1  224 125 ACUTE SKELETAL MUSCLE CONTRACTIONS ORCHESTRATE SIGNALING MECHANISMS TO TRIGGER NUCLEAR NFATC1 SHUTTLING AND EPIGENETIC HISTONE MODIFICATIONS. BACKGROUND/AIMS: CALCIUM (CA(2)(+)) COORDINATES SKELETAL MUSCLE FUNCTIONS BY CONTROLLING CONTRACTIONS AS WELL AS SIGNALING PATHWAYS AND TRANSCRIPTIONAL PROPERTIES. THE RYANODINE RECEPTOR 1 (RYR1), ITS PHOSPHORYLATION SITE (PRYR1SER(2)(8)(4)(0)) AND ITS STABILIZERS NAVIGATE CA(2)(+) OSCILLATIONS TO COMMAND MUSCLE SIGNALING CASCADES AND TRANSCRIPTIONAL ACTIVITIES. WHILE CHRONIC EXERCISE INCREASES PRYR1SER(2)(8)(4)(0), INVESTIGATIONS ON ACUTE EXERCISE'S EFFECTS ON RYR1 AND CA(2)(+)-DEPENDENT MODIFICATIONS OF SKELETAL MUSCLE ARE RARE. THE AIM OF THIS STUDY WAS TO EXAMINE MOLECULAR EVENTS LEADING TO RYR1 PHOSPHORYLATION IN A PHYSIOLOGICAL MODEL OF ACUTE EXERCISE. WE HYPOTHESIZED THAT EXERCISE-INDUCED RYR1 PHOSPHORYLATION IS ASSOCIATED WITH ALTERED CA(2)(+)-DEPENDENT PHYSIOLOGICAL PHENOTYPES. METHODS: WE ANALYZED PRYR1SER(2)(8)(4)(0), ITS STABILIZERS, INVOLVED SIGNALING PATHWAYS, AND CA(2)(+)-SENSITIVE MUSCLE-DETERMINING FACTORS (I.E. NFATC1 AND EPIGENETIC HISTONE H3 MODIFICATIONS) IN RAT MUSCLES UPON ONE SINGLE RUNNING BOUT OF EITHER CONCENTRIC OR ECCENTRIC CONTRACTIONS. RESULTS: BOTH ACUTE EXERCISES SIGNIFICANTLY INCREASED PRYRSER(2)(8)(4)(0) LEVELS IN MUSCLES, WHICH WAS ACCOMPANIED BY DISSOCIATIONS OF STABILIZERS FROM RYR1. ADDITIONALLY, RYR1 PHOSPHORYLATION-INDUCING SIGNALING CASCADES PTEN/CAMKII/ PKA WERE SIGNIFICANTLY ACTIVATED UPON EXERCISE. FURTHER, RYR1 PHOSPHORYLATIONS WERE ASSOCIATED WITH INCREASED CA(2)(+)-DEPENDENT NFATC1 NUCLEAR ABUNDANCES AS WELL AS INCREASED CA(2)(+)-DEPENDENT EPIGENETIC H3 ACETYLATIONS POINTING TO A PRYR1SER(2)(8)(4)(0)-DEPENDENT RAPID AND NOVEL CA(2)(+) EQUILIBRIUM UPON EXERCISE. CONCLUSION: OUR DATA REPORT SYNERGISTIC ACTIONS OF SEVERAL DISTINCT PATHWAYS TO MODIFY RYR1 FUNCTION TO GOVERN PHYSIOLOGICAL PHENOTYPES, HERE EXPRESSED AS INCREASED NUCLEAR NFATC1 ABUNDANCES AND EPIGENETIC H3 MODIFICATIONS.	2019	
                                                                                                                                                                                                                                                                                                                                                               
2  216  36 ACUTE BETA-ADRENERGIC ACTIVATION TRIGGERS NUCLEAR IMPORT OF HISTONE DEACETYLASE 5 AND DELAYS G(Q)-INDUCED TRANSCRIPTIONAL ACTIVATION. DURING HEMODYNAMIC STRESS, CATECHOLAMINES AND NEUROHUMORAL STIMULI MAY INDUCE CO-ACTIVATION OF G(Q)-COUPLED RECEPTORS AND BETA-ADRENERGIC RECEPTORS (BETA-AR), LEADING TO CARDIAC REMODELING. DYNAMIC REGULATION OF HISTONE DEACETYLASE 5 (HDAC5), A TRANSCRIPTIONAL REPRESSOR, IS CRUCIAL DURING STRESS SIGNALING DUE TO ITS ROLE IN EPIGENETIC CONTROL OF FETAL GENE MARKERS. LITTLE IS KNOWN ABOUT ITS REGULATION DURING ACUTE AND CHRONIC BETA-AR STIMULATION AND ITS CROSS-INTERACTION WITH G(Q) SIGNALING IN ADULT CARDIAC MYOCYTES. HERE, WE EVALUATE THE POTENTIAL CROSS-TALK BETWEEN G(Q)-DRIVEN AND BETA-AR MEDIATED SIGNALING AT THE LEVEL OF NUCLEOCYTOPLASMIC SHUTTLING OF HDAC5. WE SHOW THE TRANSLOCATION OF GFP-TAGGED WILD TYPE HDAC5 OR MUTANTS (S279A AND S279D) IN RESPONSE TO BETA-AR OR G(Q) AGONISTS. ISOPROTERENOL (ISO) OR PKA ACTIVATION RESULTS IN STRONG NUCLEAR ACCUMULATION OF HDAC5 IN CONTRAST TO NUCLEAR EXPORT DRIVEN BY CA(2+)-CALMODULIN PROTEIN KINASE II AND PROTEIN KINASE D. MOREOVER, NUCLEAR ACCUMULATION OF HDAC5 UNDER ACUTE ISO/PKA SIGNALING IS DEPENDENT ON PHOSPHORYLATION OF SER-279 AND CAN BLOCK SUBSEQUENT G(Q)-MEDIATED NUCLEAR HDAC5 EXPORT. INTRIGUINGLY, THE ATTENUATION OF G(Q)-INDUCED EXPORT IS ABOLISHED AFTER CHRONIC PKA ACTIVATION, YET NUCLEAR HDAC5 REMAINS ELEVATED. LAST, THE EFFECT OF CHRONIC BETA-AR SIGNALING ON HDAC5 TRANSLOCATION WAS EXAMINED IN ADULT MYOCYTES FROM A RABBIT MODEL OF HEART FAILURE, WHERE ISO-INDUCED NUCLEAR IMPORT IS ABLATED, BUT G(Q)-AGONIST MEDIATED EXPORT IS PRESERVED. ACUTE BETA-AR/PKA ACTIVATION PROTECTS AGAINST HYPERTROPHIC SIGNALING BY DELAYING G(Q)-MEDIATED TRANSCRIPTIONAL ACTIVATION. THIS SERVES AS A KEY PHYSIOLOGICAL CONTROL SWITCH BEFORE ALLOWING GENETIC REPROGRAMMING VIA HDAC5 NUCLEAR EXPORT DURING MORE SEVERE STRESS, SUCH AS HEART FAILURE.	2013	
                                                                                                                                                                                                                                                                                                                                                                                                                                
