1 3840 144 IRON DEFICIENCY REPROGRAMS PHOSPHORYLATION SIGNALING AND REDUCES O-GLCNAC PATHWAYS IN NEURONAL CELLS. MICRONUTRIENT SENSING IS CRITICAL FOR CELLULAR GROWTH AND DIFFERENTIATION. DEFICIENCIES IN ESSENTIAL NUTRIENTS SUCH AS IRON STRONGLY AFFECT NEURONAL CELL DEVELOPMENT AND MAY LEAD TO DEFECTS IN NEURONAL FUNCTION THAT CANNOT BE REMEDIED BY SUBSEQUENT IRON SUPPLEMENTATION. TO UNDERSTAND THE ADAPTIVE INTRACELLULAR RESPONSES TO IRON DEFICIENCY IN NEURONAL CELLS, WE DEVELOPED AND UTILIZED A STABLE ISOTOPIC LABELING OF AMINO ACIDS IN CELL CULTURE (SILAC)-BASED QUANTITATIVE PHOSPHOPROTEOMICS WORKFLOW. OUR INTEGRATED APPROACH WAS DESIGNED TO COMPREHENSIVELY ELUCIDATE THE CHANGES IN PHOSPHORYLATION SIGNALING UNDER BOTH ACUTE AND CHRONIC IRON-DEFICIENT CELL MODELS. IN ADDITION, WE ANALYZED THE DIFFERENTIAL CELLULAR RESPONSES BETWEEN IRON DEFICIENCY AND HYPOXIA (OXYGEN-DEPRIVED) IN NEURONAL CELLS. OUR ANALYSIS IDENTIFIED NEARLY 16,000 PHOSPHORYLATION SITES IN HT-22 CELLS, A HIPPOCAMPAL-DERIVED NEURONAL CELL LINE, MORE THAN TEN PERCENT OF WHICH SHOWED AT LEAST 2-FOLD CHANGES IN RESPONSE TO EITHER HYPOXIA OR ACUTE/CHRONIC IRON DEFICIENCY. BIOINFORMATIC ANALYSIS REVEALED THAT IRON DEFICIENCY ALTERED KEY METABOLIC AND EPIGENETIC PATHWAYS INCLUDING THE PHOSPHORYLATION OF PROTEINS INVOLVED IN IRON SEQUESTRATION, GLUTAMATE METABOLISM, AND HISTONE METHYLATION. IN PARTICULAR, IRON DEFICIENCY INCREASED GLUTAMINE-FRUCTOSE-6-PHOSPHATE TRANSAMINASE (GFPT1) PHOSPHORYLATION, WHICH IS A KEY ENZYME IN THE GLUCOSAMINE BIOSYNTHESIS PATHWAY AND A TARGET OF 5' AMP-ACTIVATED PROTEIN KINASE (AMPK), LEADING TO REDUCED GFPT1 ENZYMATIC ACTIVITY AND CONSEQUENTLY LOWER GLOBAL O-GLCNAC MODIFICATION IN NEURONAL CELLS. TAKEN TOGETHER, OUR ANALYSIS OF THE PHOSPHOPROTEOME DYNAMICS IN RESPONSE TO IRON AND OXYGEN DEPRIVATION DEMONSTRATED AN ADAPTIVE CELLULAR RESPONSE BY MOUNTING POST-TRANSLATIONAL MODIFICATIONS THAT ARE CRITICAL FOR INTRACELLULAR SIGNALING AND EPIGENETIC PROGRAMMING IN NEURONAL CELLS. 2021 2 2002 31 EPIGENETIC AND POST-TRANSCRIPTIONAL REPRESSION SUPPORT METABOLIC SUPPRESSION IN CHRONICALLY HYPOXIC GOLDFISH. GOLDFISH ENTER A HYPOMETABOLIC STATE TO SURVIVE CHRONIC HYPOXIA. WE RECENTLY DESCRIBED TISSUE-SPECIFIC CONTRIBUTIONS OF MEMBRANE LIPID COMPOSITION REMODELING AND MITOCHONDRIAL FUNCTION TO METABOLIC SUPPRESSION ACROSS DIFFERENT GOLDFISH TISSUES. HOWEVER, THE MOLECULAR AND ESPECIALLY EPIGENETIC FOUNDATIONS OF HYPOXIA TOLERANCE IN GOLDFISH UNDER METABOLIC SUPPRESSION ARE NOT WELL UNDERSTOOD. HERE WE SHOW THAT COMPONENTS OF THE MOLECULAR OXYGEN-SENSING MACHINERY ARE ROBUSTLY ACTIVATED ACROSS TISSUES IRRESPECTIVE OF HYPOXIA DURATION. INDUCTION OF GENE EXPRESSION OF ENZYMES INVOLVED IN DNA METHYLATION TURNOVER AND MICRORNA BIOGENESIS SUGGEST A ROLE FOR EPIGENETIC TRANSCRIPTIONAL AND POST-TRANSCRIPTIONAL SUPPRESSION OF GENE EXPRESSION IN THE HYPOXIA-ACCLIMATED BRAIN. CONVERSELY, MECHANISTIC TARGET OF RAPAMYCIN-DEPENDENT TRANSLATIONAL MACHINERY ACTIVITY IS NOT REDUCED IN LIVER AND WHITE MUSCLE, SUGGESTING THIS PATHWAY DOES NOT CONTRIBUTE TO LOWERING CELLULAR ENERGY EXPENDITURE. FINALLY, MOLECULAR EVIDENCE SUPPORTS PREVIOUSLY REPORTED CHRONIC HYPOXIA-DEPENDENT CHANGES IN MEMBRANE CHOLESTEROL, LIPID METABOLISM AND MITOCHONDRIAL FUNCTION VIA CHANGES IN TRANSCRIPTS INVOLVED IN CHOLESTEROL BIOSYNTHESIS, BETA-OXIDATION, AND MITOCHONDRIAL FUSION IN MULTIPLE TISSUES. OVERALL, THIS STUDY SHOWS THAT CHRONIC HYPOXIA ROBUSTLY INDUCES EXPRESSION OF OXYGEN-SENSING MACHINERY ACROSS TISSUES, INDUCES REPRESSIVE TRANSCRIPTIONAL AND POST-TRANSCRIPTIONAL EPIGENETIC MARKS ESPECIALLY IN THE CHRONIC HYPOXIA-ACCLIMATED BRAIN AND SUPPORTS A ROLE FOR MEMBRANE REMODELING AND MITOCHONDRIAL FUNCTION AND DYNAMICS IN PROMOTING METABOLIC SUPPRESSION. 