1 6904 83 [THE ROLE OF ALUMINUM AND LEAD IN THE DEVELOPMENT OF ALZHEIMER'S AND PARKINSON'S DISEASES]. THE ARTICLE SUMMARIZES THE DATA AVAILABLE IN THE LITERATURE ON THE TOXIC EFFECTS OF ALUMINUM AND LEAD ON THE HUMAN BRAIN AND ASSESSES THE RELATIONSHIP OF THESE EFFECTS TO THE ETIOPATHOGENESIS OF THE MOST COMMON NEURODEGENERATIVE DISEASES, SUCH AS ALZHEIMER'S AND PARKINSON'S DISEASES. THE ACCUMULATION OF IONS OF THESE METALS IN THE BRAIN STRUCTURES LEADS TO CHRONIC INTOXICATION THAT IS MANIFESTED BY THE MORPHOLOGICAL SIGNS THAT ARE TYPICAL FOR ALZHEIMER'S DISEASE, SUCH AS DEPOSITS OF BETA-AMYLOID AND TAU-PROTEIN MAINLY IN THE FRONTAL AND TEMPORAL REGIONS OF THE CORTEX, AND FOR PARKINSON'S DISEASE, SUCH AS DEGENERATION OF DOPAMINE NEURONS IN THE SUBSTANTIA NIGRA AND THEIR ACCUMULATION OF ALPHA-SYNUCLEIN. THE MOST LIKELY FORMS OF PARTICIPATION OF ALUMINUM AND LEAD IONS IN THE MECHANISMS OF NEURODEGENERATION ARE THE REPLACEMENT OF BIVALENT METAL IONS NECESSARY FOR BRAIN FUNCTIONING, OXIDATIVE STRESS INITIATION, EPIGENETIC MODIFICATIONS OF HISTONES, AND INCREASED EXPRESSION OF NONCODING RIBONUCLEIC ACIDS. 2021 2 330 27 ALPHA-SYNUCLEIN AND MECHANISMS OF EPIGENETIC REGULATION. SYNUCLEINOPATHIES ARE A GROUP OF NEURODEGENERATIVE DISEASES WITH COMMON PATHOLOGICAL LESIONS ASSOCIATED WITH THE EXCESSIVE ACCUMULATION AND ABNORMAL INTRACELLULAR DEPOSITION OF TOXIC SPECIES OF ALPHA-SYNUCLEIN. THE SHARED CLINICAL FEATURES ARE CHRONIC PROGRESSIVE DECLINE OF MOTOR, COGNITIVE, AND BEHAVIORAL FUNCTIONS. THESE DISORDERS INCLUDE PARKINSON'S DISEASE, DEMENTIA WITH LEWY BODY, AND MULTIPLE SYSTEM ATROPHY. VIGOROUS RESEARCH IN THE MECHANISMS OF PATHOLOGY OF THESE ILLNESSES IS CURRENTLY UNDER WAY TO FIND DISEASE-MODIFYING TREATMENT AND MOLECULAR MARKERS FOR EARLY DIAGNOSIS. ALPHA-SYNUCLEIN IS A PRONE-TO-AGGREGATE, SMALL AMYLOIDOGENIC PROTEIN WITH MULTIPLE ROLES IN SYNAPTIC VESICLE TRAFFICKING, NEUROTRANSMITTER RELEASE, AND INTRACELLULAR SIGNALING EVENTS. ITS EXPRESSION IS CONTROLLED BY SEVERAL MECHANISMS, ONE OF WHICH IS EPIGENETIC REGULATION. WHEN TRANSMITTED TO THE NUCLEUS, ALPHA-SYNUCLEIN BINDS TO DNA AND HISTONES AND PARTICIPATES IN EPIGENETIC REGULATORY FUNCTIONS CONTROLLING SPECIFIC GENE TRANSCRIPTION. HERE, WE DISCUSS THE VARIOUS ASPECTS OF ALPHA-SYNUCLEIN INVOLVEMENT IN EPIGENETIC REGULATION IN HEALTH AND DISEASES. 2023 3 1199 24 CORTICOTROPIN RELEASING FACTOR-BINDING PROTEIN (CRF-BP) AS A POTENTIAL NEW THERAPEUTIC TARGET IN ALZHEIMER'S DISEASE AND STRESS DISORDERS. ALZHEIMER'S DISEASE IS THE MOST COMMON CAUSE OF DEMENTIA AND ONE OF THE MOST COMPLEX HUMAN NEURODEGENERATIVE DISEASES. NUMEROUS STUDIES HAVE DEMONSTRATED A CRITICAL ROLE OF THE ENVIRONMENT IN THE PATHOGENESIS AND PATHOPHYSIOLOGY OF THE DISEASE, WHERE DAILY LIFE STRESS PLAYS AN IMPORTANT ROLE. A LOT OF EPIGENETIC STUDIES HAVE LED TO THE CONCLUSION THAT CHRONIC STRESS AND STRESS-RELATED DISORDERS PLAY AN IMPORTANT PART IN THE ONSET OF NEURODEGENERATIVE DISORDERS, AND AN ENORMOUS AMOUNT OF RESEARCH YIELDED VALUABLE DISCOVERIES BUT HAS SO FAR NOT LED TO THE DEVELOPMENT OF EFFECTIVE TREATMENT STRATEGIES FOR ALZHEIMER'S DISEASE. CORTICOTROPIN-RELEASING FACTOR (CRF) IS ONE OF THE MAJOR HORMONES AND AT THE SAME TIME A NEUROPEPTIDE ACTING IN STRESS RESPONSE. DEREGULATION OF PROTEIN LEVELS OF CRF IS INVOLVED IN THE PATHOGENESIS OF ALZHEIMER'S DISEASE, BUT LITTLE IS KNOWN ABOUT THE PRECISE ROLES OF CRF AND ITS BINDING PROTEIN, CRF-BP, IN NEURODEGENERATIVE DISEASES. IN THIS REVIEW, WE SUMMARIZE THE KEY EVIDENCE FOR AND AGAINST THE INVOLVEMENT OF STRESS-ASSOCIATED MODULATION OF THE CRF SYSTEM IN THE PATHOGENESIS OF ALZHEIMER'S DISEASE AND DISCUSS HOW RECENT FINDINGS COULD LEAD TO NEW POTENTIAL TREATMENT POSSIBILITIES IN ALZHEIMER'S DISEASE BY USING CRF-BP AS A THERAPEUTIC TARGET. 