1 6267 146 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 2 5815 45 STRESS AND GLUCOCORTICOID RECEPTOR TRANSCRIPTIONAL PROGRAMMING IN TIME AND SPACE: IMPLICATIONS FOR THE BRAIN-GUT AXIS. BACKGROUND: CHRONIC PSYCHOLOGICAL STRESS IS ASSOCIATED WITH ENHANCED ABDOMINAL PAIN AND ALTERED INTESTINAL BARRIER FUNCTION THAT MAY RESULT FROM A PERTURBATION IN THE HYPOTHALAMIC-PITUITARY-ADRENAL (HPA) AXIS. THE GLUCOCORTICOID RECEPTOR (GR) EXPLOITS DIVERSE MECHANISMS TO ACTIVATE OR SUPPRESS CONGENERIC GENE EXPRESSION, WITH REGULATORY VARIATION ASSOCIATED WITH STRESS-RELATED DISORDERS IN PSYCHIATRY AND GASTROENTEROLOGY. PURPOSE: DURING ACUTE AND CHRONIC STRESS, CORTICOTROPIN-RELEASING HORMONE DRIVES SECRETION OF ADRENOCORTICOTROPIC HORMONE FROM THE PITUITARY, ULTIMATELY LEADING TO THE RELEASE OF CORTISOL (HUMAN) AND CORTICOSTERONE (RODENT) FROM THE ADRENAL GLANDS. CORTISOL BINDS WITH THE GR IN THE CYTOSOL, TRANSLOCATES TO THE NUCLEUS, AND ACTIVATES THE NR3C1 (NUCLEAR RECEPTOR SUBFAMILY 3, GROUP C, MEMBER 1 [GR]) GENE. THIS REVIEW FOCUSES ON THE RAPIDLY DEVELOPING OBSERVATIONS THAT CORTISOL IS RESPONSIBLE FOR DRIVING CIRCADIAN AND ULTRADIAN BURSTS OF TRANSCRIPTIONAL ACTIVITY IN THE CLOCK (CLOCK CIRCADIAN REGULATOR) AND PER (PERIOD CIRCADIAN CLOCK 1) GENE FAMILIES, AND THIS RHYTHM IS DISRUPTED IN MAJOR DEPRESSIVE DISORDER, BIPOLAR DISORDER, AND STRESS-RELATED GASTROINTESTINAL AND IMMUNE DISORDERS. GLUCOCORTICOID RECEPTOR REGULATES DIFFERENT SETS OF TRANSCRIPTS IN A TISSUE-SPECIFIC MANNER, THROUGH PULSATILE WAVES OF GENE EXPRESSION THAT INCLUDES OCCUPANCY OF GLUCOCORTICOID RESPONSE ELEMENTS LOCATED WITHIN CONSTITUTIVELY OPEN SPATIAL DOMAINS IN CHROMATIN. EMERGING EVIDENCE SUPPORTS A POTENTIALLY PIVOTAL ROLE FOR EPIGENETIC REGULATION OF HOW GR INTERACTS WITH OTHER CHROMATIN REGULATORS TO CONTROL THE EXPRESSION OF ITS TARGET GENES. DYSREGULATION OF THE CENTRAL AND PERIPHERAL GR REGULOME HAS POTENTIALLY SIGNIFICANT CONSEQUENCES FOR STRESS-RELATED DISORDERS AFFECTING THE BRAIN-GUT AXIS. 2016 3 1017 32 CIRCADIAN RHYTHMS IN LIVER PHYSIOLOGY AND LIVER DISEASES. IN MAMMALS, CIRCADIAN RHYTHMS FUNCTION TO COORDINATE A DIVERSE PANEL OF PHYSIOLOGICAL PROCESSES WITH ENVIRONMENTAL CONDITIONS SUCH AS FOOD AND LIGHT. AS THE DRIVING FORCE FOR CIRCADIAN RHYTHMICITY, THE MOLECULAR CLOCK IS A SELF-SUSTAINED TRANSCRIPTION-TRANSLATIONAL FEEDBACK LOOP SYSTEM CONSISTING OF TRANSCRIPTION FACTORS, EPIGENETIC MODULATORS, KINASES/PHOSPHATASES, AND UBIQUITIN E3 LIGASES. THE MOLECULAR CLOCK EXISTS NOT ONLY IN THE SUPRACHIASMATIC NUCLEI OF THE HYPOTHALAMUS BUT ALSO IN THE PERIPHERAL TISSUES TO REGULATE CELLULAR AND PHYSIOLOGICAL FUNCTION IN A TISSUE-SPECIFIC MANNER. THE CIRCADIAN CLOCK SYSTEM IN THE LIVER PLAYS IMPORTANT ROLES IN REGULATING METABOLISM AND ENERGY HOMEOSTASIS. CLOCK GENE MUTANT ANIMALS DISPLAY IMPAIRED GLUCOSE AND LIPID METABOLISM AND ARE SUSCEPTIBLE TO DIET-INDUCED OBESITY AND METABOLIC DYSFUNCTION, PROVIDING STRONG EVIDENCE FOR THE CONNECTION BETWEEN THE CIRCADIAN CLOCK AND METABOLIC