2022 3 1326 26 DEPLETION OF NUCLEAR HISTONE H2A VARIANTS IS ASSOCIATED WITH CHRONIC DNA DAMAGE SIGNALING UPON DRUG-EVOKED SENESCENCE OF HUMAN SOMATIC CELLS. CELLULAR SENESCENCE IS ASSOCIATED WITH GLOBAL CHROMATIN CHANGES, ALTERED GENE EXPRESSION, AND ACTIVATION OF CHRONIC DNA DAMAGE SIGNALING. THESE EVENTS ULTIMATELY LEAD TO MORPHOLOGICAL AND PHYSIOLOGICAL TRANSFORMATIONS IN PRIMARY CELLS. IN THIS STUDY, WE SHOW THAT CHRONIC DNA DAMAGE SIGNALS CAUSED BY GENOTOXIC STRESS IMPACT THE EXPRESSION OF HISTONES H2A FAMILY MEMBERS AND LEAD TO THEIR DEPLETION IN THE NUCLEI OF SENESCENT HUMAN FIBROBLASTS. OUR DATA REINFORCE THE HYPOTHESIS THAT PROGRESSIVE CHROMATIN DESTABILIZATION MAY LEAD TO THE LOSS OF EPIGENETIC INFORMATION AND IMPAIRED CELLULAR FUNCTION ASSOCIATED WITH CHRONIC DNA DAMAGE UPON DRUG-EVOKED SENESCENCE. WE PROPOSE THAT CHANGES IN THE HISTONE BIOSYNTHESIS AND CHROMATIN ASSEMBLY MAY DIRECTLY CONTRIBUTE TO CELLULAR AGING. IN ADDITION, WE ALSO OUTLINE THE METHOD THAT ALLOWS FOR QUANTITATIVE AND UNBIASED MEASUREMENT OF THESE CHANGES. 2012 4 4768 31 NUCLEAR EFFECTS OF ETHANOL-INDUCED PROTEASOME INHIBITION IN LIVER CELLS. ALCOHOL INGESTION CAUSES ALTERATION IN SEVERAL CELLULAR MECHANISMS, AND LEADS TO INFLAMMATION, APOPTOSIS, IMMUNOLOGICAL RESPONSE DEFECTS, AND FIBROSIS. THESE PHENOMENA ARE ASSOCIATED WITH SIGNIFICANT CHANGES IN THE EPIGENETIC MECHANISMS, AND SUBSEQUENTLY, TO LIVER CELL MEMORY. THE UBIQUITIN-PROTEASOME PATHWAY IS ONE OF THE VITAL PATHWAYS IN THE CELL THAT BECOMES DYSFUNCTIONAL AS A RESULT OF CHRONIC ETHANOL CONSUMPTION. INHIBITION OF THE PROTEASOME ACTIVITY IN THE NUCLEUS CAUSES CHANGES IN THE TURNOVER OF TRANSCRIPTIONAL FACTORS, HISTONE MODIFYING ENZYMES, AND THEREFORE, AFFECTS EPIGENETIC MECHANISMS. ALCOHOL CONSUMPTION HAS BEEN ASSOCIATED WITH AN INCREASE IN HISTONE ACETYLATION AND A DECREASE IN HISTONE METHYLATION, WHICH LEADS TO GENE EXPRESSION CHANGES. DNA AND HISTONE MODIFICATIONS THAT RESULT FROM ETHANOL-INDUCED PROTEASOME INHIBITION ARE KEY PLAYERS IN REGULATING GENE EXPRESSION, ESPECIALLY GENES INVOLVED IN THE CELL CYCLE, IMMUNOLOGICAL RESPONSES, AND METABOLISM OF ETHANOL. THE PRESENT REVIEW HIGHLIGHTS THE CONSEQUENCES OF ETHANOL-INDUCED PROTEASOME INHIBITION IN THE NUCLEUS OF LIVER CELLS THAT ARE CHRONICALLY EXPOSED TO ETHANOL. 2009 5 2119 31 EPIGENETIC HISTONE MODIFICATION REGULATES DEVELOPMENTAL LEAD EXPOSURE INDUCED HYPERACTIVITY IN RATS. LEAD (PB) EXPOSURE WAS COMMONLY CONSIDERED AS A HIGH ENVIRONMENTAL RISK FACTOR FOR THE DEVELOPMENT OF ATTENTION-DEFICIT/HYPERACTIVITY DISORDER (ADHD). HOWEVER, THE MOLECULAR BASIS OF THIS PATHOLOGICAL PROCESS STILL REMAINS ELUSIVE. IN LIGHT OF THE ROLE OF EPIGENETICS IN MODULATING THE NEUROLOGICAL DISEASE AND THE CAUSATIVE ENVIRONMENT, THE ALTERATIONS OF HISTONE MODIFICATIONS IN THE HIPPOCAMPUS OF RATS EXPOSED BY VARIOUS DOSES OF LEAD, ALONG WITH CONCOMITANT BEHAVIORAL DEFICITS, WERE INVESTIGATED IN THIS STUDY. ACCORDING TO THE FREE AND FORCED OPEN FIELD TEST, THERE SHOWED THAT IN A DOSAGE-DEPENDENT MANNER, LEAD EXPOSURE COULD RESULT IN THE INCREASED LOCOMOTOR ACTIVITY OF RATS, THAT IS, HYPERACTIVITY: A SUBTYPE OF ADHD. WESTERN BLOTTING ASSAYS REVEALED THAT THE LEVELS OF HISTONE ACETYLATION INCREASED SIGNIFICANTLY IN THE HIPPOCAMPUS BY CHRONIC LEAD EXPOSURE, WHILE NO DRAMATIC CHANGES WERE DETECTED IN TERMS OF EXPRESSION YIELDS OF ADHD-RELATED DOPAMINERGIC PROTEINS, INDICATING THAT HISTONE ACETYLATION PLAYS ESSENTIAL ROLES IN THIS TOXICANT-INVOLVED PATHOGENESIS. IN ADDITION, THE INCREASED LEVEL OF HISTONE ACETYLATION MIGHT BE ATTRIBUTED TO THE ENZYMATIC ACTIVITY OF P300, A TYPICAL HISTONE ACETYLTRANSFERASE, AS THE TRANSCRIPTIONAL LEVEL OF P300 WAS SIGNIFICANTLY INCREASED UPON HIGHER-DOSE PB EXPOSURE. IN SUMMARY, THIS STUDY FIRST DISCOVERED THE EPIGENETIC MECHANISM BRIDGING THE ENVIRONMENTAL INFLUENCE (PB) AND THE DISEASE ITSELF (ADHD) IN THE HISTONE MODIFICATION LEVEL, PAVING THE WAY FOR THE COMPREHENSIVE UNDERSTANDING OF ADHD'S ETIOLOGY AND IN FURTHER STEPS, ESTABLISHING THE THERAPY STRATEGY OF THIS WIDESPREAD NEUROLOGICAL DISORDER. 