1 5617 144 SARCOSINE SUPPRESSES EPILEPTOGENESIS IN RATS WITH EFFECTS ON HIPPOCAMPAL DNA METHYLATION. EPILEPTOGENESIS IS A COMMON CONSEQUENCE OF BRAIN INSULTS, HOWEVER, THE PREVENTION OR DELAY OF THE EPILEPTOGENIC PROCESS REMAINS AN IMPORTANT UNMET MEDICAL CHALLENGE. OVEREXPRESSION OF GLYCINE TRANSPORTER 1 (GLYT1) IS PROPOSED AS A PATHOLOGICAL HALLMARK IN THE HIPPOCAMPUS OF PATIENTS WITH TEMPORAL LOBE EPILEPSY (TLE), AND WE PREVIOUSLY DEMONSTRATED IN RODENT EPILEPSY MODELS THAT AUGMENTATION OF GLYCINE SUPPRESSED CHRONIC SEIZURES AND ALTERED ACUTE SEIZURE THRESHOLDS. IN THE PRESENT STUDY WE EVALUATED THE EFFECT OF THE GLYT1 INHIBITOR, SARCOSINE (AKA N-METHYLGLYCINE), ON EPILEPTOGENESIS AND ALSO INVESTIGATED POSSIBLE MECHANISMS. WE DEVELOPED A MODIFIED RAPID KINDLING MODEL OF EPILEPTOGENESIS IN RATS COMBINED WITH SEIZURE SCORE MONITORING TO EVALUATE THE ANTIEPILEPTOGENIC EFFECT OF SARCOSINE. WE USED IMMUNOHISTOCHEMISTRY AND WESTERN BLOT ANALYSIS FOR THE EVALUATION OF GLYT1 EXPRESSION AND EPIGENETIC CHANGES OF 5-METHYLCYTOSINE (5MC) AND 5-HYDROXYMETHYLCYTOSINE (5HMC) IN THE EPILEPTOGENIC HIPPOCAMPI OF RATS, AND FURTHER EVALUATED EXPRESSION CHANGES IN ENZYMES INVOLVED IN THE REGULATION OF DNA METHYLATION, TEN-ELEVEN TRANSLOCATION METHYLCYTOSINE DIOXYGENASE 1 (TET1), DNA-METHYLTRANSFERASE 1 (DNMT1), AND DNMT3A. OUR RESULTS DEMONSTRATED: (I) EXPERIMENTAL EVIDENCE THAT SARCOSINE (3 G/KG, I.P. DAILY) SUPPRESSED KINDLING EPILEPTOGENESIS IN RATS; (II) THE SARCOSINE-INDUCED ANTIEPILEPTOGENIC EFFECT WAS ACCOMPANIED BY A SUPPRESSED HIPPOCAMPAL GLYT1 EXPRESSION AS WELL AS A REDUCTION OF HIPPOCAMPAL 5MC LEVELS AND A CORRESPONDING INCREASE IN 5HMC; AND (III) SARCOSINE TREATMENT CAUSED DIFFERENTIAL EXPRESSION CHANGES OF TET1 AND DNMTS. TOGETHER, THESE FINDINGS SUGGEST THAT SARCOSINE HAS UNPRECEDENTED DISEASE-MODIFYING PROPERTIES IN A KINDLING MODEL OF EPILEPTOGENESIS IN RATS, WHICH WAS ASSOCIATED WITH ALTERED HIPPOCAMPAL DNA METHYLATION. THUS, MANIPULATION OF THE GLYCINE SYSTEM IS A POTENTIAL THERAPEUTIC APPROACH TO ATTENUATE THE DEVELOPMENT OF EPILEPSY. 2020 2 213 42 ACUTE AND CHRONIC ELECTROCONVULSIVE SEIZURES (ECS) DIFFERENTIALLY REGULATE THE EXPRESSION OF EPIGENETIC MACHINERY IN THE ADULT RAT HIPPOCAMPUS. BACKGROUND: ELECTROCONVULSIVE SEIZURE TREATMENT IS A FAST-ACTING ANTIDEPRESSANT THERAPY THAT EVOKES RAPID TRANSCRIPTIONAL, NEUROGENIC, AND BEHAVIORAL CHANGES. EPIGENETIC MECHANISMS CONTRIBUTE TO ALTERED GENE REGULATION, WHICH UNDERLIES THE NEUROGENIC AND BEHAVIORAL EFFECTS OF ELECTROCONVULSIVE SEIZURE. WE HYPOTHESIZED THAT ELECTROCONVULSIVE SEIZURE MAY MODULATE THE EXPRESSION OF EPIGENETIC MACHINERY, THUS ESTABLISHING POTENTIAL ALTERATIONS IN THE EPIGENETIC LANDSCAPE. METHODS: WE EXAMINED THE INFLUENCE OF ACUTE AND CHRONIC ELECTROCONVULSIVE SEIZURE ON THE GENE EXPRESSION OF HISTONE MODIFIERS, NAMELY HISTONE ACETYLTRANSFERASES, HISTONE DEACETYLASES, HISTONE METHYLTRANSFERASES, AND HISTONE (LYSINE) DEMETHYLASES AS WELL AS DNA MODIFYING ENZYMES, INCLUDING DNA METHYLTRANSFERASES, DNA DEMETHYLASES, AND METHYL-CPG-BINDING PROTEINS IN THE HIPPOCAMPI OF ADULT MALE WISTAR RATS USING QUANTITATIVE REAL TIME-PCR ANALYSIS. FURTHER, WE EXAMINED THE INFLUENCE OF ACUTE AND CHRONIC ELECTROCONVULSIVE SEIZURE ON GLOBAL AND RESIDUE-SPECIFIC HISTONE ACETYLATION AND METHYLATION LEVELS WITHIN THE HIPPOCAMPUS, A BRAIN REGION IMPLICATED IN THE CELLULAR AND BEHAVIORAL EFFECTS OF ELECTROCONVULSIVE SEIZURE. RESULTS: ACUTE AND CHRONIC ELECTROCONVULSIVE SEIZURE INDUCED A PRIMARILY UNIQUE, AND IN CERTAIN CASES BIDIRECTIONAL, REGULATION OF HISTONE AND DNA MODIFIERS, AND METHYL-CPG-BINDING PROTEINS, WITH AN OVERLAPPING PATTERN OF GENE REGULATION RESTRICTED TO SIRT4, MLL3, JMJD3, GADD45B, TET2, AND TET3. GLOBAL HISTONE ACETYLATION AND METHYLATION LEVELS WERE PREDOMINANTLY UNCHANGED, WITH THE EXCEPTION OF A SIGNIFICANT DECLINE IN H3K9 ACETYLATION IN THE HIPPOCAMPUS FOLLOWING CHRONIC ELECTROCONVULSIVE SEIZURE. CONCLUSIONS: ELECTROCONVULSIVE SEIZURE TREATMENT EVOKES THE TRANSCRIPTIONAL REGULATION OF SEVERAL HISTONE AND DNA MODIFIERS, AND METHYL-CPG-BINDING PROTEINS WITHIN THE HIPPOCAMPUS, WITH A PREDOMINANTLY DISTINCT PATTERN OF REGULATION INDUCED BY ACUTE AND CHRONIC ELECTROCONVULSIVE SEIZURE. 