1 2486 133 EPIGENETIC-SENSITIVE CHALLENGES OF CARDIOHEPATIC INTERACTIONS: CLINICAL AND THERAPEUTIC IMPLICATIONS IN HEART FAILURE PATIENTS. HEART FAILURE AND LIVER DYSFUNCTION CAN COEXIST OWING TO COMPLEX CARDIOHEPATIC INTERACTIONS INCLUDING THE DEVELOPMENT OF HYPOXIC HEPATITIS AND CONGESTIVE HEPATOPATHY IN PATIENTS WITH HEART FAILURE AS WELL AS 'CIRRHOTIC CARDIOMYOPATHY' IN ADVANCED LIVER DISEASE AND FOLLOWING LIVER TRANSPLANTATION. THE INVOLVEMENT OF LIVER DYSFUNCTION IN PATIENTS WITH HEART FAILURE REFLECTS CRUCIAL SYSTEMIC HEMODYNAMIC MODIFICATIONS OCCURRING DURING THE EVOLUTION OF THIS SYNDROME. THE ARTERIAL HYPOPERFUSION AND DOWNSTREAM HYPOXIA CAN LEAD TO HYPOXIC HEPATITIS IN ACUTE HEART FAILURE PATIENTS WHEREAS PASSIVE CONGESTION IS CORRELATED WITH CONGESTIVE HEPATOPATHY OCCURRING IN PATIENTS WITH CHRONIC HEART FAILURE. NOWADAYS, LIQUID BIOPSY STRATEGIES MEASURING LIVER FUNCTION ARE WELL ESTABLISHED IN EVALUATING THE PROGNOSIS OF PATIENTS WITH HEART FAILURE. LARGE RANDOMIZED CLINICAL TRIALS CONFIRMED THAT GAMMA-GLUTAMYLTRANSFERASE, BILIRUBIN, LACTATE DEIHYDROGENASE, AND TRANSAMINASES ARE USEFUL PROGNOSTIC BIOMARKERS IN PATIENTS WITH HEART FAILURE AFTER TRANSPLANTATION. DEEPER KNOWLEDGE ABOUT THE PATHOGENIC MECHANISMS UNDERLYING CARDIOHEPATIC INTERACTIONS WOULD BE USEFUL TO IMPROVE DIAGNOSIS, PROGNOSIS, AND TREATMENTS OF THESE COMORBID PATIENTS. EPIGENETIC-SENSITIVE MODIFICATIONS ARE HERITABLE CHANGES TO GENE EXPRESSION WITHOUT INVOLVING DNA SEQUENCE, COMPRISING DNA METHYLATION, HISTONE MODIFICATIONS, AND NONCODING RNAS WHICH SEEM TO BE RELEVANT IN THE PATHOGENESIS OF HEART FAILURE AND LIVER DISEASES WHEN CONSIDERED IN A SEPARATE WAY. THE GOAL OF OUR REVIEW IS TO HIGHLIGHT THE PERTINENCE OF DETECTING EPIGENETIC MODIFICATIONS DURING THE COMPLEX CARDIOHEPATIC INTERACTIONS IN CLINICAL SETTING. MOREOVER, WE PROPOSE A CLINICAL RESEARCH PROGRAM WHICH MAY BE USEFUL TO IDENTIFY EPIGENETIC-SENSITIVE BIOMARKERS OF CARDIOHEPATIC INTERACTIONS AND ADVANCE PERSONALIZED THERAPY IN THESE COMORBID PATIENTS. 2021 2 5572 25 ROLE OF MICRORNA IN DIABETIC CARDIOMYOPATHY: FROM MECHANISM TO INTERVENTION. DIABETIC CARDIOMYOPATHY IS A CHRONIC AND IRREVERSIBLE HEART COMPLICATION IN DIABETIC PATIENTS, AND IS CHARACTERIZED BY COMPLEX PATHOPHYSIOLOGIC EVENTS INCLUDING EARLY DIASTOLIC DYSFUNCTION, CARDIAC HYPERTROPHY, VENTRICULAR DILATION AND SYSTOLIC DYSFUNCTION, EVENTUALLY RESULTING IN HEART FAILURE. DESPITE THESE CHARACTERISTICS, THE UNDERLYING MECHANISMS LEADING TO DIABETIC CARDIOMYOPATHY ARE STILL ELUSIVE. RECENT STUDIES HAVE IMPLICATED MICRORNA, A SMALL AND HIGHLY CONSERVED NON-CODING RNA MOLECULE, IN THE ETIOLOGY OF DIABETES AND ITS COMPLICATIONS, SUGGESTING A POTENTIALLY NOVEL APPROACH FOR THE DIAGNOSIS AND TREATMENT OF DIABETIC CARDIOMYOPATHY. THIS BRIEF REVIEW AIMS AT CAPTURING RECENT STUDIES RELATED TO THE ROLE OF MICRORNA IN DIABETIC CARDIOMYOPATHY. THIS ARTICLE IS PART OF A SPECIAL ISSUE ENTITLED: GENETIC AND EPIGENETIC CONTROL OF HEART FAILURE - EDITED BY JUN REN & MEGAN YINGMEI ZHANG. 2017 3 2554 27 EPIGENETICS IN REACTIVE AND REPARATIVE CARDIAC FIBROGENESIS: THE PROMISE OF EPIGENETIC THERAPY. EPIGENETIC CHANGES PLAY A PIVOTAL ROLE IN THE DEVELOPMENT OF A WIDE SPECTRUM OF HUMAN DISEASES INCLUDING CARDIOVASCULAR DISEASES, CANCER, DIABETES, AND INTELLECTUAL DISABILITIES. CARDIAC FIBROGENESIS IS A COMMON PATHOPHYSIOLOGICAL PROCESS SEEN DURING CHRONIC AND STRESS-INDUCED ACCELERATED CARDIAC AGING. WHILE ADEQUATE PRODUCTION OF EXTRACELLULAR MATRIX (ECM) PROTEINS IS NECESSARY FOR POST-INJURY WOUND HEALING, EXCESSIVE SYNTHESIS AND ACCUMULATION OF EXTRACELLULAR MATRIX PROTEIN IN THE STRESSED OR INJURED HEARTS CAUSES DECREASED OR LOSS OF LUSITROPY THAT LEADS TO CARDIAC