Normal remodeling of the oxygen-injured lung requires the cyclin-dependent kinase inhibitor p21(Cip1/WAF1/Sdi1)

Alveolar cells of the lung are injured and killed when exposed to elevated levels of inspired oxygen. Damaged tissue architecture and pulmonary function is restored during recovery in room air as endothelial and type II epithelial cells proliferate. Although excessive fibroblast proliferation and inflammation occur when abnormal remodeling occurs, genes that regulate repair remain unknown. Our recent observation that hyperoxia inhibits proliferation through induction of the cyclin-dependent kinase inhibitor p21(Cip1/WAF1/Sdi1), which also facilitates DNA repair, suggested that p21 may participate in remodeling. This hypothesis was tested in p21-wild-type and -deficient mice exposed to 100% FiO(2) and recovered in room air. p21 increased during hyperoxia, remained elevated after 1 day of recovery before returning to unexposed levels. Increased proliferation occurred when p21 expression decreased. In contrast, higher and sustained levels of proliferation, resulting in myofibroblast hyperplasia and monocytic inflammation, occurred in recovered p21-deficient lungs. Cells with DNA strand breaks and expressing p53 were observed in hyperplastic regions suggesting that DNA integrity had not been restored. Normal recovery of endothelial and type II epithelial cells, as assessed by expression of cell-type-specific genes was also delayed in p21-deficient lungs. These results reveal that p21 is required for remodeling the oxygen-injured lung and suggest that failure to limit replication of damaged DNA may lead to cell death, inflammation, and abnormal remodeling. This observation has important implications for therapeutic strategies designed to attenuate long-term chronic lung disease after oxidant injury.     

Neonatal oxygen increases sensitivity to influenza A virus infection in adult mice by suppressing epithelial expression of Ear1

Oxygen exposure in premature infants is a major risk factor for bronchopulmonary dysplasia and can impair the host response to respiratory viral infections later in life. Similarly, adult mice exposed to hyperoxia as neonates display alveolar simplification associated with a reduced number of alveolar epithelial type II cells and exhibit persistent inflammation, fibrosis, and mortality when infected with influenza A virus. Because type II cells participate in innate immunity and alveolar repair, their loss may contribute to oxygen-mediated sensitivity to viral infection. A genomewide screening of type II cells identified eosinophil-associated RNase 1 (Ear1). Ear1 was also detected in airway epithelium and was reduced in lungs of mice exposed to neonatal hyperoxia. Electroporation-mediated gene delivery of Ear1 to the lung before infection successfully reduced viral replication and leukocyte recruitment during infection. It also diminished the enhanced morbidity and mortality attributed to neonatal hyperoxia. These findings demonstrate that novel epithelial expression of Ear1 functions to limit influenza A virus infection, and its loss contributes to oxygen-associated epithelial injury and fibrosis after infection. People born prematurely may have defects in epithelial innate immunity that increase their risk for respiratory viral infections.     

Transgenic overexpression of granulocyte macrophage-colony stimulating factor in the lung prevents hyperoxic lung injury

Granulocyte macrophage-colony stimulating factor (GM-CSF) plays an important role in pulmonary homeostasis, with effects on both alveolar macrophages and alveolar epithelial cells. We hypothesized that overexpression of GM-CSF in the lung would protect mice from hyperoxic lung injury by limiting alveolar epithelial cell injury. Wild-type C57BL/6 mice and mutant mice in which GM-CSF was overexpressed in the lung under control of the SP-C promoter (SP-C-GM mice) were placed in >95% oxygen. Within 6 days, 100% of the wild-type mice had died, while 70% of the SP-C-GM mice remained alive after 10 days in hyperoxia. Histological assessment of the lungs at day 4 revealed less disruption of the alveolar wall in SP-C-GM mice compared to wild-type mice. The concentration of albumin in bronchoalveolar lavage fluid after 4 days in hyperoxia was significantly lower in SP-C-GM mice than in wild-type mice, indicating preservation of alveolar epithelial barrier properties in the SP-C-GM mice. Alveolar fluid clearance was preserved in SP-C-GM mice in hyperoxia, but decreased significantly in hyperoxia-exposed wild-type mice. Staining of lung tissue for caspase 3 demonstrated increased apoptosis in alveolar wall cells in wild-type mice in hyperoxia compared to mice in room air. In contrast, SP-C-GM mice exposed to hyperoxia demonstrated only modest increase in alveolar wall apoptosis compared to room air. Systemic treatment with GM-CSF (9 micro g/kg/day) during 4 days of hyperoxic exposure resulted in decreased apoptosis in the lungs compared to placebo. In studies using isolated murine type II alveolar epithelial cells, treatment with GM-CSF greatly reduced apoptosis in response to suspension culture. In conclusion, overexpression of GM-CSF enhances survival of mice in hyperoxia; this effect may be explained by preservation of alveolar epithelial barrier function and fluid clearance, at least in part because of reduction in hyperoxia-induced apoptosis of cells in the alveolar wall.     

