1 3738 138 INORGANIC ARSENIC-INDUCED CELLULAR TRANSFORMATION IS COUPLED WITH GENOME WIDE CHANGES IN CHROMATIN STRUCTURE, TRANSCRIPTOME AND SPLICING PATTERNS. BACKGROUND: ARSENIC (AS) EXPOSURE IS A SIGNIFICANT WORLDWIDE ENVIRONMENTAL HEALTH CONCERN. LOW DOSE, CHRONIC ARSENIC EXPOSURE HAS BEEN ASSOCIATED WITH A HIGHER THAN NORMAL RISK OF SKIN, LUNG, AND BLADDER CANCER, AS WELL AS CARDIOVASCULAR DISEASE AND DIABETES. WHILE ARSENIC-INDUCED BIOLOGICAL CHANGES PLAY A ROLE IN DISEASE PATHOLOGY, LITTLE IS KNOWN ABOUT THE DYNAMIC CELLULAR CHANGES RESULTING FROM ARSENIC EXPOSURE AND WITHDRAWAL. RESULTS: IN THESE STUDIES, WE SOUGHT TO UNDERSTAND THE MOLECULAR MECHANISMS BEHIND THE BIOLOGICAL CHANGES INDUCED BY ARSENIC EXPOSURE. A COMPREHENSIVE GLOBAL APPROACH WAS EMPLOYED TO DETERMINE GENOME-WIDE CHANGES TO CHROMATIN STRUCTURE, TRANSCRIPTOME PATTERNS AND SPLICING PATTERNS IN RESPONSE TO CHRONIC LOW DOSE ARSENIC AND ITS SUBSEQUENT WITHDRAWAL. OUR RESULTS SHOW THAT CELLS EXPOSED TO CHRONIC LOW DOSES OF SODIUM ARSENITE HAVE DISTINCT TEMPORAL AND COORDINATED CHROMATIN, GENE EXPRESSION, AND MIRNA CHANGES CONSISTENT WITH DIFFERENTIATION AND ACTIVATION OF MULTIPLE BIOCHEMICAL PATHWAYS. MOST OF THESE TEMPORAL PATTERNS IN GENE EXPRESSION ARE REVERSED WHEN ARSENIC IS WITHDRAWN. HOWEVER, SOME GENE EXPRESSION PATTERNS REMAINED ALTERED, PLAUSIBLY AS A RESULT OF AN ADAPTIVE RESPONSE BY CELLS. ADDITIONALLY, THE CORRELATION OF CHANGES TO GENE EXPRESSION AND CHROMATIN STRUCTURE SOLIDIFY THE ROLE OF CHROMATIN STRUCTURE IN GENE REGULATORY CHANGES DUE TO ARSENITE EXPOSURE. LASTLY, WE SHOW THAT ARSENITE EXPOSURE INFLUENCES GENE REGULATION BOTH AT THE INITIATION OF TRANSCRIPTION AS WELL AS AT THE LEVEL OF SPLICING. CONCLUSIONS: OUR RESULTS SHOW THAT ADAPTATION OF CELLS TO IAS-MEDIATED EMT IS COUPLED TO CHANGES IN CHROMATIN STRUCTURE EFFECTING DIFFERENTIAL TRANSCRIPTIONAL AND SPLICING PATTERNS OF GENES. THESE STUDIES PROVIDE NEW INSIGHTS INTO THE MECHANISM OF IAS-MEDIATED PATHOLOGY, WHICH INCLUDES EPIGENETIC CHROMATIN CHANGES COUPLED WITH CHANGES TO THE TRANSCRIPTOME AND SPLICING PATTERNS OF KEY GENES. 2015 2 930 47 CHRONIC IRRADIATION OF HUMAN CELLS REDUCES HISTONE LEVELS AND DEREGULATES GENE EXPRESSION. OVER THE PAST DECADES, THERE HAVE BEEN HUGE ADVANCES IN UNDERSTANDING CELLULAR RESPONSES TO IONISING RADIATION (IR) AND DNA DAMAGE. THESE STUDIES, HOWEVER, WERE MOSTLY EXECUTED WITH CELL LINES AND MICE USING SINGLE OR MULTIPLE ACUTE DOSES OF RADIATION. HENCE, RELATIVELY LITTLE IS KNOWN ABOUT HOW CONTINUOUS EXPOSURE TO LOW DOSE IONISING RADIATION AFFECTS NORMAL CELLS AND ORGANISMS, EVEN THOUGH OUR CELLS ARE CONSTANTLY EXPOSED TO LOW LEVELS OF RADIATION. WE ADDRESSED THIS ISSUE BY EXAMINING THE CONSEQUENCES OF EXPOSING HUMAN PRIMARY CELLS TO CONTINUOUS IONISING GAMMA-RADIATION DELIVERED AT 6-20 MGY/H. ALTHOUGH THESE DOSE RATES ARE ESTIMATED TO INFLICT FEWER THAN A SINGLE DNA DOUBLE-STRAND BREAK (DSB) PER HOUR PER CELL, THEY STILL CAUSED DOSE-DEPENDENT REDUCTIONS IN CELL PROLIFERATION AND INCREASED CELLULAR SENESCENCE. WE CONCOMITANTLY OBSERVED HISTONE PROTEIN LEVELS TO REDUCE BY UP TO 40%, WHICH IN CONTRAST TO PREVIOUS OBSERVATIONS, WAS NOT MAINLY DUE TO PROTEIN DEGRADATION BUT INSTEAD CORRELATED WITH REDUCED HISTONE GENE EXPRESSION. HISTONE REDUCTIONS WERE ACCOMPANIED BY ENLARGED NUCLEAR SIZE PARALLELED BY AN INCREASE IN GLOBAL TRANSCRIPTION, INCLUDING THAT OF PRO-INFLAMMATORY GENES. THUS, CHRONIC IRRADIATION, EVEN AT LOW DOSE-RATES, CAN INDUCE CELL SENESCENCE AND ALTER GENE EXPRESSION VIA A HITHERTO UNCHARACTERISED EPIGENETIC ROUTE. THESE FEATURES OF CHRONIC RADIATION REPRESENT A NEW ASPECT OF RADIATION BIOLOGY. 2020 3 5645 30 SEX DEPENDENT ALTERATION OF EPIGENETIC MARKS AFTER CHRONIC MORPHINE TREATMENT IN MICE ORGANS. EPIGENETIC MARKS MAY BE ALSO AFFECTED BY SEVERAL FACTORS, SUCH AS AGE, LIFESTYLE, EARLY LIFE EXPERIENCES AND EXPOSURE TO CHEMICALS OR DRUGS, SUCH AS OPIOIDS. PREVIOUS STUDIES HAVE FOCUSED ON HOW MORPHINE EPIGENETICALLY REGULATES DIFFERENT REGIONS OF THE BRAIN THAT ARE IMPLICATED IN TOLERANCE, DEPENDENCE AND OTHER PSYCHIATRIC DISORDERS MORE RELATED TO THE PHYSIO-PATHOLOGICAL EFFECTS OF OPIOIDS. NEVERTHELESS, A SIGNIFICANT KNOWLEDGE GAP REMAINS REGARDING THE EFFECT OF CHRONIC TREATMENT ON OTHER ORGANS AND BIOLOGICAL SYSTEMS. THEREFORE, THE AIM OF THIS WORK IS TO INCREASE OUR