1 5823 97 STRESS INCREASES DNA METHYLATION OF THE NEURONAL PAS DOMAIN 4 (NPAS4) GENE. NEURONAL PER ARNT SIM DOMAIN 4 (NPAS4), A BRAIN-SPECIFIC HELIX-LOOP-HELIX TRANSCRIPTION FACTOR, WAS RECENTLY SHOWN TO REGULATE THE DEVELOPMENT OF GABAERGIC INHIBITORY NEURONS. NPAS4 MRNA EXPRESSION LEVELS WERE DECREASED IN THE HIPPOCAMPUS OF MICE EXPOSED TO STRESS, WHICH WAS ACCOMPANIED BY BRAIN DYSFUNCTION. WE HAVE SUGGESTED THAT TRANSIENT STRESS REDUCED NPAS4 TRANSCRIPTION THROUGH THE GLUCOCORTICOID RECEPTOR. IN THE PRESENT REPORT, WE INVESTIGATED THE POTENTIAL CONTRIBUTION OF EPIGENETIC MODIFICATIONS INDUCED BY STRESS ON NPAS4 GENE EXPRESSION. THE NPAS4 PROMOTER REGION CONTAINS TWO CPG ISLANDS; IN THE HIPPOCAMPUS, CHRONIC RESTRAINT STRESS INCREASES THE DNA METHYLATION LEVELS OF BOTH OF THESE CPG ISLANDS. IN THE NEURO2A CELL LINE, TREATMENT WITH A DNA METHYLTRANSFERASE INHIBITOR, 5-AZA-2'-DEOXYCYTIDINE, INCREASED NPAS4 MRNA LEVELS AND MARKEDLY REDUCED THE DNA METHYLATION LEVELS OF CPG ISLAND 2 IN THE NPAS4 PROMOTER. THE DNA METHYLATION SITES IN CPG ISLAND 2 OVERLAP WITH TWO CYCLIC ADENOSINE MONOPHOSPHATE RESPONSE ELEMENT (CRE) SEQUENCES. MUTATION OF THESE CRE SEQUENCES REDUCED NPAS4 PROMOTER ACTIVITY. THESE RESULTS SUGGEST THAT TRANSCRIPTION OF THE NPAS4 GENE IS DOWNREGULATED BY STRESS THROUGH DNA METHYLATION OF ITS PROMOTER. 2015 2 4236 30 METHYLATION OF THE TYROSINE HYDROXYLASE GENE IS DYSREGULATED BY COCAINE DEPENDENCE IN THE HUMAN STRIATUM. COCAINE DEPENDENCE IS A CHRONIC, RELAPSING DISORDER CAUSED BY LASTING CHANGES IN THE BRAIN. ANIMAL STUDIES HAVE IDENTIFIED COCAINE-RELATED ALTERATIONS IN STRIATAL DNA METHYLATION; HOWEVER, IT IS UNCLEAR HOW METHYLATION IS RELATED TO COCAINE DEPENDENCE IN HUMANS. WE GENERATED METHYLOMIC PROFILES OF THE NUCLEUS ACCUMBENS USING HUMAN POSTMORTEM BRAINS FROM A COHORT OF INDIVIDUALS WITH COCAINE DEPENDENCE AND HEALTHY CONTROLS (N = 25 PER GROUP). WE FOUND HYPERMETHYLATION IN A CLUSTER OF CPGS WITHIN THE GENE BODY OF TYROSINE HYDROXYLASE (TH), CONTAINING A PUTATIVE BINDING SITE FOR THE EARLY GROWTH RESPONSE 1 (EGR1) TRANSCRIPTION FACTOR, WHICH IS HYPERMETHYLATED IN THE CAUDATE NUCLEUS OF COCAINE-DEPENDENT INDIVIDUALS. WE REPLICATED THIS FINDING AND FOUND IT TO BE SPECIFIC TO STRIATAL NEURONAL NUCLEI. FURTHERMORE, THIS LOCUS DEMONSTRATES ENHANCER ACTIVITY WHICH IS ATTENUATED BY METHYLATION AND ENHANCED BY EGR1 OVEREXPRESSION. THESE RESULTS SUGGEST THAT COCAINE DEPENDENCE ALTERS THE EPIGENETIC REGULATION OF DOPAMINERGIC SIGNALING GENES. 2021 3 1620 36 DNA METHYLTRANSFERASE-MEDIATED TRANSCRIPTIONAL SILENCING IN MALIGNANT GLIOMA: A COMBINED WHOLE-GENOME MICROARRAY AND PROMOTER ARRAY ANALYSIS. EPIGENETIC INACTIVATION OF TUMOR SUPPRESSOR GENES IS A COMMON FEATURE IN HUMAN CANCER. PROMOTER HYPERMETHYLATION AND HISTONE DEACETYLATION ARE REVERSIBLE EPIGENETIC MECHANISMS ASSOCIATED WITH TRANSCRIPTIONAL REGULATION. DNA METHYLTRANSFERASES (DNMT1 AND DNMT3B) REGULATE AND MAINTAIN PROMOTER METHYLATION AND ARE OVEREXPRESSED IN HUMAN CANCER. WE PERFORMED WHOLE-GENOME MICROARRAY ANALYSIS TO IDENTIFY GENES WITH ALTERED EXPRESSION AFTER RNAI-INDUCED SUPPRESSION OF DNMT IN A GLIOBLASTOMA MULTIFORME (GBM) CELL LINE. WE THEN IDENTIFIED GENES WITH BOTH DECREASED EXPRESSION AND EVIDENCE OF PROMOTER CPG ISLAND HYPERMETHYLATION IN GBM TISSUE SAMPLES USING A COMBINED WHOLE-GENOME MICROARRAY TRANSCRIPTOME ANALYSIS IN CONJUNCTION WITH A PROMOTER ARRAY ANALYSIS AFTER DNA IMMUNOPRECIPITATION WITH ANTI-5-METHYLCYTIDINE. DNMT1 AND 3B KNOCKDOWN RESULTED IN THE RESTORED EXPRESSION OF 308 GENES THAT ALSO CONTAINED PROMOTER REGION HYPERMETHYLATION. OF THESE, 43 WERE ALSO FOUND TO BE DOWNREGULATED IN GBM TISSUE SAMPLES. THREE DOWNREGULATED GENES WITH HYPERMETHYLATED PROMOTERS AND RESTORED EXPRESSION IN RESPONSE TO ACUTE DNMT SUPPRESSION WERE ASSAYED FOR METHYLATION CHANGES USING BISULFITE SEQUENCE ANALYSIS OF THE PROMOTER REGION AFTER CHRONIC DNMT SUPPRESSION. RESTORATION OF GENE EXPRESSION WAS NOT ASSOCIATED WITH CHANGES IN PROMOTER REGION METHYLATION, BUT RATHER WITH CHANGES IN HISTONE METHYLATION AND CHROMATIN CONFORMATION. TWO OF THE IDENTIFIED GENES EXHIBITED GROWTH SUPPRESSIVE ACTIVITY IN IN VITRO ASSAYS. COMBINING TARGETED GENETIC MANIPULATIONS WITH COMPREHENSIVE GENOMIC AND EXPRESSION ANALYSES PROVIDES A POTENTIALLY POWERFUL NEW APPROACH FOR IDENTIFYING EPIGENETICALLY REGULATED GENES IN GBM. 2009 4 3176 38 H3.3 BARCODING OF NUCLEUS ACCUMBENS TRANSCRIPTIONAL ACTIVITY IDENTIFIES NOVEL MOLECULAR CASCADES ASSOCIATED WITH COCAINE