1 3856 117 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 2 5420 36 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 3466 32 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 4 2034 25 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 5 5497 35 REVIEW: ANIMAL MODELS OF ACQUIRED EPILEPSY: INSIGHTS INTO MECHANISMS OF HUMAN EPILEPTOGENESIS. IN MANY PATIENTS WHO SUFFER FROM EPILEPSIES, RECURRENT EPILEPTIC SEIZURES DO NOT START AT BIRTH BUT DEVELOP LATER IN LIFE. THIS HOLDS PARTICULARLY TRUE FOR EPILEPSIES WITH A FOCAL SEIZURE ORIGIN INCLUDING FOCAL CORTICAL DYSPLASIAS AND TEMPORAL LOBE EPILEPSY (TLE). TLE MOST FREQUENTLY HAS ITS SEIZURE ONSET IN THE HIPPOCAMPAL FORMATION. HIPPOCAMPAL BIOPSIES OF PHARMACORESISTANT TLE PATIENTS UNDERGOING EPILEPSY SURGERY FOR SEIZURE CONTROL MOST FREQUENTLY REVEAL THE DAMAGE PATTERN OF HIPPOCAMPAL SCLEROSIS, THAT IS, SEGMENTAL NEURONAL CELL LOSS AND CONCOMITANT ASTROGLIOSIS. MANY TLE PATIENTS REPORT ON TRANSIENT BRAIN INSULTS EARLY IN LIFE, WHICH IS FOLLOWED BY A 'LATENCY' PERIOD LACKING SEIZURE ACTIVITY OF MONTHS OR EVEN YEARS BEFORE CHRONIC RECURRENT SEIZURES START. THE PLETHORA OF STRUCTURAL AND CELLULAR MECHANISMS THAT CONVERT THE HIPPOCAMPAL FORMATION TO BECOME CHRONICALLY HYPEREXCITABLE AFTER A TRANSIENT INSULT TO THE BRAIN ARE SUMMARIZED UNDER THE TERM EPILEPTOGENESIS. IN CONTRAST TO THE OBSTACLES ARISING FOR EXPERIMENTAL STUDIES OF EPILEPTOGENESIS ASPECTS IN HUMAN SURGICAL HIPPOCAMPAL TISSUE, RECENT ANIMAL MODEL APPROACHES ALLOW INSIGHTS INTO MECHANISMS OF EPILEPTOGENESIS. RELEVANT MODELS OF TRANSIENT BRAIN INSULTS IN THIS CONTEXT COMPRISE SEVERAL DISTINCT TYPES OF LESIONS INCLUDING EXCITOXIC STATUS EPILEPTICUS (SE), ELECTRICAL SEIZURE INDUCTION, TRAUMATIC BRAIN INJURY, INDUCTION OF INFLAMMATORY PROCESSES BY HYPERTHERMIA AND VIRAL INFLAMMATION AND OTHERS. IN PATHOGENETIC TERMS, ABERRANT TRANSCRIPTIONAL AND EPIGENETIC REPROGRAMMING, ACQUIRED CHANNEL- AND SYNAPTOPATHIES, NEURONAL NETWORK AND BLOOD-BRAIN BARRIER DYSFUNCTION AS WELL AS INNATE AND ADAPTIVE IMMUNITY-MEDIATED DAMAGE PLAY MAJOR ROLES. IN SUBSEQUENT STEPS, RESPECTIVE ANIMAL MODELS HAVE BEEN USED IN ORDER TO TEST WHETHER THIS DYNAMIC PROCESS CAN BE EITHER RETARDED OR EVEN ABOLISHED BY INTERFERING WITH EPILEPTOGENIC MECHANISMS. WELL-CONTROLLED SUBSEQUENT ANALYSES OF EPILEPTOGENIC CASCADES CHARACTERIZED IN ANIMAL MODELS USING CAREFULLY STRATIFIED HUMAN HIPPOCAMPAL BIOPSIES TO EXPLOIT THE UNIQUE OPPORTUNITIES GIVEN BY THESE RARE AND PRECIOUS BRAIN TISSUE SAMPLES AIM TO TRANSLATE INTO NOVEL ANTIEPILEPTOGENIC APPROACHES. RESPECTIVE PRECLINICAL TESTS CAN OPEN ENTIRELY NEW PERSPECTIVES FOR TAILOR-MADE TREATMENTS IN PATIENTS WITH THE POTENTIAL TO AVOID THE EMERGENCE OF CHRONIC FOCAL SEIZURE EVENTS. 