1 5363 65 RECENT ADVANCES IN DIABETIC KIDNEY DISEASES: FROM KIDNEY INJURY TO KIDNEY FIBROSIS. DIABETIC KIDNEY DISEASE (DKD) IS THE LEADING CAUSE OF CHRONIC KIDNEY DISEASE AND END-STAGE RENAL DISEASE. THE NATURAL HISTORY OF DKD INCLUDES GLOMERULAR HYPERFILTRATION, PROGRESSIVE ALBUMINURIA, DECLINING ESTIMATED GLOMERULAR FILTRATION RATE, AND, ULTIMATELY, KIDNEY FAILURE. IT IS KNOWN THAT DKD IS ASSOCIATED WITH METABOLIC CHANGES CAUSED BY HYPERGLYCEMIA, RESULTING IN GLOMERULAR HYPERTROPHY, GLOMERULOSCLEROSIS, AND TUBULOINTERSTITIAL INFLAMMATION AND FIBROSIS. HYPERGLYCEMIA IS ALSO KNOWN TO CAUSE PROGRAMMED EPIGENETIC MODIFICATION. HOWEVER, THE DETAILED MECHANISMS INVOLVED IN THE ONSET AND PROGRESSION OF DKD REMAIN ELUSIVE. IN THIS REVIEW, WE DISCUSS RECENT ADVANCES REGARDING THE PATHOGENIC MECHANISMS INVOLVED IN DKD. 2021 2 5420 22 REGULATION OF HYPOXIA-INDUCIBLE FACTOR IN KIDNEY DISEASE. HYPOXIA PLAYS A CRUCIAL ROLE IN THE PATHOPHYSIOLOGY OF ACUTE KIDNEY INJURY (AKI) AND PRESUMABLY ALSO CHRONIC KIDNEY DISEASE (CKD). HYPOXIA-INDUCIBLE FACTOR (HIF) IS THE MASTER TRANSCRIPTION FACTOR THAT REGULATES ADAPTIVE RESPONSES AGAINST HYPOXIA. UNDER HYPOXIC CONDITIONS, HIF ACTIVATES TARGET GENES WITH HYPOXIA-RESPONSIVE ELEMENTS IN THEIR REGULATORY REGIONS. THE HIF ISOFORMS AND REGULATORS OF HIF (I.E. PROLYL HYDROXYLASES) SHOW CELL TYPE-SPECIFIC DISTRIBUTIONS. HYPOXIA IS OBSERVED IN BOTH ISCHAEMIC AND SO-CALLED NON-ISCHAEMIC FORMS OF AKI. IN ADDITION TO THE ACUTE PHASE, HYPOXIA MAY ENSUE DURING THE RECOVERY PHASE OF AKI, POSSIBLY DUE TO THE OXYGEN-CONSUMING PROCESSES OF CELL GROWTH AND PROLIFERATION FOR REPAIR. ALTHOUGH HIF PROTECTS THE KIDNEY AGAINST AKI, INTRINSIC HIF ACTIVATION IS SUBMAXIMAL IN AKI AND FURTHER AUGMENTATION OF HIF AMELIORATES DISEASE MANIFESTATIONS. THE KIDNEY IN CKD ALSO SUFFERS FROM HYPOXIA CAUSED BY MULTIPLE MECHANISMS, INCLUDING SUSTAINED OXYGEN DEMANDS IN THE REMAINING NEPHRONS DUE TO MALADAPTIVE TUBULOGLOMERULAR FEEDBACK. WHETHER HIF IS CHRONICALLY UPREGULATED IN CKD IS CONTENTIOUS. HYPOXIA-INDUCIBLE FACTOR ACTIVATION IS A PROMISING THERAPEUTIC APPROACH TO CKD, BUT EXCESSIVE ACTIVATION OF HIF MAY BE DELETERIOUS. IT IS LIKELY THAT THERE IS A THERAPEUTIC WINDOW OF HIF ACTIVATION IN CHRONIC CONDITIONS. UNDER CERTAIN CIRCUMSTANCES, ANIMALS WITH CKD ARE PROTECTED AGAINST AKI AND THIS MAY BE EXPLAINED BY NON-PHYSIOLOGICAL HYPOXIA OF THE KIDNEY AND SUBSEQUENT HIF EXPRESSION. IN ADDITION, AN ACUTE HYPOXIC INSULT MAY INDUCE LONG-LASTING CHANGES, POSSIBLY INCLUDING EPIGENETIC MODIFICATIONS INDUCED BY HIF. THESE OBSERVATIONS SUGGEST A COMPLEX INTERACTION BETWEEN AKI AND CKD VIA HYPOXIA AND HIF ACTIVATION. 