MAPK pathways mediate hyperoxia-induced oncotic cell death in lung epithelial cells

Abstract

Cell injury and cell death of pulmonary epithelium plays an important role in the pathogenesis of acute lung injury in animals exposed to prolonged hyperoxia. The aim of this study was to decipher the molecular mechanisms modulating cell death induced by hyperoxia in lung epithelium. Cell death is thought to be either apoptotic, with shrinking phenotypes and activated caspases, or oncotic, with swelling organelles. Exposure to 95% O₂ (hyperoxia) induced cell death of MLE-12 cells with cellular as well as nuclear swelling, cytosolic vacuolation, and loss of mitochondrial structure and enzyme function. Neither elevated caspase-3 activity nor phosphatidylserine translocation were detected, suggesting that in hyperoxia, MLE-12 cells die via oncosis rather than apoptosis. In addition, hyperoxia triggered a sustained activation of the transcription factor AP-1, as well as mitogen-activated protein kinase (MAPK) family members p38 and JNK. Importantly, survival of MLE-12 cells in hyperoxia was significantly enhanced when either AP-1, p38, or JNK activation was inhibited by either specific inhibitors or dominant negative DNA constructs, indicating that in lung epithelial cells hyperoxia induces a program-driven oncosis, involving AP-1, JNK, and p38 MAPK. Interestingly, hydrogen peroxide-induced oxidative apoptosis of MLE-12 cells, with a shrinking nuclear morphology and activated caspase-3 activity, is also mediated by AP-1, JNK, and p38. Therefore, our data indicate that although they have divergent downstream events, oxidative oncosis and apoptosis share upstream JNK/p38 and AP-1 pathways, which could be used as potential targets for reducing hyperoxic inflammatory lung injury.

Introduction

Mechanical ventilation with hyperoxic conditions is often used to treat patients, especially premature newborns, with respiratory distress due to hypoxemia. However, prolonged exposure to hyperoxia causes acute inflammatory lung injury, accompanied by injury and death of both pulmonary endothelial and epithelial cells in animal models, including mice, rats, and rabbits 1, 2, 3, 4, 5. Alveolar epithelial cells are essential in maintaining the integrity of the alveolar-capillary barrier. The compromised integrity of alveolar epithelial cells leads to the leakage of fluid, macromolecules, and lymphatic infiltrates into the air spaces, causing pulmonary edema, lung dysfunction, and even death 6, 7. Therefore, a thorough understanding of the regulation of the pathways leading to alveolar epithelial cell injury and cell death may provide some insights for improving the outcome in these patients.

The terms apoptosis, necrosis, and oncosis are associated with the current thinking about cell death. Whereas necrosis is defined by the loss of plasma membrane integrity, both apoptosis and oncosis are used to describe the cell death processes leading to the loss of plasma membrane integrity 8, 9. Apoptosis is an active process requiring adenosine triphosphate (ATP), characterized by cellular shrinkage, nuclear condensation, and activation of caspase-3 [10]. On the other hand, cell death that is marked by cellular swelling should be called oncosis [11]. Although it has long been confused with necrosis, oncosis describes a process leading to cell death, whereas necrosis refers to the morphological alterations appearing after either apoptosis or oncosis [11]. Much attention has been focused on the signaling pathways that lead to apoptosis induced by various stresses in different cell types. However, aside from its use in classifying dying cells that have swollen organelles, little is known about oncosis 8, 9, 11.

Increasing evidence suggests that bronchial and alveolar epithelia exposed to prolonged hyperoxia suffer from multiple modes of cell injury and cell death, with both oncotic and apoptotic morphologies in hyperoxia-injured animal lungs 3, 12, 13, 14. Morphometric and ultrastructural analyses revealed that these cells exhibit swelling of the intracellular organelles, including the mitochondria and endoplasmic reticulum, typical markers of oncosis. Conversely, characteristics of apoptosis, including chromatin condensation, plasma membrane blebbing, and increased internucleosomal DNA ladders, can be observed concurrently in hyperoxic-injured lungs 5, 14, 15, 16, 17, 18.

Although strategies aimed at attenuating apoptotic cell death may be effective, preventing injury and death of nonapoptotic cells with an oncotic morphology may also be beneficial in preventing tissue injury, especially inflammatory injures. First, because apoptotic cells can be recognized via translocated phosphatidylserine and subsequently cleared, it is reasonable to assume that it is easier to prevent the release of inflammatory-causing contents from apoptotic cells than from nonapoptotic cells. In fact, inflammatory diseases, such as hyperoxic acute lung injury, have been proposed as a result of nonapoptotic cell death [19]. In addition, high mobility group protein-1 (HMG-1) has been shown to be a mediator for acute inflammatory lung injury [20], and the release of HMG-1 from nonapoptotic cells occurs more readily than from apoptotic cells 21, 22. Therefore, interventions focused on pathways leading to oncotic cell injury and cell death may prove to be useful in alleviating inflammatory hyperoxic lung injury.

Mouse lung epithelial (MLE-12) cells have been used as a model system for alveolar epithelial cells by a number of laboratories 23, 24. To investigate the signal transduction pathways to hyperoxia-induced cell injury and cell death in alveolar epithelium, MLE-12 cells were used as a model system in which the detection of signaling events are not complicated by that from other cell types as in the lung. In this report we demonstrate that in hyperoxia, MLE-12 cells died via oncosis, with swollen cell nuclei, cytosolic vacuolation, and disrupted mitochondrial structure and function, in the absence of either increased caspase-3 activity or phosphatidylserine translocation.

Little is known about the pathways leading to oncotic cell death. To begin the dissection of the pathways to hyperoxic oncosis and to examine whether these oncotic cells undergo similar events as oxidative apoptosis, we focused on the upstream pathways that are important in apoptosis. Numerous studies demonstrate that the transcription factor AP-1 and its trans-activators, JNK and p38, are activated by genotoxic stresses [25]. Although AP-1 is involved in modulating both cell proliferation and death in a cell type- and stimulus-dependent manner, sustained activation of AP-1 under persistent genotoxic stress is thought to be more closely associated with apoptosis 26, 27, 28. Under these circumstances, JNK and p38 MAPK play pivotal roles in mediating the induction and sustained activation of AP-1 [25]. Therefore, both AP-1 and its upstream regulators, JNK and p38 MAPK, play essential roles in genotoxic stress-induced apoptosis. However, it is unclear whether such pathways are activated and play causal roles in the less characterized oncotic cell death. In this report, we showed that JNK and p38 MAPK signal transduction pathways mediate not only oxidative apoptosis, but also hyperoxia-induced oncotic cell death.