1 856 101 CHROMATIN ACCESSIBILITY MAPPING OF THE STRIATUM IDENTIFIES TYROSINE KINASE FYN AS A THERAPEUTIC TARGET FOR HEROIN USE DISORDER. THE CURRENT OPIOID EPIDEMIC NECESSITATES A BETTER UNDERSTANDING OF HUMAN ADDICTION NEUROBIOLOGY TO DEVELOP EFFICACIOUS TREATMENT APPROACHES. HERE, WE PERFORM GENOME-WIDE ASSESSMENT OF CHROMATIN ACCESSIBILITY OF THE HUMAN STRIATUM IN HEROIN USERS AND MATCHED CONTROLS. OUR STUDY REVEALS DISTINCT NEURONAL AND NON-NEURONAL EPIGENETIC SIGNATURES, AND IDENTIFIES A LOCUS IN THE PROXIMITY OF THE GENE ENCODING TYROSINE KINASE FYN AS THE MOST AFFECTED REGION IN NEURONS. FYN EXPRESSION, KINASE ACTIVITY AND THE PHOSPHORYLATION OF ITS TARGET TAU ARE INCREASED BY HEROIN USE IN THE POST-MORTEM HUMAN STRIATUM, AS WELL AS IN RATS TRAINED TO SELF-ADMINISTER HEROIN AND PRIMARY STRIATAL NEURONS TREATED WITH CHRONIC MORPHINE IN VITRO. PHARMACOLOGICAL OR GENETIC MANIPULATION OF FYN ACTIVITY SIGNIFICANTLY ATTENUATES HEROIN SELF-ADMINISTRATION AND RESPONDING FOR DRUG-PAIRED CUES IN RODENTS. OUR FINDINGS SUGGEST THAT STRIATAL FYN IS AN IMPORTANT DRIVER OF HEROIN-RELATED NEURODEGENERATIVE-LIKE PATHOLOGY AND DRUG-TAKING BEHAVIOR, MAKING FYN A PROMISING THERAPEUTIC TARGET FOR HEROIN USE DISORDER. 2020 2 5503 26 RGS9-2--CONTROLLED ADAPTATIONS IN THE STRIATUM DETERMINE THE ONSET OF ACTION AND EFFICACY OF ANTIDEPRESSANTS IN NEUROPATHIC PAIN STATES. THE STRIATAL PROTEIN REGULATOR OF G-PROTEIN SIGNALING 9-2 (RGS9-2) PLAYS A KEY MODULATORY ROLE IN OPIOID, MONOAMINE, AND OTHER G-PROTEIN-COUPLED RECEPTOR RESPONSES. HERE, WE USE THE MURINE SPARED-NERVE INJURY MODEL OF NEUROPATHIC PAIN TO INVESTIGATE THE MECHANISM BY WHICH RGS9-2 IN THE NUCLEUS ACCUMBENS (NAC), A BRAIN REGION INVOLVED IN MOOD, REWARD, AND MOTIVATION, MODULATES THE ACTIONS OF TRICYCLIC ANTIDEPRESSANTS (TCAS). PREVENTION OF RGS9-2 ACTION IN THE NAC INCREASES THE EFFICACY OF THE TCA DESIPRAMINE AND DRAMATICALLY ACCELERATES ITS ONSET OF ACTION. BY CONTROLLING THE ACTIVATION OF EFFECTOR MOLECULES BY G PROTEIN ALPHA AND BETAGAMMA SUBUNITS, RGS9-2 AFFECTS SEVERAL PROTEIN INTERACTIONS, PHOSPHOPROTEIN LEVELS, AND THE FUNCTION OF THE EPIGENETIC MODIFIER HISTONE DEACETYLASE 5, WHICH ARE IMPORTANT FOR TCA RESPONSIVENESS. FURTHERMORE, INFORMATION FROM RNA-SEQUENCING ANALYSIS REVEALS THAT RGS9-2 IN THE NAC AFFECTS THE EXPRESSION OF MANY GENES KNOWN TO BE INVOLVED IN NOCICEPTION, ANALGESIA, AND ANTIDEPRESSANT DRUG ACTIONS. OUR FINDINGS PROVIDE NOVEL INFORMATION ON NAC-SPECIFIC CELLULAR MECHANISMS THAT MEDIATE THE ACTIONS OF TCAS IN NEUROPATHIC PAIN STATES. 2015 3 195 25 ACF CHROMATIN-REMODELING COMPLEX MEDIATES STRESS-INDUCED DEPRESSIVE-LIKE BEHAVIOR. IMPROVED TREATMENT FOR MAJOR DEPRESSIVE DISORDER (MDD) REMAINS ELUSIVE BECAUSE OF THE LIMITED UNDERSTANDING OF ITS UNDERLYING BIOLOGICAL MECHANISMS. IT IS LIKELY THAT STRESS-INDUCED MALADAPTIVE TRANSCRIPTIONAL REGULATION IN LIMBIC NEURAL CIRCUITS CONTRIBUTES TO THE DEVELOPMENT OF MDD, POSSIBLY THROUGH EPIGENETIC FACTORS THAT REGULATE CHROMATIN STRUCTURE. WE ESTABLISH THAT PERSISTENT UPREGULATION OF THE ACF (ATP-UTILIZING CHROMATIN ASSEMBLY AND REMODELING FACTOR) ATP-DEPENDENT CHROMATIN-REMODELING COMPLEX, OCCURRING IN THE NUCLEUS ACCUMBENS OF STRESS-SUSCEPTIBLE MICE AND DEPRESSED HUMANS, IS NECESSARY FOR STRESS-INDUCED DEPRESSIVE-LIKE BEHAVIORS. WE FOUND THAT ALTERED ACF BINDING AFTER CHRONIC STRESS WAS CORRELATED WITH ALTERED NUCLEOSOME POSITIONING, PARTICULARLY AROUND THE TRANSCRIPTION START SITES OF AFFECTED GENES. THESE ALTERATIONS IN ACF BINDING AND NUCLEOSOME POSITIONING WERE ASSOCIATED WITH REPRESSED EXPRESSION OF GENES IMPLICATED IN SUSCEPTIBILITY TO STRESS. TOGETHER, OUR FINDINGS IDENTIFY THE ACF CHROMATIN-REMODELING COMPLEX AS A CRITICAL COMPONENT IN THE DEVELOPMENT OF SUSCEPTIBILITY TO DEPRESSION AND IN REGULATING STRESS-RELATED BEHAVIORS. 