SELF-ADMINISTRATION IN MICE. ALTHOUGH NUMEROUS EPIGENETIC MODIFICATIONS HAVE BEEN ASSOCIATED WITH ADDICTION, LITTLE WORK HAS EXPLORED THE TURNOVER OF HISTONE VARIANTS. UNIQUELY, THE H3.3 VARIANT INCORPORATES STABLY AND PREFERENTIALLY INTO CHROMATIN INDEPENDENTLY OF DNA REPLICATION AT ACTIVE SITES OF TRANSCRIPTION AND TRANSCRIPTION FACTOR BINDING. THUS, GENOMIC REGIONS ASSOCIATED WITH H3.3-CONTAINING NUCLEOSOMES ARE PARTICULARLY LIKELY TO BE INVOLVED IN PLASTICITY, SUCH AS FOLLOWING REPEATED COCAINE EXPOSURE. A RECENTLY DEVELOPED MOUSE LINE EXPRESSING A NEURON-SPECIFIC HEMAGGLUTININ (HA)-TAGGED H3.3 PROTEIN WAS USED TO TRACK TRANSCRIPTIONALLY ACTIVE SITES CUMULATIVELY ACROSS 19 D OF COCAINE SELF-ADMINISTRATION. RNA-SEQ AND H3.3-HA CHIP-SEQ ANALYSES WERE PERFORMED ON NACC TISSUE COLLECTED FOLLOWING COCAINE OR FOOD SELF-ADMINISTRATION IN MALE MICE. RNA SEQUENCING REVEALED FIVE GENES UPREGULATED IN COCAINE RELATIVE TO FOOD SELF-ADMINISTERING MICE: FOSB, NPAS4, VGF, NPTX2, AND PMEPA1, WHICH REFLECT KNOWN AND NOVEL COCAINE PLASTICITY-ASSOCIATED GENES. SUBSEQUENT CHIP-SEQ ANALYSIS CONFIRMED INCREASED H3.3 AGGREGATION AT FOUR OF THESE FIVE LOCI, THUS VALIDATING H3.3 INSERTION AS A MARKER OF ENHANCED COCAINE-INDUCED TRANSCRIPTION. FURTHER MOTIF RECOGNITION ANALYSIS OF THE CHIP-SEQ DATA SHOWED THAT COCAINE-ASSOCIATED DIFFERENTIAL H3.3 ACCUMULATION CORRELATED WITH THE PRESENCE OF SEVERAL TRANSCRIPTION FACTOR BINDING MOTIFS, INCLUDING RBPJ1, EGR1, AND SOX4, SUGGESTING THAT THESE ARE POTENTIALLY IMPORTANT REGULATORS OF MOLECULAR CASCADES ASSOCIATED WITH COCAINE-INDUCED NEURONAL PLASTICITY. ADDITIONAL ONTOLOGICAL ANALYSIS REVEALED DIFFERENTIAL H3.3 ACCUMULATION MAINLY NEAR GENES INVOLVED IN NEURONAL DIFFERENTIATION AND DENDRITE FORMATION. THESE RESULTS ESTABLISH THE H3.3-HA TRANSGENIC MOUSE LINE AS A COMPELLING MOLECULAR BARCODING TOOL TO IDENTIFY THE CUMULATIVE EFFECTS OF LONG-TERM ENVIRONMENTAL PERTURBATIONS, SUCH AS EXPOSURE TO DRUGS OF ABUSE.SIGNIFICANCE STATEMENT HISTONE H3.3 IS A CORE HISTONE VARIANT THAT IS STABLY INCORPORATED AT ACTIVE SITES OF TRANSCRIPTION. WE USED A TAGGED VERSION OF H3.3 EXPRESSED EXCLUSIVELY IN NEURONS TO DELINEATE ACTIVE TRANSCRIPTION SITES FOLLOWING EXTENDED COCAINE SELF-ADMINISTRATION IN MICE. THIS APPROACH REVEALED THE CUMULATIVE LIST OF GENES EXPRESSED IN RESPONSE TO COCAINE TAKING OVER THE COURSE OF SEVERAL WEEKS. WE COMBINED THIS TECHNIQUE WITH RNA SEQUENCING OF TISSUE COLLECTED FROM THE SAME ANIMALS 24 H AFTER THE LAST COCAINE EXPOSURE. COMPARING THESE DATASETS PROVIDED A FULL PICTURE OF GENES THAT RESPOND TO CHRONIC COCAINE EXPOSURE IN NACC NEURONS. THESE STUDIES REVEALED NOVEL TRANSCRIPTION FACTORS THAT ARE LIKELY INVOLVED IN COCAINE-INDUCED PLASTICITY AND ADDICTION-LIKE BEHAVIORS. 2019 5 4497 35 MORPHINE LEADS TO GLOBAL GENOME CHANGES IN H3K27ME3 LEVELS VIA A POLYCOMB REPRESSIVE COMPLEX 2 (PRC2) SELF-REGULATORY MECHANISM IN MESCS. BACKGROUND: ENVIRONMENTALLY INDUCED EPIGENETIC CHANGES CAN LEAD TO HEALTH PROBLEMS OR DISEASE, BUT THE MECHANISMS INVOLVED REMAIN UNCLEAR. MORPHINE CAN PASS THROUGH THE PLACENTAL BARRIER LEADING TO ABNORMAL EMBRYO DEVELOPMENT. HOWEVER, THE MECHANISM BY WHICH MORPHINE CAUSES THESE EFFECTS AND HOW THEY SOMETIMES PERSIST INTO ADULTHOOD IS NOT WELL KNOWN. TO UNRAVEL THE MORPHINE-INDUCED CHROMATIN ALTERATIONS INVOLVED IN ABERRANT EMBRYO DEVELOPMENT, WE EXPLORED THE ROLE OF THE H3K27ME3/PRC2 REPRESSIVE COMPLEX IN GENE EXPRESSION AND ITS TRANSMISSION ACROSS CELLULAR GENERATIONS IN RESPONSE TO MORPHINE. RESULTS: USING MOUSE EMBRYONIC STEM CELLS AS A MODEL SYSTEM, WE FOUND THAT CHRONIC MORPHINE TREATMENT INDUCES A GLOBAL DOWNREGULATION OF THE HISTONE MODIFICATION H3K27ME3. CONVERSELY, CHIP-SEQ SHOWED A REMARKABLE INCREASE IN H3K27ME3 LEVELS AT SPECIFIC GENOMIC SITES, PARTICULARLY PROMOTERS, DISRUPTING SELECTIVE TARGET GENES RELATED TO EMBRYO DEVELOPMENT, CELL CYCLE AND METABOLISM. THROUGH A SELF-REGULATORY MECHANISM, MORPHINE DOWNREGULATED THE TRANSCRIPTION OF PRC2 COMPONENTS RESPONSIBLE FOR H3K27ME3 BY ENRICHING HIGH H3K27ME3 LEVELS AT THE PROMOTER REGION. DOWNREGULATION OF PRC2 COMPONENTS PERSISTED FOR AT LEAST 48 H (4 CELL CYCLES) FOLLOWING MORPHINE REMOVAL, THOUGH PROMOTER H3K27ME3 LEVELS RETURNED TO CONTROL LEVELS. CONCLUSIONS: MORPHINE INDUCES TARGETING OF THE PRC2 COMPLEX TO SELECTED PROMOTERS, INCLUDING THOSE OF PRC2 COMPONENTS, LEADING TO CHARACTERISTIC CHANGES IN GENE EXPRESSION AND A GLOBAL REDUCTION IN H3K27ME3. FOLLOWING MORPHINE REMOVAL, ENHANCED PROMOTER H3K27ME3 LEVELS REVERT TO NORMAL SOONER THAN GLOBAL H3K27ME3 OR PRC2 COMPONENT TRANSCRIPT LEVELS. WE SUGGEST THAT H3K27ME3 IS INVOLVED IN INITIATING MORPHINE-INDUCED CHANGES IN GENE EXPRESSION, BUT NOT IN THEIR MAINTENANCE. MODEL OF POLYCOMB REPRESSIVE COMPLEX 2 (PRC2) AND H3K27ME3 ALTERATIONS INDUCED BY CHRONIC MORPHINE EXPOSURE. MORPHINE INDUCES H3K27ME3 ENRICHMENT AT PROMOTERS OF GENES ENCODING CORE MEMBERS OF THE PRC2 COMPLEX AND IS ASSOCIATED WITH THEIR TRANSCRIPTIONAL DOWNREGULATION. 