1 2066 114 EPIGENETIC CONTROL OF ION CHANNEL EXPRESSION AND CELL-SPECIFIC SPLICING IN NOCICEPTORS: CHRONIC PAIN MECHANISMS AND POTENTIAL THERAPEUTIC TARGETS. ION CHANNELS UNDERLIE ALL FORMS FOR ELECTRICAL SIGNALING INCLUDING THE TRANSMISSION OF INFORMATION ABOUT HARMFUL EVENTS. VOLTAGE-GATED CALCIUM ION CHANNELS HAVE DUAL FUNCTION, THEY SUPPORT ELECTRICAL SIGNALING AS WELL AS INTRACELLULAR CALCIUM SIGNALING THROUGH EXCITATION-DEPENDENT CALCIUM ENTRY ACROSS THE PLASMA MEMBRANE. MECHANISMS THAT REGULATE ION CHANNEL FORMS AND ACTIONS ARE ESSENTIAL FOR MYRIAD CELL FUNCTIONS AND THESE ARE TARGETED BY DRUGS AND THERAPEUTICS. WHEN DISRUPTED, THE CELLULAR MECHANISMS THAT CONTROL ION CHANNEL ACTIVITY CAN CONTRIBUTE TO DISEASE PATHOPHYSIOLOGY. FOR EXAMPLE, ALTERNATIVE PRE-MRNA SPLICING IS A MAJOR STEP IN DEFINING THE PRECISE COMPOSITION OF THE TRANSCRIPTOME ACROSS DIFFERENT CELL TYPES FROM EARLY CELLULAR DIFFERENTIATION TO PROGRAMMED APOPTOSIS. AN ESTIMATED 30% OF DISEASE-CAUSING MUTATIONS ARE ASSOCIATED WITH ALTERED ALTERNATIVE SPLICING, AND MIS-SPLICING IS A FEATURE OF NUMEROUS HIGHLY PREVALENT DISEASES INCLUDING NEURODEGENERATIVE, CANCER, AND CHRONIC PAIN. HERE WE DISCUSS THE IMPORTANT ROLE OF EPIGENETIC REGULATION OF GENE EXPRESSION AND CELL-SPECIFIC ALTERNATIVE SPLICING OF CALCIUM ION CHANNELS IN NOCICEPTORS, WITH EMPHASIS ON HOW THESE PROCESSES ARE DISRUPTED IN CHRONIC PAIN, THE POTENTIAL THERAPEUTIC BENEFIT OF CORRECTING OR COMPENSATING FOR ABERRANT ION CHANNEL SPLICING IN CHRONIC PAIN. 2021 2 3201 32 HDAC2 IN PRIMARY SENSORY NEURONS CONSTITUTIVELY RESTRAINS CHRONIC PAIN BY REPRESSING ALPHA2DELTA-1 EXPRESSION AND ASSOCIATED NMDA RECEPTOR ACTIVITY. ALPHA2DELTA-1 (ENCODED BY THE CACNA2D1 GENE) IS A NEWLY DISCOVERED NMDA RECEPTOR-INTERACTING PROTEIN AND IS THE THERAPEUTIC TARGET OF GABAPENTINOIDS (E.G., GABAPENTIN AND PREGABALIN) FREQUENTLY USED FOR TREATING PATIENTS WITH NEUROPATHIC PAIN. NERVE INJURY CAUSES SUSTAINED ALPHA2DELTA-1 UPREGULATION IN THE DORSAL ROOT GANGLION (DRG), WHICH PROMOTES NMDA RECEPTOR SYNAPTIC TRAFFICKING AND ACTIVATION IN THE SPINAL DORSAL HORN, A HALLMARK OF CHRONIC NEUROPATHIC PAIN. HOWEVER, LITTLE IS KNOWN ABOUT HOW NERVE INJURY INITIATES AND MAINTAINS THE HIGH EXPRESSION LEVEL OF ALPHA2DELTA-1 TO SUSTAIN CHRONIC PAIN. HERE, WE SHOW THAT NERVE INJURY CAUSED HISTONE HYPERACETYLATION AND DIMINISHED ENRICHMENT OF HISTONE DEACETYLASE-2 (HDAC2), BUT NOT HDAC3, AT THE CACNA2D1 PROMOTER IN THE DRG. STRIKINGLY, HDAC2 KNOCKDOWN OR CONDITIONAL KNOCKOUT IN DRG NEURONS IN MALE AND FEMALE MICE CONSISTENTLY INDUCED LONG-LASTING MECHANICAL PAIN HYPERSENSITIVITY, WHICH WAS READILY REVERSED BY BLOCKING NMDA RECEPTORS, INHIBITING ALPHA2DELTA-1 WITH GABAPENTIN OR DISRUPTING THE ALPHA2DELTA-1-NMDA RECEPTOR INTERACTION AT THE SPINAL CORD LEVEL. HDAC2 DELETION IN DRG NEURONS INCREASED HISTONE ACETYLATION LEVELS AT THE CACNA2D1 PROMOTER, UPREGULATED ALPHA2DELTA-1 IN THE DRG, AND POTENTIATED ALPHA2DELTA-1-DEPENDENT NMDA RECEPTOR ACTIVITY AT PRIMARY AFFERENT CENTRAL TERMINALS IN THE SPINAL DORSAL HORN. CORRESPONDINGLY, HDAC2 KNOCKDOWN-INDUCED PAIN HYPERSENSITIVITY WAS BLUNTED IN CACNA2D1 KNOCKOUT MICE. THUS, OUR FINDINGS REVEAL THAT HDAC2 FUNCTIONS AS A PIVOTAL TRANSCRIPTIONAL REPRESSOR OF NEUROPATHIC PAIN VIA CONSTITUTIVELY SUPPRESSING ALPHA2DELTA-1 EXPRESSION AND ENSUING PRESYNAPTIC NMDA RECEPTOR ACTIVITY IN THE SPINAL CORD. HDAC2 ENRICHMENT LEVELS AT THE CACNA2D1 PROMOTER IN DRG NEURONS CONSTITUTE A UNIQUE EPIGENETIC MECHANISM THAT GOVERNS ACUTE-TO-CHRONIC PAIN TRANSITION.SIGNIFICANCE STATEMENT EXCESS ALPHA2DELTA-1 PROTEINS PRODUCED AFTER NERVE INJURY DIRECTLY INTERACT WITH