1 5993 105 TGFBETA PROMOTES FIBROSIS BY MYST1-DEPENDENT EPIGENETIC REGULATION OF AUTOPHAGY. ACTIVATION OF FIBROBLASTS IS ESSENTIAL FOR PHYSIOLOGICAL TISSUE REPAIR. UNCONTROLLED ACTIVATION OF FIBROBLASTS, HOWEVER, MAY LEAD TO TISSUE FIBROSIS WITH ORGAN DYSFUNCTION. ALTHOUGH SEVERAL PATHWAYS CAPABLE OF PROMOTING FIBROBLAST ACTIVATION AND TISSUE REPAIR HAVE BEEN IDENTIFIED, THEIR INTERPLAY IN THE CONTEXT OF CHRONIC FIBROTIC DISEASES REMAINS INCOMPLETELY UNDERSTOOD. HERE, WE PROVIDE EVIDENCE THAT TRANSFORMING GROWTH FACTOR-BETA (TGFBETA) ACTIVATES AUTOPHAGY BY AN EPIGENETIC MECHANISM TO AMPLIFY ITS PROFIBROTIC EFFECTS. TGFBETA INDUCES AUTOPHAGY IN FIBROTIC DISEASES BY SMAD3-DEPENDENT DOWNREGULATION OF THE H4K16 HISTONE ACETYLTRANSFERASE MYST1, WHICH REGULATES THE EXPRESSION OF CORE COMPONENTS OF THE AUTOPHAGY MACHINERY SUCH AS ATG7 AND BECLIN1. ACTIVATION OF AUTOPHAGY IN FIBROBLASTS PROMOTES COLLAGEN RELEASE AND IS BOTH, SUFFICIENT AND REQUIRED, TO INDUCE TISSUE FIBROSIS. FORCED EXPRESSION OF MYST1 ABROGATES THE STIMULATORY EFFECTS OF TGFBETA ON AUTOPHAGY AND RE-ESTABLISHES THE EPIGENETIC CONTROL OF AUTOPHAGY IN FIBROTIC CONDITIONS. INTERFERENCE WITH THE ABERRANT ACTIVATION OF AUTOPHAGY INHIBITS TGFBETA-INDUCED FIBROBLAST ACTIVATION AND AMELIORATES EXPERIMENTAL DERMAL AND PULMONARY FIBROSIS. THESE FINDINGS LINK UNCONTROLLED TGFBETA SIGNALING TO ABERRANT AUTOPHAGY AND DEREGULATED EPIGENETICS IN FIBROTIC DISEASES AND MAY CONTRIBUTE TO THE DEVELOPMENT OF THERAPEUTIC INTERVENTIONS IN FIBROTIC DISEASES. 2021 2 2361 25 EPIGENETIC REGULATION OF SKELETAL TISSUE INTEGRITY AND OSTEOPOROSIS DEVELOPMENT. BONE TURNOVER IS SOPHISTICATEDLY BALANCED BY A DYNAMIC COUPLING OF BONE FORMATION AND RESORPTION AT VARIOUS RATES. THE ORCHESTRATION OF THIS CONTINUOUS REMODELING OF THE SKELETON FURTHER AFFECTS OTHER SKELETAL TISSUES THROUGH ORGAN CROSSTALK. CHRONIC EXCESSIVE BONE RESORPTION COMPROMISES BONE MASS AND ITS POROUS MICROSTRUCTURE AS WELL AS PROPER BIOMECHANICS. THIS ACCELERATES THE DEVELOPMENT OF OSTEOPOROTIC DISORDERS, A LEADING CAUSE OF SKELETAL DEGENERATION-ASSOCIATED DISABILITY AND PREMATURE DEATH. BONE-FORMING CELLS PLAY IMPORTANT ROLES IN MAINTAINING BONE DEPOSIT AND OSTEOCLASTIC RESORPTION. A POOR ORGANELLE MACHINERY, SUCH AS MITOCHONDRIAL DYSFUNCTION, ENDOPLASMIC RETICULUM STRESS, AND DEFECTIVE AUTOPHAGY, ETC., DYSREGULATES GROWTH FACTOR SECRETION, MINERALIZATION MATRIX PRODUCTION, OR OSTEOCLAST-REGULATORY CAPACITY IN OSTEOBLASTIC CELLS. A PLETHORA OF EPIGENETIC PATHWAYS REGULATE BONE FORMATION, SKELETAL INTEGRITY, AND THE DEVELOPMENT OF OSTEOPOROSIS. MICRORNAS INHIBIT PROTEIN TRANSLATION BY BINDING THE 3'-UNTRANSLATED REGION OF MRNAS OR PROMOTE TRANSLATION THROUGH POST-TRANSCRIPTIONAL PATHWAYS. DNA METHYLATION AND POST-TRANSLATIONAL MODIFICATION OF HISTONES ALTER THE CHROMATIN STRUCTURE, HINDERING HISTONE ENRICHMENT IN PROMOTER REGIONS. MICRORNA-PROCESSING ENZYMES AND DNA AS WELL AS HISTONE MODIFICATION ENZYMES CATALYZE THESE MODIFYING REACTIONS. GAIN AND LOSS OF THESE EPIGENETIC MODIFIERS IN BONE-FORMING CELLS AFFECT THEIR EPIGENETIC LANDSCAPES, INFLUENCING BONE HOMEOSTASIS, MICROARCHITECTURAL INTEGRITY, AND OSTEOPOROTIC CHANGES. THIS ARTICLE CONVEYS PRODUCTIVE INSIGHTS INTO BIOLOGICAL ROLES OF DNA METHYLATION, MICRORNA, AND HISTONE MODIFICATION AND HIGHLIGHTS THEIR INTERACTIONS DURING SKELETAL DEVELOPMENT AND BONE LOSS UNDER PHYSIOLOGICAL AND PATHOLOGICAL CONDITIONS. 