Role of Mitochondria in Ferroptosis

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Role of Mitochondria in Human Aging

Mitochondria are the major intracellular source and target sites of reactive oxygen species (ROS) that are continually generated as by-products of aerobic metabolism in animal and human cells. It has been demonstrated that mitochondrial respiratory function declines with age in various human tissues and that a defective respiratory chain results in enhanced production of ROS and free radicals in mitochondria. On the other hand, accumulating evidence now indicates that lipid peroxidation, protein modification and mitochondrial DNA (mtDNA) muutation are concurrently increased during aging. On the basis of these observations and the fact that the rate of cellular production of superoxide anions and hydrogen peroxide increases with age, it has recently been postulated that oxidative stress is a major contributory factor in the aging process. A causal relationship between oxidative modification and mutation of mtDNA, mitochondrial dysfunction and aging has emerged, although some details have remained unsolved. In this article, the role of mitochondria in the human aging process is reviewed on the basis of recent findings gathered from our and other laboratories.     

The Role of Mitochondria in Glioma Pathophysiology

It has long been recognised that malignant tumours favour aerobic glycolysis to generate ATP and contain abnormalities of the intrinsic, mitochondria-dependent, apoptotic pathway, suggesting the involvement of dysfunctional mitochondria in tumour pathophysiology. However, the mechanisms underlying such processes in gliomas are poorly understood. Few recent studies have evaluated mitochondrial ultrastructure and proteomics in the pathophysiology of malignant gliomas. However, aberrant energy metabolism has been reported in gliomas and mitochondrial dysfunction links to glioma apoptotic signalling have been observed. Mitochondrial structural abnormalities and dysfunction in malignant gliomas is a neglected area of research. Definition of abnormalities in mitochondrial proteomics, membrane potential regulation, energy metabolism and intrinsic apoptotic pathway signalling in gliomas may open novel therapeutic opportunities.     

The Role of Mitochondria in Stem Cell Biology

This mini-review summarizes the current literature on the role of mitochondrial DNA mutations and mitochondrial metabolism in stem cell biology. The possible uses of stem cells as a therapeutic tool in mitochondrial disorders are also reported.     

Role of Mitochondria in the Mechanisms of Glutamate Toxicity

Current data on glutamate-induced functional and morphological changes in mitochondria correlating with or being a result of their membrane potential changes are reviewed. The important role of Ca²⁺, Na⁺, and H⁺ in the potentiation of such changes is considered. It is assumed that glutamate-induced loss of mitochondrial potential is mediated by Ca²⁺ overload resulting in the induction of nonspecific permeability of the inner mitochondrial membrane.__________Translated from Biokhimiya, Vol. 70, No. 6, 2005, pp. 741–750.Original Russian Text Copyright © 2005 by Isaev, Andreeva, Stel’mashuk, Zorov.     

Role of Mitochondria in the Production of RNA-Containing Tumor Viruses

The role of mitochondria in the reproduction of RNA-containing tumor viruses was examined by using ethidium bromide (EB) to induce degenerative effects in mitochondria. The effects of EB in murine and avian cells were monitored by electron microscopy. Chronically infected mouse (JLS-V5) cells, in which extensive mitochondrial changes were induced, continued to produce murine leukemia virus. Also, complete reproductive cycles of Rous sarcoma virus (RSV) occurred in newly infected chicken embryo cells exposed to EB. Morphological transformation characteristic of infection of chicken embryo cells by RSV occurred in cells which contained induced aberrant mitochondria. The results demonstrate that mitochondria play a relatively minor role, if any, in the reproduction of RNA-containing tumor viruses.     

线粒体在运动保护心肌免受缺血再灌注损伤中的作用

线粒体是参与心肌缺血再灌注(myocardial ischemia and reperfusion,MI/R)损伤的关键细胞器,线粒体活性氧(reactive oxygen species,ROS)爆发、Ca²⁺失调、线粒体通透性转换孔(mitochondrial permeability transition pore,mPTP)开放、线粒体肿胀、促凋亡蛋白释放等都会导致线粒体功能障碍,心肌功能受损。运动是预防MI/R损伤的有效干预手段,其保护作用可能通过线粒体来实现。运动保护MI/R损伤的线粒体机制由多种因素决定,如线粒体能量学、K_ATP通道、mPTP、线粒体跨膜电位(ΔΨ_m)、线粒体蛋白、线粒体脂质、线粒体质量控制、远程调控因子等。本文综述了MI/R产生的线粒体机制,运动对MI/R的保护作用以及线粒体在其中的作用,以期为MI/R损伤的线粒体治疗策略提供参考。     

