1 6590 115 TUMOR SUPPRESSOR INACTIVATION IN THE PATHOGENESIS OF ADULT T-CELL LEUKEMIA. TUMOR SUPPRESSOR FUNCTIONS ARE ESSENTIAL TO CONTROL CELLULAR PROLIFERATION, TO ACTIVATE THE APOPTOSIS OR SENESCENCE PATHWAY TO ELIMINATE UNWANTED CELLS, TO LINK DNA DAMAGE SIGNALS TO CELL CYCLE ARREST CHECKPOINTS, TO ACTIVATE APPROPRIATE DNA REPAIR PATHWAYS, AND TO PREVENT THE LOSS OF ADHESION TO INHIBIT INITIATION OF METASTASES. THEREFORE, TUMOR SUPPRESSOR GENES ARE INDISPENSABLE TO MAINTAINING GENETIC AND GENOMIC INTEGRITY. CONSEQUENTLY, INACTIVATION OF TUMOR SUPPRESSORS BY SOMATIC MUTATIONS OR EPIGENETIC MECHANISMS IS FREQUENTLY ASSOCIATED WITH TUMOR INITIATION AND DEVELOPMENT. IN CONTRAST, REACTIVATION OF TUMOR SUPPRESSOR FUNCTIONS CAN EFFECTIVELY REVERSE THE TRANSFORMED PHENOTYPE AND LEAD TO CELL CYCLE ARREST OR DEATH OF CANCEROUS CELLS AND BE USED AS A THERAPEUTIC STRATEGY. ADULT T-CELL LEUKEMIA/LYMPHOMA (ATLL) IS AN AGGRESSIVE LYMPHOPROLIFERATIVE DISEASE ASSOCIATED WITH INFECTION OF CD4 T CELLS BY THE HUMAN T-CELL LEUKEMIA VIRUS TYPE 1 (HTLV-I). HTLV-I-ASSOCIATED T-CELL TRANSFORMATION IS THE RESULT OF A MULTISTEP ONCOGENIC PROCESS IN WHICH THE VIRUS INITIALLY INDUCES CHRONIC T-CELL PROLIFERATION AND ALTERS CELLULAR PATHWAYS RESULTING IN THE ACCUMULATION OF GENETIC DEFECTS AND THE DEREGULATED GROWTH OF VIRALLY INFECTED CELLS. THIS REVIEW WILL FOCUS ON THE CURRENT KNOWLEDGE OF THE GENETIC AND EPIGENETIC MECHANISMS REGULATING THE INACTIVATION OF TUMOR SUPPRESSORS IN THE PATHOGENESIS OF HTLV-I. 2015 2 6444 53 THERAPEUTIC ASPECTS OF C-MYC SIGNALING IN INFLAMMATORY AND CANCEROUS COLONIC DISEASES. COLONIC INFLAMMATION IS REQUIRED TO HEAL INFECTIONS, WOUNDS, AND MAINTAIN TISSUE HOMEOSTASIS. AS THE SEVENTH HALLMARK OF CANCER, HOWEVER, IT MAY AFFECT ALL PHASES OF TUMOR DEVELOPMENT, INCLUDING TUMOR INITIATION, PROMOTION, INVASION AND METASTATIC DISSEMINATION, AND ALSO EVASION IMMUNE SURVEILLANCE. INFLAMMATION ACTS AS A CELLULAR STRESSOR AND MAY TRIGGER DNA DAMAGE OR GENETIC INSTABILITY, AND, FURTHER, CHRONIC INFLAMMATION CAN PROVOKE GENETIC MUTATIONS AND EPIGENETIC MECHANISMS THAT PROMOTE MALIGNANT CELL TRANSFORMATION. BOTH SPORADICAL AND COLITIS-ASSOCIATED COLORECTAL CARCINOGENESIS ARE MULTI-STEP, COMPLEX PROCESSES ARISING FROM THE UNCONTROLLED PROLIFERATION AND SPREADING OF MALIGNANTLY TRANSFORMED CELL CLONES WITH THE OBVIOUS ABILITY TO EVADE THE HOST'S PROTECTIVE IMMUNITY. IN CELLS UPON DNA DAMAGE SEVERAL PROTO-ONCOGENES, INCLUDING C-MYC ARE ACTIVATED IN PARELELL WITH THE INACTIVATION OF TUMOR SUPPRESSOR GENES. THE TARGET GENES OF THE C-MYC PROTEIN PARTICIPATE IN DIFFERENT CELLULAR FUNCTIONS, INCLUDING CELL CYCLE, SURVIVAL, PROTEIN SYNTHESIS, CELL ADHESION, AND MICRO-RNA EXPRESSION. THE TRANSCRIPTIONAL PROGRAM REGULATED BY C-MYC IS CONTEXT DEPENDENT, THEREFORE THE FINAL CELLULAR RESPONSE TO ELEVATED C-MYC LEVELS MAY RANGE FROM INCREASED PROLIFERATION TO AUGMENTED APOPTOSIS. CONSIDERING PHYSIOLOGICAL INTESTINAL HOMEOSTASIS, C-MYC DISPLAYS A FUNDAMENTAL ROLE IN THE REGULATION OF CELL PROLIFERATION AND CRYPT CELL NUMBER. HOWEVER, C-MYC GENE IS FREQUENTLY DEREGULATED IN INFLAMMATION, AND OVEREXPRESSED IN BOTH SPORADIC AND COLITIS-ASSOCIATED COLON ADENOCARCINOMAS. RECENT RESULTS DEMONSTRATED THAT ENDOGENOUS C-MYC IS ESSENTIAL FOR EFFICIENT INDUCTION OF P53-DEPENDENT APOPTOSIS FOLLOWING DNA DAMAGE, BUT C-MYC FUNCTION IS ALSO INVOLVED IN AND REGULATED BY AUTOPHAGY-RELATED MECHANISMS, WHILE ITS EXPRESSION IS AFFECTED BY DNA-METHYLATION, OR HISTONE ACETYLATION. MOLECULES DIRECTLY TARGETING C-MYC, OR AGENTS ACTING ON OTHER GENES INVOLVED IN THE C-MYC PATHWAY COULD BE SELECTED FOR COMBINED REGIMENTS. HOWEVER, DUE TO ITS CONTEXT-DEPENDENT CELLULAR FUNCTION, IT IS CLINICALLY ESSENTIAL TO CONSIDER WHICH CYTOTOXIC DRUGS ARE USED IN COMBINATION WITH C-MYC TARGETED AGENTS IN VARIOUS TISSUES. INCREASING OUR KNOWLEDGE ABOUT MYC-DEPENDENT PATHWAYS MIGHT PROVIDE DIRECTION TO NOVEL ANTI-INFLAMMATORY AND COLORECTAL CANCER THERAPIES. 