1 5600 130 ROLES OF VOLTAGE-DEPENDENT SODIUM CHANNELS IN NEURONAL DEVELOPMENT, PAIN, AND NEURODEGENERATION. BESIDES INITIATING AND PROPAGATING ACTION POTENTIALS IN ESTABLISHED NEURONAL CIRCUITS, VOLTAGE-DEPENDENT SODIUM CHANNELS SCULPT AND BOLSTER THE FUNCTIONAL NEURONAL NETWORK FROM EARLY IN EMBRYONIC DEVELOPMENT THROUGH ADULTHOOD (E.G., DIFFERENTIATION OF OLIGODENDROCYTE PRECURSOR CELLS INTO OLIGODENDROCYTES, MYELINATING AXON; COMPETITION BETWEEN NEIGHBORING EQUIPOTENTIAL NEURITES FOR DEVELOPMENT INTO A SINGLE AXON; ENHANCING AND OPPOSING FUNCTIONAL INTERACTIONS WITH ATTRACTIVE AND REPULSIVE MOLECULES FOR AXON PATHFINDING; EXTENDING AND RETRACTING TERMINAL ARBORIZATION OF AXON FOR CORRECT SYNAPSE FORMATION; EXPERIENCE-DRIVEN COGNITION; NEURONAL SURVIVAL; AND REMYELINATION OF DEMYELINATED AXONS). SURPRISINGLY, DIFFERENT PATTERNS OF ACTION POTENTIALS DIRECT HOMEOSTASIS-BASED EPIGENETIC SELECTION FOR NEUROTRANSMITTER PHENOTYPE, THUS EXCITABILITY BY SODIUM CHANNELS SPECIFYING EXPRESSION OF INHIBITORY NEUROTRANSMITTERS. MECHANISMS FOR THESE PLEIOTROPIC EFFECTS OF SODIUM CHANNELS INCLUDE RECIPROCAL INTERACTIONS BETWEEN NEURONS AND GLIA VIA NEUROTRANSMITTERS, GROWTH FACTORS, AND CYTOKINES AT SYNAPSES AND AXONS. SODIUM CHANNELOPATHIES CAUSING PAIN (E.G., ALLODYNIA) AND NEURODEGENERATION (E.G., MULTIPLE SCLEROSIS) DERIVE FROM 1) ELECTROPHYSIOLOGICAL DISTURBANCES BY INSULTS (E.G., ISCHEMIA/HYPOXIA, TOXINS, AND ANTIBODIES); 2) LOSS-OF-PHYSIOLOGICAL FUNCTION OR GAIN-OF-PATHOLOGICAL FUNCTION OF MUTANT SODIUM CHANNEL PROTEINS; 3) SPATIOTEMPORAL INAPPROPRIATE EXPRESSION OF NORMAL SODIUM CHANNEL PROTEINS; OR 4) DE-REPRESSED EXPRESSION OF OTHERWISE SILENT SODIUM CHANNEL GENES. NA(V)1.7 PROVED TO ACCOUNT FOR PAIN IN HUMAN ERYTHERMALGIA AND INFLAMMATION, BEING THE CONVINCING MOLECULAR TARGET OF PAIN TREATMENT. 2006 2 6567 19 TRANSLATOMIC RESPONSE OF RETINAL MULLER GLIA TO ACUTE AND CHRONIC STRESS. ANALYSIS OF RETINA CELL TYPE-SPECIFIC EPIGENETIC AND TRANSCRIPTOMIC SIGNATURES IS CRUCIAL TO UNDERSTANDING THE PATHOPHYSIOLOGY OF RETINAL DEGENERATIONS SUCH AS AGE-RELATED MACULAR DEGENERATION (AMD) AND DELINEATING CELL AUTONOMOUS AND CELL-NON-AUTONOMOUS MECHANISMS. WE HAVE DISCOVERED THAT ALDH1L1 IS SPECIFICALLY EXPRESSED IN THE MAJOR MACROGLIA OF THE RETINA, MULLER GLIA, AND, UNLIKE THE BRAIN, IS NOT EXPRESSED IN RETINAL ASTROCYTES. THIS ALLOWS USE OF ALDH1L1 CRE DRIVERS AND NUCLEAR TAGGING AND TRANSLATING RIBOSOME AFFINITY PURIFICATION (NUTRAP) CONSTRUCTS FOR TEMPORALLY CONTROLLED LABELING AND PAIRED ANALYSIS OF MULLER GLIA EPIGENOMES AND TRANSLATOMES. AS VALIDATED THROUGH A VARIETY OF APPROACHES, THE ALDH1L1CRE/ERT2-NUTRAP MODEL PROVIDES MULLER GLIA SPECIFIC TRANSLATOMIC AND EPIGENOMIC PROFILES WITHOUT THE NEED TO ISOLATE WHOLE CELLS. APPLICATION OF THIS APPROACH TO MODELS OF ACUTE INJURY (OPTIC NERVE CRUSH) AND CHRONIC STRESS (AGING) UNCOVERED FEW COMMON MULLER GLIA-SPECIFIC TRANSCRIPTOME CHANGES IN INFLAMMATORY PATHWAYS, AND MOSTLY DIFFERENTIAL SIGNATURES FOR EACH STIMULUS. THE EXPRESSION OF MEMBERS OF THE IL-6 AND INTEGRIN-LINKED KINASE SIGNALING PATHWAYS WAS ENHANCED IN MULLER GLIA IN RESPONSE TO OPTIC NERVE CRUSH BUT NOT AGING. UNIQUE CHANGES IN NEUROINFLAMMATION AND FIBROSIS SIGNALING PATHWAYS WERE OBSERVED IN RESPONSE TO AGING BUT NOT WITH OPTIC NERVE CRUSH. THE ALDH1L1CRE/ERT2-NUTRAP MODEL ALLOWS FOCUSED MOLECULAR ANALYSES OF A SINGLE, MINORITY CELL TYPE WITHIN THE RETINA, PROVIDING MORE SUBSTANTIAL EFFECT SIZES THAN WHOLE TISSUE ANALYSES. THE NUTRAP MODEL, NUCLEIC ACID ISOLATION, AND VALIDATION APPROACHES PRESENTED HERE CAN BE APPLIED TO ANY RETINA CELL TYPE FOR WHICH A CELL TYPE-SPECIFIC CRE IS AVAILABLE. 