2013 3 4016 25 LOW-DOSE HYDRALAZINE PREVENTS FIBROSIS IN A MURINE MODEL OF ACUTE KIDNEY INJURY-TO-CHRONIC KIDNEY DISEASE PROGRESSION. ACUTE KIDNEY INJURY (AKI) AND PROGRESSIVE CHRONIC KIDNEY DISEASE (CKD) ARE INTRINSICALLY TIED SYNDROMES. IN THIS REGARD, THE ACUTELY INJURED KIDNEY OFTEN DOES NOT ACHIEVE ITS FULL REGENERATIVE CAPACITY AND AKI DIRECTLY TRANSITIONS INTO PROGRESSIVE CKD ASSOCIATED WITH TUBULOINTERSTITIAL FIBROSIS. UNDERLYING MECHANISMS OF SUCH AKI-TO-CKD PROGRESSION ARE STILL INCOMPLETELY UNDERSTOOD AND SPECIFIC THERAPEUTIC INTERVENTIONS ARE STILL ELUSIVE. BECAUSE EPIGENETIC MODIFICATIONS PLAY A ROLE IN MAINTAINING TISSUE FIBROSIS, WE USED A MURINE MODEL OF ISCHEMIA-REPERFUSION INJURY TO DETERMINE WHETHER ABERRANT PROMOTER METHYLATION OF RASAL1 CONTRIBUTES CAUSALLY TO THE SWITCH BETWEEN PHYSIOLOGICAL REGENERATION AND TUBULOINTERSTITIAL FIBROGENESIS, A HALLMARK OF AKI-TO-CKD PROGRESSION. IT IS KNOWN THAT THE ANTIHYPERTENSIVE DRUG HYDRALAZINE HAS DEMETHYLATING ACTIVITY, AND THAT ITS OPTIMUM DEMETHYLATING ACTIVITY OCCURS AT CONCENTRATIONS BELOW BLOOD PRESSURE-LOWERING DOSES. ADMINISTRATION OF LOW-DOSE HYDRALAZINE EFFECTIVELY INDUCED EXPRESSION OF HYDROXYLASE TET3, WHICH CATALYZED RASAL1 HYDROXYMETHYLATION AND SUBSEQUENT RASAL1 PROMOTER DEMETHYLATION. HYDRALAZINE-INDUCED CPG PROMOTER DEMETHYLATION SUBSEQUENTLY ATTENUATED RENAL FIBROSIS AND PRESERVED EXCRETORY RENAL FUNCTION INDEPENDENT OF ITS BLOOD PRESSURE-LOWERING EFFECTS. IN COMPARISON, RASAL1 DEMETHYLATION AND INHIBITION OF TUBULOINTERSTITIAL FIBROSIS WAS NOT DETECTED UPON ADMINISTRATION OF THE ANGIOTENSIN-CONVERTING ENZYME INHIBITOR RAMIPRIL IN THIS MODEL. THUS, RASAL1 PROMOTER METHYLATION AND SUBSEQUENT TRANSCRIPTIONAL RASAL1 SUPPRESSION PLAYS A CAUSAL ROLE IN AKI-TO-CKD PROGRESSION. 2017 4 3466 25 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 5 3048 22 GENOME-WIDE ANALYSIS REVEALED THAT DZNEP REDUCES TUBULOINTERSTITIAL FIBROSIS VIA DOWN-REGULATION OF PRO-FIBROTIC GENES. TUBULOINTERSTITIAL FIBROSIS HAS BEEN RECENTLY REPORTED TO BE CAUSED BY THE COLLAPSE OF THE EPIGENETIC REGULATION OF KIDNEY DISEASES. WE EXAMINED WHETHER PHARMACOLOGICAL INHIBITION OF HISTONE MODIFICATION IS EFFECTIVE AGAINST RENAL FIBROSIS. DZNEP (3-DEAZANEPLANOCIN A) WAS ORIGINALLY DEVELOPED AS AN ANTI-CANCER DRUG TO INHIBIT THE REPRESSIVE HISTONE MARK, H3K27ME3. WE USED A MODEL OF CHRONIC TUBULOINTERSTITIAL FIBROSIS INDUCED BY UNILATERAL ISCHAEMIA/REPERFUSION AND ADMINISTERED DZNEP INTRAVENOUSLY TO THE MICE FOR 8 WEEKS. WE FOUND DZNEP CONTRIBUTES TO THE REDUCTION OF TUBULOINTERSTITIAL FIBROSIS. WE SELECTED ONLY TUBULAR CELLS FROM IN VIVO SAMPLES USING LASER-CAPTURE MICRODISSECTION BECAUSE EPIGENETIC REGULATION IS SPECIFIC TO THE CELL TYPES, AND WE FOCUSED ON THE CHANGES IN THE TUBULAR CELLS. WE PERFORMED