1 5140 106 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 2 5632 29 SENESCENT CELLS: SASPECTED DRIVERS OF AGE-RELATED PATHOLOGIES. THE PROGRESSION OF PHYSIOLOGICAL AGEING IS DRIVEN BY INTRACELLULAR ABERRATIONS INCLUDING TELOMERE ATTRITION, GENOMIC INSTABILITY, EPIGENETIC ALTERATIONS AND LOSS OF PROTEOSTASIS. THESE IN TURN DAMAGE CELLS AND COMPROMISE THEIR FUNCTIONALITY. CELLULAR SENESCENCE, A STABLE IRREVERSIBLE CELL-CYCLE ARREST, IS ELICITED IN DAMAGED CELLS AND PREVENTS THEIR PROPAGATION IN THE ORGANISM. UNDER NORMAL CONDITIONS, SENESCENT CELLS RECRUIT THE IMMUNE SYSTEM WHICH FACILITATES THEIR REMOVAL FROM TISSUES. NEVERTHELESS, DURING AGEING, TISSUE-RESIDING SENESCENT CELLS TEND TO ACCUMULATE, AND MIGHT NEGATIVELY IMPACT THEIR MICROENVIRONMENT VIA PROFOUND SECRETORY PHENOTYPE WITH PRO-INFLAMMATORY CHARACTERISTICS, TERMED SENESCENCE-ASSOCIATED SECRETORY PHENOTYPE (SASP). INDEED, SENESCENT CELLS ARE MOSTLY ABUNDANT AT SITES OF AGE-RELATED PATHOLOGIES, INCLUDING DEGENERATIVE DISORDERS AND MALIGNANCIES. INTERESTINGLY, STUDIES ON PROGEROID MICE INDICATE THAT SELECTIVE ELIMINATION OF SENESCENT CELLS CAN DELAY AGE-RELATED DETERIORATION. THIS SUGGESTS THAT CHRONIC INFLAMMATION INDUCED BY SENESCENT CELLS MIGHT BE A MAIN DRIVER OF THESE PATHOLOGIES. IMPORTANTLY, SENESCENT CELLS ACCUMULATE AS A RESULT OF DEFICIENT IMMUNE SURVEILLANCE, AND THEIR REMOVAL IS INCREASED UPON THE USE OF IMMUNE STIMULATORY AGENTS. INSIGHTS INTO MECHANISMS OF SENESCENCE SURVEILLANCE COULD BE COMBINED WITH CURRENT APPROACHES FOR CANCER IMMUNOTHERAPY TO PROPOSE NEW PREVENTIVE AND THERAPEUTIC STRATEGIES FOR AGE-RELATED DISEASES. 2014 3 5801 30 STIFFNESS AND AGING IN CARDIOVASCULAR DISEASES: THE DANGEROUS RELATIONSHIP BETWEEN FORCE AND SENESCENCE. BIOLOGICAL AGING IS A PROCESS ASSOCIATED WITH A GRADUAL DECLINE IN TISSUES' HOMEOSTASIS BASED ON THE PROGRESSIVE INABILITY OF THE CELLS TO SELF-RENEW. CELLULAR SENESCENCE IS ONE OF THE HALLMARKS OF THE AGING PROCESS, CHARACTERIZED BY AN IRREVERSIBLE CELL CYCLE ARREST DUE TO REACTIVE OXYGEN SPECIES (ROS) PRODUCTION, TELOMERES SHORTENING, CHRONIC INFLAMMATORY ACTIVATION, AND CHROMATIN MODIFICATIONS. IN THIS REVIEW, WE WILL DESCRIBE THE EFFECTS OF SENESCENCE ON TISSUE STRUCTURE, EXTRACELLULAR MATRIX (ECM) ORGANIZATION, AND NUCLEUS ARCHITECTURE, AND SEE HOW THESE CHANGES AFFECT (ARE AFFECTED BY) MECHANO-TRANSDUCTION. IN OUR VIEW, THIS IS ESSENTIAL FOR A DEEPER UNDERSTANDING OF THE PROGRESSIVE PATHOLOGICAL EVOLUTION OF THE CARDIOVASCULAR SYSTEM AND ITS RELATIONSHIP WITH THE DETRIMENTAL EFFECTS OF RISK FACTORS, KNOWN TO ACT AT AN EPIGENETIC LEVEL. 