1 1569 98 DNA METHYLATION OF TXNIP INDEPENDENTLY ASSOCIATED WITH INFLAMMATION AND DIABETES MELLITUS IN TWINS. THIOREDOXIN-INTERACTING PROTEIN (TXNIP) PLAYS A KEY ROLE IN DIABETES DEVELOPMENT AND PROGNOSIS THROUGH ITS ROLE IN PANCREATIC BETA-CELL DYSFUNCTION AND DEATH AS WELL AS IN UPREGULATING THE INFLAMMATORY RESPONSE IN HYPERGLYCEMIA. DNA METHYLATION (DNAM) OF TXNIP (TXNIP-CG19693031) IS ASSOCIATED WITH THE PREVALENCE AND INCIDENCE OF TYPE 2 DIABETES (T2D); HOWEVER, ITS ROLE IN INFLAMMATION AND ITS RELATIONSHIP WITH T2D REMAIN UNCLEAR. WE AIMED TO INVESTIGATE THE EPIGENETIC ASSOCIATIONS OF TXNIP-CG19693031 WITH A PANEL OF INFLAMMATORY BIOMARKERS AND TO EXAMINE WHETHER THESE INFLAMMATORY BIOMARKERS MODIFY THE ASSOCIATION BETWEEN TXNIP-CG19693031 METHYLATION AND DIABETES IN 218 MIDDLE-AGED MALE TWINS FROM THE EMORY TWIN STUDY. WE CONFIRMED THE ASSOCIATION OF TXNIP-CG19693031 DNAM WITH T2D, AS WELL AS WITH HBA1C, INSULIN AND FASTING GLUCOSE. WE FOUND THAT HYPOMETHYLATION AT TXNIP-CG19693031 IS STRONGLY ASSOCIATED WITH BOTH TYPE 2 DIABETES AND HIGHER LEVELS OF INFLAMMATORY BIOMARKERS (VCAM-1, ICAM-1, MMP-2, SRAGE AND P-SELECTIN); HOWEVER, THE RELATIONSHIP BETWEEN TXNIP-CG19693031 AND T2D IS INDEPENDENT OF THE LEVELS OF THESE INFLAMMATORY BIOMARKERS. OUR RESULTS SUGGEST THAT DNA METHYLATION OF TXNIP IS LINKED WITH MULTIPLE BIOLOGICAL PROCESSES, THROUGH WHICH THE TXNIP MAY HAVE BROAD INFLUENCE ON CHRONIC DISEASE RISK.	2021	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                       
2 1567 36 DNA METHYLATION OF THE KLF14 GENE REGION IN WHOLE BLOOD CELLS PROVIDES PREDICTION FOR THE CHRONIC INFLAMMATION IN THE ADIPOSE TISSUE. KRUPPEL-LIKE FACTOR 14 (KLF14) GENE, WHICH APPEARS TO BE A MASTER REGULATOR OF GENE EXPRESSION IN THE ADIPOSE TISSUE AND HAVE PREVIOUSLY BEEN ASSOCIATED WITH BMI AND TYPE 2 DIABETES (T2D) BY LARGE GENOME-WIDE ASSOCIATION STUDIES. IN ORDER TO FIND PREDICTIVE BIOMARKERS FOR THE DEVELOPMENT OF T2D, IT IS NECESSARY TO TAKE EPIGENOMIC CHANGES AFFECTED BY ENVIRONMENTAL FACTORS INTO ACCOUNT. THIS STUDY FOCUSES ON AGEING AND OBESITY, WHICH ARE T2D RISK FACTORS, AND EXAMINES EPIGENETIC CHANGES AND INFLAMMATORY CHANGES. WE INVESTIGATED DNA METHYLATION CHANGES IN THE KLF14 PROMOTER REGION IN DIFFERENT ORGANS OF MICE FOR COMPARING AGING AND WEIGHT. WE FOUND THAT METHYLATION LEVELS OF THESE SITES WERE INCREASED WITH AGING AND WEIGHT IN THE SPLEEN, THE ADIPOSE TISSUE, THE KIDNEY, THE LUNG, THE COLON AND THE WHOLE BLOOD CELLS. IN ADDITION, IN THE SPLEEN, THE ADIPOSE TISSUE AND THE WHOLE BLOOD, THESE EPIGENETIC CHANGES WERE ALSO SIGNIFICANTLY ASSOCIATED WITH INFLAMMATORY LEVELS. MOREOVER, NOT ONLY KLF14, BUT ALSO EXPRESSION LEVELS OF SOME DOWNSTREAM GENES WERE DECREASED WITH METHYLATION IN THE SPLEEN, THE ADIPOSE TISSUE AND THE WHOLE BLOOD CELLS. TAKEN TOGETHER, OUR RESULTS SUGGEST THAT METHYLATION CHANGES OF KLF14 IN THOSE TISSUES MAY BE ASSOCIATED WITH CHANGES IN GENE EXPRESSION AND INFLAMMATION ON THE ADIPOSE TISSUE OF OBESITY AND T2D. IN ADDITION, THE METHYLATION CHANGES IN THE WHOLE BLOOD CELLS MAY SERVE AS A PREDICTIVE EPIGENETIC BIOMARKER FOR THE DEVELOPMENT OF T2D.	2018	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                           
3  366 32 AMINO ACID-INDUCED GENE EXPRESSION PROFILING IN CLONAL BETA-CELL LINE INS-1E CELLS. BACKGROUND: THERE IS ABUNDANT EVIDENCE THAT GLUCOTOXICITY AND LIPOTOXICITY CONTRIBUTE TO IMPAIRED BETA-CELL FUNCTION IN TYPE 2 DIABETES. INTERESTINGLY, AMINO ACID (AA) DERANGEMENT IS ALSO A CHARACTERISTIC PART OF THE DIABETIC STATE. THE ACUTE EFFECTS OF AA ON PANCREATIC BETA-CELL FUNCTION HAVE BEEN WIDELY EXPLORED; HOWEVER, TO OUR KNOWLEDGE, THE CHRONIC EFFECTS OF AA, E.G. PROLINE (PRO), HOMOCYSTEINE (HCY), AND LEUCINE (LEU), ON PANCREATIC BETA-CELL FUNCTION AND INTEGRITY HAVE NOT YET BEEN STUDIED. WE AIMED TO INVESTIGATE GLOBAL ALTERATIONS IN BETA-CELL GENE EXPRESSION AFTER LONG-TERM EXPOSURE OF CLONAL INS-1E CELLS TO ELEVATED LEVEL OF SPECIFIC AA IN VITRO. METHODS: GLOBAL GENE EXPRESSION PROFILING WAS PERFORMED TO CHARACTERIZE GENES DIFFERENTLY MODIFIED BY PRO, HCY, AND LEU, RESPECTIVELY, IN INS-1E CELLS. RESULTS: GENE EXPRESSION PROFILING REVEALED SIGNIFICANT CHANGES IN INS-1E CELL MRNAS INVOLVED IN THE CONTROL OF SEVERAL ASPECTS OF BETA-CELL FUNCTION, E.G. EPIGENETIC REGULATION OF GENE EXPRESSION, METABOLISM, INNATE AND ADAPTIVE IMMUNE RESPONSES, CELLULAR SIGNALLING, PROTEIN SYNTHESIS, APOPTOSIS, AND CELLULAR STRESS RESPONSE. AFTER 72 H, INS-1E CELLS WERE DIFFERENTIALLY REGULATED (>/=1.5- OR </= -1.5-FOLD) BY PRO (295 TRANSCRIPTS), HCY (301 TRANSCRIPTS), AND LEU (701 TRANSCRIPTS). IT APPEARS THAT HCY EFFECTS CHANGES OPPOSITE TO THOSE INDUCED BY LEU AND/OR PRO. CONCLUSIONS: AA APPEARS TO PARTICIPATE IN AND TO INFLUENCE MANY PHYSIOLOGICAL PROCESSES INCLUDING THOSE INVOLVED IN CHOLESTEROL METABOLISM, IMMUNE RESPONSES, AND OXIDATIVE PHOSPHORYLATION. WHETHER SUCH EVENTS PROMOTE THE BETA-CELL DYSFUNCTION AND THE BETA-CELL FAILURE IN DIABETES REMAINS TO BE ELUCIDATED. OUR DATA STRONGLY INDICATE THAT AA ELEVATION MAY TAKE PART IN THE PROGRESSIVE DEVELOPMENT OF TYPE 2 DIABETES.	2011	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                           
