1 5293 92 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 2 799 29 CELLULAR SIGNALING AND POTENTIAL NEW TREATMENT TARGETS IN DIABETIC RETINOPATHY. DYSFUNCTION AND DEATH OF MICROVASCULAR CELLS AND IMBALANCE BETWEEN THE PRODUCTION AND THE DEGRADATION OF EXTRACELLULAR MATRIX (ECM) PROTEINS ARE A CHARACTERISTIC FEATURE OF DIABETIC RETINOPATHY (DR). GLUCOSE-INDUCED BIOCHEMICAL ALTERATIONS IN THE VASCULAR ENDOTHELIAL CELLS MAY ACTIVATE A CASCADE OF SIGNALING PATHWAYS LEADING TO INCREASED PRODUCTION OF ECM PROTEINS AND CELLULAR DYSFUNCTION/DEATH. CHRONIC DIABETES LEADS TO THE ACTIVATION OF A NUMBER OF SIGNALING PROTEINS INCLUDING PROTEIN KINASE C, PROTEIN KINASE B, AND MITOGEN-ACTIVATED PROTEIN KINASES. THESE SIGNALING CASCADES ARE ACTIVATED IN RESPONSE TO HYPERGLYCEMIA-INDUCED OXIDATIVE STRESS, POLYOL PATHWAY, AND ADVANCED GLYCATION END PRODUCT FORMATION AMONG OTHERS. THE ABERRANT SIGNALING PATHWAYS ULTIMATELY LEAD TO ACTIVATION OF TRANSCRIPTION FACTORS SUCH AS NUCLEAR FACTOR-KAPPAB AND ACTIVATING PROTEIN-1. THE ACTIVITY OF THESE TRANSCRIPTION FACTORS IS ALSO REGULATED BY EPIGENETIC MECHANISMS THROUGH TRANSCRIPTIONAL COACTIVATOR P300. THESE COMPLEX SIGNALING PATHWAYS MAY BE INVOLVED IN GLUCOSE-INDUCED ALTERATIONS OF ENDOTHELIAL CELL PHENOTYPE LEADING TO THE PRODUCTION OF INCREASED ECM PROTEINS AND VASOACTIVE EFFECTOR MOLECULES CAUSING FUNCTIONAL AND STRUCTURAL CHANGES IN THE MICROVASCULATURE. UNDERSTANDING OF SUCH MECHANISTIC PATHWAYS WILL HELP TO DEVELOP FUTURE ADJUVANT THERAPIES FOR DIABETIC RETINOPATHY. 2007 3 4768 27 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 4 2344 23 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 5 3184 23 HARNESSING METABOLISM OF HEPATIC MACROPHAGES TO AID LIVER REGENERATION. LIVER REGENERATION IS A DYNAMIC AND REGULATED PROCESS THAT INVOLVES INFLAMMATION, GRANULATION, AND TISSUE REMODELING. HEPATIC MACROPHAGES, ABUNDANTLY DISTRIBUTED IN THE LIVER, ARE ESSENTIAL COMPONENTS THAT ACTIVELY PARTICIPATE IN EACH STEP TO ORCHESTRATE LIVER REGENERATION. IN THE HOMEOSTATIC LIVER, RESIDENT MACROPHAGES (KUPFFER CELLS) ACQUIRE A TOLEROGENIC PHENOTYPE AND CONTRIBUTE TO IMMUNOLOGICAL TOLERANCE. FOLLOWING TOXICITY-INDUCED DAMAGE OR PHYSICAL RESECTION, KUPFFER CELLS AS WELL AS MONOCYTE-DERIVED MACROPHAGES CAN BE ACTIVATED AND PROMOTE AN INFLAMMATORY PROCESS THAT SUPPORTS THE SURVIVAL AND ACTIVATION OF HEPATIC