Relationship of alveolar epithelial injury and repair to the induction of pulmonary fibrosis.

Explants of mouse lung were cultured at various stages of injury after exposure to hyperoxia for determination of whether endothelial or epithelial injury alone could stimulate fibrosis in a blood-free environment. Mice were exposed to 95% O2 for periods up to 6 days. Then one lobe of lung was prepared for organ culture, and others were used for assessment of lung damage by morphologic studies and by the protein and cellular content of bronchoalveolar lavage (BAL) fluid. Explants cultured when the lung showed endothelial injury only were not different from air-exposed controls. As alveolar damage, particularly to Type 1 epithelial cells, increased at 6 days, more protein was found by lavage; and after culture, overall DNA synthesis in explants was reduced. Autoradiography showed that epithelial cell proliferation was preferentially retarded while fibroblast growth became predominant. Collagen production was also significantly increased after 3 and 6 days of culture. In these explants there were few macrophages and no white blood cells or other blood components. Some mice, returned to air after hyperoxia, showed prompt epithelial repair, and cultures of these lungs were not different from controls. The results suggest that severe injury and retarded repair of the alveolar epithelium disturbs normal epithelial-fibroblast interactions and is sufficient to promote the fibrotic process. Less severe injury involving the endothelium only is not associated with fibrosis.     

Multiple Wall In-folds Sub-divide Single Segments During Capillary Regression in Hyperoxic Acute Lung Injury

Abstract

The present study provides further insight into the structural processes that remodel pulmonary capillaries in the injured adult lung. Early in hyperoxia acute lung injury (HALI), many sub-dividing segments are present throughout the capillary network before segment occlusion and loss predominate and capillary density decreases later in the period. A second segment sub-division triggered in regenerating capillaries after air breathing (post-HALI) demonstrates a similar mechanism of organization at a time of contrasting change in the capillary density. As we have previously reported, the process of segment sub-division includes in-folding of the endothelial-epithelial surface (alveolar–capillary membrane) to form inter-luminal structures (ILSs) and loops, with loop separation increasing segment number. Unexpectedly, the findings support remodeling of the capillary density by wall in-folding in acute lung injury, demonstrating a similar mechanism in capillary regression as well as in regeneration in the adult lung.     

Application of linear integration in the morphometric study of mild and severe pulmonary alveolar injury

In this study we applied linear integration morphometry to characterize the pulmonary alveolar reaction to toxic injury and to study possible relationships between the major tissue and cell compartments of alveolar tissue, normal and injured. Acute alveolar injury of mild and severe intensity was induced in Swiss-Webster mice by the ip administration of the chemicals diquat (4 mg/kg) and butylated hydroxytoluene (BHT; 400 mg/kg). Animals were sacrificed at Days 1 and 2 after diquat treatment and at Days 1, 3, and 5 after BHT treatment. Sampling and analysis of alveolar tissue were conducted at both levels of light and electron microscopy. Thickness distributions of arithmetic and reciprocal intercepts, as well as the arithmetic (tau) and harmonic (tau h) mean thicknesses, were established for the following alveolar compartments: septum, alveolo-capillary barrier (ACB), type I and total epithelia, capillary endothelium, and interstitium. A relative measure of the pulmonary diffusion capacity and the capillary load of alveolar septa were also determined. The parameters calculated from these thickness distributions, such as their slopes, percentages of thin intercepts, and tau/tau h ratios, proved very sensitive and useful in the detection and characterization of morphological alterations in the type I epithelial and capillary endothelial cells following either mild or severe alveolar injury. The epithelial, endothelial, and interstitial layers of pulmonary septa were all characterized by their own pattern of structural changes, so that it proved impossible to relate them in a simple way to the tissue reaction, which can be easily studied at the light microscopic level. Linear integration morphometry thus proved very useful as a morphometric approach to the study of pulmonary alveolar injury and repair.     