A GENOME-WIDE ANALYSIS OF TUBULAR CELLS USING HIGH-THROUGHPUT SEQUENCING (RNA-SEQ) TO IDENTIFY NOVEL EPIGENETIC FACTORS ASSOCIATED WITH RENAL FIBROSIS. WE FOUND THAT PRO-FIBROTIC GENES SUCH AS COL3A1 (COLLAGEN TYPE 3A1) AND TIMP2 (TISSUE INHIBITOR OF METALLOPROTEINASE 2) WERE SUPPRESSED BY DZNEP IN VIVO. IN ADDITION, PRO-FIBROTIC GENES SUCH AS COL4A1 (COLLAGEN TYPE 4A1), TIMP2 AND MMP14 WERE DOWN-REGULATED BY DZNEP IN VITRO. IN CONCLUSION, WE FOUND THAT PHARMACOLOGICAL EPIGENETIC MODIFICATION BY DZNEP DECREASED THE EXPRESSION LEVELS OF FIBROGENIC GENES IN TUBULAR CELLS AND INHIBITED TUBULOINTERSTITIAL FIBROSIS. 2018 6 6575 29 TREATMENT OF DIABETIC KIDNEY DISEASE: CURRENT AND FUTURE. DIABETIC KIDNEY DISEASE (DKD) IS THE MAJOR CAUSE OF END-STAGE KIDNEY DISEASE. HOWEVER, ONLY RENIN-ANGIOTENSIN SYSTEM INHIBITOR WITH MULTIDISCIPLINARY TREATMENTS IS EFFECTIVE FOR DKD. IN 2019, SODIUM-GLUCOSE COTRANSPORTER 2 (SGLT2) INHIBITOR SHOWED EFFICACY AGAINST DKD IN CANAGLIFLOZIN AND RENAL EVENTS IN DIABETES WITH ESTABLISHED NEPHROPATHY CLINICAL EVALUATION (CREDENCE) TRIAL, ADDING A NEW TREATMENT OPTION. HOWEVER, THE PROGRESSION OF DKD HAS NOT BEEN COMPLETELY CONTROLLED. THE PATIENTS WITH TRANSIENT EXPOSURE TO HYPERGLYCEMIA DEVELOP DIABETIC COMPLICATIONS, INCLUDING DKD, EVEN AFTER NORMALIZATION OF THEIR BLOOD GLUCOSE. TEMPORARY HYPERGLYCEMIA CAUSES ADVANCED GLYCATION END PRODUCT (AGE) ACCUMULATIONS AND EPIGENETIC CHANGES AS METABOLIC MEMORY. THE DRUGS THAT IMPROVE METABOLIC MEMORY ARE AWAITED, AND AGE INHIBITORS AND HISTONE MODIFICATION INHIBITORS ARE THE FOCUS OF CLINICAL AND BASIC RESEARCH. IN ADDITION, INCRETIN-RELATED DRUGS SHOWED A RENOPROTECTIVE ABILITY IN MANY CLINICAL TRIALS, AND THESE TRIALS WITH RENAL OUTCOME AS THEIR PRIMARY ENDPOINT ARE CURRENTLY ONGOING. HYPOXIA-INDUCIBLE FACTOR PROLYL HYDROXYLASE INHIBITORS RECENTLY APPROVED FOR RENAL ANEMIA MAY BE RENOPROTECTIVE SINCE THEY IMPROVE TUBULOINTERSTITIAL HYPOXIA. FURTHERMORE, NF-E2-RELATED FACTOR 2 ACTIVATORS IMPROVED THE GLOMERULAR FILTRATION RATE OF DKD PATIENTS IN BARDOXOLONE METHYL TREATMENT: RENAL FUNCTION IN CHRONIC KIDNEY DISEASE/TYPE 2 DIABETES (BEAM) TRIAL AND PHASE II STUDY OF BARDOXOLONE METHYL IN PATIENTS WITH CHRONIC KIDNEY DISEASE AND TYPE 2 DIABETES (TSUBAKI) TRIAL. THUS, FOLLOWING SGLT2 INHIBITOR, NUMEROUS NOVEL DRUGS COULD BE UTILIZED IN TREATING DKD. FUTURE STUDIES ARE EXPECTED TO PROVIDE NEW INSIGHTS. 