1 1725 145 DYSREGULATION OF INFLAMMATION, OXIDATIVE STRESS, AND GLUCOSE METABOLISM-RELATED GENES AND MIRNAS IN VISCERAL ADIPOSE TISSUE OF WOMEN WITH TYPE 2 DIABETES MELLITUS. BACKGROUND HUMAN VISCERAL ADIPOSE TISSUE (VAT), NOW IDENTIFIED AS AN ENDOCRINE ORGAN, PLAYS A SIGNIFICANT ROLE IN IMPAIRED FASTING GLUCOSE AND DIABETES THROUGH THE DEREGULATED METABOLISM AND ADIPOGENESIS OF VISCERAL ADIPOCYTES IN OBESITY. OUR STUDY FOCUSES ON EXPLORING THE LINK BETWEEN INFLAMMATION, OXIDATIVE STRESS, AND GLUCOSE METABOLISM-ASSOCIATED GENES WITH CORRESPONDING MIRNAS IN HUMAN VISCERAL ADIPOCYTES AND VAT FROM INDIVIDUALS WITH GLUCOSE METABOLISM DISORDERS. MATERIAL AND METHODS WE EXAMINED THE EXPRESSION OF ATM, NFKB1, SOD2, INSR, AND TIGAR, ALONG WITH THEIR RELATED MIRNAS USING PCR, IN TWO CONTEXTS:1 - DURING THE THREE-STAGE VISCERAL ADIPOGENESIS UNDER NORMAL GLUCOSE LEVELS (5.5 MILLIMOLES), INTERMITTENT, AND CHRONIC HYPERGLYCEMIA (30 MILLIMOLES).2 - IN VISCERAL ADIPOSE TISSUE FROM SUBJECTS (34 F, 18 M) WITH NORMAL GLUCOSE METABOLISM, IMPAIRED FASTING GLUCOSE, AND TYPE 2 DIABETES MELLITUS. RESULTS BOTH CHRONIC AND INTERMITTENT HYPERGLYCEMIA SIMILARLY INFLUENCED ATM, NFKB1, TIGAR, SOD2, INSR GENE EXPRESSION IN VISCERAL ADIPOCYTES, WITH CORRESPONDING CHANGES IN A FEW TESTED MIRNAS (EG, LET-7G-5P, MIR-145-5P, MIR-21-5P). ANTHROPOMETRIC AND BIOCHEMICAL PARAMETERS LED US TO FOCUS ON FEMALE SUBJECTS. OUR RESULTS SHOWED TRANSACTIVATION OF NFKB1, TIGAR, MIR-10B-5P, MIR-132-3P, MIR-20A-5P, MIR-21-5P, AND MIR-26A-5P EXCLUSIVELY IN TYPE 2 DIABETES MELLITUS. UPREGULATED MOLECULES (EXCLUDING MIR-10B-5P AND MIR-20A-5P) POSITIVELY CORRELATED WITH GLUCOSE METABOLISM MARKERS. CONCLUSIONS THE GENES STUDIED MAY UNDERGO MIRNA INTERFERENCES AND HYPERGLYCEMIC MEMORY IN VISCERAL ADIPOCYTES UNDER HYPERGLYCEMIC CONDITIONS. VAT FROM WOMEN WITH TYPE 2 DIABETES MELLITUS, BUT NOT WITH IMPAIRED FASTING GLUCOSE, SHOWED TRANSACTIVATED MIRNAS AND A MOLECULAR DYSREGULATION OF TIGAR AND NFKB1, POSSIBLY ENHANCING INFLAMMATION, OXIDATIVE STRESS, AND DISRUPTED GLUCOSE METABOLISM. THESE FINDINGS HIGHLIGHT THE EPIGENETIC AND MOLECULAR DISTURBANCES IN VAT RELATED TO GLUCOSE METABOLISM ABNORMALITIES. HOWEVER, ADDITIONAL RESEARCH IS NECESSARY TO FURTHER UNDERSTAND THEIR BIOLOGICAL SIGNIFICANCE. 2023 2 3359 27 HISTONE H4 LYSINE 16 ACETYLATION CONTROLS CENTRAL CARBON METABOLISM AND DIET-INDUCED OBESITY IN MICE. NONCOMMUNICABLE DISEASES (NCDS) ACCOUNT FOR OVER 70% OF DEATHS WORLD-WIDE. PREVIOUS WORK HAS LINKED NCDS SUCH AS TYPE 2 DIABETES (T2D) TO DISRUPTION OF CHROMATIN REGULATORS. HOWEVER, THE EXACT MOLECULAR ORIGINS OF THESE CHRONIC CONDITIONS REMAIN ELUSIVE. HERE, WE IDENTIFY THE H4 LYSINE 16 ACETYLTRANSFERASE MOF AS A CRITICAL REGULATOR OF CENTRAL CARBON METABOLISM. HIGH-THROUGHPUT METABOLOMICS UNVEIL A SYSTEMIC AMINO ACID AND CARBOHYDRATE IMBALANCE IN MOF DEFICIENT MICE, MANIFESTING IN T2D PREDISPOSITION. ORAL GLUCOSE TOLERANCE TESTING (OGTT) REVEALS DEFECTS IN GLUCOSE ASSIMILATION AND INSULIN SECRETION IN THESE ANIMALS. FURTHERMORE, MOF