Oehm, Andreas WAndreas WOehmOliveira Esteves, Blandina I.Blandina I.Oliveira EstevesHetzel, UdoUdoHetzelAlves, Marco P.Marco P.AlvesSchnyder, ManuelaManuelaSchnyder2025-04-032025-04-032025-03-22https://boris-portal.unibe.ch/handle/20.500.12422/208946The airway epithelium represents a central barrier against pathogens and toxins while playing a crucial role in modulating the immune response within the upper respiratory tract. Understanding these mechanisms is particularly relevant for red foxes (Vulpes vulpes), which serve as reservoirs for various zoonotic pathogens like rabies or the fox tapeworm (Echinococcus multilocularis). The study aimed to develop, establish, and validate an air-liquid interface (ALI) organoid model of the fox respiratory tract using primary airway epithelial cells isolated from the tracheas and main bronchi of hunted red foxes. The resulting ALI cultures exhibited a structurally differentiated, pseudostratified epithelium, characterised by ciliated cells, mucus secretion, and tight junctions, as confirmed through histological and immunohistochemical analysis. Functional assessments using a paracellular permeability assay and measurement of transepithelial electrical resistance, demonstrated a tight epithelial barrier. The potential of model's utility for studying innate immune responses to respiratory infections was validated by exposing the cultures to lipopolysaccharide, phorbol-12-myristate-13-acetate and ionomycin, and nematode somatic antigens. Quantitative PCR revealed notable changes in the expression of pro-inflammatory cytokines TNF and IL-33. This in vitro model represents a significant advancement in respiratory research for non-classical species that may act as important wildlife reservoirs for a range of zoonotic pathogens.enIn vitro modelFoxHost-pathogen interactionRespiratory tractWildlife reservoir600 - Technology::610 - Medicine & health500 - Science::590 - Animals (Zoology)article10.48620/870004012132510.1038/s41598-025-94033-x