1 5408 129 REGULATION AND SIGNALING OF THE GPR17 RECEPTOR IN OLIGODENDROGLIAL CELLS. REMYELINATION, NAMELY, THE FORMATION OF NEW MYELIN SHEATHS AROUND DENUDED AXONS, COUNTERACTS AXONAL DEGENERATION AND RESTORES NEURONAL FUNCTION. CONSIDERABLE ADVANCES HAVE BEEN MADE IN UNDERSTANDING THIS REGENERATIVE PROCESS THAT OFTEN FAILS IN DISEASES LIKE MULTIPLE SCLEROSIS, LEAVING AXONS DEMYELINATED AND VULNERABLE TO DAMAGE, THUS CONTRIBUTING TO DISEASE PROGRESSION. THE IDENTIFICATION OF THE MEMBRANE RECEPTOR GPR17 ON A SUBSET OF OLIGODENDROCYTE PRECURSOR CELLS (OPCS), WHICH MEDIATE REMYELINATION IN THE ADULT CENTRAL NERVOUS SYSTEM (CNS), HAS LED TO A HUGE AMOUNT OF EVIDENCE THAT VALIDATED THIS RECEPTOR AS A NEW ATTRACTIVE TARGET FOR REMYELINATING THERAPIES. HERE, WE SUMMARIZE THE ROLE OF GPR17 IN OPC FUNCTION, MYELINATION AND REMYELINATION, DESCRIBING ITS ATYPICAL PHARMACOLOGY, ITS DOWNSTREAM SIGNALING, AND THE GENETIC AND EPIGENETIC FACTORS MODULATING ITS ACTIVITY. WE ALSO HIGHLIGHT CRUCIAL INSIGHTS INTO GPR17 PATHOPHYSIOLOGY COMING FROM THE DEMONSTRATION THAT OLIGODENDROCYTE INJURY, ASSOCIATED WITH INFLAMMATION IN CHRONIC NEURODEGENERATIVE CONDITIONS, IS INVARIABLY CHARACTERIZED BY ABNORMAL AND PERSISTENT GPR17 UPREGULATION, WHICH, IN TURN, IS ACCOMPANIED BY A BLOCK OF OPCS AT IMMATURE PREMYELINATING STAGES. FINALLY, WE DISCUSS THE CURRENT LITERATURE IN LIGHT OF THE POTENTIAL EXPLOITMENT OF GPR17 AS A THERAPEUTIC TARGET TO PROMOTE REMYELINATION. 2020 2 764 29 CBP/P300 ACTIVATION PROMOTES AXON GROWTH, SPROUTING, AND SYNAPTIC PLASTICITY IN CHRONIC EXPERIMENTAL SPINAL CORD INJURY WITH SEVERE DISABILITY. THE INTERRUPTION OF SPINAL CIRCUITRY FOLLOWING SPINAL CORD INJURY (SCI) DISRUPTS NEURAL ACTIVITY AND IS FOLLOWED BY A FAILURE TO MOUNT AN EFFECTIVE REGENERATIVE RESPONSE RESULTING IN PERMANENT NEUROLOGICAL DISABILITY. FUNCTIONAL RECOVERY REQUIRES THE ENHANCEMENT OF AXONAL AND SYNAPTIC PLASTICITY OF SPARED AS WELL AS INJURED FIBRES, WHICH NEED TO SPROUT AND/OR REGENERATE TO FORM NEW CONNECTIONS. HERE, WE HAVE INVESTIGATED WHETHER THE EPIGENETIC STIMULATION OF THE REGENERATIVE GENE EXPRESSION PROGRAM CAN OVERCOME THE CURRENT INABILITY TO PROMOTE NEUROLOGICAL RECOVERY IN CHRONIC SCI WITH SEVERE DISABILITY. WE DELIVERED THE CBP/P300 ACTIVATOR CSP-TTK21 OR VEHICLE CSP WEEKLY BETWEEN WEEK 12 AND 22 FOLLOWING A TRANSECTION MODEL OF SCI IN MICE HOUSED IN AN ENRICHED ENVIRONMENT. DATA ANALYSIS SHOWED THAT CSP-TTK21 ENHANCED CLASSICAL REGENERATIVE SIGNALLING IN DORSAL ROOT GANGLIA SENSORY BUT NOT CORTICAL MOTOR NEURONS, STIMULATED MOTOR AND SENSORY AXON GROWTH, SPROUTING, AND SYNAPTIC PLASTICITY, BUT FAILED TO PROMOTE NEUROLOGICAL SENSORIMOTOR RECOVERY. THIS WORK PROVIDES DIRECT EVIDENCE THAT CLINICALLY SUITABLE PHARMACOLOGICAL CBP/P300 ACTIVATION CAN PROMOTE THE EXPRESSION OF REGENERATION-ASSOCIATED GENES AND AXONAL GROWTH IN A CHRONIC SCI WITH SEVERE NEUROLOGICAL DISABILITY. 2022 3 1430 26 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 4 6117 36 THE EPIGENETIC DRUG TRICHOSTATIN A AMELIORATES EXPERIMENTAL AUTOIMMUNE ENCEPHALOMYELITIS VIA T CELL TOLERANCE INDUCTION AND IMPAIRED INFLUX OF T CELLS INTO THE SPINAL CORD. MULTIPLE SCLEROSIS IS A T CELL MEDIATED CHRONIC DEMYELINATING DISEASE OF THE CENTRAL NERVOUS SYSTEM. ALTHOUGH CURRENTLY AVAILABLE THERAPIES REDUCE RELAPSES, THEY DO NOT FACILITATE TOLERIZATION OF MYELIN ANTIGEN-SPECIFIC T LYMPHOCYTES TO ENSURE PROLONGED PROTECTION AGAINST MULTIPLE SCLEROSIS. HERE, WE SHOW THAT TREATMENT OF NOD MICE WITH THE HISTONE DEACETYLASE INHIBITOR, TRICHOSTATIN A AFFORDS ROBUST PROTECTION AGAINST MYELIN PEPTIDE INDUCED EXPERIMENTAL AUTOIMMUNE