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 stageAmino-terminal proteolytic fragment of the axon growth inhibitor Nogo-A (Rtn4A) is upregulated by injury and promotes axon regeneration
Sekine Y, Wang X, Kikkawa K, Honda S, Strittmatter S. Amino-terminal proteolytic fragment of the axon growth inhibitor Nogo-A (Rtn4A) is upregulated by injury and promotes axon regeneration. Journal Of Biological Chemistry 2023, 299: 105232. PMID: 37690690, PMCID: PMC10622843, DOI: 10.1016/j.jbc.2023.105232.Peer-Reviewed Original ResearchConceptsAxon regenerationCentral nervous system injuryPersistent neurological deficitsCerebral cortical neuronsNervous system injuryNeurological deficitsSystem injuryCNS injuryCortical neuronsAmino-terminal fragmentInjuryExtracellular actionPhysiological productionNogoInhibitory proteinMiceNeuronsInhibitory domainOverexpression increasesVaried resultsProteolytic fragmentsAxotomyExpressionNogoAGene targeting
2022
Rabphilin3A reduces integrin-dependent growth cone signaling to restrict axon regeneration after trauma
Sekine Y, Kannan R, Wang X, Strittmatter SM. Rabphilin3A reduces integrin-dependent growth cone signaling to restrict axon regeneration after trauma. Experimental Neurology 2022, 353: 114070. PMID: 35398339, PMCID: PMC9555232, DOI: 10.1016/j.expneurol.2022.114070.Peer-Reviewed Original ResearchConceptsAxon regenerationModerate spinal cord contusion injurySpinal cord contusion injuryTraumatic spinal cord injuryAdult mammalian central nervous systemGrowth conesRetinal ganglion cell axonsOptic nerve crushSpinal cord crush injuryGanglion cell axonsSpinal cord injuryMammalian central nervous systemCentral nervous systemCorticospinal axon regenerationContusion injuryAxonal sproutingCrush injuryNerve crushAxonal growth conesCord injuryAxon sproutingCell axonsProximal bodyNervous systemNeural repair
2021
Optic nerve regeneration screen identifies multiple genes restricting adult neural repair
Lindborg JA, Tran NM, Chenette DM, DeLuca K, Foli Y, Kannan R, Sekine Y, Wang X, Wollan M, Kim IJ, Sanes JR, Strittmatter SM. Optic nerve regeneration screen identifies multiple genes restricting adult neural repair. Cell Reports 2021, 34: 108777. PMID: 33657370, PMCID: PMC8009559, DOI: 10.1016/j.celrep.2021.108777.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAxonsCRISPR-Cas SystemsDependovirusFemaleGene EditingGene Expression RegulationGenetic Association StudiesHEK293 CellsHumansInterleukinsMaleMAP Kinase Kinase KinasesMice, Inbred C57BLMice, TransgenicNerve RegenerationNeurogenesisOptic NerveOptic Nerve InjuriesRetinal Ganglion CellsSignal TransductionSTAT3 Transcription FactorConceptsOptic nerve crushRetinal ganglion cellsRegeneration-associated genesShort hairpin RNAIL-22Neural repairCentral nervous system traumaNeurological deficits persistNervous system traumaNerve crushAxonal damageAxonal regenerationGanglion cellsSystem traumaInflammatory responseCNS regenerationDeficits persistAxonal growthHairpin RNAConcurrent activationTranscription 3Cell-autonomous factorsKinase pathwaySignal transducerRepair
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
A proteolytic C-terminal fragment of Nogo-A (reticulon-4A) is released in exosomes and potently inhibits axon regeneration
Sekine Y, Lindborg JA, Strittmatter SM. A proteolytic C-terminal fragment of Nogo-A (reticulon-4A) is released in exosomes and potently inhibits axon regeneration. Journal Of Biological Chemistry 2019, 295: 2175-2183. PMID: 31748413, PMCID: PMC7039549, DOI: 10.1074/jbc.ra119.009896.Peer-Reviewed Original ResearchConceptsMembrane-associated proteinsRecombinant protein expressionMatrix-associated proteinOligodendrocyte plasma membraneProteolytic C-terminal fragmentsRegeneration assaysC-terminal fragmentPlasma membraneNeurite outgrowth inhibitor NogoAxonal regenerationExosomal releaseDiffusible inhibitorC-terminalSiRNA knockdownCleavage siteCultured cellsLong fragmentPrimary cortical neuron culturesCentral nervous system traumaExosomesEnzyme inhibitor treatmentExosomal fractionSpinal cord crush injuryCerebral cortex neuronsProteinLimiting 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 mediators
2018
Diltiazem Promotes Regenerative Axon Growth
