1 4618 125 NERVE INJURY-INDUCED EPIGENETIC SILENCING OF OPIOID RECEPTORS CONTROLLED BY DNMT3A IN PRIMARY AFFERENT NEURONS. OPIOIDS ARE THE GOLD STANDARD FOR PHARMACOLOGICAL TREATMENT OF NEUROPATHIC PAIN, BUT THEIR ANALGESIC EFFECTS ARE UNSATISFACTORY IN PART DUE TO NERVE INJURY-INDUCED DOWNREGULATION OF OPIOID RECEPTORS IN DORSAL ROOT GANGLIA (DRG) NEURONS. HOW NERVE INJURY DRIVES SUCH DOWNREGULATION REMAINS ELUSIVE. DNA METHYLTRANSFERASE (DNMT)-TRIGGERED DNA METHYLATION REPRESSES GENE EXPRESSION. WE SHOW HERE THAT BLOCKING THE NERVE INJURY-INDUCED INCREASE IN DRG DNMT3A (A DE NOVO DNMT) RESCUED THE EXPRESSION OF OPRM1 AND OPRK1 MRNAS AND THEIR RESPECTIVE ENCODING MU-OPIOID RECEPTOR (MOR) AND KAPPA-OPIOID RECEPTOR (KOR) PROTEINS IN THE INJURED DRG. BLOCKING THIS INCREASE ALSO PREVENTED THE NERVE INJURY-INDUCED INCREASE IN DNA METHYLATION IN THE PROMOTER AND 5'-UNTRANSLATED REGION OF THE OPRM1 GENE IN THE INJURED DRG, RESTORED MORPHINE OR LOPERAMIDE (A PERIPHERAL ACTING MOR PREFERRING AGONIST) ANALGESIC EFFECTS, AND ATTENUATED THE DEVELOPMENT OF THEIR ANALGESIC TOLERANCE UNDER NEUROPATHIC PAIN CONDITIONS. MIMICKING THIS INCREASE REDUCED THE EXPRESSION OF OPRM1 AND OPRK1 MRNAS AND THEIR CODING MOR AND KOR IN DRG AND AUGMENTED MOR-GATED NEUROTRANSMITTER RELEASE FROM THE PRIMARY AFFERENTS. MECHANISTICALLY, DNMT3A REGULATION OF OPRM1 GENE EXPRESSION REQUIRED THE METHYL-CPG-BINDING PROTEIN 1, MBD1, AS MBD1 KNOCKOUT RESULTED IN THE DECREASED BINDING OF DNMT3A TO THE OPRM1 GENE PROMOTER AND BLOCKED THE DNMT3A-TRIGGERED REPRESSION OF OPRM1 GENE EXPRESSION IN DRG NEURONS. THESE DATA SUGGEST THAT DNMT3A IS REQUIRED FOR NERVE INJURY-INDUCED AND MBD1-MEDIATED EPIGENETIC SILENCING OF THE MOR AND KOR IN THE INJURED DRG. DNMT3A INHIBITION MAY SERVE AS A PROMISING ADJUVANT THERAPY FOR OPIOID USE IN NEUROPATHIC PAIN MANAGEMENT. 2017 2 2883 62 G9A INHIBITS CREB-TRIGGERED EXPRESSION OF MU OPIOID RECEPTOR IN PRIMARY SENSORY NEURONS FOLLOWING PERIPHERAL NERVE INJURY. NEUROPATHIC PAIN, A DISTRESSING AND DEBILITATING DISORDER, IS STILL POORLY MANAGED IN CLINIC. OPIOIDS, LIKE MORPHINE, REMAIN THE MAINSTAY OF PRESCRIBED MEDICATIONS IN THE TREATMENT OF THIS DISORDER, BUT THEIR ANALGESIC EFFECTS ARE HIGHLY UNSATISFACTORY IN PART DUE TO NERVE INJURY-INDUCED REDUCTION OF OPIOID RECEPTORS IN THE FIRST-ORDER SENSORY NEURONS OF DORSAL ROOT GANGLIA. G9A IS A REPRESSOR OF GENE EXPRESSION. WE FOUND THAT NERVE INJURY-INDUCED INCREASES IN G9A AND ITS CATALYZED REPRESSIVE MARKER H3K9M2 ARE RESPONSIBLE FOR EPIGENETIC SILENCING OF OPRM1, OPRK1, AND OPRD1 GENES IN THE INJURED DORSAL ROOT GANGLIA. BLOCKING THESE INCREASES RESCUED DORSAL ROOT GANGLIA OPRM1, OPRK1, AND OPRD1 GENE EXPRESSION AND MORPHINE OR LOPERAMIDE ANALGESIA AND PREVENTED THE DEVELOPMENT OF MORPHINE OR LOPERAMIDE-INDUCED ANALGESIC TOLERANCE UNDER NEUROPATHIC PAIN CONDITIONS. CONVERSELY, MIMICKING THESE INCREASES REDUCED THE EXPRESSION OF THREE OPIOID RECEPTORS AND PROMOTED THE MU OPIOID RECEPTOR-GATED RELEASE OF PRIMARY AFFERENT NEUROTRANSMITTERS. MECHANISTICALLY, NERVE INJURY-INDUCED INCREASES IN THE BINDING ACTIVITY OF G9A AND H3K9ME2 TO THE OPRM1 GENE WERE ASSOCIATED WITH THE REDUCED BINDING OF CYCLIC AMP RESPONSE ELEMENT BINDING PROTEIN TO THE OPRM1 GENE. THESE FINDINGS SUGGEST THAT G9A PARTICIPATES IN THE NERVE INJURY-INDUCED REDUCTION OF THE OPRM1 GENE LIKELY THROUGH G9A-TRIGGERED BLOCKAGE IN THE ACCESS OF CYCLIC AMP RESPONSE ELEMENT BINDING PROTEIN TO THIS GENE. 2016 3 2363 37 EPIGENETIC REGULATION OF SPINAL CORD GENE EXPRESSION CONTRIBUTES TO ENHANCED POSTOPERATIVE PAIN AND ANALGESIC TOLERANCE SUBSEQUENT TO CONTINUOUS OPIOID EXPOSURE. BACKGROUND: OPIOIDS HAVE BECOME THE MAINSTAY FOR TREATMENT OF MODERATE TO SEVERE PAIN AND ARE COMMONLY USED TO TREAT SURGICAL PAIN. WHILE OPIOID ADMINISTRATION HAS BEEN SHOWN TO CAUSE OPIOID-INDUCED HYPERALGESIA AND TOLERANCE, INTERACTIONS BETWEEN OPIOID ADMINISTRATION AND SURGERY WITH RESPECT TO THESE PROBLEMATIC ADAPTATIONS HAVE SCARCELY BEEN ADDRESSED. ACCUMULATING EVIDENCE SUGGESTS OPIOIDS AND NOCICEPTIVE SIGNALING MAY CONVERGE ON EPIGENETIC MECHANISMS IN SPINAL CORD TO ENHANCE OR PROLONG NEUROPLASTIC CHANGES. EPIGENETIC REGULATION OF BDNF (BRAIN-DERIVED NEUROTROPHIC FACTOR) AND PDYN (PRODYNORPHIN) GENES MAY BE INVOLVED. RESULTS: FOUR DAYS OF ASCENDING DOSES OF MORPHINE TREATMENT CAUSED OPIOID-INDUCED HYPERALGESIA AND REDUCED