1 193 98 ACETYLATION-MEDIATED EPIGENETIC REGULATION OF GLUCOCORTICOID RECEPTOR ACTIVITY: CIRCADIAN RHYTHM-ASSOCIATED ALTERATIONS OF GLUCOCORTICOID ACTIONS IN TARGET TISSUES. GLUCOCORTICOIDS INFLUENCE ORGAN FUNCTIONS THROUGH THE GLUCOCORTICOID RECEPTOR, A PROTEIN ACETYLATED AND DEACETYLATED BY SEVERAL HISTONE ACETYLTRANSFERASES AND DEACETYLASES. WE REPORTED THAT THE CIRCADIAN RHYTHM-RELATED TRANSCRIPTION FACTOR "CLOCK", A KEY COMPONENT OF THE BIOLOGICAL CLOCK WITH INHERENT HISTONE ACETYLTRANSFERASE ACTIVITY, ACETYLATES GLUCOCORTICOID RECEPTOR LYSINES WITHIN ITS HINGE REGION--A "LYSINE CLUSTER" CONTAINING A KXKK MOTIF--AND REPRESSES ITS TRANSCRIPTIONAL ACTIVITY. THIS CLOCK-INDUCED REPRESSION OF THE GLUCOCORTICOID RECEPTOR ACTIVITY IS INVERSELY PHASED TO THE DIURNALLY CIRCULATING GLUCOCORTICOIDS AND MAY ACT AS A LOCAL COUNTER REGULATORY MECHANISM TO THE ACTIONS OF THESE HORMONES. IMPORTANTLY, UNCOUPLING OF THE CENTRAL CLOCK-REGULATED HYPOTHALAMIC-PITUITARY-ADRENAL AXIS AND PERIPHERAL CLOCK-MEDIATED ALTERATIONS OF GLUCOCORTICOID ACTION, SUCH AS CHRONIC STRESS AND FREQUENT TRANS-TIME ZONE TRAVEL OR NIGHT-SHIFT WORK, MAY CAUSE FUNCTIONAL HYPERCORTISOLISM AND CONTRIBUTE TO VARIOUS PATHOLOGIES. THUS, ACETYLATION-MEDIATED EPIGENETIC REGULATION OF THE GLUCOCORTICOID RECEPTOR MAY BE ESSENTIAL FOR THE MAINTENANCE OF PROPER TIME-INTEGRATED GLUCOCORTICOID ACTION, SIGNIFICANTLY INFLUENCING HUMAN WELL-BEING AND LONGEVITY. 2011 2 195 27 ACF CHROMATIN-REMODELING COMPLEX MEDIATES STRESS-INDUCED DEPRESSIVE-LIKE BEHAVIOR. IMPROVED TREATMENT FOR MAJOR DEPRESSIVE DISORDER (MDD) REMAINS ELUSIVE BECAUSE OF THE LIMITED UNDERSTANDING OF ITS UNDERLYING BIOLOGICAL MECHANISMS. IT IS LIKELY THAT STRESS-INDUCED MALADAPTIVE TRANSCRIPTIONAL REGULATION IN LIMBIC NEURAL CIRCUITS CONTRIBUTES TO THE DEVELOPMENT OF MDD, POSSIBLY THROUGH EPIGENETIC FACTORS THAT REGULATE CHROMATIN STRUCTURE. WE ESTABLISH THAT PERSISTENT UPREGULATION OF THE ACF (ATP-UTILIZING CHROMATIN ASSEMBLY AND REMODELING FACTOR) ATP-DEPENDENT CHROMATIN-REMODELING COMPLEX, OCCURRING IN THE NUCLEUS ACCUMBENS OF STRESS-SUSCEPTIBLE MICE AND DEPRESSED HUMANS, IS NECESSARY FOR STRESS-INDUCED DEPRESSIVE-LIKE BEHAVIORS. WE FOUND THAT ALTERED ACF BINDING AFTER CHRONIC STRESS WAS CORRELATED WITH ALTERED NUCLEOSOME POSITIONING, PARTICULARLY AROUND THE TRANSCRIPTION START SITES OF AFFECTED GENES. THESE ALTERATIONS IN ACF BINDING AND NUCLEOSOME POSITIONING WERE ASSOCIATED WITH REPRESSED EXPRESSION OF GENES IMPLICATED IN SUSCEPTIBILITY TO STRESS. TOGETHER, OUR FINDINGS IDENTIFY THE ACF CHROMATIN-REMODELING COMPLEX AS A CRITICAL COMPONENT IN THE DEVELOPMENT OF SUSCEPTIBILITY TO DEPRESSION AND IN REGULATING STRESS-RELATED BEHAVIORS. 2015 3 2246 23 EPIGENETIC MODULATION OF INFLAMMATION AND SYNAPTIC PLASTICITY PROMOTES RESILIENCE AGAINST STRESS IN MICE. MAJOR DEPRESSIVE DISORDER IS ASSOCIATED WITH ABNORMALITIES IN THE BRAIN AND THE IMMUNE SYSTEM. CHRONIC STRESS IN ANIMALS SHOWED THAT EPIGENETIC AND INFLAMMATORY MECHANISMS PLAY IMPORTANT ROLES IN MEDIATING RESILIENCE AND SUSCEPTIBILITY TO DEPRESSION. HERE, THROUGH A HIGH-THROUGHPUT SCREENING, WE IDENTIFY TWO PHYTOCHEMICALS, DIHYDROCAFFEIC ACID (DHCA) AND MALVIDIN-3'-O-GLUCOSIDE (MAL-GLUC) THAT ARE EFFECTIVE IN PROMOTING RESILIENCE AGAINST STRESS BY MODULATING BRAIN SYNAPTIC PLASTICITY AND PERIPHERAL INFLAMMATION. DHCA/MAL-GLUC ALSO SIGNIFICANTLY REDUCES DEPRESSION-LIKE PHENOTYPES IN A MOUSE MODEL OF INCREASED SYSTEMIC INFLAMMATION INDUCED BY TRANSPLANTATION OF HEMATOPOIETIC PROGENITOR CELLS FROM STRESS-SUSCEPTIBLE MICE. DHCA REDUCES PRO-INFLAMMATORY INTERLEUKIN 6 (IL-6) GENERATIONS BY INHIBITING DNA METHYLATION AT THE CPG-RICH IL-6 SEQUENCES INTRONS 1 AND 3, WHILE MAL-GLUC MODULATES SYNAPTIC PLASTICITY BY INCREASING HISTONE ACETYLATION OF THE REGULATORY SEQUENCES OF THE RAC1 GENE. PERIPHERAL INFLAMMATION AND SYNAPTIC MALADAPTATION ARE IN LINE WITH NEWLY HYPOTHESIZED CLINICAL INTERVENTION TARGETS FOR DEPRESSION THAT ARE NOT ADDRESSED BY CURRENTLY AVAILABLE ANTIDEPRESSANTS. 