Project description:INPP5D, which encodes the lipid phosphatase SHIP1, is one of the most common genes associated with the risk of Alzheimer’s disease and is enriched in microglia in the central nervous system. SHIP1 has been found to be highly expressed in plaque-associated microglia. However, how it regulates microglial function and influences brain physiology has been poorly investigated. Here we show that SHIP1 is not only enriched in microglia associated with amyloid beta plaques, but also in early stages of healthy brain development. By combining in vivo loss-of-function approaches and proteomics, we discovered that conditional knockout mice lacking microglial SHIP1 (cKO) display increased complement and synapse loss in the early postnatal brain. Additionally, SHIP1 KO microglia show reduced morphological complexity, altered transcriptional signatures, and abnormal synaptic pruning, which is dependent on the complement system. Single nucleus RNA-sequencing analysis of the entire hippocampus confirmed decreased interaction for synaptic structure-related pathways in both excitatory and inhibitory neurons. Importantly, cKO mice show cognitive defects in adulthood only when microglial SHIP1 is depleted at early postnatal days, but not when depleted at later stages. Finally, using CRISPR/Cas9 we generated human iPSC-derived microglia lacking SHIP1, and validated the increased engulfment of synaptic structures. Altogether, these findings suggest that SHIP1 is essential for proper microglia-mediated synapse remodeling through the complement system in the early postnatal brain. Disrupting this process has lasting behavioral effects and may provide a link to vulnerability to neurodegeneration.

Project description:INPP5D, which encodes the lipid phosphatase SHIP1, is one of the most common genes associated with the risk of Alzheimer’s disease and is enriched in microglia in the central nervous system. SHIP1 has been found to be highly expressed in plaque-associated microglia. However, how it regulates microglial function and influences brain physiology has been poorly investigated. Here we show that SHIP1 is not only enriched in microglia associated with amyloid beta plaques, but also in early stages of healthy brain development. By combining in vivo loss-of-function approaches and proteomics, we discovered that conditional knockout mice lacking microglial SHIP1 (cKO) display increased complement and synapse loss in the early postnatal brain. Additionally, SHIP1 KO microglia show reduced morphological complexity, altered transcriptional signatures, and abnormal synaptic pruning, which is dependent on the complement system. Single nucleus RNA-sequencing analysis of the entire hippocampus confirmed decreased interaction for synaptic structure related pathways in both excitatory and inhibitory neurons. Importantly, cKO mice show cognitive defects in adulthood only when microglial SHIP1 is depleted at early postnatal days, but not when depleted at later stages. Finally, using CRISPR/Cas9 we generated human iPSC-derived microglia lacking SHIP1, and validated the increased engulfment of synaptic structures. Altogether, these findings suggest that SHIP1 is essential for proper microglia-mediated synapse remodeling through the complement system in the early postnatal brain. Disrupting this process has lasting behavioral effects and may provide a link to vulnerability to neurodegeneration.

Project description:INPP5D, which encodes the lipid phosphatase SHIP1, is one of the most common genes associated with the risk of Alzheimer’s disease and is enriched in microglia in the central nervous system. SHIP1 has been found to be highly expressed in plaque-associated microglia. However, how it regulates microglial function and influences brain physiology has been poorly investigated. Here we show that SHIP1 is not only enriched in microglia associated with amyloid beta plaques, but also in early stages of healthy brain development. By combining in vivo loss-of-function approaches and proteomics, we discovered that conditional knockout mice lacking microglial SHIP1 (cKO) display increased complement and synapse loss in the early postnatal brain. Additionally, SHIP1 KO microglia show reduced morphological complexity, altered transcriptional signatures, and abnormal synaptic pruning, which is dependent on the complement system. Single nucleus RNA-sequencing analysis of the entire hippocampus confirmed decreased interaction for synaptic structure-related pathways in both excitatory and inhibitory neurons. Importantly, cKO mice show cognitive defects in adulthood only when microglial SHIP1 is depleted at early postnatal days, but not when depleted at later stages. Finally, using CRISPR/Cas9 we generated human iPSC-derived microglia lacking SHIP1, and validated the increased engulfment of synaptic structures. Altogether, these findings suggest that SHIP1 is essential for proper microglia-mediated synapse remodeling through the complement system in the early postnatal brain. Disrupting this process has lasting behavioral effects and may provide a link to vulnerability to neurodegeneration.

Project description: Not available

Project description:Several experiments have shown that mechanical forces significantly influence the initiation, growth, and retraction of neurites of cultured neurons. A similar role has long been suggested for mechanical forces in vivo, but this hypothesis has remained unverified due to the paucity of in vivo studies of neuronal mechanical behavior. In this study, we used high-resolution micromechanical force sensors to study the mechanical response of motor neurons in live Drosophila embryos. Our experiments showed that Drosophila neurons maintained a rest tension (1-13 nN) and behaved like viscoelastic solids (i.e., with a linear force-deformation response followed by force relaxation to steady state) in response to sustained stretching. More importantly, when the tension was suddenly diminished by a release of the externally applied force, the neurons contracted and actively generated force to restore tension, sometimes to a value close to their rest tension. In addition, axons that were slackened by displacing the neuromuscular junction contracted and became taut in 10-30 min. These observations are remarkably similar to results from in vitro studies and suggest that mechanical tension may also strongly influence neuronal behavior in vivo.

