1 601 106 BETA-GLUCAN "TRAINED IMMUNITY" IMMUNOMODULATORY PROPERTIES POTENTIATE TISSUE WOUND MANAGEMENT AND ACCELERATE FITNESS RECOVER. INTRODUCTION: IT IS WELL ESTABLISHED THAT MODERATE PHYSICAL ACTIVITY CAN IMPROVE THE IMMUNE STATUS, RATHER EXCESS OR HIGH-INTENSITY PHYSICAL EXERCISE CAN CAUSE DAMAGE TO THE IMMUNE SYSTEM. IN ADDITION, MUSCLE INJURIES RESULTING FROM INCREASED FREQUENCY AND INTENSITY OF EXERCISES COMPROMISE INNATE IMMUNE ACTIVITY AND MAY DECREASE TISSUE REGENERATION. THUS, BETA-GLUCANS, A NATURAL COMPOUND, MAY REPRESENT AN IMPORTANT SUBSTANCE WITH STRONG IMMUNOMODULATORY PROPERTIES ACTING AS AN IMMUNOSTIMULANT THERAPY KNOWN AS "TRAINED IMMUNITY". THIS IMMUNE STIMULATING THERAPEUTIC IS AN IMMUNOLOGICAL MEMORY PHENOMENON LINKED TO THE INNATE IMMUNE SYSTEM, TRIGGERING CELLULAR CHANGES AT EPIGENETIC, TRANSCRIPTIONAL, AND FUNCTIONAL LEVELS, TO REGULATE THE IMMUNE SYSTEM AND RECOVER ITS HOMEOSTASIS WITH CLINICAL BENEFITS. CONCLUSION: THIS NARRATIVE REVIEW WORKS WITH THE CURRENT EVIDENCE REGARDING BETA-GLUCANS AS A POSSIBLE ALTERNATIVE THERAPY FOR WOUND HEALING AND ITS SAFETY AND EFFICACY IN THE TREATMENT OF MUSCLE INJURIES AND PHYSICAL RECOVERY INCLUDING OTHER CHRONIC CONDITIONS AND DISEASES. 2022 2 6166 34 THE GLUTATHIONE SYSTEM: A NEW DRUG TARGET IN NEUROIMMUNE DISORDERS. GLUTATHIONE (GSH) HAS A CRUCIAL ROLE IN CELLULAR SIGNALING AND ANTIOXIDANT DEFENSES EITHER BY REACTING DIRECTLY WITH REACTIVE OXYGEN OR NITROGEN SPECIES OR BY ACTING AS AN ESSENTIAL COFACTOR FOR GSH S-TRANSFERASES AND GLUTATHIONE PEROXIDASES. GSH ACTING IN CONCERT WITH ITS DEPENDENT ENZYMES, KNOWN AS THE GLUTATHIONE SYSTEM, IS RESPONSIBLE FOR THE DETOXIFICATION OF REACTIVE OXYGEN AND NITROGEN SPECIES (ROS/RNS) AND ELECTROPHILES PRODUCED BY XENOBIOTICS. ADEQUATE LEVELS OF GSH ARE ESSENTIAL FOR THE OPTIMAL FUNCTIONING OF THE IMMUNE SYSTEM IN GENERAL AND T CELL ACTIVATION AND DIFFERENTIATION IN PARTICULAR. GSH IS A UBIQUITOUS REGULATOR OF THE CELL CYCLE PER SE. GSH ALSO HAS CRUCIAL FUNCTIONS IN THE BRAIN AS AN ANTIOXIDANT, NEUROMODULATOR, NEUROTRANSMITTER, AND ENABLER OF NEURON SURVIVAL. DEPLETION OF GSH LEADS TO EXACERBATION OF DAMAGE BY OXIDATIVE AND NITROSATIVE STRESS; HYPERNITROSYLATION; INCREASED LEVELS OF PROINFLAMMATORY MEDIATORS AND INFLAMMATORY POTENTIAL; DYSFUNCTIONS OF INTRACELLULAR SIGNALING NETWORKS, E.G., P53, NUCLEAR FACTOR-KAPPAB, AND JANUS KINASES; DECREASED CELL PROLIFERATION AND DNA SYNTHESIS; INACTIVATION OF COMPLEX I OF THE ELECTRON TRANSPORT CHAIN; ACTIVATION OF CYTOCHROME C AND THE APOPTOTIC MACHINERY; BLOCKADE OF THE METHIONINE CYCLE; AND COMPROMISED EPIGENETIC REGULATION OF GENE EXPRESSION. AS SUCH, GSH DEPLETION HAS MARKED CONSEQUENCES FOR THE HOMEOSTATIC CONTROL OF THE IMMUNE SYSTEM, OXIDATIVE AND NITROSATIVE STRESS (O&NS) PATHWAYS, REGULATION OF ENERGY PRODUCTION, AND MITOCHONDRIAL SURVIVAL AS WELL. GSH DEPLETION AND CONCOMITANT INCREASE IN O&NS AND MITOCHONDRIAL DYSFUNCTIONS PLAY A ROLE IN THE PATHOPHYSIOLOGY OF DIVERSE NEUROIMMUNE DISORDERS, INCLUDING DEPRESSION, MYALGIC ENCEPHALOMYELITIS/CHRONIC FATIGUE SYNDROME AND PARKINSON'S DISEASE, SUGGESTING THAT DEPLETED GSH IS AN INTEGRAL PART OF THESE DISEASES. THERAPEUTICAL INTERVENTIONS THAT AIM TO INCREASE GSH CONCENTRATIONS IN VIVO INCLUDE N-ACETYL CYSTEINE; NRF-2 ACTIVATION VIA HYPERBARIC OXYGEN THERAPY; DIMETHYL FUMARATE; PHYTOCHEMICALS, INCLUDING CURCUMIN, RESVERATROL, AND CINNAMON; AND FOLATE SUPPLEMENTATION. 