1 3175 115 H2AX PHOSPHORYLATION REGULATED BY P38 IS INVOLVED IN BIM EXPRESSION AND APOPTOSIS IN CHRONIC MYELOGENOUS LEUKEMIA CELLS INDUCED BY IMATINIB. INCREASING EVIDENCE SUGGESTS THAT HISTONE H2AX PLAYS A CRITICAL ROLE IN REGULATION OF TUMOR CELL APOPTOSIS AND ACTS AS A NOVEL HUMAN TUMOR SUPPRESSOR PROTEIN. HOWEVER, THE ACTION OF H2AX IN CHRONIC MYELOGENOUS LEUKEMIA (CML) CELLS IS UNKNOWN. THE DETAILED MECHANISM AND EPIGENETIC REGULATION BY H2AX REMAIN ELUSIVE IN CANCER CELLS. HERE, WE REPORT THAT H2AX WAS INVOLVED IN APOPTOSIS OF CML CELLS. OVEREXPRESSION OF H2AX INCREASED APOPTOTIC SENSITIVITY OF CML CELLS (K562) INDUCED BY IMATINIB. HOWEVER, OVEREXPRESSION OF SER139-MUTATED H2AX (BLOCKING PHOSPHORYLATION) DECREASED SENSITIVITY OF K562 CELLS TO APOPTOSIS. SIMILARLY, KNOCKDOWN OF H2AX MADE K562 CELLS RESISTANT TO APOPTOTIC INDUCTION. THESE RESULTS REVEALED THAT THE FUNCTION OF H2AX INVOLVED IN APOPTOSIS IS STRICTLY RELATED TO ITS PHOSPHORYLATION (SER139). OUR DATA FURTHER INDICATED THAT IMATINIB MAY STIMULATE MITOGEN-ACTIVATED PROTEIN KINASE (MAPK) FAMILY MEMBER P38, AND H2AX PHOSPHORYLATION FOLLOWED A SIMILAR TIME COURSE, SUGGESTING A PARALLEL RESPONSE. H2AX PHOSPHORYLATION CAN BE BLOCKED BY P38 SIRNA OR ITS INHIBITOR. THESE DATA DEMONSTRATED THAT H2AX PHOSPHORYLATION WAS REGULATED BY P38 MAPK PATHWAY IN K562 CELLS. HOWEVER, THE P38 MAPK DOWNSTREAM, MITOGEN- AND STRESS-ACTIVATED PROTEIN KINASE-1 AND -2, WHICH PHOSPHORYLATED HISTONE H3, WERE NOT REQUIRED FOR H2AX PHOSPHORYLATION DURING APOPTOSIS. FINALLY, WE PROVIDED EPIGENETIC EVIDENCE THAT H2AX PHOSPHORYLATION REGULATED APOPTOSIS-RELATED GENE BIM EXPRESSION. BLOCKING OF H2AX PHOSPHORYLATION INHIBITED BIM GENE EXPRESSION. TAKEN TOGETHER, THESE DATA DEMONSTRATED THAT H2AX PHOSPHORYLATION REGULATED BY P38 IS INVOLVED IN BIM EXPRESSION AND APOPTOSIS IN CML CELLS INDUCED BY IMATINIB. 2014 2 799 28 CELLULAR SIGNALING AND POTENTIAL NEW TREATMENT TARGETS IN DIABETIC RETINOPATHY. DYSFUNCTION AND DEATH OF MICROVASCULAR CELLS AND IMBALANCE BETWEEN THE PRODUCTION AND THE DEGRADATION OF EXTRACELLULAR MATRIX (ECM) PROTEINS ARE A CHARACTERISTIC FEATURE OF DIABETIC RETINOPATHY (DR). GLUCOSE-INDUCED BIOCHEMICAL ALTERATIONS IN THE VASCULAR ENDOTHELIAL CELLS MAY ACTIVATE A CASCADE OF SIGNALING PATHWAYS LEADING TO INCREASED PRODUCTION OF ECM PROTEINS AND CELLULAR DYSFUNCTION/DEATH. CHRONIC DIABETES LEADS TO THE ACTIVATION OF A NUMBER OF SIGNALING PROTEINS INCLUDING PROTEIN KINASE C, PROTEIN KINASE B, AND MITOGEN-ACTIVATED PROTEIN KINASES. THESE SIGNALING CASCADES ARE ACTIVATED IN RESPONSE TO HYPERGLYCEMIA-INDUCED OXIDATIVE STRESS, POLYOL PATHWAY, AND ADVANCED GLYCATION END PRODUCT FORMATION AMONG OTHERS. THE ABERRANT SIGNALING PATHWAYS ULTIMATELY LEAD TO ACTIVATION OF TRANSCRIPTION FACTORS SUCH AS NUCLEAR FACTOR-KAPPAB AND ACTIVATING PROTEIN-1. THE ACTIVITY OF THESE TRANSCRIPTION FACTORS IS ALSO REGULATED BY EPIGENETIC MECHANISMS THROUGH TRANSCRIPTIONAL COACTIVATOR P300. THESE COMPLEX SIGNALING PATHWAYS MAY BE INVOLVED IN GLUCOSE-INDUCED ALTERATIONS OF ENDOTHELIAL CELL PHENOTYPE LEADING TO THE PRODUCTION OF INCREASED ECM PROTEINS AND VASOACTIVE EFFECTOR MOLECULES CAUSING FUNCTIONAL AND STRUCTURAL CHANGES IN THE MICROVASCULATURE. UNDERSTANDING OF SUCH MECHANISTIC PATHWAYS WILL HELP TO DEVELOP FUTURE ADJUVANT THERAPIES FOR DIABETIC RETINOPATHY. 2007 3 4902 25 OXIDATIVE-STRESS-INDUCED EPIGENETIC CHANGES IN CHRONIC DIABETIC COMPLICATIONS. OXIDATIVE STRESS PLAYS AN IMPORTANT ROLE IN THE DEVELOPMENT AND PROGRESSION OF CHRONIC DIABETIC COMPLICATIONS. DIABETES CAUSES MITOCHONDRIAL SUPEROXIDE OVERPRODUCTION IN THE ENDOTHELIAL CELLS OF BOTH LARGE AND SMALL VESSELS. THIS INCREASED SUPEROXIDE PRODUCTION CAUSES THE ACTIVATION OF SEVERAL SIGNAL PATHWAYS INVOLVED IN THE PATHOGENESIS OF CHRONIC COMPLICATIONS. IN PARTICULAR, ENDOTHELIAL CELLS ARE MAJOR TARGETS OF GLUCOSE-INDUCED OXIDATIVE DAMAGE IN THE TARGET ORGANS. OXIDATIVE STRESS ACTIVATES CELLULAR SIGNALING PATHWAYS AND TRANSCRIPTION FACTORS IN ENDOTHELIAL CELLS INCLUDING PROTEIN KINASE C (PKC), C-JUN-N-TERMINAL