Role of MINOS in mitochondrial membrane architecture and biogenesis

Opinion

Role of MINOS in mitochondrial membrane architecture and biogenesis Martin van der Laan1,2, Maria Bohnert1, Nils Wiedemann1,2 and Nikolaus Pfanner1,2 1

Institut fu¨r Biochemie und Molekularbiologie, Zentrum fu¨r Biochemie und Molekulare Zellforschung (ZBMZ), Universita¨t Freiburg, 79104 Freiburg, Germany 2 Centre for Biological Signaling Studies (BIOSS), Universita¨t Freiburg, 79104 Freiburg, Germany

Mitochondria possess a complex architecture with two membranes. The inner membrane is divided into two domains: the inner boundary membrane, which is adjacent to the outer membrane, and membrane invaginations termed cristae. Both domains are connected by tubular openings, the crista junctions. Recent studies led to the identification of a large protein complex that is crucial for establishing inner-membrane architecture. This mitochondrial inner-membrane organizing system (MINOS) interacts with protein translocases of the outer membrane that are functionally connected to the endoplasmic reticulum (ER)–mitochondria encounter structure. Here, we propose that MINOS forms a central part of an ER–mitochondria organizing network (ERMIONE) that controls mitochondrial membrane architecture and biogenesis. Mitochondrial membrane architecture Mitochondria are involved in numerous cellular processes. In addition to their central role in ATP production by oxidative phosphorylation, they are involved in the metabolism of amino acids, lipids and iron, and they play important roles in the regulation of programmed cell death (apoptosis) [1–7]. Mitochondria contain two membranes with different functions and architecture. The outer membrane forms the barrier to the rest of the cell. It contains channels formed by the abundant outer-membrane protein porin, also known as the voltage-dependent anion channel (VDAC), which permits the passage of numerous metabolites between cytosol and the mitochondrial intermembrane space. The outer membrane contains also the main protein entry gate of mitochondria, the translocase of the outer membrane (TOM), as well as the sorting and assembly machinery (SAM) and key molecules involved in mitochondrial fusion and fission [1,3,8–12]. The mitochondrial inner membrane possesses a much larger surface than the outer membrane and consists of two topologically different regions: the inner boundary membrane, which is in proximity to the outer membrane, and the cristae membranes that form characteristic membrane invaginations with a large variety of shapes from tubular to lamellar structures [13–17]. The mitochondrial inner membrane is a highly protein-rich membrane, but the proteins are not equally distributed between inner Corresponding author: Pfanner, N. ([email protected]). Keywords: ERMES; MINOS; Mio10; mitochondrial contact sites; mitochondrial cristae; mitofilin.

