grant

The regulation of the microglial response to amyloid-beta plaques by the polycomb repressive complex 2

Organization ICAHN SCHOOL OF MEDICINE AT MOUNT SINAILocation NEW YORK, UNITED STATESPosted 1 Dec 2022Deadline 30 Nov 2026
NIHUS FederalResearch GrantFY2026AD dementiaAD modelAD pathologyAD riskAD risk factorAblationActinsAddressAffinity ChromatographyAlzheimer Type DementiaAlzheimer beta-ProteinAlzheimer disease dementiaAlzheimer risk factorAlzheimer sclerosisAlzheimer syndromeAlzheimer'sAlzheimer's Amyloid beta-ProteinAlzheimer's DiseaseAlzheimer's amyloidAlzheimer's disease modelAlzheimer's disease pathologyAlzheimer's disease riskAlzheimer's pathologyAlzheimers DementiaAmyloidAmyloid (Aβ) plaquesAmyloid Alzheimer's Dementia Amyloid ProteinAmyloid Beta-PeptideAmyloid PlaquesAmyloid Protein A4Amyloid SubstanceAmyloid beta-ProteinAmyloid βAmyloid β-PeptideAmyloid β-ProteinAssayBioassayBiological AssayBrainBrain Nervous SystemBrain regionCUT&RUNCell BodyCell Communication and SignalingCell Growth and MaintenanceCell Growth in NumberCell MaintenanceCell MultiplicationCell NucleusCell ProliferationCell SignalingCell SurvivalCell ViabilityCellsCellular ProliferationCessation of lifeChemotaxisCleavage Targets and Release Using NucleaseCleavage Under Targets and Release Using NucleaseComplexCytoplasmDataDeathDegenerative Neurologic DisordersDevelopmentDiseaseDisease associated microgliaDisorderDysfunctionEncephalonEnvironmentEpigeneticEpigenetic ChangeEpigenetic MechanismEpigenetic ProcessExpression SignatureFibroblastsFore-BrainForebrainFunctional disorderGene Down-RegulationGene ExpressionGene Expression ProfileGene InactivationGene SilencingGene TranscriptionGenesGeneticGenetic TranscriptionGenetic predisposing factorGenetic studyHortega cellImmuneImmunesIn VitroInflammatory ResponseIntermediary MetabolismIntracellular Communication and SignalingL-LysineLate Onset Alzheimer DiseaseLate onset ADLysineMaintenanceMeasuresMediatingMetabolic ProcessesMetabolismMiceMice MammalsMicrogliaModelingMurineMusMyelogenousMyeloidNervous System Degenerative DiseasesNeural Degenerative DiseasesNeural degenerative DisordersNeuritic PlaquesNeurodegenerative DiseasesNeurodegenerative DisordersNeurologic Degenerative ConditionsNucleusPathway interactionsPhagocytosisPhenotypePhysiopathologyPlayPolycombPolymersPrimary Senile Degenerative DementiaProliferatingPropertyProsencephalonRNA ExpressionReceptor ActivationReceptor ProteinRegulationRibosomesRisk FactorsRisk-associated variantRoleSenile PlaquesSignal InductionSignal PathwaySignal TransductionSignal Transduction SystemsSignalingSpecific qualifier valueSpecifiedTREM2TREM2 geneTau forming aggregatesToxic effectToxicitiesTranscriptionTranscription RepressionTranscriptional ControlTranscriptional RegulationTranslatingTriggering Receptor Expressed in Myeloid Cells 2Triggering Receptor Expressed on Myeloid Cells 2a beta peptideabetaabeta accumulationabeta aggregationabnormally aggregated tau proteinaffinity purificationaggregation in taualzheimer modelalzheimer riskamyloid betaamyloid beta accumulationamyloid beta aggregationamyloid beta plaqueamyloid β accumulationamyloid β aggregationamyloid-b plaqueamyloid-b proteinaβ accumulationaβ aggregationaβ plaquesbeta amyloid fibrilbiological signal transductionbrain cellcell typecored plaquedegenerative diseases of motor and sensory neuronsdegenerative neurological diseasesdevelopmentaldiffuse plaqueeffective therapyeffective treatmentepigeneticallyexperimentexperimental researchexperimental studyexperimentsfilamentous tau inclusiongene expression patterngene expression signaturegene repressiongenetic approachgenetic risk factorgenetic strategygitter cellglial activationglial cell activationhistone methylationin vivoinherited factorlate onset alzheimerloss of function mutationmesogliamicroglial cellmicrogliocytemicrotubule associated protein tau aggregationmicrotubule associated protein tau depositmigrationmouse modelmurine modelnerve cell deathnerve cell lossneurodegenerative illnessneuron cell deathneuron cell lossneuron deathneuron lossneuronal cell deathneuronal cell lossneuronal deathneuronal losspaired helical filament of taupathophysiologypathwayperivascular glial cellpharmacologicpolymerpolymericpolymerizationprimary degenerative dementiareceptorresponserisk allelerisk factor for developing Alzheimer'srisk factor in Alzheimer'srisk generisk genotyperisk locirisk locusrisk of developing Alzheimer'srisk variantself-aggregate tausenile dementia of the Alzheimer typesocial rolesoluble amyloid precursor proteintau PHFtau accumulationtau aggregatetau aggregationtau fibrillationtau fibrillizationtau filamenttau inclusiontau neurofibrillary tangletau oligomertau paired helical filamenttau polymerizationtau protein accumulationtau protein aggregationtau-tau interactiontranscriptional profiletranscriptional signaturetranscriptional silencingvirtualτ aggregation
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Full Description

