1 5165 128 PRECLINICAL RESERPINE MODELS RECAPITULATING MOTOR AND NON-MOTOR FEATURES OF PARKINSON'S DISEASE: ROLES OF EPIGENETIC UPREGULATION OF ALPHA-SYNUCLEIN AND AUTOPHAGY IMPAIRMENT. RESERPINE IS AN EFFECTIVE DRUG FOR THE CLINICAL TREATMENT OF HYPERTENSION. IT ALSO INDUCES PARKINSON'S DISEASE (PD)-LIKE SYMPTOMS IN HUMANS AND ANIMALS POSSIBLE THROUGH THE INHIBITION OF MONOAMINE VESICULAR TRANSPORTERS, THUS DECREASING THE LEVELS OF MONOAMINE NEUROTRANSMITTERS IN THE BRAIN. HOWEVER, THE PRECISE MECHANISMS REMAIN UNCLEAR. HEREIN, WE AIMED TO DEVELOP A PRECLINICAL RESERPINE MODEL RECAPITULATING THE NON-MOTOR AND MOTOR SYMPTOMS OF PD AND INVESTIGATE THE UNDERLYING POTENTIAL CELLULAR MECHANISMS. INCUBATION OF RESERPINE INDUCED APOPTOSIS, LED TO THE ACCUMULATION OF INTRACELLULAR REACTIVE OXYGEN SPECIES (ROS), LOWERED DNA METHYLATION OF ALPHA-SYNUCLEIN GENE, RESULTED IN ALPHA-SYNUCLEIN PROTEIN DEPOSITION, AND ELEVATED THE RATIO OF LC3-II/LC3-I AND P62 IN CULTURED SH-SY5Y CELLS. FEEDING RESERPINE DOSE-DEPENDENTLY SHORTENED THE LIFESPAN AND CAUSED IMPAIRMENT OF MOTOR FUNCTIONS IN MALE AND FEMALE DROSOPHILA. MOREOVER, LONG-TERM ORAL ADMINISTRATION OF RESERPINE LED TO MULTIPLE MOTOR AND NON-MOTOR SYMPTOMS, INCLUDING CONSTIPATION, PAIN HYPERSENSITIVITY, OLFACTORY IMPAIRMENT, AND DEPRESSION-LIKE BEHAVIORS IN MICE. THE MECHANISTIC STUDIES SHOWED THAT CHRONIC RESERPINE EXPOSURE CAUSED HYPOMETHYLATION OF THE ALPHA-SYNUCLEIN GENE AND UP-REGULATED ITS EXPRESSION AND ELEVATED THE RATIO OF LC3-II/LC3-I AND EXPRESSION OF P62 IN THE SUBSTANTIA NIGRA OF MICE. THUS, WE ESTABLISHED PRECLINICAL ANIMAL MODELS USING RESERPINE TO RECAPITULATE THE MOTOR AND NON-MOTOR SYMPTOMS OF PD. CHRONIC RESERPINE EXPOSURE EPIGENETICALLY ELEVATED THE LEVELS OF ALPHA-SYNUCLEIN EXPRESSION POSSIBLE BY LOWERING THE DNA METHYLATION STATUS AND INDUCING AUTOPHAGIC IMPAIRMENT IN VITRO AND IN VIVO. 2022 2 2352 25 EPIGENETIC REGULATION OF NRF2/KEAP1 BY PHYTOCHEMICALS. EPIGENETICS HAS PROVIDED A NEW DIMENSION TO OUR UNDERSTANDING OF NUCLEAR FACTOR ERYTHROID 2-RELATED FACTOR 2/KELCH-LIKE ECH-ASSOCIATED PROTEIN 1 (HUMAN NRF2/KEAP1 AND MURINE NRF2/KEAP1) SIGNALING. UNLIKE THE GENETIC CHANGES AFFECTING DNA SEQUENCE, THE REVERSIBLE NATURE OF EPIGENETIC ALTERATIONS PROVIDES AN ATTRACTIVE AVENUE FOR CANCER INTERCEPTION. THUS, TARGETING EPIGENETIC MECHANISMS IN THE CORRESPONDING SIGNALING NETWORKS REPRESENTS AN ENTICING STRATEGY FOR THERAPEUTIC INTERVENTION WITH DIETARY PHYTOCHEMICALS ACTING AT TRANSCRIPTIONAL, POST-TRANSCRIPTIONAL, AND POST-TRANSLATIONAL LEVELS. THIS REGULATION INVOLVES THE INTERPLAY OF HISTONE MODIFICATIONS AND DNA METHYLATION STATES IN THE HUMAN NFE2L2/KEAP1 AND MURINE NFE2L2/KEAP1 GENES, ACETYLATION OF LYSINE RESIDUES IN NRF2 AND NRF2, INTERACTION WITH BROMODOMAIN AND EXTRATERMINAL DOMAIN (BET) ACETYL "READER" PROTEINS, AND NON-CODING RNAS SUCH AS MICRORNA (MIRNA) AND LONG NON-CODING RNA (LNCRNA). PHYTOCHEMICALS DOCUMENTED TO MODULATE NRF2 SIGNALING ACT BY REVERSING HYPERMETHYLATED STATES IN THE CPG ISLANDS OF NFE2L2 OR NFE2L2, VIA THE INHIBITION OF DNA METHYLTRANSFERASES (DNMTS) AND HISTONE DEACETYLASES (HDACS), THROUGH THE INDUCTION OF TEN-ELEVEN TRANSLOCATION (TET) ENZYMES, OR BY INDUCING MIRNA TO TARGET THE 3'-UTR OF THE CORRESPONDING MRNA TRANSCRIPTS. TO DATE, FEWER THAN TWENTY PHYTOCHEMICALS HAVE BEEN REPORTED AS NRF2 EPIGENETIC MODIFIERS, INCLUDING CURCUMIN, SULFORAPHANE, RESVERATROL, RESERPINE, AND URSOLIC ACID. THIS OPENS AVENUES FOR EXPLORING ADDITIONAL DIETARY PHYTOCHEMICALS THAT REGULATE THE HUMAN EPIGENOME, AND THE POTENTIAL FOR NOVEL STRATEGIES TO TARGET NRF2 SIGNALING WITH A VIEW TO BENEFICIAL INTERCEPTION OF CANCER AND OTHER CHRONIC DISEASES. 