1 4674 113 NEW INSIGHTS INTO THE ROLE AND MECHANISM OF PARTIAL EPITHELIAL-MESENCHYMAL TRANSITION IN KIDNEY FIBROSIS. EPITHELIAL-MESENCHYMAL TRANSITION (EMT) IS DESCRIBED AS THE PROCESS IN WHICH INJURED RENAL TUBULAR EPITHELIAL CELLS UNDERGO A PHENOTYPE CHANGE, ACQUIRING MESENCHYMAL CHARACTERISTICS AND MORPHING INTO FIBROBLASTS. INITIALLY, IT WAS WIDELY THOUGHT OF AS A CRITICAL MECHANISM OF FIBROGENESIS UNDERLYING CHRONIC KIDNEY DISEASE. HOWEVER, EVIDENCE THAT RENAL TUBULAR EPITHELIAL CELLS CAN CROSS THE BASEMENT MEMBRANE AND BECOME FIBROBLASTS IN THE RENAL INTERSTITIUM IS RARE, LEADING TO DEBATE ABOUT THE EXISTENCE OF EMT. RECENT RESEARCH HAS DEMONSTRATED THAT AFTER INJURY, RENAL TUBULAR EPITHELIAL CELLS ACQUIRE MESENCHYMAL CHARACTERISTICS AND THE ABILITY TO PRODUCE A VARIETY OF PROFIBROTIC FACTORS AND CYTOKINES, BUT REMAIN ATTACHED TO THE BASEMENT MEMBRANE. ON THIS BASIS, A NEW CONCEPT OF "PARTIAL EPITHELIAL-MESENCHYMAL TRANSITION (PEMT)" WAS PROPOSED TO EXPLAIN THE CONTRIBUTION OF RENAL EPITHELIAL CELLS TO RENAL FIBROGENESIS. IN THIS REVIEW, WE DISCUSS THE CONCEPT OF PEMT AND THE MOST RECENT FINDINGS RELATED TO THIS PROCESS, INCLUDING CELL CYCLE ARREST, METABOLIC ALTERNATION OF EPITHELIAL CELLS, INFILTRATION OF IMMUNE CELLS, EPIGENETIC REGULATION AS WELL AS THE NOVEL SIGNALING PATHWAYS THAT MEDIATE THIS DISTURBED EPITHELIAL-MESENCHYMAL COMMUNICATION. A DEEPER UNDERSTANDING OF THE ROLE AND THE MECHANISM OF PEMT MAY HELP IN DEVELOPING NOVEL THERAPIES TO PREVENT AND HALT FIBROSIS IN KIDNEY DISEASE. 2020 2 3466 31 HYPOXIA AS A KEY PLAYER IN THE AKI-TO-CKD TRANSITION. RECENT CLINICAL AND ANIMAL STUDIES HAVE SHOWN THAT ACUTE KIDNEY INJURY (AKI), EVEN IF FOLLOWED BY COMPLETE RECOVERY OF RENAL FUNCTION, CAN EVENTUALLY RESULT IN CHRONIC KIDNEY DISEASE (CKD). RENAL HYPOXIA IS EMERGING AS A KEY PLAYER IN THE PATHOPHYSIOLOGY OF THE AKI-TO-CKD TRANSITION. CAPILLARY RAREFACTION AFTER AKI EPISODES INDUCES RENAL HYPOXIA, WHICH CAN IN TURN PROFOUNDLY AFFECT TUBULAR EPITHELIAL CELLS, (MYO)FIBROBLASTS, AND INFLAMMATORY CELLS, CULMINATING IN TUBULOINTERSTITIAL FIBROSIS, I.E., PROGRESSION TO CKD. DAMAGED TUBULAR EPITHELIAL CELLS THAT FAIL TO REDIFFERENTIATE MIGHT SUPPLY A DECREASED AMOUNT OF VASCULAR ENDOTHELIAL GROWTH FACTOR AND CONTRIBUTE TO CAPILLARY RAREFACTION, THUS AGGRAVATING HYPOXIA AND FORMING A VICIOUS CYCLE. MOUNTING EVIDENCE ALSO SHOWS THAT EPIGENETIC CHANGES ARE CLOSELY RELATED TO RENAL HYPOXIA IN THE PATHOPHYSIOLOGY OF CKD PROGRESSION. ANIMAL EXPERIMENTS SUGGEST THAT TARGETING HYPOXIA IS A PROMISING STRATEGY TO BLOCK THE TRANSITION FROM AKI TO CKD. HOWEVER, THE PRECISE MECHANISMS BY WHICH HYPOXIA INDUCES THE AKI-TO-CKD TRANSITION AND BY WHICH HYPOXIA-INDUCIBLE FACTOR ACTIVATION CAN EXERT A PROTECTIVE EFFECT IN THIS CONTEXT SHOULD BE CLARIFIED IN FURTHER STUDIES. 