2014 6 3527 38 IL-6 ENHANCES THE NUCLEAR TRANSLOCATION OF DNA CYTOSINE-5-METHYLTRANSFERASE 1 (DNMT1) VIA PHOSPHORYLATION OF THE NUCLEAR LOCALIZATION SEQUENCE BY THE AKT KINASE. THE EPIGENETIC PROGRAMMING OF GENOMIC DNA IS ACCOMPLISHED, IN PART, BY SEVERAL DNA CYTOSINE-5-METHYLTRANSFERASES THAT ACT BY COVALENTLY MODIFYING CYTOSINES WITH THE ADDITION OF A METHYL GROUP. THIS COVALENT MODIFICATION IS MAINTAINED BY THE DNA CYTOSINE-5-METHYLTRANSFERASE-1 ENZYME (DNMT1), WHICH IS CAPABLE OF ACTING IN CONCERT WITH OTHER SIMILAR ENZYMES TO SILENCE IMPORTANT TUMOR SUPPRESSOR GENES. IL-6 IS A MULTIFUNCTIONAL MEDIATOR OF INFLAMMATION, ACTING THROUGH SEVERAL MAJOR SIGNALING CASCADES, INCLUDING THE PHOSPHATIDYLINOSITOL-3-KINASE PATHWAY (PI-3-K), WHICH ACTIVATES PROTEIN KINASE B (AKT/PKB) DOWNSTREAM. HERE, WE SHOW THAT THE SUBCELLULAR LOCALIZATION OF DNMT1 CAN BE ALTERED BY THE ADDITION OF IL-6, INCREASING THE RATE OF NUCLEAR TRANSLOCATION OF THE ENZYME FROM THE CYTOSOLIC COMPARTMENT. THE MECHANISM OF NUCLEAR TRANSLOCATION OF DNMT1 IS GREATLY ENHANCED BY PHOSPHORYLATION OF THE DNMT1 NUCLEAR LOCALIZATION SIGNAL (NLS) BY PKB/AKT KINASE. MUTAGENIC ALTERATION OF THE TWO AKT TARGET AMINO ACIDS WITHIN THE NLS RESULTS IN A MAJOR LOSS OF DNMT1 NUCLEAR TRANSLOCATION, WHILE THE CREATION OF A "PHOSPHO-MIMIC" AMINO ACID (MUTATION TO ACIDIC RESIDUES) RESTORES THIS COMPARTMENTATION ABILITY. THESE OBSERVATIONS SUGGEST AN INTERESTING HYPOTHESIS REGARDING HOW MEDIATORS OF CHRONIC INFLAMMATION MAY DISTURB THE DELICATE BALANCE OF CELLULAR COMPARTMENTALIZATION OF IMPORTANT PROTEINS, AND REVEALS A POTENTIAL MECHANISM FOR THE INDUCTION OR ENHANCEMENT OF TUMOR GROWTH VIA ALTERATION OF THE COMPONENTS INVOLVED IN THE EPIGENETIC PROGRAMMING OF A CELL. 2007 7 2926 34 GENERATION OF AN EPIGENETIC SIGNATURE BY CHRONIC HYPOXIA IN PROSTATE CELLS. INCREASING LEVELS OF TISSUE HYPOXIA HAVE BEEN REPORTED AS A NATURAL FEATURE OF THE AGING PROSTATE GLAND AND MAY BE A RISK FACTOR FOR THE DEVELOPMENT OF PROSTATE CANCER. IN THIS STUDY, WE HAVE USED PWR-1E BENIGN PROSTATE EPITHELIAL CELLS AND AN EQUIVALENTLY AGED HYPOXIA-ADAPTED PWR-1E SUB-LINE TO IDENTIFY PHENOTYPIC AND EPIGENETIC CONSEQUENCES OF CHRONIC HYPOXIA IN PROSTATE CELLS. WE HAVE IDENTIFIED A SIGNIFICANTLY ALTERED CELLULAR PHENOTYPE IN RESPONSE TO CHRONIC HYPOXIA AS CHARACTERIZED BY INCREASED RECEPTOR-MEDIATED APOPTOTIC RESISTANCE, THE INDUCTION OF CELLULAR SENESCENCE, INCREASED INVASION AND THE INCREASED SECRETION OF IL-1 BETA, IL6, IL8 AND TNFALPHA CYTOKINES. IN ASSOCIATION WITH THESE PHENOTYPIC CHANGES AND THE ABSENCE OF HIF-1 ALPHA PROTEIN EXPRESSION, WE HAVE DEMONSTRATED SIGNIFICANT INCREASES IN GLOBAL LEVELS OF DNA METHYLATION AND H3K9 HISTONE ACETYLATION IN THESE CELLS, CONCOMITANT WITH THE INCREASED EXPRESSION OF DNA METHYLTRANSFERASE DMNT3B AND GENE-SPECIFIC CHANGES IN DNA METHYLATION AT KEY IMPRINTING LOCI. IN CONCLUSION, WE HAVE DEMONSTRATED A GENOME-WIDE ADJUSTMENT OF DNA METHYLATION AND HISTONE ACETYLATION UNDER CHRONIC HYPOXIC CONDITIONS IN THE PROSTATE. THESE EPIGENETIC SIGNATURES MAY REPRESENT AN ADDITIONAL MECHANISM TO PROMOTE AND MAINTAIN A HYPOXIC-ADAPTED CELLULAR PHENOTYPE WITH A POTENTIAL ROLE IN TUMOUR DEVELOPMENT. 2009 8 4987 34 PATTERNS OF CALCIUM SIGNALING: A LINK BETWEEN CHRONIC EMOTIONS AND CANCER. INTRA AND INTER-CELLULAR CALCIUM SIGNALING IS PRESENT IN ALL TYPES OF CELLS AND BODY TISSUES. IN THE HUMAN BRAIN, CALCIUM CURRENTS AND WAVES ARE RELATED TO MENTAL ACTIVITIES, INCLUDING EMOTIONS. WE PRESENT A THEORETICAL INTERPRETATION OF THESE PHENOMENA SUGGESTING THEIR INVOLVEMENT IN CHRONIC EMOTIONAL PATTERNS AND IN THE PATHOLOGY OF CANCER. RECENT DEVELOPMENTS ON BIOPHYSICS, TRANSLATIONAL BIOLOGY AND PSYCHONEUROENDOCRINOIMMUNOLOGY (PNEI) CAN SUPPORT EXPLANATORY HYPOTHESES ABOUT THE LINK BETWEEN EMOTIONAL STRESSES AND THE ORIGIN AND DEVELOPMENT OF DIFFERENT TYPES OF TUMOR CELLS. CHRONIC STRESSES MAY CAUSE PERTURBATIONS OF RHYTHMS OF THE PNEI SYSTEM, EXCESSIVE ACTIVATION OF HPA AXIS AND ABNORMAL ACTIVATION OF CALCIUM SIGNALS IN SOMATIC TISSUES, WITH DELETERIOUS EFFECTS ON DIFFERENT PARTS OF THE BODY. THE INCREASING OF CALCIUM SIGNALING INSIDE CELLS MAY LEAD TO A DEREGULATION OF DIFFERENT PATHWAYS AND EPIGENETIC SYSTEMS THAT PROMOTE THE PRODUCTION OF GENOMIC MUTATIONS IN A SECOND PHASE. IN PARTICULAR, THE HYPERACTIVATION OF THE TRANSCRIPTION NUCLEAR FACTOR