4 3764 30 INTEGRATIVE ANALYSIS OF DNA METHYLATION AND GENE EXPRESSION DATA IDENTIFIES EPAS1 AS A KEY REGULATOR OF COPD. CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) IS A COMPLEX DISEASE. GENETIC, EPIGENETIC, AND ENVIRONMENTAL FACTORS ARE KNOWN TO CONTRIBUTE TO COPD RISK AND DISEASE PROGRESSION. THEREFORE WE DEVELOPED A SYSTEMATIC APPROACH TO IDENTIFY KEY REGULATORS OF COPD THAT INTEGRATES GENOME-WIDE DNA METHYLATION, GENE EXPRESSION, AND PHENOTYPE DATA IN LUNG TISSUE FROM COPD AND CONTROL SAMPLES. OUR INTEGRATIVE ANALYSIS IDENTIFIED 126 KEY REGULATORS OF COPD. WE IDENTIFIED EPAS1 AS THE ONLY KEY REGULATOR WHOSE DOWNSTREAM GENES SIGNIFICANTLY OVERLAPPED WITH MULTIPLE GENES SETS ASSOCIATED WITH COPD DISEASE SEVERITY. EPAS1 IS DISTINCT IN COMPARISON WITH OTHER KEY REGULATORS IN TERMS OF METHYLATION PROFILE AND DOWNSTREAM TARGET GENES. GENES PREDICTED TO BE REGULATED BY EPAS1 WERE ENRICHED FOR BIOLOGICAL PROCESSES INCLUDING SIGNALING, CELL COMMUNICATIONS, AND SYSTEM DEVELOPMENT. WE CONFIRMED THAT EPAS1 PROTEIN LEVELS ARE LOWER IN HUMAN COPD LUNG TISSUE COMPARED TO NON-DISEASE CONTROLS AND THAT EPAS1 GENE EXPRESSION IS REDUCED IN MICE CHRONICALLY EXPOSED TO CIGARETTE SMOKE. AS EPAS1 DOWNSTREAM GENES WERE SIGNIFICANTLY ENRICHED FOR HYPOXIA RESPONSIVE GENES IN ENDOTHELIAL CELLS, WE TESTED EPAS1 FUNCTION IN HUMAN ENDOTHELIAL CELLS. EPAS1 KNOCKDOWN BY SIRNA IN ENDOTHELIAL CELLS IMPACTED GENES THAT SIGNIFICANTLY OVERLAPPED WITH EPAS1 DOWNSTREAM GENES IN LUNG TISSUE INCLUDING HYPOXIA RESPONSIVE GENES, AND GENES ASSOCIATED WITH EMPHYSEMA SEVERITY. OUR FIRST INTEGRATIVE ANALYSIS OF GENOME-WIDE DNA METHYLATION AND GENE EXPRESSION PROFILES ILLUSTRATES THAT NOT ONLY DOES DNA METHYLATION PLAY A 'CAUSAL' ROLE IN THE MOLECULAR PATHOPHYSIOLOGY OF COPD, BUT IT CAN BE LEVERAGED TO DIRECTLY IDENTIFY NOVEL KEY MEDIATORS OF THIS PATHOPHYSIOLOGY.	2015	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                        
5 4736 27 NOVEL EPIGENETIC BIOMARKERS MEDIATING BISPHENOL A EXPOSURE AND METABOLIC PHENOTYPES IN FEMALE MICE. THERE IS COMPELLING EVIDENCE THAT EPIGENETIC MODIFICATIONS LINK DEVELOPMENTAL ENVIRONMENTAL INSULTS TO ADULT DISEASE SUSCEPTIBILITY. ANIMAL STUDIES HAVE ASSOCIATED PERINATAL BISPHENOL A (BPA) EXPOSURE TO ALTERED DNA METHYLATION, BUT THESE STUDIES ARE OFTEN LIMITED TO CANDIDATE GENE AND GLOBAL NON-LOCI-SPECIFIC APPROACHES. BY USING AN EPIGENOME-WIDE DISCOVERY PLATFORM, WE ELUCIDATED EPIGENETIC ALTERATIONS IN LIVER TISSUE FROM ADULT MICE OFFSPRING (10 MONTHS) FOLLOWING PERINATAL BPA EXPOSURE AT HUMAN PHYSIOLOGICALLY RELEVANT DOSES (50-NG, 50-MUG, AND 50-MG BPA/KG DIET). BIOLOGICAL PATHWAY ANALYSIS IDENTIFIED AN ENRICHMENT OF SIGNIFICANT DIFFERENTIALLY METHYLATED REGIONS IN METABOLIC PATHWAYS AMONG FEMALES. FURTHERMORE, THROUGH THE USE OF TOP ENRICHED BIOLOGICAL PATHWAYS, 4 CANDIDATE GENES WERE CHOSEN TO ASSESS DNA METHYLATION AS A MEDIATING FACTOR LINKING THE ASSOCIATION OF PERINATAL BPA EXPOSURE TO METABOLIC PHENOTYPES PREVIOUSLY OBSERVED IN FEMALE OFFSPRING. DNA METHYLATION STATUS AT JANUS KINASE-2 (JAK-2), RETINOID X RECEPTOR (RXR), REGULATORY FACTOR X-ASSOCIATED PROTEIN (RFXAP), AND TRANSMEMBRANE PROTEIN 238 (TMEM238) WAS USED WITHIN A MEDIATIONAL REGRESSION ANALYSIS. DNA METHYLATION IN ALL FOUR OF THE CANDIDATE GENES WAS IDENTIFIED AS A MEDIATOR IN THE MECHANISTIC PATHWAY OF DEVELOPMENTAL BPA EXPOSURE AND FEMALE-SPECIFIC ENERGY EXPENDITURE, BODY WEIGHT, AND BODY FAT PHENOTYPES. DATA GENERATED FROM THIS STUDY ARE CRUCIAL FOR DECIPHERING THE MECHANISTIC ROLE OF EPIGENETICS IN THE PATHOGENESIS OF CHRONIC DISEASE AND THE DEVELOPMENT OF EPIGENETIC-BASED PREVENTION AND THERAPEUTIC STRATEGIES FOR COMPLEX HUMAN DISEASE.	2017	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                            
