Starvation-induced autophagocytosis paradoxically decreases the susceptibility to oxidative stress of the extremely oxidative stress-sensitive NIT insulinoma cells

Summary

Glucose and amino acid starvation of cells in culture generally enhances their sensitivity to oxidative stress. This is explained by compensatory autophagocytosis, which results in increased amounts of lysosomal low-molecular-weight, redox-active iron, due to the degradation of metallo-proteins, with a potential increase in iron-catalyzed, intralysosomal oxidative reactions. Such reactions diminish the stability of lysosomal membranes, with resultant leakage of hydrolytic enzymes into the cytosol and ensuing cellular degeneration, often of apoptotic type. However, starvation of NIT insulinoma cells, which are normally remarkably sensitive to oxidative stress, actually attenuated the sensitivity to such stress. We found that starved NIT cells rapidly synthesized ferritin. Moreover, ferritin was found to be autophagocytosed, and the lysosomes were stabilized, as assayed by the acridine orange relocation test. We hypothesize that compensatory autophagocytosis during starvation increases the cytosolic pool of redox-active iron, as a reflection of enhanced transportation of low-molecular-weight iron from autophagic lysosomes to the cytosol, resulting in ferritin induction. The newly formed ferritin would, in turn, become autophagocytosed and bind redox-active lysosomal iron in a non-redox-active form. We also suggest that the proposed mechanism may be a way for oxidative stress-sensitive cells to compensate partly for their failing capacity to degrade hydrogen peroxide before it leaks into the acidic vacuolar apparatus and induces intralysosomal oxidative stress. The insulin-producing beta cell may belong to this type of cells.     

Exposure of cells to nonlethal concentrations of hydrogen peroxide induces degeneration-repair mechanisms involving lysosomal destabilization

The cytotoxicity of hydrogen peroxide is, at least partly, mediated by the induction of intralysosomal iron-catalyzed oxidative reactions with damage to lysosomal membranes and leakage of destructive contents. We hypothesize that minor such leakage may be nonlethal, and the ensuing cellular degeneration repairable. Consequently, we investigated, using a model system of cultured J-774 cells, the effects of hydrogen peroxide in moderate concentrations on cellular viability, lysosomal membrane integrity, morphology, and ATP and reduced glutathione concentrations. These parameters were initially estimated directly after a 30 min exposure to a bolus dose of hydrogen peroxide in phosphate buffered saline at 37°C, and then again following subsequent recovery periods of different lengths under ordinary culture conditions. All cells survived an exposure to 250 μM hydrogen peroxide for 30 min, whereas 350 and 500 μM exposure was lethal to a small fraction of cells. The oxidative stress caused early, time- and dose-dependent, partial relocalization of the lysosomotropic weak base acridine orange from the lysosomal compartment to the cytosol. This phenomenon is known to parallel leakage of damaging lysosomal contents such as hydrolytic enzymes. There were also signs of cellular damage in the form of surface blebbing and increased autophagocytosis, more marked with the higher doses of hydrogen peroxide. Also found was a rapid depletion of ATP and GSH. These alterations were all reversible, as long as cells were exposed to nonlethal amounts of hydrogen peroxide. Based on these and previous findings, we suggest that lysosomes are less stable organelles than has hitherto been assumed. Restricted lysosomal leakage might be a common event, for example, during sublethal oxidative stress, causing reversible, degenerative alterations, which are repaired by autophagocytosis.     

