Your search keyword '"Mitochondrial carrier"' showing total 36 results

1. The switching mechanism of the mitochondrial ADP/ATP carrier explored by free-energy landscapes

Author

Ciro Leonardo Pierri, Ferdinando Palmieri, Martin Klingenberg, and Adriana Pietropaolo

Subjects

Models, Molecular, 0301 basic medicine, Adenosine monophosphate, Biophysics, 010402 general chemistry, 01 natural sciences, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Adenosine Triphosphate, Binding site, Binding Sites, Molecular Structure, Metadynamics, Biological Transport, Cell Biology, Mitochondrial carrier, Adenosine Monophosphate, Mitochondria, Protein Structure, Tertiary, 0104 chemical sciences, Adenosine Diphosphate, Transmembrane domain, Crystallography, Adenosine diphosphate, 030104 developmental biology, chemistry, Thermodynamics, ATP–ADP translocase, Mitochondrial ADP, ATP Translocases, Adenosine triphosphate, Protein Binding

Abstract

The ADP/ATP carrier (AAC) of mitochondria has been an early example for elucidating the transport mechanism alternating between the external (c-) and internal (m-) states (M. Klingenberg, Biochim. Biophys. Acta 1778 (2008) 1978-2021). An atomic resolution crystal structure of AAC is available only for the c-state featuring a three repeat transmembrane domain structure. Modeling of transport mechanism remained hypothetical for want of an atomic structure of the m-state. Previous molecular dynamics studies simulated the binding of ADP or ATP to the AAC remaining in the c-state. Here, a full description of the AAC switching from the c- to the m-state is reported using well-tempered metadynamics simulations. Free-energy landscapes of the entire translocation from the c- to the m-state, based on the gyration radii of the c- and m-gates and of the center of mass, were generated. The simulations revealed three free-energy basins attributed to the c-, intermediate- and m-states separated by activation barriers. These simulations were performed with the empty and with the ADP- and ATP-loaded AAC as well as with the poorly transported AMP and guanine nucleotides, showing in the free energy landscapes that ADP and ATP lowered the activation free-energy barriers more than the other substrates. Upon binding AMP and guanine nucleotides a deeper free-energy level stabilized the intermediate-state of the AAC2 hampering the transition to the m-state. The structures of the substrate binding sites in the different states are described producing a full picture of the translocation events in the AAC.

Published

2016

2. Calcium-induced conformational changes in the regulatory domain of the human mitochondrial ATP-Mg/Pi carrier

Author

Steven P. D. Harborne, Jonathan J. Ruprecht, and Edmund R.S. Kunji

Subjects

LMNG, lauryl maltose neopentyl glycol, Biophysics, chemistry.chemical_element, Calcium, Biology, Biochemistry, Article, RD, regulatory domain, Regulation of adenine nucleotides, Adenine nucleotide, Inner mitochondrial membrane, APC, ATP-Mg/Pi carrier, EF-hand conformational change, Calcium metabolism, SCaMC, Adenine nucleotide translocase, RMSD, root-mean-squared deviation, EGTA, ethylene glycol tetraacetic acid, SCaMC, short calcium binding mitochondrial carrier, Cell Biology, Mitochondrial carrier, Transport protein, Cytosol, chemistry, DTT, dithiothreitol, Mitochondrial matrix, SEC, size exclusion chromatography, Calcium regulation mechanism

Abstract

The mitochondrial ATP-Mg/Pi carrier imports adenine nucleotides from the cytosol into the mitochondrial matrix and exports phosphate. The carrier is regulated by the concentration of cytosolic calcium, altering the size of the adenine nucleotide pool in the mitochondrial matrix in response to energetic demands. The protein consists of three domains; (i) the N-terminal regulatory domain, which is formed of two pairs of fused calcium-binding EF-hands, (ii) the C-terminal mitochondrial carrier domain, which is involved in transport, and (iii) a linker region with an amphipathic α-helix of unknown function. The mechanism by which calcium binding to the regulatory domain modulates substrate transport in the carrier domain has not been resolved. Here, we present two new crystal structures of the regulatory domain of the human isoform 1. Careful analysis by SEC confirmed that although the regulatory domain crystallised as dimers, full-length ATP-Mg/Pi carrier is monomeric. Therefore, the ATP-Mg/Pi carrier must have a different mechanism of calcium regulation than the architecturally related aspartate/glutamate carrier, which is dimeric. The structure showed that an amphipathic α-helix is bound to the regulatory domain in a hydrophobic cleft of EF-hand 3/4. Detailed bioinformatics analyses of different EF-hand states indicate that upon release of calcium, EF-hands close, meaning that the regulatory domain would release the amphipathic α-helix. We propose a mechanism for ATP-Mg/Pi carriers in which the amphipathic α-helix becomes mobile upon release of calcium and could block the transport of substrates across the mitochondrial inner membrane., Graphical abstract, Highlights • The mechanism of calcium-regulation in the ATP-Mg/Pi carrier is unresolved. • The human ATP-Mg/Pi carrier is monomeric in the presence and absence of calcium. • In the presence of calcium an amphipathic α-helix binds in a cleft of EF-hand 3/4. • Without calcium the amphipathic α-helix is released from the regulatory domain. • Regulation could occur by the amphipathic α-helix blocking substrate translocation.

Published

2015

3. Mitochondrial carriers function as monomers

Author

Paul G. Crichton and Edmund R.S. Kunji

Subjects

Models, Molecular, Detergent, Saccharomyces cerevisiae Proteins, Protein Conformation, Detergents, Oligomeric state, Biophysics, Crystallography, X-Ray, Microscopy, Atomic Force, Biochemistry, Chromatography, Affinity, Protein–protein interaction, Mitochondrial Proteins, Scattering, Small Angle, Animals, Freeze Fracturing, Humans, Electrophoresis, Gel, Two-Dimensional, Electrochemical gradient, Inner mitochondrial membrane, Protein Structure, Quaternary, Chemistry, Cryoelectron Microscopy, Cell Biology, Lipid, Mitochondrial carrier, Mitochondria, Cytosol, Neutron Diffraction, Mitochondrial matrix, Membrane protein, Chromatography, Gel, Mutagenesis, Site-Directed, ATP–ADP translocase, Salt bridge, Transport mechanism, Carrier Proteins, Mitochondrial ADP, ATP Translocases, Ultracentrifugation

Abstract

Mitochondrial carriers link biochemical pathways in the mitochondrial matrix and cytosol by transporting metabolites, inorganic ions, nucleotides and cofactors across the mitochondrial inner membrane. Uncoupling proteins that dissipate the proton electrochemical gradient also belong to this protein family. For almost 35years the general consensus has been that mitochondrial carriers are dimeric in structure and function. This view was based on data from inhibitor binding studies, small-angle neutron scattering, electron microscopy, differential tagging/affinity chromatography, size-exclusion chromatography, analytical ultracentrifugation, native gel electrophoresis, cross-linking experiments, tandem-fusions, negative dominance studies and mutagenesis. However, the structural folds of the ADP/ATP carriers were found to be monomeric, lacking obvious dimerisation interfaces. Subsequently, the yeast ADP/ATP carrier was demonstrated to function as a monomer. Here, we revisit the data that have been published in support of a dimeric state of mitochondrial carriers. Our analysis shows that when critical factors are taken into account, the monomer is the only plausible functional form of mitochondrial carriers. We propose a transport model based on the monomer, in which access to a single substrate binding site is controlled by two flanking salt bridge networks, explaining uniport and strict exchange of substrates.

