1 4575 117 MYOFIBROBLASTS. PURPOSE OF REVIEW: INTEREST IN THE MYOFIBROBLAST AS A KEY PLAYER IN PROPAGATION OF CHRONIC PROGRESSIVE FIBROSIS CONTINUES TO ELICIT MANY PUBLICATIONS, WITH FOCUS ON ITS CELLULAR ORIGINS AND THE MECHANISMS UNDERPINNING THEIR DIFFERENTIATION AND/OR TRANSITION. THE OBJECTIVE OF THE REVIEW IS TO HIGHLIGHT THIS RECENT PROGRESS. RECENT FINDINGS: THE EPITHELIAL ORIGIN OF THE MYOFIBROBLAST IN FIBROSIS HAS BEEN CHALLENGED BY RECENT STUDIES, WITH THE PERICYTE SUGGESTED AS A POSSIBLE PRECURSOR INSTEAD. ADDITIONAL SIGNALING PATHWAYS, INCLUDING NOTCH, WNT, AND HEDGEHOG, ARE IMPLICATED IN MYOFIBROBLAST DIFFERENTIATION. THE IMPORTANCE OF NADPH OXIDASE 4 WAS HIGHLIGHTED RECENTLY TO SUGGEST A POTENTIAL LINK BETWEEN CELLULAR/OXIDATIVE STRESS AND THE GENESIS OF THE MYOFIBROBLAST. RECENT OBSERVATIONS ON THE IMPORTANCE OF LYSOPHOSPHATIDIC ACID IN FIBROSIS SUGGEST THAT THIS MAY BE DUE, IN PART, TO ITS ABILITY TO REGULATE MYOFIBROBLAST DIFFERENTIATION. FINALLY, THERE IS INCREASING EVIDENCE FOR THE ROLE OF EPIGENETIC MECHANISMS IN REGULATING MYOFIBROBLAST DIFFERENTIATION, INCLUDING DNA METHYLATION AND MIRNA REGULATION OF GENE EXPRESSION. SUMMARY: THESE RECENT DISCOVERIES OPEN UP A WHOLE NEW ARRAY OF POTENTIAL TARGETS FOR NOVEL ANTIFIBROTIC THERAPIES. THIS IS OF SPECIAL IMPORTANCE GIVEN THE CURRENT BLEAK OUTLOOK FOR CHRONIC PROGRESSIVE FIBROTIC DISEASES, SUCH AS SCLERODERMA, DUE TO LACK OF EFFECTIVE THERAPIES. 2013 2 197 33 ACINAR ATP8B1/LPC PATHWAY PROMOTES MACROPHAGE EFFEROCYTOSIS AND CLEARANCE OF INFLAMMATION DURING CHRONIC PANCREATITIS DEVELOPMENT. NONINFLAMMATORY CLEARANCE OF DYING CELLS BY PROFESSIONAL PHAGOCYTES, TERMED EFFEROCYTOSIS, IS FUNDAMENTAL IN BOTH HOMEOSTASIS AND INFLAMMATORY FIBROSIS DISEASE BUT HAS NOT BEEN CONFIRMED TO OCCUR IN CHRONIC PANCREATITIS (CP). HERE, WE INVESTIGATED WHETHER EFFEROCYTOSIS CONSTITUTES A NOVEL REGULATORY TARGET IN CP AND ITS MECHANISMS. PRSS1 TRANSGENIC (PRSS1(TG)) MICE WERE TREATED WITH CAERULEIN TO MIMIC CP DEVELOPMENT. PHOSPHOLIPID METABOLITE PROFILING AND EPIGENETIC ASSAYS WERE PERFORMED WITH PRSS1(TG) CP MODELS. THE POTENTIAL FUNCTIONS OF ATP8B1 IN CP MODEL WERE CLARIFIED USING ATP8B1-OVEREXPRESSING ADENO-ASSOCIATED VIRUS, IMMUNOFLUORESCENCE, ENZYME-LINKED IMMUNOSORBENT ASSAY(ELISA), AND LIPID METABOLOMIC APPROACHES. ATAC-SEQ COMBINED WITH RNA-SEQ WAS THEN USED TO IDENTIFY TRANSCRIPTION FACTORS BINDING TO THE ATP8B1 PROMOTER, AND CHIP-QPCR AND LUCIFERASE ASSAYS WERE USED TO CONFIRM THAT THE IDENTIFIED TRANSCRIPTION FACTOR BOUND TO THE ATP8B1 PROMOTER, AND TO IDENTIFY THE SPECIFIC BINDING SITE. FLOW CYTOMETRY WAS PERFORMED TO ANALYZE THE PROPORTION OF PANCREATIC MACROPHAGES. DECREASED EFFEROCYTOSIS WITH AGGRAVATED INFLAMMATION WAS IDENTIFIED IN CP. THE LYSOPHOSPHATIDYLCHOLINE (LPC) PATHWAY WAS THE MOST OBVIOUSLY DYSREGULATED PHOSPHOLIPID