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Cell May 2021Damaged mitochondria need to be cleared to maintain the quality of the mitochondrial pool. Here, we report mitocytosis, a migrasome-mediated mitochondrial...
Damaged mitochondria need to be cleared to maintain the quality of the mitochondrial pool. Here, we report mitocytosis, a migrasome-mediated mitochondrial quality-control process. We found that, upon exposure to mild mitochondrial stresses, damaged mitochondria are transported into migrasomes and subsequently disposed of from migrating cells. Mechanistically, mitocytosis requires positioning of damaged mitochondria at the cell periphery, which occurs because damaged mitochondria avoid binding to inward motor proteins. Functionally, mitocytosis plays an important role in maintaining mitochondrial quality. Enhanced mitocytosis protects cells from mitochondrial stressor-induced loss of mitochondrial membrane potential (MMP) and mitochondrial respiration; conversely, blocking mitocytosis causes loss of MMP and mitochondrial respiration under normal conditions. Physiologically, we demonstrate that mitocytosis is required for maintaining MMP and viability in neutrophils in vivo. We propose that mitocytosis is an important mitochondrial quality-control process in migrating cells, which couples mitochondrial homeostasis with cell migration.
Topics: Animals; Biological Transport; Cell Line; Cell Movement; Cytoplasm; Exocytosis; Female; Homeostasis; Male; Membrane Potential, Mitochondrial; Mice; Mice, Inbred C57BL; Microscopy, Electron, Transmission; Mitochondria; Mitochondrial Membranes; Organelles
PubMed: 34048705
DOI: 10.1016/j.cell.2021.04.027 -
International Journal of Molecular... May 2021Glutathione (GSH) is the most abundant non-protein thiol, and plays crucial roles in the antioxidant defense system and the maintenance of redox homeostasis in neurons.... (Review)
Review
Glutathione (GSH) is the most abundant non-protein thiol, and plays crucial roles in the antioxidant defense system and the maintenance of redox homeostasis in neurons. GSH depletion in the brain is a common finding in patients with neurodegenerative diseases, such as Alzheimer's disease and Parkinson's disease, and can cause neurodegeneration prior to disease onset. Excitatory amino acid carrier 1 (EAAC1), a sodium-dependent glutamate/cysteine transporter that is selectively present in neurons, plays a central role in the regulation of neuronal GSH production. The expression of EAAC1 is posttranslationally controlled by the glutamate transporter-associated protein 3-18 (GTRAP3-18) or miR-96-5p in neurons. The regulatory mechanism of neuronal GSH production mediated by EAAC1 may be a new target in therapeutic strategies for these neurodegenerative diseases. This review describes the regulatory mechanism of neuronal GSH production and its potential therapeutic application in the treatment of neurodegenerative diseases.
Topics: Animals; Antioxidants; Biomarkers; Brain; Disease Management; Disease Susceptibility; Excitatory Amino Acid Transporter 3; Gene Expression Regulation; Glutamate Plasma Membrane Transport Proteins; Glutathione; Humans; Metabolic Networks and Pathways; Microglia; Neurodegenerative Diseases; Neurons; Oxidation-Reduction; Reactive Oxygen Species
PubMed: 34065042
DOI: 10.3390/ijms22095010 -
Cell Metabolism Mar 2021The metabolic rewiring of cardiomyocytes is a widely accepted hallmark of heart failure (HF). These metabolic changes include a decrease in mitochondrial pyruvate...
The metabolic rewiring of cardiomyocytes is a widely accepted hallmark of heart failure (HF). These metabolic changes include a decrease in mitochondrial pyruvate oxidation and an increased export of lactate. We identify the mitochondrial pyruvate carrier (MPC) and the cellular lactate exporter monocarboxylate transporter 4 (MCT4) as pivotal nodes in this metabolic axis. We observed that cardiac assist device-induced myocardial recovery in chronic HF patients was coincident with increased myocardial expression of the MPC. Moreover, the genetic ablation of the MPC in cultured cardiomyocytes and in adult murine hearts was sufficient to induce hypertrophy and HF. Conversely, MPC overexpression attenuated drug-induced hypertrophy in a cell-autonomous manner. We also introduced a novel, highly potent MCT4 inhibitor that mitigated hypertrophy in cultured cardiomyocytes and in mice. Together, we find that alteration of the pyruvate-lactate axis is a fundamental and early feature of cardiac hypertrophy and failure.
