1 689 136 BRD4 AS A THERAPEUTIC TARGET IN PULMONARY DISEASES. BROMODOMAIN AND EXTRA-TERMINAL DOMAIN (BET) PROTEINS ARE EPIGENETIC MODULATORS THAT REGULATE GENE TRANSCRIPTION THROUGH INTERACTING WITH ACETYLATED LYSINE RESIDUES OF HISTONE PROTEINS. BET PROTEINS HAVE MULTIPLE ROLES IN REGULATING KEY CELLULAR FUNCTIONS SUCH AS CELL PROLIFERATION, DIFFERENTIATION, INFLAMMATION, OXIDATIVE AND REDOX BALANCE, AND IMMUNE RESPONSES. AS A RESULT, BET PROTEINS HAVE BEEN FOUND TO BE ACTIVELY INVOLVED IN A BROAD RANGE OF HUMAN LUNG DISEASES INCLUDING ACUTE LUNG INFLAMMATION, ASTHMA, PULMONARY ARTERIAL HYPERTENSION, PULMONARY FIBROSIS, AND CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). DUE TO THE IDENTIFICATION OF SPECIFIC SMALL MOLECULAR INHIBITORS OF BET PROTEINS, TARGETING BET IN THESE LUNG DISEASES HAS BECOME AN AREA OF INCREASING INTEREST. EMERGING EVIDENCE HAS DEMONSTRATED THE BENEFICIAL EFFECTS OF BET INHIBITORS IN PRECLINICAL MODELS OF VARIOUS HUMAN LUNG DISEASES. THIS IS, IN GENERAL, LARGELY RELATED TO THE ABILITY OF BET PROTEINS TO BIND TO PROMOTERS OF GENES THAT ARE CRITICAL FOR INFLAMMATION, DIFFERENTIATION, AND BEYOND. BY MODULATING THESE CRITICAL GENES, BET PROTEINS ARE INTEGRATED INTO THE PATHOGENESIS OF DISEASE PROGRESSION. THE INTRINSIC HISTONE ACETYLTRANSFERASE ACTIVITY OF BROMODOMAIN-CONTAINING PROTEIN 4 (BRD4) IS OF PARTICULAR INTEREST, SEEMS TO ACT INDEPENDENTLY OF ITS BROMODOMAIN BINDING ACTIVITY, AND HAS IMPLICATION IN SOME CONTEXTS. IN THIS REVIEW, WE PROVIDE A BRIEF OVERVIEW OF THE RESEARCH ON BET PROTEINS WITH A FOCUS ON BRD4 IN SEVERAL MAJOR HUMAN LUNG DISEASES, THE UNDERLYING MOLECULAR MECHANISMS, AS WELL AS FINDINGS OF TARGETING BET PROTEINS USING PHARMACEUTICAL INHIBITORS IN DIFFERENT LUNG DISEASES PRECLINICALLY. 2023 2 697 50 BROMODOMAIN AND EXTRATERMINAL PROTEINS AS NOVEL EPIGENETIC TARGETS FOR RENAL DISEASES. EPIGENETIC MECHANISMS, ESPECIALLY DNA METHYLATION AND HISTONE MODIFICATIONS, ARE DYNAMIC PROCESSES THAT REGULATE THE GENE EXPRESSION TRANSCRIPTIONAL PROGRAM IN NORMAL AND DISEASED STATES. THE BROMODOMAIN AND EXTRATERMINAL (BET) PROTEIN FAMILY (BRD2, BRD3, BRD4, AND BRDT) ARE EPIGENETIC READERS THAT, VIA BROMODOMAINS, REGULATE GENE TRANSCRIPTION BY BINDING TO ACETYLATED LYSINE RESIDUES ON HISTONES AND MASTER TRANSCRIPTIONAL FACTORS. EXPERIMENTAL DATA HAVE DEMONSTRATED THE INVOLVEMENT OF SOME BET PROTEINS IN MANY PATHOLOGICAL CONDITIONS, INCLUDING TUMOR