2021 4 5322 20 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 5 4145 26 MECHANISMS OF VASCULAR AGING. AGING OF THE VASCULATURE PLAYS A CENTRAL ROLE IN MORBIDITY AND MORTALITY OF OLDER PEOPLE. TO DEVELOP NOVEL TREATMENTS FOR AMELIORATION OF UNSUCCESSFUL VASCULAR AGING AND PREVENTION OF AGE-RELATED VASCULAR PATHOLOGIES, IT IS ESSENTIAL TO UNDERSTAND THE CELLULAR AND FUNCTIONAL CHANGES THAT OCCUR IN THE VASCULATURE DURING AGING. IN THIS REVIEW, THE PATHOPHYSIOLOGICAL ROLES OF FUNDAMENTAL CELLULAR AND MOLECULAR MECHANISMS OF AGING, INCLUDING OXIDATIVE STRESS, MITOCHONDRIAL DYSFUNCTION, IMPAIRED RESISTANCE TO MOLECULAR STRESSORS, CHRONIC LOW-GRADE INFLAMMATION, GENOMIC INSTABILITY, CELLULAR SENESCENCE, EPIGENETIC ALTERATIONS, LOSS OF PROTEIN HOMEOSTASIS, DEREGULATED NUTRIENT SENSING, AND STEM CELL DYSFUNCTION IN THE VASCULAR SYSTEM ARE CONSIDERED IN TERMS OF THEIR CONTRIBUTION TO THE PATHOGENESIS OF BOTH MICROVASCULAR AND MACROVASCULAR DISEASES ASSOCIATED WITH OLD AGE. THE IMPORTANCE OF PROGERONIC AND ANTIGERONIC CIRCULATING FACTORS IN RELATION TO DEVELOPMENT OF VASCULAR AGING PHENOTYPES ARE DISCUSSED. FINALLY, FUTURE DIRECTIONS AND OPPORTUNITIES TO DEVELOP NOVEL INTERVENTIONS TO PREVENT/DELAY AGE-RELATED VASCULAR PATHOLOGIES BY TARGETING FUNDAMENTAL CELLULAR AND MOLECULAR AGING PROCESSES ARE PRESENTED. 2018 6 3640 22 INCREASED EXTRACELLULAR MATRIX PROTEIN PRODUCTION IN CHRONIC DIABETIC COMPLICATIONS: IMPLICATIONS OF NON-CODING RNAS. MANAGEMENT OF CHRONIC DIABETIC COMPLICATIONS REMAINS A MAJOR MEDICAL CHALLENGE WORLDWIDE. ONE OF THE CHARACTERISTIC FEATURES OF ALL CHRONIC DIABETIC COMPLICATIONS IS AUGMENTED PRODUCTION OF EXTRACELLULAR MATRIX (ECM) PROTEINS. SUCH ECM PROTEINS ARE DEPOSITED IN ALL TISSUES AFFECTED BY CHRONIC COMPLICATIONS, ULTIMATELY CAUSING ORGAN DAMAGE AND DYSFUNCTION. A CONTRIBUTING FACTOR TO THIS PATHOGENETIC PROCESS IS GLUCOSE-INDUCED ENDOTHELIAL DAMAGE, WHICH INVOLVES PHENOTYPIC TRANSFORMATION OF ENDOTHELIAL CELLS (ECS). THIS PHENOTYPIC TRANSITION OF ECS, FROM A QUIESCENT STATE TO AN ACTIVATED DYSFUNCTIONAL STATE, CAN BE MEDIATED THROUGH ALTERATIONS IN THE SYNTHESIS OF CELLULAR PROTEINS. IN THIS REVIEW, WE