1 3955 144 LONG MARCH TOWARD SAFE AND EFFECTIVE ANALGESIA BY ENHANCING GENE EXPRESSION OF KCC2: FIRST STEPS TAKEN. LOW INTRANEURONAL CHLORIDE IN SPINAL CORD DORSAL HORN PAIN RELAY NEURONS IS CRITICAL FOR PHYSIOLOGIC TRANSMISSION OF PRIMARY PAIN AFFERENTS BECAUSE LOW INTRANEURONAL CHLORIDE DICTATES WHETHER GABA-ERGIC AND GLYCIN-ERGIC NEUROTRANSMISSION IS INHIBITORY. IF THE NEURONAL CHLORIDE ELEVATES TO PATHOLOGIC LEVELS, THEN SPINAL CORD PRIMARY PAIN RELAY BECOMES LEAKY AND EXHIBITS THE BEHAVIORAL HALLMARKS OF PATHOLOGIC PAIN, NAMELY HYPERSENSITIVITY AND ALLODYNIA. LOW CHLORIDE IN SPINAL CORD DORSAL HORN NEURONS IS MAINTAINED BY PROPER GENE EXPRESSION OF KCC2 AND SUSTAINED PHYSIOLOGIC FUNCTION OF THE KCC2 CHLORIDE EXTRUDING ELECTRONEUTRAL TRANSPORTER. PERIPHERAL NERVE INJURY AND OTHER FORMS OF NEURAL INJURY EVOKE GREATLY DIMINISHED KCC2 GENE EXPRESSION AND SUBSEQUENT CORRUPTION OF INHIBITORY NEUROTRANSMISSION IN THE SPINAL CORD DORSAL HORN, THUS CAUSING DERAILMENT OF THE GATE FUNCTION FOR PAIN. HERE I REVIEW KEY DISCOVERIES THAT HAVE HELPED US UNDERSTAND THESE FUNDAMENTALS, AND FOCUS ON RECENT INSIGHTS RELATING TO THE DISCOVERY OF KCC2 GENE EXPRESSION ENHANCING COMPOUNDS VIA COMPOUND SCREENS IN NEURONS. ONE SUCH STUDY CHARACTERIZED THE KINASE INHIBITOR, KENPAULLONE, MORE IN-DEPTH, REVEALING ITS FUNCTION AS A ROBUST AND LONG-LASTING ANALGESIC IN PRECLINICAL MODELS OF NERVE INJURY AND CANCER BONE PAIN, ALSO ELUCIDATING ITS MECHANISM OF ACTION VIA GSK3BETA INHIBITION, DIMINISHING DELTA-CATENIN PHOSPHORYLATION, AND FACILITATING ITS NUCLEAR TRANSFER AND SUBSEQUENT ENHANCEMENT OF KCC2 GENE EXPRESSION BY DE-REPRESSING KAISO EPIGENETIC TRANSCRIPTIONAL REGULATOR. FUTURE DIRECTIONS RE KCC2 GENE EXPRESSION ENHANCEMENT ARE DISCUSSED, NAMELY COMBINATION WITH OTHER ANALGESICS AND ANALGESIC METHODS, SUCH AS SPINAL CORD STIMULATION AND ELECTROACUPUNCTURE, GENE THERAPY, AND LEVERAGING KCC2 GENE EXPRESSION-ENHANCING NANOMATERIALS. 2022 2 6139 33 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 3 3194 37 HDAC INHIBITORS ATTENUATE THE DEVELOPMENT OF HYPERSENSITIVITY IN MODELS OF NEUROPATHIC PAIN. HISTONE DEACETYLASE INHIBITORS (HDACIS) INTERFERE WITH THE EPIGENETIC PROCESS OF HISTONE ACETYLATION AND ARE KNOWN TO HAVE ANALGESIC PROPERTIES IN MODELS OF CHRONIC INFLAMMATORY PAIN. THE AIM OF THIS STUDY WAS TO DETERMINE WHETHER THESE COMPOUNDS COULD ALSO AFFECT NEUROPATHIC PAIN. DIFFERENT CLASS I HDACIS WERE DELIVERED INTRATHECALLY INTO RAT SPINAL CORD IN MODELS OF TRAUMATIC NERVE INJURY AND ANTIRETROVIRAL DRUG-INDUCED PERIPHERAL NEUROPATHY (STAVUDINE, D4T). MECHANICAL AND THERMAL HYPERSENSITIVITY WAS ATTENUATED BY 40% TO 50% AS A RESULT OF HDACI TREATMENT, BUT ONLY IF STARTED BEFORE ANY INSULT. THE DRUGS GLOBALLY INCREASED HISTONE ACETYLATION IN THE SPINAL CORD, BUT APPEARED TO HAVE NO MEASURABLE EFFECTS IN RELEVANT DORSAL ROOT GANGLIA IN THIS TREATMENT PARADIGM, SUGGESTING