1 6474 115 TOBACCO HEATING SYSTEM 2.2 HAS A LIMITED IMPACT ON DNA METHYLATION OF CANDIDATE ENHANCERS IN MOUSE LUNG COMPARED WITH CIGARETTE SMOKE. CIGARETTE SMOKE (CS) EXPOSURE HAS BEEN SHOWN TO CORRELATE WITH CHANGES IN DNA METHYLATION LEVELS, HOWEVER, THE IMPACT OF CS ON DNA METHYLATION AT GENOME-WIDE SCALE IS MISSING. HERE, WE USED WHOLE-GENOME BISULFITE SEQUENCING TO ASSESS THE EFFECTS OF CS EXTRACT AND AEROSOL FROM THE TOBACCO HEATING SYSTEM (THS) 2.2, A CANDIDATE MODIFIED RISK TOBACCO PRODUCT, ON DNA METHYLATION IN LUNG AND LIVER TISSUES FROM APOLIPOPROTEIN E-DEFICIENT MICE DURING AN EIGHT-MONTH PERIOD OF EXPOSURE. WE FOUND THAT IN LUNG TISSUE, CS MAINLY INDUCED HYPERMETHYLATION OF CANDIDATE ENHANCERS AT LATE TIME POINTS, WHILE PROMOTERS WERE LESS AFFECTED. THIS EFFECT WAS STRONGLY REDUCED UPON CESSATION OR SWITCHING TO THS 2.2. BY CONTRAST, CHRONIC EXPOSURE TO THS 2.2 HAD A LIMITED EFFECT ON DNA METHYLATION AT BOTH PROMOTERS AND ENHANCERS. WE ALSO IDENTIFIED MEMBERS OF THE ETS AND FOX FAMILIES OF TRANSCRIPTION FACTORS AS POTENTIAL PLAYERS IN THE EPIGENETIC RESPONSE TO CS EXPOSURE IN LUNG TISSUE. IN CONTRAST TO THE LUNG, DNA METHYLATION IN THE LIVER WAS LARGELY INSENSITIVE TO ALL INVESTIGATED EXPOSURES. IN SUMMARY, OUR INVESTIGATIONS INDICATE THAT CS-RELATED DNA METHYLATION ALTERATIONS ARE TISSUE-SPECIFIC, OCCUR MAINLY AT ENHANCERS AND ARE STRONGLY REDUCED UPON SMOKING CESSATION OR SWITCHING TO THS2.2. 2019 2 1705 38 DYNAMICS OF SMOKING-INDUCED GENOME-WIDE METHYLATION CHANGES WITH TIME SINCE SMOKING CESSATION. SEVERAL STUDIES HAVE RECENTLY IDENTIFIED STRONG EPIGENETIC SIGNALS RELATED TO TOBACCO SMOKING. HOWEVER, AN ASPECT THAT DID NOT RECEIVE MUCH ATTENTION IS THE EVOLUTION OF EPIGENETIC CHANGES WITH TIME SINCE SMOKING CESSATION. WE CONDUCTED A SERIES OF EPIGENOME-WIDE ASSOCIATION STUDIES TO CAPTURE THE DYNAMICS OF SMOKING-INDUCED EPIGENETIC CHANGES AFTER SMOKING CESSATION, USING GENOME-WIDE METHYLATION PROFILES OBTAINED FROM BLOOD SAMPLES IN 745 WOMEN FROM 2 EUROPEAN POPULATIONS. TWO DISTINCT CLASSES OF CPG SITES WERE IDENTIFIED: SITES WHOSE METHYLATION REVERTS TO LEVELS TYPICAL OF NEVER SMOKERS WITHIN DECADES AFTER SMOKING CESSATION, AND SITES REMAINING DIFFERENTIALLY METHYLATED, EVEN MORE THAN 35 YEARS AFTER SMOKING CESSATION. OUR RESULTS SUGGEST THAT THE DYNAMICS OF METHYLATION CHANGES FOLLOWING SMOKING CESSATION ARE DRIVEN BY A DIFFERENTIAL AND SITE-SPECIFIC MAGNITUDE OF THE SMOKING-INDUCED ALTERATIONS (WITH PERSISTENT SITES BEING MOST AFFECTED) IRRESPECTIVE OF THE INTENSITY AND DURATION OF SMOKING. ANALYSES OF THE LINK BETWEEN METHYLATION AND EXPRESSION LEVELS REVEALED THAT METHYLATION PREDOMINANTLY AND REMOTELY DOWN-REGULATES GENE EXPRESSION. AMONG GENES WHOSE EXPRESSION WAS ASSOCIATED WITH OUR CANDIDATE CPG SITES, LRRN3 APPEARED TO BE PARTICULARLY INTERESTING AS IT WAS ONE OF THE FEW GENES WHOSE METHYLATION AND EXPRESSION WERE DIRECTLY ASSOCIATED, AND THE ONLY GENE IN WHICH BOTH METHYLATION AND GENE EXPRESSION WERE FOUND ASSOCIATED WITH SMOKING. OUR STUDY HIGHLIGHTS PERSISTENT EPIGENETIC MARKERS OF SMOKING, WHICH CAN POTENTIALLY BE DETECTED DECADES AFTER CESSATION. SUCH HISTORICAL SIGNATURES ARE PROMISING BIOMARKERS TO REFINE INDIVIDUAL RISK PROFILING OF SMOKING-INDUCED CHRONIC DISEASE SUCH AS LUNG CANCER. 2015 3 1551 32 DNA METHYLATION IS GLOBALLY DISRUPTED AND ASSOCIATED WITH EXPRESSION CHANGES IN CHRONIC OBSTRUCTIVE PULMONARY DISEASE SMALL AIRWAYS. DNA METHYLATION IS AN EPIGENETIC MODIFICATION THAT IS HIGHLY DISRUPTED IN RESPONSE TO CIGARETTE SMOKE AND INVOLVED IN A WIDE SPECTRUM OF MALIGNANT AND NONMALIGNANT DISEASES, BUT SURPRISINGLY NOT PREVIOUSLY ASSESSED IN SMALL AIRWAYS OF PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). SMALL AIRWAYS ARE THE PRIMARY SITES OF AIRFLOW OBSTRUCTION IN COPD. WE SOUGHT TO DETERMINE WHETHER DNA METHYLATION PATTERNS ARE DISRUPTED IN SMALL AIRWAY EPITHELIA OF PATIENTS WITH COPD, AND EVALUATE WHETHER CHANGES IN GENE EXPRESSION ARE ASSOCIATED WITH THESE DISRUPTIONS. GENOME-WIDE METHYLATION AND GENE EXPRESSION ANALYSIS WERE PERFORMED ON SMALL AIRWAY EPITHELIAL DNA AND RNA OBTAINED FROM THE SAME PATIENT DURING BRONCHOSCOPY, USING ILLUMINA'S INFINIUM HM27 AND AFFYMETRIX'S GENECHIP HUMAN GENE 1.0 ST ARRAYS. TO CONTROL FOR KNOWN EFFECTS OF CIGARETTE SMOKING ON DNA METHYLATION, METHYLATION AND GENE EXPRESSION PROFILES WERE COMPARED BETWEEN FORMER SMOKERS WITH AND WITHOUT COPD MATCHED FOR AGE, PACK-YEARS, AND YEARS OF SMOKING CESSATION. OUR RESULTS INDICATE THAT