3 5636  42 SERELAXIN ALLEVIATES CARDIAC FIBROSIS THROUGH INHIBITING ENDOTHELIAL-TO-MESENCHYMAL TRANSITION VIA RXFP1. RATIONALE: CARDIAC FIBROSIS IS AN INTEGRAL CONSTITUENT OF EVERY FORM OF CHRONIC HEART DISEASE, AND PERSISTENCE OF FIBROSIS REDUCES TISSUE COMPLIANCE AND ACCELERATES THE PROGRESSION TO HEART FAILURE. RELAXIN-2 IS A HUMAN HORMONE, WHICH HAS VARIOUS PHYSIOLOGICAL FUNCTIONS SUCH AS MEDIATING RENAL VASODILATION IN PREGNANCY. ITS RECOMBINANT FORM SERELAXIN HAS RECENTLY BEEN TESTED IN CLINICAL TRIALS AS A THERAPY FOR ACUTE HEART FAILURE BUT DID NOT MEET ITS PRIMARY ENDPOINTS. THE AIM OF THIS STUDY IS TO EXAMINE WHETHER SERELAXIN HAS AN ANTI-FIBROTIC EFFECT IN THE HEART AND THEREFORE COULD BE BENEFICIAL IN CHRONIC HEART FAILURE. METHODS: WE UTILIZED TWO DIFFERENT CARDIAC FIBROSIS MOUSE MODELS (ASCENDING AORTIC CONSTRICTION (AAC) AND ANGIOTENSIN II (ATII) ADMINISTRATION VIA OSMOTIC MINIPUMPS) TO ASSESS THE ANTI-FIBROTIC POTENTIAL OF SERELAXIN. HISTOLOGICAL ANALYSIS, IMMUNOFLUORESCENCE STAINING AND MOLECULAR ANALYSIS WERE PERFORMED TO ASSESS THE FIBROSIS LEVEL AND INDICATE ENDOTHELIAL CELLS WHICH ARE UNDERGOING ENDMT. IN VITRO TGFBETA1-INDUCED ENDOTHELIAL-TO-MESENCHYMAL TRANSITION (ENDMT) ASSAYS WERE PERFORMED IN HUMAN CORONARY ARTERY ENDOTHELIAL CELLS AND MOUSE CARDIAC ENDOTHELIAL CELLS (MCECS) AND WERE EXAMINED USING MOLECULAR METHODS. CHROMATIN IMMUNOPRECIPITATION-QPCR ASSAY WAS UTILIZED TO IDENTIFY THE SERELAXIN EFFECT ON CHROMATIN REMODELING IN THE RXFP1 PROMOTER REGION IN MCECS. RESULTS: OUR RESULTS DEMONSTRATE A SIGNIFICANT AND DOSE-DEPENDENT ANTI-FIBROTIC EFFECT OF SERELAXIN IN THE HEART IN BOTH MODELS. WE FURTHER SHOW THAT SERELAXIN MEDIATES THIS EFFECT, AT LEAST IN PART, THROUGH INHIBITION OF ENDMT THROUGH THE ENDOTHELIAL RELAXIN FAMILY PEPTIDE RECEPTOR 1 (RXFP1). WE FURTHER DEMONSTRATE THAT SERELAXIN ADMINISTRATION IS ABLE TO INCREASE ITS OWN RECEPTOR EXPRESSION (RXFP1) THROUGH EPIGENETIC REGULATION IN FORM OF HISTONE MODIFICATIONS BY ATTENUATING TGFBETA-PSMAD2/3 SIGNALING IN ENDOTHELIAL CELLS. CONCLUSIONS: THIS STUDY IS THE FIRST TO IDENTIFY THAT SERELAXIN INCREASES THE EXPRESSION OF ITS OWN RECEPTOR RXFP1 AND THAT THIS MEDIATES THE INHIBITION OF ENDMT AND CARDIAC FIBROSIS, SUGGESTING THAT SERELAXIN MAY HAVE A BENEFICIAL EFFECT AS ANTI-FIBROTIC THERAPY IN CHRONIC HEART FAILURE.	2020	
                            
4 6012  22 THE APKC-CBP PATHWAY REGULATES POST-STROKE NEUROVASCULAR REMODELING AND FUNCTIONAL RECOVERY. EPIGENETIC MODIFICATIONS HAVE EMERGED AS ATTRACTIVE MOLECULAR SUBSTRATES THAT INTEGRATE EXTRINSIC CHANGES INTO THE DETERMINATION OF CELL IDENTITY. SINCE STROKE-RELATED BRAIN DAMAGE RELEASES MICRO-ENVIRONMENTAL CUES, WE EXAMINED THE ROLE OF A SIGNALING-INDUCED EPIGENETIC PATHWAY, AN ATYPICAL PROTEIN KINASE C (APKC)-MEDIATED PHOSPHORYLATION OF CREB-BINDING PROTEIN (CBP), IN POST-STROKE NEUROVASCULAR REMODELING. USING A KNOCKIN MOUSE STRAIN (CBPS436A) WHERE THE APKC-CBP PATHWAY WAS DEFECTIVE, WE SHOW THAT DISRUPTION OF THE APKC-CBP PATHWAY IN A MURINE FOCAL ISCHEMIC STROKE MODEL INCREASES THE REPROGRAMMING EFFICIENCY OF ISCHEMIA-ACTIVATED PERICYTES (I-PERICYTES) TO NEURAL PRECURSORS. AS A CONSEQUENCE OF ENHANCED CELLULAR REPROGRAMMING, CBPS436A MICE SHOW AN INCREASED TRANSIENT POPULATION OF LOCALLY DERIVED NEURAL PRECURSORS AFTER STROKE, WHILE DISPLAYING A REDUCED NUMBER OF I-PERICYTES, IMPAIRED VASCULAR REMODELING, AND PERTURBED MOTOR RECOVERY DURING THE CHRONIC PHASE OF STROKE. TOGETHER, THIS STUDY ELUCIDATES THE ROLE OF THE APKC-CBP PATHWAY IN MODULATING NEUROVASCULAR REMODELING AND FUNCTIONAL RECOVERY FOLLOWING FOCAL ISCHEMIC STROKE.	2017	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                   
5 3049  30 GENOME-WIDE ANALYSIS REVEALS ZINC TRANSPORTER ZIP9 REGULATED BY DNA METHYLATION PROMOTES RADIATION-INDUCED SKIN FIBROSIS VIA THE TGF-BETA SIGNALING PATHWAY. RADIATION-INDUCED SKIN FIBROSIS IS A DETRIMENTAL AND CHRONIC DISORDER THAT OCCURS AFTER RADIATION EXPOSURE. DNA METHYLATION HAS BEEN CHARACTERIZED AS AN IMPORTANT REGULATORY MECHANISM OF MULTIPLE PATHOLOGICAL PROCESSES. IN THIS STUDY, WE COMPARED THE GENOME-WIDE DNA METHYLATION STATUS IN RADIATION-INDUCED FIBROTIC SKIN AND ADJACENT NORMAL TISSUES OF RATS BY METHYLATED DNA IMMUNOPRECIPITATION SEQUENCING. RADIATION-INDUCED FIBROTIC SKIN SHOWED DIFFERENTIALLY METHYLATED REGIONS ASSOCIATED WITH 3,650 PROTEIN-CODING GENES, 72 MICRORNAS, 5,836 LONG NONCODING RNAS AND 3 PIWI-INTERACTING RNAS. BY INTEGRATING THE MRNA AND METHYLATION PROFILES, THE ZINC TRANSPORTER SLC39A9/ZIP9 WAS INVESTIGATED IN GREATER DETAIL. THE PROTEIN LEVEL OF ZIP9 WAS INCREASED IN IRRADIATED SKIN TISSUES OF HUMANS, MONKEYS, AND RATS, ESPECIALLY IN RADIOGENIC FIBROTIC SKIN TISSUES. RADIATION INDUCED THE DEMETHYLATION OF A CPG DINUCLEOTIDE IN EXON 1 OF ZIP9 THAT RESULTED IN RECRUITMENT OF THE TRANSCRIPTIONAL FACTOR SP1 AND INCREASED ZIP9 EXPRESSION. OVEREXPRESSION OF ZIP9 RESULTED IN ACTIVATION OF THE PROFIBROTIC TRANSFORMING GROWTH FACTOR-BETA SIGNALING PATHWAY THROUGH PROTEIN KINASE B IN HUMAN FIBROBLASTS. IN ADDITION, RADIATION-INDUCED SKIN FIBROSIS WAS ASSOCIATED WITH INCREASED ZINC ACCUMULATION. THE ZINC CHELATOR N,N,N',N'-TETRAKIS(2-PYRIDYLMETHYL)-1,2-ETHYLENEDIAMINE ABROGATED ZIP9-INDUCED ACTIVATION OF THE TRANSFORMING GROWTH FACTOR-BETA SIGNALING PATHWAY AND ATTENUATED RADIATION-INDUCED SKIN FIBROSIS IN A RAT MODEL. IN SUMMARY, OUR FINDINGS ILLUSTRATE EPIGENETIC REGULATION OF ZIP9 AND ITS CRITICAL ROLE IN PROMOTING RADIATION-INDUCED SKIN FIBROSIS.	2020	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                      
