ABSTRACT
The mitochondrial outer membrane harbors two protein translocases that are essential for cell viability: the translocase of the outer mitochondrial membrane (TOM) and the sorting and assembly machinery (SAM). The precursors of ß-barrel proteins use both translocases-TOM for import to the intermembrane space and SAM for export into the outer membrane. It is unknown if the translocases cooperate and where the ß-barrel of newly imported proteins is formed. We established a position-specific assay for monitoring ß-barrel formation in vivo and in organello and demonstrated that the ß-barrel was formed and membrane inserted while the precursor was bound to SAM. ß-barrel formation was inhibited by SAM mutants and, unexpectedly, by mutants of the central import receptor, Tom22. We show that the cytosolic domain of Tom22 links TOM and SAM into a supercomplex, facilitating precursor transfer on the intermembrane space side. Our study reveals receptor-mediated coupling of import and export translocases as a means of precursor channeling.
Subject(s)
Mitochondria/metabolism , Mitochondrial Membrane Transport Proteins/metabolism , Mitochondrial Proteins/metabolism , Protein Transport , Saccharomyces cerevisiae Proteins/metabolism , Saccharomyces cerevisiae/metabolism , Mitochondrial Membrane Transport Proteins/genetics , Mitochondrial Proteins/chemistry , Mutation , Porins/chemistry , Porins/metabolism , Protein Folding , Protein Structure, Secondary , Saccharomyces cerevisiae Proteins/chemistry , Saccharomyces cerevisiae Proteins/geneticsABSTRACT
Communication of mitochondria with the rest of the cell requires beta-barrel proteins of the outer membrane. All beta-barrel proteins are synthesized as precursors in the cytosol and imported into mitochondria by the general translocase TOM and the sorting machinery SAM. The SAM complex contains two proteins essential for cell viability, the channel-forming Sam50 and Sam35. We have identified the sorting signal of mitochondrial beta-barrel proteins that is universal in all eukaryotic kingdoms. The beta-signal initiates precursor insertion into a hydrophilic, proteinaceous membrane environment by forming a ternary complex with Sam35 and Sam50. Sam35 recognizes the beta-signal, inducing a major conductance increase of the Sam50 channel. Subsequent precursor release from SAM is coupled to integration into the lipid phase. We propose that a two-stage mechanism of signal-driven insertion into a membrane protein complex and subsequent integration into the lipid phase may represent a general mechanism for biogenesis of beta-barrel proteins.
Subject(s)
Mitochondrial Membranes/metabolism , Mitochondrial Proteins/metabolism , Membrane Transport Proteins/chemistry , Membrane Transport Proteins/metabolism , Mitochondria/metabolism , Mitochondrial Membrane Transport Proteins , Mitochondrial Membranes/chemistry , Mitochondrial Proteins/chemistry , Protein Sorting Signals , Protein Structure, Secondary , Protein Structure, Tertiary , Protein Transport , Saccharomyces cerevisiae/cytology , Saccharomyces cerevisiae/metabolism , Saccharomyces cerevisiae Proteins/chemistry , Saccharomyces cerevisiae Proteins/metabolismABSTRACT
The Nup84 complex constitutes a key building block in the nuclear pore complex (NPC). Here we present the crystal structure of one of its 7 components, Nup120, which reveals a beta propeller and an alpha-helical domain representing a novel fold. We discovered a previously unidentified interaction of Nup120 with Nup133 and confirmed the physiological relevance in vivo. As mapping of the individual components in the Nup84 complex places Nup120 and Nup133 at opposite ends of the heptamer, our findings indicate a head-to-tail arrangement of elongated Nup84 complexes into a ring structure, consistent with a fence-like coat for the nuclear pore membrane. The attachment site for Nup133 lies at the very end of an extended unstructured region, which allows for flexibility in the diameter of the Nup84 complex ring. These results illuminate important roles of terminal unstructured segments in nucleoporins for the architecture, function, and assembly of the NPC.
