1 3367 96 HISTONE METHYLTRANSFERASE EZH2: A POTENTIAL THERAPEUTIC TARGET FOR KIDNEY DISEASES. ENHANCER OF ZESTE HOMOLOG 2 (EZH2) IS A HISTONE-LYSINE N-METHYLTRANSFERASE ENZYME THAT CATALYZES THE ADDITION OF METHYL GROUPS TO HISTONE H3 AT LYSINE 27, LEADING TO GENE SILENCING. MUTATION OR OVER-EXPRESSION OF EZH2 HAS BEEN LINKED TO MANY CANCERS INCLUDING RENAL CARCINOMA. RECENT STUDIES HAVE SHOWN THAT EZH2 EXPRESSION AND ACTIVITY ARE ALSO INCREASED IN SEVERAL ANIMAL MODELS OF KIDNEY INJURY, SUCH AS ACUTE KIDNEY INJURY (AKI), RENAL FIBROSIS, DIABETIC NEPHROPATHY, LUPUS NEPHRITIS (LN), AND RENAL TRANSPLANTATION REJECTION. THE PHARMACOLOGICAL AND/OR GENETIC INHIBITION OF EZH2 CAN ALLEVIATE AKI, RENAL FIBROSIS, AND LN, BUT POTENTIATE PODOCYTE INJURY IN ANIMAL MODELS, SUGGESTING THAT THE FUNCTIONAL ROLE OF EZH2 VARIES WITH RENAL CELL TYPE AND DISEASE MODEL. IN THIS ARTICLE, WE SUMMARIZE THE ROLE OF EZH2 IN THE PATHOLOGY OF RENAL INJURY AND RELEVANT MECHANISMS AND HIGHLIGHT EZH2 AS A POTENTIAL THERAPEUTIC TARGET FOR KIDNEY DISEASES. 2021 2 6321 52 THE ROLE AND MECHANISM OF LYSINE METHYLTRANSFERASE AND ARGININE METHYLTRANSFERASE IN KIDNEY DISEASES. METHYLATION CAN OCCUR IN BOTH HISTONES AND NON-HISTONES. KEY LYSINE AND ARGININE METHYLTRANSFERASES UNDER INVESTIGATION FOR RENAL DISEASE TREATMENT INCLUDE ENHANCER OF ZESTE HOMOLOG 2 (EZH2), G9A, DISRUPTOR OF TELOMERIC SILENCING 1-LIKE PROTEIN (DOT1L), AND PROTEIN ARGININE METHYLTRANSFERASES (PRMT) 1 AND 5. RECENT STUDIES HAVE SHOWN THAT METHYLTRANSFERASES EXPRESSION AND ACTIVITY ARE ALSO INCREASED IN SEVERAL ANIMAL MODELS OF KIDNEY INJURY, SUCH AS ACUTE KIDNEY INJURY(AKI), OBSTRUCTIVE NEPHROPATHY, DIABETIC NEPHROPATHY AND LUPUS NEPHRITIS. THE INHIBITION OF MOST METHYLTRANSFERASES CAN ATTENUATE KIDNEY INJURY, WHILE THE ROLE OF METHYLTRANSFERASE IN DIFFERENT ANIMAL MODELS REMAINS CONTROVERSIAL. IN THIS ARTICLE, WE SUMMARIZE THE ROLE AND MECHANISM OF LYSINE METHYLTRANSFERASE AND ARGININE METHYLTRANSFERASE IN VARIOUS KIDNEY DISEASES AND HIGHLIGHT METHYLTRANSFERASE AS A POTENTIAL THERAPEUTIC TARGET FOR KIDNEY DISEASES. 2022 3 3326 41 HISTONE DEACETYLASE 3 (HDAC3) AS AN IMPORTANT EPIGENETIC REGULATOR OF KIDNEY DISEASES. DEVELOPMENT AND PROGRESSION OF MANY KIDNEY DISEASES ARE SUBSTANTIALLY INFLUENCED BY ABERRANT PROTEIN ACETYLATION MODIFICATIONS OF GENE EXPRESSION CRUCIAL FOR KIDNEY FUNCTIONS. HISTONE DEACETYLASE (HDAC) EXPRESSION ALTERATIONS ARE DETECTED FROM RENAL SAMPLES OF PATIENTS AND ANIMAL MODELS OF VARIOUS KIDNEY DISEASES, AND THE ADMINISTRATIONS OF HDAC INHIBITORS DISPLAY IMPRESSIVE RENAL PROTECTIVE EFFECTS IN VITRO AND IN VIVO. HOWEVER, WHEN THE EXPRESSION ALTERATIONS OF MULTIPLE HDACS OCCUR, NOT ALL THE HDACS CAUSALLY AFFECT THE DISEASE ONSET OR PROGRESSION. IDENTIFICATION OF A SINGLE HDAC AS A DISEASE-CAUSING FACTOR WILL ALLOW SUBTYPE-TARGETED INTERVENTION WITH LESS SIDE EFFECT. HDAC3 IS A UNIQUE HDAC WITH DISTINCT STRUCTURAL AND SUBCELLULAR DISTRIBUTION FEATURES AND CO-REPRESSOR DEPENDENCY. HDAC3 IS REQUIRED FOR KIDNEY DEVELOPMENT AND ITS ABERRATIONS ACTIVELY PARTICIPATE IN MANY PATHOLOGICAL PROCESSES, SUCH AS CANCER, CARDIOVASCULAR DISEASES, DIABETES, AND NEURODEGENERATIVE DISORDERS, AND CONTRIBUTE SIGNIFICANTLY TO THE PATHOGENESIS