Project description:The contribution of resident brain and meningeal cells in facilitating brain metastasis remains underappreciated. Here, we characterise the pre-metastatic molecular changes that occur in brain and meningeal resident cells in mouse models of breast cancer using single-cell and spatial transcriptomics. Increased inflammatory alterations preceding metastasis were identified in bridging veins spanning the leptomeninges, forming adhesion hotspots by upregulating Icam1 and Vcam1. Furthermore, bridging veins and encapsulating leptomeningeal fibroblasts upregulate cell trafficking ligands, including chemokines. Brain metastasising tumour cells correspondingly upregulate adhesion counter-receptor LFA-1 and chemokine receptors, demonstrating an enhanced capacity to traffic towards altered brain vessels and stroma. Moreover, PD-L1+ immunosuppressive neutrophils infiltrate the dura and brain, coupled with upregulation of checkpoint molecule PD-1 in CD8+ T cells. Neutrophils furthermore upregulate VEGFA, driving angiogenesis and vascular remodelling. These results indicate that breast cancers can drive multiple alterations in the leptomeningeal and dural vasculature that collectively facilitate formation of brain metastases.

Project description:Meningeal immune cells monitor the central nervous system (CNS) and influence neuroinflammation in mice, but the human leptomeningeal immune landscape and the changes that occur in this immunological niche in neurodegeneration remain underexplored. We performed single-cell RNA and T cell receptor (TCR) sequencing of 99,625 high-quality immune cells from 57 leptomeninges and brain samples from donors with Alzheimer’s disease (AD), amyotrophic lateral sclerosis, and Parkinson’s disease and found that while the leptomeninges are home to highly clonally expanded CD8 tissue-resident memory (TRM) T cells, the maximal level of clonal expansion was decreased in AD in comparison to non-neurodegenerative controls. Intra-patient paired tissue analysis further revealed that brain and leptomeningeal TCR repertoires share significant similarities, but tissue-specific clones emerge in AD. Finally in AD, the degree of CD8 TRM clonal expansion was positively correlated with microglial TGFB2, suggesting that brain and leptomeningeal immune cells coordinate their activities in AD. In addition to identifying key inflammatory dynamics in the human degenerating CNS, this study establishes a foundational resource for future studies that could inform treatment for AD and other neuroinflammatory diseases.

Project description:The meninges are a set of connective tissue layers that surround the central nervous system, protecting the brain from mechanical shock, supporting its buoyancy, guarding it from infection and injury, and maintaining brain homeostasis. Despite their critical role, the molecular identity, developmental origins, and functional properties of the cell types populating the meninges remain poorly characterized. This is in large part due to lack of cell type specific markers and difficulty in visualizing and studying these structures through the thick mammalian skull. Here, we show that the zebrafish, a genetically and experimentally accessible vertebrate, possesses an easily imaged mammalian-like meninges. Anatomical and cellular characterization of its composition via histology, electron microscopy, and confocal imaging shows that the adult zebrafish possesses complex multilayered meninges with double-layered dura mater and intricate leptomeningeal layers. Using single cell transcriptomics, we define the molecular identities of meningeal cell populations, including a unique ependymin (epd)-expressing cell population that constitutes the major cellular component of the leptomeningeal barrier and is essential for brain development and survival. These findings support the use of zebrafish as a useful comparative model for studying the meninges, provide a foundational description for future zebrafish meningeal research, and identify a new Leptomeningeal Barrier Cell that serves as the primary epithelial cell component of the leptomeninges.

Project description:The mechanisms of communication between the brain and the neighboring meningeal immune cells are still unclear. Here we characterized the resident group 1 innate lymphoid cells in the meninges of adult mice, and identified ILC1/NK cell-derived interferon- and acetylcholine as mediators involved in the modulation of brain circuitries underlying anxiety-like behavior and memory. This discloses a new meningeal-to-brain communication mechanism that modulates brain functions under physiological conditions.

Project description:Leptomeningeal metastasis is a rare type of brain metastasis without effective therapeutic guidelines. Herein, we report emergency Ommaya capsule implantation performed for treating meningeal metastases from parathyroid carcinoma in a patient with intracranial hypertension. A 52-year-old woman was admitted to our hospital with recurrent headaches for 2 months and episodic vertigo for 2 days. The patient was hospitalised but did not exhibit abnormal intracranial signals. As her symptoms did not improve following transfer, the patient was diagnosed with a meningeal tumour, with a high suspicion of metastasis from parathyroid cancer. Conservative treatment was ineffective, and her symptoms worsened with severe headaches and shortness of breath.