6 2997 23 GENETIC VARIANTS IN DNMT1 AND THE RISK OF CARDIAC AUTONOMIC NEUROPATHY IN WOMEN WITH TYPE 1 DIABETES. AIMS/INTRODUCTION: EPIGENETICS PARTICIPATE IN THE PATHOGENESIS OF METABOLIC MEMORY, A SITUATION IN WHICH HYPERGLYCEMIA EXERTS PROLONGED DELETERIOUS EFFECTS EVEN AFTER ITS NORMALIZATION. WE TESTED THE HYPOTHESIS THAT GENETIC VARIANTS IN AN EPIGENETIC GENE COULD PREDISPOSE TO DIABETES COMPLICATIONS. MATERIAL AND METHODS: WE ASSESSED THE FREQUENCY OF FIVE SINGLE-NUCLEOTIDE POLYMORPHISMS IN THE GENE ENCODING DEOXYRIBONUCLEIC ACID METHYTRANSFERASE 1 (DNMT1; RS8112895, RS7254567, RS11085721, RS17291414 AND RS10854076), AND THEIR ASSOCIATIONS WITH DIABETIC KIDNEY DISEASE, RETINOPATHY, DISTAL POLYNEUROPATHY AND AUTONOMIC CARDIOVASCULAR NEUROPATHY IN 359 INDIVIDUALS WITH LONG-TERM TYPE 1 DIABETES. RESULTS: NONE OF THE SINGLE-NUCLEOTIDE POLYMORPHISMS STUDIED WAS SIGNIFICANTLY ASSOCIATED WITH THE PRESENCE OF CHRONIC COMPLICATIONS IN THE OVERALL POPULATION. HOWEVER, AFTER SEX STRATIFICATION, THE MINOR ALLELE C OF RS11085721 CONFERRED RISK FOR CARDIOVASCULAR NEUROPATHY IN WOMEN AFTER ADJUSTMENT FOR CONFOUNDING VARIABLES (ODDS RATIO 2.32; 95% CONFIDENCE INTERVAL 1.26-4.33; P = 0.006). CONCLUSIONS: THE FACT THAT HETEROZYGOUS MUTATIONS IN DNMT1 ARE ASSOCIATED WITH HEREDITARY SENSORY AUTONOMIC NEUROPATHY PROVIDES PLAUSIBILITY TO THE PRESENT FINDING. IF CONFIRMED IN INDEPENDENT SAMPLES, IT SUGGESTS THAT GENETIC VARIANTS IN EPIGENETIC GENES MIGHT PREDISPOSE TO MORE OR FEWER EPIGENETIC CHANGES IN THE FACE OF SIMILAR METABOLIC DERANGEMENTS TRIGGERED BY HYPERGLYCEMIA, CONSTITUTING THE "GENETICS OF EPIGENETICS" FOR MICROVASCULAR DIABETES COMPLICATIONS.	2019	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                 
7 1347 29 DETECTION OF TYPE 2 DIABETES RELATED MODULES AND GENES BASED ON EPIGENETIC NETWORKS. BACKGROUND: TYPE 2 DIABETES (T2D) IS ONE OF THE MOST COMMON CHRONIC METABOLIC DISEASES CHARACTERIZED BY INSULIN RESISTANCE AND THE DECREASE OF INSULIN SECRETION. GENETIC VARIATION CAN ONLY EXPLAIN PART OF THE HERITABILITY OF T2D, SO THERE NEED NEW METHODS TO DETECT THE SUSCEPTIBILITY GENES OF THE DISEASE. EPIGENETICS COULD ESTABLISH THE INTERFACE BETWEEN THE ENVIRONMENTAL FACTOR AND THE T2D PATHOLOGICAL MECHANISM. RESULTS: BASED ON THE NETWORK THEORY AND BY COMBINING EPIGENETIC CHARACTERISTICS WITH HUMAN INTERACTOME, THE WEIGHTED HUMAN DNA METHYLATION NETWORK (WMPN) WAS CONSTRUCTED, AND A T2D-RELATED SUBNETWORK (TMSN) WAS OBTAINED THROUGH T2D-RELATED DIFFERENTIALLY METHYLATED GENES. IT IS FOUND THAT TMSN HAD A T2D SPECIFIC NETWORK STRUCTURE THAT NON-FATAL METABOLIC DISEASE CAUSING GENES WERE OFTEN LOCATED IN THE TOPOLOGICAL AND FUNCTIONAL PERIPHERY OF NETWORK. COMBINED WITH CHROMATIN MODIFICATIONS, THE WEIGHTED CHROMATIN MODIFICATION NETWORK (WCPN) WAS BUILT, AND A T2D-RELATED CHROMATIN MODIFICATION PATTERN SUBNETWORK WAS OBTAINED BY THE TMSN GENE SET. TCSN HAD A DENSELY CONNECTED NETWORK COMMUNITY, INDICATING THAT TMSN AND TCSN COULD REPRESENT A COLLECTION OF T2D-RELATED EPIGENETIC DYSREGULATED SUB-PATHWAYS. USING THE CUMULATIVE HYPERGEOMETRIC TEST, 24 INTERPLAY MODULES OF DNA METHYLATION AND CHROMATIN MODIFICATIONS WERE IDENTIFIED. BY THE ANALYSIS OF GENE EXPRESSION IN HUMAN T2D ISLET TISSUE, IT IS FOUND THAT THERE EXISTED GENES WITH THE VARIANT EXPRESSION LEVEL CAUSED BY THE ABERRANT DNA METHYLATION AND (OR) CHROMATIN MODIFICATIONS, WHICH MIGHT AFFECT AND PROMOTE THE DEVELOPMENT OF T2D. CONCLUSIONS: HERE WE HAVE DETECTED THE POTENTIAL INTERPLAY MODULES OF DNA METHYLATION AND CHROMATIN MODIFICATIONS FOR T2D. THE STUDY OF T2D EPIGENETIC NETWORKS PROVIDES A NEW WAY FOR UNDERSTANDING THE PATHOGENIC MECHANISM OF T2D CAUSED BY EPIGENETIC DISORDERS.	2014	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                
8 2776 30 EXTRAUTERINE GROWTH RESTRICTION ON PULMONARY VASCULAR ENDOTHELIAL DYSFUNCTION IN ADULT MALE RATS: THE ROLE OF EPIGENETIC MECHANISMS. OBJECTIVE: EARLY POSTNATAL LIFE IS CONSIDERED AS A CRITICAL TIME WINDOW FOR THE DETERMINATION OF LONG-TERM METABOLIC STATES AND ORGAN FUNCTIONS. EXTRAUTERINE GROWTH RESTRICTION (EUGR) CAUSES THE DEVELOPMENT OF ADULT-ONSET CHRONIC DISEASES, INCLUDING PULMONARY HYPERTENSION. HOWEVER, THE EFFECTS OF NUTRITIONAL DISADVANTAGES DURING THE EARLY POSTNATAL PERIOD ON PULMONARY VASCULAR CONSEQUENCES IN LATER LIFE ARE NOT FULLY UNDERSTOOD. OUR STUDY WAS DESIGNED TO TEST WHETHER EPIGENETICS DYSREGULATION MEDIATES THE CELLULAR MEMORY OF THIS EARLY POSTNATAL EVENT. METHODS AND RESULTS: TO TEST THIS HYPOTHESIS, WE ISOLATED PULMONARY VASCULAR ENDOTHELIAL CELLS BY MAGNETIC-ACTIVATED CELL SORTING FROM EUGR AND CONTROL RATS. A POSTNATAL INSULT, NUTRITIONAL RESTRICTION-INDUCED EUGR CAUSED DEVELOPMENT OF AN INCREASED PULMONARY ARTERY PRESSURE