DEFICIENT MICE ARE RESISTANT TO DIET-INDUCED FAT GAIN DUE TO DEFECTS IN GLUCOSE UPTAKE IN ADIPOSE TISSUE. MOF-MEDIATED H4K16AC DEPOSITION CONTROLS EXPRESSION OF THE MASTER REGULATOR OF GLUCOSE METABOLISM, PPARG AND THE ENTIRE DOWNSTREAM TRANSCRIPTIONAL NETWORK. GLUCOSE UPTAKE AND LIPID STORAGE CAN BE RECONSTITUTED IN MOF-DEPLETED ADIPOCYTES IN VITRO BY ECTOPIC GLUT4 EXPRESSION, PPARGAMMA AGONIST THIAZOLIDINEDIONE (TZD) TREATMENT OR SIRT1 INHIBITION. HENCE, CHRONIC IMBALANCE IN H4K16AC PROMOTES A DESTABILISATION OF METABOLISM TRIGGERING THE DEVELOPMENT OF A METABOLIC DISORDER, AND ITS MAINTENANCE PROVIDES AN UNPRECEDENTED REGULATORY EPIGENETIC MECHANISM CONTROLLING DIET-INDUCED OBESITY. 2021 3 4891 35 OXIDATIVE STRESS AND INFLAMMATORY MARKERS IN PREDIABETES AND DIABETES. PREDIABETES IS A STATE OF ELEVATED PLASMA GLUCOSE IN WHICH THE THRESHOLD FOR DIABETES HAS NOT YET BEEN REACHED AND CAN PREDISPOSE TO THE DEVELOPMENT OF TYPE 2 DIABETES AND CARDIOVASCULAR DISEASES. INSULIN RESISTANCE AND IMPAIRED BETA-CELL FUNCTION ARE OFTEN ALREADY PRESENT IN PREDIABETES. HYPERGLYCEMIA CAN UPREGULATE MARKERS OF CHRONIC INFLAMMATION AND CONTRIBUTE TO INCREASED REACTIVE OXYGEN SPECIES (ROS) GENERATION, WHICH ULTIMATELY CAUSE VASCULAR DYSFUNCTION. CONVERSELY, INCREASED OXIDATIVE STRESS AND INFLAMMATION CAN LEAD TO INSULIN RESISTANCE AND IMPAIRED INSULIN SECRETION. PROPER TREATMENT OF HYPERGLYCEMIA AND INHIBITION OF ROS OVERPRODUCTION IS CRUCIAL FOR DELAYING ONSET OF DIABETES AND FOR PREVENTION OF CARDIOVASCULAR COMPLICATIONS. THUS, IT IS IMPERATIVE TO DETERMINE THE MECHANISMS INVOLVED IN THE PROGRESSION FROM PREDIABETES TO DIABETES INCLUDING A CLARIFICATION OF HOW OLD AND NEW MEDICATIONS AFFECT OXIDATIVE AND IMMUNE MECHANISMS OF DIABETES. IN THIS REVIEW, WE DISCUSS THE RELATIONSHIP BETWEEN OXIDATIVE STRESS AND HYPERGLYCEMIA ALONG WITH LINKS BETWEEN INFLAMMATION AND PREDIABETES. ADDITIONALLY, THE EFFECTS OF HYPERGLYCEMIC MEMORY, MICROVESICLES, MICRO-RNA, AND EPIGENETIC REGULATION ON INFLAMMATION, OXIDATIVE STATE, AND GLYCEMIC CONTROL ARE HIGHLIGHTED. ADIPOSE TISSUE AND THEIR INFLUENCE ON CHRONIC INFLAMMATION ARE ALSO BRIEFLY REVIEWED. FINALLY, THE ROLE OF IMMUNE-TARGETED THERAPIES AND ANTI-DIABETIC MEDICATION ON GLYCEMIC CONTROL AND OXIDATIVE STRESS ARE DISCUSSED. 2019 4 4433 32 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 5 5448 30 REPRESSION OF HDAC5 BY ACETATE RESTORES HYPOTHALAMIC-PITUITARY-OVARIAN FUNCTION IN TYPE 2 DIABETES MELLITUS. TYPE 2 DIABETES MELLITUS (T2DM) ACCOUNTS FOR 90-95 % OF WORLDWIDE DIABETES CASES AND IS PRIMARILY CHARACTERIZED BY INSULIN RESISTANCE. ITS PROGRESSION AS A CHRONIC METABOLIC DISEASE HAS BEEN LARGELY ASSOCIATED WITH FEMALE REPRODUCTIVE ABNORMALITIES, INCLUDING OVARIAN DYSFUNCTION WITH CONSEQUENT INFERTILITY. EPIGENETIC MODIFICATIONS HAVE BEEN SUGGESTED AS A POSSIBLE LINK TO METABOLIC COMORBIDITIES. WE THEREFORE HYPOTHESIZED THAT SHORT CHAIN FATTY ACIDS, ACETATE (ACA), A POTENTIAL HISTONE DEACETYLASE INHIBITOR (HDAC) AMELIORATES