1 3364 101 HISTONE METHYLATION BY THE KLEEFSTRA SYNDROME PROTEIN EHMT1 MEDIATES HOMEOSTATIC SYNAPTIC SCALING. HOMEOSTATIC PLASTICITY, A FORM OF SYNAPTIC PLASTICITY, MAINTAINS THE FINE BALANCE BETWEEN OVERALL EXCITATION AND INHIBITION IN DEVELOPING AND MATURE NEURONAL NETWORKS. ALTHOUGH THE SYNAPTIC MECHANISMS OF HOMEOSTATIC PLASTICITY ARE WELL CHARACTERIZED, THE ASSOCIATED TRANSCRIPTIONAL PROGRAM REMAINS POORLY UNDERSTOOD. WE SHOW THAT THE KLEEFSTRA-SYNDROME-ASSOCIATED PROTEIN EHMT1 PLAYS A CRITICAL AND CELL-AUTONOMOUS ROLE IN SYNAPTIC SCALING BY RESPONDING TO ATTENUATED NEURONAL FIRING OR SENSORY DRIVE. CHRONIC ACTIVITY DEPRIVATION INCREASED THE AMOUNT OF NEURONAL DIMETHYLATED H3 AT LYSINE 9 (H3K9ME2), THE CATALYTIC PRODUCT OF EHMT1 AND AN EPIGENETIC MARKER FOR GENE REPRESSION. GENETIC KNOCKDOWN AND PHARMACOLOGICAL BLOCKADE OF EHMT1 OR EHMT2 PREVENTED THE INCREASE OF H3K9ME2 AND SYNAPTIC SCALING UP. FURTHERMORE, BDNF REPRESSION WAS PRECEDED BY EHMT1/2-MEDIATED H3K9ME2 DEPOSITION AT THE BDNF PROMOTER DURING SYNAPTIC SCALING UP, BOTH IN VITRO AND IN VIVO. OUR FINDINGS SUGGEST THAT H3K9ME2-MEDIATED CHANGES IN CHROMATIN STRUCTURE GOVERN A REPRESSIVE PROGRAM THAT CONTROLS SYNAPTIC SCALING. 2016 2 1697 32 DYNAMIC DNA METHYLATION CONTROLS GLUTAMATE RECEPTOR TRAFFICKING AND SYNAPTIC SCALING. HEBBIAN PLASTICITY, INCLUDING LONG-TERM POTENTIATION AND LONG-TERM DEPRESSION, HAS LONG BEEN REGARDED AS IMPORTANT FOR LOCAL CIRCUIT REFINEMENT IN THE CONTEXT OF MEMORY FORMATION AND STABILIZATION. HOWEVER, CIRCUIT DEVELOPMENT AND STABILIZATION ADDITIONALLY RELIES ON NON-HEBBIAN, HOMEOSTATIC, FORMS OF PLASTICITY SUCH AS SYNAPTIC SCALING. SYNAPTIC SCALING IS INDUCED BY CHRONIC INCREASES OR DECREASES IN NEURONAL ACTIVITY. SYNAPTIC SCALING IS ASSOCIATED WITH CELL-WIDE ADJUSTMENTS IN POSTSYNAPTIC RECEPTOR DENSITY, AND CAN OCCUR IN A MULTIPLICATIVE MANNER RESULTING IN PRESERVATION OF RELATIVE SYNAPTIC STRENGTHS ACROSS THE ENTIRE NEURON'S POPULATION OF SYNAPSES. BOTH ACTIVE DNA METHYLATION AND DEMETHYLATION HAVE BEEN VALIDATED AS CRUCIAL REGULATORS OF GENE TRANSCRIPTION DURING LEARNING, AND SYNAPTIC SCALING IS KNOWN TO BE TRANSCRIPTIONALLY DEPENDENT. HOWEVER, IT HAS BEEN UNCLEAR WHETHER HOMEOSTATIC FORMS OF PLASTICITY SUCH AS SYNAPTIC SCALING ARE REGULATED VIA EPIGENETIC MECHANISMS. THIS REVIEW DESCRIBES EXCITING RECENT WORK THAT HAS DEMONSTRATED A ROLE FOR ACTIVE CHANGES IN NEURONAL DNA METHYLATION AND DEMETHYLATION AS A CONTROLLER OF SYNAPTIC SCALING AND GLUTAMATE RECEPTOR TRAFFICKING. THESE FINDINGS BRING TOGETHER THREE MAJOR CATEGORIES OF MEMORY-ASSOCIATED MECHANISMS THAT WERE PREVIOUSLY LARGELY CONSIDERED SEPARATELY: DNA METHYLATION, HOMEOSTATIC PLASTICITY, AND GLUTAMATE RECEPTOR TRAFFICKING. THIS REVIEW DESCRIBES EXCITING RECENT WORK THAT HAS DEMONSTRATED A ROLE FOR ACTIVE CHANGES IN NEURONAL DNA METHYLATION AND DEMETHYLATION AS A CONTROLLER OF SYNAPTIC SCALING AND GLUTAMATE RECEPTOR TRAFFICKING. THESE FINDINGS BRING TOGETHER THREE MAJOR CATEGORIES OF MEMORY-ASSOCIATED MECHANISMS THAT WERE PREVIOUSLY CONSIDERED SEPARATELY: GLUTAMATE RECEPTOR TRAFFICKING, DNA METHYLATION, AND HOMEOSTATIC PLASTICITY. 