OF KIDNEY DISEASES. THIS REVIEW WILL DISCUSS THE RECENT STUDIES THAT INVESTIGATE THE CRITICAL ROLES OF HDAC3 ABERRATIONS IN KIDNEY DEVELOPMENT, RENAL AGING, RENAL CELL CARCINOMA, RENAL FIBROSIS, CHRONIC KIDNEY DISEASE, POLYCYSTIC KIDNEY DISEASE, GLOMERULAR PODOCYTE INJURY, AND DIABETIC NEPHROPATHY. THESE STUDIES REVEAL THE DISTINCT CHARACTERS OF HDAC3 ABERRATIONS THAT ACT ON DIFFERENT MOLECULES/SIGNALING PATHWAYS UNDER VARIOUS RENAL PATHOLOGICAL CONDITIONS, WHICH MIGHT SHED LIGHTS INTO THE EPIGENETIC MECHANISMS OF RENAL DISEASES AND THE POTENTIALLY THERAPEUTIC STRATEGIES. 2022 4 347 36 ALTERED DNA METHYLATION IN KIDNEY DISEASE: USEFUL MARKERS AND THERAPEUTIC TARGETS. RECENT STUDIES HAVE DEMONSTRATED THE ASSOCIATION OF ALTERED EPIGENOMES WITH LIFESTYLE-RELATED DISEASES. EPIGENETIC REGULATION PROMOTES BIOLOGICAL PLASTICITY IN RESPONSE TO ENVIRONMENTAL CHANGES, AND SUCH PLASTICITY MAY CAUSE A 'MEMORY EFFECT', A SUSTAINED EFFECT OF TRANSIENT TREATMENT OR AN INSULT IN THE COURSE OF LIFESTYLE-RELATED DISEASES. WE INVESTIGATED THE SIGNIFICANCE OF EPIGENETIC CHANGES IN SEVERAL GENES REQUIRED FOR RENAL INTEGRITY, INCLUDING THE NEPHRIN GENE IN PODOCYTES, AND THE SUSTAINED ANTI-PROTEINURIC EFFECT, FOCUSING ON THE TRANSCRIPTION FACTOR KRUPPEL-LIKE FACTOR 4 (KLF4). WE FURTHER REPORTED THE ROLE OF THE DNA REPAIR FACTOR LYSINE-ACETYL TRANSFERASE 5 (KAT5), WHICH ACTS COORDINATELY WITH KLF4, IN PODOCYTE INJURY CAUSED BY A HYPERGLYCEMIC STATE THROUGH THE ACCELERATION OF DNA DAMAGE AND EPIGENETIC ALTERATION. IN CONTRAST, KAT5 IN PROXIMAL TUBULAR CELLS PREVENTS ACUTE KIDNEY INJURY VIA GLOMERULAR FILTRATION REGULATION BY AN EPIGENETIC MECHANISM AS WELL AS PROMOTION OF DNA REPAIR, INDICATING THE CELL TYPE-SPECIFIC ACTION AND ROLES OF DNA REPAIR FACTORS. THIS REVIEW SUMMARIZES EPIGENETIC ALTERATIONS IN KIDNEY DISEASES, ESPECIALLY DNA METHYLATION, AND THEIR UTILITY AS MARKERS AND POTENTIAL THERAPEUTIC TARGETS. FOCUSING ON TRANSCRIPTION FACTORS OR DNA DAMAGE REPAIR FACTORS ASSOCIATED WITH EPIGENETIC CHANGES MAY BE MEANINGFUL DUE TO THEIR CELL-SPECIFIC EXPRESSION OR ACTION. WE BELIEVE THAT A BETTER UNDERSTANDING OF EPIGENETIC ALTERATIONS IN THE KIDNEY WILL LEAD TO THE DEVELOPMENT OF A NOVEL STRATEGY FOR CHRONIC KIDNEY DISEASE (CKD) TREATMENT. 2022 5 6510 32 TRANSCRIPTION FACTORS AND EPIGENETIC MODULATION: ITS THERAPEUTIC IMPLICATION IN CHRONIC KIDNEY DISEASE. RECENTLY EMERGING EVIDENCE HAS SHOWN THAT EPIGENETIC MECHANISMS ARE INVOLVED IN INITIATION AND PROGRESSION OF VARIOUS DISEASES, INCLUDING KIDNEY DISEASES. IN THE PRESENT ARTICLE, WE REVIEW THE CURRENT DATA REGARDING THE ROLE OF EPIGENETIC MODULATION IN CHRONIC KIDNEY DISEASE (CKD) AND KIDNEY FIBROSIS, INCLUDING DNA METHYLATION AND HISTONE MODIFICATION. ESPECIALLY WE FOCUSED ON THE ROLE OF TRANSCRIPTION FACTORS IN EPIGENETIC MODULATION AND THE POSSIBILITY OF THERAPEUTIC TARGET OF CKD. WE HAVE RECENTLY REPORTED THAT TRANSCRIPTION FACTOR KRUPPEL-LIKE FACTOR 4 (ALSO KNOWN AS GUT-ENRICHED KRUPPEL-LIKE FACTOR) IS EXPRESSED IN KIDNEY PODOCYTES (VISCERAL EPITHELIAL CELLS) AND MODULATES PODOCYTE PHENOTYPE BY GENE-SELECTIVE EPIGENETIC CONTROL. TARGETING TRANSCRIPTION FACTORS FOR EPIGENETIC MODIFICATION MAY BE A GOOD CANDIDATE FOR REMISSION AND REGRESSION OF CKD. IT IS NECESSARY FOR THE THERAPY OF CKD WITH AN EPIGENETIC-BASED APPROACH TO INVESTIGATE ORGAN-, TISSUE-, OR GENE-SPECIFIC TREATMENT METHODS FOR REDUCTION OF SIDE EFFECTS. 