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11	Efeito dos oxisteróis na sinalização através de cavéolas e sua relevância na aterosclerose / Effect of oxysterols in cell signaling through caveolae and its relevance to atherosclerosis Jurado, Marcia Cristiane 11 February 2011 (has links) Oxisteróis (por exemplo, 7hidroxicolesterol) são gerados por modificações oxidativas que ocorrem na molécula de colesterol. Podem ser encontrados em elevados níveis plasmáticos em pacientes com aterosclerose e como componentes da placa aterosclerótica. Considerando que o colesterol é o principal componente da cavéola (domínios específicos da membrana plasmática que ancoram diversas proteínas de sinalização) formulamos a hipótese que os oxisteróis podem ser incorporados a estes domínios, interferindo com as vias de sinalização aí localizadas. Células endoteliais de veia umbilical humana (HUVECs) em cultura foram expostas a 7hidroxicolesterol (10g/mL) por diferentes tempos. Analisamos a incorporação desse oxisterol à cavéola utilizando espectrometria de massa e a atividade das proteínas de sinalização presentes neste domínio: óxido nítrico sintase endotelial (eNOS), CD40/CD40L, receptor do fator de crescimento de fibroblastos (rFGF), utilizando PCR quantitativo e imunoblots. Inicialmente mostramos que o 7hidroxycholesterol, em concentrações fisiológicas, foi incorporado às cavéolas mais acentuadamente que em outros domínios de membrana. Esse fenômeno impediu o desligamento entre eNOS e caveolina, prejudicando a função dessa enzima. Também mostramos que o receptor CD40 apresentou uma maior incorporação à cavéola e o rFGF manteve uma ativação mais longa quando células foram expostas ao 7hidroxicolesterol. Esses efeitos gerados pelo oxisterol não estavam relacionados à sua ação sobre mediadores inflamatórios ou receptores nucleares, desde que nenhuma diferença foi observada no perfil de citocinas ou na expressão de genes dependentes da ativação de LXR. Assim, concluímos que a incorporação de 7hidroxycholesterol nos domínios de cavéola pode interferir com vias de sinalização sabidamente envolvidas na aterogênese ou na ruptura da placa / Oxysterols (for example, 7hidroxycholesterol) are generated by oxidative modifications to cholesterol molecules. They have been described in high levels in patients with atherosclerosis and as components of the atherosclerotic plaque. Since cholesterol is the main component of caveolae (plasma membrane domains that anchor several signaling proteins), we hypothesized that oxysterol could be incorporated to these domains, interfering with the signaling networks that use this pathway. Human umbilical vein endothelial cells (HUVECs) in culture were exposed to 7hidroxycholesterol (10g/mL) for different times. We analyzed incorporation of this oxysterol to caveolae using mass spectroscopy and the activity of signaling pathways present in these domains: endothelial nitric oxide synthase (eNOS), CD40/CD40L, fibroblast growth factor receptor (FGFr), using quantitative PCR and immunoblots. Initially we showed that 7hidroxycholesterol, in physiological concentrations, was incorporated to caveolae more prominently than to other plasma membrane domains. This phenomenon caused a difficulty in eNOS release from caveolin, impairing its function. We also showed that the receptor CD40 presented a stronger incorporation to caveolae and FGFr maintained a longer activation when cells were exposed to 7hidroxycholesterol. These oxysterol effects were not related to its action in inflammatory mediators or nuclear receptors, since no difference could be observed in cytokine profiles or in the expression of genes dependent on LXR activation. Therefore we conclude that 7hidroxycholesterol incorporation in caveolae domains may interfere with signaling pathways known to be involved in atherogenesis or in plaque rupture Aterosclerose Atherosclerosis Caveolae Cavéolas Endothelial nitric oxide synthase Óxido nítrico sintase tipo III Oxisterol Oxysterol
