Global ETD Search

81	Analysis of Human Appendiceal Peritoneal Carcinomatosis Samples Infected with Oncolytic Viruses Zerhouni, Siham 11 December 2013 (has links) Peritoneal carcinomatosis (PC), the intra-abdominal dissemination of malignancy, is equated with a 5-year survival of 15%, depending on the source. Appendiceal PC is a challenge to treat as cancer cells are embedded in copious amounts of mucin and are difficult to target. Oncolytic viruses (OVs) preferentially replicate and lyse cancer cells and present a targeted, novel strategy for PC. The hypothesis of this study is that appendiceal PC will show variable susceptibility to OVs and that protein expression in these tumours will predict OV replication efficiency. Human appendiceal PC infected ex-vivo with 4 different OVs displayed variable infectivity and replication by fluorescence microscopy and plaque assay. Immunohistochemistry analysis revealed differential expression of IRF3, pERK and TK in tumour compared to normal appendix. No correlation of protein expression with viral replication was observed. Personalizing OV therapy will be critical in the optimization of future care of patients treated with this modality. Peritoneal carcinomatosis Appendix cancer Oncolytic virus Carcinomatosis Vaccinia virus Herpes simplex virus Maraba virus Farmington virus 0564
82	Analysis of Human Appendiceal Peritoneal Carcinomatosis Samples Infected with Oncolytic Viruses Zerhouni, Siham 11 December 2013 (has links) Peritoneal carcinomatosis (PC), the intra-abdominal dissemination of malignancy, is equated with a 5-year survival of 15%, depending on the source. Appendiceal PC is a challenge to treat as cancer cells are embedded in copious amounts of mucin and are difficult to target. Oncolytic viruses (OVs) preferentially replicate and lyse cancer cells and present a targeted, novel strategy for PC. The hypothesis of this study is that appendiceal PC will show variable susceptibility to OVs and that protein expression in these tumours will predict OV replication efficiency. Human appendiceal PC infected ex-vivo with 4 different OVs displayed variable infectivity and replication by fluorescence microscopy and plaque assay. Immunohistochemistry analysis revealed differential expression of IRF3, pERK and TK in tumour compared to normal appendix. No correlation of protein expression with viral replication was observed. Personalizing OV therapy will be critical in the optimization of future care of patients treated with this modality. Peritoneal carcinomatosis Appendix cancer Oncolytic virus Carcinomatosis Vaccinia virus Herpes simplex virus Maraba virus Farmington virus 0564
83	Vliv interferon regulujícího faktoru 3 na imunitní odpověď proti viru vakcínie v atopickém organismu / Effects of the Interferon regulatory factor 3 on immune responses to vaccinia virus in the atopic organism Pilná, Hana January 2019 (has links) Vaccinia virus (VACV) is an enveloped DNA virus, member of the Orthopoxviridae genus. VACV genome size is about 200 kbp. This huge genome capacity allows VACV to encode a set of factors that are non-essential for virus replication and spread in vitro. While these factors are needed for interfering with host immune responses, VACV remains strongly immunogenic. Cell-mediated and humoral immune responses in atopic disorders are deregulated to a certain extent, leading to complications in case of infection or vaccination with vaccines based on replicating viruses, such as eczema vaccinatum caused by VACV. VACV effects on immune responses consist among others in the inhibition of expression of type I interferon (IFN) at various levels - for example in a specific inhibition of phosphorylation of the interferon regulatory factor-3 (IRF-3) via inhibition of the activity of TANK-binding kinase 1 (TBK 1) that normally phosphorylates IRF-3. Phosphorylation allows IRF-3 to translocate into the nucleus where it initiates transcription of IFNβ followed by induction of expression of IFN and interferon stimulated genes. Expression of these genes is shut down when IRF-3 activity is inhibited. To overcome this block, a recombinant VACV expressing murine IRF-3 under VACV p7.5 promotor (WR-IRF3) was generated....