6  984  36 CHRONIC PSYCHOLOGICAL STRESS ALTERS GENE EXPRESSION IN RAT COLON EPITHELIAL CELLS PROMOTING CHROMATIN REMODELING, BARRIER DYSFUNCTION AND INFLAMMATION. CHRONIC STRESS IS COMMONLY ASSOCIATED WITH ENHANCED ABDOMINAL PAIN (VISCERAL HYPERSENSITIVITY), BUT THE CELLULAR MECHANISMS UNDERLYING HOW CHRONIC STRESS INDUCES VISCERAL HYPERSENSITIVITY ARE POORLY UNDERSTOOD. IN THIS STUDY, WE EXAMINED CHANGES IN GENE EXPRESSION IN COLON EPITHELIAL CELLS FROM A RAT MODEL USING RNA-SEQUENCING TO EXAMINE STRESS-INDUCED CHANGES TO THE TRANSCRIPTOME. FOLLOWING CHRONIC STRESS, THE MOST SIGNIFICANTLY UP-REGULATED GENES INCLUDED ATG16L1, COQ10B, DCAF13, NAT2, PTBP2, RRAS2, SPINK4 AND DOWN-REGULATED GENES INCLUDING ABAT, CITED2, CNNM2, DAB2IP, PLEKHM1, SCD2, AND TAB2. THE PRIMARY ALTERED BIOLOGICAL PROCESSES REVEALED BY NETWORK ENRICHMENT ANALYSIS WERE INFLAMMATION/IMMUNE RESPONSE, TISSUE MORPHOGENESIS AND DEVELOPMENT, AND NUCLEOSOME/CHROMATIN ASSEMBLY. THE MOST SIGNIFICANTLY DOWN-REGULATED PROCESS WAS THE DIGESTIVE SYSTEM DEVELOPMENT/FUNCTION, WHEREAS THE MOST SIGNIFICANTLY UP-REGULATED PROCESSES WERE INFLAMMATORY RESPONSE, ORGANISMAL INJURY, AND CHROMATIN REMODELING MEDIATED BY H3K9 METHYLATION. FURTHERMORE, A SUBPOPULATION OF STRESSED RATS DEMONSTRATED VERY SIGNIFICANTLY ALTERED GENE EXPRESSION AND TRANSCRIPT ISOFORMS, ENRICHED FOR THE DIFFERENTIAL EXPRESSION OF GENES INVOLVED IN THE INFLAMMATORY RESPONSE, INCLUDING UPREGULATION OF CYTOKINE AND CHEMOKINE RECEPTOR GENE EXPRESSION COUPLED WITH DOWNREGULATION OF EPITHELIAL ADHERENS AND TIGHT JUNCTION MRNAS. IN SUMMARY, THESE FINDINGS SUPPORT THAT CHRONIC STRESS IS ASSOCIATED WITH INCREASED LEVELS OF CYTOKINES AND CHEMOKINES, THEIR DOWNSTREAM SIGNALING PATHWAYS COUPLED TO DYSREGULATION OF INTESTINAL CELL DEVELOPMENT AND FUNCTION. EPIGENETIC REGULATION OF CHROMATIN REMODELING LIKELY PLAYS A PROMINENT ROLE IN THIS PROCESS. RESULTS ALSO SUGGEST THAT SUPER ENHANCERS PLAY A PRIMARY ROLE IN CHRONIC STRESS-ASSOCIATED INTESTINAL BARRIER DYSFUNCTION.	2022	
                                                                                                                                                                                                                                                                                                                                                               
7  685  37 BRAIN-DERIVED NEUROTROPHIC FACTOR INVOLVED EPIGENETIC REPRESSION OF UGT2B7 IN COLORECTAL CARCINOMA: A MECHANISM TO ALTER MORPHINE GLUCURONIDATION IN TUMOR. URIDINE DIPHOSPHATE-GLUCURONOSYLTRANSFERASE (UGT) 2B7, AS ONE OF SIGNIFICANT DRUG ENZYMES, IS RESPONSIBLE ON THE GLUCURONIDATION OF ABUNDANT ENDOBIOTICS OR XENOBIOTICS. WE HERE REPORT THAT IT IS MARKEDLY REPRESSED IN THE TUMOR TISSUES OF COLORECTAL CARCINOMA (CRC) PATIENTS. ACCORDINGLY, MORPHINE IN CRC CELLS WILL STIMULATE THE EXPRESSION OF ITS MAIN METABOLIC ENZYME, UGT2B7 DURING TOLERANCE GENERATION BY ACTIVATING THE POSITIVE SIGNALS IN HISTONE 3, ESPECIALLY FOR TRIMETHYLATED LYSINE 27 (H3K4ME3) AND ACETYLATED LYSINE 4 (H3K27AC). FURTHER STUDY REVEALS THAT BRAIN-DERIVED NEUTROPHILIC FACTOR (BDNF), A SECRETORY NEUROTROPHIN, ENRICHED IN CRC CAN INTERACT AND INHIBIT UGT2B7 BY PRIMARILY BLOCKING THE POSITIVE SIGNALS OF H3K4ME3 AS WELL AS ACTIVATING H3K27AC ON THE PROMOTER REGION OF UGT2B7. MEANWHILE, BDNF REPRESSION ATTRIBUTES TO THE SENSITIZATIONS OF MAIN CORE FACTORS IN POLY-COMB REPRESSIVE COMPLEX (PRC) 1 RATHER THAN PRC2 AS THE REASON OF THE DEPRESSION OF SUZ12 IN THE LATER COMPLEX. BESIDES THAT, THE PRODUCTIONS OF TWO MAIN MORPHINE GLUCURONIDES ARE BOTH INCREASED IN THE BDNF DEFICIENT OR TSA AND BIX-01294 TREATED MORPHINE TOLERANCE-LIKE HCT-116 CELLS. ON THE SAME CONDITION, ACTIVE METABOLITE, MORPHINE-6-GLUCURONIDE (M6G) WAS ACCUMULATED MORE THAN INACTIVE M3G. OUR FINDINGS IMPLY THAT ENZYMATIC ACTIVITY ENHANCEMENT AND SUBSTRATE REGIOSELECTIVE CATALYSIS ALTERATION OF UGT2B7 MAY RELEASE MORPHINE TOLERANCE UNDER THE CURE OF TUMOR-INDUCED PAIN.	2017	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                         
