1 4718 103 NON-TYPEABLE HAEMOPHILUS INFLUENZAE ISOLATES FROM PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE CONTAIN NEW PHASE-VARIABLE MODA METHYLTRANSFERASE ALLELES CONTROLLING PHASEVARIONS. PHASEVARIONS (PHASE-VARIABLE REGULONS) ARE EMERGING AS AN IMPORTANT AREA OF BACTERIAL GENE REGULATION. MANY BACTERIAL PATHOGENS CONTAIN PHASEVARIONS, WITH GENE EXPRESSION CONTROLLED BY THE PHASE-VARIABLE EXPRESSION OF DNA METHYLTRANSFERASES VIA EPIGENETIC MECHANISMS. NON-TYPEABLE HAEMOPHILUS INFLUENZAE (NTHI) CONTAINS THE PHASE-VARIABLE METHYLTRANSFERASE MODA, OF WHICH MULTIPLE ALLELIC VARIANTS EXIST (MODA1-21). WE HAVE PREVIOUSLY DEMONSTRATED 5 OF 21 THESE MODA ALLELES ARE OVERREPRESENTED IN NTHI STRAINS ISOLATED FROM CHILDREN WITH MIDDLE EAR INFECTIONS. IN THIS STUDY WE INVESTIGATED THE MODA ALLELE DISTRIBUTION IN NTHI STRAINS ISOLATED FROM PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE, COPD. WE DEMONSTRATE THAT THE DISTRIBUTION OF MODA ALLELES IN A LARGE PANEL OF COPD ISOLATES IS DIFFERENT TO THE DISTRIBUTION SEEN IN MIDDLE EAR INFECTIONS, SUGGESTING DIFFERENT MODA ALLELES MAY PROVIDE DISTINCT ADVANTAGES IN THE DIFFERING NICHES OF THE MIDDLE EAR AND COPD AIRWAYS. WE ALSO IDENTIFIED TWO NEW PHASE-VARIABLE MODA ALLELES - MODA15 AND MODA18 - AND DEMONSTRATE THAT THESE ALLELES METHYLATE DISTINCT DNA SEQUENCES AND CONTROL UNIQUE PHASEVARIONS. THE MODA15 AND MODA18 ALLELES HAVE ONLY BEEN OBSERVED IN COPD ISOLATES, INDICATING THAT THESE TWO ALLELES MAY BE MARKERS FOR ISOLATES LIKELY TO CAUSE EXACERBATIONS OF COPD. 2019 2 1080 36 CLOSED COMPLETE GENOME SEQUENCES OF TWO NONTYPEABLE HAEMOPHILUS INFLUENZAE STRAINS CONTAINING NOVEL MODA ALLELES FROM THE SPUTUM OF PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE. NONTYPEABLE HAEMOPHILUS INFLUENZAE (NTHI) IS AN IMPORTANT BACTERIAL PATHOGEN THAT CAUSES OTITIS MEDIA AND EXACERBATIONS OF CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). HERE, WE REPORT THE COMPLETE GENOME SEQUENCES OF NTHI STRAINS 10P129H1 AND 84P36H1, ISOLATED FROM COPD PATIENTS, WHICH CONTAIN THE PHASE-VARIABLE EPIGENETIC REGULATORS MODA15 AND MODA18, RESPECTIVELY. 2018 3 2273 45 EPIGENETIC REGULATION ALTERS BIOFILM ARCHITECTURE AND COMPOSITION IN MULTIPLE CLINICAL ISOLATES OF NONTYPEABLE HAEMOPHILUS INFLUENZAE. BIOFILMS PLAY A CRITICAL ROLE IN THE COLONIZATION, PERSISTENCE, AND PATHOGENESIS OF MANY HUMAN PATHOGENS. MULTIPLE MUCOSA-ASSOCIATED PATHOGENS HAVE EVOLVED A MECHANISM OF RAPID ADAPTATION, TERMED THE PHASEVARION, WHICH FACILITATES A COORDINATED REGULATION OF NUMEROUS GENES THROUGHOUT THE BACTERIAL GENOME. THIS EPIGENETIC REGULATION OCCURS VIA PHASE VARIATION OF A DNA METHYLTRANSFERASE, MOD. THE PHASEVARION OF NONTYPEABLE HAEMOPHILUS INFLUENZAE (NTHI) SIGNIFICANTLY AFFECTS THE SEVERITY OF EXPERIMENTAL OTITIS MEDIA AND REGULATES SEVERAL DISEASE-RELATED PROCESSES. HOWEVER, THE ROLE OF THE NTHI PHASEVARION IN BIOFILM FORMATION IS UNCLEAR. THE PRESENT STUDY SHOWS THAT THE PHASEVARIONS OF MULTIPLE NTHI CLINICAL ISOLATES REGULATE IN VITRO BIOFILM FORMATION UNDER DISEASE-SPECIFIC MICROENVIRONMENTAL CONDITIONS. THE IMPACT OF PHASEVARION REGULATION WAS GREATEST UNDER ALKALINE