ENCEPHALOMYELITIS, A MOUSE MODEL OF MULTIPLE SCLEROSIS. PROTECTION WAS ACCOMPANIED BY HISTONE HYPERACETYLATION, AND REDUCED INFLAMMATION AND AXONAL DAMAGE IN THE SPINAL CORD. DRUG TREATMENT DIMINISHED THE GENERATION OF CD4(+) MEMORY T CELLS AND INDUCED TOLERANCE IN CD4(+) T CELLS RECOGNIZING THE IMMUNIZING MYELIN PEPTIDE. DURING THE EARLY IMMUNIZATION PERIOD, CD4(+) T CELLS PRODUCING GM-CSF+IFN-GAMMA, GM-CSF+IL-17A, AS WELL AS THOSE EXPRESSING BOTH IL-17A+IFN-GAMMA (DOUBLE-PRODUCERS) WERE DETECTED IN THE SECONDARY LYMPHOID ORGANS FOLLOWED BY THE APPEARANCE OF CELLS PRODUCING IFN-GAMMA AND GM-CSF. ON THE OTHER HAND, IFN-GAMMA PRODUCING TH1 CELLS APPEAR FIRST IN THE SPINAL CORD FOLLOWED BY CELLS PRODUCING IL-17A AND GM-CSF. TREATMENT WITH TRICHOSTATIN A SUBSTANTIALLY REDUCED THE FREQUENCIES OF ALL T CELLS SECRETING VARIOUS LYMPHOKINES BOTH IN THE PERIPHERY AND IN THE SPINAL CORD. THESE DATA INDICATE THAT EPIGENETIC MODIFICATIONS INDUCED BY HISTONE HYPERACETYLATION FACILITATES T CELL TOLERANCE INDUCTION IN THE PERIPHERY LEADING TO REDUCED MIGRATION OF T CELLS TO THE SPINAL CORD AND MITIGATION OF NEURONAL DAMAGE AND IMPROVED CLINICAL OUTCOME. THESE RESULTS SUGGEST THAT EPIGENETIC MODULATION OF THE GENOME MAY SIMILARLY OFFER BENEFITS TO MULTIPLE SCLEROSIS PATIENTS VIA ABROGATING THE FUNCTION OF ENCEPHALITOGENIC T LYMPHOCYTES WITHOUT EXERTING SEVERE SIDE EFFECTS ASSOCIATED WITH CURRENTLY USED DISEASE-MODIFYING THERAPIES. 2017 5 5426 41 REGULATION OF SIRTUIN EXPRESSION IN AUTOIMMUNE NEUROINFLAMMATION: INDUCTION OF SIRT1 IN OLIGODENDROCYTE PROGENITOR CELLS. IN MULTIPLE SCLEROSIS (MS) REGENERATION OF OLIGODENDROCYTES FOLLOWING INFLAMMATORY DEMYELINATION IS LIMITED BY THE COMPROMISED ABILITY OF PROGENITORS TO REPOPULATE LESIONED AREAS AND TRANSITION TO FUNCTIONALLY COMPETENT OLIGODENDROCYTES. REGARDING UNDERLYING MECHANISMS, THE INVOLVEMENT OF EPIGENETIC PROCESSES HAS BEEN SUGGESTED, E.G. THE CONTRIBUTION OF HISTONE DEACETYLASES (HDAC) KNOWN TO REGULATE OLIGODENDROCYTE PROGENITOR CELL (OPC) DIFFERENTIATION. HOWEVER, THEIR PRECISE EXPRESSION PATTERNS, PARTICULAR OF REDOX-SENSITIVE NAD(+) HDACS, REMAINS LARGELY UNKNOWN. IN THIS STUDY, WE DETERMINED THE EXPRESSION AND ACTIVITY OF SIRTUINS, MEMBERS OF THE HDAC CLASS III FAMILY WITH A SPECIFIC FOCUS ON SIRT1, PREVIOUSLY ASSOCIATED WITH NEURODEGENERATIVE, INFLAMMATORY AND DEMYELINATING DISORDERS OF THE CENTRAL NERVOUS SYSTEM (CNS). BY INVESTIGATING MOUSE EXPERIMENTAL AUTOIMMUNE ENCEPHALOMYELITIS (EAE), A MODEL FOR MS, WE FOUND THAT TRANSCRIPTION OF SIRT1, SIRT2 AND SIRT6 WAS SIGNIFICANTLY INCREASED IN THE CNS DURING CHRONIC DISEASE STAGES. WE CONFIRMED THIS FINDING FOR SIRT1 PROTEIN EXPRESSION AND WERE ABLE TO LOCALIZE UPREGULATED SIRT1 IN NUCLEI OF NG2(+) OR PDGFRALPHA(+) OPCS IN DEMYELINATED BRAIN LESIONS. IN CULTURED MOUSE A2B5(+) OPCS BLOCKADE OF SIRT1 ACTIVITY BY THE SMALL MOLECULE COMPOUND EX527 ENHANCED MITOTIC ACTIVITY BUT DID NOT AFFECT THE CAPACITY TO DIFFERENTIATE. A SIMILAR PATTERN WAS DETECTABLE IN OPCS DERIVED FROM SIRT1-DEFICIENT ANIMALS. TAKEN TOGETHER, OUR DATA SUGGEST THAT SIRT1 INHIBITION MAY HELP TO EXPAND THE ENDOGENOUS POOL OF OPCS WITHOUT AFFECTING THEIR DIFFERENTIATION. 