2021 7 2034 23 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 8 5370 22 RECENT ADVANCES IN UNDERSTANDING OF CHRONIC KIDNEY DISEASE. CHRONIC KIDNEY DISEASE (CKD) IS DEFINED AS ANY CONDITION THAT CAUSES REDUCED KIDNEY FUNCTION OVER A PERIOD OF TIME. FIBROSIS, TUBULAR ATROPHY AND INTERSTITIAL INFLAMMATION ARE THE HALLMARK OF PATHOLOGICAL FEATURES IN CKD. REGARDLESS OF INITIAL INSULT, CKD HAS SOME COMMON PATHWAYS LEADING CKD TO END-STAGE KIDNEY DISEASE, INCLUDING HYPOXIA IN THE TUBULOINTERSTITIUM AND PROTEINURIA. RECENT ADVANCES IN GENOME EDITING TECHNOLOGIES AND STEM CELL RESEARCH GIVE GREAT INSIGHTS TO UNDERSTAND THE PATHOGENESIS OF CKD, INCLUDING IDENTIFICATIONS OF THE ORIGINS OF RENAL MYOFIBROBLASTS AND TUBULAR EPITHELIAL CELLS UPON INJURY. ENVIRONMENTAL FACTORS SUCH AS HYPOXIA, OXIDATIVE STRESS, AND EPIGENETIC FACTORS IN RELATION TO CKD ARE ALSO DISCUSSED. 2015 9 4755 25 NOVEL THERAPEUTIC STRATEGY WITH HYPOXIA-INDUCIBLE FACTORS VIA REVERSIBLE EPIGENETIC REGULATION MECHANISMS IN PROGRESSIVE TUBULOINTERSTITIAL FIBROSIS. HYPOXIA-INDUCIBLE FACTOR (HIF) IS A TRANSCRIPTIONAL MASTER REGULATOR THAT TAKES CONTROL OF THE GENE EXPRESSIONS UNDER HYPOXIA. SEVERAL LINES OF EVIDENCE HAVE SHOWN THAT CHRONIC HYPOXIA IN TUBULOINTERSTITIUM RESULTS IN IRREVERSIBLE RENAL DISEASE. RECENTLY, HIF1 WAS REPORTED TO ORGANIZE A CLUSTER OF HISTONE-MODIFYING ENZYMES BY BINDING TO THEIR PROMOTER REGIONS IN VARIOUS KINDS OF CELL LINES. HOWEVER, ITS FUNCTION IN RENAL DISEASE REMAINS LARGELY UNKNOWN. WE FOCUSED ON THE EPIGENETIC REGULATION ON THE PROGRESSION OF CHRONIC KIDNEY DISEASE AND HAVE REVIEWED THE LATEST KNOWLEDGE IN THIS AREA WITH SPECIAL EMPHASIS ON THE INVOLVEMENT OF HIF. FOR EXAMPLE, A SET OF HIF1 DOWNSTREAM TARGET GENES ALSO WERE REPORTED TO BE REGULATED BY COOPERATIVE COMBINATION OF HIF1 AND HISTONE DEMETHYLASE. WE SUGGEST A NOVEL EPIGENETIC PATHWAY THAT AFFECTS THE FINAL COMMON PATHWAY TO END-STAGE RENAL DISEASE IN ADDITION TO THE TUBULOINTERSTITIAL HYPOXIA. WE EMPHASIZE THE IMPORTANCE OF FIGURING OUT THE EPIGENETIC MECHANISMS OF RENAL FAILURE TO FIND THE NOVEL THERAPEUTIC APPROACH OF CHRONIC KIDNEY DISEASE. 2013 10 4513 17 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 11 5565 25 ROLE OF HYPOXIA IN PROGRESSIVE CHRONIC KIDNEY DISEASE AND IMPLICATIONS FOR THERAPY. PURPOSE OF REVIEW: CHRONIC HYPOXIA IN THE TUBULOINTERSTITIUM HAS BEEN RECOGNIZED AS A FINAL COMMON PATHWAY THAT LEADS TO THE DEVELOPMENT OF END-STAGE RENAL DISEASE. HYPOXIA-INDUCIBLE FACTOR (HIF), A MASTER REGULATOR OF THE ADAPTIVE RESPONSE AGAINST HYPOXIA, IS INVOLVED IN THE PATHOGENESIS OF CHRONIC KIDNEY DISEASE (CKD). THIS REVIEW FOCUSES ON HIF AND NOVEL THERAPEUTIC STRATEGIES TARGETING HIF. RECENT FINDINGS: ALTHOUGH HIF UPREGULATION IS BENEFICIAL AGAINST HYPOXIC KIDNEY INJURY, IT MAY BE HARMFUL UNDER CERTAIN PATHOLOGICAL CONDITIONS. RECENT ADVANCES IN EPIGENETIC CHANGES PROVIDE AN ADDITIONAL LAYER OF COMPLEXITY TO OUR UNDERSTANDING OF GENE REGULATION IN RESPONSE TO HYPOXIA, WHICH IS MOST LIKELY INVOLVED IN THE