Cell sensitivity to oxidative stress is influenced by ferritin autophagy

To test the consequences of lysosomal degradation of differently iron-loaded ferritin molecules and to mimic ferritin autophagy under iron-overload and normal conditions, J774 cells were allowed to endocytose heavily iron loaded ferritin, probably with some adventitious iron (Fe-Ft), or iron-free apo-ferritin (apo-Ft). When cells subsequently were exposed to a bolus dose of hydrogen peroxide, apo-Ft prevented lysosomal membrane permeabilization (LMP), whereas Fe-Ft enhanced LMP. A 4-h pulse of Fe-Ft initially increased oxidative stress-mediated LMP that was reversed after another 3h under standard culture conditions, suggesting that lysosomal iron is rapidly exported from lysosomes, with resulting upregulation of apo-ferritin that supposedly is autophagocytosed, thereby preventing LMP by binding intralysosomal redox-active iron. The obtained data suggest that upregulation of the stress protein ferritin is a rapid adaptive mechanism that counteracts LMP and ensuing apoptosis during oxidative stress. In addition, prolonged iron starvation was found to induce apoptotic cell death that, interestingly, was preceded by LMP, suggesting that LMP is a more general phenomenon in apoptosis than so far recognized. The findings provide new insights into aging and neurodegenerative diseases that are associated with enhanced amounts of cellular iron and show that lysosomal iron loading sensitizes to oxidative stress.     

Lysosomal heterogeneity between and within cells with respect to resistance against oxidative stress

The prevailing opinion on lysosomal endurance is that, as long as the cells are still alive, these organelles are generally quite stable and, thus, do not induce cell damage by leaking their numerous powerful hydrolytic enzymes to the cytosol. We suggest that this opinion is basically wrong and consider that many lysosomes are quite vulnerable, especially to oxidative stress. Moreover, we suggest that cellular degeneration, including apoptosis as well as necrosis, follows upon lysosomal disruption. We have found differing stability of lysosomal membranes to oxidative stress, not only among different cell types, but also between cells of the same type and between lysosomes of individual cells. We suggest that cellular resistance to oxidative stress is mainly a function of three parameters: (i) the capacity to degrade hydrogen peroxide before it reaches, and may diffuse into, the acidic vacuolar compartment; (ii) the resistance to reactive oxygen species of lysosomal membranes; and (iii) the intralysosomal amounts of redox-active, low molecular weight iron. Iron-catalysed intralysosomal reactions, if pronounced enough, result in peroxidation and destabilization of the lysosomal membrane. Owing to differences in the cellular synthesis of hydrogen peroxide-degrading enzymes, degree of autophagocytotic degradation of iron-containing metalloproteins, lysosomal localization within the cytoplasm and intralysosomal iron chelation, the above three parameters may vary between both different and similar cells and between lysosomes of individual cells as well, explaining their observed variability with respect to resistance against oxidative stress     

Lethal hydrogen peroxide toxicity involves lysosomal iron-catalyzed reactions with membrane damage

Secondary lysosomes contain low-molecular weight iron-complexes as a consequence of normal autophagocytotic degradation of various metallo-proteins. Thus, entry of hydrogen peroxide into these organelles may induce ironcatalyzed oxidative reactions with ensuing damage to lysosomal membranes and leakage of destructive contents. The amount of lysosomal reactive iron and the cellular capacity to degrade hydrogen peroxide would then be important determining factors in cellular resistance to oxidative stress. The effects of hydrogen peroxide on cell viability and, in particular, on lysosomal membrane integrity, evaluated by acridine orange, lucifer yellow, neutral red, and cathepsin D relocalization, were investigated in a model system of cultured J-774 cells. The protective effect of the iron-chelator desferal was studied after exposure to the drug under ordinary culture conditions and after inhibition of cellular endocytosis. Hydrogen peroxide-exposure (500 μM in PBS, 37°C, 5–90 min) was manifested as a time-dependent decrease in cell viability. This was preceded by a rapid reduction of the proton gradient across the lysosomal membranes, as judged by relocalization of acridine orange. Another early sign of damage was plasma membrane blebbing, found on many cells within minutes after the initiation of hydrogen peroxide-exposure. The cells also showed a partial redistribution of the lysosomal markers lucifer yellow, neutral red, and cathepsin D, indicating lysosomal destabilization. The pre-exposure of cells to desferal in culture prevented all these phenomena, unless endocytotic uptake of the drug was prevented.     