2014 3 4661 28 NEW ASPECTS OF THE EPIGENETIC REGULATION OF EMT RELATED TO PULMONARY FIBROSIS. PULMONARY FIBROSIS IS A CHRONIC AND PROGRESSIVE FIBROTIC DISEASE THAT RESULTS IN IMPAIRED GAS EXCHANGE, VENTILATION, AND EVENTUAL DEATH. THE PRO-FIBROTIC ENVIRONMENT IS INSTIGATED BY VARIOUS FACTORS, LEADING TO THE TRANSFORMATION OF EPITHELIAL CELLS INTO MYOFIBROBLASTS AND/OR FIBROBLASTS THAT TRIGGER FIBROSIS. EPITHELIAL MESENCHYMAL TRANSITION (EMT) IS A BIOLOGICAL PROCESS THAT PLAYS A CRITICAL ROLE IN THE PATHOGENESIS OF PULMONARY FIBROSIS. EPIGENETIC REGULATION OF TISSUE-STROMAL CROSSTALK INVOLVING DNA METHYLATION, HISTONE MODIFICATIONS, NON-CODING RNA, AND CHROMATIN REMODELING PLAYS A KEY ROLE IN THE CONTROL OF EMT. THE REVIEW INVESTIGATES THE EPIGENETIC REGULATION OF EMT AND ITS SIGNIFICANCE IN PULMONARY FIBROSIS. 2023 4 6451 36 THERAPIES TARGETING EPIGENETIC ALTERATIONS IN ACUTE KIDNEY INJURY-TO-CHRONIC KIDNEY DISEASE TRANSITION. ACUTE KIDNEY INJURY (AKI) WAS PREVIOUSLY THOUGHT TO BE A MERELY TRANSIENT EVENT; HOWEVER, RECENT EPIDEMIOLOGICAL EVIDENCE SUPPORTS THE EXISTENCE OF A CAUSAL RELATIONSHIP BETWEEN AKI EPISODES AND SUBSEQUENT PROGRESSION TO CHRONIC KIDNEY DISEASE (CKD). ALTHOUGH THE PATHOPHYSIOLOGY OF THIS AKI-TO-CKD TRANSITION IS NOT FULLY UNDERSTOOD, IT IS MEDIATED BY THE INTERPLAY AMONG MULTIPLE COMPONENTS OF THE KIDNEY INCLUDING TUBULAR EPITHELIAL CELLS, ENDOTHELIAL CELLS, PERICYTES, INFLAMMATORY CELLS, AND MYOFIBROBLASTS. EPIGENETIC ALTERATIONS INCLUDING HISTONE MODIFICATION, DNA METHYLATION, NON-CODING RNAS, AND CHROMATIN CONFORMATIONAL CHANGES, ARE ALSO EXPECTED TO BE LARGELY INVOLVED IN THE PATHOPHYSIOLOGY AS A "MEMORY" OF THE INITIAL INJURY THAT CAN PERSIST AND PREDISPOSE TO CHRONIC PROGRESSION OF FIBROSIS. EACH EPIGENETIC MODIFICATION HAS A GREAT POTENTIAL AS A THERAPEUTIC TARGET OF AKI-TO-CKD TRANSITION; TIMELY AND TARGET-SPECIFIC EPIGENETIC INTERVENTIONS TO THE VARIOUS TEMPORAL STAGES OF AKI-TO-CKD TRANSITION WILL BE THE KEY TO FUTURE THERAPEUTIC APPLICATIONS IN CLINICAL PRACTICE. THIS REVIEW ELABORATES ON THE LATEST KNOWLEDGE OF EACH MECHANISM AND THE CURRENTLY AVAILABLE THERAPEUTIC AGENTS THAT TARGET EPIGENETIC MODIFICATION IN THE CONTEXT OF AKI-TO-CKD TRANSITION. FURTHER STUDIES WILL ELUCIDATE MORE DETAILED MECHANISMS AND NOVEL THERAPEUTIC TARGETS OF AKI-TO-CKD TRANSITION. 