1 6534 232 TRANSCRIPTIONAL REGULATION OF NMDA RECEPTOR EXPRESSION. THE N-METHYL-D-ASPARTATE (NMDA) SUBTYPES OF GLUTAMATE RECEPTORS ARE INTIMATELY INVOLVED IN A NUMBER OF IMPORTANT NEURONAL ACTIVITIES IN MAMMALIAN NERVOUS SYSTEMS INCLUDING NEURONAL MIGRATION, SYNAPTOGENESIS, NEURONAL PLASTICITY, NEURONAL SURVIVAL, AND EXCITOTOXICITY. THROUGH THESE ACTIVITIES, NMDA RECEPTORS (NRS) PLAY AN IMPORTANT ROLE IN THE DEVELOPMENT OF DRUG ADDICTION, PAIN PERCEPTION, AND THE PATHOGENESIS OF NEUROLOGICAL DISORDERS SUCH AS SCHIZOPHRENIA AND HUNTINGTON'S DISEASE [1-10]. IT IS GENERALLY BELIEVED THAT ABERRANT OR PATHOLOGICAL NR EFFECTS OCCUR MAINLY VIA ABNORMAL RECEPTOR ACTIVITY, RESULTING FROM ALTERED AVAILABILITY OF AGONISTS OR MODIFIED QUALITY OR QUANTITY OF MEMBRANE-ASSOCIATED RECEPTORS. IN MAMMALS, FUNCTIONAL NRS ARE HETEROTETRAMERS OF SUBUNITS ENCODED BY THREE GENE FAMILIES, I.E., NMDAR1 (NR1 OR GRIN1), NMDAR2 (NR2 OR GRIN2), AND NMDAR3 (NR3 OR GRIN3) [3,4,11]. THE NR1 FAMILY HAS ONE GENE; THE NR2 FAMILY HAS FOUR (DESIGNATED A THROUGH D); AND THE NR3 FAMILY HAS TWO (A AND B). STRUCTURALLY, NR1 IS AN ESSENTIAL COMPONENT FOUND IN ALL TETRAMERS, WHILE DIFFERENT NR2 MEMBERS ARE INCORPORATED BASED ON AGE AND NERVOUS SYSTEM REGION. NR3 PROTEINS FUNCTION AS NEGATIVE COMPONENTS WHEN INCLUDED IN THE STRUCTURES [3,4,11,12]. EIGHT VARIANTS OF NR1 PROTEIN ARE PRODUCED BY ALTERNATIVE SPLICING AND DISTRIBUTED DIFFERENTIALLY IN NERVOUS SYSTEMS [13-15]. THIS COMPLEX COMPOSITION OF DIFFERENT SUBUNITS AND SPLICING VARIANTS FORMS THE PRIMARY BASIS OF THE FUNCTIONAL DIVERSITY OF NRS. FROM JANUARY 1992 TO JUNE 2007, MORE THAN 1000 RESEARCH ARTICLES RELEVANT TO NR EXPRESSION WERE PUBLISHED. IN SUM, THEY CONCLUDED THAT THE EXPRESSION OF NR GENES IS CELL- OR TISSUE-SPECIFIC, RELATIVELY STABLE, AND REGULATED DIFFERENTIALLY BY VARIOUS PHYSIOLOGICAL, PHARMACOLOGICAL, AND PATHOLOGICAL FACTORS. MOST OF THESE CONCLUSIONS WERE BASED ON ASSESSMENTS OF CHANGES OF THE STEADY STATE LEVELS OF MRNA AND PROTEIN THAT MAY BE DRIVEN BY NUMEROUS SOPHISTICATED MECHANISMS. TRANSCRIPTION IS THE INITIAL STEP AND GENERALLY THE MOST SENSITIVE TO CELLULAR NEEDS AND ENVIRONMENTAL CUES. THUS, IT SERVES AS A MAJOR MECHANISM CONTROLLING GENE EXPRESSION [16]. PRECISE SPATIAL AND TEMPORAL EXPRESSION OF A SELECTIVE SET OF GENES DETERMINES PHENOTYPIC DIFFERENCES AMONG DISTINCT TISSUES AND CELLS IN HIGHER EUKARYOTES [16-18]. IN THE CASE OF THE NR GENE FAMILIES, TRANSCRIPTION OF EACH SUBUNIT GENE IN A GIVEN NEURON OR CELL MUST BE COORDINATELY CONTROLLED BUT DIFFERENTIALLY RESPONSIVE TO CELL TYPE, DEVELOPMENTAL STAGE, AND ENVIRONMENTAL SIGNALS