1 2821 84 FINE-TUNING AUTOPHAGY: FROM TRANSCRIPTIONAL TO POSTTRANSLATIONAL REGULATION. MACROAUTOPHAGY (HEREAFTER CALLED AUTOPHAGY) IS A VACUOLAR LYSOSOMAL PATHWAY FOR DEGRADATION OF INTRACELLULAR MATERIAL IN EUKARYOTIC CELLS. AUTOPHAGY PLAYS CRUCIAL ROLES IN TISSUE HOMEOSTASIS, IN ADAPTATION TO STRESS SITUATIONS, AND IN IMMUNE AND INFLAMMATORY RESPONSES. ALTERATION OF AUTOPHAGY IS ASSOCIATED WITH CANCER, DIABETES AND OBESITY, CARDIOVASCULAR DISEASE, NEURODEGENERATIVE DISEASE, AUTOIMMUNE DISEASE, INFECTION, AND CHRONIC INFLAMMATORY DISEASE. AUTOPHAGY IS CONTROLLED BY AUTOPHAGY-RELATED (ATG) PROTEINS THAT ACT IN A COORDINATED MANNER TO BUILD UP THE INITIAL AUTOPHAGIC VACUOLE NAMED THE AUTOPHAGOSOME. IT IS NOW KNOWN THAT THE ACTIVITIES OF ATG PROTEINS ARE MODULATED BY POSTTRANSLATIONAL MODIFICATIONS SUCH AS PHOSPHORYLATION, UBIQUITINATION, AND ACETYLATION. MOREOVER, TRANSCRIPTIONAL AND EPIGENETIC CONTROLS ARE INVOLVED IN THE REGULATION OF AUTOPHAGY IN STRESS SITUATIONS. HERE WE SUMMARIZE AND DISCUSS HOW POSTTRANSLATIONAL MODIFICATIONS AND TRANSCRIPTIONAL AND EPIGENETIC CONTROLS REGULATE THE INVOLVEMENT OF AUTOPHAGY IN THE PROTEOSTASIS NETWORK. 2016 2 4211 33 METFORMIN FOR CARDIOVASCULAR PROTECTION, INFLAMMATORY BOWEL DISEASE, OSTEOPOROSIS, PERIODONTITIS, POLYCYSTIC OVARIAN SYNDROME, NEURODEGENERATION, CANCER, INFLAMMATION AND SENESCENCE: WHAT IS NEXT? DIABETES IS ACCOMPANIED BY SEVERAL COMPLICATIONS. HIGHER PREVALENCE OF CANCERS, CARDIOVASCULAR DISEASES, CHRONIC KIDNEY DISEASE (CKD), OBESITY, OSTEOPOROSIS, AND NEURODEGENERATIVE DISEASES HAS BEEN REPORTED AMONG PATIENTS WITH DIABETES. METFORMIN IS THE OLDEST ORAL ANTIDIABETIC DRUG AND CAN IMPROVE COEXISTING COMPLICATIONS OF DIABETES. CLINICAL TRIALS AND OBSERVATIONAL STUDIES UNCOVERED THAT METFORMIN CAN REMARKABLY PREVENT OR ALLEVIATE CARDIOVASCULAR DISEASES, OBESITY, POLYCYSTIC OVARIAN SYNDROME (PCOS), OSTEOPOROSIS, CANCER, PERIODONTITIS, NEURONAL DAMAGE AND NEURODEGENERATIVE DISEASES, INFLAMMATION, INFLAMMATORY BOWEL DISEASE (IBD), TUBERCULOSIS, AND COVID-19. IN ADDITION, METFORMIN HAS BEEN PROPOSED AS AN ANTIAGING AGENT. NUMEROUS MECHANISMS WERE SHOWN TO BE INVOLVED IN THE PROTECTIVE EFFECTS OF METFORMIN. METFORMIN ACTIVATES THE LKB1/AMPK PATHWAY TO INTERACT WITH SEVERAL INTRACELLULAR SIGNALING PATHWAYS AND MOLECULAR MECHANISMS. THE DRUG MODIFIES THE BIOLOGIC FUNCTION OF NF-KAPPAB, PI3K/AKT/MTOR, SIRT1/PGC-1ALPHA, NLRP3, ERK, P38 MAPK, WNT/BETA-CATENIN, NRF2, JNK, AND OTHER MAJOR MOLECULES IN THE INTRACELLULAR SIGNALING NETWORK. IT ALSO REGULATES THE EXPRESSION OF NONCODING RNAS. THEREBY, METFORMIN CAN REGULATE METABOLISM, GROWTH, PROLIFERATION, INFLAMMATION, TUMORIGENESIS, AND SENESCENCE. ADDITIONALLY, METFORMIN MODULATES IMMUNE RESPONSE, AUTOPHAGY, MITOPHAGY, ENDOPLASMIC RETICULUM (ER) STRESS, AND APOPTOSIS AND EXERTS EPIGENETIC EFFECTS. FURTHERMORE, METFORMIN PROTECTS AGAINST OXIDATIVE STRESS AND GENOMIC INSTABILITY, PRESERVES TELOMERE LENGTH, AND PREVENTS STEM CELL EXHAUSTION. IN THIS REVIEW, THE PROTECTIVE EFFECTS OF METFORMIN ON EACH DISEASE WILL BE DISCUSSED USING THE RESULTS OF RECENT META-ANALYSES, CLINICAL TRIALS, AND OBSERVATIONAL STUDIES. THEREAFTER, IT WILL BE METICULOUSLY EXPLAINED HOW METFORMIN REPROGRAMS INTRACELLULAR SIGNALING PATHWAYS AND ALTERS MOLECULAR AND CELLULAR INTERACTIONS TO MODIFY THE CLINICAL PRESENTATIONS OF SEVERAL DISEASES. 