1 5065 124 PHOTOPERIOD-INDUCED NEUROTRANSMITTER PLASTICITY DECLINES WITH AGING: AN EPIGENETIC REGULATION? NEUROPLASTICITY HAS CLASSICALLY BEEN UNDERSTOOD TO ARISE THROUGH CHANGES IN SYNAPTIC STRENGTH OR SYNAPTIC CONNECTIVITY. A NEWLY DISCOVERED FORM OF NEUROPLASTICITY, NEUROTRANSMITTER SWITCHING, INVOLVES CHANGES IN NEUROTRANSMITTER IDENTITY. CHRONIC EXPOSURE TO DIFFERENT PHOTOPERIODS ALTERS THE NUMBER OF DOPAMINE (TYROSINE HYDROXYLASE, TH+) AND SOMATOSTATIN (SST+) NEURONS IN THE PARAVENTRICULAR NUCLEUS (PAVN) OF THE HYPOTHALAMUS OF ADULT RATS AND RESULTS IN DISCRETE BEHAVIORAL CHANGES. HERE, WE INVESTIGATE WHETHER PHOTOPERIOD-INDUCED NEUROTRANSMITTER SWITCHING PERSISTS DURING AGING AND WHETHER EPIGENETIC MECHANISMS OF HISTONE ACETYLATION AND DNA METHYLATION MAY CONTRIBUTE TO THIS NEUROTRANSMITTER PLASTICITY. WE SHOW THAT THIS PLASTICITY IN RATS IS ROBUST AT 1 AND AT 3 MONTHS BUT REDUCED IN TH+ NEURONS AT 12 MONTHS AND COMPLETELY ABOLISHED IN BOTH TH+ AND SST+ NEURONS BY 18 MONTHS. DE NOVO EXPRESSION OF DNMT3A CATALYZING DNA METHYLATION AND ANTI-ACETYLH3 ASSESSING HISTONE 3 ACETYLATION WERE OBSERVED FOLLOWING SHORT-DAY PHOTOPERIOD EXPOSURE IN BOTH TH+ AND SST+ NEURONS AT 1 AND 3 MONTHS WHILE AN OVERALL INCREASE IN DNMT3A IN SST+ NEURONS PARALLELED NEUROPLASTICITY REDUCTION AT 12 AND 18 MONTHS. HISTONE ACETYLATION INCREASED IN TH+ NEURONS AND DECREASED IN SST+ NEURONS FOLLOWING SHORT-DAY EXPOSURE AT 3 MONTHS WHILE THE TOTAL NUMBER OF ANTI-ACETYLH3+ PAVN NEURONS REMAINED CONSTANT. RECIPROCAL HISTONE ACETYLATION IN TH+ AND SST+ NEURONS INDICATES THE IMPORTANCE OF STUDYING EPIGENETIC REGULATION AT THE CIRCUIT LEVEL FOR IDENTIFIED CELL PHENOTYPES. THE FINDINGS MAY BE USEFUL FOR DEVELOPING APPROACHES FOR NONINVASIVE TREATMENT OF DISORDERS CHARACTERIZED BY NEUROTRANSMITTER DYSFUNCTION. 2020 2 4999 36 PERINATAL PROGRAMMING OF CIRCADIAN CLOCK-STRESS CROSSTALK. AN INTACT COMMUNICATION BETWEEN CIRCADIAN CLOCKS AND THE STRESS SYSTEM IS IMPORTANT FOR MAINTAINING PHYSIOLOGICAL HOMEOSTASIS UNDER RESTING CONDITIONS AND IN RESPONSE TO EXTERNAL STIMULI. THERE IS ACCUMULATING EVIDENCE FOR A RECIPROCAL INTERACTION BETWEEN BOTH-FROM THE SYSTEMIC TO THE MOLECULAR LEVEL. DISRUPTION OF THIS INTERACTION BY EXTERNAL FACTORS SUCH AS SHIFTWORK, JETLAG, OR CHRONIC STRESS INCREASES THE RISK OF DEVELOPING METABOLIC, IMMUNE, OR MOOD DISORDERS. FROM