84	Viral Control of SR Protein Activity Estmer Nilsson, Camilla January 2001 (has links) <p>Viruses modulate biosynthetic machineries of the host cell for a rapid and efficient virus replication. One important way of modulating protein activity in eukaryotic cells is by reversible phosphorylation. In this thesis we have studied adenovirus and vaccinia virus, two DNA viruses with different replication stategies. Adenovirus replicates and assembles new virions in the nucleus, requiring the host cell transcription and splicing machinieries, whereas vaccinia virus replicates in the cytoplasm, only requiring the cellular translation machinery for its replication. </p><p>Adenovirus uses alternative RNA splicing to produce its proteins. We have shown that adenovirus takes over the cellular splicing machinery by modulating the activity of the essential cellular SR family of splicing factors. Vaccinia virus, that does not use RNA splicing, was shown to completely inactivate SR proteins as splicing regulatory factors. SR proteins are highly phosphorylated, a modification which is important for their activity as regulators of cellular pre-mRNA splicing. We have found that reversible phosphorylation of SR proteins is one mechanism to regulate alternative RNA splicing. We have demonstrated that adenovirus and vaccinia virus induce SR protein dephosphorylation, which inhibit their activity as splicing repressor and splicing activator proteins. We further showed that the adenovirus E4-ORF4 protein, which binds to the cellular protein phosphatase 2A, induced dephosphorylation of a specific SR protein, ASF/SF2, and that this mechanism was important for regulation of adenovirus alternative RNA splicing.</p><p>Inhibition of cellular pre-mRNA splicing results in a block in nuclear- to cytoplasmic transport of cellular mRNAs, ensuring free access of viral mRNAs to the translation machinery. We propose that SR protein dephosphorylation may be a general viral mechanism by which mammalian viruses take control over host cell gene expression.</p> Biochemistry adenovirus ASF/SF2 dephosphorylation E4-ORF4 L1 MLTU PP2A splicing SR proteins vaccinia virus Biokemi Biochemistry Biokemi
85	Viral Control of SR Protein Activity Estmer Nilsson, Camilla January 2001 (has links) Viruses modulate biosynthetic machineries of the host cell for a rapid and efficient virus replication. One important way of modulating protein activity in eukaryotic cells is by reversible phosphorylation. In this thesis we have studied adenovirus and vaccinia virus, two DNA viruses with different replication stategies. Adenovirus replicates and assembles new virions in the nucleus, requiring the host cell transcription and splicing machinieries, whereas vaccinia virus replicates in the cytoplasm, only requiring the cellular translation machinery for its replication. Adenovirus uses alternative RNA splicing to produce its proteins. We have shown that adenovirus takes over the cellular splicing machinery by modulating the activity of the essential cellular SR family of splicing factors. Vaccinia virus, that does not use RNA splicing, was shown to completely inactivate SR proteins as splicing regulatory factors. SR proteins are highly phosphorylated, a modification which is important for their activity as regulators of cellular pre-mRNA splicing. We have found that reversible phosphorylation of SR proteins is one mechanism to regulate alternative RNA splicing. We have demonstrated that adenovirus and vaccinia virus induce SR protein dephosphorylation, which inhibit their activity as splicing repressor and splicing activator proteins. We further showed that the adenovirus E4-ORF4 protein, which binds to the cellular protein phosphatase 2A, induced dephosphorylation of a specific SR protein, ASF/SF2, and that this mechanism was important for regulation of adenovirus alternative RNA splicing. Inhibition of cellular pre-mRNA splicing results in a block in nuclear- to cytoplasmic transport of cellular mRNAs, ensuring free access of viral mRNAs to the translation machinery. We propose that SR protein dephosphorylation may be a general viral mechanism by which mammalian viruses take control over host cell gene expression. Biochemistry adenovirus ASF/SF2 dephosphorylation E4-ORF4 L1 MLTU PP2A splicing SR proteins vaccinia virus Biokemi Biochemistry Biokemi