Topics: Animals; Anion Transport Proteins; Cardiomegaly; Heart Failure; Heart-Assist Devices; Humans; Lactic Acid; Membrane Potential, Mitochondrial; Mice; Mice, Inbred C57BL; Mice, Knockout; Mitochondria; Mitochondrial Membrane Transport Proteins; Monocarboxylic Acid Transporters; Muscle Proteins; Myocytes, Cardiac; Pyruvic Acid; RNA Interference; RNA, Small Interfering; Reactive Oxygen Species; Ventricular Function, Left
PubMed: 33333007
DOI: 10.1016/j.cmet.2020.12.003 -
International Journal of Molecular... Jul 2019The mammalian mitochondrial electron transport chain (ETC) includes complexes I‑IV, as well as the electron transporters ubiquinone and cytochrome c. There are two...
The mammalian mitochondrial electron transport chain (ETC) includes complexes I‑IV, as well as the electron transporters ubiquinone and cytochrome c. There are two electron transport pathways in the ETC: Complex I/III/IV, with NADH as the substrate and complex II/III/IV, with succinic acid as the substrate. The electron flow is coupled with the generation of a proton gradient across the inner membrane and the energy accumulated in the proton gradient is used by complex V (ATP synthase) to produce ATP. The first part of this review briefly introduces the structure and function of complexes I‑IV and ATP synthase, including the specific electron transfer process in each complex. Some electrons are directly transferred to O2 to generate reactive oxygen species (ROS) in the ETC. The second part of this review discusses the sites of ROS generation in each ETC complex, including sites IF and IQ in complex I, site IIF in complex II and site IIIQo in complex III, and the physiological and pathological regulation of ROS. As signaling molecules, ROS play an important role in cell proliferation, hypoxia adaptation and cell fate determination, but excessive ROS can cause irreversible cell damage and even cell death. The occurrence and development of a number of diseases are closely related to ROS overproduction. Finally, proton leak and uncoupling proteins (UCPS) are discussed. Proton leak consists of basal proton leak and induced proton leak. Induced proton leak is precisely regulated and induced by UCPs. A total of five UCPs (UCP1‑5) have been identified in mammalian cells. UCP1 mainly plays a role in the maintenance of body temperature in a cold environment through non‑shivering thermogenesis. The core role of UCP2‑5 is to reduce oxidative stress under certain conditions, therefore exerting cytoprotective effects. All diseases involving oxidative stress are associated with UCPs.
Topics: Animals; Cell Hypoxia; Cell Proliferation; Electron Transport Chain Complex Proteins; Humans; Mitochondria; Mitochondrial Uncoupling Proteins; Oxidative Stress; Reactive Oxygen Species; Signal Transduction; Thermogenesis
PubMed: 31115493
DOI: 10.3892/ijmm.2019.4188 -
Science (New York, N.Y.) Dec 2021For electrons to continuously enter and flow through the mitochondrial electron transport chain (ETC), they must ultimately land on a terminal electron acceptor (TEA),...
For electrons to continuously enter and flow through the mitochondrial electron transport chain (ETC), they must ultimately land on a terminal electron acceptor (TEA), which is known to be oxygen in mammals. Paradoxically, we find that complex I and dihydroorotate dehydrogenase (DHODH) can still deposit electrons into the ETC when oxygen reduction is impeded. Cells lacking oxygen reduction accumulate ubiquinol, driving the succinate dehydrogenase (SDH) complex in reverse to enable electron deposition onto fumarate. Upon inhibition of oxygen reduction, fumarate reduction sustains DHODH and complex I activities. Mouse tissues display varying capacities to use fumarate as a TEA, most of which net reverse the SDH complex under hypoxia. Thus, we delineate a circuit of electron flow in the mammalian ETC that maintains mitochondrial functions under oxygen limitation.
