Global ETD Search

1	De Novo Initiated RNA Synthesis by the Hepatitis C Virus RNA-dependent RNA Polymerase Reddy Chinnaswamy, Sreedhar 2010 May 1900 (has links) Hepatitis C Virus (HCV) is a positive-strand RNA virus that has infected more than 3% of the world population. Chronic infections by the virus lead to cirrhosis and hepatocellular carcinoma. HCV is currently the leading cause for liver transplantation in the US. The nonstructural protein NS5B of HCV is the RNA-dependent RNA polymerase (RdRp) that replicates the viral RNA on host derived membranous structures. Structurally NS5B has the characteristic fingers, thumb and palm domains seen in all polymerase proteins. However, extensive interactions between the fingers and thumb domains completely encircle the active site of NS5B as seen in solved X-ray diffraction crystal structures. These interactions are primarily mediated by a short (35 residues) flexible loop called the Delta 1 loop. NS5B produced from heterologous systems can initiate RNA synthesis by a de novo initiation mechanism from 3?ends of RNA templates or can also extend from 3'ends of primers that are annealed stably to a template RNA in biochemical assays. The closed conformation of NS5B as per X-ray crystal structures can only accommodate a ssRNA but not a dsRNA, hence necessitating a conformational change between de novo initiation and elongation. The details of these conformational changes are not known and will prove to be important to design potent polymerase inhibitors. The study performed for this dissertation focused on the conformational requirements of NS5B during de novo initiation and primer extension (or elongation). Biochemical assays utilizing template RNAs that can lead to both de novo initiation and primer extension products were utilized, and a systematic mutational analysis of the template channel of the RdRp was performed. Mutants W397A and H428A were identified that showed only primer extension but no de novo initiation. Structural analysis of NS5B suggested that these residues were important contact points in the Delta 1 loop and thumb domain interactions. A deletion mutant, m26-30 with a five amino acid deletion at the apex of the Delta 1 loop also failed in de novo initiation but not primer extension reactions. Biophysical and gel shift assays showed that m26-30 was in a more open conformation than the WT enzyme. Furthermore, oligomerization of NS5B was demonstrated and its role in RNA synthesis was examined. It was found that the de novo initiation competent conformation of NS5B is maintained by oligomeric contacts between individual subunits, likely by stabilizing the Delta 1 loop and thumb domain interactions. Mutations disrupting the Delta 1 loop and thumb domain interactions as well as those in the allosteric GTP binding site induced conformational changes in the protein partially explaining the defect in de novo initiation activity in enzymes carrying those mutations. These results not only contribute to the overall mechanism of RNA synthesis in viral RdRps but also open new avenues for developing HCV polymerase inhibitors. HCV RdRp Polymerase Conformation Oligomerization
2	Early Endocytosis Pathways in SSN-1 Cells Infected by Dragon Grouper Nervous Necrosis Virus Liu, Wang-ta 23 January 2006 (has links) Many fish undergo betanodavirus infection. To study the infection process of dragon grouper nervous necrosis virus (DGNNV), native virus and E. coli-produced virus-like particles (VLPs) were used to analyze the binding and internalization in SSN-1 cells. The binding of DGNNV and VLPs to SSN-1 cells was demonstrated using Western blotting and indirect enzyme-linked immunosorbent assay (ELISA). As estimated by ELISA, the DGNNV particles bound SSN-1 cells in a dose-dependent manner up to 8 ¡Ñ 104 particles per cell. The binding of VLPs was sensitive to neuraminidase and tunicamycin, suggesting that cell-surface sialic acid is involved in binding. The recombinant VLPs block attachment of native virus to the surface of cultured fish nerve cells, blocking infection by the native virus. It is suggesting that the outer shell of DGNNV VLPs is structurally indistinguishable from native virus. The penetration of DGNNV into cells, which was monitored by electron microscopy, appeared mainly to occur via the spherical pit and membrane ruffling pathways. Occasionally, a spherical pit was engulfed by membrane ruffling so as to form a large figure 8-shaped vesicle with an open connection. Our observations suggest that DGNNV utilizes both micro- and macro-pinocytosis pathways to enter SSN-1 cells. Both of nucleotide and amino acid sequences of MGNNV protein A were comparison with all of Nodaviridae members, revealed that MGNNV were most closely related to RGNNV. No correlation of sequences of betanodavirus with geographical habitat was detected. All thirteen nodavirus protein A amino acid sequences contained canonical RNA polymerase motifs in their C-terminal halves and conserved elements of predicted secondary structure throughout. By Phyre web server identification, the BVDV RdRp as the best template for fold recognition of the RdRp domain of MGNNV and allowed the construction of a congruent 3D model. RdRp coat protein VLPs endocytosis betanodavirus