2016 3 3276 38 HEPATOCYTE GROWTH CONTROL BY SOCS1 AND SOCS3. THE EXTRAORDINARY CAPACITY OF THE LIVER TO REGENERATE FOLLOWING INJURY IS DEPENDENT ON COORDINATED AND REGULATED ACTIONS OF CYTOKINES AND GROWTH FACTORS. WHEREAS HEPATOCYTE GROWTH FACTOR (HGF) AND EPIDERMAL GROWTH FACTOR (EGF) ARE DIRECT MITOGENS TO HEPATOCYTES, INFLAMMATORY CYTOKINES SUCH AS TNFALPHA AND IL-6 ALSO PLAY ESSENTIAL ROLES IN THE LIVER REGENERATION PROCESS. THESE CYTOKINES AND GROWTH FACTORS ACTIVATE DIFFERENT SIGNALING PATHWAYS IN A SEQUENTIAL MANNER TO ELICIT HEPATOCYTE PROLIFERATION. THE KINETICS AND MAGNITUDE OF THESE HEPATOCYTE-ACTIVATING STIMULI ARE TIGHTLY REGULATED TO ENSURE RESTORATION OF A FUNCTIONAL LIVER MASS WITHOUT CAUSING UNCONTROLLED CELL PROLIFERATION. HEPATOCYTE PROLIFERATION CAN BECOME DEREGULATED UNDER CONDITIONS OF CHRONIC INFLAMMATION, LEADING TO ACCUMULATION OF GENETIC ABERRATIONS AND EVENTUAL NEOPLASTIC TRANSFORMATION. AMONG THE CONTROL MECHANISMS THAT REGULATE HEPATOCYTE PROLIFERATION, NEGATIVE FEEDBACK INHIBITION BY THE 'SUPPRESSOR OF CYTOKINE SIGNALING (SOCS)' FAMILY PROTEINS SOCS1 AND SOCS3 PLAY CRUCIAL ROLES IN ATTENUATING CYTOKINE AND GROWTH FACTOR SIGNALING. LOSS OF SOCS1 OR SOCS3 IN THE MOUSE LIVER INCREASES THE RATE OF LIVER REGENERATION AND RENDERS HEPATOCYTES SUSCEPTIBLE TO NEOPLASTIC TRANSFORMATION. THE FREQUENT EPIGENETIC REPRESSION OF THE SOCS1 AND SOCS3 GENES IN HEPATOCELLULAR CARCINOMA HAS STIMULATED RESEARCH IN UNDERSTANDING THE GROWTH REGULATORY MECHANISMS OF SOCS1 AND SOCS3 IN HEPATOCYTES. WHEREAS SOCS3 IS IMPLICATED IN REGULATING JAK-STAT SIGNALING INDUCED BY IL-6 AND ATTENUATING EGFR SIGNALING, SOCS1 IS CRUCIAL FOR THE REGULATION OF HGF SIGNALING. THESE TWO PROTEINS ALSO MODULE THE FUNCTIONS OF CERTAIN KEY PROTEINS THAT CONTROL THE CELL CYCLE. IN THIS REVIEW, WE DISCUSS THE CURRENT UNDERSTANDING OF THE FUNCTIONS OF SOCS1 AND SOCS3 IN CONTROLLING HEPATOCYTE PROLIFERATION, AND ITS IMPLICATIONS TO LIVER HEALTH AND DISEASE. 2019 4 6757 34 WNT SIGNALING IN LIVER FIBROSIS: PROGRESS, CHALLENGES AND POTENTIAL DIRECTIONS. LIVER FIBROSIS IS A COMMON WOUND-HEALING RESPONSE TO CHRONIC LIVER INJURIES, INCLUDING ALCOHOLIC OR DRUG TOXICITY, PERSISTENT VIRAL INFECTION, AND GENETIC FACTORS. MYOFIBROBLASTIC TRANSDIFFERENTIATION (MTD) IS THE PIVOTAL EVENT DURING LIVER FIBROGENESIS, AND RESEARCH IN THE PAST FEW YEARS HAS IDENTIFIED KEY MEDIATORS AND MOLECULAR MECHANISMS RESPONSIBLE FOR MTD OF HEPATIC STELLATE CELLS (HSCS). HSCS ARE UNDIFFERENTIATED CELLS WHICH PLAY AN IMPORTANT ROLE IN LIVER REGENERATION. RECENT EVIDENCE DEMONSTRATES THAT HSCS DERIVE FROM MESODERM AND AT LEAST IN PART VIA SEPTUM TRANSVERSUM AND MESOTHELIUM, AND HSCS EXPRESS MARKERS FOR DIFFERENT CELL TYPES WHICH DERIVE FROM MULTIPOTENT MESENCHYMAL PROGENITORS. THERE IS A REGULATORY COMMONALITY BETWEEN DIFFERENTIATION OF ADIPOCYTES AND THAT OF HSC, AND THE SHIFT FROM ADIPOGENIC TO MYOGENIC OR NEURONAL PHENOTYPE CHARACTERIZES HSC MTD. CENTRAL OF THIS SHIFT IS A LOSS OF EXPRESSION OF THE MASTER ADIPOGENIC REGULATOR PEROXISOME PROLIFERATOR ACTIVATED RECEPTOR GAMMA (PPARGAMMA). RESTORED EXPRESSION OF PPARGAMMA AND/OR OTHER ADIPOGENIC TRANSCRIPTION GENES CAN REVERSE MYOFIBROBLASTIC HSCS TO DIFFERENTIATED CELLS. VERTEBRATE WNT AND DROSOPHILA