1 6621 138 UNDERSTANDING FIBROSIS IN SYSTEMIC SCLEROSIS: SHIFTING PARADIGMS, EMERGING OPPORTUNITIES. FIBROSIS IN MULTIPLE ORGANS IS A PROMINENT PATHOLOGICAL FINDING AND DISTINGUISHING HALLMARK OF SYSTEMIC SCLEROSIS (SSC). FINDINGS DURING THE PAST 5 YEARS HAVE CONTRIBUTED TO A MORE COMPLETE UNDERSTANDING OF THE COMPLEX CELLULAR AND MOLECULAR UNDERPINNING OF FIBROSIS IN SSC. FIBROBLASTS, THE PRINCIPAL EFFECTOR CELLS, ARE ACTIVATED IN THE PROFIBROTIC CELLULAR MILIEU BY CYTOKINES AND GROWTH FACTORS, DEVELOPMENTAL PATHWAYS, ENDOTHELIN 1 AND THROMBIN. INNATE IMMUNE SIGNALING VIA TOLL-LIKE RECEPTORS, MATRIX-GENERATED BIOMECHANICAL STRESS SIGNALING VIA INTEGRINS, HYPOXIA AND OXIDATIVE STRESS SEEM TO BE IMPLICATED IN PERPETUATING THE PROCESS. BEYOND CHRONIC FIBROBLAST ACTIVATION, FIBROSIS REPRESENTS A FAILURE TO TERMINATE TISSUE REPAIR, COUPLED WITH AN EXPANDED POPULATION OF MESENCHYMAL CELLS ORIGINATING FROM BONE MARROW AND TRANSDIFFERENTIATION OF EPITHELIAL CELLS, ENDOTHELIAL CELLS AND PERICYTES. IN ADDITION, STUDIES HAVE IDENTIFIED INTRINSIC ALTERATIONS IN SSC FIBROBLASTS RESULTING FROM EPIGENETIC CHANGES, AS WELL AS ALTERED MICRORNA EXPRESSION THAT MIGHT UNDERLIE THE CELL-AUTONOMOUS, PERSISTENT ACTIVATION PHENOTYPE OF THESE CELLS. PRECISE CHARACTERIZATION OF THE DEREGULATED EXTRACELLULAR AND INTRACELLULAR SIGNALING PATHWAYS, MEDIATORS AND CELLULAR DIFFERENTIATION PROGRAMS THAT CONTRIBUTE TO FIBROSIS IN SSC WILL FACILITATE THE DEVELOPMENT OF SELECTIVE, TARGETED THERAPEUTIC STRATEGIES. EFFECTIVE ANTIFIBROTIC THERAPY WILL ULTIMATELY INVOLVE NOVEL COMPOUNDS AND REPURPOSING OF DRUGS THAT ARE ALREADY APPROVED FOR OTHER INDICATIONS. 2011 2 4453 29 MOLECULAR MECHANISMS AND PATHWAYS AS TARGETS FOR CANCER PREVENTION AND PROGRESSION WITH DIETARY COMPOUNDS. A UNIQUE FEATURE OF BIOACTIVE FOOD INGREDIENTS IS THEIR BROAD ANTIOXIDANT FUNCTION. ANTIOXIDANTS HAVING A WIDE SPECTRUM OF CHEMICAL STRUCTURE AND ACTIVITY BEYOND BASIC NUTRITION; DISPLAY DIFFERENT HEALTH BENEFITS BY THE PREVENTION AND PROGRESSION OF CHRONIC DISEASES. FUNCTIONAL FOOD COMPONENTS ARE CAPABLE OF ENHANCING THE NATURAL ANTIOXIDANT DEFENSE SYSTEM BY SCAVENGING REACTIVE OXYGEN AND NITROGEN SPECIES, PROTECTING AND REPAIRING DNA DAMAGE, AS WELL AS MODULATING THE SIGNAL TRANSDUCTION PATHWAYS AND GENE EXPRESSION. MAJOR PATHWAYS AFFECTED BY BIOACTIVE FOOD INGREDIENTS INCLUDE THE PRO-INFLAMMATORY PATHWAYS REGULATED BY NUCLEAR FACTOR KAPPA B (NF-KAPPAB), AS WELL AS THOSE ASSOCIATED WITH CYTOKINES AND CHEMOKINES. THE PRESENT REVIEW SUMMARIZES THE IMPORTANCE OF PLANT BIOACTIVES AND THEIR ROLES IN THE REGULATION OF INFLAMMATORY PATHWAYS. BIOACTIVES INFLUENCE SEVERAL PHYSIOLOGICAL PROCESSES SUCH AS GENE EXPRESSION, CELL CYCLE REGULATION, CELL PROLIFERATION, CELL MIGRATION, ETC., RESULTING IN CANCER PREVENTION. CANCER INITIATION IS ASSOCIATED WITH CHANGES IN METABOLIC PATHWAYS SUCH AS GLUCOSE METABOLISM, AND THE EFFECT OF BIOACTIVES IN NORMALIZING THIS PROCESS HAS BEEN PROVIDED. INITIATION AND PROGRESSION OF INFLAMMATORY BOWEL DISEASES (IBD) WHICH INCREASE THE CHANCES OF DEVELOPING OF COLORECTAL CANCERS CAN BE DOWNREGULATED BY PLANT BIOACTIVES. SEVERAL ASPECTS OF THE POTENTIAL ROLES OF MICRORNAS AND EPIGENETIC MODIFICATIONS IN THE DEVELOPMENT OF CANCERS HAVE ALSO BEEN PRESENTED. 