Global ETD Search

1	Desenvolvimento e aplicação biotecnológica de replicons repórteres para triagem de drogas antivirais contra o vírus da febre amarela Gomes de Oliveira, Amanda 31 January 2011 (has links) Made available in DSpace on 2014-06-12T18:01:54Z (GMT). No. of bitstreams: 2 arquivo3099_1.pdf: 5591692 bytes, checksum: 07230239ef4ede2c2128b63b2068f8bc (MD5) license.txt: 1748 bytes, checksum: 8a4605be74aa9ea9d79846c1fba20a33 (MD5) Previous issue date: 2011 / Faculdade de Amparo à Ciência e Tecnologia do Estado de Pernambuco / A re-emergência da febre amarela e sua significância como um problema de saúde pública tem gerado um interesse para o desenvolvimento de novas ferramentas vacinais e agentes antivirais contra este vírus. Drogas antivirais, específicas para o vírus da febre amarela, não estão disponíveis para a população e cerca de 200.000 casos são estimados por ano no mundo. Métodos tradicionais para triagem de antivirais são laboriosos, demorados e dificultosos para serem utilizados em testes em larga escala. O objetivo deste trabalho foi avaliar as propriedades antivirais de diversos substratos naturais da biblioteca da Fiocruz-MG, usando uma linhagem celular estável expressando um replicon bicistrônico do vírus da febre amarela. O replicon nomeado rep-FA17D-LucNeoIres foi construído em nosso laboratório, através da deleção da proteínas estruturais virais e inserção dos genes do repórter Luciferase firefly, neomicina fosfotransferase, e um elemento Ires (Internal Ribosome Entry Site) para a tradução das proteínas não-estruturais virais. Assim, a replicação do genoma do replicon pode ser mensurada pela expressão do gene repórter Luciferase. Neste estudo nós analisamos cerca de 2000 extratos naturais brasileiros (através de um ensaio em larga escala) utilizando-se a linhagem celular BHK-21-rep-FA17D-LucNeoIres, a qual expressa constitutivamente o replicon construído. A eficiência deste sistema foi comprovada inicialmente através de uma caracterização criteriosa, com ensaios de replicação celular e utilização do antiviral interferon alfa, os quais comprovaram que o método desenvolvido é sensível, rápido e muito eficiente para triagem de drogas antivirais em larga escala. Entre os extratos naturais estudados, trinta e cinco extratos apresentaram uma inibição de 50% ou mais na expressão do gene repórter luciferase, sendo que nenhum destes extratos apresentou características citotóxicas. Estudos adicionais estão sendo realizados para a caracterização antiviral destes 35 extratos identificados. No presente estudo foi desenvolvida uma técnica inovadora de triagem antiviral e os resultados obtidos com os extratos naturais podem ser de grande impacto para a identificação e desenvolvimento de drogas antivirais contra flaviviroses Febre Amarela Antivirais Replicon
2	Characterisation of a replicon of the conjugative, multiple drug resistance, moderately promiscuous, plasmid pGSH500 Tatley, Fernanda Maria Palma Ribeiro da Silva 14 July 2017 (has links) No description available. Plasmids - analysis Replicon
3	Induction of Apoptosis by Rubella Virus Non-Structural Replicase and Rescue by Capsid Kanak, Alison Elizabeth 29 September 2008 (has links) As a model for studying apoptosis associated with pathogenesis of congenital rubella syndrome, bicistronic rubella virus (RUBV) replicons expressing an antibiotic resistance gene in the presence (925-IN) or absence (IN-IN) of RUBV capsid protein (C) were constructed. Apoptosis was assessed by detection of caspase activation, chromatin fragmentation, and flow cytometry. 925-IN cells grew similarly to Vero, but IN-IN cells demonstrated caspase activation, chromatin fragmentation and cell cycle arrest. Whereas Vero cells transfected with P150 exhibited rapid apoptosis not detected in transfected Vero cells stably expressing C, neither exhibited cell cycle alterations, indicating a cell cycle stall not associated with apoptosis. Finally, two human epithelial cells, HEK293 and A549, transfected with P150 failed to exhibit apoptosis, indicating that while replicon-transfected Vero cells are useful for studying apoptosis and cell cycle arrest, the results are not applicable to other cell types. apoptosis replicon rubella congenital rubella syndrome