PROGRESSION OF CKD. ON THE BASIS OF THIS NOVEL KNOWLEDGE, THE PHARMACOLOGICAL ACTIVATION AND MODULATION OF HIF IS EMERGING AS A NOVEL THERAPEUTIC TARGET. SUMMARY: HIF PLAYS A CRUCIAL ROLE IN THE PATHOPHYSIOLOGY OF CKD. THE UNDERLYING MOLECULAR MECHANISMS, INCLUDING EPIGENETICS, HAVE BEEN THOROUGHLY INVESTIGATED. ON THE BASIS OF THE EXPERIMENTAL DATA AVAILABLE TO DATE, THE PHARMACOLOGICAL ACTIVATION OF HIF IS LIKELY A NOVEL PROMISING THERAPY FOR CKD. 2014 12 3467 21 HYPOXIA, HIF, AND ASSOCIATED SIGNALING NETWORKS IN CHRONIC KIDNEY DISEASE. THE PATHOGENESIS OF CHRONIC KIDNEY DISEASE (CKD) IS COMPLEX AND APPARENTLY MULTIFACTORIAL. HYPOXIA OR DECREASE IN OXYGEN SUPPLY IN KIDNEY TISSUES HAS BEEN IMPLICATED IN CKD. HYPOXIA INDUCIBLE FACTORS (HIF) ARE A SMALL FAMILY OF TRANSCRIPTION FACTORS THAT ARE MAINLY RESPONSIVE TO HYPOXIA AND MEDIATE HYPOXIC RESPONSE. HIF PLAYS A CRITICAL ROLE IN RENAL FIBROSIS DURING CKD THROUGH THE MODULATION OF GENE TRANSCRIPTION, CROSSTALK WITH MULTIPLE SIGNALING PATHWAYS, EPITHELIAL-MESENCHYMAL TRANSITION, AND EPIGENETIC REGULATION. MOREOVER, HIF ALSO CONTRIBUTES TO THE DEVELOPMENT OF VARIOUS PATHOLOGICAL CONDITIONS ASSOCIATED WITH CKD, SUCH AS ANEMIA, INFLAMMATION, ABERRANT ANGIOGENESIS, AND VASCULAR CALCIFICATION. TREATMENTS TARGETING HIF AND RELATED SIGNALING PATHWAYS FOR CKD THERAPY ARE BEING DEVELOPED WITH PROMISING CLINICAL BENEFITS, ESPECIALLY FOR ANEMIA. THIS REVIEW PRESENTS AN UPDATED ANALYSIS OF HYPOXIA RESPONSE, HIF, AND THEIR ASSOCIATED SIGNALING NETWORK INVOLVED IN THE PATHOGENESIS OF CKD. 2017 13 5826 23 STRESS SIGNAL NETWORK BETWEEN HYPOXIA AND ER STRESS IN CHRONIC KIDNEY DISEASE. CHRONIC KIDNEY DISEASE (CKD) IS CHARACTERIZED BY AN IRREVERSIBLE DECREASE IN KIDNEY FUNCTION AND INDUCTION OF VARIOUS METABOLIC DYSFUNCTIONS. ACCUMULATED FINDINGS REVEAL THAT CHRONIC HYPOXIC STRESS AND ENDOPLASMIC RETICULUM (ER) STRESS ARE INVOLVED IN A RANGE OF PATHOGENIC CONDITIONS, INCLUDING THE PROGRESSION OF CKD. BECAUSE OF THE PRESENCE OF AN ARTERIOVENOUS OXYGEN SHUNT, THE KIDNEY IS THOUGHT TO BE SUSCEPTIBLE TO HYPOXIA. CHRONIC KIDNEY HYPOXIA IS INDUCED BY A NUMBER OF PATHOGENIC CONDITIONS, INCLUDING RENAL ISCHEMIA, REDUCED PERITUBULAR CAPILLARY, AND TUBULOINTERSTITIAL FIBROSIS. THE ER IS AN ORGANELLE WHICH HELPS MAINTAIN THE QUALITY OF PROTEINS THROUGH THE UNFOLDED PROTEIN RESPONSE (UPR) PATHWAY, AND ER DYSFUNCTION ASSOCIATED WITH MALADAPTIVE UPR ACTIVATION IS NAMED ER STRESS. ER STRESS IS REPORTED TO BE RELATED TO SOME OF THE EFFECTS OF PATHOGENESIS IN KIDNEY, PARTICULARLY IN THE PODOCYTE SLIT DIAPHRAGM AND TUBULOINTERSTITIUM. FURTHERMORE, CHRONIC HYPOXIA MEDIATES ER STRESS IN BLOOD VESSEL ENDOTHELIAL CELLS AND TUBULOINTERSTITIUM VIA SEVERAL MECHANISMS, INCLUDING