MYOFIBROBLASTS AND THUS PROMOTES SCAR TISSUE FORMATION. SUBSEQUENTLY, THESE MACROPHAGES, IN TURN, EXHIBIT THE ANTI-INFLAMMATORY EFFECTS CRITICAL TO EXTRACELLULAR MATRIX REMODELING DURING THE RESOLUTION STAGE. HOWEVER, CONTINUOUS DAMAGE-INDUCED CHRONIC INFLAMMATION GENERALLY LEADS TO HEPATIC MACROPHAGE DYSFUNCTION, WHICH EXACERBATES HEPATOCELLULAR INJURY AND TRIGGERS FURTHER LIVER FIBROSIS AND EVEN CIRRHOSIS. EMERGING MACROPHAGE-TARGETING STRATEGIES HAVE SHOWN EFFICACY IN BOTH PRECLINICAL AND CLINICAL STUDIES. INCREASING EVIDENCE INDICATES THAT METABOLIC REWIRING PROVIDES SUBSTRATES FOR EPIGENETIC MODIFICATION, WHICH ENDOWS MONOCYTES/MACROPHAGES WITH PROLONGED "INNATE IMMUNE MEMORY". THEREFORE, IT IS REASONABLE TO CONCEIVE NOVEL THERAPEUTIC STRATEGIES FOR METABOLICALLY REPROGRAMMING MACROPHAGES AND THUS MEDIATE A HOMEOSTATIC OR REPARATIVE PROCESS FOR HEPATIC INFLAMMATION MANAGEMENT AND LIVER REGENERATION. 2023 6 1382 33 DIABETES ALTERS ACTIVATION AND REPRESSION OF PRO- AND ANTI-INFLAMMATORY SIGNALING PATHWAYS IN THE VASCULATURE. A CENTRAL MECHANISM DRIVING VASCULAR DISEASE IN DIABETES IS IMMUNE CELL-MEDIATED INFLAMMATION. IN DIABETES, ENHANCED OXIDATION AND GLYCATION OF MACROMOLECULES, SUCH AS LIPOPROTEINS, INSULTS THE ENDOTHELIUM, AND ACTIVATES BOTH INNATE AND ADAPTIVE ARMS OF THE IMMUNE SYSTEM BY GENERATING NEW ANTIGENS FOR PRESENTATION TO ADAPTIVE IMMUNE CELLS. CHRONIC INFLAMMATION OF THE ENDOTHELIUM IN DIABETES LEADS TO CONTINUOUS INFILTRATION AND ACCUMULATION OF LEUKOCYTES AT SITES OF ENDOTHELIAL CELL INJURY. WE WILL DESCRIBE THE CENTRAL ROLE OF THE MACROPHAGE AS A SOURCE OF SIGNALING MOLECULES AND DAMAGING BY-PRODUCTS WHICH ACTIVATE INFILTRATING LYMPHOCYTES IN THE TISSUE AND CONTRIBUTE TO THE PRO-OXIDANT AND PRO-INFLAMMATORY MICROENVIRONMENT. AN IMPORTANT ASPECT TO BE CONSIDERED IS THE DIABETES-ASSOCIATED DEFECTS IN THE IMMUNE SYSTEM, SUCH AS FEWER OR DYSFUNCTIONAL ATHERO-PROTECTIVE LEUKOCYTE SUBSETS IN THE DIABETIC LESION COMPARED TO NON-DIABETIC LESIONS. THIS REVIEW WILL DISCUSS THE KEY PRO-INFLAMMATORY SIGNALING PATHWAYS RESPONSIBLE FOR LEUKOCYTE RECRUITMENT AND ACTIVATION IN THE INJURED VESSEL, WITH PARTICULAR FOCUS ON PRO- AND ANTI-INFLAMMATORY PATHWAYS ABERRANTLY ACTIVATED OR REPRESSED IN DIABETES. WE AIM TO DESCRIBE THE INTERACTION BETWEEN ADVANCED GLYCATION END PRODUCTS AND THEIR PRINCIPLE RECEPTOR RAGE, ANGIOTENSIN II, AND