1 784 90 CELL-SPECIFIC EXON METHYLATION AND CTCF BINDING IN NEURONS REGULATE CALCIUM ION CHANNEL SPLICING AND FUNCTION. CELL-SPECIFIC ALTERNATIVE SPLICING MODULATES MYRIAD CELL FUNCTIONS AND IS DISRUPTED IN DISEASE. THE MECHANISMS GOVERNING ALTERNATIVE SPLICING ARE KNOWN FOR RELATIVELY FEW GENES AND TYPICALLY FOCUS ON RNA SPLICING FACTORS. IN SENSORY NEURONS, CELL-SPECIFIC ALTERNATIVE SPLICING OF THE PRESYNAPTIC CA(V) CHANNEL CACNA1B GENE MODULATES OPIOID SENSITIVITY. HOW THIS SPLICING IS REGULATED IS UNKNOWN. WE FIND THAT CELL AND EXON-SPECIFIC DNA HYPOMETHYLATION PERMITS CTCF BINDING, THE MASTER REGULATOR OF MAMMALIAN CHROMATIN STRUCTURE, WHICH, IN TURN, CONTROLS SPLICING IN A DRG-DERIVED CELL LINE. IN VIVO, HYPOMETHYLATION OF AN ALTERNATIVE EXON SPECIFICALLY IN NOCICEPTORS, LIKELY PERMITS CTCF BINDING AND EXPRESSION OF CA(V)2.2 CHANNEL ISOFORMS WITH INCREASED OPIOID SENSITIVITY IN MICE. FOLLOWING NERVE INJURY, EXON METHYLATION IS INCREASED, AND SPLICING IS DISRUPTED. OUR STUDIES DEFINE THE MOLECULAR MECHANISMS OF CELL-SPECIFIC ALTERNATIVE SPLICING OF A FUNCTIONALLY VALIDATED EXON IN NORMAL AND DISEASE STATES - AND REVEAL A POTENTIAL TARGET FOR THE TREATMENT OF CHRONIC PAIN. 2020 2 3141 35 GLOBAL GENE EXPRESSION AND CHROMATIN ACCESSIBILITY OF THE PERIPHERAL NERVOUS SYSTEM IN ANIMAL MODELS OF PERSISTENT PAIN. BACKGROUND: EFFORTS TO UNDERSTAND GENETIC VARIABILITY INVOLVED IN AN INDIVIDUAL'S SUSCEPTIBILITY TO CHRONIC PAIN SUPPORT A ROLE FOR UPSTREAM REGULATION BY EPIGENETIC MECHANISMS. METHODS: TO EXAMINE THE TRANSCRIPTOMIC AND EPIGENETIC BASIS OF CHRONIC PAIN THAT RESIDES IN THE PERIPHERAL NERVOUS SYSTEM, WE USED RNA-SEQ AND ATAC-SEQ OF THE RAT DORSAL ROOT GANGLION (DRG) TO IDENTIFY NOVEL MOLECULAR PATHWAYS ASSOCIATED WITH PAIN HYPERSENSITIVITY IN TWO WELL-STUDIED PERSISTENT PAIN MODELS INDUCED BY CHRONIC CONSTRICTION INJURY (CCI) OF THE SCIATIC NERVE AND INTRA-PLANTAR INJECTION OF COMPLETE FREUND'S ADJUVANT (CFA) IN RATS. RESULTS: OUR RNA-SEQ STUDIES IDENTIFY A VARIETY OF BIOLOGICAL PROCESS RELATED TO SYNAPSE ORGANIZATION, MEMBRANE POTENTIAL, TRANSMEMBRANE TRANSPORT, AND ION BINDING. INTERESTINGLY, GENES THAT ENCODE TRANSCRIPTIONAL REGULATORS WERE DISPROPORTIONATELY DOWNREGULATED IN BOTH MODELS. OUR ATAC-SEQ DATA PROVIDE A COMPREHENSIVE MAP OF CHROMATIN ACCESSIBILITY CHANGES IN THE DRG. A TOTAL OF 1123 REGIONS SHOWED CHANGES IN CHROMATIN ACCESSIBILITY IN ONE OR BOTH MODELS WHEN COMPARED TO THE NAIVE AND 31 SHARED DIFFERENTIALLY ACCESSIBLE REGIONS (DAR)S. FUNCTIONAL ANNOTATION OF THE DARS IDENTIFIED DISPARATE MOLECULAR FUNCTIONS ENRICHED FOR EACH PAIN MODEL WHICH SUGGESTS THAT CHROMATIN STRUCTURE MAY BE ALTERED DIFFERENTLY FOLLOWING SCIATIC NERVE INJURY AND HIND PAW INFLAMMATION. MOTIF ANALYSIS IDENTIFIED 17 DNA SEQUENCES KNOWN TO BIND TRANSCRIPTION FACTORS IN THE CCI DARS AND 33 IN THE CFA DARS. TWO MOTIFS WERE SIGNIFICANTLY ENRICHED IN BOTH MODELS. CONCLUSIONS: OUR IMPROVED UNDERSTANDING OF THE CHANGES IN CHROMATIN ACCESSIBILITY THAT OCCUR IN CHRONIC PAIN STATES MAY IDENTIFY REGULATORY GENOMIC ELEMENTS THAT PLAY ESSENTIAL ROLES IN MODULATING GENE EXPRESSION IN THE DRG. 2021 3 3375 28 HISTONE POSTTRANSLATIONAL MODIFICATIONS PREDICT SPECIFIC ALTERNATIVE EXON SUBTYPES IN MAMMALIAN BRAIN. A