2020 3 5939 39 TARGETING MECHANOTRANSDUCTION AT THE TRANSCRIPTIONAL LEVEL: YAP AND BRD4 ARE NOVEL THERAPEUTIC TARGETS FOR THE REVERSAL OF LIVER FIBROSIS. LIVER FIBROSIS IS THE RESULT OF A DEREGULATED WOUND HEALING PROCESS CHARACTERIZED BY THE EXCESSIVE DEPOSITION OF EXTRACELLULAR MATRIX. HEPATIC STELLATE CELLS (HSCS), WHICH ARE ACTIVATED IN RESPONSE TO LIVER INJURY, ARE THE MAJOR SOURCE OF EXTRACELLULAR MATRIX AND DRIVE THE WOUND HEALING PROCESS. HOWEVER, CHRONIC LIVER DAMAGE LEADS TO PERPETUAL HSC ACTIVATION, PROGRESSIVE FORMATION OF PATHOLOGICAL SCAR TISSUE AND ULTIMATELY, CIRRHOSIS AND ORGAN FAILURE. HSC ACTIVATION IS TRIGGERED LARGELY IN RESPONSE TO MECHANOSIGNALING FROM THE MICROENVIRONMENT, WHICH INDUCES A PROFIBROTIC NUCLEAR TRANSCRIPTION PROGRAM THAT PROMOTES HSC PROLIFERATION AND EXTRACELLULAR MATRIX SECRETION THEREBY SETTING UP A POSITIVE FEEDBACK LOOP LEADING TO MATRIX STIFFENING AND SELF-SUSTAINED, PATHOLOGICAL, HSC ACTIVATION. DESPITE THE SIGNIFICANT PROGRESS IN OUR UNDERSTANDING OF LIVER FIBROSIS, THE MOLECULAR MECHANISMS THROUGH WHICH THE EXTRACELLULAR MATRIX PROMOTES HSC ACTIVATION ARE NOT WELL UNDERSTOOD AND NO EFFECTIVE THERAPIES HAVE BEEN APPROVED TO DATE THAT CAN TARGET THIS EARLY, REVERSIBLE, STAGE IN LIVER FIBROSIS. SEVERAL NEW LINES OF INVESTIGATION NOW PROVIDE IMPORTANT INSIGHT INTO THIS AREA OF STUDY AND IDENTIFY TWO NUCLEAR TARGETS WHOSE INHIBITION HAS THE POTENTIAL OF REVERSING LIVER FIBROSIS BY INTERFERING WITH HSC ACTIVATION: YES-ASSOCIATED PROTEIN (YAP), A TRANSCRIPTIONAL CO-ACTIVATOR AND EFFECTOR OF THE MECHANOSENSITIVE HIPPO PATHWAY, AND BROMODOMAIN-CONTAINING PROTEIN 4 (BRD4), AN EPIGENETIC REGULATOR OF GENE EXPRESSION. YAP AND BRD4 ACTIVITY IS INDUCED IN RESPONSE TO MECHANICAL STIMULATION OF HSCS AND EACH PROTEIN INDEPENDENTLY CONTROLS WAVES OF EARLY GENE EXPRESSION NECESSARY FOR HSC ACTIVATION. SIGNIFICANTLY, INHIBITION OF EITHER PROTEIN CAN REVERT THE CHRONIC ACTIVATION OF HSCS AND IMPEDE PATHOLOGICAL PROGRESSION OF LIVER FIBROSIS IN CLINICALLY RELEVANT MODEL SYSTEMS. IN THIS REVIEW WE WILL DISCUSS THE ROLES OF THESE NUCLEAR CO-ACTIVATORS IN HSC ACTIVATION, THEIR MECHANISM OF ACTION IN THE FIBROTIC PROCESS IN THE LIVER AND OTHER ORGANS, AND THE POTENTIAL OF TARGETING THEIR ACTIVITY WITH SMALL MOLECULE DRUGS FOR FIBROSIS REVERSAL. 2016 4 5931 34 TARGETING EPIGENETIC MODIFIERS TO REPROGRAMME MACROPHAGES IN NON-RESOLVING INFLAMMATION-DRIVEN ATHEROSCLEROSIS. EPIGENOMIC AND EPIGENETIC RESEARCH HAS BEEN PROVIDING SEVERAL NEW INSIGHTS INTO A VARIETY OF DISEASES CAUSED BY NON-RESOLVING INFLAMMATION, INCLUDING CARDIOVASCULAR DISEASES. ATHEROSCLEROSIS (AS) HAS LONG BEEN RECOGNIZED AS A CHRONIC INFLAMMATORY DISEASE OF THE ARTERIAL WALLS, CHARACTERIZED BY LOCAL PERSISTENT AND STEPWISE ACCELERATING INFLAMMATION WITHOUT RESOLUTION, ALSO KNOWN AS UNCONTROLLED INFLAMMATION. THE PATHOGENESIS OF AS IS DRIVEN PRIMARILY BY HIGHLY PLASTIC MACROPHAGES VIA THEIR POLARIZATION TO PRO- OR ANTI-INFLAMMATORY PHENOTYPES AS WELL AS OTHER NOVEL SUBTYPES RECENTLY IDENTIFIED BY SINGLE-CELL SEQUENCING. ALTHOUGH EMERGING EVIDENCE HAS INDICATED THE KEY ROLE OF THE EPIGENETIC MACHINERY IN THE REGULATION OF MACROPHAGE PLASTICITY, THE INVESTIGATION OF EPIGENETIC ALTERATIONS AND MODIFIERS IN AS AND RELATED INFLAMMATION IS STILL IN ITS INFANCY. AN INCREASING NUMBER OF THE EPIGENETIC MODIFIERS (E.G. TET2, DNMT3A, HDAC3, HDAC9, JMJD3, KDM4A) HAVE BEEN IDENTIFIED IN EPIGENETIC REMODELLING OF MACROPHAGES THROUGH DNA METHYLATION OR HISTONE