1 2882 110 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 2 5408 47 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 3 4982 30 PATHOPHYSIOLOGY OF THE BLOOD-BRAIN BARRIER: ANIMAL MODELS AND METHODS. THE SPECIALIZED CEREBRAL MICROVASCULAR ENDOTHELIUM INTERACTS WITH THE CELLULAR MILIEU OF THE BRAIN AND EXTRACELLULAR MATRIX TO FORM A NEUROVASCULAR UNIT, ONE ASPECT OF WHICH IS A REGULATED INTERFACE BETWEEN THE BLOOD AND CENTRAL NERVOUS SYSTEM (CNS). THE CONCEPT OF THIS BLOOD-BRAIN BARRIER (BBB) AS A DYNAMICALLY REGULATED SYSTEM RATHER THAN A STATIC BARRIER HAS WIDE-RANGING IMPLICATIONS FOR PATHOPHYSIOLOGY OF THE CNS. WHILE IN VITRO MODELS OF THE BBB ARE USEFUL FOR SCREENING DRUGS TARGETED TO THE CNS AND INDISPENSABLE FOR STUDIES OF CEREBRAL ENDOTHELIAL CELL BIOLOGY, THE COMPLEX INTERACTIONS OF THE NEUROVASCULAR UNIT MAKE ANIMAL-BASED MODELS AND METHODS ESSENTIAL TOOLS FOR UNDERSTANDING THE PATHOPHYSIOLOGY OF THE BBB. BBB DYSFUNCTION IS A COMPLICATION OF NEURODEGENERATIVE DISEASE AND BRAIN INJURY. STUDIES ON ANIMAL MODELS HAVE SHOWN THAT DISEASES OF THE PERIPHERY, SUCH AS DIABETES AND INFLAMMATORY PAIN, HAVE DELETERIOUS EFFECTS ON THE BBB WHICH MAY CONTRIBUTE TO NEUROLOGICAL COMPLICATIONS ASSOCIATED WITH THESE CONDITIONS. FURTHERMORE, GENETIC AND/OR EPIGENETIC ABNORMALITIES IN CONSTITUENTS OF THE BBB MAY BE SIGNIFICANT CONTRIBUTING FACTORS IN DISEASE ETIOLOGY. RESEARCH THAT APPROACHES THE BBB AS A DYNAMIC SYSTEM INTEGRATED WITH BOTH THE CNS AND THE PERIPHERY IS THEREFORE CRITICAL TO UNDERSTANDING AND TREATING DISEASES OF THE CNS. HEREIN, WE REVIEW VARIOUS METHODOLOGICAL APPROACHES USED TO STUDY BBB FUNCTION IN THE CONTEXT OF DISEASE. THESE INCLUDE MEASUREMENT OF TRANSPORT BETWEEN BLOOD AND BRAIN, IMAGING-BASED TECHNOLOGIES, AND GENOMIC/PROTEOMIC APPROACHES. 2008 4 3736 32 INNATE IMMUNE TOLERANCE IN MICROGLIA DOES NOT IMPACT ON CENTRAL NERVOUS SYSTEM PRION DISEASE. PRION DISEASES SUCH AS CREUTZFELDT-JAKOB DISEASE IN HUMANS, BOVINE SPONGIFORM ENCEPHALOPATHY IN CATTLE, AND SCRAPIE IN SHEEP, ARE INFECTIOUS AND CHRONIC NEURODEGENERATIVE DISEASES TO WHICH THERE ARE NO CURES. INFECTION WITH PRIONS IN THE CENTRAL NERVOUS SYSTEM (CNS) ULTIMATELY CAUSES EXTENSIVE NEURODEGENERATION, AND THIS IS ACCOMPANIED BY PROMINENT MICROGLIAL AND ASTROCYTIC ACTIVATION IN AFFECTED REGIONS. THE MICROGLIA ARE THE CNS MACROPHAGES AND HELP MAINTAIN NEURONAL HOMEOSTASIS, CLEAR DEAD OR DYING CELLS AND PROVIDE DEFENSE AGAINST PATHOGENS. THE MICROGLIA ALSO PROVIDE NEUROPROTECTION DURING CNS PRION