WINGLESS ARE HOMOLOGOUS GENES, AND THEIR TRANSLATED PROTEINS HAVE BEEN SHOWN TO PARTICIPATE IN THE REGULATION OF CELL PROLIFERATION, CELL POLARITY, CELL DIFFERENTIATION, AND OTHER BIOLOGICAL ROLES. MORE RECENTLY, WNT SIGNALING IS IMPLICATED IN HUMAN FIBROSING DISEASES, SUCH AS PULMONARY FIBROSIS, RENAL FIBROSIS, AND LIVER FIBROSIS. BLOCKING THE CANONICAL WNT SIGNAL PATHWAY WITH THE CO-RECEPTOR ANTAGONIST DICKKOPF-1 (DKK1) ABROGATES THESE EPIGENETIC REPRESSIONS AND RESTORES THE GENE PPARGAMMA EXPRESSION AND HSC DIFFERENTIATION. THE IDENTIFIED MORPHOGEN MEDIATED EPIGENETIC REGULATION OF PPARGAMMA AND HSC DIFFERENTIATION ALSO SERVES AS NOVEL THERAPEUTIC TARGETS FOR LIVER FIBROSIS AND LIVER REGENERATION. IN CONCLUSION, THE WNT SIGNALING PROMOTES LIVER FIBROSIS BY ENHANCING HSC ACTIVATION AND SURVIVAL, AND WE HEREIN DISCUSS WHAT WE CURRENTLY KNOW AND WHAT WE EXPECT WILL COME IN THIS FIELD IN THE NEXT FUTURE. 2013 5 3688 39 INFLAMMATION: GEARING THE JOURNEY TO CANCER. CHRONIC INFLAMMATION PLAYS A MULTIFACETED ROLE IN CARCINOGENESIS. MOUNTING EVIDENCE FROM PRECLINICAL AND CLINICAL STUDIES SUGGESTS THAT PERSISTENT INFLAMMATION FUNCTIONS AS A DRIVING FORCE IN THE JOURNEY TO CANCER. THE POSSIBLE MECHANISMS BY WHICH INFLAMMATION CAN CONTRIBUTE TO CARCINOGENESIS INCLUDE INDUCTION OF GENOMIC INSTABILITY, ALTERATIONS IN EPIGENETIC EVENTS AND SUBSEQUENT INAPPROPRIATE GENE EXPRESSION, ENHANCED PROLIFERATION OF INITIATED CELLS, RESISTANCE TO APOPTOSIS, AGGRESSIVE TUMOR NEOVASCULARIZATION, INVASION THROUGH TUMOR-ASSOCIATED BASEMENT MEMBRANE AND METASTASIS, ETC. INFLAMMATION-INDUCED REACTIVE OXYGEN AND NITROGEN SPECIES CAUSE DAMAGE TO IMPORTANT CELLULAR COMPONENTS (E.G., DNA, PROTEINS AND LIPIDS), WHICH CAN DIRECTLY OR INDIRECTLY CONTRIBUTE TO MALIGNANT CELL TRANSFORMATION. OVEREXPRESSION, ELEVATED SECRETION, OR ABNORMAL ACTIVATION OF PROINFLAMMATORY MEDIATORS, SUCH AS CYTOKINES, CHEMOKINES, CYCLOOXYGENASE-2, PROSTAGLANDINS, INDUCIBLE NITRIC OXIDE SYNTHASE, AND NITRIC OXIDE, AND A DISTINCT NETWORK OF INTRACELLULAR SIGNALING MOLECULES INCLUDING UPSTREAM KINASES AND TRANSCRIPTION FACTORS FACILITATE TUMOR PROMOTION AND PROGRESSION. WHILE INFLAMMATION PROMOTES DEVELOPMENT OF CANCER, COMPONENTS OF THE TUMOR MICROENVIRONMENT, SUCH AS TUMOR CELLS, STROMAL CELLS IN SURROUNDING TISSUE AND INFILTRATED INFLAMMATORY/IMMUNE CELLS GENERATE AN INTRATUMORAL INFLAMMATORY STATE BY ABERRANT EXPRESSION OR ACTIVATION OF SOME PROINFLAMMATORY MOLECULES. MANY OF PROINFLAMMATORY MEDIATORS, ESPECIALLY CYTOKINES, CHEMOKINES AND PROSTAGLANDINS, TURN ON THE ANGIOGENIC SWITCHES MAINLY CONTROLLED BY VASCULAR ENDOTHELIAL GROWTH FACTOR, THEREBY INDUCING INFLAMMATORY ANGIOGENESIS AND TUMOR CELL-STROMA COMMUNICATION. THIS WILL END UP WITH TUMOR ANGIOGENESIS, METASTASIS AND INVASION. MOREOVER, CELLULAR MICRORNAS ARE EMERGING AS A POTENTIAL LINK BETWEEN INFLAMMATION AND CANCER. THE PRESENT ARTICLE HIGHLIGHTS THE ROLE OF VARIOUS PROINFLAMMATORY MEDIATORS IN CARCINOGENESIS AND THEIR PROMISE AS POTENTIAL TARGETS FOR CHEMOPREVENTION OF INFLAMMATION-ASSOCIATED CARCINOGENESIS. 