2018 6 2788 40 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 7 2191 44 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 8 795 30 CELLULAR RESILIENCE. CELLULAR RESILIENCE DESCRIBES THE ABILITY OF A CELL TO COPE WITH ENVIRONMENTAL CHANGES SUCH AS TOXICANT EXPOSURE. IF CELLULAR METABOLISM DOES NOT COLLAPSE DIRECTLY AFTER THE HIT OR END IN PROGRAMMED CELL DEATH, THE ENSUING STRESS RESPONSES PROMOTE A NEW HOMEOSTASIS UNDER STRESS. THE PROCESSES OF REVERTING "BACK TO NORMAL" AND REVERSAL OF APOPTOSIS ("ANASTASIS") HAVE BEEN STUDIED LITTLE AT THE CELLULAR LEVEL. CELL TYPES SHOW ASTONISHINGLY SIMILAR VULNERABILITY TO MOST TOXICANTS, EXCEPT FOR THOSE THAT REQUIRE A VERY SPECIFIC TARGET, METABOLISM OR MECHANISM PRESENT ONLY IN SPECIFIC CELL TYPES. THE MAJORITY OF CHEMICALS TRIGGERS "GENERAL CYTOTOXICITY" IN ANY CELL AT SIMILAR CONCENTRATIONS. WE HYPOTHESIZE THAT CELLS DIFFER LESS IN THEIR VULNERABILITY TO A GIVEN TOXICANT THAN IN THEIR RESILIENCE (COPING WITH THE "HIT"). IN MANY CASES, CELLS DO NOT RETURN TO THE NAIVE STATE AFTER A TOXIC INSULT. THE PHENOMENA OF "PRE-CONDITIONING", "TOLERANCE" AND "HORMESIS" DESCRIBE THIS FOR LOW-DOSE EXPOSURES TO TOXICANTS THAT RENDER THE CELL MORE RESISTANT TO SUBSEQUENT HITS. THE DEFENSE AND RESILIENCE PROGRAMS INCLUDE EPIGENETIC CHANGES THAT LEAVE A "MEMORY/SCAR" - AN ALTERATION AS A CONSEQUENCE OF THE STRESS THE CELL HAS EXPERIENCED. THESE MEMORIES MIGHT HAVE LONG-TERM CONSEQUENCES, BOTH POSITIVE (RESISTANCE) AND NEGATIVE, THAT CONTRIBUTE TO CHRONIC AND DELAYED MANIFESTATIONS OF HAZARD AND, ULTIMATELY, DISEASE. THIS ARTICLE CALLS FOR MORE SYSTEMATIC ANALYSES OF HOW CELLS COPE WITH TOXIC PERTURBATIONS IN THE LONG-TERM AFTER STRESSOR WITHDRAWAL. A TECHNICAL PREREQUISITE FOR THESE ARE STABLE (ORGANOTYPIC) CULTURES AND A CHARACTERIZATION OF STRESS RESPONSE MOLECULAR NETWORKS. 2015 9 793 29 CELLULAR RE- AND DE-PROGRAMMING BY MICROENVIRONMENTAL MEMORY: WHY SHORT TGF-BETA1 PULSES CAN HAVE LONG EFFECTS. BACKGROUND: FIBROSIS POSES A SUBSTANTIAL SETBACK IN REGENERATIVE MEDICINE. HISTOPATHOLOGICALLY, FIBROSIS IS AN EXCESSIVE ACCUMULATION OF COLLAGEN AFFECTED BY MYOFIBROBLASTS AND THIS CAN OCCUR IN ANY TISSUE THAT IS EXPOSED TO CHRONIC INJURY OR INSULT. TRANSFORMING GROWTH FACTOR (TGF)-BETA1, A CRUCIAL MEDIATOR OF FIBROSIS, DRIVES DIFFERENTIATION OF FIBROBLASTS INTO MYOFIBROBLASTS. THESE CELLS EXHIBIT ALPHA-SMOOTH MUSCLE ACTIN (ALPHA-SMA) AND SYNTHESIZE HIGH AMOUNTS OF COLLAGEN I, THE MAJOR EXTRACELLULAR MATRIX (ECM) COMPONENT OF FIBROSIS. WHILE HORMONES STIMULATE CELLS IN A PULSATILE MANNER, LITTLE IS KNOWN ABOUT CELLULAR RESPONSE KINETICS UPON GROWTH FACTOR IMPACT. WE THEREFORE STUDIED THE EFFECTS OF SHORT TGF-BETA1 PULSES IN TERMS OF THE INDUCTION AND MAINTENANCE OF THE MYOFIBROBLAST PHENOTYPE. RESULTS: TWENTY-FOUR HOURS AFTER A SINGLE 30 MIN TGF-BETA1 PULSE, TRANSCRIPTION OF FIBROGENIC GENES WAS UPREGULATED, BUT SUBSIDED 7 DAYS LATER. IN PARALLEL, COLLAGEN I SECRETION RATE AND ALPHA-SMA PRESENCE WERE ELEVATED FOR 7 DAYS. A SECOND PULSE 24 H LATER EXTENDED THE DURATION OF EFFECTS TO 14 DAYS. WE COULD NOT ESTABLISH EPIGENETIC CHANGES ON FIBROGENIC TARGET GENES TO EXPLAIN THE LONG-LASTING EFFECTS. HOWEVER, ECM DEPOSITED UNDER SINGLY PULSED TGF-BETA1 WAS ABLE TO INDUCE MYOFIBROBLAST