COMPELLING BODY OF LITERATURE, BASED ON NEXT GENERATION CHROMATIN IMMUNOPRECIPITATION AND RNA SEQUENCING OF REWARD BRAIN REGIONS INDICATES THAT THE REGULATION OF THE EPIGENETIC LANDSCAPE LIKELY UNDERLIES CHRONIC DRUG ABUSE AND ADDICTION. IT IS NOW CRITICAL TO DEVELOP HIGHLY INNOVATIVE COMPUTATIONAL STRATEGIES TO REVEAL THE RELEVANT REGULATORY TRANSCRIPTIONAL MECHANISMS THAT MAY UNDERLIE NEUROPSYCHIATRIC DISEASE. WE HAVE ANALYZED CHROMATIN REGULATION OF ALTERNATIVE SPLICING, WHICH IS IMPLICATED IN COCAINE EXPOSURE IN MICE. RECENT LITERATURE HAS DESCRIBED CHROMATIN-REGULATED ALTERNATIVE SPLICING, SUGGESTING A NOVEL FUNCTION FOR DRUG-INDUCED NEUROEPIGENETIC REMODELING. HOWEVER, THE EXTENT OF THE GENOME-WIDE ASSOCIATION BETWEEN PARTICULAR HISTONE MODIFICATIONS AND ALTERNATIVE SPLICING REMAINS UNEXPLORED. TO ADDRESS THIS, WE HAVE DEVELOPED NOVEL COMPUTATIONAL APPROACHES TO MODEL THE ASSOCIATION BETWEEN ALTERNATIVE SPLICING AND HISTONE POSTTRANSLATIONAL MODIFICATIONS IN THE NUCLEUS ACCUMBENS (NAC), A BRAIN REWARD REGION. USING CLASSICAL STATISTICAL METHODS AND MACHINE LEARNING TO COMBINE CHIP-SEQ AND RNA-SEQ DATA, WE FOUND THAT SPECIFIC HISTONE MODIFICATIONS ARE STRONGLY ASSOCIATED WITH VARIOUS ASPECTS OF DIFFERENTIAL SPLICING. H3K36ME3 AND H3K4ME1 HAVE THE STRONGEST ASSOCIATION WITH SPLICING INDICATING THEY PLAY A SIGNIFICANT ROLE IN ALTERNATIVE SPLICING IN BRAIN REWARD TISSUE. 2017 4 2066 33 EPIGENETIC CONTROL OF ION CHANNEL EXPRESSION AND CELL-SPECIFIC SPLICING IN NOCICEPTORS: CHRONIC PAIN MECHANISMS AND POTENTIAL THERAPEUTIC TARGETS. ION CHANNELS UNDERLIE ALL FORMS FOR ELECTRICAL SIGNALING INCLUDING THE TRANSMISSION OF INFORMATION ABOUT HARMFUL EVENTS. VOLTAGE-GATED CALCIUM ION CHANNELS HAVE DUAL FUNCTION, THEY SUPPORT ELECTRICAL SIGNALING AS WELL AS INTRACELLULAR CALCIUM SIGNALING THROUGH EXCITATION-DEPENDENT CALCIUM ENTRY ACROSS THE PLASMA MEMBRANE. MECHANISMS THAT REGULATE ION CHANNEL FORMS AND ACTIONS ARE ESSENTIAL FOR MYRIAD CELL FUNCTIONS AND THESE ARE TARGETED BY DRUGS AND THERAPEUTICS. WHEN DISRUPTED, THE CELLULAR MECHANISMS THAT CONTROL ION CHANNEL ACTIVITY CAN CONTRIBUTE TO DISEASE PATHOPHYSIOLOGY. FOR EXAMPLE, ALTERNATIVE PRE-MRNA SPLICING IS A MAJOR STEP IN DEFINING THE PRECISE COMPOSITION OF THE TRANSCRIPTOME ACROSS DIFFERENT CELL TYPES FROM EARLY CELLULAR DIFFERENTIATION TO PROGRAMMED APOPTOSIS. AN ESTIMATED 30% OF DISEASE-CAUSING MUTATIONS ARE ASSOCIATED WITH ALTERED ALTERNATIVE SPLICING, AND MIS-SPLICING IS A FEATURE OF NUMEROUS HIGHLY PREVALENT DISEASES INCLUDING NEURODEGENERATIVE, CANCER, AND CHRONIC PAIN. HERE WE DISCUSS THE IMPORTANT ROLE OF EPIGENETIC REGULATION OF GENE EXPRESSION AND CELL-SPECIFIC ALTERNATIVE SPLICING OF CALCIUM ION CHANNELS IN NOCICEPTORS, WITH EMPHASIS ON HOW THESE PROCESSES ARE DISRUPTED IN CHRONIC PAIN, THE POTENTIAL THERAPEUTIC BENEFIT OF CORRECTING OR COMPENSATING FOR ABERRANT ION CHANNEL SPLICING IN CHRONIC PAIN. 2021 5 883 31 CHRONIC COCAINE-REGULATED EPIGENOMIC CHANGES IN MOUSE NUCLEUS ACCUMBENS. BACKGROUND: INCREASING EVIDENCE SUPPORTS A ROLE FOR ALTERED GENE EXPRESSION IN MEDIATING THE LASTING EFFECTS OF COCAINE ON THE BRAIN, AND RECENT WORK HAS DEMONSTRATED THE INVOLVEMENT OF CHROMATIN MODIFICATIONS IN THESE ALTERATIONS. HOWEVER, ALL SUCH STUDIES TO