DISCUSSED THE ROLES OF NON-CODING RNAS, SPECIFICALLY MICRORNAS (MIRNAS) AND LONG NON-CODING RNAS (LNCRNAS), IN SUCH PROCESSES. WE FURTHER OUTLINED OTHER EPIGENETIC MECHANISMS REGULATING THE BIOGENESIS AND/OR FUNCTION OF NON-CODING RNAS. OVERALL, WE BELIEVE THAT BETTER UNDERSTANDING OF SUCH MOLECULAR PROCESSES MAY LEAD TO THE DEVELOPMENT OF NOVEL BIOMARKERS AND THERAPEUTIC STRATEGIES IN THE FUTURE. 2019 7 293 29 AGING HALLMARKS AND THE ROLE OF OXIDATIVE STRESS. AGING IS A COMPLEX BIOLOGICAL PROCESS ACCOMPANIED BY A PROGRESSIVE DECLINE IN THE PHYSICAL FUNCTION OF THE ORGANISM AND AN INCREASED RISK OF AGE-RELATED CHRONIC DISEASES SUCH AS CARDIOVASCULAR DISEASES, CANCER, AND NEURODEGENERATIVE DISEASES. STUDIES HAVE ESTABLISHED THAT THERE EXIST NINE HALLMARKS OF THE AGING PROCESS, INCLUDING (I) TELOMERE SHORTENING, (II) GENOMIC INSTABILITY, (III) EPIGENETIC MODIFICATIONS, (IV) MITOCHONDRIAL DYSFUNCTION, (V) LOSS OF PROTEOSTASIS, (VI) DYSREGULATED NUTRIENT SENSING, (VII) STEM CELL EXHAUSTION, (VIII) CELLULAR SENESCENCE, AND (IX) ALTERED CELLULAR COMMUNICATION. ALL THESE ALTERATIONS HAVE BEEN LINKED TO SUSTAINED SYSTEMIC INFLAMMATION, AND THESE MECHANISMS CONTRIBUTE TO THE AGING PROCESS IN TIMING NOT CLEARLY DETERMINED YET. NEVERTHELESS, MITOCHONDRIAL DYSFUNCTION IS ONE OF THE MOST IMPORTANT MECHANISMS CONTRIBUTING TO THE AGING PROCESS. MITOCHONDRIA IS THE PRIMARY ENDOGENOUS SOURCE OF REACTIVE OXYGEN SPECIES (ROS). DURING THE AGING PROCESS, THERE IS A DECLINE IN ATP PRODUCTION AND ELEVATED ROS PRODUCTION TOGETHER WITH A DECLINE IN THE ANTIOXIDANT DEFENSE. ELEVATED ROS LEVELS CAN CAUSE OXIDATIVE STRESS AND SEVERE DAMAGE TO THE CELL, ORGANELLE MEMBRANES, DNA, LIPIDS, AND PROTEINS. THIS DAMAGE CONTRIBUTES TO THE AGING PHENOTYPE. IN THIS REVIEW, WE SUMMARIZE RECENT ADVANCES IN THE MECHANISMS OF AGING WITH AN EMPHASIS ON MITOCHONDRIAL DYSFUNCTION AND ROS PRODUCTION. 2023 8 1894 30 ENDOTHELIAL CELL SENESCENCE AND INFLAMMAGING: MICRORNAS AS BIOMARKERS AND INNOVATIVE THERAPEUTIC TOOLS. AGING IS ACCOMPANIED BY A PROGRESSIVE DECLINE OF ENDOTHELIAL FUNCTION AND A PROGRESSIVE DRIFT TOWARD A SYSTEMIC PRO-INFLAMMATORY STATUS THAT HAS BEEN DESIGNATED "INFLAMMAGING". BOTH PHENOMENA ARE ACCELERATED AND EXACERBATED IN PATIENTS WITH THE MOST COMMON AGE-RELATED DISEASES (ARDS), INCLUDING CANCER. THE FINDING THAT CHRONIC CELL STRESS ACTIVATES A PRO-INFLAMMATORY PROGRAM