2020 3 3341 27 HISTONE DEACETYLASE-2 IS INVOLVED IN STRESS-INDUCED COGNITIVE IMPAIRMENT VIA HISTONE DEACETYLATION AND PI3K/AKT SIGNALING PATHWAY MODIFICATION. EXPOSURE TO CHRONIC STRESS UPREGULATES BLOOD GLUCOCORTICOID LEVELS AND IMPAIRS COGNITION VIA DIVERSE EPIGENETIC MECHANISMS, SUCH AS HISTONE DEACETYLATION. HISTONE DEACETYLATION CAN LEAD TO TRANSCRIPTIONAL SILENCING OF MANY PROTEINS INVOLVED IN COGNITION AND MAY ALSO CAUSE LEARNING AND MEMORY DYSFUNCTION. HISTONE DEACETYLASE?2 (HDAC2) HAS BEEN DEMONSTRATED TO EPIGENETICALLY BLOCK COGNITION VIA A REDUCTION IN THE HISTONE ACETYLATION LEVEL; HOWEVER, IT IS UNKNOWN WHETHER HDAC2 IS INVOLVED IN THE COGNITIVE DECLINE INDUCED BY CHRONIC STRESS. TO THE BEST OF AUTHORS' KNOWLEDGE, THIS IS THE FIRST STUDY TO DEMONSTRATE THAT THE STRESS HORMONE CORTICOSTEROID UPREGULATE HDAC2 PROTEIN LEVELS IN NEURO?2A CELLS AND CAUSE CELL INJURIES. HDAC2 KNOCKDOWN RESULTED IN A SIGNIFICANT AMELIORATION OF THE PATHOLOGICAL CHANGES IN N2A CELLS VIA THE UPREGULATION OF HISTONE ACETYLATION AND MODIFICATIONS IN THE PHOSPHOINOSITIDE 3?KINASE/PROTEIN KINASE B SIGNALING PATHWAY. IN ADDITION, THE HDAC2 PROTEIN LEVELS WERE UPREGULATED IN 12?MONTH?OLD FEMALE C57BL/6J MICE UNDER CHRONIC STRESS IN VIVO. TAKEN TOGETHER, THESE FINDINGS SUGGESTED THAT HDAC2 MAY BE AN IMPORTANT NEGATIVE REGULATOR INVOLVED IN CHRONIC STRESS?INDUCED COGNITIVE IMPAIRMENT. 2017 4 2119 24 EPIGENETIC HISTONE MODIFICATION REGULATES DEVELOPMENTAL LEAD EXPOSURE INDUCED HYPERACTIVITY IN RATS. LEAD (PB) EXPOSURE WAS COMMONLY CONSIDERED AS A HIGH ENVIRONMENTAL RISK FACTOR FOR THE DEVELOPMENT OF ATTENTION-DEFICIT/HYPERACTIVITY DISORDER (ADHD). HOWEVER, THE MOLECULAR BASIS OF THIS PATHOLOGICAL PROCESS STILL REMAINS ELUSIVE. IN LIGHT OF THE ROLE OF EPIGENETICS IN MODULATING THE NEUROLOGICAL DISEASE AND THE CAUSATIVE ENVIRONMENT, THE ALTERATIONS OF HISTONE MODIFICATIONS IN THE HIPPOCAMPUS OF RATS EXPOSED BY VARIOUS DOSES OF LEAD, ALONG WITH CONCOMITANT BEHAVIORAL DEFICITS, WERE INVESTIGATED IN THIS STUDY. ACCORDING TO THE FREE AND FORCED OPEN FIELD TEST, THERE SHOWED THAT IN A DOSAGE-DEPENDENT MANNER, LEAD EXPOSURE COULD RESULT IN THE INCREASED LOCOMOTOR ACTIVITY OF RATS, THAT IS, HYPERACTIVITY: A SUBTYPE OF ADHD. WESTERN BLOTTING ASSAYS REVEALED THAT THE LEVELS OF HISTONE ACETYLATION INCREASED SIGNIFICANTLY IN THE HIPPOCAMPUS BY CHRONIC LEAD EXPOSURE, WHILE NO DRAMATIC CHANGES WERE DETECTED IN TERMS OF EXPRESSION YIELDS OF ADHD-RELATED DOPAMINERGIC PROTEINS, INDICATING THAT HISTONE ACETYLATION PLAYS ESSENTIAL ROLES IN THIS TOXICANT-INVOLVED PATHOGENESIS. IN ADDITION, THE INCREASED LEVEL OF HISTONE ACETYLATION MIGHT BE ATTRIBUTED TO THE ENZYMATIC ACTIVITY OF P300, A TYPICAL HISTONE ACETYLTRANSFERASE, AS THE TRANSCRIPTIONAL LEVEL OF P300 WAS SIGNIFICANTLY INCREASED UPON HIGHER-DOSE PB EXPOSURE. IN SUMMARY, THIS STUDY FIRST DISCOVERED THE EPIGENETIC MECHANISM BRIDGING THE ENVIRONMENTAL INFLUENCE (PB) AND THE DISEASE ITSELF (ADHD) IN THE HISTONE MODIFICATION LEVEL, PAVING THE WAY FOR THE COMPREHENSIVE UNDERSTANDING OF ADHD'S ETIOLOGY AND IN FURTHER STEPS, ESTABLISHING THE THERAPY STRATEGY OF THIS WIDESPREAD NEUROLOGICAL DISORDER. 2014 5 330 34 ALPHA-SYNUCLEIN AND MECHANISMS OF EPIGENETIC REGULATION. SYNUCLEINOPATHIES ARE A GROUP OF NEURODEGENERATIVE DISEASES WITH COMMON PATHOLOGICAL LESIONS ASSOCIATED WITH THE EXCESSIVE ACCUMULATION AND ABNORMAL INTRACELLULAR DEPOSITION OF TOXIC SPECIES OF ALPHA-SYNUCLEIN. THE SHARED CLINICAL FEATURES ARE CHRONIC PROGRESSIVE DECLINE OF MOTOR, COGNITIVE, AND BEHAVIORAL FUNCTIONS. THESE DISORDERS INCLUDE PARKINSON'S DISEASE, DEMENTIA WITH LEWY BODY, AND MULTIPLE SYSTEM ATROPHY. VIGOROUS RESEARCH IN THE MECHANISMS OF PATHOLOGY OF THESE ILLNESSES IS CURRENTLY UNDER WAY TO FIND DISEASE-MODIFYING TREATMENT AND MOLECULAR MARKERS FOR EARLY DIAGNOSIS. ALPHA-SYNUCLEIN IS A PRONE-TO-AGGREGATE, SMALL AMYLOIDOGENIC PROTEIN WITH MULTIPLE ROLES IN SYNAPTIC VESICLE TRAFFICKING, NEUROTRANSMITTER RELEASE, AND INTRACELLULAR SIGNALING EVENTS. ITS EXPRESSION IS CONTROLLED BY SEVERAL MECHANISMS, ONE OF WHICH IS EPIGENETIC REGULATION. WHEN TRANSMITTED TO THE NUCLEUS, ALPHA-SYNUCLEIN BINDS TO DNA AND HISTONES AND PARTICIPATES IN EPIGENETIC REGULATORY FUNCTIONS CONTROLLING SPECIFIC GENE TRANSCRIPTION. HERE, WE DISCUSS THE VARIOUS ASPECTS OF ALPHA-SYNUCLEIN INVOLVEMENT IN EPIGENETIC REGULATION IN HEALTH AND DISEASES. 