1 3344 75 HISTONE DEACETYLASES (HDACS) AND ATHEROSCLEROSIS: A MECHANISTIC AND PHARMACOLOGICAL REVIEW. ATHEROSCLEROSIS (AS), THE MOST COMMON UNDERLYING PATHOLOGY FOR CORONARY ARTERY DISEASE, IS A CHRONIC INFLAMMATORY, PROLIFERATIVE DISEASE IN LARGE- AND MEDIUM-SIZED ARTERIES. THE VASCULAR ENDOTHELIUM IS IMPORTANT FOR MAINTAINING VASCULAR HEALTH. ENDOTHELIAL DYSFUNCTION IS A CRITICAL EARLY EVENT LEADING TO AS, WHICH IS A MAJOR RISK FACTOR FOR STROKE AND MYOCARDIAL INFARCTION. ACCUMULATING EVIDENCE HAS SUGGESTED THE CRITICAL ROLES OF HISTONE DEACETYLASES (HDACS) IN REGULATING VASCULAR CELL HOMEOSTASIS AND AS. THE PURPOSE OF THIS REVIEW IS TO PRESENT AN UPDATED VIEW ON THE ROLES OF HDACS (CLASS I, CLASS II, CLASS IV) AND HDAC INHIBITORS IN VASCULAR DYSFUNCTION AND AS. WE ALSO ELABORATE ON THE NOVEL THERAPEUTIC TARGETS AND AGENTS IN ATHEROSCLEROTIC CARDIOVASCULAR DISEASES. 2020 2 2532 26 EPIGENETICS IN ATHEROSCLEROSIS AND INFLAMMATION. ATHEROSCLEROSIS IS A MULTIFACTORIAL DISEASE WITH A SEVERE BURDEN ON WESTERN SOCIETY. RECENT INSIGHTS INTO THE PATHOGENESIS OF ATHEROSCLEROSIS UNDERSCORE THE IMPORTANCE OF CHRONIC INFLAMMATION IN BOTH THE INITIATION AND PROGRESSION OF VASCULAR REMODELLING. EXPRESSION OF IMMUNOREGULATORY MOLECULES BY VASCULAR WALL COMPONENTS WITHIN THE ATHEROSCLEROTIC LESIONS IS ACCORDINGLY THOUGHT TO CONTRIBUTE TO THE ONGOING INFLAMMATORY PROCESS. BESIDES GENE REGULATORY PROTEINS (TRANSCRIPTION FACTORS), EPIGENETIC MECHANISMS ALSO PLAY AN ESSENTIAL AND FUNDAMENTAL ROLE IN THE TRANSCRIPTIONAL CONTROL OF GENE EXPRESSION. THESE EPIGENETIC MECHANISMS CHANGE THE ACCESSIBILITY OF CHROMATIN BY DNA METHYLATION AND HISTONE MODIFICATIONS. EPIGENETIC MODULATORS ARE THUS CRITICALLY INVOLVED IN THE REGULATION OF VASCULAR, IMMUNE AND TISSUE-SPECIFIC GENE EXPRESSION WITHIN THE ATHEROSCLEROTIC LESION. IMPORTANTLY, EPIGENETIC PROCESSES ARE REVERSIBLE AND MAY PROVIDE AN EXCELLENT THERAPEUTIC TARGET. THE CONCEPT OF EPIGENETIC REGULATION IS GRADUALLY BEING RECOGNIZED AS AN IMPORTANT FACTOR IN THE PATHOGENESIS OF ATHEROSCLEROSIS. RECENT RESEARCH PROVIDES AN ESSENTIAL LINK BETWEEN INFLAMMATION AND REPROGRAMMING OF THE EPIGENOME. IN THIS REVIEW WE THEREFORE DISCUSS THE BASIS OF EPIGENETIC REGULATION - AND THE CONTRIBUTION THEREOF IN THE REGULATION OF INFLAMMATORY PROCESSES IN GENERAL AND DURING ATHEROSCLEROSIS IN PARTICULAR. MOREOVER WE HIGHLIGHT POTENTIAL THERAPEUTIC INTERVENTIONS BASED ON EPIGENETIC MECHANISMS. 2010 3 5933 38 TARGETING EPIGENETICS AND NON-CODING RNAS IN ATHEROSCLEROSIS: FROM MECHANISMS TO THERAPEUTICS. ATHEROSCLEROSIS, THE PRINCIPAL CAUSE OF CARDIOVASCULAR DEATH WORLDWIDE, IS A PATHOLOGICAL DISEASE CHARACTERIZED BY FIBRO-PROLIFERATION, CHRONIC INFLAMMATION, LIPID ACCUMULATION, AND IMMUNE DISORDER IN THE VESSEL WALL. AS THE ATHEROMATOUS PLAQUES DEVELOP INTO ADVANCED STAGE, THE VULNERABLE PLAQUES ARE PRONE TO RUPTURE, WHICH CAUSES ACUTE CARDIOVASCULAR EVENTS, INCLUDING ISCHEMIC STROKE AND MYOCARDIAL INFARCTION. EMERGING EVIDENCE HAS SUGGESTED THAT ATHEROSCLEROSIS IS ALSO AN EPIGENETIC DISEASE WITH THE INTERPLAY OF MULTIPLE EPIGENETIC MECHANISMS. THE EPIGENETIC BASIS OF ATHEROSCLEROSIS HAS TRANSFORMED OUR KNOWLEDGE OF EPIGENETICS FROM AN IMPORTANT BIOLOGICAL PHENOMENON TO A BURGEONING FIELD IN CARDIOVASCULAR