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Mitochondria
Kinds of Mitochondria Terms modified by Mitochondria Selected AbstractsMORPHOLOGICAL CHANGES IN MITOCHONDRIAL AND CHLOROPLAST NUCLEOIDS AND MITOCHONDRIA DURING THE CHLAMYDOMONAS REINHARDTII (CHLOROPHYCEAE) CELL CYCLE,JOURNAL OF PHYCOLOGY, Issue 5 2006Takayoshi Hiramatsu Morphological changes in the organellar nucleoids and mitochondria of living Chlamydomonas reinhardtii Dang were examined during the cell cycle under conditions of 12:12 light:dark. The nucleoids were stained with SYBR-Green I, and the mitochondria were stained with 3,3-dihexyloxacarbocyanine iodide. An mocG33 mutant, which contains one large chloroplast nucleoid throughout the cell cycle, was used to distinguish between the mitochondrial and chloroplast nucleoids. Changes in the total levels of organellar DNA levels were assessed by real-time PCR. Each of the G1, S, M, and Smt,cp phases was estimated. At the start of the light period, the new daughter cells were in G1 and contained about 30 mitochondrial and 10 chloroplast nucleoids, which were dispersed and had diameters of 0.1 and 0.2 ,m, respectively. During the G1 phase of the light period, and at the start of the S phase, both nucleoids formed short thread-like or bead-like structures, probably divided, and increased continuously in number, concomitantly with DNA synthesis. The nucleoids probably became smaller due to the decrease in DNA of each particle and were indistinguishable. The cells in the S and M phases contained extremely high numbers of scattered nucleoids. However, in the G1 phase of the dark period, the nucleoids again formed short thread-like or bead-like structures, probably fused, and decreased in number. The mitochondria appeared as tangled sinuous structures that extended throughout the cytoplasm and resembled a single large mitochondrion. During the cell cycle, the numbers of mitochondrial nucleoids and sinuous structures varied relative to one another. [source] Ageing, oxidative stress, and mitochondrial uncouplingACTA PHYSIOLOGICA, Issue 4 2004M.-E. Harper Abstract Mitochondria are a cell's single greatest source of reactive oxygen species. Reactive oxygen species are important for many life sustaining processes of cells and tissues, but they can also induce cell damage and death. If their production and levels within cells is not effectively controlled, then the detrimental effects of oxidative stress can accumulate. Oxidative stress is widely thought to underpin many ageing processes, and the oxidative stress theory of ageing is one of the most widely acknowledged theories of ageing. As well as being the major source of reactive oxygen species, mitochondria are also a major site of oxidative damage. The purpose of this review is a concise and current review of the effects of oxidative stress and ageing on mitochondrial function. Emphasis is placed upon the roles of mitochondrial proton leak, the uncoupling proteins, and the anti-ageing effects of caloric restriction. [source] Deletion of mdmB impairs mitochondrial distribution and morphology in Aspergillus nidulansCYTOSKELETON, Issue 2 2003Katrin V. Koch Abstract Mitochondria form a dynamic network of interconnected tubes in the cells of Saccharomyces cerevisiae or filamentous fungi such as Aspergillus nidulans,Neurospora crassa, or Podospora anserina. The dynamics depends on the separation of mitochondrial fragments, their movement throughout the cell, and their subsequent fusion with the other parts of the organelle. Interestingly, the microtubule network is required for the distribution in N. crassa and S. pombe, while S. cerevisiae and A. nidulans appear to use the actin cytoskeleton. We studied a homologue of S. cerevisiae Mdm10 in A. nidulans, and named it MdmB. The open reading frame is disrupted by two introns, one of which is conserved in mdm10 of P. anserina. The MdmB protein consists of 428 amino acids with a predicted molecular mass of 46.5 kDa. MdmB shares 26% identical amino acids to Mdm10 from S. cerevisiae, 35% to N. crassa, and 32% to the P. anserina homologue. A MdmB-GFP fusion protein co-localized evenly distributed along mitochondria. Extraction of the protein was only possible after treatment with a non-ionic and an ionic detergent (1% Triton X-100; 0.5% SDS) suggesting that MdmB was tightly bound to the mitochondrial membrane fraction. Deletion of the gene in A. nidulans affected mitochondrial morphology and distribution at 20°C but not at 37°C. mdmB deletion cells contained two populations of mitochondria at lower temperature, the normal tubular network plus some giant, non-motile mitochondria. Cell Motil. Cytoskeleton 55:114,124, 2003. © 2003 Wiley-Liss, Inc. [source] The impact of prolonged fasting during aestivation on the structure of the small intestine in the green-striped burrowing frog, Cyclorana alboguttataACTA ZOOLOGICA, Issue 1 2005Rebecca L. Cramp Abstract The effects of short-term fasting and prolonged fasting during aestivation on the morphology of the proximal small intestine and associated organs were investigated in the green-striped burrowing frog, Cyclorana alboguttata (Anura: Hylidae). Animals were fasted for 1 week while active or for 3,9 months