1 4338 123 MICROVASCULAR BARRIER PROTECTION BY MICRORNA-183 VIA FOXO1 REPRESSION: A PATHWAY DISTURBED IN NEUROPATHY AND COMPLEX REGIONAL PAIN SYNDROME. BLOOD NERVE BARRIER DISRUPTION AND EDEMA ARE COMMON IN NEUROPATHIC PAIN AS WELL AS IN COMPLEX REGIONAL PAIN SYNDROME (CRPS). MICRORNAS (MIRNA) ARE EPIGENETIC MULTITARGET SWITCHES CONTROLLING NEURONAL AND NON-NEURONAL CELLS IN PAIN. THE MIR-183 COMPLEX ATTENUATES HYPEREXCITABILITY IN NOCICEPTORS, BUT ADDITIONAL NON-NEURONAL EFFECTS VIA TRANSCRIPTION FACTORS COULD CONTRIBUTE AS WELL. THIS STUDY EXPLORED EXOSOMAL MIR-183 IN CRPS AND MURINE NEUROPATHY, ITS EFFECT ON THE MICROVASCULAR BARRIER VIA TRANSCRIPTION FACTOR FOXO1 AND TIGHT JUNCTION PROTEIN CLAUDIN-5, AND ITS ANTIHYPERALGESIC POTENTIAL. SCIATIC MIR-183 DECREASED AFTER CCI. SUBSTITUTION WITH PERINEURAL MIR-183 MIMIC ATTENUATED MECHANICAL HYPERSENSITIVITY AND RESTORED BLOOD NERVE BARRIER FUNCTION. IN VITRO, SERUM FROM CCI MICE UND CRPS PATIENTS WEAKENED THE MICROVASCULAR BARRIER OF MURINE CEREBELLAR ENDOTHELIAL CELLS, INCREASED ACTIVE FOXO1 AND REDUCED CLAUDIN-5, CONCOMITANT WITH A LACK OF EXOSOMAL MIR-183 IN CRPS PATIENTS. CELLULAR STRESS ALSO COMPROMISED THE MICROVASCULAR BARRIER WHICH WAS RESCUED EITHER BY MIR-183 MIMIC VIA FOXO1 REPRESSION OR BY PRIOR SILENCING OF FOXO1. PERSPECTIVE: LOW MIR-183 LEADING TO BARRIER IMPAIRMENT VIA FOXO1 AND SUBSEQUENT CLAUDIN-5 SUPPRESSION IS A NEW ASPECT IN THE PATHOPHYSIOLOGY OF CRPS AND NEUROPATHIC PAIN. THIS PATHWAY MIGHT HELP UNTANGLE THE WIDE SYMPTOMATIC RANGE OF CRPS AND NURTURE FURTHER RESEARCH INTO MIRNA MIMICS OR FOXO1 INHIBITORS. 2022 2 2198 35 EPIGENETIC MODIFICATION OF DRG NEURONAL GENE EXPRESSION SUBSEQUENT TO NERVE INJURY: ETIOLOGICAL CONTRIBUTION TO COMPLEX REGIONAL PAIN SYNDROMES (PART I). DRG IS OF IMPORTANCE IN RELAYING PAINFUL STIMULATION TO THE HIGHER PAIN CENTERS AND THEREFORE COULD BE A CRUCIAL TARGET FOR EARLY INTERVENTION AIMED AT SUPPRESSING PRIMARY AFFERENT STIMULATION. COMPLEX REGIONAL PAIN SYNDROME (CRPS) IS A COMMON PAIN CONDITION WITH AN UNKNOWN ETIOLOGY. RECENTLY ADDED NEW INFORMATION ENRICHES OUR UNDERSTANDING OF CRPS PATHOPHYSIOLOGY. RESEARCHES ON GENETICS, BIOGENIC AMINES, NEUROTRANSMITTERS, AND MECHANISMS OF PAIN MODULATION, CENTRAL SENSITIZATION, AND AUTONOMIC FUNCTIONS IN CRPS REVEALED VARIOUS ABNORMALITIES INDICATING THAT MULTIPLE FACTORS AND MECHANISMS ARE INVOLVED IN THE PATHOGENESIS OF CRPS. EPIGENETICS REFERS TO MITOTICALLY AND MEIOTICALLY HERITABLE CHANGES IN GENE EXPRESSION THAT DO NOT AFFECT THE DNA SEQUENCE. AS EPIGENETIC MODIFICATIONS POTENTIALLY PLAY AN IMPORTANT ROLE IN INFLAMMATORY CYTOKINE METABOLISM, NEUROTRANSMITTER RESPONSIVENESS, AND ANALGESIC SENSITIVITY, THEY ARE LIKELY KEY FACTORS IN THE DEVELOPMENT OF CHRONIC PAIN. IN THIS DYAD REVIEW SERIES, WE SYSTEMATICALLY EXAMINE THE NERVE INJURY-RELATED CHANGES IN THE NEUROLOGICAL SYSTEM AND THEIR CONTRIBUTION TO CRPS. IN THIS PART, WE FIRST REVIEWED AND SUMMARIZED THE ROLE OF NEURAL SENSITIZATION IN DRG NEURONS IN PERFORMING FUNCTION IN THE CONTEXT OF PAIN PROCESSING. PARTICULAR EMPHASIS IS PLACED ON THE CELLULAR AND MOLECULAR CHANGES AFTER NERVE INJURY AS WELL AS DIFFERENT MODELS OF INFLAMMATORY AND NEUROPATHIC PAIN. THESE WERE CONSIDERED AS THE POTENTIAL MOLECULAR BASES THAT UNDERLIE NERVE INJURY-ASSOCIATED PATHOGENESIS OF CRPS. 2014 3 2214 32 