1 5363 65 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 2 6575 29 TREATMENT OF DIABETIC KIDNEY DISEASE: CURRENT AND FUTURE. DIABETIC KIDNEY DISEASE (DKD) IS THE MAJOR CAUSE OF END-STAGE KIDNEY DISEASE. HOWEVER, ONLY RENIN-ANGIOTENSIN SYSTEM INHIBITOR WITH MULTIDISCIPLINARY TREATMENTS IS EFFECTIVE FOR DKD. IN 2019, SODIUM-GLUCOSE COTRANSPORTER 2 (SGLT2) INHIBITOR SHOWED EFFICACY AGAINST DKD IN CANAGLIFLOZIN AND RENAL EVENTS IN DIABETES WITH ESTABLISHED NEPHROPATHY CLINICAL EVALUATION (CREDENCE) TRIAL, ADDING A NEW TREATMENT OPTION. HOWEVER, THE PROGRESSION OF DKD HAS NOT BEEN COMPLETELY CONTROLLED. THE PATIENTS WITH TRANSIENT EXPOSURE TO HYPERGLYCEMIA DEVELOP DIABETIC COMPLICATIONS, INCLUDING DKD, EVEN AFTER NORMALIZATION OF THEIR BLOOD GLUCOSE. TEMPORARY HYPERGLYCEMIA CAUSES ADVANCED GLYCATION END PRODUCT (AGE) ACCUMULATIONS AND EPIGENETIC CHANGES AS METABOLIC MEMORY. THE DRUGS THAT IMPROVE METABOLIC MEMORY ARE AWAITED, AND AGE INHIBITORS AND HISTONE MODIFICATION INHIBITORS ARE THE FOCUS OF CLINICAL AND BASIC RESEARCH. IN ADDITION, INCRETIN-RELATED DRUGS SHOWED A RENOPROTECTIVE ABILITY IN MANY CLINICAL TRIALS, AND THESE TRIALS WITH RENAL OUTCOME AS THEIR PRIMARY ENDPOINT ARE CURRENTLY ONGOING. HYPOXIA-INDUCIBLE FACTOR PROLYL HYDROXYLASE INHIBITORS RECENTLY APPROVED FOR RENAL ANEMIA MAY BE RENOPROTECTIVE SINCE THEY IMPROVE TUBULOINTERSTITIAL HYPOXIA. FURTHERMORE, NF-E2-RELATED FACTOR 2 ACTIVATORS IMPROVED THE GLOMERULAR FILTRATION RATE OF DKD PATIENTS IN BARDOXOLONE METHYL TREATMENT: RENAL FUNCTION IN CHRONIC KIDNEY DISEASE/TYPE 2 DIABETES (BEAM) TRIAL AND PHASE II STUDY OF BARDOXOLONE METHYL IN PATIENTS WITH CHRONIC KIDNEY DISEASE AND TYPE 2 DIABETES (TSUBAKI) TRIAL. THUS, FOLLOWING SGLT2 INHIBITOR, NUMEROUS NOVEL DRUGS COULD BE UTILIZED IN TREATING DKD. FUTURE STUDIES ARE EXPECTED TO PROVIDE NEW INSIGHTS. 2021 3 4433 19 MOLECULAR COMPLEXITIES UNDERLYING THE VASCULAR COMPLICATIONS OF DIABETES MELLITUS - A COMPREHENSIVE REVIEW. DIABETES IS A CHRONIC DISEASE, CHARACTERIZED BY HYPERGLYCEMIA, WHICH REFERS TO THE ELEVATED LEVELS OF GLUCOSE IN THE BLOOD, DUE TO THE INABILITY OF THE BODY TO PRODUCE OR USE INSULIN EFFECTIVELY. CHRONIC HYPERGLYCEMIA LEVELS LEAD TO MACROVASCULAR AND MICROVASCULAR COMPLICATIONS. THE MACROVASCULAR COMPLICATIONS CONSIST OF PERIPHERAL ARTERY DISEASE (PAD), CARDIOVASCULAR DISEASES (CVD) AND CEREBROVASCULAR DISEASES, WHILE THE MICROVASCULAR COMPLICATIONS COMPRISE OF DIABETIC MICROANGIOPATHY, DIABETIC NEPHROPATHY, DIABETIC RETINOPATHY AND DIABETIC NEUROPATHY. VASCULAR ENDOTHELIAL DYSFUNCTION PLAYS A CRUCIAL ROLE IN MEDIATING BOTH MACROVASCULAR AND MICROVASCULAR COMPLICATIONS UNDER HYPERGLYCEMIC CONDITIONS. IN DIABETIC MICROVASCULATURE, THE INTRACELLULAR HYPERGLYCEMIA CAUSES DAMAGE TO THE VASCULAR ENDOTHELIUM THROUGH - (I) ACTIVATION OF FOUR BIOCHEMICAL PATHWAYS, NAMELY THE POLYOL PATHWAY, PROTEIN KINASE C (PKC) PATHWAY, ADVANCED GLYCATION END PRODUCTS (AGE) PATHWAY AND HEXOSAMINE PATHWAY, ALL OF WHICH COMMUTES GLUCOSE AND ITS INTERMEDIATES LEADING TO OVERPRODUCTION OF REACTIVE OXYGEN SPECIES, (II) DYSREGULATION OF GROWTH FACTORS AND CYTOKINES, (III) EPIGENETIC CHANGES WHICH CONCERN THE CHANGES IN DNA AS A RESPONSE TO INTRACELLULAR CHANGES, AND (IV) ABNORMALITIES IN NON-CODING RNAS, SPECIFICALLY MICRORNAS. THIS REVIEW WILL FOCUS ON GAINING AN UNDERSTANDING OF THE MOLECULAR COMPLEXITIES UNDERLYING THE VASCULAR COMPLICATIONS IN DIABETES MELLITUS, TO INCREASE OUR UNDERSTANDING TOWARDS THE DEVELOPMENT OF NEW MECHANISTIC THERAPEUTIC STRATEGIES TO PREVENT OR TREAT DIABETES-INDUCED VASCULAR COMPLICATIONS. 2020 4 4137 22 MECHANISMS OF METABOLIC MEMORY AND RENAL HYPOXIA AS A THERAPEUTIC TARGET IN DIABETIC KIDNEY DISEASE. DIABETIC KIDNEY DISEASE (DKD) IS A WORLDWIDE PUBLIC HEALTH PROBLEM. THE DEFINITION OF DKD IS UNDER DISCUSSION. ALTHOUGH THE TERM DKD WAS ORIGINALLY DEFINED AS 'KIDNEY DISEASE SPECIFIC TO DIABETES,' DKD FREQUENTLY MEANS CHRONIC KIDNEY DISEASE WITH DIABETES MELLITUS AND INCLUDES NOT ONLY CLASSICAL DIABETIC NEPHROPATHY, BUT ALSO KIDNEY DYSFUNCTION AS A RESULT OF NEPHROSCLEROSIS AND OTHER CAUSES. METABOLIC MEMORY PLAYS A CRUCIAL ROLE IN THE PROGRESSION OF VARIOUS COMPLICATIONS OF DIABETES, INCLUDING DKD. THE MECHANISMS OF METABOLIC MEMORY IN DKD ARE SUPPOSED TO INCLUDE ADVANCED GLYCATION END-PRODUCTS, DEOXYRIBONUCLEIC ACID METHYLATION, HISTONE MODIFICATIONS AND NON-CODING RIBONUCLEIC ACID INCLUDING MICRO RIBONUCLEIC ACID. REGARDLESS OF THE PRESENCE OF DIABETES MELLITUS, THE FINAL COMMON PATHWAY IN CHRONIC KIDNEY DISEASE IS CHRONIC KIDNEY HYPOXIA, WHICH INFLUENCES EPIGENETIC PROCESSES, INCLUDING DEOXYRIBONUCLEIC ACID METHYLATION, HISTONE MODIFICATION, AND CONFORMATIONAL CHANGES IN MICRO RIBONUCLEIC ACID AND CHROMATIN. THEREFORE, HYPOXIA AND OXIDATIVE STRESS ARE APPROPRIATE TARGETS OF THERAPIES AGAINST DKD. PROLYL HYDROXYLASE DOMAIN INHIBITOR ENHANCES THE DEFENSIVE MECHANISMS AGAINST HYPOXIA. BARDOXOLONE METHYL PROTECTS AGAINST OXIDATIVE STRESS, AND CAN EVEN REVERSE IMPAIRED RENAL FUNCTION; A PHASE 2 TRIAL WITH CONSIDERABLE ATTENTION TO HEART COMPLICATIONS IS CURRENTLY ONGOING IN JAPAN. 2017 5 2121 32 EPIGENETIC HISTONE MODIFICATIONS IN THE PATHOGENESIS OF DIABETIC KIDNEY DISEASE. DIABETIC KIDNEY DISEASE (DKD), AS THE MAIN COMPLICATION OF DIABETES MELLITUS, IS THE PRIMARY CAUSE OF THE END-STAGE RENAL DISEASE (ESRD) AND THE MOST COMMON CHRONIC KIDNEY DISEASE. OVERALL, 30-40% OF PATIENTS WITH TYPE 1 AND TYPE 2 DIABETES EVENTUALLY DEVELOP DKD. ALTHOUGH SOME DIABETES PATIENTS HAVE INTENSIFIED GLYCEMIC CONTROL, THEY STILL DEVELOP DIABETIC KIDNEY DISEASE. CURRENT TREATMENT METHODS CAN ALLEVIATE BUT DO NOT MARKEDLY HALT DISEASE DEVELOPMENT, RESULTING IN RENAL FAILURE AND SEVERE COMPLICATIONS, EVEN CONTRIBUTING TO ELEVATED MORBIDITY AND MORTALITY RATES. DKD