RESEARCH. HERE, WE PROVIDE A SYSTEMATIC AND UP-TO-DATE OVERVIEW OF THE CURRENT KNOWLEDGE OF THREE DISTINCT BUT INTERRELATED EPIGENETIC PROCESSES (INCLUDING DNA METHYLATION, HISTONE METHYLATION/ACETYLATION, AND NON-CODING RNAS), IN ATHEROSCLEROTIC PLAQUE DEVELOPMENT AND INSTABILITY. MECHANISTIC AND CONCEPTUAL ADVANCES IN UNDERSTANDING THE BIOLOGICAL ROLES OF VARIOUS EPIGENETIC MODIFIERS IN REGULATING GENE EXPRESSION AND FUNCTIONS OF ENDOTHELIAL CELLS (VASCULAR HOMEOSTASIS, LEUKOCYTE ADHESION, ENDOTHELIAL-MESENCHYMAL TRANSITION, ANGIOGENESIS, AND MECHANOTRANSDUCTION), SMOOTH MUSCLE CELLS (PROLIFERATION, MIGRATION, INFLAMMATION, HYPERTROPHY, AND PHENOTYPIC SWITCH), AND MACROPHAGES (DIFFERENTIATION, INFLAMMATION, FOAM CELL FORMATION, AND POLARIZATION) ARE DISCUSSED. THE INHERENTLY DYNAMIC NATURE AND REVERSIBILITY OF EPIGENETIC REGULATION, ENABLES THE POSSIBILITY OF EPIGENETIC THERAPY BY TARGETING EPIGENETIC "WRITERS", "READERS", AND "ERASERS". SEVERAL FOOD DRUG ADMINISTRATION-APPROVED SMALL-MOLECULE EPIGENETIC DRUGS SHOW PROMISE IN PRE-CLINICAL STUDIES FOR THE TREATMENT OF ATHEROSCLEROSIS. FINALLY, WE DISCUSS POTENTIAL THERAPEUTIC IMPLICATIONS AND CHALLENGES FOR FUTURE RESEARCH INVOLVING CARDIOVASCULAR EPIGENETICS, WITH AN AIM TO PROVIDE A TRANSLATIONAL PERSPECTIVE FOR IDENTIFYING NOVEL BIOMARKERS OF ATHEROSCLEROSIS, AND TRANSFORMING PRECISION CARDIOVASCULAR RESEARCH AND DISEASE THERAPY IN MODERN ERA OF EPIGENETICS. 2019 4 2291 29 EPIGENETIC REGULATION IN PATHOLOGY OF ATHEROSCLEROSIS: A NOVEL PERSPECTIVE. ATHEROSCLEROSIS, CHARACTERIZED BY ATHEROSCLEROTIC PLAQUES, IS A COMPLEX PATHOLOGICAL PROCESS THAT INVOLVES DIFFERENT CELL TYPES AND CAN BE SEEN AS A CHRONIC INFLAMMATORY DISEASE. IN THE ADVANCED STAGE, THE RUPTURED ATHEROSCLEROTIC PLAQUE CAN INDUCE DEADLY ACCIDENTS INCLUDING ISCHEMIC STROKE AND MYOCARDIAL INFARCTION. EPIGENETICS REGULATION, INCLUDING DNA METHYLATION, HISTONE MODIFICATION, AND NON-CODING RNA MODIFICATION. MAINTAINS CELLULAR IDENTITY VIA AFFECTING THE CELLULAR TRANSCRIPTOME. THE EPIGENETIC MODIFICATION PROCESS, MEDIATING BY EPIGENETIC ENZYMES, IS DYNAMIC UNDER VARIOUS STIMULI, WHICH CAN BE REVERSELY ALTERED. RECENTLY, NUMEROUS STUDIES HAVE EVIDENCED THE CLOSE RELATIONSHIP BETWEEN ATHEROSCLEROSIS AND EPIGENETIC REGULATIONS IN ATHEROSCLEROSIS, PROVIDING US WITH A NOVEL PERSPECTIVE IN RESEARCHING MECHANISMS AND FINDING NOVEL THERAPEUTIC TARGETS OF THIS SERIOUS DISEASE. HERE, WE CRITICALLY REVIEW THE RECENT DISCOVERIES BETWEEN EPIGENETIC REGULATION MECHANISMS IN ATHEROSCLEROSIS. 2021 5 1872 26 EMERGING ROLE OF LONG NON-CODING RNAS IN ENDOTHELIAL DYSFUNCTION AND THEIR MOLECULAR MECHANISMS. LONG NON-CODING RNAS (LNCRNAS) ARE THE NOVEL CLASS OF TRANSCRIPTS INVOLVED IN TRANSCRIPTIONAL, POST-TRANSCRIPTIONAL, TRANSLATIONAL, AND POST-TRANSLATIONAL REGULATION OF PHYSIOLOGY AND THE PATHOLOGY OF DISEASES. STUDIES HAVE EVIDENCED THAT THE IMPAIRMENT OF ENDOTHELIUM IS A CRITICAL EVENT IN THE PATHOGENESIS OF ATHEROSCLEROSIS AND ITS COMPLICATIONS. ENDOTHELIAL DYSFUNCTION IS CHARACTERIZED BY AN IMBALANCE IN VASODILATION AND VASOCONSTRICTION, OXIDATIVE STRESS, PROINFLAMMATORY FACTORS, AND NITRIC OXIDE BIOAVAILABILITY. DISRUPTION OF THE ENDOTHELIAL BARRIER PERMEABILITY, THE FIRST STEP IN DEVELOPING ATHEROSCLEROTIC LESIONS