THAT ANY POTENTIAL MECHANISM SHOULD BE SOUGHT IN THE CENTRAL NERVOUS SYSTEM. MICROARRAY ANALYSIS OF DORSAL CORD RNA REVEALED THE SIGNATURE OF THE SPECIFIC COMPOUND USED (MS-275) AND SUGGESTED THAT ITS MAIN EFFECT WAS MEDIATED THROUGH HDAC1. TAKEN TOGETHER, THESE DATA SUPPORT A ROLE FOR HISTONE ACETYLATION IN THE EMERGENCE OF NEUROPATHIC PAIN. 2013 4 5865 28 SUPPRESSION OF HDAC2 IN SPINAL CORD ALLEVIATES MECHANICAL HYPERALGESIA AND RESTORES KCC2 EXPRESSION IN A RAT MODEL OF BONE CANCER PAIN. EPIGENETIC MODULATION PARTICIPATES IN THE MECHANISM OF MULTIPLE TYPES OF PATHOLOGICAL PAIN, SO TARGETING THE INVOLVED REGULATORS MAY BE A PROMISING STRATEGY FOR PAIN TREATMENT. OUR PREVIOUS RESEARCH IDENTIFIED THE ANALGESIC EFFECT OF THE HISTONE DEACETYLASE (HDAC) INHIBITOR TRICHOSTATIN A (TSA) ON MECHANICAL HYPERALGESIA IN A RAT MODEL OF BONE CANCER PAIN (BCP) VIA RESTORATION OF MU-OPIOID RECEPTOR (MOR) EXPRESSION. HOWEVER, THE SPECIFIC TYPES OF HDACS CONTRIBUTING TO BCP HAVE NOT BEEN EXPLORED. THE PRESENT STUDY INVESTIGATED THE EXPRESSION PATTERN OF SOME COMMON HDACS AND FOUND THAT HDAC2 WAS UP-REGULATED IN A TIME-DEPENDENT MANNER IN THE LUMBAR SPINAL CORD OF BCP RATS. TSA APPLICATION SUPPRESSED HDAC2 EXPRESSION IN CULTURED PC12 CELLS AND REVERSED THE AUGMENTED HDAC2 IN BCP RATS. AN RNA-INTERFERING STRATEGY CONFIRMED THE ESSENTIAL ROLE OF HDAC2 IN THE MODULATION OF MECHANICAL HYPERALGESIA FOLLOWING TUMOR CELL INOCULATION, AND WE FURTHER EXAMINED ITS POSSIBLE DOWNSTREAM TARGETS. NOTABLY, HDAC2 KNOCK-DOWN DID NOT RESTORE MOR EXPRESSION, BUT IT ROBUSTLY REVERSED THE DOWN-REGULATION OF POTASSIUM-CHLORIDE COTRANSPORTER 2 (KCC2). THE IMPAIRED KCC2 EXPRESSION IS A VITAL MECHANISM OF MANY TYPES OF PATHOLOGICAL PAIN. THEREFORE, OUR RESULTS DEMONSTRATED THAT HDAC2 IN SPINAL CORD CONTRIBUTED TO THE MECHANICAL HYPERALGESIA IN BCP RATS, AND THIS EFFECT MAY BE ASSOCIATED WITH KCC2 MODULATION. 2018 5 4619 30 NERVE TRAUMA-CAUSED DOWNREGULATION OF OPIOID RECEPTORS IN PRIMARY AFFERENT NEURONS: MOLECULAR MECHANISMS AND POTENTIAL MANAGEMENTS. NEUROPATHIC PAIN IS THE MOST COMMON CLINICAL DISORDER DESTROYING THE QUALITY OF PATIENT LIFE AND LEADING TO A MARKED ECONOMIC AND SOCIAL BURDEN. OPIOIDS ARE STILL LAST OPTION FOR PHARMACOLOGICAL TREATMENT OF THIS DISORDER, BUT THEIR ANTINOCICEPTIVE EFFECTS ARE LIMITED IN PART DUE TO THE DOWNREGULATION OF OPIOID RECEPTORS IN THE PRIMARY AFFERENT NEURONS AFTER PERIPHERAL NERVE TRAUMA. HOW THIS DOWNREGULATION OCCURS IS NOT COMPLETELY UNDERSTOOD, BUT RECENT STUDIES HAVE DEMONSTRATED THAT PERIPHERAL NERVE TRAUMA DRIVES THE ALTERATIONS IN EPIGENETIC MODIFICATIONS (INCLUDING DNA METHYLATION, HISTONE METHYLATION AND MCIRORNAS), EXPRESSION OF TRANSCRIPTION FACTORS, POST-TRANSCRIPTIONAL MODIFICATIONS (E.G., RNA METHYLATION) AND PROTEIN TRANSLATION INITIATION IN THE NEURONS OF NERVE TRAUMA-RELATED DORSAL ROOT GANGLION (DRG) AND THAT THESE ALTERNATIONS MAY BE