1 6453 128 THIOREDOXIN INTERACTING PROTEIN (TXNIP) INDUCES INFLAMMATION THROUGH CHROMATIN MODIFICATION IN RETINAL CAPILLARY ENDOTHELIAL CELLS UNDER DIABETIC CONDITIONS. CHRONIC HYPERGLYCEMIA AND ACTIVATION OF RECEPTOR FOR ADVANCED GLYCATION END PRODUCTS (RAGE) ARE KNOWN RISK FACTORS FOR MICROVASCULAR DISEASE DEVELOPMENT IN DIABETIC RETINOPATHY. THIOREDOXIN-INTERACTING PROTEIN (TXNIP), AN ENDOGENOUS INHIBITOR OF ANTIOXIDANT THIOREDOXIN (TRX), PLAYS A CAUSATIVE ROLE IN DIABETES AND ITS VASCULAR COMPLICATIONS. HEREIN WE INVESTIGATE WHETHER HG AND RAGE INDUCE INFLAMMATION IN RAT RETINAL ENDOTHELIAL CELLS (EC) UNDER DIABETIC CONDITIONS IN CULTURE THROUGH TXNIP ACTIVATION AND WHETHER EPIGENETIC MECHANISMS PLAY A ROLE IN INFLAMMATORY GENE EXPRESSION. WE SHOW THAT RAGE ACTIVATION BY ITS LIGAND S100B OR HG TREATMENT OF RETINAL EC INDUCES THE EXPRESSION OF TXNIP AND INFLAMMATORY GENES SUCH AS COX2, VEGF-A, AND ICAM1. TXNIP SILENCING BY SIRNA IMPEDES RAGE AND HG EFFECTS WHILE STABLE OVER-EXPRESSION OF A CDNA FOR HUMAN TXNIP IN EC ELEVATES INFLAMMATION. P38 MAPK-NF-KAPPAB SIGNALING PATHWAY AND HISTONE H3 LYSINE (K) NINE MODIFICATIONS ARE INVOLVED IN TXNIP-INDUCED INFLAMMATION. CHROMATIN IMMUNOPRECIPITATION (CHIP) ASSAYS REVEAL THAT TXNIP OVER-EXPRESSION IN EC ABOLISHES H3K9 TRI-METHYLATION, A MARKER FOR GENE INACTIVATION, AND INCREASES H3K9 ACETYLATION, AN INDICATOR OF GENE INDUCTION, AT PROXIMAL COX2 PROMOTER BEARING THE NF-KAPPAB-BINDING SITE. THESE FINDINGS HAVE IMPORTANT IMPLICATIONS TOWARD UNDERSTANDING THE MOLECULAR MECHANISMS OF OCULAR INFLAMMATION AND ENDOTHELIAL DYSFUNCTION IN DIABETIC RETINOPATHY. 2009 2 868 31 CHRONIC ADVANCED-GLYCATION END PRODUCTS TREATMENT INDUCES TXNIP EXPRESSION AND EPIGENETIC CHANGES IN GLOMERULAR PODOCYTES IN VIVO AND IN VITRO. ADVANCED GLYCATION END PRODUCTS (AGES) PLAY AN IMPORTANT ROLE IN OXIDATIVE STRESS AND INFLAMMATION, PROCESSES IMPLICATED IN THE DEVELOPMENT AND PROGRESSION OF KIDNEY DYSFUNCTION. IN THE PRESENT STUDY, WE INVESTIGATED THE PARTICIPATION OF THE PRO-OXIDANT PROTEIN THIOREDOXIN-INTERACTING PROTEIN (TXNIP) AND OF EPIGENETIC MECHANISMS ON KIDNEY TISSUE (IN VIVO, IN NON-DIABETIC RATS) AND ON TERMINALLY DIFFERENTIATED GLOMERULAR PODOCYTES (IN VITRO) CHRONICALLY EXPOSED TO AGES. AGES INDUCED TOTAL KIDNEY AND GLOMERULAR TXNIP EXPRESSION AND DECREASED H3K27ME3 CONTENT. CONCOMITANT TREATMENT WITH THE ANTIOXIDANT N-ACETYL-CYSTEINE (NAC) REVERSED ONLY THE INCREASED TXNIP EXPRESSION. TXNIP EXPRESSION POSITIVELY CORRELATED WITH PROTEINURIA AND NEGATIVELY CORRELATED WITH H3K27ME3 CONTENT. IN VITRO STUDIES IN PODOCYTES SHOWED THAT 72 H EXPOSURE TO AGES DECREASED NEPHRIN EXPRESSION AND INCREASED TXNIP, NOX4, COL4A1, AND EPITHELIAL-TO-MESENCHYMAL TRANSITION (EMT) MARKERS (ACTA2, SNAIL1, AND TGFB1). PODOCYTES TREATMENT WITH NAC REVERSED NOX4, COL4A1, ACTA2, AND TGFB1 INCREASED EXPRESSION BUT DID NOT ABROGATE THE REDUCED EXPRESSION OF NEPHRIN. MIR-29A EXPRESSION WAS DOWNREGULATED BY AGES IN VIVO, BUT NOT IN VITRO. IN CONCLUSION, TREATMENT OF NON-DIABETIC RATS WITH AGES INDUCED TXNIP EXPRESSION AND DECREASED THE CONTENTS OF THE REPRESSIVE EPIGENETIC MARK H3K27ME3 AND OF MIR-29A, POTENTIALLY DRIVING INJURY TO GLOMERULAR FILTRATION BARRIER AND PODOCYTES DYSFUNCTION. 2021 3 799 38 CELLULAR SIGNALING AND POTENTIAL NEW TREATMENT TARGETS IN DIABETIC RETINOPATHY. DYSFUNCTION AND DEATH OF MICROVASCULAR CELLS AND IMBALANCE BETWEEN THE PRODUCTION AND THE DEGRADATION OF EXTRACELLULAR MATRIX (ECM) PROTEINS ARE A CHARACTERISTIC FEATURE OF DIABETIC RETINOPATHY (DR). GLUCOSE-INDUCED BIOCHEMICAL ALTERATIONS IN THE VASCULAR ENDOTHELIAL CELLS MAY ACTIVATE A CASCADE OF SIGNALING PATHWAYS LEADING TO INCREASED PRODUCTION OF ECM PROTEINS AND CELLULAR DYSFUNCTION/DEATH. CHRONIC DIABETES LEADS TO THE ACTIVATION OF A NUMBER OF SIGNALING PROTEINS INCLUDING PROTEIN KINASE C, PROTEIN KINASE B, AND MITOGEN-ACTIVATED PROTEIN KINASES. THESE SIGNALING CASCADES ARE ACTIVATED