1 1468 90 DISTINCT EPIGENETIC PROGRAMS REGULATE CARDIAC MYOCYTE DEVELOPMENT AND DISEASE IN THE HUMAN HEART IN VIVO. EPIGENETIC MECHANISMS AND TRANSCRIPTION FACTOR NETWORKS ESSENTIAL FOR DIFFERENTIATION OF CARDIAC MYOCYTES HAVE BEEN UNCOVERED. HOWEVER, RESHAPING OF THE EPIGENOME OF THESE TERMINALLY DIFFERENTIATED CELLS DURING FETAL DEVELOPMENT, POSTNATAL MATURATION, AND IN DISEASE REMAINS UNKNOWN. HERE, WE INVESTIGATE THE DYNAMICS OF THE CARDIAC MYOCYTE EPIGENOME DURING DEVELOPMENT AND IN CHRONIC HEART FAILURE. WE FIND THAT PRENATAL DEVELOPMENT AND POSTNATAL MATURATION ARE CHARACTERIZED BY A COOPERATION OF ACTIVE CPG METHYLATION AND HISTONE MARKS AT CIS-REGULATORY AND GENIC REGIONS TO SHAPE THE CARDIAC MYOCYTE TRANSCRIPTOME. IN CONTRAST, PATHOLOGICAL GENE EXPRESSION IN TERMINAL HEART FAILURE IS ACCOMPANIED BY CHANGES IN ACTIVE HISTONE MARKS WITHOUT MAJOR ALTERATIONS IN CPG METHYLATION AND REPRESSIVE CHROMATIN MARKS. NOTABLY, CIS-REGULATORY REGIONS IN CARDIAC MYOCYTES ARE SIGNIFICANTLY ENRICHED FOR CARDIOVASCULAR DISEASE-ASSOCIATED VARIANTS. THIS STUDY UNCOVERS DISTINCT LAYERS OF EPIGENETIC REGULATION NOT ONLY DURING PRENATAL DEVELOPMENT AND POSTNATAL MATURATION BUT ALSO IN DISEASED HUMAN CARDIAC MYOCYTES. 2018 2 804 28 CENTRAL ENDOTHELIN-1 CONFERS ANALGESIA BY TRIGGERING SPINAL NEURONAL HISTONE DEACETYLASE 5 (HDAC5) NUCLEAR EXCLUSION IN PERIPHERAL NEUROPATHIC PAIN IN MICE. THE RATIONALE OF SPINAL ADMINISTRATION OF ENDOTHELIN-1(ET-1) MEDIATED ANTI-NOCICEPTIVE EFFECT HAS NOT BEEN ELUCIDATED. ET-1 IS REPORTED TO PROMOTE NUCLEAR EFFLUXION OF HISTONE DEACETYLASE 5 (HDAC5) IN MYOCYTES, AND SPINAL HDAC5 IS IMPLICATED IN MODULATION OF PAIN PROCESSING. IN THIS STUDY, WE AIMED TO INVESTIGATE WHETHER CENTRAL ET-1 PLAYS AN ANTI-NOCICEPTIVE ROLE BY FACILITATING SPINAL HDAC5 NUCLEAR SHUTTLING UNDER NEUROPATHIC PAIN. HERE, WE DEMONSTRATE THAT UPREGULATING SPINAL ET-1 ATTENUATED THE NOCICEPTION INDUCED BY PARTIAL SCIATIC NERVE LIGATION SURGERY AND THIS ANALGESIC EFFECT MEDIATED BY ET-1 WAS ATTENUATED BY INTRATHECAL INJECTION OF ENDOTHELIN A RECEPTOR SELECTIVE INHIBITOR (BQ123) OR BY BLOCKING THE EXPORTATION OF NUCLEAR HDAC5 BY ADENO-ASSOCIATED VIRUSES TARGETING NEURONAL HDAC5 (AVV-HDAC5 S259/498A MUTANT). NOTABLY, ET-1 ADMINISTRATION INCREASED SPINAL GLUTAMATE ACID DECARBOXYLASES (GAD65/67) EXPRESSION VIA INITIATING HDAC5 NUCLEAR EXPORTATION AND INCREASED THE ACETYLATION OF HISTONE 3 AT LYSINE 9 (ACETYL-H3K9) IN THE PROMOTOR REGIONS OF SPINAL GAD1 AND GAD2 GENES. THIS WAS REVERSED BY BLOCKING ENDOTHELIN A RECEPTOR FUNCTION OR BY INHIBITING THE SPINAL NEURONAL NUCLEAR EXPORTATION OF HDAC5. THEREFORE, INDUCING SPINAL GABAERGIC NEURONAL HDAC5 NUCLEAR EXPORTATION MAY BE A NOVEL THERAPEUTIC APPROACH FOR MANAGING NEUROPATHIC PAIN. PERSPECTIVE: NEUROPATHIC PAIN IS INTRACTABLE IN A CLINICAL SETTING, AND EPIGENETIC REGULATION IS CONSIDERED TO CONTRIBUTE TO THIS PROCESSING. CHARACTERIZING THE ANTI-NOCICEPTIVE EFFECT OF ET-1 AND INVESTIGATING THE ASSOCIATED EPIGENETIC MECHANISMS IN ANIMAL MODELS MAY LEAD TO THE DEVELOPMENT OF NEW THERAPEUTIC STRATEGIES AND TARGETS FOR TREATING NEUROPATHIC PAIN. 2021 3 5532 28 RODENT MODELS OF GROUP 1 PULMONARY HYPERTENSION. WORLD HEALTH ORGANIZATION CATEGORY 1 PULMONARY HYPERTENSION (PH) IS A HETEROGENEOUS SYNDROME IN WHICH PH ORIGINATES IN THE SMALL PULMONARY ARTERIES AND IS THEREFORE ALSO REFERRED TO AS PULMONARY ARTERIAL HYPERTENSION (PAH). COMMON PATHOPHYSIOLOGIC FEATURES INCLUDE ENDOTHELIAL DYSFUNCTION, EXCESSIVE PROLIFERATION AND IMPAIRED APOPTOSIS OF VASCULAR CELLS, AND MITOCHONDRIAL FRAGMENTATION. THE PROLIFERATION/APOPTOSIS IMBALANCE RELATES IN PART TO ACTIVATION OF THE TRANSCRIPTION FACTORS HYPOXIA-INDUCIBLE FACTOR-1ALPHA (HIF-1ALPHA) AND NUCLEAR FACTOR OF ACTIVATED T-CELLS (NFAT) AND APOPTOSIS REPRESSORS, SUCH AS SURVIVIN. PERIVASCULAR INFLAMMATION, DISRUPTION OF ADVENTITIAL CONNECTIVE TISSUE, AND