ASSOCIATED WITH NERVE TRAUMA-CAUSED DOWNREGULATION OF DRG OPIOID RECEPTORS. THIS REVIEW PRESENTS HOW OPIOID RECEPTORS ARE DOWNREGULATED IN THE DRG AFTER PERIPHERAL NERVE TRAUMA, SPECIFICALLY FOCUSING ON DISTINCT MOLECULAR MECHANISMS UNDERLYING TRANSCRIPTIONAL AND TRANSLATIONAL PROCESSES. THIS REVIEW ALSO DISCUSSES HOW THIS DOWNREGULATION CONTRIBUTES TO THE INDUCTION AND MAINTENANCE OF NEUROPATHIC PAIN. A DEEPER UNDERSTANDING OF THESE MOLECULAR MECHANISMS LIKELY PROVIDES A NOVEL AVENUE FOR PREVENTION AND/OR TREATMENT OF NEUROPATHIC PAIN. 2021 6 2179 32 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 2061 30 EPIGENETIC CONTROL OF HYPERSENSITIVITY IN CHRONIC INFLAMMATORY PAIN BY THE DE NOVO DNA METHYLTRANSFERASE DNMT3A2. CHRONIC PAIN IS A PATHOLOGICAL MANIFESTATION OF NEURONAL PLASTICITY SUPPORTED BY ALTERED GENE TRANSCRIPTION IN SPINAL CORD NEURONS THAT RESULTS IN LONG-LASTING HYPERSENSITIVITY. RECENTLY, THE CONCEPT THAT EPIGENETIC REGULATORS MIGHT BE IMPORTANT IN PATHOLOGICAL PAIN HAS EMERGED, BUT A CLEAR UNDERSTANDING OF THE MOLECULAR PLAYERS INVOLVED IN THE PROCESS IS STILL LACKING. IN THIS STUDY, WE LINKED DNMT3A2, A SYNAPTIC ACTIVITY-REGULATED DE NOVO DNA METHYLTRANSFERASE, TO CHRONIC INFLAMMATORY PAIN. WE OBSERVED THAT DNMT3A2 LEVELS ARE INCREASED IN THE SPINAL CORD OF ADULT MICE FOLLOWING PLANTAR INJECTION OF COMPLETE FREUND'S ADJUVANT, AN IN VIVO MODEL OF CHRONIC INFLAMMATORY PAIN. IN VIVO KNOCKDOWN OF DNMT3A2 EXPRESSION IN DORSAL HORN NEURONS BLUNTED THE INDUCTION OF GENES TRIGGERED BY COMPLETE FREUND'S ADJUVANT INJECTION. AMONG THE GENES WHOSE TRANSCRIPTION WAS FOUND TO BE INFLUENCED BY DNMT3A2 EXPRESSION IN THE SPINAL CORD IS PTGS2, ENCODING FOR COX-2, A PRIME MEDIATOR OF PAIN PROCESSING. LOWERING THE LEVELS OF DNMT3A2 PREVENTED THE ESTABLISHMENT OF LONG-LASTING INFLAMMATORY HYPERSENSITIVITY. THESE RESULTS IDENTIFY DNMT3A2 AS AN IMPORTANT EPIGENETIC REGULATOR NEEDED FOR THE ESTABLISHMENT OF CENTRAL SENSITIZATION. TARGETING EXPRESSION OR FUNCTION OF DNMT3A2 MAY BE SUITABLE FOR THE TREATMENT OF CHRONIC PAIN. 2019 8 3319 25 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 9 2785 34 EZH2 REGULATES SPINAL NEUROINFLAMMATION IN RATS WITH NEUROPATHIC PAIN. ALTERATION IN GENE EXPRESSION ALONG THE PAIN SIGNALING PATHWAY IS A KEY MECHANISM CONTRIBUTING TO THE GENESIS OF NEUROPATHIC PAIN. ACCUMULATING STUDIES HAVE SHOWN THAT EPIGENETIC REGULATION PLAYS A CRUCIAL ROLE IN NOCICEPTIVE PROCESS IN THE SPINAL DORSAL HORN. IN THIS PRESENT STUDY, WE INVESTIGATED THE ROLE OF ENHANCER OF ZESTE HOMOLOG-2 (EZH2), A SUBUNIT OF THE POLYCOMB REPRESSIVE COMPLEX 2, IN THE SPINAL DORSAL HORN IN THE GENESIS OF NEUROPATHIC PAIN IN RATS INDUCED BY PARTIAL SCIATIC NERVE LIGATION. EZH2 IS A HISTONE METHYLTRANSFERASE, WHICH CATALYZES THE METHYLATION OF HISTONE H3 ON K27 (H3K27), RESULTING IN GENE SILENCING. WE FOUND THAT LEVELS OF EZH2 AND TRI-METHYLATED H3K27 (H3K27TM) IN