AT 9 WEEKS OF AGE IN MALE SPRAGUE-DAWLEY RATS. METHYL-DNA IMMUNE PRECIPITATION CHIP, GENOME-SCALE MAPPING STUDIES TO SEARCH FOR DIFFERENTIALLY METHYLATED LOCI BETWEEN CONTROL AND EUGR RATS, REVEALED SIGNIFICANT DIFFERENCE IN CYTOSINE METHYLATION BETWEEN EUGR AND CONTROL RATS. EUGR CHANGES THE CYTOSINE METHYLATION AT APPROXIMATELY 500 LOCI IN MALE RATS AT 9 WEEKS OF AGE, PRECEDING THE DEVELOPMENT OF PULMONARY HYPERTENSION AND THESE REPRESENT THE CANDIDATE LOCI FOR MEDIATING THE PATHOGENESIS OF PULMONARY VASCULAR DISEASE THAT OCCURS LATER IN LIFE. GENE ONTOLOGY ANALYSIS ON DIFFERENTIALLY METHYLATED GENES SHOWED THAT HYPERMETHYLATED GENES IN EUGR ARE VASCULAR DEVELOPMENT-ASSOCIATED GENES AND HYPOMETHYLATED GENES IN EUGR ARE LATE-DIFFERENTIATION-ASSOCIATED AND SIGNAL TRANSDUCTION GENES. WE VALIDATED CANDIDATE DYSREGULATED LOCI WITH THE QUANTITATIVE ASSAYS OF CYTOSINE METHYLATION AND GENE EXPRESSIONS. CONCLUSION: THESE RESULTS DEMONSTRATE THAT EPIGENETICS DYSREGULATION IS A STRONG MECHANISM FOR PROPAGATING THE CELLULAR MEMORY OF EARLY POSTNATAL EVENTS, CAUSING CHANGES IN THE EXPRESSION OF GENES AND LONG-TERM SUSCEPTIBILITY TO PULMONARY HYPERTENSION, AND FURTHER PROVIDING A NEW INSIGHT INTO THE PREVENTION AND TREATMENT OF EUGR-RELATED PULMONARY HYPERTENSION.	2014	
                                                                                                                                                                                                                                                                                                                                           
9 1295 29 DECREASED GLOBAL DNA METHYLATION IN THE WHITE BLOOD CELLS OF HIGH FAT DIET FED VERVET MONKEYS (CHLOROCEBUS AETHIOPS). EPIGENETIC MECHANISMS ARE ASSOCIATED WITH THE DEVELOPMENT OF MANY CHRONIC DISEASES AND DUE TO THEIR REVERSIBLE NATURE OFFER A UNIQUE WINDOW OF OPPORTUNITY TO REVERSE THE DISEASE PHENOTYPE. THIS STUDY INVESTIGATED WHETHER GLOBAL DNA METHYLATION CORRELATES WITH DYSGLYCEMIA IN THE VERVET MONKEY (CHLOROCEBUS AETHIOPS). DIET-INDUCED CHANGES IN DNA METHYLATION WERE OBSERVED WHERE GLOBAL DNA METHYLATION WAS TWOFOLD LOWER IN MONKEYS FED A HIGH FAT DIET (N = 10) COMPARED TO MONKEYS FED A STANDARD DIET (N = 15). AN INVERSE CORRELATION WAS OBSERVED BETWEEN DNA METHYLATION, BLOOD GLUCOSE CONCENTRATIONS, BODYWEIGHT, AND AGE, ALTHOUGH THE ASSOCIATION WAS NOT STATISTICALLY SIGNIFICANT. CONSUMPTION OF A HIGH FAT DIET IS ASSOCIATED WITH THE DEVELOPMENT OF METABOLIC DISEASE; THUS, THESE RESULTS SUGGEST THE USE OF GLOBAL DNA METHYLATION AS A BIOMARKER TO ASSESS THE RISK FOR METABOLIC DISEASE. MOREOVER, THIS STUDY PROVIDES FURTHER SUPPORT FOR THE USE OF THE VERVET MONKEY AS A MODEL SYSTEM TO STUDY METABOLIC DISEASES SUCH AS TYPE 2 DIABETES. INTEGRATION OF ALTERED DNA METHYLATION PROFILES INTO PREDICTIVE MODELS COULD FACILITATE RISK STRATIFICATION AND ENABLE INTERVENTION STRATEGIES TO INHIBIT DISEASE PROGRESSION. SUCH INTERVENTIONS COULD INCLUDE LIFESTYLE MODIFICATIONS, FOR EXAMPLE, THE INCREASED CONSUMPTION OF FUNCTIONAL FOODS WITH THE CAPACITY TO MODULATE DNA METHYLATION, THUS POTENTIALLY REVERSING THE DISEASE PHENOTYPE AND PREVENTING DISEASE.	2014	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                            
10 5468 29 RESISTANCE TRAINING AND REDOX HOMEOSTASIS: CORRELATION WITH AGE-ASSOCIATED GENOMIC CHANGES. REGULAR PHYSICAL ACTIVITY IS EFFECTIVE AS PREVENTION AND TREATMENT FOR DIFFERENT CHRONIC CONDITIONS RELATED TO THE AGEING PROCESSES. IN FACT, A SEDENTARY LIFESTYLE HAS BEEN LINKED TO A WORSENING OF CELLULAR AGEING BIOMARKERS SUCH AS TELOMERE LENGTH (TL) AND/OR SPECIFIC EPIGENETIC CHANGES (E.G. DNA METHYLATION), WITH INCREASE OF THE PROPENSITY TO AGING-RELATED DISEASES AND PREMATURE DEATH. EXTENDING OUR PREVIOUS FINDINGS, WE AIMED TO TEST THE HYPOTHESIS THAT 12 WEEKS OF LOW FREQUENCY, MODERATE INTENSITY, EXPLOSIVE-TYPE RESISTANCE TRAINING (EMRT) MAY ATTENUATE AGE-ASSOCIATED GENOMIC CHANGES. TO THIS AIM, TL, GLOBAL DNA METHYLATION, TRF2, KU80, SIRT1, SIRT2 AND GLOBAL PROTEIN ACETYLATION, AS WELL AS OTHER PROTEINS INVOLVED IN APOPTOTIC PATHWAY (BCL-2, BAX AND CASPASE-3), ANTIOXIDANT RESPONSE (TRXR1 AND MNSOD) AND OXIDATIVE DAMAGE (MYELOPEROXIDASE) WERE EVALUATED BEFORE AND AFTER EMRT IN WHOLE BLOOD OR PERIPHERAL MONONUCLEAR CELLS (PBMCS) OF ELDERLY SUBJECTS. OUR FINDINGS CONFIRM THE POTENTIAL OF EMRT TO INDUCE AN ADAPTIVE CHANGE IN THE ANTIOXIDANT PROTEIN SYSTEMS AT SYSTEMIC LEVEL AND SUGGEST A PUTATIVE ROLE OF RESISTANCE TRAINING IN THE REDUCTION OF GLOBAL DNA METHYLATION. MOREOVER, WE OBSERVED THAT EMRT COUNTERACTS THE TELOMERES' SHORTENING IN A MANNER THAT PROVED TO BE DIRECTLY CORRELATED WITH THE AMELIORATION OF REDOX HOMEOSTASIS AND EFFICACY OF TRAINING REGIME, EVALUATED AS IMPROVEMENT OF BOTH MUSCLE'S POWER/STRENGTH AND FUNCTIONAL PARAMETERS.	2016	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                
