Resistance of mitochondrial DNA-depleted cells against cell death: role of mitochondrial superoxide dismutase

We have shown that mitochondrial DNA-depleted (rho(0)) SK-Hep1 hepatoma cells are resistant to apoptosis, contrary to previous papers reporting normal apoptotic susceptibility of rho(0) cells. We studied the changes of gene expression in SK-Hep1 rho(0) cells. DNA chip analysis showed that MnSOD expression was profoundly increased in rho(0) cells. O(2)(.) contents increased during rho(0) cell derivation but became normalized after establishment of rho(0) phenotypes, suggesting that MnSOD induction is an adaptive process to increased O(2)(.). rho(0) cells were resistant to menadione, paraquat, or doxorubicin, and O(2)(.) contents after treatment with them were lower in rho(0) cells compared with parental cells because of MnSOD overexpression. Expression levels and activity of glutathione peroxidases were also increased in rho(0) cells, rendering them resistant to exogenous H(2)O(2). rho(0) cells were resistant to p53, and intracellular ROS contents after p53 expression were lower compared with parental cells. Other types of rho(0) cells also showed increased MnSOD expression and resistance against ROS. Heme oxygenase-1 expression was increased in rho(0) cells, and a heme oxygenase-1 inhibitor decreased the induction of MnSOD in rho(0) cells and their resistance against ROS donors. These results indicate that rho(0) cells are resistant to cell death contrary to previous reports and suggest that an adaptive increase in the expression of antioxidant enzymes renders cancer cells or aged cells with frequent mitochondrial DNA mutations to resist against oxidative stress, host anti-cancer surveillance, or chemotherapeutic agents, conferring survival advantage on them.     

Apoptotic cell death induced by hydrogen peroxide in NT2 parental and mitochondrial DNA depleted cells

Oxidative stress has been implicated in several pathologies associated with degenerative processes. Mitochondria are involved in cell death by necrosis or apoptosis due to a large load of Ca2+, the formation of reactive oxygen species (ROS), mitochondrial depolarization and the release of cytochrome c that initiates the caspase cascade. Nevertheless, the role of mitochondria in cell death processes induced by hydrogen peroxide (H2O2) has not been fully established. In this study, we analyzed the cytotoxic effect of H2O2 on rho+ human teratocarcinoma (NT2) cells and on mitochondria-DNA depleted rho0 NT2 cells, lacking functional mitochondria. The cells were exposed to H2O2 for 24 h and cell viability was dose-dependently decreased in both cell lines upon H2O2 exposure, although cell susceptibility was higher in rho0 NT2 cells. Moreover a decrease in mitochondrial membrane potential (Deltapsi(m)), mitochondrial cytochrome c release, caspases activation and DNA fragmentation were largely induced by H2O2 and occurred in both cell lines. Nevertheless, increased cell toxicity in rho0 cells upon H2O2 exposure was accompanied by a higher activation of the effector caspases-3 and -6. The data support that, in general, no differences were observed in cells containing functional (rho+) or non-functional (rho0) mitochondria upon H2O2-induced apoptotic cell death.     

Reactive oxygen species generated at mitochondrial complex III stabilize hypoxia-inducible factor-1alpha during hypoxia: a mechanism of O2 sensing

During hypoxia, hypoxia-inducible factor-1alpha (HIF-1alpha) is required for induction of a variety of genes including erythropoietin and vascular endothelial growth factor. Hypoxia increases mitochondrial reactive oxygen species (ROS) generation at Complex III, which causes accumulation of HIF-1alpha protein responsible for initiating expression of a luciferase reporter construct under the control of a hypoxic response element. This response is lost in cells depleted of mitochondrial DNA (rho(0) cells). Overexpression of catalase abolishes hypoxic response element-luciferase expression during hypoxia. Exogenous H(2)O(2) stabilizes HIF-1alpha protein during normoxia and activates luciferase expression in wild-type and rho(0) cells. Isolated mitochondria increase ROS generation during hypoxia, as does the bacterium Paracoccus denitrificans. These findings reveal that mitochondria-derived ROS are both required and sufficient to initiate HIF-1alpha stabilization during hypoxia.     