THE SPINAL DORSAL HORN WERE INCREASED IN RATS WITH NEUROPATHIC PAIN ON DAY 3 AND DAY 10 POST NERVE INJURIES. EZH2 WAS PREDOMINANTLY EXPRESSED IN NEURONS IN THE SPINAL DORSAL HORN UNDER NORMAL CONDITIONS. THE NUMBER OF NEURONS WITH EZH2 EXPRESSION WAS INCREASED AFTER NERVE INJURY. MORE STRIKINGLY, NERVE INJURY DRASTICALLY INCREASED THE NUMBER OF MICROGLIA WITH EZH2 EXPRESSION BY MORE THAN SEVENFOLD. INTRATHECAL INJECTION OF THE EZH2 INHIBITOR ATTENUATED THE DEVELOPMENT AND MAINTENANCE OF MECHANICAL AND THERMAL HYPERALGESIA IN RATS WITH NERVE INJURY. SUCH ANALGESIC EFFECTS WERE CONCURRENTLY ASSOCIATED WITH THE REDUCED LEVELS OF EZH2, H3K27TM, IBA1, GFAP, TNF-ALPHA, IL-1BETA, AND MCP-1 IN THE SPINAL DORSAL HORN IN RATS WITH NERVE INJURY. OUR RESULTS HIGHLY SUGGEST THAT TARGETING THE EZH2 SIGNALING PATHWAY COULD BE AN EFFECTIVE APPROACH FOR THE MANAGEMENT OF NEUROPATHIC PAIN. 2017 10 4614 37 NERVE EXCITABILITY AND NEUROPATHIC PAIN IS REDUCED BY BET PROTEIN INHIBITION AFTER SPARED NERVE INJURY. NEUROPATHIC PAIN IS A COMMON DISABILITY PRODUCED BY ENHANCED NEURONAL EXCITABILITY AFTER NERVOUS SYSTEM INJURY. THE PATHOPHYSIOLOGICAL CHANGES THAT UNDERLIE THE GENERATION AND MAINTENANCE OF NEUROPATHIC PAIN REQUIRE MODIFICATIONS OF TRANSCRIPTIONAL PROGRAMS. IN PARTICULAR, THERE IS AN INDUCTION OF PRO-INFLAMMATORY NEUROMODULATORS LEVELS, AND CHANGES IN THE EXPRESSION OF ION CHANNELS AND OTHER FACTORS INTERVENING IN THE DETERMINATION OF THE MEMBRANE POTENTIAL IN NEURONAL CELLS. WE HAVE PREVIOUSLY FOUND THAT INHIBITION OF THE BET PROTEINS EPIGENETIC READERS REDUCED NEUROINFLAMMATION AFTER SPINAL CORD INJURY. WITHIN THE PRESENT STUDY WE AIMED TO DETERMINE IF BET PROTEIN INHIBITION MAY ALSO AFFECT NEUROINFLAMMATION AFTER A PERIPHERAL NERVE INJURY, AND IF THIS WOULD BENEFICIALLY ALTER NEURONAL EXCITABILITY AND NEUROPATHIC PAIN. FOR THIS PURPOSE, C57BL/6 FEMALE MICE UNDERWENT SPARED NERVE INJURY (SNI), AND WERE TREATED WITH THE BET INHIBITOR JQ1, OR VEHICLE. ELECTROPHYSIOLOGICAL AND ALGESIMETRY TESTS WERE PERFORMED ON THESE MICE. WE ALSO DETERMINED THE EFFECTS OF JQ1 TREATMENT AFTER INJURY ON NEUROINFLAMMATION, AND THE EXPRESSION OF NEURONAL COMPONENTS IMPORTANT FOR THE MAINTENANCE OF AXON MEMBRANE POTENTIAL. WE FOUND THAT TREATMENT WITH JQ1 AFFECTED NEURONAL EXCITABILITY AND MECHANICAL HYPERALGESIA AFTER SNI IN MICE. BET PROTEIN INHIBITION REGULATED CYTOKINE EXPRESSION AND REDUCED MICROGLIAL REACTIVITY AFTER INJURY. IN ADDITION, JQ1 TREATMENT ALTERED THE EXPRESSION OF SCN3A, SCN9A, KCNA1, KCNQ2, KCNQ3, HCN1 AND HCN2 ION CHANNELS, AS WELL AS THE EXPRESSION OF THE NA(+)/K(+) ATPASE PUMP SUBUNITS. IN CONCLUSION, BOTH, ALTERATION OF INFLAMMATION, AND NEURONAL TRANSCRIPTION, COULD BE THE RESPONSIBLE EPIGENETIC MECHANISMS FOR THE REDUCTION OF EXCITABILITY AND HYPERALGESIA OBSERVED AFTER BET INHIBITION. INHIBITION OF BET PROTEINS IS A PROMISING THERAPY FOR REDUCING NEUROPATHIC PAIN AFTER NEURAL INJURY. PERSPECTIVE: NEUROPATHIC PAIN IS A COMMON DISABILITY PRODUCED BY ENHANCED NEURONAL EXCITABILITY AFTER NERVOUS SYSTEM INJURY. THE UNDERLYING PATHOPHYSIOLOGICAL CHANGES REQUIRE MODIFICATIONS OF TRANSCRIPTIONAL PROGRAMS. THIS STUDY NOTES THAT INHIBITION OF BET PROTEINS IS A PROMISING THERAPY FOR REDUCING NEUROPATHIC PAIN AFTER NEURAL INJURY. 