CFTR negatively reprograms Th2 cell responses, and CFTR potentiation restrains allergic airway inflammation
Mark Rusznak, … , R. Stokes Peebles Jr., Daniel P. Cook
Mark Rusznak, … , R. Stokes Peebles Jr., Daniel P. Cook
Published March 25, 2025
Citation Information: JCI Insight. 2025;10(9):e191098. https://doi.org/10.1172/jci.insight.191098.
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Research Article Immunology Inflammation Pulmonology

CFTR negatively reprograms Th2 cell responses, and CFTR potentiation restrains allergic airway inflammation

Abstract

Type 2 inflammatory diseases, including asthma, sinusitis, and allergic bronchopulmonary aspergillosis, are common in cystic fibrosis (CF). CD4+ Th2 cells promote these diseases through secretion of IL-4, IL-5, and IL-13. Whether the CF transmembrane conductance regulator (CFTR), the mutated protein in CF, has a direct effect on Th2 development is unknown. Using murine models of CFTR deficiency and human CD4+ T cells, we show that CD4+ T cells expressed Cftr transcript and CFTR protein following activation. Loss of T cell CFTR expression increased Th2 cytokine production compared with control cells. Mice with CFTR-deficient T cells developed increased allergic airway disease to Alternaria alternata extract compared with control mice. Culture of CFTR-deficient Th2 cells demonstrated increased IL-4Rα expression and increased sensitivity to IL-4 with greater induction of GATA3 and IL-13 compared with control Th2 cell cultures. The CFTR potentiator ivacaftor reduced allergic inflammation and type 2 cytokine secretion in bronchoalveolar lavage of humanized CFTR mice following Alternaria alternata extract challenge and decreased Th2 development in human T cell culture. These data support a direct role of CFTR in regulating T cell sensitivity to IL-4 and demonstrate a potential CFTR-specific therapeutic strategy for Th2 cell–mediated allergic disease.

Authors

Mark Rusznak, Christopher M. Thomas, Jian Zhang, Shinji Toki, Weisong Zhou, Masako Abney, Danielle M. Yanda, Allison E. Norlander, Craig A. Hodges, Dawn C. Newcomb, Mark H. Kaplan, R. Stokes Peebles Jr., Daniel P. Cook

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Figure 4

Loss of CFTR in Th2 cells increases whole transcriptome type 2 immune–specific gene expression.

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Loss of CFTR in Th2 cells increases whole transcriptome type 2 immune–sp...
(A) Schematic diagram showing isolation and polarization of naive CD4+ T cells to Th2 cells for whole transcriptome analysis. (B) PCA plot of gene expression data for 3 biological replicates used for bulk RNA-Seq of Cftr+/+ (black dots) and Cftr−/− (red dots) Th2 cells. (C) Volcano plot depicting DESeq2 analysis of differentially expressed genes in Cftr+/+ and Cftr−/− Th2 cells. Red dots represent genes expressed at higher levels in Cftr−/− Th2 cells, while black dots represent genes with higher expression levels in Cftr+/+ Th2 cells. The y axis denotes −log10 FDR values while the x axis shows log2 fold change values. Select genes indicated. (D) Advanced bubble plot showing KEGG pathways enriched in Cftr−/− Th2 cells. The y axis denotes enrichment score, and −log10 FDR values are shown on the x axis. The size of the bubble represents the number of genes enriched in each pathway. Select pathways indicated. (EH) Heatmaps showing the differential gene expression profile of core Th2 associated genes including surface markers (E), cytokines (F), transcription factors (G), and CD4+ pan markers (H) in Cftr−/− versus Cftr+/+ Th2 cells. Normalized log2 gene expression determined by RNA-Seq shown to the right of each heatmap with statistically significant DEGs denoted (*) in Cftr+/+ (gray bars) and Cftr−/− (red bars) Th2 cells. RNA-Seq data were generated in biological triplicates from 3 mice and analyzed via DESeq2. KEGG was used for pathway analysis.