A GLYCOLYTIC METABOLIC SHIFT IN VASCULAR CELLS AND RIGHT VENTRICULAR MYOCYTES ALSO OCCUR IN PAH. THERE ARE IMPORTANT GENETIC AND EPIGENETIC PREDISPOSITIONS TO PAH. THIS REVIEW ASSESSES THE FIDELITY OF EXISTING ANIMAL MODELS TO HUMAN PAH. NO SINGLE MODEL CAN PERFECTLY RECAPITULATE THE MANY DIVERSE FORMS OF PH IN CATEGORY 1; HOWEVER, ACCEPTABLE MODELS EXIST. PAH INDUCED BY MONOCROTALINE AND CHRONIC HYPOXIA PLUS SU-5416 (CH+SU) IN RATS DISPLAY ENDOTHELIAL DYSFUNCTION, PROLIFERATION/APOPTOSIS IMBALANCE, AND DEVELOP THE GLYCOLYTIC METABOLIC PROFILE OF HUMAN PAH. HISTOLOGICALLY, CH+SU BEST CONFORMS TO PAH IN THAT IT DEVELOPS COMPLEX VASCULAR LESIONS, INCLUDING PLEXIFORM LESIONS. HOWEVER, THE MONOCROTALINE MODEL CAN BE INDUCED TO MANIFEST COMPLEX VASCULAR LESIONS AND DOES MANIFEST THE TENDENCY OF PAH PATIENTS TO DIE OF RIGHT VENTRICULAR (RV) FAILURE. MURINE MODELS OFFER GREATER MOLECULAR CERTAINTY THAN RAT MODELS BUT RARELY DEVELOP SIGNIFICANT PH, HAVE LESS RIGHT VENTRICULAR HYPERTROPHY (RVH) AND PULMONARY ARTERY (PA) REMODELING, AND ARE HARDER TO IMAGE AND CATHETERIZE. THE USE OF HIGH FIDELITY CATHETERIZATION AND ADVANCED IMAGING (MICROPET-CT, HIGH FREQUENCY ECHOCARDIOGRAPHY, HIGH FIELD STRENGTH MRI) AND FUNCTIONAL TESTING (TREADMILL) PERMIT ACCURATE PHENOTYPING OF EXPERIMENTAL MODELS OF PAH. PRECLINICAL TRIAL DESIGN IS AN IMPORTANT ASPECT OF TESTING EXPERIMENTAL PAH THERAPIES. THE USE OF MULTIPLE COMPLEMENTARY MODELS WITH ADEQUATE SAMPLE SIZE AND TRIAL DURATION AND APPROPRIATE ENDPOINTS ARE REQUIRED FOR PRECLINICAL ASSESSMENT OF EXPERIMENTAL PAH THERAPIES. 2013 4 598 25 BETA-ADRENERGIC SIGNALING PROMOTES TUMOR ANGIOGENESIS AND PROSTATE CANCER PROGRESSION THROUGH HDAC2-MEDIATED SUPPRESSION OF THROMBOSPONDIN-1. CHRONIC BEHAVIORAL STRESS AND BETA-ADRENERGIC SIGNALING HAVE BEEN SHOWN TO PROMOTE CANCER PROGRESSION, WHOSE UNDERLYING MECHANISMS ARE LARGELY UNCLEAR, ESPECIALLY THE INVOLVEMENT OF EPIGENETIC REGULATION. HISTONE DEACETYLASE-2 (HDAC2), AN EPIGENETIC REGULATOR, IS CRITICAL FOR STRESS-INDUCED CARDIAC HYPERTROPHY. IT IS UNKNOWN WHETHER IT IS NECESSARY FOR BETA-ADRENERGIC SIGNALING-PROMOTED CANCER PROGRESSION. USING XENOGRAFT MODELS, WE SHOWED THAT CHRONIC BEHAVIORAL STRESS AND BETA-ADRENERGIC SIGNALING PROMOTE ANGIOGENESIS AND PROSTATE CANCER PROGRESSION. HDAC2 WAS INDUCED BY BETA-ADRENERGIC SIGNALING IN VITRO AND IN MOUSE XENOGRAFTS. WE NEXT UNCOVERED THAT HDAC2 IS A DIRECT TARGET OF CAMP RESPONSE ELEMENT-BINDING PROTEIN (CREB) THAT IS ACTIVATED BY BETA-ADRENERGIC SIGNALING. NOTABLY, HDAC2 IS NECESSARY FOR BETA-ADRENERGIC SIGNALING TO INDUCE ANGIOGENESIS. WE FURTHER DEMONSTRATED THAT, UPON CREB ACTIVATION, HDAC2 REPRESSES THROMBOSPONDIN-1 (TSP1), A POTENT ANGIOGENESIS INHIBITOR, THROUGH EPIGENETIC REGULATION. TOGETHER, THESE DATA ESTABLISH A NOVEL PATHWAY THAT HDAC2 AND TSP1 ACT DOWNSTREAM OF CREB ACTIVATION IN BETA-ADRENERGIC SIGNALING TO PROMOTE CANCER PROGRESSION. 2017 5 3201 29 HDAC2 IN PRIMARY SENSORY NEURONS CONSTITUTIVELY RESTRAINS CHRONIC PAIN BY REPRESSING ALPHA2DELTA-1 EXPRESSION AND ASSOCIATED NMDA RECEPTOR ACTIVITY. ALPHA2DELTA-1 (ENCODED BY THE CACNA2D1 GENE) IS A NEWLY DISCOVERED NMDA RECEPTOR-INTERACTING PROTEIN AND IS THE THERAPEUTIC TARGET OF GABAPENTINOIDS (E.G., GABAPENTIN AND PREGABALIN) FREQUENTLY USED FOR TREATING PATIENTS WITH NEUROPATHIC PAIN. NERVE INJURY CAUSES SUSTAINED ALPHA2DELTA-1 UPREGULATION IN THE DORSAL ROOT GANGLION (DRG), WHICH PROMOTES NMDA RECEPTOR SYNAPTIC TRAFFICKING AND ACTIVATION IN THE SPINAL DORSAL HORN, A HALLMARK OF CHRONIC NEUROPATHIC PAIN. HOWEVER, LITTLE IS KNOWN ABOUT HOW NERVE INJURY INITIATES AND MAINTAINS THE HIGH EXPRESSION LEVEL OF ALPHA2DELTA-1 TO SUSTAIN CHRONIC PAIN. HERE, WE SHOW THAT NERVE INJURY CAUSED HISTONE HYPERACETYLATION AND DIMINISHED ENRICHMENT OF HISTONE DEACETYLASE-2 (HDAC2), BUT NOT HDAC3, AT THE CACNA2D1 PROMOTER IN THE DRG. STRIKINGLY, HDAC2 