1 5262 125 PROLACTIN ACTIVATES IRF1 AND LEADS TO ALTERED BALANCE OF HISTONE ACETYLATION: IMPLICATIONS FOR SYSTEMIC LUPUS ERYTHEMATOSUS. OBJECTIVES: PROLACTIN IS KNOWN TO BE ASSOCIATED WITH AUTOIMMUNE DISEASE; HOWEVER, THE MECHANISMS ARE INCOMPLETELY UNDERSTOOD. PREVIOUS STUDIES HAVE HIGHLIGHTED THE EFFECTS ON B-CELL TOLERANCE AND MONOCYTE/MACROPHAGE ACTIVATION. ONE STUDY FOUND THAT PROLACTIN COULD ACTIVATE IRF1, A TRANSCRIPTION FACTOR IMPLICATED IN SLE AND INTERFERON RESPONSES. WE HYPOTHESIZED THAT PROLACTIN ELICITED TRANSCRIPTIONAL REGULATION THOUGH AN EPIGENETIC PROCESS RELATED TO IRF1 ACTIVATION IN MONOCYTES. THIS STUDY EXAMINED IRF1 ACTIVATION AND DOWNSTREAM EPIGENETIC EFFECTS.METHODS: PROTEIN ANALYSIS, QRT-PCR, AND CHIP ASSAYS WERE USED IN A HUMAN MONOCYTIC CELL LINE AND PRIMARY MONOCYTES TO DEFINE CHANGES RELATED TO ACUTE AND CHRONIC PROLACTIN EXPOSURE.RESULTS: WE FOUND THAT PROLACTIN ACUTELY INDUCED BOTH EXPRESSION AND ACTIVATION OF IRF1. PROLACTIN INDUCED INTERACTIONS OF IRF1 WITH THE HISTONE ACETYLTRANSFERASE CO-ACTIVATORS CBP AND P300. CHRONIC PROLACTIN INDUCED EXPRESSION OF MULTIPLE HISTONE MODIFYING PROTEINS AND GENES WITHIN THE INTERFERON SIGNATURE SUGGESTING THAT THE PROLONGED EXPOSURE TO PROLACTIN RESETS THE LANDSCAPE AND BALANCE OF CHROMATIN MODIFYING ENZYMES.CONCLUSION: THESE DATA PROVIDE INSIGHT INTO THE MECHANISM OF THE ASSOCIATION OF PROLACTIN WITH AUTOIMMUNITY. WE FOUND EFFECTS AT THE LEVEL OF EPIGENETICS, AN AREA NOT PREVIOUSLY EXPLORED. OUR DATA SUPPORT A ROLE FOR CHRONIC PROLACTIN REGULATING THE EXPRESSION OF GENES SETTING THE LANDSCAPE OF CHROMATIN MODIFYING ENZYMES AND DRIVING THE INTERFERON SIGNATURE. THIS NOVEL FINDING IS OF RELEVANCE IN SYSTEMIC LUPUS ERYTHEMATOSUS, WHERE CLINICAL EFFECTS OF HYPERPROLACTINEMIA HAVE BEEN RECOGNIZED. 2020 2 5136 27 POTENTIAL MECHANISMS LINKING PSYCHOLOGICAL STRESS TO BONE HEALTH. CHRONIC PSYCHOLOGICAL STRESS AFFECTS MANY BODY SYSTEMS, INCLUDING THE SKELETON, THROUGH VARIOUS MECHANISMS. THIS REVIEW AIMS TO PROVIDE AN OVERVIEW OF THE FACTORS MEDIATING THE RELATIONSHIP BETWEEN PSYCHOLOGICAL STRESS AND BONE HEALTH. THESE FACTORS CAN BE DIVIDED INTO PHYSIOLOGICAL AND BEHAVIOURAL CHANGES INDUCED BY PSYCHOLOGICAL STRESS. THE PHYSIOLOGICAL FACTORS INVOLVE ENDOCRINOLOGICAL CHANGES, SUCH AS INCREASED GLUCOCORTICOIDS, PROLACTIN, LEPTIN AND PARATHYROID HORMONE LEVELS AND REDUCED GONADAL HORMONES. LOW-GRADE INFLAMMATION AND HYPERACTIVATION OF THE SYMPATHETIC NERVOUS SYSTEM DURING PSYCHOLOGICAL STRESS ARE ALSO PHYSIOLOGICAL CHANGES DETRIMENTAL TO BONE HEALTH. THE BEHAVIOURAL CHANGES DURING MENTAL STRESS, SUCH AS ALTERED DIETARY PATTERN, CIGARETTE SMOKING, ALCOHOLISM AND PHYSICAL INACTIVITY, ALSO THREATEN THE SKELETAL SYSTEM. PSYCHOLOGICAL STRESS MAY BE PARTLY RESPONSIBLE FOR EPIGENETIC REGULATION OF SKELETAL DEVELOPMENT. IT MAY ALSO MEDIATE THE RELATIONSHIP BETWEEN SOCIOECONOMIC STATUS AND BONE HEALTH. HOWEVER, MORE DIRECT EVIDENCE IS REQUIRED TO PROVE THESE HYPOTHESES. IN CONCLUSION, CHRONIC PSYCHOLOGICAL STRESS SHOULD BE RECOGNISED AS A RISK FACTOR OF OSTEOPOROSIS AND STRESS-COPING METHODS SHOULD BE INCORPORATED AS PART OF THE COMPREHENSIVE OSTEOPOROSIS-PREVENTING STRATEGY. 2021 3 3093 33 GENOMIC AND EPIGENOMIC RESPONSES TO CHRONIC STRESS INVOLVE MIRNA-MEDIATED PROGRAMMING. STRESS REPRESENTS A CRITICAL INFLUENCE ON MOTOR SYSTEM FUNCTION AND HAS BEEN SHOWN TO IMPAIR MOVEMENT PERFORMANCE. WE HYPOTHESIZED THAT STRESS-INDUCED MOTOR IMPAIRMENTS ARE DUE TO BRAIN-SPECIFIC CHANGES IN MIRNA AND PROTEIN-ENCODING GENE EXPRESSION. HERE WE SHOW A CAUSAL LINK BETWEEN STRESS-INDUCED MOTOR IMPAIRMENT AND ASSOCIATED GENETIC AND EPIGENETIC RESPONSES IN RELEVANT CENTRAL MOTOR AREAS IN A RAT MODEL. EXPOSURE TO TWO WEEKS OF MILD RESTRAINT STRESS ALTERED THE EXPRESSION OF 39 GENES AND NINE MIRNAS IN THE CEREBELLUM. IN LINE WITH PERSISTENT BEHAVIOURAL IMPAIRMENTS, SOME CHANGES IN GENE AND MIRNA EXPRESSION WERE RESISTANT TO RECOVERY FROM STRESS. INTERESTINGLY, STRESS