12	The Signaling Pathway of Oxysterol Induced Apoptosis in Chinese Hamster Ovary (CHO)-K1 Cells. Yang, Lin 16 August 2002 (has links) (PDF) Apoptosis, a form of genetically programmed cell death, plays a key role in regulation of cellularity of the arterial wall. During atherogenesis, improper apoptosis may cause abnormalities of arterial morphogenesis, wall structural stability, and metabolisms. It has been well established that vascular cells undergo apoptosis after uptake of oxidized low-density lipoprotein (oxLDL). Thus, an analysis of the signaling pathway of apoptotic induction by oxLDL is of value in understanding the development of atherosclerotic plaque. In order to elucidate the signaling pathway of apoptosis induced by oxLDL, we have used Chinese hamster ovary (CHO)-K1 cells treated with a potent oxysterol, 25-hydroxycholesterol (25-OHC). In the present study, we find that oxLDL can induce apoptosis in any cell types if cells present the specific receptors on their surface to take up oxLDL, and that apoptosis-inducing activity is associated with oxysterol components in oxLDL. Oxysterol-induced apoptosis does not involve regulation of sterol regulatory element-binding protein proteolysis pathway. 25-OHC stimulates calcium uptake by CHO-K1 cells within 2 min after addition. Treatment of CHO-K1 cells with the calcium channel blocker nifedipine prevents 25-OHC induction of apoptosis. One possible signal transduction pathway initiated by calcium ion fluxes is the activation of cytosolic phospholipase A2 (cPLA2). We demonstrate that activation of cPLA2 does occur in CHO-K1 treated with 25-OHC. Activation is evidenced by 25-OHC-induced relocalization of cPLA2 to the nuclear envelope and arachidonic acid (AA) release. Loss of cPLA2 activity by treatment with a cPLA2 inhibitor results in an attenuation of AA release as well as of the apoptotic response to 25-OHC in CHO-K1 cells. CPLA2ûmediated liberation of AA leads to the formation of a cyclooxygenase product, probably a prostaglandin, which activates the transcription factor PPARγ and induces apoptosis. We also examined the execution phase of the apoptotic pathway in CHO-K1 cell death induced by 25-OHC. Oxysterol-induced apoptosis in CHO-K1 is accompanied by caspase activation and is preceded by mitochondrial cytochrome C release. Furthermore, treatment with a cPLA2 inhibitor results in an inhibition of caspase-3 activation in CHO-K1 cells. These data provide strong evidence indicating that 25-OHC induces caspase-3-mediated apoptosis via an activation of calcium-dependent cPLA2. caspase cPLA2 PPAR PPARgamma oxysterol Apoptosis Medical Sciences Medicine and Health Sciences
13	Treinamento físico aeróbio altera seletivamente a concentração e o metabolismo arterial de óxidos de colesterol e reduz colesterol na aorta de camundongos dislipidêmicos / Aerobic exercise training selectively changes oxysterol levels and metabolism reducing cholesterol accumulation in the aorta of dyslipidemic mice Ferreira, Guilherme da Silva 04 October 2017 (has links) Os óxidos de colesterol modulam o desenvolvimento da aterosclerose por mediarem a síntese, captação e exportação de colesterol, além de inflamação e citotoxicidade na parede arterial. O exercício físico regular previne e regride a lesão aterosclerótica, por melhorar o perfil lipídico, transporte reverso de colesterol e defesas antioxidantes. A proteína cinase ativada por AMP (AMPK) é um importante mediador dos efeitos metabólicos do exercício físico. Em macrófagos, sua ativação vincula-se ao aumento no efluxo de colesterol e diminuição na captação de LDL. Entretanto, não está claro se o treinamento físico modula as concentrações de óxidos de colesterol, refletindo seu benefício sobre a prevenção da aterosclerose, e se esses efeitos podem ser mediados pela AMPK. O objetivo do presente estudo foi avaliar, em camundongos dislipidêmicos, o papel de 6 semanas de treinamento físico aeróbio sobre: o infiltrado de colesterol arterial e a distribuição de óxidos de colesterol no arco aórtico e no plasma; a expressão gênica de proteínas envolvidas na metabolização de óxidos de colesterol na parede arterial; e o efeito da ativação da AMPK em macrófagos, in vitro, sobre a concentração dos óxidos de colesterol e expressão de genes envolvidos na metabolização de óxidos de colesterol. Para tanto, camundongos machos knockout para apolipoproteína E, com 16 semanas de idade, alimentados com dieta padrão, foram incluídos no estudo. O treinamento físico foi realizado em esteira, 15 m/min, por 60 min, 5 dias/semana, durante 6 semanas. Lípides plasmáticos e glicose foram determinados por ensaio enzimático e glicosímetro, respectivamente, antes e após o treinamento físico. Colesterol arterial e óxidos de colesterol foram avaliados por