MODIFICATIONS (E.G. METHYLATION, ACETYLATION, AND RECENTLY LACTYLATION) IN INFLAMMATION. THESE OR MANY UNEXPLORED MODIFIERS FUNCTION TO DETERMINE OR SWITCH THE DIRECTION OF MACROPHAGE POLARIZATION VIA TRANSCRIPTIONAL REPROGRAMMING OF GENE EXPRESSION AND INTRACELLULAR METABOLIC REWIRING UPON MICROENVIRONMENTAL CUES, THEREBY REPRESENTING A PROMISING TARGET FOR ANTI-INFLAMMATORY THERAPY IN AS. HERE, WE REVIEW UP-TO-DATE FINDINGS INVOLVING THE EPIGENETIC REGULATION OF MACROPHAGES TO SHED LIGHT ON THE MECHANISM OF UNCONTROLLED INFLAMMATION DURING AS ONSET AND PROGRESSION. WE ALSO DISCUSS CURRENT CHALLENGES FOR DEVELOPING AN EFFECTIVE AND SAFE ANTI-AS THERAPY THAT TARGETS THE EPIGENETIC MODIFIERS AND PROPOSE A POTENTIAL ANTI-INFLAMMATORY STRATEGY THAT REPOLARIZES MACROPHAGES FROM PRO- TO ANTI-INFLAMMATORY PHENOTYPES. 2021 5 3207 28 HDACI: CELLULAR EFFECTS, OPPORTUNITIES FOR RESTORATIVE DENTISTRY. ACETYLATION OF HISTONE AND NON-HISTONE PROTEINS ALTERS GENE EXPRESSION AND INDUCES A HOST OF CELLULAR EFFECTS. THE ACETYLATION PROCESS IS HOMEOSTATICALLY BALANCED BY TWO GROUPS OF CELLULAR ENZYMES, HISTONE ACETYLTRANSFERASES (HATS) AND HISTONE DEACETYLASES (HDACS). HAT ACTIVITY RELAXES THE STRUCTURE OF THE HUMAN CHROMATIN, RENDERING IT TRANSCRIPTIONALLY ACTIVE, THEREBY INCREASING GENE EXPRESSION. IN CONTRAST, HDAC ACTIVITY LEADS TO GENE SILENCING. THE ENZYMATIC BALANCE CAN BE 'TIPPED' BY HISTONE DEACETYLASE INHIBITORS (HDACI), LEADING TO AN ACCUMULATION OF ACETYLATED PROTEINS, WHICH SUBSEQUENTLY MODIFY CELLULAR PROCESSES INCLUDING STEM CELL DIFFERENTIATION, CELL CYCLE, APOPTOSIS, GENE EXPRESSION, AND ANGIOGENESIS. THERE IS A VARIETY OF NATURAL AND SYNTHETIC HDACI AVAILABLE, AND THEIR PLEIOTROPIC EFFECTS HAVE CONTRIBUTED TO DIVERSE CLINICAL APPLICATIONS, NOT ONLY IN CANCER BUT ALSO IN NON-CANCER AREAS, SUCH AS CHRONIC INFLAMMATORY DISEASE, BONE ENGINEERING, AND NEURODEGENERATIVE DISEASE. INDEED, IT APPEARS THAT HDACI-MODULATED EFFECTS MAY DIFFER BETWEEN 'NORMAL' AND TRANSFORMED CELLS, PARTICULARLY WITH REGARD TO REACTIVE OXYGEN SPECIES ACCUMULATION, APOPTOSIS, PROLIFERATION, AND CELL CYCLE ARREST. THE POTENTIAL BENEFICIAL EFFECTS OF HDACI FOR HEALTH, RESULTING FROM THEIR ABILITY TO REGULATE GLOBAL GENE EXPRESSION BY EPIGENETIC MODIFICATION OF DNA-ASSOCIATED PROTEINS, ALSO OFFER POTENTIAL FOR APPLICATION WITHIN RESTORATIVE DENTISTRY, WHERE THEY MAY PROMOTE DENTAL TISSUE REGENERATION FOLLOWING PULPAL DAMAGE. 2011 6 6532 18 TRANSCRIPTIONAL REGULATION OF INFLAMMASOMES. INFLAMMASOMES ARE MULTIMOLECULAR COMPLEXES WITH POTENT INFLAMMATORY ACTIVITY. AS SUCH, THEIR ACTIVITY IS TIGHTLY REGULATED AT THE TRANSCRIPTIONAL AND POST-TRANSCRIPTIONAL LEVELS. IN THIS REVIEW, WE PRESENT THE TRANSCRIPTIONAL REGULATION OF INFLAMMASOME GENES FROM SENSORS (E.G., NLRP3) TO SUBSTRATES (E.G., IL-1BETA). LINEAGE-DETERMINING TRANSCRIPTION FACTORS SHAPE INFLAMMASOME RESPONSES IN DIFFERENT CELL TYPES WITH PROFOUND CONSEQUENCES ON THE RESPONSIVENESS TO INFLAMMASOME-ACTIVATING STIMULI. PRO-INFLAMMATORY SIGNALS (STERILE OR MICROBIAL) HAVE A KEY TRANSCRIPTIONAL IMPACT ON INFLAMMASOME GENES, WHICH IS LARGELY MEDIATED BY NF-KAPPAB AND THAT TRANSLATES INTO HIGHER ANTIMICROBIAL IMMUNE RESPONSES. FURTHERMORE, DIVERSE INTRINSIC (E.G., CIRCADIAN CLOCK, METABOLITES) OR EXTRINSIC (E.G., XENOBIOTICS) SIGNALS ARE INTEGRATED BY SIGNAL-DEPENDENT TRANSCRIPTION FACTORS AND CHROMATIN STRUCTURE CHANGES TO MODULATE TRANSCRIPTIONALLY INFLAMMASOME RESPONSES. FINALLY, ANTI-INFLAMMATORY SIGNALS (E.G., IL-10) COUNTERBALANCE INFLAMMASOME GENES INDUCTION TO LIMIT DELETERIOUS INFLAMMATION. TRANSCRIPTIONAL REGULATIONS THUS APPEAR AS THE FIRST LINE OF INFLAMMASOME REGULATION TO RAISE THE DEFENSE LEVEL IN FRONT OF STRESS AND INFECTIONS BUT ALSO TO LIMIT EXCESSIVE OR CHRONIC INFLAMMATION. 