1 1205 136 COULD THE INHIBITOR OF DNA BINDING 2 AND 4 PLAY A ROLE IN WHITE MATTER INJURY? WHITE MATTER INJURY (WMI) PREVENTS THE NORMAL DEVELOPMENT OF MYELINATION, LEADING TO CENTRAL NERVOUS SYSTEM MYELINATION DISORDERS AND THE PRODUCTION OF CHRONIC SEQUELAE ASSOCIATED WITH WMI, SUCH AS CHRONIC DYSKINESIA, COGNITIVE IMPAIRMENT AND CEREBRAL PALSY. THIS RESULTS IN A LARGE EMOTIONAL AND SOCIOECONOMIC BURDEN. DECREASED MYELINATION IN PRETERM INFANT WMI IS ASSOCIATED WITH THE DELAYED DEVELOPMENT OR DESTRUCTION OF OLIGODENDROCYTE (OL) LINEAGE CELLS, PARTICULARLY OLIGODENDROCYTE PRECURSOR CELLS (OPCS). THE DEVELOPMENT OF CELLS FROM THE OL LINEAGE INVOLVES THE MIGRATION, PROLIFERATION AND DIFFERENT STAGES OF OL DIFFERENTIATION, FINALLY LEADING TO MYELINATION. A SERIES OF COMPLEX INTRINSIC, EXTRINSIC AND EPIGENETIC FACTORS REGULATE THE OPC CELL CYCLE WITHDRAWAL, OL LINEAGE PROGRESSION AND MYELINATION. WE FOCUS ON THE INHIBITOR OF DNA BINDING 2 (ID2), BECAUSE IT IS WIDELY INVOLVED IN THE DIFFERENT STAGES OF OL DIFFERENTIATION AND GENESIS. ID2 IS A KEY TRANSCRIPTION FACTOR FOR THE NORMAL DEVELOPMENT OF OL LINEAGE CELLS, AND THE PATHOGENESIS OF WMI IS CLOSELY LINKED WITH OL DEVELOPMENTAL DISORDERS. ID4, ANOTHER FAMILY MEMBER OF THE IDS PROTEIN, ALSO PLAYS A SIMILAR ROLE IN OL DIFFERENTIATION AND GENESIS. ID2 AND ID4 BELONG TO THE HELIX-LOOP-HELIX FAMILY; THEY LACK THE DNA-BINDING SEQUENCES AND INHIBIT OLIGODENDROGENESIS AND OPC DIFFERENTIATION. IN THIS REVIEW, WE MAINLY DISCUSS THE ROLES OF ID2 IN OL DEVELOPMENT, ESPECIALLY DURING OPC DIFFERENTIATION, AND SUMMARIZE THE ID2-MEDIATED INTRACELLULAR AND EXTRACELLULAR SIGNALING PATHWAYS THAT REGULATE THESE PROCESSES. WE ALSO DISCUSS ID4 IN RELATION TO BONE MORPHOGENETIC PROTEIN SIGNALING AND OLIGODENDROGENESIS. IT IS LIKELY THAT THESE DEVELOPMENTAL MECHANISMS ARE ALSO INVOLVED IN THE MYELIN REPAIR OR REMYELINATION IN HUMAN NEUROLOGICAL DISEASES. 2019 2 1179 32 CONVERGENCE AND DIVERGENCE IN THE ETIOLOGY OF MYELIN IMPAIRMENT IN PSYCHIATRIC DISORDERS AND DRUG ADDICTION. IMPAIRMENT OF OLIGODENDROGLIA (OL)-DEPENDENT MYELINATION IN THE CENTRAL NERVOUS SYSTEM (CNS) IS A REMARKABLE PARALLEL RECENTLY IDENTIFIED IN MAJOR PSYCHIATRIC DISORDERS AND CHRONIC DRUG ABUSE. NEUROIMAGING AND NEUROPATHOLOGICAL STUDIES REVEALED MYELIN DEFECTS AND MICROARRAY-PROFILING ANALYSIS DEMONSTRATED ABERRANT EXPRESSION OF MYELIN-RELATED GENES IN SCHIZOPHRENIA (SZ), BIPOLAR DISORDER (BD), MAJOR DEPRESSIVE DISORDER (MDD) AND COCAINE ADDICTION. HOWEVER, THE ETIOLOGY UNDERLYING MYELIN IMPAIRMENT IN THESE CLINICALLY DISTINCT SUBJECTS REMAINS ELUSIVE. THIS ARTICLE REVIEWS MYELIN IMPAIRMENT IN LINE WITH DOPAMINERGIC DYSFUNCTION, A PRIME NEUROPATHOPHYSIOLOGICAL TRAIT SHARED IN PSYCHIATRIC DISORDERS AND DRUG ABUSE, AS WELL AS THE GENETIC AND EPIGENETIC ALTERATIONS ASSOCIATED WITH THESE DISEASES. THE CURRENT FINDINGS SUPPORT THE HYPOTHESIS THAT ABERRANT DOPAMINE (DA) ACTION ON OLS IS A COMMON PATHOLOGIC MECHANISM FOR MYELIN IMPAIRMENT IN THE AFOREMENTIONED MENTAL MORBIDITIES, WHEREAS INHERITED GENETIC VARIATIONS THAT SPECIFICALLY AFFECT OL DEVELOPMENT AND MYELINOGENESIS MAY FURTHER INCREASE MYELIN VULNERABILITY IN PSYCHIATRIC DISORDERS. IMPORTANTLY, OL DEFECT IS NOT ONLY A PATHOLOGICAL CONSEQUENCE BUT ALSO A CAUSATIVE FACTOR FOR DOPAMINERGIC DYSFUNCTION. HENCE, MYELIN IMPAIRMENT IS A KEY FACTOR IN THE PATHOGENIC LOOP OF PSYCHIATRIC DISEASES AND DRUG ADDICTION. 