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Autophagy is indispensable for normal maturation and function of macrophages and neutrophilsStranks, Amanda Jane January 2013 (has links)
Macrophages and neutrophils are vital cells of the immune system, performing crucial innate functions and bridging innate and adaptive immunity. However, inappropriate activation or poor resolution of responses results in chronic inflammatory and autoimmune conditions due to accumulation of myeloid cells and uncontrolled cytokine production, as is commonly seen in the aging immune system. It is not clear what is required to maintain healthy myeloid cells throughout life or what links inflammation and myeloid dysfunction during the aging process. We have shown that autophagy, a vital intracellular degradation mechanism, is required for normal macrophage innate and adaptive immune functions such as phagocytosis and antigen presentation, as well as being an important regulator of the inflammatory response. Loss of autophagy also results in reduced surface antigen expression and increased glycolysis. We found that autophagy-deficient macrophages have a similar phenotype to aged macrophages. Furthermore, aged macrophages exhibit reduced autophagy compared with young macrophages, suggesting a link between reduced autophagy and acquisition of the aging macrophage phenotype. Finally, we show that autophagy plays a vital role in normal neutrophil differentiation, with autophagy-deficient neutrophils exhibiting altered nuclear morphology and aberrant granule formation. These data show that autophagy plays a critical role in the maintenance of essential macrophage homeostasis and functions by regulating inflammation and metabolism, thereby preventing immunosenescence. We postulate that autophagy modulation in macrophages and neutrophils may be used to prevent excess inflammation, such as in inflammatory and autoimmune diseases. Moreover, inflammation due to aging may potentially be delayed by induction or preservation of autophagy, which could improve immune responses and reduce the morbidity and mortality associated with “inflamm-aging”.
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Implication of a novel nerve growth factor (NGF) maturation and degradation cascade in the Fischer-344 rat model of age-associated memory deficitsBossy, Tanya. January 2009 (has links)
Despite the overwhelming evidence for atrophy of the NGF-dependant Basal Forebrain Cholinergic neurons during aging, there is no persuasive evidence towards a decrease in NGF and/or NGF mRNA content in the brain of aged animals. Previous experiments from our laboratory have shown that NGF is released as a precursor protein and cleaved into the mature form in the extracellular space under the influence of a complex protease cascade. These recent findings have lead us to propose that any alterations in levels and/or activity of this maturation/degradation cascade might affect NGF's biological activity and perhaps lead to cognitive impairments in a subset of aged rats. To investigate this possibility, we measured protein and mRNA levels of the protease cascade players (NGF, pro-NGF, tPA, plasminogen, plasmin, MMP-9, neuroserpin). We found significantly decreased levels of both pro-NGF protein and NGF mRNA, but no difference in the remaining elements of the protease cascade, when comparing aged impaired (Al) to the aged unimpaired (AU) animals. Our second objective was to investigate whether animals trained in the Morris Water Maze would preserve their cognitive status in two additional behavioral paradigms, the Novel Object Location (NOL, spatial memory) and Novel Object Recognition (NOR, nonspatial memory) tasks. We found that both AU and AI animals in the MWM were impaired in the NOL when compared to the young controls, with the AI animals performing significantly worse than the AU in this particular task. In the NOR tasks, AI animals performed significantly worse compared to both young and AU animals. In conclusion, further experiments are required to better understand the implication of the complex protease cascade involved in NGF's maturation and degradation as well as its effect on memory of aged animals. In addition, because the segregation of animals (aged impaired/unimpaired) is a crucial step in aging research, we now have additional behavioral paradigms (NOL/NOR) that confirm the cognitive status of these animals.
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Implication of a novel nerve growth factor (NGF) maturation and degradation cascade in the Fischer-344 rat model of age-associated memory deficitsBossy, Tanya. January 2009 (has links)
No description available.