TO MAINTAIN HEALTHY CELLULAR FUNCTION. HOW THIS COORDINATED CONTROL TAKES PLACE IS AN IMPORTANT AND CHALLENGING QUESTION. THIS CHAPTER REVIEWS STUDIES THAT EXPLORE THE TRANSCRIPTIONAL CONTROL OF NR GENES. IT DISCUSSES STUDIES OF PROMOTER AND REGULATORY SEQUENCES, REGULATORY UNITS, DEVELOPMENTAL REGULATION, CELL TYPE SPECIFICITY, GROWTH FACTOR REGULATION, NEUROLOGICAL DISORDERS, AND EPIGENETIC MECHANISMS. 2009 2 6895 35 [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 3 6226 20 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 4 6130 35 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 5 405 41 ANALYSIS OF EPIGENETIC MECHANISMS REGULATING OPIOID RECEPTOR GENE TRANSCRIPTION. OPIOID DRUGS ARE GENERALLY USED FOR MODERATE AND SEVERE PAIN REDUCTIONS WHICH ACT THROUGH OPIOID RECEPTORS. STUDIES ON TRANSCRIPTIONAL REGULATION OF OPIOID RECEPTORS ARE STILL INVALUABLE BECAUSE NOT ONLY TRANSCRIPTION IS THE FIRST STEP TO PRODUCE PROTEIN PRODUCTS IN CELLS, BUT THE RECEPTOR TRANSCRIPTION LEVELS ALSO AFFECT THE PAIN REDUCTION BY OPIOIDS, AS OBSERVED IN STUDIES OF HETEROZYGOUS OPIOID RECEPTOR KNOCKOUT MICE.THERE ARE GROWING EVIDENCES THAT EPIGENETIC REGULATION HAS PLAYED SIGNIFICANT ROLES IN TRANSCRIPTIONAL REGULATION OF GENES, INCLUDING OPIOID RECEPTORS. IN GENERAL, EPIGENETIC MECHANISMS INCLUDE THREE MAIN REGULATORY FACTORS: DNA METHYLATION, CHROMATIN MODIFICATION, AND NONCODING RNAS (SUCH AS MICRORNA). FROM PREVIOUS STUDIES OF OURS AND OTHERS ON OPIOID RECEPTORS, THOSE EPIGENETIC FACTORS WERE CLEARLY INVOLVED IN REGULATING OPIOID RECEPTOR EXPRESSION IN VIVO AND IN VITRO. IN THIS CHAPTER, AMONG THOSE THREE TECHNIQUES WE DESCRIBE MORE DETAILS OF DNA METHYLATION METHODS BECAUSE OF EMERGING CONCEPTS OF DNA METHYLATION WITH THE RECENT DISCOVERY OF 5-HYDROXYMETHYLCYTOSINE CONVERTING ENZYME, TET1. ANOTHER ANALYTICAL METHOD OF THE EPIGENETIC FACTORS, CHROMATIN MODIFICATION, WILL BE DESCRIBED BRIEFLY AND INFORMATION OF ANALYZING NONCODING RNAS IS BRIEFLY MENTIONED IN SUBHEADING 1. 2015 6 3418 36 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 7 6137 39 THE EPIGENETICS OF PSYCHOSIS: A STRUCTURED REVIEW WITH REPRESENTATIVE LOCI. THE EVIDENCE FOR AN ENVIRONMENTAL COMPONENT IN CHRONIC PSYCHOTIC DISORDERS IS STRONG AND RESEARCH ON THE EPIGENETIC MANIFESTATIONS OF THESE ENVIRONMENTAL IMPACTS HAS COMMENCED IN EARNEST. IN REVIEWING THIS RESEARCH, THE FOCUS IS ON THREE GENES AS MODELS FOR DIFFERENTIAL METHYLATION, MCHR1, AKT1 AND TDO2, EACH OF WHICH HAVE BEEN INVESTIGATED FOR GENETIC ASSOCIATION WITH PSYCHOTIC DISORDERS. ENVIRONMENTAL FACTORS ASSOCIATED WITH PSYCHOTIC DISORDERS, AND WHICH