1 3242 137 HEPATIC NCOR1 DELETION EXACERBATES ALCOHOL-INDUCED LIVER INJURY IN MICE BY PROMOTING CCL2-MEDIATED MONOCYTE-DERIVED MACROPHAGE INFILTRATION. NUCLEAR RECEPTOR COREPRESSOR 1 (NCOR1) IS A COREPRESSOR OF THE EPIGENETIC REGULATION OF GENE TRANSCRIPTION THAT HAS IMPORTANT FUNCTIONS IN METABOLISM AND INFLAMMATION, BUT LITTLE IS KNOWN ABOUT ITS ROLE IN ALCOHOL-ASSOCIATED LIVER DISEASE (ALD). IN THIS STUDY, WE DEVELOPED MICE WITH HEPATOCYTE-SPECIFIC NCOR1 KNOCKOUT (NCOR1(HEP-/-)) USING THE ALBUMIN-CRE/LOXP SYSTEM AND INVESTIGATED THE ROLE OF NCOR1 IN THE PATHOGENESIS OF ALD AND THE UNDERLYING MECHANISMS. THE TRADITIONAL ALCOHOL FEEDING MODEL AND NIAAA MODEL OF ALD WERE BOTH ESTABLISHED IN WILD-TYPE AND NCOR1(HEP-/-) MICE. WE SHOWED THAT AFTER ALD WAS ESTABLISHED, NCOR1(HEP-/-) MICE HAD WORSE LIVER INJURY BUT LESS STEATOSIS THAN WILD-TYPE MICE. WE DEMONSTRATED THAT HEPATOCYTE-SPECIFIC LOSS OF NCOR1 ATTENUATED LIVER STEATOSIS BY PROMOTING FATTY ACID OXIDATION BY UPREGULATING BMAL1 (A CIRCADIAN CLOCK COMPONENT THAT HAS BEEN REPORTED TO PROMOTE PEROXISOME PROLIFERATOR ACTIVATED RECEPTOR ALPHA (PPARALPHA)-MEDIATED FATTY BETA-OXIDATION BY UPREGULATING DE NOVO LIPID SYNTHESIS). ON THE OTHER HAND, HEPATOCYTE-SPECIFIC LOSS OF NCOR1 EXACERBATED ALCOHOL-INDUCED LIVER INFLAMMATION AND OXIDATIVE STRESS BY RECRUITING MONOCYTE-DERIVED MACROPHAGES VIA C-C MOTIF CHEMOKINE LIGAND 2 (CCL2). IN THE MOUSE HEPATOCYTE LINE AML12, NCOR1 KNOCKDOWN SIGNIFICANTLY INCREASED ETHANOL-INDUCED CCL2 RELEASE. THESE RESULTS SUGGEST THAT HEPATOCYTE NCOR1 PLAYS DISTINCT ROLES IN CONTROLLING LIVER INFLAMMATION AND STEATOSIS, WHICH PROVIDES NEW INSIGHTS INTO THE DEVELOPMENT OF TREATMENTS FOR STEATOHEPATITIS INDUCED BY CHRONIC ALCOHOL CONSUMPTION. 2022 2 975 32 CHRONIC OCCUPATIONAL EXPOSURE TO ARSENIC INDUCES CARCINOGENIC GENE SIGNALING NETWORKS AND NEOPLASTIC TRANSFORMATION IN HUMAN LUNG EPITHELIAL CELLS. CHRONIC ARSENIC EXPOSURE REMAINS A HUMAN HEALTH RISK; HOWEVER A CLEAR MODE OF ACTION TO UNDERSTAND GENE SIGNALING-DRIVEN ARSENIC CARCINOGENESIS IS CURRENTLY LACKING. THIS STUDY CHRONICALLY EXPOSED HUMAN LUNG EPITHELIAL BEAS-2B CELLS TO LOW-DOSE ARSENIC TRIOXIDE TO ELUCIDATE CANCER PROMOTING GENE SIGNALING NETWORKS ASSOCIATED WITH ARSENIC-TRANSFORMED (B-AS) CELLS. FOLLOWING A 6MONTH EXPOSURE, EXPOSED CELLS WERE ASSESSED FOR ENHANCED CELL PROLIFERATION, COLONY FORMATION, INVASION ABILITY AND IN VIVO TUMOR FORMATION COMPARED TO CONTROL CELL LINES. COLLECTED MRNA WAS SUBJECTED TO WHOLE GENOME EXPRESSION MICROARRAY PROFILING FOLLOWED BY IN SILICO INGENUITY PATHWAY ANALYSIS (IPA) TO IDENTIFY LUNG CARCINOGENESIS MODES OF ACTION. B-AS CELLS DISPLAYED SIGNIFICANT INCREASES IN PROLIFERATION, COLONY FORMATION AND INVASION ABILITY COMPARED TO BEAS-2B CELLS. B-AS INJECTIONS INTO NUDE MICE RESULTED IN DEVELOPMENT OF PRIMARY AND SECONDARY METASTATIC TUMORS. ARSENIC EXPOSURE RESULTED IN WIDESPREAD UP-REGULATION OF GENES ASSOCIATED WITH MITOCHONDRIAL METABOLISM AND INCREASED REACTIVE OXYGEN SPECIES PROTECTION SUGGESTING MITOCHONDRIAL DYSFUNCTION. CARCINOGENIC INITIATION VIA REACTIVE OXYGEN SPECIES AND EPIGENETIC MECHANISMS WAS FURTHER SUPPORTED BY ALTERED DNA REPAIR, HISTONE, AND ROS-SENSITIVE SIGNALING. NF-KAPPAB, MAPK AND NCOR1 SIGNALING DISRUPTED PPARALPHA/DELTA-MEDIATED LIPID HOMEOSTASIS. A 'PRO-CANCER' GENE SIGNALING NETWORK IDENTIFIED INCREASED SURVIVAL, PROLIFERATION, INFLAMMATION, METABOLISM, ANTI-APOPTOSIS AND MOBILITY SIGNALING. IPA-RANKED SIGNALING NETWORKS IDENTIFIED ALTERED P21, EF1ALPHA, AKT, MAPK, AND NF-KAPPAB SIGNALING NETWORKS PROMOTING GENETIC DISORDER, ALTERED CELL CYCLE, CANCER AND CHANGES IN NUCLEIC ACID AND ENERGY METABOLISM. IN CONCLUSION, TRANSFORMED B-AS CELLS WITH THEIR WHOLE GENOME EXPRESSION PROFILE PROVIDE AN IN VITRO ARSENIC MODEL FOR FUTURE LUNG CANCER SIGNALING RESEARCH AND DATA FOR CHRONIC ARSENIC EXPOSURE RISK ASSESSMENT. 2012 3 5150 38 PPARALPHA IN THE EPIGENETIC DRIVER SEAT OF NAFLD: NEW THERAPEUTIC OPPORTUNITIES FOR EPIGENETIC DRUGS? NONALCOHOLIC FATTY LIVER DISEASE (NAFLD) IS A GROWING EPIDEMIC AND THE MOST COMMON CAUSE OF CHRONIC LIVER DISEASE WORLDWIDE. IT CONSISTS OF A SPECTRUM OF LIVER DISORDERS RANGING FROM SIMPLE STEATOSIS TO NASH WHICH PREDISPOSES PATIENTS TO FURTHER FIBROSIS, CIRRHOSIS AND EVEN HEPATOCARCINOMA. DESPITE MUCH RESEARCH, AN APPROVED TREATMENT IS STILL LACKING. FINDING NEW THERAPEUTIC TARGETS HAS THEREFORE BEEN A MAIN PRIORITY. KNOWN AS A MAIN REGULATOR OF THE LIPID METABOLISM AND HIGHLY EXPRESSED IN THE LIVER, THE NUCLEAR RECEPTOR PEROXISOME PROLIFERATOR-ACTIVATED