1 1012 111 CIGARETTE SMOKE INDUCES DISTINCT HISTONE MODIFICATIONS IN LUNG CELLS: IMPLICATIONS FOR THE PATHOGENESIS OF COPD AND LUNG CANCER. CIGARETTE SMOKE (CS)-MEDIATED OXIDATIVE STRESS INDUCES SEVERAL SIGNALING CASCADES, INCLUDING KINASES, WHICH RESULTS IN CHROMATIN MODIFICATIONS (HISTONE ACETYLATION/DEACETYLATION AND HISTONE METHYLATION/DEMETHYLATION). WE HAVE PREVIOUSLY REPORTED THAT CS INDUCES CHROMATIN REMODELING IN PRO-INFLAMMATORY GENE PROMOTERS; HOWEVER, THE UNDERLYING SITE-SPECIFIC HISTONE MARKS FORMED IN HISTONES H3 AND H4 DURING CS EXPOSURE IN LUNGS IN VIVO AND IN LUNG CELLS IN VITRO, WHICH CAN EITHER DRIVE GENE EXPRESSION OR REPRESSION, ARE NOT KNOWN. WE HYPOTHESIZE THAT CS EXPOSURE IN MOUSE AND HUMAN BRONCHIAL EPITHELIAL CELLS (H292) CAN CAUSE SITE-SPECIFIC POSTTRANSLATIONAL HISTONE MODIFICATIONS (PTMS) THAT MAY PLAY AN IMPORTANT ROLE IN THE PATHOGENESIS OF CS-INDUCED CHRONIC LUNG DISEASES. WE USED A BOTTOM-UP MASS SPECTROMETRY APPROACH TO IDENTIFY SOME POTENTIALLY NOVEL HISTONE MARKS, INCLUDING ACETYLATION, MONOMETHYLATION, AND DIMETHYLATION, IN SPECIFIC LYSINE AND ARGININE RESIDUES OF HISTONES H3 AND H4 IN MOUSE LUNGS AND H292 CELLS. WE FOUND THAT CS-INDUCED DISTINCT POSTTRANSLATIONAL HISTONE MODIFICATION PATTERNS IN HISTONE H3 AND HISTONE H4 IN LUNG CELLS, WHICH MAY BE CONSIDERED AS USABLE BIOMARKERS FOR CS-INDUCED CHRONIC LUNG DISEASES. THESE IDENTIFIED HISTONE MARKS (HISTONE H3 AND HISTONE H4) MAY PLAY AN IMPORTANT ROLE IN THE EPIGENETIC STATE DURING THE PATHOGENESIS OF SMOKING-INDUCED CHRONIC LUNG DISEASES, SUCH AS CHRONIC OBSTRUCTIVE PULMONARY DISEASE AND LUNG CANCER. 2014 2 6176 24 THE HISTONE H3 LYSINE-27 DEMETHYLASE JMJD3 LINKS INFLAMMATION TO INHIBITION OF POLYCOMB-MEDIATED GENE SILENCING. EPIGENETIC CHROMATIN MARKS RESTRICT THE ABILITY OF DIFFERENTIATED CELLS TO CHANGE GENE EXPRESSION PROGRAMS IN RESPONSE TO ENVIRONMENTAL CUES AND TO TRANSDIFFERENTIATE. POLYCOMB GROUP (PCG) PROTEINS MEDIATE GENE SILENCING AND REPRESS TRANSDIFFERENTIATION IN A MANNER DEPENDENT ON HISTONE H3 LYSINE 27 TRIMETHYLATION (H3K27ME3). HOWEVER, MACROPHAGES MIGRATED INTO INFLAMED TISSUES CAN TRANSDIFFERENTIATE, BUT IT IS UNKNOWN WHETHER INFLAMMATION ALTERS PCG-DEPENDENT SILENCING. HERE WE SHOW THAT THE JMJC-DOMAIN PROTEIN JMJD3 IS A H3K27ME DEMETHYLASE EXPRESSED IN MACROPHAGES IN RESPONSE TO BACTERIAL PRODUCTS AND INFLAMMATORY CYTOKINES. JMJD3 BINDS PCG TARGET GENES AND REGULATES THEIR H3K27ME3 LEVELS AND TRANSCRIPTIONAL ACTIVITY. THE DISCOVERY OF AN INDUCIBLE ENZYME THAT ERASES A HISTONE MARK CONTROLLING DIFFERENTIATION AND CELL IDENTITY PROVIDES A LINK BETWEEN INFLAMMATION AND REPROGRAMMING OF THE EPIGENOME, WHICH COULD BE THE BASIS FOR MACROPHAGE PLASTICITY AND MIGHT EXPLAIN THE DIFFERENTIATION ABNORMALITIES IN CHRONIC INFLAMMATION. 