IN RESPONSE TO HYPERGLYCEMIA-INDUCED OXIDATIVE STRESS, POLYOL PATHWAY, AND ADVANCED GLYCATION END PRODUCT FORMATION AMONG OTHERS. THE ABERRANT SIGNALING PATHWAYS ULTIMATELY LEAD TO ACTIVATION OF TRANSCRIPTION FACTORS SUCH AS NUCLEAR FACTOR-KAPPAB AND ACTIVATING PROTEIN-1. THE ACTIVITY OF THESE TRANSCRIPTION FACTORS IS ALSO REGULATED BY EPIGENETIC MECHANISMS THROUGH TRANSCRIPTIONAL COACTIVATOR P300. THESE COMPLEX SIGNALING PATHWAYS MAY BE INVOLVED IN GLUCOSE-INDUCED ALTERATIONS OF ENDOTHELIAL CELL PHENOTYPE LEADING TO THE PRODUCTION OF INCREASED ECM PROTEINS AND VASOACTIVE EFFECTOR MOLECULES CAUSING FUNCTIONAL AND STRUCTURAL CHANGES IN THE MICROVASCULATURE. UNDERSTANDING OF SUCH MECHANISTIC PATHWAYS WILL HELP TO DEVELOP FUTURE ADJUVANT THERAPIES FOR DIABETIC RETINOPATHY. 2007 4 4902 35 OXIDATIVE-STRESS-INDUCED EPIGENETIC CHANGES IN CHRONIC DIABETIC COMPLICATIONS. OXIDATIVE STRESS PLAYS AN IMPORTANT ROLE IN THE DEVELOPMENT AND PROGRESSION OF CHRONIC DIABETIC COMPLICATIONS. DIABETES CAUSES MITOCHONDRIAL SUPEROXIDE OVERPRODUCTION IN THE ENDOTHELIAL CELLS OF BOTH LARGE AND SMALL VESSELS. THIS INCREASED SUPEROXIDE PRODUCTION CAUSES THE ACTIVATION OF SEVERAL SIGNAL PATHWAYS INVOLVED IN THE PATHOGENESIS OF CHRONIC COMPLICATIONS. IN PARTICULAR, ENDOTHELIAL CELLS ARE MAJOR TARGETS OF GLUCOSE-INDUCED OXIDATIVE DAMAGE IN THE TARGET ORGANS. OXIDATIVE STRESS ACTIVATES CELLULAR SIGNALING PATHWAYS AND TRANSCRIPTION FACTORS IN ENDOTHELIAL CELLS INCLUDING PROTEIN KINASE C (PKC), C-JUN-N-TERMINAL KINASE (JNK), P38 MITOGEN-ACTIVATED PROTEIN KINASE (MAPK), FORKHEAD BOX O (FOXO), AND NUCLEAR FACTOR KAPPA-B (NF-KAPPAB). OXIDATIVE STRESS ALSO CAUSES DNA DAMAGE AND ACTIVATES DNA NUCLEOTIDE EXCISION REPAIR ENZYMES INCLUDING THE EXCISION REPAIR CROSS COMPLIMENTING 1(ERCC1), ERCC4, AND POLY(ADP-RIBOSE) POLYMERASE (PARP). AUGMENTED PRODUCTION OF HISTONE ACETYLTRANSFERASE P300, AND ALTERATIONS OF HISTONE DEACETYLASES, INCLUDING CLASS III DEACETYLASES SIRTUINS, ARE ALSO INVOLVED IN THIS PROCESS. RECENT RESEARCH HAS FOUND THAT SMALL NONCODING RNAS, LIKE MICRORNA, ARE A NEW KIND OF REGULATOR ASSOCIATED WITH CHRONIC DIABETIC COMPLICATIONS. THERE ARE EXTENSIVE AND COMPLICATED INTERACTIONS AND AMONG THESE MOLECULES. THE PURPOSE OF THIS REVIEW IS TO DEMONSTRATE THE ROLE OF OXIDATIVE STRESS IN THE DEVELOPMENT OF DIABETIC COMPLICATIONS IN RELATION TO EPIGENETIC CHANGES SUCH AS ACETYLATION AND MICRORNA ALTERATIONS. 2013 5 141 28 ABERRANT DNA METHYLATION OF MTOR PATHWAY GENES PROMOTES INFLAMMATORY ACTIVATION OF IMMUNE CELLS IN DIABETIC KIDNEY DISEASE. DNA METHYLATION HAS BEEN IMPLICATED IN THE PATHOGENESIS OF DIABETIC KIDNEY DISEASE (DKD), BUT THE UNDERLYING MECHANISMS REMAIN UNCLEAR. IN THIS STUDY, WE TESTED THE HYPOTHESIS THAT ABERRANT DNA METHYLATION IN PERIPHERAL IMMUNE CELLS CONTRIBUTES TO DKD PROGRESSION. WE SHOWED THAT LEVELS OF DNA METHYLTRANSFERASE 1 (DNMT1), A KEY ENZYME FOR DNA METHYLATION, WERE INCREASED ALONG WITH INFLAMMATORY ACTIVITY OF PERIPHERAL BLOOD MONONUCLEAR CELLS IN DKD PATIENTS. INHIBITION OF DNMT1 WITH 5-AZA-2'-DEOXYCYTIDINE (5-AZA) MARKEDLY INCREASED THE PROPORTION OF CD4(+)CD25(+) REGULATORY T CELLS IN PERIPHERAL BLOOD MONONUCLEAR CELLS IN CULTURE AND IN DIABETIC ANIMALS. ADOPTIVE TRANSFER OF IMMUNE CELLS FROM 5-AZA-TREATED ANIMALS SHOWED BENEFICIAL EFFECTS ON THE HOST IMMUNE SYSTEM, RESULTING IN A SIGNIFICANT IMPROVEMENT OF DKD. USING GENOME-WIDE DNA METHYLATION ASSAYS, WE IDENTIFIED THE DIFFERENTIALLY METHYLATED CYTOSINES IN THE PROMOTER REGIONS OF MAMMALIAN TARGET OF RAPAMYCIN (MTOR) REGULATORS IN PERIPHERAL BLOOD MONONUCLEAR CELLS OF DIABETIC PATIENTS. FURTHER, MRNA ARRAYS CONFIRMED THE CONSISTENT INDUCTION OF GENES EXPRESSED IN THE MTOR PATHWAY. IMPORTANTLY, DOWN-REGULATION OF DNMT1 EXPRESSION VIA RNA INTERFERENCE RESULTED IN PROMINENT CYTOSINE DEMETHYLATION OF MTOR NEGATIVE REGULATORS AND SUBSEQUENT DECREASE OF MTOR ACTIVITY. LASTLY, MODULATION OF MTOR RESULTED IN CHANGES IN