KAPPAB (NF-KAPPAB), IF IS NOT COUNTERBALANCED BY THE FOLLOWING ACTIVATION OF THE NUCLEAR FACTOR (ERYTHROID-DERIVED 2)-LIKE 2 (NFE2L2 OR NRF2), INCREASES THE PRODUCTION OF OXIDATIVE CATABOLITES, AS THE ADVANCED GLYCATION END PRODUCTS (AGE), WHICH PLAY A KEY ROLE IN THE PROGRESSION OF DIFFERENT TYPES OF CANCER AND OTHER DEGENERATIVE DISEASES. CORTISOL BINDING TO GLUCOCORTICOID RECEPTOR (GR) REDUCES THE ACTIVITY OF BOTH NF-KAPPAB AND NRF2 INSIDE THE CELLS BUT INHIBITS THE CELLULAR IMMUNITY AND THE ANABOLIC PROCESSES OF TISSUE REGENERATION. THE TISSUE ATROPHY AND THE DEFECTIVE ANTI-AGEING MECHANISMS PROMOTES THE TUMORAL CELLS GROWTH AND THEIR ESCAPE FROM THE IMMUNE-SURVEILLANCE. 2017 9 315 31 ALCOHOL, DNA METHYLATION, AND CANCER. CANCER IS ONE OF THE MOST SIGNIFICANT DISEASES ASSOCIATED WITH CHRONIC ALCOHOL CONSUMPTION, AND CHRONIC DRINKING IS A STRONG RISK FACTOR FOR CANCER, PARTICULARLY OF THE UPPER AERODIGESTIVE TRACT, LIVER, COLORECTUM, AND BREAST. SEVERAL FACTORS CONTRIBUTE TO ALCOHOL-INDUCED CANCER DEVELOPMENT (I.E., CARCINOGENESIS), INCLUDING THE ACTIONS OF ACETALDEHYDE, THE FIRST AND PRIMARY METABOLITE OF ETHANOL, AND OXIDATIVE STRESS. HOWEVER, INCREASING EVIDENCE SUGGESTS THAT ABERRANT PATTERNS OF DNA METHYLATION, AN IMPORTANT EPIGENETIC MECHANISM OF TRANSCRIPTIONAL CONTROL, ALSO COULD BE PART OF THE PATHOGENETIC MECHANISMS THAT LEAD TO ALCOHOL-INDUCED CANCER DEVELOPMENT. THE EFFECTS OF ALCOHOL ON GLOBAL AND LOCAL DNA METHYLATION PATTERNS LIKELY ARE MEDIATED BY ITS ABILITY TO INTERFERE WITH THE AVAILABILITY OF THE PRINCIPAL BIOLOGICAL METHYL DONOR, S-ADENOSYLMETHIONINE (SAME), AS WELL AS PATHWAYS RELATED TO IT. SEVERAL MECHANISMS MAY MEDIATE THE EFFECTS OF ALCOHOL ON DNA METHYLATION, INCLUDING REDUCED FOLATE LEVELS AND INHIBITION OF KEY ENZYMES IN ONE-CARBON METABOLISM THAT ULTIMATELY LEAD TO LOWER SAME LEVELS, AS WELL AS INHIBITION OF ACTIVITY AND EXPRESSION OF ENZYMES INVOLVED IN DNA METHYLATION (I.E., DNA METHYLTRANSFERASES). FINALLY, VARIATIONS (I.E., POLYMORPHISMS) OF SEVERAL GENES INVOLVED IN ONE-CARBON METABOLISM ALSO MODULATE THE RISK OF ALCOHOL-ASSOCIATED CARCINOGENESIS. 2013 10 834 29 CHEMICAL BIOLOGY OF LYSINE DEMETHYLASES. ABNORMAL LEVELS OF DNA METHYLATION AND/OR HISTONE MODIFICATIONS ARE OBSERVED IN PATIENTS WITH A WIDE VARIETY OF CHRONIC DISEASES. METHYLATION OF LYSINES WITHIN HISTONE TAILS IS A KEY MODIFICATION THAT CONTRIBUTES TO INCREASED GENE EXPRESSION OR REPRESSION DEPENDING ON THE SPECIFIC RESIDUE AND DEGREE OF METHYLATION, WHICH IS IN TURN CONTROLLED BY THE INTERPLAY OF LYSINE METHYL TRANSFERASES AND DEMETHYLASES. DRUGS THAT TARGET THESE AND OTHER ENZYMES CONTROLLING CHROMATIN MODIFICATIONS CAN MODULATE THE EXPRESSION OF CLUSTERS OF GENES, POTENTIALLY OFFERING HIGHER THERAPEUTIC EFFICACY THAN CLASSICAL AGENTS ACTING ON DOWNSTREAM BIOCHEMICAL PATHWAYS THAT ARE SUSCEPTIBLE TO DEGENERACY. LYSINE DEMETHYLASES, FIRST DISCOVERED IN 2004, ARE THE SUBJECT OF INCREASING INTEREST AS THERAPEUTIC TARGETS. THIS REVIEW PROVIDES AN OVERVIEW OF RECENT FINDINGS IMPLICATING LYSINE DEMETHYLASES IN A RANGE OF THERAPEUTIC AREAS INCLUDING ONCOLOGY, IMMUNOINFLAMMATION, METABOLIC DISORDERS, NEUROSCIENCE, VIROLOGY AND REGENERATIVE MEDICINE, TOGETHER WITH A SUMMARY OF RECENT ADVANCES IN STRUCTURAL BIOLOGY AND SMALL MOLECULE INHIBITOR DISCOVERY, SUPPORTING THE TRACTABILITY OF THE PROTEIN FAMILY FOR THE DEVELOPMENT OF SELECTIVE DRUGLIKE INHIBITORS. 2011 11 5396 31 REDUCED HISTONE BIOSYNTHESIS AND CHROMATIN CHANGES ARISING FROM A DAMAGE SIGNAL AT TELOMERES. DURING REPLICATIVE AGING OF PRIMARY CELLS MORPHOLOGICAL TRANSFORMATIONS OCCUR, THE EXPRESSION PATTERN IS ALTERED AND CHROMATIN CHANGES GLOBALLY. HERE WE SHOW THAT CHRONIC DAMAGE SIGNALS, PROBABLY CAUSED BY TELOMERE PROCESSING, AFFECT EXPRESSION OF HISTONES AND LEAD TO THEIR DEPLETION. WE INVESTIGATED THE ABUNDANCE AND CELL CYCLE EXPRESSION OF HISTONES AND HISTONE CHAPERONES AND FOUND DEFECTS IN HISTONE BIOSYNTHESIS DURING REPLICATIVE AGING. SIMULTANEOUSLY, EPIGENETIC MARKS WERE REDISTRIBUTED ACROSS THE PHASES OF THE CELL CYCLE AND THE DNA DAMAGE RESPONSE (DDR) MACHINERY WAS ACTIVATED. THE AGE-DEPENDENT REPROGRAMMING AFFECTED TELOMERIC CHROMATIN ITSELF, WHICH WAS PROGRESSIVELY DESTABILIZED, LEADING TO A BOOST OF THE TELOMERE-ASSOCIATED DDR WITH EACH SUCCESSIVE CELL CYCLE. WE PROPOSE A MECHANISM IN WHICH CHANGES IN THE STRUCTURAL AND EPIGENETIC INTEGRITY OF TELOMERES AFFECT CORE HISTONES AND THEIR CHAPERONES, ENFORCING A SELF-PERPETUATING PATHWAY OF GLOBAL EPIGENETIC CHANGES THAT ULTIMATELY LEADS TO SENESCENCE. 