DEVELOPMENT, INFECTIONS, AUTOIMMUNITY, AND INFLAMMATION. SELECTIVE BROMODOMAIN INHIBITORS ARE EPIGENETIC DRUGS THAT BLOCK THE INTERACTION BETWEEN BET PROTEINS AND ACETYLATED PROTEINS, THUS EXERTING BENEFICIAL EFFECTS. RECENT DATA HAVE DESCRIBED THE BENEFICIAL EFFECT OF BET INHIBITION ON EXPERIMENTAL RENAL DISEASES. EMERGING EVIDENCE UNDERSCORES THE IMPORTANCE OF ENVIRONMENTAL MODIFICATIONS IN THE ORIGIN OF PATHOLOGICAL FEATURES IN CHRONIC KIDNEY DISEASES (CKD). SEVERAL CELLULAR PROCESSES SUCH AS OXIDATION, METABOLIC DISORDERS, CYTOKINES, INFLAMMATION, OR ACCUMULATED UREMIC TOXINS MAY INDUCE EPIGENETIC MODIFICATIONS THAT REGULATE KEY PROCESSES INVOLVED IN RENAL DAMAGE AND IN OTHER PATHOLOGICAL CONDITIONS OBSERVED IN CKD PATIENTS. HERE, WE REVIEW HOW TARGETING BROMODOMAINS IN BET PROTEINS MAY REGULATE ESSENTIAL PROCESSES INVOLVED IN RENAL DISEASES AND IN ASSOCIATED COMPLICATIONS FOUND IN CKD PATIENTS, SUCH AS CARDIOVASCULAR DAMAGE, HIGHLIGHTING THE POTENTIAL OF EPIGENETIC THERAPEUTIC STRATEGIES AGAINST BET PROTEINS FOR CKD TREATMENT AND ASSOCIATED RISKS. 2019 3 799 33 CELLULAR SIGNALING AND POTENTIAL NEW TREATMENT TARGETS IN DIABETIC RETINOPATHY. DYSFUNCTION AND DEATH OF MICROVASCULAR CELLS AND IMBALANCE BETWEEN THE PRODUCTION AND THE DEGRADATION OF EXTRACELLULAR MATRIX (ECM) PROTEINS ARE A CHARACTERISTIC FEATURE OF DIABETIC RETINOPATHY (DR). GLUCOSE-INDUCED BIOCHEMICAL ALTERATIONS IN THE VASCULAR ENDOTHELIAL CELLS MAY ACTIVATE A CASCADE OF SIGNALING PATHWAYS LEADING TO INCREASED PRODUCTION OF ECM PROTEINS AND CELLULAR DYSFUNCTION/DEATH. CHRONIC DIABETES LEADS TO THE ACTIVATION OF A NUMBER OF SIGNALING PROTEINS INCLUDING PROTEIN KINASE C, PROTEIN KINASE B, AND MITOGEN-ACTIVATED PROTEIN KINASES. THESE SIGNALING CASCADES ARE ACTIVATED IN RESPONSE TO HYPERGLYCEMIA-INDUCED OXIDATIVE STRESS, POLYOL PATHWAY, AND ADVANCED GLYCATION END PRODUCT FORMATION AMONG OTHERS. THE ABERRANT SIGNALING PATHWAYS ULTIMATELY LEAD TO ACTIVATION OF TRANSCRIPTION FACTORS SUCH AS NUCLEAR FACTOR-KAPPAB AND ACTIVATING PROTEIN-1. THE ACTIVITY OF THESE TRANSCRIPTION FACTORS IS ALSO REGULATED BY EPIGENETIC MECHANISMS THROUGH TRANSCRIPTIONAL COACTIVATOR P300. THESE COMPLEX SIGNALING PATHWAYS MAY BE INVOLVED IN GLUCOSE-INDUCED ALTERATIONS OF ENDOTHELIAL CELL PHENOTYPE LEADING TO THE PRODUCTION OF INCREASED ECM PROTEINS AND VASOACTIVE EFFECTOR MOLECULES CAUSING FUNCTIONAL AND STRUCTURAL CHANGES IN THE MICROVASCULATURE. UNDERSTANDING OF SUCH MECHANISTIC PATHWAYS WILL HELP TO DEVELOP FUTURE ADJUVANT THERAPIES FOR DIABETIC RETINOPATHY. 