2008 3 6531 46 TRANSCRIPTIONAL REGULATION OF BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) BY METHYL CPG BINDING PROTEIN 2 (MECP2): A NOVEL MECHANISM FOR RE-MYELINATION AND/OR MYELIN REPAIR INVOLVED IN THE TREATMENT OF MULTIPLE SCLEROSIS (MS). MULTIPLE SCLEROSIS (MS) IS A CHRONIC PROGRESSIVE, NEUROLOGICAL DISEASE CHARACTERIZED BY THE TARGETED IMMUNE SYSTEM-MEDIATED DESTRUCTION OF CENTRAL NERVOUS SYSTEM (CNS) MYELIN. AUTOREACTIVE CD4+ T HELPER CELLS HAVE A KEY ROLE IN ORCHESTRATING MS-INDUCED MYELIN DAMAGE. ONCE ACTIVATED, CIRCULATING TH1-CELLS SECRETE A VARIETY OF INFLAMMATORY CYTOKINES THAT FOSTER THE BREAKDOWN OF BLOOD-BRAIN BARRIER (BBB) EVENTUALLY INFILTRATING INTO THE CNS. INSIDE THE CNS, THEY BECOME REACTIVATED UPON EXPOSURE TO THE MYELIN STRUCTURAL PROTEINS AND CONTINUE TO PRODUCE INFLAMMATORY CYTOKINES SUCH AS TUMOR NECROSIS FACTOR ALPHA (TNFALPHA) THAT LEADS TO DIRECT ACTIVATION OF ANTIBODIES AND MACROPHAGES THAT ARE INVOLVED IN THE PHAGOCYTOSIS OF MYELIN. PROLIFERATING OLIGODENDROCYTE PRECURSORS (OPS) MIGRATING TO THE LESION SITES ARE CAPABLE OF ACUTE REMYELINATION BUT UNABLE TO COMPLETELY REPAIR OR RESTORE THE IMMUNE SYSTEM-MEDIATED MYELIN DAMAGE. THIS RESULTS IN VARIOUS PERMANENT CLINICAL NEUROLOGICAL DISABILITIES SUCH AS COGNITIVE DYSFUNCTION, FATIGUE, BOWEL/BLADDER ABNORMALITIES, AND NEUROPATHIC PAIN. AT PRESENT, THERE IS NO CURE FOR MS. RECENT REMYELINATION AND/OR MYELIN REPAIR STRATEGIES HAVE FOCUSED ON THE ROLE OF THE NEUROTROPHIN BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) AND ITS UPSTREAM TRANSCRIPTIONAL REPRESSOR METHYL CPG BINDING PROTEIN (MECP2). RESEARCH IN THE FIELD OF EPIGENETIC THERAPEUTICS INVOLVING HISTONE DEACETYLASE (HDAC) INHIBITORS AND LYSINE ACETYL TRANSFERASE (KAT) INHIBITORS IS BEING EXPLORED TO REPRESS THE DETRIMENTAL EFFECTS OF MECP2. THIS REVIEW WILL ADDRESS THE ROLE OF MECP2 AND BDNF IN REMYELINATION AND/OR MYELIN REPAIR AND THE POTENTIAL OF HDAC AND KAT INHIBITORS AS NOVEL THERAPEUTIC INTERVENTIONS FOR MS. 2016 4 6136 40 THE EPIGENETICS OF MULTIPLE SCLEROSIS AND OTHER RELATED DISORDERS. MULTIPLE SCLEROSIS (MS) IS A DEMYELINATING DISEASE CHARACTERIZED BY CHRONIC INFLAMMATION OF THE CENTRAL NERVOUS SYSTEM (CNS) GRAY AND WHITE MATTER. ALTHOUGH THE CAUSE OF MS IS UNKNOWN, IT IS WIDELY APPRECIATED THAT INNATE AND ADAPTIVE IMMUNE PROCESSES CONTRIBUTE TO ITS PATHOGENESIS. THESE INCLUDE MICROGLIA/MACROPHAGE ACTIVATION, PRO-INFLAMMATORY T-CELL (TH1) RESPONSES AND HUMORAL RESPONSES. ADDITIONALLY, THERE IS EVIDENCE INDICATING THAT MS HAS A NEURODEGENERATIVE COMPONENT SINCE NEURONAL AND AXONAL LOSS OCCURS EVEN IN THE ABSENCE OF OVERT INFLAMMATION. THESE ASPECTS ALSO FORM THE RATIONALE FOR CLINICAL MANAGEMENT OF THE DISEASE. HOWEVER, THE CURRENTLY AVAILABLE THERAPIES TO CONTROL THE DISEASE ARE ONLY PARTIALLY EFFECTIVE AT BEST INDICATING THAT MORE EFFECTIVE THERAPEUTIC SOLUTIONS ARE URGENTLY NEEDED. IT IS APPRECIATED THAT IN THE IMMUNE-DRIVEN AND NEURODEGENERATIVE PROCESSES MS-SPECIFIC DEREGULATION OF GENE EXPRESSIONS AND RESULTING PROTEIN DYSFUNCTION ARE THOUGHT TO PLAY A CENTRAL ROLE. THESE DEVIATIONS IN GENE EXPRESSION PATTERNS CONTRIBUTE TO THE INFLAMMATORY RESPONSE IN THE CNS, AND TO NEURONAL OR AXONAL LOSS. EPIGENETIC MECHANISMS CONTROL TRANSCRIPTION OF MOST, IF NOT ALL GENES, IN NUCLEATED CELLS INCLUDING CELLS OF THE CNS AND IN HAEMATOPOIETIC CELLS. MS-SPECIFIC ALTERATIONS IN EPIGENETIC REGULATION OF GENE EXPRESSION MAY THEREFORE LIE AT THE HEART OF THE DEREGULATION OF GENE EXPRESSION IN MS. AS SUCH, EPIGENETIC MECHANISMS MOST LIKELY PLAY AN IMPORTANT ROLE IN DISEASE PATHOGENESIS. IN THIS REVIEW WE DISCUSS A ROLE FOR MS-SPECIFIC DEREGULATION OF EPIGENETIC FEATURES THAT CONTROL GENE EXPRESSION IN THE CNS AND IN THE PERIPHERY. FURTHERMORE, WE DISCUSS THE APPLICATION OF SMALL MOLECULE INHIBITORS THAT TARGET THE EPIGENETIC MACHINERY TO AMELIORATE DISEASE IN EXPERIMENTAL ANIMAL MODELS, INDICATING THAT SUCH APPROACHES MAY BE APPLICABLE TO MS PATIENTS. 