2020 6 5034 24 PHARMACOEPIGENETICS OF THE ROLE OF DNA METHYLATION IN MU-OPIOID RECEPTOR EXPRESSION IN DIFFERENT HUMAN BRAIN REGIONS. AIM: EXPOSURE TO OPIOIDS HAS BEEN ASSOCIATED WITH EPIGENETIC EFFECTS. STUDIES IN RODENTS SUGGESTED A ROLE OF VARYING DEGREES OF DNA METHYLATION IN THE DIFFERENTIAL REGULATION OF MU-OPIOID RECEPTOR EXPRESSION ACROSS THE BRAIN. METHODS: IN A TRANSLATIONAL INVESTIGATION, USING TISSUE ACQUIRED POSTMORTEM FROM 21 BRAIN REGIONS OF FORMER OPIATE ADDICTS, REPRESENTING A HUMAN COHORT WITH CHRONIC OPIOID EXPOSURE, MU-OPIOID RECEPTOR EXPRESSION WAS ANALYZED AT THE LEVEL OF DNA METHYLATION, MRNA AND PROTEIN. RESULTS & CONCLUSION: WHILE HIGH OR LOW MU-OPIOID RECEPTOR EXPRESSION SIGNIFICANTLY CORRELATED WITH LOCAL OPRM1 MRNA LEVELS, THERE WAS NO CORRESPONDING ASSOCIATION WITH OPRM1 METHYLATION STATUS. ADDITIONAL EXPERIMENTS IN HUMAN CELL LINES SHOWED THAT CHANGES IN DNA METHYLATION ASSOCIATED WITH CHANGES IN MU-OPIOID EXPRESSION WERE AN ORDER OF MAGNITUDE GREATER THAN DIFFERENCES IN BRAIN. HENCE, DIFFERENT DEGREES OF DNA METHYLATION ASSOCIATED WITH CHRONIC OPIOID EXPOSURE ARE UNLIKELY TO EXERT A MAJOR ROLE IN THE REGION-SPECIFICITY OF MU-OPIOID RECEPTOR EXPRESSION IN THE HUMAN BRAIN. 2016 7 4173 30 MELATONIN INDUCES HISTONE HYPERACETYLATION IN THE RAT BRAIN. WE HAVE REPORTED THAT MELATONIN INDUCES HISTONE HYPERACETYLATION IN MOUSE NEURAL STEM CELLS, SUGGESTING AN EPIGENETIC ROLE FOR THIS PLEIOTROPIC HORMONE. TO SUPPORT SUCH A ROLE, IT IS NECESSARY TO DEMONSTRATE THAT MELATONIN PRODUCES SIMILAR EFFECTS IN VIVO. HISTONE ACETYLATION, FOLLOWING CHRONIC TREATMENT WITH MELATONIN (4MUG/ML IN DRINKING WATER FOR 17 DAYS), WAS EXAMINED BY WESTERN BLOTTING IN SELECTED RAT BRAIN REGIONS. MELATONIN INDUCED SIGNIFICANT INCREASES IN HISTONE H3 AND HISTONE H4 ACETYLATION IN THE HIPPOCAMPUS. HISTONE H4 WAS ALSO HYPERACETYLATED IN THE STRIATUM, BUT THERE WERE NO SIGNIFICANT CHANGES IN HISTONE H3 ACETYLATION IN THIS BRAIN REGION. NO SIGNIFICANT CHANGES IN THE ACETYLATION OF EITHER HISTONE H3 OR H4 WERE OBSERVED IN THE MIDBRAIN AND CEREBELLUM. AN EXAMINATION OF KINASE ACTIVATION, WHICH MAY BE RELATED TO THESE CHANGES, REVEALED THAT MELATONIN TREATMENT INCREASED THE LEVELS OF PHOSPHO-ERK (EXTRACELLULAR SIGNAL-REGULATED KINASE) IN THE HIPPOCAMPUS AND STRIATUM, BUT PHOSPHO-AKT (PROTEIN KINASE B) LEVELS WERE UNCHANGED. THESE FINDINGS SUGGEST THAT CHROMATIN REMODELING AND ASSOCIATED CHANGES IN THE EPIGENETIC REGULATION OF GENE EXPRESSION UNDERLIE THE MULTIPLE PHYSIOLOGICAL EFFECTS OF MELATONIN. 2013 8 531 33 ASTROCYTE REACTIVITY FOLLOWING BLAST EXPOSURE INVOLVES ABERRANT HISTONE ACETYLATION. BLAST INDUCED NEUROTRAUMA (BINT) IS A PREVALENT INJURY WITHIN MILITARY AND CIVILIAN POPULATIONS. THE INJURY IS CHARACTERIZED BY PERSISTENT INFLAMMATION AT THE CELLULAR LEVEL WHICH MANIFESTS AS A MULTITUDE OF COGNITIVE AND FUNCTIONAL IMPAIRMENTS. EPIGENETIC REGULATION OF TRANSCRIPTION OFFERS AN IMPORTANT CONTROL MECHANISM FOR GENE EXPRESSION AND CELLULAR FUNCTION WHICH MAY UNDERLIE CHRONIC INFLAMMATION AND RESULT IN NEURODEGENERATION. WE HYPOTHESIZE THAT ALTERED HISTONE ACETYLATION PATTERNS MAY BE INVOLVED IN BLAST INDUCED INFLAMMATION AND THE CHRONIC ACTIVATION OF GLIAL CELLS. THIS STUDY AIMED TO ELUCIDATE CHANGES TO HISTONE ACETYLATION OCCURRING FOLLOWING INJURY AND THE ROLES THESE CHANGES MAY HAVE WITHIN THE PATHOLOGY. SPRAGUE DAWLEY RATS WERE SUBJECTED TO EITHER A 10 OR 17 PSI BLAST OVERPRESSURE WITHIN AN ADVANCED BLAST SIMULATOR (ABS). SHAM ANIMALS UNDERWENT THE SAME PROCEDURES WITHOUT BLAST EXPOSURE. MEMORY IMPAIRMENTS WERE MEASURED USING THE NOVEL OBJECT RECOGNITION (NOR) TEST AT 2 AND 7 DAYS POST-INJURY. TISSUES WERE COLLECTED AT 7 DAYS FOR WESTERN BLOT AND IMMUNOHISTOCHEMISTRY (IHC) ANALYSIS. SHAM ANIMALS SHOWED INTACT MEMORY AT EACH TIME POINT. THE NOVEL OBJECT DISCRIMINATION DECREASED SIGNIFICANTLY BETWEEN TWO AND 7 DAYS FOR EACH INJURY GROUP (P < 0.05). THIS IS INDICATIVE OF THE ONSET OF MEMORY IMPAIRMENT. WESTERN BLOT ANALYSIS SHOWED GLIAL FIBRILLARY ACIDIC PROTEIN (GFAP), A KNOWN MARKER OF ACTIVATED ASTROCYTES, WAS ELEVATED IN THE PREFRONTAL CORTEX (PFC) FOLLOWING BLAST EXPOSURE FOR BOTH INJURY GROUPS. ANALYSIS OF HISTONE PROTEIN EXTRACT SHOWED NO CHANGES IN THE LEVEL OF ANY TOTAL HISTONE PROTEINS WITHIN THE PFC. HOWEVER, ACETYLATION LEVELS OF HISTONE H2B, H3, AND H4 WERE DECREASED IN BOTH GROUPS (P < 0.05). CO-LOCALIZATION IMMUNOFLUORESCENCE WAS USED TO FURTHER INVESTIGATE ANY POTENTIAL CORRELATION BETWEEN DECREASED HISTONE ACETYLATION AND ASTROCYTE ACTIVATION. THESE EXPERIMENTS SHOWED A SIMILAR DECREASE IN H3 ACETYLATION IN ASTROCYTES EXPOSED TO A 17 PSI BLAST BUT NOT A 10 PSI BLAST. FURTHER INVESTIGATION OF GENE EXPRESSION BY POLYMERASE CHAIN REACTION (PCR) ARRAY, SHOWED DYSREGULATION OF SEVERAL CYTOKINE AND CYTOKINE RECEPTORS THAT ARE INVOLVED IN NEUROINFLAMMATORY PROCESSES. WE HAVE SHOWN ABERRANT HISTONE ACETYLATION PATTERNS INVOLVED IN BLAST INDUCED ASTROGLIOSIS AND COGNITIVE IMPAIRMENTS. FURTHER UNDERSTANDING OF THEIR ROLE IN THE INJURY PROGRESSION MAY LEAD TO NOVEL THERAPEUTIC TARGETS. 2016 9 1656 29 DOUBLE STRAND BREAKS CAN INITIATE GENE SILENCING AND SIRT1-DEPENDENT ONSET OF DNA METHYLATION IN AN EXOGENOUS PROMOTER CPG ISLAND. CHRONIC EXPOSURE TO INDUCERS OF DNA BASE OXIDATION AND SINGLE AND DOUBLE STRAND BREAKS CONTRIBUTE TO TUMORIGENESIS. IN ADDITION TO THE GENETIC CHANGES CAUSED BY THIS DNA DAMAGE, SUCH TUMORS OFTEN CONTAIN EPIGENETICALLY SILENCED GENES WITH ABERRANT PROMOTER REGION CPG ISLAND DNA HYPERMETHYLATION. WE HEREIN EXPLORE THE RELATIONSHIPS BETWEEN SUCH DNA DAMAGE AND EPIGENETIC GENE SILENCING USING AN EXPERIMENTAL MODEL IN WHICH WE INDUCE A DEFINED DOUBLE STRAND BREAK IN AN EXOGENOUS PROMOTER CONSTRUCT OF THE E-CADHERIN CPG ISLAND, WHICH IS FREQUENTLY ABERRANTLY DNA HYPERMETHYLATED IN EPITHELIAL CANCERS. FOLLOWING THE ONSET OF REPAIR OF THE BREAK, WE OBSERVE RECRUITMENT TO THE SITE OF DAMAGE OF KEY PROTEINS INVOLVED IN ESTABLISHING AND MAINTAINING TRANSCRIPTIONAL REPRESSION, NAMELY SIRT1, EZH2, DNMT1, AND DNMT3B, AND THE APPEARANCE OF THE SILENCING HISTONE MODIFICATIONS, HYPOACETYL H4K16, H3K9ME2 AND ME3, AND H3K27ME3. ALTHOUGH IN MOST CELLS SELECTED AFTER THE BREAK, DNA REPAIR OCCURS FAITHFULLY WITH PRESERVATION OF ACTIVITY OF THE PROMOTER, A SMALL PERCENTAGE OF THE PLATED CELLS DEMONSTRATE INDUCTION OF HERITABLE SILENCING. THE CHROMATIN AROUND THE BREAK SITE IN SUCH A SILENT CLONE IS ENRICHED FOR MOST OF THE ABOVE SILENT CHROMATIN PROTEINS AND HISTONE MARKS, AND THE REGION HARBORS THE APPEARANCE OF INCREASING DNA METHYLATION IN THE CPG ISLAND OF THE PROMOTER. DURING THE ACUTE BREAK, SIRT1 APPEARS TO BE REQUIRED FOR THE TRANSIENT RECRUITMENT OF DNMT3B AND SUBSEQUENT METHYLATION OF THE PROMOTER IN THE SILENT CLONES. TAKEN TOGETHER, OUR DATA SUGGEST THAT NORMAL REPAIR OF A DNA BREAK CAN OCCASIONALLY CAUSE HERITABLE SILENCING OF A CPG ISLAND-CONTAINING PROMOTER BY RECRUITMENT OF PROTEINS INVOLVED IN SILENCING. FURTHERMORE, WITH CONTRIBUTION OF THE STRESS-RELATED PROTEIN SIRT1, THE BREAK CAN LEAD TO THE ONSET OF ABERRANT CPG ISLAND DNA METHYLATION, WHICH IS FREQUENTLY ASSOCIATED WITH TIGHT GENE SILENCING IN CANCER. 2008 10 1831 33 EFFECTS OF MATERNAL SEPARATION AND ANTIDEPRESSANT DRUG ON EPIGENETIC REGULATION OF THE BRAIN-DERIVED NEUROTROPHIC FACTOR EXON I PROMOTER IN THE ADULT RAT HIPPOCAMPUS. AIM: EARLY LIFE STRESS CAN INDUCE EPIGENETIC CHANGES THROUGH GENETIC AND ENVIRONMENTAL INTERACTIONS AND IS A RISK FACTOR FOR DEPRESSION. BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) HAS BEEN IMPLICATED IN THE PATHOPHYSIOLOGY OF DEPRESSION AND ANTIDEPRESSANT DRUG ACTION. WE INVESTIGATED EPIGENETIC CHANGES AT THE BDNF EXON I PROMOTER IN THE HIPPOCAMPUS OF ADULT RATS SUBJECTED TO MATERNAL SEPARATION (MS) DURING EARLY LIFE AND TREATED WITH AN ANTIDEPRESSANT DRUG AS ADULTS. METHODS: RAT PUPS WERE SUBJECTED TO MS FROM POSTNATAL DAY 1 TO 21 AND RECEIVED CHRONIC ESCITALOPRAM (ESC) AS ADULTS. WE ASSESSED THE EFFECTS OF MS AND ESC ON BDNF EXON I AND DNA METHYLTRANSFERASES (DNMT) MRNA LEVELS (QUANTITATIVE REVERSE-TRANSCRIPTION POLYMERASE CHAIN REACTION), ACETYLATED HISTONE H3, AND MECP2 BINDING TO THE BDNF PROMOTER I (CHROMATIN IMMUNOPRECIPITATION FOLLOWED BY REAL-TIME POLYMERASE CHAIN REACTION), AND BDNF PROTEIN LEVELS (ENZYME-LINKED IMMUNOSORBENT ASSAY). RESULTS: THE LEVELS OF BDNF PROTEIN, EXON I MRNA, HISTONE H3 ACETYLATION, AND DNMT1 AND DNMT3A MRNA WERE ALTERED IN THE MS GROUP COMPARED WITH THE CONTROL GROUP. SIGNIFICANT DECREASES WERE OBSERVED IN THE BDNF PROTEIN, EXON I MRNA, AND HISTONE H3 ACETYLATION LEVELS AND THERE WERE SIGNIFICANT INCREASES IN DNMT1 AND DNMT3A MRNA LEVELS. THE COMPARISON BETWEEN THE MS + ESC AND MS GROUPS REVEALED SIGNIFICANT INCREASES IN BDNF PROTEIN, EXON I MRNA, AND HISTONE H3 ACETYLATION LEVELS AND SIGNIFICANT DECREASES IN MECP2 AND DNMT1 AND DNMT3A MRNA LEVELS. CONCLUSION: THESE FINDINGS INDICATE THAT MS INDUCED EPIGENETIC CHANGES AT THE BDNF EXON I PROMOTER AND THESE CHANGES WERE PREVENTED BY ANTIDEPRESSANT DRUG TREATMENT DURING ADULTHOOD. 