during aestivation. Short-duration fasting (1 week) had little effect on the morphology of the small intestine, whilst prolonged fasting during aestivation induced marked enteropathy including reductions in intestinal mass, length and diameter, longitudinal fold height and tunica muscularis thickness. Enterocyte morphology was also affected markedly by prolonged fasting: enterocyte cross-sectional area and microvillous height were reduced during aestivation, intercellular spaces were visibly reduced and the prevalence of lymphocytes amongst enterocytes was increased. Mitochondria and nuclei were also affected by 9 months of aestivation with major disruptions to mitochondrial cristae and increased clumping of nuclear material and increased infolding of the nuclear envelope. The present study demonstrates that the intestine of an aestivating frog responds to prolonged food deprivation during aestivation by reducing in size, presumably to reduce the energy expenditure of the organ. [source] Electrochemistry of Mitochondria: A New Way to Understand Their Structure and FunctionELECTROANALYSIS, Issue 14 2008Jing Zhao Abstract In this article, electrochemistry of mitochondria is achieved. Cyclic voltammograms of freshly prepared mitochondria were obtained by immobilizing mitochondria together with glutaraldehyde and bovine serum albumin on the surface of a pyrolytic graphite electrode. Two pairs of redox peaks could be observed which were ascribed to the electron transfer reactions of cytochrome c and FAD/FADH2. Study of submitochondrial particles was also conducted, which could confirm the results of the study of the entire mitochondria. The redox wave of NADH could be obtained due to the destruction of the membrane of mitochondria. We have also checked the function of succinate in mitochondria by employing the electrochemical method. This work is not only the first to be able to obtain the direct electrochemistry of mitochondria, but is also beneficial to the further understanding of the structure and function of mitochondria in vitro. [source] 13C-breath tests for clinical investigation of liver mitochondrial functionEUROPEAN JOURNAL OF CLINICAL INVESTIGATION, Issue 9 2010Ignazio Grattagliano Eur J Clin Invest 2010; 40 (9): 843,850 Abstract Background, Mitochondria play a major role in cell energetic metabolism; therefore, mitochondrial dysfunction inevitably participates in or even determines the onset and progression of chronic liver diseases. The assessment of mitochondrial function in vivo, by providing more insight into the pathogenesis of liver diseases, would be a helpful tool to study specific hepatic functions and to develop rational diagnostic, prognostic and therapeutic strategies. Design, This review focuses on the utility of breath tests to assess mitochondrial function in humans and experimental animals. Results, The introduction in the clinical setting of specific breath tests may allow elegantly and noninvasively overcoming the difficulties caused by previous complex techniques and might provide clinically relevant information, i.e the effects of drugs on mitochondria. Substrates meeting this requirement are alpha-keto-isocaproic acid and methionine that are both decarboxylated by mitochondria. Long-and medium-chain fatty acids that are metabolized through the Krebs cycle, and benzoic acid which undergoes glycine conjugation, may also reflect the function of mitochondria. Conclusions, Breath tests to assess in vivo mitochondrial function in humans represent a potentially useful diagnostic and prognostic tool in clinical investigation. [source] Haemodialysis induces mitochondrial dysfunction and apoptosisEUROPEAN JOURNAL OF CLINICAL INVESTIGATION, Issue 12 2007D. S. C. Raj Abstract Background Mitochondria play a crucial role in the regulation of the endogenous pathways of apoptosis activated by oxidant stress. Nuclear factor-,B (NF-,B) is a central integration site for pro-inflammatory signals and oxidative stress. Materials and methods Peripheral blood mononuclear cells (PBMC) were isolated from eight end-stage renal disease (ESRD) patients before haemodialysis (Pre-HD) and during the last 10 min of HD (End-HD). A new polysulfone membrane (F70, Fresenius) was used for dialysis. Intracellular generation of reactive oxygen species (ROS), mitochondrial redox potential (,,m) and PBMC apoptosis were determined by flow-cytometry. Results Plasma levels of interleukin-6 (IL-6) (24·9 ± 7·0 vs. 17·4 ± 5·5 pg dL,1, P < 0·05), IL-6 soluble receptor (52·2 ± 4·9 vs. 37·6 ± 3·2 ng dL,1, P < 0·02) and IL-6 gp130 (405·7 ± 41·0 vs. 235·1 ± 38·4 ng dL,1, P < 0·02) were higher end-HD compared to pre-HD. IL-6 secretion by the isolated PBMC (24·0 ± 2·3 vs. 19·3 ± 3·5 pg dL,1, P < 0·02) increased end-HD. Percentage of lymphocytes exhibiting collapse of mitochondrial membrane potential (43·4 ± 4·6% vs. 32·6 ± 2·9%, P < 0·01), apoptosis (33·4 ± 7·1% vs. 23·7 ± 7·7%, P < 0·01), and generation of superoxide (20·7 ± 5·2% vs. 12·5 ± 2·9%, P < 0·02) and hydrogen peroxide (51·1 ± 7·8% vs.38·2 ± 5·9%, P < 0·04) were higher at end-HD than pre-HD. NF-,B activation (3144·1 ± 208·1 vs. 2033·4 ± 454·6 pg well,1, P < 0·02), expression of B-cell lymphoma protein-2 (6494·6 ± 1461 