8 5503  35 RGS9-2--CONTROLLED ADAPTATIONS IN THE STRIATUM DETERMINE THE ONSET OF ACTION AND EFFICACY OF ANTIDEPRESSANTS IN NEUROPATHIC PAIN STATES. THE STRIATAL PROTEIN REGULATOR OF G-PROTEIN SIGNALING 9-2 (RGS9-2) PLAYS A KEY MODULATORY ROLE IN OPIOID, MONOAMINE, AND OTHER G-PROTEIN-COUPLED RECEPTOR RESPONSES. HERE, WE USE THE MURINE SPARED-NERVE INJURY MODEL OF NEUROPATHIC PAIN TO INVESTIGATE THE MECHANISM BY WHICH RGS9-2 IN THE NUCLEUS ACCUMBENS (NAC), A BRAIN REGION INVOLVED IN MOOD, REWARD, AND MOTIVATION, MODULATES THE ACTIONS OF TRICYCLIC ANTIDEPRESSANTS (TCAS). PREVENTION OF RGS9-2 ACTION IN THE NAC INCREASES THE EFFICACY OF THE TCA DESIPRAMINE AND DRAMATICALLY ACCELERATES ITS ONSET OF ACTION. BY CONTROLLING THE ACTIVATION OF EFFECTOR MOLECULES BY G PROTEIN ALPHA AND BETAGAMMA SUBUNITS, RGS9-2 AFFECTS SEVERAL PROTEIN INTERACTIONS, PHOSPHOPROTEIN LEVELS, AND THE FUNCTION OF THE EPIGENETIC MODIFIER HISTONE DEACETYLASE 5, WHICH ARE IMPORTANT FOR TCA RESPONSIVENESS. FURTHERMORE, INFORMATION FROM RNA-SEQUENCING ANALYSIS REVEALS THAT RGS9-2 IN THE NAC AFFECTS THE EXPRESSION OF MANY GENES KNOWN TO BE INVOLVED IN NOCICEPTION, ANALGESIA, AND ANTIDEPRESSANT DRUG ACTIONS. OUR FINDINGS PROVIDE NOVEL INFORMATION ON NAC-SPECIFIC CELLULAR MECHANISMS THAT MEDIATE THE ACTIONS OF TCAS IN NEUROPATHIC PAIN STATES.	2015	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                
9 2758  28 EXPRESSION OF HORMONAL CARCINOGENESIS GENES AND RELATED REGULATORY MICRORNAS IN UTERUS AND OVARIES OF DDT-TREATED FEMALE RATS. THE INSECTICIDE DICHLORODIPHENYLTRICHLOROETHANE (DDT) IS A NONMUTAGENIC XENOBIOTIC COMPOUND ABLE TO EXERT ESTROGEN-LIKE EFFECTS RESULTING IN ACTIVATION OF ESTROGEN RECEPTOR-ALPHA (ERALPHA) FOLLOWED BY CHANGED EXPRESSION OF ITS DOWNSTREAM TARGET GENES. IN ADDITION, STUDIES PERFORMED OVER RECENT YEARS SUGGEST THAT DDT MAY ALSO INFLUENCE EXPRESSION OF MICRORNAS. HOWEVER, AN IMPACT OF DDT ON EXPRESSION OF ER, MICRORNAS, AND RELATED TARGET GENES HAS NOT BEEN FULLY ELUCIDATED. HERE, USING REAL-TIME PCR, WE ASSESSED CHANGES IN EXPRESSION OF KEY GENES INVOLVED IN HORMONAL CARCINOGENESIS AS WELL AS POTENTIALLY RELATED REGULATORY ONCOGENIC/TUMOR SUPPRESSOR MICRORNAS AND THEIR TARGET GENES IN THE UTERUS AND OVARIES OF FEMALE WISTAR RATS DURING SINGLE AND CHRONIC MULTIPLE-DOSE DDT EXPOSURE. WE FOUND THAT APPLYING DDT RESULTS IN ALTERED EXPRESSION OF MICRORNAS-221, -222, -205, -126A, AND -429, THEIR TARGET GENES (PTEN, DICER1), AS WELL AS GENES INVOLVED IN HORMONAL CARCINOGENESIS (ESR1, PGR, CCND1, CYP19A1). NOTABLY, CYP19A1 EXPRESSION SEEMS TO BE ALSO REGULATED BY MICRORNAS-221, -222, AND -205. THE DATA SUGGEST THAT EPIGENETIC EFFECTS INDUCED BY DDT AS A POTENTIAL CARCINOGEN MAY BE BASED ON AT LEAST TWO MECHANISMS: (I) ACTIVATION OF ERALPHA FOLLOWED BY ALTERED EXPRESSION OF THE TARGET GENES ENCODING RECEPTOR PGR AND CCND1 AS WELL AS IMPAIRED EXPRESSION OF CYP19A1, AFFECTING, THEREBY, CELL HORMONE BALANCE; AND (II) CHANGED EXPRESSION OF MICRORNAS RESULTING IN IMPAIRED EXPRESSION OF RELATED TARGET GENES INCLUDING REDUCED LEVEL OF CYP19A1 MRNA.	2017	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                              
10 5838  33 STRIATAL SHATI/NAT8L-BDNF PATHWAYS DETERMINE THE SENSITIVITY TO SOCIAL DEFEAT STRESS IN MICE THROUGH EPIGENETIC REGULATION. THE GLOBAL NUMBER OF PATIENTS WITH DEPRESSION INCREASES IN CORRELATION TO EXPOSURE TO SOCIAL STRESS. CHRONIC STRESS DOES NOT TRIGGER DEPRESSION IN ALL INDIVIDUALS, AS SOME REMAIN RESILIENT. THE UNDERLYING MOLECULAR MECHANISMS THAT CONTRIBUTE TO STRESS SENSITIVITY HAVE BEEN POORLY UNDERSTOOD, ALTHOUGH REVEALING THE REGULATION OF STRESS SENSITIVITY COULD HELP DEVELOP TREATMENTS FOR DEPRESSION. WE PREVIOUSLY FOUND THAT STRIATAL SHATI/NAT8L, AN N-ACETYLTRANSFERASE, WAS INCREASED IN A DEPRESSION MOUSE MODEL. WE INVESTIGATED THE ROLES OF SHATI/NAT8L IN STRESS SENSITIVITY IN MICE AND FOUND THAT SHATI/NAT8L AND BRAIN-DERIVED NEUROTROPHIC FACTOR (BDNF) LEVELS IN THE DORSAL STRIATUM WERE INCREASED IN STRESS-SUSCEPTIBLE MICE BUT NOT IN RESILIENT MICE EXPOSED TO REPEATED SOCIAL DEFEAT STRESS (RSDS). KNOCKDOWN OF SHATI/NAT8L IN THE DORSAL STRIATUM INDUCED RESILIENCE TO RSDS. IN ADDITION, BLOCKADE OF BDNF SIGNALING IN THE DORSAL STRIATUM BY ANA-12, A BDNF-SPECIFIC RECEPTOR TROPOMYOSIN-RECEPTOR-KINASE B (TRKB) INHIBITOR, ALSO INDUCED RESILIENCE TO STRESS. SHATI/NAT8L IS CORRELATED WITH BDNF EXPRESSION AFTER RSDS, AND BDNF IS DOWNSTREAM OF SHATI/NAT8L PATHWAYS IN THE DORSAL STRIATUM; SHATI/NAT8L IS EPIGENETICALLY REGULATED BY BDNF VIA HISTONE ACETYLATION. OUR RESULTS DEMONSTRATE THAT STRIATAL SHATI/NAT8L-BDNF PATHWAYS DETERMINE STRESS SENSITIVITY THROUGH EPIGENETIC REGULATION. THE STRIATAL SHATI/NAT8L-BDNF PATHWAY COULD BE A NOVEL TARGET FOR TREATMENTS OF DEPRESSION AND COULD ESTABLISH A NOVEL THERAPEUTIC STRATEGY FOR DEPRESSION PATIENTS.	2021	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                       
