Mechanisms of stress resistance in Snell dwarf mouse fibroblasts: Enhanced antioxidant and DNA base excision repair capacity,but no differences in mitochondrial metabolism

Dermal fibroblasts from long-lived Snell dwarf mice can withstand a variety of oxidative and non-oxidative stressors compared to normal littermate controls. Here, we report differences in the levels and activities of intracellular antioxidant and DNA repair enzymes between normal and Snell dwarf mice fibroblasts cultured under a variety of conditions, including: 3% and 20% ambient O₂; the presence and absence of serum; and the addition of an exogenous oxidative stress. The only significant difference between normal and dwarf cells cultured in complete medium, at 20% O₂, was an approximately 40% elevation of glutathione peroxidase (GPx) activity in the mutant cells. Serum deprivation elicited increases in GPx in both genotypes, but these activities remained higher in dwarf mouse cells. Dwarf mouse cells deprived of serum and challenged with exposure to paraquat or hydrogen peroxide showed a generally greater upregulation of catalase and DNA base excision repair enzymes. As these toxins can interact with mitochondria to increase mitochondrial ROS production, we explored whether there were differences in mitochondrial metabolism between normal and dwarf mouse cells. However, neither mitochondrial content nor the apparent mitochondrial membrane potential differed between genotypes. Overall, the results suggest that superior hydrogen peroxide metabolism and a marginally greater DNA base excision repair capacity contribute to the stress resistance phenotype of Snell dwarf mouse fibroblasts.     

Cancer cells metabolically “fertilize” the tumor microenvironment with hydrogen peroxide,driving the Warburg effect: Implications for PET imaging of human tumors

Previously, we proposed that cancer cells behave as metabolic parasites, as they use targeted oxidative stress as a “weapon” to extract recycled nutrients from adjacent stromal cells. Oxidative stress in cancer-associated fibroblasts triggers autophagy and mitophagy, resulting in compartmentalized cellular catabolism, loss of mitochondrial function, and the onset of aerobic glycolysis, in the tumor stroma. As such, cancer-associated fibroblasts produce high-energy nutrients (such as lactate and ketones) that fuel mitochondrial biogenesis and oxidative metabolism in cancer cells. We have termed this new energy-transfer mechanism the “reverse Warburg effect.” To further test the validity of this hypothesis, here we used an in vitro MCF7-fibroblast co-culture system and quantitatively measured a variety of metabolic parameters by FACS analysis (analogous to laser-capture micro-dissection). Mitochondrial activity, glucose uptake and ROS production were measured with highly-sensitive fluorescent probes (MitoTracker, NBD-2-deoxy-glucose and DCF-DA). Interestingly, using this approach, we directly show that cancer cells initially secrete hydrogen peroxide that then triggers oxidative stress in neighboring fibroblasts. Thus, oxidative stress is contagious (spreads like a virus) and is propagated laterally and vectorially from cancer cells to adjacent fibroblasts. Experimentally, we show that oxidative stress in cancer-associated fibroblasts quantitatively reduces mitochondrial activity and increases glucose uptake, as the fibroblasts become more dependent on aerobic glycolysis. Conversely, co-cultured cancer cells show significant increases in mitochondrial activity and corresponding reductions in both glucose uptake and GLUT1 expression. Pre-treatment of co-cultures with extracellular catalase (an anti-oxidant enzyme that detoxifies hydrogen peroxide) blocks the onset of oxidative stress and potently induces the death of cancer cells, likely via starvation. Given that cancer-associated fibroblasts show the largest increases in glucose uptake, we suggest that PET imaging of human tumors, with Fluoro-2-deoxy-D-glucose (F-2-DG), may be specifically detecting the tumor stroma, rather than epithelial cancer cells.Key words: tumor stroma, microenvironment, hydrogen peroxide, aerobic glycolysis, mitochondrial oxidative phosphorylation, glucose uptake, oxidative stress, reactive oxygen species (ROS), cancer associated fibroblasts, PET imaging, the field effect, caveolin-1     