2022 3 1734 26 EAAT2 AS A RESEARCH TARGET IN BIPOLAR DISORDER AND UNIPOLAR DEPRESSION: A SYSTEMATIC REVIEW. GLUTAMATE IS IMPLICATED IN THE NEUROPATHOLOGY OF BOTH MAJOR DEPRESSIVE DISORDER AND BIPOLAR DISORDER. EXCITATORY AMINO ACID TRANSPORTER 2 (EAAT2) IS THE MAJOR GLUTAMATE TRANSPORTER IN THE MAMMALIAN BRAIN, REMOVING GLUTAMATE FROM THE SYNAPTIC CLEFT AND TRANSPORTING IT INTO GLIA FOR RECYCLING. IT IS THEREBY THE PRINCIPAL REGULATOR OF EXTRACELLULAR GLUTAMATE LEVELS AND PREVENTS NEURONAL EXCITOTOXICITY. EAAT2 IS A PROMISING TARGET FOR ELUCIDATING THE MECHANISMS BY WHICH THE GLUTAMATE-GLUTAMINE CYCLE INTERACTS WITH NEURONAL SYSTEMS IN MOOD DISORDERS. FORTY EAAT2 STUDIES (PUBLISHED JANUARY 1992-JANUARY 2018) WERE IDENTIFIED VIA A SYSTEMATIC LITERATURE SEARCH. THE STUDIES DEMONSTRATED THAT CHRONIC STRESS/STEROIDS WERE MOST COMMONLY ASSOCIATED WITH DECREASED EAAT2. IN RODENTS, EAAT2 INHIBITION WORSENED DEPRESSIVE BEHAVIORS. HUMAN EAAT2 EXPRESSION USUALLY DECREASED IN DEPRESSION, WITH SOME REGIONAL BRAIN DIFFERENCES. FEWER DATA HAVE BEEN COLLECTED REGARDING THE ROLES AND REGULATION OF EAAT2 IN BIPOLAR DISORDER. FUTURE DIRECTIONS FOR RESEARCH INCLUDE CORRELATING EAAT2 AND GLUTAMATE LEVELS IN VIVO, ELUCIDATING GENETIC VARIABILITY AND EPIGENETIC REGULATION, CLARIFYING INTRACELLULAR PROTEIN AND PHARMACOLOGIC INTERACTIONS, AND EXAMINING EAAT2 IN DIFFERENT BIPOLAR MOOD STATES. AS PART OF A MACROMOLECULAR COMPLEX WITHIN GLIA, EAAT2 MAY CONTRIBUTE SIGNIFICANTLY TO INTRACELLULAR SIGNALING, ENERGY REGULATION, AND CELLULAR HOMEOSTASIS. AN ENHANCED UNDERSTANDING OF THIS SYSTEM IS NEEDED. 2020 4 21 15 5-HYDROXYMETHYLCYTOSINE (5HMC) AND TEN-ELEVEN TRANSLOCATION 1-3 (TET1-3) PROTEINS IN THE DORSAL ROOT GANGLIA OF MOUSE: EXPRESSION AND DYNAMIC REGULATION IN NEUROPATHIC PAIN. EPIGENETIC MECHANISMS ARE INCREASINGLY IMPLICATED IN CHRONIC PAIN PATHOLOGY. IN THIS STUDY, WE DEMONSTRATE THAT THE NOVEL EPIGENETIC MARK 5-HYDROXYMETHYLCYTOSINE (5HMC) IS PRESENT IN DORSAL ROOT GANGLIA (DRG) NEURONS AND GLIA, AND ITS LEVELS INCREASE FOLLOWING NERVE INJURY. FURTHERMORE, WE SHOW THAT THE 5HMC-GENERATING TEN-ELEVEN TRANSLOCATION 1-3 (TET1-3) PROTEINS ARE EXPRESSED IN A CELL-TYPE SPECIFIC MANNER IN THE DRG, WITH TET3 DISPLAYING DIFFERENTIAL UPREGULATION AFTER INJURY, SUGGESTING A POTENTIAL ROLE IN NEUROPATHIC PAIN. 2017 5 4645 25 NEUROPATHIC PAIN: FROM MECHANISMS TO TREATMENT. NEUROPATHIC PAIN CAUSED BY A LESION OR DISEASE OF THE SOMATOSENSORY NERVOUS SYSTEM IS A COMMON CHRONIC PAIN CONDITION WITH MAJOR IMPACT ON QUALITY OF LIFE. EXAMPLES INCLUDE TRIGEMINAL NEURALGIA, PAINFUL POLYNEUROPATHY, POSTHERPETIC NEURALGIA, AND CENTRAL POSTSTROKE PAIN. MOST PATIENTS COMPLAIN OF AN ONGOING OR INTERMITTENT SPONTANEOUS PAIN OF, FOR EXAMPLE, BURNING, PRICKING, SQUEEZING QUALITY, WHICH MAY BE ACCOMPANIED BY EVOKED PAIN, PARTICULAR TO LIGHT TOUCH AND COLD. ECTOPIC ACTIVITY IN, FOR EXAMPLE, NERVE-END NEUROMA, COMPRESSED NERVES OR NERVE ROOTS, DORSAL ROOT GANGLIA, AND THE THALAMUS MAY IN DIFFERENT CONDITIONS UNDERLIE THE SPONTANEOUS PAIN. EVOKED PAIN MAY SPREAD TO NEIGHBORING AREAS, AND THE UNDERLYING PATHOPHYSIOLOGY INVOLVES PERIPHERAL AND CENTRAL SENSITIZATION. MALADAPTIVE STRUCTURAL CHANGES AND A NUMBER OF CELL-CELL INTERACTIONS AND MOLECULAR SIGNALING UNDERLIE THE SENSITIZATION OF NOCICEPTIVE PATHWAYS. THESE INCLUDE ALTERATION IN ION CHANNELS, ACTIVATION OF IMMUNE CELLS, GLIAL-DERIVED MEDIATORS, AND EPIGENETIC REGULATION. THE MAJOR CLASSES OF THERAPEUTICS INCLUDE DRUGS ACTING ON ALPHA(2)DELTA SUBUNITS OF CALCIUM CHANNELS, SODIUM CHANNELS, AND DESCENDING MODULATORY INHIBITORY PATHWAYS. 2021 6 6139 29 THE ETIOLOGICAL CONTRIBUTION OF GABAERGIC PLASTICITY TO THE PATHOGENESIS OF NEUROPATHIC PAIN. NEUROPATHIC PAIN DEVELOPING AFTER PERIPHERAL OR CENTRAL NERVE INJURY IS THE RESULT OF PATHOLOGICAL CHANGES GENERATED THROUGH COMPLEX MECHANISMS. DISRUPTION IN THE HOMEOSTASIS OF EXCITATORY AND INHIBITORY NEURONS WITHIN THE CENTRAL NERVOUS SYSTEM IS A CRUCIAL FACTOR IN THE FORMATION OF HYPERALGESIA OR ALLODYNIA OCCURRING WITH NEUROPATHIC PAIN. THE CENTRAL GABAERGIC PATHWAY HAS RECEIVED ATTENTION FOR ITS EXTENSIVE DISTRIBUTION AND FUNCTION IN NEURAL CIRCUITS, INCLUDING THE GENERATION AND DEVELOPMENT OF NEUROPATHIC PAIN. GABAERGIC INHIBITORY CHANGES THAT OCCUR IN THE INTERNEURONS ALONG DESCENDING MODULATORY AND NOCICEPTIVE PATHWAYS IN THE CENTRAL NERVOUS SYSTEM ARE BELIEVED TO GENERATE NEURONAL PLASTICITY, SUCH AS SYNAPTIC PLASTICITY OR FUNCTIONAL PLASTICITY OF THE RELATED GENES OR PROTEINS, THAT IS THE FOUNDATION OF PERSISTENT NEUROPATHIC PAIN. THE PRIMARY GABAERGIC PLASTICITY OBSERVED IN NEUROPATHIC PAIN INCLUDES GABAERGIC SYNAPSE HOMO- AND HETEROSYNAPTIC PLASTICITY, DECREASED SYNTHESIS