1 2778 147 EZH1 IS AN ANTIPSYCHOTIC-SENSITIVE EPIGENETIC MODULATOR OF SOCIAL AND MOTIVATIONAL BEHAVIOR THAT IS DYSREGULATED IN SCHIZOPHRENIA. BACKGROUND: WITH THE CAPACITY TO MODULATE GENE NETWORKS IN AN ENVIRONMENTALLY-SENSITIVE MANNER, THE ROLE OF EPIGENETIC SYSTEMS IN MENTAL DISORDERS HAS COME UNDER INTENSE INVESTIGATION. DYSREGULATION OF EPIGENETIC EFFECTORS, INCLUDING MICRORNAS AND HISTONE-MODIFYING ENZYMES, MAY BETTER EXPLAIN THE ROLE OF ENVIRONMENTAL RISK FACTORS AND THE OBSERVED HERITABILITY RATE THAT CANNOT BE FULLY ATTRIBUTED TO KNOWN GENETIC RISK ALLELES. HERE, WE AIMED TO IDENTIFY NOVEL EPIGENETIC TARGETS OF THE SCHIZOPHRENIA-ASSOCIATED MICRORNA 132 (MIR-132). METHODS: HISTONE MODIFICATIONS WERE QUANTIFIED BY IMMUNODETECTION IN RESPONSE TO VIRAL-MEDIATED OVEREXPRESSION OF MIR-132 WHILE A LUMINESCENT REPORTER SYSTEM WAS USED TO VALIDATE TARGETS OF MIR-132 IN VITRO. GENOME-WIDE PROFILING, QUANTITATIVE PCR AND NANOSTING WERE USED TO QUANTIFY GENE EXPRESSION IN POST-MORTEM HUMAN BRAINS, NEURONAL CULTURES AND PREFRONTAL CORTEX (PFC) OF MICE CHRONICALLY EXPOSED TO ANTIPSYCHOTICS. FOLLOWING VIRAL-MEDIATED DEPLETION OF ENHANCER OF ZESTE 1 (EZH1) IN THE MURINE PFC, BEHAVIORS INCLUDING SOCIABILITY AND MOTIVATION WERE ASSESSED USING A 3-CHAMBERED APPARATUS AND FORCED-SWIM TEST, RESPECTIVELY. RESULTS: OVEREXPRESSION OF MIR-132 DECREASED GLOBAL HISTONE 3 LYSINE 27 TRI-METHYLATION (H3K27ME3), A REPRESSIVE EPIGENETIC MARK. MOREOVER, THE POLYCOMB-ASSOCIATED H3K27 METHYLTRANSFERASE, EZH1, IS REGULATED BY MIR-132 AND UPREGULATED IN THE PFC OF SCHIZOPHRENICS. UNLIKE ITS HOMOLOG EZH2, EXPRESSION OF EZH1 IN THE MURINE PFC DECREASED FOLLOWING CHRONIC EXPOSURE TO ANTIPSYCHOTICS. VIRAL-MEDIATED DEPLETION OF EZH1 IN THE MOUSE PFC ATTENUATED SOCIABILITY, ENHANCED MOTIVATIONAL BEHAVIORS, AND AFFECTED GENE EXPRESSION PATHWAYS RELATED TO NEUROTRANSMISSION AND BEHAVIORAL PHENOTYPES. CONCLUSIONS: EZH1 IS DYSREGULATED IN SCHIZOPHRENIA, SENSITIVE TO ANTIPSYCHOTIC MEDICATIONS, AND A BRAIN-ENRICHED MIR-132 TARGET THAT CONTROLS NEUROBEHAVIORAL PHENOTYPES.	2018	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                              
2 1731  47 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	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                         
3 1698  35 DYNAMIC EFFECTS OF EARLY ADOLESCENT STRESS ON DEPRESSIVE-LIKE BEHAVIORS AND EXPRESSION OF CYTOKINES AND JMJD3 IN THE PREFRONTAL CORTEX AND HIPPOCAMPUS OF RATS. AIMS: EXPRESSION OF INFLAMMATORY CYTOKINES IN THE BRAIN HAS BEEN REPORTED TO BE INVOLVED IN THE PATHOGENESIS OF AND SUSCEPTIBILITY TO DEPRESSION. JUMONJI DOMAIN-CONTAINING 3 (JMJD3), WHICH IS A HISTONE H3 LYSINE 27 (H3K27) DEMETHYLASE AND CAN REGULATE MICROGLIAL ACTIVATION, HAS BEEN REGARDED AS A CRUCIAL ELEMENT IN THE EXPRESSION OF INFLAMMATORY CYTOKINES. FURTHERMORE, RECENT STUDIES HIGHLIGHTED THE FACT THAT LIPOPOLYSACCHARIDES INDUCE DEPRESSIVE-LIKE BEHAVIORS AND HIGHER JMJD3 EXPRESSION AND LOWER H3K27ME3 EXPRESSION IN THE BRAIN. HOWEVER, WHETHER THE PROCESS OF JMJD3 MEDIATING INFLAMMATORY CYTOKINES WAS INVOLVED IN THE SUSCEPTIBILITY TO DEPRESSION DUE TO EARLY-LIFE STRESS REMAINED ELUSIVE. METHODS: RATS