1  1718 118 DYSREGULATED LONG NON-CODING RNAS IN THE TEMPORAL LOBE EPILEPSY MOUSE MODEL. PURPOSE: TO PERFORM COMPREHENSIVE PROFILING OF LONG NON-CODING RNAS (LNCRNAS) IN TEMPORAL LOBE EPILEPSY. METHODS: WE PERFORMED EXTENSIVE PROFILING OF LNCRNAS AND MRNAS IN THE MOUSE PILOCARPINE MODEL IN SPECIFIC BRAIN REGIONS, THE HIPPOCAMPUS AND CORTEX, AND COMPARED THE RESULTS TO THOSE OF THE CONTROL MOUSE. DIFFERENTIALLY EXPRESSED LNCRNAS AND MRNAS WERE IDENTIFIED WITH A MICROARRAY ANALYSIS (ARRAYSTAR MOUSE LNCRNA EXPRESSION MICROARRAY V3.0). THEN, GENE ONTOLOGY (GO) AND PATHWAY ANALYSIS WERE PERFORMED TO INVESTIGATE THE POTENTIAL ROLES OF THE DIFFERENTIALLY EXPRESSED MRNAS IN THE PILOCARPINE MODEL. PROTEIN-PROTEIN INTERACTIONS TRANSCRIBED BY DYSREGULATED MRNAS WITH/WITHOUT CO-DYSREGULATED LNCRNAS WERE ANALYZED USING STRING V10 (HTTP://STRING-DB.ORG/). RESULTS: A TOTAL OF 22 AND 83 LNCRNAS WERE UP- AND DOWN-REGULATED (>/=2.0-FOLD, ALL P < .05), RESPECTIVELY, IN THE HIPPOCAMPUS OF THE EPILEPSY MODEL, WHILE 46 AND 659 LNCRNAS WERE UP- AND DOWN-REGULATED, RESPECTIVELY, IN THE CORTEX OF THE EPILEPSY MODEL. GO AND PATHWAY ANALYSIS REVEALED THAT THE DYSREGULATED MRNAS WERE CLOSELY ASSOCIATED WITH A PROCESS ALREADY KNOWN TO BE INVOLVED IN EPILEPTOGENESIS: ACUTE INFLAMMATION, CALCIUM ION REGULATION, EXTRACELLULAR MATRIX REMODELING, AND NEURONAL DIFFERENTIATION. AMONG THE LNCRNAS, WE IDENTIFIED 10 LNCRNAS COMMONLY DYSREGULATED WITH CORRESPONDING MRNAS IN THE CORTEX. THE STRING ANALYSIS SHOWED THAT THE DYSREGULATED MRNAS WERE INTERCONNECTED AROUND TWO CENTERS: THE MTOR PATHWAY-RELATED GENES AND REST PATHWAY-RELATED GENES. CONCLUSION: LNCRNAS WERE DYSREGULATED IN THE PILOCARPINE MOUSE MODEL ACCORDING TO THE BRAIN REGIONS OF THE HIPPOCAMPUS AND CORTEX. THE DYSREGULATED LNCRNAS WITH CO-DYSREGULATED MRNAS MIGHT BE POSSIBLE THERAPEUTIC TARGETS FOR THE EPIGENETIC REGULATION OF CHRONIC EPILEPSY.	2018	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                               
2  2755  33 EXPRESSION OF CLASS II HISTONE DEACETYLASES IN TWO MOUSE MODELS OF TEMPORAL LOBE EPILEPSY. EPIGENETIC MECHANISMS LIKE ALTERED HISTONE ACETYLATION MAY HAVE A CRUCIAL ROLE IN EPILEPTOGENESIS. IN TWO MOUSE MODELS OF TEMPORAL LOBE EPILEPSY, WE INVESTIGATED CHANGES IN THE EXPRESSION OF CLASS II HISTONE DEACETYLASES (HDAC), A GROUP OF SIGNAL TRANSDUCERS THAT SHUTTLE BETWEEN NUCLEUS AND CYTOPLASM. INTRAHIPPOCAMPAL INJECTION OF KAINIC ACID (KA) INDUCED A STATUS EPILEPTICUS, DEVELOPMENT OF SPONTANEOUS SEIZURES (AFTER 3 DAYS), AND FINALLY CHRONIC EPILEPSY AND GRANULE CELL DISPERSION. EXPRESSION OF CLASS II HDAC MRNAS WAS INVESTIGATED AT DIFFERENT TIME INTERVALS AFTER KA INJECTION IN THE GRANULE CELL LAYERS AND IN SECTORS CA1 AND CA3 CONTRALATERAL TO THE SITE OF KA INJECTION LACKING NEURODEGENERATION. INCREASED EXPRESSION OF HDAC5 AND 9 MRNAS COINCIDED WITH PRONOUNCED GRANULE CELL DISPERSION IN THE KA-INJECTED HIPPOCAMPUS AT LATE INTERVALS (14-28 DAYS AFTER KA) AND EQUALLY AFFECTED BOTH HDAC9 SPLICE VARIANTS. IN CONTRAST, IN THE PILOCARPINE MODEL (SHOWING NO GRANULE CELL DISPERSION), WE OBSERVED DECREASES IN THE EXPRESSION OF HDAC5 AND 9 AT THE SAME TIME INTERVALS. BEYOND THIS, STRIKING SIMILARITIES BETWEEN BOTH TEMPORAL LOBE EPILEPSY MODELS SUCH AS FAST DECREASES IN HDAC7 AND 10 MRNAS DURING THE ACUTE STATUS EPILEPTICUS WERE OBSERVED, NOTABLY ALSO IN THE CONTRALATERAL HIPPOCAMPUS NOT AFFECTED BY NEURODEGENERATION. THE PARTICULAR PATTERNS OF HDAC MRNA EXPRESSION SUGGEST A ROLE IN EPILEPTOGENESIS AND GRANULE CELL DISPERSION. REDUCED EXPRESSION OF HDACS MAY RESULT IN INCREASED EXPRESSION OF PRO- AND ANTICONVULSIVE PROTEINS. ON THE OTHER HAND, EXPORT OF HDACS FROM THE NUCLEUS INTO THE CYTOPLASM COULD ALLOW FOR DEACETYLATION OF CYTOPLASMATIC PROTEINS INVOLVED IN AXONAL AND DENDRITIC REMODELING, LIKE GRANULE CELL DISPERSION. HDAC 5 AND HDAC 9 EXPRESSION IS HIGHLY INCREASED IN GRANULE CELLS OF THE KA-INJECTED HIPPOCAMPUS AND PARALLELS GRANULE CELL DISPERSION. BOTH HDACS ARE THOUGHT TO BE TARGETED TO THE CYTOPLASM AND TO ACT THERE BY DEACETYLATING CYTOPLASMATIC (E.G. CYTOSCELETON-RELATED) PROTEINS.	2016	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                          