ABERRANT DNA METHYLATION IS (1) A GENOME-WIDE PHENOMENON IN SMALL AIRWAYS OF PATIENTS WITH COPD, AND (2) ASSOCIATED WITH ALTERED EXPRESSION OF GENES AND PATHWAYS IMPORTANT TO COPD, SUCH AS THE NF-E2-RELATED FACTOR 2 OXIDATIVE RESPONSE PATHWAY. DNA METHYLATION IS LIKELY AN IMPORTANT MECHANISM CONTRIBUTING TO MODULATION OF GENES IMPORTANT TO COPD PATHOLOGY. BECAUSE THESE METHYLATION EVENTS MAY UNDERLIE DISEASE-SPECIFIC GENE EXPRESSION CHANGES, THEIR CHARACTERIZATION IS A CRITICAL FIRST STEP TOWARD THE DEVELOPMENT OF EPIGENETIC MARKERS AND AN OPPORTUNITY FOR DEVELOPING NOVEL EPIGENETIC THERAPEUTIC INTERVENTIONS FOR COPD. 2014 4 1589 43 DNA METHYLATION PROFILING IN A CIGARETTE SMOKE-EXPOSED MOUSE MODEL OF AIRWAY INFLAMMATION. PURPOSE: DNA METHYLATION, A MAJOR EPIGENETIC MODIFICATION, HAS BEEN DOCUMENTED TO PLAY AN IMPORTANT ROLE IN CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). IN THIS STUDY, WE AIMED TO PROFILE THE DNA METHYLATION PATTERNS IN A MOUSE MODEL OF AIRWAY INFLAMMATION INDUCED BY CIGARETTE SMOKE (CS), A FOREMOST RISK FACTOR OF COPD. MATERIAL AND METHODS: TO ESTABLISH A MODEL OF AIRWAY INFLAMMATION, WILD-TYPE MICE WERE EXPOSED TO MAINSTREAM CS OR ROOM AIR FOR 2 HOURS TWICE DAILY, 6 DAYS PER WEEK FOR CONSECUTIVE 4 WEEKS. LUNG TISSUES OF THE MICE WERE COLLECTED FOR GENOME-WIDE DNA METHYLATION ANALYSIS BY LIQUID HYBRIDIZATION CAPTURE-BASED BISULFITE SEQUENCING, WHICH WERE USED FOR INTERSECTION ANALYSIS WITH GENE EXPRESSION BY CDNA MICROARRAY TO IDENTIFY CANDIDATE METHYLATED GENES. THEN, FUNCTIONAL ENRICHMENT ANALYSES WITH PROTEIN-PROTEIN INTERACTION (PPI) NETWORK REGARDING THESE GENES WERE CONDUCTED TO EXPLORE THE POTENTIAL MECHANISMS. RESULTS: AFTER 4-WEEK CS EXPOSURE, THE LEVEL OF DNA METHYLATION ACCOMPANIED BY A SUBACUTE AIRWAY INFLAMMATION WAS MARKEDLY ENHANCED, AND 2002 DIFFERENTIALLY METHYLATED GENES (DMGS) WERE ANNOTATED, INCLUDING 565 DMGS CONTAINED METHYLATIONS IN GENE PROMOTERS, WHICH WERE USED FOR INTERSECTION WITH THE DIFFERENTIALLY EXPRESSED GENES. THEN, 135 CANDIDATE METHYLATED GENES WERE FURTHER SELECTED BY THE INTERSECTION, AMONG WHICH 58 GENES WITH FUNCTIONAL METHYLATED MODIFICATION WERE FINALLY IDENTIFIED. FURTHER ANALYSES REVEALED CANDIDATE METHYLATED GENES WERE SIGNIFICANTLY ENRICHED IN A COMPLICATED NETWORK OF SIGNALS AND PROCESSES, INCLUDING INTERLEUKINS, TOLL-LIKE RECEPTORS, T-CELLS DIFFERENTIATION, OXIDATIVE STRESS, MAST CELLS ACTIVATION, STEM CELLS PROLIFERATION, ETC., AS WELL AS THE 58 FUNCTIONAL METHYLATED GENES WERE PARTIALLY LOCATED AT KEY POSITIONS IN PPI NETWORK, ESPECIALLY CXCL1, DDX58 AND JAK3. CONCLUSION: THIS STUDY SUGGESTS CS EXPOSURE SIGNIFICANTLY ENHANCES DNA METHYLATED LEVEL, AND THE POTENTIAL FUNCTIONAL METHYLATED GENES ARE CLOSELY RELATED TO COMPLICATED INFLAMMATORY-IMMUNE RESPONSES, WHICH MAY PROVIDE SOME NEW EXPERIMENTAL EVIDENCE IN UNDERSTANDING THE EPIGENETIC MECHANISMS OF CS-INDUCED AIRWAY INFLAMMATION IN COPD. 2022 5 5741 37 SMOKING INDUCES DNA METHYLATION CHANGES IN MULTIPLE SCLEROSIS PATIENTS WITH EXPOSURE-RESPONSE RELATIONSHIP. CIGARETTE SMOKING IS AN ESTABLISHED ENVIRONMENTAL RISK FACTOR FOR MULTIPLE SCLEROSIS (MS), A CHRONIC INFLAMMATORY AND NEURODEGENERATIVE DISEASE, ALTHOUGH A MECHANISTIC BASIS REMAINS LARGELY UNKNOWN. WE AIMED AT INVESTIGATING HOW SMOKING AFFECTS BLOOD DNA METHYLATION IN MS PATIENTS, BY ASSAYING GENOME-WIDE DNA METHYLATION AND COMPARING SMOKERS, FORMER SMOKERS AND NEVER SMOKERS IN TWO SWEDISH COHORTS, DIFFERING FOR KNOWN MS RISK FACTORS. SMOKING AFFECTS DNA METHYLATION GENOME-WIDE SIGNIFICANTLY, AN EXPOSURE-RESPONSE RELATIONSHIP EXISTS AND THE TIME SINCE SMOKING CESSATION AFFECTS METHYLATION LEVELS. THE RESULTS ALSO SHOW THAT THE CHANGES WERE LARGER IN THE COHORT BEARING THE MAJOR GENETIC RISK FACTORS FOR MS (FEMALE SEX AND HLA RISK HAPLOTYPES). FURTHERMORE, CPG SITES MAPPING TO GENES WITH KNOWN GENETIC OR FUNCTIONAL ROLE IN THE DISEASE ARE DIFFERENTIALLY METHYLATED BY SMOKING. MODELING OF THE METHYLATION LEVELS FOR A CPG SITE IN THE AHRR GENE INDICATES THAT MS MODIFIES THE EFFECT OF SMOKING ON METHYLATION CHANGES, BY SIGNIFICANTLY INTERACTING WITH THE EFFECT OF SMOKING LOAD. ALONGSIDE, WE REPORT THAT THE GENE EXPRESSION OF AHRR INCREASED IN MS PATIENTS AFTER SMOKING. OUR RESULTS SUGGEST THAT EPIGENETIC MODIFICATIONS MAY REVEAL THE LINK BETWEEN A MODIFIABLE RISK FACTOR AND THE PATHOGENETIC MECHANISMS. 