2008 6 5939 31 TARGETING MECHANOTRANSDUCTION AT THE TRANSCRIPTIONAL LEVEL: YAP AND BRD4 ARE NOVEL THERAPEUTIC TARGETS FOR THE REVERSAL OF LIVER FIBROSIS. LIVER FIBROSIS IS THE RESULT OF A DEREGULATED WOUND HEALING PROCESS CHARACTERIZED BY THE EXCESSIVE DEPOSITION OF EXTRACELLULAR MATRIX. HEPATIC STELLATE CELLS (HSCS), WHICH ARE ACTIVATED IN RESPONSE TO LIVER INJURY, ARE THE MAJOR SOURCE OF EXTRACELLULAR MATRIX AND DRIVE THE WOUND HEALING PROCESS. HOWEVER, CHRONIC LIVER DAMAGE LEADS TO PERPETUAL HSC ACTIVATION, PROGRESSIVE FORMATION OF PATHOLOGICAL SCAR TISSUE AND ULTIMATELY, CIRRHOSIS AND ORGAN FAILURE. HSC ACTIVATION IS TRIGGERED LARGELY IN RESPONSE TO MECHANOSIGNALING FROM THE MICROENVIRONMENT, WHICH INDUCES A PROFIBROTIC NUCLEAR TRANSCRIPTION PROGRAM THAT PROMOTES HSC PROLIFERATION AND EXTRACELLULAR MATRIX SECRETION THEREBY SETTING UP A POSITIVE FEEDBACK LOOP LEADING TO MATRIX STIFFENING AND SELF-SUSTAINED, PATHOLOGICAL, HSC ACTIVATION. DESPITE THE SIGNIFICANT PROGRESS IN OUR UNDERSTANDING OF LIVER FIBROSIS, THE MOLECULAR MECHANISMS THROUGH WHICH THE EXTRACELLULAR MATRIX PROMOTES HSC ACTIVATION ARE NOT WELL UNDERSTOOD AND NO EFFECTIVE THERAPIES HAVE BEEN APPROVED TO DATE THAT CAN TARGET THIS EARLY, REVERSIBLE, STAGE IN LIVER FIBROSIS. SEVERAL NEW LINES OF INVESTIGATION NOW PROVIDE IMPORTANT INSIGHT INTO THIS AREA OF STUDY AND IDENTIFY TWO NUCLEAR TARGETS WHOSE INHIBITION HAS THE POTENTIAL OF REVERSING LIVER FIBROSIS BY INTERFERING WITH HSC ACTIVATION: YES-ASSOCIATED PROTEIN (YAP), A TRANSCRIPTIONAL CO-ACTIVATOR AND EFFECTOR OF THE MECHANOSENSITIVE HIPPO PATHWAY, AND BROMODOMAIN-CONTAINING PROTEIN 4 (BRD4), AN EPIGENETIC REGULATOR OF GENE EXPRESSION. YAP AND BRD4 ACTIVITY IS INDUCED IN RESPONSE TO MECHANICAL STIMULATION OF HSCS AND EACH PROTEIN INDEPENDENTLY CONTROLS WAVES OF EARLY GENE EXPRESSION NECESSARY FOR HSC ACTIVATION. SIGNIFICANTLY, INHIBITION OF EITHER PROTEIN CAN REVERT THE CHRONIC ACTIVATION OF HSCS AND IMPEDE PATHOLOGICAL PROGRESSION OF LIVER FIBROSIS IN CLINICALLY RELEVANT MODEL SYSTEMS. IN THIS REVIEW WE WILL DISCUSS THE ROLES OF THESE NUCLEAR CO-ACTIVATORS IN HSC ACTIVATION, THEIR MECHANISM OF ACTION IN THE FIBROTIC PROCESS IN THE LIVER AND OTHER ORGANS, AND THE POTENTIAL OF TARGETING THEIR ACTIVITY WITH SMALL MOLECULE DRUGS FOR FIBROSIS REVERSAL. 2016 7 5795 26 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 8 6910 27 [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 9 3289 30 HIF-1ALPHA MEDIATES TUMOR HYPOXIA TO CONFER A PERPETUAL MESENCHYMAL PHENOTYPE FOR MALIGNANT PROGRESSION. ALTHOUGH TUMOR PROGRESSION INVOLVES GENETIC AND EPIGENETIC ALTERATIONS TO NORMAL CELLULAR BIOLOGY, THE UNDERLYING MECHANISMS OF THESE CHANGES REMAIN OBSCURE. NUMEROUS STUDIES HAVE SHOWN THAT HYPOXIA-INDUCIBLE FACTOR 1ALPHA (HIF-1ALPHA) IS OVEREXPRESSED IN MANY HUMAN CANCERS AND UP-REGULATES A HOST OF HYPOXIA-RESPONSIVE GENES FOR CANCER GROWTH AND SURVIVAL. WE RECENTLY IDENTIFIED AN ALTERNATIVE MECHANISM OF HIF-1ALPHA FUNCTION THAT INDUCES GENETIC ALTERATIONS BY SUPPRESSING DNA REPAIR. HERE, WE SHOW THAT LONG-TERM HYPOXIA, WHICH MIMICS THE TUMOR MICROENVIRONMENT, DRIVES A PERPETUAL EPITHELIAL-MESENCHYMAL TRANSITION (EMT) THROUGH UP-REGULATION OF THE ZINC FINGER E-BOX BINDING HOMEOBOX PROTEIN ZEB2, WHEREAS SHORT-TERM HYPOXIA INDUCES A REVERSIBLE EMT THAT REQUIRES THE TRANSCRIPTION FACTOR TWIST1. MOREOVER, WE SHOW THAT THE PERPETUAL EMT DRIVEN BY CHRONIC HYPOXIA DEPENDS ON HIF-1ALPHA INDUCTION OF GENETIC ALTERATIONS RATHER THAN ITS CANONICAL TRANSCRIPTIONAL ACTIVATOR FUNCTION. THESE MESENCHYMAL TUMOR CELLS NOT ONLY ACQUIRE TUMORIGENICITY BUT ALSO DISPLAY CHARACTERISTICS OF ADVANCED CANCERS, INCLUDING NECROSIS, AGGRESSIVE INVASION, AND METASTASIS. HENCE, THESE RESULTS REVEAL A MECHANISM BY WHICH HIF-1ALPHA PROMOTES A PERPETUAL MESENCHYMAL PHENOTYPE, THEREBY ADVANCING TUMOR PROGRESSION. 