Mammalian Oxa1 protein is useful for assessment of submitochondrial protein localization and mitochondrial membrane integrity

Taking advantage of the unique topology of oxidase assembly 1 (Oxa1) protein, a mitochondrial inner membrane protein with N (intermembrane space)-C (matrix) orientation, we explored the usefulness of the protein as a marker for submitochondrial protein localization. Mammalian Oxa1 protein exhibited different proteolytic patterns depending on mitochondrial membrane integrity, and in mitochondria with a disrupted outer membrane and outer and inner membranes, the proteolytic patterns of Oxa1 protein were consistent with those of mitochondrial intermembrane space and matrix marker proteins, respectively, suggesting that Oxa1 protein, a single molecule, can serve as a versatile submitochondrial localization marker that doubles as a membrane integrity marker.     

Ubiquitin-dependent mitochondrial protein degradation

Progressive mitochondrial failure is tightly associated with the onset of many age-related human pathologies. This tight connection results from the double-edged sword of mitochondrial respiration, which is responsible for generating both ATP and ROS, as well as from risks that are inherent to mitochondrial biogenesis. To prevent and treat these diseases, a precise understanding of the mechanisms that maintain functional mitochondria is necessary. Mitochondrial protein quality control is one of the mechanisms that protect mitochondrial integrity, and increasing evidence implicates the cytosolic ubiquitin/proteasome system (UPS) as part of this surveillance network. In this review, we will discuss our current understanding of UPS-dependent mitochondrial protein degradation, its roles in diseases progression, and insights into future studies.     

MitoTimer probe reveals the impact of autophagy,fusion, and motility on subcellular distribution of young and old mitochondrial protein and on relative mitochondrial protein age

To study mitochondrial protein age dynamics, we targeted a time-sensitive fluorescent protein, MitoTimer, to the mitochondrial matrix. Mitochondrial age was revealed by the integrated portions of young (green) and old (red) MitoTimer protein. Mitochondrial protein age was dependent on turnover rates as pulsed synthesis, decreased import, or autophagic inhibition all increased the proportion of aged MitoTimer protein. Mitochondrial fusion promotes the distribution of young mitochondrial protein across the mitochondrial network as cells lacking essential fusion genes Mfn1 and Mfn2 displayed increased heterogeneity in mitochondrial protein age. Experiments in hippocampal neurons illustrate that the distribution of older and younger mitochondrial protein within the cell is determined by subcellular spatial organization and compartmentalization of mitochondria into neurites and soma. This effect was altered by overexpression of mitochondrial transport protein, RHOT1/MIRO1. Collectively our data show that distribution of young and old protein in the mitochondrial network is dependent on turnover, fusion, and transport.     

Fast kinase domain-containing protein 3 is a mitochondrial protein essential for cellular respiration

Fas-activated serine/threonine phosphoprotein (FAST) is the founding member of the FAST kinase domain-containing protein (FASTKD) family that includes FASTKD1-5. FAST is a sensor of mitochondrial stress that modulates protein translation to promote the survival of cells exposed to adverse conditions. Mutations in FASTKD2 have been linked to a mitochondrial encephalomyopathy that is associated with reduced cytochrome c oxidase activity, an essential component of the mitochondrial electron transport chain. We have confirmed the mitochondrial localization of FASTKD2 and shown that all FASTKD family members are found in mitochondria. Although human and mouse FASTKD1-5 genes are expressed ubiquitously, some of them are most abundantly expressed in mitochondria-enriched tissues. We have found that RNA interference-mediated knockdown of FASTKD3 severely blunts basal and stress-induced mitochondrial oxygen consumption without disrupting the assembly of respiratory chain complexes. Tandem affinity purification reveals that FASTKD3 interacts with components of mitochondrial respiratory and translation machineries. Our results introduce FASTKD3 as an essential component of mitochondrial respiration that may modulate energy balance in cells exposed to adverse conditions by functionally coupling mitochondrial protein synthesis to respiration.     

