Ren Hui, Birch Nigel P, Suresh Vinod
Auckland Bioengineering Institute, University of Auckland, Auckland, New Zealand.
School of Biological Sciences, University of Auckland, Auckland, New Zealand.
PLoS One. 2016 Oct 25;11(10):e0165225. doi: 10.1371/journal.pone.0165225. eCollection 2016.
Robust and reproducible in vitro models are required for investigating the pathways involved in fluid homeostasis in the human alveolar epithelium. We performed functional and phenotypic characterisation of ion transport in the human pulmonary epithelial cell lines NCI-H441 and A549 to determine their similarity to primary human alveolar type II cells. NCI-H441 cells exhibited high expression of junctional proteins ZO-1, and E-cadherin, seal-forming claudin-3, -4, -5 and Na+-K+-ATPase while A549 cells exhibited high expression of pore-forming claudin-2. Consistent with this phenotype NCI-H441, but not A549, cells formed a functional barrier with active ion transport characterised by higher electrical resistance (529 ± 178 Ω cm2 vs 28 ± 4 Ω cm2), lower paracellular permeability ((176 ± 42) ×10-8 cm/s vs (738 ± 190) ×10-8 cm/s) and higher transepithelial potential difference (11.9 ± 4 mV vs 0 mV). Phenotypic and functional properties of NCI-H441 cells were tuned by varying cell seeding density and supplement concentrations. The cells formed a polarised monolayer typical of in vivo epithelium at seeding densities of 100,000 cells per 12-well insert while higher densities resulted in multiple cell layers. Dexamethasone and insulin-transferrin-selenium supplements were required for the development of high levels of electrical resistance, potential difference and expression of claudin-3 and Na+-K+-ATPase. Treatment of NCI-H441 cells with inhibitors and agonists of sodium and chloride channels indicated sodium absorption through ENaC under baseline and forskolin-stimulated conditions. Chloride transport was not sensitive to inhibitors of the cystic fibrosis transmembrane conductance regulator (CFTR) under either condition. Channels inhibited by 5-nitro-1-(3-phenylpropylamino) benzoic acid (NPPB) contributed to chloride secretion following forskolin stimulation, but not at baseline. These data precisely define experimental conditions for the application of NCI-H441 cells as a model for investigating ion and water transport in the human alveolar epithelium and also identify the pathways of sodium and chloride transport.
为了研究参与人类肺泡上皮液体稳态的相关途径,需要稳健且可重复的体外模型。我们对人类肺上皮细胞系NCI-H441和A549中的离子转运进行了功能和表型特征分析,以确定它们与原代人类肺泡II型细胞的相似性。NCI-H441细胞表现出紧密连接蛋白ZO-1、E-钙黏蛋白、形成紧密连接的claudin-3、-4、-5和钠钾ATP酶的高表达,而A549细胞表现出形成孔道的claudin-2的高表达。与这种表型一致,NCI-H441细胞(而非A549细胞)形成了具有主动离子转运功能的屏障,其特征为更高的电阻(529±178Ω·cm²对28±4Ω·cm²)、更低的细胞旁通透性((176±42)×10⁻⁸cm/s对(738±190)×10⁻⁸cm/s)和更高的跨上皮电位差(11.9±4mV对0mV)。通过改变细胞接种密度和补充剂浓度来调节NCI-H441细胞的表型和功能特性。在每12孔插入物接种100,000个细胞的密度下,细胞形成了体内上皮典型的极化单层,而更高的密度则导致多层细胞。地塞米松和胰岛素-转铁蛋白-硒补充剂是高水平电阻、电位差以及claudin-3和钠钾ATP酶表达所必需的。用钠和氯通道的抑制剂和激动剂处理NCI-H441细胞表明,在基线和福斯高林刺激条件下,钠通过上皮钠通道(ENaC)吸收。在两种条件下,氯转运对囊性纤维化跨膜传导调节因子(CFTR)的抑制剂均不敏感。在福斯高林刺激后,5-硝基-1-(3-苯丙基氨基)苯甲酸(NPPB)抑制的通道参与了氯分泌,但在基线时不参与。这些数据精确地定义了将NCI-H441细胞用作研究人类肺泡上皮离子和水转运模型的实验条件,同时也确定了钠和氯的转运途径。
