Spelling suggestions: "subject:"rottlerin"" "subject:"rottlerine""
1 |
Étude fonctionnelle d'inhibiteurs de kinases réprimant la réplication du virus de la rage / Functional study of kinase inhibitors repressing rabies virus replicationLama, Zoé 11 December 2017 (has links)
Alors que les étapes du cycle du virus de la rage sont plutôt bien décrites, les interactions du virus avec la machinerie cellulaire restent mal connues. Le but de ce projet de thèse a été d’identifier et caractériser les voies de signalisation cellulaires impliquées dans le déroulement du cycle viral. Les kinases cellulaires jouent un rôle majeur dans la régulation de ces voies et certaines protéines rabiques ont déjà été décrites comme cibles de ces enzymes. Afin d’identifier les kinases impliquées dans le déroulement du cycle viral, nous avons réalisé un criblage d’une banque d’inhibiteur de kinases. L’analyse a été effectuée par cytométrie en flux dans des cellules infectées avec un virus rabique recombinant exprimant la protéine fluorescente GFP. Nous avons ainsi pu isoler deux inhibiteurs de kinases bloquant l’infection : La Tyrphostin 9,un inhibiteur de l’autophosphorylation du récepteur au PDGF (platelet-derived growth factor) (PDGF.R), et la Rottlerin, un inhibiteur de la PKCδ et découplant mitochondrial. Nous avons confirmé leur activité anti-virale dans différents types cellulaires (fibroblaste, glioblastome,neuroblastome et neurones primaires) et sur deux souches rabiques (CVS et SAD-B19). Par diverses approches expérimentales, nous avons identifié l’étape du cycle viral ciblée par chacun de ces inhibiteurs. Les résultats obtenus montrent que la Tyrphostin 9 perturbe une étape très précoce de l’infection : la fusion virale et plus particulièrement l’acidification endosomale. Nous avons observé que la Tyrphostin 9 provoquait également une désagrégation de l’appareil de Golgi. L’inhibition de l’acidification endosomale pourrait donc découler de cet effet. En présence de Rottlerin, le cycle viral est également inhibé au niveau d’une étape précoce : la réplication. A l’aide de siRNA, nous avons montré que cet effet de la Rottlerin est indépendant de la PKCδ. Les expériences réalisées avec un découplant mitochondrial bien caractérisé, le CCCP, tendent à montrer que l’effet de la Rottlerin est dû à sa fonction de découplant mitochondrial, qui induit une diminution du niveau d’ATP intracellulaire. Ce travail a permis d’identifier deux inhibiteurs de kinases inhibant des étapes précoces du cycle rabique. Les cibles cellulaires précisément impactées ainsi que l’effet sur le fonctionnement cellulaire lors de l’infection virale restent à déterminer. Des études in vivo pourraient valider leur utilisation en tant qu’agents antiviraux. / However the rabies viral cycle is fairly well described, the interactions with the cellular machinery are not. This thesis project aimed at identifying and characterizing the cellular signaling pathways involved in the establishment and progress of the viral cycle through the study of cellular kinases. Indeed, kinases are the main actors of these pathways and their effects on certain rabies proteins have already been reported. In order to identify kinases involved in the viral cycle, we screened a kinase inhibitor library for anti-viral activity using a recombinant rabies virus expressing the GFP fluorescent protein. This assay allowed us to isolate two kinase inhibitors that block rabies virus infection: Tyrphostin 9, an inhibitor of the receptor tyrosine kinase platelet-derived growth factor receptor (PDGF.R), and Rottlerin, a PKCδ inhibitor and mitochondrial uncoupler. We confirmed their anti-viral action in different cell types (fibroblast, glioblastoma, neuroblastoma, as well as primary neurons) and on different rabies strains (CVS and SAD-B19). Using various experimental approaches, we found that each inhibitor impairs an early stage of the viral cycle: the viral fusion and more specifically the endosomal acidification by Tyrphostin 9 and the viral replication step by Rottlerin. We observed that Tyrphostin 9 also caused disintegration of the Golgi apparatus. The inhibition of endosomal acidification could therefore result from this effect. Seeking for the mechanisms involved in Rottlerin’s effect, we evidenced that it is independent of PKCδ. Experiments with a well characterized mitochondrial uncoupler (CCCP), revealed that the Rottlerin anti-viral effect is rather due to its mitochondrial uncoupling function, which leads to a decrease of the cellular ATP level. This study allowed the identification of two kinase inhibitors with anti-viral effects acting on early stages of the rabies cycle. The cellular targets as well as the effect on the cellular functions during viral infection remain to be determined. In vivo studies could validate their use in therapeutics as anti-rabies agents.