GLUTAMATE NMDA RECEPTORS TO POTENTIATE SYNAPTIC NMDA RECEPTOR ACTIVITY IN THE SPINAL CORD, A PROMINENT MECHANISM OF NERVE PAIN. BECAUSE ALPHA2DELTA-1 UPREGULATION AFTER NERVE INJURY IS LONG LASTING, GABAPENTINOIDS RELIEVE PAIN SYMPTOMS ONLY TEMPORARILY. OUR STUDY DEMONSTRATES FOR THE FIRST TIME THE UNEXPECTED ROLE OF INTRINSIC HDAC2 ACTIVITY AT THE ALPHA2DELTA-1 GENE PROMOTER IN LIMITING ALPHA2DELTA-1 GENE TRANSCRIPTION, NMDA RECEPTOR-DEPENDENT SYNAPTIC PLASTICITY, AND CHRONIC PAIN DEVELOPMENT AFTER NERVE INJURY. THESE FINDINGS CHALLENGE THE PREVAILING VIEW ABOUT THE ROLE OF GENERAL HDAC ACTIVITY IN PROMOTING CHRONIC PAIN. RESTORING THE REPRESSIVE HDAC2 FUNCTION AND/OR REDUCING HISTONE ACETYLATION AT THE ALPHA2DELTA-1 GENE PROMOTER IN PRIMARY SENSORY NEURONS COULD LEAD TO LONG-LASTING RELIEF OF NERVE PAIN. 2022 3 5600 25 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 4 6585 29 TRPV4-MEDIATED ANTI-NOCICEPTIVE EFFECT OF SUBERANILOHYDROXAMIC ACID ON MECHANICAL PAIN. BIOLOGICAL EFFECTS OF SUBERANILOHYDROXAMIC ACID (SAHA) HAVE MAINLY BEEN OBSERVED IN THE CONTEXT OF TUMOR SUPPRESSION VIA EPIGENETIC MECHANISMS, BUT OTHER POTENTIAL OUTCOMES FROM ITS USE HAVE ALSO BEEN PROPOSED IN DIFFERENT FIELDS SUCH AS PAIN MODULATION. HERE, WE TRIED TO UNDERSTAND WHETHER SAHA MODULATES SPECIFIC PAIN MODALITIES BY A NON-EPIGENETIC UNKNOWN MECHANISM. FROM 24 H COMPLETE FREUND'S ADJUVANT (CFA)-INFLAMED HIND PAWS OF MICE, MECHANICAL AND THERMAL INFLAMMATORY PAIN INDICES WERE COLLECTED WITH OR WITHOUT IMMEDIATE INTRAPLANTAR INJECTION OF SAHA. TO EXAMINE THE ACTION OF SAHA ON SENSORY RECEPTOR-SPECIFIC PAIN, TRANSIENT RECEPTOR POTENTIAL (TRP) ION CHANNEL-MEDIATED PAIN INDICES WERE COLLECTED IN THE SAME MANNER OF INTRAPLANTAR TREATMENT. ACTIVITIES OF PRIMARILY CULTURED SENSORY NEURONS AND HETEROLOGOUS CELLS TRANSFECTED WITH TRP CHANNELS WERE MONITORED TO DETERMINE THE MOLECULAR MECHANISM UNDERLYING THE PAIN-MODULATING EFFECT OF SAHA. AS A RESULT, IMMEDIATE AND LOCALIZED PRETREATMENT WITH SAHA, AVOIDING AN EPIGENETIC INTERVENTION, ACUTELY ATTENUATED MECHANICAL INFLAMMATORY PAIN AND RECEPTOR-SPECIFIC PAIN EVOKED BY INJECTION OF A TRP CHANNEL AGONIST IN ANIMAL MODELS. WE SHOW THAT A COMPONENT OF THE MECHANISMS INVOLVES TRPV4 INHIBITION BASED ON IN VITRO INTRACELLULAR CA(2+) IMAGING AND ELECTROPHYSIOLOGICAL ASSESSMENTS WITH HETEROLOGOUS EXPRESSION SYSTEMS AND CULTURED SENSORY NEURONS. TAKEN TOGETHER, THE PRESENT STUDY PROVIDES EVIDENCE OF A NOVEL OFF-TARGET ACTION AND ITS MECHANISM OF SAHA IN ITS MODALITY-SPECIFIC ANTI-NOCICEPTIVE EFFECT AND SUGGESTS THE UTILITY OF THIS COMPOUND FOR PHARMACOLOGICAL MODULATION OF PAIN. 2019 5 2214 40 EPIGENETIC MODIFICATIONS ASSOCIATED TO NEUROINFLAMMATION AND NEUROPATHIC PAIN AFTER NEURAL TRAUMA. ACCUMULATING EVIDENCE SUGGESTS THAT EPIGENETIC ALTERATIONS LIE BEHIND THE INDUCTION AND MAINTENANCE OF NEUROPATHIC PAIN. NEUROPATHIC PAIN IS USUALLY A CHRONIC CONDITION CAUSED BY A LESION, OR PATHOLOGICAL CHANGE, WITHIN THE NERVOUS SYSTEM. NEUROPATHIC PAIN APPEARS FREQUENTLY AFTER NERVE AND SPINAL CORD INJURIES OR DISEASES, PRODUCING A DEBILITATION OF THE PATIENT AND A DECREASE OF THE QUALITY OF LIFE. AT THE CELLULAR LEVEL, NEUROPATHIC PAIN IS THE RESULT OF NEURONAL PLASTICITY SHAPED BY AN INCREASE IN THE SENSITIVITY AND EXCITABILITY OF SENSORY NEURONS OF THE CENTRAL AND PERIPHERAL NERVOUS SYSTEM. ONE OF THE MECHANISMS THOUGHT TO CONTRIBUTE TO HYPEREXCITABILITY AND THEREFORE TO THE ONTOGENY OF NEUROPATHIC PAIN IS THE ALTERED EXPRESSION, TRAFFICKING, AND FUNCTIONING OF RECEPTORS AND ION CHANNELS EXPRESSED BY PRIMARY SENSORY NEURONS. BESIDES, NEURONAL AND GLIAL CELLS, SUCH AS