1 6166 166 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 2 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 3 6387 32 THE ROLE OF REACTIVE OXYGEN SPECIES IN ARSENIC TOXICITY. ARSENIC POISONING IS A GLOBAL HEALTH PROBLEM. CHRONIC EXPOSURE TO ARSENIC HAS BEEN ASSOCIATED WITH THE DEVELOPMENT OF A WIDE RANGE OF DISEASES AND HEALTH PROBLEMS IN HUMANS. ARSENIC EXPOSURE INDUCES THE GENERATION OF INTRACELLULAR REACTIVE OXYGEN SPECIES (ROS), WHICH MEDIATE MULTIPLE CHANGES TO CELL BEHAVIOR BY ALTERING SIGNALING PATHWAYS AND EPIGENETIC MODIFICATIONS, OR CAUSE DIRECT OXIDATIVE DAMAGE TO MOLECULES. ANTIOXIDANTS WITH THE POTENTIAL TO REDUCE ROS LEVELS HAVE BEEN SHOWN TO AMELIORATE ARSENIC-INDUCED LESIONS. HOWEVER, EMERGING EVIDENCE SUGGESTS THAT CONSTRUCTIVE ACTIVATION OF ANTIOXIDATIVE PATHWAYS AND DECREASED ROS LEVELS CONTRIBUTE TO CHRONIC ARSENIC TOXICITY IN SOME CASES. THIS REVIEW DETAILS THE PATHWAYS INVOLVED IN ARSENIC-INDUCED REDOX IMBALANCE, AS WELL AS CURRENT STUDIES ON PROPHYLAXIS AND TREATMENT STRATEGIES USING ANTIOXIDANTS. 2020 4 2950 28 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 5 5052 32 PHARMACOLOGICAL TARGETING OF HEME OXYGENASE-1 IN OSTEOARTHRITIS. OSTEOARTHRITIS (OA) IS A COMMON AGING-ASSOCIATED DISEASE THAT CLINICALLY MANIFESTS AS JOINT PAIN, MOBILITY LIMITATIONS, AND COMPROMISED QUALITY OF LIFE. TODAY, OA TREATMENT IS LIMITED TO PAIN MANAGEMENT AND JOINT ARTHROPLASTY AT THE LATER STAGES OF DISEASE PROGRESSION. OA PATHOGENESIS IS PREDOMINANTLY MEDIATED BY OXIDATIVE DAMAGE TO JOINT CARTILAGE EXTRACELLULAR MATRIX AND LOCAL CELLS SUCH AS CHONDROCYTES, OSTEOCLASTS, OSTEOBLASTS, AND SYNOVIAL FIBROBLASTS. UNDER NORMAL CONDITIONS, CELLS PREVENT THE ACCUMULATION OF REACTIVE OXYGEN SPECIES (ROS) UNDER OXIDATIVELY STRESSFUL CONDITIONS THROUGH THEIR ADAPTIVE CYTOPROTECTIVE MECHANISMS. HEME OXYGENASE-1 (HO-1) IS AN IRON-DEPENDENT CYTOPROTECTIVE ENZYME THAT FUNCTIONS AS THE INDUCIBLE FORM OF HO. HO-1 AND ITS METABOLITES CARBON MONOXIDE AND BILIVERDIN CONTRIBUTE TOWARDS THE MAINTENANCE OF REDOX HOMEOSTASIS. HO-1 EXPRESSION IS PRIMARILY REGULATED AT THE TRANSCRIPTIONAL LEVEL THROUGH TRANSCRIPTIONAL FACTOR NUCLEAR FACTOR ERYTHROID 2 (NF-E2)-RELATED FACTOR 2 (NRF2), SPECIFICITY PROTEIN 1 (SP1), TRANSCRIPTIONAL REPRESSOR BTB-AND-CNC HOMOLOGY 1 (BACH1), AND EPIGENETIC REGULATION. SEVERAL STUDIES REPORT THAT HO-1 EXPRESSION CAN BE REGULATED USING VARIOUS ANTIOXIDATIVE FACTORS AND CHEMICAL COMPOUNDS, SUGGESTING THERAPEUTIC IMPLICATIONS IN OA PATHOGENESIS AS WELL AS IN THE WIDER CONTEXT OF JOINT DISEASE. HERE, WE REVIEW THE PROTECTIVE ROLE OF HO-1 IN OA WITH A FOCUS ON THE REGULATORY MECHANISMS THAT MEDIATE HO-1 ACTIVITY. 