3  5345  38 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  1727  53 DYSREGULATION OF LONG NON-CODING RNAS IN MOUSE MODELS OF LOCALIZATION-RELATED EPILEPSY. GENOME-WIDE PROFILING HAS REVEALED THAT EUKARYOTIC GENOMES ARE TRANSCRIBED INTO NUMEROUS NON-CODING RNAS. IN PARTICULAR, LONG NON-CODING RNAS (LNCRNAS) HAVE BEEN IMPLICATED IN VARIOUS HUMAN DISEASES DUE TO THEIR BIOCHEMICAL AND FUNCTIONAL DIVERSITY. EPILEPTIC DISORDERS HAVE BEEN CHARACTERIZED BY DYSREGULATION OF EPIGENETIC REGULATORY MECHANISMS, AND RECENT STUDIES HAVE IDENTIFIED SEVERAL LNCRNAS INVOLVED IN NEURAL DEVELOPMENT AND NETWORK FUNCTION. HOWEVER, COMPREHENSIVE PROFILING OF LNCRNAS IMPLICATED IN CHRONIC EPILEPSY HAS BEEN LACKING. IN THIS STUDY, MICROARRAY ANALYSIS WAS PERFORMED TO OBTAIN THE EXPRESSION PROFILE OF LNCRNAS DYSREGULATED IN PILOCARPINE AND KAINATE MODELS, TWO MODELS OF TEMPORAL LOBE EPILEPSY COMMONLY USED FOR STUDYING EPILEPTIC MECHANISMS. TOTAL OF 4622 LNCRNAS WERE ANALYZED: 384 LNCRNAS WERE SIGNIFICANTLY DYSREGULATED IN PILOCARPINE MODEL, AND 279 LNCRNAS WERE SIGNIFICANTLY DYSREGULATED IN KAINATE MODEL COMPARED WITH CONTROL MICE (>/=3.0-FOLD, P < 0.05). AMONG THESE, 54 AND 14 LNCRNAS, RESPECTIVELY, HAD ADJACENT PROTEIN-CODING GENES WHOSE EXPRESSIONS WERE ALSO SIGNIFICANTLY DYSREGULATED (>/=2.0-FOLD, P < 0.05). MAJORITY OF THESE PAIRS OF LNCRNAS AND ADJACENT GENES SHARED THE SAME DIRECTION OF DYSREGULATION. FOR THE SELECTED ADJACENT GENE-LNCRNA PAIRS, SIGNIFICANT GENE ONTOLOGY TERMS WERE EMBRYONIC APPENDAGE MORPHOGENESIS AND NEURON DIFFERENTIATION. THIS WAS THE FIRST STUDY TO COMPREHENSIVELY IDENTIFY DYSREGULATED LNCRNAS IN TWO DIFFERENT MODELS OF CHRONIC EPILEPSY AND WILL LIKELY PROVIDE A NOVEL INSIGHT INTO DEVELOPING LNCRNA THERAPEUTICS.	2015	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                   
5  5120  43 POSSIBLE EPIGENETIC REGULATORY EFFECT OF DYSREGULATED CIRCULAR RNAS IN EPILEPSY. CIRCULAR RNAS (CIRCRNAS) INVOLVE IN THE EPIGENETIC REGULATION AND ITS MAJOR MECHANISM IS THE SEQUESTRATION OF THE TARGET MICRO RNAS (MIRNAS). WE HYPOTHESIZED THAT CIRCRNAS MIGHT BE RELATED WITH THE PATHOPHYSIOLOGY OF CHRONIC EPILEPSY AND EVALUATED THE ALTERED CIRCRNA EXPRESSIONS AND THEIR POSSIBLE REGULATORY EFFECTS ON THEIR TARGET MIRNAS AND MRNAS IN A MOUSE EPILEPSY MODEL. THE CIRCRNA EXPRESSION PROFILE IN THE HIPPOCAMPUS OF THE PILOCARPINE MICE WAS ANALYZED AND COMPARED WITH CONTROL. THE CORRELATION BETWEEN THE EXPRESSION OF MIRNA BINDING SITES (MIRNA RESPONSE ELEMENTS, MRE) IN THE DYSREGULATED CIRCRNAS AND THE EXPRESSION OF THEIR TARGET MIRNAS WAS EVALUATED. AS MIRNAS ALSO INHIBIT THEIR TARGET MRNAS, CIRCRNA-MIRNA-MRNA REGULATORY NETWORK, COMPRISED OF DYSREGULATED RNAS THAT TARGETS ONE ANOTHER WERE SEARCHED. FOR THE IDENTIFIED NETWORKS, BIOINFORMATICS ANALYSES WERE PERFORMED. AS THE RESULT, FORTY-THREE CIRCRNAS WERE DYSREGULATED IN THE HIPPOCAMPUS (UP-REGULATED, 26; DOWN-REGULATED, 17). THE CHANGE IN THE EXPRESSION OF MRE IN THOSE CIRCRNAS NEGATIVELY CORRELATED WITH THE CHANGE IN THE RELEVANT TARGET MIRNA EXPRESSION (R = -0.461, P<0.001), SUPPORTING THAT CIRCRNAS INHIBIT THEIR TARGET MIRNA. 