CONDITIONS THAT MIMIC THOSE KNOWN TO OCCUR IN THE MIDDLE EAR DURING DISEASE. UNDER ALKALINE CONDITIONS, NTHI STRAINS THAT EXPRESS THE MODA2 METHYLTRANSFERASE FORMED BIOFILMS WITH SIGNIFICANTLY GREATER BIOMASS AND LESS DISTINCT ARCHITECTURE THAN THOSE FORMED BY A MODA2-DEFICIENT POPULATION. THE BIOFILMS FORMED BY NTHI STRAINS THAT EXPRESS MODA2 ALSO CONTAINED LESS EXTRACELLULAR DNA (EDNA) AND SIGNIFICANTLY LESS EXTRACELLULAR HU, A DNABII DNA-BINDING PROTEIN CRITICAL FOR BIOFILM STRUCTURAL STABILITY. STABLE BIOFILM STRUCTURE IS CRITICAL FOR BACTERIAL PATHOGENESIS AND PERSISTENCE IN MULTIPLE EXPERIMENTAL MODELS OF DISEASE. THESE RESULTS IDENTIFY A ROLE FOR THE PHASEVARION IN REGULATION OF BIOFILM FORMATION, A PROCESS INTEGRAL TO THE CHRONIC NATURE OF MANY INFECTIONS. UNDERSTANDING THE ROLE OF THE PHASEVARION IN BIOFILM FORMATION IS CRITICAL TO THE DEVELOPMENT OF PREVENTION AND TREATMENT STRATEGIES FOR THESE CHRONIC DISEASES.IMPORTANCE UPPER RESPIRATORY TRACT INFECTIONS ARE THE NUMBER ONE REASON FOR A CHILD TO VISIT THE EMERGENCY DEPARTMENT, AND OTITIS MEDIA (MIDDLE EAR INFECTION) RANKS THIRD OVERALL. BIOFILMS CONTRIBUTE SIGNIFICANTLY TO THE CHRONIC NATURE OF BACTERIAL RESPIRATORY TRACT INFECTIONS, INCLUDING OTITIS MEDIA, AND MAKE THESE DISEASES PARTICULARLY DIFFICULT TO TREAT. SEVERAL MUCOSA-ASSOCIATED HUMAN PATHOGENS UTILIZE A MECHANISM OF RAPID ADAPTATION TERMED THE PHASEVARION, OR PHASEVARIABLE REGULON, TO RESIST ENVIRONMENTAL AND HOST IMMUNE PRESSURES. IN THIS STUDY, WE ASSESSED THE ROLE OF THE PHASEVARION IN REGULATION OF BIOFILM FORMATION BY NONTYPEABLE HAEMOPHILUS INFLUENZAE (NTHI), WHICH CAUSES NUMEROUS RESPIRATORY TRACT DISEASES. WE FOUND THAT THE NTHI PHASEVARION REGULATES BIOFILM STRUCTURE AND CRITICAL BIOFILM MATRIX COMPONENTS UNDER DISEASE-SPECIFIC CONDITIONS. THE FINDINGS OF THIS WORK COULD BE SIGNIFICANT IN THE DESIGN OF IMPROVED STRATEGIES AGAINST NTHI INFECTIONS, AS WELL AS DISEASES DUE TO OTHER PATHOGENS THAT UTILIZE A PHASEVARION. 2018 4 6261 45 THE MORAXELLA CATARRHALIS PHASE-VARIABLE DNA METHYLTRANSFERASE MODM3 IS AN EPIGENETIC REGULATOR THAT AFFECTS BACTERIAL SURVIVAL IN AN IN VIVO MODEL OF OTITIS MEDIA. BACKGROUND: MORAXELLA CATARRHALIS IS A LEADING CAUSE OF OTITIS MEDIA (OM) AND CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). M. CATARRHALIS CONTAINS A TYPE III DNA ADENINE METHYLTRANSFERASE (MODM) THAT IS PHASE-VARIABLY EXPRESSED (I.E., ITS EXPRESSION IS SUBJECT TO RANDOM, REVERSIBLE ON/OFF SWITCHING). MODM HAS SIX TARGET RECOGNITION DOMAIN ALLELES (MODM1-6), AND WE HAVE PREVIOUSLY SHOWN THAT MODM2 IS THE PREDOMINANT ALLELE, WHILE MODM3 IS ASSOCIATED WITH OM. PHASE-VARIABLE DNA METHYLTRANSFERASES MEDIATE EPIGENETIC REGULATION AND MODULATE PATHOGENESIS IN SEVERAL BACTERIA. MODM2 OF M. CATARRHALIS REGULATES THE EXPRESSION OF A PHASEVARION CONTAINING GENES IMPORTANT FOR COLONIZATION AND INFECTION. HERE WE DESCRIBE THE PHASE-VARIABLE EXPRESSION OF MODM3, THE MODM3 METHYLATION SITE AND THE SUITE OF GENES REGULATED WITHIN THE MODM3 PHASEVARION. RESULTS: PHASE-VARIABLE EXPRESSION OF MODM3, MEDIATED BY VARIATION IN LENGTH OF A 5'-(CAAC)(N)-3' TETRANUCLEOTIDE REPEAT TRACT