2018 4 3002 24 GENETIC, EPIGENETIC AND POSTTRANSCRIPTIONAL MECHANISMS FOR TREATMENT OF MAJOR DEPRESSION: THE 5-HT1A RECEPTOR GENE AS A PARADIGM. MAJOR DEPRESSION AND ANXIETY ARE HIGHLY PREVALENT AND INVOLVE CHRONIC DYSREGULATION OF SEROTONIN, BUT THEY REMAIN POORLY UNDERSTOOD. HERE, WE REVIEW NOVEL TRANSCRIPTIONAL (GENETIC, EPIGENETIC) AND POSTTRANSCRIPTIONAL (MICRORNA, ALTERNATIVE SPLICING) MECHANISMS IMPLICATED IN MENTAL ILLNESS, FOCUSING ON A KEY SEROTONIN-RELATED REGULATOR, THE SEROTONIN 1A (5-HT1A) RECEPTOR. FUNCTIONAL SINGLE-NUCLEOTIDE POLYMORPHISMS AND STRESS-INDUCED DNA METHYLATION OF THE 5-HT1A PROMOTER CONVERGE TO DIFFERENTIALLY ALTER PRE- AND POSTSYNAPTIC 5-HT1A RECEPTOR EXPRESSION ASSOCIATED WITH MAJOR DEPRESSION AND REDUCED THERAPEUTIC RESPONSE TO SEROTONERGIC ANTIDEPRESSANTS. MAJOR DEPRESSION IS ALSO ASSOCIATED WITH ALTERED LEVELS OF SPLICE FACTORS AND MICRORNA, POSTTRANSCRIPTIONAL MECHANISMS THAT REGULATE RNA STABILITY. THE HUMAN 5-HT1A 3'-UNTRANSLATED REGION IS ALTERNATIVELY SPLICED, REMOVING MICRORNA SITES AND INCREASING 5-HT1A EXPRESSION, WHICH IS REDUCED IN MAJOR DEPRESSION AND MAY BE GENOTYPE-DEPENDENT. THUS, THE 5-HT1A RECEPTOR GENE ILLUSTRATES THE CONVERGENCE OF GENETIC, EPIGENETIC AND POSTTRANSCRIPTIONAL MECHANISMS IN GENE EXPRESSION, NEURODEVELOPMENT AND NEUROPLASTICITY, AND MAJOR DEPRESSION. UNDERSTANDING GENE REGULATORY MECHANISMS COULD ENHANCE THE DETECTION, CATEGORIZATION AND PERSONALIZED TREATMENT OF MAJOR DEPRESSION. 2019 5 5832 22 STRESS-INDUCED EPIGENETIC CHANGES IN HIPPOCAMPAL MKP-1 PROMOTE PERSISTENT DEPRESSIVE BEHAVIORS. CHRONIC STRESS INDUCES PERSISTENT DEPRESSIVE BEHAVIORS. STRESS-INDUCED TRANSCRIPTIONAL ALTERATION OVER THE HOMEOSTATIC RANGE IN STRESS HORMONE-SENSITIVE BRAIN REGIONS IS BELIEVED TO UNDERLIE LONG-LASTING DEPRESSIVE BEHAVIORS. HOWEVER, THE DETAILED MECHANISMS BY WHICH CHRONIC STRESS CAUSES THOSE ADAPTIVE CHANGES ARE NOT CLEARLY UNDERSTOOD. IN THE PRESENT STUDY, WE INVESTIGATED WHETHER EPIGENETIC CHANGES REGULATE STRESS-INDUCED DEPRESSIVE BEHAVIORS. WE FOUND THAT CHRONIC STRESS IN MICE DOWNREGULATES THE EPIGENETIC FACTORS HDAC2 AND SUV39H1 IN THE HIPPOCAMPUS. A SERIES OF FOLLOW-UP ANALYSES INCLUDING CHIP ASSAY AND SIRNA-MEDIATED FUNCTIONAL ANALYSES REVEAL THAT GLUCOCORTICOIDS RELEASED BY STRESS CUMULATIVELY INCREASE MKP-1 EXPRESSION IN THE HIPPOCAMPUS, AND INCREASED MKP-1 THEN DEBILITATES P-CREB AND PPARGAMMA, WHICH IN TURN SUPPRESS THE EPIGENETIC FACTORS HDAC2 AND SUV39H1. FURTHERMORE, HDAC2 AND SUV39H1 NORMALLY SUPPRESS THE TRANSCRIPTION OF THE MKP-1, AND THEREFORE THE REDUCED EXPRESSION OF HDAC2 AND SUV39H1 INCREASES MKP-1 EXPRESSION. ACCORDINGLY, REPEATED STRESS PROGRESSIVELY STRENGTHENS A VICIOUS CYCLE OF THE MKP-1 SIGNALING CASCADE THAT FACILITATES DEPRESSIVE BEHAVIORS. THESE RESULTS SUGGEST THAT THE HIPPOCAMPAL STRESS ADAPTATION SYSTEM COMPRISING HDAC2/SUV39H1-REGULATED MKP-1 SIGNALING NETWORK DETERMINES THE VULNERABILITY TO CHRONIC STRESS AND THE MAINTENANCE OF DEPRESSIVE BEHAVIORS. 2019 6 984 24 CHRONIC PSYCHOLOGICAL STRESS ALTERS GENE EXPRESSION IN RAT COLON EPITHELIAL CELLS PROMOTING CHROMATIN REMODELING, BARRIER DYSFUNCTION AND INFLAMMATION. CHRONIC STRESS IS COMMONLY ASSOCIATED WITH ENHANCED ABDOMINAL PAIN (VISCERAL HYPERSENSITIVITY), BUT THE CELLULAR MECHANISMS UNDERLYING HOW CHRONIC STRESS INDUCES VISCERAL HYPERSENSITIVITY ARE POORLY UNDERSTOOD. IN THIS STUDY, WE EXAMINED CHANGES IN GENE EXPRESSION IN COLON EPITHELIAL CELLS FROM A RAT MODEL USING RNA-SEQUENCING TO EXAMINE STRESS-INDUCED CHANGES TO THE TRANSCRIPTOME. FOLLOWING CHRONIC STRESS, THE MOST SIGNIFICANTLY UP-REGULATED GENES INCLUDED ATG16L1, COQ10B, DCAF13, NAT2, PTBP2, RRAS2, SPINK4 AND DOWN-REGULATED GENES INCLUDING ABAT, CITED2, CNNM2, DAB2IP, PLEKHM1, SCD2, AND TAB2. THE PRIMARY ALTERED BIOLOGICAL PROCESSES REVEALED BY