KNOWLEDGE ABOUT THE IMPACT OF CHRONIC MORPHINE EXPOSURE ON DNA METHYLATION AND HISTONE MODIFICATION LEVELS IN EACH OF THE ORGANS OF MALE AND FEMALE MODEL MICE IN VIVO. OUR RESULTS REVEAL, FOR THE FIRST TIME, THAT CHRONIC MORPHINE TREATMENT INDUCED CHANGES IN DNA METHYLATION/HYDROXYMETHYLATION AND HISTONE MODIFICATION IN-VIVO AT THE SYSTEMIC LEVEL, REVEALING A POTENTIAL PHYSIOLOGICAL EFFECT ON THE REGULATION OF GENE EXPRESSION. NOTABLY, MORPHINE-INDUCED EPIGENETIC MODIFICATION OCCURS IN A SEX-DEPENDENT MANNER, REVEALING THE EXISTENCE OF DIFFERENT UNDERLYING MECHANISMS OF EPIGENETIC MODIFICATION IN MALE AND FEMALE MICE. 2021 4 126 49 A TOXICOGENOMICS APPROACH TO IDENTIFY NEW PLAUSIBLE EPIGENETIC MECHANISMS OF OCHRATOXIN A CARCINOGENICITY IN RAT. OCHRATOXIN A (OTA) IS A MYCOTOXIN OCCURRING NATURALLY IN A WIDE RANGE OF FOOD COMMODITIES. IN ANIMALS, IT HAS BEEN SHOWN TO CAUSE A VARIETY OF ADVERSE EFFECTS, NEPHROCARCINOGENICITY BEING THE MOST PROMINENT. BECAUSE OF ITS HIGH TOXIC POTENCY AND THE CONTINUOUS EXPOSURE OF THE HUMAN POPULATION, OTA HAS RAISED PUBLIC HEALTH CONCERNS. THERE IS SIGNIFICANT DEBATE ON HOW TO USE THE RAT CARCINOGENICITY DATA TO ASSESS THE POTENTIAL RISK TO HUMANS. IN THIS CONTEXT, THE QUESTION OF THE MECHANISM OF ACTION OF OTA APPEARS OF KEY IMPORTANCE AND WAS STUDIED THROUGH THE APPLICATION OF A TOXICOGENOMICS APPROACH. MALE FISCHER RATS WERE FED OTA FOR UP TO 2 YEARS. RENAL TUMORS WERE DISCOVERED DURING THE LAST 6 MONTHS OF THE STUDY. THE TOTAL TUMOR INCIDENCE REACHED 25% AT THE END OF THE STUDY. GENE EXPRESSION PROFILE WAS ANALYZED IN GROUPS OF ANIMALS TAKEN IN INTERVALS FROM 7 DAYS TO 12 MONTHS. TISSUE-SPECIFIC RESPONSES WERE OBSERVED IN KIDNEY VERSUS LIVER. FOR SELECTED GENES, MICROARRAY DATA WERE CONFIRMED AT BOTH MRNA AND PROTEIN LEVELS. IN KIDNEY, SEVERAL GENES KNOWN AS MARKERS OF KIDNEY INJURY AND CELL REGENERATION WERE SIGNIFICANTLY MODULATED BY OTA. THE EXPRESSION OF GENES KNOWN TO BE INVOLVED IN DNA SYNTHESIS AND REPAIR, OR GENES INDUCED AS A RESULT OF DNA DAMAGE, WAS ONLY MARGINALLY MODULATED. VERY LITTLE OR NO EFFECT WAS FOUND AMONGST GENES ASSOCIATED WITH APOPTOSIS. ALTERATIONS OF GENE EXPRESSION INDICATING EFFECTS ON CALCIUM HOMEOSTASIS AND A DISRUPTION OF PATHWAYS REGULATED BY THE TRANSCRIPTION FACTORS HEPATOCYTE NUCLEAR FACTOR 4 ALPHA (HNF4ALPHA) AND NUCLEAR FACTOR-ERYTHROID 2-RELATED FACTOR 2 (NRF2) WERE OBSERVED IN THE KIDNEY BUT NOT IN THE LIVER. PREVIOUS DATA HAVE SUGGESTED THAT A REDUCTION IN HNF4ALPHA MAY BE ASSOCIATED WITH NEPHROCARCINOGENICITY. MANY NRF2-REGULATED GENES ARE INVOLVED IN CHEMICAL DETOXICATION AND ANTIOXIDANT DEFENSE. THE DEPLETION OF THESE GENES IS LIKELY TO IMPAIR THE DEFENSE POTENTIAL OF THE CELLS, RESULTING IN CHRONIC ELEVATION OF OXIDATIVE STRESS IN THE KIDNEY. THE INHIBITION OF DEFENSE MECHANISM APPEARS AS A HIGHLY PLAUSIBLE NEW MECHANISM, WHICH COULD CONTRIBUTE TO OTA CARCINOGENICITY. 2006 5 1815 35 EFFECTS OF CHRONIC EXPOSURE TO ARSENIC AND ESTROGEN ON EPIGENETIC REGULATORY GENES EXPRESSION AND EPIGENETIC CODE IN HUMAN PROSTATE EPITHELIAL CELLS. CHRONIC EXPOSURES TO ARSENIC AND ESTROGEN ARE KNOWN RISK FACTORS FOR PROSTATE CANCER. THOUGH THE EVIDENCE SUGGESTS THAT EXPOSURE TO ARSENIC OR ESTROGENS CAN DISRUPT NORMAL DNA METHYLATION PATTERNS AND HISTONE MODIFICATIONS, THE MECHANISMS BY WHICH THESE CHEMICALS INDUCE EPIGENETIC CHANGES ARE NOT FULLY UNDERSTOOD. MOREOVER, THE EPIGENETIC EFFECTS OF CO-EXPOSURE TO THESE TWO CHEMICALS ARE NOT KNOWN. THEREFORE, THE OBJECTIVE OF THIS STUDY WAS TO EVALUATE THE EFFECTS OF CHRONIC EXPOSURE TO ARSENIC AND ESTROGEN, BOTH ALONE AND IN COMBINATION, ON THE EXPRESSION OF EPIGENETIC REGULATORY GENES, THEIR CONSEQUENCES ON DNA METHYLATION, AND HISTONE MODIFICATIONS. HUMAN PROSTATE EPITHELIAL CELLS, RWPE-1, CHRONICALLY EXPOSED TO ARSENIC AND ESTROGEN ALONE AND IN COMBINATION WERE USED FOR ANALYSIS OF EPIGENETIC REGULATORY GENES EXPRESSION, GLOBAL DNA METHYLATION CHANGES, AND HISTONE MODIFICATIONS AT PROTEIN LEVEL. THE RESULT OF THIS STUDY REVEALED THAT EXPOSURE TO ARSENIC, ESTROGEN, AND THEIR COMBINATION ALTERS THE EXPRESSION OF EPIGENETIC REGULATORY GENES AND CHANGES GLOBAL DNA METHYLATION AND HISTONE MODIFICATION PATTERNS IN RWPE-1 CELLS. THESE CHANGES WERE SIGNIFICANTLY GREATER IN ARSENIC AND ESTROGEN COMBINATION TREATED GROUP THAN INDIVIDUALLY TREATED GROUP. THE FINDINGS OF THIS STUDY WILL HELP EXPLAIN THE EPIGENETIC MECHANISM OF ARSENIC- AND/OR ESTROGEN-INDUCED PROSTATE CARCINOGENESIS. 