2016 3 5345 51 RAPID CHANGES IN EXPRESSION OF CLASS I AND IV HISTONE DEACETYLASES DURING EPILEPTOGENESIS IN MOUSE MODELS OF TEMPORAL LOBE EPILEPSY. A PROMINENT ROLE OF EPIGENETIC MECHANISMS IN MANIFESTATION OF EPILEPSY HAS BEEN PROPOSED. THUS ALTERED HISTONE H3 AND H4 ACETYLATION HAS BEEN DEMONSTRATED IN EXPERIMENTAL MODELS OF TEMPORAL LOBE EPILEPSY (TLE). WE NOW INVESTIGATED CHANGES IN THE EXPRESSION OF THE CLASS I AND CLASS IV HISTONE DEACETYLASES (HDAC) IN TWO COMPLEMENTARY MOUSE TLE MODELS. UNILATERAL INTRAHIPPOCAMPAL INJECTION OF KAINIC ACID (KA) INDUCED A STATUS EPILEPTICUS LASTING 6 TO 24H, DEVELOPMENT OF SPONTANEOUS LIMBIC SEIZURES (2 TO 3 DAYS AFTER KA INJECTION) AND CHRONIC EPILEPSY, AS REVEALED BY TELEMETRIC RECORDINGS OF THE EEGS. MICE WERE KILLED AT DIFFERENT INTERVALS AFTER KA INJECTION AND EXPRESSION OF HDAC MRNAS WAS INVESTIGATED BY IN SITU HYBRIDIZATION. WE OBSERVED MARKED DECREASES IN THE EXPRESSION OF HDACS 1, 2 AND 11 (BY UP TO 75%) IN THE GRANULE CELL AND PYRAMIDAL CELL LAYERS OF THE HIPPOCAMPUS DURING THE ACUTE STATUS EPILEPTICUS (2 TO 6H AFTER KA INJECTION). THIS WAS FOLLOWED BY INCREASED EXPRESSION OF ALL CLASS I HDAC MRNAS IN ALL PRINCIPAL CELL LAYERS OF THE HIPPOCAMPUS AFTER 12 TO 48 H. IN THE CHRONIC PHASE, 14 AND 28 DAYS AFTER KA, ONLY MODEST INCREASES IN THE EXPRESSION OF HDAC1 MRNA WERE OBSERVED IN GRANULE AND PYRAMIDAL CELLS. IMMUNOHISTOCHEMISTRY USING AN ANTIBODY DETECTING HDAC2 REVEALED RESULTS CONSISTENT WITH THE MRNA DATA AND INDICATES ALSO EXPRESSION IN GLIAL CELLS ON THE INJECTION SIDE. SIMILAR CHANGES AS SEEN IN THE KA MODEL WERE OBSERVED AFTER A PILOCARPINE-INDUCED STATUS EPILEPTICUS EXCEPT THAT DECREASES IN HDACS 2, 3 AND 8 WERE ALSO SEEN AT THE CHRONIC 28 DAY INTERVAL. THE PROMINENT DECREASES IN HDAC EXPRESSION DURING STATUS EPILEPTICUS ARE CONSISTENT WITH THE PREVIOUSLY DEMONSTRATED INCREASED EXPRESSION OF NUMEROUS PROTEINS AND WITH THE AUGMENTED ACETYLATION OF HISTONE H4. IT IS SUGGESTED THAT RESPECTIVE PUTATIVE GENE PRODUCTS COULD FACILITATE PROCONVULSIVE AS WELL AS ANTICONVULSIVE MECHANISMS. THE INCREASED EXPRESSION OF ALL CLASS I HDACS DURING THE "SILENT PHASE", ON THE OTHER HAND, MAY BE RELATED TO DECREASED HISTONE ACETYLATION, WHICH COULD CAUSE A DECREASE IN EXPRESSION OF CERTAIN PROTEINS, A MECHANISM THAT COULD ALSO PROMOTE EPILEPTOGENESIS. THUS, ADDRESSING HDAC EXPRESSION MAY HAVE A THERAPEUTIC POTENTIAL IN INTERFERING WITH A STATUS EPILEPTICUS AND WITH THE MANIFESTATION OF TLE. 2015 4 2057 33 EPIGENETIC CONTROL OF EPILEPSY TARGET GENES CONTRIBUTES TO A CELLULAR MEMORY OF EPILEPTOGENESIS IN CULTURED RAT HIPPOCAMPAL NEURONS. HYPERSYNCHRONOUS NEURONAL EXCITATION MANIFESTS CLINICALLY AS SEIZURE (ICTOGENESIS), AND MAY RECUR SPONTANEOUSLY AND REPETITIVELY AFTER A VARIABLE LATENCY PERIOD (EPILEPTOGENESIS). DESPITE TREMENDOUS RESEARCH EFFORTS TO DESCRIBE MOLECULAR PATHWAYS AND SIGNATURES OF EPILEPTOGENESIS, MOLECULAR PATHOMECHANISMS LEADING TO CHRONIC EPILEPSY REMAIN TO BE CLARIFIED. WE HYPOTHESIZED THAT EPIGENETIC MODIFICATIONS MAY FORM THE BASIS FOR A CELLULAR MEMORY OF EPILEPTOGENESIS, AND USED A PRIMARY NEURONAL CELL CULTURE MODEL OF THE RAT HIPPOCAMPUS TO STUDY THE TRANSLATION OF MASSIVE NEURONAL EXCITATION INTO PERSISTING CHANGES OF EPIGENETIC SIGNATURES AND PRO-EPILEPTOGENIC TARGET GENE EXPRESSION. INCREASED SPONTANEOUS ACTIVATION OF CULTURED NEURONS WAS DETECTED 3 AND 7 DAYS AFTER STIMULATION WITH 10 MUM GLUTAMATE WHEN COMPARED TO SHAM-TREATED TIME-MATCHED CONTROLS USING CALCIUM-IMAGING IN VITRO. CHROMATIN-IMMUNOPRECIPITATION EXPERIMENTS REVEALED SHORT-TERM (3 H, 7 H, AND 24 H) AND LONG-TERM (3 D AND 2 WEEKS) CHANGES IN HISTONE MODIFICATIONS, WHICH WERE DIRECTLY LINKED TO DECREASED EXPRESSION OF TWO SELECTED EPILEPSY TARGET GENES, E.G. EXCITATORY GLUTAMATE RECEPTOR GENES GRIA2 AND GRIN2A. INCREASED PROMOTER METHYLATION OBSERVED 4 WEEKS AFTER GLUTAMATE STIMULATION AT RESPECTIVE GENES SUGGESTED LONG-TERM REPRESSION OF GRIA2 AND GRIN2A GENES. INHIBITION OF GLUTAMATERGIC ACTIVATION OR BLOCKING THE PROPAGATION OF ACTION POTENTIALS IN CULTURED NEURONS RESCUED ALTERED GENE EXPRESSION AND REGULATORY EPIGENETIC MODIFICATIONS. OUR DATA SUPPORT THE CONCEPT OF A CELLULAR MEMORY OF EPILEPTOGENESIS AND PERSISTING EPIGENETIC MODIFICATIONS OF EPILEPSY TARGET GENES, WHICH ARE ABLE TO TURN NORMAL INTO PRO-EPILEPTIC NEURONS AND CIRCUITS. 