INTERACT WITH THESE MODEL GENES, ARE EXPLORED IN DEPTH. THE LOCATION OF TRANSCRIPTION FACTOR MOTIFS RELATIVE TO KEY METHYLATION SITES IS EVALUATED FOR PREDICTED GENE EXPRESSION RESULTS, AND FOR OTHER SITES, EVIDENCE IS PRESENTED FOR METHYLATION DIRECTING ALTERNATIVE SPLICING. EXPERIMENTAL RESULTS FROM KEY STUDIES SHOW DIFFERENTIAL METHYLATION: FOR MCHR1, IN PSYCHOSIS CASES VERSUS CONTROLS; FOR AKT1, AS A PRE-EXISTING METHYLATION PATTERN INFLUENCING BRAIN ACTIVATION FOLLOWING ACUTE ADMINISTRATION OF A PSYCHOSIS-ELICITING ENVIRONMENTAL STIMULUS; AND FOR TDO2, IN A PATTERN ASSOCIATED WITH A DEVELOPMENTAL FACTOR OF RISK FOR PSYCHOSIS, IN ALL CASES THE PREDICTED EXPRESSION IMPACT BEING HIGHLY DEPENDENT ON LOCATION. METHYLATION INDUCED BY SMOKING, A CONFOUNDING VARIABLE, EXHIBITS AN INTRIGUING PATTERN FOR ALL THREE GENES. FINALLY, HOW DIFFERENTIAL METHYLATION MESHES WITH DARWINIAN PRINCIPLES IS EXAMINED, IN PARTICULAR AS IT RELATES TO THE "FLEXIBLE STEM" THEORY OF EVOLUTION. 2022 8 6846 43 [MIGRAINE: IGNITION OF THE BRAIN]. ALTHOUGH OUR KNOWLEDGE OF WHICH SYSTEMS ARE ACTIVATED DURING MIGRAINE IS REASONABLY COMPLETE, WHY THE SYSTEM IS ACTIVATED REMAINS UNKNOWN. INCORPORATING THE FINDINGS OBTAINED IN STUDIES ON PAIN IN GENERAL HAS ALLOWED A MORE INTEGRATED MODEL TO BE GENERATED. ACCORDING TO THIS NEW MODEL, THERE IS AN ANATOMICAL SUBSTRATE CONSISTING IN A COMPLEX FRAMEWORK OF PAIN THAT IS MADE UP NOT ONLY OF THE TRIGEMINOVASCULAR SYSTEM (END PATHWAY) BUT OF A NUMBER OF NETWORKS THAT ARE IN TURN CONNECTED TO ONE ANOTHER, LIKE THE NEUROLIMBIC, THE ASCENDING AND DESCENDING MODULATORY SYSTEM. THIS COMPLEX NETWORK IS RESPONSIBLE FOR MODULATING AND CONVEYING NOCICEPTIVE SIGNALS. IN PATIENTS WITH MIGRAINE, HYPEREXCITABILITY OF THIS FRAMEWORK IS CONDITIONED BY GENETIC AND EPIGENETIC ALTERATIONS. EPIGENETIC CHANGES ARE CHEMICAL MODIFICATIONS AFFECTING CHROMATIN, WHICH MODULATES THE ACTIVITY OF GENES WITHOUT MODIFYING THE DNA SEQUENCE, AND WHICH ARE CAPABLE OF MODULATING THE EXPRESSION OF GENES INVOLVED IN A NUMBER OF DIFFERENT ASPECTS, SUCH AS PLASTICITY, SYSTEM EXCITABILITY, MEMORY OF PAIN OR MOODS. IN TURN, THE PRESENCE OF EXTERNAL FACTORS (SUCH AS ENVIRONMENTAL CHANGES OR ALCOHOL) AND INTERNAL FACTORS (SUCH AS HORMONES OR SLEEP DISORDERS) CONTRIBUTE TO ACTIVATE THIS LOADED ANATOMICAL SUBSTRATE, RESULTING IN THE ATTACK OF MIGRAINE. 