1 2013 158 EPIGENETIC BASIS OF THE DARK SIDE OF ALCOHOL ADDICTION. ALCOHOLISM IS A COMPLEX BRAIN DISEASE CHARACTERIZED BY THREE DISTINCT STAGES OF THE ADDICTION CYCLE THAT MANIFEST AS NEUROADAPTIVE CHANGES IN THE BRAIN. ONE SUCH STAGE OF THE ADDICTION CYCLE IS ALCOHOL WITHDRAWAL AND THE NEGATIVE AFFECTIVE STATES THAT PROMOTE DRINKING AND MAINTAIN ADDICTION. REPEATED ALCOHOL USE, GENETIC PREDISPOSITION TO ALCOHOLISM AND ANXIETY, AND ALCOHOL EXPOSURE DURING CRUCIAL DEVELOPMENTAL PERIODS ALL CONTRIBUTE TO THE DEVELOPMENT OF ALCOHOL-INDUCED WITHDRAWAL AND NEGATIVE AFFECTIVE SYMPTOMS. EPIGENETIC MODIFICATIONS WITHIN THE AMYGDALA HAVE PROVIDED A MOLECULAR BASIS OF THESE NEGATIVE AFFECTIVE SYMPTOMS, ALSO KNOWN AS THE DARK SIDE OF ADDICTION. HERE, WE PROPOSE THAT ALLOSTATIC CHANGE WITHIN THE EPIGENOME IN THE AMYGDALA IS A PRIME MECHANISM OF THE BIOLOGICAL BASIS OF NEGATIVE AFFECTIVE STATES RESULTING FROM, AND CONTRIBUTING TO, ALCOHOLISM. ACUTE ALCOHOL EXPOSURE PRODUCES AN ANXIOLYTIC RESPONSE WHICH IS ASSOCIATED WITH THE OPENING OF CHROMATIN DUE TO INCREASED HISTONE ACETYLATION, INCREASED CREB BINDING PROTEIN (CBP) LEVELS, AND HISTONE DEACETYLASE (HDAC) INHIBITION. AFTER CHRONIC ETHANOL EXPOSURE, THESE CHANGES RETURN TO BASELINE ALONG WITH ANXIETY-LIKE BEHAVIORS. HOWEVER, DURING WITHDRAWAL, HISTONE ACETYLATION DECREASES DUE TO INCREASED HDAC ACTIVITY AND DECREASED CBP LEVELS IN THE AMYGDALA CIRCUITRY LEADING TO THE DEVELOPMENT OF ANXIETY-LIKE BEHAVIORS. ADDITIONALLY, INNATELY HIGHER EXPRESSION OF THE HDAC2 ISOFORM LEADS TO A DEFICIT IN GLOBAL AND GENE-SPECIFIC HISTONE ACETYLATION IN THE AMYGDALA THAT IS ASSOCIATED WITH A DECREASE IN THE EXPRESSION OF SEVERAL SYNAPTIC PLASTICITY-ASSOCIATED GENES AND MAINTAINING HEIGHTENED ANXIETY-LIKE BEHAVIOR AND EXCESSIVE ALCOHOL INTAKE. ADOLESCENT ALCOHOL EXPOSURE ALSO LEADS TO HIGHER EXPRESSION OF HDAC2 AND A DEFICIT IN HISTONE ACETYLATION LEADING TO DECREASED EXPRESSION OF SYNAPTIC PLASTICITY-ASSOCIATED GENES AND HIGH ANXIETY AND DRINKING BEHAVIOR IN ADULTHOOD. ALL THESE STUDIES INDICATE THAT THE EPIGENOME CAN UNDERGO ALLOSTATIC REPROGRAMMING IN THE AMYGDALOID CIRCUITRY DURING VARIOUS STAGES OF ALCOHOL EXPOSURE. FURTHERMORE, OPENING THE CHROMATIN BY INHIBITING HDACS USING PHARMACOLOGICAL OR GENETIC MANIPULATIONS CAN LEAD TO THE ATTENUATION OF ANXIETY AS WELL AS ALCOHOL INTAKE. CHROMATIN REMODELING PROVIDES A CLEAR BIOLOGICAL BASIS FOR THE NEGATIVE AFFECTIVE STATES SEEN DURING ALCOHOL ADDICTION AND PRESENTS OPPORTUNITIES FOR NOVEL DRUG DEVELOPMENT AND TREATMENT OPTIONS. THIS ARTICLE IS PART OF THE SPECIAL ISSUE ENTITLED "ALCOHOLISM". 2017 2 2058 32 EPIGENETIC CONTROL OF GENE EXPRESSION IN THE ALCOHOLIC BRAIN. CHRONIC ALCOHOL EXPOSURE CAUSES WIDESPREAD CHANGES IN BRAIN GENE EXPRESSION IN HUMANS AND ANIMAL MODELS. MANY OF THESE CONTRIBUTE TO CELLULAR ADAPTATIONS THAT ULTIMATELY LEAD TO BEHAVIORAL TOLERANCE AND ALCOHOL DEPENDENCE. THERE IS AN EMERGING APPRECIATION FOR THE ROLE OF EPIGENETIC PROCESSES IN ALCOHOL-INDUCED CHANGES IN BRAIN GENE EXPRESSION AND BEHAVIOR. FOR EXAMPLE, CHRONIC ALCOHOL EXPOSURE PRODUCES CHANGES IN DNA AND HISTONE METHYLATION, HISTONE ACETYLATION, AND MICRORNA EXPRESSION THAT AFFECT EXPRESSION OF MULTIPLE GENES IN VARIOUS TYPES OF BRAIN CELLS (I.E., NEURONS AND GLIA) AND CONTRIBUTE TO BRAIN PATHOLOGY AND BRAIN PLASTICITY ASSOCIATED WITH ALCOHOL ABUSE AND DEPENDENCE. DRUGS TARGETING THE EPIGENETIC "MASTER REGULATORS" ARE EMERGING AS POTENTIAL THERAPEUTICS FOR NEURODEGENERATIVE DISORDERS AND DRUG ADDICTION. 