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Excitatory Amino Acids in Health and DiseaseThomas, R J. 01 November 1995 (has links)
PURPOSE: To review the role of excitatory neurotransmitters in normal mammalian brain function, the concept of excitotoxic neuronal death as an important final common path in a variety of diseases, and modification of excitatory synaptic transmission as an important new pharmacological principle. These principles are discussed, with special emphasis on diseases of importance to older adults. DATA SOURCES: A MEDLINE search from 1966 to May 1995 was undertaken, as well as a manual search of current issues of clinical and basic neuroscience journals, for articles that addressed glutamate N-methyl-D-aspartate and/or excitotoxicity. STUDY SELECTION: A total of 5398 original and 68 review articles were identified that addressed animal and human experimentation relevant to excitotoxic neuronal death. There were 364 articles with potential significance for clinical application identified; 132 of the most recent references are provided. DATA EXTRACTION: All articles were classified into three categories: general receptor, biology pathogenesis of disease, and pharmacotherapy. RESULTS: Glutamic and aspartic acids are the physiological mediators of most excitatory synaptic transmission. This is critical to several normal nervous system functions, including memory and long-term modification of synaptic transmission and nociception. Activation of the inotropic NMDA and non-NMDA receptors increases transmembrane calcium and sodium fluxes, and the metabotropic glutamate receptor activation results in generation of inositol triphosphate and inhibition of adenylate cyclase. Numerous modulatory sites exist, especially on the NMDA receptor. Nitric oxide, arachidonic acid, superoxide, and intracellular calcium overload are the ultimate mediators of neuronal death. Glutamate re-uptake transporters belong to a unique family of amino acid transport systems, the malfunction of which is intricately involved in disease pathogenesis. Ischemic stroke, hypoglycemia, Parkinson's disease, alcohol intoxication and withdrawal, Alzheimer's disease, epilepsy, and chronic pain syndromes are only some of the important clinical neurological disorders with a major pathogenic role for the excitatory amino acids. CONCLUSIONS: Pharmacological manipulation of the excitatory amino acid receptors is likely to be of benefit in important and common diseases of the nervous system. Only a few of the currently available drugs that modify excitatory neurotransmission, such as remacemide, lamotrigine, and tizanidine, have an acceptable therapeutic index. The identification of numerous receptor subtypes, topographic variabilities of distribution, and multiple modulatory sites will provide a true challenge to the neuropharmacologist.
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Análise da mobilidade mitocondrial em células vivas do hipocampo, substância negra e locus coeruleus anterior à agregação proteica envolvida em neurodegeneração / Analisys of mitochondrial mobility in living hippocampal, substantita nigra and locus coeruleos cells before protein aggregation involved in neurodegenerationMartins, Stephanie Alves 29 November 2013 (has links)
A alteração do tráfego mitocondrial em neurônios leva ao aumento do estresse oxidativo, privação de energia, deficiência da comunicação intercelular e neurodegeneração. Há evidências de que essas alterações de tráfego antecedem a morte neuronal associada à agregação proteica. Portanto, conhecer a relação entre a mobilidade mitocondrial e a formação de agregados proteicos pode ser um passo importante para o melhor entendimento dos mecanismos da neurodegeneração. Com isso, o objetivo do presente estudo é analisar a mobilidade das mitocôndrias em culturas de células do hipocampo, substância negra e locus coeruleus expostas a rotenona e MPTP, como agentes neurodegenerativos, e à rapamicina como ativador da autofagia. Um outro objetivo do estudo é avaliar o papel do cálcio (através do emprego de EGTA e ionomicina) no modelo experimental. Os resultados mostraram aumento da mobilidade mitocondrial no hipocampo e diminuição na substância negra, já no locus coeruleus houve aumento seguido de diminuição da mobilidade mitocondrial dependendo da concentração de rotenona. O emprego do EGTA e ionomicina mostra que a ação da rotenona sobre o tráfego mitocondrial envolve o cálcio, mas não se relaciona com uma possível alteração da integridade mitocondrial, já que não foi observada alteração no potencial de membrana mitocondrial. Foram também realizados experimentos a fim de avaliar a mobilidade mitocondrial em modelo utilizando rapamicina para ativar a autofagia e MPTP como indutor da neurodegeneração em culturas de células, onde foi observado aumento da mobilidade no hipocampo e no locus coeruleus quando exposto a rapamicina e aumento da mobilidade mitocondrial em cultura de células do hipocampo exposto a MPTP já no locus coeruleus houve uma diminuição significativa da mobilidade mitocondrial. Os resultados permitem concluir que o tráfego mitocondrial está alterado antes da agregação proteica podendo contribuir com a neurodegeneração / Altered mitochondrial traffic in neurons can lead to increased oxidative stress, energy deprivation, impaired intercellular communication and neurodegeneration. There are evidences mitochondria disturbing precedes neuronal death associated with protein aggregation. Therefore, the study of mitochondrial traffic and protein aggregation can be an important step towards a better understanding of the