OF GABA, DOWN-EXPRESSION OF GLUTAMIC ACID DECARBOXYLASE AND GABA TRANSPORTER, ABNORMAL EXPRESSION OF NKCC1 OR KCC2, AND DISTURBED FUNCTION OF GABA RECEPTORS. IN THIS REVIEW, WE DESCRIBE POSSIBLE MECHANISMS ASSOCIATED WITH GABAERGIC PLASTICITY, SUCH AS CENTRAL SENSITIZATION AND GABAERGIC INTERNEURON APOPTOSIS, AND THE EPIGENETIC ETIOLOGIES OF GABAERGIC PLASTICITY IN NEUROPATHIC PAIN. MOREOVER, WE SUMMARIZE POTENTIAL THERAPEUTIC TARGETS OF GABAERGIC PLASTICITY THAT MAY ALLOW FOR SUCCESSFUL RELIEF OF HYPERALGESIA FROM NERVE INJURY. FINALLY, WE COMPARE THE EFFECTS OF THE GABAERGIC SYSTEM IN NEUROPATHIC PAIN TO OTHER TYPES OF CHRONIC PAIN TO UNDERSTAND THE CONTRIBUTION OF GABAERGIC PLASTICITY TO NEUROPATHIC PAIN. 2019 7 1430 18 DIFFERENTIAL EXPRESSION OF SOX11 AND BDNF MRNA ISOFORMS IN THE INJURED AND REGENERATING NERVOUS SYSTEMS. IN BOTH THE CENTRAL NERVOUS SYSTEM (CNS) AND THE PERIPHERAL NERVOUS SYSTEM (PNS), AXONAL INJURY INDUCES CHANGES IN NEURONAL GENE EXPRESSION. IN THE PNS, A RELATIVELY WELL-CHARACTERIZED ALTERATION IN TRANSCRIPTIONAL ACTIVATION IS KNOWN TO PROMOTE AXONAL REGENERATION. THIS TRANSCRIPTIONAL CASCADE INCLUDES THE NEUROTROPHIN BDNF AND THE TRANSCRIPTION FACTOR SOX11. ALTHOUGH BOTH MOLECULES ACT TO FACILITATE SUCCESSFUL AXON REGENERATION IN THE PNS, THIS PROCESS DOES NOT OCCUR IN THE CNS. THE PRESENT STUDY EXAMINES THE DIFFERENTIAL EXPRESSION OF SOX11 AND BDNF MRNA ISOFORMS IN THE PNS AND CNS USING THREE EXPERIMENTAL PARADIGMS AT DIFFERENT TIME POINTS: (I) THE ACUTELY INJURED CNS (RETINA AFTER OPTIC NERVE CRUSH) AND PNS (DORSAL ROOT GANGLION AFTER SCIATIC NERVE CRUSH), (II) A CNS REGENERATION MODEL (RETINA AFTER OPTIC NERVE CRUSH AND INDUCED REGENERATION); AND (III) THE RETINA DURING A CHRONIC FORM OF CENTRAL NEURODEGENERATION (THE DBA/2J GLAUCOMA MODEL). WE FIND AN INITIAL INCREASE OF SOX11 IN BOTH PNS AND CNS AFTER INJURY; HOWEVER, THE EXPRESSION OF BDNF ISOFORMS IS HIGHER IN THE PNS RELATIVE TO THE CNS. SUSTAINED UPREGULATION OF SOX11 IS SEEN IN THE INJURED RETINA FOLLOWING REGENERATION TREATMENT, WHILE THE EXPRESSION OF TWO BDNF MRNA ISOFORMS IS SUPPRESSED. FURTHERMORE, TWO ISOFORMS OF SOX11 WITH DIFFERENT 3'UTR LENGTHS ARE PRESENT IN THE RETINA, AND THE LONG ISOFORM IS SPECIFICALLY UPREGULATED IN LATER STAGES OF GLAUCOMA. THESE RESULTS PROVIDE INSIGHT INTO THE MOLECULAR CASCADES ACTIVE DURING AXONAL INJURY AND REGENERATION IN MAMMALIAN NEURONS. 2017 8 2756 26 EXPRESSION OF DNA METHYLTRANSFERASES IN ADULT DORSAL ROOT GANGLIA IS CELL-TYPE SPECIFIC AND UP REGULATED IN A RODENT MODEL OF NEUROPATHIC PAIN. NEUROPATHIC PAIN IS ASSOCIATED WITH HYPEREXCITABILITY AND INTRINSIC FIRING OF DORSAL ROOT GANGLIA (DRG) NEURONS. THESE PHENOTYPICAL CHANGES CAN BE LONG LASTING, POTENTIALLY SPANNING THE ENTIRE LIFE OF ANIMAL MODELS, AND DEPEND ON ALTERED EXPRESSION OF NUMEROUS PROTEINS, INCLUDING MANY ION CHANNELS. YET, HOW DRGS MAINTAIN LONG-TERM CHANGES IN PROTEIN EXPRESSION IN NEUROPATHIC CONDITIONS REMAINS UNCLEAR. DNA METHYLATION IS A WELL-KNOWN MECHANISM OF EPIGENETIC CONTROL OF GENE EXPRESSION AND IS ACHIEVED BY THE ACTION OF THREE ENZYMES: DNA METHYLTRANSFERASE (DNMT) 1, 3A, AND 3B, WHICH HAVE BEEN STUDIED PRIMARILY DURING DEVELOPMENT. WE FIRST PERFORMED IMMUNOHISTOCHEMICAL ANALYSIS TO ASSESS WHETHER THESE ENZYMES ARE EXPRESSED IN ADULT RAT DRGS (L4-5) AND FOUND THAT DNMT1 IS EXPRESSED IN BOTH GLIA AND NEURONS, DNMT3A IS PREFERENTIALLY EXPRESSED IN GLIA AND DNMT3B IS PREFERENTIALLY EXPRESSED IN NEURONS. A RAT MODEL OF NEUROPATHIC PAIN WAS THEN USED TO DETERMINE WHETHER NERVE INJURY MAY INDUCE EPIGENETIC CHANGES IN DRGS AT MULTIPLE TIME POINTS AFTER PAIN ONSET. REAL-TIME RT PCR ANALYSIS REVEALED ROBUST AND TIME-DEPENDENT CHANGES IN DNMT TRANSCRIPT EXPRESSION IN IPSILATERAL DRGS FROM SPARED NERVE INJURY (SNI) BUT NOT SHAM RATS. INTERESTINGLY, DNMT3B TRANSCRIPT SHOWED A ROBUST UPREGULATION THAT APPEARED ALREADY 1 WEEK AFTER SURGERY AND PERSISTED AT 4 WEEKS (OUR ENDPOINT); IN CONTRAST, DNMT1 AND DNMT3A TRANSCRIPTS SHOWED ONLY MODERATE UPREGULATION THAT WAS TRANSIENT AND DID NOT APPEAR UNTIL THE SECOND WEEK. WE SUGGEST THAT DNMT REGULATION IN ADULT DRGS MAY BE A CONTRIBUTOR TO THE PAIN PHENOTYPE AND MERITS FURTHER STUDY. 