RECEPTOR-ALPHA (PPARALPHA) HAS BEEN IDENTIFIED AS AN ATTRACTIVE THERAPEUTIC TARGET. SINCE ITS EXPRESSION IS SILENCED BY DNA HYPERMETHYLATION IN NAFLD PATIENTS, MANY RESEARCH STRATEGIES HAVE AIMED TO RESTORE THE EXPRESSION OF PPARALPHA AND ITS TARGET GENES INVOLVED IN LIPID METABOLISM. ALTHOUGH PREVIOUSLY TESTED PPARALPHA AGONISTS DID NOT AMELIORATE THE DISEASE, CURRENT RESEARCH HAS SHOWN THAT PPARALPHA ALSO INTERACTS AND REGULATES EPIGENETIC DNMT1, JMJD3, TET AND SIRT1 ENZYMES. MOREOVER, THERE IS A GROWING BODY OF EVIDENCE SUGGESTING THE ORCHESTRATING ROLE OF EPIGENETICS IN THE DEVELOPMENT AND PROGRESSION OF NAFLD. THEREFORE, CURRENT THERAPEUTIC STRATEGIES ARE SHIFTING MORE TOWARDS EPIGENETIC DRUGS. THIS REVIEW PROVIDES A CONCISE OVERVIEW OF THE EPIGENETIC REGULATION OF NAFLD WITH A FOCUS ON PPARALPHA REGULATION AND HIGHLIGHTS RECENTLY IDENTIFIED EPIGENETIC INTERACTION PARTNERS OF PPARALPHA. 2022 4 3240 43 HEPATIC LIPID ACCUMULATION ALTERS GLOBAL HISTONE H3 LYSINE 9 AND 4 TRIMETHYLATION IN THE PEROXISOME PROLIFERATOR-ACTIVATED RECEPTOR ALPHA NETWORK. RECENT DATA SUGGEST THAT THE ETIOLOGY OF SEVERAL METABOLIC DISEASES IS CLOSELY ASSOCIATED WITH TRANSCRIPTOME ALTERATION BY ABERRANT HISTONE METHYLATION. WE PERFORMED DNA MICROARRAY AND CHIP-ON-CHIP ANALYSES TO EXAMINE TRANSCRIPTOME PROFILING AND TRIMETHYLATION ALTERATIONS TO IDENTIFY THE GENOMIC SIGNATURE OF NONALCOHOLIC FATTY LIVER DISEASE (NAFLD), THE MOST COMMON FORM OF CHRONIC LIVER DISEASE. TRANSCRIPTOME ANALYSIS SHOWED THAT STEATOTIC LIVERS IN HIGH-FAT DIET-FED APOLIPOPROTEIN E2 MICE SIGNIFICANTLY ALTERED THE EXPRESSION OF APPROXIMATELY 70% OF TOTAL GENES COMPARED WITH NORMAL DIET-FED CONTROL LIVERS, SUGGESTING THAT HEPATIC LIPID ACCUMULATION INDUCES DRAMATIC ALTERATIONS IN GENE EXPRESSION IN VIVO. ALSO, PATHWAY ANALYSIS SUGGESTED THAT GENES ENCODING CHROMATIN-REMODELING ENZYMES, SUCH AS JUMONJI C-DOMAIN-CONTAINING HISTONE DEMETHYLASES THAT REGULATE HISTONE H3K9 AND H3K4 TRIMETHYLATION (H3K9ME3, H3K4ME3), WERE SIGNIFICANTLY ALTERED IN STEATOTIC LIVERS. THUS, WE FURTHER INVESTIGATED THE GLOBAL H3K9ME3 AND H3K4ME3 STATUS IN LIPID-ACCUMULATED MOUSE PRIMARY HEPATOCYTES BY CHIP-ON-CHIP ANALYSIS. RESULTS SHOWED THAT HEPATIC LIPID ACCUMULATION INDUCED ABERRANT H3K9ME3 AND H3K4ME3 STATUS IN PEROXISOME PROLIFERATOR-ACTIVATED RECEPTOR ALPHA AND HEPATIC LIPID CATABOLISM NETWORK GENES, REDUCING THEIR MRNA EXPRESSION COMPARED WITH NON-TREATED CONTROL HEPATOCYTES. THIS STUDY PROVIDES THE FIRST EVIDENCE THAT EPIGENETIC REGULATION BY H3K9ME3 AND H3K4ME3 IN HEPATOCYTES MAY BE INVOLVED IN HEPATIC STEATOSIS AND THE PATHOGENESIS OF NAFLD. THUS, CONTROL OF H3K9ME3 AND H3K4ME3 REPRESENTS A POTENTIAL NOVEL NAFLD PREVENTION AND TREATMENT STRATEGY. 2012 5 5438 32 REMOVAL OF EPIGENETIC REPRESSIVE MARK ON INFLAMMATORY GENES IN FAT LIVER. NONALCOHOLIC FATTY LIVER DISEASE (NAFLD) IS THE MOST COMMON CHRONIC LIVER DISEASE WORLDWIDE. THE DETAILED EPIGENOMIC CHANGES DURING FAT ACCUMULATION IN LIVER ARE NOT CLEAR YET. HERE, WE PERFORMED CHIP-SEQ ANALYSIS IN THE LIVER TISSUES OF HIGH-FAT DIET AND REGULAR CHOW DIET MICE AND INVESTIGATED THE DYNAMIC LANDSCAPES OF H3K27AC AND H3K9ME3 MARKS ON CHROMATIN. WE FIND THAT THE ACTIVATED TYPICAL ENHANCERS MARKED WITH H3K27AC ARE ENRICHED ON LIPID METABOLIC PATHWAYS IN FAT LIVER; HOWEVER, SUPER ENHANCERS DO NOT CHANGE MUCH. THE REGIONS COVERED WITH H3K9ME3 REPRESSIVE MARK SEEM TO UNDERGO GREAT CHANGES, AND ITS PEAK NUMBER AND INTENSITY BOTH DECREASE IN FAT LIVER. THE ENHANCERS LOCATED IN LOST H3K9ME3 REGIONS ARE ENRICHED IN LIPID METABOLISM AND INFLAMMATORY PATHWAYS; AND MOTIF ANALYSIS SHOWS THAT THEY ARE POTENTIAL TARGETS FOR TRANSCRIPTION FACTORS INVOLVED IN METABOLIC AND INFLAMMATORY PROCESSES. OUR STUDY HAS REVEALED THAT H3K9ME3 MAY PLAY AN IMPORTANT ROLE DURING THE PATHOGENESIS OF NAFLD THROUGH REGULATING THE ACCESSIBILITY OF ENHANCERS. 2023 6 2780 36 EZH2 DOWN-REGULATION EXACERBATES LIPID ACCUMULATION AND INFLAMMATION IN IN VITRO AND IN VIVO NAFLD. NON-ALCOHOLIC FATTY LIVER DISEASE (NAFLD) IS ONE OF THE MOST PREVALENT, CHRONIC LIVER DISEASES, WORLDWIDE. IT IS A MULTIFACTORIAL DISEASE CAUSED BY COMPLEX INTERACTIONS BETWEEN GENETIC, EPIGENETIC AND ENVIRONMENTAL FACTORS. RECENTLY, SEVERAL MICRORNAS, SOME OF WHICH EPIGENETICALLY REGULATED, HAVE BEEN FOUND TO BE UP- AND/OR DOWN-REGULATED DURING NAFLD DEVELOPMENT. HOWEVER, IN NAFLD, THE ESSENTIAL ROLE OF THE POLYCOMB GROUP PROTEIN ENHANCER OF ZESTE HOMOLOG 2 (EZH2), WHICH CONTROLS THE EPIGENETIC SILENCING OF SPECIFIC GENES AND/OR MICRORNAS BY TRIMETHYLATING LYS27 ON HISTONE