1 4763 80 NRF2-RELATED EPIGENETIC MODIFICATIONS IN CARDIAC AND VASCULAR COMPLICATIONS OF DIABETES MELLITUS. DIABETES MELLITUS (DM) IS A HIGHLY PREVALENT CHRONIC DISEASE THAT IS ACCOMPANIED WITH SERIOUS COMPLICATIONS, ESPECIALLY CARDIAC AND VASCULAR COMPLICATIONS. THUS, THERE IS AN URGENT NEED TO IDENTIFY NEW STRATEGIES TO TREAT DIABETIC CARDIAC AND VASCULAR COMPLICATIONS. NUCLEAR FACTOR ERYTHROID 2-RELATED FACTOR 2 (NRF2) HAS BEEN VERIFIED AS A CRUCIAL TARGET FOR THE PREVENTION AND TREATMENT OF DIABETIC COMPLICATIONS. THE FUNCTION OF NRF2 IN THE TREATMENT OF DIABETIC COMPLICATIONS HAS BEEN WIDELY REPORTED, BUT THE ROLE OF NRF2-RELATED EPIGENETIC MODIFICATIONS REMAINS UNCLEAR. THE PURPOSE OF THIS REVIEW IS TO SUMMARIZE THE RECENT ADVANCES IN TARGETING NRF2-RELATED EPIGENETIC MODIFICATIONS IN THE TREATMENT OF CARDIAC AND VASCULAR COMPLICATIONS ASSOCIATED WITH DM. WE ALSO DISCUSS AGONISTS THAT COULD POTENTIALLY REGULATE NRF2-ASSOCIATED EPIGENETIC MECHANISMS. THIS REVIEW PROVIDES A BETTER UNDERSTANDING OF STRATEGIES TO TARGET NRF2 TO PROTECT AGAINST DM-RELATED CARDIAC AND VASCULAR COMPLICATIONS. 2021 2 4336 26 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 3 4719 26 NONCODING RNA AND EPIGENETIC GENE REGULATION IN RENAL DISEASES. KIDNEYS HAVE A MAJOR ROLE IN NORMAL PHYSIOLOGY AND METABOLIC HOMEOSTASIS. LOSS OR IMPAIRMENT OF KIDNEY FUNCTION IS A COMMON OCCURRENCE IN SEVERAL METABOLIC DISORDERS, INCLUDING HYPERTENSION AND DIABETES. CHRONIC KIDNEY DISEASE (CKD) AFFECT NEARLY 10% OF THE POPULATION WORLDWIDE; RANKS 18TH IN THE LIST OF CAUSES OF DEATH; AND CONTRIBUTES TO A SIGNIFICANT PROPORTION OF HEALTHCARE COSTS. THE TISSUE REPAIR AND REGENERATIVE POTENTIAL OF KIDNEYS ARE LIMITED AND THEY DECLINE DURING AGING. RECENT STUDIES HAVE DEMONSTRATED A KEY ROLE FOR EPIGENETIC PROCESSES AND PLAYERS, SUCH AS DNA METHYLATION, HISTONE MODIFICATIONS, NONCODING (NC)RNA, AND SO ON, IN BOTH KIDNEY DEVELOPMENT AND DISEASE. IN THIS REVIEW, WE HIGHLIGHT THESE RECENT FINDINGS WITH AN EMPHASIS ON ABERRANT EPIGENETIC CHANGES THAT ACCOMPANY RENAL DISEASES, KEY TARGETS, AND THEIR THERAPEUTIC VALUE. 2017 4 6200 35 THE INFLAMMATORY EFFECT OF EPIGENETIC FACTORS AND MODIFICATIONS IN TYPE 2 DIABETES. INFLAMMATION HAS A CENTRAL ROLE IN THE ETIOLOGY OF TYPE 2 DIABETES (T2D) AND ITS COMPLICATIONS. BOTH GENETIC AND EPIGENETIC FACTORS HAVE BEEN IMPLICATED IN THE DEVELOPMENT OF T2D-ASSOCIATED INFLAMMATION. EPIGENETIC MECHANISMS REGULATE THE FUNCTION OF SEVERAL COMPONENTS OF THE IMMUNE SYSTEM. DIABETIC CONDITIONS TRIGGER ABERRANT EPIGENETIC ALTERATIONS THAT CONTRIBUTE TO THE PROGRESSION OF INSULIN RESISTANCE AND BETA-CELL DYSFUNCTION BY INDUCTION OF INFLAMMATORY RESPONSES. THUS, TARGETING EPIGENETIC FACTORS AND MODIFICATIONS, AS ONE OF THE UNDERLYING CAUSES OF INFLAMMATION, COULD LEAD TO THE DEVELOPMENT OF NOVEL IMMUNE-BASED STRATEGIES FOR THE TREATMENT OF T2D. THE