Oxygenation as a driving factor in epithelial differentiation at the air-liquid interface.

IF 1.5 4区 生物学 Q4 CELL BIOLOGY Integrative Biology Pub Date : 2021-03-17 DOI:10.1093/intbio/zyab002
Sonya Kouthouridis, Julie Goepp, Carolina Martini, Elizabeth Matthes, John W Hanrahan, Christopher Moraes
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Abstract

Culture at the air-liquid interface is broadly accepted as necessary for differentiation of cultured epithelial cells towards an in vivo-like phenotype. However, air-liquid interface cultures are expensive, laborious and challenging to scale for increased throughput applications. Deconstructing the microenvironmental parameters that drive these differentiation processes could circumvent these limitations, and here we hypothesize that reduced oxygenation due to diffusion limitations in liquid media limits differentiation in submerged cultures; and that this phenotype can be rescued by recreating normoxic conditions at the epithelial monolayer, even under submerged conditions. Guided by computational models, hyperoxygenation of atmospheric conditions was applied to manipulate oxygenation at the monolayer surface. The impact of this rescue condition was confirmed by assessing protein expression of hypoxia-sensitive markers. Differentiation of primary human bronchial epithelial cells isolated from healthy patients was then assessed in air-liquid interface, submerged and hyperoxygenated submerged culture conditions. Markers of differentiation, including epithelial layer thickness, tight junction formation, ciliated surface area and functional capacity for mucociliary clearance, were assessed and found to improve significantly in hyperoxygenated submerged cultures, beyond standard air-liquid interface or submerged culture conditions. These results demonstrate that an air-liquid interface is not necessary to produce highly differentiated epithelial structures, and that increased availability of oxygen and nutrient media can be leveraged as important strategies to improve epithelial differentiation for applications in respiratory toxicology and therapeutic development.

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充氧是气液界面上皮细胞分化的驱动因素。
气液界面培养被广泛认为是培养上皮细胞向活体表型分化的必要条件。然而,气液界面培养成本高昂、费时费力,而且难以扩大规模以提高应用通量。在此,我们假设,由于液体培养基中的扩散限制导致氧含量降低,从而限制了浸没培养物的分化;即使在浸没条件下,也可以通过在上皮单层重建常氧条件来挽救这种表型。在计算模型的指导下,应用大气条件下的高氧来操纵单层表面的含氧量。通过评估缺氧敏感标记物的蛋白质表达,证实了这种拯救条件的影响。然后,在气液界面、浸没和高氧浸没培养条件下评估了从健康患者身上分离出来的原代人类支气管上皮细胞的分化情况。评估发现,在高氧浸没培养条件下,上皮层厚度、紧密连接形成、纤毛表面积和粘液纤毛清除功能能力等分化标志物都有显著改善,超过了标准的气液界面或浸没培养条件。这些结果表明,产生高度分化的上皮结构并不需要空气-液体界面,增加氧气和营养介质的可用性可作为改善上皮分化的重要策略,应用于呼吸毒理学和治疗开发。
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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来源期刊
Integrative Biology
Integrative Biology 生物-细胞生物学
CiteScore
4.90
自引率
0.00%
发文量
15
审稿时长
1 months
期刊介绍: Integrative Biology publishes original biological research based on innovative experimental and theoretical methodologies that answer biological questions. The journal is multi- and inter-disciplinary, calling upon expertise and technologies from the physical sciences, engineering, computation, imaging, and mathematics to address critical questions in biological systems. Research using experimental or computational quantitative technologies to characterise biological systems at the molecular, cellular, tissue and population levels is welcomed. Of particular interest are submissions contributing to quantitative understanding of how component properties at one level in the dimensional scale (nano to micro) determine system behaviour at a higher level of complexity. Studies of synthetic systems, whether used to elucidate fundamental principles of biological function or as the basis for novel applications are also of interest.
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