1 446 148 APABETALONE DOWNREGULATES FIBROTIC, INFLAMMATORY AND CALCIFIC PROCESSES IN RENAL MESANGIAL CELLS AND PATIENTS WITH RENAL IMPAIRMENT. EPIGENETIC MECHANISMS ARE IMPLICATED IN TRANSCRIPTIONAL PROGRAMS DRIVING CHRONIC KIDNEY DISEASE (CKD). APABETALONE IS AN ORALLY AVAILABLE INHIBITOR OF BROMODOMAIN AND EXTRATERMINAL (BET) PROTEINS, WHICH ARE EPIGENETIC READERS THAT MODULATE GENE EXPRESSION. IN THE PHASE 3 BETONMACE TRIAL, APABETALONE REDUCED RISK OF MAJOR ADVERSE CARDIAC EVENTS (MACE) BY 50% IN THE CKD SUBPOPULATION, INDICATING FAVORABLE EFFECTS ALONG THE KIDNEY-HEART AXIS. ACTIVATION OF HUMAN RENAL MESANGIAL CELLS (HRMCS) TO A CONTRACTILE PHENOTYPE THAT OVERPRODUCES EXTRACELLULAR MATRIX (ECM) AND INFLAMMATORY CYTOKINES, AND PROMOTES CALCIFICATION, FREQUENTLY ACCOMPANIES CKD TO DRIVE PATHOLOGY. HERE, WE SHOW APABETALONE DOWNREGULATED HRMC ACTIVATION WITH TGF-BETA1 STIMULATION BY SUPPRESSING TGF-BETA1-INDUCED ALPHA-SMOOTH MUSCLE ACTIN (ALPHA-SMA) EXPRESSION, ALPHA-SMA ASSEMBLY INTO STRESS FIBERS, ENHANCED CONTRACTION, COLLAGEN OVERPRODUCTION, AND EXPRESSION OF KEY DRIVERS OF FIBROSIS, INFLAMMATION, OR CALCIFICATION INCLUDING THROMBOSPONDIN, FIBRONECTIN, PERIOSTIN, SPARC, INTERLEUKIN 6, AND ALKALINE PHOSPHATASE. LIPOPOLYSACCHARIDE-STIMULATED EXPRESSION OF INFLAMMATORY GENES IL6, IL1B, AND PTGS2 WAS ALSO SUPPRESSED. TRANSCRIPTOMICS CONFIRMED APABETALONE AFFECTED GENE SETS OF ECM REMODELING AND INTEGRINS. CLINICAL TRANSLATION OF IN VITRO RESULTS WAS INDICATED IN CKD PATIENTS WHERE A SINGLE DOSE OF APABETALONE REDUCED PLASMA LEVELS OF KEY PRO-FIBROTIC AND INFLAMMATORY MARKERS, AND INDICATED INHIBITION OF TGF-BETA1 SIGNALING. WHILE PLASMA PROTEINS CANNOT BE TRACED TO THE KIDNEY ALONE, ANTI-FIBROTIC AND ANTI-INFLAMMATORY EFFECTS OF APABETALONE IDENTIFIED IN THIS STUDY ARE CONSISTENT WITH THE OBSERVED DECREASE IN CARDIOVASCULAR RISK IN CKD PATIENTS. 2023 2 5907 34 TARGET-BASED SMALL MOLECULE DRUG DISCOVERY TOWARDS NOVEL THERAPEUTICS FOR INFLAMMATORY BOWEL DISEASES. INFLAMMATORY BOWEL DISEASE (IBD), INCLUDING ULCERATIVE COLITIS (UC) AND CROHN'S DISEASE (CD), IS A CLASS OF SEVERE AND CHRONIC DISEASES OF THE GASTROINTESTINAL (GI) TRACT WITH RECURRENT SYMPTOMS AND SIGNIFICANT MORBIDITY. LONG-TERM PERSISTENCE OF CHRONIC INFLAMMATION IN IBD IS A MAJOR CONTRIBUTING FACTOR TO NEOPLASTIC TRANSFORMATION AND THE DEVELOPMENT OF COLITIS-ASSOCIATED COLORECTAL CANCER. CONVERSELY, PERSISTENCE OF TRANSMURAL INFLAMMATION IN CD IS ASSOCIATED WITH FORMATION OF FIBROSING STRICTURES, RESULTING IN SUBSTANTIAL MORBIDITY. THE RECENT INTRODUCTION OF BIOLOGICAL RESPONSE MODIFIERS AS IBD THERAPIES, SUCH AS ANTIBODIES NEUTRALIZING TUMOR NECROSIS FACTOR (TNF)-ALPHA, HAVE REPLACED NONSELECTIVE ANTI-INFLAMMATORY CORTICOSTEROIDS IN DISEASE MANAGEMENT. HOWEVER, A LARGE PROPORTION (~40%) OF PATIENTS WITH THE TREATMENT OF ANTI-TNF-ALPHA ANTIBODIES ARE DISCONTINUED OR WITHDRAWN FROM THERAPY BECAUSE OF (1) PRIMARY NONRESPONSE, (2) SECONDARY LOSS OF RESPONSE, (3) OPPORTUNISTIC INFECTION, OR (4) ONSET OF CANCER. THEREFORE, THE DEVELOPMENT OF NOVEL AND EFFECTIVE THERAPEUTICS TARGETING SPECIFIC SIGNALING PATHWAYS IN THE PATHOGENESIS OF IBD IS URGENTLY NEEDED. IN THIS COMPREHENSIVE REVIEW, WE SUMMARIZE THE RECENT ADVANCES IN DRUG DISCOVERY OF NEW SMALL MOLECULES IN PRECLINICAL OR CLINICAL DEVELOPMENT FOR TREATING IBD THAT TARGET BIOLOGICALLY RELEVANT PATHWAYS IN MUCOSAL INFLAMMATION. THESE