THE ANG II TYPE 1 RECEPTOR, IN ADDITION TO REACTIVE OXYGEN SPECIES (ROS) PRODUCTION BY NADPH-OXIDASE ENZYMES THAT ARE RELEVANT TO VASCULAR AND IMMUNE CELL FUNCTION IN THE CONTEXT OF DIABETIC VASCULOPATHY. FURTHERMORE, WE WILL TOUCH ON RECENT ADVANCES IN EPIGENETIC MEDICINE THAT HAVE REVEALED HIGH GLUCOSE-MEDIATED CHANGES IN THE TRANSCRIPTION OF GENES WITH KNOWN PRO-INFLAMMATORY DOWNSTREAM TARGETS. FINALLY, NOVEL ANTI-ATHEROSCLEROSIS STRATEGIES THAT TARGET THE VASCULAR IMMUNE INTERFACE WILL BE EXPLORED; SUCH AS VACCINATION AGAINST MODIFIED LOW-DENSITY LIPOPROTEIN AND PHARMACOLOGICAL INHIBITION OF ROS-PRODUCING ENZYMES. 2013 7 6532 25 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 8 3678 25 INFLAMMATION AND REGENERATION IN THE DENTIN-PULP COMPLEX: A DOUBLE-EDGED SWORD. DENTAL TISSUE INFECTION AND DISEASE RESULT IN ACUTE AND CHRONIC ACTIVATION OF THE INNATE IMMUNE RESPONSE, WHICH IS MEDIATED BY MOLECULAR AND CELLULAR SIGNALING. DIFFERENT CELL TYPES WITHIN THE DENTIN-PULP COMPLEX ARE ABLE TO DETECT INVADING BACTERIA AT ALL STAGES OF THE INFECTION. INDEED, AT RELATIVELY EARLY DISEASE STAGES, ODONTOBLASTS WILL RESPOND TO BACTERIAL COMPONENTS, AND AS THE DISEASE PROGRESSES, CORE PULPAL CELLS INCLUDING FIBROBLASTS, STEMS CELLS, ENDOTHELIAL CELLS, AND IMMUNE CELLS WILL BECOME INVOLVED. PATTERN RECOGNITION RECEPTORS, SUCH AS TOLL-LIKE RECEPTORS EXPRESSED ON THESE CELL TYPES, ARE RESPONSIBLE FOR DETECTING BACTERIAL COMPONENTS, AND THEIR LIGAND BINDING LEADS TO THE ACTIVATION OF THE NUCLEAR FACTOR-KAPPA B AND P38 MITOGEN-ACTIVATED PROTEIN (MAP) KINASE INTRACELLULAR SIGNALING CASCADES. SUBSEQUENT NUCLEAR TRANSLOCATION OF THE TRANSCRIPTION FACTOR SUBUNITS FROM THESE PATHWAYS WILL LEAD TO PROINFLAMMATORY MEDIATOR EXPRESSION, INCLUDING INCREASES IN CYTOKINES AND CHEMOKINES, WHICH TRIGGER HOST CELLULAR DEFENSE MECHANISMS. THE COMPLEX MOLECULAR SIGNALING WILL RESULT IN THE RECRUITMENT OF IMMUNE SYSTEM CELLS TARGETED AT COMBATING THE INVADING MICROBES; HOWEVER, THE TRAFFICKING AND ANTIBACTERIAL ACTIVITY OF THESE CELLS CAN LEAD TO COLLATERAL TISSUE DAMAGE. RECENT EVIDENCE SUGGESTS THAT IF INFLAMMATION IS RESOLVED RELATIVELY LOW LEVELS OF PROINFLAMMATORY MEDIATORS MAY PROMOTE TISSUE REPAIR, WHEREAS IF CHRONIC INFLAMMATION ENSUES REPAIR MECHANISMS BECOME INHIBITED. THUS, THE EFFECTS OF MEDIATORS ARE TEMPORAL CONTEXT DEPENDENT. ALTHOUGH CONTAINMENT AND REMOVAL OF THE INFECTION ARE KEYS TO ENABLE DENTAL TISSUE REPAIR, IT IS FEASIBLE THAT THE DEVELOPMENT OF ANTI-INFLAMMATORY AND IMMUNOMODULATORY APPROACHES, BASED ON MOLECULAR, EPIGENETIC, AND PHOTOBIOMODULATORY TECHNOLOGIES, MAY ALSO BE BENEFICIAL FOR FUTURE ENDODONTIC TREATMENTS. 