1 1654 93 DORSAL ROOT GANGLIA COACTIVATOR-ASSOCIATED ARGININE METHYLTRANSFERASE 1 CONTRIBUTES TO PERIPHERAL NERVE INJURY-INDUCED PAIN HYPERSENSITIVITIES. NEUROPATHIC PAIN IS ASSOCIATED WITH GENE EXPRESSION CHANGES WITHIN THE DORSAL ROOT GANGLION (DRG) AFTER PERIPHERAL NERVE INJURY, WHICH INVOLVES EPIGENETIC MECHANISMS. COACTIVATOR-ASSOCIATED ARGININE METHYLTRANSFERASE 1 (CARM1), AN EPIGENETIC ACTIVATOR, REGULATES GENE TRANSCRIPTIONAL ACTIVITY BY PROTEIN POSTTRANSLATIONAL MODIFICATIONS. HOWEVER, WHETHER CARM1 PLAYS AN ESSENTIAL ROLE IN THE DEVELOPMENT AND MAINTENANCE OF NEUROPATHIC PAIN IS UNKNOWN. WE REPORT HERE THAT PERIPHERAL NERVE INJURY INDUCED THE UPREGULATION OF THE MRNA AND PROTEIN EXPRESSION OF CARM1 IN THE INJURED DRG, AND BLOCKING ITS EXPRESSION THROUGH SMALL INTERFERING RNA (SIRNA) IN THE INJURED DRG ATTENUATED THE DEVELOPMENT AND MAINTENANCE OF NEUROPATHIC PAIN. FURTHERMORE, PHARMACOLOGICAL INHIBITION OF CARM1 MITIGATED PERIPHERAL NERVE INJURY-INDUCED MECHANICAL ALLODYNIA AND THERMAL HYPERALGESIA. GIVEN THAT CARM1 INHIBITION OR KNOCKDOWN ATTENUATED THE INDUCTION AND MAINTENANCE OF NEUROPATHIC PAIN AFTER PERIPHERAL NERVE INJURY, OUR FINDINGS SUGGEST THAT CARM1 MAY SERVE AS A PROMISING THERAPEUTIC TARGET FOR NEUROPATHIC PAIN TREATMENT IN CLINICAL APPLICATIONS. 2018 2 4003 33 LOSS OF PRMT7 REPROGRAMS GLYCINE METABOLISM TO SELECTIVELY ERADICATE LEUKEMIA STEM CELLS IN CML. OUR GROUP HAS REPORTED PREVIOUSLY ON THE ROLE OF VARIOUS MEMBERS OF THE PROTEIN ARGININE METHYLTRANSFERASE (PRMT) FAMILY, WHICH ARE INVOLVED IN EPIGENETIC REGULATION, IN THE PROGRESSION OF LEUKEMIA. HERE, WE EXPLORED THE ROLE OF PRMT7, GIVEN ITS UNIQUE FUNCTION WITHIN THE PRMT FAMILY, IN THE MAINTENANCE OF LEUKEMIA STEM CELLS (LSCS) IN CHRONIC MYELOID LEUKEMIA (CML). GENETIC LOSS OF PRMT7, AND THE DEVELOPMENT AND TESTING OF A SMALL-MOLECULE SPECIFIC INHIBITOR OF PRMT7, SHOWED THAT TARGETING PRMT7 DELAYED LEUKEMIA DEVELOPMENT AND IMPAIRED SELF-RENEWAL OF LSCS IN A CML MOUSE MODEL AND IN PRIMARY CML CD34(+) CELLS FROM HUMANS WITHOUT AFFECTING NORMAL HEMATOPOIESIS. MECHANISTICALLY, LOSS OF PRMT7 RESULTED IN REDUCED EXPRESSIONS OF GLYCINE DECARBOXYLASE, LEADING TO THE REPROGRAMING OF GLYCINE METABOLISM TO GENERATE METHYLGLYOXAL, WHICH IS DETRIMENTAL TO LSCS. THESE FINDINGS LINK HISTONE ARGININE METHYLATION WITH GLYCINE METABOLISM, WHILE SUGGESTING PRMT7 AS A POTENTIAL THERAPEUTIC TARGET FOR THE ERADICATION OF LSCS IN CML. 2022 3 6015 29 THE ARGININE METHYLTRANSFERASE PRMT7 PROMOTES EXTRAVASATION OF MONOCYTES RESULTING IN TISSUE INJURY IN COPD. EXTRAVASATION OF MONOCYTES INTO TISSUE AND TO THE SITE OF INJURY IS A FUNDAMENTAL IMMUNOLOGICAL PROCESS, WHICH REQUIRES RAPID RESPONSES VIA POST TRANSLATIONAL MODIFICATIONS (PTM) OF PROTEINS. PROTEIN ARGININE METHYLTRANSFERASE 7 (PRMT7) IS AN EPIGENETIC FACTOR THAT HAS THE CAPACITY TO MONO-METHYLATE HISTONES ON ARGININE RESIDUES. HERE WE SHOW THAT IN CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) PATIENTS, PRMT7 EXPRESSION IS ELEVATED IN THE LUNG TISSUE AND LOCALIZED TO THE MACROPHAGES. IN MOUSE MODELS OF COPD, LUNG FIBROSIS AND SKIN INJURY, REDUCED EXPRESSION OF PRMT7 ASSOCIATES WITH DECREASED RECRUITMENT OF MONOCYTES TO THE SITE OF INJURY AND HENCE LESS SEVERE SYMPTOMS. MECHANISTICALLY, ACTIVATION OF NF-KAPPAB/RELA IN MONOCYTES