2017 5 2116 43 EPIGENETIC HISTONE DEACETYLATION INHIBITION PREVENTS THE DEVELOPMENT AND PERSISTENCE OF TEMPORAL LOBE EPILEPSY. EPILEPSY IS A CHRONIC BRAIN DISEASE CHARACTERIZED BY REPEATED UNPROVOKED SEIZURES. CURRENTLY, NO DRUG THERAPY EXISTS FOR CURING EPILEPSY OR DISEASE MODIFICATION IN PEOPLE AT RISK. DESPITE SEVERAL EMERGING MECHANISMS, THERE HAVE BEEN FEW STUDIES OF EPIGENETIC SIGNALING IN EPILEPTOGENESIS, THE PROCESS WHEREBY A NORMAL BRAIN BECOMES PROGRESSIVELY EPILEPTIC BECAUSE OF PRECIPITATING FACTORS. HERE, WE REPORT A NOVEL ROLE OF HISTONE DEACETYLATION AS A CRITICAL EPIGENETIC MECHANISM IN EPILEPTOGENESIS. EXPERIMENTS WERE CONDUCTED USING THE HISTONE DEACETYLASE (HDAC) INHIBITOR SODIUM BUTYRATE IN THE HIPPOCAMPUS KINDLING MODEL OF TEMPORAL LOBE EPILEPSY (TLE), A CLASSIC MODEL HEAVILY USED TO APPROVE DRUGS FOR TREATMENT OF EPILEPSY. DAILY TREATMENT WITH BUTYRATE SIGNIFICANTLY INHIBITED HDAC ACTIVITY AND RETARDED THE DEVELOPMENT OF LIMBIC EPILEPTOGENESIS WITHOUT AFFECTING AFTER-DISCHARGE SIGNAL. HDAC INHIBITION MARKEDLY IMPAIRED THE PERSISTENCE OF SEIZURE EXPRESSION MANY WEEKS AFTER EPILEPSY DEVELOPMENT. MOREOVER, SUBCHRONIC HDAC INHIBITION FOR 2 WEEKS RESULTED IN A STRIKING RETARDATION OF EPILEPTOGENESIS. HDAC INHIBITION, UNEXPECTEDLY, ALSO SHOWED ERASURE OF THE EPILEPTOGENIC STATE IN EPILEPTIC ANIMALS. FINALLY, BUTYRATE-TREATED ANIMALS EXHIBITED A POWERFUL REDUCTION IN MOSSY FIBER SPROUTING, A MORPHOLOGIC INDEX OF EPILEPTOGENESIS. TOGETHER THESE RESULTS UNDERSCORE THAT HDAC INHIBITION PREVENTS THE DEVELOPMENT OF TLE, INDICATING HDAC'S CRITICAL SIGNALING ROLE IN EPILEPTOGENESIS. THESE FINDINGS, THEREFORE, ENVISAGE A UNIQUE NOVEL THERAPY FOR PREVENTING OR CURING EPILEPSY BY TARGETING THE EPIGENETIC HDAC PATHWAY. 2018 6 1301 36 DEEP SEQUENCING REVEALS INCREASED DNA METHYLATION IN CHRONIC RAT EPILEPSY. EPILEPSY IS A FREQUENT NEUROLOGICAL DISORDER, ALTHOUGH ONSET AND PROGRESSION OF SEIZURES REMAIN DIFFICULT TO PREDICT IN AFFECTED PATIENTS, IRRESPECTIVE OF THEIR EPILEPTOGENIC CONDITION. PREVIOUS STUDIES IN ANIMAL MODELS AS WELL AS HUMAN EPILEPTIC BRAIN TISSUE REVEALED A REMARKABLY DIVERSE PATTERN OF GENE EXPRESSION IMPLICATING EPIGENETIC CHANGES TO CONTRIBUTE TO DISEASE PROGRESSION. HERE WE MAPPED FOR THE FIRST TIME GLOBAL DNA METHYLATION PATTERNS IN CHRONIC EPILEPTIC RATS AND CONTROLS. USING METHYL-CPG CAPTURE ASSOCIATED WITH MASSIVE PARALLEL SEQUENCING (METHYL-SEQ) WE REPORT THE GENOMIC METHYLATION SIGNATURE OF THE CHRONIC EPILEPTIC STATE. WE OBSERVED A PREDOMINANT INCREASE, RATHER THAN LOSS OF DNA METHYLATION IN CHRONIC RAT EPILEPSY. ABERRANT METHYLATION PATTERNS WERE INVERSELY CORRELATED WITH GENE EXPRESSION CHANGES USING MRNA SEQUENCING FROM SAME ANIMALS AND TISSUE SPECIMENS. ADMINISTRATION OF A KETOGENIC, HIGH-FAT, LOW-CARBOHYDRATE DIET ATTENUATED SEIZURE PROGRESSION AND AMELIORATED DNA METHYLATION MEDIATED CHANGES IN GENE EXPRESSION. THIS IS THE FIRST REPORT OF UNSUPERVISED CLUSTERING OF AN EPIGENETIC MARK BEING USED IN EPILEPSY RESEARCH TO SEPARATE EPILEPTIC FROM NON-EPILEPTIC ANIMALS AS WELL AS FROM ANIMALS RECEIVING ANTI-CONVULSIVE DIETARY TREATMENT. WE FURTHER DISCUSS THE POTENTIAL IMPACT OF EPIGENETIC CHANGES AS A PATHOGENIC MECHANISM OF EPILEPTOGENESIS. 