OXIDATIVE STRESS, EPIGENETIC ALTERATION, LIPID METABOLISM, AND THE AKT PATHWAY. IN SUMMARY, A GROWING CONSENSUS CONSIDERS THAT THESE STRESSES INTERACT VIA COMPLICATED STRESS SIGNAL NETWORKS, WHICH LEADS TO THE EXACERBATION OF CKD (FIGURE 1). THIS STRESS SIGNAL NETWORK MIGHT BE A TARGET FOR INTERVENTIONS AIMED AT AMELIORATING CKD. 2017 14 3885 31 KIDNEY FIBROSIS: FROM MECHANISMS TO THERAPEUTIC MEDICINES. CHRONIC KIDNEY DISEASE (CKD) IS ESTIMATED TO AFFECT 10-14% OF GLOBAL POPULATION. KIDNEY FIBROSIS, CHARACTERIZED BY EXCESSIVE EXTRACELLULAR MATRIX DEPOSITION LEADING TO SCARRING, IS A HALLMARK MANIFESTATION IN DIFFERENT PROGRESSIVE CKD; HOWEVER, AT PRESENT NO ANTIFIBROTIC THERAPIES AGAINST CKD EXIST. KIDNEY FIBROSIS IS IDENTIFIED BY TUBULE ATROPHY, INTERSTITIAL CHRONIC INFLAMMATION AND FIBROGENESIS, GLOMERULOSCLEROSIS, AND VASCULAR RAREFACTION. FIBROTIC NICHE, WHERE ORGAN FIBROSIS INITIATES, IS A COMPLEX INTERPLAY BETWEEN INJURED PARENCHYMA (LIKE TUBULAR CELLS) AND MULTIPLE NON-PARENCHYMAL CELL LINEAGES (IMMUNE AND MESENCHYMAL CELLS) LOCATED SPATIALLY WITHIN SCARRING AREAS. ALTHOUGH THE MECHANISMS OF KIDNEY FIBROSIS ARE COMPLICATED DUE TO THE KINDS OF CELLS INVOLVED, WITH THE HELP OF SINGLE-CELL TECHNOLOGY, MANY KEY QUESTIONS HAVE BEEN EXPLORED, SUCH AS WHAT KIND OF RENAL TUBULES ARE PROFIBROTIC, WHERE MYOFIBROBLASTS ORIGINATE, WHICH IMMUNE CELLS ARE INVOLVED, AND HOW CELLS COMMUNICATE WITH EACH OTHER. IN ADDITION, GENETICS AND EPIGENETICS ARE DEEPER MECHANISMS THAT REGULATE KIDNEY FIBROSIS. AND THE REVERSIBLE NATURE OF EPIGENETIC CHANGES INCLUDING DNA METHYLATION, RNA INTERFERENCE, AND CHROMATIN REMODELING, GIVES AN OPPORTUNITY TO STOP OR REVERSE KIDNEY FIBROSIS BY THERAPEUTIC STRATEGIES. MORE MARKETED (E.G., RAS BLOCKAGE, SGLT2 INHIBITORS) HAVE BEEN DEVELOPED TO DELAY CKD PROGRESSION IN RECENT YEARS. FURTHERMORE, A BETTER UNDERSTANDING OF RENAL FIBROSIS IS ALSO FAVORED TO DISCOVER BIOMARKERS OF FIBROTIC INJURY. IN THE REVIEW, WE UPDATE RECENT ADVANCES IN THE MECHANISM OF RENAL FIBROSIS AND SUMMARIZE NOVEL BIOMARKERS AND ANTIFIBROTIC TREATMENT FOR CKD. 2023 15 4381 29 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 16 6647 24 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 17 6051 20 THE CONTRIBUTION OF HISTONE CROTONYLATION TO TISSUE HEALTH AND DISEASE: FOCUS ON KIDNEY HEALTH. ACUTE KIDNEY INJURY (AKI) AND CHRONIC KIDNEY DISEASE (CKD) ARE THE MOST SEVERE CONSEQUENCES OF KIDNEY INJURY. THEY ARE INTERCONNECTED SYNDROMES AS CKD PREDISPOSES TO AKI AND AKI MAY ACCELERATE CKD PROGRESSION. DESPITE THEIR GROWING IMPACT ON THE GLOBAL BURDEN OF DISEASE, THERE IS NO SATISFACTORY TREATMENT FOR AKI AND CURRENT THERAPEUTIC APPROACHES TO CKD REMAIN SUBOPTIMAL. RECENT