1   872 132 CHRONIC ALCOHOL EXPOSURE DIFFERENTIALLY ALTERS ONE-CARBON METABOLISM IN RAT LIVER AND BRAIN. BACKGROUND: EPIGENETIC MECHANISMS SUCH AS DNA METHYLATION PLAY AN IMPORTANT ROLE IN REGULATING THE PATHOPHYSIOLOGY OF ALCOHOLISM. CHRONIC ALCOHOL EXPOSURE LEADS TO BEHAVIORAL CHANGES AS WELL AS DECREASED EXPRESSION OF GENES ASSOCIATED WITH SYNAPTIC PLASTICITY. IN THE LIVER, IT HAS BEEN DOCUMENTED THAT CHRONIC ALCOHOL EXPOSURE IMPAIRS METHIONINE SYNTHASE (MS) ACTIVITY LEADING TO A DECREASE IN S-ADENOSYL METHIONINE/S-ADENOSYL HOMOCYSTEINE (SAM/SAH) RATIO WHICH RESULTS IN DNA HYPOMETHYLATION; HOWEVER, IT IS NOT KNOWN WHETHER SIMILAR ALTERATIONS OF SAM AND SAH LEVELS ARE ALSO PRODUCED IN BRAIN. METHODS: MALE ADULT SPRAGUE DAWLEY RATS WERE FED CHRONICALLY WITH LIEBER-DECARLI ETHANOL (ETOH) (9% V/V) OR CONTROL DIET. THE ETOH-DIET-FED RATS WERE WITHDRAWN FOR 0 AND 24 HOURS. THE CEREBELLUM AND LIVER TISSUES WERE DISSECTED AND USED TO INVESTIGATE CHANGES IN ONE-CARBON METABOLISM, SAM, AND SAH LEVELS. RESULTS: WE FOUND THAT CHRONIC ETOH EXPOSURE DECREASED SAM LEVELS, SAM/SAH RATIO, MS, METHYLENE TETRAHYDROFOLATE REDUCTASE, AND BETAINE HOMOCYSTEINE METHYLTRANSFERASE (BHMT) EXPRESSION AND INCREASED METHIONINE ADENOSYLTRANSFERASE-2B (MAT2B) BUT NOT MAT2A EXPRESSION IN THE LIVER. IN CONTRAST, CHRONIC ETOH EXPOSURE DECREASED SAH LEVELS, INCREASED SAM/SAH RATIO AND THE EXPRESSION OF MAT2A AND S-ADENOSYL HOMOCYSTEINE HYDROLASE, WHILE THE LEVELS OF SAM OR BHMT EXPRESSION IN CEREBELLUM REMAINED UNALTERED. HOWEVER, IN BOTH LIVER AND CEREBELLUM, CHRONIC ETOH EXPOSURE DECREASED THE EXPRESSION OF MS AND INCREASED MAT2B EXPRESSION. ALL CHRONIC ETOH-INDUCED CHANGES OF ONE-CARBON METABOLISM IN CEREBELLUM, BUT NOT LIVER, RETURNED TO NEAR-NORMAL LEVELS DURING ETOH WITHDRAWAL. CONCLUSIONS: THESE RESULTS INDICATE A DECREASED "METHYLATION INDEX" IN LIVER AND AN INCREASED "METHYLATION INDEX" IN CEREBELLUM. THE OPPOSING CHANGES OF THE "METHYLATION INDEX" SUGGEST ALTERED DNA METHYLATION IN LIVER AND CEREBELLUM, THUS IMPLICATING ONE-CARBON METABOLISM IN THE PATHOPHYSIOLOGY OF ALCOHOLISM.	2017	
                                                                                                                                                                                                                                                                                                                                                                                        
2  1781  34 EFFECT OF 1 YEAR B AND D VITAMIN SUPPLEMENTATION ON LINE-1 REPETITIVE ELEMENT METHYLATION IN OLDER SUBJECTS. BACKGROUND: DISTURBED DNA METHYLATION IS CAUSALLY RELATED TO CHRONIC DISEASES LIKE CANCER AND ATHEROSCLEROSIS. B VITAMINS ARE COFACTORS REQUIRED FOR METHYL GROUP SYNTHESIS AND MAY THEREFORE AFFECT DNA METHYLATION. VITAMIN D HAS EPIGENETIC EFFECTS. WE TESTED IF B AND D VITAMIN SUPPLEMENTATION HAS AN EFFECT ON GENOMIC LONG INTERSPERSED NUCLEAR ELEMENT-1 (LINE-1) METHYLATION AND THE METABOLITES S-ADENOSYLMETHIONINE (SAM) AND S-ADENOSYLHOMOCYSTEINE (SAH). METHODS: FIFTY SUBJECTS (MEDIAN AGE 68.0 YEARS) WERE SUPPLEMENTED WITH A DAILY ORAL DOSE OF B VITAMINS (500 MICROG FOLIC ACID, 500 MICROG VITAMIN B12 AND 50 MG VITAMIN B6), 1200 IU VITAMIN D AND 456 MG CALCIUM. FASTING BLOOD SAMPLES WERE COLLECTED BEFORE AND AFTER 1 YEAR OF SUPPLEMENTATION. LINE-1 METHYLATION WAS DETERMINED IN GENOMIC DNA FROM BLOOD CELLS AS A SURROGATE FOR WHOLE GENOME METHYLATION. IN ADDITION, SAM, SAH AND TOTAL HOMOCYSTEINE (THCY) WERE MEASURED IN PLASMA SAMPLES. RESULTS: PLASMA HOMOCYSTEINE DECREASED SIGNIFICANTLY AFTER SUPPLEMENTATION (12.8 VS. 9.1 MICROMOL/L; P<0.05), WHEREAS SAM, SAH, THE SAM/SAH RATIO AND LINE-1 METHYLATION DID NOT CHANGE SIGNIFICANTLY. LINE-1 METHYLATION WAS NOT SIGNIFICANTLY CORRELATED WITH SAH, HOMOCYSTEINE OR B VITAMINS. CONCLUSIONS: LONG-TERM VITAMIN B SUPPLEMENTATION HAD NO EFFECT ON LINE-1 METHYLATION IN BLOOD CELLS NOR ON PLASMA LEVELS OF SAM AND SAH. VITAMIN B AND D SUPPLEMENTATION SEEMS TO HAVE NO EFFECT ON DNA METHYLATION, ESPECIALLY IN CASES WHERE NO SEVERE DEFICIENCY EXISTS.	2013	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                               
3  6220  31 THE KIDNEY IS THE MAJOR SITE OF S-ADENOSYLHOMOCYSTEINE DISPOSAL IN HUMANS. S-ADENOSYLHOMOCYSTEINE (SAH), THE METABOLIC PRECURSOR OF HOMOCYSTEINE IN THE BODY, IS A POTENT INHIBITOR OF METHYLATION REACTIONS. SEVERAL METHYLATION REACTIONS PLAY A MAJOR ROLE IN EPIGENETIC REGULATION OF PROTEIN EXPRESSION, ATHEROSCLEROSIS, AND CANCER DEVELOPMENT. HERE WE STUDIED THE MECHANISMS RESPONSIBLE FOR THE MAINTENANCE OF CIRCULATING SAH LEVELS BY MEASUREMENT OF THE ARTERIO-VENOUS DIFFERENCES ACROSS THE KIDNEY, SPLANCHNIC ORGANS, AND THE LUNG IN HUMANS. THE LUNGS DID NOT REMOVE OR ADD ANY CIRCULATING SAH, WHEREAS THE LIVER RELEASED IT INTO THE HEPATIC VEINS. THE KIDNEY EXTRACTED 40% OF SAH AND THE SAH ARTERIO-VENOUS DIFFERENCE ACROSS THE KIDNEY WAS DIRECTLY AND SIGNIFICANTLY RELATED TO ITS ARTERIAL LEVELS. THUS, THE KIDNEY PLAYS A MAJOR ROLE IN MAINTAINING SAH LEVELS AND MAY, INDIRECTLY, CONTROL TISSUE TRANSMETHYLATION REACTIONS. OUR FINDINGS OF A PIVOTAL ROLE FOR THE HUMAN KIDNEY IN SULFUR AMINO ACID METABOLISM MAY ALSO ACCOUNT FOR THE INCREASED PLASMA LEVELS OF SAH IN PATIENTS WITH CHRONIC KIDNEY DISEASES.	2009	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                    