2010 12 3643 34 INCREASED INFLAMMATORY RESPONSE IN AGED MICE IS ASSOCIATED WITH AGE-RELATED ZINC DEFICIENCY AND ZINC TRANSPORTER DYSREGULATION. AGING IS A COMPLEX PROCESS ASSOCIATED WITH PHYSIOLOGICAL CHANGES IN NUMEROUS ORGAN SYSTEMS. IN PARTICULAR, AGING OF THE IMMUNE SYSTEM IS CHARACTERIZED BY PROGRESSIVE DYSREGULATION OF IMMUNE RESPONSES, RESULTING IN INCREASED SUSCEPTIBILITY TO INFECTIOUS DISEASES, IMPAIRED VACCINATION EFFICACY AND SYSTEMIC LOW-GRADE CHRONIC INFLAMMATION. INCREASING EVIDENCE SUGGEST THAT INTRACELLULAR ZINC HOMEOSTASIS, REGULATED BY ZINC TRANSPORTER EXPRESSION, IS CRITICALLY INVOLVED IN THE SIGNALING AND ACTIVATION OF IMMUNE CELLS. WE HYPOTHESIZE THAT EPIGENETIC ALTERATIONS AND NUTRITIONAL DEFICITS ASSOCIATED WITH AGING MAY LEAD TO ZINC TRANSPORTER DYSREGULATION, RESULTING IN DECREASES IN CELLULAR ZINC LEVELS AND ENHANCED INFLAMMATION WITH AGE. THE GOAL OF THIS STUDY WAS TO EXAMINE THE CONTRIBUTION OF AGE-RELATED ZINC DEFICIENCY AND ZINC TRANSPORTER DYSREGULATION ON THE INFLAMMATORY RESPONSE IN IMMUNE CELLS. THE EFFECTS OF ZINC DEFICIENCY AND AGE ON THE INDUCTION OF INFLAMMATORY RESPONSES WERE DETERMINED USING AN IN VITRO CELL CULTURE SYSTEM AND AN AGED MOUSE MODEL. WE SHOWED THAT ZINC DEFICIENCY, PARTICULARLY THE REDUCTION IN INTRACELLULAR ZINC IN IMMUNE CELLS, WAS ASSOCIATED WITH INCREASED INFLAMMATION WITH AGE. FURTHERMORE, REDUCED ZIP 6 EXPRESSION ENHANCED PROINFLAMMATORY RESPONSE, AND AGE-SPECIFIC ZIP 6 DYSREGULATION CORRELATED WITH AN INCREASE IN ZIP 6 PROMOTER METHYLATION. FURTHERMORE, RESTORING ZINC STATUS VIA DIETARY SUPPLEMENTATION REDUCED AGED-ASSOCIATED INFLAMMATION. OUR DATA SUGGESTED THAT AGE-RELATED EPIGENETIC DYSREGULATION IN ZINC TRANSPORTER EXPRESSION MAY INFLUENCE CELLULAR ZINC LEVELS AND CONTRIBUTE TO INCREASED SUSCEPTIBILITY TO INFLAMMATION WITH AGE. 2013 13 1900 31 ENERGY SENSING PATHWAYS: BRIDGING TYPE 2 DIABETES AND COLORECTAL CANCER? THE RECENTLY RAPID INCREASE OF OBESITY AND TYPE 2 DIABETES MELLITUS HAS CAUSED GREAT BURDEN TO OUR SOCIETY. A POSITIVE ASSOCIATION BETWEEN TYPE 2 DIABETES AND RISK OF COLORECTAL CANCER HAS BEEN REPORTED BY INCREASING EPIDEMIOLOGICAL STUDIES. THE MOLECULAR MECHANISM OF THIS CONNECTION REMAINS ELUSIVE. HOWEVER, TYPE 2 DIABETES MAY RESULT IN ABNORMAL CARBOHYDRATE AND LIPID METABOLISM, HIGH LEVELS OF CIRCULATING INSULIN, INSULIN GROWTH FACTOR-1, AND ADIPOCYTOKINES, AS WELL AS CHRONIC INFLAMMATION. ALL THESE FACTORS COULD LEAD TO THE ALTERATION OF ENERGY SENSING PATHWAYS SUCH AS THE AMP ACTIVATED KINASE (PRKA), MECHANISTIC (MAMMALIAN) TARGET OF RAPAMYCIN (MTOR), SIRT1, AND AUTOPHAGY SIGNALING PATHWAYS. THE RESULTED IMPAIRED SIRT1 AND AUTOPHAGY SIGNALING PATHWAY COULD INCREASE THE RISK OF GENE MUTATION AND CANCER GENESIS BY DECREASING GENETIC STABILITY AND DNA MISMATCH REPAIR. THE DYSREGULATED MTOR AND PRKA PATHWAY COULD REMODEL CELL METABOLISM DURING THE GROWTH AND METASTASIS OF CANCER IN ORDER FOR THE CANCER CELL TO SURVIVE THE UNFAVORABLE MICROENVIRONMENT SUCH AS HYPOXIA AND LOW BLOOD SUPPLY. MOREOVER, THESE PATHWAYS MAY BE COUPLING METABOLIC AND EPIGENETIC ALTERATIONS THAT ARE CENTRAL TO ONCOGENIC TRANSFORMATION. FURTHER RESEARCHES INCLUDING MOLECULAR PATHOLOGIC EPIDEMIOLOGIC STUDIES ARE WARRANTED TO BETTER ADDRESS THE PRECISE LINKS BETWEEN THESE TWO IMPORTANT DISEASES. 