Ongoing Production of Tissue-Resident Macrophages from Hematopoietic Stem Cells in Healthy Adult Macaques

Abstract

AbstractMacrophages are critical orchestrators of tissue immunity, from the initiation and resolution of antimicrobial immune responses to the subsequent repair of damaged tissue. Murine studies have demonstrated that tissue-resident macrophages are comprised of a mixture of yolk sac-derived cells that populate the tissue before birth and hematopoietic-derived replacements that are recruited in adult tissues both at steady-state and in increased numbers in response to tissue damage or infection. While resident macrophages in some murine tissues are readily turned over and replaced, other tissues primarily retain their original, yolk sac-derived complement of macrophages. How this translates to species that are constantly under immunologic challenge, such as humans, is unknown. To understand the ontogeny and longevity of tissue-resident macrophages in nonhuman primates (NHPs), we employ a model of autologous HSPC transplantation with HSPCs genetically modified to express individual bar-coded markers allowing for subsequent analysis of clonal differentiation of leukocyte subsets. We study the contribution of HSPC to tissue-macrophages and their clonotypic profiles relative to leukocyte subsets across tissues and peripheral blood. We also use in vivo bromodeoxyuracil infusions to monitor tissue macrophage turnover in NHPs at steady state. We find that, in all anatomic sites we studied, HSPC contribute to tissue-resident macrophage populations. Their clonotypic profile is dynamic and overlaps significantly with the clonal hierarchy of contemporaneous monocytes in peripheral blood. Moreover, we find evidence of tissue-macrophage turnover at steady state in otherwise unmanipulated NHPs. These data demonstrate the life span of tissue-resident macrophages can be limited and they can be replenished from HSPCs. Thus, in primates not all yolk-sac derived tissue-macrophages survive for the duration of the host’s life.