EXPOSED TO CHRONIC UNPREDICTABLE MILD STRESS (CUMS) IN ADOLESCENCE WERE USED IN ORDER TO DETECT DYNAMIC ALTERATIONS IN DEPRESSIVE-LIKE BEHAVIORS AND EXPRESSION OF CYTOKINES, JMJD3, AND H3K27ME3 IN THE PREFRONTAL CORTEX AND HIPPOCAMPUS. MOREOVER, MINOCYCLINE, AN INHIBITOR OF MICROGLIAL ACTIVATION, WAS EMPLOYED TO OBSERVE THE PROTECTIVE EFFECTS. RESULTS: OUR RESULTS SHOWED THAT CUMS DURING THE ADOLESCENT PERIOD INDUCED DEPRESSIVE-LIKE BEHAVIORS, OVER-EXPRESSION OF CYTOKINES, AND INCREASED JMJD3 AND DECREASED H3K27ME3 EXPRESSION IN THE PREFRONTAL CORTEX AND HIPPOCAMPUS OF BOTH ADOLESCENT AND ADULT RATS. HOWEVER, MINOCYCLINE RELIEVED ALL THE ALTERATIONS. CONCLUSION: THE STUDY REVEALED THAT JMJD3 MIGHT BE INVOLVED IN THE SUSCEPTIBILITY TO DEPRESSIVE-LIKE BEHAVIORS BY MODULATING H3K27ME3 AND PRO-INFLAMMATORY CYTOKINE EXPRESSION IN THE PREFRONTAL CORTEX AND HIPPOCAMPUS OF RATS THAT HAD BEEN STRESSED DURING EARLY ADOLESCENCE.	2018	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                        
4 1614  41 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	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                             
5 5791  45 STABLE HISTONE METHYLATION CHANGES AT PROTEOGLYCAN NETWORK GENES FOLLOWING ETHANOL EXPOSURE. ALCOHOL USE DISORDER (AUD) IS A CHRONIC MENTAL ILLNESS IN WHICH PATIENTS OFTEN ACHIEVE PROTRACTED PERIODS OF ABSTINENCE PRIOR TO RELAPSE. EPIGENETIC MECHANISMS MAY PROVIDE AN EXPLANATION FOR THE PERSISTING GENE EXPRESSION CHANGES THAT CAN BE OBSERVED EVEN AFTER LONG PERIODS OF ABSTINENCE AND MAY CONTRIBUTE TO RELAPSE. IN THIS STUDY, WE EXAMINED TWO HISTONE MODIFICATIONS, HISTONE 3 LYSINE 4 TRI-METHYLATION (H3K4ME3) AND HISTONE 3 LYSINE 27 TRI-METHYLATION (H3K27ME3), IN THE PREFRONTAL CORTEX OF WITHDRAWAL SEIZURE RESISTANT (WSR) MICE 21 DAYS AFTER 72 H OF ETHANOL VAPOR EXPOSURE. THESE HISTONE MODIFICATIONS WERE SELECTED BECAUSE THEY ARE ASSOCIATED WITH ACTIVE PROMOTERS (H3K4ME3) AND REPRESSED GENE EXPRESSION IN A EUCHROMATIC ENVIRONMENT (H3K27ME3). WE PERFORMED A GENOME-WIDE ANALYSIS TO IDENTIFY DIFFERENCES IN H3K4ME3 AND H3K27ME3 LEVELS IN POST-ETHANOL EXPOSURE VS. CONTROL MICE BY CHIP-SEQ. WE DETECTED A GLOBAL REDUCTION IN H3K4ME3 PEAKS AND INCREASE IN H3K27ME3 PEAKS IN POST-ETHANOL EXPOSURE MICE COMPARED TO CONTROLS, THESE CHANGES ARE CONSISTENT WITH PERSISTENT REDUCTIONS IN GENE EXPRESSION. PATHWAY ANALYSIS OF GENES DISPLAYING CHANGES IN H3K4ME3 AND H3K27ME3 REVEALED ENRICHMENT FOR GENES INVOLVED IN PROTEOGLYCAN AND CALCIUM SIGNALING PATHWAYS, RESPECTIVELY. MICROARRAY ANALYSIS OF 7,683 GENES AND QPCR ANALYSIS IDENTIFIED EIGHT GENES DISPLAYING CONCORDANT REGULATION OF GENE EXPRESSION AND H3K4ME3/H3K27ME3. WE ALSO COMPARED CHANGES IN H3K4ME3 AND/OR H3K27ME3 FROM OUR STUDY WITH CHANGES IN GENE EXPRESSION IN RESPONSE TO ETHANOL FROM PUBLISHED LITERATURE AND WE FOUND THAT THE EXPRESSION OF 52% OF THE GENES WITH ALTERED H3K4ME3 BINDING AND 40% OF GENES WITH H3K27ME3 DIFFERENCES ARE ALTERED BY ETHANOL EXPOSURE. THE CHROMATIN CHANGES ASSOCIATED WITH THE 21-DAY POST-EXPOSURE PERIOD SUGGEST THAT THIS PERIOD IS A UNIQUE STATE IN THE ADDICTION CYCLE THAT DIFFERS FROM ETHANOL INTOXICATION AND ACUTE WITHDRAWAL. THESE RESULTS PROVIDE INSIGHTS INTO THE ENDURING EFFECTS OF ETHANOL ON PROTEOGLYCAN AND CALCIUM SIGNALING GENES IN THE BRAIN.	