INCLUDE INTRACELLULAR ENZYMES (JANUS KINASES, RECEPTOR INTERACTING PROTEIN, PHOSPHODIESTERASE 4, IKAPPAB KINASE), INTEGRINS, G PROTEIN-COUPLED RECEPTORS (S1P, CCR9, CXCR4, CB2) AND INFLAMMASOME MEDIATORS (NLRP3), ETC. WE WILL ALSO DISCUSS EMERGING EVIDENCE OF A DISTINCT MECHANISM OF ACTION, BROMODOMAIN-CONTAINING PROTEIN 4, AN EPIGENETIC REGULATOR OF PATHWAYS INVOLVED IN THE ACTIVATION, COMMUNICATION, AND TRAFFICKING OF IMMUNE CELLS. WE HIGHLIGHT THEIR CHEMOTYPES, MODE OF ACTIONS, STRUCTURE-ACTIVITY RELATIONSHIPS, CHARACTERIZATIONS, AND THEIR IN VITRO/IN VIVO ACTIVITIES AND THERAPEUTIC POTENTIAL. THE PERSPECTIVES ON THE RELEVANT CHALLENGES, NEW OPPORTUNITIES, AND FUTURE DIRECTIONS IN THIS FIELD ARE ALSO DISCUSSED. 2021 3 6621 30 UNDERSTANDING FIBROSIS IN SYSTEMIC SCLEROSIS: SHIFTING PARADIGMS, EMERGING OPPORTUNITIES. FIBROSIS IN MULTIPLE ORGANS IS A PROMINENT PATHOLOGICAL FINDING AND DISTINGUISHING HALLMARK OF SYSTEMIC SCLEROSIS (SSC). FINDINGS DURING THE PAST 5 YEARS HAVE CONTRIBUTED TO A MORE COMPLETE UNDERSTANDING OF THE COMPLEX CELLULAR AND MOLECULAR UNDERPINNING OF FIBROSIS IN SSC. FIBROBLASTS, THE PRINCIPAL EFFECTOR CELLS, ARE ACTIVATED IN THE PROFIBROTIC CELLULAR MILIEU BY CYTOKINES AND GROWTH FACTORS, DEVELOPMENTAL PATHWAYS, ENDOTHELIN 1 AND THROMBIN. INNATE IMMUNE SIGNALING VIA TOLL-LIKE RECEPTORS, MATRIX-GENERATED BIOMECHANICAL STRESS SIGNALING VIA INTEGRINS, HYPOXIA AND OXIDATIVE STRESS SEEM TO BE IMPLICATED IN PERPETUATING THE PROCESS. BEYOND CHRONIC FIBROBLAST ACTIVATION, FIBROSIS REPRESENTS A FAILURE TO TERMINATE TISSUE REPAIR, COUPLED WITH AN EXPANDED POPULATION OF MESENCHYMAL CELLS ORIGINATING FROM BONE MARROW AND TRANSDIFFERENTIATION OF EPITHELIAL CELLS, ENDOTHELIAL CELLS AND PERICYTES. IN ADDITION, STUDIES HAVE IDENTIFIED INTRINSIC ALTERATIONS IN SSC FIBROBLASTS RESULTING FROM EPIGENETIC CHANGES, AS WELL AS ALTERED MICRORNA EXPRESSION THAT MIGHT UNDERLIE THE CELL-AUTONOMOUS, PERSISTENT ACTIVATION PHENOTYPE OF THESE CELLS. PRECISE CHARACTERIZATION OF THE DEREGULATED EXTRACELLULAR AND INTRACELLULAR SIGNALING PATHWAYS, MEDIATORS AND CELLULAR DIFFERENTIATION PROGRAMS THAT CONTRIBUTE TO FIBROSIS IN SSC WILL FACILITATE THE DEVELOPMENT OF SELECTIVE, TARGETED THERAPEUTIC STRATEGIES. EFFECTIVE ANTIFIBROTIC THERAPY WILL ULTIMATELY INVOLVE NOVEL COMPOUNDS AND REPURPOSING OF DRUGS THAT ARE ALREADY APPROVED FOR OTHER INDICATIONS. 2011 4 6394 32 THE ROLE OF THE HOST-NEUTROPHIL BIOLOGY. NEUTROPHILIC POLYMORPHONUCLEAR LEUKOCYTES (NEUTROPHILS) ARE MYELOID CELLS PACKED WITH LYSOSOMAL GRANULES (HENCE ALSO CALLED GRANULOCYTES) THAT CONTAIN A FORMIDABLE ANTIMICROBIAL ARSENAL. THEY ARE TERMINALLY DIFFERENTIATED CELLS THAT PLAY A CRITICAL ROLE IN ACUTE AND CHRONIC INFLAMMATION, AS WELL AS IN THE RESOLUTION OF INFLAMMATION AND WOUND HEALING. NEUTROPHILS EXPRESS A DENSE ARRAY OF SURFACE RECEPTORS FOR MULTIPLE LIGANDS, RANGING FROM INTEGRINS TO SUPPORT THEIR EGRESS FROM BONE MARROW INTO THE CIRCULATION AND FROM THE CIRCULATION INTO TISSUES, TO CYTOKINE/CHEMOKINE RECEPTORS THAT DRIVE THEIR NAVIGATION TO THE SITE OF INFECTION OR TISSUE DAMAGE AND ALSO PRIME THEM FOR A SECOND STIMULUS, TO PATTERN RECOGNITION RECEPTORS AND IMMUNOGLOBULIN RECEPTORS TO FACILITATE THE DESTRUCTION AND REMOVAL OF INFECTIVE AGENTS OR DEBRIDEMENT OF DAMAGED TISSUES. WHEN AFFERENT NEUTROPHIL SIGNALS ARE PROPORTIONATE AND COORDINATED THEY WILL PHAGOCYTOSE OPSONIZED AND