2011 10 699 19 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 11 952 23 CHRONIC MYELOID LEUKEMIA STEM CELL BIOLOGY. LEUKEMIA PROGRESSION AND RELAPSE IS FUELED BY LEUKEMIA STEM CELLS (LSC) THAT ARE RESISTANT TO CURRENT TREATMENTS. IN THE PROGRESSION OF CHRONIC MYELOID LEUKEMIA (CML), BLAST CRISIS PROGENITORS ARE CAPABLE OF ADOPTING MORE PRIMITIVE BUT DEREGULATED STEM CELL FEATURES WITH ACQUIRED RESISTANCE TO TARGETED THERAPIES. THIS IN TURN PROMOTES LSC BEHAVIOR CHARACTERIZED BY ABERRANT SELF-RENEWAL, DIFFERENTIATION, AND SURVIVAL CAPACITY. MULTIPLE REPORTS SUGGEST THAT CELL CYCLE ALTERATIONS, ACTIVATION OF CRITICAL SIGNALING PATHWAYS, ABERRANT MICROENVIRONMENTAL CUES FROM THE HEMATOPOIETIC NICHE, AND ABERRANT EPIGENETIC EVENTS AND DEREGULATION OF RNA PROCESSING MAY FACILITATE THE ENHANCED SURVIVAL AND MALIGNANT TRANSFORMATION OF CML PROGENITORS. HERE WE REVIEW THE MOLECULAR EVOLUTION OF CML LSC THAT PROMOTES CML PROGRESSION AND RELAPSE. RECENT ADVANCES IN THESE AREAS HAVE IDENTIFIED NOVEL TARGETS THAT REPRESENT IMPORTANT AVENUES FOR FUTURE THERAPEUTIC APPROACHES AIMED AT SELECTIVELY ERADICATING THE LSC POPULATION WHILE SPARING NORMAL HEMATOPOIETIC PROGENITORS IN PATIENTS SUFFERING FROM CHRONIC MYELOID MALIGNANCIES. 2012 12 4501 22 MORPHOGENS AND HEPATIC STELLATE CELL FATE REGULATION IN CHRONIC LIVER DISEASE. HEPATIC STELLATE CELLS (HSC) ARE THE LIVER MESENCHYMAL CELL TYPE WHICH RESPONDS TO HEPATOCELLULAR DAMAGE AND PARTICIPATES IN WOUND HEALING. ALTHOUGH HSC MYOFIBROBLASTIC TRANS-DIFFERENTIATION (ACTIVATION) IS IMPLICATED IN EXCESSIVE EXTRACELLULAR MATRIX DEPOSITION, MOLECULAR UNDERSTANDING OF THIS PHENOTYPIC SWITCH FROM THE VIEWPOINT OF CELL FATE REGULATION IS LIMITED. RECENT STUDIES DEMONSTRATE THE ROLES OF ANTI-ADIPOGENIC MORPHOGENS (WNT, NECDIN, SHH) IN EPIGENETIC REPRESSION OF THE HSC DIFFERENTIATION GENE PPARGAMMA AS A CAUSAL EVENT IN HSC ACTIVATION. THESE MORPHOGENS HAVE POSITIVE CROSS-INTERACTIONS WHICH CONVERGE TO EPIGENETIC REPRESSION OF PPARGAMMA INVOLVING THE METHYL-CPG BINDING PROTEIN MECP2. HOWEVER, THESE MORPHOGENS EXPRESSED BY ACTIVATED HSC MAY ALSO PARTICIPATE IN CROSS-TALK BETWEEN HSC AND HEPATOBLASTS/HEPATOCYTES TO SUPPORT LIVER REGENERATION, AND THEIR ABERRANT REGULATION MAY CONTRIBUTE TO LIVER TUMORIGENESIS. IMPLICATIONS OF HSC-DERIVED MORPHOGENS IN THESE POSSIBILITIES ARE DISCUSSED. 2012 13 3702 30 INFLAMMATORY SIGNALING PATHWAYS IN PRELEUKEMIC AND LEUKEMIC STEM CELLS. HEMATOPOIETIC STEM CELLS (HSCS) ARE A RARE SUBSET OF BONE MARROW CELLS THAT USUALLY EXIST IN A QUIESCENT STATE, ONLY ENTERING THE CELL CYCLE TO REPLENISH THE BLOOD COMPARTMENT, THEREBY LIMITING THE POTENTIAL FOR ERRORS IN REPLICATION. INFLAMMATORY SIGNALS THAT ARE RELEASED IN RESPONSE TO ENVIRONMENTAL STRESSORS, SUCH AS INFECTION, TRIGGER ACTIVE CYCLING OF HSCS. THESE INFLAMMATORY SIGNALS CAN ALSO DIRECTLY INDUCE HSCS TO RELEASE CYTOKINES INTO THE BONE MARROW ENVIRONMENT, PROMOTING MYELOID DIFFERENTIATION. AFTER STRESS MYELOPOIESIS IS TRIGGERED, HSCS REQUIRE INTRACELLULAR SIGNALING PROGRAMS TO DEACTIVATE THIS RESPONSE AND RETURN TO STEADY STATE. PROLONGED OR EXCESSIVE EXPOSURE TO INFLAMMATORY CYTOKINES, SUCH AS IN PROLONGED INFECTION OR IN CHRONIC RHEUMATOLOGIC CONDITIONS, CAN LEAD TO CONTINUED HSC CYCLING AND EVENTUAL HSC LOSS. THIS PROMOTES BONE MARROW FAILURE, AND CAN PRECIPITATE PRELEUKEMIC STATES OR LEUKEMIA THROUGH THE ACQUISITION OF GENETIC AND EPIGENETIC CHANGES IN HSCS. THIS CAN OCCUR THROUGH THE INITIATION OF CLONAL HEMATOPOIESIS, FOLLOWED BY THE EMERGENCE PRELEUKEMIC STEM CELLS (PRE-LSCS). IN THIS REVIEW, WE DESCRIBE THE ROLES OF MULTIPLE INFLAMMATORY SIGNALING PATHWAYS IN THE GENERATION OF PRE-LSCS AND IN PROGRESSION TO MYELODYSPLASTIC SYNDROME (MDS), MYELOPROLIFERATIVE NEOPLASMS, AND ACUTE MYELOID LEUKEMIA (AML). IN AML, ACTIVATION OF SOME INFLAMMATORY SIGNALING PATHWAYS CAN PROMOTE THE CYCLING AND DIFFERENTIATION OF LSCS, AND THIS CAN BE EXPLOITED THERAPEUTICALLY. WE ALSO DISCUSS THE THERAPEUTIC POTENTIAL OF MODULATING INFLAMMATORY SIGNALING FOR THE TREATMENT OF MYELOID MALIGNANCIES. 