2017 6 1655 27 DOSE-DEPENDENCE, SEX- AND TISSUE-SPECIFICITY, AND PERSISTENCE OF RADIATION-INDUCED GENOMIC DNA METHYLATION CHANGES. RADIATION IS A WELL-KNOWN GENOTOXIC AGENT AND HUMAN CARCINOGEN THAT GIVES RISE TO A VARIETY OF LONG-TERM EFFECTS. ITS DETRIMENTAL INFLUENCE ON CELLULAR FUNCTION IS ACTIVELY STUDIED NOWADAYS. ONE OF THE MOST ANALYZED, YET LEAST UNDERSTOOD LONG-TERM EFFECTS OF IONIZING RADIATION IS TRANSGENERATIONAL GENOMIC INSTABILITY. THE INHERITANCE OF GENOMIC INSTABILITY SUGGESTS THE POSSIBLE INVOLVEMENT OF EPIGENETIC MECHANISMS, SUCH AS CHANGES OF THE METHYLATION OF CYTOSINE RESIDUES LOCATED WITHIN CPG DINUCLEOTIDES. IN THE CURRENT STUDY WE EVALUATED THE DOSE-DEPENDENCE OF THE RADIATION-INDUCED GLOBAL GENOME DNA METHYLATION CHANGES. WE ALSO ANALYZED THE EFFECTS OF ACUTE AND CHRONIC HIGH DOSE (5GY) EXPOSURE ON DNA METHYLATION IN LIVER, SPLEEN, AND LUNG TISSUES OF MALE AND FEMALE MICE AND EVALUATED THE POSSIBLE PERSISTENCE OF THE RADIATION-INDUCED DNA METHYLATION CHANGES. HERE WE REPORT THAT RADIATION-INDUCED DNA METHYLATION CHANGES WERE SEX- AND TISSUE-SPECIFIC, DOSE-DEPENDENT, AND PERSISTENT. IN PARALLEL WE HAVE STUDIED THE LEVELS OF DNA DAMAGE IN THE EXPOSED TISSUES. BASED ON THE CORRELATION BETWEEN THE LEVELS OF DNA METHYLATION AND DNA DAMAGE WE PROPOSE THAT RADIATION-INDUCED GLOBAL GENOME DNA HYPOMETHYLATION IS DNA REPAIR-RELATED. 2004 7 5418 43 REGULATION OF DNA METHYLATION SIGNATURES ON NF-KAPPAB AND STAT3 PATHWAY GENES AND TET ACTIVITY IN CIGARETTE SMOKE EXTRACT-CHALLENGED CELLS/COPD EXACERBATION MODEL IN VITRO. BACKGROUND: CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) IS A GLOBAL HEALTH PROBLEM. CURRENTLY, THERE IS A LACK OF KNOWLEDGE ABOUT THE PATHOBIOLOGY OF THIS DISEASE AND AVAILABLE THERAPIES ARE INEFFECTIVE. CIGARETTE SMOKING IS THE LEADING CAUSE OF COPD; HOWEVER, NOT ALL SMOKERS DEVELOP COPD. EXACERBATIONS OF COPD CAUSED BY MICROBES ARE COMMON AND DETRIMENTAL. APPROXIMATELY 20-50% OF PATIENT EXACERBATIONS ARE CAUSED BY BACTERIAL COLONIZATION IN THE LOWER AIRWAYS. IT IS GENERALLY ACCEPTED THAT EPIGENETIC MECHANISMS, ESPECIALLY DNA METHYLATION, PLAY AN IMPORTANT ROLE DURING PROGRESSION OF COPD. THUS, WE HYPOTHESIZED THAT DNA METHYLATION PATTERNS VARY SIGNIFICANTLY FOLLOWING SMOKE EXPOSURE AND DURING EXACERBATIONS CAUSED BY BACTERIAL INFECTIONS. TO TEST OUR HYPOTHESIS, WE USED AN IN VITRO STUDY MODEL THAT MIMICS COPD EXACERBATIONS AND PERFORMED EXTENSIVE STUDIES TO UNDERSTAND THE ROLE OF CPG PROMOTER METHYLATION OF NF-KAPPAB AND STAT3-MEDIATED PATHWAY GENES. BOTH NF-KAPPAB AND STAT3 TRANSCRIPTION FACTORS PLAY CRITICAL ROLES IN ORCHESTRATING INFLAMMATORY RESPONSES DURING CIGARETTE SMOKE EXPOSURE. IN BRIEF, HUMAN LUNG ADENOCARCINOMA CELLS WITH TYPE II ALVEOLAR EPITHELIUM CHARACTERISTICS (A549) WERE CHALLENGED WITH CIGARETTE SMOKE EXTRACT (CSE) OR DMSO (CONTROL) FOLLOWED BY A 3-H CHALLENGE WITH BACTERIAL LIPOPOLYSACCHARIDE (LPS; FROM PSEUDOMONAS AERUGINOSA) PRIOR TO THE TERMINATION OF CSE EXPOSURE (COPD EXACERBATION GROUP). THE PRODUCTION OF CYTOKINES/CHEMOKINES, REGULATION OF TRANSCRIPTION FACTORS, AND DNA METHYLATION OF SPECIFIC GENES WERE THEN ASSESSED. WE ALSO STUDIED CHANGES IN THE EXPRESSION AND ACTIVITY OF TEN-ELEVEN TRANSLOCASES (TETS), THE ENZYMES RESPONSIBLE FOR DNA DEMETHYLATION, AND ASSESSED THEIR ROLE IN REGULATING DNA METHYLATION IN THE CSE-CHALLENGED GROUP. RESULTS: THERE WAS A SIGNIFICANT INCREASE IN THE RELEASE OF CYTOKINES/CHEMOKINES (IL-8, MCP-1, IL-6 AND CCL5) IN THE COPD EXACERBATION GROUP AS COMPARED TO THE CONTROL GROUP. HYPOMETHYLATION OF NF-KAPPAB-MEDIATED PATHWAY GENES CORRELATED WITH THEIR INDUCTION IN OUR COPD EXACERBATION STUDY MODEL. FURTHER, WE OBSERVED AN IMPORTANT ROLE OF TET1/2 IN REGULATING THE DNA METHYLATION OF NF-KAPPAB, STAT3, IKK, AND NIK GENES AND CYTOKINE/CHEMOKINE PRODUCTION BY A549 CELLS DURING CSE CHALLENGE. CONCLUSIONS: STUDIES TO FURTHER DEFINE THE ROLE OF TETS IN CSE-MEDIATED EPIGENETIC REGULATION MAY LEAD TO THE DEVELOPMENT OF BETTER AND MORE EFFECTIVE THERAPEUTIC INTERVENTION STRATEGIES FOR COPD. 2020 8 348 32 ALTERED DNA METHYLATION IS ASSOCIATED WITH ABERRANT GENE EXPRESSION IN PARENCHYMAL BUT NOT AIRWAY FIBROBLASTS ISOLATED FROM INDIVIDUALS WITH COPD. BACKGROUND: CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) IS A HETEROGENEOUS DISEASE OF THE LUNGS THAT IS CURRENTLY THE FOURTH LEADING CAUSE OF DEATH WORLDWIDE. GENETIC FACTORS ACCOUNT FOR ONLY A SMALL AMOUNT OF COPD RISK, BUT EPIGENETIC MECHANISMS, INCLUDING DNA METHYLATION, HAVE THE POTENTIAL TO MEDIATE THE INTERACTIONS BETWEEN AN INDIVIDUAL'S GENETICS AND ENVIRONMENTAL EXPOSURE. DNA METHYLATION IS