1 2788 130 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 2 3757 40 INTEGRATED MECHANISMS OF CAMKII-DEPENDENT VENTRICULAR REMODELING. CAMKII HAS BEEN SHOWN TO BE ACTIVATED DURING DIFFERENT CARDIAC PATHOLOGICAL PROCESSES, AND CAMKII-DEPENDENT MECHANISMS CONTRIBUTE TO PATHOLOGICAL CARDIAC REMODELING, CARDIAC ARRHYTHMIAS, AND CONTRACTILE DYSFUNCTION DURING HEART FAILURE. ACTIVATION OF CAMKII DURING CARDIAC STRESS RESULTS IN A BROAD NUMBER OF BIOLOGICAL EFFECTS SUCH AS, ON THE ONE HAND, ACUTE EFFECTS DUE TO PHOSPHORYLATION OF DISTINCT CELLULAR PROTEINS AS ION CHANNELS AND CALCIUM HANDLING PROTEINS AND, ON THE OTHER HAND, INTEGRATIVE MECHANISMS BY CHANGING GENE EXPRESSION. THIS REVIEW FOCUSES ON TRANSCRIPTIONAL AND EPIGENETIC EFFECTS OF CAMKII ACTIVATION DURING CHRONIC CARDIAC REMODELING. MULTIPLE MECHANISMS HAVE BEEN DESCRIBED HOW CAMKII MEDIATES CHANGES IN CARDIAC GENE EXPRESSION. CAMKII HAS BEEN SHOWN TO DIRECTLY PHOSPHORYLATE COMPONENTS OF THE CARDIAC GENE REGULATION MACHINERY. CAMKII PHOSPHORYLATES SEVERAL TRANSCRIPTION FACTORS SUCH AS CREB THAT INDUCES THE ACTIVATION OF SPECIFIC GENE PROGRAMS. CAMKII ACTIVATES TRANSCRIPTIONAL REGULATORS ALSO INDIRECTLY BY PHOSPHORYLATING HISTONE DEACETYLASES, ESPECIALLY HDAC4, WHICH IN TURN INHIBITS TRANSCRIPTION FACTORS THAT DRIVE CARDIAC HYPERTROPHY, FIBROSIS, AND DYSFUNCTION. RECENT STUDIES DEMONSTRATE THAT CAMKII ALSO PHOSPHORYLATE DIRECTLY HISTONES, WHICH MAY CONTRIBUTE TO CHANGES IN GENE EXPRESSION. THESE FINDINGS OF CAMKII-DEPENDENT GENE REGULATION DURING CARDIAC REMODELING PROCESSES SUGGEST NOVEL STRATEGIES FOR CAMKII-DEPENDENT "TRANSCRIPTIONAL OR EPIGENETIC THERAPIES" TO CONTROL CARDIAC GENE EXPRESSION AND FUNCTION. MANIPULATION OF CAMKII-DEPENDENT SIGNALING PATHWAYS IN THE SETTINGS OF PATHOLOGICAL CARDIAC GROWTH, REMODELING, AND HEART FAILURE REPRESENTS AN AUSPICIOUS THERAPEUTIC APPROACH. 2014 3 5420 46 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 4 3466 43 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 2034 35 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 29 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 3467 35 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 8 4381 50 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 5951 29 TARGETING THE RENIN-ANGIOTENSIN-ALDOSTERONE SYSTEM TO PREVENT HYPERTENSION AND KIDNEY DISEASE OF DEVELOPMENTAL ORIGINS. THE RENIN-ANGIOTENSIN-ALDOSTERONE SYSTEM (RAAS) IS IMPLICATED IN HYPERTENSION AND KIDNEY DISEASE. THE DEVELOPING KIDNEY CAN BE PROGRAMMED BY VARIOUS EARLY-LIFE INSULTS