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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Proteomics in viral disease

Gangadharan, Bevin January 2006 (has links)
The separation, identification, and characterisation of the proteins present in a tissue or biological sample is called ‘proteomics’. This technique can be used for example to identify biomarkers and investigate signalling pathways. Increasingly, proteomics is being applied to the analysis of virus related samples; here two such examples are described. Presently there is no reliable non-invasive way of assessing liver fibrosis. Here a novel 2D-PAGE based proteomics study was used to identify potential fibrosis biomarkers. Serum from patients with varying degrees of hepatic scarring induced by infection with the hepatitis C virus (HCV) was analysed. Several proteins associated with liver scarring and/or viral infection were identified. The most prominent changes were observed when comparing serum samples from cirrhotic patients with healthy controls: Expression of inter-α-trypsin inhibitor heavy chain H4 fragments, α1 antichymotrypsin, apolipoprotein L1 (Apo L1), prealbumin and albumin was decreased in cirrhotic serum, whereas CD5 antigen like protein (CD5L) and β2 glycoprotein I (β2GPI) increased. In general, α2 macroglobulin (a2M) and immunoglobulin components increased with hepatic fibrosis whereas haptoglobin and complement components (C3, C4 and factor H-related protein 1) decreased. Novel proteins associated with HCV-induced fibrosis include the inter-alpha-trypsin inhibitor heavy chain H4 fragments, complement factor H-related protein 1, CD5L, Apo L1, β2GPI and the increase in thiolester cleaved products of a2M. The relationship between these changes is discussed. One of the accessory genes of the HIV viral genome encodes for the Nef protein. Nef is present in lipid rafts and increases viral replication within infected host cells by binding to a guanine nucleotide exchange factor, Vav. This leads to activation of a GTPase, Cdc42, however, the signalling pathway is poorly understood. 2D-PAGE based proteomics was used to identify differentially expressed raft-associated proteins by comparing T cells in the presence and absence of Nef. A ubiquitin conjugating enzyme UbcH7, which acts in conjugation with c-Cbl, was absent from the rafts of Nef-transfected cells. Vav ubiquitination was also absent from these rafts. In collaboration with Dr. Alison Simmons and Prof. Andrew McMichael the absence of UbcH7 in rafts was found to be caused by β-Pix forming a ternary complex with c-Cbl and activated Cdc42. Vav ubiquitination was restored and viral replication was diminished when β-Pix was knocked down providing a new candidate target for inhibiting HIV replication. This thesis demonstrates the use of proteomics in providing novel information for virus related samples. This influential technology benefits in both biomarker discovery to aid clinicians with early diagnosis of diseased individuals and in the elucidation of novel signalling pathways in infected cells to provide new candidate targets.
2

Mechanisms of HIV-Nef Induced Endothelial Cell Stress: Implications of HIV-Nef Protein Persistence in Aviremic HIV Patients

Chelvanambi, Sarvesh 05 1900 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / HIV-associated cardio-pulmonary vascular pathologies such as coronary artery disease, pulmonary hypertension and emphysema remain a major issue in the HIVinfected population even in the era of antiretroviral therapy (ART). The continued production of HIV encoded pro-apoptotic protein, such as Nef in latently HIV-infected cells is a possible mechanism for vascular dysfunction underlying these diseases. HIVNef persists in two compartments in these patients: (i) extracellular vesicles (EV) of plasma and bronchoalveolar lavage (BAL) fluid and (ii) PBMC and BAL derived cells. Here I demonstrate that the presence of HIV-Nef protein in cells and EV is capable of stressing endothelial cells by inducing ROS production leading to endothelial cell apoptosis. HIV-Nef protein hijacks host cell signaling by interacting with small GTP binding protein Rac1 which activates PAK2 to promote the release of pro-apoptotic cargo containing EV and surface expression of pro-apoptotic protein Endothelial Monocyte Activating Polypeptide II (EMAPII). Using this mechanism, Nef protein robustly induces apoptosis in Human Coronary Artery Endothelial Cells and Human Lung microvascular endothelial cells. Endothelial specific expression of HIV-Nef protein in transgenic mice was sufficient to induce vascular pathologies as evidenced by impaired endothelium mediated vasodilation of the aorta and vascular remodeling and emphysema like alveolar rarefaction in the lung. Furthermore, EV isolated from HIV patients on ART was capable of inducing endothelial apoptosis in a Nef dependent fashion. Of therapeutic interest, EMAPII neutralizing antibodies to block EMAPII mediated apoptosis and statin treatment to ameliorate Nef induced Rac1 signaling was capable of blocking Nef induced endothelial stress in both in vivo and in vitro. In conclusion, HIV-Nef protein uses a Rac1-Pak2 signaling axis to promote its dissemination in EV, which in turn induces endothelial cell stress after its uptake.
3

