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A Role for ETA(253-412) in Peptide-based Delivery of Therapeutic Molecules into CellsBroad, Amaalia 15 February 2010 (has links)
The delivery of biomolecules by cell penetrating peptides (CPPs) is an innovative therapeutic strategy. However delivery efficiency is hindered by the entrapment of CPPs in vesicles, degradation, or recycling out of cells, which limits their delivery into the cell cytoplasm and nucleus. To overcome these barriers, we investigated a bacterial protein domain derived from Pseudomonas aeruginosa, Exotoxin A (ETA, residues 253-412) that is able to exit vesicular compartments. A series of CPP-ETA(253-412) fusion proteins were constructed, expressed, and purified. Confocal microscopy and flow cytometry confirmed the internalization at 37oC of constructs containing CPPs (poly-arginine or TAT). In addition, constructs containing CPP-ETA(253-412)-eGFP were shown to relocate from endosomes to the cytosol. CPP-ETA(253-412) constructs were also able to act as carriers of DNA cargos facilitating their delivery to the cytosol. The ETA(253-412) translocation domain may prove useful for the intracellular delivery of drugs, protein therapeutics, siRNA delivery, and vaccine formulations.
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A Role for ETA(253-412) in Peptide-based Delivery of Therapeutic Molecules into CellsBroad, Amaalia 15 February 2010 (has links)
The delivery of biomolecules by cell penetrating peptides (CPPs) is an innovative therapeutic strategy. However delivery efficiency is hindered by the entrapment of CPPs in vesicles, degradation, or recycling out of cells, which limits their delivery into the cell cytoplasm and nucleus. To overcome these barriers, we investigated a bacterial protein domain derived from Pseudomonas aeruginosa, Exotoxin A (ETA, residues 253-412) that is able to exit vesicular compartments. A series of CPP-ETA(253-412) fusion proteins were constructed, expressed, and purified. Confocal microscopy and flow cytometry confirmed the internalization at 37oC of constructs containing CPPs (poly-arginine or TAT). In addition, constructs containing CPP-ETA(253-412)-eGFP were shown to relocate from endosomes to the cytosol. CPP-ETA(253-412) constructs were also able to act as carriers of DNA cargos facilitating their delivery to the cytosol. The ETA(253-412) translocation domain may prove useful for the intracellular delivery of drugs, protein therapeutics, siRNA delivery, and vaccine formulations.
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Multi-functional Bio-synthetic Hybrid Nanostructures for Enhanced Cellular Uptake, Endosomal Escape and Targeted Delivery Toward Diagnostics and TherapeuticsShrestha, Ritu 1984- 14 March 2013 (has links)
Applications of nanotechnology in medicine, also known as nanomedicine, is a rapidly growing field as it holds great potential in the development of novel therapeutics toward treatment of various diseases. Shell crosslinked knedel-like nanoparticles (SCKs) that are self assembled from amphiphilic block copolymers into polymeric micelles followed by crosslinking selectively throughout the shell domain have been investigated as theranostic agents for the delivery of nucleic acids and incorporation of imaging probes. The main focus of this dissertation is to design and develop unique multifunctional bio-synthetic hybrid nanoparticles that can carry agents for radiolabeling, moieties for inducing stealth properties to minimize protein adsorption in vivo, ligands for site-specific targeting, therapeutic payloads, and are optimized for efficient delivery of cargoes intracellularly and to the target sites toward constructing novel nanoscopic objects for therapy and diagnosis.
Alteration of polymeric building blocks of the nanoparticles provides opportunities for precise control over the sizes, shapes, compositions, structures and properties of the nanoparticles. To ensure ideal performance of nanoparticles as theranostic agents, it is critical to ensure high intracellular bioavailability of the therapeutic payload conjugated to nanoparticles. Special efforts were made by employing well-defined multi-step polymerization and polymer modification reactions that involved conjugation of peptide nucleic acids (PNAs) to chain terminus of poly(ethylene glycol) (PEG) chain grafts such that they were presented at the outermost surface of SCKs. Additionally, chemical modification reactions were performed on the polymer backbone to integrate positive charges onto the shell of the nanoparticles to afford cationic SCKs (cSCKs) for facilitating cellular entry and electrostatic interactions with negatively charged nucleic acids. Covalent conjugation of F3, a tumor homing peptide, post-assembly of the nanoparticles enhanced cellular uptake and knockdown of nucleolin (a shuttling protein overexpressed at the sites of angiogenesis) and thus inhibiting tumor cell growth. Furthermore, these polymer precursors of the cSCKs were modified with partial to full incorporation of histamines to facilitate their endosomal escape for efficient delivery into the cytosol. The cSCKs were further templated onto high aspect ratio anionic cylinders to form hierarchically-assembled nanostructures that bring together individual components with unique functions, such as one carrying a therapeutic payload and the other with sites for radiolabeling. These higher order nanoobjects enhance circulation in vivo, have capabilities to package nucleic acids electrostatically and contain sites for radiolabeling, providing an overall advantage over the individual components, which could each facilitate only one or the other of the combined functions. Hierarchically-assembled nanostructures were investigated for their cellular uptake, transfection behavior and radiolabeling efficiency, as the next generation of theranostic agents.