vs. 3501·5 ± 796·5 ng mL,1, P < 0·03) and heat shock protein-70 (9·81 ± 1·47 vs. 6·38 ± 1·0 ng mL,1, P < 0·05) increased during HD. Conclusions Intra-dialytic activation of cytokines, together with impaired mitochondrial function, promotes generation of ROS culminating in augmented PBMC apoptosis. There is concomitant activation of pathways aimed at attenuation of cell stress and apoptosis during HD. [source] Mitochondrial function and endocrine diseasesEUROPEAN JOURNAL OF CLINICAL INVESTIGATION, Issue 4 2007R. Stark Abstract Mitochondria are fundamental for oxidative energy production and impairment of their functionality can lead to reduced ATP synthesis and contribute to initiation of apoptosis. Endocrine tissues critically rely on oxidative phosphorylation so that mitochondrial abnormalities may either be causes or consequences of diminished hormone production or action. Abnormalities typical for diseases caused by mitochondrial DNA mutations such as Kearns,Sayre syndrome or mitochondrial encephalomyopathy, lactic acidosis, and stroke,like episodes syndrome are also seen in certain endocrine diseases. Lack or excess of thyroid hormones, major ubiquitous regulators of mitochondrial content and activity, cause muscular abnormalities and multisystem disorders. Mitochondria are a further prerequisite for steroidogenesis as well as insulin secretion and action. Recent studies showed that reduced mitochondrial ATP synthesis in skeletal muscle is a feature of certain hereditary and acquired forms of insulin resistance and diabetes mellitus. Finally, ageing is not only accompanied by various degrees of hormonal deficiency and insulin resistance but is also associated with a progressive decline of mitochondrial number and function. Future research is needed to examine whether mitochondrial abnormalities are the cause or consequence of ageing and frequent metabolic diseases such as obesity and type 2 diabetes mellitus, and to address mitochondria as a target for novel therapeutic regimes. [source] Oxygen sensing in hypoxic pulmonary vasoconstriction: using new tools to answer an age-old questionEXPERIMENTAL PHYSIOLOGY, Issue 1 2008Gregory B. Waypa Hypoxic pulmonary vasoconstriction (HPV) becomes activated in response to alveolar hypoxia and, although the characteristics of HPV have been well described, the underlying mechanism of O2 sensing which initiates the HPV response has not been fully established. Mitochondria have long been considered as a putative site of oxygen sensing because they consume O2 and therefore represent the intracellular site with the lowest oxygen tension. However, two opposing theories have emerged regarding mitochondria-dependent O2 sensing during hypoxia. One model suggests that there is a decrease in mitochondrial reactive oxygen species (ROS) levels during the transition from normoxia to hypoxia, resulting in the shift in cytosolic redox to a more reduced state. An alternative model proposes that hypoxia paradoxically increases mitochondrial ROS signalling in pulmonary arterial smooth muscle. Experimental resolution of the question of whether the mitochondrial ROS levels increase or decrease during hypoxia has been problematic owing to the technical limitations of the tools used to assess oxidant stress as well as the pharmacological agents used to inhibit the mitochondrial electron transport chain. However, recent developments in genetic techniques and redox-sensitive probes may allow us eventually to reach a consensus concerning the O2 sensing mechanism underlying HPV. [source] Effect of fatty acid-binding proteins on intermembrane fatty acid transportFEBS JOURNAL, Issue 19 2000Studies on different types, mutant proteins Liposomes of different charge fixed to nitrocellulose filters were used to study the transfer of fatty acids to rat heart or liver mitochondria in the presence of fatty acid-binding protein (FABP) or albumin. [14C]Palmitate oxidation was used as a parameter. Different FABP types and heart FABP mutants were tested. The charge of the liposomes did not influence the solubilization and mitochondrial oxidation of palmitate without FABP and the amount of solubilized palmitate in the presence of FABP. Mitochondria did not show a preference for oxidation of FABP-bound palmitate over their tissue-specific FABP type. All FABP types increased palmitate oxidation by heart and liver mitochondria with neutral, positive and negative liposomes by 2.5-fold, 3.2-fold and twofold, respectively. Ileal lipid-binding protein and H-FABP mutants that do not bind fatty acid had no effect. Other H-FABP mutants had different effects, dependent on the site of mutation. The effect of albumin was similar to, but not dependent on, liposome charge. The ionic strength had only a slight effect. In conclusion, the transfer of palmitate from liposomal membranes to mitochondria was increased by all FABP types to a similar extent. The membrane charge had a large effect in contrast to the origin of the mitochondria. [source] Ultrastructural clues for the potent therapeutic effect of melatonin on aging skin in pinealectomized ratsFUNDAMENTAL & CLINICAL PHARMACOLOGY, Issue 6 2006Mukaddes E Abstract Recently we have reported a significant reduction in