KINASE (JNK), P38 MITOGEN-ACTIVATED PROTEIN KINASE (MAPK), FORKHEAD BOX O (FOXO), AND NUCLEAR FACTOR KAPPA-B (NF-KAPPAB). OXIDATIVE STRESS ALSO CAUSES DNA DAMAGE AND ACTIVATES DNA NUCLEOTIDE EXCISION REPAIR ENZYMES INCLUDING THE EXCISION REPAIR CROSS COMPLIMENTING 1(ERCC1), ERCC4, AND POLY(ADP-RIBOSE) POLYMERASE (PARP). AUGMENTED PRODUCTION OF HISTONE ACETYLTRANSFERASE P300, AND ALTERATIONS OF HISTONE DEACETYLASES, INCLUDING CLASS III DEACETYLASES SIRTUINS, ARE ALSO INVOLVED IN THIS PROCESS. RECENT RESEARCH HAS FOUND THAT SMALL NONCODING RNAS, LIKE MICRORNA, ARE A NEW KIND OF REGULATOR ASSOCIATED WITH CHRONIC DIABETIC COMPLICATIONS. THERE ARE EXTENSIVE AND COMPLICATED INTERACTIONS AND AMONG THESE MOLECULES. THE PURPOSE OF THIS REVIEW IS TO DEMONSTRATE THE ROLE OF OXIDATIVE STRESS IN THE DEVELOPMENT OF DIABETIC COMPLICATIONS IN RELATION TO EPIGENETIC CHANGES SUCH AS ACETYLATION AND MICRORNA ALTERATIONS. 2013 4 4105 20 MECHANISM AND THERAPEUTIC TARGETS OF C-JUN-N-TERMINAL KINASES ACTIVATION IN NONALCOHOLIC FATTY LIVER DISEASE. NON-ALCOHOLIC FATTY LIVER (NAFL) IS THE MOST COMMON CHRONIC LIVER DISEASE. ACTIVATION OF MITOGEN-ACTIVATED KINASES (MAPK) CASCADE, WHICH LEADS TO C-JUN N-TERMINAL KINASE (JNK) ACTIVATION OCCURS IN THE LIVER IN RESPONSE TO THE NUTRITIONAL AND METABOLIC STRESS. THE ABERRANT ACTIVATION OF MAPKS, ESPECIALLY C-JUN-N-TERMINAL KINASES (JNKS), LEADS TO UNWANTED GENETIC AND EPI-GENETIC MODIFICATIONS IN ADDITION TO THE METABOLIC STRESS ADAPTATION IN HEPATOCYTES. A MECHANISM OF SUSTAINED P-JNK ACTIVATION WAS IDENTIFIED IN ACUTE AND CHRONIC LIVER DISEASES, SUGGESTING AN IMPORTANT ROLE OF ABERRANT JNK ACTIVATION IN NASH. THEREFORE, MODULATION OF JNK ACTIVATION, RATHER THAN TARGETING JNK PROTEIN LEVELS, IS A PLAUSIBLE THERAPEUTIC APPLICATION FOR THE TREATMENT OF CHRONIC LIVER DISEASE. 2022 5 5944 38 TARGETING SMALL MOLECULE TYROSINE KINASES BY POLYPHENOLS: NEW MOVE TOWARDS ANTI-TUMOR DRUG DISCOVERY. BACKGROUND: CANCER IS A COMPLEX DISEASE INVOLVING GENETIC AND EPIGENETIC ALTERATION THAT ALLOWS CELLS TO ESCAPE NORMAL HOMEOSTASIS. KINASES PLAY A CRUCIAL ROLE IN SIGNALING PATHWAYS THAT REGULATE CELL FUNCTIONS. DEREGULATION OF KINASES LEADS TO A VARIETY OF PATHOLOGICAL CHANGES, ACTIVATING CANCER CELL PROLIFERATION AND METASTASES. THE MOLECULAR MECHANISM OF CANCER IS COMPLEX AND THE DYSREGULATION OF TYROSINE KINASES LIKE ANAPLASTIC LYMPHOMA KINASE (ALK), BCR-ABL (FUSION GENE FOUND IN PATIENT WITH CHRONIC MYELOGENOUS LEUKEMIA (CML), JAK (JANUS ACTIVATED KINASE), SRC FAMILY KINASES (SFKS), ALK (ANAPLASTIC LYMPHOMA KINASE), C-MET (MESENCHYMAL- EPITHELIAL TRANSITION), EGFR (EPIDERMAL GROWTH FACTOR RECEPTOR), PDGFR (PLATELET-DERIVED GROWTH FACTOR RECEPTOR), RET (REARRANGED DURING TRANSFECTION) AND VEGFR (VASCULAR ENDOTHELIAL GROWTH FACTOR RECEPTOR) PLAYS MAJOR ROLE IN THE PROCESS OF CARCINOGENESIS. RECENTLY, KINASE INHIBITORS HAVE OVERCOME MANY PROBLEMS OF TRADITIONAL CANCER CHEMOTHERAPY AS THEY EFFECTIVELY SEPARATE OUT NORMAL, NON-CANCER CELLS AS WELL AS RAPIDLY MULTIPLYING CANCER CELLS. METHODS: ELECTRONIC DATABASES WERE SEARCHED TO EXPLORE THE SMALL MOLECULE TYROSINE KINASES BY POLYPHENOLS WITH THE HELP OF DOCKING STUDY (GLIDE-7.6 PROGRAM INTERFACED WITH MAESTRO-V11.3 OF SCHRODINGER 2017) TO SHOW THE BINDING ENERGIES OF POLYPHENOLS INHIBITOR WITH DIFFERENT TYROSINE KINASES IN ORDER TO DIFFERENTIATE BETWEEN THE TARGETS. RESULTS: FROM THE LITERATURE SURVEY, IT WAS OBSERVED THAT THE NUMBER OF POLYPHENOLS DERIVED FROM NATURAL SOURCES ALTERS THE EXPRESSION AND SIGNALING CASCADE OF TYROSINE KINASE IN VARIOUS TUMOR MODELS. THEREFORE, THE DEVELOPMENT OF POLYPHENOLS AS A TYROSINE KINASE INHIBITOR AGAINST TARGETED PROTEINS IS REGARDED AS AN UPCOMING TREND FOR CHEMOPREVENTION. CONCLUSION: IN THIS REVIEW, WE HAVE DISCUSSED THE ROLE OF POLYPHENOLS AS CHEMORECEPTIVE WHICH WILL HELP IN FUTURE FOR THE DEVELOPMENT AND DISCOVERY OF NOVEL SEMISYNTHETIC ANTICANCER AGENTS COUPLED WITH POLYPHENOLS. 