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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.
11

NUCLEAR IMPORT AND INTERACTIONS OF POTATO YELLOW DWARF VIRUS NUCLEOCAPSID, MATRIX, AND PHOSPHOPROTEIN

Anderson, Gavin Lloyd Franklin 01 January 2014 (has links)
Potato yellow dwarf virus (PYDV) is the type species of the genus Nucleorhabdovirus and, like all members of this genus, replication and morphogenesis occurs inside the nuclei of infected cells. Protein localization prediction algorithms failed to identify a nuclear localization signal (NLS) in PYDV nucleocapsid (N) protein, although PYDV-N has been shown to localize exclusively to the nucleus when expressed as a green fluorescent protein (GFP):N fusion in plant cells. Deletion analysis and alanine-scanning mutagenesis identified two amino acid motifs, 419QKR421 and 432KR433, that were shown to be essential for nuclear import and interaction with importin-α. Additional bimolecular fluorescence complementation showed that the PYDV-N-NLS mutants cannot be ferried into the nucleus via interaction with PYDV-P or-M. In contrast, interaction with N-NLS mutants appeared to retard the nuclear import of PYDV-P. Taken together, it was determined that PYDV-N contains the bipartite NLS 419QKRANEEAPPAAQKR433. Similarly, alanine-scanning mutagenesis was performed to determine the regions responsible for the nuclear import of PYDV-M and -P. A non-canonical NLS was identified in PYDV-P, consisting of three regions in the N-terminus of the protein required for nuclear import. PYDV-P does not interact with any Nicotiana benthamiana importins, but was found to interact with importin-α7 and -α9 of the non-host plant Arabidopsis thaliana. Two amino acids of PYDV-M, 225KR226, were found to be critical for nuclear import and interaction with importin-α. In addition, site-directed mutagenesis identified that amino acids 223LL224 of PYDV-M, which are adjacent to the two amino acids identified as responsible for nuclear import, are critical for inducing invaginations of the inner nuclear membrane. Bimolecular fluorescence complementation (BiFC) was then used to identify any differences in localization and interaction caused by the mutations introduced to PYDV-P and -M. The PYDV-P and -M proteins were still able to interact with other PYDV proteins, although the localization of the interaction differs between mutants.
12

Novirhabdovirus Infection in Wild-Type and Rag1 Mutant Zebrafish Suggests Roles of Lymphocytes in Resistance

Nguyen, Du Ngoc 12 August 2016 (has links) (PDF)
Disease development of wild-type and Rag1 mutant zebrafish was evaluated after challenge with Snakehead Rhabdovirus (SHRV), a novirhabdovirus. Rag1 mutants lack T and B lymphocytes and thus lack lymphocyte-based acquired immunity. Wild-type zebrafish became more disease resistant as they aged (4 months and older) and at an elevated temperature (28°C) but mutants remained sensitive at all ages and temperatures tested. Quantitative reverse transcription polymerase chain reaction (RT qPCR) demonstrated that interferon gamma and MxA expression significantly increased in both types of fish at 2 days post-infection with subsequent dwindling of expression. The high interferon gamma expression suggests activation of natural killer cells (and/or T lymphocytes in wild-type fish), and the up-regulation of MxA expression indicated an activation of type 1 interferon response. The development of protection in virus exposed fish was evaluated by lethal challenge at 3 weeks post vaccination. Vaccinated wild-type fish showed significant protection and while most of the mutant groups showed no protection. One vaccination treatment group of the mutants demonstrated a significantly slower mortality and less overall mortality. The results suggest that lymphocyte based immunity imparts a robust protective response to SHRV while low-level protection can develop in the absence of lymphocytes. A cell mediated cytotoxicity assay was established. Cell lines were developed from the inbred fish populations and class I MHC U lineage genes were compared. The mhc1uba and mhc1uca genes were found in the mutant and cells but no class I MHC U lineage genes were detected in the wild-type fish or cells. These cells were used as targets in cytotoxicity assays. Kidney-marrow cells of vaccinated mutant or wild-type zebrafish killed more SHRV infected target cells than did those from non-vaccinated fish with the wild-type effectors showing higher cytotoxicity. The lymphocyte component appears responsible for the temperature and age associated resistance. This helps explain why novirhabdoviruses cause higher losses in young fish and at low temperatures. Further studies are needed to understand the relative contribution of the cellular components that play important role in SHRV resistance, but the establishment of cytotoxicity assays is an important first step in dissecting the cellular defenses in zebrafish.
13