2023 6 2417 27 EPIGENETIC SIGNATURE OF CHRONIC CEREBRAL HYPOPERFUSION AND BENEFICIAL EFFECTS OF S-ADENOSYLMETHIONINE IN RATS. CHRONIC CEREBRAL HYPOPERFUSION IS ASSOCIATED WITH COGNITIVE DECLINE IN AGING AND AGE-RELATED NEURODEGENERATIVE DISEASE. EPIGENETIC MECHANISMS ARE INVOLVED IN THE MAINTENANCE OF LONG-TERM HYPOXIA-ADAPTED CELLULAR PHENOTYPES. IN THE PRESENT STUDY, THE EPIGENETIC SIGNATURES SUCH AS DNA METHYLATION AND HISTONE ACETYLATION, AS WELL AS S-ADENOSYLMETHIONINE (SAM) CYCLE USING CHRONIC CEREBRAL HYPOPERFUSION RAT MODEL WERE EXPLORED. CHRONIC CEREBRAL HYPOXIA-INDUCED GLOBAL DNA HYPERMETHYLATION ASSOCIATED WITH THE INCREASE OF DNA METHYLTRANSFERASE (DNMT) 3A AS WELL AS ALTERATION OF SAM CYCLE. MEANWHILE, AN ENHANCED LEVEL OF GLOBAL HISTONE H4 ACETYLATION ACCOMPANIED WITH THE UPREGULATION OF HISTONE ACETYLTRANSFERASE, P300/CREB-BINDING PROTEIN (CBP), AND THE DOWNREGULATION OF HISTONE DEACETYLASES (HDACS), WAS ALSO OBSERVED. SAM COULD IMPROVE SPATIAL CAPACITY THROUGH THE UPREGULATION OF ACETYLCHOLINE AND BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) RATHER THAN ALTERATION OF DNA METHYLATION LEVELS. IN CONCLUSION, WE HAVE DEMONSTRATED A GENOME-WIDE ADJUSTMENT OF DNA METHYLATION AND HISTONE ACETYLATION UNDER CHRONIC CEREBRAL HYPOXIC CONDITIONS IN A RAT'S BRAIN. THESE EPIGENETIC SIGNATURES MAY REPRESENT AN ADDITIONAL MECHANISM TO PROMOTE AND MAINTAIN A HYPOXIC-ADAPTED CELLULAR RESPONDS WITH A POTENTIAL ROLE IN MEMORY DEFICITS. 2014 7 4768 21 NUCLEAR EFFECTS OF ETHANOL-INDUCED PROTEASOME INHIBITION IN LIVER CELLS. ALCOHOL INGESTION CAUSES ALTERATION IN SEVERAL CELLULAR MECHANISMS, AND LEADS TO INFLAMMATION, APOPTOSIS, IMMUNOLOGICAL RESPONSE DEFECTS, AND FIBROSIS. THESE PHENOMENA ARE ASSOCIATED WITH SIGNIFICANT CHANGES IN THE EPIGENETIC MECHANISMS, AND SUBSEQUENTLY, TO LIVER CELL MEMORY. THE UBIQUITIN-PROTEASOME PATHWAY IS ONE OF THE VITAL PATHWAYS IN THE CELL THAT BECOMES DYSFUNCTIONAL AS A RESULT OF CHRONIC ETHANOL CONSUMPTION. INHIBITION OF THE PROTEASOME ACTIVITY IN THE NUCLEUS CAUSES CHANGES IN THE TURNOVER OF TRANSCRIPTIONAL FACTORS, HISTONE MODIFYING ENZYMES, AND THEREFORE, AFFECTS EPIGENETIC MECHANISMS. ALCOHOL CONSUMPTION HAS BEEN ASSOCIATED WITH AN INCREASE IN HISTONE ACETYLATION AND A DECREASE IN HISTONE METHYLATION, WHICH LEADS TO GENE EXPRESSION CHANGES. DNA AND HISTONE MODIFICATIONS THAT RESULT FROM ETHANOL-INDUCED PROTEASOME INHIBITION ARE KEY PLAYERS IN REGULATING GENE EXPRESSION, ESPECIALLY GENES INVOLVED IN THE CELL CYCLE, IMMUNOLOGICAL RESPONSES, AND METABOLISM OF ETHANOL. THE PRESENT REVIEW HIGHLIGHTS THE CONSEQUENCES OF ETHANOL-INDUCED PROTEASOME INHIBITION IN THE NUCLEUS OF LIVER CELLS THAT ARE CHRONICALLY EXPOSED TO ETHANOL. 2009 8 6775 30 [ALCOHOL DEPENDENCE MEDIATED BY MONOAMINE NEUROTRANSMITTERS IN THE CENTRAL NERVOUS SYSTEM]. ALCOHOL DEPENDENCE, A CHRONIC RELAPSING BRAIN DISEASE WITH THE CHARACTERISTICS OF DRINKING ALCOHOL OUT OF CONTROL, HAS BECOME A SERIOUS SOCIAL PROBLEM. MONOAMINE NEUROTRANSMITTERS, MAINLY INCLUDING DOPAMINE AND 5-HYDROXYTRYP NOTTAMINE, PLAY IMPORTANT ROLES IN THE OCCURRENCE, DEVELOPMENT AND NEURAL DYSFUNCTION OF ALCOHOL DEPENDENCE SYNDROME. IN THIS REVIEW, THE ROLES OF KEY FACTORS OF THE MONOAMINE SYSTEM (DOPAMINE RECEPTOR GENES, 5-HYDROXYTRYPTAMINE RECEPTOR GENES, TRANSPORTER GENES, TYROSINE HYDROXYLASE GENE, TRYPTOPHANHYDROXYLASE GENE AND MONOAMINE OXIDASE GENE) IN ALCOHOL DEPENDENCE WERE DISCUSSED, AND STRATEGIES FOR FURTHER STUDIES OF MOLECULAR MECHANISMS WERE PROPOSED BASED ON GENE KNOCKOUT MICE MODELS GENERATED IN OUR LABORATORY. THEN, COMBINING WITH STUDIES ON TYROSINE HYDROXYLASE ACTIVATOR CAMKII IN OUR LAB, THERAPEUTIC TARGETS WERE DISCUSSED. BESIDES, EPIGENETIC STRATEGIES FOR PREVENTION AND TREATMENT OF ALCOHOL DEPENDENCE SYNDROME WERE PROPOSED. FURTHERMORE, MANIPULATING METHYLATION LEVELS IN GENE REGULATORY REGIONS AND ALTERNATIVE SPLICING OF PRE-MRNAS MIGHT ALSO HAVE CLINICAL IMPLICATIONS. FINALLY, BASED ON NEW FINDINGS ON GENETIC POLYMORPHISM, IT IS OF GREAT POTENTIAL TO CARRY OUT INDIVIDUAL PREVENTION AND TREATMENT FOR PATIENTS SUFFERING FROM ALCOHOL DEPENDENCE. 