HOMEOSTASIS. CIRCADIAN-CONTROLLED HEPATIC METABOLISM IS PARTIALLY ACHIEVED BY CONTROLLING THE EXPRESSION AND/OR ACTIVITY OF KEY METABOLIC ENZYMES, TRANSCRIPTION FACTORS, SIGNALING MOLECULES, AND TRANSPORTERS. RECIPROCALLY, INTRACELLULAR METABOLITES MODULATE THE MOLECULAR CLOCK ACTIVITY IN RESPONSE TO THE ENERGY STATUS. ALTHOUGH STILL AT THE EARLY STAGE, CIRCADIAN CLOCK DYSFUNCTION HAS BEEN IMPLICATED IN COMMON CHRONIC LIVER DISEASES. CIRCADIAN DYSREGULATION OF LIPID METABOLISM, DETOXIFICATION, REACTIVE OXYGEN SPECIES (ROS) PRODUCTION, AND CELL-CYCLE CONTROL MIGHT CONTRIBUTE TO THE ONSET AND PROGRESSION OF LIVER STEATOSIS, FIBROSIS, AND EVEN CARCINOGENESIS. IN SUMMARY, THESE FINDINGS CALL FOR A COMPREHENSIVE STUDY OF THE FUNCTION AND MECHANISMS OF HEPATIC CIRCADIAN CLOCK TO GAIN BETTER UNDERSTANDING OF LIVER PHYSIOLOGY AND DISEASES. 2013 4 4064 31 MATERNAL AND EARLY-LIFE CIRCADIAN DISRUPTION HAVE LONG-LASTING NEGATIVE CONSEQUENCES ON OFFSPRING DEVELOPMENT AND ADULT BEHAVIOR IN MICE. MODERN LIFE INVOLVES CHRONIC CIRCADIAN DISRUPTION THROUGH ARTIFICIAL LIGHT AND THESE DISRUPTIONS ARE ASSOCIATED WITH NUMEROUS MENTAL AND PHYSICAL HEALTH MALADIES. BECAUSE THE DEVELOPING NERVOUS SYSTEM IS PARTICULARLY VULNERABLE TO PERTURBATION, WE HYPOTHESIZED THAT EARLY-LIFE CIRCADIAN DISRUPTION WOULD NEGATIVELY IMPACT OFFSPRING DEVELOPMENT AND ADULT FUNCTION. PREGNANT MICE WERE SUBJECTED TO CHRONIC CIRCADIAN DISRUPTION FROM THE TIME OF UTERINE IMPLANTATION THROUGH WEANING. TO DISSOCIATE IN UTERO FROM POSTNATAL EFFECTS, A SUBSET OF LITTERS WAS CROSS-FOSTERED AT BIRTH FROM DISRUPTED DAMS TO CONTROL DAMS AND VICE VERSA. POSTNATAL CIRCADIAN DISRUPTION WAS ASSOCIATED WITH REDUCED ADULT BODY MASS, SOCIAL AVOIDANCE, AND HYPERACTIVITY. IN UTERO DISRUPTION RESULTED IN MORE PRONOUNCED SOCIAL AVOIDANCE AND HYPERACTIVITY, PHENOTYPES NOT ABROGATED BY CROSS-FOSTERING TO CONTROL MOTHERS. TO EXAMINE WHETHER CIRCADIAN DISRUPTION AFFECTS DEVELOPMENT BY ACTING AS AN EARLY LIFE STRESSOR, WE EXAMINED BIRTHWEIGHT, LITTER SIZE, MATERNAL CANNIBALISM, AND EPIGENETIC MODIFICATIONS. NONE OF THESE VARIABLES DIFFERED BETWEEN CONTROL AND DISRUPTED DAMS, OR RESEMBLED PATTERNS SEEN FOLLOWING EARLY-LIFE STRESS. OUR FINDINGS INDICATE THAT DEVELOPMENTAL CHRONIC CIRCADIAN DISRUPTION PERMANENTLY AFFECTS SOMATIC AND BEHAVIORAL DEVELOPMENT IN A STAGE-OF-LIFE-DEPENDENT MANNER, INDEPENDENT OF EARLY LIFE STRESS MECHANISMS, UNDERSCORING THE IMPORTANCE OF TEMPORAL STRUCTURE DURING DEVELOPMENT, BOTH IN UTERO AND EARLY POSTNATAL LIFE. 2017 5 4088 28 MATERNAL OBESITY PROGRAMS OFFSPRING NON-ALCOHOLIC FATTY LIVER DISEASE THROUGH DISRUPTION OF 24-H RHYTHMS IN MICE. BACKGROUND: MATERNAL OBESITY INCREASES OFFSPRING PROPENSITY TO METABOLIC DYSFUNCTIONS AND TO NON-ALCOHOLIC FATTY LIVER DISEASE (NAFLD), WHICH MAY LEAD TO CIRRHOSIS OR LIVER CANCER. THE CIRCADIAN CLOCK IS A TRANSCRIPTIONAL/EPIGENETIC MOLECULAR MACHINERY SYNCHRONISING PHYSIOLOGICAL PROCESSES TO COORDINATE ENERGY UTILISATION WITHIN A 24-H LIGHT/DARK PERIOD. ALTERATIONS IN RHYTHMICITY HAVE PROFOUND