Pneumocystis pneumonia increases the susceptibility of mice to sublethal hyperoxia

Patients with Pneumocystis pneumonia often develop respiratory failure after entry into medical care, and one mechanism for this deterioration may be increased alveolar epithelial cell injury. In vitro, we previously demonstrated that Pneumocystis is not cytotoxic for alveolar epithelial cells. In vivo, however, infection with Pneumocystis could increase susceptibility to injury by stressors that, alone, would be sublethal. We examined transient exposure to hyperoxia as a prototypical stress that does cause mortality in normal mice. Mice were depleted of CD4+ T cells and inoculated intratracheally with Pneumocystis. Control mice were depleted of CD4+ T cells but did not receive Pneumocystis. After 4 weeks, mice were maintained in normoxia, were exposed to hyperoxia for 4 days, or were exposed to hyperoxia for 4 days followed by return to normoxia. CD4-depleted mice with Pneumocystis pneumonia demonstrated significant mortality after transient exposure to hyperoxia, while all uninfected control mice survived this stress. We determined that organism burdens were not different. However, infected mice exposed to hyperoxia and then returned to normoxia demonstrated significant increases in inflammatory cell accumulation and lung cell apoptosis. We conclude that Pneumocystis pneumonia leads to increased mortality following a normally sublethal hyperoxic insult, accompanied by alveolar epithelial cell injury and increased pulmonary inflammation.     

Matrilysin (matrix metalloproteinase-7) mediates E-cadherin ectodomain shedding in injured lung epithelium

Matrilysin (matrix metalloproteinase-7) is highly expressed in lungs of patients with pulmonary fibrosis and other conditions associated with airway and alveolar injury. Although matrilysin is required for closure of epithelial wounds ex vivo, the mechanism of its action in repair is unknown. We demonstrate that matrilysin mediates shedding of E-cadherin ectodomain from injured lung epithelium both in vitro and in vivo. In alveolar-like epithelial cells, transfection of activated matrilysin resulted in shedding of E-cadherin and accelerated cell migration. In vivo, matrilysin co-localized with E-cadherin at the basolateral surfaces of migrating tracheal epithelium, and the reorganization of cell-cell junctions seen in wild-type injured tissue was absent in matrilysin-null samples. E-cadherin ectodomain was shed into the bronchoalveolar lavage fluid of bleomycin-injured wild-type mice, but was not shed in matrilysin-null mice. These findings identify E-cadherin as a novel substrate for matrilysin and indicate that shedding of E-cadherin ectodomain is required for epithelial repair.     

Fate and effects of adult bone marrow cells in lungs of normoxic and hyperoxic newborn mice

Cell-based therapy in adult lung injury models is associated with highly variable donor cell engraftment and epithelial reconstitution. The role of marrow-derived cell therapy in neonatal lung injury is largely unknown. In this study, we determined the fate and effects of adult bone marrow cells in a model of neonatal lung injury. Wild-type mice placed in a normoxic or hyperoxic (95% O(2)) environment received bone marrow cells from animals expressing green fluorescent protein (GFP) at Postnatal Day (P)5. Controls received vehicle buffer. Lungs were analyzed between Post-Transplantation (TPX) Day 2 and Week 8. The volume of GFP-immunoreactive donor cells, monitored by stereologic volumetry, remained constant between Post-TPX Weeks 1 and 8 and was similar in normoxic and hyperoxia-exposed recipients. Virtually all marrow-derived cells showed colocalization of GFP and the pan-macrophage marker, F4/80, by double immunofluorescence studies. Epithelial transdifferentiation was not seen. Marrow cell administration had adverse effects on somatic growth and alveolarization in normoxic mice, while no effects were discerned in hyperoxia-exposed recipients. Reexposure of marrow-treated animals to hyperoxia at P66 resulted in significant expansion of the donor-derived macrophage population. In conclusion, intranasal administration of unfractionated bone marrow cells to newborn mice does not achieve epithelial reconstitution, but establishes persistent alveolar macrophage chimerism. The predominantly adverse effects of marrow treatment in newborn lungs are likely due to macrophage-associated paracrine effects. While this model and route of cell therapy may not achieve epithelial reconstitution, the role of selected stem cell populations and/or alternate routes of administration for cell-based therapy in injured newborn lungs deserve further investigation.     

The cyclin-dependent kinase inhibitor p21 protects the lung from oxidative stress.