UNOPSONIZED BACTERIA, ACTIVATING THE NICOTINAMIDE ADENINE DINUCLEOTIDE PHOSPHATE OXIDASE (RESPIRATORY BURST) TO GENERATE REACTIVE OXYGEN SPECIES, WHICH AUGMENT THE PROTEOLYTIC DESTRUCTION OF MICROBES SECURED WITHIN THE PHAGOSOME. A HIGHLY ORCHESTRATED PROCESS OF APOPTOSIS FOLLOWS, FORMING MEMBRANE-BOUND SUBSTRUCTURES THAT ARE REMOVED BY MACROPHAGES. NEUTROPHILS ARE CAPABLE OF VARIOUS OTHER FORMS OF PROGRAMMED CELL DEATH, SUCH AS NETOSIS AND PYROPTOTIC CELL DEATH, AS WELL AS NONPROGRAMMED CELL DEATH BY NECROSIS. IN RECENT YEARS, RESEARCH HAS REVEALED THAT NEUTROPHILS ARE CAPABLE OF FAR MORE SUBTLE CELL-CELL INTERACTIONS THAN PREVIOUSLY THOUGHT POSSIBLE. THIS INCLUDES SYNTHESIS OF VARIOUS INFLAMMATORY MEDIATORS AND ALSO MYELOID CELL TRAINING WITHIN BONE MARROW, WHERE EPIGENETIC AND METABOLIC SIGNALS ASSOCIATED WITH RETURNING NEUTROPHILS THAT UNDERGO REVERSE EGRESS FROM TISSUES INTO THE VASCULATURE AND BACK TO BONE MARROW PROGRAM A HYPERREACTIVE SUBSET OF NEUTROPHILS DURING MYELOPOIESIS THAT ARE CAPABLE OF HYPERSENSITIVE REACTIONS TO MICROBIAL AGGRESSORS. THESE CHARACTERISTICS ARE EVIDENT IN VARIOUS NEUTROPHIL SUBSETS/SUBPOPULATIONS, CREATING BROAD HETEROGENEITY IN THE BEHAVIOR AND BIOLOGICAL REPERTOIRE OF THESE SEEMINGLY SCHIZOPHRENIC IMMUNE CELLS. MOREOVER, NEUTROPHILS ARE CRITICAL EFFECTOR CELLS OF ADAPTIVE AND INNATE IMMUNITY, BINDING TO OPSONIZED BACTERIA AND DESTROYING THEM BY EXTRACELLULAR AND INTRACELLULAR METHODS. THE FORMER CREATES SUBSTANTIAL COLLATERAL HOST TISSUE DAMAGE, AS THEY ARE LESS SPECIFIC THAN T-CYTOTOXIC CELL-KILLING MECHANISMS, AND IN CONDITIONS SUCH AS PERI-IMPLANTITIS, WHERE PLASMA CELLS AND NEUTROPHILS DOMINATE THE IMMUNE INFILTRATE, BONE AND TISSUE DESTRUCTION ARE RAPID AND APPEAR RELENTLESS. FINALLY, THE ROLE OF NEUTROPHILS AS CONDUITS FOR PERIODONTAL-SYSTEMIC DISEASE CONNECTIONS AND FOR OXIDATIVE DAMAGE TO ACT AS A CAUSAL LINK BETWEEN THE TWO HAS ONLY RECENTLY BEEN REALIZED. IN THIS CHAPTER, WE ATTEMPT TO EXPAND ON THESE ISSUES, EMPHASIZING THE CONTRIBUTIONS OF EUROPEAN SCIENTISTS THROUGHOUT A DETAILED APPRAISAL OF THE BENEFITS AND SIDE EFFECTS OF NEUTROPHILIC INFLAMMATION AND IMMUNE FUNCTION. 2023 5 111 30 A ROLE FOR G-PROTEIN COUPLED ESTROGEN RECEPTOR (GPER) IN ESTROGEN-INDUCED CARCINOGENESIS: DYSREGULATED GLANDULAR HOMEOSTASIS, SURVIVAL AND METASTASIS. MECHANISMS OF CARCINOGENESIS BY ESTROGEN CENTER ON ITS MITOGENIC AND GENOTOXIC POTENTIAL ON TUMOR TARGET CELLS. THESE MODELS SUGGEST THAT ESTROGEN RECEPTOR (ER) SIGNALING PROMOTES EXPANSION OF THE TRANSFORMED POPULATION AND THAT SUBSEQUENT ACCUMULATION OF SOMATIC MUTATIONS THAT DRIVE CANCER PROGRESSION OCCUR VIA METABOLIC ACTIVATION OF CATHECOL ESTROGENS OR BY EPIGENETIC MECHANISMS. RECENT FINDINGS THAT GPER IS LINKED TO OBESITY, VASCULAR PATHOLOGY AND IMMUNOSUPPRESSION, KEY EVENTS IN THE DEVELOPMENT OF METABOLIC SYNDROME AND INTRA-TISSULAR ESTROGEN SYNTHESIS, PROVIDES AN ALTERNATE VIEW OF ESTROGEN-INDUCED CARCINOGENESIS. CONSISTENT WITH THIS CONCEPT, GPER IS DIRECTLY ASSOCIATED WITH CLINICOPATHOLOGICAL INDICES THAT PREDICT CANCER PROGRESSION AND POOR SURVIVAL IN BREAST AND GYNECOLOGICAL CANCERS. MOREOVER, GPER MANIFESTS CELL BIOLOGICAL RESPONSES AND A MICROENVIRONMENT CONDUCIVE FOR TUMOR DEVELOPMENT AND CANCER PROGRESSION, REGULATING CELLULAR RESPONSES ASSOCIATED WITH GLANDULAR HOMEOSTASIS AND SURVIVAL, INVADING SURROUNDING TISSUE AND ATTRACTING A VASCULAR SUPPLY. THUS, THE