2007 4 4582 39 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 5 5939 54 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 6 6687 30 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 7 3322 34 HISTONE ACETYLTRANSFERASE P300 INDUCES DE NOVO SUPER-ENHANCERS TO DRIVE CELLULAR SENESCENCE. ACCUMULATION OF SENESCENT CELLS DURING AGING CONTRIBUTES TO CHRONIC INFLAMMATION AND AGE-RELATED DISEASES. WHILE SENESCENCE IS ASSOCIATED WITH PROFOUND ALTERATIONS OF THE EPIGENOME, A SYSTEMATIC VIEW OF EPIGENETIC FACTORS IN REGULATING SENESCENCE IS LACKING. HERE, WE CURATED A LIBRARY OF SHORT HAIRPIN RNAS FOR TARGETED SILENCING OF ALL KNOWN EPIGENETIC PROTEINS AND PERFORMED A HIGH-THROUGHPUT SCREEN TO IDENTIFY KEY CANDIDATES WHOSE DOWNREGULATION CAN DELAY REPLICATIVE SENESCENCE OF PRIMARY HUMAN CELLS. THIS SCREEN IDENTIFIED MULTIPLE NEW PLAYERS INCLUDING THE HISTONE ACETYLTRANSFERASE P300 THAT WAS FOUND TO BE A PRIMARY DRIVER OF THE SENESCENT PHENOTYPE. P300, BUT NOT THE PARALOGOUS CBP, INDUCES A DYNAMIC HYPER-ACETYLATED CHROMATIN STATE AND PROMOTES THE FORMATION OF ACTIVE ENHANCER ELEMENTS IN THE NON-CODING GENOME, LEADING TO A SENESCENCE-SPECIFIC GENE EXPRESSION PROGRAM. OUR WORK ILLUSTRATES A CAUSAL ROLE OF HISTONE ACETYLTRANSFERASES AND ACETYLATION IN SENESCENCE AND SUGGESTS P300 AS A POTENTIAL THERAPEUTIC TARGET FOR SENESCENCE AND AGE-RELATED DISEASES. 2019 8 4836 42 ONCOGENIC FUNCTIONS OF THE TRANSCRIPTION FACTOR NRF2. NUCLEAR FACTOR E2-RELATED FACTOR 2 (NRF2) IS A TRANSCRIPTION FACTOR THAT CONTROLS THE EXPRESSION OF A LARGE POOL OF ANTIOXIDANT AND CYTOPROTECTIVE GENES REGULATING THE CELLULAR RESPONSE TO OXIDATIVE AND ELECTROPHILIC STRESS. NRF2 IS NEGATIVELY REGULATED BY KELCH-LIKE ECH-ASSOCIATED PROTEIN 1 (KEAP1) AND, UPON STIMULATION BY AN OXIDATIVE OR ELECTROPHILIC INSULT, IS RAPIDLY ACTIVATED BY PROTEIN STABILIZATION. OWING TO ITS CYTOPROTECTIVE FUNCTIONS, NRF2 HAS BEEN TRADITIONALLY STUDIED IN THE FIELD OF CHEMOPREVENTION; HOWEVER, THERE IS ACCUMULATED EVIDENCE THAT KEAP1/NRF2 MUTATIONS OR UNBALANCED REGULATION THAT LEADS TO OVEREXPRESSION OR HYPERACTIVATION OF NRF2 MAY PARTICIPATE IN TUMORIGENESIS AND BE INVOLVED IN CHEMORESISTANCE OF A WIDE NUMBER OF SOLID CANCERS AND LEUKEMIAS. IN ADDITION TO PROTECTING CELLS FROM REACTIVE OXYGEN SPECIES, NRF2 SEEMS TO PLAY A DIRECT ROLE IN CELL GROWTH CONTROL AND IS RELATED TO APOPTOSIS-REGULATING