Project description:While the roles of parenchymal microglia in brain homeostasis and disease are fairly clear, other brain-resident myeloid cells remain less understood. By dissecting border regions and combining single-cell RNA sequencing with high-dimensional cytometry, bulk RNA-sequencing, fate-mapping and microscopy, we reveal the diversity of non-parenchymal brain macrophages. Border-associated macrophages (BAMs) residing in the dura mater, subdural meninges and choroid plexus consisted of distinct subsets with tissue-specific transcriptional signatures, and their cellular composition changed during postnatal development. BAMs exhibited a mixed ontogeny and subsets displayed distinct self-renewal capacities upon depletion and repopulation. Single-cell and fate-mapping analysis both suggested there is a unique microglial subset residing on the apical surface of the choroid plexus epithelium. Finally, gene network analysis and conditional deletion revealed IRF8 as a master regulator that drives the maturation and diversity of brain macrophages. Our results provide a framework for understanding host-macrophage interactions in the healthy and diseased brain.

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.

Project description:Immune response following CNS disease and injury comprises three different compartments, parenchymal, perivascular and blood involving specialized immune cells. Microglia are the major immune cell residing in the CNS parenchymal compartment but together with other macrophages which are residing in the non-parenchymal structures such as perivascular spaces, leptomeninges and choroid plexus constitute the total macrophage population of the CNS. While the homeostatic functions of these specialized macrophages in not very well understood, evidence shows that these macrophages at the blood-brain interface might involve immune-surveillance and establish a gate way for the recruitment of peripheral immune cells in to the CNS in response to the pathological stimuli. In humans and rats these macrophages identified exclusively by the high levels of scavenger receptor CD163

Project description:A mouse model of maternal immune activation (MIA) is commonly used to study neurodevelopmental disorders. Gene expression analysis has suggested that fetal brain macrophages may be activated by MIA, but it is unclear whether these transcriptional changes connect to behavioral phenotypes in offspring. Here, we have shown that the induction of autism spectrum disorder (ASD)-like behavioral phenotypes by MIA in male offspring is dependent upon fetal activation of the toll-like receptor 3 (TLR3) signaling molecule TRIF. Using single-cell RNA sequencing, we identified a cluster of border-associated macrophages (BAMs) that was significantly enriched in wild-type fetal brains following TLR3-MIA but not diminished in Trif -/- fetal brains. Moreover, after TLR3-MIA, the number of fetal BAMs in the choroid plexus, but not in the meninges, was increased, and these cells were characterized by increased S100a8/9 expression. Finally, we proposed that activation of fetal TLR3-TRIF signaling was induced by transplacental viral infection. Overall, our data suggest that fetal TLR3 signaling contributes to MIA-induced ASD-like behavioral phenotypes in mice.

Project description:The immune cells of the central nervous system (CNS) comprise parenchymal microglia and at the CNS border regions meningeal, perivascular and choroid plexus macrophages (summarized as CNS-associated macrophages, CAMs). Previous work has uncovered that microglial properties are strongly dependent on environmental signals from the commensal microbiota while its effect on CAMs remained unknown. By combining several microbiota manipulation approaches, genetic mouse models and single-cell RNA-sequencing, we comprehensively characterized CNS myeloid cell composition and function. Under steady-state, the transcriptional profile and numbers of choroid plexus macrophages were found to be tightly steered by complex microbiota. Divergently, perivascular and meningeal macrophages were affected to a lesser extent. An acute perturbation through viral infection evoked an attenuated immune response of all CAMs in germ-free mice. Additionally, we assessed CAMs in a more chronic pathological state in 5xFAD mice as a model for Alzheimer’s disease whereby exclusively perivascular macrophages displayed enhanced amyloid beta uptake in GF 5xFAD mice. Our results provide novel insights for understanding distinct microbiota-CNS macrophage interactions during health and perturbation that could potentially be targeted therapeutically.

Project description:Gene expression profiles generated from human tumor cells laser-microdissected from surgical samples of seven choroid plexus papillomas (Grade I WHO) as eight samples of epithelial cells lasermicrodissected from normal choroid plexus obtained at autopsy. Choroid plexus tumors are rare pediatric brain tumors derrived from the choroid plexus epithelium. Gene expression profiles of lasermicrodissected tumor cells from 7 individual choroid plexus tumor samples obtained at surgery were compared to gene expression profiles from non-neoplastic choroid plexus epithelial cells lasermicrodissected from normal non-neoplastic choroid plexus obtained at autopsy (Am J Surg Pathol. 2006 Jan;30(1):66-74.) in order to identfy genes differentially expressed in choroid plexus tumor cells.

Project description:Parenchymal border macrophages regulate CSF flow dynamics [brain]

Project description:The choroid plexus produces cerebrospinal fluid (CSF) by transport of electrolytes and water from the vasculature to the brain ventricles. The choroid plexus plays additional roles in brain development and homeostasis by secreting neurotrophic molecules, and by serving as a CSF-blood barrier and immune interface. Prior studies have identified transporters on the epithelial cells that transport water and ions into the ventricles and tight junctions involved in the CSF-blood barrier. Yet, how the choroid plexus epithelial cells maintain the brain ventricle system and control brain physiology remain unresolved. To provide novel insights into the physiological roles of the choroid plexus, we use juvenile and adult zebrafish as model systems. Upon histological and transcriptomic analyses, we first identified that the zebrafish choroid plexus is highly conserved with the mammalian choroid plexus and that it expresses all transporters necessary for CSF secretion. Using novel genetic lines, we also identified that the choroid plexus secretes proteins into the CSF. Next, we generated a transgenic line allowing us to ablate specifically the epithelial cells in the choroid plexus. Using the ablation system, we identified a reduction of the ventricular sizes, but no alterations of the CSF-blood barrier. Altogether, our findings identified that the zebrafish choroid plexus is evolutionarily conserved and critical for maintaining the size and homeostasis of the brain ventricles.

Project description:Microglia and border-associated macrophages (BAMs) are brain-resident self-renewing cells with important homeostatic functions. However, their fate during and after severe episodes of brain inflammation and their relation to recruited monocyte-derived cells remain poorly understood. Here, we show that Trypanosoma brucei parasites invade the brain via its border regions, triggering a disruption of brain barriers and the recruitment of large numbers of monocytes. Fate-mapping combined with single-cell sequencing revealed the remarkable dynamics of resident macrophages, including microglia accumulation around the ventricular ependyma and an expansion of epiplexus cells. Resident macrophages were important for attracting peripheral immune cells and driving a pro-inflammatory response. However, recruited monocyte-derived macrophages reached higher cell densities and exhibited more transcriptional plasticity, adopting anti-microbial gene expression profiles not observed resident macrophages. Remarkably, recruited macrophages were short-lived and rapidly removed upon disease resolution, while activated resident macrophages progressively reverted towards a homeostatic state. Long-term transcriptional alterations were limited for microglia but more pronounced in BAMs. Together our results reveal the diverging responses and dynamics of resident and recruited macrophages upon Trypanosome invasion of the brain.