11 5845 26 STUDY PROTOCOL FOR THE EPIGENETIC CHARACTERIZATION OF ANGOR PECTORIS ACCORDING TO THE AFFECTED CORONARY COMPARTMENT: GLOBAL AND COMPREHENSIVE ASSESSMENT OF THE RELATIONSHIP BETWEEN INVASIVE CORONARY PHYSIOLOGY AND MICRORNAS. BACKGROUND: MICRORNAS (MIRNAS) ARE NONCODING RNAS INVOLVED IN POST-TRANSCRIPTIONAL GENETIC REGULATION WITH A PROPOSED ROLE IN INTERCELLULAR COMMUNICATION. MIRNAS ARE CONSIDERED PROMISING BIOMARKERS IN ISCHEMIC HEART DISEASE. INVASIVE PHYSIOLOGICAL EVALUATION ALLOWS A PRECISE ASSESSMENT OF EACH AFFECTED CORONARY COMPARTMENT. ALTHOUGH SOME STUDIES HAVE ASSOCIATED THE EXPRESSION OF CIRCULATING MIRNAS WITH INVASIVE PHYSIOLOGICAL INDEXES, THEIR GLOBAL RELATIONSHIP WITH CORONARY COMPARTMENTS HAS NOT BEEN ASSESSED. HERE, WE WILL EVALUATE CIRCULATING MIRNAS PROFILES ACCORDING TO THE CORONARY PATTERN OF THE VASCULAR COMPARTMENT AFFECTATION. STUDY AND DESIGN: THIS IS AN INVESTIGATOR-INITIATED, MULTICENTRE, DESCRIPTIVE STUDY TO BE CONDUCTED AT THREE CENTRES IN SPAIN (NCT05374694). THE STUDY WILL INCLUDE ONE HUNDRED CONSECUTIVE PATIENTS OLDER THAN 18 YEARS WITH CHEST PAIN OF PRESUMED CORONARY CAUSE UNDERGOING INVASIVE PHYSIOLOGICAL EVALUATION, INCLUDING FRACTIONAL FLOW RESERVE (FFR) AND INDEX OF MICROVASCULAR RESISTANCE (IMR). PATIENTS WILL BE INITIALLY CLASSIFIED INTO FOUR GROUPS, ACCORDING TO FFR AND IMR: MACROVASCULAR AND MICROVASCULAR AFFECTATION (FFR</=0.80 / IMR>/=25), ISOLATED MACROVASCULAR AFFECTATION (FFR</=0.80 / IMR<25), ISOLATED MICROVASCULAR AFFECTATION (FFR>0.80 / IMR >/=25) AND NORMAL CORONARY INDEXES (FFR>0.80 / IMR<25). PATIENTS WITH ISOLATED MICROVASCULAR AFFECTATION OR NORMAL INDEXES WILL ALSO UNDERGO THE ACETYLCHOLINE TEST AND MAY BE RECLASSIFIED AS A FIFTH GROUP IN THE PRESENCE OF SPASM. A PANEL OF MIRNAS PREVIOUSLY ASSOCIATED WITH MOLECULAR MECHANISMS LINKED TO CHRONIC CORONARY SYNDROME WILL BE ANALYSED USING RT-QPCR. CONCLUSIONS: THE RESULTS OF THIS STUDY WILL IDENTIFY MIRNA PROFILES ASSOCIATED WITH PATTERNS OF CORONARY AFFECTATION AND WILL CONTRIBUTE TO A BETTER UNDERSTANDING OF THE MECHANISTIC PATHWAYS OF CORONARY PATHOLOGY.	2023	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                           
12 1841 29 EFFECTS OF SHORT CHAIN FATTY ACID PRODUCING BACTERIA ON EPIGENETIC REGULATION OF FFAR3 IN TYPE 2 DIABETES AND OBESITY. THE HUMAN GUT MICROBIOTA AND MICROBIAL INFLUENCES ON LIPID AND GLUCOSE METABOLISM, SATIETY, AND CHRONIC LOW-GRADE INFLAMMATION ARE KNOWN TO BE INVOLVED IN METABOLIC SYNDROME. FERMENTATION END PRODUCTS, ESPECIALLY SHORT CHAIN FATTY ACIDS, ARE BELIEVED TO ENGAGE THE EPIGENETIC REGULATION OF INFLAMMATORY REACTIONS VIA FFARS (FREE FATTY ACID RECEPTOR) AND OTHER SHORT CHAIN FATTY ACID RECEPTORS. WE STUDIED A POTENTIAL INTERACTION OF THE MICROBIOTA WITH EPIGENETIC REGULATION IN OBESE AND TYPE 2 DIABETES PATIENTS COMPARED TO A LEAN CONTROL GROUP OVER A FOUR MONTH INTERVENTION PERIOD. INTERVENTION COMPRISED A GLP-1 AGONIST (GLUCAGON-LIKE PEPTIDE 1) FOR TYPE 2 DIABETICS AND NUTRITIONAL COUNSELING FOR BOTH INTERVENTION GROUPS. MICROBIOTA WAS ANALYZED FOR ABUNDANCE, BUTYRYL-COA:ACETATE COA-TRANSFERASE GENE AND FOR DIVERSITY BY POLYMERASE CHAIN REACTION AND 454 HIGH-THROUGHPUT SEQUENCING. EPIGENETIC METHYLATION OF THE PROMOTER REGION OF FFAR3 AND LINE1 (LONG INTERSPERSED NUCLEAR ELEMENT 1) WAS ANALYZED USING BISULFITE CONVERSION AND PYROSEQUENCING. THE DIVERSITY OF THE MICROBIOTA AS WELL AS THE ABUNDANCE OF FAECALIBACTERIUM PRAUSNITZII WERE SIGNIFICANTLY LOWER IN OBESE AND TYPE 2 DIABETIC PATIENTS COMPARED TO LEAN INDIVIDUALS. RESULTS FROM CLOSTRIDIUM CLUSTER IV AND CLOSTRIDIUM CLUSTER XIVA SHOWED A DECREASING TREND IN TYPE 2 DIABETICS IN COMPARISON TO THE BUTYRYL-COA:ACETATE COA-TRANSFERASE GENE AND ACCORDING TO MELT CURVE ANALYSIS. DURING INTERVENTION NO SIGNIFICANT CHANGES WERE OBSERVED IN EITHER INTERVENTION GROUP. THE ANALYSIS OF FIVE CPGS IN THE PROMOTER REGION OF FFAR3 SHOWED A SIGNIFICANT LOWER METHYLATION IN OBESE AND TYPE 2 DIABETICS WITH AN INCREASE IN OBESE PATIENTS OVER THE INTERVENTION PERIOD. THESE RESULTS DISCLOSED A SIGNIFICANT CORRELATION BETWEEN A HIGHER BODY MASS INDEX AND LOWER METHYLATION OF FFAR3. LINE-1, A MARKER OF GLOBAL METHYLATION, INDICATED NO SIGNIFICANT DIFFERENCES BETWEEN THE THREE GROUPS OR THE TIME POINTS, ALTHOUGH METHYLATION OF TYPE 2 DIABETICS TENDED TO INCREASE OVER TIME. OUR RESULTS PROVIDE EVIDENCE THAT A DIFFERENT COMPOSITION OF GUT MICROBIOTA IN OBESITY AND TYPE 2 DIABETES AFFECT THE EPIGENETIC REGULATION OF GENES. INTERACTIONS BETWEEN THE MICROBIOTA AND EPIGENETIC REGULATION MAY INVOLVE NOT ONLY SHORT CHAIN FATTY ACIDS BINDING TO FFARS. THEREFORE DIETARY INTERVENTIONS INFLUENCING MICROBIAL COMPOSITION MAY BE CONSIDERED AS AN OPTION IN THE ENGAGEMENT AGAINST METABOLIC SYNDROME.	2014	