333 DYSREGULATED CIRCRNA-MIRNA-MRNA NETWORKS WERE IDENTIFIED. GENE ONTOLOGY AND PATHWAY ANALYSES DEMONSTRATED THAT THE UP-REGULATED MRNAS IN THOSE NETWORKS WERE CLOSELY RELATED TO THE MAJOR PROCESSES IN EPILEPSY. AMONG THEM, STRING ANALYSIS IDENTIFIED 37 KEY MRNAS WITH ABUNDANT (>/=4) INTERACTIONS WITH OTHER DYSREGULATED TARGET MRNAS. THE DYSREGULATION OF THE CIRCRNAS WHICH HAD MULTIPLE INTERACTIONS WITH KEY MRNAS WERE VALIDATED BY PCR. WE CONCLUDED THAT DYSREGULATED CIRCRNAS MIGHT HAVE A PATHOPHYSIOLOGIC ROLE IN CHRONIC EPILEPSY BY REGULATING MULTIPLE DISEASE RELEVANT MRNAS VIA CIRCRNA-MIRNA-MRNA INTERACTIONS.	2018	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                      
6  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	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                        
7  3647  26 INCREASED REELIN PROMOTER METHYLATION IS ASSOCIATED WITH GRANULE CELL DISPERSION IN HUMAN TEMPORAL LOBE EPILEPSY. MESIAL TEMPORAL SCLEROSIS (MTS) IS THE MOST COMMON LESION IN CHRONIC, INTRACTABLE TEMPORAL LOBE EPILEPSIES (TLE) AND CHARACTERIZED BY SEGMENTAL NEURONAL CELL LOSS IN MAJOR HIPPOCAMPAL SEGMENTS. ANOTHER HISTOPATHOLOGICAL HALLMARK INCLUDES GRANULE CELL DISPERSION (GCD), AN ARCHITECTURAL DISTURBANCE OF THE DENTATE GYRUS ENCOUNTERED IN APPROXIMATELY 50% OF PATIENTS WITH MESIAL TEMPORAL SCLEROSIS. REELIN, WHICH PLAYS A KEY ROLE DURING HIPPOCAMPAL DEVELOPMENT AND MAINTENANCE OF LAMINAR ORGANIZATION, IS SYNTHESIZED AND RELEASED BY CAJAL-RETZIUS CELLS OF THE DENTATE MOLECULAR LAYER, AND PREVIOUS STUDIES HAVE SHOWN THAT REELIN TRANSCRIPT LEVELS ARE DOWNREGULATED IN HUMAN TEMPORAL LOBE EPILEPSIES SPECIMENS. TO INVESTIGATE WHETHER EPIGENETIC SILENCING BY REELIN PROMOTER METHYLATION MAY BE AN UNDERLYING PATHOGENETIC MECHANISM OF GCD, DNA WAS HARVESTED FROM 3 MICRODISSECTED HIPPOCAMPAL SUBREGIONS (I.E. MOLECULAR AND GRANULE CELL LAYERS OF THE DENTATE GYRUS AND PRESUBICULUM) FROM 8 MTS SPECIMENS WITH GCD, 5 TLE SAMPLES WITHOUT GCD, AND 3 AUTOPSY CONTROLS. PROMOTER METHYLATION WAS ANALYZED AFTER BISULFITE TREATMENT, CLONING, AND DIRECT SEQUENCING; IMMUNOHISTOCHEMISTRY WAS PERFORMED TO IDENTIFY CAJAL-RETZIUS CELLS. REELIN PROMOTER METHYLATION WAS FOUND TO BE GREATER IN TLE SPECIMENS THAN IN CONTROLS; PROMOTER METHYLATION CORRELATED WITH GCD AMONG TLE SPECIMENS (P < 0.0002). NO OTHER CLINICAL OR HISTOPATHOLOGICAL PARAMETER (I.E. SEX, AGE, SEIZURE DURATION, MEDICATION OR EXTENT, OF MTS) CORRELATED WITH PROMOTER METHYLATION. THESE DATA SUPPORT A COMPROMISED REELIN-SIGNALING PATHWAY AND IDENTIFY PROMOTER METHYLATION AS AN EPIGENETIC MECHANISM IN THE PATHOGENESIS OF TLE.	2009	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                               
8  3494  35 IDENTIFICATION OF MICRORNAS WITH DYSREGULATED EXPRESSION IN STATUS EPILEPTICUS INDUCED EPILEPTOGENESIS. THE INVOLVEMENT OF MIRNA IN MESIAL TEMPORAL LOBE EPILEPSY (MTLE) PATHOGENESIS HAS INCREASINGLY BECOME A FOCUS OF EPIGENETIC STUDIES. DESPITE ADVANCES, THE NUMBER OF KNOWN MIRNAS WITH A CONSISTENT EXPRESSION RESPONSE DURING EPILEPTOGENESIS IS STILL SMALL. ADDRESSING THIS SITUATION REQUIRES ADDITIONAL MIRNA PROFILING STUDIES COUPLED TO DETAILED INDIVIDUAL EXPRESSION ANALYSES. HERE, WE PERFORM A MIRNA MICROARRAY ANALYSIS OF THE HIPPOCAMPUS OF WISTAR RATS 24 HOURS AFTER INTRA-HIPPOCAMPAL PILOCARPINE-INDUCED STATUS EPILEPTICUS (H-PILO SE). WE IDENTIFIED 73 MIRNAS THAT UNDERGO SIGNIFICANT CHANGES, OF WHICH 36 WERE UP-REGULATED AND 37 WERE DOWN-REGULATED. TO VALIDATE, WE SELECTED 5 OF THESE (10A-5P, 128A-3P, 196B-5P, 352 AND 324-3P) FOR RT-QPCR ANALYSIS. OUR RESULTS CONFIRMED THAT MIR-352 AND 196B-5P LEVELS WERE SIGNIFICANTLY HIGHER AND MIR-128A-3P LEVELS WERE SIGNIFICANTLY LOWER IN THE HIPPOCAMPUS OF H-PILO SE RATS. WE ALSO EVALUATED WHETHER THE 3 MIRNAS SHOW A DYSREGULATED HIPPOCAMPAL EXPRESSION AT THREE TIME PERIODS (0H, 24H AND CHRONIC PHASE) AFTER SYSTEMIC PILOCARPINE-INDUCED STATUS EPILEPTICUS (S-PILO SE). WE DEMONSTRATE THAT MIR-128A-3P TRANSCRIPTS ARE SIGNIFICANTLY REDUCED AT ALL TIME POINTS COMPARED TO THE NAIVE GROUP. MOREOVER, MIR-196B-5P WAS SIGNIFICANTLY HIGHER ONLY AT 24H POST-SE, WHILE MIR-352 TRANSCRIPTS WERE SIGNIFICANTLY UP-REGULATED AFTER 24H AND IN CHRONIC PHASE (EPILEPTIC) RATS. FINALLY, WHEN WE COMPARED HIPPOCAMPI OF EPILEPTIC AND NON-EPILEPTIC HUMANS, WE OBSERVED THAT TRANSCRIPT LEVELS OF MIRNAS SHOW SIMILAR TRENDS TO THE ANIMAL MODELS. IN SUMMARY, WE SUCCESSFULLY IDENTIFIED TWO NOVEL DYSREGULATED MIRNAS (196B-5P AND 352) AND CONFIRMED MIR-128A-3P DOWNREGULATION IN SE-INDUCED EPILEPTOGENESIS. FURTHER FUNCTIONAL ASSAYS ARE REQUIRED TO UNDERSTAND THE ROLE OF THESE MIRNAS IN MTLE PATHOGENESIS.	2016	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                          
9  2116  27 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	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                       
10  5348  30 RASGRF1, A POTENTIAL METHYLATIC MEDIATOR OF ANTI-EPILEPTOGENESIS? EPILEPTOGENESIS, INDUCED BY STATUS EPILEPTICUS (SE), IS A CHRONIC PROCESS, AND INTERVENTION IN THIS PROGRESS MAY PREVENT CHRONIC EPILEPSY. IT HAS BEEN PROPOSED THAT DNA METHYLATION MIGHT BE RELATED WITH EPILEPTOGENESIS. RASGRF1 HAS A DIFFERENTIALLY METHYLATED REGION AT THE PROMOTER WHICH CAN SILENCE GENE EXPRESSION. WE HAVE PREVIOUSLY OBSERVED THE DOWN-REGULATION OF RASGRF1 IN EPILEPSY PATIENTS AND PROVED THAT HYPERMETHYLATION OF RASGRF1 REACHES MAXIMAL LEVEL AT THE LATENT PERIOD IN MICE AFTER KAINATE-INDUCED SE (KA MICE), WITH CORRESPONDING ALTERATION OF RASGRF1 EXPRESSION. IN THE PRESENT STUDY, N-PHTHALYL-L-TRYPTOPHAN (RG108), A DNA METHYLTRANSFERASE INHIBITOR, WAS APPLIED IN KA MICE AT LATENT PHASE AND THE BEHAVIOR, ELECTROENCEPHALOGRAM AND PATHOLOGICAL CHANGES WERE OBSERVED IN CHRONIC PHASE. METHYLATION AND EXPRESSION OF RASGRF1 WERE DETERMINED BY POLYMERASE CHAIN REACTION (PCR), WESTERN BLOTTING, AND BISULFITE SEQUENCING PCR. THE RESULTS SHOWED THAT THE INCIDENCE OF SPONTANEOUS RECURRENT SEIZURES (SRS) WAS SIGNIFICANTLY LOWER IN THE RG108 GROUP THAN THE NORMAL SALINE (NS) GROUP. SUBGROUP ANALYSIS SHOWED SIGNIFICANT HYPERMETHYLATION AND LOWER EXPRESSION OF RASGRF1 IN THE RG108-SRS SUBGROUP AND THE NS-SRS SUBGROUP BUT NOT IN THE RG108-NSRS (NO SRS) SUBGROUP AND THE NS-NSRS SUBGROUP COMPARED WITH THE CONTROL GROUP. NO SIGNIFICANT DIFFERENCE WAS FOUND BETWEEN THE RG108-SRS AND NS-SRS SUBGROUPS. MEANWHILE, HIPPOCAMPAL NEURONAL LOSS WAS OBSERVED IN RG108-SRS AND NS-SRS SUBGROUPS. WE THUS DEMONSTRATED THAT RG108 COULD MODIFY THE PROGRESSION OF EPILEPTOGENESIS AFTER KA INDUCED SE AND PREVENT CHRONIC EPILEPSY. MEANWHILE, HYPERMETHYLATION OF RASGRF1 AFTER KA INDUCED SE COULD BE REVERSED WITH CORRESPONDING CHANGES OF RASGRF1 EXPRESSION. ADDITIONALLY, WE SPECULATED THAT RASGRF1 MIGHT BE A POTENTIAL EPIGENETIC MEDIATOR IN EPILEPTOGENESIS AND CHRONIC EPILEPSY.	2018	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                 
11   124  37 A SYSTEMS APPROACH DELIVERS A FUNCTIONAL MICRORNA CATALOG AND EXPANDED TARGETS FOR SEIZURE SUPPRESSION IN TEMPORAL LOBE EPILEPSY. TEMPORAL LOBE EPILEPSY IS THE MOST COMMON DRUG-RESISTANT FORM OF EPILEPSY IN ADULTS. THE REORGANIZATION OF NEURAL NETWORKS AND THE GENE EXPRESSION LANDSCAPE UNDERLYING PATHOPHYSIOLOGIC NETWORK BEHAVIOR IN BRAIN STRUCTURES SUCH AS THE HIPPOCAMPUS HAS BEEN SUGGESTED TO BE CONTROLLED, IN PART, BY MICRORNAS. TO SYSTEMATICALLY ASSESS THEIR SIGNIFICANCE, WE SEQUENCED ARGONAUTE-LOADED MICRORNAS TO DEFINE FUNCTIONALLY ENGAGED MICRORNAS IN THE HIPPOCAMPUS OF THREE DIFFERENT ANIMAL MODELS IN TWO SPECIES AND AT SIX TIME POINTS