EFFECTS ON METABOLIC PATHWAYS, WHICH WE SOUGHT TO INVESTIGATE IN OFFSPRING WITH PROGRAMMED NAFLD. METHODS: MICE WERE FED A STANDARD OR AN OBESOGENIC DIET (OD), BEFORE AND THROUGHOUT PREGNANCY, AND DURING LACTATION. OFFSPRING WERE WEANED ONTO STANDARD OR AN OD AT 3 WEEKS POSTPARTUM AND HOUSED IN 12:12 LIGHT/DARK CONDITIONS. BIOCHEMICAL AND HISTOLOGICAL INDICATORS OF NAFLD AND FIBROSIS, ANALYSIS OF CANONICAL CLOCK GENES WITH METHYLATION STATUS AND LOCOMOTOR ACTIVITY WERE INVESTIGATED AT 6 MONTHS. RESULTS: WE SHOW THAT MATERNAL OBESITY INTERACTS WITH AN OBESOGENIC POST-WEANING DIET TO PROMOTE THE DEVELOPMENT OF NAFLD WITH DISRUPTION OF CANONICAL METABOLIC RHYTHMICITY GENE EXPRESSION IN THE LIVER. WE DEMONSTRATE HYPERMETHYLATION OF BMAL-1 (BRAIN AND MUSCLE ARNT LIKE-1) AND PER2 PROMOTER REGIONS AND ALTERED 24-H RHYTHMICITY OF HEPATIC PRO-INFLAMMATORY AND FIBROGENIC MEDIATORS. CONCLUSIONS: THESE DATA IMPLICATE DISORDERED CIRCADIAN RHYTHMS IN NAFLD AND SUGGEST THAT DISRUPTION OF THIS SYSTEM DURING CRITICAL DEVELOPMENTAL PERIODS MAY BE RESPONSIBLE FOR THE ONSET OF CHRONIC LIVER DISEASE IN ADULTHOOD. 2015 6 3973 38 LONG-TERM BEHAVIORAL AND NEUROENDOCRINE ALTERATIONS FOLLOWING CHRONIC SOCIAL STRESS IN MICE: IMPLICATIONS FOR STRESS-RELATED DISORDERS. THE PERIOD OF ADOLESCENCE IS CHARACTERIZED BY A HIGH VULNERABILITY TO STRESS AND TRAUMA, WHICH MIGHT RESULT IN LONG-LASTING CONSEQUENCES AND AN INCREASED RISK TO DEVELOP PSYCHIATRIC DISORDERS. USING A RECENTLY DEVELOPED MOUSE MODEL FOR CHRONIC SOCIAL STRESS DURING ADOLESCENCE, WE STUDIED PERSISTENT NEUROENDOCRINE AND BEHAVIORAL EFFECTS OF CHRONIC SOCIAL STRESS OBTAINED 12 MONTHS AFTER CESSATION OF THE STRESSOR. AS A REFERENCE, WE INVESTIGATED IMMEDIATE EFFECTS OF CHRONIC STRESS EXPOSURE OBTAINED AT THE END OF THE CHRONIC STRESS PERIOD. IMMEDIATELY AFTER THE 7 WEEK CHRONIC STRESS PERIOD STRESSED ANIMALS SHOW SIGNIFICANTLY INCREASED ADRENAL WEIGHTS, DECREASED THYMUS WEIGHT, INCREASED BASAL CORTICOSTERONE SECRETION AND A FLATTENED CIRCADIAN RHYTHM. FURTHERMORE, STRESSED ANIMALS DISPLAY AN INCREASED ANXIETY-LIKE BEHAVIOR IN THE ELEVATED PLUS MAZE AND THE NOVELTY-INDUCED SUPPRESSION OF FEEDING TEST. HIPPOCAMPAL MINERALOCORTICOID RECEPTOR (MR) AND THE GLUCOCORTICOID RECEPTOR (GR) MRNA LEVELS WERE SIGNIFICANTLY DECREASED. TO INVESTIGATE PERSISTENT CONSEQUENCES OF THIS EARLY STRESSFUL EXPERIENCE, THE SAME PARAMETERS WERE ASSESSED IN AGED MICE 12 MONTHS AFTER THE CESSATION OF THE STRESSOR. INTERESTINGLY, WE STILL FOUND DIFFERENCES BETWEEN FORMERLY STRESSED AND CONTROL MICE IN IMPORTANT STRESS-RELATED PARAMETERS. MR EXPRESSION LEVELS WERE SIGNIFICANTLY LOWER IN STRESSED ANIMALS, SUGGESTING LASTING, POSSIBLY EPIGENETIC ALTERATIONS IN GENE EXPRESSION REGULATION. FURTHERMORE, WE OBSERVED LONG-TERM BEHAVIORAL ALTERATIONS IN ANIMALS STRESSED DURING ADOLESCENCE. THUS, WE COULD DEMONSTRATE THAT CHRONIC STRESS EXPOSURE DURING A CRUCIAL DEVELOPMENTAL TIME PERIOD RESULTS IN LONG-TERM, PERSISTENT EFFECTS ON PHYSIOLOGICAL AND BEHAVIORAL PARAMETERS THROUGHOUT LIFE, WHICH MAY CONTRIBUTE TO AN ENHANCED VULNERABILITY TO STRESS-INDUCED DISEASES. 