DISEASE, BUT THEIR PRO-INFLAMMATORY ACTIVATION MAY EXACERBATE THE DEVELOPMENT OF THE NEUROPATHOLOGY. INNATE IMMUNE TOLERANCE INDUCED BY CONSECUTIVE SYSTEMIC BACTERIAL LIPOPOLYSACCHARIDE (LPS) TREATMENT CAN INDUCE LONG-TERM EPIGENETIC CHANGES IN THE MICROGLIA IN THE BRAIN THAT SEVERAL MONTHS LATER CAN DAMPEN THEIR RESPONSIVENESS TO SUBSEQUENT LPS TREATMENT AND IMPEDE THE DEVELOPMENT OF NEURITIC DAMAGE IN A TRANSGENIC MOUSE MODEL OF ALZHEIMER'S DISEASE-LIKE PATHOLOGY. WE THEREFORE REASONED THAT INNATE IMMUNE TOLERANCE IN MICROGLIA MIGHT SIMILARLY IMPEDE THE SUBSEQUENT DEVELOPMENT OF CNS PRION DISEASE. TO TEST THIS HYPOTHESIS GROUPS OF MICE WERE FIRST INFECTED WITH PRIONS BY INTRACEREBRAL INJECTION, AND 35 DAYS LATER GIVEN FOUR CONSECUTIVE SYSTEMIC INJECTIONS WITH LPS TO INDUCE INNATE IMMUNE TOLERANCE. OUR DATA SHOW THAT CONSECUTIVE SYSTEMIC LPS TREATMENT DID NOT AFFECT THE SUBSEQUENT DEVELOPMENT OF CNS PRION DISEASE. OUR DATA SUGGESTS INNATE IMMUNE TOLERANCE IN MICROGLIA DOES NOT INFLUENCE THE SUBSEQUENT ONSET OF PRION DISEASE-INDUCED NEUROPATHOLOGY IN MICE, DESPITE PREVIOUSLY PUBLISHED EVIDENCE OF THIS EFFECT IN AN ALZHEIMER'S DISEASE MOUSE MODEL. 2022 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 6531 33 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 7 1179 29 CONVERGENCE AND DIVERGENCE IN THE ETIOLOGY OF MYELIN IMPAIRMENT IN PSYCHIATRIC DISORDERS AND DRUG ADDICTION. IMPAIRMENT OF OLIGODENDROGLIA (OL)-DEPENDENT MYELINATION IN THE CENTRAL NERVOUS SYSTEM (CNS) IS A REMARKABLE PARALLEL RECENTLY IDENTIFIED IN MAJOR PSYCHIATRIC DISORDERS AND CHRONIC DRUG ABUSE. NEUROIMAGING AND NEUROPATHOLOGICAL STUDIES REVEALED MYELIN DEFECTS AND MICROARRAY-PROFILING ANALYSIS DEMONSTRATED ABERRANT EXPRESSION OF MYELIN-RELATED GENES IN SCHIZOPHRENIA (SZ), BIPOLAR DISORDER (BD), MAJOR DEPRESSIVE DISORDER (MDD) AND COCAINE ADDICTION. HOWEVER, THE ETIOLOGY UNDERLYING MYELIN IMPAIRMENT IN THESE CLINICALLY DISTINCT SUBJECTS REMAINS ELUSIVE. THIS ARTICLE REVIEWS MYELIN IMPAIRMENT IN LINE WITH DOPAMINERGIC DYSFUNCTION, A PRIME NEUROPATHOPHYSIOLOGICAL TRAIT SHARED IN PSYCHIATRIC DISORDERS AND DRUG ABUSE, AS WELL AS THE GENETIC AND EPIGENETIC ALTERATIONS ASSOCIATED WITH THESE DISEASES. THE CURRENT FINDINGS SUPPORT THE HYPOTHESIS THAT ABERRANT DOPAMINE (DA) ACTION ON OLS IS A COMMON PATHOLOGIC MECHANISM FOR MYELIN IMPAIRMENT IN THE AFOREMENTIONED MENTAL MORBIDITIES, WHEREAS INHERITED GENETIC VARIATIONS THAT SPECIFICALLY AFFECT OL DEVELOPMENT AND MYELINOGENESIS MAY FURTHER INCREASE MYELIN VULNERABILITY IN PSYCHIATRIC DISORDERS. IMPORTANTLY, OL DEFECT IS NOT ONLY A PATHOLOGICAL CONSEQUENCE BUT ALSO A CAUSATIVE FACTOR FOR DOPAMINERGIC DYSFUNCTION. HENCE, MYELIN IMPAIRMENT IS A KEY FACTOR IN THE PATHOGENIC LOOP OF PSYCHIATRIC DISEASES AND DRUG ADDICTION. 