IS A DISEASE WITH INTERACTIONS OF GENES AND THE ENVIRONMENT. EMERGING EVIDENCE INDICATES THAT DKD-ASSOCIATED KEY GENES ARE ALSO REGULATED BY THE EPIGENETIC MECHANISM. RECENTLY, INCREASING RESEARCHES INVOLVING CELLS AND EXPERIMENTAL ANIMALS DEMONSTRATED THAT HISTONE POST-TRANSLATIONAL MODIFICATIONS CAN MEDIATE GENE EXPRESSION, WHICH CORRELATED WITH DIABETIC KIDNEY DISEASE. NOVEL THERAPEUTIC STRATEGIES FOR EPIGENETIC EVENTS COULD BE BENEFICIAL FOR THE EARLY DETECTION AND TREATMENT OF DKD TO PREVENT IT FROM DEVELOPING INTO END-STAGE RENAL DISEASE (ESRD). IN THIS REVIEW, WE DISCUSS PRIOR FINDINGS IN THE FIELD OF HISTONE MODIFICATIONS IN DKD, ESPECIALLY HISTONE ACETYLATION AND HISTONE METHYLATION. WE THEN FOCUS ON RECENT DEVELOPMENTS IN HISTONE ACETYLATION AND METHYLATION INVOLVED IN THE PATHOGENESIS OF DKD. 2021 6 4459 25 MOLECULAR MECHANISMS OF DIABETIC VASCULAR COMPLICATIONS. DIABETIC COMPLICATIONS ARE THE MAJOR CAUSES OF MORBIDITY AND MORTALITY IN PATIENTS WITH DIABETES. MICROVASCULAR COMPLICATIONS INCLUDE RETINOPATHY, NEPHROPATHY AND NEUROPATHY, WHICH ARE LEADING CAUSES OF BLINDNESS, END-STAGE RENAL DISEASE AND VARIOUS PAINFUL NEUROPATHIES; WHEREAS MACROVASCULAR COMPLICATIONS INVOLVE ATHEROSCLEROSIS RELATED DISEASES, SUCH AS CORONARY ARTERY DISEASE, PERIPHERAL VASCULAR DISEASE AND STROKE. DIABETIC COMPLICATIONS ARE THE RESULT OF INTERACTIONS AMONG SYSTEMIC METABOLIC CHANGES, SUCH AS HYPERGLYCEMIA, LOCAL TISSUE RESPONSES TO TOXIC METABOLITES FROM GLUCOSE METABOLISM, AND GENETIC AND EPIGENETIC MODULATORS. CHRONIC HYPERGLYCEMIA IS RECOGNIZED AS A MAJOR INITIATOR OF DIABETIC COMPLICATIONS. MULTIPLE MOLECULAR MECHANISMS HAVE BEEN PROPOSED TO MEDIATE HYPERGLYCEMIA'S ADVERSE EFFECTS ON VASCULAR TISSUES. THESE INCLUDE INCREASED POLYOL PATHWAY, ACTIVATION OF THE DIACYLGLYCEROL/PROTEIN KINASE C PATHWAY, INCREASED OXIDATIVE STRESS, OVERPRODUCTION AND ACTION OF ADVANCED GLYCATION END PRODUCTS, AND INCREASED HEXOSAMINE PATHWAY. IN ADDITION, THE ALTERATIONS OF SIGNAL TRANSDUCTION PATHWAYS INDUCED BY HYPERGLYCEMIA OR TOXIC METABOLITES CAN ALSO LEAD TO CELLULAR DYSFUNCTIONS AND DAMAGE VASCULAR TISSUES BY ALTERING GENE EXPRESSION AND PROTEIN FUNCTION. LESS STUDIED THAN THE TOXIC MECHANISMS, HYPERGLYCEMIA MIGHT ALSO INHIBIT THE ENDOGENOUS VASCULAR PROTECTIVE FACTORS SUCH AS INSULIN, VASCULAR ENDOTHELIAL GROWTH FACTOR, PLATELET-DERIVED GROWTH FACTOR AND ACTIVATED PROTEIN C, WHICH PLAY IMPORTANT ROLES IN MAINTAINING VASCULAR HOMEOSTASIS. THUS, EFFECTIVE THERAPIES FOR DIABETIC COMPLICATIONS NEED TO INHIBIT MECHANISMS INDUCED BY HYPERGLYCEMIA'S TOXIC EFFECTS AND ALSO ENHANCE THE ENDOGENOUS PROTECTIVE FACTORS. THE PRESENT REVIEW SUMMARIZES THESE MULTIPLE BIOCHEMICAL PATHWAYS ACTIVATED BY HYPERGLYCEMIA AND THE POTENTIAL THERAPEUTIC INTERVENTIONS THAT MIGHT PREVENT DIABETIC COMPLICATIONS. (J DIABETES INVEST, DOI: 10.1111/J.2040-1124.2010.00018.X, 2010). 