Spelling suggestions: "subject:"lipid droplets""
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Mechanisms of lipid droplet formation by conjugated linoleic acid (CLA) isomers and its effects on cell viabilityThiyam, Gayatri 10 January 2011 (has links)
The putative peroxisome proliferator-activated receptor (PPAR) α ligand, conjugated linoleic acid (CLA) induced cytoplasmic lipid droplet (LD) formation in H4IIE rat hepatoma cells. Currently, the mechanism(s) by which CLA isomers affects hepatic LD formation is unclear. We have investigated the role of PPARα and fatty acid (FA) activation in the regulation of hepatic LD formation induced by CLA isomers [cis-9,trans-11 (c9,t11), trans-10,cis-12 (t10,c12)] and linoleic acid (LA) in an in vitro model of lipid accumulation. Dose response of c9,t11 and t10,c12 CLA isomers as well as LA in quiescent H4IIE cells was assessed by Oil Red O staining and subsequent quantification after 24 hours. LD formation was induced by the CLA isomers similar to LA in a dose-dependent manner. However, treatment with the acyl CoA synthetase (ACS) inhibitor, triacsin C, resulted in significantly reduced LD formation. A similar reduction in lipid accumulation was observed with the PPARα activator, Wy14643. Furthermore, CLA isomers promoted H4IIE viability at 60 µM but decreased viability at a higher dose of 180 µM.
To further understand the role of PPARα in hepatic steatosis, we studied the level and phosphorylation of PPARα in livers of male lean and fa/fa Zucker rats fed either a control diet or fa/fa Zucker rats fed a CLA isomer (0.4% wt/wt c9,t11 or 0.4% wt/wt t10,c12) diet for 8 weeks. Immunoblotting results showed that only the t10,c12 CLA isomer significantly reduced phospho-PPARα S21 compared to the lean control (ln Ctl) and it was associated with a significant increase in the phosphorylation of p38 mitogen activated protein kinase (MAPK).These changes were not observed with the c9,t11 CLA isomer.
Taken together, we have shown that CLA isomers directly induce LD formation in quiescent H4IIEs by activation of the lipid storage pathway which was significantly reduced by triacsin C or Wy14643. Also, we demonstrate for the first time that only the t10,c12 CLA isomer significantly reduced PPARα phosphorylation while it increased p38 MAPK phosphorylation. These results indicate that the anti-steatotic effects of the t10,c12 CLA isomer is associated with changes in PPARα phosphorylation and thereby its activity in a MAPK-independent manner.
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Defining an Intracellular Role of Hepatic Lipase in the Formation of Very Low Density Lipoproteins and High Density LipoproteinsBamji-Mirza, Michelle January 2011 (has links)
Hepatic lipase (HL) plays a pivotal role in the catabolism of apolipoprotein (apo)B-containing lipoproteins and high density lipoprotein (HDL) particles through its reported catalytic and non-catalytic extracellular functions. The current study tested the hypothesis that HL expression might impair formation and secretion of hepatic derived very low density lipoproteins (VLDL) and apoA-I (nascent HDL). Stable or transient expression of human HL (hHL) in McA-RH7777 cells resulted in decreased incorporation of [3H]glycerol into cell-associated and secreted (VLDL-associated) 3H-triacylglcyerol (TAG) relative to control cells. Stable expression of catalytically-inactive hHL (hHLSG) also resulted in decreased secretion of VLDL-associated 3H-TAG whereas cell-associated 3H-TAG levels were unchanged. Expression of hHL or hHLSG increased cell-associated 35S-apoB100 with relatively no change in secreted 35S-apoB100. Importantly, hHL or hHLSG expression resulted in reduced 3H-TAG associated with the microsomal lumen
lipid droplets (LLD), and increased relative expression of ApoB and genes involved in lipogenesis and fatty acyl oxidation. Transient expression of hHL in HL-null primary hepatocytes, mediated by adenoviral gene transfer, resulted in decreased steady-state
levels of cell-associated and secreted apoA-I and reduced rates of synthesis and secretion
of 35S-apoA-I. HL-null hepatocytes exhibited increased levels of secreted 35S-apoA-I relative to wildtype hepatocytes while cell-associated 35S-apoA-I levels were normal.