2014 3 5986 31 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 4 6540 26 TRANSCRIPTIONAL, EPIGENETIC, AND FUNCTIONAL REPROGRAMMING OF MONOCYTES FROM NON-HUMAN PRIMATES FOLLOWING CHRONIC ALCOHOL DRINKING. CHRONIC HEAVY DRINKING (CHD) OF ALCOHOL IS A KNOWN RISK FACTOR FOR INCREASED SUSCEPTIBILITY TO BACTERIAL AND VIRAL INFECTION AS WELL AS IMPAIRED WOUND HEALING. EVIDENCE SUGGESTS THAT THESE DEFECTS ARE MEDIATED BY A DYSREGULATED INFLAMMATORY RESPONSE ORIGINATING FROM MYELOID CELLS, NOTABLY MONOCYTES AND MACROPHAGES, BUT THE MECHANISMS REMAIN POORLY UNDERSTOOD. OUR ABILITY TO STUDY CHD IS IMPACTED BY THE COMPLEXITIES OF HUMAN DRINKING PATTERNS AND BEHAVIOR AS WELL AS COMORBIDITIES AND CONFOUNDING RISK FACTORS FOR PATIENTS WITH ALCOHOL USE DISORDERS. TO OVERCOME THESE CHALLENGES, WE UTILIZED A TRANSLATIONAL RHESUS MACAQUE MODEL OF VOLUNTARY ETHANOL SELF-ADMINISTRATION THAT CLOSELY RECAPITULATES HUMAN DRINKING PATTERNS AND CHRONICITY. IN THIS STUDY, WE EXAMINED THE EFFECTS OF CHD ON BLOOD MONOCYTES IN CONTROL AND CHD FEMALE MACAQUES AFTER 12 MONTHS OF DAILY ETHANOL CONSUMPTION. WHILE MONOCYTES FROM CHD FEMALE MACAQUES GENERATED A HYPER-INFLAMMATORY RESPONSE TO EX VIVO LPS STIMULATION, THEIR RESPONSE TO E. COLI WAS DAMPENED. IN DEPTH SCRNA-SEQ ANALYSIS OF PURIFIED MONOCYTES REVEALED SIGNIFICANT SHIFTS IN CLASSICAL MONOCYTE SUBSETS WITH ACCUMULATION OF CELLS EXPRESSING MARKERS OF HYPOXIA (HIF1A) AND INFLAMMATION (NFKB SIGNALING PATHWAY) IN CHD MACAQUES. THE INCREASED PRESENCE OF MONOCYTE SUBSETS SKEWED TOWARDS INFLAMMATORY PHENOTYPES WAS COMPLEMENTED BY EPIGENETIC ANALYSIS, WHICH REVEALED HIGHER ACCESSIBILITY OF PROMOTER REGIONS THAT REGULATE GENES INVOLVED IN CYTOKINE SIGNALING PATHWAYS. COLLECTIVELY, DATA PRESENTED IN THIS MANUSCRIPT DEMONSTRATE THAT CHD SHIFTS CLASSICAL MONOCYTE SUBSET COMPOSITION AND PRIMES THE MONOCYTES TOWARDS A MORE HYPER-INFLAMMATORY RESPONSE TO LPS, BUT COMPROMISED PATHOGEN RESPONSE. 2021 5 3151 29 GLUCOCORTICOIDS, EPIGENETIC CONTROL AND STRESS RESILIENCE. GLUCOCORTICOID HORMONES PLAY A PIVOTAL ROLE IN THE RESPONSE TO STRESSFUL CHALLENGES. THE SURGE IN GLUCOCORTICOID HORMONE SECRETION AFTER STRESS NEEDS TO BE TIGHTLY CONTROLLED WITH CHARACTERISTICS LIKE PEAK HEIGHT, CURVATURE AND DURATION DEPENDING ON THE NATURE AND SEVERITY OF THE CHALLENGE. THIS IS IMPORTANT AS CHRONIC HYPER- OR HYPO-RESPONSES ARE DETRIMENTAL TO HEALTH DUE TO INCREASING THE RISK FOR DEVELOPING A STRESS-RELATED MENTAL DISORDER. PROPER GLUCOCORTICOID RESPONSES TO STRESS ARE CRITICAL FOR ADAPTATION. THEREFORE, THE TIGHT CONTROL OF BASELINE AND STRESS-EVOKED GLUCOCORTICOID SECRETION ARE IMPORTANT CONSTITUENTS OF AN ORGANISM'S RESILIENCE. HERE, WE ADDRESS A NUMBER OF MECHANISMS THAT ILLUSTRATE THE MULTITUDE AND COMPLEXITY OF MEASURES SAFEGUARDING THE CONTROL OF GLUCOCORTICOID FUNCTION. THESE MECHANISMS INCLUDE THE CONTROL OF MINERALOCORTICOID (MR) AND GLUCOCORTICOID RECEPTOR (GR) OCCUPANCY AND CONCENTRATION, THE DYNAMIC CONTROL OF FREE GLUCOCORTICOID HORMONE AVAILABILITY BY CORTICOSTEROID-BINDING GLOBULIN (CBG), AND THE CONTROL EXERTED BY GLUCOCORTICOIDS AT THE SIGNALING, EPIGENETIC AND GENOMIC LEVEL ON