2010 7 4971 26 PATHOPHYSIOLOGIC MECHANISMS IN DIABETIC KIDNEY DISEASE: A FOCUS ON CURRENT AND FUTURE THERAPEUTIC TARGETS. DIABETIC KIDNEY DISEASE (DKD) IS THE PRIMARY CAUSE OF CHRONIC KIDNEY DISEASE AROUND THE GLOBE AND IS ONE OF THE MAIN COMPLICATIONS IN PATIENTS WITH TYPE 1 AND 2 DIABETES. THE STANDARD TREATMENT FOR DKD IS DRUGS CONTROLLING HYPERGLYCEMIA AND HIGH BLOOD PRESSURE. RENIN ANGIOTENSIN ALDOSTERONE SYSTEM BLOCKADE AND SODIUM GLUCOSE COTRANSPORTER 2 (SGLT2) INHIBITION HAVE YIELDED PROMISING RESULTS IN DKD, BUT MANY DIABETIC PATIENTS ON SUCH TREATMENTS NEVERTHELESS CONTINUE TO DEVELOP DKD, LEADING TO KIDNEY FAILURE AND CARDIOVASCULAR COMORBIDITIES. NEW THERAPEUTIC OPTIONS ARE URGENTLY REQUIRED. WE REVIEW HERE THE PROMISING THERAPEUTIC AVENUES BASED ON INSIGHTS INTO THE MECHANISMS OF DKD THAT HAVE RECENTLY EMERGED, INCLUDING MINERALOCORTICOID RECEPTOR ANTAGONISTS, SGLT2 INHIBITORS, GLUCAGON-LIKE PEPTIDE-1 RECEPTOR AGONIST, ENDOTHELIN RECEPTOR A INHIBITION, ANTI-INFLAMMATORY AGENTS, AUTOPHAGY ACTIVATORS AND EPIGENETIC REMODELLING. THE INVOLVEMENT OF SEVERAL MOLECULAR MECHANISMS IN DKD PATHOGENESIS, TOGETHER WITH THE GENETIC AND EPIGENETIC VARIABILITY OF THIS CONDITION, MAKES IT DIFFICULT TO TARGET THIS HETEROGENEOUS PATIENT POPULATION WITH A SINGLE DRUG. PERSONALIZED MEDICINE, TAKING INTO ACCOUNT THE GENETIC AND MECHANISTIC VARIABILITY, MAY THEREFORE IMPROVE RENAL AND CARDIOVASCULAR PROTECTION IN DIABETIC PATIENTS WITH DKD. 2020 8 2171 22 EPIGENETIC MECHANISMS IN THE PATHOGENESIS OF DIABETIC FOOT ULCERS. THE INCIDENCE OF DIABETES MELLITUS, A CHRONIC METABOLIC DISEASE ASSOCIATED WITH BOTH PREDISPOSING GENETIC AND ENVIRONMENTAL FACTORS, IS INCREASING GLOBALLY. AS A RESULT, IT IS EXPECTED THAT THERE WILL ALSO BE AN INCREASING INCIDENCE OF DIABETIC COMPLICATIONS WHICH ARISE AS A RESULT OF POOR GLYCEMIC CONTROL. COMPLICATIONS INCLUDE CARDIOVASCULAR DISEASES, NEPHROPATHY, RETINOPATHY AND DIABETIC FOOT ULCERS. THE FINDINGS OF SEVERAL MAJOR CLINICAL TRIALS HAVE IDENTIFIED THAT DIABETIC COMPLICATIONS MAY ARISE EVEN AFTER MANY YEARS OF PROPER GLYCEMIC CONTROL. THIS HAS LED TO THE CONCEPT OF PERSISTENT EPIGENETIC CHANGES. VARIOUS EPIGENETIC MECHANISMS HAVE BEEN IDENTIFIED AS IMPORTANT CONTRIBUTORS TO THE PATHOGENESIS OF DIABETES AND DIABETIC COMPLICATIONS. THE AIM OF THIS REVIEW IS TO PROVIDE AN OVERVIEW OF THE PATHOBIOLOGY OF TYPE 2 DIABETES WITH AN EMPHASIS ON COMPLICATIONS, PARTICULARLY DIABETIC FOOT ULCERS. AN OVERVIEW OF EPIGENETIC MECHANISMS IS PROVIDED AND THE FOCUS IS ON THE EMERGING EVIDENCE FOR ABERRANT EPIGENETIC MECHANISMS IN DIABETIC FOOT ULCERS. 