CELLULAR ACTIONS ATTRIBUTED TO GPER FIT WELL WITH THE KNOWN MOLECULAR MECHANISMS OF G-PROTEIN COUPLED RECEPTORS, GPCRS, NAMELY, THEIR ABILITY TO TRANSACTIVATE INTEGRINS AND EGF RECEPTORS AND ALTER THE INTERACTION BETWEEN GLANDULAR EPITHELIA AND THEIR EXTRACELLULAR ENVIRONMENT, AFFECTING EPITHELIAL-TO-MESENCHYMAL TRANSITION (EMT) AND ALLOWING FOR TUMOR CELL SURVIVAL AND DISSEMINATION. THIS PERSPECTIVE REVIEWS THE MOLECULAR AND CELLULAR RESPONSES MANIFESTED BY GPER AND EVALUATES ITS CONTRIBUTION TO FEMALE REPRODUCTIVE CANCERS AS DISEASES THAT PROGRESS AS A RESULT OF DYSREGULATED GLANDULAR HOMEOSTASIS RESULTING IN CHRONIC INFLAMMATION AND METASTASIS. THIS REVIEW IS ORGANIZED IN SECTIONS AS FOLLOWS: I) A BRIEF SYNOPSIS OF THE CURRENT STATE OF KNOWLEDGE REGARDING ESTROGEN-INDUCED CARCINOGENESIS, II) A REVIEW OF EVIDENCE FROM CLINICAL AND ANIMAL-BASED STUDIES THAT SUPPORT A ROLE FOR GPER IN CANCER PROGRESSION, AND III) A MECHANISTIC FRAMEWORK DESCRIBING HOW GPER-MEDIATED ESTROGEN ACTION MAY INFLUENCE THE TUMOR AND ITS MICROENVIRONMENT. 2018 6 4211 34 METFORMIN FOR CARDIOVASCULAR PROTECTION, INFLAMMATORY BOWEL DISEASE, OSTEOPOROSIS, PERIODONTITIS, POLYCYSTIC OVARIAN SYNDROME, NEURODEGENERATION, CANCER, INFLAMMATION AND SENESCENCE: WHAT IS NEXT? DIABETES IS ACCOMPANIED BY SEVERAL COMPLICATIONS. HIGHER PREVALENCE OF CANCERS, CARDIOVASCULAR DISEASES, CHRONIC KIDNEY DISEASE (CKD), OBESITY, OSTEOPOROSIS, AND NEURODEGENERATIVE DISEASES HAS BEEN REPORTED AMONG PATIENTS WITH DIABETES. METFORMIN IS THE OLDEST ORAL ANTIDIABETIC DRUG AND CAN IMPROVE COEXISTING COMPLICATIONS OF DIABETES. CLINICAL TRIALS AND OBSERVATIONAL STUDIES UNCOVERED THAT METFORMIN CAN REMARKABLY PREVENT OR ALLEVIATE CARDIOVASCULAR DISEASES, OBESITY, POLYCYSTIC OVARIAN SYNDROME (PCOS), OSTEOPOROSIS, CANCER, PERIODONTITIS, NEURONAL DAMAGE AND NEURODEGENERATIVE DISEASES, INFLAMMATION, INFLAMMATORY BOWEL DISEASE (IBD), TUBERCULOSIS, AND COVID-19. IN ADDITION, METFORMIN HAS BEEN PROPOSED AS AN ANTIAGING AGENT. NUMEROUS MECHANISMS WERE SHOWN TO BE INVOLVED IN THE PROTECTIVE EFFECTS OF METFORMIN. METFORMIN ACTIVATES THE LKB1/AMPK PATHWAY TO INTERACT WITH SEVERAL INTRACELLULAR SIGNALING PATHWAYS AND MOLECULAR MECHANISMS. THE DRUG MODIFIES THE BIOLOGIC FUNCTION OF NF-KAPPAB, PI3K/AKT/MTOR, SIRT1/PGC-1ALPHA, NLRP3, ERK, P38 MAPK, WNT/BETA-CATENIN, NRF2, JNK, AND OTHER MAJOR MOLECULES IN THE INTRACELLULAR SIGNALING NETWORK. IT ALSO REGULATES THE EXPRESSION OF NONCODING RNAS. THEREBY, METFORMIN CAN REGULATE METABOLISM, GROWTH, PROLIFERATION, INFLAMMATION, TUMORIGENESIS, AND SENESCENCE. ADDITIONALLY, METFORMIN MODULATES IMMUNE RESPONSE, AUTOPHAGY, MITOPHAGY, ENDOPLASMIC RETICULUM (ER) STRESS, AND APOPTOSIS AND EXERTS EPIGENETIC EFFECTS. FURTHERMORE, METFORMIN PROTECTS AGAINST OXIDATIVE STRESS AND GENOMIC INSTABILITY, PRESERVES TELOMERE LENGTH, AND PREVENTS STEM CELL EXHAUSTION. IN THIS REVIEW, THE PROTECTIVE EFFECTS OF METFORMIN ON EACH DISEASE WILL BE DISCUSSED USING THE RESULTS OF RECENT META-ANALYSES, CLINICAL TRIALS, AND OBSERVATIONAL STUDIES. THEREAFTER, IT WILL BE METICULOUSLY EXPLAINED HOW METFORMIN REPROGRAMS INTRACELLULAR SIGNALING PATHWAYS AND ALTERS MOLECULAR AND CELLULAR INTERACTIONS TO MODIFY THE CLINICAL PRESENTATIONS OF SEVERAL DISEASES. 