2008 7 3463 38 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 8 4814 26 OBSTRUCTIVE SLEEP APNEA, CIRCADIAN CLOCK DISRUPTION, AND METABOLIC CONSEQUENCES. OBSTRUCTIVE SLEEP APNEA (OSA) IS A CHRONIC DISORDER CHARACTERIZED BY RECURRENT EPISODES OF APNEA AND HYPOPNEA DURING SLEEP. IT IS ASSOCIATED WITH VARIOUS CARDIOVASCULAR AND METABOLIC COMPLICATIONS, INCLUDING TYPE 2 DIABETES MELLITUS (T2DM) AND OBESITY. MANY PATHWAYS CAN BE RESPONSIBLE FOR T2DM DEVELOPMENT IN OSA PATIENTS, E.G., THOSE RELATED TO HIF-1 AND SIRT1 EXPRESSION. MOREOVER, EPIGENETIC MECHANISMS, SUCH AS MIRNA181A OR MIRNA199, ARE POSTULATED TO PLAY A PIVOTAL ROLE IN THIS LINK. IT HAS BEEN PROVEN THAT OSA INCREASES THE OCCURRENCE OF CIRCADIAN CLOCK DISRUPTION, WHICH IS ALSO A RISK FACTOR FOR METABOLIC DISEASE DEVELOPMENT. CIRCADIAN CLOCK DISRUPTION IMPAIRS THE METABOLISM OF GLUCOSE, LIPIDS, AND THE SECRETION OF BILE ACIDS. THEREFORE, OSA-INDUCED CIRCADIAN CLOCK DISRUPTION MAY BE A POTENTIAL, COMPLEX, UNDERLYING PATHWAY INVOLVED IN DEVELOPING AND EXACERBATING METABOLIC DISEASES AMONG OSA PATIENTS. THE CURRENT PAPER SUMMARIZES THE AVAILABLE INFORMATION PERTAINING TO THE RELATIONSHIP BETWEEN OSA AND CIRCADIAN CLOCK DISRUPTION IN THE CONTEXT OF POTENTIAL MECHANISMS LEADING TO METABOLIC DISORDERS. 2022 9 3092 38 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 10 235 24 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 11 1752 41 EARLY LIFE STRESS RESTRICTS TRANSLATIONAL REACTIVITY IN CA3 NEURONS ASSOCIATED WITH ALTERED STRESS RESPONSES IN ADULTHOOD. EARLY LIFE EXPERIENCES PROGRAM BRAIN STRUCTURE AND FUNCTION AND CONTRIBUTE TO BEHAVIORAL ENDOPHENOTYPES IN ADULTHOOD. EPIGENETIC CONTROL OF GENE EXPRESSION BY THOSE EXPERIENCES AFFECT DISCRETE BRAIN REGIONS INVOLVED IN MOOD, COGNITIVE FUNCTION AND REGULATION OF HYPOTHALAMIC-PITUITARY-ADRENAL (HPA) AXIS. IN RODENTS, ACUTE RESTRAINT STRESS INCREASES THE EXPRESSION OF THE REPRESSIVE HISTONE H3 LYSINE 9 TRI-METHYLATION (H3K9ME3) IN HIPPOCAMPAL FIELDS, INCLUDING THE CA3 PYRAMIDAL NEURONS. THESE CA3 NEURONS ARE CRUCIALLY INVOLVED IN COGNITIVE FUNCTION AND MOOD REGULATION AS WELL AS ACTIVATION OF GLUCOCORTICOID (CORT) SECRETION. CA3 NEURONS ALSO EXHIBIT STRUCTURAL AND FUNCTIONAL CHANGES AFTER EARLY-LIFE STRESS (ELS) AS WELL AS AFTER CHRONIC STRESS IN ADULTHOOD. USING A PROTOCOL OF CHRONIC ELS INDUCED BY LIMITED BEDDING AND NESTING MATERIAL FOLLOWED BY ACUTE-SWIM STRESS (AS) IN ADULTHOOD, WE SHOW THAT MICE WITH A HISTORY OF ELS DISPLAY A BLUNTED CORT RESPONSE TO AS, DESPITE EXHIBITING ACTIVATION OF IMMEDIATE EARLY GENES AFTER STRESS SIMILAR TO THAT FOUND IN CONTROL MICE. WE FIND THAT ELS INDUCED PERSISTENTLY INCREASED EXPRESSION OF THE REPRESSIVE H3K9ME3 HISTONE MARK IN THE CA3 SUBFIELD AT BASELINE THAT WAS SUBSEQUENTLY DECREASED FOLLOWING AS. IN CONTRAST, AS INDUCED A TRANSIENT INCREASE OF THIS MARK IN CONTROL MICE. USING TRANSLATING RIBOSOME AFFINITY PURIFICATION (TRAP) METHOD TO