2021 6 5942 40 TARGETING OF CELLULAR REDOX METABOLISM FOR MITIGATION OF RADIATION INJURY. ACCIDENTAL EXPOSURE TO IONIZING RADIATION IS A SERIOUS CONCERN TO HUMAN LIFE. STUDIES ON THE MITIGATION OF SIDE EFFECTS FOLLOWING EXPOSURE TO ACCIDENTAL RADIATION EVENTS ARE ONGOING. RECENT STUDIES HAVE SHOWN THAT RADIATION CAN ACTIVATE SEVERAL SIGNALING PATHWAYS, LEADING TO CHANGES IN THE METABOLISM OF FREE RADICALS INCLUDING REACTIVE OXYGEN SPECIES (ROS) AND NITRIC OXIDE (NO). CELLULAR AND MOLECULAR MECHANISMS SHOW THAT RADIATION CAN CAUSE DISRUPTION OF NORMAL REDUCTION/OXIDATION (REDOX) SYSTEM. MITOCHONDRIA MALFUNCTION FOLLOWING EXPOSURE TO RADIATION AND MUTATIONS IN MITOCHONDRIA DNA (MTDNA) HAVE A KEY ROLE IN CHRONIC OXIDATIVE STRESS. FURTHERMORE, EXPOSURE TO RADIATION LEADS TO INFILTRATION OF INFLAMMATORY CELLS SUCH AS MACROPHAGES, LYMPHOCYTES AND MAST CELLS, WHICH ARE IMPORTANT SOURCES OF ROS AND NO. THESE CELLS GENERATE FREE RADICALS VIA UPREGULATION OF SOME PRO-OXIDANT ENZYMES SUCH AS NADPH OXIDASES, INDUCIBLE NITRIC OXIDE SYNTHASE (INOS) AND CYCLOOXYGENASE-2 (COX-2). EPIGENETIC CHANGES ALSO HAVE A KEY ROLE IN A SIMILAR WAY. OTHER MEDIATORS SUCH AS MAMMALIAN TARGET OF RAPAMYCIN (MTOR) AND PEROXISOME PROLIFERATOR-ACTIVATED RECEPTOR (PPAR), WHICH ARE INVOLVED IN THE NORMAL METABOLISM OF CELLS HAVE ALSO BEEN SHOWN TO REGULATE CELL DEATH FOLLOWING EXPOSURE TO RADIATION. THESE MECHANISMS ARE TISSUE SPECIFIC. INHIBITION OR ACTIVATION OF EACH OF THESE TARGETS CAN BE SUGGESTED FOR MITIGATION OF RADIATION INJURY IN A SPECIFIC TISSUE. IN THE CURRENT PAPER, WE REVIEW THE CELLULAR AND MOLECULAR CHANGES IN THE METABOLISM OF CELLS AND ROS/NO FOLLOWING EXPOSURE TO RADIATION. FURTHERMORE, THE POSSIBLE STRATEGIES FOR MITIGATION OF RADIATION INJURY THROUGH MODULATION OF CELLULAR METABOLISM IN IRRADIATED ORGANS WILL BE DISCUSSED. 2020 7 4510 50 MTOR-DEPENDENT OXIDATIVE STRESS REGULATES OXLDL-INDUCED TRAINED INNATE IMMUNITY IN HUMAN MONOCYTES. INTRODUCTION: CELLS OF THE INNATE IMMUNE SYSTEM PARTICULARLY MONOCYTES AND MACROPHAGES HAVE BEEN RECOGNIZED AS PIVOTAL PLAYERS BOTH DURING THE INITIAL INSULT AS WELL AS THE CHRONIC PHASE OF ATHEROSCLEROSIS. IT HAS RECENTLY BEEN SHOWN THAT OXIDIZED LOW-DENSITY LIPOPROTEIN (OXLDL) INDUCES A LONG-TERM PRO-INFLAMMATORY RESPONSE IN MONOCYTES DUE TO EPIGENETIC AND METABOLIC REPROGRAMMING, AN EMERGING NEW CONCEPT CALLED TRAINED INNATE IMMUNITY. CHANGES IN THE CELLULAR REDOX STATE ARE CRUCIAL EVENTS IN THE REGULATION OF MANY PHYSIOLOGIC FUNCTIONS IN MACROPHAGES INCLUDING TRANSCRIPTION, DIFFERENTIATION AND INFLAMMATORY RESPONSE. HERE WE HAVE ANALYZED THE ROLE OF REACTIVE OXYGEN SPECIES (ROS) IN REGULATING THIS PROINFLAMMATORY MONOCYTE PRIMING IN RESPONSE TO OXLDL-TREATMENT. METHODS AND RESULTS: HUMAN MONOCYTES WERE ISOLATED AND INCUBATED WITH OXLDL FOR 24 H. AFTER 5 DAYS OF RESTING, OXLDL TREATED CELLS PRODUCED SIGNIFICANTLY MORE INFLAMMATORY CYTOKINES UPON RESTIMULATION WITH THE TLR2-AGONIST PAM3CYS. FURTHERMORE, OXLDL INCUBATION INDUCED PERSISTENT MTOR ACTIVATION, ROS FORMATION, HIF1ALPHA ACCUMULATION AND HIF1ALPHA TARGET GENE EXPRESSION, WHILE PHARMACOLOGIC MTOR INHIBITION OR SIRNA MEDIATED INHIBITION OF THE MTORC1 SUBUNIT RAPTOR PREVENTED ROS FORMATION AND PROINFLAMMATORY PRIMING. MTOR DEPENDENT ROS FORMATION WAS ASSOCIATED WITH INCREASED EXPRESSION OF NAPDH OXIDASES AND NECESSARY FOR THE EMERGENCE OF THE PRIMED PHENOTYPE AS ANTIOXIDANT TREATMENT BLOCKED OXLDL PRIMING. INHIBITION OF CYTOSOLIC ROS FORMATION COULD ALSO BLOCK MTOR ACTIVATION AND HIF1ALPHA ACCUMULATION SUGGESTING A POSITIVE FEEDBACK LOOP BETWEEN MTOR AND CYTOSOLIC