Published

2010

4. Characterization of two different acyl carrier proteins in complex I from Yarrowia lipolytica

Author

Stefan Kerscher, Ulrich Brandt, Krzysztof Dobrynin, Carola Hunte, Albina Abdrakhmanova, and Sebastian Richers

Subjects

Proteomics, Yarrowia lipolytica, Protein subunit, Blotting, Western, Biophysics, Yarrowia, Mitochondrion, Assembly defect, Biochemistry, Fungal Proteins, Mitochondrial Proteins, Mitochondrial acyl carrier protein, Organelle, Complex I, Acyl Carrier Protein, ACPM, Electrophoresis, Gel, Two-Dimensional, Cloning, Molecular, Phosphorylation, Alanine, Electron Transport Complex I, biology, Lipid metabolism, Cell Biology, Lipid Metabolism, biology.organism_classification, Mitochondrial carrier, Mitochondria, Protein Subunits, Mitochondrial matrix, Mitochondrial Membranes, Gene Deletion

Abstract

Acyl carrier proteins of mitochondria (ACPMs) are small (approximately 10 kDa) acidic proteins that are homologous to the corresponding central components of prokaryotic fatty acid synthase complexes. Genomic deletions of the two genes ACPM1 and ACPM2 in the strictly aerobic yeast Yarrowia lipolytica resulted in strains that were not viable or retained only trace amounts of assembled mitochondrial complex I, respectively. This suggested different functions for the two proteins that despite high similarity could not be complemented by the respective other homolog still expressed in the deletion strains. Remarkably, the same phenotypes were observed if just the conserved serine carrying the phosphopantethein moiety was exchanged with alanine. Although this suggested a functional link to the lipid metabolism of mitochondria, no changes in the lipid composition of the organelles were found. Proteomic analysis revealed that both ACPMs were tightly bound to purified mitochondrial complex I. Western blot analysis revealed that the affinity tagged ACPM1 and ACPM2 proteins were exclusively detectable in mitochondrial membranes but not in the mitochondrial matrix as reported for other organisms. Hence we conclude that the ACPMs can serve all their possible functions in mitochondrial lipid metabolism and complex I assembly and stabilization as subunits bound to complex I.

Published

2010

5. Energetics of protein translocation into mitochondria

Author

Walter Neupert and Dejana Mokranjac

Subjects

Biophysics, Oxidative folding, Mitochondrion, Models, Biological, Biochemistry, Mitochondrial membrane transport protein, Cysteine, Membrane potential, biology, Proteins, Cell Biology, Mitochondrial carrier, Mitochondria, Transport protein, Cell biology, ATP, Protein Transport, Mitochondrial Membranes, Translocase of the inner membrane, biology.protein, Driving force, ATP–ADP translocase, Carrier Proteins, Energy Metabolism, Energy source, Biogenesis

Abstract

Biogenesis of mitochondria depends on the coordinated action of at least six protein translocases present in both mitochondrial membranes. They use different energy sources to drive unidirectional transport of proteins across and into mitochondrial membranes. Here we present an overview on the energetic requirements of different mitochondrial import pathways.

Published

2008

6. Enolase takes part in a macromolecular complex associated to mitochondria in yeast

Author

James L. Graham, Christelle Lemaitre-Guillier, Ivan Tarassov, Nina Entelis, Lee J. Sweetlove, Robert P. Martin, Irina Brandina, Igor A. Krasheninnikov, Génétique moléculaire, génomique, microbiologie (GMGM), Université Louis Pasteur - Strasbourg I-Centre National de la Recherche Scientifique (CNRS), and Dalhousie University [Halifax]

Subjects

Lysine-tRNA Ligase, Saccharomyces cerevisiae Proteins, MESH: Mitochondria, Saccharomyces cerevisiae, Enolase, Biophysics, Biology, Mitochondrion, MESH: RNA, Transfer, Lys, MESH: Phosphopyruvate Hydratase, Biochemistry, MESH: Enzyme Precursors, 03 medical and health sciences, MESH: Saccharomyces cerevisiae Proteins, Immunoprecipitation, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, Inner mitochondrial membrane, 030304 developmental biology, Enzyme Precursors, 0303 health sciences, MESH: Immunoprecipitation, MESH: Lysine-tRNA Ligase, 030302 biochemistry & molecular biology, tRNA import, Cell Biology, MESH: Multiprotein Complexes, biology.organism_classification, Mitochondrial carrier, MESH: Saccharomyces cerevisiae, Mitochondria, Citric acid cycle, Cytosol, Multiprotein Complexes, Phosphopyruvate Hydratase, MESH: Glycolysis, Transfer RNA, RNA, Transfer, Lys, Electrophoresis, Polyacrylamide Gel, Glycolysis, MESH: Electrophoresis, Polyacrylamide Gel

Abstract

In eucaryotes, glycolytic enzymes are classically regarded as being localised in the cytosol. Recently, we have shown that part of the cellular pool of the glycolytic enzyme, enolase, is tightly associated with the mitochondrial surface in the yeast Saccharomyces cerevisiae (N. Entelis, I. Brandina, P. Kamenski, I.A. Krasheninnikov, R.P. Martin and I. Tarassov, A glycolytic enzyme, enolase, is recruited as a cofactor of tRNA targeting toward mitochondria in Saccharomyces cerevisiae, Genes Dev. 20 (2006) 1609-1620). Here, using enzymatic assays, we show that all glycolytic enzymes are associated with mitochondria in yeast, to extents similar to those previously reported for Arabidopsis cells. Using separation of mitochondrial complexes by blue-native/SDS-PAGE and coimmunoprecipitation of mitochondrial proteins with anti-enolase antibodies, we found that enolase takes part in a large macromolecular complex associated to mitochondria. The identified components included additional glycolytic enzymes, mitochondrial membrane carriers, and enzymes of the TCA cycle. We suggest a possible role of the enolase complex in the channeling of pyruvate, the terminal product of glycolysis, towards the TCA cycle within mitochondria. Moreover, we show that the mitochondrial enolase-containing complex also contains the cytosolic tRNACUULys, which is mitochondrially-imported, and its presumed import carrier, the precursor of the mitochondrial lysyl-tRNA synthetase. This suggests an unsuspected novel function for this complex in tRNA mitochondrial import.