GENE TRANSCRIPTIONAL RESPONSES TO STRESS. WE REVIEW THE BENEFICIAL EFFECTS OF REGULAR EXERCISE ON HPA AXIS AND SLEEP PHYSIOLOGY, AND COGNITIVE AND ANXIETY-RELATED BEHAVIOR. FURTHERMORE, WE DESCRIBE THAT, POSSIBLY THROUGH CHANGES IN THE GABAERGIC SYSTEM, EXERCISE REDUCES THE IMPACT OF STRESS ON A SIGNALING PATHWAY SPECIFICALLY IN THE DENTATE GYRUS THAT IS STRONGLY IMPLICATED IN THE BEHAVIORAL RESPONSE TO THAT STRESSOR. THESE OBSERVATIONS UNDERLINE THE IMPACT OF LIFE STYLE ON STRESS RESILIENCE. FINALLY, WE ADDRESS HOW SINGLE NUCLEOTIDE POLYMORPHISMS (SNPS) AFFECTING GLUCOCORTICOID ACTION CAN COMPROMISE STRESS RESILIENCE, WHICH BECOMES MOST APPARENT UNDER CONDITIONS OF CHILDHOOD ABUSE. 2015 6 3760 17 INTEGRATED SINGLE CELL ANALYSIS SHOWS CHRONIC ALCOHOL DRINKING DISRUPTS MONOCYTE DIFFERENTIATION IN THE BONE MARROW. CHRONIC HEAVY ALCOHOL DRINKING (CHD) REWIRES MONOCYTES AND MACROPHAGES TOWARD HEIGHTENED INFLAMMATORY STATES WITH COMPROMISED ANTIMICROBIAL DEFENSES THAT PERSIST AFTER 1-MONTH ABSTINENCE. TO DETERMINE WHETHER THESE CHANGES ARE MEDIATED THROUGH ALTERATIONS IN THE BONE MARROW NICHE, WE PROFILED MONOCYTES AND HEMATOPOIETIC STEM CELL PROGENITORS (HSCPS) FROM CHD RHESUS MACAQUES USING A COMBINATION OF FUNCTIONAL ASSAYS AND SINGLE CELL GENOMICS. CHD RESULTED IN TRANSCRIPTIONAL PROFILES CONSISTENT WITH INCREASED ACTIVATION AND INFLAMMATION WITHIN BONE MARROW RESIDENT MONOCYTES AND MACROPHAGES. FURTHERMORE, CHD RESULTED IN TRANSCRIPTIONAL SIGNATURES ASSOCIATED WITH INCREASED OXIDATIVE AND CELLULAR STRESS IN HSCP. DIFFERENTIATION OF HSCP IN VITRO REVEALED SKEWING TOWARD MONOCYTES EXPRESSING "NEUTROPHIL-LIKE" MARKERS WITH GREATER INFLAMMATORY RESPONSES TO BACTERIAL AGONISTS. FURTHER ANALYSES OF HSCPS SHOWED BROAD EPIGENETIC CHANGES THAT WERE IN LINE WITH EXACERBATED INFLAMMATORY RESPONSES WITHIN MONOCYTES AND THEIR PROGENITORS. IN SUMMARY, CHD ALTERS HSCPS IN THE BONE MARROW LEADING TO THE PRODUCTION OF MONOCYTES POISED TO GENERATE DYSREGULATED HYPER-INFLAMMATORY RESPONSES. 2023 7 951 31 CHRONIC MILD STRESS MODIFIED EPIGENETIC MECHANISMS LEADING TO ACCELERATED SENESCENCE AND IMPAIRED COGNITIVE PERFORMANCE IN MICE. COGNITIVE AND BEHAVIOURAL DISTURBANCES ARE A GROWING PUBLIC HEALTHCARE ISSUE FOR THE MODERN SOCIETY, AS STRESSFUL LIFESTYLE IS BECOMING MORE AND MORE COMMON. BESIDES, SEVERAL PIECES OF EVIDENCE STATE THAT ENVIRONMENT IS CRUCIAL IN THE DEVELOPMENT OF SEVERAL DISEASES AS WELL AS COMPROMISING HEALTHY AGING. THEREFORE, IT IS IMPORTANT TO STUDY THE EFFECTS OF STRESS ON COGNITION AND ITS RELATIONSHIP WITH AGING. TO ADDRESS THESE QUERIES, CHRONIC MILD STRESS (CMS) PARADIGM WAS USED IN THE SENESCENCE-ACCELERATED MOUSE PRONE 8 (SAMP8) AND RESISTANT 1 (SAMR1). ON ONE HAND, WE DETERMINED THE CHANGES PRODUCED IN THE THREE MAIN EPIGENETIC MARKS AFTER 4 WEEKS OF CMS TREATMENT, SUCH AS A REDUCTION IN HISTONE POSTTRANSLATIONAL MODIFICATIONS AND DNA METHYLATION, AND UP-REGULATION OR DOWN-REGULATION OF SEVERAL MIRNA INVOLVED IN DIFFERENT CELLULAR PROCESSES IN MICE. IN ADDITION, CMS TREATMENT INDUCED REACTIVE OXYGEN SPECIES (ROS) DAMAGE ACCUMULATION AND LOSS OF ANTIOXIDANT DEFENCE MECHANISMS, AS WELL AS INFLAMMATORY SIGNALLING ACTIVATION THROUGH NF-KAPPAB PATHWAY AND ASTROGLIOSIS MARKERS, LIKE GFAP. REMARKABLY, CMS ALTERED MTORC1 SIGNALLING