FAILURE. THIS SELF-PERPETUATING DEPOSITION OF COLLAGEN AND OTHER MATRIX PROTEINS EVENTUALLY ALTER CELLULAR HOMEOSTASIS; IMPAIR TISSUE ELASTICITY AND LEADS TO MULTI-ORGAN FAILURE, AS SEEN DURING PATHOGENESIS OF CARDIOVASCULAR DISEASES, CHRONIC KIDNEY DISEASES, CIRRHOSIS, IDIOPATHIC PULMONARY FIBROSIS, AND SCLERODERMA. IN THE LAST 25 YEARS, MULTIPLE STUDIES HAVE INVESTIGATED THE MOLECULAR BASIS OF ORGAN FIBROSIS AND HIGHLIGHTED ITS MULTI-FACTORIAL GENETIC, EPIGENETIC, AND ENVIRONMENTAL REGULATION. IN THIS MINIREVIEW, WE FOCUS ON FIVE MAJOR EPIGENETIC REGULATORS AND DISCUSS THEIR CENTRAL ROLE IN CARDIAC FIBROGENESIS. ADDITIONALLY, WE COMPARE AND CONTRAST THE EPIGENETIC REGULATION OF HYPERTENSION-INDUCED REACTIVE FIBROGENESIS AND MYOCARDIAL INFARCTION-INDUCED REPARATIVE OR REPLACEMENT CARDIAC FIBROGENESIS. AS MICRORNAS-ONE OF THE MAJOR EPIGENETIC REGULATORS-CIRCULATE IN PLASMA, WE ALSO ADVOCATE THEIR POTENTIAL DIAGNOSTIC ROLE IN CARDIAC FIBROSIS. LASTLY, WE DISCUSS THE EVOLUTION OF NOVEL EPIGENETIC-REGULATING DRUGS AND PREDICT THEIR CLINICAL ROLE IN THE SUPPRESSION OF PATHOLOGICAL CARDIAC REMODELING, CARDIAC AGING, AND HEART FAILURE. J. CELL. PHYSIOL. 232: 1941-1956, 2017. (C) 2016 WILEY PERIODICALS, INC. 2017 4 246 41 ADULT STEM CELL THERAPY FOR CARDIAC REPAIR IN PATIENTS AFTER ACUTE MYOCARDIAL INFARCTION LEADING TO ISCHEMIC HEART FAILURE: AN OVERVIEW OF EVIDENCE FROM THE RECENT CLINICAL TRIALS. BACKGROUND: CARDIOVASCULAR DISEASES (CVD) STILL REPRESENT THE LEADING CAUSE OF MORTALITY WORLDWIDE, DESPITE THE REMARKABLE ADVANCES IN INTERVENTIONAL CARDIOLOGY, CARDIAC SURGERY, AND MODERN PHARMACOTHERAPY, PARTICULARLY IN THE SETTING OF ACUTE MYOCARDIAL INFARCTION (AMI), CHRONIC ISCHEMIC HEART FAILURE (HF), CARDIOMYOPATHY (CM), AND THE ASSOCIATED LEFT VENTRICULAR (LV) DYSFUNCTION. A SIGNIFICANT LOSS OF CARDIOMYOCYTES THAT UNDERLIES ALL OF THESE CONDITIONS WAS PREVIOUSLY CONSIDERED IRREVERSIBLE. HOWEVER, CURRENT EVIDENCE INDICATES THAT THE HUMAN HEART HAS SOME POTENTIAL FOR REPAIR, AND OVER THE PAST DECADE, MANY RESEARCH STUDIES HAVE BEEN EXPLORING THE USE OF STEM CELLS (SCS) TO FACILITATE RESTORATION OF MYOCARDIUM. CONSEQUENTLY, THE SAFETY, FEASIBILITY, AND EFFECTIVENESS OF SC THERAPY HAVE BEEN REPORTED IN MANY RANDOMIZED CLINICAL TRIALS (RCTS), USING DIFFERENT LINEAGES OF ADULT SCS. NEVERTHELESS, THE CLINICAL BENEFITS OF SC THERAPY ARE NOT YET WELL ESTABLISHED. IN THE NEAR FUTURE, UNDERSTANDING OF THE COMPLEX INTERRELATIONS BETWEEN SCS, PARACRINE FACTORS, GENETIC OR EPIGENETIC PREDISPOSITIONS, AND MYOCARDIAL MICROENVIRONMENT, IN THE CONTEXT OF AN INDIVIDUAL PATIENT, WILL BE CRUCIAL FOR TRANSLATION OF THIS KNOWLEDGE INTO PRACTICAL DEVELOPMENT OF SUCCESSFUL, LONG-TERM REGENERATIVE SC THERAPEUTIC APPLICATIONS, IN A GROWING POPULATION OF PATIENTS SUFFERING FROM PREVIOUS MYOCARDIAL INFARCTION (MI) LEADING TO CHRONIC ISCHEMIC CARDIOMYOPATHY. CONCLUSION: THIS OVERVIEW HIGHLIGHTS THE THERAPEUTIC POTENTIAL OF ADULT SCS IN TERMS OF THEIR POSSIBLE REGENERATIVE CAPACITY, SAFETY, AND CLINICAL OUTCOMES, IN PATIENTS WITH AMI, AND/OR SUBSEQUENT HF (DUE TO CHRONIC ISCHEMIC CARDIOMYOPATHY). THIS REVIEW WAS BASED UPON PUBMED DATABASE SEARCH FOR TRIALS ON SC THERAPY, IN PATIENTS WITH AMI AND HF, AND THE MAIN TIMEFRAME WAS SET FROM 2006 TO 2016. 