MICROGLIA AND ASTROCYTES, TOGETHER WITH BLOOD BORNE MACROPHAGES, PLAY A CRITICAL ROLE IN THE INDUCTION AND MAINTENANCE OF NEUROPATHIC PAIN BY RELEASING POWERFUL NEUROMODULATORS SUCH AS PRO-INFLAMMATORY CYTOKINES AND CHEMOKINES, WHICH ENHANCE NEURONAL EXCITABILITY. ALTERED GENE EXPRESSION OF NEURONAL RECEPTORS, ION CHANNELS, AND PRO-INFLAMMATORY CYTOKINES AND CHEMOKINES, HAVE BEEN ASSOCIATED TO EPIGENETIC ADAPTATIONS OF THE INJURED TISSUE. WITHIN THIS REVIEW, WE DISCUSS THE INVOLVEMENT OF THESE EPIGENETIC CHANGES, INCLUDING HISTONE MODIFICATIONS, DNA METHYLATION, NON-CODING RNAS, AND ALTERATION OF CHROMATIN MODIFIERS, THAT HAVE BEEN SHOWN TO TRIGGER MODIFICATION OF NOCICEPTION AFTER NEURAL LESIONS. IN PARTICULAR, THE FUNCTION ON THESE PROCESSES OF EZH2, JMJD3, MECP2, SEVERAL HISTONE DEACETYLASES (HDACS) AND HISTONE ACETYL TRANSFERASES (HATS), G9A, DNMT, REST AND DIVERSE NON-CODING RNAS, ARE DESCRIBED. DESPITE THE EFFORT ON DEVELOPING NEW THERAPIES, CURRENT TREATMENTS HAVE ONLY PRODUCED LIMITED RELIEF OF THIS PAIN IN A PORTION OF PATIENTS. THUS, THE PRESENT REVIEW AIMS TO CONTRIBUTE TO FIND NOVEL TARGETS FOR CHRONIC NEUROPATHIC PAIN TREATMENT. 2018 6 2179 28 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 7 2772 34 EXTRACELLULAR ATP AND NEURODEGENERATION. ATP IS A POTENT SIGNALING MOLECULE ABUNDANTLY PRESENT IN THE CNS. IT ELICITS A WIDE ARRAY OF PHYSIOLOGICAL EFFECTS AND IS REGARDED AS THE PHYLOGENETICALLY MOST ANCIENT EPIGENETIC FACTOR PLAYING CRUCIAL BIOLOGICAL ROLES IN SEVERAL DIFFERENT TISSUES. THESE CAN RANGE FROM NEUROTRANSMISSION, SMOOTH MUSCLE CONTRACTION, CHEMOSENSORY SIGNALING, SECRETION AND VASODILATATION, TO MORE COMPLEX PHENOMENA SUCH AS IMMUNE RESPONSES, PAIN, MALE REPRODUCTION, FERTILIZATION AND EMBRYONIC DEVELOPMENT. ATP IS RELEASED INTO THE EXTRACELLULAR SPACE EITHER EXOCYTOTICALLY OR FROM DAMAGED AND DYING CELLS. IT IS OFTEN CO-RELEASED WITH OTHER NEUROTRANSMITTERS AND IT CAN INTERACT WITH GROWTH FACTORS AT BOTH RECEPTOR- AND/OR SIGNAL TRANSDUCTION-LEVEL. ONCE IN THE EXTRACELLULAR ENVIRONMENT, ATP BINDS TO SPECIFIC RECEPTORS TERMED P2. BASED ON PHARMACOLOGICAL PROFILES, ON SELECTIVITY OF COUPLING TO SECOND-MESSENGER PATHWAYS AND ON MOLECULAR CLONING, TWO MAIN SUBCLASSES WITH MULTIPLE SUBTYPES HAVE BEEN DISTINGUISHED. THEY ARE P2X, I.E. FAST CATION-SELECTIVE RECEPTOR CHANNELS (NA+, K+, CA2+), POSSESSING LOW AFFINITY FOR ATP AND RESPONSIBLE FOR FAST EXCITATORY NEUROTRANSMISSION, AND P2Y, I.E. SLOW G PROTEIN-COUPLED METABOTROPIC RECEPTORS, POSSESSING HIGHER AFFINITY FOR THE LIGAND. IN THE NERVOUS SYSTEM, THEY ARE BROADLY EXPRESSED IN BOTH NEURONS AND GLIAL CELLS AND CAN MEDIATE DUAL EFFECTS: SHORT-TERM SUCH AS NEUROTRANSMISSION, AND LONG-TERM SUCH AS TROPHIC ACTIONS. SINCE MASSIVE EXTRACELLULAR RELEASE OF ATP OFTEN OCCURS AFTER METABOLIC STRESS, BRAIN ISCHEMIA AND TRAUMA, PURINERGIC MECHANISMS ARE ALSO CORRELATED TO AND INVOLVED IN THE ETIOPATHOLOGY OF MANY NEURODEGENERATIVE CONDITIONS. FURTHERMORE, EXTRACELLULAR ATP PER SE IS TOXIC FOR PRIMARY NEURONAL DISSOCIATED AND ORGANOTYPIC CNS CULTURES FROM CORTEX, STRIATUM AND CEREBELLUM AND P2 RECEPTORS CAN MEDIATE AND AGGRAVATE HYPOXIC SIGNALING IN MANY CNS NEURONS. CONVERSELY, SEVERAL P2 RECEPTOR ANTAGONISTS ABOLISH THE CELL DEATH FATE OF PRIMARY NEURONAL CULTURES EXPOSED TO EXCESSIVE GLUTAMATE, SERUM/POTASSIUM DEPRIVATION, HYPOGLYCEMIA AND CHEMICAL HYPOXIA. IN PARALLEL WITH THESE DETRIMENTAL EFFECTS, ALSO TROPHIC FUNCTIONS HAVE BEEN EXTENSIVELY DESCRIBED FOR EXTRACELLULAR PURINES (BOTH FOR NEURONAL AND NON-NEURONAL CELLS), BUT THESE MIGHT EITHER AGGRAVATE OR AMELIORATE THE NORMAL CELLULAR CONDITIONS. IN SUMMARY, EXTRACELLULAR ATP PLAYS A VERY COMPLEX ROLE NOT ONLY IN THE REPAIR, REMODELING AND SURVIVAL OCCURRING IN THE NERVOUS SYSTEM, BUT EVEN IN CELL DEATH AND THIS CAN OCCUR EITHER AFTER NORMAL DEVELOPMENTAL CONDITIONS, AFTER INJURY, OR ACUTE AND CHRONIC DISEASES. 