2013 7 345 47 ALTERED BRAIN EXPRESSION OF DNA METHYLATION AND HYDROXYMETHYLATION EPIGENETIC ENZYMES IN A RAT MODEL OF NEUROPATHIC PAIN. THE ROLE OF EPIGENETICS IN CHRONIC PAIN AT THE SUPRASPINAL LEVEL IS YET TO BE FULLY CHARACTERIZED. DNA HISTONE METHYLATION IS CRUCIALLY REGULATED BY DE NOVO METHYLTRANSFERASES (DNMT1-3) AND TEN-ELEVEN TRANSLOCATION DIOXYGENASES (TET1-3). EVIDENCE HAS SHOWN THAT METHYLATION MARKERS ARE ALTERED IN DIFFERENT CNS REGIONS RELATED TO NOCICEPTION, NAMELY THE DORSAL ROOT GANGLIA, THE SPINAL CORD, AND DIFFERENT BRAIN AREAS. DECREASED GLOBAL METHYLATION WAS FOUND IN THE DRG, THE PREFRONTAL CORTEX, AND THE AMYGDALA, WHICH WAS ASSOCIATED WITH DECREASED DNMT1/3A EXPRESSION. IN CONTRAST, INCREASED METHYLATION LEVELS AND MRNA LEVELS OF TET1 AND TET3 WERE LINKED TO AUGMENTED PAIN HYPERSENSITIVITY AND ALLODYNIA IN INFLAMMATORY AND NEUROPATHIC PAIN MODELS. SINCE EPIGENETIC MECHANISMS MAY BE RESPONSIBLE FOR THE REGULATION AND COORDINATION OF VARIOUS TRANSCRIPTIONAL MODIFICATIONS DESCRIBED IN CHRONIC PAIN STATES, WITH THIS STUDY, WE AIMED TO EVALUATE THE FUNCTIONAL ROLE OF TET1-3 AND DNMT1/3A GENES IN NEUROPATHIC PAIN IN SEVERAL BRAIN AREAS. IN A SPARED NERVE INJURY RAT MODEL OF NEUROPATHIC PAIN, 21 DAYS AFTER SURGERY, WE FOUND INCREASED TET1 EXPRESSION IN THE MEDIAL PREFRONTAL CORTEX AND DECREASED EXPRESSION IN THE CAUDATE-PUTAMEN AND THE AMYGDALA; TET2 WAS UPREGULATED IN THE MEDIAL THALAMUS; TET3 MRNA LEVELS WERE REDUCED IN THE MEDIAL PREFRONTAL CORTEX AND THE CAUDATE-PUTAMEN; AND DNMT1 WAS DOWNREGULATED IN THE CAUDATE-PUTAMEN AND THE MEDIAL THALAMUS. NO STATISTICALLY SIGNIFICANT CHANGES IN EXPRESSION WERE OBSERVED WITH DNMT3A. OUR RESULTS SUGGEST A COMPLEX FUNCTIONAL ROLE FOR THESE GENES IN DIFFERENT BRAIN AREAS IN THE CONTEXT OF NEUROPATHIC PAIN. THE NOTION OF DNA METHYLATION AND HYDROXYMETHYLATION BEING CELL-TYPE SPECIFIC AND NOT TISSUE SPECIFIC, AS WELL AS THE POSSIBILITY OF CHRONOLOGICALLY DIFFERENTIAL GENE EXPRESSION AFTER THE ESTABLISHMENT OF NEUROPATHIC OR INFLAMMATORY PAIN MODELS, OUGHT TO BE ADDRESSED IN FUTURE STUDIES. 2023 8 1425 40 DIFFERENTIAL DNA METHYLATION PROFILES OF CODING AND NON-CODING GENES DEFINE HIPPOCAMPAL SCLEROSIS IN HUMAN TEMPORAL LOBE EPILEPSY. TEMPORAL LOBE EPILEPSY IS ASSOCIATED WITH LARGE-SCALE, WIDE-RANGING CHANGES IN GENE EXPRESSION IN THE HIPPOCAMPUS. EPIGENETIC CHANGES TO DNA ARE ATTRACTIVE MECHANISMS TO EXPLAIN THE SUSTAINED HYPEREXCITABILITY OF CHRONIC EPILEPSY. HERE, THROUGH METHYLATION ANALYSIS OF ALL ANNOTATED C-PHOSPHATE-G ISLANDS AND PROMOTER REGIONS IN THE HUMAN GENOME, WE REPORT A PILOT STUDY OF THE METHYLATION PROFILES OF TEMPORAL LOBE EPILEPSY WITH OR WITHOUT HIPPOCAMPAL SCLEROSIS. FURTHERMORE, BY COMPARATIVE ANALYSIS OF EXPRESSION AND PROMOTER METHYLATION, WE IDENTIFY METHYLATION SENSITIVE NON-CODING RNA IN HUMAN TEMPORAL LOBE EPILEPSY. A TOTAL OF 146 PROTEIN-CODING GENES EXHIBITED ALTERED DNA METHYLATION IN TEMPORAL LOBE EPILEPSY HIPPOCAMPUS (N = 9) WHEN COMPARED TO CONTROL (N = 5), WITH 81.5% OF THE PROMOTERS OF THESE GENES DISPLAYING HYPERMETHYLATION. UNIQUE METHYLATION PROFILES WERE EVIDENT IN TEMPORAL LOBE EPILEPSY WITH OR WITHOUT HIPPOCAMPAL SCLEROSIS, IN ADDITION TO A COMMON METHYLATION PROFILE REGARDLESS OF PATHOLOGY GRADE. GENE ONTOLOGY TERMS ASSOCIATED WITH DEVELOPMENT, NEURON REMODELLING AND NEURON MATURATION WERE OVER-REPRESENTED IN THE METHYLATION PROFILE OF WATSON GRADE 1 SAMPLES (MILD HIPPOCAMPAL SCLEROSIS). IN ADDITION TO GENES ASSOCIATED WITH NEURONAL, NEUROTRANSMITTER/SYNAPTIC TRANSMISSION AND CELL DEATH FUNCTIONS, DIFFERENTIAL HYPERMETHYLATION OF GENES ASSOCIATED WITH TRANSCRIPTIONAL REGULATION WAS EVIDENT IN TEMPORAL LOBE EPILEPSY, BUT OVERALL FEW GENES PREVIOUSLY ASSOCIATED WITH EPILEPSY WERE AMONG THE DIFFERENTIALLY METHYLATED. FINALLY, A PANEL OF 13, METHYLATION-SENSITIVE MICRORNA WERE IDENTIFIED IN TEMPORAL LOBE EPILEPSY INCLUDING MIR27A, MIR-193A-5P (MIR193A) AND MIR-876-3P (MIR876), AND THE DIFFERENTIAL METHYLATION OF LONG NON-CODING RNA DOCUMENTED FOR THE FIRST TIME. THE PRESENT STUDY THEREFORE REPORTS SELECT, GENOME-WIDE DNA METHYLATION CHANGES IN HUMAN TEMPORAL LOBE EPILEPSY THAT MAY CONTRIBUTE TO THE MOLECULAR ARCHITECTURE OF THE EPILEPTIC BRAIN. 