IS A CONSEQUENCE OF ENDOTHELIAL DYSFUNCTION. THOUGH SEVERAL FACTORS INTERFERE WITH THE NORMAL FUNCTIONING OF THE ENDOTHELIUM, INTRINSIC EPIGENETIC MECHANISMS GOVERNING ENDOTHELIAL FUNCTION ARE REGULATED BY LNCRNAS AND PERTURBATIONS CONTRIBUTE TO THE PATHOGENESIS OF THE DISEASE. THIS REVIEW COMPREHENSIVELY ADDRESSES THE BIOGENESIS OF LNCRNA AND MOLECULAR MECHANISMS UNDERLYING AND REGULATION IN ENDOTHELIAL FUNCTION. AN INSIGHT CORRELATING LNCRNAS AND ENDOTHELIAL DYSFUNCTION-ASSOCIATED DISEASES CAN POSITIVELY IMPACT THE DEVELOPMENT OF NOVEL BIOMARKERS AND THERAPEUTIC TARGETS IN ENDOTHELIAL DYSFUNCTION-ASSOCIATED DISEASES AND TREATMENT STRATEGIES. 2022 6 6103 36 THE EMERGING ROLE OF HDACS: PATHOLOGY AND THERAPEUTIC TARGETS IN DIABETES MELLITUS. DIABETES MELLITUS (DM) IS ONE OF THE PRINCIPAL MANIFESTATIONS OF METABOLIC SYNDROME AND ITS PREVALENCE WITH MODERN LIFESTYLE IS INCREASING INCESSANTLY. CHRONIC HYPERGLYCEMIA CAN INDUCE SEVERAL VASCULAR COMPLICATIONS THAT WERE REFERRED TO BE THE MAJOR CAUSE OF MORBIDITY AND MORTALITY IN DM. ALTHOUGH SEVERAL THERAPEUTIC TARGETS HAVE BEEN IDENTIFIED AND ACCESSED CLINICALLY, THE IMMINENT RISK OF DM AND ITS PREVALENCE ARE STILL ASCENDING. SUBSTANTIAL PIECES OF EVIDENCE REVEALED THAT HISTONE DEACETYLASE (HDAC) ISOFORMS CAN REGULATE VARIOUS MOLECULAR ACTIVITIES IN DM VIA EPIGENETIC AND POST-TRANSLATIONAL REGULATION OF SEVERAL TRANSCRIPTION FACTORS. TO DATE, 18 HDAC ISOFORMS HAVE BEEN IDENTIFIED IN MAMMALS THAT WERE CATEGORIZED INTO FOUR DIFFERENT CLASSES. CLASSES I, II, AND IV ARE REGARDED AS CLASSICAL HDACS, WHICH OPERATE THROUGH A ZN-BASED MECHANISM. IN CONTRAST, CLASS III HDACS OR SIRTUINS DEPEND ON NICOTINAMIDE ADENINE DINUCLEOTIDE (NAD(+)) FOR THEIR MOLECULAR ACTIVITY. FUNCTIONALLY, MOST OF THE HDAC ISOFORMS CAN REGULATE BETA CELL FATE, INSULIN RELEASE, INSULIN EXPRESSION AND SIGNALING, AND GLUCOSE METABOLISM. MOREOVER, THE ROLES OF HDAC MEMBERS HAVE BEEN IMPLICATED IN THE REGULATION OF OXIDATIVE STRESS, INFLAMMATION, APOPTOSIS, FIBROSIS, AND OTHER PATHOLOGICAL EVENTS, WHICH SUBSTANTIALLY CONTRIBUTE TO DIABETES-RELATED VASCULAR DYSFUNCTIONS. THEREFORE, HDACS COULD SERVE AS THE POTENTIAL THERAPEUTIC TARGET IN DM TOWARDS DEVELOPING NOVEL INTERVENTION STRATEGIES. THIS REVIEW SHEDS LIGHT ON THE EMERGING ROLE OF HDACS/ISOFORMS IN DIABETIC PATHOPHYSIOLOGY AND EMPHASIZED THE SCOPE OF THEIR TARGETING IN DM FOR CONSTITUTING NOVEL INTERVENTIONAL STRATEGIES FOR METABOLIC DISORDERS/COMPLICATIONS. 2021 7 1712 40 DYSFUNCTIONAL VASCULAR ENDOTHELIUM AS A DRIVER OF ATHEROSCLEROSIS: EMERGING INSIGHTS INTO PATHOGENESIS AND TREATMENT. ATHEROSCLEROSIS, THE CHRONIC ACCUMULATION OF CHOLESTEROL-RICH PLAQUE WITHIN ARTERIES, IS ASSOCIATED WITH A BROAD SPECTRUM OF CARDIOVASCULAR DISEASES INCLUDING MYOCARDIAL INFARCTION, AORTIC ANEURYSM, PERIPHERAL VASCULAR DISEASE, AND STROKE. ATHEROSCLEROTIC CARDIOVASCULAR DISEASE REMAINS A LEADING CAUSE OF MORTALITY IN HIGH-INCOME COUNTRIES AND RECENT YEARS HAVE WITNESSED A NOTABLE INCREASE IN PREVALENCE WITHIN LOW- AND MIDDLE-INCOME REGIONS OF THE WORLD. CONSIDERING THIS PROMINENT AND EVOLVING GLOBAL BURDEN, THERE IS A NEED TO IDENTIFY THE CELLULAR MECHANISMS THAT UNDERLIE THE PATHOGENESIS OF ATHEROSCLEROSIS TO DISCOVER NOVEL THERAPEUTIC TARGETS FOR PREVENTING OR