Published

2006

7. MTERF3, the most conserved member of the mTERF-family, is a modular factor involved in mitochondrial protein synthesis

Author

Caterina Manzari, Maria Nicola Gadaleta, Paola Loguercio Polosa, Palmiro Cantatore, Marina Roberti, and Francesco Bruni

Subjects

Sequence analysis, Mitochondrial translation, RNA, Mitochondrial, Molecular Sequence Data, Biophysics, Mitochondrion, Biology, Biochemistry, Mitochondrial Proteins, Transcription (biology), mitochondrial protein synthesis, Animals, Drosophila Proteins, Amino Acid Sequence, RNA, Messenger, Conserved Sequence, HSPA9, Genetics, Cell Biology, Mitochondrial carrier, mitochondria, Drosophila melanogaster, Gene Expression Regulation, Protein Biosynthesis, MTERF3, DNAJA3, RNA, Drosophila, RNA Interference, ATP–ADP translocase, mTERF, Sequence Alignment

Abstract

The MTERF-family is a wide family of proteins identified in Metazoa and plants which includes the known mitochondrial transcription termination factors. With the aim to shed light on the function of MTERF-family members in Drosophila, we performed the cloning and characterization of D-MTERF3, a component of the most conserved group of this family. D-MTERF3 is a mitochondrial protein of 323 amino acids. Sequence analysis in seven different organisms showed that the protein contains five conserved “mTERF-motifs”, three of which include a leucine zipper-like domain. D-MTERF3 knock-down, obtained by RNAi in D.Mel-2 cells, did not affect mitochondrial replication and transcription. On the contrary, it decreased to a variable extent the rate of labelling of about half of the mitochondrial polypeptides, with ND1 being the most affected by D-MTERF3 depletion. These results indicate that D-MTERF3 is involved in mitochondrial translation. This role, likely based on protein–protein interactions, may be exerted either through a direct interaction with the translation machinery or by bridging the mitochondrial transcription and translation apparatus.

Published

2006

8. The protein import and assembly machinery of the mitochondrial outer membrane

Author

Rebecca D. Taylor and Nikolaus Pfanner

Subjects

SAM complex, Translocase of the outer membrane, Biophysics, Receptors, Cell Surface, TIM/TOM complex, Mitochondrial Membrane Transport Proteins, Biochemistry, Protein sorting, Evolution, Molecular, 03 medical and health sciences, Mitochondrial membrane transport protein, 0302 clinical medicine, TOM complex, Mitochondrial Precursor Protein Import Complex Proteins, Protein Precursors, Inner mitochondrial membrane, Sorting and assembly machinery, 030304 developmental biology, 0303 health sciences, biology, Protein assembly, Porin, Membrane Transport Proteins, Intracellular Membranes, Cell Biology, Mitochondrial carrier, Mitochondria, Cell biology, Mitochondrial biogenesis, Translocase of the inner membrane, biology.protein, 030217 neurology & neurosurgery

Abstract

The process of mitochondrial protein import has been studied for many years. Despite this attention, many processes associated with mitochondrial biogenesis are poorly understood. Insight into one of these processes, assembly of beta-barrel proteins into the mitochondrial outer membrane, will be discussed. This review focuses on recent data that suggest that assembly of beta-barrel proteins into the outer mitochondrial membrane is dependent on a newly identified protein complex termed the sorting and assembly machinery (SAM complex). Members of the SAM complex have been identified in both eukaryotic and prokaryotic organisms, suggesting that the process of beta-barrel assembly into membranes has been conserved through evolution.

Published

2004

9. Structure of a complete mitochondrial ATP synthase dimer reveals molecular basis of inner membrane morphology

Author

Deryck J. Mills, Janet Vonck, Werner Kühlbrandt, Alexander Hahn, and Thomas Meier

Subjects

Morphology (linguistics), Dimer, Biophysics, Cell Biology, Mitochondrial carrier, Biochemistry, Crista, chemistry.chemical_compound, chemistry, Translocase of the inner membrane, Inner membrane, ATP–ADP translocase, Inner mitochondrial membrane

Published

2016

10. Expression of the bovine heart mitochondrial ADP/ATP carrier in yeast mitochondria: significantly enhanced expression by replacement of the N-terminal region of the bovine carrier by the corresponding regions of the yeast carriers

Author

Hiroshi Terada, Naoshi Yamazaki, Yasuo Shinohara, Takashi Hatanaka, Eiji Majima, and Mitsuru Hashimoto

Subjects

Molecular Sequence Data, Saccharomyces cerevisiae, Biophysics, Mitochondrion, Biochemistry, Mitochondria, Heart, Animals, Oxidative phosphorylation, Amino Acid Sequence, Inner mitochondrial membrane, Heart metabolism, biology, Functional expression of mammalian protein, Biological Transport, Chimeric recombination, Cell Biology, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Mitochondrial carrier, Mitochondria, Cytosol, ADP transport, Mutation, ADP/ATP carrier, Cattle, ATP–ADP translocase, Mitochondrial ADP, ATP Translocases, Plasmids

Abstract

To characterize the transport mechanism mediated by the mammalian mitochondrial ADP/ATP carrier (AAC), we tried to express bovine heart mitochondrial AAC (bhAAC) in Saccharomyces cerevisiae. The open reading frame of the bhAAC was introduced into the haploid strain WB-12, in which intrinsic AAC genes were disrupted. Growth of the transformant was very low in glycerol medium, and a little amount of bhAAC was detected in the mitochondrial membrane. For improvement of bhAAC expression in WB-12, we introduced DNA fragments encoding chimeric bhAACs, in which the N-terminal region of the bhAAC extending into the cytosol was replaced by the corresponding regions of the type 1 and type 2 yeast AAC isoforms (yAAC1 and yAAC2). These transformants grew well, and the amounts of the chimeric bhAACs in their mitochondria were as high as that of yAAC2. The carriers expressed showed essentially the same ADP transport activities as that of AAC in bovine heart mitochondria.