2003 8 2756 34 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 6139 32 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 10 5778 32 SPINAL CORD INJURY INDUCED NEUROPATHIC PAIN: MOLECULAR TARGETS AND THERAPEUTIC APPROACHES. NEUROPATHIC PAIN, ESPECIALLY THAT RESULTING FROM SPINAL CORD INJURY, IS A TREMENDOUS CLINICAL CHALLENGE. A MYRIAD OF BIOLOGICAL CHANGES HAVE BEEN IMPLICATED IN PRODUCING THESE PAIN STATES INCLUDING CELLULAR INTERACTIONS, EXTRACELLULAR PROTEINS, ION CHANNEL EXPRESSION, AND EPIGENETIC INFLUENCES. PHYSIOLOGICAL CONSEQUENCES OF THESE CHANGES ARE VARIED AND INCLUDE FUNCTIONAL DEFICITS AND PAIN RESPONSES. DEVELOPING THERAPIES THAT EFFECTIVELY ADDRESS THE CAUSE OF THESE SYMPTOMS REQUIRE A DEEPER KNOWLEDGE OF ALTERATIONS IN THE MOLECULAR PATHWAYS. MATRIX METALLOPROTEINASES AND TISSUE INHIBITORS OF METALLOPROTEINASES ARE TWO PROMISING THERAPEUTIC TARGETS. MATRIX METALLOPROTEINASES INTERACT WITH AND INFLUENCE MANY OF THE STUDIED PAIN PATHWAYS. GENE EXPRESSION OF ION CHANNELS AND INFLAMMATORY MEDIATORS CLEARLY CONTRIBUTES TO NEUROPATHIC PAIN. LOCALIZED AND TIME DEPENDENT TARGETING OF THESE PROTEINS COULD ALLEVIATE AND EVEN PREVENT NEUROPATHIC PAIN FROM DEVELOPING. CURRENT THERAPEUTIC OPTIONS FOR NEUROPATHIC PAIN ARE LIMITED PRIMARILY TO ANALGESICS TARGETING THE OPIOID PATHWAY. THERAPIES DIRECTED AT MOLECULAR TARGETS ARE HIGHLY DESIRABLE AND IN EARLY STAGES OF DEVELOPMENT. THESE INCLUDE TRANSPLANTATION OF EXOGENOUSLY ENGINEERED CELL POPULATIONS AND TARGETED GENE MANIPULATION. THIS REVIEW DESCRIBES SPECIFIC MOLECULAR TARGETS AMENABLE TO THERAPEUTIC INTERVENTION USING CURRENTLY AVAILABLE DELIVERY SYSTEMS. 2015 11 4304 34 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 12 4645 34 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 13 4617 26 NERVE INJURY-INDUCED CHRONIC PAIN IS ASSOCIATED WITH PERSISTENT DNA METHYLATION REPROGRAMMING IN DORSAL ROOT GANGLION. NERVE INJURY-INDUCED HYPERACTIVITY OF PRIMARY SENSORY NEURONS IN THE DORSAL ROOT GANGLION (DRG) CONTRIBUTES TO CHRONIC PAIN DEVELOPMENT, BUT THE UNDERLYING EPIGENETIC MECHANISMS REMAIN POORLY UNDERSTOOD. HERE WE DETERMINED GENOME-WIDE CHANGES IN DNA METHYLATION IN THE NERVOUS SYSTEM IN NEUROPATHIC PAIN. SPINAL NERVE LIGATION (SNL), BUT NOT PACLITAXEL TREATMENT, IN MALE SPRAGUE DAWLEY RATS INDUCED A CONSISTENT LOW-LEVEL HYPOMETHYLATION IN THE CPG SITES IN THE DRG DURING THE ACUTE AND CHRONIC PHASES OF NEUROPATHIC PAIN. DNA METHYLATION REMODELING IN THE DRG OCCURRED EARLY AFTER SNL AND PERSISTED FOR AT LEAST 3 WEEKS. SNL CAUSED DNA METHYLATION CHANGES AT 8% OF CPG SITES WITH PREVAILING HYPOMETHYLATION OUTSIDE OF CPG ISLANDS, IN INTRONS, INTERGENIC REGIONS, AND REPETITIVE SEQUENCES. IN CONTRAST, SNL CAUSED MORE GAINS OF METHYLATION IN THE SPINAL CORD AND PREFRONTAL CORTEX. THE DNA METHYLATION CHANGES IN THE INJURED DRGS RECAPITULATED DEVELOPMENTAL REPROGRAMMING AT THE NEONATAL STAGE. METHYLATION REPROGRAMMING WAS CORRELATED WITH INCREASED GENE EXPRESSION VARIABILITY. A DIET DEFICIENT IN METHYL DONORS INDUCED HYPOMETHYLATION AND PAIN HYPERSENSITIVITY. INTRATHECAL ADMINISTRATION OF THE DNA METHYLTRANSFERASE INHIBITOR RG108 CAUSED LONG-LASTING PAIN HYPERSENSITIVITY. DNA METHYLATION REPROGRAMMING IN THE DRG THUS CONTRIBUTES TO NERVE INJURY-INDUCED CHRONIC PAIN. RESTORING DNA METHYLATION MAY REPRESENT A NEW THERAPEUTIC APPROACH TO TREAT NEUROPATHIC