2007 3 2910 48 GENE EXPRESSION PROFILING OF EPIGENETIC CHROMATIN MODIFICATION ENZYMES AND HISTONE MARKS BY CIGARETTE SMOKE: IMPLICATIONS FOR COPD AND LUNG CANCER. CHROMATIN-MODIFYING ENZYMES MEDIATE DNA METHYLATION AND HISTONE MODIFICATIONS ON RECRUITMENT TO SPECIFIC TARGET GENE LOCI IN RESPONSE TO VARIOUS STIMULI. THE KEY ENZYMES THAT REGULATE CHROMATIN ACCESSIBILITY FOR MAINTENANCE OF MODIFICATIONS IN DNA AND HISTONES, AND FOR MODULATION OF GENE EXPRESSION PATTERNS IN RESPONSE TO CIGARETTE SMOKE (CS), ARE NOT KNOWN. WE HYPOTHESIZE THAT CS EXPOSURE ALTERS THE GENE EXPRESSION PATTERNS OF CHROMATIN-MODIFYING ENZYMES, WHICH THEN AFFECTS MULTIPLE DOWNSTREAM PATHWAYS INVOLVED IN THE RESPONSE TO CS. WE HAVE, THEREFORE, ANALYZED CHROMATIN-MODIFYING ENZYME PROFILES AND VALIDATED BY QUANTITATIVE REAL-TIME PCR (QPCR). WE ALSO PERFORMED IMMUNOBLOT ANALYSIS OF TARGETED HISTONE MARKS IN C57BL/6J MICE EXPOSED TO ACUTE AND SUBCHRONIC CS, AND OF LUNGS FROM NONSMOKERS, SMOKERS, AND PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). WE FOUND A SIGNIFICANT INCREASE IN EXPRESSION OF SEVERAL CHROMATIN MODIFICATION ENZYMES, INCLUDING DNA METHYLTRANSFERASES, HISTONE ACETYLTRANSFERASES, HISTONE METHYLTRANSFERASES, AND SET DOMAIN PROTEINS, HISTONE KINASES, AND UBIQUITINASES. OUR QPCR VALIDATION DATA REVEALED A SIGNIFICANT DOWNREGULATION OF DNMT1, DNMT3A, DNMT3B, HDAC2, HDAC4, HAT1, PRMT1, AND AURKB WE IDENTIFIED TARGETED CHROMATIN HISTONE MARKS (H3K56AC AND H4K12AC), WHICH ARE INDUCED BY CS. THUS CS-INDUCED GENOTOXIC STRESS DIFFERENTIALLY AFFECTS THE EXPRESSION OF EPIGENETIC MODULATORS THAT REGULATE TRANSCRIPTION OF TARGET GENES VIA DNA METHYLATION AND SITE-SPECIFIC HISTONE MODIFICATIONS. THIS MAY HAVE IMPLICATIONS IN DEVISING EPIGENETIC-BASED THERAPIES FOR COPD AND LUNG CANCER. 2016 4 356 35 ALTERING A HISTONE H3K4 METHYLATION PATHWAY IN GLOMERULAR PODOCYTES PROMOTES A CHRONIC DISEASE PHENOTYPE. METHYLATION OF SPECIFIC LYSINE RESIDUES IN CORE HISTONE PROTEINS IS ESSENTIAL FOR EMBRYONIC DEVELOPMENT AND CAN IMPART ACTIVE AND INACTIVE EPIGENETIC MARKS ON CHROMATIN DOMAINS. THE UBIQUITOUS NUCLEAR PROTEIN PTIP IS ENCODED BY THE PAXIP1 GENE AND IS AN ESSENTIAL COMPONENT OF A HISTONE H3 LYSINE 4 (H3K4) METHYLTRANSFERASE COMPLEX CONSERVED IN METAZOANS. IN ORDER TO DETERMINE IF PTIP AND ITS ASSOCIATED COMPLEXES ARE NECESSARY FOR MAINTAINING STABLE GENE EXPRESSION PATTERNS IN A TERMINALLY DIFFERENTIATED, NON-DIVIDING CELL, WE CONDITIONALLY DELETED PTIP IN GLOMERULAR PODOCYTES IN MICE. RENAL DEVELOPMENT AND FUNCTION WERE NOT IMPAIRED IN YOUNG MICE. HOWEVER, OLDER ANIMALS PROGRESSIVELY EXHIBITED PROTEINURIA AND PODOCYTE ULTRA STRUCTURAL DEFECTS SIMILAR TO CHRONIC GLOMERULAR DISEASE. LOSS OF PTIP RESULTED IN SUBTLE CHANGES IN GENE EXPRESSION PATTERNS PRIOR TO THE ONSET OF A RENAL DISEASE PHENOTYPE. CHROMATIN IMMUNOPRECIPITATION SHOWED A LOSS OF PTIP BINDING AND LOWER H3K4 METHYLATION AT THE NTRK3 (NEUROTROPHIC TYROSINE KINASE RECEPTOR, TYPE 3) LOCUS, WHOSE EXPRESSION WAS SIGNIFICANTLY REDUCED AND WHOSE FUNCTION MAY BE ESSENTIAL FOR PODOCYTE FOOT PROCESS PATTERNING. THESE DATA DEMONSTRATE THAT ALTERATIONS OR MUTATIONS IN AN EPIGENETIC REGULATORY PATHWAY CAN ALTER THE PHENOTYPES OF DIFFERENTIATED CELLS AND LEAD TO A CHRONIC DISEASE STATE. 