ROS. ALTHOUGH MITOCHONDRIAL ROS SCAVENGING DID NOT BLOCK HIF1ALPHA-ACCUMULATION AT AN EARLY TIME POINT (24 H), IT WAS PERSISTENTLY REDUCED ON DAY 6. THEREFORE, MITOCHONDRIAL ROS FORMATION APPEARS TO OCCUR INITIALLY DOWNSTREAM OF THE MTOR-CYTOROS-HIF1ALPHA FEEDBACK LOOP BUT SEEMS TO BE A CRUCIAL FACTOR THAT CONTROLS THE LONG-TERM ACTIVATION OF THE MTOR-HIF1ALPHA-AXIS. CONCLUSION: IN SUMMARY, OUR DATA DEMONSTRATE THAT MTOR DEPENDENT ROS PRODUCTION CONTROLS THE OXLDL-INDUCED TRAINED INNATE IMMUNITY PHENOTYPE IN HUMAN MONOCYTE DERIVED MACROPHAGES. PHARMACOLOGIC MODULATION OF THESE PATHWAYS MIGHT PROVIDE A POTENTIAL APPROACH TO MODULATE INFLAMMATION, ASSOCIATED WITH ABERRANT MONOCYTE ACTIVATION, DURING ATHEROSCLEROSIS DEVELOPMENT. 2018 8 199 27 ACTIVATED HISTONE ACETYLTRANSFERASE P300/CBP-RELATED SIGNALLING PATHWAYS MEDIATE UP-REGULATION OF NADPH OXIDASE, INFLAMMATION, AND FIBROSIS IN DIABETIC KIDNEY. ACCUMULATING EVIDENCE IMPLICATES THE HISTONE ACETYLATION-BASED EPIGENETIC MECHANISMS IN THE PATHOETIOLOGY OF DIABETES-ASSOCIATED MICRO-/MACROVASCULAR COMPLICATIONS. DIABETIC KIDNEY DISEASE (DKD) IS A PROGRESSIVE CHRONIC INFLAMMATORY MICROVASCULAR DISORDER ULTIMATELY LEADING TO GLOMERULOSCLEROSIS AND KIDNEY FAILURE. WE HYPOTHESIZED THAT HISTONE ACETYLTRANSFERASE P300/CBP MAY BE INVOLVED IN MEDIATING DIABETES-ACCELERATED RENAL DAMAGE. IN THIS STUDY, WE AIMED AT INVESTIGATING THE POTENTIAL ROLE OF P300/CBP IN THE UP-REGULATION OF RENAL NADPH OXIDASE (NOX), REACTIVE OXYGEN SPECIES (ROS) PRODUCTION, INFLAMMATION, AND FIBROSIS IN DIABETIC MICE. DIABETIC C57BL/6J MICE WERE RANDOMIZED TO RECEIVE 10 MG/KG C646, A SELECTIVE P300/CBP INHIBITOR, OR ITS VEHICLE FOR 4 WEEKS. WE FOUND THAT IN THE KIDNEY OF C646-TREATED DIABETIC MICE, THE LEVEL OF H3K27AC, AN EPIGENETIC MARK OF ACTIVE GENE EXPRESSION, WAS SIGNIFICANTLY REDUCED. PHARMACOLOGICAL INHIBITION OF P300/CBP SIGNIFICANTLY DOWN-REGULATED THE DIABETES-INDUCED ENHANCED EXPRESSION OF NOX SUBTYPES, PRO-INFLAMMATORY, AND PRO-FIBROTIC MOLECULES IN THE KIDNEY OF MICE, AND THE GLOMERULAR ROS OVERPRODUCTION. OUR STUDY PROVIDES EVIDENCE THAT THE ACTIVATION OF P300/CBP ENHANCES ROS PRODUCTION, POTENTIALLY GENERATED BY UP-REGULATED NOX, INFLAMMATION, AND THE PRODUCTION OF EXTRACELLULAR MATRIX PROTEINS IN THE DIABETIC KIDNEY. THE DATA SUGGEST THAT P300/CBP-PHARMACOLOGICAL INHIBITORS MAY BE ATTRACTIVE TOOLS TO MODULATE DIABETES-ASSOCIATED PATHOLOGICAL PROCESSES TO EFFICIENTLY REDUCE THE BURDEN OF DKD. 2021 9 4372 41 MIRNAS, OXIDATIVE STRESS, AND CANCER: A COMPREHENSIVE AND UPDATED REVIEW. OXIDATIVE STRESS REFERS TO ELEVATED LEVELS OF INTRACELLULAR REACTIVE OXYGEN SPECIES (ROS). ROS HOMEOSTASIS FUNCTIONS AS A SIGNALING PATHWAY FOR NORMAL CELL SURVIVAL AND APPROPRIATE CELL SIGNALING. CHRONIC INFLAMMATION INDUCED BY IMBALANCED LEVELS OF ROS CONTRIBUTES TO MANY DISEASES AND DIFFERENT TYPES OF CANCER. ROS CAN ALTER THE EXPRESSION OF ONCOGENES AND TUMOR SUPPRESSOR GENES THROUGH EPIGENETIC MODIFICATIONS, TRANSCRIPTION FACTORS, AND NON-CODING RNAS. MICRORNAS (MIRNAS) ARE SMALL NON-CODING RNAS THAT PLAY A KEY ROLE IN MOST BIOLOGICAL PATHWAYS. EACH MIRNA REGULATES HUNDREDS