2021 7 6687 20 VALIDATION OF THE EPIGENETIC READER BROMODOMAIN-CONTAINING PROTEIN 4 (BRD4) AS A THERAPEUTIC TARGET FOR TREATMENT OF AIRWAY REMODELING. STRUCTURAL REMODELING IS CENTRAL TO THE INITIATION AND PROGRESSION OF MANY CHRONIC LUNG DISEASES, REPRESENTING AN IMPORTANT UNMET NEED. WE EXAMINE THE EVIDENCE SUPPORTING BROMODOMAIN-CONTAINING PROTEIN 4 (BRD4) AS A VALIDATED BIOLOGICAL TARGET FOR TREATMENT OF AIRWAY REMODELING. IN EPITHELIAL CELLS AND FIBROBLASTS, BRD4 SERVES AS A SCAFFOLD FOR CHROMATIN REMODELING COMPLEXES IN ACTIVE SUPER-ENHANCERS. IN RESPONSE TO INFLAMMATORY STIMULI, BRD4 IS REPOSITIONED TO INNATE AND MESENCHYMAL GENES ACTIVATING THEIR PRODUCTION. PROOF-OF-CONCEPT STUDIES SHOW PROMISING BENEFIT OF SELECTIVE BRD4 INHIBITORS IN DISRUPTING EPITHELIAL MESENCHYMAL TRANSITION AND MYOFIBROBLAST TRANSITION IN DIVERSE MODELS OF LUNG INJURY. RECENT IDENTIFICATION OF BIOMARKERS OF BRD4 PROVIDES A BASIS FOR FURTHER DRUG DEVELOPMENT FOR APPLICATION IN VIRAL-INDUCED AIRWAY INFLAMMATION, COPD AND INTERSTITIAL LUNG DISEASES. 2020 8 5939 38 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 9 4582 34 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 10 593 47 BET PROTEIN INHIBITION REGULATES CYTOKINE PRODUCTION AND PROMOTES NEUROPROTECTION AFTER SPINAL CORD INJURY. BACKGROUND: SPINAL CORD INJURY (SCI) USUALLY CAUSES A DEVASTATING LIFELONG DISABILITY FOR PATIENTS. AFTER A TRAUMATIC LESION, DISRUPTION OF THE BLOOD-SPINAL CORD BARRIER INDUCES THE INFILTRATION OF MACROPHAGES INTO THE LESION SITE AND THE ACTIVATION OF RESIDENT GLIAL CELLS, WHICH RELEASE CYTOKINES AND CHEMOKINES. THESE EVENTS RESULT IN A PERSISTENT INFLAMMATION, WHICH HAS BOTH DETRIMENTAL AND BENEFICIAL EFFECTS, BUT EVENTUALLY LIMITS FUNCTIONAL RECOVERY AND CONTRIBUTES TO THE APPEARANCE OF NEUROPATHIC PAIN. BROMODOMAIN AND EXTRA-TERMINAL DOMAIN (BET) PROTEINS ARE EPIGENETIC READERS THAT REGULATE THE EXPRESSION OF INFLAMMATORY GENES BY INTERACTING WITH ACETYLATED LYSINE RESIDUES. WHILE BET INHIBITORS ARE A PROMISING THERAPEUTIC STRATEGY FOR CANCER, LITTLE IS KNOWN ABOUT THEIR IMPLICATION AFTER SCI. THUS, THE CURRENT STUDY WAS AIMED TO INVESTIGATE THE ANTI-INFLAMMATORY ROLE OF BET INHIBITORS IN THIS PATHOLOGIC CONDITION. METHODS: WE EVALUATED THE EFFECTIVENESS OF THE BET INHIBITOR JQ1 TO MODIFY MACROPHAGE REACTIVITY IN VITRO AND TO MODULATE INFLAMMATION IN A SCI MICE MODEL. WE ANALYZED THE EFFECTS OF BET INHIBITION IN PRO-INFLAMMATORY AND ANTI-INFLAMMATORY CYTOKINE PRODUCTION IN VITRO AND IN VIVO. WE DETERMINED THE EFFECTIVENESS OF BET INHIBITION IN TISSUE SPARING, INFLAMMATION, NEURONAL PROTECTION, AND BEHAVIORAL OUTCOME AFTER SCI. RESULTS: WE HAVE FOUND THAT THE BET INHIBITOR JQ1 REDUCED THE LEVELS OF PRO-INFLAMMATORY MEDIATORS AND INCREASED THE EXPRESSION OF ANTI-INFLAMMATORY CYTOKINES. A PROLONGED TREATMENT WITH JQ1 ALSO DECREASED REACTIVITY OF MICROGLIA/MACROPHAGES, ENHANCED NEUROPROTECTION AND FUNCTIONAL RECOVERY, AND ACUTELY REDUCED NEUROPATHIC PAIN AFTER SCI. CONCLUSIONS: BET PROTEIN INHIBITION IS AN EFFECTIVE TREATMENT TO REGULATE CYTOKINE PRODUCTION AND PROMOTE NEUROPROTECTION AFTER SCI. THESE NOVEL RESULTS DEMONSTRATE FOR THE FIRST TIME THAT TARGETING BET PROTEINS IS AN ENCOURAGING APPROACH FOR SCI REPAIR AND A POTENTIAL STRATEGY TO TREAT OTHER INFLAMMATORY PATHOLOGIES. 