FEATURES IN PREVIOUSLY UNTREATED FIBROBLASTS. DEPENDENT ON THE AGE OF THE ECM (1 DAY VERSUS 7 DAYS' FORMATION TIME), THIS PROPERTY WAS DIMINISHED. VICE VERSA, MYOFIBROBLASTS WERE CULTURED ON FIBROBLAST ECM AND CELLS OBSERVED TO EXPRESS REDUCED (IN COMPARISON WITH MYOFIBROBLASTS) LEVELS OF COLLAGEN I. CONCLUSIONS: WE DEMONSTRATED THAT SHORT TGF-BETA1 PULSES CAN EXERT LONG-LASTING EFFECTS ON FIBROBLASTS BY CHANGING THEIR MICROENVIRONMENT, THUS LEAVING AN IMPRINT AND CREATING A RECIPROCAL FEED-BACK LOOP. THEREFORE, THE ECM MIGHT ACT AS MID-TERM MEMORY FOR PATHOBIOCHEMICAL EVENTS. WE WOULD EXPECT THIS MICROENVIRONMENTAL MEMORY TO BE DEPENDENT ON MATRIX TURNOVER AND, AS SUCH, TO BE ERASABLE. OUR FINDINGS CONTRIBUTE TO THE CURRENT UNDERSTANDING OF FIBROBLAST INDUCTION AND MAINTENANCE, AND HAVE BEARING ON THE DEVELOPMENT OF ANTIFIBROTIC DRUGS. 2013 10 6192 26 THE IMPACT OF NUTRITIONAL INSULTS DURING FETAL LIFE ON BLOOD PRESSURE. NUMEROUS EPIDEMIOLOGICAL AND EXPERIMENTAL STUDIES PROVIDE COMPELLING EVIDENCE THAT NUTRITIONAL INSULTS THAT IMPACT FETAL GROWTH PROGRAM A MARKED INCREASE IN BLOOD PRESSURE IN LATER LIFE. SEX AND AGE ALSO INFLUENCE THE DEVELOPMENTAL PROGRAMMING OF HYPERTENSION; YET THE EXACT MECHANISMS THAT PERMANENTLY CHANGE THE STRUCTURE, PHYSIOLOGY, AND ENDOCRINE HEALTH OF AN INDIVIDUAL ACROSS THEIR LIFESPAN FOLLOWING EXPOSURE TO A NUTRITIONAL INSULT ARE NOT ENTIRELY CLEAR. FETAL EXPOSURE TO MATERNAL GLUCOCORTICOIDS IS POSTULATED AS AN INITIATING EVENT. IN ADDITION, INAPPROPRIATE SUPPRESSION OR ACTIVATION OF THE RENIN ANGIOTENSIN SYSTEM (RAS) AND/OR ACTIVATION OF THE SYMPATHETIC NERVOUS SYSTEM (SNS) LEADING TO MARKED INCREASES IN OXIDATIVE STRESS AND ENDOTHELIN PRODUCTION ARE IMPLICATED IN THE ETIOLOGY OF HYPERTENSION THAT HAS ITS ORIGINS IN FETAL LIFE. THE RISK OF HYPERTENSION AND CHRONIC DISEASE IN ONE GENERATION IS TRANSMITTED TO THE NEXT IN THE ABSENCE OF AN ADDITIONAL PRENATAL INSULT IMPLICATING EPIGENETIC PROCESSES. YET, FURTHER STUDIES ARE NEEDED TO FULLY ELUCIDATE THE MECHANISMS THAT CONTRIBUTE TO HYPERTENSION PROGRAMMED IN RESPONSE TO NUTRITIONAL INSULTS DURING EARLY LIFE IN ORDER TO IMPROVE THE CARDIOVASCULAR HEALTH OF AN INDIVIDUAL ACROSS THEIR LIFESPAN. 2015 11 4381 38 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 12 4275 25 MICROGLIA ACTIVATION IN THE MIDBRAIN OF THE HUMAN NEONATE: THE EFFECT OF PERINATAL HYPOXIC-ISCHEMIC INJURY. PERINATAL HYPOXIA-ISCHEMIA (PHI) IS A MAJOR RISK FACTOR FOR THE DEVELOPMENT OF NEUROPSYCHIATRIC DEFICITS LATER IN LIFE. WE PREVIOUSLY REPORTED THAT AFTER PROLONGED PHI, THE DOPAMINERGIC NEURONS OF THE HUMAN NEONATE SHOWED A DRAMATIC REDUCTION OF TYROSINE HYDROXYLASE (TH) IN THE SUBSTANTIA NIGRA, WITHOUT IMPORTANT SIGNS OF NEURONAL DEGENERATION DESPITE THE SIGNIFICANT REDUCTION IN THEIR CELL SIZE. SINCE MICROGLIA ACTIVATION COULD PRECEDE NEURONAL DEATH, WE NOW INVESTIGATED 2 MICROGLIA ACTIVATION MARKERS, IONIZED CALCIUM-BINDING ADAPTER MOLECULE 1 (IBA1), AND THE PHAGOCYTOSIS MARKER CD68. THE HIGHEST IBA1 