Department of Pathology, Roy J. and Lucille A. Carver College of Medicine, University of Iowa, Iowa City, IA, USA.
Department of Internal Medicine, Roy J. and Lucille A. Carver College of Medicine, University of Iowa, Iowa City, IA, USA.
Lab Invest. 2018 Jun;98(6):825-838. doi: 10.1038/s41374-018-0026-7. Epub 2018 Feb 21.
Loss of cystic fibrosis transmembrane conductance regulator (CFTR) function causes cystic fibrosis (CF), predisposing the lungs to chronic infection and inflammation. In young infants with CF, structural airway defects are increasingly recognized before the onset of significant lung disease, which suggests a developmental origin and a possible role in lung disease pathogenesis. The role(s) of CFTR in lung development is unclear and developmental studies in humans with CF are not feasible. Young CF pigs have structural airway changes and develop spontaneous postnatal lung disease similar to humans; therefore, we studied lung development in the pig model (non-CF and CF). CF trachea and proximal airways had structural lesions detectable as early as pseudoglandular development. At this early developmental stage, budding CF airways had smaller, hypo-distended lumens compared to non-CF airways. Non-CF lung explants exhibited airway lumen distension in response to forskolin/IBMX as well as to fibroblast growth factor (FGF)-10, consistent with CFTR-dependent anion transport/secretion, but this was lacking in CF airways. We studied primary pig airway epithelial cell cultures and found that FGF10 increased cellular proliferation (non-CF and CF) and CFTR expression/function (in non-CF only). In pseudoglandular stage lung tissue, CFTR protein was exclusively localized to the leading edges of budding airways in non-CF (but not CF) lungs. This discreet microanatomic localization of CFTR is consistent with the site, during branching morphogenesis, where airway epithelia are responsive to FGF10 regulation. In summary, our results suggest that the CF proximal airway defects originate during branching morphogenesis and that the lack of CFTR-dependent anion transport/liquid secretion likely contributes to these hypo-distended airways.
囊性纤维化跨膜电导调节因子 (CFTR) 功能丧失会导致囊性纤维化 (CF),使肺部容易受到慢性感染和炎症的影响。在患有 CF 的婴儿中,在出现明显的肺部疾病之前,越来越多地认识到气道结构缺陷,这表明其具有发育起源,并可能在肺部疾病发病机制中发挥作用。CFTR 在肺部发育中的作用尚不清楚,且在 CF 患者中进行的发育研究是不可行的。年幼的 CF 猪存在气道结构改变,并在出生后自发发展为类似于人类的肺部疾病;因此,我们在猪模型(非 CF 和 CF)中研究了肺部发育。CF 气管和近端气道在假腺样发育阶段即可检测到结构病变。在这个早期发育阶段,与非 CF 气道相比,CF 气道芽的管腔更小、膨胀不足。非 CF 肺外植体在福司可林/IBMX 以及成纤维细胞生长因子 (FGF)-10 的作用下显示出气道管腔扩张,这与 CFTR 依赖的阴离子转运/分泌一致,但 CF 气道缺乏这种作用。我们研究了原代猪气道上皮细胞培养物,发现 FGF10 增加了细胞增殖(非 CF 和 CF)和 CFTR 表达/功能(仅在非 CF 中)。在假腺样发育阶段的肺组织中,CFTR 蛋白仅在非 CF(而非 CF)肺部的气道芽的前沿定位。CFTR 的这种离散的微观解剖定位与分支形态发生过程中一致,在该过程中,气道上皮对 FGF10 调节有反应。总之,我们的结果表明 CF 近端气道缺陷起源于分支形态发生过程中,缺乏 CFTR 依赖的阴离子转运/液体分泌可能导致这些气道膨胀不足。