PAIN.SIGNIFICANCE STATEMENT EPIGENETIC MECHANISMS ARE CRITICALLY INVOLVED IN THE TRANSITION FROM ACUTE TO CHRONIC PAIN AFTER NERVE INJURY. HOWEVER, GENOME-WIDE CHANGES IN DNA METHYLATION IN THE NERVOUS SYSTEM AND THEIR ROLES IN NEUROPATHIC PAIN DEVELOPMENT REMAIN UNCLEAR. HERE WE USED DIGITAL RESTRICTION ENZYME ANALYSIS OF METHYLATION TO QUANTITATIVELY DETERMINE GENOME-WIDE DNA METHYLATION CHANGES CAUSED BY NERVE INJURY. WE SHOWED THAT NERVE INJURY CAUSED DNA METHYLATION CHANGES AT 8% OF CPG SITES WITH PREVAILING HYPOMETHYLATION OUTSIDE OF CPG ISLANDS IN THE DORSAL ROOT GANGLION. REDUCING DNA METHYLATION INDUCED PAIN HYPERSENSITIVITY, WHEREAS INCREASING DNA METHYLATION ATTENUATED NEUROPATHIC PAIN. THESE FINDINGS EXTEND OUR UNDERSTANDING OF THE EPIGENETIC MECHANISM OF CHRONIC NEUROPATHIC PAIN AND SUGGEST NEW STRATEGIES TO TREAT NERVE INJURY-INDUCED CHRONIC PAIN. 2018 14 5006 41 PERIPHERAL NERVE INJURY IS ACCOMPANIED BY CHRONIC TRANSCRIPTOME-WIDE CHANGES IN THE MOUSE PREFRONTAL CORTEX. BACKGROUND: PERIPHERAL NERVE INJURY CAN HAVE LONG-TERM CONSEQUENCES INCLUDING PAIN-RELATED MANIFESTATIONS, SUCH AS HYPERSENSITIVITY TO CUTANEOUS STIMULI, AS WELL AS AFFECTIVE AND COGNITIVE DISTURBANCES, SUGGESTING THE INVOLVEMENT OF SUPRASPINAL MECHANISMS. CHANGES IN BRAIN STRUCTURE AND CORTICAL FUNCTION ASSOCIATED WITH MANY CHRONIC PAIN CONDITIONS HAVE BEEN REPORTED IN THE PREFRONTAL CORTEX (PFC). THE PFC IS IMPLICATED IN PAIN-RELATED CO-MORBIDITIES SUCH AS DEPRESSION, ANXIETY AND IMPAIRED EMOTIONAL DECISION-MAKING ABILITY. WE RECENTLY REPORTED THAT THIS REGION IS SUBJECT TO SIGNIFICANT EPIGENETIC REPROGRAMMING FOLLOWING PERIPHERAL NERVE INJURY, AND NORMALIZATION OF PAIN-RELATED STRUCTURAL, FUNCTIONAL AND EPIGENETIC ABNORMALITIES IN THE PFC ARE ALL ASSOCIATED WITH EFFECTIVE PAIN REDUCTION. IN THIS STUDY, WE USED THE SPARED NERVE INJURY (SNI) MODEL OF NEUROPATHIC PAIN TO TEST THE HYPOTHESIS THAT PERIPHERAL NERVE INJURY TRIGGERS PERSISTENT LONG-LASTING CHANGES IN GENE EXPRESSION IN THE PFC, WHICH ALTER FUNCTIONAL GENE NETWORKS, THUS PROVIDING A POSSIBLE EXPLANATION FOR CHRONIC PAIN ASSOCIATED BEHAVIORS. RESULTS: SNI OR SHAM SURGERY WHERE PERFORMED IN MALE CD1 MICE AT THREE MONTHS OF AGE. SIX MONTHS AFTER INJURY, WE PERFORMED TRANSCRIPTOME-WIDE SEQUENCING (RNASEQ), WHICH REVEALED 1147 DIFFERENTIALLY REGULATED TRANSCRIPTS IN THE PFC IN NERVE-INJURED VS. CONTROL MICE. CHANGES IN GENE EXPRESSION OCCURRED ACROSS A NUMBER OF FUNCTIONAL GENE CLUSTERS ENCODING CARDINAL BIOLOGICAL PROCESSES AS REVEALED BY INGENUITY PATHWAY ANALYSIS. SIGNIFICANTLY ALTERED BIOLOGICAL PROCESSES INCLUDED NEUROLOGICAL DISEASE, SKELETAL MUSCULAR DISORDERS, BEHAVIOR, AND PSYCHOLOGICAL DISORDERS. SEVERAL OF THE CHANGES DETECTED BY RNASEQ WERE VALIDATED BY RT-QPCR AND INCLUDED TRANSCRIPTS WITH KNOWN ROLES IN CHRONIC PAIN AND/OR NEURONAL PLASTICITY INCLUDING THE NMDA RECEPTOR (GLUTAMATE RECEPTOR, IONOTROPIC, NMDA; GRIN1), NEURITE OUTGROWTH (ROUNDABOUT 3; ROBO3), GLIOSIS (GLIAL FIBRILLARY ACIDIC PROTEIN; GFAP), VESICULAR RELEASE (SYNAPTOTAGMIN 2; SYT2), AND NEURONAL EXCITABILITY (VOLTAGE-GATED SODIUM CHANNEL, TYPE I; SCN1A). CONCLUSIONS: THIS STUDY USED AN UNBIASED APPROACH TO DOCUMENT LONG-TERM ALTERATIONS IN GENE EXPRESSION IN THE BRAIN FOLLOWING PERIPHERAL NERVE INJURY. WE PROPOSE THAT THESE CHANGES ARE MAINTAINED AS A MEMORY OF AN INSULT THAT IS TEMPORALLY AND SPATIALLY DISTANT FROM THE INITIAL INJURY. 