2020 7 5550 36 ROLE OF EPIGENETICS IN INFLAMMATION-ASSOCIATED DISEASES. THERE IS CONSIDERABLE EVIDENCE SUGGESTING THAT EPIGENETIC MECHANISMS MAY MEDIATE DEVELOPMENT OF CHRONIC INFLAMMATION BY MODULATING THE EXPRESSION OF PRO-INFLAMMATORY CYTOKINE TNF-ALPHA, INTERLEUKINS, TUMOR SUPPRESSOR GENES, ONCOGENES AND AUTOCRINE AND PARACRINE ACTIVATION OF THE TRANSCRIPTION FACTOR NF-KAPPAB. THESE MOLECULES ARE CONSTITUTIVELY PRODUCED BY A VARIETY OF CELLS UNDER CHRONIC INFLAMMATORY CONDITIONS, WHICH IN TURN LEADS TO THE DEVELOPMENT OF MAJOR DISEASES SUCH AS AUTOIMMUNE DISORDERS, CHRONIC OBSTRUCTIVE PULMONARY DISEASES, NEURODEGENERATIVE DISEASES AND CANCER. DISTINCT OR GLOBAL CHANGES IN THE EPIGENETIC LANDSCAPE ARE HALLMARKS OF CHRONIC INFLAMMATION DRIVEN DISEASES. EPIGENETICS INCLUDE CHANGES TO DISTINCT MARKERS ON THE GENOME AND ASSOCIATED CELLULAR TRANSCRIPTIONAL MACHINERY THAT ARE COPIED DURING CELL DIVISION (MITOSIS AND MEIOSIS). THESE CHANGES APPEAR FOR A SHORT SPAN OF TIME AND THEY NECESSARILY DO NOT MAKE PERMANENT CHANGES TO THE PRIMARY DNA SEQUENCE ITSELF. HOWEVER, THE MOST FREQUENTLY OBSERVED EPIGENETIC CHANGES INCLUDE ABERRANT DNA METHYLATION, AND HISTONE ACETYLATION AND DEACETYLATION. IN THIS CHAPTER, WE FOCUS ON PRO-INFLAMMATORY MOLECULES THAT ARE REGULATED BY ENZYMES INVOLVED IN EPIGENETIC MODIFICATIONS SUCH AS ARGININE AND LYSINE METHYL TRANSFERASES, DNA METHYLTRANSFERASE, HISTONE ACETYLTRANSFERASES AND HISTONE DEACETYLASES AND THEIR ROLE IN INFLAMMATION DRIVEN DISEASES. AGENTS THAT MODULATE OR INHIBIT THESE EPIGENETIC MODIFICATIONS, SUCH AS HAT OR HDAC INHIBITORS HAVE SHOWN GREAT POTENTIAL IN INHIBITING THE PROGRESSION OF THESE DISEASES. GIVEN THE PLASTICITY OF THESE EPIGENETIC CHANGES AND THEIR READINESS TO RESPOND TO INTERVENTION BY SMALL MOLECULE INHIBITORS, THERE IS A TREMENDOUS POTENTIAL FOR THE DEVELOPMENT OF NOVEL THERAPEUTICS THAT WILL SERVE AS DIRECT OR ADJUVANT THERAPEUTIC COMPOUNDS IN THE TREATMENT OF THESE DISEASES. 2013 8 313 23 ALCOHOL METABOLISM AND EPIGENETICS CHANGES. METABOLITES, INCLUDING THOSE GENERATED DURING ETHANOL METABOLISM, CAN IMPACT DISEASE STATES BY BINDING TO TRANSCRIPTION FACTORS AND/OR MODIFYING CHROMATIN STRUCTURE, THEREBY ALTERING GENE EXPRESSION PATTERNS. FOR EXAMPLE, THE ACTIVITIES OF ENZYMES INVOLVED IN EPIGENETIC MODIFICATIONS SUCH AS DNA AND HISTONE METHYLATION AND HISTONE ACETYLATION, ARE INFLUENCED BY THE LEVELS OF METABOLITES SUCH AS NICOTINAMIDE ADENINE DINUCLEOTIDE (NAD), ADENOSINE TRIPHOSPHATE (ATP), AND S-ADENOSYLMETHIONINE (SAM). CHRONIC ALCOHOL CONSUMPTION LEADS TO SIGNIFICANT REDUCTIONS IN SAM LEVELS, THEREBY CONTRIBUTING TO DNA HYPOMETHYLATION. SIMILARLY, ETHANOL METABOLISM ALTERS THE RATIO OF NAD+ TO REDUCED NAD (NADH) AND PROMOTES THE FORMATION OF REACTIVE OXYGEN SPECIES AND ACETATE, ALL OF WHICH IMPACT EPIGENETIC REGULATORY MECHANISMS. IN ADDITION TO ALTERED CARBOHYDRATE METABOLISM, INDUCTION OF CELL DEATH, AND CHANGES IN MITOCHONDRIAL PERMEABILITY TRANSITION, THESE METABOLISM-RELATED CHANGES CAN LEAD TO MODULATION OF EPIGENETIC REGULATION OF GENE EXPRESSION. UNDERSTANDING THE NATURE OF THESE EPIGENETIC CHANGES WILL HELP RESEARCHERS DESIGN NOVEL MEDICATIONS TO TREAT OR AT LEAST AMELIORATE ALCOHOL-INDUCED ORGAN DAMAGE. 