2017 3 5469 36 RESOLUTION OF INFLAMMATION AS A NOVEL CHEMOPREVENTIVE STRATEGY. ACUTE INFLAMMATION, A PHYSIOLOGIC RESPONSE TO PROTECT CELLS FROM MICROBIAL INFECTION AND OTHER NOXIOUS STIMULI, IS AUTOMATICALLY TERMINATED BY ENDOGENOUS ANTI-INFLAMMATORY AND PRO-RESOLVING MEDIATORS TO RESTORE HOMEOSTATIC CONDITIONS. HOWEVER, IF TIMELY RESOLUTION OF INFLAMMATION IS FAILED, INFLAMMATION PERSISTS AND CAN PROGRESS TO A CHRONIC INFLAMMATION WHICH HAS LONG BEEN THOUGHT AS A PREDISPOSING FACTOR TO CARCINOGENESIS. EXCESSIVE AND PATHOLOGIC INFLAMMATION CAUSES DNA DAMAGE, GENOMIC INSTABILITY, EPIGENETIC DYSREGULATION, AND ALTERATION OF INTRACELLULAR SIGNALING, ALL OF WHICH ARE INVOLVED IN NEOPLASTIC TRANSFORMATION. TO PREVENT CHRONIC INFLAMMATION AND RESULTING INFLAMMATION-PROMOTED CANCER DEVELOPMENT, UNDERSTANDING THE PROCESS THAT RESOLVES INFLAMMATION IS ESSENTIAL. RESOLUTION OF INFLAMMATION IS AN ACTIVE COORDINATED PROCESS REGULATED BY DISTINCT ANTI-INFLAMMATORY AND PRO-RESOLVING ENDOGENOUS LIPID MEDIATORS, SUCH AS RESOLVINS AND LIPOXINS. THE ROLE OF PRO-INFLAMMATORY SIGNALING IN CARCINOGENESIS HAS BECOME MORE AND MORE EVIDENT AND WELL CHARACTERIZED, BUT THE POTENTIAL ROLE OF PRO-RESOLVING MEDIATORS IN CANCER PREVENTION REMAINS STILL ELUSIVE. IN SEARCHING FOR AN EFFICACIOUS WAY TO PREVENT CHRONIC INFLAMMATION-ASSOCIATED CANCER, THE PRO-RESOLVING SIGNAL TRANSDUCTION PATHWAYS AND THEIR REGULATORS SHOULD BE UNRAVELED. 2013 4 4380 33 MITOCHONDRIAL DYSFUNCTION AND OXIDATIVE STRESS IN RHEUMATOID ARTHRITIS. CONTROL OF EXCESSIVE MITOCHONDRIAL OXIDATIVE STRESS COULD PROVIDE NEW TARGETS FOR BOTH PREVENTIVE AND THERAPEUTIC INTERVENTIONS IN THE TREATMENT OF CHRONIC INFLAMMATION OR ANY PATHOLOGY THAT DEVELOPS UNDER AN INFLAMMATORY SCENARIO, SUCH AS RHEUMATOID ARTHRITIS (RA). INCREASING EVIDENCE HAS DEMONSTRATED THE ROLE OF MITOCHONDRIAL ALTERATIONS IN AUTOIMMUNE DISEASES MAINLY DUE TO THE INTERPLAY BETWEEN METABOLISM AND INNATE IMMUNITY, BUT ALSO IN THE MODULATION OF INFLAMMATORY RESPONSE OF RESIDENT CELLS, SUCH AS SYNOVIOCYTES. THUS, MITOCHONDRIAL DYSFUNCTION DERIVED FROM SEVERAL DANGER SIGNALS COULD ACTIVATE TRICARBOXYLIC ACID (TCA) DISRUPTION, THEREBY FAVORING A VICIOUS CYCLE OF OXIDATIVE/MITOCHONDRIAL STRESS. MITOCHONDRIAL DYSFUNCTION CAN ACT THROUGH MODULATING INNATE IMMUNITY VIA REDOX-SENSITIVE INFLAMMATORY PATHWAYS OR DIRECT ACTIVATION OF THE INFLAMMASOME. BESIDES, MITOCHONDRIA ALSO HAVE A CENTRAL ROLE IN REGULATING CELL DEATH, WHICH IS DEEPLY ALTERED IN RA. ADDITIONALLY, MULTIPLE EVIDENCE SUGGESTS THAT PATHOLOGICAL PROCESSES IN RA CAN BE SHAPED BY EPIGENETIC MECHANISMS AND THAT IN TURN, MITOCHONDRIA ARE INVOLVED IN EPIGENETIC REGULATION. FINALLY, WE WILL DISCUSS ABOUT THE INVOLVEMENT OF SOME DIETARY COMPONENTS IN THE ONSET AND PROGRESSION OF RA. 2022 5 6205 28 THE INFLUENCE OF PLANT EXTRACTS AND PHYTOCONSTITUENTS ON ANTIOXIDANT ENZYMES ACTIVITY AND GENE EXPRESSION IN THE PREVENTION AND TREATMENT OF IMPAIRED GLUCOSE HOMEOSTASIS AND DIABETES COMPLICATIONS. DIABETES IS A COMPLEX METABOLIC DISORDER RESULTING EITHER FROM INSULIN RESISTANCE OR AN IMPAIRED INSULIN SECRETION. PROLONGED ELEVATED BLOOD GLUCOSE CONCENTRATION, THE KEY CLINICAL SIGN OF DIABETES, INITIATES AN ENHANCEMENT OF REACTIVE OXYGEN SPECIES DERIVED FROM GLUCOSE AUTOXIDATION AND GLYCOSYLATION OF