OF TARGET GENES BY INHIBITING PROTEIN TRANSLATION AND/OR PROMOTING MESSENGER RNA DEGRADATION. IN NORMAL CONDITIONS, MIRNAS PLAY A PHYSIOLOGICAL ROLE IN CELL PROLIFERATION, DIFFERENTIATION, AND APOPTOSIS. HOWEVER, DIFFERENT FACTORS THAT CAN DYSREGULATE CELL SIGNALING AND CELLULAR HOMEOSTASIS CAN ALSO AFFECT MIRNA EXPRESSION. THE ALTERATION OF MIRNA EXPRESSION CAN WORK AGAINST DISTURBING FACTORS OR MEDIATE THEIR EFFECTS. OXIDATIVE STRESS IS ONE OF THESE FACTORS. CONSIDERING THE COMPLEX INTERPLAY BETWEEN ROS LEVEL AND MIRNA REGULATION AND BOTH OF THESE WITH CANCER DEVELOPMENT, WE REVIEW THE ROLE OF MIRNAS IN CANCER, FOCUSING ON THEIR FUNCTION IN OXIDATIVE STRESS. 2020 10 293 37 AGING HALLMARKS AND THE ROLE OF OXIDATIVE STRESS. AGING IS A COMPLEX BIOLOGICAL PROCESS ACCOMPANIED BY A PROGRESSIVE DECLINE IN THE PHYSICAL FUNCTION OF THE ORGANISM AND AN INCREASED RISK OF AGE-RELATED CHRONIC DISEASES SUCH AS CARDIOVASCULAR DISEASES, CANCER, AND NEURODEGENERATIVE DISEASES. STUDIES HAVE ESTABLISHED THAT THERE EXIST NINE HALLMARKS OF THE AGING PROCESS, INCLUDING (I) TELOMERE SHORTENING, (II) GENOMIC INSTABILITY, (III) EPIGENETIC MODIFICATIONS, (IV) MITOCHONDRIAL DYSFUNCTION, (V) LOSS OF PROTEOSTASIS, (VI) DYSREGULATED NUTRIENT SENSING, (VII) STEM CELL EXHAUSTION, (VIII) CELLULAR SENESCENCE, AND (IX) ALTERED CELLULAR COMMUNICATION. ALL THESE ALTERATIONS HAVE BEEN LINKED TO SUSTAINED SYSTEMIC INFLAMMATION, AND THESE MECHANISMS CONTRIBUTE TO THE AGING PROCESS IN TIMING NOT CLEARLY DETERMINED YET. NEVERTHELESS, MITOCHONDRIAL DYSFUNCTION IS ONE OF THE MOST IMPORTANT MECHANISMS CONTRIBUTING TO THE AGING PROCESS. MITOCHONDRIA IS THE PRIMARY ENDOGENOUS SOURCE OF REACTIVE OXYGEN SPECIES (ROS). DURING THE AGING PROCESS, THERE IS A DECLINE IN ATP PRODUCTION AND ELEVATED ROS PRODUCTION TOGETHER WITH A DECLINE IN THE ANTIOXIDANT DEFENSE. ELEVATED ROS LEVELS CAN CAUSE OXIDATIVE STRESS AND SEVERE DAMAGE TO THE CELL, ORGANELLE MEMBRANES, DNA, LIPIDS, AND PROTEINS. THIS DAMAGE CONTRIBUTES TO THE AGING PHENOTYPE. IN THIS REVIEW, WE SUMMARIZE RECENT ADVANCES IN THE MECHANISMS OF AGING WITH AN EMPHASIS ON MITOCHONDRIAL DYSFUNCTION AND ROS PRODUCTION. 2023 11 5010 30 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 12 4890 38 OXIDATIVE STRESS AND HEPATIC NOX PROTEINS IN CHRONIC HEPATITIS C AND HEPATOCELLULAR CARCINOMA. HEPATOCELLULAR CARCINOMA (HCC) IS THE MOST COMMON LIVER CANCER AND A LEADING CAUSE OF CANCER-RELATED MORTALITY IN THE WORLD. HEPATITIS C VIRUS (HCV) IS A MAJOR ETIOLOGIC AGENT OF HCC. A MAJORITY OF HCV INFECTIONS LEAD TO CHRONIC INFECTION THAT CAN PROGRESS TO CIRRHOSIS AND, EVENTUALLY, HCC AND LIVER FAILURE. A COMMON PATHOGENIC FEATURE PRESENT IN HCV INFECTION, AND OTHER CONDITIONS LEADING TO HCC, IS OXIDATIVE STRESS. HCV DIRECTLY INCREASES SUPEROXIDE AND H2O2 FORMATION IN HEPATOCYTES BY ELEVATING NOX PROTEIN EXPRESSION AND SENSITIZING MITOCHONDRIA TO REACTIVE OXYGEN SPECIES GENERATION WHILE DECREASING GLUTATHIONE. NITRIC OXIDE SYNTHESIS AND HEPATIC IRON ARE ALSO ELEVATED. FURTHERMORE, ACTIVATION OF PHAGOCYTIC NADPH OXIDASE (NOX) 2 OF HOST IMMUNE CELLS IS LIKELY TO EXACERBATE OXIDATIVE STRESS IN