2018	
                                                                                                                                                                                                                                                                                                                                                                                              
6 4497  37 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	
                                                                                                                                                                                                                                                                                                                           
7 4628  33 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	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                        
8  531  40 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  213  35 ACUTE AND CHRONIC ELECTROCONVULSIVE SEIZURES (ECS) DIFFERENTIALLY REGULATE THE EXPRESSION OF EPIGENETIC MACHINERY IN THE ADULT RAT HIPPOCAMPUS. BACKGROUND: ELECTROCONVULSIVE SEIZURE TREATMENT IS A FAST-ACTING ANTIDEPRESSANT THERAPY THAT EVOKES RAPID TRANSCRIPTIONAL, NEUROGENIC, AND BEHAVIORAL CHANGES. EPIGENETIC MECHANISMS CONTRIBUTE TO ALTERED GENE REGULATION, WHICH UNDERLIES THE NEUROGENIC AND BEHAVIORAL EFFECTS OF ELECTROCONVULSIVE SEIZURE. WE HYPOTHESIZED THAT ELECTROCONVULSIVE SEIZURE MAY MODULATE THE EXPRESSION OF EPIGENETIC MACHINERY, THUS ESTABLISHING POTENTIAL ALTERATIONS IN THE EPIGENETIC LANDSCAPE. METHODS: WE EXAMINED THE INFLUENCE OF ACUTE AND CHRONIC ELECTROCONVULSIVE SEIZURE ON THE GENE EXPRESSION OF HISTONE MODIFIERS, NAMELY HISTONE ACETYLTRANSFERASES, HISTONE DEACETYLASES, HISTONE METHYLTRANSFERASES, AND HISTONE (LYSINE) DEMETHYLASES AS WELL AS DNA MODIFYING ENZYMES, INCLUDING DNA METHYLTRANSFERASES, DNA DEMETHYLASES, AND METHYL-CPG-BINDING PROTEINS IN THE HIPPOCAMPI OF ADULT MALE WISTAR RATS USING QUANTITATIVE REAL TIME-PCR ANALYSIS. FURTHER, WE EXAMINED THE INFLUENCE OF ACUTE AND CHRONIC ELECTROCONVULSIVE SEIZURE ON GLOBAL AND RESIDUE-SPECIFIC HISTONE ACETYLATION AND METHYLATION LEVELS WITHIN THE HIPPOCAMPUS, A BRAIN REGION IMPLICATED IN THE CELLULAR AND BEHAVIORAL EFFECTS OF ELECTROCONVULSIVE SEIZURE. RESULTS: ACUTE AND CHRONIC ELECTROCONVULSIVE SEIZURE INDUCED A PRIMARILY UNIQUE, AND IN CERTAIN CASES BIDIRECTIONAL, REGULATION OF HISTONE AND DNA MODIFIERS, AND METHYL-CPG-BINDING PROTEINS, WITH AN OVERLAPPING PATTERN OF GENE REGULATION RESTRICTED TO SIRT4, MLL3, JMJD3, GADD45B, TET2, AND TET3. GLOBAL HISTONE ACETYLATION AND METHYLATION LEVELS WERE PREDOMINANTLY UNCHANGED, WITH THE EXCEPTION OF A SIGNIFICANT DECLINE IN H3K9 ACETYLATION IN THE HIPPOCAMPUS FOLLOWING CHRONIC ELECTROCONVULSIVE SEIZURE. CONCLUSIONS: ELECTROCONVULSIVE SEIZURE TREATMENT EVOKES THE TRANSCRIPTIONAL REGULATION OF SEVERAL HISTONE AND DNA MODIFIERS, AND METHYL-CPG-BINDING PROTEINS WITHIN THE HIPPOCAMPUS, WITH A PREDOMINANTLY DISTINCT PATTERN OF REGULATION INDUCED BY ACUTE AND CHRONIC ELECTROCONVULSIVE SEIZURE.	