PATHWAY, AND LPC AND ATP8B1 EXPRESSION GRADUALLY DECREASED DURING CP DEVELOPMENT. H3K27ME3 CHIP-SEQ SHOWED THAT INCREASED ATP8B1 PROMOTER METHYLATION LED TO TRANSCRIPTIONAL INHIBITION. ATP8B1 COMPLEMENTATION SUBSTANTIALLY INCREASED THE LPC CONCENTRATION AND IMPROVED CP OUTCOMES. BHLHA15 WAS IDENTIFIED AS A TRANSCRIPTION FACTOR THAT BINDS TO THE ATP8B1 PROMOTER AND REGULATES PHOSPHOLIPID METABOLISM. OUR STUDY INDICATES THAT THE ACINAR ATP8B1/LPC PATHWAY ACTS AS AN IMPORTANT "FIND-ME" SIGNAL FOR MACROPHAGES AND PLAYS A PROTECTIVE ROLE IN CP, WITH ATP8B1 TRANSCRIPTION PROMOTED BY THE ACINAR CELL-SPECIFIC TRANSCRIPTION FACTOR BHLHA15. BHLHA15, ATP8B1, AND LPC COULD BE CLINICALLY TRANSLATED INTO VALUABLE THERAPEUTIC TARGETS TO OVERCOME THE LIMITATIONS OF CURRENT CP THERAPIES. 2022 3 4358 27 MIR-338-3P BLOCKS TGFBETA-INDUCED MYOFIBROBLAST DIFFERENTIATION THROUGH THE INDUCTION OF PTEN. IDIOPATHIC PULMONARY FIBROSIS (IPF) IS A CHRONIC INTERSTITIAL LUNG DISEASE. THE PATHOGENESIS OF IPF IS NOT COMPLETELY UNDERSTOOD. HOWEVER, NUMEROUS GENES ARE ASSOCIATED WITH THE DEVELOPMENT AND PROGRESSION OF PULMONARY FIBROSIS, INDICATING THERE IS A SIGNIFICANT GENETIC COMPONENT TO THE PATHOGENESIS OF IPF. EPIGENETIC INFLUENCES ON THE DEVELOPMENT OF HUMAN DISEASE, INCLUDING PULMONARY FIBROSIS, REMAIN TO BE FULLY ELUCIDATED. IN THIS PAPER, WE IDENTIFY MIR-338-3P AS A MICRORNA SEVERELY DOWNREGULATED IN THE LUNGS OF PATIENTS WITH PULMONARY FIBROSIS AND IN EXPERIMENTAL MODELS OF PULMONARY FIBROSIS. TREATMENT OF PRIMARY HUMAN LUNG FIBROBLASTS WITH MIR-338-3P INHIBITS MYOFIBROBLAST DIFFERENTIATION AND MATRIX PROTEIN PRODUCTION. PUBLISHED AND PROPOSED TARGETS OF MIR-338-3P SUCH AS TGFBETA RECEPTOR 1, MEK/ERK 1/2, CDK4, AND CYCLIN D ARE ALSO NOT RESPONSIBLE FOR THE REGULATION OF PULMONARY FIBROBLAST BEHAVIOR BY MIR-338-3P. MIR-338-3P INHIBITS MYOFIBROBLAST DIFFERENTIATION BY PREVENTING TGFBETA-MEDIATED DOWNREGULATION OF PHOSPHATASE AND TENSIN HOMOLOG (PTEN), A KNOWN ANTIFIBROTIC MEDIATOR. 2022 4 5394 31 REDUCED DNA METHYLATION OF SPHINGOSINE-1 PHOSPHATE RECEPTOR 5 IN ALVEOLAR MACROPHAGES IN COPD: A POTENTIAL LINK TO FAILED EFFEROCYTOSIS. BACKGROUND AND OBJECTIVE: WE PREVIOUSLY SHOWED THAT ALVEOLAR MACROPHAGES FROM COPD PATIENTS ARE DEFECTIVE IN THEIR ABILITY TO PHAGOCYTOSE APOPTOTIC CELLS ('EFFEROCYTOSIS') AND THAT THIS DEFECT IS POTENTIALLY LINKED TO THE SPHINGOSINE-1 PHOSPHATE (S1P) SYSTEM, IN PARTICULAR THE SPHINGOSINE-1 PHOSPHATE RECEPTOR 5 (S1PR5). IN ALVEOLAR MACROPHAGES FROM COPD PATIENTS, S1PR5 MRNA EXPRESSION LEVELS INCREASED AND WERE CORRELATED WITH BOTH LUNG FUNCTION AND EFFEROCYTOSIS. HOWEVER, IT US UNKNOWN WHETHER THESE CHANGES ARE UNDER EPIGENETIC CONTROL VIA DNA METHYLATION OR WHETHER DNA METHYLATION DIRECTLY MODULATES MACROPHAGE FUNCTION. METHODS: BISULFITE SEQUENCING WAS USED TO ASSESS DNA METHYLATION LEVELS AT CPG