IMMUNOREACTIVITY WAS FOUND IN NEONATES WITH NEUROPATHOLOGICAL LESIONS OF SEVERE/ABRUPT PHI, WHILE THE LOWEST IN SUBJECTS WITH MODERATE/PROLONGED OR OLDER PHI. SUBJECTS WITH VERY SEVERE/PROLONGED OR CHRONIC PHI SHOWED AN INCREASED IBA1 EXPRESSION AND VERY ACTIVATED MICROGLIAL MORPHOLOGY. HEAVY ATTACHMENT OF MICROGLIA ON TH NEURONS AND REMARKABLE EXPRESSION OF CD68 WERE ALSO OBSERVED INDICATING PHAGOCYTOSIS IN THIS GROUP. FEMALES APPEAR TO EXPRESS MORE IBA1 THAN MALES, SUGGESTING A GENDER DIFFERENCE IN MICROGLIA MATURATION AND IMMUNE REACTIVITY AFTER PHI INSULT. PHI-INDUCED MICROGLIAL "PRIMING" DURING THE SENSITIVE FOR BRAIN DEVELOPMENT PERINATAL/NEONATAL PERIOD, IN COMBINATION WITH GENETIC OR OTHER EPIGENETIC FACTORS, COULD PREDISPOSE THE SURVIVORS TO NEUROPSYCHIATRIC DISORDERS LATER IN LIFE, POSSIBLY THROUGH A SEXUALLY DIMORPHIC WAY. 2022 13 4633 34 NEUROIMMUNE ACTIVATION DRIVES MULTIPLE BRAIN STATES. NEUROIMMUNE SIGNALING IS INCREASINGLY IDENTIFIED AS A CRITICAL COMPONENT OF NEURONAL PROCESSES UNDERLYING MEMORY, EMOTION AND COGNITION. THE INTERACTIONS OF MICROGLIA AND ASTROCYTES WITH NEURONS AND SYNAPSES, AND THE INDIVIDUAL CYTOKINES AND IMMUNE SIGNALING MOLECULES THAT MEDIATE THESE INTERACTIONS ARE A CURRENT FOCUS OF MUCH RESEARCH. HERE, WE DISCUSS NEUROIMMUNE ACTIVATION AS A MECHANISM TRIGGERING DIFFERENT STATES THAT MODULATE COGNITIVE AND AFFECTIVE PROCESSES TO ALLOW FOR APPROPRIATE BEHAVIOR DURING AND AFTER ILLNESS OR INJURY. WE PROPOSE THAT THESE STATES LIE ON A CONTINUUM FROM A NAIVE HOMEOSTATIC BASELINE STATE IN THE ABSENCE OF STIMULATION, TO ACUTE NEUROIMMUNE ACTIVITY AND CHRONIC ACTIVATION. IMPORTANTLY, CONSEQUENCES OF ILLNESS OR INJURY INCLUDING COGNITIVE DEFICITS AND MOOD IMPAIRMENTS CAN PERSIST LONG AFTER RESOLUTION OF IMMUNE SIGNALING. THIS SUGGESTS THAT NEUROIMMUNE ACTIVATION ALSO RESULTS IN AN ENDURING SHIFT IN THE HOMEOSTATIC BASELINE STATE WITH LONG LASTING CONSEQUENCES FOR NEURAL FUNCTION AND BEHAVIOR. SUCH DIFFERENT STATES CAN BE IDENTIFIED IN A MULTIDIMENSIONAL WAY, USING PATTERNS OF CYTOKINE AND GLIAL ACTIVATION, BEHAVIORAL AND COGNITIVE CHANGES, AND EPIGENETIC SIGNATURES. IDENTIFYING DISTINCT NEUROIMMUNE STATES AND THEIR CONSEQUENCES FOR NEURAL FUNCTION WILL PROVIDE A FRAMEWORK FOR PREDICTING VULNERABILITY TO DISORDERS OF MEMORY, COGNITION AND EMOTION BOTH DURING AND LONG AFTER RECOVERY FROM ILLNESS. 2018 14 4278 37 MICROGLIAL INNATE MEMORY AND EPIGENETIC REPROGRAMMING IN NEUROLOGICAL DISORDERS. MICROGLIA ARE MYELOID-DERIVED CELLS RECOGNIZED AS BRAIN-RESIDENT MACROPHAGES. THEY ACT AS THE FIRST AND MAIN LINE OF IMMUNE DEFENSE IN THE CENTRAL NERVOUS SYSTEM (CNS). MICROGLIA HAVE HIGH PHENOTYPIC PLASTICITY AND ARE ESSENTIAL FOR REGULATING HEALTHY BRAIN HOMEOSTASIS, AND THEIR DYSREGULATION UNDERLIES THE ONSET AND PROGRESSION OF SEVERAL CNS PATHOLOGIES THROUGH IMPAIRED INFLAMMATORY RESPONSES. ABERRANT MICROGLIAL ACTIVATION, FOLLOWING AN INFLAMMATORY INSULT, IS ASSOCIATED WITH EPIGENETIC DYSREGULATION IN VARIOUS CNS PATHOLOGIES. EMERGING DATA