2017 5 2537 28 EPIGENETICS IN HEART FAILURE PHENOTYPES. CHRONIC HEART FAILURE (HF) IS A LEADING CLINICAL AND PUBLIC PROBLEM POSING A HIGHER RISK OF MORBIDITY AND MORTALITY IN DIFFERENT POPULATIONS. HF APPEARS TO BE IN BOTH PHENOTYPIC FORMS: HF WITH REDUCED LEFT VENTRICULAR EJECTION FRACTION (HFREF) AND HF WITH PRESERVED LEFT VENTRICULAR EJECTION FRACTION (HFPEF). ALTHOUGH BOTH HF PHENOTYPES CAN BE DISTINGUISHED THROUGH CLINICAL FEATURES, CO-MORBIDITY STATUS, PREDICTION SCORE, AND TREATMENT, THE CLINICAL OUTCOMES IN PATIENTS WITH HFREF AND HFPEF ARE SIMILAR. IN THIS CONTEXT, INVESTIGATION OF VARIOUS MOLECULAR AND CELLULAR MECHANISMS LEADING TO THE DEVELOPMENT AND PROGRESSION OF BOTH HF PHENOTYPES IS VERY IMPORTANT. THERE IS EMERGING EVIDENCE THAT EPIGENETIC REGULATION MAY HAVE A CLUE IN THE PATHOGENESIS OF HF. THIS REVIEW REPRESENTS CURRENT AVAILABLE EVIDENCE REGARDING THE IMPLICATION OF EPIGENETIC MODIFICATIONS IN THE DEVELOPMENT OF DIFFERENT HF PHENOTYPES AND PERSPECTIVES OF EPIGENETIC-BASED THERAPIES OF HF. 2016 6 4191 35 METABOLIC LANDSCAPE IN CARDIAC AGING: INSIGHTS INTO MOLECULAR BIOLOGY AND THERAPEUTIC IMPLICATIONS. CARDIAC AGING IS EVIDENT BY A REDUCTION IN FUNCTION WHICH SUBSEQUENTLY CONTRIBUTES TO HEART FAILURE. THE METABOLIC MICROENVIRONMENT HAS BEEN IDENTIFIED AS A HALLMARK OF MALIGNANCY, BUT RECENT STUDIES HAVE SHED LIGHT ON ITS ROLE IN CARDIOVASCULAR DISEASES (CVDS). VARIOUS METABOLIC PATHWAYS IN CARDIOMYOCYTES AND NONCARDIOMYOCYTES DETERMINE CELLULAR SENESCENCE IN THE AGING HEART. METABOLIC ALTERATION IS A COMMON PROCESS THROUGHOUT CARDIAC DEGENERATION. IMPORTANTLY, THE INVOLVEMENT OF CELLULAR SENESCENCE IN CARDIAC INJURIES, INCLUDING HEART FAILURE AND MYOCARDIAL ISCHEMIA AND INFARCTION, HAS BEEN REPORTED. HOWEVER, METABOLIC COMPLEXITY AMONG HUMAN AGING HEARTS HINDERS THE DEVELOPMENT OF STRATEGIES THAT TARGETS METABOLIC SUSCEPTIBILITY. ADVANCES OVER THE PAST DECADE HAVE LINKED CELLULAR SENESCENCE AND FUNCTION WITH THEIR METABOLIC REPROGRAMMING PATHWAY IN CARDIAC AGING, INCLUDING AUTOPHAGY, OXIDATIVE STRESS, EPIGENETIC MODIFICATIONS, CHRONIC INFLAMMATION, AND MYOCYTE SYSTOLIC PHENOTYPE REGULATION. IN ADDITION, METABOLIC STATUS IS INVOLVED IN CRUCIAL ASPECTS OF MYOCARDIAL BIOLOGY, FROM FIBROSIS TO HYPERTROPHY AND CHRONIC INFLAMMATION. HOWEVER, FURTHER ELUCIDATION OF THE METABOLISM INVOLVEMENT IN CARDIAC DEGENERATION IS STILL NEEDED. THUS, DECIPHERING THE MECHANISMS UNDERLYING HOW METABOLIC REPROGRAMMING IMPACTS CARDIAC AGING IS THOUGHT TO CONTRIBUTE TO THE NOVEL INTERVENTIONS TO PROTECT OR EVEN RESTORE CARDIAC FUNCTION IN AGING HEARTS. HERE, WE SUMMARIZE EMERGING CONCEPTS ABOUT METABOLIC LANDSCAPES OF CARDIAC AGING, WITH SPECIFIC FOCUSES ON WHY METABOLIC PROFILE ALTERS DURING CARDIAC DEGENERATION AND HOW WE COULD UTILIZE THE CURRENT KNOWLEDGE TO IMPROVE THE MANAGEMENT OF CARDIAC AGING. 2023 7 6413 20 THE STATE OF ART OF REGENERATIVE THERAPY IN CARDIOVASCULAR ISCHEMIC DISEASE: BIOLOGY, SIGNALING PATHWAYS, AND EPIGENETICS OF ENDOTHELIAL PROGENITOR CELLS. ISCHEMIC HEART DISEASE IS CURRENTLY A MAJOR CAUSE OF MORTALITY AND MORBIDITY WORLDWIDE. NEVERTHELESS, THE ACTUAL THERAPEUTIC SCENARIO DOES NOT TARGET MYOCARDIAL CELL REGENERATION AND CONSEQUENTLY, THE PROGRESSION TOWARD THE LATE STAGE OF CHRONIC HEART FAILURE IS COMMON. ENDOTHELIAL PROGENITOR CELLS (EPCS) ARE BONE MARROW-DERIVED STEM CELLS THAT CONTRIBUTE TO THE HOMEOSTASIS OF THE ENDOTHELIAL WALL IN ACUTE AND CHRONIC ISCHEMIC DISEASE. CALCIUM MODULATION AND OTHER MOLECULAR PATHWAYS (NOTCH, VEGFR, AND CXCR4) CONTRIBUTE TO EPC PROLIFERATION AND DIFFERENTIATION. THE PRESENT REVIEW PROVIDES A SUMMARY OF EPC BIOLOGY WITH A PARTICULAR FOCUS ON THE REGULATORY PATHWAYS OF EPCS AND DESCRIBES PROMISING APPLICATIONS FOR CARDIOVASCULAR CELL THERAPY. 