2022 5 2034 28 EPIGENETIC CHANGES IN THE ACUTE KIDNEY INJURY-TO-CHRONIC KIDNEY DISEASE TRANSITION. PREVIOUSLY ACUTE KIDNEY INJURY (AKI) HAD BEEN BELIEVED TO BE A TRANSIENT EVENT, AND RECOVERY FROM AKI HAD BEEN THOUGHT TO LEAD TO NO CONSEQUENCES. HOWEVER, RECENT EPIDEMIOLOGICAL STUDIES HAVE SHOWN THAT EVEN IF THERE IS COMPLETE RECOVERY OF THE KIDNEY FUNCTION, AKI CAN EVENTUALLY RESULT IN CHRONIC KIDNEY DISEASE (CKD) AND EVENTUALLY IN END-STAGE KIDNEY DISEASE IN THE LONG TERM. TRANSITION OF AKI TO CKD IS MEDIATED BY MULTIPLE MECHANISMS, INCLUDING ABERRANT CELL CYCLE ARREST AND HYPOXIA. HYPOXIA OF THE KIDNEY IS INDUCED BY RAREFACTION OF THE PERITUBULAR CAPILLARIES AFTER AKI EPISODES, AND INDUCES INFLAMMATION AND FIBROSIS. IT SHOULD ALSO BE NOTED THAT EPIGENETIC CHANGES ARE CLOSELY RELATED TO HYPOXIA, AND EPIGENETIC CHANGES INDUCED BY HYPOXIA, CALLED "HYPOXIC MEMORY" CAN EXPLAIN THE AKI-TO-CKD TRANSITION IN THE LONG TERM AFTER COMPLETE RECOVERY FROM THE INITIAL AKI EPISODE. TARGETING HYPOXIA AND SUBSEQUENT EPIGENETIC CHANGES ARE PROMISING STRATEGIES TO BLOCK THE TRANSITION FROM AKI TO CKD. 2017 6 4513 25 MULTI-OMIC APPROACHES TO ACUTE KIDNEY INJURY AND REPAIR. THE KIDNEY HAS A REMARKABLE REGENERATIVE CAPACITY. IN RESPONSE TO ISCHEMIC OR TOXIC INJURY, PROXIMAL TUBULE CELLS CAN PROLIFERATE TO REBUILD DAMAGED TUBULES AND RESTORE KIDNEY FUNCTION. HOWEVER, SEVERE ACUTE KIDNEY INJURY (AKI) OR RECURRENT AKI EVENTS CAN LEAD TO MALADAPTIVE REPAIR AND DISEASE PROGRESSION FROM AKI TO CHRONIC KIDNEY DISEASE (CKD). THE APPLICATION OF SINGLE CELL TECHNOLOGIES HAS IDENTIFIED INJURED PROXIMAL TUBULE CELL STATES WEEKS AFTER AKI, DISTINGUISHED BY A PRO-INFLAMMATORY SENESCENT MOLECULAR SIGNATURE. EPIGENETIC STUDIES HIGHLIGHTED DYNAMIC CHANGES IN THE CHROMATIN LANDSCAPE OF THE KIDNEY FOLLOWING AKI AND DESCRIBED KEY TRANSCRIPTION FACTORS LINKED TO THE AKI RESPONSE. THE INTEGRATION OF MULTI-OMIC TECHNOLOGIES OPENS NEW POSSIBILITIES TO IMPROVE OUR UNDERSTANDING OF AKI AND THE DRIVING FORCES BEHIND THE AKI-TO-CKD TRANSITION, WITH THE ULTIMATE GOAL OF DESIGNING TAILORED DIAGNOSTIC AND THERAPEUTIC STRATEGIES TO IMPROVE AKI OUTCOMES AND PREVENT KIDNEY DISEASE PROGRESSION. 2021 7 2191 42 EPIGENETIC MEMORY CONTRIBUTING TO THE PATHOGENESIS OF AKI-TO-CKD TRANSITION. EPIGENETIC MEMORY, WHICH REFERS TO THE ABILITY OF CELLS TO RETAIN AND TRANSMIT EPIGENETIC MARKS TO THEIR DAUGHTER CELLS, MAINTAINS UNIQUE GENE EXPRESSION PATTERNS. ESTABLISHING PROGRAMMED EPIGENETIC MEMORY AT EACH STAGE OF DEVELOPMENT IS REQUIRED FOR CELL DIFFERENTIATION. MOREOVER, ACCUMULATING EVIDENCE SHOWS THAT EPIGENETIC MEMORY ACQUIRED IN RESPONSE TO ENVIRONMENTAL STIMULI MAY BE ASSOCIATED WITH DIVERSE DISEASES. IN THE FIELD OF KIDNEY DISEASES, THE "MEMORY" OF ACUTE KIDNEY INJURY (AKI) LEADS TO PROGRESSION TO CHRONIC KIDNEY DISEASE (CKD); EPIDEMIOLOGICAL STUDIES SHOW THAT PATIENTS WHO RECOVER FROM AKI ARE AT HIGH RISK OF