Lysosomal heterogeneity between and within cells with respect to resistance against oxidative stress

The prevailing opinion on lysosomal endurance is that, as long as the cells are still alive, these organelles are generally quite stable and, thus, do not induce cell damage by leaking their numerous powerful hydrolytic enzymes to the cytosol. We suggest that this opinion is basically wrong and consider that many lysosomes are quite vulnerable, especially to oxidative stress. Moreover, we suggest that cellular degeneration, including apoptosis as well as necrosis, follows upon lysosomal disruption. We have found differing stability of lysosomal membranes to oxidative stress, not only among different cell types, but also between cells of the same type and between lysosomes of individual cells. We suggest that cellular resistance to oxidative stress is mainly a function of three parameters: (i) the capacity to degrade hydrogen peroxide before it reaches, and may diffuse into, the acidic vacuolar compartment; (ii) the resistance to reactive oxygen species of lysosomal membranes; and (iii) the intralysosomal amounts of redox-active, low molecular weight iron. Iron-catalysed intralysosomal reactions, if pronounced enough, result in peroxidation and destabilization of the lysosomal membrane. Owing to differences in the cellular synthesis of hydrogen peroxide-degrading enzymes, degree of autophagocytotic degradation of iron-containing metalloproteins, lysosomal localization within the cytoplasm and intralysosomal iron chelation, the above three parameters may vary between both different and similar cells and between lysosomes of individual cells as well, explaining their observed variability with respect to resistance against oxidative stress This revised version was published online in November 2006 with corrections to the Cover Date.     

Lysosomal heterogeneity between and within cells with respect to resistance against oxidative stress

The prevailing opinion on lysosomal endurance is that, as long as the cells are still alive, these organelles are generally quite stable and, thus, do not induce cell damage by leaking their numerous powerful hydrolytic enzymes to the cytosol. We suggest that this opinion is basically wrong and consider that many lysosomes are quite vulnerable, especially to oxidative stress. Moreover, we suggest that cellular degeneration, including apoptosis as well as necrosis, follows upon lysosomal disruption. We have found differing stability of lysosomal membranes to oxidative stress, not only among different cell types, but also between cells of the same type and between lysosomes of individual cells. We suggest that cellular resistance to oxidative stress is mainly a function of three parameters: (i) the capacity to degrade hydrogen peroxide before it reaches, and may diffuse into, the acidic vacuolar compartment; (ii) the resistance to reactive oxygen species of lysosomal membranes; and (iii) the intralysosomal amounts of redox-active, low molecular weight iron. Iron-catalysed intralysosomal reactions, if pronounced enough, result in peroxidation and destabilization of the lysosomal membrane. Owing to differences in the cellular synthesis of hydrogen peroxide-degrading enzymes, degree of autophagocytotic degradation of iron-containing metalloproteins, lysosomal localization within the cytoplasm and intralysosomal iron chelation, the above three parameters may vary between both different and similar cells and between lysosomes of individual cells as well, explaining their observed variability with respect to resistance against oxidative stress This revised version was published online in November 2006 with corrections to the Cover Date.     

Endogenous ferritin protects cells with iron-laden lysosomes against oxidative stress

Previous studies have shown that a variety of mammalian cell types, including macrophages, contain small amounts of redox-active iron in their lysosomes. Increases in the level of this iron pool predispose the cell to oxidative stress. Limiting the availability of intralysosomal redox-active iron could therefore represent potential cytoprotection for cells under oxidative stress.