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 4 4604 27 NEGATIVE EVIDENCE FOR A FUNCTIONAL ROLE OF NEURONAL DNMT3A IN PERSISTENT PAIN. TRADITIONALLY, NEUROSCIENCE HAS HAD TO RELY ON MIXED TISSUE ANALYSIS TO EXAMINE TRANSCRIPTIONAL AND EPIGENETIC CHANGES IN THE CONTEXT OF NERVOUS SYSTEM FUNCTION OR PATHOLOGY. HOWEVER, PARTICULARLY WHEN STUDYING CHRONIC PAIN CONDITIONS, THIS APPROACH CAN BE FLAWED, SINCE IT NEGLECTS TO TAKE INTO ACCOUNT THE SHIFTING CONTRIBUTION OF DIFFERENT CELL TYPES ACROSS EXPERIMENTAL CONDITIONS. HERE, WE DEMONSTRATE THIS USING THE EXAMPLE OF DNA METHYLTRANSFERASES (DNMTS) - A GROUP OF EPIGENETIC MODIFIERS CONSISTING OF DNMT1, DNMT3A, AND DNMT3B IN MAMMALIAN CELLS. WE USED SENSORY NEURON-SPECIFIC KNOCKOUT MICE FOR DNMT3A/3B AS WELL AS PHARMACOLOGICAL BLOCKADE OF DNMT1 TO STUDY THEIR ROLE IN NOCICEPTION. IN CONTRAST TO PREVIOUS ANALYSES ON WHOLE TISSUE, WE FIND THAT DNMT3A AND 3B PROTEIN IS NOT EXPRESSED IN ADULT DRG NEURONS, THAT NONE OF THE DNA METHYLTRANSFERASES ARE REGULATED WITH INJURY AND THAT INTERFERING WITH THEIR FUNCTION HAS NO EFFECT ON NOCICEPTION. OUR RESULTS THEREFORE CURRENTLY DO NOT SUPPORT A ROLE FOR NEURONAL DNA METHYLTRANSFERASES IN PAIN PROCESSING IN ADULT ANIMALS. 2018 5 3754 25 INTEGRATED ANALYSIS OF OMICS DATA REVEAL AP-1 AS A POTENTIAL REGULATION HUB IN THE INFLAMMATION-INDUCED HYPERALGESIA RAT MODEL. INFLAMMATION-ASSOCIATED CHRONIC PAIN IS A GLOBAL CLINICAL PROBLEM, AFFECTING MILLIONS OF PEOPLE WORLDWIDE. HOWEVER, THE UNDERLYING MECHANISMS THAT MEDIATE INFLAMMATION-ASSOCIATED CHRONIC PAIN REMAIN UNCLEAR. A RAT MODEL OF CUTANEOUS INFLAMMATION INDUCED BY COMPLETE FREUND'S ADJUVANT (CFA) HAS BEEN WIDELY USED AS AN INFLAMMATION-INDUCED PAIN HYPERSENSITIVITY MODEL. WE PRESENT THE TRANSCRIPTOMICS PROFILE OF CFA-INDUCED INFLAMMATION IN THE RAT DORSAL ROOT GANGLION (DRG) VIA AN APPROACH THAT TARGETS GENE EXPRESSION, DNA METHYLATION, AND POST-TRANSCRIPTIONAL REGULATION. WE IDENTIFIED 418 DIFFERENTIALLY EXPRESSED MRNAS, 120 DIFFERENTIALLY EXPRESSED MICRORNAS (MIRNAS), AND 2,670 DIFFERENTIALLY METHYLATED REGIONS (DMRS), WHICH WERE ALL HIGHLY ASSOCIATED WITH MULTIPLE INFLAMMATION-RELATED PATHWAYS, INCLUDING NUCLEAR FACTOR KAPPA B (NF-KAPPAB) AND INTERFERON (IFN) SIGNALING PATHWAYS. AN INTEGRATED ANALYSIS FURTHER DEMONSTRATED THAT THE ACTIVATOR PROTEIN 1 (AP-1) NETWORK, WHICH MAY ACT AS A REGULATOR OF THE INFLAMMATORY RESPONSE, IS REGULATED AT BOTH THE TRANSCRIPTOMIC AND EPIGENETIC LEVELS. WE BELIEVE OUR DATA WILL NOT ONLY PROVIDE DRUG SCREENING TARGETS FOR THE TREATMENT OF CHRONIC PAIN AND INFLAMMATION BUT WILL ALSO SHED LIGHT ON THE MOLECULAR NETWORK ASSOCIATED WITH INFLAMMATION-INDUCED HYPERALGESIA. 2021 6 5007 29 PERIPHERAL NERVE INJURY IS ASSOCIATED WITH CHRONIC, REVERSIBLE CHANGES IN GLOBAL DNA METHYLATION IN THE MOUSE PREFRONTAL CORTEX. CHANGES IN BRAIN STRUCTURE AND CORTICAL FUNCTION ARE ASSOCIATED WITH MANY CHRONIC PAIN CONDITIONS INCLUDING LOW BACK PAIN AND FIBROMYALGIA. THE MAGNITUDE OF THESE CHANGES CORRELATES WITH THE DURATION AND/OR THE INTENSITY OF CHRONIC PAIN. MOST STUDIES REPORT CHANGES IN COMMON AREAS INVOLVED IN PAIN MODULATION, INCLUDING THE PREFRONTAL CORTEX (PFC), AND PAIN-RELATED PATHOLOGICAL CHANGES IN THE PFC CAN BE REVERSED WITH EFFECTIVE TREATMENT. WHILE THE MECHANISMS UNDERLYING THESE CHANGES ARE UNKNOWN, THEY MUST BE DYNAMICALLY