Helge Dalen

Photo-oxidative disruption of lysosomal membranes causes apoptosis of cultured human fibroblasts.

Acridine orange (AO) is a lysosomotropic weak base, a metachromatic fluorochrome, and a photosensitizer, as well. Living cells that are exposed for a short period of time to this compound at low concentration, and under ordinary culture conditions, accumulate the drug within their acidic vacuolar compartment, giving rise to a mainly red, granular fluoresence upon excitation with blue light. When AO-loaded cells are irradiated with intense blue light, AO soon starts to leak from late endosomes and lysosomes, partially shifting the fluorescence to a green, nuclear and diffuse cytosolic, one. This AO-relocalization is a consequence of photo-oxidation of the lysosomal membranes, which initially results in disruption of their proton-gradients and later, in leakage into the cytosol of a host of hydrolytic enzymes--as was here demonstrated by immunocytochemistry--which are capable of causing cellular damage. Most fibroblasts survived minor photo-oxidation, with a period of reparative autophagocytosis. Severe photo-oxidation, which resulted in severe lysosomal damage, caused cellular necrosis; whereas moderate stress, resulting in only partial lysosomal leakiness lead to apoptosis with TUNEL-positive nuclei and shrunken cytoplasm. The findings of the present study show that photo-oxidative damage to the membranes that surround the acidic vacuolar compartment, is an event that results in release of proteolytic and DNA-fragmenting enzymes into the cytosol, which may induce either necrosis, apoptosis, or reparable sublethal damage, depending on the magnitude of lysosomal rupture. Furthermore, the results strongly suggest that proteases and endonucleases of lysosomal origin may induce apoptosis if relocalized from the acidic vacuolar compartment into the cytosol.

Induction of cell death by the lysosomotropic detergent MSDH

Controlled lysosomal rupture was initiated in lysosome‐rich, macrophage‐like cells by the synthetic lysosomotropic detergent, O‐methyl‐serine dodecylamide hydrochloride (MSDH). When MSDH was applied at low concentrations, resulting in partial lysosomal rupture, activation of pro‐caspase‐3‐like proteases and apoptosis followed after some hours. Early during apoptosis, but clearly secondary to lysosomal destabilization, the mitochondrial transmembrane potential declined. At high concentrations, MSDH caused extensive lysosomal rupture and necrosis. It is suggested that lysosomal proteases, if released to the cytosol, may cause apoptosis directly by pro‐caspase activation and/or indirectly by mitochondrial attack with ensuing discharge of pro‐apoptotic factors.

Lysosomal destabilization in p53-induced apoptosis

The tumor suppressor wild-type p53 can induce apoptosis. M1-t-p53 myeloid leukemic cells have a temperature-sensitive p53 protein that changes its conformation to wild-type p53 after transfer from 37°C to 32°C. We have now found that these cells showed an early lysosomal rupture after transfer to 32°C. Mitochondrial damage, including decreased membrane potential and release of cytochrome c, and the appearance of apoptotic cells occurred later. Lysosomal rupture, mitochondrial damage, and apoptosis were all inhibited by the cytokine IL-6. Some other compounds can also inhibit apoptosis induced by p53. The protease inhibitor N-tosyl-l-phenylalanine chloromethyl ketone inhibited the decrease in mitochondrial membrane potential and cytochrome c release, the Ca2+-ATPase inhibitor thapsigargin inhibited only cytochrome c release, and the antioxidant butylated hydroxyanisole inhibited only the decrease in mitochondrial membrane potential. In contrast to IL-6, these other compounds that inhibited some of the later occurring mitochondrial damage did not inhibit the earlier p53-induced lysosomal damage. The results indicate that apoptosis is induced by p53 through a lysosomal-mitochondrial pathway that is initiated by lysosomal destabilization, and that this pathway can be dissected by using different apoptosis inhibitors. These findings on the induction of p53-induced lysosomal destabilization can also help to formulate new therapies for diseases with apoptotic disorders.

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 degrees C, and then again following subsequent recovery periods of different lengths under ordinary culture conditions. All cells survived an exposure to 250 microM hydrogen peroxide for 30 min, whereas 350 and 500 microM 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.