|
2 |
Novel insights into MACC1 transcriptional regulation for identifying small molecule MACC1 inhibitors to restrict colorectal cancer progressionJuneja, Manisha 09 October 2014 (has links)
MACC1 wurde als prognostischer Biomarker für die Tumorprogression und das Metastasen-freie Überleben im KRK sowie in anderen soliden Tumoren beschrieben. Das Gen induziert Zellmotilität und Proliferation in Zellkultur sowie die Metastasierung im Mausmodell. Damit stellt MACC1 ein vielversprechendes Ziel für die Intervention bei Tumorprogression und –metastasierung und damit für die Behandlung von KRK-Patienten dar. Unser Ziel war es, die Transkription von MACC1 zu inhibieren. Hierfür identifizierten wir zunächst die Promoter-Region von MACC1 und untersuchten MACC1s transkriptionelles Regulationsnetzwerk. Durch ortsgerichtete Mutagenese, Chromatin Immunopräzipitation und Electrophoretic Mobility Shift Assay ermittelten wir, dass Transkriptionsfaktoren wie Ap-1, Sp1, C/EBPs und GIPC1 an den MACC1-Promoter binden und die Transkription des MACC1-Gens kontrollieren. Darüberhinaus konnten wir durch Hochdurchsatz-Screening die bisher ersten Inhibitoren gegen MACC1 identifizieren: Rottlerin und Lovastatin. Wir zeigten, dass diese spezifisch auf den endogenen MACC1-Promoter wirken, was eine zeit- und konzentrationsabhängige Reduktion der MACC1-Expression zur Folge hatte. Beide Inhibitoren begrenzten das Expressionsniveau von Sp1 und interferierten mit der Bindung von c-Jun mit dem MACC1-Promoter, was in einer Inhibition der MACC1-Transkription resultierte. Ferner führte die tägliche Behandlung von Xenograft-Mausmodellen mit Rottlerin zu einer Inhibition der MACC1-Expression im Primärtumor und einer damit einhergehenden Begrenzung des Tumorwachstums. Zusammenfassend lässt sich festhalten, dass in der vorliegenden Arbeit zum ersten Mal der MACC1-Promoter und seine transkriptionelle Regulation beleuchtet wurden. Die neuen Erkenntnisse wurden zur Identifizierung der ersten Inhibitoren gegen MACC1 genutzt. Zur Behandlung von KRK-Patienten mit einem hohen Risiko für MACC1-induzierte Metastasierung könnten diese Inhibitoren Potential für die klinische Anwendung beherbergen. / MACC1 has been reported as a prognostic biomarker for tumor progression and metastasis-free survival in CRC along with other solid tumors. It induces cell motility and proliferation in cell culture and metastasis in mouse models. Consequently, targeting MACC1 to intervene in tumor progression and metastasis formation holds a promising approach to treat CRC patients. We designed a strategy to inhibit MACC1 via targeting its transcription. We first identified MACC1 gene promoter by creating various promoter-luciferase constructs. We then established that transcription factors such as Ap-1, Sp1, C/EBPs and GIPC1 bind to the MACC1 promoter and govern MACC1 transcription, expression and thus motility in vitro and in CRC patients. Using a high throughput screening targeting the MACC1 promoter, we identified small molecule MACC1 inhibitors, Rottlerin and Lovastatin. These inhibitors specifically restricted endogenous MACC1 promoter leading to reduced MACC1 expression in a time- and concentration-dependent manner. In vitro functional assays demonstrated the impact of the small molecule inhibitors on retarding cell proliferation and motility. Both inhibitors restricted Sp1 levels and interfered with the binding of c-Jun to the MACC1 promoter, thereby inhibiting MACC1 transcription. The study further described the effect of Rottlerin on a CRC-xenografted mouse model. Daily treatment of xenografted mice with Rottlerin resulted in the inhibition of MACC1 expression in the primary tumor accompanied with the restricted tumor growth. To summarize, this is the first study unraveling the MACC1 promoter, its transcriptional regulation and identification of newly identified MACC1 inhibitors. In clinical settings, inhibition of MACC1 expression using these inhibitors might provide immense potential for the treatment of CRC patients who are at high risk for MACC1-induced metastasis linked to shorter survival.