RESEARCH HAS FOCUSED ON THE THERAPEUTIC TARGET POTENTIAL OF EPIGENETIC REGULATION OF GENE EXPRESSION, INCLUDING NON-CODING RNAS AND THE COVALENT MODIFICATIONS OF HISTONES AND DNA. INDEED, SEVERAL DRUGS TARGETING HISTONE MODIFICATIONS ARE IN CLINICAL USE OR UNDERGOING CLINICAL TRIALS. ACYL-LYSINE HISTONE MODIFICATIONS (E.G. METHYLATION, ACETYLATION, AND CROTONYLATION) HAVE MODULATED EXPERIMENTAL KIDNEY INJURY. MOST RECENTLY, INCREASED HISTONE LYSINE CROTONYLATION (KCR) WAS OBSERVED DURING EXPERIMENTAL AKI AND COULD BE REPRODUCED IN CULTURED TUBULAR CELLS EXPOSED TO INFLAMMATORY STRESS TRIGGERED BY THE CYTOKINE TWEAK. THE DEGREE OF KIDNEY HISTONE CROTONYLATION WAS MODULATED BY CROTONATE AVAILABILITY AND CROTONATE SUPPLEMENTATION PROTECTED FROM NEPHROTOXIC AKI. WE NOW REVIEW THE FUNCTIONAL RELEVANCE OF HISTONE CROTONYLATION IN KIDNEY DISEASE AND OTHER PATHOPHYSIOLOGICAL CONTEXTS, AS WELL AS THE IMPLICATIONS FOR THE DEVELOPMENT OF NOVEL THERAPEUTIC APPROACHES. THESE STUDIES PROVIDE INSIGHTS INTO THE OVERALL ROLE OF HISTONE CROTONYLATION IN HEALTH AND DISEASE. 2020 18 4137 22 MECHANISMS OF METABOLIC MEMORY AND RENAL HYPOXIA AS A THERAPEUTIC TARGET IN DIABETIC KIDNEY DISEASE. DIABETIC KIDNEY DISEASE (DKD) IS A WORLDWIDE PUBLIC HEALTH PROBLEM. THE DEFINITION OF DKD IS UNDER DISCUSSION. ALTHOUGH THE TERM DKD WAS ORIGINALLY DEFINED AS 'KIDNEY DISEASE SPECIFIC TO DIABETES,' DKD FREQUENTLY MEANS CHRONIC KIDNEY DISEASE WITH DIABETES MELLITUS AND INCLUDES NOT ONLY CLASSICAL DIABETIC NEPHROPATHY, BUT ALSO KIDNEY DYSFUNCTION AS A RESULT OF NEPHROSCLEROSIS AND OTHER CAUSES. METABOLIC MEMORY PLAYS A CRUCIAL ROLE IN THE PROGRESSION OF VARIOUS COMPLICATIONS OF DIABETES, INCLUDING DKD. THE MECHANISMS OF METABOLIC MEMORY IN DKD ARE SUPPOSED TO INCLUDE ADVANCED GLYCATION END-PRODUCTS, DEOXYRIBONUCLEIC ACID METHYLATION, HISTONE MODIFICATIONS AND NON-CODING RIBONUCLEIC ACID INCLUDING MICRO RIBONUCLEIC ACID. REGARDLESS OF THE PRESENCE OF DIABETES MELLITUS, THE FINAL COMMON PATHWAY IN CHRONIC KIDNEY DISEASE IS CHRONIC KIDNEY HYPOXIA, WHICH INFLUENCES EPIGENETIC PROCESSES, INCLUDING DEOXYRIBONUCLEIC ACID METHYLATION, HISTONE MODIFICATION, AND CONFORMATIONAL CHANGES IN MICRO RIBONUCLEIC ACID AND CHROMATIN. THEREFORE, HYPOXIA AND OXIDATIVE STRESS ARE APPROPRIATE TARGETS OF THERAPIES AGAINST DKD. PROLYL HYDROXYLASE DOMAIN INHIBITOR ENHANCES THE DEFENSIVE MECHANISMS AGAINST HYPOXIA. BARDOXOLONE METHYL PROTECTS AGAINST OXIDATIVE STRESS, AND CAN EVEN REVERSE IMPAIRED RENAL FUNCTION; A PHASE 2 TRIAL WITH CONSIDERABLE ATTENTION TO HEART COMPLICATIONS IS CURRENTLY ONGOING IN JAPAN. 