2019 4 6324 27 THE ROLE OF ALPHA-SYNUCLEIN IN THE PATHOPHYSIOLOGY OF ALCOHOLISM. ALCOHOLISM HAS COMPLEX ETIOLOGY AND THERE IS EVIDENCE FOR BOTH GENETIC AND ENVIRONMENTAL FACTORS IN ITS PATHOPHYSIOLOGY. CHRONIC, LONG-TERM ALCOHOL ABUSE AND ALCOHOL DEPENDENCE ARE ASSOCIATED WITH NEURONAL LOSS WITH THE PREFRONTAL CORTEX BEING PARTICULARLY SUSCEPTIBLE TO NEUROTOXIC DAMAGE. THIS BRAIN REGION IS INVOLVED IN THE DEVELOPMENT AND PERSISTENCE OF ALCOHOL ADDICTION AND NEUROTOXIC DAMAGE IS LIKELY TO EXACERBATE THE REINFORCING EFFECTS OF ALCOHOL AND MAY HINDER TREATMENT. UNDERSTANDING THE MECHANISM OF ALCOHOL'S NEUROTOXIC EFFECTS ON THE BRAIN AND THE GENETIC RISK FACTORS ASSOCIATED WITH ALCOHOL ABUSE ARE THE FOCUS OF CURRENT RESEARCH. BECAUSE OF ITS WELL-ESTABLISHED ROLE IN NEURODEGENERATIVE AND NEUROPSYCHOLOGICAL DISORDERS, AND ITS EMERGING ROLE IN THE PATHOPHYSIOLOGY OF ADDICTION, HERE WE REVIEW THE GENETIC AND EPIGENETIC FACTORS INVOLVED IN REGULATING ALPHA-SYNUCLEIN EXPRESSION AND ITS POTENTIAL ROLE IN THE PATHOPHYSIOLOGY OF CHRONIC ALCOHOL ABUSE. ELUCIDATION OF THE MECHANISMS OF ALPHA-SYNUCLEIN REGULATION MAY PROVE BENEFICIAL IN UNDERSTANDING THE ROLE OF THIS KEY SYNAPTIC PROTEIN IN DISEASE AND ITS POTENTIAL FOR THERAPEUTIC MODULATION IN THE TREATMENT OF SUBSTANCE USE DISORDERS AS WELL AS OTHER NEURODEGENERATIVE DISEASES. 2013 5 2010 25 EPIGENETIC BASIS OF LEAD-INDUCED NEUROLOGICAL DISORDERS. ENVIRONMENTAL LEAD (PB) EXPOSURE IS CLOSELY ASSOCIATED WITH PATHOGENESIS OF A RANGE OF NEUROLOGICAL DISORDERS, INCLUDING ALZHEIMER'S DISEASE (AD), PARKINSON'S DISEASE (PD), AMYOTROPHIC LATERAL SCLEROSIS (ALS), ATTENTION DEFICIT/HYPERACTIVITY DISORDER (ADHD), ETC. EPIGENETIC MACHINERY MODULATES NEURAL DEVELOPMENT AND ACTIVITIES, WHILE FAULTY EPIGENETIC REGULATION CONTRIBUTES TO THE DIVERSE FORMS OF CNS (CENTRAL NERVOUS SYSTEM) ABNORMALITIES AND DISEASES. AS A POTENT EPIGENETIC MODIFIER, LEAD IS THOUGHT TO CAUSE NEUROLOGICAL DISORDERS THROUGH MODULATING EPIGENETIC MECHANISMS. SPECIFICALLY, INCREASING EVIDENCE LINKED ABERRANT DNA METHYLATIONS, HISTONE MODIFICATIONS AS WELL AS NCRNAS (NON-CODING RNAS) WITH AD CASES, AMONG WHICH CIRCRNA (CIRCULAR RNA) STANDS OUT AS A NEW AND PROMISING FIELD FOR ASSOCIATION STUDIES. IN 23-YEAR-OLD PRIMATES WITH DEVELOPMENTAL LEAD TREATMENT, ZAWIA GROUP DISCOVERED A VARIETY OF EPIGENETIC CHANGES RELATING TO AD PATHOGENESIS. THIS IS A DIRECT EVIDENCE IMPLICATING EPIGENETIC BASIS IN LEAD-INDUCED AD ANIMALS WITH AN ENTIRE LIFESPAN. ADDITIONALLY, SOME EPIGENETIC MOLECULES ASSOCIATED WITH AD ETIOLOGY WERE ALSO KNOWN TO RESPOND TO CHRONIC LEAD EXPOSURE IN COMPARABLE DISEASE MODELS, INDICATING POTENTIALLY INTERLACED MECHANISMS WITH RESPECT TO THE STUDIED NEUROTOXIC AND PATHOLOGICAL EVENTS. OF NOTE, EPIGENETIC MOLECULES ACTED VIA GLOBALLY OR SELECTIVELY INFLUENCING THE EXPRESSION OF DISEASE-RELATED GENES. COMPARED TO AD, THE ASSOCIATION OF LEAD EXPOSURE WITH OTHER NEUROLOGICAL DISORDERS WERE PRIMARILY SUPPORTED BY EPIDEMIOLOGICAL SURVEY, WITH FEWER REPORTS CONNECTING EPIGENETIC REGULATORS WITH LEAD-INDUCED PATHOGENESIS. SOME PHARMACEUTICALS, SUCH AS HDAC (HISTONE DEACETYLASE) INHIBITORS AND DNA METHYLATION INHIBITORS, WERE DEVELOPED TO DEAL WITH CNS DISEASE BY TARGETING EPIGENETIC COMPONENTS. STILL, UNDERSTANDINGS ARE INSUFFICIENT REGARDING THE CAUSE-CONSEQUENCE RELATIONS OF EPIGENETIC FACTORS AND NEUROLOGICAL ILLNESS. THEREFORE, CLEAR EVIDENCE SHOULD BE PROVIDED IN FUTURE INVESTIGATIONS TO ADDRESS DETAILED ROLES OF NOVEL EPIGENETIC FACTORS IN LEAD-INDUCED NEUROLOGICAL DISORDERS, AND EFFORTS OF DEVELOPING SPECIFIC EPIGENETIC THERAPEUTICS SHOULD BE APPRAISED. 