HCV-INFECTED PATIENTS. KEY MECHANISMS OF HCC INCLUDE GENOME INSTABILITY, EPIGENETIC REGULATION, INFLAMMATION WITH CHRONIC TISSUE INJURY AND SUSTAINED CELL PROLIFERATION, AND MODULATION OF CELL GROWTH AND DEATH. OXIDATIVE STRESS, OR NOX PROTEINS, PLAYS VARIOUS ROLES IN THESE MECHANISMS. NOX PROTEINS ALSO FUNCTION IN HEPATIC FIBROSIS, WHICH COMMONLY PRECEDES HCC, AND NOX4 ELEVATION BY HCV IS MEDIATED BY TRANSFORMING GROWTH FACTOR BETA. THIS REVIEW SUMMARIZES MECHANISMS OF ONCOGENESIS BY HCV, HIGHLIGHTING THE ROLES OF OXIDATIVE STRESS AND HEPATIC NOX ENZYMES IN HCC. 2014 13 4384 41 MITOCHONDRIAL EPIGENETICS REGULATING INFLAMMATION IN CANCER AND AGING. INFLAMMATION IS A DEFINING FACTOR IN DISEASE PROGRESSION; EPIGENETIC MODIFICATIONS OF THIS FIRST LINE OF DEFENCE PATHWAY CAN AFFECT MANY PHYSIOLOGICAL AND PATHOLOGICAL CONDITIONS, LIKE AGING AND TUMORIGENESIS. INFLAMMAGEING, ONE OF THE HALLMARKS OF AGING, REPRESENTS A CHRONIC, LOW KEY BUT A PERSISTENT INFLAMMATORY STATE. OXIDATIVE STRESS, ALTERATIONS IN MITOCHONDRIAL DNA (MTDNA) COPY NUMBER AND MIS-LOCALIZED EXTRA-MITOCHONDRIAL MTDNA ARE SUGGESTED TO DIRECTLY INDUCE VARIOUS IMMUNE RESPONSE PATHWAYS. THIS COULD ULTIMATELY PERTURB CELLULAR HOMEOSTASIS AND LEAD TO PATHOLOGICAL CONSEQUENCES. EPIGENETIC REMODELLING OF MTDNA BY DNA METHYLATION, POST-TRANSLATIONAL MODIFICATIONS OF MTDNA BINDING PROTEINS AND REGULATION OF MITOCHONDRIAL GENE EXPRESSION BY NUCLEAR DNA OR MTDNA ENCODED NON-CODING RNAS, ARE SUGGESTED TO DIRECTLY CORRELATE WITH THE ONSET AND PROGRESSION OF VARIOUS TYPES OF CANCER. MITOCHONDRIA ARE ALSO CAPABLE OF REGULATING IMMUNE RESPONSE TO VARIOUS INFECTIONS AND TISSUE DAMAGE BY PRODUCING PRO- OR ANTI-INFLAMMATORY SIGNALS. THIS OCCURS BY ALTERING THE LEVELS OF MITOCHONDRIAL METABOLITES AND REACTIVE OXYGEN SPECIES (ROS) LEVELS. SINCE MITOCHONDRIA ARE KNOWN AS THE GUARDIANS OF THE INFLAMMATORY RESPONSE, IT IS PLAUSIBLE THAT MITOCHONDRIAL EPIGENETICS MIGHT PLAY A PIVOTAL ROLE IN INFLAMMATION. HENCE, THIS REVIEW FOCUSES ON THE INTRICATE DYNAMICS OF EPIGENETIC ALTERATIONS OF INFLAMMATION, WITH EMPHASIS ON MITOCHONDRIA IN CANCER AND AGING. 2022 14 3837 39 IONIZING RADIATION-INDUCED OXIDATIVE STRESS, EPIGENETIC CHANGES AND GENOMIC INSTABILITY: THE PIVOTAL ROLE OF MITOCHONDRIA. PURPOSE: TO REVIEW THE DATA CONCERNING THE ROLE OF ENDOGENOUSLY GENERATED REACTIVE OXYGEN SPECIES (ROS) IN THE NON-TARGETED IONIZING RADIATION (IR) EFFECTS AND IN DETERMINATION OF THE CELL POPULATION'S FATE, BOTH EARLY AFTER EXPOSURE AND AFTER MANY GENERATIONS. CONCLUSIONS: THE SHORT-TERM AS WELL AS CHRONIC OXIDATIVE STRESS RESPONSES MAINLY ARE PRODUCED DUE TO ROS GENERATION BY THE ELECTRON TRANSPORT CHAIN (ETC) OF THE MITOCHONDRIA AND BY THE CYTOPLASMIC NADPH OXIDASES. WHETHER THE INDUCTION OF THE OXIDATIVE STRESS AND ITS CONSEQUENCES OCCUR OR ARE HAMPERED IN A SINGLE CELL LARGELY DEPENDS ON THE INTERACTION BETWEEN THE NUCLEUS AND THE CELLULAR POPULATION OF SEVERAL HUNDRED OR THOUSANDS OF MITOCHONDRIA THAT ARE GENETICALLY HETEROGENEOUS. HIGH INTRA-MITOCHONDRIAL ROS LEVEL IS DAMAGING THE MITOCHONDRIAL (MT) DNA AND ITS MUTATIONS AFFECT THE EPIGENETIC CONTROL MECHANISMS OF THE NUCLEAR (N) DNA, BY DECREASING THE ACTIVITY OF METHYLTRANSFERASES AND THUS, CAUSING GLOBAL DNA HYPOMETHYLATION. THESE CHANGES ARE TRANSMITTED TO THE PROGENY OF THE IRRADIATED CELLS. THE CHRONIC OXIDATIVE STRESS IS THE MAIN CAUSE OF THE LATE POST-RADIATION EFFECTS, INCLUDING CANCER, AND THIS MAKES IT AN IMPORTANT ADVERSE EFFECT OF EXPOSURE TO IR AND A TARGET FOR RADIOLOGICAL PROTECTION. 