2021 3 5993 19 TGFBETA PROMOTES FIBROSIS BY MYST1-DEPENDENT EPIGENETIC REGULATION OF AUTOPHAGY. ACTIVATION OF FIBROBLASTS IS ESSENTIAL FOR PHYSIOLOGICAL TISSUE REPAIR. UNCONTROLLED ACTIVATION OF FIBROBLASTS, HOWEVER, MAY LEAD TO TISSUE FIBROSIS WITH ORGAN DYSFUNCTION. ALTHOUGH SEVERAL PATHWAYS CAPABLE OF PROMOTING FIBROBLAST ACTIVATION AND TISSUE REPAIR HAVE BEEN IDENTIFIED, THEIR INTERPLAY IN THE CONTEXT OF CHRONIC FIBROTIC DISEASES REMAINS INCOMPLETELY UNDERSTOOD. HERE, WE PROVIDE EVIDENCE THAT TRANSFORMING GROWTH FACTOR-BETA (TGFBETA) ACTIVATES AUTOPHAGY BY AN EPIGENETIC MECHANISM TO AMPLIFY ITS PROFIBROTIC EFFECTS. TGFBETA INDUCES AUTOPHAGY IN FIBROTIC DISEASES BY SMAD3-DEPENDENT DOWNREGULATION OF THE H4K16 HISTONE ACETYLTRANSFERASE MYST1, WHICH REGULATES THE EXPRESSION OF CORE COMPONENTS OF THE AUTOPHAGY MACHINERY SUCH AS ATG7 AND BECLIN1. ACTIVATION OF AUTOPHAGY IN FIBROBLASTS PROMOTES COLLAGEN RELEASE AND IS BOTH, SUFFICIENT AND REQUIRED, TO INDUCE TISSUE FIBROSIS. FORCED EXPRESSION OF MYST1 ABROGATES THE STIMULATORY EFFECTS OF TGFBETA ON AUTOPHAGY AND RE-ESTABLISHES THE EPIGENETIC CONTROL OF AUTOPHAGY IN FIBROTIC CONDITIONS. INTERFERENCE WITH THE ABERRANT ACTIVATION OF AUTOPHAGY INHIBITS TGFBETA-INDUCED FIBROBLAST ACTIVATION AND AMELIORATES EXPERIMENTAL DERMAL AND PULMONARY FIBROSIS. THESE FINDINGS LINK UNCONTROLLED TGFBETA SIGNALING TO ABERRANT AUTOPHAGY AND DEREGULATED EPIGENETICS IN FIBROTIC DISEASES AND MAY CONTRIBUTE TO THE DEVELOPMENT OF THERAPEUTIC INTERVENTIONS IN FIBROTIC DISEASES. 2021 4 4117 30 MECHANISMS OF AUTOPHAGIC RESPONSES TO ALTERED NUTRITIONAL STATUS. AUTOPHAGY IS A DYNAMIC PROCESS AND CRITICAL FOR CELLULAR REMODELING AND ORGANELLE QUALITY CONTROL. IN RESPONSE TO ALTERED NUTRITIONAL STATUS (E.G., FASTING AND FEEDING), AUTOPHAGIC ACTIVITY IS FINELY TUNED BY TRANSCRIPTIONAL, POSTTRANSLATIONAL, AND EPIGENETIC REGULATIONS VIA VARIOUS SIGNALING PATHWAYS, INCLUDING ENERGY SENSORS (E.G., MECHANISTIC TARGET OF RAPAMYCIN (MTOR)/ AMP-ACTIVATED PROTEIN KINASE - UNC-51 LIKE AUTOPHAGY ACTIVATING KINASE 1, MTORC1- WD REPEAT DOMAIN, PHOSPHOINOSITIDE INTERACTING 2, MTORC1- TRANSCRIPTION FACTOR EB, PERILIPIN 5- SIRTUIN 1, AND SIRTUIN 1-MEDIATED DEACETYLATION OF AUTOPHAGY PROTEINS), FASTING OR FEEDING INDUCED HORMONES (E.G., FIBROBLAST GROWTH FACTOR [FGF21]- PROTEIN KINASE A - JUMONJI DOMAIN-CONTAINING PROTEIN D3, FGF21- DOWNSTREAM REGULATORY ELEMENT ANTAGONIST MODULATOR - E3 LIGASE MIDLINE-1- TRANSCRIPTION FACTOR EB, FGF19-SHP- LYSINE-SPECIFIC DEMETHYLASE, INSULIN- INSULIN RECEPTOR SUBSTRATE - PROTEIN KINASE B - FORKHEAD BOX O, GLUCAGON- PROTEIN KINASE A - CAMP RESPONSE BINDING PROTEIN), AND LYSOSOMAL ENZYMES (E.G., CATHEPSIN B AND CATHEPSIN L). IN CONTRAST TO FASTING THAT INDUCES AUTOPHAGY AND HEALTH BENEFITS, NUTRIENT OVERSUPPLY (OVERFEEDING OR FEEDING ON HIGH ENERGY DIETS) DYSREGULATES AUTOPHAGY, WHICH HAS BEEN INCREASINGLY OBSERVED IN ANIMAL MODELS OF HUMAN CHRONIC DISEASES SUCH AS OBESITY, DIABETES, NON-ALCOHOLIC FATTY LIVER DISEASE, AND CARDIOVASCULAR DISEASE. STUDIES HAVE REVEALED MULTIFACETED EFFECTS OF HIGH ENERGY DIETS ON AUTOPHAGY, BEING EITHER AN INHIBITOR OR ENHANCER OF AUTOPHAGY. THE CONUNDRUM MAY ARISE FROM THE VARIATIONS IN METHODS FOR AUTOPHAGY ANALYSIS, COMPONENTS OF HIGH ENERGY DIETS AND CONTROL DIETS FOR TREATMENTS, TREATMENT DURATIONS, AND THE AGES OF GENETIC BACKGROUNDS OF LABORATORY ANIMALS. IN THIS ARTICLE, WE REVIEWED THE EVIDENCE FROM BOTH HUMAN AND ANIMAL STUDIES, PRESENTING THE MOLECULAR MECHANISM OF AUTOPHAGIC RESPONSE TO ALTERED NUTRITIONAL STATUS AND DISCUSSING THE CONTRIBUTING FACTORS OF AND POSSIBLE SOLUTION TO THE CURRENT CONUNDRUM CONCERNING THE EXACT ROLE OF HIGH ENERGY DIETS IN AUTOPHAGIC REGULATION. 