2020 6 4635 31 NEUROINFLAMMATORY MECHANISMS IN PARKINSON'S DISEASE: POTENTIAL ENVIRONMENTAL TRIGGERS, PATHWAYS, AND TARGETS FOR EARLY THERAPEUTIC INTERVENTION. MOST ACUTE AND CHRONIC NEURODEGENERATIVE CONDITIONS ARE ACCOMPANIED BY NEUROINFLAMMATION; YET THE EXACT NATURE OF THE INFLAMMATORY PROCESSES AND WHETHER THEY MODIFY DISEASE PROGRESSION IS NOT WELL UNDERSTOOD. IN THIS REVIEW, WE DISCUSS THE KEY EPIDEMIOLOGICAL, CLINICAL, AND EXPERIMENTAL EVIDENCE IMPLICATING INFLAMMATORY PROCESSES IN THE PROGRESSIVE DEGENERATION OF THE DOPAMINERGIC (DA) NIGROSTRIATAL PATHWAY AND THEIR POTENTIAL CONTRIBUTION TO THE PATHOPHYSIOLOGY OF PARKINSON'S DISEASE (PD). GIVEN THAT INTERPLAY BETWEEN GENETICS AND ENVIRONMENT ARE LIKELY TO CONTRIBUTE TO RISK FOR DEVELOPMENT OF IDIOPATHIC PD, RECENT DATA SHOWING INTERACTIONS BETWEEN PRODUCTS OF GENES LINKED TO HERITABLE PD THAT FUNCTION TO PROTECT DA NEURONS AGAINST OXIDATIVE OR PROTEOLYTIC STRESS AND INFLAMMATION PATHWAYS WILL BE DISCUSSED. CELLULAR MECHANISMS ACTIVATED OR ENHANCED BY INFLAMMATORY PROCESSES THAT MAY CONTRIBUTE TO MITOCHONDRIAL DYSFUNCTION, OXIDATIVE STRESS, OR APOPTOSIS OF DOPAMINERGIC (DA) NEURONS WILL BE REVIEWED, WITH SPECIAL EMPHASIS ON TUMOR NECROSIS FACTOR (TNF) AND INTERLEUKIN-1-BETA (IL-1BETA) SIGNALING PATHWAYS. EPIGENETIC FACTORS WHICH HAVE THE POTENTIAL TO TRIGGER NEUROINFLAMMATION, INCLUDING ENVIRONMENTAL EXPOSURES AND AGE-ASSOCIATED CHRONIC INFLAMMATORY CONDITIONS, WILL BE DISCUSSED AS POSSIBLE 'SECOND-HIT' TRIGGERS THAT MAY AFFECT DISEASE ONSET OR PROGRESSION OF IDIOPATHIC PD. IF INFLAMMATORY PROCESSES HAVE AN ACTIVE ROLE IN NIGROSTRIATAL PATHWAY DEGENERATION, THEN EVIDENCE SHOULD EXIST TO INDICATE THAT SUCH PROCESSES BEGIN IN THE EARLY STAGES OF DISEASE AND THAT THEY CONTRIBUTE TO NEURONAL DYSFUNCTION AND/OR HASTEN NEURODEGENERATION OF THE NIGROSTRIATAL PATHWAY. THERAPEUTICALLY, IF ANTI-INFLAMMATORY INTERVENTIONS CAN BE SHOWN TO RESCUE NIGRAL DA NEURONS FROM DEGENERATION AND LOWER PD RISK, THEN TIMELY USE OF ANTI-INFLAMMATORY THERAPIES SHOULD BE INVESTIGATED FURTHER IN WELL-DESIGNED CLINICAL TRIALS FOR THEIR ABILITY TO PREVENT OR DELAY THE PROGRESSIVE LOSS OF NIGRAL DA NEURONS IN GENETICALLY SUSCEPTIBLE POPULATIONS. 2007 7 2235 21 EPIGENETIC MODIFICATIONS, ALCOHOLIC BRAIN AND POTENTIAL DRUG TARGETS. ACUTE AND CHRONIC ALCOHOL EXPOSURE EVIDENTLY INFLUENCES EPIGENETIC CHANGES, BOTH TRANSIENTLY AND PERMANENTLY, AND THESE CHANGES IN TURN INFLUENCE A VARIETY OF CELLS AND ORGAN SYSTEMS THROUGHOUT THE BODY. MANY OF THE ALCOHOL-INDUCED EPIGENETIC MODIFICATIONS CAN CONTRIBUTE TO CELLULAR ADAPTATIONS THAT ULTIMATELY LEAD TO BEHAVIORAL TOLERANCE AND ALCOHOL DEPENDENCE. THE PERSISTENCE OF BEHAVIORAL CHANGES DEMONSTRATES THAT LONG-LASTING CHANGES IN GENE EXPRESSION, WITHIN PARTICULAR REGIONS OF THE BRAIN, MAY CONTRIBUTE IMPORTANTLY TO THE ADDICTION PHENOTYPE. THE RESEARCH ACTIVITIES OVER THE PAST YEARS HAVE DEMONSTRATED A CRUCIAL ROLE OF EPIGENETIC MECHANISMS IN CAUSING LONG LASTING AND TRANSIENT CHANGES IN THE EXPRESSION OF SEVERAL GENES IN DIVERSE TISSUES, INCLUDING BRAIN. THIS HAS STIMULATED RECENT RESEARCH WORK THAT IS AIMED AT CHARACTERIZING THE INFLUENCE OF EPIGENETIC REGULATORY EVENTS IN MEDIATING THE LONG LASTING AND TRANSIENT EFFECTS OF ALCOHOL ABUSE ON THE BRAIN IN HUMANS AND ANIMAL MODELS OF ALCOHOL ADDICTION. IN THIS STUDY, WE UPDATE OUR CURRENT UNDERSTANDING OF THE IMPACT OF ALCOHOL EXPOSURE ON EPIGENETIC MECHANISMS IN THE BRAIN AND REFURBISH THE KNOWLEDGE OF EPIGENETICS IN THE DIRECTION OF NEW DRUGS DEVELOPMENT. 