86	Mechanisms of Host-Range Function of Vaccinia Virus K1L Gene: a Dissertation Bradley, Ritu Rakshit 13 July 2005 (has links) The KIL gene of vaccinia virus encodes for a host range protein; in the absence of which, the virus is unable to grow in certain cell lines (RK-13 and some human cell lines). KIL function can be complemented in RK-13 cells by the cowpox host range gene product CP77 despite a lack of homology between the two proteins except for ankyrin repeats. We investigated the role of ankyrin repeats ofthe K1L gene in the host-range restriction of growth in RK-13 cells. The growth of a recombinant vaccinia virus, with the K1L gene mutated in the most conserved ankyrin repeat, was severely impaired as evidenced by lack of plaque formation and reduction in viral titers. Infection of RK-I3 cells with the mutant recombinant vaccinia virus resulted in total shutdown of both cellular and viral protein synthesis early in infection, indicating that the host restriction mediated by the ankyrin repeat is due to a translational block. A comparison of the cellular localization of the K1L wild type and mutated forms showed no difference, as both localized exclusively in the cytoplasm of RK-I3 cells. We also investigated the interaction of the vaccinia virus K1L protein with cellular proteins in RK-13 cells and co-immunoprecipitated a 90 kDa protein identified as the rabbit homologue of human ACAP2, a GTPase-activating protein with ankyrin repeats. Our result suggests the importance of ankyrin repeat for host-range function of K1L in RK-13 cells and identifies ACAP2 as a cellular protein which may be interacting with K1L. Vaccinia virus GTPase-Activating Proteins Orthopoxvirus Amino Acids, Peptides, and Proteins Genetic Phenomena Life Sciences Medicine and Health Sciences Viruses
87	Développement d'un vecteur virus de la vaccine, réplicatif et atténué, pour la vaccination antivariolique et pour la vaccination contre la fièvre hémorragique à virus Ebola / Development of an attenuated replicative Vaccinia virus vector to protect against Variola and Ebola haemorragic fever Dimier, Julie 30 October 2012 (has links) Le virus Ebola, responsable d'une fièvre hémorragique virale létale et le virus de la variole, agent étiologique de la variole, sont des armes biologiques potentielles. Il n'existe pas de traitement ou de prophylaxie autorisés contre le virus Ebola, quelques candidats vaccins étant en cours de développement. Concernant la variole, des vaccins dits de première génération (virus de la vaccine) ont permis l'éradication de la maladie cependant ils sont à l'origine de complications post-vaccinales parfois sévères alors que des vaccins plus récents dits de troisième génération, non-réplicatifs, ont été développés pour leur innocuité mais restent faiblement immunogènes. Nous avons récemment développé plusieurs vecteurs viraux de type virus de la vaccine (VACV) par délétion d'un certain nombre de facteurs de virulence. Nous avons évalué leur innocuité, leur immunogénicité et leur efficacité en tant que candidats vaccins antivarioliques chez la souris puis utilisé l'un de ces vecteurs pour développer un candidat vaccin bivalent antivariolique et anti-virus Ebola. Ces virus de la vaccine délétés sont réplicatifs mais fortement atténués. Ils induisent une réponse en anticorps neutralisants spécifiques anti-vaccine similaire à celle induite par le vaccin antivariolique de première génération et induisent des réponses immunitaires cellulaires CD4+ et CD8+ spécifiques suffisantes pour protéger l'animal d'un challenge létal de cowpoxvirus en intranasal, simulant une infection par le virus de la variole. Le virus délété le plus immunogène et le plus sûr, nommé MVL, a été utilisé pour construire un vecteur viral codant pour la glycoprotéine du virus Ebola (EGP). Le gène entier d'EGP ou une forme chimérique d'EGP (fusion entre l'ectodomaine d'EGP et le domaine transmembranaire de la glycoprotéine B5 du VACV) ont été clonés dans le génome du vecteur viral. Ces deux vecteurs produisent des virus ayant incorporé EGP dans leur enveloppe. Ces deux candidats vaccins recombinants induisent de fortes réponses humorales spécifiques anti-EGP et anti-vaccine chez la souris immunocompétente. En conclusion, nous avons développé plusieurs candidats vaccins antivarioliques aussi immunogènes et efficaces que le vaccin historique et avec une atténuation similaire aux vaccins de troisième génération. L'un de ces candidats (MVL) a été utilisé comme vecteur viral pour exprimer la glycoprotéine hétérologue EGP, contre laquelle il induit une réponse immunitaire humorale forte / Ebola virus, causing a lethal haemorrhagic fever and variola virus, the agent of smallpox are potential biological weapons. There is no treatment and no prophylaxis authorised against Ebola, although some vaccine viral vectors were developed these last years. Concerning smallpox, several types of vaccines exist against smallpox (based on vaccinia virus), first generation that allowed the disease eradication but responsible