2023
Development of neural repair therapy for chronic spinal cord trauma: soluble Nogo receptor decoy from discovery to clinical trial
Howard E, Strittmatter S. Development of neural repair therapy for chronic spinal cord trauma: soluble Nogo receptor decoy from discovery to clinical trial. Current Opinion In Neurology 2023, 36: 516-522. PMID: 37865850, PMCID: PMC10841037, DOI: 10.1097/wco.0000000000001205.Peer-Reviewed Original ResearchConceptsSpinal cord injuryChronic cervical spinal cord injuryCervical spinal cord injuryRecent clinical trialsCentral nervous systemClinical trialsAnimal studiesNeural repairChronic spinal cord injuryIncomplete spinal cord injuryTraumatic spinal cord injuryAdult mammalian central nervous systemContusion spinal cord injuryTreatment-naïve patientsSpinal cord traumaMammalian central nervous systemNeural repair therapiesUpper extremity strengthNonhuman primate studiesReceptor 1 pathwayNeurological recoveryNeurological deficitsCord traumaMedical therapyChronic stage
2021
B-cells expressing NgR1 and NgR3 are localized to EAE-induced inflammatory infiltrates and are stimulated by BAFF
Bakhuraysah MM, Theotokis P, Lee JY, Alrehaili AA, Aui PM, Figgett WA, Azari MF, Abou-Afech JP, Mackay F, Siatskas C, Alderuccio F, Strittmatter SM, Grigoriadis N, Petratos S. B-cells expressing NgR1 and NgR3 are localized to EAE-induced inflammatory infiltrates and are stimulated by BAFF. Scientific Reports 2021, 11: 2890. PMID: 33536561, PMCID: PMC7858582, DOI: 10.1038/s41598-021-82346-6.Peer-Reviewed Original ResearchConceptsExperimental autoimmune encephalomyelitisEAE-induced miceB cellsB-cell activating factorMeningeal B cellsLumbosacral spinal cordSecretion of immunoglobulinsG0/G1 phaseImmune cell signalingNeurological progressionAutoimmune encephalomyelitisInflammatory infiltrateAxonal dystrophyCentral nervous system myelinSpinal cordRecombinant BAFFActivating factorNgR1Score 1BAFFBAFF stimulationInfiltratesNgR3System myelinG1 phase
2020
Nogo receptor decoy promotes recovery and corticospinal growth in non-human primate spinal cord injury
Wang X, Zhou T, Maynard GD, Terse PS, Cafferty WB, Kocsis JD, Strittmatter SM. Nogo receptor decoy promotes recovery and corticospinal growth in non-human primate spinal cord injury. Brain 2020, 143: 1697-1713. PMID: 32375169, PMCID: PMC7850069, DOI: 10.1093/brain/awaa116.Peer-Reviewed Original ResearchConceptsPrimate spinal cord injurySpinal cord injuryCord injuryFemale African green monkeysTreatment-related adverse eventsChronic neurological deficitsNogo receptor 1Left motor cortexRecovery of functionPreclinical rodent modelsSpinal cord injury animalsAfrican green monkeysRaphespinal fibersAdverse eventsCervical cordNeurological deficitsSurgical complicationsCNS traumaTreatment cessationCorticospinal axonsLumbar catheterInjury animalsNeural recoverySpontaneous feedingLateral hemisection
2019
Limiting Neuronal Nogo Receptor 1 Signaling during Experimental Autoimmune Encephalomyelitis Preserves Axonal Transport and Abrogates Inflammatory Demyelination