Impaired mitochondrial function protects against free radical-mediated cell death

Free radical damage can have fatal consequences. Mitochondria carry out essential cellular functions and produce high levels of reactive oxygen species (ROS). Many agents also generate ROS. Using the yeast Saccharomyces cerevisiae as a eukaryotic model, the role of functional mitochondria in surviving free radical damage was investigated. Respiratory-deficient cells lacking mitochondrial DNA (rho(0)) were up to 100-fold more resistant than isogenic rho(+) cells to killing by ROS generated by the bleomycin-phleomycin family of oxidative agents. Up to approximately 90% of the survivors of high oxidative stress lost mitochondrial function and became "petites." The selective advantage of respiratory deficiency was studied in several strains, including DNA repair-deficient rad52/rad52 and blm5/blm5 diploid strains. These mutant strains are hypersensitive to lethal effects of free radicals and accumulate more DNA damage than related wild-type strains. Losses in mitochondrial function were dose-dependent, and mutational alteration of the RAD52 or BLM5 gene did not affect the resistance of surviving cells lacking mitochondrial function. The results indicate that inactivation of mitochondrial function protects cells against lethal effects of oxygen free radicals.     

Induction of HIF-2alpha is dependent on mitochondrial O2 consumption in an O2-sensitive adrenomedullary chromaffin cell line

During low O2 (hypoxia), hypoxia-inducible factor (HIF)-alpha is stabilized and translocates to the nucleus, where it regulates genes critical for survival and/or adaptation in low O2. While it appears that mitochondria play a critical role in HIF induction, controversy surrounds the underlying mechanism(s). To address this, we monitored HIF-2alpha expression and oxygen consumption in an O2-sensitive immortalized rat adrenomedullary chromaffin (MAH) cell line. Hypoxia (2-8% O2) caused a concentration- and time-dependent increase in HIF-2alpha induction, which was blocked in MAH cells with either RNA interference knockdown of the Rieske Fe-S protein, a component of complex III, or knockdown of cytochrome-c oxidase subunit of complex IV, or defective mitochondrial DNA (rho0 cells). Additionally, pharmacological inhibitors of mitochondrial complexes I, III, IV, i.e., rotenone (1 microM), myxothiazol (1 microM), antimycin A (1 microg/ml), and cyanide (1 mM), blocked HIF-2alpha induction in control MAH cells. Interestingly, the inhibitory effects of the mitochondrial inhibitors were dependent on O2 concentration such that at moderate-to-severe hypoxia (6% O2), HIF-2alpha induction was blocked by low inhibitor concentrations that were ineffective at more severe hypoxia (2% O2). Manipulation of the levels of reactive oxygen species (ROS) had no effect on HIF-2alpha induction. These data suggest that in this O2-sensitive cell line, mitochondrial O2 consumption, rather than changes in ROS, regulates HIF-2alpha during hypoxia.     

Nuclear origin of specific yeast mitochondrial aminoacyl-tRNA synthetases.

Hydroxylapatite chromatographies of mitochondrial and total enzymes from a rho+ yeast, or from the related rho degrees mitochondrial DNA-less mutant, show the occurrence in the mitochondrial enzyme of one Phe-, one Met-, one Leu-tRNA synthetase peak which elutes distinctly from the cytoplasmic counterpart and charges well mitochondrial tRNA, whereas the cytoplasmic enzyme does not. The measurement of the mitochondrial synthetases activities in various enzymatic extracts shows that they are not repressed in rho+ cells grown on 10% glucose and that they are concentrated in the mitochondria (Phe- and Met- tRNA synthetases) but are also present outside the mitochondria. It is concluded that yeast mitochondrial protein biosynthesis involves the nuclear coded mitochondrial specific Phe-, Met- and Leu-tRNA synthetases and that the entrance of the synthetases into the mitochondria needs no factor depending on the mitochondrial DNA.     