Transient expression of a hHL chimera (hHLmt), in which the C-terminus of hHL was replaced with mouse HL sequences, exerted an inhibitory effect on apoA-I production similar to that of hHL even though hHLmt was secreted less effectively than hHL with impaired exit from the endoplasmic reticulum (ER) as compared with hHL. In contrast, stable expression of hHL in McA-RH7777 cells resulted in a dose-dependent increase in cell-associated and secreted 35S-apoA-I levels. These studies demonstrate that hHL has an intracellular (but non-catalytic) role in reducing the content of the LLD and ultimately the buoyancy of secreted VLDL particles, and that the N-terminal sequences of ER-residing hHL directly or indirectly modulates the production and secretion of apoA-I (nascent HDL) from hepatocytes.
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Protein aggregation in the cytoplasmAmen, Triana 28 April 2021 (has links)
No description available.
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Homologs of Mammalian Lysosomal Lipase in Arabidopsis and Their Roles in Lipid Droplet DynamicsMcClinchie, Elizabeth A 12 1900 (has links)
Lipid droplets (LDs) are organelles with many functions in cells and numerous protein interactors facilitate their biogenesis, maintenance, and turnover. The mammalian lipase responsible for LD turnover during lipophagy, LipA, has two candidate homologs in Arabidopsis: MPL1 and LIP1. One or both of these plant homologs may function in a similar manner to mammalian LipA, providing an LD breakdown pathway. To test this hypothesis, wild type (WT) Arabidopsis plants, MPL1 over-expressing (OE) mutants, and T-DNA insertion mutants of MPL1 (mpl1) and LIP1 (lip1) were examined for LD phenotypes in normal conditions and in environments where LD numbers are known to fluctuate. Plants to be imaged by confocal microscopy were exposed to heat stress and wounding to increase LD accumulation, senescence was induced in leaves to deplete lipids, and LDs were imaged throughout the day/night period to observe their diurnal regulation. The mutation of both MPL1 and LIP1 lead to an increase in LDs within the leaf mesophyll cells, although the spatial distribution of the LDs differed between the two mutants. mpl1 mutants had disrupted diurnal regulation of their LDs, but lip1 mutants did not. Alternately, lip1 mutants retained LDs during dark-induced senescence, and mpl1 mutants did not. Together these results suggest that MPL1 and LIP1 are likely both important for LD dynamics; however they appear have roles in different aspects of LD accumulation and turnover.
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Mathematische Modellierung der Dynamik von Lipidtropfen in LeberzellenWallstab, Christin 03 April 2017 (has links)
Diese Dissertation befasst sich mit der Dynamik von Lipidtropfen (LDs), die der Speicherung von Lipiden (hauptsächlich Triacylglycerol, TAG) dienen. Das epidemische Auftreten von Adipositas und der sogenannten Fettleber (Steatose) hat das wissenschaftliche Interesse an der Regulation der zellulären Speicherung in LDs stark beflügelt. Es gibt inzwischen zahlreiche Publikationen zu einzelnen Aspekten der Bildung, des Wachstums und des Abbaus von Lipidtropfen. Ein detailliertes mathematisches Modell, das diese Einzelergebnisse in ein konsistentes Bild zusammenfügt, gibt es allerdings nicht. Die Aufstellung, Validierung und Anwendung eines umfassenden mathematischen Modells der Dynamik von LDs steht daher im Mittelpunkt dieser Arbeit. Dieses Modell umfasst unter anderem die Aufnahme von freien Fettsäuren aus dem Blutplasma, die Veresterung zu TAG, die Bildung, das Wachstum und die Lipolyse von Lipidtropfen, die durch etliche regulatorische Oberflächenproteine (ROPs) gesteuert werden. Eine wesentliche Frage im Zusammenhang mit der Entstehung einer Fettleber gilt den Mechanismen, die den heterogenen Fetteinlagerungen in der Leber zugrunde liegen. Eigene Experimente mit humanen