1 5716 120 SIRT6 PROTECTS VASCULAR SMOOTH MUSCLE CELLS FROM OSTEOGENIC TRANSDIFFERENTIATION VIA RUNX2 IN CHRONIC KIDNEY DISEASE. VASCULAR CALCIFICATION (VC) IS REGARDED AS AN IMPORTANT PATHOLOGICAL CHANGE LACKING EFFECTIVE TREATMENT AND ASSOCIATED WITH HIGH MORTALITY. SIRTUIN 6 (SIRT6) IS A MEMBER OF THE SIRTUIN FAMILY, A CLASS III HISTONE DEACETYLASE AND A KEY EPIGENETIC REGULATOR. SIRT6 HAS A PROTECTIVE ROLE IN PATIENTS WITH CHRONIC KIDNEY DISEASE (CKD). HOWEVER, THE EXACT ROLE AND MOLECULAR MECHANISM OF SIRT6 IN VC IN PATIENTS WITH CKD REMAIN UNCLEAR. HERE, WE DEMONSTRATED THAT SIRT6 WAS MARKEDLY DOWNREGULATED IN PERIPHERAL BLOOD MONONUCLEAR CELLS (PBMCS) AND IN THE RADIAL ARTERY TISSUE OF PATIENTS WITH CKD WITH VC. SIRT6-TRANSGENIC (SIRT6-TG) MICE SHOWED ALLEVIATED VC, WHILE VASCULAR SMOOTH MUSCLE CELL-SPECIFIC (VSMC-SPECIFIC) SIRT6 KNOCKED-DOWN MICE SHOWED SEVERE VC IN CKD. SIRT6 SUPPRESSED THE OSTEOGENIC TRANSDIFFERENTIATION OF VSMCS VIA REGULATION OF RUNT-RELATED TRANSCRIPTION FACTOR 2 (RUNX2). COIMMUNOPRECIPITATION (CO-IP) AND IMMUNOPRECIPITATION (IP) ASSAYS CONFIRMED THAT SIRT6 BOUND TO RUNX2. MOREOVER, RUNX2 WAS DEACETYLATED BY SIRT6 AND FURTHER PROMOTED NUCLEAR EXPORT VIA EXPORTIN 1 (XPO1), WHICH IN TURN CAUSED DEGRADATION OF RUNX2 THROUGH THE UBIQUITIN-PROTEASOME SYSTEM. THESE RESULTS DEMONSTRATED THAT SIRT6 PREVENTED VC BY SUPPRESSING THE OSTEOGENIC TRANSDIFFERENTIATION OF VSMCS, AND AS SUCH TARGETING SIRT6 MAY BE AN APPEALING THERAPEUTIC TARGET FOR VC IN CKD. 2022 2 364 44 AMELIORATION OF UREMIC TOXIN INDOXYL SULFATE-INDUCED OSTEOBLASTIC CALCIFICATION BY SET DOMAIN CONTAINING LYSINE METHYLTRANSFERASE 7/9 PROTEIN. BACKGROUND: VASCULAR CALCIFICATION (VC) IS A VERY COMMON PHENOMENON IN PATIENTS WITH CHRONIC KIDNEY DISEASE (CKD). IT HAS BEEN REPORTED THAT SOME HISTONE METHYLATION PLAY A ROLE IN VC AS AN EPIGENETIC REGULATOR. INDOXYL SULFATE (IS) IS A PROTEIN-BOUND UREMIC TOXIN THAT HAS BEEN PROVEN AS ONE OF THE MAJOR RISK FACTORS OF CARDIOVASCULAR DISEASE IN CKD. SET DOMAIN CONTAINING LYSINE METHYLTRANSFERASE 7/9 (SET7/9) IS ONE OF THE IMPORTANT HISTONE METHYLTRANSFERASES. OBJECTIVES: THIS STUDY AIMED TO DETERMINE THE EFFECT OF IS ON THE EXPRESSION OF SET7/9 AND THE ROLE OF SET7/9 IN IS-INDUCED OSTEOBLASTIC DIFFERENTIATION AND CALCIFICATION OF VASCULAR SMOOTH MUSCLE CELLS (VSMCS). METHODS: VSMCS WERE INCUBATED WITH VARIOUS CONCENTRATIONS OF IS FOR DIFFERENT DURATIONS TO ASSESS OSTEOBLASTIC DIFFERENTIATION AND EXPRESSION OF SET7/9. WESTERN BLOT ANALYSIS AND QUANTITATIVE REAL-TIME POLYMERASE CHAIN REACTION WERE PERFORMED TO ASSESS THE PROTEIN AND MRNA LEVELS OF SET7/9 RESPECTIVELY. THE CALCIUM CONTENT WAS MEASURED TO EVALUATE CALCIFICATION. RESULTS: OSTEOBLASTIC DIFFERENTIATION AND CALCIFICATION OF VSMCS AND DOWNREGULATION OF THE EXPRESSION OF SET7/9 WERE OBSERVED AFTER IS TREATMENT. THE AUTOPHAGY WAS ACTIVATED AFTER TREATMENT WITH IS, WHEREAS THE INHIBITION OF THE AUTOPHAGY PARTIALLY ATTENUATED THE EFFECT OF IS ON BOTH THE STIMULATION OF THE EXPRESSION OF RUNT-RELATED TRANSCRIPTION FACTOR 2 AND CALCIUM DEPOSITION. CONCLUSIONS: OUR DATA DEMONSTRATED THAT SET7/9 DOWNREGULATION AND AUTOPHAGY ACTIVATION MAY BE THE KEY MECHANISM OF IS-INDUCED VC IN CKD. 2019 3 3656 43 INDUCIBLE PRMT1 ABLATION IN ADULT VASCULAR SMOOTH MUSCLE LEADS TO CONTRACTILE DYSFUNCTION AND AORTIC DISSECTION. VASCULAR SMOOTH MUSCLE CELLS (VSMCS) HAVE REMARKABLE PLASTICITY IN RESPONSE TO DIVERSE ENVIRONMENTAL CUES. ALTHOUGH THESE CELLS ARE VERSATILE, CHRONIC STRESS CAN TRIGGER VSMC DYSFUNCTION, WHICH ULTIMATELY LEADS TO VASCULAR DISEASES SUCH AS AORTIC ANEURYSM AND ATHEROSCLEROSIS. PROTEIN ARGININE METHYLTRANSFERASE 1 (PRMT1) IS A MAJOR ENZYME CATALYZING ASYMMETRIC ARGININE DIMETHYLATION OF PROTEINS THAT ARE SOURCES OF ASYMMETRIC DIMETHYLARGININE (ADMA), AN ENDOGENOUS INHIBITOR OF NITRIC OXIDE SYNTHASE. ALTHOUGH A POTENTIAL ROLE OF PRMT1 IN VASCULAR PATHOGENESIS HAS BEEN PROPOSED, ITS ROLE IN VASCULAR FUNCTION HAS YET TO BE CLARIFIED. HERE, WE INVESTIGATED THE ROLE AND UNDERLYING MECHANISM OF PRMT1 IN VASCULAR SMOOTH MUSCLE CONTRACTILITY AND FUNCTION. THE EXPRESSION OF PRMT1 AND CONTRACTILE-RELATED GENES WAS SIGNIFICANTLY DECREASED IN THE AORTAS OF ELDERLY HUMANS AND PATIENTS WITH AORTIC ANEURYSMS. MICE WITH VSMC-SPECIFIC PRMT1 ABLATION (SMKO) EXHIBITED PARTIAL LETHALITY, LOW BLOOD PRESSURE AND AORTIC DILATION. THE PRMT1-ABLATED AORTAS SHOWED AORTIC DISSECTION WITH ELASTIC FIBER DEGENERATION AND CELL