2010 5 4889 49 OXIDATIVE STRESS AND CHROMATIN REMODELING IN CHRONIC OBSTRUCTIVE PULMONARY DISEASE AND SMOKING-RELATED DISEASES. SIGNIFICANCE: CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) IS PREDOMINANTLY A TOBACCO SMOKE-TRIGGERED DISEASE WITH FEATURES OF CHRONIC LOW-GRADE SYSTEMIC INFLAMMATION AND AGING (INFLAMMAGING) OF THE LUNG ASSOCIATED WITH STEROID RESISTANCE INDUCED BY CIGARETTE SMOKE (CS)-MEDIATED OXIDATIVE STRESS. OXIDATIVE STRESS INDUCES VARIOUS KINASE SIGNALING PATHWAYS LEADING TO CHROMATIN MODIFICATIONS (HISTONE ACETYLATION/DEACETYLATION AND HISTONE METHYLATION/DEMETHYLATION) IN INFLAMMATION, SENESCENCE, AND STEROID RESISTANCE. RECENT ADVANCES: HISTONE MONO-, DI-, OR TRI-METHYLATION AT LYSINE RESIDUES RESULT IN EITHER GENE ACTIVATION (H3K4, H3K36, AND H3K79) OR REPRESSION (H3K9, H3K27, AND H3K20). CROSS-TALK OCCURS BETWEEN VARIOUS EPIGENETIC MARKS ON HISTONES AND DNA METHYLATION. BOTH CS AND OXIDANTS ALTER HISTONE ACETYLATION/DEACETYLATION AND METHYLATION/DEMETHYLATION LEADING TO ENHANCED PROINFLAMMATORY GENE EXPRESSION. CHROMATIN MODIFICATIONS OCCUR IN LUNGS OF PATIENTS WITH COPD. HISTONE DEACETYLASE 2 (HDAC2) REDUCTION (LEVELS AND ACTIVITY) IS ASSOCIATED WITH STEROID RESISTANCE IN RESPONSE TO OXIDATIVE STRESS. CRITICAL ISSUES: HISTONE MODIFICATIONS ARE ASSOCIATED WITH DNA DAMAGE/REPAIR AND EPIGENOMIC INSTABILITY AS WELL AS PREMATURE LUNG AGING, WHICH HAVE IMPLICATIONS IN THE PATHOGENESIS OF COPD. HDAC2/SIRTUIN1 (SIRT1)-DEPENDENT CHROMATIN MODIFICATIONS ARE ASSOCIATED WITH DNA DAMAGE-INDUCED INFLAMMATION AND SENESCENCE IN RESPONSE TO CS-MEDIATED OXIDATIVE STRESS. FUTURE DIRECTIONS: UNDERSTANDING CS/OXIDATIVE STRESS-MEDIATED CHROMATIN MODIFICATIONS AND THE CROSS-TALK BETWEEN HISTONE ACETYLATION AND METHYLATION WILL DEMONSTRATE THE INVOLVEMENT OF EPIGENETIC REGULATION OF CHROMATIN REMODELING IN INFLAMMAGING. THIS WILL LEAD TO IDENTIFICATION OF NOVEL EPIGENETIC-BASED THERAPIES AGAINST COPD AND OTHER SMOKING-RELATED LUNG DISEASES. PHARMACOLOGICAL ACTIVATION OF HDAC2/SIRT1 OR REVERSAL OF THEIR OXIDATIVE POST-TRANSLATIONAL MODIFICATIONS MAY OFFER THERAPIES FOR TREATMENT OF COPD AND CS-RELATED DISEASES BASED ON EPIGENETIC HISTONE MODIFICATIONS. 2013 6 2370 34 EPIGENETIC REGULATION OF THE ALTERNATIVELY ACTIVATED MACROPHAGE PHENOTYPE. ALTERNATIVELY ACTIVATED (M2) MACROPHAGES PLAY CRITICAL ROLES IN DIVERSE CHRONIC DISEASES, INCLUDING PARASITE INFECTIONS, CANCER, AND ALLERGIC RESPONSES. HOWEVER, LITTLE IS KNOWN ABOUT THE ACQUISITION AND MAINTENANCE OF THEIR PHENOTYPE. WE REPORT THAT M2-MACROPHAGE MARKER GENES ARE EPIGENETICALLY REGULATED BY RECIPROCAL CHANGES IN HISTONE H3 LYSINE-4 (H3K4) AND HISTONE H3 LYSINE-27 (H3K27) METHYLATION; AND THE LATTER METHYLATION MARKS ARE REMOVED BY THE H3K27 DEMETHYLASE JUMONJI DOMAIN CONTAINING 3 (JMJD3). WE FOUND THAT CONTINUOUS INTERLEUKIN-4 (IL-4) TREATMENT LEADS TO DECREASED H3K27 METHYLATION, AT THE PROMOTER OF M2 MARKER GENES, AND A CONCOMITANT INCREASE IN JMJD3 EXPRESSION. FURTHERMORE, WE DEMONSTRATE THAT IL-4-DEPENDENT JMJD3 EXPRESSION IS