MITIGATING ITS CLINICAL SEQUELAE. DESPITE DECADES OF RESEARCH, WE STILL DO NOT FULLY UNDERSTAND THE COMPLEX CELL-CELL INTERACTIONS THAT DRIVE ATHEROSCLEROSIS, BUT NEW INVESTIGATIVE APPROACHES ARE RAPIDLY SHEDDING LIGHT ON THESE ESSENTIAL MECHANISMS. THE VASCULAR ENDOTHELIUM RESIDES AT THE INTERFACE OF SYSTEMIC CIRCULATION AND THE UNDERLYING VESSEL WALL AND PLAYS AN ESSENTIAL ROLE IN GOVERNING PATHOPHYSIOLOGICAL PROCESSES DURING ATHEROGENESIS. IN THIS REVIEW, WE PRESENT EMERGING EVIDENCE THAT IMPLICATES THE ACTIVATED ENDOTHELIUM AS A DRIVER OF ATHEROSCLEROSIS BY DIRECTING SITE-SPECIFICITY OF PLAQUE FORMATION AND BY PROMOTING PLAQUE DEVELOPMENT THROUGH INTRACELLULAR PROCESSES, WHICH REGULATE ENDOTHELIAL CELL PROLIFERATION AND TURNOVER, METABOLISM, PERMEABILITY, AND PLASTICITY. MOREOVER, WE HIGHLIGHT NOVEL MECHANISMS OF INTERCELLULAR COMMUNICATION BY WHICH ENDOTHELIAL CELLS MODULATE THE ACTIVITY OF KEY VASCULAR CELL POPULATIONS INVOLVED IN ATHEROGENESIS, AND DISCUSS HOW ENDOTHELIAL CELLS CONTRIBUTE TO RESOLUTION BIOLOGY - A PROCESS THAT IS DYSREGULATED IN ADVANCED PLAQUES. FINALLY, WE DESCRIBE IMPORTANT FUTURE DIRECTIONS FOR PRECLINICAL ATHEROSCLEROSIS RESEARCH, INCLUDING EPIGENETIC AND TARGETED THERAPIES, TO LIMIT THE PROGRESSION OF ATHEROSCLEROSIS IN AT-RISK OR AFFECTED PATIENTS. 2021 8 2168 26 EPIGENETIC MECHANISMS IN MONOCYTES/MACROPHAGES REGULATE INFLAMMATION IN CARDIOMETABOLIC AND VASCULAR DISEASE. CARDIOMETABOLIC AND VASCULAR DISEASE, WITH THEIR ASSOCIATED SECONDARY COMPLICATIONS, ARE THE LEADING CAUSE OF MORBIDITY AND MORTALITY IN WESTERN SOCIETY. CHRONIC INFLAMMATION IS A COMMON THEME THAT UNDERLIES INITIATION AND PROGRESSION OF CARDIOVASCULAR DISEASE. IN THIS REGARD, MONOCYTES/MACROPHAGES ARE KEY PLAYERS IN THE DEVELOPMENT OF A CHRONIC INFLAMMATORY STATE. OVER THE PAST DECADE, EPIGENETIC MODIFICATIONS, SUCH AS DNA METHYLATION AND POSTTRANSLATIONAL HISTONE PROCESSING, HAVE EMERGED AS IMPORTANT REGULATORS OF IMMUNE CELL PHENOTYPES. ACCUMULATING STUDIES REVEAL THE IMPORTANCE OF EPIGENETIC ENZYMES IN THE DYNAMIC REGULATION OF KEY SIGNALING PATHWAYS THAT ALTER MONOCYTE/MACROPHAGE PHENOTYPES IN RESPONSE TO ENVIRONMENTAL STIMULI. IN THIS REVIEW, WE HIGHLIGHT THE CURRENT PARADIGMS OF MONOCYTE/MACROPHAGE POLARIZATION AND THE EMERGING ROLE OF EPIGENETIC MODIFICATION IN THE REGULATION OF MONOCYTE/MACROPHAGE PHENOTYPE IN OBESITY, DIABETES MELLITUS, ATHEROSCLEROSIS, AND ABDOMINAL AORTIC ANEURYSMS. 2019 9 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 10 3366 23 HISTONE METHYLATION RELATED THERAPEUTIC CHALLENGE IN CARDIOVASCULAR DISEASES. THE EPIDEMIC OF CARDIOVASCULAR DISEASES (CVDS) IS PREDICTED TO SPREAD RAPIDLY IN ADVANCED COUNTRIES ACCOMPANIED BY THE HIGH PREVALENCE OF RISK FACTORS. IN TERMS OF PATHOGENESIS, THE PATHOPHYSIOLOGY OF CVDS IS FEATURED BY MULTIPLE DISORDERS, INCLUDING VASCULAR INFLAMMATION ACCOMPANIED BY SIMULTANEOUSLY PERTURBED PATHWAYS, SUCH AS CELL DEATH AND ACUTE/CHRONIC INFLAMMATORY REACTIONS. EPIGENETIC ALTERATION IS INVOLVED IN THE REGULATION OF GENOME STABILIZATION AND CELLULAR HOMEOSTASIS. THE ASSOCIATION BETWEEN CVD PROGRESSION AND HISTONE MODIFICATIONS IS WIDELY KNOWN. AMONG THE HISTONE MODIFICATIONS, HISTONE METHYLATION IS A REVERSIBLE PROCESS INVOLVED IN THE DEVELOPMENT AND HOMEOSTASIS