NETWORK ENRICHMENT ANALYSIS WERE INFLAMMATION/IMMUNE RESPONSE, TISSUE MORPHOGENESIS AND DEVELOPMENT, AND NUCLEOSOME/CHROMATIN ASSEMBLY. THE MOST SIGNIFICANTLY DOWN-REGULATED PROCESS WAS THE DIGESTIVE SYSTEM DEVELOPMENT/FUNCTION, WHEREAS THE MOST SIGNIFICANTLY UP-REGULATED PROCESSES WERE INFLAMMATORY RESPONSE, ORGANISMAL INJURY, AND CHROMATIN REMODELING MEDIATED BY H3K9 METHYLATION. FURTHERMORE, A SUBPOPULATION OF STRESSED RATS DEMONSTRATED VERY SIGNIFICANTLY ALTERED GENE EXPRESSION AND TRANSCRIPT ISOFORMS, ENRICHED FOR THE DIFFERENTIAL EXPRESSION OF GENES INVOLVED IN THE INFLAMMATORY RESPONSE, INCLUDING UPREGULATION OF CYTOKINE AND CHEMOKINE RECEPTOR GENE EXPRESSION COUPLED WITH DOWNREGULATION OF EPITHELIAL ADHERENS AND TIGHT JUNCTION MRNAS. IN SUMMARY, THESE FINDINGS SUPPORT THAT CHRONIC STRESS IS ASSOCIATED WITH INCREASED LEVELS OF CYTOKINES AND CHEMOKINES, THEIR DOWNSTREAM SIGNALING PATHWAYS COUPLED TO DYSREGULATION OF INTESTINAL CELL DEVELOPMENT AND FUNCTION. EPIGENETIC REGULATION OF CHROMATIN REMODELING LIKELY PLAYS A PROMINENT ROLE IN THIS PROCESS. RESULTS ALSO SUGGEST THAT SUPER ENHANCERS PLAY A PRIMARY ROLE IN CHRONIC STRESS-ASSOCIATED INTESTINAL BARRIER DYSFUNCTION. 2022 7 4861 27 ORGANIC ANION TRANSPORTER 1 IS AN HDAC4-REGULATED MEDIATOR OF NOCICEPTIVE HYPERSENSITIVITY IN MICE. PERSISTENT PAIN IS SUSTAINED BY MALADAPTIVE CHANGES IN GENE TRANSCRIPTION RESULTING IN ALTERED FUNCTION OF THE RELEVANT CIRCUITS; THERAPIES ARE STILL UNSATISFACTORY. THE EPIGENETIC MECHANISMS AND AFFECTED GENES LINKING NOCICEPTIVE ACTIVITY TO TRANSCRIPTIONAL CHANGES AND PATHOLOGICAL SENSITIVITY ARE UNCLEAR. HERE, WE FOUND THAT, AMONG SEVERAL HISTONE DEACETYLASES (HDACS), SYNAPTIC ACTIVITY SPECIFICALLY AFFECTS HDAC4 IN MURINE SPINAL CORD DORSAL HORN NEURONS. NOXIOUS STIMULI THAT INDUCE LONG-LASTING INFLAMMATORY HYPERSENSITIVITY CAUSE NUCLEAR EXPORT AND INACTIVATION OF HDAC4. THE DEVELOPMENT OF INFLAMMATION-ASSOCIATED MECHANICAL HYPERSENSITIVITY, BUT NEITHER ACUTE NOR BASAL SENSITIVITY, IS IMPAIRED BY THE EXPRESSION OF A CONSTITUTIVELY NUCLEAR LOCALIZED HDAC4 MUTANT. NEXT GENERATION RNA-SEQUENCING REVEALED AN HDAC4-REGULATED GENE PROGRAM COMPRISING MEDIATORS OF SENSITIZATION INCLUDING THE ORGANIC ANION TRANSPORTER OAT1, KNOWN FOR ITS RENAL TRANSPORT FUNCTION. USING PHARMACOLOGICAL AND MOLECULAR TOOLS TO MODULATE OAT1 ACTIVITY OR EXPRESSION, WE CAUSALLY LINK OAT1 TO PERSISTENT INFLAMMATORY HYPERSENSITIVITY IN MICE. THUS, HDAC4 IS A KEY EPIGENETIC REGULATOR THAT TRANSLATES NOCICEPTIVE ACTIVITY INTO SENSITIZATION BY REGULATING OAT1, WHICH IS A POTENTIAL TARGET FOR PAIN-RELIEVING THERAPIES. 2022 8 5474 28 RESTORATION OF HISTONE ACETYLATION AMELIORATES DISEASE AND METABOLIC ABNORMALITIES IN A FUS MOUSE MODEL. DYSREGULATION OF EPIGENETIC MECHANISMS IS EMERGING AS A CENTRAL EVENT IN NEURODEGENERATIVE DISORDERS, INCLUDING AMYOTROPHIC LATERAL SCLEROSIS (ALS). IN MANY MODELS OF NEURODEGENERATION, GLOBAL HISTONE ACETYLATION IS DECREASED IN THE AFFECTED NEURONAL TISSUES. HISTONE ACETYLATION IS CONTROLLED BY THE ANTAGONISTIC ACTIONS OF TWO PROTEIN FAMILIES -THE HISTONE ACETYLTRANSFERASES (HATS) AND THE HISTONE DEACETYLASES (HDACS). DRUGS INHIBITING HDAC ACTIVITY ARE ALREADY USED IN THE CLINIC AS ANTI-CANCER AGENTS. THE AIM OF THIS STUDY WAS TO EXPLORE THE THERAPEUTIC POTENTIAL OF HDAC INHIBITION IN THE CONTEXT OF ALS. WE DISCOVERED THAT TRANSGENIC MICE OVEREXPRESSING WILD-TYPE FUS ("TG FUS+/+"), WHICH RECAPITULATE MANY ASPECTS OF HUMAN ALS, SHOWED REDUCED GLOBAL HISTONE ACETYLATION AND ALTERATIONS IN METABOLIC GENE EXPRESSION, RESULTING IN A DYSREGULATED METABOLIC HOMEOSTASIS. CHRONIC TREATMENT OF TG FUS+/+ MICE WITH ACY-738, A POTENT HDAC INHIBITOR THAT CAN CROSS THE BLOOD-BRAIN BARRIER, AMELIORATED THE MOTOR PHENOTYPE AND SUBSTANTIALLY EXTENDED THE LIFE SPAN OF THE TG FUS+/+ MICE. AT THE MOLECULAR LEVEL, ACY-738 RESTORED GLOBAL HISTONE ACETYLATION AND METABOLIC GENE EXPRESSION, THEREBY RE-ESTABLISHING METABOLITE LEVELS IN THE SPINAL CORD. TAKEN TOGETHER, OUR FINDINGS LINK EPIGENETIC ALTERATIONS TO METABOLIC DYSREGULATION IN ALS PATHOLOGY, AND HIGHLIGHT ACY-738 AS A POTENTIAL THERAPEUTIC STRATEGY TO TREAT THIS DEVASTATING DISEASE. 