2020 8 750 26 CARDIAC INVOLVEMENT IN PATIENTS WITH HEMATOLOGIC MALIGNANCIES. AUTHORS HAVE REVIEWED LITERATURE ABOUT THE MANAGEMENT OF PATIENTS WITH CARDIOLOGIC DISEASE OCCURRING SECONDARY TO HEMATOLOGIC PATHOLOGY ITSELF OR ITS THERAPY, WITH A FOCUS ON INFILTRATION OF MYOCARDIUM IN ACUTE AND CHRONIC LEUKEMIA, LYMPHOMA, MULTIPLE MYELOMA, AND HYPEREOSINOPHILIC SYNDROME. MOREOVER, THEY EVALUATED CHEMOTHERAPY-ASSOCIATED TOXICITY, PARTICULARLY FOR NEW DRUGS SUCH AS MONOCLONAL ANTIBODY THERAPY, TYROSINE KINASE INHIBITORS, ARSENIC TRIOXIDE, BORTEZOMIB, AND EPIGENETIC THERAPY. IN FACT, CARDIAC TOXICITY MAY RANGE FROM ASYMPTOMATIC SUBCLINICAL ABNORMALITIES, SUCH AS ELECTROCARDIOGRAPHIC CHANGES AND LEFT VENTRICULAR EJECTION DECLINE, TO LIFE-THREATENING EVENTS AND LEAD TO CHEMOTHERAPY DOSE REDUCTION AND DELAY AND, IN SOME CASES, FOR PATIENTS WITH SEVERE SIDE EFFECTS, DISCONTINUATION OF TREATMENT. FINALLY, THEY DISCUSSED ON THE IDENTIFICATION OF EARLY MARKERS OF CARDIAC INJURY AND ON CARDIAC STEM CELL THERAPY AS A PROMISING APPROACH TO FACILITATE MYOCARDIAL REGENERATION. 2010 9 5988 26 TGF-BETA/SMAD AND RENAL FIBROSIS. RENAL FIBROSIS IS CHARACTERIZED BY EXCESSIVE DEPOSITION OF EXTRACELLULAR MATRIX (ECM) THAT DISRUPTS AND REPLACES FUNCTIONAL PARENCHYMA, WHICH LEADS TO ORGAN FAILURE. IT IS KNOWN AS THE MAJOR PATHOLOGICAL MECHANISM OF CHRONIC KIDNEY DISEASE (CKD). ALTHOUGH CKD HAS AN IMPACT ON NO LESS THAN 10% OF THE WORLD POPULATION, THERAPEUTIC OPTIONS ARE STILL LIMITED. REGARDLESS OF ETIOLOGY, ELEVATED TGF-BETA LEVELS ARE HIGHLY CORRELATED WITH THE ACTIVATED PRO-FIBROTIC PATHWAYS AND DISEASE PROGRESSION. TGF-BETA, THE KEY DRIVER OF RENAL FIBROSIS, IS INVOLVED IN A DYNAMIC PATHOPHYSIOLOGICAL PROCESS THAT LEADS TO CKD AND END-STAGE RENAL DISEASE (ESRD). IT IS BECOMING CLEAR THAT EPIGENETICS REGULATES RENAL PROGRAMMING, AND THEREFORE, THE DEVELOPMENT AND PROGRESSION OF RENAL DISEASE. INDEED, RECENT EVIDENCE SHOWS TGF-BETA1/SMAD SIGNALING REGULATES RENAL FIBROSIS VIA EPIGENETIC-CORRELATED MECHANISMS. THIS REVIEW FOCUSES ON THE FUNCTION OF TGF-BETA/SMADS IN RENAL FIBROGENESIS, AND THE ROLE OF EPIGENETICS AS A REGULATOR OF PRO-FIBROTIC GENE EXPRESSION. 2019 10 3064 36 GENOME-WIDE DNA METHYLATION ENCODES CARDIAC TRANSCRIPTIONAL REPROGRAMMING IN HUMAN ISCHEMIC HEART FAILURE. ISCHEMIC CARDIOMYOPATHY (ICM) IS THE CLINICAL ENDPOINT OF CORONARY HEART DISEASE AND A LEADING CAUSE OF HEART FAILURE. DESPITE GROWING DEMANDS TO DEVELOP PERSONALIZED APPROACHES TO TREAT ICM, PROGRESS IS LIMITED BY INADEQUATE KNOWLEDGE OF ITS PATHOGENESIS. SINCE EPIGENETICS HAS BEEN IMPLICATED IN THE DEVELOPMENT OF OTHER CHRONIC DISEASES, THE CURRENT STUDY WAS DESIGNED TO DETERMINE WHETHER TRANSCRIPTIONAL AND/OR EPIGENETIC CHANGES ARE SUFFICIENT TO DISTINGUISH ICM FROM OTHER ETIOLOGIES OF HEART FAILURE. SPECIFICALLY, WE HYPOTHESIZE THAT GENOME-WIDE DNA METHYLATION ENCODES TRANSCRIPTIONAL REPROGRAMMING IN ICM. RNA-SEQUENCING ANALYSIS WAS PERFORMED ON HUMAN ISCHEMIC LEFT VENTRICULAR TISSUE OBTAINED FROM PATIENTS WITH END-STAGE HEART FAILURE, WHICH ENRICHED KNOWN TARGETS OF THE POLYCOMB METHYLTRANSFERASE EZH2 COMPARED TO NON-ISCHEMIC HEARTS. COMBINED RNA SEQUENCING AND GENOME-WIDE DNA METHYLATION ANALYSIS REVEALED A ROBUST GENE EXPRESSION PATTERN CONSISTENT WITH SUPPRESSION OF OXIDATIVE METABOLISM, INDUCED ANAEROBIC GLYCOLYSIS, AND ALTERED CELLULAR REMODELING. LASTLY, KLF15 WAS IDENTIFIED AS A PUTATIVE UPSTREAM REGULATOR OF METABOLIC GENE EXPRESSION THAT WAS ITSELF REGULATED BY EZH2 IN A SET DOMAIN-DEPENDENT MANNER. OUR OBSERVATIONS THEREFORE DEFINE A NOVEL ROLE OF DNA METHYLATION IN THE METABOLIC REPROGRAMMING OF ICM. FURTHERMORE, WE IDENTIFY EZH2 AS AN EPIGENETIC REGULATOR OF KLF15 ALONG WITH DNA HYPERMETHYLATION, AND WE PROPOSE A NOVEL MECHANISM THROUGH WHICH CORONARY HEART DISEASE REPROGRAMS THE EXPRESSION OF BOTH INTERMEDIATE ENZYMES AND UPSTREAM REGULATORS OF CARDIAC METABOLISM SUCH AS KLF15. 