ABSTRACT
cAMP regulates a wide variety of physiological functions in mammals. This single second messenger can regulate multiple, seemingly disparate functions within independently regulated cell compartments. We have previously identified one such compartment inside the matrix of the mitochondria, where soluble adenylyl cyclase (sAC) regulates oxidative phosphorylation (OXPHOS). We now show that sAC knockout fibroblasts have a defect in OXPHOS activity and attempt to compensate for this defect by increasing OXPHOS proteins. Importantly, sAC knockout cells also exhibit decreased probability of endoplasmic reticulum (ER) Ca2+ release associated with diminished phosphorylation of the inositol 3-phosphate receptor. Restoring sAC expression exclusively in the mitochondrial matrix rescues OXPHOS activity and reduces mitochondrial biogenesis, indicating that these phenotypes are regulated by intramitochondrial sAC. In contrast, Ca2+ release from the ER is only rescued when sAC expression is restored throughout the cell. Thus, we show that functionally distinct, sAC-defined, intracellular cAMP signaling domains regulate metabolism and Ca2+ signaling.
Subject(s)
Adenylyl Cyclases/metabolism , Calcium Signaling , Calcium/metabolism , Cyclic AMP/metabolism , Endoplasmic Reticulum/metabolism , Mitochondria/metabolism , Adenylyl Cyclases/genetics , Animals , Cell Fractionation , Cell Line , Endoplasmic Reticulum/ultrastructure , Fibroblasts/cytology , Fibroblasts/metabolism , Gene Expression Regulation , Gene Knockout Techniques , Inositol 1,4,5-Trisphosphate Receptors/genetics , Inositol 1,4,5-Trisphosphate Receptors/metabolism , Mice , Mitochondria/ultrastructure , Oxidative Phosphorylation , Oxygen ConsumptionABSTRACT
Coenzyme A (CoA) and acetyl-coenzyme A (acetyl-CoA) play essential roles in cell energy metabolism. Dysregulation of the biosynthesis and functioning of both compounds may contribute to various pathological conditions. We describe here a simple and sensitive HPLC-UV based method for simultaneous determination of CoA and acetyl-CoA in a variety of biological samples, including cells in culture, mouse cortex, and rat plasma, liver, kidney, and brain tissues. The limits of detection for CoA and acetyl-CoA are >10-fold lower than those obtained by previously described HPLC procedures, with coefficients of variation <1% for standard solutions, and 1-3% for deproteinized biological samples. Recovery is 95-97% for liver extracts spiked with Co-A and acetyl-CoA. Many factors may influence the tissue concentrations of CoA and acetyl-CoA (e.g., age, fed, or fasted state). Nevertheless, the values obtained by the present HPLC method for the concentration of CoA and acetyl-CoA in selected rodent tissues are in reasonable agreement with literature values. The concentrations of CoA and acetyl-CoA were found to be very low in rat plasma, but easily measurable by the present HPLC method. The method should be useful for studying cellular energy metabolism under normal and pathological conditions, and during targeted drug therapy treatment.
Subject(s)
Acetyl Coenzyme A/blood , Acetyl Coenzyme A/chemistry , Chromatography, High Pressure Liquid , Coenzyme A/blood , Coenzyme A/chemistry , Spectrophotometry, Ultraviolet , Animals , Cell Line , Cerebral Cortex/enzymology , Female , Humans , Mice , RatsABSTRACT
Huntington's disease (HD) is a neurodegenerative disorder caused by an abnormal expansion of a CAG repeat encoding a polyglutamine tract in the huntingtin (Htt) protein. The mutation leads to neuronal death through mechanisms which are still unknown. One hypothesis is that mitochondrial defects may play a key role. In support of this, the activity of mitochondrial complex II (C-II) is preferentially reduced in the striatum of HD patients. Here, we studied C-II expression in different genetic models of HD expressing N-terminal fragments of mutant Htt (mHtt). Western blot analysis showed that the expression of the 30 kDa Iron-Sulfur (Ip) subunit of C-II was significantly reduced in the striatum of the R6/1 transgenic mice, while the levels of the FAD containing catalytic 70 kDa subunit (Fp) were not significantly changed. Blue native gel analysis showed that the assembly of C-II in mitochondria was altered early in N171-82Q transgenic mice. Early loco-regional reduction in C-II activity and Ip protein expression was also demonstrated in a rat model of HD using intrastriatal injection of lentiviral vectors encoding mHtt. Infection of the rat striatum with a lentiviral vector coding the C-II Ip or Fp subunits induced a significant overexpression of these proteins that led to significant neuroprotection of striatal neurons against mHtt neurotoxicity. These results obtained in vivo support the hypothesis that structural and functional alterations of C-II induced by mHtt may play a critical role in the degeneration of striatal neurons in HD and that mitochondrial-targeted therapies may be useful in its treatment.