16S Mitochondrial Ribosomal RNA Degradation Is Associated with Apoptosis

The use of mitochondrial RNA as an indicator of apoptosis was investigated. Exposure of HA-1 fibroblastic cells to 10 H₂O₂ per 10⁷ cells induced nuclear fragmentation, cell shrinkage, and internucleosomal DNA fragmentation, all characteristics of apoptosis. RNA extracted from control and apoptotic cultures, and analyzed by Northern blot hybridization, revealed a significant increase in the degradation of mitochondrial 16S ribosomal RNA (rRNA) that was associated with apoptosis. Conversely, minimal, if any, degradation of glyceraldehyde-3-phosphate dehydrogenase or actin mRNAs was observed. Similar results were obtained for HA-1 cells treated with the protein kinase inhibitor staurosporine, and for HT-2 T-lymphocytes induced to undergo apoptosis by interleukin-2 withdrawal. In addition, 16S rRNA degradation was an early event that was discernable well before chromatin condensation in hydrogen peroxide-treated HA-1 cells. These observations suggest that degradation of mitochondrial 16S ribosomal RNA is a new marker of mammalian cell apoptosis. © 1997 Elsevier Science Inc.     

Cancer cells metabolically "fertilize" the tumor microenvironment with hydrogen peroxide,driving the Warburg effect

Previously, we proposed that cancer cells behave as metabolic parasites, as they use targeted oxidative stress as a “weapon” to extract recycled nutrients from adjacent stromal cells. Oxidative stress in cancer-associated fibroblasts triggers autophagy and mitophagy, resulting in compartmentalized cellular catabolism, loss of mitochondrial function, and the onset of aerobic glycolysis, in the tumor stroma. As such, cancer-associated fibroblasts produce high-energy nutrients (such as lactate and ketones) that fuel mitochondrial biogenesis, and oxidative metabolism in cancer cells. We have termed this new energy-transfer mechanism the “reverse Warburg effect.” To further test the validity of this hypothesis, here we used an in vitro MCF7-fibroblast co-culture system, and quantitatively measured a variety of metabolic parameters by FACS analysis (analogous to laser-capture micro-dissection). Mitochondrial activity, glucose uptake, and ROS production were measured with highly-sensitive fluorescent probes (MitoTracker, NBD-2-deoxy-glucose, and DCF-DA). Interestingly, using this approach, we directly show that cancer cells initially secrete hydrogen peroxide that then triggers oxidative stress in neighboring fibroblasts. Thus, oxidative stress is contagious (spreads like a virus) and is propagated laterally and vectorially from cancer cells to adjacent fibroblasts. Experimentally, we show that oxidative stress in cancer-associated fibroblasts quantitatively reduces mitochondrial activity, and increases glucose uptake, as the fibroblasts become more dependent on aerobic glycolysis. Conversely, co-cultured cancer cells show significant increases in mitochondrial activity, and corresponding reductions in both glucose uptake and GLUT1 expression. Pre-treatment of co-cultures with extracellular catalase (an anti-oxidant enzyme that detoxifies hydrogen peroxide) blocks the onset of oxidative stress, and potently induces the death of cancer cells, likely via starvation. Given that cancer-associated fibroblasts show the largest increases in glucose uptake, we suggest that PET imaging of human tumors, with Fluoro-2-deoxy-D-glucose (F-2-DG), may be specifically detecting the tumor stroma, rather than epithelial cancer cells.     

Heat-induced cytotoxicity in H2O2-resistant Chinese hamster fibroblasts

Hydrogen-peroxide-resistant Chinese hamster fibroblasts, derived from the HA-1 cell line, were isolated following continuous culturing in the presence of progressively increasing concentrations of hydrogen peroxide. The hydrogen-peroxide-resistant phenotype has been stable for over 360 days following removal from H2O2 stress. These H2O2-resistant cell lines demonstrate increased resistance to hyperthermic cell killing mediated by continuous heating at 43 degrees C but not 45 degrees C. The relationship between mammalian cellular adaptation to oxidative stress mediated by H2O2 and resistance to 43 degrees C hyperthermia is discussed.     

