Planar organization of airway epithelial cell morphology using hydrogel grooves during ciliogenesis fails to induce ciliary alignment

Topographical cues are known to influence cell organization both in native tissues and in vitro . In the trachea, the matrix beneath the epithelial lining is composed of collagen fibres that run along the long axis of the airway. Previous studies have shown that grooved topography can induce morphol...

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Veröffentlicht in:Biomaterials science 2022-01, Vol.1 (2), p.396-49
Hauptverfasser: Varma, Ratna, Poon, James, Liao, Zhongfa, Aitchison, J. Stewart, Waddell, Thomas K, Karoubi, Golnaz, McGuigan, Alison P
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Sprache:eng
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Zusammenfassung:Topographical cues are known to influence cell organization both in native tissues and in vitro . In the trachea, the matrix beneath the epithelial lining is composed of collagen fibres that run along the long axis of the airway. Previous studies have shown that grooved topography can induce morphological and cytoskeletal alignment in epithelial cell lines. In the present work we assessed the impact of substrate topography on the organization of primary human tracheal epithelial cells (HTECs) and human induced pluripotent stem cell (hiPSC)-derived airway progenitors and the resulting alignment of cilia after maturation of the airway cells under Air-Liquid-Interface (ALI) culture. Grooves with optimized dimensions were imprinted into collagen vitrigel membranes (CVM) to produce gel inserts for ALI culture. Grooved CVM substrates induced cell alignment in HTECs and hiPSC airway progenitors in submerged culture. Further, both cell types were able to terminally differentiate into a multi-ciliated epithelium on both flat and groove CVM substrates. When exposed to ALI conditions, HTECs lost alignment after 14 days. Meanwhile, hiPSC-derived airway progenitors maintained their alignment throughout 31 days of ALI culture. Interestingly, neither initial alignment on the grooves, nor maintained alignment on the grooves induced alignment of cilia basal bodies, an indication of the direction of ciliary beating direction in the airway cells. Planar organization of airway cells during or prior to ciliogenesis therefore does not appear to be a feasible strategy to control cilia organization and subsequent airway epithelial function and additional cues are likely necessary to produce cilia alignment. Here we align airway epithelial cells on hydrogel grooves and induce apical-basal polarization and cilia formation. Neither initial alignment, nor maintained alignment on the grooves induced polarized cilia alignment in the epithelial sheet.
ISSN:2047-4830
2047-4849
DOI:10.1039/d1bm01327k