Topics: Animals; Cell Hypoxia; Cell Line; Cell Line, Tumor; Dihydroorotate Dehydrogenase; Electron Transport; Electron Transport Complex I; Electron Transport Complex III; Electron Transport Complex IV; Electrons; Female; Fumarates; Humans; Mice; Mice, Inbred C57BL; Mitochondria; Oxidation-Reduction; Oxygen; Succinate Dehydrogenase; Ubiquinone
PubMed: 34855504
DOI: 10.1126/science.abi7495 -
Cell Metabolism Feb 2020Glutamine is an essential nutrient that regulates energy production, redox homeostasis, and signaling in cancer cells. Despite the importance of glutamine in...
Glutamine is an essential nutrient that regulates energy production, redox homeostasis, and signaling in cancer cells. Despite the importance of glutamine in mitochondrial metabolism, the mitochondrial glutamine transporter has long been unknown. Here, we show that the SLC1A5 variant plays a critical role in cancer metabolic reprogramming by transporting glutamine into mitochondria. The SLC1A5 variant has an N-terminal targeting signal for mitochondrial localization. Hypoxia-induced gene expression of the SLC1A5 variant is mediated by HIF-2α. Overexpression of the SLC1A5 variant mediates glutamine-induced ATP production and glutathione synthesis and confers gemcitabine resistance to pancreatic cancer cells. SLC1A5 variant knockdown and overexpression alter cancer cell and tumor growth, supporting an oncogenic role. This work demonstrates that the SLC1A5 variant is a mitochondrial glutamine transporter for cancer metabolic reprogramming.
Topics: Amino Acid Transport System ASC; Animals; Basic Helix-Loop-Helix Transcription Factors; Cell Line, Tumor; Cellular Reprogramming; Female; Glutamine; Humans; Mice; Mice, Inbred BALB C; Minor Histocompatibility Antigens; Mitochondria; Neoplasms; Tumor Hypoxia
PubMed: 31866442
DOI: 10.1016/j.cmet.2019.11.020 -
Cell Metabolism Apr 2020NADH provides electrons for aerobic ATP production. In cells deprived of oxygen or with impaired electron transport chain activity, NADH accumulation can be toxic. To...
NADH provides electrons for aerobic ATP production. In cells deprived of oxygen or with impaired electron transport chain activity, NADH accumulation can be toxic. To minimize such toxicity, elevated NADH inhibits the classical NADH-producing pathways: glucose, glutamine, and fat oxidation. Here, through deuterium-tracing studies in cultured cells and mice, we show that folate-dependent serine catabolism also produces substantial NADH. Strikingly, when respiration is impaired, serine catabolism through methylene tetrahydrofolate dehydrogenase (MTHFD2) becomes a major NADH source. In cells whose respiration is slowed by hypoxia, metformin, or genetic lesions, mitochondrial serine catabolism inhibition partially normalizes NADH levels and facilitates cell growth. In mice with engineered mitochondrial complex I deficiency (NDUSF4-/-), serine's contribution to NADH is elevated, and progression of spasticity is modestly slowed by pharmacological blockade of serine degradation. Thus, when respiration is impaired, serine catabolism contributes to toxic NADH accumulation.
Topics: Animals; Cell Hypoxia; Cell Line; Humans; Mice; Mice, Inbred C57BL; Mice, Nude; Mitochondria; NAD; Oxygen; Serine
PubMed: 32187526
DOI: 10.1016/j.cmet.2020.02.017 -
Nature Dec 2020Mitochondria require nicotinamide adenine dinucleotide (NAD) to carry out the fundamental processes that fuel respiration and mediate cellular energy transduction....
Mitochondria require nicotinamide adenine dinucleotide (NAD) to carry out the fundamental processes that fuel respiration and mediate cellular energy transduction. Mitochondrial NAD transporters have been identified in yeast and plants, but their existence in mammals remains controversial. Here we demonstrate that mammalian mitochondria can take up intact NAD, and identify SLC25A51 (also known as MCART1)-an essential mitochondrial protein of previously unknown function-as a mammalian mitochondrial NAD transporter. Loss of SLC25A51 decreases mitochondrial-but not whole-cell-NAD content, impairs mitochondrial respiration, and blocks the uptake of NAD into isolated mitochondria. Conversely, overexpression of SLC25A51 or SLC25A52 (a nearly identical paralogue of SLC25A51) increases mitochondrial NAD levels and restores NAD uptake into yeast mitochondria lacking endogenous NAD transporters. Together, these findings identify SLC25A51 as a mammalian transporter capable of importing NAD into mitochondria.