2013 9 2913 34 GENE REGULATORY MECHANISMS UNDERLYING SEX DIFFERENCES IN BRAIN DEVELOPMENT AND PSYCHIATRIC DISEASE. THE SEXUAL DIFFERENTIATION OF THE MAMMALIAN NERVOUS SYSTEM REQUIRES THE PRECISE COORDINATION OF THE TEMPORAL AND SPATIAL REGULATION OF GENE EXPRESSION IN DIVERSE CELL TYPES. SEX HORMONES ACT AT MULTIPLE DEVELOPMENTAL TIME POINTS TO SPECIFY SEX-TYPICAL DIFFERENTIATION DURING EMBRYONIC AND EARLY DEVELOPMENT AND TO COORDINATE SUBSEQUENT RESPONSES TO GONADAL HORMONES LATER IN LIFE BY ESTABLISHING SEX-TYPICAL PATTERNS OF EPIGENETIC MODIFICATIONS ACROSS THE GENOME. THUS, MUTATIONS ASSOCIATED WITH NEUROPSYCHIATRIC CONDITIONS MAY RESULT IN SEXUALLY DIMORPHIC SYMPTOMS BY ACTING ON DIFFERENT NEURAL SUBSTRATES OR CHROMATIN LANDSCAPES IN MALES AND FEMALES. FINALLY, AS STRESS HORMONE SIGNALING MAY DIRECTLY ALTER THE MOLECULAR MACHINERY THAT INTERACTS WITH SEX HORMONE RECEPTORS TO REGULATE GENE EXPRESSION, THE CONTRIBUTION OF CHRONIC STRESS TO THE PATHOGENESIS OR PRESENTATION OF MENTAL ILLNESS MAY BE ADDITIONALLY DIFFERENT BETWEEN THE SEXES. HERE, WE REVIEW THE MECHANISMS THAT CONTRIBUTE TO SEXUAL DIFFERENTIATION IN THE MAMMALIAN NERVOUS SYSTEM AND CONSIDER SOME OF THE IMPLICATIONS OF THESE PROCESSES FOR SEX DIFFERENCES IN NEUROPSYCHIATRIC CONDITIONS. 2018 10 1199 39 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 11 980 21 CHRONIC PAIN: EMERGING EVIDENCE FOR THE INVOLVEMENT OF EPIGENETICS. EPIGENETIC PROCESSES, SUCH AS HISTONE MODIFICATIONS AND DNA METHYLATION, HAVE BEEN ASSOCIATED WITH MANY NEURAL FUNCTIONS INCLUDING SYNAPTIC PLASTICITY, LEARNING, AND MEMORY. HERE, WE CRITICALLY EXAMINE EMERGING EVIDENCE LINKING EPIGENETIC MECHANISMS TO THE DEVELOPMENT OR MAINTENANCE OF CHRONIC PAIN STATES. ALTHOUGH IN ITS INFANCY, RESEARCH IN THIS AREA POTENTIALLY UNIFIES SEVERAL PATHOPHYSIOLOGICAL PROCESSES UNDERPINNING ABNORMAL PAIN PROCESSING AND OPENS UP A DIFFERENT AVENUE FOR THE DEVELOPMENT OF NOVEL ANALGESICS. 2012 12 5130 34 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 13 2176 28 EPIGENETIC MECHANISMS OF CHRONIC PAIN. NEUROPATHIC AND INFLAMMATORY PAIN PROMOTE A LARGE NUMBER OF PERSISTING ADAPTATIONS AT THE CELLULAR AND MOLECULAR LEVEL, ALLOWING EVEN TRANSIENT TISSUE OR NERVE DAMAGE TO ELICIT CHANGES IN CELLS THAT CONTRIBUTE TO THE DEVELOPMENT OF CHRONIC PAIN AND ASSOCIATED SYMPTOMS. THERE IS EVIDENCE THAT INJURY-INDUCED CHANGES IN CHROMATIN STRUCTURE DRIVE STABLE CHANGES IN GENE EXPRESSION AND NEURAL FUNCTION, WHICH MAY CAUSE SEVERAL SYMPTOMS, INCLUDING ALLODYNIA, HYPERALGESIA, ANXIETY, AND DEPRESSION. RECENT FINDINGS ON EPIGENETIC CHANGES IN THE SPINAL CORD AND BRAIN DURING CHRONIC PAIN MAY GUIDE FUNDAMENTAL ADVANCES IN NEW TREATMENTS. HERE, WE PROVIDE A BRIEF OVERVIEW OF EPIGENETIC REGULATION IN THE NERVOUS SYSTEM AND THEN DISCUSS THE STILL-LIMITED LITERATURE THAT DIRECTLY IMPLICATES EPIGENETIC MODIFICATIONS IN CHRONIC PAIN SYNDROMES. 