OPIOID ANALGESIC EFFICACY IN MICE. BOTH OPIOID-INDUCED HYPERALGESIA AND THE REDUCED OPIOID ANALGESIC EFFICACY WERE ENHANCED IN MICE THAT RECEIVED HINDPAW INCISIONS. THE EXPRESSION OF BDNF AND PDYN (QPCR) WAS INCREASED AFTER MORPHINE TREATMENT AND INCISION. CHROMATIN IMMUNOPRECIPITATION ASSAYS DEMONSTRATED THAT THE PDYN AND BDNF PROMOTERS WERE MORE STRONGLY ASSOCIATED WITH ACETYLATED H3K9 AFTER MORPHINE PLUS INCISION THAN IN THE MORPHINE OR INCISION ALONE GROUPS. SELECTIVE TROPOMYOSIN-RELATED KINASE B (ANA-12) AND KAPPA-OPIOID RECEPTOR (NOR-BINALTORPHIMINE) ANTAGONISTS WERE ADMINISTERED INTRATHECALLY, BOTH REDUCED HYPERALGESIA ONE OR THREE DAYS AFTER SURGERY. ADMINISTRATION OF ANA-12 OR NOR-BINALTORPHIMINE ATTENUATED THE DECREASED MORPHINE ANALGESIC EFFICACY ON DAY 1, BUT ONLY NOR-BINALTORPHIMINE WAS EFFECTIVE ON DAY 3 AFTER INCISION IN OPIOID-EXPOSED GROUP. COADMINISTRATION OF HISTONE ACETYLTRANSFERASE INHIBITOR ANACARDIC ACID DAILY WITH MORPHINE BLOCKED THE DEVELOPMENT OF OPIOID-INDUCED HYPERALGESIA AND ATTENUATED INCISION-ENHANCED HYPERALGESIA IN MORPHINE-TREATED MICE. ANACARDIC ACID HAD SIMILAR EFFECTS ON ANALGESIC TOLERANCE, SHOWING THE INVOLVEMENT OF HISTONE ACETYLATION IN THE INTERACTIONS DETECTED. CONCLUSIONS: SPINAL EPIGENETIC CHANGES INVOLVING BDNF AND PDYN MAY CONTRIBUTE TO THE ENHANCED POSTOPERATIVE NOCICEPTIVE SENSITIZATION AND ANALGESIC TOLERANCE OBSERVED AFTER CONTINUOUS OPIOID EXPOSURE. TREATMENTS BLOCKING THE EPIGENETICALLY MEDIATED UP-REGULATION OF THESE GENES OR ADMINISTRATION OF TRKB OR KAPPA-OPIOID RECEPTOR ANTAGONISTS MAY IMPROVE THE CLINICAL UTILITY OF OPIOIDS, PARTICULARLY AFTER SURGERY. 2016 4 4615 50 NERVE INJURY DIMINISHES OPIOID ANALGESIA THROUGH LYSINE METHYLTRANSFERASE-MEDIATED TRANSCRIPTIONAL REPRESSION OF MU-OPIOID RECEPTORS IN PRIMARY SENSORY NEURONS. THE MU-OPIOID RECEPTOR (MOR, ENCODED BY OPRM1) AGONISTS ARE THE MAINSTAY ANALGESICS FOR TREATING MODERATE TO SEVERE PAIN. NERVE INJURY CAUSES DOWN-REGULATION OF MORS IN THE DORSAL ROOT GANGLION (DRG) AND DIMINISHES THE OPIOID EFFECT ON NEUROPATHIC PAIN. HOWEVER, THE EPIGENETIC MECHANISMS UNDERLYING THE DIMINISHED MOR EXPRESSION CAUSED BY NERVE INJURY ARE NOT CLEAR. G9A (ENCODED BY EHMT2), A HISTONE 3 AT LYSINE 9 METHYLTRANSFERASE, IS A KEY CHROMATIN REGULATOR RESPONSIBLE FOR GENE SILENCING. IN THIS STUDY, WE DETERMINED THE ROLE OF G9A IN DIMINISHED MOR EXPRESSION AND OPIOID ANALGESIC EFFECTS IN ANIMAL MODELS OF NEUROPATHIC PAIN. WE FOUND THAT NERVE INJURY IN RATS INDUCED A LONG-LASTING REDUCTION IN THE EXPRESSION LEVEL OF MORS IN THE DRG BUT NOT IN THE SPINAL CORD. NERVE INJURY CONSISTENTLY INCREASED THE ENRICHMENT OF THE G9A PRODUCT HISTONE 3 AT LYSINE 9 DIMETHYLATION IN THE PROMOTER OF OPRM1 IN THE DRG. G9A INHIBITION OR SIRNA KNOCKDOWN FULLY REVERSED MOR EXPRESSION IN THE INJURED DRG AND POTENTIATED THE MORPHINE EFFECT ON PAIN HYPERSENSITIVITY INDUCED BY NERVE INJURY. IN MICE LACKING EHMT2 IN DRG NEURONS, NERVE INJURY FAILED TO REDUCE THE EXPRESSION LEVEL OF MORS AND THE MORPHINE EFFECT. IN ADDITION, G9A INHIBITION OR EHMT2 KNOCKOUT IN DRG NEURONS NORMALIZED NERVE INJURY-INDUCED REDUCTION IN THE INHIBITORY EFFECT OF THE OPIOID ON SYNAPTIC GLUTAMATE RELEASE FROM PRIMARY AFFERENT NERVES. OUR FINDINGS INDICATE THAT G9A CONTRIBUTES CRITICALLY TO TRANSCRIPTIONAL REPRESSION OF MORS IN PRIMARY SENSORY NEURONS IN NEUROPATHIC PAIN. G9A INHIBITORS MAY BE USED TO ENHANCE THE OPIOID ANALGESIC EFFECT IN THE TREATMENT OF CHRONIC NEUROPATHIC PAIN. 2016 5 5021 34 PERSISTENT PAIN MAINTAINS MORPHINE-SEEKING BEHAVIOR AFTER MORPHINE WITHDRAWAL THROUGH REDUCED MECP2 REPRESSION OF GLUA1 IN RAT CENTRAL AMYGDALA. AS LONG-TERM OPIOIDS ARE INCREASINGLY USED FOR CONTROL OF CHRONIC PAIN, HOW PAIN AFFECTS THE REWARDING EFFECT OF OPIOIDS AND HENCE RISK OF PRESCRIPTION OPIOID MISUSE AND ABUSE REMAINS A HEALTHCARE CONCERN AND A CHALLENGING ISSUE IN CURRENT PAIN MANAGEMENT. IN THIS STUDY, USING A RAT MODEL OF MORPHINE SELF-ADMINISTRATION, WE INVESTIGATED THE MOLECULAR MECHANISMS UNDERLYING THE IMPACT OF PAIN ON OPERANT BEHAVIOR OF MORPHINE INTAKE AND MORPHINE SEEKING BEFORE AND AFTER MORPHINE WITHDRAWAL. WE FOUND THAT RATS WITH PERSISTENT PAIN CONSUMED A SIMILAR AMOUNT OF DAILY MORPHINE TO THAT IN CONTROL RATS WITHOUT PAIN, BUT MAINTAINED THEIR LEVEL-PRESSING BEHAVIOR OF MORPHINE SEEKING AFTER ABSTINENCE OF MORPHINE AT 0.2 MG/KG, WHEREAS THIS