2019 9 1162 23 CONTRASTING EFFECTS OF ACUTE AND CHRONIC STRESS ON THE TRANSCRIPTOME, EPIGENOME, AND IMMUNE RESPONSE OF ATLANTIC SALMON. STRESS EXPERIENCED DURING EARLY LIFE MAY HAVE LASTING EFFECTS ON THE IMMUNE SYSTEM, WITH IMPACTS ON HEALTH AND DISEASE DEPENDENT ON THE NATURE AND DURATION OF THE STRESSOR. THE EPIGENOME IS ESPECIALLY SENSITIVE TO ENVIRONMENTAL STIMULI DURING EARLY LIFE AND REPRESENTS A POTENTIAL MECHANISM THROUGH WHICH STRESS MAY CAUSE LONG-LASTING HEALTH EFFECTS. HOWEVER, THE EXTENT TO WHICH THE EPIGENOME RESPONDS DIFFERENTLY TO CHRONIC VS ACUTE STRESSORS IS UNCLEAR, ESPECIALLY FOR NON-MAMMALIAN SPECIES. WE EXAMINED THE EFFECTS OF ACUTE STRESS (COLD-SHOCK DURING EMBRYOGENESIS) AND CHRONIC STRESS (ABSENCE OF TANK ENRICHMENT DURING LARVAL-STAGE) ON GLOBAL GENE EXPRESSION (USING RNA-SEQ) AND DNA METHYLATION (USING RRBS) IN THE GILLS OF ATLANTIC SALMON (SALMO SALAR) FOUR MONTHS AFTER HATCHING. CHRONIC STRESS INDUCED PRONOUNCED TRANSCRIPTIONAL DIFFERENCES, WHILE ACUTE STRESS CAUSED FEW LASTING TRANSCRIPTIONAL EFFECTS. HOWEVER, BOTH ACUTE AND CHRONIC STRESS CAUSED LASTING AND CONTRASTING CHANGES IN THE METHYLOME. CRUCIALLY, WE FOUND THAT ACUTE STRESS ENHANCED TRANSCRIPTIONAL IMMUNE RESPONSE TO A PATHOGENIC CHALLENGE (BACTERIAL LIPOPOLYSACCHARIDE, LPS), WHILE CHRONIC STRESS SUPPRESSED IT. WE IDENTIFIED STRESS-INDUCED CHANGES IN PROMOTER AND GENE-BODY METHYLATION THAT WERE ASSOCIATED WITH ALTERED EXPRESSION FOR A SMALL PROPORTION OF IMMUNE-RELATED GENES, AND EVIDENCE OF WIDER EPIGENETIC REGULATION WITHIN SIGNALLING PATHWAYS INVOLVED IN IMMUNE RESPONSE. OUR RESULTS SUGGEST THAT STRESS CAN AFFECT IMMUNO-COMPETENCE THROUGH EPIGENETIC MECHANISMS, AND HIGHLIGHT THE MARKEDLY DIFFERENT EFFECTS OF CHRONIC LARVAL AND ACUTE EMBRYONIC STRESS. THIS KNOWLEDGE COULD BE USED TO HARNESS THE STIMULATORY EFFECTS OF ACUTE STRESS ON IMMUNITY, PAVING THE WAY FOR IMPROVED STRESS AND DISEASE MANAGEMENT THROUGH EPIGENETIC CONDITIONING. 2018 10 2886 21 GABA-AALPHA5 MIGHT BE INVOLVED IN LEARNING-MEMORY DYSFUNCTION IN THE OFFSPRINGS OF CHRONIC ETHANOL-TREATED RATS VIA GABA-AALPHA5 HISTONE H3K9 ACETYLATION. RECENTLY, NUMEROUS STUDIES HAVE BEEN FOCUSED ON THE RELATIONSHIP BETWEEN GABA-A RECEPTORS AND ALCOHOL-INDUCED SPATIAL LEARNING AND MEMORY DEFICITS. GABA-AALPHA5, A SUBUNIT OF GABA-A RECEPTORS, IS CONSIDERED TO PLAY AN IMPORTANT ROLE IN ALCOHOL-INDUCED COGNITIVE IMPAIRMENT, HOWEVER, THE MECHANISM REMAINS OBSCURE. IN THIS STUDY, WE FOUND THAT THE EXPRESSION OF GABA-AALPHA5 INCREASED IN RATS TREATED WITH CHRONIC ETHANOL VIA HISTONE H3K9 ACETYLATION. FURTHERMORE, THIS EPIGENETIC MODIFICATION COULD BE INHERITED BY THE NEXT GENERATIONS, WHICH EVENTUALLY EXHIBIT SIMILAR SPATIAL LEARNING AND MEMORY DEFICITS IN THE OFFSPRINGS. IN SUMMARY, OUR RESULTS SUGGESTED THAT GABA-AALPHA5 MIGHT BE INVOLVED IN CHRONIC ETHANOL TREATMENT-INDUCED LEARNING-MEMORY DYSFUNCTION AND FOR THE FIRST TIME PROVED THAT LEARNING-MEMORY DYSFUNCTION COULD BE INHERITED BY THE OFFSPRINGS VIA HISTONE H3K9 ACETYLATION. HOPEFULLY, IN THE NEAR FUTURE, GABA-AALPHA5 INHIBITORS WOULD BE AN EFFECTIVE WAY TO TREAT ALCOHOL-INDUCED COGNITION IMPAIRMENT. 