2015 4 3002 26 GENETIC, EPIGENETIC AND POSTTRANSCRIPTIONAL MECHANISMS FOR TREATMENT OF MAJOR DEPRESSION: THE 5-HT1A RECEPTOR GENE AS A PARADIGM. MAJOR DEPRESSION AND ANXIETY ARE HIGHLY PREVALENT AND INVOLVE CHRONIC DYSREGULATION OF SEROTONIN, BUT THEY REMAIN POORLY UNDERSTOOD. HERE, WE REVIEW NOVEL TRANSCRIPTIONAL (GENETIC, EPIGENETIC) AND POSTTRANSCRIPTIONAL (MICRORNA, ALTERNATIVE SPLICING) MECHANISMS IMPLICATED IN MENTAL ILLNESS, FOCUSING ON A KEY SEROTONIN-RELATED REGULATOR, THE SEROTONIN 1A (5-HT1A) RECEPTOR. FUNCTIONAL SINGLE-NUCLEOTIDE POLYMORPHISMS AND STRESS-INDUCED DNA METHYLATION OF THE 5-HT1A PROMOTER CONVERGE TO DIFFERENTIALLY ALTER PRE- AND POSTSYNAPTIC 5-HT1A RECEPTOR EXPRESSION ASSOCIATED WITH MAJOR DEPRESSION AND REDUCED THERAPEUTIC RESPONSE TO SEROTONERGIC ANTIDEPRESSANTS. MAJOR DEPRESSION IS ALSO ASSOCIATED WITH ALTERED LEVELS OF SPLICE FACTORS AND MICRORNA, POSTTRANSCRIPTIONAL MECHANISMS THAT REGULATE RNA STABILITY. THE HUMAN 5-HT1A 3'-UNTRANSLATED REGION IS ALTERNATIVELY SPLICED, REMOVING MICRORNA SITES AND INCREASING 5-HT1A EXPRESSION, WHICH IS REDUCED IN MAJOR DEPRESSION AND MAY BE GENOTYPE-DEPENDENT. THUS, THE 5-HT1A RECEPTOR GENE ILLUSTRATES THE CONVERGENCE OF GENETIC, EPIGENETIC AND POSTTRANSCRIPTIONAL MECHANISMS IN GENE EXPRESSION, NEURODEVELOPMENT AND NEUROPLASTICITY, AND MAJOR DEPRESSION. UNDERSTANDING GENE REGULATORY MECHANISMS COULD ENHANCE THE DETECTION, CATEGORIZATION AND PERSONALIZED TREATMENT OF MAJOR DEPRESSION. 2019 5 3465 27 HYPOTHESIS: REGULATION OF NEUROPLASTICITY MAY INVOLVE I-MOTIF AND G-QUADRUPLEX DNA FORMATION MODULATED BY EPIGENETIC MECHANISMS. RECENT STUDIES DEMONSTRATED THE EXISTENCE IN VIVO OF VARIOUS FUNCTIONAL DNA STRUCTURES THAT DIFFER FROM THE DOUBLE HELIX. THE G-QUADRUPLEX (G4) AND INTERCALATED MOTIF (I-MOTIF OR IM) DNA STRUCTURES ARE FORMED AS KNOTS WHERE, CORRESPONDINGLY, GUANINES OR CYTOSINES ON THE SAME STRAND OF DNA BIND TO EACH OTHER. THERE ARE GROUNDS TO BELIEVE THAT G4 AND IM SEQUENCES PLAY A SIGNIFICANT ROLE IN REGULATING GENE EXPRESSION CONSIDERING THEIR TENDENCY TO BE FOUND IN OR NEAR REGULATORY SITES (SUCH AS PROMOTERS, ENHANCERS, AND TELOMERES) AS WELL AS THE CORRELATION BETWEEN THE PREVALENCE OF G4 OR IM CONFORMATIONS AND SPECIFIC PHASES OF CELL CYCLE. NOTABLY, G4 AND IM CAPABLE SEQUENCES TEND TO BE FOUND ON THE OPPOSITE STRANDS OF THE SAME DNA SITE WITH AT MOST ONE OF THE TWO STRUCTURES FORMED AT ANY GIVEN TIME. THE RECENT EVIDENCE THAT K(+), MG(2+) CONCENTRATIONS DIRECTLY AFFECT IM FORMATION (AND LIKELY G4 FORMATION INDIRECTLY) LEAD US TO BELIEVE THAT THESE STRUCTURES MAY PLAY A MAJOR ROLE IN SYNAPTIC PLASTICITY OF NEURONS, AND, THEREFORE, IN A VARIETY OF CENTRAL NERVOUS SYSTEM (CNS) FUNCTIONS INCLUDING MEMORY, LEARNING, HABITUAL BEHAVIORS, PAIN PERCEPTION AND OTHERS. FURTHERMORE, EPIGENETIC MECHANISMS, WHICH HAVE AN IMPORTANT ROLE IN SYNAPTIC PLASTICITY AND MEMORY FORMATION, WERE ALSO SHOWN TO INFLUENCE FORMATION AND STABILITY OF G4S AND IMS. OUR HYPOTHESIS IS THAT NON-CANONICAL DNA AND RNA STRUCTURES COULD BE AN INTEGRAL PART OF NEUROPLASTICITY CONTROL VIA GENE EXPRESSION REGULATION AT THE LEVEL OF TRANSCRIPTION, TRANSLATION AND SPLICING. WE PROPOSE THAT THE REGULATORY ACTIVITY OF DNA IM AND G4 STRUCTURES IS MODULATED BY DNA METHYLATION/DEMETHYLATION OF THE IM AND/OR G4 SEQUENCES, WHICH FACILITATES THE SWITCH BETWEEN CANONICAL AND NON-CANONICAL CONFORMATION. OTHER NEURONAL MECHANISMS INTERACTING WITH THE FORMATION AND REGULATORY ACTIVITY OF NON-CANONICAL DNA AND RNA STRUCTURES, PARTICULARLY G4, IM AND TRIPLEXES, MAY INVOLVE MICRORNAS AS WELL AS ION AND PROTON FLUXES. WE ARE PROPOSING EXPERIMENTS IN ACUTE BRAIN SLICES AND IN VIVO TO TEST OUR HYPOTHESIS. THE PROPOSED STUDIES WOULD PROVIDE NEW INSIGHTS INTO FUNDAMENTAL NEURONAL MECHANISMS IN HEALTH AND DISEASE AND POTENTIALLY OPEN NEW AVENUES FOR TREATING MENTAL HEALTH DISORDERS. 