Targeting CEBPA to restore cellular identity and tissue homeostasis in pulmonary fibrosis
Qi Tan, Jack H. Wellmerling, Shengren Song, Sara R. Dresler, Jeffrey A. Meridew, Kyoung M. Choi, Yong Li, Y.S. Prakash, Daniel J. Tschumperlin
Qi Tan, Jack H. Wellmerling, Shengren Song, Sara R. Dresler, Jeffrey A. Meridew, Kyoung M. Choi, Yong Li, Y.S. Prakash, Daniel J. Tschumperlin
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Research Article Pulmonology Stem cells

Targeting CEBPA to restore cellular identity and tissue homeostasis in pulmonary fibrosis

Abstract

Fibrosis in the lung is thought to be driven by epithelial cell dysfunction and aberrant cell-cell interactions. Unveiling the molecular mechanisms of cellular plasticity and cell-cell interactions is imperative to elucidating lung regenerative capacity and aberrant repair in pulmonary fibrosis. By mining publicly available RNA-Seq data sets, we identified loss of CCAAT enhancer-binding protein alpha (CEBPA) as a candidate contributor to idiopathic pulmonary fibrosis (IPF). We used conditional KO mice, scRNA-Seq, lung organoids, small-molecule inhibition, and potentially novel gene manipulation methods to investigate the role of CEBPA in lung fibrosis and repair. Long-term (6 months or more) of Cebpa loss in AT2 cells caused spontaneous fibrosis and increased susceptibility to bleomycin-induced fibrosis. Cebpa knockout (KO) in these mice significantly decreased AT2 cell numbers in the lung and reduced expression of surfactant homeostasis genes, while increasing inflammatory cell recruitment as well as upregulating S100a8/a9 in AT2 cells. In vivo treatment with an S100A8/A9 inhibitor alleviated experimental lung fibrosis. Restoring CEBPA expression in lung organoids ex vivo and during experimental lung fibrosis in vivo rescued CEBPA deficiency–mediated phenotypes. Our study establishes a direct mechanistic link between CEBPA repression, impaired AT2 cell identity, disrupted tissue homeostasis, and lung fibrosis.

Authors

Qi Tan, Jack H. Wellmerling, Shengren Song, Sara R. Dresler, Jeffrey A. Meridew, Kyoung M. Choi, Yong Li, Y.S. Prakash, Daniel J. Tschumperlin

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Figure 3

Single-cell transcriptome analysis reveals disrupted epithelial homeostasis.

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Single-cell transcriptome analysis reveals disrupted epithelial homeosta...
(A) UMAP plot of lung samples from CebpaΔSftpc (n = 3) and Cebpafl/fl (n = 3) mice showing major cellular clusters, each representing a different cell type. (B) Dot plot for AT1 and AT2 cells obtained from CebpaΔSftpc versus Cebpafl/fl mice showing (a) percentage of cells expressing a marker gene, proportional to dot size, and (b) average expression level of that gene based on unique molecular identifier (UMI) counts, accounting for differences in total UMI counts and cell-type frequencies. (C) Heatmap showing top downregulated genes in AT2 cells from CebpaΔSftpc versus Cebpafl/fl mice. (D) UMAP plot of lung epithelial cells from CebpaΔSftpc versus Cebpafl/fl mice. (E) UMAP plot of S100a8/a9 expression in the lung epithelial cells. (F) Heatmap showing top upregulated genes in AT2 cells from CebpaΔSftpc versus Cebpafl/fl mice. (G) Graph of transcriptional noise (represented by the Fano factor) in epithelial cells from CebpaΔSftpc versus Cebpafl/fl mice. (H) Transcriptional noise plotted against log2 fold change for genes differentially expressed between CebpaΔSftpc and Cebpafl/fl mouse epithelial cells. (I) UMAP plot of pseudotime single-cell trajectory analysis in epithelial cells from CebpaΔSftpc versus Cebpafl/fl mice. Data were analyzed using an unpaired, 2-tailed Student’s t test. ****P < 0.0001.