2014 9 2280 33 EPIGENETIC REGULATION IN DRUG ADDICTION. THE INTERACTION BETWEEN ENVIRONMENTAL SIGNALS AND GENES HAS NOW TAKEN ON A CLEAR MOLECULAR FORM AS DEMONSTRATED BY STABLE CHANGES IN CHROMATIN STRUCTURE. THESE CHANGES OCCUR THROUGH ACTIVATION OR REPRESSION OF SPECIFIC GENE PROGRAMMES BY A COMBINATION OF CHROMATIN REMODELLING, ACTIVATION AND ENZYMATIC MODIFICATION OF DNA AND HISTONES AS WELL AS NUCLEOSOMAL SUBUNIT EXCHANGE. RECENT RESEARCH INVESTIGATING THE MOLECULAR MECHANISMS CONTROLLING DRUG-INDUCED TRANSCRIPTIONAL, BEHAVIOURAL AND SYNAPTIC ACTIVITY HAS SHOWN A DIRECT ROLE FOR CHROMATIN REMODELLING--TERMED AS EPIGENETIC REGULATION--OF NEURONAL GENE PROGRAMMES AND SUBSEQUENT ADDICTIVE BEHAVIOUR ARISING FROM IT. RECENT DATA SUGGEST THAT REPEATED EXPOSURE TO CERTAIN DRUGS PROMOTES CHANGES IN LEVELS OF HISTONE ACETYLATION, PHOSPHORYLATION AND METHYLATION, TOGETHER WITH ALTERATIONS IN DNA METHYLATION LEVELS IN THE NEURONS OF THE BRAIN REWARD CENTRE, LOCALISED IN THE NUCLEUS ACCUMBENS (NAC) REGION OF THE LIMBIC SYSTEM. THE COMBINATION OF ACETYLATING, PHOSPHORYLATING AND METHYLATING H3 AND H4 HISTONE TAILS ALTER CHROMATIN COMPACTION THEREBY PROMOTING ALTERED LEVELS OF CELLULAR GENE EXPRESSION. HISTONE MODIFICATIONS, WHICH WEAKEN HISTONE INTERACTION WITH DNA OR THAT PROMOTE RECRUITMENT OF TRANSCRIPTIONAL ACTIVATING COMPLEXES, CORRELATE WITH PERMISSIVE GENE EXPRESSION. HISTONE DEACETYLATION, (WHICH STRENGTHEN HISTONE: DNA CONTACTS), OR HISTONE METHYLATION, (WHICH RECRUITS REPRESSIVE COMPLEXES TO CHROMATIN), PROMOTE A STATE OF TRANSCRIPTIONAL REPRESSION. USING ANIMAL MODELS, ACUTE COCAINE TREATMENT INCREASES H4 ACETYLATION AT ACUTELY REGULATED GENE PROMOTERS, WHEREAS H3 ACETYLATION APPEARS TO PREDOMINATE AT CHRONICALLY INDUCED PROMOTERS. CHRONIC COCAINE AND ALCOHOL TREATMENT ACTIVATE AND REPRESS MANY GENES SUCH AS FOSB, CDK5, AND BDNF, WHERE THEIR DYSREGULATION, AT THE CHROMATIN LEVEL, CONTRIBUTE TO THE DEVELOPMENT AND MAINTENANCE OF ADDICTION. FOLLOWING DRUG EXPOSURE, IT IS STILL UNKNOWN, HOWVER, HOW LONG THESE CHANGES IN CHROMATIN STRUCTURE PERSIST IN AFFECTING NEURONAL FUNCTION, BUT SOME DO SO FOR LIFE. 2012 10 3527 21 IL-6 ENHANCES THE NUCLEAR TRANSLOCATION OF DNA CYTOSINE-5-METHYLTRANSFERASE 1 (DNMT1) VIA PHOSPHORYLATION OF THE NUCLEAR LOCALIZATION SEQUENCE BY THE AKT KINASE. THE EPIGENETIC PROGRAMMING OF GENOMIC DNA IS ACCOMPLISHED, IN PART, BY SEVERAL DNA CYTOSINE-5-METHYLTRANSFERASES THAT ACT BY COVALENTLY MODIFYING CYTOSINES WITH THE ADDITION OF A METHYL GROUP. THIS COVALENT MODIFICATION IS MAINTAINED BY THE DNA CYTOSINE-5-METHYLTRANSFERASE-1 ENZYME (DNMT1), WHICH IS CAPABLE OF ACTING IN CONCERT WITH OTHER SIMILAR ENZYMES TO SILENCE IMPORTANT TUMOR SUPPRESSOR GENES. IL-6 IS A MULTIFUNCTIONAL MEDIATOR OF INFLAMMATION, ACTING THROUGH SEVERAL MAJOR SIGNALING CASCADES, INCLUDING THE PHOSPHATIDYLINOSITOL-3-KINASE PATHWAY (PI-3-K), WHICH ACTIVATES PROTEIN KINASE B (AKT/PKB) DOWNSTREAM. HERE, WE SHOW THAT THE SUBCELLULAR LOCALIZATION OF DNMT1 CAN BE ALTERED BY THE ADDITION OF IL-6, INCREASING THE RATE OF NUCLEAR TRANSLOCATION OF THE ENZYME FROM THE CYTOSOLIC COMPARTMENT. THE MECHANISM OF NUCLEAR TRANSLOCATION OF DNMT1 IS GREATLY ENHANCED BY PHOSPHORYLATION OF THE DNMT1 NUCLEAR LOCALIZATION SIGNAL (NLS) BY PKB/AKT KINASE. MUTAGENIC ALTERATION OF THE TWO AKT TARGET AMINO ACIDS WITHIN THE NLS RESULTS IN A MAJOR LOSS OF DNMT1 NUCLEAR TRANSLOCATION, WHILE THE CREATION OF A "PHOSPHO-MIMIC" AMINO ACID (MUTATION TO ACIDIC RESIDUES) RESTORES THIS COMPARTMENTATION ABILITY. THESE OBSERVATIONS SUGGEST AN INTERESTING HYPOTHESIS REGARDING HOW MEDIATORS OF CHRONIC INFLAMMATION MAY DISTURB THE DELICATE BALANCE OF CELLULAR COMPARTMENTALIZATION OF IMPORTANT PROTEINS, AND REVEALS A POTENTIAL MECHANISM FOR THE INDUCTION OR ENHANCEMENT OF TUMOR GROWTH VIA ALTERATION OF THE COMPONENTS INVOLVED IN