2019 11 445 61 APABETALONE (RVX-208) REDUCES VASCULAR INFLAMMATION IN VITRO AND IN CVD PATIENTS BY A BET-DEPENDENT EPIGENETIC MECHANISM. BACKGROUND: APABETALONE (RVX-208) IS A BROMODOMAIN AND EXTRATERMINAL PROTEIN INHIBITOR (BETI) THAT IN PHASE II TRIALS REDUCED THE RELATIVE RISK (RR) OF MAJOR ADVERSE CARDIAC EVENTS (MACE) IN PATIENTS WITH CARDIOVASCULAR DISEASE (CVD) BY 44% AND IN DIABETIC CVD PATIENTS BY 57% ON TOP OF STATINS. A PHASE III TRIAL, BETONMACE, IS CURRENTLY ASSESSING APABETALONE'S ABILITY TO REDUCE MACE IN STATIN-TREATED POST-ACUTE CORONARY SYNDROME TYPE 2 DIABETIC CVD PATIENTS WITH LOW HIGH-DENSITY LIPOPROTEIN C. THE LEADING CAUSE OF MACE IS ATHEROSCLEROSIS, DRIVEN BY DYSFUNCTIONAL LIPID METABOLISM AND CHRONIC VASCULAR INFLAMMATION (VI). IN VITRO STUDIES HAVE IMPLICATED THE BET PROTEIN BRD4 AS AN EPIGENETIC DRIVER OF INFLAMMATION AND ATHEROGENESIS, SUGGESTING THAT BETI MAY BE CLINICALLY EFFECTIVE IN COMBATING VI. HERE, WE ASSESSED APABETALONE'S ABILITY TO REGULATE INFLAMMATION-DRIVEN GENE EXPRESSION AND CELL ADHESION IN VITRO AND INVESTIGATED THE MECHANISM BY WHICH APABETALONE SUPPRESSES EXPRESSION. THE CLINICAL IMPACT OF APABETALONE ON MEDIATORS OF VI WAS ASSESSED WITH PROTEOMIC ANALYSIS OF PHASE II CVD PATIENT PLASMA. RESULTS: IN VITRO, APABETALONE PREVENTED INFLAMMATORY (TNFALPHA, LPS, OR IL-1BETA) INDUCTION OF KEY FACTORS THAT DRIVE ENDOTHELIAL ACTIVATION, MONOCYTE RECRUITMENT, ADHESION, AND PLAQUE DESTABILIZATION. BRD4 ABUNDANCE ON INFLAMMATORY AND ADHESION GENE PROMOTERS AND ENHANCERS WAS REDUCED BY APABETALONE. BRD2-4 DEGRADATION BY MZ-1 ALSO PREVENTED TNFALPHA-INDUCED TRANSCRIPTION OF MONOCYTE AND ENDOTHELIAL CELL ADHESION MOLECULES AND INFLAMMATORY MEDIATORS, CONFIRMING BET-DEPENDENT REGULATION. TRANSCRIPTIONAL REGULATION BY APABETALONE TRANSLATED INTO A REDUCTION IN MONOCYTE ADHESION TO AN ENDOTHELIAL MONOLAYER. IN A PHASE II TRIAL, APABETALONE TREATMENT REDUCED THE ABUNDANCE OF MULTIPLE VI MEDIATORS IN THE PLASMA OF CVD PATIENTS (SOMASCAN(R) 1.3 K). THESE PROTEINS CORRELATE WITH CVD RISK AND INCLUDE ADHESION MOLECULES, CYTOKINES, AND METALLOPROTEINASES. INGENUITY(R) PATHWAY ANALYSIS (IPA(R)) PREDICTED THAT APABETALONE INHIBITS PRO-ATHEROGENIC REGULATORS AND PATHWAYS AND PREVENTS DISEASE STATES ARISING FROM LEUKOCYTE RECRUITMENT. CONCLUSIONS: APABETALONE SUPPRESSED GENE EXPRESSION OF VI MEDIATORS IN MONOCYTES AND ENDOTHELIAL CELLS BY INHIBITING BET-DEPENDENT TRANSCRIPTION INDUCED BY MULTIPLE INFLAMMATORY STIMULI. IN CVD PATIENTS, APABETALONE TREATMENT REDUCED CIRCULATING LEVELS OF VI MEDIATORS, AN OUTCOME CONDUCIVE WITH ATHEROSCLEROTIC PLAQUE STABILIZATION AND MACE REDUCTION. INHIBITION OF INFLAMMATORY AND ADHESION MOLECULE GENE EXPRESSION BY APABETALONE IS PREDICTED TO CONTRIBUTE TO MACE REDUCTION IN THE PHASE III BETONMACE TRIAL. 2019 12 3931 24 LIVER INJURY AND THE ACTIVATION OF THE HEPATIC MYOFIBROBLASTS. LIVER FIBROSIS IS A WOUND HEALING PROCESS, THE END RESULT OF CHRONIC LIVER INJURY ELICITED BY DIFFERENT NOXIOUS STIMULI. ACTIVATED HEPATIC STELLATE CELLS OR MYOFIBROBLASTS AND PORTAL MYOFIBROBLASTS ARE CONSIDERED AS THE MAIN PRODUCERS OF THE EXTRACELLULAR MATRIX IN THE LIVER. UPON LIVER INJURY THE QUIESCENT STELLATE CELLS TRANSDIFFERENTIATE INTO MYOFIBROBLASTS A PROCESS HIGHLIGHTED BY THE LOSS OF VITAMIN A STORES, UPREGULATION OF INTERSTITIAL TYPE COLLAGENS, SMOOTH MUSCLE ALPHA ACTIN, MATRIX METALLOPROTEINASES, PROTEOGLYCANS, AND THE INDUCTION OF CELL SURVIVAL PATHWAYS. ACTIVATION OF HEPATIC STELLATE CELLS IS A RESULT OF A COMPLEX INTERPLAY BETWEEN THE PARENCHYMAL CELLS, IMMUNE CELLS, EXTRACELLULAR MATRIX MECHANICS AND EXTRAHEPATIC MILIEU SUCH AS THE GUT MICROBIOME. IN THIS REVIEW WE WILL FOCUS ON THE PATHOMECHANISM OF STELLATE CELL ACTIVATION FOLLOWING CHRONIC LIVER INJURY; WITH THE AIM OF IDENTIFYING POSSIBLE TREATMENT TARGETS FOR ANTI-FIBROGENIC AGENTS. 