2015 15 4702 37 NICOTINE-INDUCED OXIDATIVE STRESS CONTRIBUTES TO EMT AND STEMNESS DURING NEOPLASTIC TRANSFORMATION THROUGH EPIGENETIC MODIFICATIONS IN HUMAN KIDNEY EPITHELIAL CELLS. NICOTINE IS A COMPONENT OF CIGARETTE SMOKE AND MOUNTING EVIDENCE SUGGESTS TOXICITY AND CARCINOGENICITY OF TOBACCO SMOKE IN KIDNEY. CARCINOGENICITY OF NICOTINE ITSELF IN KIDNEY AND THE UNDERLYING MOLECULAR MECHANISMS ARE NOT WELL-UNDERSTOOD. HENCE, THE OBJECTIVE OF THIS STUDY WAS TO DETERMINE THE CARCINOGENIC EFFECTS OF CHRONIC NICOTINE EXPOSURE IN HK-2 HUMAN KIDNEY EPITHELIAL CELLS. THE EFFECTS OF NICOTINE EXPOSURE ON THE EXPRESSION OF GENES FOR CELLULAR REPROGRAMMING, REDOX STATUS, AND GROWTH SIGNALING PATHWAYS WERE ALSO EVALUATED TO UNDERSTAND THE MOLECULAR MECHANISMS. RESULTS REVEALED THAT CHRONIC EXPOSURE TO NICOTINE INDUCED GROWTH AND NEOPLASTIC TRANSFORMATION IN HK-2 CELLS. INCREASED LEVELS OF INTRACELLULAR REACTIVE OXYGEN SPECIES (ROS), ACQUIRED STEM CELL-LIKE SPHERE FORMATION, AND EPITHELIAL-MESENCHYMAL-TRANSITION (EMT) CHANGES WERE OBSERVED IN NICOTINE EXPOSED CELLS. TREATMENT WITH ANTIOXIDANT N-ACETYL CYSTEINE (NAC) RESULTED IN ABROGATION OF EMT AND STEMNESS IN HK-2 CELLS, INDICATING THE ROLE OF NICOTINE-INDUCED ROS IN THESE MORPHOLOGICAL CHANGES. THE RESULT ALSO SUGGESTS THAT ROS CONTROLS THE STEMNESS THROUGH REGULATION OF AKT PATHWAY DURING EARLY STAGES OF CARCINOGENESIS. ADDITIONALLY, THE EXPRESSION OF EPIGENETIC REGULATORY GENES WAS ALTERED IN NICOTINE-EXPOSED CELLS AND THE CHANGES WERE REVERSED BY NAC. THE EPIGENETIC THERAPEUTICS 5-AZA-2'-DEOXYCYTIDINE AND TRICHOSTATIN A ALSO ABROGATED THE STEMNESS. THIS SUGGESTS THE NICOTINE-INDUCED OXIDATIVE STRESS CAUSED EPIGENETIC ALTERATIONS CONTRIBUTING TO STEMNESS DURING NEOPLASTIC TRANSFORMATION. TO OUR KNOWLEDGE, THIS IS THE FIRST REPORT SHOWING THE ROS-MEDIATED EPIGENETIC MODIFICATIONS AS THE UNDERLYING MECHANISM FOR CARCINOGENICITY OF NICOTINE IN HUMAN KIDNEY EPITHELIAL CELLS. THIS STUDY FURTHER SUGGESTS THE POTENTIAL OF EPIGENETIC THERAPEUTICS FOR PHARMACOLOGICAL INTERVENTION IN NICOTINE-INDUCED KIDNEY CANCER. 2019 16 616 40 BIOACTIVE COMPOUNDS IN OXIDATIVE STRESS-MEDIATED DISEASES: TARGETING THE NRF2/ARE SIGNALING PATHWAY AND EPIGENETIC REGULATION. OXIDATIVE STRESS IS A PATHOLOGICAL CONDITION OCCURRING DUE TO AN IMBALANCE BETWEEN THE OXIDANTS AND ANTIOXIDANT DEFENSE SYSTEMS IN THE BODY. NUCLEAR FACTOR E2-RELATED FACTOR 2 (NRF2), ENCODED BY THE GENE NFE2L2, IS THE MASTER REGULATOR OF PHASE II ANTIOXIDANT ENZYMES THAT PROTECT AGAINST OXIDATIVE STRESS AND INFLAMMATION. NRF2/ARE SIGNALING HAS BEEN CONSIDERED AS A PROMISING TARGET AGAINST OXIDATIVE STRESS-MEDIATED DISEASES LIKE DIABETES, FIBROSIS, NEUROTOXICITY, AND CANCER. THE CONSUMPTION OF DIETARY