2019 11 3465 29 HYPOTHESIS: REGULATION OF NEUROPLASTICITY MAY INVOLVE I-MOTIF AND G-QUADRUPLEX DNA FORMATION MODULATED BY EPIGENETIC MECHANISMS. RECENT STUDIES DEMONSTRATED THE EXISTENCE IN VIVO OF VARIOUS FUNCTIONAL DNA STRUCTURES THAT DIFFER FROM THE DOUBLE HELIX. THE G-QUADRUPLEX (G4) AND INTERCALATED MOTIF (I-MOTIF OR IM) DNA STRUCTURES ARE FORMED AS KNOTS WHERE, CORRESPONDINGLY, GUANINES OR CYTOSINES ON THE SAME STRAND OF DNA BIND TO EACH OTHER. THERE ARE GROUNDS TO BELIEVE THAT G4 AND IM SEQUENCES PLAY A SIGNIFICANT ROLE IN REGULATING GENE EXPRESSION CONSIDERING THEIR TENDENCY TO BE FOUND IN OR NEAR REGULATORY SITES (SUCH AS PROMOTERS, ENHANCERS, AND TELOMERES) AS WELL AS THE CORRELATION BETWEEN THE PREVALENCE OF G4 OR IM CONFORMATIONS AND SPECIFIC PHASES OF CELL CYCLE. NOTABLY, G4 AND IM CAPABLE SEQUENCES TEND TO BE FOUND ON THE OPPOSITE STRANDS OF THE SAME DNA SITE WITH AT MOST ONE OF THE TWO STRUCTURES FORMED AT ANY GIVEN TIME. THE RECENT EVIDENCE THAT K(+), MG(2+) CONCENTRATIONS DIRECTLY AFFECT IM FORMATION (AND LIKELY G4 FORMATION INDIRECTLY) LEAD US TO BELIEVE THAT THESE STRUCTURES MAY PLAY A MAJOR ROLE IN SYNAPTIC PLASTICITY OF NEURONS, AND, THEREFORE, IN A VARIETY OF CENTRAL NERVOUS SYSTEM (CNS) FUNCTIONS INCLUDING MEMORY, LEARNING, HABITUAL BEHAVIORS, PAIN PERCEPTION AND OTHERS. FURTHERMORE, EPIGENETIC MECHANISMS, WHICH HAVE AN IMPORTANT ROLE IN SYNAPTIC PLASTICITY AND MEMORY FORMATION, WERE ALSO SHOWN TO INFLUENCE FORMATION AND STABILITY OF G4S AND IMS. OUR HYPOTHESIS IS THAT NON-CANONICAL DNA AND RNA STRUCTURES COULD BE AN INTEGRAL PART OF NEUROPLASTICITY CONTROL VIA GENE EXPRESSION REGULATION AT THE LEVEL OF TRANSCRIPTION, TRANSLATION AND SPLICING. WE PROPOSE THAT THE REGULATORY ACTIVITY OF DNA IM AND G4 STRUCTURES IS MODULATED BY DNA METHYLATION/DEMETHYLATION OF THE IM AND/OR G4 SEQUENCES, WHICH FACILITATES THE SWITCH BETWEEN CANONICAL AND NON-CANONICAL CONFORMATION. OTHER NEURONAL MECHANISMS INTERACTING WITH THE FORMATION AND REGULATORY ACTIVITY OF NON-CANONICAL DNA AND RNA STRUCTURES, PARTICULARLY G4, IM AND TRIPLEXES, MAY INVOLVE MICRORNAS AS WELL AS ION AND PROTON FLUXES. WE ARE PROPOSING EXPERIMENTS IN ACUTE BRAIN SLICES AND IN VIVO TO TEST OUR HYPOTHESIS. THE PROPOSED STUDIES WOULD PROVIDE NEW INSIGHTS INTO FUNDAMENTAL NEURONAL MECHANISMS IN HEALTH AND DISEASE AND POTENTIALLY OPEN NEW AVENUES FOR TREATING MENTAL HEALTH DISORDERS. 2019 12 4627 23 NEUROENDOCRINOLOGICAL AND EPIGENETIC MECHANISMS SUBSERVING AUTONOMIC IMBALANCE AND HPA DYSFUNCTION IN THE METABOLIC SYNDROME. IMPACT OF ENVIRONMENTAL STRESS UPON PATHOPHYSIOLOGY OF THE METABOLIC SYNDROME (METS) HAS BEEN SUBSTANTIATED BY EPIDEMIOLOGICAL, PSYCHOPHYSIOLOGICAL, AND ENDOCRINOLOGICAL STUDIES. THIS REVIEW DISCUSSES RECENT ADVANCES IN THE UNDERSTANDING OF CAUSATIVE ROLES OF NUTRITIONAL FACTORS, SYMPATHOMEDULLO-ADRENAL (SMA) AND HYPOTHALAMIC-PITUITARY ADRENOCORTICAL (HPA) AXES, AND ADIPOSE TISSUE CHRONIC LOW-GRADE INFLAMMATION PROCESSES IN METS. DISTURBANCES IN THE NEUROENDOCRINE SYSTEMS FOR LEPTIN, MELANOCORTIN, AND NEUROPEPTIDE Y (NPY)/AGOUTI-RELATED PROTEIN SYSTEMS HAVE BEEN FOUND RESULTING DIRECTLY IN METS-LIKE CONDITIONS. THE REVIEW IDENTIFIES CANDIDATE RISK GENES FROM FACTORS SHOWN CRITICAL FOR THE FUNCTIONING OF EACH OF THESE NEUROENDOCRINE SIGNALING CASCADES. IN ITS META-ANALYTIC PART, RECENT STUDIES IN EPIGENETIC MODIFICATION (HISTONE METHYLATION, ACETYLATION, PHOSPHORYLATION, UBIQUITINATION) AND POSTTRANSCRIPTIONAL GENE REGULATION BY MICRORNAS ARE EVALUATED. SEVERAL STUDIES SUGGEST MODIFICATION MECHANISMS OF EARLY LIFE STRESS (ELS) AND DIET-INDUCED OBESITY (DIO) PROGRAMMING IN THE HYPOTHALAMIC REGIONS WITH POPULATIONS OF POMC-EXPRESSING NEURONS. EPIGENETIC MODIFICATIONS WERE FOUND IN CORTISOL (HERE HSD11B1 EXPRESSION), MELANOCORTIN, LEPTIN, NPY, AND ADIPONECTIN GENES. WITH RESPECT TO ADIPOSITY GENES, EPIGENETIC MODIFICATIONS WERE DOCUMENTED FOR FAT MASS GENE CLUSTER APOA1/C3/A4/A5, AND THE LIPOLYSIS GENE LIPE. WITH REGARD TO INFLAMMATORY, IMMUNE AND SUBCELLULAR METABOLISM, PPARG, NKBF1, TNFA, TCF7C2, AND THOSE GENES EXPRESSING CYTOCHROME P450 FAMILY ENZYMES INVOLVED IN STEROIDOGENESIS AND IN HEPATIC LIPOPROTEINS WERE DOCUMENTED FOR EPIGENETIC MODIFICATIONS. 