Previously published online as an Autophagy E-publication: http://www.landesbioscience.com/journals/autophagy/abstract.php?id=2229 KEY WORDS ACKNOWLEDGEMENTSWe thank Dr. Lihua He and Dr. Jae-Sung Kim for helpful discussions and Ms. Sherry Grissom for expert technical assistance. This work was supported, in part, by Grants 1 P01 DK59340 and 5-R01 AG07218 from the National Institutes of Health. Dr. Rodriguez-Enriquez was supported by a fellowship from CONACyT-Mexico. Imaging facilities were supported, in part, by center grants 5-P30-DK34987 and 1-P50-AA11605 from the National Institutes of Health. Research PaperTracker Dyes to Probe Mitochondrial Autophagy (Mitophagy) in Rat Hepatocytes ABSTRACT Mitochondria become targets for autophagic degradation after nutrient deprivation, a process also termed mitophagy. In this study, we used LysoTracker Red (LTR) and MitoTracker Green to characterize the kinetics of autophagosomal proliferation and mitophagy in cultured rat hepatocytes. Autophagy induced by nutrient deprivation plus glucagon increased LTR uptake assessed with a fluorescence plate reader and the number of LTR-labeled acidic organelles assessed with confocal microscopy in individual hepatocytes both by 4-to 6-fold. Serial imaging of hepatocytes coloaded with MitoTracker Green (MTG) revealed an average mitochondrial digestion time of 7.5 min after autophagic induction. In the presence of protease inhibitors, digestion time more than doubled, and the total number of LTR-labeled organelles increased about 40%, but the proportion of the LTR-labeled acidic organelles containing MTG fluorescence remained constant at about 75%. Autophagy inhibitors, 3-methyladenine, wortmannin and LY204002, suppressed the increase of LTR uptake after nutrient deprivation by up to 85%, confirming that increased LTR uptake reflected autophagy induction. Cyclosporin A and NIM811, specific inhibitors of the mitochondrial permeability transition (MPT), also decreased LTR uptake, whereas tacrolimus, an immunosuppressive reagent that does not inhibit the MPT, was without effect. In addition, the c-Jun N-terminal kinase (JNK) inhibitors, SCP25041 and SP600125, blocked LTR uptake by 47% and 61%, respectively, but ERK1, p38 and caspase inhibitors had no effect. The results show that mitochondria once selected for mitophagy are rapidly digested and support the concept that mitochondrial autophagy involves the MPT and signaling through PI3 kinase and possibly JNK.
Storage of donor livers in Euro-Collins solution for human transplantation surgery is limited to about 8 hr. Here, tissue damage to isolated rat livers stored under the same conditions as human livers was characterized following reperfusion. The purpose of this work was to determine the importance of nutritional status on injury due to cold storage and reperfusion, to establish whether lethal injury occurs during cold storage or only after reperfusion, and to identify the cell types most vulnerable to damage. Rat livers were perfused with Krebs-Henseleit-bicarbonate buffer, stored 8 to 48 hr in Euro-Collins solution and reperfused with warm, oxygenated Krebs-Henseleit buffer for 15 min. Nuclear trypan blue uptake and lactate dehydrogenase release were used as indices of cell death. After 8 hr of cold storage and reperfusion, little loss of parenchymal or nonparenchymal viability occurred. After 24 or 48 hr, virtually all parenchymal cells remained viable. However, severe damage to nonparenchymal cells was observed, and about 40% of nonparenchymal cells were trypan blue positive. Nutritional status (fed vs. fasted) did not affect the extent of cell damage. Nonparenchymal cell killing was accompanied by cellular rounding, nuclear pyknosis and protrusion of cells into sinusoidal lumens. Scanning electron micrographs demonstrated denudation of the sinusoidal lining. Rounding and pyknosis were not observed in 24-hr-stored livers which were not reperfused, and trypan blue uptake did not occur in stored livers infused with cold, anoxic Euro-Collins solution. Based on cytochemistry and electron microscopy, lethal cell injury occurred predominantly to endothelial cells.(ABSTRACT TRUNCATED AT 250 WORDS)
Reperfusion injury characterized by loss of endothelial cell viability occurs after cold ischemic storage of livers for transplantation surgery. Here, ultrastructural changes in stored rat livers were examined by scanning and transmission electron microscopy. With increasing times of storage in Euro-Collins solution (4 to 24 hr) followed by 15 min of reperfusion at 37 degrees C, a sequence of structural alterations was observed involving endothelial and Kupffer cells. Widening of endothelial fenestrations occurred after 4 hr and progressed over 8 to 24 hr to retraction of cellular processes, ball-like rounding, sinusoidal denudation and ultrastructural derangements consistent with loss of cell viability. Kupffer cells exhibited progressive rounding, ruffling of the cell surface, polarization, appearance of wormlike densities, vacuolization and degranulation over a similar time course. By contrast, the structures of parenchymal and fat-storing cells were relatively undisturbed by cold storage and reperfusion. Alterations to endothelial and Kupffer cells were also studied as a function of time of reperfusion. After 24 hr of storage, endothelial cells showed retraction of cytoplasm before reperfusion that progressed quickly to loss of viability and denudation during reperfusion. Kupffer cell activation (ruffling, degranulation) during reperfusion was slower and occurred after deterioration of endothelial cells. Livers stored in Euro-Collins solution were also compared with livers stored in University of Wisconsin cold storage solution, an improved preservation medium for transplantation. University of Wisconsin solution provided better preservation of endothelial structure and markedly reduced parenchymal cell blebbing and swelling before reperfusion. University of Wisconsin solution also reduced Kupffer cell activation and release of lysosomal enzymes. In conclusion, endothelial cell deterioration followed by Kupffer cell activation occurred after increasing times of cold ischemic storage and reperfusion of rat livers. Both changes may contribute to the pathophysiology of graft failure caused by reperfusion-mediated storage injury.