Lee JY, Kim MJ, Thomas S, Oorschot V, Ramm G, Aui PM, Sekine Y, Deliyanti D, Wilkinson-Berka J, Niego B, Harvey AR, Theotokis P, McLean C, Strittmatter SM, Petratos S. Limiting Neuronal Nogo Receptor 1 Signaling during Experimental Autoimmune Encephalomyelitis Preserves Axonal Transport and Abrogates Inflammatory Demyelination. Journal Of Neuroscience 2019, 39: 5562-5580. PMID: 31061088, PMCID: PMC6616297, DOI: 10.1523/jneurosci.1760-18.2019.Peer-Reviewed Original ResearchMeSH KeywordsAdultAgedAged, 80 and overAnimalsAxonal TransportAxonsCells, CulturedEncephalomyelitis, Autoimmune, ExperimentalFemaleHumansIntercellular Signaling Peptides and ProteinsKinesinsMaleMiceMice, Inbred C57BLMiddle AgedMyelin SheathNerve Tissue ProteinsNogo Receptor 1Retinal Ganglion CellsSignal TransductionConceptsExperimental autoimmune encephalomyelitisCollapsin response mediator protein 2Optic nerveAxonal degenerationMultiple sclerosisAxonal vesicular transportAutoimmune encephalomyelitisInflammatory demyelinationAxonal integritySeverity of EAECre deletionAxonal transportRetinal ganglion cell axonsAxonal motor proteinsEAE-induced miceImmune-mediated destructionProgressive multiple sclerosisNeuron-specific deletionNogo receptor 1Ganglion cell axonsAnterograde transportFlx/Response mediator protein 2Adeno-associated virus serotype 2Phosphorylation of CRMP2Plexina2 and CRMP2 Signaling Complex Is Activated by Nogo-A-Liganded Ngr1 to Restrict Corticospinal Axon Sprouting after Trauma
Sekine Y, Algarate PT, Cafferty WBJ, Strittmatter SM. Plexina2 and CRMP2 Signaling Complex Is Activated by Nogo-A-Liganded Ngr1 to Restrict Corticospinal Axon Sprouting after Trauma. Journal Of Neuroscience 2019, 39: 3204-3216. PMID: 30804090, PMCID: PMC6788813, DOI: 10.1523/jneurosci.2996-18.2019.Peer-Reviewed Original ResearchConceptsCNS traumaNeural repairMouse cervical spinal cordSpinal cord traumaCervical spinal cordNon-neuronal cellsInteraction of NogoAxon growth inhibitionAxonal guidance mechanismsNeurological recoveryAxonal sproutingCNS pathwaysCord traumaFunctional recoveryAxon sproutingSpinal cordNgR1 functionUnilateral pyramidotomyAxon regenerationAdult traumaNgR1TraumaAxon growthNogoCytoplasmic mediatorsSystematic and standardized comparison of reported amyloid-β receptors for sufficiency, affinity, and Alzheimer's disease relevance
Smith LM, Kostylev MA, Lee S, Strittmatter SM. Systematic and standardized comparison of reported amyloid-β receptors for sufficiency, affinity, and Alzheimer's disease relevance. Journal Of Biological Chemistry 2019, 294: 6042-6053. PMID: 30787106, PMCID: PMC6463724, DOI: 10.1074/jbc.ra118.006252.Peer-Reviewed Original ResearchConceptsAlzheimer's diseaseAD brainLeukocyte immunoglobulin-like receptorsNogo receptor 1Human AD brainsImmunoglobulin-like receptorsB member 2Brains of individualsReceptor candidatesSoluble AβOsDisease relevanceCell surface expressionHippocampal neuronsMouse modelSynthetic AβAβO bindingMemory impairmentReceptor 1Cellular prion proteinNeuronal synapsesNgR1Molecular pathologyAβAβ speciesMember 2
2018
The nociceptin receptor inhibits axonal regeneration and recovery from spinal cord injury
Sekine Y, Siegel CS, Sekine-Konno T, Cafferty WBJ, Strittmatter SM. The nociceptin receptor inhibits axonal regeneration and recovery from spinal cord injury. Science Signaling 2018, 11 PMID: 29615517, PMCID: PMC6179440, DOI: 10.1126/scisignal.aao4180.Peer-Reviewed Original ResearchConceptsSpinal cord injuryCord injuryAxonal regenerationMid-thoracic spinal cordTraumatic spinal cord injuryPartial neurological recoveryTraumatic CNS injuryDorsal hemisectionNeurological recoveryPeptide nociceptinCNS injuryAxon sproutingORL1 agonistSelective blockadeSpinal cordLocomotor functionNociceptin receptorAxon regenerationNeural repairPrimary neuronsNgR1 proteinAxonal growthNull miceMRNA expressionORL1
2016