MEDIATED BY STAT6, A MAJOR TRANSCRIPTION FACTOR OF IL-4-MEDIATED SIGNALING. AFTER IL-4 STIMULATION, ACTIVATED STAT6 IS INCREASED AND BINDS TO CONSENSUS SITES AT THE JMJD3 PROMOTER. INCREASED JMJD3 CONTRIBUTES TO THE DECREASE OF H3K27 DIMETHYLATION AND TRIMETHYLATION (H3K27ME2/3) MARKS AS WELL AS THE TRANSCRIPTIONAL ACTIVATION OF SPECIFIC M2 MARKER GENES. THE DECREASE IN H3K27ME2/3 AND INCREASE IN JMJD3 RECRUITMENT WERE CONFIRMED BY IN VIVO STUDIES USING A SCHISTOSOMA MANSONI EGG-CHALLENGED MOUSE MODEL, A WELL-STUDIED SYSTEM KNOWN TO SUPPORT AN M2 PHENOTYPE. COLLECTIVELY, THESE DATA INDICATE THAT CHROMATIN REMODELING IS MECHANISTICALLY IMPORTANT IN THE ACQUISITION OF THE M2-MACROPHAGE PHENOTYPE. 2009 7 2280 32 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 8 4004 29 LOSS OF THE POLYCOMB MARK FROM BIVALENT PROMOTERS LEADS TO ACTIVATION OF CANCER-PROMOTING GENES IN COLORECTAL TUMORS. IN COLON TUMORS, THE TRANSCRIPTION OF MANY GENES BECOMES DEREGULATED BY POORLY DEFINED EPIGENETIC MECHANISMS THAT HAVE BEEN STUDIED MAINLY IN ESTABLISHED CELL LINES. IN THIS STUDY, WE USED FROZEN HUMAN COLON TISSUES TO ANALYZE PATTERNS OF HISTONE MODIFICATION AND DNA CYTOSINE METHYLATION IN CANCER AND MATCHED NORMAL MUCOSA SPECIMENS. DNA METHYLATION IS STRONGLY TARGETED TO BIVALENT H3K4ME3- AND H3K27ME3-ASSOCIATED PROMOTERS, WHICH LOSE BOTH HISTONE MARKS AND ACQUIRE DNA METHYLATION. HOWEVER, WE FOUND THAT LOSS OF THE POLYCOMB MARK H3K27ME3 FROM BIVALENT PROMOTERS WAS ACCOMPANIED OFTEN BY ACTIVATION OF GENES ASSOCIATED WITH CANCER PROGRESSION, INCLUDING NUMEROUS STEM CELL REGULATORS, ONCOGENES, AND PROLIFERATION-ASSOCIATED GENES. INDEED, WE FOUND MANY OF THESE SAME GENES WERE ALSO ACTIVATED IN PATIENTS WITH ULCERATIVE COLITIS WHERE CHRONIC INFLAMMATION PREDISPOSES THEM TO COLON CANCER. BASED ON OUR FINDINGS, WE PROPOSE THAT A LOSS OF POLYCOMB REPRESSION AT BIVALENT GENES COMBINED WITH AN ENSUING SELECTION FOR TUMOR-DRIVING EVENTS PLAYS A MAJOR ROLE IN CANCER PROGRESSION. 2014 9 3072 26 GENOME-WIDE DNA METHYLATION REPROGRAMMING IN RESPONSE TO INORGANIC ARSENIC LINKS INHIBITION OF CTCF BINDING, DNMT EXPRESSION AND CELLULAR TRANSFORMATION. CHRONIC LOW DOSE INORGANIC ARSENIC (IAS) EXPOSURE LEADS TO CHANGES IN GENE EXPRESSION AND EPITHELIAL-TO-MESENCHYMAL TRANSFORMATION. DURING THIS TRANSFORMATION, CELLS ADOPT A FIBROBLAST-LIKE PHENOTYPE ACCOMPANIED BY PROFOUND GENE EXPRESSION CHANGES. WHILE MANY MECHANISMS HAVE BEEN IMPLICATED IN THIS TRANSFORMATION, STUDIES THAT FOCUS ON THE ROLE OF EPIGENETIC ALTERATIONS IN THIS PROCESS ARE JUST EMERGING. DNA METHYLATION CONTROLS GENE EXPRESSION IN PHYSIOLOGIC AND PATHOLOGIC STATES. SEVERAL STUDIES SHOW ALTERATIONS IN DNA METHYLATION PATTERNS IN IAS-MEDIATED PATHOGENESIS, BUT THESE STUDIES FOCUSED ON SINGLE GENES. WE PRESENT A COMPREHENSIVE GENOME-WIDE DNA METHYLATION ANALYSIS USING METHYL-SEQUENCING TO MEASURE CHANGES BETWEEN NORMAL AND IAS-TRANSFORMED CELLS. ADDITIONALLY, THESE DIFFERENTIAL METHYLATION CHANGES CORRELATED POSITIVELY WITH CHANGES IN GENE EXPRESSION