DEVELOPING CKD. THE UNDERLYING PATHOLOGICAL PROCESSES INCLUDE NEPHRON LOSS, MALADAPTIVE EPITHELIAL REPAIR, INFLAMMATION, AND ENDOTHELIAL INJURY WITH VASCULAR RAREFACTION. FURTHER, EPIGENETIC ALTERATIONS MAY CONTRIBUTE AS WELL TO THE PATHOPHYSIOLOGY OF THIS AKI-TO-CKD TRANSITION. EPIGENETIC CHANGES INDUCED BY AKI, WHICH CAN BE RECORDED IN CELLS, EXERT LONG-TERM EFFECTS AS EPIGENETIC MEMORY. CONSIDERING THE LATEST FINDINGS ON THE MOLECULAR BASIS OF EPIGENETIC MEMORY AND THE PATHOPHYSIOLOGY OF AKI-TO-CKD TRANSITION, WE PROPOSE HERE THAT EPIGENETIC MEMORY CONTRIBUTING TO AKI-TO-CKD TRANSITION CAN BE CLASSIFIED ACCORDING TO THE PRESENCE OR ABSENCE OF PERSISTENT CHANGES IN THE ASSOCIATED REGULATION OF GENE EXPRESSION, WHICH WE DESIGNATE "DRIVING" MEMORY AND "PRIMING" MEMORY, RESPECTIVELY. "DRIVING" MEMORY, WHICH PERSISTENTLY ALTERS THE REGULATION OF GENE EXPRESSION, MAY CONTRIBUTE TO DISEASE PROGRESSION BY ACTIVATING FIBROGENIC GENES OR INHIBITING RENOPROTECTIVE GENES. THIS PROCESS MAY BE INVOLVED IN GENERATING THE PROINFLAMMATORY AND PROFIBROTIC PHENOTYPES OF MALADAPTIVELY REPAIRED TUBULAR CELLS AFTER KIDNEY INJURY. "PRIMING" MEMORY IS STORED IN SEEMINGLY SUCCESSFULLY REPAIRED TUBULAR CELLS IN THE ABSENCE OF DETECTABLE PERSISTENT PHENOTYPIC CHANGES, WHICH MAY ENHANCE A SUBSEQUENT TRANSCRIPTIONAL RESPONSE TO THE SECOND STIMULUS. THIS TYPE OF MEMORY MAY CONTRIBUTE TO AKI-TO-CKD TRANSITION THROUGH THE CUMULATIVE EFFECTS OF ENHANCED EXPRESSION OF PROFIBROTIC GENES REQUIRED FOR WOUND REPAIR AFTER RECURRENT AKI. FURTHER UNDERSTANDING OF EPIGENETIC MEMORY WILL IDENTIFY THERAPEUTIC TARGETS OF FUTURE EPIGENETIC INTERVENTION TO PREVENT AKI-TO-CKD TRANSITION. 2022 8 4381 40 MITOCHONDRIAL DYSFUNCTION AND THE AKI-TO-CKD TRANSITION. ACUTE KIDNEY INJURY (AKI) HAS BEEN WIDELY RECOGNIZED AS AN IMPORTANT RISK FACTOR FOR THE OCCURRENCE AND DEVELOPMENT OF CHRONIC KIDNEY DISEASE (CKD). EVEN MILDER AKI HAS ADVERSE CONSEQUENCES AND COULD PROGRESS TO RENAL FIBROSIS, WHICH IS THE ULTIMATE COMMON PATHWAY FOR VARIOUS TERMINAL KIDNEY DISEASES. THUS, IT IS URGENT TO DEVELOP A STRATEGY TO HINDER THE TRANSITION FROM AKI TO CKD. SOME MECHANISMS OF THE AKI-TO-CKD TRANSITION HAVE BEEN REVEALED, SUCH AS NEPHRON LOSS, CELL CYCLE ARREST, PERSISTENT INFLAMMATION, ENDOTHELIAL INJURY WITH VASCULAR RAREFACTION, AND EPIGENETIC CHANGES. PREVIOUS STUDIES HAVE ELUCIDATED THE PIVOTAL ROLE OF MITOCHONDRIA IN ACUTE INJURIES AND DEMONSTRATED THAT THE FITNESS OF THIS ORGANELLE IS A MAJOR DETERMINANT IN BOTH THE PATHOGENESIS AND RECOVERY OF ORGAN FUNCTION. RECENT RESEARCH HAS SUGGESTED THAT DAMAGE TO MITOCHONDRIAL FUNCTION IN EARLY AKI IS A CRUCIAL FACTOR LEADING TO TUBULAR INJURY AND PERSISTENT