Proteome and cytoskeleton responses in osteosarcoma cells with reduced OXPHOS activity

We have recently shown disorganization of the vimentin network in cultured cells deficient in oxidative phosphorylation (OXPHOS). We describe here the cellular responses to OXPHOS deficiency in osteosarcoma cells upon complex I (CI) and complex IV (CIV) inhibition, and upon the lack of mitochondrial DNA (rho0 cells). We examined the cytoskeletal organization and the distribution of mitochondria and analysed total proteome by 2-DE and vimentin expression by ELISA. Upon CIV inhibition and in rho0 cells, the vimentin network had collapsed around the nucleus and formed thick bundles. The mitochondria formed a perinuclear crescent upon CIV inhibition, whereas they accumulated around the nucleus in the rho0 cells, where the amount of vimentin was increased. Analysis of the total proteome revealed that a lack of mitochondrial DNA or inhibition of CI or CIV led to changes in the expression of cytoskeletal and cytoskeleton-associated proteins and proteins involved in apoptosis, OXPHOS, glycolysis, the tricarboxylic acid cycle, and oxidative stress responses. Our findings suggest that a deficiency in the energy converting system and oxidative stress can lead to cytoskeletal changes.     

Antioxidant defences and homeostasis of reactive oxygen species in different human mitochondrial DNA-depleted cell lines.

Three pairs of parental (rho+) and established mitochondrial DNA depleted (rho0) cells, derived from bone, lung and muscle were used to verify the influence of the nuclear background and the lack of efficient mitochondrial respiratory chain on antioxidant defences and homeostasis of intracellular reactive oxygen species (ROS). Mitochondrial DNA depletion significantly lowered glutathione reductase activity, glutathione (GSH) content, and consistently altered the GSH2 : oxidized glutathione ratio in all of the rho0 cell lines, albeit to differing extents, indicating the most oxidized redox state in bone rho0 cells. Activity, as well as gene expression and protein content, of superoxide dismutase showed a decrease in bone and muscle rho0 cell lines but not in lung rho0 cells. GSH peroxidase activity was four times higher in all three rho0 cell lines in comparison to the parental rho+, suggesting that this may be a necessary adaptation for survival without a functional respiratory chain. Taken together, these data suggest that the lack of respiratory chain prompts the cells to reduce their need for antioxidant defences in a tissue-specific manner, exposing them to a major risk of oxidative injury. In fact bone-derived rho0 cells displayed the highest steady-state level of intracellular ROS (measured directly by 2',7'-dichlorofluorescin, or indirectly by aconitase activity) compared to all the other rho+ and rho0 cells, both in the presence or absence of glucose. Analysis of mitochondrial and cytosolic/iron regulatory protein-1 aconitase indicated that most ROS of bone rho0 cells originate from sources other than mitochondria.     

Metabolic capacity regulates iron homeostasis in endothelial cells

The sensitivity of endothelial cells to oxidative stress and the high concentrations of iron in mitochondria led us to test the hypotheses that (1) changes in respiratory capacity alter iron homeostasis, and (2) lack of aerobic metabolism decreases labile iron stores and attenuates oxidative stress. Two respiration-deficient (rho(o)) endothelial cell lines with selective deletion of mitochondrial DNA (mtDNA) were created by exposing a parent endothelial cell line (EA) to ethidium bromide. Surviving cells were cloned and mtDNA-deficient cell lines were demonstrated to have diminished oxygen consumption. Total cellular and mitochondrial iron levels were measured, and iron uptake and compartmentalization were measured by inductively coupled plasma atomic emission spectroscopy. Iron transport and storage protein expression were analyzed by real-time polymerase chain reaction and Western blot or ELISA, and total and mitochondrial reactive oxygen species (ROS) generation was measured. Mitochondrial iron content was the same in all three cell lines, but both rho(o) lines had lower iron uptake and total cellular iron. Protein and mRNA expressions of major cytosolic iron transport constituents were down-regulated in rho(o) cells, including transferrin receptor, divalent metal transporter-1 (-IRE isoform), and ferritin. The mitochondrial iron-handling protein, frataxin, was also decreased in respiration-deficient cells. The rho(o) cell lines generated less mitochondrial ROS but released more extracellular H(2)O(2), and demonstrated significantly lower levels of lipid aldehyde formation than control cells. In summary, rho(o) cells with a minimal aerobic capacity had decreased iron uptake and storage. This work demonstrates that mitochondria regulate iron homeostasis in endothelial cells.     