HYPOTHALAMIC-PITUITARY-OVARIAN (HPO) DYSFUNCTION IN T2DM. FEMALE WISTAR RATS WEIGHING 160-190 G WERE ALLOTTED INTO THREE GROUPS (N = 6/GROUP): CONTROL (VEHICLE; PO), T2D AND T2D + ACA (200 MG/KG; PO). T2DM WAS INDUCED BY FRUCTOSE ADMINISTRATION (10 %; W/V) FOR 6 WEEKS AND SINGLE DOSE OF STREPTOZOTOCIN (35 MG/KG; IP). THE PRESENT DATA SHOWED THAT IN ADDITION TO INSULIN RESISTANCE, INCREASED FASTING BLOOD GLUCOSE AND INSULIN, T2DM INDUCED ELEVATED PLASMA, HYPOTHALAMIC AND OVARIAN TRIGLYCERIDE, LIPID PEROXIDATION, TNF-ALPHA AND GLUTATHIONE DEPLETION. ASIDE, T2DM ALSO LED TO INCREASED PLASMA LACTATE PRODUCTION AND GAMMA-GLUTAMYL TRANSFERASE AS WELL AS DECREASED GONADOTROPINS/17BETA-ESTRADIOL. HISTOLOGICALLY, HYPOTHALAMUS, PITUITARY AND OVARIES REVEALED DISRUPTED NEURONAL CELLS/MODERATE HEMORRHAGE, ALTERED MORPHOLOGY/VASCULAR CONGESTIONS, AND DEGENERATED ANTRAL FOLLICLE/GRAAFIAN FOLLICLE WITH MILD FIBROSIS AND INFILTRATED INFLAMMATORY CELLS RESPECTIVELY IN T2D ANIMALS. INTERESTINGLY, THESE ALTERATIONS WERE ACCOMPANIED BY ELEVATED PLASMA/HYPOTHALAMIC HDAC5 AND ATTENUATED WHEN TREATED WITH ACETATE. THE PRESENT RESULTS DEMONSTRATE THAT T2DM INDUCES HPO DYSFUNCTION, WHICH IS ACCOMPANIED BY ELEVATED CIRCULATING/HYPOTHALAMIC HDAC5. THE RESULTS IN ADDITION SUGGEST THAT ACETATE RESTORES HPO FUNCTION IN T2DM BY SUPPRESSION OF HDAC5 AND ENHANCEMENT OF INSULIN SENSITIVITY. 2021 6 5090 24 PLACENTAL ADIPONECTIN GENE DNA METHYLATION LEVELS ARE ASSOCIATED WITH MOTHERS' BLOOD GLUCOSE CONCENTRATION. GROWING EVIDENCE SUGGESTS THAT EPIGENETIC PROFILE CHANGES OCCURRING DURING FETAL DEVELOPMENT IN RESPONSE TO IN UTERO ENVIRONMENT VARIATIONS COULD BE ONE OF THE MECHANISMS INVOLVED IN THE EARLY DETERMINANTS OF ADULT CHRONIC DISEASES. IN THIS STUDY, WE TESTED WHETHER MATERNAL GLYCEMIC STATUS IS ASSOCIATED WITH THE ADIPONECTIN GENE (ADIPOQ) DNA METHYLATION PROFILE IN PLACENTA TISSUE, IN MATERNAL CIRCULATING BLOOD CELLS, AND IN CORD BLOOD CELLS. WE FOUND THAT LOWER DNA METHYLATION LEVELS IN THE PROMOTER OF ADIPOQ ON THE FETAL SIDE OF THE PLACENTA WERE CORRELATED WITH HIGHER MATERNAL GLUCOSE LEVELS DURING THE SECOND TRIMESTER OF PREGNANCY (2-H GLUCOSE AFTER THE ORAL GLUCOSE TOLERANCE TEST; R(S) /= 30 KG/M(2), HAS BEEN INCREASING WORLDWIDE ON A PANDEMIC SCALE WITH ACCOMPANYING SYNDEMIC HEALTH PROBLEMS, INCLUDING GLUCOSE INTOLERANCE, INSULIN RESISTANCE (IR), AND DIABETES. IMPAIRED TISSUE SENSITIVITY TO INSULIN OR IR PARADOXICALLY LEADS TO DISEASES WITH AN INFLAMMATORY COMPONENT DESPITE HYPERINSULINEMIA. THEREFORE, AN EXCESS OF VISCERAL AT IN OBESITY INITIATES CHRONIC LOW-GRADE INFLAMMATORY CONDITIONS THAT INTERFERE WITH INSULIN SIGNALING VIA INSULIN RECEPTORS (INSRS). MOREOVER, IN RESPONSE TO IR, HYPERGLYCEMIA ITSELF STIMULATES A PRIMARILY DEFENSIVE INFLAMMATORY RESPONSE ASSOCIATED WITH THE SUBSEQUENT RELEASE OF NUMEROUS INFLAMMATORY CYTOKINES AND A REAL THREAT OF ORGAN FUNCTION DETERIORATION. IN THIS REVIEW, ALL COMPONENTS OF THIS VICIOUS CYCLE ARE CHARACTERIZED WITH PARTICULAR EMPHASIS ON THE INTERPLAY BETWEEN INSULIN SIGNALING AND BOTH THE INNATE AND ADAPTIVE IMMUNE RESPONSES RELATED TO OBESITY. INCREASED VISCERAL AT ACCUMULATION IN OBESITY SHOULD BE CONSIDERED THE MAIN ENVIRONMENTAL FACTOR RESPONSIBLE FOR THE DISRUPTION IN THE EPIGENETIC REGULATORY MECHANISMS IN THE IMMUNE SYSTEM, RESULTING IN AUTOIMMUNITY AND INFLAMMATION. 