|
3 |
Energy metabolism in the brain and rapid distribution of glutamate transporter GLAST in astrocytesNguyen, Khoa Thuy Diem January 2008 (has links)
Doctor of Philosophy (Medicine) / Glutamate transporters play a role in removing extracellular excitatory neurotransmitter, L-glutamate into the cells. The rate of the uptake depends on the density of the transporters at the membrane. Some studies claimed that glutamate transporters could transit between the cytoplasm and the membrane on a time-scale of minutes. The present study examined the distribution of glutamate transporter GLAST predominantly expressed in rat cortical cultured astrocytes between the membrane and the cytoplasm by using deconvolution microscopy and then analyzing the images. The regulation of the distribution of GLAST was studied in the presence of glutamate transporter substrate (D-aspartate), purinergic receptor activators (α,β-methylene ATP, adenosine), neuroleptic drugs (clozapine, haloperidol), ammonia (hyperammonia) and Na+/K+-ATPase inhibitors (ouabain, digoxin and FCCP). It was demonstrated that the translocation of GLAST towards the plasma membrane was induced by D-aspartate, α,β-methylene ATP, adenosine, clozapine and ammonia (at 100 μM and very high concentrations of 10 mM). However, the inhibition of Na+/K+-ATPase activity had an opposite effect, resulting in redistribution of GLAST away from the membrane. It has previously been claimed that the membrane-cytoplasm trafficking of GLAST was regulated by phosphorylation catalysed by protein kinase C delta (PKC-delta). Involvement of this mechanism has, however, been put to doubt when rottlerin, a PKC-delta inhibitor, used to test the hypothesis showed to inhibit Na+/K+-ATPase-mediated uptake of Rb+, suggesting that rottlerin influenced the activity of Na+/K+-ATPase. As Na+/K+-ATPase converts ATP to energy and pumps Na+, K+ ions, thus helping to maintain normal electrochemical and ionic gradients across the cell membrane. Its inhibition also reduced D-aspartate transport and could impact on the cytoplasm-to-membrane traffic of GLAST molecules. Furthermore, rottlerin decreased the activity of Na+/K+-ATPase by acting as a mitochondrial inhibitor. The present study has focused on the inhibition of Na+/K+-ATPase activity by rottlerin, ouabain and digoxin in homogenates prepared from rat kidney and cultured astrocytes. The activity of Na+/K+-ATPase was measured by the absorption of inorganic phosphate product generated from the hydrolysis of ATP and the fluorescent transition of the dye RH421 induced by the movement of Na+/K+-ATPase. This approach has a potential to test whether the rottlerin effect on Na+/K+-ATPase is a direct inhibition of the enzyme activity. Rottlerin has been found to block the activity of Na+/K+-ATPase in a dose-dependent manner in both rat kidney and astrocyte homogenates. Therefore, rottlerin inhibited the activity of Na+/K+-ATPase directly in a cell-free preparation, thus strongly indicating that the effect was direct on the enzyme. In parallel experiments, ouabain and digoxin produced similar inhibitions of Na+/K+-ATPase activity in rat kidney while digoxin blocked the activity of Na+/K+-ATPase to a greater extent than ouabain in rat cortical cultured astrocytes. In a separate set of experiments, Na+/K+-ATPase in the astrocytic membrane was found to be unsaturated in E1(Na+)3 conformation in the presence of Na+ ions and this could explain the differences between the effects of digoxin and ouabain on the activity of Na+/K+-ATPase in rat astrocytes. In addition, it was found that at low concentrations of rottlerin, the activity of Na+/K+-ATPase was increased rather than inhibited. This effect was further investigated by studying rottlerin interactions with membrane