In the present study we have shown that an initial 6 h exposure of J774 macrophages to 30 μM iron, added to the culture medium as FeCl₃, increased the lysosomal iron content and their sensitivity to H₂O₂-induced (0.25 mM for 30 min) oxidative stress. Over time (24-72 h), however, the cells were desensitized to the cytotoxic effects of H₂O₂; most likely as a consequence of both lysosomal iron exocytosis and of ferritin synthesis (demonstrated by atomic absorption spectrophotometry, autometallography, and immunohistochemistry). When the cells were exposed to a second dose of iron, their lysosomal content of iron increased again but the cells became no further sensitized to the cytotoxic effects of H₂O₂. Using the lysosomotropic weak base, acridine orange, we demonstrated that after the second exposure to iron and H₂O₂, lysosomes remained intact and were no different from control cells which were exposed to H₂O₂ but not iron.

These data suggest that the initial induction of ferritin synthesis leads to enrichment of lysosomes with ferritin via autophagocytosis. This limits the redox-availability of intralysosomal iron and, in turn, decreases the cells' sensitivity to oxidative stress. These in vitro observations could also explain why cells under pathological conditions, such as haemochromatosis, are apparently able to withstand high iron concentrations for some time in vivo.     

Oxidative stress,growth factor starvation and Fas activation may all cause apoptosis through lysosomal leak

Abstract

Oxidative stress, growth factor starvation, and activation of the Fas/APO-1/CD95 receptor all induce apoptosis in a variety of cell-types, including the established human Jurkat T-cell line. Oxidative stress, in the form of exposure of the cells to a bolus dose of hydrogen peroxide, results in intra-lysosomal, iron-catalyzed oxidative reactions. This is accompanied by a time- and dose-dependent lysosomal destabilization — as evaluated by a decreased lysosomal uptake of the metachromatic fluorochrome, and weak base, acridine orange —in combination with leakage to the cytosol of lysosomal contents, including hydrolytic enzymes. Moderate lysosomal rupture is followed by apoptosis within initially intact plasma membranes, while necrosis and cell lysis are associated with a more complete lysosomal breach. Prior endocytosis of the potent iron-chelator desferrioxamine,resulting in binding of intralysosomal low molecular weight iron in a non-redox active form, largely prevents not only oxidative stress-induced lysosomal labilization, but apoptosis as well. When apoptosis is induced by the use of a monoclonal IgM anti-human Fas/APO-1/CD95 receptor antibody, the apoptotic process is again found to be accompanied by lysosomal leak. It is, however, not prevented by a preceding endocytosis of desferrioxamine and, consequently, could not be a function of intralysosomal iron-catalyzed oxidative reactions,but must be due to other mechanisms. Growth factor starvation of Jurkat cultures for a few days results in a high proportion of apoptotic cells, which contain lysosomes many of which have lost their proton gradient and appear to have released their contents. Overall, our results indicate that lysosomal leakage/rupture precedes apoptosis in Jurkat cells regardless of the initiating agent, but that such rupture may occur through multiple mechanisms. Lysosomal enzymes, leaking out of their normal vacuolar compartment, may then induce apoptosis, perhaps by proteolytic activation of the caspase-family of enzymes. Regardless of the precise mechanism, these observations suggest that partial rupture of the acidic vacuolar compartment may be one of the finalpathways in apoptosis.     

Oxidative stress, growth factor starvation and Fas activation may all cause apoptosis through lysosomal leak