BEHAVIOR WAS GRADUALLY DIMINISHED IN CONTROL RATS. IN THE CENTRAL NUCLEUS OF AMYGDALA (CEA), A LIMBIC STRUCTURE CRITICALLY INVOLVED IN THE AFFECTIVE DIMENSION OF PAIN, PROTEINS OF GLUA1 SUBUNITS OF GLUTAMATE AMPA RECEPTORS WERE UPREGULATED DURING MORPHINE WITHDRAWAL, AND VIRAL KNOCKDOWN OF CEA GLUA1 ELIMINATED THE MORPHINE-SEEKING BEHAVIOR IN WITHDRAWN RATS OF THE PAIN GROUP. CHROMATIN IMMUNOPRECIPITATION ANALYSIS REVEALED THAT THE METHYL CPG-BINDING PROTEIN 2 (MECP2) WAS ENRICHED IN THE PROMOTER REGION OF GRIA1 ENCODING GLUA1 AND THIS ENRICHMENT WAS SIGNIFICANTLY ATTENUATED IN WITHDRAWN RATS OF THE PAIN GROUP. FURTHERMORE, VIRAL OVEREXPRESSION OF CEA MECP2 REPRESSED THE GLUA1 LEVEL AND ELIMINATED THE MAINTENANCE OF MORPHINE-SEEKING BEHAVIOR AFTER MORPHINE WITHDRAWAL. THESE RESULTS SUGGEST DIRECT MECP2 REPRESSION OF GLUA1 FUNCTION AS A LIKELY MECHANISM FOR MORPHINE-SEEKING BEHAVIOR MAINTAINED BY LONG-LASTING AFFECTIVE PAIN AFTER MORPHINE WITHDRAWAL. 2015 6 4160 60 MECP2 EPIGENETIC SILENCING OF OPRM1 GENE IN PRIMARY SENSORY NEURONS UNDER NEUROPATHIC PAIN CONDITIONS. OPIOIDS ARE THE LAST OPTION FOR THE PHARMACOLOGICAL TREATMENT OF NEUROPATHIC PAIN, BUT THEIR ANTINOCICEPTIVE EFFECTS ARE LIMITED. DECREASED MU OPIOID RECEPTOR (MOR) EXPRESSION IN THE PERIPHERAL NERVOUS SYSTEM MAY CONTRIBUTE TO THIS. HERE, WE SHOWED THAT NERVE INJURY INDUCED HYPERMETHYLATION OF THE OPRM1 GENE PROMOTER AND AN INCREASED EXPRESSION OF METHYL-CPG BINDING PROTEIN 2 (MECP2) IN INJURED DORSAL ROOT GANGLION (DRG). THE DOWNREGULATION OF MOR IN THE DRG IS CLOSELY RELATED TO THE AUGMENTATION OF MECP2, AN EPIGENETIC REPRESSOR, WHICH COULD RECRUIT HDAC1 AND BIND TO THE METHYLATED REGIONS OF THE OPRM1 GENE PROMOTER. MECP2 KNOCKDOWN RESTORED THE EXPRESSION OF MOR IN INJURED DRG AND ENHANCED THE ANALGESIC EFFECT OF MORPHINE, WHILE THE MIMICKING OF THIS INCREASE VIA THE INTRATHECAL INFUSION OF VIRAL VECTOR-MEDIATED MECP2 WAS SUFFICIENT TO REDUCE MOR IN THE DRG. MOREOVER, HDAC1 INHIBITION WITH SUBEROYLANILIDE HYDROXAMIC ACID, AN HDAC INHIBITOR, ALSO PREVENTED MOR REDUCTION IN THE DRG OF NEUROPATHIC PAIN MICE, CONTRIBUTING TO THE AUGMENTATION OF MORPHINE ANALGESIA EFFECTS. MECHANISTICALLY, UPREGULATED MECP2 PROMOTES THE BINDING OF A HIGH LEVEL OF HDCA1 TO HYPERMETHYLATED REGIONS OF THE OPRM1 GENE PROMOTER, REDUCES THE ACETYLATION OF HISTONE H3 (ACH3) LEVELS OF THE OPRM1 GENE PROMOTER, AND ATTENUATES OPRM1 TRANSCRIPTION IN INJURED DRG. THUS, UPREGULATED MECP2 AND HDAC1 IN OPRM1 GENE PROMOTER SITES, NEGATIVELY REGULATES MOR EXPRESSION IN INJURED DRG, MITIGATING THE ANALGESIC EFFECT OF THE OPIOIDS. TARGETING MECP2/HDAC1 MAY THUS PROVIDE A NEW SOLUTION FOR IMPROVING THE THERAPEUTIC EFFECT OF OPIOIDS IN A CLINICAL SETTING. 2021 7 69 35 A MEDIAL PREFRONTAL CORTEX-NUCLEUS ACUMENS CORTICOTROPIN-RELEASING FACTOR CIRCUITRY FOR NEUROPATHIC PAIN-INCREASED SUSCEPTIBILITY TO OPIOID REWARD. RECENT STUDIES HAVE SHOWN THAT PERSISTENT PAIN FACILITATES THE RESPONSE TO MORPHINE REWARD. HOWEVER, THE CIRCUIT MECHANISM UNDERLYING THIS PROCESS REMAINS AMBIGUOUS. IN THIS STUDY, USING CHRONIC CONSTRICTION INJURY (CCI) OF THE SCIATIC NERVE IN MICE, WE FOUND THAT PERSISTENT NEUROPATHIC PAIN REDUCED THE MINIMUM NUMBER OF MORPHINE CONDITIONING SESSIONS REQUIRED TO INDUCE CONDITIONED PLACE PREFERENCE (CPP) BEHAVIOR. THIS DOSE OF MORPHINE HAD NO EFFECT ON THE PAIN THRESHOLD. IN THE MEDIAL PREFRONTAL CORTEX (MPFC), WHICH IS INVOLVED IN BOTH PAIN AND EMOTION PROCESSING, CORTICOTROPIN-RELEASING FACTOR (CRF) EXPRESSING NEURONAL ACTIVITY WAS INCREASED IN CCI MICE. CHEMOGENETIC INHIBITION OF MPFC CRF NEURONS REVERSED CCI-INDUCED MORPHINE CPP FACILITATION. FURTHERMORE, THE NUCLEUS ACUMENS (NAC) RECEIVED MPFC CRF FUNCTIONAL PROJECTIONS THAT EXERTED EXCITATORY EFFECTS ON NAC NEURONS. OPTOGENETIC INHIBITION OF MPCF NEURONAL TERMINALS OR LOCAL INFUSION OF THE CRF RECEPTOR 1 (CRFR1) ANTAGONIST IN THE NAC RESTORED THE EFFECTS OF NEUROPATHIC PAIN ON MORPHINE-INDUCED CPP BEHAVIOR, BUT NOT IN NORMAL MICE. ON A MOLECULAR LEVEL, IN CCI MICE, CRFR1 PROTEIN EXPRESSION WAS INCREASED IN THE NAC BY A HISTONE DIMETHYLTRANSFERASE G9A-MEDIATED EPIGENETIC MECHANISM. LOCAL G9A KNOCKDOWN INCREASED THE EXPRESSION OF CRFR1 AND MIMICKED CCI-INDUCED HYPERSENSITIVITY TO ACQUIRING MORPHINE CPP. TAKEN TOGETHER, THESE FINDINGS DEMONSTRATE A PREVIOUSLY UNKNOWN AND SPECIFIC MPFC CRF ENGAGEMENT OF NAC NEURONAL