Showing papers by "Warren M. Zapol published in 2002"

Cytosolic phospholipase A2 in hypoxic pulmonary vasoconstriction

Abstract: Cytosolic phospholipase A2 (cPLA2) releases arachidonic acid (AA) from phospholipids in cell membranes. To assess the role of cPLA2 in hypoxic pulmonary vasoconstriction (HPV), we measured the increase in left lung pulmonary vascular resistance (LPVR) before and during hypoxia produced by left main stem bronchus occlusion (LMBO) in mice with and without a targeted deletion of the PLA2g4a gene that encodes cPLA2α. LMBO increased LPVR in cPLA2α+/+ mice but not in cPLA2α–/– mice. cPLA2α+/+ mice were better able to maintain systemic oxygenation during LMBO than were cPLA2α–/– mice. Administration of a cPLA2 inhibitor, arachidonyl trifluoromethyl ketone, blocked the LMBO-induced increase in LPVR in wild-type mice, while exogenous AA restored HPV in cPLA2α–/– mice. Intravenous angiotensin II infusion increased PVR similarly in cPLA2α+/+ and cPLA2α–/– mice. Inhibitors of cyclooxygenase or nitric oxide synthase restored HPV in cPLA2α–/– mice. Breathing 10% oxygen for 3 weeks produced less right ventricular hypertrophy in cPLA2α–/– than in cPLA2α+/+ mice, but restored HPV in cPLA2α–/– mice despite the continued absence of cPLA2 activity. These results indicate that cPLA2 contributes to the murine pulmonary vasoconstrictor response to hypoxia. Augmenting pulmonary vascular tone restores HPV in the absence of cPLA2 activity.

Cytosolic phospholipase A(2) in hypoxic pulmonary vasoconstriction.

Abstract: Cytosolic phospholipase A(2) (cPLA(2)) releases arachidonic acid (AA) from phospholipids in cell membranes. To assess the role of cPLA(2) in hypoxic pulmonary vasoconstriction (HPV), we measured the increase in left lung pulmonary vascular resistance (LPVR) before and during hypoxia produced by left main stem bronchus occlusion (LMBO) in mice with and without a targeted deletion of the PLA2g4a gene that encodes cPLA(2alpha). LMBO increased LPVR in cPLA(2alpha)(+/+) mice but not in cPLA(2alpha)(-/-) mice. cPLA(2alpha)(+/+) mice were better able to maintain systemic oxygenation during LMBO than were cPLA(2alpha)(-/-) mice. Administration of a cPLA(2) inhibitor, arachidonyl trifluoromethyl ketone, blocked the LMBO-induced increase in LPVR in wild-type mice, while exogenous AA restored HPV in cPLA(2alpha)(-/-) mice. Intravenous angiotensin II infusion increased PVR similarly in cPLA(2alpha)(+/+) and cPLA(2alpha)(-/-) mice. Inhibitors of cyclooxygenase or nitric oxide synthase restored HPV in cPLA(2alpha)(-/-) mice. Breathing 10% oxygen for 3 weeks produced less right ventricular hypertrophy in cPLA(2alpha)(-/-) than in cPLA(2alpha)(+/+) mice, but restored HPV in cPLA(2alpha)(-/-) mice despite the continued absence of cPLA(2) activity. These results indicate that cPLA(2) contributes to the murine pulmonary vasoconstrictor response to hypoxia. Augmenting pulmonary vascular tone restores HPV in the absence of cPLA(2) activity.

Reactive Oxygen Species Scavengers Attenuate Endotoxin-induced Impairment of Hypoxic Pulmonary Vasoconstriction in Mice

Abstract: BackgroundSepsis and endotoxemia attenuate hypoxic pulmonary vasoconstriction (HPV), thereby impairing systemic oxygenation. Reactive oxygen species (ROS) are implicated in the pathogenesis of sepsis-induced lung injury. The authors investigated whether treatment with scavengers of ROS prevents impa

Myeloperoxidase-associated tyrosine nitration after intratracheal administration of lipopolysaccharide in rats.