13 3152 25 GLUCOSE VARIABILITY: HOW DOES IT WORK? A GROWING BODY OF EVIDENCE POINTS TO THE ROLE OF GLUCOSE VARIABILITY (GV) IN THE DEVELOPMENT OF THE MICROVASCULAR AND MACROVASCULAR COMPLICATIONS OF DIABETES. IN THIS REVIEW, WE SUMMARIZE DATA ON GV-INDUCED BIOCHEMICAL, CELLULAR AND MOLECULAR EVENTS INVOLVED IN THE PATHOGENESIS OF DIABETIC COMPLICATIONS. CURRENT DATA INDICATE THAT THE DETERIORATING EFFECT OF GV ON TARGET ORGANS CAN BE REALIZED THROUGH OXIDATIVE STRESS, GLYCATION, CHRONIC LOW-GRADE INFLAMMATION, ENDOTHELIAL DYSFUNCTION, PLATELET ACTIVATION, IMPAIRED ANGIOGENESIS AND RENAL FIBROSIS. THE EFFECTS OF GV ON OXIDATIVE STRESS, INFLAMMATION, ENDOTHELIAL DYSFUNCTION AND HYPERCOAGULABILITY COULD BE AGGRAVATED BY HYPOGLYCEMIA, ASSOCIATED WITH HIGH GV. OSCILLATING HYPERGLYCEMIA CONTRIBUTES TO BETA CELL DYSFUNCTION, WHICH LEADS TO A FURTHER INCREASE IN GV AND COMPLETES THE VICIOUS CIRCLE. IN CELLS, THE GV-INDUCED CYTOTOXIC EFFECT INCLUDES MITOCHONDRIAL DYSFUNCTION, ENDOPLASMIC RETICULUM STRESS AND DISTURBANCES IN AUTOPHAGIC FLUX, WHICH ARE ACCOMPANIED BY REDUCED VIABILITY, ACTIVATION OF APOPTOSIS AND ABNORMALITIES IN CELL PROLIFERATION. THESE EFFECTS ARE REALIZED THROUGH THE UP- AND DOWN-REGULATION OF A LARGE NUMBER OF GENES AND THE ACTIVITY OF SIGNALING PATHWAYS SUCH AS PI3K/AKT, NF-KAPPAB, MAPK (ERK), JNK AND TGF-BETA/SMAD. EPIGENETIC MODIFICATIONS MEDIATE THE POSTPONED EFFECTS OF GLUCOSE FLUCTUATIONS. THE MULTIPLE DETERIORATIVE EFFECTS OF GV PROVIDE FURTHER SUPPORT FOR CONSIDERING IT AS A THERAPEUTIC TARGET IN DIABETES.	2021	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                      
14 2024 34 EPIGENETIC CHANGES CAUSED BY DIABETES AND THEIR POTENTIAL ROLE IN THE DEVELOPMENT OF PERIODONTITIS. AIMS/INTRODUCTION: PERIODONTAL DISEASE, A CHRONIC INFLAMMATION INDUCED BY BACTERIA, IS CLOSELY LINKED WITH DIABETES MELLITUS. MANY COMPLICATIONS ASSOCIATED WITH DIABETES ARE RELATED TO EPIGENETIC CHANGES. HOWEVER, THE EXACT EPIGENETIC CHANGES WHEREBY DIABETES AFFECTS PERIODONTAL DISEASE REMAIN LARGELY UNKNOWN. THUS, WE SOUGHT TO INVESTIGATE THE ROLE OF DIABETES-DEPENDENT EPIGENETIC CHANGES OF GINGIVAL TISSUE IN THE SUSCEPTIBILITY TO PERIODONTAL DISEASE. MATERIALS AND METHODS: WE STUDIED THE EFFECT OF STREPTOZOTOCIN-INDUCED DIABETES IN MINIPIGS ON GINGIVAL MORPHOLOGICAL AND EPIGENETIC TISSUE CHANGES. ACCORDINGLY, WE RANDOMLY DIVIDED SIX MINIPIGS INTO TWO GROUPS: STREPTOZOTOCIN-INDUCED DIABETES GROUP, N = 3; AND NON-DIABETES HEALTHY CONTROL GROUP, N = 3. AFTER 85 DAYS, ALL ANIMALS WERE KILLED, AND GINGIVAL TISSUE WAS COLLECTED FOR HISTOLOGY, DEOXYRIBONUCLEIC ACID METHYLATION ANALYSIS AND IMMUNOHISTOCHEMISTRY. RESULTS: A DIABETES MELLITUS MODEL WAS SUCCESSFULLY CREATED, AS EVIDENCED BY SIGNIFICANTLY INCREASED BLOOD GLUCOSE LEVELS, REDUCTION OF PANCREATIC INSULIN-PRODUCING BETA-CELLS AND HISTOPATHOLOGICAL CHANGES IN THE KIDNEYS. THE GINGIVAL TISSUES IN THE DIABETES GROUP PRESENTED ACANTHOSIS OF BOTH GINGIVAL SQUAMOUS EPITHELIUM AND SULCULAR/JUNCTIONAL EPITHELIUM, AND A SIGNIFICANT REDUCTION IN THE NUMBER AND LENGTH OF RETE PEGS. DEOXYRIBONUCLEIC ACID METHYLATION ANALYSIS SHOWED A TOTAL OF 1,163 AFFECTED GENES, OF WHICH 599 AND 564 WERE SIGNIFICANTLY HYPERMETHYLATED AND HYPOMETHYLATED, RESPECTIVELY. IMMUNOHISTOCHEMISTRY STAINING SHOWED THAT THE HYPOMETHYLATED GENES - TUMOR NECROSIS FACTOR-ALPHA AND INTERLEUKIN-6 - WERE POSITIVELY EXPRESSED UNDER THE JUNCTIONAL EPITHELIUM AREA IN THE DIABETES GROUP. CONCLUSIONS: DIABETES MELLITUS INDUCES MORPHOLOGICAL AND EPIGENETIC CHANGES IN PERIODONTAL TISSUE, WHICH MIGHT CONTRIBUTE TO THE INCREASED SUSCEPTIBILITY OF PERIODONTAL DISEASES IN PATIENTS WITH DIABETES.	2021	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                              