2019 11 2356 33 EPIGENETIC REGULATION OF PULMONARY ARTERIAL HYPERTENSION-INDUCED VASCULAR AND RIGHT VENTRICULAR REMODELING: NEW OPPORTUNITIES? PULMONARY ARTERY HYPERTENSION (PAH) IS A RARE CHRONIC DISEASE WITH HIGH IMPACT ON PATIENTS' QUALITY OF LIFE AND CURRENTLY NO AVAILABLE CURE. PAH IS CHARACTERIZED BY CONSTANT REMODELING OF THE PULMONARY ARTERY BY INCREASED PROLIFERATION AND MIGRATION OF PULMONARY ARTERIAL SMOOTH MUSCLE CELLS (PASMCS), FIBROBLASTS (FBS) AND ENDOTHELIAL CELLS (ECS). THIS REMODELING EVENTUALLY LEADS TO INCREASED PRESSURE IN THE RIGHT VENTRICLE (RV) AND SUBSEQUENT RIGHT VENTRICLE HYPERTROPHY (RVH) WHICH, WHEN LEFT UNTREATED, PROGRESSES INTO RIGHT VENTRICLE FAILURE (RVF). PAH CAN NOT ONLY ORIGINATE FROM HERITABLE MUTATIONS, BUT ALSO DEVELOP AS A CONSEQUENCE OF CONGENITAL HEART DISEASE, EXPOSURE TO DRUGS OR TOXINS, HIV, CONNECTIVE TISSUE DISEASE OR BE IDIOPATHIC. WHILE MUCH ATTENTION WAS DRAWN INTO INVESTIGATING AND DEVELOPING THERAPIES RELATED TO THE MOST WELL UNDERSTOOD SIGNALING PATHWAYS IN PAH, IN THE LAST DECADE, A SHIFT TOWARDS UNDERSTANDING THE EPIGENETIC MECHANISMS DRIVING THE DISEASE OCCURRED. IN THIS REVIEW, WE REFLECT ON THE DIFFERENT EPIGENETIC REGULATORY FACTORS THAT ARE ASSOCIATED WITH THE PATHOLOGY OF RV REMODELING, AND ON THEIR RELEVANCE TOWARDS A BETTER UNDERSTANDING OF THE DISEASE AND SUBSEQUENTLY, THE DEVELOPMENT OF NEW AND MORE EFFICIENT THERAPEUTIC STRATEGIES. 2020 12 5363 22 RECENT ADVANCES IN DIABETIC KIDNEY DISEASES: FROM KIDNEY INJURY TO KIDNEY FIBROSIS. DIABETIC KIDNEY DISEASE (DKD) IS THE LEADING CAUSE OF CHRONIC KIDNEY DISEASE AND END-STAGE RENAL DISEASE. THE NATURAL HISTORY OF DKD INCLUDES GLOMERULAR HYPERFILTRATION, PROGRESSIVE ALBUMINURIA, DECLINING ESTIMATED GLOMERULAR FILTRATION RATE, AND, ULTIMATELY, KIDNEY FAILURE. IT IS KNOWN THAT DKD IS ASSOCIATED WITH METABOLIC CHANGES CAUSED BY HYPERGLYCEMIA, RESULTING IN GLOMERULAR HYPERTROPHY, GLOMERULOSCLEROSIS, AND TUBULOINTERSTITIAL INFLAMMATION AND FIBROSIS. HYPERGLYCEMIA IS ALSO KNOWN TO CAUSE PROGRAMMED EPIGENETIC MODIFICATION. HOWEVER, THE DETAILED MECHANISMS INVOLVED IN THE ONSET AND PROGRESSION OF DKD REMAIN ELUSIVE. IN THIS REVIEW, WE DISCUSS RECENT ADVANCES REGARDING THE PATHOGENIC MECHANISMS INVOLVED IN DKD. 2021 13 5068 34 PHYSICAL ACTIVITY AND PROGENITOR CELL-MEDIATED ENDOTHELIAL REPAIR IN CHRONIC HEART FAILURE: IS THERE A ROLE FOR EPIGENETICS? CHRONIC HEART FAILURE (CHF) IS THE MOST COMMON CARDIAC DISEASE AMONG THE ELDERLY AND A LEADING CAUSE OF MORTALITY IN ELDERLY PATIENTS. ENDOTHELIAL DYSFUNCTION IS HELD TO HAVE A MAJOR ROLE IN THE DEVELOPMENT AND PROGRESSION OF CHF, WHICH RESULTS IN PROGRESSIVELY IMPAIRED FUNCTIONAL CAPACITY. ENDOTHELIAL PROGENITOR CELLS (EPCS) AND CIRCULATING ANGIOGENIC CELLS (CACS) ARE THE MAIN PLAYERS INVOLVED IN THE ENDOGENOUS REPAIR MECHANISMS THAT CAN COUNTERACT ENDOTHELIAL DYSFUNCTION. A MOUNTING BODY OF DATA INDICATES THAT EXERCISE ENHANCES ENDOTHELIAL RENEWAL THROUGH MOBILIZATION OF BONE MARROW-DERIVED EPCS AND CACS, MAKING IT AN EFFECTIVE THERAPEUTIC TOOL FOR CHF. INTERESTINGLY, EMERGING EVIDENCE HAS BEEN SHOWING THAT EXERCISE TRAINING CAN ALSO PROMOTE EPIGENETIC MODIFICATIONS, E.G. DNA METHYLATION, HISTONE MODIFICATIONS, AND DIFFERENTIAL EXPRESSION OF SPECIFIC NON-CODING RNAS LIKE MICRORNA (MIRNAS). SINCE DEREGULATION OF THE MIRNAS INVOLVED IN ENDOTHELIAL FUNCTION MODULATION HAS WIDELY BEEN DOCUMENTED IN CIRCULATING CELLS AND PLASMA OF CHF PATIENTS, DEREGULATION OF EPIGENETIC FEATURES COULD PLAY A KEY ROLE IN DISEASE PROGRESSION. HERE, WE REVIEW CURRENT KNOWLEDGE OF THE CONTRIBUTION OF EPCS AND CACS TO ENDOTHELIAL REPAIR MECHANISMS IN CHF PATIENTS, FOCUSING ON THE EFFECTS INDUCED BY EXERCISE TRAINING AND HYPOTHESIZING THAT SOME OF THESE EFFECTS CAN BE MEDIATED BY EPIGENETIC MECHANISMS. 