2015 6 4463 28 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 7 5925 36 TARGETING EPIGENETIC DNA AND HISTONE MODIFICATIONS TO TREAT KIDNEY DISEASE. EPIGENETICS REFERS TO HERITABLE CHANGES IN GENE EXPRESSION PATTERNS NOT CAUSED BY AN ALTERED NUCLEOTIDE SEQUENCE, AND INCLUDES NON-CODING RNAS AND COVALENT MODIFICATIONS OF DNA AND HISTONES. THIS REVIEW FOCUSES ON FUNCTIONAL EVIDENCE FOR THE INVOLVEMENT OF DNA AND HISTONE EPIGENETIC MODIFICATIONS IN THE PATHOGENESIS OF KIDNEY DISEASE AND THE POTENTIAL THERAPEUTIC IMPLICATIONS. THERE IS EVIDENCE OF ACTIVATION OF EPIGENETIC REGULATORY MECHANISMS IN ACUTE KIDNEY INJURY (AKI), CHRONIC KIDNEY DISEASE (CKD) AND THE AKI-TO-CKD TRANSITION OF DIVERSE AETIOLOGIES, INCLUDING ISCHAEMIA-REPERFUSION INJURY, NEPHROTOXICITY, URETERAL OBSTRUCTION, DIABETES, GLOMERULONEPHRITIS AND POLYCYSTIC KIDNEY DISEASE. A BENEFICIAL IN VIVO EFFECT OVER PRECLINICAL KIDNEY INJURY HAS BEEN REPORTED FOR DRUGS THAT DECREASE DNA METHYLATION BY EITHER INHIBITING DNA METHYLATION (E.G. 5-AZACYTIDINE AND DECITABINE) OR ACTIVATING DNA DEMETHYLATION (E.G. HYDRALAZINE), DECREASE HISTONE METHYLATION BY INHIBITING HISTONE METHYLTRANSFERASES, INCREASE HISTONE ACETYLATION BY INHIBITING HISTONE DEACETYLASES (HDACS, E.G. VALPROIC ACID, VORINOSTAT, ENTINOSTAT), INCREASE HISTONE CROTONYLATION (CROTONATE) OR INTERFERE WITH HISTONE MODIFICATION READERS [E.G. INHIBITS OF BROMODOMAIN AND EXTRA-TERMINAL PROTEINS (BET)]. MOST PRECLINICAL STUDIES ADDRESSED CKD OR THE AKI-TO-CKD TRANSITION. CROTONATE ADMINISTRATION PROTECTED FROM NEPHROTOXIC AKI, BUT EVIDENCE IS CONFLICTING ON DNA METHYLATION INHIBITORS FOR PRECLINICAL AKI. SEVERAL DRUGS TARGETING EPIGENETIC REGULATORS ARE IN CLINICAL DEVELOPMENT OR USE, MOST OF THEM FOR MALIGNANCY. THE BET INHIBITOR APABETALONE IS IN PHASE 3 TRIALS FOR ATHEROSCLEROSIS, KIDNEY FUNCTION BEING A SECONDARY ENDPOINT, BUT NEPHROTOXICITY WAS REPORTED FOR DNA AND HDAC INHIBITORS. WHILE RESEARCH INTO EPIGENETIC MODULATORS MAY PROVIDE NOVEL THERAPIES FOR KIDNEY DISEASE, CAUTION SHOULD BE EXERCISED BASED ON THE CLINICAL NEPHROTOXICITY OF SOME DRUGS. 2018 8 3349 34 HISTONE DEACETYLASES TAKE CENTER STAGE ON REGULATION OF PODOCYTE FUNCTION. BACKGROUND: PODOCYTES (HIGHLY SPECIALIZED AND TERMINALLY DIFFERENTIATED EPITHELIAL CELLS) ARE INTEGRAL COMPONENTS OF THE GLOMERULAR FILTRATION BARRIER THAT ARE VULNERABLE TO A VARIETY OF INJURIES AND, AS A RESULT, THEY UNDERGO A SERIES OF CHANGES RANGING FROM HYPERTROPHY TO DETACHMENT AND APOPTOSIS. PODOCYTE INJURY IS A MAJOR DETERMINANT IN PROTEINURIC KIDNEY DISEASE AND IDENTIFICATION OF POTENTIAL THERAPEUTIC TARGETS FOR PREVENTING PODOCYTE INJURY HAS CLINICAL IMPORTANCE. ALTHOUGH NUMEROUS STUDIES HAVE ACHIEVED DRAMATIC ADVANCES IN THE UNDERSTANDING OF PODOCYTE BIOLOGY AND ITS RELEVANCE TO RENAL INJURY, FEW EFFECTIVE AND SPECIFIC THERAPIES ARE AVAILABLE. SUMMARY: EPIGENETIC MODIFICATIONS HAVE BEEN PROVEN TO PLAY IMPORTANT ROLES IN THE PATHOGENESIS OF KIDNEY DISEASES. AMONG THEM, HISTONE DEACETYLASE (HDAC)-MEDIATED EPIGENETIC ACETYLATION IN