1 5209 134 PRENATAL XENOBIOTIC EXPOSURE AND INTRAUTERINE HYPOTHALAMUS-PITUITARY-ADRENAL AXIS PROGRAMMING ALTERATION. THE HYPOTHALAMIC-PITUITARY-ADRENAL (HPA) AXIS IS ONE OF THE MOST IMPORTANT NEUROENDOCRINE AXES AND PLAYS AN IMPORTANT ROLE IN STRESS DEFENSE RESPONSES BEFORE AND AFTER BIRTH. PRENATAL EXPOSURE TO XENOBIOTICS, INCLUDING ENVIRONMENTAL TOXINS (SUCH AS SMOKE, SULFUR DIOXIDE AND CARBON MONOXIDE), DRUGS (SUCH AS SYNTHETIC GLUCOCORTICOIDS), AND FOODS AND BEVERAGE CATEGORIES (SUCH AS ETHANOL AND CAFFEINE), AFFECTS FETAL DEVELOPMENT INDIRECTLY BY CHANGING THE MATERNAL STATUS OR DAMAGING THE PLACENTA. CERTAIN XENOBIOTICS (SUCH AS CAFFEINE, ETHANOL AND DEXAMETHASONE) MAY ALSO AFFECT THE FETUS DIRECTLY BY CROSSING THE PLACENTA INTO THE FETUS DUE TO THEIR LIPOPHILIC PROPERTIES AND LOWER MOLECULAR WEIGHTS. ALL OF THESE FACTORS PROBABLY RESULT IN INTRAUTERINE PROGRAMMING ALTERATION OF THE HPA AXIS, WHICH SHOWED A LOW BASAL ACTIVITY BUT HYPERSENSITIVITY TO CHRONIC STRESS. THESE ALTERATIONS WILL, THEREFORE, INCREASE THE SUSCEPTIBILITY TO ADULT NEUROPSYCHIATRIC (SUCH AS DEPRESSION AND SCHIZOPHRENIA) AND METABOLIC DISEASES (SUCH AS HYPERTENSION, DIABETES AND NON-ALCOHOLIC FATTY LIVER DISEASE). THE "OVER-EXPOSURE OF FETUSES TO MATERNAL GLUCOCORTICOIDS" MAY BE THE MAIN INITIATION FACTOR BY WHICH THE FETAL HPA AXIS PROGRAMMING IS ALTERED. MEANTIME, XENOBIOTICS CAN DIRECTLY INDUCE ABNORMAL EPIGENETIC MODIFICATIONS AND EXPRESSION ON THE IMPORTANT FETAL GENES (SUCH AS HIPPOCAMPAL GLUCOCORTICOID RECEPTOR, ADRENAL STEROIDOGENIC ACUTE REGULATORY PROTEIN, ET AL) OR DAMAGE BY IN SITU OXIDATIVE METABOLISM OF FETAL ADRENALS, WHICH MAY ALSO BE CONTRIBUTED TO THE PROGRAMMING ALTERATION OF FETAL HPA AXIS. 2014 2 1488 25 DNA DAMAGE RECOGNITION IN THE RAT ZYGOTE FOLLOWING CHRONIC PATERNAL CYCLOPHOSPHAMIDE EXPOSURE. THE DETRIMENTAL EFFECTS OF PRECONCEPTIONAL PATERNAL EXPOSURE TO THE ALKYLATING ANTICANCER AGENT, CYCLOPHOSPHAMIDE, INCLUDE ABERRANT EPIGENETIC PROGRAMMING, DYSREGULATED ZYGOTIC GENE ACTIVATION, AND ABNORMALITIES IN THE OFFSPRING THAT ARE TRANSMITTED TO THE NEXT GENERATION. THE ADVERSE DEVELOPMENTAL CONSEQUENCES OF GENOMIC INSTABILITIES TRANSMITTED VIA THE SPERMATOZOON EMPHASIZE THE NEED TO ELUCIDATE THE MECHANISMS BY WHICH THE EARLY EMBRYO RECOGNIZES DNA DAMAGE IN THE PATERNAL GENOME. LITTLE INFORMATION EXISTS ON DNA DAMAGE DETECTION IN THE ZYGOTE. WE ASSESSED THE IMPACT OF PATERNAL CYCLOPHOSPHAMIDE EXPOSURE ON PHOSPHORYLATED H2AX (GAMMAH2AX) AND POLY(ADP-RIBOSE) POLYMERASE-1(PARP-1), BIOMARKERS OF DNA DAMAGE, TO DETERMINE THE CAPACITY IN THE RAT ZYGOTE TO RECOGNIZE GENOMIC DAMAGE AND INITIATE A RESPONSE TO DNA LESIONS. AN AMPLIFIED BIPHASIC GAMMAH2AX RESPONSE WAS TRIGGERED IN THE PATERNAL PRONUCLEUS IN ZYGOTES SIRED BY DRUG-TREATED MALES; THE MATERNAL GENOME WAS NOT AFFECTED. PARP-1 IMMUNOREACTIVITY WAS SUBSTANTIALLY ELEVATED IN BOTH PARENTAL GENOMES, COINCIDENT WITH THE SECOND PHASE OF GAMMAH2AX INDUCTION IN EMBRYOS SIRED BY CYCLOPHOSPHAMIDE-EXPOSED SPERMATOZOA. THUS, PATERNAL EXPOSURE TO A DNA DAMAGING AGENT RAPIDLY ACTIVATES SIGNALS IMPLEMENTAL FOR DNA DAMAGE RECOGNITION IN THE ZYGOTE. INEFFICIENT REPAIR OF DNA LESIONS MAY LEAD TO PERSISTENT ALTERATIONS OF THE HISTONE CODE AND CHROMATIN INTEGRITY, RESULTING IN ABERRANT EMBRYOGENESIS. WE PROPOSE THAT THE RESPONSE OF THE EARLY EMBRYO TO DISTURBANCES IN SPERMATOZOAL GENOMIC INTEGRITY PLAYS A VITAL ROLE IN DETERMINING ITS OUTCOME. 