DATE HAVE BEEN RESTRICTED BY THEIR RELIANCE ON MICROARRAY TECHNOLOGIES THAT HAVE INTRINSIC LIMITATIONS. RESULTS: WE USE NEXT GENERATION SEQUENCING METHODS, RNA-SEQ AND CHIP-SEQ FOR RNA POLYMERASE II AND SEVERAL HISTONE METHYLATION MARKS, TO OBTAIN A MORE COMPLETE VIEW OF COCAINE-INDUCED CHANGES IN GENE EXPRESSION AND ASSOCIATED ADAPTATIONS IN NUMEROUS MODES OF CHROMATIN REGULATION IN THE MOUSE NUCLEUS ACCUMBENS, A KEY BRAIN REWARD REGION. WE DEMONSTRATE AN UNEXPECTEDLY LARGE NUMBER OF PRE-MRNA SPLICING ALTERATIONS IN RESPONSE TO REPEATED COCAINE TREATMENT. IN ADDITION, WE IDENTIFY COMBINATIONS OF CHROMATIN CHANGES, OR SIGNATURES, THAT CORRELATE WITH COCAINE-DEPENDENT REGULATION OF GENE EXPRESSION, INCLUDING THOSE INVOLVING PRE-MRNA ALTERNATIVE SPLICING. THROUGH BIOINFORMATIC PREDICTION AND BIOLOGICAL VALIDATION, WE IDENTIFY ONE PARTICULAR SPLICING FACTOR, A2BP1(RBFOX1/FOX-1), WHICH IS ENRICHED AT GENES THAT DISPLAY CERTAIN CHROMATIN SIGNATURES AND CONTRIBUTES TO DRUG-INDUCED BEHAVIORAL ABNORMALITIES. TOGETHER, THIS DELINEATION OF THE COCAINE-INDUCED EPIGENOME IN THE NUCLEUS ACCUMBENS REVEALS SEVERAL NOVEL MODES OF REGULATION BY WHICH COCAINE ALTERS THE BRAIN. CONCLUSIONS: WE ESTABLISH COMBINATORIAL CHROMATIN AND TRANSCRIPTIONAL PROFILES IN MOUSE NUCLEUS ACCUMBENS AFTER REPEATED COCAINE TREATMENT. THESE RESULTS SERVE AS AN IMPORTANT RESOURCE FOR THE FIELD AND PROVIDE A TEMPLATE FOR THE ANALYSIS OF OTHER SYSTEMS TO REVEAL NEW TRANSCRIPTIONAL AND EPIGENETIC MECHANISMS OF NEURONAL REGULATION. 2014 6 405 26 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 7 4604 28 NEGATIVE EVIDENCE FOR A FUNCTIONAL ROLE OF NEURONAL DNMT3A IN PERSISTENT PAIN. TRADITIONALLY, NEUROSCIENCE HAS HAD TO RELY ON MIXED TISSUE ANALYSIS TO EXAMINE TRANSCRIPTIONAL AND EPIGENETIC CHANGES IN THE CONTEXT OF NERVOUS SYSTEM FUNCTION OR PATHOLOGY. HOWEVER, PARTICULARLY WHEN STUDYING CHRONIC PAIN CONDITIONS, THIS APPROACH CAN BE FLAWED, SINCE IT NEGLECTS TO TAKE INTO ACCOUNT THE SHIFTING CONTRIBUTION OF DIFFERENT CELL TYPES ACROSS EXPERIMENTAL CONDITIONS. HERE, WE DEMONSTRATE THIS USING THE EXAMPLE OF DNA METHYLTRANSFERASES (DNMTS) - A GROUP OF EPIGENETIC MODIFIERS CONSISTING OF DNMT1, DNMT3A, AND DNMT3B IN MAMMALIAN CELLS. WE USED SENSORY NEURON-SPECIFIC KNOCKOUT MICE FOR DNMT3A/3B AS WELL AS PHARMACOLOGICAL BLOCKADE OF DNMT1 TO STUDY THEIR ROLE IN NOCICEPTION. IN CONTRAST TO PREVIOUS ANALYSES ON WHOLE TISSUE, WE FIND THAT DNMT3A AND 3B PROTEIN IS NOT EXPRESSED IN ADULT DRG NEURONS, THAT NONE OF THE DNA METHYLTRANSFERASES ARE REGULATED WITH INJURY AND THAT INTERFERING WITH THEIR FUNCTION HAS NO EFFECT ON NOCICEPTION. OUR RESULTS THEREFORE CURRENTLY DO NOT SUPPORT A ROLE FOR NEURONAL DNA METHYLTRANSFERASES IN PAIN PROCESSING IN ADULT ANIMALS. 2018 8 5626 27 SELECTIVE REPRESSION OF GENE EXPRESSION IN NEUROPATHIC PAIN BY THE NEURON-RESTRICTIVE SILENCING FACTOR/REPRESSOR ELEMENT-1 SILENCING TRANSCRIPTION (NRSF/REST). NEUROPATHIC PAIN OFTEN DEVELOPS FOLLOWING NERVE INJURY AS A RESULT OF MALADAPTIVE CHANGES THAT OCCUR IN THE INJURED NERVE AND ALONG THE NOCICEPTIVE PATHWAYS OF THE PERIPHERAL AND CENTRAL NERVOUS SYSTEMS. MULTIPLE CELLULAR AND MOLECULAR MECHANISMS LIKELY ACCOUNT FOR THESE CHANGES; HOWEVER, THE EXACT NATURE OF THESE