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Mitochondrial Compartments (mitochondrial + compartment)
Selected AbstractsAstrocyte targeted overexpression of Hsp72 or SOD2 reduces neuronal vulnerability to forebrain ischemiaGLIA, Issue 9 2010Lijun Xu Abstract Brief forebrain ischemia is a model of the delayed hippocampal neuronal loss seen in patients following cardiac arrest and resuscitation. Previous studies demonstrated that selective dysfunction of hippocampal CA1 subregion astrocytes occurs hours to days before delayed neuronal death. In this study we tested the strategy of directing protection to astrocytes to protect neighboring neurons from forebrain ischemia. Two well-studied protective proteins, heat shock protein 72 (Hsp72) or superoxide dismutase 2 (SOD2), were genetically targeted for expression in astrocytes using the astrocyte-specific human glial fibrillary acidic protein (GFAP) promoter. The expression constructs were injected stereotacticly immediately above the hippocampal CA1 region on one side of the rat brain two days prior to forebrain ischemia. Cell type specific expression was confirmed by double label immunohistochemistry. When the expression constructs were injected two days before transient forebrain ischemia, the loss of CA1 hippocampal neurons observed seven days later was significantly reduced on the injected side compared with controls. This neuroprotection was associated with significantly better preservation of astrocyte glutamate transporter-1 immunoreactivity at 5-h reperfusion and reduced oxidative stress. Improving the resistance of astrocytes to ischemic stress by targeting either the cytosolic or mitochondrial compartment was thus associated with preservation of CA1 neurons following forebrain ischemia. Targeting astrocytes is a promising strategy for neuronal preservation following cardiac arrest and resuscitation. © 2010 Wiley-Liss, Inc. [source] Cell Compartmentalization in Redox SignalingIUBMB LIFE, Issue 1 2001Giovambattista Pani Abstract From a growing body of evidence on the role of Reactive Oxygen Species as intracellular signaling molecules, the concept starts to emerge that cell responses to redox changes are function of the intracellular site where oxidants are produced and/or meet their molecular targets. In particular,a major distinction between oxidative events in the cytosolic versus the mitochondrial compartment appears to exist in terms of physiological stimuli, signaling mechanisms and functional consequences. Experimental data supporting this view are reviewed here, and the potential implications of this new perspective in redox signaling are discussed. [source] Walker tumor cells express larger amounts of the antiapoptotic protein Bcl-2 and presents higher resistance to toxic concentrations of Ca2+ than the tumor cells K 562DRUG DEVELOPMENT RESEARCH, Issue 4 2001Graziela Milani Abstract Ca2+ homeostasis was studied in two tumor cell lines (Walker 256 and K 562) previously shown to exhibit different mitochondrial Ca2+ accumulation capacity. When intact, both cells present cytosolic Ca2+ concentrations within the range expected for mammalian cells, as determined through fura-2 fluorescence ratios. In order to study intracellular Ca2+ distribution, digitonin was used to permeabilize the plasma membrane without affecting intracellular organelle structure, as assessed using electron microscopy. Digitonin-permeabilized Walker 256 cells incubated with Ca2+ presented uptake of the cation exclusively through mitochondrial activity. In addition, very large Ca2+ loads were necessary to promote a disruption of Walker 256 mitochondrial membrane potential. K 562 cells presented active Ca2+ uptake through both nonmitochondrial and mitochondrial compartments and suffered disruption of mitochondrial membrane potential at lower Ca2+ loads than Walker 256 mitochondria. The higher Ca2+ resistance in Walker 256 cells could be attributed to Bcl-2 overexpression, as evidenced by immunocytochemical staining. Thus, we correlate natural Bcl-2 overexpression, observed in Walker 256 cells, with higher resistance to mitochondrial Ca2+ overload, as was shown previously in mitochondria from cells transfected with the bcl-2 gene. Drug Dev. Res. 52:508,514, 2001. © 2001 Wiley-Liss, Inc. [source] Increased glucose metabolism and ATP level in brain tissue of Huntington's disease transgenic miceFEBS JOURNAL, Issue 19 2008Judit Oláh Huntington's disease (HD) is a progressive neurodegenerative disorder characterized by multifarious dysfunctional alterations including mitochondrial impairment. In the present study, the formation of inclusions caused by the mutation of huntingtin protein and its relationship with changes in energy metabolism and with pathological alterations were investigated both in transgenic and 3-nitropropionic acid-treated mouse models for HD. The HD and normal mice were characterized clinically; the affected brain regions were identified by immunohistochemistry and used for biochemical analysis of the ATP-producing systems in the cytosolic and the mitochondrial compartments. In both HD models, the activities of some glycolytic enzymes were somewhat higher. By contrast, the activity of glyceraldehyde-3-phosphate dehydrogenase was much lower in the affected region of the brain compared to that of the control. Paradoxically, at the system level, glucose conversion into lactate was enhanced in cytosolic extracts from the HD brain tissue, and the level of ATP was higher in the tissue itself. The paradox could be resolved by taking all the observed changes in glycolytic enzymes into account, ensuing an experiment-based detailed mathematical model of the glycolytic pathway. The mathematical modelling using the experimentally determined kinetic parameters of the individual enzymes and the well-established rate equations predicted the measured flux and concentrations in the case of the control. The same mathematical model with the experimentally determined altered Vmax values of the enzymes did account for an increase of glycolytic flux in the HD sample, although the