AND ALTERNATIVE SPLICING. INTERESTINGLY, MOST OF THESE DIFFERENTIALLY METHYLATED GENES FUNCTION IN CELL ADHESION AND COMMUNICATION PATHWAYS. TO GAIN INSIGHT INTO HOW GENOMIC DNA METHYLATION PATTERNS ARE REGULATED DURING IAS-MEDIATED CARCINOGENESIS, WE SHOW THAT IAS PROBABLY TARGETS CTCF BINDING AT THE PROMOTER OF DNA METHYLTRANSFERASES, REGULATING THEIR EXPRESSION. THESE FINDINGS REVEAL HOW CTCF BINDING REGULATES DNA METHYLTRANSFERASE TO REPROGRAM THE METHYLOME IN RESPONSE TO AN ENVIRONMENTAL TOXIN. 2017 10 1468 30 DISTINCT EPIGENETIC PROGRAMS REGULATE CARDIAC MYOCYTE DEVELOPMENT AND DISEASE IN THE HUMAN HEART IN VIVO. EPIGENETIC MECHANISMS AND TRANSCRIPTION FACTOR NETWORKS ESSENTIAL FOR DIFFERENTIATION OF CARDIAC MYOCYTES HAVE BEEN UNCOVERED. HOWEVER, RESHAPING OF THE EPIGENOME OF THESE TERMINALLY DIFFERENTIATED CELLS DURING FETAL DEVELOPMENT, POSTNATAL MATURATION, AND IN DISEASE REMAINS UNKNOWN. HERE, WE INVESTIGATE THE DYNAMICS OF THE CARDIAC MYOCYTE EPIGENOME DURING DEVELOPMENT AND IN CHRONIC HEART FAILURE. WE FIND THAT PRENATAL DEVELOPMENT AND POSTNATAL MATURATION ARE CHARACTERIZED BY A COOPERATION OF ACTIVE CPG METHYLATION AND HISTONE MARKS AT CIS-REGULATORY AND GENIC REGIONS TO SHAPE THE CARDIAC MYOCYTE TRANSCRIPTOME. IN CONTRAST, PATHOLOGICAL GENE EXPRESSION IN TERMINAL HEART FAILURE IS ACCOMPANIED BY CHANGES IN ACTIVE HISTONE MARKS WITHOUT MAJOR ALTERATIONS IN CPG METHYLATION AND REPRESSIVE CHROMATIN MARKS. NOTABLY, CIS-REGULATORY REGIONS IN CARDIAC MYOCYTES ARE SIGNIFICANTLY ENRICHED FOR CARDIOVASCULAR DISEASE-ASSOCIATED VARIANTS. THIS STUDY UNCOVERS DISTINCT LAYERS OF EPIGENETIC REGULATION NOT ONLY DURING PRENATAL DEVELOPMENT AND POSTNATAL MATURATION BUT ALSO IN DISEASED HUMAN CARDIAC MYOCYTES. 2018 11 4497 36 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 12 1532 19 DNA METHYLATION DYNAMICS AND COCAINE IN THE BRAIN: PROGRESS AND PROSPECTS. CYTOSINE MODIFICATIONS, INCLUDING DNA METHYLATION, ARE STABLE EPIGENETIC MARKS THAT MAY TRANSLATE ENVIRONMENTAL CHANGE INTO TRANSCRIPTIONAL REGULATION. RESEARCH HAS BEGUN TO INVESTIGATE DNA METHYLATION DYNAMICS IN RELATION TO COCAINE USE DISORDERS. SPECIFICALLY, DNA METHYLATION MACHINERY, INCLUDING METHYLTRANSFERASES AND BINDING PROTEINS, ARE DYSREGULATED IN BRAIN REWARD PATHWAYS AFTER CHRONIC COCAINE EXPOSURE. IN ADDITION, NUMEROUS METHYLOME-WIDE AND CANDIDATE PROMOTER STUDIES HAVE IDENTIFIED DIFFERENTIAL METHYLATION, AT THE NUCLEOTIDE LEVEL, IN RODENT MODELS OF COCAINE ABUSE AND DRUG SEEKING BEHAVIOR. THIS REVIEW HIGHLIGHTS THE CURRENT PROGRESS IN THE FIELD OF COCAINE-RELATED METHYLATION, AND OFFERS CONSIDERATIONS FOR FUTURE RESEARCH. 