15 3959 28 LONG NON-CODING RNAS TARGET PATHOGENETICALLY RELEVANT GENES AND PATHWAYS IN RHEUMATOID ARTHRITIS. RHEUMATOID ARTHRITIS (RA) IS A CHRONIC INFLAMMATORY AUTOIMMUNE DISEASE DRIVEN BY GENETIC, ENVIRONMENTAL AND EPIGENETIC FACTORS. LONG NON-CODING RNAS (LNCRNAS) ARE A KEY COMPONENT OF THE EPIGENETIC MECHANISMS AND ARE KNOWN TO BE INVOLVED IN THE DEVELOPMENT OF AUTOIMMUNE DISEASES. IN THIS WORK WE AIMED TO IDENTIFY SIGNIFICANTLY DIFFERENTIALLY EXPRESSED LNCRNAS (DE-LNCRNAS) THAT ARE FUNCTIONALLY CONNECTED TO MODULATED GENES STRICTLY ASSOCIATED WITH RA. IN TOTAL, 542,500 TRANSCRIPTS HAVE BEEN PROFILED IN PERIPHERAL BLOOD MONONUCLEAR CELLS (PBMCS) FROM FOUR PATIENTS WITH EARLY ONSET RA PRIOR ANY TREATMENT AND FOUR HEALTHY DONORS USING CLARIOM D ARRAYS. RESULTS WERE CONFIRMED BY REAL-TIME PCR IN 20 PATIENTS AND 20 CONTROLS. SIX DE-LNCRNAS TARGET EXPERIMENTALLY VALIDATED MIRNAS ABLE TO REGULATE DIFFERENTIALLY EXPRESSED GENES (DEGS) IN RA; AMONG THEM, ONLY FTX, HNRNPU-AS1 AND RP11-498C9.15 TARGETED A LARGE NUMBER OF DEGS. MOST IMPORTANTLY, RP11-498C9.15 TARGETED THE LARGEST NUMBER OF SIGNALLING PATHWAYS THAT WERE FOUND TO BE ENRICHED BY THE GLOBAL AMOUNT OF RA-DEGS AND THAT HAVE ALREADY BEEN ASSOCIATED WITH RA AND RA-SYNOVIOCYTES. MOREOVER, RP11-498C9.15 TARGETED THE MOST HIGHLY CONNECTED GENES IN THE RA INTERACTOME, THUS SUGGESTING ITS INVOLVEMENT IN CRUCIAL GENE REGULATION. THESE RESULTS INDICATE THAT, BY MODULATING BOTH MICRORNAS AND GENE EXPRESSION, RP11-498C9.15 MAY PLAY A PIVOTAL ROLE IN RA PATHOGENESIS.	2019	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                      
16 1584 24 DNA METHYLATION PROFILES OF SELECTED PRO-INFLAMMATORY CYTOKINES IN ALZHEIMER DISEASE. BY MEANS OF FUNCTIONAL GENOMICS ANALYSIS, WE RECENTLY DESCRIBED THE MRNA EXPRESSION PROFILES OF VARIOUS GENES INVOLVED IN THE NEUROINFLAMMATORY RESPONSE IN THE BRAINS OF SUBJECTS WITH LATE-ONSET ALZHEIMER DISEASE (LOAD). SOME OF THESE GENES, NAMELY INTERLEUKIN (IL)-1BETA AND IL-6, SHOWED DISTINCT EXPRESSION PROFILES WITH PEAK EXPRESSION DURING THE FIRST STAGES OF THE DISEASE AND CONTROL-LIKE LEVELS AT LATER STAGES. IL-1BETA AND IL-6 GENES ARE MODULATED BY DNA METHYLATION IN DIFFERENT CHRONIC AND DEGENERATIVE DISEASES; IT IS ALSO WELL KNOWN THAT LOAD MAY HAVE AN EPIGENETIC BASIS. INDEED, WE AND OTHERS HAVE PREVIOUSLY REPORTED GENE-SPECIFIC DNA METHYLATION ALTERATIONS IN LOAD AND IN RELATED ANIMAL MODELS. BASED ON THESE DATA, WE STUDIED THE DNA METHYLATION PROFILES, AT SINGLE CYTOSINE RESOLUTION, OF IL-1BETA AND IL-6 5'-FLANKING REGION BY BISULPHITE MODIFICATION IN THE CORTEX OF HEALTHY CONTROLS AND LOAD PATIENTS AT 2 DIFFERENT DISEASE STAGES: BRAAK I-II/A AND BRAAK V-VI/C. OUR ANALYSIS PROVIDES EVIDENCE THAT NEUROINFLAMMATION IN LOAD IS ASSOCIATED WITH (AND POSSIBLY MEDIATED BY) EPIGENETIC MODIFICATIONS.	2017	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                   
17  662 25 BLOOD MONOCYTE TRANSCRIPTOME AND EPIGENOME ANALYSES REVEAL LOCI ASSOCIATED WITH HUMAN ATHEROSCLEROSIS. LITTLE IS KNOWN REGARDING THE EPIGENETIC BASIS OF ATHEROSCLEROSIS. HERE WE PRESENT THE CD14+ BLOOD MONOCYTE TRANSCRIPTOME AND EPIGENOME SIGNATURES ASSOCIATED WITH HUMAN ATHEROSCLEROSIS. THE TRANSCRIPTOME SIGNATURE INCLUDES TRANSCRIPTION COACTIVATOR, ARID5B, WHICH IS KNOWN TO FORM A CHROMATIN DEREPRESSOR COMPLEX WITH A HISTONE H3K9ME2-SPECIFIC DEMETHYLASE AND PROMOTE ADIPOGENESIS AND SMOOTH MUSCLE DEVELOPMENT. ARID5B CPG (CG25953130) METHYLATION IS INVERSELY ASSOCIATED WITH BOTH ARID5B EXPRESSION AND ATHEROSCLEROSIS, CONSISTENT WITH THIS CPG RESIDING IN AN ARID5B ENHANCER REGION, BASED ON CHROMATIN CAPTURE AND HISTONE MARKS DATA. MEDIATION ANALYSIS SUPPORTS ASSUMPTIONS THAT ARID5B EXPRESSION MEDIATES EFFECTS OF CG25953130 METHYLATION AND SEVERAL CARDIOVASCULAR DISEASE RISK FACTORS ON ATHEROSCLEROTIC BURDEN. IN LIPOPOLYSACCHARIDE-STIMULATED HUMAN THP1 MONOCYTES, ARID5B KNOCKDOWN REDUCED EXPRESSION OF GENES INVOLVED IN ATHEROSCLEROSIS-RELATED INFLAMMATORY AND LIPID METABOLISM PATHWAYS, AND INHIBITED CELL MIGRATION AND PHAGOCYTOSIS. THESE DATA SUGGEST THAT ARID5B EXPRESSION, POSSIBLY REGULATED BY AN EPIGENETICALLY CONTROLLED ENHANCER, PROMOTES ATHEROSCLEROSIS BY DYSREGULATING IMMUNOMETABOLISM TOWARDS A CHRONIC INFLAMMATORY PHENOTYPE.THE MOLECULAR MECHANISMS MEDIATING THE IMPACT OF ENVIRONMENTAL FACTORS IN ATHEROSCLEROSIS ARE UNCLEAR. HERE, THE AUTHORS EXAMINE CD14+ BLOOD MONOCYTE'S TRANSCRIPTOME AND EPIGENOME SIGNATURES TO FIND DIFFERENTIAL METHYLATION AND EXPRESSION OF ARID5B TO BE ASSOCIATED WITH HUMAN ATHEROSCLEROSIS.	2017	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                            