2014 9 5396 24 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 10 5550 33 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 11 1300 20 DEDIFFERENTIATION AND IN VIVO REPROGRAMMING OF COMMITTED CELLS IN WOUND REPAIR (REVIEW). ACCUMULATING EVIDENCE HAS SHOWN THAT CELL DEDIFFERENTIATION OR REPROGRAMMING IS A PIVOTAL PROCEDURE FOR ANIMALS TO DEAL WITH INJURY AND PROMOTE ENDOGENOUS TISSUE REPAIR. TISSUE DAMAGE IS A CRITICAL FACTOR THAT TRIGGERS CELL DEDIFFERENTIATION OR REPROGRAMMING IN VIVO. BY CONTRAST, MICROENVIRONMENTAL CHANGES, INCLUDING THE LOSS OF STEM CELLS, HYPOXIA, CELL SENESCENCE, INFLAMMATION AND IMMUNITY, CAUSED BY TISSUE DAMAGE CAN RETURN CELLS TO AN UNSTABLE STATE. IF THE WOUND PERSISTS IN THE LONG?TERM DUE TO CHRONIC DAMAGE, THEN DEDIFFERENTIATION OR REPROGRAMMING OF THE SURROUNDING CELLS MAY LEAD TO CARCINOGENESIS. IN RECENT YEARS, EXTENSIVE RESEARCH HAS BEEN PERFORMED INVESTIGATING CELL DEDIFFERENTIATION OR REPROGRAMMING IN VIVO, WHICH CAN HAVE SIGNIFICANT IMPLICATIONS FOR WOUND REPAIR, TREATMENT AND PREVENTION OF CANCER IN THE FUTURE. THE CURRENT REVIEW SUMMARIZES THE MOLECULAR EVENTS THAT ARE KNOWN TO DRIVE CELL DEDIFFERENTIATION DIRECTLY FOLLOWING TISSUE INJURY AND THE EFFECTS OF EPIGENETIC MODIFICATION ON DEDIFFERENTIATION OR REPROGRAMMING IN VIVO. IN ADDITION, THE PRESENT REVIEW EXPLORES THE INTRACELLULAR MECHANISM OF ENDOGENOUS TISSUE REPAIR AND ITS RELATIONSHIP WITH CANCER, WHICH IS ESSENTIAL FOR BALANCING THE RISK BETWEEN TISSUE REPAIR AND MALIGNANT TRANSFORMATION AFTER INJURY. 2022 12 5942 26 TARGETING OF CELLULAR REDOX METABOLISM FOR MITIGATION OF RADIATION INJURY. ACCIDENTAL EXPOSURE TO IONIZING RADIATION IS A SERIOUS CONCERN TO HUMAN LIFE. STUDIES ON THE MITIGATION OF SIDE EFFECTS FOLLOWING EXPOSURE TO ACCIDENTAL RADIATION EVENTS ARE ONGOING. RECENT STUDIES HAVE SHOWN THAT RADIATION CAN ACTIVATE SEVERAL SIGNALING PATHWAYS, LEADING TO CHANGES IN THE METABOLISM OF FREE RADICALS INCLUDING REACTIVE OXYGEN SPECIES (ROS) AND NITRIC OXIDE (NO). CELLULAR AND MOLECULAR MECHANISMS SHOW THAT RADIATION CAN CAUSE DISRUPTION OF NORMAL