The human SIRT3 protein deacetylase is exclusively mitochondrial

It has recently been suggested that perhaps as many as 20% of all mitochondrial proteins are regulated through lysine acetylation while SIRT3 has been implicated as an important mitochondrial protein deacetylase. It is therefore of crucial importance that the mitochondrial localization of potential protein deacetylases is unambiguously established. Although mouse SIRT3 was recently shown to be mitochondrial, HsSIRT3 (human SIRT3) was reported to be both nuclear and mitochondrial and to relocate from the nucleus to the mitochondrion upon cellular stress. In the present study we show, using various HsSIRT3 expression constructs and a combination of immunofluorescence and careful subcellular fractionation, that in contrast with earlier reports HsSIRT3 is exclusively mitochondrial. We discuss possible experimental explanations for these discrepancies. In addition we suggest, on the basis of the analysis of public genome databases, that the full-length mouse SIRT3 protein is a 37 kDa mitochondrial precursor protein contrary to the previously suggested 29 kDa protein.     

Rotaviral nonstructural protein 4 triggers dynamin‐related protein 1‐dependent mitochondrial fragmentation during infection

Dynamic equilibrium between mitochondrial fission and mitochondrial fusion serves as an important quality control system within cells ensuring cellular vitality and homeostasis. Viruses often target mitochondrial dynamics as a part of their obligatory cellular reprogramming. The present study was undertaken to assess the status and regulation of mitochondrial dynamics during rotavirus infection. Distinct fragmentation of mitochondrial syncytia was observed during late hours of RV (SA11, Wa, A5‐13) infection. RV nonstructural protein 4 (NSP4) was identified as the viral trigger for disrupted mitochondrial morphology. Severance of mitochondrial interconnections was found to be a dynamin‐related protein 1 (Drp1)‐dependent process resulting synergistically from augmented mitochondrial fission and attenuated mitochondrial fusion. Cyclin‐dependent kinase 1 was subsequently identified as the cellular kinase responsible for fission‐active Ser616 phosphorylation of Drp1. In addition to its positive role in mitochondrial fission, Drp1 also resulted in mitochondrial translocation of E3‐ubiquitin ligase Parkin leading to degradation of mitochondrial fusion protein Mitofusin 1. Interestingly, RV‐NSP4 was found to interact with and be involved in recruiting fission‐active pool of Serine 616 phosphoDrp1 (Ser616 pDrp1) to mitochondria independent of accessory adaptors Mitochondrial fission factor and Fission protein 1 (Fis1). Inhibition of either Drp1 or Ser616 pDrp1 resulted in significant decrease in RV‐NSP4‐induced intrinsic apoptotic pathway. Overall, this study underscores an efficient strategy utilised by RV to couple apoptosis to mitochondrial fission facilitating dissemination of viral progeny.     

MicroRNA-382 silencing induces a mitonuclear protein imbalance and activates the mitochondrial unfolded protein response in muscle cells

Proper mitochondrial function plays a central role in cellular metabolism. Various diseases as well as aging are associated with diminished mitochondrial function. Previously, we identified 19 miRNAs putatively involved in the regulation of mitochondrial metabolism in skeletal muscle, a highly metabolically active tissue. In the current study, these 19 miRNAs were individually silenced in C2C12 myotubes using antisense oligonucleotides, followed by measurement of the expression of 27 genes known to play a major role in regulating mitochondrial metabolism. Based on the outcomes, we then focused on miR-382-5p and identified pathways affected by its silencing using microarrays, investigated protein expression, and studied cellular respiration. Silencing of miRNA-382-5p significantly increased the expression of several genes involved in mitochondrial dynamics and biogenesis. Conventional microarray analysis in C2C12 myotubes silenced for miRNA-382-5p revealed a collective downregulation of mitochondrial ribosomal proteins and respiratory chain proteins. This effect was accompanied by an imbalance between mitochondrial proteins encoded by the nuclear and mitochondrial DNA (1.35-fold, p < 0.01) and an induction of HSP60 protein (1.31-fold, p < 0.05), indicating activation of the mitochondrial unfolded protein response (mtUPR). Furthermore, silencing of miR-382-5p reduced basal oxygen consumption rate by 14% ( p < 0.05) without affecting mitochondrial content, pointing towards a more efficient mitochondrial function as a result of improved mitochondrial quality control. Taken together, silencing of miR-382-5p induces a mitonuclear protein imbalance and activates the mtUPR in skeletal muscle, a phenomenon that was previously associated with improved longevity.     

Stimulation of mitochondrial protein synthesis by metal ions.