boundary membrane and cristae membranes, as shown by biochemical fractionation [18] and analysis by electron microscopy and fluorescence microscopy [19–22]. The inner boundary membrane preferentially contains preprotein translocase machineries such as the presequence translocase of the inner membrane (TIM23) and the mitochondrial intermembrane space assembly machinery (Mia40), as well as a fraction of proteins involved in mitochondrial Glossary Crista junctions: the mitochondrial inner membrane consists of the inner boundary membrane (adjacent to the outer membrane) and membrane invaginations (cristae). Crista junctions form the tubular connections between inner boundary membrane and cristae membranes. ERMES: the ER–mitochondria encounter structure (ERMES) physically links the outer mitochondrial membrane with the ER membrane. ERMES is composed of the mitochondrial outer-membrane proteins Mdm10, Mdm34 and Gem1, the ER membrane protein Mmm1 and the adaptor protein Mdm12. ERMIONE: the ER–mitochondria organizing network (ERMIONE) comprises a branched chain of physical and genetic interactions that structurally and functionally link three intracellular membranes and the adjacent aqueous compartments from the mitochondrial matrix to the lumen of the endoplasmic reticulum. Key players in this network are the membrane-bridging ERMES and MINOS complexes. Fusion of mitochondria: fusion of the mitochondrial membranes involves two dynamin-related GTPases, the outer-membrane protein mitofusin/Fzo1, and the inner-membrane protein Opa1/Mgm1. In fungi, the outer-membrane protein Ugo1 functions in an adapter-like manner between Fzo1 and Mgm1. MIA: the mitochondrial intermembrane space import and assembly machinery (MIA) mediates the biogenesis of intermembrane space proteins that contain characteristic cysteine-rich internal signal sequences. This process involves the formation of transient intermolecular disulfides with the intermembrane space receptor Mia40 as well as the activity of the sulfhydryl oxidase Erv1. MINOS: the mitochondrial inner-membrane organizing system (MINOS) is involved in connecting the two subdomains of the inner mitochondrial membrane, the inner boundary membrane and the cristae. In yeast, MINOS consists of at least six different subunits: the mitofilin protein Fcj1, Mio10, Mio27, Aim5, Aim13 and Aim37. MINOS deficiency leads to detachment of cristae from the inner boundary membrane and loss of crista junctions. Additionally, MINOS components are engaged in multiple interactions with the outer mitochondrial membrane. Prohibitins: mitochondrial prohibitins belong to a large protein family also including flotillin and stomatin proteins, characterized by a so-called PHB domain. It has been suggested that these proteins are involved in the organization of membrane domains, most likely through specific lipid-binding properties. SAM: the sorting and assembly machinery (SAM complex) of the outer mitochondrial membrane mediates the membrane integration and folding of b-barrel proteins. SAM is composed of the membrane-integral Sam50 protein and the peripherally associated subunits Sam35 and Sam37. The morphology protein Mdm10 associates with SAM to support the assembly of some a-helical proteins. TOM: the translocase of the outer mitochondrial membrane (TOM complex) mediates the import of the vast majority of nuclear-encoded mitochondrial precursor proteins into the organelle. The protein-conducting channel of the TOM complex is formed by the b-barrel protein Tom40, which associates with several receptor proteins and small subunits involved in stabilization and dynamics of the TOM complex.

0962-8924/$ – see front matter ß 2012 Elsevier Ltd. All rights reserved. doi:10.1016/j.tcb.2012.01.004 Trends in Cell Biology, April 2012, Vol. 22, No. 4

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Figure 1. Organization of the mitochondrial inner membrane. (a) Schematic view of mitochondrial outer and inner membranes. The inner membrane consists of two domains – the inner boundary membrane and the cristae membranes – which are connected by crista junctions. Proteins are differentially enriched in the two domains, although the distribution is not static but dynamic. Protein-transport machineries such as the presequence translocase (TIM23) and Mia40 are enriched in the inner boundary membrane, whereas respiratory complexes such as complexes II, III and IV and the F1Fo-ATP synthase are enriched in cristae membranes. Isoforms of the fusion protein Mgm1 are differentially enriched in inner boundary membrane and cristae membrane [97]. The mitochondrial inner-membrane organizing system (MINOS) is enriched in the vicinity of crista junctions. MINOS interacts with protein translocases of the outer membrane (TOM, SAM), the channel-forming protein porin (VDAC), the outer-membrane fusion component Ugo1, and the intermembrane space receptor Mia40. (b) The inner membrane of wild-type mitochondria forms invaginations (cristae). In MINOS mutant mitochondria, most crista junctions are lost and large internal membrane stacks, resembling a labyrinth, are observed. The ancient Greek drachma shows the head of Zeus or his son Minos and the mythical labyrinth of Knossos, Crete; in Greek mythology Minos was a king of Crete when the labyrinth was built. Photo of the drachma with permission from Fritz Rudolf Ku¨nker GmbH & Co. KG, Osnabru¨ck, www.kuenker.de, and Lu¨bke & Wiedemann, Stuttgart. (c) The MINOS complex contains six inner-membrane proteins. The nomenclatures in yeast (left) and metazoa (right) are indicated. ORF, open reading frame and systematic name in the yeast Saccharomyces cerevisiae. The domain structures of the MINOS subunits are shown; numbers refer to the first and last amino acid residues of the yeast proteins.

fusion (Mgm1/Opa1) (Figure 1a). The cristae membranes mainly contain the complexes of the respiratory chain, the F1Fo-ATP synthase, and metabolite carriers such as the ADP/ATP carrier [19,20]. Inner boundary membrane and cristae membranes are connected by tubular openings (Figure 1a,b). These 186

crista junctions (see Glossary) are believed to limit diffusion between both membrane domains, although there is no strict separation, but the distribution of molecules between the membrane domains is dynamic [17,20,22]. Crista junctions are also thought to limit diffusion of soluble molecules between the intracristal space and the remainder of the