EXPERIMENTS IN RODENTS, WE KNOW THAT BOTH SYSTEMS MATURATE DURING THE PERINATAL PERIOD. DURING THAT TIME, EXOGENOUS FACTORS SUCH AS STRESS OR ALTERATIONS IN THE EXTERNAL PHOTOPERIOD MAY CRITICALLY AFFECT-OR PROGRAM-PHYSIOLOGICAL FUNCTIONS LATER IN LIFE. THIS DEVELOPMENTAL PROGRAMMING PROCESS HAS BEEN ATTRIBUTED TO MATERNAL STRESS SIGNALS REACHING THE EMBRYO, WHICH LASTINGLY CHANGE GENE EXPRESSION THROUGH THE INDUCTION OF EPIGENETIC MECHANISMS. DESPITE THE WELL-KNOWN FUNCTION OF THE ADULT CIRCADIAN SYSTEM IN TEMPORAL COORDINATION OF PHYSIOLOGY AND BEHAVIOR, THE ROLE OF MATERNAL AND EMBRYONIC CIRCADIAN CLOCKS DURING PREGNANCY AND POSTNATAL DEVELOPMENT IS STILL POORLY DEFINED. A BETTER UNDERSTANDING OF THE CIRCADIAN-STRESS CROSSTALK AT DIFFERENT PERIODS OF DEVELOPMENT MAY HELP TO IMPROVE STRESS RESISTANCE AND DEVISE PREVENTIVE AND THERAPEUTIC STRATEGIES AGAINST CHRONIC STRESS-ASSOCIATED DISORDERS. 2018 3 5812 38 STRESS AND ANXIETY: STRUCTURAL PLASTICITY AND EPIGENETIC REGULATION AS A CONSEQUENCE OF STRESS. 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, AS WELL AS DEVELOPING BRAIN, POSSESS A REMARKABLE ABILITY TO SHOW REVERSIBLE STRUCTURAL AND FUNCTIONAL PLASTICITY IN RESPONSE TO STRESSFUL AND OTHER EXPERIENCES, INCLUDING NEURONAL REPLACEMENT, DENDRITIC REMODELING, AND SYNAPSE TURNOVER. THIS IS PARTICULARLY EVIDENT IN THE HIPPOCAMPUS, WHERE ALL THREE TYPES OF STRUCTURAL PLASTICITY HAVE BEEN RECOGNIZED AND INVESTIGATED, USING A COMBINATION OF MORPHOLOGICAL, MOLECULAR, PHARMACOLOGICAL, ELECTROPHYSIOLOGICAL AND BEHAVIORAL APPROACHES. THE AMYGDALA AND THE PREFRONTAL CORTEX, BRAIN REGIONS INVOLVED IN ANXIETY AND FEAR, MOOD, COGNITIVE FUNCTION AND BEHAVIORAL CONTROL, ALSO SHOW STRUCTURAL PLASTICITY. ACUTE AND CHRONIC STRESS CAUSE AN IMBALANCE OF NEURAL CIRCUITRY SUBSERVING COGNITION, DECISION MAKING, ANXIETY AND MOOD THAT CAN INCREASE OR DECREASE EXPRESSION OF THOSE BEHAVIORS AND BEHAVIORAL STATES. IN THE SHORT TERM, SUCH 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 OR MOOD ANXIETY DISORDERS. WE SHALL REVIEW CELLULAR AND MOLECULAR MECHANISMS, AS WELL AS RECENT WORK ON INDIVIDUAL DIFFERENCES IN ANXIETY-LIKE BEHAVIOR AND ALSO DEVELOPMENTAL INFLUENCES THAT BIAS HOW THE BRAIN RESPONDS TO STRESSORS. FINALLY, WE SUGGEST THAT SUCH AN APPROACH NEEDS TO BE EXTENDED TO OTHER BRAIN AREAS THAT ARE ALSO INVOLVED IN ANXIETY AND MOOD. THIS ARTICLE IS PART OF A SPECIAL ISSUE ENTITLED 'ANXIETY AND DEPRESSION'. 