2016 3 3370 29 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 4 2442 27 EPIGENETIC STABILITY IN THE ADULT MOUSE CORTEX UNDER CONDITIONS OF PHARMACOLOGICALLY INDUCED HISTONE ACETYLATION. HISTONE ACETYLATION IS CONSIDERED A MAJOR EPIGENETIC PROCESS THAT AFFECTS BRAIN DEVELOPMENT AND SYNAPTIC PLASTICITY, AS WELL AS LEARNING AND MEMORY. THE TRANSCRIPTIONAL EFFECTORS AND MORPHOLOGICAL CHANGES RESPONSIBLE FOR PLASTICITY AS A RESULT OF LONG-TERM MODIFICATIONS TO HISTONE ACETYLATION ARE NOT FULLY UNDERSTOOD. TO THIS END, WE PHARMACOLOGICALLY INHIBITED HISTONE DEACETYLATION USING TRICHOSTATIN A IN ADULT (6-MONTH-OLD) MICE AND FOUND SIGNIFICANT INCREASES IN THE LEVELS OF THE ACETYLATED HISTONE MARKS H3LYS9, H3LYS14 AND H4LYS12. HIGH-RESOLUTION TRANSCRIPTOME ANALYSIS OF DIVERSE BRAIN REGIONS UNCOVERED FEW DIFFERENCES IN GENE EXPRESSION BETWEEN TREATED AND CONTROL ANIMALS, NONE OF WHICH WERE PLASTICITY RELATED. INSTEAD, AFTER INCREASED HISTONE ACETYLATION, WE DETECTED A LARGE NUMBER OF NOVEL TRANSCRIPTIONALLY ACTIVE REGIONS, WHICH CORRESPOND TO LONG NON-CODING RNAS (LNCRNAS). WE ALSO SURPRISINGLY FOUND NO SIGNIFICANT CHANGES IN DENDRITIC SPINE PLASTICITY IN LAYERS 1 AND 2/3 OF THE VISUAL CORTEX USING LONG-TERM IN VIVO TWO-PHOTON IMAGING. OUR RESULTS INDICATE THAT CHRONIC PHARMACOLOGICALLY INDUCED HISTONE ACETYLATION CAN BE DECOUPLED FROM GENE EXPRESSION AND INSTEAD, MAY POTENTIALLY EXERT A POST-TRANSCRIPTIONAL EFFECT THROUGH THE DIFFERENTIAL PRODUCTION OF LNCRNAS. 2016 5 5065 33 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 6 6804 34 [EPIGENETIC REGULATION IN DEPRESSION]. RECENT RESEARCH HAS RAISED THE NOTION THAT EPIGENETIC MECHANISMS (E.G., DNA METHYLATION AND HISTONE MODIFICATIONS), WHICH EXERT LASTING CONTROL OVER GENE EXPRESSION WITHOUT ALTERING THE GENETIC CODE, COULD MEDIATE STABLE CHANGES IN BRAIN FUNCTION. HOWEVER, THE ROLE OF ENVIRONMENTAL FACTORS ALONG WITH GENETIC FACTORS IN THE EPIGENETIC REGULATION OF THE PATHOGENESIS OF DEPRESSION IS LARGELY UNKNOWN. TWO GENETICALLY DISTINCT MICE STRAINS, BALB/C (BALB) AND C57BL/6 (B6), EXHIBIT DIFFERENT BEHAVIORAL RESPONSES TO CHRONIC STRESS. WITH CHRONIC STRESS, BALB MICE SHOWED DEPRESSIVE-LIKE BEHAVIORS, BUT NOT B6 MICE, AND GLIAL CELL-DERIVED NEUROTROPHIC FACTOR (GDNF) EXPRESSION LEVEL WAS DECREASED IN THE VENTRAL STRIATUM OF BALB MICE BUT INCREASED IN B6 MICE. IN BALB MICE, DEPRESSIVE-LIKE BEHAVIORS AND DECREASED GDNF EXPRESSION WERE RECOVERED BY CHRONIC ANTIDEPRESSANT TREATMENT. THEREFORE, WE USED THESE TWO MICE STRAINS TO INVESTIGATE HOW THE EPIGENETIC STATUS OF THE GDNF GENE IN THE VENTRAL STRIATUM MODULATES STRESS VULNERABILITY. BOTH MICE STRAINS SHOWED INCREASED DNA METHYLATION LEVELS AND MECP2 RECRUITMENT IN THE GDNF PROMOTER REGION. HOWEVER, HISTONE H3 ACETYLATION LEVEL WAS DECREASED IN BALB MICE, BUT INCREASED IN B6 MICE. FURTHERMORE, BALB MICE SHOWED INCREASED HISTONE DEACETYLASE2 (HDAC2) EXPRESSION LEVEL AND RE-CHIP ASSAY REVEALED HDAC2-MECP2 COMPLEX IN BALB MICE. OUR RESULTS INDICATE THE CRUCIAL ROLE OF HISTONE MODIFICATION BY HDAC2 AND MECP2 COMPLEX FOR THE CONTROL OF GDNF EXPRESSION AND SUBSEQUENT BEHAVIORAL RESPONSES TO CHRONIC STRESS, IN OTHER WORDS, THE SUSCEPTIBILITY TO STRESS. IN ADDITION, WE INVESTIGATED THE EFFECT OF ANTIDEPRESSANTS ON THE EPIGENETIC REGULATION OF GDNF EXPRESSION. WE FOUND