PROTEINS. CONSEQUENTLY, CHRONIC OXIDATIVE STRESS OVERWHELMS CELLULAR ENDOGENOUS ANTIOXIDANT DEFENSES AND LEADS TO THE ACUTE AND LONG-STANDING STRUCTURAL AND FUNCTIONAL CHANGES OF MACROMOLECULES RESULTING IN IMPAIRED CELLULAR FUNCTIONING, CELL DEATH AND ORGAN DYSFUNCTION. THE OXIDATIVE STRESS PROVOKED CHAIN OF PATHOLOGICAL EVENTS OVER TIME CAUSE DIABETIC COMPLICATIONS SUCH AS NEPHROPATHY, PERIPHERAL NEUROPATHY, CARDIOMYOPATHY, RETINOPATHY, HYPERTENSION, AND LIVER DISEASE. UNDER DIABETIC CONDITIONS, ACCOMPANYING GENOME/EPIGENOME AND METABOLITE MARKERS ALTERATIONS MAY ALSO AFFECT GLUCOSE HOMEOSTASIS, PANCREATIC BETA-CELLS, MUSCLE, LIVER, AND ADIPOSE TISSUE. BY PROVIDING DEEPER GENETIC/EPIGENETIC INSIGHT OF DIRECT OR INDIRECT DIETARY EFFECTS, NUTRIGENOMICS OFFERS A PROMISING OPPORTUNITY TO IMPROVE THE QUALITY OF LIFE OF DIABETIC PATIENTS. NATURAL PLANT EXTRACTS, OR THEIR NATURALLY OCCURRING COMPOUNDS, WERE SHOWN TO BE VERY PROFICIENT IN THE PREVENTION AND TREATMENT OF DIFFERENT PATHOLOGIES ASSOCIATED WITH OXIDATIVE STRESS INCLUDING DIABETES AND ITS COMPLICATIONS. CONSIDERING THAT FOOD INTAKE IS ONE OF THE CRUCIAL COMPONENTS IN DIABETES' PREVALENCE, PROGRESSION AND COMPLICATIONS, THIS REVIEW SUMMARIZES THE EFFECT OF THE MAJOR PLANT SECONDARY METABOLITE AND PHYTOCONSTITUENTS ON THE ANTIOXIDANT ENZYMES ACTIVITY AND GENE EXPRESSION UNDER DIABETIC CONDITIONS. 2021 6 6374 34 THE ROLE OF MITOCHONDRIA IN MYOCARDIAL DAMAGE CAUSED BY ENERGY METABOLISM DISORDERS: FROM MECHANISMS TO THERAPEUTICS. MYOCARDIAL DAMAGE IS THE MOST SERIOUS PATHOLOGICAL CONSEQUENCE OF CARDIOVASCULAR DISEASES AND AN IMPORTANT REASON FOR THEIR HIGH MORTALITY. IN RECENT YEARS, BECAUSE OF THE HIGH PREVALENCE OF SYSTEMIC ENERGY METABOLISM DISORDERS (E.G., OBESITY, DIABETES MELLITUS, AND METABOLIC SYNDROME), COMPLICATIONS OF MYOCARDIAL DAMAGE CAUSED BY THESE DISORDERS HAVE ATTRACTED WIDESPREAD ATTENTION. ENERGY METABOLISM DISORDERS ARE INDEPENDENT OF TRADITIONAL INJURY-RELATED RISK FACTORS, SUCH AS ISCHEMIA, HYPOXIA, TRAUMA, AND INFECTION. AN IMBALANCE OF MYOCARDIAL METABOLIC FLEXIBILITY AND MYOCARDIAL ENERGY DEPLETION ARE USUALLY THE INITIAL CHANGES OF MYOCARDIAL INJURY CAUSED BY ENERGY METABOLISM DISORDERS, AND ABNORMAL MORPHOLOGY AND FUNCTIONAL DESTRUCTION OF THE MITOCHONDRIA ARE THEIR IMPORTANT FEATURES. SPECIFICALLY, MITOCHONDRIA ARE THE CENTERS OF ENERGY METABOLISM, AND RECENT EVIDENCE HAS SHOWN THAT DECREASED MITOCHONDRIAL FUNCTION, CAUSED BY AN IMBALANCE IN MITOCHONDRIAL QUALITY CONTROL, MAY PLAY A KEY ROLE IN MYOCARDIAL INJURY CAUSED BY ENERGY METABOLISM DISORDERS. UNDER CHRONIC ENERGY STRESS, MITOCHONDRIA UNDERGO PATHOLOGICAL FISSION, WHILE MITOPHAGY, MITOCHONDRIAL FUSION, AND BIOGENESIS ARE INHIBITED, AND MITOCHONDRIAL PROTEIN BALANCE AND TRANSFER ARE DISTURBED, RESULTING IN THE ACCUMULATION OF NONFUNCTIONAL AND DAMAGED MITOCHONDRIA. CONSEQUENTLY, DAMAGED MITOCHONDRIA LEAD TO MYOCARDIAL ENERGY DEPLETION AND THE ACCUMULATION OF LARGE AMOUNTS OF REACTIVE OXYGEN SPECIES, FURTHER AGGRAVATING THE IMBALANCE IN MITOCHONDRIAL QUALITY CONTROL AND FORMING A VICIOUS CYCLE. IN ADDITION, IMPAIRED MITOCHONDRIA COORDINATE CALCIUM HOMEOSTASIS IMBALANCE, AND EPIGENETIC ALTERATIONS PARTICIPATE IN THE PATHOGENESIS OF MYOCARDIAL DAMAGE. THESE PATHOLOGICAL CHANGES INDUCE RAPID PROGRESSION OF MYOCARDIAL DAMAGE, EVENTUALLY LEADING TO HEART FAILURE OR SUDDEN CARDIAC DEATH. TO INTERVENE MORE SPECIFICALLY IN THE MYOCARDIAL DAMAGE CAUSED BY METABOLIC DISORDERS, WE NEED TO UNDERSTAND THE SPECIFIC ROLE OF MITOCHONDRIA IN THIS CONTEXT IN DETAIL. ACCORDINGLY, PROMISING THERAPEUTIC STRATEGIES HAVE BEEN PROPOSED. WE ALSO SUMMARIZE THE EXISTING THERAPEUTIC STRATEGIES TO PROVIDE A REFERENCE FOR CLINICAL TREATMENT AND DEVELOPING NEW THERAPIES. 