RENAL INSUFFICIENCY. DYSREGULATION OF MITOCHONDRIAL HOMEOSTASIS, ALTERATIONS IN BIOENERGETICS, AND ORGANELLE STRESS CROSS TALK CONTRIBUTE TO THE AKI-TO-CKD TRANSITION. IN THIS REVIEW, WE FOCUS ON THE PATHOPHYSIOLOGY OF MITOCHONDRIA IN RENAL RECOVERY AFTER AKI AND PROGRESSION TO CKD, CONFIRMING THAT TARGETING MITOCHONDRIA REPRESENTS A POTENTIALLY EFFECTIVE THERAPEUTIC STRATEGY FOR THE PROGRESSION OF AKI TO CKD. 2020 9 6647 35 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 10 6910 28 [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 11 4463 35 MOLECULAR MECHANISMS OF HISTONE DEACETYLASES AND INHIBITORS IN RENAL FIBROSIS PROGRESSION. RENAL FIBROSIS IS A COMMON PROGRESSIVE MANIFESTATION OF CHRONIC KIDNEY DISEASE. THIS PHENOMENON OF SELF-REPAIR IN RESPONSE TO KIDNEY DAMAGE SERIOUSLY AFFECTS THE NORMAL FILTRATION FUNCTION OF THE KIDNEY. YET, THERE ARE NO SPECIFIC TREATMENTS FOR THE CONDITION, WHICH MARKS FIBROSIS AS AN IRREVERSIBLE PATHOLOGICAL SEQUELA. AS SUCH, THERE IS A PRESSING NEED TO IMPROVE OUR UNDERSTANDING OF HOW FIBROSIS DEVELOPS AT THE CELLULAR AND MOLECULAR LEVELS AND EXPLORE SPECIFIC TARGETED THERAPIES FOR THESE PATHOGENIC MECHANISMS. IT IS NOW GENERALLY ACCEPTED THAT RENAL FIBROSIS IS A PATHOLOGICAL TRANSITION MEDIATED BY EXTRACELLULAR MATRIX (ECM) DEPOSITION, ABNORMAL ACTIVATION OF MYOFIBROBLASTS, AND EPITHELIAL-MESENCHYMAL TRANSITION (EMT) OF RENAL TUBULAR EPITHELIAL CELLS UNDER THE REGULATION OF TGF-BETA. HISTONE DEACETYLASES (HDACS) APPEAR TO PLAY AN ESSENTIAL ROLE IN PROMOTING RENAL FIBROSIS THROUGH NON-HISTONE EPIGENETIC MODIFICATIONS. IN THIS REVIEW, WE SUMMARIZE THE MECHANISMS OF RENAL FIBROSIS AND THE SIGNALING PATHWAYS THAT MIGHT BE INVOLVED IN HDACS IN RENAL FIBROSIS, AND THE SPECIFIC MECHANISMS OF ACTION OF VARIOUS HDAC INHIBITORS (HDACI) IN THE ANTI-FIBROTIC PROCESS TO ELUCIDATE HDACI AS A NOVEL THERAPEUTIC TOOL TO SLOW DOWN THE PROGRESSION OF RENAL FIBROSIS. 2022 12 3512 35 IDIOPATHIC PULMONARY FIBROSIS. IDIOPATHIC PULMONARY FIBROSIS IS A DEVASTATING, AGE-RELATED LUNG DISEASE OF UNKNOWN CAUSE THAT HAS FEW TREATMENT OPTIONS. THIS DISEASE WAS ONCE THOUGHT TO BE A CHRONIC INFLAMMATORY PROCESS, BUT CURRENT EVIDENCE INDICATES THAT THE FIBROTIC RESPONSE IS DRIVEN BY ABNORMALLY ACTIVATED ALVEOLAR EPITHELIAL CELLS (AECS). THESE CELLS PRODUCE MEDIATORS THAT INDUCE THE FORMATION OF FIBROBLAST AND MYOFIBROBLAST FOCI THROUGH THE PROLIFERATION OF RESIDENT MESENCHYMAL CELLS, ATTRACTION OF CIRCULATING FIBROCYTES, AND STIMULATION OF THE EPITHELIAL TO MESENCHYMAL TRANSITION. THE FIBROBLAST AND MYOFIBROBLAST FOCI SECRETE EXCESSIVE AMOUNTS OF EXTRACELLULAR MATRIX, MAINLY COLLAGENS, RESULTING IN SCARRING AND DESTRUCTION