4	Development of a foot-and-mouth disease virus replicon system for the study of RNA replication Tulloch, Fiona January 2015 (has links) Foot-and-mouth disease (FMD) is a highly infectious disease of wild and domestic cloven–hoofed animals such as cattle, swine and deer. It is caused by one of the most contagious animal diseases known; FMD virus (FMDV). Since the disease is endemic in many countries, transmission by international travel/trade presents an on-going potential threat to the UK. Very little is known at the molecular level about how FMDV replicates within host cells. In this study, FMDV replicons have been used to investigate FMDV RNA replication and to improve our understanding of the viral life cycle: a process which will aid in the production of a new generation of live-attenuated vaccine candidate strains. Sequences encoding the capsid coding region of the genome have been replaced with green fluorescent protein (GFP) such that replication can be monitored in live cells via GFP fluorescence. This provides a rapid, non-invasive screen for replicative fitness that can be used outwith high disease security facilities. Differences between replicating and non-replicating forms could easily be distinguished, highlighting the potential of this system to screen for attenuated genomes. The FMDV replicon system was improved through a series of construct modifications until an optimal system was produced. A range of different methods were used to attenuate the replication of these genomes. Of major significance is the finding that increasing dinucleotide frequencies were shown to decrease growth kinetics of Echovirus 7 – as opposed to altering the codon-pair bias - and the application of this finding to construction of further replicon systems (and RNA viruses in general) is described. 579.2
5	Induction of Apoptosis by Rubella Virus Non-Structural Replicase and Rescue by Capsid Kanak, Alison Elizabeth 29 September 2008 (has links) As a model for studying apoptosis associated with pathogenesis of congenital rubella syndrome, bicistronic rubella virus (RUBV) replicons expressing an antibiotic resistance gene in the presence (925-IN) or absence (IN-IN) of RUBV capsid protein (C) were constructed. Apoptosis was assessed by detection of caspase activation, chromatin fragmentation, and flow cytometry. 925-IN cells grew similarly to Vero, but IN-IN cells demonstrated caspase activation, chromatin fragmentation and cell cycle arrest. Whereas Vero cells transfected with P150 exhibited rapid apoptosis not detected in transfected Vero cells stably expressing C, neither exhibited cell cycle alterations, indicating a cell cycle stall not associated with apoptosis. Finally, two human epithelial cells, HEK293 and A549, transfected with P150 failed to exhibit apoptosis, indicating that while replicon-transfected Vero cells are useful for studying apoptosis and cell cycle arrest, the results are not applicable to other cell types. apoptosis replicon rubella congenital rubella syndrome Biology, general
6	Estratégias moleculares para utilização do vírus da febre amarela como vetor vacinal / Molecular strategies to use the yellow fever virus as a vaccine vector Queiroz, Sabrina Ribeiro de Almeida January 2011 (has links) Made available in DSpace on 2015-06-01T19:28:08Z (GMT). No. of bitstreams: 2 501.pdf: 2806630 bytes, checksum: 5dbcbb44377fbc1620ff4879d96a08d9 (MD5) license.txt: 1748 bytes, checksum: 8a4605be74aa9ea9d79846c1fba20a33 (MD5) Previous issue date: 2011 / A vacina da febre amarela 17D (YFV-17D) é bastante segura e uma dose única confere imunidade potente e duradoura. Por essas e outras características, diferentes tecnologias têm sido propostas para a utilização da cepa 17D como vetor vacinal. Estratégias promissoras para o desenvolvimento de novas vacinas têm se baseado na construção de