1 1066 197 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 2 6166 33 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 3 5010 33 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 4 2772 38 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 5 4625 50 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 6 4683 46 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 7 4044 29 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 8 5074 28 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 9 313 22 ALCOHOL METABOLISM AND EPIGENETICS CHANGES. METABOLITES, INCLUDING THOSE GENERATED DURING ETHANOL METABOLISM, CAN IMPACT DISEASE STATES BY BINDING TO TRANSCRIPTION FACTORS AND/OR MODIFYING CHROMATIN STRUCTURE, THEREBY ALTERING GENE EXPRESSION PATTERNS. FOR EXAMPLE, THE ACTIVITIES OF ENZYMES INVOLVED IN EPIGENETIC MODIFICATIONS SUCH AS DNA AND HISTONE METHYLATION AND HISTONE ACETYLATION, ARE INFLUENCED BY THE LEVELS OF METABOLITES SUCH AS NICOTINAMIDE ADENINE DINUCLEOTIDE (NAD), ADENOSINE TRIPHOSPHATE (ATP), AND S-ADENOSYLMETHIONINE (SAM). CHRONIC ALCOHOL CONSUMPTION LEADS TO SIGNIFICANT REDUCTIONS IN SAM LEVELS, THEREBY CONTRIBUTING TO DNA HYPOMETHYLATION. SIMILARLY, ETHANOL METABOLISM ALTERS THE RATIO OF NAD+ TO REDUCED NAD (NADH) AND PROMOTES THE FORMATION OF REACTIVE OXYGEN SPECIES AND ACETATE, ALL OF WHICH IMPACT EPIGENETIC REGULATORY MECHANISMS. IN ADDITION TO ALTERED CARBOHYDRATE METABOLISM, INDUCTION OF CELL DEATH, AND CHANGES IN MITOCHONDRIAL PERMEABILITY TRANSITION, THESE METABOLISM-RELATED CHANGES CAN LEAD TO MODULATION OF EPIGENETIC REGULATION OF GENE EXPRESSION. UNDERSTANDING THE NATURE OF THESE EPIGENETIC CHANGES WILL HELP RESEARCHERS DESIGN NOVEL MEDICATIONS TO TREAT OR AT LEAST AMELIORATE ALCOHOL-INDUCED ORGAN DAMAGE. 2013 10 4214 60 METHIONINE METABOLISM IN YUCATAN MINIATURE SWINE. METHIONINE IS AN ESSENTIAL AMINO ACID WHICH WHEN NOT INCORPORATED INTO PROTEIN, CAN BE CONVERTED TO S-ADENOSYLMETHIONINE, THE UNIVERSAL METHYL DONOR IN OVER 200 TRANSMETHYLATION REACTIONS, WHICH INCLUDE CREATINE AND PHOSPHATIDYLCHOLINE (PC) SYNTHESIS, AS WELL AS DEOXYRIBONUCLEIC ACID (DNA) METHYLATION. FOLLOWING TRANSMETHYLATION, HOMOCYSTEINE IS FORMED, WHICH CAN BE CONVERTED TO CYSTEINE VIA TRANSSULFURATION OR REMETHYLATED TO METHIONINE BY RECEIVING A METHYL GROUP FROM FOLATE OR BETAINE. CHANGES TO METHYL GROUP AVAILABILITY IN UTERO CAN LEAD TO PERMANENT CHANGES IN EPIGENETIC PATTERNS OF DNA METHYLATION, WHICH HAS BEEN IMPLICATED IN "FETAL PROGRAMMING", A PHENOMENON ASSOCIATED WITH POOR NUTRITION DURING FETAL DEVELOPMENT THAT RESULTS IN LOW BIRTH WEIGHT AND DISEASE IN LATER LIFE. IT HAS