OF THE CARDIOVASCULAR SYSTEM. ABNORMAL METHYLATION CAN PROMOTE CVD PROGRESSION. THIS REVIEW DISCUSSES HISTONE METHYLATION AND THE ENZYMES INVOLVED IN THE CARDIOVASCULAR SYSTEM AND DETERMINE THE EFFECTS OF HISTONE METHYLTRANSFERASES AND DEMETHYLASES ON THE PATHOGENESIS OF CVDS. WE WILL FURTHER DEMONSTRATE KEY PROTEINS MEDIATED BY HISTONE METHYLATION IN BLOOD VESSELS AND REVIEW HISTONE METHYLATION-MEDIATED CARDIOMYOCYTES AND CELLULAR FUNCTIONS AND PATHWAYS IN CVDS. FINALLY, WE WILL SUMMARIZE THE ROLE OF INHIBITORS OF HISTONE METHYLATION AND DEMETHYLATION IN CVDS AND ANALYZE THEIR THERAPEUTIC POTENTIAL, BASED ON PREVIOUS STUDIES. 2021 11 2550 34 EPIGENETICS IN OSTEOARTHRITIS: POTENTIAL OF HDAC INHIBITORS AS THERAPEUTICS. OSTEOARTHRITIS (OA) IS THE MOST COMMON JOINT DISEASE AND THE LEADING CAUSE OF CHRONIC DISABILITY IN MIDDLE-AGED AND OLDER POPULATIONS WORLDWIDE. THE DEVELOPMENT OF DISEASE MODIFYING THERAPY FOR OA IS IN ITS INFANCY LARGELY BECAUSE THE REGULATORY MECHANISMS FOR THE MOLECULAR EFFECTORS OF OA PATHOGENESIS ARE POORLY UNDERSTOOD. RECENT STUDIES IDENTIFIED EPIGENETIC EVENTS AS A CRITICAL REGULATOR OF MOLECULAR PLAYERS INVOLVED IN THE INDUCTION AND DEVELOPMENT OF OA. EPIGENETIC MECHANISMS INCLUDE DNA METHYLATION, NON-CODING RNA AND HISTONE MODIFICATIONS. THE AIM OF THIS REVIEW IS TO BRIEFLY HIGHLIGHT THE RECENT ADVANCES IN THE EPIGENETICS OF CARTILAGE AND POTENTIAL OF HDACS (HISTONE DEACETYLASES) INHIBITORS IN THE THERAPEUTIC MANAGEMENT OF OA. WE SUMMARIZE THE RECENT STUDIES UTILIZING HDAC INHIBITORS AS POTENTIAL THERAPEUTICS FOR INHIBITING DISEASE PROGRESSION AND PREVENTING THE CARTILAGE DESTRUCTION IN OA. HDACS CONTROL NORMAL CARTILAGE DEVELOPMENT AND HOMEOSTASIS AND UNDERSTANDING THE IMPACT OF HDACS INHIBITORS ON THE DISEASE PATHOGENESIS IS OF INTEREST BECAUSE OF ITS IMPORTANCE IN AFFECTING OVERALL CARTILAGE HEALTH AND HOMEOSTASIS. THESE FINDINGS ALSO SHED NEW LIGHT ON CARTILAGE DISEASE PATHOPHYSIOLOGY AND PROVIDE SUBSTANTIAL EVIDENCE THAT HDACS MAY BE POTENTIAL NOVEL THERAPEUTIC TARGETS IN OA. 2018 12 5561 32 ROLE OF HISTONE DEACETYLASES IN MONOCYTE FUNCTION IN HEALTH AND CHRONIC INFLAMMATORY DISEASES. HISTONE DEACETYLASES (HDACS) ARE A FAMILY OF 18 MEMBERS THAT PARTICIPATE IN THE EPIGENETIC REGULATION OF GENE EXPRESSION. IN ADDITION TO HISTONES, SOME HDACS ALSO DEACETYLATE TRANSCRIPTION FACTORS AND SPECIFIC CYTOPLASMIC PROTEINS.MONOCYTES, AS PART OF THE INNATE IMMUNE SYSTEM, MAINTAIN TISSUE HOMEOSTASIS AND HELP FIGHT INFECTIONS AND CANCER. IN THESE CELLS, HDACS ARE INVOLVED IN MULTIPLE PROCESSES INCLUDING PROLIFERATION, MIGRATION, DIFFERENTIATION, INFLAMMATORY RESPONSE, INFECTIONS, AND TUMORIGENESIS. HERE, A SYSTEMATIC DESCRIPTION OF THE ROLE THAT MOST HDACS PLAY IN THESE FUNCTIONS IS REVIEWED. SPECIFICALLY, SOME HDACS INDUCE A PRO-INFLAMMATORY RESPONSE AND PLAY MAJOR ROLES IN HOST DEFENSE. CONVERSELY, OTHER HDACS REPROGRAM MONOCYTES AND MACROPHAGES TOWARDS AN IMMUNOSUPPRESSIVE PHENOTYPE. THE RIGHT BALANCE BETWEEN BOTH TYPES HELPS MONOCYTES TO RESPOND CORRECTLY TO THE DIFFERENT PHYSIOLOGICAL/PATHOLOGICAL STIMULI. HOWEVER, ABERRANT EXPRESSIONS OR ACTIVITIES OF SPECIFIC HDACS ARE ASSOCIATED WITH AUTOIMMUNE DISEASES ALONG WITH OTHER CHRONIC INFLAMMATORY DISEASES, INFECTIONS, OR CANCER.THIS PAPER CRITICALLY REVIEWS THE INTERESTING AND EXTENSIVE KNOWLEDGE REGARDING THE ROLE OF SOME HDACS IN THESE PATHOLOGIES. IT ALSO SHOWS THAT AS YET, VERY LITTLE PROGRESS HAS BEEN MADE TOWARD THE GOAL OF FINDING EFFECTIVE HDAC-TARGETED THERAPIES. HOWEVER, GIVEN THEIR OBVIOUS POTENTIAL, WE CONCLUDE THAT IT IS WORTH THE EFFORT TO DEVELOP MONOCYTE-SPECIFIC DRUGS THAT SELECTIVELY TARGET HDAC SUBTYPES WITH THE AIM OF FINDING EFFECTIVE TREATMENTS FOR DISEASES IN WHICH OUR INNATE IMMUNE SYSTEM IS INVOLVED. 