Subject(s)
Nuclear Pore Complex Proteins/metabolism , Nuclear Pore/metabolism , Saccharomyces cerevisiae Proteins/metabolism , Saccharomyces cerevisiae/metabolism , Amino Acid Sequence , Crystallization , Genetic Complementation Test , Green Fluorescent Proteins/genetics , Green Fluorescent Proteins/metabolism , In Situ Hybridization, Fluorescence , Microscopy, Fluorescence , Models, Molecular , Molecular Sequence Data , Mutation , Nuclear Pore Complex Proteins/chemistry , Nuclear Pore Complex Proteins/genetics , Protein Binding , Protein Conformation , Protein Structure, Secondary , Protein Structure, Tertiary , Recombinant Fusion Proteins/genetics , Recombinant Fusion Proteins/metabolism , Saccharomyces cerevisiae/genetics , Saccharomyces cerevisiae Proteins/chemistry , Saccharomyces cerevisiae Proteins/genetics , Sequence Homology, Amino Acid , X-Ray DiffractionABSTRACT
Mitochondria and the nucleus are key features that distinguish eukaryotic cells from prokaryotic cells. Mitochondria originated from a bacterium that was endosymbiotically taken up by another cell more than a billion years ago. Subsequently, most mitochondrial genes were transferred and integrated into the host cell's genome, making the evolution of pathways for specific import of mitochondrial proteins necessary. The mitochondrial protein translocation machineries are composed of numerous subunits. Interestingly, many of these subunits are at least in part derived from bacterial proteins, although only few of them functioned in bacterial protein translocation. We propose that the primitive alpha-proteobacterium, which was once taken up by the eukaryote ancestor cell, contained a number of components that were utilized for the generation of mitochondrial import machineries. Many bacterial components of seemingly unrelated pathways were integrated to form the modern cooperative mitochondria-specific protein translocation system.
Subject(s)
Biological Evolution , Mitochondria , Mitochondrial Proteins/metabolism , Alphaproteobacteria/cytology , Alphaproteobacteria/genetics , Alphaproteobacteria/metabolism , Bacterial Proteins/classification , Bacterial Proteins/genetics , Bacterial Proteins/metabolism , Eukaryotic Cells/cytology , Eukaryotic Cells/metabolism , Membrane Proteins/classification , Membrane Proteins/genetics , Membrane Proteins/metabolism , Mitochondria/genetics , Mitochondria/metabolism , Mitochondrial Proteins/classification , Mitochondrial Proteins/genetics , Protein TransportABSTRACT
The biogenesis of mitochondria, chloroplasts, and Gram-negative bacteria requires the insertion of ß-barrel proteins into the outer membranes. Homologous Omp85 proteins are essential for membrane insertion of ß-barrel precursors. It is unknown if precursors are threaded through the Omp85-channel interior and exit laterally or if they are translocated into the membrane at the Omp85-lipid interface. We have mapped the interaction of a precursor in transit with the mitochondrial Omp85-channel Sam50 in the native membrane environment. The precursor is translocated into the channel interior, interacts with an internal loop, and inserts into the lateral gate by ß-signal exchange. Transport through the Omp85-channel interior followed by release through the lateral gate into the lipid phase may represent a basic mechanism for membrane insertion of ß-barrel proteins.
Subject(s)
Mitochondria/metabolism , Mitochondrial Membrane Transport Proteins/metabolism , Mitochondrial Membranes/metabolism , Mitochondrial Proteins/metabolism , Porins/metabolism , Saccharomyces cerevisiae Proteins/metabolism , Saccharomyces cerevisiae/metabolism , Voltage-Dependent Anion Channel 1/metabolism , Mitochondrial Membrane Transport Proteins/genetics , Mitochondrial Proteins/chemistry , Mitochondrial Proteins/genetics , Porins/genetics , Protein Conformation, beta-Strand , Protein Folding , Protein Transport , Saccharomyces cerevisiae Proteins/chemistry , Saccharomyces cerevisiae Proteins/genetics , Voltage-Dependent Anion Channel 1/geneticsABSTRACT
Until recently, adenovirus-based gene therapy has been almost exclusively based on human adenovirus serotype 5 (Ad5). The aim of this study was to systematically compare the efficiency of transduction of primary muscle cells from various species by two adenoviral vectors from subgroups C and D. Transduction of a panel of myoblasts demonstrated a striking specificity of an Ad19a-based replication-defective E1-deleted vector (Ad19aEGFP) for human cells, whereas the Ad5-based vector had high affinity for nonhuman primate myoblasts. Transgene expression correlated well with cell-associated vector genomes. Up to 6.59% of the initially applied Ad19aEGFP vector particles were taken up by human myoblasts, as compared with 0.1% of the corresponding Ad5 vector. Remarkably, Ad19aEGFP but not Ad5EGFP efficiently transduced differentiated human myotubes, an in vitro model for skeletal muscle transduction. Uptake of Ad19aEGFP vector particles in human myotubes was 12-fold more efficient than that of Ad5EGFP. Moreover, both vectors demonstrated an early block at the level of vector uptake in mouse myoblasts and rat L6 cells. Investigation of the underlying mechanism for binding and uptake of the two vectors by human myoblasts showed high susceptibility for Ad19a to neuraminidase and wheat germ agglutinin (WGA) lectin, whereas Ad5-mediated transduction was dependent on binding to the coxsackie-adenovirus receptor (CAR) and sensitive to soluble RGD peptide and heparin. Our study offers insights into species-dependent factors that determine Ad tropism and, moreover, provides a basis for application of the novel Ad19a-based vector for gene transfer into human skeletal muscle.