2012 4 4632 32 NEUROIMAGING GENETIC APPROACHES TO POSTTRAUMATIC STRESS DISORDER. NEUROIMAGING GENETIC STUDIES THAT ASSOCIATE GENETIC AND EPIGENETIC VARIATION WITH NEURAL ACTIVITY OR STRUCTURE PROVIDE AN OPPORTUNITY TO LINK GENES TO PSYCHIATRIC DISORDERS, OFTEN BEFORE PSYCHOPATHOLOGY IS DISCERNABLE IN BEHAVIOR. HERE WE REVIEW NEUROIMAGING GENETICS STUDIES WITH PARTICIPANTS WHO HAVE POSTTRAUMATIC STRESS DISORDER (PTSD). RESULTS SHOW THAT GENES RELATED TO THE PHYSIOLOGICAL STRESS RESPONSE (E.G., GLUCOCORTICOID RECEPTOR AND ACTIVITY, NEUROENDOCRINE RELEASE), LEARNING AND MEMORY (E.G., PLASTICITY), MOOD, AND PAIN PERCEPTION ARE TIED TO NEURAL INTERMEDIATE PHENOTYPES ASSOCIATED WITH PTSD. THESE GENES ARE ASSOCIATED WITH AND SOMETIMES PREDICT NEURAL STRUCTURE AND FUNCTION IN AREAS INVOLVED IN ATTENTION, EXECUTIVE FUNCTION, MEMORY, DECISION-MAKING, EMOTION REGULATION, SALIENCE OF POTENTIAL THREATS, AND PAIN PERCEPTION. EVIDENCE SUGGESTS THESE RISK POLYMORPHISMS AND NEURAL INTERMEDIATE PHENOTYPES ARE VULNERABILITIES TOWARD DEVELOPING PTSD IN THE AFTERMATH OF TRAUMA, OR VULNERABILITIES TOWARD PARTICULAR SYMPTOMS ONCE PTSD HAS DEVELOPED. WORK DISTINGUISHING BETWEEN THE RE-EXPERIENCING AND DISSOCIATIVE SUB-TYPES OF PTSD, AND EXAMINING OTHER PTSD SYMPTOM CLUSTERS IN ADDITION TO THE RE-EXPERIENCING AND HYPERAROUSAL SYMPTOMS, WILL FURTHER CLARIFY NEUROBIOLOGICAL MECHANISMS AND INCONSISTENT FINDINGS. FURTHERMORE, AN EXCITING POSSIBILITY IS THAT GENETIC ASSOCIATIONS WITH PTSD MAY EVENTUALLY BE UNDERSTOOD THROUGH DIFFERENTIAL INTERMEDIATE PHENOTYPES OF NEURAL CIRCUIT STRUCTURE AND FUNCTION, POSSIBLY UNDERLYING THE DIFFERENT SYMPTOM CLUSTERS SEEN WITHIN PTSD. 2016 5 235 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 6 23 33 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 7 1877 18 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 8 4222 30 METHYLATION AT THE CPG ISLAND SHORE REGION UPREGULATES NR3C1 PROMOTER ACTIVITY AFTER EARLY-LIFE STRESS. EARLY-LIFE STRESS (ELS) INDUCES LONG-LASTING CHANGES IN GENE EXPRESSION CONFERRING AN INCREASED RISK FOR THE DEVELOPMENT OF STRESS-RELATED MENTAL DISORDERS. GLUCOCORTICOID RECEPTORS (GR) MEDIATE THE NEGATIVE FEEDBACK ACTIONS OF GLUCOCORTICOIDS (GC) IN THE PARAVENTRICULAR NUCLEUS (PVN) OF THE HYPOTHALAMUS AND