2019 6 2882 47 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 7 6531 41 TRANSCRIPTIONAL REGULATION OF BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) BY METHYL CPG BINDING PROTEIN 2 (MECP2): A NOVEL MECHANISM FOR RE-MYELINATION AND/OR MYELIN REPAIR INVOLVED IN THE TREATMENT OF MULTIPLE SCLEROSIS (MS). MULTIPLE SCLEROSIS (MS) IS A CHRONIC PROGRESSIVE, NEUROLOGICAL DISEASE CHARACTERIZED BY THE TARGETED IMMUNE SYSTEM-MEDIATED DESTRUCTION OF CENTRAL NERVOUS SYSTEM (CNS) MYELIN. AUTOREACTIVE CD4+ T HELPER CELLS HAVE A KEY ROLE IN ORCHESTRATING MS-INDUCED MYELIN DAMAGE. ONCE ACTIVATED, CIRCULATING TH1-CELLS SECRETE A VARIETY OF INFLAMMATORY CYTOKINES THAT FOSTER THE BREAKDOWN OF BLOOD-BRAIN BARRIER (BBB) EVENTUALLY INFILTRATING INTO THE CNS. INSIDE THE CNS, THEY BECOME REACTIVATED UPON EXPOSURE TO THE MYELIN STRUCTURAL PROTEINS AND CONTINUE TO PRODUCE INFLAMMATORY CYTOKINES SUCH AS TUMOR NECROSIS FACTOR ALPHA (TNFALPHA) THAT LEADS TO DIRECT ACTIVATION OF ANTIBODIES AND MACROPHAGES THAT ARE INVOLVED IN THE PHAGOCYTOSIS OF MYELIN. PROLIFERATING OLIGODENDROCYTE PRECURSORS (OPS) MIGRATING TO THE LESION SITES ARE CAPABLE OF ACUTE REMYELINATION BUT UNABLE TO COMPLETELY REPAIR OR RESTORE THE IMMUNE SYSTEM-MEDIATED MYELIN DAMAGE. THIS RESULTS IN VARIOUS PERMANENT CLINICAL NEUROLOGICAL DISABILITIES SUCH AS COGNITIVE DYSFUNCTION, FATIGUE, BOWEL/BLADDER ABNORMALITIES, AND NEUROPATHIC PAIN. AT PRESENT, THERE IS NO CURE FOR MS. RECENT REMYELINATION AND/OR MYELIN REPAIR STRATEGIES HAVE FOCUSED ON THE ROLE OF THE NEUROTROPHIN BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) AND ITS UPSTREAM TRANSCRIPTIONAL REPRESSOR METHYL CPG BINDING PROTEIN (MECP2). RESEARCH IN THE FIELD OF EPIGENETIC THERAPEUTICS INVOLVING HISTONE DEACETYLASE (HDAC) INHIBITORS AND LYSINE ACETYL TRANSFERASE (KAT) INHIBITORS IS BEING EXPLORED TO REPRESS THE DETRIMENTAL EFFECTS OF MECP2. THIS REVIEW WILL ADDRESS THE ROLE OF MECP2 AND BDNF IN REMYELINATION AND/OR MYELIN REPAIR AND THE POTENTIAL OF HDAC AND KAT INHIBITORS AS NOVEL THERAPEUTIC INTERVENTIONS FOR MS. 2016 8 4721 40 NONCODING RNAS IN MULTIPLE SCLEROSIS. MULTIPLE SCLEROSIS (MS), A CHRONIC INFLAMMATORY DEMYELINATING DISEASE OF THE CENTRAL NERVOUS SYSTEM, IS CHARACTERIZED BY AXONAL DEGENERATION AND GLIOSIS. ALTHOUGH THE CAUSES OF MS REMAIN UNKNOWN, GENE DYSREGULATION IN THE CENTRAL NERVOUS SYSTEM HAS BEEN ASSOCIATED WITH THE DISEASE PATHOGENESIS. AS SUCH, THE VARIOUS REGULATORS OF GENE EXPRESSION MAY BE CONTRIBUTING FACTORS. THE NONCODING (NC) RNAS HAVE PIQUED THE INTEREST OF MS RESEARCHERS DUE TO THEIR KNOWN FUNCTIONS IN HUMAN PHYSIOLOGY AND VARIOUS PATHOLOGICAL PROCESSES, DESPITE BEING GENERALLY CHARACTERIZED AS TRANSCRIPTS WITHOUT APPARENT PROTEIN-CODING CAPACITY. ACCUMULATING EVIDENCE HAS INDICATED THAT NCRNAS PARTICIPATE IN THE REGULATION OF MS BY ACTING AS EPIGENETIC FACTORS, ESPECIALLY THE LONG (L) NCRNAS AND THE MICRO (MI) RNAS, AND THEY ARE NOW RECOGNIZED AS KEY REGULATORY MOLECULES IN MS. IN THIS REVIEW, WE SUMMARIZE THE MOST CURRENT STUDIES ON THE CONTRIBUTION OF NCRNAS IN MS PATHOGENIC PROCESSES AND DISCUSS THEIR POTENTIAL APPLICATIONS IN THE DIAGNOSIS AND TREATMENT OF MS. 2018 9 4304 44 MICRORNA-223 PROTECTS NEURONS FROM DEGENERATION IN EXPERIMENTAL AUTOIMMUNE ENCEPHALOMYELITIS. MULTIPLE SCLEROSIS IS A CHRONIC INFLAMMATORY, DEMYELINATING, AND NEURODEGENERATIVE DISEASE AFFECTING THE BRAIN, SPINAL CORD AND OPTIC NERVES. NEURONAL DAMAGE IS TRIGGERED BY VARIOUS HARMFUL FACTORS THAT ENGAGE DIVERSE SIGNALLING CASCADES IN NEURONS; THUS, THERAPEUTIC APPROACHES TO PROTECT NEURONS WILL NEED TO FOCUS ON AGENTS THAT CAN TARGET MULTIPLE BIOLOGICAL PROCESSES. WE HAVE THEREFORE FOCUSED OUR ATTENTION ON MICRORNAS: SMALL NON-CODING RNAS THAT PRIMARILY FUNCTION AS POST-TRANSCRIPTIONAL REGULATORS THAT TARGET MESSENGER RNAS AND REPRESS THEIR TRANSLATION INTO PROTEINS. A SINGLE MICRORNA CAN TARGET MANY FUNCTIONALLY RELATED MESSENGER RNAS MAKING MICRORNAS POWERFUL EPIGENETIC REGULATORS. DYSREGULATION OF MICRORNAS HAS BEEN DESCRIBED IN MANY NEURODEGENERATIVE DISEASES INCLUDING MULTIPLE SCLEROSIS. HERE, WE