BEEN SHOWN THAT PROGRAMMING CAN ALSO OCCUR IN THE NEONATE. OUR GLOBAL OBJECTIVE WAS TO UNDERSTAND HOW THE VARIABILITY OF NUTRIENTS INVOLVED IN METHIONINE METABOLISM CAN AFFECT METHIONINE AND METHYL GROUP AVAILABILITY. WE HYPOTHESIZE THAT NUTRIENTS THAT CONVERGE ON METHIONINE METABOLISM CAN AFFECT METHIONINE AVAILABILITY FOR ITS VARIOUS FUNCTIONS. IN THIS THESIS, WE USED INTRAUTERINE GROWTH RESTRICTED (IUGR) PIGLETS TO INVESTIGATE WHETHER A GLOBAL NUTRITIONAL INSULT IN UTERO CAN LEAD TO A PERTURBED METHIONINE METABOLISM. OUR RESULTS DEMONSTRATE THAT IUGR PIGLETS HAVE A LOWER CAPACITY TO DISPOSE OF HOMOCYSTEINE VIA BOTH TRANSSULFURATION AND REMETHYLATION PATHWAYS, AS WELL AS A LOWER INCORPORATION OF METHYL GROUPS INTO PC. THE SECOND OBJECTIVE OF THIS THESIS WAS TO DETERMINE WHETHER VARIATION IN METHIONINE SUPPLY AND DEMAND CAN AFFECT METHIONINE AVAILABILITY. WE DEMONSTRATED THAT STIMULATING EITHER ACUTE OR CHRONIC CREATINE SYNTHESIS LEADS TO LOWER METHYL INCORPORATION INTO PROTEIN AND PC IN PIGS. FURTHERMORE, WHEN METHIONINE IS LIMITING, SUPPLEMENTATION WITH EITHER FOLATE OR BETAINE LEADS TO HIGHER METHIONINE AVAILABILITY FOR PROTEIN SYNTHESIS. FINALLY, BECAUSE CREATINE IS INCREASINGLY BEING UTILIZED AS AN ERGOGENIC AND NEUROPROTECTIVE SUPPLEMENT, WE WANTED TO DETERMINE WHETHER PROVISION OF THE CREATINE PRECURSOR, GUANIDINOACETATE (GAA), COULD EFFECTIVELY INCREASE TISSUE CREATINE STORES. WE SHOWED THAT 2.5 WEEKS OF SUPPLEMENTATION WITH GAA IS MORE EFFECTIVE THAN CREATINE AT INCREASING HEPATIC AND MUSCLE CREATINE STORES. THE RESULTS OF THIS THESIS DEMONSTRATE THAT THE PRESENCE OF IUGR, AN INCREASED DEMAND FOR CREATINE SYNTHESIS, OR THE SUPPLEMENTATION WITH REMETHYLATION NUTRIENTS CAN EACH AFFECT METHIONINE AVAILABILITY; ALL ARE IMPORTANT WHEN CONSIDERING NEONATAL NUTRIENT REQUIREMENTS. FURTHERMORE, ALTHOUGH GAA IS EFFECTIVE AT INCREASING LEVELS OF TISSUE CREATINE, HIGHER GAA METHYLATION CAN LIMIT METHIONINE AVAILABILITY FOR GROWTH AND SYNTHESIS OF PC. 2016 11 4788 44 NUTRITION, EPIGENETICS, AND METABOLIC SYNDROME. SIGNIFICANCE: EPIDEMIOLOGICAL AND ANIMAL STUDIES HAVE DEMONSTRATED A CLOSE LINK BETWEEN MATERNAL NUTRITION AND CHRONIC METABOLIC DISEASE IN CHILDREN AND ADULTS. COMPELLING EXPERIMENTAL RESULTS ALSO INDICATE THAT ADVERSE EFFECTS OF INTRAUTERINE GROWTH RESTRICTION ON OFFSPRING CAN BE CARRIED FORWARD TO SUBSEQUENT GENERATIONS THROUGH COVALENT MODIFICATIONS OF DNA AND CORE HISTONES. RECENT ADVANCES: DNA METHYLATION IS CATALYZED BY S-ADENOSYLMETHIONINE-DEPENDENT DNA METHYLTRANSFERASES. METHYLATION, DEMETHYLATION, ACETYLATION, AND DEACETYLATION OF HISTONE PROTEINS ARE PERFORMED BY HISTONE