In the inner mitochondrial membrane, the respiratory chain complexes generate an electrochemical proton gradient, which is utilized to synthesize most of the cellular ATP. According to an increasing number of biochemical studies, these complexes are assembled into supercomplexes. However, little is known about the architecture of the proposed multicomplex assemblies. Here, we report the electron microscopic characterization of the two respiratory chain supercomplexes I 1 III 2 and I 1 III 2 IV 1 in bovine heart mitochondria, which are also two major supercomplexes in human mitochondria. After purification and demonstration of enzymatic activity, their structures in projection were determined by single particle image analysis. A difference map between the supercomplexes I 1 III 2 and I 1 III 2 IV 1 closely fits the x-ray structure of monomeric complex IV and shows its location in the assembly. By comparing different views of supercomplex I 1 III 2 IV 1 , the location and mutual arrangement of complex I and the complex III dimer are discussed. Detailed knowledge of the architecture of the active supercomplexes is a prerequisite for a deeper understanding of energy conversion by mitochondria in mammals.All living organisms use a series of integral membrane protein complexes for energy conversion and ATP synthesis. In eukaryotes, electrons are transported by the respiratory chain, starting from NADH via complex I (NADH:ubiquinone oxidoreductase) or from succinate via complex II (succinate:ubiquinone oxidoreductase), the membrane integral electron carrier ubiquinol, complex III (ubiquinol:cytochrome c oxidoreductase), the peripheral electron carrier cytochrome c, and complex IV (cytochrome c oxidase) to the terminal acceptor molecular oxygen (1). The electron transport chain generates a proton gradient across the inner mitochondrial membrane, which is used by complex V (F O F 1 -ATP synthase) to synthesize ATP. In the last decade, structures of the individual respiratory chain complexes from various organisms have been determined. Atomic models exist for bovine heart mitochondrial complex III (2) and IV (3). A high resolution structure of complex I is not yet available, but electron microscopy indicates that it is L-shaped in all organisms investigated, and a 2.2-nm resolution map from cryoelectron microscopy exists for the bovine heart complex I (4).Two alternative models for the arrangement of the respiratory chain complexes in the membrane have been proposed. According to the currently favored random collision model (5), all components of the respiratory chain diffuse individually in the membrane, and electron transfer depends on the random, transient encounter of the individual protein complexes and the smaller electron carriers. In the solid state model (6) proposed 50 years ago, the substrate is channeled directly from one enzyme to the next. Recently isolated stoichiometric assemblies, so-called supercomplexes, support this model. Respiratory supercomplexes of different compositions have been described in bact...
To elucidate the molecular basis of the link between respiration and longevity, we have studied the organization of the respiratory chain of a wild-type strain and of two long-lived mutants of the filamentous fungus Podospora anserina. This established aging model is able to respire by either the standard or the alternative pathway. In the latter pathway, electrons are directly transferred from ubiquinol to the alternative oxidase and thus bypass complexes III and IV. We show that the cytochrome c oxidase pathway is organized according to the mammalian "respirasome" model (Schä gger, H., and Pfeiffer, K. (2000) EMBO J. 19, 1777-1783). In contrast, the alternative pathway is composed of distinct supercomplexes of complexes I and III (i.e. I 2 and I 2 III 2 ), which have not been described so far. Enzymatic analysis reveals distinct functional properties of complexes I and III belonging to either cytochrome c oxidase-or alternative oxidase-dependent pathways. By a gentle colorless-native PAGE, almost all of the ATP synthases from mitochondria respiring by either pathway were preserved in the dimeric state. Our data are of significance for the understanding of both respiratory pathways as well as lifespan control and aging.