Axonal branching in lateral olfactory tract is promoted by Nogo signaling
Iketani M, Yokoyama T, Kurihara Y, Strittmatter SM, Goshima Y, Kawahara N, Takei K. Axonal branching in lateral olfactory tract is promoted by Nogo signaling. Scientific Reports 2016, 6: 39586. PMID: 28000762, PMCID: PMC5175167, DOI: 10.1038/srep39586.Peer-Reviewed Original ResearchConceptsLateral olfactory tractCultured OB neuronsOB neuronsCollateral branchesAxonal branchingOlfactory bulbOlfactory tractAxonal bundlesMajor projection neuronsReceptor 1 antagonistKnockdown of NogoCollateral formationProjection neuronsPrimary axonsNogo signalingMitral cellsMiceNeuronsExpression levelsAbnormal increaseTractNogoAntagonistAxons
2015
Erasure of fear memories is prevented by Nogo Receptor 1 in adulthood
Bhagat SM, Butler SS, Taylor JR, McEwen BS, Strittmatter SM. Erasure of fear memories is prevented by Nogo Receptor 1 in adulthood. Molecular Psychiatry 2015, 21: 1281-1289. PMID: 26619810, PMCID: PMC4887429, DOI: 10.1038/mp.2015.179.Peer-Reviewed Original ResearchConceptsPost-traumatic stress disorderExtinction trainingFear memorySpontaneous fear recoveryBasolateral amygdalaJuvenile rodentsFear recoveryFear renewalFear extinctionFear expressionInhibitory synapse markersNgR1 expressionStress disorderNogo receptor 1Anxiety disordersInfralimbic cortexCritical periodNeural plasticityMemoryTemporary windowsReceptor 1TrainingAdulthoodNgR1 functionNaive miceComprehensive Corticospinal Labeling with mu-crystallin Transgene Reveals Axon Regeneration after Spinal Cord Trauma in ngr1−/− Mice
Fink KL, Strittmatter SM, Cafferty WB. Comprehensive Corticospinal Labeling with mu-crystallin Transgene Reveals Axon Regeneration after Spinal Cord Trauma in ngr1−/− Mice. Journal Of Neuroscience 2015, 35: 15403-15418. PMID: 26586827, PMCID: PMC4649010, DOI: 10.1523/jneurosci.3165-15.2015.Peer-Reviewed Original ResearchMeSH KeywordsAmidinesAnalysis of VarianceAnimalsAxonsBiotinCrystallinsDextransDisease Models, AnimalFunctional LateralityGene Expression RegulationGlial Fibrillary Acidic ProteinGPI-Linked ProteinsLuminescent ProteinsMiceMice, Inbred C57BLMice, TransgenicMu-CrystallinsMyelin ProteinsNerve RegenerationNogo Receptor 1Pyramidal TractsReceptors, Cell SurfaceRecovery of FunctionSpinal Cord InjuriesConceptsCorticospinal tractCST axonsTransgenic miceMotor tractsDextran amineFunctional deficitsSpinal cordAxon regenerationSpinal Cord Injury StudySpontaneous axon regenerationSpinal cord traumaNogo receptor 1Permanent functional deficitsPersistent functional deficitsBilateral pyramidotomyDorsal hemisectionMidthoracic cordCord traumaMotor pathwaysAdult CNSCST regenerationInjury studiesLesion siteRegenerating fibersNeural repair
2014
Human NgR-Fc Decoy Protein via Lumbar Intrathecal Bolus Administration Enhances Recovery from Rat Spinal Cord Contusion
Wang X, Yigitkanli K, Kim CY, Sekine-Konno T, Wirak D, Frieden E, Bhargava A, Maynard G, Cafferty WB, Strittmatter SM. Human NgR-Fc Decoy Protein via Lumbar Intrathecal Bolus Administration Enhances Recovery from Rat Spinal Cord Contusion. Journal Of Neurotrauma 2014, 31: 1955-1966. PMID: 24964223, PMCID: PMC4245872, DOI: 10.1089/neu.2014.3355.Peer-Reviewed Original ResearchConceptsSpinal cord injuryTraumatic spinal cord injurySpinal cord contusionNeurological recoveryCord contusionRat spinal cord contusionSpinal contusion injuryLumbar intrathecal spaceLumbar spinal cordContinuous intracerebroventricular infusionRodent SCI modelsPercentage of ratsRaphespinal axonsContusion injuryAdministration regimenSCI modelContinuous infusionCord injuryIntracerebroventricular infusionIntrathecal spaceSpinal cordPreclinical modelsEffective treatmentWalking tasksClinical testingThe Nogo Receptor NgR1 Mediates Infection by Mammalian Reovirus