H3, STILL REMAINS UNKNOWN. IN THIS STUDY, WE DEMONSTRATE THAT THE NUCLEAR EXPRESSION/ACTIVITY OF THE EZH2 PROTEIN IS DOWN-REGULATED BOTH IN LIVERS FROM NAFLD RATS AND IN THE FREE FATTY ACID-TREATED HEPG2. THE DROP IN EZH2 IS INVERSELY CORRELATED WITH: (I) LIPID ACCUMULATION; (II) THE EXPRESSION OF PRO-INFLAMMATORY MARKERS INCLUDING TNF-ALPHA AND TGF-BETA; AND (III) THE EXPRESSION OF MIR-200B AND MIR-155. CONSISTENTLY, THE PHARMACOLOGICAL INHIBITION OF EZH2 BY 3-DEAZANEPLANOCIN A (DZNEP) SIGNIFICANTLY REDUCES EZH2 EXPRESSION/ACTIVITY, WHILE IT INCREASES LIPID ACCUMULATION, INFLAMMATORY MOLECULES AND MICRORNAS. IN CONCLUSION, THE RESULTS OF THIS STUDY SUGGEST THAT THE DEFECTIVE ACTIVITY OF EZH2 CAN ENHANCE THE NAFLD DEVELOPMENT BY FAVOURING STEATOSIS AND THE DE-REPRESSION OF THE INFLAMMATORY GENES AND THAT OF SPECIFIC MICRORNAS. 2013 7 1615 43 DNA METHYLTRANSFERASE 3B PLAYS A PROTECTIVE ROLE AGAINST HEPATOCARCINOGENESIS CAUSED BY CHRONIC INFLAMMATION VIA MAINTAINING MITOCHONDRIAL HOMEOSTASIS. MOST HEPATOCELLULAR CARCINOMAS (HCCS) DEVELOP ON THE BASIS OF CHRONIC HEPATITIS, BUT THE MECHANISM OF EPIGENETIC REGULATION IN INFLAMMATORY HEPATOCARCINOGENESIS HAS YET TO BE ELUCIDATED. AMONG DE NOVO DNA METHYLTRANSFERASES (DNMTS), DNMT3B HAS LATELY BEEN REPORTED TO ACT SPECIFICALLY ON ACTIVELY TRANSCRIBED GENES, SUGGESTING THE POSSIBILITY THAT IT PLAYS A ROLE IN THE PATHOGENESIS OF CANCER. WE CONFIRMED THAT DNMT3B ISOFORMS LACKING ITS CATALYTIC DOMAIN WERE HIGHLY EXPRESSED IN HCCS COMPARED WITH NON-TUMOROUS LIVER TISSUE. TO ELUCIDATE THE ROLE OF DNMT3B IN HEPATOCARCINOGENESIS, WE GENERATED A GENETICALLY ENGINEERED MOUSE MODEL WITH HEPATOCYTE-SPECIFIC DNMT3B DELETION. THE LIVER OF THE DNMT3B-DEFICIENT MICE EXHIBITED AN EXACERBATION OF THIOACETAMIDE-INDUCED HEPATITIS, PROGRESSION OF LIVER FIBROSIS AND A HIGHER INCIDENCE OF HCC COMPARED WITH THE LIVER OF THE CONTROL MICE. WHOLE-GENOME BISULFITE SEQUENCING VERIFIED A LOWER CG METHYLATION LEVEL IN THE DNMT3B-DEFICIENT LIVER, DEMONSTRATING DIFFERENTIALLY METHYLATED REGIONS THROUGHOUT THE GENOME. TRANSCRIPTOME ANALYSIS REVEALED DECREASED EXPRESSION OF GENES RELATED TO OXIDATIVE PHOSPHORYLATION IN THE DNMT3B-DEFICIENT LIVER. MOREOVER, PRIMARY HEPATOCYTES ISOLATED FROM THE DNMT3B-DEFICIENT MICE SHOWED REDUCED MITOCHONDRIAL RESPIRATORY CAPACITY, LEADING TO THE ENHANCEMENT OF OXIDATIVE STRESS IN THE LIVER TISSUE. OUR FINDINGS SUGGEST THE PROTECTIVE ROLE OF DNMT3B AGAINST CHRONIC INFLAMMATION AND HCC DEVELOPMENT VIA MAINTAINING MITOCHONDRIAL HOMEOSTASIS. 2020 8 4768 27 NUCLEAR EFFECTS OF ETHANOL-INDUCED PROTEASOME INHIBITION IN LIVER CELLS. ALCOHOL INGESTION CAUSES ALTERATION IN SEVERAL CELLULAR MECHANISMS, AND LEADS TO INFLAMMATION, APOPTOSIS, IMMUNOLOGICAL RESPONSE DEFECTS, AND FIBROSIS. THESE PHENOMENA ARE ASSOCIATED WITH SIGNIFICANT CHANGES IN THE EPIGENETIC MECHANISMS, AND SUBSEQUENTLY, TO LIVER CELL MEMORY. THE UBIQUITIN-PROTEASOME PATHWAY IS ONE OF THE VITAL PATHWAYS IN THE CELL THAT BECOMES DYSFUNCTIONAL AS A RESULT OF CHRONIC ETHANOL CONSUMPTION. INHIBITION OF THE PROTEASOME ACTIVITY IN THE NUCLEUS CAUSES CHANGES IN THE TURNOVER OF TRANSCRIPTIONAL FACTORS, HISTONE MODIFYING ENZYMES, AND THEREFORE, AFFECTS EPIGENETIC MECHANISMS. ALCOHOL CONSUMPTION HAS BEEN ASSOCIATED WITH AN INCREASE IN HISTONE ACETYLATION AND A DECREASE IN HISTONE METHYLATION, WHICH LEADS TO GENE EXPRESSION CHANGES. DNA AND HISTONE MODIFICATIONS THAT RESULT FROM ETHANOL-INDUCED PROTEASOME INHIBITION ARE KEY PLAYERS IN REGULATING GENE EXPRESSION, ESPECIALLY GENES INVOLVED IN THE CELL CYCLE, IMMUNOLOGICAL RESPONSES, AND METABOLISM OF ETHANOL. THE PRESENT REVIEW HIGHLIGHTS THE CONSEQUENCES OF ETHANOL-INDUCED PROTEASOME INHIBITION IN THE NUCLEUS OF LIVER CELLS THAT ARE CHRONICALLY EXPOSED TO ETHANOL. 2009 9 1666 47 DOWNREGULATION OF MICRORNA-145A-5P PROMOTES STEATOSIS-TO-NASH PROGRESSION THROUGH UPREGULATION OF NR4A2. BACKGROUND & AIMS: THE MOLECULAR MECHANISMS UNDERLYING THE PROGRESSION OF SIMPLE STEATOSIS TO NON-ALCOHOLIC STEATOHEPATITIS (NASH) REMAIN INCOMPLETELY UNDERSTOOD, THOUGH THE POTENTIAL ROLE OF EPIGENETIC REGULATION BY MICRORNA (MIRNAS) IS AN AREA OF INCREASING INTEREST. IN THE PRESENT STUDY, WE AIMED TO INVESTIGATE THE ROLE AND MECHANISM OF MIRNAS DURING STEATOSIS-TO-NASH PROGRESSION. METHODS: MIR-145A-5P WAS IDENTIFIED AS AN IMPORTANT CHECKPOINT IN STEATOSIS-TO-NASH PROGRESSION. IN VIVO LOSS-OF-FUNCTION AND GAIN-OF-FUNCTION STUDIES WERE PERFORMED TO EXPLORE THE ROLE OF MIR-145A-5P AND NR4A2 IN NASH PROGRESSION. RNA-SEQUENCING AND BIOINFORMATIC ANALYSIS WERE USED