2023 9 1302 29 DEFECTIVE FUNCTIONAL BETA-CELL MASS AND TYPE 2 DIABETES IN THE GOTO-KAKIZAKI RAT MODEL. INCREASING EVIDENCE INDICATES THAT DECREASED FUNCTIONAL BETA-CELL MASS IS THE HALLMARK OF TYPE 2 DIABETES MELLITUS. THEREFORE, THE DEBATE FOCUSES ON THE POSSIBLE MECHANISMS RESPONSIBLE FOR ABNORMAL ISLET MICROENVIRONMENT, DECREASED BETA-CELL NUMBER, IMPAIRED BETA-CELL FUNCTION AND THEIR MULTIFACTORIAL ETIOLOGIES. THE INFORMATION AVAILABLE ON THE GOTO-KAKIZAKI/PAR RAT LINE, ONE OF THE BEST CHARACTERIZED ANIMAL MODELS OF SPONTANEOUS TYPE 2 DIABETES MELLITUS, ARE REVIEWED IN SUCH A PERSPECTIVE. WE PROPOSE THAT THE DEFECTIVE BETA-CELL MASS AND FUNCTION IN THE GOTO-KAKIZAKI/PAR MODEL REFLECT THE COMPLEX INTERACTIONS OF MULTIPLE PATHOGENIC PLAYERS, INCLUDING SEVERAL INDEPENDENT LOCI CONTAINING GENES RESPONSIBLE FOR SOME DIABETIC TRAITS (BUT NOT DECREASED BETA-CELL MASS), GESTATIONAL METABOLIC IMPAIRMENT INDUCING AN EPIGENETIC PROGRAMMING OF THE PANCREAS (DECREASED BETA-CELL NEOGENESIS), WHICH IS TRANSMITTED TO THE NEXT GENERATION, AND LOSS OF BETA-CELL DIFFERENTIATION DUE TO CHRONIC EXPOSURE TO HYPERGLYCEMIA, INFLAMMATORY MEDIATORS, OXIDATIVE STRESS AND PERTURBED ISLET MICROARCHITECTURE. 2007 10 44 35 A COMPREHENSIVE REVIEW ON HIGH -FAT DIET-INDUCED DIABETES MELLITUS: AN EPIGENETIC VIEW. MODERN LIFESTYLE, GENETICS, NUTRITIONAL OVERLOAD THROUGH HIGH-FAT DIET ATTRIBUTED PREVALENCE AND DIABETES OUTCOMES WITH VARIOUS COMPLICATIONS PRIMARILY DUE TO OBESITY IN WHICH ENERGY-DENSE DIETS FREQUENTLY AFFECT METABOLIC HEALTH. ONE POSSIBLE ISSUE USUALLY ASSOCIATED WITH ELEVATED CHRONIC FAT INTAKE IS INSULIN RESISTANCE, AND HYPERGLYCEMIA CONSTITUTES AN IMPORTANT FUNCTION IN ALTERING THE CARBOHYDRATES AND LIPIDS METABOLISM. SIMILARLY, IN ASSESSING HUMAN SUSCEPTIBILITY TO WEIGHT GAIN AND OBESITY, GENETIC VARIATIONS PLAY A CENTRAL ROLE, CONTRIBUTING TO KEEN INTEREST IN IDENTIFYING THE POSSIBLE ROLE OF EPIGENETICS AS A MEDIATOR OF GENE-ENVIRONMENTAL INTERACTIONS INFLUENCING THE PRODUCTION OF TYPE 2 DIABETES MELLITUS AND ITS RELATED CONCERNS. EPIGENETIC MODIFICATIONS ASSOCIATED WITH THE ACCEPTANCE OF A SEDENTARY LIFESTYLE AND ENVIRONMENTAL STRESS FACTORS IN RESPONSE TO ENERGY INTAKE AND EXPENDITURE IMBALANCES COMPLEMENT GENETIC ALTERATIONS AND LEAD TO THE PRODUCTION AND ADVANCEMENT OF METABOLIC DISORDERS SUCH AS DIABETES AND OBESITY. METHYLATION OF DNA, HISTONE MODIFICATIONS, AND INCREASES IN THE EXPRESSION OF NON-CODING RNAS CAN RESULT IN REDUCED TRANSCRIPTIONAL ACTIVITY OF KEY BETA-CELL GENES THUS CREATING INSULIN RESISTANCE. EPIGENETICS CONTRIBUTE TO CHANGES IN THE EXPRESSION OF THE UNDERLYING INSULIN RESISTANCE AND INSUFFICIENCY GENE NETWORKS, ALONG WITH LOW-GRADE OBESITY-RELATED INFLAMMATION, INCREASED ROS GENERATION, AND DNA DAMAGE IN MULTIORGANS. THIS REVIEW FOCUSED ON EPIGENETIC MECHANISMS AND METABOLIC REGULATIONS ASSOCIATED WITH HIGH-FAT DIET (HFD)-INDUCED DIABETES MELLITUS. 