OF THE LUNG ARCHITECTURE. THE MECHANISMS THAT LINK IDIOPATHIC PULMONARY FIBROSIS WITH AGEING AND ABERRANT EPITHELIAL ACTIVATION ARE UNKNOWN; EVIDENCE SUGGESTS THAT THE ABNORMAL RECAPITULATION OF DEVELOPMENTAL PATHWAYS AND EPIGENETIC CHANGES HAVE A ROLE. IN THIS SEMINAR, WE REVIEW RECENT DATA ON THE CLINICAL COURSE, THERAPEUTIC OPTIONS, AND UNDERLYING MECHANISMS THOUGHT TO BE INVOLVED IN THE PATHOGENESIS OF IDIOPATHIC PULMONARY FIBROSIS. 2011 13 95 32 A POSSIBLE ROLE FOR EPIGENETIC FEEDBACK REGULATION IN THE DYNAMICS OF THE EPITHELIAL-MESENCHYMAL TRANSITION (EMT). THE EPITHELIAL-MESENCHYMAL TRANSITION (EMT) OFTEN PLAYS A CRITICAL ROLE IN CANCER METASTASIS AND CHEMORESISTANCE, AND DECODING ITS DYNAMICS IS CRUCIAL TO DESIGN EFFECTIVE THERAPEUTICS. EMT IS REGULATED AT MULTIPLE LEVELS-TRANSCRIPTIONAL, TRANSLATIONAL, PROTEIN STABILITY AND EPIGENETICS; THE MECHANISMS BY WHICH EPIGENETIC REGULATION CAN ALTER THE DYNAMICS OF EMT REMAIN ELUSIVE. HERE, TO IDENTIFY THE POSSIBLE EFFECTS OF EPIGENETIC REGULATION IN EMT, WE INCORPORATE A FEEDBACK TERM IN OUR PREVIOUSLY PROPOSED MODEL OF EMT REGULATION OF THE MIR-200/ZEB/MIR-34/SNAIL CIRCUIT. THIS EPIGENETIC FEEDBACK THAT STABILIZES LONG-TERM TRANSCRIPTIONAL ACTIVITY CAN ALTER THE RELATIVE STABILITY AND DISTRIBUTION OF STATES IN A GIVEN CELL POPULATION, PARTICULARLY WHEN INCORPORATED IN THE INHIBITORY EFFECT ON MIR-200 FROM ZEB. THIS FEEDBACK CAN STABILIZE THE MESENCHYMAL STATE, THUS MAKING TRANSITIONS OUT OF THAT STATE DIFFICULT. CONVERSELY, EPIGENETIC REGULATION OF THE SELF-ACTIVATION OF ZEB HAS ONLY MINOR EFFECTS. OUR MODEL PREDICTS THAT THIS EFFECT COULD BE SEEN IN EXPERIMENTS, WHEN EPITHELIAL CELLS ARE TREATED WITH AN EXTERNAL EMT-INDUCING SIGNAL FOR A SUFFICIENTLY LONG PERIOD OF TIME AND THEN ALLOWED TO RECOVER. OUR PRELIMINARY EXPERIMENTAL DATA INDICATES THAT A CHRONIC TGF-BETA EXPOSURE GIVES RISE TO IRREVEVERSIBLE EMT STATE; I.E. UNABLE TO REVERSE BACK TO THE EPITHELIAL STATE. THUS, THIS INTEGRATED THEORETICAL-EXPERIMENTAL APPROACH YIELDS INSIGHTS INTO HOW AN EPIGENETIC FEEDBACK MAY ALTER THE DYNAMICS OF EMT. 2019 14 3674 35 INFLAMMATION AND DYSREGULATED FIBROBLAST PROLIFERATION--NEW MECHANISMS? IDIOPATHIC PULMONARY FIBROSIS (IPF) IS A DEVASTATING, AGE-RELATED LUNG DISEASE OF UNKNOWN CAUSE THAT HAS FEW TREATMENT OPTIONS. ONCE THOUGHT TO BE A CHRONIC INFLAMMATORY PROCESS, CURRENT EVIDENCE INDICATES THAT THE FIBROTIC RESPONSE MAY PRIMARILY BE DRIVEN BY ABNORMALLY ACTIVATED ALVEOLAR EPITHELIAL CELLS AND THE UNDERLYING MESENCHYME. THE MEDIATORS PRODUCED AND PRESENT IN THIS MICROENVIRONMENT INDUCE THE FORMATION OF FIBROBLAST FOCI THROUGH THE PROLIFERATION OF RESIDENT MESENCHYMAL CELLS, ATTRACTION