11 3096  33 GENOMIC CHARACTERIZATION REVEALS NOVEL MECHANISMS UNDERLYING THE VALOSIN-CONTAINING PROTEIN-MEDIATED CARDIAC PROTECTION AGAINST HEART FAILURE. CHRONIC HYPERTENSION IS A KEY RISK FACTOR FOR HEART FAILURE. HOWEVER, THE UNDERLYING MOLECULAR MECHANISMS ARE NOT FULLY UNDERSTOOD. OUR PREVIOUS STUDIES FOUND THAT THE VALOSIN-CONTAINING PROTEIN (VCP), AN ATPASE-ASSOCIATED PROTEIN, WAS SIGNIFICANTLY DECREASED IN THE HYPERTENSIVE HEART TISSUES. IN THIS STUDY, WE TESTED THE HYPOTHESIS THAT RESTORATION OF VCP PROTECTED THE HEART AGAINST PRESSURE OVERLOAD-INDUCED HEART FAILURE. WITH A CARDIAC-SPECIFIC TRANSGENIC (TG) MOUSE MODEL, WE SHOWED THAT A MODERATE INCREASE OF VCP WAS ABLE TO ATTENUATE CHRONIC PRESSURE OVERLOAD-INDUCED MALADAPTIVE CARDIAC HYPERTROPHY AND DYSFUNCTION. RNA SEQUENCING AND A COMPREHENSIVE BIOINFORMATIC ANALYSIS FURTHER DEMONSTRATED THAT OVEREXPRESSION OF VCP IN THE HEART NORMALIZED THE PRESSURE OVERLOAD-STIMULATED HYPERTROPHIC SIGNALS AND REPRESSED THE STRESS-INDUCED INFLAMMATORY RESPONSE. IN ADDITION, VCP OVEREXPRESSION PROMOTED CELL SURVIVAL BY ENHANCING THE MITOCHONDRIA RESISTANCE TO THE OXIDATIVE STRESS VIA ACTIVATING THE RICTOR-MEDIATED-GENE NETWORKS. VCP WAS ALSO FOUND TO BE INVOLVED IN THE REGULATION OF THE ALTERNATIVE SPLICING AND DIFFERENTIAL ISOFORM EXPRESSION FOR SOME GENES THAT ARE RELATED TO ATP PRODUCTION AND PROTEIN SYNTHESIS BY INTERACTING WITH LONG NO-CODING RNAS AND HISTONE DEACETYLASES, INDICATING A NOVEL EPIGENETIC REGULATION OF VCP IN INTEGRATING CODING AND NONCODING GENOMIC NETWORK IN THE STRESSED HEART. IN SUMMARY, OUR STUDY DEMONSTRATED THAT THE RESCUING OF A DEFICIENT VCP IN THE HEART COULD PREVENT PRESSURE OVERLOAD-INDUCED HEART FAILURE BY RECTIFYING CARDIAC HYPERTROPHIC AND INFLAMMATORY SIGNALING AND ENHANCING THE CARDIAC RESISTANCE TO OXIDATIVE STRESS, WHICH BROUGHT IN NOVEL INSIGHTS INTO THE UNDERSTANDING OF THE MECHANISM OF VCP IN PROTECTING PATIENTS FROM HYPERTENSIVE HEART FAILURE.	2020	
                                                                                                                                                                                                                                                                                                                                                                                                                
12 3128  39 GIPC-REGULATED IGFBP-3 PROMOTES HSC MIGRATION IN VITRO AND PORTAL HYPERTENSION IN VIVO THROUGH A BETA1-INTEGRIN PATHWAY. BACKGROUND & AIMS: TRANSFORMING GROWTH FACTOR (TGF-BETA)-INDUCED ACTIVATION OF QUIESCENT HEPATIC STELLATE CELLS (HSCS) AND THEIR TRANSFORMATION TO MYOFIBROBLASTS IS A KEY EVENT IN LIVER FIBROSIS AND PORTAL HYPERTENSION. GIPC (ALSO REFERRED TO AS SYNECTIN) IS A DOWNSTREAM SIGNAL ACTIVATION MOLECULE OF TGF-BETA AND OTHER RECEPTORS. IN THIS STUDY, WE SOUGHT TO IDENTIFY NOVEL GENES TARGETED BY TGF-BETA AND GIPC AND ELUCIDATE IF AND HOW THEY MAY CONTRIBUTE TO LIVER FIBROSIS. METHODS: WE PERFORMED SEQUENTIAL MESSENGER RNA SEQUENCING ANALYSIS ON TGF-BETA-STIMULATED HSCS AND THEN ON TGF-BETA-STIMULATED HSCS IN THE PRESENCE AND ABSENCE OF GIPC ALSO REFERRED TO AS SYNECTIN (GIPC) KNOCKDOWN. INSULIN-LIKE GROWTH FACTOR BINDING PROTEIN-3 (IGFBP-3) TRANSPORT PROTEIN EMERGED AS A TOP ACTIVATION TARGET OF BOTH TGF-BETA AND GIPC. QUANTITATIVE POLYMERASE CHAIN REACTION, ENZYME-LINKED IMMUNOSORBENT ASSAY, TARGETED CHROMATIN IMMUNOPRECIPITATION, AND WESTERN BLOT ANALYSIS WERE DONE FOR FURTHER CONFIRMATION. RESULTS: IGFBP-3, AN INSULIN GROWTH FACTOR TRANSPORT PROTEIN, EMERGED AS A TOP ACTIVATION TARGET OF BOTH TGF-BETA AND GIPC, WHICH WAS CONFIRMED BY QUANTITATIVE POLYMERASE CHAIN REACTION, ENZYME-LINKED IMMUNOSORBENT ASSAY, AND WESTERN BLOT ANALYSIS. TARGETED CHROMATIN IMMUNOPRECIPITATION SHOWED THAT GIPC INCREASES THE HISTONE 3 LYSINE 27 (H3K27) ACETYLATION ACTIVATING MARK AND CONCURRENTLY DECREASES THE H3K27 INHIBITORY TRIMETHYLATION (H3K27M3) MARK, PROVIDING AN EPIGENETIC CORRELATE TO THE GENE REGULATION CHANGES. IN VIVO, GLOBAL KNOCKOUT OF IGFBP-3 MICE RESULTED IN ATTENUATION OF HSC ACTIVATION MARKERS AND ATTENUATION OF PORTAL PRESSURE IN RESPONSE TO CHRONIC LIVER INJURY MODELS. ANALYSIS OF SERUM LEVELS FROM CIRRHOTIC PATIENTS ALSO SHOWED AN IGFBP-3 INCREASE OF MORE THAN 2-FOLD COMPARED WITH HEALTHY CONTROLS. FINALLY, IN VITRO MECHANISM STUDIES SHOWED THAT IGFBP-3 PROMOTES HSC MIGRATION THROUGH INTEGRIN-DEPENDENT PHOSPHORYLATION OF PROTEIN KINASE B. CONCLUSIONS: TGF-BETA UP-REGULATES IGFBP-3 THROUGH GIPC, LEADING TO INCREASED HSC MIGRATION IN VITRO AND PROMOTES PORTAL HYPERTENSION IN VIVO. THESE STUDIES SUPPORT THE ROLE OF IGFBP-3 AS A POTENTIAL PATHOPHYSIOLOGIC TARGET OR BIOMARKER IN CHRONIC LIVER DISEASE.	2020	