THE EFFECT OF 5-AZA ON DIABETIC IMMUNE CELLS. THUS, UP-REGULATION OF DNMT1 IN DIABETIC IMMUNE CELLS INDUCES ABERRANT CYTOSINE METHYLATION OF THE UPSTREAM REGULATORS OF MTOR, LEADING TO PATHOGENIC ACTIVATION OF THE MTOR PATHWAY AND CONSEQUENT INFLAMMATION IN DIABETIC KIDNEYS. HENCE, THIS STUDY HIGHLIGHTS THERAPEUTIC POTENTIAL OF TARGETING EPIGENETIC EVENTS IN IMMUNE SYSTEM FOR TREATING DKD. 2019 6 1382 42 DIABETES ALTERS ACTIVATION AND REPRESSION OF PRO- AND ANTI-INFLAMMATORY SIGNALING PATHWAYS IN THE VASCULATURE. A CENTRAL MECHANISM DRIVING VASCULAR DISEASE IN DIABETES IS IMMUNE CELL-MEDIATED INFLAMMATION. IN DIABETES, ENHANCED OXIDATION AND GLYCATION OF MACROMOLECULES, SUCH AS LIPOPROTEINS, INSULTS THE ENDOTHELIUM, AND ACTIVATES BOTH INNATE AND ADAPTIVE ARMS OF THE IMMUNE SYSTEM BY GENERATING NEW ANTIGENS FOR PRESENTATION TO ADAPTIVE IMMUNE CELLS. CHRONIC INFLAMMATION OF THE ENDOTHELIUM IN DIABETES LEADS TO CONTINUOUS INFILTRATION AND ACCUMULATION OF LEUKOCYTES AT SITES OF ENDOTHELIAL CELL INJURY. WE WILL DESCRIBE THE CENTRAL ROLE OF THE MACROPHAGE AS A SOURCE OF SIGNALING MOLECULES AND DAMAGING BY-PRODUCTS WHICH ACTIVATE INFILTRATING LYMPHOCYTES IN THE TISSUE AND CONTRIBUTE TO THE PRO-OXIDANT AND PRO-INFLAMMATORY MICROENVIRONMENT. AN IMPORTANT ASPECT TO BE CONSIDERED IS THE DIABETES-ASSOCIATED DEFECTS IN THE IMMUNE SYSTEM, SUCH AS FEWER OR DYSFUNCTIONAL ATHERO-PROTECTIVE LEUKOCYTE SUBSETS IN THE DIABETIC LESION COMPARED TO NON-DIABETIC LESIONS. THIS REVIEW WILL DISCUSS THE KEY PRO-INFLAMMATORY SIGNALING PATHWAYS RESPONSIBLE FOR LEUKOCYTE RECRUITMENT AND ACTIVATION IN THE INJURED VESSEL, WITH PARTICULAR FOCUS ON PRO- AND ANTI-INFLAMMATORY PATHWAYS ABERRANTLY ACTIVATED OR REPRESSED IN DIABETES. WE AIM TO DESCRIBE THE INTERACTION BETWEEN ADVANCED GLYCATION END PRODUCTS AND THEIR PRINCIPLE RECEPTOR RAGE, ANGIOTENSIN II, AND THE ANG II TYPE 1 RECEPTOR, IN ADDITION TO REACTIVE OXYGEN SPECIES (ROS) PRODUCTION BY NADPH-OXIDASE ENZYMES THAT ARE RELEVANT TO VASCULAR AND IMMUNE CELL FUNCTION IN THE CONTEXT OF DIABETIC VASCULOPATHY. FURTHERMORE, WE WILL TOUCH ON RECENT ADVANCES IN EPIGENETIC MEDICINE THAT HAVE REVEALED HIGH GLUCOSE-MEDIATED CHANGES IN THE TRANSCRIPTION OF GENES WITH KNOWN PRO-INFLAMMATORY DOWNSTREAM TARGETS. FINALLY, NOVEL ANTI-ATHEROSCLEROSIS STRATEGIES THAT TARGET THE VASCULAR IMMUNE INTERFACE WILL BE EXPLORED; SUCH AS VACCINATION AGAINST MODIFIED LOW-DENSITY LIPOPROTEIN AND PHARMACOLOGICAL INHIBITION OF ROS-PRODUCING ENZYMES. 2013 7 3527 29 IL-6 ENHANCES THE NUCLEAR TRANSLOCATION OF DNA CYTOSINE-5-METHYLTRANSFERASE 1 (DNMT1) VIA PHOSPHORYLATION OF THE NUCLEAR LOCALIZATION SEQUENCE BY THE AKT KINASE. THE EPIGENETIC PROGRAMMING OF GENOMIC DNA IS ACCOMPLISHED, IN PART, BY SEVERAL DNA CYTOSINE-5-METHYLTRANSFERASES THAT ACT BY COVALENTLY MODIFYING CYTOSINES WITH THE ADDITION OF A METHYL GROUP. THIS COVALENT MODIFICATION IS MAINTAINED BY THE DNA CYTOSINE-5-METHYLTRANSFERASE-1 ENZYME (DNMT1), WHICH IS CAPABLE OF ACTING IN CONCERT WITH OTHER SIMILAR ENZYMES TO SILENCE IMPORTANT TUMOR SUPPRESSOR GENES. IL-6 IS A MULTIFUNCTIONAL MEDIATOR OF INFLAMMATION, ACTING THROUGH SEVERAL MAJOR SIGNALING CASCADES, INCLUDING THE PHOSPHATIDYLINOSITOL-3-KINASE PATHWAY (PI-3-K), WHICH ACTIVATES PROTEIN KINASE B (AKT/PKB) DOWNSTREAM. HERE, WE SHOW THAT THE SUBCELLULAR LOCALIZATION OF DNMT1 CAN BE ALTERED BY THE ADDITION OF IL-6, INCREASING THE RATE OF NUCLEAR TRANSLOCATION OF THE ENZYME FROM THE CYTOSOLIC COMPARTMENT. THE MECHANISM OF NUCLEAR TRANSLOCATION OF DNMT1 IS GREATLY ENHANCED BY PHOSPHORYLATION OF THE DNMT1 NUCLEAR LOCALIZATION SIGNAL (NLS) BY PKB/AKT KINASE. MUTAGENIC ALTERATION OF THE TWO AKT TARGET AMINO ACIDS WITHIN THE NLS RESULTS IN A MAJOR LOSS OF DNMT1 NUCLEAR TRANSLOCATION, WHILE THE CREATION OF A "PHOSPHO-MIMIC" AMINO ACID (MUTATION TO ACIDIC RESIDUES) RESTORES THIS COMPARTMENTATION ABILITY. THESE OBSERVATIONS SUGGEST AN INTERESTING HYPOTHESIS REGARDING HOW MEDIATORS