LEADING TO ACQUISITION OF THE SENESCENCE-ASSOCIATED SECRETORY PHENOTYPE (SASP) AND TO THE PROPAGATION OF SENESCENCE TO SURROUNDING CELLS THROUGH THE SECRETOME, SUGGESTS THAT CELL SENESCENCE MAY HAVE A ROLE IN BOTH PROCESSES. HERE WE: I) DESCRIBE THE ROLE OF CELL SENESCENCE IN ENDOTHELIAL DYSFUNCTION, II) EMPHASIZE THE CONTRIBUTION OF THE ENDOTHELIAL CELL SASP TO INFLAMMAGING, AND III) SUGGEST THAT SELECTIVE REMOVAL OF SENESCENT ENDOTHELIAL CELLS MAY NOT ONLY HINDER SUCH HARMFUL PROCESSES, BUT ALSO REDUCE THE RISK OF DEVELOPING ARDS AND THEIR COMPLICATIONS. ALTHOUGH IN VIVO DETECTION AND TARGETING OF SENESCENT ENDOTHELIAL CELLS ARE STILL BEING INVESTIGATED, IT IS LIKELY THAT THERAPEUTIC STRATEGIES BASED ON ANTIOXIDANT AND ANTI-INFLAMMATORY COMPOUNDS WOULD INVOLVE GENERALIZED ANTI-AGING EFFECTS ALSO BENEFITING ENDOTHELIAL CELLS. MICRORNA (MIRNAS) - SINGLE-STRANDED, NON-CODING RNAS EXPRESSED BY ALL LIVING CELLS AND INVOLVED IN THE EPIGENETIC MODULATION OF ALL TRANSCRIPTIONAL PROGRAMS - MAY CONSTITUTE AN INNOVATIVE, VALUABLE TOOL TO DETECT AND TARGET SENESCENT ENDOTHELIAL CELLS AND TO DEVISE TREATMENTS THAT CAN SLOW DOWN THE PRO-INFLAMMATORY PROGRAM ACTIVATED IN SENESCENT ENDOTHELIAL CELLS. 2016 9 1864 35 EMERGING AVENUES LINKING INFLAMMATION AND CANCER. THE ROLE OF INFLAMMATION IN CARCINOGENESIS HAS BEEN EXTENSIVELY INVESTIGATED AND WELL DOCUMENTED. MANY BIOCHEMICAL PROCESSES THAT ARE ALTERED DURING CHRONIC INFLAMMATION HAVE BEEN IMPLICATED IN TUMORIGENESIS. THESE INCLUDE SHIFTING CELLULAR REDOX BALANCE TOWARD OXIDATIVE STRESS; INDUCTION OF GENOMIC INSTABILITY; INCREASED DNA DAMAGE; STIMULATION OF CELL PROLIFERATION, METASTASIS, AND ANGIOGENESIS; DEREGULATION OF CELLULAR EPIGENETIC CONTROL OF GENE EXPRESSION; AND INAPPROPRIATE EPITHELIAL-TO-MESENCHYMAL TRANSITION. A WIDE ARRAY OF PROINFLAMMATORY CYTOKINES, PROSTAGLANDINS, NITRIC OXIDE, AND MATRICELLULAR PROTEINS ARE CLOSELY INVOLVED IN PREMALIGNANT AND MALIGNANT CONVERSION OF CELLS IN A BACKGROUND OF CHRONIC INFLAMMATION. INAPPROPRIATE TRANSCRIPTION OF GENES ENCODING INFLAMMATORY MEDIATORS, SURVIVAL FACTORS, AND ANGIOGENIC AND METASTATIC PROTEINS IS THE KEY MOLECULAR EVENT IN LINKING INFLAMMATION AND CANCER. ABERRANT CELL SIGNALING PATHWAYS COMPRISING VARIOUS KINASES AND THEIR DOWNSTREAM TRANSCRIPTION FACTORS HAVE BEEN IDENTIFIED AS THE MAJOR CONTRIBUTORS IN ABNORMAL GENE EXPRESSION ASSOCIATED WITH INFLAMMATION-DRIVEN CARCINOGENESIS. THE POSTTRANSCRIPTIONAL REGULATION OF GENE EXPRESSION BY MICRORNAS ALSO PROVIDES THE MOLECULAR BASIS FOR LINKING INFLAMMATION TO CANCER. THIS REVIEW HIGHLIGHTS THE MULTIFACETED ROLE OF INFLAMMATION IN CARCINOGENESIS IN THE CONTEXT OF ALTERED CELLULAR REDOX SIGNALING. 