2014 9 4149 21 MECHANISTIC INSIGHT INTO THE EFFECTS OF CURCUMIN ON NEUROINFLAMMATION-DRIVEN CHRONIC PAIN. CHRONIC PAIN IS A PERSISTENT AND UNREMITTING CONDITION THAT HAS IMMENSE EFFECTS ON PATIENTS' QUALITY OF LIFE. STUDIES HAVE SHOWN THAT NEUROINFLAMMATION IS ASSOCIATED WITH THE INDUCTION AND PROGRESSION OF CHRONIC PAIN. THE ACTIVATION OF MICROGLIA AND ASTROCYTES IS THE MAJOR HALLMARK OF SPINAL NEUROINFLAMMATION LEADING TO NEURONAL EXCITABILITY IN THE PROJECTION NEURONS. EXCESSIVE ACTIVATION OF MICROGLIA AND ASTROCYTES IS ONE OF THE MAJOR CONTRIBUTING FACTORS TO THE EXACERBATION OF PAIN. HOWEVER, THE CURRENT CHRONIC PAIN TREATMENTS, MAINLY BY TARGETING THE NEURONAL CELLS, REMAIN INEFFECTIVE AND UNABLE TO MEET THE PATIENTS' NEEDS. CURCUMIN, A NATURAL PLANT PRODUCT FOUND IN THE CURCUMA GENUS, IMPROVES CHRONIC PAIN BY DIMINISHING THE RELEASE OF INFLAMMATORY MEDIATORS FROM THE SPINAL GLIA. THIS REVIEW DETAILS THE ROLE OF CURCUMIN IN MICROGLIA AND ASTROCYTES BOTH IN VITRO AND IN VIVO AND HOW IT IMPROVES PAIN. WE ALSO DESCRIBE THE MECHANISM OF CURCUMIN BY HIGHLIGHTING THE MAJOR GLIA-MEDIATED CASCADES IN PAIN. MOREOVER, THE ROLE OF CURCUMIN ON INFLAMMASOME AND EPIGENETIC REGULATION IS DISCUSSED. FURTHERMORE, WE DISCUSS THE STRATEGIES USED TO IMPROVE THE EFFICACY OF CURCUMIN. THIS REVIEW ILLUSTRATES THAT CURCUMIN MODULATING MICROGLIA AND ASTROCYTES COULD ASSURE THE TREATMENT OF CHRONIC PAIN BY SUPPRESSING SPINAL NEUROINFLAMMATION. 2021 10 4641 24 NEURONAL NUCLEI ISOLATION FROM HUMAN POSTMORTEM BRAIN TISSUE. NEURONS IN THE HUMAN BRAIN BECOME POSTMITOTIC LARGELY DURING PRENATAL DEVELOPMENT, AND THUS MAINTAIN THEIR NUCLEI THROUGHOUT THE FULL LIFESPAN. HOWEVER, LITTLE IS KNOWN ABOUT CHANGES IN NEURONAL CHROMATIN AND NUCLEAR ORGANIZATION DURING THE COURSE OF DEVELOPMENT AND AGING, OR IN CHRONIC NEUROPSYCHIATRIC DISEASE. HOWEVER, TO DATE MOST CHROMATIN AND DNA BASED ASSAYS (OTHER THAN FISH) LACK SINGLE CELL RESOLUTION. TO THIS END, THE CONSIDERABLE CELLULAR HETEROGENEITY OF BRAIN TISSUE POSES A SIGNIFICANT LIMITATION, BECAUSE TYPICALLY VARIOUS SUBPOPULATIONS OF NEURONS ARE INTERMINGLED WITH DIFFERENT TYPES OF GLIA AND OTHER NON-NEURONAL CELLS. ONE POSSIBLE SOLUTION WOULD BE TO GROW CELL-TYPE SPECIFIC CULTURES, BUT MOST CNS CELLS, INCLUDING NEURONS, ARE EX VIVO SUSTAINABLE, AT BEST, FOR ONLY A FEW WEEKS AND THUS WOULD PROVIDE AN INCOMPLETE MODEL FOR EPIGENETIC MECHANISMS POTENTIALLY OPERATING ACROSS THE FULL LIFESPAN. HERE, WE PROVIDE A PROTOCOL TO EXTRACT AND PURIFY NUCLEI FROM FROZEN (NEVER FIXED) HUMAN POSTMORTEM BRAIN. THE METHOD INVOLVES EXTRACTION OF NUCLEI IN HYPOTONIC LYSIS BUFFER, FOLLOWED BY ULTRACENTRIFUGATION AND IMMUNOTAGGING WITH ANTI-NEUN ANTIBODY. LABELED NEURONAL NUCLEI ARE THEN COLLECTED SEPARATELY USING FLUORESCENCE-ACTIVATED SORTING. THIS METHOD SHOULD BE APPLICABLE TO ANY BRAIN REGION IN A WIDE RANGE OF SPECIES AND SUITABLE FOR CHROMATIN IMMUNOPRECIPITATION STUDIES WITH SITE- AND MODIFICATION-SPECIFIC ANTI-HISTONE ANTIBODIES, AND FOR DNA METHYLATION AND OTHER ASSAYS. 2008 11 3968 30 LONG-LASTING ANALGESIA VIA TARGETED IN SITU REPRESSION OF NA(V)1.7 IN MICE. CURRENT TREATMENTS FOR CHRONIC PAIN RELY LARGELY ON OPIOIDS DESPITE THEIR SUBSTANTIAL SIDE EFFECTS AND RISK OF ADDICTION. GENETIC STUDIES HAVE IDENTIFIED IN HUMANS KEY TARGETS PIVOTAL TO NOCICEPTIVE PROCESSING. IN PARTICULAR, A HEREDITARY LOSS-OF-FUNCTION MUTATION IN NA(V)1.7, A SODIUM CHANNEL PROTEIN ASSOCIATED WITH SIGNALING IN NOCICEPTIVE SENSORY AFFERENTS, LEADS TO INSENSITIVITY TO PAIN WITHOUT OTHER NEURODEVELOPMENTAL ALTERATIONS. HOWEVER, THE HIGH SEQUENCE AND STRUCTURAL SIMILARITY BETWEEN NA(V) SUBTYPES HAS FRUSTRATED EFFORTS TO DEVELOP SELECTIVE INHIBITORS. HERE, WE INVESTIGATED TARGETED EPIGENETIC REPRESSION OF NA(V)1.7 IN PRIMARY AFFERENTS VIA EPIGENOME ENGINEERING APPROACHES BASED ON CLUSTERED REGULARLY INTERSPACED SHORT PALINDROMIC REPEATS (CRISPR)-DCAS9 AND ZINC FINGER PROTEINS AT THE SPINAL LEVEL AS A POTENTIAL TREATMENT FOR CHRONIC PAIN. TOWARD THIS END, WE FIRST OPTIMIZED THE EFFICIENCY OF NA(V)1.7 REPRESSION IN VITRO IN NEURO2A CELLS AND THEN, BY THE LUMBAR INTRATHECAL ROUTE, DELIVERED BOTH EPIGENOME ENGINEERING PLATFORMS