Graft failure after liver transplantation may involve mitochondrial dysfunction. We examined whether prevention of mitochondrial injury would improve graft function. Orthotopic rat liver transplantation was performed after 18 hours' cold storage in University of Wisconsin solution and treatment with vehicle, minocycline, tetracycline, or N-methyl-4-isoleucine cyclosporin (NIM811) of explants and recipients. Serum alanine aminotransferase (ALT), necrosis, and apoptosis were assessed 6 hours after implantation. Mitochondrial polarization and cell viability were assessed by intravital microscopy. Respiration and the mitochondrial permeability transition (MPT) were assessed in isolated rat liver mitochondria. After transplantation with vehicle or tetracycline, ALT increased to 5242 U/L and 4373 U/L, respectively. Minocycline and NIM811 treatment decreased ALT to 2374 U/L and 2159 U/L, respectively (P < 0.01). Necrosis and terminal deoxynucleotidyl transferase-mediated nick-end labeling (TUNEL) also decreased from 21.4% and 21 cells/field, respectively, after vehicle to 10.1% and 6 cells/field after minocycline and to 8.7% and 5.2 cells/field after NIM811 (P < 0.05). Additionally, minocycline decreased caspase-3 activity in graft homogenates (P < 0.05). Long-term graft survival was 27% and 33%, respectively, after vehicle and tetracycline treatment, which increased to 60% and 70% after minocycline and NIM811 (P < 0.05). In isolated mitochondria, minocycline and NIM811 but not tetracycline blocked the MPT. Minocycline blocked the MPT by decreasing mitochondrial Ca 2؉ uptake, whereas NIM811 blocks by interaction with cyclophilin D. Intravital microscopy showed that minocycline and NIM811 preserved mitochondrial polarization and cell viability after transplantation (P < 0.05). Conclusion: Minocycline and NIM811 attenuated graft injury after rat liver transplantation and improved graft survival. Minocycline and/or NIM811 might be useful clinically in hepatic surgery and transplantation. (HEPATOLOGY 2008;47:236-246.)
Zhong Z, Ramshesh VK, Rehman H, Currin RT, Sridharan V, Theruvath TP, Kim I, Wright GL, Lemasters JJ. Activation of the oxygen-sensing signal cascade prevents mitochondrial injury after mouse liver ischemia-reperfusion. Am J Physiol Gastrointest Liver Physiol 295: G823-G832, 2008. First published September 4, 2008 doi:10.1152/ajpgi.90287.2008.-The mitochondrial permeability transition (MPT) plays an important role in hepatocyte death caused by ischemia-reperfusion (IR). This study investigated whether activation of the cellular oxygen-sensing signal cascade by prolyl hydroxylase inhibitors (PHI) protects against the MPT after hepatic IR. Ethyl 3,4-dihyroxybenzoate (EDHB, 100 mg/kg ip), a PHI, increased mouse hepatic hypoxia-inducible factor-1␣ and heme oxygenase-1 (HO-1). EDHB-treated and untreated mice were subjected to 1 h of warm ischemia to ϳ70% of the liver followed by reperfusion. Mitochondrial polarization, cell death, and the MPT were assessed by intravital confocal/multiphoton microscopy of rhodamine 123, propidium iodide, and calcein. EDHB largely blunted alanine aminotransferase (ALT) release and necrosis after reperfusion. In vehicle-treated mice at 2 h after reperfusion, viable cells with depolarized mitochondria were 72%, and dead cells were 2%, indicating that depolarization preceded necrosis. Mitochondrial voids excluding calcein disappeared, indicating MPT onset in vivo. NIM811, a specific inhibitor of the MPT, blocked mitochondrial depolarization after IR, further confirming that mitochondrial depolarization was due to MPT onset. EDHB decreased mitochondrial depolarization to 16% and prevented the MPT. Tin protoporphyrin (10 mol/kg sc), an HO-1 inhibitor, partially abrogated protection by EDHB against ALT release, necrosis, and mitochondrial depolarization. In conclusion, IR causes the MPT and mitochondrial dysfunction, leading to hepatocellular death. PHI prevents MPT onset and liver damage through an effect mediated partially by HO-1. ethyl 3,4-dihyroxybenzoate; heme oxygenase; hepatic ischemia-reperfusion; mitochondrial permeability transition; prolyl hydroxylase inhibitor ISCHEMIA-REPERFUSION (IR) injury to the liver occurs in trauma, hemorrhagic and cardiac shock, vascular diseases, and hepatic surgery, including tumor resection and liver transplantation. A variety of pathophysiological processes likely contribute to development of IR injury. Reactive oxygen species (ROS) play a critical role in the injury caused by IR (18,36,57). ROS not only directly damage cell membranes, DNA, and protein; they also trigger formation of toxic cytokines and increase adhesion molecules leading to inflammatory responses, tissue damage, and multiple organ failure (1,10,17,41). Recently, growing evidence supports an important role of the mitochondrial permeability transition (MPT) in cell injury after IR (24,25,45,58). The mitochondrial membrane potential collapses when the MPT occurs, leading to failure of ATP synthesis, release of cytochrome c, and cell death (24,25,55). ROS cause opening of MPT pores (22...
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