4  5587  39 ROLE OF S-ADENOSYLHOMOCYSTEINE IN CARDIOVASCULAR DISEASE AND ITS POTENTIAL EPIGENETIC MECHANISM. TRANSMETHYLATION REACTIONS UTILIZE S-ADENOSYLMETHIONINE (SAM) AS A METHYL DONOR AND ARE CENTRAL TO THE REGULATION OF MANY BIOLOGICAL PROCESSES: MORE THAN FIFTY SAM-DEPENDENT METHYLTRANSFERASES METHYLATE A BROAD SPECTRUM OF CELLULAR COMPOUNDS INCLUDING DNA, HISTONES, PHOSPHOLIPIDS AND OTHER SMALL MOLECULES. COMMON TO ALL SAM-DEPENDENT TRANSMETHYLATION REACTIONS IS THE RELEASE OF THE POTENT INHIBITOR S-ADENOSYLHOMOCYSTEINE (SAH) AS A BY-PRODUCT. SAH IS REVERSIBLY HYDROLYZED TO ADENOSINE AND HOMOCYSTEINE BY SAH HYDROLASE. HYPERHOMOCYSTEINEMIA IS AN INDEPENDENT RISK FACTOR FOR CARDIOVASCULAR DISEASE. HOWEVER, A MAJOR UNANSWERED QUESTION IS IF HOMOCYSTEINE IS CAUSALLY INVOLVED IN DISEASE PATHOGENESIS OR SIMPLY A PASSIVE AND INDIRECT INDICATOR OF A MORE COMPLEX MECHANISM. A CHRONIC ELEVATION IN HOMOCYSTEINE LEVELS RESULTS IN A PARALLEL INCREASE IN INTRACELLULAR OR PLASMA SAH, WHICH IS A MORE SENSITIVE BIOMARKER OF CARDIOVASCULAR DISEASE THAN HOMOCYSTEINE AND SUGGESTS THAT SAH IS A CRITICAL PATHOLOGICAL FACTOR IN HOMOCYSTEINE-ASSOCIATED DISORDERS. PREVIOUS REPORTS INDICATE THAT SUPPLEMENTATION WITH FOLATE AND B VITAMINS EFFICIENTLY LOWERS HOMOCYSTEINE LEVELS BUT NOT PLASMA SAH LEVELS, WHICH POSSIBLY EXPLAINS THE FAILURE OF HOMOCYSTEINE-LOWERING VITAMINS TO REDUCE VASCULAR EVENTS IN SEVERAL RECENT CLINICAL INTERVENTION STUDIES. FURTHERMORE, MORE STUDIES ARE FOCUSING ON THE ROLE AND MECHANISMS OF SAH IN DIFFERENT CHRONIC DISEASES RELATED TO HYPERHOMOCYSTEINEMIA, SUCH AS CARDIOVASCULAR DISEASE, KIDNEY DISEASE, DIABETES, AND OBESITY. THIS REVIEW SUMMARIZES THE CURRENT ROLE OF SAH IN CARDIOVASCULAR DISEASE AND ITS EFFECT ON SEVERAL RELATED RISK FACTORS. IT ALSO EXPLORES POSSIBLE THE MECHANISMS, SUCH AS EPIGENETICS AND OXIDATIVE STRESS, OF SAH. THIS ARTICLE IS PART OF A DIRECTED ISSUE ENTITLED: EPIGENETIC DYNAMICS IN DEVELOPMENT AND DISEASE.	2015	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                   
5  1855  36 ELEVATION IN S-ADENOSYLHOMOCYSTEINE AND DNA HYPOMETHYLATION: POTENTIAL EPIGENETIC MECHANISM FOR HOMOCYSTEINE-RELATED PATHOLOGY. CHRONIC NUTRITIONAL DEFICIENCIES IN FOLATE, CHOLINE, METHIONINE, VITAMIN B-6 AND/OR VITAMIN B-12 CAN PERTURB THE COMPLEX REGULATORY NETWORK THAT MAINTAINS NORMAL ONE-CARBON METABOLISM AND HOMOCYSTEINE HOMEOSTASIS. GENETIC POLYMORPHISMS IN THESE PATHWAYS CAN ACT SYNERGISTICALLY WITH NUTRITIONAL DEFICIENCIES TO ACCELERATE METABOLIC PATHOLOGY ASSOCIATED WITH OCCLUSIVE HEART DISEASE, BIRTH DEFECTS AND DEMENTIA. A MAJOR UNANSWERED QUESTION IS WHETHER HOMOCYSTEINE IS CAUSALLY INVOLVED IN DISEASE PATHOGENESIS OR WHETHER HOMOCYSTEINEMIA IS SIMPLY A PASSIVE AND INDIRECT INDICATOR OF A MORE COMPLEX MECHANISM. S-ADENOSYLMETHIONINE AND S-ADENOSYLHOMOCYSTEINE (SAH), AS THE SUBSTRATE AND PRODUCT OF METHYLTRANSFERASE REACTIONS, ARE IMPORTANT METABOLIC INDICATORS OF CELLULAR METHYLATION STATUS. CHRONIC ELEVATION IN HOMOCYSTEINE LEVELS RESULTS IN PARALLEL INCREASES IN INTRACELLULAR SAH AND POTENT PRODUCT INHIBITION OF DNA METHYLTRANSFERASES. SAH-MEDIATED DNA HYPOMETHYLATION AND ASSOCIATED ALTERATIONS IN GENE EXPRESSION AND CHROMATIN STRUCTURE MAY PROVIDE NEW HYPOTHESES FOR PATHOGENESIS OF DISEASES RELATED TO HOMOCYSTEINEMIA.	2002	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                   
6  2120  45 EPIGENETIC HISTONE MODIFICATIONS IN A CLINICALLY RELEVANT RAT MODEL OF CHRONIC ETHANOL-BINGE-MEDIATED LIVER INJURY. PURPOSE: ETHANOL BINGE AUGMENTS LIVER INJURY AFTER CHRONIC ETHANOL CONSUMPTION IN HUMANS, BUT THE MECHANISM BEHIND THE ENHANCED LIVER INJURY BY ETHANOL BINGE IS NOT KNOWN. IN THIS STUDY WE USED A CLINICALLY RELEVANT RAT MODEL IN WHICH LIVER INJURY IS AMPLIFIED BY BINGE AFTER CHRONIC ETHANOL TREATMENT AND INVESTIGATED THE IMPORTANCE OF HISTONE MODIFICATIONS. METHODS: EIGHT-WEEK-OLD SPRAGUE-DAWLEY RATS WERE FED ETHANOL IN A LIQUID DIET FOR 4 WEEKS. CONTROL RATS WERE FED AN ISOCALORIC LIQUID DIET. THIS WAS FOLLOWED BY THREE BINGE ADMINISTRATIONS OF ETHANOL (INTRAGASTRIC 5 G/KG BODY WEIGHT, 12 H APART). IN THE CONTROL, ETHANOL WAS REPLACED BY WATER. FOUR HOURS AFTER THE LAST BINGE