2016	
                                                                                                                                                                                                                                                                                                                                                                                                              
10 4879  18 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	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                   
11 5007  37 PERIPHERAL NERVE INJURY IS ASSOCIATED WITH CHRONIC, REVERSIBLE CHANGES IN GLOBAL DNA METHYLATION IN THE MOUSE PREFRONTAL CORTEX. CHANGES IN BRAIN STRUCTURE AND CORTICAL FUNCTION ARE ASSOCIATED WITH MANY CHRONIC PAIN CONDITIONS INCLUDING LOW BACK PAIN AND FIBROMYALGIA. THE MAGNITUDE OF THESE CHANGES CORRELATES WITH THE DURATION AND/OR THE INTENSITY OF CHRONIC PAIN. MOST STUDIES REPORT CHANGES IN COMMON AREAS INVOLVED IN PAIN MODULATION, INCLUDING THE PREFRONTAL CORTEX (PFC), AND PAIN-RELATED PATHOLOGICAL CHANGES IN THE PFC CAN BE REVERSED WITH EFFECTIVE TREATMENT. WHILE THE MECHANISMS UNDERLYING THESE CHANGES ARE UNKNOWN, THEY MUST BE DYNAMICALLY REGULATED. EPIGENETIC MODULATION OF GENE EXPRESSION IN RESPONSE TO EXPERIENCE AND ENVIRONMENT IS REVERSIBLE AND DYNAMIC. EPIGENETIC MODULATION BY DNA METHYLATION IS ASSOCIATED WITH ABNORMAL BEHAVIOR AND PATHOLOGICAL GENE EXPRESSION IN THE CENTRAL NERVOUS SYSTEM. DNA METHYLATION MIGHT ALSO BE INVOLVED IN MEDIATING THE PATHOLOGIES ASSOCIATED WITH CHRONIC PAIN IN THE BRAIN. WE THEREFORE TESTED A) WHETHER ALTERATIONS IN DNA METHYLATION ARE FOUND IN THE BRAIN LONG AFTER CHRONIC NEUROPATHIC PAIN IS INDUCED IN THE PERIPHERY USING THE SPARED NERVE INJURY MODAL AND B) WHETHER THESE INJURY-ASSOCIATED CHANGES ARE REVERSIBLE BY INTERVENTIONS THAT REVERSE THE PATHOLOGIES ASSOCIATED WITH CHRONIC PAIN. SIX MONTHS FOLLOWING PERIPHERAL NERVE INJURY, ABNORMAL SENSORY THRESHOLDS AND INCREASED ANXIETY WERE ACCOMPANIED BY DECREASED GLOBAL METHYLATION IN THE PFC AND THE AMYGDALA BUT NOT IN THE VISUAL CORTEX OR THE THALAMUS. ENVIRONMENTAL ENRICHMENT ATTENUATED NERVE INJURY-INDUCED HYPERSENSITIVITY AND REVERSED THE CHANGES IN GLOBAL PFC METHYLATION. FURTHERMORE, GLOBAL PFC METHYLATION CORRELATED WITH MECHANICAL AND THERMAL SENSITIVITY IN NEUROPATHIC MICE. IN SUMMARY, INDUCTION OF CHRONIC PAIN BY PERIPHERAL NERVE INJURY IS ASSOCIATED WITH EPIGENETIC CHANGES IN THE BRAIN. THESE CHANGES ARE DETECTED LONG AFTER THE ORIGINAL INJURY, AT A LONG DISTANCE FROM THE SITE OF INJURY AND ARE REVERSIBLE WITH ENVIRONMENTAL MANIPULATION. CHANGES IN BRAIN STRUCTURE AND CORTICAL FUNCTION THAT ARE ASSOCIATED WITH CHRONIC PAIN CONDITIONS MAY THEREFORE BE MEDIATED BY EPIGENETIC MECHANISMS.	2013	
                                                                                                                                                                                                                                                                                                                     
