Abstract A population of pathologic fibroblasts has been identified in several human fibrotic lung diseases, including IPF. These cells, marked by high expression of collagen triple-helix repeat containing 1 (CTHRC1), display an invasive phenotype and aggressively deposit extracellular matrix. The goal of this study was to identify transcriptional regulators of the CTHRC1+ pathologic fibroblast state. We analyzed published single-cell RNA sequencing data of IPF and control lungs to predict transcription factor activity in CTHRC1+ fibroblasts, which led us to hypothesize that transcription factors in the nuclear factor of activated T-cells (NFAT) family may contribute to the pathologic fibroblast state. To test whether NFAT family members promote and/or maintain pathologic fibroblasts, we silenced each cytosol-localized NFAT (NFATc1-4) in lung fibroblasts from IPF donors (passage 3-6, N = 5 donors) and measured expression of key NFAT target genes related to fibrosis using qPCR. NFATC1 silencing significantly reduced expression of CTHRC1, SERPINE1, FN1, HAS2, and TNC, whereas other computationally predicted regulators showed little effect. Our computational analysis also predicted high activator protein 1 (AP-1) activity in pathologic fibroblasts, which interestingly has been found to act in concert with NFATs to promote an effector response in T-cells. Thus, we hypothesized that NFAT:AP-1 signaling may be involved in lung fibroblast activation. To test this hypothesis, we employed a small molecule inhibitor of NFAT:AP-1 complex formation on DNA (“Compound 10”, 25-50 µM). NFAT:AP-1 inhibition significantly reduced expression of fibrillar collagens COL1A1 and COL3A1, as well as CTHRC1 in primary IPF lung fibroblasts. Additionally, NFAT:AP-1 inhibition prevented TGF-β-mediated increase of several fibrosis-related NFATc1 targets. Aside from CTHRC1, NFAT:AP-1 inhibition led to decrease in a different set of NFATc1 targets than NFATc1 silencing, suggesting a potentially complex relationship between NFATc1 and AP-1 in fibroblast gene regulation. Finally, in mouse precision cut lung slices (PCLS) stimulated with a fibrosis-inducing cocktail ex vivo, NFAT:AP-1 inhibition prevented increased expression of Col1a1 and Cthrc1. Taken together, these studies suggest that NFATc1, together with AP-1, is involved in fibrogenic activation of pathological fibroblasts. Ongoing and future experiments will determine the roles of these signaling mechanisms in matrix deposition and contraction, as well as fibroblast invasion using human fibroblasts and PCLS models. Furthermore, we aim to determine how mechanical forces and soluble factors encountered in IPF lungs promote NFAT signaling in fibroblasts. This abstract is funded by: NHLBI, Pulmonary Fibrosis Foundation
Wellmerling et al. (Fri,) studied this question.
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