2023 7 601 27 BETA-GLUCAN "TRAINED IMMUNITY" IMMUNOMODULATORY PROPERTIES POTENTIATE TISSUE WOUND MANAGEMENT AND ACCELERATE FITNESS RECOVER. INTRODUCTION: IT IS WELL ESTABLISHED THAT MODERATE PHYSICAL ACTIVITY CAN IMPROVE THE IMMUNE STATUS, RATHER EXCESS OR HIGH-INTENSITY PHYSICAL EXERCISE CAN CAUSE DAMAGE TO THE IMMUNE SYSTEM. IN ADDITION, MUSCLE INJURIES RESULTING FROM INCREASED FREQUENCY AND INTENSITY OF EXERCISES COMPROMISE INNATE IMMUNE ACTIVITY AND MAY DECREASE TISSUE REGENERATION. THUS, BETA-GLUCANS, A NATURAL COMPOUND, MAY REPRESENT AN IMPORTANT SUBSTANCE WITH STRONG IMMUNOMODULATORY PROPERTIES ACTING AS AN IMMUNOSTIMULANT THERAPY KNOWN AS "TRAINED IMMUNITY". THIS IMMUNE STIMULATING THERAPEUTIC IS AN IMMUNOLOGICAL MEMORY PHENOMENON LINKED TO THE INNATE IMMUNE SYSTEM, TRIGGERING CELLULAR CHANGES AT EPIGENETIC, TRANSCRIPTIONAL, AND FUNCTIONAL LEVELS, TO REGULATE THE IMMUNE SYSTEM AND RECOVER ITS HOMEOSTASIS WITH CLINICAL BENEFITS. CONCLUSION: THIS NARRATIVE REVIEW WORKS WITH THE CURRENT EVIDENCE REGARDING BETA-GLUCANS AS A POSSIBLE ALTERNATIVE THERAPY FOR WOUND HEALING AND ITS SAFETY AND EFFICACY IN THE TREATMENT OF MUSCLE INJURIES AND PHYSICAL RECOVERY INCLUDING OTHER CHRONIC CONDITIONS AND DISEASES. 2022 8 4981 42 PATHOPHYSIOLOGY OF SYSTEMIC SCLEROSIS: CURRENT UNDERSTANDING AND NEW INSIGHTS. INTRODUCTION: SYSTEMIC SCLEROSIS (SSC) IS A COMPLEX AUTOIMMUNE CONNECTIVE TISSUE DISEASE CHARACTERIZED BY CHRONIC AND PROGRESSIVE TISSUE AND ORGAN FIBROSIS WITH BROAD PATIENT-TO-PATIENT VARIABILITY. SOME RISK FACTORS ARE KNOWN AND INCLUDE COMBINATION OF PERSISTENT RAYNAUD'S PHENOMENON, STEROID HORMONE IMBALANCE, SELECTED CHEMICALS, THERMAL, OR OTHER INJURIES. ENDOGENOUS AND/OR EXOGENOUS ENVIRONMENTAL TRIGGER/RISK FACTORS PROMOTE EPIGENETIC MECHANISMS IN GENETICALLY PRIMED SUBJECTS. DISEASE PATHOGENESIS PRESENTS EARLY MICROVASCULAR CHANGES WITH ENDOTHELIAL CELL DYSFUNCTION, FOLLOWED BY THE ACTIVATION OF MECHANISMS PROMOTING THEIR TRANSITION INTO MYOFIBROBLASTS. A COMPLEX AUTOIMMUNE RESPONSE, INVOLVING INNATE AND ADAPTIVE IMMUNITY WITH SPECIFIC/FUNCTIONAL AUTOANTIBODY PRODUCTION, CHARACTERIZES THE DISEASE. PROGRESSIVE FIBROSIS AND ISCHEMIA INVOLVE SKIN AND VISCERAL ORGANS RESULTING IN THEIR IRREVERSIBLE DAMAGE/FAILURE. PROGENITOR CIRCULATING CELLS (MONOCYTES, FIBROCYTES), TOGETHER WITH GROWTH FACTORS AND CYTOKINES PARTICIPATE IN DISEASE DIFFUSION AND EVOLUTION. EPIGENETIC, VASCULAR AND IMMUNOLOGIC MECHANISMS IMPLICATED IN SYSTEMIC FIBROSIS, REPRESENT MAJOR TARGETS FOR INCOMING DISEASE MODIFYING THERAPEUTIC APPROACHES. AREAS COVERED: THIS REVIEW DISCUSSES CURRENT UNDERSTANDING AND NEW INSIGHTS OF SSC PATHOGENESIS, THROUGH AN OVERVIEW OF THE MOST RELEVANT ADVANCEMENTS TO PRESENT ASPECTS AND MECHANISMS INVOLVED IN DISEASE PATHOGENESIS. EXPERT OPINION: CONSIDERING SSC INTRICACY/HETEROGENEITY, EARLY COMBINATION THERAPY WITH VASODILATORS, IMMUNOSUPPRESSIVE AND ANTIFIBROTIC DRUGS SHOULD SUCCESSFULLY DOWNREGULATE THE DISEASE PROGRESSION, ESPECIALLY IF STARTED FROM THE BEGINNING. 