Suprabasal cells retain progenitor cell identity programs in eosinophilic esophagitis–driven basal cell hyperplasia
Margarette H. Clevenger, Adam L. Karami, Dustin A. Carlson, Peter J. Kahrilas, Nirmala Gonsalves, John E. Pandolfino, Deborah R. Winter, Kelly A. Whelan, Marie-Pier Tétreault
Margarette H. Clevenger, Adam L. Karami, Dustin A. Carlson, Peter J. Kahrilas, Nirmala Gonsalves, John E. Pandolfino, Deborah R. Winter, Kelly A. Whelan, Marie-Pier Tétreault
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Research Article Gastroenterology Inflammation

Suprabasal cells retain progenitor cell identity programs in eosinophilic esophagitis–driven basal cell hyperplasia

Abstract

Eosinophilic esophagitis (EoE) is an esophageal immune-mediated disease characterized by eosinophilic inflammation and epithelial remodeling, including basal cell hyperplasia (BCH). Although BCH is known to correlate with disease severity and with persistent symptoms in patients in histological remission, the molecular processes driving BCH remain poorly defined. Here, we demonstrate that BCH is predominantly characterized by an expansion of nonproliferative suprabasal cells that are still committed to early differentiation. Furthermore, we discovered that suprabasal and superficial esophageal epithelial cells retain progenitor identity programs in EoE, evidenced by increased quiescent cell identity scoring and the enrichment of signaling pathways regulating stem cell pluripotency. Enrichment and trajectory analyses identified SOX2 and KLF5 as potential drivers of the increased quiescent identity and epithelial remodeling observed in EoE. Notably, these alterations were not observed in gastroesophageal reflux disease. These findings provide additional insights into the differentiation process in EoE and highlight the distinct characteristics of suprabasal and superficial esophageal epithelial cells in the disease.

Authors

Margarette H. Clevenger, Adam L. Karami, Dustin A. Carlson, Peter J. Kahrilas, Nirmala Gonsalves, John E. Pandolfino, Deborah R. Winter, Kelly A. Whelan, Marie-Pier Tétreault

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Figure 7

Pseudotemporal trajectory analysis of EEC reveals a shift in global differentiation toward basal identity in EoE.

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Pseudotemporal trajectory analysis of EEC reveals a shift in global diff...
(A) UMAP showing merged scRNA-Seq data sets of EEC from HC and EoE, colored by integrated clusters. (B) Pseudotime trajectory analysis calculated using HC and EoE samples, with cycling cells as the pseudotime origin. (C) Average pseudotime values across epithelial clusters. Pseudotime is rooted in cycling cells and progresses toward either quiescence or terminal differentiation. (D) Ridgeline plot illustrating the pseudotime value distribution between EEC in HC and EoE. (E) Ridgeline plots depicting pseudotime value distribution between epithelial compartments in HC and EoE. Arrows indicate peaks with differential density between EoE and HC. (F) Box plot showing the distribution of pseudotime values for every suprabasal and superficial cell cluster in HC or EoE. Boxes indicate quartiles, whiskers indicate minima/maxima separated by 1.5 times the interquartile range, and lines through each box indicate median pseudotime value. Indicated P values were determined using Wilcoxon signed-ranked test with Benjamini & Hochberg adjustment for multiple comparisons. **P ≤ 0.01, ***P ≤ 0.001. B, Basal; Q, Quiescent; BD, Basal_Dividing; EB, Epibasal; SB, Suprabasal; SF, Superficial.