Project description:In the context of neurodegeneration, activated microglia facilitate inflammation via secretion of TNF-α, IL-1α, and C1q. Astrocytes exposed to this signaling array polarize to a reactive inflammatory phenotype, termed A1 or A1-like. Astrocytes are essential for neuronal survival, synaptic support, and blood-brain barrier (BBB) function, but A1-like astrocytes upregulate inflammatory gene expression, downregulate neurotrophic factors, and secrete neurotoxic signals. The consequences of A1-like polarization on BBB function are unknown but may have etiological implications for some diseases. Frequently identified by upregulation of complement component 3 (C3), A1-like astrocytes have been characterized in neurodegenerative disorders like Alzheimer’s disease, with polarization correlated with disease progression and severity. However, the role of A1-like astrocytes in neurodegeneration associated with chronic viral infections, like HIV-1-associated neurocognitive disorder (HAND), remains unclear. An in vitro system using primary human astrocytes, as well as a BBB model featuring primary human brain microvascular endothelial cells (BMECs) co-cultured with astrocytes, was used to elucidate cellular and molecular consequences of chronic astrocyte activation. As measured by whole transcriptome analysis and protein expression assays, repeated treatment with TNF-α, IL-1α, and C1q induced A1-like polarization of astrocytes both in monoculture and in a BBB model, resulting in increased secretion of pro-inflammatory signals. No substantial change to BBB permeability was observed. In contrast, exposure to HIV-1 viral protein Tat did not independently induce A1-like polarization. Ongoing investigations into the effect of astrocyte polarization on BBB integrity and treatment with pathogenic proteins may provide insights into the role of neurotoxic astrocytes in neuroviral pathologies.

Project description:Ischemic stroke (IS) is one of the most serious neurological diseases, characterized by high mortality and disability rates. Glia cells, particularly microglia and astrocytes, occupy a pivotal position in the progression of IS. In response to stroke, microglia undergo polarization, transforming into either pro-inflammatory M1 phenotype or anti-inflammatory M2 phenotype. Analogously, astrocytes would polarize to pro-inflammatory A1 phenotype or anti-inflammatory A2 phenotype. It has been documented that A1 astrocytes can be activated by M1 microglia, although precise underlying mechanism remains elusive. In our study, we emulated ischemic injury using a middle cerebral artery occlusion/reperfusion (MCAO/R) model in mice and an oxygen-glucose deprivation/reoxygenation (OGD/R) model in primary astrocytes. Our findings revealed that M1 microglia could activate A1 astrocytes by secreting exosomes. According to RNA sequencing, circSTRN3 was enriched in M1 microglia-derived exosomes. Based on the review of literature and bioinformatics analysis, it was suggested that circSTRN3 could sponge miR-331-5p, while miR-331-5p could bind to MAVS and participate in the activation of NF-kB pathway and A1 astrocytes. Western blotting and qRT-PCR experiments verified this process. Furtherly, overexpression of circSTRN3 could aggravate neurological deficits, increase infarct volume, and promote cell death in MCAO/R model, whereas miR-331-5p inhibited this process. Furthermore, we conducted tests on circSTRN3 and miR-331-5p in exosomes isolated from the peripheral blood of IS patients, thereby confirming the correlation among circSTRN3, miR-331-5p, and the stroke severity score. Taken together, our study indicated that M1 microglia-derived exosomes could promote A1 astrocyte activation and exacerbate ischemic brain injury through the circSTRN3-miR331-5P/MAVS/NF-KB pathway.

Project description:The blood-brain barrier (BBB) consists of specific physical barriers, enzymes and transporters, which together maintain the necessary extracellular environment of the central nervous system (CNS). The main physical barrier is found in the CNS endothelial cell, and depends on continuous complexes of tight junctions combined with reduced vesicular transport. Other possible constituents of the BBB include extracellular matrix, astrocytes and pericytes, but the relative contribution of these different components to the BBB remains largely unknown. Here we demonstrate a direct role of pericytes at the BBB in vivo. Using a set of adult viable pericyte-deficient mouse mutants we show that pericyte deficiency increases the permeability of the BBB to water and a range of low-molecular-mass and high-molecular-mass tracers. The increased permeability occurs by endothelial transcytosis, a process that is rapidly arrested by the drug imatinib. Furthermore, we show that pericytes function at the BBB in at least two ways: by regulating BBB-specific gene expression patterns in endothelial cells, and by inducing polarization of astrocyte end-feet surrounding CNS blood vessels. Our results indicate a novel and critical role for pericytes in the integration of endothelial and astrocyte functions at the neurovascular unit, and in the regulation of the BBB. The brain microvascular fragments were isolated from mice with different genotypes, each represented by 3-4 biological replicates. Genotypes 1-2: Platelet derived growth factor-B (PDGF-B) retention-motif knockout (pdgfbret/ret) represent the pericyte-deficient situation, and the heterozygous mice (pdgfbret/+) are used as controls. Genotypes 3-4: Hypomorphic PDGF-B mutants that rescue pdgfb-/- null mice, in which a one copy of a conditionally silent human PDGF-B transgene targeted to the Rosa 26 locus (R26P) is turned on by endothelial-specific expression of Cre recombinase. In this data set these mice are named as Tie2Cre, R26P+/0, pdgfb-/- (representing the pericyte-deficient situation). Mice wt for pdgfb (pdgfb+/+) and carrying one silent copy of R26P (R26P+/0), are used as controls. Genotype 5: Adult Notch3+/+ wildtype (WT).