2012 10 5432 23 REJUVENATION OF MESENCHYMAL STEM CELLS TO AMELIORATE SKELETAL AGING. ADVANCED AGE IS A SHARED RISK FACTOR FOR MANY CHRONIC AND DEBILITATING SKELETAL DISEASES INCLUDING OSTEOPOROSIS AND PERIODONTITIS. MESENCHYMAL STEM CELLS DEVELOP VARIOUS AGING PHENOTYPES INCLUDING THE ONSET OF SENESCENCE, INTRINSIC LOSS OF REGENERATIVE POTENTIAL AND EXACERBATION OF INFLAMMATORY MICROENVIRONMENT VIA SECRETORY FACTORS. THIS REVIEW ELABORATES ON THE EMERGING CONCEPTS ON THE MOLECULAR AND EPIGENETIC MECHANISMS OF MSC SENESCENCE, SUCH AS THE ACCUMULATION OF OXIDATIVE STRESS, DNA DAMAGE AND MITOCHONDRIAL DYSFUNCTION. SENESCENT MSCS AGGRAVATE LOCAL INFLAMMATION, DISRUPT BONE REMODELING AND BONE-FAT BALANCE, THEREBY CONTRIBUTING TO THE PROGRESSION OF AGE-RELATED BONE DISEASES. VARIOUS REJUVENATION STRATEGIES TO TARGET SENESCENT MSCS COULD PRESENT A PROMISING PARADIGM TO RESTORE SKELETAL AGING. 2023 11 4384 25 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 12 4377 27 MITOCHONDRIAL AGING: FOCUS ON MITOCHONDRIAL DNA DAMAGE IN ATHEROSCLEROSIS - A MINI-REVIEW. ATHEROSCLEROSIS IS A COMPLEX DISEASE WHICH CAN BE DESCRIBED AS AN EXCESSIVE FIBROFATTY, PROLIFERATIVE, INFLAMMATORY RESPONSE TO DAMAGE TO THE ARTERY WALL INVOLVING SEVERAL CELL TYPES SUCH AS SMOOTH MUSCLE CELLS, MONOCYTE-DERIVED MACROPHAGES, LYMPHOCYTES, DENDRITIC CELLS AND PLATELETS. ON THE OTHER HAND, ATHEROSCLEROSIS IS A TYPICAL AGE-RELATED DEGENERATIVE PATHOLOGY, WHICH IS CHARACTERIZED BY SIGNS OF CELL SENESCENCE IN THE ARTERIAL WALL INCLUDING REDUCED CELL PROLIFERATION, IRREVERSIBLE GROWTH ARREST AND APOPTOSIS, INCREASED DNA DAMAGE, THE PRESENCE OF EPIGENETIC MODIFICATIONS, SHORTENING OF TELOMERE LENGTH AND MITOCHONDRIAL DYSFUNCTION. THE MOST PROMINENT CHARACTERISTICS OF MITOCHONDRIAL AGING ARE THEIR STRUCTURAL ALTERATIONS AND MITOCHONDRIAL DNA DAMAGE. THE MECHANISMS OF MITOCHONDRIAL GENOME DAMAGE IN THE DEVELOPMENT OF CHRONIC AGE-RELATED DISEASES SUCH AS ATHEROSCLEROSIS ARE NOT YET WELL UNDERSTOOD. THIS REVIEW FOCUSES ON THE LATEST FINDINGS FROM STUDIES OF THOSE MUTATIONS OF THE MITOCHONDRIAL GENOME WHICH MAY PLAY AN IMPORTANT ROLE IN THE DEVELOPMENT OF ATHEROSCLEROSIS AND WHICH ARE, AT THE SAME TIME, ALSO MARKERS OF MITOCHONDRIAL AGING AND CELL SENESCENCE. 