2013 3 1981 35 EPIGENETIC ALTERATIONS IN DNA AND HISTONE MODIFICATIONS CAUSED BY DEPRESSION AND ANTIDEPRESSANT DRUGS: LESSONS FROM THE RODENT MODELS. EPIGENETIC MODIFICATIONS REGULATE CHROMATIN FOLDING AND FUNCTION. EPIGENETIC MECHANISMS REGULATE TRANSCRIPTION MEDIATING EFFECTS OF VARIOUS STIMULI ON GENE EXPRESSION. THESE MECHANISMS ARE INVOLVED IN TRANSCRIPTIONAL CONTROL IN VARIOUS PHYSIOLOGICAL AND PATHOLOGICAL CONDITIONS INCLUDING NEUROPSYCHIATRIC DISORDERS AND BEHAVIORAL ABNORMALITIES SUCH AS DEPRESSION. IN RODENTS, EXPOSURE TO CHRONIC SOCIAL STRESS WAS SHOWN TO INDUCE BEHAVIORAL IMPAIRMENTS AND MEMORY/LEARNING DEFICITS THAT RESEMBLE DEPRESSIVE-LIKE PHENOTYPE IN HUMANS. THE RODENT MODELS OF CHRONIC STRESS WERE WIDELY USED TO STUDY MOLECULAR MECHANISMS OF DEPRESSION. IN THESE MODELS, EARLY EXPOSURE TO CHRONIC STRESS SUCH AS PRENATAL OR POSTNATAL STRESS INDUCES LONG-TERM HYPERACTIVE STRESS RESPONSES, BEHAVIORAL ABNORMALITIES, AND FUNCTIONAL IMPAIRMENTS IN BRAIN FUNCTION THAT PERSIST IN ADULTHOOD. FURTHERMORE, THESE ALTERATIONS CAN BE TRANSMITTED TO OFFSPRING OF CHRONICALLY STRESSED ANIMALS ACROSS SEVERAL GENERATIONS. MOLECULAR STUDIES IN ANIMAL MODELS SHOWED THAT CHRONIC STRESS INDUCES STABLE EPIGENETIC CHANGES IN SPECIFIC BRAIN REGIONS, PRIMARILY IN THE LIMBIC SYSTEM. THESE CHANGES LEAD TO LONG-LASTING ABNORMALITIES IN BEHAVIOR THAT PERSIST IN ADULTHOOD AND CAN BE TRANSMITTED TO OFFSPRING. TREATMENT WITH EPIGENETICALLY ACTIVE ANTIDEPRESSANTS DISRUPTS THE ABNORMAL STRESS-INDUCED EPIGENETIC PROGRAMMING AND PROVIDES EPIGENETIC PATTERNS THAT RESEMBLE EPIGENETIC BACKGROUND OF STRESS RESILIENT INDIVIDUALS. 2017 4 6094 35 THE EFFECTS OF MATERNAL AND POSTNATAL DIETARY METHYL NUTRIENTS ON EPIGENETIC CHANGES THAT LEAD TO NON-COMMUNICABLE DISEASES IN ADULTHOOD. THE RISK FOR NON-COMMUNICABLE DISEASES IN ADULTHOOD CAN BE PROGRAMMED BY EARLY NUTRITION. THIS PROGRAMMING IS MEDIATED BY CHANGES IN EXPRESSION OF KEY GENES IN VARIOUS METABOLIC PATHWAYS DURING DEVELOPMENT, WHICH PERSIST INTO ADULTHOOD. THESE DEVELOPMENTAL MODIFICATIONS OF GENES ARE DUE TO EPIGENETIC ALTERATIONS IN DNA METHYLATION PATTERNS. RECENT STUDIES HAVE DEMONSTRATED THAT DNA METHYLATION CAN BE AFFECTED BY MATERNAL OR EARLY POSTNATAL DIETS. BECAUSE METHYL GROUPS FOR METHYLATION REACTIONS COME FROM METHIONINE CYCLE NUTRIENTS (I.E., METHIONINE, CHOLINE, BETAINE, FOLATE), DEFICIENCY OR SUPPLEMENTATION OF THESE METHYL NUTRIENTS CAN DIRECTLY CHANGE EPIGENETIC REGULATION OF GENES PERMANENTLY. ALTHOUGH MANY STUDIES HAVE DESCRIBED THE EARLY PROGRAMMING OF ADULT DISEASES BY MATERNAL AND INFANT NUTRITION, THIS REVIEW DISCUSSES STUDIES THAT HAVE ASSOCIATED EARLY DIETARY METHYL NUTRIENT MANIPULATION WITH DIRECT EFFECTS ON EPIGENETIC PATTERNS THAT COULD LEAD TO CHRONIC DISEASES IN ADULTHOOD. THE MATERNAL SUPPLY OF METHYL NUTRIENTS DURING GESTATION AND LACTATION CAN ALTER EPIGENETICS, BUT PROGRAMMING EFFECTS VARY DEPENDING ON THE TIMING OF DIETARY INTERVENTION, THE TYPE OF METHYL NUTRIENT MANIPULATED, AND THE TISSUE RESPONSIBLE FOR THE PHENOTYPE. MOREOVER, THE POSTNATAL MANIPULATION OF METHYL NUTRIENTS CAN PROGRAM EPIGENETICS, BUT MORE RESEARCH IS NEEDED ON WHETHER THIS APPROACH CAN RESCUE MATERNALLY PROGRAMMED OFFSPRING. 2020 5 3398 38 HOW ALCOHOL DRINKING AFFECTS OUR GENES: AN EPIGENETIC POINT OF VIEW. THIS WORK HIGHLIGHTS RECENT STUDIES IN EPIGENETIC MECHANISMS THAT PLAY A ROLE IN ALCOHOLISM, WHICH IS A COMPLEX MULTIFACTORIAL DISORDER. THERE IS A LARGE BODY OF EVIDENCE SHOWING THAT ALCOHOL CAN MODIFY GENE EXPRESSION THROUGH EPIGENETIC PROCESSES, NAMELY DNA METHYLATION AND NUCLEOSOMAL REMODELING VIA HISTONE MODIFICATIONS. IN THAT REGARD, CHRONIC EXPOSURE TO ETHANOL MODIFIES DNA AND HISTONE METHYLATION, HISTONE ACETYLATION, AND MICRORNA EXPRESSION. THE ALCOHOL-MEDIATED CHROMATIN REMODELING IN THE BRAIN PROMOTES THE TRANSITION FROM USE TO ABUSE AND ADDICTION. UNRAVELLING THE MULTIPLEX PATTERN OF MOLECULAR MODIFICATIONS INDUCED BY ETHANOL COULD SUPPORT THE DEVELOPMENT OF NEW THERAPIES FOR ALCOHOLISM AND DRUG ADDICTION TARGETING EPIGENETIC PROCESSES. 