HIGHLY CELL TYPE-SPECIFIC, AND INDIVIDUAL CELL TYPE STUDIES OF DNA METHYLATION IN COPD ARE SPARSE. FIBROBLASTS ARE PRESENT WITHIN THE AIRWAY AND PARENCHYMA OF THE LUNG AND CONTRIBUTE TO THE ABERRANT DEPOSITION OF EXTRACELLULAR MATRIX IN COPD. NO ASSESSMENT OR COMPARISON OF GENOME-WIDE DNA METHYLATION PROFILES IN THE AIRWAY AND PARENCHYMAL FIBROBLASTS FROM INDIVIDUALS WITH AND WITHOUT COPD HAS BEEN UNDERTAKEN. THESE DATA PROVIDE VALUABLE INSIGHT INTO THE MOLECULAR MECHANISMS CONTRIBUTING TO COPD AND THE DIFFERING PATHOLOGIES OF SMALL AIRWAYS DISEASE AND EMPHYSEMA IN COPD. METHODS: GENOME-WIDE DNA METHYLATION WAS EVALUATED AT OVER 485,000 CPG SITES USING THE ILLUMINA INFINIUM HUMANMETHYLATION450 BEADCHIP ARRAY IN THE AIRWAY (NON-COPD N = 8, COPD N = 7) AND PARENCHYMAL FIBROBLASTS (NON-COPD N = 17, COPD N = 29) ISOLATED FROM INDIVIDUALS WITH AND WITHOUT COPD. TARGETED GENE EXPRESSION WAS ASSESSED BY QPCR IN MATCHED RNA SAMPLES. RESULTS: DIFFERENTIALLY METHYLATED DNA REGIONS WERE IDENTIFIED BETWEEN CELLS ISOLATED FROM INDIVIDUALS WITH AND WITHOUT COPD IN BOTH AIRWAY AND PARENCHYMAL FIBROBLASTS. ONLY IN PARENCHYMAL FIBROBLASTS WAS DIFFERENTIAL DNA METHYLATION ASSOCIATED WITH DIFFERENTIAL GENE EXPRESSION. A SECOND ANALYSIS OF DIFFERENTIAL DNA METHYLATION VARIABILITY IDENTIFIED 359 INDIVIDUAL DIFFERENTIALLY VARIABLE CPG SITES IN PARENCHYMAL FIBROBLASTS. NO DIFFERENTIALLY VARIABLE CPG SITES WERE IDENTIFIED IN THE AIRWAY FIBROBLASTS. FIVE DIFFERENTIALLY VARIABLE-METHYLATED CPG SITES, ASSOCIATED WITH THREE GENES, WERE SUBSEQUENTLY ASSESSED FOR GENE EXPRESSION DIFFERENCES. TWO GENES (OAT AND GRIK2) DISPLAYED SIGNIFICANTLY INCREASED GENE EXPRESSION IN CELLS ISOLATED FROM INDIVIDUALS WITH COPD. CONCLUSIONS: DIFFERENTIAL AND VARIABLE DNA METHYLATION WAS ASSOCIATED WITH COPD STATUS IN THE PARENCHYMAL FIBROBLASTS BUT NOT AIRWAY FIBROBLASTS. ABERRANT DNA METHYLATION WAS ASSOCIATED WITH ALTERED GENE EXPRESSION IMPARTING BIOLOGICAL FUNCTION TO DNA METHYLATION CHANGES. CHANGES IN DNA METHYLATION ARE THEREFORE IMPLICATED IN THE MOLECULAR MECHANISMS UNDERLYING COPD PATHOGENESIS AND MAY REPRESENT NOVEL THERAPEUTIC TARGETS. 2018 9 287 35 AGING AND CHRONIC SUN EXPOSURE CAUSE DISTINCT EPIGENETIC CHANGES IN HUMAN SKIN. EPIGENETIC CHANGES ARE WIDELY CONSIDERED TO PLAY AN IMPORTANT ROLE IN AGING, BUT EXPERIMENTAL EVIDENCE TO SUPPORT THIS HYPOTHESIS HAS BEEN SCARCE. WE HAVE USED ARRAY-BASED ANALYSIS TO DETERMINE GENOME-SCALE DNA METHYLATION PATTERNS FROM HUMAN SKIN SAMPLES AND TO INVESTIGATE THE EFFECTS OF AGING, CHRONIC SUN EXPOSURE, AND TISSUE VARIATION. OUR RESULTS REVEAL A HIGH DEGREE OF TISSUE SPECIFICITY IN THE METHYLATION PATTERNS AND ALSO SHOWED VERY LITTLE INTERINDIVIDUAL VARIATION WITHIN TISSUES. DATA STRATIFICATION BY AGE REVEALED THAT DNA FROM OLDER INDIVIDUALS WAS CHARACTERIZED BY A SPECIFIC HYPERMETHYLATION PATTERN AFFECTING LESS THAN 1% OF THE MARKERS ANALYZED. INTERESTINGLY, STRATIFICATION BY SUN EXPOSURE PRODUCED A FUNDAMENTALLY DIFFERENT PATTERN WITH A SIGNIFICANT TREND TOWARDS HYPOMETHYLATION. OUR RESULTS THUS IDENTIFY DEFINED AGE-RELATED DNA METHYLATION CHANGES AND SUGGEST THAT THESE ALTERATIONS MIGHT CONTRIBUTE TO THE PHENOTYPIC CHANGES ASSOCIATED WITH SKIN AGING. 2010 10 1528 34 DNA METHYLATION CHANGES IN REGIONAL LUNG MACROPHAGES ARE ASSOCIATED WITH METABOLIC DIFFERENCES. A NUMBER OF PULMONARY DISEASES OCCUR WITH UPPER LOBE PREDOMINANCE, INCLUDING CYSTIC FIBROSIS AND SMOKING-RELATED CHRONIC OBSTRUCTIVE PULMONARY DISEASE. IN THE HEALTHY LUNG, SEVERAL PHYSIOLOGIC AND METABOLIC FACTORS EXHIBIT DISPARITY WHEN COMPARING THE UPPER LOBE OF THE LUNG TO LOWER LOBE, INCLUDING DIFFERENCES IN OXYGENATION, VENTILATION, LYMPHATIC FLOW, PH, AND BLOOD FLOW. IN THIS STUDY, WE ASKED WHETHER THESE REGIONAL DIFFERENCES IN THE LUNG ARE ASSOCIATED WITH DNA METHYLATION CHANGES IN LUNG MACROPHAGES THAT COULD POTENTIALLY LEAD TO ALTERED CELL RESPONSIVENESS UPON SUBSEQUENT ENVIRONMENTAL CHALLENGE. ALL ANALYSES WERE PERFORMED USING PRIMARY LUNG MACROPHAGES COLLECTED VIA BRONCHOALVEOLAR LAVAGE FROM HEALTHY HUMAN SUBJECTS WITH NORMAL PULMONARY FUNCTION. EPIGENOME-WIDE DNA METHYLATION WAS EXAMINED VIA INFINIUM METHYLATIONEPIC (850K) ARRAY AND VALIDATED BY TARGETED NEXT-GENERATION BISULFITE SEQUENCING. WE OBSERVED 95 CPG LOCI WITH SIGNIFICANT DIFFERENTIAL METHYLATION IN LUNG MACROPHAGES, COMPARING UPPER LOBE TO LOWER LOBE (ALL FALSE DISCOVERY RATE < 0.05). SEVERAL OF THESE GENES, INCLUDING CLIP4, HSH2D, NR4A1, SNX10, AND TYK2, HAVE BEEN IMPLICATED