Project description:Neurovascular unit (NVU) communications guide vascular patterning, BBB maturation, and neuronal homeostasis, yet whether these interactions differ across brain regions during development remains unclear. Here, we combine spatial transcriptomics with region-resolved endothelial single-cell RNA sequencing to map cortical and thalamic NVU communication dynamics. We uncover spatiotemporal divergence of endothelial programs and show that neuronal and glial maturation parallels region-specific angiogenic trajectories. We identify neuronal–endothelial TGFβ2 signaling as an essential regulator of thalamic vascularization during a critical postnatal period. Loss of endothelial TGFβR1 signaling leads to mTOR hyperactivation and thalamus-predominant vascular malformations and hemorrhage within this developmental window, and these defects are rescued by mTOR inhibition. Together, these findings show that circuit maturation and region-specific NVU communication programs coordinate postnatal angiogenesis and vascular maturation, providing a framework for understanding regional vulnerability in neurovascular disorders.

Project description:Neurovascular interactions (NVIs) are critical in establishing vascular patterning, barrier function, and in regulating cerebral blood flow, thereby maintaining neuronal homeostasis and brain health. While developmental programs and neuronal activity play a central role in cerebral cortex angiogenesis during a critical postnatal period, whether cellular heterogeneity causes region-specific angiogenic regulation remains unknown. Here, we combine spatial and endothelial single-cell RNAseq (scRNAseq) transcriptomic analysis to establish a molecular atlas of developing brain regions and a comprehensive list of spatiotemporal-specific NVIs. We find that the thalamic area has a higher vascular density than the other brain regions and our atlas identifies transforming growth factor β (Tgfβ) and Vegfc ligands enrichment in this area during a critical postnatal period. Neonatal endothelial Tgfβr1 deletion (Tgfβr1iEKO) induces vascular malformations and hemorrhages, primarily in the thalamic area. Mechanistically, we show that loss of endothelial TGFβ signaling increases VEGFC-induced AKT/mTOR signaling in vitro and in vivo, and that mTOR inhibitor Rapamycin efficiently inhibits intracerebral bleeding and vascular defects in Tgfβr1iEKO mice. Altogether, our data suggest that spatiotemporal-specific NVIs control brain vascular heterogeneity, which extends our knowledge of region-specific cerebrovascular development and will benefit our understanding of neurovascular disorders.

Project description:The neurovascular unit (NVU) plays a crucial role in maintaining brain functions by integrating vascular cells, neurons, and glia to ensure metabolic support and blood-brain barrier integrity. While vascular dysfunction has been implicated in Alzheimer's disease (AD), the specific contributions of various vascular cell types remain understudied, partly due to challenges in isolating these cells from post-mortem tissue. In this study, we analyzed prefrontal cortex tissue from AD patients and control subjects using single-nuclei RNA sequencing to create a high-resolution atlas capturing major vascular and parenchymal cell types. Our findings reveal distinct associations between AD risk and gene expression profiles specific to pericytes, perivascular fibroblasts, and activated microglia. Functional analyses indicate that these genes converge on amyloid-related pathways, suggesting that perivascular compartments and immune modulators play significant roles in the early stages of AD pathobiology. Additionally, we identified a new endothelial-mesenchymal transition population that is diminished in AD, indicating a potential disruption in endothelial plasticity that may contribute to vascular dysfunction. Key ligand-receptor interactions between vascular and parenchymal cell types, such as ANGPT2, were found to be markedly dysregulated, highlighting potential targets that could drive NVU breakdown in AD. These findings provide a comprehensive framework for evaluating NVU cells in human disease and underscore novel links between vascular dynamics and AD pathogenesis. The study offers valuable insights into disease mechanisms and suggests new therapeutic avenues aimed at protecting and restoring the brain's neurovascular interface.

Project description:In vitro neuronal models are essential for studying neurological physiology, disease mechanisms and potential treatments. Most in vitro models lack controlled vasculature, despite its necessity in brain physiology and disease. Organ-on-chip models offer microfluidic culture systems with dedicated micro-compartments for neurons and vascular cells. Such multi-cell type organs-on-chips can emulate neurovascular unit (NVU) physiology, however there is a lack of systematic data on how individual cell types are affected by culturing on microfluidic systems versus conventional culture plates. This information can provide perspective on initial findings of studies using organs-on-chip models, and further optimizes these models in terms of cellular maturity and neurovascular physiology. Here, we analysed the transcriptomic profiles of co-cultures of human induced pluripotent stem cell (hiPSC)-derived neurons and rat astrocytes, as well as one-day monocultures of human endothelial cells, cultured on microfluidic chips. For each cell type, large gene expression changes were observed when cultured on microfluidic chips compared to conventional culture plates. Endothelial cells showed decreased cell division, neurons and astrocytes exhibited increased cell adhesion, and neurons showed increased maturity when cultured on a microfluidic chip. Our results demonstrate that culturing NVU cell types on microfluidic chips changes their gene expression profiles, presumably due to distinct surface-to-volume ratios and substrate materials. These findings inform further NVU organ-on-chip model optimization and support their future application in disease studies and drug testing.