VIA ADENO-ASSOCIATED VIRUSES (AAVS) TO ASSESS THEIR EFFECTS IN THREE MOUSE MODELS OF PAIN: CARRAGEENAN-INDUCED INFLAMMATORY PAIN, PACLITAXEL-INDUCED NEUROPATHIC PAIN, AND BZATP-INDUCED PAIN. OUR RESULTS SHOW EFFECTIVE REPRESSION OF NA(V)1.7 IN LUMBAR DORSAL ROOT GANGLIA, REDUCED THERMAL HYPERALGESIA IN THE INFLAMMATORY STATE, DECREASED TACTILE ALLODYNIA IN THE NEUROPATHIC STATE, AND NO CHANGES IN NORMAL MOTOR FUNCTION IN MICE. WE ANTICIPATE THAT THIS LONG-LASTING ANALGESIA VIA TARGETED IN VIVO EPIGENETIC REPRESSION OF NA(V)1.7 METHODOLOGY WE DUB PAIN LATER, MIGHT HAVE THERAPEUTIC POTENTIAL IN MANAGEMENT OF PERSISTENT PAIN STATES. 2021 12 2882 25 G-PROTEIN-COUPLED RECEPTOR GPR17 REGULATES OLIGODENDROCYTE DIFFERENTIATION IN RESPONSE TO LYSOLECITHIN-INDUCED DEMYELINATION. OLIGODENDROCYTES ARE THE MYELIN-PRODUCING CELLS OF THE CENTRAL NERVOUS SYSTEM (CNS). A VARIETY OF BRAIN DISORDERS FROM "CLASSICAL" DEMYELINATING DISEASES, SUCH AS MULTIPLE SCLEROSIS, STROKE, SCHIZOPHRENIA, DEPRESSION, DOWN SYNDROME AND AUTISM, ARE SHOWN MYELINATION DEFECTS. OLIGODENDROCYTE MYELINATION IS REGULATED BY A COMPLEX INTERPLAY OF INTRINSIC, EPIGENETIC AND EXTRINSIC FACTORS. GPR17 (G PROTEIN-COUPLED RECEPTOR 17) IS A G PROTEIN-COUPLED RECEPTOR, AND HAS BEEN IDENTIFIED TO BE A REGULATOR FOR OLIGODENDROCYTE DEVELOPMENT. HERE, WE DEMONSTRATE THAT THE ABSENCE OF GPR17 ENHANCES REMYELINATION IN VIVO WITH A TOXIN-INDUCED MODEL WHEREBY FOCAL DEMYELINATED LESIONS ARE GENERATED IN SPINAL CORD WHITE MATTER OF ADULT MICE BY LOCALIZED INJECTION OF LPC(L-A-LYSOPHOSPHATIDYLCHOLINE). THE INCREASED EXPRESSION OF THE ACTIVATED FORM OF ERK1/2 (PHOSPHO-ERK1/2) IN LESION AREAS SUGGESTED THE POTENTIAL ROLE OF ERK1/2 ACTIVITY ON THE GPR17-DEPENDENT MODULATION OF MYELINATION. THE ABSENCE OF GPR17 ENHANCES REMYELINATION IS CORRELATE WITH THE ACTIVATED ERK1/2 (PHOSPHO-ERK1/2).BEING A MEMBRANE RECEPTOR, GPR17 REPRESENTS AN IDEAL DRUGGABLE TARGET TO BE EXPLOITED FOR INNOVATIVE REGENERATIVE APPROACHES TO ACUTE AND CHRONIC CNS DISEASES. 2018 13 533 28 ASTROCYTIC TRANSCRIPTION FACTOR REST UPREGULATES GLUTAMATE TRANSPORTER EAAT2, PROTECTING DOPAMINERGIC NEURONS FROM MANGANESE-INDUCED EXCITOTOXICITY. CHRONIC EXPOSURE TO HIGH LEVELS OF MANGANESE (MN) LEADS TO MANGANISM, A NEUROLOGICAL DISORDER WITH SIMILAR SYMPTOMS TO THOSE INHERENT TO PARKINSON'S DISEASE. HOWEVER, THE UNDERLYING MECHANISMS OF THIS PATHOLOGICAL CONDITION HAVE YET TO BE ESTABLISHED. SINCE THE HUMAN EXCITATORY AMINO ACID TRANSPORTER 2 (EAAT2) (GLUTAMATE TRANSPORTER 1 IN RODENTS) IS PREDOMINANTLY EXPRESSED IN ASTROCYTES AND ITS DYSREGULATION IS INVOLVED IN MN-INDUCED EXCITOTOXIC NEURONAL INJURY, CHARACTERIZATION OF THE MECHANISMS THAT MEDIATE THE MN-INDUCED IMPAIRMENT IN EAAT2 FUNCTION IS CRUCIAL FOR THE DEVELOPMENT OF NOVEL THERAPEUTICS AGAINST MN NEUROTOXICITY. REPRESSOR ELEMENT 1-SILENCING TRANSCRIPTION FACTOR (REST) EXERTS PROTECTIVE EFFECTS IN MANY NEURODEGENERATIVE DISEASES. BUT THE EFFECTS OF REST ON EAAT2 EXPRESSION AND ENSUING NEUROPROTECTION ARE UNKNOWN. GIVEN THAT THE EAAT2 PROMOTER CONTAINS REST BINDING SITES, THE PRESENT STUDY INVESTIGATED THE ROLE OF REST IN EAAT2 EXPRESSION AT THE TRANSCRIPTIONAL LEVEL IN ASTROCYTES AND MN-INDUCED NEUROTOXICITY IN AN ASTROCYTE-NEURON COCULTURE SYSTEM. THE RESULTS REVEAL THAT ASTROCYTIC REST POSITIVELY REGULATES EAAT2 EXPRESSION WITH THE RECRUITMENT OF AN EPIGENETIC MODIFIER, CAMP RESPONSE ELEMENT-BINDING PROTEIN-BINDING PROTEIN/P300, TO ITS CONSENSUS BINDING SITES IN THE EAAT2 PROMOTER. MOREOVER, ASTROCYTIC OVEREXPRESSION OF REST ATTENUATES MN-INDUCED REDUCTION IN EAAT2 EXPRESSION, LEADING TO ATTENUATION OF GLUTAMATE-INDUCED NEUROTOXICITY IN THE ASTROCYTE-NEURON COCULTURE SYSTEM. OUR FINDINGS DEMONSTRATE THAT ASTROCYTIC REST PLAYS A CRITICAL ROLE IN PROTECTION AGAINST MN-INDUCED NEUROTOXICITY BY ATTENUATING MN-INDUCED EAAT2 REPRESSION AND THE ENSUING EXCITOTOXIC DOPAMINERGIC NEURONAL INJURY. THIS INDICATES THAT ASTROCYTIC REST COULD BE A POTENTIAL MOLECULAR TARGET FOR THE TREATMENT OF MN TOXICITY AND OTHER NEUROLOGICAL DISORDERS ASSOCIATED WITH EAAT2 DYSREGULATION. 