INDUCES PRMT7 TRANSCRIPTION AND CONSEQUENTIAL MONO-METHYLATION OF HISTONES AT THE REGULATORY ELEMENTS OF RAP1A, WHICH LEADS TO INCREASED TRANSCRIPTION OF THIS GENE THAT IS RESPONSIBLE FOR ADHESION AND MIGRATION OF MONOCYTES. PERSISTENT MONOCYTE-DERIVED MACROPHAGE ACCUMULATION LEADS TO ALOX5 OVER-EXPRESSION AND ACCUMULATION OF ITS METABOLITE LTB4, WHICH TRIGGERS EXPRESSION OF ACSL4 A FERROPTOSIS PROMOTING GENE IN LUNG EPITHELIAL CELLS. CONCLUSIVELY, INHIBITION OF ARGININE MONO-METHYLATION MIGHT OFFER TARGETED INTERVENTION IN MONOCYTE-DRIVEN INFLAMMATORY CONDITIONS THAT LEAD TO EXTENSIVE TISSUE DAMAGE IF LEFT UNTREATED. 2022 4 657 45 BLOCKING THE SPINAL FBXO3/CARM1/K(+) CHANNEL EPIGENETIC SILENCING PATHWAY AS A STRATEGY FOR NEUROPATHIC PAIN RELIEF. MANY EPIGENETIC REGULATORS ARE INVOLVED IN PAIN-ASSOCIATED SPINAL PLASTICITY. COACTIVATOR-ASSOCIATED ARGININE METHYLTRANSFERASE 1 (CARM1), AN EPIGENETIC REGULATOR OF HISTONE ARGININE METHYLATION, IS A HIGHLY INTERESTING TARGET IN NEUROPLASTICITY. HOWEVER, ITS POTENTIAL CONTRIBUTION TO SPINAL PLASTICITY-ASSOCIATED NEUROPATHIC PAIN DEVELOPMENT REMAINS POORLY EXPLORED. HERE, WE REPORT THAT NERVE INJURY DECREASED THE EXPRESSION OF SPINAL CARM1 AND INDUCED ALLODYNIA. MOREOVER, DECREASING SPINAL CARM1 EXPRESSION BY FBXO3-MEDIATED CARM1 UBIQUITINATION PROMOTED H3R17ME2 DECREMENT AT THE K(+) CHANNEL PROMOTER, THEREBY CAUSING K(+) CHANNEL EPIGENETIC SILENCING AND THE DEVELOPMENT OF NEUROPATHIC PAIN. REMARKABLY, IN NAIVE RATS, DECREASING SPINAL CARM1 USING CARM1 SIRNA OR A CARM1 INHIBITOR RESULTED IN SIMILAR EPIGENETIC SIGNALING AND ALLODYNIA. FURTHERMORE, INTRATHECAL ADMINISTRATION OF BC-1215 (A NOVEL FBXO3 INHIBITOR) PREVENTED CARM1 UBIQUITINATION TO BLOCK K(+) CHANNEL GENE SILENCING AND AMELIORATE ALLODYNIA AFTER NERVE INJURY. COLLECTIVELY, THE RESULTS REVEAL THAT THIS NEWLY IDENTIFIED SPINAL FBXO3-CARM1-K(+) CHANNEL GENE FUNCTIONAL AXIS PROMOTES NEUROPATHIC PAIN. THESE FINDINGS PROVIDE ESSENTIAL INSIGHTS THAT WILL AID IN THE DEVELOPMENT OF MORE EFFICIENT AND SPECIFIC THERAPIES AGAINST NEUROPATHIC PAIN. 2021 5 756 29 CARM1 REGULATES SENESCENCE DURING AIRWAY EPITHELIAL CELL INJURY IN COPD PATHOGENESIS. CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) IS A LIFE-THREATENING LUNG DISEASE. ALTHOUGH CIGARETTE SMOKE WAS CONSIDERED THE MAIN CAUSE OF DEVELOPMENT, THE HETEROGENEOUS NATURE OF THE DISEASE LEAVES IT UNCLEAR WHETHER OTHER FACTORS CONTRIBUTE TO THE PREDISPOSITION OR IMPAIRED REGENERATION RESPONSE OBSERVED. RECENTLY, EPIGENETIC MODIFICATION HAS EMERGED TO BE A KEY PLAYER IN THE PATHOGENESIS OF COPD. THE ADDITION OF METHYL GROUPS TO ARGININE RESIDUES IN BOTH HISTONE AND NONHISTONE PROTEINS BY PROTEIN ARGININE METHYLTRANSFERASES (PRMTS) IS AN IMPORTANT POSTTRANSLATIONAL EPIGENETIC MODIFICATION EVENT REGULATING CELLULAR PROLIFERATION, DIFFERENTIATION, APOPTOSIS, AND SENESCENCE. HERE, WE HYPOTHESIZE THAT COACTIVATOR-ASSOCIATED ARGININE METHYLTRANSFERASE-1 (CARM1) REGULATES AIRWAY EPITHELIAL CELL INJURY IN COPD PATHOGENESIS BY CONTROLLING CELLULAR SENESCENCE. USING THE NAPHTHALENE (NA)-INDUCED MOUSE MODEL OF AIRWAY EPITHELIAL DAMAGE, WE DEMONSTRATE THAT LOSS OF CC10-POSITIVE CLUB CELLS IS ACCOMPANIED BY A REDUCTION IN CARM1-EXPRESSING CELLS OF THE AIRWAY EPITHELIUM. FURTHERMORE, CARM1 HAPLOINSUFFFICENT MICE