Hypoxic but not anoxic stabilization of HIF-1alpha requires mitochondrial reactive oxygen species

The molecular mechanisms by which cells detect hypoxia (1.5% O2), resulting in the stabilization of hypoxia-inducible factor 1alpha (HIF-1alpha) protein remain unclear. One model proposes that mitochondrial generation of reactive oxygen species is required to stabilize HIF-1alpha protein. Primary evidence for this model comes from the observation that cells treated with complex I inhibitors, such as rotenone, or cells that lack mitochondrial DNA (rho(0)-cells) fail to generate reactive oxygen species or stabilize HIF-1alpha protein in response to hypoxia. In the present study, we investigated the role of mitochondria in regulating HIF-1alpha protein stabilization under anoxia (0% O2). Wild-type A549 and HT1080 cells stabilized HIF-1alpha protein in response to hypoxia and anoxia. The rho(0)-A549 cells and rho(0)-HT1080 cells failed to accumulate HIF-1alpha protein in response to hypoxia. However, both rho(0)-A549 and rho(0)-HT1080 were able to stabilize HIF-1alpha protein levels in response to anoxia. Rotenone inhibited hypoxic, but not anoxic, stabilization of HIF-1alpha protein. These results indicate that a functional electron transport chain is required for hypoxic but not anoxic stabilization of HIF-1alpha protein.     

HSP70 and other possible heat shock or oxidative stress proteins are induced in skeletal muscle, heart, and liver during exercise

Exercise causes heat shock (muscle temperatures of up to 45 degrees C, core temperatures of up to 44 degrees C) and oxidative stress (generation of O2- and H2O2), and exercise training promotes mitochondrial biogenesis (2-3-fold increases in muscle mitochondria). The concentrations of at least 15 possible heat shock or oxidative stress proteins (including one with a molecular weight of 70 kDa) were increased, in skeletal muscle, heart, and liver, by exercise. Soleus, plantaris, and extensor digitorum longus (EDL) muscles exhibited differential protein synthetic responses ([3H]leucine incorporation) to heat shock and oxidative stress in vitro but five proteins (particularly a 70 kDa protein and a 106 kDa protein) were common to both stresses. HSP70 mRNA levels were next analyzed by Northern transfer, using a [32P]-labeled HSP70 cDNA probe. HSP70 mRNA levels were increased, in skeletal and cardiac muscle, by exercise and by both heat shock and oxidative stress. Skeletal muscle HSP70 mRNA levels peaked 30-60 min following exercise, and appeared to decline slowly towards control levels by 6 h postexercise. Two distinct HSP70 mRNA species were observed in cardiac muscle; a 2.3 kb mRNA which returned to control levels within 2-3 h postexercise, and a 3.5 kb mRNA species which remained at elevated concentrations for some 6 h postexercise. The induction of HSP70 appears to be a physiological response to the heat shock and oxidative stress of exercise. Exercise hyperthermia may actually cause oxidative stress since we also found that muscle mitochondria undergo progressive uncoupling and increased O2- generation with increasing temperatures.(ABSTRACT TRUNCATED AT 250 WORDS)     

The efficiency of functional mitochondrial replacement in Saccharomyces species has directional character