1--10 muM Cu2+, Ag+, and Au3+ were found to stimulate rat liver mitochondrial protein synthesis in vitro. Cu2+ and Ag+ also produced an increase in mitochondrial volume ("swelling"). Thus, thyroid hormones and their analogs are not unique, as suggested previously (Buchanan, J.L., Primack, M.P. and Tapley, D.F. (1970) Endocrinology 87, 993--999), in stimulating both mitochondrial protein synthesis and swelling. Furthermore, the data suggest a role for Cu2+ in the regulation of mitochondrial protein synthesis.     

Discoordinate expression of the yeast mitochondrial ribosomal protein MRP1

We have examined expression of the protein coded within the MRP 1 locus of Saccharomyces cerevisiae. Direct evidence is provided for the assignment of the MRP1 gene product as a protein component of the small subunit of mitochondrial ribosomes. Further studies examined the extent to which the expression of the MRP1 protein is coordinated with the expression of other mitochondrial ribosomal components coded in the nuclear and mitochondrial genomes. Extra copies of the MRP1 gene were introduced into yeast cells to perturb expression from MRP1 relative to other mitochondrial ribosomal components to determine whether forms of regulation function to limit the accumulation of either MRP1 mRNA or protein under these conditions. Increases in MRP1 gene dosage were accompanied by substantial increases in both MRP1 mRNA and protein, indicating that their accumulation was not linked to the level of expression of other mitochondrial ribosomal components. This conclusion was confirmed by additional studies that showed that the accumulation of the MRP1 protein was unaffected in cells that did not express mitochondrially-encoded rRNAs. These results contrast with previous studies on the expression of two other mitochondrial ribosomal proteins indicating that regulatory properties of mitochondrial ribosomal proteins are quite diverse.     

Mitochondrial protein phosphorylation: lessons from yeasts

The genome of Saccharomyces cerevisiae contains as many as 136 protein kinase encoding genes. However, only a limited number of mitochondrial protein kinases have been characterized. A computer-aided analysis revealed that only seven members of this large protein family are potentially localized in mitochondria. The low abundance of mitochondrially targeted protein kinases in yeast reflects the reductive evolution of mitochondrial signaling components and/or the apparent lack of selection pressure for acquiring mitochondrially localized protein kinases encoded by the host genome. This suggests that mitochondria, like obligatory intracellular bacterial parasites, are no longer dependent on signalling mechanisms mediated by protein kinases residing within the mitochondria. Instead, the nucleo-mitochondrial communication system requiring protein phosphorylation may be predominantly regulated by protein kinases, which are cytosolic and/or anchored to the outer mitochondrial membrane.     

线粒体呼吸链膜蛋白复合体的结构

线粒体作为真核细胞的重要“能量工厂”,是细胞进行呼吸作用的场所,呼吸作用包括柠檬酸循环和氧化磷酸化两个过程,其中氧化磷酸化过程的电子传递链（又称线粒体呼吸链）位于线粒体内膜上,由四个相对分子质量很大的跨膜蛋白复合体（Ⅰ、Ⅱ、Ⅲ、和Ⅳ）、介于Ⅰ／Ⅱ与Ⅲ之间的泛醌以及介于Ⅲ与Ⅳ之间的细胞色素c共同组成。线粒体呼吸链的功能是进行生物氧化,并与称之为复合物V的ATP合成酶（磷酸化过程）相偶联,共同完成氧化磷酸化过程,并生产能量分子ATP。线粒体呼吸链的结构生物学研究对于彻底了解电子传递和能量转化的机理是至关重要的,本文分别论述线粒体呼吸链复合体Ⅰ、Ⅱ、Ⅲ和Ⅳ的结构,并跟踪线粒体呼吸链超复合体的结构研究进展。     

Ubiquitin-like protein 5 positively regulates chaperone gene expression in the mitochondrial unfolded protein response

Perturbation of the protein-folding environment in the mitochondrial matrix selectively upregulates the expression of nuclear genes encoding mitochondrial chaperones. To identify components of the signal transduction pathway(s) mediating this mitochondrial unfolded protein response (UPR(mt)), we first isolated a temperature-sensitive mutation (zc32) that conditionally activates the UPR(mt) in C. elegans and subsequently searched for suppressors by systematic inactivation of genes. RNAi of ubl-5, a gene encoding a ubiquitin-like protein, suppresses activation of the UPR(mt) markers hsp-60::gfp and hsp-6::gfp by the zc32 mutation and by other manipulations that promote mitochondrial protein misfolding. ubl-5 (RNAi) inhibits the induction of endogenous mitochondrial chaperone encoding genes hsp-60 and hsp-6 and compromises the ability of animals to cope with mitochondrial stress. Mitochondrial morphology and assembly of multi-subunit mitochondrial complexes of biotinylated proteins are also perturbed in ubl-5(RNAi) worms, indicating that UBL-5 also counteracts physiological levels of mitochondrial stress. Induction of mitochondrial stress promotes accumulation of GFP-tagged UBL-5 in nuclei of transgenic worms, suggesting that UBL-5 effects a nuclear step required for mounting a response to the threat of mitochondrial protein misfolding.     