Circadian Rhythms in Neurospora crassa: The Role of Mitochondria

Energy metabolism and mitochondria have been discussed with respect to their role in the circadian rhythm mechanism for some time. Numerous examples of inhibitors that affect the mitochondria of plants and animals and microorganisms are known, which cause large phase shifts in the rhythms of these organisms. Analogous studies on the role of mitochondria in the Neurospora circadian rhythm mechanism have also been reported and summarized. This communication differs from previous studies on other organisms in that it will focus on two lines of evidence derived from studies on Neurospora strains carrying mutations affecting the mitochondria, (a) Strains whose growth rate is resistant to oligomycin (oli^t) owing to an altered protein in the F₀ sector of the mitochondrial ATPase, showed no phase shifts when pulsed with oligomycin. Control strains (oli⁸) showed large phase shifts when pulsed with oligomycin. This indicates that the phase-shifting effect of oligomycin is due to the direct inhibition of the mitochondrial ATPase and not some side effect of this inhibitor, (b) In Neurospora, many different strains are known that carry mutations in the nuclear or mitochondrial genome that affect mitochondrially localized proteins. Some of these, such as oli', [MI-3], or cya-5, showed shorter (≥ 19-h) periods compared with the normal (21.5-h) period. Others showed little or no change in period. Those mutant strains exhibiting shorter periods also contained ≥60% more mitochondrial protein per gram total protein in extracts compared with the normal strains. Assays of the level of a mitochondrial-specific protein, acyl carrier protein, showed that the cellular content of this protein was approximately doubled. A parallel set of studies on the effects of antimycin or chloramphenicol on Neurospora demonstrated that these inhibitors also produced shorter periods as well as increased amounts of mitochondrial proteins. These two new lines of evidence may be interpreted to indicate that in Neurospora either some part of the oscillator is localized to the mitochondria and/or that mitochondria exert their effect on the clock mechanism through their effects on biosynthetic pathways or by their contribution in determining ion gradients.     

Circadian Rhythms in Neurospora crassa: The Role of Mitochondria

Energy metabolism and mitochondria have been discussed with respect to their role in the circadian rhythm mechanism for some time. Numerous examples of inhibitors that affect the mitochondria of plants and animals and microorganisms are known, which cause large phase shifts in the rhythms of these organisms. Analogous studies on the role of mitochondria in the Neurospora circadian rhythm mechanism have also been reported and summarized. This communication differs from previous studies on other organisms in that it will focus on two lines of evidence derived from studies on Neurospora strains carrying mutations affecting the mitochondria, (a) Strains whose growth rate is resistant to oligomycin (oli^t) owing to an altered protein in the F₀ sector of the mitochondrial ATPase, showed no phase shifts when pulsed with oligomycin. Control strains (oli⁸) showed large phase shifts when pulsed with oligomycin. This indicates that the phase-shifting effect of oligomycin is due to the direct inhibition of the mitochondrial ATPase and not some side effect of this inhibitor, (b) In Neurospora, many different strains are known that carry mutations in the nuclear or mitochondrial genome that affect mitochondrially localized proteins. Some of these, such as oli', [MI-3], or cya-5, showed shorter (≥ 19-h) periods compared with the normal (21.5-h) period. Others showed little or no change in period. Those mutant strains exhibiting shorter periods also contained ≥60% more mitochondrial protein per gram total protein in extracts compared with the normal strains. Assays of the level of a mitochondrial-specific protein, acyl carrier protein, showed that the cellular content of this protein was approximately doubled. A parallel set of studies on the effects of antimycin or chloramphenicol on Neurospora demonstrated that these inhibitors also produced shorter periods as well as increased amounts of mitochondrial proteins. These two new lines of evidence may be interpreted to indicate that in Neurospora either some part of the oscillator is localized to the mitochondria and/or that mitochondria exert their effect on the clock mechanism through their effects on biosynthetic pathways or by their contribution in determining ion gradients.     