2013 9 2280 27 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 10 1383 33 DIABETES AND ITS CARDIOVASCULAR COMPLICATIONS: POTENTIAL ROLE OF THE ACETYLTRANSFERASE P300. DIABETES HAS BEEN SHOWN TO ACCELERATE VASCULAR SENESCENCE, WHICH IS ASSOCIATED WITH CHRONIC INFLAMMATION AND OXIDATIVE STRESS, BOTH IMPLICATED IN THE DEVELOPMENT OF ENDOTHELIAL DYSFUNCTION. THIS CONDITION REPRESENTS THE INITIAL ALTERATION LINKING DIABETES TO RELATED CARDIOVASCULAR (CV) COMPLICATIONS. RECENTLY, IT HAS BEEN HYPOTHESISED THAT THE ACETYLTRANSFERASE, P300, MAY CONTRIBUTE TO ESTABLISHING AN EARLY VASCULAR SENESCENT PHENOTYPE, PLAYING A RELEVANT ROLE IN DIABETES-ASSOCIATED INFLAMMATION AND OXIDATIVE STRESS, WHICH DRIVE ENDOTHELIAL DYSFUNCTION. SPECIFICALLY, P300 CAN MODULATE VASCULAR INFLAMMATION THROUGH EPIGENETIC MECHANISMS AND TRANSCRIPTION FACTORS ACETYLATION. INDEED, IT REGULATES THE INFLAMMATORY PATHWAY BY INTERACTING WITH NUCLEAR FACTOR KAPPA-LIGHT-CHAIN-ENHANCER OF ACTIVATED B CELLS P65 SUBUNIT (NF-KAPPAB P65) OR BY INDUCING ITS ACETYLATION, SUGGESTING A CRUCIAL ROLE OF P300 AS A BRIDGE BETWEEN NF-KAPPAB P65 AND THE TRANSCRIPTIONAL MACHINERY. ADDITIONALLY, P300-MEDIATED EPIGENETIC MODIFICATIONS COULD BE UPSTREAM OF THE ACTIVATION OF INFLAMMATORY CYTOKINES, AND THEY MAY INDUCE OXIDATIVE STRESS BY AFFECTING THE PRODUCTION OF REACTIVE OXYGEN SPECIES (ROS). BECAUSE SEVERAL IN VITRO AND IN VIVO STUDIES SHED LIGHT ON THE POTENTIAL USE OF ACETYLTRANSFERASE INHIBITORS, A BETTER UNDERSTANDING OF THE MECHANISMS UNDERLYING THE ROLE OF P300 IN DIABETIC VASCULAR DYSFUNCTION COULD HELP IN FINDING NEW STRATEGIES FOR THE CLINICAL MANAGEMENT OF CV DISEASES RELATED TO DIABETES. 2023 11 3403 20 HOW EPIGENETIC MODIFICATIONS DRIVE THE EXPRESSION AND MEDIATE THE ACTION OF PGC-1ALPHA IN THE REGULATION OF METABOLISM. EPIGENETIC CHANGES ARE A HALLMARK OF SHORT- AND LONG-TERM TRANSCRIPTIONAL REGULATION, AND HENCE INSTRUMENTAL IN THE CONTROL OF CELLULAR IDENTITY AND PLASTICITY. EPIGENETIC MECHANISMS LEADING TO CHANGES IN CHROMATIN STRUCTURE, ACCESSIBILITY FOR RECRUITMENT OF TRANSCRIPTIONAL COMPLEXES, AND INTERACTION OF ENHANCERS AND PROMOTERS ALL CONTRIBUTE TO ACUTE AND CHRONIC ADAPTATIONS OF CELLS, TISSUES AND ORGANS TO INTERNAL AND EXTERNAL PERTURBATIONS. SIMILARLY, THE PEROXISOME PROLIFERATOR-ACTIVATED RECEPTOR GAMMA COACTIVATOR 1ALPHA (PGC-1ALPHA) IS ACTIVATED BY STIMULI THAT ALTER THE CELLULAR ENERGETIC DEMAND, AND SUBSEQUENTLY CONTROLS COMPLEX TRANSCRIPTIONAL NETWORKS RESPONSIBLE FOR CELLULAR PLASTICITY. IT THUS IS OF NO SURPRISE THAT PGC-1ALPHA IS UNDER THE CONTROL OF EPIGENETIC MECHANISMS, AND CONSTITUTES A MEDIATOR OF EPIGENETIC CHANGES IN VARIOUS TISSUES AND CONTEXTS. IN THIS REVIEW, WE SUMMARIZE THE CURRENT KNOWLEDGE OF THE LINK BETWEEN EPIGENETICS AND PGC-1ALPHA IN HEALTH AND DISEASE. 2019 12 215 27 ACUTE AND LONG-TERM NUTRIENT-LED MODIFICATIONS OF GENE EXPRESSION: POTENTIAL ROLE OF SIRT1 AS A CENTRAL CO-ORDINATOR OF SHORT AND LONGER-TERM PROGRAMMING OF TISSUE FUNCTION. ENVIRONMENTAL FACTORS CAN INFLUENCE THE ACUTE AND LONGER-TERM RISKS OF DEVELOPING DISEASES, INCLUDING TYPE 2 DIABETES MELLITUS AND CARDIOVASCULAR DISEASE; HOWEVER, THE UNDERLYING MECHANISM REMAINS ELUSIVE. INCREASING EVIDENCE SUGGESTS THAT THESE EFFECTS CAN BE ACHIEVED BY MODIFICATION OF METABOLIC GENE EXPRESSION. THESE INCLUDE ACUTE CHANGES IN HISTONE