OF CIRCULATING FIBROCYTES, AND STIMULATION OF EPITHELIAL TO MESENCHYMAL TRANSITION. THE FIBROBLAST AND MYOFIBROBLAST FOCI SECRETE EXCESSIVE AMOUNTS OF EXTRACELLULAR MATRIX, MAINLY COLLAGENS, RESULTING IN SCARRING AND DESTRUCTION OF THE LUNG ARCHITECTURE. THE DETAILED MECHANISMS THAT LINK IPF WITH AGEING AND ABERRANT EPITHELIAL ACTIVATION ARE UNKNOWN, BUT SOME EVIDENCE SUGGESTS THAT THE ABNORMAL RECAPITULATION OF DEVELOPMENTAL PATHWAYS AND EPIGENETIC CHANGES MAY PLAY A ROLE. THIS REVIEW PROVIDES A BRIEF SYNOPSIS OF HIGHLIGHTS IN THE CURRENT UNDERSTANDING OF THE PATHOPHYSIOLOGY OF IPF, AS WELL AS NOVEL THERAPEUTICS BEING EXPLORED IN CLINICAL TRIALS FOR THE TREATMENT OF THIS DEVASTATING DISEASE. 2013 15 5992 34 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 16 2293 35 EPIGENETIC REGULATION IN THE ACUTE KIDNEY INJURY TO CHRONIC KIDNEY DISEASE TRANSITION. EPIGENETIC MODIFICATIONS HAVE EMERGED AS A NEW, IMPORTANT CONTRIBUTOR TO GENE EXPRESSION REGULATION IN BOTH NORMAL AND PATHOPHYSIOLOGICAL CONDITIONS. EPIGENETICS HAVE BEEN STUDIED IN MANY DISEASES AND CONDITIONS SUCH AS ACUTE KIDNEY INJURY (AKI), A SYNDROME WITH A HIGH PREVALENCE THAT CARRIES A POOR PROGNOSIS WITH INCREASED MORBIDITY AND MORTALITY. IN ADDITION, IT HAS RECENTLY BEEN SHOWN THAT AKI INCREASES THE RISK FOR THE DEVELOPMENT OF CHRONIC KIDNEY DISEASE (CKD). THE SPECIFIC MOLECULAR MECHANISMS BY WHICH AKI INCREASES THE RISK OF CKD AND END STAGE RENAL DISEASE (ESRD) REMAIN UNKNOWN, ALTHOUGH THERE IS NEW EVIDENCE SUPPORTING A ROLE OF EPIGENETIC CHANGES. THE MOST STUDIED EPIGENETIC REGULATIONS IN AKI ARE CHROMATIN COMPACTION, DNA METHYLATION, AND HISTONE ACETYLATION/DEACETYLATION. THESE MODIFICATIONS PREDOMINANTLY INCREASE THE PRODUCTION OF PRO-INFLAMMATORY AND PROFIBROTIC CYTOKINES SUCH AS: MONOCYTE CHEMOATTRACTANT PROTEIN-1 (MCP-1), COMPLEMENT PROTEIN 3 (C3), TRANSFORMING GROWTH FACTOR BETA (TGF-BETA) THAT HAVE BEEN SHOWN FOR PERPETUATING INFLAMMATION, PROMOTING EPITHELIAL-TO-MESENCHYMAL TRANSITION (EMT) AND ULTIMATELY CAUSING RENAL FIBROSIS. A REVIEW OF EPIGENETIC MECHANISMS, THE PATHOPHYSIOLOGY OF AKI AND RECENT STUDIES THAT IMPLICATE EPIGENETIC MODIFICATIONS IN AKI AND IN THE TRANSITION TO CKD ARE DISCUSSED BELOW. 2015 17 3289 27 HIF-1ALPHA MEDIATES TUMOR HYPOXIA TO CONFER A PERPETUAL MESENCHYMAL PHENOTYPE FOR MALIGNANT PROGRESSION. ALTHOUGH TUMOR PROGRESSION INVOLVES GENETIC AND EPIGENETIC ALTERATIONS TO NORMAL CELLULAR BIOLOGY, THE UNDERLYING MECHANISMS OF THESE CHANGES REMAIN OBSCURE. NUMEROUS STUDIES HAVE SHOWN THAT HYPOXIA-INDUCIBLE FACTOR 1ALPHA (HIF-1ALPHA) IS OVEREXPRESSED IN MANY HUMAN CANCERS AND UP-REGULATES A HOST OF HYPOXIA-RESPONSIVE GENES FOR CANCER GROWTH