1 533 135 ASTROCYTIC TRANSCRIPTION FACTOR REST UPREGULATES GLUTAMATE TRANSPORTER EAAT2, PROTECTING DOPAMINERGIC NEURONS FROM MANGANESE-INDUCED EXCITOTOXICITY. CHRONIC EXPOSURE TO HIGH LEVELS OF MANGANESE (MN) LEADS TO MANGANISM, A NEUROLOGICAL DISORDER WITH SIMILAR SYMPTOMS TO THOSE INHERENT TO PARKINSON'S DISEASE. HOWEVER, THE UNDERLYING MECHANISMS OF THIS PATHOLOGICAL CONDITION HAVE YET TO BE ESTABLISHED. SINCE THE HUMAN EXCITATORY AMINO ACID TRANSPORTER 2 (EAAT2) (GLUTAMATE TRANSPORTER 1 IN RODENTS) IS PREDOMINANTLY EXPRESSED IN ASTROCYTES AND ITS DYSREGULATION IS INVOLVED IN MN-INDUCED EXCITOTOXIC NEURONAL INJURY, CHARACTERIZATION OF THE MECHANISMS THAT MEDIATE THE MN-INDUCED IMPAIRMENT IN EAAT2 FUNCTION IS CRUCIAL FOR THE DEVELOPMENT OF NOVEL THERAPEUTICS AGAINST MN NEUROTOXICITY. REPRESSOR ELEMENT 1-SILENCING TRANSCRIPTION FACTOR (REST) EXERTS PROTECTIVE EFFECTS IN MANY NEURODEGENERATIVE DISEASES. BUT THE EFFECTS OF REST ON EAAT2 EXPRESSION AND ENSUING NEUROPROTECTION ARE UNKNOWN. GIVEN THAT THE EAAT2 PROMOTER CONTAINS REST BINDING SITES, THE PRESENT STUDY INVESTIGATED THE ROLE OF REST IN EAAT2 EXPRESSION AT THE TRANSCRIPTIONAL LEVEL IN ASTROCYTES AND MN-INDUCED NEUROTOXICITY IN AN ASTROCYTE-NEURON COCULTURE SYSTEM. THE RESULTS REVEAL THAT ASTROCYTIC REST POSITIVELY REGULATES EAAT2 EXPRESSION WITH THE RECRUITMENT OF AN EPIGENETIC MODIFIER, CAMP RESPONSE ELEMENT-BINDING PROTEIN-BINDING PROTEIN/P300, TO ITS CONSENSUS BINDING SITES IN THE EAAT2 PROMOTER. MOREOVER, ASTROCYTIC OVEREXPRESSION OF REST ATTENUATES MN-INDUCED REDUCTION IN EAAT2 EXPRESSION, LEADING TO ATTENUATION OF GLUTAMATE-INDUCED NEUROTOXICITY IN THE ASTROCYTE-NEURON COCULTURE SYSTEM. OUR FINDINGS DEMONSTRATE THAT ASTROCYTIC REST PLAYS A CRITICAL ROLE IN PROTECTION AGAINST MN-INDUCED NEUROTOXICITY BY ATTENUATING MN-INDUCED EAAT2 REPRESSION AND THE ENSUING EXCITOTOXIC DOPAMINERGIC NEURONAL INJURY. THIS INDICATES THAT ASTROCYTIC REST COULD BE A POTENTIAL MOLECULAR TARGET FOR THE TREATMENT OF MN TOXICITY AND OTHER NEUROLOGICAL DISORDERS ASSOCIATED WITH EAAT2 DYSREGULATION. 2021 2 1734 38 EAAT2 AS A RESEARCH TARGET IN BIPOLAR DISORDER AND UNIPOLAR DEPRESSION: A SYSTEMATIC REVIEW. GLUTAMATE IS IMPLICATED IN THE NEUROPATHOLOGY OF BOTH MAJOR DEPRESSIVE DISORDER AND BIPOLAR DISORDER. EXCITATORY AMINO ACID TRANSPORTER 2 (EAAT2) IS THE MAJOR GLUTAMATE TRANSPORTER IN THE MAMMALIAN BRAIN, REMOVING GLUTAMATE FROM THE SYNAPTIC CLEFT AND TRANSPORTING IT INTO GLIA FOR RECYCLING. IT IS THEREBY THE PRINCIPAL REGULATOR OF EXTRACELLULAR GLUTAMATE LEVELS AND PREVENTS NEURONAL EXCITOTOXICITY. EAAT2 IS A PROMISING TARGET FOR ELUCIDATING THE MECHANISMS BY WHICH THE GLUTAMATE-GLUTAMINE CYCLE INTERACTS WITH NEURONAL SYSTEMS IN MOOD DISORDERS. FORTY EAAT2 STUDIES (PUBLISHED JANUARY 1992-JANUARY 2018) WERE IDENTIFIED VIA A SYSTEMATIC LITERATURE SEARCH. THE STUDIES DEMONSTRATED THAT CHRONIC STRESS/STEROIDS WERE MOST COMMONLY ASSOCIATED WITH DECREASED EAAT2. IN RODENTS, EAAT2 INHIBITION WORSENED DEPRESSIVE BEHAVIORS. HUMAN EAAT2 EXPRESSION USUALLY DECREASED IN DEPRESSION, WITH SOME REGIONAL BRAIN DIFFERENCES. FEWER DATA HAVE BEEN COLLECTED REGARDING THE ROLES AND REGULATION OF EAAT2 IN BIPOLAR DISORDER. FUTURE DIRECTIONS FOR RESEARCH INCLUDE CORRELATING EAAT2 AND GLUTAMATE LEVELS IN VIVO, ELUCIDATING GENETIC VARIABILITY AND EPIGENETIC REGULATION, CLARIFYING INTRACELLULAR PROTEIN AND PHARMACOLOGIC INTERACTIONS, AND EXAMINING EAAT2 IN DIFFERENT BIPOLAR MOOD STATES. AS PART OF A MACROMOLECULAR COMPLEX WITHIN GLIA, EAAT2 MAY CONTRIBUTE SIGNIFICANTLY TO INTRACELLULAR SIGNALING, ENERGY REGULATION, AND CELLULAR HOMEOSTASIS. AN ENHANCED UNDERSTANDING OF THIS SYSTEM IS NEEDED. 2020 3 6425 59 THE TRANSCRIPTION FACTOR REST UP-REGULATES TYROSINE HYDROXYLASE AND ANTIAPOPTOTIC GENES AND PROTECTS DOPAMINERGIC NEURONS AGAINST MANGANESE TOXICITY. DOPAMINERGIC FUNCTIONS ARE IMPORTANT FOR VARIOUS BIOLOGICAL ACTIVITIES, AND THEIR IMPAIRMENT LEADS TO NEURODEGENERATION, A HALLMARK OF PARKINSON'S DISEASE (PD). CHRONIC MANGANESE (MN) EXPOSURE CAUSES THE NEUROLOGICAL DISORDER MANGANISM, PRESENTING SYMPTOMS SIMILAR TO THOSE OF PD. EMERGING EVIDENCE HAS LINKED THE TRANSCRIPTION FACTOR RE1-SILENCING TRANSCRIPTION FACTOR (REST) TO PD AND ALSO ALZHEIMER'S DISEASE. BUT REST'S ROLE IN DOPAMINERGIC NEURONS IS UNCLEAR. HERE, WE INVESTIGATED WHETHER REST PROTECTS DOPAMINERGIC NEURONS AGAINST MN-INDUCED TOXICITY AND ENHANCES EXPRESSION OF THE DOPAMINE-SYNTHESIZING ENZYME TYROSINE HYDROXYLASE (TH). WE REPORT THAT REST BINDS TO RE1 CONSENSUS SITES IN THE TH GENE PROMOTER, STIMULATES TH TRANSCRIPTION, AND INCREASES TH