2015 14 5288 25 PROSPECTS FOR EPIGENETIC COMPOUNDS IN THE TREATMENT OF AUTOIMMUNE DISEASE. THERE IS GROWING EVIDENCE FOR A ROLE FOR EPIGENETIC MECHANISMS IN THE DEVELOPMENT OF AUTOIMMUNE DISEASES. IN MOST CASES OFAUTOIMMUNE DISEASE THE PRECISE EPIGENETIC MECHANISM INVOLVED REMAINS TO BE RESOLVED, HOWEVER DNA HYPOMETHYLATION ACCOMPANIED BY HYPOACETYLATION OFHISTONE H3/H4 IS COMMONLY OBSERVED. DUE TO THE REVERSIBLE NATURE OF EPIGENETIC MARKS THEIR MAINTENANCE ENZYMES SUCH AS DNA METHYLTRANSFERASES (DNMTS), HISTONE DEACETYLASES (HDACS) AND HISTONE LYSINE METHYLTRANSFERASES (HKMT) ARE ATTRACTIVE DRUG TARGETS. SMALL MOLECULE INHIBITORS OF HISTONE MODIFICATION AND DNA METHYLATION MAINTENANCE ARE INCREASINGLY BECOMING AVAILABLE AND WILL BE USEFUL CHEMICAL BIOLOGICAL TOOLS TO DISSECT EPIGENETIC MECHANISMS IN THESE DISEASES. HOWEVER, ALTHOUGH EPIGENETIC THERAPIES USED IN CANCER TREATMENT ARE A PROMISING STARTING POINT FOR THE EXPLORATION OF AUTOIMMUNE DISEASE TREATMENT, THERE IS A REQUIREMENT FOR MORE SPECIFIC AND LESS TOXIC AGENTS FOR THESE CHRONIC DISEASES OR FOR USE AS CHEMOPREVENTATIVE AGENTS. 2011 15 6720 40 VITAMIN D METABOLISM GENES ARE DIFFERENTIALLY METHYLATED IN INDIVIDUALS WITH CHRONIC KNEE PAIN. CONTEXT: RECENT EVIDENCE SUGGESTS THAT VITAMIN D MAY INTERACT WITH THE EPIGENOME AND PLAY A ROLE IN THE PAIN EXPERIENCE. IN ORDER FOR PROPER FUNCTIONING TO OCCUR, THERE MUST BE AN ADEQUATE LEVEL OF VITAMIN D PRESENT, MADE POSSIBLE BY ENZYMATIC REACTIONS THAT ALLOW VITAMIN D TO BE BIOLOGICALLY ACTIVE. THE PURPOSE OF THIS STUDY WAS TO EXPLORE THE EPIGENETIC LANDSCAPE OF GENES INVOLVED IN VITAMIN D METABOLISM IN INDIVIDUALS WITH AND WITHOUT CHRONIC KNEE PAIN. PROCEDURES: COMMUNITY-DWELLING INDIVIDUALS RECRUITED AS PART OF A LARGER STUDY FOCUSED ON KNEE PAIN PROVIDED DEMOGRAPHIC, CLINICAL AND PAIN-RELATED INFORMATION, AS WELL AS AN INTRAVENOUS BLOOD SAMPLE TO DETERMINE DNA METHYLATION LEVELS AT CPG SITES. MAIN FINDINGS: THERE WERE DIFFERENCES IN DNA METHYLATION BETWEEN THOSE WITH AND WITHOUT PAIN IN GENES THAT CODE FOR ENZYMES RELATED TO VITAMIN D METABOLISM: CYP24A1 (24-HYDROXYLASE) AND CYP27B1 (1-?-HYDROXYLASE). THERE WAS ALSO HYPERMETHYLATION ON THE GENE THAT CODES FOR THE VITAMIN D RECEPTOR (VDR). PRINCIPAL CONCLUSIONS: THE PRESENCE OF CHRONIC PAIN IS ASSOCIATED WITH EPIGENETIC MODIFICATIONS IN GENES RESPONSIBLE FOR THE EXPRESSION OF ENZYMES INVOLVED IN VITAMIN D METABOLISM AND CELLULAR FUNCTION. THESE RESULTS LAY GROUNDWORK IN UNDERSTANDING THE MECHANISM UNDERLYING THE ASSOCIATION BETWEEN VITAMIN D AND CHRONIC PAIN. 2023 16 6136 47 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 