REDUCTION/OXIDATION (REDOX) SYSTEM. MITOCHONDRIA MALFUNCTION FOLLOWING EXPOSURE TO RADIATION AND MUTATIONS IN MITOCHONDRIA DNA (MTDNA) HAVE A KEY ROLE IN CHRONIC OXIDATIVE STRESS. FURTHERMORE, EXPOSURE TO RADIATION LEADS TO INFILTRATION OF INFLAMMATORY CELLS SUCH AS MACROPHAGES, LYMPHOCYTES AND MAST CELLS, WHICH ARE IMPORTANT SOURCES OF ROS AND NO. THESE CELLS GENERATE FREE RADICALS VIA UPREGULATION OF SOME PRO-OXIDANT ENZYMES SUCH AS NADPH OXIDASES, INDUCIBLE NITRIC OXIDE SYNTHASE (INOS) AND CYCLOOXYGENASE-2 (COX-2). EPIGENETIC CHANGES ALSO HAVE A KEY ROLE IN A SIMILAR WAY. OTHER MEDIATORS SUCH AS MAMMALIAN TARGET OF RAPAMYCIN (MTOR) AND PEROXISOME PROLIFERATOR-ACTIVATED RECEPTOR (PPAR), WHICH ARE INVOLVED IN THE NORMAL METABOLISM OF CELLS HAVE ALSO BEEN SHOWN TO REGULATE CELL DEATH FOLLOWING EXPOSURE TO RADIATION. THESE MECHANISMS ARE TISSUE SPECIFIC. INHIBITION OR ACTIVATION OF EACH OF THESE TARGETS CAN BE SUGGESTED FOR MITIGATION OF RADIATION INJURY IN A SPECIFIC TISSUE. IN THE CURRENT PAPER, WE REVIEW THE CELLULAR AND MOLECULAR CHANGES IN THE METABOLISM OF CELLS AND ROS/NO FOLLOWING EXPOSURE TO RADIATION. FURTHERMORE, THE POSSIBLE STRATEGIES FOR MITIGATION OF RADIATION INJURY THROUGH MODULATION OF CELLULAR METABOLISM IN IRRADIATED ORGANS WILL BE DISCUSSED. 2020 13 3207 26 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 14 2950 19 GENETIC AND EPIGENETIC DAMAGE INDUCED BY REACTIVE NITROGEN SPECIES: IMPLICATIONS IN CARCINOGENESIS. CHRONIC INFECTION AND INFLAMMATION ARE RECOGNIZED RISK FACTORS FOR HUMAN CANCER AT VARIOUS SITES. INFECTION AND INFLAMMATION CAN ACTIVATE AND INDUCE A VARIETY OF OXIDANT-GENERATING ENZYMES, INCLUDING NADPH OXIDASE AND INDUCIBLE NITRIC OXIDE SYNTHASE. REACTIVE OXYGEN AND NITROGEN SPECIES PRODUCED BY SUCH ENZYMES REACT WITH EACH OTHER TO GENERATE NEW AND MORE POTENT REACTIVE SPECIES. THESE OXIDANTS NOT ONLY CAN DAMAGE DNA AND INDUCE MUTATIONS, BUT ALSO CAN ACTIVATE ONCOGENE PRODUCTS AND/OR INACTIVATE TUMOR-SUPPRESSOR PROTEINS, THUS CONTRIBUTING TO MOST PROCESSES OF CARCINOGENESIS. APPROPRIATE TREATMENT OF INFLAMMATION SHOULD BE FURTHER EXPLORED FOR CHEMOPREVENTION OF HUMAN CANCERS, ESPECIALLY THOSE ASSOCIATED WITH CHRONIC INFLAMMATION. 