Project description:Microglia arise from yolk sac progenitors and are thought to persist throughout life with minimal input from adult hematopoiesis. However, whether brain-engrafted monocyte-derived macrophages (MDM) exist at homeostasis and during turnover, and how they function relative to yolk sac-derived microglia (YSM) remain unsettled. Here, we combine lineage tracing, pharmacological microglia depletion, and multi-omics profiling to define the ontogeny, identity, and function of brain parenchymal macrophages. Despite sharing the parenchymal milieu, MDM display transcriptional and epigenetic landscapes distinct from YSM. Fate-mapping reveals that brain-engrafted MDM transiently express CD206, echoing a developmental stage of microglial precursors. MDM engraftment and polarization are modulated by IL-34 and CCR2. Furthermore, parabiosis and skull‑flap transplantation reveal that both blood and skull marrow supply the niche, yielding origin‑biased MDM states. Functionally, MDM engraftment enhanced cuprizone-mediated demyelination. Together, our study defines the origins, molecular features, and context-dependent roles of brain parenchymal macrophages across homeostasis, turnover, and CNS pathology.

Project description:Microglia arise from yolk sac progenitors and are thought to persist throughout life with minimal input from adult hematopoiesis. However, whether brain-engrafted monocyte-derived macrophages (MDM) exist at homeostasis and during turnover, and how they function relative to yolk sac-derived microglia (YSM) remain unsettled. Here, we combine lineage tracing, pharmacological microglia depletion, and multi-omics profiling to define the ontogeny, identity, and function of brain parenchymal macrophages. Despite sharing the parenchymal milieu, MDM display transcriptional and epigenetic landscapes distinct from YSM. Fate-mapping reveals that brain-engrafted MDM transiently express CD206, echoing a developmental stage of microglial precursors. MDM engraftment and polarization are modulated by IL-34 and CCR2. Furthermore, parabiosis and skull‑flap transplantation reveal that both blood and skull marrow supply the niche, yielding origin‑biased MDM states. Functionally, MDM engraftment enhanced cuprizone-mediated demyelination. Together, our study defines the origins, molecular features, and context-dependent roles of brain parenchymal macrophages across homeostasis, turnover, and CNS pathology.

Project description:Microglia arise from yolk sac progenitors and are thought to persist throughout life with minimal input from adult hematopoiesis. However, whether brain-engrafted monocyte-derived macrophages (MDM) exist at homeostasis and during turnover, and how they function relative to yolk sac-derived microglia (YSM) remain unsettled. Here, we combine lineage tracing, pharmacological microglia depletion, and multi-omics profiling to define the ontogeny, identity, and function of brain parenchymal macrophages. Despite sharing the parenchymal milieu, MDM display transcriptional and epigenetic landscapes distinct from YSM. Fate-mapping reveals that brain-engrafted MDM transiently express CD206, echoing a developmental stage of microglial precursors. MDM engraftment and polarization are modulated by IL-34 and CCR2. Furthermore, parabiosis and skull‑flap transplantation reveal that both blood and skull marrow supply the niche, yielding origin‑biased MDM states. Functionally, MDM engraftment enhanced cuprizone-mediated demyelination. Together, our study defines the origins, molecular features, and context-dependent roles of brain parenchymal macrophages across homeostasis, turnover, and CNS pathology.

Project description:Microglia arise from yolk sac (YS) progenitors and are thought to persist throughout life with minimal input from adult hematopoiesis. However, whether brain-engrafted monocyte-derived macrophages (MDM) exist at homeostasis and during turnover, and how they function relative to yolk sac-derived microglia (YSM) remain unsettled. Here, we combine lineage tracing, pharmacological microglia depletion, and multi-omics profiling to define the ontogeny, identity, and function of MDM in the mouse brain. Despite sharing the parenchymal milieu, MDM display unique transcriptional and epigenetic landscapes distinct from YSM. Fate-mapping reveals that newly engrafted MDM transiently express CD206, echoing a developmental stage of embryonic microglial precursors. The engraftment and polarization of MDM are modulated by the CSF1R ligand IL 34 and the chemokine receptor CCR2. Furthermore, parabiosis and skull‑flap transplantation reveal that both blood and skull marrow supply the niche via distinct routes, yielding origin‑biased MDM states. Functionally, engraftment of MDM exacerbates cuprizone-mediated demyelination. Together, our study reveals the cellular dynamics of brain parenchymal macrophages at homeostasis and during turnover. We define the core molecular features and heterogeneous origins of MDM and imply their context-dependent roles in CNS pathology.

Project description:Microglia arise from yolk sac (YS) progenitors and are thought to persist throughout life with minimal input from adult hematopoiesis. However, whether brain-engrafted monocyte-derived macrophages (MDM) exist at homeostasis and during turnover, and how they function relative to yolk sac-derived microglia (YSM) remain unsettled. Here, we combine lineage tracing, pharmacological microglia depletion, and multi-omics profiling to define the ontogeny, identity, and function of MDM in the mouse brain. Despite sharing the parenchymal milieu, MDM display unique transcriptional and epigenetic landscapes distinct from YSM. Fate-mapping reveals that newly engrafted MDM transiently express CD206, echoing a developmental stage of embryonic microglial precursors. The engraftment and polarization of MDM are modulated by the CSF1R ligand IL 34 and the chemokine receptor CCR2. Furthermore, parabiosis and skull‑flap transplantation reveal that both blood and skull marrow supply the niche via distinct routes, yielding origin‑biased MDM states. Functionally, engraftment of MDM exacerbates cuprizone-mediated demyelination. Together, our study reveals the cellular dynamics of brain parenchymal macrophages at homeostasis and during turnover. We define the core molecular features and heterogeneous origins of MDM and imply their context-dependent roles in CNS pathology.