KNOCKDOWN OR CONDITIONAL KNOCKOUT IN DRG NEURONS IN MALE AND FEMALE MICE CONSISTENTLY INDUCED LONG-LASTING MECHANICAL PAIN HYPERSENSITIVITY, WHICH WAS READILY REVERSED BY BLOCKING NMDA RECEPTORS, INHIBITING ALPHA2DELTA-1 WITH GABAPENTIN OR DISRUPTING THE ALPHA2DELTA-1-NMDA RECEPTOR INTERACTION AT THE SPINAL CORD LEVEL. HDAC2 DELETION IN DRG NEURONS INCREASED HISTONE ACETYLATION LEVELS AT THE CACNA2D1 PROMOTER, UPREGULATED ALPHA2DELTA-1 IN THE DRG, AND POTENTIATED ALPHA2DELTA-1-DEPENDENT NMDA RECEPTOR ACTIVITY AT PRIMARY AFFERENT CENTRAL TERMINALS IN THE SPINAL DORSAL HORN. CORRESPONDINGLY, HDAC2 KNOCKDOWN-INDUCED PAIN HYPERSENSITIVITY WAS BLUNTED IN CACNA2D1 KNOCKOUT MICE. THUS, OUR FINDINGS REVEAL THAT HDAC2 FUNCTIONS AS A PIVOTAL TRANSCRIPTIONAL REPRESSOR OF NEUROPATHIC PAIN VIA CONSTITUTIVELY SUPPRESSING ALPHA2DELTA-1 EXPRESSION AND ENSUING PRESYNAPTIC NMDA RECEPTOR ACTIVITY IN THE SPINAL CORD. HDAC2 ENRICHMENT LEVELS AT THE CACNA2D1 PROMOTER IN DRG NEURONS CONSTITUTE A UNIQUE EPIGENETIC MECHANISM THAT GOVERNS ACUTE-TO-CHRONIC PAIN TRANSITION.SIGNIFICANCE STATEMENT EXCESS ALPHA2DELTA-1 PROTEINS PRODUCED AFTER NERVE INJURY DIRECTLY INTERACT WITH GLUTAMATE NMDA RECEPTORS TO POTENTIATE SYNAPTIC NMDA RECEPTOR ACTIVITY IN THE SPINAL CORD, A PROMINENT MECHANISM OF NERVE PAIN. BECAUSE ALPHA2DELTA-1 UPREGULATION AFTER NERVE INJURY IS LONG LASTING, GABAPENTINOIDS RELIEVE PAIN SYMPTOMS ONLY TEMPORARILY. OUR STUDY DEMONSTRATES FOR THE FIRST TIME THE UNEXPECTED ROLE OF INTRINSIC HDAC2 ACTIVITY AT THE ALPHA2DELTA-1 GENE PROMOTER IN LIMITING ALPHA2DELTA-1 GENE TRANSCRIPTION, NMDA RECEPTOR-DEPENDENT SYNAPTIC PLASTICITY, AND CHRONIC PAIN DEVELOPMENT AFTER NERVE INJURY. THESE FINDINGS CHALLENGE THE PREVAILING VIEW ABOUT THE ROLE OF GENERAL HDAC ACTIVITY IN PROMOTING CHRONIC PAIN. RESTORING THE REPRESSIVE HDAC2 FUNCTION AND/OR REDUCING HISTONE ACETYLATION AT THE ALPHA2DELTA-1 GENE PROMOTER IN PRIMARY SENSORY NEURONS COULD LEAD TO LONG-LASTING RELIEF OF NERVE PAIN. 2022 6 2448 25 EPIGENETIC SUPPRESSION OF GAD65 EXPRESSION MEDIATES PERSISTENT PAIN. CHRONIC PAIN IS A COMMON NEUROLOGICAL DISEASE INVOLVING LASTING, MULTIFACETED MALADAPTATIONS RANGING FROM GENE MODULATION TO SYNAPTIC DYSFUNCTION AND EMOTIONAL DISORDERS. SUSTAINED PATHOLOGICAL STIMULI IN MANY DISEASES ALTER THE OUTPUT ACTIVITIES OF CERTAIN GENES THROUGH EPIGENETIC MODIFICATIONS, BUT IT IS UNCLEAR HOW EPIGENETIC MECHANISMS OPERATE IN THE DEVELOPMENT OF CHRONIC PAIN. WE SHOW HERE THAT IN THE RAT BRAINSTEM NUCLEUS RAPHE MAGNUS, WHICH IS IMPORTANT FOR CENTRAL MECHANISMS OF CHRONIC PAIN, PERSISTENT INFLAMMATORY AND NEUROPATHIC PAIN EPIGENETICALLY SUPPRESSES GAD2 (ENCODING GLUTAMIC ACID DECARBOXYLASE 65 (GAD65)) TRANSCRIPTION THROUGH HISTONE DEACETYLASE (HDAC)-MEDIATED HISTONE HYPOACETYLATION, RESULTING IN IMPAIRED GAMMA-AMINOBUTYRIC ACID (GABA) SYNAPTIC INHIBITION. GAD2 KNOCKOUT MICE SHOWED SENSITIZED PAIN BEHAVIOR AND IMPAIRED GABA SYNAPTIC FUNCTION IN THEIR BRAINSTEM NEURONS. IN WILD-TYPE BUT NOT GAD2 KNOCKOUT MICE, HDAC INHIBITORS STRONGLY INCREASED GAD65 ACTIVITY, RESTORED GABA SYNAPTIC FUNCTION AND RELIEVED SENSITIZED PAIN BEHAVIOR. THESE FINDINGS SUGGEST GAD65 AND HDACS AS POTENTIAL THERAPEUTIC TARGETS IN AN EPIGENETIC APPROACH TO THE TREATMENT OF CHRONIC PAIN. 2011 7 2452 23 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 8 687 28 BRAINSTEM BRAIN-DERIVED NEUROTROPHIC FACTOR SIGNALING IS REQUIRED FOR HISTONE DEACETYLASE INHIBITOR-INDUCED PAIN RELIEF. OUR PREVIOUS STUDY DEMONSTRATED THAT PERSISTENT PAIN CAN EPIGENETICALLY SUPPRESS THE TRANSCRIPTION OF GAD2 [ENCODING GLUTAMIC ACID DECARBOXYLASE 65 (GAD65)] AND CONSEQUENTLY IMPAIR THE INHIBITORY FUNCTION OF GABAERGIC SYNAPSES IN CENTRAL PAIN-MODULATING NEURONS. THIS CONTRIBUTES TO THE DEVELOPMENT OF PERSISTENT PAIN SENSITIZATION. HISTONE DEACETYLASE (HDAC) INHIBITORS INCREASED GAD65 ACTIVITY CONSIDERABLY, RESTORED