2019 6 2445 30 EPIGENETIC STATUS OF GDNF IN THE VENTRAL STRIATUM DETERMINES SUSCEPTIBILITY AND ADAPTATION TO DAILY STRESSFUL EVENTS. STRESSFUL EVENTS DURING ADULTHOOD ARE POTENT ADVERSE ENVIRONMENTAL FACTORS THAT CAN PREDISPOSE INDIVIDUALS TO PSYCHIATRIC DISORDERS, INCLUDING DEPRESSION; HOWEVER, MANY INDIVIDUALS EXPOSED TO STRESSFUL EVENTS CAN ADAPT AND FUNCTION NORMALLY. WHILE STRESS VULNERABILITY MAY INFLUENCE DEPRESSION, THE MOLECULAR MECHANISMS UNDERLYING THE SUSCEPTIBILITY AND ADAPTATION TO CHRONIC STRESS WITHIN THE BRAIN ARE POORLY UNDERSTOOD. IN THIS STUDY, TWO GENETICALLY DISTINCT MOUSE STRAINS THAT EXHIBIT DIFFERENT BEHAVIORAL RESPONSES TO CHRONIC STRESS WERE USED TO DEMONSTRATE HOW THE DIFFERENTIAL EPIGENETIC STATUS OF THE GLIAL CELL-DERIVED NEUROTROPHIC FACTOR (GDNF) GENE IN THE VENTRAL STRIATUM MODULATES SUSCEPTIBILITY AND ADAPTATION TO CHRONIC STRESS. OUR RESULTS SUGGEST THAT THE HISTONE MODIFICATIONS AND DNA METHYLATION OF THE GDNF PROMOTER HAVE CRUCIAL ROLES IN THE CONTROL OF BEHAVIORAL RESPONSES TO CHRONIC STRESS. OUR DATA PROVIDE INSIGHTS INTO THESE MECHANISMS, SUGGESTING THAT EPIGENETIC MODIFICATIONS OF GDNF, ALONG WITH GENETIC AND ENVIRONMENTAL FACTORS, CONTRIBUTE TO BEHAVIORAL RESPONSES TO STRESS. 2011 7 2606 58 EPIGENETICS-BEYOND THE GENOME IN ALCOHOLISM. GENETIC AND ENVIRONMENTAL FACTORS PLAY A ROLE IN THE DEVELOPMENT OF ALCOHOLISM. WHOLE-GENOME EXPRESSION PROFILING HAS HIGHLIGHTED THE IMPORTANCE OF SEVERAL GENES THAT MAY CONTRIBUTE TO ALCOHOL ABUSE DISORDERS. IN ADDITION, MORE RECENT FINDINGS HAVE ADDED YET ANOTHER LAYER OF COMPLEXITY TO THE OVERALL MOLECULAR MECHANISMS INVOLVED IN A PREDISPOSITION TO ALCOHOLISM AND ADDICTION BY DEMONSTRATING THAT PROCESSES RELATED TO GENETIC FACTORS THAT DO NOT MANIFEST AS DNA SEQUENCE CHANGES (I.E., EPIGENETIC PROCESSES) PLAY A ROLE. BOTH ACUTE AND CHRONIC ETHANOL EXPOSURE CAN ALTER GENE EXPRESSION LEVELS IN SPECIFIC NEURONAL CIRCUITS THAT GOVERN THE BEHAVIORAL CONSEQUENCES RELATED TO TOLERANCE AND DEPENDENCE. THE UNREMITTING CYCLE OF ALCOHOL CONSUMPTION OFTEN INCLUDES SATIATION AND SELF-MEDICATION WITH ALCOHOL, FOLLOWED BY EXCRUCIATING WITHDRAWAL SYMPTOMS AND THE RESULTANT RELAPSE, WHICH REFLECTS BOTH THE POSITIVE AND NEGATIVE AFFECTIVE STATES OF ALCOHOL ADDICTION. RECENT STUDIES HAVE INDICATED THAT BEHAVIORAL CHANGES INDUCED BY ACUTE AND CHRONIC ETHANOL EXPOSURE MAY INVOLVE CHROMATIN REMODELING RESULTING FROM COVALENT HISTONE MODIFICATIONS AND DNA METHYLATION IN THE NEURONAL CIRCUITS INVOLVING A BRAIN REGION CALLED THE AMYGDALA. THESE FINDINGS HAVE HELPED IDENTIFY ENZYMES INVOLVED IN EPIGENETIC MECHANISMS, SUCH AS THE HISTONE DEACETYLASE, HISTONE ACETYLTRANSFERASE, AND DNA METHYLTRANSFERASE ENZYMES, AS NOVEL THERAPEUTIC TARGETS FOR THE DEVELOPMENT OF FUTURE PHARMACOTHERAPIES FOR THE TREATMENT OF ALCOHOLISM. 2012 8 3952 28 LOCUS-SPECIFIC EPIGENETIC REMODELING CONTROLS ADDICTION- AND DEPRESSION-RELATED BEHAVIORS. CHRONIC EXPOSURE TO DRUGS OF ABUSE OR STRESS REGULATES TRANSCRIPTION FACTORS, CHROMATIN-MODIFYING ENZYMES AND HISTONE POST-TRANSLATIONAL MODIFICATIONS IN DISCRETE BRAIN REGIONS. GIVEN THE PROMISCUITY OF THE ENZYMES INVOLVED, IT HAS NOT YET BEEN POSSIBLE TO OBTAIN DIRECT CAUSAL EVIDENCE TO IMPLICATE THE REGULATION OF TRANSCRIPTION AND CONSEQUENT BEHAVIORAL PLASTICITY BY CHROMATIN REMODELING THAT OCCURS AT A SINGLE GENE. WE INVESTIGATED THE MECHANISM LINKING CHROMATIN DYNAMICS TO NEUROBIOLOGICAL PHENOMENA BY APPLYING ENGINEERED TRANSCRIPTION FACTORS TO SELECTIVELY MODIFY CHROMATIN AT A SPECIFIC MOUSE GENE IN VIVO. WE FOUND THAT HISTONE METHYLATION OR ACETYLATION AT THE FOSB LOCUS IN NUCLEUS ACCUMBENS, A BRAIN REWARD REGION, WAS SUFFICIENT TO CONTROL DRUG- AND STRESS-EVOKED TRANSCRIPTIONAL AND BEHAVIORAL RESPONSES VIA INTERACTIONS WITH THE ENDOGENOUS TRANSCRIPTIONAL MACHINERY. THIS APPROACH ALLOWED US TO RELATE THE EPIGENETIC LANDSCAPE AT A GIVEN GENE DIRECTLY TO REGULATION OF ITS EXPRESSION AND TO ITS SUBSEQUENT EFFECTS ON REWARD BEHAVIOR. 