MECHANISMS REMAIN LARGELY UNKNOWN. A GROWING NUMBER OF STUDIES SUGGEST THAT ALTERATION IN GENE EXPRESSION IS AN IMPORTANT STEP IN THE PROGRESSION FROM ACUTE TO CHRONIC PAIN STATES AND EPIGENETIC REGULATION HAS BEEN PROPOSED TO DRIVE THIS CHANGE IN GENE EXPRESSION. IN THIS REVIEW, WE DISCUSS RECENT EVIDENCE THAT THE DNA-BINDING PROTEIN NEURON-RESTRICTIVE SILENCING FACTOR/REPRESSOR ELEMENT-1 SILENCING TRANSCRIPTION FACTOR (NRSF/REST) IS AN IMPORTANT COMPONENT IN THE DEVELOPMENT AND MAINTENANCE OF NEUROPATHIC PAIN THROUGH ITS ROLE AS A TRANSCRIPTIONAL REGULATOR FOR A SELECT SUBSET OF GENES THAT IT NORMALLY REPRESSES DURING DEVELOPMENT. 2016 9 3754 26 INTEGRATED ANALYSIS OF OMICS DATA REVEAL AP-1 AS A POTENTIAL REGULATION HUB IN THE INFLAMMATION-INDUCED HYPERALGESIA RAT MODEL. INFLAMMATION-ASSOCIATED CHRONIC PAIN IS A GLOBAL CLINICAL PROBLEM, AFFECTING MILLIONS OF PEOPLE WORLDWIDE. HOWEVER, THE UNDERLYING MECHANISMS THAT MEDIATE INFLAMMATION-ASSOCIATED CHRONIC PAIN REMAIN UNCLEAR. A RAT MODEL OF CUTANEOUS INFLAMMATION INDUCED BY COMPLETE FREUND'S ADJUVANT (CFA) HAS BEEN WIDELY USED AS AN INFLAMMATION-INDUCED PAIN HYPERSENSITIVITY MODEL. WE PRESENT THE TRANSCRIPTOMICS PROFILE OF CFA-INDUCED INFLAMMATION IN THE RAT DORSAL ROOT GANGLION (DRG) VIA AN APPROACH THAT TARGETS GENE EXPRESSION, DNA METHYLATION, AND POST-TRANSCRIPTIONAL REGULATION. WE IDENTIFIED 418 DIFFERENTIALLY EXPRESSED MRNAS, 120 DIFFERENTIALLY EXPRESSED MICRORNAS (MIRNAS), AND 2,670 DIFFERENTIALLY METHYLATED REGIONS (DMRS), WHICH WERE ALL HIGHLY ASSOCIATED WITH MULTIPLE INFLAMMATION-RELATED PATHWAYS, INCLUDING NUCLEAR FACTOR KAPPA B (NF-KAPPAB) AND INTERFERON (IFN) SIGNALING PATHWAYS. AN INTEGRATED ANALYSIS FURTHER DEMONSTRATED THAT THE ACTIVATOR PROTEIN 1 (AP-1) NETWORK, WHICH MAY ACT AS A REGULATOR OF THE INFLAMMATORY RESPONSE, IS REGULATED AT BOTH THE TRANSCRIPTOMIC AND EPIGENETIC LEVELS. WE BELIEVE OUR DATA WILL NOT ONLY PROVIDE DRUG SCREENING TARGETS FOR THE TREATMENT OF CHRONIC PAIN AND INFLAMMATION BUT WILL ALSO SHED LIGHT ON THE MOLECULAR NETWORK ASSOCIATED WITH INFLAMMATION-INDUCED HYPERALGESIA. 2021 10 1562 25 DNA METHYLATION OF ENHANCER ELEMENTS IN MYELOID NEOPLASMS: THINK OUTSIDE THE PROMOTERS? GENE REGULATION THROUGH DNA METHYLATION IS A WELL DESCRIBED PHENOMENON THAT HAS A PROMINENT ROLE IN PHYSIOLOGICAL AND PATHOLOGICAL CELL-STATES. THIS EPIGENETIC MODIFICATION IS USUALLY GROUPED IN REGIONS DENOMINATED CPG ISLANDS, WHICH FREQUENTLY CO-LOCALIZE WITH GENE PROMOTERS, SILENCING THE TRANSCRIPTION OF THOSE GENES. RECENT GENOME-WIDE DNA METHYLATION STUDIES HAVE CHALLENGED THIS PARADIGM, DEMONSTRATING THAT DNA METHYLATION OF REGULATORY REGIONS OUTSIDE PROMOTERS IS ABLE TO INFLUENCE CELL-TYPE SPECIFIC GENE EXPRESSION PROGRAMS UNDER PHYSIOLOGIC OR PATHOLOGIC CONDITIONS. COUPLING GENOME-WIDE DNA METHYLATION ASSAYS WITH HISTONE MARK ANNOTATION HAS ALLOWED FOR THE IDENTIFICATION OF SPECIFIC EPIGENOMIC CHANGES THAT AFFECT ENHANCER REGULATORY REGIONS, REVEALING AN ADDITIONAL LAYER OF COMPLEXITY TO THE EPIGENETIC REGULATION OF GENE EXPRESSION. IN THIS REVIEW, WE SUMMARIZE THE NOVEL EVIDENCE FOR THE MOLECULAR AND BIOLOGICAL REGULATION OF DNA METHYLATION IN ENHANCER REGIONS AND THE DYNAMISM OF THESE CHANGES CONTRIBUTING TO THE FINE-TUNING OF GENE EXPRESSION. WE ALSO ANALYZE THE CONTRIBUTION OF ENHANCER DNA METHYLATION ON THE EXPRESSION OF RELEVANT GENES IN ACUTE MYELOID LEUKEMIA AND CHRONIC MYELOPROLIFERATIVE NEOPLASMS. THE CHARACTERIZATION OF THE ABERRANT ENHANCER DNA METHYLATION PROVIDES NOT ONLY A NOVEL PATHOGENIC MECHANISM FOR DIFFERENT TUMORS BUT ALSO HIGHLIGHTS NOVEL POTENTIAL THERAPEUTIC TARGETS FOR MYELOID DERIVED NEOPLASMS. 