IN THE OPEN READING FRAME WAS DEMONSTRATED IN M. CATARRHALIS STRAIN CCRI-195ME WITH GENESCAN FRAGMENT LENGTH ANALYSIS AND WESTERN IMMUNOBLOT. WE DETERMINED THAT MODM3 IS AN ACTIVE N6-ADENINE METHYLTRANSFERASE THAT METHYLATES THE SEQUENCE 5'-AC(M6)ATC-3'. METHYLATION WAS DETECTED AT ALL 4446 5'-ACATC-3' SITES IN THE GENOME WHEN MODM3 IS EXPRESSED. RNASEQ ANALYSIS IDENTIFIED 31 GENES THAT ARE DIFFERENTIALLY EXPRESSED BETWEEN MODM3 ON AND OFF VARIANTS, INCLUDING FIVE GENES THAT ARE INVOLVED IN THE RESPONSE TO OXIDATIVE AND NITROSATIVE STRESS, WITH POTENTIAL ROLES IN BIOFILM FORMATION AND SURVIVAL IN ANAEROBIC ENVIRONMENTS. AN IN VIVO CHINCHILLA (CHINCHILLA LANIGERA) MODEL OF OTITIS MEDIA DEMONSTRATED THAT TRANSBULLAR CHALLENGE WITH THE MODM3 OFF VARIANT RESULTED IN AN INCREASED MIDDLE EAR BACTERIAL LOAD COMPARED TO A MODM3 ON VARIANT. IN ADDITION, CO-INFECTION EXPERIMENTS WITH NTHI AND M. CATARRHALIS MODM3 ON OR MODM3 OFF VARIANTS REVEALED THAT PHASE VARIATION OF MODM3 ALTERED SURVIVAL OF NTHI IN THE MIDDLE EAR DURING EARLY AND LATE STAGE INFECTION. CONCLUSIONS: PHASE VARIATION OF MODM3 EPIGENETICALLY REGULATES THE EXPRESSION OF A PHASEVARION CONTAINING MULTIPLE GENES THAT ARE POTENTIALLY IMPORTANT IN THE PROGRESSION OF OTITIS MEDIA. 2019 5 4494 43 MORAXELLA CATARRHALIS RESTRICTION-MODIFICATION SYSTEMS ARE ASSOCIATED WITH PHYLOGENETIC LINEAGE AND DISEASE. MORAXELLA CATARRHALIS IS A HUMAN-ADAPTED PATHOGEN, AND A MAJOR CAUSE OF OTITIS MEDIA (OM) AND EXACERBATIONS OF CHRONIC OBSTRUCTIVE PULMONARY DISEASE. THE SPECIES IS COMPRISED OF TWO MAIN PHYLOGENETIC LINEAGES, RB1 AND RB2/3. RESTRICTION-MODIFICATION (R-M) SYSTEMS ARE AMONG THE FEW LINEAGE-ASSOCIATED GENES IDENTIFIED IN OTHER BACTERIAL GENERA AND HAVE MULTIPLE FUNCTIONS INCLUDING DEFENSE AGAINST FOREIGN INVADING DNA, MAINTENANCE OF SPECIATION, AND EPIGENETIC REGULATION OF GENE EXPRESSION. HERE, WE DEFINE THE REPERTOIRE OF R-M SYSTEMS IN 51 PUBLICLY AVAILABLE M. CATARRHALIS GENOMES AND REPORT THEIR DISTRIBUTION AMONG M. CATARRHALIS PHYLOGENETIC LINEAGES. AN ASSOCIATION WITH PHYLOGENETIC LINEAGE (RB1 OR RB2/3) WAS OBSERVED FOR SIX R-M SYSTEMS, WHICH MAY CONTRIBUTE TO THE EVOLUTION OF THE LINEAGES BY RESTRICTING DNA TRANSFORMATION. IN ADDITION, WE OBSERVED A RELATIONSHIP BETWEEN A MUTUALLY EXCLUSIVE TYPE I R-M SYSTEM AND A TYPE III R-M SYSTEM AT A SINGLE LOCUS CONSERVED THROUGHOUT A GEOGRAPHICALLY AND CLINICALLY DIVERSE SET OF M. CATARRHALIS ISOLATES. THE TYPE III R-M SYSTEM AT THIS LOCUS CONTAINS THE PHASE-VARIABLE TYPE III DNA METHYLTRANSFERASE, MODM, WHICH CONTROLS A PHASEVARION (PHASE-VARIABLE REGULON). WE OBSERVED AN ASSOCIATION BETWEEN MODM PRESENCE AND OM-ASSOCIATED MIDDLE EAR ISOLATES, INDICATING A POTENTIAL ROLE FOR MODM-MEDIATED EPIGENETIC REGULATION IN OM PATHOBIOLOGY. 