Hepatomzellen (PLC) zeigten, dass eine Heterogenität in der TAG-Speicherung auch in isolierten Zellen existiert, wenn man sie einer Fettsäurebelastung unterwirft. Modellsimulationen zeigen, dass Schwankungen in der Expression zentraler regulatorischer Proteine bereits eine Heterogenität bis zu 50% erklären können. Unter der Annahme, dass eine solche Variabilität der Genexpression auch im intakten Organ vorliegt, prognostiziert das Modell eine Variation im TAG-Gehalt einzelner Zellen um einen Faktor drei bis sechs. Zusammenfassend ist zu sagen, dass der Modellansatz zahlreiche experimentelle Ergebnisse von einzelnen Prozessen im zellulären TAG-Metabolismus und im Metabolismus der LD-Dynamik in ein konsistentes, neuartiges und dynamisches Modell eines metabolischen Netzwerks integriert. / This dissertation occupies with the dynamics of lipid droplets (LDs) serving as lipid deposit transporting, mainly triacylglycerol (TAG). The epidemic occurrence of obesity and steatosis has inspired strongly the scientific interest in regulation of hepatic TAG accumulation. There are now numerous publications regarding individual aspects of formation, maturation and lipolysis of LDs. However, a detailed computational model putting together this fractional knowledge is lacking so far. I focus on development, validation and implementation a kinetic model encompassing the pathways of the fatty acids (FFA) and TAG metabolism and the main molecular processes governing the dynamics of LDs. Experiments with primary human hepatocytes incubated with an excess of FFA show a large heterogeneity of TAG content and LD size distribution. Intriguingly, a large cell-to-cell heterogeneity with respect to the number and size of LDs has been found in various cell types. These findings suggest that the extent of cellular lipid accumulation is not only determined by the imbalance between lipid supply and utilization but also by variations in the expression of regulatory surface proteins and metabolic enzymes. To better understand the relative regulatory impact of individual processes involved in the cellular TAG turnover we varied randomly the expression of RSPs and metabolic enzymes. A random fold change by a factor of about 2 in the activity of RSPs was sufficient to reproduce the large diversity of droplet size distributions. Under the premise that the same extent of variability of RSPs holds for the intact organ, our model predicts variations in the TAG content of individual hepatocytes by a factor of about three to six depending on the nutritional regime. Taken together, our modeling approach integrates numerous experimental findings on individual processes in the cellular TAG metabolism and LD dynamics metabolism to a consistent state-of-the-art dynamic network model.
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The Role of lysine Acetylation on the Regulation of Phospholipid Homeostasis in YeastDacquay, 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.
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Der Einfluss von Repin1 auf die Fettzellgröße und den Glukosetransport in AdipozytenIlles, Monica 10 January 2012 (has links) (PDF)
An der Spitze der Morbiditäts - und Mortalitätsstatistik steht weltweit das
Metabolische Syndrom, bestehend aus androider Adipositas, pathologischer
Glukosetoleranz, Dyslipidämie und arterieller Hypertonie, verbunden mit einer
erhöhten Inzidenz atherosklerotischer Gefäßerkrankungen. Der Replikationsinitiator
1 (Repin1) wurde kürzlich als mögliches Kandidatengen für Adipositas sowie damit
verbundene metabolische Funktionsstörungen in kongenen sowie subkongenen
Rattenstämmen identifiziert. Ziel der Arbeit war es, den Einfluss von Repin1 auf den
Fettzellstoffwechsel zu untersuchen. Hierfür wurde die Expression von Repin1 in 3T3–
L1 Präadipozyten und differenzierten 3T3-L1 Adipozyten mittels siRNA Technologie
stark vermindert, um so auf mögliche Funktionen des Proteins schließen zu können.