Oxidative stress, growth factor starvation, and activation of the Fas/APO-1/CD95 receptor all induce apoptosis in a variety of cell-types, including the established human Jurkat T-cell line. Oxidative stress, in the form of exposure of the cells to a bolus dose of hydrogen peroxide, results in intralysosomal, iron-catalyzed oxidative reactions. This is accompanied by a time- and dose-dependent lysosomal destabilization--as evaluated by a decreased lysosomal uptake of the metachromatic fluorochrome, and weak base, acridine orange--in combination with leakage to the cytosol of lysosomal contents, including hydrolytic enzymes. Moderate lysosomal rupture is followed by apoptosis within initially intact plasma membranes, while necrosis and cell lysis are associated with a more complete lysosomal breach. Prior endocytosis of the potent iron-chelator desferrioxamine, resulting in binding of intralysosomal low molecular weight iron in a non-redox active form, largely prevents not only oxidative stress-induced lysosomal labilization, but apoptosis as well. When apoptosis is induced by the use of a monoclonal IgM anti-human Fas/APO-1/CD95 receptor antibody, the apoptotic process is again found to be accompanied by lysosomal leak. It is, however, not prevented by a preceding endocytosis of desferrioxamine and, consequently, could not be a function of intralysosomal iron-catalyzed oxidative reactions, but must be due to other mechanisms. Growth factor starvation of Jurkat cultures for a few days results in a high proportion of apoptotic cells, which contain lysosomes many of which have lost their proton gradient and appear to have released their contents. Overall, our results indicate that lysosomal leakage/rupture precedes apoptosis in Jurkat cells regardless of the initiating agent, but that such rupture may occur through multiple mechanisms. Lysosomal enzymes, leaking out of their normal vacuolar compartment, may then induce apoptosis, perhaps by proteolytic activation of the caspase-family of enzymes. Regardless of the precise mechanism, these observations suggest that partial rupture of the acidic vacuolar compartment may be one of the final pathways in apoptosis.     

On the Cytoprotective Role of Ferritin in Macrophages and its Ability to Enhance Lysosomal Stability

Macrophages have a great capacity to take up (eg. by endocytosis and phagocytosis) exogenous sources of iron which could potentially become cytotoxic, particularly following the intralysosomal formation of low-molecular weight, redox active iron, and under conditions of oxidative stress. Following autophago-cytosis of endogenous ferritin/apoferritin, these compounds may serve as chelators of such lysosomal iron and counteract the occurrence of iron-mediated intralysosomal oxidative reactions. Such redox-reactions have been shown to lead to destabilisation of lysosomal membranes and result in leakage of damaging lysosomal contents to the cytosol. In this study we have shown: (i) human monocyte-derived macrophages to accumulate ferritin in response to iron exposure; (ii) iron to destabilise macrophage secondary lysosomes when the cells are exposed to H₂O₂; and (iii) endocytosed apoferritin to act as a stabiliser of the acidic vacuolar compartment of iron-loaded macrophages. While the endogenous ferritin accumulation which was induced by iron exposure was not sufficient to protect cells from the damaging effects of H₂O₂, exogenously added apoferritin, as well as the potent iron chelator desferrioxamine, afforded significant protection. It is suggested that intralysosomal formation of haemosiderin, from partially degraded ferritin, is a protective strategy to suppress intralysosomal iron-catalysed redox reactions. However, under conditions of severe macrophage lysosomal iron-overload, induction of ferritin synthesis is not enough to completely prevent the enhanced cytotoxic effects of H₂O₂.     

ARPE-19 retinal pigment epitheliaL CELLS are highly resistant to oxidative stress and exercise strict control over their lysosomal redox-active iron

Normal retinal pigment epithelial (RPE) cells are postmitotic, long-lived and basically not replaced. Daily, they phagocytose substantial amounts of lipid-rich material (photoreceptor outer segment discs), and they do so in the most oxygenated part of the body – the retina. One would imagine that this state of affairs should be associated with a rapid formation of the age pigment lipofuscin (LF). However, LF accumulation is slow and reaches significant amounts only late in life when, if substantial, it often coincides with or causes age-related macular degeneration. LF formation occurs inside the lysosomal compartment as a result of iron-catalyzed peroxidation and polymerization. This process requires phagocytosed or autophagocytosed material under degradation, but also the presence of redox-active low mass iron and hydrogen peroxide. To gain some information on how RPE cells are able to evade LF formation, we investigated the response of immortalized human RPE cells (ARPE-19) to oxidative stress with/without the protection of a strong iron-chelator. The cells were found to be extremely resistant to hydrogen peroxide-induced lysosomal rupture and ensuing cell death. This marked resistance to oxidative stress was not explained by enhanced degradation of hydrogen peroxide, but to a certain extent further increased by the potent lipophilic iron chelator SIH. The cells were also able to survive, and even replicate, at high concentrations of SIH and showed a high degree of basal autophagic flux. We hypothesize that RPE cells have a highly developed capacity to keep lysosomal iron in a non-redox-active form, perhaps by pronounced autophagy of iron-binding proteins in combination with an ability to rapidly relocate low mass iron from the lysosomal compartment.     