17 4424 52 MOLECULAR AND NEUROLOGIC RESPONSES TO CHRONIC ALCOHOL USE. THIS CHAPTER PROVIDES AN OVERVIEW OF CURRENT KNOWLEDGE ON THE MOLECULAR AND CLINICAL ASPECTS OF CHRONIC ALCOHOL EFFECTS ON THE CENTRAL NERVOUS SYSTEM. THIS DRUG IS ALMOST UBIQUITOUS, WIDELY ENJOYED SOCIALLY, BUT PRODUCES A DIVERSE SPECTRUM OF NEUROLOGIC DISEASE WHEN ABUSED. ACUTELY, ALCOHOL INTERACTS PREDOMINANTLY WITH GAMMA-AMINOBUTYRIC ACID-A (GABA-A) AND N-METHYL-D-ASPARTATE (NMDA) RECEPTORS, BUT TRIGGERS DIVERSE SIGNALING EVENTS WITHIN WELL-DEFINED NEURAL PATHWAYS. THESE EVENTS RESULT IN ADAPTIVE CHANGES IN GENE EXPRESSION THAT ULTIMATELY PRODUCE TWO MAJOR STATES: ADDICTION AND TOXICITY. EPIGENETIC MODIFICATIONS OF CHROMATIN COULD LEAD TO LONG-LIVED OR EVEN TRANSGENERATIONAL CHANGES IN GENE EXPRESSION, THUS PRODUCING ASPECTS OF THE HERITABILITY OF ALCOHOL USE DISORDERS (AUD) AND LONG-TERM BEHAVIORS SUCH AS RECIDIVISM. THE DIVERSE CLINICAL SYNDROMES PRODUCED BY CHRONIC ALCOHOL ACTIONS IN THE CENTRAL NERVOUS SYSTEM REFLECT THE MOLECULAR PATHOLOGY AND PREDOMINANTLY INVOLVE ASPECTS OF TOLERANCE/WITHDRAWAL, SELECTIVE VULNERABILITY (MANIFEST AS CENTRAL PONTINE MYELINOLYSIS, MARCHIAFAVA-BIGNAMI DISEASE), AND ADDITIONAL ENVIRONMENTAL FACTORS (E.G., THIAMINE DEFICIENCY IN WERNICKE-KORSAKOFF'S SYNDROME). ADDITIONALLY, DELETERIOUS ASPECTS OF CHRONIC ALCOHOL ON SIGNALING, SYNAPTIC TRANSMISSION, AND CELL TOXICITY LEAD TO PRIMARY ALCOHOLIC DEMENTIA. GENETICALLY DETERMINED ASPECTS OF MYELIN STRUCTURE AND ALCOHOL ACTIONS ON MYELIN GENE EXPRESSION MAY BE A PROMINENT MOLECULAR MECHANISM RESULTING IN A PREDISPOSITION TO, OR CAUSATION OF, AUD AND MULTIPLE OTHER NEUROLOGIC COMPLICATIONS OF CHRONIC ALCOHOL. THE DRAMATIC PROGRESS MADE IN UNDERSTANDING MOLECULAR ACTIONS OF ALCOHOL HOLDS GREAT PROMISE FOR OUR EVENTUAL TREATMENT OR PREVENTION OF AUD AND NEUROLOGIC COMPLICATIONS RESULTING FROM CHRONIC ALCOHOL ABUSE. 2014 18 2119 34 EPIGENETIC HISTONE MODIFICATION REGULATES DEVELOPMENTAL LEAD EXPOSURE INDUCED HYPERACTIVITY IN RATS. LEAD (PB) EXPOSURE WAS COMMONLY CONSIDERED AS A HIGH ENVIRONMENTAL RISK FACTOR FOR THE DEVELOPMENT OF ATTENTION-DEFICIT/HYPERACTIVITY DISORDER (ADHD). HOWEVER, THE MOLECULAR BASIS OF THIS PATHOLOGICAL PROCESS STILL REMAINS ELUSIVE. IN LIGHT OF THE ROLE OF EPIGENETICS IN MODULATING THE NEUROLOGICAL DISEASE AND THE CAUSATIVE ENVIRONMENT, THE ALTERATIONS OF HISTONE MODIFICATIONS IN THE HIPPOCAMPUS OF RATS EXPOSED BY VARIOUS DOSES OF LEAD, ALONG WITH CONCOMITANT BEHAVIORAL DEFICITS, WERE INVESTIGATED IN THIS STUDY. ACCORDING TO THE FREE AND FORCED OPEN FIELD TEST, THERE SHOWED THAT IN A DOSAGE-DEPENDENT