3	Caractérisation d'antiviraux contre divers Bunyaviridae, criblage, validation et étude du cap-snatching et les mécanismes d'initiation de la transcription du phlebovirus Toscana / Characterization of antivirals against various Bunyaviridae, screening, validation and study of cap-snatching and transcription initiation mechanisms of phlebovirus Toscana Amroun, Abdennour 21 December 2017 (has links) Lors d’un crible d’une chimiothèque de ChemBridge (28 500 composés), nous avons identifié deux molécules (T10 et T13), chimiquement très proches, capables d’inhiber la réplication du phlebovirus Toscana (TOSV) (Phenuiviridae) dans des cellules de singe Vero E6. Une recherche d’analogues disponibles commercialement a permis d’identifier le (T101) capable d’inhiber divers virus appartenant à l’ordre des Bunyavirales, mais aussi des flavivirus et des alphavirus. Le large spectre d’activité du T101 suggérait une cible cellulaire que nous avons pu identifier avec son mécanisme d’action potentiel (confidentiel avant dépôt de brevet). En collaboration avec un groupe de chimistes de l’Institut de Virologie de Hambourg (Allemagne), nous avons synthétisé et testé environ 300 analogues structuraux (2D et 3D) de ces molécules en vue d’optimiser l’activité antivirale par une étude SAR (relation structure-activité). Les meilleures molécules (index de sélectivité CC50/IC50> 400) suivant les virus et l’origine de l’espèce cellulaire (humaine, singe et souris), ont été sélectionnées pour des études de leurs propriétés de solubilité, d’absorption, et de stabilité métabolique (ADME-TOX). La molécule la plus active sur cellules murines sera testée lors d’infections expérimentales de souris.En parallèle, j’ai écrit une revue sur la RdRp des Bunyavirales en décrivant sa structure, ses motifs et les différents mécanismes de synthèse des ARN viraux. J’ai également fait une étude sur le mécanisme de vol de coiffe du TOSV. J’ai essayé de construire un système de génétique inverse pour TOSV. Enfin j’ai aussi participé à l’étude de l’évolution du CHIKV dans les cellules d’insectes et de mammifères / We have screened a subset of the ChemBridge chemical library (28,500 compounds) for compounds inhibiting the replication of Toscana phlebovirus (TOSV) (Phenuiviridae family) in Vero E6 primate cell cultures. Tow molecules chemically very close (T10, T13) have been validated as good inhibitors of TOSV replication. The search for commercially available analogs allowed the identification of (T101). This compound is found active against viruses from highly divergent families such as Bunyavirales order, Flavivirus and Alphavirus. We have determined that the target of this compound family is a cellular enzyme (the cellular target and the mechanism of action are confidential). The inhibitors family was further explored through the synthesis, by a group of chemists (Hambourg University, Germany), of about 300 structural analogs in order to optimize the antiviral activity using SAR studies (structure-activity relationship). The most active molecules (selectivity index CC50 / IC50> 400) depending on virus species and origin of cell species (human, monkey and mouse) were selected for studies of solubility, absorption, metabolic stability (ADME-TOX) and pharmacodynamics. The most promising compound that is active in murine cells will be tested in experimentally infected mice.I wrote a review on the RdRp of bunyaviruses describing its structure, motifs and the various mechanisms of viral RNA synthesis. I also made a study on the cap-snatching mechanism and the initiation of transcription of TOSV and tried to develop a reverse genetics system for TOSV. In parallel I also participated in the study of the evolution of Chikungunya virus (CHIKV) in insect and mammalian cells. Bunyavirales Antiviraux RdRp Vol de coiffe Le virus Toscana Bunyavirales Antiviral RdRp Cap-Snatching Toscana virus
4	CRITICAL EVENTS IN HUMAN METAPNEUMOVIRUS INFECTION: FROM ENTRY TO EGRESS Hackett, Brent A 01 January 2013 (has links) Human metapneumovirus (HMPV) is a respiratory pathogen in Paramyxovirus family that demonstrates extremely high morbidity in the population, with most individuals having been infected by the age of five. Despite the prevalence of this negative-sense RNA virus in the population for decades, it was only identified in 2001. As such, there is currently no specific treatment for HMPV and the potentially severe consequences of infection for elderly and immunocompromised individuals and particularly infants make development of antivirals targeting HMPV of high significance. HMPV constitutes a quarter of all respiratory hospitalizations among infants, placing it second only to RSV, in addition to becoming a greater concern in concentrated populations of seniors. For these susceptible populations, the consequences of infection have a much greater probability of leading to pneumonia, bronchiolitis and even death. These studies investigate events throughout the infectious cycle of HMPV. They describe specific amino acids that modulate the triggering of viral fusion activity in response to low pH. They also include a report on the dynamic and variable control exercised over gene transcription by viral promoters. Finally, the interplay between viral nonstructural proteins and their distinct roles in both replication and assembly are examined. Ultimately, this work seeks to elucidate the goings-on within an HMPV-infected cell at multiple points throughout the process. Human metapneumovirus (HMPV) RNA-dependent RNA polymerase (RdRp) phosphoprotein nucleocapsid minireplicon Biochemistry Virology