UP-REGULATED THE EXPRESSION OF ADIPOQ AND PROLACTIN RECEPTOR MRNAS IN THE CEREBELLUM. STRESS ALSO ALTERED THE EXPRESSION OF PRLR, MIR-186, AND MIR-709 IN HIPPOCAMPUS AND PREFRONTAL CORTEX. IN ADDITION, OUR FINDINGS DEMONSTRATE THAT MIR-186 TARGETS THE GENE EPS15. FURTHERMORE, WE FOUND AN AGE-DEPENDENT INCREASE IN EPHRINB3 AND GABAA4 RECEPTORS. THESE DATA SHOW THAT EVEN MILD STRESS RESULTS IN SUBSTANTIAL GENOMIC AND EPIGENOMIC CHANGES INVOLVING MIRNA EXPRESSION AND ASSOCIATED GENE TARGETS IN THE MOTOR SYSTEM. THESE FINDINGS SUGGEST A CENTRAL ROLE OF MIRNA-REGULATED GENE EXPRESSION IN THE STRESS RESPONSE AND IN ASSOCIATED NEUROLOGICAL FUNCTION. 2012 4 1149 33 CONNECTING THE IMMUNE SYSTEM, SYSTEMIC CHRONIC INFLAMMATION AND THE GUT MICROBIOME: THE ROLE OF SEX. UNRESOLVED LOW GRADE SYSTEMIC INFLAMMATION REPRESENTS THE UNDERLYING PATHOLOGICAL MECHANISM DRIVING IMMUNE AND METABOLIC PATHWAYS INVOLVED IN AUTOIMMUNE DISEASES (AID). MECHANISTIC STUDIES IN ANIMAL MODELS OF AID AND OBSERVATIONAL STUDIES IN PATIENTS HAVE FOUND ALTERATIONS IN GUT MICROBIOTA COMMUNITIES AND THEIR METABOLITES, SUGGESTING A MICROBIAL CONTRIBUTION TO THE ONSET OR PROGRESSION OF AID. THE GUT MICROBIOTA AND ITS METABOLITES HAVE BEEN SHOWN TO INFLUENCE IMMUNE FUNCTIONS AND IMMUNE HOMEOSTASIS BOTH WITHIN THE GUT AND SYSTEMATICALLY. MICROBIAL DERIVED-SHORT CHAIN FATTY ACID (SCFA) AND BIO-TRANSFORMED BILE ACID (BA) HAVE BEEN SHOWN TO INFLUENCE THE IMMUNE SYSTEM ACTING AS LIGANDS SPECIFIC CELL SIGNALING RECEPTORS LIKE GPRCS, TGR5 AND FXR, OR VIA EPIGENETIC PROCESSES. SIMILARLY, INTESTINAL PERMEABILITY (LEAKY GUT) AND BACTERIAL TRANSLOCATION ARE IMPORTANT CONTRIBUTORS TO CHRONIC SYSTEMIC INFLAMMATION AND, WITHOUT REPAIR OF THE INTESTINAL BARRIER, MIGHT REPRESENT A CONTINUOUS INFLAMMATORY STIMULUS CAPABLE OF TRIGGERING AUTOIMMUNE PROCESSES. RECENT STUDIES INDICATE GENDER-SPECIFIC DIFFERENCES IN IMMUNITY, WITH THE GUT MICROBIOTA SHAPING AND BEING CONCOMITANTLY SHAPED BY THE HORMONAL MILIEU GOVERNING DIFFERENCES BETWEEN THE SEXES. A BI-DIRECTIONAL CROSS-TALK BETWEEN MICROBIOTA AND THE ENDOCRINE SYSTEM IS EMERGING WITH BACTERIA BEING ABLE TO PRODUCE HORMONES (E.G. SEROTONIN, DOPAMINE AND SOMATOSTATINE), RESPOND TO HOST HORMONES (E.G. ESTROGENS) AND REGULATE HOST HORMONES' HOMEOSTASIS (E.G BY INHIBITING GENE PROLACTIN TRANSCRIPTION OR CONVERTING GLUCOCORTICOIDS TO ANDROGENS). WE REVIEW HEREIN HOW GUT MICROBIOTA AND ITS METABOLITES REGULATE IMMUNE FUNCTION, INTESTINAL PERMEABILITY AND POSSIBLY AID PATHOLOGICAL PROCESSES. FURTHER, WE DESCRIBE THE DYSBIOSIS WITHIN THE GUT MICROBIOTA OBSERVED IN DIFFERENT AID AND SPECULATE HOW RESTORING GUT MICROBIOTA COMPOSITION AND ITS REGULATORY METABOLITES BY DIETARY INTERVENTION INCLUDING PREBIOTICS AND PROBIOTICS COULD HELP IN PREVENTING OR AMELIORATING AID. FINALLY, WE SUGGEST THAT, GIVEN CONSISTENT OBSERVATIONS OF MICROBIOTA DYSBIOSIS ASSOCIATED WITH AID AND THE ABILITY OF SCFA AND BA TO REGULATE INTESTINAL PERMEABILITY AND INFLAMMATION, FURTHER MECHANISTIC STUDIES, EXAMINING HOW DIETARY MICROBIOTA MODULATION CAN PROTECT AGAINST AID, HOLD CONSIDERABLE POTENTIAL TO TACKLE INCREASED INCIDENCE OF AID AT THE POPULATION LEVEL. 2018 5 3092 24 GENOMIC AND EPIGENOMIC MECHANISMS OF GLUCOCORTICOIDS IN THE BRAIN. FOLLOWING THE DISCOVERY OF GLUCOCORTICOID RECEPTORS IN THE HIPPOCAMPUS AND OTHER BRAIN REGIONS, RESEARCH HAS FOCUSED ON UNDERSTANDING THE EFFECTS OF GLUCOCORTICOIDS IN THE BRAIN AND THEIR ROLE IN REGULATING EMOTION AND COGNITION. GLUCOCORTICOIDS ARE ESSENTIAL FOR ADAPTATION TO STRESSORS (ALLOSTASIS) AND IN MALADAPTATION RESULTING FROM ALLOSTATIC LOAD AND OVERLOAD. ALLOSTATIC OVERLOAD, WHICH CAN OCCUR DURING CHRONIC STRESS, CAN RESHAPE THE HYPOTHALAMIC-PITUITARY-ADRENAL AXIS THROUGH EPIGENETIC MODIFICATION OF GENES IN THE HIPPOCAMPUS, HYPOTHALAMUS AND OTHER STRESS-RESPONSIVE BRAIN REGIONS. GLUCOCORTICOIDS EXERT THEIR EFFECTS ON THE BRAIN THROUGH GENOMIC MECHANISMS THAT INVOLVE BOTH GLUCOCORTICOID RECEPTORS AND MINERALOCORTICOID RECEPTORS DIRECTLY BINDING TO DNA, AS WELL AS BY NON-GENOMIC MECHANISMS. FURTHERMORE, GLUCOCORTICOIDS SYNERGIZE BOTH GENOMICALLY AND NON-GENOMICALLY WITH NEUROTRANSMITTERS, NEUROTROPHIC FACTORS, SEX HORMONES AND OTHER STRESS MEDIATORS TO SHAPE AN ORGANISM'S PRESENT AND FUTURE RESPONSES TO A STRESSFUL ENVIRONMENT. HERE, WE DISCUSS THE MECHANISMS OF GLUCOCORTICOID ACTION IN THE BRAIN AND REVIEW HOW GLUCOCORTICOIDS INTERACT WITH STRESS MEDIATORS IN THE CONTEXT OF ALLOSTASIS, ALLOSTATIC LOAD AND STRESS-INDUCED NEUROPLASTICITY. 