Novel cellular defenses against iron and oxidation: ferritin and autophagocytosis preserve lysosomal stability in airway epithelium

Adsorbed to a variety of particles, iron may be carried to the lungs by inhalation thereby contributing to a number of inflammatory lung disorders. Redox-active iron is a potent catalyst of oxidative processes, but intracellularly it is bound primarily to ferritin in a non-reactive form and probably is catalytically active largely within the lysosomal compartment. Damage to the membranes of these organelles causes the release to the cytosol of a host of powerful hydrolytic enzymes, inducing apoptotic or necrotic cell death. The results of this study, using cultured BEAS-2B cells, which are adenovirus transformed human bronchial epithelial cells, and A549 cells, which have characteristics similar to type II alveolar epithelial cells, suggest that the varying abilities of different types of lung cells to resist oxidative stress may be due to differences in intralysosomal iron chelation. Cellular ferritin and iron were assayed by ELISA and atomic absorption, while plasma and lysosomal membrane stability were evaluated by the acridine orange uptake and trypan blue dye exclusion tests, respectively. Normally, and also after exposure to an iron complex, A549 cells contained significantly more ferritin (2.26 +/- 0.60 versus 0.63 +/- 0.33 ng/microg protein, P <0.001) and less iron (0.96 +/- 0.14 versus 1.48 +/- 0.21 ng/microg protein, P <0.05) than did BEAS-2B cells. Probably as a consequence, iron-exposed A549 cells displayed more stable lysosomes (P <0.05) and better survival (P <0.05) following oxidative stress. Following starvation-induced autophagocytosis, which also enhances resistance to oxidant stress, the A549 cells showed a significant reduction in ferritin, and the BEAS-2B cells did not. These results suggest that intralysosomal ferritin enhances lysosomal stability by iron-chelation, preventing Fenton-type chemistry. This notion was further supported by the finding that endocytosis of apoferritin, added to the medium, stabilized lysosomes (P <0.001 versus P <0.01) and increased survival (P <0.01 versus P <0.05) of iron-loaded A549 and BEAS-2B cells. Assuming that primary cell lines of the alveolar and bronchial epithelium behave in a similar manner as these respiratory cell lines, intrabronchial instillation of apoferritin-containing liposomes may in the future be a treatment for iron-dependent airway inflammatory processes.     

Autophagy, ageing and apoptosis: the role of oxidative stress and lysosomal iron

As an outcome of normal autophagic degradation of ferruginous materials, such as ferritin and mitochondrial metalloproteins, the lysosomal compartment is rich in labile iron and, therefore, sensitive to the mild oxidative stress that cells naturally experience because of their constant production of hydrogen peroxide. Diffusion of hydrogen peroxide into the lysosomes results in Fenton-type reactions with the formation of hydroxyl radicals and ensuing peroxidation of lysosomal contents with formation of lipofuscin that amasses in long-lived postmitotic cells. Lipofuscin is a non-degradable polymeric substance that forms at a rate that is inversely related to the average lifespan across species and is built up of aldehyde-linked protein residues. The normal accumulation of lipofuscin in lysosomes seems to reduce autophagic capacity of senescent postmitotic cells--probably because lipofuscin-loaded lysosomes continue to receive newly formed lysosomal enzymes, which results in lack of such enzymes for autophagy. The result is an insufficient and declining rate of autophagic turnover of worn-out and damaged cellular components that consequently accumulate in a way that upsets normal metabolism. In the event of a more substantial oxidative stress, enhanced formation of hydroxyl radicals within lysosomes jeopardizes the membrane stability of particularly iron-rich lysosomes, specifically of autophagolysosomes that have recently participated in the degradation of iron-rich materials. For some time, the rupture of a limited number of lysosomes has been recognized as an early upstream event in many cases of apoptosis, particularly oxidative stress-induced apoptosis, while necrosis results from a major lysosomal break. Consequently, the regulation of the lysosomal content of redox-active iron seems to be essential for the survival of cells both in the short- and the long-term.     