ADMINISTRATION, LIVER SAMPLES WERE ANALYZED FOR HISTONE MODIFICATIONS AND PARAMETERS OF LIVER INJURY. RESULTS: CHRONIC ETHANOL ADMINISTRATION ALONE CAUSED AN INCREASE IN HISTONE H3 SER10 AND SER28 (H3S10 OR S28) PHOSPHORYLATION, AND BINGE ETHANOL REDUCED THEIR LEVELS. LEVELS OF DUALLY MODIFIED PHOSPHOACETYLATED HISTONE H3 (H3ACK9/PS10) INCREASED AFTER ACUTE BINGE ETHANOL AND REMAINED SAME AFTER CHRONIC ETHANOL BINGE. IN CONTRAST, HISTONE H3 LYSINE-9 ACETYLATION (H3ACK9) WAS NOT INCREASED AFTER CHRONIC ETHANOL BUT INCREASED SIGNIFICANTLY AFTER ACUTE BINGE AND CHRONIC ETHANOL BINGE. INCREASE IN HISTONE ACETYLATION WAS ACCOMPANIED BY INCREASED PHOSPHO-ERK1/2 IN THE NUCLEAR EXTRACTS. INCREASED ACETYLATION AFTER CHRONIC ETHANOL BINGE WAS ALSO ACCOMPANIED BY INCREASED PROTEIN LEVELS OF GCN5 HISTONE ACETYL TRANSFERASE AND A MODEST INCREASE IN HDAC3 IN THE NUCLEUS. HISTONE LYSINE-9 DIMETHYLATION WAS SIGNIFICANTLY INCREASED AFTER CHRONIC ETHANOL BINGE. CHRONIC ETHANOL BINGE ALSO RESULTED IN A DECREASE IN THE SAM:SAH RATIO WITH A RELATIVE DECREASE OF SAM LEVELS AND A CORRESPONDING INCREASE IN SAH LEVELS. CONCLUSIONS: ETHANOL BINGE AFTER CHRONIC ETHANOL ALTERED THE PROFILE OF SITE-SPECIFIC HISTONE MODIFICATIONS AND MAY UNDERLIE THE MECHANISM OF AUGMENTED LIVER INJURY BY CHRONIC-ETHANOL-BINGE-TREATED RATS.	2014	
                                                                                                                                                                                                                                                                                                                                                   
7  3619  40 IN VIVO ACUTE ON CHRONIC ETHANOL EFFECTS IN LIVER: A MOUSE MODEL EXHIBITING EXACERBATED INJURY, ALTERED METABOLIC AND EPIGENETIC RESPONSES. CHRONIC ALCOHOLICS WHO ALSO BINGE DRINK (I.E., ACUTE ON CHRONIC) ARE PRONE TO AN EXACERBATED LIVER INJURY BUT ITS MECHANISM IS NOT UNDERSTOOD. WE THEREFORE INVESTIGATED THE IN VIVO EFFECTS OF CHRONIC AND BINGE ETHANOL INGESTION AND COMPARED TO CHRONIC ETHANOL FOLLOWED BY THREE REPEAT BINGE ETHANOL ON THE LIVER OF MALE C57/BL6 MICE FED ETHANOL IN LIQUID DIET (4%) FOR FOUR WEEKS FOLLOWED BY BINGE ETHANOL (INTRAGASTRIC ADMINISTRATION, 3.5 G/KG BODY WEIGHT, THREE DOSES, 12H APART). CHRONIC FOLLOWED BY BINGE ETHANOL EXACERBATED FAT ACCUMULATION, NECROSIS, DECREASE IN HEPATIC SAM AND SAM:SAH RATIO, INCREASE IN ADENOSINE LEVELS, AND ELEVATED CYP2E1 LEVELS. HISTONE H3 LYSINE ACETYLATION (H3ACK9), DUALLY MODIFIED PHOSPHOACETYLATED HISTONE H3 (H3ACK9/PS10), AND PHOSPHORYLATED H2AX INCREASED AFTER BINGE WHEREAS PHOSPHORYLATION OF HISTONE H3 SER 10 (H3S10) AND H3 SER 28 (H3S28) INCREASED AFTER CHRONIC ETHANOL-BINGE. HISTONE H3 LYSINE 4 AND 9 DIMETHYLATION INCREASED WITH A MARKED DIMETHYLATION IN H3K9 IN CHRONIC ETHANOL BINGE GROUP. TRIMETHYLATED HISTONE H3 LEVELS DID NOT CHANGE. NUCLEAR LEVELS OF HISTONE ACETYL TRANSFERASE GCN5 AND HISTONE DEACETYLASE HDAC3 WERE ELEVATED WHEREAS PHOSPHO-CREB DECREASED IN A DISTINCTIVE MANNER. TAKEN TOGETHER, ACUTE ON CHRONIC ETHANOL INGESTION CAUSED AMPLIFICATION OF LIVER INJURY AND ELICITED CHARACTERISTIC PROFILES OF HISTONE MODIFICATIONS, METABOLIC ALTERATIONS, AND CHANGES IN NUCLEAR PROTEIN LEVELS. THESE FINDINGS DEMONSTRATE THAT CHRONIC ETHANOL EXPOSURE RENDERS LIVER MORE SUSCEPTIBLE TO REPEAT ACUTE/BINGE ETHANOL INDUCED ACCELERATION OF ALCOHOLIC LIVER DISEASE.	2015	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                               
8   558  36 B-VITAMIN DEPENDENT METHIONINE METABOLISM AND ALCOHOLIC LIVER DISEASE. CONVINCING EVIDENCE LINKS ABERRANT B-VITAMIN DEPENDENT HEPATIC METHIONINE METABOLISM TO THE PATHOGENESIS OF ALCOHOLIC LIVER DISEASE (ALD). THIS REVIEW FOCUSES ON THE ESSENTIAL ROLES OF FOLATE AND VITAMINS B6 AND B12 IN HEPATIC METHIONINE METABOLISM, THE CAUSES OF THEIR DEFICIENCIES AMONG CHRONIC ALCOHOLIC PERSONS, AND HOW THEIR DEFICIENCIES TOGETHER WITH CHRONIC ALCOHOL EXPOSURE IMPACT ON ABERRANT METHIONINE METABOLISM IN THE PATHOGENESIS OF ALD. FOLATE IS THE DIETARY TRANSMETHYLATION DONOR FOR THE PRODUCTION OF S-ADENOSYLMETHIONINE (SAM), WHICH IS THE SUBSTRATE FOR ALL METHYLTRANSFERASES THAT REGULATE GENE EXPRESSIONS IN PATHWAYS OF LIVER INJURY, AS WELL AS A REGULATOR OF THE TRANSSULFURATION PATHWAY THAT IS ESSENTIAL FOR PRODUCTION OF GLUTATHIONE (GSH), THE PRINCIPAL ANTIOXIDANT FOR DEFENSE AGAINST OXIDATIVE LIVER INJURY. VITAMIN B12 REGULATES TRANSMETHYLATION REACTIONS FOR SAM PRODUCTION AND VITAMIN B6 REGULATES TRANSSULFURATION REACTIONS FOR GSH PRODUCTION. FOLATE DEFICIENCY ACCELERATES THE EXPERIMENTAL DEVELOPMENT OF ALD IN ETHANOL-FED ANIMALS WHILE REDUCING LIVER SAM LEVELS WITH RESULTANT ABNORMAL GENE EXPRESSION AND DECREASED PRODUCTION OF ANTIOXIDANT GSH. THROUGH ITS EFFECTS ON FOLATE METABOLISM, REDUCED SAM ALSO IMPAIRS NUCLEOTIDE BALANCE WITH RESULTANT INCREASED DNA STRAND BREAKS, OXIDATION, HEPATOCELLULAR APOPTOSIS, AND RISK OF CARCINOGENESIS. THE REVIEW ENCOMPASSES REFERENCED STUDIES ON MECHANISMS FOR PERTURBATIONS OF METHIONINE METABOLISM IN ALD, EVIDENCE FOR ALTERED GENE EXPRESSIONS AND THEIR EPIGENETIC REGULATION IN THE PATHOGENESIS OF ALD, AND CLINICAL STUDIES ON POTENTIAL PREVENTION AND TREATMENT OF ALD BY CORRECTION OF METHIONINE METABOLISM WITH SAM.	2013	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                 