CIRCUITS, THE SENSITIZATION OF WHICH FACILITATES BEHAVIORAL RESPONSES TO MORPHINE REWARD IN NEUROPATHIC PAIN STATES VIA CRFR1S. 2018 8 4163 32 MECP2 REPRESSION OF G9A IN REGULATION OF PAIN AND MORPHINE REWARD. OPIOIDS ARE COMMONLY USED FOR PAIN RELIEF, BUT THEIR STRONG REWARDING EFFECTS DRIVE OPIOID MISUSE AND ABUSE. HOW PAIN AFFECTS THE LIABILITY OF OPIOID ABUSE IS UNKNOWN AT PRESENT. IN THIS STUDY, WE IDENTIFIED AN EPIGENETIC REGULATING CASCADE ACTIVATED BY BOTH PAIN AND THE OPIOID MORPHINE. BOTH PERSISTENT PAIN AND REPEATED MORPHINE UPREGULATED THE TRANSCRIPTIONAL REGULATOR MECP2 IN MOUSE CENTRAL NUCLEUS OF THE AMYGDALA (CEA). CHROMATIN IMMUNOPRECIPITATION ANALYSIS REVEALED THAT MECP2 BOUND TO AND REPRESSED THE TRANSCRIPTIONAL REPRESSOR HISTONE DIMETHYLTRANSFERASE G9A, REDUCING G9A-CATALYZED REPRESSIVE MARK H3K9ME2 IN CEA. REPRESSION OF G9A ACTIVITY INCREASED EXPRESSION OF BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF). BEHAVIORALLY, PERSISTENT INFLAMMATORY PAIN INCREASED THE SENSITIVITY TO ACQUIRING MORPHINE-INDUCED, REWARD-RELATED BEHAVIOR OF CONDITIONED PLACE PREFERENCE IN MICE. LOCAL VIRAL VECTOR-MEDIATED MECP2 OVEREXPRESSION, CRE-INDUCED G9A KNOCKDOWN, AND CEA APPLICATION OF BDNF MIMICKED, WHEREAS MECP2 KNOCKDOWN INHIBITED, THE PAIN EFFECT. THESE RESULTS SUGGEST THAT MECP2 DIRECTLY REPRESSES G9A AS A SHARED MECHANISM IN CENTRAL AMYGDALA FOR REGULATION OF EMOTIONAL RESPONSES TO PAIN AND OPIOID REWARD, AND FOR THEIR BEHAVIORAL INTERACTION. 2014 9 4511 38 MU OPIOID RECEPTOR-TRIGGERED NOTCH-1 ACTIVATION CONTRIBUTES TO MORPHINE TOLERANCE: ROLE OF NEURON-GLIA COMMUNICATION. THE DEVELOPMENT OF ANALGESIC TOLERANCE TO OPIOIDS IS AN IMPORTANT LIMITATION IN THE MANAGEMENT OF CHRONIC PAIN. SPINAL CORD GLIAL CELL ACTIVATION APPEARS TO PLAY A PIVOTAL ROLE IN THE DEVELOPMENT AND MAINTENANCE OF OPIOID TOLERANCE, INDICATING THE PRESENCE OF AN OPIOID-INDUCED NEURONAL-GLIAL INTERACTION; HOWEVER, HOW OPIOIDS DRIVE THIS CROSS-TALK IS STILL ELUSIVE. IN SEARCH OF TREATMENTS TO ATTENUATE MORPHINE ANALGESIC TOLERANCE, OUR RESEARCH FOCUSED ON THE ROLE OF NOTCH SIGNALING PATHWAY, ONE OF THE MOST IMPORTANT MECHANISMS OF CELL-TO-CELL INTERACTIONS, IN THE SPINAL DORSAL HORN AFTER MORPHINE REPEATED EXPOSURE AND WHETHER NOTCH INHIBITION ATTENUATES MORPHINE ANALGESIC TOLERANCE. DOUBLE IMMUNOFLUORESCENCE EXPERIMENTS ON SPINAL SECTIONS FROM MORPHINE-TOLERANT MICE SHOWED A NEURONAL LOCALIZATION OF NOTCH-1 RECEPTOR WHEREAS THE NOTCH LIGAND JAGGED WAS LOCALIZED ON NEIGHBORING ASTROCYTES. MORPHINE-INDUCED MU OPIOID RECEPTOR (MOR) STIMULATION TRIGGERED NOTCH-1 SIGNALING ACTIVATION AND THIS EVENT WAS MEDIATED BY ASTROCYTE JNK ACTIVATION. NOTCH-1 ACTIVATION SELECTIVELY REDUCED THE EXPRESSION OF HISTONE DEACETYLASE (HDAC)-1, RESULTING IN AN OVERPHOSPHORYLATION OF PKC AND ERK, KINASES INVOLVED IN MOR PHOSPHORYLATION AND INTERNALIZATION AFTER REPEATED MORPHINE EXPOSURE. NOTCH-1 SIGNALING INHIBITION, THROUGH INTRATHECAL ADMINISTRATION OF THE GAMMA-SECRETASE INHIBITOR, DAPT, COUNTERACTED PKC AND ERK OVERPHOSPHORYLATION, MOR INTERNALIZATION, AND ANALGESIC TOLERANCE. CONVERSELY, THE HDAC-1 INHIBITOR, LG325, FURTHER AGGRAVATED MOR INTERNALIZATION, PKC OVERPHOSPHORYLATION, AND ANALGESIC TOLERANCE.OUR FINDINGS IMPLICATE THE MOR-TRIGGERED NOTCH-1 SIGNALING IN PROMOTING MOR INTERNALIZATION AND MORPHINE ANALGESIC TOLERANCE BY EPIGENETIC REGULATION MECHANISMS. THESE DATA SUGGEST THAT NOTCH-1 INHIBITORS COULD REPRESENT AN INNOVATIVE THERAPEUTIC PERSPECTIVE FOR THE MANAGEMENT OF OPIOID TOLERANCE IN CHRONIC PAIN THERAPY. 2020 10 5574 60 ROLE OF MICRORNA-143 IN NERVE INJURY-INDUCED UPREGULATION OF DNMT3A EXPRESSION IN PRIMARY SENSORY NEURONS. PERIPHERAL NERVE INJURY INCREASED THE EXPRESSION OF THE DNA METHYLTRANSFERASE 3A (DNMT3A) MRNA AND ITS ENCODING DNMT3A PROTEIN IN INJURED DORSAL ROOT GANGLIA (DRG). THIS INCREASE IS CONSIDERED AS AN ENDOGENOUS INSTIGATOR IN NEUROPATHIC PAIN GENESIS THROUGH EPIGENETIC SILENCING OF PAIN-ASSOCIATED GENES (SUCH AS OPRM1) IN INJURED DRG. HOWEVER, HOW DRG DNMT3A IS INCREASED FOLLOWING PERIPHERAL NERVE INJURY IS STILL ELUSIVE. WE REPORTED HERE THAT PERIPHERAL NERVE INJURY CAUSED BY THE FIFTH SPINAL NERVE LIGATION (SNL) DOWNREGULATED MICRORNA (MIR)-143 EXPRESSION IN INJURED DRG. THIS DOWNREGULATION WAS REQUIRED FOR SNL-INDUCED DRG DNMT3A INCREASE AS RESCUING MIR-143 DOWNREGULATION THROUGH MICROINJECTION