the thickness of epidermis and epidermis + dermis in the back, abdominal and thoracic skin of the long-term pinealectomized rats and the potent therapeutic effect of melatonin on the pinealectomy-induced morphometric changes. The present study was aimed to determine the fine structure of the abdominal and thoracic skin in pinealectomized rats and the effect of melatonin on skin ultrastructure. Rats were pinealectomized or sham operated (control) for 6 months. Half of the pinealectomized rats were treated with 4 mg/kg melatonin during the last month of the experiment. Pinealectomy resulted in prominent ultrastructural changes in the skin. Epidermal atrophy, disorganization and cytological atypia were obvious. Tonofilament distribution was not uniform, and intercellular space was narrow. Nuclear irregularity and heterochromatin condensation were detected. Many mitochondria were irregular and edematous with increased translucence of the matrix, either partial or total destruction of crests and frequently the presence of vacuoles, myelin figures and dense bodies. Microprojections of basal cells into the dermis were observed. The dermis was thin, and collagenous fibers were loosely arranged. The epidermis in melatonin administered pinealectomized rats was obviously thicker than that of pinealectomized rats. The cells of each layers had characteristic morphological and ultrastructural features. Nuclear irregularity and heterochromatin condensation were not seen. Mitochondria were generally normal in ultrastructural appearance but rarely vacuoles and myelin figures were observed. The dermis was thick, and collagenous fibers were closely packaged. This paper provides an additional ultrastructural evidence that the damage to mitochondria is the major contributory factor to skin aging and that melatonin has potent therapeutic effects in reducing age-related changes via protecting fine structure of the skin. [source] A member of the YER057c/yjgf/Uk114 family links isoleucine biosynthesis and intact mitochondria maintenance in Saccharomyces cerevisiaeGENES TO CELLS, Issue 6 2001Jong-Myong Kim Background Two paralogs, YIL051c and YER057c, in the Saccharomyces cerevisiae genome are members of the YER057c/Yigf/Uk114 family, which is highly conserved among Eubacteria, Archaea and Eukarya. Although the molecular function of this protein family is not clear, previous studies suggest that it plays a role in the regulation of metabolic pathways and cell differentiation. Results Yil051cp is 70% identical in amino acid sequence to Yer057cp, and differs in that the former is longer by 16 amino acids containing, in part, the mitochondrial targeting signal at the N-terminus of the protein. An HA-tagged protein of Yil051cp is localized strictly in mitochondria, while that of Yer057cp is found in both cytoplasm and nucleus. Disruption of YIL051c (yil051c,) resulted in severe growth retardation in glucose medium due to isoleucine auxotroph, and no growth in glycerol medium due to the loss of mitochondria. An extract prepared from yil051c, cells showed no transaminase activity for isoleucine, while that for valine or leucine was intact. Haploid yil051c, cells newly isolated from the YIL051c/yil051c, hetero-diploids gradually lost mitochondrial DNA within 24 h in the absence of, but not in the presence of, an isoleucine. Mutants either requiring leucine (leu2,112) or isoleucine-valine (bat1,, bat2,) in a YIL051c background showed no changes in mitochondrial DNA maintenance in the absence of requirements. Conclusions Based on these results, we named Yil051c as Ibm1 (Isoleucine Biosynthesis and Mitochondria maintenance1) and concluded that: (i) Ibm1p determines the specificity of isoleucine biosynthesis, probably at the transamination step, (ii) Ibm1p is required for the maintenance of mitochondrial DNA when isoleucine is deficient, and (iii) Isoleucine compensates for the lack of Ibm1p. Taken together, Ibm1p may act as a sensor for isoleucine deficiency as well as a regulator determining the specificity for branched amino acid transaminase. [source] Chronic alcohol consumption increases the sensitivity of rat liver mitochondrial respiration to inhibition by nitric oxideHEPATOLOGY, Issue 1 2003Aparna Venkatraman Chronic alcohol consumption is a well-known risk factor for hepatic injury, and mitochondrial damage plays a significant role in this process. Nitric oxide (NO) is an important modulator of mitochondrial function and is known to inhibit mitochondrial respiration. However, the impact of chronic alcohol consumption on NO-dependent control of liver mitochondrial function is unknown. This study examines the effect of alcohol exposure on liver mitochondria in a rat model and explores the interaction of NO and mitochondrial respiration in this context. Mitochondria were isolated from the liver of both control and ethanol-fed rats after 5 to 6 weeks of alcohol consumption. Mitochondria isolated from ethanol-treated rats showed a significant decrease in state 3 respiration and respiratory control ratio that was accompanied by an increased sensitivity to NO-dependent inhibition of respiration. In conclusion, we show that chronic alcohol consumption leads to increased sensitivity to the