2019 6 2246 22 EPIGENETIC MODULATION OF INFLAMMATION AND SYNAPTIC PLASTICITY PROMOTES RESILIENCE AGAINST STRESS IN MICE. MAJOR DEPRESSIVE DISORDER IS ASSOCIATED WITH ABNORMALITIES IN THE BRAIN AND THE IMMUNE SYSTEM. CHRONIC STRESS IN ANIMALS SHOWED THAT EPIGENETIC AND INFLAMMATORY MECHANISMS PLAY IMPORTANT ROLES IN MEDIATING RESILIENCE AND SUSCEPTIBILITY TO DEPRESSION. HERE, THROUGH A HIGH-THROUGHPUT SCREENING, WE IDENTIFY TWO PHYTOCHEMICALS, DIHYDROCAFFEIC ACID (DHCA) AND MALVIDIN-3'-O-GLUCOSIDE (MAL-GLUC) THAT ARE EFFECTIVE IN PROMOTING RESILIENCE AGAINST STRESS BY MODULATING BRAIN SYNAPTIC PLASTICITY AND PERIPHERAL INFLAMMATION. DHCA/MAL-GLUC ALSO SIGNIFICANTLY REDUCES DEPRESSION-LIKE PHENOTYPES IN A MOUSE MODEL OF INCREASED SYSTEMIC INFLAMMATION INDUCED BY TRANSPLANTATION OF HEMATOPOIETIC PROGENITOR CELLS FROM STRESS-SUSCEPTIBLE MICE. DHCA REDUCES PRO-INFLAMMATORY INTERLEUKIN 6 (IL-6) GENERATIONS BY INHIBITING DNA METHYLATION AT THE CPG-RICH IL-6 SEQUENCES INTRONS 1 AND 3, WHILE MAL-GLUC MODULATES SYNAPTIC PLASTICITY BY INCREASING HISTONE ACETYLATION OF THE REGULATORY SEQUENCES OF THE RAC1 GENE. PERIPHERAL INFLAMMATION AND SYNAPTIC MALADAPTATION ARE IN LINE WITH NEWLY HYPOTHESIZED CLINICAL INTERVENTION TARGETS FOR DEPRESSION THAT ARE NOT ADDRESSED BY CURRENTLY AVAILABLE ANTIDEPRESSANTS. 2018 7 889 24 CHRONIC DIETARY ADMINISTRATION OF VALPROIC ACID PROTECTS NEURONS OF THE RAT NUCLEUS BASALIS MAGNOCELLULARIS FROM IBOTENIC ACID NEUROTOXICITY. VALPROIC ACID (VPA) HAS BEEN USED FOR MANY YEARS AS A DRUG OF CHOICE FOR EPILEPSY AND MOOD DISORDERS. RECENTLY, EVIDENCE HAS BEEN PROPOSED FOR A WIDE SPECTRUM OF ACTIONS OF THIS DRUG, INCLUDING ANTITUMORAL AND NEUROPROTECTIVE PROPERTIES. VALPROIC ACID-MEDIATED NEUROPROTECTION IN VIVO HAS BEEN SO FAR DEMONSTRATED IN A LIMITED NUMBER OF EXPERIMENTAL MODELS. IN THIS STUDY, WE HAVE TESTED THE NEUROPROTECTIVE POTENTIAL OF CHRONIC (4 + 1 WEEKS) DIETARY ADMINISTRATION OF VPA ON DEGENERATION OF CHOLINERGIC AND GABAERGIC NEURONS OF THE RAT NUCLEUS BASALIS MAGNOCELLULARIS (NBM), INJECTED WITH THE EXCITOTOXIN, IBOTENIC ACID (IBO), AN ANIMAL MODELS THAT IS RELEVANT FOR ALZHEIMER'S DISEASE-LIKE NEURODEGENERATION. WE SHOW THAT VPA TREATMENT SIGNIFICANTLY PROTECTS BOTH CHOLINERGIC AND GABAERGIC NEURONS PRESENT IN THE INJECTED AREA FROM THE EXCITOTOXIC INSULT. A SIGNIFICANT LEVEL OF NEUROPROTECTION, IN PARTICULAR, IS EXERTED TOWARDS THE CHOLINERGIC NEURONS OF THE NBM PROJECTING TO THE CORTEX, AS DEMONSTRATED BY THE SUBSTANTIALLY HIGHER LEVELS OF CHOLINERGIC MARKERS MAINTAINED IN THE TARGET CORTICAL AREA OF VPA-TREATED RATS AFTER IBO INJECTION IN THE NBM. WE FURTHER SHOW THAT CHRONIC VPA ADMINISTRATION RESULTS IN INCREASED ACETYLATION OF HISTONE H3 IN BRAIN, CONSISTENT WITH THE HISTONE DEACETYLASE INHIBITORY ACTION OF VPA AND PUTATIVELY LINKED TO A NEUROPROTECTIVE ACTION OF THE DRUG MEDIATED AT THE EPIGENETIC LEVEL. 2009 8 984 27 CHRONIC PSYCHOLOGICAL STRESS ALTERS GENE EXPRESSION IN RAT COLON EPITHELIAL CELLS PROMOTING CHROMATIN REMODELING, BARRIER DYSFUNCTION AND INFLAMMATION. CHRONIC STRESS IS COMMONLY ASSOCIATED WITH ENHANCED ABDOMINAL PAIN (VISCERAL HYPERSENSITIVITY), BUT THE CELLULAR MECHANISMS UNDERLYING HOW CHRONIC STRESS INDUCES VISCERAL HYPERSENSITIVITY ARE POORLY UNDERSTOOD. IN THIS STUDY, WE EXAMINED CHANGES IN GENE EXPRESSION IN COLON EPITHELIAL CELLS FROM A RAT MODEL USING RNA-SEQUENCING TO EXAMINE STRESS-INDUCED CHANGES TO THE TRANSCRIPTOME. FOLLOWING CHRONIC STRESS, THE MOST SIGNIFICANTLY UP-REGULATED GENES INCLUDED ATG16L1, COQ10B, DCAF13, NAT2, PTBP2, RRAS2, SPINK4 AND DOWN-REGULATED GENES INCLUDING ABAT, CITED2, CNNM2, DAB2IP, PLEKHM1, SCD2, AND TAB2. THE PRIMARY ALTERED BIOLOGICAL PROCESSES REVEALED BY NETWORK ENRICHMENT ANALYSIS WERE INFLAMMATION/IMMUNE RESPONSE, TISSUE MORPHOGENESIS AND DEVELOPMENT, AND