2017 6 5970 19 TESTOSTERONE ACTS WITHIN THE MEDIAL AMYGDALA OF RATS TO REDUCE INNATE FEAR TO PREDATOR ODOR AKIN TO THE EFFECTS OF TOXOPLASMA GONDII INFECTION. RATS INFECTED WITH THE PROTOZOAN TOXOPLASMA GONDII EXHIBIT A REDUCED AVERSION TO CAT ODOR. THIS BEHAVIORAL CHANGE IS THOUGHT TO INCREASE TROPHIC TRANSMISSION OF THE PARASITE. INFECTED MALE RATS ALSO SHOW A GREATER TESTICULAR SYNTHESIS OF TESTOSTERONE AND EPIGENETIC CHANGE IN ARGININE VASOPRESSIN WITHIN THE MEDIAL AMYGDALA. HERE, WE SHOW THAT EXOGENOUS SUPPLY OF TESTOSTERONE WITHIN MEA OF UNINFECTED CASTRATES RECAPITULATES REDUCTION IN INNATE FEAR AKIN TO BEHAVIORAL CHANGE ATTRIBUTED TO THE PARASITE. WE ALSO SHOW THAT CASTRATION POST ESTABLISHMENT OF CHRONIC INFECTION PRECLUDES CHANGES IN FEAR AND MEDIAL AMYGDALA ARGININE VASOPRESSIN IN THE INFECTED MALE RATS. THESE OBSERVATIONS SUPPORT THE ROLE OF GONADAL HORMONES AND PURSUANT NEUROENDOCRINE CHANGES IN MEDIATING THE LOSS OF FEAR IN THE INFECTED RATS. THIS WORK ALSO DEMONSTRATES THAT TESTOSTERONE ACTING SPECIFICALLY WITHIN THE MEDIAL AMYGDALA SUFFICIENTLY EXPLAINS REDUCED DEFENSIVE BEHAVIORS OFTEN OBSERVED DURING THE APPETITIVE COMPONENT OF REPRODUCTIVE BEHAVIORS. 2020 7 235 21 ADDING FUEL TO THE FIRE: THE IMPACT OF STRESS ON THE AGEING BRAIN. BOTH AGEING AND CHRONIC STRESS ARE ASSOCIATED WITH ALTERED BRAIN PLASTICITY, DYSREGULATION OF THE IMMUNE SYSTEM, AND AN INCREASED RISK OF DEVELOPING BRAIN DISORDERS; ALL OF WHICH HAVE CONSEQUENCES FOR COGNITIVE AND EMOTIONAL PROCESSING. HERE WE EXAMINE THE SIMILARITIES BETWEEN BEHAVIOURAL CHANGES DURING AGEING AND STRESS ALTERED BEHAVIOURS (ANXIETY, DEPRESSIVE-LIKE BEHAVIOUR, COGNITION, AND SOCIABILITY) IN RODENTS AND HUMANS. THE MOLECULAR MECHANISMS HYPOTHESISED TO MEDIATE AGE-RELATED CHANGES IN BRAIN FUNCTION INCLUDING DYSFUNCTION OF THE HYPOTHALAMIC-PITUITARY-ADRENAL (HPA) AXIS, DYSREGULATION OF NEUROTRANSMISSION AND NEUROTROPHIC FACTOR SIGNALLING, INCREASED INFLAMMATORY STATE, GENETIC AND EPIGENETIC CHANGES, OXIDATIVE STRESS, METABOLIC CHANGES, AND CHANGES IN THE MICROBIOTA-GUT-BRAIN AXIS ARE DISCUSSED. FINALLY, WE EXPLORE HOW THE ALREADY STRESSED AGED BRAIN PSYCHOLOGICALLY AND PHYSIOLOGICALLY RESPONDS TO EXTERNAL STRESSORS. 2015 8 2144 25 EPIGENETIC LANDSCAPE OF STRESS SURFEIT DISORDERS: KEY ROLE FOR DNA METHYLATION DYNAMICS. CHRONIC EXPOSURE TO STRESS THROUGHOUT LIFESPAN ALTERS BRAIN STRUCTURE AND FUNCTION, INDUCING A MALADAPTIVE RESPONSE TO ENVIRONMENTAL STIMULI, THAT CAN CONTRIBUTE TO THE DEVELOPMENT OF A PATHOLOGICAL PHENOTYPE. STUDIES HAVE SHOWN THAT HYPOTHALAMIC-PITUITARY-ADRENAL (HPA) AXIS DYSFUNCTION IS ASSOCIATED WITH VARIOUS NEUROPSYCHIATRIC DISORDERS, INCLUDING MAJOR DEPRESSIVE, ALCOHOL USE AND POST-TRAUMATIC STRESS DISORDERS. DOWNSTREAM ACTORS OF THE HPA AXIS, GLUCOCORTICOIDS ARE CRITICAL MEDIATORS OF THE STRESS RESPONSE AND EXERT THEIR FUNCTION THROUGH SPECIFIC RECEPTORS, I.E., THE GLUCOCORTICOID RECEPTOR (GR), HIGHLY EXPRESSED IN STRESS/REWARD-INTEGRATIVE PATHWAYS. GRS ARE LIGAND-ACTIVATED TRANSCRIPTION FACTORS THAT RECRUIT EPIGENETIC ACTORS TO REGULATE GENE EXPRESSION VIA DNA METHYLATION, ALTERING CHROMATIN STRUCTURE AND THUS SHAPING THE RESPONSE TO STRESS. THE DYNAMIC INTERPLAY BETWEEN STRESS RESPONSE AND EPIGENETIC MODIFIERS SUGGEST DNA METHYLATION PLAYS A KEY ROLE IN THE DEVELOPMENT OF STRESS SURFEIT DISORDERS. 