2015 13 3245 21 HEPATIC STELLATE CELLS AS KEY TARGET IN LIVER FIBROSIS. PROGRESSIVE LIVER FIBROSIS, INDUCED BY CHRONIC VIRAL AND METABOLIC DISORDERS, LEADS TO MORE THAN ONE MILLION DEATHS ANNUALLY VIA DEVELOPMENT OF CIRRHOSIS, ALTHOUGH NO ANTIFIBROTIC THERAPY HAS BEEN APPROVED TO DATE. TRANSDIFFERENTIATION (OR "ACTIVATION") OF HEPATIC STELLATE CELLS IS THE MAJOR CELLULAR SOURCE OF MATRIX PROTEIN-SECRETING MYOFIBROBLASTS, THE MAJOR DRIVER OF LIVER FIBROGENESIS. PARACRINE SIGNALS FROM INJURED EPITHELIAL CELLS, FIBROTIC TISSUE MICROENVIRONMENT, IMMUNE AND SYSTEMIC METABOLIC DYSREGULATION, ENTERIC DYSBIOSIS, AND HEPATITIS VIRAL PRODUCTS CAN DIRECTLY OR INDIRECTLY INDUCE STELLATE CELL ACTIVATION. DYSREGULATED INTRACELLULAR SIGNALING, EPIGENETIC CHANGES, AND CELLULAR STRESS RESPONSE REPRESENT CANDIDATE TARGETS TO DEACTIVATE STELLATE CELLS BY INDUCING REVERSION TO INACTIVATED STATE, CELLULAR SENESCENCE, APOPTOSIS, AND/OR CLEARANCE BY IMMUNE CELLS. CELL TYPE- AND TARGET-SPECIFIC PHARMACOLOGICAL INTERVENTION TO THERAPEUTICALLY INDUCE THE DEACTIVATION WILL ENABLE MORE EFFECTIVE AND LESS TOXIC PRECISION ANTIFIBROTIC THERAPIES. 2017 14 4037 23 MACROPHAGE IMMUNOMETABOLISM AND INFLAMMAGING: ROLES OF MITOCHONDRIAL DYSFUNCTION, CELLULAR SENESCENCE, CD38, AND NAD. AGING IS A COMPLEX PROCESS THAT INVOLVES DYSFUNCTION ON MULTIPLE LEVELS, ALL OF WHICH SEEM TO CONVERGE ON INFLAMMATION. MACROPHAGES ARE INTIMATELY INVOLVED IN INITIATING AND RESOLVING INFLAMMATION, AND THEIR DYSREGULATION WITH AGE IS A PRIMARY CONTRIBUTOR TO INFLAMMAGING-A STATE OF CHRONIC, LOW-GRADE INFLAMMATION THAT DEVELOPS DURING AGING. AMONG THE AGE-RELATED CHANGES THAT OCCUR TO MACROPHAGES ARE A HEIGHTENED STATE OF BASAL INFLAMMATION AND DIMINISHED OR HYPERACTIVE INFLAMMATORY RESPONSES, WHICH SEEM TO BE DRIVEN BY METABOLIC-DEPENDENT EPIGENETIC CHANGES. IN THIS REVIEW ARTICLE WE PROVIDE A BRIEF OVERVIEW OF MITOCHONDRIAL FUNCTIONS AND AGE-RELATED CHANGES THAT OCCUR TO MACROPHAGES, WITH AN EMPHASIS ON HOW THE INFLAMMAGING ENVIRONMENT, SENESCENCE, AND NAD DECLINE CAN AFFECT THEIR METABOLISM, PROMOTE DYSREGULATION, AND CONTRIBUTE TO INFLAMMAGING AND AGE-RELATED PATHOLOGIES. 