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The Parkinson’s Disease-Associated Protein Kinase LRRK2 Modulates Notch Signaling through the Endosomal Pathway / パーキンソン病関連蛋白質キナーゼLRRK2はエンドソーム経路を介してNotchシグナルを修飾するKobayashi, Yoshito 25 January 2021 (has links)
京都大学 / 0048 / 新制・論文博士 / 博士(医学) / 乙第13384号 / 論医博第2216号 / 新制||医||1048(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 高橋 淳, 教授 渡邊 直樹, 教授 中川 一路 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Liposomal Coencapsulation of Doxorubicin with Listeriolysin O Increases Potency via Subcellular TargetingWalls, Zachary F., Gong, Henry, Wilson, Rebecca J. 07 March 2016 (has links)
Liposomal doxorubicin is a clinically important drug formulation indicated for the treatment of several different forms of cancer. For doxorubicin to exert a therapeutic effect, it must gain access to the nucleus. However, a large proportion of the liposomal doxorubicin dose fails to work because it is sequestered within endolysosomal organelles following endocytosis of the liposomes due to the phenomenon of ion trapping. Listeriolysin O (LLO) is a pore-forming protein that can provide a mechanism for endosomal escape. The present study demonstrates that liposomal coencapsulation of doxorubicin with LLO enables a significantly larger percentage of the dose to colocalize with the nucleus compared to liposomes containing doxorubicin alone. The change in intracellular distribution resulted in a significantly more potent formulation of liposomal doxorubicin as demonstrated in both the ovarian carcinoma cell line A2780 and its doxorubicin-resistant derivative A2780ADR.
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Studies on entry events during calicivirus replicationShivanna, Vinay January 1900 (has links)
Doctor of Philosophy / Department of Diagnostic Medicine and Pathobiology / Kyeong-Ok Chang / Caliciviruses are important pathogens of humans and animals. Noroviruses are major
causes of foodborne gastroenteritis cases, but their research is hindered due to the inability to grow human noroviruses in cell culture. Detailed studies on entry events of caliciviruses are lacking and may be crucial for development of cell culture models. We examined the entry events of caliciviruses using porcine enteric calicivirus (PEC), feline calicivirus (FCV) and murine norovirus-1 (MNV-1). PEC replication in LLC-PK cells requires bile acid in the medium, but the mechanism is not well understood. Our studies showed that bile acids are required in the early stage of virus replication, and while internalization of PEC is not dependent of them, they are required for endosomal escape and successful replication. Further examination on virus entry, we demonstrated that endosomal acidification and cathepsin L activity are essential in the replication of PEC, FCV and MNV-1. The results showed that inhibition of endosomal acidification or cathepsin L activity led to retention of viruses in the endosomes. Also we demonstrated that recombinant cathepsin L cleaved structural protein of PEC, FCV or MNV-1, which suggests that the enzyme may facilitate uncoating viruses in endosomes. In addition to
bile acids, we found that a cold shock treatment during virus entry supported PEC replication by facilitating the endosomal escape. While PEC alone did not induce ceramide formation, bile acids or cold shock treatment induce ceramide formation on endosomes through activation acid sphingomyelinase (ASM), and this event was crucial for virus replication because inhibition of ASM blocked ceramide formation and significantly reduced PEC replication. Incubation of FCV or MNV-1 with cells led to ceramide formation during virus entry, and inhibition of ASM also significantly reduced their replication. Inhibition of ASM led to endosomal retention of PEC, FCV or MNV-1 during virus entry, which may be the reason for the reduction of viral replication. These studies revealed the important and common events during calicivirus entry for successful replication, including virus endosomal escape, cathepsin L activity and ASM/ceramide formation. This detailed information may provide clues for understanding the replication of fastidious caliciviruses and for potential therapeutic targets.