Konopka-Anstadt JL, Mainou BA, Sutherland DM, Sekine Y, Strittmatter SM, Dermody TS. The Nogo Receptor NgR1 Mediates Infection by Mammalian Reovirus. Cell Host & Microbe 2014, 15: 681-691. PMID: 24922571, PMCID: PMC4100558, DOI: 10.1016/j.chom.2014.05.010.Peer-Reviewed Original ResearchConceptsCentral nervous systemReceptor NgR1Reovirus infectionExpression of NgR1Primary cortical neuronsDistinct cell surface moleculesJunctional adhesion molecule ASoluble NgR1Cell surface moleculesNeurotropic virusesCortical neuronsMammalian reovirusesNonsusceptible cellsNervous systemNgR1Null miceSystemic spreadInfectionIndependent receptorsMultiple receptorsReovirus replicationInitial siteReovirus virionsNeuronsReceptors
2012
Axonal regeneration induced by blockade of glial inhibitors coupled with activation of intrinsic neuronal growth pathways
Wang X, Hasan O, Arzeno A, Benowitz LI, Cafferty WB, Strittmatter SM. Axonal regeneration induced by blockade of glial inhibitors coupled with activation of intrinsic neuronal growth pathways. Experimental Neurology 2012, 237: 55-69. PMID: 22728374, PMCID: PMC3418451, DOI: 10.1016/j.expneurol.2012.06.009.Peer-Reviewed Original ResearchConceptsRetinal ganglion cellsAxonal regenerationPharmacological approachesCrush injuryChondroitin sulfate proteoglycanInjury siteNeural repairOptic nerve crush injuryDorsal root ganglion neuronsNgr1-/- miceNerve crush injurySciatic nerve axotomySpinal cord injury sitePrimary afferent fibersEffective pharmacological approachSpinal cord injuryAdult mammalian neuronsIntrinsic growth potentialGlial inhibitorsTriple therapyNerve axotomyViral gene therapyWT miceAfferent fibersCNS injuryLimiting multiple sclerosis related axonopathy by blocking Nogo receptor and CRMP-2 phosphorylation
Petratos S, Ozturk E, Azari MF, Kenny R, Lee JY, Magee KA, Harvey AR, McDonald C, Taghian K, Moussa L, Aui P, Siatskas C, Litwak S, Fehlings MG, Strittmatter SM, Bernard CC. Limiting multiple sclerosis related axonopathy by blocking Nogo receptor and CRMP-2 phosphorylation. Brain 2012, 135: 1794-1818. PMID: 22544872, PMCID: PMC3589918, DOI: 10.1093/brain/aws100.Peer-Reviewed Original ResearchMeSH KeywordsAdultAnalysis of VarianceAnimalsAntibodiesAxonsCD3 ComplexCell Line, TumorDemyelinating DiseasesDisease Models, AnimalEncephalomyelitis, Autoimmune, ExperimentalFemaleGene Expression RegulationGlycoproteinsGPI-Linked ProteinsGreen Fluorescent ProteinsHumansImmunoprecipitationIntercellular Signaling Peptides and ProteinsMaleMiceMice, Inbred C57BLMice, KnockoutMiddle AgedMultiple SclerosisMutationMyelin ProteinsMyelin-Oligodendrocyte GlycoproteinNerve DegenerationNerve Tissue ProteinsNeuroblastomaNeurofilament ProteinsNogo Receptor 1Optic NervePeptide FragmentsPhosphorylationReceptors, Cell SurfaceRetinal Ganglion CellsSeverity of Illness IndexSilver StainingSpinal CordTau ProteinsTime FactorsTransduction, GeneticTubulinConceptsExperimental autoimmune encephalomyelitisAutoimmune encephalomyelitisMyelin oligodendrocyte glycoproteinMultiple sclerosisAxonal degenerationSpinal cordChronic active multiple sclerosis lesionsOptic nerve axonal degenerationNogo-66 receptor 1CRMP-2Axonal growth inhibitorsCollapsin response mediator protein 2Improved clinical outcomesSpinal cord neuronsRetinal ganglion cellsResponse mediator protein 2Central nervous systemViable therapeutic targetAdeno-associated viral vectorMultiple sclerosis lesionsClinical outcomesOptic nerveCord neuronsOligodendrocyte glycoproteinGanglion cells
