1 329 130 ALPHA-OXOGLUTARATE INHIBITS THE PROLIFERATION OF IMMORTALIZED NORMAL BLADDER EPITHELIAL CELLS VIA AN EPIGENETIC SWITCH INVOLVING ARID1A. INTERSTITIAL CYSTITIS (IC) IS A CHRONIC URINARY TRACT DISEASE THAT IS CHARACTERIZED BY UNPLEASANT SENSATIONS, SUCH AS PERSISTENT PELVIC PAIN, IN THE ABSENCE OF INFECTION OR OTHER IDENTIFIABLE CAUSES. WE PREVIOUSLY PERFORMED COMPREHENSIVE METABOLOMICS PROFILING OF URINE SAMPLES FROM IC PATIENTS USING NUCLEAR MAGNETIC RESONANCE AND GAS-CHROMATOGRAPHY/MASS SPECTROMETRY AND FOUND THAT URINARY ALPHA-OXOGLUTARATE (ALPHA-OG), WAS SIGNIFICANTLY ELEVATED. ALPHA-OG, A TRICARBOXYLIC ACID (TCA) CYCLE INTERMEDIATE, REPORTEDLY FUNCTIONS TO SUPPRESS THE PROLIFERATION OF IMMORTALIZED NORMAL HUMAN BLADDER EPITHELIAL CELLS. HERE, WE IDENTIFIED AT-RICH INTERACTIVE DOMAIN 1 A (ARID1A), A KEY CHROMATIN REMODELER, AS BEING HYPOMETHYLATED AND UPREGULATED BY ALPHA-OG TREATMENT. THIS WAS DONE THROUGH EPIC DNA METHYLATION PROFILING AND SUBSEQUENT BIOCHEMICAL APPROACHES, INCLUDING QUANTITATIVE RT-PCR AND WESTERN BLOT ANALYSES. FURTHERMORE, WE FOUND THAT ALPHA-OG ALMOST COMPLETELY SUPPRESSES TEN-ELEVEN TRANSLOCATION (TET) ACTIVITY, BUT DOES NOT AFFECT DNA METHYLTRANSFERASE (DNMT) ACTIVITY. ALTOGETHER, OUR STUDIES REVEAL THE POTENTIAL ROLE OF ALPHA-OG IN EPIGENETIC REMODELING THROUGH ITS EFFECTS ON ARID1A AND TET EXPRESSION IN THE BLADDER. THIS MAY PROVIDE A NEW POSSIBLE THERAPEUTIC STRATEGY IN TREATING IC. 2018 2 3419 28 HUMAN LINE-1 RETROTRANSPOSONS: IMPACTS ON THE GENOME AND REGULATION BY HOST FACTORS. GENOME SEQUENCING REVEALED THAT NEARLY HALF OF THE HUMAN GENOME IS COMPRISED OF TRANSPOSABLE ELEMENTS. ALTHOUGH MOST OF THESE ELEMENTS HAVE BEEN RENDERED INACTIVE DUE TO MUTATIONS, FULL-LENGTH INTACT LONG INTERSPERSED ELEMENT-1 (LINE-1 OR L1) COPIES RETAIN THE ABILITY TO MOBILIZE THROUGH RNA INTERMEDIATES BY A SO-CALLED "COPY-AND-PASTE" MECHANISM, TERMED RETROTRANSPOSITION. L1 IS THE ONLY KNOWN AUTONOMOUS MOBILE GENETIC ELEMENT IN THE GENOME, AND ITS RETROTRANSPOSITION CONTRIBUTES TO INTER- OR INTRA-INDIVIDUAL GENETIC VARIATION WITHIN THE HUMAN POPULATION. HOWEVER, L1 RETROTRANSPOSITION ALSO POSES A THREAT TO GENOME INTEGRITY DUE TO GENE DISRUPTION AND CHROMOSOMAL INSTABILITY. MOREOVER, RECENT STUDIES SUGGEST THAT ABERRANT L1 EXPRESSION CAN IMPACT HUMAN HEALTH BY CAUSING DISEASES SUCH AS CANCER AND CHRONIC INFLAMMATION THAT MIGHT LEAD TO AUTOIMMUNE DISORDERS. TO COUNTERACT THESE ADVERSE EFFECTS, THE HOST CELLS HAVE EVOLVED MULTIPLE LAYERS OF DEFENSE MECHANISMS AT THE EPIGENETIC, RNA AND PROTEIN LEVELS. INTRIGUINGLY, SEVERAL HOST FACTORS HAVE ALSO BEEN REPORTED TO FACILITATE L1 RETROTRANSPOSITION, SUGGESTING THAT THERE IS COMPETITION BETWEEN NEGATIVE AND POSITIVE REGULATION OF L1 BY HOST FACTORS. HERE, WE SUMMARIZE THE KNOWN HOST PROTEINS THAT REGULATE L1 ACTIVITY AT DIFFERENT STAGES OF THE REPLICATION CYCLE AND DISCUSS HOW THESE FACTORS MODULATE DISEASE-ASSOCIATED PHENOTYPES CAUSED BY L1. 