2019 11 2280 29 EPIGENETIC REGULATION IN DRUG ADDICTION. THE INTERACTION BETWEEN ENVIRONMENTAL SIGNALS AND GENES HAS NOW TAKEN ON A CLEAR MOLECULAR FORM AS DEMONSTRATED BY STABLE CHANGES IN CHROMATIN STRUCTURE. THESE CHANGES OCCUR THROUGH ACTIVATION OR REPRESSION OF SPECIFIC GENE PROGRAMMES BY A COMBINATION OF CHROMATIN REMODELLING, ACTIVATION AND ENZYMATIC MODIFICATION OF DNA AND HISTONES AS WELL AS NUCLEOSOMAL SUBUNIT EXCHANGE. RECENT RESEARCH INVESTIGATING THE MOLECULAR MECHANISMS CONTROLLING DRUG-INDUCED TRANSCRIPTIONAL, BEHAVIOURAL AND SYNAPTIC ACTIVITY HAS SHOWN A DIRECT ROLE FOR CHROMATIN REMODELLING--TERMED AS EPIGENETIC REGULATION--OF NEURONAL GENE PROGRAMMES AND SUBSEQUENT ADDICTIVE BEHAVIOUR ARISING FROM IT. RECENT DATA SUGGEST THAT REPEATED EXPOSURE TO CERTAIN DRUGS PROMOTES CHANGES IN LEVELS OF HISTONE ACETYLATION, PHOSPHORYLATION AND METHYLATION, TOGETHER WITH ALTERATIONS IN DNA METHYLATION LEVELS IN THE NEURONS OF THE BRAIN REWARD CENTRE, LOCALISED IN THE NUCLEUS ACCUMBENS (NAC) REGION OF THE LIMBIC SYSTEM. THE COMBINATION OF ACETYLATING, PHOSPHORYLATING AND METHYLATING H3 AND H4 HISTONE TAILS ALTER CHROMATIN COMPACTION THEREBY PROMOTING ALTERED LEVELS OF CELLULAR GENE EXPRESSION. HISTONE MODIFICATIONS, WHICH WEAKEN HISTONE INTERACTION WITH DNA OR THAT PROMOTE RECRUITMENT OF TRANSCRIPTIONAL ACTIVATING COMPLEXES, CORRELATE WITH PERMISSIVE GENE EXPRESSION. HISTONE DEACETYLATION, (WHICH STRENGTHEN HISTONE: DNA CONTACTS), OR HISTONE METHYLATION, (WHICH RECRUITS REPRESSIVE COMPLEXES TO CHROMATIN), PROMOTE A STATE OF TRANSCRIPTIONAL REPRESSION. USING ANIMAL MODELS, ACUTE COCAINE TREATMENT INCREASES H4 ACETYLATION AT ACUTELY REGULATED GENE PROMOTERS, WHEREAS H3 ACETYLATION APPEARS TO PREDOMINATE AT CHRONICALLY INDUCED PROMOTERS. CHRONIC COCAINE AND ALCOHOL TREATMENT ACTIVATE AND REPRESS MANY GENES SUCH AS FOSB, CDK5, AND BDNF, WHERE THEIR DYSREGULATION, AT THE CHROMATIN LEVEL, CONTRIBUTE TO THE DEVELOPMENT AND MAINTENANCE OF ADDICTION. FOLLOWING DRUG EXPOSURE, IT IS STILL UNKNOWN, HOWVER, HOW LONG THESE CHANGES IN CHROMATIN STRUCTURE PERSIST IN AFFECTING NEURONAL FUNCTION, BUT SOME DO SO FOR LIFE. 2012 12 1336 24 DESCRIBING A TRANSCRIPTION FACTOR DEPENDENT REGULATION OF THE MICRORNA TRANSCRIPTOME. WHILE THE TRANSCRIPTION REGULATION OF PROTEIN CODING GENES WAS EXTENSIVELY STUDIED, LITTLE IS KNOWN ON HOW TRANSCRIPTION FACTORS ARE INVOLVED IN TRANSCRIPTION OF NON-CODING RNAS, SPECIFICALLY OF MICRORNAS. HERE, WE PROPOSE A STRATEGY TO STUDY THE POTENTIAL ROLE OF TRANSCRIPTION FACTOR IN REGULATING TRANSCRIPTION OF MICRORNAS USING PUBLICALLY AVAILABLE DATA, COMPUTATIONAL RESOURCES AND HIGH THROUGHPUT DATA. WE USE THE H3K4ME3 EPIGENETIC SIGNATURE TO IDENTIFY MICRORNA PROMOTERS AND CHROMATIN IMMUNOPRECIPITATION (CHIP)-SEQUENCING DATA FROM THE ENCODE PROJECT TO IDENTIFY MICRORNA PROMOTERS THAT ARE ENRICHED WITH TRANSCRIPTION FACTOR BINDING SITES. BY TRANSFECTING CELLS OF INTEREST WITH SHRNA TARGETING A TRANSCRIPTION FACTOR OF INTEREST AND SUBJECTING THE CELLS TO MICRORNA ARRAY, WE STUDY THE EFFECT OF THIS TRANSCRIPTION FACTOR ON THE MICRORNA TRANSCRIPTOME. AS AN ILLUSTRATIVE EXAMPLE WE USE OUR STUDY ON THE EFFECT OF STAT3 ON THE MICRORNA TRANSCRIPTOME OF CHRONIC LYMPHOCYTIC LEUKEMIA (CLL) CELLS. 