THE KIDNEY HAS ATTRACTED MUCH ATTENTION, WHICH MAY PLAY MULTIPLE ROLES IN BOTH KIDNEY DEVELOPMENT AND THE PATHOGENESIS OF KIDNEY DISEASE. RECENT STUDIES HAVE DEMONSTRATED THAT HDAC PROTECT AGAINST PODOCYTE INJURY BY REGULATION OF INFLAMMATION, APOPTOSIS, AUTOPHAGY, MITOCHONDRIAL FUNCTION, AND INSULIN RESISTANCE. IN THIS REVIEW, WE SUMMARIZE RECENT ADVANCES IN THE UNDERSTANDING OF THE FUNCTIONS AND REGULATORY MECHANISMS OF HDAC IN PODOCYTES AND ASSOCIATED PROTEINURIC KIDNEY DISEASES. IN ADDITION, WE PROVIDE EVIDENCE OF THE POTENTIAL THERAPEUTIC EFFECTS OF HDAC INHIBITORS FOR PROTEINURIC KIDNEY DISEASE. KEY MESSAGES: PHARMACOLOGICAL TARGETING OF HDAC-MEDIATED EPIGENETIC PROCESSES MAY OPEN NEW THERAPEUTIC AVENUES FOR CHRONIC KIDNEY DISEASE. 2020 9 3369 42 HISTONE METHYLTRANSFERASES AS THERAPEUTIC TARGETS FOR KIDNEY DISEASES. EMERGING EVIDENCE HAS DEMONSTRATED THAT EPIGENETIC REGULATION PLAYS A VITAL ROLE IN GENE EXPRESSION UNDER NORMAL AND PATHOLOGICAL CONDITIONS. ALTERATIONS IN THE EXPRESSION AND ACTIVATION OF HISTONE METHYLTRANSFERASES (HMTS) HAVE BEEN REPORTED IN PRECLINICAL MODELS OF MULTIPLE KIDNEY DISEASES, INCLUDING ACUTE KIDNEY INJURY, CHRONIC KIDNEY DISEASE, DIABETIC NEPHROPATHY, POLYCYSTIC KIDNEY DISEASE, AND RENAL CELL CARCINOMA. PHARMACOLOGICAL INHIBITION OF THESE ENZYMES HAS SHOWN PROMISE IN PRECLINICAL MODELS OF THOSE RENAL DISEASES. IN THIS REVIEW, WE SUMMARIZE RECENT KNOWLEDGE REGARDING EXPRESSION AND ACTIVATION OF VARIOUS HMTS AND THEIR FUNCTIONAL ROLES IN SOME KIDNEY DISEASES. THE PRECLINICAL ACTIVITY OF CURRENTLY AVAILABLE HMT INHIBITORS AND THE MECHANISMS OF THEIR ACTIONS ARE HIGHLIGHTED. 2019 10 1474 33 DISTINCT PATTERNS OF TRANSCRIPTIONAL AND EPIGENETIC ALTERATIONS CHARACTERIZE ACUTE AND CHRONIC KIDNEY INJURY. ACUTE KIDNEY INJURY (AKI) AND CHRONIC KIDNEY DISEASE (CKD) ARE CONSIDERED EARLY AND LATE PHASES OF A PATHOLOGIC CONTINUUM OF INTERCONNECTED DISEASE STATES. ALTHOUGH CHANGES IN GENE EXPRESSION PATTERNS HAVE RECENTLY BEEN ELUCIDATED FOR THE TRANSITION OF AKI TO CKD, THE EPIGENETIC REGULATION OF KEY KIDNEY INJURY RELATED GENES REMAINS POORLY UNDERSTOOD. WE USED MULTIPLEX RT-QPCR, CHIP-QPCR AND INTEGRATIVE ANALYSIS TO COMPARE TRANSCRIPTIONAL AND EPIGENETIC CHANGES AT RENAL DISEASE-ASSOCIATED GENES ACROSS MOUSE AKI AND CKD MODELS. THESE STUDIES SHOWED THAT: (I) THERE ARE SUBSETS OF GENES WITH DISTINCT TRANSCRIPTIONAL AND EPIGENETICALLY PROFILES SHARED BY AKI AND CKD BUT ALSO SUBSETS THAT ARE SPECIFIC TO EITHER THE EARLY OR LATE STAGES OF RENAL INJURY; (II) DIFFERENCES IN EXPRESSION OF A SMALL NUMBER OF GENES IS SUFFICIENT TO DISTINGUISH AKI FROM CKD; (III) TRANSCRIPTION PLAYS A KEY ROLE IN THE UPREGULATION OF BOTH AKI AND CKD GENES WHILE POST-TRANSCRIPTIONAL REGULATION APPEARS TO PLAY A MORE SIGNIFICANT ROLE IN DECREASED EXPRESSION OF BOTH AKI AND CKD GENES; AND (IV) SUBSETS OF TRANSCRIPTIONALLY UPREGULATED GENES SHARE EPIGENETIC SIMILARITIES WHILE DOWNREGULATED GENES DO NOT. COLLECTIVELY, OUR STUDY SUGGESTS THAT IDENTIFIED COMMON TRANSCRIPTIONAL AND EPIGENETIC PROFILES OF KIDNEY INJURY LOCI COULD BE EXPLOITED FOR THERAPEUTIC TARGETING IN AKI AND CKD. 2018 11 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 12 2589 23 EPIGENETICS OF PROGRESSION OF