2017 14 2435 35 EPIGENETIC SILENCING OF SFRP1 ACTIVATES THE CANONICAL WNT PATHWAY AND CONTRIBUTES TO INCREASED CELL GROWTH AND PROLIFERATION IN HEPATOCELLULAR CARCINOMA. THE WNT PATHWAY IS A KEY REGULATOR OF EMBRYONIC DEVELOPMENT AND STEM CELLS, AND ITS ABERRANT ACTIVATION IS ASSOCIATED WITH HUMAN MALIGNANCIES, MOST NOTABLY HEPATOCELLULAR CARCINOMA (HCC). EPIGENETIC DEREGULATION OF THE GENES ENCODING THE SECRETED FRIZZLED-RELATED PROTEINS (SFRPS), THE WNT SIGNALLING ANTAGONISTS, HAS BEEN LINKED WITH ABERRANT HYPERACTIVATION OF THE WNT SIGNALLING IN HCC CELLS; HOWEVER, THE PRECISE UNDERLYING MECHANISM REMAINS ELUSIVE. WE INVESTIGATED THE METHYLATION PROFILES OF WNT ANTAGONISTS IN LIVER SAMPLES OF DIFFERENT STAGES OF HCC DEVELOPMENT AND LIVER CANCER CELL LINES AND STUDIED THE FUNCTIONAL IMPACT OF ABERRANT EPIGENETIC SILENCING OF SFRPS ON THE CANONICAL WNT PATHWAY AND CELL VIABILITY. WE FOUND THAT THE SFRP1 GENE ENCODING THE SUBUNIT IS A FREQUENT TARGET OF ABERRANT DNA HYPERMETHYLATION AND SILENCING IN HCC TUMOURS, WHEREAS OTHER EXTRACELLULAR WNT ANTAGONISTS, WIF1 AND DKK3, EXHIBITED NO METHYLATION IN TUMOUR CELLS, CONSISTENT WITH THE NOTION THAT ABERRANT METHYLATION EVENTS IN CANCER CELLS ARE NON-RANDOMLY DISTRIBUTED AMONG THE GENES AND THAT THERE IS A STRONG PREFERENCE FOR HYPERMETHYLATION OF SPECIFIC GENES IN HCC. IN ADDITION, BY COMPARING SFRP1 METHYLATION STATUS IN HCC TUMOURS WITH NORMAL, CIRRHOTIC AND CHRONIC HEPATITIS LIVER TISSUES, WE IDENTIFIED SFRP1 GENE AS A POTENTIAL EARLY MARKER OF HCC. THE RESTORATION OF SFRP1 EXPRESSION IN CANCER CELLS BY ECTOPIC EXPRESSION INHIBITED WNT ACTIVITY ACCOMPANIED WITH DESTABILIZATION OF BETA-CATENIN AND DOWNREGULATION OF C-MYC AND CYCLIN D1, THE KNOWN DOWNSTREAM TARGETS OF WNT PATHWAY. IMPORTANTLY, RESTORING SFRP1 LEVELS IN CANCER CELLS INHIBITED CELL GROWTH AND INDUCED APOPTOTIC CELL DEATH. THIS STUDY SUPPORTS THE CRITICAL ROLE FOR SFRP1 SILENCING IN HEPATOCELLULAR CARCINOMA AND REINFORCES THE IMPORTANCE OF THE WNT ANTAGONISTS IN PREVENTING ONCOGENIC STABILIZATION OF BETA-CATENIN AND CHRONIC ACTIVATION OF THE CANONICAL WNT PATHWAY, SUGGESTING THAT SFRP1 MAY BE AN ATTRACTIVE TARGET FOR EARLY CANCER DETECTION AND THERAPEUTIC INTERVENTION. 2012 15 4448 33 MOLECULAR MECHANISM AND TREATMENT OF VIRAL HEPATITIS-RELATED LIVER FIBROSIS. HEPATIC FIBROSIS IS A WOUND-HEALING RESPONSE TO VARIOUS CHRONIC STIMULI, INCLUDING VIRAL HEPATITIS B OR C INFECTION. ACTIVATED MYOFIBROBLASTS, PREDOMINANTLY DERIVED FROM THE HEPATIC STELLATE CELLS (HSCS), REGULATE THE BALANCE BETWEEN MATRIX METALLOPROTEINASES AND THEIR TISSUE INHIBITORS TO MAINTAIN EXTRACELLULAR MATRIX HOMEOSTASIS. TRANSFORMING GROWTH FACTOR-BETA AND PLATELET-DERIVED GROWTH FACTOR ARE CLASSIC PROFIBROGENIC SIGNALS THAT ACTIVATE HSC PROLIFERATION. IN ADDITION, PROINFLAMMATORY CYTOKINES AND CHEMOKINES COORDINATE MACROPHAGES, T CELLS, NK/NKT CELLS, AND LIVER SINUSOIDAL ENDOTHELIAL CELLS IN COMPLEX FIBROGENIC AND REGRESSION PROCESSES. IN ADDITION, FIBROGENESIS INVOLVES ANGIOGENESIS, METABOLIC REPROGRAMMING, AUTOPHAGY, MICRORNA, AND EPIGENETIC REGULATIONS. HEPATIC INFLAMMATION IS THE DRIVING FORCE BEHIND LIVER FIBROSIS; HOWEVER, HOST SINGLE NUCLEOTIDE POLYMORPHISMS AND VIRAL FACTORS, INCLUDING THE GENOTYPE, VIRAL LOAD, VIRAL MUTATION, AND VIRAL PROTEINS, HAVE BEEN ASSOCIATED WITH FIBROSIS PROGRESSION. ELIMINATING THE UNDERLYING ETIOLOGY IS THE MOST CRUCIAL ANTIFIBROTIC THERAPY. GROWING EVIDENCE HAS INDICATED THAT PERSISTENT VIRAL SUPPRESSION WITH ANTIVIRAL THERAPY CAN RESULT IN FIBROSIS REGRESSION, REDUCED LIVER DISEASE PROGRESSION, DECREASED HEPATOCELLULAR CARCINOMA, AND IMPROVED CHANCES OF SURVIVAL. PRECLINICAL STUDIES AND CLINICAL TRIALS ARE CURRENTLY EXAMINING SEVERAL INVESTIGATIONAL AGENTS THAT TARGET KEY FIBROGENIC PATHWAYS; THE RESULTS ARE PROMISING AND SHED LIGHT ON THIS DEBILITATING ILLNESS. 