1 871 134 CHRONIC ALCOHOL EXPOSURE AFFECTS PANCREATIC ACINAR MITOCHONDRIAL THIAMIN PYROPHOSPHATE UPTAKE: STUDIES WITH MOUSE 266-6 CELL LINE AND PRIMARY CELLS. THIAMIN IS ESSENTIAL FOR NORMAL METABOLIC ACTIVITY OF ALL MAMMALIAN CELLS, INCLUDING THOSE OF THE PANCREAS. CELLS OBTAIN THIAMIN FROM THEIR SURROUNDINGS AND ENZYMATICALLY CONVERT IT INTO THIAMIN PYROPHOSPHATE (TPP) IN THE CYTOPLASM; TPP IS THEN TAKEN UP BY MITOCHONDRIA VIA A SPECIFIC CARRIER THE MITOCHONDRIAL TPP TRANSPORTER (MTPPT; PRODUCT OF THE SLC25A19 GENE). CHRONIC ALCOHOL EXPOSURE NEGATIVELY IMPACTS THE HEALTH OF PANCREATIC ACINAR CELLS (PAC), BUT ITS EFFECT ON PHYSIOLOGICAL/MOLECULAR PARAMETERS OF MTPPT IS NOT KNOWN. WE ADDRESSED THIS ISSUE USING MOUSE PANCREATIC ACINAR TUMOR CELL LINE 266-6 AND PRIMARY PAC OF WILD-TYPE AND TRANSGENIC MICE CARRYING THE SLC25A19 PROMOTER THAT WERE FED ALCOHOL CHRONICALLY. CHRONIC ALCOHOL EXPOSURE OF 266-6 CELLS (BUT NOT TO ITS NONOXIDATIVE METABOLITES ETHYL PALMITATE AND ETHYL OLEATE) LED TO A SIGNIFICANT INHIBITION IN MITOCHONDRIAL TPP UPTAKE, WHICH WAS ASSOCIATED WITH A DECREASED EXPRESSION OF MTPPT PROTEIN, MRNA, AND ACTIVITY OF THE SLC25A19 PROMOTER. SIMILARLY, CHRONIC ALCOHOL FEEDING OF MICE LED TO A SIGNIFICANT INHIBITION IN EXPRESSION OF MTPPT PROTEIN, MRNA, HETEROGENEOUS NUCLEAR RNA, AS WELL AS IN ACTIVITY OF SLC25A19 PROMOTER IN PAC. WHILE CHRONIC ALCOHOL EXPOSURE DID NOT AFFECT DNA METHYLATION OF THE SLC25A19 PROMOTER, A SIGNIFICANT DECREASE IN HISTONE H3 EUCHROMATIN MARKERS AND AN INCREASE IN H3 HETEROCHROMATIN MARKER WERE OBSERVED. THESE FINDINGS SHOW, FOR THE FIRST TIME, THAT CHRONIC ALCOHOL EXPOSURE NEGATIVELY IMPACTS PANCREATIC MTPPT, AND THAT THIS EFFECT IS EXERTED, AT LEAST IN PART, AT THE LEVEL OF SLC25A19 TRANSCRIPTION AND APPEARS TO INVOLVE EPIGENETIC MECHANISM(S). 2015 2 873 75 CHRONIC ALCOHOL EXPOSURE INHIBITS BIOTIN UPTAKE BY PANCREATIC ACINAR CELLS: POSSIBLE INVOLVEMENT OF EPIGENETIC MECHANISMS. CHRONIC EXPOSURE TO ALCOHOL AFFECTS DIFFERENT PHYSIOLOGICAL ASPECTS OF PANCREATIC ACINAR CELLS (PAC), BUT ITS EFFECT ON THE UPTAKE PROCESS OF BIOTIN IS NOT KNOWN. WE ADDRESSED THIS ISSUE USING MOUSE-DERIVED PANCREATIC ACINAR 266-6 CELLS CHRONICALLY EXPOSED TO ALCOHOL AND WILD-TYPE AND TRANSGENIC MICE (CARRYING THE HUMAN SLC5A6 5'-PROMOTER) FED ALCOHOL CHRONICALLY. FIRST WE ESTABLISHED THAT BIOTIN UPTAKE BY PAC IS NA(+) DEPENDENT AND CARRIER MEDIATED AND INVOLVES SODIUM-DEPENDENT MULTIVITAMIN TRANSPORTER (SMVT). CHRONIC EXPOSURE OF 266-6 CELLS TO ALCOHOL LED TO A SIGNIFICANT INHIBITION IN BIOTIN UPTAKE, EXPRESSION OF SMVT PROTEIN, AND MRNA AS WELL AS IN THE ACTIVITY OF THE SLC5A6 PROMOTER. SIMILARLY, CHRONIC ALCOHOL FEEDING OF WILD-TYPE AND TRANSGENIC MICE CARRYING THE SLC5A6 PROMOTER LED TO A SIGNIFICANT INHIBITION IN BIOTIN UPTAKE BY PAC, AS WELL AS IN THE EXPRESSION OF SMVT PROTEIN AND MRNA AND THE ACTIVITY OF THE SLC5A6 PROMOTERS EXPRESSED IN THE TRANSGENIC MICE. WE ALSO FOUND THAT CHRONIC ALCOHOL FEEDING OF MICE IS ASSOCIATED WITH A SIGNIFICANT INCREASE IN THE METHYLATION STATUS OF CPG ISLANDS PREDICTED TO BE IN THE MOUSE SLC5A6 PROMOTERS AND A DECREASE IN THE LEVEL OF EXPRESSION OF TRANSCRIPTION FACTOR KLF-4, WHICH PLAYS AN IMPORTANT ROLE IN REGULATING SLC5A6 PROMOTER ACTIVITY. THESE RESULTS DEMONSTRATE, FOR THE FIRST TIME, THAT CHRONIC ALCOHOL EXPOSURE NEGATIVELY IMPACTS BIOTIN UPTAKE IN PAC AND THAT THIS EFFECT IS EXERTED (AT LEAST IN PART) AT THE LEVEL OF TRANSCRIPTION OF THE SLC5A6 GENE AND MAY INVOLVE EPIGENETIC/MOLECULAR MECHANISMS. 2014 3 1787 57 EFFECT OF CHRONIC ALCOHOL EXPOSURE ON GUT VITAMIN B7 UPTAKE: INVOLVEMENT OF EPIGENETIC MECHANISMS AND EFFECT OF ALCOHOL METABOLITES. VITAMIN B7 (BIOTIN) IS ESSENTIAL FOR NORMAL HEALTH AND ITS DEFICIENCY/SUBOPTIMAL LEVELS OCCUR IN A VARIETY OF CONDITIONS INCLUDING CHRONIC ALCOHOLISM. MAMMALS, INCLUDING HUMANS, OBTAIN BIOTIN FROM DIET AND GUT-MICROBIOTA VIA ABSORPTION ALONG THE INTESTINAL TRACT. THE ABSORPTION PROCESS IS CARRIER MEDIATED AND INVOLVES THE SODIUM-DEPENDENT MULTIVITAMIN TRANSPORTER (SMVT; SLC5A6). WE HAVE PREVIOUSLY SHOWN THAT CHRONIC ALCOHOL EXPOSURE SIGNIFICANTLY INHIBITS INTESTINAL/COLONIC BIOTIN UPTAKE VIA SUPPRESSION OF SLC5A6 TRANSCRIPTION IN ANIMAL AND CELL LINE MODELS. HOWEVER, LITTLE IS KNOWN ABOUT THE TRANSCRIPTIONAL/EPIGENETIC FACTORS THAT MEDIATE THIS SUPPRESSION. IN ADDITION, THE EFFECT OF ALCOHOL METABOLITES (GENERATED VIA ALCOHOL METABOLISM BY GUT MICROBIOTA AND HOST TISSUES) ON BIOTIN UPTAKE IS STILL UNKNOWN. TO ADDRESS THESE QUESTIONS, WE FIRST DEMONSTRATED THAT CHRONIC ALCOHOL EXPOSURE INHIBITS SMALL INTESTINAL AND COLONIC BIOTIN UPTAKE AND SMVT EXPRESSION IN HUMAN DIFFERENTIATED ENTEROID AND COLONOID MONOLAYERS. WE THEN SHOWED THAT CHRONIC ALCOHOL EXPOSURES OF BOTH, CACO-2 CELLS AND MICE, ARE ASSOCIATED WITH A SIGNIFICANT SUPPRESSION IN EXPRESSION OF THE NUCLEAR FACTOR KLF-4 (NEEDED FOR SLC5A6 PROMOTER ACTIVITY), AS WELL AS WITH EPIGENETIC ALTERATIONS (HISTONE MODIFICATIONS). WE ALSO FOUND THAT CHRONIC EXPOSURE OF NCM460 HUMAN COLONIC