REGULATED. EPIGENETIC MODULATION OF GENE EXPRESSION IN RESPONSE TO EXPERIENCE AND ENVIRONMENT IS REVERSIBLE AND DYNAMIC. EPIGENETIC MODULATION BY DNA METHYLATION IS ASSOCIATED WITH ABNORMAL BEHAVIOR AND PATHOLOGICAL GENE EXPRESSION IN THE CENTRAL NERVOUS SYSTEM. DNA METHYLATION MIGHT ALSO BE INVOLVED IN MEDIATING THE PATHOLOGIES ASSOCIATED WITH CHRONIC PAIN IN THE BRAIN. WE THEREFORE TESTED A) WHETHER ALTERATIONS IN DNA METHYLATION ARE FOUND IN THE BRAIN LONG AFTER CHRONIC NEUROPATHIC PAIN IS INDUCED IN THE PERIPHERY USING THE SPARED NERVE INJURY MODAL AND B) WHETHER THESE INJURY-ASSOCIATED CHANGES ARE REVERSIBLE BY INTERVENTIONS THAT REVERSE THE PATHOLOGIES ASSOCIATED WITH CHRONIC PAIN. SIX MONTHS FOLLOWING PERIPHERAL NERVE INJURY, ABNORMAL SENSORY THRESHOLDS AND INCREASED ANXIETY WERE ACCOMPANIED BY DECREASED GLOBAL METHYLATION IN THE PFC AND THE AMYGDALA BUT NOT IN THE VISUAL CORTEX OR THE THALAMUS. ENVIRONMENTAL ENRICHMENT ATTENUATED NERVE INJURY-INDUCED HYPERSENSITIVITY AND REVERSED THE CHANGES IN GLOBAL PFC METHYLATION. FURTHERMORE, GLOBAL PFC METHYLATION CORRELATED WITH MECHANICAL AND THERMAL SENSITIVITY IN NEUROPATHIC MICE. IN SUMMARY, INDUCTION OF CHRONIC PAIN BY PERIPHERAL NERVE INJURY IS ASSOCIATED WITH EPIGENETIC CHANGES IN THE BRAIN. THESE CHANGES ARE DETECTED LONG AFTER THE ORIGINAL INJURY, AT A LONG DISTANCE FROM THE SITE OF INJURY AND ARE REVERSIBLE WITH ENVIRONMENTAL MANIPULATION. CHANGES IN BRAIN STRUCTURE AND CORTICAL FUNCTION THAT ARE ASSOCIATED WITH CHRONIC PAIN CONDITIONS MAY THEREFORE BE MEDIATED BY EPIGENETIC MECHANISMS. 2013 7 4348 37 MIR-146A DYSREGULATES ENERGY METABOLISM DURING NEUROINFLAMMATION. ALZHEIMER'S DISEASE (AD) AND OTHER NEURODEGENERATIVE DISEASES ARE CHARACTERIZED BY CHRONIC NEUROINFLAMMATION AND A REDUCTION IN BRAIN ENERGY METABOLISM. AN IMPORTANT ROLE HAS EMERGED FOR SMALL, NON-CODING RNA MOLECULES KNOWN AS MICRORNAS (MIRNAS) IN THE PATHOPHYSIOLOGY OF MANY NEURODEGENERATIVE DISORDERS. AS EPIGENETIC REGULATORS, MIRNAS POSSESS THE CAPACITY TO REGULATE AND FINE TUNE PROTEIN PRODUCTION BY INHIBITING TRANSLATION. SEVERAL MIRNAS, WHICH INCLUDE MIR-146A, ARE ELEVATED IN THE BRAIN, CSF, AND PLASMA OF AD PATIENTS. MIR-146A PARTICIPATES IN PATHWAYS THAT REGULATE IMMUNE ACTIVATION AND HAS SEVERAL MRNA TARGETS WHICH ENCODE FOR PROTEINS INVOLVED IN CELLULAR ENERGY METABOLISM. AN ADDITIONAL ROLE FOR EXTRACELLULAR VESICLES (EVS) HAS ALSO EMERGED IN THE PROGRESSION AD, AS EVS CAN TRANSFER FUNCTIONALLY ACTIVE PROTEINS AND RNAS FROM DISEASED TO HEALTHY CELLS. IN THE CURRENT STUDY, WE EXPOSED VARIOUS CELL TYPES PRESENT WITHIN THE CNS TO IMMUNOMODULATORY MOLECULES AND OBSERVED SIGNIFICANT UPREGULATION OF MIR-146A EXPRESSION, BOTH WITHIN CELLS AND WITHIN THEIR SECRETED EVS. FURTHER, WE ASSESSED THE EFFECTS OF MIR-146A OVEREXPRESSION ON BIOENERGETIC FUNCTION IN PRIMARY RAT GLIAL CELLS AND FOUND SIGNIFICANT REDUCTIONS IN OXIDATIVE PHOSPHORYLATION AND GLYCOLYSIS. LASTLY, WE CORRELATED MIR-146A EXPRESSION LEVELS WITHIN VARIOUS REGIONS OF THE AD BRAIN TO DISEASE STAGING AND FOUND SIGNIFICANT, POSITIVE CORRELATIONS. THESE NOVEL RESULTS DEMONSTRATE THAT THE MODULATION OF MIR-146A IN RESPONSE TO NEUROINFLAMMATORY STIMULI MAY MEDIATE THE LOSS OF MITOCHONDRIAL INTEGRITY AND FUNCTION IN CELLS, THEREBY CONTRIBUTING TO THE PROGRESSION OF BETA-AMYLOID AND TAU PATHOLOGY IN THE AD BRAIN. MULTIPLE INFLAMMATORY STIMULI CAN UPREGULATE MIRNA-146A EXPRESSION WITHIN NEURONS, MIXED GLIAL CELLS, AND BRAIN ENDOTHELIAL CELLS, WHICH IS EITHER RETAINED WITHIN THESE CELLS OR RELEASED FROM THEM AS EXTRACELLULAR VESICLE CARGO. THE UPREGULATION OF MIR-146A DISRUPTS CELLULAR BIOENERGETICS IN MIXED GLIAL CELLS. THIS MECHANISM MAY PLAY A CRITICAL ROLE IN THE NEUROINFLAMMATORY RESPONSE OBSERVED DURING ALZHEIMER'S DISEASE. 