GABA SYNAPTIC FUNCTION, AND RENDERED SENSITIZED PAIN BEHAVIOR LESS PRONOUNCED. HOWEVER, THE MOLECULAR MECHANISMS BY WHICH HDAC REGULATES GABAERGIC TRANSMISSION THROUGH GAD65 UNDER PAIN CONDITIONS ARE UNKNOWN. THIS WORK SHOWED THAT HDAC INHIBITOR-INDUCED INCREASES IN COLOCALIZATION OF GAD65 AND SYNAPTIC PROTEIN SYNAPSIN I ON THE PRESYNAPTIC AXON TERMINALS OF THE NUCLEUS RAPHE MAGNUS (NRM) WERE BLOCKED BY A TRKB RECEPTOR ANTAGONIST K252A [(9S,10R,12R)-2,3,9,10,11,12-HEXAHYDRO-10-HYDROXY-9-METHYL-1-OXO-9,12-EPOXY-1H-DIINDOLO[1,2,3-FG:3',2',1'-KL]PYRROLO[3,4-I][1,6]BENZODIAZOCINE-10-CARBOXYLIC ACID METHYL ESTER], INDICATING THAT BDNF-TRKB SIGNALING MAY BE REQUIRED IN GAD65 MODULATION OF GABA SYNAPTIC FUNCTION. AT THE BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) PROMOTER, HDAC INHIBITORS INDUCED SIGNIFICANT INCREASES IN H3 HYPERACETYLATION, CONSISTENT WITH THE INCREASE IN BDNF MRNA AND TOTAL PROTEINS. ALTHOUGH EXOGENOUS BDNF FACILITATED GABA MINIATURE INHIBITORY POSTSYNAPTIC CURRENTS AND GAD65 ACCUMULATION IN NRM NEURONAL SYNAPSES IN NORMAL RATS, IT FAILED TO DO SO IN ANIMALS SUBJECTED TO PERSISTENT INFLAMMATION. IN ADDITION, BLOCKADE OF THE TRKB RECEPTOR WITH K252A HAS NO EFFECT ON MINIATURE INHIBITORY POSTSYNAPTIC CURRENTS AND SYNAPTIC GAD65 ACCUMULATION UNDER NORMAL CONDITIONS. IN ADDITION, THE ANALGESIC EFFECTS OF HDAC INHIBITORS ON BEHAVIOR WERE BLOCKED BY NRM INFUSION OF K252A. THESE FINDINGS SUGGEST THAT BDNF-TRKB SIGNALING IS REQUIRED FOR DRUGS THAT REVERSE THE EPIGENETIC EFFECTS OF CHRONIC PAIN AT THE GENE LEVEL, SUCH AS HDAC INHIBITORS. 2015 9 3721 27 INHIBITION OF CLASS II HISTONE DEACETYLASES IN THE SPINAL CORD ATTENUATES INFLAMMATORY HYPERALGESIA. BACKGROUND: SEVERAL CLASSES OF HISTONE DEACETYLASES (HDACS) ARE EXPRESSED IN THE SPINAL CORD THAT IS A CRITICAL STRUCTURE OF THE NOCICEPTIVE PATHWAY. HDAC-REGULATED HISTONE ACETYLATION IS AN IMPORTANT COMPONENT OF CHROMATIN REMODELING LEADING TO EPIGENETIC REGULATION OF GENE TRANSCRIPTION. TO UNDERSTAND THE ROLE OF HISTONE ACETYLATION IN EPIGENETIC REGULATION OF PATHOLOGICAL PAIN, WE HAVE STUDIED THE IMPACT OF DIFFERENT CLASSES OF HDACS IN THE SPINAL CORD ON INFLAMMATORY HYPERALGESIA INDUCED BY COMPLETE FREUND'S ADJUVANT (CFA). RESULTS: WE INTRATHECALLY APPLIED INHIBITORS SPECIFIC TO DIFFERENT CLASSES OF HDACS AND EVALUATED THEIR IMPACT ON INFLAMMATORY HYPERALGESIA. PRE-INJECTED INHIBITORS TARGETING CLASS I AS WELL AS II (SAHA, TSA, LAQ824) OR IIA (VPA, 4-PB) HDACS SIGNIFICANTLY DELAYED THE THERMAL HYPERALGESIA INDUCED BY UNILATERAL CFA INJECTION IN THE HINDPAW. EXISTING HYPERALGESIA INDUCED BY CFA WAS ALSO ATTENUATED BY THE HDAC INHIBITORS (HDACIS). IN CONTRAST, THESE INHIBITORS DID NOT INTERFERE WITH THE THERMAL RESPONSE EITHER IN NAIVE ANIMALS, OR ON THE CONTRALATERAL SIDE OF INFLAMED ANIMALS. INTERESTINGLY, MS-275 THAT SPECIFICALLY INHIBITS CLASS I HDACS FAILED TO ALTER THE HYPERALGESIA ALTHOUGH IT INCREASED HISTONE 3 ACETYLATION IN THE SPINAL CORD AS SAHA DID. USING IMMUNOBLOT ANALYSIS, WE FURTHER FOUND THAT THE LEVELS OF CLASS IIA HDAC MEMBERS (HDAC4, 5, 7, 9) IN THE SPINAL DORSAL HORN WERE UPREGULATED FOLLOWING CFA INJECTION WHILE THOSE OF CLASS I HDAC MEMBERS (HDAC1, 2, 3) REMAINED STABLE OR WERE SLIGHTLY REDUCED. CONCLUSIONS: OUR DATA SUGGEST THAT ACTIVITY OF CLASS II HDACS IN THE SPINAL CORD IS CRITICAL TO THE INDUCTION AND MAINTENANCE OF INFLAMMATORY HYPERALGESIA INDUCED BY CFA, WHILE ACTIVITY OF CLASS I HDACS MAY BE UNNECESSARY. COMPARISON OF THE EFFECTS OF HDACIS SPECIFIC TO CLASS II AND IIA AS WELL AS THE EXPRESSION PATTERN OF DIFFERENT HDACS IN THE SPINAL CORD IN RESPONSE TO CFA SUGGESTS THAT THE MEMBERS OF CLASS IIA HDACS MAY BE POTENTIAL TARGETS FOR ATTENUATING PERSISTENT INFLAMMATORY PAIN. 2010 10 2745 23 EXPRESS: HISTONE HYPERACETYLATION MODULATES SPINAL TYPE II METABOTROPIC GLUTAMATE RECEPTOR ALLEVIATING STRESS-INDUCED VISCERAL