AIM OF THIS REVIEW IS TO PROVIDE AN OVERVIEW OF THE EPIGENETIC MECHANISMS INVOLVED IN THE PROPAGATION AND PERPETUATION OF CHRONIC INFLAMMATION IN T2D. WE ALSO DISCUSS THE POSSIBLE ANTI-INFLAMMATORY APPROACHES THAT TARGET EPIGENETIC FACTORS FOR THE TREATMENT OF T2D. 2020 5 6357 29 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 6 6103 33 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 7 125 26 A SYSTEMS BIOLOGY OVERVIEW ON HUMAN DIABETIC NEPHROPATHY: FROM GENETIC SUSCEPTIBILITY TO POST-TRANSCRIPTIONAL AND POST-TRANSLATIONAL MODIFICATIONS. DIABETIC NEPHROPATHY (DN), A MICROVASCULAR COMPLICATION OCCURRING IN APPROXIMATELY 20-40% OF PATIENTS WITH TYPE 2 DIABETES MELLITUS (T2DM), IS CHARACTERIZED BY THE PROGRESSIVE IMPAIRMENT OF GLOMERULAR FILTRATION AND THE DEVELOPMENT OF KIMMELSTIEL-WILSON LESIONS LEADING TO END-STAGE RENAL FAILURE (ESRD). THE CAUSES AND MOLECULAR MECHANISMS MEDIATING THE ONSET OF T2DM CHRONIC COMPLICATIONS ARE YET SKETCHY AND IT IS NOT CLEAR WHY DISEASE PROGRESSION OCCURS ONLY IN SOME PATIENTS. WE PERFORMED A SYSTEMATIC ANALYSIS OF THE MOST RELEVANT STUDIES INVESTIGATING GENETIC SUSCEPTIBILITY AND SPECIFIC TRANSCRIPTOMIC, EPIGENETIC, PROTEOMIC, AND METABOLOMIC PATTERNS IN ORDER TO SUMMARIZE THE MOST SIGNIFICANT TRAITS ASSOCIATED WITH THE DISEASE ONSET AND PROGRESSION. THE PICTURE THAT EMERGES IS COMPLEX AND FASCINATING AS IT INCLUDES THE REGULATION/DYSREGULATION OF NUMEROUS BIOLOGICAL PROCESSES, CONVERGING TOWARD THE ACTIVATION OF INFLAMMATORY PROCESSES, OXIDATIVE STRESS, REMODELING OF CELLULAR FUNCTION AND MORPHOLOGY, AND DISTURBANCE OF METABOLIC PATHWAYS. THE GROWING INTEREST IN THE CHARACTERIZATION OF PROTEIN POST-TRANSLATIONAL MODIFICATIONS AND THE IMPORTANCE OF HANDLING LARGE DATASETS USING A SYSTEMS BIOLOGY APPROACH ARE ALSO DISCUSSED. 2016 8 1505 30 DNA METHYLATION AND HISTONE MODIFICATION IN HYPERTENSION. SYSTEMIC HYPERTENSION, WHICH EVENTUALLY RESULTS IN HEART FAILURE, RENAL FAILURE OR STROKE, IS A COMMON CHRONIC HUMAN DISORDER THAT PARTICULARLY AFFECTS ELDERS. ALTHOUGH MANY SIGNALING PATHWAYS INVOLVED IN THE DEVELOPMENT OF HYPERTENSION HAVE BEEN REPORTED OVER THE PAST DECADES, WHICH HAS LED TO THE IMPLEMENTATION OF A WIDE VARIETY OF ANTI-HYPERTENSIVE THERAPIES, ONE HALF OF ALL HYPERTENSIVE PATIENTS STILL DO NOT HAVE THEIR BLOOD PRESSURE CONTROLLED. THE FRONTIER IN UNDERSTANDING THE MOLECULAR MECHANISMS UNDERLYING HYPERTENSION HAS NOW ADVANCED TO THE LEVEL OF EPIGENOMICS. PARTICULARLY, INCREASING EVIDENCE IS EMERGING THAT DNA METHYLATION AND HISTONE MODIFICATIONS PLAY AN IMPORTANT ROLE IN GENE REGULATION AND ARE INVOLVED IN ALTERATION OF THE PHENOTYPE AND FUNCTION OF VASCULAR CELLS IN RESPONSE TO ENVIRONMENTAL STRESSES. THIS REVIEW SEEKS TO HIGHLIGHT THE RECENT ADVANCES IN OUR KNOWLEDGE OF THE EPIGENETIC REGULATIONS AND MECHANISMS OF HYPERTENSION, FOCUSING ON THE ROLE OF DNA METHYLATION AND HISTONE MODIFICATION IN THE VASCULAR WALL. A BETTER UNDERSTANDING OF THE EPIGENOMIC REGULATION IN THE HYPERTENSIVE VESSEL MAY LEAD TO THE IDENTIFICATION OF NOVEL TARGET MOLECULES THAT, IN TURN, MAY LEAD TO NOVEL DRUG DISCOVERIES FOR THE TREATMENT OF HYPERTENSION. 