2014 9 2513 34 EPIGENETICS AND PSYCHOSTIMULANT ADDICTION. CHRONIC DRUG EXPOSURE ALTERS GENE EXPRESSION IN THE BRAIN AND PRODUCES LONG-TERM CHANGES IN NEURAL NETWORKS THAT UNDERLIE COMPULSIVE DRUG TAKING AND SEEKING. EXACTLY HOW DRUG-INDUCED CHANGES IN SYNAPTIC PLASTICITY AND SUBSEQUENT GENE EXPRESSION ARE TRANSLATED INTO PERSISTENT NEUROADAPTATIONS REMAINS UNCLEAR. EMERGING EVIDENCE SUGGESTS THAT COMPLEX DRUG-INDUCED NEUROADAPTATIONS IN THE BRAIN ARE MEDIATED BY HIGHLY SYNCHRONIZED AND DYNAMIC PATTERNS OF GENE REGULATION. RECENTLY, IT HAS BECOME CLEAR THAT EPIGENETIC MECHANISMS CONTRIBUTE TO DRUG-INDUCED STRUCTURAL, SYNAPTIC, AND BEHAVIORAL PLASTICITY BY REGULATING EXPRESSION OF GENE NETWORKS. HERE WE REVIEW HOW ALTERATIONS IN HISTONE MODIFICATIONS, DNA METHYLATION, AND MICRORNAS REGULATE GENE EXPRESSION AND CONTRIBUTE TO PSYCHOSTIMULANT ADDICTION WITH A FOCUS ON THE EPIGENETIC MECHANISMS THAT REGULATE BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) EXPRESSION FOLLOWING CHRONIC COCAINE EXPOSURE. IDENTIFYING EPIGENETIC SIGNATURES THAT DEFINE PSYCHOSTIMULANT ADDICTION MAY LEAD TO NOVEL, EFFICACIOUS TREATMENTS FOR DRUG CRAVING AND RELAPSE. 2013 10 110 33 A ROLE FOR ACTIVITY-DEPENDENT EPIGENETICS IN THE DEVELOPMENT AND TREATMENT OF MAJOR DEPRESSIVE DISORDER. CHRONIC STRESSORS, DURING DEVELOPMENTAL SENSITIVE PERIODS AND BEYOND, CONTRIBUTE TO THE RISK OF DEVELOPING PSYCHIATRIC CONDITIONS, INCLUDING MAJOR DEPRESSIVE DISORDER (MDD). EPIGENETIC MECHANISMS INCLUDING DNA METHYLATION AND HISTONE MODIFICATIONS, AT KEY STRESS RESPONSE AND NEUROTROPHIN GENES, ARE INCREASINGLY IMPLICATED IN MEDIATING THIS RISK. ALTHOUGH THE EXACT MECHANISMS THROUGH WHICH STRESSFUL ENVIRONMENTAL STIMULI ALTER THE EPIGENOME ARE STILL UNCLEAR, RESEARCH FROM THE LEARNING AND MEMORY FIELDS INDICATES THAT EPIGENOMIC MARKS CAN BE ALTERED, AT LEAST IN PART, THROUGH CALCIUM-DEPENDENT SIGNALING CASCADES IN DIRECT RESPONSE TO NEURONAL ACTIVITY. IN THIS REVIEW, WE HIGHLIGHT KEY FINDINGS FROM THE STRESS, MDD, AND LEARNING AND MEMORY FIELDS TO PROPOSE A MODEL WHERE STRESS REGULATES DOWNSTREAM CELLULAR FUNCTIONING THROUGH ACTIVITY-DEPENDENT EPIGENETIC CHANGES. FURTHERMORE, WE SUGGEST THAT BOTH TYPICAL AND NOVEL ANTIDEPRESSANT TREATMENTS MAY EXERT POSITIVE INFLUENCE THROUGH SIMILAR, ACTIVITY-DEPENDENT PATHWAYS. 2018 11 4011 31 LOW PATERNAL DIETARY FOLATE ALTERS THE MOUSE SPERM EPIGENOME AND IS ASSOCIATED WITH NEGATIVE PREGNANCY OUTCOMES. EPIDEMIOLOGICAL STUDIES SUGGEST THAT A FATHER'S DIET CAN INFLUENCE OFFSPRING HEALTH. A PROPOSED MECHANISM FOR PATERNAL TRANSMISSION OF ENVIRONMENTAL INFORMATION IS VIA THE SPERM EPIGENOME. THE EPIGENOME INCLUDES HERITABLE INFORMATION SUCH AS DNA METHYLATION. WE HYPOTHESIZE THAT THE DIETARY SUPPLY OF METHYL DONORS WILL ALTER EPIGENETIC REPROGRAMMING IN SPERM. HERE WE FEED MALE MICE EITHER A FOLATE-DEFICIENT OR FOLATE-SUFFICIENT DIET THROUGHOUT LIFE. PATERNAL FOLATE DEFICIENCY IS ASSOCIATED WITH INCREASED BIRTH DEFECTS IN THE OFFSPRING, WHICH INCLUDE CRANIOFACIAL AND MUSCULOSKELETAL MALFORMATIONS. GENOME-WIDE DNA METHYLATION ANALYSIS AND THE SUBSEQUENT FUNCTIONAL ANALYSIS IDENTIFY DIFFERENTIAL METHYLATION IN SPERM OF GENES IMPLICATED IN DEVELOPMENT, CHRONIC DISEASES SUCH AS CANCER, DIABETES, AUTISM AND SCHIZOPHRENIA. WHILE >300 GENES ARE DIFFERENTIALLY EXPRESSED IN OFFSPRING PLACENTA, ONLY TWO CORRESPOND TO GENES WITH DIFFERENTIAL METHYLATION IN SPERM. THIS MODEL SUGGESTS EPIGENETIC TRANSMISSION MAY INVOLVE SPERM HISTONE H3 METHYLATION OR DNA METHYLATION AND THAT ADEQUATE PATERNAL DIETARY FOLATE IS ESSENTIAL FOR OFFSPRING HEALTH. 