2018 6 4395 51 MODM DNA METHYLTRANSFERASE METHYLOME ANALYSIS REVEALS A POTENTIAL ROLE FOR MORAXELLA CATARRHALIS PHASEVARIONS IN OTITIS MEDIA. MORAXELLA CATARRHALIS IS A SIGNIFICANT CAUSE OF OTITIS MEDIA AND EXACERBATIONS OF CHRONIC OBSTRUCTIVE PULMONARY DISEASE. HERE, WE CHARACTERIZE A PHASE-VARIABLE DNA METHYLTRANSFERASE (MODM), WHICH CONTAINS 5'-CAAC-3' REPEATS IN ITS OPEN READING FRAME THAT MEDIATE HIGH-FREQUENCY MUTATION RESULTING IN REVERSIBLE ON/OFF SWITCHING OF MODM EXPRESSION. THREE MODM ALLELES HAVE BEEN IDENTIFIED (MODM1-3), WITH MODM2 BEING THE MOST COMMONLY FOUND ALLELE. USING SINGLE-MOLECULE, REAL-TIME (SMRT) GENOME SEQUENCING AND METHYLOME ANALYSIS, WE HAVE DETERMINED THAT THE MODM2 METHYLATION TARGET IS 5'-GAR(M6)AC-3', AND 100% OF THESE SITES ARE METHYLATED IN THE GENOME OF THE M. CATARRHALIS 25239 MODM2 ON STRAIN. PROTEOMIC ANALYSIS OF MODM2 ON AND OFF VARIANTS REVEALED THAT MODM2 REGULATES EXPRESSION OF MULTIPLE GENES THAT HAVE POTENTIAL ROLES IN COLONIZATION, INFECTION, AND PROTECTION AGAINST HOST DEFENSES. INVESTIGATION OF THE DISTRIBUTION OF MODM ALLELES IN A PANEL OF M. CATARRHALIS STRAINS, ISOLATED FROM THE NASOPHARYNX OF HEALTHY CHILDREN OR MIDDLE EAR EFFUSIONS FROM PATIENTS WITH OTITIS MEDIA, REVEALED A STATISTICALLY SIGNIFICANT ASSOCIATION OF MODM3 WITH OTITIS MEDIA ISOLATES. THE MODULATION OF GENE EXPRESSION VIA THE MODM PHASE-VARIABLE REGULON (PHASEVARION), AND THE SIGNIFICANT ASSOCIATION OF THE MODM3 ALLELE WITH OTITIS MEDIA, SUGGESTS A KEY ROLE FOR MODM PHASEVARIONS IN THE PATHOGENESIS OF THIS ORGANISM. 2014 7 4493 35 MORAXELLA CATARRHALIS INDUCES INFLAMMATORY RESPONSE OF BRONCHIAL EPITHELIAL CELLS VIA MAPK AND NF-KAPPAB ACTIVATION AND HISTONE DEACETYLASE ACTIVITY REDUCTION. MORAXELLA CATARRHALIS IS A MAJOR CAUSE OF INFECTIOUS EXACERBATIONS OF CHRONIC OBSTRUCTIVE LUNG DISEASE (COPD) AND MAY ALSO CONTRIBUTE TO THE PATHOGENESIS OF COPD. LITTLE IS KNOWN ABOUT M. CATARRHALIS-BRONCHIAL EPITHELIUM INTERACTION. WE INVESTIGATED ACTIVATION OF M. CATARRHALIS INFECTED BRONCHIAL EPITHELIAL CELLS AND CHARACTERIZED THE SIGNAL TRANSDUCTION PATHWAYS. MOREOVER, WE TESTED THE HYPOTHESIS THAT THE M. CATARRHALIS-INDUCED CYTOKINE EXPRESSION IS REGULATED BY ACETYLATION OF HISTONE RESIDUES AND CONTROLLED BY HISTONE DEACETYLASE ACTIVITY (HDAC). WE DEMONSTRATED THAT M. CATARRHALIS INDUCED A STRONG TIME- AND DOSE-DEPENDENT INFLAMMATORY RESPONSE IN THE BRONCHIAL EPITHELIAL CELL LINE (BEAS-2B), CHARACTERIZED BY THE RELEASE OF IL-8 AND GM-CSF. FOR THIS CYTOKINE LIBERATION ACTIVATION OF THE ERK AND P38 MITOGEN-ACTIVATED PROTEIN (MAP) KINASES AND TRANSCRIPTION FACTOR NF-KAPPAB WAS REQUIRED. FURTHERMORE, M. CATARRHALIS-INFECTED BRONCHIAL EPITHELIAL CELLS SHOWED AN ENHANCED ACETYLATION OF HISTONE H3 AND H4 GLOBALLY AND AT THE PROMOTER OF THE IL8 GENE. PREVENTING HISTONE DEACETYLATION BY THE HISTONE DEACETYLASE INHIBITOR TRICHOSTATIN A AUGMENTED THE M. CATARRHALIS-INDUCED IL-8 RESPONSE. AFTER EXPOSURE TO M. CATARRHALIS, WE FOUND A DECREASE IN GLOBAL HISTONE DEACETYLASE EXPRESSION AND ACTIVITY. OUR FINDINGS SUGGEST THAT M. CATARRHALIS-INDUCED ACTIVATION OF IL8 GENE TRANSCRIPTION WAS CAUSED BY INTERFERENCE WITH EPIGENETIC MECHANISMS REGULATING IL8 GENE ACCESSIBILITY. OUR FINDINGS PROVIDE INSIGHT INTO IMPORTANT MOLECULAR AND CELLULAR MECHANISMS OF M. CATARRHALIS-INDUCED ACTIVATION OF HUMAN BRONCHIAL EPITHELIUM. 