2008 8 3540 30 IMMUNE-DERIVED CYTOKINES IN THE NERVOUS SYSTEM: EPIGENETIC INSTRUCTIVE SIGNALS OR NEUROPATHOGENIC MEDIATORS? THE INVESTIGATION OF THE EFFECTS OF INFLAMMATORY CYTOKINES (IC) ON THE GROWTH AND DIFFERENTIATION OF NEURAL CELLS HAS PROVIDED NEW INSIGHTS ON THE ROLE OF SUCH SOLUBLE MEDIATORS IN NERVOUS SYSTEM DEVELOPMENT AND/OR PLASTIC REMODELING AS WELL AS IN THE PATHOGENESIS OF INFLAMMATORY NEURODEGENERATIVE DISORDERS, WHICH ARE CHARACTERIZED BY CHRONIC IC DYSREGULATION IN THE CENTRAL NERVOUS SYSTEM (CNS). THUS, THE STUDY OF THE INTERACTION BETWEEN CNS AND IMMUNE-DERIVED SOLUBLE SIGNALS IN PHYSIOLOGICAL OR PATHOLOGICAL CONDITIONS IS OF INCREASING INTEREST. THIS REVIEW FIRST DISCUSSES EXPERIMENTAL EVIDENCE SUPPORTING THE INSTRUCTIVE/PERMISSIVE ROLE OF IMMUNE-DERIVED CYTOKINES ON CNS DEVELOPMENT AND PLASTICITY. NEXT, WE FOCUS ON HUMAN NEUROLOGICAL DISEASE STATES SUCH AS MULTIPLE SCLEROSIS AND THE NEURODEGENERATION ASSOCIATED TO THE ACQUIRED IMMUNE DEFICIENCY SYNDROME IN WHICH DIFFERENT INFLAMMATORY CYTOKINES HAVE BEEN PROPOSED AS POTENTIAL NEUROPATHOGENIC MEDIATORS. 1999 9 4304 40 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 4590 34 NANOPORE SEQUENCING IDENTIFIES DIFFERENTIALLY METHYLATED GENES IN THE CENTRAL NERVOUS SYSTEM IN EXPERIMENTAL AUTOIMMUNE ENCEPHALOMYELITIS. MULTIPLE SCLEROSIS (MS) IS A CHRONIC AUTOIMMUNE-MEDIATED DEMYELINATING DISEASE OF THE CENTRAL NERVOUS SYSTEM (CNS) THAT MIGHT BE TRIGGERED BY ABERRANT EPIGENETIC CHANGES IN THE GENOME. DNA METHYLATION IS THE MOST STUDIED EPIGENETIC MECHANISM THAT PARTICIPATES IN MS PATHOGENESIS. HOWEVER, THE OVERALL METHYLATION LEVEL IN THE CNS OF MS PATIENTS REMAINS ELUSIVE. WE USED DIRECT LONG-READ NANOPORE DNA SEQUENCING AND CHARACTERIZED THE DIFFERENTIALLY METHYLATED GENES IN THE BRAIN FROM MICE WITH EXPERIMENTAL AUTOIMMUNE ENCEPHALOMYELITIS (EAE), AN ANIMAL MODEL OF MS. WE IDENTIFIED 163 HYPOMETHYLATED PROMOTERS AND 327 HYPERMETHYLATED PROMOTERS. THESE GENOMIC ALTERATIONS WERE LINKED TO VARIOUS BIOLOGICAL PROCESSES INCLUDING METABOLISM, IMMUNE RESPONSES, NEURAL ACTIVITIES, AND MITOCHONDRIAL DYNAMICS, ALL OF WHICH ARE VITAL FOR EAE DEVELOPMENT. OUR RESULTS INDICATE A GREAT POTENTIAL OF NANOPORE SEQUENCING IN IDENTIFYING GENOMIC DNA METHYLATION IN EAE AND PROVIDE IMPORTANT GUIDANCE FOR FUTURE STUDIES INVESTIGATING THE MS/EAE PATHOLOGY. 