1 3115 180 GEROMETABOLITES: THE PSEUDOHYPOXIC AGING SIDE OF CANCER ONCOMETABOLITES. ONCOMETABOLITES ARE DEFINED AS SMALL-MOLECULE COMPONENTS (OR ENANTIOMERS) OF NORMAL METABOLISM WHOSE ACCUMULATION CAUSES SIGNALING DYSREGULATION TO ESTABLISH A MILIEU THAT INITIATES CARCINOGENESIS. IN A SIMILAR MANNER, WE PROPOSE THE TERM "GEROMETABOLITES" TO REFER TO SMALL-MOLECULE COMPONENTS OF NORMAL METABOLISM WHOSE DEPLETION CAUSES SIGNALING DYSREGULATION TO ESTABLISH A MILIEU THAT DRIVES AGING. IN AN INVESTIGATION OF THE PATHOGENIC ACTIVITIES OF THE CURRENTLY RECOGNIZED ONCOMETABOLITES R(-)-2-HYDROXYGLUTARATE (2-HG), FUMARATE, AND SUCCINATE, WHICH ACCUMULATE DUE TO MUTATIONS IN ISOCITRATE DEHYDROGENASES (IDH), FUMARATE HYDRATASE (FH), AND SUCCINATE DEHYDROGENASE (SDH), RESPECTIVELY, WE ILLUSTRATE THE FACT THAT METABOLIC PSEUDOHYPOXIA, THE ACCUMULATION OF HYPOXIA-INDUCIBLE FACTOR (HIFALPHA) UNDER NORMOXIC CONDITIONS, AND THE SUBSEQUENT WARBURG-LIKE REPROGRAMMING THAT SHIFTS GLUCOSE METABOLISM FROM THE OXIDATIVE PATHWAY TO AEROBIC GLYCOLYSIS ARE THE SAME MECHANISMS THROUGH WHICH THE DECLINE OF THE "GEROMETABOLITE" NICOTINAMIDE ADENINE DINUCLEOTIDE (NAD)(+) REVERSIBLY DISRUPTS NUCLEAR-MITOCHONDRIAL COMMUNICATION AND CONTRIBUTES TO THE DECLINE IN MITOCHONDRIAL FUNCTION WITH AGE. FROM AN EVOLUTIONARY PERSPECTIVE, IT IS REASONABLE TO VIEW NAD(+)-DRIVEN MITOCHONDRIAL HOMEOSTASIS AS A CONSERVED RESPONSE TO CHANGES IN ENERGY SUPPLIES AND OXYGEN LEVELS. SIMILARLY, THE NATURAL ABILITY OF 2-HG TO SIGNIFICANTLY ALTER EPIGENETICS MIGHT REFLECT AN EVOLUTIONARILY ANCIENT ROLE OF CERTAIN METABOLITES TO SIGNAL FOR ELEVATED GLUTAMINE/GLUTAMATE METABOLISM AND/OR OXYGEN DEFICIENCY. HOWEVER, WHEN CHRONICALLY ALTERED, THESE RESPONSES BECOME CONSERVED CAUSES OF AGING AND CANCER. BECAUSE HIFALPHA-DRIVEN PSEUDOHYPOXIA MIGHT DRIVE THE OVERPRODUCTION OF 2-HG, THE INTRIGUING POSSIBILITY EXISTS THAT THE DECLINE OF GEROMETABOLITES SUCH AS NAD(+) COULD PROMOTE THE CHRONIC ACCUMULATION OF ONCOMETABOLITES IN NORMAL CELLS DURING AGING. IF THE SOLE ACTIVATION OF A WARBURG-LIKE METABOLIC REPROGRAMMING IN NORMAL TISSUES MIGHT BE ABLE TO SIGNIFICANTLY INCREASE THE ENDOGENOUS PRODUCTION OF BONA FIDE ETIOLOGICAL DETERMINANTS IN CANCER, SUCH AS ONCOMETABOLITES, THIS UNDESIRABLE TRADE-OFF BETWEEN MITOCHONDRIAL DYSFUNCTION AND ACTIVATION OF ONCOMETABOLITES PRODUCTION MIGHT THEN PAVE THE WAY FOR THE EPIGENETIC INITIATION OF CARCINOGENESIS IN A STRICTLY METABOLIC-DEPENDENT MANNER. PERHAPS IT IS TIME TO DEFINITELY ADOPT THE VIEW THAT AGING AND AGING DISEASES INCLUDING CANCER ARE GOVERNED BY A PIVOTAL REGULATORY ROLE OF METABOLIC REPROGRAMMING IN CELL FATE DECISIONS. 2014 2 6166 38 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 4197 38 METABOLIC PROFILES IN OVINE CAROTID ARTERIES WITH DEVELOPMENTAL MATURATION AND LONG-TERM HYPOXIA. BACKGROUND: LONG-TERM HYPOXIA (LTH) IS AN IMPORTANT STRESSOR RELATED TO HEALTH AND DISEASE DURING DEVELOPMENT. AT DIFFERENT TIME POINTS FROM FETUS TO ADULT, WE ARE EXPOSED TO HYPOXIC STRESS BECAUSE OF PLACENTAL INSUFFICIENCY, HIGH-ALTITUDE RESIDENCE, SMOKING, CHRONIC ANEMIA, PULMONARY, AND HEART DISORDERS, AS WELL AS CANCERS. INTRAUTERINE HYPOXIA CAN LEAD TO FETAL GROWTH RESTRICTION AND LONG-TERM SEQUELAE SUCH AS COGNITIVE IMPAIRMENTS, HYPERTENSION, CARDIOVASCULAR DISORDERS, DIABETES, AND SCHIZOPHRENIA. SIMILARLY, PROLONGED HYPOXIC