AS PARTICIPANTS IN INFLAMMATORY/IMMUNE-RELATED BIOLOGICAL PROCESSES. FUNCTIONALLY, WE IDENTIFIED PHENOTYPIC DIFFERENCES IN OXYGEN USE, COMPARING UPPER VERSUS LOWER LUNG MACROPHAGES. OUR RESULTS SUPPORT A HYPOTHESIS THAT EPIGENETIC CHANGES, SPECIFICALLY DNA METHYLATION, AT A MULTITUDE OF GENE LOCI IN LUNG MACROPHAGES ARE ASSOCIATED WITH METABOLIC DIFFERENCES REGIONALLY IN LUNG. 2019 11 2483 30 EPIGENETIC VARIATION AND HUMAN DISEASE. CYTOSINE GUANINE DINUCLEOTIDE (CPG) ISLAND METHYLATION IS A KNOWN MECHANISM OF EPIGENETIC INHERITANCE IN POSTMEIOTIC CELLS. THROUGH ASSOCIATED CHROMATIN CHANGES AND SILENCING, SUCH EPIGENETIC STATES CAN INFLUENCE CELLULAR PHYSIOLOGY AND AFFECT DISEASE RISK AND SEVERITY. OUR STUDIES OF CPG ISLAND METHYLATION IN NORMAL COLORECTAL MUCOSA REVEALED PROGRESSIVE AGE-RELATED INCREASES AT MULTIPLE GENE LOCI, SUGGESTING GENOME-WIDE MOLECULAR ALTERATIONS WITH POTENTIAL TO SILENCE GENE EXPRESSION. HOWEVER, THERE WAS CONSIDERABLE VARIATION IN THE DEGREE OF METHYLATION AMONG INDIVIDUALS OF COMPARABLE AGES. SUCH VARIATION COULD BE RELATED TO GENETIC FACTORS, LIFESTYLE, OR ENVIRONMENTAL EXPOSURES. STUDIES IN ULCERATIVE COLITIS AND HEPATOCELLULAR CIRRHOSIS AND NEOPLASIA REVEALED THAT CHRONIC INFLAMMATORY STATES ARE ACCOMPANIED BY MARKED INCREASES IN CPG ISLAND METHYLATION IN NORMAL-APPEARING TISSUES, CONFIRMING THE HYPOTHESIS THAT PROINFLAMMATORY EXPOSURES COULD ACCOUNT FOR PART OF THE EPIGENETIC VARIATION IN HUMAN POPULATIONS. PRELIMINARY DATA ALSO SUGGEST POTENTIAL INFLUENCES OF LIFESTYLE AND EXPOSURE FACTORS ON CPG ISLAND METHYLATION. IT IS SUGGESTED THAT EPIGENETIC VARIATION RELATED TO AGING, LIFESTYLE, EXPOSURES AND POSSIBLY GENETIC FACTORS, IS ONE OF THE MODULATORS OF ACQUIRED, AGE-RELATED HUMAN DISEASES, INCLUDING NEOPLASIA. 2002 12 3079 44 GENOME-WIDE METHYLATION AND EXPRESSION ANALYSES REVEAL THE EPIGENETIC LANDSCAPE OF IMMUNE-RELATED DISEASES FOR TOBACCO SMOKING. BACKGROUND: SMOKING IS A MAJOR CAUSAL RISK FACTOR FOR LUNG CANCER, CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD), CARDIOVASCULAR DISEASE (CVD), AND IS THE MAIN PREVENTABLE CAUSE OF DEATHS IN THE WORLD. THE COMPONENTS OF CIGARETTE SMOKE ARE INVOLVED IN IMMUNE AND INFLAMMATORY PROCESSES, WHICH MAY INCREASE THE PREVALENCE OF CIGARETTE SMOKE-RELATED DISEASES. HOWEVER, THE UNDERLYING MOLECULAR MECHANISMS LINKING SMOKING AND DISEASES HAVE NOT BEEN WELL EXPLORED. THIS STUDY WAS AIMED TO DEPICT A GLOBAL MAP OF DNA METHYLATION AND GENE EXPRESSION CHANGES INDUCED BY TOBACCO SMOKING AND TO EXPLORE THE MOLECULAR MECHANISMS BETWEEN SMOKING AND HUMAN DISEASES THROUGH WHOLE-GENOME BISULFITE SEQUENCING (WGBS) AND RNA-SEQUENCING (RNA-SEQ). RESULTS: WE PERFORMED WGBS ON 72 SAMPLES (36 SMOKERS AND 36 NONSMOKERS) AND RNA-SEQ ON 75 SAMPLES (38 SMOKERS AND 37 NONSMOKERS), AND CYTOKINE IMMUNOASSAY ON PLASMA FROM 22 MALES (9 SMOKERS AND 13 NONSMOKERS) WHO WERE RECRUITED FROM THE CITY OF JINCHENG IN CHINA. BY COMPARING THE DATA OF THE TWO GROUPS, WE DISCOVERED A GENOME-WIDE METHYLATION LANDSCAPE OF DIFFERENTIALLY METHYLATED REGIONS (DMRS) ASSOCIATED WITH SMOKING. FUNCTIONAL ENRICHMENT ANALYSES REVEALED THAT BOTH SMOKING-RELATED HYPER-DMR GENES (DMGS) AND HYPO-DMGS WERE RELATED TO SYNAPSE-RELATED PATHWAYS, WHEREAS THE HYPO-DMGS WERE SPECIFICALLY RELATED TO CANCER AND ADDICTION. THE DIFFERENTIALLY EXPRESSED GENES (DEGS) REVEALED BY RNA-SEQ ANALYSIS WERE SIGNIFICANTLY ENRICHED IN THE "IMMUNOSUPPRESSION" PATHWAY. CORRELATION ANALYSIS OF DMRS WITH THEIR CORRESPONDING GENE EXPRESSION SHOWED THAT GENES AFFECTED BY TOBACCO SMOKING WERE MOSTLY RELATED TO IMMUNE SYSTEM DISEASES. FINALLY, BY COMPARING CYTOKINE CONCENTRATIONS BETWEEN SMOKERS AND NONSMOKERS, WE FOUND THAT VASCULAR ENDOTHELIAL GROWTH FACTOR (VEGF) WAS SIGNIFICANTLY UPREGULATED IN SMOKERS. CONCLUSIONS: IN SUM, WE FOUND THAT SMOKING-INDUCED DMRS HAVE DIFFERENT DISTRIBUTION PATTERNS IN HYPERMETHYLATED AND HYPOMETHYLATED AREAS BETWEEN SMOKERS AND NONSMOKERS. WE FURTHER IDENTIFIED AND VERIFIED SMOKING-RELATED DMGS AND DEGS THROUGH MULTI-OMICS INTEGRATION ANALYSIS OF DNA METHYLOME AND TRANSCRIPTOME DATA. THESE FINDINGS PROVIDE US A COMPREHENSIVE GENOMIC MAP OF THE MOLECULAR CHANGES INDUCED BY SMOKING WHICH WOULD ENHANCE OUR UNDERSTANDING OF THE HARMS OF SMOKING AND ITS RELATIONSHIP WITH DISEASES. 