Optimal interactions among nuclear and mitochondria-coded proteins are required to assemble functional complexes of mitochondrial oxidative phosphorylation. The communication between the nuclear and mitochondrial genomes has been studied by transplacement of mitochondria from related species into mutants devoid of mitochondrial DNA (rho0). Recently we have reported that the mitochondria transferred from Saccharomyces paradoxus restored partially the respiration in Saccharomyces cerevisiae rho0 mutants. Here we present evidence that the S. cerevisiae mitochondria completely salvage from respiration deficiency, not only in conspecific isolates but also in S. paradoxus. The respiratory capacity in less-related species can be recovered exclusively in the presence of S. cerevisiae chromosomes. The efficiency of the re-established oxidative phosphorylation did not rely on the presence of introns in the S. cerevisiae mitochondrial DNA. Our results suggest that, apart from evolutionary distance, the direction of mitochondrial replacement could play a significant role in installing the complete (wild-type-like) interaction between mitochondria and nuclei from different species.     

Cells depleted of mitochondrial DNA (rho0) yield insight into physiological mechanisms.

A resurgence of interest in mitochondrial physiology has recently developed as a result of new experimental data demonstrating that mitochondria function as important participants in a diverse collection of novel intracellular signaling pathways. Cells depleted of mitochondrial DNA, or rho0 cells, lack critical respiratory chain catalytic subunits that are encoded in the mitochondrial genome. Although rho0 cells contain petit mitochondria, they cannot support normal oxidative phosphorylation and must survive and replicate using ATP derived solely from glycolysis. Without a functional electron transport chain, rho0 cells cannot normally regulate redox potential and their mitochondria appear to be incapable of generating reactive oxygen species. Emerging evidence suggests that these signals are important components in a number of mitochondria-initiated signaling pathways. The present article focuses on how rho0 cells have contributed to an understanding of the role that mitochondria play in distinct physiological pathways involved with apoptosis, glucose-induced insulin secretion, and oxygen sensing.     

The involvement of topoisomerases and DNA polymerase I in the mechanism of induced thermal and radiation resistance in yeast

Either an ionizing radiation exposure or a heat shock is capable of inducing both thermal tolerance and radiation resistance in yeast. Yeast mutants, deficient in topoisomerase I, in topoisomerase II, or in DNA polymerase I, were used to investigate the mechanism of these inducible resistances. The absence of either or both topoisomerase activities did not prevent induction of either heat or radiation resistance. However, if both topoisomerase I and II activities were absent, the sensitivity of yeast to become thermally tolerant (in response to a heat stress) was markedly increased. The absence of only topoisomerase I activity (top1) resulted in the constitutive expression of increased radiation resistance equivalent to that induced by a heat shock in wild-type cells, and the topoisomerase I-deficient cells were not further inducible by heat. This heat-inducible component of radiation resistance (or its equivalent constitutive expression in top1 cells) was, in turn, only a portion of the full response inducible by radiation. The absence of polymerase I activity had no detectable effect on either response. Our results indicate that the actual systems that confer resistance to heat or radiation are independent of either topoisomerase activity or DNA polymerase function, but suggest that topoisomerases may have a regulatory role during the signaling of these mechanisms. The results of our experiments imply that maintenance of correct DNA topology prevents induction of the heat-shock response, and that heat-shock induction of a component of the full radiation resistance in yeast may be the consequence of topoisomerase I inactivation.     

Mitochondrial Telomerase Protects Cancer Cells from Nuclear DNA Damage and Apoptosis