Project description:The neurovascular unit (NVU) is a complex multicellular structure that helps maintain cerebral homeostasis and blood-brain barrier (BBB) integrity. While extensive evidence links NVU alterations to cerebrovascular diseases and neurodegeneration, the underlying molecular mechanisms remain unclear. Here, we use zebrafish embryos carrying a mutation in Scavenger Receptor B2, a highly conserved endolysosomal protein expressed predominantly in Radial Glia Cells (RGCs), to investigate the interplay among different NVU components. Through live imaging and genetic manipulations, we demonstrate that compromised acidification of the endolysosomal compartment in mutant RGCs leads to impaired Notch3 signaling, thereby inducing excessive neurogenesis and reduced glial differentiation. We further demonstrate that alterations to the neuron/glia balance result in impaired VEGF and Wnt signaling, leading to severe vascular defects, hemorrhages, and a leaky BBB. Altogether, our findings provide novel insights into NVU formation and function and offer new avenues for investigating diseases involving white matter defects and vascular abnormalities. The neurovascular unit (NVU) is a complex multicellular structure that helps maintain cerebral homeostasis and blood-brain barrier (BBB) integrity. While extensive evidence links NVU alterations to cerebrovascular diseases and neurodegeneration, the underlying molecular mechanisms remain unclear. Here, we use zebrafish embryos carrying a mutation in Scavenger Receptor B2, a highly conserved endolysosomal protein expressed predominantly in Radial Glia Cells (RGCs), to investigate the interplay among different NVU components. Through live imaging and genetic manipulations, we demonstrate that compromised acidification of the endolysosomal compartment in mutant RGCs leads to impaired Notch3 signaling, thereby inducing excessive neurogenesis and reduced glial differentiation. We further demonstrate that alterations to the neuron/glia balance result in impaired VEGF and Wnt signaling, leading to severe vascular defects, hemorrhages, and a leaky BBB. Altogether, our findings provide novel insights into NVU formation and function and offer new avenues for investigating diseases involving white matter defects and vascular abnormalities. The neurovascular unit (NVU) is a complex multicellular structure that helps maintain cerebral homeostasis and blood-brain barrier (BBB) integrity. While extensive evidence links NVU alterations to cerebrovascular diseases and neurodegeneration, the underlying molecular mechanisms remain unclear. Here, we use zebrafish embryos carrying a mutation in Scavenger Receptor B2, a highly conserved endolysosomal protein expressed predominantly in Radial Glia Cells (RGCs), to investigate the interplay among different NVU components. Through live imaging and genetic manipulations, we demonstrate that compromised acidification of the endolysosomal compartment in mutant RGCs leads to impaired Notch3 signaling, thereby inducing excessive neurogenesis and reduced glial differentiation. We further demonstrate that alterations to the neuron/glia balance result in impaired VEGF and Wnt signaling, leading to severe vascular defects, hemorrhages, and a leaky BBB. Altogether, our findings provide novel insights into NVU formation and function and offer new avenues for investigating diseases involving white matter defects and vascular abnormalities.

Project description:Alzheimer’s disease is the most common form of dementia and is associated with the accumulation of amyloid peptide β in the brain parenchyma. Vascular damage and microvascular thrombosis contribute to the neuronal degeneration and the loss of brain function typical of this disease. In this study, we utilised a murine model of Alzheimer’s disease to evaluate the neurovascular effects of this disease. Upon detection of an increase in the phosphorylation of the endothelial surface receptor VE-cadherin, we focused our attention on endothelial cells.

Project description:The blood-brain barrier (BBB) plays important roles in brain tumor pathogenesis and treatment response, yet our understanding of its function and heterogeneity within or across brain tumor types remains poorly characterized. Here we analyze the neurovascular unit (NVU) of pediatric high-grade glioma (pHGG) and diffuse midline glioma (DMG) using patient derived xenografts and natively forming glioma mouse models. We show tumor-associated vascular differences between these glioma subtypes, and parallels between PDX and mouse model systems, with DMG models maintaining a more normal vascular architecture, BBB function and endothelial transcriptional program relative to pHGG models. Unlike prior work in angiogenic brain tumors, we find that expression of secreted Wnt antagonists do not alter the tumor-associated vascular phenotype in DMG tumor models. Together, these findings highlight vascular heterogeneity between pHGG and DMG and differences in their response to alterations in developmental BBB signals that may participate in driving these pathological differences.