SHOWED PERTURBED CLUB CELL REGENERATION FOLLOWING NA TREATMENT. IN ADDITION, CARM1 REDUCTION LED TO DECREASED NUMBERS OF ANTISENESCENT SIRTUIN 1-EXPRESSING CELLS ACCOMPANIED BY HIGHER P21, P16, AND BETA-GALACTOSIDASE-POSITIVE SENESCENT CELLS IN THE MOUSE AIRWAY FOLLOWING NA TREATMENT. IMPORTANTLY, CARM1-SILENCED HUMAN BRONCHIAL EPITHELIAL CELLS SHOWED IMPAIRED WOUND HEALING AND HIGHER BETA-GALACTOSIDASE ACTIVITY. THESE RESULTS DEMONSTRATE THAT CARM1 CONTRIBUTES TO AIRWAY REPAIR AND REGENERATION BY REGULATING AIRWAY EPITHELIAL CELL SENESCENCE. 2019 6 5940 28 TARGETING METHYLTRANSFERASE PRMT5 ELIMINATES LEUKEMIA STEM CELLS IN CHRONIC MYELOGENOUS LEUKEMIA. IMATINIB-INSENSITIVE LEUKEMIA STEM CELLS (LSCS) ARE BELIEVED TO BE RESPONSIBLE FOR RESISTANCE TO BCR-ABL TYROSINE KINASE INHIBITORS AND RELAPSE OF CHRONIC MYELOGENOUS LEUKEMIA (CML). IDENTIFYING THERAPEUTIC TARGETS TO ERADICATE CML LSCS MAY BE A STRATEGY TO CURE CML. IN THE PRESENT STUDY, WE DISCOVERED A POSITIVE FEEDBACK LOOP BETWEEN BCR-ABL AND PROTEIN ARGININE METHYLTRANSFERASE 5 (PRMT5) IN CML CELLS. OVEREXPRESSION OF PRMT5 WAS OBSERVED IN HUMAN CML LSCS. SILENCING PRMT5 WITH SHRNA OR BLOCKING PRMT5 METHYLTRANSFERASE ACTIVITY WITH THE SMALL-MOLECULE INHIBITOR PJ-68 REDUCED SURVIVAL, SERIAL REPLATING CAPACITY, AND LONG-TERM CULTURE-INITIATING CELLS (LTC-ICS) IN LSCS FROM CML PATIENTS. FURTHER, PRMT5 KNOCKDOWN OR PJ-68 TREATMENT DRAMATICALLY PROLONGED SURVIVAL IN A MURINE MODEL OF RETROVIRAL BCR-ABL-DRIVEN CML AND IMPAIRED THE IN VIVO SELF-RENEWAL CAPACITY OF TRANSPLANTED CML LSCS. PJ-68 ALSO INHIBITED LONG-TERM ENGRAFTMENT OF HUMAN CML CD34+ CELLS IN IMMUNODEFICIENT MICE. MOREOVER, INHIBITION OF PRMT5 ABROGATED THE WNT/BETA-CATENIN PATHWAY IN CML CD34+ CELLS BY DEPLETING DISHEVELLED HOMOLOG 3 (DVL3). THIS STUDY SUGGESTS THAT EPIGENETIC METHYLATION MODIFICATION ON HISTONE PROTEIN ARGININE RESIDUES IS A REGULATORY MECHANISM TO CONTROL SELF-RENEWAL OF LSCS AND INDICATES THAT PRMT5 MAY REPRESENT A POTENTIAL THERAPEUTIC TARGET AGAINST LSCS. 2016 7 6321 24 THE ROLE AND MECHANISM OF LYSINE METHYLTRANSFERASE AND ARGININE METHYLTRANSFERASE IN KIDNEY DISEASES. METHYLATION CAN OCCUR IN BOTH HISTONES AND NON-HISTONES. KEY LYSINE AND ARGININE METHYLTRANSFERASES UNDER INVESTIGATION FOR RENAL DISEASE TREATMENT INCLUDE ENHANCER OF ZESTE HOMOLOG 2 (EZH2), G9A, DISRUPTOR OF TELOMERIC SILENCING 1-LIKE PROTEIN (DOT1L), AND PROTEIN ARGININE METHYLTRANSFERASES (PRMT) 1 AND 5. RECENT STUDIES HAVE SHOWN THAT METHYLTRANSFERASES EXPRESSION AND ACTIVITY ARE ALSO INCREASED IN SEVERAL ANIMAL MODELS OF KIDNEY INJURY, SUCH AS ACUTE KIDNEY INJURY(AKI), OBSTRUCTIVE NEPHROPATHY, DIABETIC NEPHROPATHY AND LUPUS NEPHRITIS. THE INHIBITION OF MOST METHYLTRANSFERASES CAN ATTENUATE KIDNEY INJURY, WHILE THE ROLE OF METHYLTRANSFERASE IN DIFFERENT ANIMAL MODELS REMAINS CONTROVERSIAL. IN THIS ARTICLE, WE SUMMARIZE THE ROLE AND MECHANISM OF LYSINE METHYLTRANSFERASE AND ARGININE METHYLTRANSFERASE IN VARIOUS KIDNEY DISEASES AND HIGHLIGHT METHYLTRANSFERASE AS A POTENTIAL THERAPEUTIC TARGET FOR KIDNEY DISEASES. 