2017 13 6517 25 TRANSCRIPTIONAL AND EPIGENETIC MECHANISMS OF ADDICTION. INVESTIGATIONS OF LONG-TERM CHANGES IN BRAIN STRUCTURE AND FUNCTION THAT ACCOMPANY CHRONIC EXPOSURE TO DRUGS OF ABUSE SUGGEST THAT ALTERATIONS IN GENE REGULATION CONTRIBUTE SUBSTANTIALLY TO THE ADDICTIVE PHENOTYPE. HERE, WE REVIEW MULTIPLE MECHANISMS BY WHICH DRUGS ALTER THE TRANSCRIPTIONAL POTENTIAL OF GENES. THESE MECHANISMS RANGE FROM THE MOBILIZATION OR REPRESSION OF THE TRANSCRIPTIONAL MACHINERY - INCLUDING THE TRANSCRIPTION FACTORS DELTAFOSB, CYCLIC AMP-RESPONSIVE ELEMENT BINDING PROTEIN (CREB) AND NUCLEAR FACTOR-KAPPAB (NF-KAPPAB) - TO EPIGENETICS - INCLUDING ALTERATIONS IN THE ACCESSIBILITY OF GENES WITHIN THEIR NATIVE CHROMATIN STRUCTURE INDUCED BY HISTONE TAIL MODIFICATIONS AND DNA METHYLATION, AND THE REGULATION OF GENE EXPRESSION BY NON-CODING RNAS. INCREASING EVIDENCE IMPLICATES THESE VARIOUS MECHANISMS OF GENE REGULATION IN THE LASTING CHANGES THAT DRUGS OF ABUSE INDUCE IN THE BRAIN, AND OFFERS NOVEL INROADS FOR ADDICTION THERAPY. 2011 14 5438 25 REMOVAL OF EPIGENETIC REPRESSIVE MARK ON INFLAMMATORY GENES IN FAT LIVER. NONALCOHOLIC FATTY LIVER DISEASE (NAFLD) IS THE MOST COMMON CHRONIC LIVER DISEASE WORLDWIDE. THE DETAILED EPIGENOMIC CHANGES DURING FAT ACCUMULATION IN LIVER ARE NOT CLEAR YET. HERE, WE PERFORMED CHIP-SEQ ANALYSIS IN THE LIVER TISSUES OF HIGH-FAT DIET AND REGULAR CHOW DIET MICE AND INVESTIGATED THE DYNAMIC LANDSCAPES OF H3K27AC AND H3K9ME3 MARKS ON CHROMATIN. WE FIND THAT THE ACTIVATED TYPICAL ENHANCERS MARKED WITH H3K27AC ARE ENRICHED ON LIPID METABOLIC PATHWAYS IN FAT LIVER; HOWEVER, SUPER ENHANCERS DO NOT CHANGE MUCH. THE REGIONS COVERED WITH H3K9ME3 REPRESSIVE MARK SEEM TO UNDERGO GREAT CHANGES, AND ITS PEAK NUMBER AND INTENSITY BOTH DECREASE IN FAT LIVER. THE ENHANCERS LOCATED IN LOST H3K9ME3 REGIONS ARE ENRICHED IN LIPID METABOLISM AND INFLAMMATORY PATHWAYS; AND MOTIF ANALYSIS SHOWS THAT THEY ARE POTENTIAL TARGETS FOR TRANSCRIPTION FACTORS INVOLVED IN METABOLIC AND INFLAMMATORY PROCESSES. OUR STUDY HAS REVEALED THAT H3K9ME3 MAY PLAY AN IMPORTANT ROLE DURING THE PATHOGENESIS OF NAFLD THROUGH REGULATING THE ACCESSIBILITY OF ENHANCERS. 2023 15 5403 30 REGENERATION AFTER ACUTE KIDNEY INJURY REQUIRES PTIP-MEDIATED EPIGENETIC MODIFICATIONS. A TERMINALLY DIFFERENTIATED CELLULAR PHENOTYPE IS THOUGHT TO BE MAINTAINED, AT LEAST IN PART, BY BOTH ACTIVE AND REPRESSIVE HISTONE MARKS. HOWEVER, IT IS UNCLEAR WHETHER REGENERATING CELLS AFTER INJURY NEED TO REPLICATE SUCH EPIGENETIC MARKS TO RECOVER. TO TEST WHETHER RENAL EPITHELIAL CELL REGENERATION IS DEPENDENT ON HISTONE H3K4 METHYLATION, WE GENERATED A MOUSE MODEL THAT DELETED THE PAXIP1 GENE IN MATURE RENAL PROXIMAL TUBULES. PAXIP1 ENCODES PTIP, AN ESSENTIAL PROTEIN IN THE MLL3/4 HISTONE H3K4 METHYLTRANSFERASE COMPLEX. MICE WITH PTIP DELETIONS IN THE ADULT KIDNEY PROXIMAL TUBULES WERE VIABLE AND FERTILE. UPON ACUTE KIDNEY INJURY, SUCH MICE FAILED TO REGENERATE DAMAGED TUBULES, LEADING TO SCARRING AND INTERSTITIAL FIBROSIS. THE INABILITY TO REPAIR DAMAGE WAS LIKELY DUE TO A FAILURE TO REENTER MITOSIS AND REACTIVATE REGULATORY GENES SUCH AS SOX9. PTIP DELETION REDUCED HISTONE H3K4 METHYLATION IN UNINJURED ADULT KIDNEYS BUT DID NOT SIGNIFICANTLY AFFECT FUNCTION OR THE EXPRESSION OF EPITHELIAL SPECIFIC MARKERS. STRIKINGLY, CELL LINEAGE TRACING REVEALED THAT SURVIVING PTIP MUTANT CELLS COULD ALTER THEIR PHENOTYPE AND LOSE EPITHELIAL MARKERS. THESE DATA DEMONSTRATE THAT PTIP AND ASSOCIATED MLL3/4-MEDIATED HISTONE METHYLATION ARE NEEDED FOR REGENERATING PROXIMAL TUBULES AND TO MAINTAIN OR REESTABLISH THE CELLULAR EPITHELIAL PHENOTYPE. 