A REDUCED LEVEL OF HDAC4 RECRUITMENT AT THE GDNF PROMOTER REGION WITH ANTIDEPRESSANTS. THUS, OUR DATA SUGGEST THAT ANTIDEPRESSANTS INCREASE TRANSCRIPTIONAL ACTIVITY OF THE GDNF GENE THROUGH THE MODULATION OF HISTONE ACETYLATION BY HDAC4. FINALLY, WE EXAMINED THE EXPRESSIONS OF GDNF AND EPIGENETIC-RELATED MOLECULES MRNAS WITH MAJOR DEPRESSIVE AND BIPOLAR DISORDER PATIENTS BY USING QUANTITATIVE REAL-TIME PCR. WE FOUND THE ABERRANT EXPRESSION OF GDNF AND EPIGENETIC-RELATED GENES INCLUDING HDAC2 AND HDAC4 IN MOOD DISORDER PATIENTS. THUS, OUR DATA PROVIDE NOVEL INSIGHTS SUGGESTING THAT EPIGENETIC MECHANISMS OF GDNF EXPRESSION ARE INVOLVED IN THE PATHOGENESIS OR PATHOPHYSIOLOGY OF DEPRESSION. 2012 7 4861 25 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 4742 30 NOVEL HISTONE MODIFICATIONS IN MICROGLIA DERIVED FROM A MOUSE MODEL OF CHRONIC PAIN. AS THE RESIDENT IMMUNE CELLS IN THE CENTRAL NERVOUS SYSTEM, MICROGLIA PLAY AN IMPORTANT ROLE IN THE MAINTENANCE OF ITS HOMEOSTASIS. DYSREGULATION OF MICROGLIA HAS BEEN ASSOCIATED WITH THE DEVELOPMENT AND MAINTENANCE OF CHRONIC PAIN. HOWEVER, THE RELEVANT MOLECULAR PATHWAYS REMAIN POORLY DEFINED. IN THIS STUDY, WE USED A MASS SPECTROMETRY-BASED PROTEOMIC APPROACH TO SCREEN POTENTIAL CHANGES OF HISTONE PROTEIN MODIFICATIONS IN MICROGLIA ISOLATED FROM THE BRAIN OF CONTROL AND CISPLATIN-INDUCED NEUROPATHIC PAIN ADULT C57BL/6J MALE MICE. WE IDENTIFIED SEVERAL NOVEL MICROGLIAL HISTONE MODIFICATIONS ASSOCIATED WITH PAIN, INCLUDING STATISTICALLY SIGNIFICANTLY DECREASED HISTONE H3.1 LYSINE 27 MONO-METHYLATION (H3.1K27ME1, 54.8% OF CONTROL) AND H3 LYSINE 56 TRI-METHYLATION (7.5% OF CONTROL), AS WELL AS A TREND SUGGESTING INCREASED H3 TYROSINE 41 NITRATION. WE FURTHER INVESTIGATED THE FUNCTIONAL ROLE OF H3.1K27ME1 AND FOUND THAT TREATMENT OF CULTURED MICROGLIAL CELLS FOR 4 CONSECUTIVE DAYS WITH 1-10 MUM OF NCDM-64, A POTENT AND SELECTIVE INHIBITOR OF LYSINE DEMETHYLASE 7A, AN ENZYME RESPONSIBLE FOR THE DEMETHYLATION OF H3K27ME1, DOSE-DEPENDENTLY ELEVATED ITS LEVELS WITH A GREATER THAN A TWO-FOLD INCREASE OBSERVED AT 10 MUM COMPARED TO VEHICLE-TREATED CONTROL CELLS. MOREOVER, PRETREATMENT OF MICE WITH NCDM-64 (10 OR 25 MG/KG/DAY, I.P.) PRIOR TO CISPLATIN TREATMENT PREVENTED THE DEVELOPMENT OF NEUROPATHIC PAIN IN MICE. THE IDENTIFICATION OF SPECIFIC CHROMATIN MARKS IN MICROGLIA ASSOCIATED WITH CHRONIC PAIN MAY YIELD CRITICAL INSIGHT INTO THE CONTRIBUTION OF MICROGLIA TO THE DEVELOPMENT AND MAINTENANCE OF PAIN, AND OPENS NEW AVENUES FOR THE DEVELOPMENT OF NOVEL NONOPIOID THERAPEUTICS FOR THE EFFECTIVE MANAGEMENT OF CHRONIC PAIN. 2022 9 710 32 C-TERMINAL DOMAIN SMALL PHOSPHATASE 1 (CTDSP1) REGULATES GROWTH FACTOR EXPRESSION AND AXONAL REGENERATION IN PERIPHERAL NERVE TISSUE. PERIPHERAL NERVE INJURY (PNI) REPRESENTS A MAJOR CLINICAL AND ECONOMIC BURDEN. DESPITE THE ABILITY OF PERIPHERAL NEURONS TO REGENERATE THEIR AXONS AFTER AN INJURY, PATIENTS ARE OFTEN LEFT WITH MOTOR AND/OR SENSORY DISABILITY AND MAY DEVELOP CHRONIC PAIN. SUCCESSFUL REGENERATION AND TARGET ORGAN REINNERVATION REQUIRE COMPREHENSIVE TRANSCRIPTIONAL CHANGES IN BOTH INJURED NEURONS AND SUPPORT CELLS LOCATED AT THE SITE OF INJURY. THE EXPRESSION OF MOST OF THE GENES REQUIRED FOR