2006 8 1590 33 DNA METHYLATION PROFILING IN HUMAN LUNG TISSUE IDENTIFIES GENES ASSOCIATED WITH COPD. CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) IS A SMOKING-RELATED DISEASE CHARACTERIZED BY GENETIC AND PHENOTYPIC HETEROGENEITY. ALTHOUGH ASSOCIATION STUDIES HAVE IDENTIFIED MULTIPLE GENOMIC REGIONS WITH REPLICATED ASSOCIATIONS TO COPD, GENETIC VARIATION ONLY PARTIALLY EXPLAINS THE SUSCEPTIBILITY TO LUNG DISEASE, AND SUGGESTS THE RELEVANCE OF EPIGENETIC INVESTIGATIONS. WE PERFORMED GENOME-WIDE DNA METHYLATION PROFILING IN HOMOGENIZED LUNG TISSUE SAMPLES FROM 46 CONTROL SUBJECTS WITH NORMAL LUNG FUNCTION AND 114 SUBJECTS WITH COPD, ALL FORMER SMOKERS. THE DIFFERENTIALLY METHYLATED LOCI WERE INTEGRATED WITH PREVIOUS GENOME-WIDE ASSOCIATION STUDY RESULTS. THE TOP 535 DIFFERENTIALLY METHYLATED SITES, FILTERED FOR A MINIMUM MEAN METHYLATION DIFFERENCE OF 5% BETWEEN CASES AND CONTROLS, WERE ENRICHED FOR CPG SHELVES AND SHORES. PATHWAY ANALYSIS REVEALED ENRICHMENT FOR TRANSCRIPTION FACTORS. THE TOP DIFFERENTIALLY METHYLATED SITES FROM THE INTERSECTION WITH PREVIOUS GWAS WERE IN CHRM1, GLT1D1, AND C10ORF11; SORTED BY GWAS P-VALUE, THE TOP SITES INCLUDED FRMD4A, THSD4, AND C10ORF11. EPIGENETIC ASSOCIATION STUDIES COMPLEMENT GENETIC ASSOCIATION STUDIES TO IDENTIFY GENES POTENTIALLY INVOLVED IN COPD PATHOGENESIS. ENRICHMENT FOR GENES IMPLICATED IN ASTHMA AND LUNG FUNCTION AND FOR TRANSCRIPTION FACTORS SUGGESTS THE POTENTIAL PATHOGENIC RELEVANCE OF GENES IDENTIFIED THROUGH DIFFERENTIAL METHYLATION AND THE INTERSECTION WITH A BROADER RANGE OF GWAS ASSOCIATIONS. 2016 9 348 39 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 10 1551 36 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 11 1591 38 DNA METHYLATION PROFILING IN PERIPHERAL LUNG TISSUES OF SMOKERS AND PATIENTS WITH COPD. BACKGROUND: EPIGENETICS CHANGES HAVE BEEN SHOWN TO BE AFFECTED BY CIGARETTE SMOKING. CIGARETTE SMOKE (CS)-MEDIATED DNA METHYLATION CAN POTENTIALLY AFFECT SEVERAL CELLULAR AND PATHOPHYSIOLOGICAL PROCESSES, ACUTE EXACERBATIONS, AND COMORBIDITY IN THE LUNGS OF PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). WE SOUGHT TO DETERMINE WHETHER GENOME-WIDE LUNG DNA METHYLATION PROFILES OF SMOKERS AND PATIENTS WITH COPD WERE SIGNIFICANTLY DIFFERENT FROM NON-SMOKERS. WE ISOLATED DNA FROM PARENCHYMAL LUNG TISSUES OF PATIENTS INCLUDING EIGHT LIFELONG NON-SMOKERS, EIGHT CURRENT SMOKERS, AND EIGHT PATIENTS WITH COPD AND ANALYZED THE SAMPLES USING ILLUMINA'S INFINIUM HUMANMETHYLATION450 BEADCHIP. RESULTS: OUR DATA REVEALED THAT THE DIFFERENTIALLY METHYLATED GENES WERE RELATED TO TOP CANONICAL PATHWAYS (E.G., G BETA GAMMA SIGNALING, MECHANISMS OF CANCER, AND NNOS SIGNALING IN NEURONS), DISEASE AND DISORDERS (ORGANISMAL INJURY AND ABNORMALITIES, CANCER, AND RESPIRATORY DISEASE), AND MOLECULAR AND CELLULAR FUNCTIONS (CELL DEATH AND SURVIVAL, CELLULAR ASSEMBLY AND ORGANIZATION, CELLULAR FUNCTION AND MAINTENANCE) IN PATIENTS WITH COPD. THE GENOME-WIDE DNA METHYLATION ANALYSIS IDENTIFIED SUGGESTIVE GENES, SUCH AS NOS1AP, TNFAIP2, BID, GABRB1, ATXN7, AND THOC7 WITH DNA METHYLATION CHANGES IN COPD LUNG TISSUES THAT WERE FURTHER VALIDATED BY PYROSEQUENCING. PYROSEQUENCING VALIDATION CONFIRMED HYPER-METHYLATION IN SMOKERS AND PATIENTS WITH COPD AS COMPARED TO NON-SMOKERS. HOWEVER, WE DID NOT DETECT