OF MIR-143 MIMICS INTO INJURED DRG BLOCKED THE SNL-INDUCED INCREASE IN DNMT3A AND RESTORED THE SNL-INDUCED DECREASES IN OPRM1 MRNA AND ITS ENCODING MU OPIOID RECEPTOR (MOR) IN INJURED DRG, IMPAIRED SPINAL CORD CENTRAL SENSITIZATION AND NEUROPATHIC PAIN, AND IMPROVED MORPHINE ANALGESIC EFFECTS FOLLOWING SNL. MIMICKING SNL-INDUCED DRG MIR-143 DOWNREGULATION THROUGH DRG MICROINJECTION OF MIR143 INHIBITORS IN NAIVE RATS INCREASED THE EXPRESSION OF DNMT3A AND REDUCED THE EXPRESSION OF OPRM1 MRNA AND MOR IN INJECTED DRG AND PRODUCED NEUROPATHIC PAIN-LIKE SYMPTOMS. THESE FINDINGS SUGGEST THAT MIR-143 IS A NEGATIVE REGULATOR IN DNMT3A EXPRESSION IN THE DRG UNDER NEUROPATHIC PAIN CONDITIONS AND MAY BE A POTENTIAL TARGET FOR THERAPEUTIC MANAGEMENT OF NEUROPATHIC PAIN. 2017 11 6424 46 THE TRANSCRIPTION FACTOR C/EBPBETA IN THE DORSAL ROOT GANGLION CONTRIBUTES TO PERIPHERAL NERVE TRAUMA-INDUCED NOCICEPTIVE HYPERSENSITIVITY. CHANGES IN GENE TRANSCRIPTION IN THE DORSAL ROOT GANGLION (DRG) AFTER NERVE TRAUMA CONTRIBUTE TO THE GENESIS OF NEUROPATHIC PAIN. WE REPORT THAT PERIPHERAL NERVE TRAUMA CAUSED BY CHRONIC CONSTRICTION INJURY (CCI) INCREASED THE ABUNDANCE OF THE TRANSCRIPTION FACTOR C/EBPBETA (CCAAT/ENHANCER BINDING PROTEIN BETA) IN THE DRG. BLOCKING THIS INCREASE MITIGATED THE DEVELOPMENT AND MAINTENANCE OF CCI-INDUCED MECHANICAL, THERMAL, AND COLD PAIN HYPERSENSITIVITIES WITHOUT AFFECTING BASAL RESPONSES TO ACUTE PAIN AND LOCOMOTOR ACTIVITY. CONVERSELY, MIMICKING THIS INCREASE PRODUCED HYPERSENSITIVITY TO MECHANICAL, THERMAL, OR COLD PAIN. IN THE IPSILATERAL DRG, C/EBPBETA PROMOTED A DECREASE IN THE ABUNDANCE OF THE VOLTAGE-GATED POTASSIUM CHANNEL SUBUNIT KV1.2 AND MU OPIOID RECEPTOR (MOR) AT THE MRNA AND PROTEIN LEVELS, WHICH WOULD BE PREDICTED TO INCREASE EXCITABILITY IN THE IPSILATERAL DRG NEURONS AND REDUCE THE EFFICACY OF MORPHINE ANALGESIA. THESE EFFECTS REQUIRED C/EPBBETA-MEDIATED TRANSCRIPTIONAL ACTIVATION OF EHMT2 (EUCHROMATIC HISTONE-LYSINE N-METHYLTRANSFERASE 2), WHICH ENCODES G9A, AN EPIGENETIC SILENCER OF THE GENES ENCODING KV1.2 AND MOR. BLOCKING THE INCREASE IN C/EBPBETA IN THE DRG IMPROVED MORPHINE ANALGESIA AFTER CCI. THESE RESULTS SUGGEST THAT C/EBPBETA IS AN ENDOGENOUS INITIATOR OF NEUROPATHIC PAIN AND COULD BE A POTENTIAL TARGET FOR THE PREVENTION AND TREATMENT OF THIS DISORDER. 2017 12 2364 38 EPIGENETIC REGULATION OF SPINAL CORD GENE EXPRESSION CONTROLS OPIOID-INDUCED HYPERALGESIA. BACKGROUND: THE LONG TERM USE OF OPIOIDS FOR THE TREATMENT OF PAIN LEADS TO A GROUP OF MALADAPTATIONS WHICH INCLUDES OPIOID-INDUCED HYPERALGESIA (OIH). OIH TYPICALLY RESOLVES WITHIN FEW DAYS AFTER CESSATION OF MORPHINE TREATMENT IN MICE BUT IS PROLONGED FOR WEEKS IF HISTONE DEACETYLASE (HDAC) ACTIVITY IS INHIBITED DURING OPIOID TREATMENT. THE PRESENT WORK SEEKS TO IDENTIFY GENE TARGETS SUPPORTING THE EPIGENETIC EFFECTS RESPONSIBLE FOR OIH PROLONGATION. RESULTS: MICE WERE TREATED WITH MORPHINE ACCORDING TO AN ASCENDING DOSE PROTOCOL. SOME MICE ALSO RECEIVED THE SELECTIVE HDAC INHIBITOR SUBEROYLANILIDE HYDROXAMIC ACID (SAHA) ADDITIONALLY. CHRONIC MORPHINE TREATMENT WITH SIMULTANEOUS HDAC INHIBITION ENHANCED OIH, AND SEVERAL SPINAL CORD GENES WERE UP-REGULATED. THE EXPRESSION OF BDNF (BRAIN-DERIVED NEUROTROPHIC FACTOR) AND PDYN (PRODYNORPHIN) WERE MOST CLOSELY RELATED TO THE OBSERVED BEHAVIORAL CHANGES. CHIP (CHROMATIN IMMUOPRECIPATION) ASSAYS DEMONSTRATED THAT PROMOTER REGIONS OF PDYN AND BDNF WERE STRONGLY ASSOCIATED WITH ACEH3K9 (ACETYLATED HISTONE H3 LYSINE9) AFTER MORPHINE AND SAHA TREATMENT. FURTHERMORE, MORPHINE TREATMENT CAUSED AN INCREASE IN SPINAL BDNF AND DYNORPHIN LEVELS, AND THESE LEVELS WERE FURTHER INCREASED IN SAHA TREATED MICE. THE SELECTIVE TRKB (TROPOMYOSIN-RECEPTOR-KINASE) ANTAGONIST ANA-12 REDUCED OIH WHEN GIVEN ONE OR SEVEN DAYS AFTER CESSATION OF MORPHINE. TREATMENT WITH THE SELECTIVE KAPPA OPIOID RECEPTOR ANTAGONIST NOR-BNI ALSO REDUCED ESTABLISHED OIH. THE CO-ADMINISTRATION OF EITHER RECEPTOR ANTAGONIST AGENT DAILY WITH MORPHINE RESULTED IN ATTENUATION OF HYPERALGESIA PRESENT ONE DAY AFTER CESSATION OF TREATMENT. ADDITIONALLY, REPEATED MORPHINE EXPOSURE INDUCED A RISE IN BDNF EXPRESSION THAT WAS ASSOCIATED WITH AN INCREASED NUMBER OF BDNF+ CELLS IN THE SPINAL CORD DORSAL HORN, SHOWING STRONG CO-LOCALIZATION WITH ACEH3K9 IN NEURONAL CELLS. LASTLY, SPINAL APPLICATION OF LOW DOSE BDNF OR DYNORPHIN A AFTER RESOLUTION OF OIH PRODUCED MECHANICAL HYPERSENSITIVITY, WITH NO EFFECT IN CONTROLS. CONCLUSIONS: THE PRESENT STUDY IDENTIFIED TWO GENES WHOSE EXPRESSION IS REGULATED BY EPIGENETIC MECHANISMS DURING MORPHINE EXPOSURE. TREATMENTS AIMED AT PREVENTING THE ACETYLATION OF HISTONES OR BLOCKING BDNF AND DYNORPHIN SIGNALING MAY REDUCE OIH AND IMPROVE LONG-TERM PAIN USING OPIOIDS. 