METHYLTRANSFERASE, HISTONE DEMETHYLASE, HISTONE ACETYLTRANSFERASE, AND HISTONE DEACETYLTRANSFERASE, RESPECTIVELY. HISTONE ACTIVITIES ARE ALSO INFLUENCED BY PHOSPHORYLATION, UBIQUITINATION, ADP-RIBOSYLATION, SUMOYLATION, AND GLYCOSYLATION. METABOLISM OF AMINO ACIDS (GLYCINE, HISTIDINE, METHIONINE, AND SERINE) AND VITAMINS (B6, B12, AND FOLATE) PLAYS A KEY ROLE IN PROVISION OF METHYL DONORS FOR DNA AND PROTEIN METHYLATION. CRITICAL ISSUES: DISRUPTION OF EPIGENETIC MECHANISMS CAN RESULT IN OXIDATIVE STRESS, OBESITY, INSULIN RESISTANCE, DIABETES, AND VASCULAR DYSFUNCTION IN ANIMALS AND HUMANS. DESPITE A RECOGNIZED ROLE FOR EPIGENETICS IN FETAL PROGRAMMING OF METABOLIC SYNDROME, RESEARCH ON THERAPIES IS STILL IN ITS INFANCY. POSSIBLE INTERVENTIONS INCLUDE: 1) INHIBITION OF DNA METHYLATION, HISTONE DEACETYLATION, AND MICRORNA EXPRESSION; 2) TARGETING EPIGENETICALLY DISTURBED METABOLIC PATHWAYS; AND 3) DIETARY SUPPLEMENTATION WITH FUNCTIONAL AMINO ACIDS, VITAMINS, AND PHYTOCHEMICALS. FUTURE DIRECTIONS: MUCH WORK IS NEEDED WITH ANIMAL MODELS TO UNDERSTAND THE BASIC MECHANISMS RESPONSIBLE FOR THE ROLES OF SPECIFIC NUTRIENTS IN FETAL AND NEONATAL PROGRAMMING. SUCH NEW KNOWLEDGE IS CRUCIAL TO DESIGN EFFECTIVE THERAPEUTIC STRATEGIES FOR PREVENTING AND TREATING METABOLIC ABNORMALITIES IN OFFSPRING BORN TO MOTHERS WITH A PREVIOUS EXPERIENCE OF MALNUTRITION. 2012 12 593 35 BET PROTEIN INHIBITION REGULATES CYTOKINE PRODUCTION AND PROMOTES NEUROPROTECTION AFTER SPINAL CORD INJURY. BACKGROUND: SPINAL CORD INJURY (SCI) USUALLY CAUSES A DEVASTATING LIFELONG DISABILITY FOR PATIENTS. AFTER A TRAUMATIC LESION, DISRUPTION OF THE BLOOD-SPINAL CORD BARRIER INDUCES THE INFILTRATION OF MACROPHAGES INTO THE LESION SITE AND THE ACTIVATION OF RESIDENT GLIAL CELLS, WHICH RELEASE CYTOKINES AND CHEMOKINES. THESE EVENTS RESULT IN A PERSISTENT INFLAMMATION, WHICH HAS BOTH DETRIMENTAL AND BENEFICIAL EFFECTS, BUT EVENTUALLY LIMITS FUNCTIONAL RECOVERY AND CONTRIBUTES TO THE APPEARANCE OF NEUROPATHIC PAIN. BROMODOMAIN AND EXTRA-TERMINAL DOMAIN (BET) PROTEINS ARE EPIGENETIC READERS THAT REGULATE THE EXPRESSION OF INFLAMMATORY GENES BY INTERACTING WITH ACETYLATED LYSINE RESIDUES. WHILE BET INHIBITORS ARE A PROMISING THERAPEUTIC STRATEGY FOR CANCER, LITTLE IS KNOWN ABOUT THEIR IMPLICATION AFTER SCI. THUS, THE CURRENT STUDY WAS AIMED TO INVESTIGATE THE ANTI-INFLAMMATORY ROLE OF BET INHIBITORS IN THIS PATHOLOGIC CONDITION. METHODS: WE EVALUATED THE EFFECTIVENESS OF THE BET INHIBITOR JQ1 TO MODIFY MACROPHAGE REACTIVITY IN VITRO AND TO MODULATE INFLAMMATION IN A SCI MICE MODEL. WE ANALYZED THE EFFECTS OF BET INHIBITION IN PRO-INFLAMMATORY