1 5481 136 RESVERATROL-INDUCED APOPTOSIS DEPENDS ON THE LIPID KINASE ACTIVITY OF VPS34 AND ON THE FORMATION OF AUTOPHAGOLYSOSOMES. IN HUMAN COLORECTAL DLD1 CANCER CELLS, THE DIETARY BIOFLAVONOID RESVERATROL (RV) RAPIDLY INDUCED AUTOPHAGY. THIS EFFECT WAS REVERSIBLE (ON REMOVAL OF THE DRUG) AND WAS ASSOCIATED WITH INCREASED EXPRESSION AND CYTOSOLIC REDISTRIBUTION OF THE PROTEINS BECLIN1 AND LC3 II. SUPPLEMENTING THE CELLS WITH ASPARAGINE (ASN) ABROGATED THE BECLIN-DEPENDENT AUTOPHAGY. WHEN APPLIED ACUTELY (2 H), RV WAS NOT TOXIC; HOWEVER, REITERATE CHRONIC (48 H) EXPOSURE TO RV EVENTUALLY LED TO ANNEXIN V- AND TERMINAL DEOXINUCLEOTIDYL TRANSFERASE-MEDIATED DUTP-BIOTIN NICK END LABELING-POSITIVE CELL DEATH. THIS TOXIC EFFECT WAS AUTOPHAGY DEPENDENT, AS IT WAS PREVENTED EITHER BY ASN, BY EXPRESSING A DOMINANT-NEGATIVE LIPID KINASE-DEFICIENT CLASS III PHOSPHOINOSITIDE 3-PHOSPHATE KINASE, OR BY RNA INTERFERENCE KNOCKDOWN OF BECLIN1. LAMP2B SILENCING ABOLISHED THE FUSION OF AUTOPHAGOSOMES WITH LYSOSOMES AND PRESERVED CELL VIABILITY DESPITE THE ONGOING FORMATION OF AUTOPHAGOSOMES IN CELLS CHRONICALLY EXPOSED TO RV. THE PAN-CASPASE INHIBITOR BENZYLOXYCARBONYL-VAL-ALA-ASP-FLUOROMETHYLKETONE INHIBITED RV-INDUCED CELL DEATH, BUT NOT AUTOPHAGY. THESE RESULTS UNCOVER A NOVEL PATHWAY OF RV CYTOTOXICITY IN WHICH AUTOPHAGY PLAYS A DUAL ROLE: (I) AT FIRST, IT ACTS AS A PROSURVIVAL STRESS RESPONSE AND (II) AT A LATER TIME, IT SWITCHES TO A CASPASE-DEPENDENT APOPTOSIS PATHWAY. THE PRESENT DATA ALSO INDICATE THAT GENETIC OR EPIGENETIC INACTIVATION OF AUTOPHAGY PROTEINS IN CANCER CELLS MAY CONFER RESISTANCE TO RV-MEDIATED KILLING. 2008 2 2647 27 EPIGENOMIC PLASTICITY OF ARABIDOPSIS MSH1 MUTANTS UNDER PROLONGED COLD STRESS. DYNAMIC TRANSCRIPTIONAL AND EPIGENETIC CHANGES ENABLE RAPID ADAPTIVE BENEFIT TO ENVIRONMENTAL FLUCTUATIONS. HOWEVER, THE UNDERLYING MECHANISMS AND THE EXTENT TO WHICH THIS OCCURS ARE NOT WELL KNOWN. MUTS HOMOLOG 1 (MSH1) MUTANTS CAUSE HERITABLE DEVELOPMENTAL PHENOTYPES ACCOMPANIED BY MODULATION OF DEFENSE, PHYTOHORMONE, STRESS-RESPONSE, AND CIRCADIAN RHYTHM GENES, AS WELL AS HERITABLE CHANGES IN DNA METHYLATION PATTERNS. CONSISTENT WITH GENE EXPRESSION CHANGES, MSH1 MUTANTS DISPLAY ENHANCED TOLERANCE FOR ABIOTIC STRESS INCLUDING DROUGHT AND SALT STRESS, WHILE SHOWING INCREASED SUSCEPTIBILITY TO FREEZING TEMPERATURES. DESPITE CHANGES IN DEFENSE AND BIOTIC STRESS-RESPONSE GENES, MSH1 MUTANTS SHOWED INCREASING SUSCEPTIBILITY TO THE BACTERIAL PATHOGEN PSEUDOMONAS SYRINGAE. OUR RESULTS SUGGEST THAT CHRONIC COLD AND LOW LIGHT STRESS (10 DEGREES C, 150 MUMOL M(-2) S(-1)) INFLUENCES NON-CG METHYLATION TO A GREATER DEGREE IN MSH1 MUTANTS COMPARED TO WILD-TYPE COL-0. FURTHERMORE, CHG CHANGES ARE MORE CLOSELY PERICENTROMERIC, WHEREAS CHH CHANGES ARE GENERALLY MORE DISPERSED. THIS INCREASED VARIATION IN NON-CG METHYLATION PATTERN DOES NOT SIGNIFICANTLY AFFECT THE MSH1-DERIVED ENHANCED GROWTH BEHAVIOR AFTER MUTANTS ARE CROSSED WITH ISOGENIC WILD TYPE, REITERATING THE IMPORTANCE OF CG METHYLATION CHANGES IN MSH1-DERIVED ENHANCED VIGOR. THESE RESULTS INDICATE THAT MSH1METHYLOME IS HYPER-RESPONSIVE TO ENVIRONMENTAL STRESS IN A MANNER DISTINCT FROM THE WILD-TYPE RESPONSE, BUT CG METHYLATION CHANGES ARE POTENTIALLY RESPONSIBLE FOR GROWTH VIGOR CHANGES IN THE CROSSED PROGENY. 2018 3 1486 24 DNA CYTOSINE HYDROXYMETHYLATION LEVELS ARE DISTINCT AMONG NON-OVERLAPPING CLASSES OF PERIPHERAL BLOOD LEUKOCYTES. BACKGROUND: PERIPHERAL BLOOD LEUKOCYTES ARE THE MOST COMMONLY USED SURROGATES TO STUDY EPIGENOME-INDUCED RISK AND EPIGENOMIC RESPONSE TO DISEASE-RELATED STRESS. WE CONSIDERED THE HYPOTHESIS THAT THE VARIOUS CLASSES OF PERIPHERAL LEUKOCYTES DIFFERENTIALLY REGULATE THE SYNTHESIS OF 5-METHYLCYTOSINE (5MCG) AND ITS REMOVAL VIA TEN-ELEVEN TRANSLOCATION (TET) DIOXYGENASE CATALYZED HYDROXYMETHYLATION TO 5-HYDROXYMETHYLCYTOSINE (5HMCG), REFLECTING THEIR RESPONSIVENESS TO ENVIRONMENT. ALTHOUGH IT IS KNOWN THAT REDUCTIONS IN TET1 AND/OR TET2 ACTIVITY LEAD TO THE OVER-PROLIFERATION OF VARIOUS LEUKOCYTE PRECURSORS IN BONE MARROW AND IN DEVELOPMENT OF CHRONIC MYELOMONOCYTIC LEUKEMIA AND MYELOPROLIFERATIVE NEOPLASMS, THE ROLE OF 5MCG HYDROXYMETHYLATION IN PERIPHERAL BLOOD IS LESS WELL STUDIED. RESULTS: WE DEVELOPED SIMPLIFIED PROTOCOLS TO RAPIDLY AND REITERATIVELY ISOLATE NON-OVERLAPPING LEUKOCYTE POPULATIONS FROM A SINGLE SMALL SAMPLE OF FRESH OR FROZEN WHOLE BLOOD. AMONG PERIPHERAL LEUKOCYTE TYPES WE FOUND EXTREME VARIATION IN THE LEVELS OF TRANSCRIPTS ENCODING PROTEINS INVOLVED IN CYTOSINE METHYLATION (DNMT1, 3A, 3B), THE TURNOVER OF 5MC BY DEMETHYLATION (TET1, 2, 3), AND DNA REPAIR (GADD45A, B, G) AND IN THE GLOBAL AND GENE-REGION-SPECIFIC LEVELS OF DNA 5HMCG (CD4+ T CELLS>>CD14+ MONOCYTES>CD16+ NEUTROPHILS>CD19+ B CELLS>CD56+ NK CELLS>SIGLEC8+ EOSINOPHILS>CD8+ T CELLS). CONCLUSIONS: OUR DATA TAKEN TOGETHER SUGGEST A POTENTIAL HIERARCHY OF RESPONSIVENESS AMONG CLASSES OF LEUKOCYTES WITH CD4+, CD8+ T CELLS AND CD14+ MONOCYTES BEING THE MOST DISTINCTLY POISED FOR A RAPID METHYLOME RESPONSE TO PHYSIOLOGICAL STRESS AND DISEASE. 2016 4 5982 32 TET2 REGULATES IMMUNE TOLERANCE IN CHRONICALLY ACTIVATED MAST CELLS. MUTATION OF THE TET2 DNA-HYDROXYMETHYLASE HAS BEEN ASSOCIATED WITH A NUMBER OF IMMUNE PATHOLOGIES. THE DISPARITY IN PHENOTYPE AND CLINICAL PRESENTATION AMONG THESE PATHOLOGIES LEADS TO QUESTIONS REGARDING THE ROLE OF TET2 MUTATION IN PROMOTING DISEASE EVOLUTION IN DIFFERENT IMMUNE CELL TYPES. HERE WE SHOW THAT, IN PRIMARY MAST CELLS, TET2 EXPRESSION IS INDUCED IN RESPONSE TO CHRONIC AND ACUTE ACTIVATION SIGNALS. IN TET2-DEFICIENT MAST CELLS, CHRONIC ACTIVATION VIA THE ONCOGENIC KITD816V ALLELE ASSOCIATED WITH MASTOCYTOSIS, SELECTS FOR A SPECIFIC EPIGENETIC SIGNATURE CHARACTERIZED BY HYPERMETHYLATED DNA REGIONS (HMR) AT IMMUNE RESPONSE GENES. H3K27AC AND TRANSCRIPTION FACTOR BINDING IS CONSISTENT WITH PRIMING OR MORE OPEN CHROMATIN AT BOTH HMR AND NON-HMR IN PROXIMITY TO IMMUNE GENES IN THESE CELLS, AND THIS SIGNATURE COINCIDES WITH INCREASED PATHOLOGICAL INFLAMMATION SIGNALS. HMR ARE ALSO ASSOCIATED WITH A SUBSET OF IMMUNE GENES THAT ARE DIRECT TARGETS OF TET2 AND REPRESSED IN TET2-DEFICIENT CELLS. REPRESSION OF THESE GENES RESULTS IN IMMUNE TOLERANCE TO ACUTE STIMULATION THAT CAN BE RESCUED WITH VITAMIN C TREATMENT OR REITERATED WITH A TET INHIBITOR. OVERALL, OUR DATA SUPPORT A MODEL WHERE TET2 PLAYS A DIRECT ROLE IN PREVENTING IMMUNE TOLERANCE IN CHRONICALLY ACTIVATED MAST CELLS, SUPPORTING TET2 AS A VIABLE TARGET TO REPROGRAM THE INNATE IMMUNE RESPONSE FOR INNOVATIVE THERAPIES. 2022 5 5965 19 TEN-ELEVEN-TRANSLOCATION 2 (TET2) NEGATIVELY REGULATES HOMEOSTASIS AND DIFFERENTIATION OF HEMATOPOIETIC STEM CELLS IN MICE. THE TEN-ELEVEN-TRANSLOCATION 2 (TET2) GENE ENCODES A MEMBER OF TET FAMILY ENZYMES THAT ALTERS THE EPIGENETIC STATUS OF DNA BY OXIDIZING 5-METHYLCYTOSINE TO 5-HYDROXYMETHYLCYTOSINE (5HMC). SOMATIC LOSS-OF-FUNCTION MUTATIONS OF TET2 ARE FREQUENTLY OBSERVED IN PATIENTS WITH DIVERSE MYELOID MALIGNANCIES, INCLUDING MYELODYSPLASTIC SYNDROMES, MYELOPROLIFERATIVE NEOPLASMS, AND CHRONIC MYELOMONOCYTIC LEUKEMIA. BY ANALYZING MICE WITH TARGETED DISRUPTION OF THE TET2 CATALYTIC DOMAIN, WE SHOW HERE THAT TET2 IS A CRITICAL REGULATOR OF SELF-RENEWAL AND DIFFERENTIATION OF HEMATOPOIETIC STEM CELLS (HSCS). TET2 DEFICIENCY LED TO DECREASED GENOMIC LEVELS OF 5HMC AND AUGMENTED THE SIZE OF THE HEMATOPOIETIC STEM/PROGENITOR CELL POOL IN A CELL-AUTONOMOUS MANNER. IN COMPETITIVE TRANSPLANTATION ASSAYS, TET2-DEFICIENT HSCS WERE CAPABLE OF MULTILINEAGE RECONSTITUTION AND POSSESSED A COMPETITIVE ADVANTAGE OVER WILD-TYPE HSCS, RESULTING IN ENHANCED HEMATOPOIESIS INTO BOTH LYMPHOID AND MYELOID LINEAGES. IN VITRO, TET2 DEFICIENCY DELAYED HSC DIFFERENTIATION AND SKEWED DEVELOPMENT TOWARD THE MONOCYTE/MACROPHAGE LINEAGE. OUR DATA INDICATE THAT TET2 HAS A CRITICAL ROLE IN REGULATING THE EXPANSION AND FUNCTION OF HSCS, PRESUMABLY BY CONTROLLING 5HMC LEVELS AT GENES IMPORTANT FOR THE SELF-RENEWAL, PROLIFERATION, AND DIFFERENTIATION OF HSCS. 2011 6 2111 20 EPIGENETIC FUNCTION OF TET FAMILY, 5-METHYLCYTOSINE, AND 5-HYDROXYMETHYLCYTOSINE IN HEMATOLOGIC MALIGNANCIES. DNA METHYLATION PLAYS SIGNIFICANT ROLES IN A VARIETY OF BIOLOGICAL AND PATHOLOGICAL PROCESSES INCLUDING MAMMALIAN DEVELOPMENT, GENOMIC IMPRINTING, RETROTRANSPOSON SILENCING, AND X-CHROMOSOME INACTIVATION. RECENT DISCOVERIES INDICATED THAT TEN-ELEVEN TRANSLOCATION (TET) FAMILY OF DIOXYGENASES CAN CONVERT 5-METHYLCYTOSINE (5-MC) INTO 5-HYDROXYMETHYLCYTOSINE (5-HMC). THE TET FAMILY INCLUDES THREE MEMBERS: TET1, TET2, AND TET3. WITH INCREASING EVIDENCE, MORE AND MORE BIOLOGICAL AND PATHOLOGICAL PROCESSES IN WHICH 5-HMC AND TET FAMILY SERVE UNPARALLELED BIOLOGICAL ROLES ARE NOTICED, FOR EXAMPLE, DNA DEMETHYLATION AND TRANSCRIPTIONAL REGULATION OF DIFFERENT TARGET GENES, WHICH ARE INVOLVED IN MANY HUMAN DISEASES, ESPECIALLY HEMATOLOGIC MALIGNANCIES, RESEMBLING CHRONIC MYELOMONOCYTIC LEUKEMIA, MYELODYSPLASTIC SYNDROMES, AND SO ON. IN THIS REVIEW, WE FOCUS ON THE DIVERSE FUNCTIONS OF TET FAMILY AND THE NOVEL EPIGENETIC MARKS, 5-MC AND 5-HMC, IN HEMATOLOGIC MALIGNANCIES. THIS REVIEW WILL PROVIDE VALUABLE INSIGHTS INTO THE POTENTIAL TARGETS OF HEMATOLOGIC MALIGNANCIES. FURTHER UNDERSTANDING OF THE NORMAL AND PATHOLOGICAL FUNCTIONS OF TET FAMILY MAY PROVIDE NEW METHODS TO DEVELOP NOVEL EPIGENETIC THERAPIES FOR TREATING HEMATOLOGIC MALIGNANCIES. 2019 7 5975 18 TET1 IS AN IMPORTANT TRANSCRIPTIONAL ACTIVATOR OF TNFALPHA EXPRESSION IN MACROPHAGES. ACTIVATION OF MACROPHAGES AND OVEREXPRESSION OF TNFALPHA IS ASSOCIATED WITH THE PATHOGENESIS OF CHRONIC INFLAMMATORY DISEASES. HOWEVER, THE MECHANISMS LEADING TO TNFALPHA OVEREXPRESSION ARE STILL UNKNOWN. 5-METHYLOCYTOSINE (5-MC) IS AN EPIGENETIC MODIFICATION THAT IS ASSOCIATED WITH SILENCED GENES. RECENT STUDIES SHOWED THAT IT IS CONVERTED TO 5-HYDROXYLMETHYLOCYTOSINE (5-HMC) AND REACTIVATES GENE EXPRESSION THROUGH THE ACTION OF THE FAMILY OF TEN-ELEVEN-TRANSLOCATION (TET1-3) ENZYMES. IN THIS STUDY, WE SHOW THAT 5-HMC LEVELS ARE INCREASED GLOBALLY AND SPECIFICALLY IN THE TNFALPHA PROMOTER DURING THE DIFFERENTIATION OF MONOCYTES TO MACROPHAGES. IN ADDITION, THE LEVELS OF 5-HMC ARE INCREASED UPON LPS STIMULATION OF MACROPHAGES. FURTHERMORE, CRIPSR STABLE KNOCKOUT OF TET1 DECREASES THE EXPRESSION OF TNFALPHA AND OTHER PRO-INFLAMMATORY CYTOKINES. IN CONCLUSION, WE SHOWED THAT TET1 CONTRIBUTES TO THE ACTIVATION OF MACROPHAGES POSSIBLY THROUGH REGULATION OF 5-HYDROXYMETHYLATION IN THE PROMOTER OF PRO-INFLAMMATORY CYTOKINE GENES. THE TET1 ENZYME COULD BE A PROMISING THERAPEUTIC TARGET TO INHIBIT THE PERSISTENT INFLAMMATION CAUSED BY MACROPHAGES IN CHRONIC INFLAMMATORY DISEASES. 2019 8 5301 23 PROTEIN PHOSPHATASE 2A CATALYTIC SUBUNIT ALPHA PLAYS A MYD88-DEPENDENT, CENTRAL ROLE IN THE GENE-SPECIFIC REGULATION OF ENDOTOXIN TOLERANCE. MYD88, THE INTRACELLULAR ADAPTOR OF MOST TLRS, MEDIATES EITHER PROINFLAMMATORY OR IMMUNOSUPPRESSIVE SIGNALING THAT CONTRIBUTES TO CHRONIC INFLAMMATION-ASSOCIATED DISEASES. ALTHOUGH GENE-SPECIFIC CHROMATIN MODIFICATIONS REGULATE INFLAMMATION, THE ROLE OF MYD88 SIGNALING IN ESTABLISHING SUCH EPIGENETIC LANDSCAPES UNDER DIFFERENT INFLAMMATORY STATES REMAINS ELUSIVE. USING QUANTITATIVE PROTEOMICS TO ENUMERATE THE INFLAMMATION-PHENOTYPIC CONSTITUENTS OF THE MYD88 INTERACTOME, WE FOUND THAT IN ENDOTOXIN-TOLERANT MACROPHAGES, PROTEIN PHOSPHATASE 2A CATALYTIC SUBUNIT ALPHA (PP2AC) ENHANCES ITS ASSOCIATION WITH MYD88 AND IS CONSTITUTIVELY ACTIVATED. KNOCKDOWN OF PP2AC PREVENTS SUPPRESSION OF PROINFLAMMATORY GENES AND RESISTANCE TO APOPTOSIS. THROUGH SITE-SPECIFIC DEPHOSPHORYLATION, CONSTITUTIVELY ACTIVE PP2AC DISRUPTS THE SIGNAL-PROMOTING TLR4-MYD88 COMPLEX AND BROADLY SUPPRESSES THE ACTIVITIES OF MULTIPLE PROINFLAMMATORY/PROAPOPTOTIC PATHWAYS AS WELL, SHIFTING PROINFLAMMATORY MYD88 SIGNALING TO A PROSURVIVAL MODE. CONSTITUTIVELY ACTIVE PP2AC TRANSLOCATED WITH MYD88 INTO THE NUCLEI OF TOLERANT MACROPHAGES ESTABLISHES THE IMMUNOSUPPRESSIVE PATTERN OF CHROMATIN MODIFICATIONS AND REPRESSES CHROMATIN REMODELING TO SELECTIVELY SILENCE PROINFLAMMATORY GENES, COORDINATING THE MYD88-DEPENDENT INFLAMMATION CONTROL AT BOTH SIGNALING AND EPIGENETIC LEVELS UNDER ENDOTOXIN-TOLERANT CONDITIONS. 