Subject(s)
Adenoviruses, Human/genetics , Genetic Therapy/methods , Genetic Vectors/pharmacology , Muscle, Skeletal/virology , Animals , Cells, Cultured , Coxsackie and Adenovirus Receptor-Like Membrane Protein , Epitopes/chemistry , Epitopes/metabolism , Flow Cytometry/methods , Genetic Vectors/genetics , Heparitin Sulfate/metabolism , Humans , Mice , Muscle Fibers, Skeletal/cytology , Muscle Fibers, Skeletal/virology , Muscle, Skeletal/cytology , Muscle, Skeletal/physiology , Myoblasts/cytology , Myoblasts/virology , N-Acetylneuraminic Acid/chemistry , N-Acetylneuraminic Acid/metabolism , Rats , Receptors, Virus/chemistry , Receptors, Virus/metabolism , Species Specificity , Transduction, Genetic , Tropism , Virus ReplicationABSTRACT
The biogenesis of mitochondria requires the import of a large number of proteins from the cytosol [1, 2]. Although numerous studies have defined the proteinaceous machineries that mediate mitochondrial protein sorting, little is known about the role of lipids in mitochondrial protein import. Cardiolipin, the signature phospholipid of the mitochondrial inner membrane [3-5], affects the stability of many inner-membrane protein complexes [6-12]. Perturbation of cardiolipin metabolism leads to the X-linked cardioskeletal myopathy Barth syndrome [13-18]. We report that cardiolipin affects the preprotein translocases of the mitochondrial outer membrane. Cardiolipin mutants genetically interact with mutants of outer-membrane translocases. Mitochondria from cardiolipin yeast mutants, as well as Barth syndrome patients, are impaired in the biogenesis of outer-membrane proteins. Our findings reveal a new role for cardiolipin in protein sorting at the mitochondrial outer membrane and bear implications for the pathogenesis of Barth syndrome.
Subject(s)
Barth Syndrome/metabolism , Cardiolipins/metabolism , Membrane Transport Proteins/biosynthesis , Mitochondria/metabolism , Mitochondrial Membranes/chemistry , Autoradiography , Barth Syndrome/physiopathology , Cardiolipins/genetics , Cell Line , Electrophoresis , Electrophoresis, Polyacrylamide Gel , Humans , Immunoblotting , Membrane Transport Proteins/metabolism , Saccharomyces cerevisiaeABSTRACT
The translocase of the outer membrane (TOM complex) is the central entry gate for nuclear-encoded mitochondrial precursor proteins. All Tom proteins are also encoded by nuclear genes and synthesized as precursors in the cytosol. The channel-forming beta-barrel protein Tom40 is targeted to mitochondria via Tom receptors and inserted into the outer membrane by the sorting and assembly machinery (SAM complex). A further outer membrane protein, Mim1, plays a less defined role in assembly of Tom40 into the TOM complex. The three receptors Tom20, Tom22, and Tom70 are anchored in the outer membrane by a single transmembrane alpha-helix, located at the N terminus in the case of Tom20 and Tom70 (signal-anchored) or in the C-terminal portion in the case of Tom22 (tail-anchored). Insertion of the precursor of Tom22 into the outer membrane requires pre-existing Tom receptors while the import pathway of the precursors of Tom20 and Tom70 is only poorly understood. We report that Mim1 is required for efficient membrane insertion and assembly of Tom20 and Tom70, but not Tom22. We show that Mim1 associates with SAM(core) components to a large SAM complex, explaining its role in late steps of the assembly pathway of Tom40. We conclude that Mim1 is not only required for biogenesis of the beta-barrel protein Tom40 but also for membrane insertion and assembly of signal-anchored Tom receptors. Thus, Mim1 plays an important role in the efficient assembly of the mitochondrial TOM complex.