AND ANTI-INFLAMMATORY CYTOKINE PRODUCTION IN VITRO AND IN VIVO. WE DETERMINED THE EFFECTIVENESS OF BET INHIBITION IN TISSUE SPARING, INFLAMMATION, NEURONAL PROTECTION, AND BEHAVIORAL OUTCOME AFTER SCI. RESULTS: WE HAVE FOUND THAT THE BET INHIBITOR JQ1 REDUCED THE LEVELS OF PRO-INFLAMMATORY MEDIATORS AND INCREASED THE EXPRESSION OF ANTI-INFLAMMATORY CYTOKINES. A PROLONGED TREATMENT WITH JQ1 ALSO DECREASED REACTIVITY OF MICROGLIA/MACROPHAGES, ENHANCED NEUROPROTECTION AND FUNCTIONAL RECOVERY, AND ACUTELY REDUCED NEUROPATHIC PAIN AFTER SCI. CONCLUSIONS: BET PROTEIN INHIBITION IS AN EFFECTIVE TREATMENT TO REGULATE CYTOKINE PRODUCTION AND PROMOTE NEUROPROTECTION AFTER SCI. THESE NOVEL RESULTS DEMONSTRATE FOR THE FIRST TIME THAT TARGETING BET PROTEINS IS AN ENCOURAGING APPROACH FOR SCI REPAIR AND A POTENTIAL STRATEGY TO TREAT OTHER INFLAMMATORY PATHOLOGIES. 2019 13 3881 44 KETOGENIC DIETS AND THE NERVOUS SYSTEM: A SCOPING REVIEW OF NEUROLOGICAL OUTCOMES FROM NUTRITIONAL KETOSIS IN ANIMAL STUDIES. OBJECTIVES: KETOGENIC DIETS HAVE REPORTED EFFICACY FOR NEUROLOGICAL DYSFUNCTIONS; HOWEVER, THERE ARE LIMITED PUBLISHED HUMAN CLINICAL TRIALS ELUCIDATING THE MECHANISMS BY WHICH NUTRITIONAL KETOSIS PRODUCES THERAPEUTIC EFFECTS. THE PURPOSE OF THIS PRESENT STUDY WAS TO INVESTIGATE ANIMAL MODELS THAT REPORT VARIATIONS IN NERVOUS SYSTEM FUNCTION BY CHANGING FROM A STANDARD ANIMAL DIET TO A KETOGENIC DIET, SYNTHESISE THESE INTO BROAD THEMES, AND COMPARE THESE WITH MECHANISMS REPORTED AS TARGETS IN PAIN NEUROSCIENCE TO INFORM HUMAN CHRONIC PAIN TRIALS. METHODS: AN ELECTRONIC SEARCH OF SEVEN DATABASES WAS CONDUCTED IN JULY 2020. TWO INDEPENDENT REVIEWERS SCREENED STUDIES FOR ELIGIBILITY, AND DESCRIPTIVE OUTCOMES RELATING TO NERVOUS SYSTEM FUNCTION WERE EXTRACTED FOR A THEMATIC ANALYSIS, THEN SYNTHESISED INTO BROAD THEMES. RESULTS: IN TOTAL, 170 STUDIES FROM EIGHTEEN DIFFERENT DISEASE MODELS WERE IDENTIFIED AND GROUPED INTO FOURTEEN BROAD THEMES: ALTERATIONS IN CELLULAR ENERGETICS AND METABOLISM, BIOCHEMICAL, CORTICAL EXCITABILITY, EPIGENETIC REGULATION, MITOCHONDRIAL FUNCTION, NEUROINFLAMMATION, NEUROPLASTICITY, NEUROPROTECTION, NEUROTRANSMITTER FUNCTION, NOCICEPTION, REDOX BALANCE, SIGNALLING PATHWAYS, SYNAPTIC TRANSMISSION AND VASCULAR SUPPLY. DISCUSSION: THE MECHANISMS PRESENTED CENTRED AROUND THE REDUCTION OF INFLAMMATION AND OXIDATIVE STRESS AS WELL AS A REDUCTION IN NERVOUS SYSTEM EXCITABILITY. GIVEN THE MULTIPLE POTENTIAL MECHANISMS PRESENTED, IT IS LIKELY THAT MANY OF THESE ARE INVOLVED SYNERGISTICALLY AND UNDERGO ADAPTIVE PROCESSES WITHIN THE HUMAN BODY, AND CONTROLLED ANIMAL MODELS THAT LIMIT THE INVESTIGATION TO A PARTICULAR PATHWAY IN ISOLATION MAY REACH DIFFERING CONCLUSIONS. ATTENTION IS REQUIRED WHEN TRANSLATING THIS INFORMATION TO HUMAN CHRONIC PAIN POPULATIONS OWING TO THE LIMITATIONS OUTLINED FROM THE ANIMAL RESEARCH. 