2023 11 6347 26 THE ROLE OF EPIGENETICS IN NEUROINFLAMMATORY-DRIVEN DISEASES. NEURODEGENERATIVE DISORDERS ARE CHARACTERIZED BY THE PROGRESSIVE LOSS OF CENTRAL AND/OR PERIPHERAL NERVOUS SYSTEM NEURONS. WITHIN THIS CONTEXT, NEUROINFLAMMATION COMES UP AS ONE OF THE MAIN FACTORS LINKED TO NEURODEGENERATION PROGRESSION. IN FACT, NEUROINFLAMMATION HAS BEEN RECOGNIZED AS AN OUTSTANDING FACTOR FOR ALZHEIMER'S DISEASE (AD), AMYOTROPHIC LATERAL SCLEROSIS (ALS), PARKINSON'S DISEASE (PD), AND MULTIPLE SCLEROSIS (MS). INTERESTINGLY, NEUROINFLAMMATORY DISEASES ARE CHARACTERIZED BY DRAMATIC CHANGES IN THE EPIGENETIC PROFILE, WHICH MIGHT PROVIDE NOVEL PROGNOSTIC AND THERAPEUTIC FACTORS TOWARDS NEUROINFLAMMATORY TREATMENT. DEEP CHANGES IN DNA AND HISTONE METHYLATION, ALONG WITH HISTONE ACETYLATION AND ALTERED NON-CODING RNA EXPRESSION, HAVE BEEN REPORTED AT THE ONSET OF INFLAMMATORY DISEASES. THE AIM OF THIS WORK IS TO REVIEW THE CURRENT KNOWLEDGE ON THIS FIELD. 2022 12 1430 22 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 13 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 14 3380 29 HIV-1 INFECTION OF GENETICALLY ENGINEERED IPSC-DERIVED CENTRAL NERVOUS SYSTEM-ENGRAFTED MICROGLIA IN A HUMANIZED MOUSE MODEL. THE CENTRAL NERVOUS SYSTEM (CNS) IS A MAJOR HUMAN IMMUNODEFICIENCY VIRUS TYPE 1 RESERVOIR. MICROGLIA ARE THE PRIMARY TARGET CELL OF HIV-1 INFECTION IN THE CNS. CURRENT MODELS HAVE NOT ALLOWED THE PRECISE MOLECULAR PATHWAYS OF ACUTE AND CHRONIC CNS MICROGLIAL INFECTION TO BE TESTED WITH IN VIVO GENETIC METHODS. HERE, WE DESCRIBE A NOVEL HUMANIZED MOUSE MODEL UTILIZING HUMAN-INDUCED PLURIPOTENT STEM CELL-DERIVED MICROGLIA TO XENOGRAFT INTO MURINE HOSTS. THESE MICE ARE ADDITIONALLY ENGRAFTED WITH HUMAN PERIPHERAL BLOOD MONONUCLEAR CELLS THAT SERVED AS A MEDIUM TO ESTABLISH A PERIPHERAL INFECTION THAT THEN SPREAD TO THE CNS MICROGLIA XENOGRAFT, MODELING A TRANS-BLOOD-BRAIN BARRIER ROUTE OF ACUTE CNS HIV-1 INFECTION WITH HUMAN TARGET CELLS. THE APPROACH IS COMPATIBLE WITH IPSC GENETIC ENGINEERING, INCLUDING INSERTING TARGETED TRANSGENIC REPORTER CASSETTES TO TRACK THE XENOGRAFTED HUMAN CELLS, ENABLING THE TESTING OF NOVEL TREATMENT AND VIRAL TRACKING STRATEGIES IN A COMPARATIVELY SIMPLE AND COST-EFFECTIVE WAY VIVO MODEL FOR NEUROHIV. IMPORTANCE: OUR MOUSE MODEL IS A POWERFUL TOOL FOR INVESTIGATING THE GENETIC MECHANISMS GOVERNING CNS HIV-1 INFECTION AND LATENCY IN THE CNS AT A SINGLE-CELL