IN BOTH STRAINS, DECREASING AUTOPHAGY ONLY IN SAMR1 MICE. WE FOUND A DECREASE IN GLYCOGEN SYNTHASE KINASE 3 BETA (GSK-3BETA) INACTIVATION, HYPERPHOSPHORYLATION OF TAU AND AN INCREASE IN SAPPBETA PROTEIN LEVELS IN MICE UNDER CMS. MOREOVER, REDUCTION IN THE NON-AMYLOIDOGENIC SECRETASE ADAM10 PROTEIN LEVELS WAS FOUND IN SAMR1 CMS GROUP. CONSEQUENTLY, DETRIMENTAL EFFECTS ON BEHAVIOUR AND COGNITIVE PERFORMANCE WERE DETECTED IN CMS TREATED MICE, AFFECTING MAINLY SAMR1 MICE, PROMOTING A TURNING TO SAMP8 PHENOTYPE. IN CONCLUSION, CMS IS A FEASIBLE INTERVENTION TO UNDERSTAND THE INFLUENCE OF STRESS ON EPIGENETIC MECHANISMS UNDERLYING COGNITION AND ACCELERATING SENESCENCE. 2020 8 5313 28 PSYCHOLOGICAL STRESS AS A MODULATOR OF FUNCTIONAL RECOVERY FOLLOWING SPINAL CORD INJURY. THERE IS STRONG EVIDENCE INDICATING THAT THE SOCIAL ENVIRONMENT TRIGGERS CHANGES TO THE PSYCHOLOGICAL STRESS RESPONSE AND GLUCOCORTICOID RECEPTOR FUNCTION. CONSIDERABLE LITERATURE LINKS THE SUBSEQUENT CHANGES IN STRESS RESILIENCY TO PHYSICAL HEALTH. HERE, CONVERGING EVIDENCE FOR THE MODULATORY ROLE OF CHRONIC PSYCHOLOGICAL STRESS IN THE RECOVERY PROCESS FOLLOWING SPINAL CORD INJURY (SCI) IS PRESENTED. DESPITE THE CONSIDERABLE ADVANCES IN SCI RESEARCH, WE ARE STILL UNABLE TO IDENTIFY THE CAUSES OF VARIABILITY IN PATIENTS' RECOVERY FOLLOWING INJURY. WE PROPOSE THAT INDIVIDUALS' PAST AND PRESENT LIFE EXPERIENCES (IN THE FORM OF STRESS EXPOSURE) MAY SIGNIFICANTLY MODULATE PATIENTS' OUTCOME POST-SCI. WE PROPOSE A THEORETICAL MODEL TO EXPLAIN THE NEGATIVE IMPACT OF CHRONIC PSYCHOLOGICAL STRESS ON PHYSICAL AND PSYCHOLOGICAL RECOVERY. THE STRESS EXPERIENCED IN LIFE PRIOR TO SCI AND ALSO AS A RESULT OF THE TRAUMATIC INJURY, COULD COMPROMISE GLUCOCORTICOID RECEPTOR SENSITIVITY AND FUNCTION, AND CONTRIBUTE TO HIGH LEVELS OF INFLAMMATION AND APOPTOSIS POST-SCI, DECREASING THE TISSUE REMAINING AT THE INJURY SITE AND UNDERMINING RECOVERY OF FUNCTION. BOTH STRESS-INDUCED GLUCOCORTICOID RESISTANCE AND STRESS-INDUCED EPIGENETIC CHANGES TO THE GLUCOCORTICOID RECEPTOR CAN MODULATE THE NUCLEAR FACTOR-KAPPA B REGULATED INFLAMMATORY PATHWAYS AND THE BCL-2 REGULATED APOPTOSIS PATHWAYS. THIS MODEL NOT ONLY CONTRIBUTES TO THE THEORETICAL UNDERSTANDING OF THE RECOVERY PROCESS FOLLOWING INJURY, BUT ALSO PROVIDES CONCRETE TESTABLE HYPOTHESES FOR FUTURE STUDIES. 2014 9 948 21 CHRONIC METABOLIC DERANGEMENT-INDUCED COGNITIVE DEFICITS AND NEUROTOXICITY ARE ASSOCIATED WITH REST INACTIVATION. CHRONIC METABOLIC ALTERATIONS MAY REPRESENT A RISK FACTOR FOR THE DEVELOPMENT OF COGNITIVE IMPAIRMENT, DEMENTIA, OR NEURODEGENERATIVE DISEASES. HYPERGLYCEMIA AND OBESITY ARE KNOWN TO IMPRINT EPIGENETIC MARKERS THAT COMPROMISE THE PROPER EXPRESSION OF CELL SURVIVAL GENES. HERE, WE SHOWED THAT CHRONIC HYPERGLYCEMIA (60 DAYS) INDUCED BY A SINGLE INTRAPERITONEAL INJECTION OF STREPTOZOTOCIN COMPROMISED COGNITION BY REDUCING HIPPOCAMPAL ERK SIGNALING AND BY INDUCING NEUROTOXICITY IN RATS. THE MECHANISMS APPEAR TO BE LINKED TO REDUCED ACTIVE DNA DEMETHYLATION AND DIMINISHED EXPRESSION OF THE NEUROPROTECTIVE TRANSCRIPTION FACTOR REST. THE IMPACT OF THE RELATIONSHIP BETWEEN ADIPOSITY AND DNA HYPERMETHYLATION ON REST EXPRESSION WAS ALSO DEMONSTRATED IN PERIPHERAL BLOOD MONONUCLEAR CELLS IN OBESE CHILDREN WITH REDUCED LEVELS OF BLOOD ASCORBATE. THE REVERSIBLE NATURE OF EPIGENETIC MODIFICATIONS AND THE COGNITIVE IMPAIRMENT REPORTED IN OBESE CHILDREN, ADOLESCENTS, AND ADULTS SUGGEST THAT THE CORRECTION OF THE ANTHROPOMETRY AND THE PERIPHERAL METABOLIC ALTERATIONS WOULD PROTECT BRAIN HOMEOSTASIS AND REDUCE THE RISK OF DEVELOPING NEURODEGENERATIVE DISEASES. 