STRAIN-SPECIFIC PROTEIN INTERACTION AND LOCALIZATION OF TWO STRAINS OF POTATO YELLOW DWARF VIRUS AND FUNCTIONAL DOMAINS OF THEIR MATRIX PROTEIN

Jang, Chanyong 01 January 2019 (has links)
Potato yellow dwarf virus (PYDV) is the type species of the genus nucleorhabdovirus which is typified by its nucleotropic characters of the members. The virus accomplishes its replication and morphogenesis in the nuclei of infected cells. Two strains, Constricta strain (CYDV) and Sanguinolenta strain (SYDV) have been described at the level of vector-specificity. CYDV is vectored by Agallia constricta and SYDV is transmitted by Aceratagllia sanguinolenta. The full-length genome of CYDV was sequenced. The 12,792 nt antisense genome encodes seven open reading frames in the order of, nucleocapsid protein (N), unknown protein (X), phosphoprotein (P), movement protein (Y), matrix protein (M), glycoprotein (G), and large polymerase protein (L). The features of each protein including a nuclear localization signal, isoelectric point, and transmembrane domain, were determined by predictive algorithms. The gene coding region was flanked by leader and trailer, and each ORF was separated by a conserved intergenic junction. In the intergenic junctions, the highly conserved cis-regulatory elements, polyadenylation signal, gene spacer, and transcription start site, were identified. The similarities of amino acid sequences between each cognate protein of SYDV and CYDV were higher than 80% except for X and P proteins. The protein localization and interaction assays of each CYDV protein identified strain-specific associations in comparison with those of SYDV and generated unique protein interaction and localization map compared to SYDV. Phylogenetic analysis using L protein identified that CYDV forms a clade with other leafhopper-transmitted rhabdoviruses. Protein sequence comparisons revealed that CYDV X has greater similarity to the cognate protein of Eggplant mottle disease virus than to SYDV X. The localization patterns of CYDV-N and -Y were different compared the cognate proteins of SYDV. The functional nuclear export domain of SYDV M was identified using c-terminal fragments of the Mwt(aa 211-243), MLL223AA(aa 211-243), and MKR225AA(aa 211-243). Based on the data, the functional domains M mediating membrane association, nuclear import and export were mapped for both strains and suggested a model whereby M mediates intra- and intercellular movement of PYDV nucleocapsid.
14

Endogenous Lymphocytes Play a Critical Role in the Elimination of Solid Tumors in the Context of Adoptive Cell Combined with Oncolytic Vaccination / COOPERATION BETWEEN ENDOGENOUS LYMPHOCYTES AND ACT