2007 3 6374 32 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 4 620 34 BIOCHEMISTRY AND MOLECULAR BIOLOGY OF GELATINASE B OR MATRIX METALLOPROTEINASE-9 (MMP-9): THE NEXT DECADE. RESEARCH ON MATRIX METALLOPROTEINASES (MMPS) AND IN PARTICULAR ON GELATINASE B, ALIAS MMP-9, HAS GROWN EXPONENTIALLY IN THE DECADE 2003-2012. STRUCTURAL DETAILS ABOUT FLEXIBILITY OF MMP-9 MONOMERS, TOGETHER WITH GLYCOSYLATION, OLIGOMERIZATION, HETEROGENEITY AND INSTABILITY OF THE WILDTYPE ENZYME EXPLAIN WHY CRYSTALLOGRAPHY EXPERIMENTS HAVE NOT YET BEEN SUCCESSFUL FOR THE INTACT ENZYME. MMP-9 MAY BE VIEWED AS A MULTIDOMAIN ENZYME IN WHICH THE HEMOPEXIN, THE O-GLYCOSYLATED AND THE CATALYTIC DOMAINS YIELD SUPPORT FOR ATTACHMENT, ARTICULATION AND CATALYSIS, RESPECTIVELY. THE STEPWISE PROTEOLYTIC ACTIVATION OF THE INACTIVE ZYMOGEN INTO A CATALYTICALLY ACTIVE FORM BECOMES GRADUALLY BETTER UNDERSTOOD. PRIMING OF ACTIVATION BY MMP-3 MAY BE EXECUTED BY MEPRINS THAT DESTABILIZE THE INTERACTION OF THE AMINOTERMINUS WITH THE THIRD FIBRONECTIN REPEAT. ALTERNATIVELY, AUTOCATALYTIC ACTIVATION MAY OCCUR IN THE PRESENCE OF MOLECULES THAT TIGHTLY BIND TO THE CATALYTIC SITE AND THAT PUSH THE CYSTEIN RESIDUE IN THE PRODOMAIN AWAY FROM THE CATALYTIC ZINC ION. THANKS TO THE DEVELOPMENT OF DEGRADOMICS TECHNOLOGIES, SUBSTRATE REPERTOIRES OF MMP-9 HAVE BEEN DEFINED, BUT IT REMAINS A CHALLENGE TO DETERMINE AND PROVE WHICH SUBSTRATES ARE BIOLOGICALLY RELEVANT. THE SUBSTRATE REPERTOIRE HAS BEEN ENLARGED FROM EXTRACELLULAR TO MEMBRANE-BOUND AND EFFICIENT INTRACELLULAR SUBSTRATES, SUCH AS CRYSTALLINS, TUBULINS AND ACTINS. BIOLOGICAL STUDIES OF MMP-9 HAVE TUNED THE FIELD FROM BEING PRIMARILY CANCER-ORIENTED TOWARDS VASCULAR AND INFLAMMATORY RESEARCH. IN TUMOR BIOLOGY, IT HAS BEEN INCREASINGLY APPRECIATED THAT MMP-9 FROM INFLAMMATORY CELLS, PARTICULARLY NEUTROPHILS, CO-DETERMINES PROGNOSIS AND OUTCOME. ASIDE FROM THE CATALYTIC FUNCTIONS EXECUTED BY AMINOTERMINAL DOMAINS OF MMP-9, THE CARBOXYTERMINAL HEMOPEXIN (PEX) DOMAIN OF GELATINASE B EXERTS NON-CATALYTIC ANTI-APOPTOTIC SIGNALING EFFECTS. THE RECOGNITION THAT GELATINASE B IS INDUCED BY MANY PRO-INFLAMMATORY CYTOKINES, WHEREAS ITS INHIBITORS ARE INCREASED BY ANTI-INFLAMMATORY CYTOKINES, HAS GENERATED INTEREST TO TARGET MMP-9 IN ACUTE LETHAL CONDITIONS, SUCH AS BACTERIAL MENINGITIS, SEPSIS AND ENDOTOXIN SHOCK, AND IN ACUTE EXACERBATIONS OF CHRONIC DISEASES. PREVIOUSLY DESCRIBED TRANSCRIPTIONAL REGULATION OF MMP-9 IS COMPLEMENTED BY EPIGENETIC CHECKPOINTS, INCLUDING HISTONE MODIFICATIONS AND MICRORNAS. BECAUSE ACTIVATION OF PROMMP-9 MAY BE EXECUTED BY OTHER MMPS, THE THERAPEUTIC DOGMA THAT MMP INHIBITORS NEED TO BE HIGHLY SELECTIVE MAY BE KEYED DOWN FOR THE TREATMENT OF LIFE-THREATENING CONDITIONS. WHEN INFLAMMATION AND MMP-9 FULFILL BENEFICIAL FUNCTIONS TO CLEAR DAMAGING PROTEIN COMPLEXES, SUCH AS IN SYSTEMIC AUTOIMMUNE DISEASES, THERAPEUTIC MMP INHIBITION HAS TO BE AVOIDED. IN MMP9 GENE KNOCKOUT MICE, SPECIFIC SPONTANEOUS