2017 14 4969 35 PATHOLOGICAL NEUROINFLAMMATORY CONVERSION OF REACTIVE ASTROCYTES IS INDUCED BY MICROGLIA AND INVOLVES CHROMATIN REMODELING. FOLLOWING BRAIN INJURY OR IN NEURODEGENERATIVE DISEASES, ASTROCYTES BECOME REACTIVE AND MAY SUFFER PATHOLOGICAL REMODELING, FEATURES OF WHICH ARE THE LOSS OF THEIR HOMEOSTATIC FUNCTIONS AND A PRO-INFLAMMATORY GAIN OF FUNCTION THAT FACILITATES NEURODEGENERATION. PHARMACOLOGICAL INTERVENTION TO MODULATE THIS ASTROGLIAL RESPONSE AND NEUROINFLAMMATION IS AN INTERESTING NEW THERAPEUTIC RESEARCH STRATEGY, BUT IT STILL REQUIRES A DEEPER UNDERSTANDING OF THE UNDERLYING CELLULAR AND MOLECULAR MECHANISMS OF THE PHENOMENON. BASED ON THE KNOWN MICROGLIAL-ASTROGLIAL INTERACTION, THE PROMINENT ROLE OF THE NUCLEAR FACTOR KAPPA B (NF-KAPPAB) PATHWAY IN MEDIATING ASTROGLIAL PATHOLOGICAL PRO-INFLAMMATORY GAIN OF FUNCTION, AND ITS ABILITY TO RECRUIT CHROMATIN-REMODELING ENZYMES, WE FIRST EXPLORED THE MICROGLIAL ROLE IN THE INITIATION OF ASTROGLIAL PRO-INFLAMMATORY CONVERSION AND THEN MONITORED THE PROGRESSION OF EPIGENETIC CHANGES IN THE ASTROCYTIC CHROMATIN. DIFFERENT CONFIGURATIONS OF PRIMARY GLIAL CULTURE WERE USED TO MODULATE MICROGLIA-ASTROCYTE CROSSTALK WHILE INDUCING PRO-INFLAMMATORY GAIN OF FUNCTION BY LIPOPOLYSACCHARIDE (LPS) EXPOSURE. IN VIVO, BRAIN ISCHEMIA BY CORTICAL DEVASCULARIZATION (PIAL DISRUPTION) WAS PERFORMED TO VERIFY THE PRESENCE OF EPIGENETIC MARKS IN REACTIVE ASTROCYTES. OUR RESULTS SHOWED THAT 1) MICROGLIA IS REQUIRED TO INITIATE THE PATHOLOGICAL CONVERSION OF ASTROCYTES BY TRIGGERING THE NF-KAPPAB SIGNALING PATHWAY; 2) THIS INTERACTION IS MEDIATED BY SOLUBLE FACTORS AND INDUCES STABLE ASTROGLIAL PHENOTYPIC CHANGES; 3) THE PATHOLOGICAL CONVERSION PROMOTES CHROMATIN REMODELING WITH STABLE INCREASE IN H3K9K14AC, TEMPORARY INCREASE IN H3K27AC, AND TEMPORARY REDUCTION IN HETEROCHROMATIN MARK H3K9ME3; AND 4) IN VIVO REACTIVE ASTROCYTES SHOW INCREASED H3K27AC MARK IN THE NEUROINFLAMMATORY MILIEU FROM THE ISCHEMIC PENUMBRA. OUR FINDINGS INDICATE THAT ASTROGLIAL PATHOLOGICAL PRO-INFLAMMATORY GAIN OF FUNCTION IS ASSOCIATED WITH PROFOUND CHANGES IN THE CONFIGURATION OF ASTROCYTIC CHROMATIN, WHICH IN TURN ARE INITIATED BY MICROGLIA-DERIVED CUES. THESE RESULTS OPEN A NEW AVENUE IN THE STUDY OF POTENTIAL PHARMACOLOGICAL INTERVENTIONS THAT MODIFY THE INITIATION AND STABILIZATION OF ASTROGLIAL PATHOLOGICAL REMODELING, WHICH WOULD BE USEFUL IN ACUTE AND CHRONIC CNS INJURY. EPIGENETIC CHANGES REPRESENT A PLAUSIBLE PHARMACOLOGICAL TARGET TO INTERFERE WITH THE STABILIZATION OF THE PATHOLOGICAL ASTROGLIAL PHENOTYPE. 2021 15 3148 39 GLUCOCORTICOID INDUCED LOSS OF OESTROGEN RECEPTOR ALPHA GENE METHYLATION AND RESTORATION OF SENSITIVITY TO FULVESTRANT IN TRIPLE NEGATIVE BREAST CANCER. THE RESPONSE TO PSYCHOLOGICAL STRESS CAN DIFFER DEPENDING ON THE TYPE AND DURATION OF THE STRESSOR. ACUTE STRESS CAN FACILITATE A "FIGHT OR FLIGHT RESPONSE" AND AID SURVIVAL, WHEREAS CHRONIC LONG-TERM STRESS WITH THE PERSISTENT RELEASE OF STRESS HORMONES SUCH AS CORTISOL HAS BEEN SHOWN TO BE DETRIMENTAL TO HEALTH. WE ARE NOW BEGINNING TO UNDERSTAND HOW THIS STRESS HORMONE RESPONSE IMPACTS IMPORTANT PROCESSES SUCH AS DNA REPAIR AND CELL PROLIFERATION PROCESSES IN BREAST CANCER. HOWEVER, IT IS NOT KNOWN WHAT EPIGENETIC CHANGES STRESS HORMONES INDUCE IN BREAST CANCER. EPIGENETIC MECHANISMS INCLUDE MODIFICATION OF DNA AND HISTONES WITHIN CHROMATIN THAT MAY BE INVOLVED IN GOVERNING THE TRANSCRIPTIONAL PROCESSES IN CANCER CELLS IN RESPONSE TO CHANGES BY ENDOGENOUS STRESS HORMONES. THE CONTRIBUTION OF ENDOGENOUS ACUTE OR LONG-TERM EXPOSURE OF GLUCOCORTICOID STRESS HORMONES, AND EXOGENOUS GLUCOCORTICOIDS TO METHYLATION PATTERNS IN BREAST CANCER TISSUES WITH DIFFERENT AETIOLOGIES REMAINS TO BE EVALUATED. IN VITRO AND IN VIVO MODELS WERE DEVELOPED TO INVESTIGATE THE EPIGENETIC MODIFICATIONS AND THEIR CONTRIBUTION TO BREAST CANCER PROGRESSION AND AETIOLOGY. A PANEL OF TRIPLE NEGATIVE BREAST CANCER CELL LINES WERE TREATED WITH THE GLUCOCORTICOID, CORTISOL WHICH RESULTED IN EPIGENETIC ALTERATION CHARACTERISED BY LOSS OF METHYLATION ON PROMOTER REGIONS OF TUMOUR SUPPRESSOR GENES INCLUDING ESR1, AND LOSS OF METHYLATION ON LINE-1 REPETITIVE ELEMENT USED AS A SURROGATE MARKER FOR GLOBAL METHYLATION. THIS WAS VERIFIED IN VIVO IN MDA-MB-231 XENOGRAFTS; THE MODEL VERIFIED THE LOSS OF METHYLATION ON ESR1 PROMOTER, AND SUBSEQUENT INCREASE IN ESR1 EXPRESSION IN PRIMARY TUMOURS IN MICE SUBJECTED TO RESTRAINT STRESS. OUR STUDY HIGHLIGHTS THAT DNA METHYLATION LANDSCAPE IN BREAST CANCER CAN BE ALTERED IN RESPONSE TO STRESS AND GLUCOCORTICOID TREATMENT. 