2016 13 2597 28 EPIGENETICS OF SUBCELLULAR STRUCTURE FUNCTIONING IN THE ORIGIN OF RISK OR RESILIENCE TO COMORBIDITY OF NEUROPSYCHIATRIC AND CARDIOMETABOLIC DISORDERS. MECHANISMS CONTROLLING MITOCHONDRIAL FUNCTION, PROTEIN FOLDING IN THE ENDOPLASMIC RETICULUM (ER) AND NUCLEAR PROCESSES SUCH AS TELOMERE LENGTH AND DNA REPAIR MAY BE SUBJECT TO EPIGENETIC CUES THAT RELATE THE GENOMIC EXPRESSION AND ENVIRONMENTAL EXPOSURES IN EARLY STAGES OF LIFE. THEY MAY ALSO BE INVOLVED IN THE COMORBID APPEARANCE OF CARDIOMETABOLIC (CMD) AND NEUROPSYCHIATRIC DISORDERS (NPD) DURING ADULTHOOD. MITOCHONDRIAL FUNCTION AND PROTEIN FOLDING IN THE ENDOPLASMIC RETICULUM ARE ASSOCIATED WITH OXIDATIVE STRESS AND ELEVATED INTRACELLULAR CALCIUM LEVELS AND MAY ALSO UNDERLIE THE VULNERABILITY FOR COMORBID CMD AND NPD. MITOCHONDRIA PROVIDE KEY METABOLITES SUCH AS NICOTINAMIDE ADENINE DINUCLEOTIDE (NAD+), ATP, ALPHA-KETOGLUTARATE AND ACETYL COENZYME A THAT ARE REQUIRED FOR MANY TRANSCRIPTIONAL AND EPIGENETIC PROCESSES. THEY ARE ALSO A SOURCE OF FREE RADICALS. ON THE OTHER HAND, EPIGENETIC MARKERS IN NUCLEAR DNA DETERMINE MITOCHONDRIAL BIOGENESIS. THE ER IS THE SUBCELLULAR ORGANELLE IN WHICH SECRETORY PROTEINS ARE FOLDED. MANY ENVIRONMENTAL FACTORS STOP THE ABILITY OF CELLS TO PROPERLY FOLD PROTEINS AND MODIFY POST-TRANSLATIONALLY SECRETORY AND TRANSMEMBRANE PROTEINS LEADING TO ENDOPLASMIC RETICULUM STRESS AND OXIDATIVE STRESS. ER FUNCTIONING MAY BE EPIGENETICALLY DETERMINED. CHRONIC ER STRESS IS EMERGING AS A KEY CONTRIBUTOR TO A GROWING LIST OF HUMAN DISEASES, INCLUDING CMD AND NPD. TELOMERE LOSS CAUSES CHROMOSOMAL FUSION, ACTIVATION OF THE CONTROL OF DNA DAMAGE-RESPONSES, UNSTABLE GENOME AND ALTERED STEM CELL FUNCTION, WHICH MAY UNDERLIE THE COMORBIDITY OF CMD AND NPD. THE LENGTH OF TELOMERES IS RELATED TO OXIDATIVE STRESS AND MAY BE EPIGENETICALLY PROGRAMMED. PATHWAYS INVOLVED IN DNA REPAIR MAY BE EPIGENETICALLY PROGRAMMED AND MAY CONTRIBUTE TO DISEASES. IN THIS PAPER, WE DESCRIBE SUBCELLULAR MECHANISMS THAT ARE DETERMINED BY EPIGENETIC MARKERS AND THEIR POSSIBLE RELATION TO THE DEVELOPMENT OF INCREASED SUSCEPTIBILITY TO DEVELOP CMD AND NPD. 2018 14 3370 32 HISTONE MODIFICATION OF NEDD4 UBIQUITIN LIGASE CONTROLS THE LOSS OF AMPA RECEPTORS AND COGNITIVE IMPAIRMENT INDUCED BY REPEATED STRESS. STRESS AND THE MAJOR STRESS HORMONE CORTICOSTERONE INDUCE PROFOUND INFLUENCES IN THE BRAIN. ALTERED HISTONE MODIFICATION AND TRANSCRIPTIONAL DYSFUNCTION HAVE BEEN IMPLICATED IN STRESS-RELATED MENTAL DISORDERS. WE PREVIOUSLY FOUND THAT REPEATED STRESS CAUSED AN IMPAIRMENT OF PREFRONTAL CORTEX (PFC)-MEDIATED COGNITIVE FUNCTIONS BY INCREASING THE UBIQUITINATION AND DEGRADATION OF AMPA-TYPE GLUTAMATE RECEPTORS VIA A MECHANISM DEPENDING ON THE E3 UBIQUITIN LIGASE NEDD4. HERE, WE DEMONSTRATED THAT IN PFC OF REPEATEDLY STRESSED RATS, ACTIVE GLUCOCORTICOID RECEPTOR HAD THE INCREASED BINDING TO THE GLUCOCORTICOID RESPONSE ELEMENT OF HISTONE DEACETYLASE 2 (HDAC2) PROMOTER, RESULTING IN THE UPREGULATION OF HDAC2. INHIBITION OR KNOCK-DOWN OF HDAC2 BLOCKED THE STRESS-INDUCED IMPAIRMENT OF SYNAPTIC TRANSMISSION, AMPAR EXPRESSION, AND RECOGNITION MEMORY. FURTHERMORE, WE FOUND THAT, IN STRESSED ANIMALS, THE HDAC2-DEPENDENT DOWNREGULATION OF HISTONE METHYLTRANSFERASE EHMT2 (G9A) LED TO THE LOSS OF REPRESSIVE HISTONE METHYLATION AT THE NEDD4-1 PROMOTER AND THE TRANSCRIPTIONAL ACTIVATION OF NEDD4. THESE RESULTS HAVE PROVIDED AN EPIGENETIC MECHANISM AND A POTENTIAL TREATMENT STRATEGY FOR THE DETRIMENTAL EFFECTS OF CHRONIC STRESS. SIGNIFICANCE STATEMENT: PROLONGED STRESS EXPOSURE CAN INDUCE ALTERED HISTONE MODIFICATION AND TRANSCRIPTIONAL DYSFUNCTION, WHICH MAY UNDERLIE THE PROFOUND INFLUENCE OF STRESS IN REGULATING BRAIN FUNCTIONS. WE REPORT AN IMPORTANT FINDING ABOUT THE EPIGENETIC MECHANISM CONTROLLING THE DETRIMENTAL EFFECTS OF REPEATED STRESS ON SYNAPTIC TRANSMISSION AND COGNITIVE FUNCTION. FIRST, IT HAS REVEALED THE STRESS-INDUCED ALTERATION OF KEY EPIGENETIC REGULATORS HDAC2 AND EHMT2, WHICH DETERMINES THE SYNAPTIC AND BEHAVIORAL EFFECTS OF REPEATED STRESS. SECOND, IT HAS UNCOVERED THE STRESS-INDUCED HISTONE MODIFICATION OF THE TARGET GENE NEDD4, AN E3 LIGASE THAT IS CRITICALLY INVOLVED IN THE UBIQUITINATION AND DEGRADATION OF AMPA RECEPTORS AND COGNITION. THIRD, IT HAS PROVIDED THE EPIGENETIC APPROACH, HDAC2 INHIBITION OR KNOCK-DOWN, TO RESCUE SYNAPTIC AND COGNITIVE FUNCTIONS IN STRESSED ANIMALS. 