EXPOSURE DURING ADULT LIFE CAN LEAD TO ACUTE MOUNTAIN SICKNESS, CHRONIC FATIGUE, CHRONIC HEADACHE, COGNITIVE IMPAIRMENT, ACUTE CEREBRAL AND/OR PULMONARY EDEMA, AND DEATH. AIM: LTH ALSO CAN LEAD TO ALTERATION IN METABOLITES SUCH AS FUMARATE, 2-OXOGLUTARATE, MALATE, AND LACTATE, WHICH ARE LINKED TO EPIGENETIC REGULATION OF GENE EXPRESSION. IMPORTANTLY, DURING THE INTRAUTERINE LIFE, A FETUS IS UNDER A RELATIVE HYPOXIC ENVIRONMENT, AS COMPARED TO NEWBORN OR ADULT. THUS, THE CHANGES IN GENE EXPRESSION WITH DEVELOPMENT FROM FETUS TO NEWBORN TO ADULT MAY BE AS A CONSEQUENCE OF UNDERLYING CHANGES IN THE METABOLIC PROFILE BECAUSE OF THE HYPOXIC ENVIRONMENT ALONG WITH DEVELOPMENTAL MATURATION. TO EXAMINE THIS POSSIBILITY, WE EXAMINED THE METABOLIC PROFILE IN CAROTID ARTERIES FROM NEAR-TERM FETUS, NEWBORN, AND ADULT SHEEP IN BOTH NORMOXIC AND LONG-TERM HYPOXIC ACCLIMATIZED GROUPS. RESULTS: OUR RESULTS DEMONSTRATE THAT LTH DIFFERENTIALLY REGULATED GLUCOSE METABOLISM, MITOCHONDRIAL METABOLISM, NICOTINAMIDE COFACTOR METABOLISM, OXIDATIVE STRESS AND ANTIOXIDANTS, MEMBRANE LIPID HYDROLYSIS, AND FREE FATTY ACID METABOLISM, EACH OF WHICH MAY PLAY A ROLE IN GENETIC-EPIGENETIC REGULATION. 2015 4 3544 32 IMMUNOMETABOLIC CONTROL OF TRAINED IMMUNITY. INNATE IMMUNE CELLS CAN ADOPT LONG-TERM INFLAMMATORY PHENOTYPES FOLLOWING BRIEF ENCOUNTERS WITH EXOGENOUS (MICROBIAL) OR ENDOGENOUS STIMULI. THIS PHENOMENON IS NAMED TRAINED IMMUNITY AND CAN IMPROVE HOST DEFENSE AGAINST (RECURRENT) INFECTIONS. IN CONTRAST, TRAINED IMMUNITY CAN ALSO BE MALADAPTIVE IN THE CONTEXT OF CHRONIC INFLAMMATORY DISORDERS, SUCH AS ATHEROSCLEROSIS. KEY TO FUTURE THERAPEUTIC EXPLOITATION OF THIS MECHANISM IS THOROUGH KNOWLEDGE OF THE MECHANISMS DRIVING TRAINED IMMUNITY, WHICH CAN BE USED AS PHARMACOLOGICAL TARGETS. THESE MECHANISMS INCLUDE PROFOUND CHANGES IN INTRACELLULAR METABOLISM, WHICH ARE CLOSELY INTERTWINED WITH EPIGENETIC REPROGRAMMING AT THE LEVEL OF HISTONE MODIFICATIONS. GLYCOLYSIS, GLUTAMINE REPLENISHMENT OF THE TRICARBOXYLIC ACID CYCLE WITH ACCUMULATION OF FUMARATE, AND THE MEVALONATE PATHWAY HAVE ALL BEEN IDENTIFIED AS CRITICAL PATHWAYS FOR TRAINED IMMUNITY IN MONOCYTES AND MACROPHAGES. IN THIS REVIEW, WE PROVIDE A STATE-OF-THE-ART OVERVIEW OF HOW THESE METABOLIC PATHWAYS INTERACT WITH EPIGENETIC PROGRAMS TO DEVELOP TRAINED IMMUNITY. 2021 5 2937 38 GENETIC AND EPIGENETIC ALTERATIONS DURING RENAL CARCINOGENESIS. RENAL CELL CARCINOMA (RCC) IS NOT A SINGLE ENTITY, BUT COMPRISES A GROUP OF TUMORS INCLUDING CLEAR CELL RCC, PAPILLARY RCC AND CHROMOPHOBE RCC, WHICH ARISE FROM THE EPITHELIUM OF RENAL TUBULES. THE MAJORITY OF CLEAR CELL RCCS, THE MAJOR HISTOLOGICAL SUBTYPE, HAVE GENETIC OR EPIGENETIC INACTIVATION OF THE VON HIPPEL-LINDAU (VHL) GENE. GERMLINE MUTATIONS IN THE MET AND FUMARATE HYDRATASE (FH) GENES LEAD TO THE DEVELOPMENT OF TYPE 1 AND TYPE 2 PAPILLARY RCCS, RESPECTIVELY, AND SUCH MUTATIONS OF EITHER THE TSC1 OR TSC2 GENE INCREASE THE RISK OF RCC. GENOME-WIDE COPY NUMBER ALTERATION ANALYSIS HAS SUGGESTED THAT LOSS OF CHROMOSOME 3P AND GAIN OF CHROMOSOMES 5Q AND 7 MAY BE COPY NUMBER ABERRATIONS INDISPENSABLE FOR THE DEVELOPMENT OF CLEAR CELL RCC. WHEN CHROMOSOME 1P, 4, 9, 13Q OR 14Q IS ALSO LOST, MORE CLINICOPATHOLOGICALLY AGGRESSIVE CLEAR CELL RCC MAY DEVELOP. SINCE RENAL CARCINOGENESIS IS ASSOCIATED WITH NEITHER CHRONIC INFLAMMATION NOR