2023 16 2499 29 EPIGENETICS AND EXERCISE. EPIGENETICS CAN BE DEFINED AS 'THE STRUCTURAL ADAPTATION OF CHROMOSOMAL REGIONS SO AS TO REGISTER, SIGNAL, OR PERPETUATE ALTERED ACTIVITY STATES.' INCREASED TRANSCRIPTION OF KEY REGULATORY, METABOLIC, AND MYOGENIC GENES IS AN EARLY RESPONSE TO EXERCISE AND IS IMPORTANT IN MEDIATING SUBSEQUENT ADAPTATIONS IN SKELETAL MUSCLE. DNA HYPOMETHYLATION AND HISTONE HYPERACETYLATION ARE EMERGING AS IMPORTANT CRUCIAL EVENTS FOR INCREASED TRANSCRIPTION. THE COMPLEX INTERACTIONS BETWEEN MULTIPLE EPIGENETIC MODIFICATIONS AND THEIR REGULATION BY METABOLIC CHANGES AND SIGNALING EVENTS DURING EXERCISE, WITH IMPLICATIONS FOR ENHANCED UNDERSTANDING OF THE ACUTE AND CHRONIC ADAPTATIONS TO EXERCISE, ARE QUESTIONS FOR FURTHER INVESTIGATION. 2019 17 4391 33 MODERATE EXERCISE INDUCES TRAINED IMMUNITY IN MACROPHAGES. DESPITE ITS IMPORTANCE IN PROTECTING THE HOST FROM INFECTIONS AND INJURY, EXCESSIVE INFLAMMATION MAY LEAD TO SERIOUS HUMAN DISEASES INCLUDING AUTOIMMUNE DISORDERS, CARDIOVASCULAR DISEASES, DIABETES, AND CANCER. EXERCISE IS A KNOWN IMMUNOMODULATOR; HOWEVER, WHETHER EXERCISE CAUSES LONG-TERM CHANGES IN INFLAMMATORY RESPONSES AND HOW THESE CHANGES OCCUR ARE LACKING. HERE, WE SHOW THAT CHRONIC MODERATE-INTENSITY TRAINING OF MICE LEADS TO PERSISTENT METABOLIC REWIRING AND CHANGES TO CHROMATIN ACCESSIBILITY IN BONE MARROW-DERIVED MACROPHAGES (BMDMS), WHICH, IN TURN, TEMPERS THEIR INFLAMMATORY RESPONSES. WE SHOW THAT BMDMS FROM EXERCISED MICE EXHIBITED A DECREASE IN LIPOPOLYSACCHARIDE (LPS)-INDUCED NF-KAPPAB ACTIVATION AND PROINFLAMMATORY GENE EXPRESSION ALONG WITH AN INCREASE IN M2-LIKE-ASSOCIATED GENES WHEN COMPARED WITH BMDMS FROM SEDENTARY MICE. THIS WAS ASSOCIATED WITH IMPROVED MITOCHONDRIAL QUALITY AND INCREASED RELIANCE ON OXIDATIVE PHOSPHORYLATION ACCOMPANIED WITH REDUCED MITOCHONDRIAL REACTIVE OXYGEN SPECIES (ROS) PRODUCTION. MECHANISTICALLY, ASSAY FOR TRANSPOSASE-ACCESSIBLE CHROMATIN (ATAC)-SEQ ANALYSIS SHOWED CHANGES IN CHROMATIN ACCESSIBILITY OF GENES ASSOCIATED WITH INFLAMMATORY AND METABOLIC PATHWAYS. OVERALL, OUR DATA SUGGEST THAT CHRONIC MODERATE EXERCISE CAN INFLUENCE THE INFLAMMATORY RESPONSES OF MACROPHAGES BY REPROGRAMMING THEIR METABOLIC AND EPIGENETIC LANDSCAPE.NEW & NOTEWORTHY IN THIS STUDY, WE EXPLAIN HOW LONG-TERM MODERATE EXERCISE TRAINING CAN REDUCE INFLAMMATION IN MOUSE MACROPHAGES BY REPROGRAMMING THE WAY THEY SENSE AND RESPOND TO THE PRESENCE OF PATHOGENS. WE COMPLETED A THOROUGH ANALYSIS AND SHOWED THAT THESE CHANGES PERSIST IN MACROPHAGES BECAUSE EXERCISE IMPROVES THE ABILITY OF CELLS TO UTILIZE OXYGEN WITHOUT PRODUCING DAMAGING COMPOUNDS, AND CHANGES THE WAY THEY ACCESS THEIR DNA. 2023 18 6895 24 [SYSTEMIC CONTROL OF THE MOLECULAR, CELL, AND EPIGENETIC MECHANISMS OF LONG-LASTING CONSEQUENCES OF STRESS]. BASED ON M.E. LOBASHEV'S VIEWS OF THE SYSTEMIC CONTROL OF GENETIC AND CYTOGENEITC PROCESSES AND A SUBSTANTIAL EFFECT OF EXCITABILITY ON PLASTIC CHANGES IN THE CENTRAL NERVOUS SYSTEM (CNS), THE EFFECT OF PROLONGED EMOTIONAL AND PAIN STRESS (PEPS) ON THE MOLECULAR, CELL, AND EPIGENETIC MECHANISMS OF INJURY MEMORY WAS STUDIED IN RAT STRAINS BRED FOR A CERTAIN EXCITABILITY OF THE NERVOUS SYSTEM. PEPS WAS FOR THE FIRST TIME FOUND TO CAUSE LONG-LASTING (2 MONTHS) MORPHOLOGICAL ALTERATIONS OF THE CA3 REGION OF THE HIPPOCAMPUS AND TO MODIFY THE GENOME ACTIVITY OF ITS PYRAMIDAL NEURONS. THE TWO PHENOMENA WERE POTENTIATED BY A GENETICALLY DETERMINED LOW FUNCTIONAL STATE OF THE CNS. THE POST-STRESS REGULATION OF THE GENOME FUNCTION IN HIPPOCAMPAL NEURONS WAS MEDIATED BY CHANGES IN HETEROCHROMATIN CONFORMATION, ACTIVATION OF METHYL-CPG-BINDING PROTEIN (MECP2) SYNTHESIS, AND SUBSEQUENT CHANGES IN ACETYLATION OF HISTONE H4. GENETICALLY DETERMINED HIGH EXCITABILITY OF THE NERVOUS SYSTEM PROVED TO BE A RISK FACTOR THAT AFFECTS THE SPECIFICS AND TIME COURSE OF THE OBSERVED MOLECULAR, CELL, AND GENETIC TRANSFORMATIONS OF NEURONS. THE RESULTS PROVIDE FOR A BETTER UNDERSTANDING OF THE EPIGENETIC MECHANISMS OF INJURY MEMORY, WHICH FORMS A PATHOGENETIC BASIS FOR POSTTRAUMATIC STRESS DISORDER AND OTHER HUMAN PSYCHOGENIC CONDITIONS CHARACTERIZED BY A PROLONGED DURATION. 