2022 11 4202 24 METABOLIC SYNDROME IN CHILDREN BORN SMALL-FOR-GESTATIONAL AGE. BEING BORN SMALL-FOR-GESTATIONAL AGE AND A RAPID INCREASE IN WEIGHT DURING EARLY CHILDHOOD AND INFANCY HAS BEEN STRONGLY LINKED WITH CHRONIC DISEASES, INCLUDING METABOLIC SYNDROME, WHICH HAS BEEN RELATED TO INTRAUTERINE LIFE ENVIRONMENT AND LINKED TO EPIGENETIC FETAL PROGRAMMING. METABOLIC SYNDROME INCLUDES WAIST CIRCUMFERENCE >/= 90(TH) PERCENTILE FOR AGE, SEX AND RACE, HIGHER LEVELS OF BLOOD PRESSURE, TRIGLYCERIDES AND FASTING GLUCOSE, AND LOW LEVELS OF HDL-CHOLESTEROL. INSULIN RESISTANCE MAY BE PRESENT AS EARLY AS 1 YEAR OF AGE, AND OBESITY AND/OR TYPE 2 DIABETES ARE MORE PREVALENT IN THOSE BORN SGA THAN THOSE BORN AGA. THE PROGRAMMING OF ADAPTIVE RESPONSES IN CHILDREN BORN SGA INCLUDES AN ASSOCIATION WITH INCREASED BLOOD PRESSURE, CHANGES IN ENDOTHELIAL FUNCTION, ARTERIAL PROPERTIES AND CORONARY DISEASE. EARLY INTERVENTIONS SHOULD BE DIRECTED TO APPROPRIATE MATERNAL NUTRITION, BEFORE AND DURING PREGNANCY, PROMOTION OF BREAST FEEDING, AND PREVENTION OF RAPID WEIGHT GAIN DURING INFANCY, AND TO PROMOTE A HEALTHY LIFESTYLE. 2011 12 5190 25 PRENATAL CAUSES OF KIDNEY DISEASE. IT HAS RECENTLY BEEN INCREASINGLY RECOGNISED THAT DISTURBED INTRA-UTERINE DEVELOPMENT MAY IMPACT ON RENAL AND CARDIOVASCULAR RISK IN ADULT LIFE, E.G. ALBUMINURIA AND CHRONIC KIDNEY DISEASE, HYPERTENSION, TYPE 2 DIABETES OR CARDIOVASCULAR EVENTS. ACCORDING TO BARKER'S HYPOTHESIS, WHEN RESOURCES IN UTERO ARE RESTRICTED, THEIR ALLOCATION TO THE DEVELOPMENT OF THE KIDNEY AND PANCREATIC ISLETS IS RESTRICTED TO GUARANTEE APPROPRIATE DEVELOPMENT OF THE BRAIN AND HEART. THE UNDERLYING EPIGENETIC MECHANISMS INVOLVE MODIFICATION OF GENE EXPRESSION BY ALTERED DNA METHYLATION AND HISTONE ACETYLATION AS WELL AS BY ALLOCATION OF STEM CELLS. THE RESULT OF THIS TRADE-OFF BETWEEN THE BRAIN AND KIDNEY DURING ORGANOGENESIS IS A DIMINISHED NUMBER OF NEPHRONS ('NEPHRON UNDERDOSING') WHICH PREDISPOSES TO ALBUMINURIA AND RISK OF CHRONIC KIDNEY DISEASE, AS WELL AS HYPERTENSION. IN PARALLEL, CHANGED APPETITE CENTRES, INSULIN RESISTANCE AND BETA-CELL DEVELOPMENT PREDISPOSE TO OBESITY, METABOLIC SYNDROME AND TYPE 2 DIABETES AND THE RESULTING RENAL SEQUELAE. NUMEROUS FACTORS MAY TRIGGER INTRA-UTERINE RESTRICTION OF FETAL GROWTH, SUCH AS UTERINE UNDERPERFUSION, MATERNAL MALNUTRITION, HYPERGLYCAEMIA AND HYPERINSULINAEMIA OF THE MOTHER, SMOKING OR MEDICATIONS. 