EPITHELIAL CELLS AS WELL AS HUMAN DIFFERENTIATED COLONOID MONOLAYERS, TO ALCOHOL METABOLITES (ACETALDEHYDE, ETHYL PALMITATE, ETHYL OLEATE) SIGNIFICANTLY INHIBITED BIOTIN UPTAKE AND SMVT EXPRESSION. THESE FINDINGS SHED LIGHT ONTO THE MOLECULAR/EPIGENETIC MECHANISMS THAT MEDIATE THE INHIBITORY EFFECT OF CHRONIC ALCOHOL EXPOSURE ON INTESTINAL BIOTIN UPTAKE. THEY FURTHER SHOW THAT ALCOHOL METABOLITES ARE ALSO CAPABLE OF INHIBITING BIOTIN UPTAKE IN THE GUT.NEW & NOTEWORTHY USING COMPLEMENTARY MODELS, INCLUDING HUMAN DIFFERENTIATED ENTEROID AND COLONOID MONOLAYERS, THIS STUDY SHOWS THE INVOLVEMENT OF MOLECULAR AND EPIGENETIC MECHANISMS IN MEDIATING THE INHIBITORY EFFECT OF CHRONIC ALCOHOL EXPOSURE ON BIOTIN UPTAKE ALONG THE INTESTINAL TRACT. THE STUDY ALSO SHOWS THAT ALCOHOL METABOLITES (GENERATED BY GUT MICROBIOTA AND HOST TISSUES) CAUSE INHIBITION IN GUT BIOTIN UPTAKE. 2021 4 3359 23 HISTONE H4 LYSINE 16 ACETYLATION CONTROLS CENTRAL CARBON METABOLISM AND DIET-INDUCED OBESITY IN MICE. NONCOMMUNICABLE DISEASES (NCDS) ACCOUNT FOR OVER 70% OF DEATHS WORLD-WIDE. PREVIOUS WORK HAS LINKED NCDS SUCH AS TYPE 2 DIABETES (T2D) TO DISRUPTION OF CHROMATIN REGULATORS. HOWEVER, THE EXACT MOLECULAR ORIGINS OF THESE CHRONIC CONDITIONS REMAIN ELUSIVE. HERE, WE IDENTIFY THE H4 LYSINE 16 ACETYLTRANSFERASE MOF AS A CRITICAL REGULATOR OF CENTRAL CARBON METABOLISM. HIGH-THROUGHPUT METABOLOMICS UNVEIL A SYSTEMIC AMINO ACID AND CARBOHYDRATE IMBALANCE IN MOF DEFICIENT MICE, MANIFESTING IN T2D PREDISPOSITION. ORAL GLUCOSE TOLERANCE TESTING (OGTT) REVEALS DEFECTS IN GLUCOSE ASSIMILATION AND INSULIN SECRETION IN THESE ANIMALS. FURTHERMORE, MOF DEFICIENT MICE ARE RESISTANT TO DIET-INDUCED FAT GAIN DUE TO DEFECTS IN GLUCOSE UPTAKE IN ADIPOSE TISSUE. MOF-MEDIATED H4K16AC DEPOSITION CONTROLS EXPRESSION OF THE MASTER REGULATOR OF GLUCOSE METABOLISM, PPARG AND THE ENTIRE DOWNSTREAM TRANSCRIPTIONAL NETWORK. GLUCOSE UPTAKE AND LIPID STORAGE CAN BE RECONSTITUTED IN MOF-DEPLETED ADIPOCYTES IN VITRO BY ECTOPIC GLUT4 EXPRESSION, PPARGAMMA AGONIST THIAZOLIDINEDIONE (TZD) TREATMENT OR SIRT1 INHIBITION. HENCE, CHRONIC IMBALANCE IN H4K16AC PROMOTES A DESTABILISATION OF METABOLISM TRIGGERING THE DEVELOPMENT OF A METABOLIC DISORDER, AND ITS MAINTENANCE PROVIDES AN UNPRECEDENTED REGULATORY EPIGENETIC MECHANISM CONTROLLING DIET-INDUCED OBESITY. 2021 5 1066 31 CLINICAL USE OF AMINO ACIDS AS DIETARY SUPPLEMENT: PROS AND CONS. NITROGEN SUPPLY IS PIVOTAL FOR THE MAINTENANCE OF LIFE. AMINO ACIDS CAN BE UTILIZED TO SYNTHESIZE BOTH GLUCOSE AND LIPIDS. THE OPPOSITE, I.E., PRODUCTION OF AMINO ACIDS FROM EITHER ONE OF THEM, IS NOT POSSIBLE IN THE ABSENCE OF OTHER AMINO ACIDS AS DONORS OF NITROGEN. THE QUALITY OF AMINO ACID CONTENT IN PROTEIN HAS BEEN RE-EVALUATED RECENTLY, AND THE RELEVANCE OF ESSENTIAL AMINO ACIDS HAS BEEN REPEATEDLY UNDERLINED. ESSENTIAL AMINO ACID REQUIREMENTS IN DIFFERENT MAMMALS ARE NOT IDENTICAL, AND RATIOS AMONG THEM SHOULD BE TAKEN INTO ACCOUNT WHEN PROJECTING AN EFFICIENT FORMULATION. RECENT RESEARCH HAS DEMONSTRATED THAT GENES RESPOND TO DIFFERENT QUALITIES AND QUANTITIES OF NUTRITIONAL SUPPLY, AND INCREASED PROVISION OF ESSENTIAL AMINO ACIDS INCREASES LIFESPAN IN ANIMAL EXPERIMENTS THROUGH MITOCHONDRIOGENESIS AND MAINTENANCE OF ELEVATED RATES OF SYNTHESIS OF ANTI-OXIDANT MOLECULES. MOREOVER, GENETIC EXPRESSION OF KEY CONTROLLERS OF SYNTHESIS, LIKE MTOR, MAY BE PARTICULARLY IMPORTANT FOR UNDERSTANDING SKELETAL MUSCLE MAINTENANCE. LOSSES OF MUSCLE MASS AND IMPAIRED IMMUNE FUNCTION ARE RELATED TO REDUCED PROTEIN SUPPLY, AND THERE IS INCREASING EVIDENCE THAT REGULAR ESSENTIAL AMINO ACID INTAKE AS PART OF AN ORAL DIET IS EFFECTIVE IN REVERSING MUSCLE CATABOLISM, PROMOTING MUSCLE ANABOLISM, AND RESTORING IMMUNOLOGICAL FUNCTION. THEREFORE, THE USE OF AMINO ACIDS AS SUPPLEMENTS TO DIET WOULD BE EXPANDING IN THE NEAR FUTURE. IS THIS SAFE? FEW DATA ARE AVAILABLE ON AMINO ACID TOXICITY, AND ONLY ONE ESSENTIAL AMINO ACID MAY BE CONSIDERED TO HAVE CLINICALLY RELEVANT TOXICITY: METHIONINE, BECAUSE IT IS TRANSFORMED INTO A TOXIC INTERMEDIATE, HOMOCYSTEINE, WHEN CYSTEINE SYNTHESIS IS REQUIRED BY METABOLIC NEEDS. MATCHING OF STOICHIOMETRIC RATIOS BETWEEN METHIONINE AND CYSTEINE MAY SOLVE THE PROBLEM OF SUPPLYING SUFFICIENT AMOUNTS OF SULFUR TO THE BODY. ARGININE AND GLUTAMINE ARE TWO NON-ESSENTIAL AMINO ACIDS THAN CAN BECOME "CONDITIONALLY ESSENTIAL" BECAUSE OF ELEVATED NEEDS DURING PATHOLOGICAL CONDITIONS, AND METABOLISM MAY NOT BE ABLE TO MAINTAIN THEIR CONCENTRATIONS AT SUFFICIENT LEVELS TO MATCH METABOLIC REQUIREMENTS. CHRONIC EXOGENOUS ARGININE SUPPLEMENTATION HAS NOT PROVEN TO EXERT POSITIVE CLINICAL EFFECTS IN DIFFERENT TRIALS, AND SEQUENTIAL ARTICULATION OF THE KNOWLEDGE OF INTRODUCTION OF ARGININE-DRIVEN TRANSCRIPTIONAL, TRANSLATIONAL, AND EPIGENETIC ADAPTATIONS MAY GIVE US A KEY FOR INTERPRETING THOSE PUZZLING RESULTS. 