lipids. The activity of Na+/K+-ATPase has been reported to be regulated by membrane lipids. The enzyme activity can be enhanced by increasing fluidity of the lipid membrane. I have, therefore, proposed that rottlerin binds to the membrane lipids and the effects of rottlerin on Na+/K+-ATPase are mediated by changes in the properties (fluidity) of the membrane. The hypothesis was tested by comparing rottlerin and a detergent, DOC (sodium deoxycholate), for their binding to the lipids by using a DMPC (1,2-Dimyristoyl-sn-Glycero-3-Phosphocholine) monolayer technique. DOC has been shown to both increase and inhibit activity of Na+/K+-ATPase in a manner similar to that displayed by rottlerin. The effects of rottlerin and DOC on the DMPC monolayers were studied by measuring the surface pressure of DMPC monolayers and surface area per DMPC molecule. I established that both rottlerin and DOC decreased the surface pressure of DMPC monolayers and increased the surface area per DMPC molecule. This indicates that both rottlerin and DOC penetrated into the DMPC monolayers. If rottlerin can interact with the lipids, changes in fluidity of the lipid membrane cannot be ruled out and should be considered as a possible factor contributing to the effects of rottlerin on the activity of Na+/K+-ATPase. Overall, the study demonstrates that rottlerin is not only a PKC-delta inhibitor but can have additional effects, both on the enzyme activities (Na+/K+-ATPase) and/or on lipid-containing biological structures such as membranes. The findings have implication not only for studies where rottlerin was used as a supposedly specific PKC-delta inhibitor but also for mechanisms of its toxicity.
|
4 |
Energy metabolism in the brain and rapid distribution of glutamate transporter GLAST in astrocytesNguyen, Khoa Thuy Diem January 2008 (has links)
Doctor of Philosophy (Medicine) / Glutamate transporters play a role in removing extracellular excitatory neurotransmitter, L-glutamate into the cells. The rate of the uptake depends on the density of the transporters at the membrane. Some studies claimed that glutamate transporters could transit between the cytoplasm and the membrane on a time-scale of minutes. The present study examined the distribution of glutamate transporter GLAST predominantly expressed in rat cortical cultured astrocytes between the membrane and the cytoplasm by using deconvolution microscopy and then analyzing the images. The regulation of the distribution of GLAST was studied in the presence of glutamate transporter substrate (D-aspartate), purinergic receptor activators (α,β-methylene ATP, adenosine), neuroleptic drugs (clozapine, haloperidol), ammonia (hyperammonia) and Na+/K+-ATPase inhibitors (ouabain, digoxin and FCCP). It was demonstrated that the translocation of GLAST towards the plasma membrane was induced by D-aspartate, α,β-methylene ATP, adenosine, clozapine and ammonia (at 100 μM and very high concentrations of 10 mM). However, the inhibition of Na+/K+-ATPase activity had an opposite effect, resulting in redistribution of GLAST away from the membrane. It has previously been claimed that the membrane-cytoplasm trafficking of GLAST was regulated by phosphorylation catalysed by protein kinase C delta (PKC-delta). Involvement of this mechanism has, however, been put to doubt when rottlerin, a PKC-delta inhibitor, used to test the hypothesis showed to inhibit Na+/K+-ATPase-mediated uptake of Rb+, suggesting that rottlerin influenced the activity of Na+/K+-ATPase. As Na+/K+-ATPase converts ATP to energy and pumps Na+, K+ ions, thus helping to maintain normal electrochemical and ionic gradients across the cell membrane. Its inhibition also reduced D-aspartate transport and could impact on the cytoplasm-to-membrane traffic