grant

Selective neuronal autophagy in phosphorylated tau degradation and Alzheimer's disease

Organization HARVARD MEDICAL SCHOOLLocation BOSTON, UNITED STATESPosted 1 Jun 2023Deadline 31 May 2026
NIHUS FederalResearch GrantFY202520S Catalytic Proteasome20S Core Proteasome20S Proteasome20S ProteosomeAD dementiaAD pathologyAPF-1ATP-Dependent Proteolysis Factor 1Adaptor ProteinAdaptor Protein GeneAdaptor Signaling ProteinAdaptor Signaling Protein GeneAddressAffectAgingAlzheimer Type DementiaAlzheimer beta-ProteinAlzheimer disease dementiaAlzheimer sclerosisAlzheimer syndromeAlzheimer'sAlzheimer's Amyloid beta-ProteinAlzheimer's DiseaseAlzheimer's amyloidAlzheimer's brainAlzheimer's disease brainAlzheimer's disease pathologyAlzheimer's disease patientAlzheimer's pathologyAlzheimer's patientAlzheimers DementiaAmentiaAmino AcidsAmyloid (Aβ) plaquesAmyloid Alzheimer's Dementia Amyloid ProteinAmyloid Beta-PeptideAmyloid PlaquesAmyloid Protein A4Amyloid beta-ProteinAmyloid βAmyloid β-PeptideAmyloid β-ProteinAssayAutophagocytosisAutoregulationB-Cell Chronic Lymphocytic Leukemia Associated OncogeneB-cell Leukemia 1BAG3BAG3 geneBCLBCL1 OncogeneBCL2-Associated Athanogene 3BioassayBiological AssayBortezomibBrainBrain Nervous SystemCRISPR approachCRISPR based approachCRISPR methodCRISPR methodologyCRISPR techniqueCRISPR technologyCRISPR toolsCRISPR-CAS-9CRISPR-based methodCRISPR-based techniqueCRISPR-based technologyCRISPR-based toolCRISPR/CAS approachCRISPR/Cas methodCRISPR/Cas technologyCRISPR/Cas9CRISPR/Cas9 technologyCas nuclease technologyChaperoneClinicalClustered Regularly Interspaced Short Palindromic Repeats approachClustered Regularly Interspaced Short Palindromic Repeats methodClustered Regularly Interspaced Short Palindromic Repeats methodologyClustered Regularly Interspaced Short Palindromic Repeats techniqueClustered Regularly Interspaced Short Palindromic Repeats technologyCognitive DisturbanceCognitive ImpairmentCognitive declineCognitive function abnormalCompensationDataDementiaDisturbance in cognitionEncephalonExposure toFLJ11330GeneticHMG-20High Mobility Protein 20HomeostasisHumanImmunoblottingImpaired cognitionIndividualInduced pluripotent stem cell derived neuronsKnock-outKnockoutLate Onset Alzheimer DiseaseMT-bound tauMacropainMacroxyproteinaseMass Photometry/Spectrum AnalysisMass SpectrometryMass SpectroscopyMass SpectrumMass Spectrum AnalysesMass Spectrum AnalysisMeasuresMediatingMemoryMetabolic Protein DegradationModalityModern ManMolecularMolecular ChaperonesMulticatalytic ProteinaseNF-Kb-Activating Kinase GeneNerve CellsNerve DegenerationNerve UnitNeural CellNeuritic PlaquesNeurocyteNeurofibrillary TanglesNeuron DegenerationNeuron from iPSCNeuron from induced pluripotent stem cellsNeuronsPhysiologicPhysiologic pulsePhysiologicalPhysiological HomeostasisPlayPredispositionPrimary Senile Degenerative DementiaProsomeProteasomeProteasome Endopeptidase ComplexProteasome InhibitorProtein TurnoverProteinsProteomicsProteosomeProtocolProtocols documentationPulseRegulationRegulatory Protein DegradationReporterRiskRoleSenile PlaquesStable Isotope LabelingSusceptibilitySystemT2KTBK1TBK1 geneUbiquitinWestern BlottingWestern ImmunoblottingWorka beta peptideabetaabnormally aggregated tau proteinadapter proteinaminoacidamyloid betaamyloid beta plaqueamyloid-b plaqueamyloid-b proteinautophagyaβ plaquesbeta amyloid fibrilcognitive dysfunctioncognitive losscohortcored plaquediffuse plaqueexcitatory neuronextracellularfilamentous tau inclusionhyper-phosphorylated tauhyperphosphorylated tauiPS neuronsiPSC derived-neuronsinduced pluripotent stem cell neuronsinsoluble aggregateinterestknock-downknockdownlate onset alzheimermicrotubule associated protein tau aggregationmicrotubule associated protein tau depositmicrotubule bound taumicrotubule-bound taumulti-electrode arraysmulticatalytic endopeptidase complexmultielectrode arraysneural degenerationneurodegenerationneurodegenerativeneurofibrillary degenerationneurofibrillary lesionneurofibrillary pathologyneurological degenerationneuronalneuronal degenerationneurons derived from induced pluripotent stem cellsneurons differentiated from induced pluripotent stem cellsneuropathologicneuropathologicalneuropathologyneurotoxicnew drug targetnew drug treatmentsnew druggable targetnew drugsnew pharmacological therapeuticnew pharmacotherapy targetnew therapeutic targetnew therapeuticsnew therapynew therapy targetnext generation therapeuticsnovel drug targetnovel drug treatmentsnovel druggable targetnovel drugsnovel pharmaco-therapeuticnovel pharmacological therapeuticnovel pharmacotherapy targetnovel therapeutic targetnovel therapeuticsnovel therapynovel therapy targetp-taup-τpaired helical filament of taupatient living with Alzheimer's diseasepatient suffering from Alzheimer's diseasepatient with Alzheimer'spatient with Alzheimer's diseasephospho-tauphospho-τphosphorylated taupost-translational modification of tauposttranslational modification of tauprimary degenerative dementiaprotein activationprotein aggregateprotein aggregationprotein blottingprotein degradationprotein homeostasisproteostasisreligious order studyresponseself-aggregate tausenile dementia of the Alzheimer typeshRNAshort hairpin RNAsmall hairpin RNAsocial rolesoluble amyloid precursor proteintangletargeted drug therapytargeted drug treatmentstargeted therapeutictargeted therapeutic agentstargeted therapytargeted treatmenttautau PHFtau Proteinstau accumulationtau aggregatetau aggregationtau factortau fibrillizationtau filamenttau neurofibrillary tangletau oligomertau paired helical filamenttau phosphorylationtau polymerizationtau posttranslational modificationtau-1tau-tau interactionτ Proteinsτ aggregationτ phosphorylation
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Full Description