2018 9 1487 24 DNA DAMAGE AND EPIGENETIC CHANGES IN KIDNEY DISEASES - FOCUSED ON TRANSCRIPTION FACTORS IN PODOCYTES. RECENTLY IT HAS BEEN SHOWN THAT EPIGENETIC MECHANISMS ARE INVOLVED IN INITIATION AND PROGRESSION OF CARIDIOVASCULAR AND METABOLIC DISEASES, INCLUDING DIABETES, OBESITY, ATHEROSCLEROSIS, HEART FAILURE, HYPERTENSION AND KIDNEY DISEASES. IN THESE CHRONIC DISEASES, VARIOUS EXOGENOUS AND ENDOGENOUS STRESSES CAUSE DNA DAMAGE, FOLLOWED BY DNA REPAIR PROCESS. ACCUMULATION OF DNA DAMAGES AND IMPAIRED REPAIR PROCESS CAN LEAD TO EPIGENETIC CHANGES, WHICH MAY CONTRIBUTE TO ONSET AND PROGRESSION OF DISEASES. RECENTLY WE HAVE SHOWN THAT THERAPEUTIC EFFECT OF TRANSCRIPTION FACTOR KLF4 (KRUPPEL-LIKE FACTOR 4) IN KIDNEY GLOMERULAR EPITHELIAL CELLS (PODOCYTES) ON PROTEINURIC KIDNEY DISEASES THROUGH EPIGENETIC MECHANISMS. OUR RESULT SUGGESTS THE POSSIBILITY OF TRANSCRIPTION FACTORS AS A TARGET OF SELECTIVE EPIGENETIC THERAPY. MOREOVER, WE HAVE REPORTED THAT RENIN-ANGIOTENSIN SYSTEM (RAS) BLOCKERS, WHICH ARE WIDELY PRESCRIBED FOR THE TREATMENT OF CARDIOVASCULAR DISEASES, CAN RESTORE EPIGENETIC CHANGES THROUGH KLF4 IN PART. THESE RESULTS SUGGEST THAT ACTIVATION OF RAS CAUSES EPIGENETIC CHANGES IN DISEASE STATES, AND ELUCIDATION OF THE PRECISE MECHANISM MAY LEAD TO ESTABLISHMENT OF NOVEL THERAPEUTIC TARGET OF KIDNEY DISEASES. IN THIS REVIEW WE FOCUS ON DNA DAMAGE REPAIR SYSTEM AND EPIGENETIC MODULATORS IN DISEASE STATES, AND SPECULATE A CANDIDATE FOR EPIGENETIC THERAPY OF KIDNEY DISEASES. 2016 10 6022 28 THE BENEFICIAL EFFECTS OF ZN ON AKT-MEDIATED INSULIN AND CELL SURVIVAL SIGNALING PATHWAYS IN DIABETES. ZINC IS ONE OF THE ESSENTIAL TRACE ELEMENTS AND PARTICIPATES IN NUMEROUS PHYSIOLOGICAL PROCESSES. ABNORMALITIES IN ZINC HOMEOSTASIS OFTEN RESULT IN THE PATHOGENESIS OF VARIOUS CHRONIC METABOLIC DISORDERS, SUCH AS DIABETES AND ITS COMPLICATIONS. ZINC HAS INSULIN-MIMETIC AND ANTI-DIABETIC EFFECTS AND DEFICIENCY HAS BEEN SHOWN TO AGGRAVATE DIABETES-INDUCED OXIDATIVE STRESS AND TISSUE INJURY IN DIABETIC RODENT MODELS AND HUMAN SUBJECTS WITH DIABETES. AKT SIGNALING PATHWAY PLAYS A CENTRAL ROLE IN INSULIN-STIMULATED GLUCOSE METABOLISM AND CELL SURVIVAL. ANTI-DIABETIC EFFECTS OF ZINC ARE LARGELY DEPENDENT ON THE ACTIVATION OF AKT SIGNALING. ZN IS ALSO AN INDUCER OF METALLOTHIONEIN THAT PLAYS IMPORTANT ROLE IN ANTI-OXIDATIVE STRESS AND DAMAGE. HOWEVER, THE EXACT MOLECULAR MECHANISMS UNDERLYING ZINC-INDUCED ACTIVATION OF AKT SIGNALING PATHWAY REMAINS TO BE ELUCIDATED. THIS REVIEW SUMMARIZES THE RECENT ADVANCES IN DECIPHERING THE POSSIBLE MECHANISMS OF ZINC ON AKT-MEDIATED INSULIN AND CELL SURVIVAL SIGNALING PATHWAYS IN DIABETES CONDITIONS. INSIGHTS INTO THE EFFECTS OF ZINC ON EPIGENETIC REGULATION AND AUTOPHAGY IN DIABETIC NEPHROPATHY ARE ALSO DISCUSSED IN THE LATTER PART OF THIS REVIEW. 