2017 19 221 23 ACUTE KIDNEY INJURY TO CHRONIC KIDNEY DISEASE TRANSITION. BACKGROUND: ACUTE KIDNEY INJURY (AKI), EVEN IF FOLLOWED BY RENAL RECOVERY, IS A RISK FACTOR FOR THE FUTURE DEVELOPMENT OF CHRONIC KIDNEY DISEASE (CKD) AND END-STAGE RENAL DISEASE (ESRD). IN THE PREVIOUS YEARS, NOVEL INSIGHTS IN THE PATHOPHYSIOLOGY OF CKD PROGRESSION SUGGESTED A CAUSAL LINK BETWEEN AKI AND CKD DUE TO A MALADAPTIVE REPAIR AFTER SEVERE AND REPEATED INJURY. SUMMARY: SEVERAL PATHOLOGICAL MECHANISMS HAVE BEEN PROPOSED TO CONTRIBUTE TO THE PROGRESSION OF AKI AND TRANSITION TO CKD/ESRD INCLUDING HYPOXIA AND MICROVASCULAR RAREFACTION, ALTERATIONS OF RENAL RESIDENT CELL PHENOTYPES AND FUNCTIONS, CELL CYCLE ARREST IN THE G2/M PHASE, PERSISTENT CHRONIC INFLAMMATION, AND DEVELOPMENT OF INTERSTITIAL FIBROSIS, MITOCHONDRIAL FRAGMENTATION, EPIGENETIC CHANGES, ACTIVATION OF RENIN-ANGIOTENSIN SYSTEM (RAS), CELL AND TISSUE SENESCENCE. FURTHERMORE, SEVERAL CLINICAL FACTORS HAVE BEEN IDENTIFIED SUCH AS SEVERITY OF AKI, AGE, AND COMORBIDITIES. THE IDENTIFICATION OF AKI-TO-CKD BIOMARKERS COULD IMPROVE THE EARLY IDENTIFICATION OF AKI PATIENTS WITH HIGHER RISK FOR CKD PROGRESSION. HOWEVER, ALTHOUGH OUR UNDERSTANDING IN THE PATHOPHYSIOLOGY OF AKI-TO-CKD TRANSITION IS SIGNIFICANTLY IMPROVED, NO NOVEL INTERVENTION HAS BEEN VALIDATED. POTENTIAL THERAPEUTIC APPROACHES TO TREAT AKI AND BLOCK THE TRANSITION TO CKD/ESRD HAVE BEEN RECENTLY REPORTED, BUT THEY NEED FURTHER VALIDATIONS. KEY MESSAGES: MALADAPTIVE REPAIR AFTER AKI IS STRONGLY ASSOCIATED TO THE DEVELOPMENT OF CKD AND LONG-TERM CONSEQUENCES. THE PROMPT IDENTIFICATION OF PATIENTS AT HIGHER RISK FOR LATE CKD PROGRESSION AND THE DEVELOPMENT OF NEW THERAPEUTIC INTERVENTIONS REMAIN CRITICAL RESEARCH GOALS. 2018 20 5988 26 TGF-BETA/SMAD AND RENAL FIBROSIS. RENAL FIBROSIS IS CHARACTERIZED BY EXCESSIVE DEPOSITION OF EXTRACELLULAR MATRIX (ECM) THAT DISRUPTS AND REPLACES FUNCTIONAL PARENCHYMA, WHICH LEADS TO ORGAN FAILURE. IT IS KNOWN AS THE MAJOR PATHOLOGICAL MECHANISM OF CHRONIC KIDNEY DISEASE (CKD). ALTHOUGH CKD HAS AN IMPACT ON NO LESS THAN 10% OF THE WORLD POPULATION, THERAPEUTIC OPTIONS ARE STILL LIMITED. REGARDLESS OF ETIOLOGY, ELEVATED TGF-BETA LEVELS ARE HIGHLY CORRELATED WITH THE ACTIVATED PRO-FIBROTIC PATHWAYS AND DISEASE PROGRESSION. TGF-BETA, THE KEY DRIVER OF RENAL FIBROSIS, IS INVOLVED IN A DYNAMIC PATHOPHYSIOLOGICAL PROCESS THAT LEADS TO CKD AND END-STAGE RENAL DISEASE (ESRD). IT IS BECOMING CLEAR THAT EPIGENETICS REGULATES RENAL PROGRAMMING, AND THEREFORE, THE DEVELOPMENT AND PROGRESSION OF RENAL DISEASE. INDEED, RECENT EVIDENCE SHOWS TGF-BETA1/SMAD SIGNALING REGULATES RENAL FIBROSIS VIA EPIGENETIC-CORRELATED MECHANISMS. THIS REVIEW FOCUSES ON THE FUNCTION OF TGF-BETA/SMADS IN RENAL FIBROGENESIS, AND THE ROLE OF EPIGENETICS AS A REGULATOR OF PRO-FIBROTIC GENE EXPRESSION. 2019