HYPERSENSITIVITY IN FEMALE RATS. STRESS IS OFTEN A TRIGGER TO EXACERBATE CHRONIC PAIN INCLUDING VISCERAL HYPERSENSITIVITY ASSOCIATED WITH IRRITABLE BOWEL SYNDROME, A FEMALE PREDOMINANT FUNCTIONAL BOWEL DISORDER. EPIGENETIC MECHANISMS THAT MEDIATE STRESS RESPONSES ARE A POTENTIAL TARGET TO INTERFERE WITH VISCERAL PAIN. THE PURPOSE OF THIS STUDY WAS TO EXAMINE THE EFFECT OF A HISTONE DEACETYLASE INHIBITOR, SUBEROYLANILIDE HYDROXAMIC ACID, ON VISCERAL HYPERSENSITIVITY INDUCED BY A SUBCHRONIC STRESSOR IN FEMALE RATS AND TO INVESTIGATE THE INVOLVEMENT OF SPINAL GLUTAMATE RECEPTORS. THREE DAILY SESSIONS OF FORCED SWIM INDUCED VISCERAL HYPERSENSITIVITY. INTRATHECAL SUBEROYLANILIDE HYDROXAMIC ACID PREVENTED OR REVERSED THE STRESS-INDUCED VISCERAL HYPERSENSITIVITY, INCREASED SPINAL HISTONE 3 ACETYLATION AND INCREASED MGLUR2 AND MGLUR3 EXPRESSION. CHROMATIN IMMUNOPRECIPITATION (CHIP) ANALYSIS REVEALED ENRICHMENT OF H3K9AC AND H3K18AC AT SEVERAL PROMOTER GRM2 AND GRM3 REGIONS. THE MGLUR2/3 ANTAGONIST LY341495 REVERSED THE INHIBITORY EFFECT OF SUBEROYLANILIDE HYDROXAMIC ACID ON THE STRESS-INDUCED VISCERAL HYPERSENSITIVITY. IN SURPRISING CONTRAST, STRESS AND/OR SUBEROYLANILIDE HYDROXAMIC ACID HAD NO EFFECT ON SPINAL NMDA RECEPTOR EXPRESSION OR FUNCTION. THESE DATA REVEAL HISTONE MODIFICATION MODULATES MGLUR2/3 EXPRESSION IN THE SPINAL CORD TO ATTENUATE STRESSINDUCED VISCERAL HYPERSENSITIVITY. HDAC INHIBITORS MAY PROVIDE A POTENTIAL APPROACH TO RELIEVE VISCERAL HYPERSENSITIVITY ASSOCIATED WITH IRRITABLE BOWEL SYNDROME. 2016 11 1441 28 DIFFERENTIAL REGULATION OF K(CA) 2.1 (KCNN1) K(+) CHANNEL EXPRESSION BY HISTONE DEACETYLASES IN ATRIAL FIBRILLATION WITH CONCOMITANT HEART FAILURE. ATRIAL FIBRILLATION (AF) WITH CONCOMITANT HEART FAILURE (HF) POSES A SIGNIFICANT THERAPEUTIC CHALLENGE. MECHANISM-BASED APPROACHES MAY OPTIMIZE AF THERAPY. SMALL-CONDUCTANCE, CALCIUM-ACTIVATED K(+) (K(CA) , KCNN) CHANNELS CONTRIBUTE TO CARDIAC ACTION POTENTIAL REPOLARIZATION. KCNN1 EXHIBITS PREDOMINANT ATRIAL EXPRESSION AND IS DOWNREGULATED IN CHRONIC AF PATIENTS WITH PRESERVED CARDIAC FUNCTION. EPIGENETIC REGULATION IS SUGGESTED BY AF SUPPRESSION FOLLOWING HISTONE DEACETYLASE (HDAC) INHIBITION. WE HYPOTHESIZED THAT HDAC-DEPENDENT KCNN1 REMODELING CONTRIBUTES TO ARRHYTHMOGENESIS IN AF COMPLICATED BY HF. THE AIM OF THIS STUDY WAS TO ASSESS KCNN1 AND HDAC1-7 AND 9 TRANSCRIPT LEVELS IN AF/HF PATIENTS AND IN A PIG MODEL OF ATRIAL TACHYPACING-INDUCED AF WITH REDUCED LEFT VENTRICULAR FUNCTION. IN HL-1 ATRIAL MYOCYTES, TACHYPACING AND ANTI-HDAC SIRNAS WERE EMPLOYED TO INVESTIGATE EFFECTS ON KCNN1 MRNA LEVELS. KCNN1 EXPRESSION DISPLAYED SIDE-SPECIFIC REMODELING IN AF/HF PATIENTS WITH UPREGULATION IN LEFT AND SUPPRESSION IN RIGHT ATRIUM. IN PIGS, KCNN1 REMODELING SHOWED INTERMEDIATE PHENOTYPES. HDAC LEVELS WERE DIFFERENTIALLY ALTERED IN HUMANS AND PIGS, REFLECTING HIGHLY VARIABLE EPIGENETIC REGULATION. TACHYPACING RECAPITULATED DOWNREGULATION OF HDACS 1, 3, 4, 6, AND 7 WITH A TENDENCY TOWARDS REDUCED KCNN1 LEVELS IN VITRO, INDICATING THAT ATRIAL HIGH RATES INDUCE REMODELING. FINALLY, KCNN1 EXPRESSION WAS DECREASED BY KNOCKDOWN OF HDACS 2, 3, 6, AND 7 AND ENHANCED BY GENETIC HDAC9 INACTIVATION, WHILE ANTI-HDAC 1, 4, AND 5 SIRNAS DID NOT AFFECT KCNN1 TRANSCRIPT LEVELS. IN CONCLUSION, KCNN1 AND HDAC EXPRESSION IS DIFFERENTIALLY REMODELED IN AF COMPLICATED BY HF. DIRECT REGULATION OF KCNN1 BY HDACS IN ATRIAL MYOCYTES PROVIDES A BASIS FOR MECHANISM-BASED ANTIARRHYTHMIC THERAPY. 