Published

1999

11. Quantification of active mitochondrial permeability transition pores using GNX-4975 inhibitor titrations provides insights into molecular identity

Author

Andrew P. Halestrap and Andrew P. Richardson

Subjects

Male, Stereochemistry, animal diseases, Biophysics, Mitochondria, Liver, Biology, Mitochondrial Membrane Transport Proteins, Biochemistry, chemistry.chemical_compound, Cyclosporin a, Animals, adenine nucleotide translocase, Phenylarsine oxide, Rats, Wistar, Inner mitochondrial membrane, mitochondrial phosphate carrier, Research Articles, Oxidoreductases Acting on CH-NH Group Donors, calcium, Binding Sites, mitochondrial permeability transition pores, Mitochondrial Permeability Transition Pore, MPTP, Nitrilotriacetic acid, Adenine Nucleotide Translocator 1, Cell Biology, Mitochondrial carrier, inhibition, nervous system diseases, Rats, Dissociation constant, Proton-Translocating ATPases, nervous system, chemistry, Mitochondrial permeability transition pore, cardiovascular system, molecular mechanism, Research Article

Abstract

The molecular identity of the mitochondrial permeability transition pore (MPTP), a key player in cell death, remains controversial. Here we use a novel MPTP inhibitor to demonstrate that formation of the pore involves native mitochondrial membrane proteins adopting novel conformations., Inhibition of the mitochondrial permeability transition pore (MPTP) by the novel inhibitor GNX-4975 was characterized. Titration of MPTP activity in de-energized rat liver mitochondria allowed determination of the number of GNX-4975-binding sites and their dissociation constant (Ki). Binding sites increased in number when MPTP opening was activated by increasing [Ca2+], phenylarsine oxide (PAO) or KSCN, and decreased when MPTP opening was inhibited with bongkrekic acid (BKA) or ADP. Values ranged between 9 and 50 pmol/mg of mitochondrial protein, but the Ki remained unchanged at ∼1.8 nM when the inhibitor was added before Ca2+. However, when GNX-4975 was added after Ca2+ it was much less potent with a Ki of ∼140 nM. These data imply that a protein conformational change is required to form the MPTP complex and generate the GNX-4975-binding site. Occupation of the latter with GNX-4975 prevents the Ca2+ binding that triggers pore opening. We also demonstrated that GNX-4975 stabilizes an interaction between the adenine nucleotide translocase (ANT), held in its ‘c’ conformation with carboxyatractyloside (CAT), and the phosphate carrier (PiC) bound to immobilized PAO. No components of the F1Fo-ATP synthase bound significantly to immobilized PAO. Our data are consistent with our previous proposal that the MPTP may form at an interface between the PiC and ANT (or other similar mitochondrial carrier proteins) when they adopt novel conformations induced by factors that sensitize the MPTP to [Ca2+]. We propose that GNX-4975 binds to this interface preventing a calcium-triggered event that opens the interface into a pore.

Published

2016

12. Mitochondrial carrier structure and diseases

Author

Palmieri Ferdinando and Pierri Ciro Leonardo

Subjects

Chemistry, Biophysics, Cell Biology, Mitochondrial carrier, Biochemistry

Published

2012

13. Function of the outer mitochondrial compartment in regulation of energy metabolism

Author

Dieter Brdiczka

Subjects

biology, Kinase, Muscles, Adenine nucleotide translocator, Phosphotransferases, Biophysics, Brain, Porins, Mitochondria, Liver, Cell Biology, Creatine, Mitochondrial carrier, Biochemistry, Oxidative Phosphorylation, Mitochondria, Phosphocreatine, chemistry.chemical_compound, chemistry, biology.protein, Animals, Creatine kinase, Kinase activity, Energy Metabolism, Inner mitochondrial membrane

Abstract

Electron microscopy showed the organization of several kinases at the mitochondrial surface as complexes between outer membrane (porin), kinase, and inner membrane (presumably adenine nucleotide translocator?). The complexes were enriched in the isolated contact site fraction. Interaction of porin with the kinases in vitro led to formation of tetramers of hexokinase and active creatine kinase. Kinetic analyses of mitochondria with intact outer compartment showed separate ATP/ADP exchange between kinases and oxidative phosphorylation. Considering these results, we postulate that the mitochondrial metabolism in intact cells is not regulated by free ADP, but induced by substrates wf kinases such as glucose or creatine (Fig 1). Increased ATP turnover in muscle during contraction results in only a small change in the free ADP but causes a larger change of creatine because the equilibrium constant of the creatine kinase reaction at pH 7.2 favours ATP formation (ATP creatine/ADP phosphocreatine = 104.7) [38]. In addition, the level of phosphocreatine is roughly 10-times higher compared to ATP. Considering the higher concentration and the equilibrium constant, it can be calculated that a change of ADP between 40 and 70 microM results in creatine increasing from 8 to 12 mM. Thus creatine can be the signal that stimulates the mitochondrial metabolism transmitted by the mitochondrial creatine kinase [39]. Likewise, increased blood glucose in muscle at rest or in the liver stimulates the mitochondrial metabolism transmitted by the activity of bound hexokinase utilizing external ATP. The mitochondrial metabolism provides the UTP for glycogen synthesis through mitochondrial nucleoside-diphosphate kinase activity (Fig 1).

Published

1994

14. Establishing the role of the mitochondrial carrier MTCH2

Author

Atan Gross, Edmund R.S. Kunji, and Alan J. Robinson

Subjects

Chemistry, Biophysics, Cell Biology, Mitochondrial carrier, Biochemistry, Cell biology

Published

2010

15. Binding of the inhibitor proteins IF1 to mitochondrial F1-ATPases

Author

John V. Bason, Graham C. Robinson, Ian M. Fearnley, Michael J. Runswick, and John E. Walker

Subjects

0106 biological sciences, Inhibitor of apoptosis domain, 0303 health sciences, biology, Chemistry, ATPase, Bcl-2 family, Biophysics, Cell Biology, Mitochondrial carrier, 01 natural sciences, Biochemistry, Cell biology, 03 medical and health sciences, DNAJA3, biology.protein, ATP–ADP translocase, 030304 developmental biology, 010606 plant biology & botany

Published

2010

16. S5.8 Biogenesis of the mitochondrial carrier translocase

Author

Katrin Brandner, Karina Wagner, Peter Rehling, Bernard Guiard, and Nikolaus Pfanner

Subjects

biology, Chemistry, Translocase of the outer membrane, Biophysics, TIM/TOM complex, Cell Biology, Mitochondrial carrier, Biochemistry, Cell biology, Translocase of the inner membrane, biology.protein, Translocase, ATP–ADP translocase, Intermembrane space, Biogenesis

Published

2008

17. Identification of the mammalian mitochondrial pyruvate carrier

Author

Andrew P. Halestrap and Chloe Ls. Burns

Subjects

0106 biological sciences, 0303 health sciences, Pyruvate dehydrogenase lipoamide kinase isozyme 1, Chemistry, Biophysics, Cell Biology, Pyruvate carrier, PKM2, Mitochondrial carrier, 01 natural sciences, Biochemistry, 03 medical and health sciences, Identification (biology), 030304 developmental biology, 010606 plant biology & botany

Published

2010

18. Structure and evolution of mitochondrial outer membrane proteins

Author

Kornelius Zeth

Subjects

biology, Chemistry, Translocase of the outer membrane, Peripheral membrane protein, Biophysics, Cell Biology, Mitochondrial carrier, Biochemistry, Mitochondrial membrane transport protein, Membrane protein, Translocase of the inner membrane, biology.protein, Outer membrane efflux proteins, Inner mitochondrial membrane