Project Summary/Abstract
A gap exists in our understanding of the pathophysiology behind Alzheimer’s Disease (AD), which has led to
virtually nonexistent treatment options. Recent studies have identified microglia, the innate immune cells of the
brain, as key players in the response to AD that may help us fill this gap. Specifically, microglia appear to play
a protective role against toxicity associated with amyloid-ß containing plaques. Through activation of the
triggering receptor expressed in myeloid cells 2 (TREM2) signaling pathway, microglia migrate towards and
surround these plaques while inducing a distinct transcriptional signature known as the Disease Associated
Microglia (DAM) phenotype. An important outstanding question is how microglia regulate this state, both
transcriptionally and functionally. Our lab has previously identified the polycomb repressive complex 2 (PRC2)
as an important epigenetic regulator of brain region specific microglia subpopulations. PRC2 is an epigenetic
complex involved in gene silencing and has also been implicated as a signaling regulator in immune cells.
Notably, we found that PRC2 deficient microglia downregulate many genes in the TREM2 signaling pathway. I
hypothesize that PRC2 controls the microglial response to amyloid-ß containing plaques in a TREM2-
dependent mechanism. In support of this, I generated a PRC2-deficient microglia mouse line crossed to the
5xFAD amyloid model of AD and showed that PRC2-deficiency leads to loss of plaque associated microglia,
similar to TREM2-deficient models. This could be due to transcriptional regulation of the TREM2 pathway or
direct modulation of TREM2 signaling. To further investigate my hypothesis, I will first characterize the
epigenetic and transcriptional role PRC2 plays in 5xFAD microglia. There are multiple TREM2-dependent
mechanisms that could lead to decreased plaque associated microglia – inability to sense plaques, increased
death at the plaques, or lack of migration towards the plaques. To determine if PRC2 regulates these
phenotypes in a TREM2-dependent manner, I will culture primary mouse microglia and pharmacologically
inhibit PRC2, followed by induction of TREM2 signaling. With this model, I will assay TREM2-dependent
sensing, survival, and migration. The results of this proposal will reveal whether PRC2 is a master regulator of
the microglial response to AD amyloid-ß containing plaques through its control of TREM2 signaling, either
transcriptionally or through direct regulation of the signaling pathway. These data are critical to furthering our
understanding of how microglial functional states are regulated, opening avenues for the development of
effective treatments against Alzheimer’s Disease.

Grant Number: 5F30AG079492-04
NIH Institute/Center: NIH
Principal Investigator: Matthew Challman

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