2022 3 3469 24 HYPOXIA-INDUCIBLE HISTONE LYSINE DEMETHYLASES: IMPACT ON THE AGING PROCESS AND AGE-RELATED DISEASES. HYPOXIA IS AN ENVIRONMENTAL STRESS AT HIGH ALTITUDE AND UNDERGROUND CONDITIONS BUT IT IS ALSO PRESENT IN MANY CHRONIC AGE-RELATED DISEASES, WHERE BLOOD FLOW INTO TISSUES IS IMPAIRED. THE OXYGEN-SENSING SYSTEM STIMULATES GENE EXPRESSION PROTECTING TISSUES AGAINST HYPOXIC INSULTS. HYPOXIA STABILIZES THE EXPRESSION OF HYPOXIA-INDUCIBLE TRANSCRIPTION FACTOR-1ALPHA (HIF-1ALPHA), WHICH CONTROLS THE EXPRESSION OF HUNDREDS OF SURVIVAL GENES RELATED TO E.G. ENHANCED ENERGY METABOLISM AND AUTOPHAGY. MOREOVER, MANY STRESS-RELATED SIGNALING MECHANISMS, SUCH AS OXIDATIVE STRESS AND ENERGY METABOLIC DISTURBANCES, AS WELL AS THE SIGNALING CASCADES VIA CERAMIDE, MTOR, NF-KAPPAB, AND TGF-BETA PATHWAYS, CAN ALSO INDUCE THE EXPRESSION OF HIF-1ALPHA PROTEIN TO FACILITATE CELL SURVIVAL IN NORMOXIA. HYPOXIA IS LINKED TO PROMINENT EPIGENETIC CHANGES IN CHROMATIN LANDSCAPE. SCREENING STUDIES HAVE INDICATED THAT THE STABILIZATION OF HIF-1ALPHA INCREASES THE EXPRESSION OF DISTINCT HISTONE LYSINE DEMETHYLASES (KDM). HIF-1ALPHA STIMULATES THE EXPRESSION OF KDM3A, KDM4B, KDM4C, AND KDM6B, WHICH ENHANCE GENE TRANSCRIPTION BY DEMETHYLATING H3K9 AND H3K27 SITES (REPRESSIVE EPIGENETIC MARKS). IN ADDITION, HIF-1ALPHA INDUCES THE EXPRESSION OF KDM2B AND KDM5B, WHICH REPRESS TRANSCRIPTION BY DEMETHYLATING H3K4ME2,3 SITES (ACTIVATING MARKS). HYPOXIA-INDUCIBLE KDMS SUPPORT LOCALLY THE GENE TRANSCRIPTION INDUCED BY HIF-1ALPHA, ALTHOUGH THEY CAN ALSO CONTROL GENOME-WIDE CHROMATIN LANDSCAPE, ESPECIALLY KDMS WHICH DEMETHYLATE H3K9 AND H3K27 SITES. THESE EPIGENETIC MARKS HAVE IMPORTANT ROLE IN THE CONTROL OF HETEROCHROMATIN SEGMENTS AND 3D FOLDING OF CHROMOSOMES, AS WELL AS THE GENETIC LOCI REGULATING CELL TYPE COMMITMENT, PROLIFERATION, AND CELLULAR SENESCENCE, E.G. THE INK4 BOX. A CHRONIC STIMULATION OF HIF-1ALPHA CAN PROVOKE TISSUE FIBROSIS AND CELLULAR SENESCENCE, WHICH BOTH ARE INCREASINGLY PRESENT WITH AGING AND AGE-RELATED DISEASES. WE WILL REVIEW THE REGULATION OF HIF-1ALPHA-DEPENDENT INDUCTION OF KDMS AND CLARIFY THEIR ROLE IN PATHOLOGICAL PROCESSES EMPHASIZING THAT LONG-TERM STRESS-RELATED INSULTS CAN IMPAIR THE MAINTENANCE OF CHROMATIN LANDSCAPE AND PROVOKE CELLULAR SENESCENCE AND TISSUE FIBROSIS ASSOCIATED WITH AGING AND AGE-RELATED DISEASES. 2016 4 4374 35 MISMATCH REPAIR PROTEINS RECRUIT DNA METHYLTRANSFERASE 1 TO SITES OF OXIDATIVE DNA DAMAGE. AT SITES OF CHRONIC INFLAMMATION, EPITHELIAL CELLS ARE EXPOSED TO HIGH LEVELS OF REACTIVE OXYGEN SPECIES AND UNDERGO CANCER-ASSOCIATED DNA METHYLATION CHANGES, SUGGESTING THAT INFLAMMATION MAY INITIATE EPIGENETIC ALTERATIONS. PREVIOUSLY, WE DEMONSTRATED THAT OXIDATIVE DAMAGE CAUSES EPIGENETIC SILENCING PROTEINS TO BECOME PART OF A LARGE COMPLEX THAT IS LOCALIZED TO GC-RICH REGIONS OF THE GENOME, INCLUDING PROMOTER CPG ISLANDS THAT ARE EPIGENETICALLY SILENCED IN CANCER. HOWEVER, WHETHER THESE PROTEINS WERE RECRUITED DIRECTLY TO DAMAGED DNA OR DURING THE DNA REPAIR PROCESS WAS UNKNOWN. HERE WE DEMONSTRATE THAT THE MISMATCH REPAIR PROTEIN HETERODIMER MSH2-MSH6 PARTICIPATES IN THE OXIDATIVE DAMAGE-INDUCED RECRUITMENT OF DNA METHYLTRANSFERASE 1 (DNMT1) TO CHROMATIN. HYDROGEN PEROXIDE TREATMENT INDUCES THE INTERACTION OF MSH2-MSH6 WITH DNMT1, SUGGESTING THAT THE RECRUITMENT IS THROUGH A PROTEIN-PROTEIN INTERACTION. IMPORTANTLY, THE REDUCTION IN TRANSCRIPTION FOR GENES WITH CPG ISLAND-CONTAINING PROMOTERS CAUSED BY OXIDATIVE DAMAGE IS ABROGATED BY KNOCKDOWN OF MSH6 AND/OR DNMT1. OUR FINDINGS PROVIDE EVIDENCE THAT THE ROLE OF DNMT1 AT SITES OF OXIDATIVE DAMAGE IS TO REDUCE TRANSCRIPTION, POTENTIALLY PREVENTING TRANSCRIPTION FROM INTERFERING WITH THE REPAIR PROCESS. THIS STUDY UNIQUELY BRINGS TOGETHER SEVERAL FACTORS THAT ARE KNOWN TO CONTRIBUTE TO COLON CANCER, NAMELY INFLAMMATION, MISMATCH REPAIR PROTEINS, AND EPIGENETIC CHANGES. 