OF CHRONIC INFLAMMATION MAY DISTURB THE DELICATE BALANCE OF CELLULAR COMPARTMENTALIZATION OF IMPORTANT PROTEINS, AND REVEALS A POTENTIAL MECHANISM FOR THE INDUCTION OR ENHANCEMENT OF TUMOR GROWTH VIA ALTERATION OF THE COMPONENTS INVOLVED IN THE EPIGENETIC PROGRAMMING OF A CELL. 2007 8 1383 39 DIABETES AND ITS CARDIOVASCULAR COMPLICATIONS: POTENTIAL ROLE OF THE ACETYLTRANSFERASE P300. DIABETES HAS BEEN SHOWN TO ACCELERATE VASCULAR SENESCENCE, WHICH IS ASSOCIATED WITH CHRONIC INFLAMMATION AND OXIDATIVE STRESS, BOTH IMPLICATED IN THE DEVELOPMENT OF ENDOTHELIAL DYSFUNCTION. THIS CONDITION REPRESENTS THE INITIAL ALTERATION LINKING DIABETES TO RELATED CARDIOVASCULAR (CV) COMPLICATIONS. RECENTLY, IT HAS BEEN HYPOTHESISED THAT THE ACETYLTRANSFERASE, P300, MAY CONTRIBUTE TO ESTABLISHING AN EARLY VASCULAR SENESCENT PHENOTYPE, PLAYING A RELEVANT ROLE IN DIABETES-ASSOCIATED INFLAMMATION AND OXIDATIVE STRESS, WHICH DRIVE ENDOTHELIAL DYSFUNCTION. SPECIFICALLY, P300 CAN MODULATE VASCULAR INFLAMMATION THROUGH EPIGENETIC MECHANISMS AND TRANSCRIPTION FACTORS ACETYLATION. INDEED, IT REGULATES THE INFLAMMATORY PATHWAY BY INTERACTING WITH NUCLEAR FACTOR KAPPA-LIGHT-CHAIN-ENHANCER OF ACTIVATED B CELLS P65 SUBUNIT (NF-KAPPAB P65) OR BY INDUCING ITS ACETYLATION, SUGGESTING A CRUCIAL ROLE OF P300 AS A BRIDGE BETWEEN NF-KAPPAB P65 AND THE TRANSCRIPTIONAL MACHINERY. ADDITIONALLY, P300-MEDIATED EPIGENETIC MODIFICATIONS COULD BE UPSTREAM OF THE ACTIVATION OF INFLAMMATORY CYTOKINES, AND THEY MAY INDUCE OXIDATIVE STRESS BY AFFECTING THE PRODUCTION OF REACTIVE OXYGEN SPECIES (ROS). BECAUSE SEVERAL IN VITRO AND IN VIVO STUDIES SHED LIGHT ON THE POTENTIAL USE OF ACETYLTRANSFERASE INHIBITORS, A BETTER UNDERSTANDING OF THE MECHANISMS UNDERLYING THE ROLE OF P300 IN DIABETIC VASCULAR DYSFUNCTION COULD HELP IN FINDING NEW STRATEGIES FOR THE CLINICAL MANAGEMENT OF CV DISEASES RELATED TO DIABETES. 2023 9 273 34 AGE-INDUCED SUPPRESSION OF EZH2 MEDIATES INJURY OF PODOCYTES BY REDUCING H3K27ME3. BACKGROUND: CHRONIC HYPERGLYCEMIA, A PIVOTAL FEATURE OF DIABETES MELLITUS (DM), INITIATES THE FORMATION OF ADVANCED GLYCATION END PRODUCTS (AGES) AND THE DYSREGULATION OF EPIGENETIC MECHANISMS, WHICH MAY CAUSE INJURY TO RENAL PODOCYTES, A CENTRAL FEATURE OF DIABETIC KIDNEY DISEASE (DKD). PREVIOUS DATA OF OUR GROUP SHOWED THAT AGES SIGNIFICANTLY REDUCE THE EXPRESSION OF NIPP1 (NUCLEAR INHIBITOR OF PROTEIN PHOSPHATASE 1) IN PODOCYTES IN VITRO AS WELL AS IN HUMAN AND MURINE DKD. NIPP1 WAS SHOWN BY OTHERS TO INTERACT WITH ENHANCER OF ZESTE HOMOLOG 2 (EZH2), WHICH CATALYZES THE REPRESSIVE METHYLATION OF H3K27ME3 ON HISTONE 3. THEREFORE, WE HYPOTHESIZED THAT AGES CAN DIRECTLY INDUCE EPIGENETIC CHANGES IN PODOCYTES. METHODS: WE ANALYZED THE RELEVANCE OF AGES ON EZH2 EXPRESSION AND ACTIVITY IN A MURINE PODOCYTE CELL LINE. CELLS WERE TREATED WITH 5 MG/ML GLYCATED BSA FOR 24 H. TO DETERMINE THE MEANING OF EZH2 SUPPRESSION, EZH2 ACTIVITY WAS INHIBITED BY INCUBATING THE CELLS WITH THE PHARMACOLOGICAL METHYLTRANSFERASE INHIBITOR 3-DEAZANEPLANOCIN A; EZH2 EXPRESSION WAS REPRESSED WITH SIRNA. MRNA EXPRESSION WAS ANALYZED WITH REAL-TIME PCR, AND PROTEIN EXPRESSION WITH WESTERN BLOT. EZH2 EXPRESSION AND LEVEL OF H3K27 TRIMETHYLATION IN PODOCYTES OF DIABETIC DB/DB MICE, A MOUSE MODEL FOR TYPE 2 DM, WERE ANALYZED USING IMMUNOFLUORESCENCE. RESULTS: OUR DATA DEMONSTRATED THAT AGES DECREASE EZH2 EXPRESSION IN PODOCYTES AND CONSEQUENTLY REDUCE H3K27ME3. THIS SUPPRESSION OF EZH2 MIMICKED THE AGE EFFECTS AND CAUSED AN UPREGULATED EXPRESSION OF PATHOLOGICAL FACTORS THAT CONTRIBUTE TO PODOCYTE INJURY IN DKD. IN ADDITION, ANALYSES OF DB/DB MICE SHOWED SIGNIFICANTLY REDUCED H3K27ME3 AND EZH2 EXPRESSION IN PODOCYTES. MOREOVER, THE SUPPRESSION OF NIPP1 AND EZH2 SHOWED SIMILAR EFFECTS REGARDING PODOCYTE INJURY. CONCLUSIONS: OUR STUDIES PROVIDE A NOVEL PATHWAY HOW AGES CONTRIBUTE TO PODOCYTE INJURY AND THE FORMATION OF THE SO-CALLED METABOLIC MEMORY