2013 9 2185 26 EPIGENETIC MECHANISMS UNDERLYING HIV-INFECTION INDUCED SUSCEPTIBILITY OF CD4+ T CELLS TO ENHANCED ACTIVATION-INDUCED FASL EXPRESSION AND CELL DEATH. BACKGROUND: CHRONIC IMMUNE ACTIVATION AND CD4 T CELL DEPLETION ARE SIGNIFICANT PATHOGENIC FEATURES OF HIV INFECTION. EXPRESSION OF FAS LIGAND (FASL), A KEY MEDIATOR OF ACTIVATION-INDUCED CELL DEATH IN T CELLS, IS ELEVATED IN PEOPLE LIVING WITH HIV-1 INFECTION (PLWH). HOWEVER, THE EPIGENETIC MECHANISMS UNDERLYING THE ENHANCED INDUCTION OF FASL EXPRESSION IN CD4 T LYMPHOCYTES IN PLWH ARE NOT COMPLETELY ELUCIDATED. HENCE, THE CURRENT WORK EXAMINED THE EFFECT OF HIV INFECTION ON FASL PROMOTER-ASSOCIATED HISTONE MODIFICATIONS AND TRANSCRIPTIONAL REGULATION IN CD4 T LYMPHOCYTES IN PLWH. METHOD: FLOW CYTOMETRIC ANALYSIS WAS PERFORMED TO EXAMINE THE FAS-FASL EXPRESSION ON TOTAL CD4 T CELLS AND NAIVE/MEMORY CD4 T CELL SUBSETS. EPIGENETIC FASL PROMOTER HISTONE MODIFICATIONS WERE INVESTIGATED BY CHROMATIN IMMUNOPRECIPITATION-QUANTITATIVE REAL-TIME POLYMERASE CHAIN REACTION ANALYSIS USING FRESHLY ISOLATED TOTAL CD4 T LYMPHOCYTES FROM HIV-1 INFECTED AND NONINFECTED INDIVIDUALS. RESULTS: ALL NAIVE/MEMORY CD4 T CELL SUBSETS FROM PLWH SHOWED MARKEDLY GREATER FREQUENCY OF FASL EXPRESSION. NOTABLY, EXAMINATION OF FUNCTIONAL OUTCOME OF FASL/FAS CO-EXPRESSION DEMONSTRATED THE PREFERENTIAL SUSCEPTIBILITY OF TCM AND TEM SUBSETS TO ACTIVATION-INDUCED APOPTOSIS. IMPORTANTLY, THESE CD4 T CELLS COLLECTIVELY DEMONSTRATED A DISTINCT FASL PROMOTER HISTONE PROFILE INVOLVING A COORDINATED CROSS-TALK BETWEEN HISTONE H3 MODIFICATIONS LEADING TO ENHANCED FASL GENE EXPRESSION. SPECIFICALLY, LEVELS OF TRANSCRIPTIONALLY PERMISSIVE HISTONE H3K4-TRIMETHYLATION (H3K4ME3) AND HISTONE H3K9-ACETYLATION (H3K9AC) WERE INCREASED, WITH A CONCOMITANT DECREASE IN THE REPRESSIVE H3K9-TRIMETHYLATION (H3K9ME3). CONCLUSION: THE PRESENT WORK DEMONSTRATES THAT EPIGENETIC MECHANISMS INVOLVING PROMOTER-HISTONE MODIFICATIONS REGULATE TRANSCRIPTIONAL COMPETENCE AND FASL EXPRESSION IN CD4 T CELLS FROM PLWH AND RENDER THEM SUSCEPTIBLE TO ACTIVATION-INDUCED CELL DEATH. 2021 10 4980 22 PATHOPHYSIOLOGY OF LIVER FIBROSIS. PROGRESSIVE ACCUMULATION OF FIBRILLAR EXTRACELLULAR MATRIX (ECM) IN THE LIVER IS THE CONSEQUENCE OF REITERATED LIVER TISSUE DAMAGE DUE TO INFECTIVE (MOSTLY HEPATITIS B AND C VIRUSES), TOXIC/DRUG-INDUCED, METABOLIC AND AUTOIMMUNE CAUSES, AND THE RELATIVE CHRONIC ACTIVATION OF THE WOUND-HEALING REACTION. THE PROCESS MAY RESULT IN CLINICALLY EVIDENT LIVER CIRRHOSIS AND HEPATIC FAILURE. ALTHOUGH CIRRHOSIS IS THE COMMON RESULT OF PROGRESSIVE FIBROGENESIS, THERE ARE DISTINCT PATTERNS OF FIBROTIC DEVELOPMENT RELATED TO THE UNDERLYING DISORDERS CAUSING THE FIBROSIS. THESE DIFFERENT PATTERNS OF FIBROGENIC EVOLUTION ARE RELATED TO DIFFERENT FACTORS AND PARTICULARLY: (1) THE TOPOGRAPHIC LOCALIZATION OF TISSUE DAMAGE, (2) THE RELATIVE CONCENTRATION OF PROFIBROGENIC FACTORS AND (3) THE PREVALENT PROFIBROGENIC MECHANISM(S). THE MECHANISMS RESPONSIBLE FOR THE FIBROGENIC EVOLUTION OF CHRONIC LIVER DISEASES CAN BE SUMMARIZED IN THREE MAIN GROUPS: CHRONIC ACTIVATION OF THE WOUND-HEALING REACTION, OXIDATIVE STRESS-RELATED MOLECULAR MECHANISMS, AND THE DERANGEMENT OF THE SO-CALLED 'EPITHELIAL-MESENCHYMAL' INTERACTION LEADING TO THE GENERATION OF REACTIVE CHOLANGIOCYTES AND PERIBILIARY FIBROSIS. MOST OF THE KNOWLEDGE ON THE CELL AND MOLECULAR BIOLOGY OF HEPATIC FIBROSIS DERIVES FROM IN VITRO STUDIES EMPLOYING CULTURE OF ACTIVATED HEPATIC STELLATE CELLS ISOLATED FROM RAT, MOUSE OR HUMAN LIVER. IT IS NOW EVIDENT THAT OTHER ECM-PRODUCING CELLS, I.E. FIBROBLASTS AND MYOFIBROBLASTS OF THE PORTAL TRACT AND CIRCULATING 'FIBROCYTES', ARE LIKELY TO CONTRIBUTE TO LIVER FIBROSIS. MORE RECENTLY, THE ATTENTION IS PROGRESSIVELY SHIFTING TO THE PROFIBROTIC MICROENVIRONMENT OF THE LIVER WITH INCREASING INTEREST FOR THE ROLE OF IMMUNE CELLS AND SPECIFIC SUBSETS OF MACROPHAGES REGULATING THE PROGRESSION OR THE REGRESSION OF FIBROSIS, THE ROLE OF INTESTINAL MICROBIOTA AND THE INFLUENCE OF TISSUE STIFFNESS. OTHER MAJOR AREAS OF DEVELOPMENT INCLUDE THE ROLE OF TISSUE HYPOXIA AND THE ESTABLISHMENT OF AN ANAEROBIC PROINFLAMMATORY ENVIRONMENT AND THE INFLUENCE OF EPIGENETIC MODIFICATION IN CONDITIONING THE PROGRESSION OF FIBROSIS. 