2022 8 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 9 593 38 BET PROTEIN INHIBITION REGULATES CYTOKINE PRODUCTION AND PROMOTES NEUROPROTECTION AFTER SPINAL CORD INJURY. BACKGROUND: SPINAL CORD INJURY (SCI) USUALLY CAUSES A DEVASTATING LIFELONG DISABILITY FOR PATIENTS. AFTER A TRAUMATIC LESION, DISRUPTION OF THE BLOOD-SPINAL CORD BARRIER INDUCES THE INFILTRATION OF MACROPHAGES INTO THE LESION SITE AND THE ACTIVATION OF RESIDENT GLIAL CELLS, WHICH RELEASE CYTOKINES AND CHEMOKINES. THESE EVENTS RESULT IN A PERSISTENT INFLAMMATION, WHICH HAS BOTH DETRIMENTAL AND BENEFICIAL EFFECTS, BUT EVENTUALLY LIMITS FUNCTIONAL RECOVERY AND CONTRIBUTES TO THE APPEARANCE OF NEUROPATHIC PAIN. BROMODOMAIN AND EXTRA-TERMINAL DOMAIN (BET) PROTEINS ARE EPIGENETIC READERS THAT REGULATE THE EXPRESSION OF INFLAMMATORY GENES BY INTERACTING WITH ACETYLATED LYSINE RESIDUES. WHILE BET INHIBITORS ARE A PROMISING THERAPEUTIC STRATEGY FOR CANCER, LITTLE IS KNOWN ABOUT THEIR IMPLICATION AFTER SCI. THUS, THE CURRENT STUDY WAS AIMED TO INVESTIGATE THE ANTI-INFLAMMATORY ROLE OF BET INHIBITORS IN THIS PATHOLOGIC CONDITION. METHODS: WE EVALUATED THE EFFECTIVENESS OF THE BET INHIBITOR JQ1 TO MODIFY MACROPHAGE REACTIVITY IN VITRO AND TO MODULATE INFLAMMATION IN A SCI MICE MODEL. WE ANALYZED THE EFFECTS OF BET INHIBITION IN PRO-INFLAMMATORY AND ANTI-INFLAMMATORY CYTOKINE PRODUCTION IN VITRO AND IN VIVO. WE DETERMINED THE EFFECTIVENESS OF BET INHIBITION IN TISSUE SPARING, INFLAMMATION, NEURONAL PROTECTION, AND BEHAVIORAL OUTCOME AFTER SCI. RESULTS: WE HAVE FOUND THAT THE BET INHIBITOR JQ1 REDUCED THE LEVELS OF PRO-INFLAMMATORY MEDIATORS AND INCREASED THE EXPRESSION OF ANTI-INFLAMMATORY CYTOKINES. A PROLONGED TREATMENT WITH JQ1 ALSO DECREASED REACTIVITY OF MICROGLIA/MACROPHAGES, ENHANCED NEUROPROTECTION AND FUNCTIONAL RECOVERY, AND ACUTELY REDUCED NEUROPATHIC PAIN AFTER SCI. CONCLUSIONS: BET PROTEIN INHIBITION IS AN EFFECTIVE TREATMENT TO REGULATE CYTOKINE PRODUCTION AND PROMOTE NEUROPROTECTION AFTER SCI. THESE NOVEL RESULTS DEMONSTRATE FOR THE FIRST TIME THAT TARGETING BET PROTEINS IS AN ENCOURAGING APPROACH FOR SCI REPAIR AND A POTENTIAL STRATEGY TO TREAT OTHER INFLAMMATORY PATHOLOGIES. 2019 10 5626 24 SELECTIVE REPRESSION OF GENE EXPRESSION IN NEUROPATHIC PAIN BY THE NEURON-RESTRICTIVE SILENCING FACTOR/REPRESSOR ELEMENT-1 SILENCING TRANSCRIPTION (NRSF/REST). NEUROPATHIC PAIN OFTEN DEVELOPS FOLLOWING NERVE INJURY AS A RESULT OF MALADAPTIVE CHANGES THAT OCCUR IN THE INJURED NERVE AND ALONG THE NOCICEPTIVE PATHWAYS OF THE PERIPHERAL AND CENTRAL NERVOUS SYSTEMS. MULTIPLE CELLULAR AND MOLECULAR MECHANISMS LIKELY ACCOUNT FOR THESE CHANGES; HOWEVER, THE EXACT NATURE OF THESE MECHANISMS REMAIN LARGELY UNKNOWN. A GROWING NUMBER OF STUDIES SUGGEST THAT ALTERATION IN GENE EXPRESSION IS AN IMPORTANT STEP IN THE PROGRESSION FROM ACUTE TO CHRONIC PAIN STATES AND EPIGENETIC REGULATION HAS BEEN PROPOSED TO DRIVE THIS CHANGE IN GENE EXPRESSION. IN THIS REVIEW, WE DISCUSS RECENT EVIDENCE THAT THE DNA-BINDING PROTEIN NEURON-RESTRICTIVE SILENCING FACTOR/REPRESSOR ELEMENT-1 SILENCING TRANSCRIPTION FACTOR (NRSF/REST) IS AN IMPORTANT COMPONENT IN THE DEVELOPMENT AND MAINTENANCE OF NEUROPATHIC PAIN THROUGH ITS ROLE AS A TRANSCRIPTIONAL REGULATOR FOR A SELECT SUBSET OF GENES THAT IT NORMALLY REPRESSES DURING DEVELOPMENT. 