2016 8 2227 23 EPIGENETIC MODIFICATIONS OF CHRONIC HYPOXIA-MEDIATED NEURODEGENERATION IN ALZHEIMER'S DISEASE. ALZHEIMER'S DISEASE (AD) IS THE MOST COMMON NEURODEGENERATIVE DISORDER AFFECTING THE ELDERLY PEOPLE. AD IS CHARACTERIZED BY PROGRESSIVE AND GRADUAL DECLINE IN COGNITIVE FUNCTION AND MEMORY LOSS. WHILE FAMILIAL EARLY-ONSET AD IS USUALLY ASSOCIATED WITH GENE MUTATIONS, THE ETIOLOGY OF SPORADIC LATE-ONSET FORM OF AD IS LARGELY UNKNOWN. IT HAS BEEN REPORTED THAT ENVIRONMENTAL FACTORS AND EPIGENETIC ALTERATIONS SIGNIFICANTLY CONTRIBUTE TO THE PROCESS OF AD. OUR PREVIOUS STUDIES HAVE DOCUMENTED THAT CHRONIC HYPOXIA IS ONE OF THE ENVIRONMENTAL FACTORS THAT MAY TRIGGER THE AD DEVELOPMENT AND AGGRAVATE THE DISEASE PROGRESSION. IN THIS REVIEW, WE WILL SUMMARIZE THE PATHOLOGICAL EFFECTS OF CHRONIC HYPOXIA ON THE ONSET AND DEVELOPMENT OF AD AND PUT FORWARD THE POSSIBLE MOLECULE MECHANISMS UNDERLYING THE CHRONIC HYPOXIA MEDIATED AD PATHOGENESIS. FINALLY, WE PROPOSE THAT EPIGENETIC REGULATIONS MAY REPRESENT NEW OPPORTUNITY FOR THE THERAPEUTIC INTERVENTION OF THIS DISEASE. 2014 9 2350 26 EPIGENETIC REGULATION OF NEUROINFLAMMATION IN PARKINSON'S DISEASE. NEUROINFLAMMATION IS ONE OF THE MOST SIGNIFICANT FACTORS INVOLVED IN THE INITIATION AND PROGRESSION OF PARKINSON'S DISEASE. PD IS A NEURODEGENERATIVE DISORDER WITH A MOTOR DISABILITY LINKED WITH VARIOUS COMPLEX AND DIVERSIFIED RISK FACTORS. THESE FACTORS TRIGGER MYRIADS OF CELLULAR AND MOLECULAR PROCESSES, SUCH AS MISFOLDING DEFECTIVE PROTEINS, OXIDATIVE STRESS, MITOCHONDRIAL DYSFUNCTION, AND NEUROTOXIC SUBSTANCES THAT INDUCE SELECTIVE NEURODEGENERATION OF DOPAMINE NEURONS. THIS NEURONAL DAMAGE ACTIVATES THE NEURONAL IMMUNE SYSTEM, INCLUDING GLIAL CELLS AND INFLAMMATORY CYTOKINES, TO TRIGGER NEUROINFLAMMATION. THE TRANSITION OF ACUTE TO CHRONIC NEUROINFLAMMATION ENHANCES THE SUSCEPTIBILITY OF INFLAMMATION-INDUCED DOPAMINERGIC NEURON DAMAGE, FORMING A VICIOUS CYCLE AND PROMPTING AN INDIVIDUAL TO PD DEVELOPMENT. EPIGENETIC MECHANISMS RECENTLY HAVE BEEN AT THE FOREFRONT OF THE REGULATION OF NEUROINFLAMMATORY FACTORS IN PD, PROPOSING A NEW DAWN FOR BREAKING THIS VICIOUS CYCLE. THIS REVIEW EXAMINED THE CORE EPIGENETIC MECHANISMS INVOLVED IN THE ACTIVATION AND PHENOTYPIC TRANSFORMATION OF GLIAL CELLS MEDIATED NEUROINFLAMMATION IN PD. WE FOUND THAT EPIGENETIC MECHANISMS DO NOT WORK INDEPENDENTLY, DESPITE BEING COORDINATED WITH EACH OTHER TO ACTIVATE NEUROINFLAMMATORY PATHWAYS. IN THIS REGARD, WE ATTEMPTED TO FIND THE SYNERGIC CORRELATION AND CONTRIBUTION OF THESE EPIGENETIC MODIFICATIONS WITH VARIOUS NEUROINFLAMMATORY PATHWAYS TO BROADEN THE CANVAS OF UNDERLYING PATHOLOGICAL MECHANISMS INVOLVED IN PD DEVELOPMENT. MOREOVER, THIS STUDY HIGHLIGHTED THE DUAL CHARACTERISTICS (NEUROPROTECTIVE/NEUROTOXIC) OF THESE EPIGENETIC MARKS, WHICH MAY COUNTERACT PD PATHOGENESIS AND MAKE THEM POTENTIAL CANDIDATES FOR DEVISING FUTURE PD DIAGNOSIS AND TREATMENT. 