2012 6 3148 41 GLUCOCORTICOID INDUCED LOSS OF OESTROGEN RECEPTOR ALPHA GENE METHYLATION AND RESTORATION OF SENSITIVITY TO FULVESTRANT IN TRIPLE NEGATIVE BREAST CANCER. THE RESPONSE TO PSYCHOLOGICAL STRESS CAN DIFFER DEPENDING ON THE TYPE AND DURATION OF THE STRESSOR. ACUTE STRESS CAN FACILITATE A "FIGHT OR FLIGHT RESPONSE" AND AID SURVIVAL, WHEREAS CHRONIC LONG-TERM STRESS WITH THE PERSISTENT RELEASE OF STRESS HORMONES SUCH AS CORTISOL HAS BEEN SHOWN TO BE DETRIMENTAL TO HEALTH. WE ARE NOW BEGINNING TO UNDERSTAND HOW THIS STRESS HORMONE RESPONSE IMPACTS IMPORTANT PROCESSES SUCH AS DNA REPAIR AND CELL PROLIFERATION PROCESSES IN BREAST CANCER. HOWEVER, IT IS NOT KNOWN WHAT EPIGENETIC CHANGES STRESS HORMONES INDUCE IN BREAST CANCER. EPIGENETIC MECHANISMS INCLUDE MODIFICATION OF DNA AND HISTONES WITHIN CHROMATIN THAT MAY BE INVOLVED IN GOVERNING THE TRANSCRIPTIONAL PROCESSES IN CANCER CELLS IN RESPONSE TO CHANGES BY ENDOGENOUS STRESS HORMONES. THE CONTRIBUTION OF ENDOGENOUS ACUTE OR LONG-TERM EXPOSURE OF GLUCOCORTICOID STRESS HORMONES, AND EXOGENOUS GLUCOCORTICOIDS TO METHYLATION PATTERNS IN BREAST CANCER TISSUES WITH DIFFERENT AETIOLOGIES REMAINS TO BE EVALUATED. IN VITRO AND IN VIVO MODELS WERE DEVELOPED TO INVESTIGATE THE EPIGENETIC MODIFICATIONS AND THEIR CONTRIBUTION TO BREAST CANCER PROGRESSION AND AETIOLOGY. A PANEL OF TRIPLE NEGATIVE BREAST CANCER CELL LINES WERE TREATED WITH THE GLUCOCORTICOID, CORTISOL WHICH RESULTED IN EPIGENETIC ALTERATION CHARACTERISED BY LOSS OF METHYLATION ON PROMOTER REGIONS OF TUMOUR SUPPRESSOR GENES INCLUDING ESR1, AND LOSS OF METHYLATION ON LINE-1 REPETITIVE ELEMENT USED AS A SURROGATE MARKER FOR GLOBAL METHYLATION. THIS WAS VERIFIED IN VIVO IN MDA-MB-231 XENOGRAFTS; THE MODEL VERIFIED THE LOSS OF METHYLATION ON ESR1 PROMOTER, AND SUBSEQUENT INCREASE IN ESR1 EXPRESSION IN PRIMARY TUMOURS IN MICE SUBJECTED TO RESTRAINT STRESS. OUR STUDY HIGHLIGHTS THAT DNA METHYLATION LANDSCAPE IN BREAST CANCER CAN BE ALTERED IN RESPONSE TO STRESS AND GLUCOCORTICOID TREATMENT. 2023 7 948 24 CHRONIC METABOLIC DERANGEMENT-INDUCED COGNITIVE DEFICITS AND NEUROTOXICITY ARE ASSOCIATED WITH REST INACTIVATION. CHRONIC METABOLIC ALTERATIONS MAY REPRESENT A RISK FACTOR FOR THE DEVELOPMENT OF COGNITIVE IMPAIRMENT, DEMENTIA, OR NEURODEGENERATIVE DISEASES. HYPERGLYCEMIA AND OBESITY ARE KNOWN TO IMPRINT EPIGENETIC MARKERS THAT COMPROMISE THE PROPER EXPRESSION OF CELL SURVIVAL GENES. HERE, WE SHOWED THAT CHRONIC HYPERGLYCEMIA (60 DAYS) INDUCED BY A SINGLE INTRAPERITONEAL INJECTION OF STREPTOZOTOCIN COMPROMISED COGNITION BY REDUCING HIPPOCAMPAL ERK SIGNALING AND BY INDUCING NEUROTOXICITY IN RATS. THE MECHANISMS APPEAR TO BE LINKED TO REDUCED ACTIVE DNA DEMETHYLATION AND DIMINISHED EXPRESSION OF THE NEUROPROTECTIVE TRANSCRIPTION FACTOR REST. THE IMPACT OF THE RELATIONSHIP BETWEEN ADIPOSITY AND DNA HYPERMETHYLATION ON REST EXPRESSION WAS ALSO DEMONSTRATED IN PERIPHERAL BLOOD MONONUCLEAR CELLS IN OBESE CHILDREN WITH REDUCED LEVELS OF BLOOD ASCORBATE. THE REVERSIBLE NATURE OF EPIGENETIC MODIFICATIONS AND THE COGNITIVE IMPAIRMENT REPORTED IN OBESE CHILDREN, ADOLESCENTS, AND ADULTS SUGGEST THAT THE CORRECTION OF THE ANTHROPOMETRY AND THE PERIPHERAL METABOLIC ALTERATIONS WOULD PROTECT BRAIN HOMEOSTASIS AND REDUCE THE RISK OF DEVELOPING NEURODEGENERATIVE DISEASES. 2019 8 712 39 CADMIUM AND ITS EPIGENETIC EFFECTS. CADMIUM (CD) IS A TOXIC, NONESSENTIAL TRANSITION METAL AND CONTRIBUTES A HEALTH RISK TO HUMANS, INCLUDING VARIOUS CANCERS AND CARDIOVASCULAR DISEASES; HOWEVER, UNDERLYING MOLECULAR MECHANISMS REMAIN LARGELY UNKNOWN. CELLS TRANSMIT INFORMATION TO THE NEXT GENERATION VIA TWO DISTINCT WAYS: GENETIC AND EPIGENETIC. CHEMICAL MODIFICATIONS TO DNA OR HISTONE THAT ALTERS THE STRUCTURE OF CHROMATIN WITHOUT CHANGE OF DNA NUCLEOTIDE SEQUENCE ARE KNOWN AS EPIGENETICS. THESE HERITABLE EPIGENETIC CHANGES INCLUDE DNA METHYLATION, POST-TRANSLATIONAL MODIFICATIONS OF HISTONE TAILS (ACETYLATION, METHYLATION, PHOSPHORYLATION, ETC), AND HIGHER ORDER PACKAGING OF DNA AROUND NUCLEOSOMES. APART FROM DNA METHYLTRANSFERASES, HISTONE MODIFICATION ENZYMES SUCH AS HISTONE ACETYLTRANSFERASE, HISTONE DEACETYLASE, AND METHYLTRANSFERASE, AND MICRORNAS (MIRNAS) ALL