Club Cell Loss as a Feature of Bronchiolization in ILD

Paul Reynaud, Engi Ahmed, Isabelle Serre, Lucie Knabe, Sébastien Bommart, Carey Suehs, Isabelle Vachier, Jean Philippe Berthet, Micaela Romagnoli, Charlotte Vernisse, Jean Pierre Mallet, Anne Sophie Gamez, Arnaud Bourdin, Paul Reynaud, Engi Ahmed, Isabelle Serre, Lucie Knabe, Sébastien Bommart, Carey Suehs, Isabelle Vachier, Jean Philippe Berthet, Micaela Romagnoli, Charlotte Vernisse, Jean Pierre Mallet, Anne Sophie Gamez, Arnaud Bourdin

Abstract

Background: Distal airway metaplasia may precede honeycombing in progressive fibrosing interstitial lung disease (ILD). The SCGB1A1+ bronchiolar-specific club cell may play a role in this aberrant regenerative process. Objective: To assess the presence of club cells in the small airways of patients suffering from ILD. Methods: Small airways (internal diameter <2 mm) in lung samples [surgical lung biopsy (SLB) and/or transbronchial lung cryobiopsy (TBLC)] from 14 patients suffering from ILD and 10 controls were morphologically assessed and stained for SCGB1A1. SCGB1A1 was weighted by epithelial height as a marker of airway generation (SCGB1A1/EH). Correlations between clinical, functional, and high-resolution CT (HRCT) prognostic factors and histomorphometry were assessed. Results: Small airways from samples with ILD patterns were significantly less dense in terms of SCGB1A1+ cells [0.064 (0.020-0.172)] as compared to controls' sample's small airways [0.393 (0.082-0.698), p < 0.0001]. Usual interstitial pneumonia (UIP) patterns most frequently contained small airways with limited or absent SCGB1A1 expression (SCGB1A1/EH <0.025): UIP (18/33; 55%) as compared with non-UIP patterns (4/31; 13%) or controls (0/29; 0%): p < 0.0001. In addition, correlations with HRCT indicated a significant negative relationship between SCGB1A1 and bronchiectasis as a feature of bronchiolization (Rho -0.63, p < 0.001) and a positive relationship with both forced vital capacity (FVC) and Hounsfield unit (HU)-distribution pattern in kurtosis (Rho 0.38 and 0.50, respectively, both p < 0.001) as markers of fibrotic changes. Conclusion: Compared with controls, the small airways of patients with ILD more often lack SCGB1A1, especially so in UIP. Low densities of SCGB1A1-marked cells correlate with bronchiectasis and fibrotic changes. Further research investigating SCGB1A1 staining as a pathological feature of the bronchiolization process is merited.

Keywords: SCGB1A1; bronchiolization; club (clara) cell; idiopathic pulmonary fibrosis; interstitial lung disease; metaplasia.

Conflict of interest statement

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Copyright © 2021 Reynaud, Ahmed, Serre, Knabe, Bommart, Suehs, Vachier, Berthet, Romagnoli, Vernisse, Mallet, Gamez and Bourdin.

Figures

Figure 1
Figure 1
After SCGB1A1 staining, small airway epithelia were isolated via thresholding, perimeters, thickness/height, and by the area quantified.
Figure 2
Figure 2
(A) Small airways are immune-stained for SCGB1A1 in controls, UIP, and non-UIP patterns. Upper left: (A) SLB from a control (no TBLC were available in this group). Middle row: (B) Very limited staining in some (left lower part) but not all small airways sampled by SLB; Inserts are: Serial cut with a Blue Alcian staining suggestive of the presence of mucin-costaining and a higher magnification suggestive of goblet cell morphology for SCGB1A1 positively stained epithelial cells. Ectasic small airway from a TBLC UIP pattern with bronchiolar metaplasia nearly free of staining despite abundant mucostasis. Right: SCGB1A1 stained small airways obtained by SLB (D) and by TBLC (E) in non-UIP patterns. (B) Box plots demonstrating group differences (Control vs. ILD for SLB and TBLC) for SCGB1A1 staining variables. TBLC, transbronchial lung cryobiopsies; SLB, surgical lung biopsy; UIP, usual interstitial pneumonia; ILD, interstitial lung disease.
Figure 3
Figure 3
The proportion of samples with SCGB1A1/EH p = 0.0027)].
Figure 4
Figure 4
Scatterplots demonstrating the relationships between selected pulmonary function variables [bronchiectasis score (A), % predicted forced vital capacity (FVC, % predicted) (B), and kurtosis of lung attenuation scores (C)] and % epithelial area of small airways that stains SCGB1B1+ weighted by epithelial height (EASCGB1B1+/EH). Smoothing is performed via a local loess estimator (in black). Spearman's correlation statistics (Rho and FDR-corrected p-value) are provided.

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