2013 15 2300 25 EPIGENETIC REGULATION OF BDNF EXPRESSION IN THE PRIMARY SENSORY NEURONS AFTER PERIPHERAL NERVE INJURY: IMPLICATIONS IN THE DEVELOPMENT OF NEUROPATHIC PAIN. BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) IS KNOWN TO BE UP-REGULATED IN THE DORSAL ROOT GANGLION (DRG) AFTER PERIPHERAL NERVE INJURY, AND TO CONTRIBUTE TO NEUROPATHIC PAIN. HERE, WE FOUND THAT THERMAL HYPERALGESIA AND MECHANICAL ALLODYNIA AT DAY 7 POST-INJURY WERE INHIBITED ONLY WHEN ANTI-BDNF ANTIBODY WAS INTRATHECALLY ADMINISTRATED AT DAY 2 POST-INJURY. CONSISTENT WITH BEHAVIORAL RESULTS, WESTERN BLOT ANALYSIS SHOWED THAT THE EXPRESSION LEVELS OF BDNF PROTEIN IN THE SPINAL DORSAL HORN WERE MARKEDLY INDUCED DURING EARLY STAGE POST-INJURY. MOREOVER, THE MAXIMAL INCREASE IN BDNF MRNA EXPRESSION IN THE DRG WAS OBSERVED AT DAY 1 POST-INJURY, AND SIGNIFICANTLY ELEVATED LEVELS WERE SUSTAINED FOR AT LEAST 14 DAYS. FOUR OF FIVE BDNF MRNA TRANSCRIPTS WERE UP-REGULATED AFTER NERVE INJURY, AND THE MOST INDUCIBLE TRANSCRIPT WAS EXON I. USING A CHROMATIN IMMUNOPRECIPITATION (CHIP) ASSAY, WE FOUND THAT NERVE INJURY PROMOTES HISTONE H3 AND H4 ACETYLATION, TRANSCRIPTIONALLY ACTIVE MODIFICATIONS, AT BDNF PROMOTER I AT DAY 1 POST-INJURY, AND THE LEVELS OF HISTONE ACETYLATION REMAIN ELEVATED FOR AT LEAST 7 DAYS. TAKEN TOGETHER, OUR FINDINGS SUGGEST THAT AN INITIAL INCREASE IN BDNF EXON I EXPRESSION CONTROLLED BY EPIGENETIC MECHANISMS MIGHT HAVE A CRUCIAL ROLE IN THE DEVELOPMENT OF NEUROPATHIC PAIN. 2013 16 2452 28 EPIGENETIC SUPPRESSION OF POTASSIUM-CHLORIDE CO-TRANSPORTER 2 EXPRESSION IN INFLAMMATORY PAIN INDUCED BY COMPLETE FREUND'S ADJUVANT (CFA). BACKGROUND: MULTIPLE MECHANISMS CONTRIBUTE TO THE STIMULUS-EVOKED PAIN HYPERSENSITIVITY THAT MAY BE EXPERIENCED AFTER PERIPHERAL INFLAMMATION. PERSISTENT PATHOLOGICAL STIMULI IN MANY PAIN CONDITIONS AFFECT THE EXPRESSION OF CERTAIN GENES THROUGH EPIGENETIC ALTERNATIONS. THE MAIN PURPOSE OF OUR STUDY WAS TO INVESTIGATE THE ROLE OF EPIGENETIC MODIFICATION ON POTASSIUM-CHLORIDE CO-TRANSPORTER 2 (KCC2) GENE EXPRESSION IN THE PERSISTENCE OF INFLAMMATORY PAIN. METHODS: PERSISTENT INFLAMMATORY PAIN WAS INDUCED THROUGH THE INJECTION OF COMPLETE FREUND'S ADJUVANT (CFA) IN THE LEFT HIND PAW OF RATS. ACETYL-HISTONE H3 AND H4 LEVEL WAS DETERMINED BY CHROMATIN IMMUNOPRECIPITATION IN THE SPINAL DORSAL HORN. PAIN BEHAVIOUR AND INHIBITORY SYNAPTIC FUNCTION OF SPINAL CORD WERE DETERMINED BEFORE AND AFTER CFA INJECTION. KCC2 EXPRESSION WAS DETERMINED BY REAL TIME RT-PCR AND WESTERN BLOT. INTRATHECAL KCC2 SIRNA (2 MUG PER 10 MUL PER RAT) OR HDAC INHIBITOR (10 MUG PER 10 MUL PER RAT) WAS INJECTED ONCE DAILY FOR 3 DAYS BEFORE CFA INJECTION. RESULTS: PERSISTENT INFLAMMATORY PAIN EPIGENETICALLY SUPPRESSED KCC2 EXPRESSION THROUGH HISTONE DEACETYLASE (HDAC)-MEDIATED HISTONE HYPOACETYLATION, RESULTING IN DECREASED INHIBITORY SIGNALLING EFFICACY. KCC2 KNOCK-DOWN CAUSED BY INTRATHECAL ADMINISTRATION OF KCC2 SIRNA IN NAIVE RATS REDUCED KCC2 EXPRESSION IN THE SPINAL CORD, LEADING TO SENSITIZED PAIN BEHAVIOURS AND IMPAIRED INHIBITORY SYNAPTIC TRANSMISSION IN THEIR SPINAL CORDS. MOREOVER, INTRATHECAL HDAC INHIBITOR INJECTION IN CFA RATS INCREASED KCC2 EXPRESSION, PARTIALLY RESTORING THE SPINAL INHIBITORY SYNAPTIC TRANSMISSION AND RELIEVING THE SENSITIZED PAIN BEHAVIOUR. CONCLUSION: THESE FINDINGS SUGGEST THAT THE TRANSCRIPTION OF SPINAL KCC2 IS REGULATED BY HISTONE ACETYLATION EPIGENETICALLY FOLLOWING CFA. SIGNIFICANCE: PERSISTENT PAIN SUPPRESSES KCC2 EXPRESSION THROUGH HDAC-MEDIATED HISTONE HYPOACETYLATION AND CONSEQUENTLY IMPAIRS THE INHIBITORY FUNCTION OF INHIBITORY INTERNEURONS. DRUGS SUCH AS HDAC INHIBITORS THAT SUPPRESS THE INFLUENCES OF PERSISTENT PAIN ON THE EXPRESSION OF KCC2 MAY SERVE AS A NOVEL ANALGESIC. 