Opinion intermembrane space, which is located between inner boundary membrane and outer membrane. Crista junctions thus help to form a microenvironment in the intracristal space that may enhance the capacity of the oxidative phosphorylation system of mitochondria [16,17,23–25]. Despite detailed morphological analyses of mitochondrial ultrastructure, little has been known about the molecules that are involved in the maintenance of cristae organization [16,17]. Recent studies by several groups led to the identification of a large protein complex that functions as a mitochondrial inner-membrane organizing system (MINOS) [26–29]. Surprisingly, MINOS interacts with a variety of different partner proteins, including several protein complexes of the mitochondrial outer membrane (Figure 1a). Here, we put the different observations into context and propose that MINOS forms a central core of a large organizing system that extends from ER–mitochondria junctions to mitochondrial outer and inner membranes and mitochondrial DNA (mtDNA) nucleoids. We term this organizing system ERMIONE, for ER–mitochondria organizing network, and suggest that ERMIONE functions as a regulatory system that includes both biochemical and genetic interactions. Mitochondrial inner-membrane organization Yeast mutants that affect the dimerization of the F1Fo-ATP synthase display altered cristae morphologies [23,29–33]. The F1Fo-ATP synthase can assemble into large spiral-like oligomeric structures that may form a scaffold for the stabilization of cristae structures, in particular for the formation of cristae tips [24,25,33,34]. However, the F1Fo-ATP synthase is probably not responsible for the formation or maintenance of crista junctions [33]. The inner-membrane protein Mgm1 (yeast)/Opa1 (mammals) is required for fusion of mitochondrial membranes [35–39]. In addition, mutants of Mgm1/Opa1 show altered cristae morphology. It is thought that oligomerization of Mgm1/Opa1 is required

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for normal cristae structure [37,39,40], although further work is needed to define the molecular mechanisms. The inner-membrane protein Mdm33 also affects innermembrane structure, possibly by regulating innermembrane division [41]. Characterization of the mitochondrial inner-membrane protein mitofilin was a major step in the analysis of crista junctions [26–29,33,42–44]. Mitofilin was initially identified in heart muscle cells [45] and received its name due to its colocalization with the filamentous mitochondrial network in fibroblasts [46]. Mitofilin was found in the proteome of purified mitochondria [47,48]. It is targeted to mitochondria by an N-terminal presequence and anchored in the inner membrane by a single hydrophobic transmembrane region that follows the presequence. The remainder of the protein is exposed to the mitochondrial intermembrane space and includes a coiled-coil region that supports protein–protein interactions (Figure 1c) [33,42]. Cells with decreased levels of mitofilin or mutant cells completely lacking mitofilin show a striking alteration of the inner morphology of mitochondria. The cristae membranes are detached from the inner boundary membrane and form large internal membrane stacks (Figure 1b) [33,42]. Because crista junctions are largely absent in mitofilin mutant cells, it was concluded that mitofilin is required for formation of crista junctions, and was therefore also termed Fcj1 in yeast [33]. However, crista junctions are not completely absent in mitofilin mutants [26,28] and thus mitofilin is not strictly essential for their formation. The available results are explained best by a role of mitofilin in the maintenance of crista junctions, including the prevention of cristae release from the inner boundary membrane. Though it was originally assumed that mitofilin mainly undergoes homotypic interactions [33,42], recent studies have led to the identification of a large hetero-oligomeric protein complex in the inner membrane that contains