of some post-vaccination complications and some non-replicative 3rd generation vaccines which are safe but not very immunogenic. We have recently developed several vaccinia virus (VACV) vectors by deletion of some virulence genes, and we have evaluated their safety, immunogenicity and efficacy as smallpox vaccine in mice and used one of them as a bivalent vaccine against Ebola and smallpox. These viral vectors are higly attenuated and replicative competent. They induce a neutralizing specific-VACV antibodies response similar to that of the historical vaccine and induce VACV-specific CD8+ and CD4+ immune responses efficient to protect immunocompetent mouse model intranasally infected by cowpox virus, simulating variola virus infection.The most safety and immunogenic vaccinia virus vector, named MVL, has been used to construct a vector encoding the Ebola glycoprotein (EGP) for immunization against Ebola. The native EGP gene or a chimeric EGP gene (a fusion between the EGP ectodomain and the transmembrane domain of the VACV B5 glycoprotein) have been cloned into the viral vector genome. These two recombinant vaccine candidates induce specific humoral immune responses against Ebola and vaccinia virus in immunocompetent mice. In conclusion, we have developed several vaccine candidates against smallpox as immunogenic and protective as the historical vaccine and as safe as 3rd generation vaccines. One of these candidates, MVL, has been used as a viral vector to express the heterologous glycoprotein EGP, against which it induce a strong humoral immune response. Vaccin Virus de la vaccine Virus Ebola Variole Fièvre hémorragique virale Vaccine Vaccinia virus Ebola virus Smallpox Viral haemorrhagic fever
88	New approaches for improving the immunogenicity of modified vaccinia virus Ankara as a recombinant vaccine vector Alharbi, Naif K. January 2014 (has links) No description available. 615.3
89	Selection and characterization of human recombinant antibodies against Orthopoxviruses from an immunoglobulin library and mapping of functional epitopes of Vaccinia virus surface proteins Ahsendorf, Henrike 04 November 2019 (has links) No description available. 630 Vaccinia virus epitope mapping antibody engineering recombinant proteins immunoglobulin library recombinant antibodies Orthopoxvirus Land- und Forstwirtschaft (PPN621302791)
90	Investigation of the mechanisms of ozone-mediated viral inactivation Ohmine, Seiga 10 July 2005 (has links) (PDF) Previous studies have established that ozone-oxygen mixtures can be used to inactivate a variety of microorganisms including bacteria, fungi and viruses. Ozone is a potent reactive oxygen species (ROS) that rapidly decays into a variety of additional short half-life ROS which have been shown to cause oxidative damage to biological molecules. I hypothesize that controlled ozone exposure and the subsequent generation of additional ROS would reduce viral infectivity by lipid and/or protein peroxidation. A proprietary ozone-oxygen delivery system was used to inactivate a series of enveloped [herpes simplex virus type-1 strain McIntyre (HSV-1), vaccinia strain Elstree (VAC), vesicular stomatitis virus strain Indiana (VSV), and influenza A strain (H1N1) A/WS/33] and non-enveloped [human adenovirus type2 (Ad2)] viruses. Plaque reduction and suspension-infection viral antigen assays were used to determine inactivation kinetics. After ozonation, HSV-1 and VSV lost up to 6 log10 infectious particles in 15 min, while VAC and influenza A lost up to 5 log10 in 40 min and 30 min, respectively. In comparison, the non-enveloped Ad2 lost up to 5 log10 in 60 min. Increasing amounts of serum supplementation in the ozone treated virus suspensions slowed the rate of inactivation in both enveloped and non-enveloped viruses, suggesting the protective effect of serum against ozone. Lipid peroxidation was determined through a chromogenic assay for malondialdehyde (MDA), a byproduct of peroxidation events. MDA concentrations were inversely correlated with virus infectivity, as MDA concentrations elevated with virus exposure time to ozone. Transmission electron microscopy images of Ad2, HSV-1, VAC and VSV confirmed the drastic morphological changes that resulted from ozone treatment. The ROS-mediated attack compromised the integrity of the lipid envelopes and protein shells of the viruses. These data suggest that a wide range of viruses can be inactivated through use of an innovative ozone delivery system, thus validating my hypothesis. ozone virus adenovirus herpes simplex virus influenza vaccinia virus vesicular stomatitis virus reactive oxygen species (ROS) Microbiology

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