2003 15 6543 21 TRANSCRIPTOME REMODELING IN HYPOXIC INFLAMMATION. HYPOXIA IS AN INTEGRAL COMPONENT OF THE INFLAMED TISSUE MICROENVIRONMENT. TODAY, THE INFLUENCE OF HYPOXIA ON THE NATURAL EVOLUTION OF INFLAMMATORY RESPONSES IS WIDELY ACCEPTED; HOWEVER, MANY MOLECULAR AND CELLULAR MECHANISMS MEDIATING THIS RELATIONSHIP REMAIN TO BE CLARIFIED. HYPOXIC STRESS AFFECTS SEVERAL INDEPENDENT TRANSCRIPTIONAL REGULATORS RELATED TO INFLAMMATION IN WHICH HIF-1 AND NF-KAPPAB PLAY CENTRAL ROLES. TRANSCRIPTION FACTORS INTERACT WITH BOTH HATS AND HDACS, WHICH ARE COMPONENTS OF LARGE MULTIPROTEIN CO-REGULATORY COMPLEXES. THIS REVIEW SUMMARIZES THE CURRENT KNOWLEDGE ON HYPOXIA-RESPONSIVE TRANSCRIPTIONAL PATHWAYS IN INFLAMMATION AND THEIR IMPORTANCE IN THE ETIOLOGY OF CHRONIC INFLAMMATORY DISEASES, WITH THE PRIMARY FOCUS ON TRANSCRIPTIONAL CO-REGULATORS AND HISTONE MODIFICATIONS IN DEFINING GENE-SPECIFIC TRANSCRIPTIONAL RESPONSES IN HYPOXIA, AND ON THE RECENT PROGRESS IN THE UNDERSTANDING OF HYPOXIA-MEDIATED EPIGENETIC REPROGRAMMING. FURTHERMORE, THIS REVIEW DISCUSSES THE MOLECULAR CROSS-TALK BETWEEN GLUCOCORTICOID ANTI-INFLAMMATORY PATHWAYS AND HYPOXIA. 2010 16 5937 30 TARGETING HISTONE DEACETYLASE ACTIVITY IN RHEUMATOID ARTHRITIS AND ASTHMA AS PROTOTYPES OF INFLAMMATORY DISEASE: SHOULD WE KEEP OUR HATS ON? CELLULAR ACTIVATION, PROLIFERATION AND SURVIVAL IN CHRONIC INFLAMMATORY DISEASES IS REGULATED NOT ONLY BY ENGAGEMENT OF SIGNAL TRANS-DUCTION PATHWAYS THAT MODULATE TRANSCRIPTION FACTORS REQUIRED FOR THESE PROCESSES, BUT ALSO BY EPIGENETIC REGULATION OF TRANSCRIPTION FACTOR ACCESS TO GENE PROMOTER REGIONS. HISTONE ACETYL TRANSFERASES COORDINATE THE RECRUITMENT AND ACTIVATION OF TRANSCRIPTION FACTORS WITH CONFORMATIONAL CHANGES IN HISTONES THAT ALLOW GENE PROMOTER EXPOSURE. HISTONE DEACETYLASES (HDACS) COUNTERACT HISTONE ACETYL TRANSFERASE ACTIVITY THROUGH THE TARGETING OF BOTH HISTONES AS WELL AS NONHISTONE SIGNAL TRANSDUCTION PROTEINS IMPORTANT IN INFLAMMATION. NUMEROUS STUDIES HAVE INDICATED THAT DEPRESSED HDAC ACTIVITY IN PATIENTS WITH INFLAMMATORY AIRWAY DISEASES MAY CONTRIBUTE TO LOCAL PROINFLAMMATORY CYTOKINE PRODUCTION AND DIMINISH PATIENT RESPONSES TO CORTICOSTEROID TREATMENT. RECENT OBSERVATIONS THAT HDAC ACTIVITY IS DEPRESSED IN RHEUMATOID ARTHRITIS PATIENT SYNOVIAL TISSUE HAVE PREDICTED THAT STRATEGIES RESTORING HDAC FUNCTION MAY BE THERAPEUTIC IN THIS DISEASE AS WELL. PHARMACOLOGICAL INHIBITORS OF HDAC ACTIVITY, HOWEVER, HAVE DEMONSTRATED POTENT THERAPEUTIC EFFECTS IN ANIMAL MODELS OF ARTHRITIS AND OTHER CHRONIC INFLAMMATORY DISEASES. IN THE PRESENT REVIEW WE ASSESS AND RECONCILE THESE OUTWARDLY PARADOXICAL STUDY RESULTS TO PROVIDE A WORKING MODEL FOR HOW ALTERATIONS IN HDAC ACTIVITY MAY CONTRIBUTE TO PATHOLOGY IN RHEUMATOID ARTHRITIS, AND HIGHLIGHT KEY QUESTIONS TO BE ANSWERED IN THE PRECLINICAL EVALUATION OF COMPOUNDS MODULATING THESE ENZYMES. 