Project description:Microglial SHIP1 controls synaptic pruning in the developing hippocampus via the complement system

Project description:Microglial SHIP1 controls synaptic pruning in the developing hippocampus via the complement system

Project description:C1q, a member of the immune complement cascade, is implicated in the selective pruning of synapses by microglial phagocytosis. C1q-mediated synapse elimination has been shown to occur during brain development, while increased activation and complement-dependent synapse loss is observed in neurodegenerative diseases. However, the molecular mechanisms underlying C1q-controlled synaptic pruning are mostly unknown. This study addresses distortions in the synaptic proteome leading to C1q-tagged synapses. Our data demonstrated the preferential localization of C1q to the presynapse. Proteomic investigation and pathway analysis of C1q-tagged synaptosomes revealed the presence of apoptotic-like processes in C1q-tagged synapses, which was confirmed experimentally with apoptosis markers. Moreover, the induction of synaptic apoptotic-like mechanisms in a model of sensory deprivation-induced synaptic depression led to elevated C1q levels. Our results unveiled that C1q label-based synaptic pruning is triggered by and directly linked to apoptotic-like processes in the synaptic compartment.

Project description:Entamoeba histolytica is the cause of amoebiasis. The trophozoite (amoeba) form of this parasite is capable of invading the intestine and can disseminate through the bloodstream to other organs. The mechanisms that allow amoebae to evade complement deposition during dissemination have not been well characterized. We previously discovered a novel complement-evasion mechanism employed by E. histolytica. E. histolytica ingests small bites of living human cells in a process termed trogocytosis. We demonstrated that amoebae were protected from lysis by human serum following trogocytosis of human cells and that amoebae acquired and displayed human membrane proteins from the cells they ingested. Here, we aimed to define how amoebae are protected from complement lysis after performing trogocytosis. We found that amoebae were protected from complement lysis after ingestion of both human Jurkat T cells and red blood cells and that the level of protection correlated with the amount of material ingested. Trogocytosis of human cells led to a reduction in deposition of C3b on the surface of amoebae. We asked whether display of human complement regulators is involved in amoebic protection, and found that CD59 was displayed by amoebae after trogocytosis. Deletion of a single complement-regulatory protein, CD59 or CD46, from Jurkat cells was not sufficient to alter amoebic protection from lysis, suggesting that multiple, redundant complement regulators mediate amoebic protection. However, exogeneous expression of CD46 or CD55 in amoebae was sufficient to confer protection from lysis. These studies shed light on a novel strategy for immune evasion by a pathogen. IMPORTANCE Entamoeba histolytica is the cause of amoebiasis, a diarrheal disease of global importance. While infection is often asymptomatic, the trophozoite (amoeba) form of this parasite is capable of invading and ulcerating the intestine and can disseminate through the bloodstream to other organs. Understanding how E. histolytica evades the complement system during dissemination is of great interest. Here, we demonstrate for the first time that amoebae that have performed trogocytosis (nibbling of human cells) resist deposition of the complement protein C3b. Amoebae that have performed trogocytosis display the complement-regulatory protein CD59. Overall, our studies suggest that acquisition and display of multiple, redundant complement regulators is involved in amoebic protection from complement lysis. These findings shed light on a novel strategy for immune evasion by a pathogen. Since other parasites use trogocytosis for cell killing, our findings may apply to the pathogenesis of other infections.

Project description:Axon pruning and synapse elimination promote neural connectivity and synaptic plasticity. Stereotyped pruning of axons that originate in the hippocampal dentate gyrus (DG) and extend along the infrapyramidal tract (IPT) occurs during postnatal murine development by neurite retraction and resembles axon repulsion. The chemorepellent Sema3F is required for IPT axon pruning, dendritic spine remodeling, and repulsion of DG axons. The signaling events that regulate IPT axon pruning are not known. We find that inhibition of the small G protein Rac1 by the Rac GTPase-activating protein (GAP) ?2-Chimaerin (?2Chn) mediates Sema3F-dependent pruning. The Sema3F receptor neuropilin-2 selectively binds ?2Chn, and ligand engagement activates this GAP to ultimately restrain Rac1-dependent effects on cytoskeletal reorganization. ?2Chn is necessary for axon pruning both in vitro and in vivo, but it is dispensable for axon repulsion and spine remodeling. Therefore, a Npn2/?2Chn/Rac1 signaling axis distinguishes DG axon pruning from the effects of Sema3F on repulsion and dendritic spine remodeling.