2022 8 5297 44 PROTEIN ARGININE METHYLTRANSFERASE 5 CONTRIBUTES TO PACLITAXEL-INDUCED NEUROPATHIC PAIN BY ACTIVATING TRANSIENT RECEPTOR POTENTIAL VANILLOID 1 EPIGENETIC MODIFICATION IN DORSAL ROOT GANGLION. BACKGROUND: PACLITAXEL (PTX), WHICH IS A FIRST-LINE CHEMOTHERAPY DRUG USED TO TREAT VARIOUS TYPES OF CANCERS, EXHIBITS PERIPHERAL NEUROPATHY AS A COMMON SIDE EFFECT THAT IS DIFFICULT TO TREAT. PROTEIN ARGININE METHYLTRANSFERASE 5 (PRMT 5) IS A KEY REGULATOR OF THE CHEMOTHERAPY RESPONSE, AS CHEMOTHERAPY DRUGS INDUCE PRMT5 EXPRESSION. HOWEVER, LITTLE IS KNOWN ABOUT THE PRMT5-MEDIATED EPIGENETIC MECHANISMS INVOLVED IN PTX-INDUCED NEUROPATHIC ALLODYNIA. METHODS: SPRAGUE-DAWLEY RATS WERE INTRAPERITONEALLY GIVEN PTX TO INDUCE NEUROPATHIC PAIN. BIOCHEMICAL ANALYSES WERE CONDUCTED TO MEASURE THE PROTEIN EXPRESSION LEVELS IN THE DORSAL ROOT GANGLION (DRG) OF THE ANIMALS. THE VON FREY TEST AND HOT PLATE TEST WERE USED TO EVALUATE NOCICEPTIVE BEHAVIORS. RESULTS: PTX INCREASED THE PRMT5 (MEAN DIFFERENCE [MD]: 0.68, 95% CONFIDENCE INTERVAL [CI], 0.88-0.48; P < .001 FOR VEHICLE)-MEDIATED DEPOSITION OF HISTONE H3R2 DIMETHYL SYMMETRIC (H3R2ME2S) AT THE TRANSIENT RECEPTOR POTENTIAL VANILLOID 1 (TRPV1) PROMOTER IN THE DRG. PRMT5-INDUCED H3R2ME2S RECRUITED WD REPEAT DOMAIN 5 (WDR5) TO INCREASE TRIMETHYLATION OF LYSINE 4 ON HISTONE H3 (H3K4ME3) AT TRPV1 PROMOTERS, THUS RESULTING IN TRPV1 TRANSCRIPTIONAL ACTIVATION (MD: 0.65, 95% CI, 0.82-0.49; P < .001 FOR VEHICLE) IN DRG IN PTX-INDUCED NEUROPATHIC PAIN. MOREOVER, PTX INCREASED THE ACTIVITY OF NADPH OXIDASE 4 (NOX4) (MD: 0.66, 95% CI, 0.81-0.51; P < .001 FOR VEHICLE), PRMT5-INDUCED H3R2ME2S, AND WDR5-MEDIATED H3K4ME3 IN THE DRG IN PTX-INDUCED NEUROPATHIC PAIN. PHARMACOLOGICAL ANTAGONISM AND THE SELECTIVE KNOCKDOWN OF PRMT5 IN DRG NEURONS COMPLETELY BLOCKED PRMT5-MEDIATED H3R2ME2S, WDR5-MEDIATED H3K4ME3, OR TRPV1 EXPRESSION AND NEUROPATHIC PAIN DEVELOPMENT AFTER PTX INJECTION. REMARKABLY, NOX4 INHIBITION NOT ONLY ATTENUATED ALLODYNIA BEHAVIOR AND REVERSED THE ABOVE-MENTIONED SIGNALING BUT ALSO REVERSED NOX4 UPREGULATION VIA PTX. CONCLUSIONS: THUS, THE NOX4/PRMT5-ASSOCIATED EPIGENETIC MECHANISM IN DRG HAS A DOMINANT FUNCTION IN THE TRANSCRIPTIONAL ACTIVATION OF TRPV1 IN PTX-INDUCED NEUROPATHIC PAIN. 2023 9 5226 35 PRMT5 RESTRICTS HEPATITIS B VIRUS REPLICATION THROUGH EPIGENETIC REPRESSION OF COVALENTLY CLOSED CIRCULAR DNA TRANSCRIPTION AND INTERFERENCE WITH PREGENOMIC RNA ENCAPSIDATION. CHRONIC HEPATITIS B VIRUS (HBV) INFECTION REMAINS A MAJOR HEALTH PROBLEM WORLDWIDE. THE COVALENTLY CLOSED CIRCULAR DNA (CCCDNA) MINICHROMOSOME, WHICH SERVES AS THE TEMPLATE FOR THE TRANSCRIPTION OF VIRAL RNAS, PLAYS A KEY ROLE IN VIRAL PERSISTENCE. WHILE ACCUMULATING EVIDENCE SUGGESTS THAT CCCDNA TRANSCRIPTION IS REGULATED BY EPIGENETIC MACHINERY, PARTICULARLY THE ACETYLATION OF CCCDNA-BOUND HISTONE 3 (H3) AND H4, THE POTENTIAL CONTRIBUTIONS OF HISTONE METHYLATION AND RELATED HOST FACTORS REMAIN OBSCURE. HERE, BY SCREENING A SERIES OF METHYLTRANSFERASES AND DEMETHYLASES, WE IDENTIFIED PROTEIN ARGININE METHYLTRANSFERASE 5 (PRMT5) AS AN EFFECTIVE RESTRICTOR OF HBV TRANSCRIPTION AND REPLICATION. IN CELL CULTURE-BASED MODELS FOR HBV INFECTION AND IN LIVER TISSUES OF PATIENTS WITH CHRONIC HBV INFECTION, WE FOUND THAT SYMMETRIC DIMETHYLATION OF ARGININE 3 ON H4 ON CCCDNA WAS A REPRESSIVE MARKER OF CCCDNA TRANSCRIPTION AND WAS REGULATED BY PRMT5 DEPENDING ON ITS METHYLTRANSFERASE DOMAIN. MOREOVER, PRMT5-TRIGGERED SYMMETRIC DIMETHYLATION OF ARGININE 3 ON H4 ON THE CCCDNA