18  546 35 ATTENUATED EXPRESSION OF SLCO2A1 CAUSED BY DNA METHYLATION IN PEDIATRIC INFLAMMATORY BOWEL DISEASE. BACKGROUND: SLCO2A1 ENCODES A PROSTAGLANDIN (PG) TRANSPORTER, AND AUTOSOMAL RECESSIVE PATHOGENIC VARIANTS OF THIS GENE CAUSE CHRONIC ENTEROPATHY ASSOCIATED WITH SLCO2A1. IT IS UNCLEAR WHETHER A HETEROZYGOUS PATHOGENIC VARIANT OF SLCO2A1 HAS A ROLE IN THE PATHOGENESIS OF OTHER TYPES OF INFLAMMATORY BOWEL DISEASE (IBD). IN THIS STUDY, WE INVESTIGATED THE POSSIBLE INVOLVEMENT OF A LOCAL EPIGENETIC ALTERATION IN SLCO2A1 IN PATIENTS WITH A HETEROZYGOUS PATHOGENIC VARIANT. METHODS: WE CONDUCTED WHOLE-EXOME SEQUENCING OF SAMPLES FROM 2 SISTERS WITH SUSPECTED MONOGENIC IBD. IN ADDITION, WE PERFORMED BISULFITE SEQUENCING USING DNA EXTRACTED FROM THEIR SMALL AND LARGE INTESTINE SAMPLES TO EXPLORE EPIGENETIC ALTERATIONS. RESULTS: A HETEROZYGOUS SPLICING SITE VARIANT, SLCO2A1:C.940 + 1G > A, WAS DETECTED IN BOTH PATIENTS. TO EXPLORE THE POSSIBLE INVOLVEMENT OF EPIGENETIC ALTERATIONS, WE ANALYZED PROTEIN AND MESSENGER RNA EXPRESSION OF SLCO2A1, AND OBSERVED ATTENUATED SLCO2A1 EXPRESSION IN THE INFLAMED LESIONS OF THESE PATIENTS COMPARED WITH THAT IN THE CONTROL INDIVIDUALS. FURTHERMORE, BISULFITE SEQUENCING INDICATED DENSE METHYLATION IN THE PROMOTER REGION OF SLCO2A1 ONLY IN THE INFLAMED LESIONS OF BOTH PATIENTS. THE URINARY PG METABOLITE LEVELS IN THESE PATIENTS WERE COMPARABLE TO THOSE IN PATIENTS WITH CHRONIC ENTEROPATHY ASSOCIATED WITH SLCO2A1 AND HIGHER THAN THOSE IN THE CONTROL INDIVIDUALS. WE FOUND CONSIDERABLY HIGHER LEVELS OF THE METABOLITES IN PATIENT 1, WHO SHOWED MORE SEVERE SYMPTOMS THAN PATIENT 2. CONCLUSIONS: LOCAL DNA METHYLATION ATTENUATED SLCO2A1 EXPRESSION, WHICH MAY EVOKE LOCAL INFLAMMATION OF THE MUCOSA BY THE UNINCORPORATED PG. THESE FINDINGS MAY IMPROVE OUR UNDERSTANDING OF THE EPIGENETIC MECHANISMS UNDERLYING IBD DEVELOPMENT.	2023	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                              
19 6354 28 THE ROLE OF GENETICS AND EPIGENETICS IN THE PATHOGENESIS OF GESTATIONAL DIABETES MELLITUS. DIABETES MELLITUS (DM) IS A HETEROGENEOUS GROUP OF DISORDERS WHOSE COMMON TRAIT IS CHRONIC HYPERGLYCEMIA. GESTATIONAL DIABETES MELLITUS (GDM) IS ONE OF THE SUBTYPES OF DM THAT MANIFESTS DURING PREGNANCY. IT IS BELIEVED THAT 2%-5% OF PREGNANCIES WORLDWIDE ARE COMPLICATED WITH GDM, WITH THE PREVALENCE HAVING SIGNIFICANTLY INCREASED OVER THE LAST DECADE. WHILE THE PATHOGENESIS OF THE DISEASE REMAINS LARGELY UNKNOWN, GDM IS BELIEVED TO BE A RESULT OF INTERACTIONS BETWEEN GENETIC, EPIGENETIC, AND ENVIRONMENTAL FACTORS. LINKAGE AND ASSOCIATION STUDIES, INCLUDING THOSE THAT ARE GENOME-WIDE, HAVE ALLOWED US TO IDENTIFY COMPLEX GENETIC AND EPIGENETIC MECHANISMS THAT LEAD TO THE DEVELOPMENT OF GDM. MULTIPLE COMMON VARIANTS IN CANDIDATE GENES SUCH AS POTASSIUM INWARDLY RECTIFYING CHANNEL SUBFAMILY J, MEMBER 11 (KCNJ11), GLUCOKINASE (GCK), OR HEPATOCYTE NUCLEAR FACTOR 1ALPHA (HNF1A) HAVE BEEN FOUND TO INCREASE THE DISEASE RISK. IN THIS REVIEW, WE PROVIDE A DETAILED OVERVIEW OF THE CURRENT KNOWLEDGE CONCERNING THE INFLUENCE OF GENETICS AND EPIGENETICS ON THE DEVELOPMENT OF GDM.	2020	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                     
20 6642 27 UNRAVELING THE PATHOGENESIS OF ASTHMA AND CHRONIC OBSTRUCTIVE PULMONARY DISEASE OVERLAP: FOCUSING ON EPIGENETIC MECHANISMS. ASTHMA AND COPD OVERLAP (ACO) IS CHARACTERIZED BY PATIENTS PRESENTING WITH PERSISTENT AIRFLOW LIMITATION AND FEATURES OF BOTH ASTHMA AND COPD. IT IS ASSOCIATED WITH A HIGHER FREQUENCY AND SEVERITY OF EXACERBATIONS, A FASTER LUNG FUNCTION DECLINE, AND A HIGHER HEALTHCARE COST. SYSTEMIC INFLAMMATION IN COPD AND ASTHMA IS DRIVEN BY TYPE 1 T HELPER (TH1) AND TH2 IMMUNE RESPONSES, RESPECTIVELY, BOTH OF WHICH MAY CONTRIBUTE TO AIRWAY REMODELING IN ACO. ACO-RELATED BIOMARKERS CAN BE CLASSIFIED INTO FOUR CATEGORIES: NEUTROPHIL-MEDIATED INFLAMMATION, TH2 CELL RESPONSES, ARACHIDONIC ACID-EICOSANOIDS PATHWAY, AND METABOLITES. GENE-ENVIRONMENT INTERACTIONS ARE KEY CONTRIBUTORS TO THE COMPLEXITY OF ACO AND ARE REGULATED BY EPIGENETIC MECHANISMS, INCLUDING DNA METHYLATION, HISTONE MODIFICATIONS, AND NON-CODING RNAS. THUS, THIS REVIEW FOCUSES ON THE LINK BETWEEN EPIGENETICS AND ACO, AND OUTLINES THE FOLLOWING: (I) INHERITING EPIGENOTYPES WITHOUT CHANGE WITH ENVIRONMENTAL STIMULI, OR EPIGENETIC CHANGES IN RESPONSE TO LONG-TERM EXPOSURE TO INHALED PARTICLES PLUS INTERMITTENT EXPOSURE TO SPECIFIC ALLERGENS; (II) EPIGENETIC MARKERS DISTINGUISHING ACO FROM COPD AND ASTHMA; (III) POTENTIAL EPIGENETIC DRUGS THAT CAN REVERSE OXIDATIVE STRESS, GLUCOCORTICOID INSENSITIVITY, AND CELL INJURY. IMPROVED UNDERSTANDING OF THE EPIGENETIC REGULATIONS HOLDS GREAT VALUE TO GIVE DEEPER INSIGHT INTO THE MECHANISMS, AND CLARIFY THEIR IMPLICATIONS FOR BIOMEDICAL RESEARCH IN ACO.	2022