MRNA AND PROTEIN LEVELS IN DOPAMINERGIC CELLS. REST BINDING TO THE TH PROMOTER RECRUITED THE EPIGENETIC MODIFIER CAMP-RESPONSE ELEMENT-BINDING PROTEIN-BINDING PROTEIN/P300 AND THEREBY UP-REGULATED TH EXPRESSION. REST RELIEVED MN-INDUCED REPRESSION OF TH PROMOTER ACTIVITY, MRNA, AND PROTEIN LEVELS AND ALSO REDUCED MN-INDUCED OXIDATIVE STRESS, INFLAMMATION, AND APOPTOSIS IN DOPAMINERGIC NEURONS. REST REDUCED MN-INDUCED PROINFLAMMATORY CYTOKINES, INCLUDING TUMOR NECROSIS FACTOR ALPHA, INTERLEUKIN 1BETA (IL-1BETA), IL-6, AND INTERFERON GAMMA. MOREOVER, REST INHIBITED THE MN-INDUCED PROAPOPTOTIC PROTEINS BCL-2-ASSOCIATED X PROTEIN (BAX) AND DEATH-ASSOCIATED PROTEIN 6 (DAXX) AND ATTENUATED AN MN-INDUCED DECREASE IN THE ANTIAPOPTOTIC PROTEINS BCL-2 AND BCL-XL. REST ALSO ENHANCED THE EXPRESSION OF ANTIOXIDANT PROTEINS, INCLUDING CATALASE, NF-E2-RELATED FACTOR 2 (NRF2), AND HEME OXYGENASE 1 (HO-1). OUR FINDINGS INDICATE THAT REST ACTIVATES TH EXPRESSION AND THEREBY PROTECTS NEURONS AGAINST MN-INDUCED TOXICITY AND NEUROLOGICAL DISORDERS ASSOCIATED WITH DOPAMINERGIC NEURODEGENERATION. 2020 4 4136 46 MECHANISMS OF MANGANESE-INDUCED NEUROTOXICITY AND THE PURSUIT OF NEUROTHERAPEUTIC STRATEGIES. CHRONIC EXPOSURE TO ELEVATED LEVELS OF MANGANESE VIA OCCUPATIONAL OR ENVIRONMENTAL SETTINGS CAUSES A NEUROLOGICAL DISORDER KNOWN AS MANGANISM, RESEMBLING THE SYMPTOMS OF PARKINSON'S DISEASE, SUCH AS MOTOR DEFICITS AND COGNITIVE IMPAIRMENT. NUMEROUS STUDIES HAVE BEEN CONDUCTED TO CHARACTERIZE MANGANESE'S NEUROTOXICITY MECHANISMS IN SEARCH OF EFFECTIVE THERAPEUTICS, INCLUDING NATURAL AND SYNTHETIC COMPOUNDS TO TREAT MANGANESE TOXICITY. SEVERAL POTENTIAL MOLECULAR TARGETS OF MANGANESE TOXICITY AT THE EPIGENETIC AND TRANSCRIPTIONAL LEVELS HAVE BEEN IDENTIFIED RECENTLY, WHICH MAY CONTRIBUTE TO DEVELOP MORE PRECISE AND EFFECTIVE GENE THERAPIES. THIS REVIEW UPDATES FINDINGS ON MANGANESE-INDUCED NEUROTOXICITY MECHANISMS ON INTRACELLULAR INSULTS SUCH AS OXIDATIVE STRESS, INFLAMMATION, EXCITOTOXICITY, AND MITOPHAGY, AS WELL AS TRANSCRIPTIONAL DYSREGULATIONS INVOLVING YIN YANG 1, RE1-SILENCING TRANSCRIPTION FACTOR, TRANSCRIPTION FACTOR EB, AND NUCLEAR FACTOR ERYTHROID 2-RELATED FACTOR 2 THAT COULD BE TARGETS OF MANGANESE NEUROTOXICITY THERAPIES. THIS REVIEW ALSO FEATURES INTRACELLULAR PROTEINS SUCH AS PTEN-INDUCIBLE KINASE 1, PARKIN, SIRTUINS, LEUCINE-RICH REPEAT KINASE 2, AND ALPHA-SYNUCLEIN, WHICH ARE ASSOCIATED WITH MANGANESE-INDUCED DYSREGULATION OF AUTOPHAGY/MITOPHAGY. IN ADDITION, NEWER THERAPEUTIC APPROACHES TO TREAT MANGANESE'S NEUROTOXICITY INCLUDING NATURAL AND SYNTHETIC COMPOUNDS MODULATING EXCITOTOXICITY, AUTOPHAGY, AND MITOPHAGY, WERE REVIEWED. TAKEN TOGETHER, IN-DEPTH MECHANISTIC KNOWLEDGE ACCOMPANIED BY ADVANCES IN GENE AND DRUG DELIVERY STRATEGIES WILL MAKE SIGNIFICANT PROGRESS IN THE DEVELOPMENT OF RELIABLE THERAPEUTIC INTERVENTIONS AGAINST MANGANESE-INDUCED NEUROTOXICITY. 2022 5 5143 40 POTENTIAL ROLE OF EPIGENETIC MECHANISM IN MANGANESE INDUCED NEUROTOXICITY. MANGANESE IS A VITAL NUTRIENT AND IS MAINTAINED AT AN OPTIMAL LEVEL (2.5-5 MG/DAY) IN HUMAN BODY. CHRONIC EXPOSURE TO MANGANESE IS ASSOCIATED WITH NEUROTOXICITY AND CORRELATED WITH THE DEVELOPMENT OF VARIOUS NEUROLOGICAL DISORDERS SUCH AS PARKINSON'S DISEASE. OXIDATIVE STRESS MEDIATED APOPTOTIC CELL DEATH HAS BEEN WELL ESTABLISHED MECHANISM IN MANGANESE INDUCED TOXICITY. OXIDATIVE STRESS HAS A POTENTIAL TO ALTER THE EPIGENETIC MECHANISM OF GENE REGULATION. EPIGENETIC INSIGHT OF MANGANESE NEUROTOXICITY IN CONTEXT OF ITS CORRELATION WITH THE DEVELOPMENT OF PARKINSONISM IS POORLY UNDERSTOOD. PARKINSON'S DISEASE IS CHARACTERIZED BY THE ALPHA-SYNUCLEIN AGGREGATION IN THE FORM OF LEWY BODIES IN NEURONAL CELLS. RECENT FINDINGS ILLUSTRATE THAT MANGANESE CAN CAUSE OVEREXPRESSION OF ALPHA-SYNUCLEIN. ALPHA-SYNUCLEIN ACTS EPIGENETICALLY VIA INTERACTION WITH HISTONE PROTEINS IN REGULATING APOPTOSIS. ALPHA-SYNUCLEIN ALSO CAUSES GLOBAL DNA HYPOMETHYLATION THROUGH SEQUESTRATION OF DNA METHYLTRANSFERASE IN CYTOPLASM. AN INDIVIDUAL GENETIC DIFFERENCE MAY ALSO HAVE AN INFLUENCE ON EPIGENETIC SUSCEPTIBILITY TO MANGANESE NEUROTOXICITY AND THE DEVELOPMENT OF PARKINSON'S DISEASE. THIS REVIEW PRESENTS THE CURRENT STATE OF FINDINGS IN RELATION TO ROLE OF EPIGENETIC MECHANISM IN MANGANESE INDUCED NEUROTOXICITY, WITH A SPECIAL EMPHASIS ON THE DEVELOPMENT OF PARKINSON'S DISEASE. 