane potential was not due to loss of mitochondrial DNA, a reduced capacity of oxidative phosphorylation, or to altered cristae morphology. We propose a role for the supracomplexes of the F 1 F 0 -ATP synthase in organizing microdomains within the inner membrane, ensuring optimal bioenergetic competence of mitochondria.

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