BY SO-CALLED RENAL PROGRAMMING, RESULTING IN HYPERTENSION AND KIDNEY DISEASE IN ADULTHOOD. THIS THEORY IS KNOWN AS DEVELOPMENTAL ORIGINS OF HEALTH AND DISEASE (DOHAD). CONVERSELY, EARLY RAAS-BASED INTERVENTIONS COULD REVERSE PROGRAM PROCESSES TO PREVENT A DISEASE FROM OCCURRING BY SO-CALLED REPROGRAMMING. IN THE CURRENT REVIEW, WE MAINLY SUMMARIZE (1) THE CURRENT KNOWLEDGE ON THE RAAS IMPLICATED IN RENAL PROGRAMMING; (2) CURRENT EVIDENCE SUPPORTING THE CONNECTIONS BETWEEN THE ABERRANT RAAS AND OTHER MECHANISMS BEHIND RENAL PROGRAMMING, SUCH AS OXIDATIVE STRESS, NITRIC OXIDE DEFICIENCY, EPIGENETIC REGULATION, AND GUT MICROBIOTA DYSBIOSIS; AND (3) AN OVERVIEW OF HOW RAAS-BASED REPROGRAMMING INTERVENTIONS MAY PREVENT HYPERTENSION AND KIDNEY DISEASE OF DEVELOPMENTAL ORIGINS. TO ACCELERATE THE TRANSITION OF RAAS-BASED INTERVENTIONS FOR PREVENTION OF HYPERTENSION AND KIDNEY DISEASE, AN EXTENDED COMPREHENSION OF THE RAAS IMPLICATED IN RENAL PROGRAMMING IS NEEDED, AS WELL AS A GREATER FOCUS ON FURTHER CLINICAL TRANSLATION. 2021 10 5565 43 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 11 3338 39 HISTONE DEACETYLASE INHIBITORS: THE EPIGENETIC THERAPEUTICS THAT REPRESS HYPOXIA-INDUCIBLE FACTORS. HISTONE DEACETYLASE INHIBITORS (HDACIS) HAVE BEEN ACTIVELY EXPLORED AS A NEW GENERATION OF CHEMOTHERAPEUTICS FOR CANCERS, GENERALLY KNOWN AS EPIGENETIC THERAPEUTICS. RECENT FINDINGS INDICATE THAT SEVERAL TYPES OF HDACIS REPRESS ANGIOGENESIS, A PROCESS ESSENTIAL FOR TUMOR METABOLISM AND PROGRESSION. ACCUMULATING EVIDENCE SUPPORTS THAT THIS REPRESSION IS MEDIATED BY DISRUPTING THE FUNCTION OF HYPOXIA-INDUCIBLE FACTORS (HIF-1, HIF-2, AND COLLECTIVELY, HIF), WHICH ARE THE MASTER REGULATORS OF ANGIOGENESIS AND CELLULAR ADAPTATION TO HYPOXIA. SINCE HIF ALSO REGULATE GLUCOSE METABOLISM, CELL SURVIVAL, MICROENVIRONMENT REMODELING, AND OTHER ALTERATIONS COMMONLY REQUIRED FOR TUMOR PROGRESSION, THEY ARE CONSIDERED AS NOVEL TARGETS FOR CANCER CHEMOTHERAPY. THOUGH THE PRECISE BIOCHEMICAL MECHANISM UNDERLYING THE HDACI-TRIGGERED REPRESSION OF HIF FUNCTION REMAINS UNCLEAR, POTENTIAL CELLULAR FACTORS THAT MAY LINK THE INHIBITION OF DEACETYLASE ACTIVITY TO THE REPRESSION OF HIF FUNCTION HAVE BEEN PROPOSED. HERE WE REVIEW PUBLISHED DATA THAT INHIBITORS OF TYPE I/II HDACS REPRESS HIF FUNCTION BY EITHER REDUCING FUNCTIONAL HIF-1ALPHA LEVELS, OR REPRESSING HIF-ALPHA TRANSACTIVATION ACTIVITY. IN ADDITION, UNDERLYING MECHANISMS AND POTENTIAL PROTEINS INVOLVED IN THE REPRESSION WILL BE DISCUSSED. A THOROUGH UNDERSTANDING OF HDACI-INDUCED REPRESSION OF HIF FUNCTION MAY FACILITATE THE DEVELOPMENT OF FUTURE THERAPIES TO EITHER REPRESS OR PROMOTE ANGIOGENESIS FOR CANCER OR CHRONIC ISCHEMIC DISORDERS, RESPECTIVELY. 