2021 10 3123 27 GETTING AN INSIGHT INTO THE COMPLEXITY OF MAJOR CHRONIC INFLAMMATORY AND DEGENERATIVE DISEASES: A POTENTIAL NEW SYSTEMIC APPROACH TO THEIR TREATMENT. AS THE MODERN SOCIETY IS TROUBLED BY MULTI-FACTORIAL DISEASES, RESEARCH HAS BEEN CONDUCTED ON COMPLEX REALITIES INCLUDING CHRONIC INFLAMMATION, CANCER, OBESITY, HIV INFECTION, METABOLIC SYNDROME AND ITS DETRIMENTAL CARDIOVASCULAR COMPLICATIONS AS WELL AS DEPRESSION AND OTHER BRAIN DISORDERS. DETERIORATION OF CRUCIAL HOMEOSTATIC MECHANISMS IN SUCH DISEASES INVARIABLY RESULTS IN ACTIVATION OF INFLAMMATORY MEDIATORS, CHRONIC INFLAMMATION, LOSS IN IMMUNOLOGICAL FUNCTION, INCREASED SUSCEPTIBILITY TO DISEASES, ALTERATION OF METABOLISM, DECREASE OF ENERGY PRODUCTION AND NEURO-COGNITIVE DECLINE. REGULATION OF GENES EXPRESSION BY EPIGENETIC CODE IS THE DOMINANT MECHANISM FOR THE TRANSDUCTION OF ENVIRONMENTAL INPUTS, SUCH AS STRESS AND INFLAMMATION TO LASTING PHYSIOLOGICAL CHANGES. ACUTE AND CHRONIC STRESS DETERMINES DNA METHYLATION AND HISTONE MODIFICATIONS IN BRAIN REGIONS WHICH MAY CONTRIBUTE TO NEURO-DEGENERATIVE DISORDERS. NUCLEAR GLUCOCORTICOIDS RECEPTOR INTERACTS WITH THE EPIGENOMA RESULTING IN A CORTISOL RESISTANCE STATUS ASSOCIATED WITH A DETERIORATION OF THE METABOLIC AND IMMUNE FUNCTIONS. GONADAL STEROIDS RECEPTORS HAVE A SIMILAR CAPACITY TO PRODUCE EPIGENOMIC REORGANIZATION OF CHROMATINE STRUCTURE. EPIGENOMIC-INDUCED REDUCTION IN IMMUNE CELLS TELOMERES LENGTH HAS BEEN OBSERVED IN MANY DEGENERATIVE DISEASES, INCLUDING ALL TYPES OF CANCER. THE FINAL RESULT OF THESE EPIGENETIC ALTERATIONS IS A SERIOUS DAMAGE TO THE NEURO-ENDOCRINE-IMMUNE-METABOLIC ADAPTIVE SYSTEMS. IN THIS STUDY, WE PROPOSE A TREATMENT WITH STEM CELLS DIFFERENTIATION STAGE FACTORS TAKEN FROM ZEBRAFISH EMBRYOS WHICH ARE ABLE TO REGULATE THE GENES EXPRESSION OF NORMAL AND PATHOLOGICAL STEM CELLS IN A DIFFERENT SPECIFIC WAY. 2015 11 5143 24 POTENTIAL ROLE OF EPIGENETIC MECHANISM IN MANGANESE INDUCED NEUROTOXICITY. MANGANESE IS A VITAL NUTRIENT AND IS MAINTAINED AT AN OPTIMAL LEVEL (2.5-5 MG/DAY) IN HUMAN BODY. CHRONIC EXPOSURE TO MANGANESE IS ASSOCIATED WITH NEUROTOXICITY AND CORRELATED WITH THE DEVELOPMENT OF VARIOUS NEUROLOGICAL DISORDERS SUCH AS PARKINSON'S DISEASE. OXIDATIVE STRESS MEDIATED APOPTOTIC CELL DEATH HAS BEEN WELL ESTABLISHED MECHANISM IN MANGANESE INDUCED TOXICITY. OXIDATIVE STRESS HAS A POTENTIAL TO ALTER THE EPIGENETIC MECHANISM OF GENE REGULATION. EPIGENETIC INSIGHT OF MANGANESE NEUROTOXICITY IN CONTEXT OF ITS CORRELATION WITH THE DEVELOPMENT OF PARKINSONISM IS POORLY UNDERSTOOD. PARKINSON'S DISEASE IS CHARACTERIZED BY THE ALPHA-SYNUCLEIN AGGREGATION IN THE FORM OF LEWY BODIES IN NEURONAL CELLS. RECENT FINDINGS ILLUSTRATE THAT MANGANESE CAN CAUSE OVEREXPRESSION OF ALPHA-SYNUCLEIN. ALPHA-SYNUCLEIN ACTS EPIGENETICALLY VIA INTERACTION WITH HISTONE PROTEINS IN REGULATING APOPTOSIS. ALPHA-SYNUCLEIN ALSO CAUSES GLOBAL DNA HYPOMETHYLATION THROUGH SEQUESTRATION OF DNA METHYLTRANSFERASE IN CYTOPLASM. AN INDIVIDUAL GENETIC DIFFERENCE MAY ALSO HAVE AN INFLUENCE ON EPIGENETIC SUSCEPTIBILITY TO MANGANESE NEUROTOXICITY AND THE DEVELOPMENT OF PARKINSON'S DISEASE. THIS REVIEW PRESENTS THE CURRENT STATE OF FINDINGS IN RELATION TO ROLE OF EPIGENETIC MECHANISM IN MANGANESE INDUCED NEUROTOXICITY, WITH A SPECIAL EMPHASIS ON THE DEVELOPMENT OF PARKINSON'S DISEASE. 2016 12 679 16 BRAIN FOODS - THE ROLE OF DIET IN BRAIN PERFORMANCE AND HEALTH. THE PERFORMANCE OF THE HUMAN BRAIN IS BASED ON AN INTERPLAY BETWEEN THE INHERITED GENOTYPE AND EXTERNAL ENVIRONMENTAL FACTORS, INCLUDING DIET. FOOD AND NUTRITION, ESSENTIAL IN MAINTENANCE OF BRAIN PERFORMANCE, ALSO AID IN PREVENTION AND TREATMENT OF MENTAL DISORDERS. BOTH THE OVERALL COMPOSITION OF THE HUMAN DIET AND SPECIFIC DIETARY COMPONENTS HAVE BEEN SHOWN TO HAVE AN IMPACT ON BRAIN FUNCTION IN VARIOUS EXPERIMENTAL MODELS AND EPIDEMIOLOGICAL STUDIES. THIS NARRATIVE REVIEW PROVIDES AN OVERVIEW OF THE ROLE OF DIET IN 5 KEY AREAS OF BRAIN FUNCTION RELATED TO MENTAL HEALTH AND PERFORMANCE, INCLUDING: (1) BRAIN DEVELOPMENT, (2) SIGNALING NETWORKS AND NEUROTRANSMITTERS IN THE BRAIN, (3) COGNITION AND MEMORY, (4) THE BALANCE BETWEEN PROTEIN FORMATION AND DEGRADATION, AND (5) DETERIORATIVE EFFECTS DUE TO CHRONIC INFLAMMATORY PROCESSES. FINALLY, THE ROLE OF DIET IN EPIGENETIC REGULATION OF BRAIN PHYSIOLOGY IS DISCUSSED. 