2019 9 4974 34 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 10 2342 31 EPIGENETIC REGULATION OF MACROPHAGE POLARIZATION AND FUNCTION. MACROPHAGE POLARIZATION REFERS TO DEVELOPMENT OF A SPECIFIC PHENOTYPE IMPORTANT FOR TISSUE HOMEOSTASIS OR HOST DEFENSE IN RESPONSE TO ENVIRONMENTAL CUES. ENVIRONMENTAL FACTORS THAT INDUCE MACROPHAGE POLARIZATION INCLUDE CYTOKINES AND MICROBIAL FACTORS PRODUCED BY PATHOGENS OR COMMENSAL MICROBIOTA. SIGNALING PATHWAYS UTILIZED BY THESE POLARIZING FACTORS HAVE BEEN WELL CHARACTERIZED, BUT IT IS LESS CLEAR HOW SIGNALS ARE CONVERTED INTO COMPLEX AND SUSTAINED PATTERNS OF GENE EXPRESSION, AND HOW MACROPHAGES ARE REPROGRAMMED DURING POLARIZATION TO ALTER THEIR RESPONSES TO SUBSEQUENT ENVIRONMENTAL CHALLENGES. EMERGING EVIDENCE, REVIEWED HERE, SUGGESTS AN IMPORTANT ROLE FOR EPIGENETIC MECHANISMS IN MODULATING AND TRANSMITTING SIGNALS DURING MACROPHAGE POLARIZATION AND REPROGRAMMING. DEEPER UNDERSTANDING OF EPIGENETIC REGULATION OF MACROPHAGE PHENOTYPE WILL ENABLE DEVELOPMENT OF GENE-SPECIFIC THERAPEUTIC APPROACHES TO ENHANCE HOST DEFENSE WHILE PRESERVING TISSUE INTEGRITY AND PREVENTING CHRONIC INFLAMMATORY DISEASES. 2013 11 2812 30 FIBROBLAST MEMORY IN DEVELOPMENT, HOMEOSTASIS AND DISEASE. FIBROBLASTS ARE THE MAJOR CELL POPULATION IN THE CONNECTIVE TISSUE OF MOST ORGANS, WHERE THEY ARE ESSENTIAL FOR THEIR STRUCTURAL INTEGRITY. THEY ARE BEST KNOWN FOR THEIR ROLE IN REMODELLING THE EXTRACELLULAR MATRIX, HOWEVER MORE RECENTLY THEY HAVE BEEN RECOGNISED AS A FUNCTIONALLY HIGHLY DIVERSE CELL POPULATION THAT CONSTANTLY RESPONDS AND ADAPTS TO THEIR ENVIRONMENT. BIOLOGICAL MEMORY IS THE PROCESS OF A SUSTAINED ALTERED CELLULAR STATE AND FUNCTIONS IN RESPONSE TO A TRANSIENT OR PERSISTENT ENVIRONMENTAL STIMULUS. WHILE IT IS WELL ESTABLISHED THAT FIBROBLASTS RETAIN A MEMORY OF THEIR ANATOMICAL LOCATION, HOW OTHER ENVIRONMENTAL STIMULI INFLUENCE FIBROBLAST BEHAVIOUR AND FUNCTION IS LESS CLEAR. THE ABILITY OF FIBROBLASTS TO RESPOND AND MEMORISE DIFFERENT ENVIRONMENTAL STIMULI IS ESSENTIAL FOR TISSUE DEVELOPMENT AND HOMEOSTASIS AND MAY BECOME DYSREGULATED IN CHRONIC DISEASE CONDITIONS SUCH AS FIBROSIS AND CANCER. HERE WE SUMMARISE THE FOUR EMERGING KEY AREAS OF FIBROBLAST ADAPTATION: POSITIONAL, MECHANICAL, INFLAMMATORY, AND METABOLIC MEMORY AND HIGHLIGHT THE UNDERLYING MECHANISMS AND THEIR IMPLICATIONS IN TISSUE HOMEOSTASIS AND DISEASE. 2021 12 799 36 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 13 1383 34 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 14 5816 29 STRESS AND STEM CELLS. THE UNIQUE PROPERTIES AND FUNCTIONS OF STEM CELLS MAKE THEM PARTICULARLY SUSCEPTIBLE TO STRESSES AND ALSO LEAD TO THEIR REGULATION BY STRESS. STEM CELL DIVISION MUST RESPOND TO THE DEMAND TO REPLENISH CELLS DURING NORMAL TISSUE TURNOVER AS WELL AS IN RESPONSE TO DAMAGE. OXIDATIVE STRESS, MECHANICAL STRESS, GROWTH FACTORS, AND CYTOKINES SIGNAL STEM CELL DIVISION AND DIFFERENTIATION. MANY OF THE CONSERVED PATHWAYS REGULATING STEM CELL SELF-RENEWAL AND DIFFERENTIATION ARE ALSO STRESS-RESPONSE PATHWAYS. THE LONG LIFE SPAN AND DIVISION