THE EPIGENETIC PROGRAMMING OF A CELL. 2007 11 5143 29 POTENTIAL ROLE OF EPIGENETIC MECHANISM IN MANGANESE INDUCED NEUROTOXICITY. MANGANESE IS A VITAL NUTRIENT AND IS MAINTAINED AT AN OPTIMAL LEVEL (2.5-5 MG/DAY) IN HUMAN BODY. CHRONIC EXPOSURE TO MANGANESE IS ASSOCIATED WITH NEUROTOXICITY AND CORRELATED WITH THE DEVELOPMENT OF VARIOUS NEUROLOGICAL DISORDERS SUCH AS PARKINSON'S DISEASE. OXIDATIVE STRESS MEDIATED APOPTOTIC CELL DEATH HAS BEEN WELL ESTABLISHED MECHANISM IN MANGANESE INDUCED TOXICITY. OXIDATIVE STRESS HAS A POTENTIAL TO ALTER THE EPIGENETIC MECHANISM OF GENE REGULATION. EPIGENETIC INSIGHT OF MANGANESE NEUROTOXICITY IN CONTEXT OF ITS CORRELATION WITH THE DEVELOPMENT OF PARKINSONISM IS POORLY UNDERSTOOD. PARKINSON'S DISEASE IS CHARACTERIZED BY THE ALPHA-SYNUCLEIN AGGREGATION IN THE FORM OF LEWY BODIES IN NEURONAL CELLS. RECENT FINDINGS ILLUSTRATE THAT MANGANESE CAN CAUSE OVEREXPRESSION OF ALPHA-SYNUCLEIN. ALPHA-SYNUCLEIN ACTS EPIGENETICALLY VIA INTERACTION WITH HISTONE PROTEINS IN REGULATING APOPTOSIS. ALPHA-SYNUCLEIN ALSO CAUSES GLOBAL DNA HYPOMETHYLATION THROUGH SEQUESTRATION OF DNA METHYLTRANSFERASE IN CYTOPLASM. AN INDIVIDUAL GENETIC DIFFERENCE MAY ALSO HAVE AN INFLUENCE ON EPIGENETIC SUSCEPTIBILITY TO MANGANESE NEUROTOXICITY AND THE DEVELOPMENT OF PARKINSON'S DISEASE. THIS REVIEW PRESENTS THE CURRENT STATE OF FINDINGS IN RELATION TO ROLE OF EPIGENETIC MECHANISM IN MANGANESE INDUCED NEUROTOXICITY, WITH A SPECIAL EMPHASIS ON THE DEVELOPMENT OF PARKINSON'S DISEASE. 2016 12 2442 27 EPIGENETIC STABILITY IN THE ADULT MOUSE CORTEX UNDER CONDITIONS OF PHARMACOLOGICALLY INDUCED HISTONE ACETYLATION. HISTONE ACETYLATION IS CONSIDERED A MAJOR EPIGENETIC PROCESS THAT AFFECTS BRAIN DEVELOPMENT AND SYNAPTIC PLASTICITY, AS WELL AS LEARNING AND MEMORY. THE TRANSCRIPTIONAL EFFECTORS AND MORPHOLOGICAL CHANGES RESPONSIBLE FOR PLASTICITY AS A RESULT OF LONG-TERM MODIFICATIONS TO HISTONE ACETYLATION ARE NOT FULLY UNDERSTOOD. TO THIS END, WE PHARMACOLOGICALLY INHIBITED HISTONE DEACETYLATION USING TRICHOSTATIN A IN ADULT (6-MONTH-OLD) MICE AND FOUND SIGNIFICANT INCREASES IN THE LEVELS OF THE ACETYLATED HISTONE MARKS H3LYS9, H3LYS14 AND H4LYS12. HIGH-RESOLUTION TRANSCRIPTOME ANALYSIS OF DIVERSE BRAIN REGIONS UNCOVERED FEW DIFFERENCES IN GENE EXPRESSION BETWEEN TREATED AND CONTROL ANIMALS, NONE OF WHICH WERE PLASTICITY RELATED. INSTEAD, AFTER INCREASED HISTONE ACETYLATION, WE DETECTED A LARGE NUMBER OF NOVEL TRANSCRIPTIONALLY ACTIVE REGIONS, WHICH CORRESPOND TO LONG NON-CODING RNAS (LNCRNAS). WE ALSO SURPRISINGLY FOUND NO SIGNIFICANT CHANGES IN DENDRITIC SPINE PLASTICITY IN LAYERS 1 AND 2/3 OF THE VISUAL CORTEX USING LONG-TERM IN VIVO TWO-PHOTON IMAGING. OUR RESULTS INDICATE THAT CHRONIC PHARMACOLOGICALLY INDUCED HISTONE ACETYLATION CAN BE DECOUPLED FROM GENE EXPRESSION AND INSTEAD, MAY POTENTIALLY EXERT A POST-TRANSCRIPTIONAL EFFECT THROUGH THE DIFFERENTIAL PRODUCTION OF LNCRNAS. 2016 13 3319 21 HISTONE ACETYLATION AND HISTONE DEACETYLATION IN NEUROPATHIC PAIN: AN UNRESOLVED PUZZLE? CHRONIC PAIN IS BROADLY CLASSIFIED INTO SOMATIC, VISCERAL OR NEUROPATHIC PAIN DEPENDING UPON THE LOCATION AND EXTENT OF PAIN PERCEPTION. EVIDENCES FROM DIFFERENT ANIMAL STUDIES SUGGEST THAT INFLAMMATORY OR NEUROPATHIC PAIN IS ASSOCIATED WITH ALTERED ACETYLATION AND DEACETYLATION OF HISTONE PROTEINS, WHICH RESULT IN ABNORMAL TRANSCRIPTION OF NOCICEPTIVE PROCESSING GENES. THERE HAVE BEEN A NUMBER OF STUDIES INDICATING THAT NERVE INJURY UP-REGULATES HISTONE DEACETYLASE ENZYMES, WHICH LEADS TO INCREASED HISTONE DEACETYLATION AND INDUCE CHRONIC PAIN. TREATMENT WITH HISTONE DEACETYLASE INHIBITORS RELIEVES PAIN BY NORMALIZING NERVE INJURY-INDUCED DOWN REGULATION OF METABOTROPIC GLUTAMATE RECEPTORS, GLUTAMATE TRANSPORTERS, GLUTAMIC ACID DECARBOXYLASE 65, NEURON RESTRICTIVE SILENCER FACTOR AND SERUM AND GLUCOCORTICOID INDUCIBLE KINASE 1. ON THE OTHER HAND, A FEW STUDIES REFER TO INCREASED EXPRESSION OF HISTONE ACETYLASE ENZYMES IN RESPONSE TO NERVE INJURY THAT PROMOTES HISTONE ACETYLATION LEADING TO PAIN INDUCTION. TREATMENT WITH HISTONE ACETYL TRANSFERASE INHIBITORS HAVE BEEN REPORTED TO RELIEVE CHRONIC PAIN BY BLOCKING THE UP-REGULATION OF CHEMOKINES AND CYCLOOXYGENASE-2, THE CRITICAL FACTORS ASSOCIATED WITH HISTONE ACETYLATION-INDUCED PAIN. THE PRESENT REVIEW DESCRIBES THE DUAL ROLE OF HISTONE ACETYLATION/DEACETYLATION IN DEVELOPMENT OR ATTENUATION OF NEUROPATHIC PAIN ALONG WITH THE UNDERLYING MECHANISMS. 