2015 9 2297 39 EPIGENETIC REGULATION OF ACUTE INFLAMMATORY PAIN. ACUTE PAIN IS ASSOCIATED WITH TISSUE DAMAGE, WHICH RESULTS IN THE RELEASE OF INFLAMMATORY MEDIATORS. RECENT STUDIES POINT TO THE INVOLVEMENT OF EPIGENETIC MECHANISMS (DNA METHYLATION) IN THE DEVELOPMENT OF PAIN. WE HAVE FOUND THAT DURING ACUTE INFLAMMATORY PAIN INDUCED BY THE APPLICATION OF 10% MUSTARD OIL ON THE TONGUES OF RATS, LEVELS OF DNMT3A AND 3B WERE ELEVATED MARKEDLY (36 AND 42 % RESPECTIVELY), WHEREAS THE LEVEL OF DNMT1 WAS NOT CHANGED SIGNIFICANTLY. PREVIOUS INJECTION OF XEFOCAM WITH 0,4 MG/KG DOSE DECREASED LEVELS OF DNMT3A AND 3B (25 AND 24% RESPECTIVELY). THE LEVEL OF DNMT1 WAS NOT CHANGED SIGNIFICANTLY COMPARED TO THE CONTROL GROUP. THE FINDINGS SUPPORT THE IDEA THAT INHIBITORS OF DNA-METHYLTRANSFERASES COULD BE USEFUL FOR PAIN MANAGEMENT. OUR DATA SUGGEST THAT NSAIDS (ALONE OR IN COMBINATION WITH DNMT INHIBITORS) MAY BE PROPOSED AS POSSIBLE EPIGENETIC REGULATORY AGENTS, WHICH MAY PLAY A ROLE IN EPIGENETIC MECHANISMS INDIRECTLY THROUGH ALTERING THE ACTIVITY OF INFLAMMATORY MEDIATORS INVOLVED IN PAIN DEVELOPMENT. 2014 10 6419 44 THE TET2-UPF1 COMPLEX MODULATES MRNA STABILITY UNDER STRESS CONDITIONS. INTRODUCTION: ENVIRONMENTAL STRESS PROMOTES EPIGENETIC ALTERATIONS THAT IMPACT GENE EXPRESSION AND SUBSEQUENTLY PARTICIPATE IN THE PATHOLOGICAL PROCESSES OF THE DISORDER. AMONG EPIGENETIC REGULATIONS, TEN-ELEVEN TRANSLOCATION (TET) ENZYMES OXIDIZE 5-METHYLCYTOSINE (5MC) TO 5-HYDROXYMETHYLCYTOSINE (5HMC) IN DNA AND RNA AND FUNCTION AS CRITICAL PLAYERS IN THE PATHOGENESIS OF DISEASES. OUR PREVIOUS RESULTS SHOWED THAT CHRONIC STRESS INCREASES THE EXPRESSION OF CYTOPLASMIC TET2 IN THE HIPPOCAMPUS OF MICE EXPOSED TO CHRONIC MILD STRESS (CMS). WHETHER THE CYTOPLASMIC TET2 ALTERS RNA 5HMC MODIFICATION IN CHRONIC STRESS-RELATED PROCESSES REMAINS LARGELY UNKNOWN. METHODS: TO EXPLORE THE ROLE OF CYTOPLASMIC TET2 UNDER CMS CONDITIONS, WE ESTABLISHED CMS MICE MODEL AND DETECTED THE EXPRESSION OF RNA 5HMC BY DOT BLOT. WE VERIFIED THE INTERACTION OF TET2 AND ITS INTERACTING PROTEIN BY CO-IMMUNOPRECIPITATION COMBINED WITH MASS SPECTROMETRY AND SCREENED DOWNSTREAM TARGET GENES BY CLUSTER ANALYSIS OF TET2 AND UPSTREAM FRAMESHIFT 1 (UPF1) INTERACTING RNA. THE EXPRESSION OF PROTEIN WAS DETECTED BY WESTERN BLOT AND THE EXPRESSION OF THE SCREENED TARGET GENES WAS DETECTED BY QRT-PCR. RESULTS: IN THIS STUDY, WE FOUND THAT INCREASED CYTOPLASMIC TET2 EXPRESSION UNDER CMS CONDITIONS LEADS TO INCREASE IN TOTAL RNA 5HMC MODIFICATION. TET2 INTERACTED WITH THE KEY NON-SENSE-MEDIATED MRNA DECAY (NMD) FACTOR UPF1, REGULATED THE STABILITY OF STRESS-RELATED GENES SUCH AS UNC5B MRNA, AND MIGHT THEREBY AFFECT NEURODEVELOPMENT. DISCUSSION: IN SUMMARY, THIS STUDY REVEALED THAT TET2-MEDIATED RNA 5HMC MODIFICATION IS INVOLVED IN STRESS-RELATED MRNA STABILITY REGULATION AND MAY SERVE AS A POTENTIAL THERAPEUTIC TARGET FOR CHRONIC STRESS-RELATED DISEASES SUCH AS DEPRESSION. 2023 11 2654 38 EPILEPSY PROGRESSION IS ASSOCIATED WITH CUMULATIVE DNA METHYLATION CHANGES IN INFLAMMATORY GENES. MESIAL TEMPORAL LOBE EPILEPSY WITH HIPPOCAMPAL SCLEROSIS (MTLE-HS) IS THE MOST COMMON FOCAL EPILEPSY IN ADULTS. IT IS CHARACTERIZED BY ALARMING RATES OF PHARMACORESISTANCE. EPILEPTOGENESIS IS ASSOCIATED WITH THE OCCURRENCE OF EPIGENETIC ALTERATIONS, AND THE FEW EPIGENETIC STUDIES CARRIED OUT IN MTLE-HS HAVE MAINLY FOCUSED ON THE HIPPOCAMPUS. IN THIS STUDY, WE OBTAINED THE DNA METHYLATION PROFILES FROM BOTH THE HIPPOCAMPUS AND ANTERIOR TEMPORAL NEOCORTEX OF MTLE-HS PATIENTS SUBJECTED TO RESECTIVE EPILEPSY SURGERY AND AUTOPSIED NON-EPILEPTIC CONTROLS. WE ASSESSED THE PROGRESSIVE NATURE OF DNA METHYLATION CHANGES IN RELATION TO EPILEPSY DURATION. WE IDENTIFIED SIGNIFICANTLY ALTERED HIPPOCAMPAL DNA METHYLATION PATTERNS ENCOMPASSING MULTIPLE PATHWAYS KNOWN TO BE INVOLVED IN EPILEPTOGENESIS. DNA METHYLATION CHANGES WERE EVEN MORE STRIKING IN THE NEOCORTEX, WHEREIN PATHOGENIC PATHWAYS AND GENES WERE COMMON TO BOTH TISSUES. MOST IMPORTANTLY, DNA METHYLATION CHANGES AT MANY GENOMIC SITES VARIED SIGNIFICANTLY WITH EPILEPSY DURATION. SUCH PROGRESSIVE CHANGES WERE ASSOCIATED WITH INFLAMMATION-RELATED GENES IN THE HIPPOCAMPUS. OUR RESULTS SUGGEST THAT THE NEOCORTEX, RELATIVELY SPARED OF EXTENSIVE HISTOPATHOLOGICAL DAMAGE, MAY ALSO BE INVOLVED IN EPILEPSY DEVELOPMENT. THESE RESULTS ALSO OPEN THE POSSIBILITY THAT THE OBSERVED NEOCORTICAL IMPAIRMENT COULD REPRESENT A PRELIMINARY STAGE OF EPILEPTOGENESIS BEFORE THE ESTABLISHMENT OF CHRONIC LESIONS OR A CONSEQUENCE OF PROLONGED SEIZURE EXPOSURE. OUR TWO-TISSUE MULTI-LEVEL CHARACTERIZATION OF THE MTLE-HS DNA METHYLOME SUGGESTS THE OCCURRENCE OF A SELF-PROPAGATING INFLAMMATORY WAVE OF EPIGENETIC DYSREGULATION. 