CHRONIC KIDNEY DISEASE: FACT OR FANTASY? EPIGENETIC MODIFICATIONS ARE IMPORTANT IN THE NORMAL FUNCTIONING OF THE CELL, FROM REGULATING DYNAMIC EXPRESSION OF ESSENTIAL GENES AND ASSOCIATED PROTEINS TO REPRESSING THOSE THAT ARE UNNEEDED. EPIGENETIC CHANGES ARE ESSENTIAL FOR DEVELOPMENT AND FUNCTIONING OF THE KIDNEY, AND ABERRANT METHYLATION, HISTONE MODIFICATIONS, AND EXPRESSION OF MICRORNA COULD LEAD TO CHRONIC KIDNEY DISEASE (CKD). HERE, EPIGENETIC MODIFICATIONS MODULATE TRANSFORMING GROWTH FACTOR BETA SIGNALING, INFLAMMATION, PROFIBROTIC GENES, AND THE EPITHELIAL-TO-MESENCHYMAL TRANSITION, PROMOTING RENAL FIBROSIS AND PROGRESSION OF CKD. IDENTIFICATION OF THESE EPIGENETIC CHANGES IS IMPORTANT BECAUSE THEY ARE POTENTIALLY REVERSIBLE AND MAY SERVE AS THERAPEUTIC TARGETS IN THE FUTURE TO PREVENT SUBSEQUENT RENAL FIBROSIS AND CKD. IN THIS REVIEW WE DISCUSS THE DIFFERENT TYPES OF EPIGENETIC CONTROL, METHODS TO STUDY EPIGENETIC MODIFICATIONS, AND HOW EPIGENETICS PROMOTES PROGRESSION OF CKD. 2013 13 3826 37 INVESTIGATION OF EPIGENETICS IN KIDNEY CELL BIOLOGY. EPIGENETICS IS THE STUDY OF HERITABLE CHANGES IN DNA OR ITS ASSOCIATED PROTEINS EXCEPT MUTATIONS IN GENE SEQUENCE. EPIGENETIC REGULATION PLAYS FUNDAMENTAL ROLES IN THE PROCESSES OF KIDNEY CELL BIOLOGY THROUGH THE ACTION OF DNA METHYLATION, CHROMATIN MODIFICATIONS VIA EPIGENETIC REGULATORS AND INTERACTION VIA TRANSCRIPTION FACTORS, AND NONCODING RNA SPECIES. KIDNEY DISEASES, INCLUDING ACUTE KIDNEY INJURY, CHRONIC KIDNEY DISEASE, NEPHRITIC AND NEPHROTIC SYNDROMES, PYELONEPHRITIS AND POLYCYSTIC KIDNEY DISEASES ARE DRIVEN BY ABERRANT ACTIVITY IN NUMEROUS SIGNALING PATHWAYS IN EVEN INDIVIDUAL KIDNEY CELL. EPIGENETIC ALTERATIONS, INCLUDING DNA METHYLATION, HISTONE ACETYLATION AND METHYLATION, NONCODING RNAS, AND PROTEIN POSTTRANSLATIONAL MODIFICATIONS, COULD DISRUPT ESSENTIAL PATHWAYS THAT PROTECT THE RENAL CELLS FROM UNCONTROLLED GROWTH, APOPTOSIS AND ESTABLISHMENT OF OTHER RENAL ASSOCIATED SYNDROMES, WHICH HAVE BEEN RECOGNIZED AS ONE OF THE CRITICAL MECHANISMS FOR REGULATING FUNCTIONAL CHANGES THAT DRIVE AND MAINTAIN THE KIDNEY DISEASE PHENOTYPE. IN THIS CHAPTER, WE BRIEFLY SUMMARIZE THE EPIGENETIC MECHANISMS IN KIDNEY CELL BIOLOGY AND EPIGENETIC BASIS OF KIDNEY DEVELOPMENT, AND INTRODUCE EPIGENETIC TECHNIQUES THAT CAN BE USED IN INVESTIGATING THE MOLECULAR MECHANISM OF KIDNEY CELL BIOLOGY AND KIDNEYS DISEASES, PRIMARILY FOCUSING ON THE INTEGRATION OF DNA METHYLATION AND CHROMATIN IMMUNOPRECIPITATION TECHNOLOGIES INTO KIDNEY DISEASE ASSOCIATED STUDIES. FUTURE STUDIES USING THESE EMERGING TECHNOLOGIES WILL ELUCIDATE HOW ALTERATIONS IN THE RENAL CELL EPIGENOME COOPERATE WITH GENETIC ABERRATIONS FOR KIDNEY DISEASE INITIATION AND PROGRESSION. INCORPORATING EPIGENOMIC TESTING INTO THE CLINICAL RESEARCH IS ESSENTIAL TO FUTURE STUDIES WITH EPIGENETICS BIOMARKERS AND PRECISION MEDICINE USING EMERGING EPIGENETIC THERAPIES. 