Subject(s)
Corpus Striatum/metabolism , Electron Transport Complex II/metabolism , Huntington Disease/metabolism , Mitochondria/metabolism , Mitochondrial Proteins/genetics , Mitochondrial Proteins/metabolism , Nerve Tissue Proteins/metabolism , Animals , Cells, Cultured , Corpus Striatum/physiopathology , Disease Models, Animal , Electron Transport Complex II/genetics , Female , Humans , Huntingtin Protein , Huntington Disease/genetics , Huntington Disease/physiopathology , Male , Mice , Mice, Transgenic , Mitochondria/genetics , Mutant Proteins/metabolism , Mutation , Neurons/metabolism , Rats , Rats, Sprague-DawleyABSTRACT
Energy metabolism could influence amyotrophic lateral sclerosis (ALS) and progressive lateral sclerosis (PLS) pathogenesis and the response to therapy. We developed a novel assay to simultaneously assess mitochondrial content and membrane potential in patients' skin fibroblasts. In ALS and PLS fibroblasts, membrane potential was increased and mitochondrial content decreased, relative to healthy controls. In ALS higher mitochondrial membrane potential correlated with age at diagnosis, and in PLS it correlated with disease severity. These unprecedented findings in ALS and PLS fibroblasts could shed new light onto disease pathogenesis and help in developing biomarkers to predict disease evolution and the individual response to therapy in motor neuron diseases.
Subject(s)
Amyotrophic Lateral Sclerosis/pathology , Energy Metabolism/physiology , Fibroblasts/pathology , Motor Neuron Disease/pathology , Skin/pathology , Adult , Aged , Aldehydes , Biomarkers , Humans , Male , Membrane Potential, Mitochondrial/physiology , Middle Aged , Rhodamines/metabolismABSTRACT
Cardiolipin is a mitochondrion-specific phospholipid that stabilizes the assembly of respiratory chain complexes, favoring full-yield operation. It also mediates key steps in apoptosis. In Barth syndrome, an X chromosome-linked cardiomyopathy caused by tafazzin mutations, cardiolipins display acyl chain modifications and are present at abnormally low concentrations, whereas monolysocardiolipin accumulates. Using immortalized lymphoblasts from Barth syndrome patients, we showed that the production of abnormal cardiolipin led to mitochondrial alterations. Indeed, the lack of normal cardiolipin led to changes in electron transport chain stability, resulting in cellular defects. We found a destabilization of the supercomplex (respirasome) I+III2+IVn but also decreased amounts of individual complexes I and IV and supercomplexes I+III and III+IV. No changes were observed in the amounts of individual complex III and complex II. We also found decreased levels of complex V. This complex is not part of the supercomplex suggesting that cardiolipin is required not only for the association/stabilization of the complexes into supercomplexes but also for the modulation of the amount of individual respiratory chain complexes. However, these alterations were compensated by an increase in mitochondrial mass, as demonstrated by electron microscopy and measurements of citrate synthase activity. We suggest that this compensatory increase in mitochondrial content prevents a decrease in mitochondrial respiration and ATP synthesis in the cells. We also show, by extensive flow cytometry analysis, that the type II apoptosis pathway was blocked at the mitochondrial level and that the mitochondria of patients with Barth syndrome cannot bind active caspase-8. Signal transduction is thus blocked before any mitochondrial event can occur. Remarkably, basal levels of superoxide anion production were slightly higher in patients' cells than in control cells as previously evidenced via an increased protein carbonylation in the taz1Δ mutant in the yeast. This may be deleterious to cells in the long term. The consequences of mitochondrial dysfunction and alterations to apoptosis signal transduction are considered in light of the potential for the development of future treatments.