2020 6 6910 20 [TRANSFORMING GROWTH FACTOR-BETA AND RENAL FIBROSIS]. TRANSFORMING GROWTH FACTOR-BETA (TGF-BETA) IS A DRIVING FORCE OF RENAL FIBROSIS, WHICH MAY LEAD TO CHRONIC KIDNEY DISEASES AND EVEN END STAGE RENAL DISEASES. BY ACTIVATING CANONICAL AND NON-CANONICAL SIGNALING PATHWAYS, TGF-BETA PROMOTES THE SYNTHESIS OF EXTRACELLULAR MATRIX WHILE PREVENTING THEIR DEGRADATION. IN THE INJURED KIDNEY, TGF-BETA INDUCES APOPTOSIS, PROLIFERATION AND FIBROTIC RESPONSE OF RENAL CELLS INCLUDING EPITHELIAL CELLS, ENDOTHELIAL CELLS, PODOCYTES, FIBROBLASTS, PERICYTES AND MACROPHAGES, AND IT ALSO PROMOTES TRANSDIFFERENTIATION, ACTIVATION AND PROLIFERATION OF MYOFIBROBLASTS. ADDITIONALLY, TGF-BETA EXERTS PROFIBROTIC EFFECTS BY INTERPLAYING WITH OTHER SIGNALING PATHWAYS LIKE BMP-7, WNT/BETA-CATENIN AND MAP KINASE. SMAD3 IS THE CENTRAL PATHOLOGICAL GENE IN RENAL FIBROSIS, AND EPIGENETIC REGULATION OF TGF-BETA/SMAD3 IS A HOT TOPIC IN KIDNEY FIELD. ALTHOUGH DIRECT TARGETING TGF-BETA MAY CAUSE SIDE EFFECTS INCLUDING TUMORIGENESIS AND IMMUNE DISEASES, THE THERAPEUTIC STRATEGIES TARGETING THE BALANCE OF DOWNSTREAM SMAD3 AND SMAD7 MAY PREVENT OR DELAY THE PROGRESSION OF FIBROTIC KIDNEY DISEASE. 2018 7 1036 27 CLASS I HISTONE DEACETYLASES REGULATE P53/NF-KAPPAB CROSSTALK IN CANCER CELLS. THE TRANSCRIPTION FACTORS NF-KAPPAB AND P53 AS WELL AS THEIR CROSSTALK DETERMINE THE FATE OF TUMOR CELLS UPON THERAPEUTIC INTERVENTIONS. REPLICATIVE STRESS AND CYTOKINES PROMOTE SIGNALING CASCADES THAT LEAD TO THE CO-REGULATION OF P53 AND NF-KAPPAB. CONSEQUENTLY, NUCLEAR P53/NF-KAPPAB SIGNALING COMPLEXES ACTIVATE NF-KAPPAB-DEPENDENT SURVIVAL GENES. THE 18 HISTONE DEACETYLASES (HDACS) ARE EPIGENETIC MODULATORS THAT FALL INTO FOUR CLASSES (I-IV). INHIBITORS OF HISTONE DEACETYLASES (HDACI) BECOME INCREASINGLY APPRECIATED AS ANTI-CANCER AGENTS. BASED ON THEIR EFFECTS ON P53 AND NF-KAPPAB, WE ADDRESSED WHETHER CLINICALLY RELEVANT HDACI AFFECT THE NF-KAPPAB/P53 CROSSTALK. THE CHEMOTHERAPEUTICS HYDROXYUREA, ETOPOSIDE, AND FLUDARABINE HALT CELL CYCLE PROGRESSION, INDUCE DNA DAMAGE, AND LEAD TO DNA FRAGMENTATION. THESE AGENTS CO-INDUCE P53 AND NF-KAPPAB-DEPENDENT GENE EXPRESSION IN CELL LINES FROM BREAST AND COLON CANCER AND IN PRIMARY CHRONIC LYMPHATIC LEUKEMIA (CLL) CELLS. USING SPECIFIC HDACI, WE FIND THAT THE CLASS I SUBGROUP OF HDACS, BUT NOT THE CLASS IIB DEACETYLASE HDAC6, ARE REQUIRED FOR THE HYDROXYUREA-INDUCED CROSSTALK BETWEEN P53 AND NF-KAPPAB. HDACI DECREASE THE BASAL AND STRESS-INDUCED EXPRESSION OF P53 AND BLOCK NF-KAPPAB-REGULATED GENE EXPRESSION. WE FURTHER SHOW THAT CLASS I HDACI INDUCE SENESCENCE IN PANCREATIC CANCER CELLS WITH MUTANT P53. 2017 8 616 32 BIOACTIVE COMPOUNDS IN OXIDATIVE STRESS-MEDIATED DISEASES: TARGETING THE NRF2/ARE SIGNALING PATHWAY AND EPIGENETIC REGULATION. OXIDATIVE STRESS IS A PATHOLOGICAL CONDITION OCCURRING DUE TO AN IMBALANCE BETWEEN THE OXIDANTS AND ANTIOXIDANT DEFENSE SYSTEMS IN THE BODY. NUCLEAR FACTOR E2-RELATED FACTOR 2 (NRF2), ENCODED BY THE GENE NFE2L2, IS THE MASTER REGULATOR OF PHASE II ANTIOXIDANT ENZYMES THAT PROTECT AGAINST OXIDATIVE STRESS AND INFLAMMATION. NRF2/ARE SIGNALING HAS BEEN CONSIDERED AS A PROMISING TARGET AGAINST OXIDATIVE STRESS-MEDIATED DISEASES LIKE DIABETES, FIBROSIS, NEUROTOXICITY, AND CANCER. THE CONSUMPTION OF DIETARY PHYTOCHEMICALS ACTS AS AN EFFECTIVE MODULATOR OF NRF2/ARE IN VARIOUS ACUTE AND CHRONIC DISEASES. IN THE PRESENT REVIEW, WE DISCUSSED THE ROLE OF NRF2 IN DIABETES, ALZHEIMER'S DISEASE (AD), PARKINSON'S DISEASE (PD), CANCER, AND ATHEROSCLEROSIS. ADDITIONALLY, WE DISCUSSED THE PHYTOCHEMICALS LIKE CURCUMIN, QUERCETIN, RESVERATROL, EPIGALLOCATECHIN GALLATE, APIGENIN, SULFORAPHANE, AND URSOLIC ACID THAT HAVE EFFECTIVELY MODIFIED NRF2 SIGNALING AND PREVENTED VARIOUS DISEASES IN BOTH IN VITRO AND IN VIVO MODELS. BASED ON THE LITERATURE, IT IS CLEAR THAT DIETARY PHYTOCHEMICALS CAN PREVENT DISEASES BY (1) BLOCKING OXIDATIVE STRESS-INHIBITING INFLAMMATORY MEDIATORS THROUGH INHIBITING KEAP1 OR ACTIVATING NRF2 EXPRESSION AND ITS DOWNSTREAM TARGETS IN THE NUCLEUS, INCLUDING HO-1, SOD, AND CAT; (2) REGULATING NRF2 SIGNALING BY VARIOUS KINASES LIKE GSK3BETA, PI3/AKT, AND MAPK; AND (3) MODIFYING EPIGENETIC MODULATION, SUCH AS METHYLATION, AT THE NRF2 PROMOTER REGION; HOWEVER, FURTHER INVESTIGATION INTO OTHER UPSTREAM SIGNALING MOLECULES LIKE NRF2 AND THE EFFECT OF PHYTOCHEMICALS ON THEM STILL NEED TO BE INVESTIGATED IN THE NEAR FUTURE. 