cromatografia gasosa acoplada à espectrometria de massa. A expressão de genes envolvidos no metabolismo de lípides foi avaliada RT-qPCR. Os resultados foram comparados por ANOVA de um fator com pós-teste de Newman-Keuls ou teste t de Student. Peso corporal, colesterol total, TG, HDL-c, glicose e óxidos de colesterol no plasma foram semelhantes entre os grupos. O treinamento físico aumentou a concentração de 7alfa-OH C (70%) e reduziu a de colesterol (32%) na aorta. Além disso, o exercício físico aumentou a expressão gênica da Cyp27a1 (54%), Cd36 (75%), Cat (70%), Prkaa1 (AMPKalfa1) (40%) e Prkaa2 (AMPKalfa2) (51%) e reduziu Abcg1 (31%), Olr1 (LOX-1) (65%), Cyp7b1 (35%) e Ch25h (48%). Nenhuma alteração foi observada na expressão de Abca1, Nr1h3 (LXRalfa) e Nr1h2 (LXRbeta). Nos macrófagos, a ativação da AMPK por AICAR, reduziu o conteúdo de 7alfa-OH C após estimulo com HDL2. O tratamento com AICAR aumentou a expressão gênica de Abca1 (52%) e Cd36 (220%) e diminuiu Prkaa1 (19%) e Cyp27a1 (47%), e não alterou Abcg1, Nr1h3 e Nr1h2. Em conclusão, em camundongos dislipidêmicos, o treinamento físico aeróbio, por 6 semanas, aumentou a concentração de 7 beta -OH C, o que se vincula à maior expressão de Cd36 no arco aórtico. A rápida difusão de óxidos de colesterol, como via complementar ao transporte reverso de colesterol, pode também ser favorecida pelo aumento e redução, respectivamente, na expressão de Cyp27a1 e Cyp7b1, favorecendo maior liberação de 27-OH C das células. Juntamente com suas ações diretas que beneficiam o transporte reverso de colesterol, previamente descritas o treinamento físico diminui a concentração de colesterol na parede arterial, prevenindo a aterosclerose. Baseado nos ensaios in vitro a ativação da AMPK não parece contribuir para o aumento das concentrações de óxidos de colesterol após treinamento físico / Oxysterols modulate the development of atherosclerosis by mediating cholesterol synthesis, uptake and exportation as well as inflammation and cytotoxicity in the arterial wall. Regular physical exercise prevents and regresses atherosclerosis by improving lipid metabolism, reverse cholesterol transport and antioxidant defenses. AMP-activated protein kinase (AMPK) plays an important role in the beneficial metabolic adaptations of physical exercise. In macrophages, its activation is related to the enhancement in cholesterol efflux and reduction in LDL uptake. However, it is not clear whether exercise training benefits in atherosclerosis is mediated by its action in oxysterols concentrations, and whether this can be modulated by AMPK. The aim of this study was to evaluate the role of a 6-week aerobic exercise training program in dyslipidemic mice in the arterial and plasma accumulation of cholesterol and oxysterols subspecies; expression of genes related to oxysterols metabolisms in the aortic arch, and the effect of AMPK activation in macrophage on the concentration of oxysterols and expression of genes linked to oxysterols metabolism. Sixteen-week-old male apoE knockout mice fed a chow diet were included in the protocol. Animals were trained in a treadmill running, 15 m/min, 60 min, 5 days/week, during 6 weeks. Plasma lipids and glucose were determined by enzymatic techniques and glycosometer, respectively. Cholesterol in aortic arch and oxysterols were measured by gas chromatography/mass spectrometer. The expression of genes involved in lipid metabolism was determined by RT-qPCR. Results (mean ± SD) were compared by one-way ANOVA with Newman-Keuls posttest or Student\'s t-test. Body weight and plasma total cholesterol, TG, HDL-c, glucose, and oxysterols were similar among groups. The exercise training enhanced 7beta-hydroxycholesterol (70%) and reduced cholesterol (32%) in the aortic arch. In addition, exercise increased Cyp27a1 (54%), Cd36 (75%), cat (70%), Prkaa1 (AMPKalpha1) (40%) and Prkaa2 (AMPKalpha2) (51%) mRNA. No changes were observed in the expression of Abca1, Nr1h3 (LXRalpha) and Nr1h2 (LXRbeta). In macrophages, the activation of AMPK by AICAR, reduced 7beta-hydroxycholesterol level after stimulation by HDL2. Treatment with AICAR increased Abca1 (52%) and Cd36 (220%), decreased Prkaa1 (19%) e Cyp27a1 (47%), and did not change Abcg1, Nr1h3 e Nr1h2. In conclusion, in dyslipidemic mice aerobic exercise training increases the nonenzymatic-driven oxysterol, 7beta-hydroxycholesterol, which is related