9  2907  42 GENE EXPRESSION MODIFICATIONS IN THE LIVER CAUSED BY BINGE DRINKING AND S-ADENOSYLMETHIONINE FEEDING. THE ROLE OF EPIGENETIC CHANGES. CHRONIC ETHANOL INGESTION, ACHIEVED BY FEEDING ETHANOL AT A CONSTANT RATE USING INTRAGASTRIC TUBE FEEDING, ALTERS THE EXPRESSION OF GENES IN THE LIVER. THIS IS DONE BY EPIGENETIC MECHANISMS, WHICH DEPEND ON THE BLOOD ALCOHOL LEVELS AT THE TIME OF KILLING. HOWEVER, ACUTE BOLUS FEEDING OF ETHANOL CHANGES GENE EXPRESSION WITHOUT LASTING EPIGENETIC CHANGES. THIS OCCURS WITH HISTONE 3 METHYLATION AND ACETYLATION MODIFICATIONS. THE GENE EXPRESSION RESPONSE TO AN ACUTE BOLUS OF ETHANOL MIGHT BE MODIFIED BY FEEDING S-ADENOSYLMETHIONINE (SAME), A METHYL DONOR. IN THE PRESENT STUDY, RATS WERE GIVEN A BOLUS OF ETHANOL (6 G/KG BODY WEIGHT (BW), SAME (1 G/KG BW), ETHANOL + SAME, OR ISOCALORIC GLUCOSE. THE GROUP OF RATS (N = 3) WERE KILLED AT 3 AND 12 H POST BOLUS, AND GENE MICROARRAY ANALYSIS WAS PERFORMED ON THEIR LIVER CELLS. SAME REDUCED THE 3 H BLOOD ETHANOL LEVELS AND INCREASED THE ALT LEVELS AT 3 H. VENN DIAGRAMS SHOWED THAT ALCOHOL CHANGED THE EXPRESSION OF 646 GENES AT 3 H POST BOLUS AND 586 GENES AT 12 H. SAME CHANGED THE EXPRESSION OF 1,012 GENES WHEN FED WITH ETHANOL 3 H POST ETHANOL BOLUS AND 554 GENES AT 12 H POST ETHANOL BOLUS. SAME ALONE CHANGED THE EXPRESSION OF 1,751 GENES AT 3 H AND 1,398 AT 12 H. THERE WERE MORE CHANGES IN GENE EXPRESSION AT 3 H THAN AT 12 H POST ETHANOL WHEN ETHANOL ALONE WAS COMPARED TO THE DEXTROSE CONTROL. THE SAME WAS TRUE WHEN SAME WAS COMPARED TO SAME + ETHANOL. ETHANOL UP REGULATED GENE EXPRESSION IN MOST FUNCTIONAL PATHWAYS AT 3 H. HOWEVER, WHEN SAME WAS FED WITH ETHANOL AT 3 H, MOST PATHWAYS WERE DOWN REGULATED. AT 12 H, HOWEVER, WHEN ETHANOL WAS FED, THE PATHWAYS WERE HALF UP REGULATED AND HALF DOWN REGULATED. THE SAME WAS TRUE WHEN SAME + ETHANOL WAS FED. THE EXPRESSION OF EPIGENETICALLY IMPORTANT GENES, SUCH AS BHMT AND FOXN3, WAS UP REGULATED 3 H POST ALCOHOL BOLUS. AT 3 H, SAME DOWN REGULATED THE EXPRESSION OF GENES, SUCH AS BHMT, MAT2A, JUN, TNFRS9, AHCY 1, TGFBR1 AND 2, AND PCAF. AT 12 H, THE INSULIN SIGNALING PATHWAYS WERE HALF DOWN REGULATED BY ETHANOL, WHICH WAS PARTLY PREVENTED BY SAME. THE MAPK PATHWAY WAS UP REGULATED BY ETHANOL, BUT SAME DID NOT PREVENT THIS. IN CONCLUSION, PROFOUND CHANGES IN GENE EXPRESSION EVOLVED BETWEEN 3 H AND 12 POST ETHANOL BOLUS. SAME DOWN REGULATED THESE CHANGES IN GENE EXPRESSION AT 3 H, AND LESS SO AT 12 H.	2010	

10  2008  36 EPIGENETIC BASIS FOR MONOCYTE DYSFUNCTION IN PATIENTS WITH SEVERE ALCOHOLIC HEPATITIS. BACKGROUND & AIMS: SEVERE FORMS OF ALCOHOL-RELATED LIVER DISEASE ARE ASSOCIATED WITH INCREASED SUSCEPTIBILITY TO INFECTIONS WHICH ARE ASSOCIATED WITH POOR PROGNOSIS. THE CELLULAR AND MOLECULAR MECHANISMS RESPONSIBLE FOR THIS ALTERED HOST DEFENSE ARE INCOMPLETELY UNDERSTOOD. METHODS: WE PERFORMED WHOLE BLOOD PHENOTYPIC ANALYSIS AND EX VIVO STIMULATION WITH VARIOUS PATHOGEN-ASSOCIATED MOLECULAR PATTERNS (PAMPS). WE INCLUDED 34 PATIENTS WITH ALCOHOL-RELATED CIRRHOSIS (18 OF WHOM HAD BIOPSY-PROVEN SEVERE ALCOHOLIC HEPATITIS [SAH]), 12 HEALTHY CONTROLS AND 11 PATIENTS WITH CHRONIC ALCOHOL CONSUMPTION WITHOUT SIGNIFICANT LIVER DISEASE. WE ALSO EVALUATED THE TRANSCRIPTOMIC (RNA-SEQ) AND CHROMATIN ACCESSIBILITY (ATAC-SEQ) PROFILES OF CD14(+) MONOCYTES FROM A SUBSET OF PATIENTS. RESULTS: CIRCULATING MONOCYTES AND CONVENTIONAL DENDRITIC CELLS (DCS) FROM PATIENTS WITH SAH DISPLAYED COMPLEX ALTERATIONS CHARACTERIZED BY INCREASED EXPRESSION OF BOTH ACTIVATING AND INHIBITORY SURFACE MARKERS AND AN IMPAIRED PRO-INFLAMMATORY RESPONSE UPON STIMULATION WITH PAMPS REPRESENTATIVE OF GRAM-NEGATIVE BACTERIA (LIPOPOLYSACCHARIDE, PAM3CSK4) OR FUNGAL PATHOGENS (ZYMOSAN). THEIR DECREASED ABILITY TO PRODUCE MORE THAN 1 CYTOKINE (POLYFUNCTIONALITY) UPON PAMP STIMULATION CORRELATED WITH THE RISK OF DEVELOPING INFECTION AT 28 DAYS OR MORTALITY AT 90 DAYS. THE PRESENCE OF ACUTE-ON-CHRONIC LIVER FAILURE IN PATIENTS WITH SAH DID NOT SIGNIFICANTLY MODIFY THE IMMUNE PROFILE OF MONOCYTES AND DCS. MOREOVER, CD14(+) MONOCYTES OF PATIENTS WITH SAH DISPLAYED ALTERED TRANSCRIPTIONAL AND EPIGENOMIC PROFILES CHARACTERIZED BY DOWNREGULATION OF KEY INNATE IMMUNE AND METABOLIC PATHWAYS AND UPREGULATION OF IMPORTANT IMMUNOMODULATORY FACTORS. CONCLUSIONS: IN PATIENTS WITH SAH, THE ALTERED TRANSCRIPTIONAL PROGRAM AND FUNCTIONAL PROPERTIES OF MONOCYTES THAT CONTRIBUTE TO PATIENTS' SUSCEPTIBILITY TO INFECTION HAVE STRONG EPIGENETIC DETERMINANTS. LAY SUMMARY: PATIENTS WITH SEVERE ALCOHOLIC HEPATITIS ARE AT INCREASED RISK OF INFECTIONS, WHICH CONTRIBUTE TO THE POOR PROGNOSIS ASSOCIATED WITH THE DISEASE. HEREIN, WE SHOW THAT EPIGENETIC DETERMINANTS UNDERLY THE IMMUNE CELL DYSFUNCTION AND INAPPROPRIATE RESPONSES TO PATHOGENS THAT ARE ASSOCIATED WITH SEVERE ALCOHOLIC HEPATITIS.	2020	
                                                                                                          
