THE ROLE OF STRETCH-INDUCED MECHANOTRANSDUCTION IN THE AIRWAY EPITHELIUM OF THE DEVELOPING LUNG

Date
2019-05
Journal Title
Journal ISSN
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Publisher
University of Delaware
Abstract
This study provides a quantitative methodology to measure and apply controlled strain to a cellular system as a means of studying embryonic lung development. The development of the type of model it provides will enable researchers to obtain new insight on lung mechanotransduction pathways and to determine the effects of various parameters of strain on developing lungs. An acrylic strain device was used and calibrated to deliver repeatable strain to the MLE-12 cell line. The device was coated with fibronectin for one hour, which enabled cell adhesion. Cells were then seeded and cultured overnight such that they reached 80- 90% confluency prior to the experiment. A novel LabView program was developed to operate the strain device and enabled control of parameters including frequency of stretch and amount of stretch to be applied. Assays were optimized for the MLE-12 cell line including: Fluo-8AM and K-Ras pulldown assay. Whole lung explants were analyzed to determined baseline frequency of lung contractions and kymographs were obtained. Cells were stretched at a frequency of 3.30 with a duty cycle of 3.33%, which corresponds to a 10 second stretch, once every 5 minutes. Cells were analyzed for proliferation with an Edu Assay Kit. Analysis was done using a novel MatLab script created by our lab and modified. A GCamp cell line was created in order to visualize calcium flux in real time during stretch. Effects were analyzed using ImageJ. Proliferation data did not follow the trends suggested by the literature and decreasing background fluorescence skewed fluorescence measurements in the GCamp dataset. Deviations from suggested trends were likely due to flaws in the device itself, as shown in calibration data. Overall, this study provides a methodology for studying lung development with the creation of a novel strain device. The methods described in this study could help to guide future experiments that will enable researchers to elucidate pathways of mechanotransduction in the developing lung and develop targeted therapeutics for developmental pulmonary diseases.
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Keywords
Neuroscience,Mechanotransduction, Lung
Citation