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Membrane-remodeling by SNX18 in endosomal transport and autophagy / SNX18 - ett membranaktivt protein vid endosomal transport och autofagiHåberg, Karin January 2012 (has links)
The intracellular space of eukaryotic cells is subdivided into functionally distinct membrane-enclosed organelles. Regulation of these intracellular membranes requires an intricate network of specialized lipids and proteins that maintain organellar integrity and mediate transport between organelles. Proteins of the sorting nexin (SNX) family are membrane-binding regulators of transport events within the endomembrane system. The endomembrane system includes organelles associated with endocytic, secretory and degradative processes in the cell. The aims of this thesis were to functionally characterize SNX18 and SNX33, members of the SNX9-subfamily of sorting nexins, and to elucidate the role of SNX18 in autophagy. We demonstrated that all three proteins in the SNX9-family are capable of both membrane binding and remodeling, and interact with the membrane scission enzyme dynamin. We found that SNX18 localizes to endosomal structures in the endomembrane system, together with several identified factors previously described as regulators of endosomal transport. These results indicate that SNX18 mediates budding of membrane carriers in endosomal trafficking. In addition to this, knockdown of SNX18 in cultured cells was found to inhibit autophagy. Autophagy is a catabolic process by which cells degrade and recycle cellular components. It is a cellular response to various stress conditions such as oxidative stress, nutrient deprivation and infections. The components destined for degradation by autophagy are sequestered into a double-membrane structure called the autophagosome in which they are delivered to the lysosome. SNX18 interacts directly with proteins connected to autophagosome formation. Moreover, we demonstrated that the membrane-remodeling capability of SNX18 is a prerequisite for autophagosome formation. Taken together, our results lead to the conclusions that SNX18 remodels cellular membranes during formation of carriers for endosomal transport and that it is a positive regulator of autophagy and autophagosome formation.
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mTORC1 Activates SREBP-2 through Maintenance of Endosomal Cycling and Suppression of AutophagyEid, Walaa January 2017 (has links)
The mammalian target of rapamycin complex 1 (mTORC1) is known to regulate lipogenesis through sterol regulatory element binding proteins (SREBPs), master regulators of cholesterol and fatty acid synthesis. Through an incompletely understood mechanism, mTORC1 triggers translocation of SREBPs, an endoplasmic reticulum (ER) resident protein, to the Golgi, where mature SREBP is proteolytically produced to activate transcription of lipogenic genes. Low ER cholesterol is a well-known trigger for SREBPs activation, which includes translocation, maturation, and transcriptional activation. The study investigated whether mTORC1 activates SREBP by limiting cholesterol delivery to the ER. The findings indicate an increase in mTORC1 activity is accompanied by lower ER cholesterol and by SREBP-2 activation, a transcription factor primarily responsible for cholesterol synthesis. A decrease in mTORC1 activity, on another hand, coincides with higher ER cholesterol and lower SERBP-2 activity. I further report that this ER cholesterol is of lysosomal origin, as blocking the exit of cholesterol from lysosomes by U18666A or NPC1 siRNA prevents ER cholesterol from rising and, consequently, SREBP-2 is activated without mTORC1 activation. I identified two membrane trafficking processes, triggered by low mTORC1 activity, supply the lysosomes with cholesterol: autophagy and re-routing of endosomes to lysosomes. Indeed, a dual blockade by Atg5-/- and rab5 kept the ER cholesterol low even when mTORC1 activity was low, and resulted in SREBP-2 activation. Conversely, over-expressing Atg7, which forces autophagy, raises the ER cholesterol and suppresses SREBP-2 activity even when mTORC1 activity is high. Thus, it can be concluded that mTORC1 actively suppresses the formation of autophagosomes and promotes endosomal recycling, both of which prevents cholesterol to reach the lysosomes, thereby reducing cholesterol levels in the ER and activating SREBP-2.