2011 6 4625 32 NEUROBIOLOGY OF VITAMIN C: EXPANDING THE FOCUS FROM ANTIOXIDANT TO ENDOGENOUS NEUROMODULATOR. ASCORBIC ACID (AA) IS A WATER-SOLUBLE VITAMIN (C) FOUND IN ALL BODILY ORGANS. MOST MAMMALS SYNTHESIZE IT, HUMANS ARE REQUIRED TO EAT IT, BUT ALL MAMMALS NEED IT FOR HEALTHY FUNCTIONING. AA REACHES ITS HIGHEST CONCENTRATION IN THE BRAIN WHERE BOTH NEURONS AND GLIA RELY ON TIGHTLY REGULATED UPTAKE FROM BLOOD VIA THE GLUCOSE TRANSPORT SYSTEM AND SODIUM-COUPLED ACTIVE TRANSPORT TO ACCUMULATE AND MAINTAIN AA AT MILLIMOLAR LEVELS. AS A PROTOTYPE ANTIOXIDANT, AA IS NOT ONLY NEUROPROTECTIVE, BUT ALSO FUNCTIONS AS A COFACTOR IN REDOX-COUPLED REACTIONS ESSENTIAL FOR THE SYNTHESIS OF NEUROTRANSMITTERS (E.G., DOPAMINE AND NOREPINEPHRINE) AND PARACRINE LIPID MEDIATORS (E.G., EPOXIECOISATRIENOIC ACIDS) AS WELL AS THE EPIGENETIC REGULATION OF DNA. ALTHOUGH REDOX CAPACITY LED TO THE PROMOTION OF AA IN HIGH DOSES AS POTENTIAL TREATMENT FOR VARIOUS NEUROPATHOLOGICAL AND PSYCHIATRIC CONDITIONS, AMPLE EVIDENCE HAS NOT SUPPORTED THIS THERAPEUTIC STRATEGY. HERE, WE FOCUS ON SOME LONG-NEGLECTED ASPECTS OF AA NEUROBIOLOGY, INCLUDING ITS MODULATORY ROLE IN SYNAPTIC TRANSMISSION AS DEMONSTRATED BY THE LONG-ESTABLISHED LINK BETWEEN RELEASE OF ENDOGENOUS AA IN BRAIN EXTRACELLULAR FLUID AND THE CLEARANCE OF GLUTAMATE, AN EXCITATORY AMINO ACID. EVIDENCE THAT THIS LINK CAN BE DISRUPTED IN ANIMAL MODELS OF HUNTINGTON S DISEASE IS REVEALING OPPORTUNITIES FOR NEW RESEARCH PATHWAYS AND THERAPEUTIC APPLICATIONS (E.G., EPILEPSY AND PAIN MANAGEMENT). IN FACT, WE SUGGEST THAT IMPROVED UNDERSTANDING OF THE REGULATION OF ENDOGENOUS AA AND ITS INTERACTION WITH KEY BRAIN NEUROTRANSMITTER SYSTEMS, RATHER THAN ADMINISTRATION OF AA IN EXCESS, SHOULD BE THE TARGET OF FUTURE BRAIN-BASED THERAPIES. 2019 7 169 35 ABNORMALITIES OF AMPK ACTIVATION AND GLUCOSE UPTAKE IN CULTURED SKELETAL MUSCLE CELLS FROM INDIVIDUALS WITH CHRONIC FATIGUE SYNDROME. BACKGROUND: POST EXERTIONAL MUSCLE FATIGUE IS A KEY FEATURE IN CHRONIC FATIGUE SYNDROME (CFS). ABNORMALITIES OF SKELETAL MUSCLE FUNCTION HAVE BEEN IDENTIFIED IN SOME BUT NOT ALL PATIENTS WITH CFS. TO TRY TO LIMIT POTENTIAL CONFOUNDERS THAT MIGHT CONTRIBUTE TO THIS CLINICAL HETEROGENEITY, WE DEVELOPED A NOVEL IN VITRO SYSTEM THAT ALLOWS COMPARISON OF AMP KINASE (AMPK) ACTIVATION AND METABOLIC RESPONSES TO EXERCISE IN CULTURED SKELETAL MUSCLE CELLS FROM CFS PATIENTS AND CONTROL SUBJECTS. METHODS: SKELETAL MUSCLE CELL CULTURES WERE ESTABLISHED FROM 10 SUBJECTS WITH CFS AND 7 AGE-MATCHED CONTROLS, SUBJECTED TO ELECTRICAL PULSE STIMULATION (EPS) FOR UP TO 24H AND EXAMINED FOR CHANGES ASSOCIATED WITH EXERCISE. RESULTS: IN THE BASAL STATE, CFS CULTURES SHOWED INCREASED MYOGENIN EXPRESSION BUT DECREASED IL6 SECRETION DURING DIFFERENTIATION COMPARED WITH CONTROL CULTURES. CONTROL CULTURES SUBJECTED TO 16 H EPS SHOWED A SIGNIFICANT INCREASE IN BOTH AMPK PHOSPHORYLATION AND GLUCOSE UPTAKE COMPARED WITH UNSTIMULATED CELLS. IN CONTRAST, CFS CULTURES SHOWED NO INCREASE IN AMPK PHOSPHORYLATION OR GLUCOSE UPTAKE AFTER 16 H EPS. HOWEVER, GLUCOSE UPTAKE REMAINED RESPONSIVE TO INSULIN IN THE CFS CELLS POINTING TO AN EXERCISE-RELATED DEFECT. IL6 SECRETION IN RESPONSE TO EPS WAS SIGNIFICANTLY REDUCED IN CFS COMPARED WITH CONTROL CULTURES AT ALL TIME POINTS MEASURED. CONCLUSION: EPS IS AN EFFECTIVE MODEL FOR ELICITING MUSCLE CONTRACTION AND THE METABOLIC CHANGES ASSOCIATED WITH EXERCISE IN CULTURED SKELETAL MUSCLE CELLS. WE FOUND FOUR MAIN DIFFERENCES IN CULTURED SKELETAL MUSCLE CELLS FROM SUBJECTS WITH CFS; INCREASED MYOGENIN EXPRESSION IN THE BASAL STATE, IMPAIRED ACTIVATION OF AMPK, IMPAIRED STIMULATION OF GLUCOSE UPTAKE AND DIMINISHED RELEASE OF IL6. THE RETENTION OF THESE DIFFERENCES IN CULTURED MUSCLE CELLS FROM CFS SUBJECTS POINTS TO A GENETIC/EPIGENETIC MECHANISM, AND PROVIDES A SYSTEM TO IDENTIFY NOVEL THERAPEUTIC TARGETS. 2015 8 6166 31 THE GLUTATHIONE SYSTEM: A NEW DRUG TARGET IN NEUROIMMUNE DISORDERS. GLUTATHIONE (GSH) HAS A CRUCIAL ROLE IN CELLULAR SIGNALING AND ANTIOXIDANT DEFENSES EITHER BY REACTING DIRECTLY WITH REACTIVE OXYGEN OR NITROGEN SPECIES OR BY ACTING AS AN ESSENTIAL COFACTOR FOR GSH S-TRANSFERASES AND GLUTATHIONE PEROXIDASES. GSH ACTING IN CONCERT WITH ITS DEPENDENT ENZYMES, KNOWN AS THE GLUTATHIONE SYSTEM, IS RESPONSIBLE FOR THE DETOXIFICATION OF REACTIVE OXYGEN AND NITROGEN SPECIES (ROS/RNS) AND ELECTROPHILES PRODUCED BY XENOBIOTICS. ADEQUATE LEVELS OF GSH ARE ESSENTIAL FOR THE OPTIMAL FUNCTIONING OF THE IMMUNE SYSTEM IN GENERAL AND T CELL ACTIVATION AND DIFFERENTIATION IN PARTICULAR. GSH IS A UBIQUITOUS REGULATOR OF THE CELL CYCLE PER SE. GSH ALSO HAS CRUCIAL FUNCTIONS IN THE BRAIN AS AN ANTIOXIDANT, NEUROMODULATOR, NEUROTRANSMITTER, AND ENABLER OF NEURON SURVIVAL. DEPLETION OF GSH LEADS TO EXACERBATION OF DAMAGE BY OXIDATIVE AND NITROSATIVE STRESS; HYPERNITROSYLATION; INCREASED LEVELS OF PROINFLAMMATORY MEDIATORS AND INFLAMMATORY POTENTIAL; DYSFUNCTIONS OF INTRACELLULAR SIGNALING NETWORKS, E.G., P53, NUCLEAR FACTOR-KAPPAB, AND JANUS KINASES; DECREASED CELL PROLIFERATION AND DNA SYNTHESIS; INACTIVATION OF COMPLEX I OF THE ELECTRON TRANSPORT CHAIN; ACTIVATION OF CYTOCHROME C AND