2021 13 676 27 BRAIN AGING: A IANUS-FACED PLAYER BETWEEN HEALTH AND NEURODEGENERATION. NEURODEGENERATIVE DISEASES ARE INCURABLE DEBILITATING DISORDERS CHARACTERIZED BY STRUCTURAL AND FUNCTIONAL NEURONAL LOSS. APPROXIMATELY 30 MILLION PEOPLE ARE AFFECTED WORLDWIDE, AND THIS NUMBER IS PREDICTED TO REACH MORE THAN 150 MILLION BY 2050. NEURODEGENERATIVE DISORDERS INCLUDE ALZHEIMER'S, PARKINSON'S, AND PRION DISEASES AMONG OTHERS. THESE DISORDERS ARE CHARACTERIZED BY THE ACCUMULATION OF AGGREGATING PROTEINS FORMING AMYLOID, RESPONSIBLE FOR THE DISEASE-ASSOCIATED PATHOLOGICAL LESIONS. THE AGGREGATION OF AMYLOIDOGENIC PROTEINS CAN RESULT EITHER IN GAINING OF TOXIC FUNCTIONS, DERIVED FROM THE DAMAGE PROVOKED BY THESE DEPOSITS IN AFFECTED TISSUE, OR IN A LOSS OF FUNCTIONS, DUE TO THE SEQUESTRATION AND THE CONSEQUENT INABILITY OF THE AGGREGATING PROTEIN TO ENSURE ITS PHYSIOLOGICAL ROLE. WHILE IT IS WIDELY ACCEPTED THAT AGING REPRESENTS THE MAIN RISK FACTOR FOR NEURODEGENERATION, THERE IS STILL NO CLEAR CUT-OFF LINE BETWEEN THE TWO CONDITIONS. INDEED, MANY OF THE PATHWAYS THAT ARE COMMONLY ALTERED IN NEURODEGENERATION-MISFOLDED PROTEIN ACCUMULATION, CHRONIC INFLAMMATION, MITOCHONDRIAL DYSFUNCTION, IMPAIRED IRON HOMEOSTASIS, EPIGENETIC MODIFICATIONS-HAVE BEEN OFTEN CORRELATED ALSO WITH HEALTHY AGING. THIS OVERLAP COULD BE EXPLAINED BY THE FACT THAT THE CONTINUOUS ACCUMULATION OF CELLULAR DAMAGES, TOGETHER WITH A PROGRESSIVE DECLINE IN METABOLIC EFFICIENCY DURING AGING, MAKES THE NEURONS MORE VULNERABLE TO TOXIC INJURIES. WHEN A GIVEN THRESHOLD IS EXCEEDED, ALL THESE ALTERATIONS MIGHT GIVE RISE TO PATHOLOGICAL PHENOTYPES THAT ULTIMATELY LEAD TO NEURODEGENERATION. 2020 14 6886 23 [ROLE OF EPIGENETIC MODIFICATION IN HIGHER BRAIN DYSFUNCTION AND AGING]. EPIGENETIC MECHANISMS TYPICALLY INVOLVE HERITABLE ALTERATIONS IN CHROMATIN STRUCTURE, WHICH, IN TURN, REGULATE GENE EXPRESSION. FUNDAMENTAL INSIGHTS ABOUT EPIGENETIC HERITABILITY HAVE COME FROM STUDIES OF CELL DIVISION AND DEVELOPMENT. HOWEVER, THERE IS INCREASING EVIDENCE THAT THE REGULATION OF CHROMATIN STRUCTURE THROUGH HISTONE MODIFICATIONS AND DNA METHYLATION MIGHT MEDIATE THE EXPRESSION OF KEY GENES INVOLVED IN ACQUIRED CHRONIC DISORDERS. THIS IDEA IS FASCINATING BECAUSE SIMILAR MECHANISMS ARE USED FOR TRIGGERING AND STORING LONG-TERM MEMORIES AT THE CELLULAR LEVEL DURING, FOR EXAMPLE, HIGHER-BRAIN DYSFUNCTION, STRESS DISEASE, DRUG DEPENDENCE, AGING, AND CHRONIC PAIN. THIS REVIEW WILL EXPLORE THE MOST CURRENT ISSUES IN THE FIELD OF EPIGENETICS, WITH A FOCUS ON NEXT LEVELS OF TRANSCRIPTIONAL MECHANISMS UNDERLYING AGING, ENRICHED ENVIRONMENT AND DRUG ADDICTION. EPIGENETIC MECHANISMS, WHICH ARE KEY CELLULAR AND MOLECULAR PROCESSES THAT INTEGRATE DIVERSE ENVIRONMENTAL STIMULI TO EXERT POTENT AND OFTEN LONG-LASTING CHANGES IN GENE EXPRESSION THROUGH THE REGULATION OF CHROMATIN STRUCTURE, CONTRIBUTE TO TRANSCRIPTIONAL AND BEHAVIORAL CHANGES. 