Analysis of differential DNA damage in the mitochondrial genome employing a semi-long run real-time PCR approach

The maintenance of the mitochondrial genomic integrity is a prerequisite for proper mitochondrial function. Due to the high concentration of reactive oxygen species (ROS) generated by the oxidative phosphorylation pathway, the mitochondrial genome is highly exposed to oxidative stress leading to mitochondrial DNA injury. Accordingly, mitochondrial DNA damage was shown to be associated with ageing as well as with numerous human diseases including neurodegenerative disorders and cancer. To date, several methods have been described to detect damaged mitochondrial DNA, but those techniques are semi-quantitative and often require high amounts of genomic input DNA. We developed a rapid and quantitative method to evaluate the relative levels of damage in mitochondrial DNA by using the real time-PCR amplification of mitochondrial DNA fragments of different lengths. We investigated mitochondrial DNA damage in SH-SY5Y human neuroblastoma cells exposed to hydrogen peroxide or stressed by over-expression of the tyrosinase gene. In the past, there has been speculation about a variable vulnerability to oxidative stress along the mitochondrial genome. Our results indicate the existence of at least one mitochondrial DNA hot spot, namely the D-Loop, being more prone to ROS-derived damage.     

Jak2 tyrosine kinase mediates oxidative stress-induced apoptosis in vascular smooth muscle cells

In vascular smooth muscle cells, Jak2 tyrosine kinase becomes activated in response to oxidative stress in the form of hydrogen peroxide. Although it has been postulated that hydrogen peroxide-induced Jak2 activation promotes cell survival, this has never been tested. We therefore examined the role that Jak2 plays in vascular smooth muscle cell apoptosis following hydrogen peroxide treatment. Here, we report that Jak2 tyrosine kinase activation by hydrogen peroxide is required for apoptosis of vascular smooth muscle cells. Upon treatment of primary rat aortic smooth muscle cells with hydrogen peroxide, we observed laddering of genomic DNA and nuclear condensation, both hallmarks of apoptotic cells. However, apoptosis was prevented by either the expression of a dominant negative Jak2 protein or by the Jak2 pharmacological inhibitor AG490. Moreover, expression of the proapoptotic Bax protein was induced following hydrogen peroxide treatment. Again, expression of a dominant negative Jak2 protein or treatment of cells with AG490 prevented this Bax induction. Following Bax induction by hydrogen peroxide, mitochondrial membrane integrity was compromised, and caspase-9 became activated. In contrast, in cells expressing a Jak2 dominant negative we observed that mitochondrial membrane integrity was preserved, and no caspase-9 activation occurred. These data demonstrate that the activation of Jak2 tyrosine kinase by hydrogen peroxide is essential for apoptosis of vascular smooth muscle cells. Furthermore, this report identifies Jak2 as a potential therapeutic target in vascular diseases in which vascular smooth muscle cell apoptosis contributes to pathological progression.     

Effects of ectopic expression of Drosophila DNA glycosylases dOgg1 and RpS3 in mitochondria

The main purpose of this study was to determine whether enhancement of repair capacity would attenuate mitochondrial DNA oxidative damage and result in greater cell survival under stressful conditions. The repair of oxidative damage is initiated by DNA glycosylases, which catalyze the excision of oxidized bases, such as 8-hydroxydeoxyguanosine (8-oxodG). Drosophila DNA glycosylases, dOgg1 and RpS3, were ectopically expressed within the mitochondrial matrix in Drosophila S2 cells, causing a severalfold decrease in the levels of 8-oxodG in mitochondrial DNA. Unexpectedly, cells did not show increased resistance to oxidative stress, but instead became more susceptible to treatment with hydrogen peroxide or paraquat. Even in the absence of oxidative challenge, cells expressing RpS3 or dOgg1 in mitochondria exhibited increased apoptosis relative to controls, as determined by flow-cytometric analysis of Annexin V and DNA degradation measured by the Comet assay. Another notable finding was that ectopic expression of either dOgg1 or RpS3 in mitochondria increased cell survival after exposure to the nitric oxide donor SNAP. These results suggest that ectopic expression of one of the constituents of the DNA repair system in mitochondria may cause a perturbation in the base excision repair pathway and lower, rather than enhance, survivability.     