THE APOPTOTIC MACHINERY; BLOCKADE OF THE METHIONINE CYCLE; AND COMPROMISED EPIGENETIC REGULATION OF GENE EXPRESSION. AS SUCH, GSH DEPLETION HAS MARKED CONSEQUENCES FOR THE HOMEOSTATIC CONTROL OF THE IMMUNE SYSTEM, OXIDATIVE AND NITROSATIVE STRESS (O&NS) PATHWAYS, REGULATION OF ENERGY PRODUCTION, AND MITOCHONDRIAL SURVIVAL AS WELL. GSH DEPLETION AND CONCOMITANT INCREASE IN O&NS AND MITOCHONDRIAL DYSFUNCTIONS PLAY A ROLE IN THE PATHOPHYSIOLOGY OF DIVERSE NEUROIMMUNE DISORDERS, INCLUDING DEPRESSION, MYALGIC ENCEPHALOMYELITIS/CHRONIC FATIGUE SYNDROME AND PARKINSON'S DISEASE, SUGGESTING THAT DEPLETED GSH IS AN INTEGRAL PART OF THESE DISEASES. THERAPEUTICAL INTERVENTIONS THAT AIM TO INCREASE GSH CONCENTRATIONS IN VIVO INCLUDE N-ACETYL CYSTEINE; NRF-2 ACTIVATION VIA HYPERBARIC OXYGEN THERAPY; DIMETHYL FUMARATE; PHYTOCHEMICALS, INCLUDING CURCUMIN, RESVERATROL, AND CINNAMON; AND FOLATE SUPPLEMENTATION. 2014 9 5074 32 PHYSIOLOGIC AND EPIGENETIC EFFECTS OF NUTRIENTS ON DISEASE PATHWAYS. BACKGROUND/OBJECTIVES: EPIGENETIC REGULATION BY NUTRIENTS CAN INFLUENCE THE DEVELOPMENT OF SPECIFIC DISEASES. THIS STUDY SOUGHT TO EXAMINE THE EFFECT OF INDIVIDUAL NUTRIENTS AND NUTRIENT FAMILIES IN THE CONTEXT OF PREVENTING CHRONIC METABOLIC DISEASES VIA EPIGENETIC REGULATION. THE INHIBITION OF LIPID ACCUMULATION AND INFLAMMATION BY NUTRIENTS INCLUDING PROTEINS, LIPIDS, VITAMINS, AND MINERALS WERE OBSERVED, AND HISTONE ACETYLATION BY HISTONE ACETYLTRANSFERASE (HAT) WAS MEASURED. CORRELATIVE ANALYSES WERE ALSO PERFORMED. MATERIALS/METHODS: NUTRIENTS WERE SELECTED ACCORDING TO INFORMATION FROM THE KOREAN MINISTRY OF FOOD AND DRUG SAFETY. SELECTED NUTRIENT FUNCTIONALITIES, INCLUDING THE ATTENUATION OF FATTY ACID-INDUCED LIPID ACCUMULATION AND LIPOPOLYSACCHARIDE-MEDIATED ACUTE INFLAMMATION WERE EVALUATED IN MOUSE MACROPHAGE RAW264.7 AND MOUSE HEPATOCYTE AML-12 CELLS. EFFECTS OF THE SELECTED NUTRIENTS ON IN VITRO HAT INHIBITION WERE ALSO EVALUATED. RESULTS: NITRIC OXIDE (NO) PRODUCTION CORRELATED WITH HAT ACTIVITY, WHICH WAS REGULATED BY THE AMINO ACIDS GROUP, SUGGESTING THAT AMINO ACIDS POTENTIALLY CONTRIBUTE TO THE ATTENUATION OF NO PRODUCTION VIA THE INHIBITION OF HAT ACTIVITY. UNSATURATED FATTY ACIDS TENDED TO ATTENUATE INFLAMMATION BY INHIBITING NO PRODUCTION, WHICH MAY BE ATTRIBUTABLE TO THE INHIBITION OF IN VITRO HAT ACTIVITY. IN CONTRAST TO WATER-SOLUBLE VITAMINS, THE LIPID-SOLUBLE VITAMINS SIGNIFICANTLY DECREASED NO PRODUCTION. WATER- AND LIPID-SOLUBLE VITAMINS BOTH EXHIBITED SIGNIFICANT INHIBITORY ACTIVITIES AGAINST HAT. IN ADDITION, CALCIUM AND MANGANESE SIGNIFICANTLY INHIBITED LIPID ACCUMULATION, NO PRODUCTION, AND HAT ACTIVITY. CONCLUSIONS: SEVERAL CANDIDATE NUTRIENTS AND THEIR FAMILY MEMBERS MAY HAVE ROLES IN THE PREVENTION OF DISEASES, INCLUDING HEPATIC STEATOSIS AND INFLAMMATION-RELATED DISEASES (I.E., NONALCOHOLIC STEATOHEPATITIS) VIA EPIGENETIC REGULATION. FURTHER STUDIES ARE WARRANTED TO DETERMINE WHICH SPECIFIC AMINO ACIDS, UNSATURATED FATTY ACIDS AND LIPID-SOLUBLE VITAMINS OR SPECIFIC MINERALS INFLUENCE THE DEVELOPMENT OF STEATOSIS AND INFLAMMATORY-RELATED DISEASES. 2023 10 2702 33 EXCITOTOXICITY AND OVERNUTRITION ADDITIVELY IMPAIR METABOLIC FUNCTION AND IDENTITY OF PANCREATIC BETA-CELLS. A SUSTAINED INCREASE IN INTRACELLULAR CA(2+) CONCENTRATION (REFERRED TO HEREAFTER AS EXCITOTOXICITY), BROUGHT ON BY CHRONIC METABOLIC STRESS, MAY CONTRIBUTE TO PANCREATIC BETA-CELL FAILURE. TO DETERMINE THE ADDITIVE EFFECTS OF EXCITOTOXICITY AND OVERNUTRITION ON BETA-CELL FUNCTION AND GENE EXPRESSION, WE ANALYZED THE IMPACT OF A HIGH-FAT DIET (HFD) ON ABCC8 KNOCKOUT MICE. EXCITOTOXICITY CAUSED BETA-CELLS TO BE MORE SUSCEPTIBLE TO HFD-INDUCED IMPAIRMENT OF GLUCOSE HOMEOSTASIS, AND THESE EFFECTS WERE MITIGATED BY VERAPAMIL, A CA(2+) CHANNEL BLOCKER. EXCITOTOXICITY, OVERNUTRITION, AND THE COMBINATION OF BOTH STRESSES CAUSED SIMILAR BUT DISTINCT ALTERATIONS IN THE BETA-CELL TRANSCRIPTOME, INCLUDING ADDITIVE INCREASES IN GENES ASSOCIATED WITH MITOCHONDRIAL ENERGY METABOLISM, FATTY ACID BETA-OXIDATION, AND MITOCHONDRIAL BIOGENESIS AND THEIR KEY REGULATOR PPARGC1A OVERNUTRITION WORSENED EXCITOTOXICITY-INDUCED MITOCHONDRIAL DYSFUNCTION, INCREASING METABOLIC INFLEXIBILITY AND MITOCHONDRIAL DAMAGE. IN ADDITION, EXCITOTOXICITY AND OVERNUTRITION, INDIVIDUALLY AND TOGETHER, IMPAIRED BOTH BETA-CELL FUNCTION AND IDENTITY BY REDUCING EXPRESSION OF GENES IMPORTANT FOR INSULIN SECRETION, CELL POLARITY, CELL JUNCTION, CILIA, CYTOSKELETON, VESICULAR TRAFFICKING, AND REGULATION OF BETA-CELL EPIGENETIC AND TRANSCRIPTIONAL PROGRAM. SEX HAD AN IMPACT ON ALL BETA-CELL RESPONSES, WITH MALE ANIMALS EXHIBITING GREATER METABOLIC STRESS-INDUCED IMPAIRMENTS THAN FEMALES. TOGETHER, THESE FINDINGS INDICATE THAT A SUSTAINED INCREASE IN INTRACELLULAR CA(2+), BY ALTERING MITOCHONDRIAL FUNCTION AND IMPAIRING BETA-CELL IDENTITY, AUGMENTS OVERNUTRITION-INDUCED BETA-CELL FAILURE. 