2014 13 4850 34 OPIOIDS AND OPIOID RECEPTORS; UNDERSTANDING PHARMACOLOGICAL MECHANISMS AS A KEY TO THERAPEUTIC ADVANCES AND MITIGATION OF THE MISUSE CRISIS. OPIOIDS ARE A MAINSTAY IN ACUTE PAIN MANAGEMENT AND PRODUCE THEIR EFFECTS AND SIDE EFFECTS (E.G., TOLERANCE, OPIOID-USE DISORDER AND IMMUNE SUPPRESSION) BY INTERACTION WITH OPIOID RECEPTORS. I WILL DISCUSS OPIOID PHARMACOLOGY IN SOME CONTROVERSIAL AREAS OF ENQUIRY OF ANAESTHETIC RELEVANCE. THE MAIN OPIOID TARGET IS THE MICRO (MU,MOP) RECEPTOR BUT OTHER MEMBERS OF THE OPIOID RECEPTOR FAMILY, DELTA (DELTA; DOP) AND KAPPA (KAPPA; KOP) OPIOID RECEPTORS ALSO PRODUCE ANALGESIC ACTIONS. THESE ARE NALOXONE-SENSITIVE. THERE IS IMPORTANT CLINICAL DEVELOPMENT RELATING TO THE NOCICEPTIN/ORPHANIN FQ (NOP) RECEPTOR, AN OPIOID RECEPTOR THAT IS NOT NALOXONE-SENSITIVE. BETTER UNDERSTANDING OF THE DRIVERS FOR OPIOID EFFECTS AND SIDE EFFECTS MAY FACILITATE SEPARATION OF SIDE EFFECTS AND PRODUCTION OF SAFER DRUGS. OPIOIDS BIND TO THE RECEPTOR ORTHOSTERIC SITE TO PRODUCE THEIR EFFECTS AND CAN ENGAGE MONOMER OR HOMO-, HETERODIMER RECEPTORS. SOME LIGANDS CAN DRIVE ONE INTRACELLULAR PATHWAY OVER ANOTHER. THIS IS THE BASIS OF BIASED AGONISM (OR FUNCTIONAL SELECTIVITY). OPIOID ACTIONS AT THE ORTHOSTERIC SITE CAN BE MODULATED ALLOSTERICALLY AND POSITIVE ALLOSTERIC MODULATORS THAT ENHANCE OPIOID ACTION ARE IN DEVELOPMENT. AS WELL AS TARGETING LIGAND-RECEPTOR INTERACTION AND TRANSDUCTION, MODULATING RECEPTOR EXPRESSION AND HENCE FUNCTION IS ALSO TRACTABLE. THERE IS EVIDENCE FOR EPIGENETIC ASSOCIATIONS WITH DIFFERENT TYPES OF PAIN AND ALSO SUBSTANCE MISUSE. AS LONG AS THE OPIOID NARRATIVE IS DEFINED BY THE 'OPIOID CRISIS' THE DRIVE TO REMOVE THEM COULD GATHER PACE. THIS WILL DENY USE WHERE THEY ARE EFFECTIVE, AND ACCESS TO MORPHINE FOR PAIN RELIEF IN LOW INCOME COUNTRIES. 2023 14 2353 33 EPIGENETIC REGULATION OF OPIOID-INDUCED HYPERALGESIA, DEPENDENCE, AND TOLERANCE IN MICE. REPEATED ADMINISTRATION OF OPIOIDS SUCH AS MORPHINE INDUCES PERSISTENT BEHAVIORAL CHANGES INCLUDING OPIOID-INDUCED HYPERALGESIA (OIH), TOLERANCE, AND PHYSICAL DEPENDENCE. IN THE CURRENT WORK WE EXPLORED HOW THE BALANCE OF HISTONE ACETYLTRANSFERASE (HAT) VERSUS HISTONE DEACETYLASE (HDAC) MIGHT REGULATE THESE MORPHINE-INDUCED CHANGES. NOCICEPTIVE THRESHOLDS, ANALGESIA, AND PHYSICAL DEPENDENCE WERE ASSESSED DURING AND FOR A PERIOD OF SEVERAL WEEKS AFTER MORPHINE EXPOSURE. TO PROBE THE ROLES OF HISTONE ACETYLATION, THE HAT INHIBITOR CURCUMIN OR A SELECTIVE HDAC INHIBITOR SUBEROYLANILIDE HYDROXAMIC ACID (SAHA) WAS ADMINISTERED DAILY TO GROUPS OF ANIMALS. HISTONE ACETYLATION IN SPINAL CORD WAS ASSESSED BY WESTERN BLOT AND IMMUNOHISTOCHEMISTRY. CONCURRENT ADMINISTRATION OF CURCUMIN WITH MORPHINE FOR 4 DAYS SIGNIFICANTLY REDUCED DEVELOPMENT OF OPIOID-INDUCED MECHANICAL ALLODYNIA, THERMAL HYPERALGESIA, TOLERANCE, AND PHYSICAL DEPENDENCE. CONVERSELY, THE HDAC INHIBITOR SAHA ENHANCED THESE RESPONSES. INTERESTINGLY, SAHA TREATMENT AFTER THE TERMINATION OF OPIOID ADMINISTRATION SUSTAINED THESE BEHAVIORAL CHANGES FOR AT LEAST 4 WEEKS. HISTONE H3 ACETYLATION IN THE DORSAL HORN OF THE SPINAL CORD WAS INCREASED AFTER CHRONIC MORPHINE TREATMENT, BUT H4 ACETYLATION WAS UNCHANGED. MOREOVER, WE OBSERVED A DECREASE IN HDAC ACTIVITY IN THE SPINAL CORDS OF MORPHINE-TREATED MICE WHILE OVERALL HAT ACTIVITY WAS UNCHANGED, SUGGESTING A SHIFT TOWARD A STATE OF ENHANCED HISTONE ACETYLATION. PERSPECTIVE: THE CURRENT STUDY INDICATES THAT EPIGENETIC MECHANISMS PLAY A CRUCIAL ROLE IN OPIOID-INDUCED LONG-LASTING NEUROPLASTICITY. THESE RESULTS PROVIDE NEW SIGHT INTO UNDERSTANDING THE MECHANISMS OF OPIOID-INDUCED NEUROPLASTICITY AND SUGGEST NEW STRATEGIES TO LIMIT OPIOID ABUSE POTENTIAL AND INCREASE THE VALUE OF THESE DRUGS AS ANALGESICS. 