INVOLVE IN THESE EPIGENETIC CHANGES. RECENT STUDIES INDICATE THAT CD IS ABLE TO INDUCE VARIOUS EPIGENETIC CHANGES IN PLANT AND MAMMALIAN CELLS IN VITRO AND IN VIVO. SINCE ABERRANT EPIGENETICS PLAYS A CRITICAL ROLE IN THE DEVELOPMENT OF VARIOUS CANCERS AND CHRONIC DISEASES, CD MAY CAUSE THE ABOVE-MENTIONED PATHOGENIC RISKS VIA EPIGENETIC MECHANISMS. HERE WE REVIEW THE IN VITRO AND IN VIVO EVIDENCE OF EPIGENETIC EFFECTS OF CD. THE AVAILABLE FINDINGS INDICATE THAT EPIGENETICS OCCURRED IN ASSOCIATION WITH CD INDUCTION OF MALIGNANT TRANSFORMATION OF CELLS AND PATHOLOGICAL PROLIFERATION OF TISSUES, SUGGESTING THAT EPIGENETIC EFFECTS MAY PLAY A ROLE IN CD TOXIC, PARTICULARLY CARCINOGENIC EFFECTS. THE FUTURE OF ENVIRONMENTAL EPIGENOMIC RESEARCH ON CD SHOULD INCLUDE THE ROLE OF EPIGENETICS IN DETERMINING LONG-TERM AND LATE-ONSET HEALTH EFFECTS FOLLOWING CD EXPOSURE. 2012 9 2405 51 EPIGENETIC RESPONSE IN MICE MASTITIS: ROLE OF HISTONE H3 ACETYLATION AND MICRORNA(S) IN THE REGULATION OF HOST INFLAMMATORY GENE EXPRESSION DURING STAPHYLOCOCCUS AUREUS INFECTION. BACKGROUND: THERE IS RENEWED INTEREST TOWARDS UNDERSTANDING THE HOST-PATHOGEN INTERACTION IN THE LIGHT OF EPIGENETIC MODIFICATIONS. ALTHOUGH EPITHELIAL TISSUE IS THE MAJOR SITE FOR HOST-PATHOGEN INTERACTIONS, THERE IS HANDFUL OF STUDIES TO SHOW HOW EPITHELIAL CELLS RESPOND TO PATHOGENS. BACTERIAL INFECTION IN THE MAMMARY GLAND PARENCHYMA INDUCES LOCAL AND SUBSEQUENTLY SYSTEMIC INFLAMMATION THAT RESULTS IN A COMPLEX DISEASE CALLED MASTITIS. GLOBALLY STAPHYLOCOCCUS AUREUS IS THE SINGLE LARGEST MASTITIS PATHOGEN AND THE INFECTION CAN ULTIMATELY RESULT IN EITHER SUBCLINICAL OR CHRONIC AND SOMETIMES LIFELONG INFECTION. RESULTS: IN THE PRESENT REPORT WE HAVE ADDRESSED THE DIFFERENTIAL INFLAMMATORY RESPONSE IN MICE MAMMARY TISSUE DURING INTRAMAMMARY INFECTION AND THE ALTERED EPIGENETIC CONTEXT INDUCED BY TWO CLOSELY RELATED STRAINS OF S. AUREUS, ISOLATED FROM FIELD SAMPLES. IMMUNOHISTOCHEMICAL AND IMMUNOBLOTTING ANALYSIS SHOWED STRAIN SPECIFIC HYPERACETYLATION AT HISTONE H3K9 AND H3K14 RESIDUES. GLOBAL GENE EXPRESSION ANALYSIS IN S. AUREUS INFECTED MICE MAMMARY TISSUE REVEALED A SELECTIVE SET OF UPREGULATED GENES THAT SIGNIFICANTLY CORRELATED WITH THE PROMOTER SPECIFIC, HISTONE H3K14 ACETYLATION. FURTHERMORE, WE HAVE IDENTIFIED SEVERAL DIFFERENTIALLY EXPRESSED KNOWN MIRNAS AND 3 NOVEL MIRNAS IN S. AUREUS INFECTED MICE MAMMARY TISSUE BY SMALL RNA SEQUENCING. BY EMPLOYING THESE GENE EXPRESSION DATA, AN ATTEMPT HAS BEEN MADE TO DELINEATE THE GENE REGULATORY NETWORKS IN THE STRAIN SPECIFIC INFLAMMATORY RESPONSE. APPARENTLY, ONE OF THE ISOLATES OF S. AUREUS ACTIVATED THE NF-KAPPAB SIGNALING LEADING TO DRASTIC INFLAMMATORY RESPONSE AND INDUCTION OF IMMUNE SURVEILLANCE, WHICH COULD POSSIBLY LEAD TO RAPID CLEARANCE OF THE PATHOGEN. THE OTHER STRAIN REPRESSED MOST OF THE INFLAMMATORY RESPONSE, WHICH MIGHT HELP IN ITS SUSTENANCE IN THE HOST TISSUE. CONCLUSION: TAKEN TOGETHER, OUR STUDIES SHED SUBSTANTIAL LIGHTS TO UNDERSTAND THE MECHANISMS OF STRAIN SPECIFIC DIFFERENTIAL INFLAMMATORY RESPONSE TO S. AUREUS INFECTION DURING MASTITIS. IN A BROADER PERSPECTIVE THIS STUDY ALSO PAVES THE WAY TO UNDERSTAND HOW CERTAIN BACTERIA CAN EVADE THE IMMUNE SURVEILLANCE AND CAUSE SUSTAINED INFECTION WHILE OTHERS ARE RAPIDLY CLEARED FROM THE HOST BODY. 2014 10 5711 37 SIRT1 IS A HIGHLY NETWORKED PROTEIN THAT MEDIATES THE ADAPTATION TO CHRONIC PHYSIOLOGICAL STRESS. SIRT1 IS A NAD(+)-DEPENDENT PROTEIN DEACETYLASE THAT HAS A VERY LARGE NUMBER OF ESTABLISHED PROTEIN SUBSTRATES AND AN EQUALLY IMPRESSIVE LIST OF BIOLOGICAL FUNCTIONS THOUGHT TO BE REGULATED BY ITS ACTIVITY. PERHAPS AS NOTABLE IS THE REMARKABLE NUMBER OF POINTS OF CONFLICT CONCERNING THE ROLE OF SIRT1 IN BIOLOGICAL PROCESSES. FOR EXAMPLE, EVIDENCE EXISTS SUGGESTING THAT SIRT1 IS A TUMOR SUPPRESSOR, IS AN ONCOGENE, OR HAS NO EFFECT ON ONCOGENESIS. SIMILARLY, SIRT1 IS VARIABLY REPORTED TO INDUCE, INHIBIT, OR HAVE NO EFFECT ON AUTOPHAGY. WE BELIEVE THAT THE RESOLUTION OF MANY CONFLICTING RESULTS IS POSSIBLE BY CONSIDERING RECENT REPORTS INDICATING THAT SIRT1 IS AN IMPORTANT HUB INTERACTING WITH A COMPLEX NETWORK OF PROTEINS THAT COLLECTIVELY REGULATE A WIDE VARIETY OF BIOLOGICAL PROCESSES INCLUDING CANCER AND AUTOPHAGY. A NUMBER OF THE INTERACTING PROTEINS ARE THEMSELVES HUBS THAT, LIKE