2022 5 5986 30 TFEB IS A CENTRAL REGULATOR OF THE AGING PROCESS AND AGE-RELATED DISEASES. OLD AGE IS ASSOCIATED WITH A GREATER BURDEN OF DISEASE, INCLUDING NEURODEGENERATIVE DISORDERS SUCH AS ALZHEIMER'S DISEASE AND PARKINSON'S DISEASE, AS WELL AS OTHER CHRONIC DISEASES. COINCIDENTALLY, POPULAR LIFESTYLE INTERVENTIONS, SUCH AS CALORIC RESTRICTION, INTERMITTENT FASTING, AND REGULAR EXERCISE, IN ADDITION TO PHARMACOLOGICAL INTERVENTIONS INTENDED TO PROTECT AGAINST AGE-RELATED DISEASES, INDUCE TRANSCRIPTION FACTOR EB (TFEB) AND AUTOPHAGY. IN THIS REVIEW, WE SUMMARIZE EMERGING DISCOVERIES THAT POINT TO TFEB ACTIVITY AFFECTING THE HALLMARKS OF AGING, INCLUDING INHIBITING DNA DAMAGE AND EPIGENETIC MODIFICATIONS, INDUCING AUTOPHAGY AND CELL CLEARANCE TO PROMOTE PROTEOSTASIS, REGULATING MITOCHONDRIAL QUALITY CONTROL, LINKING NUTRIENT-SENSING TO ENERGY METABOLISM, REGULATING PRO- AND ANTI-INFLAMMATORY PATHWAYS, INHIBITING SENESCENCE AND PROMOTING CELL REGENERATIVE CAPACITY. FURTHERMORE, THE THERAPEUTIC IMPACT OF TFEB ACTIVATION ON NORMAL AGING AND TISSUE-SPECIFIC DISEASE DEVELOPMENT IS ASSESSED IN THE CONTEXTS OF NEURODEGENERATION AND NEUROPLASTICITY, STEM CELL DIFFERENTIATION, IMMUNE RESPONSES, MUSCLE ENERGY ADAPTATION, ADIPOSE TISSUE BROWNING, HEPATIC FUNCTIONS, BONE REMODELING, AND CANCER. SAFE AND EFFECTIVE STRATEGIES OF ACTIVATING TFEB HOLD PROMISE AS A THERAPEUTIC STRATEGY FOR MULTIPLE AGE-ASSOCIATED DISEASES AND FOR EXTENDING LIFESPAN. 2023 6 5322 18 PULMONARY DISEASES AND AGEING. CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) AND IDIOPATHIC PULMONARY FIBROSIS ARE REGARDED AS A DISEASES OF ACCELERATED LUNG AGEING AND SHOW ALL OF THE HALLMARKS OF AGEING, INCLUDING TELOMERE SHORTENING, CELLULAR SENESCENCE, ACTIVATION OF PI3 KINASE-MTOR SIGNALING, IMPAIRED AUTOPHAGY, MITOCHONDRIAL DYSFUNCTION, STEM CELL EXHAUSTION, EPIGENETIC CHANGES, ABNORMAL MICRORNA PROFILES, IMMUNOSENESCENCE AND A LOW GRADE CHRONIC INFLAMMATION DUE TO SENESCENCE-ASSOCIATED SECRETORY PHENOTYPE (SASP). MANY OF THESE AGEING MECHANISMS ARE DRIVEN BY EXOGENOUS AND ENDOGENOUS OXIDATIVE STRESS. THERE IS ALSO A REDUCTION IN ANTI-AGEING MOLECULES, SUCH AS SIRTUINS AND KLOTHO, WHICH FURTHER ACCELERATE THE AGEING PROCESS. UNDERSTANDING THESE MOLECULAR MECHANISMS HAS IDENTIFIED SEVERAL NOVEL THERAPEUTIC TARGETS AND SEVERAL DRUGS AND DIETARY INTERVENTIONS ARE NOW IN DEVELOPMENT TO TREAT CHRONIC LUNG DISEASE. 2019 7 5629 22 SENESCENCE IN COPD AND ITS COMORBIDITIES. CHRONIC OBSTRUCTIVE PULMONARY DISEASE (COPD) IS REGARDED AS A DISEASE OF ACCELERATED LUNG AGING. THIS AFFLICTION SHOWS ALL OF THE HALLMARKS OF AGING, INCLUDING TELOMERE SHORTENING, CELLULAR SENESCENCE, ACTIVATION OF PI3 KINASE-MTOR SIGNALING, IMPAIRED AUTOPHAGY, MITOCHONDRIAL DYSFUNCTION, STEM CELL EXHAUSTION, EPIGENETIC CHANGES, ABNORMAL MICRORNA PROFILES, IMMUNOSENESCENCE, AND A LOW-GRADE CHRONIC INFLAMMATION (INFLAMMAGING). MANY OF THESE PATHWAYS ARE DRIVEN BY CHRONIC EXOGENOUS AND ENDOGENOUS OXIDATIVE STRESS. THERE IS ALSO A REDUCTION IN ANTIAGING MOLECULES, SUCH AS SIRTUINS AND KLOTHO, WHICH FURTHER ACCELERATE THE AGING PROCESS. COPD IS ASSOCIATED WITH SEVERAL COMORBIDITIES (MULTIMORBIDITY), SUCH AS CARDIOVASCULAR AND METABOLIC DISEASES, THAT SHARE THE SAME PATHWAYS OF ACCELERATED AGING. UNDERSTANDING THESE MECHANISMS HAS HELPED IDENTIFY SEVERAL NOVEL THERAPEUTIC TARGETS, AND SEVERAL DRUGS AND DIETARY INTERVENTIONS ARE NOW IN DEVELOPMENT TO TREAT MULTIMORBIDITY. 