11  3841  43 IRON SUPPLEMENTATION REVERSES THE REDUCTION OF HYDROXYMETHYLCYTOSINE IN HEPATIC DNA ASSOCIATED WITH CHRONIC ALCOHOL CONSUMPTION IN RATS. BACKGROUND: ALCOHOL IS KNOWN TO AFFECT TWO EPIGENETIC PHENOMENA, DNA METHYLATION AND DNA HYDROXYMETHYLATION, AND IRON IS A COFACTOR OF TEN-ELEVEN TRANSLOCATION (TET) ENZYMES THAT CATALYZE THE CONVERSION FROM METHYLCYTOSINE TO HYDROXYMETHYLCYTOSINE. IN THE PRESENT STUDY WE AIMED TO DETERMINE THE EFFECTS OF ALCOHOL ON DNA HYDROXYMETHYLATION AND FURTHER EFFECTS OF IRON ON ALCOHOL ASSOCIATED EPIGENETIC CHANGES. METHODS: TWENTY-FOUR MALE SPRAGUE-DAWLEY RATS WERE FED EITHER LIEBER-DECARLI ALCOHOL DIET (36% CALORIES FROM ETHANOL) OR LIEBER-DECARLI CONTROL DIET ALONG WITH OR WITHOUT IRON SUPPLEMENTATION (0.6% CARBONYL IRON) FOR 8 WEEKS. HEPATIC NON-HEME IRON CONCENTRATIONS WERE MEASURED BY COLORIMETRIC ASSAYS. PROTEIN LEVELS OF HEPATIC FERRITIN AND TRANSFERRIN RECEPTOR WERE DETERMINED BY WESTERN BLOTTING. METHYLCYTOSINE, HYDROXYMETHYLCYTOSINE AND UNMODIFIED CYTOSINE IN DNA WERE SIMULTANEOUSLY MEASURED BY LIQUID CHROMATOGRAPHY/MASS SPECTROMETRY METHOD. RESULTS: IRON SUPPLEMENTATION SIGNIFICANTLY INCREASED HEPATIC NON-HEME IRON CONTENTS (P < 0.05) BUT ALCOHOL ALONE DID NOT. HOWEVER, BOTH ALCOHOL AND IRON SIGNIFICANTLY INCREASED HEPATIC FERRITIN LEVELS AND DECREASED HEPATIC TRANSFERRIN RECEPTOR LEVELS (P < 0.05). ALCOHOL REDUCED HEPATIC DNA HYDROXYMETHYLATION (0.21% +/- 0.04% VS. 0.33% +/- 0.04%, P = 0.01) COMPARED TO CONTROL, WHILE IRON SUPPLEMENTATION TO ALCOHOL DIET DID NOT CHANGE DNA HYDROXYMETHYLATION. THERE WAS NO SIGNIFICANT DIFFERENCE IN METHYLCYTOSINE LEVELS, WHILE UNMODIFIED CYTOSINE LEVELS WERE SIGNIFICANTLY INCREASED IN ALCOHOL-FED GROUPS COMPARED TO CONTROL (95.61% +/- 0.08% VS. 95.26% +/- 0.12%, P = 0.03), SUGGESTING THAT ALCOHOL FURTHER INCREASES THE CONVERSION FROM HYDROXYMETHYLCYTOSINE TO UNMODIFIED CYTOSINE. CONCLUSIONS: CHRONIC ALCOHOL CONSUMPTION ALTERS GLOBAL DNA HYDROXYMETHYLATION IN THE LIVER BUT IRON SUPPLEMENTATION REVERSES THE EPIGENETIC EFFECT OF ALCOHOL.	2016	
                                                                                                                                                                                                                                                                                                                                                                                                                               
12  5609  41 S-ADENOSYLMETHIONINE DECREASES THE PEAK BLOOD ALCOHOL LEVELS 3 H AFTER AN ACUTE BOLUS OF ETHANOL BY INDUCING ALCOHOL METABOLIZING ENZYMES IN THE LIVER. INTRODUCTION: AN ALCOHOL BOLUS CAUSES THE BLOOD ALCOHOL LEVEL (BAL) TO PEAK AT 1-2 H POST INGESTION. THE ETHANOL ELIMINATION RATE IS REGULATED BY ALCOHOL METABOLIZING ENZYMES, PRIMARILY ALCOHOL DEHYDROGENASE (ADH1), ACETALDEHYDE DEHYDROGENASE (ALDH), AND CYTOCHROME P450 (CYP2E1). RECENTLY, S-ADENOSYLMETHIONINE (SAME) WAS FOUND TO REDUCE ACUTE BALS 3 H AFTER AN ALCOHOL BOLUS. THE QUESTION, THEN, WAS: WHAT IS THE MECHANISM INVOLVED IN THIS REDUCTION OF BAL BY FEEDING SAME? TO ANSWER THIS QUESTION, WE INVESTIGATED THE CHANGES IN ETHANOL METABOLIZING ENZYMES AND THE EPIGENETIC CHANGES THAT REGULATE THE EXPRESSION OF THESE ENZYMES DURING ACUTE BINGE DRINKING AND CHRONIC DRINKING. METHODS: RATS WERE FED A BOLUS OF ETHANOL WITH OR WITHOUT SAME, AND WERE SACRIFICED AT 3 H OR 12 H AFTER THE BOLUS. RESULTS: RT-PCR AND WESTERN BLOT ANALYSES SHOWED THAT SAME SIGNIFICANTLY INDUCED ADH1 LEVELS IN THE 3 H LIVER SAMPLES. HOWEVER, SAME DID NOT AFFECT THE CHANGES IN ADH1 PROTEIN LEVELS 12 H POST BOLUS. SINCE SAME IS A METHYL DONOR, IT WAS POSTULATED THAT THE ADH1 GENE EXPRESSION UP REGULATION AT 3 H WAS DUE TO A HISTONE MODIFICATION INDUCED BY METHYLATION FROM METHYL TRANSFERASES. DIMETHYLATED HISTONE 3 LYSINE 4 (H3K4ME2), A MODIFICATION RESPONSIBLE FOR GENE EXPRESSION ACTIVATION, WAS FOUND TO BE SIGNIFICANTLY INCREASED BY SAME AT 3 H POST BOLUS. CONCLUSION: THESE RESULTS CORRELATED WITH THE LOW BAL FOUND AT 3 H POST BOLUS, AND SUPPORT THE CONCEPT THAT SAME INCREASED THE GENE EXPRESSION TO INCREASE THE ELIMINATION RATE OF ETHANOL IN BINGE DRINKING BY INCREASING H3K4ME2.	2010	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                     