AXON GROWTH AND GUIDANCE AND FOR SYNAPSIS FORMATION IS REPRESSED BY A SINGLE MASTER TRANSCRIPTIONAL REGULATOR, THE REPRESSOR ELEMENT 1 SILENCING TRANSCRIPTION FACTOR (REST). SUSTAINED INCREASE OF REST LEVELS AFTER INJURY INHIBITS AXON REGENERATION AND LEADS TO CHRONIC PAIN. AS TARGETING OF TRANSCRIPTION FACTORS IS CHALLENGING, WE TESTED WHETHER MODULATION OF REST ACTIVITY COULD BE ACHIEVED THROUGH KNOCKDOWN OF CARBOXY-TERMINAL DOMAIN SMALL PHOSPHATASE 1 (CTDSP1), THE ENZYME THAT STABILIZES REST BY PREVENTING ITS TARGETING TO THE PROTEASOME. TO TEST WHETHER KNOCKDOWN OF CTDSP1 PROMOTES NEUROTROPHIC FACTOR EXPRESSION IN BOTH SUPPORT CELLS LOCATED AT THE SITE OF INJURY AND IN PERIPHERAL NEURONS, WE TRANSFECTED MESENCHYMAL PROGENITOR CELLS (MPCS), A TYPE OF SUPPORT CELLS THAT ARE PRESENT AT HIGH CONCENTRATIONS AT THE SITE OF INJURY, AND DORSAL ROOT GANGLION (DRG) NEURONS WITH REST OR CTDSP1 SPECIFIC SIRNA. WE QUANTIFIED NEUROTROPHIC FACTOR EXPRESSION BY RT-QPCR AND WESTERN BLOT, AND BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) RELEASE IN THE CELL CULTURE MEDIUM BY ELISA, AND WE MEASURED NEURITE OUTGROWTH OF DRG NEURONS IN CULTURE. OUR RESULTS SHOW THAT CTDSP1 KNOCKDOWN PROMOTES NEUROTROPHIC FACTOR EXPRESSION IN BOTH DRG NEURONS AND THE SUPPORT CELLS MPCS, AND PROMOTES DRG NEURON REGENERATION. THERAPEUTICS TARGETING CTDSP1 ACTIVITY MAY, THEREFORE, REPRESENT A NOVEL EPIGENETIC STRATEGY TO PROMOTE PERIPHERAL NERVE REGENERATION AFTER PNI BY PROMOTING THE REGENERATIVE PROGRAM REPRESSED BY INJURY-INDUCED INCREASED LEVELS OF REST IN BOTH NEURONS AND SUPPORT CELLS. 2021 10 4299 21 MICRORNA-15B CONTRIBUTES TO DEPRESSION-LIKE BEHAVIOR IN MICE BY AFFECTING SYNAPTIC PROTEIN LEVELS AND FUNCTION IN THE NUCLEUS ACCUMBENS. MAJOR DEPRESSION IS A PREVALENT AFFECTIVE DISORDER CHARACTERIZED BY RECURRENT LOW MOOD. IT PRESUMABLY RESULTS FROM STRESS-INDUCED DETERIORATIONS OF MOLECULAR NETWORKS AND SYNAPTIC FUNCTIONS IN BRAIN REWARD CIRCUITS OF GENETICALLY-SUSCEPTIBLE INDIVIDUALS THROUGH EPIGENETIC PROCESSES. EPIGENETIC REGULATOR MICRORNA-15B INHIBITS NEURONAL PROGENITOR PROLIFERATION AND IS UP-REGULATED IN THE MEDIAL PREFRONTAL CORTEX OF MICE THAT DEMONSTRATE DEPRESSION-LIKE BEHAVIOR, INDICATING THE CONTRIBUTION OF MICRORNA-15 TO MAJOR DEPRESSION. USING A MOUSE MODEL OF MAJOR DEPRESSION INDUCED BY CHRONIC UNPREDICTABLE MILD STRESS (CUMS), HERE WE EXAMINED THE EFFECTS OF MICRORNA-15B ON SYNAPSES AND SYNAPTIC PROTEINS IN THE NUCLEUS ACCUMBENS OF THESE MICE. THE APPLICATION OF A MICRORNA-15B ANTAGOMIR INTO THE NUCLEUS ACCUMBENS SIGNIFICANTLY REDUCED THE INCIDENCE OF CUMS-INDUCED DEPRESSION AND REVERSED THE ATTENUATIONS OF EXCITATORY SYNAPSE AND SYNTAXIN-BINDING PROTEIN 3 (STXBP3A)/VESICLE-ASSOCIATED PROTEIN 1 (VAMP1) EXPRESSION. IN CONTRAST, THE INJECTION OF A MICRORNA-15B ANALOG INTO THE NUCLEUS ACCUMBENS INDUCED DEPRESSION-LIKE BEHAVIOR AS WELL AS ATTENUATED EXCITATORY SYNAPSES AND STXBP3A/VAMP1 EXPRESSION SIMILAR TO THE DOWN-REGULATION OF THESE PROCESSES INDUCED BY THE CUMS. WE CONCLUDE THAT MICRORNA-15B-5P MAY PLAY A CRITICAL ROLE IN CHRONIC STRESS-INDUCED DEPRESSION BY DECREASING SYNAPTIC PROTEINS, INNERVATIONS, AND ACTIVITIES IN THE NUCLEUS ACCUMBENS. WE PROPOSE THAT THE TREATMENT OF ANTI-MICRORNA-15B-5P MAY CONVERT STRESS-INDUCED DEPRESSION INTO RESILIENCE. 