2016 15 222 25 ACUTE LIVER STEATOSIS TRANSLATIONALLY CONTROLS THE EPIGENETIC REGULATOR MIER1 TO PROMOTE LIVER REGENERATION IN A STUDY WITH MALE MICE. THE EARLY PHASE LIPID ACCUMULATION IS ESSENTIAL FOR LIVER REGENERATION. HOWEVER, WHETHER THIS ACUTE LIPID ACCUMULATION CAN SERVE AS SIGNALS TO DIRECT LIVER REGENERATION RATHER THAN SIMPLY PROVIDING BUILDING BLOCKS FOR CELL PROLIFERATION REMAINS UNCLEAR. THROUGH IN VIVO CRISPR SCREENING, WE IDENTIFY MIER1 (MESODERM INDUCTION EARLY RESPONSE 1) AS A KEY EPIGENETIC REGULATOR THAT BRIDGES THE ACUTE LIPID ACCUMULATION AND CELL CYCLE GENE EXPRESSION DURING LIVER REGENERATION IN MALE ANIMALS. PHYSIOLOGICALLY, LIVER ACUTE LIPID ACCUMULATION INDUCES THE PHOSPHORYLATION OF EIF2S1(EUKARYOTIC TRANSLATION INITIATION FACTOR 2), WHICH CONSEQUENTLY ATTENUATED MIER1 TRANSLATION. MIER1 DOWNREGULATION IN TURN PROMOTES CELL CYCLE GENE EXPRESSION AND REGENERATION THROUGH CHROMATIN REMODELING. IMPORTANTLY, THE LIPIDS-EIF2S1-MIER1 PATHWAY IS IMPAIRED IN ANIMALS WITH CHRONIC LIVER STEATOSIS; WHEREAS MIER1 DEPLETION SIGNIFICANTLY IMPROVES REGENERATION IN THESE ANIMALS. TAKEN TOGETHER, OUR STUDIES IDENTIFY AN EPIGENETIC MECHANISM BY WHICH THE EARLY PHASE LIPID REDISTRIBUTION FROM ADIPOSE TISSUE TO LIVER DURING REGENERATION IMPACTS HEPATOCYTE PROLIFERATION, AND SUGGEST A POTENTIAL STRATEGY TO BOOST LIVER REGENERATION. 2023 16 3093 17 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 17 3390 28 HOPX PLAYS A CRITICAL ROLE IN ANTIRETROVIRAL DRUGS INDUCED EPIGENETIC MODIFICATION AND CARDIAC HYPERTROPHY. PEOPLE LIVING WITH HIV (PLWH) HAVE TO TAKE AN ANTIRETROVIRAL THERAPY (ART) FOR LIFE AND SHOW NONCOMMUNICABLE ILLNESSES SUCH AS CHRONIC INFLAMMATION, IMMUNE ACTIVATION, AND MULTIORGAN DYSREGULATION. RECENT STUDIES SUGGEST THAT LONG-TERM USE OF ART INDUCES COMORBID CONDITIONS AND IS ONE OF THE LEADING CAUSES OF HEART FAILURE IN PLWH. HOWEVER, THE MOLECULAR MECHANISM OF ANTIRETROVIRAL DRUGS (ARVS) INDUCED HEART FAILURE IS UNCLEAR. TO DETERMINE THE MECHANISM OF ARVS INDUCED CARDIAC DYSFUNCTION, WE PERFORMED GLOBAL TRANSCRIPTOMIC PROFILING OF ARVS TREATED NEONATAL RAT VENTRICULAR CARDIOMYOCYTES IN CULTURE. DIFFERENTIALLY EXPRESSED GENES WERE IDENTIFIED BY RNA-SEQUENCING. OUR DATA SHOW THAT ARVS TREATMENT CAUSES UPREGULATION OF SEVERAL BIOLOGICAL FUNCTIONS ASSOCIATED WITH CARDIOTOXICITY, HYPERTROPHY, AND HEART FAILURE. GLOBAL GENE EXPRESSION DATA WERE VALIDATED IN CARDIAC TISSUE ISOLATED FROM HIV PATIENTS HAVING A HISTORY OF ART. INTERESTINGLY, WE FOUND THAT HOMEODOMAIN-ONLY PROTEIN HOMEOBOX (HOPX) EXPRESSION WAS SIGNIFICANTLY INCREASED IN CARDIOMYOCYTES TREATED WITH ARVS AND IN THE HEART TISSUE OF HIV PATIENTS. FURTHERMORE, WE FOUND THAT HOPX PLAYS A CRUCIAL ROLE IN ARVS MEDIATED CELLULAR HYPERTROPHY. MECHANISTICALLY, WE FOUND THAT HOPX PLAYS A CRITICAL ROLE IN EPIGENETIC REGULATION, THROUGH DEACETYLATION OF HISTONE, WHILE THE HDAC INHIBITOR, TRICHOSTATIN A, CAN RESTORE THE ACETYLATION LEVEL OF HISTONE 3 IN THE PRESENCE OF ARVS. 2021 18 5153 25 PPP2R2B HYPERMETHYLATION CAUSES ACQUIRED APOPTOSIS DEFICIENCY IN SYSTEMIC AUTOIMMUNE DISEASES. CHRONIC INFLAMMATION CAUSES TARGET ORGAN DAMAGE IN PATIENTS WITH SYSTEMIC AUTOIMMUNE DISEASES. THE FACTORS THAT ALLOW THIS PROTRACTED RESPONSE ARE POORLY UNDERSTOOD. WE ANALYZED THE TRANSCRIPTIONAL REGULATION OF PPP2R2B (B55SS), A MOLECULE NECESSARY FOR THE TERMINATION OF THE IMMUNE RESPONSE, IN PATIENTS WITH AUTOIMMUNE DISEASES. ALTERED EXPRESSION OF B55SS CONDITIONED RESISTANCE TO CYTOKINE WITHDRAWAL-INDUCED DEATH (CWID) IN PATIENTS WITH AUTOIMMUNE DISEASES. THE IMPAIRED UPREGULATION