12 5177  36 PREFRONTAL CORTEX EXPRESSION OF CHROMATIN MODIFIER GENES IN MALE WSP AND WSR MICE CHANGES ACROSS ETHANOL DEPENDENCE, WITHDRAWAL, AND ABSTINENCE. ALCOHOL-USE DISORDER (AUD) IS A RELAPSING DISORDER ASSOCIATED WITH EXCESSIVE ETHANOL CONSUMPTION. RECENT STUDIES SUPPORT THE INVOLVEMENT OF EPIGENETIC MECHANISMS IN THE DEVELOPMENT OF AUD. STUDIES CARRIED OUT SO FAR HAVE FOCUSED ON A FEW SPECIFIC EPIGENETIC MODIFICATIONS. THE GOAL OF THIS PROJECT WAS TO INVESTIGATE GENE EXPRESSION CHANGES OF EPIGENETIC REGULATORS THAT MEDIATE A BROAD ARRAY OF CHROMATIN MODIFICATIONS AFTER CHRONIC ALCOHOL EXPOSURE, CHRONIC ALCOHOL EXPOSURE FOLLOWED BY 8 H WITHDRAWAL, AND CHRONIC ALCOHOL EXPOSURE FOLLOWED BY 21 DAYS OF ABSTINENCE IN WITHDRAWAL-RESISTANT (WSR) AND WITHDRAWAL SEIZURE-PRONE (WSP) SELECTED MOUSE LINES. WE FOUND THAT CHRONIC VAPOR EXPOSURE TO HIGHLY INTOXICATING LEVELS OF ETHANOL ALTERS THE EXPRESSION OF SEVERAL CHROMATIN REMODELING GENES MEASURED BY QUANTITATIVE PCR ARRAY ANALYSES. THE IDENTIFIED EFFECTS WERE INDEPENDENT OF SELECTED LINES, WHICH, HOWEVER, DISPLAYED BASELINE DIFFERENCES IN EPIGENETIC GENE EXPRESSION. WE REPORTED DYSREGULATION IN THE EXPRESSION OF GENES INVOLVED IN HISTONE ACETYLATION, DEACETYLATION, LYSINE AND ARGININE METHYLATION AND UBIQUITINATIONHYLATION DURING CHRONIC ETHANOL EXPOSURE AND WITHDRAWAL, BUT NOT AFTER 21 DAYS OF ABSTINENCE. ETHANOL-INDUCED CHANGES ARE CONSISTENT WITH DECREASED HISTONE ACETYLATION AND WITH DECREASED DEPOSITION OF THE PERMISSIVE UBIQUITINATION MARK H2BK120UB, ASSOCIATED WITH REDUCED TRANSCRIPTION. ON THE OTHER HAND, ETHANOL-INDUCED CHANGES IN THE EXPRESSION OF GENES INVOLVED IN HISTONE LYSINE METHYLATION ARE CONSISTENT WITH INCREASED TRANSCRIPTION. THE NET RESULT OF THESE MODIFICATIONS ON GENE EXPRESSION IS LIKELY TO DEPEND ON THE COMBINATION OF THE SPECIFIC HISTONE TAIL MODIFICATIONS PRESENT AT A GIVEN TIME ON A GIVEN PROMOTER. SINCE ALCOHOL DOES NOT MODULATE GENE EXPRESSION UNIDIRECTIONALLY, IT IS NOT SURPRISING THAT ALCOHOL DOES NOT UNIDIRECTIONALLY ALTER CHROMATIN STRUCTURE TOWARD A CLOSED OR OPEN STATE, AS SUGGESTED BY THE RESULTS OF THIS STUDY.	2017	
                                                                                                                                                                                                                                                                                                                                                                                                                             
13 4173  28 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	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                     
14 5624  26 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	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                              
15 2417  29 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	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                         