IN DKD. 2020 10 199 34 ACTIVATED HISTONE ACETYLTRANSFERASE P300/CBP-RELATED SIGNALLING PATHWAYS MEDIATE UP-REGULATION OF NADPH OXIDASE, INFLAMMATION, AND FIBROSIS IN DIABETIC KIDNEY. ACCUMULATING EVIDENCE IMPLICATES THE HISTONE ACETYLATION-BASED EPIGENETIC MECHANISMS IN THE PATHOETIOLOGY OF DIABETES-ASSOCIATED MICRO-/MACROVASCULAR COMPLICATIONS. DIABETIC KIDNEY DISEASE (DKD) IS A PROGRESSIVE CHRONIC INFLAMMATORY MICROVASCULAR DISORDER ULTIMATELY LEADING TO GLOMERULOSCLEROSIS AND KIDNEY FAILURE. WE HYPOTHESIZED THAT HISTONE ACETYLTRANSFERASE P300/CBP MAY BE INVOLVED IN MEDIATING DIABETES-ACCELERATED RENAL DAMAGE. IN THIS STUDY, WE AIMED AT INVESTIGATING THE POTENTIAL ROLE OF P300/CBP IN THE UP-REGULATION OF RENAL NADPH OXIDASE (NOX), REACTIVE OXYGEN SPECIES (ROS) PRODUCTION, INFLAMMATION, AND FIBROSIS IN DIABETIC MICE. DIABETIC C57BL/6J MICE WERE RANDOMIZED TO RECEIVE 10 MG/KG C646, A SELECTIVE P300/CBP INHIBITOR, OR ITS VEHICLE FOR 4 WEEKS. WE FOUND THAT IN THE KIDNEY OF C646-TREATED DIABETIC MICE, THE LEVEL OF H3K27AC, AN EPIGENETIC MARK OF ACTIVE GENE EXPRESSION, WAS SIGNIFICANTLY REDUCED. PHARMACOLOGICAL INHIBITION OF P300/CBP SIGNIFICANTLY DOWN-REGULATED THE DIABETES-INDUCED ENHANCED EXPRESSION OF NOX SUBTYPES, PRO-INFLAMMATORY, AND PRO-FIBROTIC MOLECULES IN THE KIDNEY OF MICE, AND THE GLOMERULAR ROS OVERPRODUCTION. OUR STUDY PROVIDES EVIDENCE THAT THE ACTIVATION OF P300/CBP ENHANCES ROS PRODUCTION, POTENTIALLY GENERATED BY UP-REGULATED NOX, INFLAMMATION, AND THE PRODUCTION OF EXTRACELLULAR MATRIX PROTEINS IN THE DIABETIC KIDNEY. THE DATA SUGGEST THAT P300/CBP-PHARMACOLOGICAL INHIBITORS MAY BE ATTRACTIVE TOOLS TO MODULATE DIABETES-ASSOCIATED PATHOLOGICAL PROCESSES TO EFFICIENTLY REDUCE THE BURDEN OF DKD. 2021 11 2965 44 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 6564 34 TRANSIENT EXPOSURE TO ELEVATED GLUCOSE LEVELS CAUSES PERSISTENT CHANGES IN DERMAL MICROVASCULAR ENDOTHELIAL CELL RESPONSES TO INJURY. BACKGROUND: THE PURPOSE OF THIS STUDY WAS TO DETERMINE WHETHER ELEVATED GLUCOSE CAN INDUCE A DERMAL MICROVASCULAR ENDOTHELIAL CELL METABOLIC MEMORY, THUS AFFECTING ANGIOGENESIS IN THE REPAIR PROCESS OF MAMMALIAN CUTANEOUS WOUND. WE HYPOTHESIZED THAT TRANSIENT ELEVATED GLUCOSE LEVELS CAUSE SUSTAINED ALTERATION OF ENDOTHELIAL CELL RESPONSES TO INJURY AND PERSISTENT EPIGENETIC CHANGES IN GENE EXPRESSION. METHODS: HUMAN DERMAL MICROVASCULAR ENDOTHELIAL CELLS WERE EXPOSED TO EXPERIMENTAL CONDITIONS WITH OR WITHOUT 30 MM D-GLUCOSE. THE CONTROL GROUP WAS MAINTAINED AT 5 MM D-GLUCOSE; WHILE IN THE TRANSIENT GLUCOSE GROUP, AFTER BEING EXPOSED TO 30 MM D-GLUCOSE FOR TWO DAYS, THEN BEING PUT UNDER THE CONTROL CONDITIONS DURING THE EXPERIMENT. BESIDES, IN THE WHOLE PROCESS OF THE EXPERIMENT, THE CHRONIC GLUCOSE GROUP WAS KEPT IN THE CONDITION WITH 30 MM D-GLUCOSE. PROLIFERATION, MIGRATION, TUBE FORMATION, GENE EXPRESSION AND HISTONE METHYLATION WERE ASSESSED FOR INDIVIDUAL CONDITIONS. RESULTS: TRANSIENT ELEVATED GLUCOSE CAUSED SUSTAINED EFFECTS ON ENDOTHELIAL CELL MIGRATION, TUBE FORMATION AND TIMP3 GENE EXPRESSION. THE EFFECTS ON TIMP3 EXPRESSION WERE ASSOCIATED WITH PERSISTENT CHANGES IN HISTONE MODIFICATION AT THE 5' END OF THE TIMP3 GENE, SUGGESTING AN EPIGENETIC EFFECT. CONCLUSIONS: HYPERGLYCEMIA INDUCED METABOLIC MEMORY COULD PROMOTE THE REGULATION OF TIMP3, AND IT CAN BE USED AS A POSSIBLE INNOVATIVE MOLECULAR TARGET FOR THERAPEUTIC INTERVENTION IN THE TREATMENT OF CHRONIC NON-HEALING DIABETIC WOUNDS. 