ANTERIOR PITUITARY AND THEREFORE PLAY A KEY ROLE IN THE REGULATION OF THE HYPOTHALAMIC-PITUITARY-ADRENAL (HPA) AXIS AND THE ENDOCRINE RESPONSE TO STRESS. WE HERE SHOW THAT ELS PROGRAMS THE EXPRESSION OF THE GR GENE (NR3C1) BY SITE-SPECIFIC HYPERMETHYLATION AT THE CPG ISLAND (CGI) SHORE IN HYPOTHALAMIC NEURONS THAT PRODUCE CORTICOTROPIN-RELEASING HORMONE (CRH), THUS PREVENTING CRH UPREGULATION UNDER CONDITIONS OF CHRONIC STRESS. CPGS MAPPING TO THE NR3C1 CGI SHORE REGION ARE DYNAMICALLY REGULATED BY ELS AND UNDERPIN METHYLATION-SENSITIVE CONTROL OF THIS REGION'S INSULATION-LIKE FUNCTION VIA YING YANG 1 (YY1) BINDING. OUR RESULTS PROVIDE NEW INSIGHT INTO HOW A GENOMIC ELEMENT INTEGRATES EXPERIENCE-DEPENDENT EPIGENETIC PROGRAMMING OF THE COMPOSITE PROXIMAL NR3C1 PROMOTER, AND ASSIGNS AN INSULATING ROLE TO THE CGI SHORE. 2015 9 1750 20 EARLY LIFE STRESS AND PEDIATRIC POSTTRAUMATIC STRESS DISORDER. TRAUMATIC STRESS EXPOSURE DURING CRITICAL PERIODS OF DEVELOPMENT MAY HAVE ESSENTIAL AND LONG-LASTING EFFECTS ON THE PHYSICAL AND MENTAL HEALTH OF INDIVIDUALS. TWO THIRDS OF YOUTH ARE EXPOSED TO POTENTIALLY TRAUMATIC EXPERIENCES BY THE AGE OF 17, AND APPROXIMATELY 5% OF ADOLESCENTS MEET LIFETIME CRITERIA FOR POSTTRAUMATIC STRESS DISORDER (PTSD). THE ROLE OF THE STRESS SYSTEM IS THE MAINTENANCE OF HOMEOSTASIS IN THE PRESENCE OF REAL/PERCEIVED AND ACUTE/CHRONIC STRESSORS. EARLY-LIFE STRESS (ELS) HAS AN IMPACT ON NEURONAL BRAIN NETWORKS INVOLVED IN STRESS REACTIONS, AND COULD EXERT A PROGRAMMING EFFECT ON GLUCOCORTICOID SIGNALING. STUDIES ON PEDIATRIC PTSD REVEAL DIVERSE NEUROENDOCRINE RESPONSES TO ADVERSE EVENTS AND RELATED LONG-TERM NEUROENDOCRINE AND EPIGENETIC ALTERATIONS. NEUROENDOCRINE, NEUROIMAGING, AND GENETIC STUDIES IN CHILDREN WITH PTSD AND ELS EXPERIENCES ARE CRUCIAL IN UNDERSTANDING RISK AND RESILIENCE FACTORS, AND ALSO THE NATURAL HISTORY OF PTSD. 2020 10 5876 28 SYNAPTIC PLASTICITY AND PAIN AVERSION. NEGATIVE AFFECTIVE EMOTIONS ARE DEFINED AS THE CONCEPTUAL FEATURE OF PAIN. A NUMBER OF CLINICAL AND ANIMAL STUDIES HAVE INDICATED THAT THE LIMBIC SYSTEM INCLUDING THE ANTERIOR CINGULATE CORTEX (ACC) AND AMYGDALA PLAYS A CRITICAL ROLE IN THE PROCESSING OF AFFECTIVE COMPONENTS OF PAIN. GLUTAMATERGIC TRANSMISSION PLAYS AN IMPORTANT ROLE IN THE PROCESSING OF AFFECTIVE ASPECTS OF PAIN. LONG-TERM CHANGES ON GLUTAMATERGIC SYNAPSES