DEATH. EX VIVO AND IN VITRO ANALYSES INDICATED THAT PRMT1 ABLATION SIGNIFICANTLY DECREASED THE CONTRACTILITY OF THE AORTA AND TRACTION FORCES OF VSMCS. PRMT1 ABLATION DOWNREGULATED THE EXPRESSION OF CONTRACTILE GENES SUCH AS MYOCARDIN WHILE UPREGULATING THE EXPRESSION OF SYNTHETIC GENES, THUS CAUSING THE CONTRACTILE TO SYNTHETIC PHENOTYPIC SWITCH OF VSMCS. IN ADDITION, MECHANISTIC STUDIES DEMONSTRATED THAT PRMT1 DIRECTLY REGULATES MYOCARDIN GENE ACTIVATION BY MODULATING EPIGENETIC HISTONE MODIFICATIONS IN THE MYOCARDIN PROMOTER REGION. THUS, OUR STUDY DEMONSTRATES THAT VSMC PRMT1 IS ESSENTIAL FOR VASCULAR HOMEOSTASIS AND THAT ITS ABLATION CAUSES AORTIC DILATION/DISSECTION THROUGH IMPAIRED MYOCARDIN EXPRESSION. 2021 4 2378 31 EPIGENETIC REGULATION OF VASCULAR SMOOTH MUSCLE CELL PHENOTYPE SWITCHING IN ATHEROSCLEROTIC ARTERY REMODELING: A MINI-REVIEW. ATHEROSCLEROSIS IS A CHRONIC INFLAMMATORY DISEASE CHARACTERIZED BY EXTENSIVE REMODELING OF MEDIUM AND LARGE-SIZED ARTERIES. INWARD REMODELING (=LUMEN SHRINKAGE) OF THE VASCULAR WALLS IS THE UNDERLYING CAUSE FOR ISCHEMIA IN TARGET ORGANS. THEREFORE, INWARD REMODELING CAN BE CONSIDERED THE PREDOMINANT FEATURE OF ATHEROSCLEROTIC PATHOLOGY. OUTWARD REMODELING (=LUMEN ENLARGEMENT) IS A PHYSIOLOGICAL RESPONSE COMPENSATING FOR LUMEN SHRINKAGE CAUSED BY NEOINTIMAL HYPERPLASIA, BUT AS A PATHOLOGICAL RESPONSE TO CHANGES IN BLOOD FLOW, OUTWARD REMODELING LEADS TO SUBSTANTIAL ARTERIAL WALL THINNING. THINNED VASCULAR WALLS ARE PRONE TO RUPTURE, AND SUBSEQUENT THROMBUS FORMATION ACCOUNTS FOR THE MAJORITY OF ACUTE CARDIOVASCULAR EVENTS. PATHOLOGICAL REMODELING IS DRIVEN BY INFLAMMATORY CELLS WHICH INDUCE VASCULAR SMOOTH MUSCLE CELLS TO SWITCH FROM QUIESCENT TO A PROLIFERATIVE AND MIGRATORY PHENOTYPE. AFTER DECADES OF INTENSIVE RESEARCH, THE MOLECULAR MECHANISMS OF ARTERIAL REMODELING ARE STARTING TO UNFOLD. IN THIS MINI-REVIEW, WE SUMMARIZE THE CURRENT KNOWLEDGE OF THE EPIGENETIC AND TRANSCRIPTIONAL REGULATION OF VASCULAR SMOOTH MUSCLE CELL PHENOTYPE SWITCHING FROM THE CONTRACTILE TO THE SYNTHETIC PHENOTYPE INVOLVED IN ARTERIAL REMODELING AND DISCUSS POTENTIAL THERAPEUTIC OPTIONS. 2021 5 3295 49 HIGH PHOSPHATE-INDUCED DOWNREGULATION OF PPARGAMMA CONTRIBUTES TO CKD-ASSOCIATED VASCULAR CALCIFICATION. MEDIAL ARTERIAL CALCIFICATION ASSOCIATED WITH HYPERPHOSPHATEMIA IS A MAIN CAUSE OF CARDIOVASCULAR MORTALITY IN PATIENTS WITH CHRONIC KIDNEY DISEASE (CKD), BUT THE MECHANISMS UNDERLYING HIGH PHOSPHATE-INDUCED VASCULAR CALCIFICATION REMAIN LARGELY UNKNOWN. HERE, WE OBSERVED A SIGNIFICANT DECREASE IN THE EXPRESSION OF PEROXISOME PROLIFERATOR-ACTIVATED RECEPTOR-GAMMA (PPARGAMMA) IN CALCIFIED ARTERIES BOTH IN CKD PATIENTS AND IN A MOUSE MODEL OF CKD WITH HYPERPHOSPHATEMIA. IN VITRO, HIGH PHOSPHATE TREATMENT LED TO A DECREASED EXPRESSION OF PPARGAMMA IN MOUSE VASCULAR SMOOTH MUSCLE CELLS (VMSCS), ACCOMPANIED BY APPARENT OSTEOGENIC DIFFERENTIATION AND CALCIFICATION. PRETREATMENT WITH PPARGAMMA AGONIST ROSIGLITAZONE SIGNIFICANTLY REVERSED HIGH PHOSPHATE-INDUCED VSMCS CALCIFICATION. FURTHER INVESTIGATION SHOWED THAT METHYL-CPG BINDING PROTEIN 2 (MECP2)-MEDIATED EPIGENETIC REPRESSION WAS INVOLVED IN HIGH PHOSPHATE-INDUCED PPARGAMMA DOWNREGULATION. MOREOVER, THE EXPRESSION OF KLOTHO THAT HAS THE ABILITY TO INHIBIT VASCULAR CALCIFICATION BY REGULATING PHOSPHATE UPTAKE DECREASED WITH THE PPARGAMMA REDUCTION IN VSMCS AFTER HIGH PHOSPHATE TREATMENT, AND ROSIGLITAZONE FAILED TO INHIBIT HIGH PHOSPHATE-INDUCED CALCIFICATION IN VSMCS WITH KNOCKDOWN OF KLOTHO OR IN AORTIC RINGS FROM KLOTHO-DEFICIENT (KL/KL) MICE. FINALLY, AN IN VIVO STUDY DEMONSTRATED THAT ORAL ADMINISTRATION OF ROSIGLITAZONE COULD INCREASE KLOTHO EXPRESSION AND PROTECT AGAINST HIGH PHOSPHATE-INDUCED VASCULAR CALCIFICATION IN CKD MICE. THESE FINDINGS SUGGEST THAT THE INHIBITION OF PPARGAMMA EXPRESSION MAY CONTRIBUTE TO THE PATHOGENESIS OF HIGH PHOSPHATE-INDUCED VASCULAR CALCIFICATION, WHICH MAY PROVIDE A NEW THERAPEUTIC TARGET FOR VASCULAR CALCIFICATION IN CKD PATIENTS. 