ISLANDS ASSOCIATED WITH GENES ENCODING SELECTED S1P SYSTEM COMPONENTS, INCLUDING SPHINGOSINE KINASE 1 (SPHK1), S1PR1 AND S1PR5, IN ALVEOLAR MACROPHAGES FROM 20 COPD PATIENTS, 7 HEALTHY SMOKERS AND 10 HEALTHY NON/EX-SMOKERS) BY METHYL QUANTITATIVE REAL-TIME PCR (METHYL QPCR). THE EFFECT OF THE DNA METHYLTRANSFERASE INHIBITOR, 5-AZACYTIDINE ON THE EFFEROCYTOSIS CAPACITY OF THP-1 MACROPHAGES WAS ASSESSED USING FLOW CYTOMETRY. RESULTS: AMONG THE S1P SYSTEM GENES EXAMINED, S1PR5 WAS THE SINGLE TARGET THAT SHOWED SIGNIFICANT CHANGES IN DNA METHYLATION BETWEEN PATIENT GROUPS. ALVEOLAR MACROPHAGES ISOLATED FROM COPD PATIENTS SHOWED LOWER METHYLATION LEVELS IN THE SAME REGION COMPARED TO MACROPHAGES FROM NON/EX-SMOKERS. IN VITRO STUDIES USING THP-1 MACROPHAGES SHOWED THAT DNA DEMETHYLATION WITH 5-AZACYTIDINE INCREASED THE EFFEROCYTOSIS CAPACITY AND DOSE-DEPENDENTLY RESCUED THE CELLS FROM THE CIGARETTE SMOKE-INDUCED DEFECT IN EFFEROCYTOSIS. CONCLUSION: MACROPHAGE FUNCTION CAN BE MODULATED EPIGENETICALLY. REDUCED METHYLATION MAY UNDERLIE THE INCREASED EXPRESSION OF THE S1PR5 GENE IN ALVEOLAR MACROPHAGES AND ASSOCIATED DEFECTIVE EFFEROCYTOSIS IN COPD. 2017 5 3245 26 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 6 6647 34 UPDATE OF PERICYTES FUNCTION AND THEIR ROLES IN KIDNEY DISEASES. STUDIES HAVE HIGHLIGHTED THE SIGNIFICANT INVOLVEMENT OF KIDNEY PERICYTES IN RENAL FIBROSIS. KIDNEY PERICYTES, CLASSIFIED AS INTERSTITIAL MESENCHYMAL CELLS, ARE EXTENSIVELY BRANCHED, COLLAGEN-PRODUCING CELLS THAT CLOSELY INTERACT WITH ENDOTHELIAL CELLS. THIS ARTICLE AIMS TO PROVIDE AN OVERVIEW OF THE RECENT ADVANCEMENTS IN UNDERSTANDING THE PHYSIOLOGICAL FUNCTIONS OF PERICYTES AND THEIR ROLES IN KIDNEY DISEASES. IN A HEALTHY KIDNEY, PERICYTES HAVE ESSENTIAL PHYSIOLOGICAL FUNCTION IN ANGIOGENESIS, ERYTHROPOIETIN (EPO) PRODUCTION, AND THE REGULATION OF RENAL BLOOD FLOW. NEVERTHELESS, PERICYTE-MYOFIBROBLAST TRANSITION HAS BEEN IDENTIFIED AS THE PRIMARY CAUSE OF DISEASE PROGRESSION IN ACUTE KIDNEY INJURY (AKI)-TO-CHRONIC KIDNEY DISEASE (CKD) CONTINUUM. OUR RECENT RESEARCH HAS DEMONSTRATED THAT HYPOXIA-INDUCIBLE FACTOR-2ALPHA (HIF-2ALPHA) REGULATES ERYTHROPOIETIN PRODUCTION IN PERICYTES. HOWEVER, THIS PRODUCTION IS REPRESSED BY EPO GENE HYPERMETHYLATION AND HIF-2ALPHA DOWNREGULATION WHICH WERE INDUCED BY TRANSFORMING GROWTH FACTOR-BETA1-ACTIVATED DNA METHYLTRANSFERASE AND ACTIVIN RECEPTOR-LIKE KINASE-5 SIGNALING PATHWAY DURING RENAL FIBROSIS, RESPECTIVELY. ADDITIONALLY, AKI INDUCES EPIGENETIC MODIFICATIONS IN PERICYTES, RENDERING THEM MORE PRONE TO EXTRACELLULAR MATRIX PRODUCTION, CELL MIGRATION AND PROLIFERATION, THEREBY CONTRIBUTING TO SUBSEQUENT CAPILLARY RAREFACTION AND RENAL FIBROSIS. FURTHER INVESTIGATION INTO THE SPECIFIC FUNCTIONS AND ROLES OF DIFFERENT SUBPOPULATIONS OF PERICYTES MAY CONTRIBUTE FOR THE DEVELOPMENT OF TARGETED THERAPIES AIMED AT ATTENUATING KIDNEY DISEASE AND MITIGATING THEIR ADVERSE EFFECTS. 