Porosome reconstitution therapy: A biologic rescue from cystic fibrosis

Won Jin Cho, Ha Vo, Yongxin Zhao, Douglas J Taatjes, Bhanu P Jena
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Abstract

Cystic fibrosis (CF) is a genetic disorder resulting from mutations in the CF Transmembrane Conductance Regulator (CFTR) gene that codes for a chloride transporting channel at the cell plasma membrane. In CF, highly viscous mucus is secreted in the airways preventing its clearance, leading to lung infections and respiratory failure. A major challenge in treating CF patients has been the presence of more than 2,000 different CFTR mutations or due to the absence of CFTR expression. CFTR is among the 34 major proteins composing the 100 nm porosome secretory machinery in the human airway epithelia, involved in mucin secretion. The airways is coated with a thin film of mucus, composed primarily of mucin MUC5AC and MUC5B. Sputum from patients with CF show a >70% decrease in MUC5B and MUC5AC secretion. Our studies using differentiated 3D cultures of human airway epithelial cell line, also demonstrate loss of both chloride and mucus secretion following exposure to CFTR inhibitors thiazolidinone 172 or the hydrazide GlyH101. Our studies show that human bronchial epithelial (HBE) cells with ΔF508 CFTR mutation, affects nearly a dozen porosome proteins including CFTR. Therefore, we hypothesized that the introduction of normal functional porosomes carrying wild type CFTR into the cell plasma membrane of CF cells would rescue from all forms of CF. Air liquid interface (ALI) 3D differentiated HBE WT-CFTR cells and ΔF508-CFTR CF HBE cell cultures mimicking normal lung physiology, responding to CFTR inhibitors and CF corrector and modulator drugs Tezacaftor, Ivacaftor and TRIKAFTA, was used in the study. Introduction of functional porosome complexes obtained from WT-CFTR HBE cells into the plasma membrane (PM) of ΔF508-CFTR CF cells, was demonstrated by an increase in PM-associated CFTR using Magnify expansion microscopy. Mucin secretion assays demonstrate porosome reconstitution to restore mucin secretion more than twice as effectively as TRIKAFTA. These results are further supported by preliminary nasal potential different studies in ΔF508 mice, where treatment of the nasal passage with porosome isolates from WT-CFTR HBE cells, restore chloride secretion in the nasal passage of mice, a further validation of the highly effective porosome reconstitution therapy for CF.
多糖体重建疗法:从生物学角度拯救囊性纤维化
囊性纤维化(CF)是一种遗传性疾病,由 CF 跨膜传导调节器(CFTR)基因突变引起,该基因编码细胞质膜上的氯离子转运通道。CF 患者的呼吸道会分泌高粘度粘液,阻碍粘液的清除,导致肺部感染和呼吸衰竭。治疗 CF 患者的一大挑战是存在 2,000 多种不同的 CFTR 突变或 CFTR 表达缺失。CFTR 是构成人体气道上皮 100 纳米孔体分泌机制的 34 种主要蛋白质之一,参与粘蛋白的分泌。气道表面覆盖着一层粘液薄膜,主要由粘蛋白 MUC5AC 和 MUC5B 组成。CF 患者的痰液显示 MUC5B 和 MUC5AC 的分泌减少了 70%。我们利用分化的三维培养人气道上皮细胞系进行的研究也表明,暴露于 CFTR 抑制剂噻唑烷酮 172 或酰肼 GlyH101 后,氯化物和粘液分泌均会减少。我们的研究表明,人支气管上皮(HBE)细胞中的ΔF508 CFTR突变会影响包括CFTR在内的近十种孔体蛋白。因此,我们假设将携带野生型 CFTR 的正常功能孔体引入 CF 细胞的细胞质膜,将能挽救所有形式的 CF。研究中使用了气液界面(ALI)三维分化的HBE WT-CFTR细胞和模拟正常肺生理学的ΔF508-CFTR CF HBE细胞培养物,它们对CFTR抑制剂和CF校正和调节药物Tezacaftor、Ivacaftor和TRIKAFTA都有反应。将从 WT-CFTR HBE 细胞中获得的功能性孔小体复合物导入 ΔF508-CFTR CF 细胞的质膜(PM)中,使用放大扩增显微镜观察与 PM 相关的 CFTR 的增加情况。粘蛋白分泌试验表明,孔小体重组恢复粘蛋白分泌的效果是 TRIKAFTA 的两倍多。对ΔF508小鼠进行的初步鼻腔潜能不同研究进一步证实了这些结果,用从WT-CFTR HBE细胞中分离出的孔隙体处理小鼠鼻腔,可恢复小鼠鼻腔的氯化物分泌,这进一步验证了孔隙体重组疗法对CF的高效治疗作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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