PHENOTYPES EMERGED WITH EFFECTS ON THE SKELETAL, REPRODUCTIVE AND NERVOUS SYSTEMS. THESE FINDINGS NOT ONLY HAVE CLINICAL CORRELATES IN BONE GROWTH AND FERTILITY, BUT ALSO STIMULATE RESEARCH ON THE ROLES OF MMPS AND MMP-9 IN ENDOCRINOLOGY, IMMUNOLOGY AND THE NEUROSCIENCES. MMP9-DEFICIENT MICE ARE VALUABLE TOOLS TO DEFINE MMP-9 SUBSTRATES IN VIVO AND TO STUDY THE ROLE OF THIS ENZYME IN ANIMAL MODELS OF INFLAMMATORY, VASCULAR, NEOPLASTIC AND DEGENERATIVE DISEASES. FUTURE CHALLENGES INCLUDE SOLVING THE CRYSTAL STRUCTURE, DEFINITION OF THE FUNCTIONS OF COVALENT OLIGOMERS AND HETEROMERS IN BIOLOGY AND PATHOLOGY, LIFE-IMAGING OF MMP-9 ACTIVITY, SUBSTRATE DETERMINATION IN SITU AND THE STUDY OF INHIBITOR EFFECTS ON FERTILITY, CANCER AND INFLAMMATION AND IN NEUROBIOLOGY AND REGENERATIVE MEDICINE. SUCH STUDIES WILL BETTER DEFINE CONDITIONS IN WHICH INHIBITION OF MMP-9 IS BENEFICIAL OR HAS TO BE AVOIDED. 2013 5 1382 30 DIABETES ALTERS ACTIVATION AND REPRESSION OF PRO- AND ANTI-INFLAMMATORY SIGNALING PATHWAYS IN THE VASCULATURE. A CENTRAL MECHANISM DRIVING VASCULAR DISEASE IN DIABETES IS IMMUNE CELL-MEDIATED INFLAMMATION. IN DIABETES, ENHANCED OXIDATION AND GLYCATION OF MACROMOLECULES, SUCH AS LIPOPROTEINS, INSULTS THE ENDOTHELIUM, AND ACTIVATES BOTH INNATE AND ADAPTIVE ARMS OF THE IMMUNE SYSTEM BY GENERATING NEW ANTIGENS FOR PRESENTATION TO ADAPTIVE IMMUNE CELLS. CHRONIC INFLAMMATION OF THE ENDOTHELIUM IN DIABETES LEADS TO CONTINUOUS INFILTRATION AND ACCUMULATION OF LEUKOCYTES AT SITES OF ENDOTHELIAL CELL INJURY. WE WILL DESCRIBE THE CENTRAL ROLE OF THE MACROPHAGE AS A SOURCE OF SIGNALING MOLECULES AND DAMAGING BY-PRODUCTS WHICH ACTIVATE INFILTRATING LYMPHOCYTES IN THE TISSUE AND CONTRIBUTE TO THE PRO-OXIDANT AND PRO-INFLAMMATORY MICROENVIRONMENT. AN IMPORTANT ASPECT TO BE CONSIDERED IS THE DIABETES-ASSOCIATED DEFECTS IN THE IMMUNE SYSTEM, SUCH AS FEWER OR DYSFUNCTIONAL ATHERO-PROTECTIVE LEUKOCYTE SUBSETS IN THE DIABETIC LESION COMPARED TO NON-DIABETIC LESIONS. THIS REVIEW WILL DISCUSS THE KEY PRO-INFLAMMATORY SIGNALING PATHWAYS RESPONSIBLE FOR LEUKOCYTE RECRUITMENT AND ACTIVATION IN THE INJURED VESSEL, WITH PARTICULAR FOCUS ON PRO- AND ANTI-INFLAMMATORY PATHWAYS ABERRANTLY ACTIVATED OR REPRESSED IN DIABETES. WE AIM TO DESCRIBE THE INTERACTION BETWEEN ADVANCED GLYCATION END PRODUCTS AND THEIR PRINCIPLE RECEPTOR RAGE, ANGIOTENSIN II, AND THE ANG II TYPE 1 RECEPTOR, IN ADDITION TO REACTIVE OXYGEN SPECIES (ROS) PRODUCTION BY NADPH-OXIDASE ENZYMES THAT ARE RELEVANT TO VASCULAR AND IMMUNE CELL FUNCTION IN THE CONTEXT OF DIABETIC VASCULOPATHY. FURTHERMORE, WE WILL TOUCH ON RECENT ADVANCES IN EPIGENETIC MEDICINE THAT HAVE REVEALED HIGH GLUCOSE-MEDIATED CHANGES IN THE TRANSCRIPTION OF GENES WITH KNOWN PRO-INFLAMMATORY DOWNSTREAM TARGETS. FINALLY, NOVEL ANTI-ATHEROSCLEROSIS STRATEGIES THAT TARGET THE VASCULAR IMMUNE INTERFACE WILL BE EXPLORED; SUCH AS VACCINATION AGAINST MODIFIED LOW-DENSITY LIPOPROTEIN AND PHARMACOLOGICAL INHIBITION OF ROS-PRODUCING ENZYMES. 