SUGGEST THAT CERTAIN STIMULI TO MYELOID CELLS DETERMINE ENHANCED OR ATTENUATED RESPONSES TO SUBSEQUENT STIMULI. THESE PHENOMENA, GENERALLY TERMED INNATE IMMUNE MEMORY (IIM), ARE HIGHLY DEPENDENT ON EPIGENETIC REPROGRAMMING. MICROGLIAL PRIMING HAS BEEN REPORTED IN SEVERAL NEUROLOGICAL DISEASES AND CORRESPONDS TO A STATE OF INCREASED PERMISSIVENESS OR EXACERBATED RESPONSE, PROMOTED BY CONTINUOUS EXPOSURE TO A CHRONIC PRO-INFLAMMATORY ENVIRONMENT. IN THIS ARTICLE, WE PROVIDE EXTENSIVE EVIDENCE OF THESE EPIGENETIC-MEDIATED PHENOMENA UNDER NEUROLOGICAL CONDITIONS AND DISCUSS THEIR CONTRIBUTION TO PATHOGENESIS AND THEIR CLINICAL IMPLICATIONS, INCLUDING THOSE CONCERNING POTENTIAL NOVEL THERAPEUTIC APPROACHES. 2021 15 2770 35 EXTENDING INJURY- AND DISEASE-RESISTANT CNS PHENOTYPES BY REPETITIVE EPIGENETIC CONDITIONING. SIGNIFICANT REDUCTIONS IN THE EXTENT OF ACUTE INJURY IN THE CNS CAN BE ACHIEVED BY EXPOSURE TO DIFFERENT PRECONDITIONING STIMULI, BUT THE DURATION OF THE INDUCED PROTECTIVE PHENOTYPE IS TYPICALLY SHORT-LASTING, AND THUS IS DEEMED AS LIMITING ITS CLINICAL APPLICABILITY. EXTENDING THE PERIOD OVER WHICH SUCH ADAPTIVE EPIGENETIC CHANGES PERSIST - IN EFFECT, EXPANDING CONDITIONING'S "THERAPEUTIC WINDOW" - WOULD SIGNIFICANTLY BROADEN THE POTENTIAL APPLICATIONS OF SUCH A TREATMENT APPROACH IN PATIENTS. THE FREQUENCY OF THE CONDITIONING STIMULUS MAY HOLD THE KEY. WHILE TRANSIENT (1-3 DAYS) PROTECTION AGAINST CNS ISCHEMIC INJURY IS WELL ESTABLISHED PRECLINICALLY FOLLOWING A SINGLE PRECONDITIONING STIMULUS, REPETITIVELY PRESENTING PRECONDITIONING STIMULI EXTENDS THE DURATION OF ISCHEMIC TOLERANCE BY MANY WEEKS. MOREOVER, REPETITIVE INTERMITTENT POSTCONDITIONING ENHANCES POST-ISCHEMIC RECOVERY METRICS AND IMPROVES LONG-TERM SURVIVAL. INTERMITTENT CONDITIONING IS ALSO EFFICACIOUS FOR PREVENTING OR DELAYING INJURY IN PRECLINICAL MODELS OF CHRONIC NEURODEGENERATIVE DISEASE, AND FOR PROMOTING LONG-LASTING FUNCTIONAL IMPROVEMENTS IN A NUMBER OF OTHER PATHOLOGIES AS WELL. ALTHOUGH THE DETAILED MECHANISMS UNDERLYING THESE PROTRACTED KINDS OF NEUROPLASTICITY REMAIN LARGELY UNSTUDIED, ACCUMULATING EMPIRICAL EVIDENCE SUPPORTS THE CONTENTION THAT ALL OF THESE ADAPTIVE PHENOTYPES ARE EPIGENETICALLY MEDIATED. GOING FORWARD, ADDITIONAL PRECLINICAL DEMONSTRATIONS OF THE ABILITY TO INDUCE SUSTAINED BENEFICIAL PHENOTYPES THAT REDUCE THE BURDEN OF ACUTE AND CHRONIC NEURODEGENERATION, AND EXPERIMENTAL INTERROGATIONS OF THE REGULATORY CONSTRUCTS RESPONSIBLE FOR THESE EPIGENETIC RESPONSES, WILL ACCELERATE THE IDENTIFICATION OF NOT ONLY EFFICACIOUS BUT ALSO PRACTICAL, ADAPTIVE EPIGENETICS-BASED TREATMENTS FOR INDIVIDUALS WITH NEUROLOGICAL DISEASE. 