2017 17 4138 34 MECHANISMS OF MICROGLIAL ACTIVATION IN MODELS OF INFLAMMATION AND HYPOXIA: IMPLICATIONS FOR CHRONIC INTERMITTENT HYPOXIA. CHRONIC INTERMITTENT HYPOXIA (CIH) IS A HALLMARK OF SLEEP APNOEA, A CONDITION ASSOCIATED WITH DIVERSE CLINICAL DISORDERS. CIH AND SLEEP APNOEA ARE CHARACTERIZED BY INCREASED REACTIVE OXYGEN SPECIES FORMATION, PERIPHERAL AND CNS INFLAMMATION, NEURONAL DEATH AND NEUROCOGNITIVE DEFICITS. FEW STUDIES HAVE EXAMINED THE ROLE OF MICROGLIA, THE RESIDENT CNS IMMUNE CELLS, IN MODELS OF CIH. THUS, LITTLE IS KNOWN CONCERNING THEIR DIRECT CONTRIBUTIONS TO NEUROPATHOLOGY OR THE CELLULAR MECHANISMS REGULATING THEIR ACTIVITIES DURING OR FOLLOWING PATHOLOGICAL CIH. IN THIS REVIEW, WE IDENTIFY GAPS IN KNOWLEDGE REGARDING CIH-INDUCED MICROGLIAL ACTIVATION, AND PROPOSE MECHANISMS BASED ON DATA FROM RELATED MODELS OF HYPOXIA AND/OR HYPOXIA-REOXYGENATION. CIH MAY DIRECTLY AFFECT MICROGLIA, OR MAY HAVE INDIRECT EFFECTS VIA THE PERIPHERY OR OTHER CNS CELLS. PERIPHERAL INFLAMMATION MAY INDIRECTLY ACTIVATE MICROGLIA VIA ENTRY OF PRO-INFLAMMATORY MOLECULES INTO THE CNS, AND/OR ACTIVATION OF VAGAL AFFERENTS THAT TRIGGER CNS INFLAMMATION. CIH-INDUCED RELEASE OF DAMAGE-ASSOCIATED MOLECULAR PATTERNS FROM INJURED CNS CELLS MAY ALSO ACTIVATE MICROGLIA VIA INTERACTIONS WITH PATTERN RECOGNITION RECEPTORS EXPRESSED ON MICROGLIA. FOR EXAMPLE, TOLL-LIKE RECEPTORS ACTIVATE MITOGEN-ACTIVATED PROTEIN KINASE/TRANSCRIPTION FACTOR PATHWAYS REQUIRED FOR MICROGLIAL INFLAMMATORY GENE EXPRESSION. ALTHOUGH EPIGENETIC EFFECTS FROM CIH HAVE NOT YET BEEN STUDIED IN MICROGLIA, POTENTIAL EPIGENETIC MECHANISMS IN MICROGLIAL REGULATION ARE DISCUSSED, INCLUDING MICRORNAS, HISTONE MODIFICATIONS AND DNA METHYLATION. EPIGENETIC EFFECTS CAN OCCUR DURING CIH, OR LONG AFTER IT HAS ENDED. A BETTER UNDERSTANDING OF CIH EFFECTS ON MICROGLIAL ACTIVITIES MAY BE IMPORTANT TO REVERSE CIH-INDUCED NEUROPATHOLOGY IN PATIENTS WITH SLEEP DISORDERED BREATHING. 2016 18 742 24 CANNABINOID CB2 RECEPTORS ARE UPREGULATED VIA BIVALENT HISTONE MODIFICATIONS AND CONTROL PRIMARY AFFERENT INPUT TO THE SPINAL CORD IN NEUROPATHIC PAIN. TYPE-2 CANNABINOID RECEPTORS (CB2, ENCODED BY THE CNR2 GENE) ARE MAINLY EXPRESSED IN IMMUNE CELLS, AND CB2 AGONISTS NORMALLY HAVE NO ANALGESIC EFFECT. HOWEVER, NERVE INJURY UPREGULATES CB2 IN THE DORSAL ROOT GANGLION (DRG), FOLLOWING WHICH CB2 STIMULATION REDUCES NEUROPATHIC PAIN. IT IS UNCLEAR HOW NERVE INJURY INCREASES CB2 EXPRESSION OR HOW CB2 ACTIVITY IS TRANSFORMED IN NEUROPATHIC PAIN. IN THIS STUDY, IMMUNOBLOTTING SHOWED THAT SPINAL NERVE LIGATION (SNL) INDUCED A DELAYED AND SUSTAINED INCREASE IN CB2 EXPRESSION IN THE DRG AND DORSAL SPINAL CORD SYNAPTOSOMES. RNASCOPE IN SITU HYBRIDIZATION ALSO SHOWED THAT SNL SUBSTANTIALLY INCREASED CB2 MRNA LEVELS, MOSTLY IN MEDIUM AND LARGE DRG NEURONS. FURTHERMORE, WE FOUND THAT THE SPECIFIC CB2 AGONIST JWH-133 SIGNIFICANTLY INHIBITS THE AMPLITUDE OF DORSAL ROOT-EVOKED GLUTAMATERGIC EXCITATORY POSTSYNAPTIC CURRENTS IN SPINAL DORSAL HORN NEURONS IN SNL RATS, BUT NOT IN SHAM CONTROL RATS; INTRATHECAL INJECTION OF JWH-133 REVERSED PAIN HYPERSENSITIVITY IN SNL RATS, BUT HAD NO EFFECT IN SHAM CONTROL RATS. IN ADDITION, CHROMATIN IMMUNOPRECIPITATION-QPCR ANALYSIS SHOWED THAT SNL INCREASED ENRICHMENT OF TWO ACTIVATING HISTONE MARKS (H3K4ME3 AND H3K9AC) AND DIMINISHED OCCUPANCY OF TWO REPRESSIVE HISTONE MARKS (H3K9ME2 AND H3K27ME3) AT THE CNR2 PROMOTER IN THE DRG. IN CONTRAST, SNL HAD NO EFFECT ON DNA METHYLATION LEVELS AROUND THE CNR2 PROMOTER. OUR FINDINGS SUGGEST THAT PERIPHERAL NERVE INJURY PROMOTES CB2 EXPRESSION IN PRIMARY SENSORY NEURONS VIA EPIGENETIC BIVALENT HISTONE MODIFICATIONS AND THAT CB2 ACTIVATION REDUCES NEUROPATHIC PAIN BY ATTENUATING NOCICEPTIVE TRANSMISSION