2008 17 4897 31 OXIDATIVE STRESS IN ALCOHOL-RELATED LIVER DISEASE. ALCOHOL CONSUMPTION IS ONE OF THE LEADING CAUSES OF THE GLOBAL BURDEN OF DISEASE AND RESULTS IN HIGH HEALTHCARE AND ECONOMIC COSTS. HEAVY ALCOHOL MISUSE LEADS TO ALCOHOL-RELATED LIVER DISEASE, WHICH IS RESPONSIBLE FOR A SIGNIFICANT PROPORTION OF ALCOHOL-ATTRIBUTABLE DEATHS GLOBALLY. OTHER THAN REDUCING ALCOHOL CONSUMPTION, THERE ARE CURRENTLY NO EFFECTIVE TREATMENTS FOR ALCOHOL-RELATED LIVER DISEASE. OXIDATIVE STRESS REFERS TO AN IMBALANCE IN THE PRODUCTION AND ELIMINATION OF REACTIVE OXYGEN SPECIES AND ANTIOXIDANTS. IT PLAYS IMPORTANT ROLES IN SEVERAL ASPECTS OF ALCOHOL-RELATED LIVER DISEASE PATHOGENESIS. HERE, WE REVIEW HOW CHRONIC ALCOHOL USE RESULTS IN OXIDATIVE STRESS THROUGH INCREASED METABOLISM VIA THE CYTOCHROME P450 2E1 SYSTEM PRODUCING REACTIVE OXYGEN SPECIES, ACETALDEHYDE AND PROTEIN AND DNA ADDUCTS. THESE TRIGGER INFLAMMATORY SIGNALING PATHWAYS WITHIN THE LIVER LEADING TO EXPRESSION OF PRO-INFLAMMATORY MEDIATORS CAUSING HEPATOCYTE APOPTOSIS AND NECROSIS. REACTIVE OXYGEN SPECIES EXPOSURE ALSO RESULTS IN MITOCHONDRIAL STRESS WITHIN HEPATOCYTES CAUSING STRUCTURAL AND FUNCTIONAL DYSREGULATION OF MITOCHONDRIA AND UPREGULATING APOPTOTIC SIGNALING. THERE IS ALSO EVIDENCE THAT OXIDATIVE STRESS AS WELL AS THE DIRECT EFFECT OF ALCOHOL INFLUENCES EPIGENETIC REGULATION. INCREASED GLOBAL HISTONE METHYLATION AND ACETYLATION AND SPECIFIC HISTONE ACETYLATION INHIBITS ANTIOXIDANT RESPONSES AND PROMOTES EXPRESSION OF KEY PRO-INFLAMMATORY GENES. THIS REVIEW HIGHLIGHTS ASPECTS OF THE ROLE OF OXIDATIVE STRESS IN DISEASE PATHOGENESIS THAT WARRANT FURTHER STUDY INCLUDING MITOCHONDRIAL STRESS AND EPIGENETIC REGULATION. IMPROVED UNDERSTANDING OF THESE PROCESSES MAY IDENTIFY NOVEL TARGETS FOR THERAPY. 