Macrophages are professional phagocytic cells that orchestrate homeostatic and innate immune functions, via the scavenging of cells, debris, and pathogens, and the production of cytokines, both concurring to tissue homeostasis and repair. This project aimed to investigate in vivo the development and functions of macrophages, which have considerable phenotypic and functional diversity depending on their tissue of residence and pathophysiological conditions. Because this diversity is not well understood, the functions of macrophages in vivo have not been well characterized. In contrast to hematopoietic stem cells (HSC)-derived macrophages, Resident macrophages are generated from yolk sac progenitors, expand and differentiate within developing seeded tissues, and self-maintain in adults independently of HSC. Thus, two lineages of macrophages coexist in most adult tissues. The overall objectives of the project were to characterize (i) the developmental trajectory of yolk sac progenitors, at the single-cell level in vivo, (ii) how macrophage networks are maintained and, (iii) the specific function of resident macrophage during tissue repair/regeneration.
First, we elucidated the heterogeneity of HSC-independent progenitors that emerge from the yolk sac and characterized their niche-specific developmental pathways when committing and differentiating into erythrocytes, megakaryocytes, mast cells, neutrophils and macrophages. Importantly, we found that HSC-independent erythromyeloid progenitors (EMP) sustain the production of red blood and myeloid cells until birth, with little to no input from HSC. Second, we demonstrated that low grade chronic inflammation was responsible for the loss of HSC-independent macrophages over time without hampering their proliferative capacities. And lastly, we have characterized macrophage ontogeny and functions during placental organogenesis, skin wound healing and after myocardial infarction.
The results from this project have laid the foundation of a new framework to understand how the immune system contributes to the developmental origins of health and disease, by focusing on transient hematopoietic progenitors and their long-lived progeny, the tissue resident macrophages. Finally, uncovering the developmental pathways and molecular mechanisms involved in these fetal progenitors will contribute to improve of understanding of pediatric disorders.