OGG1 is degraded by calpain following oxidative stress and cisplatin exposure

Deficient repair activity for 8-hydroxy-2'-deoxyguanine (8-oxoguanine), a premutagenic oxidative DNA damage, has been observed in affected tissues in neurodegenerative diseases of aging, such as Alzheimer's disease, and in ischemia/reperfusion injury, type 2 diabetes mellitus, and cancer. These conditions have in common the accumulation of oxidative DNA damage, which is believed to play a role in disease progression, and loss of intracellular calcium regulation. These observations suggest that oxidative DNA damage repair capacity may be influenced by fluctuations in cellular calcium. We have identified human 8-oxoguanine-DNA glycosylase 1 (OGG1), the major 8-oxoguanine repair activity, as a specific target of the Ca(2+)-dependent protease Calpain I. Protein sequencing of a truncated partially calpain-digested OGG1 revealed that calpain recognizes OGG1 for degradation at a putative PEST (proline, glutamic acid, serine, threonine) sequence in the C-terminus of the enzyme. Co-immunoprecipitation experiments showed that OGG1 and Calpain I are associated in human cells. Exposure of HeLa cells to hydrogen peroxide or cisplatin resulted in the degradation of OGG1. Pretreatment of cells with the calpain inhibitor calpeptin resulted in inhibition of OGG1 proteolysis and suggests that OGG1 is a target for calpain-mediated degradation in vivo during oxidative stress- and cisplatin-induced apoptosis. Polymorphic OGG1 S326C was comparatively resistant to calpain digestion in vitro, yet was also degraded by a calpain-dependent pathway in vivo following DNA damaging agent exposure. The degradation of OGG1 by calpain may contribute to decreased 8-oxoguanine repair activity and elevated levels of 8-oxoguanine reported in tissues undergoing chronic oxidative stress, ischemia/reperfusion, and other cellular stressors known to produce perturbations of intracellular calcium homeostasis which activate calpain.     

Glucose-6-phosphate dehydrogenase deficiency: a new hypothesis for an old disease

Summary

We have previously shown insulinoma (HIT-T15 and RINm5F) cells in culture to be very sensitive, in comparison with a reference cell line (J-774), to the oxidative stress that is created when alloxan reacts extracellularly with reducing agents, forming superoxide and hydrogen peroxide. The toxic effects are prevented by catalase added to the medium, suggesting that alloxan does not need to be taken up in order to affect cells. Rather, alloxan seems to exert its action through extracellular formation of hydrogen peroxide that influences the stability of the cells' lysosomes following diffusion into them. To further analyse the mechanisms in operation, we studied the influence of induced autophagocytosis on the sensitivity to ensuing oxidative stress. Starvation for 60–120 min in PBS at 37°C markedly enhanced autophagocytosis and, in parallel, increased the cytotoxic effect and lysosomal vulnerability of ensuing exposure to hydrogen peroxide, while not significantly changing the antioxidative status or the energy balance. Autophagocytosis increased the size of the intralysosomal pool of reactive, low-molecular-weight, iron, probably by degradation of metallo-proteins, as shown by autometallography and HPLC demonstration of desferrioxamine-reactive intracellular iron. Moreover, exposure to the iron-chelator desferrioxamine before treatment with hydrogen peroxide prevented lysosomal destabilization and cellular death of both starved and control cells, further proving the importance of intralysosomal iron for the response to oxidative stress. We hypothesize that β-cells which, like insulinoma cells, have a weak antioxidative defence system under conditions of enhanced general autophagocytosis, or crinophagy, might become vulnerable to even low, or moderate, oxidative stress.     