PERSISTENT VIRAL INFECTION, AND HARDLY ANY HISTOLOGICAL CHANGE IS EVIDENT IN CORRESPONDING NON-TUMOROUS RENAL TISSUE FROM PATIENTS WITH RENAL TUMORS, PRECANCEROUS CONDITIONS IN THE KIDNEY HAVE BEEN RARELY DESCRIBED. HOWEVER, REGIONAL DNA HYPERMETHYLATION ON C-TYPE CPG ISLANDS HAS ALREADY ACCUMULATED IN SUCH NON-CANCEROUS RENAL TISSUES, SUGGESTING THAT, FROM THE VIEWPOINT OF ALTERED DNA METHYLATION, THE PRESENCE OF PRECANCEROUS CONDITIONS CAN BE RECOGNIZED EVEN IN THE KIDNEY. GENOME-WIDE DNA METHYLATION PROFILES IN PRECANCEROUS CONDITIONS ARE BASICALLY INHERITED BY THE CORRESPONDING CLEAR CELL RCCS DEVELOPING IN INDIVIDUAL PATIENTS: DNA METHYLATION ALTERATIONS AT THE PRECANCEROUS STAGE MAY FURTHER PREDISPOSE RENAL TISSUE TO EPIGENETIC AND GENETIC ALTERATIONS, GENERATE MORE MALIGNANT CANCERS, AND EVEN DETERMINE PATIENT OUTCOME. THE LIST OF TUMOR-RELATED GENES SILENCED BY DNA HYPERMETHYLATION HAS RECENTLY BEEN INCREASING. GENETIC AND EPIGENETIC PROFILING PROVIDES AN OPTIMAL MEANS OF PROGNOSTICATION FOR PATIENTS WITH RCCS. RECENTLY DEVELOPED HIGH-THROUGHPUT TECHNOLOGIES FOR GENETIC AND EPIGENETIC ANALYSES WILL FURTHER ACCELERATE THE IDENTIFICATION OF KEY MOLECULES FOR USE IN THE PREVENTION, DIAGNOSIS AND THERAPY OF RCCS. 2010 6 1502 29 DNA METHYLATION AND EPIGENETIC EVENTS UNDERLYING RENAL CELL CARCINOMAS. RENAL CELL CARCINOMA (RCC) REFERS TO A GROUP OF TUMORS THAT DEVELOP FROM THE EPITHELIUM OF THE KIDNEY TUBES, INCLUDING CLEAR CELL RCC, PAPILLARY RCC, AND CHROMOPHOBE RCC. MOST CLEAR CELL RENAL CARCINOMAS HAVE A LARGE HISTOLOGIC SUBTYPE, GENETIC OR EPIGENETIC VON HIPPEL-LINDAU (VHL). A COMPREHENSIVE ANALYSIS OF THE GENETIC MODIFICATION GENOME SUGGESTED THAT CHROMOSOME 3P LOSS AND CHROMOSOME GAINS 5Q AND 7 MAY BE SIGNIFICANT COPY DEFECTS IN THE DEVELOPMENT OF CLEAR RCC. A MORE POTENT RCC MAY DEVELOP IF CHROMOSOME 1P, 4, 9, 13Q, OR 14Q IS ALSO LOST. RENAL CARCINOGENESIS IS NOT ASSOCIATED WITH CHRONIC INFLAMMATION OR HISTOLOGICAL CHANGES. HOWEVER, IF REGIONAL HYPERMETHYLATION OF DNA IN CPG C-TYPE ISLANDS HAS ALREADY ACCUMULATED IN CANCER-FREE KIDNEY TISSUE, IT IMPLIES THAT THE PRESENCE OF MALIGNANT KIDNEY LESIONS MAY ALSO BE DETECTED BY MODIFIED DNA METHYLATION. MODIFICATION OF DNA METHYLATION IN CANCEROUS KIDNEY TISSUE MAY ADVANCE KIDNEY TISSUE TO EPIGENETIC MUTATIONS AND GENES, LEADING TO MORE SERIOUS CANCERS AND EVEN DETERMINING A PATIENT'S OUTCOME. THE GENETIC AND EPIGENETIC PROFILE PROVIDES ACCURATE PREDICTORS FOR PATIENTS WITH KIDNEY CANCER. NEW GENETIC AND EPIGENETIC ANALYSIS TECHNOLOGIES WILL HELP TO SPEED UP THE IDENTIFICATION OF VITAL CELLS FOR KIDNEY CANCER PREVENTION, DIAGNOSIS, AND TREATMENT. 2022 7 6493 43 TRAINED IMMUNITY AND REACTIVITY OF MACROPHAGES AND ENDOTHELIAL CELLS. INNATE IMMUNE CELLS CAN DEVELOP EXACERBATED IMMUNOLOGIC RESPONSE AND LONG-TERM INFLAMMATORY PHENOTYPE FOLLOWING BRIEF EXPOSURE TO ENDOGENOUS OR EXOGENOUS INSULTS, WHICH LEADS TO AN ALTERED RESPONSE TOWARDS A SECOND CHALLENGE AFTER THE RETURN TO A NONACTIVATED STATE. THIS PHENOMENON IS KNOWN AS TRAINED IMMUNITY (TI). TI IS NOT ONLY IMPORTANT FOR HOST DEFENSE AND VACCINE RESPONSE BUT ALSO FOR CHRONIC INFLAMMATIONS SUCH AS CARDIOVASCULAR AND METABOLIC DISEASES SUCH AS ATHEROSCLEROSIS. TI CAN OCCUR IN INNATE IMMUNE CELLS SUCH AS MONOCYTES/MACROPHAGES, NATURAL KILLER CELLS, ENDOTHELIAL CELLS (ECS), AND NONIMMUNE CELLS, SUCH AS FIBROBLAST. IN