NUCLEOSOME/CHROMATIN ASSEMBLY. THE MOST SIGNIFICANTLY DOWN-REGULATED PROCESS WAS THE DIGESTIVE SYSTEM DEVELOPMENT/FUNCTION, WHEREAS THE MOST SIGNIFICANTLY UP-REGULATED PROCESSES WERE INFLAMMATORY RESPONSE, ORGANISMAL INJURY, AND CHROMATIN REMODELING MEDIATED BY H3K9 METHYLATION. FURTHERMORE, A SUBPOPULATION OF STRESSED RATS DEMONSTRATED VERY SIGNIFICANTLY ALTERED GENE EXPRESSION AND TRANSCRIPT ISOFORMS, ENRICHED FOR THE DIFFERENTIAL EXPRESSION OF GENES INVOLVED IN THE INFLAMMATORY RESPONSE, INCLUDING UPREGULATION OF CYTOKINE AND CHEMOKINE RECEPTOR GENE EXPRESSION COUPLED WITH DOWNREGULATION OF EPITHELIAL ADHERENS AND TIGHT JUNCTION MRNAS. IN SUMMARY, THESE FINDINGS SUPPORT THAT CHRONIC STRESS IS ASSOCIATED WITH INCREASED LEVELS OF CYTOKINES AND CHEMOKINES, THEIR DOWNSTREAM SIGNALING PATHWAYS COUPLED TO DYSREGULATION OF INTESTINAL CELL DEVELOPMENT AND FUNCTION. EPIGENETIC REGULATION OF CHROMATIN REMODELING LIKELY PLAYS A PROMINENT ROLE IN THIS PROCESS. RESULTS ALSO SUGGEST THAT SUPER ENHANCERS PLAY A PRIMARY ROLE IN CHRONIC STRESS-ASSOCIATED INTESTINAL BARRIER DYSFUNCTION. 2022 9 4499 30 MORPHINE WITHDRAWAL PRODUCES ERK-DEPENDENT AND ERK-INDEPENDENT EPIGENETIC MARKS IN NEURONS OF THE NUCLEUS ACCUMBENS AND LATERAL SEPTUM. EPIGENETIC CHANGES SUCH AS COVALENT MODIFICATIONS OF HISTONE PROTEINS REPRESENT COMPLEX MOLECULAR SIGNATURES THAT PROVIDE A CELLULAR MEMORY OF PREVIOUSLY EXPERIENCED STIMULI WITHOUT IRREVERSIBLE CHANGES OF THE GENETIC CODE. IN THIS STUDY WE SHOW THAT NEW GENE EXPRESSION INDUCED IN VIVO BY MORPHINE WITHDRAWAL OCCURS WITH CONCOMITANT EPIGENETIC MODIFICATIONS IN BRAIN REGIONS CRITICALLY INVOLVED IN DRUG-DEPENDENT BEHAVIORS. WE FOUND THAT NALOXONE-PRECIPITATED WITHDRAWAL, BUT NOT CHRONIC MORPHINE ADMINISTRATION, CAUSED A STRONG INDUCTION OF PHOSPHO-HISTONE H3 IMMUNOREACTIVITY IN THE NUCLEUS ACCUMBENS (NAC) SHELL/CORE AND IN THE LATERAL SEPTUM (LS), A CHANGE THAT WAS ACCOMPANIED BY AUGMENTED H3 ACETYLATION (LYS14) IN NEURONS OF THE NAC SHELL. MORPHINE WITHDRAWAL INDUCED THE PHOSPHORYLATION OF THE EPIGENETIC FACTOR METHYL-CPG-BINDING PROTEIN 2 (MECP2) IN SER421 BOTH IN THE LS AND THE NAC SHELL. THESE EPIGENETIC CHANGES WERE ACCOMPANIED BY THE ACTIVATION OF MEMBERS OF THE ERK PATHWAY AS WELL AS INCREASED EXPRESSION OF THE IMMEDIATE EARLY GENES (IEG) C-FOS AND ACTIVITY-REGULATED CYTOSKELETON-ASSOCIATED PROTEIN (ARC/ARG3.1). USING A PHARMACOLOGICAL APPROACH, WE FOUND THAT H3 PHOSPHORYLATION AND IEG EXPRESSION WERE PARTIALLY DEPENDENT ON ERK ACTIVATION, WHILE MECP2 PHOSPHORYLATION WAS FULLY ERK-INDEPENDENT. THESE FINDINGS PROVIDE NEW IMPORTANT INFORMATION ON THE ROLE OF THE ERK PATHWAY IN THE REGULATION OF EPIGENETIC MARKS AND GENE EXPRESSION THAT MAY CONCUR TO REGULATE IN VIVO THE CELLULAR CHANGES UNDERLYING THE ONSET OF THE OPIOID WITHDRAWAL SYNDROME. 2013 10 5838 27 STRIATAL SHATI/NAT8L-BDNF PATHWAYS DETERMINE THE SENSITIVITY TO SOCIAL DEFEAT STRESS IN MICE THROUGH EPIGENETIC REGULATION. THE GLOBAL NUMBER OF PATIENTS WITH DEPRESSION INCREASES IN CORRELATION TO EXPOSURE TO SOCIAL STRESS. CHRONIC STRESS DOES NOT TRIGGER DEPRESSION IN ALL INDIVIDUALS, AS SOME REMAIN RESILIENT. THE UNDERLYING MOLECULAR MECHANISMS THAT CONTRIBUTE TO STRESS SENSITIVITY HAVE BEEN POORLY UNDERSTOOD, ALTHOUGH REVEALING THE REGULATION OF STRESS SENSITIVITY COULD HELP DEVELOP TREATMENTS FOR DEPRESSION. WE PREVIOUSLY FOUND THAT STRIATAL SHATI/NAT8L, AN N-ACETYLTRANSFERASE, WAS INCREASED IN A DEPRESSION MOUSE MODEL. WE INVESTIGATED THE ROLES OF SHATI/NAT8L IN STRESS SENSITIVITY IN MICE AND FOUND THAT SHATI/NAT8L AND BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) LEVELS IN THE DORSAL STRIATUM WERE INCREASED IN STRESS-SUSCEPTIBLE MICE BUT NOT IN RESILIENT MICE EXPOSED TO REPEATED SOCIAL DEFEAT STRESS (RSDS). KNOCKDOWN OF SHATI/NAT8L IN THE DORSAL STRIATUM INDUCED RESILIENCE