2016 11 842 28 CHEMOKINES IN CHRONIC PAIN: CELLULAR AND MOLECULAR MECHANISMS AND THERAPEUTIC POTENTIAL. CHRONIC PAIN RESULTING FROM NERVE INJURY, TISSUE INFLAMMATION, AND TUMOR INVASION OR TREATMENT, IS A MAJOR HEALTH PROBLEM IMPACTING THE QUALITY OF LIFE AND PRODUCING A SIGNIFICANT ECONOMIC AND SOCIAL BURDEN. HOWEVER, THE CURRENT ANALGESIC DRUGS INCLUDING NON-STEROIDAL ANTI-INFLAMMATORY DRUGS AND OPIOIDS ARE INADEQUATE TO RELIEVE CHRONIC PAIN DUE TO THE LACK OF EFFICACY OR SEVERE SIDE-EFFECTS. CHEMOKINES ARE A FAMILY OF SMALL SECRETED PROTEINS THAT BIND TO G PROTEIN-COUPLED RECEPTORS TO TRIGGER INTRACELLULAR SIGNALING PATHWAYS AND DIRECT CELL MIGRATION, PROLIFERATION, SURVIVAL, AND INFLAMMATION UNDER HOMEOSTATIC AND PATHOLOGICAL CONDITIONS. ACCUMULATING EVIDENCE SUPPORTS THE IMPORTANT ROLE OF CHEMOKINES AND CHEMOKINE RECEPTORS IN THE PERIPHERAL AND CENTRAL NERVOUS SYSTEM IN MEDIATING CHRONIC PAIN VIA ENHANCING NEUROINFLAMMATION. IN THIS REVIEW, WE FOCUS ON RECENT PROGRESS IN UNDERSTANDING THE COMPREHENSIVE ROLES OF CHEMOKINES AND CHEMOKINE RECEPTORS IN THE GENERATION AND MAINTENANCE OF DIFFERENT TYPES OF CHRONIC PAIN, INCLUDING NEUROPATHIC PAIN, INFLAMMATORY PAIN, CANCER PAIN, AND VISCERAL PAIN. THE CURRENT REVIEW ALSO SUMMARIZES THE UPSTREAM SIGNALING OF TRANSCRIPTIONAL AND EPIGENETIC REGULATION ON THE EXPRESSION OF CHEMOKINES AND CHEMOKINE RECEPTORS AS WELL AS THE DOWNSTREAM SIGNALING OF CHEMOKINE RECEPTORS UNDERLYING CHRONIC PAIN. AS CHRONIC ITCH AND CHRONIC PAIN SHARE SOME COMMON MECHANISMS, WE ALSO DISCUSS THE EMERGING ROLES OF CHEMOKINES AND CHEMOKINE RECEPTORS IN CHRONIC ITCH. TARGETING SPECIFIC CHEMOKINES OR CHEMOKINE RECEPTORS BY SIRNAS, BLOCKING ANTIBODIES, OR SMALL-MOLECULE ANTAGONISTS MAY OFFER NEW THERAPEUTIC POTENTIAL FOR THE MANAGEMENT OF CHRONIC PAIN. 2020 12 6427 22 THE TRANSITION FROM ACUTE TO CHRONIC PAIN: DYNAMIC EPIGENETIC REPROGRAMMING OF THE MOUSE PREFRONTAL CORTEX UP TO 1 YEAR AFTER NERVE INJURY. CHRONIC PAIN IS ASSOCIATED WITH PERSISTENT STRUCTURAL AND FUNCTIONAL CHANGES THROUGHOUT THE NEUROAXIS, INCLUDING IN THE PREFRONTAL CORTEX (PFC). THE PFC IS IMPORTANT IN THE INTEGRATION OF SENSORY, COGNITIVE, AND EMOTIONAL INFORMATION AND IN CONDITIONED PAIN MODULATION. WE PREVIOUSLY REPORTED WIDESPREAD EPIGENETIC REPROGRAMMING IN THE PFC MANY MONTHS AFTER NERVE INJURY IN RODENTS. EPIGENETIC MODIFICATIONS, INCLUDING DNA METHYLATION, CAN DRIVE CHANGES IN GENE EXPRESSION WITHOUT MODIFYING DNA SEQUENCES. TO DATE, LITTLE IS KNOWN ABOUT EPIGENETIC DYSREGULATION AT THE ONSET OF ACUTE PAIN OR HOW IT PROGRESSES AS PAIN TRANSITIONS FROM ACUTE TO CHRONIC. WE HYPOTHESIZE THAT ACUTE PAIN AFTER INJURY RESULTS IN RAPID AND PERSISTENT EPIGENETIC REMODELLING IN THE PFC THAT EVOLVES AS PAIN BECOMES CHRONIC. WE FURTHER PROPOSE THAT UNDERSTANDING EPIGENETIC REMODELLING WILL PROVIDE INSIGHTS INTO THE MECHANISMS DRIVING PAIN-RELATED CHANGES IN THE BRAIN. EPIGENOME-WIDE ANALYSIS WAS PERFORMED IN THE MOUSE PFC 1 DAY, 2 WEEKS, 