2022 14 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 15 4398 38 MODULATION OF DNA METHYLTRANSFERASE PROFILE BY METHYL DONOR STARVATION FOLLOWED BY GAMMA IRRADIATION. DNA METHYLATION IS AN IMPORTANT EPIGENETIC MECHANISM OF TRANSCRIPTIONAL CONTROL, WHICH PLAYS AN ESSENTIAL ROLE IN MAINTAINING CELLULAR FUNCTION. ROLE OF ONE-CARBON TRANSFER AGENTS/METHYL DONORS NAMELY FOLATE, CHOLINE AND METHIONINE IN DNA METHYLATION HAS BEEN THE SUBJECT OF EXTENSIVE INVESTIGATION. THE METHYLATION PATTERN OF DNA IS ESTABLISHED DURING EMBRYOGENESIS BY DNA METHYLTRANSFERASE 3 (DNMT3) AND IS SUBSEQUENTLY MAINTAINED BY MAINTENANCE METHYLATION ACTIVITY OF THE ENZYME DNA METHYLTRANSFERASE 1 (DNMT1). IONIZING RADIATION IS KNOWN TO EXTENSIVELY DAMAGE THE DNA. SUFFICIENT DIETARY AVAILABILITY OF METHYL DONORS IS KNOWN TO CONTRIBUTE TOWARDS ONE-CARBON TRANSFER MEDIATED REPAIR OF DAMAGED DNA WHERE FOLATE IS INVOLVED IN NUCLEOTIDE BASE SYNTHESIS. IN THE PRESENT STUDY, MODIFICATION IN ACTIVITIES OF DNMT1 AND DNMT3 BY METHYL DONOR STARVATION FOLLOWED BY GAMMA-IRRADIATION WAS OBSERVED. ASSAYS WERE BASED ON THE CATALYTIC TRANSFER OF (3)H-METHYL GROUPS FROM S-ADENOSYL-L: -METHIONINE TO A DNA SUBSTRATE. EXPERIMENTS SHOWED A DOSE AND METHYL DONORS STARVATION DEPENDENT ATTENUATION IN DNMT1 ACTIVITY. ATTENUATION OF DNMT1 ACTIVITY WAS MOST SIGNIFICANT FOR DIET DEPRIVED OF ALL THE THREE-METHYL DONORS. NO SIGNIFICANT CHANGE IN NUCLEAR OR CYTOPLASMIC DNMT3 ACTIVITY WAS OBSERVED WHEN EITHER OR ALL THE THREE POSSIBLE SOURCE OF DIETARY METHYL GROUP SUPPLY WERE REMOVED. IONIZING RADIATION AND METHYL DONOR DEFICIENCY WERE OBSERVED TO ACT SYNERGISTICALLY TOWARDS INHIBITING DNMT1 ACTIVITY. PRESENT RESULTS SUGGESTED POSSIBILITY OF INTERACTION AMONG FOLATE, METHIONINE AND CHOLINE DEFICIENCY TO POTENTIATE SYMPTOMS OF IONIZING RADIATION STRESS. THESE ENZYMATIC MODIFICATIONS MIGHT CONTRIBUTE TO ALTERED DNA METHYLATION AFTER CHRONIC FEEDING OF METHYL DONOR FREE DIETS FOLLOWED BY GAMMA IRRADIATION. THESE RESULTS SUGGESTED THAT DIETARY AVAILABILITY OF METHYL DONORS AND GAMMA-RADIATION STRESS MIGHT SIGNIFICANTLY ALTER THE DNMT1 PROFILE. 