2012 9 1832 29 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 10 6648 25 UPDATE ON DIAGNOSIS, PATHOPHYSIOLOGY, AND MANAGEMENT OF DIABETIC KIDNEY DISEASE. DIABETIC KIDNEY DISEASE (DKD) IS A CHRONIC COMPLICATION OF DIABETES MELLITUS WHICH MAY EVENTUALLY LEAD TO END-STAGE KIDNEY DISEASE (ESKD). DESPITE IMPROVEMENTS IN GLYCAEMIC CONTROL AND BLOOD PRESSURE MANAGEMENT WITH RENIN-ANGIOTENSIN-ALDOSTERONE SYSTEM (RAAS) BLOCKADE, THE CURRENT THERAPY CANNOT COMPLETELY HALT DKD PROGRESSION TO ESKD IN SOME PATIENTS. DKD IS A HETEROGENEOUS DISEASE ENTITY IN TERMS OF ITS CLINICAL MANIFESTATIONS, HISTOPATHOLOGY AND THE RATE OF PROGRESSION, WHICH MAKES IT DIFFICULT TO DEVELOP EFFECTIVE THERAPEUTICS. IT WAS FORMERLY CONSIDERED THAT ALBUMINURIA PRECEDED KIDNEY FUNCTION DECLINE IN DKD, BUT RECENT EPIDEMIOLOGICAL STUDIES REVEALED THAT A DISTINCT GROUP OF PATIENTS PRESENTED KIDNEY DYSFUNCTION WITHOUT DEVELOPING ALBUMINURIA. OTHER COMORBIDITIES, SUCH AS HYPERTENSION, OBESITY AND GOUT, ALSO AFFECT THE CLINICAL COURSE OF DKD. THE PATHOPHYSIOLOGY OF DKD IS COMPLEX AND MULTIFACTORIAL, INVOLVING BOTH METABOLIC AND HAEMODYNAMIC FACTORS. THESE INDUCE ACTIVATION OF INTRACELLULAR SIGNALLING PATHWAYS, OXIDATIVE STRESS, HYPOXIA, DYSREGULATED AUTOPHAGY AND EPIGENETIC CHANGES, WHICH RESULT IN KIDNEY INFLAMMATION AND FIBROSIS. RECENTLY, TWO GROUPS OF ANTIDIABETIC DRUGS, SODIUM-GLUCOSE COTRANSPORTER 2 (SGLT2) INHIBITORS AND GLUCAGON-LIKE PEPTIDE-1 (GLP-1) RECEPTOR AGONISTS, WERE DEMONSTRATED TO PROVIDE RENOPROTECTION ON TOP OF THEIR GLUCOSE-LOWERING EFFECTS. SEVERAL OTHER THERAPEUTIC AGENTS ARE ALSO BEING DEVELOPED AND EVALUATED IN CLINICAL TRIALS. 2021 11 2009 20 EPIGENETIC BASIS OF DIABETIC VASCULOPATHY. TYPE 2 DIABETES MELLITUS (T2DM) CAUSES PERIPHERAL VASCULAR DISEASE BECAUSE OF WHICH SEVERAL BLOOD-BORNE FACTORS, INCLUDING VITAL NUTRIENTS FAIL TO REACH THE AFFECTED TISSUE. TISSUE EPIGENOME IS SENSITIVE TO CHRONIC HYPERGLYCEMIA AND IS KNOWN TO CAUSE PATHOGENESIS OF MICRO- AND MACROVASCULAR COMPLICATIONS. THESE VASCULAR COMPLICATIONS OF T2DM MAY PERPETUATE THE ONSET OF ORGAN DYSFUNCTION. THE BURDEN OF DIABETES IS PRIMARILY BECAUSE OF A WIDE RANGE OF COMPLICATIONS OF WHICH NONHEALING DIABETIC ULCERS REPRESENT A MAJOR COMPONENT. THUS, IT IS IMPERATIVE THAT CURRENT RESEARCH HELP RECOGNIZE MORE EFFECTIVE METHODS FOR THE DIAGNOSIS AND MANAGEMENT OF EARLY VASCULAR INJURIES. THIS REVIEW ADDRESSES THE SIGNIFICANCE OF EPIGENETIC PROCESSES SUCH AS DNA METHYLATION AND HISTONE MODIFICATIONS IN THE EVOLUTION OF MACROVASCULAR AND MICROVASCULAR COMPLICATIONS OF T2DM. 2022 12 6075 29 THE DYNAMICS AND PLASTICITY OF EPIGENETICS IN DIABETIC KIDNEY DISEASE: THERAPEUTIC APPLICATIONS VIS-A-VIS. CHRONIC KIDNEY DISEASE (CKD) REFERS TO THE PHENOMENON OF PROGRESSIVE DECLINE IN THE GLOMERULAR FILTRATION RATE ACCOMPANIED BY ADVERSE CONSEQUENCES, INCLUDING FLUID RETENTION, ELECTROLYTE IMBALANCE, AND AN INCREASED CARDIOVASCULAR RISK COMPARED TO THOSE WITH NORMAL RENAL FUNCTION. THE TRIGGERS FOR THE IRREVERSIBLE RENAL FUNCTION DETERIORATION ARE MULTIFACTORIAL, AND DIABETES MELLITUS SERVES AS A MAJOR CONTRIBUTOR TO THE DEVELOPMENT OF CKD, NAMELY DIABETIC KIDNEY DISEASE (DKD). RECENTLY, EPIGENETIC