CONTRIBUTE TO THE EXPRESSION OF AVERSION BEHAVIOR INDUCED BY PAIN. IN THIS ARTICLE, THE NEUROCIRCUITS INVOLVED IN THE PROCESSING OF AFFECTIVE ASPECTS OF PAIN, THE GLUTAMATERGIC SYNAPTIC PLASTICITY IN THESE BRAIN REGIONS, AND THE EPIGENETIC MECHANISMS UNDERLYING PAIN-RELATED SYNAPTIC PLASTICITY WILL BE REVIEWED AND DISCUSSED. NEW DISCOVERIES REGARDING THE INTERACTION BETWEEN THE SYNAPTIC PLASTICITY AND AFFECTIVE COMPONENTS OF PAIN MAY ADVANCE OUR UNDERSTANDING ON THE PAIN MECHANISM, AND LEAD TO NEW STRATEGIES FOR PAIN TREATMENT. 2011 11 2269 40 EPIGENETIC PROGRAMMING OF THE NEUROENDOCRINE STRESS RESPONSE BY ADULT LIFE STRESS. THE HYPOTHALAMIC-PITUITARY-ADRENAL (HPA) AXIS IS CRITICALLY INVOLVED IN THE NEUROENDOCRINE REGULATION OF STRESS ADAPTATION, AND THE RESTORATION OF HOMEOSTASIS FOLLOWING STRESS EXPOSURE. DYSREGULATION OF THIS AXIS IS ASSOCIATED WITH STRESS-RELATED PATHOLOGIES LIKE MAJOR DEPRESSIVE DISORDER, POST-TRAUMATIC STRESS DISORDER, PANIC DISORDER AND CHRONIC ANXIETY. IT HAS LONG BEEN UNDERSTOOD THAT STRESS DURING EARLY LIFE CAN HAVE A SIGNIFICANT LASTING INFLUENCE ON THE DEVELOPMENT OF THE NEUROENDOCRINE SYSTEM AND ITS NEURAL REGULATORS, PARTIALLY BY MODIFYING EPIGENETIC REGULATION OF GENE EXPRESSION, WITH IMPLICATIONS FOR HEALTH AND WELL-BEING IN LATER LIFE. EVIDENCE IS ACCUMULATING THAT EPIGENETIC PLASTICITY ALSO EXTENDS TO ADULTHOOD, PROPOSING IT AS A MECHANISM BY WHICH PSYCHOLOGICAL TRAUMA LATER IN LIFE CAN LONG-LASTINGLY AFFECT HPA AXIS FUNCTION, BRAIN PLASTICITY, NEURONAL FUNCTION AND BEHAVIOURAL ADAPTATION TO NEUROPSYCHOLOGICAL STRESS. FURTHER CORROBORATING THIS CLAIM IS THE PHENOMENON THAT THESE EPIGENETIC CHANGES CORRELATE WITH THE BEHAVIOURAL CONSEQUENCES OF TRAUMA EXPOSURE. THEREBY, EPIGENETIC MODIFICATIONS PROVIDE A PUTATIVE MOLECULAR MECHANISM BY WHICH THE BEHAVIOURAL PHENOTYPE AND TRANSCRIPTIONAL/TRANSLATIONAL POTENTIAL OF GENES INVOLVED IN HPA AXIS REGULATION CAN CHANGE DRASTICALLY IN RESPONSE TO ENVIRONMENTAL CHALLENGES, AND APPEAR AN IMPORTANT TARGET FOR TREATMENT OF STRESS-RELATED DISORDERS. HOWEVER, IMPROVED INSIGHT IS REQUIRED TO INCREASE THEIR THERAPEUTIC (DRUG) POTENTIAL. HERE, WE PROVIDE AN OVERVIEW OF THE GROWING BODY OF LITERATURE DESCRIBING THE EPIGENETIC MODULATION OF THE (PRIMARILY NEUROENDOCRINE) STRESS RESPONSE AS A CONSEQUENCE OF ADULT LIFE STRESS AND INTERPRET THE IMPLICATIONS FOR, AND THE CHALLENGES INVOLVED IN APPLYING THIS KNOWLEDGE TO, THE IDENTIFICATION AND TREATMENT OF STRESS-RELATED PSYCHIATRIC DISORDERS. 