2013 12 1396 43 DIET INDUCED EPIGENETIC CHANGES AND THEIR IMPLICATIONS FOR HEALTH. DIETARY EXPOSURES CAN HAVE CONSEQUENCES FOR HEALTH YEARS OR DECADES LATER AND THIS RAISES QUESTIONS ABOUT THE MECHANISMS THROUGH WHICH SUCH EXPOSURES ARE 'REMEMBERED' AND HOW THEY RESULT IN ALTERED DISEASE RISK. THERE IS GROWING EVIDENCE THAT EPIGENETIC MECHANISMS MAY MEDIATE THE EFFECTS OF NUTRITION AND MAY BE CAUSAL FOR THE DEVELOPMENT OF COMMON COMPLEX (OR CHRONIC) DISEASES. EPIGENETICS ENCOMPASSES CHANGES TO MARKS ON THE GENOME (AND ASSOCIATED CELLULAR MACHINERY) THAT ARE COPIED FROM ONE CELL GENERATION TO THE NEXT, WHICH MAY ALTER GENE EXPRESSION, BUT WHICH DO NOT INVOLVE CHANGES IN THE PRIMARY DNA SEQUENCE. THESE INCLUDE THREE DISTINCT, BUT CLOSELY INTER-ACTING, MECHANISMS INCLUDING DNA METHYLATION, HISTONE MODIFICATIONS AND NON-CODING MICRORNAS (MIRNA) WHICH, TOGETHER, ARE RESPONSIBLE FOR REGULATING GENE EXPRESSION NOT ONLY DURING CELLULAR DIFFERENTIATION IN EMBRYONIC AND FOETAL DEVELOPMENT BUT ALSO THROUGHOUT THE LIFE-COURSE. THIS REVIEW SUMMARIZES THE GROWING EVIDENCE THAT NUMEROUS DIETARY FACTORS, INCLUDING MICRONUTRIENTS AND NON-NUTRIENT DIETARY COMPONENTS SUCH AS GENISTEIN AND POLYPHENOLS, CAN MODIFY EPIGENETIC MARKS. IN SOME CASES, FOR EXAMPLE, EFFECTS OF ALTERED DIETARY SUPPLY OF METHYL DONORS ON DNA METHYLATION, THERE ARE PLAUSIBLE EXPLANATIONS FOR THE OBSERVED EPIGENETIC CHANGES, BUT TO A LARGE EXTENT, THE MECHANISMS RESPONSIBLE FOR DIET-EPIGENOME-HEALTH RELATIONSHIPS REMAIN TO BE DISCOVERED. IN ADDITION, RELATIVELY LITTLE IS KNOWN ABOUT WHICH EPIGENOMIC MARKS ARE MOST LABILE IN RESPONSE TO DIETARY EXPOSURES. GIVEN THE PLASTICITY OF EPIGENETIC MARKS AND THEIR RESPONSIVENESS TO DIETARY FACTORS, THERE IS POTENTIAL FOR THE DEVELOPMENT OF EPIGENETIC MARKS AS BIOMARKERS OF HEALTH FOR USE IN INTERVENTION STUDIES. 2011 13 4642 46 NEURONAL PLASTICITY: A LINK BETWEEN STRESS AND MOOD DISORDERS. ALTHOUGH STRESS REPRESENTS THE MAJOR ENVIRONMENTAL ELEMENT OF SUSCEPTIBILITY FOR MOOD DISORDERS, THE RELATIONSHIP BETWEEN STRESS AND DISEASE REMAINS TO BE FULLY ESTABLISHED. IN THE PRESENT ARTICLE WE REVIEW THE EVIDENCE IN SUPPORT FOR A ROLE OF NEURONAL PLASTICITY, AND IN PARTICULAR OF NEUROTROPHIC FACTORS. EVEN THOUGH DECREASED LEVELS OF NOREPINEPHRINE AND SEROTONIN MAY UNDERLIE DEPRESSIVE SYMPTOMS, COMPELLING EVIDENCE NOW SUGGESTS THAT MOOD DISORDERS ARE CHARACTERIZED BY REDUCED NEURONAL PLASTICITY, WHICH CAN BE BROUGHT ABOUT BY EXPOSURE TO STRESS AT DIFFERENT STAGES OF LIFE. INDEED THE EXPRESSION OF NEUROTROPHIC MOLECULES, SUCH AS THE NEUROTROPHIN BDNF, IS REDUCED IN DEPRESSED SUBJECTS AS WELL AS IN EXPERIMENTAL ANIMALS EXPOSED TO ADVERSE EXPERIENCE AT EARLY STAGES OF LIFE OR AT ADULTHOOD. THESE CHANGES SHOW AN ANATOMICAL SPECIFICITY AND MIGHT BE SUSTAINED BY EPIGENETIC MECHANISMS. PHARMACOLOGICAL INTERVENTION MAY NORMALIZE SUCH DEFECTS AND IMPROVE NEURONAL FUNCTION THROUGH THE MODULATION OF THE SAME FACTORS THAT ARE DEFECTIVE IN DEPRESSION. SEVERAL STUDIES HAVE DEMONSTRATED THAT CHRONIC, BUT NOT ACUTE, ANTIDEPRESSANT TREATMENT INCREASES THE EXPRESSION OF BDNF AND MAY ENHANCE ITS LOCALIZATION AT SYNAPTIC LEVEL. ANTIDEPRESSANT TREATMENT CAN NORMALIZE DEFICITS IN NEUROTROPHIN EXPRESSION PRODUCED BY CHRONIC STRESS PARADIGMS, BUT MAY ALSO ALTER THE MODULATION OF BDNF UNDER ACUTE STRESSFUL CONDITIONS. IN SUMMARY, THERE IS GOOD AGREEMENT IN CONSIDERING NEURONAL PLASTICITY, AND THE EXPRESSION OF KEY PROTEINS SUCH AS THE NEUROTROPHIN BDNF, AS A CENTRAL PLAYER FOR THE EFFECTS OF STRESS ON BRAIN FUNCTION AND ITS IMPLICATION FOR PSYCHOPATHOLOGY. ACCORDINGLY, EFFECTIVE TREATMENTS SHOULD NOT LIMIT THEIR EFFECTS TO THE CONTROL OF NEUROTRANSMITTER AND HORMONAL DYSFUNCTIONS, BUT SHOULD BE ABLE TO NORMALIZE DEFECTIVE MECHANISMS THAT SUSTAIN THE IMPAIRMENT OF NEURONAL PLASTICITY. 