2021 13 6902 38 [THE IMPACT OF CHROMATIN MODIFICATION ON THE DEVELOPMENT OF CHRONIC COMPLICATIONS IN PATIENTS WITH DIABETES]. DIABETES IS A CHRONIC, METABOLIC DISEASE. OVER 347 MILLION PEOPLE WORLDWIDE HAVE DIABETES. CHRONIC COMPLICATIONS (RETINOPATHY, NEPHROPATHY OR NEUROPATHY) ARE THE MAJOR DANGEROUS OUTCOME OF THIS DISEASE. RECENT STUDIES INDICATE A SIGNIFICANT ROLE OF EPIGENETIC REGULATION IN THE DEVELOPMENT OF CHRONIC COMPLICATIONS IN PATIENTS WITH DIABETES. HYPERGLYCEMIA COULD CAUSE ABNORMAL REGULATION OF THE ACTIVITY OF ENZYMES PARTICIPATING IN THE POST-TRANSLATIONAL HISTONE MODIFICATIONS (PTHMS) AND INITIATION OF CHANGES IN PATTERNS OF DNA METHYLATION. IT LEADS TO MODIFICATION OF CHROMATIN STRUCTURE. THESE EPIGENETIC ABNORMALITIES RESULT IN CHANGES IN THE EXPRESSION OF GENES INVOLVED IN DEVELOPMENT OF CHRONIC INFLAMMATION, SUCH AS NF-KAPPAB (NUCLEAR FACTOR KAPPAB GENE), TNFALPHA (TUMOR NECROSIS FACTOR A GENE), IL6 (INTERLEUKIN 6 GENE) OR MCP1 (MONOCYTE CHEMOATTRACTANT PROTEIN 1 GENE). IT ENHANCES ENDOTHELIAL CELL DYSFUNCTION, WHICH PLAYS AN IMPORTANT ROLE IN DEVELOPMENT OF CHRONIC, DIABETIC COMPLICATIONS. IN ADDITION, CAUSED BY HYPERGLYCEMIA EPIGENETIC MODIFICATIONS CHANGES IN STRUCTURE OF CHROMATIN EXPLAINS "METABOLIC MEMORY", A PHENOMENON OF PRESENCE OF PATHOLOGICAL PATHWAYS RELATED TO THE PROLONGED HYPERGLYCEMIA IN THE PAST, DESPITE MAINTAINING GOOD METABOLIC CONTROL LATER ON. 2015 14 3436 26 HYPERGLYCEMIC MEMORY OF INNATE IMMUNE CELLS PROMOTES IN VITRO PROINFLAMMATORY RESPONSES OF HUMAN MONOCYTES AND MURINE MACROPHAGES. IT HAS BEEN WELL ESTABLISHED THAT THE PRESENCE OF DIABETES IS ACCOMPANIED BY A CHRONIC INFLAMMATORY STATE PROMOTING VARIOUS DIABETES-ASSOCIATED COMPLICATIONS. ONE POTENTIAL DRIVER OF THIS ENHANCED INFLAMMATORY STATE IN PATIENTS WITH DIABETES IS HYPERGLYCEMIA. EVEN AFTER BLOOD GLUCOSE CONTROL IS ACHIEVED, DIABETES-ASSOCIATED COMPLICATIONS PERSIST, SUGGESTING THE PRESENCE OF A "HYPERGLYCEMIC MEMORY." INNATE IMMUNE CELLS, CRITICALLY INVOLVED IN VARIOUS COMPLICATIONS ASSOCIATED WITH DIABETES, CAN BUILD NONSPECIFIC, IMMUNOLOGICAL MEMORY (TRAINED IMMUNITY) VIA EPIGENETIC REGULATION. WE EXAMINE THE POTENTIAL INVOLVEMENT OF HYPERGLYCEMIA-INDUCED TRAINED IMMUNITY IN PROMOTING INFLAMMATION. OUR RESULTS SHOW THAT HYPERGLYCEMIA INDUCES A TRAINED PHENOTYPE IN VIVO IN MICE AND IN VITRO IN HUMAN MONOCYTES, REPRESENTATIVE BY AN INCREASED TNF-ALPHA SECRETION AFTER EX VIVO STIMULATION WITH LPS. THESE EFFECTS WERE LARGELY MEDIATED BY EPIGENETIC CHANGES CONTROLLED BY THE MIXED LINEAGE LEUKEMIA (MLL) FAMILY BECAUSE TREATMENT WITH THE MLL INHIBITOR MENIN-MLL DURING THE PROCESS OF TRAINED IMMUNITY ACQUISITION REPRESSED THE PROINFLAMMATORY PHENOTYPE. COLLECTIVELY, OUR RESULTS IDENTIFY A NOVEL LINK BETWEEN HYPERGLYCEMIA AND INFLAMMATION IN INNATE IMMUNE CELLS THAT MIGHT EXPLAIN THE INCREASED PROINFLAMMATORY STATE DURING DIABETES POTENTIALLY CONTRIBUTING TO THE DEVELOPMENT OF VARIOUS DIABETES-ASSOCIATED COMPLICATIONS. 2021 15 4574 31 MYOCARDIN-RELATED TRANSCRIPTION FACTOR A EPIGENETICALLY REGULATES RENAL FIBROSIS IN DIABETIC NEPHROPATHY. DIABETIC NEPHROPATHY (DN) IS ONE OF THE MOST COMMON COMPLICATIONS ASSOCIATED WITH DIABETES AND CHARACTERIZED BY RENAL MICROVASCULAR INJURY ALONG WITH ACCELERATED SYNTHESIS OF EXTRACELLULAR MATRIX PROTEINS CAUSING TUBULOINTERSTITIAL FIBROSIS. PRODUCTION OF TYPE I COLLAGEN, THE MAJOR COMPONENT OF EXTRACELLULAR MATRIX, IS AUGMENTED DURING RENAL FIBROSIS AFTER CHRONIC EXPOSURE TO HYPERGLYCEMIA. HOWEVER, THE TRANSCRIPTIONAL MODULATOR RESPONSIBLE FOR THE EPIGENETIC MANIPULATION LEADING TO INDUCTION OF TYPE I COLLAGEN GENES IS NOT CLEARLY DEFINED. WE SHOW HERE THAT TUBULOINTERSTITIAL FIBROSIS AS A RESULT OF DN WAS DIMINISHED IN MYOCARDIN-RELATED TRANSCRIPTION FACTOR A (MRTF-A) -DEFICIENT MICE. IN CULTURED RENAL TUBULAR EPITHELIAL CELLS AND THE KIDNEYS OF MICE WITH DN, MRTF-A WAS INDUCED BY GLUCOSE AND SYNERGIZED WITH GLUCOSE TO ACTIVATE COLLAGEN TRANSCRIPTION. NOTABLY, MRTF-A SILENCING LED TO THE DISAPPEARANCE OF PROMINENT HISTONE MODIFICATIONS INDICATIVE OF TRANSCRIPTIONAL ACTIVATION, INCLUDING ACETYLATED HISTONE H3K18/K27 AND TRIMETHYLATED HISTONE H3K4. DETAILED ANALYSIS REVEALED THAT MRTF-A RECRUITED P300, A HISTONE ACETYLTRANSFERASE, AND WD REPEAT-CONTAINING PROTEIN 5 (WDR5), A KEY COMPONENT OF THE HISTONE H3K4 METHYLTRANSFERASE COMPLEX, TO THE COLLAGEN PROMOTERS AND ENGAGED THESE PROTEINS IN TRANSCRIPTIONAL ACTIVATION. ESTRADIOL SUPPRESSED COLLAGEN PRODUCTION BY DAMPENING THE EXPRESSION AND BINDING ACTIVITY OF MRTF-A AND INTERFERING WITH THE INTERACTION BETWEEN P300 AND WDR5 IN RENAL EPITHELIAL CELLS. THEREFORE, TARGETING THE MRTF-A-ASSOCIATED EPIGENETIC MACHINERY MIGHT YIELD INTERVENTIONAL STRATEGIES AGAINST DN-ASSOCIATED RENAL FIBROSIS. 