Huebner EA, Budel S, Jiang Z, Omura T, Ho TS, Barrett L, Merkel JS, Pereira LM, Andrews NA, Wang X, Singh B, Kapur K, Costigan M, Strittmatter SM, Woolf CJ. Diltiazem Promotes Regenerative Axon Growth. Molecular Neurobiology 2018, 56: 3948-3957. PMID: 30232777, PMCID: PMC6424671, DOI: 10.1007/s12035-018-1349-5.Peer-Reviewed Original ResearchConceptsL-type calcium channel blockerDorsal root gangliaCentral nervous systemChondroitin sulfate proteoglycanAxon regenerationMouse dorsal root gangliaAdult central nervous systemHuman sensory neuronsCalcium channel blockersSpinal cord injuryRat cortical culturesCord injuryAxonal regrowthRoot gangliaCortical culturesChannel blockersRegenerative propensityRegenerative axon growthSensory neuronsNervous systemPharmacological enhancersAxon growthPermanent lossSulfate proteoglycanAxotomyHuman neuroepithelial stem cell regional specificity enables spinal cord repair through a relay circuit
Dell’Anno M, Wang X, Onorati M, Li M, Talpo F, Sekine Y, Ma S, Liu F, Cafferty WBJ, Sestan N, Strittmatter SM. Human neuroepithelial stem cell regional specificity enables spinal cord repair through a relay circuit. Nature Communications 2018, 9: 3419. PMID: 30143638, PMCID: PMC6109094, DOI: 10.1038/s41467-018-05844-8.Peer-Reviewed Original ResearchConceptsHuman neuroepithelial stem cellsNeuroepithelial stem cellsSpinal cord injury recoverySpinal cord injury resultsNeural stem cell transplantationStem cell transplantationSpinal cord repairOptimal cell typeStem cellsGrafted neuronsPersistent disabilityFunctional recoveryTherapeutic optionsCell transplantationHost axonsInjury resultsSpinal cordRobust engraftmentImmunodeficient miceInjury recoveryAnatomical sitesNeural elementsSpecific marker proteinsTransplantationAdherent conditionsThe 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 expressionORL1Functional Genome-wide Screen Identifies Pathways Restricting Central Nervous System Axonal Regeneration
Sekine Y, Lin-Moore A, Chenette DM, Wang X, Jiang Z, Cafferty WB, Hammarlund M, Strittmatter SM. Functional Genome-wide Screen Identifies Pathways Restricting Central Nervous System Axonal Regeneration. Cell Reports 2018, 23: 415-428. PMID: 29642001, PMCID: PMC5937716, DOI: 10.1016/j.celrep.2018.03.058.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAxonsCaenorhabditis elegansCaenorhabditis elegans ProteinsCentral Nervous SystemFemaleGene Regulatory NetworksGenomeMiceMice, Inbred C57BLMice, KnockoutNerve RegenerationOptic NerveRab GTP-Binding ProteinsRecovery of FunctionRetinal Ganglion CellsRNA InterferenceRNA, Small InterferingSpinal Cord InjuriesSuppressor of Cytokine Signaling ProteinsConceptsAxonal regenerationCentral nervous system axonal regenerationRetinal ganglion cell axon regenerationGreater motor functionOptic nerve crushCerebral cortical neuronsSpinal cord traumaNeurological recoveryCord traumaNerve crushCNS injuryAxonal regrowthCortical neuronsMotor functionAxon regenerationReceptor bindingComprehensive functional screenAdult mammalsInjuryMultiple pathwaysExpression profilesIdentifies pathwaysSignificant overlapPathwayFunction screen
2017
Regulation of axonal regeneration by the level of function of the endogenous Nogo receptor antagonist LOTUS
Hirokawa T, Zou Y, Kurihara Y, Jiang Z, Sakakibara Y, Ito H, Funakoshi K, Kawahara N, Goshima Y, Strittmatter SM, Takei K. Regulation of axonal regeneration by the level of function of the endogenous Nogo receptor antagonist LOTUS. Scientific Reports 2017, 7: 12119. PMID: 28935984, PMCID: PMC5608707, DOI: 10.1038/s41598-017-12449-6.Peer-Reviewed Original ResearchConceptsSpinal cord injuryOptic nerve crushAxonal regenerationMotor recoveryNerve crushNeural repairRetinal ganglion cell axonal regenerationAdult mammalian central nervous systemIntrinsic motor recoverySpontaneous neural repairAxonal growth inhibitorsMammalian central nervous systemCentral nervous systemNon-permissive environmentLevel of functionUntreated miceFunctional recoveryCord injuryReceptor antagonistNeuronal overexpressionNervous systemGenetic deletionViral overexpressionCrushInhibitorsIdentification of Intrinsic Axon Growth Modulators for Intact CNS Neurons after Injury
Fink KL, López-Giráldez F, Kim IJ, Strittmatter SM, Cafferty WB. Identification of Intrinsic Axon Growth Modulators for Intact CNS Neurons after Injury. Cell Reports 2017, 18: 2687-2701. PMID: 28297672, PMCID: PMC5389739, DOI: 10.1016/j.celrep.2017.02.058.Peer-Reviewed Original ResearchConceptsSpinal cord injuryCentral nervous systemFunctional recoveryIntact neuronsAdult mammalian central nervous systemPartial spinal cord injuryInjury-induced sproutingUnilateral brainstem lesionsGreater functional recoverySpontaneous functional recoveryCorticospinal motor neuronsCorticospinal tract axonsMammalian central nervous systemWild-type miceNew synapse formationGrowth modulatorsAdjacent injuryBrainstem lesionsCord injuryFunctional deficitsIntact circuitryCNS neuronsMotor neuronsCircuit plasticityNervous system