13  3387  24 HOMOCYSTEINE ASSOCIATED GENOMIC DNA HYPERMETHYLATION IN PATIENTS WITH CHRONIC ALCOHOLISM. HIGHER PLASMA HOMOCYSTEINE CONCENTRATIONS CAN INFLUENCE GENOMIC DNA METHYLATION IN PERIPHERAL BLOOD CELLS. IN THE PRESENT CONTROLLED STUDY WE OBSERVED A SIGNIFICANT INCREASE (10%) OF GENOMIC DNA METHYLATION IN PATIENTS WITH ALCOHOLISM (T = -3.16, DF = 158, P = 0.002) WHICH WAS SIGNIFICANTLY ASSOCIATED WITH THEIR ELEVATED HOMOCYSTEINE LEVELS (MULTIPLE LINEAR REGRESSION, P < 0.001). SINCE METHYLATION OF DNA IS AN IMPORTANT EPIGENETIC FACTOR IN REGULATION OF GENE EXPRESSION THESE FINDINGS MAY HAVE IMPORTANT IMPLICATIONS FOR A POSSIBLE SUBSEQUENT DERANGEMENT OF EPIGENETIC CONTROL THESE PATIENTS.	2004	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                       
14  1356  28 DEVELOPMENT OF A DIETARY METHYL DONOR FOOD FREQUENCY QUESTIONNAIRE TO ASSESS FOLATE AND VITAMIN B(12) STATUS IN CHILDREN WITH CHRONIC HEPATITIS B VIRUS INFECTION. OBJECTIVE: TO DEVELOP A DIETARY METHYL DONOR FOOD FREQUENCY QUESTIONNAIRE (DMD-FFQ) THAT IS VALIDATED IN A COHORT OF US CHILDREN AND TO DETERMINE WHETHER THE CONSUMPTION OF FOLATE AND VITAMIN B(12), PRINCIPAL DMDS, CORRELATES WITH HBV DNA LEVELS AND ITS METHYLATION DENSITY. STUDY DESIGN: WE DEVELOPED A SEMIQUANTITATIVE DMD-FFQ TO ESTIMATE INTAKE OF FOLATE AND VITAMIN B(12) AND VALIDATED THIS INSTRUMENT AGAINST A 24-HOUR DIETARY RECALL AND BIOMARKERS-RED BLOOD CELL FOLATE, SERUM VITAMIN B(12), AND HOMOCYSTEINE-IN 35 CHILDREN WITH CHRONIC HBV INFECTION WITHOUT OTHER MEDICAL COMORBIDITIES. ESTIMATES OF DMD, AS WELL AS THE SERUM BIOMARKERS, WERE CORRELATED WITH THE METHYLATION DENSITY OF HBV CPG ISLAND 2 AND HBV DNA LEVELS. RESULTS: FOLATE PER KILOGRAM OF BODY WEIGHT BY THE DMD-FFQ CORRELATED POSITIVELY WITH 24-HOUR RECALL (R = 0.60; P < .001) AND RED BLOOD CELL FOLATE (R = 0.40; P = .02), AND NEGATIVELY WITH HOMOCYSTEINE (R = -0.54; P < .001). VITAMIN B(12) PER KILOGRAM BY DMD-FFQ ALSO CORRELATED POSITIVELY WITH 24-HOUR RECALL (R = 0.57; P < .001) AND SERUM VITAMIN B(12) (R = 0.36, P = .04), AND NEGATIVELY WITH HOMOCYSTEINE (R = -0.44; P = .008). NEITHER DMD INTAKE (FROM DMD-FFQ OR 24-HOUR RECALL) NOR SERUM BIOMARKERS CORRELATED WITH HBV DNA LEVELS OR ITS METHYLATION DENSITY. CONCLUSIONS: OUR DMD-FFQ CORRELATES WELL WITH A 24-HOUR RECALL AND CIRCULATING BIOMARKERS. ALTHOUGH LITTLE EVIDENCE EXISTED THAT CONSUMPTION OF THESE MICRONUTRIENTS CORRELATED WITH HBV REPLICATION, THIS TOOL COULD PROVE USEFUL FOR INVESTIGATING EPIGENETIC MODIFICATION BY DIET FOR SEVERAL PEDIATRIC DISEASES.	2018	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                  
15   286  43 AGING AND ALCOHOL INTERACT TO ALTER HEPATIC DNA HYDROXYMETHYLATION. BACKGROUND: AGING AND CHRONIC ALCOHOL CONSUMPTION ARE BOTH MODIFIERS OF DNA METHYLATION, BUT IT IS NOT YET KNOWN WHETHER CHRONIC ALCOHOL CONSUMPTION ALSO ALTERS DNA HYDROXYMETHYLATION, A NEWLY DISCOVERED EPIGENETIC MARK PRODUCED BY OXIDATION OF METHYLCYTOSINE. FURTHERMORE, IT HAS NOT BEEN TESTED WHETHER AGING AND ALCOHOL INTERACT TO MODIFY THIS EPIGENETIC PHENOMENON, THEREBY HAVING AN INDEPENDENT EFFECT ON GENE EXPRESSION. METHODS: OLD (18 MONTHS) AND YOUNG (4 MONTHS) MALE C57BL/6 MICE WERE PAIR-FED EITHER A LIEBER-DECARLI LIQUID DIET WITH ALCOHOL (18% OF ENERGY) OR AN ISOCALORIC LIEBER-DECARLI CONTROL DIET FOR 5 WEEKS. GLOBAL DNA HYDROXYMETHYLATION AND DNA METHYLATION WERE ANALYZED FROM HEPATIC DNA USING A NEW LIQUID CHROMATOGRAPHY-TANDEM MASS SPECTROMETRY METHOD. HEPATIC MRNA EXPRESSION OF THE TET ENZYMES WERE MEASURED VIA QUANTITATIVE REAL-TIME POLYMERASE CHAIN REACTION. RESULTS: IN YOUNG MICE, MILD CHRONIC ALCOHOL EXPOSURE SIGNIFICANTLY REDUCED GLOBAL DNA HYDROXYMETHYLATION COMPARED WITH CONTROL MICE (0.22 +/- 0.01 VS. 0.29 +/- 0.06%, P = 0.004). ALCOHOL DID NOT SIGNIFICANTLY ALTER HYDROXYMETHYLCYTOSINE LEVELS IN OLD MICE. OLD MICE FED THE CONTROL DIET SHOWED DECREASED GLOBAL DNA HYDROXYMETHYLATION COMPARED WITH YOUNG MICE FED THE CONTROL DIET (0.24 +/- 0.02 VS. 0.29 +/- 0.06%, P = 0.04). THIS MODEL SUGGESTS AN INTERACTION BETWEEN AGING AND ALCOHOL IN DETERMINING DNA HYDROXYMETHYLATION (PINTERACTION = 0.009). EXPRESSION OF TET2 AND TET3 WAS DECREASED IN THE OLD MICE RELATIVE TO THE YOUNG (P < 0.005). CONCLUSIONS: THE OBSERVATION THAT ALCOHOL ALTERS DNA HYDROXYMETHYLATION INDICATES A NEW EPIGENETIC EFFECT OF ALCOHOL. THIS IS THE FIRST STUDY DEMONSTRATING THE INTERACTIVE EFFECTS OF CHRONIC ALCOHOL CONSUMPTION AND AGING ON DNA HYDROXYMETHYLATION.	2014	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                  