2015 16 4138 37 MECHANISMS OF MICROGLIAL ACTIVATION IN MODELS OF INFLAMMATION AND HYPOXIA: IMPLICATIONS FOR CHRONIC INTERMITTENT HYPOXIA. CHRONIC INTERMITTENT HYPOXIA (CIH) IS A HALLMARK OF SLEEP APNOEA, A CONDITION ASSOCIATED WITH DIVERSE CLINICAL DISORDERS. CIH AND SLEEP APNOEA ARE CHARACTERIZED BY INCREASED REACTIVE OXYGEN SPECIES FORMATION, PERIPHERAL AND CNS INFLAMMATION, NEURONAL DEATH AND NEUROCOGNITIVE DEFICITS. FEW STUDIES HAVE EXAMINED THE ROLE OF MICROGLIA, THE RESIDENT CNS IMMUNE CELLS, IN MODELS OF CIH. THUS, LITTLE IS KNOWN CONCERNING THEIR DIRECT CONTRIBUTIONS TO NEUROPATHOLOGY OR THE CELLULAR MECHANISMS REGULATING THEIR ACTIVITIES DURING OR FOLLOWING PATHOLOGICAL CIH. IN THIS REVIEW, WE IDENTIFY GAPS IN KNOWLEDGE REGARDING CIH-INDUCED MICROGLIAL ACTIVATION, AND PROPOSE MECHANISMS BASED ON DATA FROM RELATED MODELS OF HYPOXIA AND/OR HYPOXIA-REOXYGENATION. CIH MAY DIRECTLY AFFECT MICROGLIA, OR MAY HAVE INDIRECT EFFECTS VIA THE PERIPHERY OR OTHER CNS CELLS. PERIPHERAL INFLAMMATION MAY INDIRECTLY ACTIVATE MICROGLIA VIA ENTRY OF PRO-INFLAMMATORY MOLECULES INTO THE CNS, AND/OR ACTIVATION OF VAGAL AFFERENTS THAT TRIGGER CNS INFLAMMATION. CIH-INDUCED RELEASE OF DAMAGE-ASSOCIATED MOLECULAR PATTERNS FROM INJURED CNS CELLS MAY ALSO ACTIVATE MICROGLIA VIA INTERACTIONS WITH PATTERN RECOGNITION RECEPTORS EXPRESSED ON MICROGLIA. FOR EXAMPLE, TOLL-LIKE RECEPTORS ACTIVATE MITOGEN-ACTIVATED PROTEIN KINASE/TRANSCRIPTION FACTOR PATHWAYS REQUIRED FOR MICROGLIAL INFLAMMATORY GENE EXPRESSION. ALTHOUGH EPIGENETIC EFFECTS FROM CIH HAVE NOT YET BEEN STUDIED IN MICROGLIA, POTENTIAL EPIGENETIC MECHANISMS IN MICROGLIAL REGULATION ARE DISCUSSED, INCLUDING MICRORNAS, HISTONE MODIFICATIONS AND DNA METHYLATION. EPIGENETIC EFFECTS CAN OCCUR DURING CIH, OR LONG AFTER IT HAS ENDED. A BETTER UNDERSTANDING OF CIH EFFECTS ON MICROGLIAL ACTIVITIES MAY BE IMPORTANT TO REVERSE CIH-INDUCED NEUROPATHOLOGY IN PATIENTS WITH SLEEP DISORDERED BREATHING. 2016 17 2702 30 EXCITOTOXICITY AND OVERNUTRITION ADDITIVELY IMPAIR METABOLIC FUNCTION AND IDENTITY OF PANCREATIC BETA-CELLS. A SUSTAINED INCREASE IN INTRACELLULAR CA(2+) CONCENTRATION (REFERRED TO HEREAFTER AS EXCITOTOXICITY), BROUGHT ON BY CHRONIC METABOLIC STRESS, MAY CONTRIBUTE TO PANCREATIC BETA-CELL FAILURE. TO DETERMINE THE ADDITIVE EFFECTS OF EXCITOTOXICITY AND OVERNUTRITION ON BETA-CELL FUNCTION AND GENE EXPRESSION, WE ANALYZED THE IMPACT OF A HIGH-FAT DIET (HFD) ON ABCC8 KNOCKOUT MICE. EXCITOTOXICITY CAUSED BETA-CELLS TO BE MORE SUSCEPTIBLE TO HFD-INDUCED IMPAIRMENT OF GLUCOSE HOMEOSTASIS, AND THESE EFFECTS WERE MITIGATED BY VERAPAMIL, A CA(2+) CHANNEL BLOCKER. EXCITOTOXICITY, OVERNUTRITION, AND THE COMBINATION OF BOTH STRESSES CAUSED SIMILAR BUT DISTINCT ALTERATIONS IN THE BETA-CELL TRANSCRIPTOME, INCLUDING ADDITIVE INCREASES IN GENES ASSOCIATED WITH MITOCHONDRIAL ENERGY METABOLISM, FATTY ACID BETA-OXIDATION, AND MITOCHONDRIAL BIOGENESIS AND THEIR KEY REGULATOR PPARGC1A OVERNUTRITION WORSENED EXCITOTOXICITY-INDUCED MITOCHONDRIAL DYSFUNCTION, INCREASING METABOLIC INFLEXIBILITY AND MITOCHONDRIAL DAMAGE. IN ADDITION, EXCITOTOXICITY AND OVERNUTRITION, INDIVIDUALLY AND TOGETHER, IMPAIRED BOTH BETA-CELL FUNCTION AND IDENTITY BY REDUCING EXPRESSION OF GENES IMPORTANT FOR INSULIN SECRETION, CELL POLARITY, CELL JUNCTION, CILIA, CYTOSKELETON, VESICULAR TRAFFICKING, AND REGULATION OF BETA-CELL EPIGENETIC AND TRANSCRIPTIONAL PROGRAM. SEX HAD AN IMPACT ON ALL BETA-CELL RESPONSES, WITH MALE ANIMALS EXHIBITING GREATER METABOLIC STRESS-INDUCED IMPAIRMENTS THAN FEMALES. TOGETHER, THESE FINDINGS INDICATE THAT A SUSTAINED INCREASE IN INTRACELLULAR CA(2+), BY ALTERING MITOCHONDRIAL FUNCTION AND IMPAIRING BETA-CELL IDENTITY, AUGMENTS OVERNUTRITION-INDUCED BETA-CELL FAILURE. 