2019 10 4620 22 NEURO-IMMUNE DYSFUNCTION DURING BRAIN AGING: NEW INSIGHTS IN MICROGLIAL CELL REGULATION. MICROGLIA, THE RESIDENT IMMUNE CELLS OF THE BRAIN, ARE AT THE CENTER OF COMMUNICATION BETWEEN THE CENTRAL NERVOUS SYSTEM AND IMMUNE SYSTEM. WHILE THESE BRAIN-IMMUNE INTERACTIONS ARE BALANCED IN HEALTHY ADULTHOOD, THE ABILITY TO MAINTAIN HOMEOSTASIS DURING AGING IS IMPAIRED. MICROGLIA DEVELOP A LOSS OF INTEGRATED REGULATORY NETWORKS INCLUDING ABERRANT SIGNALING FROM OTHER BRAIN CELLS, IMMUNE SENSORS, AND EPIGENETIC MODIFIERS. THE LOW-GRADE CHRONIC NEUROINFLAMMATION ASSOCIATED WITH THIS DYSFUNCTIONAL ACTIVITY LIKELY CONTRIBUTES TO COGNITIVE DEFICITS AND SUSCEPTIBILITY TO AGE-RELATED PATHOLOGIES. A BETTER UNDERSTANDING OF THE UNDERLYING MECHANISMS RESPONSIBLE FOR NEURO-IMMUNE DYSREGULATION WITH AGE IS CRUCIAL FOR PROVIDING TARGETED THERAPEUTIC STRATEGIES TO SUPPORT BRAIN REPAIR AND HEALTHY AGING. 2016 11 6520 39 TRANSCRIPTIONAL AND EPIGENETIC REGULATION OF MONOCYTE AND MACROPHAGE DYSFUNCTION BY CHRONIC ALCOHOL CONSUMPTION. DRINKING ALCOHOL, EVEN IN MODERATION, CAN AFFECT THE IMMUNE SYSTEM. STUDIES HAVE SHOWN DISPROPORTIONATE EFFECTS OF ALCOHOL ON CIRCULATING AND TISSUE-RESIDENT MYELOID CELLS (GRANULOCYTES, MONOCYTES, MACROPHAGES, DENDRITIC CELLS). THESE CELLS ORCHESTRATE THE BODY'S FIRST LINE OF DEFENSE AGAINST MICROBIAL CHALLENGES AS WELL AS MAINTAIN TISSUE HOMEOSTASIS AND REPAIR. ALCOHOL'S EFFECTS ON THESE CELLS ARE DEPENDENT ON EXPOSURE PATTERN, WITH ACUTE DRINKING DAMPENING BUT CHRONIC DRINKING ENHANCING PRODUCTION OF INFLAMMATORY MEDIATORS. ALTHOUGH CHRONIC DRINKING IS ASSOCIATED WITH HEIGHTENED SYSTEMIC INFLAMMATION, STUDIES ON TISSUE RESIDENT MACROPHAGE POPULATIONS IN SEVERAL ORGANS INCLUDING THE SPLEEN, LIVER, BRAIN, AND LUNG HAVE ALSO SHOWN COMPROMISED FUNCTIONAL AND METABOLIC CAPACITIES OF THESE CELLS. MANY OF THESE EFFECTS ARE THOUGHT TO BE MEDIATED BY OXIDATIVE STRESS CAUSED BY ALCOHOL AND ITS METABOLITES WHICH CAN DIRECTLY IMPACT THE CELLULAR EPIGENETIC LANDSCAPES. IN ADDITION, SINCE MYELOID CELLS ARE RELATIVELY SHORT-LIVED IN CIRCULATION AND ARE UNDER CONSTANT REPOPULATION FROM THE BONE MARROW COMPARTMENT, ALCOHOL'S EFFECTS ON BONE MARROW PROGENITORS AND HEMATOPOIESIS ARE IMPORTANT FOR UNDERSTANDING THE IMPACT OF ALCOHOL SYSTEMICALLY ON THESE MYELOID POPULATIONS. ALCOHOL-INDUCED DISRUPTION OF PROGENITOR, CIRCULATING, AND TISSUE RESIDENT MYELOID POPULATIONS CONTRIBUTE TO THE INCREASED SUSCEPTIBILITY OF PATIENTS WITH ALCOHOL USE DISORDERS TO VIRAL AND BACTERIAL INFECTIONS. IN THIS REVIEW, WE PROVIDE AN OVERVIEW OF THE IMPACT OF CHRONIC ALCOHOL CONSUMPTION ON THE FUNCTION OF MONOCYTES AND MACROPHAGES IN HOST DEFENSE, TISSUE REPAIR AND INFLAMMATION. WE THEN SUMMARIZE OUR CURRENT UNDERSTANDING OF THE MECHANISMS UNDERLYING ALCOHOL-INDUCED DISRUPTION AND EXAMINE CHANGES IN TRANSCRIPTOME AND EPIGENOME OF MONOCYTES AND MCROPHAGES. OVERALL, CHRONIC ALCOHOL CONSUMPTION LEADS TO HYPER-INFLAMMATION CONCOMITANT WITH DECREASED MICROBIAL AND WOUND HEALING RESPONSES BY MONOCYTES/MACROPHAGES DUE TO A REWIRING OF THE EPIGENTIC AND TRANSCRIPTIONAL LANDSCAPE. HOWEVER, IN ADVANCED ALCOHOLIC LIVER DISEASE, MYELOID CELLS BECOME IMMUNOSUPPRESSED AS A RESPONSE TO THE SURROUNDING HYPER-INFLAMMATORY MILIEU. THEREFORE, THE EFFECT OF CHRONIC ALCOHOL ON THE INFLAMMATORY RESPONSE DEPENDS ON DISEASE STATE AND THE IMMUNE CELL POPULATION. 