2019 14 6511 30 TRANSCRIPTION FACTORS AS THERAPEUTIC TARGETS IN CHRONIC KIDNEY DISEASE. THE GROWING NUMBER OF PATIENTS WITH CHRONIC KIDNEY DISEASE (CKD) IS RECOGNIZED AS AN EMERGING PROBLEM WORLDWIDE. RECENT STUDIES HAVE INDICATED THAT DEREGULATION OF TRANSCRIPTION FACTORS IS ASSOCIATED WITH THE ONSET OR PROGRESSION OF KIDNEY DISEASE. SEVERAL CLINICAL TRIALS INDICATED THAT REGRESSION OF CKD MAY BE FEASIBLE VIA ACTIVATION OF THE TRANSCRIPTION FACTOR NUCLEAR FACTOR ERYTHROID-2 RELATED FACTOR 2 (NRF2), WHICH SUGGESTS THAT TRANSCRIPTION FACTORS MAY BE POTENTIAL DRUG TARGETS FOR CKD. AGENTS STABILIZING HYPOXIA-INDUCIBLE FACTOR (HIF), WHICH MAY BE BENEFICIAL FOR RENAL ANEMIA AND RENAL PROTECTION, ARE ALSO NOW UNDER CLINICAL TRIAL. RECENTLY, WE HAVE REPORTED THAT THE TRANSCRIPTION FACTOR KRUPPEL-LIKE FACTOR 4 (KLF4) REGULATES THE GLOMERULAR PODOCYTE EPIGENOME, AND THAT THE ANTIPROTEINURIC EFFECT OF THE RENIN(-)ANGIOTENSIN SYSTEM BLOCKADE MAY BE PARTIALLY MEDIATED BY KLF4. KLF4 IS ONE OF THE YAMANAKA FACTORS THAT INDUCES IPS CELLS AND IS REPORTED TO BE INVOLVED IN EPIGENETIC REMODELING. IN THIS ARTICLE, WE SUMMARIZE THE TRANSCRIPTION FACTORS ASSOCIATED WITH CKD AND PARTICULARLY FOCUS ON THE POSSIBILITY OF TRANSCRIPTION FACTORS BEING NOVEL DRUG TARGETS FOR CKD THROUGH EPIGENETIC MODULATION. 2018 15 2542 31 EPIGENETICS IN KIDNEY DISEASES. EPIGENETICS EXAMINES HERITABLE CHANGES IN DNA AND ITS ASSOCIATED PROTEINS EXCEPT MUTATIONS IN GENE SEQUENCE. EPIGENETIC REGULATION PLAYS FUNDAMENTAL ROLES IN KIDNEY CELL BIOLOGY THROUGH THE ACTION OF DNA METHYLATION, CHROMATIN MODIFICATION VIA EPIGENETIC REGULATORS AND NON-CODING RNA SPECIES. KIDNEY DISEASES, INCLUDING ACUTE KIDNEY INJURY, CHRONIC KIDNEY DISEASE, DIABETIC KIDNEY DISEASE AND RENAL FIBROSIS ARE MULTISTEP PROCESSES ASSOCIATED WITH NUMEROUS MOLECULAR ALTERATIONS EVEN IN INDIVIDUAL KIDNEY CELLS. EPIGENETIC ALTERATIONS, INCLUDING ANOMALOUS DNA METHYLATION, ABERRANT HISTONE ALTERATIONS AND CHANGES OF MICRORNA EXPRESSION ALL CONTRIBUTE TO KIDNEY PATHOGENESIS. THESE CHANGES ALTER THE GENOME-WIDE EPIGENETIC SIGNATURES AND DISRUPT ESSENTIAL PATHWAYS THAT PROTECT RENAL CELLS FROM UNCONTROLLED GROWTH, APOPTOSIS AND DEVELOPMENT OF OTHER RENAL ASSOCIATED SYNDROMES. MOLECULAR CHANGES IMPACT CELLULAR FUNCTION WITHIN KIDNEY CELLS AND ITS MICROENVIRONMENT TO DRIVE AND MAINTAIN DISEASE PHENOTYPE. IN THIS CHAPTER, WE BRIEFLY SUMMARIZE EPIGENETIC MECHANISMS IN FOUR KIDNEY DISEASES INCLUDING ACUTE KIDNEY INJURY, CHRONIC KIDNEY DISEASE, DIABETIC KIDNEY DISEASE AND RENAL FIBROSIS. WE PRIMARILY FOCUS ON CURRENT KNOWLEDGE ABOUT THE GENOME-WIDE PROFILING OF DNA METHYLATION AND HISTONE MODIFICATION, AND EPIGENETIC REGULATION ON SPECIFIC GENE(S) IN THE PATHOPHYSIOLOGY OF THESE DISEASES AND THE TRANSLATIONAL POTENTIAL OF IDENTIFYING NEW BIOMARKERS AND TREATMENT FOR PREVENTION AND THERAPY. INCORPORATING EPIGENOMIC TESTING INTO CLINICAL RESEARCH IS ESSENTIAL TO ELUCIDATE NOVEL EPIGENETIC BIOMARKERS AND DEVELOP PRECISION MEDICINE USING EMERGING THERAPIES. 2021 16 476 35 ARSENIC INDUCES FIBROGENIC CHANGES IN HUMAN KIDNEY EPITHELIAL CELLS POTENTIALLY THROUGH EPIGENETIC ALTERATIONS IN DNA METHYLATION. ARSENIC CONTAMINATION IS A SIGNIFICANT PUBLIC HEALTH ISSUE, AND KIDNEY IS ONE OF THE TARGET ORGAN FOR ARSENIC-INDUCED ADVERSE EFFECTS. RENAL FIBROSIS IS A WELL-KNOWN PATHOLOGICAL STAGE FREQUENTLY OBSERVED IN PROGRESSIVE CHRONIC KIDNEY DISEASE (CKD). EPIDEMIOLOGICAL STUDIES IMPLICATE ARSENIC EXPOSURE TO CKD, BUT THE ROLE OF ARSENIC IN KIDNEY FIBROSIS AND THE UNDERLYING MECHANISM IS