POTENTIAL OF STEM CELLS CREATE A PROPENSITY FOR TRANSFORMATION (CANCER) AND SPECIFIC STRESS RESPONSES SUCH AS APOPTOSIS AND SENESCENCE ACT AS ANTITUMOR MECHANISMS. QUIESCENCE REGULATED BY CDK INHIBITORS AND A HYPOXIC NICHE REGULATED BY FOXO TRANSCRIPTION FACTOR FUNCTION TO REDUCE STRESS FOR SEVERAL TYPES OF STEM CELLS TO FACILITATE LONG-TERM MAINTENANCE. AGING IS A PARTICULARLY RELEVANT STRESS FOR STEM CELLS, BECAUSE REPEATED DEMANDS ON STEM CELL FUNCTION OVER THE LIFE SPAN CAN HAVE CUMULATIVE CELL-AUTONOMOUS EFFECTS INCLUDING EPIGENETIC DYSREGULATION, MUTATIONS, AND TELOMERE EROSION. IN ADDITION, AGING OF THE ORGANISM IMPAIRS FUNCTION OF THE STEM CELL NICHE AND SYSTEMIC SIGNALS, INCLUDING CHRONIC INFLAMMATION AND OXIDATIVE STRESS. 2012 15 6532 21 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 16 1300 26 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 17 5631 31 SENESCENCE-INFLAMMATORY REGULATION OF REPARATIVE CELLULAR REPROGRAMMING IN AGING AND CANCER. THE INABILITY OF ADULT TISSUES TO TRANSITORILY GENERATE CELLS WITH FUNCTIONAL STEM CELL-LIKE PROPERTIES IS A MAJOR OBSTACLE TO TISSUE SELF-REPAIR. NUCLEAR REPROGRAMMING-LIKE PHENOMENA THAT INDUCE A TRANSIENT ACQUISITION OF EPIGENETIC PLASTICITY AND PHENOTYPE MALLEABILITY MAY CONSTITUTE A REPARATIVE ROUTE THROUGH WHICH HUMAN TISSUES RESPOND TO INJURY, STRESS, AND DISEASE. HOWEVER, TISSUE REJUVENATION SHOULD INVOLVE NOT ONLY THE TRANSIENT EPIGENETIC REPROGRAMMING OF DIFFERENTIATED CELLS, BUT ALSO THE COMMITTED RE-ACQUISITION OF THE ORIGINAL OR ALTERNATIVE COMMITTED CELL FATE. CHRONIC OR UNRESTRAINED EPIGENETIC PLASTICITY WOULD DRIVE AGING PHENOTYPES BY IMPAIRING THE REPAIR OR THE REPLACEMENT OF DAMAGED CELLS; SUCH UNCONTROLLED PHENOMENA OF IN VIVO REPROGRAMMING MIGHT ALSO GENERATE CANCER-LIKE CELLULAR STATES. WE HEREIN PROPOSE THAT THE ABILITY OF SENESCENCE-ASSOCIATED INFLAMMATORY SIGNALING TO REGULATE IN VIVO REPROGRAMMING CYCLES OF TISSUE REPAIR OUTLINES A THRESHOLD MODEL OF AGING AND CANCER. THE DEGREE OF SENESCENCE/INFLAMMATION-ASSOCIATED DEVIATION FROM THE HOMEOSTATIC STATE MAY DELINEATE A TYPE OF THRESHOLDING ALGORITHM DISTINGUISHING BENEFICIAL FROM DELETERIOUS EFFECTS OF IN VIVO REPROGRAMMING. FIRST, TRANSIENT ACTIVATION OF NF-KAPPAB-RELATED INNATE IMMUNITY AND SENESCENCE-ASSOCIATED INFLAMMATORY COMPONENTS (E.G., IL-6) MIGHT FACILITATE REPARATIVE CELLULAR REPROGRAMMING IN RESPONSE TO ACUTE INFLAMMATORY EVENTS. SECOND, PARA-INFLAMMATION SWITCHES MIGHT PROMOTE LONG-LASTING BUT REVERSIBLE REFRACTORINESS TO REPARATIVE CELLULAR REPROGRAMMING. THIRD, CHRONIC SENESCENCE-ASSOCIATED INFLAMMATORY SIGNALING MIGHT LOCK CELLS IN HIGHLY PLASTIC EPIGENETIC STATES DISABLED FOR REPARATIVE DIFFERENTIATION. THE CONSIDERATION OF A CELLULAR REPROGRAMMING-CENTERED VIEW OF EPIGENETIC PLASTICITY AS A FUNDAMENTAL ELEMENT OF A TISSUE'S CAPACITY TO UNDERGO SUCCESSFUL REPAIR, AGING DEGENERATION OR MALIGNANT TRANSFORMATION SHOULD PROVIDE CHALLENGING STOCHASTIC INSIGHTS INTO THE CURRENT DETERMINISTIC GENETIC PARADIGM FOR MOST CHRONIC DISEASES, THEREBY INCREASING THE SPECTRUM OF THERAPEUTIC APPROACHES FOR PHYSIOLOGICAL AGING AND CANCER. 