2016 5 3362 30 HISTONE LYSINE DEMETHYLASE KDM5B MAINTAINS CHRONIC MYELOID LEUKEMIA VIA MULTIPLE EPIGENETIC ACTIONS. THE HISTONE LYSINE DEMETHYLASE KDM5 FAMILY IS IMPLICATED IN NORMAL DEVELOPMENT AND STEM CELL MAINTENANCE BY EPIGENETIC MODULATION OF HISTONE METHYLATION STATUS. DEREGULATION OF THE KDM5 FAMILY HAS BEEN REPORTED IN VARIOUS TYPES OF CANCERS, INCLUDING HEMATOLOGICAL MALIGNANCIES. HOWEVER, THEIR TRANSCRIPTIONAL REGULATORY ROLES IN THE CONTEXT OF LEUKEMIA REMAIN UNCLEAR. HERE, WE FIND THAT KDM5B IS STRONGLY EXPRESSED IN NORMAL CD34(+) HEMATOPOIETIC STEM/PROGENITOR CELLS AND CHRONIC MYELOID LEUKEMIA (CML) CELLS. KNOCKDOWN OF KDM5B IN K562 CML CELLS REDUCED LEUKEMIA COLONY-FORMING POTENTIAL. TRANSCRIPTOME PROFILING OF KDM5B KNOCKDOWN K562 CELLS REVEALED THE DEREGULATION OF GENES INVOLVED IN MYELOID DIFFERENTIATION AND TOLL-LIKE RECEPTOR SIGNALING. THROUGH THE INTEGRATION OF TRANSCRIPTOME AND CHIP-SEQ PROFILING DATA, WE SHOW THAT KDM5B IS ENRICHED AT THE BINDING SITES OF THE GATA AND AP-1 TRANSCRIPTION FACTOR FAMILIES, SUGGESTING THEIR COLLABORATIONS IN THE REGULATION OF TRANSCRIPTION. EVEN THOUGH THE BINDING OF KDM5B SUBSTANTIALLY OVERLAPPED WITH H3K4ME1 OR H3K4ME3 MARK AT GENE PROMOTERS, ONLY A SMALL SUBSET OF THE KDM5B TARGETS SHOWED DIFFERENTIAL EXPRESSION IN ASSOCIATION WITH THE HISTONE DEMETHYLATION ACTIVITY. BY CHARACTERIZING THE INTERACTING PROTEINS IN K562 CELLS, WE DISCOVERED THAT KDM5B RECRUITS PROTEIN COMPLEXES INVOLVED IN THE MRNA PROCESSING MACHINERY, IMPLYING AN ALTERNATIVE EPIGENETIC ACTION MEDIATED BY KDM5B IN GENE REGULATION. OUR STUDY HIGHLIGHTS THE ONCOGENIC FUNCTIONS OF KDM5B IN CML CELLS AND SUGGESTS THAT KDM5B IS VITAL TO THE TRANSCRIPTIONAL REGULATION VIA MULTIPLE EPIGENETIC MECHANISMS. 2020 6 3470 30 HYPOXIA-INDUCIBLE KDM3A ADDICTION IN MULTIPLE MYELOMA. IN MULTIPLE MYELOMA (MM), THE BONE MARROW (BM) MICROENVIRONMENT MAY CONTAIN A MYELOMA CELL FRACTION THAT HAS ACQUIRED TREATMENT RESISTANCE BY UNDERGOING AN EPIGENETIC GENE EXPRESSION CHANGE. HYPOXIC STRESS IS AN IMPORTANT FACTOR IN THE BM MICROENVIRONMENT. RECENTLY, WE DEMONSTRATED THAT MIR-210 WAS UPREGULATED IN HYPOXIA AND DOWNREGULATED IRF4, WHICH IS KNOWN AS AN ESSENTIAL FACTOR IN MYELOMA ONCOGENESIS IN NORMOXIA. IN THE STUDY, WE DEMONSTRATED THAT MYELOMA CELLS STILL SHOWED A STRONG ANTIAPOPTOTIC PHENOTYPE DESPITE IRF4 DOWNREGULATION, SUGGESTING THAT ANOTHER ANTIAPOPTOTIC FACTOR MIGHT BE INVOLVED UNDER HYPOXIC STRESS. TO DETERMINE THE FACTOR OR FACTORS, WE CONDUCTED GENE EXPRESSION ANALYSIS ON MYELOMA CELLS (PRIMARY SAMPLES AND CELL LINES) THAT WERE EXPOSED TO CHRONIC HYPOXIA AND OBSERVED UPREGULATION OF GLYCOLYTIC GENES AND GENES ENCODING H3K9 DEMETHYLASES IN MYELOMA CELLS WITH HYPOXIA. AMONG THESE, KDM3A WAS MOST SIGNIFICANTLY UPREGULATED IN ALL EXAMINED CELLS, AND ITS KNOCKDOWN INDUCED APOPTOSIS OF MYELOMA CELLS IN CHRONIC HYPOXIA. EXPRESSION OF KDM3A WAS DEPENDENT ON HIF-1ALPHA, WHICH IS A TRANSCRIPTION FACTOR SPECIFICALLY UPREGULATED IN HYPOXIA. WE FURTHER DEMONSTRATED THAT AN ESSENTIAL TARGET OF KDM3A WAS A NONCODING GENE, MALAT1, WHOSE UPREGULATION CONTRIBUTED TO ACQUISITION OF AN ANTIAPOPTOTIC PHENOTYPE BY ACCUMULATION OF HIF-1ALPHA, LEADING TO UPREGULATION OF GLYCOLYTIC GENES UNDER HYPOXIA. THIS PROCESS WAS INDEPENDENT FROM IRF4. THESE RESULTS LED US TO CONCLUDE THAT THE HYPOXIA-INDUCIBLE HIF-1ALPHA-KDM3A-MALAT1 AXIS ALSO CONTRIBUTES TO ACQUISITION OF THE ANTIAPOPTOTIC PHENOTYPE VIA UPREGULATION OF GLYCOLYSIS-PROMOTING GENES. THUS, THIS AXIS IS A PROMISING THERAPEUTIC TARGET AGAINST MYELOMA CELLS IN THE BM MICROENVIRONMENT. 