Neutrophils in nasal polyps exhibit transcriptional adaptation and proinflammatory roles that depend on local polyp milieu
Chen Zhang, … , Huan Wang, Xicai Sun
Chen Zhang, … , Huan Wang, Xicai Sun
Published October 3, 2024
Citation Information: JCI Insight. 2024;9(22):e184739. https://doi.org/10.1172/jci.insight.184739.
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Research Article Inflammation

Neutrophils in nasal polyps exhibit transcriptional adaptation and proinflammatory roles that depend on local polyp milieu

Abstract

Chronic rhinosinusitis with nasal polyps (CRSwNP) is an inflammatory upper airway disease, divided into eosinophilic CRSwNP (eCRSwNP) and noneosinophilic CRSwNP (neCRSwNP) according to eosinophilic levels. Neutrophils are major effector cells in CRSwNP, but their roles in different inflammatory environments remain largely unclear. We performed an integrated transcriptome analysis of polyp-infiltrating neutrophils from patients with CRSwNP, using healthy donor blood as a control. Additional experiments, including flow cytometry and in vitro epithelial cell and fibroblast culture, were performed to evaluate the phenotypic feature and functional role of neutrophils in CRSwNP. Single-cell RNA-sequencing analysis demonstrated that neutrophils could be classified into 5 functional subsets, with GBP5+ neutrophils occurring mainly in neCRSwNP and a high proportion of CXCL8+ neutrophils in both subendotypes. GBP5+ neutrophils exhibited significant IFN-I pathway activity in neCRSwNP. CXCL8+ neutrophils displayed increased neutrophil activation scores and mainly secreted oncostatin M (OSM), which facilitates communication with other cells. In vitro experiments showed that OSM enhanced IL-13– or IL-17–mediated immune responses in nasal epithelial cells and fibroblasts. Our findings indicate that neutrophils display transcriptional plasticity and activation when exposed to polyp tissue, contributing to CRSwNP pathogenesis by releasing OSM, which interacts with epithelial cells and fibroblasts depending on the inflammatory environment.

Authors

Chen Zhang, Qianqian Zhang, Jiani Chen, Han Li, Fuying Cheng, Yizhang Wang, Yingqi Gao, Yumin Zhou, Le Shi, Yufei Yang, Juan Liu, Kai Xue, Yaguang Zhang, Hongmeng Yu, Dehui Wang, Li Hu, Huan Wang, Xicai Sun

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Figure 3

Neutrophils in nasal polyps consist of distinct transcriptional subsets.

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Neutrophils in nasal polyps consist of distinct transcriptional subsets....
(A) The UMAP plot depicting 10 clusters of neutrophils. (B) Line graph presenting the ratio of observed to expected cell numbers (Ro/e) for each cluster. (C) Dot plot depicting the top 3 genes in each neutrophil cluster. (D) UMAP plot depicting 5 subsets of neutrophils. (E) Heatmap showing the Ro/e level of each subset. (F) Box-and-whisker plot depicting the proportions of neutrophil subsets in different groups. Shown are the median (line within box), IQR (box bounds), and the range (whiskers); data points beyond whiskers are outliers. (G) Heatmap visualizing the 40 genes with the highest expression levels and pathway enrichment for each neutrophil subset. (H) The violin plot showing the signature score of the senescence pathway in different neutrophil subsets. (I) The violin plot showing the signature score of the neutrophil activation pathway in different neutrophil subsets. (J) Left: The density heatmap displaying the signature score of the response to type I IFN pathway in neutrophils. Right: The violin plot showing the signature score of the response to type I IFN pathway in the neCRSwNPs. (K) The dot plot depicting the gene expression level related to the response to type I IFN pathway in different neutrophil subsets. (L) The scatter plot showing the correlation between the signature score of the response to type I IFN pathway and the average MX1 expression level in the scRNA-seq data of nasal polyps evaluated with Spearman’s rank test. (M) The scatter dot plot displaying the MX1 mRNA level in control uncinate tissues and nasal polyps evaluated with the Kruskal-Wallis test with Dunn’s post hoc test (control, n = 13; neCRSwNP, n = 14; eCRSwNP, n = 14). *P < 0.05.