LEVEL. A MAJOR ADVANTAGE OF OUR MODEL IS THAT IT USES IPSC-DERIVED MICROGLIA, WHICH ENABLES HUMAN GENETICS, INCLUDING GENE FUNCTION AND THERAPEUTIC GENE MANIPULATION, TO BE EXPLORED IN VIVO , WHICH IS MORE CHALLENGING TO STUDY WITH CURRENT HEMATOPOIETIC STEM CELL-BASED MODELS FOR NEUROHIV. OUR TRANSGENIC TRACING OF XENOGRAFTED HUMAN CELLS WILL PROVIDE A QUANTITATIVE MEDIUM TO DEVELOP NEW MOLECULAR AND EPIGENETIC STRATEGIES FOR REDUCING THE HIV-1 LATENT RESERVOIR AND TO TEST THE IMPACT OF THERAPEUTIC INFLAMMATION-TARGETING DRUG INTERVENTIONS ON CNS HIV-1 LATENCY. 2023 15 5541 29 ROLE OF DIETARY PHENOLS IN MITIGATING MICROGLIA-MEDIATED NEUROINFLAMMATION. CHRONIC NEUROINFLAMMATION IS A PATHOLOGICAL FEATURE OF A NUMBER OF CENTRAL NERVOUS SYSTEM (CNS) DISEASES AND IS MEDIATED BY SUSTAINED ACTIVATION OF MICROGLIAL CELLS, THE INNATE IMMUNE CELLS OF THE CNS. STUDIES HAVE MAINLY FOCUSED ON IDENTIFYING THE MOLECULAR AND EPIGENETIC MECHANISMS OF MICROGLIAL ACTIVATION. THIS IS CRUCIAL IN DESIGNING THERAPEUTIC STRATEGIES FOR NEUROPATHOLOGIES IN WHICH PROLONGED MICROGLIAL ACTIVATION IS KNOWN TO EXACERBATE DISEASE CONDITION. IN RECENT YEARS, INCREASING EVIDENCE SHOW THAT NATURALLY OCCURRING COMPOUNDS PRESENT IN REGULAR DIET COULD FUNCTION AS "NUTRACEUTICALS," ARRESTING MICROGLIAL ACTIVATION, AND THUS CONFERRING NEUROPROTECTION. THIS REVIEW SUMMARIZES OUR UNDERSTANDING OF THE ROLE OF DIETARY PHENOLIC NUTRACEUTICALS IN MITIGATING MICROGLIA-MEDIATED NEUROINFLAMMATION. STUDIES SHOW THAT THESE NATURAL PHENOLS INHIBIT KEY SIGNALING PATHWAYS IN ACTIVATED MICROGLIA SUCH AS THE NFKAPPAB, MAPK AND JAK-STAT THAT TRIGGER MICROGLIA-MEDIATED INFLAMMATION IN VARIOUS NEUROPATHOLOGICAL CONDITIONS SUCH AS INJURY, INFECTION, STROKE, AUTISM AND NEURODEGENERATIVE DISEASES, I.E., ALZHEIMER'S DISEASE AND PARKINSON'S DISEASE. THE ANTI-INFLAMMATORY AND ANTIOXIDANT EFFECT EXERTED BY THESE NATURAL PHENOLS HAVE SHOWN CONSIDERABLE SUCCESS IN IMPROVING DISEASE CONDITION IN ANIMAL MODELS OF NEUROPATHOLOGIES, AND THUS SEEM TO BE SUITABLE CANDIDATES FOR DEVELOPING THERAPEUTIC STRATEGIES. 2016 16 4721 32 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 17 4333 32 MICRORNAS: KEY PLAYERS IN MICROGLIA AND ASTROCYTE MEDIATED INFLAMMATION IN CNS PATHOLOGIES. THE SIGNIFICANCE OF MICROGLIA AND ASTROCYTES IN NEURAL DEVELOPMENT, IN MAINTAINING SYNAPTIC CONNECTIONS AND HOMEOSTASIS IN THE HEALTHY BRAIN IS WELL ESTABLISHED. MICROGLIA ARE DYNAMIC IMMUNE CELLS OF THE BRAIN THAT ELICIT AN IMMUNE RESPONSE DURING BRAIN DAMAGE AND