2021 12 201 33 ACTIVATING TRANSCRIPTION FACTOR 3 PROTECTS AGAINST PRESSURE-OVERLOAD HEART FAILURE VIA THE AUTOPHAGY MOLECULE BECLIN-1 PATHWAY. ACTIVATING TRANSCRIPTION FACTOR 3 (ATF3), A CAMP RESPONSE ELEMENT-BINDING PROTEIN/ATF FAMILY TRANSCRIPTION FACTORS MEMBER, HAS BEEN IMPLICATED IN THE CARDIOVASCULAR AND INFLAMMATORY SYSTEM AND IS RAPIDLY INDUCED BY ISCHEMIC-REPERFUSION INJURIES. WE PERFORMED TRANSVERSE AORTIC BANDING (TAB) EXPERIMENTS USING ATF3 GENE-DELETED MICE (ATF3(-/-)) AND WILD-TYPE (WT) MICE TO DETERMINE WHAT EFFECT IT MIGHT HAVE ON HEART FAILURE INDUCED BY PRESSURE OVERLOADING. COMPARED WITH THE WT MICE, ATF3(-/-) MICE WERE FOUND BY ECHOCARDIOGRAPHY TO HAVE DECREASED LEFT VENTRICULAR CONTRACTILITY WITH LOSS OF NORMAL CARDIAC HYPERTROPHIC REMODELING. THE ATF3(-/-) MICE HAD GREATER NUMBERS OF TERMINAL DEOXYNUCLEOTIDYL TRANSFERASE-MEDIATED DIGOXIGENIN-DEOXYURIDINE NICK-END LABELING-POSITIVE CELLS AND HIGHER LEVELS OF ACTIVATED CASPASE-3, AS WELL AS MORE APOPTOSIS. RESTORATION OF ATF3 EXPRESSION IN THE HEART OF ATF3(-/-) MICE BY ADENOVIRUS-INDUCED ATF3 TREATMENT SIGNIFICANTLY IMPROVED CARDIAC CONTRACTILITY AFTER TAB. THE RESULTS FROM MOLECULAR AND BIOCHEMICAL ANALYSES, INCLUDING CHROMATIN IMMUNE-PRECIPITATION AND IN VITRO /IN VIVO PROMOTER ASSAYS, SHOWED THAT ATF3 BOUND TO THE ATF/CAMP RESPONSE ELEMENT OF THE BECLIN-1 PROMOTER AND THAT ATF3 REDUCED AUTOPHAGY VIA SUPPRESSION OF THE BECLIN-1-DEPENDENT PATHWAY. FURTHERMORE, INFUSION OF TERT-BUTYLHYDROQUINONE (TBHQ), A SELECTIVE ATF3 INDUCER, INCREASED THE EXPRESSION OF ATF3 VIA THE NUCLEAR FACTOR ERYTHROID 2-RELATED TRANSCRIPTIONAL FACTOR, INHIBITED TAB-INDUCED CARDIAC DILATATION, AND INCREASED LEFT VENTRICULAR CONTRACTILITY, THEREBY RESCUING HEART FAILURE. OUR STUDY IDENTIFIED A NEW EPIGENETIC REGULATION MEDIATED BY THE STRESS-INDUCIBLE GENE ATF3 ON TAB-INDUCED CARDIAC DYSFUNCTION. THESE FINDINGS SUGGEST THAT THE ATF3 ACTIVATOR TBHQ MAY HAVE THERAPEUTIC POTENTIAL FOR THE TREATMENT OF PRESSURE-OVERLOAD HEART FAILURE INDUCED BY CHRONIC HYPERTENSION OR OTHER PRESSURE OVERLOAD MECHANISMS. 2014 13 245 35 ADRENERGIC REPRESSION OF THE EPIGENETIC READER MECP2 FACILITATES CARDIAC ADAPTATION IN CHRONIC HEART FAILURE. RATIONALE: IN CHRONIC HEART FAILURE, INCREASED ADRENERGIC ACTIVATION CONTRIBUTES TO STRUCTURAL REMODELING AND ALTERED GENE EXPRESSION. ALTHOUGH ADRENERGIC SIGNALING ALTERS HISTONE MODIFICATIONS, IT IS UNKNOWN, WHETHER IT ALSO AFFECTS OTHER EPIGENETIC PROCESSES, INCLUDING DNA METHYLATION AND ITS RECOGNITION. OBJECTIVE: THE AIM OF THIS STUDY WAS TO IDENTIFY THE MECHANISM OF REGULATION OF THE METHYL-CPG-BINDING PROTEIN 2 (MECP2) AND ITS FUNCTIONAL SIGNIFICANCE DURING CARDIAC PRESSURE OVERLOAD AND UNLOADING. METHODS AND RESULTS: MECP2 WAS IDENTIFIED AS A REVERSIBLY REPRESSED GENE IN MOUSE HEARTS AFTER TRANSVERSE AORTIC CONSTRICTION AND WAS NORMALIZED AFTER REMOVAL OF THE CONSTRICTION. SIMILARLY, MECP2 REPRESSION IN HUMAN FAILING HEARTS RESOLVED AFTER UNLOADING BY A LEFT VENTRICULAR ASSIST DEVICE. THE CLUSTER MIR-212/132 WAS UPREGULATED AFTER TRANSVERSE AORTIC CONSTRICTION OR ON ACTIVATION OF ALPHA1- AND BETA1-ADRENOCEPTORS AND MIR-212/132 LED TO REPRESSION OF MECP2. PREVENTION OF MECP2 REPRESSION BY A CARDIOMYOCYTE-SPECIFIC, DOXYCYCLINE-REGULATABLE TRANSGENIC MOUSE MODEL AGGRAVATED CARDIAC HYPERTROPHY, FIBROSIS, AND CONTRACTILE DYSFUNCTION AFTER TRANSVERSE AORTIC CONSTRICTION. ABLATION OF MECP2 IN CARDIOMYOCYTES FACILITATED RECOVERY OF FAILING HEARTS AFTER REVERSIBLE TRANSVERSE AORTIC CONSTRICTION. GENOME-WIDE EXPRESSION ANALYSIS, CHROMATIN IMMUNOPRECIPITATION EXPERIMENTS, AND DNA METHYLATION ANALYSIS IDENTIFIED MITOCHONDRIAL GENES AND THEIR TRANSCRIPTIONAL REGULATORS AS MECP2 TARGET GENES. COINCIDENT WITH ITS REPRESSION, MECP2 WAS REMOVED FROM ITS TARGET GENES, WHEREAS DNA METHYLATION OF MECP2 TARGET GENES REMAINED STABLE DURING PRESSURE OVERLOAD. CONCLUSIONS: THESE DATA CONNECT ADRENERGIC ACTIVATION WITH A MICRORNA-MECP2 EPIGENETIC PATHWAY THAT IS IMPORTANT FOR CARDIAC ADAPTATION DURING THE DEVELOPMENT AND RECOVERY FROM HEART FAILURE. 