2018 6 6658 44 UPREGULATED LNCRNA H19 SPONGES MIR-106A-5P AND CONTRIBUTES TO ALDOSTERONE-INDUCED VASCULAR CALCIFICATION VIA ACTIVATING THE RUNX2-DEPENDENT PATHWAY. BACKGROUND: EXCESS ALDOSTERONE IS IMPLICATED IN VASCULAR CALCIFICATION (VC), BUT THE MECHANISM BY WHICH ALDOSTERONE-MR (MINERALOCORTICOID RECEPTOR) COMPLEX PROMOTES VC IS UNCLEAR. EMERGING EVIDENCE INDICATES THAT LONG-NONCODING RNA H19 (H19) PLAYS A CRITICAL ROLE IN VC. WE EXAMINED WHETHER ALDOSTERONE-INDUCED OSTEOGENIC DIFFERENTIATION OF VASCULAR SMOOTH MUSCLE CELLS (VSMCS) THROUGH H19 EPIGENETIC MODIFICATION OF RUNX2 (RUNT-RELATED TRANSCRIPTION FACTOR-2) IN A MR-DEPENDENT MANNER. METHODS: WE INDUCED IN VIVO RAT MODEL OF CHRONIC KIDNEY DISEASE USING A HIGH ADENINE AND PHOSPHATE DIET TO EXPLORE THE RELATIONSHIP AMONG ALDOSTERONE, MR, H19, AND VC. WE ALSO CULTURED HUMAN AORTIC VSMCS TO EXPLORE THE ROLES OF H19 IN ALDOSTERONE-MR COMPLEX-INDUCED OSTEOGENIC DIFFERENTIATION AND CALCIFICATION OF VSMCS. RESULTS: H19 AND RUNX2 WERE SIGNIFICANTLY INCREASED IN ALDOSTERONE-INDUCED VSMC OSTEOGENIC DIFFERENTIATION AND VC, BOTH IN VITRO AND IN VIVO, WHICH WERE SIGNIFICANTLY BLOCKED BY THE MR ANTAGONIST SPIRONOLACTONE. MECHANISTICALLY, OUR FINDINGS REVEAL THAT THE ALDOSTERONE-ACTIVATED MR BOUND TO H19 PROMOTER AND INCREASED ITS TRANSCRIPTIONAL ACTIVITY, AS DETERMINED BY CHROMATIN IMMUNOPRECIPITATION, ELECTROPHORETIC MOBILITY SHIFT ASSAY, AND LUCIFERASE REPORTER ASSAY. SILENCING H19 INCREASED MICRORNA-106A-5P (MIR-106A-5P) EXPRESSION, WHICH SUBSEQUENTLY INHIBITED ALDOSTERONE-INDUCED RUNX2 EXPRESSION AT THE POSTTRANSCRIPTIONAL LEVEL. IMPORTANTLY, WE OBSERVED A DIRECT INTERACTION BETWEEN H19 AND MIR-106A-5P, AND DOWNREGULATION OF MIR-106A-5P EFFICIENTLY REVERSED THE SUPPRESSION OF RUNX2 INDUCED BY H19 SILENCING. CONCLUSIONS: OUR STUDY CLARIFIES A NOVEL MECHANISM BY WHICH UPREGULATION OF H19 CONTRIBUTES TO ALDOSTERONE-MR COMPLEX-PROMOTED RUNX2-DEPENDENT VSMC OSTEOGENIC DIFFERENTIATION AND VC THROUGH SPONGING MIR-106A-5P. THESE FINDINGS HIGHLIGHT A POTENTIAL THERAPEUTIC TARGET FOR ALDOSTERONE-INDUCED VC. 2023 7 4415 37 MOLECULAR AND CELLULAR MECHANISMS THAT INDUCE ARTERIAL CALCIFICATION BY INDOXYL SULFATE AND P-CRESYL SULFATE. THE PROTEIN-BOUND UREMIC TOXINS, INDOXYL SULFATE (IS) AND P-CRESYL SULFATE (PCS), ARE CONSIDERED TO BE HARMFUL VASCULAR TOXINS. ARTERIAL MEDIA CALCIFICATION, OR THE DEPOSITION OF CALCIUM PHOSPHATE CRYSTALS IN THE ARTERIES, CONTRIBUTES SIGNIFICANTLY TO CARDIOVASCULAR COMPLICATIONS, INCLUDING LEFT VENTRICULAR HYPERTROPHY, HYPERTENSION, AND IMPAIRED CORONARY PERFUSION IN THE ELDERLY AND PATIENTS WITH CHRONIC KIDNEY DISEASE (CKD) AND DIABETES. RECENTLY, WE REPORTED THAT BOTH IS AND PCS TRIGGER MODERATE TO SEVERE CALCIFICATION IN THE AORTA AND PERIPHERAL VESSELS OF CKD RATS. THIS REVIEW DESCRIBES THE MOLECULAR AND CELLULAR MECHANISMS BY WHICH THESE UREMIC TOXINS INDUCE ARTERIAL MEDIA CALCIFICATION. A COMPLEX INTERPLAY BETWEEN INFLAMMATION, COAGULATION, AND LIPID METABOLISM PATHWAYS, INFLUENCED BY EPIGENETIC FACTORS, IS CRUCIAL IN IS/PCS-INDUCED ARTERIAL MEDIA CALCIFICATION. HIGH LEVELS OF GLUCOSE ARE LINKED TO THESE EVENTS, SUGGESTING THAT A GOOD BALANCE BETWEEN GLUCOSE AND LIPID LEVELS MIGHT BE IMPORTANT. ON THE CELLULAR LEVEL, EFFECTS ON ENDOTHELIAL CELLS, WHICH ACT AS THE PRIMARY SENSORS OF CIRCULATING PATHOLOGICAL TRIGGERS, MIGHT BE AS IMPORTANT AS THOSE ON VASCULAR SMOOTH MUSCLE CELLS. ENDOTHELIAL DYSFUNCTION, PROVOKED BY IS AND PCS TRIGGERED OXIDATIVE STRESS, MAY BE CONSIDERED A KEY EVENT IN THE ONSET AND DEVELOPMENT OF ARTERIAL MEDIA CALCIFICATION. IN THIS REVIEW A NUMBER OF IMPORTANT OUTSTANDING QUESTIONS SUCH AS THE ROLE OF MIRNA'S, PHENOTYPIC SWITCHING OF BOTH ENDOTHELIAL AND VASCULAR SMOOTH MUSCLE CELLS AND NEW TYPES OF PROGRAMMED CELL DEATH IN ARTERIAL MEDIA CALCIFICATION RELATED TO PROTEIN-BOUND UREMIC TOXINS ARE PUT FORWARD AND DISCUSSED. 2020 8 3654 45 INDOXYL SULFATE ACCELERATES VASCULAR SMOOTH MUSCLE CELL CALCIFICATION VIA MICRORNA-29B DEPENDENT REGULATION OF WNT/BETA-CATENIN SIGNALING. VASCULAR CALCIFICATION (VC) IS A VERY COMMON PHENOMENON IN PATIENTS WITH CHRONIC KIDNEY DISEASE(CKD) AND IT INCREASES THE INCIDENCE OF CARDIOVASCULAR DISEASE AND LEADS TO HIGH MORTALITY IN CKD PATIENTS. IT HAS BEEN REPORTED THAT SOME MICRORNAS (MIRS) PLAY ROLES IN VASCULAR CALCIFICATION AS AN EPIGENETIC REGULATOR. INDOXYL SULFATE (IS) IS A PROTEIN-BOUND UREMIC TOXIN WHICH HAS BEEN PROVEN AS ONE OF THE MAJOR RISK FACTORS OF CARDIOVASCULAR DISEASE IN CKD. HERE WE INVESTIGATED WHETHER MICRORNA-29B (MIR-29B) IS INVOLVED IN IS-INDUCED VASCULAR CALCIFICATION. WE FOUND THAT VASCULAR MIR-29B WAS DOWN-REGULATED IN RADIAL ARTERIES OF PATIENTS WITH END-STAGE RENAL DISEASE. CONSISTENTLY, IS ALSO DECREASED MIR-29B EXPRESSION IN HUMAN AORTIC SMOOTH MUSCLE CELLS (HASMCS) AND POTENTIATED THEIR CALCIFICATION. MIR-29B MIMICS SIGNIFICANTLY SUPPRESSED, WHILE MIR-29B