BACKGROUND: Static stretch is frequently observed in the lung. Both static stretch and cyclic stretch can induce cell death and Na(+)/K(+)-ATPase trafficking, but stretch-induced alveolar epithelial cell (AEC) functions are much less responsive to static than to cyclic stretch. AEC remodeling under static stretch may be partly explained. OBJECTIVE: The aim of this study was to explore the AEC remodeling and functional changes under static stretch conditions. METHOD: We used A549 cells as a model of AEC type II cells. We assessed F-actin content and cell viability by fluorescence staining at various static-stretch magnitudes and time points. Specifically, we used scanning electron microscopy to explore the possible biological mechanisms used by A549 cells to 'escape' static-stretch-induced injury. Finally, we measured choline cytidylyltransferase-alpha (CCT alpha) mRNA and protein by real-time PCR and Western blot to evaluate cellular secretory function. RESULTS: The results showed that the magnitude of static stretch was the primary determinant of static-stretch-induced cell death and cytoskeleton organization, but an extended duration of high static deformation/stretch (37% change in surface area) had no cumulative effects on cell death and cytoskeleton organization. AEC remodeling (expansion-contraction-reexpansion) under static stretch conditions may explain this interesting phenomenon partly. After cell remodeling, CCT alpha expression in A549 cells was influenced not only by stretch magnitude but also by stretch time. CONCLUSION: Under static stretch conditions, A549 cells undergo morphological and functional changes. They can survive stress failure from overstretching by remodeling their body to 'escape' the injury. During this complex course of remodeling, cellular function was partly damaged. (c) 2009 S. Karger AG, Basel.
BACKGROUND: Static stretch is frequently observed in the lung. Both static stretch and cyclic stretch can induce cell death and Na(+)/K(+)-ATPase trafficking, but stretch-induced alveolar epithelial cell (AEC) functions are much less responsive to static than to cyclic stretch. AEC remodeling under static stretch may be partly explained. OBJECTIVE: The aim of this study was to explore the AEC remodeling and functional changes under static stretch conditions. METHOD: We used A549 cells as a model of AEC type II cells. We assessed F-actin content and cell viability by fluorescence staining at various static-stretch magnitudes and time points. Specifically, we used scanning electron microscopy to explore the possible biological mechanisms used by A549 cells to 'escape' static-stretch-induced injury. Finally, we measured choline cytidylyltransferase-alpha (CCT alpha) mRNA and protein by real-time PCR and Western blot to evaluate cellular secretory function. RESULTS: The results showed that the magnitude of static stretch was the primary determinant of static-stretch-induced cell death and cytoskeleton organization, but an extended duration of high static deformation/stretch (37% change in surface area) had no cumulative effects on cell death and cytoskeleton organization. AEC remodeling (expansion-contraction-reexpansion) under static stretch conditions may explain this interesting phenomenon partly. After cell remodeling, CCT alpha expression in A549 cells was influenced not only by stretch magnitude but also by stretch time. CONCLUSION: Under static stretch conditions, A549 cells undergo morphological and functional changes. They can survive stress failure from overstretching by remodeling their body to 'escape' the injury. During this complex course of remodeling, cellular function was partly damaged. (c) 2009 S. Karger AG, Basel.