BETWEEN THE INITIAL PRECIPITATING INSULT THROUGH TO THE ESTABLISHMENT OF CHRONIC EPILEPSY. WE THEN SELECTED COMMONLY UP-REGULATED MICRORNAS FOR A FUNCTIONAL IN VIVO THERAPEUTIC SCREEN USING OLIGONUCLEOTIDE INHIBITORS. ARGONAUTE SEQUENCING GENERATED 1.44 BILLION SMALL RNA READS OF WHICH UP TO 82% WERE MICRORNAS, WITH OVER 400 UNIQUE MICRORNAS DETECTED PER MODEL. APPROXIMATELY HALF OF THE DETECTED MICRORNAS WERE DYSREGULATED IN EACH EPILEPSY MODEL. WE PRIORITIZED COMMONLY UP-REGULATED MICRORNAS THAT WERE FULLY CONSERVED IN HUMANS AND DESIGNED CUSTOM ANTISENSE OLIGONUCLEOTIDES FOR THESE CANDIDATE TARGETS. ANTISEIZURE PHENOTYPES WERE OBSERVED UPON KNOCKDOWN OF MIR-10A-5P, MIR-21A-5P, AND MIR-142A-5P AND ELECTROPHYSIOLOGICAL ANALYSES INDICATED BROAD SAFETY OF THIS APPROACH. COMBINED INHIBITION OF THESE THREE MICRORNAS REDUCED SPONTANEOUS SEIZURES IN EPILEPTIC MICE. PROTEOMIC DATA, RNA SEQUENCING, AND PATHWAY ANALYSIS ON PREDICTED AND VALIDATED TARGETS OF THESE MICRORNAS IMPLICATED DEREPRESSED TGF-BETA SIGNALING AS A SHARED SEIZURE-MODIFYING MECHANISM. CORRESPONDINGLY, INHIBITION OF TGF-BETA SIGNALING OCCLUDED THE ANTISEIZURE EFFECTS OF THE ANTAGOMIRS. TOGETHER, THESE RESULTS IDENTIFY SHARED, DYSREGULATED, AND FUNCTIONALLY ACTIVE MICRORNAS DURING THE PATHOGENESIS OF EPILEPSY WHICH REPRESENT THERAPEUTIC ANTISEIZURE TARGETS.	2020	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                        
12   510  30 ASSOCIATION OF RASGRF1 METHYLATION WITH EPILEPTIC SEIZURES. DNA METHYLATION, ONE OF THE MECHANISMS OF EPIGENETIC REGULATION, HAS BEEN SUGGESTED TO BE RELATED WITH EPILEPSY. RASGRF1 IS A PATERNALLY IMPRINTED GENE AND HAS A DIFFERENTIALLY METHYLATED REGION (DMR) AT THE PROMOTER THAT CAN SILENCE GENE EXPRESSION. WE HAVE PREVIOUSLY OBSERVED THE DOWN-REGULATION OF RASGRF1 IN THE TEMPORAL NEOCORTEX OF EPILEPSY PATIENTS AND IN THE HIPPOCAMPUS OF EPILEPTIC ANIMALS. HERE, WE FURTHER EXPLORED THE DYNAMIC CHANGE (1-DAY ACUTE PERIOD, 10-DAY LATENT PERIOD AND 45-DAY CHRONIC PHASE) OF DNA METHYLATION AND RASGRF1 EXPRESSION AFTER ACUTE EPILEPTIC SEIZURES IN KAINIC ACID (KA)-TREATED MICE, AND WE OBSERVED THE IMPACT OF N-PHTHALYL-L-TRYPTOPHAN (RG108), A DNA METHYLTRANSFERASE (DNMT) INHIBITOR, ON AN ACUTE EPILEPTIC MODEL BY POLYMERASE CHAIN REACTION (PCR), WESTERN BLOTTING, AND BISULFITE SEQUENCING PCR (BSP). THE RESULTS DIRECTLY SHOWED THAT THE METHYLATION OF THE RASGRF1 PROMOTER GRADUALLY INCREASED AND REACHED A MAXIMAL LEVEL AT THE LATENT PERIOD, WITH SUBSEQUENT SUPPRESSION OF RASGRF1 MRNA AND PROTEIN EXPRESSION LEVELS, WHICH REACHED A MINIMUM LEVEL IN THE CHRONIC PHASE. RG108 INHIBITED THE INCREASED METHYLATION OF THE RASGRF1 GENE, WITH SIGNIFICANT INHIBITION OCCURRING AT THE LATENT PERIOD, AND RESTORED RASGRF1 EXPRESSION LEVELS IN THE CHRONIC PHASE. IN ADDITION, WE DEMONSTRATED THAT RG108 COULD SUPPRESS ACUTE EPILEPTIC SEIZURES IN KA-TREATED MICE AND EPILEPTIC DISCHARGES IN 4-AMINOPYRIDINE (4-AP)-TREATED HIPPOCAMPAL SLICES. THESE FINDINGS DEMONSTRATE THAT RASGRF1 IS CLOSELY ASSOCIATED WITH EPILEPSY VIA THE ABERRANT METHYLATION OF RASGRF1, AND REGULATING THE METHYLATION STATUS OF RELEVANT GENES MIGHT BE AN INTRIGUING TOPIC IN FUTURE RESEARCH ON EPILEPSY.	2017	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                    