2018 11 3082 38 GENOME-WIDE REDISTRIBUTION OF MECP2 IN DORSAL ROOT GANGLIA AFTER PERIPHERAL NERVE INJURY. BACKGROUND: METHYL-CPG-BINDING PROTEIN 2 (MECP2), A PROTEIN WITH AFFINITY FOR METHYLATED CYTOSINES, IS CRUCIAL FOR NEURONAL DEVELOPMENT AND FUNCTION. MECP2 REGULATES GENE EXPRESSION THROUGH ACTIVATION, REPRESSION AND CHROMATIN REMODELING. MUTATIONS IN MECP2 CAUSE RETT SYNDROME, AND THESE PATIENTS DISPLAY IMPAIRED NOCICEPTION. WE OBSERVED AN INCREASE IN MECP2 EXPRESSION IN MOUSE DORSAL ROOT GANGLIA (DRG) AFTER PERIPHERAL NERVE INJURY. THE FUNCTIONAL IMPLICATION OF INCREASED MECP2 IS LARGELY UNKNOWN. TO IDENTIFY REGIONS OF THE GENOME BOUND BY MECP2 IN THE DRG AND THE CHANGES INDUCED BY NERVE INJURY, A CHROMATIN IMMUNOPRECIPITATION OF MECP2 FOLLOWED BY SEQUENCING (CHIP-SEQ) WAS PERFORMED 4 WEEKS AFTER SPARED NERVE INJURY (SNI). RESULTS: WHILE THE NUMBER OF BINDING SITES ACROSS THE GENOME REMAINED SIMILAR IN THE SNI MODEL AND SHAM CONTROL, SNI INDUCED THE REDISTRIBUTION OF MECP2 TO TRANSCRIPTIONALLY RELEVANT REGIONS. TO DETERMINE HOW DIFFERENTIAL BINDING OF MECP2 CAN AFFECT GENE EXPRESSION IN THE DRG, WE INVESTIGATED MMU-MIR-126, A MICRORNA LOCUS THAT HAD ENRICHED MECP2 BINDING IN THE SNI MODEL. ENRICHED MECP2 BINDING TO MIR-126 LOCUS AFTER NERVE INJURY REPRESSED MIR-126 EXPRESSION, AND THIS WAS NOT MEDIATED BY ALTERATIONS IN METHYLATION PATTERN AT THE MIR-126 LOCUS. DOWNREGULATION OF MIR-126 RESULTED IN THE UPREGULATION OF ITS TWO TARGET GENES DNMT1 AND VEGFA IN NEURO 2A CELLS AND IN SNI MODEL COMPARED TO CONTROL. THESE TARGET GENES WERE SIGNIFICANTLY DOWNREGULATED IN MECP2-NULL MICE COMPARED TO WILD-TYPE LITTERMATES, INDICATING A REGULATORY ROLE FOR MECP2 IN ACTIVATING DNMT1 AND VEGFA EXPRESSION. INTRATHECAL DELIVERY OF MIR-126 WAS NOT SUFFICIENT TO REVERSE NERVE INJURY-INDUCED MECHANICAL AND THERMAL HYPERSENSITIVITY, BUT DECREASED DNMT1 AND VEGFA EXPRESSION IN THE DRG. CONCLUSIONS: OUR STUDY SHOWS A REGULATORY ROLE FOR MECP2 IN THAT CHANGES IN GLOBAL REDISTRIBUTION CAN RESULT IN DIRECT AND INDIRECT MODULATION OF GENE EXPRESSION IN THE DRG. ALTERATIONS IN GENOME-WIDE BINDING OF MECP2 THEREFORE PROVIDE A MOLECULAR BASIS FOR A BETTER UNDERSTANDING OF EPIGENETIC REGULATION-INDUCED MOLECULAR CHANGES UNDERLYING NERVE INJURY. 2016 12 3372 31 HISTONE MODIFICATIONS OF THE CRHR1 GENE IN A RAT MODEL OF DEPRESSION FOLLOWING CHRONIC STRESS. MULTIPLE LINES OF EVIDENCE SUGGEST A LINK BETWEEN DEPRESSION AND CHANGES IN HYPOTHALAMIC-PITUITARY-ADRENAL (HPA)-AXIS HORMONE DYNAMICS, INCLUDING ALTERED REGULATION OF THE CORTICOTROPHIN-RELEASING HORMONE (CRH) AND ITS MAIN RECEPTOR, CORTICOTROPHIN-RELEASING HORMONE RECEPTOR 1 (CRHR1). HOWEVER, THE PRECISE MOLECULAR MECHANISMS UNDERLYING DEPRESSION REMAIN POORLY UNDERSTOOD. IN THIS STUDY, WE EMPLOYED A MODEL OF DEPRESSION IN RATS BY SUBJECTING ANIMALS TO 21 DAYS OF CHRONIC UNPREDICTABLE MILD STRESS (CUMS). REAL-TIME PCR AND WESTERN BLOTTING WERE USED TO STUDY THE MRNA AND PROTEIN EXPRESSION LEVELS OF CRHR1 IN THE HYPOTHALAMUS. IN ADDITION, CHROMATIN IMMUNOPRECIPITATION ASSAYS WERE USED TO DETECT HISTONE METHYLATION AT THE CRHR1 GENE PROMOTER; THE LEVELS OF HISTONE H3 TRIMETHYLATION AT LYSINES 4 (H3K4) AND 9 (H3K9) REFLECT ACTIVE TRANSCRIPTION AND TRANSCRIPTIONAL REPRESSION, RESPECTIVELY. RATS EXPOSED TO CUMS EXHIBITED SIGNIFICANT REDUCTION IN LOCOMOTION AND SUCROSE PREFERENCE. THESE BEHAVIORAL ALTERATIONS WERE ASSOCIATED WITH ELEVATED EXPRESSION LEVELS OF CRHR1 MRNA AND PROTEIN IN THE HYPOTHALAMUS OF RATS IN THE CUMS GROUP. WE ALSO FOUND THAT THE LEVELS OF H3K9 TRIMETHYLATION AT THE CRHR1 GENE PROMOTER IN THE CUMS GROUP WERE SIGNIFICANTLY LOWER THAN THOSE IN THE CONTROL GROUP, WHEREAS H3K4 TRIMETHYLATION LEVELS WERE THE SAME FOR BOTH GROUPS. TAKEN TOGETHER, OUR FINDINGS SUGGEST THAT THE INCREASE IN CRHR1 EXPRESSION IN THE HYPOTHALAMUS OF STRESSED RATS CORRELATES WITH A DECREASE IN THE REPRESSIVE CHROMATIN STATE CAUSED BY REDUCED H3K9 TRIMETHYLATION LEVELS. THESE DATA ARE THE FIRST IN VIVO EVIDENCE OF A ROLE FOR CHROMATIN MODIFICATIONS IN THE REGULATION OF CRHR1 GENE EXPRESSION IN THE HYPOTHALAMUS, AND MAY PROVIDE NOVEL INSIGHT INTO THERAPEUTIC APPROACHES TO TREAT DEPRESSION. 