Project description:Unilateral whisker lesioning at age P4 leads to removal of thalamocortical synapses in layer IV of the barrel cortex over the course of the next 6 days. Synapse removal is mediated by microglia and induced by CX3CL1-CX3CR1 signaling between neurons and microglia. Downstream of CX3CL1-CX3CR1 activation, microglia induce astrocyte morphological changes. To identify molecular crosstalk between astrocytes and microglia, we performed translating ribosome affinty purification followed by RNA sequencing (TRAP-Seq).

Project description:Synapse loss and glial activation are hallmarks of Alzheimer's disease (AD). In Tau P301S transgenic mice, the complement pathway contributes to neuronal damage through microglial elimination of synapses. Here, we used unbiased proteomic profiling of postsynaptic density (PSD) fractions from Tau P301S mice in C1q-WT versus C1q knockout backgrounds to identify C1q-dependent changes at synapses. Integrative multi-omics analysis revealed that astrocyte- and microglia- specific proteins are increased in Tau P301S synapse fractions with age and in a C1q-dependent manner. The same set of glial proteins (including C1q, C4, Gpnmb, and S100a4) is elevated in human AD synaptic fractions, and C4 levels are raised in cerebrospinal fluid (CSF) from AD patients. Besides microglia, we show that astrocytes contribute substantially to excitatory and inhibitory synapse engulfment in Tau P301S hippocampus. Based on staining of synapse markers within lysosomes, astrocytes showed preference for excitatory synapses whereas microglia preferred to engulf inhibitory synapse markers. Genetic deletion of C1q reduced astrocytic eating of excitatory and inhibitory synapses in Tau P301S mice, and rescued synapse density. Together, our data indicate that astrocytes contact and phagocytose synapses in a C1q- dependent manner and thereby contribute to synapse loss and neurodegeneration in AD.

Project description:Unilateral whisker lesioning at age P4 leads to removal of thalamocortical synapses in layer IV of the barrel cortex over the course of the next 6 days. Synapse removal is mediated by microglia and induced by CX3CL1-CX3CR1 signaling between neurons and microglia. Downstream of CX3CL1-CX3CR1 activation, microglia induce astrocyte morphological changes and activation of canonical Wnt signaling in astrocytes. To explore the spatial pattern of microglia Wnt ligand expression and astrocyte Wnt receptor expression in astrocytes, we analyzed coronal sections containing the barrel cortex from 4 wild-type mice and 4 CX3CL1 knockout mice at 24 hours after whisker lesioning by multiplexed error-robust fluorescent in situ hybridization (MERFISH).

Project description:Astrocyte derived Hevin regulates formation and maintenance of excitatory thalamocortical synapses in the developing mouse cortex. However, the role of astrocyte secreted factors on other cell types is still understudied. To interrogate the response of microglia to the release of astrocye derived Hevin, astrocytes were virally transduced with AAVs to overexpress Hevin or mCherry-CAAX.

Project description:Cell surface receptors, including erythropoietin-producing hepatocellular A4 (EphA4), are important in regulating hippocampal synapse loss, which is the key driver of memory decline in Alzheimer’s disease (AD). However, the cellular-specific roles and mechanisms of EphA4 are unclear. Here, we show that EphA4 expression is elevated in hippocampal CA1 astrocytes in AD conditions. Specific knockout of astrocytic EphA4 ameliorates excitatory synapse loss in the hippocampus in AD transgenic mouse models. Single-nucleus RNA sequencing analysis revealed that EphA4 inhibition specifically decreases a reactive astrocyte subpopulation with enriched complement signaling, which are characteristics associated with synapse elimination by astrocytes in AD. Importantly, astrocytic EphA4 knockout in an AD transgenic mouse model decreases complement tagging on excitatory synapses and excitatory synapses within astrocytes. These findings suggest an important role of EphA4 in the astrocyte-mediated elimination of excitatory synapses in AD and highlight the crucial role of astrocytes in hippocampal synapse maintenance in AD.

Project description:Cell surface receptors, including erythropoietin-producing hepatocellular A4 (EphA4), are important in regulating hippocampal synapse loss, which is the key driver of memory decline in Alzheimer’s disease (AD). However, the cellular-specific roles and mechanisms of EphA4 are unclear. Here, we show that EphA4 expression is elevated in hippocampal CA1 astrocytes in AD conditions. Specific knockout of astrocytic EphA4 ameliorates excitatory synapse loss in the hippocampus in AD transgenic mouse models. Single-nucleus RNA sequencing analysis revealed that EphA4 inhibition specifically decreases a reactive astrocyte subpopulation with enriched complement signaling, which are characteristics associated with synapse elimination by astrocytes in AD. Importantly, astrocytic EphA4 knockout in an AD transgenic mouse model decreases complement tagging on excitatory synapses and excitatory synapses within astrocytes. These findings suggest an important role of EphA4 in the astrocyte-mediated elimination of excitatory synapses in AD and highlight the crucial role of astrocytes in hippocampal synapse maintenance in AD.