Purification of the putative import-receptor for the precursor of the mitochondrial protein

The receptor protein for the mitochondrial protein precursor synthesized in the cytosol was extensively purified from the mitochondrial membrane fraction by affinity column chromatography using a synthetic peptide containing the extrapeptide of ornithine aminotransferase as a ligand. The purified fraction contained two major proteins with molecular masses of 52 and 29 kDa. Of these proteins, only the 29 kDa protein bound to the extrapeptide of ornithine aminotransferase. Furthermore, anti-29 kDa protein Fab fragments inhibited the import of pre-ornithine aminotransferase into mitochondria, suggesting that the 29 kDa protein plays an essential role in the process of import of the mitochondrial protein precursor.     

Hypoxia affects mitochondrial protein expression in rat skeletal muscle

Hypoxia affects mammalian mitochondrial function, as well as mitochondria-based energy metabolism. The detail mechanism has not been fully understood. In this study, we detected protein expression levels in mitochondrial fractions of Wistar rats exposed to hypobaric hypoxia by use of proteomic methods. Adult male Wistar rats were randomized into an hypoxic (4,500?m, 30 days) group and a normoxic control group (sea level). Gastrocnemius muscles mitochondria were extracted and purified. Mitochondrial oxygen consumption was measured with a Clark oxygen electrode; mitochondrial transmembrane potential was detected with Rhodamine 123 as a fluoresce probe. Using 2-DE and MALDI-TOF MS analysis, we identified eight mitochondrial protein spots that were differentially expressed in the hypoxic group compared with the normoxic control. These proteins included Chain A of F1-ATPase, voltage dependent anion channel 1 (VDAC), hydroxyacyl Coenzyme A dehydrogenase α-subunit, mitochondrial F1 complex γ-subunit, androgen-regulated protein and tripartite motif protein 50. Two of the spots, VDAC and ATP synthase α-subunit, were confirmed by Western blotting analysis. Oxygen consumption during State 3 respiration, as well as the respiratory control ratio (RCR) was significantly higher in the control than that in the hypoxic group; mitochondrial transmembrane potential was significantly higher in hypoxic group than that in the control. With successful use of multiple proteomic analysis techniques, we demonstrates that 30 days hypoxia exposure has effects on the expression of mitochondrial proteins involved in ATP production and lipid metabolism, decrease the stability of mitochondrial membrane, and affect the mitochondrial electron transport chain.     

The mitochondrial protein hFis1 regulates mitochondrial fission in mammalian cells through an interaction with the dynamin-like protein DLP1

The yeast protein Fis1p has been shown to participate in mitochondrial fission mediated by the dynamin-related protein Dnm1p. In mammalian cells, the dynamin-like protein DLP1/Drp1 functions as a mitochondrial fission protein, but the mechanisms by which DLP1/Drp1 and the mitochondrial membrane interact during the fission process are undefined. In this study, we have tested the role of a mammalian homologue of Fis1p, hFis1, and provided new and mechanistic information about the control of mitochondrial fission in mammalian cells. Through differential tagging and deletion experiments, we demonstrate that the intact C-terminal structure of hFis1 is essential for mitochondrial localization, whereas the N-terminal region of hFis1 is necessary for mitochondrial fission. Remarkably, an increased level of cellular hFis1 strongly promotes mitochondrial fission, resulting in an accumulation of fragmented mitochondria. Conversely, cell microinjection of hFis1 antibodies or treatment with hFis1 antisense oligonucleotides induces an elongated and collapsed mitochondrial morphology. Further, fluorescence resonance energy transfer and coimmunoprecipitation studies demonstrate that hFis1 interacts with DLP1. These results suggest that hFis1 participates in mitochondrial fission through an interaction that recruits DLP1 from the cytosol. We propose that hFis1 is a limiting factor in mitochondrial fission and that the number of hFis1 molecules on the mitochondrial surface determines fission frequency.     