2018 7 4236 24 METHYLATION OF THE TYROSINE HYDROXYLASE GENE IS DYSREGULATED BY COCAINE DEPENDENCE IN THE HUMAN STRIATUM. COCAINE DEPENDENCE IS A CHRONIC, RELAPSING DISORDER CAUSED BY LASTING CHANGES IN THE BRAIN. ANIMAL STUDIES HAVE IDENTIFIED COCAINE-RELATED ALTERATIONS IN STRIATAL DNA METHYLATION; HOWEVER, IT IS UNCLEAR HOW METHYLATION IS RELATED TO COCAINE DEPENDENCE IN HUMANS. WE GENERATED METHYLOMIC PROFILES OF THE NUCLEUS ACCUMBENS USING HUMAN POSTMORTEM BRAINS FROM A COHORT OF INDIVIDUALS WITH COCAINE DEPENDENCE AND HEALTHY CONTROLS (N = 25 PER GROUP). WE FOUND HYPERMETHYLATION IN A CLUSTER OF CPGS WITHIN THE GENE BODY OF TYROSINE HYDROXYLASE (TH), CONTAINING A PUTATIVE BINDING SITE FOR THE EARLY GROWTH RESPONSE 1 (EGR1) TRANSCRIPTION FACTOR, WHICH IS HYPERMETHYLATED IN THE CAUDATE NUCLEUS OF COCAINE-DEPENDENT INDIVIDUALS. WE REPLICATED THIS FINDING AND FOUND IT TO BE SPECIFIC TO STRIATAL NEURONAL NUCLEI. FURTHERMORE, THIS LOCUS DEMONSTRATES ENHANCER ACTIVITY WHICH IS ATTENUATED BY METHYLATION AND ENHANCED BY EGR1 OVEREXPRESSION. THESE RESULTS SUGGEST THAT COCAINE DEPENDENCE ALTERS THE EPIGENETIC REGULATION OF DOPAMINERGIC SIGNALING GENES. 2021 8 3357 24 HISTONE H3 LYSINE 9 DI-METHYLATION AS AN EPIGENETIC SIGNATURE OF THE INTERFERON RESPONSE. EFFECTIVE ANTIVIRAL IMMUNITY DEPENDS ON THE ABILITY OF INFECTED CELLS OR CELLS TRIGGERED WITH VIRUS-DERIVED NUCLEIC ACIDS TO PRODUCE TYPE I INTERFERON (IFN), WHICH ACTIVATES TRANSCRIPTION OF NUMEROUS ANTIVIRAL GENES. HOWEVER, DISPROPORTIONATELY STRONG OR CHRONIC IFN EXPRESSION IS A COMMON CAUSE OF INFLAMMATORY AND AUTOIMMUNE DISEASES. WE DESCRIBE AN EPIGENETIC MECHANISM THAT DETERMINES CELL TYPE-SPECIFIC DIFFERENCES IN IFN AND IFN-STIMULATED GENE (ISG) EXPRESSION IN RESPONSE TO EXOGENOUS SIGNALS. WE IDENTIFY DI-METHYLATION OF HISTONE H3 AT LYSINE 9 (H3K9ME2) AS A SUPPRESSOR OF IFN AND IFN-INDUCIBLE ANTIVIRAL GENE EXPRESSION. WE SHOW THAT LEVELS OF H3K9ME2 AT IFN AND ISG CORRELATE INVERSELY WITH THE SCOPE AND AMPLITUDE OF IFN AND ISG EXPRESSION IN FIBROBLASTS AND DENDRITIC CELLS. ACCORDINGLY, GENETIC ABLATION OR PHARMACOLOGICAL INACTIVATION OF LYSINE METHYLTRANSFERASE G9A, WHICH IS ESSENTIAL FOR THE GENERATION OF H3K9ME2, RESULTED IN PHENOTYPIC CONVERSION OF FIBROBLASTS INTO HIGHLY POTENT IFN-PRODUCING CELLS AND RENDERED THESE CELLS RESISTANT TO PATHOGENIC RNA VIRUSES. IN SUMMARY, OUR STUDIES IMPLICATE H3K9ME2 AND ENZYMES CONTROLLING ITS ABUNDANCE AS KEY REGULATORS OF INNATE ANTIVIRAL IMMUNITY. 2012 9 3115 30 GEROMETABOLITES: THE PSEUDOHYPOXIC AGING SIDE OF CANCER ONCOMETABOLITES. ONCOMETABOLITES ARE DEFINED AS SMALL-MOLECULE COMPONENTS (OR ENANTIOMERS) OF NORMAL METABOLISM WHOSE ACCUMULATION CAUSES SIGNALING DYSREGULATION TO ESTABLISH A MILIEU THAT INITIATES CARCINOGENESIS. IN A SIMILAR MANNER, WE PROPOSE THE TERM "GEROMETABOLITES" TO REFER TO SMALL-MOLECULE COMPONENTS OF NORMAL METABOLISM WHOSE DEPLETION CAUSES SIGNALING DYSREGULATION TO ESTABLISH A MILIEU THAT DRIVES AGING. IN AN INVESTIGATION OF THE PATHOGENIC ACTIVITIES OF THE CURRENTLY RECOGNIZED ONCOMETABOLITES R(-)-2-HYDROXYGLUTARATE (2-HG), FUMARATE, AND SUCCINATE, WHICH ACCUMULATE DUE TO MUTATIONS IN ISOCITRATE DEHYDROGENASES (IDH), FUMARATE HYDRATASE (FH), AND SUCCINATE DEHYDROGENASE (SDH), RESPECTIVELY, WE ILLUSTRATE THE FACT THAT