Abstract Rationale The governing mechanisms of lung regeneration are still poorly understood. Studies have observed the lung’s regenerative capacity using the pneumonectomy (PNX) model, where removal of the left lung stimulates compensatory growth and neoalveolarization. However, this process is inhibited if a physical object is used to replace the extracted tissue, demonstrating that the lung can sense the available space and regenerate in response. The mechanism of this mechanosensing is unknown. As outermost tissue layer of the lung, the pulmonary mesothelium is well situated to sense the surrounding environment. We and others have hypothesized that the mesothelium can become activated in cases of injury or regeneration, but this has not been fully explored. Understanding the mechanisms controlling neoalveolarizaiton may be key to unlocking the lung’s natural regenerative capacity in humans. Methods LSL-RFP(+/-)). Following PNX, we collected the lineage-labeled cells along with the CD326+ and CD326-/CD45-/CD31- populations and performed scRNA-sequencing. As quantified by flow-cytometry, the number of RFP+ cells increased following PNX, indicating proliferation of the mesothelium. Clustering analysis elucidated the emergence of 3 activated clusters of mesothelium following PNX, representing 12.9% of the RFP+ population in Sham and 66% in PNX. These activated cells exhibited decreased expression of mesothelial hallmarks and increased expression of extracellular matrix and epithelial-to-mesenchymal transition genes. Using immunofluorescence and confocal microscopy, we observed lineage-labeled mesothelium deep within the parenchyma after PNX. We observed none or singular invaded mesothelium in no-procedure control animals and only minimal occurrence in animals exposed to Sham surgery. Compared to Sham controls, PNX post-surgical (D)ay 3, D7, and D14 had 8.5, 32.7, and 9.2-fold more cells, respectively, in the parenchyma. Moreover, in aged (18 month) mice, where regeneration is known to be significantly reduced, we likewise observed minimal mesothelial invasion following PNX. These cells were often found near or directly wrapping around progenitors of the alveolar epithelium, AT2 cells, whose proliferation is essential to neoalveolarization. Using time-lapse microscopy of precision cut lung slices, we observed the invading mesothelial cells to be highly dynamic, sending out multiple transient protrusions and interacting with neighboring cells. Conclusion Together these data support strong and potentially functional interactions between activated and invading mesothelial cells and lung regeneration following PNX. This abstract is funded by: NIH
Gilbert et al. (Fri,) studied this question.
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