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 increaseTractNogoAntagonistAxonsRewiring the spinal cord: Direct and indirect strategies
Dell’Anno M, Strittmatter SM. Rewiring the spinal cord: Direct and indirect strategies. Neuroscience Letters 2016, 652: 25-34. PMID: 28007647, PMCID: PMC5466898, DOI: 10.1016/j.neulet.2016.12.002.Peer-Reviewed Original ResearchConceptsSpinal cordNeural stem cellsNeural stem cell-derived neuronsTransplanted neural stem cellsNeural stem cell transplantationAdult central nervous systemLong-distance axonsNeutralization of myelinRecipient spinal cordStem cell transplantationSpinal cord injuryStem cell-derived neuronsCentral nervous systemCell-derived neuronsIntrinsic regenerative capacityPoor intrinsic regenerative capacityStem cellsNeurologic recoveryAxonal sproutingSecondary complicationsCell transplantationCord injuryAxonal regenerationGlial cellsAdult brainInhibition of Poly-ADP-Ribosylation Fails to Increase Axonal Regeneration or Improve Functional Recovery after Adult Mammalian CNS Injury
Wang X, Sekine Y, Byrne AB, Cafferty WB, Hammarlund M, Strittmatter SM. Inhibition of Poly-ADP-Ribosylation Fails to Increase Axonal Regeneration or Improve Functional Recovery after Adult Mammalian CNS Injury. ENeuro 2016, 3: eneuro.0270-16.2016. PMID: 28032120, PMCID: PMC5187389, DOI: 10.1523/eneuro.0270-16.2016.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAxonsBenzimidazolesCells, CulturedCerebral CortexDisease Models, AnimalFemaleIsoenzymesMaleMice, 129 StrainMice, Inbred C57BLMice, TransgenicMotor ActivityNerve RegenerationOptic Nerve InjuriesPoly (ADP-Ribose) Polymerase-1Poly(ADP-ribose) Polymerase InhibitorsRecovery of FunctionSpinal Cord InjuriesThoracic VertebraeConceptsOptic nerve crush injuryNerve crush injuryThoracic spinal cordAxonal regenerationSpinal cordDorsal hemisectionCrush injuryFunctional recoveryPARP inhibitorsMotor function recoveryRecovery of functionPoly (ADP-ribose) polymeraseClinical PARP inhibitorsNeurological recoveryShort hairpin RNACNS traumaCNS injuryFunction recoveryAxonal regrowthSystemic administrationPharmacodynamic actionAxon regenerationTraumatic damageTherapeutic efficacyNeurological traumaInhibiting poly(ADP-ribosylation) improves axon regeneration
Byrne AB, McWhirter RD, Sekine Y, Strittmatter SM, Miller DM, Hammarlund M. Inhibiting poly(ADP-ribosylation) improves axon regeneration. ELife 2016, 5: e12734. PMID: 27697151, PMCID: PMC5050021, DOI: 10.7554/elife.12734.Peer-Reviewed Original ResearchConceptsNovel intrinsic regulatorAxon regenerationDLK functionChemical inhibitionIntrinsic regulatorRegeneration pathwayPARG expressionIntrinsic regenerative potentialDLK signalingCritical functionsPARGRegenerative potentialPARP inhibitorsProteinPARPMammalian cortical neuronsRegenerationMotor neuronsGABA neuronsPolymeraseCortical neuronsSignalingRegulatorSpeciesNeurons
2015
Comprehensive 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 repairGene-Silencing Screen for Mammalian Axon Regeneration Identifies Inpp5f (Sac2) as an Endogenous Suppressor of Repair after Spinal Cord Injury
Zou Y, Stagi M, Wang X, Yigitkanli K, Siegel CS, Nakatsu F, Cafferty WB, Strittmatter SM. Gene-Silencing Screen for Mammalian Axon Regeneration Identifies Inpp5f (Sac2) as an Endogenous Suppressor of Repair after Spinal Cord Injury. Journal Of Neuroscience 2015, 35: 10429-10439. PMID: 26203138, PMCID: PMC4510284, DOI: 10.1523/jneurosci.1718-15.2015.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAxonsDisease Models, AnimalGene Knockdown TechniquesImmunohistochemistryInositol Polyphosphate 5-PhosphatasesMiceMice, Inbred C57BLMice, KnockoutNerve RegenerationPhosphoric Monoester HydrolasesRecovery of FunctionReverse Transcriptase Polymerase Chain ReactionSpinal Cord InjuriesConceptsSpinal cord injuryCord injuryEndogenous suppressorAxon regenerationNonoverlapping substrate specificityGenome-wide scaleHigh-throughput functional screensFunctional recoveryAxonal regenerationCNS axon repairSpinal cord injury researchDorsal hemisection injuryMammalian genesPI3K/AKT/mTOR pathwayCNS axon growthAKT/mTOR pathwayLipid phosphataseCorticospinal tract axonsCNS axon regenerationAdult mammalian CNSFunctional screenSubstrate specificityNovel suppressorShRNA resultsINPP5F