PATHWAYS. MOREOVER, NRF2 ACTIVITY IS CONNECTED WITH ONCOGENIC KINASE PATHWAYS, STRUCTURAL PROTEINS, HORMONAL REGULATION, OTHER TRANSCRIPTION FACTORS, AND EPIGENETIC ENZYMES INVOLVED IN THE PATHOGENESIS OF VARIOUS TYPES OF TUMORS. THE AIM OF THIS REVIEW IS TO COMPILE AND SUMMARIZE EXISTING KNOWLEDGE OF THE ONCOGENIC FUNCTIONS OF NRF2 TO PROVIDE A SOLID BASIS FOR ITS POTENTIAL USE AS A MOLECULAR MARKER AND PHARMACOLOGICAL TARGET IN CANCER. 2013 9 593 45 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 10 2493 56 EPIGENETICS AND CHROMATIN REMODELING PLAY A ROLE IN LUNG DISEASE. EPIGENETICS IS DEFINED AS HERITABLE CHANGES THAT AFFECT GENE EXPRESSION WITHOUT ALTERING THE DNA SEQUENCE. EPIGENETIC REGULATION OF GENE EXPRESSION IS FACILITATED THROUGH DIFFERENT MECHANISMS SUCH AS DNA METHYLATION, HISTONE MODIFICATIONS AND RNA-ASSOCIATED SILENCING BY SMALL NON-CODING RNAS. ALL THESE MECHANISMS ARE CRUCIAL FOR NORMAL DEVELOPMENT, DIFFERENTIATION AND TISSUE-SPECIFIC GENE EXPRESSION. THESE THREE SYSTEMS INTERACT AND STABILIZE ONE ANOTHER AND CAN INITIATE AND SUSTAIN EPIGENETIC SILENCING, THUS DETERMINING HERITABLE CHANGES IN GENE EXPRESSION. HISTONE ACETYLATION REGULATES DIVERSE CELLULAR FUNCTIONS INCLUDING INFLAMMATORY GENE EXPRESSION, DNA REPAIR AND CELL PROLIFERATION. TRANSCRIPTIONAL COACTIVATORS POSSESS INTRINSIC HISTONE ACETYLTRANSFERASE ACTIVITY AND THIS ACTIVITY DRIVES INFLAMMATORY GENE EXPRESSION. ELEVEN CLASSICAL HISTONE DEACETYLASES (HDACS) ACT TO REGULATE THE EXPRESSION OF DISTINCT SUBSETS OF INFLAMMATORY/IMMUNE GENES. THUS, LOSS OF HDAC ACTIVITY OR THE PRESENCE OF HDAC INHIBITORS CAN FURTHER ENHANCE INFLAMMATORY GENE EXPRESSION BY PRODUCING A GENE-SPECIFIC CHANGE IN HAT ACTIVITY. FOR EXAMPLE, HDAC2 EXPRESSION AND ACTIVITY ARE REDUCED IN LUNG MACROPHAGES, BIOPSY SPECIMENS, AND BLOOD CELLS FROM PATIENTS WITH SEVERE ASTHMA AND SMOKING ASTHMATICS, AS WELL AS IN PATIENTS WITH CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD). THIS MAY ACCOUNT, AT LEAST IN PART, FOR THE ENHANCED INFLAMMATION AND REDUCED STEROID RESPONSIVENESS SEEN IN THESE PATIENTS. OTHER PROTEINS, PARTICULARLY TRANSCRIPTION FACTORS, ARE ALSO ACETYLATED AND ARE TARGETS FOR DEACETYLATION BY HDACS AND SIRTUINS, A RELATED FAMILY OF 7 PREDOMINANTLY PROTEIN DEACETYLASES. THUS THE ACETYLATION/DEACETYLATION STATUS OF NF-KAPPAB AND THE GLUCOCORTICOID RECEPTOR CAN ALSO AFFECT THE OVERALL EXPRESSION PATTERN OF INFLAMMATORY GENES AND REGULATE THE INFLAMMATORY RESPONSE. UNDERSTANDING AND TARGETING SPECIFIC ENZYMES INVOLVED IN THIS PROCESS MIGHT LEAD TO NEW THERAPEUTIC AGENTS, PARTICULARLY IN SITUATIONS IN WHICH CURRENT ANTI-INFLAMMATORY THERAPIES ARE SUBOPTIMAL. 