2020 18 803 27 CENTRAL CONTROL OF VISCERAL PAIN AND URINARY TRACT FUNCTION. AFFERENT INPUT FROM ADELTA AND C-FIBRES INNERVATING THE URINARY BLADDER ARE PROCESSED DIFFERENTLY BY THE BRAIN, AND HAVE DIFFERENT ROLES IN SIGNALING BLADDER SENSATION. ADELTA FIBRES THAT SIGNAL BLADDER FILLING ACTIVATE A SPINO-BULBO-SPINAL LOOP, WHICH RELAYS IN THE MIDBRAIN PERIAQUEDUCTAL GREY (PAG) AND PONTINE MICTURITION CENTRE (PMC). THE EXCITABILITY OF THIS CIRCUITRY IS REGULATED BY TONIC GABAERGIC INHIBITORY PROCESSES. IN HUMANS AND SOCIALISED ANIMALS MICTURITION IS NORMALLY UNDER VOLITIONAL CONTROL AND INFLUENCED BY A HOST OF PSYCHOSOCIAL FACTORS. HIGHER NERVOUS DECISION-MAKING IN A SOCIAL CONTEXT TO 'GO NOW' OR 'DO NOT GO' PROBABLY RESIDES IN FRONTAL CORTICAL AREAS, WHICH ACT AS A CENTRAL CONTROL SWITCH FOR MICTURITION. EXPOSURE TO PSYCHOSOCIAL STRESS CAN HAVE PROFOUNDLY DISRUPTIVE INFLUENCE ON THE PROCESS AND LEAD TO MALADAPTIVE CHANGES IN THE BLADDER. DURING SLEEPING THE VOIDING REFLEX THRESHOLD APPEARS TO BE RESET TO A HIGHER LEVEL TO PROMOTE URINARY CONTINENCE. UNDER PHYSIOLOGICAL CONDITIONS C-FIBRE BLADDER AFFERENTS ARE NORMALLY SILENT BUT ARE ACTIVATED IN INFLAMMATORY BLADDER STATES AND BY INTENSE DISTENDING PRESSURE. FOLLOWING PROLONGED STIMULATION VISCERAL NOCICEPTORS SENSITISE, LEADING TO A LOWERED THRESHOLD AND HEIGHTENED SENSITIVITY. IN ADDITION, SENSITIZATION MAY OCCUR WITHIN THE CENTRAL PAIN PROCESSING CIRCUITRY, WHICH OUTLASTS THE ORIGINAL NOCICEPTIVE INSULT. VISCERAL NOCICEPTION MAY ALSO BE INFLUENCED BY GENETIC AND ENVIRONMENTAL INFLUENCES. A PERIOD OF CHRONIC STRESS CAN PRODUCE INCREASED SENSITIVITY TO VISCERAL PAIN THAT LASTS FOR MONTHS. ADVERSE EARLY LIFE EVENTS CAN PRODUCE EVEN LONGER LASTING EPIGENETIC CHANGES, WHICH INCREASE THE INDIVIDUAL'S SUSCEPTIBILITY TO DEVELOPING VISCERAL PAIN STATES IN ADULTHOOD. 2016 19 5006 33 PERIPHERAL NERVE INJURY IS ACCOMPANIED BY CHRONIC TRANSCRIPTOME-WIDE CHANGES IN THE MOUSE PREFRONTAL CORTEX. BACKGROUND: PERIPHERAL NERVE INJURY CAN HAVE LONG-TERM CONSEQUENCES INCLUDING PAIN-RELATED MANIFESTATIONS, SUCH AS HYPERSENSITIVITY TO CUTANEOUS STIMULI, AS WELL AS AFFECTIVE AND COGNITIVE DISTURBANCES, SUGGESTING THE INVOLVEMENT OF SUPRASPINAL MECHANISMS. CHANGES IN BRAIN STRUCTURE AND CORTICAL FUNCTION ASSOCIATED WITH MANY CHRONIC PAIN CONDITIONS HAVE BEEN REPORTED IN THE PREFRONTAL CORTEX (PFC). THE PFC IS IMPLICATED IN PAIN-RELATED CO-MORBIDITIES SUCH AS DEPRESSION, ANXIETY AND IMPAIRED EMOTIONAL DECISION-MAKING ABILITY. WE RECENTLY REPORTED THAT THIS REGION IS SUBJECT TO SIGNIFICANT EPIGENETIC REPROGRAMMING FOLLOWING PERIPHERAL NERVE