2012 15 2058 19 EPIGENETIC CONTROL OF GENE EXPRESSION IN THE ALCOHOLIC BRAIN. CHRONIC ALCOHOL EXPOSURE CAUSES WIDESPREAD CHANGES IN BRAIN GENE EXPRESSION IN HUMANS AND ANIMAL MODELS. MANY OF THESE CONTRIBUTE TO CELLULAR ADAPTATIONS THAT ULTIMATELY LEAD TO BEHAVIORAL TOLERANCE AND ALCOHOL DEPENDENCE. THERE IS AN EMERGING APPRECIATION FOR THE ROLE OF EPIGENETIC PROCESSES IN ALCOHOL-INDUCED CHANGES IN BRAIN GENE EXPRESSION AND BEHAVIOR. FOR EXAMPLE, CHRONIC ALCOHOL EXPOSURE PRODUCES CHANGES IN DNA AND HISTONE METHYLATION, HISTONE ACETYLATION, AND MICRORNA EXPRESSION THAT AFFECT EXPRESSION OF MULTIPLE GENES IN VARIOUS TYPES OF BRAIN CELLS (I.E., NEURONS AND GLIA) AND CONTRIBUTE TO BRAIN PATHOLOGY AND BRAIN PLASTICITY ASSOCIATED WITH ALCOHOL ABUSE AND DEPENDENCE. DRUGS TARGETING THE EPIGENETIC "MASTER REGULATORS" ARE EMERGING AS POTENTIAL THERAPEUTICS FOR NEURODEGENERATIVE DISORDERS AND DRUG ADDICTION. 2013 16 2596 24 EPIGENETICS OF STRESS ADAPTATIONS IN THE BRAIN. RECENT FINDINGS IN EPIGENETICS SHED NEW LIGHT ON THE REGULATION OF GENE EXPRESSION IN THE CENTRAL NERVOUS SYSTEM (CNS) DURING STRESS. THE MOST FREQUENTLY STUDIED EPIGENETIC MECHANISMS ARE DNA METHYLATION, HISTONE MODIFICATIONS AND MICRORNA ACTIVITY. THESE MECHANISMS STABLY DETERMINE CELL PHENOTYPE BUT CAN ALSO BE RESPONSIBLE FOR DYNAMIC MOLECULAR ADAPTATIONS OF THE CNS TO STRESSORS. THE LIMBIC-HYPOTHALAMIC-PITUITARY-ADRENAL AXIS (LHPA) IS THE PRIMARY CIRCUIT THAT INITIATES, REGULATES AND TERMINATES A STRESS RESPONSE. THE SAME BRAIN AREAS THAT CONTROL STRESS ALSO REACT TO STRESS DYNAMICALLY AND WITH LONG-TERM CONSEQUENCES. ONE OF THE BIOLOGICAL PROCESSES EVOKING POTENT ADAPTIVE CHANGES IN THE CNS SUCH AS CHANGES IN BEHAVIOR, GENE ACTIVITY OR SYNAPTIC PLASTICITY IN THE HIPPOCAMPUS IS PSYCHOGENIC STRESS. THIS REVIEW SUMMARIZES THE CURRENT DATA REGARDING THE EPIGENETIC BASIS OF MOLECULAR ADAPTATIONS IN THE BRAIN INCLUDING GENOME-WIDE EPIGENETIC CHANGES OF DNA METHYLATION AND PARTICULAR GENES INVOLVED IN EPIGENETIC RESPONSES THAT PARTICIPATE IN THE BRAIN RESPONSE TO CHRONIC PSYCHOGENIC STRESSORS. IT IS CONCLUDED THAT SPECIFIC EPIGENETIC MECHANISMS IN THE CNS ARE INVOLVED IN THE STRESS RESPONSE. 2013 17 338 23 ALTERATIONS IN GENE EXPRESSION DUE TO CHRONIC LEAD EXPOSURE INDUCE BEHAVIORAL CHANGES. LEAD (PB) IS A POLLUTANT COMMONLY FOUND IN THE ENVIRONMENT, DESPITE THE IMPLEMENTATION OF PUBLIC HEALTH POLICIES INTENDED TO REMOVE IT. DUE TO ITS CHEMICAL CHARACTERISTICS AS A DIVALENT ION, PB INTERACTS WITH CELLS, ENZYMES, AND TISSUES, CAUSING PATHOLOGICAL, PHYSICAL, AND BEHAVIORAL ALTERATIONS. RECENT BIOTECHNOLOGICAL ADVANCES HAVE HELPED US TO UNDERSTAND THE MECHANISMS UNDERLYING THE DAMAGE CAUSED BY PB IN HUMAN POPULATIONS AND IN EXPERIMENTAL MODELS, AND NEW EVIDENCE ON THE EPIGENETIC ALTERATIONS CAUSED BY EXPOSITION TO ENVIRONMENTAL PB IS AVAILABLE. IT IS KNOWN THAT PB EXPOSURE IMPACTS ON BEHAVIOR (CAUSING AGGRESSIVENESS, ANXIETY, AND DEPRESSION), LEADING TO LEARNING DEFICIT AND LOCOMOTOR ACTIVITY ALTERATIONS, AND ITS PRESENCE HAS BEEN LINKED WITH THE ABNORMAL RELEASE OF NEUROTRANSMITTERS AND OTHER BIOCHEMICAL CHANGES INVOLVED IN THESE DISORDERS. STILL, FURTHER REDUCTIONIST STUDIES ARE REQUIRED TO DETERMINE THE EFFECTS OF PB EXPOSURE ON DNA AND PROTEIN EXPRESSION AND UNDERSTAND THE PROCESSES UNDERLYING THE DISEASES CAUSED BY PB. THIS WILL ALSO INDICATE POSSIBLE THERAPEUTIC TARGETS TO OFFSET THE NEGATIVE EFFECTS OF THE HEAVY METAL. BY ELUCIDATING THE EPIGENETIC CHANGES INVOLVED, IT WOULD BE POSSIBLE TO MANIPULATE THEM AND PROPOSE NOVEL THERAPEUTIC APPROACHES IN THIS AREA. THIS REVIEW IS AIMED TO PROVIDE AN OVERVIEW OF STUDIES THAT LINK PB EXPOSURE TO BEHAVIORAL CHANGES, AS WELL AS BIOCHEMICAL AND EPIGENETIC ALTERATIONS AT A NEUROTRANSMITTER LEVEL, CONSIDERING THE IMPORTANCE OF THIS METAL IN BEHAVIOR ABNORMALITIES. 