2017 12 2949 25 GENETIC AND EPIGENETIC CONSEQUENCE OF EARLY-LIFE SOCIAL STRESS ON DEPRESSION: ROLE OF SEROTONIN-ASSOCIATED GENES. EARLY-LIFE ADVERSITY CAUSED BY POOR SOCIAL BONDING AND DEPRIVED MATERNAL CARE IS KNOWN TO AFFECT MENTAL WELLBEING AND PHYSICAL HEALTH. IT IS A FORM OF CHRONIC SOCIAL STRESS THAT PERSISTS BECAUSE OF A NEGATIVE ENVIRONMENT, AND THE CONSEQUENCES ARE LONG-LASTING ON MENTAL HEALTH. THE PRESENCE OF SOCIAL STRESS DURING EARLY LIFE CAN HAVE AN EPIGENETIC EFFECT ON THE BODY, POSSIBLY RESULTING IN MANY COMPLEX MENTAL DISORDERS, INCLUDING DEPRESSION IN LATER LIFE. HERE, WE REVIEW THE EVIDENCE FOR EARLY-LIFE SOCIAL STRESS-INDUCED EPIGENETIC CHANGES THAT MODULATE JUVENILE AND ADULT SOCIAL BEHAVIOR (DEPRESSION AND ANXIETY). THIS REVIEW HAS A PARTICULAR EMPHASIS ON THE INTERACTION BETWEEN EARLY-LIFE SOCIAL STRESS AND GENETIC VARIATION OF SEROTONIN ASSOCIATE GENES INCLUDING THE SEROTONIN TRANSPORTER GENE (5-HTT; ALSO KNOWN AS SLC6A4), WHICH ARE KEY MOLECULES INVOLVED IN DEPRESSION. 2020 13 4621 33 NEUROBIOLOGICAL AND SYSTEMIC EFFECTS OF CHRONIC STRESS. 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, WHICH PROMOTE ADAPTATION ("ALLOSTASIS") BUT ALSO CONTRIBUTE TO PATHOPHYSIOLOGY ("ALLOSTATIC LOAD/OVERLOAD") WHEN OVERUSED AND DYSREGULATED. THE ADULT AS WELL AS DEVELOPING BRAIN POSSESSES A REMARKABLE ABILITY TO SHOW STRUCTURAL AND FUNCTIONAL PLASTICITY IN RESPONSE TO STRESSFUL AND OTHER EXPERIENCES, INCLUDING NEURONAL REPLACEMENT, DENDRITIC REMODELING AND SYNAPSE TURNOVER. STRESS CAN CAUSE AN IMBALANCE OF NEURAL CIRCUITRY SUBSERVING COGNITION, DECISION MAKING, ANXIETY AND MOOD THAT CAN INCREASE OR DECREASE 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, THESE CHANGES MAY BE ADAPTIVE; BUT, IF THE THREAT PASSES AND THE BEHAVIORAL STATE PERSISTS ALONG WITH THE CHANGES IN NEURAL CIRCUITRY, SUCH MALADAPTATION REQUIRES INTERVENTION WITH A COMBINATION OF PHARMACOLOGICAL AND BEHAVIORAL THERAPIES. THERE ARE IMPORTANT SEX DIFFERENCES IN HOW THE BRAIN RESPONDS TO STRESSORS. MOREOVER, ADVERSE EARLY LIFE EXPERIENCE, INTERACTING WITH ALLELES OF CERTAIN GENES, PRODUCES LASTING EFFECTS ON BRAIN AND BODY VIA EPIGENETIC MECHANISMS. WHILE PREVENTION IS KEY, THE PLASTICITY OF THE BRAIN GIVES HOPE FOR THERAPIES THAT UTILIZE BRAIN-BODY INTERACTIONS. POLICIES OF GOVERNMENT AND THE PRIVATE SECTOR ARE IMPORTANT TO PROMOTE HEALTH AND INCREASE "HEALTHSPAN." 