TO INVESTIGATE THE TARGETS OF MIR-145A-5P. RESULTS: SUPPRESSION OF MIR-145A-5P IN THE LIVER AGGRAVATED LIPID ACCUMULATION AND ACTIVATED HEPATIC INFLAMMATION, LIVER INJURY AND FIBROSIS IN STEATOTIC MICE, WHEREAS ITS RESTORATION MARKEDLY ATTENUATED DIET-INDUCED NASH PATHOGENESIS. MECHANISTICALLY, MIR-145A-5P WAS ABLE TO DOWNREGULATE THE NUCLEAR RECEPTOR NR4A2 AND THUS INHIBIT THE EXPRESSION OF NASH-ASSOCIATED GENES. SIMILARLY, NR4A2 OVEREXPRESSION PROMOTED STEATOSIS-TO-NASH PROGRESSION WHILE LIVER-SPECIFIC NR4A2 KNOCKOUT MICE WERE PROTECTED FROM DIET-INDUCED NASH. THIS ROLE OF THE MIR-145A-5P/NR4A2 REGULATORY AXIS WAS ALSO CONFIRMED IN PRIMARY HUMAN HEPATOCYTES. FURTHERMORE, THE EXPRESSION OF MIR-145A-5P WAS REDUCED AND THE EXPRESSION OF NR4A2 WAS INCREASED IN THE LIVERS OF PATIENTS WITH NASH, WHILE THEIR EXPRESSION LEVELS SIGNIFICANTLY NEGATIVELY AND POSITIVELY CORRELATED WITH FEATURES OF LIVER PATHOLOGY, RESPECTIVELY. CONCLUSIONS: OUR FINDINGS HIGHLIGHT THE ROLE OF THE MIR-145A-5P/NR4A2 REGULATORY AXIS IN STEATOSIS-TO-NASH PROGRESSION, SUGGESTING THAT EITHER SUPPLEMENTATION OF MIR-145A-5P OR PHARMACOLOGICAL INHIBITION OF NR4A2 IN HEPATOCYTES MAY PROVIDE A PROMISING THERAPEUTIC APPROACH FOR THE TREATMENT OF NASH. IMPACT AND IMPLICATIONS: NON-ALCOHOLIC FATTY LIVER DISEASE (NAFLD) IS A DYNAMIC SPECTRUM OF CHRONIC LIVER DISEASES RANGING FROM SIMPLE STEATOSIS TO NON-ALCOHOLIC STEATOHEPATITIS (NASH). UNFORTUNATELY, THERE ARE CURRENTLY NO APPROVED DRUGS FOR NASH. OUR CURRENT STUDY IDENTIFIED MIR-145A-5P AS A NOVEL REGULATOR THAT INHIBITS STEATOSIS-TO-NASH PROGRESSION. WE FOUND THAT MIR-145A-5P WAS ABLE TO DOWNREGULATE THE NUCLEAR RECEPTOR NR4A2 TO SUPPRESS THE EXPRESSION OF NASH-ASSOCIATED GENES. THE DIFFERENTIAL EXPRESSION OF MIR-145A-5P AND NR4A2 WAS FURTHER CONFIRMED IN PATIENTS WITH NASH, RAISING THE POSSIBILITY THAT SUPPLEMENTATION OF MIR-145A-5P OR SUPPRESSION OF NR4A2 IN HEPATOCYTES MIGHT PROVIDE NOVEL STRATEGIES FOR TREATING NASH. 2023 10 2590 39 EPIGENETICS OF PROTEASOME INHIBITION IN THE LIVER OF RATS FED ETHANOL CHRONICALLY. AIM: TO EXAMINE THE EFFECTS OF ETHANOL-INDUCED PROTEASOME INHIBITION, AND THE EFFECTS OF PROTEASOME INHIBITION IN THE REGULATION OF EPIGENETIC MECHANISMS. METHODS: RATS WERE FED ETHANOL FOR 1 MO USING THE TSUKAMOTO-FRENCH MODEL AND WERE COMPARED TO RATS GIVEN THE PROTEASOME INHIBITOR PS-341 (BORTEZOMIB, VELCADE(TM)) BY INTRAPERITONEAL INJECTION. MICROARRAY ANALYSIS AND REAL TIME PCR WERE PERFORMED AND PROTEASOME ACTIVITY ASSAYS AND WESTERN BLOT ANALYSIS WERE PERFORMED USING ISOLATED NUCLEI. RESULTS: CHRONIC ETHANOL FEEDING CAUSED A SIGNIFICANT INHIBITION OF THE UBIQUITIN PROTEASOME PATHWAY IN THE NUCLEUS, WHICH LED TO CHANGES IN THE TURNOVER OF TRANSCRIPTIONAL FACTORS, HISTONE-MODIFYING ENZYMES, AND, THEREFORE, AFFECTED EPIGENETIC MECHANISMS. CHRONIC ETHANOL FEEDING WAS RELATED TO AN INCREASE IN HISTONE ACETYLATION, AND IT IS HYPOTHESIZED THAT THE PROTEASOME PROTEOLYTIC ACTIVITY REGULATED HISTONE MODIFICATIONS BY CONTROLLING THE STABILITY OF HISTONE MODIFYING ENZYMES, AND, THEREFORE, REGULATED THE CHROMATIN STRUCTURE, ALLOWING EASY ACCESS TO CHROMATIN BY RNA POLYMERASE, AND, THUS, PROPER GENE EXPRESSION. PROTEASOME INHIBITION BY PS-341 INCREASED HISTONE ACETYLATION SIMILAR TO CHRONIC ETHANOL FEEDING. IN ADDITION, PROTEASOME INHIBITION CAUSED DRAMATIC CHANGES IN HEPATIC REMETHYLATION REACTIONS AS THERE WAS A SIGNIFICANT DECREASE IN THE ENZYMES RESPONSIBLE FOR THE REGENERATION OF S-ADENOSYLMETHIONINE, AND, IN PARTICULAR, A SIGNIFICANT DECREASE IN THE BETAINE-HOMOCYSTEINE METHYLTRANSFERASE ENZYME. THIS SUGGESTED THAT HYPOMETHYLATION WAS ASSOCIATED WITH PROTEASOME INHIBITION, AS INDICATED BY THE DECREASE IN HISTONE METHYLATION. CONCLUSION: THE ROLE OF PROTEASOME INHIBITION IN REGULATING EPIGENETIC MECHANISMS, AND ITS LINK TO LIVER INJURY IN ALCOHOLIC LIVER DISEASE, IS THUS A PROMISING APPROACH TO STUDY LIVER INJURY DUE TO CHRONIC ETHANOL CONSUMPTION. 