2016 6 3137 42 GLOBAL DNA METHYLATION PROFILING OF MANGANESE-EXPOSED HUMAN NEUROBLASTOMA SH-SY5Y CELLS REVEALS EPIGENETIC ALTERATIONS IN PARKINSON'S DISEASE-ASSOCIATED GENES. MANGANESE (MN) IS AN ESSENTIAL TRACE ELEMENT REQUIRED FOR OPTIMAL FUNCTIONING OF CELLULAR BIOCHEMICAL PATHWAYS IN THE CENTRAL NERVOUS SYSTEM. ELEVATED EXPOSURE TO MN THROUGH ENVIRONMENTAL AND OCCUPATIONAL EXPOSURE CAN CAUSE NEUROTOXIC EFFECTS RESULTING IN MANGANISM, A CONDITION WITH CLINICAL SYMPTOMS IDENTICAL TO IDIOPATHIC PARKINSON'S DISEASE. EPIGENETICS IS NOW RECOGNIZED AS A BIOLOGICAL MECHANISM INVOLVED IN THE ETIOLOGY OF VARIOUS DISEASES. HERE, WE INVESTIGATED THE ROLE OF DNA METHYLATION ALTERATIONS INDUCED BY CHRONIC MN (100 MICROM) EXPOSURE IN HUMAN NEUROBLASTOMA (SH-SY5Y) CELLS IN RELEVANCE TO PARKINSON'S DISEASE. A COMBINED ANALYSIS OF DNA METHYLATION AND GENE EXPRESSION DATA FOR PARKINSON'S DISEASE-ASSOCIATED GENES WAS CARRIED OUT. WHOLE-GENOME BISULFITE CONVERSION AND SEQUENCING INDICATE EPIGENETIC PERTURBATION OF KEY GENES INVOLVED IN BIOLOGICAL PROCESSES ASSOCIATED WITH NEURONAL CELL HEALTH. INTEGRATION OF DNA METHYLATION DATA WITH GENE EXPRESSION REVEALS EPIGENETIC ALTERATIONS TO PINK1, PARK2 AND TH GENES THAT PLAY CRITICAL ROLES IN THE ONSET OF PARKINSONISM. THE PRESENT STUDY SUGGESTS THAT MN-INDUCED ALTERATION OF DNA METHYLATION OF PINK1-PARK2 MAY INFLUENCE MITOCHONDRIAL FUNCTION AND PROMOTE PARKINSONISM. OUR FINDINGS PROVIDE A BASIS TO FURTHER EXPLORE AND VALIDATE THE EPIGENETIC BASIS OF MN-INDUCED NEUROTOXICITY . 2017 7 6527 44 TRANSCRIPTIONAL CONTROL OF MALADAPTIVE AND PROTECTIVE RESPONSES IN ALCOHOLICS: A ROLE OF THE NF-KAPPAB SYSTEM. ALCOHOL DEPENDENCE AND ASSOCIATED COGNITIVE IMPAIRMENT APPEAR TO RESULT FROM MALADAPTIVE NEUROPLASTICITY IN RESPONSE TO CHRONIC ALCOHOL CONSUMPTION, NEUROINFLAMMATION AND NEURODEGENERATION. THE INHERENT STABILITY OF BEHAVIORAL ALTERATIONS ASSOCIATED WITH THE ADDICTED STATE SUGGESTS THAT TRANSCRIPTIONAL AND EPIGENETIC MECHANISMS ARE OPERATIVE. NF-KAPPAB TRANSCRIPTION FACTORS ARE REGULATORS OF SYNAPTIC PLASTICITY AND INFLAMMATION, AND RESPONSIVE TO A VARIETY OF STIMULI INCLUDING ALCOHOL. THESE FACTORS ARE ABUNDANT IN THE BRAIN WHERE THEY HAVE DIVERSE FUNCTIONS THAT DEPEND ON THE COMPOSITION OF THE NF-KAPPAB COMPLEX AND CELLULAR CONTEXT. IN NEURON CELL BODIES, NF-KAPPAB IS CONSTITUTIVELY ACTIVE, AND INVOLVED IN NEURONAL INJURY AND NEUROPROTECTION. HOWEVER, AT THE SYNAPSE, NF-KAPPAB IS PRESENT IN A LATENT FORM AND UPON ACTIVATION IS TRANSPORTED TO THE CELL NUCLEUS. IN GLIA, NF-KAPPAB IS INDUCIBLE AND REGULATES INFLAMMATORY PROCESSES THAT EXACERBATE ALCOHOL-INDUCED NEURODEGENERATION. ANIMAL STUDIES DEMONSTRATE THAT ACUTE ALCOHOL EXPOSURE TRANSIENTLY ACTIVATES NF-KAPPAB, WHICH INDUCES NEUROINFLAMMATORY RESPONSES AND NEURODEGENERATION. POSTMORTEM STUDIES OF BRAINS OF HUMAN ALCOHOLICS SUGGEST THAT REPEATED CYCLES OF ALCOHOL CONSUMPTION AND WITHDRAWAL CAUSE ADAPTIVE CHANGES IN THE NF-KAPPAB SYSTEM THAT MAY PERMIT THE SYSTEM TO BETTER TOLERATE EXCESSIVE STIMULATION. THIS TYPE OF TOLERANCE, ENSURING A LOW DEGREE OF RESPONSIVENESS TO APPLIED STIMULI, APPARENTLY DIFFERS FROM THAT IN THE IMMUNE SYSTEM, AND MAY REPRESENT A COMPENSATORY RESPONSE THAT PROTECTS BRAIN CELLS AGAINST ALCOHOL NEUROTOXICITY. THIS VIEW IS SUPPORTED BY FINDINGS SHOWING PREFERENTIAL DOWNREGULATION OF PRO-APOPTOTIC GENE EXPRESSION IN THE AFFECTED BRAIN AREAS IN HUMAN ALCOHOLICS. ALTHOUGH FURTHER VERIFICATION IS NEEDED, WE SPECULATE THAT NF-KAPPAB-DRIVEN NEUROINFLAMMATION AND DISRUPTION TO NEUROPLASTICITY PLAY A SIGNIFICANT ROLE IN REGULATING ALCOHOL DEPENDENCE AND COGNITIVE IMPAIRMENT. 2011 8 2214 39 EPIGENETIC MODIFICATIONS ASSOCIATED TO NEUROINFLAMMATION AND NEUROPATHIC PAIN AFTER NEURAL TRAUMA. ACCUMULATING EVIDENCE SUGGESTS THAT EPIGENETIC ALTERATIONS LIE BEHIND THE INDUCTION AND MAINTENANCE OF NEUROPATHIC PAIN. NEUROPATHIC PAIN IS USUALLY A CHRONIC CONDITION CAUSED BY A LESION, OR PATHOLOGICAL CHANGE, WITHIN THE NERVOUS SYSTEM. NEUROPATHIC PAIN APPEARS FREQUENTLY AFTER NERVE AND SPINAL CORD INJURIES OR DISEASES, PRODUCING A DEBILITATION OF THE PATIENT AND A DECREASE OF THE QUALITY OF LIFE. AT THE CELLULAR LEVEL, NEUROPATHIC PAIN IS THE RESULT OF NEURONAL PLASTICITY SHAPED BY AN INCREASE IN THE SENSITIVITY AND EXCITABILITY OF SENSORY NEURONS OF THE CENTRAL AND PERIPHERAL NERVOUS SYSTEM. ONE OF THE MECHANISMS THOUGHT TO CONTRIBUTE TO HYPEREXCITABILITY AND THEREFORE TO THE ONTOGENY OF NEUROPATHIC PAIN IS THE ALTERED EXPRESSION, TRAFFICKING, AND FUNCTIONING OF RECEPTORS AND ION CHANNELS EXPRESSED BY PRIMARY SENSORY NEURONS. BESIDES, NEURONAL AND GLIAL CELLS, SUCH AS MICROGLIA AND ASTROCYTES, TOGETHER WITH BLOOD BORNE MACROPHAGES, PLAY A CRITICAL ROLE IN THE INDUCTION AND MAINTENANCE OF NEUROPATHIC PAIN BY RELEASING POWERFUL NEUROMODULATORS SUCH AS PRO-INFLAMMATORY