SIRT1, UTILIZE INTRINSICALLY DISORDERED REGIONS FOR THEIR PROMISCUOUS INTERACTIONS. MANY STUDIES INVESTIGATING SIRT1 FUNCTION HAVE BEEN CARRIED OUT ON CELL LINES CARRYING UNDETERMINED NUMBERS OF ALTERATIONS TO THE PROTEINS COMPRISING THE SIRT1 NETWORK OR ON INBRED MOUSE STRAINS CARRYING FIXED MUTATIONS AFFECTING SOME OF THESE PROTEINS. THUS, THE EFFECTS OF MODULATING SIRT1 AMOUNT AND/OR ACTIVITY ARE IMPORTANTLY DETERMINED BY THE GENETIC BACKGROUND OF THE CELL (OR THE INBRED STRAIN OF MICE), AND THE EFFECTS ATTRIBUTED TO SIRT1 ARE SYNTHETIC WITH THE BACKGROUND OF MUTATIONS AND EPIGENETIC DIFFERENCES BETWEEN CELLS AND ORGANISMS. WORK ON MICE CARRYING ALTERATIONS TO THE SIRT1 GENE SUGGESTS THAT THE NETWORK IN WHICH SIRT1 FUNCTIONS PLAYS AN IMPORTANT ROLE IN MEDIATING PHYSIOLOGICAL ADAPTATION TO VARIOUS SOURCES OF CHRONIC STRESS SUCH AS CALORIE RESTRICTION AND CALORIE OVERLOAD. WHETHER THE CATALYTIC ACTIVITY OF SIRT1 AND THE NUCLEAR CONCENTRATION OF THE CO-FACTOR, NAD(+), ARE RESPONSIBLE FOR MODULATING THIS ACTIVITY REMAINS TO BE DETERMINED. HOWEVER, THE EFFECT OF MODULATING SIRT1 ACTIVITY MUST BE INTERPRETED IN THE CONTEXT OF THE CELL OR TISSUE UNDER INVESTIGATION. INDEED, FOR SIRT1, WE ARGUE THAT CONTEXT IS EVERYTHING. 2013 11 6427 36 THE TRANSITION FROM ACUTE TO CHRONIC PAIN: DYNAMIC EPIGENETIC REPROGRAMMING OF THE MOUSE PREFRONTAL CORTEX UP TO 1 YEAR AFTER NERVE INJURY. CHRONIC PAIN IS ASSOCIATED WITH PERSISTENT STRUCTURAL AND FUNCTIONAL CHANGES THROUGHOUT THE NEUROAXIS, INCLUDING IN THE PREFRONTAL CORTEX (PFC). THE PFC IS IMPORTANT IN THE INTEGRATION OF SENSORY, COGNITIVE, AND EMOTIONAL INFORMATION AND IN CONDITIONED PAIN MODULATION. WE PREVIOUSLY REPORTED WIDESPREAD EPIGENETIC REPROGRAMMING IN THE PFC MANY MONTHS AFTER NERVE INJURY IN RODENTS. EPIGENETIC MODIFICATIONS, INCLUDING DNA METHYLATION, CAN DRIVE CHANGES IN GENE EXPRESSION WITHOUT MODIFYING DNA SEQUENCES. TO DATE, LITTLE IS KNOWN ABOUT EPIGENETIC DYSREGULATION AT THE ONSET OF ACUTE PAIN OR HOW IT PROGRESSES AS PAIN TRANSITIONS FROM ACUTE TO CHRONIC. WE HYPOTHESIZE THAT ACUTE PAIN AFTER INJURY RESULTS IN RAPID AND PERSISTENT EPIGENETIC REMODELLING IN THE PFC THAT EVOLVES AS PAIN BECOMES CHRONIC. WE FURTHER PROPOSE THAT UNDERSTANDING EPIGENETIC REMODELLING WILL PROVIDE INSIGHTS INTO THE MECHANISMS DRIVING PAIN-RELATED CHANGES IN THE BRAIN. EPIGENOME-WIDE ANALYSIS WAS PERFORMED IN THE MOUSE PFC 1 DAY, 2 WEEKS, 6 MONTHS, AND 1 YEAR AFTER PERIPHERAL INJURY USING THE SPARED NERVE INJURY IN MICE. SPARED NERVE INJURY RESULTED IN RAPID AND PERSISTENT CHANGES IN DNA METHYLATION, WITH ROBUST DIFFERENTIAL METHYLATION OBSERVED BETWEEN SPARED NERVE INJURY AND SHAM-OPERATED CONTROL MICE AT ALL TIME POINTS. HUNDREDS OF DIFFERENTIALLY METHYLATED GENES WERE IDENTIFIED, INCLUDING MANY WITH KNOWN FUNCTION IN PAIN. PATHWAY ANALYSIS REVEALED ENRICHMENT IN GENES RELATED TO STIMULUS RESPONSE AT EARLY TIME POINTS, IMMUNE FUNCTION AT LATER TIME POINTS, AND ACTIN AND CYTOSKELETAL REGULATION THROUGHOUT THE TIME COURSE. THESE RESULTS EMPHASIZE THE IMPORTANCE OF CONSIDERING PAIN CHRONICITY IN BOTH PAIN RESEARCH AND IN TREATMENT OPTIMIZATION. 2020 12 904 46 CHRONIC EXPOSURE TO CADMIUM INDUCES DIFFERENTIAL METHYLATION IN MICE SPERMATOZOA. CADMIUM EXPOSURE IS UBIQUITOUS AND HAS BEEN LINKED TO DISEASES INCLUDING CANCERS AND REPRODUCTIVE DEFECTS. SINCE CADMIUM IS NONMUTAGENIC, IT IS THOUGHT TO EXERT ITS GENE DYSREGULATORY EFFECTS THROUGH EPIGENETIC REPROGRAMMING. SEVERAL STUDIES HAVE IMPLICATED GERMLINE EXPOSURE TO CADMIUM IN DEVELOPMENTAL REPROGRAMMING. HOWEVER, MOST OF THESE STUDIES HAVE FOCUSED ON MATERNAL EXPOSURE, WHILE THE IMPACT ON SPERM FERTILITY AND DISEASE SUSCEPTIBILITY HAS RECEIVED LESS ATTENTION. IN THIS STUDY, WE USED REDUCED REPRESENTATION BISULFITE SEQUENCING TO COMPREHENSIVELY INVESTIGATE THE IMPACT OF CHRONIC CADMIUM EXPOSURE ON MOUSE SPERMATOZOA DNA METHYLATION. ADULT MALE C57BL/J6 MICE WERE PROVIDED WATER WITH OR WITHOUT CADMIUM CHLORIDE FOR 9 WEEKS. SPERM, TESTES, LIVER, AND KIDNEY TISSUES WERE COLLECTED AT THE END OF THE TREATMENT PERIOD. CADMIUM EXPOSURE WAS CONFIRMED THROUGH GENE EXPRESSION ANALYSIS OF METALLOTHIONEIN-1 AND 2, 2 WELL-KNOWN CADMIUM-INDUCED GENES. ANALYSIS OF SPERM DNA METHYLATION CHANGES REVEALED 1788 DIFFERENTIALLY METHYLATED SITES PRESENT AT REGULATORY REGIONS IN SPERM OF MICE EXPOSED