2017 18 3576 28 IMPACT OF NUTRITION ON POLLUTANT TOXICITY: AN UPDATE WITH NEW INSIGHTS INTO EPIGENETIC REGULATION. EXPOSURE TO ENVIRONMENTAL POLLUTANTS IS A GLOBAL HEALTH PROBLEM AND IS ASSOCIATED WITH THE DEVELOPMENT OF MANY CHRONIC DISEASES, INCLUDING CARDIOVASCULAR DISEASE, DIABETES AND METABOLIC SYNDROME. THERE IS A GROWING BODY OF EVIDENCE THAT NUTRITION CAN BOTH POSITIVELY AND NEGATIVELY MODULATE THE TOXIC EFFECTS OF POLLUTANT EXPOSURE. DIETS HIGH IN PROINFLAMMATORY FATS, SUCH AS LINOLEIC ACID, CAN EXACERBATE POLLUTANT TOXICITY, WHEREAS DIETS RICH IN BIOACTIVE AND ANTI-INFLAMMATORY FOOD COMPONENTS, INCLUDING OMEGA-3 FATTY ACIDS AND POLYPHENOLS, CAN ATTENUATE TOXICANT-ASSOCIATED INFLAMMATION. PREVIOUSLY, RESEARCHERS HAVE ELUCIDATED DIRECT MECHANISMS OF NUTRITIONAL MODULATION, INCLUDING ALTERATION OF NUCLEAR FACTOR KAPPA-LIGHT-CHAIN-ENHANCER OF ACTIVATED B CELLS (NF-KAPPAB) SIGNALING, BUT RECENTLY, INCREASED FOCUS HAS BEEN GIVEN TO THE WAYS IN WHICH NUTRITION AND POLLUTANTS AFFECT EPIGENETICS. NUTRITION HAS BEEN DEMONSTRATED TO MODULATE EPIGENETIC MARKERS THAT HAVE BEEN LINKED EITHER TO INCREASED DISEASE RISKS OR TO PROTECTION AGAINST DISEASES. OVERNUTRITION (I.E. OBESITY) AND UNDERNUTRITION (I.E. FAMINE) HAVE BEEN OBSERVED TO ALTER PRENATAL EPIGENETIC TAGS THAT MAY INCREASE THE RISK OF OFFSPRING DEVELOPING DISEASE LATER IN LIFE. CONVERSELY, BIOACTIVE FOOD COMPONENTS, INCLUDING CURCUMIN, HAVE BEEN SHOWN TO ALTER EPIGENETIC MARKERS THAT SUPPRESS THE ACTIVATION OF NF-KAPPAB, THUS REDUCING INFLAMMATORY RESPONSES. EXPOSURE TO POLLUTANTS ALSO ALTERS EPIGENETIC MARKERS AND MAY CONTRIBUTE TO INFLAMMATION AND DISEASE. IT HAS BEEN DEMONSTRATED THAT POLLUTANTS, VIA EPIGENETIC MODULATIONS, CAN INCREASE THE ACTIVATION OF NF-KAPPAB AND UPREGULATE MICRORNAS ASSOCIATED WITH INFLAMMATION, CARDIAC INJURY AND OXIDATIVE DAMAGE. IMPORTANTLY, RECENT EVIDENCE SUGGESTS THAT NUTRITIONAL COMPONENTS, INCLUDING EPIGALLOCATECHIN GALLATE (EGCG), CAN PROTECT AGAINST POLLUTANT-INDUCED INFLAMMATION THROUGH EPIGENETIC REGULATION OF PROINFLAMMATORY TARGET GENES OF NF-KAPPAB. FURTHER RESEARCH IS NEEDED TO BETTER UNDERSTAND HOW NUTRITION CAN MODULATE POLLUTANT TOXICITY THROUGH EPIGENETIC REGULATION. THEREFORE, THE OBJECTIVE OF THIS REVIEW IS TO ELUCIDATE THE CURRENT EVIDENCE LINKING EPIGENETIC CHANGES TO POLLUTANT-INDUCED DISEASES AND HOW THIS REGULATION MAY BE MODULATED BY NUTRIENTS ALLOWING FOR THE DEVELOPMENT OF FUTURE PERSONALIZED LIFESTYLE INTERVENTIONS. 2017 19 5409 30 REGULATION OF ACETYLATION STATES BY NUTRIENTS IN THE INHIBITION OF VASCULAR INFLAMMATION AND ATHEROSCLEROSIS. ATHEROSCLEROSIS (AS) IS A CHRONIC METABOLIC DISORDER AND PRIMARY CAUSE OF CARDIOVASCULAR DISEASES, RESULTING IN SUBSTANTIAL MORBIDITY AND MORTALITY WORLDWIDE. INITIATED BY ENDOTHELIAL CELL STIMULATION, AS IS CHARACTERIZED BY ARTERIAL INFLAMMATION, LIPID DEPOSITION, FOAM CELL FORMATION, AND PLAQUE DEVELOPMENT. NUTRIENTS SUCH AS CAROTENOIDS, POLYPHENOLS, AND VITAMINS CAN PREVENT THE ATHEROSCLEROTIC PROCESS BY MODULATING INFLAMMATION AND METABOLIC DISORDERS THROUGH THE REGULATION OF GENE ACETYLATION STATES MEDIATED WITH HISTONE DEACETYLASES (HDACS). NUTRIENTS CAN REGULATE AS-RELATED EPIGENETIC STATES VIA SIRTUINS (SIRTS) ACTIVATION, SPECIFICALLY SIRT1 AND SIRT3. NUTRIENT-DRIVEN ALTERATIONS IN THE REDOX STATE AND GENE MODULATION IN AS PROGRESSION ARE LINKED TO THEIR PROTEIN DEACETYLATING, ANTI-INFLAMMATORY, AND ANTIOXIDANT PROPERTIES. NUTRIENTS