2021 9 791 26 CELLULAR AND MOLECULAR NETWORKS IN CHRONIC MYELOID LEUKEMIA: THE LEUKEMIC STEM, PROGENITOR AND STROMAL CELL INTERPLAY. THE USE OF IMATINIB, SECOND AND THIRD GENERATION ABL TYROSINE KINASE INHIBITORS (TKI) (I.E. DASATINIB, NILOTINIB, BOSUTINIB AND PONATINIB) MADE CML A CLINICALLY MANAGEABLE AND, IN A SMALL PERCENTAGE OF CASES, A CURED DISEASE. TKI THERAPY ALSO TURNED CML BLASTIC TRANSFORMATION INTO A RARE EVENT; HOWEVER, DISEASE PROGRESSION STILL OCCURS IN THOSE PATIENTS WHO ARE REFRACTORY, NOT COMPLIANT WITH TKI THERAPY OR DEVELOP RESISTANCE TO MULTIPLE TKIS. IN THE PAST FEW YEARS, IT BECAME CLEAR THAT THE BCRABL1 ONCOGENE DOES NOT OPERATE ALONE TO DRIVE DISEASE EMERGENCE, MAINTENANCE AND PROGRESSION. INDEED, IT SEEMS THAT BONE MARROW (BM) MICROENVIRONMENT-GENERATED SIGNALS AND CELL AUTONOMOUS BCRABL1 KINASE-INDEPENDENT GENETIC AND EPIGENETIC ALTERATIONS ALL CONTRIBUTE TO: I. PERSISTENCE OF A QUIESCENT LEUKEMIC STEM CELL (LSC) RESERVOIR, II. INNATE OR ACQUIRED RESISTANCE TO TKIS, AND III. PROGRESSION INTO THE FATAL BLAST CRISIS STAGE. HEREIN, WE REVIEW THE INTRICATE LEUKEMIC NETWORK IN WHICH ABERRANT, BUT FINELY TUNED, SURVIVAL, MITOGENIC AND SELF-RENEWAL SIGNALS ARE GENERATED BY LEUKEMIC PROGENITORS, STROMAL CELLS, IMMUNE CELLS AND METABOLIC MICROENVIRONMENTAL CONDITIONS (E.G. HYPOXIA) TO PROMOTE LSC MAINTENANCE AND BLASTIC TRANSFORMATION. 2017 10 5795 33 STAT3 INDUCTION OF MIR-146B FORMS A FEEDBACK LOOP TO INHIBIT THE NF-KAPPAB TO IL-6 SIGNALING AXIS AND STAT3-DRIVEN CANCER PHENOTYPES. INTERLEUKIN-6 (IL-6)-MEDIATED ACTIVATION OF SIGNAL TRANSDUCER AND ACTIVATOR OF TRANSCRIPTION 3 (STAT3) IS A MECHANISM BY WHICH CHRONIC INFLAMMATION CAN CONTRIBUTE TO CANCER AND IS A COMMON ONCOGENIC EVENT. WE DISCOVERED A PATHWAY, THE LOSS OF WHICH IS ASSOCIATED WITH PERSISTENT STAT3 ACTIVATION IN HUMAN CANCER. WE FOUND THAT THE GENE ENCODING THE TUMOR SUPPRESSOR MICRORNA MIR-146B IS A DIRECT STAT3 TARGET GENE, AND ITS EXPRESSION WAS INCREASED IN NORMAL BREAST EPITHELIAL CELLS BUT DECREASED IN TUMOR CELLS. METHYLATION OF THE MIR-146B PROMOTER, WHICH INHIBITED STAT3-MEDIATED INDUCTION OF EXPRESSION, WAS INCREASED IN PRIMARY BREAST CANCERS. MOREOVER, WE FOUND THAT MIR-146B INHIBITED NUCLEAR FACTOR KAPPAB (NF-KAPPAB)-DEPENDENT PRODUCTION OF IL-6, SUBSEQUENT STAT3 ACTIVATION, AND IL-6/STAT3-DRIVEN MIGRATION AND INVASION IN BREAST CANCER CELLS, THEREBY ESTABLISHING A NEGATIVE FEEDBACK LOOP. IN ADDITION, HIGHER EXPRESSION OF MIR-146B WAS POSITIVELY CORRELATED WITH PATIENT SURVIVAL IN BREAST CANCER SUBTYPES WITH INCREASED IL6 EXPRESSION AND STAT3 PHOSPHORYLATION. OUR RESULTS IDENTIFY AN EPIGENETIC MECHANISM OF CROSSTALK BETWEEN STAT3 AND NF-KAPPAB RELEVANT TO CONSTITUTIVE STAT3 ACTIVATION IN MALIGNANCY AND THE ROLE OF INFLAMMATION IN ONCOGENESIS. 2014 11 598 35 BETA-ADRENERGIC SIGNALING PROMOTES TUMOR ANGIOGENESIS AND PROSTATE CANCER PROGRESSION THROUGH HDAC2-MEDIATED SUPPRESSION OF THROMBOSPONDIN-1. CHRONIC BEHAVIORAL STRESS AND BETA-ADRENERGIC SIGNALING HAVE BEEN SHOWN TO PROMOTE CANCER PROGRESSION, WHOSE UNDERLYING MECHANISMS ARE LARGELY UNCLEAR, ESPECIALLY THE INVOLVEMENT OF EPIGENETIC REGULATION. HISTONE DEACETYLASE-2 (HDAC2), AN EPIGENETIC REGULATOR, IS CRITICAL FOR STRESS-INDUCED CARDIAC HYPERTROPHY. IT IS UNKNOWN WHETHER IT IS NECESSARY FOR BETA-ADRENERGIC SIGNALING-PROMOTED CANCER PROGRESSION. USING XENOGRAFT MODELS, WE SHOWED THAT CHRONIC BEHAVIORAL STRESS AND BETA-ADRENERGIC SIGNALING PROMOTE ANGIOGENESIS AND PROSTATE CANCER PROGRESSION. HDAC2 WAS INDUCED BY BETA-ADRENERGIC SIGNALING IN VITRO AND IN MOUSE XENOGRAFTS. WE NEXT UNCOVERED THAT HDAC2 IS A DIRECT TARGET OF CAMP RESPONSE ELEMENT-BINDING PROTEIN (CREB) THAT IS ACTIVATED BY BETA-ADRENERGIC SIGNALING. NOTABLY, HDAC2 IS NECESSARY FOR BETA-ADRENERGIC SIGNALING TO INDUCE ANGIOGENESIS. WE FURTHER DEMONSTRATED THAT, UPON CREB ACTIVATION, HDAC2 REPRESSES THROMBOSPONDIN-1 (TSP1), A POTENT ANGIOGENESIS INHIBITOR, THROUGH EPIGENETIC REGULATION. TOGETHER, THESE DATA ESTABLISH A NOVEL PATHWAY THAT HDAC2 AND TSP1 ACT DOWNSTREAM OF CREB ACTIVATION IN BETA-ADRENERGIC SIGNALING TO PROMOTE CANCER PROGRESSION. 