Global ETD Search

51	Resposta imune inata em sistema nervoso central de camundongos experimentalmente infectados com amostras de vírus rábico isoladas de diferentes espécies / Imune inate and adaptative viral response in central nervous system of mice experimentally infected with rabies virus strains isolated forom different species Allendorf, Susan Dora [UNESP] 01 July 2014 (has links) (PDF) Made available in DSpace on 2015-05-14T16:53:24Z (GMT). No. of bitstreams: 0 Previous issue date: 2014-07-01Bitstream added on 2015-05-14T16:58:53Z : No. of bitstreams: 1 000829408.pdf: 2465739 bytes, checksum: 3b6cd69550973141a95f15638eea0959 (MD5) / Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) / O controle da raiva é mundialmente reconhecido como um dos grandes desafios mundiais. As diferentes variantes virais isoladas das diversas espécies animais apresentam características imunogênicas distintas assim como na sequência de nucleotídeos, o que permite sua classificação em variantes e genótipos. Além disso, diferenças na patogenicidade também foram observadas através de inoculação experimental em camundongos e cultivo celular. Os mecanismos pelos quais o vírus rábico (RABV) infecta um indivíduo e se perpetua na natureza ainda não foram totalmente esclarecidos. Entretanto alguns fatores que levam ao sucesso da infecção já foram estabelecidos, entre os mais importantes podemos citar a capacidade de induzir a apoptose das células de defesa e preservar a integridade e funcionalidade dos neurônios. Estes eventos são mediados por citocinas que regulam diversos genes envolvidos nesse complexo processo ainda pouco compreendido. Considerando a diversidade de linhagens virais circulantes e a complexidade dos eventos envolvidos na neuroinvasão do RABV o presente projeto avaliou os genes mais importantes envolvidos na expressão gênica do processo de resposta immune inata e adaptativa após infecção e avaliou a patogenicidade de diferentes amostras virais através da inoculação experimental em camundongos SPF (Specific Pathogen Free) realizando a quantificação viral por qRT-PCR e imunofluorescência das amostras coletadas / Rabies control is considered a worldwide challenge. Different virus strains (RABV) are isolated from different species, they have distinct immunogenic characteristics as well in their nucleotides sequence, allowing their classification into variants and genotypes. Furthermore, differences in pathogenicity have also been observed through experimental inoculation in mice and cell cultures. The mechanisms by which RABV infects an individual and perpetuated the infection in nature have not been fully clarified. However some factors that lead to successful infection are already established, among the most important we can mention the ability to induce apoptosis of T cells and maintain the integrity and functionality of neurons. These events are mediated by cytokines that regulate several genes involved in this complex process still poorly understood. Considering the diversity of viral strains circulating and the complexity of events involved in the neuroinvasiveness of RABV this project aims to study the gene expression pathway, innate and adaptative immune response and pathogenicity of different virus strain by means of experimental inoculation in mice, clinical evaluation and avaliating viral replication by DFA and qRT-PCR / FAPESP: 2012/00895-5 Resposta imune Expressão gênica Camundongo como animal de laboratorio Vírus da hidrofobia Replicação viral Reação em cadeia de polimerase Virus replication Rabies virus
52	Resposta imune inata em sistema nervoso central de camundongos experimentalmente infectados com amostras de vírus rábico isoladas de diferentes espécies / Allendorf, Susan Dora. January 2014 (has links) Orientador: Jane Megido / Banca: Hélio Langoni / Banca: Maria Luiza Carrieri / Banca: Marcos Bryan Heinemann / Banca: Paulo Eduardo Brandão / Resumo: O controle da raiva é mundialmente reconhecido como um dos grandes desafios mundiais. As diferentes variantes virais isoladas das diversas espécies animais apresentam características imunogênicas distintas assim como na sequência de nucleotídeos, o que permite sua classificação em variantes e genótipos. Além disso, diferenças na patogenicidade também foram observadas através de inoculação experimental em camundongos e cultivo celular. Os mecanismos pelos quais o vírus rábico (RABV) infecta um indivíduo e se perpetua na natureza ainda não foram totalmente esclarecidos. Entretanto alguns fatores que levam ao sucesso da infecção já foram estabelecidos, entre os mais importantes podemos citar a capacidade de induzir a apoptose das células de defesa e preservar a integridade e funcionalidade dos