TO CADMIUM COMPARED WITH VEHICLE (CONTROL) MICE. FURTHERMORE, MOST OF THESE DIFFERENTIAL METHYLATION CHANGES POSITIVELY CORRELATED WITH CHANGES IN GENE EXPRESSION AT BOTH THE TRANSCRIPTION INITIATION STAGE AS WELL AS THE SPLICING LEVELS. INTERESTINGLY, THE GENES TARGETED BY CADMIUM EXPOSURE ARE INVOLVED IN SEVERAL CRITICAL DEVELOPMENTAL PROCESSES. OUR RESULTS PRESENT A COMPREHENSIVE ANALYSIS OF THE SPERM METHYLOME IN RESPONSE TO CHRONIC CADMIUM EXPOSURE. THESE DATA, THEREFORE, HIGHLIGHT A FOUNDATIONAL FRAMEWORK TO STUDY GENE EXPRESSION PATTERNS THAT MAY AFFECT FERTILITY IN THE EXPOSED INDIVIDUAL AS WELL AS THEIR OFFSPRING, THROUGH PATERNAL INHERITANCE. 2021 13 1202 38 COULD DNA HYDROXYMETHYLATION BE CRUCIAL IN INFLUENCING STEROID HORMONE SIGNALING IN ENDOMETRIAL BIOLOGY AND ENDOMETRIOSIS? ENDOMETRIOSIS AFFECTS 10% OF REPRODUCTIVE-AGED WOMEN. IT IS CHARACTERIZED BY THE GROWTH OF THE ENDOMETRIUM, OUTSIDE THE UTERUS AND IS ASSOCIATED WITH INFERTILITY AND CHRONIC ABDOMINAL PAIN. LACK OF NONINVASIVE DIAGNOSTIC TOOLS AND EARLY SCREENING TESTS RESULTS IN DELAYED TREATMENT AND SUBSEQUENTLY INCREASED DISEASE SEVERITY. ENDOMETRIOSIS IS A DISEASE ASSOCIATED WITH A DEREGULATED HORMONAL RESPONSE, THEREFORE, UNDERSTANDING THE MOLECULAR MECHANISMS THAT GOVERN THIS HORMONAL INTERPLAY IS OF PARAMOUNT IMPORTANCE. DNA METHYLATION IS AN EPIGENETIC MARK THAT REGULATES GENE EXPRESSION AND IS OFTEN ASSOCIATED WITH GENES THAT CODE FOR STEROID RECEPTORS AND ENZYMES ASSOCIATED WITH ESTROGEN SYNTHESIS AND METABOLISM IN ENDOMETRIOSIS. DNA HYDROXYMETHYLATION, WHICH IS STRUCTURALLY SIMILAR TO METHYLATION BUT FUNCTIONALLY DIFFERENT, IS A BIOLOGICALLY CRITICAL MECHANISM THAT IS ALSO KNOWN TO REGULATE GENE EXPRESSION. TEN ELEVEN TRANSLOCATION (TET) PROTEINS MEDIATE HYDROXYMETHYLATION. HOWEVER, THE ROLE OF DNA HYDROXYMETHYLATION OR TETS IN THE ENDOMETRIUM REMAINS RELATIVELY UNEXPLORED. CURRENTLY, THE "GOLD STANDARD" TECHNIQUE USED TO STUDY METHYLATION PATTERNS IS BISULFITE GENOMIC SEQUENCING. THIS TECHNIQUE ALSO DETECTS HYDROXYMETHYLATION BUT FAILS TO DISTINGUISH BETWEEN THE TWO, THEREBY LIMITING OUR UNDERSTANDING OF THESE TWO PROCESSES. THE PRESENCE OF TETS IN THE MALE AND FEMALE REPRODUCTIVE TRACT AND ITS CONTRIBUTION TO ENDOMETRIAL CANCER MAKES IT AN IMPORTANT FACTOR TO STUDY IN ENDOMETRIOSIS. THIS REVIEW SUMMARIZES THE ROLE OF DNA METHYLATION IN ABERRANT STEROID HORMONE SIGNALING AND HYPOTHESIZES THAT HYDROXYMETHYLATION COULD BE A FACTOR INFLUENCING HORMONAL INSTABILITY SEEN IN ENDOMETRIOSIS. 2020 14 1520 33 DNA METHYLATION AT DIFFERENTIALLY METHYLATED REGIONS OF IMPRINTED GENES IS RESISTANT TO DEVELOPMENTAL PROGRAMMING BY MATERNAL NUTRITION. THE NUTRITIONAL ENVIRONMENT IN WHICH THE MAMMALIAN FETUS OR INFANT DEVELOP IS RECOGNIZED AS INFLUENCING THE RISK OF CHRONIC DISEASES, SUCH AS TYPE 2 DIABETES AND HYPERTENSION, IN A PHENOMENON THAT HAS BECOME KNOWN AS DEVELOPMENTAL PROGRAMMING. THE LATE ONSET OF SUCH DISEASES IN RESPONSE TO EARLIER TRANSIENT EXPERIENCES HAS LED TO THE SUGGESTION THAT DEVELOPMENTAL PROGRAMMING MAY HAVE AN EPIGENETIC COMPONENT, BECAUSE EPIGENETIC MARKS SUCH AS DNA METHYLATION OR HISTONE TAIL MODIFICATIONS COULD PROVIDE A PERSISTENT MEMORY OF EARLIER NUTRITIONAL STATES. ONE CLASS OF GENES THAT HAS BEEN CONSIDERED A POTENTIAL TARGET OR MEDIATOR OF PROGRAMMING EVENTS IS IMPRINTED GENES, BECAUSE THESE GENES CRITICALLY DEPEND UPON EPIGENETIC MODIFICATIONS FOR CORRECT EXPRESSION AND BECAUSE MANY IMPRINTED GENES HAVE ROLES IN CONTROLLING FETAL GROWTH AS WELL AS NEONATAL AND ADULT METABOLISM. IN THIS STUDY, WE HAVE USED AN ESTABLISHED MODEL OF DEVELOPMENTAL PROGRAMMING-ISOCALORIC PROTEIN RESTRICTION TO FEMALE MICE DURING GESTATION OR LACTATION-TO EXAMINE WHETHER THERE ARE EFFECTS ON EXPRESSION AND DNA METHYLATION OF IMPRINTED GENES IN THE OFFSPRING. WE FIND THAT ALTHOUGH EXPRESSION OF SOME IMPRINTED GENES IN LIVER OF OFFSPRING IS ROBUSTLY AND SUSTAINABLY CHANGED, METHYLATION OF THE DIFFERENTIALLY METHYLATED REGIONS (DMRS) THAT CONTROL THEIR MONOALLELIC EXPRESSION REMAINS LARGELY UNALTERED. WE CONCLUDE THAT DEREGULATION OF IMPRINTING THROUGH A GENERAL EFFECT ON DMR METHYLATION IS UNLIKELY TO BE A COMMON FACTOR IN DEVELOPMENTAL PROGRAMMING. 