DYSREGULATION EMERGED AS A PIVOTAL PLAYER STEERING THE PROGRESSION OF DKD, PARTLY RESULTING FROM HYPERGLYCEMIA-ASSOCIATED METABOLIC DISTURBANCES, RISING OXIDATIVE STRESS, AND/OR UNCONTROLLED INFLAMMATION. IN THIS REVIEW, WE DESCRIBE THE MAJOR EPIGENETIC MOLECULAR MECHANISMS, FOLLOWED BY SUMMARIZING CURRENT UNDERSTANDINGS OF THE EPIGENETIC ALTERATIONS PERTAINING TO DKD. WE HIGHLIGHT THE EPIGENETIC REGULATORY PROCESSES INVOLVED IN SEVERAL CRUCIAL RENAL CELL TYPES: MESANGIAL CELLS, PODOCYTES, TUBULAR EPITHELIA, AND GLOMERULAR ENDOTHELIAL CELLS. FINALLY, WE HIGHLIGHT EPIGENETIC BIOMARKERS AND RELATED THERAPEUTIC CANDIDATES THAT HOLD PROMISING POTENTIAL FOR THE EARLY DETECTION OF DKD AND THE AMELIORATION OF ITS PROGRESSION. 2022 13 1983 28 EPIGENETIC ALTERATIONS IN PODOCYTES IN DIABETIC NEPHROPATHY. RECENTLY, EPIGENETIC ALTERATIONS HAVE BEEN SHOWN TO BE INVOLVED IN THE PATHOGENESIS OF DIABETES AND ITS COMPLICATIONS. KIDNEY PODOCYTES, WHICH ARE GLOMERULAR EPITHELIAL CELLS, ARE IMPORTANT CELLS THAT FORM A SLIT MEMBRANE-A BARRIER FOR PROTEINURIA. PODOCYTES ARE TERMINALLY DIFFERENTIATED CELLS WITHOUT CELL DIVISION OR REPLENISHMENT ABILITIES. THEREFORE, PODOCYTE DAMAGE IS SUGGESTED TO BE ONE OF THE KEY FACTORS DETERMINING RENAL PROGNOSIS. RECENT STUDIES, INCLUDING OURS, SUGGEST THAT EPIGENETIC CHANGES IN PODOCYTES ARE ASSOCIATED WITH CHRONIC KIDNEY DISEASE, INCLUDING DIABETIC NEPHROPATHY. FURTHERMORE, THE ASSOCIATION BETWEEN DNA DAMAGE REPAIR AND EPIGENETIC CHANGES IN DIABETIC PODOCYTES HAS BEEN DEMONSTRATED. DETECTION OF PODOCYTE DNA DAMAGE AND EPIGENETIC CHANGES USING HUMAN SAMPLES, SUCH AS KIDNEY BIOPSY AND URINE-DERIVED CELLS, MAY BE A PROMISING STRATEGY FOR ESTIMATING KIDNEY DAMAGE AND RENAL PROGNOSES IN PATIENTS WITH DIABETES. TARGETING EPIGENETIC PODOCYTE CHANGES AND ASSOCIATED DNA DAMAGE MAY BECOME A NOVEL THERAPEUTIC STRATEGY FOR PREVENTING PROGRESSION TO END-STAGE RENAL DISEASE (ESRD) AND PROVIDE A POSSIBLE PROGNOSTIC MARKER IN DIABETIC NEPHROPATHY. THIS REVIEW SUMMARIZES RECENT ADVANCES REGARDING EPIGENETIC CHANGES, ESPECIALLY DNA METHYLATION, IN PODOCYTES IN DIABETIC NEPHROPATHY AND ADDRESSES DETECTION OF THESE ALTERATIONS IN HUMAN SAMPLES. ADDITIONALLY, WE FOCUSED ON DNA DAMAGE, WHICH IS INCREASED UNDER HIGH-GLUCOSE CONDITIONS AND ASSOCIATED WITH THE GENERATION OF EPIGENETIC CHANGES IN PODOCYTES. FURTHERMORE, EPIGENETIC MEMORY IN DIABETES IS DISCUSSED. UNDERSTANDING THE ROLE OF EPIGENETIC CHANGES IN PODOCYTES IN DIABETIC NEPHROPATHY MAY BE OF GREAT IMPORTANCE CONSIDERING THE INCREASING DIABETIC NEPHROPATHY PATIENT POPULATION IN AN AGING SOCIETY. 