Box 1. Identification of the mitochondrial inner-membrane organizing system Four independent studies identified a large protein complex of the inner mitochondrial membrane that is crucial for maintenance of the typical inner-membrane morphology. The complex consists of the core components mitofilin/Fcj1 and MINOS1/Mio10 together with at least four additional subunits. The complex has received three different names: MINOS, MICOS, and MitOS. All studies concordantly report that mutations affecting this protein complex induce a dramatic loss of crista junctions and a detachment of cristae membranes from the inner boundary membrane.  von der Malsburg et al. [26] combined stable isotope-labeling with amino acids in cell culture (SILAC) with purification of mitofilincontaining protein complexes by affinity chromatography and mass spectrometric analysis. The identified protein complex is composed of mitofilin/Fcj1, Mio10, Mio27, Aim5, Aim13 and Aim37 and was termed mitochondrial inner-membrane organizing system (MINOS). This study also identified a physical interaction between mitofilin/ Fcj1 and the outer-membrane TOM complex. This interaction is important for protein import into the intermembrane space via the MIA pathway.  Harner et al. [27] expressed a synthetic linker protein in yeast cells as a marker for contact sites between outer and inner mitochondrial membranes. They fractionated mitochondrial membranes and analyzed proteins enriched in contact-site fractions by mass spectrometry. Six of the proteins found in contact-site fractions were shown to form an inner-membrane complex preferentially

located at crista junctions, named the mitochondrial contact-site (MICOS) complex. This study provided evidence for interaction of this complex with the Ugo1 fusion component of the outer membrane and for an interaction with the SAM complex (in agreement with further studies [51–53]).  Hoppins et al. [28] systematically analyzed genes involved in mitochondrial biogenesis and function for similar synthetic interaction patterns (MITO-MAP). One gene cluster including FCJ1 encoded subunits of a protein complex required for maintenance of mitochondrial inner-membrane morphology, termed mitochondrial organizing structure (MitOS). MitOS genes showed strong genetic interactions with ERMES and phospholipid biosynthesis genes. Fluorescence microscopy analysis of cells expressing GFP-tagged subunits suggested the formation of large structures spanning the mitochondrial intermembrane space.  Alkhaja et al. [29] identified Mio10 as a protein potentially stabilizing mitochondrial membrane protein supercomplexes. Tagged Mio10 co-purified mitofilin/Fcj1 and further components of MINOS. The human ortholog of Mio10 is also part of a mitofilincontaining complex and was termed MINOS1. Further components are the CHCHD3/MINOS3 protein, which belongs to the same protein family as yeast Aim13, as well as HSPA9 and the J-protein DnaJC11. In agreement with further studies [51–53], this work demonstrated a direct interaction of the MINOS complex with the SAM complex of the outer mitochondrial membrane. 187

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mitofilin as one of the core components (Figure 1a,c; Box 1) [26–29]. This large mitofilin complex was termed mitochondrial inner-membrane organizing system (MINOS) [26,29]. It is a remarkable coincidence that MINOS was identified in parallel by four independent studies. Thus the complex received the further names MICOS (mitochondrial contact site) and MitOS (mitochondrial organizing structure) [27,28]. Different experimental strategies and approaches led to the identification of MINOS/MICOS/MitOS (Box 1) [26–29]. The MINOS complex contains six different subunits (Figures 1c, 2). Mitofilin/Fcj1 and the small integral inner-membrane protein Mio10 are the two core components [26–29]. The absence of either leads to dissociation of the MINOS complex and massive rearrangement of inner-membrane morphology, with the loss of crista junctions and the appearance of large internal membrane stacks. Three MINOS subunits were originally identified in a genetic screen for proteins that are involved in the inheritance of mtDNA,

and were termed Aim5, Aim13 and Aim37 (altered inheritance of mitochondria) (currently, more than 40 AIM genes are listed in the Saccharomyces genome database, although the molecular function of many of them is not yet known) [49]. The three Aim proteins of the MINOS complex are all inner-membrane proteins, as are mitofilin and Mio10. Aim5 and Aim37 are integral membrane proteins, whereas Aim13 is a peripheral membrane protein (Figure 1c). Mutants of these AIM genes show phenotypes that are in principle similar to those of mutants lacking mitofilin or Mio10; however, the defects are not as severe. Lack of Aim proteins leads to a partial dissociation of the MINOS complex, a reduction of the number of crista junctions, and a partial alteration of mitochondrial morphology (with internal cristae stacks) [26–28]. The sixth subunit of the MINOS complex, Mio27, is related to Aim37; Mio27 mutants show only mild phenotypes. The recently identified C. elegans mitochondrial morphology protein MOMA-1 is an ortholog of Aim37 and Mio27 [44] (Figure 1c).