ISOLATE CA3 TRANSLATING MRNAS, WE FOUND THAT EXPRESSION OF GENES OF THE EPIGENETIC GENE FAMILY, GABA/GLUTAMATE FAMILY, AND GLUCOCORTICOID RECEPTORS BINDING GENES WERE DECREASED TRANSIENTLY IN CONTROL MICE BY AS AND SHOWED A PERSISTENT REDUCTION IN ELS MICE. IN MOST CASES, AS IN ELS MICE DID NOT INDUCE GENE EXPRESSION CHANGES. A STRINGENT FILTERING OF GENES AFFECTED BY AS IN CONTROL AND ELS MICE REVEALED A NOTEWORTHY DECREASE IN GENE EXPRESSION CHANGE IN ELS MICE COMPARED TO CONTROL. ONLY 18 GENES WERE SELECTIVELY REGULATED BY AS IN ELS MICE AND ENCOMPASSED PATHWAYS SUCH AS CIRCADIAN RHYTHM, INFLAMMATORY RESPONSE, OPIOID RECEPTORS, AND MORE GENES INCLUDED IN THE GLUCOCORTICOID RECEPTOR BINDING FAMILY. THUS, ELS PROGRAMS A RESTRICTED TRANSLATIONAL RESPONSE TO STRESS IN STRESS-SENSITIVE CA3 NEURONS LEADING TO PERSISTENT CHANGES IN GENE EXPRESSION, SOME OF WHICH MIMIC THE TRANSIENT EFFECTS OF AS IN CONTROL MICE, WHILE LEAVING IN OPERATION THE IMMEDIATE EARLY GENE RESPONSE TO AS. 2019 12 5570 28 ROLE OF MELATONIN IN METABOLIC REGULATION. ALTHOUGH THE HUMAN GENOME HAS REMAINED UNCHANGED OVER THE LAST 10,000 YEARS, OUR LIFESTYLE HAS BECOME PROGRESSIVELY MORE DIVERGENT FROM THOSE OF OUR ANCIENT ANCESTORS. THIS MALADAPTIVE CHANGE BECAME APPARENT WITH THE INDUSTRIAL REVOLUTION AND HAS BEEN ACCELERATING IN RECENT DECADES. SOCIALLY, WE ARE PEOPLE OF THE 21ST CENTURY, BUT GENETICALLY WE REMAIN SIMILAR TO OUR EARLY ANCESTORS. IN CONJUNCTION WITH THIS DISCORDANCE BETWEEN OUR ANCIENT, GENETICALLY-DETERMINED BIOLOGY AND THE NUTRITIONAL, CULTURAL AND ACTIVITY PATTERNS IN CONTEMPORARY WESTERN POPULATIONS, MANY DISEASES HAVE EMERGED. ONLY A CENTURY AGO INFECTIOUS DISEASE WAS A MAJOR CAUSE OF MORTALITY, WHEREAS TODAY NON-INFECTIOUS CHRONIC DISEASES ARE THE GREATEST CAUSE OF DEATH IN THE WORLD. EPIDEMICS OF METABOLIC DISEASES (E.G., CARDIOVASCULAR DISEASES, TYPE 2 DIABETES, OBESITY, METABOLIC SYNDROME AND CERTAIN CANCERS) HAVE BECOME MAJOR CONTRIBUTORS TO THE BURDEN OF POOR HEALTH AND THEY ARE PRESENTLY EMERGING OR ACCELERATING, IN MOST DEVELOPING COUNTRIES. ONE MAJOR LIFESTYLE CONSEQUENCE IS LIGHT AT NIGHT AND SUBSEQUENT DISRUPTED CIRCADIAN RHYTHMS COMMONLY REFERRED TO AS CIRCADIAN DISRUPTION OR CHRONODISRUPTION. MOUNTING EVIDENCE REVEALS THAT PARTICULARLY MELATONIN RHYTHMICITY HAS CRUCIAL ROLES IN A VARIETY OF METABOLIC FUNCTIONS AS AN ANTI-OXIDANT, ANTI-INFLAMMATORY CHRONOBIOTIC AND POSSIBLY AS AN EPIGENETIC REGULATOR. THIS PAPER PROVIDES A BRIEF OUTLINE ABOUT METABOLIC DYSREGULATION IN CONJUNCTION WITH A DISRUPTED MELATONIN RHYTHM. 2009 13 4343 35 MINIREVIEW: STRESS-RELATED PSYCHIATRIC DISORDERS WITH LOW CORTISOL LEVELS: A METABOLIC HYPOTHESIS. SEVERAL STRESS-ASSOCIATED NEUROPSYCHIATRIC DISORDERS, NOTABLY POSTTRAUMATIC STRESS DISORDER AND CHRONIC PAIN AND FATIGUE SYNDROMES, PARADOXICALLY EXHIBIT SOMEWHAT LOW PLASMA LEVELS OF THE STRESS HORMONE CORTISOL. THE EFFECTS APPEAR GREATEST IN THOSE INITIALLY TRAUMATIZED IN EARLY LIFE, IMPLYING A DEGREE OF DEVELOPMENTAL PROGRAMMING, PERHAPS OF BOTH