2011 12 6451 45 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 13 2800 39 FEEDBACK REGULATORS OF HYPOXIA-INDUCIBLE FACTORS AND THEIR ROLE IN CANCER BIOLOGY. MALIGNANT TUMORS ARE CHARACTERIZED BY REGIONS OF LOW OXYGEN CONCENTRATION (HYPOXIA). THE HYPOXIC TUMOR MICROENVIRONMENT CONTRIBUTES TO TUMOR PROGRESSION BY ACTIVATING A SET OF ADAPTIVE RESPONSES VIA THE KEY TRANSCRIPTIONAL REGULATORS HIF-1ALPHA AND HIF-2ALPHA. THESE FACTORS HAVE BEEN TRADITIONALLY LINKED TO AN AGGRESSIVE TUMOR PHENOTYPE BY PROMOTING PROCESSES ESSENTIAL FOR TUMOR GROWTH, SUCH AS ANGIOGENESIS, GLYCOLYSIS, METASTASIS AND INVASION, AS WELL AS DIFFERENTIATION AND SELF RENEWAL. NOTABLY, THE COMPLEX HIF PATHWAY ALSO INITIATES ANTI-TUMORIGENIC MECHANISMS THAT LEAD TO CELL CYCLE ARREST OR CELL DEATH, INDICATING THE NEED FOR A STRINGENT CONTROL OF THE EXTENT AND THE DIRECTION OF THE HYPOXIA RESPONSE. THE IMPORTANCE OF THIS CONTROL FOR TUMOR CELL SURVIVAL IS ILLUSTRATED BY THE INTRICATE REGULATION OF HIF ACTIVITY AT THE MRNA, PROTEIN AND EPIGENETIC LEVEL BY A COMPLEX NETWORK OF POSITIVE AND NEGATIVE FEEDBACK REGULATORS. WE PROPOSE THAT THESE FEEDBACK REGULATORS HELP TO FLEXIBLY ADJUST AND ADAPT HIF ACTIVATED RESPONSES TO THE FLUCTUATING OXYGEN CONCENTRATIONS WITHIN TUMORS DURING ACUTE AND CHRONIC HYPOXIA AND TO CURTAIL THE TUMOR-SUPPRESSING COMPONENTS OF THE HIF PATHWAY. MOREOVER, FEEDBACK REGULATION OF HIF INDUCES A SWITCH FROM HIF-1ALPHA TO HIF-2ALPHA DRIVEN RESPONSES UNDER CHRONIC HYPOXIA WHICH MAY HAVE ESSENTIAL FUNCTIONS IN THE REGULATION OF TUMOR CELL DIFFERENTIATION AND TUMOR STEM CELL MAINTENANCE. GIVEN THEIR CENTRAL ROLE IN CANCER BIOLOGY, HIF FEEDBACK REGULATORS MAY REPRESENT AN ATTRACTIVE AND NOVEL ANTI-TUMOR THERAPY TARGET TO OVERCOME CELL DEATH RESISTANCE IN TUMORS. 2010 14 6051 36 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 15 221 48 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 16 2191 48 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 17 6647 41 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 18 5370 35 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 19 3856 40 ISCHAEMIA REPERFUSION INJURY: MECHANISMS OF PROGRESSION TO CHRONIC GRAFT DYSFUNCTION. THE INCREASING USE OF EXTENDED CRITERIA ORGANS TO MEET THE DEMAND FOR KIDNEY TRANSPLANTATION RAISES AN IMPORTANT QUESTION OF HOW THE SEVERITY OF EARLY ISCHAEMIC