2014 5 6130 27 THE EPIGENETIC REGULATION OF THE OPIOID SYSTEM: NEW INDIVIDUALIZED PROMPT PREVENTION AND TREATMENT STRATEGIES. THE MOST WELL-KNOWN PHYSIOLOGICAL EFFECT ASSOCIATED WITH OPIOD SYSTEM IS THEIR EFFICACY IN PAIN REDUCTION OR ANALGESIA, ALTHOUGH THEIR EFFECT ON A VARIETY OF OTHER PHYSIOLOGICAL AND PHYSIOPHOLOGICAL FUNCTIONS HAS BECOME APPARENT IN RECENT YEARS. THIS REVIEW IS AN ATTEMPT TO CLARIFY IN MORE DETAIL THE EPIGENETIC REGULATION OF OPIOID SYSTEM TO UNDERSTAND WITH MORE PRECISION THEIR TRANSCRIPTIONAL AND POSTTRANSCRIPTIONAL REGULATION IN MULTIPLE PYISIOLOGICAL AND PHARMACOLOGICAL CONTEXTS. THE OPIOID RECEPTORS SHOW AN EPIGENETIC REGULATION AND OPIOID PEPTIDE PRECURSORS BY METHYLATION, CHROMATIN REMODELING AND MICRORNA. ALTHOUGH THE OPIOID RECEPTOR PROMOTERS HAVE SIMILARITY BETWEEN THEM, THEY USE DIFFERENT EPIGENETIC REGULATION FORMS AND THEY EXHIBIT DIFFERENT PATTERN OF EXPRESSION DURING THE CELL DIFFERENTIATION. DNA METHYLATION IS ALSO CONFIRMED IN OPIOID PEPTIDE PRECURSORS, BEING IMPORTANT FOR GENE EXPRESSION AND TISSUE SPECIFICITY. UNDERSTANDING THE EPIGENETIC BASIS OF THOSE PHYSIOLOGICAL AND PHYSIOPATHOLOGICAL PROCESESS IS ESSENTIAL FOR THE DEVELOPMENT OF INDIVIDUALIZED PROMPT PREVENTION AND TREATMENT STRATEGIES. 2015 6 1611 41 DNA METHYLATION: A NEW PLAYER IN MULTIPLE SCLEROSIS. MULTIPLE SCLEROSIS (MS) IS A NEUROLOGICAL AND CHRONIC INFLAMMATORY DISEASE THAT IS MEDIATED BY DEMYELINATION AND AXONAL DEGENERATION IN THE CENTRAL NERVOUS SYSTEM (CNS). STUDIES HAVE SHOWN THAT IMMUNE SYSTEM COMPONENTS SUCH AS CD4+, CD8+, CD44+ T CELLS, B LYMPHATIC CELLS, AND INFLAMMATORY CYTOKINES PLAY A CRITICAL ROLE IN INFLAMMATORY PROCESSES AND MYELIN DAMAGE ASSOCIATED WITH MS. NEVERTHELESS, THE PATHOGENESIS OF MS REMAINS POORLY DEFINED. DNA METHYLATION, A SIGNIFICANT EPIGENETIC MODIFICATION, IS REPORTED TO BE EXTENSIVELY INVOLVED IN MS PATHOGENESIS THROUGH THE REGULATION OF GENE EXPRESSION. THIS REVIEW FOCUSES ON DNA METHYLATION INVOLVED IN MS PATHOGENESIS. EVIDENCE SHOWED THE HYPERMETHYLATION OF HUMAN LEUKOCYTE ANTIGEN-DRB1 (HLA-DRB1) IN CD4+ T CELLS, THE GENOME-WIDE DNA METHYLATION IN CD8+ T CELLS, THE HYPERMETHYLATION OF INTERLEUKIN-4 (IL-4)/FORKHEAD WINGED HELIX TRANSCRIPTION FACTOR 3 (FOXP3), AND THE DEMETHYLATION OF INTERFERON-GAMMA (IFN-GAMMA)/IL-17A IN CD44+ ENCEPHALITOGENIC T CELLS. STUDIES ALSO SHOWED THE HYPERMETHYLATION OF SH2-CONTAINING PROTEIN TYROSINE PHOSPHATASE-1 (SHP-1) IN PERIPHERAL BLOOD MONONUCLEAR CELLS (PBMCS) AND METHYLATED CHANGES OF GENES REGULATING OLIGODENDROCYTE AND NEURONAL FUNCTION IN NORMAL-APPEARING WHITE MATTER. CLARIFYING THE MECHANISM OF ABERRANT METHYLATION ON MS MAY EXPLAIN PART OF THE PATHOLOGY AND WILL LEAD TO THE DEVELOPMENT OF A NEW THERAPEUTIC TARGET FOR THE TREATMENT OF MS IN THE FUTURE. 2017 7 5240 34 PROGESTERONE EFFECTS ON OLIGODENDROCYTE DIFFERENTIATION IN INJURED SPINAL CORD. SPINAL CORD LESIONS RESULT IN CHRONIC DEMYELINATION AS A CONSEQUENCE OF SECONDARY INJURY. ALTHOUGH OLIGODENDROCYTE PRECURSOR CELLS PROLIFERATE THE DIFFERENTIATION PROGRAM FAILS. SUCCESSFUL DIFFERENTIATION IMPLIES PROGRESSIVE DECREASE OF TRANSCRIPTIONAL INHIBITORS FOLLOWED BY UPREGULATION OF ACTIVATORS. PROGESTERONE EMERGES AS AN ANTI-INFLAMMATORY AND PRO-MYELINATING AGENT WHICH IMPROVES LOCOMOTOR OUTCOME AFTER SPINAL CORD INJURY. IN THIS STUDY, WE HAVE DEMONSTRATED THAT SPINAL CORD INJURY ENHANCED OLIGODENDROCYTE PRECURSOR CELL NUMBER AND DECREASED MRNA EXPRESSION OF TRANSCRIPTIONAL INHIBITORS (ID2, ID4, HES5). HOWEVER, MRNA EXPRESSION OF TRANSCRIPTIONAL ACTIVATORS (OLIG2, NKX2.2, SOX10 AND MASH1) WAS DOWN-REGULATED 3 DAYS POST INJURY. INTERESTINGLY, A DIFFERENTIATION FACTOR SUCH AS PROGESTERONE