2020 15 799 27 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 4380 25 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 17 6621 30 UNDERSTANDING FIBROSIS IN SYSTEMIC SCLEROSIS: SHIFTING PARADIGMS, EMERGING OPPORTUNITIES. FIBROSIS IN MULTIPLE ORGANS IS A PROMINENT PATHOLOGICAL FINDING AND DISTINGUISHING HALLMARK OF SYSTEMIC SCLEROSIS (SSC). FINDINGS DURING THE PAST 5 YEARS HAVE CONTRIBUTED TO A MORE COMPLETE UNDERSTANDING OF THE COMPLEX CELLULAR AND MOLECULAR UNDERPINNING OF FIBROSIS IN SSC. FIBROBLASTS, THE PRINCIPAL EFFECTOR CELLS, ARE ACTIVATED IN THE PROFIBROTIC CELLULAR MILIEU BY CYTOKINES AND GROWTH FACTORS, DEVELOPMENTAL PATHWAYS, ENDOTHELIN 1 AND THROMBIN. INNATE IMMUNE SIGNALING VIA TOLL-LIKE RECEPTORS, MATRIX-GENERATED BIOMECHANICAL STRESS SIGNALING VIA INTEGRINS, HYPOXIA AND OXIDATIVE STRESS SEEM TO BE IMPLICATED IN PERPETUATING THE PROCESS. BEYOND CHRONIC FIBROBLAST ACTIVATION, FIBROSIS REPRESENTS A FAILURE TO TERMINATE TISSUE REPAIR, COUPLED WITH AN EXPANDED POPULATION OF MESENCHYMAL CELLS ORIGINATING FROM BONE MARROW AND TRANSDIFFERENTIATION OF EPITHELIAL CELLS, ENDOTHELIAL CELLS AND PERICYTES. IN ADDITION, STUDIES HAVE IDENTIFIED INTRINSIC ALTERATIONS IN SSC FIBROBLASTS RESULTING FROM EPIGENETIC CHANGES, AS WELL AS ALTERED MICRORNA EXPRESSION THAT MIGHT UNDERLIE THE CELL-AUTONOMOUS, PERSISTENT ACTIVATION PHENOTYPE OF THESE CELLS. PRECISE CHARACTERIZATION OF THE DEREGULATED EXTRACELLULAR AND INTRACELLULAR SIGNALING PATHWAYS, MEDIATORS AND CELLULAR DIFFERENTIATION PROGRAMS THAT CONTRIBUTE TO FIBROSIS IN SSC WILL FACILITATE THE DEVELOPMENT OF SELECTIVE, TARGETED THERAPEUTIC STRATEGIES. EFFECTIVE ANTIFIBROTIC THERAPY WILL ULTIMATELY INVOLVE NOVEL COMPOUNDS AND REPURPOSING OF DRUGS THAT ARE ALREADY APPROVED FOR OTHER INDICATIONS. 2011 18 2851 31 FROM CIRRHOSIS TO HEPATOCELLULAR CARCINOMA: NEW MOLECULAR INSIGHTS ON INFLAMMATION AND CELLULAR SENESCENCE. SEQUENTIAL PROGRESSION FROM CHRONIC LIVER DISEASE TO FIBROSIS AND TO CIRRHOSIS CULMINATES IN NEOPLASIA IN HEPATOCELLULAR CARCINOMA (HCC). THE PRENEOPLASTIC SETTING OF THE CIRRHOTIC BACKGROUND PROVIDES A CONDUCIVE ENVIRONMENT FOR CELLULAR TRANSFORMATION. THE ROLE OF CLASSICAL INFLAMMATION IN CIRRHOSIS IS WIDELY KNOWN, BUT THE EXACT MECHANISM LINKING INFLAMMATION AND CANCER REMAINS ELUSIVE. RECENT STUDIES HAVE ELUCIDATED ROLES FOR NF-KAPPAB, STAT3 AND JNK AS POSSIBLE MISSING LINKS. IN ADDITION, THE "INFLAMMASOME" (A MULTIPROTEIN