TO RSDS. IN ADDITION, BLOCKADE OF BDNF SIGNALING IN THE DORSAL STRIATUM BY ANA-12, A BDNF-SPECIFIC RECEPTOR TROPOMYOSIN-RECEPTOR-KINASE B (TRKB) INHIBITOR, ALSO INDUCED RESILIENCE TO STRESS. SHATI/NAT8L IS CORRELATED WITH BDNF EXPRESSION AFTER RSDS, AND BDNF IS DOWNSTREAM OF SHATI/NAT8L PATHWAYS IN THE DORSAL STRIATUM; SHATI/NAT8L IS EPIGENETICALLY REGULATED BY BDNF VIA HISTONE ACETYLATION. OUR RESULTS DEMONSTRATE THAT STRIATAL SHATI/NAT8L-BDNF PATHWAYS DETERMINE STRESS SENSITIVITY THROUGH EPIGENETIC REGULATION. THE STRIATAL SHATI/NAT8L-BDNF PATHWAY COULD BE A NOVEL TARGET FOR TREATMENTS OF DEPRESSION AND COULD ESTABLISH A NOVEL THERAPEUTIC STRATEGY FOR DEPRESSION PATIENTS. 2021 11 2886 23 GABA-AALPHA5 MIGHT BE INVOLVED IN LEARNING-MEMORY DYSFUNCTION IN THE OFFSPRINGS OF CHRONIC ETHANOL-TREATED RATS VIA GABA-AALPHA5 HISTONE H3K9 ACETYLATION. RECENTLY, NUMEROUS STUDIES HAVE BEEN FOCUSED ON THE RELATIONSHIP BETWEEN GABA-A RECEPTORS AND ALCOHOL-INDUCED SPATIAL LEARNING AND MEMORY DEFICITS. GABA-AALPHA5, A SUBUNIT OF GABA-A RECEPTORS, IS CONSIDERED TO PLAY AN IMPORTANT ROLE IN ALCOHOL-INDUCED COGNITIVE IMPAIRMENT, HOWEVER, THE MECHANISM REMAINS OBSCURE. IN THIS STUDY, WE FOUND THAT THE EXPRESSION OF GABA-AALPHA5 INCREASED IN RATS TREATED WITH CHRONIC ETHANOL VIA HISTONE H3K9 ACETYLATION. FURTHERMORE, THIS EPIGENETIC MODIFICATION COULD BE INHERITED BY THE NEXT GENERATIONS, WHICH EVENTUALLY EXHIBIT SIMILAR SPATIAL LEARNING AND MEMORY DEFICITS IN THE OFFSPRINGS. IN SUMMARY, OUR RESULTS SUGGESTED THAT GABA-AALPHA5 MIGHT BE INVOLVED IN CHRONIC ETHANOL TREATMENT-INDUCED LEARNING-MEMORY DYSFUNCTION AND FOR THE FIRST TIME PROVED THAT LEARNING-MEMORY DYSFUNCTION COULD BE INHERITED BY THE OFFSPRINGS VIA HISTONE H3K9 ACETYLATION. HOPEFULLY, IN THE NEAR FUTURE, GABA-AALPHA5 INHIBITORS WOULD BE AN EFFECTIVE WAY TO TREAT ALCOHOL-INDUCED COGNITION IMPAIRMENT. 2019 12 6690 26 VALPROIC ACID SILENCING OF ASCL1B/ASCL1 RESULTS IN THE FAILURE OF SEROTONERGIC DIFFERENTIATION IN A ZEBRAFISH MODEL OF FETAL VALPROATE SYNDROME. FETAL VALPROATE SYNDROME (FVS) IS CAUSED BY IN UTERO EXPOSURE TO THE DRUG SODIUM VALPROATE. VALPROATE IS USED WORLDWIDE FOR THE TREATMENT OF EPILEPSY, AS A MOOD STABILISER AND FOR ITS PAIN-RELIEVING PROPERTIES. IN ADDITION TO BIRTH DEFECTS, FVS IS ASSOCIATED WITH AN INCREASED RISK OF AUTISM SPECTRUM DISORDER (ASD), WHICH IS CHARACTERISED BY ABNORMAL BEHAVIOURS. VALPROATE PERTURBS MULTIPLE BIOCHEMICAL PATHWAYS AND ALTERS GENE EXPRESSION THROUGH ITS INHIBITION OF HISTONE DEACETYLASES. WHICH, IF ANY, OF THESE MECHANISMS IS RELEVANT TO THE GENESIS OF ITS BEHAVIOURAL SIDE EFFECTS IS UNCLEAR. NEUROANATOMICAL CHANGES ASSOCIATED WITH FVS HAVE BEEN REPORTED AND, AMONG THESE, ALTERED SEROTONERGIC NEURONAL DIFFERENTIATION IS A CONSISTENT FINDING. ALTERED SEROTONIN HOMEOSTASIS IS ALSO ASSOCIATED WITH AUTISM. HERE WE HAVE USED A CHEMICAL-GENETICS APPROACH TO INVESTIGATE THE UNDERLYING MOLECULAR DEFECT IN A ZEBRAFISH FVS MODEL. VALPROATE CAUSES THE SELECTIVE FAILURE OF ZEBRAFISH CENTRAL SEROTONIN EXPRESSION. IT DOES SO BY DOWNREGULATING THE PRONEURAL GENE ASCL1B, AN ORTHOLOG OF MAMMALIAN ASCL1, WHICH IS A KNOWN DETERMINANT OF SEROTONERGIC IDENTITY IN THE MAMMALIAN BRAINSTEM. ASCL1B IS SUFFICIENT TO RESCUE SEROTONIN EXPRESSION IN VALPROATE-TREATED EMBRYOS. CHEMICAL AND GENETIC BLOCKADE OF THE HISTONE DEACETYLASE HDAC1 DOWNREGULATES ASCL1B, CONSISTENT WITH THE HDAC1-MEDIATED SILENCING OF ASCL1B EXPRESSION BY VALPROATE. MOREOVER, TONIC NOTCH SIGNALLING IS CRUCIAL FOR ASCL1B REPRESSION BY VALPROATE. CONCOMITANT BLOCKADE OF NOTCH SIGNALLING RESTORES ASCL1B EXPRESSION AND SEROTONIN EXPRESSION IN BOTH VALPROATE-EXPOSED AND HDAC1 MUTANT EMBRYOS. TOGETHER, THESE DATA PROVIDE A MOLECULAR EXPLANATION FOR SEROTONERGIC DEFECTS IN FVS AND HIGHLIGHT AN EPIGENETIC MECHANISM FOR GENOME-ENVIRONMENT INTERACTION IN DISEASE. 