METABOLIC PSEUDOHYPOXIA, THE ACCUMULATION OF HYPOXIA-INDUCIBLE FACTOR (HIFALPHA) UNDER NORMOXIC CONDITIONS, AND THE SUBSEQUENT WARBURG-LIKE REPROGRAMMING THAT SHIFTS GLUCOSE METABOLISM FROM THE OXIDATIVE PATHWAY TO AEROBIC GLYCOLYSIS ARE THE SAME MECHANISMS THROUGH WHICH THE DECLINE OF THE "GEROMETABOLITE" NICOTINAMIDE ADENINE DINUCLEOTIDE (NAD)(+) REVERSIBLY DISRUPTS NUCLEAR-MITOCHONDRIAL COMMUNICATION AND CONTRIBUTES TO THE DECLINE IN MITOCHONDRIAL FUNCTION WITH AGE. FROM AN EVOLUTIONARY PERSPECTIVE, IT IS REASONABLE TO VIEW NAD(+)-DRIVEN MITOCHONDRIAL HOMEOSTASIS AS A CONSERVED RESPONSE TO CHANGES IN ENERGY SUPPLIES AND OXYGEN LEVELS. SIMILARLY, THE NATURAL ABILITY OF 2-HG TO SIGNIFICANTLY ALTER EPIGENETICS MIGHT REFLECT AN EVOLUTIONARILY ANCIENT ROLE OF CERTAIN METABOLITES TO SIGNAL FOR ELEVATED GLUTAMINE/GLUTAMATE METABOLISM AND/OR OXYGEN DEFICIENCY. HOWEVER, WHEN CHRONICALLY ALTERED, THESE RESPONSES BECOME CONSERVED CAUSES OF AGING AND CANCER. BECAUSE HIFALPHA-DRIVEN PSEUDOHYPOXIA MIGHT DRIVE THE OVERPRODUCTION OF 2-HG, THE INTRIGUING POSSIBILITY EXISTS THAT THE DECLINE OF GEROMETABOLITES SUCH AS NAD(+) COULD PROMOTE THE CHRONIC ACCUMULATION OF ONCOMETABOLITES IN NORMAL CELLS DURING AGING. IF THE SOLE ACTIVATION OF A WARBURG-LIKE METABOLIC REPROGRAMMING IN NORMAL TISSUES MIGHT BE ABLE TO SIGNIFICANTLY INCREASE THE ENDOGENOUS PRODUCTION OF BONA FIDE ETIOLOGICAL DETERMINANTS IN CANCER, SUCH AS ONCOMETABOLITES, THIS UNDESIRABLE TRADE-OFF BETWEEN MITOCHONDRIAL DYSFUNCTION AND ACTIVATION OF ONCOMETABOLITES PRODUCTION MIGHT THEN PAVE THE WAY FOR THE EPIGENETIC INITIATION OF CARCINOGENESIS IN A STRICTLY METABOLIC-DEPENDENT MANNER. PERHAPS IT IS TIME TO DEFINITELY ADOPT THE VIEW THAT AGING AND AGING DISEASES INCLUDING CANCER ARE GOVERNED BY A PIVOTAL REGULATORY ROLE OF METABOLIC REPROGRAMMING IN CELL FATE DECISIONS. 2014 10 2280 29 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 11 5795 31 STAT3 INDUCTION OF MIR-146B FORMS A FEEDBACK LOOP TO INHIBIT THE NF-KAPPAB TO IL-6 SIGNALING AXIS AND STAT3-DRIVEN CANCER PHENOTYPES. INTERLEUKIN-6 (IL-6)-MEDIATED ACTIVATION OF SIGNAL TRANSDUCER AND ACTIVATOR OF TRANSCRIPTION 3 (STAT3) IS A MECHANISM BY WHICH CHRONIC INFLAMMATION CAN CONTRIBUTE TO CANCER AND IS A COMMON ONCOGENIC EVENT. WE DISCOVERED A PATHWAY, THE LOSS OF WHICH IS ASSOCIATED WITH PERSISTENT STAT3 ACTIVATION IN HUMAN CANCER. WE FOUND THAT THE GENE ENCODING THE TUMOR SUPPRESSOR MICRORNA MIR-146B IS A DIRECT STAT3 TARGET GENE, AND ITS EXPRESSION WAS INCREASED IN NORMAL BREAST EPITHELIAL CELLS BUT DECREASED IN TUMOR CELLS. METHYLATION OF THE MIR-146B PROMOTER, WHICH INHIBITED STAT3-MEDIATED INDUCTION OF EXPRESSION, WAS INCREASED IN PRIMARY BREAST CANCERS. MOREOVER, WE FOUND THAT MIR-146B INHIBITED NUCLEAR FACTOR KAPPAB (NF-KAPPAB)-DEPENDENT PRODUCTION OF IL-6, SUBSEQUENT STAT3 ACTIVATION, AND IL-6/STAT3-DRIVEN MIGRATION AND INVASION IN BREAST CANCER CELLS, THEREBY ESTABLISHING A NEGATIVE FEEDBACK LOOP. IN ADDITION, HIGHER EXPRESSION OF MIR-146B WAS POSITIVELY CORRELATED WITH PATIENT SURVIVAL IN BREAST CANCER SUBTYPES WITH INCREASED IL6 EXPRESSION AND STAT3 PHOSPHORYLATION. OUR RESULTS IDENTIFY AN EPIGENETIC MECHANISM OF CROSSTALK BETWEEN STAT3 AND NF-KAPPAB RELEVANT TO CONSTITUTIVE STAT3 ACTIVATION IN MALIGNANCY AND THE ROLE OF INFLAMMATION IN ONCOGENESIS. 