INJURY, AND NORMALIZATION OF PAIN-RELATED STRUCTURAL, FUNCTIONAL AND EPIGENETIC ABNORMALITIES IN THE PFC ARE ALL ASSOCIATED WITH EFFECTIVE PAIN REDUCTION. IN THIS STUDY, WE USED THE SPARED NERVE INJURY (SNI) MODEL OF NEUROPATHIC PAIN TO TEST THE HYPOTHESIS THAT PERIPHERAL NERVE INJURY TRIGGERS PERSISTENT LONG-LASTING CHANGES IN GENE EXPRESSION IN THE PFC, WHICH ALTER FUNCTIONAL GENE NETWORKS, THUS PROVIDING A POSSIBLE EXPLANATION FOR CHRONIC PAIN ASSOCIATED BEHAVIORS. RESULTS: SNI OR SHAM SURGERY WHERE PERFORMED IN MALE CD1 MICE AT THREE MONTHS OF AGE. SIX MONTHS AFTER INJURY, WE PERFORMED TRANSCRIPTOME-WIDE SEQUENCING (RNASEQ), WHICH REVEALED 1147 DIFFERENTIALLY REGULATED TRANSCRIPTS IN THE PFC IN NERVE-INJURED VS. CONTROL MICE. CHANGES IN GENE EXPRESSION OCCURRED ACROSS A NUMBER OF FUNCTIONAL GENE CLUSTERS ENCODING CARDINAL BIOLOGICAL PROCESSES AS REVEALED BY INGENUITY PATHWAY ANALYSIS. SIGNIFICANTLY ALTERED BIOLOGICAL PROCESSES INCLUDED NEUROLOGICAL DISEASE, SKELETAL MUSCULAR DISORDERS, BEHAVIOR, AND PSYCHOLOGICAL DISORDERS. SEVERAL OF THE CHANGES DETECTED BY RNASEQ WERE VALIDATED BY RT-QPCR AND INCLUDED TRANSCRIPTS WITH KNOWN ROLES IN CHRONIC PAIN AND/OR NEURONAL PLASTICITY INCLUDING THE NMDA RECEPTOR (GLUTAMATE RECEPTOR, IONOTROPIC, NMDA; GRIN1), NEURITE OUTGROWTH (ROUNDABOUT 3; ROBO3), GLIOSIS (GLIAL FIBRILLARY ACIDIC PROTEIN; GFAP), VESICULAR RELEASE (SYNAPTOTAGMIN 2; SYT2), AND NEURONAL EXCITABILITY (VOLTAGE-GATED SODIUM CHANNEL, TYPE I; SCN1A). CONCLUSIONS: THIS STUDY USED AN UNBIASED APPROACH TO DOCUMENT LONG-TERM ALTERATIONS IN GENE EXPRESSION IN THE BRAIN FOLLOWING PERIPHERAL NERVE INJURY. WE PROPOSE THAT THESE CHANGES ARE MAINTAINED AS A MEMORY OF AN INSULT THAT IS TEMPORALLY AND SPATIALLY DISTANT FROM THE INITIAL INJURY. 2013 20 3988 26 LONG-TERM WINDOW OF ISCHEMIC TOLERANCE: AN EVOLUTIONARILY CONSERVED FORM OF METABOLIC PLASTICITY REGULATED BY EPIGENETIC MODIFICATIONS? IN THE ABSENCE OF EFFECTIVE NEUROPROTECTIVE AGENTS IN THE CLINIC, ISCHEMIC AND PHARMACOLOGICAL PRECONDITIONING ARE GAINING INCREASED INTEREST IN THE FIELD OF CEREBRAL ISCHEMIA. OUR LAB RECENTLY REPORTED THAT RESVERATROL PRECONDITIONING AFFORDS TOLERANCE AGAINST A FOCAL CEREBRAL ISCHEMIC INSULT IN MICE THAT CAN LAST FOR AT LEAST 14 DAYS IN VIVO MAKING IT THE LONGEST WINDOW OF ISCHEMIC TOLERANCE DISCOVERED TO DATE BY A SINGLE ADMINISTRATION OF A PHARMACOLOGICAL AGENT. THE MECHANISM BEHIND THIS NOVEL EXTENDED WINDOW OF ISCHEMIC TOLERANCE REMAINS ELUSIVE. IN THE BELOW COMMENTARY WE DISCUSS POTENTIAL MECHANISMS THAT COULD EXPLAIN THIS NOVEL EXTENDED WINDOW OF ISCHEMIC TOLERANCE IN THE CONTEXT OF PREVIOUSLY IDENTIFIED WINDOWS AND THE KNOWN MECHANISMS BEHIND THEM. WE ALSO DRAW PARALLELS FROM THE FIELDS OF HIBERNATION AND HYPOXIA-TOLERANCE, WHICH ARE CHRONIC ADAPTATIONS TO SEVERE CONDITIONS OF HYPOXIA AND ISCHEMIA KNOWN TO BE MEDIATED BY A FORM OF METABOLIC DEPRESSION. WE ALSO BRIEFLY DISCUSS THE IMPORTANCE OF EPIGENETIC MODIFICATIONS IN MAINTAINING THIS DEPRESSED STATE OF METABOLISM. 2016