2015 11 3759 27 INTEGRATED SINGLE CELL ANALYSIS SHOWS CHRONIC ALCOHOL DRINKING DISRUPTS MONOCYTE DIFFERENTIATION IN THE BONE MARROW NICHE. CHRONIC ALCOHOL DRINKING REWIRES CIRCULATING MONOCYTES AND TISSUE-RESIDENT MACROPHAGES TOWARDS HEIGHTENED INFLAMMATORY STATES WITH COMPROMISED ANTI-MICROBIAL DEFENSES. AS THESE EFFECTS REMAIN CONSISTENT IN SHORT-LIVED MONOCYTES AFTER A 1-MONTH ABSTINENCE PERIOD IT IS UNCLEAR WHETHER THESE CHANGES ARE RESTRICTED TO THE PERIPHERY OR MEDIATED THROUGH ALTERATIONS IN THE PROGENITOR NICHE. TO TEST THIS HYPOTHESIS, WE PROFILED MONOCYTES/MACROPHAGES AND HEMATOPOIETIC STEM CELL PROGENITORS (HSCP) OF THE BONE MARROW COMPARTMENT FROM RHESUS MACAQUES AFTER 12 MONTHS OF ETHANOL CONSUMPTION USING A COMBINATION OF FUNCTIONAL ASSAYS AND SINGLE CELL GENOMICS. BONE MARROW-RESIDENT MONOCYTES/MACROPHAGES FROM ETHANOL-CONSUMING ANIMALS EXHIBITED HEIGHTENED INFLAMMATION. DIFFERENTIATION OF HSCP IN VITRO REVEALED SKEWING TOWARDS MONOCYTES EXPRESSING NEUTROPHIL-LIKE MARKERS WITH HEIGHTENED INFLAMMATORY RESPONSES TO BACTERIAL AGONISTS. SINGLE CELL TRANSCRIPTIONAL ANALYSIS OF HSCPS SHOWED REDUCED PROLIFERATION BUT INCREASED INFLAMMATORY MARKERS IN MATURE MYELOID PROGENITORS. WE OBSERVED TRANSCRIPTIONAL SIGNATURES ASSOCIATED WITH INCREASED OXIDATIVE AND CELLULAR STRESS AS WELL AS OXIDATIVE PHOSPHORYLATION IN IMMATURE AND MATURE MYELOID PROGENITORS. SINGLE CELL ANALYSIS OF THE CHROMATIN LANDSCAPE SHOWED ALTERED DRIVERS OF DIFFERENTIATION IN MONOCYTES AND PROGENITORS. COLLECTIVELY, THESE DATA INDICATE THAT CHRONIC ETHANOL DRINKING RESULTS IN REMODELING OF THE TRANSCRIPTIONAL AND EPIGENETIC LANDSCAPES OF THE BONE MARROW COMPARTMENT LEADING TO ALTERED FUNCTIONS IN THE PERIPHERY. 2023 12 5985 29 TET2-MEDIATED CLONAL HEMATOPOIESIS ACCELERATES HEART FAILURE THROUGH A MECHANISM INVOLVING THE IL-1BETA/NLRP3 INFLAMMASOME. BACKGROUND: RECENT STUDIES HAVE SHOWN THAT HEMATOPOIETIC STEM CELLS CAN UNDERGO CLONAL EXPANSION SECONDARY TO SOMATIC MUTATIONS IN LEUKEMIA-RELATED GENES, THUS LEADING TO AN AGE-DEPENDENT ACCUMULATION OF MUTANT LEUKOCYTES IN THE BLOOD. THIS SOMATIC MUTATION-RELATED CLONAL HEMATOPOIESIS IS COMMON IN HEALTHY OLDER INDIVIDUALS, BUT IT HAS BEEN ASSOCIATED WITH AN INCREASED INCIDENCE OF FUTURE CARDIOVASCULAR DISEASE. THE EPIGENETIC REGULATOR TET2 IS FREQUENTLY MUTATED IN BLOOD CELLS OF INDIVIDUALS EXHIBITING CLONAL HEMATOPOIESIS. OBJECTIVES: THIS STUDY INVESTIGATED WHETHER TET2 MUTATIONS WITHIN HEMATOPOIETIC CELLS CAN CONTRIBUTE TO HEART FAILURE IN 2 MODELS OF CARDIAC INJURY. METHODS: HEART FAILURE WAS INDUCED IN MICE BY PRESSURE OVERLOAD, ACHIEVED BY TRANSVERSE AORTIC CONSTRICTION OR CHRONIC ISCHEMIA INDUCED BY THE PERMANENT LIGATION OF THE LEFT ANTERIOR DESCENDING ARTERY. COMPETITIVE BONE MARROW TRANSPLANTATION STRATEGIES WITH TET2-DEFICIENT CELLS WERE USED TO MIMIC TET2 MUTATION-DRIVEN CLONAL HEMATOPOIESIS. ALTERNATIVELY, TET2 WAS SPECIFICALLY ABLATED IN MYELOID CELLS USING CRE RECOMBINASE EXPRESSED FROM THE LYSM PROMOTER. RESULTS: IN BOTH EXPERIMENTAL HEART FAILURE MODELS, HEMATOPOIETIC OR MYELOID TET2 DEFICIENCY WORSENED CARDIAC REMODELING AND FUNCTION, IN PARALLEL WITH INCREASED INTERLEUKIN-1BETA (IL-1BETA) EXPRESSION. TREATMENT WITH A SELECTIVE NLRP3 INFLAMMASOME INHIBITOR PROTECTED AGAINST THE DEVELOPMENT OF HEART FAILURE AND ELIMINATED THE DIFFERENCES IN CARDIAC PARAMETERS BETWEEN TET2-DEFICIENT AND WILD-TYPE MICE. CONCLUSIONS: TET2 DEFICIENCY IN HEMATOPOIETIC CELLS IS ASSOCIATED WITH GREATER CARDIAC DYSFUNCTION IN MURINE MODELS OF HEART FAILURE AS A RESULT OF ELEVATED IL-1BETA SIGNALING. THESE DATA SUGGEST THAT INDIVIDUALS WITH TET2-MEDIATED CLONAL HEMATOPOIESIS MAY BE AT GREATER RISK OF DEVELOPING HEART FAILURE AND RESPOND BETTER TO IL-1BETA-NLRP3 INFLAMMASOME INHIBITION. 2018 13 3760 18 INTEGRATED SINGLE CELL ANALYSIS SHOWS CHRONIC ALCOHOL DRINKING DISRUPTS MONOCYTE DIFFERENTIATION IN THE BONE MARROW. CHRONIC HEAVY ALCOHOL DRINKING (CHD) REWIRES MONOCYTES AND MACROPHAGES TOWARD HEIGHTENED INFLAMMATORY STATES WITH COMPROMISED ANTIMICROBIAL DEFENSES THAT PERSIST AFTER 1-MONTH ABSTINENCE. TO DETERMINE WHETHER THESE CHANGES ARE MEDIATED THROUGH ALTERATIONS IN THE BONE MARROW NICHE, WE PROFILED MONOCYTES AND HEMATOPOIETIC STEM CELL PROGENITORS (HSCPS) FROM CHD RHESUS MACAQUES USING A COMBINATION OF FUNCTIONAL ASSAYS AND SINGLE CELL GENOMICS. CHD RESULTED IN TRANSCRIPTIONAL PROFILES CONSISTENT WITH INCREASED ACTIVATION AND INFLAMMATION WITHIN BONE MARROW RESIDENT MONOCYTES AND MACROPHAGES. FURTHERMORE, CHD RESULTED IN TRANSCRIPTIONAL SIGNATURES ASSOCIATED WITH INCREASED OXIDATIVE AND CELLULAR STRESS IN HSCP. DIFFERENTIATION OF HSCP IN VITRO REVEALED SKEWING TOWARD MONOCYTES EXPRESSING "NEUTROPHIL-LIKE" MARKERS WITH GREATER INFLAMMATORY RESPONSES TO BACTERIAL AGONISTS. FURTHER ANALYSES OF HSCPS SHOWED BROAD EPIGENETIC CHANGES THAT WERE IN LINE WITH EXACERBATED INFLAMMATORY RESPONSES WITHIN MONOCYTES AND THEIR PROGENITORS. IN SUMMARY, CHD ALTERS HSCPS IN THE BONE MARROW LEADING TO THE PRODUCTION OF MONOCYTES POISED TO GENERATE DYSREGULATED HYPER-INFLAMMATORY RESPONSES. 