16  6250  40 THE METHYLENETETRAHYDROFOLATE REDUCTASE 677C>T GENE POLYMORPHISM IS NOT ASSOCIATED WITH CHRONIC PLAQUE PSORIASIS. BACKGROUND: METHYLENETETRAHYDROFOLATE REDUCTASE (MTHFR) IS INVOLVED IN THE FORMATION OF METHYL DONORS, WHICH CONTRIBUTE TO DNA METHYLATION. DNA METHYLATION IS AN ESSENTIAL EPIGENETIC FEATURE PLAYING A CRITICAL ROLE IN GENE REGULATION AND CELLULAR DIFFERENTIATION. IN ADDITION, MTHFR ACTIVITY AFFECTS PLASMA HOMOCYSTEINE LEVELS. A FUNCTIONAL POLYMORPHISM IN THE MTHFR GENE (677C>T, RS1801133) LEADING TO REDUCED ENZYME ACTIVITY HAS BEEN ASSOCIATED WITH CHRONIC PLAQUE PSORIASIS IN A CHINESE POPULATION. THIS FINDING, HOWEVER, HAS NOT YET BEEN EITHER CONFIRMED OR REFUTED IN OTHER POPULATIONS. THE PURPOSE OF THE PRESENT STUDY WAS TO INVESTIGATE A HYPOTHESIZED ASSOCIATION BETWEEN THE MTHFR 677C>T POLYMORPHISM AND THE PRESENCE OF CHRONIC PLAQUE PSORIASIS IN A CAUCASIAN POPULATION. METHODS: GENOTYPES FOR THE MTHFR 677C>T POLYMORPHISM WERE DETERMINED IN 310 PATIENTS AND 247 CONTROL SUBJECTS. IN A SUBGROUP OF 33 PATIENTS AND 33 SEX- AND AGE-MATCHED CONTROL SUBJECTS, FASTING PLASMA HOMOCYSTEINE CONCENTRATIONS WERE DETERMINED BY HIGH-PERFORMANCE LIQUID CHROMATOGRAPHY AND IMMUNOLOGICAL ASSAYS WERE USED FOR THE MEASUREMENT OF FOLATE AND VITAMIN B(12). RESULTS: PREVALENCE OF THE HOMOZYGOUS MTHFR 677TT GENOTYPE DID NOT SIGNIFICANTLY DIFFER BETWEEN PATIENTS AND CONTROLS (15.2% VS 11.7%, P = 0.24). MEAN PLASMA HOMOCYSTEINE CONCENTRATIONS WERE SIGNIFICANTLY HIGHER IN PSORIASIS PATIENTS THAN AMONG CONTROL SUBJECTS (13.5 +/- 5.3 MICROMOL/L VS 11.0 +/- 2.2 MICROMOL/L, P = 0.026). NO SIGNIFICANT DIFFERENCES BETWEEN EITHER MEAN PLASMA FOLATE OR VITAMIN B(12) CONCENTRATIONS WERE OBSERVED BETWEEN BOTH GROUPS. CONCLUSION: OUR DATA SUGGEST THAT THE MTHFR 677C>T GENE POLYMORPHISM IS NOT ASSOCIATED WITH CHRONIC PLAQUE PSORIASIS AMONG CAUCASIANS.	2008	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                        
17   894  38 CHRONIC ETHANOL FEEDING ALTERS HEPATOCYTE MEMORY WHICH IS NOT ALTERED BY ACUTE FEEDING. BACKGROUND: GENE EXPRESSION CHANGES IN THE LIVER AFTER ACUTE BINGE DRINKING MAY DIFFER FROM THE CHANGES SEEN IN CHRONIC ETHANOL FEEDING IN THE RAT. THE CHANGES IN GENE EXPRESSION AFTER CHRONIC ETHANOL FEEDING MAY SENSITIZE THE LIVER TO ALCOHOL-INDUCED LIVER DAMAGE, WHICH IS NOT SEEN AFTER ACUTE BINGE DRINKING. METHODS: TO TEST THIS HYPOTHESIS, GENE MICROARRAY ANALYSIS WAS PERFORMED ON THE LIVERS OF RATS (N = 3) FED AN ACUTE BINGE DOSE OF ETHANOL (6 G/KG BODY WT) AND KILLED AT 3 AND 12 HOURS AFTER ETHANOL BY GAVAGE. THE GENE MICROARRAYS WERE COMPARED WITH THOSE MADE ON THE LIVER OF RATS FROM A PREVIOUS STUDY, IN WHICH THE RATS WERE FED ETHANOL BY INTRAGASTRIC TUBE FOR 1 MONTH (36% OF CALORIES DERIVED FROM ETHANOL). RESULTS: MICROARRAY ANALYSIS DATA VARIED BETWEEN THE ACUTE AND CHRONIC MODELS IN SEVERAL IMPORTANT RESPECTS. GROWTH FACTORS INCREASED MAINLY IN THE CHRONIC ALCOHOL FED RAT. CHANGES IN ENZYMES INVOLVED IN OXIDATIVE STRESS WERE NOTED ONLY WITH CHRONIC ETHANOL FEEDING. GENE EXPRESSION OF FAT METABOLISM WAS INCREASED ONLY WITH CHRONIC ETHANOL FEEDING. MOST IMPORTANTLY, EPIGENETIC RELATED ENZYMES AND ACETYLATION AND METHYLATION OF HISTONES CHANGED ONLY AFTER CHRONIC ETHANOL FEEDING. CONCLUSIONS: THE RESULTS SUPPORT THE CONCEPT THAT CHRONIC ETHANOL INGESTION INDUCES ALTERED GENE EXPRESSION AS A RESULT OF CHANGES IN EPIGENETIC MECHANISMS, WHERE ACETYLATION AND METHYLATION OF HISTONES WERE ALTERED.	2009	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                
18   339  37 ALTERATIONS IN HOMOCYSTEINE METABOLISM AMONG ALCOHOL DEPENDENT PATIENTS--CLINICAL, PATHOBIOCHEMICAL AND GENETIC ASPECTS. ADDICTION RESEARCH FOCUSING ON HOMOCYSTEINE METABOLISM AND ITS ASSOCIATION WITH ASPECTS OF ALCOHOL DEPENDENCE HAS REVEALED IMPORTANT FINDINGS. RECENT LITERATURE ON THIS TOPIC HAS BEEN TAKEN INTO ACCOUNT FOR THE REVIEW PROVIDED. METHYLENETETRAHYDROFOLATE REDUCTASE (MTHFR) IS A KEY ENZYME IN THE HOMOCYSTEINE METABOLISM. PLASMA HOMOCYSTEINE LEVELS ARE INFLUENCED BY THE SINGLE-NUCLEOTIDE POLYMORPHISM (SNP) MTHFR C677T. BESIDES GENETIC FACTORS, ENVIRONMENTAL FACTORS HAVE AN IMPACT ON HOMOCYSTEINE PLASMA LEVELS TOO. THUS, CHRONIC ALCOHOL INTAKE IS ASSOCIATED WITH ELEVATED HOMOCYSTEINE PLASMA CONCENTRATIONS. ELEVATION OF PLASMA HOMOCYSTEINE CONCENTRATION IS CONSIDERED AS A PREDICTOR FOR THE OCCURRENCE OF ALCOHOL WITHDRAWAL SEIZURES AND--AS HOMOCYSTEINE IS A CARDIOVASCULAR RISK FACTOR--MIGHT CONTRIBUTE TO THE HIGHER RISK FOR MYOCARDIAL INFARCTION AMONG ALCOHOL DEPENDENT PATIENTS. HOMOCYSTEINE ACTS AS AN N-METHYL-D-ASPARTATE (NMDA) RECEPTOR AGONIST AND HAS EXCITOTOXIC EFFECTS. FURTHERMORE, IT HAS BEEN DEMONSTRATED THAT HOMOCYSTEINE HAS NEUROTOXIC EFFECTS ESPECIALLY ON DOPAMINERGIC NEURONS. AS THE REWARDING EFFECTS OF ALCOHOL ARE MEDIATED BY THE DOPAMINERGIC SYSTEM, A HOMOCYSTEINE-DEPENDENT IMPAIRMENT OF THE REWARD SYSTEM POSSIBLY LEADS TO AN ALTERED DRINKING BEHAVIOUR ACCORDING TO THE DEFICIT HYPOTHESIS OF ADDICTION. HOMOCYSTEINE IS INVOLVED IN THE METABOLISM OF METHYL GROUPS AND DNA-METHYLATION PLAYS A ROLE IN REGULATION OF GENE EXPRESSION. THEREFORE IT HAS BEEN SUGGESTED THAT HOMOCYSTEINE IS AN IMPORTANT EPIGENETIC FACTOR. IT REMAINS TO BE DETERMINED WHETHER ALCOHOL DEPENDENT PATIENTS BENEFIT FROM HOMOCYSTEINE LOWERING STRATEGIES, E.G., VIA SUPPLEMENTATION OF FOLATE, VITAMIN B6 AND B12. IN THIS RESPECT IT IS NOT CLEAR YET, IF A SUPPLEMENTATION THERAPY CAN REDUCE THE RISK FOR THE OCCURRENCE OF ALCOHOL WITHDRAWAL SEIZURES.	