neurônios. Estes eventos são mediados por citocinas que regulam diversos genes envolvidos nesse complexo processo ainda pouco compreendido. Considerando a diversidade de linhagens virais circulantes e a complexidade dos eventos envolvidos na neuroinvasão do RABV o presente projeto avaliou os genes mais importantes envolvidos na expressão gênica do processo de resposta immune inata e adaptativa após infecção e avaliou a patogenicidade de diferentes amostras virais através da inoculação experimental em camundongos SPF (Specific Pathogen Free) realizando a quantificação viral por qRT-PCR e imunofluorescência das amostras coletadas / Abstract: Rabies control is considered a worldwide challenge. Different virus strains (RABV) are isolated from different species, they have distinct immunogenic characteristics as well in their nucleotides sequence, allowing their classification into variants and genotypes. Furthermore, differences in pathogenicity have also been observed through experimental inoculation in mice and cell cultures. The mechanisms by which RABV infects an individual and perpetuated the infection in nature have not been fully clarified. However some factors that lead to successful infection are already established, among the most important we can mention the ability to induce apoptosis of T cells and maintain the integrity and functionality of neurons. These events are mediated by cytokines that regulate several genes involved in this complex process still poorly understood. Considering the diversity of viral strains circulating and the complexity of events involved in the neuroinvasiveness of RABV this project aims to study the gene expression pathway, innate and adaptative immune response and pathogenicity of different virus strain by means of experimental inoculation in mice, clinical evaluation and avaliating viral replication by DFA and qRT-PCR / Doutor Resposta imune. Expressão gênica. Camundongo como animal de laboratorio. Vírus da hidrofobia. Replicação viral. Reação em cadeia da polimerase. Virus replication. Rabies virus.
53	The Human Rev Interacting Protein (hRIP) is Required for Rev Function and HIV-1 Replication: a Dissertation Sánchez-Velar, Nuria 07 January 2005 (has links) Retroviruses have evolved sophisticated mechanisms to ensure timely export of incompletely spliced viral messenger ribonucleic acids (mRNAs) for gene expression and for viral packaging. For example, the Human Immunodeficiency Virus type 1 (HIV-1) encodes the Rev regulatory protein, a sequence-specific RNA-binding protein that is responsible for the cytoplasmic accumulation of intron-containing viral mRNAs. The HIV-1 Rev protein contains an amino terminal (N-terminal) Arginine-Rich Motif (ARM) RNA-binding domain (RBD) and a carboxy terminal (C-terminal) leucine-rich activation domain which functions as a Nuclear Export Signal (NES). The Rev ARM interacts in a sequence-specific manner with a cis-acting viral RNA stem-loop structure, the Rev Responsive Element (RRE), located in all incompletely spliced viral mRNAs. This initial interaction is followed by the recruitment of additional Rev molecules to form a RiboNucleoProtein (RNP) complex involving the RRE and Rev molecules. The cytoplasmic accumulation of the Rev:RRE RNP complex is dependent on the interaction of Rev with key cellular cofactors. Rev activation domain mutants exhibit a trans-dominant negative phenotype, suggesting that this domain of Rev interacts with cellular proteins required for Rev function. Biochemical and genetic studies have identified several cellular proteins that bind to the activation domain of Rev and are therefore candidate cofactors for Rev function. Amongst these is the human Rev Interacting Protein [hRIP, 79], which is also known as the Rev/Rex activation domain-binding protein [Rab, 18]. hRIP was identified in a yeast two-hybrid assay with the HIV-1 Rev and its functionally equivalent Human T-cell Leukemia Virus type-1 (HTLV-1) Rex protein as baits. The interaction between hRIP and HIV-1 Rev is dependent on a functional Rev NES, as predicted for a bona fide Rev cellular cofactor, and the Nucleoporin-like (Nup-like) repeats in the C-terminus of hRIP (18, 79]. Additional genetic studies indicated that the interaction between hRIP and Rev is indirect and is most likely mediated by the cellular export receptor CRM1 (Chromosomal Region Maintenance 1) [1, 153]. A role for hRIP in Rev function or HIV-1 replication has remained elusive. The goal of this dissertation was to determine whether hRIP is required for Rev function and HIV-1 replication. We used two approaches, a dominant-negative mutant and RNA interference (RNAi), to ablate hRIP activity and analyzed Rev function and HIV-1 replication