2022 12 375 18 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 13 3759 23 INTEGRATED SINGLE CELL ANALYSIS SHOWS CHRONIC ALCOHOL DRINKING DISRUPTS MONOCYTE DIFFERENTIATION IN THE BONE MARROW NICHE. CHRONIC ALCOHOL DRINKING REWIRES CIRCULATING MONOCYTES AND TISSUE-RESIDENT MACROPHAGES TOWARDS HEIGHTENED INFLAMMATORY STATES WITH COMPROMISED ANTI-MICROBIAL DEFENSES. AS THESE EFFECTS REMAIN CONSISTENT IN SHORT-LIVED MONOCYTES AFTER A 1-MONTH ABSTINENCE PERIOD IT IS UNCLEAR WHETHER THESE CHANGES ARE RESTRICTED TO THE PERIPHERY OR MEDIATED THROUGH ALTERATIONS IN THE PROGENITOR NICHE. TO TEST THIS HYPOTHESIS, WE PROFILED MONOCYTES/MACROPHAGES AND HEMATOPOIETIC STEM CELL PROGENITORS (HSCP) OF THE BONE MARROW COMPARTMENT FROM RHESUS MACAQUES AFTER 12 MONTHS OF ETHANOL CONSUMPTION USING A COMBINATION OF FUNCTIONAL ASSAYS AND SINGLE CELL GENOMICS. BONE MARROW-RESIDENT MONOCYTES/MACROPHAGES FROM ETHANOL-CONSUMING ANIMALS EXHIBITED HEIGHTENED INFLAMMATION. DIFFERENTIATION OF HSCP IN VITRO REVEALED SKEWING TOWARDS MONOCYTES EXPRESSING NEUTROPHIL-LIKE MARKERS WITH HEIGHTENED INFLAMMATORY RESPONSES TO BACTERIAL AGONISTS. SINGLE CELL TRANSCRIPTIONAL ANALYSIS OF HSCPS SHOWED REDUCED PROLIFERATION BUT INCREASED INFLAMMATORY MARKERS IN MATURE MYELOID PROGENITORS. WE OBSERVED TRANSCRIPTIONAL SIGNATURES ASSOCIATED WITH INCREASED OXIDATIVE AND CELLULAR STRESS AS WELL AS OXIDATIVE PHOSPHORYLATION IN IMMATURE AND MATURE MYELOID PROGENITORS. SINGLE CELL ANALYSIS OF THE CHROMATIN LANDSCAPE SHOWED ALTERED DRIVERS OF DIFFERENTIATION IN MONOCYTES AND PROGENITORS. COLLECTIVELY, THESE DATA INDICATE THAT CHRONIC ETHANOL DRINKING RESULTS IN REMODELING OF THE TRANSCRIPTIONAL AND EPIGENETIC LANDSCAPES OF THE BONE MARROW COMPARTMENT LEADING TO ALTERED FUNCTIONS IN THE PERIPHERY. 2023 14 2361 24 EPIGENETIC REGULATION OF SKELETAL TISSUE INTEGRITY AND OSTEOPOROSIS DEVELOPMENT. BONE TURNOVER IS SOPHISTICATEDLY BALANCED BY A DYNAMIC COUPLING OF BONE FORMATION AND RESORPTION AT VARIOUS RATES. THE ORCHESTRATION OF THIS CONTINUOUS REMODELING OF THE SKELETON FURTHER AFFECTS OTHER SKELETAL TISSUES THROUGH ORGAN CROSSTALK. CHRONIC EXCESSIVE BONE RESORPTION COMPROMISES BONE MASS AND ITS POROUS MICROSTRUCTURE AS WELL AS PROPER BIOMECHANICS. THIS ACCELERATES THE DEVELOPMENT OF OSTEOPOROTIC DISORDERS, A LEADING CAUSE OF SKELETAL DEGENERATION-ASSOCIATED DISABILITY AND PREMATURE DEATH. BONE-FORMING CELLS PLAY IMPORTANT ROLES IN MAINTAINING BONE DEPOSIT AND OSTEOCLASTIC RESORPTION. A POOR ORGANELLE MACHINERY, SUCH AS MITOCHONDRIAL DYSFUNCTION, ENDOPLASMIC RETICULUM STRESS, AND DEFECTIVE AUTOPHAGY, ETC., DYSREGULATES GROWTH FACTOR SECRETION, MINERALIZATION MATRIX PRODUCTION, OR OSTEOCLAST-REGULATORY CAPACITY IN OSTEOBLASTIC CELLS. A PLETHORA OF EPIGENETIC PATHWAYS REGULATE BONE FORMATION, SKELETAL INTEGRITY, AND THE DEVELOPMENT OF OSTEOPOROSIS. MICRORNAS INHIBIT