STILL UNCLEAR. IT IS IN THIS CONTEXT THAT THE CURRENT STUDY EVALUATED THE EFFECTS OF LONG-TERM ARSENIC EXPOSURE ON THE CELLULAR RESPONSE IN MORPHOLOGY, AND MARKER GENES EXPRESSION WITH RESPECT TO FIBROSIS USING HUMAN KIDNEY 2 (HK-2) EPITHELIAL CELLS. RESULTS OF THIS STUDY REVEALED THAT IN ADDITION TO INCREASED GROWTH, HK-2 CELLS UNDERWENT PHENOTYPIC, BIOCHEMICAL AND MOLECULAR CHANGES INDICATIVE OF EPITHELIAL-MESENCHYMAL TRANSITION (EMT) IN RESPONSE TO THE EXPOSURE TO ARSENIC. MOST IMPORTANTLY, THE ARSENIC-EXPOSED CELLS ACQUIRED THE PATHOGENIC FEATURES OF FIBROSIS AS SUPPORTED BY INCREASED EXPRESSION OF MARKERS FOR FIBROSIS, SUCH AS COLLAGEN I, FIBRONECTIN, TRANSFORMING GROWTH FACTOR BETA, AND ALPHA-SMOOTH MUSCLE ACTIN. UPREGULATION OF FIBROSIS ASSOCIATED SIGNALING MOLECULES SUCH AS TISSUE INHIBITOR OF METALLOPROTEINASES-3 AND MATRIX METALLOPROTEINASE-2 AS WELL AS ACTIVATION OF AKT WAS ALSO OBSERVED. ADDITIONALLY, THE EXPRESSION OF EPIGENETIC GENES (DNA METHYLTRANSFERASES 3A AND 3B; METHYL-CPG BINDING DOMAIN 4) WAS INCREASED IN ARSENIC-EXPOSED CELLS. TREATMENT WITH DNA METHYLATION INHIBITOR 5-AZA-2'-DC REVERSED THE EMT PROPERTIES AND RESTORED THE LEVEL OF PHOSPHO-AKT. TOGETHER, THESE DATA FOR THE FIRST TIME SUGGEST THAT LONG-TERM EXPOSURE TO ARSENIC CAN INCREASE THE RISK OF KIDNEY FIBROSIS. ADDITIONALLY, OUR DATA SUGGEST THAT THE ARSENIC-INDUCED FIBROTIC CHANGES ARE, AT LEAST IN PART, MEDIATED BY DNA METHYLATION AND THEREFORE POTENTIALLY CAN BE REVERSED BY EPIGENETIC THERAPEUTICS. 2019 17 1487 25 DNA DAMAGE AND EPIGENETIC CHANGES IN KIDNEY DISEASES - FOCUSED ON TRANSCRIPTION FACTORS IN PODOCYTES. RECENTLY IT HAS BEEN SHOWN THAT EPIGENETIC MECHANISMS ARE INVOLVED IN INITIATION AND PROGRESSION OF CARIDIOVASCULAR AND METABOLIC DISEASES, INCLUDING DIABETES, OBESITY, ATHEROSCLEROSIS, HEART FAILURE, HYPERTENSION AND KIDNEY DISEASES. IN THESE CHRONIC DISEASES, VARIOUS EXOGENOUS AND ENDOGENOUS STRESSES CAUSE DNA DAMAGE, FOLLOWED BY DNA REPAIR PROCESS. ACCUMULATION OF DNA DAMAGES AND IMPAIRED REPAIR PROCESS CAN LEAD TO EPIGENETIC CHANGES, WHICH MAY CONTRIBUTE TO ONSET AND PROGRESSION OF DISEASES. RECENTLY WE HAVE SHOWN THAT THERAPEUTIC EFFECT OF TRANSCRIPTION FACTOR KLF4 (KRUPPEL-LIKE FACTOR 4) IN KIDNEY GLOMERULAR EPITHELIAL CELLS (PODOCYTES) ON PROTEINURIC KIDNEY DISEASES THROUGH EPIGENETIC MECHANISMS. OUR RESULT SUGGESTS THE POSSIBILITY OF TRANSCRIPTION FACTORS AS A TARGET OF SELECTIVE EPIGENETIC THERAPY. MOREOVER, WE HAVE REPORTED THAT RENIN-ANGIOTENSIN SYSTEM (RAS) BLOCKERS, WHICH ARE WIDELY PRESCRIBED FOR THE TREATMENT OF CARDIOVASCULAR DISEASES, CAN RESTORE EPIGENETIC CHANGES THROUGH KLF4 IN PART. THESE RESULTS SUGGEST THAT ACTIVATION OF RAS CAUSES EPIGENETIC CHANGES IN DISEASE STATES, AND ELUCIDATION OF THE PRECISE MECHANISM MAY LEAD TO ESTABLISHMENT OF NOVEL THERAPEUTIC TARGET OF KIDNEY DISEASES. IN THIS REVIEW WE FOCUS ON DNA DAMAGE REPAIR SYSTEM AND EPIGENETIC MODULATORS IN DISEASE STATES, AND SPECULATE A CANDIDATE FOR EPIGENETIC THERAPY OF KIDNEY DISEASES. 