2015 16 4772 32 NUCLEAR SIRTUINS AND INFLAMMATORY SIGNALING PATHWAYS. THE REGULATION OF CHRONIC INFLAMMATION HAS RECEIVED CONSIDERABLE RESEARCH ATTENTION IN RECENT YEARS BECAUSE OF ITS CONTRIBUTION TO THE PATHOGENESIS OF CHRONIC DISEASES SUCH AS ARTHRITIS, DIABETES, METABOLIC SYNDROME AND OBESITY. THUS, STRATEGIES THAT INHIBIT THE INFLAMMATORY STATE MAY BE BENEFICIAL IN IMPROVING THE PATHOPHYSIOLOGY OF SEVERAL INFLAMMATION-RELATED DISORDERS. SIRTUINS ARE A FAMILY OF HISTONE DEACETYLASES THAT CONTAIN SEVEN ENZYMATIC ACTIVITIES IN MAMMALS (SIRT1-SIRT7) AND FUNCTION TO SUPPRESS GENE TRANSCRIPTION BY EPIGENETIC MECHANISMS. NUCLEAR SIRTUINS (SIRT 1, 2, 6 AND 7) IN PARTICULAR MAY PLAY AN IMPORTANT ROLE IN THE REGULATION OF INFLAMMATORY RESPONSES. IN THE PRESENT REVIEW, WE ASSESSED THE ROLES OF NUCLEAR SIRTUINS IN INFLAMMATORY REACTIONS: SIRT1 HAS BEEN SHOWN TO SUPPRESS NF-KAPPAB ACTIVITY, THE MASTER REGULATOR OF CELLULAR INFLAMMATORY RESPONSE, DECREASE COX-2 AND INOS PRODUCTION, AND INCREASE ANTIOXIDANT GENE EXPRESSION THAT SUPPRESSED INFLAMMATION. SIRT2 ACTIVITY INCLUDED THE DEACETYLATION OF P65 SUBUNIT OF NF-KAPPABETA AND RIP-1, WHILE SIRT6 HAS BEEN SHOWN TO INTERACT WITH P65/RELA BOUND TO THE NF-KAPPABETA PROMOTER REGION AND REPRESS TRANSCRIPTIONAL ACTIVITY. FURTHERMORE, RECENT STUDIES HAVE SHOWN THAT THE ABSENCE OF SIRT7 PRODUCED AN INCREASE IN INFLAMMATION, ILLUSTRATING THAT SIRT7 ALSO FUNCTIONED TO DECREASE INFLAMMATION. GIVEN THEIR SIGNIFICANT ROLES IN THE REGULATION OF CHRONIC INFLAMMATION, NUCLEAR SIRTUINS REPRESENT POTENTIAL THERAPEUTIC TARGETS IN THE CONTROL OF CHRONIC INFLAMMATORY DISEASES. 2017 17 2002 24 EPIGENETIC AND POST-TRANSCRIPTIONAL REPRESSION SUPPORT METABOLIC SUPPRESSION IN CHRONICALLY HYPOXIC GOLDFISH. GOLDFISH ENTER A HYPOMETABOLIC STATE TO SURVIVE CHRONIC HYPOXIA. WE RECENTLY DESCRIBED TISSUE-SPECIFIC CONTRIBUTIONS OF MEMBRANE LIPID COMPOSITION REMODELING AND MITOCHONDRIAL FUNCTION TO METABOLIC SUPPRESSION ACROSS DIFFERENT GOLDFISH TISSUES. HOWEVER, THE MOLECULAR AND ESPECIALLY EPIGENETIC FOUNDATIONS OF HYPOXIA TOLERANCE IN GOLDFISH UNDER METABOLIC SUPPRESSION ARE NOT WELL UNDERSTOOD. HERE WE SHOW THAT COMPONENTS OF THE MOLECULAR OXYGEN-SENSING MACHINERY ARE ROBUSTLY ACTIVATED ACROSS TISSUES IRRESPECTIVE OF HYPOXIA DURATION. INDUCTION OF GENE EXPRESSION OF ENZYMES INVOLVED IN DNA METHYLATION TURNOVER AND MICRORNA BIOGENESIS SUGGEST A ROLE FOR EPIGENETIC TRANSCRIPTIONAL AND POST-TRANSCRIPTIONAL SUPPRESSION OF GENE EXPRESSION IN THE HYPOXIA-ACCLIMATED BRAIN. CONVERSELY, MECHANISTIC TARGET OF RAPAMYCIN-DEPENDENT TRANSLATIONAL MACHINERY ACTIVITY IS NOT REDUCED IN LIVER AND WHITE MUSCLE, SUGGESTING THIS PATHWAY DOES NOT CONTRIBUTE TO LOWERING CELLULAR ENERGY EXPENDITURE. FINALLY, MOLECULAR EVIDENCE SUPPORTS PREVIOUSLY REPORTED CHRONIC HYPOXIA-DEPENDENT CHANGES IN MEMBRANE CHOLESTEROL, LIPID METABOLISM AND MITOCHONDRIAL FUNCTION VIA CHANGES IN TRANSCRIPTS INVOLVED IN CHOLESTEROL BIOSYNTHESIS, BETA-OXIDATION, AND MITOCHONDRIAL FUSION IN MULTIPLE TISSUES. OVERALL, THIS STUDY SHOWS THAT CHRONIC HYPOXIA ROBUSTLY INDUCES EXPRESSION OF OXYGEN-SENSING MACHINERY ACROSS TISSUES, INDUCES REPRESSIVE TRANSCRIPTIONAL AND POST-TRANSCRIPTIONAL EPIGENETIC MARKS ESPECIALLY IN THE CHRONIC HYPOXIA-ACCLIMATED BRAIN AND SUPPORTS A ROLE FOR MEMBRANE REMODELING AND MITOCHONDRIAL FUNCTION AND DYNAMICS IN PROMOTING METABOLIC SUPPRESSION. 