2016 13 226 29 ACUTE TRANSCRIPTOMIC AND EPIGENETIC ALTERATIONS AT T12 AFTER RAT T10 SPINAL CORD CONTUSIVE INJURY. SPINAL CORD INJURY IS A SEVERELY DEBILITATING CONDITION AFFECTING A SIGNIFICANT POPULATION IN THE USA. SPINAL CORD INJURY PATIENTS OFTEN HAVE INCREASED RISK OF DEVELOPING PERSISTENT NEUROPATHIC PAIN AND OTHER NEURODEGENERATIVE CONDITIONS BEYOND THE PRIMARY LESION CENTER LATER IN THEIR LIFE. THE MOLECULAR MECHANISM CONFERRING TO THE "LATENT" DAMAGES AT DISTAL TISSUES, HOWEVER, REMAINS ELUSIVE. HERE, WE STUDIED MOLECULAR CHANGES CONFERRING ABNORMAL FUNCTIONALITY AT DISTAL SPINAL CORD (T12) BEYOND THE LESION CENTER (T10) BY COMBINING NEXT-GENERATION SEQUENCING (RNA- AND BISULFITE SEQUENCING), SUPER-RESOLUTION MICROSCOPY, AND IMMUNOFLUORESCENCE STAINING AT 7 DAYS POST INJURY. WE OBSERVED SIGNIFICANT TRANSCRIPTOMIC CHANGES PRIMARILY ENRICHED IN NEUROINFLAMMATION AND SYNAPTOGENESIS ASSOCIATED PATHWAYS. TRANSCRIPTION FACTORS (TFS) THAT REGULATE NEUROGENESIS AND NEURON PLASTICITY, INCLUDING EGR1, KLF4, AND MYC, ARE SIGNIFICANTLY UPREGULATED. ALONG WITH GLOBAL CHANGES IN CHROMATIN ARRANGEMENTS AND DNA METHYLATION, INCLUDING 5-METHYLCYTOSINE (5MC) AND 5-HYDROXYMETHYLCYTOSINE (5HMC), BISULFITE SEQUENCING FURTHER REVEALS THE INVOLVEMENT OF DNA METHYLATION CHANGES IN REGULATING CYTOKINE, GROWTH FACTOR, AND ION CHANNEL EXPRESSION. COLLECTIVELY, OUR RESULTS PAVE THE WAY TOWARDS UNDERSTANDING TRANSCRIPTOMIC AND EPIGENOMIC MECHANISM IN CONFERRING LONG-TERM DISEASE RISKS AT DISTAL TISSUES AWAY FROM THE PRIMARY LESION CENTER AND SHED LIGHT ON POTENTIAL MOLECULAR TARGETS THAT GOVERN THE REGULATORY MECHANISM AT DISTAL SPINAL CORD TISSUES. 2023 14 5007 31 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 15 2055 22 EPIGENETIC CONTROL DURING LYMPHOID DEVELOPMENT AND IMMUNE RESPONSES: ABERRANT REGULATION, VIRUSES, AND CANCER. METHYLATION OF CYTOSINES CONTROLS A NUMBER OF BIOLOGIC PROCESSES SUCH AS IMPRINTING AND X CHROMOSOMAL INACTIVATION. DNA HYPERMETHYLATION IS CLOSELY ASSOCIATED WITH TRANSCRIPTIONAL SILENCING, WHILE DNA HYPOMETHYLATION IS ASSOCIATED WITH TRANSCRIPTIONAL ACTIVATION. HYPOACETYLATION OF HISTONES LEADS TO COMPACT CHROMATIN WITH REDUCED ACCESSIBILITY TO THE TRANSCRIPTIONAL MACHINERY. METHYL-CPG BINDING PROTEINS CAN RECRUIT COREPRESSORS AND HISTONE DEACETYLASES; THUS, THE INTERPLAY BETWEEN THESE EPIGENETIC MECHANISMS REGULATES GENE ACTIVATION. METHYLATION HAS BEEN IMPLICATED AS AN IMPORTANT MECHANISM DURING IMMUNE DEVELOPMENT, CONTROLLING VDJ RECOMBINATION, LINEAGE-SPECIFIC EXPRESSION OF CELL SURFACE ANTIGENS, AND TRANSCRIPTIONAL REGULATION OF CYTOKINE GENES DURING IMMUNE RESPONSES. ABERRATIONS IN EPIGENETIC MACHINERY, EITHER BY GENETIC MUTATIONS OR BY SOMATIC CHANGES SUCH AS VIRAL INFECTIONS, ARE ASSOCIATED WITH EARLY ALTERATIONS IN CHRONIC DISEASES SUCH AS IMMUNODEFICIENCY AND CANCER. 