13 5601  25 RORALPHA IS CRUCIAL FOR ATTENUATED INFLAMMATORY RESPONSE TO MAINTAIN INTESTINAL HOMEOSTASIS. RETINOIC ACID-RELATED ORPHAN RECEPTOR ALPHA (RORALPHA) FUNCTIONS AS A TRANSCRIPTION FACTOR FOR VARIOUS BIOLOGICAL PROCESSES, INCLUDING CIRCADIAN RHYTHM, CANCER, AND METABOLISM. HERE, WE GENERATE INTESTINAL EPITHELIAL CELL (IEC)-SPECIFIC RORALPHA-DEFICIENT (RORALPHA(DELTAIEC)) MICE AND FIND THAT RORALPHA IS CRUCIAL FOR MAINTAINING INTESTINAL HOMEOSTASIS BY ATTENUATING NUCLEAR FACTOR KAPPAB (NF-KAPPAB) TRANSCRIPTIONAL ACTIVITY. RORALPHA(DELTAIEC) MICE EXHIBIT EXCESSIVE INTESTINAL INFLAMMATION AND HIGHLY ACTIVATED INFLAMMATORY RESPONSES IN THE DEXTRAN SULFATE SODIUM (DSS) MOUSE COLITIS MODEL. TRANSCRIPTOME ANALYSIS REVEALS THAT DELETION OF RORALPHA LEADS TO UP-REGULATION OF NF-KAPPAB TARGET GENES IN IECS. CHROMATIN IMMUNOPRECIPITATION ANALYSIS REVEALS CORECRUITMENT OF RORALPHA AND HISTONE DEACETYLASE 3 (HDAC3) ON NF-KAPPAB TARGET PROMOTERS AND SUBSEQUENT DISMISSAL OF CREB BINDING PROTEIN (CBP) AND BROMODOMAIN-CONTAINING PROTEIN 4 (BRD4) FOR TRANSCRIPTIONAL REPRESSION. TOGETHER, WE DEMONSTRATE THAT RORALPHA/HDAC3-MEDIATED ATTENUATION OF NF-KAPPAB SIGNALING CONTROLS THE BALANCE OF INFLAMMATORY RESPONSES, AND THERAPEUTIC STRATEGIES TARGETING THIS EPIGENETIC REGULATION COULD BE BENEFICIAL TO THE TREATMENT OF CHRONIC INFLAMMATORY DISEASES, INCLUDING INFLAMMATORY BOWEL DISEASE (IBD).	2019	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                   
14 1335  30 DERMAL FIBROBLASTS CULTURED FROM DONORS WITH TYPE 2 DIABETES MELLITUS RETAIN AN EPIGENETIC MEMORY ASSOCIATED WITH POOR WOUND HEALING RESPONSES. THE PREVALENCE OF TYPE 2 DIABETES MELLITUS (T2DM) IS ESCALATING GLOBALLY. PATIENTS SUFFER FROM MULTIPLE COMPLICATIONS INCLUDING THE DEVELOPMENT OF CHRONIC WOUNDS THAT CAN LEAD TO AMPUTATION. THESE WOUNDS ARE CHARACTERISED BY AN INFLAMMATORY ENVIRONMENT INCLUDING ELEVATED TUMOUR NECROSIS FACTOR ALPHA (TNF-ALPHA). DERMAL FIBROBLASTS (DF) ARE CRITICAL FOR EFFECTIVE WOUND HEALING, SO WE SOUGHT TO ESTABLISH WHETHER THERE WERE ANY DIFFERENCES IN DF CULTURED FROM T2DM DONORS OR THOSE WITHOUT DIABETES (ND-DF). ND- AND T2DM-DF WHEN CULTURED SIMILARLY IN VITRO SECRETED COMPARABLE CONCENTRATIONS OF TNF-ALPHA. FUNCTIONALLY, PRE-TREATMENT WITH TNF-ALPHA REDUCED THE PROLIFERATION OF ND-DF AND TRANSIENTLY ALTERED ND-DF MORPHOLOGY; HOWEVER, T2DM-DF WERE RESISTANT TO THESE TNF-ALPHA INDUCED CHANGES. IN CONTRAST, TNF-ALPHA INHIBITED ND- AND T2DM-DF MIGRATION AND MATRIX METALLOPROTEASE EXPRESSION TO THE SAME DEGREE, ALTHOUGH T2DM-DF EXPRESSED SIGNIFICANTLY HIGHER LEVELS OF TISSUE INHIBITOR OF METALLOPROTEASES (TIMP)-2. FINALLY, TNF-ALPHA SIGNIFICANTLY INCREASED THE SECRETION OF PRO-INFLAMMATORY CYTOKINES (INCLUDING CCL2, CXCL1 AND SERPINE1) IN ND-DF, WHILST THIS EFFECT IN T2DM-DF WAS BLUNTED, PRESUMABLY DUE TO THE TENDENCY TO HIGHER BASELINE PRO-INFLAMMATORY CYTOKINE EXPRESSION OBSERVED IN THIS CELL TYPE. COLLECTIVELY, THESE DATA DEMONSTRATE THAT T2DM-DF EXHIBIT A SELECTIVE LOSS OF RESPONSIVENESS TO TNF-ALPHA, PARTICULARLY REGARDING PROLIFERATIVE AND SECRETORY FUNCTIONS. THIS HIGHLIGHTS IMPORTANT PHENOTYPIC CHANGES IN T2DM-DF THAT MAY EXPLAIN THE SUSCEPTIBILITY TO CHRONIC WOUNDS IN THESE PATIENTS.	2021	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                          
15 1298  30 DECREASED NUCLEAR RECEPTOR ACTIVITY AND EPIGENETIC MODULATION ASSOCIATES WITH DOWN-REGULATION OF HEPATIC DRUG-METABOLIZING ENZYMES IN CHRONIC KIDNEY DISEASE. PATIENTS WITH CHRONIC KIDNEY DISEASE (CKD) REQUIRE MANY MEDICATIONS. CYP2C AND CYP3A DRUG-METABOLIZING ENZYMES PLAY A CRITICAL ROLE IN DETERMINING THE PHARMACOKINETICS OF THE MAJORITY OF PRESCRIBED MEDICATIONS. THESE ENZYMES ARE TRANSCRIPTIONALLY REGULATED BY THE NUCLEAR RECEPTORS PREGNANE X RECEPTOR (PXR) AND HEPATIC NUCLEAR FACTOR 4ALPHA (HNF-4ALPHA). EXPRESSION OF CYP2C AND CYP3A IS DECREASED IN CKD; HOWEVER, THE MECHANISMS BY WHICH THIS OCCURS IS UNKNOWN. WE INDUCED CKD IN RATS BY 5/6 NEPHRECTOMY AND USED CHROMATIN IMMUNOPRECIPITATION (CHIP) TO DETERMINE NUCLEAR RECEPTOR- AND EPIGENETIC ALTERATION-MEDIATED DIFFERENCES IN THE PROMOTER REGION OF THE CYP2C AND CYP3A GENES. RNA POLYMERASE II AND HNF-4ALPHA BINDING WAS DECREASED 76 AND 57% IN THE CYP2C11 PROMOTOR AND 71 AND 77% IN THE CYP3A2 PROMOTER, RESPECTIVELY (P<0.05). CHIP ALSO REVEALED A 57% DECREASE IN PXR BINDING TO THE CYP3A2 PROMOTER IN CKD RATS (P<0.05). THE DECREASE IN PXR AND HNF-4ALPHA BINDING WAS ACCOMPANIED BY DIMINISHED HISTONE 4 ACETYLATION IN THE CYP3A2 PROMOTER (48%) AND HISTONE 3 ACETYLATION IN THE CYP2C11 (77%) AND CYP3A2 (77%) PROMOTER LOCI FOR NUCLEAR RECEPTOR ACTIVATION (P<0.05). THIS STUDY SUGGESTS THAT DECREASED NUCLEAR RECEPTOR BINDING AND HISTONE ACETYLATION MAY CONTRIBUTE TO THE MECHANISM OF DRUG-METABOLIZING ENZYME DOWN-REGULATION AND ALTERED PHARMACOKINETICS IN CKD.	2014	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                        