2017 14 5310 21 PSYCHOBIOLOGY AND MOLECULAR GENETICS OF RESILIENCE. EVERY INDIVIDUAL EXPERIENCES STRESSFUL LIFE EVENTS. IN SOME CASES ACUTE OR CHRONIC STRESS LEADS TO DEPRESSION AND OTHER PSYCHIATRIC DISORDERS, BUT MOST PEOPLE ARE RESILIENT TO SUCH EFFECTS. RECENT RESEARCH HAS BEGUN TO IDENTIFY THE ENVIRONMENTAL, GENETIC, EPIGENETIC AND NEURAL MECHANISMS THAT UNDERLIE RESILIENCE, AND HAS SHOWN THAT RESILIENCE IS MEDIATED BY ADAPTIVE CHANGES IN SEVERAL NEURAL CIRCUITS INVOLVING NUMEROUS NEUROTRANSMITTER AND MOLECULAR PATHWAYS. THESE CHANGES SHAPE THE FUNCTIONING OF THE NEURAL CIRCUITS THAT REGULATE REWARD, FEAR, EMOTION REACTIVITY AND SOCIAL BEHAVIOUR, WHICH TOGETHER ARE THOUGHT TO MEDIATE SUCCESSFUL COPING WITH STRESS. 2009 15 3972 26 LONG-TERM BEHAVIORAL AND CELL-TYPE-SPECIFIC MOLECULAR EFFECTS OF EARLY LIFE STRESS ARE MEDIATED BY H3K79ME2 DYNAMICS IN MEDIUM SPINY NEURONS. ANIMALS SUSCEPTIBLE TO CHRONIC SOCIAL DEFEAT STRESS (CSDS) EXHIBIT DEPRESSION-RELATED BEHAVIORS, WITH ABERRANT TRANSCRIPTION ACROSS SEVERAL LIMBIC BRAIN REGIONS, MOST NOTABLY IN THE NUCLEUS ACCUMBENS (NAC). EARLY LIFE STRESS (ELS) PROMOTES SUSCEPTIBILITY TO CSDS IN ADULTHOOD, BUT ASSOCIATED ENDURING CHANGES IN TRANSCRIPTIONAL CONTROL MECHANISMS IN THE NAC HAVE NOT YET BEEN INVESTIGATED. IN THIS STUDY, WE EXAMINED LONG-LASTING CHANGES TO HISTONE MODIFICATIONS IN THE NAC OF MALE AND FEMALE MICE EXPOSED TO ELS. DIMETHYLATION OF LYSINE 79 OF HISTONE H3 (H3K79ME2) AND THE ENZYMES (DOT1L AND KDM2B) THAT CONTROL THIS MODIFICATION ARE ENRICHED IN D2-TYPE MEDIUM SPINY NEURONS AND ARE SHOWN TO BE CRUCIAL FOR THE EXPRESSION OF ELS-INDUCED STRESS SUSCEPTIBILITY. WE MAPPED THE SITE-SPECIFIC REGULATION OF THIS HISTONE MARK GENOME WIDE TO REVEAL THE TRANSCRIPTIONAL NETWORKS IT MODULATES. FINALLY, SYSTEMIC DELIVERY OF A SMALL MOLECULE INHIBITOR OF DOT1L REVERSED ELS-INDUCED BEHAVIORAL DEFICITS, INDICATING THE CLINICAL RELEVANCE OF THIS EPIGENETIC MECHANISM. 