using standard assays. The results of this dissertation demonstrate that hRIP is required for Rev function and HIV-1 replication. We show that Rev function is inhibited upon ablation of hRIP activity by either a trans-dominant negative mutant or RNAL Furthermore, we find that depletion of endogenous hRIP by RNAi results in the loss of viral replication in human cell lines and primary human macrophages. Unexpectedly, in the absence of functional hRIP, RRE-containing viral RNAs accumulate in the nuclear periphery where hRIP is localized. Comparable ablation of hRIP activity did not affect the intracellular localization or trafficking of a variety of proteins or cellular poly (A+ mRNA, suggesting that the inhibition of Rev-directed RNA export is specific. In conclusion, the results of this dissertation demonstrate that hRIP is involved in the movement of Rev-directed RNAs from the nuclear periphery to the cytoplasm. Therefore, hRIP is required for Rev function and HIV-1 replication. The hRIP protein is not essential for the maintenance of cell viability and thus might represent a novel target for the development of antiviral agents for HIV-1. HIV-1 RNA-Binding Proteins Nuclear Pore Complex Proteins Virus Replication RNA, Messenger Academic Dissertations Life Sciences Medicine and Health Sciences
54	Molecular Mechanisms of Host Responses to Porcine Reproductive and Respiratory Syndrome Virus (PRRSV) Infection Catanzaro, Nicholas Jr. 24 April 2020 (has links) Porcine reproductive and respiratory syndrome virus (PRRSV) is arguably the most economically devastating pathogen affecting the global swine industry. Since the emergence of the virus in the late 1980s, vaccination strategies aimed to control the virus have not been very effective. Current commercial vaccines are generally protective against homologous or closely-related strains but ineffective at conferring heterologous protection against genetically-diverse strains of the virus. Consequently, emergence of variant and sometime more pathogenic strains of PRRSV continues in global swine herds. As such, there is a need for better understanding of the molecular mechanisms involved in the replication of the virus. In order to better understand the molecular mechanisms of host responses to PRRSV replication, we first sought to evaluate the ability of the virus to induce stress granules (SGs) during PRRSV infection. SGs are intracellular, cytoplasmic aggregates of RNA-binding proteins (RBPs) and mRNA. Formation of SGs is observed upon cellular stress and ultimately function to arrest cellular translation to promote cellular survival until the stress has been remedied. Indeed, several viruses have been shown to modulate the SG pathways to facilitate viral replication and even suppress the host's immune response. However, it is currently unknown whether PRRSV modulates the SG response. First, we used confocal microscopy and fluorescent in situ hybridization (FISH) to determine the distribution of known SG marker proteins and cellular mRNAs. Our findings revealed that PRRSV induces a potent SG response at late time points post-infection, and that SGs were closely associated with viral replication complexes (VRCs). Subsequently, we demonstrated that SGs are dispensable for viral replication, as short hairpin RNA (shRNA)-mediated knockdown of critical SG components (G3BP1 and G3BP2) did not affect viral replication. Interestingly, we found that the PRRSV-induced SGs are formed in a PERK-dependent manner. PERK is an important sensor of ER stress and activator of the unfolded protein response (UPR). Further investigation into the PERK signaling pathway revealed that PRRSV induces a significant amount of ER stress upon the cell during viral infection, and that exogenous stress significantly impaired the ability of the virus to replicate in MARC145 cells. We also showed that PRRSV potently induces all three signaling branches of the UPR, including PERK. While PERK knockdown had no effect on cell viability or viral replication, it significantly upregulated the mRNA expression of interferon-β and interferon stimulated genes (ISGs). The results from our studies suggest a critical role for PERK in regulating the host innate immune response to PRRSV infection. Only with a better understanding of the underlying molecular mechanisms of PRRSV replication will we be able to rationally design more effective vaccines against the virus. / Doctor of Philosophy / Porcine reproductive and respiratory syndrome virus (PRRSV) causes an economically-devastating disease in the global swine industry. Annually, PRRSV is estimated to cause more than $600 million in economic losses to the swine industry in the United States alone. Current