2023 14 709 31 C-MYC ONCOPROTEIN DICTATES TRANSCRIPTIONAL PROFILES OF ATP-BINDING CASSETTE TRANSPORTER GENES IN CHRONIC MYELOGENOUS LEUKEMIA CD34+ HEMATOPOIETIC PROGENITOR CELLS. RESISTANCE TO CHEMOTHERAPEUTIC AGENTS REMAINS ONE OF THE MAJOR IMPEDIMENTS TO A SUCCESSFUL TREATMENT OF CHRONIC MYELOID LEUKEMIA (CML). MISREGULATION OF THE ACTIVITY OF A SPECIFIC GROUP OF ATP-BINDING CASSETTE TRANSPORTERS (ABC) IS RESPONSIBLE FOR REDUCING THE INTRACELLULAR CONCENTRATION OF DRUGS IN LEUKEMIC CELLS. MOREOVER, A CONSISTENT BODY OF EVIDENCE ALSO SUGGESTS THAT ABC TRANSPORTERS PLAY A ROLE IN CANCER PROGRESSION BEYOND THE EFFLUX OF CYTOTOXIC DRUGS. DESPITE A LARGE NUMBER OF STUDIES THAT INVESTIGATED THE FUNCTION OF THE ABC TRANSPORTERS, LITTLE IS KNOWN ABOUT THE TRANSCRIPTIONAL REGULATION OF THE ABC GENES. HERE, WE PRESENT DATA SHOWING THAT THE ONCOPROTEIN C-MYC IS A DIRECT TRANSCRIPTIONAL REGULATOR OF A LARGE SET OF ABC TRANSPORTERS IN CML. FURTHERMORE, MOLECULAR ANALYSIS CARRIED OUT IN CD34+ HEMATOPOIETIC CELL PRECURSORS OF 21 CML PATIENTS REVEALS THAT THE OVEREXPRESSION OF ABC TRANSPORTERS DRIVEN BY C-MYC IS A PECULIAR CHARACTERISTIC OF THE CD34+ POPULATION IN CML AND WAS NOT FOUND EITHER IN THE POPULATION OF MONONUCLEAR CELLS FROM WHICH THEY HAD BEEN PURIFIED NOR IN CD34+ CELLS ISOLATED FROM HEALTHY DONORS. FINALLY, WE DESCRIBE HOW THE METHYLATION STATE OF CPG ISLANDS MAY REGULATE THE ACCESS OF C-MYC TO ABCG2 GENE PROMOTER, A WELL-STUDIED GENE ASSOCIATED WITH MULTIDRUG RESISTANCE IN CML, HENCE, AFFECTING ITS EXPRESSION. TAKEN TOGETHER, OUR FINDINGS SUPPORT A MODEL IN WHICH C-MYC-DRIVEN TRANSCRIPTIONAL EVENTS, COMBINED WITH EPIGENETIC MECHANISMS, DIRECT AND REGULATE THE EXPRESSION OF ABC GENES WITH POSSIBLE IMPLICATIONS IN TUMOR MALIGNANCY AND DRUG EFFLUX IN CML. 2011 15 83 24 A NOVEL EPIGENETIC MARKER, TEN-ELEVEN TRANSLOCATION FAMILY MEMBER 2 (TET2), IS IDENTIFIED IN THE INTRACTABLE EPILEPTIC BRAIN AND REGULATES ATP BINDING CASSETTE SUBFAMILY B MEMBER 1 (ABCB1) IN THE BLOOD-BRAIN BARRIER. DRUG-RESISTANT EPILEPSY (DRE) IS A CHRONIC CONDITION DERIVED FROM SPONTANEOUS CHANGES AND REGULATORY EFFECTS IN THE EPILEPTIC BRAIN. AS DEMETHYLATION FACTORS, TEN-ELEVEN TRANSLOCATION (TET) FAMILY MEMBERS HAVE BECOME A FOCUS IN RECENT STUDIES OF NEUROLOGICAL DISORDERS. HERE, WE QUANTIFIED AND LOCALIZED TET1, TET2 AND 5-HYDROXYMETHYLCYTOSINE (5-HMC) IN THE TEMPORAL LOBE CORTEX OF DRE PATIENTS (N = 27) AND TRAUMATIC BRAIN HEMORRHAGE CONTROLS (N = 10) BY IMMUNOCHEMICAL STAINING. TET2 AND ATP BINDING CASSETTE SUBFAMILY B MEMBER 1 (ABCB1) EXPRESSION PATTERNS WERE DETERMINED IN THE ISOLATED BRAIN CAPILLARIES OF DRE PATIENTS. TET2 EXPRESSION WAS SIGNIFICANTLY INCREASED IN THE TEMPORAL CORTICAL TISSUE OF DRE PATIENTS WITH OR WITHOUT HIPPOCAMPAL SCLEROSIS (HS) COMPARED TO CONTROL PATIENTS, WHILE TET1 AND 5-HMC SHOWED NO DIFFERENCES IN EXPRESSION. WE ALSO FOUND THAT A PARTICULARLY STRONG EXPRESSION OF TET2 IN THE VASCULAR TISSUE OF DRE PATIENTS. ABCB1 AND TET2 HAVE EVIDENTLY HIGHER EXPRESSION IN THE VASCULAR ENDOTHELIUM FROM THE NEOCORTEX OF DRE PATIENTS. IN BLOOD-BRAIN BARRIER (BBB) MODEL, TET2 DEPLETION CAN CAUSE ATTENUATED EXPRESSION AND FUNCTION OF ABCB1. DATA FROM A COHORT STUDY AND EXPERIMENTS IN A BBB MODEL SUGGEST THAT TET2 HAS A SPECIFIC REGULATORY EFFECT ON ABCB1, WHICH MAY SERVE AS A POTENTIAL MECHANISM AND TARGET IN DRE. 2022 16 5974 24 TET1 IN NUCLEUS ACCUMBENS OPPOSES DEPRESSION- AND ANXIETY-LIKE BEHAVIORS. DEPRESSION IS A LEADING CAUSE OF DISEASE BURDEN, YET CURRENT THERAPIES FULLY TREAT <50% OF AFFECTED INDIVIDUALS. INCREASING EVIDENCE IMPLICATES EPIGENETIC MECHANISMS IN DEPRESSION AND ANTIDEPRESSANT ACTION. HERE WE EXAMINED A POSSIBLE ROLE FOR THE DNA DIOXYGENASE, TEN-ELEVEN TRANSLOCATION PROTEIN 1 (TET1), IN DEPRESSION-RELATED BEHAVIORAL ABNORMALITIES. WE APPLIED CHRONIC SOCIAL DEFEAT