2011 11 6045 38 THE COMPLEXITY OF THE NRF2 PATHWAY: BEYOND THE ANTIOXIDANT RESPONSE. THE NF-E2-RELATED FACTOR 2 (NRF2)-MEDIATED SIGNALLING PATHWAY PROVIDES LIVING ORGANISMS AN EFFICIENT AND PIVOTAL LINE OF DEFENSIVE TO COUNTERACT ENVIRONMENTAL INSULTS AND ENDOGENOUS STRESSORS. NRF2 COORDINATES THE BASAL AND INDUCIBLE EXPRESSION OF ANTIOXIDANT AND PHASE II DETOXIFICATION ENZYMES TO ADAPT TO DIFFERENT STRESS CONDITIONS. THE STABILITY AND CELLULAR DISTRIBUTION OF NRF2 IS TIGHTLY CONTROLLED BY ITS INHIBITORY BINDING PROTEIN KELCH-LIKE ECH-ASSOCIATED PROTEIN 1. NRF2 SIGNALLING IS ALSO REGULATED BY POSTTRANSLATIONAL, TRANSCRIPTIONAL, TRANSLATIONAL AND EPIGENETIC MECHANISMS, AS WELL AS BY OTHER PROTEIN PARTNERS, INCLUDING P62, P21 AND IQ MOTIF-CONTAINING GTPASE ACTIVATING PROTEIN 1. MANY STUDIES HAVE DEMONSTRATED THAT NRF2 IS A PROMISING TARGET FOR PREVENTING CARCINOGENESIS AND OTHER CHRONIC DISEASES, INCLUDING CARDIOVASCULAR DISEASES, NEURODEGENERATIVE DISEASES AND PULMONARY INJURY. HOWEVER, CONSTITUTIVE ACTIVATION OF NRF2 IN ADVANCED CANCER CELLS MAY CONFER DRUG RESISTANCE. HERE, WE REVIEW THE MOLECULAR MECHANISMS OF NRF2 SIGNALLING, THE DIVERSE CLASSES OF NRF2 ACTIVATORS, INCLUDING BIOACTIVE NUTRIENTS AND OTHER CHEMICALS, AND THE CELLULAR FUNCTIONS AND DISEASE RELEVANCE OF NRF2 AND DISCUSS THE DUAL ROLE OF NRF2 IN DIFFERENT CONTEXTS. 2015 12 5937 48 TARGETING HISTONE DEACETYLASE ACTIVITY IN RHEUMATOID ARTHRITIS AND ASTHMA AS PROTOTYPES OF INFLAMMATORY DISEASE: SHOULD WE KEEP OUR HATS ON? CELLULAR ACTIVATION, PROLIFERATION AND SURVIVAL IN CHRONIC INFLAMMATORY DISEASES IS REGULATED NOT ONLY BY ENGAGEMENT OF SIGNAL TRANS-DUCTION PATHWAYS THAT MODULATE TRANSCRIPTION FACTORS REQUIRED FOR THESE PROCESSES, BUT ALSO BY EPIGENETIC REGULATION OF TRANSCRIPTION FACTOR ACCESS TO GENE PROMOTER REGIONS. HISTONE ACETYL TRANSFERASES COORDINATE THE RECRUITMENT AND ACTIVATION OF TRANSCRIPTION FACTORS WITH CONFORMATIONAL CHANGES IN HISTONES THAT ALLOW GENE PROMOTER EXPOSURE. HISTONE DEACETYLASES (HDACS) COUNTERACT HISTONE ACETYL TRANSFERASE ACTIVITY THROUGH THE TARGETING OF BOTH HISTONES AS WELL AS NONHISTONE SIGNAL TRANSDUCTION PROTEINS IMPORTANT IN INFLAMMATION. NUMEROUS STUDIES HAVE INDICATED THAT