2020 11 6666 72 UPTAKE OF ASCORBIC ACID BY PANCREATIC ACINAR CELLS IS NEGATIVELY IMPACTED BY CHRONIC ALCOHOL EXPOSURE. VITAMIN C (ASCORBIC ACID, AA) IS INDISPENSABLE FOR NORMAL METABOLISM OF ALL MAMMALIAN CELLS INCLUDING PANCREATIC ACINAR CELLS (PACS). PACS OBTAIN AA FROM THEIR SURROUNDINGS VIA TRANSPORT ACROSS THE CELL MEMBRANE. CHRONIC ALCOHOL EXPOSURE NEGATIVELY AFFECTS BODY AA HOMEOSTASIS; IT ALSO INHIBITS UPTAKE OF OTHER MICRONUTRIENTS INTO PACS, BUT ITS EFFECT ON AA UPTAKE IS NOT CLEAR. WE EXAMINED THIS ISSUE USING BOTH IN VITRO (266-6 CELLS) AND IN VIVO (MICE) MODELS OF CHRONIC ALCOHOL EXPOSURE. FIRST, WE DETERMINED THE RELATIVE EXPRESSION OF THE AA TRANSPORTERS 1 AND 2 [I.E., SODIUM-DEPENDENT VITAMIN C TRANSPORTER-1 (SVCT-1) AND SVCT-2] IN MOUSE AND HUMAN PACS AND FOUND SVCT-2 TO BE THE PREDOMINANT TRANSPORTER. CHRONIC EXPOSURE OF 266-6 CELLS TO ALCOHOL SIGNIFICANTLY INHIBITED AA UPTAKE AND CAUSED A MARKED REDUCTION IN SVCT-2 EXPRESSION AT THE PROTEIN, MRNA, AND HETEROGENEOUS NUCLEAR RNA (HNRNA) LEVELS. SIMILARLY, CHRONIC ALCOHOL FEEDING OF MICE SIGNIFICANTLY INHIBITED AA UPTAKE AND CAUSED A MARKED REDUCTION IN LEVEL OF EXPRESSION OF THE SVCT-2 PROTEIN, MRNA, AND HNRNA. THESE FINDINGS SUGGEST POSSIBLE INVOLVEMENT OF TRANSCRIPTIONAL MECHANISM(S) IN MEDIATING CHRONIC ALCOHOL EFFECT ON AA UPTAKE BY PACS. WE ALSO OBSERVED SIGNIFICANT EPIGENETIC CHANGES (HISTONE MODIFICATIONS) IN THE SLC23A2 GENE (REDUCTION IN H3K4ME3 LEVEL AND AN INCREASE IN H3K27ME3 LEVEL) IN THE ALCOHOL-EXPOSED 266-6 CELLS. THESE FINDINGS SHOW THAT CHRONIC ALCOHOL EXPOSURE INHIBITS PAC AA UPTAKE AND THAT THE EFFECT IS MEDIATED, IN PART, AT THE LEVEL OF TRANSCRIPTION OF THE SLC23A2 GENE AND MAY INVOLVE EPIGENETIC MECHANISM(S). 2016 12 2772 30 EXTRACELLULAR ATP AND NEURODEGENERATION. ATP IS A POTENT SIGNALING MOLECULE ABUNDANTLY PRESENT IN THE CNS. IT ELICITS A WIDE ARRAY OF PHYSIOLOGICAL EFFECTS AND IS REGARDED AS THE PHYLOGENETICALLY MOST ANCIENT EPIGENETIC FACTOR PLAYING CRUCIAL BIOLOGICAL ROLES IN SEVERAL DIFFERENT TISSUES. THESE CAN RANGE FROM NEUROTRANSMISSION, SMOOTH MUSCLE CONTRACTION, CHEMOSENSORY SIGNALING, SECRETION AND VASODILATATION, TO MORE COMPLEX PHENOMENA SUCH AS IMMUNE RESPONSES, PAIN, MALE REPRODUCTION, FERTILIZATION AND EMBRYONIC DEVELOPMENT. ATP IS RELEASED INTO THE EXTRACELLULAR SPACE EITHER EXOCYTOTICALLY OR FROM DAMAGED AND DYING CELLS. IT IS OFTEN CO-RELEASED WITH OTHER NEUROTRANSMITTERS AND IT CAN INTERACT WITH GROWTH FACTORS AT BOTH RECEPTOR- AND/OR SIGNAL TRANSDUCTION-LEVEL. ONCE IN THE EXTRACELLULAR ENVIRONMENT, ATP BINDS TO SPECIFIC RECEPTORS TERMED P2. BASED ON PHARMACOLOGICAL PROFILES, ON SELECTIVITY OF COUPLING TO SECOND-MESSENGER PATHWAYS AND ON MOLECULAR CLONING, TWO MAIN SUBCLASSES WITH MULTIPLE SUBTYPES HAVE BEEN DISTINGUISHED. THEY ARE P2X, I.E. FAST CATION-SELECTIVE RECEPTOR CHANNELS (NA+, K+, CA2+), POSSESSING LOW AFFINITY FOR ATP AND RESPONSIBLE FOR FAST EXCITATORY NEUROTRANSMISSION, AND P2Y, I.E. SLOW G PROTEIN-COUPLED METABOTROPIC RECEPTORS, POSSESSING HIGHER AFFINITY FOR THE LIGAND. IN THE NERVOUS SYSTEM, THEY ARE BROADLY EXPRESSED IN BOTH NEURONS AND GLIAL CELLS AND CAN MEDIATE DUAL EFFECTS: SHORT-TERM SUCH AS NEUROTRANSMISSION, AND LONG-TERM SUCH AS TROPHIC ACTIONS. SINCE MASSIVE EXTRACELLULAR RELEASE OF ATP OFTEN OCCURS AFTER METABOLIC STRESS, BRAIN ISCHEMIA AND TRAUMA, PURINERGIC MECHANISMS ARE ALSO CORRELATED TO AND INVOLVED IN THE ETIOPATHOLOGY OF MANY NEURODEGENERATIVE CONDITIONS. FURTHERMORE, EXTRACELLULAR ATP PER SE IS TOXIC FOR PRIMARY NEURONAL DISSOCIATED AND ORGANOTYPIC CNS CULTURES FROM CORTEX, STRIATUM AND CEREBELLUM AND P2 RECEPTORS CAN MEDIATE AND AGGRAVATE HYPOXIC SIGNALING IN MANY CNS NEURONS. CONVERSELY, SEVERAL P2 RECEPTOR ANTAGONISTS ABOLISH THE CELL DEATH FATE OF PRIMARY NEURONAL CULTURES EXPOSED TO EXCESSIVE GLUTAMATE, SERUM/POTASSIUM DEPRIVATION, HYPOGLYCEMIA AND CHEMICAL HYPOXIA. IN PARALLEL WITH THESE DETRIMENTAL EFFECTS, ALSO TROPHIC FUNCTIONS HAVE BEEN EXTENSIVELY DESCRIBED FOR EXTRACELLULAR PURINES (BOTH FOR NEURONAL AND NON-NEURONAL CELLS), BUT THESE MIGHT EITHER AGGRAVATE OR AMELIORATE THE NORMAL CELLULAR CONDITIONS. IN SUMMARY, EXTRACELLULAR ATP PLAYS A VERY COMPLEX ROLE NOT ONLY IN THE REPAIR, REMODELING AND SURVIVAL OCCURRING IN THE NERVOUS SYSTEM, BUT EVEN IN CELL DEATH AND THIS CAN OCCUR EITHER AFTER NORMAL DEVELOPMENTAL CONDITIONS, AFTER INJURY, OR ACUTE AND CHRONIC DISEASES. 