Impact of Oestradiol and Progesterone on Antioxidant Activity in Normal Human Breast Epithelial Cells in Culture

The risk of developing breast cancer increases after long term use of oestrogen and progestagen, and carcinogenesis in the breast is partly due to oxidative damage to DNA bases. Therefore, we studied the effects of 17 β-oestradiol and progesterone on the antioxidative status and the vulnerability to oxidative stress exhibited by normal human breast epithelial cells in culture. After exposure to hydrogen peroxide, cells grown with oestradiol alone or with both oestradiol and progesterone showed significantly decreased viability compared to cells grown in medium without added hormones. There was, however, no difference in hydrogen peroxide degradation rate between controls and hormone treated cultures. When desferrioxamine was added, the viability increased and the hydrogen peroxide degradation rate decreased. The levels of several antioxidants were altered in cells grown in the presence of oestradiol and progesterone: the concentrations of glutathione reductase and catalase decreased significantly while the levels of glutathione peroxidase and reduced glutathione did not change. The alterations in enzyme activity and cell vulnerability were more pronounced in cultures treated with a combination of oestradiol and progesterone.

We conclude that the redox balance in the cultured normal human breast epithelial cells was altered by treatment with oestradiol and progesterone, and that this change led to the increased death of cells subsequently exposed to hydrogen peroxide. This effect may have implications for sex hormone dependent diseases of the breast.     

Oxidant, mitochondria and calcium: an overview

Mitochondria are active in the continuous generation of reactive oxygen species (ROS), (e.g., superoxide), thereby favouring a situation of mitochondrial oxidative stress. Under oxidative stress--for example, ischaemia-reoxygenation injury to cells--mitochondria form superoxide, which in turn is converted to hydrogen peroxide and the potent reactive species, hydroxyl radical. Alternatively, mitochondrial superoxide may react with nitric oxide to form potent oxidant peroxynitrite and as a consequence, mitochondrial function is altered. An increase in the release of calcium from mitochondria by oxidants stimulates calcium-dependent enzymes such as calcium-dependent proteases, nucleases, and phospholipases, which subsequently trigger apoptosis of the cells. In principle, calcium can leave mitochondria by different ways: by non-specific leakage through the inner membrane by "pore formation," by changes in the membrane lipid phase, by reversal of the uniport influx carrier, by the specific calcium/hydrogen (or sodium) antiport system, by channel-mediated release pathways, or by a combination of two or more of these pathways. Additionally, the release of calcium from mitochondria can also occur either by oxidation of internal nicotinamide adenine nucleotides to ADP ribose and nicotinamide or by oxidation of thiols in membrane proteins. Once calcium efflux has been triggered, a series of common pathways of apoptosis are initiated, each of which may be sufficient to destroy the cell. Apoptosis requires the active participation of cellular components, and several genes have been suggested to control apoptosis. The proto-oncogene bcl-2 suppresses apoptosis through mitochondrial effects. Overexpression of bcl-2 in the mitochondrial membrane inhibits calcium efflux, but the underlying mechanisms are not clearly known. Further studies are needed to explore the nature of the apoptosis-inducing pathways, the precise mechanisms of calcium efflux, the molecular partners of bcl-2 oncoproteins at the level of the outer-inner membrane contact sites, the molecular biology of the apoptosis-inducing factor formation and release, and the essential molecular targets of apoptosis-inducing proteases. Clarification of these issues might facilitate the understanding of mitochondrial response on cellular calcium dynamics under oxidant stress.     