PHYTOCHEMICALS ACTS AS AN EFFECTIVE MODULATOR OF NRF2/ARE IN VARIOUS ACUTE AND CHRONIC DISEASES. IN THE PRESENT REVIEW, WE DISCUSSED THE ROLE OF NRF2 IN DIABETES, ALZHEIMER'S DISEASE (AD), PARKINSON'S DISEASE (PD), CANCER, AND ATHEROSCLEROSIS. ADDITIONALLY, WE DISCUSSED THE PHYTOCHEMICALS LIKE CURCUMIN, QUERCETIN, RESVERATROL, EPIGALLOCATECHIN GALLATE, APIGENIN, SULFORAPHANE, AND URSOLIC ACID THAT HAVE EFFECTIVELY MODIFIED NRF2 SIGNALING AND PREVENTED VARIOUS DISEASES IN BOTH IN VITRO AND IN VIVO MODELS. BASED ON THE LITERATURE, IT IS CLEAR THAT DIETARY PHYTOCHEMICALS CAN PREVENT DISEASES BY (1) BLOCKING OXIDATIVE STRESS-INHIBITING INFLAMMATORY MEDIATORS THROUGH INHIBITING KEAP1 OR ACTIVATING NRF2 EXPRESSION AND ITS DOWNSTREAM TARGETS IN THE NUCLEUS, INCLUDING HO-1, SOD, AND CAT; (2) REGULATING NRF2 SIGNALING BY VARIOUS KINASES LIKE GSK3BETA, PI3/AKT, AND MAPK; AND (3) MODIFYING EPIGENETIC MODULATION, SUCH AS METHYLATION, AT THE NRF2 PROMOTER REGION; HOWEVER, FURTHER INVESTIGATION INTO OTHER UPSTREAM SIGNALING MOLECULES LIKE NRF2 AND THE EFFECT OF PHYTOCHEMICALS ON THEM STILL NEED TO BE INVESTIGATED IN THE NEAR FUTURE. 2021 17 6456 34 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 18 1201 43 CORTICOTROPIN-RELEASING FACTOR RECEPTOR-1 MODULATES BIOMARKERS OF DNA OXIDATION IN ALZHEIMER'S DISEASE MICE. INCREASED PRODUCTION OF HYDROXYL RADICAL IS THE MAIN SOURCE OF OXIDATIVE DAMAGE IN MAMMALIAN DNA THAT ACCUMULATES IN ALZHEIMER'S DISEASE (AD). REACTIVE OXYGEN SPECIES (ROS) REACT WITH BOTH NUCLEAR DNA (NDNA) AND MITOCHONDRIAL DNA (MTDNA) TO GENERATE 8-HYDROXY-2'-DEOXYGUANOSINE (8-OHDG), BOTH OF WHICH CAN BE MEASURED IN THE URINE. KNOWLEDGE OF THIS PATHWAY HAS POSITIONED MEASUREMENT OF URINE 8-OHDG AS A RELIABLE INDEX OF DNA OXIDATION AND A POTENTIAL BIOMARKER TARGET FOR TRACKING EARLY CELLULAR DYSFUNCTION IN AD. FURTHERMORE, EPIGENETIC STUDIES DEMONSTRATE DECREASED GLOBAL DNA METHYLATION LEVELS (E.G. 5-METHYL-2'-DEOXYCYTIDINE, 5-MDC) IN AD TISSUES. MOREOVER, STRESS HORMONES CAN ACTIVATE NEURONAL OXIDATIVE STRESS WHICH WILL STIMULATE THE RELEASE OF ADDITIONAL STRESS HORMONES AND RESULT IN DAMAGES TO HIPPOCAMPAL NEURONS IN THE AD BRAIN. OUR PREVIOUS WORK SUGGESTS THAT TREATING AD TRANSGENIC MICE THE TYPE-1 CORTICOTROPIN-RELEASING FACTOR RECEPTOR (CRFR1) ANTAGONIST, R121919, TO REDUCE STRESS SIGNALING, PREVENTED ONSET OF COGNITIVE IMPAIRMENT, SYNAPTIC/DENDRITIC LOSS AND ABETA PLAQUE ACCUMULATION. THEREFORE, TO INVESTIGATE WHETHER LEVELS OF DNA OXIDATION CAN BE IMPACTED BY THE SAME THERAPEUTIC APPROACH, URINE LEVELS OF HYDROGEN PEROXIDE, 8-OHDG, 5-MDC AND TOTAL ANTIOXIDANT CAPACITY (TAC) WERE ANALYZED USING AN AD TG MOUSE MODEL. WE FOUND THAT TG ANIMALS HAD AN 80% INCREASE IN HYDROGEN PEROXIDE LEVELS COMPARED TO WILD TYPE (WT) COUNTERPARTS, AN EFFECT THAT COULD BE DRAMATICALLY REVERSED BY THE CHRONIC ADMINISTRATION WITH R121919. A SIGNIFICANT DECREASE OF 8-OHDG LEVELS WAS OBSERVED IN TG MICE TREATED WITH CRFR1 ANTAGONIST. COLLECTIVELY OUR DATA SUGGEST THAT THE BENEFICIAL EFFECTS OF CRFR1 ANTAGONISM SEEN IN TG MICE MAY BE MECHANISTICALLY LINKED TO THE MODULATION OF OXIDATIVE STRESS PATHWAYS. 