FROM PRIMARY AFFERENT NERVES TO THE SPINAL CORD. 2022 19 5657 25 SEX-DEPENDENT PRONOCICEPTIVE ROLE OF SPINAL ALPHA(5) -GABA(A) RECEPTOR AND ITS EPIGENETIC REGULATION IN NEUROPATHIC RODENTS. EXTRASYNAPTIC ALPHA(5) -SUBUNIT CONTAINING GABA(A) (ALPHA(5) -GABA(A) ) RECEPTORS PARTICIPATE IN CHRONIC PAIN. PREVIOUSLY, WE REPORTED A SEX DIFFERENCE IN THE ACTION OF ALPHA(5) -GABA(A) RECEPTORS IN DYSFUNCTIONAL PAIN. HOWEVER, THE UNDERLYING MECHANISMS REMAIN UNKNOWN. THE AIM OF THIS STUDY WAS TO EXAMINE THIS SEXUAL DIMORPHISM IN NEUROPATHIC RODENTS AND THE MECHANISMS INVOLVED. FEMALE AND MALE WISTAR RATS OR ICR MICE WERE SUBJECTED TO NERVE INJURY FOLLOWED BY ALPHA(5) -GABA(A) RECEPTOR INVERSE AGONIST INTRATHECAL ADMINISTRATION, L-655,708. THE DRUG PRODUCED AN ANTIALLODYNIC EFFECT IN NERVE-INJURED FEMALE RATS AND MICE, AND A LOWER EFFECT IN MALES. WE HYPOTHESIZED THAT CHANGES IN ALPHA(5) -GABA(A) RECEPTOR, PROBABLY INFLUENCED BY HORMONAL AND EPIGENETIC STATUS, MIGHT UNDERLIE THIS SEX DIFFERENCE. THUS, WE PERFORMED QPCR AND WESTERN BLOT. NERVE INJURY INCREASED ALPHA(5) -GABA(A) MRNA AND PROTEIN IN FEMALE DORSAL ROOT GANGLIA (DRG) AND DECREASED THEM IN DRG AND SPINAL CORD OF MALES. TO INVESTIGATE THE HORMONAL INFLUENCE OVER ALPHA(5) -GABA(A) RECEPTOR ACTIONS, WE PERFORMED NERVE INJURY TO OVARIECTOMIZED RATS AND RECONSTITUTED THEM WITH 17BETA-ESTRADIOL (E2). OVARIECTOMY ABROGATED L-655,708 ANTIALLODYNIC EFFECT AND E2 RESTORED IT. OVARIECTOMY DECREASED ALPHA(5) -GABA(A) RECEPTOR AND ESTROGEN RECEPTOR ALPHA PROTEIN IN DRG OF NEUROPATHIC FEMALE RATS, WHILE E2 ENHANCED THEM. SINCE DNA METHYLATION MIGHT CONTRIBUTE TO ALPHA(5) -GABA(A) RECEPTOR DOWN-REGULATION IN MALES, WE EXAMINED CPG ISLAND DNA METHYLATION OF ALPHA(5) -GABA(A) RECEPTOR CODING GENE THROUGH PYROSEQUENCING. NERVE INJURY INCREASED METHYLATION IN MALE, BUT NOT FEMALE RATS. PHARMACOLOGICAL INHIBITION OF DNA METHYLTRANSFERASES INCREASED ALPHA(5) -GABA(A) RECEPTOR AND ENABLED L-655,708 ANTINOCICEPTIVE EFFECT IN MALE RATS. THESE RESULTS SUGGEST THAT ALPHA(5) -GABA(A) RECEPTOR IS A SUITABLE TARGET TO TREAT CHRONIC PAIN IN FEMALES. 2021 20 3319 28 HISTONE ACETYLATION AND HISTONE DEACETYLATION IN NEUROPATHIC PAIN: AN UNRESOLVED PUZZLE? CHRONIC PAIN IS BROADLY CLASSIFIED INTO SOMATIC, VISCERAL OR NEUROPATHIC PAIN DEPENDING UPON THE LOCATION AND EXTENT OF PAIN PERCEPTION. EVIDENCES FROM DIFFERENT ANIMAL STUDIES SUGGEST THAT INFLAMMATORY OR NEUROPATHIC PAIN IS ASSOCIATED WITH ALTERED ACETYLATION AND DEACETYLATION OF HISTONE PROTEINS, WHICH RESULT IN ABNORMAL TRANSCRIPTION OF NOCICEPTIVE PROCESSING GENES. THERE HAVE BEEN A NUMBER OF STUDIES INDICATING THAT NERVE INJURY UP-REGULATES HISTONE DEACETYLASE ENZYMES, WHICH LEADS TO INCREASED HISTONE DEACETYLATION AND INDUCE CHRONIC PAIN. TREATMENT WITH HISTONE DEACETYLASE INHIBITORS RELIEVES PAIN BY NORMALIZING NERVE INJURY-INDUCED DOWN REGULATION OF METABOTROPIC GLUTAMATE RECEPTORS, GLUTAMATE TRANSPORTERS, GLUTAMIC ACID DECARBOXYLASE 65, NEURON RESTRICTIVE SILENCER FACTOR AND SERUM AND GLUCOCORTICOID INDUCIBLE KINASE 1. ON THE OTHER HAND, A FEW STUDIES REFER TO INCREASED EXPRESSION OF HISTONE ACETYLASE ENZYMES IN RESPONSE TO NERVE INJURY THAT PROMOTES HISTONE ACETYLATION LEADING TO PAIN INDUCTION. TREATMENT WITH HISTONE ACETYL TRANSFERASE INHIBITORS HAVE BEEN REPORTED TO RELIEVE CHRONIC PAIN BY BLOCKING THE UP-REGULATION OF CHEMOKINES AND CYCLOOXYGENASE-2, THE CRITICAL FACTORS ASSOCIATED WITH HISTONE ACETYLATION-INDUCED PAIN. THE PRESENT REVIEW DESCRIBES THE DUAL ROLE OF HISTONE ACETYLATION/DEACETYLATION IN DEVELOPMENT OR ATTENUATION OF NEUROPATHIC PAIN ALONG WITH THE UNDERLYING MECHANISMS. 2017