Subject(s)
Apoptosis/genetics , Barth Syndrome/genetics , Barth Syndrome/pathology , Cardiolipins/metabolism , Mitochondria/pathology , Mutation/genetics , Transcription Factors/genetics , Acyltransferases , Adenosine Triphosphate/genetics , Adenosine Triphosphate/metabolism , Barth Syndrome/metabolism , Cardiolipins/genetics , Caspase 8/genetics , Caspase 8/metabolism , Cell Death/genetics , Cell Line , Citrate (si)-Synthase/genetics , Citrate (si)-Synthase/metabolism , Electron Transport Chain Complex Proteins/genetics , Electron Transport Chain Complex Proteins/metabolism , Humans , Lymphocytes/metabolism , Lymphocytes/pathology , Lysophospholipids/genetics , Lysophospholipids/metabolism , Mitochondria/genetics , Mitochondria/metabolism , Signal Transduction/genetics , Superoxides/metabolism , Transcription Factors/metabolismABSTRACT
Mutations in CHCHD10, a mitochondrial protein with undefined functions, are associated with autosomal dominant mitochondrial diseases. Chchd10 knock-in mice harboring a heterozygous S55L mutation (equivalent to human pathogenic S59L) develop a fatal mitochondrial cardiomyopathy caused by CHCHD10 aggregation and proteotoxic mitochondrial integrated stress response (mtISR). In mutant hearts, mtISR is accompanied by a metabolic rewiring characterized by increased reliance on glycolysis rather than fatty acid oxidation. To counteract this metabolic rewiring, heterozygous S55L mice were subjected to chronic high-fat diet (HFD) to decrease insulin sensitivity and glucose uptake and enhance fatty acid utilization in the heart. HFD ameliorated the ventricular dysfunction of mutant hearts and significantly extended the survival of mutant female mice affected by severe pregnancy-induced cardiomyopathy. Gene expression profiles confirmed that HFD increased fatty acid utilization and ameliorated cardiomyopathy markers. Importantly, HFD also decreased accumulation of aggregated CHCHD10 in the S55L heart, suggesting activation of quality control mechanisms. Overall, our findings indicate that metabolic therapy can be effective in mitochondrial cardiomyopathies associated with proteotoxic stress.
Subject(s)
Cardiomyopathies , Diet, High-Fat , Mitochondrial Proteins , Animals , Diet, High-Fat/adverse effects , Cardiomyopathies/metabolism , Cardiomyopathies/genetics , Cardiomyopathies/diet therapy , Female , Mice , Mitochondrial Proteins/metabolism , Mitochondrial Proteins/genetics , Fatty Acids/metabolism , Disease Models, Animal , PregnancyABSTRACT
Mass spectrometry imaging (MSI) is a powerful technology used to define the spatial distribution and relative abundance of structurally identified and yet-undefined metabolites across tissue cryosections. While numerous software packages enable pixel-by-pixel imaging of individual metabolites, the research community lacks a discovery tool that images all metabolite abundance ratio pairs. Importantly, recognition of correlated metabolite pairs informs discovery of unanticipated molecules contributing to shared metabolic pathways, uncovers hidden metabolic heterogeneity across cells and tissue subregions, and indicates single-timepoint flux through pathways of interest. Here, we describe the development and implementation of an untargeted R package workflow for pixel-by-pixel ratio imaging of all metabolites detected in an MSI experiment. Considering untargeted MSI studies of murine brain and embryogenesis, we demonstrate that ratio imaging minimizes systematic data variation introduced by sample handling and instrument drift, markedly enhances spatial image resolution, and reveals previously unrecognized metabotype-distinct tissue regions. Furthermore, ratio imaging facilitates identification of novel regional biomarkers and provides anatomical information regarding spatial distribution of metabolite-linked biochemical pathways. The algorithm described herein is applicable to any MSI dataset containing spatial information for metabolites, peptides or proteins, offering a potent tool to enhance knowledge obtained from current spatial metabolite profiling technologies.