mechanisms of neurodegeneration. Thus, the aim of this study is to analyze mitochondria mobility in cultured cells of the hippocampus, substantia nigra and locus coeruleus exposed to rotenone and MPTP, as neurodegeneration-promoting agents, and rapamycin to activate autophagy. The other objective of the study was to analyze the role of calcium (through EGTA and ionomycin) in the experimental model. The results showed increased and decreased mobility mitochondrial in cells from hippocampus and substantia nigra, respectively, while the locus coeruleus cell culture has increased followed by decreased mitochondrial mobility depending upon rotenone concentration. The use of EGTA and ionomycin showed that alteration of mitochondrial traffic is associated with calcium, however it is not related with changes in mitochondrial membrane potential. Additional experiments were also conducted to assess mitochondrial mobility in a model using rapamycin to activate autophagy and MPTP to induce neurodegeneration in cell cultures. The results of these experiments showed increased mitochondrial mobility in the hippocampus and locus coeruleus when exposed to rapamycin; while MPTP also increased mitochondria mobility in hippocampal cell cultures, but decreased it in locus coeruleus. Results suggest that mitochondrial traffic is altered before protein aggregation, which may contribute to neurodegeneration
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Análise da mobilidade mitocondrial em células vivas do hipocampo, substância negra e locus coeruleus anterior à agregação proteica envolvida em neurodegeneração / Analisys of mitochondrial mobility in living hippocampal, substantita nigra and locus coeruleos cells before protein aggregation involved in neurodegenerationStephanie Alves Martins 29 November 2013 (has links)
A alteração do tráfego mitocondrial em neurônios leva ao aumento do estresse oxidativo, privação de energia, deficiência da comunicação intercelular e neurodegeneração. Há evidências de que essas alterações de tráfego antecedem a morte neuronal associada à agregação proteica. Portanto, conhecer a relação entre a mobilidade mitocondrial e a formação de agregados proteicos pode ser um passo importante para o melhor entendimento dos mecanismos da neurodegeneração. Com isso, o objetivo do presente estudo é analisar a mobilidade das mitocôndrias em culturas de células do hipocampo, substância negra e locus coeruleus expostas a rotenona e MPTP, como agentes neurodegenerativos, e à rapamicina como ativador da autofagia. Um outro objetivo do estudo é avaliar o papel do cálcio (através do emprego de EGTA e ionomicina) no modelo experimental. Os resultados mostraram aumento da mobilidade mitocondrial no hipocampo e diminuição na substância negra, já no locus coeruleus houve aumento seguido de diminuição da mobilidade mitocondrial dependendo da concentração de rotenona. O emprego do EGTA e ionomicina mostra que a ação da rotenona sobre o tráfego mitocondrial envolve o cálcio, mas não se relaciona com uma possível alteração da integridade mitocondrial, já que não foi observada alteração no potencial de membrana mitocondrial. Foram também realizados experimentos a fim de avaliar a mobilidade mitocondrial em modelo utilizando rapamicina para ativar a autofagia e MPTP como indutor da neurodegeneração em culturas de células, onde foi observado aumento da mobilidade no hipocampo e no locus coeruleus quando exposto a rapamicina e aumento da mobilidade mitocondrial em cultura de células do hipocampo exposto a MPTP já no locus coeruleus houve uma diminuição significativa da mobilidade mitocondrial. Os resultados permitem concluir que o tráfego mitocondrial está alterado antes da agregação proteica podendo contribuir com a neurodegeneração / Altered mitochondrial traffic in neurons can lead to increased oxidative stress, energy deprivation, impaired intercellular communication and neurodegeneration. There are evidences mitochondria disturbing precedes neuronal death associated with protein aggregation. Therefore, the study of mitochondrial traffic and protein aggregation can be an important step towards a better understanding of the mechanisms of neurodegeneration. Thus, the aim of this study is to analyze mitochondria mobility in cultured cells of the hippocampus, substantia nigra and locus coeruleus exposed to rotenone and MPTP, as neurodegeneration-promoting agents, and rapamycin to activate autophagy. The other objective of the study was to analyze the role of calcium (through EGTA and ionomycin) in the experimental model. The results showed increased and decreased mobility mitochondrial in cells from hippocampus and substantia nigra, respectively, while the locus coeruleus cell culture has increased followed by decreased mitochondrial mobility depending upon rotenone concentration. The use of EGTA and ionomycin showed that alteration of mitochondrial traffic is associated with calcium, however it is not related with changes in mitochondrial membrane potential. Additional experiments were also conducted to assess mitochondrial mobility in a model using rapamycin to activate autophagy and MPTP to induce neurodegeneration in cell cultures. The results of these experiments showed increased mitochondrial mobility in the hippocampus and locus coeruleus when exposed to rapamycin; while MPTP also increased mitochondria mobility in hippocampal cell cultures, but decreased it in locus coeruleus. Results suggest that mitochondrial traffic is altered before protein aggregation, which may contribute to neurodegeneration
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