MANNER, LEAD EXPOSURE COULD RESULT IN THE INCREASED LOCOMOTOR ACTIVITY OF RATS, THAT IS, HYPERACTIVITY: A SUBTYPE OF ADHD. WESTERN BLOTTING ASSAYS REVEALED THAT THE LEVELS OF HISTONE ACETYLATION INCREASED SIGNIFICANTLY IN THE HIPPOCAMPUS BY CHRONIC LEAD EXPOSURE, WHILE NO DRAMATIC CHANGES WERE DETECTED IN TERMS OF EXPRESSION YIELDS OF ADHD-RELATED DOPAMINERGIC PROTEINS, INDICATING THAT HISTONE ACETYLATION PLAYS ESSENTIAL ROLES IN THIS TOXICANT-INVOLVED PATHOGENESIS. IN ADDITION, THE INCREASED LEVEL OF HISTONE ACETYLATION MIGHT BE ATTRIBUTED TO THE ENZYMATIC ACTIVITY OF P300, A TYPICAL HISTONE ACETYLTRANSFERASE, AS THE TRANSCRIPTIONAL LEVEL OF P300 WAS SIGNIFICANTLY INCREASED UPON HIGHER-DOSE PB EXPOSURE. IN SUMMARY, THIS STUDY FIRST DISCOVERED THE EPIGENETIC MECHANISM BRIDGING THE ENVIRONMENTAL INFLUENCE (PB) AND THE DISEASE ITSELF (ADHD) IN THE HISTONE MODIFICATION LEVEL, PAVING THE WAY FOR THE COMPREHENSIVE UNDERSTANDING OF ADHD'S ETIOLOGY AND IN FURTHER STEPS, ESTABLISHING THE THERAPY STRATEGY OF THIS WIDESPREAD NEUROLOGICAL DISORDER. 2014 19 2010 49 EPIGENETIC BASIS OF LEAD-INDUCED NEUROLOGICAL DISORDERS. ENVIRONMENTAL LEAD (PB) EXPOSURE IS CLOSELY ASSOCIATED WITH PATHOGENESIS OF A RANGE OF NEUROLOGICAL DISORDERS, INCLUDING ALZHEIMER'S DISEASE (AD), PARKINSON'S DISEASE (PD), AMYOTROPHIC LATERAL SCLEROSIS (ALS), ATTENTION DEFICIT/HYPERACTIVITY DISORDER (ADHD), ETC. EPIGENETIC MACHINERY MODULATES NEURAL DEVELOPMENT AND ACTIVITIES, WHILE FAULTY EPIGENETIC REGULATION CONTRIBUTES TO THE DIVERSE FORMS OF CNS (CENTRAL NERVOUS SYSTEM) ABNORMALITIES AND DISEASES. AS A POTENT EPIGENETIC MODIFIER, LEAD IS THOUGHT TO CAUSE NEUROLOGICAL DISORDERS THROUGH MODULATING EPIGENETIC MECHANISMS. SPECIFICALLY, INCREASING EVIDENCE LINKED ABERRANT DNA METHYLATIONS, HISTONE MODIFICATIONS AS WELL AS NCRNAS (NON-CODING RNAS) WITH AD CASES, AMONG WHICH CIRCRNA (CIRCULAR RNA) STANDS OUT AS A NEW AND PROMISING FIELD FOR ASSOCIATION STUDIES. IN 23-YEAR-OLD PRIMATES WITH DEVELOPMENTAL LEAD TREATMENT, ZAWIA GROUP DISCOVERED A VARIETY OF EPIGENETIC CHANGES RELATING TO AD PATHOGENESIS. THIS IS A DIRECT EVIDENCE IMPLICATING EPIGENETIC BASIS IN LEAD-INDUCED AD ANIMALS WITH AN ENTIRE LIFESPAN. ADDITIONALLY, SOME EPIGENETIC MOLECULES ASSOCIATED WITH AD ETIOLOGY WERE ALSO KNOWN TO RESPOND TO CHRONIC LEAD EXPOSURE IN COMPARABLE DISEASE MODELS, INDICATING POTENTIALLY INTERLACED MECHANISMS WITH RESPECT TO THE STUDIED NEUROTOXIC AND PATHOLOGICAL EVENTS. OF NOTE, EPIGENETIC MOLECULES ACTED VIA GLOBALLY OR SELECTIVELY INFLUENCING THE EXPRESSION OF DISEASE-RELATED GENES. COMPARED TO AD, THE ASSOCIATION OF LEAD