13  1129  38 COMPREHENSIVE ANALYSIS OF MRNA-LNCRNA CO-EXPRESSION PROFILES IN MOUSE BRAIN DURING INFECTION WITH TOXOPLASMA GONDII. TOXOPLASMA GONDII IS AN OBLIGATE INTRACELLULAR PROTOZOAN PARASITE WHICH SERIOUSLY THREATENS THE HEALTH OF DOMESTIC ANIMALS AND HUMANS. LONG NON-CODING RNAS (LNCRNAS) ARE NON-PROTEIN-CODING TRANSCRIPTS GREATER THAN 200 NUCLEOTIDES, WHICH ARE WIDELY INVOLVED IN TRANSCRIPTIONAL AND EPIGENETIC REGULATIONS. HOWEVER, LITTLE IS KNOWN ABOUT THE ROLES OF HOST LNCRNAS IN THE RESPONSE TO T. GONDII INFECTIONS. IN THIS STUDY, USING ILLUMINA SEQUENCING TECHNOLOGY, WE ANALYZED THE EXPRESSION PROFILES OF MRNAS AND LNCRNAS IN BALB/C MOUSE BRAIN FOLLOWING INFECTION BY T. GONDII PRU STRAIN (TYPE II GENOTYPE) CYSTS. THE IDENTIFIED DIFFERENTIALLY EXPRESSED (DE) RNAS WERE SUBJECTED TO BIOINFORMATICS ANALYSIS. A TOTAL OF 2,090 ANNOTATED LNCRNAS ALONG WITH 3,577 NOVEL LNCRNAS WERE IDENTIFIED. IN THE ACUTELY INFECTED MOUSE BRAIN, A TOTAL OF 330 MRNAS AND 19 LNCRNAS WERE DYS-REGULATED, WHEREAS 136 DE MRNAS AND 9 DE LNCRNAS WERE IDENTIFIED IN CHRONICALLY INFECTED MOUSE BRAIN. GO ANALYSIS REVEALED THAT THESE DE MRNAS IDENTIFIED AT ACUTE INFECTION STAGE WERE INVOLVED IN IMMUNE RESPONSE, WHEREAS DE MRNAS FOUND AT CHRONIC INFECTION STAGE WERE MOSTLY ENRICHED IN RESPONSE TO PROTOZOAN. KEGG ANALYSIS SHOWED THAT DE MRNAS WERE SIGNIFICANTLY ENRICHED IN DISEASE RELATED PATHWAYS. IN ADDITION, THE PUTATIVE MRNA-LNCRNA CO-EXPRESSION NETWORK WAS CONSTRUCTED, AND SEVERAL HUB REGULATORY RNAS WERE IDENTIFIED BASED ON THE TRANSCRIPTOME DATA. THIS STUDY FIRSTLY CHARACTERIZED THE CO-EXPRESSION PROFILE OF MRNAS AND LNCRNAS IN MOUSE BRAIN INFECTED WITH T. GONDII AND PROVIDED A FRAMEWORK FOR FURTHER STUDIES OF THE ROLES OF LNCRNAS IN HOST NEUROPATHOLOGY DURING TOXOPLASMOSIS PROGRESSION.	2023	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                       
14  5617  34 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	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                 
15  3947  28 LNCRNA UCA1 INDUCES AUTOPHAGIC GENE EXPRESSION VIA EPIGENETIC REGULATION MEDIATED BY ATG16L1 AND MIR-132-3P IN SH-SY5Y CELLS TREATED WITH RETINOIC ACID. OBJECTIVE: EPILEPSY IS A CHRONIC BRAIN DISEASE WITH RECURRENT SEIZURES. AUTOPHAGY PLAYS A CRUCIAL ROLE IN THE PROGRESSION OF EPILEPSY. THIS STUDY AIMED TO EXPLORE THE FUNCTION AND INTRINSIC MECHANISM OF THE LONG NON-CODING RNA (LNCRNA) UCA1/MIR-132-3P/ATG16L1 AXIS IN EPILEPSY VIA REGULATION OF AUTOPHAGY. METHODS: THE EXPRESSION OF LNCRNA UCA1, MIR-132-3P AND ATG16L1 WAS MEASURED IN SERUM FROM EPILEPTIC PATIENTS BY QUANTITATIVE RT-PCR. A SH-SY5Y CELL MODEL WAS FURTHER CONSTRUCTED USING RETINOIC ACID TO INVESTIGATE THE UCA1/ MIR-132-3P/ATG16L1 AXIS BY QUANTITATIVE RT-PCR, WESTERN BLOTTING, FLUORESCENCE IN SITU HYBRIDISATION, RNA IMMUNOPRECIPITATION, CHROMATIN IMMUNOPRECIPITATION, AND A DUAL-LUCIFERASE REPORTER GENE ASSAY. RESULTS: IN THE SERUM OF EPILEPTIC PATIENTS, THE LEVEL OF LNCRNA UCA1 AND ATG16L1 WAS REDUCED AND MIR-132-3P ELEVATED, COMPARED TO CONTROLS. SIMILARLY, IN THE SH-SY5Y CELL MODEL, THE LEVEL OF LNCRNA UCA1 AND ATG16L1 WAS REDUCED AND MIR-132-3P ELEVATED IN RETINOIC ACID-TREATED CELLS; LNCRNA UCA1 WAS MAINLY LOCATED IN THE CYTOPLASM. LNCRNA UCA1 OVEREXPRESSION WAS SHOWN TO PROMOTE AUTOPHAGIC GENE EXPRESSION, WHICH WAS REVERSED BY MIR-132-3P OVEREXPRESSION. MOREOVER, AUTOPHAGIC GENE EXPRESSION INDUCED BY MIR-132-3P KNOCKDOWN WAS REVERSED BY ATG16L1 KNOCKDOWN. BASED ON PRECIPITATION ASSAYS, LNCRNA UCA1 AND MIR-132-3P WERE SHOWN TO FORM A COMPLEX WITH THE TRANSCRIPTION FACTOR, EZH2, AND MIR-132-3P WAS SHOWN TO INTERACT WITH ATG16L1 BASED ON A LUCIFERASE ASSAY. FINALLY, LNCRNA UCA1 WAS SHOWN TO NEGATIVELY REGULATE MIR-132-3P EXPRESSION, AND MIR-132-3P WAS SHOWN TO NEGATIVELY REGULATE ATG16L1. SIGNIFICANCE: IN THIS CELL MODEL, LNCRNA UCA1 PROMOTES AUTOPHAGIC GENE EXPRESSION VIA EPIGENETIC REGULATION MEDIATED BY ATG16L1 AND MIR-132-3P.	2022	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                         
16  2654  28 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	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                        