2013 6 225 33 ACUTE STRESS-INDUCED EPIGENETIC MODULATIONS AND THEIR POTENTIAL PROTECTIVE ROLE TOWARD DEPRESSION. PSYCHIATRIC DISORDERS ENTAIL MALADAPTIVE PROCESSES IMPAIRING INDIVIDUALS' ABILITY TO APPROPRIATELY INTERFACE WITH ENVIRONMENT. AMONG THEM, DEPRESSION IS CHARACTERIZED BY DIVERSE DEBILITATING SYMPTOMS INCLUDING HOPELESSNESS AND ANHEDONIA, DRAMATICALLY IMPACTING THE PROPENSITY TO LIVE A SOCIAL AND ACTIVE LIFE AND SERIOUSLY AFFECTING WORKING CAPABILITY. RELEVANTLY, BESIDES GENETIC PREDISPOSITION, FOREMOST RISK FACTORS ARE STRESS-RELATED, SUCH AS EXPERIENCING CHRONIC PSYCHOSOCIAL STRESS-INCLUDING BULLYING, MOBBING AND ABUSE-, AND UNDERGOING ECONOMIC CRISIS OR CHRONIC ILLNESSES. IN THE LAST FEW YEARS THE FIELD OF EPIGENETICS PROMISED TO UNDERSTAND CORE MECHANISMS OF GENE-ENVIRONMENT CROSSTALK, CONTRIBUTING TO GET INTO PATHOGENIC PROCESSES OF MANY DISORDERS HIGHLY INFLUENCED BY STRESSFUL LIFE CONDITIONS. HOWEVER, STILL VERY LITTLE IS KNOWN ABOUT MECHANISMS THAT TUNE GENE EXPRESSION TO ADAPT TO THE EXTERNAL MILIEU. IN THIS PERSPECTIVE ARTICLE, WE DISCUSS A SET OF PROTECTIVE, FUNCTIONALLY CONVERGENT EPIGENETIC PROCESSES INDUCED BY ACUTE STRESS IN THE RODENT HIPPOCAMPUS AND DEVOTED TO THE NEGATIVE MODULATION OF STRESS-INDUCED IMMEDIATE EARLY GENES (IEGS) TRANSCRIPTION, HINDERING STRESS-DRIVEN MORPHOSTRUCTURAL MODIFICATIONS OF CORTICOLIMBIC CIRCUITRY. WE ALSO SUGGEST THAT CHRONIC STRESS DAMAGING PROTECTIVE EPIGENETIC MECHANISMS, COULD BIAS THE FUNCTIONAL TRAJECTORY OF STRESS-INDUCED NEURONAL MORPHOSTRUCTURAL MODIFICATION FROM ADAPTIVE TO MALADAPTIVE, CONTRIBUTING TO THE ONSET OF DEPRESSION IN VULNERABLE INDIVIDUALS. A BETTER UNDERSTANDING OF THE EPIGENETIC RESPONSE TO STRESS WILL BE PIVOTAL TO NEW AVENUES OF THERAPEUTIC INTERVENTION TO TREAT DEPRESSION, ESPECIALLY IN LIGHT OF LIMITED EFFICACY OF AVAILABLE ANTIDEPRESSANT DRUGS. 2018 7 788 22 CELLULAR ALLOSTATIC LOAD IS LINKED TO INCREASED ENERGY EXPENDITURE AND ACCELERATED BIOLOGICAL AGING. STRESS TRIGGERS ANTICIPATORY PHYSIOLOGICAL RESPONSES THAT PROMOTE SURVIVAL, A PHENOMENON TERMED ALLOSTASIS. HOWEVER, THE CHRONIC ACTIVATION OF ENERGY-DEPENDENT ALLOSTATIC RESPONSES RESULTS IN ALLOSTATIC LOAD, A DYSREGULATED STATE THAT PREDICTS FUNCTIONAL DECLINE, ACCELERATES AGING, AND INCREASES MORTALITY IN HUMANS. THE ENERGETIC COST AND CELLULAR BASIS FOR THE DAMAGING EFFECTS OF ALLOSTATIC LOAD HAVE NOT BEEN DEFINED. HERE, BY LONGITUDINALLY PROFILING THREE UNRELATED PRIMARY HUMAN FIBROBLAST LINES ACROSS THEIR LIFESPAN, WE FIND THAT CHRONIC GLUCOCORTICOID EXPOSURE INCREASES CELLULAR ENERGY EXPENDITURE BY APPROXIMATELY 60%, ALONG WITH A METABOLIC SHIFT FROM GLYCOLYSIS TO MITOCHONDRIAL OXIDATIVE PHOSPHORYLATION (OXPHOS). THIS STATE OF STRESS-INDUCED HYPERMETABOLISM IS LINKED TO MTDNA INSTABILITY, NON-LINEARLY AFFECTS AGE-RELATED CYTOKINES SECRETION, AND ACCELERATES CELLULAR AGING BASED ON DNA METHYLATION CLOCKS, TELOMERE SHORTENING RATE, AND REDUCED LIFESPAN. PHARMACOLOGICALLY NORMALIZING OXPHOS ACTIVITY WHILE FURTHER INCREASING ENERGY EXPENDITURE EXACERBATES THE ACCELERATED AGING PHENOTYPE, POINTING TO TOTAL ENERGY EXPENDITURE AS A POTENTIAL DRIVER OF AGING DYNAMICS. TOGETHER, OUR FINDINGS DEFINE BIOENERGETIC AND MULTI-OMIC RECALIBRATIONS OF STRESS ADAPTATION, UNDERSCORING INCREASED ENERGY EXPENDITURE AND ACCELERATED CELLULAR AGING AS INTERRELATED FEATURES OF CELLULAR ALLOSTATIC LOAD. 2023 8 375 19 AN ENERGETIC VIEW OF STRESS: FOCUS ON MITOCHONDRIA. ENERGY IS REQUIRED TO SUSTAIN LIFE AND ENABLE STRESS ADAPTATION. AT THE CELLULAR LEVEL, ENERGY IS LARGELY DERIVED FROM MITOCHONDRIA - UNIQUE MULTIFUNCTIONAL ORGANELLES WITH THEIR OWN GENOME. FOUR MAIN ELEMENTS CONNECT MITOCHONDRIA TO STRESS: (1) ENERGY IS REQUIRED AT THE MOLECULAR, (EPI)GENETIC, CELLULAR, ORGANELLAR, AND SYSTEMIC LEVELS TO SUSTAIN COMPONENTS OF STRESS RESPONSES; (2) GLUCOCORTICOIDS AND OTHER STEROID HORMONES ARE PRODUCED AND METABOLIZED BY MITOCHONDRIA; (3) RECIPROCALLY, MITOCHONDRIA RESPOND TO NEUROENDOCRINE AND METABOLIC STRESS MEDIATORS; AND (4) EXPERIMENTALLY MANIPULATING MITOCHONDRIAL FUNCTIONS ALTERS PHYSIOLOGICAL AND BEHAVIORAL RESPONSES TO PSYCHOLOGICAL STRESS. THUS, MITOCHONDRIA ARE ENDOCRINE ORGANELLES THAT PROVIDE BOTH THE ENERGY AND SIGNALS THAT ENABLE AND DIRECT STRESS ADAPTATION. NEURAL CIRCUITS REGULATING SOCIAL BEHAVIOR - AS WELL AS PSYCHOPATHOLOGICAL PROCESSES - ARE ALSO INFLUENCED BY MITOCHONDRIAL ENERGETICS. AN INTEGRATIVE VIEW OF STRESS AS AN ENERGY-DRIVEN PROCESS OPENS NEW OPPORTUNITIES TO STUDY MECHANISMS OF ADAPTATION AND REGULATION ACROSS THE LIFESPAN. 2018 9 6499 27 TRAINED IMMUNITY IN PERIVASCULAR ADIPOSE TISSUE OF ABDOMINAL AORTIC ANEURYSM-A NOVEL CONCEPT FOR A STILL ELUSIVE DISEASE. ABDOMINAL AORTIC ANEURYSM (AAA) IS A CHRONIC, LIFE-THREATENING VASCULAR DISEASE WHOSE ONLY THERAPEUTIC OPTION IS A SURGICAL REPAIR TO PREVENT VESSEL RUPTURE. THE LACK OF MEDICAL THERAPY RESULTS FROM AN INADEQUATE UNDERSTANDING OF THE ETIOPATHOGENESIS OF AAA. MANY STUDIES IN ANIMAL AND HUMAN MODELS INDICATE A 'SHORT-CIRCUITING' OF THE REGULATION OF THE INFLAMMATORY-IMMUNE RESPONSE AS A MAJOR PLAYER IN THE AAA CHRONIC PROCESS. IN THIS REGARD, PERIVASCULAR ADIPOSE TISSUE (PVAT) HAS RECEIVED INCREASING INTEREST BECAUSE ITS DYSFUNCTION AFFECTS LARGE ARTERIES PRIMARILY THROUGH IMMUNE CELL INFILTRATION. CONSISTENTLY, WE HAVE RECENTLY PRODUCED EVIDENCE THAT INNATE AND ADAPTIVE IMMUNE CELLS PRESENT IN THE PVAT OF AAAS CONTRIBUTE TO SUSTAINING A DAMAGING INFLAMMATORY LOOP. HOWEVER, IT IS STILL UNCLEAR HOW THE COMPLEX CROSSTALK BETWEEN ADAPTIVE AND INNATE IMMUNITY CAN BE SELF-SUSTAINING. FROM OUR PERSPECTIVE, TRAINED IMMUNITY MAY PLAY A ROLE IN THIS CROSSTALK. TRAINED IMMUNITY IS DEFINED AS A FORM OF INNATE IMMUNE MEMORY RESULTING IN ENHANCED RESPONSIVENESS TO REPEATED TRIGGERS. SPECIFIC INNATE STIMULI AND EPIGENETIC AND METABOLIC REPROGRAMMING EVENTS INDUCE AND SHAPE TRAINED IMMUNITY IN MYELOID PROGENITOR CELLS IMPROVING HOST DEFENSE, BUT ALSO CONTRIBUTING TO THE PROGRESSION OF IMMUNE-MEDIATED AND CHRONIC INFLAMMATORY DISEASES. HERE WE PRESENT THIS HYPOTHESIS WITH DATA FROM THE LITERATURE AND OUR OBSERVATIONS TO SUPPORT IT. 2022 10 3837 28 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 11 6403 33 THE ROLES OF INDUCIBLE CHROMATIN AND TRANSCRIPTIONAL MEMORY IN CELLULAR DEFENSE SYSTEM RESPONSES TO REDOX-ACTIVE POLLUTANTS. PEOPLE ARE EXPOSED TO WIDE RANGE OF REDOX-ACTIVE ENVIRONMENTAL POLLUTANTS. AIR POLLUTION, HEAVY METALS, PESTICIDES, AND ENDOCRINE DISRUPTING CHEMICALS CAN DISRUPT CELLULAR REDOX STATUS. REDOX-ACTIVE POLLUTANTS IN OUR ENVIRONMENT ALL TRIGGER THEIR OWN SETS OF SPECIFIC CELLULAR RESPONSES, BUT