2021 14 6357 26 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 4195 23 METABOLIC MEMORY: MECHANISMS AND IMPLICATIONS FOR DIABETIC RETINOPATHY. CHRONIC HYPERGLYCEMIA OF DIABETES LEADS TO MICROVASCULAR COMPLICATIONS THAT SEVERELY IMPACT QUALITY OF LIFE. DIABETIC RETINOPATHY (DR) MAY BE THE MOST COMMON OF THESE AND IS A LEADING CAUSE OF VISUAL IMPAIRMENT AND BLINDNESS AMONG WORKING AGE ADULTS IN DEVELOPED NATIONS. MANY LARGE-SCALE TYPE 1 AND TYPE 2 DIABETES CLINICAL TRIALS HAVE DEMONSTRATED THAT EARLY INTENSIVE GLYCEMIC CONTROL CAN REDUCE THE INCIDENCE AND PROGRESSION OF MICRO AND MACROVASCULAR COMPLICATIONS. ON THE OTHER HAND, EPIDEMIOLOGICAL AND PROSPECTIVE DATA HAVE REVEALED THAT THE STRESSORS OF DIABETIC VASCULATURE PERSIST BEYOND THE POINT WHEN GLYCEMIC CONTROL HAS BEEN ACHIEVED. THESE KINDS OF PERSISTENT ADVERSE EFFECTS OF HYPERGLYCEMIA ON THE DEVELOPMENT AND PROGRESSION OF COMPLICATIONS HAS BEEN DEFINED AS "METABOLIC MEMORY", AND OXIDATIVE STRESS, ADVANCED GLYCATION END PRODUCTS AND EPIGENETIC CHANGES HAVE BEEN IMPLICATED IN THE PROCESS. RECENT STUDIES HAVE INDICATED THAT SUCH "HYPERGLYCEMIC MEMORY" MAY ALSO INFLUENCE DR, SUGGESTING THAT MANIPULATION OF HYPERGLYCEMIC MEMORY MAY PROVE A BENEFICIAL APPROACH TO PREVENTION AND TREATMENT. THIS REVIEW SUMMARIZES THE EVIDENCE FROM DR-RELATED CLINICAL TRIALS AND MECHANISTIC STUDIES TO INVESTIGATE THE SIGNIFICANCE OF METABOLIC MEMORY IN DR AND UNDERSTAND ITS POTENTIAL AS A TARGET OF MOLECULAR THERAPEUTICS AIMED AT REVERSING HYPERGLYCEMIC MEMORY. 2012 16 2210 23 EPIGENETIC MODIFICATIONS AND POTENTIAL NEW TREATMENT TARGETS IN DIABETIC RETINOPATHY. RETINOPATHY IS A DEBILITATING VASCULAR COMPLICATION OF DIABETES. AS WITH OTHER DIABETIC COMPLICATIONS, DIABETIC RETINOPATHY (DR) IS CHARACTERIZED BY THE METABOLIC MEMORY, WHICH HAS BEEN OBSERVED BOTH IN DR PATIENTS AND IN DR ANIMAL MODELS. EVIDENCES HAVE PROVIDED THAT AFTER A PERIOD OF POOR GLUCOSE CONTROL INSULIN OR DIABETES DRUG TREATMENT FAILS TO PREVENT THE DEVELOPMENT AND PROGRESSION OF DR EVEN WHEN GOOD GLYCEMIC CONTROL IS REINSTITUTED (GLUCOSE NORMALIZATION), SUGGESTING A METABOLIC MEMORY PHENOMENON. RECENT STUDIES ALSO UNDERLINE THE ROLE OF EPIGENETIC CHROMATIN MODIFICATIONS AS MEDIATORS OF THE METABOLIC MEMORY. INDEED, EPIGENETIC CHANGES MAY LEAD TO STABLE MODIFICATION OF GENE EXPRESSION, PARTICIPATING IN DR PATHOGENESIS. MOREOVER, INCREASING EVIDENCES SUGGEST THAT ENVIRONMENTAL FACTORS SUCH AS CHRONIC HYPERGLYCEMIA ARE IMPLICATED DR PROGRESSION AND MAY ALSO AFFECT THE EPIGENETIC STATE. HERE WE REVIEW RECENT FINDINGS DEMONSTRATING THE KEY ROLE OF EPIGENETICS IN THE PROGRESSION OF DR. FURTHER ELUCIDATION OF EPIGENETIC MECHANISMS, ACTING BOTH AT THE CIS- AND TRANS-CHROMATIN STRUCTURAL ELEMENTS, WILL YIELD NEW INSIGHTS INTO THE PATHOGENESIS OF DR AND WILL OPEN THE WAY FOR THE DISCOVERY OF NOVEL THERAPEUTIC TARGETS TO PREVENT DR PROGRESSION. 