Baasch, S.; Nelipovich, A.; Zhumadilova, Z.; Henschel, J.; Ghanem, N.; Doering, C.-L.; Aktories, P.; Wagner, L.; Dey, A.; Vanneste, D.; Helmstaedter, M.; Kierdorf, K.; Kolter, J.; Lubatti, G.; Sagar, S.; Marichal, T.; Ruzsics, Z.; Henneke, P.

Alveolar macrophages (AM), the most frequent resident immune cells of the lung, are at the first line of defence against respiratory pathogens and instruct structural lung cells, e.g. in tissue repair. They are long-lived and receive their terminal phenotypic imprint through signals originating from the unique location at the tissue-air interface, as well as through cytokines like granulocyte-macrophage colony-stimulating factor (GM-CSF) and transforming growth factor-{beta} (TGF-{beta}). However, the regulatory mechanisms governing their phenotypic plasticity, which is conceptually critical for their positioning and differentiation in early life and for their functional adaptation during infection, remain poorly defined. Here we explored respiratory tract infection with cytomegalovirus (CMV), which is closely linked to mammalian immune evolution. Complementary host-pathogen fate-mapping strategies revealed AM to constitute the bottleneck for efficient mouse (M)CMV infection. MCMV infection induced macrophage colony-stimulating factor (M-CSF) in the alveolar space, and culturing of AM in M-CSF led to a profound remodelling of morphology, immunophenotype, and transcriptional identity, e.g. it increased the expression of interferon-stimulated genes (ISG), which modulated susceptibility to infection. Notably, already at baseline recently differentiated neonatal AM across species retained an M-CSF-associated transcriptional program. This was linked to reduced permissiveness to respiratory MCMV infection in vivo. Overall, our findings identify the role of M-CSF-dependent signalling in conferring plasticity to AM, when it is most needed, particularly during early-life establishment and in response to viral infection.