2018 11 2965 34 GENETIC AND EPIGENETIC MODIFICATIONS IN THE PATHOGENESIS OF DIABETIC RETINOPATHY: A MOLECULAR LINK TO REGULATE GENE EXPRESSION. INTENSIFICATION IN THE FREQUENCY OF DIABETES AND THE ASSOCIATED VASCULAR COMPLICATIONS HAS BEEN A ROOT CAUSE OF BLINDNESS AND VISUAL IMPAIRMENT WORLDWIDE. ONE SUCH VASCULAR COMPLICATION WHICH HAS BEEN THE PROMINENT CAUSE OF BLINDNESS; RETINAL VASCULATURE, NEURONAL AND GLIAL ABNORMALITIES IS DIABETIC RETINOPATHY (DR), A CHRONIC COMPLICATED OUTCOME OF TYPE 1 AND TYPE 2 DIABETES. IT HAS ALSO BECOME CLEAR THAT "GENETIC" VARIATIONS IN POPULATION ALONE CAN'T EXPLAIN THE DEVELOPMENT AND PROGRESSION OF DIABETES AND ITS COMPLICATIONS INCLUDING DR. DR EXPERIENCES ENGAGEMENT OF FOREMOST MEDIATORS OF DIABETES SUCH AS HYPERGLYCEMIA, OXIDANT STRESS, AND INFLAMMATORY FACTORS THAT LEAD TO THE DYSREGULATION OF "EPIGENETIC" MECHANISMS INVOLVING HISTONE ACETYLATION AND HISTONE AND DNA METHYLATION, CHROMATIN REMODELING AND EXPRESSION OF A COMPLEX SET OF STRESS-REGULATED AND DISEASE-ASSOCIATED GENES. IN ADDITION, BOTH ELEVATED GLUCOSE CONCENTRATION AND INSULIN RESISTANCE LEAVE A ROBUST EFFECT ON EPIGENETIC REPROGRAMMING OF THE ENDOTHELIAL CELLS TOO, SINCE ENDOTHELIUM ASSOCIATED WITH THE EYE AIDS IN MAINTAINING THE VASCULAR HOMEOSTASIS. FURTHERMORE, SEVERAL STUDIES CONDUCTED ON THE DISEASE SUGGEST THAT THE MODIFICATIONS OF THE EPIGENOME MIGHT BE THE FUNDAMENTAL MECHANISM(S) FOR THE PROPOSED METABOLIC MEMORY' RESULTING INTO PROLONGED GENE EXPRESSION FOR INFLAMMATION AND CELLULAR DYSFUNCTION EVEN AFTER ATTAINING THE GLYCEMIC CONTROL IN DIABETICS. HENCEFORTH, THE PRESENT REVIEW FOCUSES ON THE ASPECTS OF GENETIC AND EPIGENETIC ALTERATIONS IN GENES SUCH AS VASCULAR ENDOTHELIAL GROWTH FACTOR AND ALDOSE REDUCTASE CONSIDERED BEING ASSOCIATED WITH DR. IN ADDITION, WE DISCUSS BRIEFLY THE ROLE OF THE THIOREDOXIN-INTERACTING PROTEIN TXNIP, WHICH IS STRONGLY INDUCED BY HIGH GLUCOSE AND DIABETES, IN CELLULAR OXIDATIVE STRESS AND MITOCHONDRIAL DYSFUNCTION POTENTIALLY LEADING TO CHROMATIN REMODELING AND OCULAR COMPLICATIONS OF DIABETES. THE IDENTIFICATION OF DISEASE-ASSOCIATED GENES AND THEIR EPIGENETIC REGULATIONS WILL LEAD TO POTENTIAL NEW DRUGS AND GENE THERAPIES AS WELL AS PERSONALIZED MEDICINE TO PREVENT OR SLOW DOWN THE PROGRESSION OF DR. 2016 12 4451 28 MOLECULAR MECHANISMS AND FUNCTIONS OF LNCRNAS IN THE INFLAMMATORY REACTION OF DIABETES MELLITUS. DIABETES IS A CHRONIC INFLAMMATORY STATE, AND SEVERAL STUDIES HAVE SHOWN THAT THE MECHANISMS OF INSULIN RESISTANCE AND ABNORMAL ISLET BETA-CELL FUNCTION IN DIABETES ARE CLOSELY RELATED TO INFLAMMATORY REACTIONS. INFLAMMATION PLAYS A CRITICAL ROLE IN DIABETIC COMPLICATIONS. LONG