MINICHROMOSOME INVOLVED AN INTERACTION WITH THE HBV CORE PROTEIN AND THE BRG1-BASED HUMAN SWI/SNF CHROMATIN REMODELER, WHICH RESULTED IN DOWN-REGULATION OF THE BINDING OF RNA POLYMERASE II TO CCCDNA. IN ADDITION TO THE INHIBITORY EFFECT ON CCCDNA TRANSCRIPTION, PRMT5 INHIBITED HBV CORE PARTICLE DNA PRODUCTION INDEPENDENTLY OF ITS METHYLTRANSFERASE ACTIVITY. FURTHER STUDY REVEALED THAT PRMT5 INTERFERED WITH PREGENOMIC RNA ENCAPSIDATION BY PREVENTING ITS INTERACTION WITH VIRAL POLYMERASE PROTEIN THROUGH BINDING TO THE REVERSE TRANSCRIPTASE-RIBONUCLEASE H REGION OF POLYMERASE, WHICH IS CRUCIAL FOR THE POLYMERASE-PREGENOMIC RNA INTERACTION. CONCLUSION: PRMT5 RESTRICTS HBV REPLICATION THROUGH A TWO-PART MECHANISM INCLUDING EPIGENETIC SUPPRESSION OF CCCDNA TRANSCRIPTION AND INTERFERENCE WITH PREGENOMIC RNA ENCAPSIDATION; THESE FINDINGS IMPROVE THE UNDERSTANDING OF EPIGENETIC REGULATION OF HBV TRANSCRIPTION AND HOST-HBV INTERACTION, THUS PROVIDING NEW INSIGHTS INTO TARGETED THERAPEUTIC INTERVENTION. (HEPATOLOGY 2017;66:398-415). 2017 10 3656 34 INDUCIBLE PRMT1 ABLATION IN ADULT VASCULAR SMOOTH MUSCLE LEADS TO CONTRACTILE DYSFUNCTION AND AORTIC DISSECTION. VASCULAR SMOOTH MUSCLE CELLS (VSMCS) HAVE REMARKABLE PLASTICITY IN RESPONSE TO DIVERSE ENVIRONMENTAL CUES. ALTHOUGH THESE CELLS ARE VERSATILE, CHRONIC STRESS CAN TRIGGER VSMC DYSFUNCTION, WHICH ULTIMATELY LEADS TO VASCULAR DISEASES SUCH AS AORTIC ANEURYSM AND ATHEROSCLEROSIS. PROTEIN ARGININE METHYLTRANSFERASE 1 (PRMT1) IS A MAJOR ENZYME CATALYZING ASYMMETRIC ARGININE DIMETHYLATION OF PROTEINS THAT ARE SOURCES OF ASYMMETRIC DIMETHYLARGININE (ADMA), AN ENDOGENOUS INHIBITOR OF NITRIC OXIDE SYNTHASE. ALTHOUGH A POTENTIAL ROLE OF PRMT1 IN VASCULAR PATHOGENESIS HAS BEEN PROPOSED, ITS ROLE IN VASCULAR FUNCTION HAS YET TO BE CLARIFIED. HERE, WE INVESTIGATED THE ROLE AND UNDERLYING MECHANISM OF PRMT1 IN VASCULAR SMOOTH MUSCLE CONTRACTILITY AND FUNCTION. THE EXPRESSION OF PRMT1 AND CONTRACTILE-RELATED GENES WAS SIGNIFICANTLY DECREASED IN THE AORTAS OF ELDERLY HUMANS AND PATIENTS WITH AORTIC ANEURYSMS. MICE WITH VSMC-SPECIFIC PRMT1 ABLATION (SMKO) EXHIBITED PARTIAL LETHALITY, LOW BLOOD PRESSURE AND AORTIC DILATION. THE PRMT1-ABLATED AORTAS SHOWED AORTIC DISSECTION WITH ELASTIC FIBER DEGENERATION AND CELL DEATH. EX VIVO AND IN VITRO ANALYSES INDICATED THAT PRMT1 ABLATION SIGNIFICANTLY DECREASED THE CONTRACTILITY OF THE AORTA AND TRACTION FORCES OF VSMCS. PRMT1 ABLATION DOWNREGULATED THE EXPRESSION OF CONTRACTILE GENES SUCH AS MYOCARDIN WHILE UPREGULATING THE EXPRESSION OF SYNTHETIC GENES, THUS CAUSING THE CONTRACTILE TO SYNTHETIC PHENOTYPIC SWITCH OF VSMCS. IN ADDITION, MECHANISTIC STUDIES DEMONSTRATED THAT PRMT1 DIRECTLY REGULATES MYOCARDIN GENE ACTIVATION BY MODULATING EPIGENETIC HISTONE MODIFICATIONS IN THE MYOCARDIN PROMOTER REGION. THUS, OUR STUDY DEMONSTRATES THAT VSMC PRMT1 IS ESSENTIAL FOR VASCULAR HOMEOSTASIS AND THAT ITS ABLATION CAUSES AORTIC DILATION/DISSECTION THROUGH IMPAIRED MYOCARDIN EXPRESSION. 