TY - JOUR
T1 - Comparison of air-liquid interface transwell and airway organoid models for human respiratory virus infection studies
AU - the Inno4Vac respiratory models team
AU - Ekanger, Camilla T.
AU - Dinesh Kumar, Nilima
AU - Koutstaal, Rosanne W.
AU - Zhou, Fan
AU - Beukema, Martin
AU - Waldock, Joanna
AU - Jochems, Simon P.
AU - Mulder, Noa
AU - van Els, Cécile A.C.M.
AU - Engelhardt, Othmar G.
AU - Mantel, Nathalie
AU - Buno, Kevin P.
AU - Brokstad, Karl Albert
AU - Engelsen, Agnete S.T.
AU - Cox, Rebecca J.
AU - Melgert, Barbro N.
AU - Huckriede, Anke L.W.
AU - van Kasteren, Puck B.
N1 - Publisher Copyright:
Copyright © 2025 Ekanger, Dinesh Kumar, Koutstaal, Zhou, Beukema, Waldock, Jochems, Mulder, van Els, Engelhardt, Mantel, Buno, Brokstad, Engelsen, Cox, Melgert, Huckriede and van Kasteren.
PY - 2025/2/6
Y1 - 2025/2/6
N2 - Introduction: Complex in vitro respiratory models, including air-liquid interface (ALI) transwell cultures and airway organoids, have emerged as promising tools for studying human respiratory virus infections. These models address several limitations of conventional two-dimensional cell line and animal models. However, the lack of standardized protocols for the application of these models in infection studies limits the possibilities for comparing results across different research groups. Therefore, we applied a collaborative approach to harmonize several aspects of experimental methodology between different research laboratories, aiming to assess the comparability of different models of human airway epithelium in the context of respiratory viral infections. Methods: In this study, we compared three different models of human respiratory epithelium: a primary human bronchial epithelial cell-derived ALI transwell model, and two airway organoid models established from human airway- and lung-derived adult stem cells. We first assessed the presence of various differentiated cell types using immunofluorescence microscopy. Using a shared stock of influenza A virus, we then assessed viral growth kinetics, epithelial cytokine responses, and serum-mediated inhibition of infection. Results: The presence of club, goblet, and ciliated cells was confirmed in all models. We observed similar viral replication kinetics with a >4-log increase in virus titre across all models using a TCID50 assay. Following infection, a reproducible antiviral cytokine response, including a consistent increase in CXCL10, IL-6, IFN-λ1, IFN-λ2/3, and IFN-β, was detected across all models. Finally, neutralization was assessed by pre-incubation of virus with human serum. Reduced viral replication was observed across all models, resulting in a 3- to 6-log decrease in virus titres as quantified by TCID50. Discussion: In conclusion, all three models produced consistent results regardless of the varying cell sources, culturing approaches, and infection methods. Our collaborative efforts to harmonize infection experiments and compare ALI transwell and airway organoid models described here aid in advancing our understanding and improving the standardization of these complex in vitro respiratory models for future studies.
AB - Introduction: Complex in vitro respiratory models, including air-liquid interface (ALI) transwell cultures and airway organoids, have emerged as promising tools for studying human respiratory virus infections. These models address several limitations of conventional two-dimensional cell line and animal models. However, the lack of standardized protocols for the application of these models in infection studies limits the possibilities for comparing results across different research groups. Therefore, we applied a collaborative approach to harmonize several aspects of experimental methodology between different research laboratories, aiming to assess the comparability of different models of human airway epithelium in the context of respiratory viral infections. Methods: In this study, we compared three different models of human respiratory epithelium: a primary human bronchial epithelial cell-derived ALI transwell model, and two airway organoid models established from human airway- and lung-derived adult stem cells. We first assessed the presence of various differentiated cell types using immunofluorescence microscopy. Using a shared stock of influenza A virus, we then assessed viral growth kinetics, epithelial cytokine responses, and serum-mediated inhibition of infection. Results: The presence of club, goblet, and ciliated cells was confirmed in all models. We observed similar viral replication kinetics with a >4-log increase in virus titre across all models using a TCID50 assay. Following infection, a reproducible antiviral cytokine response, including a consistent increase in CXCL10, IL-6, IFN-λ1, IFN-λ2/3, and IFN-β, was detected across all models. Finally, neutralization was assessed by pre-incubation of virus with human serum. Reduced viral replication was observed across all models, resulting in a 3- to 6-log decrease in virus titres as quantified by TCID50. Discussion: In conclusion, all three models produced consistent results regardless of the varying cell sources, culturing approaches, and infection methods. Our collaborative efforts to harmonize infection experiments and compare ALI transwell and airway organoid models described here aid in advancing our understanding and improving the standardization of these complex in vitro respiratory models for future studies.
KW - complex in vitro models
KW - harmonization
KW - influenza virus
KW - mucosal models
KW - respiratory tract
UR - https://www.scopus.com/pages/publications/85218673230
U2 - 10.3389/fimmu.2025.1532144
DO - 10.3389/fimmu.2025.1532144
M3 - Article
AN - SCOPUS:85218673230
SN - 1664-3224
VL - 16
JO - Frontiers in Immunology
JF - Frontiers in Immunology
M1 - 1532144
ER -