In accordance with their manifold tasks, various dysfunctions of mitochondria are critically involved in a large number of diseases and the aging process. This has inspired considerable efforts to identify all the mitochondrial proteins by denaturing approaches, notably, the standard gel-based method employing isoelectric focusing. Because a significant part of the mitochondrial proteome is membrane-associated and/or functions as homo- or heterooligomeric protein complexes, there is an urgent need to detect and identify mitochondrial proteins, both membranous and soluble ones, under conditions preserving protein-protein interactions. Here, we investigated mitochondria of five different rat organs (kidney, liver, heart, skeletal muscle, and brain) solubilized with digitonin, enabling the quantitative extraction of the five oxidative phosphorylation (OXPHOS) complexes. The analysis by blue-native (BN)-PAGE recovered the OXPHOS complexes to a large extent as supercomplexes and separated many other protein complexes and individual proteins which were resolved by subsequent 2D SDS-PAGE revealing the tissue-diverse mitochondrial proteomes. Using MS peptide mass fingerprinting, we identified in all five organs 92 nonredundant soluble and membrane-embedded non-OXPHOS proteins, among them, many as constituents of known mitochondrial protein complexes as well as novel ones such as the putative "stomatin-like protein 2 complex" with an apparent mass of ca. 1800 kDa. Interestingly, the identification list included 36 proteins known or presumed to be localized to nonmitochondrial compartments, for example, glycolytic enzymes, clathrin heavy chain, valosin-containing protein/p97, VoV1-ATPase, and Na,K-ATPase. We expect that more than 200 distinct non-OXPHOS proteins of digitonin-solubilized rat mitochondria separated by 2D BN/SDS-PAGE, representing a partial "protein interactome" map, can be identified.
Higher plant mitochondria have many unique features compared with their animal and fungal counterparts. This is to a large extent related to the close functional interdependence of mitochondria and chloroplasts, in which the two ATP-generating processes of oxidative phosphorylation and photosynthesis, respectively, take place. We show that digitonin treatment of mitochondria contaminated with chloroplasts from spinach (Spinacia oleracea) green leaves at two different buffer conditions, performed to solubilize oxidative phosphorylation supercomplexes, selectively extracts the mitochondrial membrane protein complexes and only low amounts of stroma thylakoid membrane proteins. By analysis of digitonin extracts from partially purified mitochondria of green leaves from spinach using blue and colorless native electrophoresis, we demonstrate for the first time that in green plant tissue a substantial proportion of the respiratory complex IV is assembled with complexes I and III into "respirasome"-like supercomplexes, previously observed in mammalian, fungal, and non-green plant mitochondria only. Thus, fundamental features of the supramolecular organization of the standard respiratory complexes I, III, and IV as a respirasome are conserved in all higher eukaryotes. Because the plant respiratory chain is highly branched possessing additional alternative enzymes, the functional implications of the occurrence of respiratory supercomplexes in plant mitochondria are discussed.
Analysis of the protein profile of mitochondria and its age-dependent variation is a promising approach to unravel mechanisms involved in aging and age-related diseases. Our studies focus on the mammalian mitochondrial membrane proteome, especially of the inner mitochondrial membrane with the respiratory chain complexes and other proteins possibly involved in life-span control and aging. Variations of the mitochondrial proteome during aging, with the emphasis on the abundance, composition, structure, and activity of membrane proteins, are examined in various rat tissues by native polyacrylamide gel electrophoresis techniques in combination with MALDI-TOF mass spectrometry. In rat brain, age-modulated differences in the abundance of various mitochondrial and nonmitochondrial proteins, such as Na,K-ATPase, HSP60, mitochondrial aconitase-2, V-type ATPase, MF(o)F(1) ATP synthase, and the OXPHOS complexes I-IV are detected. During aging, a decrease in the amount of intact MF(o)F(1) ATP synthase occurs in the cortex. As analytical technique, native PAGE separates not only individual proteins but also multi-subunit (membrane) proteins, (membrane) protein supercomplexes as well as interacting proteins in their native state. It reveals the occurrence and architecture of supramolecular assemblies of proteins. The age-related alterations in the oligomerization of the MF(o)F(1) ATP synthase observed by us in rat cortex might be one clue for understanding the link between respiration and longevity. Also, the abundance of OXPHOS supercomplexes, that is, the natural assemblies of the respiratory complexes I, III, and IV into supramolecular stoichiometric entities, such as I(1)III(2)IV(0-4), can differ between young and aged cortex tissue. Age-related changes in the supramolecular architecture of OXPHOS complexes might explain alterations in ROS production during aging.
Blue-native and colorless-native gel electrophoresis combined with subsequent 2D-SDS-PAGE and MALDI mass spectrometry are successfully applied for understanding the role of mitochondria in cellular dysfunction, aging, and cellular death. The partial mitochondrial proteome maps of various tissues (liver, brain, kidney, heart, and skeletal muscle) obtained from rat serve now as a database for the elucidation of age-dependent changes, including alterations in protein-protein interactions as well as in posttranslational modifications.
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