Mechanomemory of pulmonary fibroblasts demonstrates reversibility of transcriptomics and contraction phenotypes.

Fibroblasts are cells responsible for producing extracellular matrix (ECM) components, which provides physical support for organs. Although these mesenchymal cells are responsive to mechanical cues in their environment, the permanence of these mechanophenotypes is not well defined. We investigated the mechanomemory of lung fibroblasts and determined how switching culture conditions modulate cell responses and function. Primary murine lung fibroblasts were isolated and cultured on 2D tissue culture plates or within 3D collagen hydrogels and were then passaged within the same or opposite culture condition to assess changes in gene expression, protein production, fibroblast subpopulation, contractile behavior, and traction forces. Compared to fibroblasts isolated on 2D tissue culture plates, fibroblasts within 3D hydrogels exhibited a decreased activation phenotype including reduced contraction profiles, diminished cell traction forces and decreased αSMA gene expression. Cells initially isolated via 2D culture and then cultured in 3D hydrogels exhibited a reversal in activation phenotype as measured by gene expression and contraction profiles. Bulk RNAseq identified groups of genes that exhibit reversible and non-reversable expression patterns. Overall, these findings indicate that lung fibroblasts have a mechanical memory that is altered by culture condition and can be reversible through precondition of cells within a softer 3D microenvironment.