NONCODING RNAS (LNCRNAS), A NEW AREA OF GENOMIC RESEARCH FOR GENE REGULATION, HAVE COMPLEX BIOLOGICAL FUNCTIONS IN VARIOUS ASPECTS OF CELLULAR BIOLOGICAL ACTIVITY. RECENT STUDIES HAVE SHOWN THAT LNCRNAS ARE ASSOCIATED WITH THE REGULATION OF INFLAMMATORY RESPONSES IN VARIOUS WAYS, INCLUDING AT THE EPIGENETIC, TRANSCRIPTIONAL, AND POSTTRANSCRIPTIONAL LEVELS. THIS PAPER PRESENTS A BRIEF REVIEW OF STUDIES ON THE MECHANISMS OF LNCRNAS IN DIABETIC INFLAMMATION. THE PURPOSE OF THIS ARTICLE IS TO DETERMINE THE ROLE OF LNCRNAS IN THE PROCESS OF DIABETIC INFLAMMATION AND TO PROVIDE NEW STRATEGIES FOR THE USE OF LNCRNAS IN THE TREATMENTS FOR DIABETIC INFLAMMATION. 2021 13 2609 27 EPIGENETICS: A POTENTIAL KEY MECHANISM INVOLVED IN THE PATHOGENESIS OF CARDIORENAL SYNDROMES. EPIGENETICS IS DEFINED AS THE HERITABLE CHANGES IN GENE EXPRESSION PATTERNS WHICH ARE NOT DIRECTLY ENCODED BY MODIFICATIONS IN THE NUCLEOTIDE DNA SEQUENCE OF THE GENOME, INCLUDING HIGHER ORDER CHROMATIN ORGANIZATION, DNA METHYLATION, CYTOSINE MODIFICATIONS, COVALENT HISTONE TAIL MODIFICATIONS, AND SHORT NON-CODING RNA MOLECULES. RECENTLY, MUCH ATTENTION HAS BEEN PAID TO THE ROLE AND THE FUNCTION OF EPIGENETICS AND EPIMUTATIONS IN THE CELLULAR AND SUBCELLULAR PATHWAYS AND IN THE REGULATION OF GENES IN THE SETTING OF BOTH KIDNEY AND CARDIOVASCULAR DISEASE. INDEED, DEREGULATION OF HISTONE ALTERATIONS HAS BEEN HIGHLIGHTED IN A LARGE SPECTRUM OF RENAL AND CARDIAC DISEASE, INCLUDING CHRONIC AND ACUTE RENAL INJURY, RENAL AND CARDIAC FIBROSIS, CARDIAC HYPERTROPHY AND FAILURE, KIDNEY CONGENITAL ANOMALIES, RENAL HYPOXIA, AND DIABETIC RENAL COMPLICATIONS. NEVERTHELESS, THE ROLE OF EPIGENETICS IN THE PATHOGENESIS AND PATHOPHYSIOLOGY OF CARDIORENAL SYNDROMES IS CURRENTLY UNDEREXPLORED. GIVEN THE SIGNIFICANT CLINICAL RELEVANCE OF HEART-KIDNEY CROSSTALK, EFFORTS IN THE RESEARCH FOR NEW ACTION MECHANISMS CONCURRENTLY OPERATING IN BOTH PATHOLOGIES ARE THUS OF MAXIMUM INTEREST. THIS REVIEW FOCUSES ON EPIGENETIC MECHANISMS INVOLVED IN HEART AND KIDNEY DISEASE, AND THEIR POSSIBLE ROLE IN THE SETTING OF CARDIORENAL SYNDROMES. 2018 14 6511 28 TRANSCRIPTION FACTORS AS THERAPEUTIC TARGETS IN CHRONIC KIDNEY DISEASE. THE GROWING NUMBER OF PATIENTS WITH CHRONIC KIDNEY DISEASE (CKD) IS RECOGNIZED AS AN EMERGING PROBLEM WORLDWIDE. RECENT STUDIES HAVE INDICATED THAT DEREGULATION OF TRANSCRIPTION FACTORS IS ASSOCIATED WITH THE ONSET OR PROGRESSION OF KIDNEY DISEASE. SEVERAL CLINICAL TRIALS INDICATED THAT REGRESSION OF CKD MAY BE FEASIBLE VIA ACTIVATION OF THE TRANSCRIPTION FACTOR NUCLEAR FACTOR ERYTHROID-2 RELATED FACTOR 2 (NRF2), WHICH SUGGESTS THAT TRANSCRIPTION FACTORS MAY BE POTENTIAL DRUG TARGETS FOR CKD. AGENTS STABILIZING HYPOXIA-INDUCIBLE FACTOR (HIF), WHICH MAY BE BENEFICIAL FOR RENAL ANEMIA AND RENAL PROTECTION, ARE ALSO NOW UNDER CLINICAL TRIAL. RECENTLY, WE HAVE REPORTED THAT THE TRANSCRIPTION