The mechanism of HIV-1 Nef-mediated downregulation of CD4

Chaudhuri, Rittik January 2010 (has links)
Nef, an accessory protein of HIV-1, is a critical determinant of viral pathogenicity. The pathogenic effects of Nef are in large part dependent on its ability to decrease the amount of CD4 on the surface of infected cells. Early studies suggested that Nef induces downregulation by linking the cytosolic tail of CD4 to components of the host-cell protein-trafficking machinery. However, the specific sorting pathway that Nef uses to modulate CD4 expression remained uncertain. According to one model, Nef was thought to interfere with the transport of newly synthesized CD4 from the TGN to the cell-surface. Another model claimed that Nef facilitated the removal of CD4 from the plasma membrane. The primary goal of this thesis was to determine which of these models was correct. To accomplish this objective, a novel Nef-CD4 system was developed in Drosophila S2 cells. Nef was not only able to downregulate human CD4 in S2 cells, but it did so in a manner that was phenotypically indistinguishable from its activity in human cells. An RNAi screen targeting protein-trafficking genes in S2 cells revealed a requirement for clathrin and the clathrin-associated, plasma membrane-localized AP-2 complex in the Nef-mediated downregulation of CD4. In contrast, depletion of the related AP-1 and AP-3 complexes, which direct transport from the TGN and endosomes, had no effect. The requirement for AP-2 was subsequently confirmed in a human cell line. Yeast three-hybrid and GST pull-down assays were then used to demonstrate a robust, direct interaction between Nef and AP-2. This interaction was found to depend on a [D/E]xxxL[L/I]-type dileucine motif, located in the C-terminal loop of Nef, that is essential for CD4 downregulation. While mapping the binding site of AP-2 on Nef, a second determinant of interaction in the C-terminal loop was identified. Mutation of this motif, which conforms to a consensus [D/E]D diacidic sequence, prevented Nef from binding to AP-2 and down-regulating CD4. However, the same mutations did not affect the ability of Nef to interact with either AP-1 or AP-3, providing further evidence that these complexes are not required for the modulation of CD4 expression. Additional experiments indicated that the Nef diacidic motif most likely binds to a basic patch on AP-2 α-adaptin that is not present in the homologous AP-1 γ and AP-3 δ subunits. As with the Nef diluecine and diacidic motifs, the α-adaptin basic patch was shown to be necessary for CD4 downregulation. Moreover, all three of these motifs were needed for the cooperative assembly of a CD4-Nef-AP-2 tripartite complex, which was observed here for the first time using a yeast four-hybrid system. The data in this thesis uniformly support an endocytic model of Nef-mediated CD4 downregulation. Indeed, there is now strong evidence that Nef simultaneously binds CD4 and AP-2, thereby connecting the receptor to the cellular endocytic machinery and promoting its rapid internalization from the plasma membrane. In addition, the identification of novel motifs required for this process has provided new insights on endocytosis, and may facilitate the development of pharmacological inhibitors of Nef function.
4

Spécificité et inhibition des interactions protéine-protéine : Exemples d'approches