2014 13 3390 26 HOPX PLAYS A CRITICAL ROLE IN ANTIRETROVIRAL DRUGS INDUCED EPIGENETIC MODIFICATION AND CARDIAC HYPERTROPHY. PEOPLE LIVING WITH HIV (PLWH) HAVE TO TAKE AN ANTIRETROVIRAL THERAPY (ART) FOR LIFE AND SHOW NONCOMMUNICABLE ILLNESSES SUCH AS CHRONIC INFLAMMATION, IMMUNE ACTIVATION, AND MULTIORGAN DYSREGULATION. RECENT STUDIES SUGGEST THAT LONG-TERM USE OF ART INDUCES COMORBID CONDITIONS AND IS ONE OF THE LEADING CAUSES OF HEART FAILURE IN PLWH. HOWEVER, THE MOLECULAR MECHANISM OF ANTIRETROVIRAL DRUGS (ARVS) INDUCED HEART FAILURE IS UNCLEAR. TO DETERMINE THE MECHANISM OF ARVS INDUCED CARDIAC DYSFUNCTION, WE PERFORMED GLOBAL TRANSCRIPTOMIC PROFILING OF ARVS TREATED NEONATAL RAT VENTRICULAR CARDIOMYOCYTES IN CULTURE. DIFFERENTIALLY EXPRESSED GENES WERE IDENTIFIED BY RNA-SEQUENCING. OUR DATA SHOW THAT ARVS TREATMENT CAUSES UPREGULATION OF SEVERAL BIOLOGICAL FUNCTIONS ASSOCIATED WITH CARDIOTOXICITY, HYPERTROPHY, AND HEART FAILURE. GLOBAL GENE EXPRESSION DATA WERE VALIDATED IN CARDIAC TISSUE ISOLATED FROM HIV PATIENTS HAVING A HISTORY OF ART. INTERESTINGLY, WE FOUND THAT HOMEODOMAIN-ONLY PROTEIN HOMEOBOX (HOPX) EXPRESSION WAS SIGNIFICANTLY INCREASED IN CARDIOMYOCYTES TREATED WITH ARVS AND IN THE HEART TISSUE OF HIV PATIENTS. FURTHERMORE, WE FOUND THAT HOPX PLAYS A CRUCIAL ROLE IN ARVS MEDIATED CELLULAR HYPERTROPHY. MECHANISTICALLY, WE FOUND THAT HOPX PLAYS A CRITICAL ROLE IN EPIGENETIC REGULATION, THROUGH DEACETYLATION OF HISTONE, WHILE THE HDAC INHIBITOR, TRICHOSTATIN A, CAN RESTORE THE ACETYLATION LEVEL OF HISTONE 3 IN THE PRESENCE OF ARVS. 2021 14 1743 28 EARLY EPIGENOMIC AND TRANSCRIPTIONAL CHANGES REVEAL ELK-1 TRANSCRIPTION FACTOR AS A THERAPEUTIC TARGET IN HUNTINGTON'S DISEASE. HUNTINGTON'S DISEASE (HD) IS A CHRONIC NEURODEGENERATIVE DISORDER CHARACTERIZED BY A LATE CLINICAL ONSET DESPITE UBIQUITOUS EXPRESSION OF THE MUTANT HUNTINGTIN GENE (HTT) FROM BIRTH. TRANSCRIPTIONAL DYSREGULATION IS A PIVOTAL FEATURE OF HD. YET, THE GENES THAT ARE ALTERED IN THE PRODROMAL PERIOD AND THEIR REGULATORS, WHICH PRESENT OPPORTUNITIES FOR THERAPEUTIC INTERVENTION, REMAIN TO BE ELUCIDATED. USING TRANSCRIPTIONAL AND CHROMATIN PROFILING, WE FOUND ABERRANT TRANSCRIPTION AND CHANGES IN HISTONE H3K27ACETYLATION IN THE STRIATUM OF R6/1 MICE DURING THE PRESYMPTOMATIC DISEASE STAGES. INTEGRATING THESE DATA, WE IDENTIFIED THE ELK-1 TRANSCRIPTION FACTOR AS A CANDIDATE REGULATOR OF PRODROMAL CHANGES IN HD. EXOGENOUS EXPRESSION OF ELK-1 EXERTED BENEFICIAL EFFECTS IN A PRIMARY STRIATAL CELL CULTURE MODEL OF HD, AND ADENO-ASSOCIATED VIRUS-MEDIATED ELK-1 OVEREXPRESSION ALLEVIATED TRANSCRIPTIONAL DYSREGULATION IN R6/1 MICE. COLLECTIVELY, OUR WORK DEMONSTRATES THAT ABERRANT GENE EXPRESSION PRECEDES OVERT DISEASE ONSET IN HD, IDENTIFIES THE ELK-1 TRANSCRIPTION FACTOR AS A KEY REGULATOR LINKED TO EARLY EPIGENETIC AND TRANSCRIPTIONAL CHANGES IN HD, AND PRESENTS EVIDENCE FOR ELK-1 AS A TARGET FOR ALLEVIATING MOLECULAR PATHOLOGY IN HD. 2019 15 1732 23 DYSTONIA AND LEVODOPA-INDUCED DYSKINESIAS IN PARKINSON'S DISEASE: IS THERE A CONNECTION? DYSTONIA AND LEVODOPA-INDUCED DYSKINESIA (LID) ARE BOTH HYPERKINETIC MOVEMENT DISORDERS. DYSTONIA ARISES MOST OFTEN SPONTANEOUSLY, ALTHOUGH IT MAY BE SEEN AFTER STROKE, INJURY, OR AS A RESULT OF GENETIC CAUSES. LID IS ASSOCIATED WITH PARKINSON'S DISEASE (PD), EMERGING AS A CONSEQUENCE OF CHRONIC THERAPY WITH LEVODOPA, AND MAY BE EITHER DYSTONIC OR CHOREIFORM. LID AND DYSTONIA SHARE IMPORTANT PHENOMENOLOGICAL PROPERTIES AND MECHANISMS. BOTH LID AND DYSTONIA ARE GENERATED BY AN INTEGRATED CIRCUIT INVOLVING THE CORTEX, BASAL GANGLIA, THALAMUS AND CEREBELLUM. THEY ALSO SHARE DYSREGULATION OF STRIATAL CHOLINERGIC SIGNALING AND ABNORMALITIES OF STRIATAL SYNAPTIC PLASTICITY. THE LONG DURATION NATURE OF BOTH LID AND DYSTONIA SUGGESTS THAT THERE MAY BE UNDERLYING EPIGENETIC DYSREGULATION AS A PROXIMATE CAUSE. WHILE BOTH MAY IMPROVE AFTER INTERVENTIONS SUCH AS DEEP BRAIN STIMULATION (DBS), NEITHER CURRENTLY HAS A SATISFACTORY MEDICAL THERAPY, AND MANY PEOPLE ARE DISABLED BY THE SYMPTOMS OF DYSTONIA AND LID. FURTHER STUDY OF THE FUNDAMENTAL MECHANISMS CONNECTING THESE TWO DISORDERS MAY LEAD TO NOVEL APPROACHES TO TREATMENT OR PREVENTION. 