2015 14 5865 27 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 15 2884 28 G9A IS ESSENTIAL FOR EPIGENETIC SILENCING OF K(+) CHANNEL GENES IN ACUTE-TO-CHRONIC PAIN TRANSITION. NEUROPATHIC PAIN IS A DEBILITATING CLINICAL PROBLEM AND DIFFICULT TO TREAT. NERVE INJURY CAUSES A LONG-LASTING REDUCTION IN K(+) CHANNEL EXPRESSION IN THE DORSAL ROOT GANGLION (DRG), BUT LITTLE IS KNOWN ABOUT THE EPIGENETIC MECHANISMS INVOLVED. WE FOUND THAT NERVE INJURY INCREASED DIMETHYLATION OF LYS9 ON HISTONE H3 (H3K9ME2) AT KCNA4, KCND2, KCNQ2 AND KCNMA1 PROMOTERS BUT DID NOT AFFECT LEVELS OF DNA METHYLATION ON THESE GENES IN DRGS. NERVE INJURY INCREASED ACTIVITY OF EUCHROMATIC HISTONE-LYSINE N-METHYLTRANSFERASE-2 (G9A), HISTONE DEACETYLASES AND ENHANCER OF ZESTE HOMOLOG-2 (EZH2), BUT ONLY G9A INHIBITION CONSISTENTLY RESTORED K(+) CHANNEL EXPRESSION. SELECTIVE KNOCKOUT OF THE GENE ENCODING G9A IN DRG NEURONS COMPLETELY BLOCKED K(+) CHANNEL SILENCING AND CHRONIC PAIN DEVELOPMENT AFTER NERVE INJURY. REMARKABLY, RNA SEQUENCING ANALYSIS REVEALED THAT G9A INHIBITION NOT ONLY REACTIVATED 40 OF 42 SILENCED GENES ASSOCIATED WITH K(+) CHANNELS BUT ALSO NORMALIZED 638 GENES DOWN- OR UPREGULATED BY NERVE INJURY. THUS G9A HAS A DOMINANT FUNCTION IN TRANSCRIPTIONAL REPRESSION OF K(+) CHANNELS AND IN ACUTE-TO-CHRONIC PAIN TRANSITION AFTER NERVE INJURY. 2015 16 4615 28 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 17 3832 16 INVOLVEMENT OF SPINAL SIRT1 IN DEVELOPMENT OF CHRONIC CONSTRICTION INJURY INDUCED NEUROPATHIC PAIN IN RATS. IT IS KNOWN THAT THE EPIGENETIC PROCESS OF HISTONE ACETYLATION IS INVOLVED IN THE NEUROPATHIC PAIN. THE AIM OF THIS STUDY WAS TO DETERMINE WHETHER SIRTUIN TYPE 1 (SIRT1), AN NAD(+) DEPENDENT DEACETYLASE, AFFECTED ALLODYNIA AND HYPERALGESIA IN NEUROPATHIC PAIN. THE NEUROPATHIC PAIN MODEL WAS ESTABLISHED BY LIGATURE OF THE RIGHT SCIATIC NERVE TO INDUCE CHRONIC CONSTRICTION INJURY (CCI) IN RATS. HISTONE ACETYLTRANSFERASE (HAT) ACTIVITY WAS INCREASED AND, AND HISTONE DEACETYLASE (HDAC) ACTIVITY WAS DECLINED IN TISSUE OF THE SPINAL DORSA HORN IN CCI RATES BY MEANS OF ENZYME-LINKED IMMUNOSORBENT ASSAY (ELISA). THE PERSISTENT HYPERALGESIA AND ALLODYNIA CAUSED BY CCI WERE ASSOCIATED WITH DOWNREGULATION OF SIRT1 AND UPREGULATION OF ACETYLATED-H3 (AC-H3) IN TISSUE OF THE SPINAL CORD BY WESTERN BLOT ASSAY, WHICH WAS REVERSED AFTER INTRATHECAL INJECTION OF SIRT1 AGONIST SRT1720. SRT1720 TREATMENT ACHIEVED ANALGESIC THROUGH INHIBITING THE ACETYLATION OF NUCLEAR FACTOR KAPPA B (NF-KAPPAB) AND BLOCKING THE RELEASES OF THE INFLAMMATORY FACTORS INCLUDING TUMOR NECROSIS FACTOR-ALPHA (TNF-ALPHA) AND INTERLEUKIN (IL)-6 BY MEANS OF WESTERN BLOT AND REAL-TIME QUANTITATIVE PCR (RT-PCR), RESPECTIVELY. TAKEN TOGETHER, THESE DATA SUGGEST THAT SIRT1 IN THE SPINAL CORD PLAYS AN IMPORTANT ROLE IN THE NEUROPATHIC PAIN IN THE RAT MODEL. 2018 18 3332 27 HISTONE DEACETYLASE INHIBITOR-INDUCED EMERGENCE OF SYNAPTIC DELTA-OPIOID RECEPTORS AND BEHAVIORAL ANTINOCICEPTION IN PERSISTENT NEUROPATHIC PAIN. THE EFFICACY OF OPIOIDS IN PATIENTS WITH CHRONIC NEUROPATHIC PAIN REMAINS CONTROVERSIAL. ALTHOUGH ACTIVATION OF DELTA-OPIOID RECEPTORS (DORS) IN THE BRAINSTEM REDUCES INFLAMMATION-INDUCED PERSISTENT HYPERALGESIA, IT IS NOT EFFECTIVE UNDER PERSISTENT NEUROPATHIC PAIN CONDITIONS AND THESE CLINICAL PROBLEMS REMAIN LARGELY UNKNOWN. IN THIS STUDY, BY USING A CHRONIC CONSTRICTION INJURY (CCI) OF THE SCIATIC NERVE IN RATS, WE FOUND THAT IN THE BRAINSTEM NUCLEUS RAPHE MAGNUS (NRM), DORS EMERGED ON THE SURFACE MEMBRANE OF CENTRAL SYNAPTIC TERMINALS ON DAY 3 AFTER CCI SURGERY AND DISAPPEARED ON DAY 14. HISTONE DEACETYLASE (HDAC) INHIBITORS MICROINJECTED INTO THE NRM IN VIVO INCREASED THE LEVEL OF SYNAPTOSOMAL DOR PROTEIN AND NRM INFUSION OF DOR AGONISTS PRODUCING AN ANTINOCICEPTIVE EFFECT IN A NERVE GROWTH FACTOR (NGF) SIGNALING-DEPENDENT MANNER. IN VITRO, IN CCI RAT SLICES INCUBATED WITH HDAC INHIBITORS, DOR AGONISTS SIGNIFICANTLY INHIBITED EPSCS. THIS EFFECT WAS BLOCKED BY TYROSINE RECEPTOR KINASE A ANTAGONISTS. CHROMATIN IMMUNOPRECIPITATION ANALYSIS REVEALED