quimeras YFV-17D com inserção de seqüências heterólogas e produção em larga escala de replicons empacotados em partículas pseudo-infecciosas (PPIs), no entanto, ainda não existe um consenso da melhor estratégia a ser utilizada para esses fins. O presente estudo teve por objetivo avaliar diferentes estratégias de construção para a utilização do YFV-17D como vetor vacinal. Para isso foram construídos duas quimeras do YFV-17D com inserção de um gene repórter YFP (Yellow Fluorescent Protein) na junção E/NS1 e dois replicons subgenômicos do YFV-17D expressando o gene repórter luciferase. Para a produção de PPIs foi desenvolvida a linhagem HEK-YFV-prM/E-opt. O YFV-YFPSSE revelou instabilidade genética com perda do gene YFP e correlação negativa entre expressão de proteínas virais e do gene repórter. O YFV-YFP-DENV1linker mostrou-se estável geneticamente com expressão eficiente de YFP e proteínas virais, e mostrou-se ser o mais adequado para ser utilizado como vetor viral. Os replicons do YFV-17D mostraram-se funcionais e capazes de expressar eficientemente o gene heterólogo. E, embora a linhagem HEK-YFV-prM/E-opt tenha expressado as proteínas estruturais prM e E eficientemente, poucas partículas pseudo-infecciosas foram produzidas. Diante do exposto, as diferentes estratégias de manipulação genética do YFV avaliadas neste trabalho constituem ferramentas viáveis e aplicáveis ao processo de desenvolvimento de vacinas, havendo, porém, necessidade de otimização dessas estratégias para assegurar maiores segurança e eficácia Vírus da febre amarela/genética Vacinas sintéticas DNA recombinante Replicon
7	A Respiratory Syncytial Virus Replicon That Is Non-Cytotoxic and Capable of Long-Term Foreign Gene Expression Malykhina, Olga 28 July 2011 (has links) No description available. Virology RSV respiratory syncytial virus replicon chronic infection
8	Functional Analyses of West Nile Virus (WNV) Bicistronic Replicons Containing Different Sequence Elements and of Simian Hemorrhagic Fever Virus (SHFV) Polyprotein Processing Radu, Gertrud Ulrike 29 November 2007 (has links) The flavivirus West Nile virus (WNV) encodes a single polyprotein that is processed into three structural and seven nonstructural proteins. Various WNV bicistronic replicons that direct cap-dependent translation of an N-terminal viral capsid or capsid/Renilla luciferase fusion protein as well as IRES-dependent translation of the nonstructural proteins were constructed. An original replicon consisting of the WNV 5' NCR, the 5' 198 nts of the capsid coding sequence, which included the 5' cyclization sequence (Cyc), and an EMCV IRES followed by the WNV nonstructural genes and 3' NCR was generated. Real time qRT-PCR analysis of intracellular levels of this replicon RNA showed a 4 fold increase by 96 hr after transfection of BHK cells. Increasing the distance between the 5' Cyc and IRES by insertion of a 5' IRES flanking sequence alone or together with a Renilla luciferase reporter did not increase RNA replication. Addition of only a reporter decreased RNA replication. The insertion of an extended capsid coding sequence also did not enhance RNA replication, but did enhance both cap- and IRES-dependent translation of replicon RNA, as indicated by immunofluorescence and Western blot analysis. These results suggest the presence of a translation enhancer in the 3' portion of the capsid coding region. Simian hemorrhagic fever virus (SHFV) is a member of the family Arteriviridae, order Nidovirales. SHFV is unique among Nidoviruses in having three instead of two papain-like cysteine protease (PCP) motifs designated alpha, beta, and gamma, within the N-terminal region of its ORF1a. Mutations of putative PCP cleavage sites showed that the most efficient cleavage was by PCP beta at its downstream cleavage site. A large deletion located between the two catalytic residues of PCP alpha was hypothesized to render this protease inactive. However, processing was observed at the cleavage site following PCP alpha. Mutational analyses confirmed that PCP alpha is an inactive protease, and that the cleavage sites downstream of PCP alpha are cleaved by PCP gamma. When the catalytic residues of PCP gamma were mutated, PCP beta was also able to back cleave at these sites. This "back" cleavage is a previously unreported activity for an arterivirus PCP. Papain-like cysteine protease West Nile virus IRES Capsid Simian hemorrhagic fever virus Translation RNA Replication Replicon Biology, general