REPORT THAT TWO MICRORNAS, MIR-223-3P AND MIR-27A-3P, ARE UPREGULATED IN NEURONS IN THE EXPERIMENTAL AUTOIMMUNE ENCEPHALOMYELITIS MOUSE MODEL OF CNS INFLAMMATION AND IN GREY MATTER-CONTAINING MULTIPLE SCLEROSIS LESIONS. PRIOR WORK HAS SHOWN PERIPHERAL BLOOD MONONUCLEAR CELL CONDITIONED MEDIA CAUSES SUBLETHAL DEGENERATION OF NEURONS IN CULTURE. WE FIND OVEREXPRESSION OF MIR-27A-3P OR MIR-223-3P PROTECTS DISSOCIATED CORTICAL NEURONS FROM CONDITION MEDIA MEDIATED DEGENERATION. INTRODUCTION OF MIR-223-3P IN VIVO IN MOUSE RETINAL GANGLION CELLS PROTECTS THEIR AXONS FROM DEGENERATION IN EXPERIMENTAL AUTOIMMUNE ENCEPHALOMYELITIS. IN SILICO ANALYSIS REVEALED THAT MESSENGER RNAS INVOLVED IN GLUTAMATE RECEPTOR SIGNALLING ARE ENRICHED AS MIR-27A-3P AND MIR-223-3P TARGETS. WE OBSERVE THAT ANTAGONISM OF NMDA AND AMPA TYPE GLUTAMATE RECEPTORS PROTECTS NEURONS FROM CONDITION MEDIA DEPENDENT DEGENERATION. OUR RESULTS SUGGEST THAT MIR-223-3P AND MIR-27A-3P ARE UPREGULATED IN RESPONSE TO INFLAMMATION TO MEDIATE A COMPENSATORY NEUROPROTECTIVE GENE EXPRESSION PROGRAM THAT DESENSITIZES NEURONS TO GLUTAMATE BY TARGETING MESSENGER RNAS INVOLVED IN GLUTAMATE RECEPTOR SIGNALLING. 2019 10 2856 35 FROM METHYLATION TO MYELINATION: EPIGENOMIC AND TRANSCRIPTOMIC PROFILING OF CHRONIC INACTIVE DEMYELINATED MULTIPLE SCLEROSIS LESIONS. IN THE PROGRESSIVE PHASE OF MULTIPLE SCLEROSIS (MS), THE HAMPERED DIFFERENTIATION CAPACITY OF OLIGODENDROCYTE PRECURSOR CELLS (OPCS) EVENTUALLY RESULTS IN REMYELINATION FAILURE. WE HAVE PREVIOUSLY SHOWN THAT DNA METHYLATION OF ID2/ID4 IS HIGHLY INVOLVED IN OPC DIFFERENTIATION AND REMYELINATION. IN THIS STUDY, WE TOOK AN UNBIASED APPROACH BY DETERMINING GENOME-WIDE DNA METHYLATION PATTERNS WITHIN CHRONICALLY DEMYELINATED MS LESIONS AND INVESTIGATED HOW CERTAIN EPIGENETIC SIGNATURES RELATE TO OPC DIFFERENTIATION CAPACITY. WE COMPARED GENOME-WIDE DNA METHYLATION AND TRANSCRIPTIONAL PROFILES BETWEEN CHRONICALLY DEMYELINATED MS LESIONS AND MATCHED NORMAL-APPEARING WHITE MATTER (NAWM), MAKING USE OF POST-MORTEM BRAIN TISSUE (N = 9/GROUP). DNA METHYLATION DIFFERENCES THAT INVERSELY CORRELATED WITH MRNA EXPRESSION OF THEIR CORRESPONDING GENES WERE VALIDATED FOR THEIR CELL-TYPE SPECIFICITY IN LASER-CAPTURED OPCS USING PYROSEQUENCING. THE CRISPR-DCAS9-DNMT3A/TET1 SYSTEM WAS USED TO EPIGENETICALLY EDIT HUMAN-IPSC-DERIVED OLIGODENDROCYTES TO ASSESS THE EFFECT ON CELLULAR DIFFERENTIATION. OUR DATA SHOW HYPERMETHYLATION OF CPGS WITHIN GENES THAT CLUSTER IN GENE ONTOLOGIES RELATED TO MYELINATION AND AXON ENSHEATHMENT. CELL TYPE-SPECIFIC VALIDATION INDICATES A REGION-DEPENDENT HYPERMETHYLATION OF MBP, ENCODING FOR MYELIN BASIC PROTEIN, IN OPCS OBTAINED FROM WHITE MATTER LESIONS COMPARED TO NAWM-DERIVED OPCS. BY ALTERING THE DNA METHYLATION STATE OF SPECIFIC CPGS WITHIN THE PROMOTOR REGION OF MBP, USING EPIGENETIC EDITING, WE SHOW THAT CELLULAR DIFFERENTIATION AND MYELINATION CAN BE BIDIRECTIONALLY MANIPULATED USING THE CRISPR-DCAS9-DNMT3A/TET1 SYSTEM IN VITRO. OUR DATA INDICATE THAT OPCS WITHIN CHRONICALLY DEMYELINATED MS LESIONS ACQUIRE AN INHIBITORY PHENOTYPE, WHICH TRANSLATES INTO HYPERMETHYLATION OF CRUCIAL MYELINATION-RELATED GENES. ALTERING THE EPIGENETIC STATUS OF MBP CAN RESTORE THE DIFFERENTIATION CAPACITY OF OPCS AND POSSIBLY BOOST (RE)MYELINATION. 