17  1301  21 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	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                       
18  6418  28 THE TEMPORAL EXPRESSION OF CIRCULATING MICRORNAS AFTER ACUTE EXPERIMENTAL PAIN IN HUMANS. BACKGROUND: MICRORNAS (MIRNAS) CAN MODULATE SEVERAL BIOLOGICAL SYSTEMS, INCLUDING THE PAIN SYSTEM. THIS STUDY AIMED TO EVALUATE THE TEMPORAL EXPRESSION OF CIRCULATING MIRNAS IN THE PLASMA OF HEALTHY VOLUNTEERS AS A MARKER FOR EPIGENETIC CHANGES BEFORE AND AFTER AN ACUTE, EXPERIMENTAL, PAIN PROVOCATION BY INTRAMUSCULAR HYPERTONIC SALINE INJECTION. METHODS: TWENTY VOLUNTEERS WERE RANDOMLY ALLOCATED INTO TWO GROUPS AND RECEIVED EITHER HYPERTONIC (PAIN) OR ISOTONIC (CONTROL) SALINE INJECTION IN THE FIRST DORSAL INTEROSSEOUS MUSCLE OF THEIR DOMINANT HAND. PAIN INTENSITY WAS CONTINUOUSLY RECORDED FOR 20 MINUTES AFTER INJECTION ON A VAS SCALE FROM 0 TO 100 (0 INDICATES NO PAIN AND 100 THE WORST IMAGINABLE PAIN). BLOOD SAMPLES WERE TAKEN AT BASELINE, 30 MINUTES, 3 HOURS, AND 24 HOURS POST-INJECTION, AND PLASMA WAS SEPARATED. MIRNA EXTRACTS WERE USED FOR RNA SEQUENCING WITH THE ILLUMINA NEXTSEQ PLATFORM. MIRNA TRANSCRIPTS WERE COMPARED BETWEEN THE PAIN AND THE NO-PAIN, CONTROL GROUP AT EVERY TIME POINT. SIGNIFICANT DIFFERENCES WERE CONSIDERED WHEN FOLDS WERE >2 AND THE FALSE DISCOVERY RATE WAS P < 0.05. RESULTS: AFTER 30 MINUTES, 4 MIRNAS WERE SIGNIFICANTLY ALTERED IN THE PAIN GROUP COMPARED TO CONTROLS, WHICH INCREASED TO 24 AFTER 3 HOURS AND TO 42 AFTER 24 HOURS FROM BASELINE (P < 0.0001). TWO MIRNAS WERE CONSISTENTLY UPREGULATED THROUGHOUT THE EXPERIMENT. ENRICHMENT ANALYSIS SHOWED SIGNIFICANT MIRNAS INVOLVED IN BRAIN PERCEPTION OF PAIN, BRAIN SIGNALLING AND RESPONSE TO STIMULI. CONCLUSIONS: THIS EXPLORATORY STUDY IS THE FIRST TO REPORT ON THE TEMPORAL EXPRESSION OF CIRCULATING MIRNAS AFTER AN ACUTE, HUMAN EXPERIMENTAL MUSCLE PAIN MODEL. SIGNIFICANCE: THIS EXPLORATORY STUDY EVALUATED THE TEMPORAL PROFILE OF CIRCULATING MIRNAS IN THE PLASMA OF HEALTHY SUBJECTS AFTER ACUTE EXPERIMENTAL PAIN. SEVERAL MIRNAS WERE ALTERED IN SUBJECTS AT THE TIMES OF FOLLOW-UP AFTER THE ACUTE PAIN MODEL WHEN COMPARED TO CONTROLS. MIRNAS PREVIOUSLY ASSOCIATED WITH PAIN PROCESSES WERE ALTERED IN THE PAIN GROUP. OUR RESULTS, BY SHOWING THE FAST AND PROLONGED MODIFICATIONS OF MIRNA ELICITED BY THE ACUTE EXPERIMENTAL PAIN MODEL, ADD NEW PERSPECTIVES TO THE TOPIC OF EPIGENETICS AND PAIN.	2023	
                                                                                                                                                                                                                                                                                                                                                     
19  3504  35 IDENTIFICATION OF POTENTIALLY FUNCTIONAL CIRCRNAS AND PREDICTION OF CIRCRNA-MIRNA-MRNA REGULATORY NETWORK IN PERIODONTITIS: BRIDGING THE GAP BETWEEN BIOINFORMATICS AND CLINICAL NEEDS. BACKGROUND AND OBJECTIVE: PERIODONTITIS IS A MULTIFACTORIAL CHRONIC INFLAMMATORY DISEASE THAT CAN LEAD TO THE IRREVERSIBLE DESTRUCTION OF DENTAL SUPPORT TISSUES. AS AN EPIGENETIC FACTOR, THE EXPRESSION OF CIRCRNA IS TISSUE-DEPENDENT AND DISEASE-DEPENDENT. THIS STUDY AIMED TO IDENTIFY NOVEL PERIODONTITIS-ASSOCIATED CIRCRNAS AND PREDICT RELEVANT CIRCRNA-PERIODONTITIS REGULATORY NETWORK BY USING RECENTLY DEVELOPED BIOINFORMATIC TOOLS AND INTEGRATING SEQUENCING PROFILING WITH CLINICAL INFORMATION FOR GETTING A BETTER AND MORE THOROUGH IMAGE OF PERIODONTITIS PATHOGENESIS, FROM GENE TO CLINIC. MATERIAL AND METHODS: HIGH-THROUGHPUT SEQUENCING AND RT-QPCR WERE CONDUCTED TO IDENTIFY DIFFERENTIALLY EXPRESSED CIRCRNAS IN GINGIVAL TISSUES FROM PERIODONTITIS PATIENTS. THE