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Structural and Functional Basis for the Autoregulation of the Adaptor Protein TOM1Xiong, Wen 08 June 2020 (has links)
Target of Myb 1 (TOM1) is an endosomal adaptor protein that plays a role in cargo membrane trafficking for degradation by serving as an alternative endosomal sorting complex required for transport component. TOM1 has also been shown to serve as a novel phosphatidylinositol 5-phosphate (PtdIns5P) effector at signaling endosomes through its VHS domain, delaying cargo degradation in a bacterial infection model. The aim of this thesis is to clarify the structural and functional basis of the autoregulation mechanism of TOM1 to switch from endosomal protein trafficking to the bacterial survival signaling pathway.
Our thermal denaturation and spectroscopic studies demonstrate that PtdIns5P reduced thermostability, interhelical contacts, and conformational compaction of TOM1 VHS. The thermodynamic studies indicate that TOM1 VHS endothermically binds to PtdIns5P through two potential noncooperative binding sites, with its acyl chains playing a relevant role in the interaction. These findings suggest that, under Shigella flexneri infection, TOM1 may interact with downstream effectors in a different VHS domain conformational state, thus involving the protein in bacterial survival signaling pathways.
In order to obtain molecular details for the interaction of the TOM1 VHS domain for PtdIns5P and Ubiquitin (Ub), the backbone assignment information was obtained by performing NMR experiments, which assigned backbone 1H, 13C, and 15N resonances of the TOM1 VHS domain. With this structural information, our heteronuclear single quantum coherence and molecular dynamics simulations data revealed that TOM1 VHS interacts with PtdIns5P following a fast-exchange regime, with the PtdIns5P binding site predicted to be at a region spanning α-helices 6 to 8. Further mutagenesis and lipid-protein overlay assay studies indicated that K147 plays a critical role in the binding of TOM1 VHS domain to PtdIns5P.
TOM1, unexpectedly, did not bind PtdIns5P. Using truncated forms of TOM1 protein, we discovered that neither TOM1 GAT domain nor the C-terminal domain modulated TOM1 VHS's PtdIns5P binding; however, surprisingly, a linker sequence between the TOM1 VHS and GAT domains exhibited an autoinhibition role for TOM1 binding to PtdIns5P. This linker region was observed to induce local conformational changes on the structure of TOM1 VHS domain, especially around α-helices 6 and 8, which are proposed to build up the binding pocket for PtdIns5P. In order to investigate whether the linker region between TOM1 VHS and GAT domain can also regulate the Ub association of TOM1 VHS domain, the binding properties of TOM1 and its domains to Ub were explored. Unexpectedly, the binding affinity of TOM1 VHS-linker for Ub was increased about 10-fold when compared with that for the TOM1 VHS domain, suggesting that the linker enhances the avidity of TOM1 for ubiquitinated cargo. Structural analysis indicated that the linker region may cap the conventional Ub-binding site of TOM1 VHS, thus forming a more compact structure.
In summary, this study uncovered a novel intramolecular modulatory mechanism in TOM1 that regulates ligand recognition by its VHS domain. By providing the molecular basis of the TOM1 interactions, we may provide cargo sorting mechanistic insights, create functionally specific mutations, and precisely manipulate TOM1 function under bacterial infection conditions, and other yet-to-be-discovered PtdIns5P-dependent signaling pathways. / Doctor of Philosophy / Membrane trafficking is a delivery network established in a cell to transport proteins (cargoes) from one intracellular place to another one to control their activity. TOM1 is a protein involved in this process, which plays a role in transporting cargoes for degradation. Defects in this trafficking pathway lead to human diseases, such as immunodeficiency and neurodegeneration diseases. TOM1 has also been shown to be beneficial for bacterial survival in human cells. However, how TOM1 switches its role form protein trafficking to bacterial pathogenesis is still unclear. In our study, we discovered an internal region of TOM1 may serve as a switch to shift the role of TOM1 in human cells. In an "on" status, TOM1 favors to transport cargoes, while in an "off" status, TOM1 is used for bacteria survival. This study provides insights in the function of TOM1 which is beneficial for the design of novel therapeutic strategies against TOM1, which will prevent the progress of bacterial infections.