METHYLATION, ACETYLATION, PHOSPHORYLATION, AND UBIQUITINATION AND LONGER-TERM DNA SILENCING ELICITED BY DNA METHYLATION. THUS, AN INCREASED RISK OF DISEASE MAY REFLECT ACUTE OR CHRONIC STABLE MODIFICATION OF GENES THAT REGULATE NUTRIENT HANDLING, LEADING TO ALTERED NUTRIENT UTILIZATION (INCREASED LIPID OXIDATION AT THE EXPENSE OF GLUCOSE UTILIZATION) AND/OR CHANGES IN THE BALANCE BETWEEN NUTRIENT STORAGE AND ENERGY PRODUCTION, THEREBY FAVORING THE DEVELOPMENT OF OBESITY. THE REVIEW ADDRESSES THE HYPOTHESIS THAT EARLY-LIFE EPIGENETIC PROGRAMMING OF GENE EXPRESSION COULD BE MIRRORED BY CHANGES IN ACUTE FUNCTION OF NUCLEAR RECEPTORS, IN PARTICULAR THE PEROXISOME PROLIFERATOR-ACTIVATED RECEPTORS, ACHIEVED BY ENZYMES THAT ARE MORE CONVENTIONALLY INVOLVED IN REGULATING DNA METHYLATION AND POST-TRANSCRIPTIONAL MODIFICATION OF HISTONES. EMPHASIS IS PLACED ON THE POTENTIAL IMPORTANCE OF THE PROTEIN DEACETYLASE SIRTUIN-1 AS A CENTRAL CO-ORDINATOR. 2010 13 5293 22 PROTEASOMAL DEGRADATION OF THE HISTONE ACETYL TRANSFERASE P300 CONTRIBUTES TO BETA-CELL INJURY IN A DIABETES ENVIRONMENT. IN TYPE 2 DIABETES, AMYLOID OLIGOMERS, CHRONIC HYPERGLYCEMIA, LIPOTOXICITY, AND PRO-INFLAMMATORY CYTOKINES ARE DETRIMENTAL TO BETA-CELLS, CAUSING APOPTOSIS AND IMPAIRED INSULIN SECRETION. THE HISTONE ACETYL TRANSFERASE P300, INVOLVED IN REMODELING OF CHROMATIN STRUCTURE BY EPIGENETIC MECHANISMS, IS A KEY UBIQUITOUS ACTIVATOR OF THE TRANSCRIPTIONAL MACHINERY. IN THIS STUDY, WE REPORT THAT LOSS OF P300 ACETYL TRANSFERASE ACTIVITY AND EXPRESSION LEADS TO BETA-CELL APOPTOSIS, AND MOST IMPORTANTLY, THAT STRESS SITUATIONS KNOWN TO BE ASSOCIATED WITH DIABETES ALTER P300 LEVELS AND FUNCTIONAL INTEGRITY. WE FOUND THAT PROTEASOMAL DEGRADATION IS THE MECHANISM SUBSERVING P300 LOSS IN BETA-CELLS EXPOSED TO HYPERGLYCEMIA OR PRO-INFLAMMATORY CYTOKINES. WE ALSO REPORT THAT MELATONIN, A HORMONE PRODUCED IN THE PINEAL GLAND AND KNOWN TO PLAY KEY ROLES IN BETA-CELL HEALTH, PRESERVES P300 LEVELS ALTERED BY THESE TOXIC CONDITIONS. COLLECTIVELY, THESE DATA IMPLY AN IMPORTANT ROLE FOR P300 IN THE PATHOPHYSIOLOGY OF DIABETES. 2018 14 3322 25 HISTONE ACETYLTRANSFERASE P300 INDUCES DE NOVO SUPER-ENHANCERS TO DRIVE CELLULAR SENESCENCE. ACCUMULATION OF SENESCENT CELLS DURING AGING CONTRIBUTES TO CHRONIC INFLAMMATION AND AGE-RELATED DISEASES. WHILE SENESCENCE IS ASSOCIATED WITH PROFOUND ALTERATIONS OF THE EPIGENOME, A SYSTEMATIC VIEW OF EPIGENETIC FACTORS IN REGULATING SENESCENCE IS LACKING. HERE, WE CURATED A LIBRARY OF SHORT HAIRPIN RNAS FOR TARGETED SILENCING OF ALL KNOWN EPIGENETIC PROTEINS AND PERFORMED A HIGH-THROUGHPUT SCREEN TO IDENTIFY KEY CANDIDATES WHOSE DOWNREGULATION CAN DELAY REPLICATIVE SENESCENCE OF PRIMARY HUMAN CELLS. THIS SCREEN IDENTIFIED MULTIPLE NEW PLAYERS INCLUDING THE HISTONE ACETYLTRANSFERASE P300 THAT WAS FOUND TO BE A PRIMARY DRIVER OF THE SENESCENT PHENOTYPE. P300, BUT NOT THE PARALOGOUS CBP, INDUCES A DYNAMIC HYPER-ACETYLATED CHROMATIN STATE AND PROMOTES THE FORMATION OF ACTIVE ENHANCER ELEMENTS IN THE NON-CODING GENOME, LEADING TO A SENESCENCE-SPECIFIC GENE EXPRESSION PROGRAM. OUR WORK ILLUSTRATES A CAUSAL ROLE OF HISTONE ACETYLTRANSFERASES AND ACETYLATION IN SENESCENCE AND SUGGESTS P300 AS A POTENTIAL THERAPEUTIC TARGET FOR SENESCENCE AND AGE-RELATED DISEASES. 