AND SURVIVAL. WE RECENTLY IDENTIFIED AN ALTERNATIVE MECHANISM OF HIF-1ALPHA FUNCTION THAT INDUCES GENETIC ALTERATIONS BY SUPPRESSING DNA REPAIR. HERE, WE SHOW THAT LONG-TERM HYPOXIA, WHICH MIMICS THE TUMOR MICROENVIRONMENT, DRIVES A PERPETUAL EPITHELIAL-MESENCHYMAL TRANSITION (EMT) THROUGH UP-REGULATION OF THE ZINC FINGER E-BOX BINDING HOMEOBOX PROTEIN ZEB2, WHEREAS SHORT-TERM HYPOXIA INDUCES A REVERSIBLE EMT THAT REQUIRES THE TRANSCRIPTION FACTOR TWIST1. MOREOVER, WE SHOW THAT THE PERPETUAL EMT DRIVEN BY CHRONIC HYPOXIA DEPENDS ON HIF-1ALPHA INDUCTION OF GENETIC ALTERATIONS RATHER THAN ITS CANONICAL TRANSCRIPTIONAL ACTIVATOR FUNCTION. THESE MESENCHYMAL TUMOR CELLS NOT ONLY ACQUIRE TUMORIGENICITY BUT ALSO DISPLAY CHARACTERISTICS OF ADVANCED CANCERS, INCLUDING NECROSIS, AGGRESSIVE INVASION, AND METASTASIS. HENCE, THESE RESULTS REVEAL A MECHANISM BY WHICH HIF-1ALPHA PROMOTES A PERPETUAL MESENCHYMAL PHENOTYPE, THEREBY ADVANCING TUMOR PROGRESSION. 2011 18 5733 31 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 19 6687 23 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 20 2788 36 FACTORS AFFECTING THE TRANSITION OF ACUTE KIDNEY INJURY TO CHRONIC KIDNEY DISEASE: POTENTIAL MECHANISMS AND FUTURE PERSPECTIVES. ACUTE KIDNEY INJURY (AKI) IS DEFINED AS A RAPID LOSS OF KIDNEY FUNCTION CHARACTERISED BY INFLAMMATION AND CELL DEATH, ULTIMATELY LEADING TO FURTHER FUNCTIONAL AND STRUCTURAL RENAL ALTERATIONS. BASED ON EXPERIMENTAL AND EPIDEMIOLOGICAL PIECES OF EVIDENCE, AKI MAY PROGRESS TO CHRONIC KIDNEY DISEASE (CKD) EVEN AFTER A RECOVERY PERIOD DUE TO MALADAPTIVE REPAIR AND OTHER UNDERLYING MECHANISMS SUCH AS HEIGHTENED WNT SIGNALLING, OVERSTIMULATION OF THE RENIN-ANGIOTENSIN-ALDOSTERONE-SYSTEM (RAAS) PATHWAY, EPIGENETIC ALTERATIONS AND INHIBITION OF HYPOXIA-INDUCIBLE FACTOR (HIF) DEPENDENT DEFENCES. IT HAS BEEN REPORTED THAT RAAS ACTIVATION SUBSEQUENT TO RENAL INSULT MEDIATES INFLAMMATORY AND FIBROTIC MECHANISMS, WHICH ARE A HALLMARK OF CKD. MOREOVER, INTERESTING EVIDENCE REGARDING THE EXPOSURE-DEPENDENT DUAL ROLE OF WNT SIGNALLING IN BOTH INJURY AND REPAIR, EPIGENETIC CHANGES UNDERLYING KIDNEY DISEASE SUGGEST A POTENTIAL THERAPEUTIC ROLE OF THESE PATHWAYS IN AKI TO CKD CONTINUUM. IN ADDITION, THE HYPOXIA-INDEPENDENT RENAL BENEFITS OF ERYTHROPOIETIN SUCH AS ANTI-APOPTOSIS AND TUBULAR REGENERATION ALSO PRESENT AN AUSPICIOUS TARGET WHICH COULD BE USEFUL IN CLINICAL SETTINGS. IN THIS REVIEW, THE SPECIFIC ROLES OF THESE PATHWAYS IN KIDNEY DISEASE, THEIR PATHOLOGICAL MECHANISMS AND THERAPEUTIC STRATEGIES ARE DISCUSSED. MOREOVER, NOTABLE REPORTS CONCERNING STEM CELL THERAPY WHICH HOLD PROMISE IN HALTING AKI-CKD CONTINUUM WILL BE ELABORATED. 2019