2014 17 6409 27 THE SIGNALING OF CELLULAR SENESCENCE IN DIABETIC NEPHROPATHY. DIABETIC NEPHROPATHY IS THE LEADING CAUSE OF CHRONIC KIDNEY DISEASE (CKD) IN WESTERN COUNTRIES. NOTABLY, IT HAS A RAPIDLY RISING PREVALENCE IN CHINA. THE PATIENTS, COMMONLY COMPLICATED WITH CARDIOVASCULAR DISEASES AND NEUROLOGIC DISORDERS, ARE AT HIGH RISK TO PROGRESS INTO END-STAGE RENAL DISEASE (ESRD) AND DEATH. HOWEVER, THE PATHOGENIC MECHANISMS OF DIABETIC NEPHROPATHY HAVE NOT BEEN DETERMINED. CELLULAR SENESCENCE, WHICH RECENTLY HAS GAINED BROAD ATTENTION, IS THOUGHT TO BE AN IMPORTANT PLAYER IN THE ONSET AND DEVELOPMENT OF DIABETIC NEPHROPATHY. IN THIS ISSUE, WE GENERALLY REVIEW THE MECHANISMS OF CELLULAR SENESCENCE IN DIABETIC NEPHROPATHY, WHICH INVOLVE TELOMERE ATTRITION, DNA DAMAGE, EPIGENETIC ALTERATIONS, MITOCHONDRIAL DYSFUNCTION, LOSS OF KLOTHO, WNT/BETA-CATENIN SIGNALING ACTIVATION, PERSISTENT INFLAMMATION, AND ACCUMULATION OF UREMIC TOXINS. MOREOVER, WE HIGHLIGHT THE POTENTIAL THERAPEUTIC TARGETS OF CELLULAR SENESCENCE IN DIABETIC NEPHROPATHY AND PROVIDE IMPORTANT CLUES FOR CLINICAL STRATEGIES. 2019 18 4763 22 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 19 6341 23 THE ROLE OF EPIGENETIC MODIFICATIONS IN LATE COMPLICATIONS IN TYPE 1 DIABETES. TYPE 1 DIABETES IS A CHRONIC AUTOIMMUNE DISEASE IN WHICH THE DESTRUCTION OF PANCREATIC BETA CELLS LEADS TO HYPERGLYCEMIA. THE PREVENTION OF HYPERGLYCEMIA IS VERY IMPORTANT TO AVOID OR AT LEAST POSTPONE THE DEVELOPMENT OF MICRO- AND MACROVASCULAR COMPLICATIONS, ALSO KNOWN AS LATE COMPLICATIONS. THESE INCLUDE DIABETIC RETINOPATHY, CHRONIC RENAL FAILURE, DIABETIC NEUROPATHY, AND CARDIOVASCULAR DISEASES. THE IMPACT OF LONG-TERM HYPERGLYCEMIA HAS BEEN SHOWN TO PERSIST LONG AFTER THE NORMALIZATION OF BLOOD GLUCOSE LEVELS, A PHENOMENON KNOWN AS METABOLIC MEMORY. IT IS BELIEVED THAT EPIGENETIC MECHANISMS SUCH AS DNA METHYLATION, HISTONE MODIFICATIONS, AND MICRORNAS, PLAY AN IMPORTANT ROLE IN METABOLIC MEMORY. THE AIM OF THIS REVIEW IS TO ADDRESS THE IMPACT OF LONG-TERM HYPERGLYCEMIA ON EPIGENETIC MARKS IN LATE COMPLICATIONS OF TYPE 1 DIABETES. 2022 20 1896 18 ENDOTHELIAL-TO-MESENCHYMAL TRANSITION: AN UNDERAPPRECIATED MEDIATOR OF DIABETIC COMPLICATIONS. DIABETES AND ITS COMPLICATIONS REPRESENT A GREAT BURDEN ON THE GLOBAL HEALTHCARE SYSTEM. DIABETIC COMPLICATIONS ARE FUNDAMENTALLY DISEASES OF THE VASCULATURE, WITH ENDOTHELIAL CELLS BEING THE CENTERPIECE OF EARLY HYPERGLYCEMIA-INDUCED CHANGES. ENDOTHELIAL-TO-MESENCHYMAL TRANSITION IS A TIGHTLY REGULATED PROCESS THAT RESULTS IN ENDOTHELIAL CELLS LOSING ENDOTHELIAL CHARACTERISTICS AND DEVELOPING MESENCHYMAL TRAITS. ALTHOUGH ENDOTHELIAL-TO-MESENCHYMAL TRANSITION HAS BEEN FOUND TO OCCUR WITHIN MOST OF THE MAJOR COMPLICATIONS OF DIABETES, IT HAS NOT BEEN A MAJOR FOCUS OF STUDY OR A COMMON TARGET IN THE TREATMENT OR PREVENTION OF DIABETIC COMPLICATIONS. IN THIS REVIEW WE SUMMARIZE THE IMPORTANCE OF ENDOTHELIAL-TO-MESENCHYMAL TRANSITION IN EACH MAJOR DIABETIC COMPLICATION, EXAMINE SPECIFIC MECHANISMS AT PLAY, AND HIGHLIGHT POTENTIAL MECHANISMS TO PREVENT ENDOTHELIAL-TO-MESENCHYMAL TRANSITION IN EACH OF THE MAJOR CHRONIC COMPLICATIONS OF DIABETES. 2023