16 4401  37 MODULATION OF NEURONAL PLASTICITY FOLLOWING CHRONIC CONCOMITANT ADMINISTRATION OF THE NOVEL ANTIPSYCHOTIC LURASIDONE WITH THE MOOD STABILIZER VALPROIC ACID. RATIONALE: COMBINATORY THERAPY IS WIDELY USED IN PSYCHIATRY OWING TO THE POSSIBILITY THAT DRUGS WITH DIFFERENT MECHANISMS OF ACTION MAY SYNERGIZE TO IMPROVE FUNCTIONS DETERIORATED IN SCHIZOPHRENIA, BIPOLAR DISORDERS, AND MAJOR DEPRESSION. WHILE COMBINATORY STRATEGIES RELY ON RECEPTOR AND SYNAPTIC MECHANISMS, IT SHOULD ALSO BE CONSIDERED THAT TWO DRUGS MAY ALSO "INTERACT" ON THE LONG-TERM TO DETERMINE MORE ROBUST CHANGES IN NEURONAL PLASTICITY, WHICH REPRESENTS A DOWNSTREAM TARGET IMPORTANT FOR FUNCTIONAL RECOVERY. OBJECTIVE: THE AIM OF THE STUDY IS TO INVESTIGATE NEUROADAPTIVE CHANGES SET IN MOTION BY CHRONIC CONCOMITANT ADMINISTRATION OF THE NOVEL ANTIPSYCHOTIC LURASIDONE AND THE MOOD STABILIZER VALPROATE. METHODS: ANIMALS WERE CHRONICALLY TREATED WITH LURASIDONE, VALPROATE, OR THE COMBINATION OF THE TWO DRUGS AND KILLED 24 H AFTER THE LAST INJECTION TO EVALUATE ALTERATIONS OF DIFFERENT MEASURES OF NEURONAL PLASTICITY SUCH AS THE NEUROTROPHIN BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF), THE IMMEDIATE EARLY GENE ACTIVITY-REGULATED CYTOSKELETAL ASSOCIATED PROTEIN, AND THE EPIGENETIC REGULATORS HDAC 1, 2, AND 5 IN DORSAL AND VENTRAL HIPPOCAMPUS. RESULTS: THE RESULTS SUGGEST THAT COADMINISTRATION OF LURASIDONE AND VALPROATE PRODUCES, WHEN COMPARED TO THE SINGLE DRUGS, A LARGER INCREASE IN THE EXPRESSION OF BDNF IN THE VENTRAL HIPPOCAMPUS, THROUGH THE REGULATION OF SPECIFIC NEUROTROPHIN TRANSCRIPTS. WE ALSO FOUND THAT THE HISTONE DEACETYLASES WERE REGULATED BY THE DRUG COMBINATION, SUGGESTING THAT SOME OF THE TRANSCRIPTIONAL CHANGES MAY BE SUSTAINED BY EPIGENETIC MECHANISMS. CONCLUSIONS: OUR RESULTS SUGGEST THAT THE BENEFICIAL EFFECTS ASSOCIATED WITH COMBINATORY TREATMENT BETWEEN A SECOND-GENERATION ANTIPSYCHOTIC AND A MOOD STABILIZER COULD RESULT FROM THE ABILITY TO MODULATE NEUROPLASTIC MOLECULES, WHOSE EXPRESSION AND FUNCTION IS DETERIORATED IN DIFFERENT PSYCHIATRIC CONDITIONS.	2013	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                      
17  990  38 CHRONIC SOCIAL STRESS INDUCES DNA METHYLATION CHANGES AT AN EVOLUTIONARY CONSERVED INTERGENIC REGION IN CHROMOSOME X. CHRONIC STRESS RESULTING FROM PROLONGED EXPOSURE TO NEGATIVE LIFE EVENTS INCREASES THE RISK OF MOOD AND ANXIETY DISORDERS. ALTHOUGH CHRONIC STRESS CAN CHANGE GENE EXPRESSION RELEVANT FOR BEHAVIOR, MOLECULAR REGULATORS OF THIS CHANGE HAVE NOT BEEN FULLY DETERMINED. ONE PROCESS THAT COULD PLAY A ROLE IS DNA METHYLATION, AN EPIGENETIC PROCESS WHEREBY A METHYL GROUP IS ADDED ONTO NUCLEOTIDES, PREDOMINANTLY CYTOSINE IN THE CPG CONTEXT, AND WHICH CAN BE INDUCED BY CHRONIC STRESS. IT IS UNKNOWN TO WHAT EXTENT CHRONIC SOCIAL DEFEAT, A MODEL OF HUMAN SOCIAL STRESS, INFLUENCES DNA METHYLATION PATTERNS ACROSS THE GENOME. OUR STUDY ADDRESSED THIS QUESTION BY USING A TARGETED-CAPTURE APPROACH CALLED METHYL-SEQ TO INVESTIGATE DNA METHYLATION PATTERNS OF THE DENTATE GYRUS AT PUTATIVE REGULATORY REGIONS ACROSS THE MOUSE GENOME FROM MICE EXPOSED TO 14 DAYS OF SOCIAL DEFEAT. FINDINGS WERE REPLICATED IN INDEPENDENT COHORTS BY BISULFITE-PYROSEQUENCING. TWO DIFFERENTIALLY METHYLATED REGIONS (DMRS) WERE IDENTIFIED. ONE DMR WAS LOCATED AT INTRON 9 OF DROSHA, AND IT SHOWED REDUCED METHYLATION IN