ANTI-MIR MARKEDLY ENHANCED, IS-INDUCED RUNT-RELATED TRANSCRIPTION FACTOR 2 AND OSTEOPONTIN EXPRESSION. THE EXPRESSION OF WNT7B/BETA-CATENIN IN RADIAL ARTERIES WAS HIGHER IN END STAGE RENAL DISEASE THAN IN CONTROL GROUP, AND IS INCREASED WNT7B/BETA-CATENIN EXPRESSION IN HASMCS AS EARLY AS 3DAYS AFTER STIMULATION. FURTHERMORE, MIR-29B MIMICS POTENTLY REPRESSED WNT7B/BETA-CATENIN PROTEIN EXPRESSION IN HASMCS, WHEREAS MIR-29B ANTI-MIR INCREASED THEIR EXPRESSION, INDICATING MIR-29B INDEED NEGATIVELY REGULATES WNT7B/BETA-CATENIN SIGNALING. DICKKOPF-1 PROTEIN, THE WNT/BETA-CATENIN SIGNALING INHIBITOR, SUPPRESSED ANTI-MIR-29B-ENHANCED HASMCS CALCIFICATION. OUR DATA THUS INDICATE THAT MIR-29B DOWNREGULATION AND WNT/BETA-CATENIN SIGNALING ACTIVATION MAY BE THE KEY MECHANISM OF IS INDUCED VASCULAR CALCIFICATION IN CHRONIC KIDNEY DISEASE. 2018 9 3655 38 INDOXYL SULFATE ENHANCE THE HYPERMETHYLATION OF KLOTHO AND PROMOTE THE PROCESS OF VASCULAR CALCIFICATION IN CHRONIC KIDNEY DISEASE. CHRONIC KIDNEY DISEASE (CKD) IS A STATE OF KLOTHO DEFICIENCY. THE KLOTHO EXPRESSION MAY BE SUPPRESSED DUE TO DNA HYPERMETHYLATION IN CANCER CELLS SO WE HAVE INVESTIGATED THE EFFECTS AND POSSIBLE MECHANISMS BY WHICH KLOTHO EXPRESSION IS REGULATED IN HUMAN AORTIC SMOOTH MUSCLE CELLS (HASMCS). THE VASCULAR KLOTHO HYPERMETHYLATION IN RADIAL ARTERIES OF PATIENTS WITH END-STAGE RENAL DISEASE WAS DESCRIBED. CULTURED HASMCS AND 5/6-NEPHRECTOMIZED SPRAGUE DAWLEY (SD) RATS TREATED WITH INDOXYL SULFATE (IS) WERE USED AS IN VITRO AND IN VIVO MODELS, RESPECTIVELY. IS INCREASED CPG HYPERMETHYLATION OF THE KLOTHO GENE AND DECREASED KLOTHO EXPRESSION IN HASMCS, AND POTENTIATED HASMCS CALCIFICATION. THE EXPRESSION OF DNA METHYLTRANSFERASE (DNMT) 1 AND 3A IN HASMCS TREATED WITH IS WAS SIGNIFICANTLY INCREASED AND SPECIFIC INHIBITION OF DNA METHYLTRANSFERASE 1 BY 5-AZA-2'-DEOXYCYTIDINE(5AZA-2DC) CAUSED DEMETHYLATION OF THE KLOTHO GENE AND INCREASED KLOTHO EXPRESSION. IN RATS, INJECTION OF IS POTENTIATED VASCULAR CALCIFICATION, INCREASED CPG HYPERMETHYLATION OF THE KLOTHO GENE AND DECREASED KLOTHO EXPRESSION IN THE AORTIC MEDIAL LAYER AND ALL OF THESE CHANGES COULD BE REVERTED BY 5AZA-2DC TREATMENT. TRANSCRIPTIONAL SUPPRESSION OF VASCULAR KLOTHO GENE EXPRESSION BY IS AND EPIGENETIC MODIFICATION OF KLOTHO BY IS MAY BE AN IMPORTANT PATHOLOGICAL MECHANISM OF VASCULAR CALCIFICATION IN CKD. 2016 10 5596 36 ROLES OF HISTONE ACETYLATION MODIFIERS AND OTHER EPIGENETIC REGULATORS IN VASCULAR CALCIFICATION. VASCULAR CALCIFICATION (VC) IS CHARACTERIZED BY CALCIUM DEPOSITION INSIDE ARTERIES AND IS CLOSELY ASSOCIATED WITH THE MORBIDITY AND MORTALITY OF ATHEROSCLEROSIS, CHRONIC KIDNEY DISEASE, DIABETES, AND OTHER CARDIOVASCULAR DISEASES (CVDS). VC IS NOW WIDELY KNOWN TO BE AN ACTIVE PROCESS OCCURRING IN VASCULAR SMOOTH MUSCLE CELLS (VSMCS) INVOLVING MULTIPLE MECHANISMS AND FACTORS. THESE MECHANISMS SHARE FEATURES WITH THE PROCESS OF BONE FORMATION, SINCE THE PHENOTYPE SWITCHING FROM THE CONTRACTILE TO THE OSTEOCHONDROGENIC PHENOTYPE ALSO OCCURS IN VSMCS DURING VC. IN ADDITION, VC CAN BE REGULATED BY EPIGENETIC FACTORS, INCLUDING DNA METHYLATION, HISTONE MODIFICATION, AND NONCODING RNAS. ALTHOUGH VC IS COMMONLY OBSERVED IN PATIENTS WITH CHRONIC KIDNEY DISEASE AND CVD, SPECIFIC DRUGS FOR VC HAVE NOT BEEN DEVELOPED. THUS, DISCOVERING NOVEL THERAPEUTIC TARGETS MAY BE NECESSARY. IN THIS REVIEW, WE SUMMARIZE THE CURRENT EXPERIMENTAL EVIDENCE REGARDING THE ROLE OF EPIGENETIC REGULATORS INCLUDING HISTONE DEACETYLASES AND PROPOSE THE THERAPEUTIC IMPLICATION OF THESE REGULATORS IN THE TREATMENT OF VC. 2020 11 6700 39 VASCULAR CALCIFICATION MECHANISMS: UPDATES AND RENEWED INSIGHT INTO SIGNALING PATHWAYS INVOLVED IN HIGH PHOSPHATE-MEDIATED VASCULAR SMOOTH MUSCLE CELL CALCIFICATION. VASCULAR CALCIFICATION (VC) IS ASSOCIATED WITH AGING, CARDIOVASCULAR AND RENAL DISEASES AND RESULTS IN POOR MORBIDITY AND INCREASED MORTALITY. VC OCCURS IN PATIENTS WITH CHRONIC KIDNEY DISEASE (CKD), A CONDITION THAT IS ASSOCIATED WITH HIGH SERUM PHOSPHATE (PI) AND SEVERE CARDIOVASCULAR CONSEQUENCES. HIGH SERUM PI LEVEL IS RELATED TO SOME PATHOLOGIES WHICH AFFECT THE BEHAVIOUR OF VASCULAR CELLS, INCLUDING PLATELETS, ENDOTHELIAL CELLS (ECS) AND SMOOTH MUSCLE CELLS (SMCS), AND PLAYS A CENTRAL ROLE IN PROMOTING VC. VC IS A COMPLEX, ACTIVE AND CELL-MEDIATED PROCESS INVOLVING THE TRANSDIFFERENTIATION OF VASCULAR SMCS TO A BONE-LIKE PHENOTYPE, SYSTEMIC INFLAMMATION, DECREASED