OxLDL-induced macrophage cytotoxicity is mediated by lysosomal rupture and modified by intralysosomal redox-active iron

Oxidized low density lipoprotein (oxLDL) is believed to play a central role in atherogenesis. LDL is oxidized in the arterial intima by mechanisms that are still only partially understood. OxLDL is then taken up by macrophages through scavenger receptor-mediated endocytosis, which then leads to cellular damage, including apoptosis. The complex mechanisms by which oxLDL induces cell injury are mostly unknown. This study has demonstrated that oxLDL-induced damage of macrophages is associated with iron-mediated intralysosomal oxidative reactions, which cause partial lysosomal rupture and ensuing apoptosis. This series of events can be prevented by pre-exposing cells to the iron-chelator, desferrioxamine (DFO), whereas it is augmented by pretreating the cells with a low molecular weight iron complex. Since both DFO and the iron complex would be taken up by endocytosis, and thus directed to the lysosomal compartment, the results suggest that the normal contents of lysosomal low molecular weight iron may play an important role in oxLDL-induced cell damage, presumably by catalyzing intralysosomal fragmentation of lipid peroxides and the formation of toxic aldehydes and oxygen-centered radicals.     

OxLDL-induced macrophage cytotoxicity is mediated by lysosomal rupture and modified by intralysosomal redox-active iron

Oxidized low density lipoprotein (oxLDL) is believed to play a central role in atherogenesis. LDL is oxidized in the arterial intima by mechanisms that are still only partially understood. OxLDL is then taken up by macrophages through scavenger receptor-mediated endocytosis, which then leads to cellular damage, including apoptosis. The complex mechanisms by which oxLDL induces cell injury are mostly unknown. This study has demonstrated that oxLDL-induced damage of macrophages is associated with iron-mediated intralysosomal oxidative reactions, which cause partial lysosomal rupture and ensuing apoptosis. This series of events can be prevented by pre-exposing cells to the iron-chelator, desferrioxamine (DFO), whereas it is augmented by pretreating the cells with a low molecular weight iron complex. Since both DFO and the iron complex would be taken up by endocytosis, and thus directed to the lysosomal compartment, the results suggest that the normal contents of lysosomal low molecular weight iron may play an important role in oxLDL-induced cell damage, presumably by catalyzing intralysosomal fragmentation of lipid peroxides and the formation of toxic aldehydes and oxygen-centered radicals.     

Cathepsin D-Bax death pathway in oxidative stressed neuroblastoma cells

Hydrogen peroxide, the major oxidoradical species in the central nervous system, has been involved in neuronal cell death and associated neurodegenerative diseases. In this study, we have investigated the involvement of the lysosomal pathway in the cytotoxic mechanism of hydrogen peroxide in human neuroblastoma cells. Alteration of lysosomal and mitochondrial membrane integrity was shown to be an early event in the lethal cascade triggered by oxidative stress. Desferrioxamine (DFO), an iron chelator that abolishes the formation of reactive oxygen species within lysosomes, prevented lysosome leakage, mitochondrial permeabilization and caspase-dependent apoptosis in hydrogen peroxide-treated cells. Inhibition of cathepsin D, not of cathepsin B, as well as small-interference RNA-mediated silencing of the cathepsin D gene prevented hydrogen peroxide-induced injury of mitochondria, caspase activation, and TUNEL-positive cell death. Cathepsin D activity was shown indispensable for translocation of Bax onto mitochondrial membrane associated with oxidative stress. DFO abolished both the cytosolic relocation of Cathepsin D and the mitochondrial relocation of Bax in hydrogen peroxide-treated cells. siRNA-mediated down-regulation of Bax expression protected the cells from oxidoradical injury. The present study identifies the lysosome as the primary target and the axis cathepsin D-Bax as the effective pathway of hydrogen peroxide lethal activity in neuroblastoma cells.     