CAN ALSO INHIBIT ADVANCED OXIDATION PROTEIN PRODUCT FORMATION, REDUCING ARTERIAL INTIMA-MEDIA THICKNESS EPIGENETICALLY. NONETHELESS, KNOWLEDGE GAPS REMAIN WHEN IT COMES TO UNDERSTANDING EFFECTIVE AS PREVENTION THROUGH EPIGENETIC REGULATION BY NUTRIENTS. THIS WORK REVIEWS AND CONFIRMS THE UNDERLYING MECHANISMS BY WHICH NUTRIENTS PREVENT ARTERIAL INFLAMMATION AND AS, FOCUSING ON THE EPIGENETIC PATHWAYS THAT MODIFY HISTONES AND NON-HISTONE PROTEINS BY REGULATING REDOX AND ACETYLATION STATES THROUGH HDACS SUCH AS SIRTS. THESE FINDINGS MAY SERVE AS A FOUNDATION FOR DEVELOPING POTENTIAL THERAPEUTIC AGENTS TO PREVENT AS AND CARDIOVASCULAR DISEASES BY EMPLOYING NUTRIENTS BASED ON EPIGENETIC REGULATION. 2023 20 2617 38 EPIGENOME TARGETING BY PROBIOTIC METABOLITES. BACKGROUND: THE INTESTINAL MICROBIOTA PLAYS AN IMPORTANT ROLE IN IMMUNE DEVELOPMENT AND HOMEOSTASIS. A DISTURBED MICROBIOTA DURING EARLY INFANCY IS ASSOCIATED WITH AN INCREASED RISK OF DEVELOPING INFLAMMATORY AND ALLERGIC DISEASES LATER IN LIFE. THE MECHANISMS UNDERLYING THESE EFFECTS ARE POORLY UNDERSTOOD BUT ARE LIKELY TO INVOLVE ALTERATIONS IN MICROBIAL PRODUCTION OF FERMENTATION-DERIVED METABOLITES, WHICH HAVE POTENT IMMUNE MODULATING PROPERTIES AND ARE REQUIRED FOR MAINTENANCE OF HEALTHY MUCOSAL IMMUNE RESPONSES. PROBIOTICS ARE BENEFICIAL BACTERIA THAT HAVE THE CAPACITY TO ALTER THE COMPOSITION OF BACTERIAL SPECIES IN THE INTESTINE THAT CAN IN TURN INFLUENCE THE PRODUCTION OF FERMENTATION-DERIVED METABOLITES. PRINCIPAL AMONG THESE METABOLITES ARE THE SHORT-CHAIN FATTY ACIDS BUTYRATE AND ACETATE THAT HAVE POTENT ANTI-INFLAMMATORY ACTIVITIES IMPORTANT IN REGULATING IMMUNE FUNCTION AT THE INTESTINAL MUCOSAL SURFACE. THEREFORE STRATEGIES AIMED AT RESTORING THE MICROBIOTA PROFILE MAY BE EFFECTIVE IN THE PREVENTION OR TREATMENT OF ALLERGIC AND INFLAMMATORY DISEASES. PRESENTATION OF THE HYPOTHESIS: PROBIOTIC BACTERIA HAVE DIVERSE EFFECTS INCLUDING ALTERING MICROBIOTA COMPOSITION, REGULATING EPITHELIAL CELL BARRIER FUNCTION AND MODULATING OF IMMUNE RESPONSES. THE PRECISE MOLECULAR MECHANISMS MEDIATING THESE PROBIOTIC EFFECTS ARE NOT WELL UNDERSTOOD. SHORT-CHAIN FATTY ACIDS SUCH AS BUTYRATE ARE A CLASS OF HISTONE DEACETYLASE INHIBITORS IMPORTANT IN THE EPIGENETIC CONTROL OF HOST CELL RESPONSES. IT IS HYPOTHESIZED THAT THE BIOLOGICAL FUNCTION OF PROBIOTICS MAY BE A RESULT OF EPIGENETIC MODIFICATIONS THAT MAY EXPLAIN THE WIDE RANGE OF EFFECTS OBSERVED. STUDIES DELINEATING THE EFFECTS OF PROBIOTICS ON SHORT-CHAIN FATTY ACID PRODUCTION AND THE EPIGENETIC ACTIONS OF SHORT-CHAIN FATTY ACIDS WILL ASSIST IN UNDERSTANDING THE ASSOCIATION BETWEEN MICROBIOTA AND ALLERGIC OR AUTOIMMUNE DISORDERS. TESTING THE HYPOTHESIS: WE PROPOSE THAT TREATMENT WITH SPECIFIC PROBIOTIC BACTERIA UNDER IN VIVO CONDITIONS WOULD OFFER THE IDEAL CONDITIONS TO EXAMINE THE MICROBIOLOGICAL, IMMUNOLOGICAL AND EPIGENETIC MECHANISMS OF ACTION. ADVANCES IN EPIGENETIC TECHNOLOGY NOW ALLOW INVESTIGATORS TO BETTER UNDERSTAND THE COMPLEX BIOLOGICAL PROPERTIES OF PROBIOTICS AND THEIR METABOLITES. IMPLICATIONS OF THE HYPOTHESIS: DETERMINING THE PRECISE MECHANISMS OF PROBIOTIC ACTION WILL LEAD TO MORE SPECIFIC AND EFFICACIOUS THERAPEUTIC STRATEGIES IN THE PREVENTION OR TREATMENT OF CHRONIC INFLAMMATORY CONDITIONS. 2010