STRESS, AN ETHOLOGICALLY VALIDATED MOUSE MODEL OF DEPRESSION-LIKE BEHAVIORS, AND EXAMINED TET1 EXPRESSION CHANGES IN NUCLEUS ACCUMBENS (NAC), A KEY BRAIN REWARD REGION. WE SHOW DECREASED TET1 EXPRESSION IN NAC IN STRESS-SUSCEPTIBLE MICE ONLY. SURPRISINGLY, SELECTIVE KNOCKOUT OF TET1 IN NAC NEURONS OF ADULT MICE PRODUCED ANTIDEPRESSANT-LIKE EFFECTS IN SEVERAL BEHAVIORAL ASSAYS. TO IDENTIFY TET1 TARGETS THAT MEDIATE THESE ACTIONS, WE PERFORMED RNASEQ ON NAC AFTER CONDITIONAL DELETION OF TET1 AND FOUND THAT IMMUNE-RELATED GENES ARE THE MOST HIGHLY DYSREGULATED. MOREOVER, MANY OF THESE GENES ARE ALSO UPREGULATED IN THE NAC OF RESILIENT MICE AFTER CHRONIC SOCIAL DEFEAT STRESS. THESE FINDINGS REVEAL A NOVEL ROLE FOR TET1, AN ENZYME IMPORTANT FOR DNA HYDROXYMETHYLATION, IN THE BRAIN'S REWARD CIRCUITRY IN MODULATING STRESS RESPONSES IN MICE. WE ALSO IDENTIFY A SUBSET OF GENES THAT ARE REGULATED BY TET1 IN THIS CIRCUITRY. THESE FINDINGS PROVIDE NEW INSIGHT INTO THE PATHOPHYSIOLOGY OF DEPRESSION, WHICH CAN AID IN FUTURE ANTIDEPRESSANT DRUG DISCOVERY EFFORTS. 2017 17 4563 25 MYELOID DNA METHYLTRANSFERASE3B DEFICIENCY AGGRAVATES PULMONARY FIBROSIS BY ENHANCING PROFIBROTIC MACROPHAGE ACTIVATION. BACKGROUND: IDIOPATHIC PULMONARY FIBROSIS (IPF) IS A CHRONIC, PROGRESSIVE AND SEVERE DISEASE CHARACTERIZED BY EXCESSIVE MATRIX DEPOSITION IN THE LUNGS. MACROPHAGES PLAY CRUCIAL ROLES IN MAINTAINING LUNG HOMEOSTASIS BUT ARE ALSO CENTRAL IN THE PATHOGENESIS OF LUNG DISEASES LIKE PULMONARY FIBROSIS. ESPECIALLY, MACROPHAGE POLARIZATION/ACTIVATION SEEMS TO PLAY A CRUCIAL ROLE IN PATHOLOGY AND EPIGENETIC REPROGRAMING IS WELL-KNOWN TO REGULATE MACROPHAGE POLARIZATION. DNA METHYLATION ALTERATIONS IN IPF LUNGS HAVE BEEN WELL DOCUMENTED, BUT THE ROLE OF DNA METHYLATION IN SPECIFIC CELL TYPES, ESPECIALLY MACROPHAGES, IS POORLY DEFINED. METHODS: IN ORDER TO DETERMINE THE ROLE OF DNA METHYLATION IN MACROPHAGES DURING PULMONARY FIBROSIS, WE SUBJECTED MACROPHAGE SPECIFIC DNA METHYLTRANSFERASE (DNMT)3B, WHICH MEDIATES THE DE NOVO DNA METHYLATION, DEFICIENT MICE TO THE BLEOMYCIN-INDUCED PULMONARY FIBROSIS MODEL. MACROPHAGE POLARIZATION AND FIBROTIC PARAMETERS WERE EVALUATED AT 21 DAYS AFTER BLEOMYCIN ADMINISTRATION. DNMT3B KNOCKOUT AND WILD TYPE BONE MARROW-DERIVED MACROPHAGES WERE STIMULATED WITH EITHER INTERLEUKIN (IL)4 OR TRANSFORMING GROWTH FACTOR BETA 1 (TGFB1) IN VITRO, AFTER WHICH PROFIBROTIC GENE EXPRESSION AND DNA METHYLATION AT THE ARG1 PROMOTOR WERE DETERMINED. RESULTS: WE SHOW THAT DNMT3B DEFICIENCY PROMOTES ALTERNATIVE MACROPHAGE POLARIZATION INDUCED BY IL4 AND TGFB1 IN VITRO AND ALSO ENHANCES PROFIBROTIC MACROPHAGE POLARIZATION IN THE ALVEOLAR SPACE DURING PULMONARY FIBROSIS IN VIVO. MOREOVER, MYELOID SPECIFIC DELETION OF DNMT3B PROMOTED THE DEVELOPMENT OF EXPERIMENTAL PULMONARY FIBROSIS. CONCLUSIONS: IN SUMMARY, THESE DATA SUGGEST THAT MYELOID DNMT3B REPRESSES FIBROTIC MACROPHAGE POLARIZATION AND PROTECTS AGAINST BLEOMYCIN INDUCED PULMONARY FIBROSIS. 2022 18 5981 25 TET2 PROMOTES PATHOGEN INFECTION-INDUCED MYELOPOIESIS THROUGH MRNA OXIDATION. VARIETIES OF RNA MODIFICATION FORM THE EPITRANSCRIPTOME FOR POST-TRANSCRIPTIONAL REGULATION. 5-METHYLCYTOSINE (5-MC) IS A SPARSE RNA MODIFICATION IN MESSENGER RNA (MRNA) UNDER PHYSIOLOGICAL CONDITIONS. THE FUNCTION OF RNA 5-HYDROXYMETHYLCYTOSINE (5-HMC) OXIDIZED BY TEN-ELEVEN TRANSLOCATION (TET) PROTEINS IN DROSOPHILA HAS BEEN REVEALED MORE RECENTLY. HOWEVER, THE TURNOVER AND FUNCTION OF 5-MC IN MAMMALIAN MRNA HAVE BEEN LARGELY UNKNOWN. TET2 SUPPRESSES MYELOID MALIGNANCIES MOSTLY IN AN ENZYMATIC ACTIVITY-DEPENDENT MANNER, AND IS IMPORTANT IN RESOLVING INFLAMMATORY RESPONSE IN AN ENZYMATIC ACTIVITY-INDEPENDENT WAY. MYELOPOIESIS IS A COMMON HOST IMMUNE RESPONSE IN ACUTE AND CHRONIC INFECTIONS; HOWEVER, ITS EPIGENETIC MECHANISM NEEDS TO BE IDENTIFIED. HERE WE DEMONSTRATE THAT TET2 PROMOTES INFECTION-INDUCED MYELOPOIESIS IN AN MRNA OXIDATION-DEPENDENT MANNER THROUGH ADAR1-MEDIATED REPRESSION OF SOCS3 EXPRESSION AT THE POST-TRANSCRIPTION LEVEL. TET2 PROMOTES BOTH ABDOMINAL SEPSIS-INDUCED EMERGENCY MYELOPOIESIS AND PARASITE-INDUCED MAST CELL EXPANSION THROUGH DECREASING MRNA LEVELS OF SOCS3, A KEY NEGATIVE REGULATOR OF THE JAK-STAT PATHWAY THAT IS CRITICAL