SIGNIFICANT DIFFERENCES IN DNA METHYLATION FOR TNFAIP2, ATXN7, AND THOC7 GENES IN SMOKERS AND COPD GROUPS DESPITE THE CHANGES OBSERVED IN THE GENOME-WIDE ANALYSIS. CONCLUSIONS: OUR STUDY SUGGESTS THAT DNA METHYLATION IN SUGGESTIVE GENES, SUCH AS NOS1AP, BID, AND GABRB1 MAY BE USED AS EPIGENETIC SIGNATURES IN SMOKERS AND PATIENTS WITH COPD IF THE SAME IS VALIDATED IN A LARGER COHORT. FUTURE STUDIES ARE REQUIRED TO CORRELATE DNA METHYLATION STATUS WITH TRANSCRIPTOMICS OF SELECTIVE GENES IDENTIFIED IN THIS STUDY AND ELUCIDATE THEIR ROLE AND INVOLVEMENT IN THE PROGRESSION OF COPD AND ITS EXACERBATIONS. 2017 12 2631 38 EPIGENOME-WIDE ASSOCIATION STUDY OF WHOLE BLOOD GENE EXPRESSION IN FRAMINGHAM HEART STUDY PARTICIPANTS PROVIDES MOLECULAR INSIGHT INTO THE POTENTIAL ROLE OF CHRNA5 IN CIGARETTE SMOKING-RELATED LUNG DISEASES. BACKGROUND: DNA METHYLATION IS A KEY EPIGENETIC MODIFICATION THAT CAN DIRECTLY AFFECT GENE REGULATION. DNA METHYLATION IS HIGHLY INFLUENCED BY ENVIRONMENTAL FACTORS SUCH AS CIGARETTE SMOKING, WHICH IS CAUSALLY RELATED TO CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) AND LUNG CANCER. TO DATE, THERE HAVE BEEN FEW LARGE-SCALE, COMBINED ANALYSES OF DNA METHYLATION AND GENE EXPRESSION AND THEIR INTERRELATIONS WITH LUNG DISEASES. RESULTS: WE PERFORMED AN EPIGENOME-WIDE ASSOCIATION STUDY OF WHOLE BLOOD GENE EXPRESSION IN ~ 6000 INDIVIDUALS FROM FOUR COHORTS. WE DISCOVERED AND REPLICATED NUMEROUS CPGS ASSOCIATED WITH THE EXPRESSION OF CIS GENES WITHIN 500 KB OF EACH CPG, WITH 148 TO 1,741 CIS CPG-TRANSCRIPT PAIRS IDENTIFIED ACROSS COHORTS. WE FOUND THAT THE CLOSER A CPG RESIDED TO A TRANSCRIPTION START SITE, THE LARGER ITS EFFECT SIZE, AND THAT 36% OF CIS CPG-TRANSCRIPT PAIRS SHARE THE SAME CAUSAL GENETIC VARIANT. MENDELIAN RANDOMIZATION ANALYSES REVEALED THAT HYPOMETHYLATION AND LOWER EXPRESSION OF CHRNA5, WHICH ENCODES A SMOKING-RELATED NICOTINIC RECEPTOR, ARE CAUSALLY LINKED TO INCREASED RISK OF COPD AND LUNG CANCER. THIS PUTATIVELY CAUSAL RELATIONSHIP WAS FURTHER VALIDATED IN LUNG TISSUE DATA. CONCLUSIONS: OUR RESULTS PROVIDE A LARGE AND COMPREHENSIVE ASSOCIATION STUDY OF WHOLE BLOOD DNA METHYLATION WITH GENE EXPRESSION. EXPRESSION PLATFORM DIFFERENCES RATHER THAN POPULATION DIFFERENCES ARE CRITICAL TO THE REPLICATION OF CIS CPG-TRANSCRIPT PAIRS. THE LOW REPRODUCIBILITY OF TRANS CPG-TRANSCRIPT PAIRS SUGGESTS THAT DNA METHYLATION REGULATES NEARBY RATHER THAN REMOTE GENE EXPRESSION. THE PUTATIVELY CAUSAL ROLES OF METHYLATION AND EXPRESSION OF CHRNA5 IN RELATION TO COPD AND LUNG CANCER PROVIDE EVIDENCE FOR A MECHANISTIC LINK BETWEEN PATTERNS OF SMOKING-RELATED EPIGENETIC VARIATION AND LUNG DISEASES, AND HIGHLIGHT POTENTIAL THERAPEUTIC TARGETS FOR LUNG DISEASES AND SMOKING CESSATION. 2021 13 1124 24 COMPLETE GENOME SEQUENCE OF MORAXELLA CATARRHALIS STRAIN CCRI-195ME, ISOLATED FROM THE MIDDLE EAR. MORAXELLA CATARRHALIS IS AN IMPORTANT BACTERIAL PATHOGEN THAT CAUSES OTITIS MEDIA AND EXACERBATIONS OF CHRONIC OBSTRUCTIVE PULMONARY DISEASE. HERE, WE REPORT THE COMPLETE GENOME SEQUENCE OF M. CATARRHALIS STRAIN CCRI-195ME, WHICH CONTAINS THE PHASE-VARIABLE EPIGENETIC REGULATOR MODM3. 