ANTI-CALCIFIC EVENTS (LOSS OF CALCIFICATION INHIBITORS), LOSS IN SMC LINEAGE MARKERS AND ENHANCED PRO-CALCIFIC MICRORNAS (MIRS), AN INCREASED INTRACELLULAR CALCIUM LEVEL, APOPTOSIS, ABERRANT DNA DAMAGE RESPONSE (DDR) AND SENESCENCE OF VASCULAR SMCS. THIS REVIEW GIVES A BRIEF OVERVIEW OF THE CURRENT KNOWLEDGE OF VC MECHANISMS WITH A PARTICULAR FOCUS ON PI-INDUCED CHANGES IN THE VASCULAR WALL IMPORTANT IN PROMOTING CALCIFICATION. IN ADDITION TO REVIEWING THE MAIN FINDINGS, THIS REVIEW ALSO SHEDS LIGHT ON DIRECTIONS FOR FUTURE RESEARCH IN THIS AREA AND DISCUSSES EMERGING PATHWAYS SUCH AS PI-REGULATED INTRACELLULAR CALCIUM SIGNALING, EPIGENETICS, OXIDATIVE DNA DAMAGE AND SENESCENCE-MEDIATED MECHANISMS THAT MAY PLAY CRITICAL, YET TO BE EXPLORED, REGULATORY AND DRUGGABLE ROLES IN LIMITING VC. 2021 12 2786 26 EZH2 RESTRICTS THE SMOOTH MUSCLE LINEAGE DURING MOUSE LUNG MESOTHELIAL DEVELOPMENT. DURING DEVELOPMENT, THE LUNG MESODERM GENERATES A VARIETY OF CELL LINEAGES, INCLUDING AIRWAY AND VASCULAR SMOOTH MUSCLE. EPIGENETIC CHANGES IN ADULT LUNG MESODERMAL LINEAGES ARE THOUGHT TO CONTRIBUTE TOWARDS DISEASES SUCH AS IDIOPATHIC PULMONARY FIBROSIS AND CHRONIC OBSTRUCTIVE PULMONARY DISEASE, ALTHOUGH THE FACTORS THAT REGULATE EARLY LUNG MESODERM DEVELOPMENT ARE UNKNOWN. WE SHOW IN MOUSE THAT THE PRC2 COMPONENT EZH2 IS REQUIRED TO RESTRICT SMOOTH MUSCLE DIFFERENTIATION IN THE DEVELOPING LUNG MESOTHELIUM. MESODERMAL LOSS OF EZH2 LEADS TO THE FORMATION OF ECTOPIC SMOOTH MUSCLE IN THE SUBMESOTHELIAL REGION OF THE DEVELOPING LUNG MESODERM. LOSS OF EZH2 SPECIFICALLY IN THE DEVELOPING MESOTHELIUM REVEALS A MESOTHELIAL CELL-AUTONOMOUS ROLE FOR EZH2 IN REPRESSION OF THE SMOOTH MUSCLE DIFFERENTIATION PROGRAM. LOSS OF EZH2 DEREPRESSES EXPRESSION OF MYOCARDIN AND TBX18, WHICH ARE IMPORTANT REGULATORS OF SMOOTH MUSCLE DIFFERENTIATION FROM THE MESOTHELIUM AND RELATED CELL LINEAGES. TOGETHER, THESE FINDINGS UNCOVER AN EZH2-DEPENDENT MECHANISM TO RESTRICT THE SMOOTH MUSCLE GENE EXPRESSION PROGRAM IN THE DEVELOPING MESOTHELIUM AND ALLOW APPROPRIATE CELL FATE DECISIONS TO OCCUR IN THIS MULTIPOTENT MESODERM LINEAGE. 2016 13 3351 39 HISTONE DEMETHYLASE JARID1B REGULATES PROLIFERATION AND MIGRATION OF PULMONARY ARTERIAL SMOOTH MUSCLE CELLS IN MICE WITH CHRONIC HYPOXIA-INDUCED PULMONARY HYPERTENSION VIA NUCLEAR FACTOR-KAPPA B (NFKB). CHRONIC HYPOXIA-INDUCED PULMONARY HYPERTENSION (PH) IS A DISORDER THAT IS CHARACTERIZED BY INCREASED PULMONARY ARTERIAL PRESSURE RESULTING FROM LUNG DISEASES OR SHORTAGE OF OXYGEN IN THE BODY. EXCESS PROLIFERATION OF PULMONARY VASCULAR CELLS SUCH AS PULMONARY ARTERY ENDOTHELIAL CELLS (PAECS) AND PULMONARY ARTERY SMOOTH MUSCLE CELLS (PASMCS) PLAYS A CRITICAL ROLE IN THE PATHOGENESIS OF PH. RECENT EVIDENCE INDICATES THAT, IN ADDITION TO GENETIC PREDISPOSITION AND ENVIRONMENTAL FACTORS, EPIGENETIC MECHANISMS PLAY A PIVOTAL ROLE IN ETIOLOGY OF PH. IN THIS STUDY, WE INVESTIGATED THE POSSIBLE ROLE PLAYED BY JUMONJI AT-RICH INTERACTIVE DOMAIN 1B (JARID1B), A HISTONE DEMETHYLASE, IN REGULATING THE PROLIFERATION OF VASCULAR SMOOTH MUSCLE CELLS IN CHRONIC HYPOXIA-INDUCED PH CONDITION. QUANTITATIVE POLYMERASE CHAIN REACTION ANALYSIS OF SAMPLES FROM RATS WITH PH SHOWED AN ELEVATED EXPRESSION OF JARID1B IN THEIR PASMCS, POSITIVELY CORRELATING WITH INCREASED NUCLEAR FACTOR-KAPPA B (NFKB) EXPRESSION. FURTHER FUNCTIONAL STUDIES IN VITRO INDICATED THAT OVEREXPRESSION OF JARID1B INCREASED THE PROLIFERATION AND MIGRATION OF PASMCS, WHICH WERE INHIBITED BY DEPLETION OF NFKB. GENOMEWIDE TRANSCRIPTIONAL ANALYSIS REVEALED THAT THE JARID1B REGULATED NFKB SIGNALING PATHWAY BY DIRECTLY BINDING TO ITS PROMOTER. WE HAVE ALSO SHOWN THAT JARID1B INDIRECTLY REGULATES THE EXPRESSION OF VASCULAR ENDOTHELIAL GROWTH FACTOR VIA NFKB SIGNALING AND HENCE MAY ALSO PLAY A CRUCIAL ROLE IN CONTROLLING PAECS, LEADING TO CHANGES IN VASCULAR ARCHITECTURE IN PH. OUR FINDINGS COULD LEAD TO FURTHER STUDIES ON THE ROLE OF JARID1B IN PH ETIOLOGY AND THEREFORE COULD LEAD TO A POTENTIAL THERAPEUTIC TARGET FOR CHRONIC HYPOXIA INDUCED PULMONARY HYPERTENSION. 