2017 12 1945 31 EPIGALLOCATECHIN-3-GALLATE, A HISTONE ACETYLTRANSFERASE INHIBITOR, INHIBITS EBV-INDUCED B LYMPHOCYTE TRANSFORMATION VIA SUPPRESSION OF RELA ACETYLATION. BECAUSE THE P300/CBP-MEDIATED HYPERACETYLATION OF RELA (P65) IS CRITICAL FOR NUCLEAR FACTOR-KAPPAB (NF-KAPPAB) ACTIVATION, THE ATTENUATION OF P65 ACETYLATION IS A POTENTIAL MOLECULAR TARGET FOR THE PREVENTION OF CHRONIC INFLAMMATION. DURING OUR ONGOING SCREENING STUDY TO IDENTIFY NATURAL COMPOUNDS WITH HISTONE ACETYLTRANSFERASE INHIBITOR (HATI) ACTIVITY, WE IDENTIFIED EPIGALLOCATECHIN-3-GALLATE (EGCG) AS A NOVEL HATI WITH GLOBAL SPECIFICITY FOR THE MAJORITY OF HAT ENZYMES BUT WITH NO ACTIVITY TOWARD EPIGENETIC ENZYMES INCLUDING HDAC, SIRT1, AND HMTASE. AT A DOSE OF 100 MICROMOL/L, EGCG ABROGATES P300-INDUCED P65 ACETYLATION IN VITRO AND IN VIVO, INCREASES THE LEVEL OF CYTOSOLIC IKAPPABALPHA, AND SUPPRESSES TUMOR NECROSIS FACTOR ALPHA (TNFALPHA)-INDUCED NF-KAPPAB ACTIVATION. WE ALSO SHOWED THAT EGCG PREVENTS TNFALPHA-INDUCED P65 TRANSLOCATION TO THE NUCLEUS, CONFIRMING THAT HYPERACETYLATION IS CRITICAL FOR NF-KAPPAB TRANSLOCATION AS WELL AS ACTIVITY. FURTHERMORE, EGCG TREATMENT INHIBITED THE ACETYLATION OF P65 AND THE EXPRESSION OF NF-KAPPAB TARGET GENES IN RESPONSE TO DIVERSE STIMULI. FINALLY, EGCG REDUCED THE BINDING OF P300 TO THE PROMOTER REGION OF INTERLEUKIN-6 GENE WITH AN INCREASED RECRUITMENT OF HDAC3, WHICH HIGHLIGHTS THE IMPORTANCE OF THE BALANCE BETWEEN HATS AND HISTONE DEACETYLASES IN THE NF-KAPPAB-MEDIATED INFLAMMATORY SIGNALING PATHWAY. IMPORTANTLY, EGCG AT 50 MICROMOL/L DOSE COMPLETELY BLOCKS EBV INFECTION-INDUCED CYTOKINE EXPRESSION AND SUBSEQUENTLY THE EBV-INDUCED B LYMPHOCYTE TRANSFORMATION. THESE RESULTS SHOW THE CRUCIAL ROLE OF ACETYLATION IN THE DEVELOPMENT OF INFLAMMATORY-RELATED DISEASES. 2009 13 2189 26 EPIGENETIC MECHANISMS UNDERLYING THE THERAPEUTIC EFFECTS OF HDAC INHIBITORS IN CHRONIC MYELOID LEUKEMIA. CHRONIC MYELOID LEUKEMIA (CML) IS A HEMATOLOGICAL DISORDER CAUSED BY THE ONCOGENIC BCR-ABL FUSION PROTEIN IN MORE THAN 90% OF PATIENTS. DESPITE THE STRIKING IMPROVEMENTS IN THE MANAGEMENT OF CML PATIENTS SINCE THE INTRODUCTION OF TYROSINE KINASE INHIBITORS (TKIS), THE APPEARANCE OF TKI RESISTANCE AND SIDE EFFECTS LEAD TO TREATMENT FAILURE, JUSTIFYING THE NEED OF NOVEL THERAPEUTIC APPROACHES. HISTONE DEACETYLASE INHIBITORS (HDACIS), ABLE TO MODULATE GENE EXPRESSION PATTERNS AND IMPORTANT CELLULAR SIGNALING PATHWAYS THROUGH THE REGULATION OF THE ACETYLATION STATUS OF BOTH HISTONE AND NON-HISTONE PROTEIN TARGETS, HAVE BEEN REPORTED TO DISPLAY PROMISING ANTI-LEUKEMIC PROPERTIES ALONE OR IN COMBINATION WITH TKIS. THIS REVIEW SUMMARIZES PRE-CLINICAL AND CLINICAL STUDIES THAT INVESTIGATED THE MECHANISMS UNDERLYING THE ANTICANCER POTENTIAL OF HDACIS AND DISCUSSES THE RATIONALE FOR A COMBINATION OF HDACIS WITH TKIS AS A THERAPEUTIC OPTION IN CML. 2020 14 5946 32 TARGETING THE EPIGENOME IN THE TREATMENT OF ASTHMA AND CHRONIC OBSTRUCTIVE PULMONARY DISEASE. EPIGENETIC MODIFICATION OF GENE EXPRESSION BY METHYLATION OF DNA AND VARIOUS POST-TRANSLATIONAL MODIFICATIONS OF HISTONES MAY AFFECT THE EXPRESSION OF MULTIPLE INFLAMMATORY GENES. ACETYLATION OF HISTONES BY HISTONE ACETYLTRANSFERASES ACTIVATES INFLAMMATORY GENES, WHEREAS HISTONE DEACETYLATION RESULTS IN INFLAMMATORY GENE REPRESSION. CORTICOSTEROIDS EXERT THEIR ANTIINFLAMMATORY EFFECTS PARTLY BY INDUCING ACETYLATION OF ANTIINFLAMMATORY GENES, BUT MAINLY BY RECRUITING HISTONE DEACETYLASE-2 (HDAC2) TO ACTIVATED INFLAMMATORY GENES. HDAC2 DEACETYLATES ACETYLATED GLUCOCORTICOID RECEPTORS SO THAT THEY CAN SUPPRESS ACTIVATED INFLAMMATORY GENES IN ASTHMA. IN CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD), THERE