Nachfolgend wurden Veränderungen des Zellstoffwechsels mittels Glukosetransport,
Palmitataufnahme sowie Triglyceridgehalt der Adipozyten untersucht.
Repin1 wird in der 3T3-L1 Zelllinie exprimiert und zeigt eine steigende Expression
während der Adipogenese. Der Knockdown von Repin1 resultierte in kleineren
Fettzellen mit geringerer basaler, jedoch verstärkter insulinstimulierter
Glukoseaufnahme. Auch der Fettstoffwechsel zeigte sich alteriert: Neben einer
reduzierten Palmitataufnahme war die Expression verschiedener Schlüsselgene der
Fetttropfenfusion, des Glukose-sowie des Fetttransportes verändert.
Fazit: Repin1 reguliert die Expression von Genen, die eine Rolle bei der Festlegung der
Fettzellgröße und des basalen und Insulin-stimulierten Glukosetransports in
Adipozyten spielen.
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Lipogenic Proteins in Plants: Functional Homologues and ApplicationsCai, Yingqi 12 1900 (has links)
Although cytoplasmic lipid droplets (LDs) are the major reserves for energy-dense neutral lipids in plants, the cellular mechanisms for packaging neutral lipids into LDs remain poorly understood. To gain insights into the cellular processes of neutral lipid accumulation and compartmentalization, a necessary step forward would be to characterize functional roles of lipogenic proteins that participate in the compartmentalization of neutral lipids in plant cells. In this study, the lipogenic proteins, Arabidopsis thaliana SEIPIN homologues and mouse (Mus Musculus) fat storage-inducing transmembrane protein 2 (FIT2), were characterized for their functional roles in the biogenesis of cytoplasmic LDs in various plant tissues. Both Arabidopsis SEIPINs and mouse FIT2 supported the accumulation of neutral lipids and cytoplasmic LDs in plants. The three Arabidopsis SEIPIN isoforms play distinct roles in compartmentalizing neutral lipids by enhancing the numbers and sizes of LDs in various plant tissues and developmental stages. Further, the potential applications of Arabidopsis SEIPINs and mouse FIT2 in engineering neutral lipids and terpenes in plant vegetative tissues were evaluated by co-expressing these and other lipogenic proteins in Nicotiana benthamiana leaves. Arabidopsis SEIPINs and mouse FIT2 represent effective tools that may complement ongoing strategies to enhance the accumulation of desired neutral lipids and terpenes in plant vegetative tissues. Collectively, our findings in this study expand our knowledge of the broader cellular mechanisms of LD biogenesis that are partially conserved in eukaryotes and distinct in plants and suggest novel targets that can be introduced into plants to collaborate with other factors in lipid metabolism and elevate oil content in plant tissues.
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Descrição histológica e ultra-estrutural da absorção de óleo de soja pelo intestino do jacaré do pantanal (Caiman yacare, Daudin, 1802). / Histological and ultrastructural description of soybean oil absorption by the intestine of the jacaré do pantanal (Caiman yacare, Daudin, 1802).Borges, Ricardo Moraes 12 September 2014 (has links)
O cultivo de Caiman yacare demanda grandes gastos com alimentação, deste modo, é necessário formular dietas mais baratas e mais eficientes para a engorda destes animais. Uma possibilidade de redução nos custos é o acréscimo de lipídeos de origem vegetal. Neste trabalho, analisou-se o processo de absorção de óleo de soja pelo intestino de Caiman yacare para avaliar possíveis alterações patológicas pelo uso deste óleo na mucosa intestinal de um animal carnívoro. A absorção de óleo de soja ocorreu massiçamente pelo intestino delgado, gerando esteatose intestinal temporária e formando quilomícrons pequenas, que foram transportadas pelo sistema linfático. Outros parâmetros que indicam ausência de patologias na mucosa intestinal, como alteração na proliferação celular, lesão tecidual, recrutamento de granulócitos, formação de heterófilos tóxicos e degranulação de mastócitos, não foram alterados, indicando o potencial uso de óleo de soja na dieta de Caiman yacare. / Cultivation of Caiman yacare demands large financial expenditures on food, so it is desirable to reduce costs by formulating cheaper and more efficient feedings. The soybean oil addition in the diet is an opportunity to reduce spending, but very little is known about the effects of vegetable-origin oils in this carnivore species health. Here we describe the process of soybean oil absorption by the intestine of Cayman yacare in order to evaluate possible intestinal pathologies caused by the soybean oil. Soybean oil absorption occurred massively across the intestine, caused temporary intestinal steatosis and produced small-sized chylomicrons that were carried away from the intestine by the lymphatics. Some mucosal integrity parameters analyzed such as enterocyte proliferation, epithelial damage, granulocyte recruitment, toxic heterophil formation and mast cell degranulation were not altered, suggesting soybean oil may potentially be used in Caiman yacare feedings.