2016 18 2286 30 EPIGENETIC REGULATION IN KIDNEY TRANSPLANTATION. KIDNEY TRANSPLANTATION IS A STANDARD CARE FOR END STAGE RENAL DISEASE, BUT IT IS ALSO ASSOCIATED WITH A COMPLEX PATHOGENESIS INCLUDING ISCHEMIA-REPERFUSION INJURY, INFLAMMATION, AND DEVELOPMENT OF FIBROSIS. OVER THE PAST DECADE, ACCUMULATING EVIDENCE HAS SUGGESTED A ROLE OF EPIGENETIC REGULATION IN KIDNEY TRANSPLANTATION, INVOLVING DNA METHYLATION, HISTONE MODIFICATION, AND VARIOUS KINDS OF NON-CODING RNAS. HERE, WE ANALYZE THESE RECENT STUDIES SUPPORTING THE ROLE OF EPIGENETIC REGULATION IN DIFFERENT PATHOLOGICAL PROCESSES OF KIDNEY TRANSPLANTATION, I.E., ISCHEMIA-REPERFUSION INJURY, ACUTE REJECTION, AND CHRONIC GRAFT PATHOLOGIES INCLUDING RENAL INTERSTITIAL FIBROSIS. FURTHER INVESTIGATION OF EPIGENETIC ALTERATIONS, THEIR PATHOLOGICAL ROLES AND UNDERLYING MECHANISMS IN KIDNEY TRANSPLANTATION MAY LEAD TO NEW STRATEGIES FOR THE DISCOVERY OF NOVEL DIAGNOSTIC BIOMARKERS AND THERAPEUTIC INTERVENTIONS. 2022 19 4668 30 NEW INSIGHTS INTO MOLECULAR MECHANISMS OF EPIGENETIC REGULATION IN KIDNEY DISEASE. THE NUMBER OF PATIENTS WITH KIDNEY FAILURE HAS INCREASED IN RECENT YEARS. DIFFERENT FACTORS CONTRIBUTE TO THE PROGRESSION OF CHRONIC KIDNEY DISEASE, INCLUDING GLOMERULAR SCLEROSIS, ATHEROSCLEROSIS OF THE RENAL ARTERIES AND TUBULOINTERSTITIAL FIBROSIS. TUBULOINTERSTITIAL INJURY IS INDUCED BY HYPOXIA AND OTHER INFLAMMATORY SIGNALS, LEADING TO FIBROBLAST ACTIVATION. TECHNOLOGICAL ADVANCES USING HIGH-THROUGHPUT SEQUENCING HAS ENABLED THE DETERMINATION OF THE EXPRESSION PROFILE OF ALMOST ALL GENES, REVEALING THAT GENE EXPRESSION IS INTRICATELY REGULATED BY DNA METHYLATION, HISTONE MODIFICATION, CHANGES IN CHROMOSOME CONFORMATION, LONG NON-CODING RNAS AND MICRORNAS. THESE EPIGENETIC MODIFICATIONS ARE STORED AS CELLULAR EPIGENETIC MEMORY. EPIGENETIC MEMORY LEADS TO ADULT-ONSET DISEASE OR AGEING IN THE LONG TERM AND MAY POSSIBLY PLAY AN IMPORTANT ROLE IN THE KIDNEY DISEASE PROCESS. HEREIN WE EMPHASIZE THE IMPORTANCE OF CLARIFYING THE MOLECULAR MECHANISMS UNDERLYING EPIGENETIC MODIFICATIONS BECAUSE THIS MAY LEAD TO THE DEVELOPMENT OF NEW THERAPEUTIC TARGETS IN KIDNEY DISEASE. 2016 20 834 30 CHEMICAL BIOLOGY OF LYSINE DEMETHYLASES. ABNORMAL LEVELS OF DNA METHYLATION AND/OR HISTONE MODIFICATIONS ARE OBSERVED IN PATIENTS WITH A WIDE VARIETY OF CHRONIC DISEASES. METHYLATION OF LYSINES WITHIN HISTONE TAILS IS A KEY MODIFICATION THAT CONTRIBUTES TO INCREASED GENE EXPRESSION OR REPRESSION DEPENDING ON THE SPECIFIC RESIDUE AND DEGREE OF METHYLATION, WHICH IS IN TURN CONTROLLED BY THE INTERPLAY OF LYSINE METHYL TRANSFERASES AND DEMETHYLASES. DRUGS THAT TARGET THESE AND OTHER ENZYMES CONTROLLING CHROMATIN MODIFICATIONS CAN MODULATE THE EXPRESSION OF CLUSTERS OF GENES, POTENTIALLY OFFERING HIGHER THERAPEUTIC EFFICACY THAN CLASSICAL AGENTS ACTING ON DOWNSTREAM BIOCHEMICAL PATHWAYS THAT ARE SUSCEPTIBLE TO DEGENERACY. LYSINE DEMETHYLASES, FIRST DISCOVERED IN 2004, ARE THE SUBJECT OF INCREASING INTEREST AS THERAPEUTIC TARGETS. THIS REVIEW PROVIDES AN OVERVIEW OF RECENT FINDINGS IMPLICATING LYSINE DEMETHYLASES IN A RANGE OF THERAPEUTIC AREAS INCLUDING ONCOLOGY, IMMUNOINFLAMMATION, METABOLIC DISORDERS, NEUROSCIENCE, VIROLOGY AND REGENERATIVE MEDICINE, TOGETHER WITH A SUMMARY OF RECENT ADVANCES IN STRUCTURAL BIOLOGY AND SMALL MOLECULE INHIBITOR DISCOVERY, SUPPORTING THE TRACTABILITY OF THE PROTEIN FAMILY FOR THE DEVELOPMENT OF SELECTIVE DRUGLIKE INHIBITORS. 2011