CYTOKINES AND CHEMOKINES, WHICH ENHANCE NEURONAL EXCITABILITY. ALTERED GENE EXPRESSION OF NEURONAL RECEPTORS, ION CHANNELS, AND PRO-INFLAMMATORY CYTOKINES AND CHEMOKINES, HAVE BEEN ASSOCIATED TO EPIGENETIC ADAPTATIONS OF THE INJURED TISSUE. WITHIN THIS REVIEW, WE DISCUSS THE INVOLVEMENT OF THESE EPIGENETIC CHANGES, INCLUDING HISTONE MODIFICATIONS, DNA METHYLATION, NON-CODING RNAS, AND ALTERATION OF CHROMATIN MODIFIERS, THAT HAVE BEEN SHOWN TO TRIGGER MODIFICATION OF NOCICEPTION AFTER NEURAL LESIONS. IN PARTICULAR, THE FUNCTION ON THESE PROCESSES OF EZH2, JMJD3, MECP2, SEVERAL HISTONE DEACETYLASES (HDACS) AND HISTONE ACETYL TRANSFERASES (HATS), G9A, DNMT, REST AND DIVERSE NON-CODING RNAS, ARE DESCRIBED. DESPITE THE EFFORT ON DEVELOPING NEW THERAPIES, CURRENT TREATMENTS HAVE ONLY PRODUCED LIMITED RELIEF OF THIS PAIN IN A PORTION OF PATIENTS. THUS, THE PRESENT REVIEW AIMS TO CONTRIBUTE TO FIND NOVEL TARGETS FOR CHRONIC NEUROPATHIC PAIN TREATMENT. 2018 9 3319 38 HISTONE ACETYLATION AND HISTONE DEACETYLATION IN NEUROPATHIC PAIN: AN UNRESOLVED PUZZLE? CHRONIC PAIN IS BROADLY CLASSIFIED INTO SOMATIC, VISCERAL OR NEUROPATHIC PAIN DEPENDING UPON THE LOCATION AND EXTENT OF PAIN PERCEPTION. EVIDENCES FROM DIFFERENT ANIMAL STUDIES SUGGEST THAT INFLAMMATORY OR NEUROPATHIC PAIN IS ASSOCIATED WITH ALTERED ACETYLATION AND DEACETYLATION OF HISTONE PROTEINS, WHICH RESULT IN ABNORMAL TRANSCRIPTION OF NOCICEPTIVE PROCESSING GENES. THERE HAVE BEEN A NUMBER OF STUDIES INDICATING THAT NERVE INJURY UP-REGULATES HISTONE DEACETYLASE ENZYMES, WHICH LEADS TO INCREASED HISTONE DEACETYLATION AND INDUCE CHRONIC PAIN. TREATMENT WITH HISTONE DEACETYLASE INHIBITORS RELIEVES PAIN BY NORMALIZING NERVE INJURY-INDUCED DOWN REGULATION OF METABOTROPIC GLUTAMATE RECEPTORS, GLUTAMATE TRANSPORTERS, GLUTAMIC ACID DECARBOXYLASE 65, NEURON RESTRICTIVE SILENCER FACTOR AND SERUM AND GLUCOCORTICOID INDUCIBLE KINASE 1. ON THE OTHER HAND, A FEW STUDIES REFER TO INCREASED EXPRESSION OF HISTONE ACETYLASE ENZYMES IN RESPONSE TO NERVE INJURY THAT PROMOTES HISTONE ACETYLATION LEADING TO PAIN INDUCTION. TREATMENT WITH HISTONE ACETYL TRANSFERASE INHIBITORS HAVE BEEN REPORTED TO RELIEVE CHRONIC PAIN BY BLOCKING THE UP-REGULATION OF CHEMOKINES AND CYCLOOXYGENASE-2, THE CRITICAL FACTORS ASSOCIATED WITH HISTONE ACETYLATION-INDUCED PAIN. THE PRESENT REVIEW DESCRIBES THE DUAL ROLE OF HISTONE ACETYLATION/DEACETYLATION IN DEVELOPMENT OR ATTENUATION OF NEUROPATHIC PAIN ALONG WITH THE UNDERLYING MECHANISMS. 2017 10 4969 45 PATHOLOGICAL NEUROINFLAMMATORY CONVERSION OF REACTIVE ASTROCYTES IS INDUCED BY MICROGLIA AND INVOLVES CHROMATIN REMODELING. FOLLOWING BRAIN INJURY OR IN NEURODEGENERATIVE DISEASES, ASTROCYTES BECOME REACTIVE AND MAY SUFFER PATHOLOGICAL REMODELING, FEATURES OF WHICH ARE THE LOSS OF THEIR HOMEOSTATIC FUNCTIONS AND A PRO-INFLAMMATORY GAIN OF FUNCTION THAT FACILITATES NEURODEGENERATION. PHARMACOLOGICAL INTERVENTION TO MODULATE THIS ASTROGLIAL RESPONSE AND NEUROINFLAMMATION IS AN INTERESTING NEW THERAPEUTIC RESEARCH STRATEGY, BUT IT STILL REQUIRES A DEEPER UNDERSTANDING OF THE UNDERLYING CELLULAR AND MOLECULAR MECHANISMS OF THE PHENOMENON. BASED ON THE KNOWN MICROGLIAL-ASTROGLIAL INTERACTION, THE PROMINENT ROLE OF THE NUCLEAR FACTOR KAPPA B (NF-KAPPAB) PATHWAY IN MEDIATING ASTROGLIAL PATHOLOGICAL PRO-INFLAMMATORY GAIN OF FUNCTION, AND ITS ABILITY TO RECRUIT CHROMATIN-REMODELING ENZYMES, WE FIRST EXPLORED THE MICROGLIAL ROLE IN THE INITIATION OF ASTROGLIAL PRO-INFLAMMATORY CONVERSION AND THEN MONITORED THE PROGRESSION OF EPIGENETIC CHANGES IN THE ASTROCYTIC CHROMATIN. DIFFERENT CONFIGURATIONS OF PRIMARY GLIAL CULTURE WERE USED TO MODULATE MICROGLIA-ASTROCYTE CROSSTALK WHILE INDUCING PRO-INFLAMMATORY GAIN OF FUNCTION BY LIPOPOLYSACCHARIDE (LPS) EXPOSURE. IN VIVO, BRAIN ISCHEMIA BY CORTICAL DEVASCULARIZATION (PIAL DISRUPTION) WAS PERFORMED TO VERIFY THE PRESENCE OF EPIGENETIC MARKS IN REACTIVE ASTROCYTES. OUR RESULTS SHOWED THAT 1) MICROGLIA IS REQUIRED TO INITIATE THE PATHOLOGICAL CONVERSION OF ASTROCYTES BY TRIGGERING THE NF-KAPPAB SIGNALING PATHWAY; 2) THIS INTERACTION IS MEDIATED BY SOLUBLE FACTORS AND INDUCES STABLE ASTROGLIAL PHENOTYPIC CHANGES; 3) THE PATHOLOGICAL CONVERSION PROMOTES CHROMATIN REMODELING WITH STABLE INCREASE IN H3K9K14AC, TEMPORARY INCREASE IN H3K27AC, AND TEMPORARY REDUCTION IN HETEROCHROMATIN MARK H3K9ME3; AND 4) IN VIVO REACTIVE ASTROCYTES SHOW INCREASED H3K27AC MARK IN THE NEUROINFLAMMATORY MILIEU FROM THE ISCHEMIC PENUMBRA. OUR FINDINGS INDICATE THAT ASTROGLIAL PATHOLOGICAL PRO-INFLAMMATORY GAIN OF FUNCTION IS ASSOCIATED WITH PROFOUND CHANGES IN THE CONFIGURATION OF ASTROCYTIC CHROMATIN, WHICH IN TURN ARE INITIATED BY MICROGLIA-DERIVED CUES. THESE RESULTS OPEN A NEW AVENUE IN THE STUDY OF POTENTIAL PHARMACOLOGICAL INTERVENTIONS THAT MODIFY THE INITIATION AND STABILIZATION OF ASTROGLIAL PATHOLOGICAL REMODELING, WHICH WOULD BE USEFUL IN ACUTE AND CHRONIC CNS INJURY. EPIGENETIC CHANGES REPRESENT A PLAUSIBLE PHARMACOLOGICAL TARGET TO INTERFERE WITH THE STABILIZATION OF THE PATHOLOGICAL ASTROGLIAL PHENOTYPE. 