STRESSED MICE. THIS OBSERVATION REPLICATED IN ONE OF TWO INDEPENDENT COHORTS. A SECOND DMR WAS IDENTIFIED AT AN INTERGENIC REGION OF CHROMOSOME X, AND METHYLATION IN THIS REGION WAS INCREASED IN STRESSED MICE. THIS METHYLATION DIFFERENCE REPLICATED IN TWO INDEPENDENT COHORTS AND IN MAJOR DEPRESSIVE DISORDER (MDD) POSTMORTEM BRAINS. THESE RESULTS HIGHLIGHT A REGION NOT PREVIOUSLY KNOWN TO BE DIFFERENTIALLY METHYLATED BY CHRONIC SOCIAL DEFEAT STRESS AND WHICH MAY BE INVOLVED IN MDD.	2018	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                         
18 5579  33 ROLE OF MORPHINE, MIR-212/132 AND MU OPIOID RECEPTOR IN THE REGULATION OF BDNF IN ZEBRAFISH EMBRYOS. BACKGROUND: MORPHINE IS ONE OF THE FIRST-LINE THERAPIES FOR THE TREATMENT OF PAIN DESPITE ITS SECONDARY EFFECTS. IT MODIFIES THE EXPRESSION OF EPIGENETIC FACTORS LIKE MIRNAS. IN THE PRESENT STUDY, WE ANALYZED MIR-212 AND MIR-132 AND THEIR IMPLICATION IN MORPHINE EFFECTS IN THE ZEBRAFISH CENTRAL NERVOUS SYSTEM (CNS) THROUGH THE REGULATION OF BDNF EXPRESSION. METHODS: WE USED CONTROL AND KNOCK-DOWN ZEBRAFISH EMBRYOS TO ASSESS THE EFFECTS OF MORPHINE IN MIRNAS 212/132 AND MITOTIC OR APOPTOTIC CELLS BY QPCR, IMMUNOHISTOCHEMISTRY AND TUNEL ASSAY, RESPECTIVELY. BDNF AND TRKB WERE STUDIED BY WESTERN BLOT AND THROUGH A PRIMARY NEURON CULTURE. A LUCIFERASE ASSAY WAS PERFORMED TO CONFIRM THE BINDING OF MIRNAS 212/132 TO MECP2. RESULTS: MORPHINE EXPOSURE DECREASES MIR-212 BUT UPREGULATES MIR-132, AS WELLS AS BDNF AND TRKB, AND CHANGES THE LOCALIZATION OF PROLIFERATIVE CELLS. HOWEVER, BDNF EXPRESSION WAS DOWNREGULATED WHEN MIRNAS 212/132 AND OPRM1 WERE KNOCKED-DOWN. FURTHERMORE, WE PROVED THAT THESE MIRNAS INHIBIT MECP2 EXPRESSION BY BINDING TO ITS MRNA SEQUENCE. THE DESCRIBED EFFECTS WERE CORROBORATED IN A PRIMARY NEURON CULTURE FROM ZEBRAFISH EMBRYOS. CONCLUSIONS: WE PROPOSE A MECHANISM IN WHICH MORPHINE ALTERS THE LEVELS OF MIRNAS 212/132 INCREASING BDNF EXPRESSION THROUGH MECP2 INHIBITION. OPRM1 IS ALSO DIRECTLY INVOLVED IN THIS REGULATION. THE PRESENT WORK CONFIRMS A RELATIONSHIP BETWEEN THE OPIOID SYSTEM AND NEUROTROPHINS AND SHOWS A KEY ROLE OF MIR-212 AND MIR-132 ON MORPHINE EFFECTS THROUGH THE REGULATION OF BDNF PATHWAY. GENERAL SIGNIFICANCE: MIRNAS 212/132 ARE NOVEL REGULATORS OF MORPHINE EFFECTS ON CNS. OPRM1 CONTROLS THE NORMAL EXPRESSION OF BDNF.	2016	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                     
19 1086  40 COCAINE ADMINISTRATION AND ITS WITHDRAWAL ENHANCE THE EXPRESSION OF GENES ENCODING HISTONE-MODIFYING ENZYMES AND HISTONE ACETYLATION IN THE RAT PREFRONTAL CORTEX. CHRONIC EXPOSURE TO COCAINE, CRAVING, AND RELAPSE ARE ATTRIBUTED TO LONG-LASTING CHANGES IN GENE EXPRESSION ARISING THROUGH EPIGENETIC AND TRANSCRIPTIONAL MECHANISMS. ALTHOUGH SEVERAL BRAIN REGIONS ARE INVOLVED IN THESE PROCESSES, THE PREFRONTAL CORTEX SEEMS TO PLAY A CRUCIAL ROLE NOT ONLY IN MOTIVATION AND DECISION-MAKING BUT ALSO IN EXTINCTION AND SEEKING BEHAVIOR. IN THIS STUDY, WE APPLIED COCAINE SELF-ADMINISTRATION AND EXTINCTION TRAINING PROCEDURES IN RATS WITH A YOKED TRIAD TO DETERMINE DIFFERENTIALLY EXPRESSED GENES IN PREFRONTAL CORTEX. MICROARRAY ANALYSIS SHOWED