2022 12 1813 45 EFFECTS OF CAFFEIC ACID ON EPIGENETICS IN THE BRAIN OF RATS WITH CHRONIC UNPREDICTABLE MILD STRESS. THE PRESENT STUDY HYPOTHESIZED THAT CAFFEIC ACID (3,4?DIHYDROXYCINNAMIC ACID; CAA) MAY EXERT ANTIDEPRESSANT?LIKE EFFECTS IN RATS WITH CHRONIC UNPREDICTABLE MILD STRESS VIA EPIGENETIC MECHANISMS, SUCH AS DNA METHYLATION AND HYDROXYMETHYLATION. THE CHRONIC UNPREDICTABLE MILD STRESS (CUMS) MODEL WAS USED TO ANALYZE THE EFFECTS OF CAA ON BEHAVIORAL PHENOTYPES, AND TO EVALUATE THE DISTRIBUTION OF 5?METHYLCYTOSINE (5MC) AND 5?HYDROXYMETHYLCYTOSINE (5HMC) IN THE HIPPOCAMPUS AND PREFRONTAL CORTEX USING IMMUNOHISTOCHEMISTRY AND IMMUNOFLUORESCENCE. MRNA LEVELS OF THE GENES ENCODING BRAIN?DERIVED NEUROTROPIC FACTOR (BDNF) AND CATECHOL?O?METHYLTRANSFERASE (COMT), AND KEY ENZYMES REGULATING DNA METHYLATION [DNA METHYLTRANSFERASE (DNMT)1 AND DNMT3A] AND HYDROXYMETHYLATION [TEN?ELEVEN TRANSLOCATION (TET)1?3] WERE EXAMINED USING QUANTITATIVE (Q)PCR. FURTHERMORE, ENRICHMENT OF 5MC AND 5HMC AT THE PROMOTOR REGIONS OF THE BDNF AND COMT GENES WAS QUANTIFIED USING CHROMATIN IMMUNOPRECIPITATION?QPCR. BEHAVIORAL DATA SHOWED THAT CAA EXERTED A SLIGHT ANTIDEPRESSANT?LIKE EFFECT. BDNF AND COMT GENES SHOWED DIFFERENTIAL EXPRESSION PATTERNS DUE TO CUMS. CAA INTERVENTION INDUCED DIFFERENT DNMT1/DNMT3A AND TET1/TET2 MRNA LEVELS IN THE HIPPOCAMPUS AND PREFRONTAL CORTEX, RESPECTIVELY. CAA REGULATED THE RATIO OF 5MC/5HMC AT THE PROMOTOR REGION OF THE BDNF AND COMT GENES AND THEREFORE INFLUENCED GENE EXPRESSION, WHICH MAY BE A VALUABLE THERAPEUTIC OPTION FOR MAJOR DEPRESSIVE DISORDER (MDD). IN CONCLUSION, THERE WERE EPIGENETIC CHANGES IN THE HIPPOCAMPUS AND PREFRONTAL CORTEX IN CUMS RATS, AND CAA MAY FUNCTION AS A MODULATOR OF DNA METHYLATION TO REGULATE GENE TRANSCRIPTION, THUS PROVIDING A MECHANISTIC BASIS FOR THE USE OF THIS PHYTOCHEMICAL AGENT IN THE TREATMENT OF MDD. 2020 13 4173 33 MELATONIN INDUCES HISTONE HYPERACETYLATION IN THE RAT BRAIN. WE HAVE REPORTED THAT MELATONIN INDUCES HISTONE HYPERACETYLATION IN MOUSE NEURAL STEM CELLS, SUGGESTING AN EPIGENETIC ROLE FOR THIS PLEIOTROPIC HORMONE. TO SUPPORT SUCH A ROLE, IT IS NECESSARY TO DEMONSTRATE THAT MELATONIN PRODUCES SIMILAR EFFECTS IN VIVO. HISTONE ACETYLATION, FOLLOWING CHRONIC TREATMENT WITH MELATONIN (4MUG/ML IN DRINKING WATER FOR 17 DAYS), WAS EXAMINED BY WESTERN BLOTTING IN SELECTED RAT BRAIN REGIONS. MELATONIN INDUCED SIGNIFICANT INCREASES IN HISTONE H3 AND HISTONE H4 ACETYLATION IN THE HIPPOCAMPUS. HISTONE H4 WAS ALSO HYPERACETYLATED IN THE STRIATUM, BUT THERE WERE NO SIGNIFICANT CHANGES IN HISTONE H3 ACETYLATION IN THIS BRAIN REGION. NO SIGNIFICANT CHANGES IN THE ACETYLATION OF EITHER HISTONE H3 OR H4 WERE OBSERVED IN THE MIDBRAIN AND CEREBELLUM. AN EXAMINATION OF KINASE ACTIVATION, WHICH MAY BE RELATED TO THESE CHANGES, REVEALED THAT MELATONIN TREATMENT INCREASED THE LEVELS OF PHOSPHO-ERK (EXTRACELLULAR SIGNAL-REGULATED KINASE) IN THE HIPPOCAMPUS AND STRIATUM, BUT PHOSPHO-AKT (PROTEIN KINASE B) LEVELS WERE UNCHANGED. THESE FINDINGS SUGGEST THAT CHROMATIN REMODELING AND ASSOCIATED CHANGES IN THE EPIGENETIC REGULATION OF GENE EXPRESSION UNDERLIE THE MULTIPLE PHYSIOLOGICAL EFFECTS OF MELATONIN. 2013 14 531 41 ASTROCYTE REACTIVITY FOLLOWING BLAST EXPOSURE INVOLVES ABERRANT HISTONE ACETYLATION. BLAST INDUCED NEUROTRAUMA (BINT) IS A PREVALENT INJURY WITHIN MILITARY AND CIVILIAN POPULATIONS. THE INJURY IS CHARACTERIZED BY PERSISTENT INFLAMMATION AT THE CELLULAR LEVEL WHICH MANIFESTS AS A MULTITUDE OF COGNITIVE AND FUNCTIONAL IMPAIRMENTS. EPIGENETIC REGULATION OF TRANSCRIPTION OFFERS AN IMPORTANT CONTROL MECHANISM FOR GENE EXPRESSION AND CELLULAR FUNCTION WHICH MAY UNDERLIE CHRONIC INFLAMMATION AND RESULT IN NEURODEGENERATION. WE HYPOTHESIZE THAT ALTERED HISTONE ACETYLATION PATTERNS MAY BE INVOLVED IN BLAST INDUCED INFLAMMATION AND THE CHRONIC ACTIVATION OF GLIAL CELLS. THIS STUDY AIMED