inhibition of respiration by NO. We propose that this results in a greater vulnerability to hypoxia and the development of alcohol-induced hepatotoxicity. [source] Forced cytochrome B gene mutation expression induces mitochondrial proliferation and prevents apoptosis in human uroepithelial SV-HUC-1 cells,,INTERNATIONAL JOURNAL OF CANCER, Issue 12 2009Santanu Dasgupta Abstract Mitochondria encoded Cytochrome B (CYTB) gene mutations were reported in tumors of different anatomic origin but the functional significance of these mutations are not well studied. Earlier, we found a 7-amino acid deletion mutation in the CYTB gene in a primary bladder cancer patient. In the present study, we overexpressed this 7-amino acid deletion mutation of CYTB gene in SV-40 transformed human uroepithelial HUC-1 cells. The nuclear transcribed mitochondrial CYTB (mtCYTB) was targeted into the mitochondria and generated increased copies of mitochondria and mitochondrial COX-I protein in the transfected HUC-1 cells. The proapoptotic protein Bax largely remained confined to the cytoplasm of the mtCYTB transfected HUC-1 cells without release of Cytochrome C. The downstream apoptotic proteins PARP also remained uncleaved along with increased Lamin B1 in the mtCYTB transfected cells. Our results demonstrate that forced overexpression of mtCYTB in transformed human uroepithelial HUC-1 cells triggered mitochondrial proliferation and induction of an antiapoptotic signaling cascade favoring sustained cellular growth. Coding mitochondrial DNA mutations appear to have significant functional contribution in tumor progression. Published 2009 UICC. [source] Improving cellular function through modulation of energy metabolismINTERNATIONAL JOURNAL OF COSMETIC SCIENCE, Issue 5 2004D. Maes The ambivalent consequences of mitochondrial stimulation on cellular activity have been well established. Mitochondria supply the cell with energy through a process of oxidative phosphorylation but thereby generate free radicals, resulting in the accumulation of hydrogen peroxide in the cytoplasm. We have investigated the impact of cellular senescence as well as UV irradiation, on the balance between these two activities. The adenosine triphosphate (ATP) level, DNA and protein synthesis in fibroblasts obtained from donors between 30 and 90 years of age appeared to be significantly influenced by the aging process. Both DNA and protein synthesis could be stimulated by increasing intracellular ATP levels. In-vitro senescent fibroblasts showed a reduction in the level of ATP as well as a shift in mitochondrial membrane potential. At the same time, there was an increase in intracellular hydrogen peroxide with increasing population doubling, indicating a clear dysfunction of the metabolic machinery in the mitochondria of senescent cells. To counteract this degradation of the energy pool, we treated cells with creatine, which is known to restore the pool of phosphocreatine in the mitochondria. Creatine treatment significantly increased cell survival after UV exposure, stimulated the repair of UVB-induced DNA damage in keratinocytes and caused a significant reduction in the number of sunburn cells in a UVB-exposed reconstituted skin model. These results clearly indicate that restoration of the energy pool in mitochondria increased cellular self-defense mechanism. These data show the important role played by the mitochondrial energy metabolism on the aging process, and indicate a possible therapy that can be used to counteract this negative effect. Treatment with creatine seems to provide the necessary boost to the cellular metabolism, which leads to an induction of a significant amount of protection and repair to human skin cells. [source] Protein Import Into MitochondriaIUBMB LIFE, Issue 3-5 2001Stefan A. Paschen Abstract Most mitochondrial proteins are encoded by the nuclear genome and thus have to be imported into mitochondria from the cytosol. Protein translocation across and into the mitochondrial membranes is a multistep process facilitated by the coordinated action of at least four specialized translocation systems in the outer and inner membranes of mitochondria. The outer membrane contains one general translocase, the TOM complex, whereas three distinct translocases are located in the inner membrane, which facilitates translocation of different classes of preproteins. The TIM23 complex mediates import of matrix-targeted preproteins with N -terminal presequences, whereas hydrophobic preproteins with internal targeting signals are inserted into the inner membrane via the TIM22 complex. The OXA translocase mediates the insertion of preproteins from the matrix space into the inner membrane. This review focuses on the structural organization and function of the import machinery of the model organisms of Saccharomyces cerevisiae and Neurospora crassa . In addition, the molecular basis of a new human mitochondrial disorder is discussed, the Mohr-Tranebjaerg syndrome. This is the first known disease, which is caused by an impaired mitochondrial protein import machinery leading to progressive neurodegeneration. [source] Nitric Oxide, Mitochondria, and Cell DeathIUBMB LIFE, Issue 3-5 2001Guy C. Brown Abstract NO or