2021 11 6139 36 THE ETIOLOGICAL CONTRIBUTION OF GABAERGIC PLASTICITY TO THE PATHOGENESIS OF NEUROPATHIC PAIN. NEUROPATHIC PAIN DEVELOPING AFTER PERIPHERAL OR CENTRAL NERVE INJURY IS THE RESULT OF PATHOLOGICAL CHANGES GENERATED THROUGH COMPLEX MECHANISMS. DISRUPTION IN THE HOMEOSTASIS OF EXCITATORY AND INHIBITORY NEURONS WITHIN THE CENTRAL NERVOUS SYSTEM IS A CRUCIAL FACTOR IN THE FORMATION OF HYPERALGESIA OR ALLODYNIA OCCURRING WITH NEUROPATHIC PAIN. THE CENTRAL GABAERGIC PATHWAY HAS RECEIVED ATTENTION FOR ITS EXTENSIVE DISTRIBUTION AND FUNCTION IN NEURAL CIRCUITS, INCLUDING THE GENERATION AND DEVELOPMENT OF NEUROPATHIC PAIN. GABAERGIC INHIBITORY CHANGES THAT OCCUR IN THE INTERNEURONS ALONG DESCENDING MODULATORY AND NOCICEPTIVE PATHWAYS IN THE CENTRAL NERVOUS SYSTEM ARE BELIEVED TO GENERATE NEURONAL PLASTICITY, SUCH AS SYNAPTIC PLASTICITY OR FUNCTIONAL PLASTICITY OF THE RELATED GENES OR PROTEINS, THAT IS THE FOUNDATION OF PERSISTENT NEUROPATHIC PAIN. THE PRIMARY GABAERGIC PLASTICITY OBSERVED IN NEUROPATHIC PAIN INCLUDES GABAERGIC SYNAPSE HOMO- AND HETEROSYNAPTIC PLASTICITY, DECREASED SYNTHESIS OF GABA, DOWN-EXPRESSION OF GLUTAMIC ACID DECARBOXYLASE AND GABA TRANSPORTER, ABNORMAL EXPRESSION OF NKCC1 OR KCC2, AND DISTURBED FUNCTION OF GABA RECEPTORS. IN THIS REVIEW, WE DESCRIBE POSSIBLE MECHANISMS ASSOCIATED WITH GABAERGIC PLASTICITY, SUCH AS CENTRAL SENSITIZATION AND GABAERGIC INTERNEURON APOPTOSIS, AND THE EPIGENETIC ETIOLOGIES OF GABAERGIC PLASTICITY IN NEUROPATHIC PAIN. MOREOVER, WE SUMMARIZE POTENTIAL THERAPEUTIC TARGETS OF GABAERGIC PLASTICITY THAT MAY ALLOW FOR SUCCESSFUL RELIEF OF HYPERALGESIA FROM NERVE INJURY. FINALLY, WE COMPARE THE EFFECTS OF THE GABAERGIC SYSTEM IN NEUROPATHIC PAIN TO OTHER TYPES OF CHRONIC PAIN TO UNDERSTAND THE CONTRIBUTION OF GABAERGIC PLASTICITY TO NEUROPATHIC PAIN. 2019 12 3341 32 HISTONE DEACETYLASE-2 IS INVOLVED IN STRESS-INDUCED COGNITIVE IMPAIRMENT VIA HISTONE DEACETYLATION AND PI3K/AKT SIGNALING PATHWAY MODIFICATION. EXPOSURE TO CHRONIC STRESS UPREGULATES BLOOD GLUCOCORTICOID LEVELS AND IMPAIRS COGNITION VIA DIVERSE EPIGENETIC MECHANISMS, SUCH AS HISTONE DEACETYLATION. HISTONE DEACETYLATION CAN LEAD TO TRANSCRIPTIONAL SILENCING OF MANY PROTEINS INVOLVED IN COGNITION AND MAY ALSO CAUSE LEARNING AND MEMORY DYSFUNCTION. HISTONE DEACETYLASE?2 (HDAC2) HAS BEEN DEMONSTRATED TO EPIGENETICALLY BLOCK COGNITION VIA A REDUCTION IN THE HISTONE ACETYLATION LEVEL; HOWEVER, IT IS UNKNOWN WHETHER HDAC2 IS INVOLVED IN THE COGNITIVE DECLINE INDUCED BY CHRONIC STRESS. TO THE BEST OF AUTHORS' KNOWLEDGE, THIS IS THE FIRST STUDY TO DEMONSTRATE THAT THE STRESS HORMONE CORTICOSTEROID UPREGULATE HDAC2 PROTEIN LEVELS IN NEURO?2A CELLS AND CAUSE CELL INJURIES. HDAC2 KNOCKDOWN RESULTED IN A SIGNIFICANT AMELIORATION OF THE PATHOLOGICAL CHANGES IN N2A CELLS VIA THE UPREGULATION OF HISTONE ACETYLATION AND MODIFICATIONS IN THE PHOSPHOINOSITIDE 3?KINASE/PROTEIN KINASE B SIGNALING PATHWAY. IN ADDITION, THE HDAC2 PROTEIN LEVELS WERE UPREGULATED IN 12?MONTH?OLD FEMALE C57BL/6J MICE UNDER CHRONIC STRESS IN VIVO. TAKEN TOGETHER, THESE FINDINGS SUGGESTED THAT HDAC2 MAY BE AN IMPORTANT NEGATIVE REGULATOR INVOLVED IN CHRONIC STRESS?INDUCED COGNITIVE IMPAIRMENT. 2017 13 948 29 CHRONIC METABOLIC DERANGEMENT-INDUCED COGNITIVE DEFICITS AND NEUROTOXICITY ARE ASSOCIATED WITH REST INACTIVATION. CHRONIC METABOLIC ALTERATIONS MAY REPRESENT A RISK FACTOR FOR THE DEVELOPMENT OF COGNITIVE IMPAIRMENT, DEMENTIA, OR NEURODEGENERATIVE DISEASES. HYPERGLYCEMIA AND OBESITY ARE KNOWN TO IMPRINT EPIGENETIC MARKERS THAT COMPROMISE THE PROPER EXPRESSION OF CELL SURVIVAL GENES. HERE, WE SHOWED THAT CHRONIC HYPERGLYCEMIA (60 DAYS) INDUCED BY A SINGLE INTRAPERITONEAL INJECTION OF STREPTOZOTOCIN COMPROMISED COGNITION BY REDUCING HIPPOCAMPAL ERK SIGNALING AND BY INDUCING NEUROTOXICITY IN RATS. THE MECHANISMS APPEAR TO BE LINKED TO REDUCED ACTIVE DNA DEMETHYLATION AND DIMINISHED EXPRESSION OF THE NEUROPROTECTIVE TRANSCRIPTION FACTOR REST. THE IMPACT OF THE RELATIONSHIP BETWEEN ADIPOSITY AND DNA HYPERMETHYLATION ON REST EXPRESSION WAS ALSO DEMONSTRATED IN PERIPHERAL BLOOD MONONUCLEAR CELLS IN OBESE CHILDREN WITH REDUCED LEVELS OF BLOOD ASCORBATE. THE REVERSIBLE NATURE OF EPIGENETIC MODIFICATIONS AND THE COGNITIVE IMPAIRMENT REPORTED IN OBESE CHILDREN, ADOLESCENTS, AND ADULTS SUGGEST THAT THE CORRECTION OF THE ANTHROPOMETRY AND THE PERIPHERAL METABOLIC ALTERATIONS WOULD PROTECT BRAIN HOMEOSTASIS AND REDUCE THE RISK OF DEVELOPING NEURODEGENERATIVE DISEASES. 