LOWER CORTISOL AND VULNERABILITY TO PSYCHOPATHOLOGY. IN THESE CONDITIONS, LOWERED CORTISOL IS NOT DUE TO ANY ADRENAL OR PITUITARY INSUFFICIENCY. INSTEAD, TWO PROCESSES APPEAR INVOLVED. FIRST, THERE IS INCREASED TARGET CELL SENSITIVITY TO GLUCOCORTICOID ACTION, NOTABLY NEGATIVE FEEDBACK UPON THE HYPOTHALAMIC-PITUITARY-ADRENAL (STRESS) AXIS. ALTERED DENSITY OF THE GLUCOCORTICOID RECEPTOR IS INFERRED, SQUARING WITH MUCH PRECLINICAL DATA SHOWING EARLY LIFE CHALLENGES CAN PERMANENTLY PROGRAM GLUCOCORTICOID RECEPTORS IN A TISSUE-SPECIFIC MANNER. THESE EFFECTS INVOLVE EPIGENETIC MECHANISMS. SECOND, EARLY LIFE TRAUMA/STARVATION INDUCES LONG-LASTING LOWERING OF GLUCOCORTICOID CATABOLISM, SPECIFICALLY BY 5ALPHA-REDUCTASE TYPE 1 (PREDOMINANTLY A LIVER ENZYME) AND 11BETA-HYDROXYSTEROID DEHYDROGENASE TYPE 2 (IN KIDNEY), AN EFFECT ALSO SEEN IN MODEL SYSTEMS. THESE CHANGES REFLECT A PLAUSIBLE EARLY-LIFE ADAPTATION TO INCREASE THE PERSISTENCE OF ACTIVE CORTISOL IN LIVER (TO MAXIMIZE FUEL OUTPUT) AND KIDNEY (TO INCREASE SALT RETENTION) WITHOUT ELEVATION OF CIRCULATING LEVELS, THUS AVOIDING THEIR DELETERIOUS EFFECTS ON BRAIN AND MUSCLE. MODESTLY LOWERED CIRCULATING CORTISOL AND INCREASED VULNERABILITY TO STRESS-ASSOCIATED DISORDERS MAY BE THE OUTCOME. THIS NOTION IMPLIES A VULNERABLE EARLY-LIFE PHENOTYPE MAY BE DISCERNABLE AND INDICATES POTENTIAL THERAPY BY MODEST GLUCOCORTICOID REPLACEMENT. INDEED, EARLY CLINICAL TRIALS WITH CORTISOL HAVE SHOWN A MODICUM OF PROMISE. 2011 14 3151 41 GLUCOCORTICOIDS, EPIGENETIC CONTROL AND STRESS RESILIENCE. GLUCOCORTICOID HORMONES PLAY A PIVOTAL ROLE IN THE RESPONSE TO STRESSFUL CHALLENGES. THE SURGE IN GLUCOCORTICOID HORMONE SECRETION AFTER STRESS NEEDS TO BE TIGHTLY CONTROLLED WITH CHARACTERISTICS LIKE PEAK HEIGHT, CURVATURE AND DURATION DEPENDING ON THE NATURE AND SEVERITY OF THE CHALLENGE. THIS IS IMPORTANT AS CHRONIC HYPER- OR HYPO-RESPONSES ARE DETRIMENTAL TO HEALTH DUE TO INCREASING THE RISK FOR DEVELOPING A STRESS-RELATED MENTAL DISORDER. PROPER GLUCOCORTICOID RESPONSES TO STRESS ARE CRITICAL FOR ADAPTATION. THEREFORE, THE TIGHT CONTROL OF BASELINE AND STRESS-EVOKED GLUCOCORTICOID SECRETION ARE IMPORTANT CONSTITUENTS OF AN ORGANISM'S RESILIENCE. HERE, WE ADDRESS A NUMBER OF MECHANISMS THAT ILLUSTRATE THE MULTITUDE AND COMPLEXITY OF MEASURES SAFEGUARDING THE CONTROL OF GLUCOCORTICOID FUNCTION. THESE MECHANISMS INCLUDE THE CONTROL OF MINERALOCORTICOID (MR) AND GLUCOCORTICOID RECEPTOR (GR) OCCUPANCY AND CONCENTRATION, THE DYNAMIC CONTROL OF FREE GLUCOCORTICOID HORMONE AVAILABILITY BY CORTICOSTEROID-BINDING GLOBULIN (CBG), AND THE CONTROL EXERTED BY GLUCOCORTICOIDS AT THE SIGNALING, EPIGENETIC AND GENOMIC LEVEL ON GENE TRANSCRIPTIONAL RESPONSES TO STRESS. WE REVIEW THE BENEFICIAL EFFECTS OF REGULAR EXERCISE ON HPA AXIS AND SLEEP PHYSIOLOGY, AND COGNITIVE AND ANXIETY-RELATED BEHAVIOR. FURTHERMORE, WE DESCRIBE THAT, POSSIBLY THROUGH CHANGES IN THE GABAERGIC SYSTEM, EXERCISE REDUCES THE IMPACT OF STRESS ON A SIGNALING PATHWAY SPECIFICALLY IN THE DENTATE GYRUS THAT IS STRONGLY IMPLICATED IN THE BEHAVIORAL RESPONSE TO THAT STRESSOR. THESE OBSERVATIONS UNDERLINE THE IMPACT OF LIFE STYLE ON STRESS RESILIENCE. FINALLY, WE ADDRESS HOW SINGLE NUCLEOTIDE POLYMORPHISMS (SNPS) AFFECTING GLUCOCORTICOID ACTION CAN COMPROMISE STRESS RESILIENCE, WHICH BECOMES MOST APPARENT UNDER CONDITIONS OF CHILDHOOD ABUSE. 