Abstract
The epithelial lining of the lung is often the first point of interaction between the host and inhaled pathogens, allergens and medications. Epithelial cells are therefore the main focus of studies which aim to shed light on host-pathogen interactions, to dissect the mechanisms of local host immunity and study toxicology. If these studies are not to be conducted exclusively in vivo, it is imperative that in vitro models are developed with a high in vitro- in vivo correlation. We describe here a co-culture model of the bovine alveolus, designed to overcome some of the limitations encountered with mono-culture and live animal models. Our system includes bovine pulmonary arterial endothelial cells (BPAECs) seeded onto a permeable membrane in 24 well Transwell format. The BPAECs are overlaid with immortalised bovine alveolar type II epithelial cells and cultured at air-liquid interface for 14 days before use; in our case to study host-mycobacterial interactions. Characterisation of novel cell lines and the co-culture model have provided compelling evidence that immortalised bovine alveolar type II cells are an authentic substitute for primary alveolar type II cells and their co-culture with BPAECs provides a physiologically relevant in vitro model of the bovine alveolus. The co-culture model may be used to study dynamic intracellular and extracellular host-pathogen interactions, using proteomics, genomics, live cell imaging, in-cell ELISA and confocal microscopy. The model presented in this article enables other researchers to establish an in vitro model of the bovine alveolus that is easy to set up, malleable and serves as a comparable alternative to in vivo models, whilst allowing study of early host-pathogen interactions, currently not feasible in vivo. The model therefore achieves one of the 3Rs objectives in that it replaces the use of animals in research of bovine respiratory diseases.
Highlights
The lung is a complex organ, lined in its entirety by specialised epithelium
We describe here a method by which researchers may construct a co-culture model for medium term culture, consisting of an immortalised alveolar type II epithelial cell layer overlaid onto a bovine pulmonary arterial endothelial cell (BPAEC) layer
Immortalisation involves the introduction of viral oncogenes, for example those encoding the E6 and E7 proteins of human papilloma virus (HPVE6/E7) and the large tumour (T) antigen derived from Simian virus (SV40)
Summary
The lung is a complex organ, lined in its entirety by specialised epithelium. The most distal region of the lung consists of the alveoli, designed primarily for efficient gas exchange and arranged in clusters or acini. Alveolar type I cells cover 90 % of the alveolar surface, despite only constituting in the region of 7 % of the epithelium by numbers. Alveolar type I cells cover 90 % of the alveolar surface, despite only constituting in the region of 7 % of the epithelium by numbers3 This can be attributed to the elongated squamous cell morphology of the ATI, which spreads over a large surface area and lies in close proximity to capillary endothelial cells. This lends the ATI to its primary role of gas exchange and enables the regulation of physiological solute transport between the alveolus and the circulatory system. Previous studies have provided evidence for the role for ATI cells in fluid homeostasis of the alveolar compartment, with the finding that sodium ions are transported via the epithelial sodium channel (ENaC), using active ion transport
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