THIS BRIEF REVIEW, WE ANALYZE THE SIGNIFICANCE OF TI IN ECS, WHICH ARE ALSO CONSIDERED AS INNATE IMMUNE CELLS IN ADDITION TO MACROPHAGES. TI CAN BE INDUCED BY A VARIETY OF STIMULI, INCLUDING LIPOPOLYSACCHARIDES, BCG (BACILLUS CALMETTE-GUERIN), AND OXLDL (OXIDIZED LOW-DENSITY LIPOPROTEIN), WHICH ARE DEFINED AS RISK FACTORS FOR CARDIOVASCULAR AND METABOLIC DISEASES. FURTHERMORE, TI IN ECS IS FUNCTIONAL FOR INFLAMMATION EFFECTIVENESS AND TRANSITION TO CHRONIC INFLAMMATION. REWIRING OF CELLULAR METABOLISM OF THE TRAINED CELLS TAKES PLACE DURING INDUCTION OF TI, INCLUDING INCREASED GLYCOLYSIS, GLUTAMINOLYSIS, INCREASED ACCUMULATION OF TRICARBOXYLIC ACID CYCLE METABOLITES AND ACETYL-COENZYME A PRODUCTION, AS WELL AS INCREASED MEVALONATE SYNTHESIS. SUBSEQUENTLY, THIS LEADS TO EPIGENETIC REMODELING, RESULTING IN IMPORTANT CHANGES IN CHROMATIN ARCHITECTURE THAT ENABLES INCREASED GENE TRANSCRIPTION AND ENHANCED PROINFLAMMATORY IMMUNE RESPONSE. HOWEVER, TI PATHWAYS AND INFLAMMATORY PATHWAYS ARE SEPARATED TO ENSURE MEMORY STAYS WHEN INFLAMMATION UNDERGOES RESOLUTION. ADDITIONALLY, REACTIVE OXYGEN SPECIES PLAY CONTEXT-DEPENDENT ROLES IN TI. THEREFORE, TI PLAYS SIGNIFICANT ROLES IN EC AND MACROPHAGE PATHOLOGY AND CHRONIC INFLAMMATION. HOWEVER, FURTHER CHARACTERIZATION OF TI IN ECS AND MACROPHAGES WOULD PROVIDE NOVEL INSIGHTS INTO CARDIOVASCULAR DISEASE PATHOGENESIS AND NEW THERAPEUTIC TARGETS. GRAPHIC ABSTRACT: A GRAPHIC ABSTRACT IS AVAILABLE FOR THIS ARTICLE. 2021 8 4044 32 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 9 1066 37 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 10 1231 37 CROSSTALK BETWEEN GLUCOSE METABOLISM, LACTATE PRODUCTION AND IMMUNE RESPONSE MODULATION. METABOLITES OF GLYCOLYTIC METABOLISM HAVE BEEN IDENTIFIED AS SIGNALING MOLECULES AND REGULATORS OF GENE EXPRESSION, IN ADDITION TO THEIR BASIC FUNCTION AS MAJOR ENERGY AND BIOSYNTHETIC SOURCE. IMMUNE CELLS REPROGRAM METABOLIC PATHWAYS TO CATER TO ENERGY AND BIOSYNTHESIS DEMANDS UPON ACTIVATION. MOST LYMPHOCYTES, INCLUDING INFLAMMATORY M1 MACROPHAGES, MAINLY SHIFT FROM OXIDATIVE PHOSPHORYLATION TO GLYCOLYSIS, WHEREAS REGULATORY T CELLS AND M2 MACROPHAGES PREFERENTIALLY USE THE TRICARBOXYLIC ACID (TCA) CYCLE AND HAVE REDUCED GLYCOLYSIS. RECENT STUDIES HAVE REVEALED THE "NON-METABOLIC" SIGNALING FUNCTIONS OF INTERMEDIATES OF THE MITOCHONDRIAL PATHWAY AND GLYCOLYSIS. THE ROLES OF CITRATE, SUCCINATE AND ITACONATE IN IMMUNE RESPONSE, INCLUDING POST-TRANSLATIONAL MODIFICATIONS OF PROTEINS AND MACROPHAGES ACTIVATION, HAVE BEEN HIGHLIGHTED. AS AN END PRODUCT OF GLYCOLYSIS, LACTATE HAS RECEIVED CONSIDERABLE INTEREST FROM RESEARCHERS. IN THIS REVIEW, WE SPECIFICALLY FOCUSED ON STUDIES EXPLORING THE INTEGRATION OF LACTATE INTO IMMUNE CELL BIOLOGY AND ASSOCIATED PATHOLOGIES. LACTATE CAN ACT AS A DOUBLE-EDGED SWORD. ON ONE HAND, ACTIVATED IMMUNE CELLS PREFER TO USE LACTATE TO SUPPORT THEIR FUNCTION. ON THE OTHER HAND, ACCUMULATED LACTATE IN THE TISSUE MICROENVIRONMENT ACTS AS A SIGNALING MOLECULE THAT RESTRICTS IMMUNE CELL FUNCTION. RECENTLY, A NOVEL EPIGENETIC CHANGE MEDIATED BY HISTONE LYSINE LACTYLATION HAS BEEN PROPOSED. THE BURGEONING RESEARCHES SUPPORT THE IDEA THAT HISTONE LACTYLATION PARTICIPATES IN DIVERSE CELLULAR EVENTS. THIS REVIEW DESCRIBES GLYCOLYTIC METABOLISM, INCLUDING THE IMMUNOREGULATION OF METABOLITES OF THE TCA CYCLE AND LACTATE. THESE LATEST FINDINGS STRENGTHEN OUR UNDERSTANDING ON TUMOR AND CHRONIC INFLAMMATORY DISEASES AND OFFER POTENTIAL THERAPEUTIC OPTIONS. 