The lung is a major target tissue for oxidative stress, including hyperoxia used to relieve tissue hypoxia. Unfortunately, severe hyperoxia damages DNA, inhibits proliferation, and kills cells, resulting in morbidity and mortality. Although hyperoxia induces the tumor suppressor p53 and its downstream target, the cyclin-dependent kinase inhibitor p21(Cip1/WAF1/Sdi1) (p21), their role in pulmonary injury remains unknown. Using p53- and p21-deficient mice we demonstrate that hyperoxia induces p21 in the absence of p53, suggesting that previous conclusions that p53 does not modify hyperoxic lung injury cannot be extrapolated to p21. In fact, mean survival of p21-deficient mice decreased by 40% and was associated with terminal deoxyribonucleotidyl transferase-mediated deoxyuridine triphosphate-biotin nick-end labeling staining of alveolar debris, indicative of DNA fragmentation and cell death. Ultrastructural analyses revealed that alveolar endothelial and type I epithelial cells died rapidly by necrosis. Although hyperoxia decreased DNA replication in p21-wild-type lungs, it had no effect on replication in p21-deficient lungs. Our findings suggest that p21 protects the lung from oxidative stress, in part, by inhibiting DNA replication and thereby allowing additional time to repair damaged DNA. Our findings have implications for patients suffering from the toxic effects of supplemental oxygen therapies.     

Alteration of E-cadherin and beta-catenin in mouse vestibular epithelia during induction of apoptosis

The aim of this study was to examine if adhesion molecules had relation with degeneration and regeneration processes of mammalian vestibular epithelia. The distribution of E-cadherin and beta-catenin was immunohistochemically examined in normal and aminoglycoside-treated utricles of mice. E-cadherin and beta-catenin linearly expressed between epithelial cells in normal specimens. Aminoglycoside injury resulted in temporal alteration in distribution of these molecules with induction of apoptosis in hair cells. Degradation of both molecules was widely observed in vestibular epithelia, while some supporting cells exhibited accumulation of beta-catenin. After completion of induction of apoptosis, expression of these adhesion molecules was normal in distribution. These findings suggest that the E-cadherin-beta-catenin complex plays roles in degeneration and subsequent repair processes in vestibular epithelia affected by aminoglycosides.     

The effect of neonatal hyperoxia on the lung of p21Waf1/Cip1/Sdi1-deficient mice

Hyperoxia is an important factor in the development of bronchopulmonary dysplasia and is associated with growth arrest and impaired alveolar septal development in the neonatal lung. p21(Waf1/Cip1/Sdi1) (p21), a cyclin-dependent kinase inhibitor, acts as a checkpoint regulator in the cell cycle during periods of stress and is induced in neonatal lung during hyperoxia exposure. To determine if p21 protects against lung injury during neonatal lung development, we placed newborn p21 knockout (p21(-/-)) and p21 wild-type (p21(+/+)) mice in 85-90% O(2) for 4 d. We found that newborn p21(-/-) mice exposed to O(2) had decreased survival in hyperoxia compared with p21(+/+) mice (P < 0.01). At 2 and 6 wk after exposure to neonatal hyperoxia, p21(-/-) O(2) lung had significantly larger alveoli then p21(-/-) control lung, as assessed by mean alveolar size and mean linear intercept. Pulmonary function tests at 6 wk demonstrated increased lung volume in both p21(-/-) and p21(+/+) O(2) mice consistent with altered lung growth from neonatal exposure to hyperoxia. Antibodies to nitrotyrosine, a marker for oxidative stress revealed that at 2 and 6 wk of age, p21(-/-) O(2) lung had significantly more oxidative stress than p21(-/-) and p21(+/+) control and p21(+/+) O(2) lung. We therefore conclude that p21 confers some additional protection to the lung during exposure to neonatal hyperoxia. Furthermore, p21 may be important during recovery from lung injury because it is associated with lower levels of oxidative stress and increased oxidative stress may contribute to alveolar growth abnormalities in the p21(-/-) O(2) lung.     

