What question did this study set out to answer?

This research aims to elucidate the relationship between airway physiology and leukocyte profiles in asthma, focusing on indirect airway hyperresponsiveness (AHR).

May 20, 2026

D21-18 Linking Airway Physiology and Inflammatory Endotypes in Asthma to Airway Leukocyte Profiles at Single-Cell Resolution

Key Points

This research aims to elucidate the relationship between airway physiology and leukocyte profiles in asthma, focusing on indirect airway hyperresponsiveness (AHR).
Induced sputum collected from 3 healthy individuals and 8 individuals with asthma for single-cell RNA sequencing.
Samples underwent extensive phenotyping for direct and indirect AHR using methacholine and mannitol challenges.
Data analyzed with Seurat v5 and DESeq2 to evaluate differential gene expression among leukocyte populations.
Identified five major leukocyte populations, including neutrophils, with notable differences in gene expression linked to T2-high asthma.
Higher proportions of mast cells and basophils observed in individuals with T2-high asthma and indirect AHR.
Differential expression analysis revealed 128 genes significantly varying in neutrophils between T2-high and non-T2 asthma.

Abstract

Abstract Rationale Indirect airway hyperresponsiveness (AHR) is a specific feature of airway dysfunction in asthma but the immunopathological mechanisms responsible for indirect AHR remain incompletely understood. We have previously characterized transcriptional circuits implicated in indirect AHR, which involved signaling between the airway epithelium, mast cells (MCs), and eosinophils, through bulk RNA-sequencing analysis of epithelial brushings (Murphy AJRCCM 2023). Here we examine leukocyte populations in induced sputum samples obtained from individuals with and without asthma who underwent extensive phenotyping for AHR using fixed single-cell RNA sequencing (scRNA-seq). Methods Induced sputum was collected from 3 healthy individuals and 8 individuals with asthma not receiving immune-modulating therapies who underwent characterization for direct (methacholine challenge) and indirect AHR (mannitol challenge) and T2 endotype. After squamous epithelial cell removal, samples were fixed and scRNA-seq was performed using the 10X Chromium Fixed RNA Profiling platform. Data were analyzed using Seurat v5 for filtering, integration, clustering, 0.10) between cells from T2-high versus non-T2 asthma, including higher expression of ALOX5, IL4R, and CISH in neutrophils from T2-high asthma and higher expression of C3, CXCR4, CXCL8, CD63, and SLPI in neutrophils from non-T2 asthma. Conclusions Sample fixation prior to scRNA-seq allows for successful capture of leukocyte populations from induced sputum samples in asthma, including neutrophils and other rare immune populations (mast cells/basophils, ILC2s). Preliminary results identify higher numbers of MCs/basophils in the airway lumen of individuals with T2-high asthma and those with indirect AHR, consistent with prior work. We also identified notable T2 endotype-specific differences in the transcriptional profile of airway neutrophils, which provide novel insights into the potential roles of neutrophils in both T2-high and non-T2 asthma. This abstract is funded by: NIH, Parker B. Francis Family Foundation

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D21-18 Linking Airway Physiology and Inflammatory Endotypes in Asthma to Airway Leukocyte Profiles at Single-Cell Resolution

Key Points

Abstract

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