2021 13 6219 24 THE KEY ROLE OF DNA METHYLATION AND HISTONE ACETYLATION IN EPIGENETICS OF ATHEROSCLEROSIS. ATHEROSCLEROSIS, WHICH IS THE MOST COMMON CHRONIC DISEASE OF THE CORONARY ARTERY, CONSTITUTES A VASCULAR PATHOLOGY INDUCED BY INFLAMMATION AND PLAQUE ACCUMULATION WITHIN ARTERIAL VESSEL WALLS. BOTH DNA METHYLATION AND HISTONE MODIFICATIONS ARE EPIGENETIC CHANGES RELEVANT FOR ATHEROSCLEROSIS. RECENT STUDIES HAVE SHOWN THAT THE DNA METHYLATION AND HISTONE MODIFICATION SYSTEMS ARE CLOSELY INTERRELATED AND MECHANICALLY DEPENDENT ON EACH OTHER. HEREIN, WE EXPLORE THE FUNCTIONAL LINKAGE BETWEEN THESE SYSTEMS, WITH A PARTICULAR EMPHASIS ON SEVERAL RECENT FINDINGS SUGGESTING THAT HISTONE ACETYLATION CAN HELP IN TARGETING DNA METHYLATION AND THAT DNA METHYLATION MAY CONTROL GENE EXPRESSION DURING ATHEROSCLEROSIS. 2020 14 2343 24 EPIGENETIC REGULATION OF MACROPHAGE POLARIZATION IN CARDIOVASCULAR DISEASES. CARDIOVASCULAR DISEASES (CVDS) ARE THE LEADING CAUSE OF HOSPITALIZATION AND DEATH WORLDWIDE, ESPECIALLY IN DEVELOPING COUNTRIES. THE INCREASED PREVALENCE RATE AND MORTALITY DUE TO CVDS, DESPITE THE DEVELOPMENT OF SEVERAL APPROACHES FOR PREVENTION AND TREATMENT, ARE ALARMING TRENDS IN GLOBAL HEALTH. CHRONIC INFLAMMATION AND MACROPHAGE INFILTRATION ARE KEY REGULATORS OF THE INITIATION AND PROGRESSION OF CVDS. RECENT DATA SUGGEST THAT EPIGENETIC MODIFICATIONS, SUCH AS DNA METHYLATION, POSTTRANSLATIONAL HISTONE MODIFICATIONS, AND RNA MODIFICATIONS, REGULATE CELL DEVELOPMENT, DNA DAMAGE REPAIR, APOPTOSIS, IMMUNITY, CALCIUM SIGNALING, AND AGING IN CARDIOMYOCYTES; AND ARE INVOLVED IN MACROPHAGE POLARIZATION AND CONTRIBUTE SIGNIFICANTLY TO CARDIAC DISEASE DEVELOPMENT. CARDIAC MACROPHAGES NOT ONLY TRIGGER DAMAGING INFLAMMATORY RESPONSES DURING ATHEROSCLEROTIC PLAQUE FORMATION, MYOCARDIAL INJURY, AND HEART FAILURE BUT ARE ALSO INVOLVED IN TISSUE REPAIR, REMODELING, AND REGENERATION. IN THIS REVIEW, WE SUMMARIZE THE KEY EPIGENETIC MODIFICATIONS THAT INFLUENCE MACROPHAGE POLARIZATION AND CONTRIBUTE TO THE PATHOPHYSIOLOGY OF CVDS, AND HIGHLIGHT THEIR POTENTIAL FOR THE DEVELOPMENT OF ADVANCED EPIGENETIC THERAPIES. 2023 15 3326 32 HISTONE DEACETYLASE 3 (HDAC3) AS AN IMPORTANT EPIGENETIC REGULATOR OF KIDNEY DISEASES. DEVELOPMENT AND PROGRESSION OF MANY KIDNEY DISEASES ARE SUBSTANTIALLY INFLUENCED BY ABERRANT PROTEIN ACETYLATION MODIFICATIONS OF GENE EXPRESSION CRUCIAL FOR KIDNEY FUNCTIONS. HISTONE DEACETYLASE (HDAC) EXPRESSION ALTERATIONS ARE DETECTED FROM RENAL SAMPLES OF PATIENTS AND ANIMAL MODELS OF VARIOUS KIDNEY DISEASES, AND THE ADMINISTRATIONS OF HDAC INHIBITORS DISPLAY IMPRESSIVE RENAL PROTECTIVE EFFECTS IN VITRO AND IN VIVO. HOWEVER, WHEN THE EXPRESSION ALTERATIONS OF MULTIPLE HDACS OCCUR, NOT ALL THE HDACS CAUSALLY AFFECT THE DISEASE ONSET OR