Cyr61 protects against hyperoxia-induced cell death via Akt pathway in pulmonary epithelial cells

We have used gene expression profiling approaches to identify new molecular targets in various models of lung injury and human lung diseases. Among the many genes that are significantly induced in these studies, cysteine-rich61 (Cyr61) consistently ranks as one of the most significant genes. Here, we use the well-established model of hyperoxia to better understand the function of Cyr61 in acute lung injury. Cyr61, a stress-related immediate-early response gene, has known diverse functions involving angiogenesis, tumorigenesis, and wound repair. It belongs to the newly discovered "CCN" family containing six growth and regulatory factors. We showed that hyperoxia induces Cyr61 expression in a variety of pulmonary cells and in lung tissue in vivo. Loss of function studies, by suppressing Cyr61 expression by siRNA, accelerated lung epithelial cell death after hyperoxia. Gain of function studies, by overexpressing Cyr61, significantly conferred increased resistance to hyperoxia-induced cell death. Moreover, cells overexpressing Cyr61 induce Akt activation. Inhibition of Akt by siRNA abrogated the protective effects of Cyr61-overexpressing cells in response to hyperoxia. Taken together, our data demonstrate that Cyr61 expression provides cytoprotection in hyperoxia-induced pulmonary epithelial cell death and that this effect was in part mediated via the Akt signaling pathway.     

Hepatoma-derived growth factor is involved in lung remodeling by stimulating epithelial growth

Lung epithelial cells have an integral role in the maintenance of lung homeostasis; however, the regulatory mechanism thereof has not been fully clarified. Recently, hepatoma-derived growth factor (HDGF) was reported to be involved in organ development and remodeling through its mitogenic effect. We investigated the biological role of HDGF in lung remodeling. HDGF was more highly expressed in the lungs of idiopathic pulmonary fibrosis, chiefly in the epithelial cells, than in control nonfibrotic lungs. We also confirmed the expression of HDGF protein and mRNA in the lungs of bleomycin-instilled mice, mainly in the bronchial and alveolar epithelial cells, by immunohistochemical analysis and in situ hybridization. We found that recombinant HDGF promoted DNA synthesis in rat alveolar epithelial cells and A549 cells in vitro. Endogenous HDGF overexpressed by gene transfer was translocated into the nucleus and promoted the proliferation of A549 cells. In vivo intratracheal instillation of recombinant HDGF induced the proliferation of bronchial and alveolar epithelial cells without causing marked interstitial inflammation. These findings suggest that HDGF may be involved in lung remodeling after injury by promoting the proliferation of lung epithelial cells, probably in an autocrine manner.     

Mitochondrial biogenesis in the pulmonary vasculature during inhalational lung injury and fibrosis

Cell survival and injury repair is facilitated by mitochondrial biogenesis; however, the role of this process in lung repair is unknown. We evaluated mitochondrial biogenesis in the mouse lung in two injuries that cause acute inflammation and in two that cause chronic inflammation and pulmonary fibrosis. By using reporter mice that express green fluorescent protein (GFP) exclusively in mitochondria, we tracked mitochondrial biogenesis and correlated it with histologic lung injury, proliferation, and fibrosis. At 72 hours after acute LPS or continuous exposure to hyperoxia (Fio2, 1.0), the lungs showed diffuse infiltration by inflammatory cells in the alveolar region. In reporter mice, patchy new mitochondrial fluorescence was found in the alveolar region but was most prominent and unexpected in perivascular regions. At 14 days after instillation of asbestos or bleomycin, diffuse chronic inflammation had developed, and green fluorescence appeared in inflammatory cells in the expanded interstitium and was most intense in smooth muscle cells of pulmonary vessels. In all four lung injuries, mitochondrial fluorescence colocalized with mitochondrial superoxide dismutase, but not with proliferating cell nuclear antigen. These data indicate that vascular mitochondrial biogenesis is activated in diverse inhalational lung injuries along with oxidative stress. This finding indicates a unique and unexpected mechanism of metabolic adaptation to pulmonary fibrotic injuries.     

Foxp3+ regulatory T cells promote lung epithelial proliferation

Acute respiratory distress syndrome (ARDS) causes significant morbidity and mortality each year. There is a paucity of information regarding the mechanisms necessary for ARDS resolution. Foxp3⁺ regulatory T cells (Foxp3⁺ T_reg cells) have been shown to be an important determinant of resolution in an experimental model of lung injury. We demonstrate that intratracheal delivery of endotoxin (lipopolysaccharide) elicits alveolar epithelial damage from which the epithelium undergoes proliferation and repair. Epithelial proliferation coincided with an increase in Foxp3⁺ T_reg cells in the lung during the course of resolution. To dissect the role that Foxp3⁺ T_reg cells exert on epithelial proliferation, we depleted Foxp3⁺ T_reg cells, which led to decreased alveolar epithelial proliferation and delayed lung injury recovery. Furthermore, antibody-mediated blockade of CD103, an integrin, which binds to epithelial expressed E-cadherin decreased Foxp3⁺ T_reg numbers and decreased rates of epithelial proliferation after injury. In a non-inflammatory model of regenerative alveologenesis, left lung pneumonectomy, we found that Foxp3⁺ T_reg cells enhanced epithelial proliferation. Moreover, Foxp3⁺ T_reg cells co-cultured with primary type II alveolar cells (AT2) directly increased AT2 cell proliferation in a CD103-dependent manner. These studies provide evidence of a new and integral role for Foxp3⁺ T_reg cells in repair of the lung epithelium.     