Interaction between Chloroplasts and Mitochondria in Microalgae: Role of Glycolysis

In a mutant strain of Chlamydomonas reinhardtii devoid of active ribulose 1,5-bisphosphate carboxylase oxygenase, the addition of mitochondrial inhibitors in the dark resulted in a pronounced decrease in cellular ATP, a fall of the glucose 6-phosphate content, and a rise of the NADPH concentration. These biochemical changes were accompanied by an increase of the fluorescence level, showing changes in the redox state of the chloroplastic electron transport chain. Similar results were obtained in presence of an uncoupler. These data indicated that alterations in the mitochondrial electron transport chain in dark could affect the chloroplastic chain, probably through variations of the glycolysis activity. When mitochondrial oxidases were blocked, illumination of the algae reversed the effect of the inhibitors on the ATP and glucose 6-phosphate concentrations. This last result suggested that the chloroplastic photophosphorylations in these algae played a major role in the control of the glycolytic flux.     

An Overview: The Diversified Role of Mitochondria in Cancer Metabolism

Mitochondria are intracellular organelles involved in energy production, cell metabolism and cell signaling. They are essential not only in the process of ATP synthesis, lipid metabolism and nucleic acid metabolism, but also in tumor development and metastasis. Mutations in mtDNA are commonly found in cancer cells to promote the rewiring of bioenergetics and biosynthesis, various metabolites especially oncometabolites in mitochondria regulate tumor metabolism and progression. And mutation of enzymes in the TCA cycle leads to the unusual accumulation of certain metabolites and oncometabolites. Mitochondria have been demonstrated as the target for cancer treatment. Cancer cells rely on two main energy resources: oxidative phosphorylation (OXPHOS) and glycolysis. By manipulating OXPHOS genes or adjusting the metabolites production in mitochondria, tumor growth can be restrained. For example, enhanced complex I activity increases NAD⁺/NADH to prevent metastasis and progression of cancers. In this review, we discussed mitochondrial function in cancer cell metabolism and specially explored the unique role of mitochondria in cancer stem cells and the tumor microenvironment. Targeting the OXPHOS pathway and mitochondria-related metabolism emerging as a potential therapeutic strategy for various cancers.     

Mitochondria: Role of citrulline and arginine supplementation in MELAS syndrome

Mitochondria are found in all nucleated human cells and generate most of the cellular energy. Mitochondrial disorders result from dysfunctional mitochondria that are unable to generate sufficient ATP to meet the energy needs of various organs. Mitochondrial encephalomyopathy, lactic acidosis, and stroke-like episodes (MELAS) syndrome is a frequent maternally inherited mitochondrial disorder. There is growing evidence that nitric oxide (NO) deficiency occurs in MELAS syndrome and results in impaired blood perfusion that contributes significantly to several complications including stroke-like episodes, myopathy, and lactic acidosis. Both arginine and citrulline act as NO precursors and their administration results in increased NO production and hence can potentially have therapeutic utility in MELAS syndrome. Citrulline raises NO production to a greater extent than arginine, therefore, citrulline may have a better therapeutic effect. Controlled studies assessing the effects of arginine or citrulline supplementation on different clinical aspects of MELAS syndrome are needed.     

The Role of Mitochondria in T-2 Toxin-Induced Human Chondrocytes Apoptosis

T-2 toxin, a mycotoxin produced by Fusarium species, has been shown to cause diverse toxic effects in animals and is also a possible pathogenic factor of Kashin–Beck disease (KBD). The role of mitochondria in KBD is recognized in our recent research. The aim of this study was to evaluate the role of mitochondria in T-2 toxin-induced human chondrocytes apoptosis to understand the pathogenesis of KBD. T-2 toxin decreased chondrocytes viabilities in concentration- and time-dependent manners. Exposure to T-2 toxin can reduce activities of mitochondrial complexes III, IV and V, ΔΨm and the cellular ATP, while intracellular ROS increased following treatment with T-2 toxin. Furthermore, mitochondrial cytochrome c release, caspase-9 and 3 activation and chondrocytes apoptosis were also obviously observed. Interestingly, Selenium (Se) can partly block T-2 toxin -induced mitochondria dysfunction, oxidative damage and chondrocytes apoptosis. These results suggest that the effect of T-2 toxin on human chondrocytes apoptosis may be mediated by a mitochondrial pathway, which is highly consistent with the chondrocytes changes in KBD.     