2011
Cartilage Acidic Protein–1B (LOTUS), an Endogenous Nogo Receptor Antagonist for Axon Tract Formation
Sato Y, Iketani M, Kurihara Y, Yamaguchi M, Yamashita N, Nakamura F, Arie Y, Kawasaki T, Hirata T, Abe T, Kiyonari H, Strittmatter SM, Goshima Y, Takei K. Cartilage Acidic Protein–1B (LOTUS), an Endogenous Nogo Receptor Antagonist for Axon Tract Formation. Science 2011, 333: 769-773. PMID: 21817055, PMCID: PMC3244695, DOI: 10.1126/science.1204144.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAxonsBinding SitesCalcium-Binding ProteinsCell LineCells, CulturedGPI-Linked ProteinsGrowth ConesHumansImmunohistochemistryLigandsMiceMice, Inbred ICRMyelin ProteinsNogo ProteinsNogo Receptor 1Olfactory PathwaysProsencephalonProtein BindingReceptors, Cell SurfaceSignal TransductionConceptsTract formationNogo receptor 1Axon growth inhibitorsProtein 1BEndogenous antagonismAxon tract formationReceptor antagonistGrowth cone collapseAxonal projectionsCircuitry formationNeural circuitry formationMouse brainReceptor 1LOT formationNeural regenerationNgR1Key moleculesCone collapseMiceFluorophore-assisted light inactivationGrowth inhibitorAntagonistBrainMyelinNogoMembrane-type Matrix Metalloproteinase-3 Regulates Neuronal Responsiveness to Myelin through Nogo-66 Receptor 1 Cleavage*
Ferraro GB, Morrison CJ, Overall CM, Strittmatter SM, Fournier AE. Membrane-type Matrix Metalloproteinase-3 Regulates Neuronal Responsiveness to Myelin through Nogo-66 Receptor 1 Cleavage*. Journal Of Biological Chemistry 2011, 286: 31418-31424. PMID: 21768085, PMCID: PMC3173120, DOI: 10.1074/jbc.m111.249169.Peer-Reviewed Original ResearchConceptsMatrix metalloproteinase-3Primary neuronsMetalloproteinase-3Neuronal responsesSH-SY5Y neuroblastoma cellsMetalloproteinase-dependent mannerNeuronal responsivenessAxonal regrowthCortical neuronsNeuronal knockdownNgR1Receptor 1Neuroblastoma cellsNeuronsCell surfaceMT3-MMPMyelinSpecific metalloproteinasesGlycosylphosphatidylinositol-anchored receptorInhibitorsPhysiological consequencesCleavage fragmentsCleavage-resistant formMetalloproteinasesReceptorsA Multi-domain Fragment of Nogo-A Protein Is a Potent Inhibitor of Cortical Axon Regeneration via Nogo Receptor 1*
Huebner EA, Kim BG, Duffy PJ, Brown RH, Strittmatter SM. A Multi-domain Fragment of Nogo-A Protein Is a Potent Inhibitor of Cortical Axon Regeneration via Nogo Receptor 1*. Journal Of Biological Chemistry 2011, 286: 18026-18036. PMID: 21454605, PMCID: PMC3093876, DOI: 10.1074/jbc.m110.208108.Peer-Reviewed Original ResearchConceptsMature cortical neuronsCortical neuronsNogo-66Axon regenerationReceptor 1Central nervous system injuryDorsal root ganglion neuronsNogo-66 receptor 1Expression of PirBMature cortical culturesNogo receptor 1Nervous system injuryNogo-A proteinImmunoglobulin-like receptorsChick dorsal root ganglion neuronsFunctional recoverySystem injuryGanglion neuronsCortical culturesPredominant receptorNgR1Genetic deletionPirBCell surface receptorsNeurons
2010
Nogo Receptor Deletion and Multimodal Exercise Improve Distinct Aspects of Recovery in Cervical Spinal Cord Injury