THEY ALSO ACTIVATE A COMMON SET OF GENERAL STRESS RESPONSES THAT BUFFER THE CELL AGAINST HOMEOSTATIC INSULTS. THESE CELLULAR DEFENSE SYSTEM (CDS) PATHWAYS INCLUDE THE HEAT SHOCK RESPONSE, THE OXIDATIVE STRESS RESPONSE, THE HYPOXIA RESPONSE, THE UNFOLDED PROTEIN RESPONSE, THE DNA DAMAGE RESPONSE, AND THE GENERAL STRESS RESPONSE MEDIATED BY THE STRESS-ACTIVATED P38 MITOGEN-ACTIVATED PROTEIN KINASE. OVER THE PAST TWO DECADES, THE FIELD OF ENVIRONMENTAL EPIGENETICS HAS INVESTIGATED EPIGENETIC RESPONSES TO ENVIRONMENTAL POLLUTANTS, INCLUDING REDOX-ACTIVE POLLUTANTS. STUDIES OF THESE RESPONSES HIGHLIGHT THE ROLE OF CHROMATIN MODIFICATIONS IN CONTROLLING THE TRANSCRIPTIONAL RESPONSE TO POLLUTANTS AND THE ROLE OF TRANSCRIPTIONAL MEMORY, OFTEN REFERRED TO AS "EPIGENETIC REPROGRAMMING", IN PREDISPOSING PREVIOUSLY EXPOSED INDIVIDUALS TO MORE POTENT TRANSCRIPTIONAL RESPONSES ON SECONDARY CHALLENGE. MY CENTRAL THESIS IN THIS REVIEW IS THAT HIGH DOSE OR CHRONIC EXPOSURE TO REDOX-ACTIVE POLLUTANTS LEADS TO TRANSCRIPTIONAL MEMORIES AT CDS TARGET GENES THAT INFLUENCE THE CELL'S ABILITY TO MOUNT PROTECTIVE RESPONSES. TO SUPPORT THIS THESIS, I WILL: (1) SUMMARIZE THE KNOWN CHROMATIN FEATURES REQUIRED FOR INDUCIBLE GENE ACTIVATION; (2) REVIEW THE KNOWN FORMS OF TRANSCRIPTIONAL MEMORY; (3) DISCUSS THE ROLES OF INDUCIBLE CHROMATIN AND TRANSCRIPTIONAL MEMORY IN CDS RESPONSES THAT ARE ACTIVATED BY REDOX-ACTIVE ENVIRONMENTAL POLLUTANTS; AND (4) PROPOSE A CONCEPTUAL FRAMEWORK FOR CDS PATHWAY RESPONSIVENESS AS A READOUT OF TOTAL CELLULAR EXPOSURE TO REDOX-ACTIVE POLLUTANTS. 2021 12 3734 31 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 13 4384 33 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 6502 23 TRAINED IMMUNITY: LONG-TERM ADAPTATION IN INNATE IMMUNE RESPONSES. ADAPTIVE IMMUNE RESPONSES ARE CHARACTERIZED BY ANTIGEN SPECIFICITY AND INDUCTION OF LIFELONG IMMUNOLOGIC MEMORY. RECENTLY, IT HAS BEEN REPORTED THAT INNATE IMMUNE CELLS CAN ALSO BUILD IMMUNE MEMORY CHARACTERISTICS-A PROCESS TERMED TRAINED IMMUNITY. TRAINED IMMUNITY DESCRIBES THE PERSISTENT HYPERRESPONSIVE PHENOTYPE THAT INNATE IMMUNE CELLS CAN DEVELOP AFTER BRIEF STIMULATION. PATHOGENIC STIMULI SUCH AS MICROORGANISMS, AND ALSO ENDOGENOUS MOLECULES INCLUDING URIC ACID, OXIDIZED LDL (LOW-DENSITY LIPOPROTEIN), AND CATECHOLAMINES, ARE CAPABLE OF INDUCING MEMORY IN MONOCYTES AND MACROPHAGES. WHILE TRAINED IMMUNITY PROVIDES FAVORABLE CROSS-PROTECTION IN THE CONTEXT OF INFECTIOUS DISEASES, THE HEIGHTENED IMMUNE RESPONSE CAN BE MALADAPTIVE IN DISEASES DRIVEN BY CHRONIC SYSTEMIC INFLAMMATION, SUCH AS ATHEROSCLEROSIS. TRAINED IMMUNITY IS MAINTAINED BY DISTINCT EPIGENETIC AND METABOLIC MECHANISMS AND PERSISTS FOR AT LEAST SEVERAL MONTHS IN VIVO DUE TO REPROGRAMMING OF MYELOID PROGENITOR CELLS. ADDITIONALLY, CERTAIN NONIMMUNE CELLS ARE ALSO FOUND TO EXHIBIT TRAINED IMMUNITY CHARACTERISTICS. THUS, TRAINED IMMUNITY PRESENTS AN EXCITING FRAMEWORK TO DEVELOP NEW APPROACHES TO VACCINATION AND ALSO NOVEL PHARMACOLOGICAL TARGETS IN THE TREATMENT OF INFLAMMATORY DISEASES. 