commercial vaccines against the virus are not effective against the diverse field strains largely due to the extreme heterogeneity of the virus. PRRSV is also able to potently suppress several aspects of the host's immune response and therefore establish a persistent infection. The underlying mechanisms of PRRSV-mediated immune suppression are not well understood. Therefore, in this dissertation we decided to investigate the molecular mechanisms of host responses to PRRSV infection. We first investigated the ability of the virus to induce stress granules (SGs). SGs are important intracellular regulatory components that modulate many aspects of the host's cellular processes, and have even been shown to play roles in regulating viral replication and controlling immune responses to viral infection. We demonstrate that PRRSV not only induces SGs, but that the PRRSV-induced SGs are closely associated with viral replication complexes (VRCs) within infected cells. The PRRSV-induced SGs were dispensable for viral replication. PRRSV-induced SGs were previously shown to form in a PERK dependent manner. Therefore, in the second part of this dissertation research, we decided to investigate the PERK signaling pathway during PRRSV infection. PERK is an important sensor of ER stress and activator of the unfolded protein response (UPR). Our results showed that PRRSV potently induces ER stress and all three signaling branches of the UPR, including PERK. Furthermore, we revealed that PERK may play an important role in regulating the type I interferon response to PRRSV infection. The results from our studies will aid in understanding the underlying molecular mechanism of PRRSV replication which will help rationally design the next generation of more effective vaccines against this devastating swine pathogen. stress granules (SGs) unfolded protein response (UPR) virus replication unfolded protein response (UPR)
55	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
56	Exploiting and exploring the interactions between microRNA-122 and Hepatitis C virus 2014 September 1900 (has links) Hepatitis C virus (HCV) is a single-stranded plus-sense RNA virus that is transmitted by blood-to-blood contact, and infects the human liver. HCV has a unique dependence on the liver-specific microRNA miR-122, where miR-122 binds the 5´ un-translated region of the viral RNA at two tandem sites and increases viral RNA abundance. The mechanisms of augmentation are not yet fully understood, but the interaction is known to stabilize the viral RNA, increase translation from the viral internal ribosomal entry site (IRES), and result in increased viral yield. In an attempt to create a small animal model for HCV, we added miR-122 to mouse cell lines previously thought non-permissive to HCV, which rendered these cells permissive to the virus, additionally showing that miR-122 is one of the major determinants of HCV hepatotropism. We found that some wild-type and knockout mouse cell lines – NCoA6 and PKR knockout embryonic fibroblasts – could be rendered permissive to transient HCV sub-genomic, but not full-length, RNA replication upon addition of miR-122, and that other wild-type and knockout cell lines cannot be rendered permissive to HCV replication by addition of miR-122. These knockout cell lines demonstrated varying permissiveness phenotypes between passages and isolates and eventually completely lost permissiveness, and we were unable to achieve sub-genomic RNA replication in PKR knockout primary hepatocytes. Knockdown of NCoA6 and PKR in Huh7.5 cells did not substantially impact sub-genomic replication, leading us to conclude that there are additional factors within the cell lines that affect their permissiveness for HCV replication such as epigenetic regulation during passage or transformation and immortalization. We also added miR-122 to Hep3B cells, a human hepatoma cell line lacking expression of miR-122 and previously thought to be non-permissive to HCV replication. Added miR-122 rendered the cells as highly permissive to HCV replication as the Huh7-derived cell lines commonly used to study the virus. In these cells, we were also able to observe miR-122-independent replication of sub-genomic HCV RNA. This was verified by use of a miR-122 antagonist that had no impact on the putative miR-122-independent replication, and by mutating the miR-122 binding sites to make them dependent on a single nucleotide-substituted microRNA. This replication in the absence of miR-122 was not detected in full-length HCV RNA, but was detectable using a bi-cistronic full-length genomic replicon, suggesting that the addition of a second IRES in sub-genomic and full-genomic replicons altered replication dynamics enough