INJURY INFLUENCES LONG-TERM OUTCOMES. SIGNIFICANT ACUTE ISCHAEMIC KIDNEY INJURY IS ASSOCIATED WITH DELAYED GRAFT FUNCTION, INCREASED IMMUNE-ASSOCIATED EVENTS AND, ULTIMATELY, EARLIER DETERIORATION OF GRAFT FUNCTION. A COMPREHENSIVE UNDERSTANDING OF IMMEDIATE MOLECULAR EVENTS THAT ENSUE POST-ISCHAEMIA AND THEIR POTENTIAL LONG-TERM CONSEQUENCES ARE KEY TO THE DISCOVERY OF NOVEL THERAPEUTIC TARGETS. ACUTE ISCHAEMIC INJURY PRIMARILY AFFECTS TUBULAR STRUCTURE AND FUNCTION. DEPENDING ON THE SEVERITY AND PERSISTENCE OF THE INSULT, THIS MAY RESOLVE COMPLETELY, LEADING TO RESTORATION OF NORMAL FUNCTION, OR BE SUSTAINED, RESULTING IN PERSISTENT RENAL IMPAIRMENT AND PROGRESSIVE FUNCTIONAL LOSS. LONG-TERM EFFECTS OF ACUTE RENAL ISCHAEMIA ARE MEDIATED BY SEVERAL MECHANISMS INCLUDING HYPOXIA, HIF-1 ACTIVATION, ENDOTHELIAL DYSFUNCTION LEADING TO VASCULAR RAREFACTION, SUSTAINED PRO-INFLAMMATORY STIMULI INVOLVING INNATE AND ADAPTIVE IMMUNE RESPONSES, FAILURE OF TUBULAR CELLS TO RECOVER AND EPIGENETIC CHANGES. THIS REVIEW DESCRIBES THE BIOLOGICAL RELEVANCE AND INTERACTION OF THESE MECHANISMS BASED ON CURRENTLY AVAILABLE EVIDENCE. 2019 20 4577 39 MYOSTATIN: BASIC BIOLOGY TO CLINICAL APPLICATION. MYOSTATIN IS A MEMBER OF THE TRANSFORMING GROWTH FACTOR (TGF)-BETA SUPERFAMILY. IT IS EXPRESSED BY ANIMAL AND HUMAN SKELETAL MUSCLE CELLS WHERE IT LIMITS MUSCLE GROWTH AND PROMOTES PROTEIN BREAKDOWN. ITS EFFECTS ARE INFLUENCED BY COMPLEX MECHANISMS INCLUDING TRANSCRIPTIONAL AND EPIGENETIC REGULATION AND MODULATION BY EXTRACELLULAR BINDING PROTEINS. DUE TO ITS ACTIONS IN PROMOTING MUSCLE ATROPHY AND CACHEXIA, MYOSTATIN HAS BEEN INVESTIGATED AS A PROMISING THERAPEUTIC TARGET TO COUNTERACT MUSCLE MASS LOSS IN EXPERIMENTAL MODELS AND PATIENTS AFFECTED BY DIFFERENT MUSCLE-WASTING CONDITIONS. MOREOVER, GROWING EVIDENCE INDICATES THAT MYOSTATIN, BEYOND TO REGULATE SKELETAL MUSCLE GROWTH, MAY HAVE A ROLE IN MANY PHYSIOLOGIC AND PATHOLOGIC PROCESSES, SUCH AS OBESITY, INSULIN RESISTANCE, CARDIOVASCULAR AND CHRONIC KIDNEY DISEASE. IN THIS CHAPTER, WE REVIEW MYOSTATIN BIOLOGY, INCLUDING INTRACELLULAR AND EXTRACELLULAR REGULATORY PATHWAYS, AND THE ROLE OF MYOSTATIN IN MODULATING PHYSIOLOGIC PROCESSES, SUCH AS MUSCLE GROWTH AND AGING. MOREOVER, WE DISCUSS THE MOST RELEVANT EXPERIMENTAL AND CLINICAL EVIDENCE SUPPORTING THE EXTRA-MUSCLE EFFECTS OF MYOSTATIN. FINALLY, WE CONSIDER THE MAIN STRATEGIES DEVELOPED AND TESTED TO INHIBIT MYOSTATIN IN CLINICAL TRIALS AND DISCUSS THE LIMITS AND FUTURE PERSPECTIVES OF THE RESEARCH ON MYOSTATIN. 2022