2023 11 5600 32 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 12 3839 35 IPSC-DERIVED NEURAL PRECURSOR CELLS: POTENTIAL FOR CELL TRANSPLANTATION THERAPY IN SPINAL CORD INJURY. A NUMBER OF STUDIES HAVE DEMONSTRATED THAT TRANSPLANTATION OF NEURAL PRECURSOR CELLS (NPCS) PROMOTES FUNCTIONAL RECOVERY AFTER SPINAL CORD INJURY (SCI). HOWEVER, THE NPCS HAD BEEN MOSTLY HARVESTED FROM EMBRYONIC STEM CELLS OR FETAL TISSUE, RAISING THE ETHICAL CONCERN. YAMANAKA AND HIS COLLEAGUES ESTABLISHED INDUCED PLURIPOTENT STEM CELLS (IPSCS) WHICH COULD BE GENERATED FROM SOMATIC CELLS, AND THIS INNOVATIVE DEVELOPMENT HAS MADE RAPID PROGRESSION IN THE FIELD OF SCI REGENERATION. WE AND OTHER GROUPS SUCCEEDED IN PRODUCING NPCS FROM IPSCS, AND DEMONSTRATED BENEFICIAL EFFECTS AFTER TRANSPLANTATION FOR ANIMAL MODELS OF SCI. IN PARTICULAR, EFFICACY OF HUMAN IPSC-NPCS IN NON-HUMAN PRIMATE SCI MODELS FOSTERED MOMENTUM OF CLINICAL APPLICATION FOR SCI PATIENTS. AT THE SAME TIME, HOWEVER, ARTIFICIAL INDUCTION METHODS IN IPSC TECHNOLOGY CREATED ALTERNATIVE ISSUES INCLUDING GENETIC AND EPIGENETIC ABNORMALITIES, AND TUMORIGENICITY AFTER TRANSPLANTATION. TO OVERCOME THESE PROBLEMS, IT IS CRITICALLY IMPORTANT TO SELECT ORIGINS OF SOMATIC CELLS, USE INTEGRATION-FREE SYSTEM DURING TRANSFECTION OF REPROGRAMMING FACTORS, AND THOROUGHLY INVESTIGATE THE CHARACTERISTICS OF IPSC-NPCS WITH RESPECT TO QUALITY MANAGEMENT. MOREOVER, SINCE MOST OF THE PREVIOUS STUDIES HAVE FOCUSED ON SUBACUTE PHASE OF SCI, ESTABLISHMENT OF EFFECTIVE NPC TRANSPLANTATION SHOULD BE EVALUATED FOR CHRONIC PHASE HEREAFTER. OUR GROUP IS CURRENTLY PREPARING CLINICAL-GRADE HUMAN IPSC-NPCS, AND WILL MOVE FORWARD TOWARD CLINICAL STUDY FOR SUBACUTE SCI PATIENTS SOON IN THE NEAR FUTURE. 2018 13 80 44 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 14 4350 38 MIR-181A-5P IS A POTENTIAL CANDIDATE EPIGENETIC BIOMARKER IN MULTIPLE SCLEROSIS. MULTIPLE SCLEROSIS (MS) IS A CHRONIC INFLAMMATORY DISEASE OF THE CENTRAL NERVOUS SYSTEM (CNS) CHARACTERIZED BY DEMYELINATION AND AXONAL DEGENERATION. ABNORMAL EXPRESSION OF MICRORNAS (MIRNAS) PLAYS AN IMPORTANT ROLE IN MS PATHOLOGY. IN THIS COHORT STUDY, DIFFERENTIAL EXPRESSION OF THE FOUR MIRNAS (HSA-MIR-155-5P, HSA-MIR-9-5P, HSA-MIR-181A-5P, AND HSA-MIR-125B-5P) WAS INVESTIGATED IN 69 INDIVIDUALS, INCLUDING 39 MS PATIENTS (RELAPSING-REMITTING MS (RRMS), N = 27; SECONDARY PROGRESSIVE MS (SPMS), N = 12) AND 30 HEALTHY CONTROLS. IN SILICO ANALYSES REVEALED POSSIBLE GENES AND PATHWAYS SPECIFIC TO MIRNAS. PERIPHERAL BLOOD MIRNA EXPRESSIONS WERE DETECTED BY QUANTITATIVE REAL-TIME PCR (QPCR). HSA-MIR-181A-5P WAS DOWNREGULATED AND ASSOCIATED WITH INCREASED MS RISK (P = 0.012). THE OTHER THREE MIRNAS WERE UPREGULATED AND NOT ASSOCIATED WITH MS (P < 0.05). THE AREA UNDER THE CURVE (AUC) IS 0.779. IN SILICO ANALYSES SHOWED THAT HSA-MIR-181A-5P MAY PARTICIPATE IN MS PATHOLOGY BY TARGETING MAP2K1, CREB1, ATXN1, AND ATXN3 GENES IN INFLAMMATION AND NEURODEGENERATION PATHWAYS. THE CIRCULATORY HSA-MIR-181A-5P CAN REGULATE TARGET GENES, REVERSING THE MECHANISMS INVOLVED IN MS PATHOLOGIES SUCH AS PROTEIN UPTAKE AND PROCESSING, CELL PROLIFERATION AND SURVIVAL, INFLAMMATION, AND NEURODEGENERATION. THUS, THIS MIRNA COULD BE USED AS AN EPIGENOMIC-GUIDED DIAGNOSTIC TOOL AND FOR THERAPEUTIC PURPOSE. 2022 15 3135 33 GLOBAL DNA METHYLATION AND HYDROXYMETHYLATION LEVELS IN PBMCS ARE ALTERED IN RRMS PATIENTS TREATED WITH IFN-BETA AND GA-A PRELIMINARY STUDY. MULTIPLE SCLEROSIS (MS) IS A CHRONIC DISEASE AFFECTING THE CENTRAL NERVOUS SYSTEM (CNS) DUE TO AN AUTOIMMUNE ATTACK ON AXONAL MYELIN SHEATHS. EPIGENETICS IS AN OPEN RESEARCH TOPIC ON MS, WHICH HAS BEEN INVESTIGATED IN SEARCH OF BIOMARKERS AND TREATMENT TARGETS FOR THIS HETEROGENEOUS DISEASE. IN THIS STUDY, WE QUANTIFIED GLOBAL LEVELS OF EPIGENETIC MARKS USING AN ELISA-LIKE APPROACH IN PERIPHERAL BLOOD MONONUCLEAR CELLS (PBMCS) FROM 52 PATIENTS WITH MS, TREATED WITH INTERFERON BETA (IFN-BETA) AND GLATIRAMER