2021 16 4420 24 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 1740 29 EARLY ENRICHED ENVIRONMENT PREVENTS EPIGENETIC P11 GENE CHANGES INDUCED BY ADULTHOOD STRESS IN MICE. POSITIVE EXPERIENCES IN EARLY LIFE MAY IMPROVE THE CAPACITY TO COPE WITH ADULTHOOD STRESS THROUGH EPIGENETIC MODIFICATION. WE INVESTIGATED WHETHER AN ENRICHED ENVIRONMENT (EE) IN THE POSTNATAL PERIOD AFFECTED EPIGENETIC CHANGES IN THE P11 GENE INDUCED BY CHRONIC UNPREDICTABLE STRESS (CUS) IN ADULT C57BL/6J MICE. EE WAS INTRODUCED FOR 5 WEEKS DURING POSTNATAL DAYS 21-55. AFTER EE, THE MICE WERE SUBJECTED TO CUS FOR 4 WEEKS. EE PREVENTED DEPRESSION-LIKE BEHAVIOR INDUCED BY ADULT CUS. EE PREVENTED A DECREASE IN P11 MRNA AND HISTONE H3 ACETYLATION INDUCED BY CUS, WITH CHANGES IN THE EXPRESSION OF HISTONE DEACETYLASE 5. MOREOVER, EE PREVENTED CHANGES IN TRIMETHYLATION OF HISTONE H3 LYSINE 4 (H3K4) AND H3K27 INDUCED BY CUS. FURTHERMORE, EE HAD POSITIVE EFFECTS ON BEHAVIOR AND EPIGENETIC ALTERATIONS IN ADULT MICE WITHOUT CUS. THESE RESULTS SUGGEST THAT ONE OF THE UNDERLYING MECHANISMS OF EARLY-LIFE EE MAY INVOLVE EPIGENETIC MODIFICATION OF THE HIPPOCAMPAL P11 GENE PROMOTER. 2021 18 4064 32 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 19 3092 28 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 20 3313 28 HIPPOCAMPAL BDNF IN PHYSIOLOGICAL CONDITIONS AND SOCIAL ISOLATION. EXPOSURE OF AN ORGANISM TO CHRONIC PSYCHOSOCIAL STRESS MAY AFFECT BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) EXPRESSION THAT HAS BEEN IMPLICATED IN THE ETIOLOGY OF PSYCHIATRIC DISORDERS, SUCH AS DEPRESSION. GIVEN THAT DEPRESSION IN HUMANS HAS BEEN LINKED WITH SOCIAL STRESS, THE CHRONIC SOCIAL STRESS PARADIGMS FOR MODELING PSYCHIATRIC DISORDERS IN ANIMALS HAVE THUS BEEN DEVELOPED. CHRONIC SOCIAL ISOLATION IN ANIMAL MODELS GENERALLY CAUSES CHANGES IN HYPOTHALAMIC-PITUITARY-ADRENAL AXIS FUNCTIONING, ASSOCIATED WITH ANXIETY- AND DEPRESSIVE-LIKE BEHAVIORS. ALSO, THIS CHRONIC STRESS CAUSES DOWNREGULATION OF BDNF PROTEIN AND MRNA IN THE HIPPOCAMPUS, A STRESS-SENSITIVE BRAIN REGION CLOSELY RELATED TO THE PATHOPHYSIOLOGY OF DEPRESSION. IN THIS REVIEW, WE DISCUSS THE CURRENT KNOWLEDGE REGARDING THE STRUCTURE, FUNCTION, INTRACELLULAR SIGNALING, INTER-INDIVIDUAL DIFFERENCES AND EPIGENETIC REGULATION OF BDNF IN BOTH PHYSIOLOGICAL CONDITIONS AND DEPRESSION AND CHANGES IN CORTICOSTERONE LEVELS, AS A MARKER OF STRESS RESPONSE. SINCE BDNF LEVELS ARE AGE DEPENDENT IN HUMANS AND RODENTS, THIS REVIEW WILL ALSO HIGHLIGHT THE EFFECTS OF ADOLESCENT AND ADULT CHRONIC SOCIAL ISOLATION MODELS OF BOTH GENDERS ON THE BDNF EXPRESSION. 2017