2020 16 2055 27 EPIGENETIC CONTROL DURING LYMPHOID DEVELOPMENT AND IMMUNE RESPONSES: ABERRANT REGULATION, VIRUSES, AND CANCER. METHYLATION OF CYTOSINES CONTROLS A NUMBER OF BIOLOGIC PROCESSES SUCH AS IMPRINTING AND X CHROMOSOMAL INACTIVATION. DNA HYPERMETHYLATION IS CLOSELY ASSOCIATED WITH TRANSCRIPTIONAL SILENCING, WHILE DNA HYPOMETHYLATION IS ASSOCIATED WITH TRANSCRIPTIONAL ACTIVATION. HYPOACETYLATION OF HISTONES LEADS TO COMPACT CHROMATIN WITH REDUCED ACCESSIBILITY TO THE TRANSCRIPTIONAL MACHINERY. METHYL-CPG BINDING PROTEINS CAN RECRUIT COREPRESSORS AND HISTONE DEACETYLASES; THUS, THE INTERPLAY BETWEEN THESE EPIGENETIC MECHANISMS REGULATES GENE ACTIVATION. METHYLATION HAS BEEN IMPLICATED AS AN IMPORTANT MECHANISM DURING IMMUNE DEVELOPMENT, CONTROLLING VDJ RECOMBINATION, LINEAGE-SPECIFIC EXPRESSION OF CELL SURFACE ANTIGENS, AND TRANSCRIPTIONAL REGULATION OF CYTOKINE GENES DURING IMMUNE RESPONSES. ABERRATIONS IN EPIGENETIC MACHINERY, EITHER BY GENETIC MUTATIONS OR BY SOMATIC CHANGES SUCH AS VIRAL INFECTIONS, ARE ASSOCIATED WITH EARLY ALTERATIONS IN CHRONIC DISEASES SUCH AS IMMUNODEFICIENCY AND CANCER. 2003 17 5067 26 PHYSICAL ACTIVITY AND DNA METHYLATION IN HUMANS. PHYSICAL ACTIVITY IS A STRONG STIMULUS INFLUENCING THE OVERALL PHYSIOLOGY OF THE HUMAN BODY. EXERCISES LEAD TO BIOCHEMICAL CHANGES IN VARIOUS TISSUES AND EXERT AN IMPACT ON GENE EXPRESSION. EXERCISE-INDUCED CHANGES IN GENE EXPRESSION MAY BE MEDIATED BY EPIGENETIC MODIFICATIONS, WHICH REARRANGE THE CHROMATIN STRUCTURE AND THEREFORE MODULATE ITS ACCESSIBILITY FOR TRANSCRIPTION FACTORS. ONE OF SUCH EPIGENETIC MARK IS DNA METHYLATION THAT INVOLVES AN ATTACHMENT OF A METHYL GROUP TO THE FIFTH CARBON OF CYTOSINE RESIDUE PRESENT IN CG DINUCLEOTIDES (CPG). DNA METHYLATION IS CATALYZED BY A FAMILY OF DNA METHYLTRANSFERASES. THIS REVERSIBLE DNA MODIFICATION RESULTS IN THE RECRUITMENT OF PROTEINS CONTAINING METHYL BINDING DOMAIN AND FURTHER TRANSCRIPTIONAL CO-REPRESSORS LEADING TO THE SILENCING OF GENE EXPRESSION. THE ACCUMULATION OF CPG DINUCLEOTIDES, REFERRED AS CPG ISLANDS, OCCURS AT THE PROMOTER REGIONS IN A GREAT MAJORITY OF HUMAN GENES. THEREFORE, CHANGES IN DNA METHYLATION PROFILE AFFECT THE TRANSCRIPTION OF MULTIPLE GENES. A GROWING BODY OF EVIDENCE INDICATES THAT EXERCISE TRAINING MODULATES DNA METHYLATION IN MUSCLES AND ADIPOSE TISSUE. SOME OF THESE EPIGENETIC MARKERS WERE ASSOCIATED WITH A REDUCED RISK OF CHRONIC DISEASES. THIS REVIEW SUMMARIZES THE CURRENT KNOWLEDGE ABOUT THE INFLUENCE OF PHYSICAL ACTIVITY ON THE DNA METHYLATION STATUS IN HUMANS. 