2020 11 2280 34 EPIGENETIC REGULATION IN DRUG ADDICTION. THE INTERACTION BETWEEN ENVIRONMENTAL SIGNALS AND GENES HAS NOW TAKEN ON A CLEAR MOLECULAR FORM AS DEMONSTRATED BY STABLE CHANGES IN CHROMATIN STRUCTURE. THESE CHANGES OCCUR THROUGH ACTIVATION OR REPRESSION OF SPECIFIC GENE PROGRAMMES BY A COMBINATION OF CHROMATIN REMODELLING, ACTIVATION AND ENZYMATIC MODIFICATION OF DNA AND HISTONES AS WELL AS NUCLEOSOMAL SUBUNIT EXCHANGE. RECENT RESEARCH INVESTIGATING THE MOLECULAR MECHANISMS CONTROLLING DRUG-INDUCED TRANSCRIPTIONAL, BEHAVIOURAL AND SYNAPTIC ACTIVITY HAS SHOWN A DIRECT ROLE FOR CHROMATIN REMODELLING--TERMED AS EPIGENETIC REGULATION--OF NEURONAL GENE PROGRAMMES AND SUBSEQUENT ADDICTIVE BEHAVIOUR ARISING FROM IT. RECENT DATA SUGGEST THAT REPEATED EXPOSURE TO CERTAIN DRUGS PROMOTES CHANGES IN LEVELS OF HISTONE ACETYLATION, PHOSPHORYLATION AND METHYLATION, TOGETHER WITH ALTERATIONS IN DNA METHYLATION LEVELS IN THE NEURONS OF THE BRAIN REWARD CENTRE, LOCALISED IN THE NUCLEUS ACCUMBENS (NAC) REGION OF THE LIMBIC SYSTEM. THE COMBINATION OF ACETYLATING, PHOSPHORYLATING AND METHYLATING H3 AND H4 HISTONE TAILS ALTER CHROMATIN COMPACTION THEREBY PROMOTING ALTERED LEVELS OF CELLULAR GENE EXPRESSION. HISTONE MODIFICATIONS, WHICH WEAKEN HISTONE INTERACTION WITH DNA OR THAT PROMOTE RECRUITMENT OF TRANSCRIPTIONAL ACTIVATING COMPLEXES, CORRELATE WITH PERMISSIVE GENE EXPRESSION. HISTONE DEACETYLATION, (WHICH STRENGTHEN HISTONE: DNA CONTACTS), OR HISTONE METHYLATION, (WHICH RECRUITS REPRESSIVE COMPLEXES TO CHROMATIN), PROMOTE A STATE OF TRANSCRIPTIONAL REPRESSION. USING ANIMAL MODELS, ACUTE COCAINE TREATMENT INCREASES H4 ACETYLATION AT ACUTELY REGULATED GENE PROMOTERS, WHEREAS H3 ACETYLATION APPEARS TO PREDOMINATE AT CHRONICALLY INDUCED PROMOTERS. CHRONIC COCAINE AND ALCOHOL TREATMENT ACTIVATE AND REPRESS MANY GENES SUCH AS FOSB, CDK5, AND BDNF, WHERE THEIR DYSREGULATION, AT THE CHROMATIN LEVEL, CONTRIBUTE TO THE DEVELOPMENT AND MAINTENANCE OF ADDICTION. FOLLOWING DRUG EXPOSURE, IT IS STILL UNKNOWN, HOWVER, HOW LONG THESE CHANGES IN CHROMATIN STRUCTURE PERSIST IN AFFECTING NEURONAL FUNCTION, BUT SOME DO SO FOR LIFE. 2012 12 1652 31 DOPAMINE SIGNALING LEADS TO LOSS OF POLYCOMB REPRESSION AND ABERRANT GENE ACTIVATION IN EXPERIMENTAL PARKINSONISM. POLYCOMB GROUP (PCG) PROTEINS BIND TO AND REPRESS GENES IN EMBRYONIC STEM CELLS THROUGH LINEAGE COMMITMENT TO THE TERMINAL DIFFERENTIATED STATE. PCG REPRESSED GENES ARE COMMONLY CHARACTERIZED BY THE PRESENCE OF THE EPIGENETIC HISTONE MARK H3K27ME3, CATALYZED BY THE POLYCOMB REPRESSIVE COMPLEX 2. HERE, WE PRESENT IN VIVO EVIDENCE FOR A PREVIOUSLY UNRECOGNIZED PLASTICITY OF PCG-REPRESSED GENES IN TERMINALLY DIFFERENTIATED BRAIN NEURONS OF PARKISONIAN MICE. WE SHOW THAT ACUTE ADMINISTRATION OF THE DOPAMINE PRECURSOR, L-DOPA, INDUCES A REMARKABLE INCREASE IN H3K27ME3S28 PHOSPHORYLATION. THE INDUCTION OF THE H3K27ME3S28P HISTONE MARK SPECIFICALLY OCCURS IN MEDIUM SPINY NEURONS EXPRESSING DOPAMINE D1 RECEPTORS AND IS DEPENDENT ON MSK1 KINASE ACTIVITY AND DARPP-32-MEDIATED INHIBITION OF PROTEIN PHOSPHATASE-1. CHROMATIN IMMUNOPRECIPITATION (CHIP) EXPERIMENTS SHOWED THAT INCREASED