2017 14 2590 29 EPIGENETICS OF PROTEASOME INHIBITION IN THE LIVER OF RATS FED ETHANOL CHRONICALLY. AIM: TO EXAMINE THE EFFECTS OF ETHANOL-INDUCED PROTEASOME INHIBITION, AND THE EFFECTS OF PROTEASOME INHIBITION IN THE REGULATION OF EPIGENETIC MECHANISMS. METHODS: RATS WERE FED ETHANOL FOR 1 MO USING THE TSUKAMOTO-FRENCH MODEL AND WERE COMPARED TO RATS GIVEN THE PROTEASOME INHIBITOR PS-341 (BORTEZOMIB, VELCADE(TM)) BY INTRAPERITONEAL INJECTION. MICROARRAY ANALYSIS AND REAL TIME PCR WERE PERFORMED AND PROTEASOME ACTIVITY ASSAYS AND WESTERN BLOT ANALYSIS WERE PERFORMED USING ISOLATED NUCLEI. RESULTS: CHRONIC ETHANOL FEEDING CAUSED A SIGNIFICANT INHIBITION OF THE UBIQUITIN PROTEASOME PATHWAY IN THE NUCLEUS, WHICH LED TO CHANGES IN THE TURNOVER OF TRANSCRIPTIONAL FACTORS, HISTONE-MODIFYING ENZYMES, AND, THEREFORE, AFFECTED EPIGENETIC MECHANISMS. CHRONIC ETHANOL FEEDING WAS RELATED TO AN INCREASE IN HISTONE ACETYLATION, AND IT IS HYPOTHESIZED THAT THE PROTEASOME PROTEOLYTIC ACTIVITY REGULATED HISTONE MODIFICATIONS BY CONTROLLING THE STABILITY OF HISTONE MODIFYING ENZYMES, AND, THEREFORE, REGULATED THE CHROMATIN STRUCTURE, ALLOWING EASY ACCESS TO CHROMATIN BY RNA POLYMERASE, AND, THUS, PROPER GENE EXPRESSION. PROTEASOME INHIBITION BY PS-341 INCREASED HISTONE ACETYLATION SIMILAR TO CHRONIC ETHANOL FEEDING. IN ADDITION, PROTEASOME INHIBITION CAUSED DRAMATIC CHANGES IN HEPATIC REMETHYLATION REACTIONS AS THERE WAS A SIGNIFICANT DECREASE IN THE ENZYMES RESPONSIBLE FOR THE REGENERATION OF S-ADENOSYLMETHIONINE, AND, IN PARTICULAR, A SIGNIFICANT DECREASE IN THE BETAINE-HOMOCYSTEINE METHYLTRANSFERASE ENZYME. THIS SUGGESTED THAT HYPOMETHYLATION WAS ASSOCIATED WITH PROTEASOME INHIBITION, AS INDICATED BY THE DECREASE IN HISTONE METHYLATION. CONCLUSION: THE ROLE OF PROTEASOME INHIBITION IN REGULATING EPIGENETIC MECHANISMS, AND ITS LINK TO LIVER INJURY IN ALCOHOLIC LIVER DISEASE, IS THUS A PROMISING APPROACH TO STUDY LIVER INJURY DUE TO CHRONIC ETHANOL CONSUMPTION. 2009 15 5710 26 SIRT1 DEFICIENCY IN MICROGLIA CONTRIBUTES TO COGNITIVE DECLINE IN AGING AND NEURODEGENERATION VIA EPIGENETIC REGULATION OF IL-1BETA. AGING IS THE PREDOMINANT RISK FACTOR FOR NEURODEGENERATIVE DISEASES. ONE KEY PHENOTYPE AS THE BRAIN AGES IS AN ABERRANT INNATE IMMUNE RESPONSE CHARACTERIZED BY PROINFLAMMATION. HOWEVER, THE MOLECULAR MECHANISMS UNDERLYING AGING-ASSOCIATED PROINFLAMMATION ARE POORLY DEFINED. WHETHER CHRONIC INFLAMMATION PLAYS A CAUSAL ROLE IN COGNITIVE DECLINE IN AGING AND NEURODEGENERATION HAS NOT BEEN ESTABLISHED. HERE WE REPORT A MECHANISTIC LINK BETWEEN CHRONIC INFLAMMATION AND AGING MICROGLIA AND A CAUSAL ROLE OF AGING MICROGLIA IN NEURODEGENERATIVE COGNITIVE DEFICITS. WE SHOWED THAT SIRT1 IS REDUCED WITH THE AGING OF MICROGLIA AND THAT MICROGLIAL SIRT1 DEFICIENCY HAS A CAUSATIVE ROLE IN AGING- OR TAU-MEDIATED MEMORY DEFICITS VIA IL-1BETA UPREGULATION IN MICE. INTERESTINGLY, THE SELECTIVE ACTIVATION OF IL-1BETA TRANSCRIPTION BY SIRT1 DEFICIENCY IS LIKELY MEDIATED THROUGH HYPOMETHYLATING THE SPECIFIC CPG SITES ON IL-1BETA PROXIMAL PROMOTER. IN HUMANS, HYPOMETHYLATION OF IL-1BETA IS STRONGLY ASSOCIATED WITH CHRONOLOGICAL AGE AND WITH ELEVATED IL-1BETA TRANSCRIPTION. OUR FINDINGS REVEAL A NOVEL EPIGENETIC MECHANISM IN AGING MICROGLIA THAT CONTRIBUTES TO COGNITIVE DEFICITS IN AGING AND NEURODEGENERATIVE DISEASES. 