2003 13 4309 39 MICRORNAS 29B AND 181A DOWN-REGULATE THE EXPRESSION OF THE NOREPINEPHRINE TRANSPORTER AND GLUCOCORTICOID RECEPTORS IN PC12 CELLS. MICRORNAS ARE SHORT NON-CODING RNAS THAT PROVIDE GLOBAL REGULATION OF GENE EXPRESSION AT THE POST-TRANSCRIPTIONAL LEVEL. SUCH REGULATION HAS BEEN FOUND TO PLAY A ROLE IN STRESS-INDUCED EPIGENETIC RESPONSES IN THE BRAIN. THE NOREPINEPHRINE TRANSPORTER (NET) AND GLUCOCORTICOID RECEPTORS ARE CLOSELY RELATED TO THE HOMEOSTATIC INTEGRATION AND REGULATION AFTER STRESS. OUR PREVIOUS STUDIES DEMONSTRATED THAT NET MRNA AND PROTEIN LEVELS IN RATS ARE REGULATED BY CHRONIC STRESS AND BY ADMINISTRATION OF CORTICOSTERONE, WHICH IS MEDIATED THROUGH GLUCOCORTICOID RECEPTORS. WHETHER MIRNAS ARE INTERMEDIARIES IN THE REGULATION OF THESE PROTEINS REMAINS TO BE ELUCIDATED. THIS STUDY WAS UNDERTAKEN TO DETERMINE POSSIBLE REGULATORY EFFECTS OF MIRNAS ON THE EXPRESSION OF NET AND GLUCOCORTICOID RECEPTORS IN THE NORADRENERGIC NEURONAL CELL LINE. USING COMPUTATIONAL TARGET PREDICTION, WE IDENTIFIED SEVERAL CANDIDATE MIRNAS POTENTIALLY TARGETING NET AND GLUCOCORTICOID RECEPTORS. WESTERN BLOT RESULTS SHOWED THAT OVER-EXPRESSION OF MIR-181A AND MIR-29B SIGNIFICANTLY REPRESSED PROTEIN LEVELS OF NET, WHICH IS ACCOMPANIED BY A REDUCED [(3) H] NOREPINEPHRINE UPTAKE, AND GLUCOCORTICOID RECEPTORS IN PC12 CELLS. LUCIFERASE REPORTER ASSAYS VERIFIED THAT BOTH MIR-181A AND MIR-29B BIND THE 3'UTR OF MRNA OF NET AND GLUCOCORTICOID RECEPTORS. FURTHERMORE, EXPOSURE OF PC12 CELLS TO CORTICOSTERONE MARKEDLY REDUCED THE ENDOGENOUS LEVELS OF MIR-29B, WHICH WAS NOT REVERSED BY THE APPLICATION OF GLUCOCORTICOID RECEPTOR ANTAGONIST MIFEPRISTONE. THESE OBSERVATIONS INDICATE THAT MIR-181A AND MIR-29B CAN FUNCTION AS THE NEGATIVE REGULATORS OF NET AND GLUCOCORTICOID RECEPTOR TRANSLATION IN VITRO. THIS REGULATORY EFFECT MAY BE RELATED TO STRESS-INDUCED UP-REGULATION OF THE NORADRENERGIC PHENOTYPE, A PHENOMENON OBSERVED IN STRESS MODELS AND DEPRESSIVE PATIENTS. THIS STUDY DEMONSTRATED THAT MIR-29B AND MIR-181A, TWO SHORT NON-CODING RNAS THAT PROVIDE GLOBAL REGULATION OF GENE EXPRESSION, MARKEDLY REPRESSED PROTEIN LEVELS OF NOREPINEPHRINE (NE) TRANSPORTER AND GLUCOCORTICOID RECEPTOR (GR), AS WELL AS NE UPTAKE BY BINDING THE 3'UTR OF THEIR MRNAS IN PC12 CELLS. ALSO, EXPOSURE OF CELLS TO CORTICOSTERONE SIGNIFICANTLY REDUCED MIR-29B LEVELS THROUGH A GR-INDEPENDENT WAY. 2016 14 5010 35 PEROXIDATION OF LINOLEIC, ARACHIDONIC AND OLEIC ACID IN RELATION TO THE INDUCTION OF OXIDATIVE DNA DAMAGE AND CYTOGENETIC EFFECTS. IN THE PRESENT STUDY, THE POSSIBLE ROLE OF THE POLYUNSATURATED FATTY ACIDS LINOLEIC AND ARACHIDONIC ACID IN THE CHEMICAL INDUCTION OF CARCINOGENESIS HAS BEEN INVESTIGATED. ANALYSIS OF 7,8-DIHYDRO-8-OXO-2'-DEOXYGUANOSINE (8-OXODG) LEVELS IN 2'-DEOXYGUANOSINE (DG) AND ISOLATED DNA HAS DEMONSTRATED THAT LINOLEIC AND ARACHIDONIC ACID ARE CAPABLE OF INDUCING THIS SPECIFIC GENOTOXIC DAMAGE. THIS EFFECT APPEARS TO BE RELATED TO THE DEGREE OF FATTY ACID UNSATURATION, SINCE IT WAS NOT INDUCED BY MONOUNSATURATED OLEIC ACID. ENZYMATIC PEROXIDATION OF LINOLEIC AND ARACHIDONIC ACID RESULTED IN A SIGNIFICANT INCREASE IN OXIDATIVE DNA DAMAGE. STUDIES ON THE INTERFERENCE OF RADICAL SCAVENGERS WITH THE INDUCTION OF 8-OXODG IN COMBINATION WITH ELECTRON SPIN RESONANCE SPECTROSCOPY DEMONSTRATED THAT THE SUPEROXIDE ANION WAS GENERATED DURING PEROXIDATION OF THESE FATTY ACIDS AND THAT SINGLET OXYGEN IS MOST LIKELY INVOLVED IN THE FORMATION OF OXIDATIVE DNA DAMAGE. THE LEVEL OF OXIDATIVE DAMAGE IN DG AND SINGLE-STRANDED DNA WAS HIGHER AS COMPARED TO THAT IN NATIVE DNA AFTER EQUIMOLAR TREATMENT. EXPOSURE OF HUMAN LYMPHOCYTES TO LINOLEIC OR ARACHIDONIC ACID DID NOT RESULT IN A SIGNIFICANT INCREASE IN LEVELS OF 8-OXODG. THIS MAY INDICATE THAT THE RATE OF INTRACELLULAR PEROXIDATION IS RELATIVELY LOW AND/OR THAT NUCLEAR DNA IN INTACT CELLS IS EFFECTIVELY PROTECTED AGAINST GENETIC DAMAGE INDUCED BY REACTIVE OXYGEN SPECIES. IT IS THEREFORE CONCLUDED THAT RELATIVELY SHORT PERIODS OF LINOLEIC OR ARACHIDONIC ACID ADMINISTRATION ARE NOT LIKELY TO IMPOSE A DIRECT GENOTOXIC RISK. IT CAN, HOWEVER, NOT BE EXCLUDED THAT CHRONIC EXPOSURE TO POLYUNSATURATED FATTY ACIDS INDUCES OXIDATIVE DNA DAMAGE OR IS RELATED TO CANCER RISK BY EPIGENETIC MECHANISMS, AS IS ALSO INDICATED BY THE OBSERVED CYTOTOXIC EFFECTS OF LINOLEIC AND ARACHIDONIC ACID. 1994 15 4683 35 NEW PERSPECTIVES ON FOLATE TRANSPORT IN RELATION TO ALCOHOLISM-INDUCED FOLATE MALABSORPTION--ASSOCIATION WITH EPIGENOME STABILITY AND CANCER DEVELOPMENT. FOLATES ARE MEMBERS OF THE B-CLASS OF VITAMINS, WHICH ARE REQUIRED FOR THE SYNTHESIS OF PURINES AND PYRIMIDINES, AND FOR THE METHYLATION OF ESSENTIAL BIOLOGICAL SUBSTANCES, INCLUDING PHOSPHOLIPIDS, DNA, AND NEUROTRANSMITTERS. FOLATES CANNOT BE SYNTHESIZED DE NOVO BY MAMMALS; HENCE, AN EFFICIENT INTESTINAL ABSORPTION PROCESS IS REQUIRED. INTESTINAL FOLATE TRANSPORT IS CARRIER-MEDIATED, PH-DEPENDENT AND ELECTRONEUTRAL, WITH SIMILAR AFFINITY FOR OXIDIZED AND REDUCED FOLIC ACID DERIVATIVES. THE VARIOUS TRANSPORTERS, I.E. REDUCED FOLATE CARRIER, PROTON-COUPLED FOLATE TRANSPORTER, FOLATE-BINDING PROTEIN, AND ORGANIC ANION TRANSPORTERS, ARE INVOLVED IN THE FOLATE TRANSPORT PROCESS IN VARIOUS TISSUES. ANY IMPAIRMENT IN UPTAKE OF FOLATE CAN LEAD TO A STATE OF FOLATE DEFICIENCY, THE MOST PREVALENT VITAMIN DEFICIENCY IN WORLD, AFFECTING 10% OF THE POPULATION IN THE USA. SUCH IMPAIRMENTS IN FOLATE TRANSPORT OCCUR IN A VARIETY OF CONDITIONS, INCLUDING CHRONIC USE OF ETHANOL, SOME INBORN HEREDITARY DISORDERS, AND CERTAIN DISEASES. AMONG THESE, ETHANOL INGESTION HAS BEEN THE MAJOR CONTRIBUTOR TO FOLATE DEFICIENCY. ETHANOL-ASSOCIATED FOLATE DEFICIENCY CAN DEVELOP BECAUSE OF DIETARY INADEQUACY, INTESTINAL