2003 16 6517 23 TRANSCRIPTIONAL AND EPIGENETIC MECHANISMS OF ADDICTION. INVESTIGATIONS OF LONG-TERM CHANGES IN BRAIN STRUCTURE AND FUNCTION THAT ACCOMPANY CHRONIC EXPOSURE TO DRUGS OF ABUSE SUGGEST THAT ALTERATIONS IN GENE REGULATION CONTRIBUTE SUBSTANTIALLY TO THE ADDICTIVE PHENOTYPE. HERE, WE REVIEW MULTIPLE MECHANISMS BY WHICH DRUGS ALTER THE TRANSCRIPTIONAL POTENTIAL OF GENES. THESE MECHANISMS RANGE FROM THE MOBILIZATION OR REPRESSION OF THE TRANSCRIPTIONAL MACHINERY - INCLUDING THE TRANSCRIPTION FACTORS DELTAFOSB, CYCLIC AMP-RESPONSIVE ELEMENT BINDING PROTEIN (CREB) AND NUCLEAR FACTOR-KAPPAB (NF-KAPPAB) - TO EPIGENETICS - INCLUDING ALTERATIONS IN THE ACCESSIBILITY OF GENES WITHIN THEIR NATIVE CHROMATIN STRUCTURE INDUCED BY HISTONE TAIL MODIFICATIONS AND DNA METHYLATION, AND THE REGULATION OF GENE EXPRESSION BY NON-CODING RNAS. INCREASING EVIDENCE IMPLICATES THESE VARIOUS MECHANISMS OF GENE REGULATION IN THE LASTING CHANGES THAT DRUGS OF ABUSE INDUCE IN THE BRAIN, AND OFFERS NOVEL INROADS FOR ADDICTION THERAPY. 2011 17 3072 33 GENOME-WIDE DNA METHYLATION REPROGRAMMING IN RESPONSE TO INORGANIC ARSENIC LINKS INHIBITION OF CTCF BINDING, DNMT EXPRESSION AND CELLULAR TRANSFORMATION. CHRONIC LOW DOSE INORGANIC ARSENIC (IAS) EXPOSURE LEADS TO CHANGES IN GENE EXPRESSION AND EPITHELIAL-TO-MESENCHYMAL TRANSFORMATION. DURING THIS TRANSFORMATION, CELLS ADOPT A FIBROBLAST-LIKE PHENOTYPE ACCOMPANIED BY PROFOUND GENE EXPRESSION CHANGES. WHILE MANY MECHANISMS HAVE BEEN IMPLICATED IN THIS TRANSFORMATION, STUDIES THAT FOCUS ON THE ROLE OF EPIGENETIC ALTERATIONS IN THIS PROCESS ARE JUST EMERGING. DNA METHYLATION CONTROLS GENE EXPRESSION IN PHYSIOLOGIC AND PATHOLOGIC STATES. SEVERAL STUDIES SHOW ALTERATIONS IN DNA METHYLATION PATTERNS IN IAS-MEDIATED PATHOGENESIS, BUT THESE STUDIES FOCUSED ON SINGLE GENES. WE PRESENT A COMPREHENSIVE GENOME-WIDE DNA METHYLATION ANALYSIS USING METHYL-SEQUENCING TO MEASURE CHANGES BETWEEN NORMAL AND IAS-TRANSFORMED CELLS. ADDITIONALLY, THESE DIFFERENTIAL METHYLATION CHANGES CORRELATED POSITIVELY WITH CHANGES IN GENE EXPRESSION AND ALTERNATIVE SPLICING. INTERESTINGLY, MOST OF THESE DIFFERENTIALLY METHYLATED GENES FUNCTION IN CELL ADHESION AND COMMUNICATION PATHWAYS. TO GAIN INSIGHT INTO HOW GENOMIC DNA METHYLATION PATTERNS ARE REGULATED DURING IAS-MEDIATED CARCINOGENESIS, WE SHOW THAT IAS PROBABLY TARGETS CTCF BINDING AT THE PROMOTER OF DNA METHYLTRANSFERASES, REGULATING THEIR EXPRESSION. THESE FINDINGS REVEAL HOW CTCF BINDING REGULATES DNA METHYLTRANSFERASE TO REPROGRAM THE METHYLOME IN RESPONSE TO AN ENVIRONMENTAL TOXIN. 2017 18 2442 21 EPIGENETIC STABILITY IN THE ADULT MOUSE CORTEX UNDER CONDITIONS OF PHARMACOLOGICALLY INDUCED HISTONE ACETYLATION. HISTONE ACETYLATION IS CONSIDERED A MAJOR EPIGENETIC PROCESS THAT AFFECTS BRAIN DEVELOPMENT AND SYNAPTIC PLASTICITY, AS WELL AS LEARNING AND MEMORY. THE TRANSCRIPTIONAL EFFECTORS AND MORPHOLOGICAL CHANGES RESPONSIBLE FOR PLASTICITY AS A RESULT OF LONG-TERM MODIFICATIONS TO HISTONE ACETYLATION ARE NOT FULLY UNDERSTOOD. TO THIS END, WE PHARMACOLOGICALLY INHIBITED HISTONE DEACETYLATION USING TRICHOSTATIN A IN ADULT (6-MONTH-OLD) MICE AND FOUND SIGNIFICANT INCREASES IN THE LEVELS OF THE ACETYLATED HISTONE MARKS H3LYS9, H3LYS14 AND H4LYS12. HIGH-RESOLUTION