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Figure 2. An ER–mitochondria organizing network (ERMIONE). The ER and the mitochondrial outer membrane, as well as the mitochondrial outer and inner membranes, are connected by protein–protein interactions. The lower part of the figure shows a schematic view of protein complexes that are involved in membrane contact sites. Biochemically demonstrated interactions are indicated by double arrows; genetic interactions are indicated by dotted double arrows. ER and mitochondria can be physically connected by the ERMES complex and by mitofusins (Mfn). MINOS complexes probably form an extended network on the intermembrane space side of the inner membrane. MINOS interacts with several outer-membrane proteins, including the protein translocases TOM and SAM, the abundant channel-protein porin, and fusion components. MINOS transiently interacts with Mia40 and promotes protein import through TOM into the intermembrane space. MINOS and ERMES have been linked genetically by analysis of double mutants and biochemically via the SAM complex (SAM interacts with MINOS, and the morphology protein Mdm10 is present in both SAM and ERMES). ERMES, MINOS and further inner-membrane proteins, including prohibitins and Mdm31/32, are involved in the maintenance of mitochondrial DNA that is organized in nucleoids. The network of ER–mitochondrial outer-membrane–inner-membrane interactions is termed the ER–mitochondria organizing network (ERMIONE). This network of interactions promotes the transport of lipids and calcium ions between the compartments. OM, outer membrane; IMS, intermembrane space; IM, inner membrane.

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Opinion The MINOS complex forms a large structure in the megadalton range and thus its subunits are probably present in multiple copies (Figure 2). Mitofilin and Mio10 contain sequence elements that favor protein– protein interactions and probably form homo- and hetero-oligomeric structures. Affinity-purification studies yielded various combinations of MINOS components, suggesting that multiple subcomplexes may exist that are arranged in a large, dynamic superstructure [26–29]. MINOS components are enriched in the vicinity of crista junctions [27,33], and all subunits contain domains that are exposed to the intermembrane space. Taking the biochemical and morphological evidence together [26–29], MINOS may form an extended network on the intermembrane space side of the inner membrane that is important for the maintenance of inner-membrane organization. The formation of the typical cristae structures probably involves several dynamic and structural elements, including MINOS, the F1Fo-ATP synthase, and Mgm1/Opa1. Multiple interactions of MINOS with the mitochondrial outer membrane Interactions of the MINOS complex are not limited to the mitochondrial inner membrane. Several studies surprisingly demonstrated that proteins and protein complexes of the mitochondrial outer membrane physically interact with MINOS components. The outer membrane contains two major machineries for protein transport – the TOM complex that is responsible for importing hundreds of different nuclear-encoded proteins into mitochondria, and the SAM complex (TOB complex) that mediates the insertion of b-barrel proteins into the outer membrane [1,8,9,50]. Both translocase machineries were found as interaction partners of MINOS (Figures 1a,2) [26–29, 51–53]. In the case of the TOM complex, MINOS indeed plays a supportive role in protein import. However, MINOS does not promote the import of precursor proteins into or across the inner membrane; the presequence translocase (TIM23 complex) and the carrier translocase (TIM22 complex) of the inner membrane have not been found in association with MINOS. Instead, MINOS transiently interacts with the intermembrane space import receptor Mia40 [26]. Mia40 is the core of the mitochondrial intermembrane-space assembly machinery that drives the import of proteins into the intermembrane space by an oxidative mechanism [9,54–57]. Mia40 directly interacts with the incoming substrate proteins via disulfide bonds. To capture immediately preproteins in transit through the TOM channel, Mia40 binds to the signal sequences of incoming preproteins as soon as they emerge on the intermembrane space side of the TOM complex [26]. For this task, Mia40 has to be positioned in close vicinity to the TOM complex, and this is achieved by the transient interaction of mitofilin with both the TOM complex and Mia40. Mitofilin may thus perform adapter-like functions to link different machineries of the mitochondrial protein-import apparatus. The exact molecular function of the interaction of MINOS with the SAM complex has not yet been defined. An adapter/organizing role of MINOS may support the cooperation of TOM and SAM, and thus MINOS may assist in the transfer of b-barrel proteins from the TOM complex