Subject(s)
Carrier Proteins/metabolism , Membrane Proteins/metabolism , Mitochondria/metabolism , Mitochondrial Membranes/metabolism , Saccharomyces cerevisiae Proteins/metabolism , Blotting, Western , Membrane Proteins/genetics , Membrane Transport Proteins/metabolism , Mitochondrial Membrane Transport Proteins , Mitochondrial Precursor Protein Import Complex Proteins , Mutation , Protein Binding , Protein Transport , Receptors, Cytoplasmic and Nuclear/metabolism , Saccharomyces cerevisiae/genetics , Saccharomyces cerevisiae/metabolism , Saccharomyces cerevisiae Proteins/geneticsABSTRACT
Mitochondrial precursor proteins are directed into the intermembrane space via two different routes, the presequence pathway and the redox-dependent MIA pathway. The pathways were assumed to be independent and transport different proteins. We report that the intermembrane space receptor Mia40 can switch between both pathways. In fungi, Mia40 is synthesized as large protein with an N-terminal presequence, whereas in metazoans and plants, Mia40 consists only of the conserved C-terminal domain. Human MIA40 and the C-terminal domain of yeast Mia40 (termed Mia40(core)) rescued the viability of Mia40-deficient yeast independently of the presence of a presequence. Purified Mia40(core) was imported into mitochondria via the MIA pathway. With cells expressing both full-length Mia40 and Mia40(core), we demonstrate that yeast Mia40 contains dual targeting information, directing the large precursor onto the presequence pathway and the smaller Mia40(core) onto the MIA pathway, raising interesting implications for the evolution of mitochondrial protein sorting.
Subject(s)
Mitochondria/metabolism , Mitochondrial Membrane Transport Proteins/chemistry , Saccharomyces cerevisiae Proteins/chemistry , Animals , Humans , Membrane Potentials , Mitochondrial Precursor Protein Import Complex Proteins , Mitochondrial Proteins/genetics , Models, Biological , Oxidation-Reduction , Phylogeny , Protein Structure, Tertiary , Protein Transport/genetics , Recombinant Proteins/chemistry , Saccharomyces cerevisiae/metabolism , TemperatureABSTRACT
The mitochondrial inner membrane contains different translocator systems for the import of presequence-carrying proteins and carrier proteins. The translocator assembly and maintenance protein 41 (Tam41/mitochondrial matrix protein 37) was identified as a new member of the mitochondrial protein translocator systems by its role in maintaining the integrity and activity of the presequence translocase of the inner membrane (TIM23 complex). Here we demonstrate that the assembly of proteins imported by the carrier translocase, TIM22 complex, is even more strongly affected by the lack of Tam41. Moreover, respiratory chain supercomplexes and the inner membrane potential are impaired by lack of Tam41. The phenotype of Tam41-deficient mitochondria thus resembles that of mitochondria lacking cardiolipin. Indeed, we found that Tam41 is required for the biosynthesis of the dimeric phospholipid cardiolipin. The pleiotropic effects of the translocator maintenance protein on preprotein import and respiratory chain can be attributed to its role in biosynthesis of mitochondrial cardiolipin.
Subject(s)
Cardiolipins/biosynthesis , Mitochondria/metabolism , Mitochondrial Proteins/metabolism , Saccharomyces cerevisiae Proteins/metabolism , Membrane Potential, Mitochondrial , Membrane Transport Proteins/metabolism , Mitochondrial Membrane Transport Proteins , Mitochondrial Precursor Protein Import Complex Proteins , Mitochondrial Proteins/genetics , Saccharomyces cerevisiae/metabolism , Saccharomyces cerevisiae Proteins/geneticsABSTRACT
Most mitochondrial proteins are synthesized in the cytosol and imported into one of the four mitochondrial compartments: outer membrane, intermembrane space, inner membrane, and matrix. Each compartment contains protein complexes that interact with precursor proteins and promote their transport. These translocase complexes do not act as independent units but cooperate with each other and further membrane complexes in a dynamic manner. We propose that a regulated coupling of translocases is important for the coordination of preprotein translocation and efficient sorting to intramitochondrial compartments.