2013 13 3245 20 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 14 6456 37 THYMOSIN BETA4 PREVENTS OXIDATIVE STRESS, INFLAMMATION, AND FIBROSIS IN ETHANOL- AND LPS-INDUCED LIVER INJURY IN MICE. THYMOSIN BETA 4 (TBETA4), AN ACTIN-SEQUESTERING PROTEIN, IS INVOLVED IN TISSUE DEVELOPMENT AND REGENERATION. IT PREVENTS INFLAMMATION AND FIBROSIS IN SEVERAL TISSUES. WE INVESTIGATED THE ROLE OF TBETA4 IN CHRONIC ETHANOL- AND ACUTE LIPOPOLYSACCHARIDE- (LPS-) INDUCED MOUSE LIVER INJURY. C57BL/6 MICE WERE FED 5% ETHANOL IN LIQUID DIET FOR 4 WEEKS PLUS BINGE ETHANOL (5 G/KG, GAVAGE) WITH OR WITHOUT LPS (2 MG/KG, INTRAPERITONEAL) FOR 6 HOURS. TBETA4 (1 MG/KG, INTRAPERITONEAL) WAS ADMINISTERED FOR 1 WEEK. WE DEMONSTRATED THAT TBETA4 PREVENTED ETHANOL- AND LPS-MEDIATED INCREASE IN LIVER INJURY MARKERS AS WELL AS CHANGES IN LIVER PATHOLOGY. IT ALSO PREVENTED ETHANOL- AND LPS-MEDIATED INCREASE IN OXIDATIVE STRESS BY DECREASING ROS AND LIPID PEROXIDATION AND INCREASING THE ANTIOXIDANTS, REDUCED GLUTATHIONE AND MANGANESE-DEPENDENT SUPEROXIDE DISMUTASE. IT ALSO PREVENTED THE ACTIVATION OF NUCLEAR FACTOR KAPPA B BY BLOCKING THE PHOSPHORYLATION OF THE INHIBITORY PROTEIN, IKAPPAB, THEREBY PREVENTED PROINFLAMMATORY CYTOKINE PRODUCTION. MOREOVER, TBETA4 PREVENTED FIBROGENESIS BY SUPPRESSING THE EPIGENETIC REPRESSOR, METHYL-CPG-BINDING PROTEIN 2, THAT COORDINATELY REVERSED THE EXPRESSION OF PEROXISOME PROLIFERATOR-ACTIVATED RECEPTOR-GAMMA AND DOWNREGULATED FIBROGENIC GENES, PLATELET-DERIVED GROWTH FACTOR-BETA RECEPTOR, ALPHA-SMOOTH MUSCLE ACTIN, COLLAGEN 1, AND FIBRONECTIN, RESULTING IN REDUCED FIBROSIS. OUR DATA SUGGEST THAT TBETA4 HAS ANTIOXIDANT, ANTI-INFLAMMATORY, AND ANTIFIBROTIC POTENTIAL DURING ALCOHOLIC LIVER INJURY. 2018 15 2239 43 EPIGENETIC MODULATION BY APABETALONE COUNTERS CYTOKINE-DRIVEN ACUTE PHASE RESPONSE IN VITRO, IN MICE AND IN PATIENTS WITH CARDIOVASCULAR DISEASE. CHRONIC SYSTEMIC INFLAMMATION CONTRIBUTES TO CARDIOVASCULAR DISEASE (CVD) AND CORRELATES WITH THE ABUNDANCE OF ACUTE PHASE RESPONSE (APR) PROTEINS IN THE LIVER AND PLASMA. BROMODOMAIN AND EXTRATERMINAL (BET) PROTEINS ARE EPIGENETIC READERS THAT REGULATE INFLAMMATORY GENE TRANSCRIPTION. WE SHOW THAT BET INHIBITION BY THE SMALL MOLECULE APABETALONE REDUCES APR GENE AND PROTEIN EXPRESSION IN HUMAN HEPATOCYTES, MOUSE MODELS, AND PLASMA FROM CVD PATIENTS. STEADY-STATE EXPRESSION OF SERUM AMYLOID P, PLASMINOGEN ACTIVATOR INHIBITOR 1, AND CERULOPLASMIN, APR PROTEINS LINKED TO CVD RISK, IS REDUCED BY APABETALONE IN CULTURED HEPATOCYTES AND IN HUMANIZED MOUSE LIVER. IN CYTOKINE-STIMULATED HEPATOCYTES, APABETALONE REDUCES THE EXPRESSION OF C-REACTIVE PROTEIN (CRP), ALPHA-2-MACROGLOBULIN, AND SERUM AMYLOID P. THE LATTER TWO ARE ALSO REDUCED BY APABETALONE IN THE LIVER OF ENDOTOXEMIC MICE. BET KNOCKDOWN IN VITRO ALSO COUNTERS CYTOKINE-MEDIATED INDUCTION OF THE CRP GENE. MECHANISTICALLY, APABETALONE REDUCES THE CYTOKINE-DRIVEN INCREASE IN BRD4 BET OCCUPANCY AT THE CRP PROMOTER, CONFIRMING THAT TRANSCRIPTION OF CRP IS BET-DEPENDENT. IN PATIENTS WITH STABLE CORONARY DISEASE, PLASMA APR PROTEINS CRP, IL-1 RECEPTOR ANTAGONIST, AND FIBRINOGEN GAMMA DECREASE AFTER APABETALONE TREATMENT VERSUS PLACEBO, RESULTING IN A PREDICTED DOWNREGULATION OF THE APR PATHWAY AND CYTOKINE TARGETS. WE CONCLUDE THAT CRP AND COMPONENTS OF THE APR PATHWAY ARE REGULATED BY BET PROTEINS AND THAT APABETALONE COUNTERS CHRONIC CYTOKINE SIGNALING IN PATIENTS. 