ACETATE (GA) OR UNTREATED, AND 30 HEALTHY CONTROLS. WE PERFORMED MEDIA COMPARISONS AND CORRELATION ANALYSES OF THESE EPIGENETIC MARKERS WITH CLINICAL VARIABLES IN SUBGROUPS OF PATIENTS AND CONTROLS. WE OBSERVED THAT DNA METHYLATION (5-MC) DECREASED IN TREATED PATIENTS COMPARED WITH UNTREATED AND HEALTHY CONTROLS. MOREOVER, 5-MC AND HYDROXYMETHYLATION (5-HMC) CORRELATED WITH CLINICAL VARIABLES. IN CONTRAST, HISTONE H3 AND H4 ACETYLATION DID NOT CORRELATE WITH THE DISEASE VARIABLES CONSIDERED. GLOBALLY QUANTIFIED EPIGENETIC DNA MARKS 5-MC AND 5-HMC CORRELATE WITH DISEASE AND WERE ALTERED WITH TREATMENT. HOWEVER, TO DATE, NO BIOMARKER HAS BEEN IDENTIFIED THAT CAN PREDICT THE POTENTIAL RESPONSE TO THERAPY BEFORE TREATMENT INITIATION. 2023 16 2755 29 EXPRESSION OF CLASS II HISTONE DEACETYLASES IN TWO MOUSE MODELS OF TEMPORAL LOBE EPILEPSY. EPIGENETIC MECHANISMS LIKE ALTERED HISTONE ACETYLATION MAY HAVE A CRUCIAL ROLE IN EPILEPTOGENESIS. IN TWO MOUSE MODELS OF TEMPORAL LOBE EPILEPSY, WE INVESTIGATED CHANGES IN THE EXPRESSION OF CLASS II HISTONE DEACETYLASES (HDAC), A GROUP OF SIGNAL TRANSDUCERS THAT SHUTTLE BETWEEN NUCLEUS AND CYTOPLASM. INTRAHIPPOCAMPAL INJECTION OF KAINIC ACID (KA) INDUCED A STATUS EPILEPTICUS, DEVELOPMENT OF SPONTANEOUS SEIZURES (AFTER 3 DAYS), AND FINALLY CHRONIC EPILEPSY AND GRANULE CELL DISPERSION. EXPRESSION OF CLASS II HDAC MRNAS WAS INVESTIGATED AT DIFFERENT TIME INTERVALS AFTER KA INJECTION IN THE GRANULE CELL LAYERS AND IN SECTORS CA1 AND CA3 CONTRALATERAL TO THE SITE OF KA INJECTION LACKING NEURODEGENERATION. INCREASED EXPRESSION OF HDAC5 AND 9 MRNAS COINCIDED WITH PRONOUNCED GRANULE CELL DISPERSION IN THE KA-INJECTED HIPPOCAMPUS AT LATE INTERVALS (14-28 DAYS AFTER KA) AND EQUALLY AFFECTED BOTH HDAC9 SPLICE VARIANTS. IN CONTRAST, IN THE PILOCARPINE MODEL (SHOWING NO GRANULE CELL DISPERSION), WE OBSERVED DECREASES IN THE EXPRESSION OF HDAC5 AND 9 AT THE SAME TIME INTERVALS. BEYOND THIS, STRIKING SIMILARITIES BETWEEN BOTH TEMPORAL LOBE EPILEPSY MODELS SUCH AS FAST DECREASES IN HDAC7 AND 10 MRNAS DURING THE ACUTE STATUS EPILEPTICUS WERE OBSERVED, NOTABLY ALSO IN THE CONTRALATERAL HIPPOCAMPUS NOT AFFECTED BY NEURODEGENERATION. THE PARTICULAR PATTERNS OF HDAC MRNA EXPRESSION SUGGEST A ROLE IN EPILEPTOGENESIS AND GRANULE CELL DISPERSION. REDUCED EXPRESSION OF HDACS MAY RESULT IN INCREASED EXPRESSION OF PRO- AND ANTICONVULSIVE PROTEINS. ON THE OTHER HAND, EXPORT OF HDACS FROM THE NUCLEUS INTO THE CYTOPLASM COULD ALLOW FOR DEACETYLATION OF CYTOPLASMATIC PROTEINS INVOLVED IN AXONAL AND DENDRITIC REMODELING, LIKE GRANULE CELL DISPERSION. HDAC 5 AND HDAC 9 EXPRESSION IS HIGHLY INCREASED IN GRANULE CELLS OF THE KA-INJECTED HIPPOCAMPUS AND PARALLELS GRANULE CELL DISPERSION. BOTH HDACS ARE THOUGHT TO BE TARGETED TO THE CYTOPLASM AND TO ACT THERE BY DEACETYLATING CYTOPLASMATIC (E.G. CYTOSCELETON-RELATED) PROTEINS. 2016 17 1611 42 DNA METHYLATION: A NEW PLAYER IN MULTIPLE SCLEROSIS. MULTIPLE SCLEROSIS (MS) IS A NEUROLOGICAL AND CHRONIC INFLAMMATORY DISEASE THAT IS MEDIATED BY DEMYELINATION AND AXONAL DEGENERATION IN THE CENTRAL NERVOUS SYSTEM (CNS). STUDIES HAVE SHOWN THAT IMMUNE SYSTEM COMPONENTS SUCH AS CD4+, CD8+, CD44+ T CELLS, B LYMPHATIC CELLS, AND INFLAMMATORY CYTOKINES PLAY A CRITICAL ROLE IN INFLAMMATORY PROCESSES AND MYELIN DAMAGE ASSOCIATED WITH MS. NEVERTHELESS, THE PATHOGENESIS OF MS REMAINS POORLY DEFINED. DNA METHYLATION, A SIGNIFICANT EPIGENETIC MODIFICATION, IS REPORTED TO BE EXTENSIVELY INVOLVED IN MS PATHOGENESIS THROUGH THE REGULATION OF GENE EXPRESSION. THIS REVIEW FOCUSES ON DNA METHYLATION INVOLVED IN MS PATHOGENESIS. EVIDENCE SHOWED