2022 18 5972 26 TET REPRESSION AND INCREASED DNMT ACTIVITY SYNERGISTICALLY INDUCE ABERRANT DNA METHYLATION. CHRONIC INFLAMMATION IS DEEPLY INVOLVED IN VARIOUS HUMAN DISORDERS, SUCH AS CANCER, NEURODEGENERATIVE DISORDERS, AND METABOLIC DISORDERS. INDUCTION OF EPIGENETIC ALTERATIONS, ESPECIALLY ABERRANT DNA METHYLATION, IS ONE OF THE MAJOR MECHANISMS, BUT HOW IT IS INDUCED IS STILL UNCLEAR. HERE, WE FOUND THAT EXPRESSION OF TET GENES, METHYLATION ERASERS, WAS DOWNREGULATED IN INFLAMED MOUSE AND HUMAN TISSUES, AND THAT THIS WAS CAUSED BY UPREGULATION OF TET-TARGETING MIRNAS SUCH AS MIR20A, MIR26B, AND MIR29C, LIKELY DUE TO ACTIVATION OF NF-KAPPAB SIGNALING DOWNSTREAM OF IL-1BETA AND TNF-ALPHA. HOWEVER, TET KNOCKDOWN INDUCED ONLY MILD ABERRANT METHYLATION. NITRIC OXIDE (NO), PRODUCED BY NOS2, ENHANCED ENZYMATIC ACTIVITY OF DNA METHYLTRANSFERASES (DNMTS), METHYLATION WRITERS, AND NO EXPOSURE INDUCED MINIMAL ABERRANT METHYLATION. IN CONTRAST, A COMBINATION OF TET KNOCKDOWN AND NO EXPOSURE SYNERGISTICALLY INDUCED ABERRANT METHYLATION, INVOLVING GENOMIC REGIONS NOT METHYLATED BY EITHER ALONE. THE RESULTS SHOWED THAT A VICIOUS COMBINATION OF TET REPRESSION, DUE TO NF-KAPPAB ACTIVATION, AND DNMT ACTIVATION, DUE TO NO PRODUCTION, IS RESPONSIBLE FOR ABERRANT METHYLATION INDUCTION IN HUMAN TISSUES. 2020 19 6431 29 THE USE OF TARGETED NEXT GENERATION SEQUENCING TO EXPLORE CANDIDATE REGULATORS OF TGF-BETA1'S IMPACT ON KIDNEY CELLS. AIMS/HYPOTHESIS: TRANSFORMING GROWTH FACTOR-BETA (TGF-BETA1) PLAYS AN IMPORTANT REGULATORY ROLE IN THE PROGRESSION OF CHRONIC KIDNEY FAILURE. FURTHER, DAMAGE TO KIDNEY GLOMERULAR MESANGIAL CELLS IS CENTRAL TO THE PROGRESSION OF DIABETIC NEPHROPATHY. THE AIM OF THIS STUDY WAS TO EXPLORE THE GENETIC ASSOCIATIONS BETWEEN MRNA, MICRORNA, AND EPIGENETICS IN MESANGIAL CELLS IN RESPONSE TO TGF-BETA1. METHODS: THE REGULATORY EFFECTS OF TGF-BETA1 ON MESANGIAL CELLS WERE INVESTIGATED AT DIFFERENT MOLECULAR LEVELS BY TREATING MESANGIAL CELLS WITH TGF-BETA1 FOR 3 DAYS FOLLOWED BY GENOME-WIDE MIRNA, RNA, DNA METHYLATION, AND H3K27ME3 EXPRESSION PROFILING USING NEXT GENERATION SEQUENCING (NGS). RESULTS: OUR RESULTS PROVIDE THE FIRST COMPREHENSIVE, COMPUTATIONALLY INTEGRATED REPORT OF RNA-SEQ, MIRNA-SEQ, AND EPIGENOMIC ANALYSES ACROSS ALL GENETIC VARIATIONS, CONFIRMING THE OCCURRENCE OF DNA METHYLATION AND H3K27ME3 IN RESPONSE TO TGF-BETA1. OUR FINDINGS SHOW THAT THE EXPRESSION OF KLF7 AND GJA4 ARE INVOLVED IN TGF-BETA1 REGULATED DNA METHYLATION. OUR DATA ALSO PROVIDE EVIDENCE OF THE ASSOCIATION BETWEEN EPIGENETIC CHANGES AND THE EXPRESSION OF GENES CLOSELY RELATED TO TGF-BETA1 REGULATION. CONCLUSION: THIS STUDY HAS ADVANCED OUR CURRENT KNOWLEDGE OF MECHANISMS THAT CONTRIBUTE TO THE EXPRESSION OF TGF-BETA1-REGULATED GENES INVOLVED IN THE PATHOGENESIS OF KIDNEY DISEASE. THE MOLECULAR UNDERPINNINGS OF TGF-BETA1 STIMULATION OF KIDNEY CELLS WAS DETERMINED, THEREBY PROVIDING A ROBUST PLATFORM FOR FURTHER TARGET EXPLORATION. 2018 20 5293 28 PROTEASOMAL DEGRADATION OF THE HISTONE ACETYL TRANSFERASE P300 CONTRIBUTES TO BETA-CELL INJURY IN A DIABETES ENVIRONMENT. IN TYPE 2 DIABETES, AMYLOID OLIGOMERS, CHRONIC HYPERGLYCEMIA, LIPOTOXICITY, AND PRO-INFLAMMATORY CYTOKINES ARE DETRIMENTAL TO BETA-CELLS, CAUSING APOPTOSIS AND IMPAIRED INSULIN SECRETION. THE HISTONE ACETYL TRANSFERASE P300, INVOLVED IN REMODELING OF CHROMATIN STRUCTURE BY EPIGENETIC MECHANISMS, IS A KEY UBIQUITOUS ACTIVATOR OF THE TRANSCRIPTIONAL MACHINERY. IN THIS STUDY, WE REPORT THAT LOSS OF P300 ACETYL TRANSFERASE ACTIVITY AND EXPRESSION LEADS TO BETA-CELL APOPTOSIS, AND MOST IMPORTANTLY, THAT STRESS SITUATIONS KNOWN TO BE ASSOCIATED WITH DIABETES ALTER P300 LEVELS AND FUNCTIONAL INTEGRITY. WE FOUND THAT PROTEASOMAL DEGRADATION IS THE MECHANISM SUBSERVING P300 LOSS IN BETA-CELLS EXPOSED TO HYPERGLYCEMIA OR PRO-INFLAMMATORY CYTOKINES. WE ALSO REPORT THAT MELATONIN, A HORMONE PRODUCED IN THE PINEAL GLAND AND KNOWN TO PLAY KEY ROLES IN BETA-CELL HEALTH, PRESERVES P300 LEVELS ALTERED BY THESE TOXIC CONDITIONS. COLLECTIVELY, THESE DATA IMPLY AN IMPORTANT ROLE FOR P300 IN THE PATHOPHYSIOLOGY OF DIABETES. 2018