INCREASED TRANSCRIPTIONAL ACTIVATOR MRNA LEVELS AND THE DENSITY OF OLIG2- EXPRESSING OLIGODENDROCYTE PRECURSOR CELLS. THE DIFFERENTIATION PROGRAM IS REGULATED BY EXTRACELLULAR SIGNALS WHICH MODIFY TRANSCRIPTIONAL FACTORS AND EPIGENETIC PLAYERS. AS TGFBETA1 IS A KNOWN OLIGODENDROCYTE DIFFERENTIATION FACTOR WHICH IS REGULATED BY PROGESTERONE IN REPRODUCTIVE TISSUES, WE ASSESSED WHETHER TGFBETA1 COULD MEDIATE PROGESTERONE REMYELINATING ACTIONS AFTER THE LESION. NOTWITHSTANDING THAT ASTROCYTE, OLIGODENDROCYTE PRECURSOR AND MICROGLIAL CELL DENSITY INCREASED AFTER SPINAL CORD INJURY, THE NUMBER OF THESE CELLS WHICH EXPRESSED TGFBETA1 REMAINED UNCHANGED REGARDING SHAM OPERATED RATS. HOWEVER, PROGESTERONE TREATMENT INCREASED TGFBETA1 MRNA EXPRESSION AND THE NUMBER OF ASTROCYTES AND MICROGLIAL TGFBETA1 EXPRESSING CELLS WHICH WOULD INDIRECTLY ENHANCE OLIGODENDROCYTE DIFFERENTIATION. THEREFORE, TGFBETA1 ARISES AS A POTENTIAL MEDIATOR OF PROGESTERONE DIFFERENTIATING EFFECTS ON OLIGODENDROCYTE LINAGE. 2019 8 6226 16 THE LINK BETWEEN EPIGENETICS, PAIN SENSITIVITY AND CHRONIC PAIN. INCREASING EVIDENCE SUGGESTS AN ASSOCIATION BETWEEN GENE EXPRESSION AND CLINICAL PAIN. EPIGENETIC MODIFICATIONS ARE THE MAIN MODULATORS OF GENE EXPRESSION OR PROTEIN TRANSLATION IN RESPONSE TO ENVIRONMENTAL STIMULI AND PATHOPHYSIOLOGICAL CONDITIONS. PRECLINICAL AND CLINICAL STUDIES INDICATE THAT EPIGENETIC MODIFICATIONS COULD ALSO IMPACT THE DEVELOPMENT OF PAIN, THE TRANSITION FROM ACUTE TO CHRONIC PAIN, AND THE MAINTENANCE HEREOF. 2022 9 5130 30 POSTTRANSCRIPTIONAL GENE REGULATION: NOVEL PATHWAYS FOR GLUCOCORTICOIDS' ANTI-INFLAMMATORY ACTION. POSTTRANSCRIPTIONAL GENE REGULATION (PTR) IS A FUNDAMENTAL BIOLOGICAL PROCESS THAT INTEGRATES WITH THE MASTER TRANSCRIPTIONAL CONTROL OF GENE EXPRESSION, IN WAYS THAT ONLY IN THE LAST DECADE HAVE BEEN INCREASINGLY UNDERSTOOD [1, 2]. WHILE EPIGENETIC AND TRANSCRIPTIONAL EVENTS SHAPE CELL RESPONSE QUALITATIVELY, DECIDING THE PATTERN OF GENE EXPRESSION TO 'SWITCH ON OR OFF' IN RESPONSE TO ENDOGENOUS OR ENVIRONMENTAL TRIGGERS, THE KEY TASK OF PTR IS TO ACT AS A 'RHEOSTAT' AND RAPIDLY ADAPT THE CELLULAR RESPONSE BY PROVIDING THE APPROPRIATE AMPLITUDE AND TIMING TO THE PROTEIN EXPRESSION PATTERNS [3, 4]. THE PIVOTAL ROLE OF THIS MECHANISM COMES TO THE FOREFRONT IN INFLAMMATORY AND IMMUNE RESPONSE, WHERE THE CHANGES IN AMPLITUDE AND DURATION IN THE EXPRESSION OF DANGEROUS AND PROTECTIVE GENES ARE IN DELICATE BALANCE, AND ARE CRITICAL IN DETERMINING EITHER THE SUCCESSFUL RESOLUTION OF THE IMMUNE RESPONSE OR ITS CHRONIC OVEREXPRESSION [5]. THIS BRIEF REVIEW INTRODUCES MEMBERS OF THE MAIN CLASSES OF MOLECULES MEDIATING THE CYTOPLASMIC ARM OF GENE REGULATION, NAMELY RNA-BINDING PROTEINS AND MICRO-RNA (MIRNA), AND SUMMARIZES EXPERIMENTAL DATA THAT UNDERSCORE THE ROLE OF THESE MOLECULES IN THE PATHOPHYSIOLOGY OF CHRONIC INFLAMMATION, AS WELL AS THEIR PROMISING VALUE AS MECHANISMS CONVEYING THE ANTI-INFLAMMATORY EFFECT OF SYNTHETIC GLUCOCORTICOIDS. 2012 10 6895 25 [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 11 3418 27 HUMAN HEALTH CONSEQUENCES OF ENVIRONMENTALLY-MODULATED GENE EXPRESSION: POTENTIAL ROLES OF ELF-EMF INDUCED EPIGENETIC VERSUS MUTAGENIC MECHANISMS OF DISEASE. IN ORDER TO DETERMINE IF THERE MIGHT BE BIOLOGICAL AND HEALTH CONSEQUENCES AFTER EXPOSURES TO EXTREMELY-LOW FREQUENCY ELECTROMAGNETIC FIELDS (ELF-EMF), EITHER EXPERIMENTALLY OR EPIDEMIOLOGICALLY, MECHANISTIC UNDERSTANDING OF THE POTENTIAL MEANS BY WHICH ANY ENVIRONMENTAL AGENT CAN AFFECT CELLS IN A MULTICELLULAR ORGANISM HAS TO BE REVIEWED. THE GOAL OF THIS LIMITED REVIEW IS TO DEMONSTRATE THAT, WHILE THE PREVAILING PARADIGM OF THE ENVIRONMENTALLY-INDUCED