2009 11 613 41 BINGE ALCOHOL ALTERS PNPLA3 LEVELS IN LIVER THROUGH EPIGENETIC MECHANISM INVOLVING HISTONE H3 ACETYLATION. THE HUMAN PNPLA3 (PATATIN-LIKE PHOSPHOLIPASE DOMAIN-CONTAINING 3) GENE CODES FOR A PROTEIN WHICH IS HIGHLY EXPRESSED IN ADIPOSE TISSUE AND LIVER, AND IS IMPLICATED IN LIPID HOMEOSTASIS. WHILE PNPLA3 PROTEIN CONTAINS REGIONS HOMOLOGOUS TO FUNCTIONAL LIPOLYTIC PROTEINS, THE REGULATION OF ITS TISSUE EXPRESSION IS REFLECTIVE OF LIPOGENIC GENES. A NATURALLY OCCURRING GENETIC VARIANT OF PNPLA3 IN HUMANS HAS BEEN LINKED TO INCREASED SUSCEPTIBILITY TO ALCOHOLIC LIVER DISEASE. WE HAVE EXAMINED THE MODULATORY EFFECT OF ALCOHOL ON PNPLA3 PROTEIN AND MRNA EXPRESSION AS WELL AS THE ASSOCIATION OF ITS GENE PROMOTER WITH ACETYLATED HISTONE H3K9 BY CHROMATIN IMMUNOPRECIPITATION (CHIP) ASSAY IN RAT HEPATOCYTES IN VITRO, AND IN VIVO IN MOUSE AND RAT MODELS OF ACUTE BINGE, CHRONIC, AND CHRONIC FOLLOWED BY ACUTE BINGE ETHANOL ADMINISTRATION. PROTEIN EXPRESSION OF PNPLA3 WAS SIGNIFICANTLY INCREASED BY ALCOHOL IN ALL THREE MODELS USED. PNPLA3 MRNA ALSO INCREASED, ALBEIT TO A VARYING DEGREE. CHIP ASSAY USING H3ACK9 ANTIBODY SHOWED INCREASED ASSOCIATION WITH THE PROMOTER OF PNPLA3 IN HEPATOCYTES AND IN MOUSE LIVER. THIS WAS LESS EVIDENT IN RAT LIVERS IN VIVO EXCEPT UNDER CHRONIC TREATMENT. IT IS CONCLUDED FOR THE FIRST TIME THAT HISTONE ACETYLATION PLAYS A ROLE IN THE MODULATION OF PNPLA3 LEVELS IN THE LIVER EXPOSED TO BINGE ETHANOL BOTH IN VITRO AND IN VIVO. 2017 12 420 43 ANDROGEN-MEDIATED PERTURBATION OF THE HEPATIC CIRCADIAN SYSTEM THROUGH EPIGENETIC MODULATION PROMOTES NAFLD IN PCOS MICE. IN WOMEN, EXCESS ANDROGEN CAUSES POLYCYSTIC OVARY SYNDROME (PCOS), A COMMON FERTILITY DISORDER WITH COMORBID METABOLIC DYSFUNCTIONS INCLUDING DIABETES, OBESITY, AND NONALCOHOLIC FATTY LIVER DISEASE. USING A PCOS MOUSE MODEL, THIS STUDY SHOWS THAT CHRONIC HIGH ANDROGEN LEVELS CAUSE HEPATIC STEATOSIS WHILE HEPATOCYTE-SPECIFIC ANDROGEN RECEPTOR (AR)-KNOCKOUT RESCUES THIS PHENOTYPE. MOREOVER, THROUGH RNA-SEQUENCING AND METABOLOMIC STUDIES, WE HAVE IDENTIFIED KEY METABOLIC GENES AND PATHWAYS AFFECTED BY HYPERANDROGENISM. OUR STUDIES REVEAL THAT A LARGE NUMBER OF METABOLIC GENES ARE DIRECTLY REGULATED BY ANDROGENS THROUGH AR BINDING TO ANDROGEN RESPONSE ELEMENT SEQUENCES ON THE PROMOTER REGION OF THESE GENES. INTERESTINGLY, A NUMBER OF CIRCADIAN GENES ARE ALSO DIFFERENTIALLY REGULATED BY ANDROGENS. IN VIVO AND IN VITRO STUDIES USING A CIRCADIAN REPORTER [PERIOD2::LUCIFERASE (PER2::LUC)] MOUSE MODEL DEMONSTRATE THAT ANDROGENS CAN DIRECTLY DISRUPT THE HEPATIC TIMING SYSTEM, WHICH IS A KEY REGULATOR OF LIVER METABOLISM. CONSEQUENTLY, STUDIES SHOW THAT ANDROGENS DECREASE H3K27ME3, A GENE SILENCING MARK ON THE PROMOTER OF CORE CLOCK GENES, BY INHIBITING THE EXPRESSION OF HISTONE METHYLTRANSFERASE, EZH2, WHILE INDUCING THE EXPRESSION OF THE HISTONE DEMETHYLASE, JMJD3, WHICH IS RESPONSIBLE FOR ADDING AND REMOVING THE H3K27ME3 MARK, RESPECTIVELY. FINALLY, WE REPORT THAT UNDER HYPERANDROGENIC CONDITIONS, SOME OF THE SAME CIRCADIAN/METABOLIC GENES THAT ARE UPREGULATED IN THE MOUSE LIVER ARE ALSO ELEVATED IN NONHUMAN PRIMATE LIVERS. IN SUMMARY, THESE STUDIES NOT ONLY PROVIDE AN OVERALL UNDERSTANDING OF HOW HYPERANDROGENISM ASSOCIATED WITH PCOS AFFECTS LIVER GENE EXPRESSION AND METABOLISM BUT ALSO OFFER INSIGHT INTO THE UNDERLYING MECHANISMS LEADING TO HEPATIC STEATOSIS IN PCOS. 2022 13 2104 33 EPIGENETIC EVENTS IN LIVER CANCER RESULTING FROM ALCOHOLIC LIVER DISEASE. EPIGENETIC MECHANISMS PLAY AN EXTENSIVE ROLE IN THE DEVELOPMENT OF LIVER CANCER (I.E., HEPATOCELLULAR CARCINOMA [HCC]) ASSOCIATED WITH ALCOHOLIC LIVER DISEASE (ALD) AS WELL AS IN LIVER DISEASE ASSOCIATED WITH OTHER CONDITIONS. FOR EXAMPLE, EPIGENETIC MECHANISMS, SUCH AS CHANGES IN THE METHYLATION AND/OR ACETYLATION PATTERN OF CERTAIN DNA REGIONS OR OF THE HISTONE PROTEINS AROUND WHICH THE DNA IS WRAPPED, CONTRIBUTE TO THE REVERSION OF NORMAL LIVER CELLS INTO PROGENITOR AND STEM CELLS THAT CAN DEVELOP INTO HCC. CHRONIC EXPOSURE TO BEVERAGE ALCOHOL (I.E., ETHANOL) CAN INDUCE ALL OF THESE EPIGENETIC CHANGES. THUS, ETHANOL METABOLISM RESULTS IN THE FORMATION OF COMPOUNDS THAT CAN CAUSE CHANGES IN DNA METHYLATION AND INTERFERE WITH OTHER COMPONENTS OF THE NORMAL PROCESSES REGULATING DNA METHYLATION. ALCOHOL EXPOSURE ALSO CAN ALTER HISTONE ACETYLATION/DEACETYLATION AND METHYLATION PATTERNS THROUGH A VARIETY OF MECHANISMS AND SIGNALING PATHWAYS. ALCOHOL ALSO ACTS INDIRECTLY ON ANOTHER MOLECULE CALLED TOLL-LIKE RECEPTOR 4 (TLR4) THAT IS A KEY COMPONENT IN A CRUCIAL REGULATORY PATHWAY IN THE CELLS AND WHOSE DYSREGULATION IS INVOLVED IN THE DEVELOPMENT OF HCC. FINALLY, ALCOHOL USE REGULATES AN EPIGENETIC MECHANISM INVOLVING SMALL MOLECULES CALLED MIRNAS THAT CONTROL TRANSCRIPTIONAL EVENTS AND THE EXPRESSION OF GENES IMPORTANT TO ALD. 2013 14 4659 48 NEW APPROACHES FOR STUDYING ALCOHOLIC LIVER DISEASE. ALCOHOLIC LIVER DISEASE (ALD) IS MAJOR CAUSE OF CHRONIC LIVER INJURY WHICH RESULTS IN LIVER FIBROSIS AND CIRRHOSIS. ACCORDING TO THE SURVEILLANCE REPORT PUBLISHED BY THE NATIONAL INSTITUTE ON ALCOHOL ABUSE AND ALCOHOLISM, LIVER CIRRHOSIS IS THE 12TH LEADING CAUSE