2017 8 6441 22 THERAPEUTIC APPROACHES FOR NONALCOHOLIC FATTY LIVER DISEASE: ESTABLISHED TARGETS AND DRUGS. NONALCOHOLIC FATTY LIVER DISEASE (NAFLD), AS A MULTISYSTEMIC DISEASE, IS THE MOST PREVALENT CHRONIC LIVER DISEASE CHARACTERIZED BY EXTREMELY COMPLEX PATHOGENIC MECHANISMS AND MULTIFACTORIAL ETIOLOGY, WHICH OFTEN DEVELOPS AS A CONSEQUENCE OF OBESITY, METABOLIC SYNDROME. PATHOPHYSIOLOGICAL MECHANISMS INVOLVED IN THE DEVELOPMENT OF NAFLD INCLUDE DIET, OBESITY, INSULIN RESISTANCE (IR), GENETIC AND EPIGENETIC DETERMINANTS, INTESTINAL DYSBIOSIS, OXIDATIVE/NITROSATIVE STRESS, AUTOPHAGY DYSREGULATION, HEPATIC INFLAMMATION, GUT-LIVER AXIS, GUT MICROBES, IMPAIRED MITOCHONDRIAL METABOLISM AND REGULATION OF HEPATIC LIPID METABOLISM. SOME OF THE NEW DRUGS FOR THE TREATMENT OF NAFLD ARE INTRODUCED HERE. ALL OF THEM ACHIEVE THERAPEUTIC OBJECTIVES BY INTERFERING WITH CERTAIN PATHOPHYSIOLOGICAL PATHWAYS OF NAFLD, INCLUDING FIBROBLAST GROWTH FACTORS (FGF) ANALOGUES, PEROXISOME PROLIFERATOR-ACTIVATED RECEPTORS (PPARS) AGONISTS, GLUCAGON-LIKE PEPTIDE-1 (GLP-1) AGONISTS, G PROTEIN-COUPLED RECEPTORS (GPCRS), SODIUM-GLUCOSE COTRANSPORTER-2 INHIBITORS (SGLT-2I), FARNESOID X RECEPTOR (FXR), FATTY ACID SYNTHASE INHIBITOR (FASNI), ANTIOXIDANTS, ETC. THIS REVIEW DESCRIBES SOME PATHOPHYSIOLOGICAL MECHANISMS OF NAFLD AND ESTABLISHED TARGETS AND DRUGS. 2023 9 554 31 AUTOPHAGY IN HUMAN HEALTH AND DISEASE: NOVEL THERAPEUTIC OPPORTUNITIES. SIGNIFICANCE: IN EUKARYOTES, AUTOPHAGY REPRESENTS A HIGHLY EVOLUTIONARY CONSERVED PROCESS, THROUGH WHICH MACROMOLECULES AND CYTOPLASMIC MATERIAL ARE DEGRADED INTO LYSOSOMES AND RECYCLED FOR BIOSYNTHETIC OR ENERGETIC PURPOSES. DYSFUNCTION OF THE AUTOPHAGIC PROCESS HAS BEEN ASSOCIATED WITH THE ONSET AND DEVELOPMENT OF MANY HUMAN CHRONIC PATHOLOGIES, SUCH AS CARDIOVASCULAR, METABOLIC, AND NEURODEGENERATIVE DISEASES AS WELL AS CANCER. RECENT ADVANCES: CURRENTLY, COMPREHENSIVE RESEARCH IS BEING CARRIED OUT TO DISCOVER NEW THERAPEUTIC AGENTS THAT ARE ABLE TO MODULATE THE AUTOPHAGIC PROCESS IN VIVO. RECENT EVIDENCE HAS SHOWN THAT A LARGE NUMBER OF NATURAL BIOACTIVE COMPOUNDS ARE INVOLVED IN THE REGULATION OF AUTOPHAGY BY MODULATING SEVERAL TRANSCRIPTIONAL FACTORS AND SIGNALING PATHWAYS. CRITICAL ISSUES: CRITICAL ISSUES THAT DESERVE PARTICULAR ATTENTION ARE THE INADEQUATE UNDERSTANDING OF THE COMPLEX ROLE OF AUTOPHAGY IN DISEASE PATHOGENESIS, THE LIMITED AVAILABILITY OF THERAPEUTIC DRUGS, AND THE LACK OF CLINICAL TRIALS. IN THIS CONTEXT, THE EFFECTS THAT NATURAL BIOACTIVE COMPOUNDS EXERT ON AUTOPHAGIC MODULATION SHOULD BE CLEARLY HIGHLIGHTED, SINCE THEY DEPEND ON THE TYPE AND STAGE OF THE PATHOLOGICAL CONDITIONS OF DISEASES. FUTURE DIRECTIONS: RESEARCH EFFORTS SHOULD NOW FOCUS ON UNDERSTANDING THE SURVIVAL-SUPPORTING AND DEATH-PROMOTING ROLES OF AUTOPHAGY, HOW NATURAL COMPOUNDS INTERACT EXACTLY WITH THE AUTOPHAGIC TARGETS SO AS TO INDUCE OR INHIBIT AUTOPHAGY AND ON THE EVALUATION OF THEIR PHARMACOLOGICAL EFFECTS IN A MORE IN-DEPTH AND MECHANISTIC WAY. IN ADDITION, CLINICAL STUDIES ON AUTOPHAGY-INDUCING NATURAL PRODUCTS ARE STRONGLY ENCOURAGED, ALSO TO HIGHLIGHT SOME FUNDAMENTAL ASPECTS, SUCH AS THE DOSE, THE DURATION, AND THE POSSIBLE SYNERGISTIC ACTION OF THESE COMPOUNDS WITH CONVENTIONAL THERAPY. 