ABSTRACT
Prohibitin is an essential mitochondrial protein that has been implicated in a wide variety of functions in many cell types, but its role in neurons remains unclear. In a proteomic screen of rat brains in which ischemic tolerance was induced by electrical stimulation of the cerebellar fastigial nucleus, we found that prohibitin is upregulated in mitochondria. This observation prompted us to investigate the role of prohibitin in neuronal death and survival. We found that prohibitin is upregulated also in the ischemic tolerance induced by transient ischemia in vivo, or oxygen-glucose deprivation in neuronal cultures. Cell fractionation and electron-microscopic immunolabeling studies demonstrated that prohibitin is localized to neuronal mitochondria. Upregulation of prohibitin in neuronal cultures or hippocampal slices was markedly neuroprotective, whereas prohibitin gene silencing increased neuronal vulnerability, an effect associated with loss of mitochondrial membrane potential and increased mitochondrial production of reactive oxygen species. Prohibitin upregulation was associated with reduced production of reactive oxygen species in mitochondria exposed to the complex I inhibitor rotenone. In addition, prohibitin protected complex I activity from the inhibitory effects of rotenone. These observations, collectively, establish prohibitin as an endogenous neuroprotective protein involved in ischemic tolerance. Prohibitin exerts beneficial effects on neurons by reducing mitochondrial free radical production. The data with complex I activity suggest that prohibitin may stabilize the function of complex I. The protective effect of prohibitin has potential translational relevance in diseases of the nervous system associated with mitochondrial dysfunction and oxidative stress.
Subject(s)
Brain Ischemia/prevention & control , Free Radicals/metabolism , Mitochondria/metabolism , Oxidative Stress/physiology , Repressor Proteins/physiology , Animals , Brain Ischemia/metabolism , Brain Ischemia/pathology , Hippocampus/pathology , Male , Neurons/metabolism , Neurons/pathology , Organ Culture Techniques , PC12 Cells , Primary Cell Culture , Prohibitins , Rats , Rats, Sprague-Dawley , Repressor Proteins/geneticsABSTRACT
Mutations in CHCHD10 , a mitochondrial protein with undefined functions, are associated with autosomal dominant mitochondrial diseases. Chchd10 knock-in mice harboring a heterozygous S55L mutation (equivalent to human pathogenic S59L) develop a fatal mitochondrial cardiomyopathy caused by CHCHD10 aggregation and proteotoxic mitochondrial integrated stress response (mtISR). In mutant hearts, mtISR is accompanied by a metabolic rewiring characterized by increased reliance on glycolysis rather than fatty acid oxidation. To counteract this metabolic rewiring, heterozygous S55L mice were subjected to chronic high fat diet (HFD) to decrease insulin sensitivity and glucose uptake and enhance fatty acid utilization in the heart. HFD ameliorated the ventricular dysfunction of mutant hearts and significantly extended the survival of mutant female mice affected by severe pregnancy-induced cardiomyopathy. Gene expression profiles confirmed that HFD increased fatty acid utilization and ameliorated cardiomyopathy markers. Importantly, HFD also decreased accumulation of aggregated CHCHD10 in the S55L heart, suggesting activation of quality control mechanisms. Overall, our findings indicate that metabolic therapy can be effective in mitochondrial cardiomyopathies associated with proteotoxic stress.
ABSTRACT
Mitochondrial diseases are a heterogeneous group of monogenic disorders that result from impaired oxidative phosphorylation (OXPHOS). As neuromuscular tissues are highly energy-dependent, mitochondrial diseases often affect skeletal muscle. Although genetic and bioenergetic causes of OXPHOS impairment in human mitochondrial myopathies are well established, there is a limited understanding of metabolic drivers of muscle degeneration. This knowledge gap contributes to the lack of effective treatments for these disorders. Here, we discovered fundamental muscle metabolic remodeling mechanisms shared by mitochondrial disease patients and a mouse model of mitochondrial myopathy. This metabolic remodeling is triggered by a starvation-like response that evokes accelerated oxidation of amino acids through a truncated Krebs cycle. While initially adaptive, this response evolves in an integrated multiorgan catabolic signaling, lipid store mobilization, and intramuscular lipid accumulation. We show that this multiorgan feed-forward metabolic response involves leptin and glucocorticoid signaling. This study elucidates systemic metabolic dyshomeostasis mechanisms that underlie human mitochondrial myopathies and identifies potential new targets for metabolic intervention.