2021 11 2310 34 EPIGENETIC REGULATION OF CHRONIC PAIN. CHRONIC PAIN ARISING FROM PERIPHERAL INFLAMMATION AND TISSUE OR NERVE INJURY IS A COMMON CLINICAL SYMPTOM. ALTHOUGH INTENSIVE RESEARCH ON THE NEUROBIOLOGICAL MECHANISMS OF CHRONIC PAIN HAS BEEN CARRIED OUT DURING PREVIOUS DECADES, THIS DISORDER IS STILL POORLY MANAGED BY CURRENT DRUGS SUCH AS OPIOIDS AND NONSTEROIDAL ANTI-INFLAMMATORY DRUGS. INFLAMMATION, TISSUE INJURY AND/OR NERVE INJURY-INDUCED CHANGES IN GENE EXPRESSION IN SENSORY NEURONS OF THE DORSAL ROOT GANGLION, SPINAL CORD DORSAL HORN AND PAIN-ASSOCIATED BRAIN REGIONS ARE THOUGHT TO PARTICIPATE IN CHRONIC PAIN GENESIS; HOWEVER, HOW THESE CHANGES OCCUR IS STILL ELUSIVE. EPIGENETIC MODIFICATIONS INCLUDING DNA METHYLATION AND COVALENT HISTONE MODIFICATIONS CONTROL GENE EXPRESSION. RECENT STUDIES HAVE SHOWN THAT PERIPHERAL NOXIOUS STIMULATION CHANGES DNA METHYLATION AND HISTONE MODIFICATIONS AND THAT THESE CHANGES MAY BE RELATED TO THE INDUCTION OF PAIN HYPERSENSITIVITY UNDER CHRONIC PAIN CONDITIONS. THIS REVIEW SUMMARIZES THE CURRENT KNOWLEDGE AND PROGRESS IN EPIGENETIC RESEARCH IN CHRONIC PAIN AND DISCUSSES THE POTENTIAL ROLE OF EPIGENETIC MODIFICATIONS AS THERAPEUTIC ANTINOCICEPTIVE TARGETS IN THIS DISORDER. 2015 12 2452 36 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 13 3141 29 GLOBAL GENE EXPRESSION AND CHROMATIN ACCESSIBILITY OF THE PERIPHERAL NERVOUS SYSTEM IN ANIMAL MODELS OF PERSISTENT PAIN. BACKGROUND: EFFORTS TO UNDERSTAND GENETIC VARIABILITY INVOLVED IN AN INDIVIDUAL'S SUSCEPTIBILITY TO CHRONIC PAIN SUPPORT A ROLE FOR UPSTREAM REGULATION BY EPIGENETIC MECHANISMS. METHODS: TO EXAMINE THE TRANSCRIPTOMIC AND EPIGENETIC BASIS OF CHRONIC PAIN THAT RESIDES IN THE PERIPHERAL NERVOUS SYSTEM, WE USED RNA-SEQ AND ATAC-SEQ OF THE RAT DORSAL ROOT GANGLION (DRG) TO IDENTIFY NOVEL MOLECULAR PATHWAYS ASSOCIATED WITH PAIN HYPERSENSITIVITY IN TWO WELL-STUDIED PERSISTENT PAIN MODELS INDUCED BY CHRONIC CONSTRICTION INJURY (CCI) OF THE SCIATIC NERVE AND INTRA-PLANTAR INJECTION OF COMPLETE FREUND'S ADJUVANT (CFA) IN RATS. RESULTS: OUR RNA-SEQ STUDIES IDENTIFY A VARIETY OF BIOLOGICAL PROCESS RELATED TO SYNAPSE ORGANIZATION, MEMBRANE POTENTIAL, TRANSMEMBRANE TRANSPORT, AND ION BINDING. INTERESTINGLY, GENES THAT ENCODE TRANSCRIPTIONAL REGULATORS WERE DISPROPORTIONATELY DOWNREGULATED IN BOTH MODELS. OUR ATAC-SEQ DATA PROVIDE A COMPREHENSIVE MAP OF CHROMATIN ACCESSIBILITY CHANGES IN THE DRG. A TOTAL OF 1123 REGIONS SHOWED CHANGES IN CHROMATIN ACCESSIBILITY IN ONE OR BOTH MODELS WHEN COMPARED TO THE