Project description:Neuron-microglia interactions dictate the development of neuronal circuits in the brain. However, the factors that support and broadly regulate these processes across developmental stages are largely unknown. Here, we find that IL34, a neuron-derived cytokine, is upregulated in development and plays a critical role in supporting and maintaining neuroprotective, mature microglia in the anterior cingulate cortex (ACC) of mice. We show that IL34 mRNA and protein is upregulated in neurons in the second week of postnatal life and that this increase coincides with increases in microglia number and expression of mature, homeostatic markers, e.g., TMEM119. We also found that IL34 mRNA is higher in excitatory (compared to inhibitory) neurons. Global genetic KO of IL34 reduced microglia numbers and prevented the functional maturation of microglia, and excitatory-neuron specific KO of IL34 similarly impacted microglia and increased aberrant microglial phagocytosis of excitatory thalamocortical synapses in the ACC. Acute, low dose blocking of IL34 at postnatal day (P)15 in mice decreased microglial TMEM119 protein and also increased microglial phagocytosis of excitatory thalamocortical synapses during an inappropriate time in development. In contrast, viral overexpression of IL34 early in life (P1-P8) caused early maturation of microglia and prevented microglial phagocytosis of thalamocortical synapses during the appropriate neurodevelopmental refinement window. Taken together, these findings establish IL34 as a key regulator of neuron microglia crosstalk in postnatal brain development, controlling both microglial maturation and synapse engulfment.

Project description:Neuroinflammation and synapse loss synergistically contribute to cognitive decline in Alzheimer’s disease (AD). Although microglial hyper-phagocytic activity has been shown to mediate synapse loss, the exact mechanisms underlying these pathologies remain obscure. Here, we first demonstrate that astrocytes and microglia increase the phagocytic elimination of excitatory synapses, but significantly decrease their elimination of inhibitory synapses during AD progression, suggesting neuroinflammation may be dispensable for early AD synapse loss. Instead, through single-nucleus RNA sequencing (snRNAseq), we identified Disease-Initiating Excitatory Neurons (DIENs), characterized by ectopic Erbb4 expression, as the earliest alteration in an AD mouse model. Notably, specific deletion of Erbb4 in 5XFAD excitatory neurons abrogated abnormal neuro-network activities and synapse loss, as well as reactive gliosis, amyloid plaque deposition, and cognitive deficits. Conversely, overexpression of Erbb4 in wild-type excitatory neurons recapitulated key AD phenotypes, including cognitive impairment. Subsequent snRNAseqs following Erbb4 deletion and overexpression confirm that excitatory neuronal Erbb4 is both sufficient and necessary to induce DIEN and reactive gliosis. Together, these findings reveal that the early pathophysiology of AD arises largely due to aberrant Erbb4 expression in excitatory neurons, and that targeting excitatory neuronal Erbb4 may thus represent a novel therapeutic strategy for mitigating AD progression.

Project description:Neuronal synapse formation and remodeling is essential to central nervous system (CNS) development and is dysfunctional in neurodevelopmental diseases. Innate immune signals regulate tissue remodeling in the periphery, but how this impacts CNS synapses is largely unknown. Here we show that the IL-1 family cytokine Interleukin-33 (IL-33) is produced by developing astrocytes and is developmentally required for normal synapse numbers and neural circuit function in the spinal cord and thalamus. We find that IL-33 signals primarily to microglia under physiologic conditions, that it promotes microglial synapse engulfment, and that it can drive microglial-dependent synapse depletion in vivo. These data reveal a cytokine-mediated mechanism required to maintain synapse homeostasis during CNS development.

Project description:Neuronal synapse formation and remodeling is essential to central nervous system (CNS) development and is dysfunctional in neurodevelopmental diseases. Innate immune signals regulate tissue remodeling in the periphery, but how this impacts CNS synapses is largely unknown. Here we show that the IL-1 family cytokine Interleukin-33 (IL-33) is produced by developing astrocytes and is developmentally required for normal synapse numbers and neural circuit function in the spinal cord and thalamus. We find that IL-33 signals primarily to microglia under physiologic conditions, that it promotes microglial synapse engulfment, and that it can drive microglial-dependent synapse depletion in vivo. These data reveal a cytokine-mediated mechanism required to maintain synapse homeostasis during CNS development.