2019 14 2003 27 EPIGENETIC AND TRANSCRIPTIONAL CONTROL OF THE OPIOID PRODYNORPHINE GENE: IN-DEPTH ANALYSIS IN THE HUMAN BRAIN. NEUROPEPTIDES SERVE AS NEUROHORMONES AND LOCAL PARACRINE REGULATORS THAT CONTROL NEURAL NETWORKS REGULATING BEHAVIOR, ENDOCRINE SYSTEM AND SENSORIMOTOR FUNCTIONS. THEIR EXPRESSION IS CHARACTERIZED BY EXCEPTIONALLY RESTRICTED PROFILES. CIRCUIT-SPECIFIC AND ADAPTIVE EXPRESSION OF NEUROPEPTIDE GENES MAY BE DEFINED BY TRANSCRIPTIONAL AND EPIGENETIC MECHANISMS CONTROLLED BY CELL TYPE AND SUBTYPE SEQUENCE-SPECIFIC TRANSCRIPTION FACTORS, INSULATORS AND SILENCERS. THE OPIOID PEPTIDE DYNORPHINS PLAY A CRITICAL ROLE IN NEUROLOGICAL AND PSYCHIATRIC DISORDERS, PAIN PROCESSING AND STRESS, WHILE THEIR MUTATIONS CAUSE PROFOUND NEURODEGENERATION IN THE HUMAN BRAIN. IN THIS REVIEW, WE FOCUS ON THE PRODYNORPHIN GENE AS A MODEL FOR THE IN-DEPTH EPIGENETIC AND TRANSCRIPTIONAL ANALYSIS OF EXPRESSION OF THE NEUROPEPTIDE GENES. PRODYNORPHIN STUDIES MAY PROVIDE A FRAMEWORK FOR ANALYSIS OF MECHANISMS RELEVANT FOR REGULATION OF NEUROPEPTIDE GENES IN NORMAL AND PATHOLOGICAL HUMAN BRAIN. 2021 15 5709 52 SIRT1 DECREASES EMOTIONAL PAIN VULNERABILITY WITH ASSOCIATED CAMKIIALPHA DEACETYLATION IN CENTRAL AMYGDALA. EMOTIONAL DISORDERS ARE COMMON COMORBID CONDITIONS THAT FURTHER EXACERBATE THE SEVERITY AND CHRONICITY OF CHRONIC PAIN. HOWEVER, INDIVIDUALS SHOW CONSIDERABLE VULNERABILITY TO THE DEVELOPMENT OF CHRONIC PAIN UNDER SIMILAR PAIN CONDITIONS. IN THIS STUDY ON MALE RAT AND MOUSE MODELS OF CHRONIC NEUROPATHIC PAIN, WE IDENTIFY THE HISTONE DEACETYLASE SIRTUIN 1 (SIRT1) IN CENTRAL AMYGDALA AS A KEY EPIGENETIC REGULATOR THAT CONTROLS THE DEVELOPMENT OF COMORBID EMOTIONAL DISORDERS UNDERLYING THE INDIVIDUAL VULNERABILITY TO CHRONIC PAIN. WE FOUND THAT ANIMALS THAT WERE VULNERABLE TO DEVELOPING BEHAVIORS OF ANXIETY AND DEPRESSION UNDER THE PAIN CONDITION DISPLAYED REDUCED SIRT1 PROTEIN LEVELS IN CENTRAL AMYGDALA, BUT NOT THOSE ANIMALS RESISTANT TO THE EMOTIONAL DISORDERS. VIRAL OVEREXPRESSION OF LOCAL SIRT1 REVERSED THIS VULNERABILITY, BUT VIRAL KNOCKDOWN OF LOCAL SIRT1 MIMICKED THE PAIN EFFECT, ELICITING THE PAIN VULNERABILITY IN PAIN-FREE ANIMALS. THE SIRT1 ACTION WAS ASSOCIATED WITH CAMKIIALPHA DOWNREGULATION AND DEACETYLATION OF HISTONE H3 LYSINE 9 AT THE CAMKIIALPHA PROMOTER. THESE RESULTS SUGGEST THAT, BY TRANSCRIPTIONAL REPRESSION OF CAMKIIALPHA IN CENTRAL AMYGDALA, SIRT1 FUNCTIONS TO GUARD AGAINST THE EMOTIONAL PAIN VULNERABILITY UNDER CHRONIC PAIN CONDITIONS. THIS STUDY INDICATES THAT SIRT1 MAY SERVE AS A POTENTIAL THERAPEUTIC MOLECULE FOR INDIVIDUALIZED TREATMENT OF CHRONIC PAIN WITH VULNERABLE EMOTIONAL DISORDERS.SIGNIFICANCE STATEMENT CHRONIC PAIN IS A PREVALENT NEUROLOGICAL DISEASE WITH NO EFFECTIVE TREATMENT AT PRESENT. PAIN PATIENTS DISPLAY CONSIDERABLY VARIABLE VULNERABILITY TO DEVELOPING CHRONIC PAIN, INDICATING INDIVIDUAL-BASED MOLECULAR MECHANISMS UNDERLYING THE PAIN VULNERABILITY, WHICH IS HARDLY ADDRESSED IN CURRENT PRECLINICAL RESEARCH. IN THIS STUDY, WE HAVE IDENTIFIED THE HISTONE DEACETYLASE SIRTUIN 1 (SIRT1) AS A KEY REGULATOR THAT CONTROLS THIS PAIN VULNERABILITY. THIS STUDY REVEALS THAT THE SIRT1-CAMKIIAALPHA PATHWAY IN CENTRAL AMYGDALA ACTS AS AN EPIGENETIC MECHANISM THAT GUARDS AGAINST THE DEVELOPMENT OF COMORBID EMOTIONAL DISORDERS UNDER CHRONIC PAIN, AND THAT ITS DYSFUNCTION CAUSES INCREASED VULNERABILITY TO THE DEVELOPMENT OF CHRONIC PAIN. THESE FINDINGS SUGGEST THAT SIRT1 ACTIVATORS MAY BE USED IN A NOVEL THERAPEUTIC APPROACH FOR INDIVIDUAL-BASED TREATMENT OF CHRONIC PAIN. 2020 16 5007 33 PERIPHERAL NERVE INJURY IS ASSOCIATED WITH CHRONIC, REVERSIBLE CHANGES IN GLOBAL DNA METHYLATION IN THE MOUSE PREFRONTAL CORTEX. CHANGES IN BRAIN STRUCTURE AND CORTICAL FUNCTION ARE ASSOCIATED WITH MANY CHRONIC PAIN CONDITIONS INCLUDING LOW BACK PAIN AND FIBROMYALGIA. THE MAGNITUDE OF THESE CHANGES CORRELATES WITH THE DURATION AND/OR THE INTENSITY OF CHRONIC PAIN. MOST STUDIES REPORT CHANGES IN COMMON AREAS INVOLVED IN PAIN MODULATION, INCLUDING THE PREFRONTAL CORTEX (PFC), AND PAIN-RELATED PATHOLOGICAL CHANGES IN THE PFC CAN BE REVERSED WITH EFFECTIVE TREATMENT. WHILE THE MECHANISMS UNDERLYING THESE CHANGES ARE UNKNOWN, THEY MUST BE