Topics: Animals; Biological Transport; Cell Line; Cell Respiration; Genetic Complementation Test; Humans; Mice; Mitochondria; Mitochondrial Proteins; NAD; Nucleotide Transport Proteins; Organic Cation Transport Proteins; Saccharomyces cerevisiae; Saccharomyces cerevisiae Proteins
PubMed: 32906142
DOI: 10.1038/s41586-020-2741-7 -
Nature Feb 2023Mitochondria have crucial roles in cellular energetics, metabolism, signalling and quality control. They contain around 1,000 different proteins that often assemble into...
Mitochondria have crucial roles in cellular energetics, metabolism, signalling and quality control. They contain around 1,000 different proteins that often assemble into complexes and supercomplexes such as respiratory complexes and preprotein translocases. The composition of the mitochondrial proteome has been characterized; however, the organization of mitochondrial proteins into stable and dynamic assemblies is poorly understood for major parts of the proteome. Here we report quantitative mapping of mitochondrial protein assemblies using high-resolution complexome profiling of more than 90% of the yeast mitochondrial proteome, termed MitCOM. An analysis of the MitCOM dataset resolves >5,200 protein peaks with an average of six peaks per protein and demonstrates a notable complexity of mitochondrial protein assemblies with distinct appearance for respiration, metabolism, biogenesis, dynamics, regulation and redox processes. We detect interactors of the mitochondrial receptor for cytosolic ribosomes, of prohibitin scaffolds and of respiratory complexes. The identification of quality-control factors operating at the mitochondrial protein entry gate reveals pathways for preprotein ubiquitylation, deubiquitylation and degradation. Interactions between the peptidyl-tRNA hydrolase Pth2 and the entry gate led to the elucidation of a constitutive pathway for the removal of preproteins. The MitCOM dataset-which is accessible through an interactive profile viewer-is a comprehensive resource for the identification, organization and interaction of mitochondrial machineries and pathways.
Topics: Carrier Proteins; Mitochondria; Mitochondrial Proteins; Protein Transport; Proteome; Saccharomyces cerevisiae; Fungal Proteins; Cell Respiration; Ribosomes; Datasets as Topic
PubMed: 36697829
DOI: 10.1038/s41586-022-05641-w -
Cell Reports Nov 2019Impaired mitochondrial respiratory activity contributes to the development of insulin resistance in type 2 diabetes. Metformin, a first-line antidiabetic drug, functions...
Impaired mitochondrial respiratory activity contributes to the development of insulin resistance in type 2 diabetes. Metformin, a first-line antidiabetic drug, functions mainly by improving patients' hyperglycemia and insulin resistance. However, its mechanism of action is still not well understood. We show here that pharmacological metformin concentration increases mitochondrial respiration, membrane potential, and ATP levels in hepatocytes and a clinically relevant metformin dose increases liver mitochondrial density and complex 1 activity along with improved hyperglycemia in high-fat- diet (HFD)-fed mice. Metformin, functioning through 5' AMP-activated protein kinase (AMPK), promotes mitochondrial fission to improve mitochondrial respiration and restore the mitochondrial life cycle. Furthermore, HFD-fed-mice with liver-specific knockout of AMPKα1/2 subunits exhibit higher blood glucose levels when treated with metformin. Our results demonstrate that activation of AMPK by metformin improves mitochondrial respiration and hyperglycemia in obesity. We also found that supra-pharmacological metformin concentrations reduce adenine nucleotides, resulting in the halt of mitochondrial respiration. These findings suggest a mechanism for metformin's anti-tumor effects.
Topics: AMP-Activated Protein Kinase Kinases; AMP-Activated Protein Kinases; Adenine Nucleotides; Animals; Blood Glucose; Cell Respiration; Diet, High-Fat; Electron Transport Complex I; Gene Knockout Techniques; Hepatocytes; Hyperglycemia; Hypoglycemic Agents; Insulin Resistance; Liver; Metformin; Mice; Mice, Inbred C57BL; Mitochondria, Liver; Mitochondrial Dynamics; Protein Kinases
PubMed: 31693892
DOI: 10.1016/j.celrep.2019.09.070