2022 11 5720 31 SIRTUINS LINK INFLAMMATION AND METABOLISM. SIRTUINS (SIRT), FIRST DISCOVERED IN YEAST AS NAD+ DEPENDENT EPIGENETIC AND METABOLIC REGULATORS, HAVE COMPARABLE ACTIVITIES IN HUMAN PHYSIOLOGY AND DISEASE. MOUNTING EVIDENCE SUPPORTS THAT THE SEVEN-MEMBER MAMMALIAN SIRTUIN FAMILY (SIRT1-7) GUARD HOMEOSTASIS BY SENSING BIOENERGY NEEDS AND RESPONDING BY MAKING ALTERATIONS IN THE CELL NUTRIENTS. SIRTUINS PLAY A CRITICAL ROLE IN RESTORING HOMEOSTASIS DURING STRESS RESPONSES. INFLAMMATION IS DESIGNED TO "DEFEND AND MEND" AGAINST THE INVADING ORGANISMS. EMERGING EVIDENCE SUPPORTS THAT METABOLISM AND BIOENERGY REPROGRAMMING DIRECT THE SEQUENTIAL COURSE OF INFLAMMATION; FAILURE OF HOMEOSTASIS RETRIEVAL RESULTS IN MANY CHRONIC AND ACUTE INFLAMMATORY DISEASES. ANABOLIC GLYCOLYSIS QUICKLY INDUCED (COMPARED TO OXIDATIVE PHOSPHORYLATION) FOR ROS AND ATP GENERATION IS NEEDED FOR IMMUNE ACTIVATION TO "DEFEND" AGAINST INVADING MICROORGANISMS. LIPOLYSIS/FATTY ACID OXIDATION, ESSENTIAL FOR CELLULAR PROTECTION/HIBERNATION AND CELL SURVIVAL IN ORDER TO "MEND," LEADS TO IMMUNE REPRESSION. ACUTE/CHRONIC INFLAMMATIONS ARE LINKED TO ALTERED GLYCOLYSIS AND FATTY ACID OXIDATION, AT LEAST IN PART, BY NAD+ DEPENDENT FUNCTION OF SIRTUINS. THERAPEUTICALLY TARGETING SIRTUINS MAY PROVIDE A NEW CLASS OF INFLAMMATION AND IMMUNE REGULATORS. THIS REVIEW DISCUSSES HOW SIRTUINS INTEGRATE METABOLISM, BIOENERGETICS, AND IMMUNITY DURING INFLAMMATION AND HOW SIRTUIN-DIRECTED TREATMENT IMPROVES OUTCOME IN CHRONIC INFLAMMATORY DISEASES AND IN THE EXTREME STRESS RESPONSE OF SEPSIS. 2016 12 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 13 6038 31 THE CHEMICAL DEFENSIVE SYSTEM IN THE PATHOBIOLOGY OF IDIOPATHIC ENVIRONMENT-ASSOCIATED DISEASES. CHEMICAL DEFENSIVE SYSTEM CONSISTING OF BIO-SENSORING, TRANSMITTING, AND RESPONSIVE ELEMENTS HAS BEEN EVOLVED TO PROTECT MULTI-CELLULAR ORGANISMS AGAINST ENVIRONMENTAL CHEMICAL INSULTS (XENOBIOTICS) AND TO MAINTAIN HOMEOSTASIS OF ENDOGENOUS LOW MOLECULAR WEIGHT METABOLITES (ENDOBIOTICS). BOTH GENETIC AND EPIGENETIC DEFECTS OF THE SYSTEM IN ASSOCIATION WITH CARCINOGENESIS AND INDIVIDUAL SENSITIVITY TO ANTI-TUMOR THERAPIES HAVE BEEN INTENSELY STUDIED. RECENTLY, SEVERAL NON-TUMOR HUMAN PATHOLOGIES WITH EVIDENT ENVIRONMENTAL COMPONENTS SUCH AS RATHER RARE FUNCTIONAL SYNDROMES (MULTIPLE CHEMICAL SENSITIVITY, CHRONIC FATIGUE, PERSIAN GULF, AND FIBROMYALGIA NOW COLLECTIVELY LABELED AS IDIOPATHIC ENVIRONMENTAL INTOLERANCES) AND COMMON DISEASES (VITILIGO AND SYSTEMIC LUPUS ERYTHEMATOSUS) HAVE BECOME SUBJECTS OF THE RESEARCH ON THE IMPAIRED METABOLISM AND DETOXIFICATION OF XENOBIOTICS AND ENDOGENOUS TOXINS. HERE, WE COLLECTED AND CRITICALLY REVIEWED EPIDEMIOLOGICAL, GENETIC, AND BIOCHEMICAL DATA ON THE INVOLVEMENT AND POSSIBLE ROLE OF CYTOCHROME P450 SUPER FAMILY ENZYMES, GLUTATHIONE-S-TRANSFERASE ISOZYMES, CATECHOL-O-METHYL-TRANSFERASE, UDP-GLUCURONOSYL TRANSFERASES, AND PROTEINS DETOXIFYING INORGANIC AND ORGANIC PEROXIDES (CATALASE, GLUTATHIONE PEROXIDASE, AND PEROXIREDOXIN) IN THE ABOVE PATHOLOGIES. GENETIC PREDISPOSITION ASSESSED MAINLY BY SINGLE NUCLEOTIDE POLYMORPHISM AND GENE EXPRESSION ANALYSES REVEALED CORRELATIONS BETWEEN DEFECTS IN GENES ENCODING XENOBIOTIC-METABOLIZING AND/OR DETOXIFYING ENZYMES AND RISK/SEVERITY OF THESE SYNDROMES/DISEASES. PROTEOME ANALYSIS IDENTIFIED ABNORMAL EXPRESSION OF THE ENZYMES. THEIR FUNCTIONS WERE AFFECTED EPIGENETICALLY LEADING TO METABOLIC IMPAIRMENT AND, AS A CONSEQUENCE, TO THE NEGATIVE HEALTH OUTCOMES SHARED BY SOME OF THESE PATHOLOGIES. DATA OBTAINED SO FAR SUGGEST THAT DISTINCT COMPONENTS OF THE CHEMICAL DEFENSIVE SYSTEM COULD BE SUITABLE MOLECULAR TARGETS FOR FUTURE PATHOGENIC THERAPIES. 