DYNAMICALLY REGULATED. EPIGENETIC MODULATION OF GENE EXPRESSION IN RESPONSE TO EXPERIENCE AND ENVIRONMENT IS REVERSIBLE AND DYNAMIC. EPIGENETIC MODULATION BY DNA METHYLATION IS ASSOCIATED WITH ABNORMAL BEHAVIOR AND PATHOLOGICAL GENE EXPRESSION IN THE CENTRAL NERVOUS SYSTEM. DNA METHYLATION MIGHT ALSO BE INVOLVED IN MEDIATING THE PATHOLOGIES ASSOCIATED WITH CHRONIC PAIN IN THE BRAIN. WE THEREFORE TESTED A) WHETHER ALTERATIONS IN DNA METHYLATION ARE FOUND IN THE BRAIN LONG AFTER CHRONIC NEUROPATHIC PAIN IS INDUCED IN THE PERIPHERY USING THE SPARED NERVE INJURY MODAL AND B) WHETHER THESE INJURY-ASSOCIATED CHANGES ARE REVERSIBLE BY INTERVENTIONS THAT REVERSE THE PATHOLOGIES ASSOCIATED WITH CHRONIC PAIN. SIX MONTHS FOLLOWING PERIPHERAL NERVE INJURY, ABNORMAL SENSORY THRESHOLDS AND INCREASED ANXIETY WERE ACCOMPANIED BY DECREASED GLOBAL METHYLATION IN THE PFC AND THE AMYGDALA BUT NOT IN THE VISUAL CORTEX OR THE THALAMUS. ENVIRONMENTAL ENRICHMENT ATTENUATED NERVE INJURY-INDUCED HYPERSENSITIVITY AND REVERSED THE CHANGES IN GLOBAL PFC METHYLATION. FURTHERMORE, GLOBAL PFC METHYLATION CORRELATED WITH MECHANICAL AND THERMAL SENSITIVITY IN NEUROPATHIC MICE. IN SUMMARY, INDUCTION OF CHRONIC PAIN BY PERIPHERAL NERVE INJURY IS ASSOCIATED WITH EPIGENETIC CHANGES IN THE BRAIN. THESE CHANGES ARE DETECTED LONG AFTER THE ORIGINAL INJURY, AT A LONG DISTANCE FROM THE SITE OF INJURY AND ARE REVERSIBLE WITH ENVIRONMENTAL MANIPULATION. CHANGES IN BRAIN STRUCTURE AND CORTICAL FUNCTION THAT ARE ASSOCIATED WITH CHRONIC PAIN CONDITIONS MAY THEREFORE BE MEDIATED BY EPIGENETIC MECHANISMS. 2013 17 5624 32 SELECTIVE BOOSTING OF TRANSCRIPTIONAL AND BEHAVIORAL RESPONSES TO DRUGS OF ABUSE BY HISTONE DEACETYLASE INHIBITION. HISTONE ACETYLATION AND OTHER MODIFICATIONS OF THE CHROMATIN ARE IMPORTANT REGULATORS OF GENE EXPRESSION AND, CONSEQUENTLY, MAY CONTRIBUTE TO DRUG-INDUCED BEHAVIORS AND NEUROPLASTICITY. EARLIER STUDIES HAVE SHOWN THAT A REDUCTION IN HISTONE DEACETYLASE (HDAC) ACTIVITY RESULTS IN THE ENHANCEMENT OF SOME PSYCHOSTIMULANT-INDUCED BEHAVIORS. IN THIS STUDY, WE EXTEND THOSE SEMINAL FINDINGS BY SHOWING THAT THE ADMINISTRATION OF THE HDAC INHIBITOR SODIUM BUTYRATE ENHANCES MORPHINE-INDUCED LOCOMOTOR SENSITIZATION AND CONDITIONED PLACE PREFERENCE. IN CONTRAST, THIS COMPOUND HAS NO EFFECTS ON THE DEVELOPMENT OF MORPHINE TOLERANCE AND DEPENDENCE. SIMILAR EFFECTS WERE OBSERVED FOR COCAINE AND ETHANOL-INDUCED BEHAVIORS. THESE BEHAVIORAL CHANGES WERE ACCOMPANIED BY A SELECTIVE BOOSTING OF A COMPONENT OF THE TRANSCRIPTIONAL PROGRAM ACTIVATED BY CHRONIC MORPHINE ADMINISTRATION THAT INCLUDED CIRCADIAN CLOCK GENES AND OTHER GENES RELEVANT TO ADDICTIVE BEHAVIOR. OUR RESULTS SUPPORT A SPECIFIC FUNCTION FOR HISTONE ACETYLATION AND THE EPIGENETIC MODULATION OF TRANSCRIPTION AT A REDUCED NUMBER OF BIOLOGICALLY RELEVANT LOCI ON NON-HOMEOSTATIC, LONG-LASTING, DRUG-INDUCED BEHAVIORAL PLASTICITY. 2009 18 6174 37 THE HIPPOCAMPUS, NEUROTROPHIC FACTORS AND DEPRESSION: POSSIBLE IMPLICATIONS FOR THE PHARMACOTHERAPY OF DEPRESSION. DEPRESSION IS A PREVALENT, HIGHLY DEBILITATING MENTAL DISORDER AFFECTING UP TO 15% OF THE POPULATION AT LEAST ONCE IN THEIR LIFETIME, WITH HUGE COSTS FOR SOCIETY. NEUROBIOLOGICAL MECHANISMS OF DEPRESSION ARE STILL NOT WELL KNOWN, ALTHOUGH THERE IS CONSENSUS ABOUT INTERPLAY BETWEEN GENETIC AND ENVIRONMENTAL FACTORS. ANTIDEPRESSANT MEDICATIONS ARE FREQUENTLY USED IN DEPRESSION, BUT AT LEAST 50% OF PATIENTS ARE POOR RESPONDERS, EVEN TO MORE RECENTLY DISCOVERED MEDICATIONS. FURTHERMORE, CLINICAL RESPONSE ONLY OCCURS FOLLOWING WEEKS TO MONTHS OF TREATMENT AND ONLY CHRONIC TREATMENT IS EFFECTIVE, SUGGESTING THAT ACTIONS BEYOND THE RAPIDLY OCCURRING EFFECT OF ENHANCING MONOAMINERGIC SYSTEMS, SUCH AS ADAPTATION OF THESE SYSTEMS, ARE RESPONSIBLE FOR THE EFFECTS OF ANTIDEPRESSANTS. RECENT STUDIES INDICATE THAT AN IMPAIRMENT OF SYNAPTIC PLASTICITY (NEUROGENESIS, AXON BRANCHING, DENDRITOGENESIS AND SYNAPTOGENESIS) IN SPECIFIC AREAS OF THE CNS, PARTICULARLY THE HIPPOCAMPUS, MAY BE A CORE FACTOR IN THE PATHOPHYSIOLOGY OF DEPRESSION. THE ABNORMAL NEURAL PLASTICITY MAY BE RELATED TO ALTERATIONS IN THE LEVELS OF NEUROTROPHIC FACTORS, NAMELY BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF), WHICH PLAY A CENTRAL ROLE IN PLASTICITY. AS BDNF IS REPRESSED BY STRESS, EPIGENETIC REGULATION OF THE BDNF GENE MAY PLAY AN IMPORTANT ROLE IN DEPRESSION. THE HIPPOCAMPUS IS SMALLER IN DEPRESSED PATIENTS, ALTHOUGH IT IS UNCLEAR WHETHER SMALLER SIZE IS A CONSEQUENCE OF DEPRESSION OR A PRE-EXISTING, VULNERABILITY MARKER FOR DEPRESSION. ENVIRONMENTAL STRESSORS TRIGGERING