2021 11 5227 27 PRMT6 MEDIATES INFLAMMATION VIA ACTIVATION OF THE NF-KAPPAB/P65 PATHWAY ON A CIGARETTE SMOKE EXTRACT-INDUCED MURINE EMPHYSEMA MODEL. INTRODUCTION: SMOKE-DRIVEN LUNG INFLAMMATION IS CONSIDERED TO BE THE MAJOR PATHOPHYSIOLOGY MECHANISM OF CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD)/EMPHYSEMA. PROTEIN ARGININE METHYLTRANSFERASE 6 (PRMT6) IS A KEY EPIGENETIC ENZYME, WHICH IS RELATED TO PROTECTING THE TRI-METHYLATION OF H3K4 (H3K4ME3). WE HYPOTHESIZED THAT PTMT6 PROTECTS LUNG INFLAMMATION THROUGH THE NUCLEAR FACTOR KAPPA B (NF-KAPPAB) PATHWAY. METHODS: MICE WERE INJECTED WITH CIGARETTE SMOKE EXTRACT (CSE) OR PBS TO ESTABLISH A MICE MODEL, INTRATRACHEALLY INSTILLED WITH OVEREXPRESSED PRMT6 OR NEGATIVE CONTROL VECTOR. MORPHOMETRY OF LUNG SLIDES AND LUNG FUNCTION WERE MEASURED. WE DETERMINED THE PROTEIN EXPRESSION OF PRMT6 AND ITS RELATED HISTONE TARGETS, THE ACTIVATION OF NF-KAPPAB PATHWAY, THE LEVEL OF TUMOR NECROSIS FACTOR ALPHA (TNFALPHA) AND INTERLEUKIN-1BETA (IL-1BETA). RESULTS: AFTER PRMT6 OVEREXPRESSION, THE MORPHOMETRY INDEXES AND LUNG FUNCTION WERE IMPROVED. ALSO, THE EXPRESSION OF H3K4ME3 WAS DECREASED. OVEREXPRESSED PRMT6 COULD SUPPRESS CSE-INDUCED NF-KAPPAB ACTIVATION AND PRO-INFLAMMATION GENES EXPRESSION. CONCLUSIONS: THE OVEREXPRESSED PRMT6 COULD SERVE AS AN INFLAMMATION INHIBITOR, POTENTIALLY THROUGH BLOCKING THE NF-KAPPAB/P65 PATHWAY IN THE MURINE EMPHYSEMA MODEL. 2020 12 2884 36 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 13 4906 50 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 14 1166 46 CONTRIBUTION OF DNMT1 TO NEUROPATHIC PAIN GENESIS PARTIALLY THROUGH EPIGENETICALLY REPRESSING KCNA2 IN PRIMARY AFFERENT NEURONS. EXPRESSIONAL CHANGES OF PAIN-ASSOCIATED GENES IN PRIMARY SENSORY NEURONS OF DRG ARE CRITICAL FOR NEUROPATHIC PAIN GENESIS. DNA METHYLTRANSFERASE (DNMT)-TRIGGERED DNA METHYLATION SILENCES GENE EXPRESSION. WE SHOW HERE THAT DNMT1, A CANONICAL MAINTENANCE METHYLTRANSFERASE, ACTS AS THE DE NOVO DNMT AND IS REQUIRED FOR NEUROPATHIC PAIN GENESIS LIKELY THROUGH REPRESSING AT LEAST DRG KCNA2 GENE EXPRESSION IN MALE MICE. PERIPHERAL NERVE INJURY UPREGULATED DNMT1 EXPRESSION IN THE INJURED DRG THROUGH THE TRANSCRIPTION FACTOR CAMP RESPONSE ELEMENT BINDING PROTEIN-TRIGGERED TRANSCRIPTIONAL ACTIVATION OF DNMT1 GENE. BLOCKING THIS UPREGULATION PREVENTED NERVE INJURY-INDUCED DNA METHYLATION WITHIN THE PROMOTER AND 5'-UNTRANSLATED REGION OF KCNA2 GENE, RESCUED KCNA2 EXPRESSION AND TOTAL KV CURRENT, ATTENUATED HYPEREXCITABILITY IN THE INJURED DRG NEURONS, AND ALLEVIATED NERVE INJURY-INDUCED PAIN HYPERSENSITIVITIES. GIVEN THAT KCNA2 IS A KEY PLAYER IN NEUROPATHIC PAIN, OUR FINDINGS SUGGEST THAT DRG DNMT1 MAY BE A POTENTIAL TARGET FOR NEUROPATHIC PAIN MANAGEMENT.SIGNIFICANCE STATEMENT IN THE PRESENT STUDY, WE REPORTED THAT DNMT1, A CANONICAL DNA MAINTENANCE METHYLTRANSFERASE, IS UPREGULATED VIA THE ACTIVATION OF THE TRANSCRIPTION FACTOR CREB IN THE INJURED DRG AFTER PERIPHERAL NERVE INJURY. THIS UPREGULATION WAS RESPONSIBLE FOR NERVE INJURY-INDUCED DE NOVO DNA METHYLATION WITHIN THE PROMOTER AND 5'-UNTRANSLATED REGION OF THE KCNA2 GENE, REDUCTIONS IN KCNA2 EXPRESSION AND KV CURRENT AND INCREASES IN NEURONAL EXCITABILITY IN THE INJURED DRG. SINCE PHARMACOLOGICAL INHIBITION OR GENETIC KNOCKDOWN OF DRG DNMT1 ALLEVIATED NERVE INJURY-INDUCED PAIN HYPERSENSITIVITIES, DRG DNMT1 CONTRIBUTES TO NEUROPATHIC PAIN GENESIS PARTIALLY THROUGH REPRESSION OF DRG KCNA2 GENE EXPRESSION. 