Most cancer cells express high levels of telomerase and proliferate indefinitely. In addition to its telomere maintenance function, telomerase also has a pro-survival function resulting in an increased resistance against DNA damage and decreased apoptosis induction. However, the molecular mechanisms for this protective function remain elusive and it is unclear whether it is connected to telomere maintenance or is rather a non-telomeric function of the telomerase protein, TERT. It was shown recently that the protein subunit of telomerase can shuttle from the nucleus to the mitochondria upon oxidative stress where it protects mitochondrial function and decreases intracellular oxidative stress. Here we show that endogenous telomerase (TERT protein) shuttles from the nucleus into mitochondria upon oxidative stress in cancer cells and analyzed the nuclear exclusion patterns of endogenous telomerase after treatment with hydrogen peroxide in different cell lines. Cell populations excluded TERT from the nucleus upon oxidative stress in a heterogeneous fashion. We found a significant correlation between nuclear localization of telomerase and high DNA damage, while cells which excluded telomerase from the nucleus displayed no or very low DNA damage. We modeled nuclear and mitochondrial telomerase using organelle specific localization vectors and confirmed that mitochondrial localization of telomerase protects the nucleus from inflicted DNA damage and apoptosis while, in contrast, nuclear localization of telomerase correlated with higher amounts of DNA damage and apoptosis. It is known that nuclear DNA damage can be caused by mitochondrially generated reactive oxygen species (ROS). We demonstrate here that mitochondrial localization of telomerase specifically prevents nuclear DNA damage by decreasing levels of mitochondrial ROS. We suggest that this decrease of oxidative stress might be a possible cause for high stress resistance of cancer cells and could be especially important for cancer stem cells.     

Mitochondrial dynamics in yeast cell death and aging

Mitochondria play crucial roles in programmed cell death and aging. Different stimuli activate distinct mitochondrion-dependent cell death pathways, and aging is associated with a progressive increase in mitochondrial damage, culminating in oxidative stress and cellular dysfunction. Mitochondria are highly dynamic organelles that constantly fuse and divide, forming either interconnected mitochondrial networks or separated fragmented mitochondria. These processes are believed to provide a mitochondrial quality control system and enable an effective adaptation of the mitochondrial compartment to the metabolic needs of the cell. The baker's yeast, Saccharomyces cerevisiae, is an established model for programmed cell death and aging research. The present review summarizes how mitochondrial morphology is altered on induction of cell death or on aging and how this correlates with the induction of different cell death pathways in yeast. We highlight the roles of the components of the mitochondrial fusion and fission machinery that affect and regulate cell death and aging.     

Is DNA damage the signal for induction of thermal resistance? induction by radiation in yeast

Yeast, as well as higher eukaryotes, are induced to increase thermal resistance (thermotolerance) by prior exposure to a heat stress. Prior exposure to an acute dose of either 60Co gamma or 254-nm ultraviolet radiation, at sublethal or fractionally lethal doses, is shown to cause a marked increase in the resistance of Saccharomyces cerevisiae to killing by heat. Following a radiation exposure, thermal resistance increased with time during incubation in nutrient medium, and the degree of resistance reached was proportional to the dose received. Partial induction by radiation followed by maximum induction by heat did not produce an additive response when compared to a maximum induction by heat alone, suggesting that the same process was induced by both heat and radiation. Irradiation with 254-nm uv light followed by an immediate, partial photoreversal of the pyrimidine dimers with long-wavelength uv light resulted in a reduced level of resistance compared to cells not exposed to the photoreversal light, indicating that the cells specifically recognized pyrimidine dimers as a signal to increase their thermal resistance. Exposure to 254-nm uv or ionizing radiation induced thermal resistance in mutants defective in either excision repair (rad3, uv-sensitive) or recombinational repair (rad52, gamma-sensitive), suggesting that recognition and repair of DNA damage by these systems are not a part of the signal which initiates an increase in resistance to heat. The amount of induction, per unit dose, was greater in the DNA repair-deficient mutants than in the wild-type cells, suggesting that an increase in the length of time during which damage remains in the DNA results in an increase in the effectiveness of the induction. These data indicate that types of DNA damage as diverse as those produced by ionizing radiation and by ultraviolet light are recognized as a signal by the yeast cell to increase its thermal resistance. It is therefore suggested that heat-induced alterations in DNA or in DNA-dependent chromosomal organization may be the signal for heat induction of thermotolerance in this and other eukaryotes.