2019 10 5811 22 STRESS - (SELF) EATING: EPIGENETIC REGULATION OF AUTOPHAGY IN RESPONSE TO PSYCHOLOGICAL STRESS. AUTOPHAGY IS A CONSTITUTIVE AND CYTOPROTECTIVE CATABOLIC PROCESS. ABERRATIONS IN AUTOPHAGY LEAD TO A MULTITUDE OF DEGENERATIVE DISORDERS, WITH NEURODEGENERATION BEING ONE OF THE MOST WIDELY STUDIED AUTOPHAGY-RELATED DISORDERS. WHILE THE FIELD HAS LARGELY BEEN FOCUSING ON THE CYTOSOLIC CONSTITUENTS AND PROCESSES OF AUTOPHAGY, RECENT STUDIES ARE INCREASINGLY APPRECIATING THE ROLE OF CHROMATIN MODIFICATIONS AND EPIGENETIC REGULATION IN AUTOPHAGY MAINTENANCE. AUTOPHAGY HAS BEEN IMPLICATED IN THE REGULATION OF NEUROGENESIS, AND DISRUPTION OF NEUROGENESIS IN RESPONSE TO PSYCHOLOGICAL STRESS IS A PROXIMAL RISK FACTOR FOR DEVELOPMENT OF NEUROPSYCHIATRIC DISORDERS SUCH AS MAJOR DEPRESSIVE DISORDER (MDD). IN THIS REVIEW, WE WILL DISCUSS THE REGULATION OF AUTOPHAGY IN NORMAL NEUROGENESIS AS WELL AS DURING CHRONIC PSYCHOLOGICAL STRESS, FOCUSING ON THE EPIGENETIC CONTROL OF AUTOPHAGY IN THESE CONTEXTS, AND ALSO HIGHLIGHT THE LACUNAE IN OUR UNDERSTANDING OF THIS PROCESS. THE SYSTEMATIC STUDY OF THESE REGULATORY MECHANISMS WILL PROVIDE A NOVEL THERAPEUTIC STRATEGY, BASED ON THE USE EPIGENETIC REGULATORS OF AUTOPHAGY TO ENHANCE NEUROGENESIS AND POTENTIALLY ALLEVIATE STRESS-RELATED BEHAVIORAL DISORDERS. 2019 11 4136 24 MECHANISMS OF MANGANESE-INDUCED NEUROTOXICITY AND THE PURSUIT OF NEUROTHERAPEUTIC STRATEGIES. CHRONIC EXPOSURE TO ELEVATED LEVELS OF MANGANESE VIA OCCUPATIONAL OR ENVIRONMENTAL SETTINGS CAUSES A NEUROLOGICAL DISORDER KNOWN AS MANGANISM, RESEMBLING THE SYMPTOMS OF PARKINSON'S DISEASE, SUCH AS MOTOR DEFICITS AND COGNITIVE IMPAIRMENT. NUMEROUS STUDIES HAVE BEEN CONDUCTED TO CHARACTERIZE MANGANESE'S NEUROTOXICITY MECHANISMS IN SEARCH OF EFFECTIVE THERAPEUTICS, INCLUDING NATURAL AND SYNTHETIC COMPOUNDS TO TREAT MANGANESE TOXICITY. SEVERAL POTENTIAL MOLECULAR TARGETS OF MANGANESE TOXICITY AT THE EPIGENETIC AND TRANSCRIPTIONAL LEVELS HAVE BEEN IDENTIFIED RECENTLY, WHICH MAY CONTRIBUTE TO DEVELOP MORE PRECISE AND EFFECTIVE GENE THERAPIES. THIS REVIEW UPDATES FINDINGS ON MANGANESE-INDUCED NEUROTOXICITY MECHANISMS ON INTRACELLULAR INSULTS SUCH AS OXIDATIVE STRESS, INFLAMMATION, EXCITOTOXICITY, AND MITOPHAGY, AS WELL AS TRANSCRIPTIONAL DYSREGULATIONS INVOLVING YIN YANG 1, RE1-SILENCING TRANSCRIPTION FACTOR, TRANSCRIPTION FACTOR EB, AND NUCLEAR FACTOR ERYTHROID 2-RELATED FACTOR 2 THAT COULD BE TARGETS OF MANGANESE NEUROTOXICITY THERAPIES. THIS REVIEW ALSO FEATURES INTRACELLULAR PROTEINS SUCH AS PTEN-INDUCIBLE KINASE 1, PARKIN, SIRTUINS, LEUCINE-RICH REPEAT KINASE 2, AND ALPHA-SYNUCLEIN, WHICH ARE ASSOCIATED WITH MANGANESE-INDUCED DYSREGULATION OF AUTOPHAGY/MITOPHAGY. IN ADDITION, NEWER THERAPEUTIC APPROACHES TO TREAT MANGANESE'S NEUROTOXICITY INCLUDING NATURAL AND SYNTHETIC COMPOUNDS MODULATING EXCITOTOXICITY, AUTOPHAGY, AND MITOPHAGY, WERE REVIEWED. TAKEN TOGETHER, IN-DEPTH MECHANISTIC KNOWLEDGE ACCOMPANIED BY ADVANCES IN GENE AND DRUG DELIVERY STRATEGIES WILL MAKE SIGNIFICANT PROGRESS IN THE DEVELOPMENT OF RELIABLE THERAPEUTIC INTERVENTIONS AGAINST MANGANESE-INDUCED NEUROTOXICITY. 2022 12 4044 16 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 13 5140 23 POTENTIAL REGULATORS OF THE SENESCENCE-ASSOCIATED SECRETORY PHENOTYPE DURING SENESCENCE AND AGING. SENESCENT CELLS EXPRESS AND SECRETE A VARIETY OF EXTRACELLULAR MODULATORS THAT INCLUDE CYTOKINES, CHEMOKINES, PROTEASES, GROWTH FACTORS, AND SOME ENZYMES ASSOCIATED WITH EXTRACELLULAR MATRIX REMODELING, DEFINED AS THE SENESCENCE-ASSOCIATED SECRETORY PHENOTYPE (SASP). SASP REINFORCES SENESCENT CELL CYCLE ARREST, STIMULATES AND RECRUITS IMMUNE CELLS FOR IMMUNE-MEDIATED CLEARANCE OF POTENTIALLY TUMORIGENIC