Subject(s)
Mitochondrial Diseases , Mitochondrial Myopathies , Mice , Animals , Humans , Mitochondrial Myopathies/genetics , Mitochondrial Myopathies/metabolism , Muscle, Skeletal/metabolism , Energy Metabolism , LipidsABSTRACT
Using molecular, biochemical, and untargeted stable isotope tracing approaches, we identify a previously unappreciated glutamine-derived α-ketoglutarate (αKG) energy-generating anaplerotic flux to be critical in mitochondrial DNA (mtDNA) mutant cells that harbor human disease-associated oxidative phosphorylation defects. Stimulating this flux with αKG supplementation enables the survival of diverse mtDNA mutant cells under otherwise lethal obligatory oxidative conditions. Strikingly, we demonstrate that when residual mitochondrial respiration in mtDNA mutant cells exceeds 45% of control levels, αKG oxidative flux prevails over reductive carboxylation. Furthermore, in a mouse model of mitochondrial myopathy, we show that increased oxidative αKG flux in muscle arises from enhanced alanine synthesis and release into blood, concomitant with accelerated amino acid catabolism from protein breakdown. Importantly, in this mouse model of mitochondriopathy, muscle amino acid imbalance is normalized by αKG supplementation. Taken together, our findings provide a rationale for αKG supplementation as a therapeutic strategy for mitochondrial myopathies.
Subject(s)
DNA, Mitochondrial/genetics , Glutamine/metabolism , Ketoglutaric Acids , Mitochondria , Mitochondrial Myopathies , Adaptation, Physiological , Alanine/metabolism , Animals , Disease Models, Animal , Energy Metabolism , HeLa Cells , Humans , Ketoglutaric Acids/metabolism , Ketoglutaric Acids/therapeutic use , Male , Mice , Mitochondria/genetics , Mitochondria/metabolism , Mitochondrial Myopathies/genetics , Mitochondrial Myopathies/metabolism , Mutation , Oxidative PhosphorylationABSTRACT
As noted by Warburg, many cancer cells depend on the consumption of glucose. We performed a genetic screen to identify factors responsible for glucose addiction and recovered the two subunits of the xCT antiporter (system xc-), which plays an antioxidant role by exporting glutamate for cystine. Disruption of the xCT antiporter greatly improves cell viability after glucose withdrawal, because conservation of glutamate enables cells to maintain mitochondrial respiration. In some breast cancer cells, xCT antiporter expression is upregulated through the antioxidant transcription factor Nrf2 and contributes to their requirement for glucose as a carbon source. In cells carrying patient-derived mitochondrial DNA mutations, the xCT antiporter is upregulated and its inhibition improves mitochondrial function and cell viability. Therefore, although upregulation of the xCT antiporter promotes antioxidant defence, it antagonizes glutamine metabolism and restricts nutrient flexibility. In cells with mitochondrial dysfunction, the potential utility of xCT antiporter inhibition should be further tested.
Subject(s)
Amino Acid Transport System y+/genetics , Cystine/metabolism , Gene Expression Regulation, Neoplastic , Glucose/metabolism , Glutamic Acid/metabolism , Glutamine/metabolism , Amino Acid Transport System y+/metabolism , Antioxidants/metabolism , Biological Transport , Cell Line, Tumor , Cell Survival , Culture Media/chemistry , Culture Media/pharmacology , Epithelial Cells/drug effects , Epithelial Cells/metabolism , Epithelial Cells/pathology , Glucose/pharmacology , HEK293 Cells , HeLa Cells , Humans , Mitochondria/drug effects , Mitochondria/metabolism , NF-E2-Related Factor 2/genetics , NF-E2-Related Factor 2/metabolism , Oxidative Phosphorylation/drug effects , Signal TransductionABSTRACT
OBJECTIVE: We conducted a study on the functional characteristics of mitochondria in an oxyphilic thyroid tumor cell line, which may provide useful clues about Hürthle cell tumors carcinogenesis. DESIGN: The functional study on thyroid tumors with cell oxyphilia (Hürthle cell tumors), characterized by mitochondrial hyperplasia, was carried out in XTC.UC1, and B-CPAP, an oxyphilic and nonoxyphilic thyroid tumor cell line, respectively. MAIN OUTCOME: XTC.UC1 cell line showed higher activity of mitochondrial respiratory complexes I and II and decreased activity of complex III. The increased activity of complex I was not matched by increased expression of complex I subunits. The XTC.UC1 cells relied mostly on oxidative phosphorylation for energy conservation, although their mitochondrial energetic function was less efficient when related to mitochondrial content of the cells. Finally, the oxyphilic cell line produced significantly higher amounts of reactive oxygen species (ROS) in comparison with B-CPAP cell line. CONCLUSION: The involvement of ROS in mitochondrial biogenesis and proliferation as well as in carcinogenesis and apoptosis indicate that differences in activity of respiratory chain components and their unbalance may be responsible for development of morphological and functional changes observed in thyroid tumors with cell oxyphilia.