2021 14 4616 22 NERVE INJURY INCREASES BRAIN-DERIVED NEUROTROPHIC FACTOR LEVELS TO SUPPRESS BK CHANNEL ACTIVITY IN PRIMARY SENSORY NEURONS. ABNORMAL HYPEREXCITABILITY OF PRIMARY SENSORY NEURONS CONTRIBUTES TO NEUROPATHIC PAIN DEVELOPMENT AFTER NERVE INJURY. NERVE INJURY PROFOUNDLY REDUCES THE EXPRESSION OF BIG CONDUCTANCE CA(2+) -ACTIVATED K(+) (BK) CHANNELS IN THE DORSAL ROOT GANGLION (DRG). HOWEVER, LITTLE IS KNOWN ABOUT HOW NERVE INJURY AFFECTS BK CHANNEL ACTIVITY IN DRG NEURONS. IN THIS STUDY, WE DETERMINED THE CHANGES IN BK CHANNEL ACTIVITY IN DRG NEURONS IN A RAT MODEL OF NEUROPATHIC PAIN AND THE CONTRIBUTION OF BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) TO REDUCED BK CHANNEL ACTIVITY. THE BK CHANNEL ACTIVITY WAS PRESENT PREDOMINANTLY IN SMALL AND MEDIUM DRG NEURONS, AND LIGATION OF L5 AND L6 SPINAL NERVES PROFOUNDLY DECREASED THE BK CURRENT DENSITY IN THESE NEURONS. BLOCKING BK CHANNELS SIGNIFICANTLY INCREASED NEURONAL EXCITABILITY IN SHAM CONTROL, BUT NOT IN NERVE-INJURED, RATS. THE BDNF CONCENTRATION IN THE DRG WAS SIGNIFICANTLY GREATER IN NERVE-INJURED RATS THAN IN CONTROL RATS. BDNF TREATMENT LARGELY REDUCED BK CURRENTS IN DRG NEURONS IN CONTROL RATS, WHICH WAS BLOCKED BY EITHER ANTI-BDNF ANTIBODY OR K252A, A TRK RECEPTOR INHIBITOR. FURTHERMORE, EITHER ANTI-BDNF ANTIBODY OR K252A REVERSED REDUCTION IN BK CURRENTS IN INJURED DRG NEURONS. BDNF TREATMENT REDUCED THE MRNA LEVELS OF BKALPHA1 SUBUNIT IN DRG NEURONS, AND ANTI-BDNF ANTIBODY ATTENUATED THE REDUCTION IN THE BKALPHA1 MRNA LEVEL IN INJURED DRG NEURONS. THESE FINDINGS SUGGEST THAT NERVE INJURY PRIMARILY DIMINISHES THE BK CHANNEL ACTIVITY IN SMALL AND MEDIUM DRG NEURONS. INCREASED BDNF LEVELS CONTRIBUTE TO REDUCED BK CHANNEL ACTIVITY IN DRG NEURONS THROUGH EPIGENETIC AND TRANSCRIPTIONAL MECHANISMS IN NEUROPATHIC PAIN. 2012 15 1850 24 ELECTROACUPUNCTURE AMELIORATES DEPRESSION-LIKE BEHAVIORS COMORBID TO CHRONIC NEUROPATHIC PAIN VIA TET1-MEDIATED RESTORATION OF ADULT NEUROGENESIS. ALTHOUGH ELECTROACUPUNCTURE (EA) STIMULATION IS A WIDELY USED THERAPY FOR CHRONIC PAIN AND COMORBID PSYCHIATRIC DISORDERS, ITS LONG-TERM EFFECTS ON CHRONIC NEUROPATHIC PAIN-INDUCED DEPRESSION AND THE UNDERLYING MECHANISMS REMAIN ELUSIVE. IN THE PRESENT STUDY, WE FOUND THAT EA STIMULATION WAS ABLE TO RESTORE ADULT NEUROGENESIS IN THE VENTRAL DENTATE GYRUS (DG), BY BOTH INCREASING NEURONAL DIFFERENTIATION AND RESTORING THE NORMAL MORPHOLOGY OF NEWBORN DENDRITES, IN MICE WITH SPARED NERVE INJURY SURGERY. BY ABLATING THE NESTIN+ NEURAL STEM CELLS (NSCS) VIA DIPHTHERIA TOXIN FRAGMENT A EXPRESSION, WE FURTHER PROVED THAT NEUROGENESIS IN THE VENTRAL DG WAS CRUCIAL TO THE LONG-TERM, BUT NOT THE IMMEDIATE ANTIDEPRESSANT EFFECT OF EA, NOR WAS IT ASSOCIATED WITH NOCICEPTION. FURTHERMORE, WE FOUND THAT THE RESTORATION OF NEUROGENESIS WAS DEPENDENT ON TET1-MEDIATED EPIGENETIC MODIFICATION UPON EA TREATMENT. TET1 COULD BIND TO THE PROMOTER OF THE PROX1 GENE, THUS CATALYZING ITS DEMETHYLATION AND FACILITATING ITS EXPRESSION, WHICH FINALLY CONTRIBUTED TO THE RESTORATION OF NEUROGENESIS AND AMELIORATION OF DEPRESSION-LIKE BEHAVIORS INDUCED BY CHRONIC NEUROPATHIC PAIN. THUS, WE CONCLUDE THAT EA STIMULATION RESTORES INHIBITED TET1 EXPRESSION IN HIPPOCAMPAL NSCS OF MICE WITH CHRONIC NEUROPATHIC PAIN, AND INCREASED TET1 EXPRESSION AMELIORATES HYPERMETHYLATION OF PROX1 AND RESTORES NORMAL ADULT NEUROGENESIS IN THE VENTRAL DG, WHICH CONTRIBUTES TO THE LONG-TERM ANTIDEPRESSANT EFFECT OF EA. 2023 16 80 29 A NEW ROLE FOR THE P2Y-LIKE GPR17 RECEPTOR IN THE MODULATION OF MULTIPOTENCY OF OLIGODENDROCYTE PRECURSOR CELLS IN VITRO. OLIGODENDROCYTE PRECURSOR CELLS (OPCS, ALSO CALLED NG2 CELLS) ARE SCATTERED THROUGHOUT BRAIN PARENCHYMA, WHERE THEY FUNCTION AS A RESERVOIR TO REPLACE LOST OR DAMAGED OLIGODENDROCYTES, THE MYELIN-FORMING CELLS. THE HYPOTHESIS THAT, UNDER SOME CIRCUMSTANCES, OPCS CAN ACTUALLY BEHAVE AS MULTIPOTENT CELLS, THUS GENERATING ASTROCYTES AND NEURONS AS WELL, HAS ARISEN FROM SOME IN VITRO AND IN VIVO EVIDENCE, BUT THE MOLECULAR PATHWAYS CONTROLLING THIS ALTERNATIVE FATE OF OPCS ARE NOT FULLY UNDERSTOOD. THEIR IDENTIFICATION WOULD OPEN NEW OPPORTUNITIES FOR NEURONAL REPLACE STRATEGIES, BY FOSTERING THE INTRINSIC ABILITY OF THE BRAIN TO REGENERATE. HERE, WE SHOW THAT THE