2021 9 1877 15 EMERGING ROLES OF EPIGENETIC MECHANISMS IN THE ENDURING EFFECTS OF EARLY-LIFE STRESS AND EXPERIENCE ON LEARNING AND MEMORY. EPIGENETIC MECHANISMS ARE INVOLVED IN PROGRAMMING GENE EXPRESSION THROUGHOUT DEVELOPMENT. IN ADDITION, THEY ARE KEY CONTRIBUTORS TO THE PROCESSES BY WHICH EARLY-LIFE EXPERIENCE FINE-TUNES THE EXPRESSION LEVELS OF KEY NEURONAL GENES, GOVERNING LEARNING AND MEMORY THROUGHOUT LIFE. HERE WE DESCRIBE THE LONG-LASTING, BI-DIRECTIONAL EFFECTS OF EARLY-LIFE EXPERIENCE ON LEARNING AND MEMORY. WE DISCUSS HOW ENRICHED POSTNATAL EXPERIENCE ENDURINGLY AUGMENTS SPATIAL LEARNING, AND HOW CHRONIC EARLY-LIFE STRESS RESULTS IN PERSISTENT AND PROGRESSIVE DEFICITS IN THE STRUCTURE AND FUNCTION OF HIPPOCAMPAL NEURONS. THE EXISTING AND EMERGING ROLES OF EPIGENETIC MECHANISMS IN THESE FUNDAMENTAL NEUROPLASTICITY PHENOMENA ARE ILLUSTRATED. 2011 10 3463 26 HYPOTHALAMIC-PITUITARY-ADRENAL AND HYPOTHALAMIC-PITUITARY-GONADAL AXES: SEX DIFFERENCES IN REGULATION OF STRESS RESPONSIVITY. GONADAL HORMONES PLAY A KEY ROLE IN THE ESTABLISHMENT, ACTIVATION, AND REGULATION OF THE HYPOTHALAMIC-PITUITARY-ADRENAL (HPA) AXIS. BY INFLUENCING THE RESPONSE AND SENSITIVITY TO RELEASING FACTORS, NEUROTRANSMITTERS, AND HORMONES, GONADAL STEROIDS HELP ORCHESTRATE THE GAIN OF THE HPA AXIS TO FINE-TUNE THE LEVELS OF STRESS HORMONES IN THE GENERAL CIRCULATION. FROM EARLY LIFE TO ADULTHOOD, GONADAL STEROIDS CAN DIFFERENTIALLY AFFECT THE HPA AXIS, RESULTING IN SEX DIFFERENCES IN THE RESPONSIVITY OF THIS AXIS. THE HPA AXIS INFLUENCES MANY PHYSIOLOGICAL FUNCTIONS MAKING AN ORGANISM'S RESPONSE TO CHANGES IN THE ENVIRONMENT APPROPRIATE FOR ITS REPRODUCTIVE STATUS. ALTHOUGH THE ACUTE HPA RESPONSE TO STRESSORS IS A BENEFICIAL RESPONSE, CONSTANT ACTIVATION OF THIS CIRCUITRY BY CHRONIC OR TRAUMATIC STRESSFUL EPISODES MAY LEAD TO A DYSREGULATION OF THE HPA AXIS AND CAUSE PATHOLOGY. COMPARED TO MALES, FEMALE MICE AND RATS SHOW A MORE ROBUST HPA AXIS RESPONSE, AS A RESULT OF CIRCULATING ESTRADIOL LEVELS WHICH ELEVATE STRESS HORMONE LEVELS DURING NON-THREATENING SITUATIONS, AND DURING AND AFTER STRESSORS. FLUCTUATING LEVELS OF GONADAL STEROIDS IN FEMALES ACROSS THE ESTROUS CYCLE ARE A MAJOR FACTOR CONTRIBUTING TO SEX DIFFERENCES IN THE ROBUSTNESS OF HPA ACTIVITY IN FEMALES COMPARED TO MALES. MOREOVER, GONADAL STEROIDS MAY ALSO CONTRIBUTE TO EPIGENETIC AND ORGANIZATIONAL INFLUENCES ON THE HPA AXIS EVEN BEFORE PUBERTY. CORRESPONDINGLY, CROSSTALK BETWEEN THE HYPOTHALAMIC-PITUITARY-GONADAL (HPG) AND HPA AXES COULD LEAD TO ABNORMALITIES OF STRESS RESPONSES. IN HUMANS, A DYSREGULATED STRESS RESPONSE IS ONE OF THE MOST COMMON SYMPTOMS SEEN ACROSS MANY NEUROPSYCHIATRIC DISORDERS, AND AS A RESULT, SUCH INTERACTIONS MAY EXACERBATE PERIPHERAL PATHOLOGIES. IN THIS REVIEW, WE DISCUSS THE HPA AND HPG AXES AND REVIEW HOW GONADAL STEROIDS INTERACT WITH THE HPA AXIS TO REGULATE THE STRESS CIRCUITRY DURING ALL STAGES IN LIFE. 2017 11 5051 36 PHARMACOLOGICAL RESCUE OF NOCICEPTIVE HYPERSENSITIVITY AND OXYTOCIN ANALGESIA IMPAIRMENT IN A RAT MODEL OF NEONATAL MATERNAL SEPARATION. OXYTOCIN (OT), KNOWN FOR ITS NEUROHORMONAL EFFECTS AROUND BIRTH, HAS RECENTLY BEEN SUGGESTED FOR BEING A CRITICAL DETERMINANT IN NEURODEVELOPMENTAL DISORDERS. THIS HYPOTHALAMIC NEUROPEPTIDE EXERTS A POTENT ANALGESIC EFFECT THROUGH AN ACTION ON THE NOCICEPTIVE SYSTEM. THIS ENDOGENOUS CONTROL OF PAIN HAS AN IMPORTANT ADAPTIVE VALUE BUT MIGHT BE ALTERED BY EARLY LIFE STRESS, POSSIBLY CONTRIBUTING TO ITS LONG-TERM CONSEQUENCES ON PAIN RESPONSES AND ASSOCIATED COMORBIDITIES. WE TESTED THIS HYPOTHESIS USING A RAT MODEL OF NEONATAL MATERNAL SEPARATION (NMS) KNOWN TO INDUCE LONG-TERM CONSEQUENCES ON SEVERAL BRAIN FUNCTIONS INCLUDING CHRONIC STRESS, ANXIETY, ALTERED SOCIAL BEHAVIOR, AND VISCERAL HYPERSENSITIVITY. WE FOUND THAT ADULT RATS WITH A HISTORY OF NMS WERE HYPERSENSITIVE TO NOXIOUS MECHANICAL/THERMAL HOT STIMULI AND TO INFLAMMATORY PAIN. WE FAILED TO OBSERVE OT RECEPTOR-MEDIATED STRESS-INDUCED ANALGESIA AND OT ANTIHYPERALGESIA AFTER