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to the SAM complex. In cells with reduced levels of Sam50, the cristae architecture was altered [53], suggesting that the interaction of MINOS with the outer membrane may be important for maintaining inner-membrane architecture. In addition to the association with protein translocases, MINOS was also found to interact with the most abundant outer-membrane protein porin (VDAC), as well as with the fusion component Ugo1 (Figures 1a, 2) [27,28]. Porin is the major channel for transport of metabolites between the cytosol and the intermembrane space. Because metabolites are differentially distributed between intracristal space and the remainder of the intermembrane space [14,16, 58], the enrichment of MINOS in the vicinity of crista junctions may help to position the main metabolite channel of mitochondria close to crista junctions, and may thus facilitate the efficient distribution of metabolites. Ugo1 is a subunit of the outer-membrane fusion machinery of yeast mitochondria and has an adapter-like function through its linkage of two dynamin-like GTPases: the outermembrane protein Fzo1 (termed mitofusin in higher eukaryotes) and Mgm1/Opa1 of the inner membrane [59–61]. Although it is an open question whether MINOS is present in a supercomplex with Fzo1 and Mgm1, or if MINOS interacts with Ugo1 only [26,27,52], the interaction of MINOS with Ugo1 provides a link between two machineries that control mitochondrial membrane morphology and dynamics. An ER–mitochondria organizing network The large number of reported MINOS interaction partners of seemingly unrelated functions raises the question of how these findings can be put into a functional context. We propose that MINOS forms a central core of a large organizing network of mitochondria that includes numerous further components. The large size of MINOS may provide a scaffold for multiple binding partners and thus help to spatially organize and coordinate mitochondrial functions (Figure 2). Of particular importance is the functional connection of SAM and TOM to the ER–mitochondria encounter structure (ERMES) [62–65]. In fungi, ERMES physically connects ER and mitochondria by containing both an ER-located subunit (Mmm1) and mitochondrial-located subunits within the same complex (Figure 2). Remarkably, the morphology protein Mdm10 of the mitochondrial outer membrane has dual localization in SAM and ERMES [66–70]. A small TOM subunit also exhibits dual localization: Tom7 is present in the TOM complex, and also associates with Mdm10, and thus regulates the distribution of Mdm10 between SAM and ERMES [67,69,71]. Yeast mutants of ERMES components show a dramatic alteration of mitochondrial shape, leading to giant ball-like mitochondrial structures [67,68,72–79]. Yeast mutants of SAM components as well as of several TOM components lead to a similar phenotype [66,67], underscoring the functional connection between ERMES, SAM and TOM. Remarkably, mutants of the ER-located subunit Mmm1 were also reported to affect the ultrastructure of the mitochondrial inner membrane, leading to a massive disorganization of cristae membranes [80], suggesting an important connection from the ER to the mitochondrial 189