Calcium-dependent and calcium-independent mechanisms of irreversible cell injury in cultured hepatocytes

It has been proposed that alterations in intracellular calcium homeostasis mediate the genesis of lethal cell injury with an acute oxidative stress. It is shown here, however, that such changes can be dissociated by two different means from the cell death occurring with the exposure of cultured hepatocytes to hydrogen peroxide generated either in the medium by glucose oxidase or intracellularly by the mechanism of menadione. The chelation of intracellular ferric iron with deferoxamine inhibits the formation of hydroxyl radicals from hydrogen peroxide and prevents cell killing. Deferoxamine did not prevent, however, an elevation of the cytosolic Ca2+ ion concentration detected as an activation of phosphorylase alpha. Sulfhydryl reagents inhibited the rise in phosphorylase alpha activity in deferoxamine-pretreated hepatocytes. Conversely, cultured hepatocytes were depleted of Ca2+ ions by treatment with EGTA in a calcium-free medium. Calcium-depleted cells were not resistant to the toxicity of hydrogen peroxide despite the virtual elimination of the activation of phosphorylase alpha. In contrast, it was possible to kill cultured hepatocytes by a mechanism dependent upon a disordered intracellular calcium homeostasis using hepatocytes pretreated in calcium-free medium with the ionophore A23187. These cells were killed in a dose-dependent manner by the addition of calcium ions to the culture medium in concentrations ranging from 0.1 to 2.0 mM. There was a similar dose-dependent activation of phosphorylase alpha, but phosphorylase alpha activities were higher than with H2O2 at comparable cell killing. Deferoxamine pretreatment and sulfhydryl reagents had no effect on the loss of viability with this calcium-dependent cell killing.     

Hydrogen peroxide mediates the radiation-induced mutator phenotype in mammalian cells

Chronic oxidative stress has been associated with genomic instability following exposure to ionizing radiation. However, results showing direct causal linkages between specific ROS (reactive oxygen species) and the ionizing radiation-induced mutator phenotype are lacking. The present study demonstrates that ionizing radiation-induced genomically unstable cells (characterized by chromosomal instability and an increase in mutation and gene amplification frequencies) show a 3-fold increase in steady-state levels of hydrogen peroxide, but not superoxide. Furthermore, stable clones isolated from parallel studies showed significant increases in catalase and GPx (glutathione peroxidase) activity. Treatment of unstable cells with PEG-CAT (polyethylene glycol-conjugated catalase) reduced the mutation frequency and mutation rate in a dose-dependent fashion. In addition, inhibiting catalase activity in the stable clones using AT (3-aminotriazole) increased mutation frequency and rate. These results clearly demonstrate the causal relationship between chronic oxidative stress mediated by hydrogen peroxide and the mutator phenotype that persists for many generations following exposure of mammalian cells to ionizing radiation.     

Persistent impairment of mitochondrial and tissue redox status during lithium-pilocarpine-induced epileptogenesis

Mitochondrial dysfunction and oxidative stress are known to occur following acute seizure activity but their contribution during epileptogenesis is largely unknown. The goal of this study was to determine the extent of mitochondrial oxidative stress, changes to redox status, and mitochondrial DNA (mtDNA) damage during epileptogenesis in the lithium-pilocarpine model of temporal lobe epilepsy. Mitochondrial oxidative stress, changes in tissue and mitochondrial redox status, and mtDNA damage were assessed in the hippocampus and neocortex of Sprague-Dawley rats at time points (24h to 3months) following lithium-pilocarpine administration. A time-dependent increase in mitochondrial hydrogen peroxide (H(2)O(2)) production coincident with increased mtDNA lesion frequency in the hippocampus was observed during epileptogenesis. Acute increases (24-48h) in H(2)O(2) production and mtDNA lesion frequency were dependent on the severity of convulsive seizure activity during initial status epilepticus. Tissue levels of GSH, GSH/GSSG, coenzyme A (CoASH), and CoASH/CoASSG were persistently impaired at all measured time points throughout epileptogenesis, that is, acutely (24-48h), during the 'latent period' (48h to 7days), and chronic epilepsy (21days to 3months). Together with our previous work, these results demonstrate the model independence of mitochondrial oxidative stress, genomic instability, and persistent impairment of mitochondrial specific redox status during epileptogenesis. Lasting impairment of mitochondrial and tissue redox status during the latent period, in addition to the acute and chronic phases of epileptogenesis, suggests that redox-dependent processes may contribute to the progression of epileptogenesis in experimental temporal lobe epilepsy.