Clonal expansion of alveolar fibroblast progeny drives pulmonary fibrosis in mouse models
Christopher Molina, Tatsuya Tsukui, Imran S. Khan, Xin Ren, Wenli Qiu, Michael Matthay, Paul Wolters, Dean Sheppard
Christopher Molina, Tatsuya Tsukui, Imran S. Khan, Xin Ren, Wenli Qiu, Michael Matthay, Paul Wolters, Dean Sheppard
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Research Article Cell biology Pulmonology

Clonal expansion of alveolar fibroblast progeny drives pulmonary fibrosis in mouse models

Abstract

Pulmonary fibrosis (PF) has been called a fibroproliferative disease, yet the functional importance of proliferating fibroblasts to PF has not been systematically examined. In response to alveolar injury, quiescent alveolar fibroblasts differentiate into fibrotic fibroblasts that express high amounts of collagens. However, what role, if any, proliferation plays in the accumulation of fibrotic fibroblasts has remained unclear. Using 5-ethynyl-2′-deoxyuridine (EdU) incorporation, genetic lineage tracing, and single-cell RNA-Seq, we delineated the proliferation dynamics of lung fibroblasts during post-injury fibrogenesis. We found substantial DNA replication in progeny of alveolar fibroblasts in 2 independent models of PF. Lineage labeling revealed clonal expansion of these fibroblast descendants principally in regions of fibrotic remodeling. The transcriptome of proliferating fibroblasts closely resembled that of fibrotic fibroblasts, suggesting that fibroblasts can first differentiate into fibrotic fibroblasts and then proliferate. Genetic ablation of proliferating fibroblasts and selective inhibition of cytokinesis in alveolar fibroblast descendants significantly mitigated PF and rescued lung function. Furthermore, fibroblasts in precision-cut lung slices from human fibrotic lungs exhibited higher proliferation rates than did those in nondiseased lungs. Together, this work establishes fibroblast proliferation as a critical driver of PF and suggests that specifically targeting fibroblast proliferation could be a new therapeutic strategy for fibrotic diseases.

Authors

Christopher Molina, Tatsuya Tsukui, Imran S. Khan, Xin Ren, Wenli Qiu, Michael Matthay, Paul Wolters, Dean Sheppard

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Figure 2

Cthrc1+ fibrotic fibroblasts are the dominant proliferating fibroblast subtype in fibrotic lungs.

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Cthrc1+ fibrotic fibroblasts are the dominant proliferating fibroblast s...
(A) Potential pathways of fibroblast proliferation and differentiation in fibrotic lungs (B) UMAP visualization from Tsukui et al. (23), showing fibroblasts harvested from Scube2-CreER R26-Ai14 mice at days 0, 7, 14, and 21 after bleomycin injury. The proliferating fibroblast cluster was subsetted and reclustered for downstream analysis. Figure 2A was partially created in BioRender (https://BioRender.com/b92n121). (C) Most proliferating fibroblasts were lineage labeled by tdTomato. (D) Maximal fibroblast proliferation was observed at day 7 after bleomycin injury. (E) Reclustering identified 3 distinct proliferating fibroblast subpopulations: fibrotic, inflammatory, and indeterminate fibroblasts. (F) Fibrotic fibroblasts consistently emerged as the predominant proliferating type across all time points. (G) Bubble plot and feature plots (H and I) displaying marker gene expression profiles across subtypes. (J and K) Spearman correlation and scatter plot analyses confirmed the transcriptomic similarities between proliferating and nonproliferating fibrotic fibroblasts. Dashed gray line ± 0.5 average log2 FC; solid gray line ± 1 average log2 FC. (LN) Longitudinal tracking of Cthrc1+ fibrotic fibroblast clonal expansion in bleomycin-treated lungs, visualized by confocal microscopy using cleared thick sections, which showed substantial cellular proliferation within fibrotic regions. Cthrc1-CreER labeled a small percentage of lineage+ cells at baseline, so only cytoplasmic YFP+ and cytoplasmic RFP+ clones with clear fibroblast morphology were quantified. Scale bar: 30 μm.