2021 13 4224 32 METHYLATION CHANGES IN MUSCLE AND LIVER TISSUES OF MALE AND FEMALE MICE EXPOSED TO ACUTE AND CHRONIC LOW-DOSE X-RAY-IRRADIATION. THE BIOLOGICAL AND GENETIC EFFECTS OF CHRONIC LOW-DOSE RADIATION (LDR) EXPOSURE AND ITS RELATIONSHIP TO CARCINOGENESIS HAVE RECEIVED A LOT OF ATTENTION IN THE RECENT YEARS. FOR EXAMPLE, RADIATION-INDUCED GENOME INSTABILITY, WHICH IS THOUGHT TO BE A PRECURSOR OF TUMOROGENESIS, WAS SHOWN TO HAVE A TRANSGENERATIONAL NATURE. THIS INDICATES A POSSIBLE INVOLVEMENT OF EPIGENETIC MECHANISMS IN LDR-INDUCED GENOME INSTABILITY. GENOMIC DNA METHYLATION IS ONE OF THE MOST IMPORTANT EPIGENETIC MECHANISMS. EXISTING DATA ON RADIATION EFFECTS ON DNA METHYLATION PATTERNS IS LIMITED, AND NO ONE HAS SPECIFICALLY STUDIED THE EFFECTS OF THE LDR. WE REPORT THE FIRST STUDY OF THE EFFECTS OF WHOLE-BODY LDR EXPOSURE ON GLOBAL GENOME METHYLATION IN MUSCLE AND LIVER TISSUES OF MALE AND FEMALE MICE. IN PARALLEL, WE EVALUATED CHANGES IN PROMOTER METHYLATION AND EXPRESSION OF THE TUMOR SUPPRESSOR GENE P16(INKA) AND DNA REPAIR GENE O(6)-METHYLGUANINE-DNA METHYLTRANSFERASE (MGMT). WE OBSERVED DIFFERENT PATTERNS OF RADIATION-INDUCED GLOBAL GENOME DNA METHYLATION IN THE LIVER AND MUSCLE OF EXPOSED MALES AND FEMALES. WE ALSO FOUND SEX AND TISSUE-SPECIFIC DIFFERENCES IN P16(INKA) PROMOTER METHYLATION UPON LDR EXPOSURE. IN MALE LIVER TISSUE, P16(INKA) PROMOTER METHYLATION WAS MORE PRONOUNCED THAN IN FEMALE TISSUE. IN CONTRAST, NO SIGNIFICANT RADIATION-INDUCED CHANGES IN P16(INKA) PROMOTER METHYLATION WERE NOTED IN THE MUSCLE TISSUE OF EXPOSED MALES AND FEMALES. RADIATION ALSO DID NOT SIGNIFICANTLY AFFECT METHYLATION STATUS OF MGMT PROMOTER. WE ALSO OBSERVED SUBSTANTIAL SEX DIFFERENCES IN ACUTE AND CHRONIC RADIATION-INDUCED EXPRESSION OF P16(INKA) AND MGMT GENES. ANOTHER IMPORTANT OUTCOME OF OUR STUDY WAS THE FACT THAT CHRONIC LOW-DOSE RADIATION EXPOSURE PROVED TO BE A MORE POTENT INDUCER OF EPIGENETIC EFFECTS THAN THE ACUTE EXPOSURE. THIS SUPPORTS PREVIOUS FINDINGS THAT CHRONIC EXPOSURE LEADS TO GREATER GENOME DESTABILIZATION THAN ACUTE EXPOSURE. 2004 14 5067 29 PHYSICAL ACTIVITY AND DNA METHYLATION IN HUMANS. PHYSICAL ACTIVITY IS A STRONG STIMULUS INFLUENCING THE OVERALL PHYSIOLOGY OF THE HUMAN BODY. EXERCISES LEAD TO BIOCHEMICAL CHANGES IN VARIOUS TISSUES AND EXERT AN IMPACT ON GENE EXPRESSION. EXERCISE-INDUCED CHANGES IN GENE EXPRESSION MAY BE MEDIATED BY EPIGENETIC MODIFICATIONS, WHICH REARRANGE THE CHROMATIN STRUCTURE AND THEREFORE MODULATE ITS ACCESSIBILITY FOR TRANSCRIPTION FACTORS. ONE OF SUCH EPIGENETIC MARK IS DNA METHYLATION THAT INVOLVES AN ATTACHMENT OF A METHYL GROUP TO THE FIFTH CARBON OF CYTOSINE RESIDUE PRESENT IN CG DINUCLEOTIDES (CPG). DNA METHYLATION IS CATALYZED BY A FAMILY OF DNA METHYLTRANSFERASES. THIS REVERSIBLE DNA MODIFICATION RESULTS IN THE RECRUITMENT OF PROTEINS CONTAINING METHYL BINDING DOMAIN AND FURTHER TRANSCRIPTIONAL CO-REPRESSORS LEADING TO THE SILENCING OF GENE EXPRESSION. THE ACCUMULATION OF CPG DINUCLEOTIDES, REFERRED AS CPG ISLANDS, OCCURS AT THE PROMOTER REGIONS IN A GREAT MAJORITY OF HUMAN GENES. THEREFORE, CHANGES IN DNA METHYLATION PROFILE AFFECT THE TRANSCRIPTION OF MULTIPLE GENES. A GROWING BODY OF EVIDENCE INDICATES THAT EXERCISE TRAINING MODULATES DNA METHYLATION IN MUSCLES AND ADIPOSE TISSUE. SOME OF THESE EPIGENETIC MARKERS WERE ASSOCIATED WITH A REDUCED RISK OF CHRONIC DISEASES. THIS REVIEW SUMMARIZES THE CURRENT KNOWLEDGE ABOUT THE INFLUENCE OF PHYSICAL ACTIVITY ON THE DNA METHYLATION STATUS IN HUMANS. 2021 15 6562 34 TRANSIENT AND PERMANENT CHANGES IN DNA METHYLATION PATTERNS IN INORGANIC ARSENIC-MEDIATED EPITHELIAL-TO-MESENCHYMAL TRANSITION. CHRONIC LOW DOSE INORGANIC ARSENIC EXPOSURE CAUSES CELLS TO TAKE ON AN EPITHELIAL-TO-MESENCHYMAL PHENOTYPE, WHICH IS A CRUCIAL PROCESS IN CARCINOGENESIS. INORGANIC ARSENIC IS NOT A MUTAGEN AND THUS EPIGENETIC ALTERATIONS HAVE BEEN IMPLICATED IN THIS PROCESS. INDEED, DURING THE EPITHELIAL-TO-MESENCHYMAL TRANSITION, MORPHOLOGIC CHANGES TO CELLS CORRELATE WITH CHANGES IN CHROMATIN STRUCTURE AND GENE EXPRESSION, ULTIMATELY DRIVING THIS PROCESS. HOWEVER, STUDIES ON THE EFFECTS OF INORGANIC ARSENIC EXPOSURE/WITHDRAWAL ON THE EPITHELIAL-TO-MESENCHYMAL TRANSITION AND THE IMPACT OF EPIGENETIC ALTERATIONS IN THIS PROCESS ARE LIMITED. IN THIS STUDY WE USED HIGH-RESOLUTION MICROARRAY ANALYSIS TO MEASURE THE CHANGES IN DNA METHYLATION IN CELLS UNDERGOING INORGANIC ARSENIC-INDUCED EPITHELIAL-TO-MESENCHYMAL TRANSITION, AND ON THE REVERSAL OF THIS PROCESS, AFTER REMOVAL OF THE INORGANIC ARSENIC EXPOSURE. WE FOUND THAT CELLS EXPOSED TO CHRONIC, LOW-DOSE INORGANIC ARSENIC EXPOSURE SHOWED 30,530 SITES WERE DIFFERENTIALLY METHYLATED, AND WITH INORGANIC ARSENIC WITHDRAWAL SEVERAL DIFFERENTIAL METHYLATED SITES WERE REVERSED, ALBEIT NOT COMPLETELY. FURTHERMORE, THESE CHANGES IN DNA METHYLATION MAINLY CORRELATED WITH CHANGES IN GENE EXPRESSION AT MOST SITES TESTED BUT NOT AT ALL. THIS STUDY SUGGESTS THAT DNA METHYLATION CHANGES ON GENE EXPRESSION ARE NOT CLEAR-CUT AND PROVIDE A PLATFORM TO BEGIN TO UNCOVER THE RELATIONSHIP BETWEEN DNA METHYLATION AND GENE EXPRESSION, SPECIFICALLY WITHIN THE CONTEXT OF INORGANIC ARSENIC TREATMENT. 