Subject(s)
Adenoma, Oxyphilic/metabolism , Mitochondria/metabolism , Thyroid Neoplasms/metabolism , Antimycin A/pharmacology , Cell Line, Tumor , Electron Transport Complex I/metabolism , Electron Transport Complex II/metabolism , Electron Transport Complex III/metabolism , Humans , Lactic Acid/biosynthesis , Mitochondria/drug effects , Oxidative Phosphorylation , Oxygen Consumption , Reactive Oxygen Species/metabolismABSTRACT
This mini-review summarizes our present view of the biochemical alterations associated with mitochondrial DNA (mtDNA) point mutations. Mitochondrial cytopathies caused by mutations of mtDNA are well-known genetic and clinical entities, but the biochemical pathogenic mechanisms are often obscure. Leber's hereditary optic neuropathy (LHON) is due to three main mutations in genes for complex I subunits. Even if the catalytic activity of complex I is maintained except in cells carrying the 3460/ND1 mutation, in all cases there is a change in sensitivity to complex I inhibitors and an impairment of mitochondrial respiration, eliciting the possibility of generation of reactive oxygen species (ROS) by the complex. Neurogenic muscle weakness, Ataxia and Retinitis Pigmentosa (NARP), is due to a mutation in the ATPase-6 gene. In NARP patients ATP synthesis is strongly depressed to an extent proportional to the mutation load; nevertheless, ATP hydrolysis and ATP-driven proton translocation are not affected. It is suggested that the NARP mutation affects the ability of the enzyme to couple proton transport to ATP synthesis. A point mutation in subunit III of cytochrome c oxidase is accompanied by a syndrome resembling MELAS: however, no major biochemical defect is found, if we except an enhanced production of ROS. The mechanism of such enhancement is at present unknown. In this review, we draw attention to a few examples in which the overproduction of ROS might represent a common step in the induction of clinical phenotypes and/or in the progression of several human pathologies associated with mtDNA point mutations.
Subject(s)
DNA, Mitochondrial/genetics , Mitochondrial Diseases/genetics , Mitochondrial Diseases/metabolism , Adenosine Triphosphatases/genetics , Adenosine Triphosphatases/metabolism , Animals , Ataxia/genetics , Electron Transport Complex IV/genetics , Electron Transport Complex IV/metabolism , Energy Metabolism/genetics , Humans , MELAS Syndrome/genetics , Mitochondrial Diseases/enzymology , Optic Nerve Diseases/genetics , Point Mutation , Reactive Oxygen Species/metabolism , Retinitis Pigmentosa/genetics , SyndromeABSTRACT
The mitochondrial respiratory chain is a powerful source of reactive oxygen species (ROS), considered as the pathogenic agent of many diseases and of aging. We have investigated the role of Complex I in superoxide radical production and found by combined use of specific inhibitors of Complex I that the one-electron donor in the Complex to oxygen is a redox center located prior to the sites where three different types of coenzyme Q (CoQ) competitors bind, to be identified with an Fe-S cluster, most probably N2, or possibly an ubisemiquinone intermediate insensitive to all the above inhibitors. Short-chain coenzyme Q analogues enhance superoxide formation, presumably by mediating electron transfer from N2 to oxygen. The clinically used CoQ analogue idebenone is particularly effective, raising doubts about its safety as a drug. The mitochondrial theory of aging considers somatic mutations of mitochondrial DNA induced by ROS as the primary cause of energy decline; in rat liver mitochondria, Complex I appears to be most affected by aging and to become strongly rate limiting for electron transfer. Mitochondrial energetics is also deranged in human platelets upon aging, as demonstrated by the decreased Pasteur effect (enhancement of lactate production by respiratory inhibitors). Cells counteract oxidative stress by antioxidants: CoQ is the only lipophilic antioxidant to be biosynthesized. Exogenous CoQ, however, protects cells from oxidative stress by conversion into its reduced antioxidant form by cellular reductases. The plasma membrane oxidoreductase and DT-diaphorase are two such systems: likewise, they are overexpressed under oxidative stress conditions.