Lugari, Adrien 08 April 2011 (has links)
L’identification de molécules organiques capables de moduler des interactions protéine-protéine (PPIs) est longtemps restée un domaine peu exploité par la recherche pharmaceutique privée comme académique. Cependant, le développement de méthodologies innovantes pour l’étude des PPIs et la validation récente de ce type d’inhibiteurs dans des essais précliniques, démontrent que les PPIs constituent une nouvelle source de cibles importantes. Les composés capables de moduler ces interactions représentent une nouvelle classe d’outils prometteurs, tant en recherche fondamentale qu’en thérapeutique. Elles peuvent aider à différencier les multiples fonctions portées par une même protéine, à replacer la protéine dans une cascade de réactions, ainsi qu’à disséquer et reconstituer des réseaux de signalisations protéiques. Ces molécules permettront également de faire émerger de nouvelles familles d’agents pharmacologiques actifs dans diverses pathologies.Mon travail de thèse s'est projeté dans l'avenir de la recherche biomédicale, en ciblant les interactions protéine-protéine. J’ai pu durant mon doctorat mettre en œuvre plusieurs méthodologies pour étudier et caractériser des interactions protéiques afin de développer des inhibiteurs de ces interactions. J’ai ainsi pu travailler sur l’optimisation d’un composé inhibiteur de l’interaction de la protéine virale Nef VIH-1 avec les domaines SH3 des Src kinases, le composé DLC27. J’ai également pu mettre en évidence la pertinence biologique de ce composé, qui cible un mode d’interaction unique, ou très rare, au niveau cellulaire en étudiant l’interaction avec les domaines SH3 de deux protéines, ALIX (ALG2-Interacting Protein X) et la sous-unité p85 de la PI3K (phosphatidylinositol 3-kinase).J’ai également pu caractériser la surface et le mode d’interaction de protéines virales impliquées dans le complexe de réplication du virus du SRAS (Syndrome Respiratoire Aigu Sévère). Cette étude tend à montrer que la protéine virale nsp10 agit comme une plateforme de reconnaissance pour ses partenaires, les protéines virales nsp14 et nsp16. Ces interactions permettent l’activation ou l’augmentation des activités respectives de nsp16 et nsp14 et jouent un rôle au niveau de la réplication virale. Suite à l’identification d’un ‘point chaud’ d’interaction, le résidu Tyr96 à la surface de nsp10, nous avons mis en évidence la première famille de molécules inhibitrices du complexe nsp10-nsp14 en couplant des méthodes informatiques (in silico) à des criblages expérimentaux. Ces molécules pourraient être utilisées comme antiviraux ou servir d’outils pour la recherche, en permettant par exemple de mieux comprendre et d’élucider les mécanismes moléculaires impliqués dans la réplication du virus du SRAS et des coronavirus en général. / Protein-protein interactions (PPIs) participate in and regulate almost all essential cellular functions. As a consequence, they are frequently involved in various pathologies (going from cancer development to viral replication and host cell infection) but their study remains a challenge.Thus understanding those interactions as well as finding small drug candidates able to modulate them, a field of research not currently fully developed, appear as the future of the healthcare industry.In this context, I chose to learn different techniques to study PPIs that are usually employed in academic (IMR laboratory, CNRS, France) or corporate environments (Genentech, USA). Moreover, I also worked on the development of small organic inhibitors of PPIs coupling in silico methodologies (chemo-informatics, Drug Design) to biological and structural validations.During my PhD, I could manage and work on different projects involving the study of PPIs involved in cancer signaling pathways as well as the development of potent antiviral drugs targeting the HIV and SARS viruses.My organizational, personal and scientific skills as well as the practical experience I developed on various techniques (from cell biology to biophysics, structural biochemistry and Drug Design), make me feel confident on the management of PPIs drug discovery projects.I am thus able to efficiently work on, and manage, the study of protein-protein interactions in various pathologies as well as the development of potent PPIs inhibitors, that will be a major breakthrough for Biotech/Pharma companies in the coming years.
5

Transfer of intracellular HIV Nef to endothelium causes endothelial dysfunction

Wang, Ting January 2014 (has links)
Indiana University-Purdue University Indianapolis (IUPUI) / With effective antiretroviral therapy (ART), cardiovascular diseases (CVD), are emerging as a major cause of morbidity and death in the aging population with HIV infection. Although this increase in CVD could be partially explained by the toxic effects of combined anti-retroviral therapy (ART), more recently, HIV infection has emerged as an independent risk factor for CVD. However, it is unclear how HIV can contribute to CVD in patients on ART, when viral titers are low or non-detectable. Here, we provide several lines of evidence that HIV-Nef, produced in infected cells even when virus production is halted by ART, can lead to endothelial activation and dysfunction, and thus may be involved in CVD. We demonstrate that HIV-infected T cell-induced endothelial cell activation requires direct contact as well as functional HIV-Nef. Nef protein from either HIV-infected or Nef-transfected T cells rapidly transfers to endothelial cells while inducing nanotube-like conduits connecting T cells to endothelial cells. This transfer or transfection of endothelial cells results in endothelial apoptosis, ROS generation and release of monocyte attractant protein-1 (MCP-1). A Nef SH3 binding site mutant abolishes Nef-induced apoptosis and ROS formation and reduces MCP-1 production in endothelial cells, suggesting that the Nef SH3 binding site is critical for Nef effects on endothelial cells. Nef induces apoptosis of endothelial cells through both NADPH oxidase- and ROS-dependent mechanisms, while Nef-induced MCP-1 production is NF-kB dependent. Importantly, Nef can be found in CD4 positive and bystander circulating blood cells in patients receiving virally suppressive ART, and in the endothelium of chimeric SIV-infected macaques. Together, these data indicate that Nef could exert pro-atherogenic effects on the endothelium even when HIV infection is controlled and that inhibition of Nef-associated pathways may be promising new therapeutic targets for reducing the risk for cardiovascular disease in the HIV-infected population.

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