2007 16 169 34 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 17 2950 21 GENETIC AND EPIGENETIC DAMAGE INDUCED BY REACTIVE NITROGEN SPECIES: IMPLICATIONS IN CARCINOGENESIS. CHRONIC INFECTION AND INFLAMMATION ARE RECOGNIZED RISK FACTORS FOR HUMAN CANCER AT VARIOUS SITES. INFECTION AND INFLAMMATION CAN ACTIVATE AND INDUCE A VARIETY OF OXIDANT-GENERATING ENZYMES, INCLUDING NADPH OXIDASE AND INDUCIBLE NITRIC OXIDE SYNTHASE. REACTIVE OXYGEN AND NITROGEN SPECIES PRODUCED BY SUCH ENZYMES REACT WITH EACH OTHER TO GENERATE NEW AND MORE POTENT REACTIVE SPECIES. THESE OXIDANTS NOT ONLY CAN DAMAGE DNA AND INDUCE MUTATIONS, BUT ALSO CAN ACTIVATE ONCOGENE PRODUCTS AND/OR INACTIVATE TUMOR-SUPPRESSOR PROTEINS, THUS CONTRIBUTING TO MOST PROCESSES OF CARCINOGENESIS. APPROPRIATE TREATMENT OF INFLAMMATION SHOULD BE FURTHER EXPLORED FOR CHEMOPREVENTION OF HUMAN CANCERS, ESPECIALLY THOSE ASSOCIATED WITH CHRONIC INFLAMMATION. 2003 18 6721 32 VITAMIN D RECEPTOR AGONISTS' ANTI-INFLAMMATORY PROPERTIES. ONE CENTURY AFTER ITS DISCOVERY, VITAMIN D HAS BEEN SHOWN TO BE, IN FACT, A PLEIOTROPIC STEROID HORMONE, WHICH, BESIDES REGULATION OF CALCIUM HOMEOSTASIS AND BONE TURNOVER, HAS ANTIPROLIFERATIVE, PRODIFFERENTIATION, ANTIBACTERIAL, IMMUNOMODULATORY, AND ANTI-INFLAMMATORY PROPERTIES IN VARIOUS CELLS AND TISSUES. D HORMONE (1ALPHA,25(OH)2 D), REGULATED IN AN ENDOCRINE, AUTOCRINE, AND PARACRINE MANNER, MUST BE BOUND TO THE SPECIFIC NUCLEAR VITAMIN D RECEPTOR (VDR) TO EXERT EPIGENETIC AND GENETIC EFFECTS, ACTING AS A CONNECTION BETWEEN EXTRACELLULAR STIMULI AND GENOMIC RESPONSES OF THE CELLS. SINCE ONLY HIGH DOSES OF HORMONE, PROVOKING HYPERCALCEMIA, CAN ACHIEVE IMMUNOMODULATORY EFFECTS, MORE THAN 3000 VDR AGONISTS HAVE BEEN SYNTHESIZED. NUMEROUS EXPERIMENTAL TRIALS HAVE BEEN PERFORMED IN ANIMAL MODELS, EVIDENCING THE PREVENTIVE AND THERAPEUTIC POTENTIAL OF VDR AGONISTS FOR CHRONIC INFLAMMATORY DISEASES AND CANCER. CONSIDERING THE SELECTIVE ANTI-INFLAMMATORY EFFECTS OF VDR AGONISTS COMPARED TO GLUCOCORTICOIDS, SPARING MICROBICIDAL FUNCTIONS, THE FEAR OF HYPERCALCEMIA AS THEIR ONLY FREQUENT SIDE EFFECT BECOMES A QUESTIONABLE REASON FOR THE LACK OF CLINICAL STUDIES. 2014 19 375 27 AN ENERGETIC VIEW OF STRESS: FOCUS ON MITOCHONDRIA. ENERGY IS REQUIRED TO SUSTAIN LIFE AND ENABLE STRESS ADAPTATION. AT THE CELLULAR LEVEL, ENERGY IS LARGELY DERIVED FROM MITOCHONDRIA - UNIQUE MULTIFUNCTIONAL ORGANELLES WITH THEIR OWN GENOME. FOUR MAIN ELEMENTS CONNECT MITOCHONDRIA TO STRESS: (1) ENERGY IS REQUIRED AT THE MOLECULAR, (EPI)GENETIC, CELLULAR, ORGANELLAR, AND SYSTEMIC LEVELS TO SUSTAIN COMPONENTS OF STRESS RESPONSES; (2) GLUCOCORTICOIDS AND OTHER STEROID HORMONES ARE PRODUCED AND METABOLIZED BY MITOCHONDRIA; (3) RECIPROCALLY, MITOCHONDRIA RESPOND TO NEUROENDOCRINE AND METABOLIC STRESS MEDIATORS; AND (4) EXPERIMENTALLY MANIPULATING MITOCHONDRIAL FUNCTIONS ALTERS PHYSIOLOGICAL AND BEHAVIORAL RESPONSES TO PSYCHOLOGICAL