PROTEIN TRANSLATION BY BINDING THE 3'-UNTRANSLATED REGION OF MRNAS OR PROMOTE TRANSLATION THROUGH POST-TRANSCRIPTIONAL PATHWAYS. DNA METHYLATION AND POST-TRANSLATIONAL MODIFICATION OF HISTONES ALTER THE CHROMATIN STRUCTURE, HINDERING HISTONE ENRICHMENT IN PROMOTER REGIONS. MICRORNA-PROCESSING ENZYMES AND DNA AS WELL AS HISTONE MODIFICATION ENZYMES CATALYZE THESE MODIFYING REACTIONS. GAIN AND LOSS OF THESE EPIGENETIC MODIFIERS IN BONE-FORMING CELLS AFFECT THEIR EPIGENETIC LANDSCAPES, INFLUENCING BONE HOMEOSTASIS, MICROARCHITECTURAL INTEGRITY, AND OSTEOPOROTIC CHANGES. THIS ARTICLE CONVEYS PRODUCTIVE INSIGHTS INTO BIOLOGICAL ROLES OF DNA METHYLATION, MICRORNA, AND HISTONE MODIFICATION AND HIGHLIGHTS THEIR INTERACTIONS DURING SKELETAL DEVELOPMENT AND BONE LOSS UNDER PHYSIOLOGICAL AND PATHOLOGICAL CONDITIONS. 2020 15 4375 30 MISREGULATED INFLAMMATION AS AN OUTCOME OF EARLY-LIFE EXPOSURE TO ENDOCRINE-DISRUPTING CHEMICALS. THIS REVIEW INTRODUCES A POTENTIAL UNIFYING CONCEPT INVOLVING THE RISK OF CHRONIC DISEASES IN WHICH EARLY-LIFE EXPOSURE TO ENDOCRINE-DISRUPTING CHEMICALS (EDCS) CAN PROGRAM HOST RESPONSES FOR MISREGULATED INFLAMMATION. INFLAMMATION IS A PART OF HOST DEFENSE AGAINST PATHOGENIC CHALLENGES AND ONE OF THE PROCESSES NECESSARY FOR NORMAL TISSUE HOMEOREGULATION AND FOR REPRODUCTION (E.G., IMPLANTATION, LABOR). DEVIATIONS FROM TIGHTLY REGULATED INFLAMMATION PRESENT A SIGNIFICANT HEALTH RISK BECAUSE UNRESOLVED INFLAMMATION CAN COMPROMISE TISSUE FUNCTION AND INCREASE THE RISK FOR LATER-LIFE CANCER IN THE AFFECTED TARGET TISSUE. THE CRITICAL WINDOWS OF INNATE IMMUNE VULNERABILITY DURING PRENATAL AND NEONATAL MATURATION ARE WHEN DEVELOPMENTAL PROGRAMMING AND THE TRAJECTORY FOR CHILDHOOD AND ADULT INFLAMMATORY RESPONSES ARE LARGELY ESTABLISHED. MISREGULATED INFLAMMATION IS A COMMON THREAD THAT LINKS MOST SIGNIFICANT CHRONIC DISEASES AND CONDITIONS ACROSS ALL PHYSIOLOGIC SYSTEMS AS WELL AS THE ASSOCIATED COMORBID CONDITIONS. AS A RESULT, CHRONIC DISEASES EXIST BOTH AS A MYRIAD OF CONDITIONS AND AS AN INTEGRATED, DYSFUNCTIONALLY CONNECTED UNIT. BECAUSE THE HORMONE MICROENVIRONMENT EXERTS A SIGNIFICANT EFFECT ON RESIDENT INNATE IMMUNE CELL FUNCTION, ENDOCRINE DISRUPTION IS LIKELY TO PRODUCE MISREGULATED INFLAMMATION IN TISSUES. AMONG THE FACTORS DETERMINING SPECIFIC HEALTH RISKS AND DISEASE OUTCOMES ACROSS A LIFETIME ARE THE AGE OF EXPOSURE, SEX, GENETIC BACKGROUND, AND TRANSGENERATIONAL EPIGENETIC EXPERIENCES. ADDITIONAL RESEARCH INTO EARLY-LIFE EDC EXPOSURE AND MISREGULATION OF INFLAMMATION APPEARS TO BE A USEFUL AVENUE FOR REDUCING ENVIRONMENTAL HEALTH RISKS. 2012 16 4633 31 NEUROIMMUNE ACTIVATION DRIVES MULTIPLE BRAIN STATES. NEUROIMMUNE SIGNALING IS INCREASINGLY IDENTIFIED AS A CRITICAL COMPONENT OF NEURONAL PROCESSES UNDERLYING MEMORY, EMOTION AND COGNITION. THE INTERACTIONS OF MICROGLIA AND ASTROCYTES WITH NEURONS AND SYNAPSES, AND THE INDIVIDUAL CYTOKINES AND IMMUNE SIGNALING MOLECULES THAT MEDIATE THESE INTERACTIONS ARE A CURRENT FOCUS OF MUCH RESEARCH. HERE, WE DISCUSS NEUROIMMUNE ACTIVATION AS A MECHANISM TRIGGERING DIFFERENT STATES THAT MODULATE COGNITIVE AND AFFECTIVE PROCESSES TO ALLOW FOR APPROPRIATE BEHAVIOR DURING AND AFTER ILLNESS OR INJURY. WE PROPOSE THAT THESE STATES LIE ON A CONTINUUM FROM A NAIVE HOMEOSTATIC