TRANSCRIPTOME ANALYSIS OF DIVERSE BRAIN REGIONS UNCOVERED FEW DIFFERENCES IN GENE EXPRESSION BETWEEN TREATED AND CONTROL ANIMALS, NONE OF WHICH WERE PLASTICITY RELATED. INSTEAD, AFTER INCREASED HISTONE ACETYLATION, WE DETECTED A LARGE NUMBER OF NOVEL TRANSCRIPTIONALLY ACTIVE REGIONS, WHICH CORRESPOND TO LONG NON-CODING RNAS (LNCRNAS). WE ALSO SURPRISINGLY FOUND NO SIGNIFICANT CHANGES IN DENDRITIC SPINE PLASTICITY IN LAYERS 1 AND 2/3 OF THE VISUAL CORTEX USING LONG-TERM IN VIVO TWO-PHOTON IMAGING. OUR RESULTS INDICATE THAT CHRONIC PHARMACOLOGICALLY INDUCED HISTONE ACETYLATION CAN BE DECOUPLED FROM GENE EXPRESSION AND INSTEAD, MAY POTENTIALLY EXERT A POST-TRANSCRIPTIONAL EFFECT THROUGH THE DIFFERENTIAL PRODUCTION OF LNCRNAS. 2016 19 2354 17 EPIGENETIC REGULATION OF PERSISTENT PAIN. PERSISTENT OR CHRONIC PAIN IS TIGHTLY ASSOCIATED WITH VARIOUS ENVIRONMENTAL CHANGES AND LINKED TO ABNORMAL GENE EXPRESSION WITHIN CELLS PROCESSING NOCICEPTIVE SIGNALING. EPIGENETIC REGULATION GOVERNS GENE EXPRESSION IN RESPONSE TO ENVIRONMENTAL CUES. RECENT ANIMAL MODEL AND CLINICAL STUDIES INDICATE THAT EPIGENETIC REGULATION PLAYS AN IMPORTANT ROLE IN THE DEVELOPMENT OR MAINTENANCE OF PERSISTENT PAIN AND POSSIBLY THE TRANSITION OF ACUTE PAIN TO CHRONIC PAIN, THUS SHEDDING LIGHT IN A DIRECTION FOR DEVELOPMENT OF NEW THERAPEUTICS FOR PERSISTENT PAIN. 2015 20 6427 27 THE TRANSITION FROM ACUTE TO CHRONIC PAIN: DYNAMIC EPIGENETIC REPROGRAMMING OF THE MOUSE PREFRONTAL CORTEX UP TO 1 YEAR AFTER NERVE INJURY. CHRONIC PAIN IS ASSOCIATED WITH PERSISTENT STRUCTURAL AND FUNCTIONAL CHANGES THROUGHOUT THE NEUROAXIS, INCLUDING IN THE PREFRONTAL CORTEX (PFC). THE PFC IS IMPORTANT IN THE INTEGRATION OF SENSORY, COGNITIVE, AND EMOTIONAL INFORMATION AND IN CONDITIONED PAIN MODULATION. WE PREVIOUSLY REPORTED WIDESPREAD EPIGENETIC REPROGRAMMING IN THE PFC MANY MONTHS AFTER NERVE INJURY IN RODENTS. EPIGENETIC MODIFICATIONS, INCLUDING DNA METHYLATION, CAN DRIVE CHANGES IN GENE EXPRESSION WITHOUT MODIFYING DNA SEQUENCES. TO DATE, LITTLE IS KNOWN ABOUT EPIGENETIC DYSREGULATION AT THE ONSET OF ACUTE PAIN OR HOW IT PROGRESSES AS PAIN TRANSITIONS FROM ACUTE TO CHRONIC. WE HYPOTHESIZE THAT ACUTE PAIN AFTER INJURY RESULTS IN RAPID AND PERSISTENT EPIGENETIC REMODELLING IN THE PFC THAT EVOLVES AS PAIN BECOMES CHRONIC. WE FURTHER PROPOSE THAT UNDERSTANDING EPIGENETIC REMODELLING WILL PROVIDE INSIGHTS INTO THE MECHANISMS DRIVING PAIN-RELATED CHANGES IN THE BRAIN. EPIGENOME-WIDE ANALYSIS WAS PERFORMED IN THE MOUSE PFC 1 DAY, 2 WEEKS, 6 MONTHS, AND 1 YEAR AFTER PERIPHERAL INJURY USING THE SPARED NERVE INJURY IN MICE. SPARED NERVE INJURY RESULTED IN RAPID AND PERSISTENT CHANGES IN DNA METHYLATION, WITH ROBUST DIFFERENTIAL METHYLATION OBSERVED BETWEEN SPARED NERVE INJURY AND SHAM-OPERATED CONTROL MICE AT ALL TIME POINTS. HUNDREDS OF DIFFERENTIALLY METHYLATED GENES WERE IDENTIFIED, INCLUDING MANY WITH KNOWN FUNCTION IN PAIN. PATHWAY ANALYSIS REVEALED ENRICHMENT IN GENES RELATED TO STIMULUS RESPONSE AT EARLY TIME POINTS, IMMUNE FUNCTION AT LATER TIME POINTS, AND ACTIN AND CYTOSKELETAL REGULATION THROUGHOUT THE TIME COURSE. THESE RESULTS EMPHASIZE THE IMPORTANCE OF CONSIDERING PAIN CHRONICITY IN BOTH PAIN RESEARCH AND IN TREATMENT OPTIMIZATION. 2020