2008	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                         
19   853  39 CHOLINE, OTHER METHYL-DONORS AND EPIGENETICS. CHOLINE DIETARY INTAKE VARIES SUCH THAT MANY PEOPLE DO NOT ACHIEVE ADEQUATE INTAKES. DIET INTAKE OF CHOLINE CAN MODULATE METHYLATION BECAUSE, VIA BETAINE HOMOCYSTEINE METHYLTRANSFERASE (BHMT), THIS NUTRIENT (AND ITS METABOLITE, BETAINE) REGULATE THE CONCENTRATIONS OF S-ADENOSYLHOMOCYSTEINE AND S-ADENOSYLMETHIONINE. SOME OF THE EPIGENETIC MECHANISMS THAT MODIFY GENE EXPRESSION WITHOUT MODIFYING THE GENETIC CODE DEPEND ON THE METHYLATION OF DNA OR OF HISTONES; AND DIET AVAILABILITY OF CHOLINE AND OTHER METHYL-GROUP DONORS INFLUENCES BOTH OF THESE METHYLATIONS. EXAMPLES OF METHYL-DONOR MEDIATED EPIGENETIC EFFECTS INCLUDE THE CHANGES IN COAT COLOR AND BODY WEIGHT IN OFFSPRING WHEN PREGNANT AGOUTI MICE ARE FED HIGH CHOLINE, HIGH METHYL DIETS; THE CHANGES IN TAIL KINKING IN OFFSPRING WHEN PREGNANT AXIN(FU) MICE ARE FED HIGH CHOLINE, HIGH METHYL DIETS; THE CHANGES IN CDKN3 METHYLATION AND ALTERED BRAIN DEVELOPMENT THAT OCCURS IN OFFSPRING WHEN PREGNANT RODENTS ARE FED LOW CHOLINE DIETS. WHEN CHOLINE METABOLISM IS DISRUPTED BY DELETING THE GENE BHMT, DNA METHYLATION IS AFFECTED (ESPECIALLY IN A REGION OF CHROMOSOME 13), EXPRESSION OF SPECIFIC GENES IS SUPPRESSED, AND LIVER CANCERS DEVELOP. BETTER UNDERSTANDING OF HOW NUTRIENTS SUCH AS CHOLINE AND METHYL-DONORS INFLUENCE EPIGENETIC PROGRAMS HAS IMPORTANCE FOR OUR UNDERSTANDING OF NOT ONLY DEVELOPMENTAL ABNORMALITIES BUT ALSO FOR UNDERSTANDING THE ORIGINS OF CHRONIC DISEASES.	2017	
                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                                          
20  1875  53 EMERGING ROLE OF ONE-CARBON METABOLISM AND DNA METHYLATION ENRICHMENT ON DELTA-CONTAINING GABAA RECEPTOR EXPRESSION IN THE CEREBELLUM OF SUBJECTS WITH ALCOHOL USE DISORDERS (AUD). BACKGROUND: CEREBELLUM IS AN AREA OF THE BRAIN PARTICULARLY SENSITIVE TO THE EFFECTS OF ACUTE AND CHRONIC ALCOHOL CONSUMPTION. ALCOHOL EXPOSURE DECREASES CEREBELLAR PURKINJE CELL OUTPUT BY INCREASING GABA RELEASE FROM GOLGI CELLS ONTO EXTRASYNAPTIC ALPHA6/DELTA-CONTAINING GABAA RECEPTORS LOCATED ON GLUTAMATERGIC GRANULE CELLS. HERE, WE STUDIED WHETHER CHRONIC ALCOHOL CONSUMPTION INDUCES CHANGES IN GABAA RECEPTOR SUBUNIT EXPRESSION AND WHETHER THESE CHANGES ARE ASSOCIATED WITH ALTERATIONS IN EPIGENETIC MECHANISMS VIA DNA METHYLATION. METHODS: WE USED A COHORT OF POSTMORTEM CEREBELLUM FROM CONTROL AND CHRONIC ALCOHOLICS, HERE DEFINED AS ALCOHOL USE DISORDERS SUBJECTS (N=25/GROUP). S-ADENOSYL-METHIONINE/S-ADENOSYL-HOMOCYSTEINE WERE MEASURED BY HIGH-PERFORMANCE LIQUID CHROMATOGRAPHY. MRNA LEVELS OF VARIOUS GENES WERE ASSESSED BY REVERSE TRANSCRIPTASE-QUANTITATIVE POLYMERASE CHAIN REACTION. PROMOTER METHYLATION ENRICHMENT WAS ASSESSED USING METHYLATED DNA IMMUNOPRECIPITATION AND HYDROXY-METHYLATED DNA IMMUNOPRECIPITATION ASSAYS. RESULTS: MRNAS ENCODING KEY ENZYMES OF 1-CARBON METABOLISM THAT DETERMINE THE S-ADENOSYL-METHIONINE/S-ADENOSYL-HOMOCYSTEINE RATIO WERE INCREASED, INDICATING HIGHER "METHYLATION INDEX" IN ALCOHOL USE DISORDER SUBJECTS. WE FOUND THAT INCREASED METHYLATION OF THE PROMOTER OF THE DELTA SUBUNIT GABAA RECEPTOR WAS ASSOCIATED WITH REDUCED MRNA AND PROTEIN LEVELS IN THE CEREBELLUM OF ALCOHOL USE DISORDER SUBJECTS. NO CHANGES WERE OBSERVED IN ALPHA1- OR ALPHA6-CONTAINING GABAA RECEPTOR SUBUNITS. THE EXPRESSION OF DNA-METHYLTRANSFERASES (1, 3A, AND 3B) WAS UNALTERED, WHEREAS THE MRNA LEVEL OF TET1, WHICH PARTICIPATES IN THE DNA DEMETHYLATION PATHWAY, WAS DECREASED. HENCE, INCREASED METHYLATION OF THE DELTA SUBUNIT GABAA RECEPTOR PROMOTER MAY RESULT FROM ALCOHOL-INDUCED REDUCTION OF DNA DEMETHYLATION. CONCLUSION: TOGETHER, THESE RESULTS SUPPORT THE HYPOTHESIS THAT ABERRANT DNA METHYLATION PATHWAYS MAY BE INVOLVED IN CEREBELLAR PATHOPHYSIOLOGY OF ALCOHOLISM. FURTHERMORE, THIS WORK PROVIDES NOVEL EVIDENCE FOR A CENTRAL ROLE OF DNA METHYLATION MECHANISMS IN THE ALCOHOL-INDUCED NEUROADAPTIVE CHANGES OF HUMAN CEREBELLAR GABAA RECEPTOR FUNCTION.	2017