SIGNIFICANT UPREGULATION OF SEVERAL GENES ENCODING HISTONE MODIFICATION ENZYMES DURING EARLY EXTINCTION TRAINING. SUBSEQUENT REAL-TIME PCR TESTING OF THESE GENES FOLLOWING COCAINE SELF-ADMINISTRATION OR EARLY (THIRD DAY) AND LATE (TENTH DAY) EXTINCTION REVEALED ELEVATED LEVELS OF THEIR TRANSCRIPTS. INTERESTINGLY, WE FOUND THE ENRICHMENT OF BRD1 MESSENGER RNA IN RATS SELF-ADMINISTERING COCAINE THAT LASTED UNTIL EXTINCTION TRAINING DURING COCAINE WITHDRAWAL WITH CONCOMITANT INCREASED ACETYLATION OF H3K9 AND H4K8. HOWEVER, DESPITE ELEVATED LEVELS OF METHYL- AND DEMETHYLTRANSFERASE-ENCODED TRANSCRIPTS, NO CHANGES IN GLOBAL DI- AND TRI-METHYLATION OF HISTONE H3 AT LYSINE 4, 9, 27, AND 79 WERE OBSERVED. SURPRISINGLY, AT THE END OF EXTINCTION TRAINING (10 DAYS OF COCAINE WITHDRAWAL), MOST OF THE ANALYZED GENES IN THE RATS ACTIVELY AND PASSIVELY ADMINISTERING COCAINE RETURNED TO THE CONTROL LEVEL. TOGETHER, THE ALTERATIONS IDENTIFIED IN THE RAT PREFRONTAL CORTEX MAY SUGGEST ENHANCED CHROMATIN REMODELING AND TRANSCRIPTIONAL ACTIVITY INDUCED BY EARLY COCAINE ABSTINENCE; HOWEVER, TO KNOW WHETHER THEY ARE BENEFICIAL OR NOT FOR THE EXTINCTION OF DRUG-SEEKING BEHAVIOR, FURTHER IN VIVO EVALUATION IS REQUIRED.	2017	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                  
20 6427  35 THE TRANSITION FROM ACUTE TO CHRONIC PAIN: DYNAMIC EPIGENETIC REPROGRAMMING OF THE MOUSE PREFRONTAL CORTEX UP TO 1 YEAR AFTER NERVE INJURY. CHRONIC PAIN IS ASSOCIATED WITH PERSISTENT STRUCTURAL AND FUNCTIONAL CHANGES THROUGHOUT THE NEUROAXIS, INCLUDING IN THE PREFRONTAL CORTEX (PFC). THE PFC IS IMPORTANT IN THE INTEGRATION OF SENSORY, COGNITIVE, AND EMOTIONAL INFORMATION AND IN CONDITIONED PAIN MODULATION. WE PREVIOUSLY REPORTED WIDESPREAD EPIGENETIC REPROGRAMMING IN THE PFC MANY MONTHS AFTER NERVE INJURY IN RODENTS. EPIGENETIC MODIFICATIONS, INCLUDING DNA METHYLATION, CAN DRIVE CHANGES IN GENE EXPRESSION WITHOUT MODIFYING DNA SEQUENCES. TO DATE, LITTLE IS KNOWN ABOUT EPIGENETIC DYSREGULATION AT THE ONSET OF ACUTE PAIN OR HOW IT PROGRESSES AS PAIN TRANSITIONS FROM ACUTE TO CHRONIC. WE HYPOTHESIZE THAT ACUTE PAIN AFTER INJURY RESULTS IN RAPID AND PERSISTENT EPIGENETIC REMODELLING IN THE PFC THAT EVOLVES AS PAIN BECOMES CHRONIC. WE FURTHER PROPOSE THAT UNDERSTANDING EPIGENETIC REMODELLING WILL PROVIDE INSIGHTS INTO THE MECHANISMS DRIVING PAIN-RELATED CHANGES IN THE BRAIN. EPIGENOME-WIDE ANALYSIS WAS PERFORMED IN THE MOUSE PFC 1 DAY, 2 WEEKS, 6 MONTHS, AND 1 YEAR AFTER PERIPHERAL INJURY USING THE SPARED NERVE INJURY IN MICE. SPARED NERVE INJURY RESULTED IN RAPID AND PERSISTENT CHANGES IN DNA METHYLATION, WITH ROBUST DIFFERENTIAL METHYLATION OBSERVED BETWEEN SPARED NERVE INJURY AND SHAM-OPERATED CONTROL MICE AT ALL TIME POINTS. HUNDREDS OF DIFFERENTIALLY METHYLATED GENES WERE IDENTIFIED, INCLUDING MANY WITH KNOWN FUNCTION IN PAIN. PATHWAY ANALYSIS REVEALED ENRICHMENT IN GENES RELATED TO STIMULUS RESPONSE AT EARLY TIME POINTS, IMMUNE FUNCTION AT LATER TIME POINTS, AND ACTIN AND CYTOSKELETAL REGULATION THROUGHOUT THE TIME COURSE. THESE RESULTS EMPHASIZE THE IMPORTANCE OF CONSIDERING PAIN CHRONICITY IN BOTH PAIN RESEARCH AND IN TREATMENT OPTIMIZATION.	2020