B Müller1, H Garn, R Hochscheid. 1. Laboratory of Respiratory Cell Biology, Department of Internal Medicine, Philipps University of Marburg, 35033 Marburg, Germany. bmueller@mailer.uni-marburg.de
Abstract
BACKGROUND: Surfactant synthesis and secretion has been shown to be impaired in type II cells from diseased lungs. The mechanism of surfactant lipid recycling, which is an important physiological process in surfactant treatment, was studied in type II cells isolated from injured lungs. METHODS: Different stages of lung injury were induced by exposing rats to 10 ppm nitrogen dioxide (NO(2)) for 3, 20, and 28 days. Type II cells were isolated from these lungs and recycling of (3)H-DPPC labelled surfactant-like liposomes was studied in vitro. RESULTS: Uptake of liposomes (150 micro g/ml) for 20 minutes in the absence and presence of surfactant protein-A (SP-A, 5 micro g/ml) was higher in cells from NO(2) injured lungs (63-78%) than in control cells. There was no difference in liposome uptake between the groups with NO(2) exposure of different duration. After liposome uptake, most of the internalised label remained in the phosphatidylcholine (PC) fraction and increased with duration of exposure to NO(2). After 20 minutes internalisation, cells were allowed to resecrete lipids for a further 20 minute period. In cells from controls and from all stages of lung injury, liposomes that had been internalised in the presence of SP-A were resecreted to a greater extent than those internalised without SP-A. However, cells from lungs exposed to NO(2) resecreted less lipid than cells from control lungs. Again, there was no difference in resecretion between the groups with NO(2) exposure of different duration. CONCLUSION: Type II cells from injured lungs internalise more surfactant-like liposomes than cells from controls, suggesting a putative therapeutic significance to cope with limited alveolar surfactant pools in lung injury.
BACKGROUND: Surfactant synthesis and secretion has been shown to be impaired in type II cells from diseased lungs. The mechanism of surfactant lipid recycling, which is an important physiological process in surfactant treatment, was studied in type II cells isolated from injured lungs. METHODS: Different stages of lung injury were induced by exposing rats to 10 ppm nitrogen dioxide (NO(2)) for 3, 20, and 28 days. Type II cells were isolated from these lungs and recycling of (3)H-DPPC labelled surfactant-like liposomes was studied in vitro. RESULTS: Uptake of liposomes (150 micro g/ml) for 20 minutes in the absence and presence of surfactant protein-A (SP-A, 5 micro g/ml) was higher in cells from NO(2) injured lungs (63-78%) than in control cells. There was no difference in liposome uptake between the groups with NO(2) exposure of different duration. After liposome uptake, most of the internalised label remained in the phosphatidylcholine (PC) fraction and increased with duration of exposure to NO(2). After 20 minutes internalisation, cells were allowed to resecrete lipids for a further 20 minute period. In cells from controls and from all stages of lung injury, liposomes that had been internalised in the presence of SP-A were resecreted to a greater extent than those internalised without SP-A. However, cells from lungs exposed to NO(2) resecreted less lipid than cells from control lungs. Again, there was no difference in resecretion between the groups with NO(2) exposure of different duration. CONCLUSION: Type II cells from injured lungs internalise more surfactant-like liposomes than cells from controls, suggesting a putative therapeutic significance to cope with limited alveolar surfactant pools in lung injury.
Authors: Heinz Fehrenbach; Gregor Zimmermann; Ellen Starke; Vlad A Bratu; Dominik Conrad; Ali O Yildirim; Antonia Fehrenbach Journal: Thorax Date: 2007-01-18 Impact factor: 9.139
Authors: Diletta Scaccabarozzi; Katrien Deroost; Natacha Lays; Fausta Omodeo Salè; Philippe E Van den Steen; Donatella Taramelli Journal: PLoS One Date: 2015-12-01 Impact factor: 3.240