5	Overexpression of the Turnip Crinkle Virus Replicase Exerts Opposite Effects on the Synthesis of Viral Genomic RNA and a Novel Viral Long Non-Coding RNA Zhang, Shaoyan January 2020 (has links) No description available. Plant Pathology Virology positive sense RNA virus replication RdRp non-coding RNA
6	Structural and biophysical studies of RNA-dependent RNA polymerases Wright, Sam Mathew January 2010 (has links) RNA-dependent RNA polymerases (RdRps) play a vital role in the life cycle of RNA viruses, being responsible for genome replication and mRNA transcription. In this thesis viral RdRps (vRdRps) of dsRNA bacteriophage phi6 (phi6 RdRp) and Severe Acute Respiratory Syndrome (SARS) coronavirus [non structural protein 12 (NSP-12)] are studied. For SARS polymerase NSP-12, a library-based screening method known as ESPRIT (Expression of Soluble Protein by Random Incremental Truncation) was employed in an attempt to isolate domains of NSP-12 that express solubly in Escherichia coli (E. coli) and are thereby suitable for structural studies. This experiment identified for the first time in a systematic fashion, conditions under which the SARS polymerase could be solubly expressed at small scale and allowed mapping of domain boundaries. Further experiments explored different approaches for increasing expression levels of tractable fragments at large scale. Bacteriophage phi6 RdRp is one of the best studied vRdRps. It initiates RNA synthesis using a de novo mechanism without the need for a primer. Although formation of the de novo initiation complex has been well studied, little is known about the mechanism for the transition from initiation to elongation (i.e. extension of an initiated dinucleotide daughter strand). In the phi6 RdRp initiation complex the C-terminal domain (CTD) blocks the exit path of the newly synthesised dsRNA which must be displaced for the addition of the third nucleotide. The crystal structure of a C-terminally truncated phi6 RdRp (P2T1) reveals the strong non-covalent interactions between the CTD and the main body of the polymerase that must be overcome for the elongation reaction to proceed. Comparing new crystal structures of complexes of both wild-type (WT) and a mutant RdRp (E634 to Q, which removes a salt-bridge between the CTD and main body of the polymerase) with various oligonucleotides (linear and hairpin), nucleoside triphosphates (NTPs) and divalent cations, alongside their biophysical and biochemical properties, provides an insight into the precise molecular details of the transition reaction. Thermal denaturation experiments reveal that Mn2+ acquired from the cell and bound at the phi6 RdRp non-catalytic ion site sufficiently weakens the polymerase structure to facilitate the displacement of the CTD. Our crystallographic and biochemical data also indicate that Mn2+ is released during this displacement and must be replaced for the elongation to proceed. Our data explain the role of the non-catalytic divalent cation in vRdRps and pinpoint the Mn2+-dependent step in viral replication. In addition, by inserting a dysfunctional Mg2+ at the non-catalytic ion site for both WT and E634Q RdRps we captured structures with two NTPs bound within the active site in the absence of Watson-Crick base pairing with template and could map movements of divalent cations during preinitiation through to initiation. Oligonucleotides present on the surface of phi6 RdRp allowed mapping of key residues involved in template entry and unwinding of dsRNA; these preinitiation stages have not been observed previously. Considering the high structural homology of phi6 RdRp with other vRdRps, particularly from (+)ssRNA hepatitis C virus (HCV), insights into the mechanistic and structural details of phi6 RdRp are thought to be relevant to the general understanding of vRdRps. 571.4
7	Metal-Catalyzed Radical Polymerization up to High Pressure Schröder, Hendrik 02 September 2015 (has links) No description available. 540 high pressure kinetics spectroscopy pulsed-laser polymerization iron N,O ligands Chemie (PPN62138352X)
8	Kinetics and Mechanism of Cu-Catalyzed Atom Transfer Radical Polymerization Sörensen, Nicolai 26 May 2015 (has links) No description available. 540 copper deactivation termination chain-length dependence electron paramagnetic resonance (EPR) kinetics spectroscopy pulsed-laser polymerization (PLP) Chemie (PPN62138352X)
9	Advances in chain-growth control and analysis of polymer: boosting iodine-mediated polymerizations and mastering band-broadening effects in size-exclusion chromatography Wolpers, Arne 10 November 2014 (has links) No description available. 540 iodine-transfer polymerization (ITP) photopolymerization UV light size-exclusion chromatography band broadening skewing simulations chain-length dependence molar-mass determination correction Chemie (PPN62138352X)
10	Application and characterization of polymer-protein and polymer-membrane interactions Burridge, Kevin Michael 28 June 2021 (has links) No description available. Biochemistry Chemistry Polymer Chemistry Polymers Biophysics Lipid nanoparticles nanodisks macromolecular surfactants antiviral self-disinfecting polymerization RAFT ATRP RDRP bioconjugates membrane proteins protein-polymer conjugates grafting-from grafting-to paramagnetic relaxation enhancement

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