Project Summary/Abstract:
Alzheimer’s disease (AD) pathology is defined by aberrant protein aggregation of extracellular amyloid-
beta plaques and intracellular hyperphosphorylated tau tangles within the brain, resulting in progressive cognitive
decline. However, a plethora of amyloid-beta targeting therapies have yielded limited clinical benefit, lending
credence to the significance of tau aggregation in AD. Specifically, the protein degradation network, which
includes the autophagy-lysosomal system (autophagy) and the ubiquitin-proteasome system (UPS), is frequently
cited as deficient in AD, and may therefore affect neurodegeneration and intracellular tau protein clearance within
the brain. To investigate the mechanisms of selective protein degradation in neuronal proteostasis and AD I will
use an induced pluripotent stem cell (iPSC)-derived neuronal system (iNs). Specifically, our lab has generated
over 50 human iN lines from the Religious Order Study and Rush Memory and Aging Project (ROSMAP) cohorts
which represent the full clinical and neuropathological spectrum of late onset AD. Across these genetically
diverse iNs, we previously assayed basal autophagic flux and UPS capacity. Additionally, proteomic analysis
and western blotting of these same iNs revealed strong associations between phosphorylated tau species and
proteins relevant in selective autophagy of protein aggregates (aggrephagy). Of particular interest is the
ubiquitin-dependent aggrephagy adaptor protein, optineurin (OPTN), which displays the most significant
negative correlation with aggregated phospho-tau forms relevant in our AD neurons. BCL-2-associated
athanogene 3 (BAG3) is another relevant aggrephagy chaperone protein that has previously been associated
with tau homeostasis within excitatory neurons and shows a strong compensatory relationship upon UPS
inhibition in our human neuronal system. Therefore, I hypothesize that AD derived neurons have a diminished
capacity for protein degradation activation following exposure to AD relevant neurotoxic proteins and genetic
modulation of autophagy, which results in an accumulation of phospho-tau and a reduction in neuronal activity.
To address this hypothesis, I have two aims: 1) To determine the influence of OPTN regulation on neuronal tau
proteostasis and neuronal function. To this end I will expose both AD and non-AD iNs to brain extract containing
neurotoxic proteins and measure several forms of tau and neuronal firing. 2) To investigate the role of BAG3-
mediated chaperone-assisted selective autophagy in modulating protein degradation compensation in human
neurons. Here, I will modulate BAG3 expression in both AD and non-AD iNs and expose these iNs to AD brain
extract containing neurotoxic proteins. I then will measure tau accumulation, neuronal firing, and protein turnover.
Taken together, the findings of this proposal will not only further the understanding of tau protein degradation via
aggrephagy but will define the molecular mechanisms governing OPTN and BAG3 regulation and function in
neurons and may lead to novel therapeutic modalities.

Grant Number: 5F31AG082393-03
NIH Institute/Center: NIH
Principal Investigator: Zachary Augur

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