THAT NRM INFUSION OF HDAC INHIBITORS IN CCI RATS INCREASED THE LEVEL OF HISTONE H4 ACETYLATION AT NGF GENE PROMOTER REGIONS. NGF WAS INFUSED INTO THE NRM OR INCUBATED CCI RAT SLICES DROVE DORS TO THE SURFACE MEMBRANE OF SYNAPTIC TERMINALS. TAKEN TOGETHER, EPIGENETIC UPREGULATION OF NGF ACTIVITY BY HDAC INHIBITORS IN THE NRM PROMOTES THE TRAFFICKING OF DORS TO PAIN-MODULATING NEURONAL SYNAPSES UNDER NEUROPATHIC PAIN CONDITIONS, LEADING TO DELTA-OPIOID ANALGESIA. THESE FINDINGS INDICATE THAT THERAPEUTIC USE OF DOR AGONISTS COMBINED WITH HDAC INHIBITORS MIGHT BE EFFECTIVE IN CHRONIC NEUROPATHIC PAIN MANAGEMENTS. 2016 19 4906 31 P300 EXERTS AN EPIGENETIC ROLE IN CHRONIC NEUROPATHIC PAIN THROUGH ITS ACETYLTRANSFERASE ACTIVITY IN RATS FOLLOWING CHRONIC CONSTRICTION INJURY (CCI). BACKGROUND: NEUROPATHIC PAIN IS DETRIMENTAL TO HUMAN HEALTH; HOWEVER, ITS PATHOGENESIS STILL REMAINS LARGELY UNKNOWN. OVEREXPRESSION OF PAIN-ASSOCIATED GENES AND INCREASED NOCICEPTIVE SOMATO-SENSITIVITY ARE WELL OBSERVED IN NEUROPATHIC PAIN. THE IMPORTANCE OF EPIGENETIC MECHANISMS IN REGULATING THE EXPRESSION OF PRO- OR ANTI-NOCICEPTIVE GENES HAS BEEN REVEALED BY STUDIES RECENTLY, AND WE HYPOTHESIZE THAT THE TRANSCRIPTIONAL COACTIVATOR AND THE HISTONE ACETYLTRANSFERASE E1A BINDING PROTEIN P300 (P300), AS A PART OF THE EPIGENETIC MECHANISMS OF GENE REGULATION, MAY BE INVOLVED IN THE PATHOGENESIS OF NEUROPATHIC PAIN INDUCED BY CHRONIC CONSTRICTION INJURY (CCI). TO TEST THIS HYPOTHESIS, TWO DIFFERENT APPROACHES WERE USED IN THIS STUDY: (I) DOWN-REGULATING P300 WITH SPECIFIC SMALL HAIRPIN RNA (SHRNA) AND (II) CHEMICAL INHIBITION OF P300 ACETYLTRANSFERASE ACTIVITY BY A SMALL MOLECULE INHIBITOR, C646. RESULTS: USING THE CCI RAT MODEL, WE FOUND THAT THE P300 EXPRESSION WAS INCREASED IN THE LUMBAR SPINAL CORD ON DAY 14 AFTER CCI. THE TREATMENT WITH INTRATHECAL P300 SHRNA REVERSED CCI-INDUCED MECHANICAL ALLODYNIA AND THERMAL HYPERALGESIA, AND SUPPRESSED THE EXPRESSION OF CYCLOOXYGENASE-2 (COX-2), A NEUROPATHIC PAIN-ASSOCIATED FACTOR. FURTHERMORE, C646, AN INHIBITOR OF P300 ACETYLTRANSFERASE, ALSO ATTENUATED MECHANICAL ALLODYNIA AND THERMAL HYPERALGESIA, ACCOMPANIED BY A SUPPRESSED COX-2 EXPRESSION, IN THE SPINAL CORD. CONCLUSIONS: THE RESULTS SUGGEST THAT, THROUGH ITS ACETYLTRANSFERASE ACTIVITY IN THE SPINAL CORD AFTER CCI, P300 EPIGENETICALLY PLAYS AN IMPORTANT ROLE IN NEUROPATHIC PAIN. INHIBITING P300, USING INTERFERING RNA OR C646, MAY BE A PROMISING APPROACH TO THE DEVELOPMENT OF NEW NEUROPATHIC PAIN THERAPIES. 2012 20 6767 25 ZNF382 CONTROLS MOUSE NEUROPATHIC PAIN VIA SILENCER-BASED EPIGENETIC INHIBITION OF CXCL13 IN DRG NEURONS. NERVE INJURY-INDUCED CHANGES OF GENE EXPRESSION IN DORSAL ROOT GANGLION (DRG) ARE CRITICAL FOR NEUROPATHIC PAIN GENESIS. HOWEVER, HOW THESE CHANGES OCCUR REMAINS ELUSIVE. HERE WE REPORT THE DOWN-REGULATION OF ZINC FINGER PROTEIN 382 (ZNF382) IN INJURED DRG NEURONS AFTER NERVE INJURY. RESCUING THIS DOWN-REGULATION ATTENUATES NOCICEPTIVE HYPERSENSITIVITY. CONVERSELY, MIMICKING THIS DOWN-REGULATION PRODUCES NEUROPATHIC PAIN SYMPTOMS, WHICH ARE ALLEVIATED BY C-X-C MOTIF CHEMOKINE 13 (CXCL13) KNOCKDOWN OR ITS RECEPTOR CXCR5 KNOCKOUT. MECHANISTICALLY, AN IDENTIFIED CIS-ACTING SILENCER AT DISTAL UPSTREAM OF THE CXCL13 PROMOTER SUPPRESSES CXCL13 TRANSCRIPTION VIA BINDING TO ZNF382. BLOCKING THIS BINDING OR GENETICALLY DELETING THIS SILENCER ABOLISHES THE ZNF382 SUPPRESSION ON CXCL13 TRANSCRIPTION AND IMPAIRS ZNF382-INDUCED ANTINOCICEPTION. MOREOVER, ZNF382 DOWN-REGULATION DISRUPTS THE REPRESSIVE EPIGENETIC COMPLEX CONTAINING HISTONE DEACETYLASE 1 AND SET DOMAIN BIFURCATED 1 AT THE SILENCER-PROMOTER LOOP, RESULTING IN CXCL13 TRANSCRIPTIONAL ACTIVATION. THUS, ZNF382 DOWN-REGULATION IS REQUIRED FOR NEUROPATHIC PAIN LIKELY THROUGH SILENCER-BASED EPIGENETIC DISINHIBITION OF CXCL13, A KEY NEUROPATHIC PAIN PLAYER, IN DRG NEURONS. 2021