2015 16 3137 34 GLOBAL DNA METHYLATION PROFILING OF MANGANESE-EXPOSED HUMAN NEUROBLASTOMA SH-SY5Y CELLS REVEALS EPIGENETIC ALTERATIONS IN PARKINSON'S DISEASE-ASSOCIATED GENES. MANGANESE (MN) IS AN ESSENTIAL TRACE ELEMENT REQUIRED FOR OPTIMAL FUNCTIONING OF CELLULAR BIOCHEMICAL PATHWAYS IN THE CENTRAL NERVOUS SYSTEM. ELEVATED EXPOSURE TO MN THROUGH ENVIRONMENTAL AND OCCUPATIONAL EXPOSURE CAN CAUSE NEUROTOXIC EFFECTS RESULTING IN MANGANISM, A CONDITION WITH CLINICAL SYMPTOMS IDENTICAL TO IDIOPATHIC PARKINSON'S DISEASE. EPIGENETICS IS NOW RECOGNIZED AS A BIOLOGICAL MECHANISM INVOLVED IN THE ETIOLOGY OF VARIOUS DISEASES. HERE, WE INVESTIGATED THE ROLE OF DNA METHYLATION ALTERATIONS INDUCED BY CHRONIC MN (100 MICROM) EXPOSURE IN HUMAN NEUROBLASTOMA (SH-SY5Y) CELLS IN RELEVANCE TO PARKINSON'S DISEASE. A COMBINED ANALYSIS OF DNA METHYLATION AND GENE EXPRESSION DATA FOR PARKINSON'S DISEASE-ASSOCIATED GENES WAS CARRIED OUT. WHOLE-GENOME BISULFITE CONVERSION AND SEQUENCING INDICATE EPIGENETIC PERTURBATION OF KEY GENES INVOLVED IN BIOLOGICAL PROCESSES ASSOCIATED WITH NEURONAL CELL HEALTH. INTEGRATION OF DNA METHYLATION DATA WITH GENE EXPRESSION REVEALS EPIGENETIC ALTERATIONS TO PINK1, PARK2 AND TH GENES THAT PLAY CRITICAL ROLES IN THE ONSET OF PARKINSONISM. THE PRESENT STUDY SUGGESTS THAT MN-INDUCED ALTERATION OF DNA METHYLATION OF PINK1-PARK2 MAY INFLUENCE MITOCHONDRIAL FUNCTION AND PROMOTE PARKINSONISM. OUR FINDINGS PROVIDE A BASIS TO FURTHER EXPLORE AND VALIDATE THE EPIGENETIC BASIS OF MN-INDUCED NEUROTOXICITY . 2017 17 2002 25 EPIGENETIC AND POST-TRANSCRIPTIONAL REPRESSION SUPPORT METABOLIC SUPPRESSION IN CHRONICALLY HYPOXIC GOLDFISH. GOLDFISH ENTER A HYPOMETABOLIC STATE TO SURVIVE CHRONIC HYPOXIA. WE RECENTLY DESCRIBED TISSUE-SPECIFIC CONTRIBUTIONS OF MEMBRANE LIPID COMPOSITION REMODELING AND MITOCHONDRIAL FUNCTION TO METABOLIC SUPPRESSION ACROSS DIFFERENT GOLDFISH TISSUES. HOWEVER, THE MOLECULAR AND ESPECIALLY EPIGENETIC FOUNDATIONS OF HYPOXIA TOLERANCE IN GOLDFISH UNDER METABOLIC SUPPRESSION ARE NOT WELL UNDERSTOOD. HERE WE SHOW THAT COMPONENTS OF THE MOLECULAR OXYGEN-SENSING MACHINERY ARE ROBUSTLY ACTIVATED ACROSS TISSUES IRRESPECTIVE OF HYPOXIA DURATION. INDUCTION OF GENE EXPRESSION OF ENZYMES INVOLVED IN DNA METHYLATION TURNOVER AND MICRORNA BIOGENESIS SUGGEST A ROLE FOR EPIGENETIC TRANSCRIPTIONAL AND POST-TRANSCRIPTIONAL SUPPRESSION OF GENE EXPRESSION IN THE HYPOXIA-ACCLIMATED BRAIN. CONVERSELY, MECHANISTIC TARGET OF RAPAMYCIN-DEPENDENT TRANSLATIONAL MACHINERY ACTIVITY IS NOT REDUCED IN LIVER AND WHITE MUSCLE, SUGGESTING THIS PATHWAY DOES NOT CONTRIBUTE TO LOWERING CELLULAR ENERGY EXPENDITURE. FINALLY, MOLECULAR EVIDENCE SUPPORTS PREVIOUSLY REPORTED CHRONIC HYPOXIA-DEPENDENT CHANGES IN MEMBRANE CHOLESTEROL, LIPID METABOLISM AND MITOCHONDRIAL FUNCTION VIA CHANGES IN TRANSCRIPTS INVOLVED IN CHOLESTEROL BIOSYNTHESIS, BETA-OXIDATION, AND MITOCHONDRIAL FUSION IN MULTIPLE TISSUES. OVERALL, THIS STUDY SHOWS THAT CHRONIC HYPOXIA ROBUSTLY INDUCES EXPRESSION OF OXYGEN-SENSING MACHINERY ACROSS TISSUES, INDUCES REPRESSIVE TRANSCRIPTIONAL AND POST-TRANSCRIPTIONAL EPIGENETIC MARKS ESPECIALLY IN THE CHRONIC HYPOXIA-ACCLIMATED BRAIN AND SUPPORTS A ROLE FOR MEMBRANE REMODELING AND MITOCHONDRIAL FUNCTION AND DYNAMICS IN PROMOTING METABOLIC SUPPRESSION. 2022 18 6517 28 TRANSCRIPTIONAL AND EPIGENETIC MECHANISMS OF ADDICTION. INVESTIGATIONS OF LONG-TERM CHANGES IN BRAIN STRUCTURE AND FUNCTION THAT ACCOMPANY CHRONIC EXPOSURE TO DRUGS OF ABUSE SUGGEST THAT ALTERATIONS IN GENE REGULATION CONTRIBUTE SUBSTANTIALLY TO THE ADDICTIVE PHENOTYPE. HERE, WE REVIEW MULTIPLE MECHANISMS BY WHICH DRUGS ALTER THE TRANSCRIPTIONAL POTENTIAL OF GENES. THESE MECHANISMS RANGE FROM THE MOBILIZATION OR REPRESSION OF THE TRANSCRIPTIONAL MACHINERY - INCLUDING THE TRANSCRIPTION FACTORS DELTAFOSB, CYCLIC AMP-RESPONSIVE ELEMENT BINDING PROTEIN (CREB) AND NUCLEAR FACTOR-KAPPAB (NF-KAPPAB) - TO EPIGENETICS - INCLUDING ALTERATIONS IN THE ACCESSIBILITY OF GENES WITHIN THEIR NATIVE CHROMATIN STRUCTURE INDUCED BY HISTONE TAIL MODIFICATIONS AND DNA METHYLATION, AND THE REGULATION OF GENE EXPRESSION BY NON-CODING RNAS. INCREASING EVIDENCE IMPLICATES THESE VARIOUS MECHANISMS OF GENE REGULATION IN THE LASTING CHANGES THAT DRUGS OF ABUSE INDUCE IN THE BRAIN, AND OFFERS NOVEL INROADS FOR ADDICTION THERAPY. 