2018 14 444 35 AORTIC AND CAROTID ARTERIAL STIFFNESS AND EPIGENETIC REGULATOR GENE EXPRESSION CHANGES PRECEDE BLOOD PRESSURE RISE IN STROKE-PRONE DAHL SALT-SENSITIVE HYPERTENSIVE RATS. MULTIPLE CLINICAL STUDIES SHOW THAT ARTERIAL STIFFNESS, MEASURED AS PULSE WAVE VELOCITY (PWV), PRECEDES HYPERTENSION AND IS AN INDEPENDENT PREDICTOR OF HYPERTENSION END ORGAN DISEASES INCLUDING STROKE, CARDIOVASCULAR DISEASE AND CHRONIC KIDNEY DISEASE. RISK FACTOR STUDIES FOR ARTERIAL STIFFNESS IMPLICATE AGE, HYPERTENSION AND SODIUM. HOWEVER, CAUSAL MECHANISMS LINKING RISK FACTOR TO ARTERIAL STIFFNESS REMAIN TO BE ELUCIDATED. HERE, WE STUDIED THE CAUSAL RELATIONSHIP OF ARTERIAL STIFFNESS AND HYPERTENSION IN THE NA-INDUCED, STROKE-PRONE DAHL SALT-SENSITIVE (S) HYPERTENSIVE RAT MODEL, AND ANALYZED PUTATIVE MOLECULAR MECHANISMS. STROKE-PRONE AND NON-STROKE-PRONE MALE AND FEMALE RATS WERE STUDIED AT 3- AND 6-WEEKS OF AGE FOR ARTERIAL STIFFNESS (PWV, STRAIN), BLOOD PRESSURE, VESSEL WALL HISTOLOGY, AND GENE EXPRESSION CHANGES. STUDIES SHOWED THAT INCREASED LEFT CAROTID AND AORTIC ARTERIAL STIFFNESS PRECEDED HYPERTENSION, PULSE PRESSURE WIDENING, AND STRUCTURAL WALL CHANGES AT THE 6-WEEK TIME-POINT. INSTEAD, DIFFERENTIAL GENE INDUCTION WAS DETECTED IMPLICATING MOLECULAR-FUNCTIONAL CHANGES IN EXTRACELLULAR MATRIX (ECM) STRUCTURAL CONSTITUENTS, MODIFIERS, CELL ADHESION, AND MATRICELLULAR PROTEINS, AS WELL AS IN ENDOTHELIAL FUNCTION, APOPTOSIS BALANCE, AND EPIGENETIC REGULATORS. IMMUNOSTAINING TESTING HISTONE MODIFIERS EP300, HDAC3, AND PRMT5 LEVELS CONFIRMED CAROTID ARTERY-UPREGULATION IN ALL THREE LAYERS: ENDOTHELIAL, SMOOTH MUSCLE AND ADVENTITIAL CELLS. OUR STUDY RECAPITULATES OBSERVATIONS IN HUMANS THAT GIVEN SALT-SENSITIVITY, INCREASED NA-INTAKE INDUCED ARTERIAL STIFFNESS BEFORE HYPERTENSION, INCREASED PULSE PRESSURE, AND STRUCTURAL VESSEL WALL CHANGES. DIFFERENTIAL GENE EXPRESSION CHANGES ASSOCIATED WITH ARTERIAL STIFFNESS SUGGEST A MOLECULAR MECHANISM LINKING SODIUM TO FULL-VESSEL WALL RESPONSE AFFECTING GENE-NETWORKS INVOLVED IN VASCULAR ECM STRUCTURE-FUNCTION, APOPTOSIS BALANCE, AND EPIGENETIC REGULATION. 2014 15 4303 37 MICRORNA-223 INHIBITS TISSUE FACTOR EXPRESSION IN VASCULAR ENDOTHELIAL CELLS. OBJECTIVE: ATHEROSCLEROSIS IS A CHRONIC INFLAMMATORY PROCESS, IN WHICH VASCULAR ENDOTHELIAL CELLS (ECS) BECOME DYSFUNCTIONAL OWING TO THE EFFECTS OF CHEMICAL SUBSTANCES, SUCH AS INFLAMMATORY FACTOR AND GROWTH FACTORS. TISSUE FACTOR (TF) EXPRESSION IS INDUCED BY THE ABOVE CHEMICAL SUBSTANCES IN ACTIVATED ECS. TF INITIATES THROMBOSIS ON DISRUPTED ATHEROSCLEROTIC PLAQUES WHICH PLAYS AN ESSENTIAL ROLE DURING THE ONSET OF ACUTE CORONARY SYNDROMES (ACS). INCREASING EVIDENCES SUGGEST THE IMPORTANT ROLE OF MICRORNAS AS EPIGENETIC REGULATORS OF ATHEROSCLEROTIC DISEASE. THE AIM OF OUR STUDY IS TO IDENTIFY IF MICRORNA-223 (MIR-223) TARGETS TF IN ECS. METHODS AND RESULTS: BIOINFORMATIC ANALYSIS SHOWED THAT TF IS A TARGET CANDIDATE OF MIR-223. WESTERN BLOTTING ANALYSIS REVEALED THAT TUMOR NECROSIS FACTOR ALPHA (TNF-ALPHA) INCREASED TF EXPRESSION IN AORTA OF C57BL/6J MICE AND CULTURED ECS (EA.HY926 CELLS AND HUVEC) AFTER 4 H TREATMENT. IN TNF-ALPHA TREATED ECS, TF MRNA WAS ALSO INCREASED MEASURED BY REAL-TIME PCR. REAL-TIME PCR RESULTS SHOWED THAT MIR-223 LEVELS WERE DOWNREGULATED IN TNF-ALPHA-TREATED AORTA OF C57BL/6J MICE AND CULTURED ECS. TRANSFECTION OF ECS WITH MIR-223 MIMIC OR MIR-223 INHIBITOR MODIFIED TF EXPRESSION BOTH IN MRNA AND PROTEIN LEVELS. LUCIFERASE ASSAYS CONFIRMED THAT MIR-223 SUPPRESSED TF EXPRESSION BY BINDING TO THE SEQUENCE OF TF 3'-UNTRANSLATED REGIONS (3'UTR). TF PROCOAGULANT ACTIVITY WAS INHIBITED BY OVEREXPRESSING MIR-223 WITH OR WITHOUT TNF-ALPHA STIMULATION. CONCLUSIONS: MIR-223-MEDIATED SUPPRESSION OF TF EXPRESSION PROVIDES A NOVEL MOLECULAR MECHANISM FOR THE REGULATION OF COAGULATION CASCADE, AND SUGGESTS A CLUE AGAINST THROMBOGENESIS DURING THE PROCESS OF ATHEROSCLEROTIC PLAQUE RUPTURE. 2014 16 3722 30 INHIBITION OF DNA METHYLATION DURING CHRONIC OBSTRUCTIVE BLADDER DISEASE (COBD) IMPROVES FUNCTION, PATHOLOGY AND EXPRESSION. PARTIAL BLADDER OUTLET OBSTRUCTION DUE TO PROSTATE HYPERPLASIA OR POSTERIOR URETHRAL VALVES, IS A WIDESPREAD CAUSE OF URINARY DYSFUNCTION, PATIENT DISCOMFORT AND ALSO RESPONSIBLE FOR IMMENSE HEALTH CARE COSTS. EVEN AFTER REMOVAL OR RELIEF OF OBSTRUCTION, THE FUNCTIONAL AND PATHOLOGIC ASPECTS OF OBSTRUCTION REMAIN AS A CHRONIC OBSTRUCTIVE BLADDER DISEASE (COBD). EPIGENETIC CHANGES, SUCH AS DNA METHYLATION, CONTRIBUTE TO THE PERSISTENT CHARACTER OF MANY CHRONIC DISEASES, AND MAY BE ALTERED IN COBD. WE TESTED WHETHER CANDIDATE GENES AND PATHWAYS AND THE PATHOPHYSIOLOGY OF COBD WERE AFFECTED BY A HYPOMETHYLATING AGENT, DECITABINE (DAC). COBD WAS CREATED IN FEMALE SPRAGUE-DAWLEY RATS BY SURGICAL LIGATION OF THE URETHRA FOR 6 WEEKS, FOLLOWED BY