H3K27ME3S28P WAS ACCOMPANIED BY REDUCED PCG BINDING TO REGULATORY REGIONS OF GENES. AN ANALYSIS OF THE GENOME WIDE DISTRIBUTION OF L-DOPA-INDUCED H3K27ME3S28 PHOSPHORYLATION BY CHIP SEQUENCING (CHIP-SEQ) IN COMBINATION WITH EXPRESSION ANALYSIS BY RNA-SEQUENCING (RNA-SEQ) SHOWED THAT THE INDUCTION OF H3K27ME3S28P CORRELATED WITH INCREASED EXPRESSION OF A SUBSET OF PCG REPRESSED GENES. WE FOUND THAT INDUCTION OF H3K27ME3S28P PERSISTED DURING CHRONIC L-DOPA ADMINISTRATION TO PARKISONIAN MICE AND CORRELATED WITH ABERRANT GENE EXPRESSION. WE PROPOSE THAT DOPAMINERGIC TRANSMISSION CAN ACTIVATE PCG REPRESSED GENES IN THE ADULT BRAIN AND THEREBY CONTRIBUTE TO LONG-TERM MALADAPTIVE RESPONSES INCLUDING THE MOTOR COMPLICATIONS, OR DYSKINESIA, CAUSED BY PROLONGED ADMINISTRATION OF L-DOPA IN PARKINSON'S DISEASE. 2014 13 2012 29 EPIGENETIC BASIS OF OPIATE SUPPRESSION OF BDNF GENE EXPRESSION IN THE VENTRAL TEGMENTAL AREA. BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) HAS A CRUCIAL ROLE IN MODULATING NEURAL AND BEHAVIORAL PLASTICITY TO DRUGS OF ABUSE. WE FOUND A PERSISTENT DOWNREGULATION OF EXON-SPECIFIC BDNF EXPRESSION IN THE VENTRAL TEGMENTAL AREA (VTA) IN RESPONSE TO CHRONIC OPIATE EXPOSURE, WHICH WAS MEDIATED BY SPECIFIC EPIGENETIC MODIFICATIONS AT THE CORRESPONDING BDNF GENE PROMOTERS. EXPOSURE TO CHRONIC MORPHINE INCREASED STALLING OF RNA POLYMERASE II AT THESE BDNF PROMOTERS IN VTA AND ALTERED PERMISSIVE AND REPRESSIVE HISTONE MODIFICATIONS AND OCCUPANCY OF THEIR REGULATORY PROTEINS AT THE SPECIFIC PROMOTERS. FURTHERMORE, WE FOUND THAT MORPHINE SUPPRESSED BINDING OF PHOSPHO-CREB (CAMP RESPONSE ELEMENT BINDING PROTEIN) TO BDNF PROMOTERS IN VTA, WHICH RESULTED FROM ENRICHMENT OF TRIMETHYLATED H3K27 AT THE PROMOTERS, AND THAT DECREASED NURR1 (NUCLEAR RECEPTOR RELATED-1) EXPRESSION ALSO CONTRIBUTED TO BDNF REPRESSION AND ASSOCIATED BEHAVIORAL PLASTICITY TO MORPHINE. OUR FINDINGS SUGGEST PREVIOUSLY UNKNOWN EPIGENETIC MECHANISMS OF MORPHINE-INDUCED MOLECULAR AND BEHAVIORAL NEUROADAPTATIONS. 2015 14 4499 30 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 15 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 16 4497 29 MORPHINE LEADS TO GLOBAL GENOME CHANGES IN H3K27ME3 LEVELS VIA A POLYCOMB REPRESSIVE COMPLEX 2 (PRC2) SELF-REGULATORY MECHANISM IN MESCS. BACKGROUND: ENVIRONMENTALLY INDUCED EPIGENETIC CHANGES CAN LEAD TO HEALTH PROBLEMS OR DISEASE, BUT THE MECHANISMS INVOLVED REMAIN UNCLEAR. MORPHINE CAN PASS THROUGH THE PLACENTAL BARRIER LEADING TO ABNORMAL EMBRYO DEVELOPMENT. HOWEVER, THE MECHANISM BY WHICH MORPHINE CAUSES THESE EFFECTS AND HOW THEY SOMETIMES PERSIST INTO ADULTHOOD IS NOT WELL KNOWN. TO UNRAVEL THE MORPHINE-INDUCED CHROMATIN ALTERATIONS INVOLVED IN ABERRANT EMBRYO DEVELOPMENT, WE EXPLORED THE ROLE OF THE H3K27ME3/PRC2 REPRESSIVE COMPLEX IN GENE EXPRESSION AND ITS TRANSMISSION ACROSS CELLULAR GENERATIONS IN RESPONSE TO MORPHINE. RESULTS: USING MOUSE EMBRYONIC STEM CELLS AS A MODEL SYSTEM, WE FOUND THAT CHRONIC MORPHINE TREATMENT INDUCES A GLOBAL DOWNREGULATION OF THE HISTONE MODIFICATION H3K27ME3. CONVERSELY, CHIP-SEQ SHOWED A REMARKABLE INCREASE IN H3K27ME3 LEVELS AT SPECIFIC GENOMIC SITES, PARTICULARLY PROMOTERS, DISRUPTING SELECTIVE TARGET GENES