2019 16 5464 23 RESILIENCE IN LONG-TERM VIRAL INFECTION: GENETIC DETERMINANTS AND INTERACTIONS. VIRUS-INDUCED NEUROLOGICAL SEQUELAE RESULTING FROM INFECTION BY THEILER'S MURINE ENCEPHALOMYELITIS VIRUS (TMEV) ARE USED FOR STUDYING HUMAN CONDITIONS RANGING FROM EPILEPTIC SEIZURES TO DEMYELINATING DISEASE. MOUSE STRAINS ARE TYPICALLY CONSIDERED SUSCEPTIBLE OR RESISTANT TO TMEV INFECTION BASED ON VIRAL PERSISTENCE AND EXTREME PHENOTYPES, SUCH AS DEMYELINATION. WE HAVE IDENTIFIED A BROADER SPECTRUM OF PHENOTYPIC OUTCOMES BY INFECTING STRAINS OF THE GENETICALLY DIVERSE COLLABORATIVE CROSS (CC) MOUSE RESOURCE. WE EVALUATED THE CHRONIC-INFECTION GENE EXPRESSION PROFILES OF HIPPOCAMPI AND THORACIC SPINAL CORDS FOR 19 CC STRAINS IN RELATION TO PHENOTYPIC SEVERITY AND TMEV PERSISTENCE. STRAINS WERE CLUSTERED BASED ON SIMILAR PHENOTYPIC PROFILES AND TMEV LEVELS AT 90 DAYS POST-INFECTION, AND WE CATEGORIZED DISTINCT TMEV RESPONSE PROFILES. THE THREE MOST COMMON PROFILES INCLUDED "RESISTANT" AND "SUSCEPTIBLE," AS BEFORE, AS WELL AS A "RESILIENT" TMEV RESPONSE GROUP WHICH EXPERIENCED BOTH TMEV PERSISTENCE AND MILD NEUROLOGICAL PHENOTYPES EVEN AT 90 DAYS POST-INFECTION. EACH PROFILE HAD A DISTINCT GENE EXPRESSION SIGNATURE, ALLOWING THE IDENTIFICATION OF PATHWAYS AND NETWORKS SPECIFIC TO EACH TMEV RESPONSE GROUP. CC FOUNDER HAPLOTYPES FOR GENES INVOLVED IN THESE PATHWAYS/NETWORKS REVEALED CANDIDATE RESPONSE-SPECIFIC ALLELES. THESE ALLELES DEMONSTRATED PLEIOTROPY AND EPIGENETIC (MIRNA) REGULATION IN LONG-TERM TMEV INFECTION, WITH PARTICULAR RELEVANCE FOR RESILIENT MOUSE STRAINS. 2021 17 102 21 A REGULATORY ROLE FOR CHD2 IN MYELOPOIESIS. THE TRANSCRIPTIONAL PROGRAM THAT DICTATES HAEMATOPOIETIC CELL FATE AND DIFFERENTIATION REQUIRES AN EPIGENETIC REGULATORY AND MEMORY FUNCTION, PROVIDED BY A NETWORK OF EPIGENETIC FACTORS THAT REGULATE DNA METHYLATION, POST-TRANSLATIONAL HISTONE MODIFICATIONS AND CHROMATIN STRUCTURE. DISTURBED EPIGENETIC REGULATION CAUSES PERTURBATIONS IN THE BLOOD CELL DIFFERENTIATION PROGRAM THAT RESULTS IN VARIOUS TYPES OF HAEMATOPOIETIC DISORDERS. THUS, ACCURATE EPIGENETIC REGULATION IS ESSENTIAL FOR FUNCTIONAL HAEMATOPOIESIS. IN THIS STUDY, WE USED A CRISPR-CAS9 SCREENING APPROACH TO IDENTIFY NEW EPIGENETIC REGULATORS IN MYELOID DIFFERENTIATION. WE DESIGNED A CHROMATIN-UMI CRISPR GUIDE LIBRARY TARGETING 1092 EPIGENETIC REGULATORS. PHORBOL 12-MYRISTATE 13-ACETATE (PMA) TREATMENT OF THE CHRONIC MYELOID LEUKAEMIA CELL LINE K-562 WAS USED AS A MEGAKARYOCYTIC MYELOID DIFFERENTIATION MODEL. BOTH PREVIOUSLY DESCRIBED DEVELOPMENTAL EPIGENETIC REGULATORS AND NOVEL FACTORS WERE IDENTIFIED IN OUR SCREEN. IN THIS STUDY, WE VALIDATED AND CHARACTERIZED A ROLE FOR THE CHROMATIN REMODELLER CHD2 IN MYELOID PROLIFERATION AND MEGAKARYOCYTIC DIFFERENTIATION. 2020 18 5153 23 PPP2R2B HYPERMETHYLATION CAUSES ACQUIRED APOPTOSIS DEFICIENCY IN SYSTEMIC AUTOIMMUNE DISEASES. CHRONIC INFLAMMATION CAUSES TARGET ORGAN DAMAGE IN PATIENTS WITH SYSTEMIC AUTOIMMUNE DISEASES. THE FACTORS THAT ALLOW THIS PROTRACTED RESPONSE ARE POORLY UNDERSTOOD. WE ANALYZED THE TRANSCRIPTIONAL REGULATION OF PPP2R2B (B55SS), A MOLECULE NECESSARY FOR THE TERMINATION OF THE IMMUNE RESPONSE, IN PATIENTS WITH AUTOIMMUNE DISEASES. ALTERED EXPRESSION OF B55SS CONDITIONED RESISTANCE TO CYTOKINE WITHDRAWAL-INDUCED DEATH (CWID) IN PATIENTS WITH AUTOIMMUNE DISEASES. THE IMPAIRED UPREGULATION OF B55SS WAS CAUSED BY INFLAMMATION-DRIVEN HYPERMETHYLATION OF SPECIFIC CYTOSINES LOCATED WITHIN A REGULATORY ELEMENT OF PPP2R2B PREVENTING CTCF BINDING. THIS PHENOTYPE COULD BE INDUCED IN HEALTHY T CELLS BY EXPOSURE TO TNF-ALPHA. OUR RESULTS REVEAL A GENE WHOSE EXPRESSION IS AFFECTED BY AN ACQUIRED DEFECT, THROUGH AN EPIGENETIC MECHANISM, IN THE SETTING OF SYSTEMIC AUTOIMMUNITY. BECAUSE FAILURE TO REMOVE ACTIVATED T CELLS THROUGH CWID COULD CONTRIBUTE TO AUTOIMMUNE PATHOLOGY, THIS MECHANISM ILLUSTRATES A VICIOUS CYCLE THROUGH WHICH AUTOIMMUNE INFLAMMATION CONTRIBUTES TO ITS OWN PERPETUATION. 