2009 13 4459 29 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 14 4017 31 LOW-DOSE HYDRALAZINE REDUCES ALBUMINURIA AND GLOMERULOSCLEROSIS IN A MOUSE MODEL OF OBESITY-RELATED CHRONIC KIDNEY DISEASE. AIM: TO DETERMINE, USING A MOUSE MODEL OF OBESITY, WHETHER LOW-DOSE HYDRALAZINE PREVENTS OBESITY-RELATED CHRONIC KIDNEY DISEASE (CKD). METHODS: FROM 8 WEEKS OF AGE, MALE C57BL/6 MICE RECEIVED A HIGH-FAT DIET (HFD) OR CHOW, WITH OR WITHOUT LOW-DOSE HYDRALAZINE (25 MG/L) IN DRINKING WATER, FOR 24 WEEKS. BIOMETRIC AND METABOLIC VARIABLES, RENAL FUNCTION AND STRUCTURAL CHANGES, RENAL GLOBAL DNA METHYLATION, DNA METHYLATION PROFILE AND MARKERS OF RENAL FIBROSIS, INJURY, INFLAMMATION AND OXIDATIVE STRESS WERE ASSESSED. RESULTS: THE HFD-FED MICE DEVELOPED OBESITY, WITH GLUCOSE INTOLERANCE, HYPERINSULINAEMIA AND DYSLIPIDAEMIA. OBESITY INCREASED ALBUMINURIA AND GLOMERULOSCLEROSIS, WHICH WERE SIGNIFICANTLY AMELIORATED BY LOW-DOSE HYDRALAZINE IN THE ABSENCE OF A BLOOD PRESSURE-LOWERING EFFECT. OBESITY INCREASED RENAL GLOBAL DNA METHYLATION AND THIS WAS ATTENUATED BY LOW-DOSE HYDRALAZINE. HFD-INDUCED CHANGES IN METHYLATION OF INDIVIDUAL LOCI WERE ALSO SIGNIFICANTLY REVERSED BY LOW-DOSE HYDRALAZINE. OBESE MICE DEMONSTRATED INCREASED MARKERS OF KIDNEY FIBROSIS, INFLAMMATION AND OXIDATIVE STRESS, BUT THESE MARKERS WERE NOT SIGNIFICANTLY IMPROVED BY HYDRALAZINE. CONCLUSION: LOW-DOSE HYDRALAZINE AMELIORATED HFD-INDUCED ALBUMINURIA AND GLOMERULOSCLEROSIS, INDEPENDENT OF ALTERATIONS IN BIOMETRIC AND METABOLIC VARIABLES OR BLOOD PRESSURE REGULATION. ALTHOUGH THE PRECISE MECHANISM OF RENOPROTECTION IN OBESITY IS UNCLEAR, AN EPIGENETIC BASIS MAY BE IMPLICATED. THESE DATA SUPPORT REPURPOSING HYDRALAZINE AS A NOVEL THERAPY TO PREVENT CKD PROGRESSION IN OBESE PATIENTS. 2022 15 6205 31 THE INFLUENCE OF PLANT EXTRACTS AND PHYTOCONSTITUENTS ON ANTIOXIDANT ENZYMES ACTIVITY AND GENE EXPRESSION IN THE PREVENTION AND TREATMENT OF IMPAIRED GLUCOSE HOMEOSTASIS AND DIABETES COMPLICATIONS. DIABETES IS A COMPLEX METABOLIC DISORDER RESULTING EITHER FROM INSULIN RESISTANCE OR AN IMPAIRED INSULIN SECRETION. PROLONGED ELEVATED BLOOD GLUCOSE CONCENTRATION, THE KEY CLINICAL SIGN OF DIABETES, INITIATES AN ENHANCEMENT OF REACTIVE OXYGEN SPECIES DERIVED FROM GLUCOSE AUTOXIDATION AND GLYCOSYLATION OF PROTEINS. CONSEQUENTLY, CHRONIC OXIDATIVE STRESS OVERWHELMS CELLULAR ENDOGENOUS ANTIOXIDANT DEFENSES AND LEADS TO THE ACUTE AND LONG-STANDING STRUCTURAL AND FUNCTIONAL CHANGES OF MACROMOLECULES RESULTING IN IMPAIRED CELLULAR FUNCTIONING, CELL DEATH AND ORGAN DYSFUNCTION. THE OXIDATIVE STRESS PROVOKED CHAIN OF PATHOLOGICAL EVENTS OVER TIME CAUSE DIABETIC COMPLICATIONS SUCH AS NEPHROPATHY, PERIPHERAL NEUROPATHY, CARDIOMYOPATHY, RETINOPATHY, HYPERTENSION, AND LIVER DISEASE. UNDER DIABETIC CONDITIONS, ACCOMPANYING GENOME/EPIGENOME AND METABOLITE MARKERS ALTERATIONS MAY ALSO AFFECT GLUCOSE HOMEOSTASIS, PANCREATIC BETA-CELLS, MUSCLE, LIVER, AND ADIPOSE TISSUE. BY PROVIDING DEEPER GENETIC/EPIGENETIC INSIGHT OF DIRECT OR INDIRECT DIETARY EFFECTS, NUTRIGENOMICS OFFERS A PROMISING OPPORTUNITY TO IMPROVE THE QUALITY OF LIFE OF DIABETIC PATIENTS. NATURAL PLANT EXTRACTS, OR THEIR NATURALLY OCCURRING COMPOUNDS, WERE SHOWN TO BE VERY PROFICIENT IN THE PREVENTION AND TREATMENT OF DIFFERENT PATHOLOGIES ASSOCIATED WITH OXIDATIVE STRESS INCLUDING DIABETES AND ITS COMPLICATIONS. CONSIDERING THAT FOOD INTAKE IS ONE OF THE CRUCIAL COMPONENTS IN DIABETES' PREVALENCE, PROGRESSION AND COMPLICATIONS, THIS REVIEW SUMMARIZES THE EFFECT OF THE MAJOR PLANT SECONDARY METABOLITE AND PHYTOCONSTITUENTS ON THE ANTIOXIDANT ENZYMES ACTIVITY AND GENE EXPRESSION UNDER DIABETIC CONDITIONS. 