FOR CYTOKINE-INDUCED MYELOPOIESIS. TET2 REPRESSES SOCS3 EXPRESSION THROUGH ADAR1, WHICH BINDS AND DESTABILIZES SOCS3 MRNA IN A RNA EDITING-INDEPENDENT MANNER. FOR THE UNDERLYING MECHANISM OF TET2 REGULATION AT THE MRNA LEVEL, TET2 MEDIATES OXIDATION OF 5-MC IN MRNA. TET2 DEFICIENCY LEADS TO THE TRANSCRIPTOME-WIDE APPEARANCE OF METHYLATED CYTOSINES, INCLUDING ONES IN THE 3' UNTRANSLATED REGION OF SOCS3, WHICH INFLUENCES DOUBLE-STRANDED RNA FORMATION FOR ADAR1 BINDING, PROBABLY THROUGH CYTOSINE METHYLATION-SPECIFIC READERS, SUCH AS RNA HELICASES. OUR STUDY REVEALS A PREVIOUSLY UNKNOWN REGULATORY ROLE OF TET2 AT THE EPITRANSCRIPTOMIC LEVEL, PROMOTING MYELOPOIESIS DURING INFECTION IN THE MAMMALIAN SYSTEM BY DECREASING 5-MCS IN MRNAS. MOREOVER, THE INHIBITORY FUNCTION OF CYTOSINE METHYLATION ON DOUBLE-STRANDED RNA FORMATION AND ADAR1 BINDING IN MRNA REVEALS ITS NEW PHYSIOLOGICAL ROLE IN THE MAMMALIAN SYSTEM. 2018 19 1826 35 EFFECTS OF HISTONE DEACETYLASE INHIBITOR ON EXTRACELLULAR MATRIX PRODUCTION IN HUMAN NASAL POLYP ORGAN CULTURES. BACKGROUND: NASAL POLYPOSIS IS ASSOCIATED WITH A CHRONIC INFLAMMATORY CONDITION OF THE SINONASAL MUCOSA AND INVOLVES MYOFIBROBLAST DIFFERENTIATION AND EXTRACELLULAR MATRIX (ECM) ACCUMULATION. EPIGENETIC MODULATION BY HISTONE DEACETYLASE (HDAC) INHIBITORS INCLUDING TRICHOSTATIN A (TSA) HAS BEEN REPORTED TO HAVE INHIBITORY EFFECTS ON MYOFIBROBLAST DIFFERENTIATION IN LUNG AND RENAL FIBROBLASTS. THE PURPOSE OF THIS STUDY WAS TO INVESTIGATE THE INHIBITORY EFFECT OF TSA ON MYOFIBROBLAST DIFFERENTIATION AND ECM PRODUCTION IN NASAL POLYP ORGAN CULTURES. METHODS: NASAL POLYP TISSUES FROM 18 PATIENTS WERE ACQUIRED DURING ENDOSCOPIC SINUS SURGERY. AFTER ORGAN CULTURE, NASAL POLYPS WERE STIMULATED WITH TGF-BETA1 AND THEN TREATED WITH TSA. ALPHA-SMOOTH MUSCLE ACTIN (ALPHA-SMA), FIBRONECTIN, AND COLLAGEN TYPE I EXPRESSION LEVELS WERE EXAMINED BY REVERSE TRANSCRIPTION-POLYMERASE CHAIN REACTION (PCR), REAL-TIME PCR, WESTERN BLOT, AND IMMUNOFLUORESCENT STAINING. HDAC2, HDAC4, AND ACETYLATED H4 EXPRESSION LEVELS WERE ASSAYED BY WESTERN BLOT. CYTOTOXICITY WAS ANALYZED BY THE TERMINAL DEOXYNUCLEOTIDYL TRANSFERASE BIOTIN-DUTP NICK END LABELING ASSAY. RESULTS: THE EXPRESSION LEVELS OF ALPHA-SMA, FIBRONECTIN, AND COLLAGEN TYPE 1 WERE INCREASED IN NASAL POLYP AFTER TRANSFORMING GROWTH FACTOR (TGF) BETA1 TREATMENT. TSA-INHIBITED TGF-BETA1 INDUCED THESE GENE AND PROTEIN EXPRESSION LEVELS. FURTHERMORE, TSA SUPPRESSED PROTEIN EXPRESSION LEVELS OF HDAC2 AND HDAC4. HOWEVER, TSA INDUCED HYPERACETYLATION OF HISTONES H4. TREATMENT WITH TGF-BETA1 WITH OR WITHOUT TSA DID NOT HAVE CYTOTOXIC EFFECT. CONCLUSION: THESE FINDINGS PROVIDE NOVEL INSIGHTS INTO THE EPIGENETIC REGULATION IN MYOFIBROBLAST DIFFERENTIATION AND ECM PRODUCTION OF NASAL POLYP. TSA COULD BE A CANDIDATE OF A THERAPEUTIC AGENT FOR REVERSING THE TGF-BETA1-INDUCED ECM SYNTHESIS THAT LEADS TO NASAL POLYP DEVELOPMENT. 2013 20 3357 28 HISTONE H3 LYSINE 9 DI-METHYLATION AS AN EPIGENETIC SIGNATURE OF THE INTERFERON RESPONSE. EFFECTIVE ANTIVIRAL IMMUNITY DEPENDS ON THE ABILITY OF INFECTED CELLS OR CELLS TRIGGERED WITH VIRUS-DERIVED NUCLEIC ACIDS TO PRODUCE TYPE I INTERFERON (IFN), WHICH ACTIVATES TRANSCRIPTION OF NUMEROUS ANTIVIRAL GENES. HOWEVER, DISPROPORTIONATELY STRONG OR CHRONIC IFN EXPRESSION IS A COMMON CAUSE OF INFLAMMATORY AND AUTOIMMUNE DISEASES. WE DESCRIBE AN EPIGENETIC MECHANISM THAT DETERMINES CELL TYPE-SPECIFIC DIFFERENCES IN IFN AND IFN-STIMULATED GENE (ISG) EXPRESSION IN RESPONSE TO EXOGENOUS SIGNALS. WE IDENTIFY DI-METHYLATION OF HISTONE H3 AT LYSINE 9 (H3K9ME2) AS A SUPPRESSOR OF IFN AND IFN-INDUCIBLE ANTIVIRAL GENE EXPRESSION. WE SHOW THAT LEVELS OF H3K9ME2 AT IFN AND ISG CORRELATE INVERSELY WITH THE SCOPE AND AMPLITUDE OF IFN AND ISG EXPRESSION IN FIBROBLASTS AND DENDRITIC CELLS. ACCORDINGLY, GENETIC ABLATION OR PHARMACOLOGICAL INACTIVATION OF LYSINE METHYLTRANSFERASE G9A, WHICH IS ESSENTIAL FOR THE GENERATION OF H3K9ME2, RESULTED IN PHENOTYPIC CONVERSION OF FIBROBLASTS INTO HIGHLY POTENT IFN-PRODUCING CELLS AND RENDERED THESE CELLS RESISTANT TO PATHOGENIC RNA VIRUSES. IN SUMMARY, OUR STUDIES IMPLICATE H3K9ME2 AND ENZYMES CONTROLLING ITS ABUNDANCE AS KEY REGULATORS OF INNATE ANTIVIRAL IMMUNITY. 2012