2009 14 6063 29 THE DEVELOPMENTAL ENVIRONMENT, EPIGENETIC BIOMARKERS AND LONG-TERM HEALTH. EVIDENCE FROM BOTH HUMAN AND ANIMAL STUDIES HAS SHOWN THAT THE PRENATAL AND EARLY POSTNATAL ENVIRONMENTS INFLUENCE SUSCEPTIBILITY TO CHRONIC DISEASE IN LATER LIFE AND SUGGESTS THAT EPIGENETIC PROCESSES ARE AN IMPORTANT MECHANISM BY WHICH THE ENVIRONMENT ALTERS LONG-TERM DISEASE RISK. EPIGENETIC PROCESSES, INCLUDING DNA METHYLATION, HISTONE MODIFICATION AND NON-CODING RNAS, PLAY A CENTRAL ROLE IN REGULATING GENE EXPRESSION. THE EPIGENOME IS HIGHLY SENSITIVE TO ENVIRONMENTAL FACTORS IN EARLY LIFE, SUCH AS NUTRITION, STRESS, ENDOCRINE DISRUPTION AND POLLUTION, AND CHANGES IN THE EPIGENOME CAN INDUCE LONG-TERM CHANGES IN GENE EXPRESSION AND PHENOTYPE. IN THIS REVIEW WE FOCUS ON HOW THE EARLY LIFE NUTRITIONAL ENVIRONMENT CAN ALTER THE EPIGENOME LEADING TO AN ALTERED SUSCEPTIBILITY TO DISEASE IN LATER LIFE. 2015 15 313 37 ALCOHOL METABOLISM AND EPIGENETICS CHANGES. METABOLITES, INCLUDING THOSE GENERATED DURING ETHANOL METABOLISM, CAN IMPACT DISEASE STATES BY BINDING TO TRANSCRIPTION FACTORS AND/OR MODIFYING CHROMATIN STRUCTURE, THEREBY ALTERING GENE EXPRESSION PATTERNS. FOR EXAMPLE, THE ACTIVITIES OF ENZYMES INVOLVED IN EPIGENETIC MODIFICATIONS SUCH AS DNA AND HISTONE METHYLATION AND HISTONE ACETYLATION, ARE INFLUENCED BY THE LEVELS OF METABOLITES SUCH AS NICOTINAMIDE ADENINE DINUCLEOTIDE (NAD), ADENOSINE TRIPHOSPHATE (ATP), AND S-ADENOSYLMETHIONINE (SAM). CHRONIC ALCOHOL CONSUMPTION LEADS TO SIGNIFICANT REDUCTIONS IN SAM LEVELS, THEREBY CONTRIBUTING TO DNA HYPOMETHYLATION. SIMILARLY, ETHANOL METABOLISM ALTERS THE RATIO OF NAD+ TO REDUCED NAD (NADH) AND PROMOTES THE FORMATION OF REACTIVE OXYGEN SPECIES AND ACETATE, ALL OF WHICH IMPACT EPIGENETIC REGULATORY MECHANISMS. IN ADDITION TO ALTERED CARBOHYDRATE METABOLISM, INDUCTION OF CELL DEATH, AND CHANGES IN MITOCHONDRIAL PERMEABILITY TRANSITION, THESE METABOLISM-RELATED CHANGES CAN LEAD TO MODULATION OF EPIGENETIC REGULATION OF GENE EXPRESSION. UNDERSTANDING THE NATURE OF THESE EPIGENETIC CHANGES WILL HELP RESEARCHERS DESIGN NOVEL MEDICATIONS TO TREAT OR AT LEAST AMELIORATE ALCOHOL-INDUCED ORGAN DAMAGE. 2013 16 860 38 CHROMATIN MODIFICATIONS DURING REPAIR OF ENVIRONMENTAL EXPOSURE-INDUCED DNA DAMAGE: A POTENTIAL MECHANISM FOR STABLE EPIGENETIC ALTERATIONS. EXPOSURES TO ENVIRONMENTAL TOXICANTS AND TOXINS CAUSE EPIGENETIC CHANGES THAT LIKELY PLAY A ROLE IN THE DEVELOPMENT OF DISEASES ASSOCIATED WITH EXPOSURE. THE MECHANISM BEHIND THESE EXPOSURE-INDUCED EPIGENETIC CHANGES IS CURRENTLY UNKNOWN. ONE COMMONALITY BETWEEN MOST ENVIRONMENTAL EXPOSURES IS THAT THEY CAUSE DNA DAMAGE EITHER DIRECTLY OR THROUGH CAUSING AN INCREASE IN REACTIVE OXYGEN SPECIES, WHICH CAN DAMAGE DNA. LIKE TRANSCRIPTION, DNA DAMAGE REPAIR MUST OCCUR IN THE CONTEXT OF CHROMATIN REQUIRING BOTH HISTONE MODIFICATIONS AND ATP-DEPENDENT CHROMATIN REMODELING. THESE CHROMATIN CHANGES AID IN DNA DAMAGE ACCESSIBILITY AND SIGNALING. SEVERAL PROTEINS AND COMPLEXES INVOLVED IN EPIGENETIC SILENCING DURING BOTH DEVELOPMENT AND CANCER HAVE BEEN FOUND TO BE LOCALIZED TO SITES OF DNA DAMAGE. THE CHROMATIN-BASED