COMPLEX AND SENSOR OF CELLULAR DAMAGE) IS A RECENTLY IDENTIFIED PLAYER IN THIS FIELD. THE HALLMARKS OF CIRRHOSIS INCLUDE NECROINFLAMMATION, DEPOSITION OF EXTRACELLULAR MATRIX AND SHORTENING OF TELOMERES, LEADING TO SENESCENCE AND REGENERATION. ADDITIONALLY, THE ACCUMULATION OF GENETIC/EPIGENETIC CHANGES PROPELS ATYPICAL CELLS TOWARD A MALIGNANT PHENOTYPE. THIS REVIEW PROVIDES RECENT INFORMATION ON THE CLASSICAL INFLAMMATORY PATHWAY, TOGETHER WITH A SPOTLIGHT ON INFLAMMASOMES AND THE IMMUNOMODULATORY ROLE OF CELLULAR SENESCENCE DURING THE PROGRESSION FROM CIRRHOSIS TO HCC. MOREOVER, LACUNAE IN THE CURRENT KNOWLEDGE WERE IDENTIFIED AND KEY QUESTIONS RAISED ON WHETHER THE OBSERVED ADAPTIVE RESPONSES ARE BENEFICIAL OR DETRIMENTAL TO TISSUE HOMEOSTASIS IN A COMPLEX ORGAN LIKE LIVER. 2013 19 5816 30 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 20 797 31 CELLULAR SENESCENCE IN OSTEOARTHRITIS PATHOLOGY. CELLULAR SENESCENCE IS A STATE OF STABLE PROLIFERATION ARREST OF CELLS. THE SENESCENCE PATHWAY HAS MANY BENEFICIAL EFFECTS AND IS SEEN TO BE ACTIVATED IN DAMAGED/STRESSED CELLS, AS WELL AS DURING EMBRYONIC DEVELOPMENT AND WOUND HEALING. HOWEVER, THE PERSISTENCE AND ACCUMULATION OF SENESCENT CELLS IN VARIOUS TISSUES CAN ALSO IMPAIR FUNCTION AND HAVE BEEN IMPLICATED IN THE PATHOGENESIS OF MANY AGE-RELATED DISEASES. OSTEOARTHRITIS (OA), A SEVERELY DEBILITATING CHRONIC CONDITION CHARACTERIZED BY PROGRESSIVE TISSUE REMODELING AND LOSS OF JOINT FUNCTION, IS THE MOST PREVALENT DISEASE OF THE SYNOVIAL JOINTS, AND INCREASING AGE IS THE PRIMARY OA RISK FACTOR. THE PROFILE OF INFLAMMATORY AND CATABOLIC MEDIATORS PRESENT DURING THE PATHOGENESIS OF OA IS STRIKINGLY SIMILAR TO THE SECRETORY PROFILE OBSERVED IN 'CLASSICAL' SENESCENT CELLS. DURING OA, CHONDROCYTES (THE SOLE CELL TYPE PRESENT WITHIN ARTICULAR CARTILAGE) EXHIBIT INCREASED LEVELS OF VARIOUS SENESCENCE MARKERS, SUCH AS SENESCENCE-ASSOCIATED BETA-GALACTOSIDASE (SABETAGAL) ACTIVITY, TELOMERE ATTRITION, AND ACCUMULATION OF P16INK4A. THIS SUGGESTS THE HYPOTHESIS THAT SENESCENCE OF CELLS WITHIN JOINT TISSUES MAY PLAY A PATHOLOGICAL ROLE IN THE CAUSATION OF OA. IN THIS REVIEW, WE DISCUSS THE MECHANISMS BY WHICH SENESCENT CELLS MAY PREDISPOSE SYNOVIAL JOINTS TO THE DEVELOPMENT AND/OR PROGRESSION OF OA, AS WELL AS TOUCHING UPON VARIOUS EPIGENETIC ALTERATIONS ASSOCIATED WITH BOTH OA AND SENESCENCE. 2017