2021 16 5251 28 PROGRAMMED INCREASES IN LXRALPHA INDUCED BY PATERNAL ALCOHOL USE ENHANCE OFFSPRING METABOLIC ADAPTATION TO HIGH-FAT DIET INDUCED OBESITY. OBJECTIVES: PATERNALLY INHERITED ALTERATIONS IN EPIGENETIC PROGRAMMING ARE EMERGING AS RELEVANT FACTORS IN NUMEROUS DISEASE STATES, INCLUDING THE GROWTH AND METABOLIC DEFECTS OBSERVED IN FETAL ALCOHOL SPECTRUM DISORDERS. IN RODENTS, CHRONIC PATERNAL ALCOHOL USE INDUCES FETAL GROWTH RESTRICTION, AS WELL AS SEX-SPECIFIC ALTERATIONS IN INSULIN SIGNALING AND LIPID HOMEOSTASIS IN THE OFFSPRING. BASED ON PREVIOUS STUDIES, WE HYPOTHESIZED THAT THE OBSERVED METABOLIC IRREGULARITIES ARE THE CONSEQUENCE OF PATERNALLY INHERITED ALTERATIONS LIVER X RECEPTOR (LXR) ACTIVITY. METHODS: MALE OFFSPRING OF ALCOHOL-EXPOSED SIRES WERE CHALLENGED WITH A HIGH-FAT DIET AND THE MOLECULAR PATHWAYS CONTROLLING GLUCOSE AND LIPID HOMEOSTASIS ASSAYED FOR LXR-INDUCED ALTERATIONS. RESULTS: SIMILAR TO FINDINGS IN STUDIES EMPLOYING LXR AGONISTS WE FOUND THAT THE MALE OFFSPRING OF ALCOHOL-EXPOSED SIRES DISPLAY RESISTANCE TO DIET-INDUCED OBESITY AND IMPROVED GLUCOSE HOMEOSTASIS WHEN CHALLENGED WITH A HIGH-FAT DIET. THIS IMPROVED METABOLIC ADAPTATION IS MEDIATED BY LXRALPHA TRANS-REPRESSION OF INFLAMMATORY CYTOKINES, RELEASING IKKBETA INHIBITION OF THE INSULIN SIGNALING PATHWAY. INTERESTINGLY, PATERNALLY PROGRAMMED INCREASES IN LXRALPHA EXPRESSION ARE LIVER-SPECIFIC AND DO NOT MANIFEST IN THE PANCREAS OR VISCERAL FAT. CONCLUSIONS: THESE STUDIES IDENTIFY LXRALPHA AS A KEY MEDIATOR OF THE LONG-TERM METABOLIC ALTERATIONS INDUCED BY PRECONCEPTION PATERNAL ALCOHOL USE. 2019 17 2964 20 GENETIC AND EPIGENETIC MECHANISMS UNDERLYING ARSENIC-ASSOCIATED DIABETES MELLITUS: A PERSPECTIVE OF THE CURRENT EVIDENCE. CHRONIC EXPOSURE TO ARSENIC HAS BEEN ASSOCIATED WITH THE DEVELOPMENT OF DIABETES MELLITUS (DM), A DISEASE CHARACTERIZED BY HYPERGLYCEMIA RESULTING FROM DYSREGULATION OF GLUCOSE HOMEOSTASIS. THIS REVIEW SUMMARIZES FOUR MAJOR MECHANISMS BY WHICH ARSENIC INDUCES DIABETES, NAMELY INHIBITION OF INSULIN-DEPENDENT GLUCOSE UPTAKE, PANCREATIC BETA-CELL DAMAGE, PANCREATIC BETA-CELL DYSFUNCTION AND STIMULATION OF LIVER GLUCONEOGENESIS THAT ARE SUPPORTED BY BOTH IN VIVO AND IN VITRO STUDIES. ADDITIONALLY, THE ROLE OF POLYMORPHIC VARIANTS ASSOCIATED WITH ARSENIC TOXICITY AND DISEASE SUSCEPTIBILITY, AS WELL AS EPIGENETIC MODIFICATIONS ASSOCIATED WITH ARSENIC EXPOSURE, ARE CONSIDERED IN THE CONTEXT OF ARSENIC-ASSOCIATED DM. TAKEN TOGETHER, IN VITRO, IN VIVO AND HUMAN GENETIC/EPIGENETIC STUDIES SUPPORT THAT ARSENIC HAS THE POTENTIAL TO INDUCE DM PHENOTYPES AND IMPAIR KEY PATHWAYS INVOLVED IN THE REGULATION OF GLUCOSE HOMEOSTASIS. 