Project description:Although most tissue macrophages are embryonically derived it is evident that circulating monocytes can compete for virtually any macrophage niche. Monocytes can thus become long-lived replacements of tissue macrophages that are indistinguishable from their embryonic counterparts, but the factors regulating this process are incompletely understood. To study niche competition in the CNS we depleted microglia with >95% efficiency using CX3CR1CreER/+R26DTA/+ mice and monitored long-term repopulation. The microglial niche was repopulated within weeks by a combination of local microglia proliferation giving rise to CX3CR1+F4/80lowClec12a– microglia, as well as infiltration of CX3CR1+F4/80hiClec12a+ macrophages. Adoptive transfer experiments demonstrated that peripherally-derived macrophages arose directly from Ly6Chi monocytes without contribution from hematopoietic progenitors and was independent of BBB breakdown. After repopulation we sorted microglia and monocyte-derived macrophages and performed transcriptional, epigenetic (DNA methylation) and ex vivo functional profiling. This revealed that Ly6Chi monocytes upregulated microglia gene expression and adopted microglia DNA methylation signatures. However, in contrast to proliferating microglia, which rapidly regained their homeostatic gene signature, monocyte-derived macrophages retained a distinct gene signature associated with antigen presentation, interferon signaling and chemotaxis. This translated into functional changes in monocyte-derived macrophages, as demonstrated by differences in surface marker expression, phagocytosis and cytokine production. Our results demonstrate that monocytes are imprinted by the CNS microenvironment but remain transcriptionally, epigenetically and functionally distinct. This may have implications for neuroinflammatory disease states and direct design of novel therapies.

Project description:Although most tissue macrophages are embryonically derived it is evident that circulating monocytes can compete for virtually any macrophage niche. Monocytes can thus become long-lived replacements of tissue macrophages that are indistinguishable from their embryonic counterparts, but the factors regulating this process are incompletely understood. To study niche competition in the CNS we depleted microglia with >95% efficiency using CX3CR1CreER/+R26DTA/+ mice and monitored long-term repopulation. The microglial niche was repopulated within weeks by a combination of local microglia proliferation giving rise to CX3CR1+F4/80lowClec12a– microglia, as well as infiltration of CX3CR1+F4/80hiClec12a+ macrophages. Adoptive transfer experiments demonstrated that peripherally-derived macrophages arose directly from Ly6Chi monocytes without contribution from hematopoietic progenitors and was independent of BBB breakdown. After repopulation we sorted microglia and monocyte-derived macrophages and performed transcriptional, epigenetic (DNA methylation) and ex vivo functional profiling. This revealed that Ly6Chi monocytes upregulated microglia gene expression and adopted microglia DNA methylation signatures. However, in contrast to proliferating microglia, which rapidly regained their homeostatic gene signature, monocyte-derived macrophages retained a distinct gene signature associated with antigen presentation, interferon signaling and chemotaxis. This translated into functional changes in monocyte-derived macrophages, as demonstrated by differences in surface marker expression, phagocytosis and cytokine production. Our results demonstrate that monocytes are imprinted by the CNS microenvironment but remain transcriptionally, epigenetically and functionally distinct. This may have implications for neuroinflammatory disease states and direct design of novel therapies. Data was processed using the mEPIC tool PMID:29141580

Project description:Competitive repopulation of an empty microglial yields functionally distinct subsets of microglia-like cells

Project description:Competitive repopulation of an empty microglial niche gives rise to functionally distinct subsets of microglia-like cells

Project description: Not available

Project description:28d Regular Repop Study: Two-month-old male C57BL/6 (Jax 000664) were maintained on control diet for 35 days (control) or treated for 7 days with PLX3397 (600 ppm) diet, then to stimulate repopulation PLX3397 placed with control diet for 28 days (28d Recovery). Mice were sacrificed and myeloid cells were extracted from whole hemispheres. RNA was extracted from single-cell suspensions generated from fluorescence-activated cell sorting (FACS) gating for CD11b+CD45int cells. SVZ Study: Two-month-old male C57BL/6 (Jax 000664) were maintained on control diet for 19 days (control), treated for 14 days with PLX3397 (600 ppm) diet (microglial elimination), or treated for 14 days with PLX3397 (600 ppm) diet and then placed on control diet for 5 days (5d recovery). Mice were sacrificed and the subventricular zone was micro-dissected for RNA isolation. 28d Alt Repop +/- LPS Study: Two-month-old male C57BL/6 (Jax 000664) were maintained on control diet for 35 days (control) or treated for 14 days with PLX3397 (600 ppm) diet and then placed on control diet for 28 days (28d Recovery). At 6 or 24 hours (hr) prior to sacrifice, lipopolysaccharide (LPS; 0.33 mg/kg body weight) was administered via intraperitoneal injection. Some mice did not receive an LPS injection and serve as controls (0 hr). Mice were sacrificed and myeloid cells were extracted from whole hemispheres. RNA was extracted from single-cell suspensions generated from fluorescence-activated cell sorting (FACS) gating for CD11b+CD45int cells.

Project description: Not available

Project description: Not available

Project description: Not available

Project description: Not available