2023 7 4097 28 MATRIX STIFFNESS REGULATES MACROPHAGE POLARIZATION IN ATHEROSCLEROSIS. ATHEROSCLEROSIS IS A CHRONIC INFLAMMATORY DISEASE AND THE PATHOLOGICAL BASIS OF MANY FATAL CARDIOVASCULAR DISEASES. MACROPHAGES, THE MAIN INFLAMMATORY CELLS IN ATHEROSCLEROTIC PLAQUE, HAVE A PARADOX ROLE IN DISEASE PROGRESSION. IN RESPONSE TO DIFFERENT MICROENVIRONMENTS, MACROPHAGES MAINLY HAVE TWO POLARIZED DIRECTIONS: PRO-INFLAMMATORY MACROPHAGES AND ANTI-INFLAMMATORY MACROPHAGES. MORE AND MORE EVIDENCE SHOWS THAT MACROPHAGE IS MECHANOSENSITIVE AND MATRIX STIFFNESS REGULATE MACROPHAGE PHENOTYPES IN ATHEROSCLEROSIS. HOWEVER, THE MOLECULAR MECHANISM OF MATRIX STIFFNESS REGULATING MACROPHAGE POLARIZATION STILL LACKS IN-DEPTH RESEARCH, WHICH HINDERS THE DEVELOPMENT OF NEW ANTI-ATHEROSCLEROTIC THERAPIES. IN THIS REVIEW, WE DISCUSS THE IMPORTANT ROLE OF MATRIX STIFFNESS IN REGULATING MACROPHAGE POLARIZATION THROUGH MECHANICAL SIGNAL TRANSDUCTION (HIPPO, PIEZO, CYTOSKELETON, AND INTEGRIN) AND EPIGENETIC MECHANISMS (MIRNA, DNA METHYLATION, AND HISTONE). WE HOPE TO PROVIDE A NEW PERSPECTIVE FOR ATHEROSCLEROSIS THERAPY BY TARGETING MATRIX STIFFNESS AND MACROPHAGE POLARIZATION. 2022 8 5733 36 SMALL MOLECULES AGAINST THE ORIGIN AND ACTIVATION OF MYOFIBROBLAST FOR RENAL INTERSTITIAL FIBROSIS THERAPY. RENAL INTERSTITIAL FIBROSIS (RIF) IS A COMMON PATHOLOGICAL RESPONSE IN A BROAD RANGE OF PREVALENT CHRONIC KIDNEY DISEASES AND ULTIMATELY LEADS TO RENAL FAILURE AND DEATH. ALTHOUGH RIF CAUSES A HIGH MORBI-MORTALITY WORLDWIDE, EFFECTIVE THERAPEUTIC DRUGS ARE URGENTLY NEEDED. MYOFIBROBLASTS ARE IDENTIFIED AS THE MAIN EFFECTOR DURING THE PROCESS OF RIF. MULTIPLE TYPES OF CELLS, INCLUDING FIBROBLASTS, EPITHELIAL CELLS, ENDOTHELIAL CELLS, MACROPHAGES AND PERICYTES, CONTRIBUTE TO RENAL MYOFIBROBLASTS ORIGIN, AND LOTS OF MEDIATORS, INCLUDING SIGNALING PATHWAYS (TRANSFORMING GROWTH FACTOR-BETA1, MAMMALIAN TARGET OF RAPAMYCIN AND REACTIVE OXYGEN SPECIES) AND EPIGENETIC MODIFICATIONS (HISTONE ACETYLATION, MICRORNA AND LONG NON-CODING RNA) ARE PARTICIPATED IN RENAL MYOFIBROBLASTS ACTIVATION DURING RENAL FIBROGENESIS, SUGGESTING THAT THESE MEDIATORS MAY BE THE PROMISING TARGETS FOR TREATING RIF. IN ADDITION, MANY SMALL MOLECULES SHOW PROFOUND THERAPEUTIC EFFECTS ON RIF BY SUPPRESSING THE ORIGIN AND ACTIVATION OF RENAL MYOFIBROBLASTS. TAKEN TOGETHER, THE REVIEW FOCUSES ON THE MECHANISMS OF THE ORIGIN AND ACTIVATION OF RENAL MYOFIBROBLASTS IN RIF AND THE SMALL MOLECULES AGAINST THEM IMPROVING RIF, WHICH WILL PROVIDE A NEW INSIGHT FOR RIF THERAPY. 