CARRAGEENAN INFLAMMATION. THESE ALTERATIONS WERE PARTIALLY RESCUED IF NMS PUPS WERE TREATED BY INTRAPERITONEAL DAILY INJECTION DURING NMS WITH OT OR ITS DOWNSTREAM SECOND MESSENGER ALLOPREGNANOLONE. THE INVOLVEMENT OF EPIGENETIC CHANGES IN THESE ALTERATIONS WAS CONFIRMED SINCE NEONATAL TREATMENT WITH THE HISTONE DEACETYLASE INHIBITOR SAHA, NOT ONLY NORMALIZED NOCICEPTIVE SENSITIVITIES BUT ALSO RESTORED OT RECEPTOR-MEDIATED STRESS-INDUCED ANALGESIA AND THE ENDOGENOUS ANTIHYPERALGESIA IN INFLAMED NMS RATS. THERE IS GROWING EVIDENCE IN THE LITERATURE THAT EARLY LIFE STRESS MIGHT IMPAIR THE NOCICEPTIVE SYSTEM ONTOGENY AND FUNCTION. THIS STUDY SUGGESTS THAT THESE ALTERATIONS MIGHT BE RESTORED WHILE STIMULATING OT RECEPTOR SIGNALING OR HISTONE DEACETYLASE INHIBITORS, USING MOLECULES THAT ARE CURRENTLY AVAILABLE OR PART OF CLINICAL TRIALS FOR OTHER PATHOLOGIES. 2018 12 4402 23 MODULATION OF NOCICEPTION BY SOCIAL FACTORS IN RODENTS: CONTRIBUTION OF THE OPIOID SYSTEM. RATIONALE: THE OPIOID SYSTEM IS INVOLVED IN THE REGULATION OF SEVERAL BEHAVIORAL AND PHYSIOLOGICAL RESPONSES, CONTROLLING PAIN, REWARD, AND ADDICTIVE BEHAVIORS. OPIOID ADMINISTRATION, DEPENDING ON DRUGS AND DOSES, USUALLY AFFECTS SOCIABILITY REDUCING INTERACTIONS BETWEEN CONSPECIFICS, WHEREAS SOME AFFILIATIVE BEHAVIORS SUCH AS SEXUAL ACTIVITY, SOCIAL GROOMING, AND PLAY BEHAVIOR INCREASE THE ENDOGENOUS OPIOID ACTIVITY. OBJECTIVES: THE POSSIBLE INTERACTION BETWEEN ENDOGENOUS OPIOIDS RELEASED DURING SOCIO/SEXUAL BEHAVIOR AND THEIR ANALGESIC EFFECT ON PAIN RESPONSE IS REVIEWED IN THE RODENT LITERATURE. RESULTS: DIRECT EVIDENCE FOR SOCIALLY MEDIATED OPIOID CHANGES RESULTING IN INCREASE IN NOCICEPTIVE THRESHOLD DERIVES FROM STUDIES EXPLORING THE EFFECTS OF DEFEAT EXPERIENCES, SOCIAL ISOLATION, MATERNAL, SEXUAL BEHAVIOR, AND SOCIAL REUNION AMONG KIN OR FAMILIAR ANIMALS IN LABORATORY RODENTS. INDIRECT EVIDENCE FOR ENDOGENOUS ACTIVATION OF THE OPIOID SYSTEM, POSSIBLY AFFECTING PAIN SENSITIVITY, DERIVES FROM STUDIES INVESTIGATING THE RELEVANCE OF NATURAL SOCIAL REWARD USING THE CONDITIONED PLACE PREFERENCE PROTOCOLS OR ANALYZING ULTRASONIC VOCALIZATIONS ASSOCIATED TO POSITIVE AFFECTIVE CONTEXTS. FINALLY, GENETIC AND EPIGENETIC FACTORS THAT AFFECT THE OPIOID SYSTEM DURING DEVELOPMENT ARE REPORTED TO BE INVOLVED IN MODULATING THE RESPONSE TO SOCIAL STIMULI AS WELL AS NOCICEPTION. CONCLUSIONS: ALL STUDIES HIGHLIGHT THE RELEVANCE OF AFFILIATIVE CONTACT BEHAVIOR BETWEEN CONSPECIFICS THAT IS RESPONSIBLE FOR THE ACTIVATION OF THE ENDOGENOUS MU-OPIOID SYSTEM, INDUCING NOCICEPTIVE THRESHOLD INCREASE. 2012 13 5820 34 STRESS DYNAMICALLY REGULATES BEHAVIOR AND GLUTAMATERGIC GENE EXPRESSION IN HIPPOCAMPUS BY OPENING A WINDOW OF EPIGENETIC PLASTICITY. EXCITATORY AMINO ACIDS PLAY A KEY ROLE IN BOTH ADAPTIVE AND DELETERIOUS EFFECTS OF STRESSORS ON THE BRAIN, AND DYSREGULATED GLUTAMATE HOMEOSTASIS HAS BEEN ASSOCIATED WITH PSYCHIATRIC AND NEUROLOGICAL DISORDERS. HERE, WE ELUCIDATE MECHANISMS OF EPIGENETIC PLASTICITY IN THE HIPPOCAMPUS IN THE INTERACTIONS BETWEEN A HISTORY OF CHRONIC STRESS AND FAMILIAR AND NOVEL ACUTE STRESSORS THAT ALTER EXPRESSION OF ANXIETY- AND DEPRESSIVE-LIKE BEHAVIORS. WE DEMONSTRATE THAT ACUTE RESTRAINT AND ACUTE FORCED SWIM STRESSORS INDUCE DIFFERENTIAL EFFECTS ON THESE BEHAVIORS IN NAIVE MICE AND IN MICE WITH A HISTORY OF CHRONIC-RESTRAINT STRESS (CRS). THEY REVEAL A KEY ROLE FOR EPIGENETIC UP- AND DOWN-REGULATION OF THE PUTATIVE PRESYNAPTIC TYPE 2 METABOTROPIC GLUTAMATE (MGLU2) RECEPTORS AND THE POSTSYNAPTIC NR1/NMDA RECEPTORS IN THE HIPPOCAMPUS AND PARTICULARLY IN THE DENTATE GYRUS (DG), A REGION OF ACTIVE NEUROGENESIS AND A TARGET OF ANTIDEPRESSANT TREATMENT. WE SHOW CHANGES IN DG LONG-TERM POTENTIATION (LTP) THAT PARALLEL BEHAVIORAL RESPONSES, WITH HABITUATION TO THE SAME ACUTE RESTRAINT STRESSOR AND SENSITIZATION TO A NOVEL FORCED-SWIM STRESSOR. IN WT MICE AFTER CRS AND IN UNSTRESSED MICE WITH A BDNF LOSS-OF-FUNCTION ALLELE (BDNF VAL66MET), WE SHOW THAT THE EPIGENETIC ACTIVATOR OF HISTONE ACETYLATION, P300, PLAYS A PIVOTAL ROLE IN THE DYNAMIC UP- AND DOWN-REGULATION OF MGLU2 IN HIPPOCAMPUS VIA HISTONE-3-LYSINE-27-ACETYLATION (H3K27AC) WHEN ACUTE STRESSORS ARE APPLIED. THESE HIPPOCAMPAL RESPONSES REVEAL A WINDOW OF EPIGENETIC PLASTICITY THAT MAY BE USEFUL FOR TREATMENT OF DISORDERS IN WHICH GLUTAMATERGIC TRANSMISSION IS DYSREGULATED. 