RELATIONSHIP BETWEEN UPREGULATED CIRCRNAS EXPRESSION AND PROBING DEPTH (PD) WAS PERFORMED USING SPEARMAN'S CORRELATION ANALYSIS. BIOINFORMATIC ANALYSES INCLUDING GO ANALYSIS, CIRCRNA-DISEASE ASSOCIATION PREDICTION, AND CIRCRNA-MIRNA-MRNA NETWORK PREDICTION WERE PERFORMED TO CLARIFY POTENTIAL REGULATORY FUNCTIONS OF IDENTIFIED CIRCRNAS IN PERIODONTITIS. A RECEIVER-OPERATING CHARACTERISTIC (ROC) CURVE WAS ESTABLISHED TO ASSESS THE DIAGNOSTIC SIGNIFICANCE OF IDENTIFIED CIRCRNAS. RESULTS: HIGH-THROUGHPUT SEQUENCING IDENTIFIED 70 DIFFERENTIALLY EXPRESSED CIRCRNAS (68 UPREGULATED AND 2 DOWNREGULATED CIRCRNAS) IN HUMAN PERIODONTITIS (FOLD CHANGE >2.0 AND P < .05). THE TOP FIVE UPREGULATED CIRCRNAS WERE VALIDATED BY RT-QPCR THAT HAD STRONG ASSOCIATIONS WITH MULTIPLE HUMAN DISEASES, INCLUDING PERIODONTITIS. THE UPREGULATION OF CIRCRNAS WERE POSITIVELY CORRELATED WITH PD (R = .40-.69, P < .05, MODERATE). A CIRCRNA-MIRNA-MRNA NETWORK WITH THE TOP FIVE UPREGULATED CIRCRNAS, DIFFERENTIALLY EXPRESSED MRNAS, AND OVERLAPPED PREDICTED MIRNAS INDICATED POTENTIAL ROLES OF CIRCRNAS IN IMMUNE RESPONSE, CELL APOPTOSIS, MIGRATION, ADHESION, AND REACTION TO OXIDATIVE STRESS. THE ROC CURVE SHOWED THAT CIRCRNAS HAD POTENTIAL VALUE IN PERIODONTITIS DIAGNOSIS (AUC = 0.7321-0.8667, P < .05). CONCLUSION: CIRCRNA-DISEASE ASSOCIATIONS WERE PREDICTED BY ONLINE BIOINFORMATIC TOOLS. POSITIVE CORRELATION BETWEEN UPREGULATED CIRCRNAS, CIRCPTP4A2, CHR22:23101560-23135351+, CIRCARHGEF28, CIRCBARD1 AND CIRCRASA2, AND PD SUGGESTED FUNCTION OF CIRCRNAS IN PERIODONTITIS. NETWORK PREDICTION FURTHER FOCUSED ON DOWNSTREAM TARGETS REGULATED BY CIRCRNAS DURING PERIODONTITIS PATHOGENESIS.	2022	

20  3483  25 IDENTIFICATION OF CERNA NETWORK TO EXPLAIN THE MECHANISM OF COGNITIVE DYSFUNCTIONS INDUCED BY PS NPS IN MICE. PLASTICS BREAKING DOWN OF LARGER PLASTICS INTO SMALLER ONES (MICROPLASTICS AND NANOPLASTIC) AS POTENTIAL THREATS TO THE ECOSYSTEM. PREVIOUS STUDIES DEMONSTRATE THAT THE CENTRAL NERVOUS SYSTEM (CNS) IS A VULNERABLE TARGET OF NANOPLASTICS. HOWEVER, THE POTENTIALLY EPIGENETIC BIOMARKERS OF NANOPLASTIC NEUROTOXICITY IN RODENT MODELS ARE STILL UNKNOWN. THE PRESENT RESEARCH AIMED TO DETERMINE THE ROLE OF COMPETING ENDOGENOUS RNA (CERNA) IN THE PROCESS OF POLYSTYRENE NANOPLASTICS (PS NPS) EXPOSURE-INDUCED NERVE INJURY. THE STUDY WAS DESIGNED TO INVESTIGATE WHETHER 25 NM PS NPS COULD CAUSE LEARNING DYSFUNCTION AND TO ELUCIDATE THE UNDERLYING MECHANISMS IN MICE. A TOTAL OF 40 MICE WERE DIVIDED INTO 4 GROUPS AND WERE EXPOSED TO PS NPS (0, 10, 25, 50 MG/KG). CHRONIC TOXICITY WAS INTRODUCED IN MICE BY ADMINISTRATION OF ORAL GAVAGE FOR 6 MONTHS. THE EVALUATION INCLUDED ASSESSMENT OF THEIR BEHAVIOR, PATHOLOGICAL INVESTIGATION AND DETERMINATION OF THE LEVELS OF REACTIVE OXYGEN SPECIES (ROS) AND DNA DAMAGE. RNA-SEQ WAS PERFORMED TO DETECT THE EXPRESSION LEVELS OF CIRCRNAS, MIRNAS AND MRNAS IN PFC SAMPLES OF MICE TREATED WITH 0 AND 50 MG/KG PS NPS. THE RESULTS INDICATED THAT EXPOSURE OF MICE TO PS NPS CAUSED A DOSE-DEPENDENT COGNITIVE DECLINE. ROS LEVELS AND DNA DAMAGE WERE INCREASED IN THE PFC FOLLOWING EXPOSURE OF THE MICE TO PS NPS. A TOTAL OF 987 MRNAS, 29 MIRNAS AND 67 CIRCRNAS DEMONSTRATED SIGNIFICANT DIFFERENCES BETWEEN THE 0 AND 50 MG/KG PS NPS GROUPS. FUNCTIONAL ENRICHMENT ANALYSES INDICATED THAT PS NPS MAY INDUCE MAJOR INJURY IN THE SYNAPTIC FUNCTION. A TOTAL OF 96 MRNAS, WHICH WERE ASSOCIATED WITH SYNAPTIC DYSFUNCTION WERE IDENTIFIED. A COMPETING ENDOGENOUS RNA (CERNA) NETWORK CONTAINING 27 CIRCRNAS, 19 MIRNAS AND 35 SYNAPTIC DYSFUNCTION-RELATED MRNAS WAS CONSTRUCTED. THE PRESENT STUDY PROVIDED INSIGHT INTO THE MOLECULAR EVENTS ASSOCIATED WITH NANOPLASTIC TOXICITY AND INDUCTION OF COGNITIVE DYSFUNCTION.	2022