2017 14 3764 33 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 15 6691 35 VARIABLE DNA METHYLATION IS ASSOCIATED WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE AND LUNG FUNCTION. RATIONALE: CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) IS ASSOCIATED WITH LOCAL (LUNG) AND SYSTEMIC (BLOOD) INFLAMMATION AND MANIFESTATIONS. DNA METHYLATION IS AN IMPORTANT REGULATOR OF GENE TRANSCRIPTION, AND GLOBAL AND SPECIFIC GENE METHYLATION MARKS MAY VARY WITH CIGARETTE SMOKE EXPOSURE. OBJECTIVES: TO PERFORM A COMPREHENSIVE ASSESSMENT OF METHYLATION MARKS IN DNA FROM SUBJECTS WELL PHENOTYPED FOR NONNEOPLASTIC LUNG DISEASE. METHODS: WE CONDUCTED ARRAY-BASED METHYLATION SCREENS, USING A TEST-REPLICATION APPROACH, IN TWO FAMILY-BASED COHORTS (N = 1,085 AND 369 SUBJECTS). MEASUREMENTS AND MAIN RESULTS: WE OBSERVED 349 CPG SITES SIGNIFICANTLY ASSOCIATED WITH THE PRESENCE AND SEVERITY OF COPD IN BOTH COHORTS. SEVENTY PERCENT OF THE ASSOCIATED CPG SITES WERE OUTSIDE OF CPG ISLANDS, WITH THE MAJORITY OF CPG SITES RELATIVELY HYPOMETHYLATED. GENE ONTOLOGY ANALYSIS BASED ON THESE 349 CPGS (330 GENES) SUGGESTED THE INVOLVEMENT OF A NUMBER OF GENES RESPONSIBLE FOR IMMUNE AND INFLAMMATORY SYSTEM PATHWAYS, RESPONSES TO STRESS AND EXTERNAL STIMULI, AS WELL AS WOUND HEALING AND COAGULATION CASCADES. INTERESTINGLY, OUR OBSERVATIONS INCLUDE SIGNIFICANT, REPLICABLE ASSOCIATIONS BETWEEN SERPINA1 HYPOMETHYLATION AND COPD AND LOWER AVERAGE LUNG FUNCTION PHENOTYPES (COMBINED P VALUES: COPD, 1.5 X 10(-23); FEV(1)/FVC, 1.5 X 10(-35); FEV(1), 2.2 X 10(-40)). CONCLUSIONS: GENETIC AND EPIGENETIC PATHWAYS MAY BOTH CONTRIBUTE TO COPD. MANY OF THE TOP ASSOCIATIONS BETWEEN COPD AND DNA METHYLATION OCCUR IN BIOLOGICALLY PLAUSIBLE PATHWAYS. THIS LARGE-SCALE ANALYSIS SUGGESTS THAT DNA METHYLATION MAY BE A BIOMARKER OF COPD AND MAY HIGHLIGHT NEW PATHWAYS OF COPD PATHOGENESIS. 2012 16 3308 30 HIGH-RESOLUTION TRANSCRIPTOMIC AND EPIGENETIC PROFILING IDENTIFIES NOVEL REGULATORS OF COPD. PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) ARE STILL WAITING FOR CURATIVE TREATMENTS. CONSIDERING ITS ENVIRONMENTAL CAUSE, WE HYPOTHESIZED THAT COPD WILL BE ASSOCIATED WITH ALTERED EPIGENETIC SIGNALING IN LUNG CELLS. WE GENERATED GENOME-WIDE DNA METHYLATION MAPS AT SINGLE CPG RESOLUTION OF PRIMARY HUMAN LUNG FIBROBLASTS (HLFS) ACROSS COPD STAGES. WE SHOW THAT THE EPIGENETIC LANDSCAPE IS CHANGED EARLY IN COPD, WITH DNA METHYLATION CHANGES OCCURRING PREDOMINANTLY IN REGULATORY REGIONS. RNA SEQUENCING OF MATCHED FIBROBLASTS DEMONSTRATED DYSREGULATION OF GENES INVOLVED IN PROLIFERATION, DNA REPAIR, AND EXTRACELLULAR MATRIX ORGANIZATION. DATA INTEGRATION IDENTIFIED 110 CANDIDATE REGULATORS OF DISEASE PHENOTYPES THAT WERE LINKED TO FIBROBLAST REPAIR PROCESSES USING PHENOTYPIC SCREENS. OUR STUDY PROVIDES HIGH-RESOLUTION MULTI-OMIC MAPS OF HLFS ACROSS COPD STAGES. WE REVEAL NOVEL TRANSCRIPTOMIC AND EPIGENETIC SIGNATURES ASSOCIATED WITH COPD ONSET AND PROGRESSION AND IDENTIFY NEW CANDIDATE REGULATORS INVOLVED IN THE PATHOGENESIS OF CHRONIC LUNG DISEASES. THE PRESENCE OF VARIOUS EPIGENETIC FACTORS AMONG THE CANDIDATES DEMONSTRATES THAT EPIGENETIC REGULATION IN COPD IS AN EXCITING RESEARCH FIELD THAT HOLDS PROMISE FOR NOVEL THERAPEUTIC AVENUES FOR PATIENTS. 