Harel NY, Song KH, Tang X, Strittmatter SM. Nogo Receptor Deletion and Multimodal Exercise Improve Distinct Aspects of Recovery in Cervical Spinal Cord Injury. Journal Of Neurotrauma 2010, 27: 2055-2066. PMID: 20809785, PMCID: PMC2978056, DOI: 10.1089/neu.2010.1491.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBehavior, AnimalExercise TherapyFemaleGene DeletionGenotypeGPI-Linked ProteinsHand StrengthImmunohistochemistryMaleMiceMice, Inbred C57BLMyelin ProteinsNeuronal PlasticityNogo Receptor 1Physical Conditioning, AnimalPostural BalanceReceptors, Cell SurfaceReproducibility of ResultsSerotoninSpinal CordSpinal Cord InjuriesWalkingConceptsSpinal cord injuryCord injuryCervical spinal cord injuryIncomplete spinal cord injuryCervical spinal injurySignificant histological differencesMultimodal exerciseExercise trainingLateral hemisectionReceptor deletionSpinal injuryLesion modelMouse modelAdult miceLesion sizeGene deletionHistological differencesNeural plasticityMild deficitsHistological analysisTraining regimenInjuryPhysical interventionsC3-C4MiceGenetic Deletion and Pharmacological Inhibition of Nogo-66 Receptor Impairs Cognitive Outcome after Traumatic Brain Injury in Mice
Hånell A, Clausen F, Björk M, Jansson K, Philipson O, Nilsson LN, Hillered L, Weinreb PH, Lee D, McIntosh TK, Gimbel DA, Strittmatter SM, Marklund N. Genetic Deletion and Pharmacological Inhibition of Nogo-66 Receptor Impairs Cognitive Outcome after Traumatic Brain Injury in Mice. Journal Of Neurotrauma 2010, 27: 1297-1309. PMID: 20486800, PMCID: PMC2942864, DOI: 10.1089/neu.2009.1255.Peer-Reviewed Original ResearchConceptsTraumatic brain injuryMossy fiber sproutingSoluble NgR1Fiber sproutingBrain injuryCortical impact injury modelEarly post-injury periodNogo-66 receptor 1Hippocampal mossy fiber sproutingBehavioral recovery processSham-injured animalsBrain-injured animalsPost-injury periodSpinal cord injuryOligodendrocyte myelin glycoproteinPharmacological neutralizationBehavioral recoveryFunctional recoveryLoss of tissueCord injuryTimm stainInjury modelMotor functionRodent modelsHistological effects
2008
Genetic Variants of Nogo-66 Receptor with Possible Association to Schizophrenia Block Myelin Inhibition of Axon Growth
Budel S, Padukkavidana T, Liu BP, Feng Z, Hu F, Johnson S, Lauren J, Park JH, McGee AW, Liao J, Stillman A, Kim JE, Yang BZ, Sodi S, Gelernter J, Zhao H, Hisama F, Arnsten AF, Strittmatter SM. Genetic Variants of Nogo-66 Receptor with Possible Association to Schizophrenia Block Myelin Inhibition of Axon Growth. Journal Of Neuroscience 2008, 28: 13161-13172. PMID: 19052207, PMCID: PMC2892845, DOI: 10.1523/jneurosci.3828-08.2008.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBrainChick EmbryoChlorocebus aethiopsChromosome MappingCodonCOS CellsFemaleGenetic Predisposition to DiseaseGPI-Linked ProteinsGrowth ConesGrowth InhibitorsHumansMaleMiceMice, KnockoutMutationMyelin ProteinsNerve Fibers, MyelinatedNeurogenesisNeuronal PlasticityNogo Receptor 1Organ Culture TechniquesRatsReceptors, Cell SurfaceSchizophreniaConceptsMyelin inhibitionNogo-66 receptorCase-control analysisMyelin-specific genesAxonal sproutingMyelin signalGenetic predispositionAxon inhibitionNeuronal culturesPossible associationReceptor 1Disease riskAxon growthSchizophreniaAxonal proteinsPotential endophenotypeMemory functionGenetic variantsDysfunctional proteinsInhibitionSchizophrenia susceptibilityDominant negativeProtein exhibitCandidate genesChromosome 22q11