Project description:The blood-brain barrier (BBB) consists of specific physical barriers, enzymes and transporters, which together maintain the necessary extracellular environment of the central nervous system (CNS). The main physical barrier is found in the CNS endothelial cell, and depends on continuous complexes of tight junctions combined with reduced vesicular transport. Other possible constituents of the BBB include extracellular matrix, astrocytes and pericytes, but the relative contribution of these different components to the BBB remains largely unknown. Here we demonstrate a direct role of pericytes at the BBB in vivo. Using a set of adult viable pericyte-deficient mouse mutants we show that pericyte deficiency increases the permeability of the BBB to water and a range of low-molecular-mass and high-molecular-mass tracers. The increased permeability occurs by endothelial transcytosis, a process that is rapidly arrested by the drug imatinib. Furthermore, we show that pericytes function at the BBB in at least two ways: by regulating BBB-specific gene expression patterns in endothelial cells, and by inducing polarization of astrocyte end-feet surrounding CNS blood vessels. Our results indicate a novel and critical role for pericytes in the integration of endothelial and astrocyte functions at the neurovascular unit, and in the regulation of the BBB.

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:The brain vasculature is tightly regulated to control the exchange of substances between the periphery and the brain parenchyma at an interface called the blood-brain barrier (BBB). Astrocytes are glial cells that wrap the brain vasculature with a specialised structure called the endfoot, which is an integral component of the BBB. We generated adeno-associated viruses (AAVs) that express a promiscuous biotin ligase, TurboID, specifically in astrocytes, and developed a method that allows us to define the in vivo protein composition of the astrocyte endfoot with negligible contamination of other cells or other compartments of the astrocyte. Here, we isolated the biotinylated proteins from both the whole astrocyte and astrocyte endfeet from mice with acute peripheral inflammation.

Project description:Extrinsic inhibitors at sites of blood-brain barrier (BBB) disruption and neurovascular damage contribute to remyelination failure in neurological diseases. However, therapies to overcome extrinsic inhibition of remyelination are not widely available and the dynamics of glial progenitor niche remodeling at site of neurovascular dysfunction are largely unknown. By integrating in vivo two-photon (2P) imaging co-registered with electron microscopy and transcriptomics in chronic neuroinflammatory lesions, we found repressed anticoagulation pathways in oligodendrocyte precursor cells (OPCs) that clustered perivascularly at sites of limited remyelination with deposition of fibrinogen, a blood coagulation factor abundantly deposited in multiple sclerosis lesions. By developing the OPC-X-screen to identify compounds that promote remyelination in the presence of extrinsic inhibitors, we showed that known promyelinating drugs did not rescue extrinsic inhibition of remyelination by fibrinogen. In contrast, bone morphogenetic protein (BMP) receptor blockade rescued the inhibitory fibrinogen effects and restored a promyelinating progenitor niche by promoting myelinating oligodendrocytes, while suppressing astrocyte cell fate with potent therapeutic effects in chronic models of multiple sclerosis. Thus, abortive OPC differentiation by fibrinogen is refractory to known promyelinating compounds, suggesting that blockade of the BMP signaling pathway may enhance remyelinating efficacy by overcoming extrinsic inhibition in neuroinflammatory lesions with vascular damage.

Project description:Modulating M1/M2 polarization is a potential therapy for treating ischemic stroke. Repetitive transcranial magnetic stimulation (rTMS) held the capacity to regulate astrocytic polarization, but little is known about rTMS effects on microglia. Therefore, the present study aimed to investigate whether and how rTMS influence microglia polarization in ischemic stroke models. The 10-Hz rTMS was applied to transient middle cerebral artery occlusion (MCAO) rats and oxygen and glucose deprivation/ reoxygenation injured BV2 cells. Western blot, immunofluorescence and ELISA were used to detect M1/M2 markers. High-throughput sequencing, RT-PCR and FISH staining were adopted to test microRNA changes. The 10-Hz rTMS inhibited ischemia/reperfusion induced M1 microglia and significantly increased let-7b-5p. HMGA2 was proved to be the target protein of let-7b-5p and its downstream NF-κB signaling pathway were inhibited by rTMS. Microglia culture medium (MCM) collected from rTMS treated microglia had low TNF-α but high IL-10 concentration, leading to reduced neural death, minor ischemic volumes and improved functional recovery of MCAO animals. However, knockdown of let-7b-5p by antagomir reversed rTMS effects on microglia. In conclusion, high-frequency rTMS could improve functional recovery through inhibiting M1 microglia polarization via regulating let-7b-5p/HMGA2/NF-κB signaling pathway in cerebral ischemic stroke models.

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, especially in females. 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 female mice. Hippocampus were isolated from ob/ob and C57BL/6J female 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-depth bioinformatic analyses.

Project description:Function and integrity of the blood-brain-barrier (BBB) is crucial for brain homeostasis, and its malfunction critically contributes to neurovascular and neurodegenerative disorders, including cerebral small vessel disease (SVD), a common cause of stroke and vascular dementia. So far, mechanistic studies on BBB function have been mostly conducted in mice and non-physiological in vitro models, which recapitulate disease features, but often lack complex phenotypes, have limited translatability to humans, and pose challenges for drug discovery. Therefore, we aimed to establish a fully iPSC-derived 3D model of the human blood-brain-barrier. To characterize and validate our somatic cell differentiation protocols we compared our iPSC-derived cells with commercially available human primary cells: brain microvascular endothelial cells (pEC), human umbilical vein endothelial cells (HUVEC), brain vascular pericytes (pPC), brain vascular smooth muscle cells (pSMC) and midbrain astrocytes (pAS).