2014 16 6151 25 THE FIRE WITHIN: CELL-AUTONOMOUS MECHANISMS IN INFLAMMATION-DRIVEN CANCER. INFLAMMATORY CELLS ARE IMPORTANT FOR TUMOR INITIATION AND PROMOTION, PROVIDING CANCER CELLS WITH CYTOKINES THAT ENHANCE CELL PROLIFERATION AND SURVIVAL. ALTHOUGH MALIGNANT EPITHELIAL CELLS WERE TRADITIONALLY CONSIDERED TO BE ON THE RECEIVING END OF THESE MICROENVIRONMENTAL INTERACTIONS, RECENT STUDIES SHOW THAT EPITHELIAL CELLS CAN UNDERGO INFLAMMATORY REPROGRAMMING ON THEIR OWN. SUCH EPIGENETIC SWITCHES ARE OFTEN TRIGGERED BY CHRONIC TISSUE INJURY AND PLAY IMPORTANT ROLES IN TISSUE REPAIR. BY CONVERTING TERMINALLY DIFFERENTIATED CELLS THAT HARBOR EVEN A SINGLE ONCOGENIC MUTATION TO A LESS DIFFERENTIATED STATE WITH A HIGHER PROLIFERATIVE POTENTIAL, CELL-AUTONOMOUS INFLAMMATION IS AN IMPORTANT CONTRIBUTOR TO TUMOR INITIATION. 2019 17 3245 25 HEPATIC STELLATE CELLS AS KEY TARGET IN LIVER FIBROSIS. PROGRESSIVE LIVER FIBROSIS, INDUCED BY CHRONIC VIRAL AND METABOLIC DISORDERS, LEADS TO MORE THAN ONE MILLION DEATHS ANNUALLY VIA DEVELOPMENT OF CIRRHOSIS, ALTHOUGH NO ANTIFIBROTIC THERAPY HAS BEEN APPROVED TO DATE. TRANSDIFFERENTIATION (OR "ACTIVATION") OF HEPATIC STELLATE CELLS IS THE MAJOR CELLULAR SOURCE OF MATRIX PROTEIN-SECRETING MYOFIBROBLASTS, THE MAJOR DRIVER OF LIVER FIBROGENESIS. PARACRINE SIGNALS FROM INJURED EPITHELIAL CELLS, FIBROTIC TISSUE MICROENVIRONMENT, IMMUNE AND SYSTEMIC METABOLIC DYSREGULATION, ENTERIC DYSBIOSIS, AND HEPATITIS VIRAL PRODUCTS CAN DIRECTLY OR INDIRECTLY INDUCE STELLATE CELL ACTIVATION. DYSREGULATED INTRACELLULAR SIGNALING, EPIGENETIC CHANGES, AND CELLULAR STRESS RESPONSE REPRESENT CANDIDATE TARGETS TO DEACTIVATE STELLATE CELLS BY INDUCING REVERSION TO INACTIVATED STATE, CELLULAR SENESCENCE, APOPTOSIS, AND/OR CLEARANCE BY IMMUNE CELLS. CELL TYPE- AND TARGET-SPECIFIC PHARMACOLOGICAL INTERVENTION TO THERAPEUTICALLY INDUCE THE DEACTIVATION WILL ENABLE MORE EFFECTIVE AND LESS TOXIC PRECISION ANTIFIBROTIC THERAPIES. 2017 18 1479 25 DIVERSE TARGETS OF THE TRANSCRIPTION FACTOR STAT3 CONTRIBUTE TO T CELL PATHOGENICITY AND HOMEOSTASIS. STAT3, AN ESSENTIAL TRANSCRIPTION FACTOR WITH PLEIOTROPIC FUNCTIONS, PLAYS CRITICAL ROLES IN THE PATHOGENESIS OF AUTOIMMUNITY. DESPITE RECENT DATA LINKING STAT3 WITH INFLAMMATORY BOWEL DISEASE, EXACTLY HOW IT CONTRIBUTES TO CHRONIC INTESTINAL INFLAMMATION IS NOT KNOWN. USING A T CELL TRANSFER MODEL OF COLITIS, WE FOUND THAT STAT3 EXPRESSION IN T CELLS WAS ESSENTIAL FOR THE INDUCTION OF BOTH COLITIS AND SYSTEMIC INFLAMMATION. STAT3 WAS CRITICAL IN MODULATING THE BALANCE OF T HELPER 17 (TH17) AND REGULATORY T (TREG) CELLS, AS WELL AS IN PROMOTING CD4(+) T CELL PROLIFERATION. WE USED CHROMATIN IMMUNOPRECIPITATION AND MASSIVE PARALLEL SEQUENCING (CHIP-SEQ) TO DEFINE THE GENOME-WIDE TARGETS OF STAT3 IN CD4(+) T CELLS. WE FOUND THAT STAT3 BOUND TO MULTIPLE GENES INVOLVED IN TH17 CELL DIFFERENTIATION, CELL ACTIVATION, PROLIFERATION, AND SURVIVAL, REGULATING BOTH EXPRESSION AND EPIGENETIC MODIFICATIONS. THUS, STAT3 ORCHESTRATES MULTIPLE CRITICAL ASPECTS OF T CELL FUNCTION IN INFLAMMATION AND HOMEOSTASIS. 