2019 15 4615 42 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 16 2885 36 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 17 1012 22 CIGARETTE SMOKE INDUCES DISTINCT HISTONE MODIFICATIONS IN LUNG CELLS: IMPLICATIONS FOR THE PATHOGENESIS OF COPD AND LUNG CANCER. CIGARETTE SMOKE (CS)-MEDIATED OXIDATIVE STRESS INDUCES SEVERAL SIGNALING CASCADES, INCLUDING KINASES, WHICH RESULTS IN CHROMATIN MODIFICATIONS (HISTONE ACETYLATION/DEACETYLATION AND HISTONE METHYLATION/DEMETHYLATION). WE HAVE PREVIOUSLY REPORTED THAT CS INDUCES CHROMATIN REMODELING IN PRO-INFLAMMATORY GENE PROMOTERS; HOWEVER, THE UNDERLYING SITE-SPECIFIC HISTONE MARKS FORMED IN HISTONES H3 AND H4 DURING CS EXPOSURE IN LUNGS IN VIVO AND IN LUNG CELLS IN VITRO, WHICH CAN EITHER DRIVE GENE EXPRESSION OR REPRESSION, ARE NOT KNOWN. WE HYPOTHESIZE THAT CS EXPOSURE IN MOUSE AND HUMAN BRONCHIAL EPITHELIAL CELLS (H292) CAN CAUSE SITE-SPECIFIC POSTTRANSLATIONAL HISTONE MODIFICATIONS (PTMS) THAT MAY PLAY AN IMPORTANT ROLE IN THE PATHOGENESIS OF CS-INDUCED CHRONIC LUNG DISEASES. WE USED A BOTTOM-UP MASS SPECTROMETRY APPROACH TO IDENTIFY SOME POTENTIALLY NOVEL HISTONE MARKS, INCLUDING ACETYLATION, MONOMETHYLATION, AND DIMETHYLATION, IN SPECIFIC LYSINE AND ARGININE RESIDUES OF HISTONES H3 AND H4 IN MOUSE LUNGS AND H292 CELLS. WE FOUND THAT CS-INDUCED DISTINCT POSTTRANSLATIONAL HISTONE MODIFICATION PATTERNS IN HISTONE H3 AND HISTONE H4 IN LUNG CELLS, WHICH MAY BE CONSIDERED AS USABLE BIOMARKERS FOR CS-INDUCED CHRONIC LUNG DISEASES. THESE IDENTIFIED HISTONE MARKS (HISTONE H3 AND HISTONE H4) MAY PLAY AN IMPORTANT ROLE IN THE EPIGENETIC STATE DURING THE PATHOGENESIS OF SMOKING-INDUCED CHRONIC LUNG DISEASES, SUCH AS CHRONIC OBSTRUCTIVE PULMONARY DISEASE AND LUNG CANCER. 2014 18 2785 39 EZH2 REGULATES SPINAL NEUROINFLAMMATION IN RATS WITH NEUROPATHIC PAIN. ALTERATION IN GENE EXPRESSION ALONG THE PAIN SIGNALING PATHWAY IS A KEY MECHANISM CONTRIBUTING TO THE GENESIS OF NEUROPATHIC PAIN. ACCUMULATING STUDIES HAVE SHOWN THAT EPIGENETIC REGULATION PLAYS A CRUCIAL ROLE IN NOCICEPTIVE PROCESS IN THE SPINAL DORSAL HORN. IN THIS PRESENT STUDY, WE INVESTIGATED THE ROLE OF ENHANCER OF ZESTE HOMOLOG-2 (EZH2), A SUBUNIT OF THE POLYCOMB REPRESSIVE COMPLEX 2, IN THE SPINAL DORSAL HORN IN THE GENESIS OF NEUROPATHIC PAIN IN RATS INDUCED BY PARTIAL SCIATIC NERVE LIGATION. EZH2 IS A HISTONE METHYLTRANSFERASE, WHICH CATALYZES THE METHYLATION OF HISTONE H3 ON K27 (H3K27), RESULTING IN GENE SILENCING. WE FOUND THAT LEVELS OF EZH2 AND TRI-METHYLATED H3K27 (H3K27TM) IN THE SPINAL DORSAL HORN WERE INCREASED IN RATS WITH NEUROPATHIC PAIN ON DAY 3 AND DAY 10 POST NERVE INJURIES. EZH2 WAS PREDOMINANTLY EXPRESSED IN NEURONS IN THE SPINAL DORSAL HORN UNDER NORMAL CONDITIONS. THE NUMBER OF NEURONS WITH EZH2 EXPRESSION WAS INCREASED AFTER NERVE INJURY. MORE STRIKINGLY, NERVE INJURY DRASTICALLY INCREASED THE NUMBER OF MICROGLIA WITH EZH2 EXPRESSION BY MORE THAN SEVENFOLD. INTRATHECAL INJECTION OF THE EZH2 INHIBITOR ATTENUATED THE DEVELOPMENT AND MAINTENANCE OF MECHANICAL AND THERMAL HYPERALGESIA IN RATS WITH NERVE INJURY. SUCH ANALGESIC EFFECTS WERE CONCURRENTLY ASSOCIATED WITH THE REDUCED LEVELS OF EZH2, H3K27TM, IBA1, GFAP, TNF-ALPHA, IL-1BETA, AND MCP-1 IN THE SPINAL DORSAL HORN IN RATS WITH NERVE INJURY. OUR RESULTS HIGHLY SUGGEST THAT TARGETING THE EZH2 SIGNALING PATHWAY COULD BE AN EFFECTIVE APPROACH FOR THE MANAGEMENT OF NEUROPATHIC PAIN. 2017 19 4098 43 MBD1 