ACUTE AND CHRONIC DISEASES INVOLVES EITHER CELL KILLING (CYTOTOXICITY) OR GENE/CHROMOSOME MUTATIONS (GENOTOXICITY), ALTERATION OF THE EXPRESSION OF GENETIC INFORMATION AT THE TRANSCRIPTIONAL (TURNING GENES "ON" OR "OFF"), TRANSLATIONAL (STABILIZING OR DE-STABILIZING THE GENETIC MESSAGE), OR POSTTRANSLATIONAL (ALTERING THE GENE PRODUCT OR PROTEIN) LEVELS HAS THE POTENTIAL TO CONTRIBUTE TO VARIOUS DISEASES. THIS LATTER MECHANISM, "EPIGENETIC" TOXICITY, UNLIKE THE FORMER TWO WHICH ARE IRREVERSIBLE, IS CHARACTERIZED BY THRESHOLD-LIKE ACTION, MULTIPLE BIOCHEMICAL PATHWAYS AND CHRONIC, REGULAR EXPOSURES TO BE EFFECTIVE. ULTIMATELY, EPIGENETIC TOXICANTS AFFECT ONE OF FOUR POTENTIAL CELL STATES, NAMELY ALTERATION OF CELL PROLIFERATION, CELL DIFFERENTIATION, PROGRAMMED CELL DEATH (APOPTOSIS) OR ADAPTIVE RESPONSES OF DIFFERENTIATED CELLS. 2000 12 1199 34 CORTICOTROPIN RELEASING FACTOR-BINDING PROTEIN (CRF-BP) AS A POTENTIAL NEW THERAPEUTIC TARGET IN ALZHEIMER'S DISEASE AND STRESS DISORDERS. ALZHEIMER'S DISEASE IS THE MOST COMMON CAUSE OF DEMENTIA AND ONE OF THE MOST COMPLEX HUMAN NEURODEGENERATIVE DISEASES. NUMEROUS STUDIES HAVE DEMONSTRATED A CRITICAL ROLE OF THE ENVIRONMENT IN THE PATHOGENESIS AND PATHOPHYSIOLOGY OF THE DISEASE, WHERE DAILY LIFE STRESS PLAYS AN IMPORTANT ROLE. A LOT OF EPIGENETIC STUDIES HAVE LED TO THE CONCLUSION THAT CHRONIC STRESS AND STRESS-RELATED DISORDERS PLAY AN IMPORTANT PART IN THE ONSET OF NEURODEGENERATIVE DISORDERS, AND AN ENORMOUS AMOUNT OF RESEARCH YIELDED VALUABLE DISCOVERIES BUT HAS SO FAR NOT LED TO THE DEVELOPMENT OF EFFECTIVE TREATMENT STRATEGIES FOR ALZHEIMER'S DISEASE. CORTICOTROPIN-RELEASING FACTOR (CRF) IS ONE OF THE MAJOR HORMONES AND AT THE SAME TIME A NEUROPEPTIDE ACTING IN STRESS RESPONSE. DEREGULATION OF PROTEIN LEVELS OF CRF IS INVOLVED IN THE PATHOGENESIS OF ALZHEIMER'S DISEASE, BUT LITTLE IS KNOWN ABOUT THE PRECISE ROLES OF CRF AND ITS BINDING PROTEIN, CRF-BP, IN NEURODEGENERATIVE DISEASES. IN THIS REVIEW, WE SUMMARIZE THE KEY EVIDENCE FOR AND AGAINST THE INVOLVEMENT OF STRESS-ASSOCIATED MODULATION OF THE CRF SYSTEM IN THE PATHOGENESIS OF ALZHEIMER'S DISEASE AND DISCUSS HOW RECENT FINDINGS COULD LEAD TO NEW POTENTIAL TREATMENT POSSIBILITIES IN ALZHEIMER'S DISEASE BY USING CRF-BP AS A THERAPEUTIC TARGET. 2019 13 4261 33 MGMT-METHYLATION IN NON-NEOPLASTIC DISEASES OF THE CENTRAL NERVOUS SYSTEM. QUANTIFYING O(6)-METHYLGUANINE-DNA METHYLTRANSFERASE (MGMT) PROMOTER METHYLATION PLAYS AN ESSENTIAL ROLE IN ASSESSING THE POTENTIAL EFFICACY OF ALKYLATING AGENTS IN THE CHEMOTHERAPY OF MALIGNANT GLIOMAS. MGMT PROMOTER METHYLATION IS CONSIDERED TO BE A CHARACTERISTIC OF SUBGROUPS OF CERTAIN MALIGNANCIES BUT HAS ALSO BEEN DESCRIBED IN VARIOUS PERIPHERAL INFLAMMATORY DISEASES. HOWEVER, MGMT PROMOTER METHYLATION LEVELS HAVE NOT YET BEEN INVESTIGATED IN NON-NEOPLASTIC BRAIN DISEASES. THIS STUDY DEMONSTRATES FOR THE FIRST TIME THAT ONE CAN INDEED DETECT SLIGHTLY ENHANCED MGMT PROMOTER METHYLATION IN INDIVIDUAL CASES OF INFLAMMATORY DEMYELINATING CNS DISEASES SUCH AS MULTIPLE SCLEROSIS AND PROGRESSIVE MULTIFOCAL LEUCENCEPHALOPATHY (PML), AS WELL AS IN OTHER DEMYELINATING DISEASES SUCH AS CENTRAL PONTINE AND EXPTRAPONTINE MYELINOLYSIS, AND DISEASES WITH MYELIN DAMAGE SUCH AS WALLERIAN DEGENERATION. IN THIS CONTEXT, WE IDENTIFIED A REDUCTION IN THE EXPRESSION OF THE DEMETHYLASE TET1 AS A POSSIBLE CAUSE FOR THE ENHANCED MGMT PROMOTER METHYLATION. HENCE, WE SHOW FOR THE FIRST TIME THAT MGMT HYPERMETHYLATION OCCURS IN CHRONIC DISEASES THAT ARE NOT STRICTLY ASSOCIATED TO DISTINCT PATHOGENS, ONCOGENIC VIRUSES OR NEOPLASMS BUT THAT LEAD TO DAMAGE OF THE MYELIN SHEATH IN VARIOUS WAYS. WHILE THIS GIVES NEW INSIGHTS INTO EPIGENETIC AND PATHOPHYSIOLOGICAL PROCESSES INVOLVED IN DE- AND REMYELINATION, WHICH MIGHT OFFER NEW THERAPEUTIC OPPORTUNITIES FOR DEMYELINATING DISEASES IN THE FUTURE, IT ALSO REDUCES THE SPECIFICITY OF MGMT HYPERMETHYLATION AS A TUMOR BIOMARKER. 