ALSO PARTICIPATE IN TISSUE REPAIR AND REGENERATION, WHILE ASTROCYTES CONTRIBUTE TO THE LOCAL INFLAMMATORY RESPONSE BY PRODUCING PROINFLAMMATORY CYTOKINES AND RESOLVING NEURONAL DAMAGE THROUGH PRODUCTION OF ANTI-INFLAMMATORY CYTOKINES AND NEUROTROPHIC FACTORS. RECENT EFFORTS HAVE FOCUSED ON ELUCIDATING THE EPIGENETIC MECHANISMS WHICH REGULATE GLIAL CELL BEHAVIOR IN NORMAL AND PATHOLOGIC STATES. AN IMPORTANT CLASS OF EPIGENETIC REGULATORS IS MICRORNAS (MIRNAS) WHICH ARE SMALL NON-CODING RNA MOLECULES THAT REGULATE GENE EXPRESSION POSTTRANSCRIPTIONALLY. CERTAIN DYSREGULATED MIRNAS CONTRIBUTE TO CHRONIC MICROGLIAL INFLAMMATION IN THE BRAIN, THEREBY LEADING TO PROGRESSION OF NEUROLOGICAL DISEASES LIKE ALZHEIMER'S DISEASE, TRAUMATIC INJURY, AMYOTROPHIC LATERAL SCLEROSIS AND STROKE. FURTHER, SEVERAL MIRNAS ARE DIFFERENTIALLY EXPRESSED IN ASTROCYTES AFTER ISCHEMIA AND SPINAL CORD INJURY. DESPITE KNOWLEDGE ABOUT MIRNAS IN NEUROINFLAMMATION, LITTLE IS KNOWN ABOUT EFFECTIVE DELIVERY ROUTES AND PHARMACOKINETIC DATA FOR MIRNA BASED THERAPEUTICS. THIS REVIEW SUMMARIZES THE CURRENT RESEARCH ON THE ROLE OF MIRNAS IN PROMOTING AND INHIBITING INFLAMMATORY RESPONSE OF MICROGLIA AND ASTROCYTES IN A DISEASE-SPECIFIC MANNER. IN ADDITION, MIRNA DELIVERY AS A THERAPEUTIC STRATEGY TO TREAT NEUROINFLAMMATION IS DISCUSSED. 2016 18 4278 36 MICROGLIAL INNATE MEMORY AND EPIGENETIC REPROGRAMMING IN NEUROLOGICAL DISORDERS. MICROGLIA ARE MYELOID-DERIVED CELLS RECOGNIZED AS BRAIN-RESIDENT MACROPHAGES. THEY ACT AS THE FIRST AND MAIN LINE OF IMMUNE DEFENSE IN THE CENTRAL NERVOUS SYSTEM (CNS). MICROGLIA HAVE HIGH PHENOTYPIC PLASTICITY AND ARE ESSENTIAL FOR REGULATING HEALTHY BRAIN HOMEOSTASIS, AND THEIR DYSREGULATION UNDERLIES THE ONSET AND PROGRESSION OF SEVERAL CNS PATHOLOGIES THROUGH IMPAIRED INFLAMMATORY RESPONSES. ABERRANT MICROGLIAL ACTIVATION, FOLLOWING AN INFLAMMATORY INSULT, IS ASSOCIATED WITH EPIGENETIC DYSREGULATION IN VARIOUS CNS PATHOLOGIES. EMERGING DATA SUGGEST THAT CERTAIN STIMULI TO MYELOID CELLS DETERMINE ENHANCED OR ATTENUATED RESPONSES TO SUBSEQUENT STIMULI. THESE PHENOMENA, GENERALLY TERMED INNATE IMMUNE MEMORY (IIM), ARE HIGHLY DEPENDENT ON EPIGENETIC REPROGRAMMING. MICROGLIAL PRIMING HAS BEEN REPORTED IN SEVERAL NEUROLOGICAL DISEASES AND CORRESPONDS TO A STATE OF INCREASED PERMISSIVENESS OR EXACERBATED RESPONSE, PROMOTED BY CONTINUOUS EXPOSURE TO A CHRONIC PRO-INFLAMMATORY ENVIRONMENT. IN THIS ARTICLE, WE PROVIDE EXTENSIVE EVIDENCE OF THESE EPIGENETIC-MEDIATED PHENOMENA UNDER NEUROLOGICAL CONDITIONS AND DISCUSS THEIR CONTRIBUTION TO PATHOGENESIS AND THEIR CLINICAL IMPLICATIONS, INCLUDING THOSE CONCERNING POTENTIAL NOVEL THERAPEUTIC APPROACHES. 