NAIVE AND 31 SHARED DIFFERENTIALLY ACCESSIBLE REGIONS (DAR)S. FUNCTIONAL ANNOTATION OF THE DARS IDENTIFIED DISPARATE MOLECULAR FUNCTIONS ENRICHED FOR EACH PAIN MODEL WHICH SUGGESTS THAT CHROMATIN STRUCTURE MAY BE ALTERED DIFFERENTLY FOLLOWING SCIATIC NERVE INJURY AND HIND PAW INFLAMMATION. MOTIF ANALYSIS IDENTIFIED 17 DNA SEQUENCES KNOWN TO BIND TRANSCRIPTION FACTORS IN THE CCI DARS AND 33 IN THE CFA DARS. TWO MOTIFS WERE SIGNIFICANTLY ENRICHED IN BOTH MODELS. CONCLUSIONS: OUR IMPROVED UNDERSTANDING OF THE CHANGES IN CHROMATIN ACCESSIBILITY THAT OCCUR IN CHRONIC PAIN STATES MAY IDENTIFY REGULATORY GENOMIC ELEMENTS THAT PLAY ESSENTIAL ROLES IN MODULATING GENE EXPRESSION IN THE DRG. 2021 14 1126 31 COMPLEX REGULATION OF THE REGULATOR OF SYNAPTIC PLASTICITY HISTONE DEACETYLASE 2 IN THE RODENT DORSAL HORN AFTER PERIPHERAL INJURY. HISTONE DEACETYLASES (HDACS), HDAC2 IN PARTICULAR, HAVE BEEN SHOWN TO REGULATE VARIOUS FORMS OF LEARNING AND MEMORY. SINCE COGNITIVE PROCESSES SHARE MECHANISMS WITH SPINAL NOCICEPTIVE SIGNALLING, WE DECIDED TO INVESTIGATE THE HDAC2 EXPRESSION IN THE DORSAL HORN AFTER PERIPHERAL INJURY. USING IMMUNOHISTOCHEMISTRY, WE FOUND THAT SPINAL HDAC2 WAS MAINLY SEEN IN NEURONS AND ASTROCYTES, WITH NEURONAL EXPRESSION IN NAIVE TISSUE 2.6 TIMES GREATER THAN THAT IN ASTROCYTES. CYSTEINE (S)-NITROSYLATION OF HDAC2 RELEASES HDAC2 GENE SILENCING AND IS CONTROLLED BY NITRIC OXIDE (NO). A DURATION OF 48 H AFTER INTRAPLANTAR INJECTION OF COMPLETE FREUND'S ADJUVANT, THERE WAS AN IPSILATERAL INCREASE IN THE MOST IMPORTANT NO-PRODUCING ENZYME IN PAIN STATES, NITRIC OXIDE SYNTHASE (NNOS), ACCOMPANIED BY AN INCREASE IN HDAC2 S-NITROSYLATION. MOREOVER, A SUBSET OF NNOS-POSITIVE NEURONS EXPRESSED CFOS, A KNOWN TARGET OF HDAC2, SUGGESTING THAT DEREPRESSION OF CFOS EXPRESSION FOLLOWING HDAC2 S-NITROSYLATION MIGHT OCCUR AFTER NOXIOUS STIMULATION. WE SAW NO CHANGE IN GLOBAL HDAC2 EXPRESSION IN BOTH SHORT- AND LONG-TERM PAIN STATES. HOWEVER, HDAC2 WAS INCREASED IN ASTROCYTES 7 DAYS AFTER NEUROPATHIC INJURY SUGGESTING THAT HDAC2 MIGHT INHIBIT ASTROCYTIC GENE EXPRESSION IN NEUROPATHIC PAIN STATES. ALL TOGETHER, OUR RESULTS INDICATE THAT THE EPIGENETIC REGULATION OF TRANSCRIPTIONAL PROGRAMMES IN THE DORSAL HORN AFTER INJURY IS CELL SPECIFIC. MOREOVER, THE PROMINENT ROLE OF NO IN PERSISTENT PAIN STATES SUGGESTS THAT HDAC2 S-NITROSYLATION COULD PLAY A CRUCIAL ROLE IN THE REGULATION OF GENE EXPRESSION LEADING TO HYPERSENSITIVITY. OUR MANUSCRIPT DESCRIBES FOR THE FIRST TIME THE REGULATION OF THE MEMORY REGULATOR HISTONE DEACETYLASE 2 (HDAC2) IN THE SUPERFICIAL DORSAL HORN OF ADULT RATS FOLLOWING PERIPHERAL INJURY. OUR CELL-SPECIFIC APPROACH HAS REVEALED A COMPLEX PATTERN OF EXPRESSION OF SPINAL HDAC2 THAT DEPENDS ON THE INJURY AND THE CELL TYPE, SUGGESTING A SOPHISTICATED REGULATION OF GENE EXPRESSION BY HDAC2. 