Published

2010

19. P/16 Uncoupling Protein 2: Physiology data and biochemistry questions

Author

M. Mar González-Barroso, Yalin Emre, Claire Pecqueur, Daniel Ricquier, Bruno Miroux, Frédéric Bouillaud, and Tobias Nübel

Subjects

Catabolism, Chemistry, Neurodegeneration, Autophagy, Biophysics, Inflammation, Cell Biology, Carbohydrate metabolism, medicine.disease, Mitochondrial carrier, Biochemistry, Glutamine, medicine, medicine.symptom, Beta oxidation

Abstract

The mitochondrial Uncoupling Protein 2 UCP2 is a member of the mitochondrial carrier family and belongs to the UCP subfamily. It is widely expressed in tissues. In immune cells, UCP2 has a regulatory function through its effect on the production of reactive oxygen species and MAPK signalling. Ucp2 mice are resistant to infection by parasites and intracellular bacteria but are more sensitive to chronic inflammation and experimental neurodegeneration. We found that autoimmune diabetes was strongly accelerated in Ucp2 mice compared to Ucp2 mice with increased intra-islet lymphocytic infiltration. These data highlight UCP2 as a new player in autoimmune diabetes. In addition, in agreement with the known inhibitory role of UCP2 on insulin secretion, loss of function of UCP2 contributes to congenital hyperinsulinism in patients. The question of whether UCP2 fully uncouples respiration from ATP synthesis is still debated. Ucp2 cells display enhanced proliferation associated with a metabolic switch from fatty acid oxidation to glucose metabolism. This metabolic switch requires the unrestricted availability of glucose, and Ucp2 cells more readily activate autophagy than wild-type cells when deprived of glucose. Altogether, these results suggest that UCP2 promotes mitochondrial fatty acid oxidation while limiting mitochondrial catabolism of pyruvate. UCP2 expression is also required for efficient oxidation of glutamine in macrophages. This role of UCP2 in glutamine metabolism appears independent from its uncoupling activity.

Published

2008

20. Site-directed mutagenesis of charged amino acids of the human mitochondrial carnitine/acylcarnitine carrier: Insight into the molecular mechanism of transport

Author

Annamaria Tonazzi, Ferdinando Palmieri, Lara Console, Cesare Indiveri, and Nicola Giangregorio

Subjects

Models, Molecular, Mitochondrial carrier, Protein Conformation, Antiporter, Molecular Sequence Data, Biophysics, Biological Transport, Active, Transport, In Vitro Techniques, Mitochondrion, Biology, Mitochondrial Membrane Transport Proteins, Biochemistry, Carnitine, medicine, Humans, Amino Acid Sequence, Site-directed mutagenesis, Alanine, chemistry.chemical_classification, Binding Sites, Sequence Homology, Amino Acid, Mutagenesis, Cell Biology, Recombinant Proteins, Amino acid, Mitochondria, Kinetics, Amino Acid Substitution, Carnitine Acyltransferases, chemistry, Liposomes, Mutagenesis, Site-Directed, medicine.drug

Abstract

The structure/function relationships of charged residues of the human mitochondrial carnitine/acylcarnitine carrier, which are conserved in the carnitine/acylcarnitine carrier subfamily and exposed to the water-filled cavity of carnitine/acylcarnitine carrier in the c-state, have been investigated by site-directed mutagenesis. The mutants were expressed in Escherichia coli, purified and reconstituted in liposomes, and their transport activity was measured as 3H-carnitine/carnitine antiport. The mutants K35A, E132A, D179A and R275A were nearly inactive with transport activities between 5 and 10% of the wild-type carnitine/acylcarnitine carrier. R178A, K234A and D231A showed transport function of about 15% of the wild-type carnitine/acylcarnitine carrier. The substitutions of the other residues with alanine had little or no effect on the carnitine/acylcarnitine carrier activity. Marked changes in the kinetic parameters with three-fold higher Km and lower Vmax values with respect to the wild-type carnitine/acylcarnitine carrier were found when replacing Lys-35, Glu-132, Asp-179 and Arg-275 with alanine. Double mutants exhibited transport activities and kinetic parameters reflecting those of the single mutants; however, lack of D179A activity was partially rescued by the additional mutation R178A. The results provide evidence that Arg-275, Asp-179 and Arg-178, which protrude into the carrier's internal cavity at about the midpoint of the membrane, are the critical binding sites for carnitine. Furthermore, Lys-35 and Glu-132, which are very probably involved in the salt-bridge network located at the bottom of the cavity, play a major role in opening and closing the matrix gate.

21. The yeast ADP/ATP carrier. Mutagenesis and second-site revertants

Author

David R. Nelson

Subjects

Mitochondrial carrier, Ethanol, ATP transport, Mutant, Molecular Sequence Data, Biophysics, Mutagenesis (molecular biology technique), AAC2, Second-site revertant, Cell Biology, Biology, Biochemistry, Molecular biology, Yeast, chemistry.chemical_compound, Structure-Activity Relationship, chemistry, Mutagenesis, ADP/ATP carrier, Glycerol, ATP–ADP translocase, Amino Acid Sequence, Mitochondrial ADP, ATP Translocases

Abstract

Results of mutagenesis and selection of spontaneous second-site revertants of the yeast ADP/ATP carrier AAC2 is described. Currently, 50 mutants have been made in AAC2 at 35 locations. Yeast carrying mutations at K38, K48, R96, D149, R152, R204, D249, R252, R253, R254 and R294 are all unable to grow on glycerol. Seven of these mutants have yielded second-site revertants when plated on rich yeast media containing glycerol and ethanol. The R96 mutants and the R254 and R253 mutants produce similar changes in the AAC2 molecule because the same sites are affected by their revertant mutations. This system of mutations and revertants is now poised to yield insights into the dynamics of ADP and ATP transport, and mitochondrial carrier structure in general.

22. A novel subfamily of mitochondrial dicarboxylate carriers from Drosophila melanogaster: Biochemical and computational studies

Author

Chiara Carrisi, Marianna Madeo, Gianluca Tasco, Rita Casadio, Emanuela Martello, Vincenza Dolce, Domenico Iacopetta, Loredana Capobianco, Rosita Curcio, Iacopetta D, Madeo M, Tasco G, Carrisi C, Curcio R, Martello E, Casadio R, Capobianco L, Dolce V., Iacopetta, D, Madeo, M, Tasco, G, Carrisi, C, Curcio, R, Martello, E, Casadio, R, Capobianco, Loredana, and Dolce, V.