2015 14 6267 30 THE NEUROENDOCRINOLOGY OF STRESS: A NEVER ENDING STORY. EVOLUTIONARY SUCCESS DEPENDS ON OUR ABILITY TO ADAPT TO CHANGING CIRCUMSTANCES. THE NEUROENDOCRINE RESPONSE TO STRESS IS AN EXCELLENT EXAMPLE OF A PLASTIC SYSTEM THAT RESPONDS TO THREATS TO HOMEOSTASIS AND ALTERS ITS OUTPUT TO MEET CURRENT AND EXPECTED FUTURE DEMANDS. AT THE LEVEL OF THE HYPOTHALAMUS, THE CORTICOTROPH SECRETAGOGUES CORTICOTROPHIN-RELEASING HORMONE (CRH) AND ARGININE VASOPRESSIN (AVP) RESPOND RAPIDLY TO AN ACUTE STRESSOR BUT, FOLLOWING CHRONIC STRESS, THEY ADAPT WITH A REDUCTION OF CRH BUT A MAJOR INCREASE IN AVP. THE RELEASE OF CRH AND AVP ACTIVATES PRO-OPIOMELANOCORTIN IN ANTERIOR PITUITARY CORTICOTROPH CELLS AND THE RELEASE OF ADRENOCORTICOTROPHIC HORMONE INTO PERIPHERAL BLOOD FROM WHERE IT TARGETS RECEPTORS IN THE ADRENAL CORTEX TO RELEASE GLUCOCORTICOID HORMONES. THESE HORMONES (I.E. CORTICOSTERONE IN THE RAT AND CORTISOL IN MAN) ARE RELEASED IN A PULSATILE ULTRADIAN PATTERN WHICH DEFINES THE NORMAL CIRCADIAN RHYTHM. THE FREQUENCY OF THE PULSES IS INCREASED UNDER STATES OF CHRONIC STRESS, AND IN RATS WITH GENETICALLY DETERMINED HYPER-RESPONSIVENESS OF THE HYPOTHALAMIC-PITUITARY-ADRENAL AXIS. INTERESTINGLY, NEONATAL INFLUENCES CAN ALSO PROGRAMME ALTERATIONS IN ULTRADIAN RHYTHMICITY, IMPLICATING EPIGENETIC FACTORS IN ITS REGULATION. AT THE LEVEL OF TISSUE RECEPTORS, THE ALTERATION IN PATTERN OF GLUCOCORTICOID ULTRADIAN RHYTHM HAS DIFFERENTIAL EFFECTS ON MINERALOCORTICOID RECEPTOR AND GLUCOCORTICOID RECEPTOR (GR) BINDING TO DNA AND OFFERS A MECHANISM FOR TISSUE SPECIFIC RESPONSES TO ALTERED GLUCOCORTICOID DYNAMICS. THE EFFECTS OF NEONATAL EXPERIENCE ARE NOT ONLY SEEN AT THE LEVEL OF CRH AND GR REGULATION, BUT ALSO ARE EVIDENT IN BEHAVIOURAL RESPONSES TO STRESS AND IN THE RESPONSIVENESS OF BRAIN STEM SEROTONERGIC PATHWAYS, AS MEASURED BY TRYPTOPHAN HYDROXYLASE MRNA IN THE BRAIN STEM. 2008 15 4118 28 MECHANISMS OF BRAIN GLUCOCORTICOID RESISTANCE IN STRESS-INDUCED PSYCHOPATHOLOGIES. EXPOSURE TO STRESS ACTIVATES THE HYPOTHALAMIC-PITUITARY-ADRENAL AXIS AND LEADS TO INCREASED LEVELS OF GLUCOCORTICOID (GC) HORMONES. PROLONGED ELEVATION OF GC LEVELS CAUSES NEURONAL DYSFUNCTION, DECREASES THE DENSITY OF SYNAPSES, AND IMPAIRS NEURONAL PLASTICITY. DECREASED SENSITIVITY TO GLUCOCORTICOIDS (GLUCOCORTICOID RESISTANCE) THAT DEVELOPS AS A RESULT OF CHRONIC STRESS IS ONE OF THE CHARACTERISTIC FEATURES OF STRESS-INDUCED PSYCHOPATHOLOGIES. IN THIS ARTICLE, WE REVIEWED THE PUBLISHED DATA ON PROPOSED MOLECULAR MECHANISMS THAT CONTRIBUTE TO THE DEVELOPMENT OF GLUCOCORTICOID RESISTANCE IN BRAIN, INCLUDING CHANGES IN THE EXPRESSION OF THE GLUCOCORTICOID RECEPTOR (GR) GENE, BIOSYNTHESIS OF GR ISOFORMS, AND GR POSTTRANSLATIONAL MODIFICATIONS. WE ALSO PRESENT DATA ON ALTERATIONS IN THE EXPRESSION OF THE FKBP5 GENE ENCODING THE MAIN COMPONENT OF CELL ULTRA-SHORT NEGATIVE FEEDBACK LOOP OF GC SIGNALING REGULATION. RECENT DISCOVERIES ON STRESS- AND GR-INDUCED CHANGES IN EPIGENETIC MODIFICATION PATTERNS AS WELL AS NORMALIZING ACTION OF ANTIDEPRESSANTS ARE DISCUSSED. GR AND FKBP5 GENE POLYMORPHISMS ASSOCIATED WITH STRESS-INDUCED PSYCHOPATHOLOGIES ARE DESCRIBED, AND THEIR ROLE IN GLUCOCORTICOID RESISTANCE IS DISCUSSED. 