Subject(s)
Aging/physiology , Mitochondria/metabolism , Oxidative Stress , Animals , Cell Respiration/physiology , Electron Transport , Humans , Oxidation-Reduction , Oxidoreductases/metabolism , Superoxides/metabolism , Ubiquinone/metabolismABSTRACT
The conditions under which Coenzyme Q (CoQ) may protect platelet mitochondrial function of transfusional buffy coats from aging and from induced oxidative stress were investigated. The Pasteur effect, i.e. the enhancement of lactate production after inhibition of mitochondrial respiratory chain, was exploited as a marker of mitochondrial function as it allows to calculate the ratio of mitochondrial ATP to glycolytic ATP. Reduced CoQ10 improves platelet mitochondrial function of transfusional buffy coats and protects the cells from induced oxidative stress. Oxidized CoQ is usually less effective, despite the presence, shown for the first time in this study, of quinone reductase activities in the platelet plasma membranes. The addition of a CoQ reducing system to platelets is effective in enhancing the protection of platelet mitochondrial function from the oxidative stress. The results support on one hand a possibility of protection of mitochondrial function in aging by exogenous CoQ intake, on the other a possible application in protection of transfusional buffy coats from storage conditions and oxidative deterioration.
Subject(s)
Aging/physiology , Antioxidants/pharmacology , Blood Platelets/drug effects , Mitochondria/physiology , Oxidative Stress/drug effects , Ubiquinone/analogs & derivatives , Ubiquinone/pharmacology , Cell Membrane/metabolism , Cell Respiration/physiology , Chromatography, High Pressure Liquid , Coenzymes , Cytoprotection , Electron Transport , Humans , Lactic Acid/metabolism , Lipid Peroxidation , NAD(P)H Dehydrogenase (Quinone)/metabolism , Oxidation-Reduction , Oxygen/metabolism , Platelet Transfusion , Thiobarbituric Acid Reactive Substances/metabolismABSTRACT
Dichlorophenol indophenol (DCIP) reduction by intracellualr pyridine nucleotides was investigated in two different lines of cultured cells characterized by enhanced production of reacive oxygen species (ROS) with respect to suitable controls. The first line denominated XTC-UC1 was derived from a metastasis of an oxyphilic thyroid tumor characterized by mitochondrial hyperplasia and compared with a line (B-CPAP) derived from a papillary thyroid carcinoma with normal mitochondrial mass. The second line (170 MN) was a cybrid line derived from rho0 cells from an osteosarcoma line (143B) fused with platelets from a patient with a nucleotide 9957 mutation in mitochondrial DNA (encoding for cytochrome c oxidase subunit III) in comparison with the parent 143B line. The experimental lines had no major decreases of electron transfer activities with respect to the controls; both of them, however, exhibited an increased peroxide production. The XTC-UC1 cell line exhibited enhanced activity with respect to control of dicoumarol-sensitive DCIP reduction, identified with membrane bound DT-diaphorase, whereas dicoumarol insensitive DCIP reduction was not significantly changed. On the other hand the mtDNA mutated cybrids exhibited a strong increase of both dicoumarol sensitive and insensitive DCIP reduction. The results suggest that enhanced oxidative stress and not deficient respiratory activity per se is the stimulus triggering over-expression of plasma membrane oxidative enzymes.