STRESS. THUS, MITOCHONDRIA ARE ENDOCRINE ORGANELLES THAT PROVIDE BOTH THE ENERGY AND SIGNALS THAT ENABLE AND DIRECT STRESS ADAPTATION. NEURAL CIRCUITS REGULATING SOCIAL BEHAVIOR - AS WELL AS PSYCHOPATHOLOGICAL PROCESSES - ARE ALSO INFLUENCED BY MITOCHONDRIAL ENERGETICS. AN INTEGRATIVE VIEW OF STRESS AS AN ENERGY-DRIVEN PROCESS OPENS NEW OPPORTUNITIES TO STUDY MECHANISMS OF ADAPTATION AND REGULATION ACROSS THE LIFESPAN. 2018 20 4348 45 MIR-146A DYSREGULATES ENERGY METABOLISM DURING NEUROINFLAMMATION. ALZHEIMER'S DISEASE (AD) AND OTHER NEURODEGENERATIVE DISEASES ARE CHARACTERIZED BY CHRONIC NEUROINFLAMMATION AND A REDUCTION IN BRAIN ENERGY METABOLISM. AN IMPORTANT ROLE HAS EMERGED FOR SMALL, NON-CODING RNA MOLECULES KNOWN AS MICRORNAS (MIRNAS) IN THE PATHOPHYSIOLOGY OF MANY NEURODEGENERATIVE DISORDERS. AS EPIGENETIC REGULATORS, MIRNAS POSSESS THE CAPACITY TO REGULATE AND FINE TUNE PROTEIN PRODUCTION BY INHIBITING TRANSLATION. SEVERAL MIRNAS, WHICH INCLUDE MIR-146A, ARE ELEVATED IN THE BRAIN, CSF, AND PLASMA OF AD PATIENTS. MIR-146A PARTICIPATES IN PATHWAYS THAT REGULATE IMMUNE ACTIVATION AND HAS SEVERAL MRNA TARGETS WHICH ENCODE FOR PROTEINS INVOLVED IN CELLULAR ENERGY METABOLISM. AN ADDITIONAL ROLE FOR EXTRACELLULAR VESICLES (EVS) HAS ALSO EMERGED IN THE PROGRESSION AD, AS EVS CAN TRANSFER FUNCTIONALLY ACTIVE PROTEINS AND RNAS FROM DISEASED TO HEALTHY CELLS. IN THE CURRENT STUDY, WE EXPOSED VARIOUS CELL TYPES PRESENT WITHIN THE CNS TO IMMUNOMODULATORY MOLECULES AND OBSERVED SIGNIFICANT UPREGULATION OF MIR-146A EXPRESSION, BOTH WITHIN CELLS AND WITHIN THEIR SECRETED EVS. FURTHER, WE ASSESSED THE EFFECTS OF MIR-146A OVEREXPRESSION ON BIOENERGETIC FUNCTION IN PRIMARY RAT GLIAL CELLS AND FOUND SIGNIFICANT REDUCTIONS IN OXIDATIVE PHOSPHORYLATION AND GLYCOLYSIS. LASTLY, WE CORRELATED MIR-146A EXPRESSION LEVELS WITHIN VARIOUS REGIONS OF THE AD BRAIN TO DISEASE STAGING AND FOUND SIGNIFICANT, POSITIVE CORRELATIONS. THESE NOVEL RESULTS DEMONSTRATE THAT THE MODULATION OF MIR-146A IN RESPONSE TO NEUROINFLAMMATORY STIMULI MAY MEDIATE THE LOSS OF MITOCHONDRIAL INTEGRITY AND FUNCTION IN CELLS, THEREBY CONTRIBUTING TO THE PROGRESSION OF BETA-AMYLOID AND TAU PATHOLOGY IN THE AD BRAIN. MULTIPLE INFLAMMATORY STIMULI CAN UPREGULATE MIRNA-146A EXPRESSION WITHIN NEURONS, MIXED GLIAL CELLS, AND BRAIN ENDOTHELIAL CELLS, WHICH IS EITHER RETAINED WITHIN THESE CELLS OR RELEASED FROM THEM AS EXTRACELLULAR VESICLE CARGO. THE UPREGULATION OF MIR-146A DISRUPTS CELLULAR BIOENERGETICS IN MIXED GLIAL CELLS. THIS MECHANISM MAY PLAY A CRITICAL ROLE IN THE NEUROINFLAMMATORY RESPONSE OBSERVED DURING ALZHEIMER'S DISEASE. 2022