PROGRESSION. IDENTIFICATION OF A SINGLE HDAC AS A DISEASE-CAUSING FACTOR WILL ALLOW SUBTYPE-TARGETED INTERVENTION WITH LESS SIDE EFFECT. HDAC3 IS A UNIQUE HDAC WITH DISTINCT STRUCTURAL AND SUBCELLULAR DISTRIBUTION FEATURES AND CO-REPRESSOR DEPENDENCY. HDAC3 IS REQUIRED FOR KIDNEY DEVELOPMENT AND ITS ABERRATIONS ACTIVELY PARTICIPATE IN MANY PATHOLOGICAL PROCESSES, SUCH AS CANCER, CARDIOVASCULAR DISEASES, DIABETES, AND NEURODEGENERATIVE DISORDERS, AND CONTRIBUTE SIGNIFICANTLY TO THE PATHOGENESIS OF KIDNEY DISEASES. THIS REVIEW WILL DISCUSS THE RECENT STUDIES THAT INVESTIGATE THE CRITICAL ROLES OF HDAC3 ABERRATIONS IN KIDNEY DEVELOPMENT, RENAL AGING, RENAL CELL CARCINOMA, RENAL FIBROSIS, CHRONIC KIDNEY DISEASE, POLYCYSTIC KIDNEY DISEASE, GLOMERULAR PODOCYTE INJURY, AND DIABETIC NEPHROPATHY. THESE STUDIES REVEAL THE DISTINCT CHARACTERS OF HDAC3 ABERRATIONS THAT ACT ON DIFFERENT MOLECULES/SIGNALING PATHWAYS UNDER VARIOUS RENAL PATHOLOGICAL CONDITIONS, WHICH MIGHT SHED LIGHTS INTO THE EPIGENETIC MECHANISMS OF RENAL DISEASES AND THE POTENTIALLY THERAPEUTIC STRATEGIES. 2022 16 2256 27 EPIGENETIC PATHWAYS IN MACROPHAGES EMERGE AS NOVEL TARGETS IN ATHEROSCLEROSIS. ATHEROSCLEROSIS IS A LIPID-DRIVEN CHRONIC INFLAMMATORY DISORDER. MONOCYTES AND MACROPHAGES ARE KEY IMMUNE CELLS IN THE DEVELOPMENT OF DISEASE AND CLINICAL OUTCOME. IT IS BECOMING INCREASINGLY CLEAR THAT EPIGENETIC PATHWAYS GOVERN MANY ASPECTS OF MONOCYTE AND MACROPHAGE DIFFERENTIATION AND ACTIVATION. THE DYNAMIC REGULATION OF EPIGENETIC PATTERNS PROVIDES OPPORTUNITIES TO ALTER DISEASE-ASSOCIATED EPIGENETIC STATES. THEREFORE, PHARMACEUTICAL COMPANIES HAVE EMBRACED THE TARGETING OF EPIGENETIC PROCESSES AS NEW APPROACHES FOR INTERVENTIONS. PARTICULARLY HISTONE DEACETYLASE (HDAC) INHIBITORS AND DNA-METHYLTRANSFERASE INHIBITORS HAVE LONG RECEIVED ATTENTION AND SEVERAL OF THEM HAVE BEEN APPROVED FOR CLINICAL USE IN RELATION TO HEMATOLOGICAL MALIGNANCIES. THE KEY FOCUS IS STILL ON ONCOLOGY, BUT ALZHEIMER'S DISEASE, HUNTINGTON'S DISEASE AND INFLAMMATORY DISORDERS ARE COMING IN FOCUS AS WELL. THESE DEVELOPMENTS RAISE OPPORTUNITIES FOR THE EPIGENETIC TARGETING IN CARDIOVASCULAR DISEASE (CVD). IN THIS REVIEW WE DISCUSS THE EPIGENETIC REGULATION OF THE INFLAMMATORY PATHWAYS IN RELATION TO ATHEROSCLEROSIS WITH A SPECIFIC ATTENTION TO MONOCYTE- AND MACROPHAGE-RELATED PROCESSES. WHAT ARE THE OPPORTUNITIES FOR FUTURE THERAPY OF ATHEROSCLEROSIS BY EPIGENETIC INTERVENTIONS? 2015 17 3640 22 INCREASED EXTRACELLULAR MATRIX PROTEIN PRODUCTION IN CHRONIC DIABETIC COMPLICATIONS: IMPLICATIONS OF NON-CODING RNAS. MANAGEMENT OF CHRONIC DIABETIC COMPLICATIONS REMAINS A MAJOR MEDICAL CHALLENGE WORLDWIDE. ONE OF THE CHARACTERISTIC FEATURES OF ALL CHRONIC DIABETIC COMPLICATIONS IS AUGMENTED PRODUCTION OF EXTRACELLULAR MATRIX (ECM) PROTEINS. SUCH ECM PROTEINS ARE DEPOSITED IN ALL TISSUES AFFECTED BY CHRONIC COMPLICATIONS, ULTIMATELY CAUSING ORGAN DAMAGE AND DYSFUNCTION. A CONTRIBUTING FACTOR TO THIS PATHOGENETIC PROCESS IS GLUCOSE-INDUCED ENDOTHELIAL DAMAGE, WHICH INVOLVES PHENOTYPIC TRANSFORMATION OF ENDOTHELIAL CELLS (ECS). THIS PHENOTYPIC TRANSITION OF ECS, FROM A QUIESCENT STATE TO AN ACTIVATED DYSFUNCTIONAL STATE, CAN BE MEDIATED THROUGH ALTERATIONS IN THE SYNTHESIS OF CELLULAR PROTEINS. IN THIS REVIEW, WE DISCUSSED THE ROLES OF NON-CODING RNAS, SPECIFICALLY MICRORNAS (MIRNAS) AND LONG NON-CODING RNAS (LNCRNAS), IN SUCH PROCESSES. WE FURTHER OUTLINED OTHER EPIGENETIC MECHANISMS REGULATING THE BIOGENESIS AND/OR FUNCTION OF NON-CODING RNAS. OVERALL, WE BELIEVE THAT BETTER UNDERSTANDING OF SUCH MOLECULAR PROCESSES MAY LEAD TO THE DEVELOPMENT OF NOVEL BIOMARKERS AND THERAPEUTIC STRATEGIES IN THE FUTURE. 