2017 19 4897 43 OXIDATIVE STRESS IN ALCOHOL-RELATED LIVER DISEASE. ALCOHOL CONSUMPTION IS ONE OF THE LEADING CAUSES OF THE GLOBAL BURDEN OF DISEASE AND RESULTS IN HIGH HEALTHCARE AND ECONOMIC COSTS. HEAVY ALCOHOL MISUSE LEADS TO ALCOHOL-RELATED LIVER DISEASE, WHICH IS RESPONSIBLE FOR A SIGNIFICANT PROPORTION OF ALCOHOL-ATTRIBUTABLE DEATHS GLOBALLY. OTHER THAN REDUCING ALCOHOL CONSUMPTION, THERE ARE CURRENTLY NO EFFECTIVE TREATMENTS FOR ALCOHOL-RELATED LIVER DISEASE. OXIDATIVE STRESS REFERS TO AN IMBALANCE IN THE PRODUCTION AND ELIMINATION OF REACTIVE OXYGEN SPECIES AND ANTIOXIDANTS. IT PLAYS IMPORTANT ROLES IN SEVERAL ASPECTS OF ALCOHOL-RELATED LIVER DISEASE PATHOGENESIS. HERE, WE REVIEW HOW CHRONIC ALCOHOL USE RESULTS IN OXIDATIVE STRESS THROUGH INCREASED METABOLISM VIA THE CYTOCHROME P450 2E1 SYSTEM PRODUCING REACTIVE OXYGEN SPECIES, ACETALDEHYDE AND PROTEIN AND DNA ADDUCTS. THESE TRIGGER INFLAMMATORY SIGNALING PATHWAYS WITHIN THE LIVER LEADING TO EXPRESSION OF PRO-INFLAMMATORY MEDIATORS CAUSING HEPATOCYTE APOPTOSIS AND NECROSIS. REACTIVE OXYGEN SPECIES EXPOSURE ALSO RESULTS IN MITOCHONDRIAL STRESS WITHIN HEPATOCYTES CAUSING STRUCTURAL AND FUNCTIONAL DYSREGULATION OF MITOCHONDRIA AND UPREGULATING APOPTOTIC SIGNALING. THERE IS ALSO EVIDENCE THAT OXIDATIVE STRESS AS WELL AS THE DIRECT EFFECT OF ALCOHOL INFLUENCES EPIGENETIC REGULATION. INCREASED GLOBAL HISTONE METHYLATION AND ACETYLATION AND SPECIFIC HISTONE ACETYLATION INHIBITS ANTIOXIDANT RESPONSES AND PROMOTES EXPRESSION OF KEY PRO-INFLAMMATORY GENES. THIS REVIEW HIGHLIGHTS ASPECTS OF THE ROLE OF OXIDATIVE STRESS IN DISEASE PATHOGENESIS THAT WARRANT FURTHER STUDY INCLUDING MITOCHONDRIAL STRESS AND EPIGENETIC REGULATION. IMPROVED UNDERSTANDING OF THESE PROCESSES MAY IDENTIFY NOVEL TARGETS FOR THERAPY. 2020 20 449 25 APOCYNIN PREVENTS ANXIETY-LIKE BEHAVIOR AND HISTONE DEACETYLASES OVEREXPRESSION INDUCED BY SUB-CHRONIC STRESS IN MICE. ANXIETY DISORDERS ARE COMMON MENTAL HEALTH DISEASES AFFECTING UP TO 7% OF PEOPLE AROUND THE WORLD. STRESS IS CONSIDERED ONE OF THE MAJOR ENVIRONMENTAL RISK FACTORS TO PROMOTE ANXIETY DISORDERS THROUGH MECHANISMS INVOLVING EPIGENETIC CHANGES. MOREOVER, ALTERATION IN REDOX BALANCE AND INCREASED REACTIVE OXYGEN SPECIES (ROS) PRODUCTION HAVE BEEN DETECTED IN ANXIETY PATIENTS AND IN STRESSED-ANIMAL MODELS OF ANXIETY. HERE WE TESTED IF THE ADMINISTRATION OF APOCYNIN, A NATURAL ORIGIN ANTIOXIDANT, MAY PREVENT THE ANXIETY-LIKE PHENOTYPE AND REDUCTION OF HISTONE ACETYLATION INDUCED BY A SUBCHRONIC FORCED SWIMMING STRESS (FSS) PARADIGM. WE FOUND THAT APOCYNIN PREVENTED THE ENHANCED LATENCY TIME IN THE NOVELTY-SUPPRESSED FEEDING TEST, AND THE PRODUCTION OF MALONDIALDEHYDE INDUCED BY FSS. MOREOVER, APOCYNIN WAS ABLE TO BLOCK THE UPREGULATION OF P47PHOX, A KEY SUBUNIT OF THE NADPH OXIDASE COMPLEX. FINALLY, APOCYNIN PREVENTED THE RISE OF HIPPOCAMPAL HDAC1, HDAC4 AND HDAC5, AND THE REDUCTION OF HISTONE-3 ACETYLATION LEVELS PROMOTED BY FSS EXPOSURE. IN CONCLUSION, OUR RESULTS PROVIDE EVIDENCE THAT APOCYNIN REDUCES THE DELETERIOUS EFFECT OF STRESS AND SUGGESTS THAT OXIDATIVE STRESS MAY REGULATE EPIGENETIC MECHANISMS. 2021