BASELINE STATE IN THE ABSENCE OF STIMULATION, TO ACUTE NEUROIMMUNE ACTIVITY AND CHRONIC ACTIVATION. IMPORTANTLY, CONSEQUENCES OF ILLNESS OR INJURY INCLUDING COGNITIVE DEFICITS AND MOOD IMPAIRMENTS CAN PERSIST LONG AFTER RESOLUTION OF IMMUNE SIGNALING. THIS SUGGESTS THAT NEUROIMMUNE ACTIVATION ALSO RESULTS IN AN ENDURING SHIFT IN THE HOMEOSTATIC BASELINE STATE WITH LONG LASTING CONSEQUENCES FOR NEURAL FUNCTION AND BEHAVIOR. SUCH DIFFERENT STATES CAN BE IDENTIFIED IN A MULTIDIMENSIONAL WAY, USING PATTERNS OF CYTOKINE AND GLIAL ACTIVATION, BEHAVIORAL AND COGNITIVE CHANGES, AND EPIGENETIC SIGNATURES. IDENTIFYING DISTINCT NEUROIMMUNE STATES AND THEIR CONSEQUENCES FOR NEURAL FUNCTION WILL PROVIDE A FRAMEWORK FOR PREDICTING VULNERABILITY TO DISORDERS OF MEMORY, COGNITION AND EMOTION BOTH DURING AND LONG AFTER RECOVERY FROM ILLNESS. 2018 17 4044 20 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 18 5631 30 SENESCENCE-INFLAMMATORY REGULATION OF REPARATIVE CELLULAR REPROGRAMMING IN AGING AND CANCER. THE INABILITY OF ADULT TISSUES TO TRANSITORILY GENERATE CELLS WITH FUNCTIONAL STEM CELL-LIKE PROPERTIES IS A MAJOR OBSTACLE TO TISSUE SELF-REPAIR. NUCLEAR REPROGRAMMING-LIKE PHENOMENA THAT INDUCE A TRANSIENT ACQUISITION OF EPIGENETIC PLASTICITY AND PHENOTYPE MALLEABILITY MAY CONSTITUTE A REPARATIVE ROUTE THROUGH WHICH HUMAN TISSUES RESPOND TO INJURY, STRESS, AND DISEASE. HOWEVER, TISSUE REJUVENATION SHOULD INVOLVE NOT ONLY THE TRANSIENT EPIGENETIC REPROGRAMMING OF DIFFERENTIATED CELLS, BUT ALSO THE COMMITTED RE-ACQUISITION OF THE ORIGINAL OR ALTERNATIVE COMMITTED CELL FATE. CHRONIC OR UNRESTRAINED EPIGENETIC PLASTICITY WOULD DRIVE AGING PHENOTYPES BY IMPAIRING THE REPAIR OR THE REPLACEMENT OF DAMAGED CELLS; SUCH UNCONTROLLED PHENOMENA OF IN VIVO REPROGRAMMING MIGHT ALSO GENERATE CANCER-LIKE CELLULAR STATES. WE HEREIN PROPOSE THAT THE ABILITY OF SENESCENCE-ASSOCIATED INFLAMMATORY SIGNALING TO REGULATE IN VIVO REPROGRAMMING CYCLES OF TISSUE REPAIR OUTLINES A THRESHOLD MODEL OF AGING AND CANCER. THE DEGREE OF SENESCENCE/INFLAMMATION-ASSOCIATED DEVIATION FROM THE HOMEOSTATIC STATE MAY DELINEATE A TYPE OF THRESHOLDING ALGORITHM DISTINGUISHING BENEFICIAL FROM DELETERIOUS EFFECTS OF IN VIVO REPROGRAMMING. FIRST, TRANSIENT ACTIVATION OF NF-KAPPAB-RELATED INNATE IMMUNITY AND SENESCENCE-ASSOCIATED INFLAMMATORY COMPONENTS (E.G., IL-6) MIGHT FACILITATE REPARATIVE CELLULAR REPROGRAMMING IN RESPONSE TO ACUTE INFLAMMATORY EVENTS. SECOND, PARA-INFLAMMATION SWITCHES MIGHT PROMOTE LONG-LASTING BUT REVERSIBLE REFRACTORINESS TO REPARATIVE CELLULAR REPROGRAMMING. THIRD, CHRONIC SENESCENCE-ASSOCIATED INFLAMMATORY SIGNALING MIGHT LOCK CELLS IN HIGHLY PLASTIC EPIGENETIC STATES DISABLED FOR REPARATIVE DIFFERENTIATION. THE CONSIDERATION OF A CELLULAR REPROGRAMMING-CENTERED VIEW OF EPIGENETIC PLASTICITY AS A FUNDAMENTAL ELEMENT OF A TISSUE'S CAPACITY TO UNDERGO SUCCESSFUL REPAIR, AGING DEGENERATION OR MALIGNANT TRANSFORMATION SHOULD PROVIDE CHALLENGING STOCHASTIC INSIGHTS INTO THE CURRENT DETERMINISTIC GENETIC PARADIGM FOR MOST CHRONIC DISEASES, THEREBY INCREASING THE SPECTRUM OF THERAPEUTIC APPROACHES FOR PHYSIOLOGICAL AGING AND CANCER. 2017 19 5816 22 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 20 6374 30 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