FACTOR KRUPPEL-LIKE FACTOR 4 (KLF4) REGULATES THE GLOMERULAR PODOCYTE EPIGENOME, AND THAT THE ANTIPROTEINURIC EFFECT OF THE RENIN(-)ANGIOTENSIN SYSTEM BLOCKADE MAY BE PARTIALLY MEDIATED BY KLF4. KLF4 IS ONE OF THE YAMANAKA FACTORS THAT INDUCES IPS CELLS AND IS REPORTED TO BE INVOLVED IN EPIGENETIC REMODELING. IN THIS ARTICLE, WE SUMMARIZE THE TRANSCRIPTION FACTORS ASSOCIATED WITH CKD AND PARTICULARLY FOCUS ON THE POSSIBILITY OF TRANSCRIPTION FACTORS BEING NOVEL DRUG TARGETS FOR CKD THROUGH EPIGENETIC MODULATION. 2018 15 6377 28 THE ROLE OF NON-CODING RNAS IN DIABETIC NEPHROPATHY: POTENTIAL APPLICATIONS AS BIOMARKERS FOR DISEASE DEVELOPMENT AND PROGRESSION. DIABETIC NEPHROPATHY, A PROGRESSIVE KIDNEY DISEASE THAT DEVELOPS SECONDARY TO DIABETES, IS THE MAJOR CAUSE OF CHRONIC KIDNEY DISEASE IN DEVELOPED COUNTRIES, AND CONTRIBUTES SIGNIFICANTLY TO INCREASED MORBIDITY AND MORTALITY AMONG INDIVIDUALS WITH DIABETES. ALTHOUGH THE CAUSES OF DIABETIC NEPHROPATHY ARE NOT FULLY UNDERSTOOD, RECENT STUDIES DEMONSTRATE A ROLE FOR EPIGENETIC FACTORS IN THE DEVELOPMENT OF THE DISEASE. FOR EXAMPLE, NON-CODING RNA (NCRNA) MOLECULES, INCLUDING MICRORNAS (MIRNAS), HAVE BEEN SHOWN TO BE FUNCTIONALLY IMPORTANT IN MODULATING RENAL RESPONSE TO HYPERGLYCEMIA AND PROGRESSION OF DIABETIC NEPHROPATHY. CHARACTERIZATION OF MIRNA EXPRESSION IN DIABETIC NEPHROPATHY FROM STUDIES OF ANIMAL MODELS OF DIABETES, AND IN VITRO INVESTIGATIONS USING DIFFERENT TYPES OF KIDNEY CELLS ALSO SUPPORT THIS ROLE. THE GOAL OF THIS REVIEW, THEREFORE, IS TO SUMMARIZE THE CURRENT STATE OF KNOWLEDGE OF SPECIFIC NCRNAS INVOLVED IN THE DEVELOPMENT OF DIABETIC NEPHROPATHY, WITH A FOCUS ON THE POTENTIAL ROLE OF MIRNAS TO SERVE AS SENSITIVE, NON-INVASIVE BIOMARKERS OF KIDNEY DISEASE AND PROGRESSION. NON-CODING RNAS ARE CURRENTLY RECOGNIZED AS POTENTIALLY IMPORTANT REGULATORS OF GENES INVOLVED IN PROCESSES RELATED TO THE DEVELOPMENT OF DIABETIC NEPHROPATHY, AND AS SUCH, REPRESENT VIABLE TARGETS FOR BOTH CLINICAL DIAGNOSTIC STRATEGIES AND THERAPEUTIC INTERVENTION. 2013 16 6510 28 TRANSCRIPTION FACTORS AND EPIGENETIC MODULATION: ITS THERAPEUTIC IMPLICATION IN CHRONIC KIDNEY DISEASE. RECENTLY EMERGING EVIDENCE HAS SHOWN THAT EPIGENETIC MECHANISMS ARE INVOLVED IN INITIATION AND PROGRESSION OF VARIOUS DISEASES, INCLUDING KIDNEY DISEASES. IN THE PRESENT ARTICLE, WE REVIEW THE CURRENT DATA REGARDING THE ROLE OF EPIGENETIC MODULATION IN CHRONIC KIDNEY DISEASE (CKD) AND KIDNEY FIBROSIS, INCLUDING DNA METHYLATION AND HISTONE MODIFICATION. ESPECIALLY WE FOCUSED ON THE ROLE OF TRANSCRIPTION FACTORS IN EPIGENETIC MODULATION AND THE POSSIBILITY OF THERAPEUTIC TARGET OF CKD. WE HAVE RECENTLY REPORTED THAT TRANSCRIPTION FACTOR KRUPPEL-LIKE FACTOR 4 (ALSO KNOWN AS GUT-ENRICHED KRUPPEL-LIKE FACTOR) IS EXPRESSED IN KIDNEY PODOCYTES (VISCERAL EPITHELIAL CELLS) AND MODULATES PODOCYTE PHENOTYPE BY GENE-SELECTIVE EPIGENETIC CONTROL. TARGETING TRANSCRIPTION FACTORS FOR EPIGENETIC MODIFICATION MAY BE A GOOD CANDIDATE FOR REMISSION AND REGRESSION OF CKD. IT IS NECESSARY FOR THE THERAPY OF CKD WITH AN EPIGENETIC-BASED APPROACH TO INVESTIGATE ORGAN-, TISSUE-, OR GENE-SPECIFIC TREATMENT METHODS FOR REDUCTION OF SIDE EFFECTS. 