Opinion inner membrane. Indeed, strong genetic interactions have been observed between ERMES and MINOS components [28]. Taken together, we propose that ERMES, SAM, TOM and MINOS are connected in a dynamic network and thus link ER to mitochondrial outer and inner membranes. ERMES as well as MINOS have been implicated in lipid transfer and metabolism [2,27,28,62–65,81] and thus they may provide a scaffold for transport of lipid molecules between ER and both mitochondrial membranes [82]. Both complexes are genetically linked to the prohibitin ring complexes of the inner membrane that are integrated into a network of mitochondrial lipid metabolism [2,28,81]. In addition, prohibitins affect cristae morphogenesis by regulating the processing of the fusion protein Mgm1/ Opa1 [83]. The close connections between ER and mitochondria probably facilitate the uptake of calcium ions by mitochondria upon their release from the ER [84]. In higher eukaryotes, mitofusins have been reported to link physically ER and mitochondria and thus to promote calcium transfer into mitochondria (Figure 2) [85]. It is an open question whether ERMES and mitofusin tethers exist in parallel in the same organism. Interestingly, in yeast MINOS interacts with the fusion component Ugo1 that binds to Fzo1, the yeast ortholog of mitofusins [27,59]. Although an ortholog of Ugo1 has not yet been found in higher eukaryotes, it is tempting to speculate that MINOS, whose core components are conserved from yeast to human (Figure 1c), is the connecting partner of both systems that link mitochondria and the ER, providing a communication chain across three organellar membranes. ERMES has also been proposed to be involved in mitochondrial distribution and the connection of mitochondria to the cytoskeleton [73–75], although different views exist on the molecular mechanism. The recent identification of the GTPase Gem1 as a mitochondria-bound subunit of ERMES [86,87] provides an interesting twist because the protein Miro (mitochondrial Rho-like), the homolog of Gem1 in higher eukaryotes, functions as an adapter in linking mitochondria to the cytoskeleton [88–90]. Four of the MINOS subunits were found in a genetic screen for altered inheritance of mitochondria, reflected in the names Aim5, Aim13 and Aim37; the fourth, mitofilin/ Fcj1, was also termed Aim28 [49]. MINOS is thus involved in the maintenance of mtDNA. Yeast mtDNA is organized into DNA–protein complexes termed nucleoids, and ERMES can be found in foci that are adjacent to a subset of nucleoids [75,78,80,91]. Genetic interaction studies revealed a functional link between ERMES, MINOS and further inner-membrane proteins that are involved in regulating mitochondrial morphology and the maintenance of mtDNA. These include the morphology proteins Mdm31 and Mdm32 that are anchored in the inner membrane and expose large domains to the intermembrane space [79]. Yeast mutants of Mdm31 and Mdm32 show a similar alteration of mitochondrial shape as ERMES, SAM and TOM mutants (i.e. large spherical mitochondria), and Mdm31 and Mdm32 are required to organize mtDNA into nucleoids [79]. It is thus likely that MINOS, ERMES and further Mdm proteins functionally cooperate in the maintenance and organization of mtDNA (Figure 2). 190

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Box 2. Outstanding questions  What is the mechanistic role of MINOS in the formation and maintenance of crista junctions?  What are the physiological consequences of the segregation of cristae tubules from the inner boundary membrane in MINOS mutants?  How dynamic are the ERMES and MINOS complexes and which factors regulate their assembly state? Do ERMES and MINOS directly interact with each other or are further components involved?  How are the different phenotypes associated with mutations of ERMIONE components, including membrane morphology, lipid metabolism, protein biogenesis and mtDNA maintenance, related to each other at the molecular level? Are subcomplexes of MINOS or ERMES responsible for distinct functions?  Are MINOS or ERMES involved in mitochondrial or ER functions during programmed cell death?  Is there a signaling pathway extending from the mitochondrial matrix via MINOS and ERMES to the ER lumen and eventually to the nucleus?

Taken together, we propose that ERMES and MINOS are linked into an ER–mitochondria organizing network (ERMIONE) that includes machineries for protein biogenesis, lipid metabolism, metabolite and ion transport, and mtDNA organization. ER–mitochondria interaction sites have also been shown to be related to sites of mitochondrial division [92] although the molecular mechanisms are not yet known. Cristae remodeling can occur during mitochondrial steps of apoptosis [16,40,93–96]. Future studies will need to address whether MINOS, ERMES and further components of ERMIONE play a role in mitochondrial fission and apoptotic events. Concluding remarks Morphological and genetic studies led to the suggestion that there could be a multi-membrane-spanning connection from ERMES across the mitochondrial membranes to mtDNA nucleoids [63,64,75,76,79,80,91]. However, only limited information was available on the molecular composition and structural arrangement of such an organizing center. The identification of MINOS and its multiple interactions provide a new view on mitochondrial architecture and biogenesis. MINOS forms a large scaffold and interaction platform that connects to outer-membrane complexes, including ERMES, as well as to machineries inside mitochondria. The hypothesis of a large ER–mitochondria organizing network (ERMIONE) will provide a platform for research on the integrative organization of mitochondrial functions and a number of exciting questions for future research remain (Box 2). Acknowledgments This work has been supported by the Deutsche Forschungsgemeinschaft, the Excellence Initiative of the German Federal & State Governments (EXC 294), the Gottfried Wilhelm Leibniz Program, Sonderforschungsbereich 746, Landesforschungspreis Baden-Wu¨rttemberg, and the Bundesministerium fu¨r Bildung und Forschung.

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