CpG Dinucleotide Frequencies Reveal the Role of Host Methylation Capabilities in Parvovirus Evolution

Parvoviruses are rapidly evolving viruses that infect a wide range of hosts, including vertebrates and invertebrates. Extensive methylation of the parvovirus genome has been recently demonstrated. A global pattern of methylation of CpG dinucleotides is seen in vertebrate genomes, compared to “fractional” methylation patterns in invertebrate genomes. It remains unknown if the loss of CpG dinucleotides occurs in all viruses of a given DNA virus family that infect host species spanning across vertebrates and invertebrates. We investigated the link between the extent of CpG dinucleotide depletion among autonomous parvoviruses and the evolutionary lineage of the infected host. We demonstrate major differences in the relative abundance of CpG dinucleotides among autonomous parvoviruses which share similar genome organization and common ancestry, depending on the infected host species. Parvoviruses infecting vertebrate hosts had significantly lower relative abundance of CpG dinucleotides than parvoviruses infecting invertebrate hosts. The strong correlation of CpG dinucleotide depletion with the gain in TpG/CpA dinucleotides and the loss of TpA dinucleotides among parvoviruses suggests a major role for CpG methylation in the evolution of parvoviruses. Our data present evidence that links the relative abundance of CpG dinucleotides in parvoviruses to the methylation capabilities of the infected host. In sum, our findings support a novel perspective of host-driven evolution among autonomous parvoviruses.     

MyD88在抗衣原体感染的病理损伤过程中的作用

<正>沙眼衣原体(Chlamydia trachomatis,Ct)是引起泌尿生殖道感染的常见性病病原体之一,并可导致不孕、异位妊娠、宫颈鳞状细胞癌等并发症[1]。但有关沙眼衣原体确切的致病机制及机体的抗感染机制目前尚不清     

Germ Plasm and Germ-line Cell Determination: The Role of Mitochondria

Literature data on the structure and origin of material of the germ cell line determinants and on the presence of products of nuclear and mitochondrial genomes in the structured germ determinants (nuage) are reviewed. The personal data, obtained on spermatogenic cells of sea urchin and of other marine invertebrates, evidence the transformation of the mitochondrial matrix into the nuage material. The presence of matrix structures of mitochondrial origin in the germ plasm, which ensure reproduction and the function of the structured macromolecular complex of germ determinants relatively independent from the nuclear genome, is suggested.     

Role of Mitochondria in the Generation of Acetylcholine-Induced Calcium Transients in Rat Chromaffin Cells

A fluorescent probe, FURA-2M, was used to examine the role of mitochondria in the generation of calcium transients evoked by acetylcholine (ACh) in isolated rat chromaffin cells. Our experiments showed that application of 10 M CCCP (carbonyl cyanide m-chlorophenylhydrazone, a mitochondrial protonophore) caused significant intracellular calcium transients (F1/F2 wave ratio 1.05). Application of CCCP did not affect the successive responses to repeated ACh applications in a cell subpopulation with the domination of nicotinic receptors (F1/F2 = 0.90 in control, and F1/F2 = 0.89 after CCCP application). In cells with the domination of muscarinic receptors, responses to repeated ACh applications decreased under control conditions. Application of CCCP caused recovery of the successive ACh responses by 27%, as compared with the control. The results allow us to suggest that the mitochondria themselves are not directly involved in the ACh-induced calcium transients, but calcium release from the mitochondria during CCCP treatment can cause the replenishment of other intracellular stores (endoplasmic reticulum) and in such a way recover the ACh responses to repeated stimulations in the cells with dominating metabotropic receptors.     

Novel Role of Calmodulin in Regulating Protein Transport to Mitochondria in a Unicellular Eukaryote

Lower eukaryotes like the kinetoplastid parasites are good models to study evolution of cellular pathways during steps to eukaryogenesis. In this study, a kinetoplastid parasite, Leishmania donovani, was used to understand the process of mitochondrial translocation of a nucleus-encoded mitochondrial protein, the mitochondrial tryparedoxin peroxidase (mTXNPx). We report the presence of an N-terminal cleavable mitochondrial targeting signal (MTS) validated through deletion and grafting experiments. We also establish a novel finding of calmodulin (CaM) binding to the MTS of mTXNPx through specific residues. Mutation of CaM binding residues, keeping intact the residues involved in mitochondrial targeting and biochemical inhibition of CaM activity both in vitro and in vivo, prevented mitochondrial translocation. Through reconstituted import assays, we demonstrate obstruction of mitochondrial translocation either in the absence of CaM or Ca²⁺ or in the presence of CaM inhibitors. We also demonstrate the prevention of temperature-driven mTXNPx aggregation in the presence of CaM. These findings establish the idea that CaM is required for the transport of the protein to mitochondria through maintenance of translocation competence posttranslation.