2011 19 4969 29 PATHOLOGICAL NEUROINFLAMMATORY CONVERSION OF REACTIVE ASTROCYTES IS INDUCED BY MICROGLIA AND INVOLVES CHROMATIN REMODELING. FOLLOWING BRAIN INJURY OR IN NEURODEGENERATIVE DISEASES, ASTROCYTES BECOME REACTIVE AND MAY SUFFER PATHOLOGICAL REMODELING, FEATURES OF WHICH ARE THE LOSS OF THEIR HOMEOSTATIC FUNCTIONS AND A PRO-INFLAMMATORY GAIN OF FUNCTION THAT FACILITATES NEURODEGENERATION. PHARMACOLOGICAL INTERVENTION TO MODULATE THIS ASTROGLIAL RESPONSE AND NEUROINFLAMMATION IS AN INTERESTING NEW THERAPEUTIC RESEARCH STRATEGY, BUT IT STILL REQUIRES A DEEPER UNDERSTANDING OF THE UNDERLYING CELLULAR AND MOLECULAR MECHANISMS OF THE PHENOMENON. BASED ON THE KNOWN MICROGLIAL-ASTROGLIAL INTERACTION, THE PROMINENT ROLE OF THE NUCLEAR FACTOR KAPPA B (NF-KAPPAB) PATHWAY IN MEDIATING ASTROGLIAL PATHOLOGICAL PRO-INFLAMMATORY GAIN OF FUNCTION, AND ITS ABILITY TO RECRUIT CHROMATIN-REMODELING ENZYMES, WE FIRST EXPLORED THE MICROGLIAL ROLE IN THE INITIATION OF ASTROGLIAL PRO-INFLAMMATORY CONVERSION AND THEN MONITORED THE PROGRESSION OF EPIGENETIC CHANGES IN THE ASTROCYTIC CHROMATIN. DIFFERENT CONFIGURATIONS OF PRIMARY GLIAL CULTURE WERE USED TO MODULATE MICROGLIA-ASTROCYTE CROSSTALK WHILE INDUCING PRO-INFLAMMATORY GAIN OF FUNCTION BY LIPOPOLYSACCHARIDE (LPS) EXPOSURE. IN VIVO, BRAIN ISCHEMIA BY CORTICAL DEVASCULARIZATION (PIAL DISRUPTION) WAS PERFORMED TO VERIFY THE PRESENCE OF EPIGENETIC MARKS IN REACTIVE ASTROCYTES. OUR RESULTS SHOWED THAT 1) MICROGLIA IS REQUIRED TO INITIATE THE PATHOLOGICAL CONVERSION OF ASTROCYTES BY TRIGGERING THE NF-KAPPAB SIGNALING PATHWAY; 2) THIS INTERACTION IS MEDIATED BY SOLUBLE FACTORS AND INDUCES STABLE ASTROGLIAL PHENOTYPIC CHANGES; 3) THE PATHOLOGICAL CONVERSION PROMOTES CHROMATIN REMODELING WITH STABLE INCREASE IN H3K9K14AC, TEMPORARY INCREASE IN H3K27AC, AND TEMPORARY REDUCTION IN HETEROCHROMATIN MARK H3K9ME3; AND 4) IN VIVO REACTIVE ASTROCYTES SHOW INCREASED H3K27AC MARK IN THE NEUROINFLAMMATORY MILIEU FROM THE ISCHEMIC PENUMBRA. OUR FINDINGS INDICATE THAT ASTROGLIAL PATHOLOGICAL PRO-INFLAMMATORY GAIN OF FUNCTION IS ASSOCIATED WITH PROFOUND CHANGES IN THE CONFIGURATION OF ASTROCYTIC CHROMATIN, WHICH IN TURN ARE INITIATED BY MICROGLIA-DERIVED CUES. THESE RESULTS OPEN A NEW AVENUE IN THE STUDY OF POTENTIAL PHARMACOLOGICAL INTERVENTIONS THAT MODIFY THE INITIATION AND STABILIZATION OF ASTROGLIAL PATHOLOGICAL REMODELING, WHICH WOULD BE USEFUL IN ACUTE AND CHRONIC CNS INJURY. EPIGENETIC CHANGES REPRESENT A PLAUSIBLE PHARMACOLOGICAL TARGET TO INTERFERE WITH THE STABILIZATION OF THE PATHOLOGICAL ASTROGLIAL PHENOTYPE. 2021 20 5624 19 SELECTIVE BOOSTING OF TRANSCRIPTIONAL AND BEHAVIORAL RESPONSES TO DRUGS OF ABUSE BY HISTONE DEACETYLASE INHIBITION. HISTONE ACETYLATION AND OTHER MODIFICATIONS OF THE CHROMATIN ARE IMPORTANT REGULATORS OF GENE EXPRESSION AND, CONSEQUENTLY, MAY CONTRIBUTE TO DRUG-INDUCED BEHAVIORS AND NEUROPLASTICITY. EARLIER STUDIES HAVE SHOWN THAT A REDUCTION IN HISTONE DEACETYLASE (HDAC) ACTIVITY RESULTS IN THE ENHANCEMENT OF SOME PSYCHOSTIMULANT-INDUCED BEHAVIORS. IN THIS STUDY, WE EXTEND THOSE SEMINAL FINDINGS BY SHOWING THAT THE ADMINISTRATION OF THE HDAC INHIBITOR SODIUM BUTYRATE ENHANCES MORPHINE-INDUCED LOCOMOTOR SENSITIZATION AND CONDITIONED PLACE PREFERENCE. IN CONTRAST, THIS COMPOUND HAS NO EFFECTS ON THE DEVELOPMENT OF MORPHINE TOLERANCE AND DEPENDENCE. SIMILAR EFFECTS WERE OBSERVED FOR COCAINE AND ETHANOL-INDUCED BEHAVIORS. THESE BEHAVIORAL CHANGES WERE ACCOMPANIED BY A SELECTIVE BOOSTING OF A COMPONENT OF THE TRANSCRIPTIONAL PROGRAM ACTIVATED BY CHRONIC MORPHINE ADMINISTRATION THAT INCLUDED CIRCADIAN CLOCK GENES AND OTHER GENES RELEVANT TO ADDICTIVE BEHAVIOR. OUR RESULTS SUPPORT A SPECIFIC FUNCTION FOR HISTONE ACETYLATION AND THE EPIGENETIC MODULATION OF TRANSCRIPTION AT A REDUCED NUMBER OF BIOLOGICALLY RELEVANT LOCI ON NON-HOMEOSTATIC, LONG-LASTING, DRUG-INDUCED BEHAVIORAL PLASTICITY. 2009