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Optimisation d'un vecteur en immunothérapie avec les cellules dendritiques : micelles de copolymères à blocs double-hydrophiles / Optimization of a vector for immunotherapy with dendritic cells : double hydrophilic block copolymer micellesMebarek, Naila 06 December 2013 (has links)
L'objectif de cette thèse repose sur le développement de micelles de polymères polyioniques, vecteurs de molécules thérapeutiques en immunothérapie avec des cellules dendritiques (DCs). Elles sont préparées à partir d'un copolymère à blocs double-hydrophiles, l'acide polyméthacrylique-b-polyoxyde d'éthylène (PMAA-b-POE) et d'un contre ion de charge opposée. De taille nanométrique, elles sont capables d'encapsuler des molécules thérapeutiques selon une association tripartite originale et de se désassembler à pH acide pour permettre leur libération dans le milieu endosomal.Le premier axe de travail a porté sur l'évaluation de la propriété des copolymères à induire un échappement endosomal en fonction de leur masse molaire en utilisant deux modèles membranaires (liposomes et globules rouges). La complexation des copolymères de masses molaires différentes avec la poly-L-lysine comme contre-ion a permis l'obtention de micelles avec des propriétés d'échappement endosomal variables. Cette propriété est intéressante car en fonction de la stratégie thérapeutique adoptée, elle orientera le choix de la masse molaire du copolymère pour la formulation des micelles.Le second axe a consisté en l'application de ces micelles pour la vectorisation d'un peptide modèle (peptide OVA) dans les DCs. La capacité des micelles à encapsuler le peptide et à le libérer au niveau des compartiments endosomaux a été évaluée par des techniques de spectrofluorimétrie et de microscopie confocale. Enfin, l'efficacité de présentation du peptide formulé dans les différentes micelles a été mise en évidence et a montré l'amélioration de la présentation par les DCs du peptide formulé dans les micelles comparé au peptide non formulé. Cette présentation est nettement supérieure en utilisant les micelles composées de copolymères de masse molaire élevée qui n'entraînent pas d'échappement endosomal.Le troisième axe de recherche a reposé sur la transfection des DCs avec des micelles de siRNA dirigés contre la protéine de surface CD86. Seules les micelles composées de copolymères de faible masse molaire ont permis l'encapsulation du siRNA et la baisse de l'expression de la protéine CD86 à la surface des DCs. Afin d'optimiser la capacité des micelles à encapsuler et transfecter les DCs, la formulation des micelles a été optimisée en remplaçant la PLL par un autre polycation la polyethylene imine PEI. Ces micelles polyioniques à base de copolymère PMAA-b-POE apparaissent donc comme des vecteurs de molécules d'intérêt thérapeutique prometteurs pour les cellules dendritiques en immunothérapie ou en thérapie génique. / The aim of the thesis work is based on the development of polymeric micelles vectors of therapeutic molecules in immunotherapy with dendritic cells (DCs). They are composed of a double hydrophilic blocks copolymers, poly(methacrylic acid)-b-poly(ethylene oxide) (PMAA-b-PEO) and an oppositely charged polyion. They are caracterized by a nanometric size, a capacity to encapsulate therapeutic molecules according to a tripartite association and are able to disassemble at acidic pH allowing the release of their cargo.The first part of this work has focused on the evaluation of the endosomal escape property of copolymers based on their molecular weight by using two membrane models (liposomes and red blood cells). Complexation of different molecular weight copolymers with poly- L- lysine as counter ion allowed the formation of micelles with variable endosomal escape properties. This property is interesting because according to the adopted therapeutic strategy, it will guide the choice of the copolymer micelles for formulation.The second part consisted of the application of these micelles for the vectorization of a model peptide (OVA peptide) in DCs. The ability of micelles to encapsulate and release this peptide in the endosomal compartments was assessed by fluorescence spectroscopy and confocal microscopy techniques. Finally, the effectiveness of the OVA presentation formulated in the different type of micelles has been demonstrated and shown that the peptide presentation by DCs was improved when it was formulated in micelles compared to unformulated peptide. This presentation was much higher using micelles composed of high molecular weight copolymers that do not involve endosomal escape.The third part of the research was based on the transfection of DCs with siRNA directed against CD86 protein surface. Only micelles composed of low molecular weight copolymers allowed the encapsulation of siRNA molecules and decreased the expression of CD86 protein on DCs surface. To increase the ability of micelles to encapsulate and transfect DCs, the micelle formulation was optimized by changing the PLL with another polycation PEI.These polyion micelles based PMAA-b-PEO copolymers appear as vectors of therapeutic molecules for promising strategies with dendritic cells such as vaccination and gene therapy.
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