9	Detection of plasmid families carrying ESBL genes in clinical and environmental E. coli and K. pneumoniae isolates / Detektion av plasmidfamiljer som bär ESBL-gener i E. coli och K. pneumoniae isolerade från klinik och miljö Nilsson, Johanna January 2019 (has links) Extended Spectrum β-Lactamases (ESBLs) are produced by the Enterobacteriaceae bacterial family, mainly by E. coli and K. pneumoniae. As these species are some of the main causes of urinary tract infections and sepsis, ESBL-production is of major concern. Occurrence of ESBLs also gives rise to concern as it is increasing epidemically. This because the genes coding for ESBLs (i.e. bla-genes) are located on plasmids replicating and spreading the replicated copies independently. Plasmids replicate by replicons. Plasmids with the same replicon variant are grouped into the same plasmid family. The aim of this study was to detect plasmid families carrying bla-genes in E. coli and K. pneumoniae from clinical (n = 6) and environmental water (n = 22) isolates. Plasmid family prevalence was examined. Association between plasmid families and bla-genes was also examined. Plasmid families were detected by a PBRT kit (PCR Based Replicon Typing), a multiplex PCR kit that detected 30 replicons, whereof 27 replicons representing the 27 plasmid families in Enterobacteriaceae, and three novel replicons. The IncF plasmid family was the most prevalent for both species in both clinical and environmental isolates. IncF seemed to be prevalent for all examined ESBLs, but it was difficult to associate one bla-gene with one plasmid family as most isolates carried several bla-genes and several plasmid families. / Extended Spectrum β-Lactamases (ESBLs) produceras av bakteriefamiljen Enterobacteriaceae, främst av E. coli och K. pneumoniae. Eftersom dessa arter är bland de vanligaste orsakerna till urinvägsinfektioner och sepsis är ESBL-produktion ett allvarligt problem. ESBL är också oroande eftersom det sprids epidemiskt. Detta möjliggörs av att generna som kodar för ESBLs (s.k. bla-gener) ligger på plasmider, som replikerar och sprider de replikerade plasmidkopiorna självständigt. Plasmider replikeras som s.k. replikon. Plasmider med samma replikonvariant tillhör samma plasmidfamilj. Syftet med detta arbete var att detektera plasmidfamiljer som bär bla-gener i E. coli och K. pneumoniae isolerade från kliniska prov (n = 6) och miljöprov (n = 22) från Helge Å. Plasmidfamiljernas prevalens undersöktes, liksom sambandet mellan plasmidfamiljer och bla-gener. Plasmidfamiljerna detekterades med ett PBRT-kit (PCR Based Replicon Typing), ett multiplext PCR-kit som detekterade 30 replikon varav 27 replikon som representerar de 27 plasmidfamiljer som finns i Enterobacteriaceae och tre nya replikon. Plasmidfamiljen IncF var vanligast förekommande i båda arter i både kliniska isolat och miljöisolat. IncF verkade förekomma för alla undersökta typer av ESBL, men det var generellt svårt att förknippa en bla-gen med en plasmidfamilj, eftersom de flesta isolaten bar flera bla-gener och flera plasmidfamiljer. β-lactamases ESBLs bla-genes plasmid families incompatibility groups replicon typing E. coli K. pneumoniae Biomedical Laboratory Science/Technology