CELLS, LIMITS OR INDUCES FIBROSIS, AND PROMOTES WOUND HEALING AND TISSUE REGENERATION. ON THE OTHER HAND, SASP MEDIATES CHRONIC INFLAMMATION LEADING TO THE DESTRUCTION OF TISSUE STRUCTURE AND FUNCTION AND STIMULATING THE GROWTH AND SURVIVAL OF TUMOR CELLS. SASP IS HIGHLY HETEROGENEOUS AND THE ROLE OF SASP DEPENDS ON THE CONTEXT. THE REGULATION OF SASP OCCURS AT MULTIPLE LEVELS INCLUDING CHROMATIN REMODELING, TRANSCRIPTION, MRNA TRANSLATION, INTRACELLULAR TRAFFICKING, AND SECRETION. SEVERAL SASP MODULATORS HAVE ALREADY BEEN IDENTIFIED SETTING THE STAGE FOR FUTURE RESEARCH ON THEIR CLINICAL APPLICATIONS. IN THIS REVIEW, WE SUMMARIZE IN DETAIL THE POTENTIAL SIGNALING PATHWAYS THAT TRIGGER AND REGULATE SASP PRODUCTION DURING AGING AND SENESCENCE. 2022 14 5052 21 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 15 799 26 CELLULAR SIGNALING AND POTENTIAL NEW TREATMENT TARGETS IN DIABETIC RETINOPATHY. DYSFUNCTION AND DEATH OF MICROVASCULAR CELLS AND IMBALANCE BETWEEN THE PRODUCTION AND THE DEGRADATION OF EXTRACELLULAR MATRIX (ECM) PROTEINS ARE A CHARACTERISTIC FEATURE OF DIABETIC RETINOPATHY (DR). GLUCOSE-INDUCED BIOCHEMICAL ALTERATIONS IN THE VASCULAR ENDOTHELIAL CELLS MAY ACTIVATE A CASCADE OF SIGNALING PATHWAYS LEADING TO INCREASED PRODUCTION OF ECM PROTEINS AND CELLULAR DYSFUNCTION/DEATH. CHRONIC DIABETES LEADS TO THE ACTIVATION OF A NUMBER OF SIGNALING PROTEINS INCLUDING PROTEIN KINASE C, PROTEIN KINASE B, AND MITOGEN-ACTIVATED PROTEIN KINASES. THESE SIGNALING CASCADES ARE ACTIVATED IN RESPONSE TO HYPERGLYCEMIA-INDUCED OXIDATIVE STRESS, POLYOL PATHWAY, AND ADVANCED GLYCATION END PRODUCT FORMATION AMONG OTHERS. THE ABERRANT SIGNALING PATHWAYS ULTIMATELY LEAD TO ACTIVATION OF TRANSCRIPTION FACTORS SUCH AS NUCLEAR FACTOR-KAPPAB AND ACTIVATING PROTEIN-1. THE ACTIVITY OF THESE TRANSCRIPTION FACTORS IS ALSO REGULATED BY EPIGENETIC MECHANISMS THROUGH TRANSCRIPTIONAL COACTIVATOR P300. THESE COMPLEX SIGNALING PATHWAYS MAY BE INVOLVED IN GLUCOSE-INDUCED ALTERATIONS OF ENDOTHELIAL CELL PHENOTYPE LEADING TO THE PRODUCTION OF INCREASED ECM PROTEINS AND VASOACTIVE EFFECTOR MOLECULES CAUSING FUNCTIONAL AND STRUCTURAL CHANGES IN THE MICROVASCULATURE. UNDERSTANDING OF SUCH MECHANISTIC PATHWAYS WILL HELP TO DEVELOP FUTURE ADJUVANT THERAPIES FOR DIABETIC RETINOPATHY. 2007 16 1125 23 COMPLEX INHIBITION OF AUTOPHAGY BY MITOCHONDRIAL ALDEHYDE DEHYDROGENASE SHORTENS LIFESPAN AND EXACERBATES CARDIAC AGING. AUTOPHAGY, A CONSERVATIVE DEGRADATION PROCESS FOR LONG-LIVED AND DAMAGED PROTEINS, PARTICIPATES IN A CASCADE OF BIOLOGICAL PROCESSES INCLUDING AGING. A NUMBER OF AUTOPHAGY REGULATORS HAVE BEEN IDENTIFIED. HERE WE DEMONSTRATED THAT MITOCHONDRIAL ALDEHYDE DEHYDROGENASE (ALDH2), AN ENZYME WITH THE MOST COMMON SINGLE POINT MUTATION IN HUMANS, GOVERNS CARDIAC AGING THROUGH REGULATION OF AUTOPHAGY. MYOCARDIAL MECHANICAL AND AUTOPHAGY PROPERTIES WERE EXAMINED IN YOUNG (4MONTHS) AND OLD (26-28MONTHS) WILD-TYPE (WT) AND GLOBAL ALDH2 TRANSGENIC MICE. ALDH2 OVEREXPRESSION SHORTENED LIFESPAN BY 7.7% WITHOUT AFFECTING AGING-ASSOCIATED CHANGES IN PLASMA METABOLIC PROFILES. MYOCARDIAL FUNCTION WAS COMPROMISED WITH AGING ASSOCIATED WITH CARDIAC HYPERTROPHY, THE EFFECTS WERE ACCENTUATED BY ALDH2. AGING OVERTLY SUPPRESSED AUTOPHAGY AND COMPROMISED AUTOPHAGY FLUX, THE EFFECTS WERE EXACERBATED BY ALDH2. AGING DAMPENED PHOSPHORYLATION OF JNK, BCL-2, IKKBETA, AMPK AND TSC2 WHILE PROMOTING PHOSPHORYLATION OF MTOR, THE EFFECTS OF WHICH WERE EXAGGERATED BY ALDH2. CO-IMMUNOPRECIPITATION