2016 14 6357 35 THE ROLE OF HYPERGLYCAEMIA IN THE DEVELOPMENT OF DIABETIC CARDIOMYOPATHY. DIABETES MELLITUS IS A METABOLIC DISORDER WITH A CHRONIC HYPERGLYCAEMIC STATE. CARDIOVASCULAR DISEASES ARE THE PRIMARY CAUSE OF MORTALITY IN PATIENTS WITH DIABETES. INCREASING EVIDENCE SUPPORTS THE EXISTENCE OF DIABETIC CARDIOMYOPATHY, A CARDIAC DYSFUNCTION WITH IMPAIRED CARDIAC CONTRACTION AND RELAXATION, INDEPENDENT OF CORONARY AND/OR VALVULAR COMPLICATIONS. DIABETIC CARDIOMYOPATHY CAN LEAD TO HEART FAILURE. SEVERAL PRECLINICAL AND CLINICAL STUDIES HAVE AIMED TO DECIPHER THE UNDERLYING MECHANISMS OF DIABETIC CARDIOMYOPATHY. AMONG ALL THE CO-FACTORS, HYPERGLYCAEMIA SEEMS TO PLAY AN IMPORTANT ROLE IN THIS PATHOLOGY. HYPERGLYCAEMIA HAS BEEN SHOWN TO ALTER CARDIAC METABOLISM AND FUNCTION THROUGH SEVERAL DELETERIOUS MECHANISMS, SUCH AS OXIDATIVE STRESS, INFLAMMATION, ACCUMULATION OF ADVANCED GLYCATED END-PRODUCTS AND UPREGULATION OF THE HEXOSAMINE BIOSYNTHESIS PATHWAY. THESE MECHANISMS ARE RESPONSIBLE FOR THE ACTIVATION OF HYPERTROPHIC PATHWAYS, EPIGENETIC MODIFICATIONS, MITOCHONDRIAL DYSFUNCTION, CELL APOPTOSIS, FIBROSIS AND CALCIUM MISHANDLING, LEADING TO CARDIAC STIFFNESS, AS WELL AS CONTRACTILE AND RELAXATION DYSFUNCTION. THIS REVIEW AIMS TO DESCRIBE THE HYPERGLYCAEMIC-INDUCED ALTERATIONS THAT PARTICIPATE IN DIABETIC CARDIOMYOPATHY, AND THEIR CORRELATION WITH THE SEVERITY OF THE DISEASE AND PATIENT MORTALITY, AND TO PROVIDE AN OVERVIEW OF CARDIAC OUTCOMES OF GLUCOSE-LOWERING THERAPY. 2021 15 5985 31 TET2-MEDIATED CLONAL HEMATOPOIESIS ACCELERATES HEART FAILURE THROUGH A MECHANISM INVOLVING THE IL-1BETA/NLRP3 INFLAMMASOME. BACKGROUND: RECENT STUDIES HAVE SHOWN THAT HEMATOPOIETIC STEM CELLS CAN UNDERGO CLONAL EXPANSION SECONDARY TO SOMATIC MUTATIONS IN LEUKEMIA-RELATED GENES, THUS LEADING TO AN AGE-DEPENDENT ACCUMULATION OF MUTANT LEUKOCYTES IN THE BLOOD. THIS SOMATIC MUTATION-RELATED CLONAL HEMATOPOIESIS IS COMMON IN HEALTHY OLDER INDIVIDUALS, BUT IT HAS BEEN ASSOCIATED WITH AN INCREASED INCIDENCE OF FUTURE CARDIOVASCULAR DISEASE. THE EPIGENETIC REGULATOR TET2 IS FREQUENTLY MUTATED IN BLOOD CELLS OF INDIVIDUALS EXHIBITING CLONAL HEMATOPOIESIS. OBJECTIVES: THIS STUDY INVESTIGATED WHETHER TET2 MUTATIONS WITHIN HEMATOPOIETIC CELLS CAN CONTRIBUTE TO HEART FAILURE IN 2 MODELS OF CARDIAC INJURY. METHODS: HEART FAILURE WAS INDUCED IN MICE BY PRESSURE OVERLOAD, ACHIEVED BY TRANSVERSE AORTIC CONSTRICTION OR CHRONIC ISCHEMIA INDUCED BY THE PERMANENT LIGATION OF THE LEFT ANTERIOR DESCENDING ARTERY. COMPETITIVE BONE MARROW TRANSPLANTATION STRATEGIES WITH TET2-DEFICIENT CELLS WERE USED TO MIMIC TET2 MUTATION-DRIVEN CLONAL HEMATOPOIESIS. ALTERNATIVELY, TET2 WAS SPECIFICALLY ABLATED IN MYELOID CELLS USING CRE RECOMBINASE EXPRESSED FROM THE LYSM PROMOTER. RESULTS: IN BOTH EXPERIMENTAL HEART FAILURE MODELS, HEMATOPOIETIC OR MYELOID TET2 DEFICIENCY WORSENED CARDIAC REMODELING AND FUNCTION, IN PARALLEL WITH INCREASED INTERLEUKIN-1BETA (IL-1BETA) EXPRESSION. TREATMENT WITH A SELECTIVE NLRP3 INFLAMMASOME INHIBITOR PROTECTED AGAINST THE DEVELOPMENT OF HEART FAILURE AND ELIMINATED THE DIFFERENCES IN CARDIAC PARAMETERS BETWEEN TET2-DEFICIENT AND WILD-TYPE MICE. CONCLUSIONS: TET2 DEFICIENCY IN HEMATOPOIETIC CELLS IS ASSOCIATED WITH GREATER CARDIAC DYSFUNCTION IN MURINE MODELS OF HEART FAILURE AS A RESULT OF ELEVATED IL-1BETA SIGNALING. THESE DATA SUGGEST THAT INDIVIDUALS WITH TET2-MEDIATED CLONAL HEMATOPOIESIS MAY BE AT GREATER RISK OF DEVELOPING HEART FAILURE AND RESPOND BETTER TO IL-1BETA-NLRP3 INFLAMMASOME INHIBITION. 