OF DEATH IN THE UNITED STATES WITH 48 % OF THESE DEATHS BEING ATTRIBUTED TO EXCESSIVE ALCOHOL CONSUMPTION. ALD INCLUDES A SPECTRUM OF DISORDERS FROM SIMPLE STEATOSIS TO STEATOHEPATITIS, FIBROSIS, AND HEPATOCELLULAR CARCINOMA. SEVERAL MECHANISMS PLAY A CRITICAL ROLE IN THE PATHOGENESIS OF ALD. THESE INCLUDE ETHANOL-INDUCED OXIDATIVE STRESS AND DEPLETION OF GLUTATHIONE, PATHOLOGICAL METHIONINE METABOLISM, INCREASED GUT PERMEABILITY AND RELEASE OF ENDOTOXINS INTO THE PORTAL BLOOD, RECRUITMENT AND ACTIVATION OF INFLAMMATORY CELLS INCLUDING BONE MARROW-DERIVED AND LIVER RESIDENT MACROPHAGES (KUPFFER CELLS). CHRONIC ALCOHOL CONSUMPTION RESULTS IN LIVER DAMAGE AND ACTIVATION OF HEPATIC STELLATE CELLS (HSCS) AND MYOFIBROBLASTS, LEADING TO LIVER FIBROSIS. HERE WE DISCUSS THE CURRENT VIEW ON FACTORS THAT ARE SPECIFIC FOR DIFFERENT STAGES OF ALD AND THOSE THAT REGULATE ITS PROGRESSION, INCLUDING CYTOKINES AND CHEMOKINES, ALCOHOL-RESPONSIVE INTRACELLULAR SIGNALING PATHWAYS, AND TRANSCRIPTIONAL FACTORS. WE ALSO REVIEW RECENT STUDIES DEMONSTRATING THAT ALCOHOL-MEDIATED CHANGES CAN BE REGULATED ON AN EPIGENETIC LEVEL, INCLUDING MICRORNAS. FINALLY, WE DISCUSS THE REVERSIBILITY OF LIVER FIBROSIS AND INACTIVATION OF HSCS AS A POTENTIAL STRATEGY FOR TREATING ALCOHOL-INDUCED LIVER DAMAGE. 2014 15 5074 36 PHYSIOLOGIC AND EPIGENETIC EFFECTS OF NUTRIENTS ON DISEASE PATHWAYS. BACKGROUND/OBJECTIVES: EPIGENETIC REGULATION BY NUTRIENTS CAN INFLUENCE THE DEVELOPMENT OF SPECIFIC DISEASES. THIS STUDY SOUGHT TO EXAMINE THE EFFECT OF INDIVIDUAL NUTRIENTS AND NUTRIENT FAMILIES IN THE CONTEXT OF PREVENTING CHRONIC METABOLIC DISEASES VIA EPIGENETIC REGULATION. THE INHIBITION OF LIPID ACCUMULATION AND INFLAMMATION BY NUTRIENTS INCLUDING PROTEINS, LIPIDS, VITAMINS, AND MINERALS WERE OBSERVED, AND HISTONE ACETYLATION BY HISTONE ACETYLTRANSFERASE (HAT) WAS MEASURED. CORRELATIVE ANALYSES WERE ALSO PERFORMED. MATERIALS/METHODS: NUTRIENTS WERE SELECTED ACCORDING TO INFORMATION FROM THE KOREAN MINISTRY OF FOOD AND DRUG SAFETY. SELECTED NUTRIENT FUNCTIONALITIES, INCLUDING THE ATTENUATION OF FATTY ACID-INDUCED LIPID ACCUMULATION AND LIPOPOLYSACCHARIDE-MEDIATED ACUTE INFLAMMATION WERE EVALUATED IN MOUSE MACROPHAGE RAW264.7 AND MOUSE HEPATOCYTE AML-12 CELLS. EFFECTS OF THE SELECTED NUTRIENTS ON IN VITRO HAT INHIBITION WERE ALSO EVALUATED. RESULTS: NITRIC OXIDE (NO) PRODUCTION CORRELATED WITH HAT ACTIVITY, WHICH WAS REGULATED BY THE AMINO ACIDS GROUP, SUGGESTING THAT AMINO ACIDS POTENTIALLY CONTRIBUTE TO THE ATTENUATION OF NO PRODUCTION VIA THE INHIBITION OF HAT ACTIVITY. UNSATURATED FATTY ACIDS TENDED TO ATTENUATE INFLAMMATION BY INHIBITING NO PRODUCTION, WHICH MAY BE ATTRIBUTABLE TO THE INHIBITION OF IN VITRO HAT ACTIVITY. IN CONTRAST TO WATER-SOLUBLE VITAMINS, THE LIPID-SOLUBLE VITAMINS SIGNIFICANTLY DECREASED NO PRODUCTION. WATER- AND LIPID-SOLUBLE VITAMINS BOTH EXHIBITED SIGNIFICANT INHIBITORY ACTIVITIES AGAINST HAT. IN ADDITION, CALCIUM AND MANGANESE SIGNIFICANTLY INHIBITED LIPID ACCUMULATION, NO PRODUCTION, AND HAT ACTIVITY. CONCLUSIONS: SEVERAL CANDIDATE NUTRIENTS AND THEIR FAMILY MEMBERS MAY HAVE ROLES IN THE PREVENTION OF DISEASES, INCLUDING HEPATIC STEATOSIS AND INFLAMMATION-RELATED DISEASES (I.E., NONALCOHOLIC STEATOHEPATITIS) VIA EPIGENETIC REGULATION. FURTHER STUDIES ARE WARRANTED TO DETERMINE WHICH SPECIFIC AMINO ACIDS, UNSATURATED FATTY ACIDS AND LIPID-SOLUBLE VITAMINS OR SPECIFIC MINERALS INFLUENCE THE DEVELOPMENT OF STEATOSIS AND INFLAMMATORY-RELATED DISEASES. 2023 16 4286 41 MICRORNA EXPRESSION ANALYSIS IN HIGH FAT DIET-INDUCED NAFLD-NASH-HCC PROGRESSION: STUDY ON C57BL/6J MICE. BACKGROUND: HEPATOCELLULAR CARCINOMA (HCC) IS THE MOST COMMON MALIGNANT TUMOR OF THE LIVER. NON-ALCOHOLIC FATTY LIVER DISEASE (NAFLD) IS A FREQUENT CHRONIC LIVER DISORDER IN DEVELOPED COUNTRIES. NAFLD CAN PROGRESS THROUGH THE MORE SEVERE NON ALCOHOLIC STEATOHEPATITIS (NASH), CIRRHOSIS AND, LASTLY, HCC. GENETIC AND EPIGENETIC ALTERATIONS OF CODING GENES AS WELL AS DEREGULATION OF MICRORNAS (MIRNAS) ACTIVITY PLAY A ROLE IN HCC DEVELOPMENT. IN THIS STUDY, THE C57BL/6J MOUSE MODEL WAS LONG TERM HIGH-FAT (HF) OR LOW-FAT (LF) DIET FED, IN ORDER TO ANALYZE MOLECULAR MECHANISMS RESPONSIBLE FOR THE HEPATIC DAMAGE PROGRESSION. METHODS: MICE WERE HF OR LF DIET FED FOR DIFFERENT TIME POINTS, THEN PLASMA AND HEPATIC TISSUES WERE COLLECTED. HISTOLOGICAL AND CLINICAL CHEMISTRY ASSAYS WERE PERFORMED TO ASSESS THE PROGRESSION OF LIVER DISEASE. MICRORNAS' DIFFERENTIAL EXPRESSION WAS EVALUATED ON POOLED RNAS FROM TISSUES, AND SOME MIRNAS SHOWING