2023 17 6750 27 WHOLE-GENOME METHYLATION PROFILING FROM PBMCS IN ACUTE-EXACERBATION COPD PATIENTS WITH GOOD AND POOR RESPONSES TO CORTICOSTEROID TREATMENT. IDENTIFYING HETEROGENEITY IN CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) PHENOTYPES IS IMPORTANT FOR THE DEVELOPMENT OF PERSONALIZED MEDICINE. GENOME-WIDE ANALYSIS WAS USED TO COMPARE THE METHYLATION LEVELS OF PERIPHERAL BLOOD MONONUCLEAR CELL (PBMC) SAMPLES FROM 24 ACUTE-EXACERBATION (AE) COPD PATIENTS WITH GOOD/POOR RESPONSE TO CORTICOSTEROID THERAPY AND 12 NON-COPD CONTROLS. PYROSEQUENCING WAS EMPLOYED TO VALIDATE THE GENOME-WIDE ANALYSIS. IN THE DATASET SPECIFIC TO COPD PATIENTS WITH A GOOD RESPONSE, ENRICHMENT WAS IDENTIFIED FOR THE FOLLOWING: GENES IN THE UBL CONJUGATION PATHWAY, NICOTINAMIDE NUCLEOTIDE METABOLISM, THE ALKALOID METABOLIC PROCESS, AND REGULATION OF THE GLUCOSE METABOLIC PROCESS. VALIDATION RESULTS CONFIRMED CPG SITES IN PRKAG2 WITH DIFFERENT METHYLATION LEVELS IN COPD PATIENTS AND NORMAL SUBJECTS. THE CPG SITES OF ALOX5AP WERE SPECIFICALLY ASSOCIATED WITH A GOOD RESPONSE. THE RESULTS SUGGESTED THAT A GOOD RESPONSE TO CORTICOSTEROID TREATMENT FOR AE-COPD SHOULD BE CONSIDERED A DISTINCT SUBTYPE ACCORDING TO THE PUTATIVE EPIGENETIC MECHANISM. 2019 18 1528 32 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 19 1519 29 DNA METHYLATION AT ATP11A CG11702988 IS A BIOMARKER OF LUNG DISEASE SEVERITY IN CYSTIC FIBROSIS: A LONGITUDINAL STUDY. CYSTIC FIBROSIS (CF) IS A CHRONIC GENETIC DISEASE THAT MAINLY AFFECTS THE RESPIRATORY AND GASTROINTESTINAL SYSTEMS. NO CURATIVE TREATMENTS ARE AVAILABLE, BUT THE FOLLOW-UP IN SPECIALIZED CENTERS HAS GREATLY IMPROVED THE PATIENT LIFE EXPECTANCY. ROBUST BIOMARKERS ARE REQUIRED TO MONITOR THE DISEASE, GUIDE TREATMENTS, STRATIFY PATIENTS, AND PROVIDE OUTCOME MEASURES IN CLINICAL TRIALS. IN THE PRESENT STUDY, WE OUTLINE A STRATEGY TO SELECT PUTATIVE DNA METHYLATION BIOMARKERS OF LUNG DISEASE SEVERITY IN CYSTIC FIBROSIS PATIENTS. IN THE DISCOVERY STEP, WE SELECTED SEVEN POTENTIAL BIOMARKERS USING A GENOME-WIDE DNA METHYLATION DATASET THAT WE GENERATED IN NASAL EPITHELIAL SAMPLES FROM THE METHYLCF COHORT. IN THE REPLICATION STEP, WE ASSESSED THE SAME BIOMARKERS USING SPUTUM CELL SAMPLES FROM THE METHYLBIOMARK COHORT. OF INTEREST, DNA METHYLATION AT THE CG11702988 SITE (ATP11A GENE) POSITIVELY CORRELATED WITH LUNG FUNCTION AND BMI, AND NEGATIVELY CORRELATED WITH LUNG DISEASE SEVERITY, P. AERUGINOSA CHRONIC INFECTION, AND THE NUMBER OF EXACERBATIONS. THESE RESULTS WERE REPLICATED IN PROSPECTIVE SPUTUM SAMPLES COLLECTED AT FOUR TIME POINTS WITHIN AN 18-MONTH PERIOD AND LONGITUDINALLY. TO CONCLUDE, (I) WE IDENTIFIED A DNA METHYLATION BIOMARKER THAT CORRELATES WITH CF SEVERITY, (II) WE PROVIDED A METHOD TO EASILY ASSESS THIS BIOMARKER, AND (III) WE CARRIED OUT THE FIRST LONGITUDINAL ANALYSIS OF DNA METHYLATION IN CF PATIENTS. THIS NEW EPIGENETIC BIOMARKER COULD BE USED TO STRATIFY CF PATIENTS IN CLINICAL TRIALS. 2021 20 5418 39 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