2021 14 4096 27 MATRIX METALLOPROTEINASES, NEURAL EXTRACELLULAR MATRIX, AND CENTRAL NERVOUS SYSTEM PATHOLOGY. THE FUNCTIONALITY AND STABILITY OF THE CENTRAL NERVOUS SYSTEM (CNS) PABULUM, CALLED NEURAL EXTRACELLULAR MATRIX (NECM), IS PARAMOUNT FOR THE MAINTENANCE OF A HEALTHY NETWORK. THE LOOSENING OR THE DAMAGE OF THE SCAFFOLD DISRUPTS SYNAPTIC TRANSMISSION WITH THE CONSEQUENT IMBALANCE OF THE NEUROTRANSMITTERS, REACTIVE CELLS INVASION, ASTROCYTOSIS, NEW MATRIX DEPOSITION, DIGESTION OF THE PREVIOUS STRUCTURE AND ULTIMATELY, MALADAPTIVE PLASTICITY WITH THE LOSS OF NEURONAL VIABILITY. NECM IS CONSTANTLY AFFECTED BY CNS DISORDERS, PARTICULARLY IN CHRONIC MODIFYING SUCH AS NEURODEGENERATIVE DISEASE, OR IN ACUTE/SUBACUTE WITH CHRONIC SEQUELAE, LIKE CEREBROVASCULAR AND INFLAMMATORY PATHOLOGY. MATRIX METALLOPROTEINASES (MMPS) ARE THE MAIN INTERFERING AGENT OF NECM, GUIDING THE BALANCE OF DEGRADATION AND NEW DEPOSITION OF PROTEINS SUCH AS PROTEOGLYCANS AND GLYCOPROTEINS, OR GLYCOSAMINOGLYCANS, SUCH AS HYALURONIC ACID. ACTIVATION OF THESE ENZYMES IS MODULATED BY THEIR PHYSIOLOGIC INHIBITORS, THE TISSUE INHIBITORS OF MMPS OR VIA OTHER PROTEASES INHIBITORS, AS WELL AS GENETIC OR EPIGENETIC UP- OR DOWNREGULATION THROUGH MOLECULAR INTERACTION OR RECEPTOR ACTIVATION. THE APPROPRIATE UNDERSTANDING OF THE PATHWAYS UNDERLYING NECM MODIFICATIONS IN CNS PATHOLOGY IS PROBABLY ONE OF THE PIVOTAL FUTURE DIRECTIONS TO IDENTIFY THE HEALTHY BRAIN NETWORK AND SUBSEQUENTLY DESIGN NEW THERAPIES TO INTERFERE WITH THE PROGRESSION OF THE CNS DISEASE AND EVENTUALLY FIND APPROPRIATE THERAPIES. 2017 15 2002 23 EPIGENETIC AND POST-TRANSCRIPTIONAL REPRESSION SUPPORT METABOLIC SUPPRESSION IN CHRONICALLY HYPOXIC GOLDFISH. GOLDFISH ENTER A HYPOMETABOLIC STATE TO SURVIVE CHRONIC HYPOXIA. WE RECENTLY DESCRIBED TISSUE-SPECIFIC CONTRIBUTIONS OF MEMBRANE LIPID COMPOSITION REMODELING AND MITOCHONDRIAL FUNCTION TO METABOLIC SUPPRESSION ACROSS DIFFERENT GOLDFISH TISSUES. HOWEVER, THE MOLECULAR AND ESPECIALLY EPIGENETIC FOUNDATIONS OF HYPOXIA TOLERANCE IN GOLDFISH UNDER METABOLIC SUPPRESSION ARE NOT WELL UNDERSTOOD. HERE WE SHOW THAT COMPONENTS OF THE MOLECULAR OXYGEN-SENSING MACHINERY ARE ROBUSTLY ACTIVATED ACROSS TISSUES IRRESPECTIVE OF HYPOXIA DURATION. INDUCTION OF GENE EXPRESSION OF ENZYMES INVOLVED IN DNA METHYLATION TURNOVER AND MICRORNA BIOGENESIS SUGGEST A ROLE FOR EPIGENETIC TRANSCRIPTIONAL AND POST-TRANSCRIPTIONAL SUPPRESSION OF GENE EXPRESSION IN THE HYPOXIA-ACCLIMATED BRAIN. CONVERSELY, MECHANISTIC TARGET OF RAPAMYCIN-DEPENDENT TRANSLATIONAL MACHINERY ACTIVITY IS NOT REDUCED IN LIVER AND WHITE MUSCLE, SUGGESTING THIS PATHWAY DOES NOT CONTRIBUTE TO LOWERING CELLULAR ENERGY EXPENDITURE. FINALLY, MOLECULAR EVIDENCE SUPPORTS PREVIOUSLY REPORTED CHRONIC HYPOXIA-DEPENDENT CHANGES IN MEMBRANE CHOLESTEROL, LIPID METABOLISM AND MITOCHONDRIAL FUNCTION VIA CHANGES IN TRANSCRIPTS INVOLVED IN CHOLESTEROL BIOSYNTHESIS, BETA-OXIDATION, AND MITOCHONDRIAL FUSION IN MULTIPLE TISSUES. OVERALL, THIS STUDY SHOWS THAT CHRONIC HYPOXIA ROBUSTLY INDUCES EXPRESSION OF OXYGEN-SENSING MACHINERY ACROSS TISSUES, INDUCES REPRESSIVE TRANSCRIPTIONAL AND POST-TRANSCRIPTIONAL EPIGENETIC MARKS ESPECIALLY IN THE CHRONIC HYPOXIA-ACCLIMATED BRAIN AND SUPPORTS A ROLE FOR MEMBRANE REMODELING AND MITOCHONDRIAL FUNCTION AND DYNAMICS IN PROMOTING METABOLIC SUPPRESSION. 