DEPRESSED HDAC ACTIVITY IN PATIENTS WITH INFLAMMATORY AIRWAY DISEASES MAY CONTRIBUTE TO LOCAL PROINFLAMMATORY CYTOKINE PRODUCTION AND DIMINISH PATIENT RESPONSES TO CORTICOSTEROID TREATMENT. RECENT OBSERVATIONS THAT HDAC ACTIVITY IS DEPRESSED IN RHEUMATOID ARTHRITIS PATIENT SYNOVIAL TISSUE HAVE PREDICTED THAT STRATEGIES RESTORING HDAC FUNCTION MAY BE THERAPEUTIC IN THIS DISEASE AS WELL. PHARMACOLOGICAL INHIBITORS OF HDAC ACTIVITY, HOWEVER, HAVE DEMONSTRATED POTENT THERAPEUTIC EFFECTS IN ANIMAL MODELS OF ARTHRITIS AND OTHER CHRONIC INFLAMMATORY DISEASES. IN THE PRESENT REVIEW WE ASSESS AND RECONCILE THESE OUTWARDLY PARADOXICAL STUDY RESULTS TO PROVIDE A WORKING MODEL FOR HOW ALTERATIONS IN HDAC ACTIVITY MAY CONTRIBUTE TO PATHOLOGY IN RHEUMATOID ARTHRITIS, AND HIGHLIGHT KEY QUESTIONS TO BE ANSWERED IN THE PRECLINICAL EVALUATION OF COMPOUNDS MODULATING THESE ENZYMES. 2008 13 4902 42 OXIDATIVE-STRESS-INDUCED EPIGENETIC CHANGES IN CHRONIC DIABETIC COMPLICATIONS. OXIDATIVE STRESS PLAYS AN IMPORTANT ROLE IN THE DEVELOPMENT AND PROGRESSION OF CHRONIC DIABETIC COMPLICATIONS. DIABETES CAUSES MITOCHONDRIAL SUPEROXIDE OVERPRODUCTION IN THE ENDOTHELIAL CELLS OF BOTH LARGE AND SMALL VESSELS. THIS INCREASED SUPEROXIDE PRODUCTION CAUSES THE ACTIVATION OF SEVERAL SIGNAL PATHWAYS INVOLVED IN THE PATHOGENESIS OF CHRONIC COMPLICATIONS. IN PARTICULAR, ENDOTHELIAL CELLS ARE MAJOR TARGETS OF GLUCOSE-INDUCED OXIDATIVE DAMAGE IN THE TARGET ORGANS. OXIDATIVE STRESS ACTIVATES CELLULAR SIGNALING PATHWAYS AND TRANSCRIPTION FACTORS IN ENDOTHELIAL CELLS INCLUDING PROTEIN KINASE C (PKC), C-JUN-N-TERMINAL KINASE (JNK), P38 MITOGEN-ACTIVATED PROTEIN KINASE (MAPK), FORKHEAD BOX O (FOXO), AND NUCLEAR FACTOR KAPPA-B (NF-KAPPAB). OXIDATIVE STRESS ALSO CAUSES DNA DAMAGE AND ACTIVATES DNA NUCLEOTIDE EXCISION REPAIR ENZYMES INCLUDING THE EXCISION REPAIR CROSS COMPLIMENTING 1(ERCC1), ERCC4, AND POLY(ADP-RIBOSE) POLYMERASE (PARP). AUGMENTED PRODUCTION OF HISTONE ACETYLTRANSFERASE P300, AND ALTERATIONS OF HISTONE DEACETYLASES, INCLUDING CLASS III DEACETYLASES SIRTUINS, ARE ALSO INVOLVED IN THIS PROCESS. RECENT RESEARCH HAS FOUND THAT SMALL NONCODING RNAS, LIKE MICRORNA, ARE A NEW KIND OF REGULATOR ASSOCIATED WITH CHRONIC DIABETIC COMPLICATIONS. THERE ARE EXTENSIVE AND COMPLICATED INTERACTIONS AND AMONG THESE MOLECULES. THE PURPOSE OF THIS REVIEW IS TO DEMONSTRATE THE ROLE OF OXIDATIVE STRESS IN THE DEVELOPMENT OF DIABETIC COMPLICATIONS IN RELATION TO EPIGENETIC CHANGES SUCH AS ACETYLATION AND MICRORNA ALTERATIONS. 