DYSREGULATION WERE FURTHER ANALYZED AT THE INDIVIDUAL LEVEL. RESULTS: CHOLESTEROL, LOW AND HIGH DENSITY LIPOPROTEINS, TRIGLYCERIDES AND ALANINE AMINOTRANSFERASE INCREASE WAS DETECTED IN HF MICE. GROSS ANATOMICAL EXAMINATION REVEALED HEPATOMEGALY IN HF LIVERS, AND HISTOLOGICAL ANALYSIS HIGHLIGHTED DIFFERENT DEGREES AND LEVELS OF STEATOSIS, INFLAMMATORY INFILTRATE AND FIBROSIS IN HF AND LF ANIMALS, DEMONSTRATING THE PROGRESSION FROM NAFLD THROUGH NASH. MACROSCOPIC NODULES, SHOWING TYPICAL NEOPLASTIC FEATURES, WERE OBSERVED IN 20% OF HF DIET FED MICE. FIFTEEN MIRNAS DIFFERENTIALLY EXPRESSED IN HF WITH RESPECT TO LF HEPATIC TISSUES DURING THE PROGRESSION OF LIVER DAMAGE, AND IN TUMORS WITH RESPECT TO HF NON TUMOR LIVER SPECIMENS WERE IDENTIFIED. AMONG THEM, MIR-340-5P, MIR-484, MIR-574-3P, MIR-720, WHOSE EXPRESSION WAS NEVER DESCRIBED IN NAFLD, NASH AND HCC TISSUES, AND MIR-125A-5P AND MIR-182, WHICH SHOWED EARLY AND SIGNIFICANT DYSREGULATION IN THE SEQUENTIAL HEPATIC DAMAGE PROCESS. CONCLUSIONS: IN THIS STUDY, FIFTEEN MICRORNAS WHICH WERE MODULATED IN HEPATIC TISSUES AND IN TUMORS DURING THE TRANSITION NAFLD-NASH-HCC ARE REPORTED. BESIDES SOME ALREADY DESCRIBED, NEW AND EARLY DYSREGULATED MIRNAS WERE IDENTIFIED. FUNCTIONAL ANALYSES ARE NEEDED TO VALIDATE THE RESULTS HERE OBTAINED, AND TO BETTER DEFINE THE ROLE OF THESE MOLECULES IN THE PROGRESSION OF THE HEPATIC DISEASE. 2016 17 3935 40 LIVER-SPECIFIC KNOCKDOWN OF CLASS IIA HDACS HAS LIMITED EFFICACY ON GLUCOSE METABOLISM BUT ENTAILS SEVERE ORGAN SIDE EFFECTS IN MICE. HISTONE DEACETYLASES (HDACS) ARE IMPORTANT REGULATORS OF EPIGENETIC GENE MODIFICATION THAT ARE INVOLVED IN THE TRANSCRIPTIONAL CONTROL OF METABOLISM. IN PARTICULAR CLASS IIA HDACS HAVE BEEN SHOWN TO AFFECT HEPATIC GLUCONEOGENESIS AND PREVIOUS APPROACHES REVEALED THAT THEIR INHIBITION REDUCES BLOOD GLUCOSE IN TYPE 2 DIABETIC MICE. IN THE PRESENT STUDY, WE AIMED TO EVALUATE THE POTENTIAL OF CLASS IIA HDAC INHIBITION AS A THERAPEUTIC OPPORTUNITY FOR THE TREATMENT +OF METABOLIC DISEASES. FOR THAT, SIRNAS SELECTIVELY TARGETING HDAC4, 5 AND 7 WERE SELECTED AND USED TO ACHIEVE A COMBINATORIAL KNOCKDOWN OF THESE THREE CLASS IIA HDAC ISOFORMS. SUBSEQUENTLY, THE HEPATOCELLULAR EFFECTS AS WELL AS THE IMPACT ON GLUCOSE AND LIPID METABOLISM WERE ANALYZED IN VITRO AND IN VIVO. THE TRIPLE KNOCKDOWN RESULTED IN A STATISTICALLY SIGNIFICANT DECREASE OF GLUCONEOGENIC GENE EXPRESSION IN MURINE AND HUMAN HEPATOCYTE CELL MODELS. A SIMILAR HDAC-INDUCED DOWNREGULATION OF HEPATIC GLUCONEOGENESIS GENES COULD BE ACHIEVED IN MICE USING A LIVER-SPECIFIC LIPID NANOPARTICLE SIRNA FORMULATION. HOWEVER, THE EFFICACY ON WHOLE BODY GLUCOSE METABOLISM ASSESSED BY PYRUVATE-TOLERANCE TESTS WERE ONLY LIMITED AND DID NOT OUTWEIGH THE SAFETY FINDINGS OBSERVED BY HISTOPATHOLOGICAL ANALYSIS IN SPLEEN AND KIDNEY. MECHANISTICALLY, AFFYMETRIX GENE EXPRESSION STUDIES PROVIDE EVIDENCE THAT CLASS IIA HDACS DIRECTLY TARGET OTHER KEY FACTORS BEYOND THE DESCRIBED FORKHEAD BOX (FOXP) TRANSCRIPTION REGULATORS, SUCH AS HEPATOCYTE NUCLEAR FACTOR 4 ALPHA (HNF4A). DOWNSTREAM OF THESE FACTORS SEVERAL ADDITIONAL PATHWAYS WERE REGULATED NOT MERELY INCLUDING GLUCOSE AND LIPID METABOLISM AND TRANSPORT. IN CONCLUSION, THE LIVER-DIRECTED COMBINATORIAL KNOCKDOWN OF HDAC4, 5 AND 7 BY THERAPEUTIC SIRNAS AFFECTED MULTIPLE PATHWAYS IN VITRO, LEADING IN VIVO TO THE DOWNREGULATION OF GENES INVOLVED IN GLUCONEOGENESIS. HOWEVER, THE EFFECTS ON GENE EXPRESSION LEVEL WERE NOT PARALLELED BY A SIGNIFICANT REDUCTION OF GLUCONEOGENESIS IN MICE. COMBINED KNOCKDOWN OF HDAC ISOFORMS WAS ASSOCIATED WITH SEVERE ADVERSE EFFECTS IN VIVO, CHALLENGING THIS APPROACH AS A TREATMENT OPTION FOR CHRONIC METABOLIC DISORDERS LIKE TYPE 2 DIABETES. 2020 18 3241 37 HEPATIC MICRORNA MODULATION MIGHT BE AN EARLY EVENT TO NON-ALCOHOLIC FATTY LIVER DISEASE DEVELOPMENT DRIVEN BY HIGH-FAT DIET IN MALE MICE. INTRODUCTION: METABOLIC ALTERATIONS CAUSED BY AN IMBALANCE OF MACRONUTRIENT CONSUMPTION ARE OFTEN RELATED TO THE MODULATION OF MICRORNAS (MIRNAS), WHICH COULD ALTER MRNAS EXPRESSION PROFILE AND ACCELERATE THE DEVELOPMENT OF NON-ALCOHOLIC FATTY LIVER DISEASE (NAFLD). AIMS: THIS STUDY AIMED TO INVESTIGATE THE CONTRIBUTION OF MIRNAS IN MODULATING EARLY STAGES OF NAFLD IN MICE SUBMITTED TO A HIGH-FAT DIET (HFD). METHODS AND RESULTS: MALE SWISS MICE, FED EITHER A CONTROL DIET OR AN HFD FOR 1, 3, 7, 15, 30, 56 DAYS, WERE ASSESSED FOR METABOLIC ALTERATIONS, GENE EXPRESSION AND NAFLD MARKERS. A HEPATOCYTE CELL LINE WAS USED TO INVESTIGATE THE EFFECTS OF MIR-370 MODULATION ON