THE HYPERMETHYLATION OF HUMAN LEUKOCYTE ANTIGEN-DRB1 (HLA-DRB1) IN CD4+ T CELLS, THE GENOME-WIDE DNA METHYLATION IN CD8+ T CELLS, THE HYPERMETHYLATION OF INTERLEUKIN-4 (IL-4)/FORKHEAD WINGED HELIX TRANSCRIPTION FACTOR 3 (FOXP3), AND THE DEMETHYLATION OF INTERFERON-GAMMA (IFN-GAMMA)/IL-17A IN CD44+ ENCEPHALITOGENIC T CELLS. STUDIES ALSO SHOWED THE HYPERMETHYLATION OF SH2-CONTAINING PROTEIN TYROSINE PHOSPHATASE-1 (SHP-1) IN PERIPHERAL BLOOD MONONUCLEAR CELLS (PBMCS) AND METHYLATED CHANGES OF GENES REGULATING OLIGODENDROCYTE AND NEURONAL FUNCTION IN NORMAL-APPEARING WHITE MATTER. CLARIFYING THE MECHANISM OF ABERRANT METHYLATION ON MS MAY EXPLAIN PART OF THE PATHOLOGY AND WILL LEAD TO THE DEVELOPMENT OF A NEW THERAPEUTIC TARGET FOR THE TREATMENT OF MS IN THE FUTURE. 2017 18 454 36 APPLICATIONS OF INDUCED PLURIPOTENT STEM CELL TECHNOLOGIES IN SPINAL CORD INJURY. NUMEROUS BASIC RESEARCH STUDIES HAVE SUGGESTED THE POTENTIAL EFFICACY OF NEURAL PRECURSOR CELL (NPC) TRANSPLANTATION IN SPINAL CORD INJURY (SCI). HOWEVER, IN MOST SUCH STUDIES, THE ORIGIN OF THE CELLS USED WAS MAINLY FETAL TISSUE OR EMBRYONIC STEM CELLS, BOTH OF WHICH CARRY POTENTIAL ETHICAL CONCERNS WITH RESPECT TO CLINICAL USE. THE DEVELOPMENT OF INDUCED PLURIPOTENT STEM CELLS (IPSCS) OPENED A NEW PATH TOWARD REGENERATIVE MEDICINE FOR SCI. IPSCS CAN BE GENERATED FROM SOMATIC CELLS BY INDUCTION OF TRANSCRIPTION FACTORS, AND INDUCED TO DIFFERENTIATE INTO NPCS WITH CHARACTERISTICS OF CELLS OF THE CENTRAL NERVOUS SYSTEM. THE BENEFICIAL EFFECT OF IPSC-DERIVED NPC TRANSPLANTATION HAS BEEN REPORTED FROM OUR GROUP AND OTHERS WORKING IN RODENT AND NON-HUMAN PRIMATE MODELS. THESE PROMISING RESULTS FACILITATE THE APPLICATION OF IPSCS FOR CLINICAL APPLICATIONS IN SCI PATIENTS. HOWEVER, IPSCS ALSO HAVE ISSUES, SUCH AS GENETIC/EPIGENETIC ABNORMALITIES AND TUMORIGENESIS BECAUSE OF THE ARTIFICIAL INDUCTION METHOD, THAT MUST BE ADDRESSED PRIOR TO CLINICAL USE. THE SELECTION OF SOMATIC CELLS, GENERATION OF INTEGRATION-FREE IPSCS, AND CHARACTERIZATION OF DIFFERENTIATED NPCS WITH THOROUGH QUALITY MANAGEMENT ARE ALL NEEDED TO ADDRESS THESE POTENTIAL RISKS. TO ENHANCE THE EFFICACY OF THE TRANSPLANTED IPSC-NPCS, ESPECIALLY AT CHRONIC PHASE OF SCI, ADMINISTRATION OF A CHONDROITINASE OR SEMAPHORIN3A INHIBITOR REPRESENTS A POTENTIALLY IMPORTANT MEANS OF PROMOTING AXONAL REGENERATION THROUGH THE LESION SITE. THE COMBINED USE OF REHABILITATION WITH SUCH CELL THERAPY APPROACHES IS ALSO IMPORTANT, AS REPETITIVE TRAINING ENHANCES NEURITE OUTGROWTH OF TRANSPLANTED CELLS AND STRENGTHENS NEURAL CIRCUITS AT CENTRAL PATTERN GENERATORS. OUR GROUP HAS ALREADY EVALUATED CLINICAL GRADE IPSC-DERIVED NPCS, AND WE LOOK FORWARD TO INITIATING CLINICAL TESTING AS THE NEXT STEP TOWARD DETERMINING WHETHER THIS APPROACH IS SAFE AND EFFECTIVE FOR CLINICAL USE. THIS ARTICLE IS PART OF THE MINI REVIEW SERIES "60TH ANNIVERSARY OF THE JAPANESE SOCIETY FOR NEUROCHEMISTRY". 2017 19 710 32 C-TERMINAL DOMAIN SMALL PHOSPHATASE 1 (CTDSP1) REGULATES GROWTH FACTOR EXPRESSION AND AXONAL REGENERATION IN PERIPHERAL NERVE TISSUE. PERIPHERAL NERVE INJURY (PNI) REPRESENTS A MAJOR CLINICAL AND ECONOMIC BURDEN. DESPITE THE ABILITY OF PERIPHERAL NEURONS TO REGENERATE THEIR AXONS AFTER AN INJURY, PATIENTS ARE OFTEN LEFT WITH MOTOR AND/OR SENSORY DISABILITY AND MAY DEVELOP CHRONIC PAIN. SUCCESSFUL REGENERATION AND TARGET ORGAN REINNERVATION REQUIRE COMPREHENSIVE TRANSCRIPTIONAL CHANGES IN BOTH INJURED NEURONS AND SUPPORT CELLS LOCATED AT THE SITE OF INJURY. THE EXPRESSION OF MOST OF THE GENES REQUIRED FOR AXON GROWTH AND GUIDANCE AND FOR SYNAPSIS FORMATION IS REPRESSED BY A SINGLE MASTER