2014 13 4628 31 NEUROEPIGENETIC ALTERATIONS IN THE PREFRONTAL CORTEX OF TYPE 2 DIABETIC MICE THROUGH DNA HYPERMETHYLATION. BACKGROUND: DNA METHYLATION CHANGES HAVE KNOWN TO DOWNREGULATE SEVERAL REGULATORY PROTEINS EPIGENETICALLY DURING VARIOUS NEURODEGENERATIVE DISORDERS. OUR STUDY AIMS TO UNDERSTAND THE EFFECT OF THIS GLOBAL DNA METHYLATION ON THE CEREBRAL COMPLICATIONS OF TYPE 2 DIABETES MICE, AND ITS NOTABLE EFFECT ON MAINTAINING THE SYNAPTIC FIDELITY. METHODS AND RESULTS: CHRONIC HIGH FAT DIET AND STREPTOZOTOCIN-INDUCED DIABETIC MICE WERE STUDIED FOR THE NEUROBEHAVIORAL AND NEUROANATOMIC PARAMETERS PERTAINING TO PREFRONTAL CORTEX, SUBSEQUENTLY ELUCIDATING THE ASSOCIATED CHANGES IN DNA METHYLATION WITHIN THESE DIABETIC BRAINS. FURTHER, THE IMPACT OF THIS EPIGENETIC DYSREGULATION ON HSF1, BDNF AND PSD95 WERE STUDIED BY ASSESSING THE BINDING AFFINITY AND LEVEL OF % METHYLATION WITHIN THE PROMOTER SITE OF THEIR RESPECTIVE GENES. OUR STUDY SUGGEST INCREASED DNMT ABERRATIONS WITHIN THE PREFRONTAL CORTEX, WITH INCREASED MECP2 LEVELS, CONFIRMING DNA HYPERMETHYLATION. THIS WAS IN ACCORDANCE WITH THE ALTERED NEUROBEHAVIORAL CHANGES. FURTHER, THE HYPERMETHYLATION WAS FOUND TO PARTICIPATE IN GENE SILENCING OF HSF1, BDNF AND PSD95 PROTEINS, RESPONSIBLE FOR MAINTAINING THE SYNAPTIC FIDELITY. CONCLUSION: OVERALL, OUR STUDY CONCLUDES THE PLAUSIBLE INVOLVEMENT OF NEUROEPIGENETIC ALTERATIONS IN THE PREFRONTAL CORTEX (PFC) OF THE TYPE 2 DIABETES MICE, SPECIFICALLY DNA HYPERMETHYLATION. PFC PLAYS A CENTRAL ROLE IN MODULATING COGNITIVE AND OTHER EXECUTIVE FUNCTIONS THROUGH ITS CONNECTION WITH SEVERAL BRAIN REGIONS, AND THUS THERAPEUTIC STRATEGIES TARGETING EPIGENETIC MODULATIONS IN IT, CAN PAVE A WAY IN CONTROLLING SEVERAL NEUROLOGICAL ALTERATIONS IN THE BRAIN. 2022 14 1614 38 DNA METHYLTRANSFERASE 3A IS INVOLVED IN THE SUSTAINED EFFECTS OF CHRONIC STRESS ON SYNAPTIC FUNCTIONS AND BEHAVIORS. EMERGING EVIDENCE SUGGESTS THAT EPIGENETIC MECHANISMS REGULATE ABERRANT GENE TRANSCRIPTION IN STRESS-ASSOCIATED MENTAL DISORDERS. HOWEVER, IT REMAINS TO BE ELUCIDATED ABOUT THE ROLE OF DNA METHYLATION AND ITS CATALYZING ENZYMES, DNA METHYLTRANSFERASES (DNMTS), IN THIS PROCESS. HERE, WE FOUND THAT MALE RATS EXPOSED TO CHRONIC (2-WEEK) UNPREDICTABLE STRESS EXHIBITED A SUBSTANTIAL REDUCTION OF DNMT3A AFTER STRESS CESSATION IN THE PREFRONTAL CORTEX (PFC), A KEY TARGET REGION OF STRESS. TREATMENT OF UNSTRESSED CONTROL RATS WITH DNMT INHIBITORS RECAPITULATED THE EFFECT OF CHRONIC UNPREDICTABLE STRESS ON DECREASED AMPAR EXPRESSION AND FUNCTION IN PFC. IN CONTRAST, OVEREXPRESSION OF DNMT3A IN PFC OF STRESSED ANIMALS PREVENTED THE LOSS OF GLUTAMATERGIC RESPONSES. MOREOVER, THE STRESS-INDUCED BEHAVIORAL ABNORMALITIES, INCLUDING THE IMPAIRED RECOGNITION MEMORY, HEIGHTENED AGGRESSION, AND HYPERLOCOMOTION, WERE PARTIALLY ATTENUATED BY DNMT3A EXPRESSION IN PFC OF STRESSED ANIMALS. FINALLY, WE FOUND THAT THERE WERE GENOME-WIDE DNA METHYLATION CHANGES AND TRANSCRIPTOME ALTERATIONS IN PFC OF STRESSED RATS, BOTH OF WHICH WERE ENRICHED AT SEVERAL NEURAL PATHWAYS, INCLUDING GLUTAMATERGIC SYNAPSE AND MICROTUBULE-ASSOCIATED PROTEIN KINASE SIGNALING. THESE RESULTS HAVE THEREFORE RECOGNIZED THE POTENTIAL ROLE OF DNA EPIGENETIC MODIFICATION IN STRESS-INDUCED DISTURBANCE OF SYNAPTIC FUNCTIONS AND COGNITIVE AND EMOTIONAL PROCESSES. 2021 15 2371 40 EPIGENETIC REGULATION OF THE GLUCOCORTICOID RECEPTOR PROMOTER 1(7) IN ADULT RATS. REGULATION OF GLUCOCORTICOID RECEPTOR (GR) LEVELS IS AN IMPORTANT STRESS ADAPTATION MECHANISM. TRANSCRIPTION FACTOR NFGI-A AND ENVIRONMENTALLY INDUCED GR PROMOTER 1 7 METHYLATION HAVE BEEN IMPLICATED IN FINE-TUNING THE EXPRESSION OF GR 1 7 TRANSCRIPTS. HERE, WE INVESTIGATED GR PROMOTER 1 7 METHYLATION AND GR 1 7 EXPRESSION IN ADULT RATS EXPOSED TO EITHER ACUTE OR CHRONIC STRESS PARADIGMS. A STRONG NEGATIVE CORRELATION WAS OBSERVED BETWEEN THE SUM OF PROMOTER-WIDE METHYLATION LEVELS AND GR 1 7 TRANSCRIPT LEVELS, INDEPENDENT OF THE STRESSOR. METHYLATION OF INDIVIDUAL SITES DID NOT, HOWEVER, CORRELATE WITH TRANSCRIPT LEVELS. THIS SUGGESTED THAT PROMOTER 1 7 WAS DIRECTLY REGULATED BY PROMOTER-WIDE DNA METHYLATION. ALTHOUGH ACUTE STRESS INCREASED NGFI-A EXPRESSION IN THE HYPOTHALAMIC PARAVENTRICULAR NUCLEUS (PVN), GR 1 7 TRANSCRIPT LEVELS REMAINED UNAFFECTED DESPITE LOW