16 1806  34 EFFECT OF TRANSCRIPTION INHIBITION AND GENERATION OF SUPPRESSIVE VIRAL NON-CODING RNAS. BACKGROUND: HIV-1 PATIENTS RECEIVING COMBINATION ANTIRETROVIRAL THERAPY (CART) SURVIVE INFECTION BUT REQUIRE LIFE-LONG ADHERENCE AT HIGH EXPENSE. IN CHRONIC CART-TREATED PATIENTS WITH UNDETECTABLE VIRAL TITERS, CELL-ASSOCIATED VIRAL RNA IS STILL DETECTABLE, POINTING TO LOW-LEVEL VIRAL TRANSCRIPTIONAL LEAKINESS. TO DATE, THERE ARE NO FDA-APPROVED DRUGS AGAINST HIV-1 TRANSCRIPTION. WE HAVE PREVIOUSLY SHOWN THAT F07#13, A THIRD GENERATION TAT PEPTIDE MIMETIC WITH COMPETITIVE ACTIVITY AGAINST CDK9/T1-TAT BINDING SITES, INHIBITS HIV-1 TRANSCRIPTION IN VITRO AND IN VIVO. RESULTS: HERE, WE DEMONSTRATE THAT INCREASING CONCENTRATIONS OF F07#13 (0.01, 0.1, 1 MICROM) CAUSE A DECREASE IN TAT LEVELS IN A DOSE-DEPENDENT MANNER BY INHIBITING THE CDK9/T1-TAT COMPLEX FORMATION AND SUBSEQUENT UBIQUITIN-MEDIATED TAT SEQUESTRATION AND DEGRADATION. OUR DATA INDICATE THAT COMPLEXES I AND IV CONTAIN DISTINCT PATTERNS OF UBIQUITINATED TAT AND THAT TRANSCRIPTIONAL INHIBITION INDUCED BY F07#13 CAUSES AN OVERALL REDUCTION IN TAT LEVELS. THIS REDUCTION MAY BE TRIGGERED BY F07#13 BUT ULTIMATELY IS MEDIATED BY TAR-GAG VIRAL RNAS THAT BIND SUPPRESSIVE TRANSCRIPTION FACTORS (SIMILAR TO 7SK, NRON, HOTAIR, AND XIST LNCRNAS) TO ENHANCE TRANSCRIPTIONAL GENE SILENCING AND LATENCY. THESE RNAS COMPLEX WITH PRC2, SIN3A, AND CUL4B, RESULTING IN EPIGENETIC MODIFICATIONS. FINALLY, WE OBSERVED AN F07#13-MEDIATED DECREASE OF VIRAL BURDEN BY TARGETING THE R REGION OF THE LONG TERMINAL REPEAT (HIV-1 PROMOTER REGION, LTR), PROMOTING BOTH PAUSED POLYMERASES AND INCREASED EFFICIENCY OF CRISPR/CAS9 EDITING IN INFECTED CELLS. THIS IMPLIES THAT GENE EDITING MAY BE BEST PERFORMED UNDER A REPRESSED TRANSCRIPTIONAL STATE. CONCLUSIONS: COLLECTIVELY, OUR RESULTS INDICATE THAT F07#13, WHICH CAN TERMINATE RNA POLYMERASE II AT DISTINCT SITES, CAN GENERATE SCAFFOLD RNAS, WHICH MAY ASSEMBLE INTO SPECIFIC SETS OF "RNA MACHINES" THAT CONTRIBUTE TO GENE REGULATION. IT REMAINS TO BE SEEN WHETHER THESE EFFECTS CAN ALSO BE SEEN IN VARIOUS CLADES THAT HAVE VARYING PROMOTER STRENGTH, MUTANT LTRS, AND IN PATIENT SAMPLES.	2019	
                                                                                                                                                                                 
17  142  31 ABERRANT DNA METHYLATION OF PHOSPHODIESTERASE [CORRECTED] 4D ALTERS AIRWAY SMOOTH MUSCLE CELL PHENOTYPES. AIRWAY HYPERRESPONSIVENESS (AHR) IS A HALLMARK FEATURE IN ASTHMA CHARACTERIZED BY EXAGGERATED AIRWAY CONTRACTILE RESPONSE TO STIMULI DUE TO INCREASED AIRWAY SENSITIVITY AND CHRONIC AIRWAY REMODELING. WE HAVE PREVIOUSLY SHOWN THAT ALLERGEN-INDUCED AHR IN MICE IS ASSOCIATED WITH ABERRANT DNA METHYLATION IN THE LUNG GENOME, SUGGESTING THAT AHR COULD BE EPIGENETICALLY REGULATED, AND THESE CHANGES MIGHT PREDISPOSE THE ANIMALS TO ASTHMA. PREVIOUS STUDIES DEMONSTRATED THAT OVEREXPRESSION OF PHOSPHODIESTERASE 4D (PDE4D) IS ASSOCIATED WITH INCREASED AHR. HOWEVER, EPIGENETIC REGULATION OF THIS GENE IN ASTHMATIC AIRWAY SMOOTH MUSCLE CELLS (ASMCS) HAS NOT BEEN EXAMINED. IN THIS STUDY, WE AIMED TO EXAMINE THE RELATIONSHIP BETWEEN EPIGENETIC REGULATION OF PDE4D AND ASMC PHENOTYPES. WE IDENTIFIED CPG SITE-SPECIFIC HYPOMETHYLATION AT PDE4D PROMOTER IN HUMAN ASTHMATIC ASMCS. WE NEXT USED METHYLATED OLIGONUCLEOTIDES TO INTRODUCE CPG SITE-SPECIFIC METHYLATION AT PDE4D PROMOTER AND EXAMINED ITS EFFECT ON ASMCS. WE SHOWED THAT PDE4D METHYLATION DECREASED CELL PROLIFERATION AND MIGRATION OF ASTHMATIC ASMCS. WE FURTHER ELUCIDATED THAT METHYLATED PDE4D DECREASED PDE4D EXPRESSION IN ASTHMATIC ASMCS, INCREASED CAMP LEVEL, AND INHIBITED THE ABERRANT INCREASE IN CA(2+) LEVEL. MOREOVER, PDE4D METHYLATION REDUCED THE PHOSPHORYLATION LEVEL OF DOWNSTREAM EFFECTORS OF CA(2+) SIGNALING, INCLUDING MYOSIN LIGHT CHAIN KINASE AND P38. TAKEN TOGETHER, OUR FINDINGS DEMONSTRATE THAT GENE-SPECIFIC EPIGENETIC CHANGES MAY PREDISPOSE ASMCS TO ASTHMA THROUGH ALTERATIONS IN CELL PHENOTYPES. MODULATION OF ASMC PHENOTYPES BY METHYLATED PDE4D OLIGONUCLEOTIDES CAN REVERSE THE ABERRANT ASMC FUNCTIONS TO NORMAL PHENOTYPES. THIS HAS PROVIDED NEW INSIGHT TO THE DEVELOPMENT OF NOVEL THERAPEUTIC OPTIONS FOR THIS DEBILITATIVE DISEASE.	2016	
                                                                                                                                                                                                                                                                                                                                                                                                                                                     