RELATED TO EMBRYO DEVELOPMENT, CELL CYCLE AND METABOLISM. THROUGH A SELF-REGULATORY MECHANISM, MORPHINE DOWNREGULATED THE TRANSCRIPTION OF PRC2 COMPONENTS RESPONSIBLE FOR H3K27ME3 BY ENRICHING HIGH H3K27ME3 LEVELS AT THE PROMOTER REGION. DOWNREGULATION OF PRC2 COMPONENTS PERSISTED FOR AT LEAST 48 H (4 CELL CYCLES) FOLLOWING MORPHINE REMOVAL, THOUGH PROMOTER H3K27ME3 LEVELS RETURNED TO CONTROL LEVELS. CONCLUSIONS: MORPHINE INDUCES TARGETING OF THE PRC2 COMPLEX TO SELECTED PROMOTERS, INCLUDING THOSE OF PRC2 COMPONENTS, LEADING TO CHARACTERISTIC CHANGES IN GENE EXPRESSION AND A GLOBAL REDUCTION IN H3K27ME3. FOLLOWING MORPHINE REMOVAL, ENHANCED PROMOTER H3K27ME3 LEVELS REVERT TO NORMAL SOONER THAN GLOBAL H3K27ME3 OR PRC2 COMPONENT TRANSCRIPT LEVELS. WE SUGGEST THAT H3K27ME3 IS INVOLVED IN INITIATING MORPHINE-INDUCED CHANGES IN GENE EXPRESSION, BUT NOT IN THEIR MAINTENANCE. MODEL OF POLYCOMB REPRESSIVE COMPLEX 2 (PRC2) AND H3K27ME3 ALTERATIONS INDUCED BY CHRONIC MORPHINE EXPOSURE. MORPHINE INDUCES H3K27ME3 ENRICHMENT AT PROMOTERS OF GENES ENCODING CORE MEMBERS OF THE PRC2 COMPLEX AND IS ASSOCIATED WITH THEIR TRANSCRIPTIONAL DOWNREGULATION. 2020 17 5825 23 STRESS MODULATES AHI1-DEPENDENT NUCLEAR LOCALIZATION OF TEN-ELEVEN TRANSLOCATION PROTEIN 2. MAJOR DEPRESSION DISORDER IS ONE OF THE MOST COMMON PSYCHIATRIC DISEASES. RECENT EVIDENCE SUPPORTS THAT ENVIRONMENTAL STRESS AFFECTS GENE EXPRESSION AND PROMOTES THE PATHOLOGICAL PROCESS OF DEPRESSION THROUGH EPIGENETIC MECHANISMS. THREE TEN-ELEVEN TRANSLOCATION (TET) ENZYMES ARE EPIGENETIC REGULATORS OF GENE EXPRESSION THAT PROMOTE 5-HYDROXYMETHYLCYTOSINE (5HMC) MODIFICATION OF GENES. HERE, WE SHOW THAT THE LOSS OF TET2 CAN INDUCE DEPRESSION-LIKE PHENOTYPES IN MICE. PARADOXICALLY, USING THE PARADIGMS OF CHRONIC STRESS, SUCH AS CHRONIC MILD STRESS AND CHRONIC SOCIAL DEFEAT STRESS, WE FOUND THAT DEPRESSIVE BEHAVIORS WERE ASSOCIATED WITH INCREASED TET2 EXPRESSION BUT DECREASED GLOBAL 5HMC LEVEL IN HIPPOCAMPUS. WE EXAMINED THE GENOME-WIDE 5HMC PROFILE IN THE HIPPOCAMPUS OF TET2 KNOCKOUT MICE AND IDENTIFIED 651 DYNAMICALLY HYDROXYMETHYLATED REGIONS, SOME OF WHICH OVERLAPPED WITH KNOWN DEPRESSION-ASSOCIATED LOCI. WE FURTHER SHOWED THAT CHRONIC STRESS COULD INDUCE THE ABNORMAL NUCLEAR TRANSLOCATION OF TET2 PROTEIN FROM CYTOSOL. THROUGH TET2 IMMUNOPRECIPITATION AND MASS SPECTRUM ANALYSES, WE IDENTIFIED A CELLULAR TRAFFICKING PROTEIN, ABELSON HELPER INTEGRATION SITE-1 (AHI1), WHICH COULD INTERACT WITH TET2 PROTEIN. AHI1 KNOCKOUT OR KNOCKDOWN CAUSED THE ACCUMULATION OF TET2 IN CYTOSOL. THE REDUCTION OF AHI1 PROTEIN UNDER CHRONIC STRESS EXPLAINED THE ABNORMAL AHI1-DEPENDENT NUCLEAR TRANSLOCATION OF TET2. THESE FINDINGS TOGETHER PROVIDE THE EVIDENCE FOR A CRITICAL ROLE OF MODULATING TET2 NUCLEAR TRANSLOCATION IN REGULATING STRESS RESPONSE. 