METHYLATION LEVELS. ACUTE STRESS HAD LITTLE EFFECT ON THESE LOW METHYLATION LEVELS, EXCEPT AT FOUR HIPPOCAMPAL CPGS. CHRONIC STRESS ALTERED THE CORTICOSTERONE RESPONSE TO AN ACUTE STRESSOR. IN THE ADRENAL AND PITUITARY GLANDS, BUT NOT IN THE BRAIN, THIS WAS ACCOMPANIED BY AN INCREASE IN METHYLATION LEVELS IN ORCHESTRATED CLUSTERS RATHER THAN INDIVIDUAL CPGS. PVN METHYLATION LEVELS, UNAFFECTED BY ACUTE OR CHRONIC STRESS, WERE SIGNIFICANTLY MORE VARIABLE WITHIN- THAN BETWEEN-GROUPS, SUGGESTING THAT THEY WERE INSTATED PROBABLY DURING THE PERINATAL PERIOD AND REPRESENT A PRE-ESTABLISHED TRAIT. THUS, IN ADDITION TO THE KNOWN PERINATAL PROGRAMMING, THE GR 1 7 PROMOTER IS EPIGENETICALLY REGULATED BY CHRONIC STRESS IN ADULTHOOD, AND RETAINS PROMOTER-WIDE TISSUE-SPECIFIC PLASTICITY. DIFFERENCES IN METHYLATION SUSCEPTIBILITY BETWEEN THE PVN IN THE PERINATAL PERIOD AND THE PERIPHERAL HPA AXIS TISSUES IN ADULTHOOD MAY REPRESENT AN IMPORTANT "TRAIT" VS. "STATE" REGULATION OF THE GR GENE. 2012 16 4879 17 OVERLAPPING SIGNATURES OF CHRONIC PAIN IN THE DNA METHYLATION LANDSCAPE OF PREFRONTAL CORTEX AND PERIPHERAL T CELLS. WE TESTED THE HYPOTHESIS THAT EPIGENETIC MECHANISMS IN THE BRAIN AND THE IMMUNE SYSTEM ARE ASSOCIATED WITH CHRONIC PAIN. GENOME-WIDE DNA METHYLATION ASSESSED IN 9 MONTHS POST NERVE-INJURY (SNI) AND SHAM RATS, IN THE PREFRONTAL CORTEX (PFC) AS WELL AS IN T CELLS REVEALED A VAST DIFFERENCE IN THE DNA METHYLATION LANDSCAPE IN THE BRAIN BETWEEN THE GROUPS AND A REMARKABLE OVERLAP (72%) BETWEEN DIFFERENTIALLY METHYLATED PROBES IN T CELLS AND PREFRONTAL CORTEX. DNA METHYLATION STATES IN THE PFC SHOWED ROBUST CORRELATION WITH PAIN SCORE OF ANIMALS IN SEVERAL GENES INVOLVED IN PAIN. FINALLY, ONLY 11 DIFFERENTIALLY METHYLATED PROBES IN T CELLS WERE SUFFICIENT TO DISTINGUISH SNI OR SHAM INDIVIDUAL RATS. THIS STUDY SUPPORTS THE PLAUSIBILITY OF DNA METHYLATION INVOLVEMENT IN CHRONIC PAIN AND DEMONSTRATES THE POTENTIAL FEASIBILITY OF DNA METHYLATION MARKERS IN T CELLS AS NONINVASIVE BIOMARKERS OF CHRONIC PAIN SUSCEPTIBILITY. 2016 17 1809 34 EFFECTS OF ANTIPSYCHOTIC DRUGS ON THE EPIGENETIC MODIFICATION OF BRAIN-DERIVED NEUROTROPHIC FACTOR GENE EXPRESSION IN THE HIPPOCAMPI OF CHRONIC RESTRAINT STRESS RATS. RECENT STUDIES HAVE SHOWN THAT ANTIPSYCHOTIC DRUGS HAVE EPIGENETIC EFFECTS. HOWEVER, THE EFFECTS OF ANTIPSYCHOTIC DRUGS ON HISTONE MODIFICATION REMAIN UNCLEAR. THEREFORE, WE INVESTIGATED THE EFFECTS OF ANTIPSYCHOTIC DRUGS ON THE EPIGENETIC MODIFICATION OF THE BDNF GENE IN THE RAT HIPPOCAMPUS. RATS WERE SUBJECTED TO CHRONIC RESTRAINT STRESS (6 H/D FOR 21 D) AND THEN WERE ADMINISTERED WITH EITHER OLANZAPINE (2 MG/KG) OR HALOPERIDOL (1 MG/KG). THE LEVELS OF HISTONE H3 ACETYLATION AND MECP2 BINDING AT BDNF PROMOTER IV WERE ASSESSED WITH CHROMATIN IMMUNOPRECIPITATION ASSAYS. THE MRNA LEVELS OF TOTAL BDNF WITH EXON IV, HDAC5, DNMT1, AND DNMT3A WERE ASSESSED WITH A QUANTITATIVE RT-PCR PROCEDURE. CHRONIC RESTRAINT STRESS RESULTED IN THE DOWNREGULATION OF TOTAL AND EXON IV BDNF MRNA LEVELS AND A DECREASE IN HISTONE H3 ACETYLATION AND AN INCREASE IN MECP2 BINDING AT BDNF PROMOTER IV. FURTHERMORE, THERE WERE ROBUST INCREASES IN THE EXPRESSION OF HDAC5 AND DNMTS. OLANZAPINE ADMINISTRATION LARGELY PREVENTED THESE CHANGES. THE ADMINISTRATION OF HALOPERIDOL HAD NO EFFECT. THESE FINDINGS SUGGEST THAT THE ANTIPSYCHOTIC DRUG OLANZAPINE INDUCED HISTONE MODIFICATION OF BDNF GENE EXPRESSION IN THE HIPPOCAMPUS AND THAT THESE EPIGENETIC ALTERATIONS MAY REPRESENT ONE OF THE MECHANISMS UNDERLYING THE ACTIONS OF ANTIPSYCHOTIC DRUGS. 2018 18 1731 34 DYSREGULATION OF THE HISTONE DEMETHYLASE KDM6B IN ALCOHOL DEPENDENCE IS ASSOCIATED WITH EPIGENETIC REGULATION OF INFLAMMATORY SIGNALING PATHWAYS. EPIGENETIC ENZYMES OVERSEE LONG-TERM CHANGES IN GENE EXPRESSION BY INTEGRATING GENETIC AND ENVIRONMENTAL CUES. WHILE THERE ARE HUNDREDS OF ENZYMES THAT CONTROL HISTONE AND DNA MODIFICATIONS, THEIR POTENTIAL ROLES IN SUBSTANCE ABUSE AND ALCOHOL DEPENDENCE REMAIN UNDEREXPLORED. A FEW RECENT STUDIES HAVE SUGGESTED THAT EPIGENETIC PROCESSES COULD UNDERLIE TRANSCRIPTOMIC AND BEHAVIORAL HALLMARKS OF ALCOHOL ADDICTION. IN THE PRESENT STUDY, WE SOUGHT TO IDENTIFY EPIGENETIC ENZYMES IN THE BRAIN THAT ARE DYSREGULATED DURING PROTRACTED ABSTINENCE AS A CONSEQUENCE OF CHRONIC AND INTERMITTENT ALCOHOL EXPOSURE. THROUGH QUANTITATIVE MRNA EXPRESSION ANALYSIS OF OVER 100 EPIGENETIC ENZYMES, WE IDENTIFIED 11 THAT ARE SIGNIFICANTLY ALTERED IN ALCOHOL-DEPENDENT RATS COMPARED WITH CONTROLS. FOLLOW-UP