10	Understanding the Role of the Hypervariable Region in the Open Reading Frame 1 of the Hepatitis E virus in Viral Replication Pudupakam, Raghavendra Sumanth Kumar 15 March 2011 (has links) Hepatitis E virus (HEV) is a major cause of enterically transmitted acute viral hepatitis in developing countries that lack proper hygienic infrastructure. Hepatitis E is globally distributed and has emerged as an important public health disease in both developing and industrialized countries. HEV is a non-enveloped virus carrying a single-stranded positive-sense RNA genome of approximately 7.200 bp in length. The life cycle of HEV is poorly understood due to the lack of an efficient cell culture system. Animal model systems, including non-human primates, swine, and chickens are being used to study some fundamental aspects of the HEV biology. Recently, novel animal strains of rat and rabbit HEV have been discovered, and whose usage as animal model systems needs to be established. HEV infections in pigs and chickens provide excellent model systems to study the replication and pathogenesis aspects of HEV. Recently, we identified a hypervariable region (HVR) in the open reading frame 1 (ORF1) of HEV. The objectives of this dissertation were to utilize chicken and swine model systems to study the role of HVR in HEV infection in vivo, to determine the effects of HVR on replication of HEV in vitro, and to analyze the effect of exchange of HVR among different genotypes on the replication-competency and virion production in vitro. Extensive sequence variability in the HVR among HEV strains of different genotypes prompted us to study the dispensability of this region. Initially we constructed two partial deletion mutants of genotype 1 human HEV, hHVRd1 and hHVRd2, with in-frame deletion of amino acids (aa) 711 to 777 and 747 to 761 in the HVR of a sub-genomic GFP HEV replicon. Expression of enhanced green fluorescent protein by the mutant hHVRd2 confirmed the dispensability of amino acid residues 747-761 of the HVR. To confirm our in vitro results, specific-pathogen-free (SPF) chickens were intra-hepatically inoculated with capped RNA transcripts from three avian HEV HVR-deletion mutants: mutants aHVRd1 (Δ557-585), aHVRd2 (Δ612-641), and aHVRd3 (Δ557-641). Chickens intra-hepatically inoculated with the mutants, aHVRd1 and aHVRd2, developed active viral infection as evidenced by seroconversion, viremia, and fecal virus shedding. Mutant aHVRd3, with a larger HVR deletion, was apparently attenuated in chickens. Additionally, we used the swine model system to further verify our results from the chicken study. The infectivity of four genotype 3 swine HEV HVR-deletion mutants, sHVRd1 (Δ712-790), sHVRd2 (Δ722-781), sHVRd3 (Δ735-765), and sHVRd4 (Δ712-765) constructed using the genotype 3 swine HEV as the backbone was determined in SPF pigs. Pigs intra-hepatically inoculated with capped RNA transcripts from the mutants sHVRd2, sHVRd3, and sHVRd4 developed active viral infection, whereas mutant sHVRd1 (Δ712-790), with a nearly complete HVR deletion, exhibited an attenuation phenotype. The data from these studies indicate that deletions in HVR do not abolish HEV infectivity in vitro or in vivo, although evidence for attenuation was observed for HEV mutants with a larger or nearly complete HVR deletion. To further elucidate the role of HVR in HEV replication, we investigated the effects of serial amino acid deletions in HVR on the replication of HEV. We first constructed a genotype 1 human HEV luciferase replicon by replacing the ORF2 gene that encodes for the capsid protein with the fire fly luciferase reporter gene. Using the backbone of human HEV genotype 1 luciferase replicon, we constructed a series of HVR-deletion mutants with deletions of variable lengths in the HVR. Amino acid deletions Δ711-725, 711-740 and Δ711-750 were engineered at the N-terminus, deletions Δ729-754, Δ721-766, and Δ716-771 were engineered in the central region, and deletions Δ761-775, Δ746-775, and Δ736-775 were engineered at C-terminus of the HVR. The effects of these serial deletions on HEV RNA replication in the human liver carcinoma cell line, Huh7, were examined. Replication levels of mutants carrying these deletions were compared with that of the wild-type HEV in Huh7 cells. We observed that deletions in the HVR did not abolish viral RNA synthesis but substantially reduced the replication levels of viral RNA, as measured