2014 12 3633 29 INCREASE IN HDAC9 SUPPRESSES MYOBLAST DIFFERENTIATION VIA EPIGENETIC REGULATION OF AUTOPHAGY IN HYPOXIA. EXTREMELY REDUCED OXYGEN (O(2)) LEVELS ARE DETRIMENTAL TO MYOGENIC DIFFERENTIATION AND MULTINUCLEATED MYOTUBE FORMATION, AND CHRONIC EXPOSURE TO HIGH-ALTITUDE HYPOXIA HAS BEEN REPORTED TO BE AN IMPORTANT FACTOR IN SKELETAL MUSCLE ATROPHY. HOWEVER, HOW CHRONIC HYPOXIA CAUSES MUSCLE DYSFUNCTION REMAINS UNKNOWN. IN THE PRESENT STUDY, WE FOUND THAT SEVERE HYPOXIA (1% O(2)) SIGNIFICANTLY INHIBITED THE FUNCTION OF C2C12 CELLS (FROM A MYOBLAST CELL LINE). IMPORTANTLY, THE IMPAIRMENT WAS CONTINUOUSLY MANIFESTED EVEN DURING CULTURE UNDER NORMOXIC CONDITIONS FOR SEVERAL PASSAGES. MECHANISTICALLY, WE REVEALED THAT HISTONE DEACETYLASES 9 (HDAC9), A MEMBER OF THE HISTONE DEACETYLASE FAMILY, WAS SIGNIFICANTLY INCREASED IN C2C12 CELLS UNDER HYPOXIC CONDITIONS, THEREBY INHIBITING INTRACELLULAR AUTOPHAGY LEVELS BY DIRECTLY BINDING TO THE PROMOTER REGIONS OF ATG7, BECLIN1, AND LC3. THIS PHENOMENON RESULTED IN THE SEQUENTIAL DEPHOSPHORYLATION OF GSK3BETA AND INACTIVATION OF THE CANONICAL WNT PATHWAY, IMPAIRING THE FUNCTION OF THE C2C12 CELLS. TAKEN TOGETHER, OUR RESULTS SUGGEST THAT HYPOXIA-INDUCED MYOBLAST DYSFUNCTION IS DUE TO ABERRANT EPIGENETIC REGULATION OF AUTOPHAGY, AND OUR EXPERIMENTAL EVIDENCE REVEALS THE POSSIBLE MOLECULAR PATHOGENESIS RESPONSIBLE FOR SOME MUSCLE DISEASES CAUSED BY CHRONIC HYPOXIA AND SUGGESTS A POTENTIAL THERAPEUTIC OPTION. 2019 13 1614 29 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 14 4497 35 MORPHINE LEADS TO GLOBAL GENOME CHANGES IN H3K27ME3 LEVELS VIA A POLYCOMB REPRESSIVE COMPLEX 2 (PRC2) SELF-REGULATORY MECHANISM IN MESCS. BACKGROUND: ENVIRONMENTALLY INDUCED EPIGENETIC CHANGES CAN LEAD TO HEALTH PROBLEMS OR DISEASE, BUT THE MECHANISMS INVOLVED REMAIN UNCLEAR. MORPHINE CAN PASS THROUGH THE PLACENTAL BARRIER LEADING TO ABNORMAL EMBRYO DEVELOPMENT. HOWEVER, THE MECHANISM BY WHICH MORPHINE CAUSES THESE EFFECTS AND HOW THEY SOMETIMES PERSIST INTO ADULTHOOD IS NOT WELL KNOWN. TO UNRAVEL THE MORPHINE-INDUCED CHROMATIN ALTERATIONS INVOLVED IN ABERRANT EMBRYO DEVELOPMENT, WE EXPLORED THE ROLE OF THE H3K27ME3/PRC2 REPRESSIVE COMPLEX IN GENE EXPRESSION AND ITS TRANSMISSION ACROSS CELLULAR GENERATIONS IN RESPONSE TO MORPHINE. RESULTS: USING MOUSE EMBRYONIC STEM CELLS AS A MODEL SYSTEM, WE FOUND THAT CHRONIC MORPHINE TREATMENT INDUCES A GLOBAL DOWNREGULATION OF THE HISTONE MODIFICATION H3K27ME3. CONVERSELY, CHIP-SEQ SHOWED A REMARKABLE INCREASE IN H3K27ME3 LEVELS AT SPECIFIC GENOMIC SITES, PARTICULARLY PROMOTERS, DISRUPTING SELECTIVE TARGET GENES RELATED TO EMBRYO DEVELOPMENT, CELL CYCLE AND METABOLISM. THROUGH A SELF-REGULATORY MECHANISM, MORPHINE DOWNREGULATED THE TRANSCRIPTION OF PRC2 COMPONENTS RESPONSIBLE FOR H3K27ME3 BY ENRICHING HIGH H3K27ME3 LEVELS AT THE PROMOTER REGION. DOWNREGULATION OF PRC2 COMPONENTS PERSISTED FOR AT LEAST 48 H (4 CELL CYCLES) FOLLOWING MORPHINE REMOVAL, THOUGH PROMOTER H3K27ME3 LEVELS RETURNED TO CONTROL LEVELS. CONCLUSIONS: MORPHINE INDUCES TARGETING OF THE PRC2 COMPLEX TO SELECTED PROMOTERS, INCLUDING THOSE OF PRC2 COMPONENTS, LEADING TO CHARACTERISTIC CHANGES IN GENE EXPRESSION AND A GLOBAL REDUCTION IN H3K27ME3. FOLLOWING MORPHINE REMOVAL, ENHANCED PROMOTER H3K27ME3 LEVELS REVERT TO NORMAL SOONER THAN GLOBAL H3K27ME3 OR PRC2 COMPONENT TRANSCRIPT LEVELS. WE SUGGEST THAT H3K27ME3 IS INVOLVED IN INITIATING MORPHINE-INDUCED CHANGES IN GENE EXPRESSION, BUT NOT IN THEIR MAINTENANCE. MODEL OF POLYCOMB REPRESSIVE COMPLEX 2 (PRC2) AND H3K27ME3 ALTERATIONS INDUCED BY CHRONIC MORPHINE EXPOSURE. MORPHINE INDUCES H3K27ME3 ENRICHMENT AT PROMOTERS OF GENES ENCODING CORE MEMBERS OF THE PRC2 COMPLEX AND IS ASSOCIATED WITH THEIR TRANSCRIPTIONAL DOWNREGULATION. 