2012 15 2577 39 EPIGENETICS OF INFLAMMATION, MATERNAL INFECTION, AND NUTRITION. STUDIES HAVE DEMONSTRATED THAT EPIGENETIC CHANGES SUCH AS DNA METHYLATION, HISTONE MODIFICATION, AND CHROMATIN REMODELING ARE LINKED TO AN INCREASED INFLAMMATORY RESPONSE AS WELL AS INCREASED RISK OF CHRONIC DISEASE DEVELOPMENT. A FEW STUDIES HAVE BEGUN TO INVESTIGATE WHETHER DIETARY NUTRIENTS PLAY A BENEFICIAL ROLE BY MODIFYING OR REVERSING EPIGENETICALLY INDUCED INFLAMMATION. RESULTS OF THESE STUDIES SHOW THAT NUTRIENTS MODIFY EPIGENETIC PATHWAYS. HOWEVER, LITTLE IS KNOWN ABOUT HOW NUTRIENTS MODULATE INFLAMMATION BY REGULATING IMMUNE CELL FUNCTION AND/OR IMMUNE CELL DIFFERENTIATION VIA EPIGENETIC PATHWAYS. THIS OVERVIEW WILL PROVIDE INFORMATION ABOUT THE CURRENT UNDERSTANDING OF THE ROLE OF NUTRIENTS IN THE EPIGENETIC CONTROL MECHANISMS OF IMMUNE FUNCTION. 2015 16 2614 40 EPIGENETICS: NEW QUESTIONS ON THE RESPONSE TO HYPOXIA. REDUCTION IN OXYGEN LEVELS BELOW NORMAL CONCENTRATIONS PLAYS IMPORTANT ROLES IN DIFFERENT NORMAL AND PATHOLOGICAL CONDITIONS, SUCH AS DEVELOPMENT, TUMORIGENESIS, CHRONIC KIDNEY DISEASE AND STROKE. ORGANISMS EXPOSED TO HYPOXIA TRIGGER CHANGES AT BOTH CELLULAR AND SYSTEMIC LEVELS TO RECOVER OXYGEN HOMEOSTASIS. MOST OF THESE PROCESSES ARE MEDIATED BY HYPOXIA INDUCIBLE FACTORS, HIFS, A FAMILY OF TRANSCRIPTION FACTORS THAT DIRECTLY INDUCE THE EXPRESSION OF SEVERAL HUNDRED GENES IN MAMMALIAN CELLS. ALTHOUGH DIFFERENT ASPECTS OF HIF REGULATION ARE WELL KNOWN, IT IS STILL UNCLEAR BY WHICH PRECISE MECHANISM HIFS ACTIVATE TRANSCRIPTION OF THEIR TARGET GENES. CONCOMITANTLY, HYPOXIA PROVOKES A DRAMATIC DECREASE OF GENERAL TRANSCRIPTION THAT SEEMS TO RELY IN PART ON EPIGENETIC CHANGES THROUGH A POORLY UNDERSTOOD MECHANISM. IN THIS REVIEW WE DISCUSS THE CURRENT KNOWLEDGE ON CHROMATIN CHANGES INVOLVED IN HIF DEPENDENT GENE ACTIVATION, AS WELL AS ON OTHER EPIGENETIC CHANGES, NOT NECESSARILY LINKED TO HIF THAT TAKE PLACE UNDER HYPOXIC CONDITIONS. 2011 17 860 39 CHROMATIN MODIFICATIONS DURING REPAIR OF ENVIRONMENTAL EXPOSURE-INDUCED DNA DAMAGE: A POTENTIAL MECHANISM FOR STABLE EPIGENETIC ALTERATIONS. EXPOSURES TO ENVIRONMENTAL TOXICANTS AND TOXINS CAUSE EPIGENETIC CHANGES THAT LIKELY PLAY A ROLE IN THE DEVELOPMENT OF DISEASES ASSOCIATED WITH EXPOSURE. THE MECHANISM BEHIND THESE EXPOSURE-INDUCED EPIGENETIC CHANGES IS CURRENTLY UNKNOWN. ONE COMMONALITY BETWEEN MOST ENVIRONMENTAL EXPOSURES IS THAT THEY CAUSE DNA DAMAGE EITHER DIRECTLY OR THROUGH CAUSING AN INCREASE IN REACTIVE OXYGEN SPECIES, WHICH CAN DAMAGE DNA. LIKE TRANSCRIPTION, DNA DAMAGE REPAIR MUST OCCUR IN THE CONTEXT OF CHROMATIN REQUIRING BOTH HISTONE MODIFICATIONS AND ATP-DEPENDENT CHROMATIN REMODELING. THESE CHROMATIN CHANGES AID IN DNA DAMAGE ACCESSIBILITY AND SIGNALING. SEVERAL PROTEINS AND COMPLEXES INVOLVED IN EPIGENETIC SILENCING DURING BOTH DEVELOPMENT AND CANCER HAVE BEEN FOUND TO BE LOCALIZED TO SITES OF DNA DAMAGE. THE CHROMATIN-BASED RESPONSE TO DNA DAMAGE IS CONSIDERED A TRANSIENT EVENT, WITH CHROMATIN BEING RESTORED TO NORMAL AS DNA DAMAGE REPAIR IS COMPLETED. HOWEVER, IN INDIVIDUALS CHRONICALLY EXPOSED TO ENVIRONMENTAL TOXICANTS OR WITH CHRONIC INFLAMMATORY DISEASE, REPEATED DNA DAMAGE-INDUCED CHROMATIN REARRANGEMENT MAY ULTIMATELY LEAD TO PERMANENT EPIGENETIC ALTERATIONS. UNDERSTANDING THE MECHANISM BEHIND EXPOSURE-INDUCED EPIGENETIC CHANGES WILL ALLOW US TO DEVELOP STRATEGIES TO PREVENT OR REVERSE THESE CHANGES. THIS REVIEW FOCUSES ON EPIGENETIC CHANGES AND DNA DAMAGE INDUCED BY ENVIRONMENTAL EXPOSURES, THE CHROMATIN CHANGES THAT OCCUR AROUND SITES OF DNA DAMAGE, AND HOW THESE TRANSIENT CHROMATIN CHANGES MAY LEAD TO HERITABLE EPIGENETIC ALTERATIONS AT SITES OF CHRONIC EXPOSURE. 2014 18 4791 39 NUTRITIONAL CATCH-UP GROWTH. MALNUTRITION, MARKED BY VARIANT NUTRIENT DEFICIENCIES, IS CONSIDERED A LEADING CAUSE OF STUNTED GROWTH WORLDWIDE. IN DEVELOPING COUNTRIES, MALNUTRITION IS CAUSED MAINLY BY FOOD SHORTAGE AND INFECTIOUS DISEASES. MALNUTRITION MAY ALSO BE FOUND IN THE DEVELOPED WORLD, WHERE IT IS DUE MOSTLY TO PREMATURITY, CHRONIC DISEASES, AND ANOREXIA NERVOSA. IN MOST CASES, WHEN FOOD CONSUMPTION IS CORRECTED, SPONTANEOUS CATCH-UP (CU) GROWTH OCCURS. HOWEVER, CU GROWTH IS NOT ALWAYS COMPLETE, LEADING TO GROWTH DEFICITS. THEREFORE, IT IS IMPORTANT TO UNDERSTAND THE MECHANISMS THAT GOVERN THIS PROCESS. USING A RAT MODEL OF FOOD RESTRICTION FOLLOWED BY REFEEDING, WE ESTABLISHED A NUTRITION-INDUCED CU GROWTH MODEL. LEVELS OF LEPTIN