2016 15 6138 36 THE ETIOLOGICAL CHANGES OF ACETYLATION IN PERIPHERAL NERVE INJURY-INDUCED NEUROPATHIC HYPERSENSITIVITY. NEUROPATHIC PAIN IS A COMMON CHRONIC PAIN CONDITION WITH MECHANISMS FAR CLEARLY BEEN ELUCIDATED. MOUNTING PRECLINICAL AND CLINICAL STUDIES HAVE SHOWN NEUROPATHIC PAIN IS HIGHLY ASSOCIATED WITH HISTONE ACETYLATION MODIFICATION, WHICH FOLLOWS EXPRESSION REGULATION OF VARIOUS PAIN-RELATED MOLECULES SUCH AS MGLUR1/5, GLUTAMATE ASPARTATE TRANSPORTER, GLUTAMATE TRANSPORTER-1, GAD65, NA(V)1.8, KV4.3, MU-OPIOID RECEPTOR, BRAIN-DERIVED NEUROTROPHIC FACTOR, AND CERTAIN CHEMOKINES. AS TWO TYPES OF PIVOTAL ENZYMES INVOLVED IN HISTONE ACETYLATION, HISTONE DEACETYLASES INDUCE HISTONE DEACETYLATION TO SILENCE GENE EXPRESSION; IN CONTRAST, HISTONE ACETYL TRANSFERASES FACILITATE HISTONE ACETYLATION TO POTENTIATE GENE TRANSCRIPTION. ACCORDINGLY, UPREGULATION OR BLOCKADE OF ACETYLATION MAY BE A PROMISING INTERVENTION DIRECTION FOR NEUROPATHIC PAIN TREATMENT. IN FACT, NUMEROUS ANIMAL STUDIES HAVE SUGGESTED VARIOUS HISTONE DEACETYLASE INHIBITORS, SIRT (CLASS III HISTONE DEACETYLASES) ACTIVATORS, AND HISTONE ACETYL TRANSFERASES INHIBITORS ARE EFFECTIVE IN NEUROPATHIC PAIN TREATMENT VIA TARGETING SPECIFIC EPIGENETIC SITES. IN THIS REVIEW, WE SUMMARIZE THE CHARACTERISTICS OF THE MOLECULES AND MECHANISMS OF NEUROPATHY-RELATED ACETYLATION, AS WELL AS THE ACETYLATION UPREGULATION AND BLOCKADE FOR NEUROPATHIC PAIN THERAPY. FINALLY, WE WILL DISCUSS THE CURRENT DRUG ADVANCES FOCUSING ON NEUROPATHY-RELATED ACETYLATION ALONG WITH THE UNDERLYING TREATMENT MECHANISMS. 2018 16 5851 36 SUBEROYLANILIDE HYDROXAMIC ACID TRIGGERS AUTOPHAGY BY INFLUENCING THE MTOR PATHWAY IN THE SPINAL DORSAL HORN IN A RAT NEUROPATHIC PAIN MODEL. HISTONE ACETYLATION LEVELS CAN BE UPREGULATED BY TREATING CELLS WITH HISTONE DEACETYLASE INHIBITORS (HDACIS), WHICH CAN INDUCE AUTOPHAGY. AUTOPHAGY FLUX IN THE SPINAL CORD OF RATS FOLLOWING THE LEFT FIFTH LUMBER SPINAL NERVE LIGATION (SNL) IS INVOLVED IN THE PROGRESSION OF NEUROPATHIC PAIN. SUBEROYLANILIDE HYDROXAMIC ACID (SAHA), ONE OF THE HDACIS CAN INTERFERE WITH THE EPIGENETIC PROCESS OF HISTONE ACETYLATION, WHICH HAS BEEN SHOWN TO EASE NEUROPATHIC PAIN. RECENT RESEARCH SUGGEST THAT SAHA CAN STIMULATE AUTOPHAGY VIA THE MAMMALIAN TARGET OF RAPAMYCIN (MTOR) PATHWAY IN SOME TYPES OF CANCER CELLS. HOWEVER, LITTLE IS KNOWN ABOUT THE ROLE OF SAHA AND AUTOPHAGY IN NEUROPATHIC PAIN AFTER NERVE INJURY. IN THE PRESENT STUDY, WE AIM TO INVESTIGATE AUTOPHAGY FLUX AND THE ROLE OF THE MTOR PATHWAY ON SPINAL CELLS AUTOPHAGY ACTIVATION IN NEUROPATHIC PAIN INDUCED BY SNL IN RATS THAT RECEIVED SAHA TREATMENT. AUTOPHAGY-RELATED PROTEINS AND MTOR OR ITS ACTIVE FORM WERE ASSESSED BY USING WESTERN BLOT, IMMUNOHISTOCHEMISTRY, DOUBLE IMMUNOFLUORESCENCE STAINING AND TRANSMISSION ELECTRON MICROSCOPY (TEM). WE FOUND THAT SAHA DECREASED THE PAW MECHANICAL WITHDRAWAL THRESHOLD (PMWT) OF THE LOWER COMPARED WITH SNL. AUTOPHAGY FLUX WAS MAINLY