Subject(s)
Cell Membrane/enzymology , Mitochondria/physiology , Oxidative Stress/physiology , Oxidoreductases/metabolism , Reactive Oxygen Species/metabolism , Breast Neoplasms , Cell Line, Tumor , Female , Humans , Kinetics , NAD(P)H Dehydrogenase (Quinone)/metabolism , Thyroid NeoplasmsABSTRACT
In the mammalian mitochondrial electron transfer system, the majority of electrons enter at complex I, go through complexes III and IV, and are finally delivered to oxygen. Previously we generated several mouse cell lines with suppressed expression of the nuclearly encoded subunit 4 of complex IV. This led to a loss of assembly of complex IV and its defective function. Interestingly, we found that the level of assembled complex I and its activity were also significantly reduced, whereas levels and activity of complex III were normal or up-regulated. The structural and functional dependence of complex I on complex IV was verified using a human cell line carrying a nonsense mutation in the mitochondrially encoded complex IV subunit 1 gene. Our work documents that, although there is no direct electron transfer between them, an assembled complex IV helps to maintain complex I in mammalian cells.
Subject(s)
Electron Transport Complex IV/physiology , Electron Transport Complex I/physiology , Mitochondria/metabolism , Animals , Cell Line , Humans , Mice , Protein Subunits/genetics , Protein Subunits/metabolism , RNA InterferenceABSTRACT
Mitochondrial DNA (mtDNA) mutations cause heterogeneous disorders in humans. MtDNA exists in multiple copies per cell, and mutations need to accumulate beyond a critical threshold to cause disease, because coexisting wild-type mtDNA can complement the genetic defect. A better understanding of the molecular determinants of functional complementation among mtDNA molecules could help us shedding some light on the mechanisms modulating the phenotypic expression of mtDNA mutations in mitochondrial diseases. We studied mtDNA complementation in human cells by fusing two cell lines, one containing a homoplasmic mutation in a subunit of respiratory chain complex IV, COX I, and the other a distinct homoplasmic mutation in a subunit of complex III, cytochrome b. Upon cell fusion, respiration is recovered in hybrids cells, indicating that mitochondria fuse and exchange genetic and protein materials. Mitochondrial functional complementation occurs frequently, but with variable efficiency. We have investigated by native gel electrophoresis the molecular organization of the mitochondrial respiratory chain in complementing hybrid cells. We show that the recovery of mitochondrial respiration correlates with the presence of supramolecular structures (supercomplexes) containing complexes I, III and IV. We suggest that critical amounts of complexes III or IV are required in order for supercomplexes to form and provide mitochondrial functional complementation. From these findings, supercomplex assembly emerges as a necessary step for respiration, and its defect sets the threshold for respiratory impairment in mtDNA mutant cells.
Subject(s)
DNA, Mitochondrial/genetics , Electron Transport Chain Complex Proteins/genetics , Hybrid Cells/metabolism , Mutation/genetics , Cell Line , Cell Respiration/genetics , Cell Respiration/physiology , Codon, Nonsense/genetics , Cytochromes b/genetics , Cytochromes b/metabolism , Electron Transport Chain Complex Proteins/metabolism , Electron Transport Complex IV/genetics , Electron Transport Complex IV/metabolism , Frameshift Mutation/genetics , Humans , Membrane Proteins/genetics , Membrane Proteins/metabolism , Models, BiologicalABSTRACT
A growing body of evidence suggests that impaired mitochondrial energy production and increased oxidative radical damage to the mitochondria could be causally involved in motor neuron death in amyotrophic lateral sclerosis (ALS) and in familial ALS associated with mutations of Cu,Zn superoxide dismutase (SOD1). For example, morphologically abnormal mitochondria and impaired mitochondrial histoenzymatic respiratory chain activities have been described in motor neurons of patients with sporadic ALS. To investigate further the role of mitochondrial alterations in the pathogenesis of ALS, we studied mitochondria from transgenic mice expressing wild type and G93A mutated hSOD1. We found that a significant proportion of enzymatically active SOD1 was localized in the intermembrane space of mitochondria. Mitochondrial respiration, electron transfer chain, and ATP synthesis were severely defective in G93A mice at the time of onset of the disease. We also found evidence of oxidative damage to mitochondrial proteins and lipids. On the other hand, presymptomatic G93A transgenic mice and mice expressing the wild type form of hSOD1 did not show significant mitochondrial abnormalities. Our findings suggest that G93A-mutated hSOD1 in mitochondria may cause mitochondrial defects, which contribute to precipitating the neurodegenerative process in motor neurons.