IS RESISTANCE TO THE ANTIINFLAMMATORY ACTIONS OF CORTICOSTEROIDS, WHICH IS EXPLAINED BY REDUCED ACTIVITY AND EXPRESSION OF HDAC2. THIS CAN BE REVERSED BY A PLASMID VECTOR, WHICH RESTORES HDAC2 LEVELS, BUT MAY ALSO BE ACHIEVED BY LOW CONCENTRATIONS OF THEOPHYLLINE. OXIDATIVE STRESS CAUSES CORTICOSTEROID RESISTANCE BY REDUCING HDAC2 ACTIVITY AND EXPRESSION BY ACTIVATION OF PHOSPHOINOSITIDE-3-KINASE-DELTA, RESULTING IN HDAC2 PHOSPHORYLATION VIA A CASCADE OF KINASES. THEOPHYLLINE REVERSES CORTICOSTEROID RESISTANCE BY DIRECTLY INHIBITING OXIDANT-ACTIVATED PI3KDELTA AND IS MIMICKED BY PI3KDELTA KNOCKOUT OR BY SELECTIVE INHIBITORS. OTHER TREATMENTS MAY ALSO INTERACT IN THIS PATHWAY, MAKING IT POSSIBLE TO REVERSE CORTICOSTEROID RESISTANCE IN PATIENTS WITH COPD, AS WELL AS IN SMOKERS WITH ASTHMA AND SOME PATIENTS WITH SEVERE ASTHMA IN WHOM SIMILAR MECHANISMS OPERATE. OTHER HISTONE MODIFICATIONS, INCLUDING METHYLATION, TYROSINE NITRATION, AND UBIQUITINATION MAY ALSO AFFECT HISTONE FUNCTION AND INFLAMMATORY GENE EXPRESSION, AND BETTER UNDERSTANDING OF THESE EPIGENETIC PATHWAYS COULD LED TO NOVEL ANTIINFLAMMATORY THERAPIES, PARTICULARLY IN CORTICOSTEROID-RESISTANT INFLAMMATION. 2009 15 6045 33 THE COMPLEXITY OF THE NRF2 PATHWAY: BEYOND THE ANTIOXIDANT RESPONSE. THE NF-E2-RELATED FACTOR 2 (NRF2)-MEDIATED SIGNALLING PATHWAY PROVIDES LIVING ORGANISMS AN EFFICIENT AND PIVOTAL LINE OF DEFENSIVE TO COUNTERACT ENVIRONMENTAL INSULTS AND ENDOGENOUS STRESSORS. NRF2 COORDINATES THE BASAL AND INDUCIBLE EXPRESSION OF ANTIOXIDANT AND PHASE II DETOXIFICATION ENZYMES TO ADAPT TO DIFFERENT STRESS CONDITIONS. THE STABILITY AND CELLULAR DISTRIBUTION OF NRF2 IS TIGHTLY CONTROLLED BY ITS INHIBITORY BINDING PROTEIN KELCH-LIKE ECH-ASSOCIATED PROTEIN 1. NRF2 SIGNALLING IS ALSO REGULATED BY POSTTRANSLATIONAL, TRANSCRIPTIONAL, TRANSLATIONAL AND EPIGENETIC MECHANISMS, AS WELL AS BY OTHER PROTEIN PARTNERS, INCLUDING P62, P21 AND IQ MOTIF-CONTAINING GTPASE ACTIVATING PROTEIN 1. MANY STUDIES HAVE DEMONSTRATED THAT NRF2 IS A PROMISING TARGET FOR PREVENTING CARCINOGENESIS AND OTHER CHRONIC DISEASES, INCLUDING CARDIOVASCULAR DISEASES, NEURODEGENERATIVE DISEASES AND PULMONARY INJURY. HOWEVER, CONSTITUTIVE ACTIVATION OF NRF2 IN ADVANCED CANCER CELLS MAY CONFER DRUG RESISTANCE. HERE, WE REVIEW THE MOLECULAR MECHANISMS OF NRF2 SIGNALLING, THE DIVERSE CLASSES OF NRF2 ACTIVATORS, INCLUDING BIOACTIVE NUTRIENTS AND OTHER CHEMICALS, AND THE CELLULAR FUNCTIONS AND DISEASE RELEVANCE OF NRF2 AND DISCUSS THE DUAL ROLE OF NRF2 IN DIFFERENT CONTEXTS. 2015 16 4582 28 N-TERMINAL BET BROMODOMAIN INHIBITORS DISRUPT A BRD4-P65 INTERACTION AND REDUCE INDUCIBLE NITRIC OXIDE SYNTHASE TRANSCRIPTION IN PANCREATIC BETA-CELLS. CHRONIC INFLAMMATION OF PANCREATIC ISLETS IS A KEY DRIVER OF BETA-CELL DAMAGE THAT CAN LEAD TO AUTOREACTIVITY AND THE EVENTUAL ONSET OF AUTOIMMUNE DIABETES (T1D). IN THE ISLET, ELEVATED LEVELS OF PROINFLAMMATORY CYTOKINES INDUCE THE TRANSCRIPTION OF THE INDUCIBLE NITRIC OXIDE SYNTHASE (INOS) GENE, NOS2, ULTIMATELY RESULTING IN INCREASED NITRIC OXIDE (NO). EXCESSIVE OR PROLONGED EXPOSURE TO NO CAUSES BETA-CELL DYSFUNCTION AND FAILURE ASSOCIATED WITH DEFECTS IN MITOCHONDRIAL RESPIRATION. RECENT STUDIES SHOWED THAT INHIBITION OF THE BROMODOMAIN AND EXTRATERMINAL DOMAIN (BET) FAMILY OF PROTEINS, A DRUGGABLE CLASS OF EPIGENETIC READER PROTEINS, PREVENTS THE ONSET AND PROGRESSION OF T1D IN THE NON-OBESE DIABETIC MOUSE MODEL. WE HYPOTHESIZED THAT BET PROTEINS CO-ACTIVATE TRANSCRIPTION OF CYTOKINE-INDUCED INFLAMMATORY GENE TARGETS IN BETA-CELLS AND THAT SELECTIVE, CHEMOTHERAPEUTIC INHIBITION OF BET BROMODOMAINS COULD REDUCE SUCH TRANSCRIPTION. HERE, WE INVESTIGATED THE ABILITY OF BET BROMODOMAIN SMALL MOLECULE INHIBITORS TO REDUCE THE BETA-CELL RESPONSE TO THE PROINFLAMMATORY CYTOKINE INTERLEUKIN 1 BETA (IL-1BETA). BET BROMODOMAIN INHIBITION ATTENUATED IL-1BETA-INDUCED TRANSCRIPTION OF THE INFLAMMATORY MEDIATOR NOS2 AND CONSEQUENT INOS PROTEIN AND NO PRODUCTION. REDUCED NOS2 TRANSCRIPTION IS CONSISTENT WITH