REVEALED INCREASED DISSOCIATION BETWEEN BCL-2 AND BECLIN-1 (RESULT OF DECREASED BCL-2 PHOSPHORYLATION) IN AGING, THE EFFECT OF WHICH WAS EXACERBATED WITH ALDH2. CHRONIC TREATMENT OF THE AUTOPHAGY INDUCER RAPAMYCIN ALLEVIATED AGING-INDUCED CARDIAC DYSFUNCTION IN BOTH WT AND ALDH2 MICE. MOREOVER, ACTIVATION OF JNK AND INHIBITION OF EITHER BCL-2 OR IKKBETA OVERTLY ATTENUATED ALDH2 ACTIVATION-INDUCED ACCENTUATION OF CARDIOMYOCYTE AGING. EXAMINATION OF THE OTHERWISE ELDERLY INDIVIDUALS REVEALED A POSITIVE CORRELATION BETWEEN CARDIAC FUNCTION/GEOMETRY AND ALDH2 GENE MUTATION. TAKEN TOGETHER, OUR DATA REVEALED THAT ALDH2 ENZYME MAY SUPPRESS MYOCARDIAL AUTOPHAGY POSSIBLY THROUGH A COMPLEX JNK-BCL-2 AND IKKBETA-AMPK-DEPENDENT MECHANISM EN ROUTE TO ACCENTUATION OF MYOCARDIAL REMODELING AND CONTRACTILE DYSFUNCTION IN AGING. THIS ARTICLE IS PART OF A SPECIAL ISSUE ENTITLED: GENETIC AND EPIGENETIC CONTROL OF HEART FAILURE - EDITED BY JUN REN & MEGAN YINGMEI ZHANG. 2017 17 5580 27 ROLE OF NEUROTOXICANTS IN THE PATHOGENESIS OF ALZHEIMER'S DISEASE: A MECHANISTIC INSIGHT. ALZHEIMER'S DISEASE (AD) IS THE MOST CONSPICUOUS CHRONIC NEURODEGENERATIVE SYNDROME, WHICH HAS BECOME A SIGNIFICANT CHALLENGE FOR THE GLOBAL HEALTHCARE SYSTEM. MULTIPLE STUDIES HAVE CORROBORATED A CLEAR ASSOCIATION OF NEUROTOXICANTS WITH AD PATHOGENICITY, SUCH AS AMYLOID BETA (ABETA) PROTEINS AND NEUROFIBRILLARY TANGLES (NFTS), SIGNALLING PATHWAY MODIFICATIONS, CELLULAR STRESS, COGNITIVE DYSFUNCTIONS, NEURONAL APOPTOSIS, NEUROINFLAMMATION, EPIGENETIC MODIFICATION, AND SO ON. THIS REVIEW, THEREFORE, AIMED TO ADDRESS SEVERAL ESSENTIAL MECHANISMS AND SIGNALLING CASCADES, INCLUDING WNT (WINGLESS AND INT.) SIGNALLING PATHWAY, AUTOPHAGY, MAMMALIAN TARGET OF RAPAMYCIN (MTOR), PROTEIN KINASE C (PKC) SIGNALLING CASCADES, CELLULAR REDOX STATUS, ENERGY METABOLISM, GLUTAMATERGIC NEUROTRANSMISSIONS, IMMUNE CELL STIMULATIONS (E.G. MICROGLIA, ASTROCYTES) AS WELL AS AN AMYLOID PRECURSOR PROTEIN (APP), PRESENILIN-1 (PSEN1), PRESENILIN-2 (PSEN2) AND OTHER AD-RELATED GENE EXPRESSIONS THAT HAVE BEEN PRETENTIOUS AND MODULATED BY THE VARIOUS NEUROTOXICANTS. THIS REVIEW CONCLUDED THAT NEUROTOXICANTS PLAY A MOMENTOUS ROLE IN DEVELOPING AD THROUGH MODULATING VARIOUS SIGNALLING CASCADES. NEVERTHELESS, COMPREHENSION OF THIS RISK AGENT-INDUCED NEUROTOXICITY IS FAR TOO LITTLE. MORE IN-DEPTH EPIDEMIOLOGICAL AND SYSTEMATIC INVESTIGATIONS ARE NEEDED TO UNDERSTAND THE POTENTIAL MECHANISMS BETTER TO ADDRESS THESE NEUROTOXICANTS AND IMPROVE APPROACHES TO THEIR RISK EXPOSURE THAT AID IN AD PATHOGENESIS.KEY MESSAGESINEVITABLE CASCADE MECHANISMS OF HOW ALZHEIMER'S DISEASE-RELATED (AD-RELATED) GENE EXPRESSIONS ARE MODULATED BY NEUROTOXICANTS HAVE BEEN DISCUSSED.INVOLVEMENT OF THE NEUROTOXICANTS-INDUCED PATHWAYS CAUSED AN EXTENDED RISK OF AD IS EXPLICITED.INTEGRATION OF CELL CULTURE, ANIMALS AND POPULATION-BASED ANALYSIS ON THE CLINICAL SEVERITY OF AD IS ADDRESSED. 2021 18 5634 29 SENOLYTICS AND SENOMORPHICS: NATURAL AND SYNTHETIC THERAPEUTICS IN THE TREATMENT OF AGING AND CHRONIC DISEASES. CELLULAR SENESCENCE IS A HETEROGENEOUS PROCESS GUIDED BY GENETIC, EPIGENETIC AND ENVIRONMENTAL FACTORS, CHARACTERIZING MANY TYPES OF SOMATIC CELLS. IT HAS BEEN SUGGESTED AS AN AGING HALLMARK THAT IS BELIEVED TO CONTRIBUTE TO AGING AND CHRONIC DISEASES. SENESCENT CELLS (SC) EXHIBIT A SPECIFIC SENESCENCE-ASSOCIATED SECRETORY PHENOTYPE (SASP), MAINLY CHARACTERIZED BY THE PRODUCTION OF PROINFLAMMATORY AND MATRIX-DEGRADING MOLECULES. WHEN