6 MONTHS, AND 1 YEAR AFTER PERIPHERAL INJURY USING THE SPARED NERVE INJURY IN MICE. SPARED NERVE INJURY RESULTED IN RAPID AND PERSISTENT CHANGES IN DNA METHYLATION, WITH ROBUST DIFFERENTIAL METHYLATION OBSERVED BETWEEN SPARED NERVE INJURY AND SHAM-OPERATED CONTROL MICE AT ALL TIME POINTS. HUNDREDS OF DIFFERENTIALLY METHYLATED GENES WERE IDENTIFIED, INCLUDING MANY WITH KNOWN FUNCTION IN PAIN. PATHWAY ANALYSIS REVEALED ENRICHMENT IN GENES RELATED TO STIMULUS RESPONSE AT EARLY TIME POINTS, IMMUNE FUNCTION AT LATER TIME POINTS, AND ACTIN AND CYTOSKELETAL REGULATION THROUGHOUT THE TIME COURSE. THESE RESULTS EMPHASIZE THE IMPORTANCE OF CONSIDERING PAIN CHRONICITY IN BOTH PAIN RESEARCH AND IN TREATMENT OPTIMIZATION. 2020 13 2199 28 EPIGENETIC MODIFICATION OF DRG NEURONAL GENE EXPRESSION SUBSEQUENT TO NERVE INJURY: ETIOLOGICAL CONTRIBUTION TO COMPLEX REGIONAL PAIN SYNDROMES (PART II). CUMULATING EVIDENCE INDICATED THAT NERVE INJURY-ASSOCIATED CELLULAR AND MOLECULAR CHANGES PLAY AN ESSENTIAL ROLE IN CONTRIBUTING TO THE DEVELOPMENT OF PATHOLOGICAL PAIN, AND MORE RECENT FINDINGS IMPLICATED THE CRITICAL ROLE OF EPIGENETIC MECHANISMS IN PAIN-RELATED SENSITIZATION IN THE DRG SUBSEQUENT TO NERVE INJURY. IN THIS PART OF THE DYAD REVIEW (PART II), WE REVIEWED AND PAID SPECIAL ATTENTION ON THE ETIOLOGICAL CONTRIBUTION OF DGR GENE EXPRESSION MODULATED BY EPIGENETIC MECHANISMS OF CRPS. AS ESSENTIAL EFFECTORS TO DIFFERENT MOLECULAR ACTIVATION, WE FIRST DISCUSSED THE ACTIVATION OF VARIOUS SIGNALING PATHWAYS THAT SUBSEQUENTLY FROM NERVE INJURY, AND IN FURTHER ILLUSTRATED THE FUNDAMENTAL AND FUNCTIONAL UNDERPINNINGS OF NERVE INJURY-INDUCED PAIN, IN WHICH WE ARGUED FOR THE POTENTIAL EPIGENETIC MECHANISMS IN RESPONSE TO SENSITIZING STIMULI OR INJURY. THEREFORE, UNDERSTANDING THE SPECIFIC MEDIATING FACTORS THAT INFLUENCE INDIVIDUAL EPIGENETIC DIFFERENCES CONTRIBUTING TO PAIN SENSITIVITY AND RESPONSIVENESS TO ANALGESICS POSSESSES CRUCIAL CLINICAL IMPLICATIONS. 2014 14 4619 28 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 15 2003 20 EPIGENETIC AND TRANSCRIPTIONAL CONTROL OF THE OPIOID PRODYNORPHINE GENE: IN-DEPTH ANALYSIS IN THE HUMAN BRAIN. NEUROPEPTIDES SERVE AS NEUROHORMONES AND LOCAL PARACRINE REGULATORS THAT CONTROL NEURAL NETWORKS REGULATING BEHAVIOR, ENDOCRINE SYSTEM AND SENSORIMOTOR FUNCTIONS. THEIR EXPRESSION IS CHARACTERIZED BY EXCEPTIONALLY RESTRICTED PROFILES. CIRCUIT-SPECIFIC AND ADAPTIVE EXPRESSION OF NEUROPEPTIDE GENES MAY BE DEFINED BY TRANSCRIPTIONAL AND EPIGENETIC MECHANISMS CONTROLLED BY CELL TYPE AND SUBTYPE SEQUENCE-SPECIFIC TRANSCRIPTION FACTORS, INSULATORS AND SILENCERS. THE OPIOID PEPTIDE DYNORPHINS PLAY A CRITICAL ROLE IN NEUROLOGICAL AND PSYCHIATRIC DISORDERS, PAIN PROCESSING AND STRESS, WHILE THEIR MUTATIONS CAUSE PROFOUND NEURODEGENERATION IN THE HUMAN BRAIN. IN THIS REVIEW, WE FOCUS ON THE PRODYNORPHIN GENE AS A MODEL FOR THE IN-DEPTH EPIGENETIC AND TRANSCRIPTIONAL ANALYSIS OF EXPRESSION OF THE NEUROPEPTIDE GENES. PRODYNORPHIN STUDIES MAY PROVIDE A FRAMEWORK FOR ANALYSIS OF MECHANISMS RELEVANT FOR REGULATION OF NEUROPEPTIDE GENES IN NORMAL AND PATHOLOGICAL HUMAN BRAIN. 