2013 15 3315 24 HIPPOCAMPAL MU OPIOID RECEPTORS ARE MODULATED FOLLOWING COCAINE SELF-ADMINISTRATION IN RAT. COCAINE ADDICTION IS A COMPLEX PATHOLOGY INDUCED BY LONG-TERM BRAIN CHANGES. UNDERSTANDING THE NEUROCHEMICAL CHANGES UNDERLYING THE REINFORCING EFFECTS OF THIS DRUG OF ABUSE IS CRITICAL FOR REDUCING THE SOCIETAL BURDEN OF DRUG ADDICTION. THE MU OPIOID RECEPTOR PLAYS A MAJOR ROLE IN DRUG REWARD. THIS RECEPTOR IS MODULATED BY CHRONIC COCAINE TREATMENT IN SPECIFIC BRAIN STRUCTURES, BUT FEW STUDIES INVESTIGATED NEUROCHEMICAL ADAPTATIONS INDUCED BY VOLUNTARY COCAINE INTAKE. IN THIS STUDY, WE INVESTIGATED WHETHER INTRAVENOUS COCAINE-SELF ADMINISTRATION (0.33 MG/KG/INJECTION, FIXED-RATIO 1 [FR1], 10 DAYS) IN RATS INDUCES TRANSCRIPTIONAL AND FUNCTIONAL CHANGES OF THE MU OPIOID RECEPTOR IN REWARD-RELATED BRAIN REGIONS. EPIGENETIC PROCESSES WITH HISTONE MODIFICATIONS WERE EXAMINED FOR TWO ACTIVATING MARKS, H3K4ME3, AND H3K27AC. WE FOUND AN INCREASE OF MU OPIOID RECEPTOR GENE EXPRESSION ALONG WITH A POTENTIATION OF ITS FUNCTIONALITY IN HIPPOCAMPUS OF COCAINE SELF-ADMINISTERING ANIMALS COMPARED TO SALINE CONTROLS. CHROMATIN IMMUNOPRECIPITATION FOLLOWED BY QPCR REVEALED NO MODIFICATIONS OF THE HISTONE MARK H3K4ME3 AND H3K27AC LEVELS AT MU OPIOID RECEPTOR PROMOTER. OUR STUDY HIGHLIGHTS THE HIPPOCAMPUS AS AN IMPORTANT TARGET TO FURTHER INVESTIGATE NEUROADAPTIVE PROCESSES LEADING TO COCAINE ADDICTION. 2021 16 4854 37 OPRM1 METHYLATION CONTRIBUTES TO OPIOID TOLERANCE IN CANCER PATIENTS. CANCER PATIENTS IN PAIN REQUIRE HIGH DOSES OF OPIOIDS AND QUICKLY BECOME OPIOID-TOLERANT. PREVIOUS STUDIES HAVE SHOWN THAT CHRONIC CANCER PAIN AS WELL AS HIGH-DOSE OPIOID USE LEAD TO MU-OPIOID RECEPTOR DOWNREGULATION. IN THIS STUDY WE EXPLORE DOWNREGULATION OF THE MU-OPIOID RECEPTOR GENE (OPRM1), AS A MECHANISM FOR OPIOID TOLERANCE IN THE SETTING OF OPIOID USE FOR CANCER PAIN. WE DEMONSTRATE IN A COHORT OF 84 CANCER PATIENTS THAT HIGH-DOSE OPIOID USE CORRELATES WITH OPRM1 HYPERMETHYLATION IN PERIPHERAL LEUKOCYTES OF THESE PATIENTS. WE THEN REVERSE-TRANSLATE OUR CLINICAL FINDINGS BY CREATING A MOUSE CANCER PAIN MODEL; WE CREATE OPIOID TOLERANCE IN THE MOUSE CANCER MODEL TO MIMIC OPIOID TOLERANCE IN THE CANCER PATIENTS. USING THIS MODEL WE DETERMINE THE FUNCTIONAL SIGNIFICANCE OF OPRM1 METHYLATION ON CANCER PAIN AND OPIOID TOLERANCE. WE FOCUS ON 2 MAIN CELLS WITHIN THE CANCER MICROENVIRONMENT: THE CANCER CELL AND THE NEURON. WE SHOW THAT TARGETED RE-EXPRESSION OF MU-OPIOID RECEPTOR ON CANCER CELLS INHIBITS MECHANICAL AND THERMAL HYPERSENSITIVITY, AND PREVENTS OPIOID TOLERANCE, IN THE MOUSE MODEL. THE RESULTANT ANALGESIA AND PROTECTION AGAINST OPIOID TOLERANCE ARE LIKELY DUE TO PRESERVATION OF MU-OPIOID RECEPTOR EXPRESSION ON THE CANCER-ASSOCIATED NEURONS. PERSPECTIVE: WE DEMONSTRATE THAT EPIGENETIC REGULATION OF OPRM1 CONTRIBUTES TO OPIOID TOLERANCE IN CANCER PATIENTS, AND THAT TARGETED GENE THERAPY COULD TREAT CANCER-INDUCED NOCICEPTION AND OPIOID TOLERANCE IN A MOUSE CANCER MODEL. 2017 17 2885 43 G9A PARTICIPATES IN NERVE INJURY-INDUCED KCNA2 DOWNREGULATION IN PRIMARY SENSORY NEURONS. NERVE INJURY-INDUCED DOWNREGULATION OF VOLTAGE-GATED POTASSIUM CHANNEL SUBUNIT KCNA2 IN THE DORSAL ROOT GANGLION (DRG) IS CRITICAL FOR DRG NEURONAL EXCITABILITY AND NEUROPATHIC PAIN GENESIS. HOWEVER, HOW NERVE INJURY CAUSES THIS DOWNREGULATION IS STILL ELUSIVE. EUCHROMATIC HISTONE-LYSINE N-METHYLTRANSFERASE 2, ALSO KNOWN AS G9A, METHYLATES HISTONE H3 ON LYSINE RESIDUE 9 TO PREDOMINANTLY PRODUCE A DYNAMIC HISTONE DIMETHYLATION, RESULTING IN CONDENSED CHROMATIN AND GENE TRANSCRIPTIONAL REPRESSION. WE SHOWED HERE THAT BLOCKING NERVE INJURY-INDUCED INCREASE IN G9A RESCUED KCNA2 MRNA AND PROTEIN EXPRESSION IN THE AXOTOMIZED DRG AND ATTENUATED THE DEVELOPMENT OF NERVE INJURY-INDUCED PAIN HYPERSENSITIVITY. MIMICKING THIS INCREASE DECREASED KCNA2 MRNA AND PROTEIN EXPRESSION, REDUCED KV CURRENT, AND INCREASED EXCITABILITY IN THE DRG NEURONS AND LED TO SPINAL CORD CENTRAL SENSITIZATION AND NEUROPATHIC PAIN-LIKE SYMPTOMS. G9A MRNA IS CO-LOCALIZED WITH KCNA2 MRNA IN THE DRG NEURONS. THESE FINDINGS INDICATE THAT G9A CONTRIBUTES TO NEUROPATHIC PAIN DEVELOPMENT THROUGH EPIGENETIC SILENCING OF KCNA2 IN THE AXOTOMIZED DRG. 2016 18 2841 31 FREQUENCY OF THE DOPAMINE RECEPTOR D3 (RS6280) VS. OPIOID RECEPTOR MICRO1 (RS1799971) POLYMORPHIC RISK ALLELES IN PATIENTS WITH OPIOID USE DISORDER: A PREPONDERANCE OF DOPAMINERGIC MECHANISMS? WHILE OPIOIDS ARE A POWERFUL CLASS OF DRUGS THAT INHIBIT TRANSMISSION OF PAIN SIGNALS, THEIR USE IS TARNISHED BY THE CURRENT EPIDEMIC OF