ANTI-EPILEPTIC EPIGENETIC MODULATOR VALPROIC ACID (VPA) CAN PROMOTE THE GENERATION OF NEW NEURONS FROM NG2(+) OPCS UNDER NEUROGENIC PROTOCOLS IN VITRO, THROUGH THEIR INITIAL DE-DIFFERENTIATION TO A STEM CELL-LIKE PHENOTYPE THAT THEN EVOLVES TO "HYBRID" CELL POPULATION, SHOWING OPC MORPHOLOGY BUT EXPRESSING THE NEURONAL MARKER BETAIII-TUBULIN AND THE GPR17 RECEPTOR, A KEY DETERMINANT IN DRIVING OPC TRANSITION TOWARDS MYELINATING OLIGODENDROCYTES. UNDER THESE CONDITIONS, THE PHARMACOLOGICAL BLOCKADE OF THE P2Y-LIKE RECEPTOR GPR17 BY CANGRELOR, A DRUG RECENTLY APPROVED FOR HUMAN USE, PARTIALLY MIMICS THE EFFECTS MEDIATED BY VPA THUS ACCELERATING CELLS' NEUROGENIC CONVERSION. THESE DATA SHOW A CO-LOCALIZATION BETWEEN NEURONAL MARKERS AND GPR17 IN VITRO, AND SUGGEST THAT, BESIDES ITS INVOLVEMENT IN OLIGODENDROGENESIS, GPR17 CAN DRIVE THE FATE OF NEURAL PRECURSOR CELLS BY INSTRUCTING PRECURSORS TOWARDS THE NEURONAL LINEAGE. BEING A MEMBRANE RECEPTOR, GPR17 REPRESENTS AN IDEAL "DRUGGABLE" TARGET TO BE EXPLOITED FOR INNOVATIVE REGENERATIVE APPROACHES TO ACUTE AND CHRONIC BRAIN DISEASES. 2016 17 2927 27 GENERATION OF HUMAN CORTICAL NEURONS FROM A NEW IMMORTAL FETAL NEURAL STEM CELL LINE. ISOLATION AND EXPANSION OF NEURAL STEM CELLS (NSCS) OF HUMAN ORIGIN ARE CRUCIAL FOR SUCCESSFUL DEVELOPMENT OF CELL THERAPY APPROACHES IN NEURODEGENERATIVE DISEASES. DIFFERENT EPIGENETIC AND GENETIC IMMORTALIZATION STRATEGIES HAVE BEEN ESTABLISHED FOR LONG-TERM MAINTENANCE AND EXPANSION OF THESE CELLS IN VITRO. HERE WE REPORT THE GENERATION OF A NEW, CLONAL NSC (HC-NSC) LINE, DERIVED FROM HUMAN FETAL CORTICAL TISSUE, BASED ON V-MYC IMMORTALIZATION. USING IMMUNOCYTOCHEMISTRY, WE SHOW THAT THESE CELLS RETAIN THE CHARACTERISTICS OF NSCS AFTER MORE THAN 50 PASSAGES. UNDER PROLIFERATION CONDITIONS, WHEN SUPPLEMENTED WITH EPIDERMAL AND BASIC FIBROBLAST GROWTH FACTORS, THE HC-NSCS EXPRESSED NEURAL STEM/PROGENITOR CELL MARKERS LIKE NESTIN, VIMENTIN AND SOX2. WHEN GROWTH FACTORS WERE WITHDRAWN, PROLIFERATION AND EXPRESSION OF V-MYC AND TELOMERASE WERE DRAMATICALLY REDUCED, AND THE HC-NSCS DIFFERENTIATED INTO GLIA AND NEURONS (MOSTLY GLUTAMATERGIC AND GABAERGIC, AS WELL AS TYROSINE HYDROXYLASE-POSITIVE, PRESUMABLY DOPAMINERGIC NEURONS). RT-PCR ANALYSIS SHOWED THAT THE HC-NSCS RETAINED EXPRESSION OF PAX6, EMX2 AND NEUROGENIN2, WHICH ARE GENES ASSOCIATED WITH REGIONALIZATION AND CELL COMMITMENT IN CORTICAL PRECURSORS DURING BRAIN DEVELOPMENT. OUR DATA INDICATE THAT THIS HC-NSC LINE COULD BE USEFUL FOR EXPLORING THE POTENTIAL OF HUMAN NSCS TO REPLACE DEAD OR DAMAGED CORTICAL CELLS IN ANIMAL MODELS OF ACUTE AND CHRONIC NEURODEGENERATIVE DISEASES. TAKING ADVANTAGE OF ITS CLONALITY AND HOMOGENEITY, THIS CELL LINE WILL ALSO BE A VALUABLE EXPERIMENTAL TOOL TO STUDY THE REGULATORY ROLE OF INTRINSIC AND EXTRINSIC FACTORS IN HUMAN NSC BIOLOGY. 2007 18 4625 23 NEUROBIOLOGY OF VITAMIN C: EXPANDING THE FOCUS FROM ANTIOXIDANT TO ENDOGENOUS NEUROMODULATOR. ASCORBIC ACID (AA) IS A WATER-SOLUBLE VITAMIN (C) FOUND IN ALL BODILY ORGANS. MOST MAMMALS SYNTHESIZE IT, HUMANS ARE REQUIRED TO EAT IT, BUT ALL MAMMALS NEED IT FOR HEALTHY FUNCTIONING. AA REACHES ITS HIGHEST CONCENTRATION IN THE BRAIN WHERE BOTH NEURONS AND GLIA RELY ON TIGHTLY REGULATED UPTAKE FROM BLOOD VIA THE GLUCOSE TRANSPORT SYSTEM AND SODIUM-COUPLED ACTIVE TRANSPORT TO ACCUMULATE AND MAINTAIN AA AT MILLIMOLAR LEVELS. AS A PROTOTYPE ANTIOXIDANT, AA IS NOT ONLY NEUROPROTECTIVE, BUT ALSO FUNCTIONS AS A COFACTOR IN REDOX-COUPLED REACTIONS ESSENTIAL FOR THE SYNTHESIS OF NEUROTRANSMITTERS (E.G., DOPAMINE AND NOREPINEPHRINE) AND PARACRINE LIPID MEDIATORS (E.G., EPOXIECOISATRIENOIC ACIDS) AS WELL AS THE EPIGENETIC REGULATION OF DNA. ALTHOUGH REDOX CAPACITY LED TO THE PROMOTION OF AA IN HIGH DOSES AS POTENTIAL TREATMENT FOR VARIOUS NEUROPATHOLOGICAL AND PSYCHIATRIC CONDITIONS, AMPLE EVIDENCE HAS NOT SUPPORTED THIS THERAPEUTIC STRATEGY. HERE, WE FOCUS ON SOME LONG-NEGLECTED ASPECTS OF AA NEUROBIOLOGY, INCLUDING ITS MODULATORY ROLE IN SYNAPTIC TRANSMISSION AS DEMONSTRATED BY THE LONG-ESTABLISHED LINK BETWEEN RELEASE OF ENDOGENOUS AA IN BRAIN EXTRACELLULAR FLUID AND THE CLEARANCE OF GLUTAMATE, AN EXCITATORY AMINO ACID. EVIDENCE THAT THIS LINK CAN BE DISRUPTED IN ANIMAL MODELS OF HUNTINGTON S DISEASE IS REVEALING OPPORTUNITIES FOR NEW RESEARCH PATHWAYS AND THERAPEUTIC APPLICATIONS (E.G., EPILEPSY AND PAIN MANAGEMENT). IN FACT, WE SUGGEST THAT IMPROVED UNDERSTANDING OF THE REGULATION OF ENDOGENOUS AA AND ITS INTERACTION WITH KEY BRAIN NEUROTRANSMITTER SYSTEMS, RATHER THAN ADMINISTRATION OF AA IN EXCESS, SHOULD BE THE TARGET OF FUTURE BRAIN-BASED THERAPIES. 