2019 15 2344 21 EPIGENETIC REGULATION OF MACROPHAGES: FROM HOMEOSTASIS MAINTENANCE TO HOST DEFENSE. MACROPHAGES ARE CRUCIAL MEMBERS OF THE INNATE IMMUNE RESPONSE AND IMPORTANT REGULATORS. THE DIFFERENTIATION AND ACTIVATION OF MACROPHAGES REQUIRE THE TIMELY REGULATION OF GENE EXPRESSION, WHICH DEPENDS ON THE INTERACTION OF A VARIETY OF FACTORS, INCLUDING TRANSCRIPTION FACTORS AND EPIGENETIC MODIFICATIONS. EPIGENETIC CHANGES ALSO GIVE MACROPHAGES THE ABILITY TO SWITCH RAPIDLY BETWEEN CELLULAR PROGRAMS, INDICATING THE ABILITY OF EPIGENETIC MECHANISMS TO AFFECT PHENOTYPE PLASTICITY. IN THIS REVIEW, WE FOCUS ON KEY EPIGENETIC EVENTS ASSOCIATED WITH MACROPHAGE FATE, HIGHLIGHTING EVENTS RELATED TO THE MAINTENANCE OF TISSUE HOMEOSTASIS, RESPONSES TO DIFFERENT STIMULI AND THE FORMATION OF INNATE IMMUNE MEMORY. FURTHER UNDERSTANDING OF THE EPIGENETIC REGULATION OF MACROPHAGES WILL BE HELPFUL FOR MAINTAINING TISSUE INTEGRITY, PREVENTING CHRONIC INFLAMMATORY DISEASES AND DEVELOPING THERAPIES TO ENHANCE HOST DEFENSE. 2020 16 4974 28 PATHOPHYSIOLOGICAL MECHANISMS LEADING TO MUSCLE LOSS IN CHRONIC KIDNEY DISEASE. LOSS OF MUSCLE PROTEINS IS A DELETERIOUS CONSEQUENCE OF CHRONIC KIDNEY DISEASE (CKD) THAT CAUSES A DECREASE IN MUSCLE STRENGTH AND FUNCTION, AND CAN LEAD TO A REDUCTION IN QUALITY OF LIFE AND INCREASED RISK OF MORBIDITY AND MORTALITY. THE EFFECTIVENESS OF CURRENT TREATMENT STRATEGIES IN PREVENTING OR REVERSING MUSCLE PROTEIN LOSSES IS LIMITED. THE LIMITATIONS LARGELY STEM FROM THE SYSTEMIC NATURE OF DISEASES SUCH AS CKD, WHICH STIMULATE SKELETAL MUSCLE PROTEIN DEGRADATION PATHWAYS WHILE SIMULTANEOUSLY ACTIVATING MECHANISMS THAT IMPAIR MUSCLE PROTEIN SYNTHESIS AND REPAIR. STIMULI THAT INITIATE MUSCLE PROTEIN LOSS INCLUDE METABOLIC ACIDOSIS, INSULIN AND IGF1 RESISTANCE, CHANGES IN HORMONES, CYTOKINES, INFLAMMATORY PROCESSES AND DECREASED APPETITE. A GROWING BODY OF EVIDENCE SUGGESTS THAT SIGNALLING MOLECULES SECRETED FROM MUSCLE CAN ENTER THE CIRCULATION AND SUBSEQUENTLY INTERACT WITH RECIPIENT ORGANS, INCLUDING THE KIDNEYS, WHILE CONVERSELY, PATHOLOGICAL EVENTS IN THE KIDNEY CAN ADVERSELY INFLUENCE PROTEIN METABOLISM IN SKELETAL MUSCLE, DEMONSTRATING THE EXISTENCE OF CROSSTALK BETWEEN KIDNEY AND MUSCLE. TOGETHER, THESE SIGNALS, WHETHER DIRECT OR INDIRECT, INDUCE CHANGES IN THE LEVELS OF REGULATORY AND EFFECTOR PROTEINS VIA ALTERATIONS IN MRNAS, MICRORNAS AND CHROMATIN EPIGENETIC RESPONSES. ADVANCES IN OUR UNDERSTANDING OF THE SIGNALS AND PROCESSES THAT MEDIATE MUSCLE LOSS IN CKD AND OTHER MUSCLE WASTING CONDITIONS WILL SUPPORT THE FUTURE DEVELOPMENT OF THERAPEUTIC STRATEGIES TO REDUCE MUSCLE LOSS. 2022 17 697 31 BROMODOMAIN AND EXTRATERMINAL PROTEINS AS NOVEL EPIGENETIC TARGETS FOR RENAL DISEASES. EPIGENETIC MECHANISMS, ESPECIALLY DNA METHYLATION AND HISTONE MODIFICATIONS, ARE DYNAMIC PROCESSES THAT REGULATE THE GENE EXPRESSION TRANSCRIPTIONAL PROGRAM IN NORMAL AND DISEASED STATES. THE BROMODOMAIN AND EXTRATERMINAL (BET) PROTEIN FAMILY (BRD2, BRD3, BRD4, AND BRDT) ARE EPIGENETIC READERS THAT, VIA BROMODOMAINS, REGULATE GENE TRANSCRIPTION BY BINDING TO ACETYLATED LYSINE RESIDUES ON HISTONES AND MASTER TRANSCRIPTIONAL FACTORS. EXPERIMENTAL DATA HAVE DEMONSTRATED THE INVOLVEMENT OF SOME BET PROTEINS IN MANY PATHOLOGICAL CONDITIONS, INCLUDING TUMOR DEVELOPMENT, INFECTIONS, AUTOIMMUNITY, AND INFLAMMATION. SELECTIVE BROMODOMAIN INHIBITORS ARE EPIGENETIC DRUGS THAT BLOCK THE INTERACTION BETWEEN BET PROTEINS AND ACETYLATED PROTEINS, THUS EXERTING BENEFICIAL EFFECTS. RECENT DATA HAVE DESCRIBED THE BENEFICIAL EFFECT OF BET INHIBITION ON EXPERIMENTAL RENAL DISEASES. EMERGING EVIDENCE