2021 15 5942 29 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 16 5391 31 REDOX-RELATED BIOMARKERS IN HUMAN CARDIOVASCULAR DISEASE - CLASSICAL FOOTPRINTS AND BEYOND. GLOBAL EPIDEMIOLOGICAL STUDIES SHOW THAT CHRONIC NON-COMMUNICABLE DISEASES SUCH AS ATHEROSCLEROSIS AND METABOLIC DISORDERS REPRESENT THE LEADING CAUSE OF PREMATURE MORTALITY AND MORBIDITY. CARDIOVASCULAR DISEASE SUCH AS ISCHEMIC HEART DISEASE IS A MAJOR CONTRIBUTOR TO THE GLOBAL BURDEN OF DISEASE AND THE SOCIOECONOMIC HEALTH COSTS. CLINICAL AND EPIDEMIOLOGICAL DATA SHOW AN ASSOCIATION OF TYPICAL OXIDATIVE STRESS MARKERS SUCH AS LIPID PEROXIDATION PRODUCTS, 3-NITROTYROSINE OR OXIDIZED DNA/RNA BASES WITH ALL MAJOR CARDIOVASCULAR DISEASES. THIS SUPPORTS THE CONCEPT THAT THE FORMATION OF REACTIVE OXYGEN AND NITROGEN SPECIES BY VARIOUS SOURCES (NADPH OXIDASES, XANTHINE OXIDASE AND MITOCHONDRIAL RESPIRATORY CHAIN) REPRESENTS A HALLMARK OF THE LEADING CARDIOVASCULAR COMORBIDITIES SUCH AS HYPERLIPIDEMIA, HYPERTENSION AND DIABETES. THESE REACTIVE OXYGEN AND NITROGEN SPECIES CAN LEAD TO OXIDATIVE DAMAGE BUT ALSO ADVERSE REDOX SIGNALING AT THE LEVEL OF KINASES, CALCIUM HANDLING, INFLAMMATION, EPIGENETIC CONTROL, CIRCADIAN CLOCK AND PROTEASOMAL SYSTEM. THE IN VIVO FOOTPRINTS OF THESE ADVERSE PROCESSES (REDOX BIOMARKERS) ARE DISCUSSED IN THE PRESENT REVIEW WITH FOCUS ON THEIR CLINICAL RELEVANCE, WHEREAS THE DETAILS OF THEIR MECHANISMS OF FORMATION AND TECHNICAL ASPECTS OF THEIR DETECTION ARE ONLY BRIEFLY MENTIONED. THE MAJOR CATEGORIES OF REDOX BIOMARKERS ARE SUMMARIZED AND EXPLAINED ON THE BASIS OF SUITABLE EXAMPLES. ALSO THE POTENTIAL PROGNOSTIC VALUE OF REDOX BIOMARKERS IS CRITICALLY DISCUSSED TO UNDERSTAND WHAT KIND OF INFORMATION THEY CAN PROVIDE BUT ALSO WHAT THEY CANNOT ACHIEVE. 2021 17 6214 26 THE INTRACELLULAR SIGNALING PATHWAYS GOVERNING MACROPHAGE ACTIVATION AND FUNCTION IN HUMAN ATHEROSCLEROSIS. ATHEROSCLEROSIS IS A CHRONIC INFLAMMATORY DISEASE CHARACTERIZED BY LIPID ACCUMULATION AND PLAQUE FORMATION IN ARTERIAL VESSEL WALLS. ATHEROSCLEROTIC PLAQUES NARROW THE ARTERIAL LUMEN TO INCREASE THE RISK OF HEART ATTACKS, ISCHEMIC STROKE AND PERIPHERAL VASCULAR DISEASE, WHICH ARE MAJOR AND WORLDWIDE HEALTH AND ECONOMIC BURDENS. MACROPHAGE ACCUMULATION WITHIN PLAQUES IS CHARACTERISTIC OF ALL STAGES OF ATHEROSCLEROSIS AND THEIR PRESENCE IS A POTENTIAL MARKER OF DISEASE ACTIVITY AND PLAQUE STABILITY. MACROPHAGES ENGULF LIPIDS AND MODIFIED LIPOPROTEINS TO FORM FOAM CELLS THAT EXPRESS PRO-INFLAMMATORY AND CHEMOTACTIC EFFECTOR MOLECULES, STRESS INDUCING FACTORS AND REACTIVE OXYGEN SPECIES. THEY CONTROL PLAQUE STABILITY AND RUPTURE THROUGH SECRETION OF METALLOPROTEINASES AND EXTRACELLULAR MATRIX DEGRADATION. ALTHOUGH MACROPHAGES CAN WORSEN DISEASE BY PROPAGATING INFLAMMATION, THEY CAN STABILIZE ATHEROSCLEROTIC PLAQUES THROUGH TISSUE REMODELING, PROMOTING THE FORMATION OF A FIBROUS CAP, CLEARING APOPTOTIC CELLS TO PREVENT NECROTIC CORE FORMATION AND THROUGH VASCULAR REPAIR. IN ATHEROSCLEROSIS, MACROPHAGES RESPOND TO DYSLIPIDAEMIA, CYTOKINES, DYING CELLS, METABOLIC FACTORS, LIPIDS, PHYSICAL STIMULI AND EPIGENETIC FACTORS AND EXHIBIT HETEROGENEITY IN THEIR ACTIVATION DEPENDING ON THE STIMULI THEY RECEIVE. UNDERSTANDING THESE SIGNALS AND THE PATHWAYS DRIVING MACROPHAGE FUNCTION WITHIN DEVELOPING AND ESTABLISHED PLAQUES AND HOW THEY CAN BE PHARMACOLOGICALLY MODULATED, REPRESENTS A STRATEGY FOR THE PREVENTION AND TREATMENT OF ATHEROSCLEROSIS. THIS REVIEW FOCUSSES ON THE CURRENT UNDERSTANDING OF FACTORS CONTROLLING MACROPHAGE HETEROGENEITY AND FUNCTION IN ATHEROSCLEROSIS. PARTICULAR ATTENTION IS GIVEN TO THE MACROPHAGE INTRACELLULAR SIGNALING PATHWAYS AND TRANSCRIPTION FACTORS ACTIVATED BY BIOCHEMICAL AND BIOPHYSICAL STIMULI WITHIN PLAQUES, AND HOW THEY ARE INTEGRATED TO REGULATE PLAQUE FORMATION AND STABILITY. 