OPIOID USE DISORDER (OUD) AND OVERDOSE DEATHS. NOTWITHSTANDING PUBLISHED REPORTS, THERE REMAIN GAPS IN OUR KNOWLEDGE OF OPIOID RECEPTOR MECHANISMS AND THEIR ROLE IN OPIOID SEEKING BEHAVIOR. THUS, NOVEL INSIGHTS INTO MOLECULAR, NEUROGENETIC AND NEUROPHARMACOLOGICAL BASES OF OUD ARE NEEDED. WE PROPOSE THAT AN ADDICTIVE ENDOPHENOTYPE MAY NOT BE ENTIRELY SPECIFIC TO THE DRUG OF CHOICE BUT RATHER MAY BE GENERALIZABLE TO ALTERED BRAIN REWARD CIRCUITS IMPACTING NET MESOCORTICOLIMBIC DOPAMINE RELEASE. WE SUGGEST THAT GENETIC OR EPIGENETIC ALTERATIONS ACROSS DOPAMINERGIC REWARD SYSTEMS LEAD TO UNCONTROLLABLE SELF-ADMINISTRATION OF OPIOIDS AND OTHER DRUGS. FOR INSTANCE, DIMINISHED AVAILABILITY VIA KNOCKOUT OF DOPAMINE D3 RECEPTOR (DRD3) INCREASES VULNERABILITY TO OPIOIDS. BUILDING UPON THIS CONCEPT VIA THE USE OF A SOPHISTICATED POLYMORPHIC RISK ANALYSIS IN A HUMAN COHORT OF CHRONIC OPIOID USERS, WE FOUND EVIDENCE FOR A HIGHER FREQUENCY OF POLYMORPHIC DRD3 RISK ALLELE (RS6280) THAN OPIOID RECEPTOR MICRO1 (RS1799971). IN CONCLUSION, WHILE OPIOIDERGIC MECHANISMS ARE INVOLVED IN OUD, DOPAMINE-RELATED RECEPTORS MAY HAVE PRIMARY INFLUENCE ON OPIOID-SEEKING BEHAVIOR IN AFRICAN AMERICANS. THESE FINDINGS SUGGEST OUD-TARGETED NOVEL AND IMPROVED NEUROPHARMACOLOGICAL THERAPIES MAY REQUIRE FOCUS ON DRD3-MEDIATED REGULATION OF DOPAMINERGIC HOMEOSTASIS. 2022 19 1320 36 DEMETHYLATION REGULATION OF BDNF GENE EXPRESSION IN DORSAL ROOT GANGLION NEURONS IS IMPLICATED IN OPIOID-INDUCED PAIN HYPERSENSITIVITY IN RATS. REPEATED ADMINISTRATION OF MORPHINE MAY RESULT IN OPIOID-INDUCED HYPERSENSITIVITY (OIH), WHICH INVOLVES ALTERED EXPRESSION OF NUMEROUS GENES, INCLUDING BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) IN DORSAL ROOT GANGLION (DRG) NEURONS. YET, IT REMAINS UNCLEAR HOW BDNF EXPRESSION IS INCREASED IN DRG NEURONS AFTER REPEATED MORPHINE TREATMENT. DNA METHYLATION IS AN IMPORTANT MECHANISM OF EPIGENETIC CONTROL OF GENE EXPRESSION. IN THE CURRENT STUDY, WE HYPOTHESIZED THAT THE DEMETHYLATION REGULATION OF CERTAIN BDNF GENE PROMOTERS IN DRG NEURONS MAY CONTRIBUTE TO THE DEVELOPMENT OF OIH. REAL-TIME RT-PCR WAS USED TO ASSESS CHANGES IN THE MRNA TRANSCRIPTION LEVELS OF MAJOR BDNF EXONS INCLUDING EXON I, II, IV, VI, AS WELL AS TOTAL BDNF MRNA IN DRGS FROM RATS AFTER REPEATED MORPHINE ADMINISTRATION. THE LEVELS OF EXON IV AND TOTAL BDNF MRNA WERE SIGNIFICANTLY UPREGULATED BY REPEATED MORPHINE ADMINISTRATION, AS COMPARED TO THAT IN SALINE CONTROL GROUP. FURTHER, ELISA ARRAY AND IMMUNOCYTOCHEMISTRY STUDY REVEALED A ROBUST UPREGULATION OF BDNF PROTEIN EXPRESSION IN DRG NEURONS AFTER REPEATED MORPHINE EXPOSURE. CORRESPONDINGLY, THE METHYLATION LEVELS OF BDNF EXON IV PROMOTER SHOWED A SIGNIFICANT DOWNREGULATION BY MORPHINE TREATMENT. IMPORTANTLY, INTRATHECAL ADMINISTRATION OF A BDNF ANTIBODY, BUT NOT CONTROL IGG, SIGNIFICANTLY INHIBITED MECHANICAL HYPERSENSITIVITY THAT DEVELOPED IN RATS AFTER REPEATED MORPHINE TREATMENT. CONVERSELY, INTRATHECAL ADMINISTRATION OF AN INHIBITOR OF DNA METHYLATION, 5-AZA-2'-DEOXYCYTIDINE (5-AZA-DC) MARKEDLY UPREGULATED THE BDNF PROTEIN EXPRESSION IN DRG NEURONS AND ENHANCED THE MECHANICAL ALLODYNIA AFTER REPEATED MORPHINE EXPOSURE. TOGETHER, OUR FINDINGS SUGGEST THAT DEMETHYLATION REGULATION OF BDNF GENE PROMOTER MAY BE IMPLICATED IN THE DEVELOPMENT OF OIH THROUGH EPIGENETIC CONTROL OF BDNF EXPRESSION IN DRG NEURONS. 2016 20 1238 28 CURCUMIN BLOCKS CHRONIC MORPHINE ANALGESIC TOLERANCE AND BRAIN-DERIVED NEUROTROPHIC FACTOR UPREGULATION. THIS STUDY WAS CARRIED OUT BASED ON THE ASSUMPTION THAT BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) MAY COUNTERBALANCE THE ACTION OF MORPHINE IN THE BRAIN. MORPHINE ANALGESIC TOLERANCE AFTER DAILY ADMINISTRATIONS FOR SIX DAYS WAS BLOCKED BY INTRACEREBROVENTRICULAR INJECTION OF ANTI-BDNF IGG ON DAY 5, BUT NOT BY ADMINISTRATIONS ON DAYS 1-4. CHRONIC MORPHINE TREATMENT SIGNIFICANTLY INCREASED THE EXPRESSION OF EXON I AND IV BDNF TRANSCRIPTS, INDICATING DIFFERENTIAL REGULATION OF BDNF GENE EXPRESSION. DAILY ADMINISTRATION OF THE CREB-BINDING PROTEIN INHIBITOR CURCUMIN ABOLISHED THE UPREGULATION OF BDNF TRANSCRIPTION AND MORPHINE ANALGESIC TOLERANCE. THESE RESULTS SUGGEST THAT CURCUMIN MIGHT BE A PROMISING ADJUVANT TO REDUCE MORPHINE ANALGESIC TOLERANCE, AND THAT EPIGENETIC CONTROL COULD BE A NEW STRATEGY USEFUL FOR THE CONTROL OF THIS PROBLEM. 2009