MALABSORPTION, ALTERED HEPATOBILIARY METABOLISM, ENHANCED COLONIC METABOLISM, AND INCREASED RENAL EXCRETION. ETHANOL REDUCES THE INTESTINAL AND RENAL UPTAKE OF FOLATE BY ALTERING THE BINDING AND TRANSPORT KINETICS OF FOLATE TRANSPORT SYSTEMS. ALSO, ETHANOL REDUCES THE EXPRESSION OF FOLATE TRANSPORTERS IN BOTH INTESTINE AND KIDNEY, AND THIS MIGHT BE A CONTRIBUTING FACTOR FOR FOLATE MALABSORPTION, LEADING TO FOLATE DEFICIENCY. THE MAINTENANCE OF INTRACELLULAR FOLATE HOMEOSTASIS IS ESSENTIAL FOR THE ONE-CARBON TRANSFER REACTIONS NECESSARY FOR DNA SYNTHESIS AND BIOLOGICAL METHYLATION REACTIONS. DNA METHYLATION IS AN IMPORTANT EPIGENETIC DETERMINANT IN GENE EXPRESSION, IN THE MAINTENANCE OF DNA INTEGRITY AND STABILITY, IN CHROMOSOMAL MODIFICATIONS, AND IN THE DEVELOPMENT OF MUTATIONS. ETHANOL, A TOXIN THAT IS CONSUMED REGULARLY, HAS BEEN FOUND TO AFFECT THE METHYLATION OF DNA. IN ADDITION TO ITS EFFECT ON DNA METHYLATION DUE TO FOLATE DEFICIENCY, ETHANOL COULD DIRECTLY EXERT ITS EFFECT THROUGH ITS INTERACTION WITH ONE-CARBON METABOLISM, IMPAIRMENT OF METHYL GROUP SYNTHESIS, AND AFFECTING THE ENZYMES REGULATING THE SYNTHESIS OF S-ADENOSYLMETHIONINE, THE PRIMARY METHYL GROUP DONOR FOR MOST BIOLOGICAL METHYLATION REACTIONS. THUS, ETHANOL PLAYS AN IMPORTANT ROLE IN THE PATHOGENESIS OF SEVERAL DISEASES THROUGH ITS POTENTIAL ABILITY TO MODULATE THE METHYLATION OF BIOLOGICAL MOLECULES. THIS REVIEW DISCUSSES THE UNDERLYING MECHANISM OF FOLATE MALABSORPTION IN ALCOHOLISM, THE MECHANISM OF METHYLATION-ASSOCIATED SILENCING OF GENES, AND HOW THE INTERACTION BETWEEN ETHANOL AND FOLATE DEFICIENCY AFFECTS THE METHYLATION OF GENES, THEREBY MODULATING EPIGENOME STABILITY AND THE RISK OF CANCER. 2009 16 6456 28 THYMOSIN BETA4 PREVENTS OXIDATIVE STRESS, INFLAMMATION, AND FIBROSIS IN ETHANOL- AND LPS-INDUCED LIVER INJURY IN MICE. THYMOSIN BETA 4 (TBETA4), AN ACTIN-SEQUESTERING PROTEIN, IS INVOLVED IN TISSUE DEVELOPMENT AND REGENERATION. IT PREVENTS INFLAMMATION AND FIBROSIS IN SEVERAL TISSUES. WE INVESTIGATED THE ROLE OF TBETA4 IN CHRONIC ETHANOL- AND ACUTE LIPOPOLYSACCHARIDE- (LPS-) INDUCED MOUSE LIVER INJURY. C57BL/6 MICE WERE FED 5% ETHANOL IN LIQUID DIET FOR 4 WEEKS PLUS BINGE ETHANOL (5 G/KG, GAVAGE) WITH OR WITHOUT LPS (2 MG/KG, INTRAPERITONEAL) FOR 6 HOURS. TBETA4 (1 MG/KG, INTRAPERITONEAL) WAS ADMINISTERED FOR 1 WEEK. WE DEMONSTRATED THAT TBETA4 PREVENTED ETHANOL- AND LPS-MEDIATED INCREASE IN LIVER INJURY MARKERS AS WELL AS CHANGES IN LIVER PATHOLOGY. IT ALSO PREVENTED ETHANOL- AND LPS-MEDIATED INCREASE IN OXIDATIVE STRESS BY DECREASING ROS AND LIPID PEROXIDATION AND INCREASING THE ANTIOXIDANTS, REDUCED GLUTATHIONE AND MANGANESE-DEPENDENT SUPEROXIDE DISMUTASE. IT ALSO PREVENTED THE ACTIVATION OF NUCLEAR FACTOR KAPPA B BY BLOCKING THE PHOSPHORYLATION OF THE INHIBITORY PROTEIN, IKAPPAB, THEREBY PREVENTED PROINFLAMMATORY CYTOKINE PRODUCTION. MOREOVER, TBETA4 PREVENTED FIBROGENESIS BY SUPPRESSING THE EPIGENETIC REPRESSOR, METHYL-CPG-BINDING PROTEIN 2, THAT COORDINATELY REVERSED THE EXPRESSION OF PEROXISOME PROLIFERATOR-ACTIVATED RECEPTOR-GAMMA AND DOWNREGULATED FIBROGENIC GENES, PLATELET-DERIVED GROWTH FACTOR-BETA RECEPTOR, ALPHA-SMOOTH MUSCLE ACTIN, COLLAGEN 1, AND FIBRONECTIN, RESULTING IN REDUCED FIBROSIS. OUR DATA SUGGEST THAT TBETA4 HAS ANTIOXIDANT, ANTI-INFLAMMATORY, AND ANTIFIBROTIC POTENTIAL DURING ALCOHOLIC LIVER INJURY. 2018 17 3727 77 INHIBITION OF PANCREATIC ACINAR MITOCHONDRIAL THIAMIN PYROPHOSPHATE UPTAKE BY THE CIGARETTE SMOKE COMPONENT 4-(METHYLNITROSAMINO)-1-(3-PYRIDYL)-1-BUTANONE. THIAMIN IS ESSENTIAL FOR NORMAL METABOLISM IN PANCREATIC ACINAR CELLS (PAC) AND IS OBTAINED FROM THEIR MICROENVIRONMENT THROUGH SPECIFIC PLASMA-MEMBRANE TRANSPORTERS, CONVERTED TO THIAMIN PYROPHOSPHATE (TPP) IN THE CYTOPLASM, FOLLOWED BY UPTAKE OF TPP BY MITOCHONDRIA THROUGH THE MITOCHONDRIAL TPP (MTPP) TRANSPORTER (MTPPT; PRODUCT OF SLC25A19 GENE). TPP IS ESSENTIAL FOR NORMAL MITOCHONDRIAL FUNCTION. WE EXAMINED THE EFFECT OF LONG-TERM/CHRONIC EXPOSURE OF PAC IN VITRO (PANCREATIC ACINAR 266-6 CELLS) AND IN VIVO (WILD-TYPE OR TRANSGENIC MICE CARRYING THE SLC25A19 PROMOTER) OF THE CIGARETTE SMOKE TOXIN, 4-(METHYLNITROSAMINO)-1-(3-PYRIDYL)-1-BUTANONE (NNK), ON THE MTPP UPTAKE PROCESS. OUR IN VITRO AND IN VIVO FINDINGS DEMONSTRATE THAT NNK NEGATIVELY AFFECTS MTPP UPTAKE AND REDUCED EXPRESSION OF MTPPT PROTEIN, MTPPT MRNA, AND HETEROGENOUS NUCLEAR RNA, AS WELL AS SLC25A19 PROMOTER ACTIVITY. THE EFFECT OF NNK ON SLC25A19 TRANSCRIPTION WAS NEITHER MEDIATED BY CHANGES IN EXPRESSION OF TRANSCRIPTIONAL FACTOR NFY-1 (KNOWN TO DRIVE SLC25A19 TRANSCRIPTION), NOR DUE TO CHANGES IN METHYLATION PROFILE OF THE SLC25A19 PROMOTER. RATHER, IT APPEARS TO BE DUE TO CHANGES IN HISTONE MODIFICATIONS THAT INVOLVE SIGNIFICANT DECREASES IN HISTONE H3K4-TRIMETHYLATION AND H3K9-ACETYLATION (ACTIVATION MARKERS). THE EFFECT OF NNK ON MTPPT FUNCTION IS MEDIATED THROUGH THE NONNEURONAL ALPHA7-NICOTINIC ACETYLCHOLINE RECEPTOR (ALPHA7-NACHR), AS INDICATED BY BOTH IN VITRO (USING THE NACHR ANTAGONIST MECAMYLAMINE) AND IN VIVO (USING AN ALPHA7-NACHR(-/-) MOUSE MODEL) STUDIES. THESE FINDINGS DEMONSTRATE THAT CHRONIC EXPOSURE OF PAC TO NNK NEGATIVELY IMPACTS PAC MTPP UPTAKE. THIS EFFECT APPEARS TO BE EXERTED AT THE LEVEL OF SLC25A19 TRANSCRIPTION, INVOLVE EPIGENETIC MECHANISM(S), AND IS MEDIATED THROUGH THE ALPHA7-NACHR. 