2017 16 4420 26 MOLECULAR AND EPIGENETIC MECHANISMS FOR THE COMPLEX EFFECTS OF STRESS ON SYNAPTIC PHYSIOLOGY AND COGNITIVE FUNCTIONS. EVIDENCE OVER THE PAST DECADES HAS FOUND THAT STRESS, PARTICULARLY THROUGH THE CORTICOSTERONE STRESS HORMONES, PRODUCES COMPLEX CHANGES IN GLUTAMATERGIC SIGNALING IN PREFRONTAL CORTEX, WHICH LEADS TO THE ALTERATION OF COGNITIVE PROCESSES MEDICATED BY THIS BRAIN REGION. INTERESTINGLY, THE EFFECTS OF STRESS ON GLUTAMATERGIC TRANSMISSION APPEAR TO BE "U-SHAPED," DEPENDING UPON THE DURATION AND SEVERITY OF THE STRESSOR. THESE BIPHASIC EFFECTS OF ACUTE VS CHRONIC STRESS REPRESENT THE ADAPTIVE VS MALADAPTIVE RESPONSES TO STRESSFUL STIMULI. ANIMAL STUDIES SUGGEST THAT THE STRESS-INDUCED MODULATION OF EXCITATORY SYNAPTIC TRANSMISSION INVOLVES CHANGES IN PRESYNAPTIC GLUTAMATE RELEASE, POSTSYNAPTIC GLUTAMATE RECEPTOR MEMBRANE TRAFFICKING AND DEGRADATION, SPINE STRUCTURE AND CYTOSKELETON NETWORK, AND EPIGENETIC CONTROL OF GENE EXPRESSION. THIS REVIEW WILL DISCUSS CURRENT FINDINGS ON THE KEY MOLECULES INVOLVED IN THE STRESS-INDUCED REGULATION OF PREFRONTAL CORTEX SYNAPTIC PHYSIOLOGY AND PREFRONTAL CORTEX-MEDIATED FUNCTIONS. UNDERSTANDING THE MOLECULAR AND EPIGENETIC MECHANISMS THAT UNDERLIE THE COMPLEX EFFECTS OF STRESS WILL HELP TO DEVELOP NOVEL STRATEGIES TO COPE WITH STRESS-RELATED MENTAL DISORDERS. 2017 17 23 29 60 YEARS OF NEUROENDOCRINOLOGY: REDEFINING NEUROENDOCRINOLOGY: STRESS, SEX AND COGNITIVE AND EMOTIONAL REGULATION. THE DISCOVERY OF STEROID HORMONE RECEPTORS IN BRAIN REGIONS THAT MEDIATE EVERY ASPECT OF BRAIN FUNCTION HAS BROADENED THE DEFINITION OF 'NEUROENDOCRINOLOGY' TO INCLUDE THE RECIPROCAL COMMUNICATION BETWEEN THE BRAIN AND THE BODY VIA HORMONAL AND NEURAL PATHWAYS. THE BRAIN IS THE CENTRAL ORGAN OF STRESS AND ADAPTATION TO STRESS BECAUSE IT PERCEIVES AND DETERMINES WHAT IS THREATENING, AS WELL AS THE BEHAVIORAL AND PHYSIOLOGICAL RESPONSES TO THE STRESSOR. THE ADULT AND DEVELOPING BRAIN POSSESS REMARKABLE STRUCTURAL AND FUNCTIONAL PLASTICITY IN RESPONSE TO STRESS, INCLUDING NEURONAL REPLACEMENT, DENDRITIC REMODELING, AND SYNAPSE TURNOVER. STRESS CAUSES AN IMBALANCE OF NEURAL CIRCUITRY SUBSERVING COGNITION, DECISION-MAKING, ANXIETY AND MOOD THAT CAN ALTER EXPRESSION OF THOSE BEHAVIORS AND BEHAVIORAL STATES. THIS IMBALANCE, IN TURN, AFFECTS SYSTEMIC PHYSIOLOGY VIA NEUROENDOCRINE, AUTONOMIC, IMMUNE AND METABOLIC MEDIATORS. IN THE SHORT TERM, AS FOR INCREASED FEARFUL VIGILANCE AND ANXIETY IN A THREATENING ENVIRONMENT, THESE CHANGES MAY BE ADAPTIVE. BUT, IF THE DANGER PASSES AND THE BEHAVIORAL STATE PERSISTS ALONG WITH THE CHANGES IN NEURAL CIRCUITRY, SUCH MALADAPTATION MAY NEED INTERVENTION WITH A COMBINATION OF PHARMACOLOGICAL AND BEHAVIORAL THERAPIES, AS IS THE CASE FOR CHRONIC ANXIETY AND DEPRESSION. THERE ARE IMPORTANT SEX DIFFERENCES IN THE BRAIN RESPONSES TO STRESSORS THAT ARE IN URGENT NEED OF FURTHER EXPLORATION. MOREOVER, ADVERSE EARLY-LIFE EXPERIENCE, INTERACTING WITH ALLELES OF CERTAIN GENES, PRODUCE LASTING EFFECTS ON BRAIN AND BODY OVER THE LIFE-COURSE VIA EPIGENETIC MECHANISMS. WHILE PREVENTION IS MOST IMPORTANT, THE PLASTICITY OF THE BRAIN GIVES HOPE FOR THERAPIES THAT TAKE INTO CONSIDERATION BRAIN-BODY INTERACTIONS. 2015 18 5467 38 RESILIENT PHENOTYPE IN CHRONIC MILD STRESS PARADIGM IS ASSOCIATED WITH ALTERED EXPRESSION LEVELS OF MIR-18A-5P AND SEROTONIN 5-HT(1A) RECEPTOR IN DORSAL PART OF THE HIPPOCAMPUS. DISTURBED SEROTONERGIC SIGNALING IN THE HIPPOCAMPUS OBSERVED IN MANY INDIVIDUALS VULNERABLE TO STRESS HAS BEEN SUGGESTED AS ONE OF THE PRIMARY FACTORS CONTRIBUTING TO THE DEVELOPMENT OF DEPRESSION. HOWEVER, LITTLE IS KNOWN ABOUT THE PHYSIOLOGY OF THE BRAIN IN THE RESILIENT PHENOTYPE. RESILIENT SUBJECTS MAINTAIN A POSITIVE MOOD AND PSYCHOLOGICAL BALANCE DESPITE BEING UNDER THE STRESS INFLUENCE. IN OUR STUDY, WE GENERATED STRESS-VULNERABLE AND RESILIENT RATS BY USING A CHRONIC MILD STRESS (CMS) PARADIGM. USING DIFFERENT MOLECULAR APPROACHES, WE REVEALED THAT RESILIENT ANIMALS EXHIBITED A SIGNIFICANTLY DECREASED EXPRESSION LEVEL OF MIR-18A-5P AND, IN THE SAME TIME, AN ELEVATED LEVEL OF 5-HT1AR IN DORSAL, BUT NOT VENTRAL, PART OF THE HIPPOCAMPUS. DESCRIBED BIOCHEMICAL CHANGES WERE NOT OBSERVED IN ANIMALS BEHAVIORALLY VULNERABLE TO STRESS. FURTHER, IN VITRO ANALYSIS