Project description:In newborn mouse, systemic bacterial infection damages the brain even in the absence of direct bacterial invasion. However, the early immune reactions by intracranial tissues remain an enigma. We injected lipopolysaccharide (LPS) intraperitoneally into 7-day-old mice to induce systemic inflammation. Brains were removed and dissociated 24 h after LPS injection, and CD11b(+) cells were isolated using the magnetic-activated cell sorting. Total RNA samples were extracted from the brain CD11b(+) cells and were analyzed with Gene Expression Microarray. The results indicated that the transcript expressions of the following nine genes were strikingly increased: Saa3, Saa1, Saa2, Cxcl13, Ccl5, Irg1, Cxcl9, Lcn2, and Slfn4. In situ hybridization indicated that Saa 3, 2, and 1, Cxcl13, Irg1, and Ccl5 were expressed by macrophages in the meningeal and perivascular space and choroid plexus, whereas Cxcl9 and Lcn2 were expressed by arachnoid, pial, and perivascular fibroblasts. In conclusion, immune reactions of the brain to systemic inflammation were initiated by leptomeningeal and choroid plexus macrophages and leptomeningeal and perivascular fibroblasts in postnatal mice.

Project description:Aging is a major risk factor for many neurological pathologies, including Alzheimer’s disease (AD). However, the mechanisms underlying brain aging and cognitive decline remain elusive. Body tissues are perfused by interstitial fluid (ISF), which is locally reabsorbed via the lymphatic vascular network. In contrast, the parenchyma of the central nervous system (CNS) is devoid of lymphatic vasculature; in the brain, removal of cellular debris and toxic molecules, such as amyloid beta (A) peptides, is mediated by a combination of transcellular mechanisms of transport across the blood−brain and blood−cerebrospinal fluid (CSF) barriers, phagocytosis and digestion by resident microglia and recruited monocytes/macrophages, and CSF influx and ISF efflux through a paravascular route. The recent characterization of meningeal lymphatic vessels prompted a reassessment of the conventional pathways of CNS waste clearance. The role of this vasculature in brain function, specifically in the context of aging and AD, is still poorly understood. Here we show that meningeal lymphatic vessels play an essential role in maintaining brain homeostasis by draining macromolecules from the CNS (CSF and ISF) into the cervical lymph nodes. Using pharmacological, surgical, and genetic models we show that impairment of meningeal lymphatic function in adult mice slows paravascular influx of CSF macromolecules and efflux of ISF macromolecules, and induces cognitive impairment. Treatment with a lymphangiogenic factor, vascular endothelial growth factor C (VEGF-C), enhances meningeal lymphatic drainage of CSF macromolecules, improving brain perfusion and learning and memory performance in aged mice. Disruption of meningeal lymphatic vessels in transgenic mouse models of AD promotes amyloid deposition in the meninges, which closely correlates with human meningeal pathology, and aggravates overall disease severity. Our findings suggest that meningeal lymphatic dysfunction may be an aggravating factor in AD pathology and in age-associated cognitive decline. Thus, augmentation of meningeal lymphatic function might be a promising therapeutic target for preventing or delaying age-associated neurological diseases.