2009 14 2772 37 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 15 3155 27 GLUTAMINE METABOLISM IN ADIPOCYTES: A BONA FIDE EPIGENETIC MODULATOR OF INFLAMMATION. A CHRONIC LOW-GRADE INFLAMMATION OF WHITE ADIPOSE TISSUE (WAT) IS ONE OF THE HALLMARKS OF OBESITY AND IS PROPOSED TO CONTRIBUTE TO INSULIN RESISTANCE AND TYPE 2 DIABETES. DESPITE THIS, THE CAUSAL MECHANISMS UNDERLYING WAT INFLAMMATION REMAIN UNCLEAR. BASED ON METABOLOMIC ANALYSES OF HUMAN WAT, PETRUS ET AL. SHOWED THAT THE AMINO ACID GLUTAMINE WAS THE MOST MARKEDLY REDUCED POLAR METABOLITE IN THE OBESE STATE. REDUCED GLUTAMINE LEVELS IN ADIPOCYTES INDUCE AN INCREASE OF URIDINE DIPHOSPHATE N-ACETYLGLUCOSAMINE (UDP-GLCNAC) LEVELS VIA INDUCTION OF GLYCOLYSIS AND THE HEXOSAMINE BIOSYNTHETIC PATHWAYS. THIS PROMOTES NUCLEAR O-GLCNACYLATION, A POSTTRANSLATIONAL MODIFICATION THAT ACTIVATES THE TRANSCRIPTION OF PRO-INFLAMMATORY GENES. CONVERSELY, GLUTAMINE SUPPLEMENTATION IN VITRO AND IN VIVO, REVERSED THESE EFFECTS. ALTOGETHER, DYSREGULATION OF INTRACELLULAR GLUTAMINE METABOLISM IN WAT ESTABLISHES AN EPIGENETIC LINK BETWEEN ADIPOCYTES AND INFLAMMATION. THIS COMMENTARY DISCUSSES THESE FINDINGS AND THEIR POSSIBLY THERAPEUTIC RELEVANCE IN RELATION TO INSULIN RESISTANCE AND TYPE 2 DIABETES. 2020 16 6374 36 THE ROLE OF MITOCHONDRIA IN MYOCARDIAL DAMAGE CAUSED BY ENERGY METABOLISM DISORDERS: FROM MECHANISMS TO THERAPEUTICS. MYOCARDIAL DAMAGE IS THE MOST SERIOUS PATHOLOGICAL CONSEQUENCE OF CARDIOVASCULAR DISEASES AND AN IMPORTANT REASON FOR THEIR HIGH MORTALITY. IN RECENT YEARS, BECAUSE OF THE HIGH PREVALENCE OF SYSTEMIC ENERGY METABOLISM DISORDERS (E.G., OBESITY, DIABETES MELLITUS, AND METABOLIC SYNDROME), COMPLICATIONS OF MYOCARDIAL DAMAGE CAUSED BY THESE DISORDERS HAVE ATTRACTED WIDESPREAD ATTENTION. ENERGY METABOLISM DISORDERS ARE INDEPENDENT OF TRADITIONAL INJURY-RELATED RISK FACTORS, SUCH AS ISCHEMIA, HYPOXIA, TRAUMA, AND INFECTION. AN IMBALANCE OF MYOCARDIAL METABOLIC FLEXIBILITY AND MYOCARDIAL ENERGY DEPLETION ARE USUALLY THE INITIAL CHANGES OF MYOCARDIAL INJURY CAUSED BY ENERGY METABOLISM DISORDERS, AND ABNORMAL MORPHOLOGY AND FUNCTIONAL DESTRUCTION OF THE MITOCHONDRIA ARE THEIR IMPORTANT FEATURES. SPECIFICALLY, MITOCHONDRIA ARE THE CENTERS OF ENERGY METABOLISM, AND RECENT EVIDENCE HAS SHOWN THAT DECREASED MITOCHONDRIAL FUNCTION, CAUSED BY AN IMBALANCE IN MITOCHONDRIAL QUALITY CONTROL, MAY PLAY A KEY ROLE IN MYOCARDIAL INJURY CAUSED BY ENERGY METABOLISM DISORDERS. UNDER CHRONIC ENERGY STRESS, MITOCHONDRIA UNDERGO PATHOLOGICAL FISSION, WHILE MITOPHAGY, MITOCHONDRIAL FUSION, AND BIOGENESIS ARE INHIBITED, AND MITOCHONDRIAL PROTEIN BALANCE AND TRANSFER ARE DISTURBED, RESULTING IN THE ACCUMULATION OF NONFUNCTIONAL AND DAMAGED MITOCHONDRIA. CONSEQUENTLY, DAMAGED MITOCHONDRIA LEAD TO MYOCARDIAL ENERGY DEPLETION AND THE ACCUMULATION OF LARGE AMOUNTS OF REACTIVE OXYGEN SPECIES, FURTHER