RESPONSE TO DNA DAMAGE IS CONSIDERED A TRANSIENT EVENT, WITH CHROMATIN BEING RESTORED TO NORMAL AS DNA DAMAGE REPAIR IS COMPLETED. HOWEVER, IN INDIVIDUALS CHRONICALLY EXPOSED TO ENVIRONMENTAL TOXICANTS OR WITH CHRONIC INFLAMMATORY DISEASE, REPEATED DNA DAMAGE-INDUCED CHROMATIN REARRANGEMENT MAY ULTIMATELY LEAD TO PERMANENT EPIGENETIC ALTERATIONS. UNDERSTANDING THE MECHANISM BEHIND EXPOSURE-INDUCED EPIGENETIC CHANGES WILL ALLOW US TO DEVELOP STRATEGIES TO PREVENT OR REVERSE THESE CHANGES. THIS REVIEW FOCUSES ON EPIGENETIC CHANGES AND DNA DAMAGE INDUCED BY ENVIRONMENTAL EXPOSURES, THE CHROMATIN CHANGES THAT OCCUR AROUND SITES OF DNA DAMAGE, AND HOW THESE TRANSIENT CHROMATIN CHANGES MAY LEAD TO HERITABLE EPIGENETIC ALTERATIONS AT SITES OF CHRONIC EXPOSURE. 2014 17 242 42 ADOLESCENT CANNABINOID EXPOSURE MODULATES THE VULNERABILITY TO COCAINE-INDUCED CONDITIONED PLACE PREFERENCE AND DNMT3A EXPRESSION IN THE PREFRONTAL CORTEX IN SWISS MICE. RATIONALE: CANNABIS SATIVA IS THE MOST WIDELY USED DRUG BY ADOLESCENTS GLOBALLY. THE RECREATIONAL USE OF SYNTHETIC CANNABINOIDS BY TEENAGERS HAS ALSO GROWN IN RECENT YEARS. DESPITE THE WRONG PERCEPTION THAT EXPOSURE TO THESE DRUGS DOES NOT CAUSE HARM, REPEATED EXPOSURE TO CANNABINOIDS AT EARLY STAGES OF LIFE COMPROMISES IMPORTANT MATURATION PROCESSES AND BRAIN DEVELOPMENT. CHRONIC EARLY CANNABINOID USE HAS BEEN RELATED TO A HIGHER RISK OF PSYCHIATRIC OUTCOMES, INCLUDING COCAINE ADDICTION. EVIDENCE SUGGESTS THAT EXPOSURE TO NATURAL AND SYNTHETIC CANNABINOIDS DURING ADOLESCENCE MODIFIES MOLECULAR AND BEHAVIORAL EFFECTS OF COCAINE IN ADULTHOOD. RESPONSES TO COCAINE ARE REGULATED BY EPIGENETIC MECHANISMS, SUCH AS DNA METHYLATION, IN THE BRAIN'S REWARD REGIONS. HOWEVER, THE INVOLVEMENT OF THESE PROCESSES IN MODULATION OF THE VULNERABILITY TO THE EFFECTS OF COCAINE INDUCED BY PRIOR EXPOSURE TO CANNABINOIDS REMAINS POORLY UNDERSTOOD. OBJECTIVES: INVESTIGATE WHETHER EXPOSURE TO THE SYNTHETIC CANNABINOID WIN55,212-2 DURING ADOLESCENCE MODULATES ANXIETY- AND DEPRESSION-LIKE BEHAVIOR, MEMORY, AND COCAINE REWARD IN ADULT MICE. WE ALSO EVALUATED WHETHER EXPOSURE TO CANNABINOIDS DURING ADOLESCENCE MODULATES THE EXPRESSION OF ENZYMES THAT ARE INVOLVED IN DNA METHYLATION. RESULTS: EXPOSURE TO WIN55,212-2 DURING ADOLESCENCE DID NOT ALTER ANXIETY- OR DEPRESSIVE-LIKE BEHAVIOR. HOWEVER, PRIOR EXPOSURE TO CANNABINOIDS INHIBITED COCAINE-INDUCED CONDITIONED PLACE PREFERENCE WITHOUT MODULATING COCAINE-INDUCED HYPERLOCOMOTION, ACCOMPANIED BY AN INCREASE IN EXPRESSION OF THE ENZYME DNA METHYLTRANSFERASE 3A (DNMT3A) IN THE PREFRONTAL CORTEX. CONCLUSIONS: OUR FINDINGS SUGGEST THAT EXPOSURE TO WIN55,212-2 DURING ADOLESCENCE LEADS TO CHANGES IN DNMT3A EXPRESSION, AND THIS PATHWAY APPEARS TO BE RELEVANT TO MODULATING THE REWARDING EFFECTS OF COCAINE. 2021 18 1753 43 EARLY LIFE STRESS TRIGGERS SUSTAINED CHANGES IN HISTONE DEACETYLASE EXPRESSION AND HISTONE H4 MODIFICATIONS THAT ALTER RESPONSIVENESS TO ADOLESCENT ANTIDEPRESSANT TREATMENT. EARLY LIFE STRESS CAN ELICIT LONG-LASTING CHANGES IN GENE EXPRESSION AND BEHAVIOR. RECENT STUDIES ON RODENTS SUGGEST THAT THESE LASTING EFFECTS DEPEND ON THE GENETIC BACKGROUND. WHETHER EPIGENETIC FACTORS ALSO PLAY A ROLE REMAINS TO BE INVESTIGATED. HERE WE EXPOSED THE STRESS-SUSCEPTIBLE MOUSE STRAIN BALB/C AND THE MORE RESILIENT STRAIN C57BL/6 TO A POWERFUL EARLY LIFE STRESS PARADIGM, INFANT MATERNAL SEPARATION. IN BALB/C MICE, INFANT MATERNAL SEPARATION LED TO DECREASED EXPRESSION OF MRNA ENCODING THE HISTONE DEACETYLASES (HDACS) 1, 3, 7, 8, AND 10 IN THE FOREBRAIN NEOCORTEX IN ADULTHOOD, AN EFFECT ACCOMPANIED BY INCREASED EXPRESSION OF ACETYLATED HISTONE H4 PROTEINS, ESPECIALLY