Project description:Aging is a major risk factor for many neurological pathologies, including Alzheimer’s disease (AD). However, the mechanisms underlying brain aging and cognitive decline remain elusive. Body tissues are perfused by interstitial fluid (ISF), which is locally reabsorbed via the lymphatic vascular network. In contrast, the parenchyma of the central nervous system (CNS) is devoid of lymphatic vasculature; in the brain, removal of cellular debris and toxic molecules, such as amyloid beta (A) peptides, is mediated by a combination of transcellular mechanisms of transport across the blood−brain and blood−cerebrospinal fluid (CSF) barriers, phagocytosis and digestion by resident microglia and recruited monocytes/macrophages, and CSF influx and ISF efflux through a paravascular route. The recent characterization of meningeal lymphatic vessels prompted a reassessment of the conventional pathways of CNS waste clearance. The role of this vasculature in brain function, specifically in the context of aging and AD, is still poorly understood. Here we show that meningeal lymphatic vessels play an essential role in maintaining brain homeostasis by draining macromolecules from the CNS (CSF and ISF) into the cervical lymph nodes. Using pharmacological, surgical, and genetic models we show that impairment of meningeal lymphatic function in adult mice slows paravascular influx of CSF macromolecules and efflux of ISF macromolecules, and induces cognitive impairment. Treatment with a lymphangiogenic factor, vascular endothelial growth factor C (VEGF-C), enhances meningeal lymphatic drainage of CSF macromolecules, improving brain perfusion and learning and memory performance in aged mice. Disruption of meningeal lymphatic vessels in transgenic mouse models of AD promotes amyloid deposition in the meninges, which closely correlates with human meningeal pathology, and aggravates overall disease severity. Our findings suggest that meningeal lymphatic dysfunction may be an aggravating factor in AD pathology and in age-associated cognitive decline. Thus, augmentation of meningeal lymphatic function might be a promising therapeutic target for preventing or delaying age-associated neurological diseases.

Project description:Aging is a major risk factor for many neurological pathologies, including Alzheimer’s disease (AD). However, the mechanisms underlying brain aging and cognitive decline remain elusive. Body tissues are perfused by interstitial fluid (ISF), which is locally reabsorbed via the lymphatic vascular network. In contrast, the parenchyma of the central nervous system (CNS) is devoid of lymphatic vasculature; in the brain, removal of cellular debris and toxic molecules, such as amyloid beta (A) peptides, is mediated by a combination of transcellular mechanisms of transport across the blood−brain and blood−cerebrospinal fluid (CSF) barriers, phagocytosis and digestion by resident microglia and recruited monocytes/macrophages, and CSF influx and ISF efflux through a paravascular route. The recent characterization of meningeal lymphatic vessels prompted a reassessment of the conventional pathways of CNS waste clearance. The role of this vasculature in brain function, specifically in the context of aging and AD, is still poorly understood. Here we show that meningeal lymphatic vessels play an essential role in maintaining brain homeostasis by draining macromolecules from the CNS (CSF and ISF) into the cervical lymph nodes. Using pharmacological, surgical, and genetic models we show that impairment of meningeal lymphatic function in adult mice slows paravascular influx of CSF macromolecules and efflux of ISF macromolecules, and induces cognitive impairment. Treatment with a lymphangiogenic factor, vascular endothelial growth factor C (VEGF-C), enhances meningeal lymphatic drainage of CSF macromolecules, improving brain perfusion and learning and memory performance in aged mice. Disruption of meningeal lymphatic vessels in transgenic mouse models of AD promotes amyloid deposition in the meninges, which closely correlates with human meningeal pathology, and aggravates overall disease severity. Our findings suggest that meningeal lymphatic dysfunction may be an aggravating factor in AD pathology and in age-associated cognitive decline. Thus, augmentation of meningeal lymphatic function might be a promising therapeutic target for preventing or delaying age-associated neurological diseases.

Project description:The interface between the brain surface and the adjacent meninges is a selective barrier regulating fluid, protein and immune cell exchange between the CNS and periphery. However, the cell types that form this important interface are not yet fully defined. To address this limitation, we have used single cell RNA-sequencing (scRNA-seq) and single cell spatial transcriptomics together with morphological lineage tracing and immunostaining to analyze the adult murine cortex. We show that the cortical interface is comprised of three major cell types, leptomeningeal cells, border astrocytes and tissue-resident macrophages. On the peripheral side the interface is comprised of transcriptionally-distinct PDGFRα-positive leptomeningeal mesenchymal cells that are intermingled with macrophages. This leptomeningeal pial layer is lined by a population of transcriptionally-distinct border astrocytes. The interface neighborhood is rich in growth factor mRNAs, including many leptomeningeal ligands predicted to act on both the border astrocytes and macrophages. On the CNS side of the interface is the relatively cellsparse cortical layer one containing interneurons, microglia, parenchymal astrocytes, oligodendrocyte precursor cells and oligodendrocytes. Except for the border astrocytes, layer one cells are not closely-associated with the interface, suggesting that secreted ligands may be the major way the brain interface communicates with the underlying cortical parenchyma. Thus, our data provide a molecular/cellular resource describing the brain interface cell types and their interactions, thereby enabling future studies asking how this distinct cellular compartment regulates CNS:periphery interactions.