2019 19 2841 34 FREQUENCY OF THE DOPAMINE RECEPTOR D3 (RS6280) VS. OPIOID RECEPTOR MICRO1 (RS1799971) POLYMORPHIC RISK ALLELES IN PATIENTS WITH OPIOID USE DISORDER: A PREPONDERANCE OF DOPAMINERGIC MECHANISMS? WHILE OPIOIDS ARE A POWERFUL CLASS OF DRUGS THAT INHIBIT TRANSMISSION OF PAIN SIGNALS, THEIR USE IS TARNISHED BY THE CURRENT EPIDEMIC OF OPIOID USE DISORDER (OUD) AND OVERDOSE DEATHS. NOTWITHSTANDING PUBLISHED REPORTS, THERE REMAIN GAPS IN OUR KNOWLEDGE OF OPIOID RECEPTOR MECHANISMS AND THEIR ROLE IN OPIOID SEEKING BEHAVIOR. THUS, NOVEL INSIGHTS INTO MOLECULAR, NEUROGENETIC AND NEUROPHARMACOLOGICAL BASES OF OUD ARE NEEDED. WE PROPOSE THAT AN ADDICTIVE ENDOPHENOTYPE MAY NOT BE ENTIRELY SPECIFIC TO THE DRUG OF CHOICE BUT RATHER MAY BE GENERALIZABLE TO ALTERED BRAIN REWARD CIRCUITS IMPACTING NET MESOCORTICOLIMBIC DOPAMINE RELEASE. WE SUGGEST THAT GENETIC OR EPIGENETIC ALTERATIONS ACROSS DOPAMINERGIC REWARD SYSTEMS LEAD TO UNCONTROLLABLE SELF-ADMINISTRATION OF OPIOIDS AND OTHER DRUGS. FOR INSTANCE, DIMINISHED AVAILABILITY VIA KNOCKOUT OF DOPAMINE D3 RECEPTOR (DRD3) INCREASES VULNERABILITY TO OPIOIDS. BUILDING UPON THIS CONCEPT VIA THE USE OF A SOPHISTICATED POLYMORPHIC RISK ANALYSIS IN A HUMAN COHORT OF CHRONIC OPIOID USERS, WE FOUND EVIDENCE FOR A HIGHER FREQUENCY OF POLYMORPHIC DRD3 RISK ALLELE (RS6280) THAN OPIOID RECEPTOR MICRO1 (RS1799971). IN CONCLUSION, WHILE OPIOIDERGIC MECHANISMS ARE INVOLVED IN OUD, DOPAMINE-RELATED RECEPTORS MAY HAVE PRIMARY INFLUENCE ON OPIOID-SEEKING BEHAVIOR IN AFRICAN AMERICANS. THESE FINDINGS SUGGEST OUD-TARGETED NOVEL AND IMPROVED NEUROPHARMACOLOGICAL THERAPIES MAY REQUIRE FOCUS ON DRD3-MEDIATED REGULATION OF DOPAMINERGIC HOMEOSTASIS. 2022 20 5474 28 RESTORATION OF HISTONE ACETYLATION AMELIORATES DISEASE AND METABOLIC ABNORMALITIES IN A FUS MOUSE MODEL. DYSREGULATION OF EPIGENETIC MECHANISMS IS EMERGING AS A CENTRAL EVENT IN NEURODEGENERATIVE DISORDERS, INCLUDING AMYOTROPHIC LATERAL SCLEROSIS (ALS). IN MANY MODELS OF NEURODEGENERATION, GLOBAL HISTONE ACETYLATION IS DECREASED IN THE AFFECTED NEURONAL TISSUES. HISTONE ACETYLATION IS CONTROLLED BY THE ANTAGONISTIC ACTIONS OF TWO PROTEIN FAMILIES -THE HISTONE ACETYLTRANSFERASES (HATS) AND THE HISTONE DEACETYLASES (HDACS). DRUGS INHIBITING HDAC ACTIVITY ARE ALREADY USED IN THE CLINIC AS ANTI-CANCER AGENTS. THE AIM OF THIS STUDY WAS TO EXPLORE THE THERAPEUTIC POTENTIAL OF HDAC INHIBITION IN THE CONTEXT OF ALS. WE DISCOVERED THAT TRANSGENIC MICE OVEREXPRESSING WILD-TYPE FUS ("TG FUS+/+"), WHICH RECAPITULATE MANY ASPECTS OF HUMAN ALS, SHOWED REDUCED GLOBAL HISTONE ACETYLATION AND ALTERATIONS IN METABOLIC GENE EXPRESSION, RESULTING IN A DYSREGULATED METABOLIC HOMEOSTASIS. CHRONIC TREATMENT OF TG FUS+/+ MICE WITH ACY-738, A POTENT HDAC INHIBITOR THAT CAN CROSS THE BLOOD-BRAIN BARRIER, AMELIORATED THE MOTOR PHENOTYPE AND SUBSTANTIALLY EXTENDED THE LIFE SPAN OF THE TG FUS+/+ MICE. AT THE MOLECULAR LEVEL, ACY-738 RESTORED GLOBAL HISTONE ACETYLATION AND METABOLIC GENE EXPRESSION, THEREBY RE-ESTABLISHING METABOLITE LEVELS IN THE SPINAL CORD. TAKEN TOGETHER, OUR FINDINGS LINK EPIGENETIC ALTERATIONS TO METABOLIC DYSREGULATION IN ALS PATHOLOGY, AND HIGHLIGHT ACY-738 AS A POTENTIAL THERAPEUTIC STRATEGY TO TREAT THIS DEVASTATING DISEASE. 2019