Evolution of the mitochondrial protein synthetic machinery

Comparative analysis of the components of the mitochondrial translational apparatus reveals a remarkable variability. For example the mitochondrial ribosomal rRNAs, display a three-fold difference in size in different organisms as a result of insertions or deletions, which affect specific areas of the rRNA molecule. This suggests that such areas are either not essential for mitoribosome function or that they can be replaced by proteins. Also mitochondrial tRNAs and mitoribosomal proteins are much less conserved than their cytoplasmic counterparts. Not only do the mitochondrial translational molecules vary in properties, also the location of the genes from which they are derived is not the same in all cases: mitochondrial tRNA genes which usually are found in the mtDNA, may have a nuclear location in protozoa and, conversely, only in fungi one finds a mitoribosomal protein gene in the organellar genome. The high rate of change of the components of the mitochondrial protein synthesizing machinery is accompanied by a number of unique features of the translation process: (i) the mitochondrial genetic code differs substantially from the standard code in a species-specific manner; (ii) special codon-anticodon recognition rules are followed; (iii) unusual mechanisms of translational initiation may exist. These observations suggest that the evolutionary pressures that have shaped the present day mitochondrial translational apparatus have been different in different organisms and also distinct from those acting on the cytoplasmic machinery. In spite of the interspecies variability, however, many features of the mitochondrial and bacterial protein synthetic apparatus show a clear resemblance, providing support for the hypothesis of a prokaryotic endosymbiont ancestry of mitochondria.     

Mechanisms of mitochondrial protein import.

1. Most proteins of cell organelles are synthesized as precursor proteins on cytosolic polysomes and are directed by signal sequences into the correct compartments. 2. In this review, the characteristics of mitochondrial protein uptake will be described, including the specific recognition, membrane translocation, proteolytic processing and folding of nuclear-encoded precursor proteins. 3. Recent studies indicate that a proteinaceous machinery located in the mitochondrial membranes and matrix performs these key steps of protein import.     

Immunochemical detection and quantitation of brown adipose tissue uncoupling protein

A polyclonal antisera against rat brown adipose tissue mitochondrial uncoupling protein was used to examine mitochondrial samples from liver and white and brown adipose tissue from several mammalian species. A sodium dodecyl sulfate--polyacrylamide gel electrophoretic separation of proteins combined with an immunochemical method allowed for visualization of antigen--antibody complexes on nitrocellulose blots. Hamster, cavy, monkey, and mouse brown adipose tissue mitochondrial samples cross-reacted with the antisera. Mitochondria prepared from white fat obtained from young swine and sheep contained two closely migrating, antigenically active proteins. Hepatic mitochondria samples did not contain antigenically active protein. Reflectance densitometry was used for quantitation of the uncoupling protein in various mitochondrial samples. In rats fed diets low in protein, there appears to be a dissociation between the concentration of uncoupling protein and the number of nucleotide binding sites as given by the [3H]GDP binding assay. These results are indicative of a physiological activation of the uncoupling protein.     

Human diseases with impaired mitochondrial protein synthesis

Mitochondrial respiratory chain deficiencies represent one of the major causes of metabolic disorders that are related to genetic defects in mitochondrial or nuclear DNA. The mitochondrial protein synthesis allows the synthesis of the 13 respiratory chain subunits encoded by mtDNA. Altogether, about 100 different proteins are involved in the translation of the 13 proteins encoded by the mitochondrial genome emphasizing the considerable investment required to maintain mitochondrial genetic system. Mitochondrial protein synthesis deficiency can be caused by mutations in any component of the translation apparatus including tRNA, rRNA and proteins. Mutations in mitochondrial rRNA and tRNAs have been first identified in various forms of mitochondrial disorders. Moreover abnormal translation due to mutation in nuclear genes encoding tRNA-modifying enzymes, ribosomal proteins, aminoacyl-tRNA synthetases, elongation and termination factors and translational activators have been successively described. These deficiencies are characterized by a huge clinical and genetic heterogeneity hampering to establish genotype-phenotype correlations and an easy diagnosis. One can hypothesize that a new technique for gene identification, such as exome sequencing will rapidly allow to expand the list of genes involved in abnormal mitochondrial protein synthesis.