Most tissues of the body harbor resident macrophages. Yet, macrophages are phenotypically and functionally heterogeneous, a reflection of the diversity of tissue environments in which they reside. In addition to maintaining tissue homeostasis and responding to invading pathogens, macrophages contribute to numerous pathological processes, making them an attractive potential target for therapeutic intervention. To do so, however, will require a detailed understanding of macrophage origins, the mechanisms that maintain them, and their functional attributes in different tissues and disease contexts.Macrophage ontology has long engendered controversy 1,2 . Nevertheless, the concept that tissue macrophages develop exclusively from circulating bone marrow-derived monocytes has prevailed for nearly a half century 3 . Accumulated evidence, however, including recent studies using sophisticated fate-mapping approaches, have determined that some tissue macrophages and their precursors are established embryonically in the yolk sac (YS) and fetal liver before the onset of definitive hematopoiesis [4][5][6][7][8][9][10][11] . Regardless of their origin, tissue macrophages can maintain themselves in adulthood by self-renewal independent of blood monocytes 12,13 .Gene-expression profiling of macrophage populations from several tissues has established that only a small number of transcripts are expressed by all macrophages 14 , indicating the importance of the context provided by the tissue when studying macrophage function in homeostasis and disease. The normal arterial wall contains many tissue resident macrophages that contribute crucially to immunity, tissue homeostasis and wound healing following injury
15. However, the regulatory networks, ancestry and mechanisms that maintain arterial macrophages remain unknown.Using gene expression analysis, we show that arterial macrophages constitute a distinct population among tissue macrophages. Multiple fate mapping approaches demonstrated that arterial macrophages arise embryonically from CX 3 CR1 + precursors and postnatally from bone marrow-derived monocytes that colonize the tissue during a brief period immediately after birth.In adulthood, arterial macrophages were maintained by CX 3 CR1-CX 3 CL1 interactions and local proliferation without significant further contribution from blood monocytes. Self-renewal also sustained arterial macrophages after severe depletion during polymicrobial sepsis, rapidly restoring them to functional homeostasis.
ResultsPhenotype and gene expression profiling of arterial macrophages. (Fig. 1a).Principal component analysis revealed a distinct transcriptome in arterial macrophages, which clustered near other macrophage populations including microglia, alveolar macrophages, and splenic red pulp macrophages, as characterized by the Immunological Genome Consortium (Fig. 1b, Supplementary Fig. 1a)
14. Stringent comparison of gene-expression profiles among arterial, brain, alveolar and splenic red pulp macrophages revealed 212 transcripts that were at ...