PGF signaling drives fibrotic remodeling and fibroblast population dynamics in mice
Luis R. Rodriguez, … , Garret A. FitzGerald, Michael F. Beers
Luis R. Rodriguez, … , Garret A. FitzGerald, Michael F. Beers
Published November 7, 2023
Citation Information: JCI Insight. 2023;8(24):e172977. https://doi.org/10.1172/jci.insight.172977.
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Research Article Pulmonology

PGF signaling drives fibrotic remodeling and fibroblast population dynamics in mice

Abstract

Idiopathic pulmonary fibrosis (IPF) is a chronic parenchymal lung disease characterized by repetitive alveolar cell injury, myofibroblast proliferation, and excessive extracellular matrix deposition for which unmet need persists for effective therapeutics. The bioactive eicosanoid, prostaglandin F2α, and its cognate receptor FPr (Ptgfr) are implicated as a TGF-β1–independent signaling hub for IPF. To assess this, we leveraged our published murine PF model (IER-SftpcI73T) expressing a disease-associated missense mutation in the surfactant protein C (Sftpc) gene. Tamoxifen-treated IER-SftpcI73T mice developed an early multiphasic alveolitis and transition to spontaneous fibrotic remodeling by 28 days. IER-SftpcI73T mice crossed to a Ptgfr-null (FPr–/–) line showed attenuated weight loss and gene dosage–dependent rescue of mortality compared with FPr+/+ cohorts. IER-SftpcI73T/FPr–/– mice also showed reductions in multiple fibrotic endpoints for which administration of nintedanib was not additive. Single-cell RNA-Seq, pseudotime analysis, and in vitro assays demonstrated Ptgfr expression predominantly within adventitial fibroblasts, which were reprogrammed to an “inflammatory/transitional” cell state in a PGF2α /FPr-dependent manner. Collectively, the findings provide evidence for a role for PGF2α signaling in IPF, mechanistically identify a susceptible fibroblast subpopulation, and establish a benchmark effect size for disruption of this pathway in mitigating fibrotic lung remodeling.

Authors

Luis R. Rodriguez, Soon Yew Tang, Willy Roque Barboza, Aditi Murthy, Yaniv Tomer, Tian-Quan Cai, Swati Iyer, Katrina Chavez, Ujjalkumar Subhash Das, Soumita Ghosh, Charlotte H. Cooper, Thalia T. Dimopoulos, Apoorva Babu, Caitlin Connelly, Garret A. FitzGerald, Michael F. Beers

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Figure 6

Ptgfr deficiency alters fibroblast lineage trajectory through fibrotic remodeling.

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Ptgfr deficiency alters fibroblast lineage trajectory through fibrotic ...
(A) UMAP analysis of reclustered alveolar, transitional/inflammatory, and fibrotic fibroblasts with superimposed vector from pseudotime trajectory analysis reveals no Ptgfr-dependent effect on terminal node. (B) UMAP analysis of reclustered adventitial, transitional/inflammatory, and fibrotic fibroblasts with superimposed vector from pseudotime trajectory analysis demonstrates a Ptgfr-dependent effect on terminal node. In IER-SftpcI73T/Ptgfr–/–, the terminal node is found in the transitional/inflammatory cluster, while SftpcI73T/Ptgfr+/+ samples have a vector terminating in the fibrotic cluster. (C) Comparative analysis of gene expression within the fibrotic cluster of IER-SftpcI73T/Ptgfr+/+ and IER-SftpcI73T/Ptgfr–/– mice is presented by gradient gene expression dot plots. Genes seen in dot plots were combined to generate a score and plotted in a box plot. Marker genes associated with the transitional/inflammatory cluster are comparatively elevated in IER-SftpcI73T/Ptgfr–/– mice, while fibrotic marker genes are elevated in the IER-SftpcI73T/Ptgfr+/+ mice. All comparisons achieved statistical significance. (D) KEGG pathway enrichment analysis comparing the fibrotic clusters identifies multiple pathways associated with cytoskeletal rearrangement, mesenchymal activation, and TGF-β signaling that are upregulated in IER-SftpcI73T/Ptgfr+/+ mice. (E) Measurement of BALF TGF-β1 via ELISA demonstrates a significant decrease in IER-SftpcI73T/Ptgfr–/– mice (n = 18) as compared with IER-SftpcI73T/Ptgfr+/+ mice (n = 18). Ordinary 1-way ANOVA testing was performed. *P < 0.05.