Project description:Proper formation of the complex neurovascular unit (NVU) along with the blood-brain barrier is critical for building and sustaining a healthy, functioning central nervous system. The RNA binding protein argonaute2 (Ago2) mediates microRNA (miRNA)–mediated gene silencing, which is critical for many facets of brain development, including NVU development. Here, we found that Ago2 in glutamatergic neurons was critical for NVU formation in the developing cortices of mice. Glutamatergic neuron–specific loss of Ago2 diminished synaptic formation, neuronal-to-endothelial cell contacts, and morphogenesis of the brain vasculature, ultimately compromising the integrity of the blood-brain barrier. Ago2 facilitated miRNA targeting of phosphatase and tensin homolog (Pten) mRNA, which encodes a phosphatase that modulates reelin-dependent phosphatidylinositol 3-kinase (PI3K)–Akt signaling within the glutamatergic subpopulation. Conditionally deleting Pten in Ago2-deficient neurons restored Akt2 phosphorylation as well as postnatal development and survival. Several mutations in AGO2 impair small RNA silencing and are associated with Lessel-Kreienkamp syndrome, a neurodevelopmental disorder. When expressed in a neuronal cell line, these human AGO2 loss-of-function variants failed to suppress PTEN, resulting in attenuated PI3K-Akt signaling, further indicating that dysregulation of Ago2 function may contribute to both impaired development and neurological disorders. Together, these results identify Ago2 as central to the engagement of neurons with blood vessels in the developing brain.

Project description:Obesity is a global pandemic and a key risk factor for several neurodegenerative diseases including Alzheimer’s disease (AD), Parkinson’s disease, or dementia. The neurovascular unit (NVU), essential for blood-brain barrier (BBB) integrity and comprised of endothelial cells, glial cells (microglia and astrocytes), and neurons, plays an important role in the pathogenesis of neurodegenerative diseases. However, molecular mechanisms underlying the effects of obesity on endothelial and other cells of and its contribution to neurodegeneration remains largely unknown. In this study we aimed to decipher in-dept molecular modifications induced by obesity in cells of neurovascular unit by integrative multiomics analysis of endothelial cells, neurons, microglial cells, and astrocytes from the hippocampus of ob/ob mice. Hippocampus were isolated from ob/ob and C57BL/6J male mice at 17-18 weeks of age. Gene expression profiles of cells of hippocampus were obtained using single nuclei RNA sequencing (snRNAseq) and data analyzed using in-dept bioinformatic analyses. snRNAseq and UMAP analysis revealed 19 cell types in hippocampus. Comparisons of global gene expression profiles identified different global profiles between ob/ob and WT for each of the cell types of the NVU. Statistical analyses revealed 4463 DEGs in neuronal cells, 1386 DEGs in astrocytes, 125DEGs in endothelial cells, and 155 DEGs in microglia cells, suggesting that obesity significantly impacts the expression profiles of NUV cells. Enrichment analyses revealed that these genes are involved in cellular processing like focal adhesion, cell interactions, inflammation, and metabolism. Changes in the expression in endothelial cells were positively correlated with genomic changes in other cell types, changes that we correlated with tendency in increase in BBB observed using functional MRI. Taken together, obesity exert significant cell-specific changes in global gene expression, genes that are associated with development of Alzheimer’s disease or dementia.

Project description:While the neuronal underpinnings of autism spectrum disorders (ASD) are being unraveled, vascular contributions to ASD remain elusive. Here, we investigated postnatal cerebrovascular development in the 16p11.2df/+ mouse model of 16p11.2 deletion ASD syndrome. We discovered that 16p11.2 hemizygosity leads to male-specific, endothelium-dependent structural and functional neurovascular abnormalities. In 16p11.2df/+ mice, endothelial dysfunction resulted in impaired cerebral angiogenesis at postnatal day (P) 14, and in altered neurovascular coupling and cerebrovascular reactivity at P50. Moreover, we showed defective angiogenesis in primary 16p11.2df/+ mouse brain endothelial cells and in iPSC-derived endothelial cells from human 16p11.2 deletion carriers. Finally, we found that mice with endothelium-specific 16p11.2 deletion (16p11.2DEC) partially recapitulated some behavioral changes seen in 16p11.2 syndrome, specifically hyperactivity and impaired motor learning. By showing that developmental 16p11.2 haploinsufficiency from endothelial cells results in neurovascular and behavioral changes in adults, our results point to a potential role for endothelial impairment in ASD.