by the reporter luciferase activity. To further verify the effects of HVR deletions on viral RNA replication as observed with the genotype 1 human HEV replicon, we subsequently used a genetically-distinct strain of HEV, avian HEV, and constructed an avian HEV sub-genomic luciferase replicon by substituting the ORF2 gene of avian HEV with the fire fly luciferase gene. Avian HEV HVR-deletion mutants Δ557-603, Δ566-595, and Δ573-587 were then engineered using the backbone of avian HEV luciferase replicon. The replication efficiency of the three deletion mutants of avian HEV in chicken liver hepatoma cell line, LMH, was evaluated. Compared with the wild-type avian HEV, the viral RNA synthesis of the avian HEV HVR-deletion mutants was considerably reduced by the HVR deletions. To analyze the impact of the complete HVR deletion on avian HEV infectivity, we constructed an avian HEV mutant with a deletion of the entire HVR region (aaΔ557-603) using the avian HEV infectious cDNA clone as the backbone. After confirming the viability of the complete HVR-deletion mutant in LMH cells, SPF chickens were intrahepatically inoculated with capped RNA transcripts generated from the mutant. None of the chickens inoculated with the complete HVR-deletion mutant showed evidence of HEV infection, indicating that drastic reduction in replication levels due to complete HVR deletion has resulted in the loss of virus infectivity. The results indicated that HVR may have critical residues that may interact with viral/and or host factors and modulate the replication efficiency of HEV. In the final part of the dissertation research, we sought to determine if the variable sequences of HVR are genotype-specific for in vitro virus replication. By using the genotype 1 human HEV as the backbone, we swapped the HVR of genotype 1 human HEV with the HVRs of the genotype 3 swine HEV and the distantly-related avian HEV to construct two inter-genotypic chimeras, pSKHEV2-Sw and pSKHEV2-Av. Similarly, by using the genotype 3 swine HEV as the backbone, the HVR of genotype 3 swine HEV was swapped with the HVR of genotype 1 human HEV to construct the chimera, pSHEV3-Hu. The viability of these chimeras was tested in Huh7 cells that are permissive for HEV replication. Immunofluorescence assay (IFA) with anti-HEV antibodies revealed that all the three chimeras were replication-competent in Huh7 cells. The infectivity of these chimeras was subsequently evaluated in HepG2 cells. The results showed that exchange of the HVR between different genotypes of mammalian HEVs does not abolish the replication competency and infectivity of HEV. This finding suggests that HVR is not genotype-specific with respect to viral replication and infectivity. The absence of detectable viral antigen in HepG2 cells infected with chimera pSKHEV2-Av suggested a functional incompatibility of the HVR of avian HEV in the mammalian HEV genome. In summary, we identified a highly variable sequence, HVR, in the ORF1 of the HEV genome, and the sequences of the HVR vary significantly among HEV strains of different genotypes. We found that the HVR contain sequences that are dispensable for virus infectivity both in vitro and in vivo. Deletion analysis of HVR revealed that the region may play a role in modulating the replication efficiency of HEV RNA by interacting with viral and/or host factors. Finally, we demonstrated that HVR is not genotype-specific for virus replication and the region can be functionally replaced between mammalian HEV genotypes for virus replication and virion production in vitro. The results from this dissertation research have important implications for better understanding the biology and mechanism of HEV replication and may aid in our efforts to eventually develop a modified live-attenuated vaccine against HEV. / Ph. D. hepatitis E virus hypervariable region HVR subgenomic replicon HEV swine HEV human HEV avian HEV hepatitis–splenomegaly syndrome BLSD big liver and spleen disease HS syndrome

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