2021 9 5769 34 SPECIFIC EPIGENETIC REGULATORS SERVE AS POTENTIAL THERAPEUTIC TARGETS IN IDIOPATHIC PULMONARY FIBROSIS. IDIOPATHIC PULMONARY FIBROSIS (IPF), A DISORDER OBSERVED MOSTLY IN OLDER HUMAN BEINGS, IS CHARACTERISED BY CHRONIC AND PROGRESSIVE LUNG SCARRING LEADING TO AN IRREVERSIBLE DECLINE IN LUNG FUNCTION. THIS HEALTH CONDITION HAS A DISMAL PROGNOSIS AND THE CURRENTLY AVAILABLE DRUGS ONLY DELAY BUT FAIL TO REVERSE THE PROGRESSION OF LUNG DAMAGE. CONSEQUENTLY, IT BECOMES IMPERATIVE TO DISCOVER IMPROVED THERAPEUTIC COMPOUNDS AND THEIR CELLULAR TARGETS TO CURE IPF. IN THIS REGARD, A NUMBER OF RECENT STUDIES HAVE TARGETED THE EPIGENETIC REGULATION BY HISTONE DEACETYLASES (HDACS) TO DEVELOP AND CATEGORISE ANTIFIBROTIC DRUGS FOR LUNGS. THEREFORE, THIS REVIEW FOCUSES ON HOW ABERRANT EXPRESSION OR ACTIVITY OF CLASSES I, II AND III HDACS ALTER TGF-BETA SIGNALLING TO PROMOTE EVENTS SUCH AS EPITHELIAL-MESENCHYMAL TRANSITION, DIFFERENTIATION OF ACTIVATED FIBROBLASTS INTO MYOFIBROBLASTS, AND EXCESS DEPOSITION OF THE EXTRACELLULAR MATRIX TO PROPEL LUNG FIBROSIS. FURTHER, THIS STUDY DESCRIBES HOW CERTAIN CHEMICAL COMPOUNDS OR DIETARY CHANGES MODULATE DYSREGULATED HDACS TO ATTENUATE FIVE FAULTY TGF-BETA-DEPENDENT PROFIBROTIC PROCESSES, BOTH IN ANIMAL MODELS AND CELL LINES REPLICATING IPF, THEREBY IDENTIFYING PROMISING MEANS TO TREAT THIS LUNG DISORDER. 2022 10 3931 26 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 11 5939 37 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 12 5995 28 TGFBETA-INDUCED FIBROBLAST ACTIVATION REQUIRES PERSISTENT AND TARGETED HDAC-MEDIATED GENE REPRESSION. TISSUE FIBROSIS IS A CHRONIC DISEASE DRIVEN BY PERSISTENT FIBROBLAST ACTIVATION THAT HAS RECENTLY BEEN LINKED TO EPIGENETIC MODIFICATIONS. HERE, WE SCREENED A SMALL LIBRARY OF EPIGENETIC SMALL-MOLECULE MODULATORS TO IDENTIFY COMPOUNDS CAPABLE OF INHIBITING OR REVERSING TGFBETA-MEDIATED FIBROBLAST ACTIVATION. WE IDENTIFIED PRACINOSTAT, AN HDAC INHIBITOR, AS A POTENT ATTENUATOR OF LUNG FIBROBLAST ACTIVATION AND CONFIRMED ITS EFFICACY IN PATIENT-DERIVED FIBROBLASTS ISOLATED FROM FIBROTIC LUNG TISSUE. MECHANISTICALLY, WE FOUND THAT HDAC-DEPENDENT TRANSCRIPTIONAL REPRESSION WAS AN EARLY AND ESSENTIAL EVENT IN TGFBETA-MEDIATED FIBROBLAST ACTIVATION. TREATMENT OF LUNG FIBROBLASTS WITH PRACINOSTAT BROADLY ATTENUATED TGFBETA-MEDIATED EPIGENETIC REPRESSION AND PROMOTED FIBROBLAST QUIESCENCE. WE CONFIRMED A SPECIFIC ROLE FOR HDAC-DEPENDENT HISTONE DEACETYLATION IN THE PROMOTER REGION OF THE ANTI-FIBROTIC GENE PPARGC1A (PGC1ALPHA) IN RESPONSE TO TGFBETA STIMULATION. FINALLY, WE IDENTIFIED HDAC7 AS A KEY FACTOR WHOSE SIRNA-MEDIATED KNOCKDOWN ATTENUATES FIBROBLAST ACTIVATION WITHOUT ALTERING GLOBAL HISTONE ACETYLATION. TOGETHER, THESE RESULTS PROVIDE NOVEL MECHANISTIC INSIGHT INTO THE ESSENTIAL ROLE HDACS PLAY IN TGFBETA-MEDIATED FIBROBLAST ACTIVATION VIA TARGETED GENE REPRESSION. 