2010 19 5695 25 SILENCING UHRF1 ENHANCES CELL AUTOPHAGY TO PREVENT ARTICULAR CHONDROCYTES FROM APOPTOSIS IN OSTEOARTHRITIS THROUGH PI3K/AKT/MTOR SIGNALING PATHWAY. OSTEOARTHRITIS (OA) IS A COMMON CHRONIC DEGENERATIVE JOINT DISEASE, AND CHONDROCYTE APOPTOSIS IS ONE OF MOST IMPORTANT PATHOLOGICAL CHANGES OF OA PATHOGENESIS. GROWING STUDIES HAVE SHOWN THAT UBIQUITIN-LIKE WITH PHD AND RING FINGER DOMAINS 1 (UHRF1) IS AN IMPORTANT EPIGENETIC REGULATORY FACTOR THAT REGULATES CELL PROLIFERATION AND APOPTOSIS OF VARIOUS TUMORS, BUT ITS ROLE IN OA REMAINS ILL-DEFINED. IN THE PRESENT STUDY, WE FOUND THAT UHRF1 EXPRESSION WAS INCREASED IN HUMAN OA CARTILAGE TISSUES, COMPARED WITH NORMAL CARTILAGE TISSUES. INTERLEUKIN-1BETA (IL-1BETA), A MAJOR INFLAMMATORY CYTOKINE THAT PROMOTES CARTILAGE DEGRADATION IN OA, WAS USED TO STIMULATE PRIMARY HUMAN CHONDROCYTES IN VITRO. THE EXPRESSION OF UHRF1 WAS ALSO ENHANCED IN IL-1BETA-INDUCED CHONDROCYTES. MOREOVER, DOWN-REGULATION OF UHRF1 INDUCED AN INCREASE ON CELL PROLIFERATION AND AUTOPHAGY, AND A DECREASE ON APOPTOSIS OF CHONDROCYTES AFTER IL-1BETA TREATMENT. FURTHER DATA INDICATED THAT SILENCING UHRF1 ATTENUATED THE UP-REGULATION OF IL-1BETA ON PHOSPHOINOSITIDE 3-KINASE (PI3K)/PROTEIN KINASE B (AKT)/MAMMALIAN TARGET OF RAPAMYCIN (MTOR) SIGNALING PATHWAY IN CHONDROCYTES. THEN, AN ACTIVATOR OF PI3K WEAKENED THE EFFECT OF UHRF1 SILENCING ON CELL PROLIFERATION, AUTOPHAGY, APOPTOSIS OF IL-1BETA-INDUCED CHONDROCYTES, AND THE CELL AUTOPHAGY SPECIAL INHIBITOR 3-METHYLADENINE (3-MA) ALSO SHOWED A SAME IMPACT ON UHRF1, HENCE SUGGESTING THAT KNOCKDOWN OF UHRF1 ENHANCES CELL AUTOPHAGY TO PROTECT CHONDROCYTES FROM APOPTOSIS IN OA THROUGH PI3K/AKT/MTOR SIGNALING PATHWAY. IN CONCLUSION, OUR STUDY SUGGESTS THAT UHRF1 MAY BE A POTENTIAL REGULATOR OF CHONDROCYTE APOPTOSIS IN THE PATHOGENESIS OF OA. 2020 20 3946 28 LNCRNA MALAT1 BINDS CHROMATIN REMODELING SUBUNIT BRG1 TO EPIGENETICALLY PROMOTE INFLAMMATION-RELATED HEPATOCELLULAR CARCINOMA PROGRESSION. HEPATOCELLULAR CARCINOMA (HCC) IS ONE TYPE OF CANCERS WHOSE CARCINOGENESIS AND PROGRESSION ARE CLOSELY RELATED TO CHRONIC INFLAMMATION. IDENTIFYING THE MOLECULAR MECHANISMS FOR INFLAMMATION-RELATED HCC PROGRESSION WILL CONTRIBUTE TO IMPROVE THE EFFICACY OF CURRENT THERAPEUTICS FOR HCC PATIENTS. MANY KINDS OF EPIGENETIC FACTORS, INCLUDING LONG NON-CODING RNAS (LNCRNAS), HAVE BEEN DISCOVERED TO BE IMPORTANT IN HCC GROWTH AND METASTASIS. HOWEVER, HOW THE LNCRNAS PROMOTE HCC PROGRESSION AND WHAT'S THE APPLICATION OF LNCRNA SILENCING IN VIVO IN SUPPRESSING HCC REMAIN TO BE FURTHER INVESTIGATED. HERE, WE FOUND THAT LNCRNA METASTASIS ASSOCIATED LUNG ADENOCARCINOMA TRANSCRIPT1 (MALAT1) WAS UPREGULATED IN HCC TUMOR TISSUES, AND KNOCKDOWN OF MALAT1 SUPPRESSED PROLIFERATION, CELL CYCLE AND INVASION OF HCC CELLS IN RESPONSE TO LIPOPOLYSACCHARIDE (LPS) STIMULATION. KNOCKDOWN OF MALAT1 SIGNIFICANTLY INHIBITED LPS-INDUCED PRO-INFLAMMATORY MEDIATORS IL-6 AND CXCL8 EXPRESSION IN HCC CELLS, WHICH COULD BE RESTORED BY OVEREXPRESSING MALAT1. MECHANISTICALLY, MALAT1 RECRUITED BRAHMA-RELATED GENE 1 (BRG1), A CATALYTIC SUBUNIT OF CHROMATIN REMODELING COMPLEX SWITCHING/SUCROSE NON-FERMENTABLE (SWI/SNF), TO THE PROMOTER REGION OF IL-6 AND CXCL8, AND THUS FACILITATED NF-KAPPAB TO INDUCE THE EXPRESSION OF THESE INFLAMMATORY FACTORS. IMPORTANTLY, IN VIVO SILENCING OF MALAT1 IN HCC TISSUES INHIBITED GROWTH OF HCC XENOGRAFTS, AND ALSO SUPPRESSED THE EXPRESSION OF PRO-INFLAMMATORY FACTORS IN HCC TISSUES ACCORDINGLY. OUR RESULTS DEMONSTRATE THAT MALAT1 PROMOTES HCC PROGRESSION BY BINDING BRG1 TO EPIGENETICALLY ENHANCE INFLAMMATORY RESPONSE IN HCC TISSUES, AND SILENCING OF MALAT1 MAY BE A POTENTIAL APPROACH TO THE TREATMENT OF HCC. 2019