2020 15 598 17 BETA-ADRENERGIC SIGNALING PROMOTES TUMOR ANGIOGENESIS AND PROSTATE CANCER PROGRESSION THROUGH HDAC2-MEDIATED SUPPRESSION OF THROMBOSPONDIN-1. CHRONIC BEHAVIORAL STRESS AND BETA-ADRENERGIC SIGNALING HAVE BEEN SHOWN TO PROMOTE CANCER PROGRESSION, WHOSE UNDERLYING MECHANISMS ARE LARGELY UNCLEAR, ESPECIALLY THE INVOLVEMENT OF EPIGENETIC REGULATION. HISTONE DEACETYLASE-2 (HDAC2), AN EPIGENETIC REGULATOR, IS CRITICAL FOR STRESS-INDUCED CARDIAC HYPERTROPHY. IT IS UNKNOWN WHETHER IT IS NECESSARY FOR BETA-ADRENERGIC SIGNALING-PROMOTED CANCER PROGRESSION. USING XENOGRAFT MODELS, WE SHOWED THAT CHRONIC BEHAVIORAL STRESS AND BETA-ADRENERGIC SIGNALING PROMOTE ANGIOGENESIS AND PROSTATE CANCER PROGRESSION. HDAC2 WAS INDUCED BY BETA-ADRENERGIC SIGNALING IN VITRO AND IN MOUSE XENOGRAFTS. WE NEXT UNCOVERED THAT HDAC2 IS A DIRECT TARGET OF CAMP RESPONSE ELEMENT-BINDING PROTEIN (CREB) THAT IS ACTIVATED BY BETA-ADRENERGIC SIGNALING. NOTABLY, HDAC2 IS NECESSARY FOR BETA-ADRENERGIC SIGNALING TO INDUCE ANGIOGENESIS. WE FURTHER DEMONSTRATED THAT, UPON CREB ACTIVATION, HDAC2 REPRESSES THROMBOSPONDIN-1 (TSP1), A POTENT ANGIOGENESIS INHIBITOR, THROUGH EPIGENETIC REGULATION. TOGETHER, THESE DATA ESTABLISH A NOVEL PATHWAY THAT HDAC2 AND TSP1 ACT DOWNSTREAM OF CREB ACTIVATION IN BETA-ADRENERGIC SIGNALING TO PROMOTE CANCER PROGRESSION. 2017 16 3781 27 INTERFERON SIGNATURE IN PATIENTS WITH STAT1 GAIN-OF-FUNCTION MUTATION IS EPIGENETICALLY DETERMINED. STAT1 GAIN-OF-FUNCTION (GOF) VARIANTS LEAD TO DEFECTIVE TH17 CELL DEVELOPMENT AND CHRONIC MUCOCUTANEOUS CANDIDIASIS (CMC), BUT FREQUENTLY ALSO TO AUTOIMMUNITY. STIMULATION OF CELLS WITH STAT1 INDUCING CYTOKINES LIKE INTERFERONS (IFN) RESULT IN HYPERPHOSPHORYLATION AND DELAYED DEPHOSPHORYLATION OF GOF STAT1. HOWEVER, THE MECHANISM HOW THE DELAYED DEPHOSPHORYLATION EXACTLY CAUSES THE INCREASED EXPRESSION OF STAT1-DEPENDENT GENES, AND HOW THE INTRACELLULAR SIGNAL TRANSDUCTION FROM CYTOKINE RECEPTORS IS AFFECTED, REMAINS UNKNOWN. IN THIS STUDY WE SHOW THAT THE CIRCULATING LEVELS OF IFN-ALPHA WERE NOT PERSISTENTLY ELEVATED IN STAT1 GOF PATIENTS. NEVERTHELESS, THE EXPRESSION OF INTERFERON SIGNATURE GENES WAS EVIDENT EVEN IN THE PATIENT WITH LOW OR UNDETECTABLE SERUM IFN-ALPHA LEVELS. CHROMATIN IMMUNOPRECIPITATION (CHIP) EXPERIMENTS REVEALED THAT THE ACTIVE CHROMATIN MARK TRIMETHYLATION OF LYSINE 4 OF HISTONE 3 (H3K4ME3), WAS SIGNIFICANTLY ENRICHED IN AREAS ASSOCIATED WITH INTERFERON-STIMULATED GENES IN STAT1 GOF CELLS IN COMPARISON TO CELLS FROM HEALTHY DONORS. THIS SUGGESTS THAT THE CHROMATIN BINDING OF GOF STAT1 VARIANT PROMOTES EPIGENETIC CHANGES COMPATIBLE WITH HIGHER GENE EXPRESSION AND ELEVATED REACTIVITY TO TYPE I INTERFERONS, AND POSSIBLY PREDISPOSES FOR INTERFERON-RELATED AUTOIMMUNITY. THE RESULTS ALSO SUGGEST THAT EPIGENETIC REWIRING MAY BE RESPONSIBLE FOR TREATMENT FAILURE OF JANUS KINASE 1/2 (JAK1/2) INHIBITORS IN CERTAIN PATIENTS. 