to the enhanced expression of Cd36. The rapid diffusion of oxysterols, as a complementary pathway for the reverse cholesterol transport, may also be favored by the increase and reduction of Cyp27a1 and Cyp7b1 expressions, respectively, which in turns favors 27-OH C desorption from cells. Together with its direct role in improving reverse cholesterol transport as previously reported, aerobic exercise training diminishes cholesterol accumulation in the arterial wall preventing atherosclerosis. Based on in vitro assays, the AMPK activation does not seem to contribute to the effect of exercise in increasing oxysterols Aerobic exercise training AMPK AMPK Aterosclerose Atherosclerosis Cholesterol efflux Dislipidemia Dyslipidemia Efluxo de colesterol Exercício físico aeróbio Óxidos de colesterol Oxysterol
14	The Role of lysine Acetylation on the Regulation of Phospholipid Homeostasis in Yeast Dacquay, Louis January 2017 (has links) Actively proliferating cells constantly monitor and re-adjust their metabolic pathways to ensure the replenishment of phospholipids necessary for membrane biogenesis and intracellular trafficking. In Saccharomyces cerevisiae, multiple studies have suggested that lysine acetylation has a role in coordinating phospholipid metabolism, yet its contribution towards phospholipid homeostasis remains uncharacterized. In this study we undertook a genetic screen to explore the connection between lysine acetylation and phospholipid homeostasis. We found that mutants of the lysine acetyltransferase complex, NuA4, shared a negative genetic interaction with a mutant of Sec14, a lipid-binding protein that regulates Golgi phospholipid composition. Through transcriptome, genetic, cell biology, and chemical analysis, we discovered that the growth defects between NuA4 and Sec14 mutants is likely derived from impaired fatty acid biosynthesis suggesting a role for NuA4 as a positive regulator of fatty acid biosynthesis. Secondly, we discovered that acetylation on the conserved lysine residue K109 inhibits the localization and function of the Oxysterol-Binding Protein Osh4- a lipid-binding protein that antagonizes the function of Sec14 at the Golgi. Furthermore, regulation of Oxysterol-Binding Proteins by acetylation may be a conserved mechanism as we found that Osh1, a homologue of Osh4, was also acetylated on the equivalent lysine residue. Altogether, we have demonstrated that lysine acetylation can target multiple different phospholipid metabolic pathways which implies that it has a very important role for the regulation of phospholipid homeostasis. Lysine acetylation NuA4 Phospholipids Phospholipid-Binding Proteins Lipid droplet formation Inositol/choline responsive elements Phosphatidylinositol-4-phosphate Oxysterol-Binding Proteins
15	Treinamento físico aeróbio altera seletivamente a concentração e o metabolismo arterial de óxidos de colesterol e reduz colesterol na aorta de camundongos dislipidêmicos / Aerobic exercise training selectively changes oxysterol levels and metabolism reducing cholesterol accumulation in the aorta of dyslipidemic mice Guilherme da Silva Ferreira 04 October 2017 (has links) Os óxidos de colesterol modulam o desenvolvimento da aterosclerose por mediarem a síntese, captação e exportação de colesterol, além de inflamação e citotoxicidade na parede arterial. O exercício físico regular previne e regride a lesão aterosclerótica, por melhorar o perfil lipídico, transporte reverso de colesterol e defesas antioxidantes. A proteína cinase ativada por AMP (AMPK) é um importante mediador dos efeitos metabólicos do exercício físico. Em macrófagos, sua ativação vincula-se ao aumento no efluxo de colesterol e diminuição na captação de LDL. Entretanto, não está claro se o treinamento físico modula as concentrações de óxidos de colesterol, refletindo seu benefício sobre a prevenção da aterosclerose, e se esses efeitos podem ser mediados pela AMPK. O objetivo do presente estudo foi avaliar, em camundongos dislipidêmicos, o papel de 6 semanas de treinamento físico aeróbio sobre: o infiltrado de colesterol arterial e a distribuição de óxidos de colesterol no arco aórtico e no plasma; a expressão gênica de proteínas envolvidas na metabolização de óxidos de colesterol na parede arterial; e o efeito da ativação da AMPK em macrófagos, in vitro, sobre a concentração dos óxidos de colesterol e expressão de genes