EXPOSURE WITH OTHER NEUROLOGICAL DISORDERS WERE PRIMARILY SUPPORTED BY EPIDEMIOLOGICAL SURVEY, WITH FEWER REPORTS CONNECTING EPIGENETIC REGULATORS WITH LEAD-INDUCED PATHOGENESIS. SOME PHARMACEUTICALS, SUCH AS HDAC (HISTONE DEACETYLASE) INHIBITORS AND DNA METHYLATION INHIBITORS, WERE DEVELOPED TO DEAL WITH CNS DISEASE BY TARGETING EPIGENETIC COMPONENTS. STILL, UNDERSTANDINGS ARE INSUFFICIENT REGARDING THE CAUSE-CONSEQUENCE RELATIONS OF EPIGENETIC FACTORS AND NEUROLOGICAL ILLNESS. THEREFORE, CLEAR EVIDENCE SHOULD BE PROVIDED IN FUTURE INVESTIGATIONS TO ADDRESS DETAILED ROLES OF NOVEL EPIGENETIC FACTORS IN LEAD-INDUCED NEUROLOGICAL DISORDERS, AND EFFORTS OF DEVELOPING SPECIFIC EPIGENETIC THERAPEUTICS SHOULD BE APPRAISED. 2020 20 3076 37 GENOME-WIDE EPIGENOMIC ANALYSES IN PATIENTS WITH NOCICEPTIVE AND NEUROPATHIC CHRONIC PAIN SUBTYPES REVEALS ALTERATIONS IN METHYLATION OF GENES INVOLVED IN THE NEURO-MUSCULOSKELETAL SYSTEM. NOCICEPTIVE PAIN INVOLVES THE ACTIVATION OF NOCICEPTORS WITHOUT DAMAGE TO THE NERVOUS SYSTEM, WHEREAS NEUROPATHIC PAIN IS RELATED TO AN ALTERATION IN THE CENTRAL OR PERIPHERAL NERVOUS SYSTEM. CHRONIC PAIN ITSELF AND THE TRANSITION FROM ACUTE TO CHRONIC PAIN MAY BE EPIGENETICALLY CONTROLLED. IN THIS CROSS-SECTIONAL STUDY, A GENOME-WIDE DNA METHYLATION ANALYSIS WAS PERFORMED USING THE BLOOD DNA REDUCED REPRESENTATION BISULFITE SEQUENCING (RRBS) TECHNIQUE. THREE PROSPECTIVE COHORTS INCLUDING 20 HEALTHY CONTROLS (CTL), 18 PATIENTS WITH CHRONIC NOCICEPTIVE PAIN (NOCI), AND 19 PATIENTS WITH CHRONIC NEUROPATHIC PAIN (NEURO) WERE COMPARED AT BOTH THE SINGLE CPG AND DIFFERENTIALLY METHYLATED REGION (DMR) LEVELS. GENES WITH DMRS WERE SEEN IN THE NOCI AND NEURO GROUPS BELONGED TO THE NEURO-MUSCULOSKELETAL SYSTEM AND DIFFERED BETWEEN NOCI AND NEURO PATIENTS. OUR RESULTS DEMONSTRATE THAT THE EPIGENETIC DISTURBANCES ACCOMPANYING NOCICEPTIVE PAIN ARE VERY DIFFERENT FROM THOSE ACCOMPANYING NEUROPATHIC PAIN. IN THE FORMER, AMONG OTHERS, THE EPIGENETIC DISTURBANCE OBSERVED WOULD AFFECT THE FUNCTION OF THE OPIOID ANALGESIC SYSTEM, WHEREAS IN THE LATTER IT WOULD AFFECT THAT OF THE GABAERGIC REWARD SYSTEM. THIS STUDY PRESENTS BIOLOGICAL FINDINGS THAT HELP TO CHARACTERIZE NOCI- AND NEURO-AFFECTED PATHWAYS AND OPENS THE POSSIBILITY OF DEVELOPING EPIGENETIC DIAGNOSTIC ASSAYS. PERSPECTIVE: OUR RESULTS HELP TO EXPLAIN THE VARIOUS BIOLOGICAL PATHWAYS MODIFICATIONS UNDERLYING THE DIFFERENT CLINICAL MANIFESTATIONS OF NOCICEPTIVE AND NEUROPATHIC PAINS. FURTHERMORE, THE NEW TARGETS IDENTIFIED IN OUR STUDY MIGHT HELP TO DISCOVER MORE SPECIFIC TREATMENTS FOR NOCICEPTIVE OR NEUROPATHIC PAINS. 2022