2019 18 4336 23 MICRORNAS: THE UNDERLYING MEDIATORS OF PATHOGENETIC PROCESSES IN VASCULAR COMPLICATIONS OF DIABETES. DIABETES MELLITUS CAUSES CHRONIC COMPLICATIONS PRIMARILY AFFECTING THE VASCULATURE OF VARIOUS ORGANS, RISKING PATIENTS FOR RENAL FAILURE, VISION LOSS AND HEART FAILURE. A NEWLY DISCOVERED CLASS OF MOLECULES, MICRORNAS, MAY BE IMPORTANT IN THE GENESIS OF THESE PATHOLOGIC PROCESSES. MICRORNAS REGULATE GENE EXPRESSION AT THE POST-TRANSCRIPTIONAL LEVEL BY INHIBITING TARGET MESSENGER RNA TRANSLATION. IN DISEASE STATES, HOWEVER, THE EXPRESSION OF MICRORNAS OFTEN IS ALTERED, RESULTING IN FURTHER ALTERED EXPRESSION (MOSTLY OVEREXPRESSION) OF DOWNSTREAM TARGET GENES. INTERESTINGLY, RESTORING MICRORNA EXPRESSION TO NORMAL LEVELS CAN CORRECT DOWNSTREAM EFFECTS AND PREVENT DIABETES-ASSOCIATED CHANGES. INVESTIGATIONS INTO MICRORNA INVOLVED IN VARIOUS PATHOGENETIC PROCESSES MEDIATING DIABETIC NEPHROPATHY, RETINOPATHY AND CARDIOMYOPATHY ARE HIGHLIGHTED IN THIS REVIEW. FUTURE DIRECTIONS OF MICRORNA IN THERAPEUTICS AND DIAGNOSTICS ARE ALSO DISCUSSED. IT IS OUR INTENT TO HELP THE READER APPRECIATE THE DIVERSE INTERACTIONS MICRORNAS HAVE IN CELLULAR SIGNALLING AND HOW UNDERSTANDING EPIGENETIC ELEMENTS, SUCH AS MICRORNAS, POTENTIALLY CAN YIELD NEW THERAPEUTIC STRATEGIES. 2013 19 607 22 BEYOND GENETICS: EPIGENETIC CODE IN CHRONIC KIDNEY DISEASE. EPIGENETICS REFERS TO A HERITABLE CHANGE IN THE PATTERN OF GENE EXPRESSION THAT IS MEDIATED BY A MECHANISM SPECIFICALLY NOT DUE TO ALTERATIONS IN THE PRIMARY NUCLEOTIDE SEQUENCE. WELL-KNOWN EPIGENETIC MECHANISMS ENCOMPASS DNA METHYLATION, CHROMATIN REMODELING (HISTONE MODIFICATIONS), AND RNA INTERFERENCE. FUNCTIONALLY, EPIGENETICS PROVIDES AN EXTRA LAYER OF TRANSCRIPTIONAL CONTROL AND PLAYS A CRUCIAL ROLE IN NORMAL PHYSIOLOGICAL DEVELOPMENT, AS WELL AS IN PATHOLOGICAL CONDITIONS. ABERRANT DNA METHYLATION IS IMPLICATED IN IMMUNE DYSFUNCTION, INFLAMMATION, AND INSULIN RESISTANCE. EPIGENETIC CHANGES MAY BE RESPONSIBLE FOR 'METABOLIC MEMORY' AND DEVELOPMENT OF MICRO- AND MACROVASCULAR COMPLICATIONS OF DIABETES. MICRORNAS ARE CRITICAL IN THE MAINTENANCE OF GLOMERULAR HOMEOSTASIS AND HENCE RNA INTERFERENCE MAY BE IMPORTANT IN THE PROGRESSION OF RENAL DISEASE. RECENT STUDIES HAVE SHOWN THAT EPIGENETIC MODIFICATIONS ORCHESTRATE THE EPITHELIAL-MESENCHYMAL TRANSITION AND EVENTUALLY FIBROSIS OF THE RENAL TISSUE. OXIDATIVE STRESS, INFLAMMATION, HYPERHOMOCYSTEINEMIA, AND UREMIC TOXINS COULD INDUCE EPIMUTATIONS IN CHRONIC KIDNEY DISEASE. EPIGENETIC ALTERATIONS ARE ASSOCIATED WITH INFLAMMATION AND CARDIOVASCULAR DISEASE IN PATIENTS WITH CHRONIC KIDNEY DISEASE. REVERSIBLE NATURE OF THE EPIGENETIC CHANGES GIVES A UNIQUE OPPORTUNITY TO HALT OR EVEN REVERSE THE DISEASE PROCESS THROUGH TARGETED THERAPEUTIC STRATEGIES. 2011 20 1383 28 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