Lysosomotropic detergents induce time- and dose-dependent apoptosis/necrosis in cultured cells

Abstract

Oxidative stress has been found to cause lysosomal rupture due to iron-catalyzed intralysosomal oxidative reactions.^1,2 Moderate rupture induces apoptosis, while necrosis follows a more complete relocation of this type.² We have suggested that lysosomal cysteine proteases may directly activate the caspase cascade and, together with other lysosomal hydrolases, induce mitochondrial release of cytochrome c with ensuing further activation of the cascade.     

-Lipoic acid and -lipoamide prevent oxidant-induced lysosomal rupture and apoptosis

Abstract

-Lipoic acid (LA) and its corresponding derivative, -lipoamide (LM), have been described as antioxidants, but the mechanisms of their putative antioxidant effects remain largely uncharacterised. The vicinal thiols present in the reduced forms of these compounds suggest that they might possess metal chelating properties. We have shown previously that cell death caused by oxidants may be initiated by lysosomal rupture and that this latter event may involve intralysosomal iron which catalyzes Fenton-type chemistry and resultant peroxidative damage to lysosomal membranes. Here, using cultured J774 cells as a model, we show that both LA and LM stabilize lysosomes against oxidative stress, probably by chelating intralysosomal iron and, consequently, preventing intralysosomal Fenton reactions. In preventing oxidant-mediated apoptosis, LM is significantly more effective than LA, as would be expected from their differing capacities to enter cells and concentrate within the acidic lysosomal compartment. As previously reported, the powerful iron-chelator, desferrioxamine (Des) (which also locates within the lysosomal compartment), also provides protection against oxidant-mediated cell death. Interestingly, although Des enhances the partial protection afforded by LA, it confers no additional protection when added with LM. Therefore, the antioxidant actions of LA and LM may arise from intralysosomal iron chelation, with LM being more effective in this regard.     

Macrophage erythrophagocytosis and iron exocytosis

SUMMARY

Senescent, or damaged, erythrocytes are removed from the blood stream mainly by the macrophage system. Such cells may acquire and store large quantities of the redox-active transition metal iron that, if released together with superoxide and hydrogen peroxide during an oxidative burst, may induce peroxidative reactions with a variety of surrounding substances, e.g., low-density lipoprotein (LDL). In this study we demonstrate 1. the temporary sequestration of iron within the secondary lysosomal apparatus of both established macrophage-like J-774 cells and human monocyte-derived macrophages secondary to the uptake and degradation of native and photo-oxidized (ultraviolet UV light) erythrocytes; and 2. an ensuing development by these cells of a capacity for iron-exocytosis. The binding and uptake by human macrophages and J-774 cells of artificially aged, UV-irradiated erythrocytes were stimulated compared to that of native erythrocytes. The uptake resulted in lysosomal accumulation of iron in a low-molecular weight form, as shown by autometallography. Cells exposed to ferric chloride were used as positive controls. Ensuing exocytosis of iron to the culture medium was demonstrated by atomic absorption spectroscopy. Our findings suggest that macrophage erythrophagocytosis is a useful model for the study of the sequestration of iron within the macrophage acidic vacuolar apparatus, its subsequent exocytosis, and oxidative effect on extracellular LDL.