2017 16 2022 37 EPIGENETIC CHANGES ASSOCIATED WITH DISEASE PROGRESSION IN A MOUSE MODEL OF CHILDHOOD ALLERGIC ASTHMA. DEVELOPMENT OF ASTHMA IN CHILDHOOD IS LINKED TO VIRAL INFECTIONS OF THE LOWER RESPIRATORY TRACT IN EARLY LIFE, WITH SUBSEQUENT CHRONIC EXPOSURE TO ALLERGENS. PROGRESSION TO PERSISTENT ASTHMA IS ASSOCIATED WITH A TH2-BIASED IMMUNOLOGICAL RESPONSE AND STRUCTURAL REMODELLING OF THE AIRWAYS. THE UNDERLYING MECHANISMS ARE UNCLEAR, BUT COULD INVOLVE EPIGENETIC CHANGES. TO INVESTIGATE THIS, WE EMPLOYED A RECENTLY DEVELOPED MOUSE MODEL IN WHICH SELF-LIMITED NEONATAL INFECTION WITH A PNEUMOVIRUS, FOLLOWED BY SENSITISATION TO OVALBUMIN VIA THE RESPIRATORY TRACT AND LOW-LEVEL CHRONIC CHALLENGE WITH AEROSOLISED ANTIGEN, LEADS TO DEVELOPMENT OF AN ASTHMATIC PHENOTYPE. WE ASSESSED EXPRESSION OF MICRORNA BY CELLS IN THE PROXIMAL AIRWAYS, COMPARING CHANGES OVER THE PERIOD OF DISEASE PROGRESSION, AND USED TARGET PREDICTION DATABASES TO IDENTIFY GENES LIKELY TO BE UP- OR DOWNREGULATED AS A CONSEQUENCE OF ALTERED REGULATION OF MICRORNA. IN PARALLEL, WE ASSESSED DNA METHYLATION IN PULMONARY CD4(+) T CELLS. WE FOUND THAT A LIMITED NUMBER OF MICRORNAS EXHIBITED MARKED UP- OR DOWNREGULATION FOLLOWING EARLY-LIFE INFECTION AND SENSITISATION, FOR MANY OF WHICH THE LEVELS OF EXPRESSION WERE FURTHER CHANGED FOLLOWING CHRONIC CHALLENGE WITH THE SENSITIZING ANTIGEN. TARGETS OF THESE MICRORNAS INCLUDED GENES INVOLVED IN IMMUNE OR INFLAMMATORY RESPONSES (E.G. GATA3, KITL) AND IN TISSUE REMODELLING (E.G. IGF1, TGFBR1), AS WELL AS GENES FOR VARIOUS TRANSCRIPTION FACTORS AND SIGNALLING PROTEINS. IN PULMONARY CD4(+) T CELLS, THERE WAS SIGNIFICANT DEMETHYLATION AT PROMOTER SITES FOR INTERLEUKIN-4 AND INTERFERON-GAMMA, THE LATTER INCREASING FOLLOWING CHRONIC CHALLENGE. WE CONCLUDE THAT, IN THIS MODEL, PROGRESSION TO AN ASTHMATIC PHENOTYPE IS LINKED TO EPIGENETIC REGULATION OF GENES ASSOCIATED WITH INFLAMMATION AND STRUCTURAL REMODELLING, AND WITH T-CELL COMMITMENT TO A TH2 IMMUNOLOGICAL RESPONSE. EPIGENETIC CHANGES ASSOCIATED WITH THIS PATTERN OF GENE ACTIVATION MIGHT PLAY A ROLE IN THE DEVELOPMENT OF CHILDHOOD ASTHMA. 2013 17 2920 32 GENE-SET ANALYSIS IS SEVERELY BIASED WHEN APPLIED TO GENOME-WIDE METHYLATION DATA. MOTIVATION: DNA METHYLATION IS AN EPIGENETIC MARK THAT CAN STABLY REPRESS GENE EXPRESSION. BECAUSE OF ITS BIOLOGICAL AND CLINICAL SIGNIFICANCE, SEVERAL METHODS HAVE BEEN DEVELOPED TO COMPARE GENOME-WIDE PATTERNS OF METHYLATION BETWEEN GROUPS OF SAMPLES. THE APPLICATION OF GENE SET ANALYSIS TO IDENTIFY RELEVANT GROUPS OF GENES THAT ARE ENRICHED FOR DIFFERENTIALLY METHYLATED GENES IS OFTEN A MAJOR COMPONENT OF THE ANALYSIS OF THESE DATA. THIS CAN BE USED, FOR EXAMPLE, TO IDENTIFY PROCESSES OR PATHWAYS THAT ARE PERTURBED IN DISEASE DEVELOPMENT. WE SHOW THAT GENE-SET ANALYSIS, AS IT IS TYPICALLY APPLIED TO GENOME-WIDE METHYLATION ASSAYS, IS SEVERELY BIASED AS A RESULT OF DIFFERENCES IN THE NUMBERS OF CPG SITES ASSOCIATED WITH DIFFERENT CLASSES OF GENES AND GENE PROMOTERS. RESULTS: WE DEMONSTRATE THIS BIAS USING PUBLISHED DATA FROM A STUDY OF DIFFERENTIAL CPG ISLAND METHYLATION IN LUNG CANCER AND A DATASET WE GENERATED TO STUDY METHYLATION CHANGES IN PATIENTS WITH LONG-STANDING ULCERATIVE COLITIS. WE SHOW THAT SEVERAL OF THE GENE SETS THAT SEEM ENRICHED WOULD ALSO BE IDENTIFIED WITH RANDOMIZED DATA. WE SUGGEST TWO EXISTING APPROACHES THAT CAN BE ADAPTED TO CORRECT THE BIAS. ACCOUNTING FOR THE BIAS IN THE LUNG CANCER AND ULCERATIVE COLITIS DATASETS PROVIDES NOVEL BIOLOGICAL INSIGHTS INTO THE ROLE OF METHYLATION IN CANCER DEVELOPMENT AND CHRONIC INFLAMMATION, RESPECTIVELY. OUR RESULTS HAVE SIGNIFICANT IMPLICATIONS FOR MANY PREVIOUS GENOME-WIDE METHYLATION STUDIES THAT HAVE DRAWN CONCLUSIONS ON THE BASIS OF SUCH STRONGLY BIASED ANALYSIS. CONTACT: CATHAL.SEOIGHE@NUIGALWAY.IE SUPPLEMENTARY INFORMATION: SUPPLEMENTARY DATA ARE AVAILABLE AT BIOINFORMATICS ONLINE. 