Subjects

Proteomics, CG4323, Subfamily, Protein Conformation, Molecular Sequence Data, Biophysics, Mitochondrion, Biochemistry, Protein structure, Dicarboxylate carrier, CG18363, Melanogaster, dicarboxylate carrier, Animals, Protein Isoforms, Amino Acid Sequence, Inner mitochondrial membrane, proteomic, chemistry.chemical_classification, Dicarboxylic Acid Transporters, biology, Reverse Transcriptase Polymerase Chain Reaction, CG11196, Computational Biology, Gene Expression Regulation, Developmental, Cell Biology, biology.organism_classification, Mitochondrial carrier, CG8790, Recombinant Proteins, Amino acid, Mitochondria, mitochondria, Drosophila melanogaster, chemistry, Mitochondrial Membranes

Abstract

The dicarboxylate carrier is an important member of the mitochondrial carrier family, which catalyzes an electroneutral exchange across the inner mitochondrial membrane of dicarboxylates for inorganic phosphate and certain sulfur-containing compounds. Screening of the Drosophila melanogaster genome revealed the presence of a mitochondrial carrier subfamily constituted by four potential homologs of mammalian and yeast mitochondrial dicarboxylate carriers designated as DmDic1p, DmDic2p, DmDic3p, and DmDic4p. In this paper, we report that DmDIC1 is broadly expressed at comparable levels in all development stages investigated whereas DmDIC3 and DmDIC4 are expressed only in the pupal stage, no transcripts are detectable for DmDIC2. All expressed proteins are localized in mitochondria. The transport activity of DmDic1-3-4 proteins has been investigated by reconstitution of recombinant purified protein into liposomes. DmDic1p is a typical dicarboxylate carrier showing similar substrate specificity and inhibitor sensitivity as mammalian and yeast mitochondrial dicarboxylate carriers. DmDic3p seems to be an atypical dicarboxylate carrier being able to transport only inorganic phosphate and certain sulfur-containing compounds. No transport activity was observed for DmDic4p. The biochemical results have been supported at molecular level by computing the protein structures and by structural alignments. All together these results indicate that D. melanogaster dicarboxylate carriers form a protein subfamily but the modifications in the amino acids sequences are indicative of specialized functions.

23. Functional characterization and organ distribution of three mitochondrial ATP–Mg/Pi carriers in Arabidopsis thaliana

Author

Lucia Daddabbo, Luigi Palmieri, Toshihiro Obata, Ferdinando Palmieri, Angelo Vozza, Alisdair R. Fernie, Magnus Monné, M. Cristina Nicolardi, and Daniela Valeria Miniero

Subjects

chemistry.chemical_classification, Membrane transport, Mitochondrial carrier, Biophysics, Arabidopsis, Cell Biology, Biology, Mitochondrion, biology.organism_classification, Biochemistry, Mitochondria, chemistry, Adenine nucleotide, Mitochondrial transporter, Arabidopsis thaliana, Nucleotide, ATP–ADP translocase, Inner mitochondrial membrane, ATP–Mg/phosphate carrier

Abstract

The Arabidopsis thaliana genome contains 58 membrane proteins belonging to the mitochondrial carrier family. Three members of this family, here named AtAPC1, AtAPC2, and AtAPC3, exhibit high structural similarities to the human mitochondrial ATP–Mg2 +/phosphate carriers. Under normal physiological conditions the AtAPC1 gene was expressed at least five times more than the other two AtAPC genes in flower, leaf, stem, root and seedlings. However, in stress conditions the expression levels of AtAPC1 and AtAPC3 change. Direct transport assays with recombinant and reconstituted AtAPC1, AtAPC2 and AtAPC3 showed that they transport phosphate, AMP, ADP, ATP, adenosine 5′-phosphosulfate and, to a lesser extent, other nucleotides. AtAPC2 and AtAPC3 also had the ability to transport sulfate and thiosulfate. All three AtAPCs catalyzed a counter-exchange transport that was saturable and inhibited by pyridoxal-5′-phosphate. The transport activities of AtAPCs were also inhibited by the addition of EDTA or EGTA and stimulated by the addition of Ca2 +. Given that phosphate and sulfate can be recycled via their own specific carriers, these findings indicate that AtAPCs can catalyze net transfer of adenine nucleotides across the inner mitochondrial membrane in exchange for phosphate (or sulfate), and that this transport is regulated both at the transcriptional level and by Ca2 +.

24. The mitochondrial protein import machinery has multiple connections to the respiratory chain

Author

Jan Höpker, Bogusz Kulawiak, Nils Wiedemann, Michael Gebert, Natalia Gebert, and Bernard Guiard

Subjects

Mitochondrial processing peptidase, Mitochondrial intermembrane space, Translocase of the outer membrane, Respiratory chain, Biophysics, Biology, Biochemistry, Mitochondrial Membrane Transport Proteins, Models, Biological, Electron Transport, Mitochondrial Proteins, Humans, Mitochondrion, Inner mitochondrial membrane, Protein import, Membrane Potential, Mitochondrial, Electron Transport Complex II, Cell Biology, Mitochondrial carrier, Cell biology, Succinate dehydrogenase, Protein Transport, Translocase of the inner membrane, Mitochondrial Membranes, Inner membrane, ATP–ADP translocase

Abstract

The mitochondrial inner membrane harbors the complexes of the respiratory chain and protein translocases required for the import of mitochondrial precursor proteins. These complexes are functionally interdependent, as the import of respiratory chain precursor proteins across and into the inner membrane requires the membrane potential. Vice versa the membrane potential is generated by the proton pumping complexes of the respiratory chain. Besides this basic codependency four different systems for protein import, processing and assembly show further connections to the respiratory chain. The mitochondrial intermembrane space import and assembly machinery oxidizes cysteine residues within the imported precursor proteins and is able to donate the liberated electrons to the respiratory chain. The presequence translocase of the inner membrane physically interacts with the respiratory chain. The mitochondrial processing peptidase is homologous to respiratory chain subunits and the carrier translocase of the inner membrane even shares a subunit with the respiratory chain. In this review we will summarize the import of mitochondrial precursor proteins and highlight these special links between the mitochondrial protein import machinery and the respiratory chain. This article is part of a Special Issue entitled: Respiratory complex II: Role in cellular physiology and disease.

25. The many faces of the mitochondrial TIM23 complex

Author

Dejana Mokranjac and Walter Neupert

Subjects

Models, Molecular, Translocase of the outer membrane, Targeting signals, Biophysics, TIM/TOM complex, medicine.disease_cause, Mitochondrial Membrane Transport Proteins, Models, Biological, Biochemistry, Protein sorting, Mitochondrial membrane transport protein, Adenosine Triphosphate, Protein translocase, TIM23 complex, Mitochondrial Precursor Protein Import Complex Proteins, Protein targeting, medicine, Animals, Humans, Protein Precursors, Inner mitochondrial membrane, biology, Cell Biology, Mitochondrial carrier, Cell biology, Mitochondria, Protein Subunits, Protein Transport, Multiprotein Complexes, Translocase of the inner membrane, biology.protein, sense organs, Carrier Proteins, Intermembrane space, Signal Transduction

Abstract

The TIM23 complex in the inner membrane of mitochondria mediates import of essentially all matrix proteins and a large number of inner membrane proteins. Here we present an overview on the latest insights into the structure and function of this remarkable molecular machine.