2015 17 3957 24 LONG NON-CODING RNAS AS EMERGING REGULATORS OF MIRNAS AND EPIGENETICS IN DIABETES-RELATED CHRONIC KIDNEY DISEASE. DIABETES IS ONE OF THE MAJOR CAUSE OF CHRONIC KIDNEY DISEASE (CKD), INCLUDING "DIABETIC NEPHROPATHY," AND IS AN INCREASINGLY PREVALENT ACCELERATOR OF THE PROGRESSION OF NON-DIABETIC FORMS OF CKD. THE LONG NON-CODING RNAS (LNCRNAS) HAVE COME INTO THE LIMELIGHT IN THE PAST FEW YEARS AS ONE OF THE EMERGING WEAPONS AGAINST CKD IN DIABETES. AVAILABLE DATA OVER THE PAST FEW YEARS DEMONSTRATE THE INTERACTION OF LNCRNAS WITH MIRNAS AND EPIGENETIC MACHINERY. INTERESTINGLY, THE EVOLVING DATA SUGGEST THAT LNCRNAS PLAY A VITAL ROLE IN DIABETES-ASSOCIATED CKD BY REGULATION OF EPIGENETIC ENZYMES SUCH AS DNA METHYLTRANSFERASE, HISTONE DEACETYLASES, AND HISTONE METHYLTRANSFERASES. LNCRNAS ARE ALSO ENGAGED IN THE REGULATION OF SEVERAL MIRNAS IN DIABETIC NEPHROPATHY. HENCE THIS REVIEW WILL ELABORATE ON THE ASSOCIATION BETWEEN LNCRNAS AND THEIR INTERACTION WITH EPIGENETIC REGULATORS INVOLVED IN DIFFERENT ASPECTS AND THUS THE PROGRESSION OF CKD IN DIABETES. 2022 18 1832 33 EFFECTS OF METABOLIC MEMORY ON INFLAMMATION AND FIBROSIS ASSOCIATED WITH DIABETIC KIDNEY DISEASE: AN EPIGENETIC PERSPECTIVE. DIABETIC KIDNEY DISEASE (DKD) IS ONE OF THE MOST COMMON MICROVASCULAR COMPLICATION OF BOTH TYPE 1 (T1DM) AND TYPE 2 DIABETES MELLITUS (T2DM), AND THE LEADING CAUSE OF END-STAGE RENAL DISEASE (ESRD) WORLDWIDE. PERSISTENT INFLAMMATION AND SUBSEQUENT CHRONIC FIBROSIS ARE MAJOR CAUSES OF LOSS OF RENAL FUNCTION, WHICH IS ASSOCIATED WITH THE PROGRESSION OF DKD TO ESRD. IN FACT, DKD PROGRESSION IS AFFECTED BY A COMBINATION OF GENETIC AND ENVIRONMENTAL FACTORS. APPROXIMATELY, ONE-THIRD OF DIABETIC PATIENTS PROGRESS TO DEVELOP DKD DESPITE INTENSIVE GLYCEMIC CONTROL, WHICH PROPOSE AN ESSENTIAL CONCEPT "METABOLIC MEMORY." EPIGENETIC MODIFICATIONS, AN EXTENSIVELY STUDIED MECHANISM OF METABOLIC MEMORY, HAVE BEEN SHOWN TO CONTRIBUTE TO THE SUSCEPTIBILITY TO DEVELOP DKD. EPIGENETIC MODIFICATIONS ALSO PLAY A REGULATORY ROLE IN THE INTERACTIONS BETWEEN THE GENES AND THE ENVIRONMENTAL FACTORS. THE EPIGENETIC CONTRIBUTIONS TO THE PROCESSES OF INFLAMMATION AND FIBROGENESIS INVOLVED IN DKD OCCUR AT DIFFERENT REGULATORY LEVELS, INCLUDING DNA METHYLATION, HISTONE MODIFICATION AND NON-CODING RNA MODULATION. COMPARED WITH GENETIC FACTORS, EPIGENETICS REPRESENTS A NEW THERAPEUTIC FRONTIER IN UNDERSTANDING THE DEVELOPMENT DKD AND MAY LEAD TO THERAPEUTIC BREAKTHROUGHS DUE TO THE POSSIBILITY TO REVERSE THESE MODIFICATIONS THERAPEUTICALLY. EARLY RECOGNITION