2013 18 416 31 ANALYSIS OF THE DYNAMIC ABERRANT LANDSCAPE OF DNA METHYLATION AND GENE EXPRESSION DURING ARSENIC-INDUCED CELL TRANSFORMATION. INORGANIC ARSENIC IS A WELL-KNOWN CARCINOGEN ASSOCIATED WITH SEVERAL TYPES OF CANCER, BUT THE MECHANISMS INVOLVED IN ARSENIC-INDUCED CARCINOGENESIS ARE NOT FULLY UNDERSTOOD. RECENT EVIDENCE POINTS TO EPIGENETIC DYSREGULATION AS AN IMPORTANT MECHANISM IN THIS PROCESS; HOWEVER, THE EFFECTS OF EPIGENETIC ALTERATIONS IN GENE EXPRESSION HAVE NOT BEEN EXPLORED IN DEPTH. USING MICROARRAY DATA AND APPLYING A MULTIVARIATE CLUSTERING ANALYSIS IN A GAUSSIAN MIXTURE MODEL, WE DESCRIBE THE ALTERATIONS IN DNA METHYLATION AROUND THE PROMOTER REGION AND THE IMPACT ON GENE EXPRESSION IN HACAT CELLS DURING THE TRANSFORMATION PROCESS CAUSED BY CHRONIC EXPOSURE TO ARSENIC. USING THIS CLUSTERING APPROACH, THE GENES WERE GROUPED ACCORDING TO THEIR METHYLATION AND EXPRESSION STATUS IN THE EPIGENETIC LANDSCAPE, AND THE CHANGES THAT OCCURRED DURING THE CELLULAR TRANSFORMATION WERE IDENTIFIED ADEQUATELY. THUS, WE PRESENT A VALUABLE METHOD FOR IDENTIFYING EPIGENOMIC DYSREGULATION. 2019 19 990 31 CHRONIC SOCIAL STRESS INDUCES DNA METHYLATION CHANGES AT AN EVOLUTIONARY CONSERVED INTERGENIC REGION IN CHROMOSOME X. CHRONIC STRESS RESULTING FROM PROLONGED EXPOSURE TO NEGATIVE LIFE EVENTS INCREASES THE RISK OF MOOD AND ANXIETY DISORDERS. ALTHOUGH CHRONIC STRESS CAN CHANGE GENE EXPRESSION RELEVANT FOR BEHAVIOR, MOLECULAR REGULATORS OF THIS CHANGE HAVE NOT BEEN FULLY DETERMINED. ONE PROCESS THAT COULD PLAY A ROLE IS DNA METHYLATION, AN EPIGENETIC PROCESS WHEREBY A METHYL GROUP IS ADDED ONTO NUCLEOTIDES, PREDOMINANTLY CYTOSINE IN THE CPG CONTEXT, AND WHICH CAN BE INDUCED BY CHRONIC STRESS. IT IS UNKNOWN TO WHAT EXTENT CHRONIC SOCIAL DEFEAT, A MODEL OF HUMAN SOCIAL STRESS, INFLUENCES DNA METHYLATION PATTERNS ACROSS THE GENOME. OUR STUDY ADDRESSED THIS QUESTION BY USING A TARGETED-CAPTURE APPROACH CALLED METHYL-SEQ TO INVESTIGATE DNA METHYLATION PATTERNS OF THE DENTATE GYRUS AT PUTATIVE REGULATORY REGIONS ACROSS THE MOUSE GENOME FROM MICE EXPOSED TO 14 DAYS OF SOCIAL DEFEAT. FINDINGS WERE REPLICATED IN INDEPENDENT COHORTS BY BISULFITE-PYROSEQUENCING. TWO DIFFERENTIALLY METHYLATED REGIONS (DMRS) WERE IDENTIFIED. ONE DMR WAS LOCATED AT INTRON 9 OF DROSHA, AND IT SHOWED REDUCED METHYLATION IN STRESSED MICE. THIS OBSERVATION REPLICATED IN ONE OF TWO INDEPENDENT COHORTS. A SECOND DMR WAS IDENTIFIED AT AN INTERGENIC REGION OF CHROMOSOME X, AND METHYLATION IN THIS REGION WAS INCREASED IN STRESSED MICE. THIS METHYLATION DIFFERENCE REPLICATED IN TWO INDEPENDENT COHORTS AND IN MAJOR DEPRESSIVE DISORDER (MDD) POSTMORTEM BRAINS. THESE RESULTS HIGHLIGHT A REGION NOT PREVIOUSLY KNOWN TO BE DIFFERENTIALLY METHYLATED BY CHRONIC SOCIAL DEFEAT STRESS AND WHICH MAY BE INVOLVED IN MDD. 2018 20 1185 31 COORDINATED CHANGES IN AHRR METHYLATION IN LYMPHOBLASTS AND PULMONARY MACROPHAGES FROM SMOKERS. SMOKING IS ASSOCIATED WITH A WIDE VARIETY OF ADVERSE HEALTH OUTCOMES INCLUDING CANCER, CHRONIC OBSTRUCTIVE PULMONARY DISEASE, DIABETES, DEPRESSION, AND HEART DISEASE. UNFORTUNATELY, THE MOLECULAR MECHANISMS THROUGH WHICH THESE EFFECTS ARE CONVEYED ARE NOT CLEARLY UNDERSTOOD. TO EXAMINE THE POTENTIAL ROLE OF EPIGENETIC FACTORS IN THESE PROCESSES, WE EXAMINED THE RELATIONSHIP OF SMOKING TO GENOME WIDE METHYLATION AND GENE EXPRESSION USING BIOMATERIAL FROM TWO INDEPENDENT SAMPLES, LYMPHOBLAST DNA AND RNA (N = 119) AND LUNG ALVEOLAR MACROPHAGE DNA (N = 19). WE FOUND THAT IN BOTH SAMPLES CURRENT SMOKING STATUS WAS ASSOCIATED WITH SIGNIFICANT CHANGES IN DNA METHYLATION, IN PARTICULAR AT THE ARYL HYDROCARBON RECEPTOR REPRESSOR (AHRR), A KNOWN TUMOR SUPPRESSOR. BOTH BASELINE DNA METHYLATION AND SMOKER ASSOCIATED DNA METHYLATION SIGNATURES AT AHRR WERE HIGHLY CORRELATED (R = 0.94 AND 0.45, RESPECTIVELY). DNA METHYLATION AT THE MOST DIFFERENTIALLY METHYLATED AHRR CPG RESIDUE IN BOTH SAMPLES, CG0557592, WAS SIGNIFICANTLY ASSOCIATED WITH AHRR GENE EXPRESSION. PATHWAY ANALYSIS OF LYMPHOBLAST DATA (GENES WITH MOST SIGNIFICANT METHYLATION CHANGES) DEMONSTRATED ENRICHMENT IN PROTEIN KINASE C PATHWAYS AND IN TGF BETA SIGNALING PATHWAYS. FOR ALVEOLAR MACROPHAGES, PATHWAY ANALYSIS DEMONSTRATED ALTERATIONS IN INFLAMMATION-RELATED PROCESSES. WE CONCLUDE THAT SMOKING IS ASSOCIATED WITH FUNCTIONALLY SIGNIFICANT GENOME WIDE CHANGES IN DNA METHYLATION IN BOTH LYMPHOBLASTS AND PULMONARY MACROPHAGES AND THAT FURTHER INTEGRATED INVESTIGATIONS OF THESE EPIGENETIC EFFECTS OF SMOKING ON CARCINOGENESIS AND OTHER RELATED CO-MORBIDITIES ARE INDICATED. 2012