OF B55SS WAS CAUSED BY INFLAMMATION-DRIVEN HYPERMETHYLATION OF SPECIFIC CYTOSINES LOCATED WITHIN A REGULATORY ELEMENT OF PPP2R2B PREVENTING CTCF BINDING. THIS PHENOTYPE COULD BE INDUCED IN HEALTHY T CELLS BY EXPOSURE TO TNF-ALPHA. OUR RESULTS REVEAL A GENE WHOSE EXPRESSION IS AFFECTED BY AN ACQUIRED DEFECT, THROUGH AN EPIGENETIC MECHANISM, IN THE SETTING OF SYSTEMIC AUTOIMMUNITY. BECAUSE FAILURE TO REMOVE ACTIVATED T CELLS THROUGH CWID COULD CONTRIBUTE TO AUTOIMMUNE PATHOLOGY, THIS MECHANISM ILLUSTRATES A VICIOUS CYCLE THROUGH WHICH AUTOIMMUNE INFLAMMATION CONTRIBUTES TO ITS OWN PERPETUATION. 2019 19 4499 24 MORPHINE WITHDRAWAL PRODUCES ERK-DEPENDENT AND ERK-INDEPENDENT EPIGENETIC MARKS IN NEURONS OF THE NUCLEUS ACCUMBENS AND LATERAL SEPTUM. EPIGENETIC CHANGES SUCH AS COVALENT MODIFICATIONS OF HISTONE PROTEINS REPRESENT COMPLEX MOLECULAR SIGNATURES THAT PROVIDE A CELLULAR MEMORY OF PREVIOUSLY EXPERIENCED STIMULI WITHOUT IRREVERSIBLE CHANGES OF THE GENETIC CODE. IN THIS STUDY WE SHOW THAT NEW GENE EXPRESSION INDUCED IN VIVO BY MORPHINE WITHDRAWAL OCCURS WITH CONCOMITANT EPIGENETIC MODIFICATIONS IN BRAIN REGIONS CRITICALLY INVOLVED IN DRUG-DEPENDENT BEHAVIORS. WE FOUND THAT NALOXONE-PRECIPITATED WITHDRAWAL, BUT NOT CHRONIC MORPHINE ADMINISTRATION, CAUSED A STRONG INDUCTION OF PHOSPHO-HISTONE H3 IMMUNOREACTIVITY IN THE NUCLEUS ACCUMBENS (NAC) SHELL/CORE AND IN THE LATERAL SEPTUM (LS), A CHANGE THAT WAS ACCOMPANIED BY AUGMENTED H3 ACETYLATION (LYS14) IN NEURONS OF THE NAC SHELL. MORPHINE WITHDRAWAL INDUCED THE PHOSPHORYLATION OF THE EPIGENETIC FACTOR METHYL-CPG-BINDING PROTEIN 2 (MECP2) IN SER421 BOTH IN THE LS AND THE NAC SHELL. THESE EPIGENETIC CHANGES WERE ACCOMPANIED BY THE ACTIVATION OF MEMBERS OF THE ERK PATHWAY AS WELL AS INCREASED EXPRESSION OF THE IMMEDIATE EARLY GENES (IEG) C-FOS AND ACTIVITY-REGULATED CYTOSKELETON-ASSOCIATED PROTEIN (ARC/ARG3.1). USING A PHARMACOLOGICAL APPROACH, WE FOUND THAT H3 PHOSPHORYLATION AND IEG EXPRESSION WERE PARTIALLY DEPENDENT ON ERK ACTIVATION, WHILE MECP2 PHOSPHORYLATION WAS FULLY ERK-INDEPENDENT. THESE FINDINGS PROVIDE NEW IMPORTANT INFORMATION ON THE ROLE OF THE ERK PATHWAY IN THE REGULATION OF EPIGENETIC MARKS AND GENE EXPRESSION THAT MAY CONCUR TO REGULATE IN VIVO THE CELLULAR CHANGES UNDERLYING THE ONSET OF THE OPIOID WITHDRAWAL SYNDROME. 2013 20 889 23 CHRONIC DIETARY ADMINISTRATION OF VALPROIC ACID PROTECTS NEURONS OF THE RAT NUCLEUS BASALIS MAGNOCELLULARIS FROM IBOTENIC ACID NEUROTOXICITY. VALPROIC ACID (VPA) HAS BEEN USED FOR MANY YEARS AS A DRUG OF CHOICE FOR EPILEPSY AND MOOD DISORDERS. RECENTLY, EVIDENCE HAS BEEN PROPOSED FOR A WIDE SPECTRUM OF ACTIONS OF THIS DRUG, INCLUDING ANTITUMORAL AND NEUROPROTECTIVE PROPERTIES. VALPROIC ACID-MEDIATED NEUROPROTECTION IN VIVO HAS BEEN SO FAR DEMONSTRATED IN A LIMITED NUMBER OF EXPERIMENTAL MODELS. IN THIS STUDY, WE HAVE TESTED THE NEUROPROTECTIVE POTENTIAL OF CHRONIC (4 + 1 WEEKS) DIETARY ADMINISTRATION OF VPA ON DEGENERATION OF CHOLINERGIC AND GABAERGIC NEURONS OF THE RAT NUCLEUS BASALIS MAGNOCELLULARIS (NBM), INJECTED WITH THE EXCITOTOXIN, IBOTENIC ACID (IBO), AN ANIMAL MODELS THAT IS RELEVANT FOR ALZHEIMER'S DISEASE-LIKE NEURODEGENERATION. WE SHOW THAT VPA TREATMENT SIGNIFICANTLY PROTECTS BOTH CHOLINERGIC AND GABAERGIC NEURONS PRESENT IN THE INJECTED AREA FROM THE EXCITOTOXIC INSULT. A SIGNIFICANT LEVEL OF NEUROPROTECTION, IN PARTICULAR, IS EXERTED TOWARDS THE CHOLINERGIC NEURONS OF THE NBM PROJECTING TO THE CORTEX, AS DEMONSTRATED BY THE SUBSTANTIALLY HIGHER LEVELS OF CHOLINERGIC MARKERS MAINTAINED IN THE TARGET CORTICAL AREA OF VPA-TREATED RATS AFTER IBO INJECTION IN THE NBM. WE FURTHER SHOW THAT CHRONIC VPA ADMINISTRATION RESULTS IN INCREASED ACETYLATION OF HISTONE H3 IN BRAIN, CONSISTENT WITH THE HISTONE DEACETYLASE INHIBITORY ACTION OF VPA AND PUTATIVELY LINKED TO A NEUROPROTECTIVE ACTION OF THE DRUG MEDIATED AT THE EPIGENETIC LEVEL. 2009