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Machine learning implicates the IL-18 signaling axis in severe asthma
Matthew J. Camiolo, Xiuxia Zhou, Qi Wei, Humberto E. Trejo Bittar, Naftali Kaminski, Anuradha Ray, Sally E. Wenzel
Matthew J. Camiolo, Xiuxia Zhou, Qi Wei, Humberto E. Trejo Bittar, Naftali Kaminski, Anuradha Ray, Sally E. Wenzel
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Research Article Immunology Pulmonology

Machine learning implicates the IL-18 signaling axis in severe asthma

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Abstract

Asthma is a common disease with profoundly variable natural history and patient morbidity. Heterogeneity has long been appreciated, and much work has focused on identifying subgroups of patients with similar pathobiological underpinnings. Previous studies of the Severe Asthma Research Program (SARP) cohort linked gene expression changes to specific clinical and physiologic characteristics. While invaluable for hypothesis generation, these data include extensive candidate gene lists that complicate target identification and validation. In this analysis, we performed unsupervised clustering of the SARP cohort using bronchial epithelial cell gene expression data, identifying a transcriptional signature for participants suffering exacerbation-prone asthma with impaired lung function. Clinically, participants in this asthma cluster exhibited a mixed inflammatory process and bore transcriptional hallmarks of NF-κB and activator protein 1 (AP-1) activation, despite high corticosteroid exposure. Using supervised machine learning, we found a set of 31 genes that classified patients with high accuracy and could reconstitute clinical and transcriptional hallmarks of our patient clustering in an external cohort. Of these genes, IL18R1 (IL-18 Receptor 1) negatively associated with lung function and was highly expressed in the most severe patient cluster. We validated IL18R1 protein expression in lung tissue and identified downstream NF-κB and AP-1 activity, supporting IL-18 signaling in severe asthma pathogenesis and highlighting this approach for gene and pathway discovery.

Authors

Matthew J. Camiolo, Xiuxia Zhou, Qi Wei, Humberto E. Trejo Bittar, Naftali Kaminski, Anuradha Ray, Sally E. Wenzel

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Figure 1

Unsupervised clustering of SARP cohort participants using BEC gene expression.

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Unsupervised clustering of SARP cohort participants using BEC gene expre...
(A) Venn diagram of genes differentially expressed between HC, MMA, and SA participants (n = 155) after controlling for sex and corticosteroid use. (B) Patient clustering results projected on t-stochastic neighbor embedding (tSNE) space. (C) Heatmap of expression of the 758 genes included in clustering with patient cluster or clinical disease severity as indicated in row sidebar. (D) Clinical disease severity across patient clusters is represented as relative percentage in stacked bar chart with P value calculated using Pearson’s χ2 testing of raw values. (E) Percentage of patients experiencing ED visit or hospitalization for asthma exacerbation in the preceding year is represented as stacked bar chart with P value from Pearson’s χ2 testing. (F) Box plot of FEV1 measured by spirometry across patient groups with P value calculated using Kruskal-Wallis testing. Error bars represent median values, with bounds of boxes representing IQR and whiskers representing 1.5× the upper or lower IQR. (G) Stacked bar plot of BAL cell manual cell count differential across patient clusters. (H) T2-biomarkers blood absolute (ABS) eosinophils or fraction exhaled nitric oxide (FeNO) across clusters with P value calculated using Kruskal-Wallis testing. (I) Geometric mean of Type-2 asthma gene score across patient clusters with P value calculated using Kruskal-Wallis testing.

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