Project description:Microglia are yolk sac-derived macrophages residing in the parenchyma of brain and spinal cord, where they interact with neurons and other glial cells by constantly probing their surroundings with dynamic extensions. After different conditioning paradigms and bone marrow (BM) or hematopoietic stem cell (HSC) transplantation, graft-derived cells seed the brain and persistently contribute to the parenchymal brain macrophage compartment. Here we establish that graft-derived macrophages acquire, over time, microglia characteristics, including ramified morphology, longevity, radio-resistance and clonal expansion. However, even after prolonged CNS residence, transcriptomes and chromatin accessibility landscapes of engrafted, BM-derived macrophages remain distinct from yolk sac-derived host microglia. Furthermore, engrafted BM-derived cells display discrete responses to peripheral endotoxin challenge, as compared to host microglia. In human HSC transplant recipients, engrafted cells also remain distinct from host microglia, extending our finding to clinical settings. Collectively, our data emphasize the molecular and functional heterogeneity of parenchymal brain macrophages and highlight potential clinical implications for HSC gene therapies aimed to ameliorate lysosomal storage disorders, microgliopathies or general monogenic immuno-deficiencies.

Project description:Microglia are yolk sac-derived macrophages residing in the parenchyma of brain and spinal cord, where they interact with neurons and other glial cells by constantly probing their surroundings with dynamic extensions. After different conditioning paradigms and bone marrow (BM) or hematopoietic stem cell (HSC) transplantation, graft-derived cells seed the brain and persistently contribute to the parenchymal brain macrophage compartment. Here we establish that graft-derived macrophages acquire, over time, microglia characteristics, including ramified morphology, longevity, radio-resistance and clonal expansion. However, even after prolonged CNS residence, transcriptomes and chromatin accessibility landscapes of engrafted, BM-derived macrophages remain distinct from yolk sac-derived host microglia. Furthermore, engrafted BM-derived cells display discrete responses to peripheral endotoxin challenge, as compared to host microglia. In human HSC transplant recipients, engrafted cells also remain distinct from host microglia, extending our finding to clinical settings. Collectively, our data emphasize the molecular and functional heterogeneity of parenchymal brain macrophages and highlight potential clinical implications for HSC gene therapies aimed to ameliorate lysosomal storage disorders, microgliopathies or general monogenic immuno-deficiencies.

Project description:Microglia are thought to originate exclusively from primitive macrophage progenitors in the yolk sac (YS) and persist throughout life without contributions from definitive hematopoiesis. Here, using Ms4a3-Cre lineage tracing, pharmacological manipulation, and RNA-sequencing, we elucidated the presence and unique features of monocyte-derived macrophages (MDMs) in the brain parenchyma at baseline and during microglia repopulation. Using parabiosis and skull transplantation, we show that MDMs derived from both peripheral blood and skull bone marrow can repopulate microglia-depleted brains, and they display distinct transcriptional profiles compared to YS-derived microglia. Blood-derived macrophages possess a disease-associated microglia (DAM)-like phenotype, while skull-derived macrophages mirror injury-responsive microglia (IRM) and exhibit significant interactions with T cells. Repetitive microglia depletion and subsequent MDM engraftment in 5xFAD mice led to increased amyloid burden, suggesting differential responses of resident microglia and MDMs towards amyloid pathology. Our results reveal the heterogeneous origins and functions of microglia during cell turnover and neurodegeneration, offering insights that may guide microglia-targeted immunomodulatory strategies for neurological disorders.

Project description:Central nervous system (CNS) macrophages comprise parenchymal microglia and border-associated macrophages (BAMs) residing in the meninges, the choroid plexus and the perivascular spaces. With the exception of choroid plexus macrophages, most CNS macrophages emerge during primitive hematopoiesis in the extra-embryonic yolk sac. What remains unknown however, is whether microglia and BAMs share a developmental program or arise from separate predefined lineages. Here, we identified two phenotypically, transcriptionally and locally distinct brain macrophage populations throughout development, giving rise to microglia and BAMs. Two independent macrophage populations were already present in the yolk sac prior to their seeding of the brain. Using fate-mapping system, we demonstrate that in contrast to microglia, the pool of embryonic BAMs in the choroid plexus and the meninges was gradually replaced by precursors emerging later in embryogenesis. The development of microglia was dependent on TGF-β whereas the genesis and maturation of BAMs occurred independently of this cytokine. Collectively, our data show that developing parenchymal and non-parenchymal brain macrophages are separate entities in terms of ontogeny, gene expression signatures and requirement for TGF-β.

Project description:Central nervous system (CNS) macrophages comprise parenchymal microglia and border-associated macrophages (BAMs) residing in the meninges, the choroid plexus and the perivascular spaces. With the exception of choroid plexus macrophages, most CNS macrophages emerge during primitive hematopoiesis in the extra-embryonic yolk sac. What remains unknown however, is whether microglia and BAMs share a developmental program or arise from separate predefined lineages. Here, we identified two phenotypically, transcriptionally and locally distinct brain macrophage populations throughout development, giving rise to microglia and BAMs. Two independent macrophage populations were already present in the yolk sac prior to their seeding of the brain. Using fate-mapping system, we demonstrate that in contrast to microglia, the pool of embryonic BAMs in the choroid plexus and the meninges was gradually replaced by precursors emerging later in embryogenesis. The development of microglia was dependent on TGF-β whereas the genesis and maturation of BAMs occurred independently of this cytokine. Collectively, our data show that developing parenchymal and non-parenchymal brain macrophages are separate entities in terms of ontogeny, gene expression signatures and requirement for TGF-β.