of GLAST molecules. Furthermore, rottlerin decreased the activity of Na+/K+-ATPase by acting as a mitochondrial inhibitor. The present study has focused on the inhibition of Na+/K+-ATPase activity by rottlerin, ouabain and digoxin in homogenates prepared from rat kidney and cultured astrocytes. The activity of Na+/K+-ATPase was measured by the absorption of inorganic phosphate product generated from the hydrolysis of ATP and the fluorescent transition of the dye RH421 induced by the movement of Na+/K+-ATPase. This approach has a potential to test whether the rottlerin effect on Na+/K+-ATPase is a direct inhibition of the enzyme activity. Rottlerin has been found to block the activity of Na+/K+-ATPase in a dose-dependent manner in both rat kidney and astrocyte homogenates. Therefore, rottlerin inhibited the activity of Na+/K+-ATPase directly in a cell-free preparation, thus strongly indicating that the effect was direct on the enzyme. In parallel experiments, ouabain and digoxin produced similar inhibitions of Na+/K+-ATPase activity in rat kidney while digoxin blocked the activity of Na+/K+-ATPase to a greater extent than ouabain in rat cortical cultured astrocytes. In a separate set of experiments, Na+/K+-ATPase in the astrocytic membrane was found to be unsaturated in E1(Na+)3 conformation in the presence of Na+ ions and this could explain the differences between the effects of digoxin and ouabain on the activity of Na+/K+-ATPase in rat astrocytes. In addition, it was found that at low concentrations of rottlerin, the activity of Na+/K+-ATPase was increased rather than inhibited. This effect was further investigated by studying rottlerin interactions with membrane lipids. The activity of Na+/K+-ATPase has been reported to be regulated by membrane lipids. The enzyme activity can be enhanced by increasing fluidity of the lipid membrane. I have, therefore, proposed that rottlerin binds to the membrane lipids and the effects of rottlerin on Na+/K+-ATPase are mediated by changes in the properties (fluidity) of the membrane. The hypothesis was tested by comparing rottlerin and a detergent, DOC (sodium deoxycholate), for their binding to the lipids by using a DMPC (1,2-Dimyristoyl-sn-Glycero-3-Phosphocholine) monolayer technique. DOC has been shown to both increase and inhibit activity of Na+/K+-ATPase in a manner similar to that displayed by rottlerin. The effects of rottlerin and DOC on the DMPC monolayers were studied by measuring the surface pressure of DMPC monolayers and surface area per DMPC molecule. I established that both rottlerin and DOC decreased the surface pressure of DMPC monolayers and increased the surface area per DMPC molecule. This indicates that both rottlerin and DOC penetrated into the DMPC monolayers. If rottlerin can interact with the lipids, changes in fluidity of the lipid membrane cannot be ruled out and should be considered as a possible factor contributing to the effects of rottlerin on the activity of Na+/K+-ATPase. Overall, the study demonstrates that rottlerin is not only a PKC-delta inhibitor but can have additional effects, both on the enzyme activities (Na+/K+-ATPase) and/or on lipid-containing biological structures such as membranes. The findings have implication not only for studies where rottlerin was used as a supposedly specific PKC-delta inhibitor but also for mechanisms of its toxicity.
|
5 |
Regulation of Autophagy and Cell Death in Breast Carcinoma CellsKoterba, Kristen L. 10 June 2010 (has links)
No description available.
|
6 |
Modulation of Sodium Iodide Symporter-mediated Thyroidal Radioiodide Uptake by Small Molecule Inhibitors, Natural Plant-based Products and microRNAsLakshmanan, Aparna 27 May 2015 (has links)
No description available.
|
Page generated in 0.0361 seconds