SHOWED THAT MIR-18A-5P MAY BE A NEGATIVE EPIGENETIC REGULATOR OF 5-HT1AR SINCE THE TREATMENT OF ADULT HIPPOCAMPAL NEURONS WITH MIR-18A-5P MIMIC SIGNIFICANTLY LOWERED THE EXPRESSION LEVEL OF MRNA ENCODING 5-HT1AR. MOREOVER, BIOINFORMATIC ANALYSIS OF POTENTIAL TARGET GENES EXPRESSED IN THE HIPPOCAMPUS AND BEING REGULATED BY MIR-18A-5P SHOWED THAT THIS MICRORNA MAY REGULATE BIOLOGICAL PROCESSES, SUCH AS AXONOGENESIS, WHICH ARE IMPORTANT IN THE FUNCTIONING OF THE HIPPOCAMPUS IN BOTH RATS AND HUMANS. ALL THESE MOLECULAR FEATURES MAY CONTRIBUTE TO SEROTONERGIC HOMEOSTATIC BALANCE AT THE LEVEL OF SEROTONIN TURNOVER OBSERVED IN HIPPOCAMPI OF RESILIENT BUT NOT STRESS-VULNERABLE RATS. DELINEATION OF FURTHER MOLECULAR AND BIOCHEMICAL MARKERS UNDERLYING RESILIENCE TO STRESS MAY CONTRIBUTE TO THE DEVELOPMENT OF NEW ANTIDEPRESSANT STRATEGIES WHICH WILL RESTORE RESILIENT PHENOTYPE IN DEPRESSED PATIENTS. 2019 19 375 20 AN ENERGETIC VIEW OF STRESS: FOCUS ON MITOCHONDRIA. ENERGY IS REQUIRED TO SUSTAIN LIFE AND ENABLE STRESS ADAPTATION. AT THE CELLULAR LEVEL, ENERGY IS LARGELY DERIVED FROM MITOCHONDRIA - UNIQUE MULTIFUNCTIONAL ORGANELLES WITH THEIR OWN GENOME. FOUR MAIN ELEMENTS CONNECT MITOCHONDRIA TO STRESS: (1) ENERGY IS REQUIRED AT THE MOLECULAR, (EPI)GENETIC, CELLULAR, ORGANELLAR, AND SYSTEMIC LEVELS TO SUSTAIN COMPONENTS OF STRESS RESPONSES; (2) GLUCOCORTICOIDS AND OTHER STEROID HORMONES ARE PRODUCED AND METABOLIZED BY MITOCHONDRIA; (3) RECIPROCALLY, MITOCHONDRIA RESPOND TO NEUROENDOCRINE AND METABOLIC STRESS MEDIATORS; AND (4) EXPERIMENTALLY MANIPULATING MITOCHONDRIAL FUNCTIONS ALTERS PHYSIOLOGICAL AND BEHAVIORAL RESPONSES TO PSYCHOLOGICAL STRESS. THUS, MITOCHONDRIA ARE ENDOCRINE ORGANELLES THAT PROVIDE BOTH THE ENERGY AND SIGNALS THAT ENABLE AND DIRECT STRESS ADAPTATION. NEURAL CIRCUITS REGULATING SOCIAL BEHAVIOR - AS WELL AS PSYCHOPATHOLOGICAL PROCESSES - ARE ALSO INFLUENCED BY MITOCHONDRIAL ENERGETICS. AN INTEGRATIVE VIEW OF STRESS AS AN ENERGY-DRIVEN PROCESS OPENS NEW OPPORTUNITIES TO STUDY MECHANISMS OF ADAPTATION AND REGULATION ACROSS THE LIFESPAN. 2018 20 84 33 A NOVEL EPIGENETIC MECHANISM OF FXR INHIBITING GLP-1 SECRETION VIA MIR-33 AND ITS DOWNSTREAM TARGETS. TYPE II DIABETES IS A COMPLEX, CHRONIC, AND PROGRESSIVE DISEASE. PREVIOUSLY, WE DEMONSTRATE THAT FXR INHIBITS GLP-1 SECRETION VIA INTERACTING WITH CREB TO INHIBIT THE TRANSCRIPTIONAL ACTIVITY OF CREB, THUS PROMOTING THE DEVELOPMENT OF TYPE II DIABETES. EPIGENETIC MODIFICATIONS, SUCH AS DNA METHYLATION, HISTONE ACETYLATION, AND POST-TRANSCRIPTIONAL RNA REGULATION, ARE ESSENTIAL MEDIATORS CONTRIBUTING TO DIABETES-ASSOCIATED MORBIDITY AND MORTALITY. THUS, WE ATTEMPTED TO INVESTIGATE THE EPIGENETIC MECHANISMS OF FXR MODULATING GLP-1 SECRETION. FIRSTLY, THE INVOLVEMENT OF HISTONE ACETYLATION, DNA METHYLATION, AND POST-TRANSCRIPTIONAL REGULATION IN FXR INHIBITING GLP-1 SECRETION WAS VERIFIED. AS FXR OVEREXPRESSION SIGNIFICANTLY INHIBITED THE ACTIVITY OF GCG 3'-UTR, WE HYPOTHESIZE THAT MIRNA MIGHT PARTICIPATE IN THE MECHANISM. TWO ONLINE TOOLS AND REAL-TIME PCR REVEALED THAT FXR PROMOTED MIR-33 EXPRESSION. MOREOVER, MIR-33 INHIBITED THE EXPRESSION OF GCG AND CREB1 THROUGH DIRECT TARGETING IN STC-1 CELLS. FXR OVEREXPRESSION IN STC-1 CELLS SIGNIFICANTLY REDUCED THE MRNA EXPRESSION AND PROTEIN LEVELS OF BOTH GCG AND CREB1, AS WELL AS THE SECRETION OF GLP-1; MIR-33 INHIBITION EXERTED OPPOSING EFFECTS. MORE IMPORTANTLY, THE EFFECTS OF FXR OVEREXPRESSION WERE SIGNIFICANTLY REVERSED BY MIR-33 INHIBITION, INDICATING THAT FXR INHIBITED GLP-1 SECRETION THROUGH PROMOTING MIR-33 EXPRESSION, THEREFORE INHIBITING THE EXPRESSION OF MIR-33 TARGETS, GCG AND CREB1. IN CONCLUSION, WE PROVIDE A NOVEL EPIGENETIC MECHANISM BY WHICH FXR INHIBITS THE SECRETION OF GLP-1 THROUGH MIR-33 AND ITS TWO DOWNSTREAM TARGETS, GCG AND CREB1. THESE FINDINGS MIGHT PROVIDE INNOVATIVE STRATEGIES FOR IMPROVING TYPE II DIABETES, WHICH NEEDS FURTHER IN VIVO AND CLINICAL INVESTIGATION. 2019