its derivatives (reactive nitrogen species: RNS) have three types of actions on mitochondria: 1) reversible inhibition of mitochondrial respiration at cytochrome oxidase by NO, and irreversible inhibition at multiple sites by RNS; 2) stimulation of mitochondrial production of superoxide, hydrogen peroxide, and peroxynitrite by NO; and 3) induction of mitochondrial permeability transition (MPT) by RNS. Similarly there are three main roles of mitochondria in NO-induced cell death: a) NO inhibition of respiration can induce necrosis (or excitotoxicity in neurons) and inhibit apoptosis if glycolysis is insufficient to compensate, b) RNS- or oxidant-induced signal transduction or DNA damage may activate the mitochondrial pathway to apoptosis, and c) RNS-induced MPT may induce apoptosis or necrosis. [source] Uptake of Calcium by Mitochondria: Transport and Possible FunctionIUBMB LIFE, Issue 3-5 2001Thomas E. Gunter Abstract Vertebrate mitochondria contain a complex system for transport of Ca 2+ and related ions, consisting of two saturable modes of Ca 2+ influx and two separate, saturable mechanisms of Ca 2+ efflux. The characteristics of the mechanisms of Ca 2+ uptake, the uniporter and the RaM, are discussed here and suggestions are made about how the mechanisms may work together and separately to mediate the two physiological roles with which they are most commonly associated - control of the rate of cellular ATP production and induction of the permeability transition and apoptosis. It is argued that more subtlety of control of intramitochondrial free Ca 2+ concentration ([Ca 2+ ] m ) must be used by the uniporter and the RaM to fulfill their physiological roles than has been commonly recognized. This is because an increase in [Ca 2+ ] m is associated with both increased production of ATP which supports the continued life of the cell and with induction of the permeability transition and possibly apoptosis, which leads to cell death. The saturable mechanisms of mitochondrial Ca 2+ efflux and the Ca 2+ -induced mitochondrial permeability transition, which can transport Ca 2+ as well as other ions and molecules and is often considered as a Ca 2+ transport mechanism, are being reviewed separately. [source] Release of Ca 2+ from Mitochondria via the Saturable Mechanisms and the Permeability TransitionIUBMB LIFE, Issue 3-5 2001Douglas R. Pfeiffer Abstract The literature, reviewed in the previous article, supports three physiological roles for sequestration of calcium by mitochondria: 1) control of the rate of ATP production, 2) activation of the Ca 2+ -induced mitochondrial permeability transition (PT), and 3) modulation of cytosolic Ca 2+ transients. Removal of Ca 2+ from mitochondria permits rapid and efficient changes in the rate of ATP production to adapt to changing demands and can reverse the process of PT induction. Two separate, saturable mechanisms for facilitating Ca 2+ efflux from mitochondria exist. In addition, the permeability transition or PT, which may also remove Ca 2+ from the mitochondrial matrix, is intimately involved in other important functions such as apoptosis. Here we briefly review what is known about these important mitochondrial mechanisms and from their behavior speculate on their possible and probable functions. [source] Translocation of Proteins into MitochondriaIUBMB LIFE, Issue 6 2001Nicholas J. Hoogenraad Abstract The translocase of the outer mitochondrial membrane (TOM) is composed of receptors, a channel protein, and its modulators that function together to import proteins into mitochondria. Although the import pathway of proteins directed to the mitochondrial matrix has been well characterized, recent studies into the import pathway taken by proteins into the other submitochondrial compartments have broadened our understanding into the way the TOM machinery recognizes, interacts, and translocates proteins. [source] Mitochondrial Production of Hydrogen Peroxide Regulation by Nitric Oxide and the Role of UbisemiquinoneIUBMB LIFE, Issue 4-5 2000Alberto Boveris Abstract Mitochondria are considered the major cellular site for hydrogen peroxide production, a process that is kinetically controlled by the availability of oxygen and nitric oxide to cytochrome oxidase and of ADP to F1-ATPase. The multisite regulation of mi1 tochondrial respiration and energy-transducing pathways support a critical regulatory role of mitochondrion in cell signaling pathways. The cellular steady-state levels of hydrogen peroxide and the role of mitochondria in maintaining these levels are reviewed. [source] Mitochondrial Oxidative Stress Plays a Key Role in Aging and ApoptosisIUBMB LIFE, Issue 5 2000Juan Sastre Abstract Harman first suggested in 1972 that mitochondria might be the biological clock in aging, noting that the rate of oxygen consumption should determine the rate of accumulation of mitochondrial damage produced by free radical reactions. Later in 1980 Miquel and coworkers proposed the mitochondrial theory of cell aging. Mitochondria from postmitotic cells use O2 at a high rate, hence releasing oxygen radicals that exceed the cellular antioxidant defences. The key role of mitochondria in cell aging has been outlined by the degeneration induced