UNDERSCORES THE IMPORTANCE OF ENVIRONMENTAL MODIFICATIONS IN THE ORIGIN OF PATHOLOGICAL FEATURES IN CHRONIC KIDNEY DISEASES (CKD). SEVERAL CELLULAR PROCESSES SUCH AS OXIDATION, METABOLIC DISORDERS, CYTOKINES, INFLAMMATION, OR ACCUMULATED UREMIC TOXINS MAY INDUCE EPIGENETIC MODIFICATIONS THAT REGULATE KEY PROCESSES INVOLVED IN RENAL DAMAGE AND IN OTHER PATHOLOGICAL CONDITIONS OBSERVED IN CKD PATIENTS. HERE, WE REVIEW HOW TARGETING BROMODOMAINS IN BET PROTEINS MAY REGULATE ESSENTIAL PROCESSES INVOLVED IN RENAL DISEASES AND IN ASSOCIATED COMPLICATIONS FOUND IN CKD PATIENTS, SUCH AS CARDIOVASCULAR DAMAGE, HIGHLIGHTING THE POTENTIAL OF EPIGENETIC THERAPEUTIC STRATEGIES AGAINST BET PROTEINS FOR CKD TREATMENT AND ASSOCIATED RISKS. 2019 18 3289 28 HIF-1ALPHA MEDIATES TUMOR HYPOXIA TO CONFER A PERPETUAL MESENCHYMAL PHENOTYPE FOR MALIGNANT PROGRESSION. ALTHOUGH TUMOR PROGRESSION INVOLVES GENETIC AND EPIGENETIC ALTERATIONS TO NORMAL CELLULAR BIOLOGY, THE UNDERLYING MECHANISMS OF THESE CHANGES REMAIN OBSCURE. NUMEROUS STUDIES HAVE SHOWN THAT HYPOXIA-INDUCIBLE FACTOR 1ALPHA (HIF-1ALPHA) IS OVEREXPRESSED IN MANY HUMAN CANCERS AND UP-REGULATES A HOST OF HYPOXIA-RESPONSIVE GENES FOR CANCER GROWTH AND SURVIVAL. WE RECENTLY IDENTIFIED AN ALTERNATIVE MECHANISM OF HIF-1ALPHA FUNCTION THAT INDUCES GENETIC ALTERATIONS BY SUPPRESSING DNA REPAIR. HERE, WE SHOW THAT LONG-TERM HYPOXIA, WHICH MIMICS THE TUMOR MICROENVIRONMENT, DRIVES A PERPETUAL EPITHELIAL-MESENCHYMAL TRANSITION (EMT) THROUGH UP-REGULATION OF THE ZINC FINGER E-BOX BINDING HOMEOBOX PROTEIN ZEB2, WHEREAS SHORT-TERM HYPOXIA INDUCES A REVERSIBLE EMT THAT REQUIRES THE TRANSCRIPTION FACTOR TWIST1. MOREOVER, WE SHOW THAT THE PERPETUAL EMT DRIVEN BY CHRONIC HYPOXIA DEPENDS ON HIF-1ALPHA INDUCTION OF GENETIC ALTERATIONS RATHER THAN ITS CANONICAL TRANSCRIPTIONAL ACTIVATOR FUNCTION. THESE MESENCHYMAL TUMOR CELLS NOT ONLY ACQUIRE TUMORIGENICITY BUT ALSO DISPLAY CHARACTERISTICS OF ADVANCED CANCERS, INCLUDING NECROSIS, AGGRESSIVE INVASION, AND METASTASIS. HENCE, THESE RESULTS REVEAL A MECHANISM BY WHICH HIF-1ALPHA PROMOTES A PERPETUAL MESENCHYMAL PHENOTYPE, THEREBY ADVANCING TUMOR PROGRESSION. 2011 19 4768 24 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 20 2218 30 EPIGENETIC MODIFICATIONS IN FIBROTIC DISEASES: IMPLICATIONS FOR PATHOGENESIS AND PHARMACOLOGICAL TARGETS. ORGAN FIBROSIS IS A COMPLEX AND CHRONIC DISORDER THAT RESULTS FROM A VARIETY OF ACUTE INJURIES AND CONTRIBUTES TO THIRTY PERCENT OF NATURALLY OCCURRING DEATHS WORLDWIDE. THE MAIN FEATURE OF ORGAN FIBROSIS IS THE EXCESSIVE ACCUMULATION AND DEPOSIT OF EXTRACELLULAR MATRIX, THEREBY LEADING TO ORGAN DYSFUNCTION, LOSS OF ELASTICITY, AND DEVELOPMENT OF A RIGID ORGAN. ACCUMULATING EVIDENCE SHOWS THAT EPIGENETIC REMODELING, INCLUDING ABERRANT DNA METHYLATION AND NONCODING RNA EXPRESSION AS WELL AS HISTONE POST-TRANSLATIONAL MODIFICATIONS, PLAY IMPORTANT ROLES IN THE PATHOGENESIS OF FIBROSIS THROUGH THE REGULATION OF FIBROBLAST ACTIVATION, DIFFERENTIATION, AND APOPTOSIS, AS WELL AS COLLAGEN SYNTHESIS AND PROFIBROTIC GENE TRANSCRIPTION. IN THIS REVIEW, WE DISCUSS THE BASIC REGULATION OF DNA METHYLATION, NONCODING RNA EXPRESSION, AND HISTONE POST-TRANSLATIONAL MODIFICATION, AND THEIR PARTICIPATION IN THE PATHOGENESIS AND DEVELOPMENT OF ORGAN FIBROSIS. THIS REVIEW ALSO PROVIDES THE LATEST INSIGHTS INTO THE NOVEL BIOMARKERS AND THERAPEUTIC TARGETS FOR FIBROSIS THROUGH MODULATION OF EPIGENETIC REMODELING. 2015