2021 18 6347 20 THE ROLE OF EPIGENETICS IN NEUROINFLAMMATORY-DRIVEN DISEASES. NEURODEGENERATIVE DISORDERS ARE CHARACTERIZED BY THE PROGRESSIVE LOSS OF CENTRAL AND/OR PERIPHERAL NERVOUS SYSTEM NEURONS. WITHIN THIS CONTEXT, NEUROINFLAMMATION COMES UP AS ONE OF THE MAIN FACTORS LINKED TO NEURODEGENERATION PROGRESSION. IN FACT, NEUROINFLAMMATION HAS BEEN RECOGNIZED AS AN OUTSTANDING FACTOR FOR ALZHEIMER'S DISEASE (AD), AMYOTROPHIC LATERAL SCLEROSIS (ALS), PARKINSON'S DISEASE (PD), AND MULTIPLE SCLEROSIS (MS). INTERESTINGLY, NEUROINFLAMMATORY DISEASES ARE CHARACTERIZED BY DRAMATIC CHANGES IN THE EPIGENETIC PROFILE, WHICH MIGHT PROVIDE NOVEL PROGNOSTIC AND THERAPEUTIC FACTORS TOWARDS NEUROINFLAMMATORY TREATMENT. DEEP CHANGES IN DNA AND HISTONE METHYLATION, ALONG WITH HISTONE ACETYLATION AND ALTERED NON-CODING RNA EXPRESSION, HAVE BEEN REPORTED AT THE ONSET OF INFLAMMATORY DISEASES. THE AIM OF THIS WORK IS TO REVIEW THE CURRENT KNOWLEDGE ON THIS FIELD. 2022 19 6400 25 THE ROLES OF CLASS I HISTONE DEACETYLASES (HDACS) IN MEMORY, LEARNING, AND EXECUTIVE COGNITIVE FUNCTIONS: A REVIEW. COORDINATED CHANGES IN GENE EXPRESSION ARE CRITICAL FOR SYNAPTIC PLASTICITY SUPPORTING LEARNING, MEMORY, AND OPTIMAL COGNITIVE TASK PERFORMANCE. THESE GENE EXPRESSION CHANGES ARE NOT ONLY MEDIATED BY SIGNALING PATHWAYS THAT ACTIVATE TRANSCRIPTION FACTORS, BUT ALSO BY CHROMATIN MODIFICATIONS THAT INFLUENCE THE ACCESSIBILITY OF THE TRANSCRIPTIONAL MACHINERY TO SPECIFIC GENOMIC REGIONS. DURING THE PAST DECADE, EVIDENCE ACCUMULATED THAT ALTERATIONS IN CHROMATIN-BASED EPIGENETIC REGULATION OF GENE EXPRESSION ARE LINKED TO COGNITIVE DYSFUNCTIONS IN THE AGEING OR NEURODEGENERATING BRAIN AS WELL AS TO COGNITIVE DYSFUNCTIONS RESULTING FROM CHRONIC STRESS EXPOSURE. THIS REVIEW SUMMARIZES THE RESULTS OF STUDIES THAT UNRAVELED A ROLE OF HISTONE MODIFYING ENZYMES AND HISTONE MODIFICATIONS IN NORMAL AND IMPAIRED LEARNING AND MEMORY, AND IN THE DISRUPTION OF EXECUTIVE COGNITIVE TASK PERFORMANCE. IT EMPHASIZES THE DIFFERENT ROLES OF SPECIFIC CLASS I HISTONE DEACETYLASES (HDACS) IN COGNITIVE PROCESSES GOVERNED BY THE HIPPOCAMPUS AND PREFRONTAL CORTEX AND DISCUSSES THE POTENTIAL THERAPEUTIC IMPLICATIONS OF TARGETING THEM TO HOLD THE PROGRESSION OF DISEASE-RELATED COGNITIVE DYSFUNCTIONS. 2017 20 6866 23 [PAIN AND EMOTIONAL DYSREGULATION: CELLULAR MEMORY DUE TO PAIN]. GENETIC FACTORS ARE INVOLVED IN DETERMINANTS FOR THE RISK OF PSYCHIATRIC DISORDERS, AND NEUROLOGICAL AND NEURODEGENERATIVE DISEASES. CHRONIC PAIN STIMULI AND INTENSE PAIN HAVE EFFECTS AT A CELLULAR AND/OR GENE EXPRESSION LEVEL, AND WILL EVENTUALLY INDUCE "CELLULAR MEMORY DUE TO PAIN", WHICH MEANS THAT TISSUE DAMAGE, EVEN IF ONLY TRANSIENT, CAN ELICIT EPIGENETICALLY ABNORMAL TRANSCRIPTION/TRANSLATION AND POST-TRANSLATIONAL MODIFICATION IN RELATED CELLS DEPENDING ON THE DEGREE OR KIND OF INJURY OR ASSOCIATED CONDITIONS. SUCH CELL MEMORY/TRANSFORMATION DUE TO PAIN CAN CAUSE AN ABNORMALITY IN A FUNDAMENTAL INTRACELLULAR RESPONSE, SUCH AS A CHANGE IN THE THREE-DIMENSIONAL STRUCTURE OF DNA, TRANSCRIPTION, OR TRANSLATION. ON THE OTHER HAND, PAIN IS A MULTIDIMENSIONAL EXPERIENCE WITH SENSORY-DISCRIMINATIVE AND MOTIVATIONAL-AFFECTIVE COMPONENTS. RECENT HUMAN BRAIN IMAGING STUDIES HAVE EXAMINED DIFFERENCES IN ACTIVITY IN THE NUCLEUS ACCUMBENS BETWEEN CONTROLS AND PATIENTS WITH CHRONIC PAIN, AND HAVE REVEALED THAT THE NUCLEUS ACCUMBENS PLAYS A ROLE IN PREDICTING THE VALUE OF A NOXIOUS STIMULUS AND ITS OFFSET, AND IN THE CONSEQUENT CHANGES IN THE MOTIVATIONAL STATE. IN THIS REVIEW, WE PROVIDE A VERY BRIEF OVERVIEW OF A COMPREHENSIVE UNDERSTANDING OF CHRONIC PAIN ASSOCIATED WITH EMOTIONAL DYSREGULATION DUE TO TRANSCRIPTIONAL REGULATION, EPIGENETIC MODIFICATION AND MIRNA REGULATION. 2015