in cells microinjected with mitochondria isolated from fibroblasts of old rats, especially by the inverse relationship reported between the rate of mitochondrial production of hydroperoxide and the maximum life span of species. An important change in mitochondrial lipid composition is the age-related decrease found in cardiolipin content. The concurrent enhancement of lipid peroxidation and oxidative modification of proteins in mitochondria further increases mutations and oxidative damage to mitochondrial DNA (mtDNA) in the aging process. The respiratory enzymes containing the defective mtDNA-encoded protein subunits may increase the production of reactive oxygen species, which in turn would aggravate the oxidative damage to mitochondria. Moreover, superoxide radicals produced during mitochondrial respiration react with nitric oxide inside mitochondria to yield damaging peroxynitrite. Treatment with certain antioxidants, such as sulphur-containing antioxidants, vitamins C and E, or the Ginkgo biloba extract EGb 761, protects against the ageassociated oxidative damage to mtDNA and the oxidation of mitochondrial glutathione. Moreover, the EGb 761 extract also prevents changes in mitochondrial morphology and function associated with aging of the brain and liver. [source] Characterization of Sustained Atrial Tachycardia in Dogs with Rapid Ventricular Pacing-Induced Heart FailureJOURNAL OF CARDIOVASCULAR ELECTROPHYSIOLOGY, Issue 5 2003Bruce S. Stambler M.D. Introduction: Atrial arrhythmias often complicate congestive heart failure (CHF). We characterized inducible atrial tachyarrhythmias and electrophysiologic alterations in dogs with CHF and atrial enlargement produced by rapid ventricular pacing. Methods and Results: Endocardial pacing leads were implanted in the right ventricle, right atrium, and coronary sinus in 18 dogs. The right ventricular lead was connected to an implanted pacemaker capable of rapid ventricular pacing. The atrial leads were used to perform electrophysiologic studies in conscious animals at baseline in all dogs, during CHF induced by rapid ventricular pacing at 235 beats/min in 15 dogs, and during recovery from CHF in 6 dogs. After20 ± 7 daysof rapid ventricular pacing, inducibility of sustained atrial tachycardia (cycle length120 ± 12 msec) was enhanced in dogs with CHF. Atrial tachycardia required a critical decrease in atrial burst pacing cycle length (,130 msec) for induction and often could be terminated by overdrive pacing. Calcium antagonists (verapamil, flunarizine, ryanodine) terminated atrial tachycardia and suppressed inducibility. Effective refractory periods at 400- and 300-msec cycle lengths in the right atrium and coronary sinus were prolonged in dogs with CHF. Atrial cells from dogs with CHF had prolonged action potential durations and reduced resting potentials and delayed afterdepolarizations (DADs). Mitochondria from atrial tissue from dogs with CHF were enlarged and had internal cristae disorganization. Conclusions: CHF promotes inducibility of sustained atrial tachycardia. Based on the mode of tachycardia induction, responses to pacing and calcium antagonists, and presence of DADs, atrial tachycardia in this CHF model has a mechanism most consistent with DAD-induced triggered activity resulting from intracellular calcium overload.(J Cardiovasc Electrophysiol, Vol. 14, pp. 499-507, May 2003) [source] Mitochondria and Ca2+ signalingJOURNAL OF CELLULAR AND MOLECULAR MEDICINE, Issue 3 2000Emil C. Toescu Abstract Mitochondria play a central role in cell homeostasis. Amongst others, one of the important functions of mitochondria is to integrate its metabolic response with one of the major signaling pathways - the Ca2+ signaling. Mitochondria are capable to sense the levels of cytosolic Ca2+ and generate mitochondrial Ca2+ responses. Specific mechanisms for both Ca2+ uptake and Ca2+ release exist in the mitochondrial membranes. In turn, the mitochondrial Ca2+ signals are able to produce changes in the mitochondrial function and metabolism, which provide the required level of functional integration. This essay reviews briefly the current available information regarding the mitochondrial Ca2+ transport systems and some of the functional consequences of mitochondrial Ca2+ uptake [source] Mitochondria, the killer organelles and their weaponsJOURNAL OF CELLULAR PHYSIOLOGY, Issue 2 2002Luigi Ravagnan Apoptosis is a cell-autonomous mode of death that is activated to eradicate superfluous, damaged, mutated, or aged cells. In addition to their role as the cell's powerhouse, mitochondria play a central role in the control of apoptosis. Thus, numerous pro-apoptotic molecules act on mitochondria and provoke the permeabilization of mitochondrial membranes. Soluble proteins contained in the mitochondrial intermembrane space are released through the outer membrane and participate in the organized destruction of the cell. Several among these lethal proteins can activate caspases, a class of cysteine proteases specifically activated in apoptosis, whereas others act in a caspase-independent fashion, by acting as nucleases (e.g., endonuclease G), nuclease activators (e.g., apoptosis-inducing factor), or serine proteases (e.g., Omi/HtrA2). In