Simovic, Boris January 2016 (has links)
A major obstacle in the implementation of adoptive cell therapy (ACT) for solid tumors is CD8+ T cell quantity and functional quality. In order to address this issue, the ACT field has directed considerable effort toward the generation of less-differentiated memory T cells (Tm), which demonstrate superior effector function and engraftment over effector T cells. An obstacle in using Tm for ACT is their requirement for in vivo activation before full effector function can be acquired. We sought to determine if a rhabdovirus expressing a defined tumor antigen (i.e. a rhabdoviral oncolytic vaccine) could activate adoptively-transferred Tm in vivo and eliminate established tumors. We used ex vivo cultured DUC18 TCR-transgenic Tm combined with a rhabdoviral oncolytic vaccine to target established CMS5 fibrosarcomas in both balb/c and NRG mice, and we compared the efficacy of the combination treatment versus monotherapies. Our data demonstrate that the rhabdoviral oncolytic vaccine was capable of expanding adoptively-transferred Tm in order to eliminate established tumors. Furthermore, synergy between ACT and oncolytic vaccination was required for optimal therapeutic outcome. Interestingly, we observed a population of endogenous, tumor-primed lymphocytes which appeared to be required for complete tumor elimination and subsequent memory formation. This was in contrast to the current consensus in the ACT field which is that endogenous lymphocytes are detrimental to therapeutic outcome, thus necessitating lymphodepletion prior to the commencement of therapy. Our data suggest that endogenous lymphocytes may be a beneficial cell population which is overlooked by current approaches to ACT. / Thesis / Master of Science (MSc) / Current approaches to the T cell therapy of cancer are hindered by poor cell quality. It is simple to grow higher quality T cells, but it is difficult to grow very large numbers of them. Furthermore, higher quality T cells need a signal in order to “switch on” before they can start killing cancer cells. Here, we use a cancer-targeting virus as a signal for these cells to activate, grow to very large numbers in the patient, and destroy their tumor. Our vaccine also switches on other immune cells in the patient, which help guarantee the destruction of the tumor. The significance of this work is that it will improve T cell therapy for cancer by opening the possibility of using higher-quality T cells which are much better at killing cancer than the currently used type of T cells.
15

Caractérisation du complexe de fusion des rhabdovirus.

Roche, Stéphane 30 November 2004 (has links) (PDF)
La fusion membranaire est un processus biologique courant que l'on retrouve notamment lors de l'exocytose, du trafic intracellulaire ou de l'entrée des virus dans les cellules. Dans le cas des rhabdovirus, une famille où l'on retrouve notamment le virus de la rage (RV) et le virus de la stomatite vésiculaire (VSV),cette fonction est assurée à pH légèrement acide par la glycoprotéine G. Cette protéine existe sous au moins trois conformations distinctes : à pH neutre, elle est présente sous une conformation native (N). Après une brève incubation à pH acide, elle est présente sous une conformation activée (A), sous laquelle elle est capable d'interagir avec une membrane cible par l'intermédiaire d'un peptide hydrophobe. Enfin, après une incubation prolongée à pH acide, elle apparaît sous une conformation inactivée (I) et est alors incapable d'induire la fusion membranaire. Contrairement à toutes les autres familles virales étudiées à ce jour, il existe un équilibre dépendant du pH entre ces conformations. De nombreuses données dans divers systèmes suggèrent qu'une protéine unique ne serait pas suffisante pour catalyser les processus de fusion membranaire, mais qu'au contraire une machinerie constituée d'un nombre plus ou moins important de protéines fusogènes serait nécessaire. Au cours de ce travail, nous avons étudié certaines propriétés du complexe de fusion des rhabdovirus. Nous avons ainsi montré qu'il était de grande taille et qu il était probablement plus grand que ce qui avait été proposé pour d autres familles virales. De plus, il est apparu que le complexe de fusion du virus rabique n avait pas une unique architecture possible, mais qu il existait au contraire divers types de complexe. Ensuite, l'observation par microscopie électronique de particules virales en train de fusionner avec des liposomes nous a montré que le processus de fusion induit par VSV se produisait toujours par la base et qu il s accompagnait d une redisposition complète des glycoprotéines à la surface du virus suivant un réseau hélicoïdal. Enfin, nous sommes parvenu à isoler l ectodomaine de G et à en obtenir des cristaux diffractant à 3,5 Å, ce qui permet d envisager à terme une résolution de la structure de G. L étude de l interaction entre l ectodomaine de G et des liposomes nous a permis de reproduire les réseaux hélicoïdaux observés à la surface du virus et d étudier leurs propriétés. L ensemble de ces données nous a permis de proposer un nouveau modèle pour le processus de fusion chez les rhabdovirus, mais il pourrait également être pertinent pour d autres familles virales.

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