Inhibiting lung elastase activity enables lung growth in mechanically ventilated newborn mice

Inhibiting lung elastase activity enables lung growth in mechanically ventilated newborn mice

Mechanical ventilation with O₂-rich gas (MV-O₂) offers life-saving treatment for respiratory failure, but also promotes lung injury. We previously reported that MV-O2 of newborn mice increased lung elastase activity, causing elastin degradation and redistribution of elastic fibers from septal tips t...

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Bibliographic Details
Published in:American journal of respiratory and critical care medicine Vol. 184; no. 5; pp. 537 - 546
Main Authors: Hilgendorff, Anne, Parai, Kakoli, Ertsey, Robert, Jain, Noopur, Navarro, Edwin F, Peterson, Joanna L, Tamosiuniene, Rasa, Nicolls, Mark R, Starcher, Barry C, Rabinovitch, Marlene, Bland, Richard D
Format: Journal Article
Language:English
Published: United States American Thoracic Society 01-09-2011
Subjects:
Animals
Animals, Newborn
Apoptosis
Disease Models, Animal
Elafin - pharmacology
Lung - drug effects
Lung - enzymology
Lung - growth & development
Mice
Organogenesis - drug effects
Pancreatic Elastase - antagonists & inhibitors
Pancreatic Elastase - metabolism
Protease Inhibitors - pharmacology
Respiration, Artificial
Respiratory Insufficiency - enzymology
Respiratory Insufficiency - physiopathology
Respiratory Insufficiency - therapy
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Summary:Mechanical ventilation with O₂-rich gas (MV-O₂) offers life-saving treatment for respiratory failure, but also promotes lung injury. We previously reported that MV-O2 of newborn mice increased lung elastase activity, causing elastin degradation and redistribution of elastic fibers from septal tips to alveolar walls. These changes were associated with transforming growth factor (TGF)-β activation and increased apoptosis leading to defective alveolarization and lung growth arrest, as seen in neonatal chronic lung disease. To determine if intratracheal treatment of newborn mice with the serine elastase inhibitor elafin would prevent MV-O₂-induced lung elastin degradation and the ensuing cascade of events causing lung growth arrest. Five-day-old mice were treated via tracheotomy with recombinant human elafin or vehicle (lactated-Ringer solution), followed by MV with 40% O₂ for 8-24 hours; control animals breathed 40% O₂ without MV. At study's end, lungs were harvested to assess key variables noted below. MV-O₂ of vehicle-treated pups increased lung elastase and matrix metalloproteinase-9 activity when compared with unventilated control animals, causing elastin degradation (urine desmosine doubled), TGF-β activation (pSmad-2 tripled), and apoptosis (cleaved-caspase-3 increased 10-fold). Quantitative lung histology showed larger and fewer alveoli, greater inflammation, and scattered elastic fibers. Elafin blocked these MV-O₂-induced changes. Intratracheal elafin, by blocking lung protease activity, prevented MV-O₂-induced elastin degradation, TGF-β activation, apoptosis, and dispersion of matrix elastin, and attenuated lung structural abnormalities noted in vehicle-treated mice after 24 hours of MV-O₂. These findings suggest that elastin breakdown contributes to defective lung growth in response to MV-O₂ and might be targeted therapeutically to prevent MV-O₂-induced lung injury.
ISSN:1073-449X
1535-4970
DOI:10.1164/rccm.201012-2010OC