26. Is there a relationship between the supramolecular organization of the mitochondrial ATP synthase and the formation of cristae?

Author

Jacques Vaillier, Vincent Soubannier, Patrick Paumard, Daniel Brèthes, Jacques Schaeffer, Marie-France Giraud, Bénédicte Salin, Jean Velours, Jean-Paul di Rago, and Geneviève Arselin

Subjects

Morphology, Mitochondrial intermembrane space, Biophysics, Saccharomyces cerevisiae, Biochemistry, Cristae, ATP synthase gamma subunit, V-ATPase, Inner mitochondrial membrane, ATP synthase, biology, Intracellular Membranes, Cell Biology, Mitochondrial Proton-Translocating ATPases, Mitochondrial carrier, F0 subunit, Yeast, Cell biology, Mitochondria, Microscopy, Electron, Microscopy, Fluorescence, Translocase of the inner membrane, biology.protein, ATP–ADP translocase, Dimerization

Abstract

Blue native polyacrylamide gel electrophoresis (BN-PAGE) analyses of detergent mitochondrial extracts have provided evidence that the yeast ATP synthase could form dimers. Cross-linking experiments performed on a modified version of the i-subunit of this enzyme indicate the existence of such ATP synthase dimers in the yeast inner mitochondrial membrane. We also show that the first transmembrane segment of the eukaryotic b-subunit (bTM1), like the two supernumerary subunits e and g, is required for dimerization/oligomerization of ATP synthases. Unlike mitochondria of wild-type cells that display a well-developed cristae network, mitochondria of yeast cells devoid of subunits e, g, or bTM1 present morphological alterations with an abnormal proliferation of the inner mitochondrial membrane. From these observations, we postulate that an anomalous organization of the inner mitochondrial membrane occurs due to the absence of ATP synthase dimers/oligomers. We provide a model in which the mitochondrial ATP synthase is a key element in cristae morphogenesis.

27. Novel channels of the inner mitochondrial membrane

Author

Ildikò Szabò, Mario Zoratti, Umberto De Marchi, and Erich Gulbins

Subjects

Voltage-dependent anion channel, Patch-Clamp Techniques, Potassium Channels, Translocase of the outer membrane, Biophysics, Mitochondrial apoptosis-induced channel, Biochemistry, Ion Channels, Potassium Chloride, Mitochondrial membrane transport protein, Adenosine Triphosphate, Superoxides, Humans, Inner mitochondrial membrane, IKCa, Transmembrane channels, biology, Kv1.3, Cell Biology, Mitochondrial carrier, HCT116 Cells, Receptors, GABA-A, Channel, Mitochondria, Translocase of the inner membrane, Mitochondrial Membranes, biology.protein, Calcium, Inner membrane, Mitochondrial Swelling, Reactive Oxygen Species, Oxidation-Reduction, Patch-clamp

Abstract

Along with a large number of carriers, exchangers and "pumps", the inner mitochondrial membrane contains ion-conducting channels which endow it with controlled permeability to small ions. Some have been shown to be the mitochondrial counterpart of channels present also in other cellular membranes. The manuscript summarizes the current state of knowledge on the major inner mitochondrial membrane channels, properties, identity and proposed functions. Considerable attention is currently being devoted to two K(+)-selective channels, mtK(ATP) and mtBK(Ca). Their activation in "preconditioning" is considered by many to underlie the protection of myocytes and other cells against subsequent ischemic damage. We have recently shown that in apoptotic lymphocytes inner membrane mtK(V)1.3 interacts with the pro-apoptotic protein Bax after the latter has inserted into the outer mitochondrial membrane. Whether the just-discovered mtIK(Ca) has similar cellular role(s) remains to be seen. The Ca(2+) "uniporter" has been characterized electrophysiologically, but still awaits a molecular identity. Chloride-selective channels are represented by the 107 pS channel, the first mitochondrial channel to be observed by patch-clamp, and by a approximately 400 pS pore we have recently been able to fully characterize in the inner membrane of mitochondria isolated from a colon tumour cell line. This we propose to represent a component of the Permeability Transition Pore. The available data exclude the previous tentative identification with porin, and indicate that it coincides instead with the still molecularly unidentified "maxi" chloride channel.

28. Lipotoxicity, fatty acid uncoupling and mitochondrial carrier function

Author

Eduardo Rial, Leonor Rodríguez-Sánchez, M. Mar González-Barroso, Pilar Zaragoza, Eva Moyano, and Eunate Gallardo-Vara

Subjects

uncoupling, Biophysics, Transport, Oxidative phosphorylation, Mitochondrion, Models, Biological, Biochemistry, Ion Channels, Oxidative Phosphorylation, Uncoupling, Mitochondrial Proteins, Animals, Humans, oxidative stress, Uncoupling protein, adipocyte protein 2, Phylogeny, Uncoupling Protein 1, chemistry.chemical_classification, biology, Uncoupling Agents, Fatty Acids, Fatty acid, Cell Biology, lipotoxicity, Mitochondrial carrier, Thermogenin, Mitochondria, mitochondria, chemistry, Lipotoxicity, Oxidative stress, transport, biology.protein, Carrier Proteins, UCP

Abstract

7 páginas, 3 figuras -- PAGS nros. 800-806, Diseases like obesity, diabetes or generalized lipodystrophy cause a chronic elevation of circulating fatty acids that can become cytotoxic, a condition known as lipotoxicity. Fatty acids cause oxidative stress and alterations in mitochondrial structure and function. The uncoupling of the oxidative phosphorylation is one of the most recognized deleterious fatty acid effects and several metabolite transporters are known to mediate in their action. The fatty acid interaction with the carriers leads to membrane depolarization and/or the conversion of the carrier into a pore. The result is the opening of the permeability transition pore and the initiation of apoptosis. Unlike the other members of the mitochondrial carrier superfamily, the eutherian uncoupling protein UCP1 has evolved to achieve its heat-generating capacity in the physiological context provided by the brown adipocyte and therefore it is activated by the low fatty acid concentrations generated by the noradrenaline-stimulated lipolysis, This work was supported by the Spanish Ministry of Science and Innovation (SAF2009-07126 and Consolider-Ingenio2010 CSD2007-00020). M.M.G.B. was supported by the "Ramón y Cajal" program of the Spanish Ministry of Education and Science

29. The Saccharomyces cerevisiae gene YPR011c encodes a mitochondrial transporter of adenosine 5′-phosphosulfate and 3′-phospho-adenosine 5′-phosphosulfate

Author

Maria Antonietta Di Noia, Francesco M. Lasorsa, Ferdinando Palmieri, Eleonora Paradies, Alessandra Castegna, and Simona Todisco