2019 13 5993 32 TGFBETA PROMOTES FIBROSIS BY MYST1-DEPENDENT EPIGENETIC REGULATION OF AUTOPHAGY. ACTIVATION OF FIBROBLASTS IS ESSENTIAL FOR PHYSIOLOGICAL TISSUE REPAIR. UNCONTROLLED ACTIVATION OF FIBROBLASTS, HOWEVER, MAY LEAD TO TISSUE FIBROSIS WITH ORGAN DYSFUNCTION. ALTHOUGH SEVERAL PATHWAYS CAPABLE OF PROMOTING FIBROBLAST ACTIVATION AND TISSUE REPAIR HAVE BEEN IDENTIFIED, THEIR INTERPLAY IN THE CONTEXT OF CHRONIC FIBROTIC DISEASES REMAINS INCOMPLETELY UNDERSTOOD. HERE, WE PROVIDE EVIDENCE THAT TRANSFORMING GROWTH FACTOR-BETA (TGFBETA) ACTIVATES AUTOPHAGY BY AN EPIGENETIC MECHANISM TO AMPLIFY ITS PROFIBROTIC EFFECTS. TGFBETA INDUCES AUTOPHAGY IN FIBROTIC DISEASES BY SMAD3-DEPENDENT DOWNREGULATION OF THE H4K16 HISTONE ACETYLTRANSFERASE MYST1, WHICH REGULATES THE EXPRESSION OF CORE COMPONENTS OF THE AUTOPHAGY MACHINERY SUCH AS ATG7 AND BECLIN1. ACTIVATION OF AUTOPHAGY IN FIBROBLASTS PROMOTES COLLAGEN RELEASE AND IS BOTH, SUFFICIENT AND REQUIRED, TO INDUCE TISSUE FIBROSIS. FORCED EXPRESSION OF MYST1 ABROGATES THE STIMULATORY EFFECTS OF TGFBETA ON AUTOPHAGY AND RE-ESTABLISHES THE EPIGENETIC CONTROL OF AUTOPHAGY IN FIBROTIC CONDITIONS. INTERFERENCE WITH THE ABERRANT ACTIVATION OF AUTOPHAGY INHIBITS TGFBETA-INDUCED FIBROBLAST ACTIVATION AND AMELIORATES EXPERIMENTAL DERMAL AND PULMONARY FIBROSIS. THESE FINDINGS LINK UNCONTROLLED TGFBETA SIGNALING TO ABERRANT AUTOPHAGY AND DEREGULATED EPIGENETICS IN FIBROTIC DISEASES AND MAY CONTRIBUTE TO THE DEVELOPMENT OF THERAPEUTIC INTERVENTIONS IN FIBROTIC DISEASES. 2021 14 6015 23 THE ARGININE METHYLTRANSFERASE PRMT7 PROMOTES EXTRAVASATION OF MONOCYTES RESULTING IN TISSUE INJURY IN COPD. EXTRAVASATION OF MONOCYTES INTO TISSUE AND TO THE SITE OF INJURY IS A FUNDAMENTAL IMMUNOLOGICAL PROCESS, WHICH REQUIRES RAPID RESPONSES VIA POST TRANSLATIONAL MODIFICATIONS (PTM) OF PROTEINS. PROTEIN ARGININE METHYLTRANSFERASE 7 (PRMT7) IS AN EPIGENETIC FACTOR THAT HAS THE CAPACITY TO MONO-METHYLATE HISTONES ON ARGININE RESIDUES. HERE WE SHOW THAT IN CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) PATIENTS, PRMT7 EXPRESSION IS ELEVATED IN THE LUNG TISSUE AND LOCALIZED TO THE MACROPHAGES. IN MOUSE MODELS OF COPD, LUNG FIBROSIS AND SKIN INJURY, REDUCED EXPRESSION OF PRMT7 ASSOCIATES WITH DECREASED RECRUITMENT OF MONOCYTES TO THE SITE OF INJURY AND HENCE LESS SEVERE SYMPTOMS. MECHANISTICALLY, ACTIVATION OF NF-KAPPAB/RELA IN MONOCYTES INDUCES PRMT7 TRANSCRIPTION AND CONSEQUENTIAL MONO-METHYLATION OF HISTONES AT THE REGULATORY ELEMENTS OF RAP1A, WHICH LEADS TO INCREASED TRANSCRIPTION OF THIS GENE THAT IS RESPONSIBLE FOR ADHESION AND MIGRATION OF MONOCYTES. PERSISTENT MONOCYTE-DERIVED MACROPHAGE ACCUMULATION LEADS TO ALOX5 OVER-EXPRESSION AND ACCUMULATION OF ITS METABOLITE LTB4, WHICH TRIGGERS EXPRESSION OF ACSL4 A FERROPTOSIS PROMOTING GENE IN LUNG EPITHELIAL CELLS. CONCLUSIVELY, INHIBITION OF ARGININE MONO-METHYLATION MIGHT OFFER TARGETED INTERVENTION IN MONOCYTE-DRIVEN INFLAMMATORY CONDITIONS THAT LEAD TO EXTENSIVE TISSUE DAMAGE IF LEFT UNTREATED. 