envolvidos na metabolização de óxidos de colesterol. Para tanto, camundongos machos knockout para apolipoproteína E, com 16 semanas de idade, alimentados com dieta padrão, foram incluídos no estudo. O treinamento físico foi realizado em esteira, 15 m/min, por 60 min, 5 dias/semana, durante 6 semanas. Lípides plasmáticos e glicose foram determinados por ensaio enzimático e glicosímetro, respectivamente, antes e após o treinamento físico. Colesterol arterial e óxidos de colesterol foram avaliados por cromatografia gasosa acoplada à espectrometria de massa. A expressão de genes envolvidos no metabolismo de lípides foi avaliada RT-qPCR. Os resultados foram comparados por ANOVA de um fator com pós-teste de Newman-Keuls ou teste t de Student. Peso corporal, colesterol total, TG, HDL-c, glicose e óxidos de colesterol no plasma foram semelhantes entre os grupos. O treinamento físico aumentou a concentração de 7alfa-OH C (70%) e reduziu a de colesterol (32%) na aorta. Além disso, o exercício físico aumentou a expressão gênica da Cyp27a1 (54%), Cd36 (75%), Cat (70%), Prkaa1 (AMPKalfa1) (40%) e Prkaa2 (AMPKalfa2) (51%) e reduziu Abcg1 (31%), Olr1 (LOX-1) (65%), Cyp7b1 (35%) e Ch25h (48%). Nenhuma alteração foi observada na expressão de Abca1, Nr1h3 (LXRalfa) e Nr1h2 (LXRbeta). Nos macrófagos, a ativação da AMPK por AICAR, reduziu o conteúdo de 7alfa-OH C após estimulo com HDL2. O tratamento com AICAR aumentou a expressão gênica de Abca1 (52%) e Cd36 (220%) e diminuiu Prkaa1 (19%) e Cyp27a1 (47%), e não alterou Abcg1, Nr1h3 e Nr1h2. Em conclusão, em camundongos dislipidêmicos, o treinamento físico aeróbio, por 6 semanas, aumentou a concentração de 7 beta -OH C, o que se vincula à maior expressão de Cd36 no arco aórtico. A rápida difusão de óxidos de colesterol, como via complementar ao transporte reverso de colesterol, pode também ser favorecida pelo aumento e redução, respectivamente, na expressão de Cyp27a1 e Cyp7b1, favorecendo maior liberação de 27-OH C das células. Juntamente com suas ações diretas que beneficiam o transporte reverso de colesterol, previamente descritas o treinamento físico diminui a concentração de colesterol na parede arterial, prevenindo a aterosclerose. Baseado nos ensaios in vitro a ativação da AMPK não parece contribuir para o aumento das concentrações de óxidos de colesterol após treinamento físico / Oxysterols modulate the development of atherosclerosis by mediating cholesterol synthesis, uptake and exportation as well as inflammation and cytotoxicity in the arterial wall. Regular physical exercise prevents and regresses atherosclerosis by improving lipid metabolism, reverse cholesterol transport and antioxidant defenses. AMP-activated protein kinase (AMPK) plays an important role in the beneficial metabolic adaptations of physical exercise. In macrophages, its activation is related to the enhancement in cholesterol efflux and reduction in LDL uptake. However, it is not clear whether exercise training benefits in atherosclerosis is mediated by its action in oxysterols concentrations, and whether this can be modulated by AMPK. The aim of this study was to evaluate the role of a 6-week aerobic exercise training program in dyslipidemic mice in the arterial and plasma accumulation of cholesterol and oxysterols subspecies; expression of genes related to oxysterols metabolisms in the aortic arch, and the effect of AMPK activation in macrophage on the concentration of oxysterols and expression of genes linked to oxysterols metabolism. Sixteen-week-old male apoE knockout mice fed a chow diet were included in the protocol. Animals were trained in a treadmill running, 15 m/min, 60 min, 5 days/week, during 6 weeks. Plasma lipids and glucose were determined by enzymatic techniques and glycosometer, respectively. Cholesterol in aortic arch and oxysterols were measured by gas chromatography/mass spectrometer. The expression of genes involved in lipid metabolism was determined by RT-qPCR. Results (mean ± SD) were compared by one-way ANOVA with Newman-Keuls posttest or Student\'s t-test. Body weight and plasma total cholesterol, TG, HDL-c, glucose, and oxysterols were similar among groups. The exercise training enhanced 7beta-hydroxycholesterol (70%) and reduced cholesterol (32%) in the aortic arch. In addition, exercise increased Cyp27a1 (54%), Cd36 (75%), cat (70%), Prkaa1 (AMPKalpha1) (40%) and Prkaa2 (AMPKalpha2) (51%) mRNA. No changes were observed in the expression of Abca1, Nr1h3 (LXRalpha) and Nr1h2 (LXRbeta). In macrophages, the activation of AMPK by AICAR, reduced 7beta-hydroxycholesterol level after stimulation by HDL2. Treatment with AICAR increased Abca1 (52%) and Cd36 (220%), decreased Prkaa1 (19%) e Cyp27a1 (47%), and did not change Abcg1, Nr1h3 e Nr1h2. In conclusion, in dyslipidemic mice aerobic exercise training increases the nonenzymatic-driven oxysterol, 7beta-hydroxycholesterol, which is related to the enhanced expression of Cd36. The rapid diffusion of oxysterols, as a complementary pathway for the reverse cholesterol transport, may also be favored by the increase and reduction of Cyp27a1 and Cyp7b1 expressions, respectively, which in turns favors 27-OH C desorption from cells. Together with its direct role in improving reverse cholesterol transport as previously reported, aerobic exercise training diminishes cholesterol accumulation in the arterial wall preventing atherosclerosis. Based on in vitro assays, the AMPK activation does not seem to contribute to the effect of exercise in increasing oxysterols AMPK Aterosclerose Dislipidemia Efluxo de colesterol Exercício físico aeróbio Óxidos de colesterol Aerobic exercise training AMPK Atherosclerosis Cholesterol efflux Dyslipidemia Oxysterol
16	Rimonabant Is a Dual Inhibitor of Acyl CoA:Cholesterol Acyltransferases 1 and 2 Netherland, Courtney, Thewke, Douglas P. 01 August 2010 (has links) Acyl coenzyme A:cholesterol acyltransferase (ACAT) catalyzes the intracellular synthesis of cholesteryl esters (CE). Both ACAT isoforms, ACAT1 and ACAT2, play key roles in the pathophysiology of atherosclerosis and ACAT inhibition retards atherosclerosis in animal models. Rimonabant, a type 1 cannabinoid receptor (CB1) antagonist, produces anti-atherosclerotic effects in humans and animals by mechanisms which are not completely understood. Rimonabant is structurally similar to two other cannabinoid receptor antagonists, AM251 and SR144528, recently identified as potent inhibitors of ACAT. Therefore, we examined the effects of Rimonabant on ACAT using both in vivo cell-based assays and in vitro cell-free assays. Rimonabant dose-dependently reduced ACAT activity in Raw 264.7 macrophages (IC50=2.9±0.38μM) and isolated peritoneal macrophages. Rimonabant inhibited ACAT activity in intact CHO-ACAT1 and CHO-ACAT2 cells and in cell-free assays with approximately equal efficiency (IC50=1.5±1.2μM and 2.2±1.1μM for CHO-ACAT1 and CHO-ACAT2, respectively). Consistent with ACAT inhibition, Rimonabant treatment blocked ACAT-dependent processes in macrophages, oxysterol-induced apoptosis and acetylated-LDL induced foam cell formation. From these results we conclude that Rimonabant is an ACAT1/2 dual inhibitor and suggest that some of the atherosclerotic beneficial effects of Rimonabant are, at least partly, due to inhibition of ACAT. atherosclerosis foam cell formation oxysterol-induced apoptosis rimonabant type 1 cannabinoid receptor (CB1) Biomedical Sciences
17	Sterol Transport Protein ORP6 Regulates Astrocytic Cholesterol Metabolism and Brain Aβ Deposition Vijithakumar, Viyashini 07 September 2023 (has links) The mammalian brain is the most cholesterol-rich organ of the body, requiring in situ de novo cholesterol synthesis to maintain its cholesterol requirement. Defects in brain cholesterol homeostasis are implicated in cognitive deficits related to aging and in neurodegenerative diseases such as Alzheimer's Disease (AD). Oxysterol-binding protein (OSBP) - related proteins are highly conserved cytosolic proteins that coordinate lipid homeostasis by regulating cell signaling, inter-organelle membrane contact sites and non-vesicular transport of cholesterol. Previously, ORP6, a poorly characterized member of this family, was found to be part of complex transcriptional cascade coordinated by SBREP2 and emerged as a novel regulator of intracellular cholesterol trafficking in hepatocytes and macrophages. Yet how ORP6 regulates these pathways and its function in the brain where it is most highly expressed is unknown. Here, we show that ORP6 is highly expressed in the brain, where it exhibits spatial and cell-type specific expression. ORP6 expression is enriched in the hippocampus and caudal-putamen brain regions, specifically within neurons and astrocytes. ORP6 knockdown in astrocytes altered the