2019 19 2179 21 EPIGENETIC MECHANISMS OF NEURAL PLASTICITY IN CHRONIC NEUROPATHIC PAIN. NEUROPATHIC PAIN IS A CHALLENGING CLINICAL PROBLEM AND REMAINS DIFFICULT TO TREAT. ALTERED GENE EXPRESSION IN PERIPHERAL SENSORY NERVES AND NEURONS DUE TO NERVE INJURY IS WELL DOCUMENTED AND CONTRIBUTES CRITICALLY TO THE SYNAPTIC PLASTICITY IN THE SPINAL CORD AND THE INITIATION AND MAINTENANCE OF CHRONIC PAIN. HOWEVER, OUR UNDERSTANDING OF THE EPIGENETIC MECHANISMS REGULATING THE TRANSCRIPTION OF PRO-NOCICEPTIVE (E.G., NMDA RECEPTORS AND ALPHA2DELTA-1) AND ANTINOCICEPTIVE (E.G., POTASSIUM CHANNELS AND OPIOID AND CANNABINOID RECEPTORS) GENES ARE STILL LIMITED. IN THIS REVIEW, WE SUMMARIZE RECENT STUDIES DETERMINING THE ROLES OF HISTONE MODIFICATIONS (INCLUDING METHYLATION, ACETYLATION, AND UBIQUITINATION), DNA METHYLATION, AND NONCODING RNAS IN NEUROPATHIC PAIN DEVELOPMENT. WE REVIEW THE EPIGENETIC WRITER, READER, AND ERASER PROTEINS THAT PARTICIPATE IN THE TRANSCRIPTIONAL CONTROL OF THE EXPRESSION OF KEY ION CHANNELS AND NEUROTRANSMITTER RECEPTORS IN THE DORSAL ROOT GANGLION AFTER TRAUMATIC NERVE INJURY, WHICH IS COMMONLY USED AS A PRECLINICAL MODEL OF NEUROPATHIC PAIN. A BETTER UNDERSTANDING OF EPIGENETIC REPROGRAMMING INVOLVED IN THE TRANSITION FROM ACUTE TO CHRONIC PAIN COULD LEAD TO THE DEVELOPMENT OF NEW TREATMENTS FOR NEUROPATHIC PAIN. 2022 20 4614 29 NERVE EXCITABILITY AND NEUROPATHIC PAIN IS REDUCED BY BET PROTEIN INHIBITION AFTER SPARED NERVE INJURY. NEUROPATHIC PAIN IS A COMMON DISABILITY PRODUCED BY ENHANCED NEURONAL EXCITABILITY AFTER NERVOUS SYSTEM INJURY. THE PATHOPHYSIOLOGICAL CHANGES THAT UNDERLIE THE GENERATION AND MAINTENANCE OF NEUROPATHIC PAIN REQUIRE MODIFICATIONS OF TRANSCRIPTIONAL PROGRAMS. IN PARTICULAR, THERE IS AN INDUCTION OF PRO-INFLAMMATORY NEUROMODULATORS LEVELS, AND CHANGES IN THE EXPRESSION OF ION CHANNELS AND OTHER FACTORS INTERVENING IN THE DETERMINATION OF THE MEMBRANE POTENTIAL IN NEURONAL CELLS. WE HAVE PREVIOUSLY FOUND THAT INHIBITION OF THE BET PROTEINS EPIGENETIC READERS REDUCED NEUROINFLAMMATION AFTER SPINAL CORD INJURY. WITHIN THE PRESENT STUDY WE AIMED TO DETERMINE IF BET PROTEIN INHIBITION MAY ALSO AFFECT NEUROINFLAMMATION AFTER A PERIPHERAL NERVE INJURY, AND IF THIS WOULD BENEFICIALLY ALTER NEURONAL EXCITABILITY AND NEUROPATHIC PAIN. FOR THIS PURPOSE, C57BL/6 FEMALE MICE UNDERWENT SPARED NERVE INJURY (SNI), AND WERE TREATED WITH THE BET INHIBITOR JQ1, OR VEHICLE. ELECTROPHYSIOLOGICAL AND ALGESIMETRY TESTS WERE PERFORMED ON THESE MICE. WE ALSO DETERMINED THE EFFECTS OF JQ1 TREATMENT AFTER INJURY ON NEUROINFLAMMATION, AND THE EXPRESSION OF NEURONAL COMPONENTS IMPORTANT FOR THE MAINTENANCE OF AXON MEMBRANE POTENTIAL. WE FOUND THAT TREATMENT WITH JQ1 AFFECTED NEURONAL EXCITABILITY AND MECHANICAL HYPERALGESIA AFTER SNI IN MICE. BET PROTEIN INHIBITION REGULATED CYTOKINE EXPRESSION AND REDUCED MICROGLIAL REACTIVITY AFTER INJURY. IN ADDITION, JQ1 TREATMENT ALTERED THE EXPRESSION OF SCN3A, SCN9A, KCNA1, KCNQ2, KCNQ3, HCN1 AND HCN2 ION CHANNELS, AS WELL AS THE EXPRESSION OF THE NA(+)/K(+) ATPASE PUMP SUBUNITS. IN CONCLUSION, BOTH, ALTERATION OF INFLAMMATION, AND NEURONAL TRANSCRIPTION, COULD BE THE RESPONSIBLE EPIGENETIC MECHANISMS FOR THE REDUCTION OF EXCITABILITY AND HYPERALGESIA OBSERVED AFTER BET INHIBITION. INHIBITION OF BET PROTEINS IS A PROMISING THERAPY FOR REDUCING NEUROPATHIC PAIN AFTER NEURAL INJURY. PERSPECTIVE: NEUROPATHIC PAIN IS A COMMON DISABILITY PRODUCED BY ENHANCED NEURONAL EXCITABILITY AFTER NERVOUS SYSTEM INJURY. THE UNDERLYING PATHOPHYSIOLOGICAL CHANGES REQUIRE MODIFICATIONS OF TRANSCRIPTIONAL PROGRAMS. THIS STUDY NOTES THAT INHIBITION OF BET PROTEINS IS A PROMISING THERAPY FOR REDUCING NEUROPATHIC PAIN AFTER NEURAL INJURY. 2021