2021 18 6895 21 [SYSTEMIC CONTROL OF THE MOLECULAR, CELL, AND EPIGENETIC MECHANISMS OF LONG-LASTING CONSEQUENCES OF STRESS]. BASED ON M.E. LOBASHEV'S VIEWS OF THE SYSTEMIC CONTROL OF GENETIC AND CYTOGENEITC PROCESSES AND A SUBSTANTIAL EFFECT OF EXCITABILITY ON PLASTIC CHANGES IN THE CENTRAL NERVOUS SYSTEM (CNS), THE EFFECT OF PROLONGED EMOTIONAL AND PAIN STRESS (PEPS) ON THE MOLECULAR, CELL, AND EPIGENETIC MECHANISMS OF INJURY MEMORY WAS STUDIED IN RAT STRAINS BRED FOR A CERTAIN EXCITABILITY OF THE NERVOUS SYSTEM. PEPS WAS FOR THE FIRST TIME FOUND TO CAUSE LONG-LASTING (2 MONTHS) MORPHOLOGICAL ALTERATIONS OF THE CA3 REGION OF THE HIPPOCAMPUS AND TO MODIFY THE GENOME ACTIVITY OF ITS PYRAMIDAL NEURONS. THE TWO PHENOMENA WERE POTENTIATED BY A GENETICALLY DETERMINED LOW FUNCTIONAL STATE OF THE CNS. THE POST-STRESS REGULATION OF THE GENOME FUNCTION IN HIPPOCAMPAL NEURONS WAS MEDIATED BY CHANGES IN HETEROCHROMATIN CONFORMATION, ACTIVATION OF METHYL-CPG-BINDING PROTEIN (MECP2) SYNTHESIS, AND SUBSEQUENT CHANGES IN ACETYLATION OF HISTONE H4. GENETICALLY DETERMINED HIGH EXCITABILITY OF THE NERVOUS SYSTEM PROVED TO BE A RISK FACTOR THAT AFFECTS THE SPECIFICS AND TIME COURSE OF THE OBSERVED MOLECULAR, CELL, AND GENETIC TRANSFORMATIONS OF NEURONS. THE RESULTS PROVIDE FOR A BETTER UNDERSTANDING OF THE EPIGENETIC MECHANISMS OF INJURY MEMORY, WHICH FORMS A PATHOGENETIC BASIS FOR POSTTRAUMATIC STRESS DISORDER AND OTHER HUMAN PSYCHOGENIC CONDITIONS CHARACTERIZED BY A PROLONGED DURATION. 2009 19 345 29 ALTERED BRAIN EXPRESSION OF DNA METHYLATION AND HYDROXYMETHYLATION EPIGENETIC ENZYMES IN A RAT MODEL OF NEUROPATHIC PAIN. THE ROLE OF EPIGENETICS IN CHRONIC PAIN AT THE SUPRASPINAL LEVEL IS YET TO BE FULLY CHARACTERIZED. DNA HISTONE METHYLATION IS CRUCIALLY REGULATED BY DE NOVO METHYLTRANSFERASES (DNMT1-3) AND TEN-ELEVEN TRANSLOCATION DIOXYGENASES (TET1-3). EVIDENCE HAS SHOWN THAT METHYLATION MARKERS ARE ALTERED IN DIFFERENT CNS REGIONS RELATED TO NOCICEPTION, NAMELY THE DORSAL ROOT GANGLIA, THE SPINAL CORD, AND DIFFERENT BRAIN AREAS. DECREASED GLOBAL METHYLATION WAS FOUND IN THE DRG, THE PREFRONTAL CORTEX, AND THE AMYGDALA, WHICH WAS ASSOCIATED WITH DECREASED DNMT1/3A EXPRESSION. IN CONTRAST, INCREASED METHYLATION LEVELS AND MRNA LEVELS OF TET1 AND TET3 WERE LINKED TO AUGMENTED PAIN HYPERSENSITIVITY AND ALLODYNIA IN INFLAMMATORY AND NEUROPATHIC PAIN MODELS. SINCE EPIGENETIC MECHANISMS MAY BE RESPONSIBLE FOR THE REGULATION AND COORDINATION OF VARIOUS TRANSCRIPTIONAL MODIFICATIONS DESCRIBED IN CHRONIC PAIN STATES, WITH THIS STUDY, WE AIMED TO EVALUATE THE FUNCTIONAL ROLE OF TET1-3 AND DNMT1/3A GENES IN NEUROPATHIC PAIN IN SEVERAL BRAIN AREAS. IN A SPARED NERVE INJURY RAT MODEL OF NEUROPATHIC PAIN, 21 DAYS AFTER SURGERY, WE FOUND INCREASED TET1 EXPRESSION IN THE MEDIAL PREFRONTAL CORTEX AND DECREASED EXPRESSION IN THE CAUDATE-PUTAMEN AND THE AMYGDALA; TET2 WAS UPREGULATED IN THE MEDIAL THALAMUS; TET3 MRNA LEVELS WERE REDUCED IN THE MEDIAL PREFRONTAL CORTEX AND THE CAUDATE-PUTAMEN; AND DNMT1 WAS DOWNREGULATED IN THE CAUDATE-PUTAMEN AND THE MEDIAL THALAMUS. NO STATISTICALLY SIGNIFICANT CHANGES IN EXPRESSION WERE OBSERVED WITH DNMT3A. OUR RESULTS SUGGEST A COMPLEX FUNCTIONAL ROLE FOR THESE GENES IN DIFFERENT BRAIN AREAS IN THE CONTEXT OF NEUROPATHIC PAIN. THE NOTION OF DNA METHYLATION AND HYDROXYMETHYLATION BEING CELL-TYPE SPECIFIC AND NOT TISSUE SPECIFIC, AS WELL AS THE POSSIBILITY OF CHRONOLOGICALLY DIFFERENTIAL GENE EXPRESSION AFTER THE ESTABLISHMENT OF NEUROPATHIC OR INFLAMMATORY PAIN MODELS, OUGHT TO BE ADDRESSED IN FUTURE STUDIES. 2023 20 3093 25 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