2022 16 2882 37 G-PROTEIN-COUPLED RECEPTOR GPR17 REGULATES OLIGODENDROCYTE DIFFERENTIATION IN RESPONSE TO LYSOLECITHIN-INDUCED DEMYELINATION. OLIGODENDROCYTES ARE THE MYELIN-PRODUCING CELLS OF THE CENTRAL NERVOUS SYSTEM (CNS). A VARIETY OF BRAIN DISORDERS FROM "CLASSICAL" DEMYELINATING DISEASES, SUCH AS MULTIPLE SCLEROSIS, STROKE, SCHIZOPHRENIA, DEPRESSION, DOWN SYNDROME AND AUTISM, ARE SHOWN MYELINATION DEFECTS. OLIGODENDROCYTE MYELINATION IS REGULATED BY A COMPLEX INTERPLAY OF INTRINSIC, EPIGENETIC AND EXTRINSIC FACTORS. GPR17 (G PROTEIN-COUPLED RECEPTOR 17) IS A G PROTEIN-COUPLED RECEPTOR, AND HAS BEEN IDENTIFIED TO BE A REGULATOR FOR OLIGODENDROCYTE DEVELOPMENT. HERE, WE DEMONSTRATE THAT THE ABSENCE OF GPR17 ENHANCES REMYELINATION IN VIVO WITH A TOXIN-INDUCED MODEL WHEREBY FOCAL DEMYELINATED LESIONS ARE GENERATED IN SPINAL CORD WHITE MATTER OF ADULT MICE BY LOCALIZED INJECTION OF LPC(L-A-LYSOPHOSPHATIDYLCHOLINE). THE INCREASED EXPRESSION OF THE ACTIVATED FORM OF ERK1/2 (PHOSPHO-ERK1/2) IN LESION AREAS SUGGESTED THE POTENTIAL ROLE OF ERK1/2 ACTIVITY ON THE GPR17-DEPENDENT MODULATION OF MYELINATION. THE ABSENCE OF GPR17 ENHANCES REMYELINATION IS CORRELATE WITH THE ACTIVATED ERK1/2 (PHOSPHO-ERK1/2).BEING A MEMBRANE RECEPTOR, GPR17 REPRESENTS AN IDEAL DRUGGABLE TARGET TO BE EXPLOITED FOR INNOVATIVE REGENERATIVE APPROACHES TO ACUTE AND CHRONIC CNS DISEASES. 2018 17 4439 24 MOLECULAR GENETIC AND EPIGENETIC BASIS OF MULTIPLE SCLEROSIS. MULTIPLE SCLEROSIS (MS) IS A CHRONIC IMMUNE-MEDIATED DISEASE OF SPINAL CORD AND BRAIN. THE INITIAL EVENT IN MS OCCURS WHEN ACTIVATED CD4(+) T CELLS IN PERIPHERY EXACERBATES IMMUNE RESPONSES BY STIMULATING IMMUNE CELLS SUCH AS B CELLS, CD8(+) CELLS, MAST CELLS, GRANULOCYTES AND MONOCYTES. THESE PROINFLAMMATORY CELLS PASS BLOOD BRAIN BARRIER BY SECRETING PROINFLAMMATORY CYTOKINES INCLUDING TNF-ALPHA AND INF-(GAMMA) WHICH ACTIVATE ADHESION FACTORS. APCS (ANTIGEN-PRESENTING CELLS) REACTIVATE CD4(+) T CELLS AFTER INFILTRATING THE CNS AND CD4(+) T CELLS PRODUCE CYTOKINES AND CHEMOKINES. THESE PROINFLAMMATORY CYTOKINES AGGRAVATE INFLAMMATION BY INDUCING MYELIN PHAGOCYTOSIS THROUGH MICROGLIA AND ASTROCYTES ACTIVATION. MS IS BELIEVED TO HAVE A MULTIFACTORIAL ORIGIN THAT INCLUDES A COMBINATION OF MULTIPLE GENETIC, ENVIRONMENTAL AND STOCHASTIC FACTORS. ALTHOUGH THE EXACT COMPONENT OF MS RISKS THAT CAN BE EXPLAINED BY THESE FACTORS IS DIFFICULT TO DETERMINE, ESTIMATES BASED ON GENETIC AND EPIDEMIOLOGICAL STUDIES SUGGEST THAT UP TO 60-70 % OF THE TOTAL RISK OF MS MAY BE CONTRIBUTE TO GENETIC FACTORS. IN CONTINUE, FIRSTLY WE PROVIDE AN OVERVIEW OF THE CURRENT UNDERSTANDING OF EPIGENETIC MECHANISMS, AND SO PRESENT EVIDENCE OF HOW THE EPIGENETIC MODIFICATIONS CONTRIBUTE TO INCREASED SUSCEPTIBILITY OF MS. WE ALSO EXPLAIN HOW SPECIFIED EPIGENETIC MODIFICATIONS MAY INFLUENCE THE PATHOPHYSIOLOGY AND KEY ASPECTS OF DISEASE IN MS (DEMYELINATION, REMYELINATION, INFLAMMATION, AND NEURODEGENERATION). FINALLY, WE TEND TO DISCUSS HOW ENVIRONMENTAL FACTORS AND EPIGENETIC MECHANISMS MAY INTERACT TO HAVE AN EFFECT ON MS RISK AND CLINICAL OUTCOME AND RECOMMEND NEW THERAPEUTIC INTERVENTIONS THAT MIGHT MODULATE PATIENTS' EPIGENETIC PROFILES. 2017 18 4 33 "MIX OF MICS"- PHENOTYPIC AND BIOLOGICAL HETEROGENEITY OF "MULTIPOTENT" MUSCLE INTERSTITIAL CELLS (MICS). THE CAPACITY OF ADULT SKELETAL MUSCLE FOR REGENERATION APPEARS TO BE LIMITED, WITH PROGRESSIVE IMPAIRMENT IN REPAIR EFFICIENCY OF INJURED MUSCLES OBSERVED IN CHRONIC MUSCULAR DISORDERS AND DURING AGING. WHILE SATELLITE CELLS, THE COMMITTED ADULT MUSCLE STEM CELLS, ARE THE MAIN DIRECT CELL SOURCE SUPPORTING THE REGENERATIVE POTENTIAL OF ADULT SKELETAL MUSCLES, THE CHARACTERIZATION OF THE CELL TYPES AND SIGNALS THAT CONSTITUTE THE FUNCTIONAL "NICHE" OF SATELLITE CELLS IS CURRENTLY THE OBJECT OF INTENSE INVESTIGATION. RECENT STUDIES HAVE IDENTIFIED A FUNCTIONAL RELATIONSHIP BETWEEN SATELLITE CELLS AND VARIOUS CELL TYPES LOCATED IN KEY ANATOMICAL POSITION, SUCH AS THE INTERSTITIUM OF SKELETAL MUSCLES. THIS HETEROGENEOUS POPULATION OF MUSCLE INTERSTITIAL CELLS (MICS) APPEARS TO RETAIN AN INTRINSIC MULTIPOTENCY WITHIN THE MESODERMAL LINEAGE, AND THEIR DIRECT OR INDIRECT CONTRIBUTION TO MYOFIBER TURNOVER, REPAIR AND DEGENERATION HAS BEEN SUGGESTED BY MANY STUDIES THAT WILL BE REVIEWED HERE. GIVEN THE EXISTING GAP OF KNOWLEDGE ON LINEAGE IDENTITY AND FUNCTIONAL PROPERTIES OF MICS, THEIR DETAILED CHARACTERIZATION AT THE SINGLE CELL LEVEL HOLDS THE PROMISE TO PROVIDE KEY INSIGHT INTO THE COMPOSITION OF THIS HETEROGENEOUS POPULATION AND THE DYNAMIC TRANSITION THROUGH DISTINCT SUB-POPULATIONS IN HEALTHY, DISEASED AND AGING MUSCLES. THIS REVIEW PROVIDES AN OVERVIEW OF THE RESULTS OF VARIOUS STUDIES DESCRIBING THE PHENOTYPE AND THE FUNCTION OF CELLS ISOLATED FROM SKELETAL MUSCLE INTERSTITIUM, AND DISCUSSES THE IMPORTANCE OF SINGLE CELL TRANSCRIPTION PROFILING IN ORDER TO DECIPHER THE FUNCTIONAL AND PHENOTYPICAL HETEROGENEITY OF MUSCLE INTERSTITIAL CELLS (MICS). 2012 19 389 28 AN INTEGRATIVE HYPOTHESIS LINKING CANCER, DIABETES AND ATHEROSCLEROSIS: THE ROLE OF MUTATIONS AND EPIGENETIC CHANGES. IT APPEARS THAT THE DISEASE STATES OF CANCER, ALTHEROSCLEROSIS AND DIABETES MIGHT SHARE A COMMON ETIOLOGY. THESE CHRONIC DISEASES APPEAR TO BE MULTI-STAGED IN THEIR PROGRESSION, WITH GENETIC, NUTRITIONAL, PSYCHO-SOCIAL, ENVIRONMENTAL AND VIRAL FACTORS INFLUENCING THEIR APPEARANCE. WE OFFERED A HYPOTHESIS (A "MUTATION THEORY OF DISEASE"), STATING THAT THESE DISEASES CAN BE DESCRIBED BY INITIATION AND PROMOTION PHASES; INITIATION BEING THE RESULT OF THE PRODUCTION OF MUTATED CELLS AFTER UNREPAIRED DAMAGED DNA IS REPLICATED; PROMOTION BEING THE SELECTIVE PROLIFERATION OF THE INITIATED CELLS TO FORM CLONES OF MUTATED CELLS. IT WAS FURTHER POSTULATED THAT PROMOTION AFFECTS CELL PROLIFERATION BY ALTERING A MEMBRANE-CA++ REGULATORY SYSTEM. DEPENDING ON THE NATURE OF THE MUTATION IN THE CLONE OF CELLS, SPECIFIC DISEASE STATES WOULD RESULT. THE ROLES OF RADIATIONS, CHEMICALS, VIRUSES, GENES, NUTRITION AND PSYCHO-SOCIAL STRESS WERE RELATED TO EITHER THE INITIATION (MUTATION PRODUCTION) OR THE PROMOTION (CELL PROLIFERATION) PHASE OF THESE DISEASES. 1980 20 2868 32 FUNCTIONAL CONSEQUENCES OF CALCIUM-DEPENDENT SYNAPSE-TO-NUCLEUS COMMUNICATION: FOCUS ON TRANSCRIPTION-DEPENDENT METABOLIC PLASTICITY. IN THE NERVOUS SYSTEM, CALCIUM SIGNALS PLAY A MAJOR ROLE IN THE CONVERSION OF SYNAPTIC STIMULI INTO TRANSCRIPTIONAL RESPONSES. SIGNAL-REGULATED GENE TRANSCRIPTION IS FUNDAMENTAL FOR A RANGE OF LONG-LASTING ADAPTIVE BRAIN FUNCTIONS THAT INCLUDE LEARNING AND MEMORY, STRUCTURAL PLASTICITY OF NEURITES AND SYNAPSES, ACQUIRED NEUROPROTECTION, CHRONIC PAIN, AND ADDICTION. IN THIS REVIEW, WE SUMMARIZE THE DIVERSE MECHANISMS GOVERNING CALCIUM-DEPENDENT TRANSCRIPTIONAL REGULATION ASSOCIATED WITH CENTRAL NERVOUS SYSTEM PLASTICITY. WE FOCUS ON RECENT ADVANCES IN THE FIELD OF SYNAPSE-TO-NUCLEUS COMMUNICATION THAT INCLUDE STUDIES OF THE SIGNAL-REGULATED TRANSCRIPTOME IN HUMAN NEURONS, IDENTIFICATION OF NOVEL REGULATORY MECHANISMS SUCH AS ACTIVITY-INDUCED DNA DOUBLE-STRAND BREAKS, AND THE IDENTIFICATION OF NOVEL FORMS OF ACTIVITY- AND TRANSCRIPTION-DEPENDENT ADAPTATIONS, IN PARTICULAR, METABOLIC PLASTICITY. WE SUMMARIZE THE RECIPROCAL INTERACTIONS BETWEEN DIFFERENT KINDS OF NEUROADAPTATIONS AND HIGHLIGHT THE EMERGING ROLE OF ACTIVITY-REGULATED EPIGENETIC MODIFIERS IN GATING THE INDUCIBILITY OF SIGNAL-REGULATED GENES. 2020