Single-cell analysis reveals lasting immunological consequences of influenza infection and respiratory immunisation in the pig lung

Abstract

AbstractThe pig is a natural host for influenza viruses and integrally involved in virus evolution through interspecies transmissions between humans and swine. Swine have many physiological, anatomical, and immunological similarities to humans, and are an excellent model for human influenza. Here, we employed single RNA-sequencing (scRNA-seq) and flow cytometry to characterize the major leucocyte subsets in bronchoalveolar lavage (BAL), twenty-one days after H1N1pdm09 infection or respiratory immunization with an adenoviral vector vaccine expressing haemagglutinin and nucleoprotein with or without IL-1β. Mapping scRNA-seq clusters from BAL onto those previously described in peripheral blood facilitated annotation and highlighted differences between tissue resident and circulating immune cells. ScRNA-seq data and functional assays revealed lasting impacts of immune challenge on BAL populations. First, mucosal administration of IL-1β reduced the number of functionally active Treg. Second, influenza infection upregulated IFI6 in BAL cells, decreasing their susceptibility to virus replicationin vitro. Our data provides a reference map of porcine BAL cells and reveals lasting immunological consequences of influenza infection and respiratory immunisation in a highly relevant large animal model for respiratory virus infection.Author SummaryPigs and humans have a similar anatomy and physiology. In humans, cells from lung-washes are used to study immune responses and it was shown that these cells are crucial in protection against respiratory diseases such as influenza and COVID-19. To better understand lung immunity, we compared genes expressed in cells of pig lung-wash to white blood cells, providing an atlas for future studies of immunity in the lung. We also tested a vaccine given to the lung containing IL-1β, a strong immune activator that protects mice against influenza virus infection. However, although IL-1β increased pig immune responses it did not protect pigs against infection. We also showed that the number of immune cells that dampen immune responses (regulatory T cells) is reduced. In addition, we demonstrated increased expression of a protein, IFI6, 21 days after infection showing that while immune cells in the lung have common properties, the invading organisms influence them significantly. Our study elucidates why some vaccines fail despite inducing powerful immune responses, emphasizes the need for caution when applying results from small animals like mice to humans, and indicates the importance of the pig as a model to study disease in humans and livestock.