2015 15 3405 42 HOW STRESS GETS UNDER THE SKIN: EARLY LIFE ADVERSITY AND GLUCOCORTICOID RECEPTOR EPIGENETIC REGULATION. EARLY LIFE ADVERSITY IS ASSOCIATED WITH BOTH PERSISTENT DISRUPTIONS IN THE HYPOTHALAMIC-PITUITARY-ADRENAL (HPA) AXIS AND PSYCHIATRIC SYMPTOMS. GLUCOCORTICOID RECEPTORS (GRS), WHICH ARE ENCODED BY THE NR3C1 GENE, BIND TO CORTISOL AND OTHER GLUCOCORTICOIDS TO CREATE A NEGATIVE FEEDBACK LOOP WITHIN THE HPA AXIS TO REGULATE THE BODY'S NEUROENDOCRINE RESPONSE TO STRESS. EXCESS METHYLATION OF A PROMOTER SEQUENCE WITHIN NR3C1 THAT ATTENUATES GR EXPRESSION, HOWEVER, HAS BEEN ASSOCIATED WITH BOTH EARLY LIFE ADVERSITY AND PSYCHOPATHOLOGY. AS CRITICAL REGULATORS WITHIN THE HPA AXIS, GRS AND THEIR EPIGENETIC REGULATION MAY MEDIATE THE LINK BETWEEN EARLY LIFE ADVERSITY AND THE ONSET OF PSYCHOPATHOLOGY. THE PRESENT REVIEW DISCUSSES THIS WORK AS ONE MECHANISM BY WHICH STRESS MAY GET UNDER THE SKIN TO DISRUPT HPA FUNCTIONING AT AN EPIGENETIC LEVEL AND CREATE LONG-LASTING VULNERABILITIES IN THE STRESS REGULATORY SYSTEM THAT SUBSEQUENTLY PREDISPOSE INDIVIDUALS TO PSYCHOPATHOLOGY. SPANNING PRENATAL INFLUENCES TO CRITICAL PERIODS OF EARLY LIFE AND ADOLESCENCE, WE DETAIL THE IMPACT THAT EARLY ADVERSITY HAS ON GR EXPRESSION, PHYSIOLOGICAL RESPONSES TO STRESS, AND THEIR IMPLICATIONS FOR LONG-TERM STRESS MANAGEMENT. WE NEXT PROPOSE A DUAL TRANSMISSION HYPOTHESIS REGARDING BOTH GENOMIC AND NON-GENOMIC MECHANISMS BY WHICH CHRONIC AND ACUTE STRESS PROPAGATE THROUGH NUMEROUS GENERATIONS. LASTLY, WE OUTLINE SEVERAL DIRECTIONS FOR FUTURE RESEARCH, INCLUDING POTENTIAL REVERSIBILITY OF METHYLATION PATTERNS AND ITS FUNCTIONAL IMPLICATIONS, VARIATION IN BEHAVIOR DETERMINED SOLELY BY NR3C1, AND CONSENSUS ON WHICH SPECIFIC PROMOTER REGIONS SHOULD BE STUDIED. 2018 16 5209 35 PRENATAL XENOBIOTIC EXPOSURE AND INTRAUTERINE HYPOTHALAMUS-PITUITARY-ADRENAL AXIS PROGRAMMING ALTERATION. THE HYPOTHALAMIC-PITUITARY-ADRENAL (HPA) AXIS IS ONE OF THE MOST IMPORTANT NEUROENDOCRINE AXES AND PLAYS AN IMPORTANT ROLE IN STRESS DEFENSE RESPONSES BEFORE AND AFTER BIRTH. PRENATAL EXPOSURE TO XENOBIOTICS, INCLUDING ENVIRONMENTAL TOXINS (SUCH AS SMOKE, SULFUR DIOXIDE AND CARBON MONOXIDE), DRUGS (SUCH AS SYNTHETIC GLUCOCORTICOIDS), AND FOODS AND BEVERAGE CATEGORIES (SUCH AS ETHANOL AND CAFFEINE), AFFECTS FETAL DEVELOPMENT INDIRECTLY BY CHANGING THE MATERNAL STATUS OR DAMAGING THE PLACENTA. CERTAIN XENOBIOTICS (SUCH AS CAFFEINE, ETHANOL AND DEXAMETHASONE) MAY ALSO AFFECT THE FETUS DIRECTLY BY CROSSING THE PLACENTA INTO THE FETUS DUE TO THEIR LIPOPHILIC PROPERTIES AND LOWER MOLECULAR WEIGHTS. ALL OF THESE FACTORS PROBABLY RESULT IN INTRAUTERINE PROGRAMMING ALTERATION OF THE HPA