2020 16 6757 39 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 17 699 37 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 18 6910 32 [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 19 1255 32 CURRENT STATUS OF NOVEL ANTIFIBROTIC THERAPIES IN PATIENTS WITH CHRONIC LIVER DISEASE. FIBROSIS ACCUMULATION IS A DYNAMIC PROCESS RESULTING FROM A WOUND-HEALING RESPONSE TO ACUTE OR CHRONIC LIVER INJURY OF ALL CAUSES. THE CASCADE STARTS WITH HEPATOCYTE NECROSIS AND APOPTOSIS, WHICH INSTIGATE INFLAMMATORY SIGNALING BY CHEMOKINES AND CYTOKINES, RECRUITMENT OF IMMUNE CELL POPULATIONS, AND ACTIVATION OF FIBROGENIC CELLS, CULMINATING IN THE DEPOSITION OF EXTRACELLULAR MATRIX. THESE KEY ELEMENTS, ALONG WITH PATHWAYS OF TRANSCRIPTIONAL AND EPIGENETIC REGULATION, REPRESENT FERTILE THERAPEUTIC TARGETS. NEW THERAPIES INCLUDE DRUGS SPECIFICALLY DESIGNED AS ANTIFIBROTICS, AS WELL AS DRUGS ALREADY AVAILABLE WITH WELL-ESTABLISHED SAFETY PROFILES, WHOSE MECHANISM OF ACTION MAY ALSO BE ANTIFIBROTIC. AT THE SAME TIME, THE DEVELOPMENT OF NONINVASIVE FIBROGENIC MARKERS, AND TECHNIQUES (E.G. FIBROSCAN), AS WELL AS COMBINED SCORING SYSTEMS INCORPORATING SERUM AND CLINICAL FEATURES WILL ALLOW IMPROVED ASSESSMENT OF THERAPY RESPONSE. IN AGGREGATE, THE ADVANCES IN THE ELUCIDATION OF THE BIOLOGY OF FIBROSIS, COMBINED WITH IMPROVED TECHNOLOGIES FOR ASSESSMENT WILL PROVIDE A COMPREHENSIVE FRAMEWORK FOR DESIGN OF ANTIFIBROTICS AND THEIR ANALYSIS IN WELL-DESIGNED CLINICAL TRIALS. THESE EFFORTS MAY ULTIMATELY YIELD SUCCESS IN HALTING THE PROGRESSION OF, OR REVERSING, LIVER FIBROSIS. 2011 20 4044 23 MACROPHAGES IN OXIDATIVE STRESS AND MODELS TO EVALUATE THE ANTIOXIDANT FUNCTION OF DIETARY NATURAL COMPOUNDS. ANTIOXIDANT TESTING OF NATURAL PRODUCTS HAS ATTRACTED INCREASING INTEREST IN RECENT YEARS, MAINLY DUE TO THE FACT THAT AN ANTIOXIDANT-RICH DIET MIGHT PROVIDE HEALTH BENEFITS. ACTIVATED MACROPHAGES ARE A MAJOR SOURCE OF REACTIVE OXYGEN SPECIES, REACTIVE NITROGEN SPECIES, AND PEROXYNITRITE GENERATED THROUGH THE SO-CALLED RESPIRATORY BURST. CONSTITUTIVELY RELEASED PROINFLAMMATORY CYTOKINE, ESPECIALLY TUMOR NECROSIS FACTOR-ALPHA, TRIGGERS NUCLEAR FACTOR-KAPPAB, AND ACTIVATOR PROTEIN-1 TRANSLOCATION LEADING TO THE OVER PRODUCTION OF REACTIVE OXYGEN SPECIES AND REACTIVE NITROGEN SPECIES IN MACROPHAGES. ACTIVATION OF TRANSCRIPTION FACTORS IN THE LONG-LIVED TISSUE-RESIDENT MACROPHAGES AND/OR MONOCYTE-DERIVED MACROPHAGES, TRIGGER EPIGENETIC MODIFICATIONS LEADING TO THE PATHOGENESIS OF CHRONIC DISEASES. NUTRACEUTICALS INCLUDING LIPID RAFT STRUCTURE DISRUPTION AGENT, CHOLESTEROL DEPLETION AGENT, FARNESYLTRANSFERASE INHIBITOR, NUCLEAR FACTOR-KAPPAB BLOCKER (ALPHA,BETA-UNSATURATED CARBONYL COMPOUNDS), GLUCOCORTICOID RECEPTOR AGONIST, AND PEROXISOME PROLIFERATOR-ACTIVATED RECEPTOR-GAMMA AGONIST HAVE LONG BEEN USED TO INACTIVE MACROPHAGE. THE INHIBITION EFFECTS ON THE FORMATION OF NITRIC OXIDE, SUPEROXIDE, AND NITRITE PEROXIDE MAY BE RESPONSIBLE FOR THE ANTI-INFLAMMATORY FUNCTIONALITIES. ACTIVATED MACROPHAGE MODELS COULD BE USED TO IDENTIFY THE ACTIVE COMPONENTS FOR FUNCTIONAL DIETS DEVELOPMENT THROUGH A MULTIPLE TARGETS STRATEGY. 2017