Aging of Cardiac Myocytes in Culture: Oxidative Stress, Lipofuscin Accumulation, and Mitochondrial Turnover

Abstract: Oxidative stress is believed to be an important contributor to aging, mainly affecting long‐lived postmitotic cells such as cardiac myocytes and neurons. Aging cells accumulate functionally effete, often mutant and enlarged mitochondria, as well as an intralysosomal undegradable pigment, lipofuscin. To provide better insight into the role of oxidative stress, mitochondrial damage, and lipofuscinogenesis in postmitotic aging, we studied the relationship between these parameters in cultured neonatal rat cardiac myocytes. It was found that the content of lipofuscin, which varied drastically between cells, positively correlated with mitochondrial damage (evaluated by decreased innermembrane potential), as well as with the production of reactive oxygen species. These results suggest that both lipofuscin accumulation and mitochondrial damage have common underlying mechanisms, likely including imperfect autophagy and ensuing lysosomal degradation of oxidatively damaged mitochondria and other organelles. Increased size of mitochondria (possibly resulting from impaired fission due to oxidative damage to mitochondrial DNA, membranes, and proteins) also may interfere with mitochondrial turnover, leading to the appearance of so‐called “giant” mitochondria. This assumption is based on our observation that pharmacological inhibition of autophagy with 3‐methyladenine induced only moderate accumulation of large (senescent‐like) mitochondria but drastically increased numbers of small, apparently normal mitochondria, reflecting their rapid turnover and suggesting that enlarged mitochondria are poorly autophagocytosed. Overall, our findings emphasize the importance of mitochondrial turnover in postmitotic aging and provide further support for the mitochondrial‐lysosomal axis theory of aging.

Ceroid/lipofuscin-loaded human fibroblasts show decreased survival time and diminished autophagocytosis during amino acid starvation.

To test whether heavy accumulation of ceroid/lipofuscin can disturb important functions of the lysosomal system, AG-1518 human fibroblasts, ceroid/lipofuscin-loaded (following prolonged culture at normobaric hyperoxia) or not, were exposed to amino acid starvation. Ceroid/lipofuscin-loading resulted in decreased cellular survival. Also, there was an inverse relationship between amounts of ceroid/lipofuscin and the survival time of individual cells within the same cultures. Ceroid/lipofuscin-loaded fibroblasts displayed diminished autophagocytotic capacity, as demonstrated by electron microscopy and by treatment of cell cultures with NH4Cl (which inhibits autophagocytotic degradation by increasing intralysosomal pH) for 1 week before ensuing starvation. The latter treatment increased survival of control cells (due to deposition of nondegraded autophagocytosed material before start of starvation), but not that of ceroid/lipofuscin-loaded cells. Moreover, when NH4Cl treatment was combined with starvation, both groups of cells showed approximately the same shortened survival times, testifying to the causal relationship between diminished autophagocytosis and decreased survival of starving ceroid/lipofuscin-loaded cells. We hypothesize that large amounts of undegradable ceroid/lipofuscin within the acidic vacuolar compartment may interfere with lysosomal function, resulting in poor renewal of long-lived proteins and worn-out/damaged organelles, decreased adaptability, and cell death.

Inhibition of autophagy with 3-methyladenine results in impaired turnover of lysosomes and accumulation of lipofuscin-like material.

Autophagy (which includes macro-, micro-, and chaperone-mediated autophagy) is an important biological mechanism for degradation of damaged/obsolete macromolecules and organelles. Ageing non-dividing cells, however, progressively accumulate oxidised proteins, defective organelles and intralysosomal lipofuscin inclusions, suggesting inherent insufficiency of autophagy. To learn more about the role of macroautophagy in the turnover of organelles and lipofuscin formation, we inhibited autophagic sequestration with 3-methyladenine (3 MA) in growth-arrested human fibroblasts, a classical model of cellular ageing. Such treatment resulted in a dramatic accumulation of altered lysosomes, displaying lipofuscin-like autofluorescence, as well as in a moderate increase of mitochondria with lowered membrane potential. The size of the late endosomal compartment appeared not to be significantly altered following 3 MA exposure. The accumulation of lipofuscin-like material was enhanced when 3 MA administration was combined with hyperoxia. The findings suggest that macroautophagy is essential for normal turnover of lysosomes. This notion is supported by reports in the literature of lysosomal membrane proteins inside lysosomes and/or late endosomes, as well as lysosomes with active hydrolases within autophagosomes following vinblastine-induced block of fusion between lysosomes and autophagosomes. The data also suggest that specific components of lysosomes, such as membranes and proteins, may be direct sources of lipofuscin.