2019 17 211 20 ACTIVITY-DEPENDENT A-TO-I RNA EDITING IN RAT CORTICAL NEURONS. CHANGES IN NEURAL ACTIVITY INFLUENCE SYNAPTIC PLASTICITY/SCALING, GENE EXPRESSION, AND EPIGENETIC MODIFICATIONS. WE PRESENT THE FIRST EVIDENCE THAT SHORT-TERM AND PERSISTENT CHANGES IN NEURAL ACTIVITY CAN ALTER ADENOSINE-TO-INOSINE (A-TO-I) RNA EDITING, A POST-TRANSCRIPTIONAL SITE-SPECIFIC MODIFICATION FOUND IN SEVERAL NEURON-SPECIFIC TRANSCRIPTS. IN RAT CORTICAL NEURON CULTURES, ACTIVITY-DEPENDENT CHANGES IN A-TO-I RNA EDITING IN CODING EXONS ARE PRESENT AFTER 6 HR OF HIGH POTASSIUM DEPOLARIZATION BUT NOT AFTER 1 HR AND REQUIRE CALCIUM ENTRY INTO NEURONS. WHEN TREATMENTS ARE EXTENDED FROM HOURS TO DAYS, WE OBSERVE A NEGATIVE FEEDBACK PHENOMENON: CHRONIC DEPOLARIZATION INCREASES EDITING AT MANY SITES AND CHRONIC SILENCING DECREASES EDITING. WE PRESENT SEVERAL DIFFERENT MODULATIONS OF NEURAL ACTIVITY THAT CHANGE THE EXPRESSION OF DIFFERENT MRNA ISOFORMS THROUGH EDITING. 2012 18 5279 20 PROMOTER-SPECIFIC RELEVANCE OF HISTONE MODIFICATIONS INDUCED BY DEXAMETHASONE DURING THE REGULATION OF PRO-INFLAMMATORY MEDIATORS. GLUCOCORTICOSTEROIDS (GCS) ARE WIDELY USED TO TREAT DIFFERENT KINDS OF CHRONIC INFLAMMATORY AND IMMUNE DISEASES THROUGH TRANSCRIPTIONAL REGULATION OF INFLAMMATORY GENES. MODULATION OF GENE EXPRESSION BY GCS IS KNOWN TO OCCUR THROUGH DIVERSE MECHANISMS OF VARYING RELEVANCE TO SPECIFIC CLASSES OF GENES. EPIGENETIC MODIFICATIONS ARE INDEED A PIVOTAL REGULATORY FEATURE OF GLUCOCORTICOID RECEPTOR AND OTHER TRANSCRIPTION FACTORS. IN THIS STUDY, HISTONE POST-TRANSLATIONAL MODIFICATIONS WERE INVESTIGATED FOR THEIR INVOLVEMENT IN THE REGULATION OF SELECTED PRO-INFLAMMATORY GENES - EXPRESSED IN HUMAN MONOCYTE-DERIVED MACROPHAGES - IN RESPONSE TO TREATMENT WITH SYNTHETIC GC DEXAMETHASONE (DEX). WE SHOW THAT HISTONE TAIL ACETYLATION STATUS IS MODIFIED FOLLOWING DEX ADMINISTRATION, THROUGH DISTINCT AND ALTERNATIVE MECHANISMS AT THE PROMOTERS OF INTERLEUKIN-8 AND INTERLEUKIN-23. IN ADDITION TO HISTONE H3 ACETYLATION, OUR RESULTS DEMONSTRATE THAT H3 LYSINE 4 TRIMETHYLATION IS AFFECTED FOLLOWING DRUG TREATMENT. 2014 19 1656 27 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 1562 29 DNA METHYLATION OF ENHANCER ELEMENTS IN MYELOID NEOPLASMS: THINK OUTSIDE THE PROMOTERS? GENE REGULATION THROUGH DNA METHYLATION IS A WELL DESCRIBED PHENOMENON THAT HAS A PROMINENT ROLE IN PHYSIOLOGICAL AND PATHOLOGICAL CELL-STATES. THIS EPIGENETIC MODIFICATION IS USUALLY GROUPED IN REGIONS DENOMINATED CPG ISLANDS, WHICH FREQUENTLY CO-LOCALIZE WITH GENE PROMOTERS, SILENCING THE TRANSCRIPTION OF THOSE GENES. RECENT GENOME-WIDE DNA METHYLATION STUDIES HAVE CHALLENGED THIS PARADIGM, DEMONSTRATING THAT DNA METHYLATION OF REGULATORY REGIONS OUTSIDE PROMOTERS IS ABLE TO INFLUENCE CELL-TYPE SPECIFIC GENE EXPRESSION PROGRAMS UNDER PHYSIOLOGIC OR PATHOLOGIC CONDITIONS. COUPLING GENOME-WIDE DNA METHYLATION ASSAYS WITH HISTONE MARK ANNOTATION HAS ALLOWED FOR THE IDENTIFICATION OF SPECIFIC EPIGENOMIC CHANGES THAT AFFECT ENHANCER REGULATORY REGIONS, REVEALING AN ADDITIONAL LAYER OF COMPLEXITY TO THE EPIGENETIC REGULATION OF GENE EXPRESSION. IN THIS REVIEW, WE SUMMARIZE THE NOVEL EVIDENCE FOR THE MOLECULAR AND BIOLOGICAL REGULATION OF DNA METHYLATION IN ENHANCER REGIONS AND THE DYNAMISM OF THESE CHANGES CONTRIBUTING TO THE FINE-TUNING OF GENE EXPRESSION. WE ALSO ANALYZE THE CONTRIBUTION OF ENHANCER DNA METHYLATION ON THE EXPRESSION OF RELEVANT GENES IN ACUTE MYELOID LEUKEMIA AND CHRONIC MYELOPROLIFERATIVE NEOPLASMS. THE CHARACTERIZATION OF THE ABERRANT ENHANCER DNA METHYLATION PROVIDES NOT ONLY A NOVEL PATHOGENIC MECHANISM FOR DIFFERENT TUMORS BUT ALSO HIGHLIGHTS NOVEL POTENTIAL THERAPEUTIC TARGETS FOR MYELOID DERIVED NEOPLASMS. 2019