2022 15 6757 49 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 16 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 17 5992 33 TGF-BETA: THE MASTER REGULATOR OF FIBROSIS. TRANSFORMING GROWTH FACTOR-BETA (TGF-BETA) IS THE PRIMARY FACTOR THAT DRIVES FIBROSIS IN MOST, IF NOT ALL, FORMS OF CHRONIC KIDNEY DISEASE (CKD). INHIBITION OF THE TGF-BETA ISOFORM, TGF-BETA1, OR ITS DOWNSTREAM SIGNALLING PATHWAYS SUBSTANTIALLY LIMITS RENAL FIBROSIS IN A WIDE RANGE OF DISEASE MODELS WHEREAS OVEREXPRESSION OF TGF-BETA1 INDUCES RENAL FIBROSIS. TGF-BETA1 CAN INDUCE RENAL FIBROSIS VIA ACTIVATION OF BOTH CANONICAL (SMAD-BASED) AND NON-CANONICAL (NON-SMAD-BASED) SIGNALLING PATHWAYS, WHICH RESULT IN ACTIVATION OF MYOFIBROBLASTS, EXCESSIVE PRODUCTION OF EXTRACELLULAR MATRIX (ECM) AND INHIBITION OF ECM DEGRADATION. THE ROLE OF SMAD PROTEINS IN THE REGULATION OF FIBROSIS IS COMPLEX, WITH COMPETING PROFIBROTIC AND ANTIFIBROTIC ACTIONS (INCLUDING IN THE REGULATION OF MESENCHYMAL TRANSITIONING), AND WITH COMPLEX INTERPLAY BETWEEN TGF-BETA/SMADS AND OTHER SIGNALLING PATHWAYS. STUDIES OVER THE PAST 5 YEARS HAVE IDENTIFIED ADDITIONAL MECHANISMS THAT REGULATE THE ACTION OF TGF-BETA1/SMAD SIGNALLING IN FIBROSIS, INCLUDING SHORT AND LONG NONCODING RNA MOLECULES AND EPIGENETIC MODIFICATIONS OF DNA AND HISTONE PROTEINS. ALTHOUGH DIRECT TARGETING OF TGF-BETA1 IS UNLIKELY TO YIELD A VIABLE ANTIFIBROTIC THERAPY DUE TO THE INVOLVEMENT OF TGF-BETA1 IN OTHER PROCESSES, GREATER UNDERSTANDING OF THE VARIOUS PATHWAYS BY WHICH TGF-BETA1 CONTROLS FIBROSIS HAS IDENTIFIED ALTERNATIVE TARGETS FOR THE DEVELOPMENT OF NOVEL THERAPEUTICS TO HALT THIS MOST DAMAGING PROCESS IN CKD. 2016 18 6214 27 THE INTRACELLULAR SIGNALING PATHWAYS GOVERNING MACROPHAGE ACTIVATION AND FUNCTION IN HUMAN ATHEROSCLEROSIS. ATHEROSCLEROSIS IS A CHRONIC INFLAMMATORY DISEASE CHARACTERIZED BY LIPID ACCUMULATION AND PLAQUE FORMATION IN ARTERIAL VESSEL WALLS. ATHEROSCLEROTIC PLAQUES NARROW THE ARTERIAL LUMEN TO INCREASE THE RISK OF HEART ATTACKS, ISCHEMIC STROKE AND PERIPHERAL VASCULAR DISEASE, WHICH ARE MAJOR AND WORLDWIDE HEALTH AND ECONOMIC BURDENS. MACROPHAGE ACCUMULATION WITHIN PLAQUES IS CHARACTERISTIC OF ALL STAGES OF ATHEROSCLEROSIS AND THEIR PRESENCE IS A POTENTIAL MARKER OF DISEASE ACTIVITY AND PLAQUE STABILITY. MACROPHAGES ENGULF LIPIDS AND MODIFIED LIPOPROTEINS TO FORM FOAM CELLS THAT EXPRESS PRO-INFLAMMATORY AND CHEMOTACTIC EFFECTOR MOLECULES, STRESS INDUCING FACTORS AND REACTIVE OXYGEN SPECIES. THEY CONTROL PLAQUE STABILITY AND RUPTURE THROUGH SECRETION OF METALLOPROTEINASES AND EXTRACELLULAR MATRIX DEGRADATION. ALTHOUGH MACROPHAGES CAN WORSEN DISEASE BY PROPAGATING INFLAMMATION, THEY CAN STABILIZE ATHEROSCLEROTIC PLAQUES THROUGH TISSUE REMODELING, PROMOTING THE FORMATION OF A FIBROUS CAP, CLEARING APOPTOTIC