2021 16 5709 36 SIRT1 DECREASES EMOTIONAL PAIN VULNERABILITY WITH ASSOCIATED CAMKIIALPHA DEACETYLATION IN CENTRAL AMYGDALA. EMOTIONAL DISORDERS ARE COMMON COMORBID CONDITIONS THAT FURTHER EXACERBATE THE SEVERITY AND CHRONICITY OF CHRONIC PAIN. HOWEVER, INDIVIDUALS SHOW CONSIDERABLE VULNERABILITY TO THE DEVELOPMENT OF CHRONIC PAIN UNDER SIMILAR PAIN CONDITIONS. IN THIS STUDY ON MALE RAT AND MOUSE MODELS OF CHRONIC NEUROPATHIC PAIN, WE IDENTIFY THE HISTONE DEACETYLASE SIRTUIN 1 (SIRT1) IN CENTRAL AMYGDALA AS A KEY EPIGENETIC REGULATOR THAT CONTROLS THE DEVELOPMENT OF COMORBID EMOTIONAL DISORDERS UNDERLYING THE INDIVIDUAL VULNERABILITY TO CHRONIC PAIN. WE FOUND THAT ANIMALS THAT WERE VULNERABLE TO DEVELOPING BEHAVIORS OF ANXIETY AND DEPRESSION UNDER THE PAIN CONDITION DISPLAYED REDUCED SIRT1 PROTEIN LEVELS IN CENTRAL AMYGDALA, BUT NOT THOSE ANIMALS RESISTANT TO THE EMOTIONAL DISORDERS. VIRAL OVEREXPRESSION OF LOCAL SIRT1 REVERSED THIS VULNERABILITY, BUT VIRAL KNOCKDOWN OF LOCAL SIRT1 MIMICKED THE PAIN EFFECT, ELICITING THE PAIN VULNERABILITY IN PAIN-FREE ANIMALS. THE SIRT1 ACTION WAS ASSOCIATED WITH CAMKIIALPHA DOWNREGULATION AND DEACETYLATION OF HISTONE H3 LYSINE 9 AT THE CAMKIIALPHA PROMOTER. THESE RESULTS SUGGEST THAT, BY TRANSCRIPTIONAL REPRESSION OF CAMKIIALPHA IN CENTRAL AMYGDALA, SIRT1 FUNCTIONS TO GUARD AGAINST THE EMOTIONAL PAIN VULNERABILITY UNDER CHRONIC PAIN CONDITIONS. THIS STUDY INDICATES THAT SIRT1 MAY SERVE AS A POTENTIAL THERAPEUTIC MOLECULE FOR INDIVIDUALIZED TREATMENT OF CHRONIC PAIN WITH VULNERABLE EMOTIONAL DISORDERS.SIGNIFICANCE STATEMENT CHRONIC PAIN IS A PREVALENT NEUROLOGICAL DISEASE WITH NO EFFECTIVE TREATMENT AT PRESENT. PAIN PATIENTS DISPLAY CONSIDERABLY VARIABLE VULNERABILITY TO DEVELOPING CHRONIC PAIN, INDICATING INDIVIDUAL-BASED MOLECULAR MECHANISMS UNDERLYING THE PAIN VULNERABILITY, WHICH IS HARDLY ADDRESSED IN CURRENT PRECLINICAL RESEARCH. IN THIS STUDY, WE HAVE IDENTIFIED THE HISTONE DEACETYLASE SIRTUIN 1 (SIRT1) AS A KEY REGULATOR THAT CONTROLS THIS PAIN VULNERABILITY. THIS STUDY REVEALS THAT THE SIRT1-CAMKIIAALPHA PATHWAY IN CENTRAL AMYGDALA ACTS AS AN EPIGENETIC MECHANISM THAT GUARDS AGAINST THE DEVELOPMENT OF COMORBID EMOTIONAL DISORDERS UNDER CHRONIC PAIN, AND THAT ITS DYSFUNCTION CAUSES INCREASED VULNERABILITY TO THE DEVELOPMENT OF CHRONIC PAIN. THESE FINDINGS SUGGEST THAT SIRT1 ACTIVATORS MAY BE USED IN A NOVEL THERAPEUTIC APPROACH FOR INDIVIDUAL-BASED TREATMENT OF CHRONIC PAIN. 2020 17 4969 32 PATHOLOGICAL NEUROINFLAMMATORY CONVERSION OF REACTIVE ASTROCYTES IS INDUCED BY MICROGLIA AND INVOLVES CHROMATIN REMODELING. FOLLOWING BRAIN INJURY OR IN NEURODEGENERATIVE DISEASES, ASTROCYTES BECOME REACTIVE AND MAY SUFFER PATHOLOGICAL REMODELING, FEATURES OF WHICH ARE THE LOSS OF THEIR HOMEOSTATIC FUNCTIONS AND A PRO-INFLAMMATORY GAIN OF FUNCTION THAT FACILITATES NEURODEGENERATION. PHARMACOLOGICAL INTERVENTION TO MODULATE THIS ASTROGLIAL RESPONSE AND NEUROINFLAMMATION IS AN INTERESTING NEW THERAPEUTIC RESEARCH STRATEGY, BUT IT STILL REQUIRES A DEEPER UNDERSTANDING OF THE UNDERLYING CELLULAR AND MOLECULAR MECHANISMS OF THE PHENOMENON. BASED ON THE KNOWN MICROGLIAL-ASTROGLIAL INTERACTION, THE PROMINENT ROLE OF THE NUCLEAR FACTOR KAPPA B (NF-KAPPAB) PATHWAY IN MEDIATING ASTROGLIAL PATHOLOGICAL PRO-INFLAMMATORY GAIN OF FUNCTION, AND ITS ABILITY TO RECRUIT CHROMATIN-REMODELING ENZYMES, WE FIRST EXPLORED THE MICROGLIAL ROLE IN THE INITIATION OF ASTROGLIAL PRO-INFLAMMATORY CONVERSION AND THEN MONITORED THE PROGRESSION OF EPIGENETIC CHANGES IN THE ASTROCYTIC CHROMATIN. DIFFERENT CONFIGURATIONS