REMOVAL OF THE SUTURE. SHAM LIGATIONS WERE PERFORMED BY PASSING THE SUTURE BEHIND THE URETHRA. AFTER REMOVAL OF THE OBSTRUCTION OR SHAM REMOVAL, ANIMALS WERE RANDOMIZED TO DAC TREATMENT (1 MG/KG/3-TIMES/WEEK INTRAPERITONEALLY) OR VEHICLE (NORMAL SALINE). BLADDER FUNCTION WAS NON-INVASIVELY TESTED USING METABOLIC CAGES, BOTH ONE DAY PRIOR TO DE-OBSTRUCTION AT 6 WEEKS AND PRIOR TO SACRIFICE AT 10 WEEKS. RESIDUAL VOLUME AND BLADDER MASS WERE MEASURED FOR EACH BLADDER. BLADDERS WERE EXAMINED BY IMMUNOSTAINING AS WELL AS QPCR. THE EFFECTS OF DNA METHYLTRANSFERASE (DNMT)-3A KNOCKOUT OR OVEREXPRESSION ON SMOOTH MUSCLE CELL (SMC) FUNCTION AND PHENOTYPE WERE ALSO EXAMINED IN BLADDER SMC AND EX VIVO CULTURE. RESIDUAL VOLUMES OF THE DAC TREATED GROUP WERE NOT SIGNIFICANTLY DIFFERENT FROM THE NS GROUP. COMPARED TO COBD NS, COBD DAC TREATMENT HELPED PRESERVE MICTURITION VOLUME WITH A SIGNIFICANT RECOVERY OF THE VOIDING EFFICIENCY (RATIO OF THE MAXIMUM VOIDED VOLUME/MAXIMUM BLADDER CAPACITY) BY ONE THIRD (FIG. 1, P > 0.05). BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) VARIANTS 1 AND 5 WERE UPREGULATED BY COBD AND SIGNIFICANTLY REDUCED BY DAC TREATMENT. DEPOSITION OF COLLAGEN IN THE COBD BLADDER WAS REDUCED BY DAC, BUT GROSS HYPERTROPHY REMAINED. IN BLADDER SMC, DNMT3A OVEREXPRESSION LED TO A LOSS OF CONTRACTILE FUNCTION AND PHENOTYPE. IN BLADDERS, PERSISTENTLY ALTERED BY COBD, INHIBITION OF DNA-METHYLATION ENHANCES FUNCTIONAL RECOVERY, UNLIKE TREATMENT DURING PARTIAL OBSTRUCTION, WHICH EXACERBATES OBSTRUCTIVE PATHOLOGY. THE UNDERLYING MECHANISMS MAY RELATE TO THE GENE EXPRESSION CHANGES IN BDNF AND THEIR EFFECTS ON SIGNALING IN THE BLADDER. 2021 17 3306 38 HIGH-PHOSPHATE-INDUCED CALCIFICATION IS RELATED TO SM22ALPHA PROMOTER METHYLATION IN VASCULAR SMOOTH MUSCLE CELLS. HYPERPHOSPHATEMIA IS CLOSELY RELATED TO VASCULAR CALCIFICATION IN PATIENTS WITH CHRONIC KIDNEY DISEASE. VASCULAR SMOOTH MUSCLE CELLS (VSMCS) EXPOSED TO HIGH PHOSPHATE CONCENTRATIONS IN VITRO UNDERGO PHENOTYPIC TRANSITION TO OSTEOBLAST-LIKE CELLS. MECHANISMS UNDERLYING THIS TRANSDIFFERENTIATION ARE NOT CLEAR. IN THIS STUDY WE USED TWO IN VITRO MODELS, HUMAN AORTIC SMOOTH MUSCLE CELLS AND RAT AORTIC RINGS, TO INVESTIGATE THE PHENOTYPIC TRANSITION OF VSMCS INDUCED BY HIGH PHOSPHATE. WE FOUND THAT HIGH PHOSPHATE CONCENTRATION (3.3 MMOL/L) IN THE MEDIUM WAS ASSOCIATED WITH INCREASED DNA METHYLTRANSFERASE ACTIVITY AND METHYLATION OF THE PROMOTER REGION OF SM22ALPHA. THIS WAS ACCOMPANIED BY LOSS OF THE SMOOTH MUSCLE CELL-SPECIFIC PROTEIN SM22ALPHA, GAIN OF THE OSTEOBLAST TRANSCRIPTION FACTOR CBFA1, AND INCREASED ALKALINE PHOSPHATASE ACTIVITY WITH THE SUBSEQUENT IN VITRO CALCIFICATION. THE ADDITION OF A DEMETHYLATING AGENT (PROCAINE) TO THE HIGH-PHOSPHATE MEDIUM REDUCED DNA METHYLTRANSFERASE ACTIVITY AND PREVENTED METHYLATION OF THE SM22ALPHA PROMOTER, WHICH WAS ACCOMPANIED BY AN INCREASE IN SM22ALPHA EXPRESSION AND LESS CALCIFICATION. ADDITIONALLY, DOWNREGULATION OF SM22ALPHA, EITHER BY SIRNA OR BY A METHYL GROUP DONOR (S-ADENOSYL METHIONINE), RESULTED IN OVEREXPRESSION OF CBFA1. IN CONCLUSION, WE DEMONSTRATE THAT METHYLATION OF SM22ALPHA PROMOTER IS AN IMPORTANT EVENT IN VASCULAR SMOOTH MUSCLE CELL CALCIFICATION AND THAT HIGH PHOSPHATE INDUCES THIS EPIGENETIC MODIFICATION. THESE FINDINGS UNCOVER A NEW INSIGHT INTO MECHANISMS BY WHICH HIGH PHOSPHATE CONCENTRATION PROMOTES VASCULAR CALCIFICATION. 2010 18 3677 29 INFLAMMATION AND PYROPTOSIS MEDIATE MUSCLE EXPANSION IN AN INTERLEUKIN-1BETA (IL-1BETA)-DEPENDENT MANNER. MUSCLE INFLAMMATION IS OFTEN ASSOCIATED WITH ITS EXPANSION. BLADDER SMOOTH MUSCLE INFLAMMATION-INDUCED CELL DEATH IS ACCOMPANIED BY HYPERPLASIA AND HYPERTROPHY AS THE PRIMARY CAUSE FOR POOR BLADDER FUNCTION. IN MICE, DNA DAMAGE INITIATED BY CHEMOTHERAPEUTIC DRUG CYCLOPHOSPHAMIDE ACTIVATED CASPASE 1 THROUGH THE FORMATION OF THE NLRP3 COMPLEX RESULTING IN DETRUSOR HYPERPLASIA. A CYCLOPHOSPHAMIDE METABOLITE, ACROLEIN, CAUSED GLOBAL DNA METHYLATION AND ACCUMULATION OF DNA DAMAGE IN A MOUSE MODEL OF BLADDER INFLAMMATION AND IN CULTURED BLADDER MUSCLE CELLS. IN CORRELATION, GLOBAL DNA METHYLATION AND NLRP3 EXPRESSION WAS UP-REGULATED IN HUMAN CHRONIC BLADDER INFLAMMATORY TISSUES. THE EPIGENETIC SILENCING OF DNA DAMAGE REPAIR GENE, OGG1, COULD BE REVERSED BY THE USE OF DEMETHYLATING AGENTS. IN MICE, DEMETHYLATING AGENTS REVERSED CYCLOPHOSPHAMIDE-INDUCED BLADDER INFLAMMATION AND DETRUSOR EXPANSION. THE TRANSGENIC KNOCK-OUT