NOX1 is responsible for cell death through STAT3 activation in hyperoxia and is associated with the pathogenesis of Acute Respiratory Distress Syndrome

Reactive oxygen species (ROS) contribute to alveolar cell death in Acute Respiratory Distress Syndrome (ARDS) and we previously demonstrated that NOX1-derived ROS contributed to hyperoxia-induced alveolar cell death in mice. The study investigates whether NOX1 expression is modulated in epithelial cells concomitantly to cell death and associated to STAT3 signaling in the exudative phase of ARDS. In addition, the role of STAT3 activation in NOX1-dependent epithelial cell death was confirmed by using a lung epithelial cell line and in mice exposed to hyperoxia. NOX1 expression, cell death and STAT3 staining were evaluated in the lungs of control and ARDS patients by immunohistochemistry. In parallel, a stable NOX1-silenced murine epithelial cell line (MLE12) and NOX1-deficient mice were used to characterize signalling pathways. In the present study, we show that NOX1 is detected in alveolar epithelial cells of ARDS patients in the exudative stage. In addition, increased alveolar epithelial cell death and phosphorylated STAT3 are observed in ARDS patients and associated with NOX1 expression. Phosphorylated STAT3 is also correlated with TUNEL staining. We also confirmed that NOX1-dependent STAT3 activation participates to alveolar epithelial cell death. Silencing and acute inhibition of NOX1 in MLE12 led to decreased cell death and cleaved-caspase 3 induced by hyperoxia. Additionally, hyperoxia-induced STAT3 phosphorylation is dependent on NOX1 expression and associated with cell death in MLE12 and mice. This study demonstrates that NOX1 is involved in human ARDS pathophysiology and is responsible for the damage occurring in alveolar epithelial cells at least in part via STAT3 signalling pathways.     

Deletion of caveolin-1 protects against oxidative lung injury via up-regulation of heme oxygenase-1

Acute lung injury (ALI) is a major cause of morbidity and mortality in critically ill patients. Hyperoxia causes lung injury in animals and humans, and is an established model of ALI. Caveolin-1, a major constituent of caveolae, regulates numerous biological processes, including cell death and proliferation. Here we demonstrate that caveolin-1-null mice (cav-1(-/-)) were resistant to hyperoxia-induced death and lung injury. Cav-1(-/-) mice sustained reduced lung injury after hyperoxia as determined by protein levels in bronchoalveolar lavage fluid and histologic analysis. Furthermore, cav-1(-/-) fibroblasts and endothelial cells and cav-1 knockdown epithelial cells resisted hyperoxia-induced cell death in vitro. Basal and inducible expression of the stress protein heme oxygenase-1 (HO-1) were markedly elevated in lung tissue or fibroblasts from cav-1(-/-) mice. Hyperoxia induced the physical interaction between cav-1 and HO-1 in fibroblasts assessed by co-immunoprecipitation studies, which resulted in attenuation of HO activity. Inhibition of HO activity with tin protoporphyrin-IX abolished the survival benefits of cav-1(-/-) cells and cav-1(-/-) mice exposed to hyperoxia. The cav-1(-/-) mice displayed elevated phospho-p38 mitogen-activated protein kinase (MAPK) and p38beta expression in lung tissue/cells under basal conditions and during hyperoxia. Treatment with SB202190, an inhibitor of p38 MAPK, decreased hyperoxia-inducible HO-1 expression in wild-type and cav-1(-/-) fibroblasts. Taken together, our data demonstrated that cav-1 deletion protects against hyperoxia-induced lung injury, involving in part the modulation of the HO-1-cav-1 interaction, and the enhanced induction of HO-1 through a p38 MAPK-mediated pathway. These studies identify caveolin-1 as a novel component involved in hyperoxia-induced lung injury.