α-Tocopheryl succinate sensitises a T lymphoma cell line to TRAIL-induced apoptosis by suppressing NF-κB activation

Activation of nuclear factor-κB (NF-κB) can interfere with induction of apoptosis triggered by the tumour necrosis factor-related apoptosis-inducing ligand (TRAIL; Apo2L). Therefore, agents that suppress NF-κB activation may sensitise cells to TRAIL-dependent apoptosis. Exposure of Jurkat cells to TRAIL resulted in massive and saturable apoptosis induction, following an initial lag time. This lag was abolished by pretreatment of the cells with subapoptotic doses of α-tocopheryl succinate (α-TOS) or the proteasome inhibitor MG132. Exposure of the cells to TRAIL led to a rapid, transient activation of NF-κB, a process that was suppressed by cell pretreatment with α-TOS or MG132. Activation of NF-κB by TNF-α prior to TRAIL exposure increased resistance of the cells to TRAIL-mediated apoptosis. We conclude that α-TOS sensitises cells to TRAIL killing, at least in some cases, through inhibition of NF-κB activation. This further supports the possibility that this semisynthetic analogue of vitamin E is a potential adjuvant in cancer treatment, such as in the case of TRAIL-mediated inhibition of cancer.

Mitochondria transmit apoptosis signalling in cardiomyocyte-like cells and isolated hearts exposed to experimental ischemia-reperfusion injury

Abstract Ischemia-reperfusion (I/R) is a condition leading to serious complications due to death of cardiac myocytes. We used the cardiomyocyte-like cell line H9c2 to study the mechanism underlying cell damage. Exposure of the cells to simulated I/R lead to their apoptosis. Over-expression of Bcl-2 and Bcl-xL protected the cells from apoptosis while over-expression of Bax sensitized them to programmed cell death induction. Mitochondria-targeted coenzyme Q (mitoQ) and superoxide dismutase both inhibited accumulation of reactive oxygen species (ROS) and apoptosis induction. Notably, mtDNA-deficient cells responded to I/R by decreased ROS generation and apoptosis. Using both in situ and in vivo approaches, it was found that apoptosis occurred during reperfusion following ischemia, and recovery was enhanced when hearts from mice were supplemented with mitoQ. In conclusion, I/R results in apoptosis in cultured cardiac myocytes and heart tissue largely via generation of mitochondria-derived superoxide, with ensuing apoptosis during the reperfusion phase.

The integrity of experimental vein graft endothelium--implications on the etiology of early graft failure.

INTRODUCTION the vascular endothelium serves as a functional barrier between the circulating blood and the vessel wall. It is an essential element for the maintenance of vascular homeostasis and is implicated in the pathogenesis of vascular disease. Reversed vein bypass grafting is considered to be a devastating procedure for the endothelial cell layer of the graft during the first 7 days. At this time, smooth muscle cell proliferation, the forerunner of intimal hyperplasia, begins. Loss of endothelial cell integrity is cited as an important factor in this smooth muscle cell response. The integrity of the vein graft endothelial lining after grafting was examined in this study. METHODS reversed vein bypass grafting of the common carotid artery using external jugular vein was performed in 24 New Zealand white rabbits. All grafts were pressure fixed (80 mmHg) in situ, at 0 and 10 min, 6 h and 1, 3, 5, 7 and 14 days postoperatively. The endothelial cell layer was examined by light microscopy (LM), scanning (SEM) and transmission electron microscopy (TEM) and immunohistochemistry (Factor VIII) using standard histological procedures. RESULTS the endothelium was observed by SEM and confirmed by both LM, Factor VIII and TEM in all specimens. It covered almost the entire surface examined. At 0 and 10 min, endothelial cells were present and displayed minimal evidence of injury. At 6 h and 1 day, numerous red cells, polymorphonucleocytes (PMNs), platelets and fibrin were adherent to the luminal surface. Blood cells were also seen beneath the endothelium. At day 3, the adherent fibrin and cellular elements were reduced with most of the endothelial lining intact. Within 10 min, TEM demonstrated that these cells were stretched, very thin with few microvesicles and a blurred cytoplasm, which would indicate viability but a degree of cellular injury. By day 1, the endothelial cells were lifted from their underlying structures by subendothelial oedema and an infiltrate predominantly of PMNs. By day 5, the blood cells and fibrin which were adherent to the endothelium had been dispersed and the subendothelial infiltrate was to a large extent replaced by disintegrated PMNs. On days 7 and 14, a viable confluent endothelial cell layer was present and a degree of intimal hyperplasia was noted. The endothelial cells appeared to have enlarged nucleoli and cytoplasms filled with a considerable quantity of rough endoplasmic reticulum. CONCLUSION the endothelium of reversed vein grafts is preserved at the time of implantation and at all time intervals studied in this model. These findings do not support the assumption that endothelial denudation is a prerequisite for intimal hyperplasia. Endothelial cell dysfunction and morphological changes are maximal within the first 3 days after grafting but appear to recover by the 5th postoperative day. The gross preservation of the endothelial cell layer implies that therapeutic approaches, to mitigate endothelial cell injury and its consequences, should be focused on the preoperative period and the first 5 days following implantation.