OF OGG1 IN AS FEW AS 10% OF THE DETRUSOR CELLS TRIPLED THE PROLIFERATION OF THE REMAINING WILD TYPE COUNTERPARTS IN AN IN VITRO CO-CULTURE TITRATION EXPERIMENT. ANTAGONIZING IL-1BETA WITH ANAKINRA, A RHEUMATOID ARTHRITIS THERAPEUTIC, PREVENTED DETRUSOR PROLIFERATION IN CONDITIONED MEDIA EXPERIMENTS AS WELL AS IN A MOUSE MODEL OF BLADDER INFLAMMATION. RADIATION TREATMENT VALIDATED THE ROLE OF DNA DAMAGE IN THE NLRP3-ASSOCIATED CASPASE 1-MEDIATED IL-1BETA SECRETORY PHENOTYPE. A PROTEIN ARRAY ANALYSIS IDENTIFIED IGF1 TO BE DOWNSTREAM OF IL-1BETA SIGNALING. IL-1BETA-INDUCED DETRUSOR PROLIFERATION AND HYPERTROPHY COULD BE REVERSED WITH THE USE OF ANAKINRA AS WELL AS AN IGF1 NEUTRALIZING ANTIBODY. IL-1BETA ANTAGONISTS IN CURRENT CLINICAL PRACTICE CAN EXPLOIT THE REVEALED MECHANISM FOR DNA DAMAGE-MEDIATED MUSCULAR EXPANSION. 2015 19 2117 31 EPIGENETIC HISTONE METHYLATION MODULATES FIBROTIC GENE EXPRESSION. TGF-BETA1-INDUCED EXPRESSION OF EXTRACELLULAR MATRIX (ECM) GENES PLAYS A MAJOR ROLE IN THE DEVELOPMENT OF CHRONIC RENAL DISEASES SUCH AS DIABETIC NEPHROPATHY. ALTHOUGH MANY KEY TRANSCRIPTION FACTORS ARE KNOWN, MECHANISMS INVOLVING THE NUCLEAR CHROMATIN THAT MODULATE ECM GENE EXPRESSION REMAIN UNCLEAR. HERE, WE EXAMINED THE ROLE OF EPIGENETIC CHROMATIN MARKS SUCH AS HISTONE H3 LYSINE METHYLATION (H3KME) IN TGF-BETA1-INDUCED GENE EXPRESSION IN RAT MESANGIAL CELLS UNDER NORMAL AND HIGH-GLUCOSE (HG) CONDITIONS. TGF-BETA1 INCREASED THE EXPRESSION OF THE ECM-ASSOCIATED GENES CONNECTIVE TISSUE GROWTH FACTOR, COLLAGEN-ALPHA1[IOTA], AND PLASMINOGEN ACTIVATOR INHIBITOR-1. INCREASED LEVELS OF CHROMATIN MARKS ASSOCIATED WITH ACTIVE GENES (H3K4ME1, H3K4ME2, AND H3K4ME3), AND DECREASED LEVELS OF REPRESSIVE MARKS (H3K9ME2 AND H3K9ME3) AT THESE GENE PROMOTERS ACCOMPANIED THESE CHANGES IN EXPRESSION. TGF-BETA1 ALSO INCREASED EXPRESSION OF THE H3K4 METHYLTRANSFERASE SET7/9 AND RECRUITMENT TO THESE PROMOTERS. SET7/9 GENE SILENCING WITH SIRNAS SIGNIFICANTLY ATTENUATED TGF-BETA1-INDUCED ECM GENE EXPRESSION. FURTHERMORE, A TGF-BETA1 ANTIBODY NOT ONLY BLOCKED HG-INDUCED ECM GENE EXPRESSION BUT ALSO REVERSED HG-INDUCED CHANGES IN PROMOTER H3KME LEVELS AND SET7/9 OCCUPANCY. TAKEN TOGETHER, THESE RESULTS SHOW THE FUNCTIONAL ROLE OF EPIGENETIC CHROMATIN HISTONE H3KME IN TGF-BETA1-MEDIATED ECM GENE EXPRESSION IN MESANGIAL CELLS UNDER NORMAL AND HG CONDITIONS. PHARMACOLOGIC AND OTHER THERAPIES THAT REVERSE THESE MODIFICATIONS COULD HAVE POTENTIAL RENOPROTECTIVE EFFECTS FOR DIABETIC NEPHROPATHY. 2010 20 3519 30 IGF-1 SIGNALING IN NEONATAL HYPOXIA-INDUCED PULMONARY HYPERTENSION: ROLE OF EPIGENETIC REGULATION. PULMONARY HYPERTENSION IS A FATAL DISEASE CHARACTERIZED BY A PROGRESSIVE INCREASE IN PULMONARY ARTERY PRESSURE ACCOMPANIED BY PULMONARY VASCULAR REMODELING AND INCREASED VASOMOTOR TONE. ALTHOUGH SOME BIOLOGICAL PATHWAYS HAVE BEEN IDENTIFIED IN NEONATAL HYPOXIA-INDUCED PULMONARY HYPERTENSION (PH), LITTLE IS KNOWN REGARDING THE ROLE OF GROWTH FACTORS IN THE PATHOGENESIS OF PH IN NEONATES. IN THIS STUDY, USING A MODEL OF HYPOXIA-INDUCED PH IN NEONATAL MICE, WE DEMONSTRATE THAT THE GROWTH FACTOR INSULIN-LIKE GROWTH FACTOR-1 (IGF-1), A POTENT ACTIVATOR OF THE AKT SIGNALING PATHWAY, IS INVOLVED IN NEONATAL PH. AFTER EXPOSURE TO HYPOXIA, IGF-1 SIGNALING IS ACTIVATED IN PULMONARY ENDOTHELIAL AND SMOOTH MUSCLE CELLS IN VITRO, AND THE IGF-1 DOWNSTREAM SIGNAL PAKT(S473) IS UPREGULATED IN LUNGS OF NEONATAL MICE. WE FOUND THAT IGF-1 REGULATES ET-1 EXPRESSION IN PULMONARY ENDOTHELIAL CELLS AND THAT IGF-1 EXPRESSION IS REGULATED BY HISTONE DEACETYLASES (HDACS). IN ADDITION, THERE IS A DIFFERENTIAL CYTOSINE METHYLATION SITE IN THE IGF-1 PROMOTER REGION IN RESPONSE TO NEONATAL HYPOXIA. MOREOVER, INHIBITION OF HDACS WITH APICIDIN DECREASES NEONATAL HYPOXIA-INDUCED GLOBAL DNA METHYLATION LEVELS IN LUNGS AND SPECIFIC CYTOSINE METHYLATION LEVELS AROUND THE PULMONARY IGF-1 PROMOTER REGION. FINALLY, HDAC INHIBITION WITH APICIDIN REDUCES CHRONIC HYPOXIA-INDUCED ACTIVATION OF IGF-1/PAKT SIGNALING IN LUNGS AND ATTENUATES RIGHT VENTRICULAR HYPERTROPHY AND PULMONARY VASCULAR REMODELING. TAKEN TOGETHER, WE CONCLUDE THAT IGF-1, WHICH IS EPIGENETICALLY REGULATED, IS INVOLVED IN THE PATHOGENESIS OF PULMONARY HYPERTENSION IN NEONATAL MICE. THIS STUDY IMPLICATES A NOVEL HDAC/IGF-1 EPIGENETIC PATHWAY IN THE REGULATION OF HYPOXIA-INDUCED PH AND WARRANTS FURTHER STUDY OF THE ROLE OF IGF-1 IN NEONATAL PULMONARY HYPERTENSIVE DISEASE. 2015