2021 19 2004 29 EPIGENETIC ASPECTS OF MULTIPLE SCLEROSIS AND FUTURE THERAPEUTIC OPTIONS. MULTIPLE SCLEROSIS (MS) IS A CHRONIC INFLAMMATORY AND NEURODEGENERATIVE DISEASE ACCOMPANIED BY DEMYELINATION OF NEURONS IN THE CENTRAL NERVOUS SYSTEM THAT MOSTLY AFFECTS YOUNG ADULTS, ESPECIALLY WOMEN. THIS DISEASE HAS TWO PHASES INCLUDING RELAPSING-REMITTING FORM (RR-MS) BY EPISODES OF RELAPSE AND PERIODS OF CLINICAL REMISSION AND SECONDARY-PROGRESSIVE FORM (SP-MS), WHICH CAUSES MORE DISABILITY. THE INHERITANCE PATTERN OF MS IS NOT EXACTLY IDENTIFIED AND THERE IS AN AGREEMENT THAT IT HAS A COMPLEX PATTERN WITH AN INTERPLAY AMONG ENVIRONMENTAL, GENETIC AND EPIGENETIC ALTERNATIONS. EPIGENETIC MECHANISMS THAT ARE IDENTIFIED FOR MS PATHOGENESIS ARE DNA METHYLATION, HISTONE MODIFICATION AND SOME MICRORNAS' ALTERNATIONS. SEVERAL CELLULAR PROCESSES INCLUDING APOPTOSIS, DIFFERENTIATION AND EVOLUTION CAN BE MODIFIED ALONG WITH EPIGENETIC CHANGES. SOME ALTERNATIONS ARE ASSOCIATED WITH EPIGENETIC MECHANISMS IN MS PATIENTS AND THESE CHANGES CAN BECOME KEY POINTS FOR MS THERAPY. THEREFORE, THE AIM OF THIS REVIEW WAS TO DISCUSS EPIGENETIC MECHANISMS THAT ARE ASSOCIATED WITH MS PATHOGENESIS AND FUTURE THERAPEUTIC APPROACHES. 2021 20 5369 26 RECENT ADVANCES IN UNDERSTANDING NEUROPATHIC PAIN: GLIA, SEX DIFFERENCES, AND EPIGENETICS. NEUROPATHIC PAIN RESULTS FROM DISEASES OR TRAUMA AFFECTING THE NERVOUS SYSTEM. THIS PAIN CAN BE DEVASTATING AND IS POORLY CONTROLLED. THE PATHOPHYSIOLOGY IS COMPLEX, AND IT IS ESSENTIAL TO UNDERSTAND THE UNDERLYING MECHANISMS IN ORDER TO IDENTIFY THE RELEVANT TARGETS FOR THERAPEUTIC INTERVENTION. IN THIS ARTICLE, WE FOCUS ON THE RECENT RESEARCH INVESTIGATING NEURO-IMMUNE COMMUNICATION AND EPIGENETIC PROCESSES, WHICH GAIN PARTICULAR ATTENTION IN THE CONTEXT OF NEUROPATHIC PAIN. SPECIFICALLY, WE ANALYZE THE ROLE OF GLIAL CELLS, INCLUDING MICROGLIA, ASTROCYTES, AND OLIGODENDROCYTES, IN THE MODULATION OF THE CENTRAL NERVOUS SYSTEM INFLAMMATION TRIGGERED BY NEUROPATHY. CONSIDERING EPIGENETICS, WE ADDRESS DNA METHYLATION, HISTONE MODIFICATIONS, AND THE NON-CODING RNAS IN THE REGULATION OF ION CHANNELS, G-PROTEIN-COUPLED RECEPTORS, AND TRANSMITTERS FOLLOWING NEURONAL DAMAGE. THE GOAL WAS NOT ONLY TO HIGHLIGHT THE EMERGING CONCEPTS BUT ALSO TO DISCUSS CONTROVERSIES, METHODOLOGICAL COMPLICATIONS, AND INTRIGUING OPINIONS. 2016