18 3390  36 HOPX PLAYS A CRITICAL ROLE IN ANTIRETROVIRAL DRUGS INDUCED EPIGENETIC MODIFICATION AND CARDIAC HYPERTROPHY. PEOPLE LIVING WITH HIV (PLWH) HAVE TO TAKE AN ANTIRETROVIRAL THERAPY (ART) FOR LIFE AND SHOW NONCOMMUNICABLE ILLNESSES SUCH AS CHRONIC INFLAMMATION, IMMUNE ACTIVATION, AND MULTIORGAN DYSREGULATION. RECENT STUDIES SUGGEST THAT LONG-TERM USE OF ART INDUCES COMORBID CONDITIONS AND IS ONE OF THE LEADING CAUSES OF HEART FAILURE IN PLWH. HOWEVER, THE MOLECULAR MECHANISM OF ANTIRETROVIRAL DRUGS (ARVS) INDUCED HEART FAILURE IS UNCLEAR. TO DETERMINE THE MECHANISM OF ARVS INDUCED CARDIAC DYSFUNCTION, WE PERFORMED GLOBAL TRANSCRIPTOMIC PROFILING OF ARVS TREATED NEONATAL RAT VENTRICULAR CARDIOMYOCYTES IN CULTURE. DIFFERENTIALLY EXPRESSED GENES WERE IDENTIFIED BY RNA-SEQUENCING. OUR DATA SHOW THAT ARVS TREATMENT CAUSES UPREGULATION OF SEVERAL BIOLOGICAL FUNCTIONS ASSOCIATED WITH CARDIOTOXICITY, HYPERTROPHY, AND HEART FAILURE. GLOBAL GENE EXPRESSION DATA WERE VALIDATED IN CARDIAC TISSUE ISOLATED FROM HIV PATIENTS HAVING A HISTORY OF ART. INTERESTINGLY, WE FOUND THAT HOMEODOMAIN-ONLY PROTEIN HOMEOBOX (HOPX) EXPRESSION WAS SIGNIFICANTLY INCREASED IN CARDIOMYOCYTES TREATED WITH ARVS AND IN THE HEART TISSUE OF HIV PATIENTS. FURTHERMORE, WE FOUND THAT HOPX PLAYS A CRUCIAL ROLE IN ARVS MEDIATED CELLULAR HYPERTROPHY. MECHANISTICALLY, WE FOUND THAT HOPX PLAYS A CRITICAL ROLE IN EPIGENETIC REGULATION, THROUGH DEACETYLATION OF HISTONE, WHILE THE HDAC INHIBITOR, TRICHOSTATIN A, CAN RESTORE THE ACETYLATION LEVEL OF HISTONE 3 IN THE PRESENCE OF ARVS.	2021	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                            
19   35  25 A CHROMATIN ACTIVITY-BASED CHEMOPROTEOMIC APPROACH REVEALS A TRANSCRIPTIONAL REPRESSOME FOR GENE-SPECIFIC SILENCING. IMMUNE CELLS DEVELOP ENDOTOXIN TOLERANCE (ET) AFTER PROLONGED STIMULATION. ET INCREASES THE LEVEL OF A REPRESSION MARK H3K9ME2 IN THE TRANSCRIPTIONALLY SILENT CHROMATIN SPECIFICALLY ASSOCIATED WITH PRO-INFLAMMATORY GENES. HOWEVER, IT IS NOT CLEAR WHAT PROTEINS ARE FUNCTIONALLY INVOLVED IN THIS PROCESS. HERE WE SHOW THAT A NOVEL CHROMATIN ACTIVITY-BASED CHEMOPROTEOMIC (CHAC) APPROACH CAN DISSECT THE FUNCTIONAL CHROMATIN PROTEIN COMPLEXES THAT REGULATE ET-ASSOCIATED INFLAMMATION. USING UNC0638 THAT BINDS THE ENZYMATICALLY ACTIVE H3K9-SPECIFIC METHYLTRANSFERASE G9A/GLP, CHAC REVEALS THAT G9A IS CONSTITUTIVELY ACTIVE AT A G9A-DEPENDENT MEGA-DALTON REPRESSOME IN PRIMARY ENDOTOXIN-TOLERANT MACROPHAGES. G9A/GLP BROADLY IMPACTS THE ET-SPECIFIC REPROGRAMMING OF THE HISTONE CODE LANDSCAPE, CHROMATIN REMODELLING AND THE ACTIVITIES OF SELECT TRANSCRIPTION FACTORS. WE DISCOVER THAT THE G9A-DEPENDENT EPIGENETIC ENVIRONMENT PROMOTES THE TRANSCRIPTIONAL REPRESSION ACTIVITY OF C-MYC FOR GENE-SPECIFIC CO-REGULATION OF CHRONIC INFLAMMATION. CHAC MAY ALSO BE APPLICABLE TO DISSECT OTHER FUNCTIONAL PROTEIN COMPLEXES IN THE CONTEXT OF PHENOTYPIC CHROMATIN ARCHITECTURES.	2014	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                             
20  368  35 AMYLOID BETA-MEDIATED EPIGENETIC ALTERATION OF INSULIN-LIKE GROWTH FACTOR BINDING PROTEIN 3 CONTROLS CELL SURVIVAL IN ALZHEIMER'S DISEASE. SWEDISH DOUBLE MUTATION (KM670/671NL) OF AMYLOID PRECURSOR PROTEIN (APP) IS REPORTED TO INCREASE TOXIC AMYLOID BETA (ABETA) PRODUCTION VIA ABERRANT CLEAVAGE AT THE BETA-SECRETASE SITE AND THEREBY CAUSE EARLY-ONSET ALZHEIMER'S DISEASE (AD). HOWEVER, THE UNDERLYING MOLECULAR MECHANISMS LEADING TO AD PATHOGENESIS REMAINS LARGELY UNKNOWN. PREVIOUSLY, OUR TRANSCRIPTOME SEQUENCE ANALYSES REVEALED GLOBAL EXPRESSIONAL MODIFICATIONS OF OVER 600 GENES IN APP-SWEDISH MUTANT-EXPRESSING H4 (H4-SW) CELLS COMPARED TO WILD TYPE H4 CELLS. INSULIN-LIKE GROWTH FACTOR BINDING PROTEIN 3 (IGFBP3) IS ONE GENE THAT SHOWED SIGNIFICANTLY DECREASED MRNA EXPRESSION IN H4-SW CELLS. IN THIS STUDY, WE INVESTIGATED THE FUNCTIONAL ROLE OF IGFBP3 IN AD PATHOGENESIS AND ELUCIDATED THE MECHANISMS REGULATING ITS EXPRESSION. WE OBSERVED DECREASED IGFBP3 EXPRESSION IN THE H4-SW CELL LINE AS WELL AS THE HIPPOCAMPUS OF AD MODEL TRANSGENIC MICE. TREATMENT WITH EXOGENOUS IGFBP3 PROTEIN INHIBITED ABETA1-42- INDUCED CELL DEATH AND CASPASE-3 ACTIVITY, WHEREAS SIRNA-MEDIATED SUPPRESSION OF IGFBP3 EXPRESSION INDUCED CELL DEATH AND CASPASE-3 CLEAVAGE. IN PRIMARY HIPPOCAMPAL NEURONS, ADMINISTRATION OF IGFBP3 PROTEIN BLOCKED APOPTOTIC CELL DEATH DUE TO ABETA1-42 TOXICITY. THESE DATA IMPLICATE A PROTECTIVE ROLE FOR IGFBP3 AGAINST ABETA1-42-MEDIATED APOPTOSIS. NEXT, WE INVESTIGATED THE REGULATORY MECHANISMS OF IGFBP3 EXPRESSION IN AD PATHOGENESIS. WE OBSERVED ABNORMAL IGFBP3 HYPERMETHYLATION WITHIN THE PROMOTER CPG ISLAND IN H4-SW CELLS. TREATMENT WITH THE DNA METHYLTRANSFERASE INHIBITOR 5-AZA-2'-DEOXYCYTIDINE RESTORED IGFBP3 EXPRESSION AT BOTH THE MRNA AND PROTEIN LEVELS. CHRONIC EXPOSURE TO ABETA1-42 INDUCED IGFBP3 HYPERMETHYLATION AT CPGS, PARTICULARLY AT LOCI -164 AND -173, AND SUBSEQUENTLY SUPPRESSED IGFBP3 EXPRESSION. THEREFORE, WE DEMONSTRATE THAT EXPRESSION OF ANTI-APOPTOTIC IGFBP3 IS REGULATED BY EPIGENETIC DNA METHYLATION, SUGGESTING A MECHANISM THAT CONTRIBUTES TO AD PATHOGENESIS.	2014