INHIBITION OF NF-KAPPAB FACILITATED BY DISRUPTING THE INTERACTION OF A SINGLE BET FAMILY MEMBER, BRD4, WITH THE NF-KAPPAB SUBUNIT, P65. USING RECENTLY REPORTED SELECTIVE INHIBITORS OF THE FIRST AND SECOND BET BROMODOMAINS, INHIBITION OF ONLY THE FIRST BROMODOMAIN WAS NECESSARY TO REDUCE THE INTERACTION OF BRD4 WITH P65 IN BETA-CELLS. MOREOVER, INHIBITION OF THE FIRST BROMODOMAIN WAS SUFFICIENT TO MITIGATE IL-1BETA-DRIVEN DECREASES IN MITOCHONDRIAL OXYGEN CONSUMPTION RATES AND BETA-CELL VIABILITY. BY IDENTIFYING A ROLE FOR THE INTERACTION BETWEEN BRD4 AND P65 IN CONTROLLING THE RESPONSE OF BETA-CELLS TO PROINFLAMMATORY CYTOKINES, WE PROVIDE MECHANISTIC INFORMATION ON HOW BET BROMODOMAIN INHIBITION CAN DECREASE INFLAMMATION. THESE STUDIES ALSO SUPPORT THE POTENTIAL THERAPEUTIC APPLICATION OF MORE SELECTIVE BET BROMODOMAIN INHIBITORS IN ATTENUATING BETA-CELL INFLAMMATION. 2022 17 4605 32 NEGATIVE REGULATORS OF TGF-BETA1 SIGNALING IN RENAL FIBROSIS; PATHOLOGICAL MECHANISMS AND NOVEL THERAPEUTIC OPPORTUNITIES. ELEVATED EXPRESSION OF THE MULTIFUNCTIONAL CYTOKINE TRANSFORMING GROWTH FACTOR BETA1 (TGF-BETA1) IS CAUSATIVELY LINKED TO KIDNEY FIBROSIS PROGRESSION INITIATED BY DIABETIC, HYPERTENSIVE, OBSTRUCTIVE, ISCHEMIC AND TOXIN-INDUCED INJURY. THERAPEUTICALLY RELEVANT APPROACHES TO DIRECTLY TARGET THE TGF-BETA1 PATHWAY (E.G., NEUTRALIZING ANTIBODIES AGAINST TGF-BETA1), HOWEVER, REMAIN ELUSIVE IN HUMANS. TGF-BETA1 SIGNALING IS SUBJECTED TO EXTENSIVE NEGATIVE CONTROL AT THE LEVEL OF TGF-BETA1 RECEPTOR, SMAD2/3 ACTIVATION, COMPLEX ASSEMBLY AND PROMOTER ENGAGEMENT DUE TO ITS CRITICAL ROLE IN TISSUE HOMEOSTASIS AND NUMEROUS PATHOLOGIES. PROGRESSIVE KIDNEY INJURY IS ACCOMPANIED BY THE DEREGULATION (LOSS OR GAIN OF EXPRESSION) OF SEVERAL NEGATIVE REGULATORS OF THE TGF-BETA1 SIGNALING CASCADE BY MECHANISMS INVOLVING PROTEIN AND MRNA STABILITY OR EPIGENETIC SILENCING, FURTHER AMPLIFYING TGF-BETA1/SMAD3 SIGNALING AND FIBROSIS. EXPRESSION OF BONE MORPHOGENETIC PROTEINS 6 AND 7 (BMP6/7), SMAD7, SLOAN-KETTERING INSTITUTE PROTO-ONCOGENE (SKI) AND SKI-RELATED NOVEL GENE (SNON), PHOSPHATE TENSIN HOMOLOG ON CHROMOSOME 10 (PTEN), PROTEIN PHOSPHATASE MAGNESIUM/MANGANESE DEPENDENT 1A (PPM1A) AND KLOTHO ARE DRAMATICALLY DECREASED IN VARIOUS NEPHROPATHIES IN ANIMALS AND HUMANS ALBEIT WITH DIFFERENT KINETICS WHILE THE EXPRESSION OF SMURF1/2 E3 LIGASES ARE INCREASED. SUCH DEREGULATIONS FREQUENTLY INITIATE MALADAPTIVE RENAL REPAIR INCLUDING RENAL EPITHELIAL CELL DEDIFFERENTIATION AND GROWTH ARREST, FIBROTIC FACTOR (CONNECTIVE TISSUE GROWTH FACTOR (CTGF/CCN2), PLASMINOGEN ACTIVATOR INHIBITOR TYPE-1 (PAI-1), TGF-BETA1) SYNTHESIS/SECRETION, FIBROPROLIFERATIVE RESPONSES AND INFLAMMATION. THIS REVIEW ADDRESSES HOW LOSS OF THESE NEGATIVE REGULATORS OF TGF-BETA1 PATHWAY EXACERBATES RENAL LESION FORMATION AND DISCUSSES THE THERAPEUTIC VALUE IN RESTORING THE EXPRESSION OF THESE MOLECULES IN AMELIORATING FIBROSIS, THUS, PRESENTING NOVEL APPROACHES TO SUPPRESS TGF-BETA1 HYPERACTIVATION DURING CHRONIC KIDNEY DISEASE (CKD) PROGRESSION. 2021 18 3869 33 JNK1 REGULATES HISTONE ACETYLATION IN TRIGEMINAL NEURONS FOLLOWING CHEMICAL STIMULATION. TRIGEMINAL NERVE FIBERS IN NASAL AND ORAL CAVITIES ARE SENSITIVE TO VARIOUS ENVIRONMENTAL HAZARDOUS STIMULI, WHICH TRIGGER MANY NEUROTOXIC PROBLEMS SUCH AS CHRONIC MIGRAINE HEADACHE AND TRIGEMINAL IRRITATED DISORDERS. HOWEVER, THE ROLE OF JNK KINASE CASCADE AND ITS EPIGENETIC MODULATION OF HISTONE REMODELING IN TRIGEMINAL GANGLION (TG) NEURONS ACTIVATED BY ENVIRONMENTAL NEUROTOXINS REMAINS UNKNOWN. HERE WE INVESTIGATED THE ROLE OF JNK/C-JUN CASCADE IN THE REGULATION OF ACETYLATION OF H3 HISTONE IN TG NEURONS FOLLOWING IN VITRO STIMULATION BY A NEURO-INFLAMMATORY AGENT, MUSTARD OIL (MO). WE FOUND THAT MO STIMULATION ELICITED JNK/C-JUN PATHWAY SIGNIFICANTLY BY ENHANCING PHOSPHO-JNK1, PHOSPHO-C-JUN EXPRESSION, AND C-JUN ACTIVITY, WHICH WERE CORRELATED WITH AN ELEVATED ACETYLATED H3 HISTONE IN TG NEURONS. HOWEVER, INCREASES IN PHOSPHO-C-JUN AND C-JUN ACTIVITY WERE SIGNIFICANTLY BLOCKED BY A JNK INHIBITOR, SP600125. WE ALSO FOUND THAT ALTERED H3 HISTONE REMODELING, ASSESSED BY H3 ACETYLATION IN TRIGGERED TG NEURONS, WAS REDUCED BY SP600125. THE STUDY SUGGESTS THAT THE ACTIVATED JNK SIGNALING IN REGULATION OF HISTONE REMODELING MAY CONTRIBUTE TO NEURO-EPIGENTIC CHANGES IN PERIPHERAL SENSORY NEURONS FOLLOWING ENVIRONMENTAL NEUROTOXIC EXPOSURE. 