2018 16 465 39 ARE TARGETED THERAPIES FOR DIABETIC CARDIOMYOPATHY ON THE HORIZON? DIABETES INCREASES THE RISK OF HEART FAILURE APPROXIMATELY 2.5-FOLD, INDEPENDENT OF CORONARY ARTERY DISEASE AND OTHER COMORBIDITIES. THIS PROCESS, TERMED DIABETIC CARDIOMYOPATHY, IS CHARACTERIZED BY INITIAL IMPAIRMENT OF LEFT VENTRICULAR (LV) RELAXATION FOLLOWED BY LV CONTRACTILE DYSFUNCTION. POST-MORTEM EXAMINATION REVEALS THAT HUMAN DIASTOLIC DYSFUNCTION IS CLOSELY ASSOCIATED WITH LV DAMAGE, INCLUDING CARDIOMYOCYTE HYPERTROPHY, APOPTOSIS AND FIBROSIS, WITH IMPAIRED CORONARY MICROVASCULAR PERFUSION. THE PATHOPHYSIOLOGICAL MECHANISMS UNDERPINNING THE CHARACTERISTIC FEATURES OF DIABETIC CARDIOMYOPATHY REMAIN POORLY UNDERSTOOD, ALTHOUGH MULTIPLE FACTORS INCLUDING ALTERED LIPID METABOLISM, MITOCHONDRIAL DYSFUNCTION, OXIDATIVE STRESS, ENDOPLASMIC RETICULUM (ER) STRESS, INFLAMMATION, AS WELL AS EPIGENETIC CHANGES, ARE IMPLICATED. DESPITE A RECENT RISE IN RESEARCH INTERROGATING THESE MECHANISMS AND AN INCREASED UNDERSTANDING OF THE CLINICAL IMPORTANCE OF DIABETIC CARDIOMYOPATHY, THERE REMAINS A LACK OF SPECIFIC TREATMENT STRATEGIES. HOW THE CHRONIC METABOLIC DISTURBANCES OBSERVED IN DIABETES LEAD TO STRUCTURAL AND FUNCTIONAL CHANGES REMAINS A PERTINENT QUESTION, AND IT IS HOPED THAT RECENT ADVANCES, PARTICULARLY IN THE AREA OF EPIGENETICS, AMONG OTHERS, MAY PROVIDE SOME ANSWERS. THIS REVIEW HENCE EXPLORES THE TEMPORAL ONSET OF THE PATHOLOGICAL FEATURES OF DIABETIC CARDIOMYOPATHY, AND THEIR RELATIVE CONTRIBUTION TO THE RESULTANT DISEASE PHENOTYPE, AS WELL AS BOTH CURRENT AND POTENTIAL THERAPEUTIC OPTIONS. THE EMERGENCE OF GLUCOSE-OPTIMIZING AGENTS, NAMELY GLUCAGON-LIKE PEPTIDE-1 (GLP-1) AGONISTS AND SODIUM/GLUCOSE CO-TRANSPORTER (SGLT)2 INHIBITORS THAT CONFER BENEFITS ON CARDIOVASCULAR OUTCOMES, TOGETHER WITH NOVEL EXPERIMENTAL APPROACHES, HIGHLIGHT A NEW AND EXCITING ERA IN DIABETES RESEARCH, WHICH IS LIKELY TO RESULT IN MAJOR CLINICAL IMPACT. 2017 17 5950 29 TARGETING THE PROGRESSION OF CHRONIC KIDNEY DISEASE. CHRONIC KIDNEY DISEASE (CKD) IS A DEVASTATING CONDITION THAT IS REACHING EPIDEMIC LEVELS OWING TO THE INCREASING PREVALENCE OF DIABETES MELLITUS, HYPERTENSION AND OBESITY, AS WELL AS AGEING OF THE POPULATION. REGARDLESS OF THE UNDERLYING AETIOLOGY, CKD IS SLOWLY PROGRESSIVE AND LEADS TO IRREVERSIBLE NEPHRON LOSS, END-STAGE RENAL DISEASE AND/OR PREMATURE DEATH. FACTORS THAT CONTRIBUTE TO CKD PROGRESSION INCLUDE PARENCHYMAL CELL LOSS, CHRONIC INFLAMMATION, FIBROSIS AND REDUCED REGENERATIVE CAPACITY OF THE KIDNEY. CURRENT THERAPIES HAVE LIMITED EFFECTIVENESS AND ONLY DELAY DISEASE PROGRESSION, UNDERSCORING THE NEED TO DEVELOP NOVEL THERAPEUTIC APPROACHES TO EITHER STOP OR REVERSE PROGRESSION. PRECLINICAL STUDIES HAVE IDENTIFIED SEVERAL APPROACHES THAT REDUCE FIBROSIS IN EXPERIMENTAL MODELS, INCLUDING TARGETING CYTOKINES, TRANSCRIPTION FACTORS, DEVELOPMENTAL AND SIGNALLING PATHWAYS AND EPIGENETIC MODULATORS, PARTICULARLY MICRORNAS. SOME OF THESE NEPHROPROTECTIVE STRATEGIES ARE NOW BEING TESTED IN CLINICAL TRIALS. LESSONS LEARNED FROM THE FAILURE OF CLINICAL STUDIES OF TRANSFORMING GROWTH FACTOR BETA1 (TGFBETA1) BLOCKADE UNDERSCORE THE NEED FOR ALTERNATIVE APPROACHES TO CKD THERAPY, AS STRATEGIES THAT TARGET A SINGLE PATHOGENIC PROCESS MAY RESULT IN UNEXPECTED NEGATIVE EFFECTS ON SIMULTANEOUSLY OCCURRING PROCESSES. ADDITIONAL PROMISING AVENUES INCLUDE PREVENTING TUBULAR CELL INJURY AND ANTI-FIBROTIC THERAPIES THAT TARGET ACTIVATED MYOFIBROBLASTS, THE MAIN COLLAGEN-PRODUCING CELLS. 