AGGRAVATING THE IMBALANCE IN MITOCHONDRIAL QUALITY CONTROL AND FORMING A VICIOUS CYCLE. IN ADDITION, IMPAIRED MITOCHONDRIA COORDINATE CALCIUM HOMEOSTASIS IMBALANCE, AND EPIGENETIC ALTERATIONS PARTICIPATE IN THE PATHOGENESIS OF MYOCARDIAL DAMAGE. THESE PATHOLOGICAL CHANGES INDUCE RAPID PROGRESSION OF MYOCARDIAL DAMAGE, EVENTUALLY LEADING TO HEART FAILURE OR SUDDEN CARDIAC DEATH. TO INTERVENE MORE SPECIFICALLY IN THE MYOCARDIAL DAMAGE CAUSED BY METABOLIC DISORDERS, WE NEED TO UNDERSTAND THE SPECIFIC ROLE OF MITOCHONDRIA IN THIS CONTEXT IN DETAIL. ACCORDINGLY, PROMISING THERAPEUTIC STRATEGIES HAVE BEEN PROPOSED. WE ALSO SUMMARIZE THE EXISTING THERAPEUTIC STRATEGIES TO PROVIDE A REFERENCE FOR CLINICAL TREATMENT AND DEVELOPING NEW THERAPIES. 2023 17 3734 40 INNATE IMMUNE MEMORY IN MONOCYTES AND MACROPHAGES: THE POTENTIAL THERAPEUTIC STRATEGIES FOR ATHEROSCLEROSIS. ATHEROSCLEROSIS IS A COMPLEX METABOLIC DISEASE CHARACTERIZED BY THE DYSFUNCTION OF LIPID METABOLISM AND CHRONIC INFLAMMATION IN THE INTIMAL SPACE OF THE VESSEL. AS THE MOST ABUNDANT INNATE IMMUNE CELLS, MONOCYTE-DERIVED MACROPHAGES PLAY A PIVOTAL ROLE IN THE INFLAMMATORY RESPONSE, CHOLESTEROL METABOLISM, AND FOAM CELL FORMATION. IN RECENT DECADES, IT HAS BEEN DEMONSTRATED THAT MONOCYTES AND MACROPHAGES CAN ESTABLISH INNATE IMMUNE MEMORY (ALSO TERMED TRAINED IMMUNITY) VIA ENDOGENOUS AND EXOGENOUS ATHEROGENIC STIMULI AND EXHIBIT A LONG-LASTING PROINFLAMMATORY PHENOTYPE. THE IMPORTANT CELLULAR METABOLISM PROCESSES, INCLUDING GLYCOLYSIS, OXIDATIVE PHOSPHORYLATION (OXPHOS), THE TRICARBOXYLIC ACID (TCA) CYCLE, FATTY ACID SYNTHESIS, AND CHOLESTEROL SYNTHESIS, ARE REPROGRAMMED. TRAINED MONOCYTES/MACROPHAGES WITH INNATE IMMUNE MEMORY CAN BE PERSISTENTLY HYPERACTIVATED AND CAN UNDERGO EXTENSIVE EPIGENETIC REWIRING, WHICH CONTRIBUTES TO THE PATHOPHYSIOLOGICAL DEVELOPMENT OF ATHEROSCLEROSIS VIA INCREASED PROINFLAMMATORY CYTOKINE PRODUCTION AND LIPID ACCUMULATION. HERE, WE PROVIDE AN OVERVIEW OF THE REGULATION OF CELLULAR METABOLIC PROCESSES AND EPIGENETIC MODIFICATIONS OF INNATE IMMUNE MEMORY IN MONOCYTES/MACROPHAGES AS WELL AS THE POTENTIAL ENDOGENOUS AND EXOGENOUS STIMULATIONS INVOLVED IN THE PROGRESSION OF ATHEROSCLEROSIS THAT HAVE BEEN REPORTED RECENTLY. THESE ELUCIDATIONS MIGHT BE BENEFICIAL FOR FURTHER UNDERSTANDING INNATE IMMUNE MEMORY AND THE DEVELOPMENT OF THERAPEUTIC STRATEGIES FOR INFLAMMATORY DISEASES AND ATHEROSCLEROSIS. 2022 18 6467 48 TISSUE-SPECIFIC EFFECTS OF EXERCISE AS NAD(+) -BOOSTING STRATEGY: CURRENT KNOWLEDGE AND FUTURE PERSPECTIVES. NICOTINAMIDE ADENINE DINUCLEOTIDE (NAD(+) ) IS AN EVOLUTIONARILY HIGHLY CONSERVED COENZYME WITH MULTI-FACETED CELL FUNCTIONS, INCLUDING ENERGY METABOLISM, MOLECULAR SIGNALING PROCESSES, EPIGENETIC REGULATION, AND DNA REPAIR. SINCE THE DISCOVERY THAT LOWER NAD(+) LEVELS ARE A SHARED CHARACTERISTIC OF VARIOUS DISEASES AND AGING PER SE, SEVERAL NAD(+) -BOOSTING STRATEGIES HAVE EMERGED. OTHER THAN PHARMACOLOGICAL AND NUTRITIONAL APPROACHES, EXERCISE IS THOUGHT TO RESTORE NAD(+) HOMEOSTASIS THROUGH METABOLIC ADAPTION TO CHRONICALLY RECURRING STATES OF INCREASED ENERGY DEMAND. IN THIS REVIEW WE DISCUSS THE IMPACT OF ACUTE EXERCISE AND EXERCISE TRAINING ON TISSUE-SPECIFIC NAD(+) METABOLISM OF RODENTS AND HUMANS TO HIGHLIGHT THE POTENTIAL VALUE AS NAD(+) -BOOSTING STRATEGY. BY INTERCONNECTING RESULTS FROM DIFFERENT INVESTIGATIONS, WE