AXIS, WHICH SHOWED A LOW BASAL ACTIVITY BUT HYPERSENSITIVITY TO CHRONIC STRESS. THESE ALTERATIONS WILL, THEREFORE, INCREASE THE SUSCEPTIBILITY TO ADULT NEUROPSYCHIATRIC (SUCH AS DEPRESSION AND SCHIZOPHRENIA) AND METABOLIC DISEASES (SUCH AS HYPERTENSION, DIABETES AND NON-ALCOHOLIC FATTY LIVER DISEASE). THE "OVER-EXPOSURE OF FETUSES TO MATERNAL GLUCOCORTICOIDS" MAY BE THE MAIN INITIATION FACTOR BY WHICH THE FETAL HPA AXIS PROGRAMMING IS ALTERED. MEANTIME, XENOBIOTICS CAN DIRECTLY INDUCE ABNORMAL EPIGENETIC MODIFICATIONS AND EXPRESSION ON THE IMPORTANT FETAL GENES (SUCH AS HIPPOCAMPAL GLUCOCORTICOID RECEPTOR, ADRENAL STEROIDOGENIC ACUTE REGULATORY PROTEIN, ET AL) OR DAMAGE BY IN SITU OXIDATIVE METABOLISM OF FETAL ADRENALS, WHICH MAY ALSO BE CONTRIBUTED TO THE PROGRAMMING ALTERATION OF FETAL HPA AXIS. 2014 17 375 27 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 18 4948 37 PATERNAL STRESS EXPOSURE ALTERS SPERM MICRORNA CONTENT AND REPROGRAMS OFFSPRING HPA STRESS AXIS REGULATION. NEUROPSYCHIATRIC DISEASE FREQUENTLY PRESENTS WITH AN UNDERLYING HYPOREACTIVITY OR HYPERREACTIVITY OF THE HPA STRESS AXIS, SUGGESTING AN EXCEPTIONAL VULNERABILITY OF THIS CIRCUITRY TO EXTERNAL PERTURBATIONS. PARENTAL LIFETIME EXPOSURES TO ENVIRONMENTAL CHALLENGES ARE ASSOCIATED WITH INCREASED OFFSPRING NEUROPSYCHIATRIC DISEASE RISK, AND LIKELY CONTRIBUTE TO STRESS DYSREGULATION. WHILE MATERNAL INFLUENCES HAVE BEEN EXTENSIVELY EXAMINED, MUCH LESS IS KNOWN REGARDING THE SPECIFIC ROLE OF PATERNAL FACTORS. TO INVESTIGATE THE POTENTIAL MECHANISMS BY WHICH PATERNAL STRESS MAY CONTRIBUTE TO OFFSPRING HYPOTHALAMIC-PITUITARY-ADRENAL (HPA) AXIS DYSREGULATION, WE EXPOSED MICE TO 6 WEEKS OF CHRONIC STRESS BEFORE BREEDING. AS EPIDEMIOLOGICAL STUDIES SUPPORT VARIATION IN PATERNAL GERM CELL SUSCEPTIBILITY TO REPROGRAMMING ACROSS THE LIFESPAN, MALE STRESS EXPOSURE OCCURRED EITHER THROUGHOUT PUBERTY OR IN ADULTHOOD. REMARKABLY, OFFSPRING OF SIRES FROM BOTH PATERNAL STRESS GROUPS DISPLAYED SIGNIFICANTLY REDUCED HPA STRESS AXIS RESPONSIVITY. GENE SET ENRICHMENT ANALYSES IN OFFSPRING STRESS REGULATING BRAIN REGIONS, THE PARAVENTRICULAR NUCLEUS (PVN) AND THE BED NUCLEUS OF STRIA TERMINALIS, REVEALED GLOBAL PATTERN CHANGES IN TRANSCRIPTION SUGGESTIVE OF EPIGENETIC REPROGRAMMING AND CONSISTENT WITH ALTERED OFFSPRING STRESS RESPONSIVITY, INCLUDING INCREASED EXPRESSION OF GLUCOCORTICOID-RESPONSIVE GENES IN THE PVN. IN EXAMINING POTENTIAL EPIGENETIC MECHANISMS OF GERM CELL TRANSMISSION, WE FOUND ROBUST CHANGES IN SPERM MICRORNA (MIR) CONTENT, WHERE NINE SPECIFIC MIRS WERE SIGNIFICANTLY INCREASED IN BOTH PATERNAL STRESS GROUPS. OVERALL, THESE RESULTS DEMONSTRATE THAT PATERNAL EXPERIENCE ACROSS THE LIFESPAN CAN INDUCE GERM CELL EPIGENETIC REPROGRAMMING AND IMPACT OFFSPRING HPA STRESS AXIS REGULATION, AND MAY THEREFORE OFFER NOVEL INSIGHT INTO FACTORS INFLUENCING NEUROPSYCHIATRIC DISEASE RISK. 2013 19 23 38 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 20 2144 31 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