2008 19 699 31 BROMODOMAIN PROTEIN 4 IS A KEY MOLECULAR DRIVER OF TGFBETA1-INDUCED HEPATIC STELLATE CELL ACTIVATION. LIVER FIBROSIS IS CHARACTERIZED BY THE EXCESSIVE DEPOSITION OF EXTRACELLULAR MATRIX IN LIVER. CHRONIC LIVER INJURY INDUCES THE ACTIVATION OF HEPATIC STELLATE CELL (HSCS), A KEY STEP IN LIVER FIBROGENESIS. THE ACTIVATED HSC IS THE PRIMARY SOURCE OF ECM AND CONTRIBUTES SIGNIFICANTLY TO LIVER FIBROSIS. TGFBETA1 IS THE MOST POTENT PRO-FIBROTIC CYTOKINE. BROMODOMAIN PROTEIN 4 (BRD4), AN EPIGENETIC READER OF HISTONE ACETYLATION MARKS, WAS CRUCIAL FOR PROFIBROTIC GENE EXPRESSION IN HSCS. THE PRESENT STUDY AIMED TO INVESTIGATE THE ROLES OF BRD4 IN TGFBETA1-DEPENDENT HSC ACTIVATION AND LIVER FIBROSIS, FOCUSING ON TGFBETA1-INDUCED ALTERATIONS OF THE LEVELS OF THE FIBROTIC-RELATED IMPORTANT PROTEINS IN HSCS BY EMPLOYING THE HETEROZYGOUS TGFBETA1 KNOCKOUT MICE AND BRD4 KNOCKDOWN IN VIVO AND IN VITRO. RESULTS REVEALED THAT BRD4 PROTEIN LEVEL WAS SIGNIFICANTLY UPREGULATED BY TGFBETA1 AND BRD4 KNOCKDOWN REDUCED TGFBETA1-INDUCED HSC ACTIVATION AND LIVER FIBROSIS. BRD4 WAS REQUIRED FOR THE INFLUENCES OF TGFBETA1 ON PDGFBETA RECEPTOR AND ON THE PATHWAYS OF SMAD3, STAT3, AND AKT. BRD4 ALSO MEDIATED TGFBETA1-INDUCED INCREASES IN HISTONE ACETYLTRANSFERASE P300, THE PIVOTAL PRO-INFLAMMATORY NFKB P65, AND TISSUE INHIBITOR OF METALLOPROTEINASE 1 WHEREAS BRD4 REDUCED CASPASE-3 PROTEIN LEVELS IN HSCS DURING LIVER INJURY, INDEPENDENT OF TGFBETA1. FURTHER EXPERIMENTS INDICATED THE INTERACTION BETWEEN TGFBETA1-INDUCED BRD4 AND NFKB P65 IN HSCS AND IN LIVER OF TAA-INDUCED LIVER INJURY. HUMAN CIRRHOTIC LIVERS WERE DEMONSTRATED A PARALLEL INCREASE IN THE PROTEIN LEVELS OF BRD4 AND NFKB P65 IN HSCS. THIS STUDY REVEALED THAT BRD4 WAS A KEY MOLECULAR DRIVER OF TGFBETA1-INDUCED HSC ACTIVATION AND LIVER FIBROSIS. 2023 20 5868 36 SUPPRESSIVE EFFECTS OF METFORMIN ON T-HELPER 1-RELATED CHEMOKINES EXPRESSION IN THE HUMAN MONOCYTIC LEUKEMIA CELL LINE THP-1. PURPOSE OF THE STUDY: TYPE 1 AND TYPE 2 DIABETES MELLITUS (DM) ARE CHRONIC T-CELL-MEDIATED INFLAMMATORY DISEASES. METFORMIN IS A WIDELY USED DRUG FOR TYPE 2 DM THAT REDUCES THE NEED FOR INSULIN IN TYPE 1 DM. HOWEVER, WHETHER METFORMIN HAS AN ANTI-INFLAMMATORY EFFECT FOR TREATING DM IS UNKNOWN. WE INVESTIGATED THE ANTI-INFLAMMATORY MECHANISM OF METFORMIN IN THE HUMAN MONOCYTIC LEUKEMIA CELL LINE THP-1. MATERIALS AND METHODS: THE HUMAN MONOCYTIC LEUKEMIA CELL LINE THP-1 WAS PRETREATED WITH METFORMIN AND STIMULATED WITH LIPOPOLYSACCHARIDE (LPS). THE PRODUCTION OF T-HELPER (TH)-1-RELATED CHEMOKINES INCLUDING INTERFERON-GAMMA-INDUCED PROTEIN-10 (IP-10) AND MONOCYTE CHEMOATTRACTANT PROTEIN-1 (MCP-1), TH2-RELATED CHEMOKINE MACROPHAGE-DERIVED CHEMOKINE, AND THE PROINFLAMMATORY CHEMOKINE TUMOR NECROSIS FACTOR-ALPHA WAS MEASURED USING ENZYME-LINKED IMMUNOSORBENT ASSAY. INTRACELLULAR SIGNALING PATHWAYS WERE INVESTIGATED USING WESTERN BLOT ANALYSIS AND CHROMATIN IMMUNOPRECIPITATION ASSAY. RESULTS: METFORMIN SUPPRESSED LPS-INDUCED IP-10 AND MCP-1 PRODUCTION AS WELL AS LPS-INDUCED PHOSPHORYLATION OF C-JUN N-TERMINAL KINASE (JNK), P38, EXTRACELLULAR SIGNAL-REGULATED KINASE (ERK), AND NUCLEAR FACTOR-KAPPA B (NF-KAPPAB). MOREOVER, METFORMIN SUPPRESSED LPS-INDUCED ACETYLATION OF HISTONES H3 AND H4 AT THE IP-10 PROMOTER. CONCLUSIONS: METFORMIN SUPPRESSED THE PRODUCTION OF TH1-RELATED CHEMOKINES IP-10 AND MCP-1 IN THP-1 CELLS. SUPPRESSIVE EFFECTS OF METFORMIN ON IP-10 PRODUCTION MIGHT BE ATTRIBUTED AT LEAST PARTIALLY TO THE JNK, P38, ERK, AND NF-KAPPAB PATHWAYS AS WELL AS TO EPIGENETIC REGULATION THROUGH THE ACETYLATION OF HISTONES H3 AND H4. THESE RESULTS INDICATED THE THERAPEUTIC ANTI-INFLAMMATORY POTENTIAL OF METFORMIN. 2018