DISRUPTED IN THE ASTROCYTES AND NEURONAL CELLS OF THE SPINAL CORD DORSAL HORN ON POSTSURGICAL DAY 28 AND WAS REVERSED BY DAILY INTRATHECAL INJECTION OF SAHA (N = 100 NMOL/DAY OR N = 200 NMOL/DAY). SAHA ALSO DECREASED MTOR AND PHOSPHORYLATED MTOR (P-MTOR) EXPRESSION, ESPECIALLY P-MTOR EXPRESSION IN ASTROCYTES AND NEURONAL CELLS OF THE SPINAL DORSAL HORN. THESE RESULTS SUGGEST THAT SAHA ATTENUATES NEUROPATHIC PAIN AND CONTRIBUTES TO AUTOPHAGY FLUX IN ASTROCYTES AND NEURONAL CELLS OF THE SPINAL DORSAL HORN VIA THE MTOR SIGNALING PATHWAY. 2019 17 2214 35 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 18 2253 28 EPIGENETIC MODULATION OF WNT SIGNALING CONTRIBUTES TO NEUROPATHIC PAIN IN RATS. PREVIOUS STUDIES HAVE DEMONSTRATED THAT THE WNT/BETA?CATENIN SIGNALING PATHWAY IS CRITICAL TO THE INDUCTION AND MAINTENANCE OF CHRONIC NEUROPATHIC PAIN CAUSED BY PERIPHERAL INFLAMMATION AND NERVE DAMAGE. EMERGING EVIDENCE FROM RECENT STUDIES SUGGESTS THAT EPIGENETIC MECHANISMS MAY ALSO BE CRITICAL TO THE PATHOGENESIS OF CHRONIC PAIN. THE PRESENT STUDY AIMED TO ELUCIDATE THE EPIGENETIC MECHANISMS UNDERLYING ALTERED WNT SIGNALING AND THEIR INVOLVEMENT IN CCI?INDUCED NEUROPATHIC PAIN IN RAT SCIATIC NERVES. THE RESULTS OF THE PRESENT STUDY DEMONSTRATED A SIGNIFICANT INCREASE IN THE EXPRESSION LEVELS OF WNT3A IN THE DORSAL HORN OF THE RATS WITH CCI. IN ADDITION, A SIGNIFICANT INCREASE IN HISTONE H3 ACETYLATION, AND A SIGNIFICANT DECREASE IN CYTOSINE METHYLATION IN THE PROMOTER REGION OF WNT3A WAS OBSERVED IN THE DORSAL HORN OF THE RATS WITH CCI. INTRATHECAL APPLICATION OF XAV939, WHICH ACTS AS AN INHIBITOR OF WNT SIGNALING, SIGNIFICANTLY DECREASED THE EXPRESSION LEVELS OF ACTIVE BETA?CATENIN, AND ATTENUATED THE RAT BEHAVIORAL RESPONSES TO THERMAL AND MECHANICAL PAIN STIMULI. THESE RESULTS SUGGEST THAT THE EPIGENETIC UPREGULATION OF WNT3A IN THE DORSAL HORN CONTRIBUTES TO THE MAINTENANCE OF PAIN?INDUCED BEHAVIOR IN RATS WITH CCI. 2015 19 4617 33 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 20 2176 25 EPIGENETIC MECHANISMS OF CHRONIC PAIN. NEUROPATHIC AND INFLAMMATORY PAIN PROMOTE A LARGE NUMBER OF PERSISTING ADAPTATIONS AT THE CELLULAR AND MOLECULAR LEVEL, ALLOWING EVEN TRANSIENT TISSUE OR NERVE DAMAGE TO ELICIT CHANGES IN CELLS THAT CONTRIBUTE TO THE DEVELOPMENT OF CHRONIC PAIN AND ASSOCIATED SYMPTOMS. THERE IS EVIDENCE THAT INJURY-INDUCED CHANGES IN CHROMATIN STRUCTURE DRIVE STABLE CHANGES IN GENE EXPRESSION AND NEURAL FUNCTION, WHICH MAY CAUSE SEVERAL SYMPTOMS, INCLUDING ALLODYNIA, HYPERALGESIA, ANXIETY, AND DEPRESSION. RECENT FINDINGS ON EPIGENETIC CHANGES IN THE SPINAL CORD AND BRAIN DURING CHRONIC PAIN MAY GUIDE FUNDAMENTAL ADVANCES IN NEW TREATMENTS. HERE, WE PROVIDE A BRIEF OVERVIEW OF EPIGENETIC REGULATION IN THE NERVOUS SYSTEM AND THEN DISCUSS THE STILL-LIMITED LITERATURE THAT DIRECTLY IMPLICATES EPIGENETIC MODIFICATIONS IN CHRONIC PAIN SYNDROMES. 2015