TRANSCRIPTIONAL REGULATOR, THE REPRESSOR ELEMENT 1 SILENCING TRANSCRIPTION FACTOR (REST). SUSTAINED INCREASE OF REST LEVELS AFTER INJURY INHIBITS AXON REGENERATION AND LEADS TO CHRONIC PAIN. AS TARGETING OF TRANSCRIPTION FACTORS IS CHALLENGING, WE TESTED WHETHER MODULATION OF REST ACTIVITY COULD BE ACHIEVED THROUGH KNOCKDOWN OF CARBOXY-TERMINAL DOMAIN SMALL PHOSPHATASE 1 (CTDSP1), THE ENZYME THAT STABILIZES REST BY PREVENTING ITS TARGETING TO THE PROTEASOME. TO TEST WHETHER KNOCKDOWN OF CTDSP1 PROMOTES NEUROTROPHIC FACTOR EXPRESSION IN BOTH SUPPORT CELLS LOCATED AT THE SITE OF INJURY AND IN PERIPHERAL NEURONS, WE TRANSFECTED MESENCHYMAL PROGENITOR CELLS (MPCS), A TYPE OF SUPPORT CELLS THAT ARE PRESENT AT HIGH CONCENTRATIONS AT THE SITE OF INJURY, AND DORSAL ROOT GANGLION (DRG) NEURONS WITH REST OR CTDSP1 SPECIFIC SIRNA. WE QUANTIFIED NEUROTROPHIC FACTOR EXPRESSION BY RT-QPCR AND WESTERN BLOT, AND BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) RELEASE IN THE CELL CULTURE MEDIUM BY ELISA, AND WE MEASURED NEURITE OUTGROWTH OF DRG NEURONS IN CULTURE. OUR RESULTS SHOW THAT CTDSP1 KNOCKDOWN PROMOTES NEUROTROPHIC FACTOR EXPRESSION IN BOTH DRG NEURONS AND THE SUPPORT CELLS MPCS, AND PROMOTES DRG NEURON REGENERATION. THERAPEUTICS TARGETING CTDSP1 ACTIVITY MAY, THEREFORE, REPRESENT A NOVEL EPIGENETIC STRATEGY TO PROMOTE PERIPHERAL NERVE REGENERATION AFTER PNI BY PROMOTING THE REGENERATIVE PROGRAM REPRESSED BY INJURY-INDUCED INCREASED LEVELS OF REST IN BOTH NEURONS AND SUPPORT CELLS. 2021 20 2546 44 EPIGENETICS IN MULTIPLE SCLEROSIS: MOLECULAR MECHANISMS AND DIETARY INTERVENTION. INTRODUCTION: MULTIPLE SCLEROSIS (MS) IS A CHRONIC, INFLAMMATORY, NEURODEGENERATIVE DEMYELINATING DISEASE OF THE CENTRAL NERVOUS SYSTEM (CNS). UNFORTUNATELY, MS CAUSES IMPORTANT DISABILITY IN YOUNG ADULTS AND ITS PREVALENCE IS INCREASING. WHILE THE ETIOLOGY OF MS ETIOLOGY IS NOT COMPLETELY UNDERSTOOD, IT SEEMS TO BE A MULTIFACTORIAL ENTITY THAT IS INFLUENCED BY BOTH GENETIC AND EPIGENETIC MODIFICATIONS. EPIGENETIC MECHANISMS ADD OR REMOVE DIFFERENT CHEMICAL GROUPS FOR THE ACTIVATION OR INHIBITION OF GENE EXPRESSION TO BLOCK THE PRODUCTION OF PROINFLAMMATORY PROTEINS. IT IS TRULY IMPORTANT TO IDENTIFY THE FACTORS THAT CAN TRIGGER EPIGENETIC CHANGES IN MS TO COMPLEMENT THE THERAPEUTIC APPROACH, PREVENT DISABILITY AND IMPROVE PATIENTS QUALITY OF LIFE. HERE, WE HAVE CONDUCTED A REVIEW OF EXTERNAL FACTORS THAT INFLUENCE IN MS AND THEIR EPIGENETIC MECHANISMS. FOR EXAMPLE, HYPOMETHYLATION CAN PROMOTE CHANGES IN THE MYELIN AND SUBSEQUENT AUTOIMMUNE REACTIONS. THERAPEUTIC TOOLS CAN BE USED, INCLUDING THE HISTONE DEACETYLASE INHIBITOR TRICHOSTATIN A, WHICH AMELIORATES DEMYELINATING DISEASES IN RODENTS. HOWEVER, DRUGS ARE NOT ONLY THE THERAPEUTIC OPTION: RECENT STUDIES HAVE ALSO EVALUATED THE THERAPEUTIC POTENTIAL OF SEVERAL BIOACTIVE DIETARY COMPONENTS IN NEURODEGENERATION AND AXONAL DYSFUNCTION. NUMEROUS FOOD-DERIVED MOLECULES EXERT IMPORTANT METABOLIC ACTIONS. THESE MOLECULES INCLUDE PLANT POLYPHENOLS SUCH AS CATECHINS AND ISOFLAVONES, OMEGA-3 AND OMEGA-6 POLYUNSATURATED FATTY ACIDS, SHORT-CHAIN FATTY ACIDS, SULFUR-CONTAINING COMPOUNDS SUCH AS DALLY SULFIDE AND OTHER COMPOUNDS. ANTIOXIDANT AND ANTI-INFLAMMATORY COMPONENTS IN THE DIET INVOLVE TRANSCRIPTION FACTORS AS WELL. HOWEVER, MANY EXTERNAL FACTORS HAVE SHOWN TO INFLUENCE MS, ALTHOUGH NO SPECIFIC EPIGENETIC MECHANISMS ARE KNOWN. CONCLUSION: IN THIS REVIEW, WE GATHER BOTH ESTABLISHED AND NEW EVIDENCES ABOUT THE GENETIC, EPIGENETIC AND ENVIRONMENTAL FACTORS INFLUENCING MS AND THE DIETARY COMPONENTS THAT COULD MODULATE MS RELAPSE AND PROGRESSION. 2018