addition, mitochondria can generate reactive oxygen species, following uncoupling and/or inhibition of the respiratory chain. The diversity of mitochondrial factors participating in apoptosis emphasizes the central role of these organelles in apoptosis control and unravels novel mechanisms of cell death execution. © 2002 Wiley-Liss, Inc. [source] Special Issue: Mitochondria and Aging , Facts and FanciesAGING CELL, Issue 1 2004David Nicholls No abstract is available for this article. [source] Mitochondria and aging: a role for the permeability transition?AGING CELL, Issue 1 2004M. Crompton Summary When mitochondria are subjected to oxidative stress and relatively high [Ca2+], they undergo a ,permeability transition' in which the inner membrane becomes freely permeable to low-molecular-weight solutes. This phenomenon reflects reversible deformation of the adenine nucleotide translocase, the loss of its native gating properties and the stabilization of the deformed state by cyclophilin-D. The permeability transition may be a factor in cell dysfunction associated with aging. This can manifest in a number of ways ranging, in the most severe, from impaired energy transduction and compromised viability to more subtle influences on the propagation of Ca2+ signals. This article critically examines data relevant to this issue. [source] Ultrastructural pathology of Baltic salmon, Salmo salar L., yolk sac fry with the M74 syndromeJOURNAL OF FISH DISEASES, Issue 3 2002J Lundström The ultrastructural pathology in liver, brain, skeletal and cardiac muscle of Baltic salmon yolk sac fry with the M74 syndrome is described. In the clinical stage of disease, the main pathological findings in the liver were a depletion of glycogen, condensation of nuclear chromatin, hydropic degeneration of mitochondria and a dilation of the bile canaliculi. In the terminal stage, additional findings were lipid accumulation and myelin whorls in the cytoplasm. The rough endoplasmic reticulum (RER) was degranulated and vesiculated and in some individuals, it formed concentric membranous whorls. Mitochondria showed several additional lesions, such as matrix densities, pleomorphism and cristae abnormalities. Skeletal myocytes were degenerated, and intracellular lipid accumulation was seen in the myocardium. In the brain, an increased frequency of cells exhibiting pyknosis or karryorhexis was recorded. The cytoplasm of these cells formed an amorphous mass of moderate density. The evaluation of brain and skeletal muscle was complicated by sporadic occurrence of pathological findings in the reference material, i.e. clinically healthy Baltic salmon yolk sac fry. As these yolk sac fry are suspected to have a subclinical thiamine deficiency, reference material in future studies should include salmon yolk sac fry from Atlantic populations or originating from reared broodstock. [source] Degeneration of Nuclei and Mitochondria in Human HairsJOURNAL OF FORENSIC SCIENCES, Issue 2 2009Charles A. Linch B.S. Abstract:, It is generally accepted that nuclei degrade in developing hair shafts but the point at which such occurs has not been investigated. The fate of mitochondria in the keratinizing hair shaft has been less clear. This study uses transmission electron microscopy to investigate when nuclei and mitochondria are no longer visible in the developing hair shaft. Serial sections were obtained from anagen head hairs absent follicles in order to determine the sequence of degradation of nuclei and mitochondria in the hair shaft by starting at the root bulb and proceeding toward the hair tip. It was demonstrated that nuclei and mitochondria become invisible in the keratinizing hair shaft at about the same time. This was found to occur fairly early in the process at the level of the hair shaft where the hair cuticle becomes permanent. [source] Mitochondrial dysfunction, oxidative stress, regulation of exocytosis and their relevance to neurodegenerative diseasesJOURNAL OF NEUROCHEMISTRY, Issue 2 2008Damien J. Keating Abstract A common feature in the early stages of many neurodegenerative diseases lies in mitochondrial dysfunction, oxidative stress, and reduced levels of synaptic transmission. Many genes associated with neurodegenerative diseases are now known to regulate either mitochondrial function, redox state, or the exocytosis of neurotransmitters. Mitochondria are the primary source of reactive oxygen species and ATP and control apoptosis. Mitochondria are concentrated in synapses and significant alterations to synaptic mitochondrial localization, number, morphology, or function can be detrimental to synaptic transmission. Mitochondrial by-products are capable of regulating various steps of neurotransmission and mitochondrial dysfunction and oxidative stress occur in the early stages of many neurodegenerative diseases. This mini-review will highlight the prospect that mitochondria regulates synaptic exocytosis by controlling synaptic ATP and reactive oxygen species levels and that dysfunctional exocytosis caused by mitochondrial abnormalities may be a common underlying phenomenon in the initial stages of some human neurodegenerative diseases. 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