CELLS TO PREVENT NECROTIC CORE FORMATION AND THROUGH VASCULAR REPAIR. IN ATHEROSCLEROSIS, MACROPHAGES RESPOND TO DYSLIPIDAEMIA, CYTOKINES, DYING CELLS, METABOLIC FACTORS, LIPIDS, PHYSICAL STIMULI AND EPIGENETIC FACTORS AND EXHIBIT HETEROGENEITY IN THEIR ACTIVATION DEPENDING ON THE STIMULI THEY RECEIVE. UNDERSTANDING THESE SIGNALS AND THE PATHWAYS DRIVING MACROPHAGE FUNCTION WITHIN DEVELOPING AND ESTABLISHED PLAQUES AND HOW THEY CAN BE PHARMACOLOGICALLY MODULATED, REPRESENTS A STRATEGY FOR THE PREVENTION AND TREATMENT OF ATHEROSCLEROSIS. THIS REVIEW FOCUSSES ON THE CURRENT UNDERSTANDING OF FACTORS CONTROLLING MACROPHAGE HETEROGENEITY AND FUNCTION IN ATHEROSCLEROSIS. PARTICULAR ATTENTION IS GIVEN TO THE MACROPHAGE INTRACELLULAR SIGNALING PATHWAYS AND TRANSCRIPTION FACTORS ACTIVATED BY BIOCHEMICAL AND BIOPHYSICAL STIMULI WITHIN PLAQUES, AND HOW THEY ARE INTEGRATED TO REGULATE PLAQUE FORMATION AND STABILITY. 2022 19 5575 42 ROLE OF MICRORNAS IN SIGNALING PATHWAYS ASSOCIATED WITH THE PATHOGENESIS OF IDIOPATHIC PULMONARY FIBROSIS: A FOCUS ON EPITHELIAL-MESENCHYMAL TRANSITION. IDIOPATHIC PULMONARY FIBROSIS (IPF) IS A CHRONIC AND PROGRESSIVE DISEASE WITH HIGH MORTALITY AND UNCLEAR ETIOLOGY. PREVIOUS EVIDENCE SUPPORTS THAT THE ORIGIN OF THIS DISEASE IS ASSOCIATED WITH EPIGENETIC ALTERATIONS, AGE, AND ENVIRONMENTAL FACTORS. IPF INITIATES WITH CHRONIC EPITHELIAL LUNG INJURIES, FOLLOWED BY BASAL MEMBRANE DESTRUCTION, WHICH PROMOTES THE ACTIVATION OF MYOFIBROBLASTS AND EXCESSIVE SYNTHESIS OF EXTRACELLULAR MATRIX (ECM) PROTEINS, AS WELL AS EPITHELIAL-MESENCHYMAL TRANSITION (EMT). DUE TO MIRNAS' ROLE AS REGULATORS OF APOPTOSIS, PROLIFERATION, DIFFERENTIATION, AND CELL-CELL INTERACTION PROCESSES, SOME STUDIES HAVE INVOLVED MIRNAS IN THE BIOGENESIS AND PROGRESSION OF IPF. IN THIS CONTEXT, THE ANALYSIS AND DISCUSSION OF THE PROBABLE ASSOCIATION OF MIRNAS WITH THE SIGNALING PATHWAYS INVOLVED IN THE DEVELOPMENT OF IPF WOULD IMPROVE OUR KNOWLEDGE OF THE ASSOCIATED MOLECULAR MECHANISMS, THEREBY FACILITATING ITS EVALUATION AS A THERAPEUTIC TARGET FOR THIS SEVERE LUNG DISEASE. IN THIS WORK, THE MOST RECENT PUBLICATIONS EVALUATING THE ROLE OF MIRNAS AS REGULATORS OR ACTIVATORS OF SIGNAL PATHWAYS ASSOCIATED WITH THE PATHOGENESIS OF IPF WERE ANALYZED. THE SEARCH IN PUBMED WAS MADE USING THE FOLLOWING TERMS: "MIRNAS AND IDIOPATHIC PULMONARY FIBROSIS (IPF)"; "MIRNAS AND IPF AND SIGNALING PATHWAYS (SP)"; AND "MIRNAS AND IPF AND SP AND IPF PATHOGENESIS". ADDITIONALLY, WE FOCUS MAINLY ON THOSE WORKS WHERE THE SIGNALING PATHWAYS INVOLVED WITH EMT, FIBROBLAST DIFFERENTIATION, AND SYNTHESIS OF ECM COMPONENTS WERE ASSESSED. FINALLY, THE IMPORTANCE AND SIGNIFICANCE OF MIRNAS AS POTENTIAL THERAPEUTIC OR DIAGNOSTIC TOOLS FOR THE TREATMENT OF IPF ARE DISCUSSED. 2022 20 6687 24 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