TO ELUCIDATE CHANGES TO HISTONE ACETYLATION OCCURRING FOLLOWING INJURY AND THE ROLES THESE CHANGES MAY HAVE WITHIN THE PATHOLOGY. SPRAGUE DAWLEY RATS WERE SUBJECTED TO EITHER A 10 OR 17 PSI BLAST OVERPRESSURE WITHIN AN ADVANCED BLAST SIMULATOR (ABS). SHAM ANIMALS UNDERWENT THE SAME PROCEDURES WITHOUT BLAST EXPOSURE. MEMORY IMPAIRMENTS WERE MEASURED USING THE NOVEL OBJECT RECOGNITION (NOR) TEST AT 2 AND 7 DAYS POST-INJURY. TISSUES WERE COLLECTED AT 7 DAYS FOR WESTERN BLOT AND IMMUNOHISTOCHEMISTRY (IHC) ANALYSIS. SHAM ANIMALS SHOWED INTACT MEMORY AT EACH TIME POINT. THE NOVEL OBJECT DISCRIMINATION DECREASED SIGNIFICANTLY BETWEEN TWO AND 7 DAYS FOR EACH INJURY GROUP (P < 0.05). THIS IS INDICATIVE OF THE ONSET OF MEMORY IMPAIRMENT. WESTERN BLOT ANALYSIS SHOWED GLIAL FIBRILLARY ACIDIC PROTEIN (GFAP), A KNOWN MARKER OF ACTIVATED ASTROCYTES, WAS ELEVATED IN THE PREFRONTAL CORTEX (PFC) FOLLOWING BLAST EXPOSURE FOR BOTH INJURY GROUPS. ANALYSIS OF HISTONE PROTEIN EXTRACT SHOWED NO CHANGES IN THE LEVEL OF ANY TOTAL HISTONE PROTEINS WITHIN THE PFC. HOWEVER, ACETYLATION LEVELS OF HISTONE H2B, H3, AND H4 WERE DECREASED IN BOTH GROUPS (P < 0.05). CO-LOCALIZATION IMMUNOFLUORESCENCE WAS USED TO FURTHER INVESTIGATE ANY POTENTIAL CORRELATION BETWEEN DECREASED HISTONE ACETYLATION AND ASTROCYTE ACTIVATION. THESE EXPERIMENTS SHOWED A SIMILAR DECREASE IN H3 ACETYLATION IN ASTROCYTES EXPOSED TO A 17 PSI BLAST BUT NOT A 10 PSI BLAST. FURTHER INVESTIGATION OF GENE EXPRESSION BY POLYMERASE CHAIN REACTION (PCR) ARRAY, SHOWED DYSREGULATION OF SEVERAL CYTOKINE AND CYTOKINE RECEPTORS THAT ARE INVOLVED IN NEUROINFLAMMATORY PROCESSES. WE HAVE SHOWN ABERRANT HISTONE ACETYLATION PATTERNS INVOLVED IN BLAST INDUCED ASTROGLIOSIS AND COGNITIVE IMPAIRMENTS. FURTHER UNDERSTANDING OF THEIR ROLE IN THE INJURY PROGRESSION MAY LEAD TO NOVEL THERAPEUTIC TARGETS. 2016 15 2489 32 EPIGENETICALLY MODIFIED NUCLEOTIDES IN CHRONIC HEROIN AND COCAINE TREATED MICE. EPIGENETIC CHANGES INCLUDE THE ADDITION OF A METHYL GROUP TO THE 5' CARBON OF THE CYTOSINE RING, KNOWN AS DNA METHYLATION, WHICH RESULTS IN THE GENERATION OF THE FIFTH DNA BASE, NAMELY 5-METHYLCYTOSINE. DURING ACTIVE OR PASSIVE DEMETHYLATION, AN INTERMEDIATE MODIFIED BASE IS FORMED, 5-HYDROXYMETHYLCYTOSINE. WE HAVE CURRENTLY QUANTIFIED 5-METHYLCYTOSINE AND 5-HYDROXYMETHYLCYTOSINE IN THE LIVER AND BRAIN OF MICE TREATED WITH COCAINE OR HEROIN, USING LIQUID CHROMATOGRAPHY/TANDEM MASS SPECTROMETRY (LC-MS/MS). OUR RESULTS SHOW THAT GLOBAL 5-METHYLCYTOSINE LEVELS ARE NOT AFFECTED BY HEROIN OR COCAINE ADMINISTRATION, NEITHER IN THE LIVER NOR IN THE BRAIN. HOWEVER, 5-HYDROXYMETHYLCYTOSINE LEVELS ARE REDUCED IN THE LIVER FOLLOWING COCAINE ADMINISTRATION, WHILE THEY ARE NOT AFFECTED BY COCAINE IN THE BRAIN OR BY HEROIN ADMINISTRATION IN THE LIVER AND THE BRAIN. ELUCIDATION OF THE EPIGENETIC PHENOMENA THAT TAKES PLACE WITH RESPECT TO DRUG ABUSE AND ADDICTION, VIA QUANTITATIVE ANALYSIS OF DIFFERENT MODIFIED BASES, MAY ENABLE A BETTER UNDERSTANDING OF THE UNDERLYING MECHANISMS AND MAY LEAD TO MORE PERSONALIZED AND EFFECTIVE TREATMENT OPTIONS. 2014 16 920 26 CHRONIC HYPOXIA FACILITATES ALZHEIMER'S DISEASE THROUGH DEMETHYLATION OF GAMMA-SECRETASE BY DOWNREGULATING DNA METHYLTRANSFERASE 3B. INTRODUCTION: ENVIRONMENTAL FACTORS AND EPIGENETIC MECHANISMS ARE BELIEVED TO CONTRIBUTE TO ALZHEIMER'S DISEASE (AD). WE PREVIOUSLY DOCUMENTED THAT PRENATAL HYPOXIA AGGRAVATED THE COGNITIVE IMPAIRMENT AND NEUROPATHOLOGY IN OFFSPRING MICE. HERE, WE INVESTIGATE THE CHRONIC HYPOXIA-INDUCED EPIGENETIC MODIFICATIONS IN AD. METHODS: THE 3-MONTH-OLD APP(SWE)/PS1(DE9) MICE WERE EXPOSED TO HYPOXIC ENVIRONMENT 6 HOUR/DAY FOR 30 DAYS, FOLLOWED BY LEARNING AND MEMORY TESTS AND BIOCHEMICAL AND NEUROPATHOLOGY MEASUREMENT AT THE AGE OF 4, 6, AND 9 MONTHS. RESULTS: WE FOUND HYPOXIA EXAGGERATED THE NEUROPATHOLOGY AND COGNITIVE IMPAIRMENT IN AD MICE. CHRONIC HYPOXIA INDUCED DEMETHYLATION ON GENOMIC DNA AND DECREASED THE EXPRESSION OF DNA METHYLTRANSFERASE 3B (DNMT3B) IN VIVO. WE FURTHER FOUND THAT DNMTS INHIBITION ELEVATED THE PROTEIN LEVELS OF AMYLOID PRECURSOR PROTEIN, BETA- AND