2009 19 6100 33 THE EMERGING ROLE OF EPIGENETIC MODIFIERS IN REPAIR OF DNA DAMAGE ASSOCIATED WITH CHRONIC INFLAMMATORY DISEASES. AT SITES OF CHRONIC INFLAMMATION EPITHELIAL CELLS ARE EXPOSED TO HIGH LEVELS OF REACTIVE OXYGEN SPECIES (ROS), WHICH CAN CONTRIBUTE TO THE INITIATION AND DEVELOPMENT OF MANY DIFFERENT HUMAN CANCERS. ABERRANT EPIGENETIC ALTERATIONS THAT CAUSE TRANSCRIPTIONAL SILENCING OF TUMOR SUPPRESSOR GENES ARE ALSO IMPLICATED IN MANY DISEASES ASSOCIATED WITH INFLAMMATION, INCLUDING CANCER. HOWEVER, IT IS NOT CLEAR HOW ALTERED EPIGENETIC GENE SILENCING IS INITIATED DURING CHRONIC INFLAMMATION. THE HIGH LEVEL OF ROS AT SITES OF INFLAMMATION IS KNOWN TO INDUCE OXIDATIVE DNA DAMAGE IN SURROUNDING EPITHELIAL CELLS. FURTHERMORE, DNA DAMAGE IS KNOWN TO TRIGGER SEVERAL RESPONSES, INCLUDING RECRUITMENT OF DNA REPAIR PROTEINS, TRANSCRIPTIONAL REPRESSION, CHROMATIN MODIFICATIONS AND OTHER CELL SIGNALING EVENTS. RECRUITMENT OF EPIGENETIC MODIFIERS TO CHROMATIN IN RESPONSE TO DNA DAMAGE RESULTS IN TRANSIENT COVALENT MODIFICATIONS TO CHROMATIN SUCH AS HISTONE UBIQUITINATION, ACETYLATION AND METHYLATION AND DNA METHYLATION. DNA DAMAGE ALSO ALTERS NON-CODING RNA EXPRESSION. ALL OF THESE ALTERATIONS HAVE THE POTENTIAL TO ALTER GENE EXPRESSION AT SITES OF DAMAGE. TYPICALLY, THESE MODIFICATIONS AND GENE TRANSCRIPTION ARE RESTORED BACK TO NORMAL ONCE THE REPAIR OF THE DNA DAMAGE IS COMPLETED. HOWEVER, CHRONIC INFLAMMATION MAY INDUCE SUSTAINED DNA DAMAGE AND DNA DAMAGE RESPONSES THAT RESULT IN THESE TRANSIENT COVALENT CHROMATIN MODIFICATIONS BECOMING MITOTICALLY STABLE EPIGENETIC ALTERATIONS. UNDERSTANDING HOW EPIGENETIC ALTERATIONS ARE INITIATED DURING CHRONIC INFLAMMATION WILL ALLOW US TO DEVELOP PHARMACEUTICAL STRATEGIES TO PREVENT OR TREAT CHRONIC INFLAMMATION-INDUCED CANCER. THIS REVIEW WILL FOCUS ON TYPES OF DNA DAMAGE AND EPIGENETIC ALTERATIONS ASSOCIATED WITH CHRONIC INFLAMMATORY DISEASES, THE TYPES OF DNA DAMAGE AND TRANSIENT COVALENT CHROMATIN MODIFICATIONS INDUCED BY INFLAMMATION AND OXIDATIVE DNA DAMAGE AND HOW THESE MODIFICATIONS MAY RESULT IN EPIGENETIC ALTERATIONS. 2019 20 2306 28 EPIGENETIC REGULATION OF CELL-FATE CHANGES THAT DETERMINE ADULT LIVER REGENERATION AFTER INJURY. THE ADULT LIVER HAS EXCELLENT REGENERATIVE POTENTIAL FOLLOWING INJURY. IN CONTRAST TO OTHER ORGANS OF THE BODY THAT HAVE HIGH CELLULAR TURNOVER DURING HOMEOSTASIS (E.G., INTESTINE, STOMACH, AND SKIN), THE ADULT LIVER IS A SLOWLY SELF-RENEWING ORGAN AND DOES NOT CONTAIN A DEFINED STEM-CELL COMPARTMENT THAT MAINTAINS HOMEOSTASIS. HOWEVER, TISSUE DAMAGE INDUCES SIGNIFICANT PROLIFERATION ACROSS THE LIVER AND CAN TRIGGER CELL-FATE CHANGES, SUCH AS TRANS-DIFFERENTIATION AND DE-DIFFERENTIATION INTO LIVER PROGENITORS, WHICH CONTRIBUTE TO EFFICIENT TISSUE REGENERATION AND RESTORATION OF LIVER FUNCTIONS. EPIGENETIC MECHANISMS HAVE BEEN SHOWN TO REGULATE CELL-FATE DECISIONS IN BOTH EMBRYONIC AND ADULT TISSUES IN RESPONSE TO ENVIRONMENTAL CUES. UNDERLYING THEIR RELEVANCE IN LIVER BIOLOGY, EXPRESSION LEVELS AND EPIGENETIC ACTIVITY OF CHROMATIN MODIFIERS ARE OFTEN ALTERED IN CHRONIC LIVER DISEASE AND LIVER CANCER. IN THIS REVIEW, I EXAMINE THE ROLE OF SEVERAL CHROMATIN MODIFIERS IN THE REGULATION OF CELL-FATE CHANGES THAT DETERMINE EFFICIENT ADULT LIVER EPITHELIAL REGENERATION IN RESPONSE TO TISSUE INJURY IN MOUSE MODELS. SPECIFICALLY, I FOCUS ON EPIGENETIC MECHANISMS SUCH AS CHROMATIN REMODELLING, DNA METHYLATION AND HYDROXYMETHYLATION, AND HISTONE METHYLATION AND DEACETYLATION. FINALLY, I ADDRESS HOW ALTERED EPIGENETIC MECHANISMS AND THE INTERPLAY BETWEEN EPIGENETICS AND METABOLISM MAY CONTRIBUTE TO THE INITIATION AND PROGRESSION OF LIVER DISEASE AND CANCER. 2021