Abstract: Background: Previous studies have shown that lipopolysaccharide-induced inflammation in the lung results in tyrosine nitration. The objective of this study was to evaluate the contribution of myeloperoxidase and peroxynitrite pathway to the tyrosine nitration in lipopolysaccharide-administered lungs of rats that were otherwise untreated or leukocyte-depleted by cyclophosphamide or received inhaled nitric oxide (NO). Methods: The authors analyzed the immunoreactivity of inducible nitric oxide synthase (iNOS), nitrotyrosine (a product of the myeloperoxidase or peroxynitrite pathway), and chlorotyrosine (a byproduct of the myeloperoxidase pathway) by use of specific antibodies. The number of neutrophils in bronchoalveolar lavage fluid (BALF) and levels of myeloperoxidase activity in lung homogenates were also measured. Results: Lipopolysaccharide enhanced the immunoreactivity of iNOS, nitrotyrosine, and chlorotyrosine in alveolar wall cells, alveolar macrophages, and neutrophils. Leukocyte depletion by cyclophosphamide and inhibition of leukocyte accumulation in the lungs by NO inhalation did not eliminate the increase in iNOS immunoreactivity in alveolar macrophages after lipopolysaccharide treatment, but nitrotyrosine and chlorotyrosine were not produced in these cells. Tyrosine nitration in response to lipopolysaccharide was associated with increases in neutrophil count in BALF and in myeloperoxidase activity in lung homogenates, whereas NO inhalation suppressed the neutrophil count in BALF and reduced tyrosine nitration and chlorination. Conclusions: These findings suggest that myeloperoxidase pathway has a role in tyrosine nitration in the lungs of lipopolysaccharide-treated rats, and that NO inhalation during early phase of inflammation does not increase but rather decreases tyrosine nitration and chlorination, possibly by reducing neutrophil sequestration.

Radical scavengers protect murine lungs from endotoxin-induced hyporesponsiveness to inhaled nitric oxide.

Abstract: Background: Sepsis is associated with an impaired pulmonary vasodilator response to inhaled nitric oxide (NO). A combination of NO and other inflammatory mediators appears to be responsible for endotoxin-induced pulmonary vascular hyporesponsiveness to inhaled NO. The authors investigated whether scavengers of reactive oxygen species could preserve inhaled NO responsiveness in endotoxin-challenged mice. Methods: The vasorelaxation to inhaled NO was studied in isolated, perfused, and ventilated lungs obtained from mice 16 h after an intraperitoneal challenge with saline or 50 mg/kg Escherichia coli lipopolysaccharide. In some mice, challenge with saline or lipopolysaccharide was followed by intraperitoneal administration of N-acetylcysteine, dimethylthiourea, EUK-8, or polyethylene glycol-conjugated catalase. Results: The pulmonary vasodilator response of U46619-pre-constricted isolated lungs to ventilation with 0.4, 4, and 40 ppm inhaled NO in lipopolysaccharide-challenged mice was reduced to 32, 43, and 60%, respectively, of that observed in saline-challenged mice (P < 0.0001). Responsiveness to inhaled NO was partially preserved in lipopolysaccharide-challenged mice treated with a single dose of N-acetylcysteine (150 or 500 mg/kg) or 20 U/g polyethylene glycol-conjugated catalase (all P < 0.05 vs. lipopolysaccharide alone). Responsiveness to inhaled NO was fully preserved by treatment with either dimethylthiourea, EUK-8, two doses of N-acetylcysteine (150 mg/kg administered 3.5 h apart), or 100 U/g polyethylene glycol-conjugated catalase (all P < 0.01 vs. lipopolysaccharide alone). Conclusions: When administered to mice concurrently with lipopolysaccharide challenge, reactive oxygen species scavengers prevent impairment of pulmonary vasodilation to inhaled NO. Therapy with scavengers of reactive oxygen species may provide a means to preserve pulmonary vasodilation to inhaled NO in sepsis-associated acute lung injury.