GAMMA-SECRETASES, WHEREAS OVEREXPRESSION OF DNMT3B SUPPRESSED THE LEVELS OF THEM IN VITRO. DISCUSSION: OUR STUDY SUGGESTS CHRONIC HYPOXIA CAN AGGRAVATE AD PROGRESSION THROUGH DEMETHYLATION OF GENES ENCODING GAMMA-SECRETASE COMPONENTS BY DOWNREGULATION OF DNMT3B. 2016 17 226 35 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 18 5007 33 PERIPHERAL NERVE INJURY IS ASSOCIATED WITH CHRONIC, REVERSIBLE CHANGES IN GLOBAL DNA METHYLATION IN THE MOUSE PREFRONTAL CORTEX. CHANGES IN BRAIN STRUCTURE AND CORTICAL FUNCTION ARE ASSOCIATED WITH MANY CHRONIC PAIN CONDITIONS INCLUDING LOW BACK PAIN AND FIBROMYALGIA. THE MAGNITUDE OF THESE CHANGES CORRELATES WITH THE DURATION AND/OR THE INTENSITY OF CHRONIC PAIN. MOST STUDIES REPORT CHANGES IN COMMON AREAS INVOLVED IN PAIN MODULATION, INCLUDING THE PREFRONTAL CORTEX (PFC), AND PAIN-RELATED PATHOLOGICAL CHANGES IN THE PFC CAN BE REVERSED WITH EFFECTIVE TREATMENT. WHILE THE MECHANISMS UNDERLYING THESE CHANGES ARE UNKNOWN, THEY MUST BE DYNAMICALLY REGULATED. EPIGENETIC MODULATION OF GENE EXPRESSION IN RESPONSE TO EXPERIENCE AND ENVIRONMENT IS REVERSIBLE AND DYNAMIC. EPIGENETIC MODULATION BY DNA METHYLATION IS ASSOCIATED WITH ABNORMAL BEHAVIOR AND PATHOLOGICAL GENE EXPRESSION IN THE CENTRAL NERVOUS SYSTEM. DNA METHYLATION MIGHT ALSO BE INVOLVED IN MEDIATING THE PATHOLOGIES ASSOCIATED WITH CHRONIC PAIN IN THE BRAIN. WE THEREFORE TESTED A) WHETHER ALTERATIONS IN DNA METHYLATION ARE FOUND IN THE BRAIN LONG AFTER CHRONIC NEUROPATHIC PAIN IS INDUCED IN THE PERIPHERY USING THE SPARED NERVE INJURY MODAL AND B) WHETHER THESE INJURY-ASSOCIATED CHANGES ARE REVERSIBLE BY INTERVENTIONS THAT REVERSE THE PATHOLOGIES ASSOCIATED WITH CHRONIC PAIN. SIX MONTHS FOLLOWING PERIPHERAL NERVE INJURY, ABNORMAL SENSORY THRESHOLDS AND INCREASED ANXIETY WERE ACCOMPANIED BY DECREASED GLOBAL METHYLATION IN THE PFC AND THE AMYGDALA BUT NOT IN THE VISUAL CORTEX OR THE THALAMUS. ENVIRONMENTAL ENRICHMENT ATTENUATED NERVE INJURY-INDUCED HYPERSENSITIVITY AND REVERSED THE CHANGES IN GLOBAL PFC METHYLATION. FURTHERMORE, GLOBAL PFC METHYLATION CORRELATED WITH MECHANICAL AND THERMAL SENSITIVITY IN NEUROPATHIC MICE. IN SUMMARY, INDUCTION OF CHRONIC PAIN BY PERIPHERAL NERVE INJURY IS ASSOCIATED WITH EPIGENETIC CHANGES IN THE BRAIN. THESE CHANGES ARE DETECTED LONG AFTER THE ORIGINAL INJURY, AT A LONG DISTANCE FROM THE SITE OF INJURY AND ARE REVERSIBLE WITH ENVIRONMENTAL MANIPULATION. CHANGES IN BRAIN STRUCTURE AND CORTICAL FUNCTION THAT ARE ASSOCIATED WITH CHRONIC PAIN CONDITIONS MAY THEREFORE BE MEDIATED BY EPIGENETIC MECHANISMS. 2013 19 2417 33 EPIGENETIC SIGNATURE OF CHRONIC CEREBRAL HYPOPERFUSION AND BENEFICIAL EFFECTS OF S-ADENOSYLMETHIONINE IN RATS. CHRONIC CEREBRAL HYPOPERFUSION IS ASSOCIATED WITH COGNITIVE DECLINE IN AGING AND AGE-RELATED NEURODEGENERATIVE DISEASE. EPIGENETIC MECHANISMS ARE INVOLVED IN THE MAINTENANCE OF LONG-TERM HYPOXIA-ADAPTED CELLULAR PHENOTYPES. IN THE PRESENT STUDY, THE EPIGENETIC SIGNATURES SUCH AS DNA METHYLATION AND HISTONE ACETYLATION, AS WELL AS S-ADENOSYLMETHIONINE (SAM) CYCLE USING CHRONIC CEREBRAL HYPOPERFUSION RAT MODEL WERE EXPLORED. CHRONIC CEREBRAL HYPOXIA-INDUCED GLOBAL DNA HYPERMETHYLATION ASSOCIATED WITH THE INCREASE OF DNA METHYLTRANSFERASE (DNMT) 3A AS WELL AS ALTERATION OF SAM CYCLE. MEANWHILE, AN ENHANCED LEVEL OF GLOBAL HISTONE H4 ACETYLATION ACCOMPANIED WITH THE UPREGULATION OF HISTONE ACETYLTRANSFERASE, P300/CREB-BINDING PROTEIN (CBP), AND THE DOWNREGULATION OF HISTONE DEACETYLASES (HDACS), WAS ALSO OBSERVED. SAM COULD IMPROVE SPATIAL CAPACITY THROUGH THE UPREGULATION OF ACETYLCHOLINE AND BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) RATHER THAN ALTERATION OF DNA METHYLATION LEVELS. IN CONCLUSION, WE HAVE DEMONSTRATED A GENOME-WIDE ADJUSTMENT OF DNA METHYLATION AND HISTONE ACETYLATION UNDER CHRONIC CEREBRAL HYPOXIC CONDITIONS IN A RAT'S BRAIN. THESE EPIGENETIC SIGNATURES MAY REPRESENT AN ADDITIONAL MECHANISM TO PROMOTE AND MAINTAIN A HYPOXIC-ADAPTED CELLULAR RESPONDS WITH A POTENTIAL ROLE IN MEMORY DEFICITS. 2014 20 2442 31 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