STUDIES OF ONE OF THESE ENZYMES, THE HISTONE DEMETHYLASE KDM6B, SHOWED THAT THIS ENZYME EXHIBITS REGION-SPECIFIC DYSREGULATION IN THE PREFRONTAL CORTEX AND NUCLEUS ACCUMBENS OF ALCOHOL-DEPENDENT RATS. KDM6B WAS ALSO UPREGULATED IN THE HUMAN ALCOHOLIC BRAIN. UPREGULATION OF KDM6B PROTEIN IN ALCOHOL-DEPENDENT RATS WAS ACCOMPANIED BY A DECREASE OF TRIMETHYLATION LEVELS AT HISTONE H3, LYSINE 27 (H3K27ME3), CONSISTENT WITH THE KNOWN DEMETHYLASE SPECIFICITY OF KDM6B. SUBSEQUENT EPIGENETIC (CHROMATIN IMMUNOPRECIPITATION [CHIP]-SEQUENCING) ANALYSIS SHOWED THAT ALCOHOL-INDUCED CHANGES IN H3K27ME3 WERE SIGNIFICANTLY ENRICHED AT GENES IN THE IL-6 SIGNALING PATHWAY, CONSISTENT WITH THE WELL-CHARACTERIZED ROLE OF KDM6B IN MODULATION OF INFLAMMATORY RESPONSES. KNOCKDOWN OF KDM6B IN CULTURED MICROGLIAL CELLS DIMINISHED IL-6 INDUCTION IN RESPONSE TO AN INFLAMMATORY STIMULUS. OUR FINDINGS IMPLICATE A NOVEL KDM6B-MEDIATED EPIGENETIC SIGNALING PATHWAY INTEGRATED WITH INFLAMMATORY SIGNALING PATHWAYS THAT ARE KNOWN TO UNDERLIE THE DEVELOPMENT OF ALCOHOL ADDICTION. 2021 19 431 35 ANTIDEPRESSANT ADMINISTRATION MODULATES STRESS-INDUCED DNA METHYLATION AND DNA METHYLTRANSFERASE EXPRESSION IN RAT PREFRONTAL CORTEX AND HIPPOCAMPUS. STRESS AND ANTIDEPRESSANT TREATMENT CAN MODULATE DNA METHYLATION IN PROMOTER REGION OF GENES RELATED TO NEUROPLASTICITY AND MOOD REGULATION, THUS IMPLICATING THIS EPIGENETIC MECHANISM IN DEPRESSION NEUROBIOLOGY AND TREATMENT. ACCORDINGLY, SYSTEMIC ADMINISTRATION OF DNA METHYLTRANSFERASE (DNMT) INHIBITORS INDUCES ANTIDEPRESSANT-LIKE EFFECTS IN RODENTS. DNA METHYLATION IS CONVEYED BY DNMT 1, 3A AND 3B ISOFORMS, WHICH ARE DIFFERENTIALLY EXPRESSED IN THE BRAIN. IN ORDER TO INVESTIGATE IF THE BEHAVIORAL EFFECTS OF ANTIDEPRESSANTS COULD BE ASSOCIATED WITH CHANGES IN DNA METHYLATION AND DNMT EXPRESSION, WE INVESTIGATED THE EFFECTS INDUCED BY ACUTE AND REPEATED ANTIDEPRESSANT TREATMENT ON DNA METHYLATION AND DNMT EXPRESSION (1, 3A AND 3B ISOFORMS) IN DIFFERENT BRAIN REGIONS OF RATS EXPOSED TO A STRESS MODEL OF DEPRESSION, THE LEARNED HELPLESSNESS (LH). THEREFORE, RATS WERE EXPOSED TO PRETEST AND TREATED WITH ONE OR SEVEN INJECTIONS OF VEHICLE OR IMIPRAMINE (15 MG KG(-1)), WITH TEST SESSION PERFORMED ONE HOUR AFTER THE LAST INJECTION. CHRONIC, BUT NOT ACUTE, IMIPRAMINE ADMINISTRATION ATTENUATED ESCAPE FAILURES DURING THE TEST, A WELL DESCRIBED ANTIDEPRESSANT-LIKE EFFECT IN THIS MODEL. DNA METHYLATION AND DNMT (1, 3A AND 3B) LEVELS WERE MEASURED IN THE DORSAL AND VENTRAL HIPPOCAMPUS (DHPC, VHPC) AND IN THE PREFRONTAL CORTEX (PFC) OF RATS EXPOSED TO STRESS AND TREATMENT. STRESS INCREASED DNA METHYLATION, DNMT3A AND DNMT3B EXPRESSION IN THE DHPC AND PFC. CHRONIC, BUT NOT ACUTE, IMIPRAMINE ADMINISTRATION ATTENUATED STRESS EFFECTS ONLY IN THE PFC. THESE RESULTS SUGGEST THE REGULATION OF DNA METHYLATION IN THE PFC MAY BE AN IMPORTANT MECHANISM FOR ANTIDEPRESSANT-LIKE EFFECTS IN THE LH MODEL. 2018 20 6069 39 THE DIOXIN RECEPTOR IS SILENCED BY PROMOTER HYPERMETHYLATION IN HUMAN ACUTE LYMPHOBLASTIC LEUKEMIA THROUGH INHIBITION OF SP1 BINDING. THE TRANSCRIPTION FACTOR ARYL HYDROCARBON RECEPTOR (AHR) HAS RELEVANT FUNCTIONS IN CELL PROLIFERATION. INTERESTINGLY, THE AHR CAN EITHER PROMOTE OR INHIBIT PROLIFERATION DEPENDING ON THE CELL PHENOTYPE. ALTHOUGH RECENT DATA REVEAL POTENTIAL PATHWAYS FOR AHR SIGNALING IN CELL PROLIFERATION, THE MECHANISMS THAT REGULATE ITS ACTIVITY IN TUMOR CELLS REMAIN UNKNOWN. HERE, WE HAVE ANALYZED PROMOTER HYPERMETHYLATION AS A POTENTIAL MECHANISM CONTROLLING AHR EXPRESSION IN HUMAN TUMOR CELLS. AHR PROMOTER CPG METHYLATION WAS SPORADIC IN A PANEL OF 19 TUMOR CELL LINES EXCEPT FOR THE CHRONIC MYELOID LEUKEMIA (CML) K562 AND THE ACUTE LYMPHOBLASTIC LEUKEMIA (ALL) REH. WHEN COMPARED WITH NORMAL LYMPHOCYTES, REH HAD VERY LOW CONSTITUTIVE AHR EXPRESSION THAT COULD BE ATTRIBUTED TO PROMOTER HYPERMETHYLATION SINCE TREATMENT WITH THE DNA DEMETHYLATING AGENT 5-AZA-2'-DEOXYCITIDINE (AZA) SIGNIFICANTLY INCREASED AHR MRNA AND PROTEIN. THESE RESULTS IN LEUKEMIA-DERIVED CELL LINES WERE FURTHER CONFIRMED IN PRIMARY ALL, WHERE 33% OF THE PATIENTS (7/21) HAD AHR PROMOTER HYPERMETHYLATION. CHROMATIN IMMUNOPRECIPITATION (CHIP) SHOWED THAT METHYLATION IMPAIRED BINDING OF THE TRANSCRIPTION FACTOR SP1 TO THE AHR PROMOTER, THUS PROVIDING A MECHANISM FOR AHR DOWNREGULATION IN REH CELLS. THEREFORE, PROMOTER HYPERMETHYLATION REPRESENTS A NOVEL EPIGENETIC MECHANISM DOWNREGULATING AHR ACTIVITY IN HEMATOLOGICAL MALIGNANCIES SUCH AS ALL. 2006