CONTRIBUTES TO THE GENESIS OF ACUTE PAIN AND NEUROPATHIC PAIN BY EPIGENETIC SILENCING OF OPRM1 AND KCNA2 GENES IN PRIMARY SENSORY NEURONS. THE TRANSMISSION OF NORMAL SENSORY AND/OR ACUTE NOXIOUS INFORMATION REQUIRES INTACT EXPRESSION OF PAIN-ASSOCIATED GENES WITHIN THE PAIN PATHWAYS OF NERVOUS SYSTEM. EXPRESSIONAL CHANGES OF THESE GENES AFTER PERIPHERAL NERVE INJURY ARE ALSO CRITICAL FOR NEUROPATHIC PAIN INDUCTION AND MAINTENANCE. METHYL-CPG-BINDING DOMAIN PROTEIN 1 (MBD1), AN EPIGENETIC REPRESSOR, REGULATES GENE TRANSCRIPTIONAL ACTIVITY. WE REPORT HERE THAT MBD1 IN THE PRIMARY SENSORY NEURONS OF DRG IS CRITICAL FOR THE GENESIS OF ACUTE PAIN AND NEUROPATHIC PAIN AS DRG MBD1-DEFICIENT MICE EXHIBIT THE REDUCED RESPONSES TO ACUTE MECHANICAL, HEAT, COLD, AND CAPSAICIN STIMULI AND THE BLUNTED NERVE INJURY-INDUCED PAIN HYPERSENSITIVITIES. FURTHERMORE, DRG OVEREXPRESSION OF MBD1 LEADS TO SPONTANEOUS PAIN AND EVOKED PAIN HYPERSENSITIVITIES IN THE WT MICE AND RESTORES ACUTE PAIN SENSITIVITIES IN THE MBD1-DEFICIENT MICE. MECHANISTICALLY, MDB1 REPRESSES OPRM1 AND KCNA2 GENE EXPRESSION BY RECRUITING DNA METHYLTRANSFERASE DNMT3A INTO THESE TWO GENE PROMOTERS IN THE DRG NEURONS. DRG MBD1 IS LIKELY A KEY PLAYER UNDER THE CONDITIONS OF ACUTE PAIN AND NEUROPATHIC PAIN.SIGNIFICANCE STATEMENT IN THE PRESENT STUDY, WE REVEALED THAT THE MICE WITH DEFICIENCY OF METHYL-CPG-BINDING DOMAIN PROTEIN 1 (MBD1), AN EPIGENETIC REPRESSOR, IN THE DRG DISPLAYED THE REDUCED RESPONSES TO ACUTE NOXIOUS STIMULI AND THE BLUNTED NEUROPATHIC PAIN. WE ALSO SHOWED THAT DRG OVEREXPRESSION OF MBD1 PRODUCED THE HYPERSENSITIVITIES TO NOXIOUS STIMULI IN THE WT MICE AND RESCUED ACUTE PAIN SENSITIVITIES IN THE MBD1-DEFICIENT MICE. WE HAVE ALSO PROVIDED THE EVIDENCE THAT MDB1 REPRESSES OPRM1 AND KCNA2 GENE EXPRESSION BY RECRUITING DNA METHYLTRANSFERASE DNMT3A INTO THESE TWO GENE PROMOTERS IN THE DRG NEURONS. DRG MBD1 MAY PARTICIPATE IN THE GENESIS OF ACUTE PAIN AND NEUROPATHIC PAIN LIKELY THROUGH REGULATING DNMT3A-CONTROLLED OPRM1 AND KCNA2 GENE EXPRESSION IN THE DRG NEURONS. 2018 20 2197 27 EPIGENETIC MODIFICATION OF BDNF MEDIATES NEUROPATHIC PAIN VIA MIR-30A-3P/EP300 AXIS IN CCI RATS. RECENT INVESTIGATION OF MICRORNAS ON CHRONIC PAIN HAS DEVELOPED A BREAKTHROUGH IN NEUROPATHIC PAIN MANAGEMENT. IN THE PRESENT STUDY, DECREASED EXPRESSION OF MIR-30A-3P WAS REPORTED USING QRT-PCR ANALYSIS AND LOSS OF MIR-30A-3P PROMOTED NEUROPATHIC PAIN PROGRESSION IN SCIATIC NERVE CHRONIC CONSTRICTIVE INJURY RATS THROUGH DETERMINING THE PAIN THRESHOLD. WE PREDICTED MIR-30A-3P COULD TARGET E-CADHERIN TRANSCRIPTIONAL ACTIVATOR (EP300) VIA BIOINFORMATICS ANALYSIS. MEANWHILE, WE FOUND THAT BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) IS INVOLVED IN NEUROPATHIC PAIN. HERE, WE EXHIBITED THAT EP300 EPIGENETICALLY UP-REGULATED BDNF VIA ENHANCING ACETYLATED HISTONE H3 AND H4 ON THE PROMOTER. FOR ANOTHER, MIR-30A-3P WAS ABLE TO MODIFY THE LEVEL OF BDNF AND ACETYLATED HISTONE H3 AND H4. LOSS OF MIR-30A-3P ENHANCED EP300 AND BDNF COLOCALIZATION IN CCI RATS. SUBSEQUENTLY, IT WAS SHOWN THAT INCREASED EP300 INDUCED NEUROPATHIC PAIN BY AN ENHANCEMENT OF NEURONAL BDNF LEVEL IN VIVO. TO SUM UP, IT WAS REVEALED THAT EPIGENETIC MODIFICATION OF BDNF PROMOTED NEUROPATHIC PAIN VIA EP300 INDUCED BY MIR-30A-3P IN CCI RATS. 2020