2017 18 2702 28 EXCITOTOXICITY AND OVERNUTRITION ADDITIVELY IMPAIR METABOLIC FUNCTION AND IDENTITY OF PANCREATIC BETA-CELLS. A SUSTAINED INCREASE IN INTRACELLULAR CA(2+) CONCENTRATION (REFERRED TO HEREAFTER AS EXCITOTOXICITY), BROUGHT ON BY CHRONIC METABOLIC STRESS, MAY CONTRIBUTE TO PANCREATIC BETA-CELL FAILURE. TO DETERMINE THE ADDITIVE EFFECTS OF EXCITOTOXICITY AND OVERNUTRITION ON BETA-CELL FUNCTION AND GENE EXPRESSION, WE ANALYZED THE IMPACT OF A HIGH-FAT DIET (HFD) ON ABCC8 KNOCKOUT MICE. EXCITOTOXICITY CAUSED BETA-CELLS TO BE MORE SUSCEPTIBLE TO HFD-INDUCED IMPAIRMENT OF GLUCOSE HOMEOSTASIS, AND THESE EFFECTS WERE MITIGATED BY VERAPAMIL, A CA(2+) CHANNEL BLOCKER. EXCITOTOXICITY, OVERNUTRITION, AND THE COMBINATION OF BOTH STRESSES CAUSED SIMILAR BUT DISTINCT ALTERATIONS IN THE BETA-CELL TRANSCRIPTOME, INCLUDING ADDITIVE INCREASES IN GENES ASSOCIATED WITH MITOCHONDRIAL ENERGY METABOLISM, FATTY ACID BETA-OXIDATION, AND MITOCHONDRIAL BIOGENESIS AND THEIR KEY REGULATOR PPARGC1A OVERNUTRITION WORSENED EXCITOTOXICITY-INDUCED MITOCHONDRIAL DYSFUNCTION, INCREASING METABOLIC INFLEXIBILITY AND MITOCHONDRIAL DAMAGE. IN ADDITION, EXCITOTOXICITY AND OVERNUTRITION, INDIVIDUALLY AND TOGETHER, IMPAIRED BOTH BETA-CELL FUNCTION AND IDENTITY BY REDUCING EXPRESSION OF GENES IMPORTANT FOR INSULIN SECRETION, CELL POLARITY, CELL JUNCTION, CILIA, CYTOSKELETON, VESICULAR TRAFFICKING, AND REGULATION OF BETA-CELL EPIGENETIC AND TRANSCRIPTIONAL PROGRAM. SEX HAD AN IMPACT ON ALL BETA-CELL RESPONSES, WITH MALE ANIMALS EXHIBITING GREATER METABOLIC STRESS-INDUCED IMPAIRMENTS THAN FEMALES. TOGETHER, THESE FINDINGS INDICATE THAT A SUSTAINED INCREASE IN INTRACELLULAR CA(2+), BY ALTERING MITOCHONDRIAL FUNCTION AND IMPAIRING BETA-CELL IDENTITY, AUGMENTS OVERNUTRITION-INDUCED BETA-CELL FAILURE. 2020 19 6163 32 THE GK RAT BETA-CELL: A PROTOTYPE FOR THE DISEASED HUMAN BETA-CELL IN TYPE 2 DIABETES? INCREASING EVIDENCE INDICATES THAT DECREASED FUNCTIONAL BETA-CELL MASS IS THE HALLMARK OF TYPE 2 DIABETES (T2D) MELLITUS. NOWADAYS, THE DEBATE FOCUSES ON THE POSSIBLE MECHANISMS RESPONSIBLE FOR ABNORMAL ISLET MICROENVIRONMENT, DECREASED BETA-CELL NUMBER, IMPAIRED BETA-CELL FUNCTION, AND THEIR MULTIFACTORIAL AETIOLOGIES. THIS REVIEW IS AIMED TO ILLUSTRATE TO WHAT EXTEND THE GOTO-KAKIZAKI RAT, ONE OF THE BEST CHARACTERIZED ANIMAL MODELS OF SPONTANEOUS T2D, HAS PROVED BE A VALUABLE TOOL OFFERING SUFFICIENT COMMONALITIES TO STUDY THESE ASPECTS. WE PROPOSE THAT THE DEFECTIVE BETA-CELL MASS AND FUNCTION IN THE GK MODEL REFLECT THE COMPLEX INTERACTIONS OF MULTIPLE PATHOGENIC PLAYERS: (I) SEVERAL INDEPENDENT LOCI CONTAINING GENES RESPONSIBLE FOR SOME DIABETIC TRAITS (BUT NOT DECREASED BETA-CELL MASS); (II) GESTATIONAL METABOLIC IMPAIRMENT INDUCING AN EPIGENETIC PROGRAMMING OF THE PANCREAS (DECREASED BETA-CELL NEOGENESIS AND/OR PROLIFERATION) WHICH IS TRANSMITTED TO THE NEXT GENERATION; AND (III) LOSS OF BETA-CELL DIFFERENTIATION DUE TO CHRONIC EXPOSURE TO HYPERGLYCEMIA/HYPERLIPIDEMIA, INFLAMMATORY MEDIATORS, OXIDATIVE STRESS AND TO PERTURBED ISLET MICROARCHITECTURE. 2009 20 6341 21 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