2013 14 699 35 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 15 3207 41 HDACI: CELLULAR EFFECTS, OPPORTUNITIES FOR RESTORATIVE DENTISTRY. ACETYLATION OF HISTONE AND NON-HISTONE PROTEINS ALTERS GENE EXPRESSION AND INDUCES A HOST OF CELLULAR EFFECTS. THE ACETYLATION PROCESS IS HOMEOSTATICALLY BALANCED BY TWO GROUPS OF CELLULAR ENZYMES, HISTONE ACETYLTRANSFERASES (HATS) AND HISTONE DEACETYLASES (HDACS). HAT ACTIVITY RELAXES THE STRUCTURE OF THE HUMAN CHROMATIN, RENDERING IT TRANSCRIPTIONALLY ACTIVE, THEREBY INCREASING GENE EXPRESSION. IN CONTRAST, HDAC ACTIVITY LEADS TO GENE SILENCING. THE ENZYMATIC BALANCE CAN BE 'TIPPED' BY HISTONE DEACETYLASE INHIBITORS (HDACI), LEADING TO AN ACCUMULATION OF ACETYLATED PROTEINS, WHICH SUBSEQUENTLY MODIFY CELLULAR PROCESSES INCLUDING STEM CELL DIFFERENTIATION, CELL CYCLE, APOPTOSIS, GENE EXPRESSION, AND ANGIOGENESIS. THERE IS A VARIETY OF NATURAL AND SYNTHETIC HDACI AVAILABLE, AND THEIR PLEIOTROPIC EFFECTS HAVE CONTRIBUTED TO DIVERSE CLINICAL APPLICATIONS, NOT ONLY IN CANCER BUT ALSO IN NON-CANCER AREAS, SUCH AS CHRONIC INFLAMMATORY DISEASE, BONE ENGINEERING, AND NEURODEGENERATIVE DISEASE. INDEED, IT APPEARS THAT HDACI-MODULATED EFFECTS MAY DIFFER BETWEEN 'NORMAL' AND TRANSFORMED CELLS, PARTICULARLY WITH REGARD TO REACTIVE OXYGEN SPECIES ACCUMULATION, APOPTOSIS, PROLIFERATION, AND CELL CYCLE ARREST. THE POTENTIAL BENEFICIAL EFFECTS OF HDACI FOR HEALTH, RESULTING FROM THEIR ABILITY TO REGULATE GLOBAL GENE EXPRESSION BY EPIGENETIC MODIFICATION OF DNA-ASSOCIATED PROTEINS, ALSO OFFER POTENTIAL FOR APPLICATION WITHIN RESTORATIVE DENTISTRY, WHERE THEY MAY PROMOTE DENTAL TISSUE REGENERATION FOLLOWING PULPAL DAMAGE. 2011 16 1383 36 DIABETES AND ITS CARDIOVASCULAR COMPLICATIONS: POTENTIAL ROLE OF THE ACETYLTRANSFERASE P300. DIABETES HAS BEEN SHOWN TO ACCELERATE VASCULAR SENESCENCE, WHICH IS ASSOCIATED WITH CHRONIC INFLAMMATION AND OXIDATIVE STRESS, BOTH IMPLICATED IN THE DEVELOPMENT OF ENDOTHELIAL DYSFUNCTION. THIS CONDITION REPRESENTS THE INITIAL ALTERATION LINKING DIABETES TO RELATED CARDIOVASCULAR (CV) COMPLICATIONS. RECENTLY, IT HAS BEEN HYPOTHESISED THAT THE ACETYLTRANSFERASE, P300, MAY CONTRIBUTE TO ESTABLISHING AN EARLY VASCULAR SENESCENT PHENOTYPE, PLAYING A RELEVANT ROLE IN DIABETES-ASSOCIATED INFLAMMATION AND OXIDATIVE STRESS, WHICH DRIVE ENDOTHELIAL DYSFUNCTION. SPECIFICALLY, P300 CAN MODULATE VASCULAR