2020 18 5576 30 ROLE OF MICRORNAS IN THE PATHOGENESIS OF DIABETIC CARDIOMYOPATHY. THE MORBIDITY OF DIABETES MELLITUS HAS BEEN INCREASING ANNUALLY. AS A PROGRESSIVE METABOLIC DISORDER, CHRONIC COMPLICATIONS OCCUR IN THE LATE STAGE OF DIABETES. IN ADDITION, CARDIOVASCULAR DISEASES ACCOUNT FOR THE MAJOR CAUSE OF MORBIDITY AND MORTALITY AMONG THE DIABETIC POPULATION WORLDWIDE. DIABETIC CARDIOMYOPATHY (DCM) IS A TYPE OF DIABETIC HEART DISEASE. PATIENTS WITH DCM SHOW SYMPTOMS AND SIGNS OF HEART FAILURE WHILE NO SPECIFIC CAUSE, SUCH AS CORONARY DISEASE, HYPERTENSION, ALCOHOL CONSUMPTION, OR OTHER STRUCTURAL HEART DISEASES HAS BEEN IDENTIFIED. THE PATHOGENESIS OF DCM IS COMPLEX AND HAS NOT BEEN WELL UNDERSTOOD UNTIL RECENTLY. MICRORNAS (MIRS) BELONG TO A NOVEL FAMILY OF HIGHLY CONSERVED, SHORT, NON-CODING, SINGLE-STRANDED RNA MOLECULES THAT REGULATE TRANSCRIPTIONAL AND POST-TRANSCRIPTIONAL GENE EXPRESSION. FURTHERMORE, RECENT STUDIES HAVE DEMONSTRATED AN ASSOCIATION BETWEEN MIRS AND DCM. IN THE CURRENT REVIEW, THE ROLE OF MIRS IN THE PATHOGENESIS OF DCM IS SUMMARIZED. IT WAS CONCLUDED THAT MIRS CONTRIBUTE TO THE REGULATION OF CARDIOMYOCYTE HYPERTROPHY, MYOCARDIAL FIBROSIS, CARDIOMYOCYTE APOPTOSIS, MITOCHONDRIAL DYSFUNCTION, MYOCARDIAL ELECTRICAL REMODELING, EPIGENETIC MODIFICATION AND VARIOUS OTHER PATHOPHYSIOLOGICAL PROCESSES OF DCM. THESE STUDIES MAY PROVIDE NOVEL INSIGHTS INTO TARGETS FOR PREVENTION AND TREATMENT OF THE DISEASE. 2017 19 3856 30 ISCHAEMIA REPERFUSION INJURY: MECHANISMS OF PROGRESSION TO CHRONIC GRAFT DYSFUNCTION. THE INCREASING USE OF EXTENDED CRITERIA ORGANS TO MEET THE DEMAND FOR KIDNEY TRANSPLANTATION RAISES AN IMPORTANT QUESTION OF HOW THE SEVERITY OF EARLY ISCHAEMIC INJURY INFLUENCES LONG-TERM OUTCOMES. SIGNIFICANT ACUTE ISCHAEMIC KIDNEY INJURY IS ASSOCIATED WITH DELAYED GRAFT FUNCTION, INCREASED IMMUNE-ASSOCIATED EVENTS AND, ULTIMATELY, EARLIER DETERIORATION OF GRAFT FUNCTION. A COMPREHENSIVE UNDERSTANDING OF IMMEDIATE MOLECULAR EVENTS THAT ENSUE POST-ISCHAEMIA AND THEIR POTENTIAL LONG-TERM CONSEQUENCES ARE KEY TO THE DISCOVERY OF NOVEL THERAPEUTIC TARGETS. ACUTE ISCHAEMIC INJURY PRIMARILY AFFECTS TUBULAR STRUCTURE AND FUNCTION. DEPENDING ON THE SEVERITY AND PERSISTENCE OF THE INSULT, THIS MAY RESOLVE COMPLETELY, LEADING TO RESTORATION OF NORMAL FUNCTION, OR BE SUSTAINED, RESULTING IN PERSISTENT RENAL IMPAIRMENT AND PROGRESSIVE FUNCTIONAL LOSS. LONG-TERM EFFECTS OF ACUTE RENAL ISCHAEMIA ARE MEDIATED BY SEVERAL MECHANISMS INCLUDING HYPOXIA, HIF-1 ACTIVATION, ENDOTHELIAL DYSFUNCTION LEADING TO VASCULAR RAREFACTION, SUSTAINED PRO-INFLAMMATORY STIMULI INVOLVING INNATE AND ADAPTIVE IMMUNE RESPONSES, FAILURE OF TUBULAR CELLS TO RECOVER AND EPIGENETIC CHANGES. THIS REVIEW DESCRIBES THE BIOLOGICAL RELEVANCE AND INTERACTION OF THESE MECHANISMS BASED ON CURRENTLY AVAILABLE EVIDENCE. 2019 20 2314 37 EPIGENETIC REGULATION OF ENDOTHELIAL-TO-MESENCHYMAL TRANSITION IN CHRONIC HEART DISEASE. ENDOTHELIAL-TO-MESENCHYMAL TRANSITION (ENDMT) IS A PROCESS IN WHICH ENDOTHELIAL CELLS LOSE THEIR PROPERTIES AND TRANSFORM INTO FIBROBLAST-LIKE CELLS. THIS TRANSITION PROCESS CONTRIBUTES TO CARDIAC FIBROSIS, A COMMON FEATURE OF PATIENTS WITH CHRONIC HEART FAILURE. TO DATE, NO SPECIFIC THERAPIES TO HALT OR REVERSE CARDIAC FIBROSIS ARE AVAILABLE, SO KNOWLEDGE OF THE UNDERLYING MECHANISMS OF CARDIAC FIBROSIS IS URGENTLY NEEDED. IN ADDITION, ENDMT CONTRIBUTES TO OTHER CARDIOVASCULAR PATHOLOGIES SUCH AS ATHEROSCLEROSIS AND PULMONARY HYPERTENSION, BUT ALSO TO CANCER AND ORGAN FIBROSIS. REMARKABLY, THE MOLECULAR MECHANISMS DRIVING ENDMT ARE LARGELY UNKNOWN. EPIGENETICS PLAY AN IMPORTANT ROLE IN REGULATING GENE TRANSCRIPTION AND TRANSLATION AND HAVE BEEN IMPLICATED IN THE ENDMT PROCESS. THEREFORE, EPIGENETICS MIGHT BE THE MISSING LINK IN UNRAVELING THE UNDERLYING MECHANISMS OF ENDMT. HERE, WE REVIEW THE INVOLVEMENT OF EPIGENETIC REGULATORS DURING ENDMT IN THE CONTEXT OF CARDIAC FIBROSIS. THE ROLE OF DNA METHYLATION, HISTONE MODIFICATIONS (ACETYLATION AND METHYLATION), AND NONCODING RNAS (MICRORNAS, LONG NONCODING RNAS, AND CIRCULAR RNAS) IN THE FACILITATION AND INHIBITION OF ENDMT ARE DISCUSSED, AND POTENTIAL THERAPEUTIC EPIGENETIC TARGETS WILL BE HIGHLIGHTED. 2018