2016 18 2862 33 FRUCTOSE-MEDIATED EFFECTS ON GENE EXPRESSION AND EPIGENETIC MECHANISMS ASSOCIATED WITH NAFLD PATHOGENESIS. NONALCOHOLIC FATTY LIVER DISEASE (NAFLD) IS A CHRONIC, FREQUENTLY PROGRESSIVE CONDITION THAT DEVELOPS IN RESPONSE TO EXCESSIVE HEPATOCYTE FAT ACCUMULATION (I.E., STEATOSIS) IN THE ABSENCE OF SIGNIFICANT ALCOHOL CONSUMPTION. LIVER STEATOSIS DEVELOPS AS A RESULT OF IMBALANCED LIPID METABOLISM, DRIVEN LARGELY BY INCREASED RATES OF DE NOVO LIPOGENESIS AND HEPATIC FATTY ACID UPTAKE AND REDUCED FATTY ACID OXIDATION AND/OR DISPOSAL TO THE CIRCULATION. FRUCTOSE IS A NATURALLY OCCURRING SIMPLE SUGAR, WHICH IS MOST COMMONLY CONSUMED IN MODERN DIETS IN THE FORM OF SUCROSE, A DISACCHARIDE COMPRISED OF ONE MOLECULE OF FRUCTOSE COVALENTLY BONDED WITH ONE MOLECULE OF GLUCOSE. A NUMBER OF OBSERVATIONAL AND EXPERIMENTAL STUDIES HAVE DEMONSTRATED DETRIMENTAL EFFECTS OF DIETARY FRUCTOSE CONSUMPTION NOT ONLY ON DIVERSE METABOLIC OUTCOMES SUCH AS INSULIN RESISTANCE AND OBESITY, BUT ALSO ON HEPATIC STEATOSIS AND NAFLD-RELATED FIBROSIS. DESPITE THE COMPELLING EVIDENCE THAT EXCESSIVE FRUCTOSE CONSUMPTION IS ASSOCIATED WITH THE PRESENCE OF NAFLD AND MAY EVEN PROMOTE THE DEVELOPMENT AND PROGRESSION OF NAFLD TO MORE CLINICALLY SEVERE PHENOTYPES, THE MOLECULAR MECHANISMS BY WHICH FRUCTOSE ELICITS EFFECTS ON DYSREGULATED LIVER METABOLISM REMAIN UNCLEAR. EMERGING DATA SUGGEST THAT DIETARY FRUCTOSE MAY DIRECTLY ALTER THE EXPRESSION OF GENES INVOLVED IN LIPID METABOLISM, INCLUDING THOSE THAT INCREASE HEPATIC FAT ACCUMULATION OR REDUCE HEPATIC FAT REMOVAL. THE AIM OF THIS REVIEW IS TO SUMMARIZE THE CURRENT RESEARCH SUPPORTING A ROLE FOR DIETARY FRUCTOSE INTAKE IN THE MODULATION OF TRANSCRIPTOMIC AND EPIGENETIC MECHANISMS UNDERLYING THE PATHOGENESIS OF NAFLD. 2020 19 6441 20 THERAPEUTIC APPROACHES FOR NONALCOHOLIC FATTY LIVER DISEASE: ESTABLISHED TARGETS AND DRUGS. NONALCOHOLIC FATTY LIVER DISEASE (NAFLD), AS A MULTISYSTEMIC DISEASE, IS THE MOST PREVALENT CHRONIC LIVER DISEASE CHARACTERIZED BY EXTREMELY COMPLEX PATHOGENIC MECHANISMS AND MULTIFACTORIAL ETIOLOGY, WHICH OFTEN DEVELOPS AS A CONSEQUENCE OF OBESITY, METABOLIC SYNDROME. PATHOPHYSIOLOGICAL MECHANISMS INVOLVED IN THE DEVELOPMENT OF NAFLD INCLUDE DIET, OBESITY, INSULIN RESISTANCE (IR), GENETIC AND EPIGENETIC DETERMINANTS, INTESTINAL DYSBIOSIS, OXIDATIVE/NITROSATIVE STRESS, AUTOPHAGY DYSREGULATION, HEPATIC INFLAMMATION, GUT-LIVER AXIS, GUT MICROBES, IMPAIRED MITOCHONDRIAL METABOLISM AND REGULATION OF HEPATIC LIPID METABOLISM. SOME OF THE NEW DRUGS FOR THE TREATMENT OF NAFLD ARE INTRODUCED HERE. ALL OF THEM ACHIEVE THERAPEUTIC OBJECTIVES BY INTERFERING WITH CERTAIN PATHOPHYSIOLOGICAL PATHWAYS OF NAFLD, INCLUDING FIBROBLAST GROWTH FACTORS (FGF) ANALOGUES, PEROXISOME PROLIFERATOR-ACTIVATED RECEPTORS (PPARS) AGONISTS, GLUCAGON-LIKE PEPTIDE-1 (GLP-1) AGONISTS, G PROTEIN-COUPLED RECEPTORS (GPCRS), SODIUM-GLUCOSE COTRANSPORTER-2 INHIBITORS (SGLT-2I), FARNESOID X RECEPTOR (FXR), FATTY ACID SYNTHASE INHIBITOR (FASNI), ANTIOXIDANTS, ETC. THIS REVIEW DESCRIBES SOME PATHOPHYSIOLOGICAL MECHANISMS OF NAFLD AND ESTABLISHED TARGETS AND DRUGS. 2023 20 4044 18 MACROPHAGES IN OXIDATIVE STRESS AND MODELS TO EVALUATE THE ANTIOXIDANT FUNCTION OF DIETARY NATURAL COMPOUNDS. ANTIOXIDANT TESTING OF NATURAL PRODUCTS HAS ATTRACTED INCREASING INTEREST IN RECENT YEARS, MAINLY DUE TO THE FACT THAT AN ANTIOXIDANT-RICH DIET MIGHT PROVIDE HEALTH BENEFITS. ACTIVATED MACROPHAGES ARE A MAJOR SOURCE OF REACTIVE OXYGEN SPECIES, REACTIVE NITROGEN SPECIES, AND PEROXYNITRITE GENERATED THROUGH THE SO-CALLED RESPIRATORY BURST. CONSTITUTIVELY RELEASED PROINFLAMMATORY CYTOKINE, ESPECIALLY TUMOR NECROSIS FACTOR-ALPHA, TRIGGERS NUCLEAR FACTOR-KAPPAB, AND ACTIVATOR PROTEIN-1 TRANSLOCATION LEADING TO THE OVER PRODUCTION OF REACTIVE OXYGEN SPECIES AND REACTIVE NITROGEN SPECIES IN MACROPHAGES. ACTIVATION OF TRANSCRIPTION FACTORS IN THE LONG-LIVED TISSUE-RESIDENT MACROPHAGES AND/OR MONOCYTE-DERIVED MACROPHAGES, TRIGGER EPIGENETIC MODIFICATIONS LEADING TO THE PATHOGENESIS OF CHRONIC DISEASES. NUTRACEUTICALS INCLUDING LIPID RAFT STRUCTURE DISRUPTION AGENT, CHOLESTEROL DEPLETION AGENT, FARNESYLTRANSFERASE INHIBITOR, NUCLEAR FACTOR-KAPPAB BLOCKER (ALPHA,BETA-UNSATURATED CARBONYL COMPOUNDS), GLUCOCORTICOID RECEPTOR AGONIST, AND PEROXISOME PROLIFERATOR-ACTIVATED RECEPTOR-GAMMA AGONIST HAVE LONG BEEN USED TO INACTIVE MACROPHAGE. THE INHIBITION EFFECTS ON THE FORMATION OF NITRIC OXIDE, SUPEROXIDE, AND NITRITE PEROXIDE MAY BE RESPONSIBLE FOR THE ANTI-INFLAMMATORY FUNCTIONALITIES. ACTIVATED MACROPHAGE MODELS COULD BE USED TO IDENTIFY THE ACTIVE COMPONENTS FOR FUNCTIONAL DIETS DEVELOPMENT THROUGH A MULTIPLE TARGETS STRATEGY. 2017