expression of cholesterol biosynthesis, cholesterol efflux and cholesterol esterification genes, resulting in the accumulation of esterified cholesterol within cytoplasmic lipid droplets and reduced cholesterol efflux highlighting a role for ORP6 in astrocytic cholesterol metabolism. We also present in this thesis, the newly generated second viable ORP family member knockout mouse. ORP6 ablation in mice results in the dysregulation of brain and whole-body lipid homeostasis, increased Aβ deposition in the brain and neuroanatomical alterations. Together, our findings highlight a critical role for cholesterol trafficking proteins in brain cholesterol homeostasis and identify ORP6 as a potential novel target for AD. cholesterol transport lipid homeostasis intracellular trafficking Alzheimer's Disease astrocytic cholesterol metabolism cholesterol homeostasis
18	Ação dos oxisteróis nos processos de proliferação e morte das células-tronco mesenquimais derivadas de tecido adiposo / Action of oxysterols in proliferation and death processes of mesenchymal stem cells derived from adipose tissue Silva, Suelen Feitoza 22 March 2017 (has links) As células-tronco mesenquimais são células multipotentes caracterizadas pela capacidade de autorrenovação e diferenciação. Os oxisteróis abrangem um grande grupo heterogêneo derivado do colesterol pela da oxidação enzimática e não enzimática. Os efeitos dos oxisteróis no processo de morte celular, incluindo citotoxicidade e indução de apoptose, foram descritos em diversas linhagens celulares. No entanto, os efeitos dos oxisteróis são pouco conhecidos nas células-tronco mesenquimais. O 7-cetocolesterol (7-KC), um dos mais importantes oxisteróis, foi mostrado ser citotóxico em células-tronco mesenquimais de tecido adiposo. Sendo assim, este estudo descreve os efeitos citotóxicos de curta duração (24 horas) dos oxisteróis colestane-3alfa-5beta-6alfa-triol, 3,5 colestane-7-ona, (3alfa-5beta-6alfa)-colestane-3,6-diol,7-oxocolesterol-5-en-3-beta-il acetato e 5beta-6beta epoxi-colesterol em células-tronco derivadas de tecido adiposo. Os oxisteróis 3,5 colestane-7-ona e 7-oxocolesterol-5-en-3-beta-il acetato não promoveram morte celular e nem afetaram a proliferação celular. Os outros oxisteróis promoveram apoptose, necrose e autofagia, dependendo do tipo de oxisterol e da concentração. O colestane-3alfa-5beta-6alfa-triol foi o mais efetivo. A inibição da proliferação também foi promovida pelos oxisteróis, porém não foi observada alteração no ciclo celular / Mesenchymal stem cells (MSCs) are multipotent cells characterized by self-renewal and cellular differentiation capabilities. Oxysterols comprise a very heterogeneous group derived from cholesterol through enzymatic and non-enzymatic oxidation. Potent effects in cell death processes, including cytoxicity and apoptosis induction, were described in several cell lines. Very little is known about the effects of oxysterols in MSCs. 7-ketocholesterol (7-KC), one of the most important oxysterols, was shown to be cytotoxic to human adipose tissue-derived MSCs. Here, we describe the short-term (24 h) cytotoxic effects of cholestan-3alpha-5beta-6alpha-triol, 3,5 cholestan-7-one, (3alpha-5beta-6alpha)-cholestane-3,6-diol,7-oxocholest-5-en-3-beta-yl acetate, and 5beta-6beta epoxy-cholesterol, on MSCs derived from human adipose tissue. 3,5 cholestan-7-one and 7-oxocholest-5-en-3-beta-yl acetate did not promoted cell death or affect cell proliferation. The other oxysterols led to a complex mode of cell death that could include apoptosis, necrosis and autophagy, depending on the type of oxysterol and concentration. Cholestan-3alpha-5beta-6alpha-triol was the most effective. Inhibition of proliferation was also promoted by these oxysterols, but no changes in cell cycle were observed Adipose tissue Apoptose Apoptosis Cell death Células tronco mesenquimais Hiperpolarização mitocondrial Mesenchymal stem cell Mitochondrial hyperpolarization Morte celular Oxisterol Oxysterol Tecido adiposo