ACTIVATION OF THE HYPOTHALAMIC-PITUITARY-ADRENAL AXIS CAUSE THE BRAIN TO BE EXPOSED TO CORTICOSTEROIDS, AFFECTING NEUROBEHAVIOURAL FUNCTIONS WITH A STRONG DOWNREGULATION OF HIPPOCAMPAL NEUROGENESIS, AND ARE A MAJOR RISK FACTOR FOR DEPRESSION. ANTIDEPRESSANT TREATMENT INCREASES BDNF LEVELS, STIMULATES NEUROGENESIS AND REVERSES THE INHIBITORY EFFECTS OF STRESS, BUT THIS EFFECT IS EVIDENT ONLY AFTER 3-4 WEEKS OF ADMINISTRATION, THE TIME COURSE FOR MATURATION OF NEW NEURONS. THE ABLATION OF HIPPOCAMPAL NEUROGENESIS BLOCKS THE BEHAVIOURAL EFFECTS OF ANTIDEPRESSANTS IN ANIMAL MODELS. THE ABOVE FINDINGS SUGGEST NEW POSSIBLE TARGETS FOR THE PHARMACOTHERAPY OF DEPRESSION SUCH AS NEUROTROPHIC FACTORS, THEIR RECEPTORS AND RELATED INTRACELLULAR SIGNALLING CASCADES; AGENTS COUNTERACTING THE EFFECTS OF STRESS ON HIPPOCAMPAL NEUROGENESIS (INCLUDING ANTAGONISTS OF CORTICOSTEROIDS, INFLAMMATORY CYTOKINES AND THEIR RECEPTORS); AND AGENTS FACILITATING THE ACTIVATION OF GENE EXPRESSION AND INCREASING THE TRANSCRIPTION OF NEUROTROPHINS IN THE BRAIN. 2011 19 5427 30 REGULATION OF SOCIAL STRESS AND NEURAL DEGENERATION BY ACTIVITY-REGULATED GENES AND EPIGENETIC MECHANISMS IN DOPAMINERGIC NEURONS. TRANSCRIPTIONAL AND EPIGENETIC REGULATION OF BOTH DOPAMINERGIC NEURONS AND THEIR ACCOMPANYING GLIAL CELLS IS OF GREAT INTEREST IN THE SEARCH FOR THERAPIES FOR NEURODEGENERATIVE DISORDERS SUCH AS PARKINSON'S DISEASE (PD). IN THIS REVIEW, WE COLLATE TRANSCRIPTIONAL AND EPIGENETIC CHANGES IDENTIFIED IN ADULT DROSOPHILA MELANOGASTER DOPAMINERGIC NEURONS IN RESPONSE TO EITHER PROLONGED SOCIAL DEPRIVATION OR SOCIAL ENRICHMENT, AND COMPARE THEM WITH CHANGES IDENTIFIED IN MAMMALIAN DOPAMINERGIC NEURONS DURING NORMAL DEVELOPMENT, STRESS, INJURY, AND NEURODEGENERATION. SURPRISINGLY, A SMALL SET OF ACTIVITY-REGULATED GENES (ARG) ENCODING TRANSCRIPTION FACTORS, AND A SPECIFIC PATTERN OF EPIGENETIC MARKS ON GENE PROMOTERS, ARE CONSERVED IN DOPAMINERGIC NEURONS OVER THE LONG EVOLUTIONARY PERIOD BETWEEN MAMMALS AND INSECTS. IN ADDITION TO THEIR CLASSICAL FUNCTION AS IMMEDIATE EARLY GENES TO MARK ACUTE NEURONAL ACTIVITY, THESE ARG TRANSCRIPTION FACTORS ARE REPURPOSED IN BOTH INSECTS AND MAMMALS TO RESPOND TO CHRONIC PERTURBATIONS SUCH AS SOCIAL ENRICHMENT, SOCIAL STRESS, NERVE INJURY, AND NEURODEGENERATION. WE SUGGEST THAT THESE ARG TRANSCRIPTION FACTORS AND EPIGENETIC MARKS MAY REPRESENT IMPORTANT TARGETS FOR FUTURE THERAPEUTIC INTERVENTION STRATEGIES IN VARIOUS NEURODEGENERATIVE DISORDERS INCLUDING PD. 2020 20 4401 39 MODULATION OF NEURONAL PLASTICITY FOLLOWING CHRONIC CONCOMITANT ADMINISTRATION OF THE NOVEL ANTIPSYCHOTIC LURASIDONE WITH THE MOOD STABILIZER VALPROIC ACID. RATIONALE: COMBINATORY THERAPY IS WIDELY USED IN PSYCHIATRY OWING TO THE POSSIBILITY THAT DRUGS WITH DIFFERENT MECHANISMS OF ACTION MAY SYNERGIZE TO IMPROVE FUNCTIONS DETERIORATED IN SCHIZOPHRENIA, BIPOLAR DISORDERS, AND MAJOR DEPRESSION. WHILE COMBINATORY STRATEGIES RELY ON RECEPTOR AND SYNAPTIC MECHANISMS, IT SHOULD ALSO BE CONSIDERED THAT TWO DRUGS MAY ALSO "INTERACT" ON THE LONG-TERM TO DETERMINE MORE ROBUST CHANGES IN NEURONAL PLASTICITY, WHICH REPRESENTS A DOWNSTREAM TARGET IMPORTANT FOR FUNCTIONAL RECOVERY. OBJECTIVE: THE AIM OF THE STUDY IS TO INVESTIGATE NEUROADAPTIVE CHANGES SET IN MOTION BY CHRONIC CONCOMITANT ADMINISTRATION OF THE NOVEL ANTIPSYCHOTIC LURASIDONE AND THE MOOD STABILIZER VALPROATE. METHODS: ANIMALS WERE CHRONICALLY TREATED WITH LURASIDONE, VALPROATE, OR THE COMBINATION OF THE TWO DRUGS AND KILLED 24 H AFTER THE LAST INJECTION TO EVALUATE ALTERATIONS OF DIFFERENT MEASURES OF NEURONAL PLASTICITY SUCH AS THE NEUROTROPHIN BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF), THE IMMEDIATE EARLY GENE ACTIVITY-REGULATED CYTOSKELETAL ASSOCIATED PROTEIN, AND THE EPIGENETIC REGULATORS HDAC 1, 2, AND 5 IN DORSAL AND VENTRAL HIPPOCAMPUS. RESULTS: THE RESULTS SUGGEST THAT COADMINISTRATION OF LURASIDONE AND VALPROATE PRODUCES, WHEN COMPARED TO THE SINGLE DRUGS, A LARGER INCREASE IN THE EXPRESSION OF BDNF IN THE VENTRAL HIPPOCAMPUS, THROUGH THE REGULATION OF SPECIFIC NEUROTROPHIN TRANSCRIPTS. WE ALSO FOUND THAT THE HISTONE DEACETYLASES WERE REGULATED BY THE DRUG COMBINATION, SUGGESTING THAT SOME OF THE TRANSCRIPTIONAL CHANGES MAY BE SUSTAINED BY EPIGENETIC MECHANISMS. CONCLUSIONS: OUR RESULTS SUGGEST THAT THE BENEFICIAL EFFECTS ASSOCIATED WITH COMBINATORY TREATMENT BETWEEN A SECOND-GENERATION ANTIPSYCHOTIC AND A MOOD STABILIZER COULD RESULT FROM THE ABILITY TO MODULATE NEUROPLASTIC MOLECULES, WHOSE EXPRESSION AND FUNCTION IS DETERIORATED IN DIFFERENT PSYCHIATRIC CONDITIONS. 2013