INFLAMMATION THROUGH EPIGENETIC MECHANISMS AND TRANSCRIPTION FACTORS ACETYLATION. INDEED, IT REGULATES THE INFLAMMATORY PATHWAY BY INTERACTING WITH NUCLEAR FACTOR KAPPA-LIGHT-CHAIN-ENHANCER OF ACTIVATED B CELLS P65 SUBUNIT (NF-KAPPAB P65) OR BY INDUCING ITS ACETYLATION, SUGGESTING A CRUCIAL ROLE OF P300 AS A BRIDGE BETWEEN NF-KAPPAB P65 AND THE TRANSCRIPTIONAL MACHINERY. ADDITIONALLY, P300-MEDIATED EPIGENETIC MODIFICATIONS COULD BE UPSTREAM OF THE ACTIVATION OF INFLAMMATORY CYTOKINES, AND THEY MAY INDUCE OXIDATIVE STRESS BY AFFECTING THE PRODUCTION OF REACTIVE OXYGEN SPECIES (ROS). BECAUSE SEVERAL IN VITRO AND IN VIVO STUDIES SHED LIGHT ON THE POTENTIAL USE OF ACETYLTRANSFERASE INHIBITORS, A BETTER UNDERSTANDING OF THE MECHANISMS UNDERLYING THE ROLE OF P300 IN DIABETIC VASCULAR DYSFUNCTION COULD HELP IN FINDING NEW STRATEGIES FOR THE CLINICAL MANAGEMENT OF CV DISEASES RELATED TO DIABETES. 2023 17 5992 35 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 3688 37 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 19 4372 37 MIRNAS, OXIDATIVE STRESS, AND CANCER: A COMPREHENSIVE AND UPDATED REVIEW. OXIDATIVE STRESS REFERS TO ELEVATED LEVELS OF INTRACELLULAR REACTIVE OXYGEN SPECIES (ROS). ROS HOMEOSTASIS FUNCTIONS AS A SIGNALING PATHWAY FOR NORMAL CELL SURVIVAL AND APPROPRIATE CELL SIGNALING. CHRONIC INFLAMMATION INDUCED BY IMBALANCED LEVELS OF ROS CONTRIBUTES TO MANY DISEASES AND DIFFERENT TYPES OF CANCER. ROS CAN ALTER THE EXPRESSION OF ONCOGENES AND TUMOR SUPPRESSOR GENES THROUGH EPIGENETIC MODIFICATIONS, TRANSCRIPTION FACTORS, AND NON-CODING RNAS. MICRORNAS (MIRNAS) ARE SMALL NON-CODING RNAS THAT PLAY A KEY ROLE IN MOST BIOLOGICAL PATHWAYS. EACH MIRNA REGULATES HUNDREDS OF TARGET GENES BY INHIBITING PROTEIN TRANSLATION AND/OR PROMOTING MESSENGER RNA DEGRADATION. IN NORMAL CONDITIONS, MIRNAS PLAY A PHYSIOLOGICAL ROLE IN CELL PROLIFERATION, DIFFERENTIATION, AND APOPTOSIS. HOWEVER, DIFFERENT FACTORS THAT CAN DYSREGULATE CELL SIGNALING AND CELLULAR HOMEOSTASIS CAN ALSO AFFECT MIRNA EXPRESSION. THE ALTERATION OF MIRNA EXPRESSION CAN WORK AGAINST DISTURBING FACTORS OR MEDIATE THEIR EFFECTS. OXIDATIVE STRESS IS ONE OF THESE FACTORS. CONSIDERING THE COMPLEX INTERPLAY BETWEEN ROS LEVEL AND MIRNA REGULATION AND BOTH OF THESE WITH CANCER DEVELOPMENT, WE REVIEW THE ROLE OF MIRNAS IN CANCER, FOCUSING ON THEIR FUNCTION IN OXIDATIVE STRESS. 2020 20 6910 26 [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