ACETYLATED H4K12 PROTEIN. THESE CHANGES IN HDAC EXPRESSION AND HISTONE MODIFICATIONS WERE NOT DETECTED IN C57BL/6 MICE EXPOSED TO EARLY LIFE STRESS. MOREOVER, A REVERSAL OF THE H4K12 HYPERACETYLATION DETECTED IN INFANT MATERNALLY SEPARATED BALB/C MICE (ACHIEVED WITH CHRONIC ADOLESCENT TREATMENT WITH A LOW DOSE OF THEOPHYLLINE THAT ONLY ACTIVATES HDACS) WORSENED THE ABNORMAL EMOTIONAL PHENOTYPE RESULTING FROM THIS EARLY LIFE STRESS EXPOSURE. IN CONTRAST, FLUOXETINE, A DRUG WITH POTENT ANTIDEPRESSANT EFFICACY IN INFANT MATERNALLY SEPARATED BALB/C MICE, POTENTIATED ALL HISTONE MODIFICATIONS TRIGGERED BY EARLY LIFE STRESS. MOREOVER, IN NON-STRESSED BALB/C MICE, CO-ADMINISTRATION OF AN HDAC INHIBITOR AND FLUOXETINE, BUT NOT FLUOXETINE ALONE, ELICITED ANTIDEPRESSANT EFFECTS AND ALSO TRIGGERED CHANGES IN HISTONE H4 EXPRESSION THAT WERE SIMILAR TO THOSE PROVOKED BY FLUOXETINE TREATMENT OF MICE EXPOSED TO EARLY LIFE STRESS. THESE RESULTS SUGGEST THAT BALB/C MICE DEVELOP EPIGENETIC MODIFICATIONS AFTER EARLY LIFE STRESS EXPOSURE THAT, IN TERMS OF THE EMOTIVE PHENOTYPE, ARE OF ADAPTIVE NATURE, AND THAT ENHANCE THE EFFICACY OF ANTIDEPRESSANT DRUGS. 2012 19 584 62 BEHAVIORAL NEUROADAPTATION TO ALCOHOL: FROM GLUCOCORTICOIDS TO HISTONE ACETYLATION. A PRIME MECHANISM THAT CONTRIBUTES TO THE DEVELOPMENT AND MAINTENANCE OF ALCOHOLISM IS THE DYSREGULATION OF THE HYPOTHALAMIC-PITUITARY-ADRENAL AXIS ACTIVITY AND THE RELEASE OF GLUCOCORTICOIDS (CORTISOL IN HUMANS AND PRIMATES, CORTICOSTERONE IN RODENTS) FROM THE ADRENAL GLANDS. IN THE BRAIN, SUSTAINED, LOCAL ELEVATION OF GLUCOCORTICOID CONCENTRATION EVEN LONG AFTER CESSATION OF CHRONIC ALCOHOL CONSUMPTION COMPROMISES FUNCTIONAL INTEGRITY OF A CIRCUIT, INCLUDING THE PREFRONTAL CORTEX (PFC), THE HIPPOCAMPUS (HPC), AND THE AMYGDALA (AMG). THESE STRUCTURES ARE IMPLICATED IN LEARNING AND MEMORY PROCESSES AS WELL AS IN ORCHESTRATING NEUROADAPTIVE RESPONSES TO STRESS AND ANXIETY RESPONSES. THUS, POTENTIATION OF ANXIETY-RELATED NEUROADAPTATION BY ALCOHOL IS CHARACTERIZED BY AN ABNORMALLY AMG HYPERACTIVITY COUPLED WITH A HYPOFUNCTION OF THE PFC AND THE HPC. THIS REVIEW DESCRIBES RESEARCH ON MOLECULAR AND EPIGENETIC MECHANISMS BY WHICH ALCOHOL CAUSES DISTINCT REGION-SPECIFIC ADAPTIVE CHANGES IN GENE EXPRESSION PATTERNS AND ULTIMATELY LEADS TO A VARIETY OF COGNITIVE AND BEHAVIORAL IMPAIRMENTS ON PREFRONTAL- AND HIPPOCAMPAL-BASED TASKS. ALCOHOL-INDUCED NEUROADAPTATIONS INVOLVE THE DYSREGULATION OF NUMEROUS SIGNALING CASCADES, LEADING TO LONG-TERM CHANGES IN TRANSCRIPTIONAL PROFILES OF GENES, THROUGH THE ACTIONS OF TRANSCRIPTION FACTORS SUCH AS [CAMP RESPONSE ELEMENT-BINDING PROTEIN (CREB)] AND CHROMATIN REMODELING DUE TO POSTTRANSLATIONAL MODIFICATIONS OF HISTONE PROTEINS. WE DESCRIBE THE ROLE OF PREFRONTAL-HPC-AMG CIRCUIT IN MEDIATING THE EFFECTS OF ACUTE AND CHRONIC ALCOHOL ON LEARNING AND MEMORY, AND REGION-SPECIFIC MOLECULAR AND EPIGENETIC MECHANISMS INVOLVED IN THIS PROCESS. THIS REVIEW FIRST DISCUSSES THE IMPORTANCE OF BRAIN REGION-SPECIFIC DYSREGULATION OF GLUCOCORTICOID CONCENTRATION IN THE DEVELOPMENT OF ALCOHOL DEPENDENCE AND DESCRIBES HOW PERSISTENTLY INCREASED GLUCOCORTICOID LEVELS IN PFC MAY BE INVOLVED IN MEDIATING WORKING MEMORY IMPAIRMENTS AND NEUROADAPTIVE CHANGES DURING WITHDRAWAL FROM CHRONIC ALCOHOL INTAKE. IT THEN HIGHLIGHTS THE ROLE OF CAMP-PKA-CREB SIGNALING CASCADE AND HISTONE ACETYLATION WITHIN THE PFC AND LIMBIC STRUCTURES IN ALCOHOL-INDUCED ANXIETY AND BEHAVIORAL IMPAIRMENTS, AND HOW AN UNDERSTANDING OF FUNCTIONAL ALTERATIONS OF THESE PATHWAYS MIGHT LEAD TO BETTER TREATMENTS FOR NEUROPSYCHIATRIC DISORDERS. 2016 20 2280 49 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