19	Ação dos oxisteróis nos processos de proliferação e morte das células-tronco mesenquimais derivadas de tecido adiposo / Action of oxysterols in proliferation and death processes of mesenchymal stem cells derived from adipose tissue Suelen Feitoza Silva 22 March 2017 (has links) As células-tronco mesenquimais são células multipotentes caracterizadas pela capacidade de autorrenovação e diferenciação. Os oxisteróis abrangem um grande grupo heterogêneo derivado do colesterol pela da oxidação enzimática e não enzimática. Os efeitos dos oxisteróis no processo de morte celular, incluindo citotoxicidade e indução de apoptose, foram descritos em diversas linhagens celulares. No entanto, os efeitos dos oxisteróis são pouco conhecidos nas células-tronco mesenquimais. O 7-cetocolesterol (7-KC), um dos mais importantes oxisteróis, foi mostrado ser citotóxico em células-tronco mesenquimais de tecido adiposo. Sendo assim, este estudo descreve os efeitos citotóxicos de curta duração (24 horas) dos oxisteróis colestane-3alfa-5beta-6alfa-triol, 3,5 colestane-7-ona, (3alfa-5beta-6alfa)-colestane-3,6-diol,7-oxocolesterol-5-en-3-beta-il acetato e 5beta-6beta epoxi-colesterol em células-tronco derivadas de tecido adiposo. Os oxisteróis 3,5 colestane-7-ona e 7-oxocolesterol-5-en-3-beta-il acetato não promoveram morte celular e nem afetaram a proliferação celular. Os outros oxisteróis promoveram apoptose, necrose e autofagia, dependendo do tipo de oxisterol e da concentração. O colestane-3alfa-5beta-6alfa-triol foi o mais efetivo. A inibição da proliferação também foi promovida pelos oxisteróis, porém não foi observada alteração no ciclo celular / Mesenchymal stem cells (MSCs) are multipotent cells characterized by self-renewal and cellular differentiation capabilities. Oxysterols comprise a very heterogeneous group derived from cholesterol through enzymatic and non-enzymatic oxidation. Potent effects in cell death processes, including cytoxicity and apoptosis induction, were described in several cell lines. Very little is known about the effects of oxysterols in MSCs. 7-ketocholesterol (7-KC), one of the most important oxysterols, was shown to be cytotoxic to human adipose tissue-derived MSCs. Here, we describe the short-term (24 h) cytotoxic effects of cholestan-3alpha-5beta-6alpha-triol, 3,5 cholestan-7-one, (3alpha-5beta-6alpha)-cholestane-3,6-diol,7-oxocholest-5-en-3-beta-yl acetate, and 5beta-6beta epoxy-cholesterol, on MSCs derived from human adipose tissue. 3,5 cholestan-7-one and 7-oxocholest-5-en-3-beta-yl acetate did not promoted cell death or affect cell proliferation. The other oxysterols led to a complex mode of cell death that could include apoptosis, necrosis and autophagy, depending on the type of oxysterol and concentration. Cholestan-3alpha-5beta-6alpha-triol was the most effective. Inhibition of proliferation was also promoted by these oxysterols, but no changes in cell cycle were observed Apoptose Células tronco mesenquimais Hiperpolarização mitocondrial Morte celular Oxisterol Tecido adiposo Adipose tissue Apoptosis Cell death Mesenchymal stem cell Mitochondrial hyperpolarization Oxysterol
20	SNFing Glucose to PASs Mitochondrial Dysfunction: The Role of Two Sensory Protein Kinases in Metabolic Diseases Ong, Kai Li 01 July 2019 (has links) Mitochondria is no longer viewed as merely a powerhouse of the cell. It is now apparentthat mitochondria play a central role in signaling, maintaining cellular homeostasis and cell fate.Mitochondrial dysfunction has been linked to many human diseases caused by cellular metabolicderegulation, such as obesity, diabetes, neurodegenerative disease, cardiovascular disease andcancer. Eukaryotic organisms have evolved an efficient way in sensing, communicating andresponding to cellular stress and regulating mitochondrial activity correspondingly through acomplex network of intercommunicating protein kinases and their downstream effectors. Thisdissertation focuses on the interplay of two of the master metabolic regulators in the cell: AMPKand PASK, and characterization of the functions of their downstream substrates: OSBP andMED13. AMPK is an energy sensing kinase that maintains energy homeostasis in the cell,whereas PASK is a nutrient sensing kinase that regulates glucose partitioning and respiration inthe cell. Both kinases play important roles in mitochondrial function and regulation, anddeficiency in either kinase has been found to associate with various human pathologies. Furthercharacterization of the cross-talk and molecular mechanisms of both kinases in controllingmitochondrial health and function may aid in the identification of new targets for treatingmetabolic diseases. mitophagy Life Sciences Molecular Biology

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