ENZYMES INVOLVED IN BETA-OXIDATION. BODY WEIGHT AND ADIPOSITY WERE HIGHER AFTER 7 DAYS OF HFD. FASTING GLUCOSE AND INSULIN INCREASED AFTER 3 AND 7 DAYS OF HFD, RESPECTIVELY. WHILE HEPATIC LIPID CONTENT INCREASED FROM THE FIRST DAY ON, HEPATIC GLYCOGEN HAD A DECREASE AFTER 3 DAYS OF HFD CONSUMPTION. MIR-370 AND LET-7 EXPRESSION INCREASED WITH ACUTE AND CHRONIC EXPOSURE TO HFD, ACCOMPANIED BY CARNITINE PALMITOYLTRANSFERASE 1A (CPT1A), ACYL-COA DEHYDROGENASE VERY LONG CHAIN (ACADVL) AND PROTEIN KINASE AMP-ACTIVATED CATALYTIC SUBUNIT 2 (PRKAA2) DOWNREGULATION, WHILE DECREASED MIR-122 EXPRESSION WAS ACCOMPANIED BY 1-ACYLGLYCEROL-3-PHOSPHATE-O-ACYLTRANSFERASE (AGPAT) UPREGULATION AFTER 56 DAYS OF HFD CONSUMPTION, SOME OF THEM CONFIRMED BY IN VITRO EXPERIMENTS. DESPITE FLUCTUATIONS IN TNFA AND IL6 MRNA LEVELS, MOLECULAR MODULATION WAS CONSISTENT WITH HEPATIC TG AND NAFLD DEVELOPMENT. CONCLUSION: HEPATIC MIR-370-122-LET7 MIRNA MODULATION COULD BE THE FIRST INSULT TO NAFLD DEVELOPMENT, PRECEDING CHANGES IN GLYCEMIC HOMEOSTASIS AND ADIPOSITY. 2022 19 2002 29 EPIGENETIC AND POST-TRANSCRIPTIONAL REPRESSION SUPPORT METABOLIC SUPPRESSION IN CHRONICALLY HYPOXIC GOLDFISH. GOLDFISH ENTER A HYPOMETABOLIC STATE TO SURVIVE CHRONIC HYPOXIA. WE RECENTLY DESCRIBED TISSUE-SPECIFIC CONTRIBUTIONS OF MEMBRANE LIPID COMPOSITION REMODELING AND MITOCHONDRIAL FUNCTION TO METABOLIC SUPPRESSION ACROSS DIFFERENT GOLDFISH TISSUES. HOWEVER, THE MOLECULAR AND ESPECIALLY EPIGENETIC FOUNDATIONS OF HYPOXIA TOLERANCE IN GOLDFISH UNDER METABOLIC SUPPRESSION ARE NOT WELL UNDERSTOOD. HERE WE SHOW THAT COMPONENTS OF THE MOLECULAR OXYGEN-SENSING MACHINERY ARE ROBUSTLY ACTIVATED ACROSS TISSUES IRRESPECTIVE OF HYPOXIA DURATION. INDUCTION OF GENE EXPRESSION OF ENZYMES INVOLVED IN DNA METHYLATION TURNOVER AND MICRORNA BIOGENESIS SUGGEST A ROLE FOR EPIGENETIC TRANSCRIPTIONAL AND POST-TRANSCRIPTIONAL SUPPRESSION OF GENE EXPRESSION IN THE HYPOXIA-ACCLIMATED BRAIN. CONVERSELY, MECHANISTIC TARGET OF RAPAMYCIN-DEPENDENT TRANSLATIONAL MACHINERY ACTIVITY IS NOT REDUCED IN LIVER AND WHITE MUSCLE, SUGGESTING THIS PATHWAY DOES NOT CONTRIBUTE TO LOWERING CELLULAR ENERGY EXPENDITURE. FINALLY, MOLECULAR EVIDENCE SUPPORTS PREVIOUSLY REPORTED CHRONIC HYPOXIA-DEPENDENT CHANGES IN MEMBRANE CHOLESTEROL, LIPID METABOLISM AND MITOCHONDRIAL FUNCTION VIA CHANGES IN TRANSCRIPTS INVOLVED IN CHOLESTEROL BIOSYNTHESIS, BETA-OXIDATION, AND MITOCHONDRIAL FUSION IN MULTIPLE TISSUES. OVERALL, THIS STUDY SHOWS THAT CHRONIC HYPOXIA ROBUSTLY INDUCES EXPRESSION OF OXYGEN-SENSING MACHINERY ACROSS TISSUES, INDUCES REPRESSIVE TRANSCRIPTIONAL AND POST-TRANSCRIPTIONAL EPIGENETIC MARKS ESPECIALLY IN THE CHRONIC HYPOXIA-ACCLIMATED BRAIN AND SUPPORTS A ROLE FOR MEMBRANE REMODELING AND MITOCHONDRIAL FUNCTION AND DYNAMICS IN PROMOTING METABOLIC SUPPRESSION. 2022 20 3527 31 IL-6 ENHANCES THE NUCLEAR TRANSLOCATION OF DNA CYTOSINE-5-METHYLTRANSFERASE 1 (DNMT1) VIA PHOSPHORYLATION OF THE NUCLEAR LOCALIZATION SEQUENCE BY THE AKT KINASE. THE EPIGENETIC PROGRAMMING OF GENOMIC DNA IS ACCOMPLISHED, IN PART, BY SEVERAL DNA CYTOSINE-5-METHYLTRANSFERASES THAT ACT BY COVALENTLY MODIFYING CYTOSINES WITH THE ADDITION OF A METHYL GROUP. THIS COVALENT MODIFICATION IS MAINTAINED BY THE DNA CYTOSINE-5-METHYLTRANSFERASE-1 ENZYME (DNMT1), WHICH IS CAPABLE OF ACTING IN CONCERT WITH OTHER SIMILAR ENZYMES TO SILENCE IMPORTANT TUMOR SUPPRESSOR GENES. IL-6 IS A MULTIFUNCTIONAL MEDIATOR OF INFLAMMATION, ACTING THROUGH SEVERAL MAJOR SIGNALING CASCADES, INCLUDING THE PHOSPHATIDYLINOSITOL-3-KINASE PATHWAY (PI-3-K), WHICH ACTIVATES PROTEIN KINASE B (AKT/PKB) DOWNSTREAM. HERE, WE SHOW THAT THE SUBCELLULAR LOCALIZATION OF DNMT1 CAN BE ALTERED BY THE ADDITION OF IL-6, INCREASING THE RATE OF NUCLEAR TRANSLOCATION OF THE ENZYME FROM THE CYTOSOLIC COMPARTMENT. THE MECHANISM OF NUCLEAR TRANSLOCATION OF DNMT1 IS GREATLY ENHANCED BY PHOSPHORYLATION OF THE DNMT1 NUCLEAR LOCALIZATION SIGNAL (NLS) BY PKB/AKT KINASE. MUTAGENIC ALTERATION OF THE TWO AKT TARGET AMINO ACIDS WITHIN THE NLS RESULTS IN A MAJOR LOSS OF DNMT1 NUCLEAR TRANSLOCATION, WHILE THE CREATION OF A "PHOSPHO-MIMIC" AMINO ACID (MUTATION TO ACIDIC RESIDUES) RESTORES THIS COMPARTMENTATION ABILITY. THESE OBSERVATIONS SUGGEST AN INTERESTING HYPOTHESIS REGARDING HOW MEDIATORS OF CHRONIC INFLAMMATION MAY DISTURB THE DELICATE BALANCE OF CELLULAR COMPARTMENTALIZATION OF IMPORTANT PROTEINS, AND REVEALS A POTENTIAL MECHANISM FOR THE INDUCTION OR ENHANCEMENT OF TUMOR GROWTH VIA ALTERATION OF THE COMPONENTS INVOLVED IN THE EPIGENETIC PROGRAMMING OF A CELL. 2007