AND INSULIN-LIKE GROWTH FACTOR-1 WERE FOUND TO SIGNIFICANTLY DECREASE WHEN FOOD WAS RESTRICTED AND TO INCREASE ALREADY 1 DAY AFTER REFEEDING. GENE EXPRESSION ANALYSIS OF THE GROWTH PLATE REVEALED THAT FOOD RESTRICTION SPECIFICALLY AFFECTS TRANSCRIPTION FACTORS SUCH AS THE HYPOXIA INDUCIBLE FACTOR-1 AND ITS DOWNSTREAM TARGETS ON THE ONE HAND, AND GLOBAL GENE EXPRESSION, INDICATING EPIGENETIC REGULATION, ON THE OTHER. FOOD RESTRICTION ALSO REDUCED THE LEVEL OF SEVERAL MICRORNAS, INCLUDING THE CHONDROCYTE-SPECIFIC MIR-140, WHICH LED TO AN INCREASE IN ITS TARGET, SIRT1, A CLASS III HISTONE DEACETYLASE. THESE FINDINGS MAY EXPLAIN THE GLOBAL CHANGES IN GENE EXPRESSION OBSERVED UNDER NUTRITIONAL MANIPULATION. WE SUGGEST THAT MULTIPLE LEVELS OF REGULATION, INCLUDING TRANSCRIPTION FACTORS, EPIGENETIC MECHANISMS, AND MICRORNAS RESPOND TO NUTRITIONAL CUES AND OFFER A POSSIBLE EXPLANATION FOR SOME OF THE EFFECTS OF FOOD RESTRICTION ON EPIPHYSEAL GROWTH PLATE GROWTH. THE MEANS WHEREBY THESE COMPONENTS SENSE CHANGES IN NUTRITIONAL STATUS ARE STILL UNKNOWN. DECIPHERING THE ROLE OF EPIGENETIC REGULATION IN GROWTH MAY PAVE THE WAY FOR THE DEVELOPMENT OF NEW TREATMENTS FOR CHILDREN WITH GROWTH DISORDERS. 2013 19 990 40 CHRONIC SOCIAL STRESS INDUCES DNA METHYLATION CHANGES AT AN EVOLUTIONARY CONSERVED INTERGENIC REGION IN CHROMOSOME X. CHRONIC STRESS RESULTING FROM PROLONGED EXPOSURE TO NEGATIVE LIFE EVENTS INCREASES THE RISK OF MOOD AND ANXIETY DISORDERS. ALTHOUGH CHRONIC STRESS CAN CHANGE GENE EXPRESSION RELEVANT FOR BEHAVIOR, MOLECULAR REGULATORS OF THIS CHANGE HAVE NOT BEEN FULLY DETERMINED. ONE PROCESS THAT COULD PLAY A ROLE IS DNA METHYLATION, AN EPIGENETIC PROCESS WHEREBY A METHYL GROUP IS ADDED ONTO NUCLEOTIDES, PREDOMINANTLY CYTOSINE IN THE CPG CONTEXT, AND WHICH CAN BE INDUCED BY CHRONIC STRESS. IT IS UNKNOWN TO WHAT EXTENT CHRONIC SOCIAL DEFEAT, A MODEL OF HUMAN SOCIAL STRESS, INFLUENCES DNA METHYLATION PATTERNS ACROSS THE GENOME. OUR STUDY ADDRESSED THIS QUESTION BY USING A TARGETED-CAPTURE APPROACH CALLED METHYL-SEQ TO INVESTIGATE DNA METHYLATION PATTERNS OF THE DENTATE GYRUS AT PUTATIVE REGULATORY REGIONS ACROSS THE MOUSE GENOME FROM MICE EXPOSED TO 14 DAYS OF SOCIAL DEFEAT. FINDINGS WERE REPLICATED IN INDEPENDENT COHORTS BY BISULFITE-PYROSEQUENCING. TWO DIFFERENTIALLY METHYLATED REGIONS (DMRS) WERE IDENTIFIED. ONE DMR WAS LOCATED AT INTRON 9 OF DROSHA, AND IT SHOWED REDUCED METHYLATION IN STRESSED MICE. THIS OBSERVATION REPLICATED IN ONE OF TWO INDEPENDENT COHORTS. A SECOND DMR WAS IDENTIFIED AT AN INTERGENIC REGION OF CHROMOSOME X, AND METHYLATION IN THIS REGION WAS INCREASED IN STRESSED MICE. THIS METHYLATION DIFFERENCE REPLICATED IN TWO INDEPENDENT COHORTS AND IN MAJOR DEPRESSIVE DISORDER (MDD) POSTMORTEM BRAINS. THESE RESULTS HIGHLIGHT A REGION NOT PREVIOUSLY KNOWN TO BE DIFFERENTIALLY METHYLATED BY CHRONIC SOCIAL DEFEAT STRESS AND WHICH MAY BE INVOLVED IN MDD. 2018 20 3837 31 IONIZING RADIATION-INDUCED OXIDATIVE STRESS, EPIGENETIC CHANGES AND GENOMIC INSTABILITY: THE PIVOTAL ROLE OF MITOCHONDRIA. PURPOSE: TO REVIEW THE DATA CONCERNING THE ROLE OF ENDOGENOUSLY GENERATED REACTIVE OXYGEN SPECIES (ROS) IN THE NON-TARGETED IONIZING RADIATION (IR) EFFECTS AND IN DETERMINATION OF THE CELL POPULATION'S FATE, BOTH EARLY AFTER EXPOSURE AND AFTER MANY GENERATIONS. CONCLUSIONS: THE SHORT-TERM AS WELL AS CHRONIC OXIDATIVE STRESS RESPONSES MAINLY ARE PRODUCED DUE TO ROS GENERATION BY THE ELECTRON TRANSPORT CHAIN (ETC) OF THE MITOCHONDRIA AND BY THE CYTOPLASMIC NADPH OXIDASES. WHETHER THE INDUCTION OF THE OXIDATIVE STRESS AND ITS CONSEQUENCES OCCUR OR ARE HAMPERED IN A SINGLE CELL LARGELY DEPENDS ON THE INTERACTION BETWEEN THE NUCLEUS AND THE CELLULAR POPULATION OF SEVERAL HUNDRED OR THOUSANDS OF MITOCHONDRIA THAT ARE GENETICALLY HETEROGENEOUS. HIGH INTRA-MITOCHONDRIAL ROS LEVEL IS DAMAGING THE MITOCHONDRIAL (MT) DNA AND ITS MUTATIONS AFFECT THE EPIGENETIC CONTROL MECHANISMS OF THE NUCLEAR (N) DNA, BY DECREASING THE ACTIVITY OF METHYLTRANSFERASES AND THUS, CAUSING GLOBAL DNA HYPOMETHYLATION. THESE CHANGES ARE TRANSMITTED TO THE PROGENY OF THE IRRADIATED CELLS. THE CHRONIC OXIDATIVE STRESS IS THE MAIN CAUSE OF THE LATE POST-RADIATION EFFECTS, INCLUDING CANCER, AND THIS MAKES IT AN IMPORTANT ADVERSE EFFECT OF EXPOSURE TO IR AND A TARGET FOR RADIOLOGICAL PROTECTION. 2015