2021 18 883 34 CHRONIC COCAINE-REGULATED EPIGENOMIC CHANGES IN MOUSE NUCLEUS ACCUMBENS. BACKGROUND: INCREASING EVIDENCE SUPPORTS A ROLE FOR ALTERED GENE EXPRESSION IN MEDIATING THE LASTING EFFECTS OF COCAINE ON THE BRAIN, AND RECENT WORK HAS DEMONSTRATED THE INVOLVEMENT OF CHROMATIN MODIFICATIONS IN THESE ALTERATIONS. HOWEVER, ALL SUCH STUDIES TO DATE HAVE BEEN RESTRICTED BY THEIR RELIANCE ON MICROARRAY TECHNOLOGIES THAT HAVE INTRINSIC LIMITATIONS. RESULTS: WE USE NEXT GENERATION SEQUENCING METHODS, RNA-SEQ AND CHIP-SEQ FOR RNA POLYMERASE II AND SEVERAL HISTONE METHYLATION MARKS, TO OBTAIN A MORE COMPLETE VIEW OF COCAINE-INDUCED CHANGES IN GENE EXPRESSION AND ASSOCIATED ADAPTATIONS IN NUMEROUS MODES OF CHROMATIN REGULATION IN THE MOUSE NUCLEUS ACCUMBENS, A KEY BRAIN REWARD REGION. WE DEMONSTRATE AN UNEXPECTEDLY LARGE NUMBER OF PRE-MRNA SPLICING ALTERATIONS IN RESPONSE TO REPEATED COCAINE TREATMENT. IN ADDITION, WE IDENTIFY COMBINATIONS OF CHROMATIN CHANGES, OR SIGNATURES, THAT CORRELATE WITH COCAINE-DEPENDENT REGULATION OF GENE EXPRESSION, INCLUDING THOSE INVOLVING PRE-MRNA ALTERNATIVE SPLICING. THROUGH BIOINFORMATIC PREDICTION AND BIOLOGICAL VALIDATION, WE IDENTIFY ONE PARTICULAR SPLICING FACTOR, A2BP1(RBFOX1/FOX-1), WHICH IS ENRICHED AT GENES THAT DISPLAY CERTAIN CHROMATIN SIGNATURES AND CONTRIBUTES TO DRUG-INDUCED BEHAVIORAL ABNORMALITIES. TOGETHER, THIS DELINEATION OF THE COCAINE-INDUCED EPIGENOME IN THE NUCLEUS ACCUMBENS REVEALS SEVERAL NOVEL MODES OF REGULATION BY WHICH COCAINE ALTERS THE BRAIN. CONCLUSIONS: WE ESTABLISH COMBINATORIAL CHROMATIN AND TRANSCRIPTIONAL PROFILES IN MOUSE NUCLEUS ACCUMBENS AFTER REPEATED COCAINE TREATMENT. THESE RESULTS SERVE AS AN IMPORTANT RESOURCE FOR THE FIELD AND PROVIDE A TEMPLATE FOR THE ANALYSIS OF OTHER SYSTEMS TO REVEAL NEW TRANSCRIPTIONAL AND EPIGENETIC MECHANISMS OF NEURONAL REGULATION. 2014 19 1656 30 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 20 17 31 5' FLANKING REGION OF VAR GENES NUCLEATE HISTONE MODIFICATION PATTERNS LINKED TO PHENOTYPIC INHERITANCE OF VIRULENCE TRAITS IN MALARIA PARASITES. IN THE HUMAN MALARIA PARASITE PLASMODIUM FALCIPARUM ANTIGENIC VARIATION FACILITATES LONG-TERM CHRONIC INFECTION OF THE HOST. THIS IS ACHIEVED BY SEQUENTIAL EXPRESSION OF A SINGLE MEMBER OF THE 60-MEMBER VAR FAMILY. HERE WE SHOW THAT THE 5' FLANKING REGION NUCLEATES EPIGENETIC EVENTS STRONGLY LINKED TO THE MAINTENANCE OF MONO-ALLELIC VAR GENE EXPRESSION PATTERN DURING PARASITE PROLIFERATION. TRI- AND DIMETHYLATION OF HISTONE H3 LYSINE 4 PEAK IN THE 5' UPSTREAM REGION OF TRANSCRIBED VAR AND DURING THE POISED STATE (NON-TRANSCRIBED PHASE OF VAR GENES DURING THE 48 H ASEXUAL LIFE CYCLE), 'BOOKMARKING' THIS MEMBER FOR RE-ACTIVATION AT THE ONSET OF THE NEXT CYCLE. HISTONE H3 LYSINE 9 TRIMETHYLATION ACTS AS AN ANTAGONIST TO LYSINE 4 METHYLATION TO ESTABLISH STABLY SILENT VAR GENE STATES ALONG THE 5' FLANKING AND CODING REGION. FURTHERMORE, WE SHOW THAT COMPETITION EXISTS BETWEEN H3K9 METHYLATION AND H3K9 ACETYLATION IN THE 5' FLANKING REGION AND THAT THESE MARKS CONTRIBUTE EPIGENETICALLY TO REPRESSING OR ACTIVATING VAR GENE EXPRESSION. OUR WORK POINTS TO A PIVOTAL ROLE OF THE HISTONE METHYL MARK WRITING AND READING MACHINERY IN THE PHENOTYPIC INHERITANCE OF VIRULENCE TRAITS IN THE MALARIA PARASITE. 2007