extent of the increase was not predicted quantitatively. This suggested a somewhat altered regulation of this major metabolic pathway in HD tissue. We then used the mathematical model to develop a hypothesis for a new regulatory interaction that might account for the observed changes; in HD, glyceraldehyde-3-phosphate dehydrogenase may be in closer proximity (perhaps because of the binding of glyceraldehyde-3-phosphate dehydrogenase to huntingtin) with aldolase and engage in channelling for glyceraldehyde-3-phosphate. By contrast to most of the speculation in the literature, our results suggest that the neuronal damage in HD tissue may be associated with increased energy metabolism at the tissue level leading to modified levels of various intermediary metabolites with pathological consequences. [source] Cytochrome c oxidase biogenesis: New levels of regulationIUBMB LIFE, Issue 9 2008Flavia Fontanesi Abstract Eukaryotic cytochrome c oxidase (COX), the last enzyme of the mitochondrial respiratory chain, is a multimeric enzyme of dual genetic origin, whose assembly is a complicated and highly regulated process. COX displays a concerted accumulation of its constitutive subunits. Data obtained from studies performed with yeast mutants indicate that most catalytic core unassembled subunits are posttranslationally degraded. Recent data obtained in the yeast Saccharomycescerevisiae have revealed another contribution to the stoichiometric accumulation of subunits during COX biogenesis targeting subunit 1 or Cox1p. Cox1p is a mitochondrially encoded catalytic subunit of COX which acts as a seed around which the full complex is assembled. A regulatory mechanism exists by which Cox1p synthesis is controlled by the availability of its assembly partners. The unique properties of this regulatory mechanism offer a means to catalyze multiple-subunit assembly. New levels of COX biogenesis regulation have been recently proposed. For example, COX assembly and stability of the fully assembled enzyme depend on the presence in the mitochondrial compartments of two partners of the oxidative phosphorylation system, the mobile electron carrier cytochrome c and the mitochondrial ATPase. The different mechanisms of regulation of COX assembly are reviewed and discussed. © 2008 IUBMB IUBMB Life, 60(9): 557,568, 2008 [source] Mechanisms involved in the photosensitized inactivation of Acanthamoeba palestinensis trophozoitesJOURNAL OF APPLIED MICROBIOLOGY, Issue 5 2009S. Ferro Abstract Aims:, To advance our understanding of the mechanisms involved in the RLP068 phthalocyanine-photosensitized inactivation of Acanthamoeba palestinensis trophozoites through a precise identification of the targets of the photoprocess in both the cytosolic and mitochondrial compartments. Methods and Results:, We followed the activities of selected marker enzymes as well as we performed fluorescence and transmission electron microscopy investigations of the alterations induced by the photoprocess in the fine structure of subcellular compartments. RLP068 is preferentially located in the contractile vacuole: the fluorescence in that site is particularly evident in the unirradiated cells and becomes more diffused after irradiation. Electron microscopic analysis of photosensitized A. palestinensis cells clearly shows that the swelling of trophozoites and the appearance of vacuoles spread throughout the cytoplasm after phototreatment. The activity of a typical cytoplasmic enzyme, such as lactate dehydrogenase, underwent a 35% decrease as a consequence of the photoprocess, reflecting the photodamage induced by migrating phthalocyanine molecules in their micro-environment. Conclusions:, The presence of multiple targets for the phthalocyanine-photosensitized process is of utmost importance because this pattern of cell damage makes it unlikely that photoresistant A. palestinensis strains are gradually selected or mutagenic phenomena are developed as a consequence of the photoinduced damage. Significance and Impact of the Study:, Photosensitization via phthalocyanines appears to represent an efficient and safe approach for achieving a close control of the population of a potentially pathogenic protozoan such as A. palestinensis, opening new perspectives for the disinfection of microbiologically polluted waters. [source] The overexpression of major antioxidant enzymes does not extend the lifespan of miceAGING CELL, Issue 1 2009Viviana I. Pérez Summary We evaluated the effect of overexpressing antioxidant enzymes on the lifespans of transgenic mice that overexpress copper zinc superoxide dismutase (CuZnSOD), catalase, or combinations of either CuZnSOD and catalase or CuZnSOD and manganese superoxide dismutase (MnSOD). Our results show that the overexpression of these major antioxidant enzymes, which are known to scavenge superoxide and hydrogen peroxide in the cytosolic and mitochondrial compartments, is insufficient to extend lifespan in mice. [source] Mitochondrial formation of reactive oxygen speciesTHE JOURNAL OF PHYSIOLOGY, Issue 2 2003Julio F. Turrens The reduction of oxygen to water proceeds via one electron at a time. In the mitochondrial respiratory chain, Complex IV (cytochrome oxidase) retains all partially reduced intermediates until full reduction is achieved. Other redox centres in the electron transport chain, however, may leak electrons to oxygen, partially reducing this molecule to superoxide anion (O2,,). Even though O2,, is not a strong oxidant, it is a precursor of most other reactive oxygen species, and it also becomes involved in the propagation of oxidative chain reactions. Despite the presence of various antioxidant defences, the mitochondrion appears to be the main intracellular source of these oxidants. This review describes the main mitochondrial sources of reactive species and the antioxidant defences that evolved to prevent oxidative damage in all the mitochondrial compartments. We also discuss various physiological and pathological scenarios resulting from an increased steady state concentration of mitochondrial oxidants. [source] | ||||||||||