2020 18 1383 29 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 19 4705 24 NLRP3: A NEW THERAPEUTIC TARGET IN ALCOHOLIC LIVER DISEASE. THE LIVER IS IN CHARGE OF A WIDE RANGE OF CRITICAL PHYSIOLOGICAL PROCESSES AND IT PLAYS AN IMPORTANT ROLE IN ACTIVATING THE INNATE IMMUNE SYSTEM WHICH ELICITS THE INFLAMMATORY EVENTS. CHRONIC ETHANOL EXPOSURE DISRUPTS HEPATIC INFLAMMATORY MECHANISM AND LEADS TO THE RELEASE OF PROINFLAMMATORY MEDIATORS SUCH AS CHEMOKINES, CYTOKINES AND ACTIVATION OF INFLAMMASOMES. THE MECHANISM OF LIVER FIBROSIS/CIRRHOSIS INVOLVE ACTIVATION OF NLRP3 INFLAMMASOME, LEADING TO THE DESTRUCTION OF HEPATOCYTES AND SUBSEQUENT METABOLIC DYSREGULATION IN HUMANS. IN ADDITION, INCREASING EVIDENCE SUGGESTS THAT ALCOHOL INTAKE SIGNIFICANTLY MODIFIES LIVER EPIGENETICS, PROMOTING THE DEVELOPMENT OF ALCOHOLIC LIVER DISEASE (ALD). EPIGENETIC CHANGES INCLUDING HISTONE MODIFICATION, MICRORNA-INDUCED GENETIC MODULATION, AND DNA METHYLATION ARE CRUCIAL IN ALCOHOL-EVOKED CELL SIGNALING THAT AFFECTS GENE EXPRESSION IN THE HEPATIC SYSTEM. THOUGH WE ARE AT THE BEGINNING STAGE WITHOUT HAVING THE ENTIRE PRINT OF EPIGENETIC SIGNATURE, IT IS TIME TO FOCUS MORE ON NLRP3 INFLAMMASOME AND EPIGENETIC MODIFICATIONS. HERE WE REVIEW THE NOVEL ASPECT OF ALD PATHOLOGY LINKING TO INFLAMMATION AND HIGHLIGHTING THE ROLE OF EPIGENETIC MODIFICATION ASSOCIATED WITH NLRP3 INFLAMMASOME AND HOW IT COULD BE A THERAPEUTIC TARGET IN ALD. 2023 20 450 24 APOPTOSIS AND AGING: INCREASED RESISTANCE TO APOPTOSIS ENHANCES THE AGING PROCESS. APOPTOSIS IS A VITAL COMPONENT IN THE EVOLUTIONARILY CONSERVED HOST DEFENSE SYSTEM. APOPTOSIS IS THE GUARDIAN OF TISSUE INTEGRITY BY REMOVING UNFIT AND INJURED CELLS WITHOUT EVOKING INFLAMMATION. HOWEVER, APOPTOSIS SEEMS TO BE A DOUBLE-EDGED SWORD SINCE DURING LOW-LEVEL CHRONIC STRESS, SUCH AS IN AGING, INCREASED RESISTANCE TO APOPTOSIS CAN LEAD TO THE SURVIVAL OF FUNCTIONALLY DEFICIENT, POST-MITOTIC CELLS WITH DAMAGED HOUSEKEEPING FUNCTIONS. SENESCENT CELLS ARE REMARKABLY RESISTANT TO APOPTOSIS, AND SEVERAL STUDIES INDICATE THAT HOST DEFENSE MECHANISMS CAN ENHANCE ANTI-APOPTOTIC SIGNALING, WHICH SUBSEQUENTLY INDUCES A SENESCENT, PRO-INFLAMMATORY PHENOTYPE DURING THE AGING PROCESS. AT THE MOLECULAR LEVEL, AGE-RELATED RESISTANCE TO APOPTOSIS INVOLVES (1) FUNCTIONAL DEFICIENCY IN P53 NETWORK, (2) INCREASED ACTIVITY IN THE NF-KAPPAB-IAP/JNK AXIS, AND (3) CHANGES IN MOLECULAR CHAPERONES, MICRORNAS, AND EPIGENETIC REGULATION. WE WILL DISCUSS THE MOLECULAR BASIS OF AGE-RELATED RESISTANCE TO APOPTOSIS AND EMPHASIZE THAT INCREASED RESISTANCE COULD ENHANCE THE AGING PROCESS. 2011