Subjects

Thermotolerance, Mitochondrial carrier, Saccharomyces cerevisiae Proteins, Coenzyme A, Mutant, Saccharomyces cerevisiae, Genes, Fungal, Phosphoadenosine Phosphosulfate, Biophysics, Mitochondrion, Biology, Transporter, Biochemistry, Substrate Specificity, chemistry.chemical_compound, Methionine, Adenosine 5′-phosphosulfate, medicine, Escherichia coli, Mitochondrial transport, Genetic Complementation Test, Temperature, Biological Transport, Cell Biology, biology.organism_classification, Adenosine, Adaptation, Physiological, Glutathione, Recombinant Proteins, Adenosine Phosphosulfate, Mitochondria, Kinetics, chemistry, Mutant Proteins, medicine.drug

Abstract

The genome of Saccharomyces cerevisiae contains 35 members of the mitochondrial carrier family, nearly all of which have been functionally characterized. In this study, the identification of the mitochondrial carrier for adenosine 5′-phosphosulfate (APS) is described. The corresponding gene (YPR011c) was overexpressed in bacteria. The purified protein was reconstituted into phospholipid vesicles and its transport properties and kinetic parameters were characterized. It transported APS, 3′-phospho-adenosine 5′-phosphosulfate, sulfate and phosphate almost exclusively by a counter-exchange mechanism. Transport was saturable and inhibited by bongkrekic acid and other inhibitors. To investigate the physiological significance of this carrier in S. cerevisiae, mutants were subjected to thermal shock at 45°C in the presence of sulfate and in the absence of methionine. At 45°C cells lacking YPR011c, engineered cells (in which APS is produced only in mitochondria) and more so the latter cells, in which the exit of mitochondrial APS is prevented by the absence of YPR011cp, were less thermotolerant. Moreover, at the same temperature all these cells contained less methionine and total glutathione than wild-type cells. Our results show that S. cerevisiae mitochondria are equipped with a transporter for APS and that YPR011cp-mediated mitochondrial transport of APS occurs in S. cerevisiae under thermal stress conditions.

30. Mitochondrial membrane proteins in motion

Author

Timo Appelhans, Karin B. Busch, and Wladislaw Kohl

Subjects

biology, Chemistry, Translocase of the outer membrane, Biophysics, TIM/TOM complex, Cell Biology, Mitochondrial carrier, medicine.disease_cause, Biochemistry, Cell biology, Mitochondrial membrane transport protein, Translocase of the inner membrane, Protein targeting, biology.protein, medicine, ATP–ADP translocase, Inner mitochondrial membrane

31. S3.21 Contribution of mitochondrial carrier proteins to basal proton conductance

Author

Nadeene Parker and Martin D. Brand

Subjects

Basal (phylogenetics), Proton, Chemistry, Biophysics, Conductance, Cell Biology, Mitochondrial carrier, Biochemistry

32. The MINOS complex: Keeper of mitochondrial membrane architecture

Author

Ralf M. Zerbes, Karina von der Malsburg, Nikolaus Pfanner, Bettina Warscheid, Ida J. van der Klei, Martin van der Laan, Maria Bohnert, and Molecular Cell Biology

Subjects

Translocase of the outer membrane, Biophysics, TIM/TOM complex, Cell Biology, Biology, Mitochondrial carrier, Biochemistry, Crista, Translocase of the inner membrane, Bacterial outer membrane, Inner mitochondrial membrane, Intermembrane space

Abstract

Mitochondria are surrounded by two distinct membranes. While the outer membrane confines the organelle, the inner membrane has a key role in cellular energy metabolism. The inner mitochondrial membrane is subdivided into the inner boundary membrane, which is closely opposed to the outer membrane, and large irregular invagi- nations termed cristae. Narrow tubular openings – the crista junctions – connect cristae membrane and inner boundary membrane domains. Additionally, sites of contact between inner boundary and outer mitochondrial membranes are frequently observed. We have recently discovered a mitochondrial inner membrane organizing system (MINOS complex) that is crucial for both, the formation of crista junctions and membrane contact sites. MINOS is composed of six inner membrane proteins: the two highly conserved core subunits Fcj1/mitofilin and Mio10/MINOS1 together with Aim5, Aim13, Aim37 and Mio27. Deletion of FCJ1 or MIO10 in yeast abolishes MINOS formation and leads to a grossly altered mitochondrial ultrastructure with extended stacks of sheet-like cristae membranes and the loss of crista junctions. Moreover, MINOS interacts with several protein complexes of the outer mitochondrial membrane, like the SAM/TOB complex or the TOM complex at membrane contact sites. Formation of MINOS con- tact sites supports the import of precursor proteins from the cytosol into the intermembrane space and outer membrane. A detailed structure/function analysis of Fcj1/mitofilin revealed that membrane tethering, MINOS integrity and formation of crista junctions depend on different Fcj1/mitofilin protein domains.

33. Localization and orientation of TMEM70 protein in the inner mitochondrial membrane

Author

Markéta Tesařová, Lenka Nosková, Jana Buzkova, Hana Hartmannová, Hana Kratochvílová, Marek Vrbacký, Stanislav Kmoch, V. Havlíčková-Karbanová, Vilma Kaplanová, Kateřina Hejzlarová, Jiří Zeman, Josef Houštěk, Tomáš Mráček, and Alena Vrbacká-Čížková

Subjects

Chemistry, Translocase of the outer membrane, Protein targeting, Translocase of the inner membrane, Biophysics, medicine, Cell Biology, Orientation (graph theory), medicine.disease_cause, Inner mitochondrial membrane, Mitochondrial carrier, Biochemistry

34. Degradation of mitochondrial outer membrane proteins

Author

Chris Meisinger, R. Zhai, and F-Nora Vögtle

Subjects

biology, Chemistry, Translocase of the outer membrane, Biophysics, TIM/TOM complex, Cell Biology, Mitochondrial carrier, Biochemistry, Mitochondrial apoptosis-induced channel, Mitochondrial membrane transport protein, Translocase of the inner membrane, biology.protein, Outer membrane efflux proteins, Inner mitochondrial membrane

35. S3.11 The mechanism of transport across the inner mitochondrial membrane: Clues from the PxW subfamily

Author

Richard G. Moran and Scott A. Lawrence

Subjects

Subfamily, Chemistry, Translocase of the inner membrane, Biophysics, Cell Biology, Mitochondrial carrier, Inner mitochondrial membrane, Biochemistry, Mechanism (sociology), Cell biology

36. Determining the oligomeric state of mitochondrial carrier proteins by blue native gel electrophoresis

Author

Paul G. Crichton and Edmund R.S. Kunji

Subjects

Gel electrophoresis, 0303 health sciences, Two-dimensional gel electrophoresis, Chromatography, Gel electrophoresis of nucleic acids, Chemistry, Color marker, Biophysics, Cell Biology, Gel electrophoresis of proteins, Mitochondrial carrier, Biochemistry, 03 medical and health sciences, 0302 clinical medicine, Molecular-weight size marker, 030220 oncology & carcinogenesis, Polyacrylamide gel electrophoresis, 030304 developmental biology