2022 18 3544 21 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 19 4380 31 MITOCHONDRIAL DYSFUNCTION AND OXIDATIVE STRESS IN RHEUMATOID ARTHRITIS. CONTROL OF EXCESSIVE MITOCHONDRIAL OXIDATIVE STRESS COULD PROVIDE NEW TARGETS FOR BOTH PREVENTIVE AND THERAPEUTIC INTERVENTIONS IN THE TREATMENT OF CHRONIC INFLAMMATION OR ANY PATHOLOGY THAT DEVELOPS UNDER AN INFLAMMATORY SCENARIO, SUCH AS RHEUMATOID ARTHRITIS (RA). INCREASING EVIDENCE HAS DEMONSTRATED THE ROLE OF MITOCHONDRIAL ALTERATIONS IN AUTOIMMUNE DISEASES MAINLY DUE TO THE INTERPLAY BETWEEN METABOLISM AND INNATE IMMUNITY, BUT ALSO IN THE MODULATION OF INFLAMMATORY RESPONSE OF RESIDENT CELLS, SUCH AS SYNOVIOCYTES. THUS, MITOCHONDRIAL DYSFUNCTION DERIVED FROM SEVERAL DANGER SIGNALS COULD ACTIVATE TRICARBOXYLIC ACID (TCA) DISRUPTION, THEREBY FAVORING A VICIOUS CYCLE OF OXIDATIVE/MITOCHONDRIAL STRESS. MITOCHONDRIAL DYSFUNCTION CAN ACT THROUGH MODULATING INNATE IMMUNITY VIA REDOX-SENSITIVE INFLAMMATORY PATHWAYS OR DIRECT ACTIVATION OF THE INFLAMMASOME. BESIDES, MITOCHONDRIA ALSO HAVE A CENTRAL ROLE IN REGULATING CELL DEATH, WHICH IS DEEPLY ALTERED IN RA. ADDITIONALLY, MULTIPLE EVIDENCE SUGGESTS THAT PATHOLOGICAL PROCESSES IN RA CAN BE SHAPED BY EPIGENETIC MECHANISMS AND THAT IN TURN, MITOCHONDRIA ARE INVOLVED IN EPIGENETIC REGULATION. FINALLY, WE WILL DISCUSS ABOUT THE INVOLVEMENT OF SOME DIETARY COMPONENTS IN THE ONSET AND PROGRESSION OF RA. 2022 20 5816 26 STRESS AND STEM CELLS. THE UNIQUE PROPERTIES AND FUNCTIONS OF STEM CELLS MAKE THEM PARTICULARLY SUSCEPTIBLE TO STRESSES AND ALSO LEAD TO THEIR REGULATION BY STRESS. STEM CELL DIVISION MUST RESPOND TO THE DEMAND TO REPLENISH CELLS DURING NORMAL TISSUE TURNOVER AS WELL AS IN RESPONSE TO DAMAGE. OXIDATIVE STRESS, MECHANICAL STRESS, GROWTH FACTORS, AND CYTOKINES SIGNAL STEM CELL DIVISION AND DIFFERENTIATION. MANY OF THE CONSERVED PATHWAYS REGULATING STEM CELL SELF-RENEWAL AND DIFFERENTIATION ARE ALSO STRESS-RESPONSE PATHWAYS. THE LONG LIFE SPAN AND DIVISION POTENTIAL OF STEM CELLS CREATE A PROPENSITY FOR TRANSFORMATION (CANCER) AND SPECIFIC STRESS RESPONSES SUCH AS APOPTOSIS AND SENESCENCE ACT AS ANTITUMOR MECHANISMS. QUIESCENCE REGULATED BY CDK INHIBITORS AND A HYPOXIC NICHE REGULATED BY FOXO TRANSCRIPTION FACTOR FUNCTION TO REDUCE STRESS FOR SEVERAL TYPES OF STEM CELLS TO FACILITATE LONG-TERM MAINTENANCE. AGING IS A PARTICULARLY RELEVANT STRESS FOR STEM CELLS, BECAUSE REPEATED DEMANDS ON STEM CELL FUNCTION OVER THE LIFE SPAN CAN HAVE CUMULATIVE CELL-AUTONOMOUS EFFECTS INCLUDING EPIGENETIC DYSREGULATION, MUTATIONS, AND TELOMERE EROSION. IN ADDITION, AGING OF THE ORGANISM IMPAIRS FUNCTION OF THE STEM CELL NICHE AND SYSTEMIC SIGNALS, INCLUDING CHRONIC INFLAMMATION AND OXIDATIVE STRESS. 2012