AIM TO DRAW ATTENTION TO TISSUE-SPECIFIC ALTERATIONS IN NAD(+) METABOLISM AND THE ASSOCIATED IMPLICATIONS FOR WHOLE-BODY NAD(+) HOMEOSTASIS. ACUTE EXERCISE LED TO PROFOUND ALTERATIONS OF INTRACELLULAR NAD(+) METABOLISM IN VARIOUS INVESTIGATIONS, WITH THE MAGNITUDE AND DIRECTION OF CHANGES BEING STRONGLY DEPENDENT ON THE APPLIED EXERCISE MODALITY, CELL TYPE, AND INVESTIGATED ANIMAL MODEL OR HUMAN POPULATION. EXERCISE TRAINING ELEVATED NAD(+) LEVELS AND NAD(+) METABOLISM ENZYMES IN VARIOUS TISSUES. BASED ON THESE RESULTS, WE DISCUSS MOLECULAR MECHANISMS THAT MIGHT CONNECT ACUTE EXERCISE-INDUCED DISRUPTIONS OF NAD(+) /NADH HOMEOSTASIS TO CHRONIC EXERCISE ADAPTIONS IN NAD(+) METABOLISM. TAKING THIS HYPOTHESIS-DRIVEN APPROACH, WE HOPE TO INSPIRE FUTURE RESEARCH ON THE MOLECULAR MECHANISMS OF EXERCISE AS NAD(+) -MODIFYING LIFESTYLE INTERVENTION, THEREBY ELUCIDATING THE POTENTIAL THERAPEUTIC VALUE IN NAD(+) -RELATED PATHOLOGIES. 2023 19 3701 28 INFLAMMATORY RESPONSE TO REGULATED CELL DEATH IN GOUT AND ITS FUNCTIONAL IMPLICATIONS. GOUT, A CHRONIC INFLAMMATORY ARTHRITIS DISEASE, IS CHARACTERIZED BY HYPERURICEMIA AND CAUSED BY INTERACTIONS BETWEEN GENETIC, EPIGENETIC, AND METABOLIC FACTORS. ACUTE GOUT SYMPTOMS ARE TRIGGERED BY THE INFLAMMATORY RESPONSE TO MONOSODIUM URATE CRYSTALS, WHICH IS MEDIATED BY THE INNATE IMMUNE SYSTEM AND IMMUNE CELLS (E.G., MACROPHAGES AND NEUTROPHILS), THE NACHT, LRR, AND PYD DOMAINS-CONTAINING PROTEIN 3 (NLRP3) INFLAMMASOME ACTIVATION, AND PRO-INFLAMMATORY CYTOKINE (E.G., IL-1BETA) RELEASE. RECENT STUDIES HAVE INDICATED THAT THE MULTIPLE PROGRAMMED CELL DEATH PATHWAYS INVOLVED IN THE INFLAMMATORY RESPONSE INCLUDE PYROPTOSIS, NETOSIS, NECROPTOSIS, AND APOPTOSIS, WHICH INITIATE INFLAMMATORY REACTIONS. IN THIS REVIEW, WE EXPLORE THE CORRELATION AND INTERACTIONS AMONG THESE FACTORS AND THEIR ROLES IN THE PATHOGENESIS OF GOUT TO PROVIDE FUTURE RESEARCH DIRECTIONS AND POSSIBILITIES FOR IDENTIFYING POTENTIAL NOVEL THERAPEUTIC TARGETS AND ENHANCING OUR UNDERSTANDING OF GOUT PATHOGENESIS. 2022 20 4585 40 NAD(+) AND VASCULAR DYSFUNCTION: FROM MECHANISMS TO THERAPEUTIC OPPORTUNITIES. NICOTINAMIDE ADENINE DINUCLEOTIDE (NAD(+)) IS AN ESSENTIAL AND PLEIOTROPIC COENZYME INVOLVED NOT ONLY IN CELLULAR ENERGY METABOLISM, BUT ALSO IN CELL SIGNALING, EPIGENETIC REGULATION, AND POST-TRANSLATIONAL PROTEIN MODIFICATIONS. VASCULAR DISEASE RISK FACTORS ARE ASSOCIATED WITH ABERRANT NAD(+) METABOLISM. CONVERSELY, THE THERAPEUTIC INCREASE OF NAD(+) LEVELS THROUGH THE ADMINISTRATION OF NAD(+) PRECURSORS OR INHIBITORS OF NAD(+)-CONSUMING ENZYMES REDUCES CHRONIC LOW-GRADE INFLAMMATION, REACTIVATES AUTOPHAGY AND MITOCHONDRIAL BIOGENESIS, AND ENHANCES OXIDATIVE METABOLISM IN VASCULAR CELLS OF HUMANS AND RODENTS WITH VASCULAR PATHOLOGIES. AS SUCH, NAD(+) HAS EMERGED AS A POTENTIAL TARGET FOR COMBATTING AGE-RELATED CARDIOVASCULAR AND CEREBROVASCULAR DISORDERS. THIS REVIEW DISCUSSES NAD(+)-REGULATED MECHANISMS CRITICAL FOR VASCULAR HEALTH AND SUMMARIZES NEW ADVANCES IN NAD(+) RESEARCH DIRECTLY RELATED TO VASCULAR AGING AND DISEASE, INCLUDING HYPERTENSION, ATHEROSCLEROSIS, CORONARY ARTERY DISEASE, AND AORTIC ANEURYSMS. FINALLY, WE ENUMERATE CHALLENGES AND OPPORTUNITIES FOR NAD(+) REPLETION THERAPY WHILE ANTICIPATING THE FUTURE OF THIS EXCITING RESEARCH FIELD, WHICH WILL HAVE A MAJOR IMPACT ON VASCULAR MEDICINE. 2022