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Lipides et trafic : rôles de GBF1, facteur d’échange de la petite protéine G Arf1 / Lipids and Traffic : roles of the large Arf1-GEF GBF1Bouvet, Samuel 20 September 2013 (has links)
La cellule eucaryote compartimentalise ses tâches au sein d’organelles communiquant les unes avec les autres au moyen de vésicules de transport. Le trafic vésiculaire est contrôlé par des petites protéines G de la superfamille Ras, activées par un changement de nucléotide guanidique catalysé par un facteur d’échange (GEF). En particulier, au niveau du cis-Golgi la petite protéine G Arf1 est activée par GBF1, permettant le transport rétrograde des vésicules COPI vers le réticulum endoplasmique. Récemment, GBF1 a été impliqué dans d’autres fonctions, notamment dans le cycle réplicatif de certains virus ou dans le métabolisme des gouttelettes lipidiques.Les gouttelettes lipidiques sont les organelles ubiquitaires du stockage des lipides et ont un rôle majeur dans l’homéostasie des lipides à l’échelle de la cellule. Le trafic intracellulaire des ces organelles dynamiques serait contrôlé par des petites protéines G. Notre équipe à montré dans une précédente étude que GBF1 est localisé sur les gouttelettes lipidiques et est impliqué dans le recrutement de PLIN2 et de la lipase ATGL sur les gouttelettes lipidiques. Cette thèse montre, par des études de biologie cellulaire et de microscopie, que GBF1 possède un domaine de fixation aux phospholipides via une hélice amphipatique. Cette hélice est nécessaire et suffisante pour l’association aux gouttelettes lipidiques in cellulo. La régulation de la localisation de GBF1 repose sur l’interaction avec Rab1B (cascade entre Rab1 et Arf1 dans la voie sécrétoire précoce) ainsi que sur les interactions intramoléculaires entre les différents domaines de GBF1. / The eukaryotic cell physically separates its functions within several membrane-bound organelles, which communicate using vesicles. Vesicular trafficking is under the control of small GTPases that exist as an inactive GDP-bound form and an active GTP-bound form. The switch between GDP and GTP is catalyzed by a guanine nucleotide exchange factor (GEF). On cis-Golgi membranes, Arf1, activated by the large GEF GBF1, recruits the COPI coat. COPI coated vesicles ensure the retrograde transport from the Golgi to the ER. Recently, GBF1 has been implicated in other pathways, such as the life cycle of various viruses and lipid droplet metabolism.Lipid droplets (LD), the major lipid storage organelle, play a major role in lipid homeostasis within the cell. LDs are connected to membrane trafficking and are therefore under the control of GTPases. In previous studies, our team showed that GBF1 localizes around LDs and that it is required for protein loading onto the LD surface. Here, data support the idea that GBF1 localizes to the LD surface. Using cell biology tools and microscopy, we identified, within GBF1, a lipid binding domain. In this domain, a single amphipathic helix is necessary and sufficient for LD targeting in cells. The regulation of GBF1 localization relies on interaction with Rab1 (data support a Rab1-Arf1 cascade between the ER and the Golgi) and on intramolecular interactions between GBF1 domains.
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