OF EPIGENETIC EVENTS AND BIOMARKERS IS CRUCIAL FOR TIMELY DIAGNOSIS AND INTERVENTION OF DKD, AND FOR THE PREVENTION OF THE PROGRESSION OF DKD TO ESRD. HEREIN, WE WILL REVIEW THE LATEST EPIGENETIC MECHANISMS INVOLVED IN THE RENAL PATHOLOGY OF BOTH TYPE 1 (T1DN) AND TYPE 2 DIABETIC NEPHROPATHY (T2DN) AND HIGHLIGHT THE EMERGING ROLE AND POSSIBLE THERAPEUTIC STRATEGIES BASED ON THE UNDERSTANDING OF THE ROLE OF EPIGENETICS IN DKD-ASSOCIATED INFLAMMATION AND FIBROGENESIS. 2021 19 2163 28 EPIGENETIC MECHANISMS IN DIABETIC VASCULAR COMPLICATIONS. THERE HAS BEEN A RAPID INCREASE IN THE INCIDENCE OF DIABETES AS WELL THE ASSOCIATED VASCULAR COMPLICATIONS. BOTH GENETIC AND ENVIRONMENTAL FACTORS HAVE BEEN IMPLICATED IN THESE PATHOLOGIES. INCREASING EVIDENCE SUGGESTS THAT EPIGENETIC FACTORS PLAY A KEY ROLE IN THE COMPLEX INTERPLAY BETWEEN GENES AND THE ENVIRONMENT. ACTIONS OF MAJOR PATHOLOGICAL MEDIATORS OF DIABETES AND ITS COMPLICATIONS SUCH AS HYPERGLYCAEMIA, OXIDANT STRESS, AND INFLAMMATORY FACTORS CAN LEAD TO DYSREGULATED EPIGENETIC MECHANISMS THAT AFFECT CHROMATIN STRUCTURE AND GENE EXPRESSION. FURTHERMORE, PERSISTENCE OF THIS ALTERED STATE OF THE EPIGENOME MAY BE THE UNDERLYING MECHANISM CONTRIBUTING TO A 'METABOLIC MEMORY' THAT RESULTS IN CHRONIC INFLAMMATION AND VASCULAR DYSFUNCTION IN DIABETES EVEN AFTER ACHIEVING GLYCAEMIC CONTROL. FURTHER EXAMINATION OF EPIGENETIC MECHANISMS BY ALSO TAKING ADVANTAGE OF RECENTLY DEVELOPED NEXT-GENERATION SEQUENCING TECHNOLOGIES CAN PROVIDE NOVEL INSIGHTS INTO THE PATHOLOGY OF DIABETES AND ITS COMPLICATIONS AND LEAD TO THE DISCOVERY OF MUCH NEEDED NEW DRUG TARGETS FOR THESE DISEASES. IN THIS REVIEW, WE HIGHLIGHT THE ROLE OF EPIGENETICS IN DIABETES AND ITS VASCULAR COMPLICATIONS, AND RECENT TECHNOLOGICAL ADVANCES THAT HAVE SIGNIFICANTLY ACCELERATED THE FIELD. 2011 20 4456 26 MOLECULAR MECHANISMS IN RENAL DEGENERATIVE DISEASE. CHRONIC KIDNEY DISEASE (CKD) HAS BECOME A MAJOR PUBLIC HEALTH PROBLEM WORLDWIDE. THEREFORE, A CONSIDERABLE EFFORT IS CURRENTLY DIRECTED TO UNDERSTAND THE MOLECULAR MECHANISMS OF RENAL DEGENERATIVE PROCESSES. REGARDLESS OF THEIR INITIATING CAUSE, ALL CHRONIC KIDNEY DISEASES (CKD) DEVELOP AT SOME LEVEL ORGAN FIBROSIS THAT INTERFERES WITH KIDNEY FUNCTION. THIS IS ALSO TRUE FOR THE TWO MOST COMMON INHERITED CKD SYNDROMES, NEPHRONOPHTHITIS AND POLYCYSTIC KIDNEY DISEASE, WHOSE PRIMARY DEFECTS RESIDE WITHIN THE CILIUM OF KIDNEY EPITHELIAL CELLS. A COHORT OF ELEGANT RECENT STUDIES HAS ELICITED THE ROLE OF THE PRIMARY CILIUM AS A VERSATILE MECHANOSENSORY ORGANELLE THAT ALSO MIGHT COORDINATE CROSS-TALK BETWEEN MULTIPLE SIGNALING PATHWAYS. IN ADDITION, EPIGENETIC MECHANISMS ARE NOW REALIZED TO BE ESSENTIAL IN THE MAINTENANCE OF ADULT RENAL ARCHITECTURE. IN THIS REVIEW, WE WILL DISCUSS RECENT ADVANCES IN OUR UNDERSTANDING OF THE SIGNALING SYSTEMS IMPLICATED IN KIDNEY HOMEOSTASIS AND REPAIR. 2010