OF PRIMARY GLIAL CULTURE WERE USED TO MODULATE MICROGLIA-ASTROCYTE CROSSTALK WHILE INDUCING PRO-INFLAMMATORY GAIN OF FUNCTION BY LIPOPOLYSACCHARIDE (LPS) EXPOSURE. IN VIVO, BRAIN ISCHEMIA BY CORTICAL DEVASCULARIZATION (PIAL DISRUPTION) WAS PERFORMED TO VERIFY THE PRESENCE OF EPIGENETIC MARKS IN REACTIVE ASTROCYTES. OUR RESULTS SHOWED THAT 1) MICROGLIA IS REQUIRED TO INITIATE THE PATHOLOGICAL CONVERSION OF ASTROCYTES BY TRIGGERING THE NF-KAPPAB SIGNALING PATHWAY; 2) THIS INTERACTION IS MEDIATED BY SOLUBLE FACTORS AND INDUCES STABLE ASTROGLIAL PHENOTYPIC CHANGES; 3) THE PATHOLOGICAL CONVERSION PROMOTES CHROMATIN REMODELING WITH STABLE INCREASE IN H3K9K14AC, TEMPORARY INCREASE IN H3K27AC, AND TEMPORARY REDUCTION IN HETEROCHROMATIN MARK H3K9ME3; AND 4) IN VIVO REACTIVE ASTROCYTES SHOW INCREASED H3K27AC MARK IN THE NEUROINFLAMMATORY MILIEU FROM THE ISCHEMIC PENUMBRA. OUR FINDINGS INDICATE THAT ASTROGLIAL PATHOLOGICAL PRO-INFLAMMATORY GAIN OF FUNCTION IS ASSOCIATED WITH PROFOUND CHANGES IN THE CONFIGURATION OF ASTROCYTIC CHROMATIN, WHICH IN TURN ARE INITIATED BY MICROGLIA-DERIVED CUES. THESE RESULTS OPEN A NEW AVENUE IN THE STUDY OF POTENTIAL PHARMACOLOGICAL INTERVENTIONS THAT MODIFY THE INITIATION AND STABILIZATION OF ASTROGLIAL PATHOLOGICAL REMODELING, WHICH WOULD BE USEFUL IN ACUTE AND CHRONIC CNS INJURY. EPIGENETIC CHANGES REPRESENT A PLAUSIBLE PHARMACOLOGICAL TARGET TO INTERFERE WITH THE STABILIZATION OF THE PATHOLOGICAL ASTROGLIAL PHENOTYPE. 2021 18 2194 24 EPIGENETIC MODIFICATION IN NEUROPATHIC PAIN. NEUROPATHIC PAIN IS CHARACTERIZED BY COMPLICATED COMBINATION OF POSITIVE (E.G., HYPERALGESIA AND ALLODYNIA) AND NEGATIVE (E.G., HYPOESTHESIA AND HYPOALGESIA) SYMPTOMS, AND IS OFTEN REFRACTORY TO CONVENTIONAL PHARMACOLOGICAL AGENTS, INCLUDING MORPHINE. ALTHOUGH THE MOLECULAR MECHANISMS FOR POSITIVE SYMPTOMS ARE EXTENSIVELY STUDIED, THOSE FOR NEGATIVE SYMPTOMS ARE POORLY UNDERSTOOD. THERE IS CONVINCING EVIDENCE THAT ALTERED GENE EXPRESSION WITHIN PERIPHERAL AND CENTRAL NERVOUS SYSTEMS IS A KEY MECHANISM FOR NEUROPATHIC PAIN; HOWEVER, ITS TRANSCRIPTIONAL MECHANISMS ARE POORLY UNDERSTOOD. EPIGENETIC MODIFICATIONS, SUCH AS DNA METHYLATION AND HISTONE MODIFICATIONS (E.G., ACETYLATION, METHYLATION, AND PHOSPHORYLATION), ARE KNOWN TO CAUSE STABLE GENE EXPRESSION VIA CHROMATIN REMODELING. THESE MECHANISMS HAVE A ROLE NOT ONLY IN THE DETERMINATION OF DEVELOPMENTAL CELL FATES, BUT ALSO IN THE PHYSIOLOGICAL AND PATHOLOGICAL PROCESSES IN NERVOUS SYSTEM. MOREOVER, EPIGENETIC THERAPIES USING EPIGENETIC MODIFYING COMPOUNDS ARE PROGRESSIVELY ADVANCED IN THE TREATMENTS OF DIVERSE DISEASES, INCLUDING CANCER AND NEUROLOGICAL DISEASES. IMPORTANTLY, THERE IS EMERGING EVIDENCE THAT A VARIETY OF GENES UNDERGO EPIGENETIC REGULATION VIA DNA METHYLATION AND HISTONE MODIFICATIONS WITHIN PERIPHERAL AND CENTRAL NERVOUS SYSTEMS, THEREBY CONTRIBUTING TO THE ALTERATIONS IN BOTH PAIN SENSITIVITY AND PHARMACOLOGICAL EFFICACY IN NEUROPATHIC PAIN. IN THIS REVIEW, WE WILL HIGHLIGHT THE EPIGENETIC GENE REGULATION UNDERLYING NEUROPATHIC PAIN, ESPECIALLY FOCUSING ON THE NEGATIVE SYMPTOMS. MOREOVER, WE WILL DISCUSS WHETHER EPIGENETIC MECHANISMS CAN SERVE AS A POTENTIAL TARGET TO TREAT NEUROPATHIC PAIN. 2015 19 2061 23 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 20 4333 29 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