SC ACCUMULATE, A CHRONIC, SYSTEMIC, LOW-GRADE INFLAMMATION, KNOWN AS INFLAMMAGING, IS INDUCED. IN TURN, THIS CHRONIC IMMUNE SYSTEM ACTIVATION RESULTS IN REDUCED SC CLEARANCE THUS ESTABLISHING A VICIOUS CIRCLE THAT FUELS INFLAMMAGING. SC ACCUMULATION REPRESENTS A CAUSAL FACTOR FOR VARIOUS AGE-RELATED PATHOLOGIES. TARGETING OF SEVERAL AGING HALLMARKS HAS BEEN SUGGESTED AS A STRATEGY TO AMELIORATE HEALTHSPAN AND POSSIBLY LIFESPAN. CONSEQUENTLY, SC AND SASP ARE VIEWED AS POTENTIAL THERAPEUTIC TARGETS EITHER THROUGH THE SELECTIVE KILLING OF SC OR THE SELECTIVE SASP BLOCKAGE, THROUGH NATURAL OR SYNTHETIC COMPOUNDS. THESE COMPOUNDS ARE MEMBERS OF A FAMILY OF AGENTS CALLED SENOTHERAPEUTICS DIVIDED INTO SENOLYTICS AND SENOMORPHICS. FEW OF THEM ARE ALREADY IN CLINICAL TRIALS, POSSIBLY REPRESENTING A FUTURE TREATMENT OF AGE-RELATED PATHOLOGIES INCLUDING DISEASES SUCH AS ATHEROSCLEROSIS, OSTEOARTHRITIS, OSTEOPOROSIS, CANCER, DIABETES, NEURODEGENERATIVE DISEASES SUCH AS ALZHEIMER'S DISEASE, CARDIOVASCULAR DISEASES, HEPATIC STEATOSIS, CHRONIC OBSTRUCTIVE PULMONARY DISEASE, IDIOPATHIC PULMONARY FIBROSIS AND AGE-RELATED MACULAR DEGENERATION. IN THIS REVIEW, WE PRESENT THE ALREADY IDENTIFIED SENOLYTICS AND SENOMORPHICS FOCUSING ON THEIR REDOX-SENSITIVE PROPERTIES. WE DESCRIBE THE STUDIES THAT REVEALED THEIR EFFECTS ON CELLULAR SENESCENCE AND ENABLED THEIR NOMINATION AS NOVEL ANTI-AGING AGENTS. WE REFER TO THE SENOLYTICS THAT ARE ALREADY IN CLINICAL TRIALS AND WE PRESENT VARIOUS ADVERSE EFFECTS EXHIBITED BY SENOTHERAPEUTICS SO FAR. FINALLY, WE DISCUSS ASPECTS OF THE SENOTHERAPEUTICS THAT NEED IMPROVEMENT AND WE SUGGEST THE DESIGN OF FUTURE SENOTHERAPEUTICS TO TARGET SPECIFIC REDOX-REGULATED SIGNALING PATHWAYS IMPLICATED EITHER IN THE REGULATION OF SASP OR IN THE ELIMINATION OF SC. 2021 19 1874 25 EMERGING ROLE OF NF-KAPPAB SIGNALING IN THE INDUCTION OF SENESCENCE-ASSOCIATED SECRETORY PHENOTYPE (SASP). THE MAJOR HALLMARK OF CELLULAR SENESCENCE IS AN IRREVERSIBLE CELL CYCLE ARREST AND THUS IT IS A POTENT TUMOR SUPPRESSOR MECHANISM. GENOTOXIC INSULTS, E.G. OXIDATIVE STRESS, ARE IMPORTANT INDUCERS OF THE SENESCENT PHENOTYPE WHICH IS CHARACTERIZED BY AN ACCUMULATION OF SENESCENCE-ASSOCIATED HETEROCHROMATIC FOCI (SAHF) AND DNA SEGMENTS WITH CHROMATIN ALTERATIONS REINFORCING SENESCENCE (DNA-SCARS). INTERESTINGLY, SENESCENT CELLS SECRETE PRO-INFLAMMATORY FACTORS AND THUS THE CONDITION HAS BEEN CALLED THE SENESCENCE-ASSOCIATED SECRETORY PHENOTYPE (SASP). EMERGING DATA HAS REVEALED THAT NF-KAPPAB SIGNALING IS THE MAJOR SIGNALING PATHWAY WHICH STIMULATES THE APPEARANCE OF SASP. IT IS KNOWN THAT DNA DAMAGE PROVOKES NF-KAPPAB SIGNALING VIA A VARIETY OF SIGNALING COMPLEXES CONTAINING NEMO PROTEIN, AN NF-KAPPAB ESSENTIAL MODIFIER, AS WELL AS VIA THE ACTIVATION OF SIGNALING PATHWAYS OF P38MAPK AND RIG-1, RETINOIC ACID INDUCIBLE GENE-1. GENOMIC INSTABILITY EVOKED BY CELLULAR STRESS TRIGGERS EPIGENETIC CHANGES, E.G. RELEASE OF HMGB1 PROTEINS WHICH ARE ALSO POTENT ENHANCERS OF INFLAMMATORY RESPONSES. MOREOVER, ENVIRONMENTAL STRESS AND CHRONIC INFLAMMATION CAN STIMULATE P38MAPK AND CERAMIDE SIGNALING AND INDUCE CELLULAR SENESCENCE WITH PRO-INFLAMMATORY RESPONSES. ON THE OTHER HAND, TWO CYCLIN-DEPENDENT KINASE INHIBITORS, P16INK4A AND P14ARF, ARE EFFECTIVE INHIBITORS OF NF-KAPPAB SIGNALING. WE WILL REVIEW IN DETAIL THE SIGNALING PATHWAYS WHICH ACTIVATE NF-KAPPAB SIGNALING AND TRIGGER SASP IN SENESCENT CELLS. 2012 20 6374 27 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