to allow detectable RNA replication without miR-122 binding. Because miR-122 has been implicated in protecting the viral RNA from destabilization and degradation by Xrn1, the main cytoplasmic 5´ to 3´ RNA exonuclease, we employed our miR-122-independent system to test this miR-122-mediated protection. We verified that miR-122 functions to protect the viral RNA from Xrn1, but this was insufficient to account for the overall impact of miR-122 on replication, meaning that miR-122 has further functions in the virus’ life cycle. We showed that the effect of miR-122 on translation is due to stabilization of the RNA by protecting it from Xrn1, through binding at both sites. We further evaluated the role of each miR-122 binding site (S1 and S2) in the virus life cycle, and found that binding at each site contributes equally to increasing viral RNA replication, while binding at both sites exerts a co-operative effect. Finally, we determined that binding of miR-122 at site S2 is more important for protection from Xrn1, suggesting that miR-122 binding at S1 is more important for the additional functions of miR-122 in enhancing HCV RNA accumulation. Altogether, we have shown that miR-122 is partially responsible for the hepatotropic nature of Hepatitis C virus, and that supplementation with this microRNA can render non-permissive cells permissive to viral replication. We have also identified and confirmed replication of both sub-genomic and full-length HCV RNA in the absence of miR-122. Finally, we have characterized the impact of the host RNA exonuclease Xrn1 on the HCV life cycle, and determined the roles of each miR-122 binding site in shielding the viral RNA from this host restriction factor. Hepatitis C virus HCV microRNA miR-122 Hep3B murine embryonic fibroblast MEF virus-host interactions animal model model system Xrn1 virus replication
57	The influence of retroviral codon usage on the acquisition of the tRNA used to prime reverse transcription Palmer, Matthew T. January 2006 (has links) (PDF) Thesis (Ph. D.)--University of Alabama at Birmingham, 2006. / Title from first page of PDF file (viewed Feb. 14, 2008). Includes bibliographical references.
58	Cytoplasmic Localization of HIV-1 Vif Is Necessary for Apobec3G Neutralization and Viral Replication: A Dissertation Farrow, Melissa Ann 05 May 2005 (has links) The binding of HIV-1 Vif to the cellular cytidine deaminase Apobec3G and subsequent prevention of Apobec3G virion incorporation have recently been identified as critical steps for the successful completion of the HIV-1 viral life cycle. This interaction occurs in the cytoplasm where Vif complexes with Apobec3G and directs its degradation via the proteasome pathway or sequesters it away from the assembling virion, thereby preventing viral packaging of Apobec3G. While many recent studies have focused on several aspects of Vif interaction with Apobec3G, the subcellular localization of Vif and Apobec3G during the viral life cycle have not been fully considered. Inhibition of Apobec3G requires direct interaction of Vif with Apobec3G, which can only be achieved when both proteins are present in the same subcellular compartment. In this thesis, a unique approach was utilized to study the impact of Vif subcellular localization on Vif function. The question of whether localization could influence function was brought about during the course of studying a severely attenuated viral isolate from a long-term non-progressor who displayed a remarkable disease course. Initial observations indicated that this highly attenuated virus contained a mutant Vif protein that inhibited growth and replication. Upon further investigation, it was found that the Vif defect was atypical in that the mutant was fully functional in in vitro assays, but that it was aberrantly localized to the nucleus in the cell. This provided the basis for the study of Vif localization and its contribution to Vif function. In addition to the unique Vif mutant that was employed, while determining the localization and replication phenotypes of the differentially localized Vif proteins, a novel pathway for Vif function was defined. Copious publications have recently defined the mechanism for Vif inhibition of Apobec3G. Vif is able to recruit Apobec3G into a complex that is targeted for degradation by the proteasome. However, this directed degradation model did not fully explain the complete neutralization of Apobec3G observed in cell culture. Other recent works have proposed the existence of a second, complementary pathway for Vif function. This pathway is defined here as formation of an aggresome that prevents Apobec3G packaging by binding and sequestering Apobec3G in a perinuclear aggregate. This second mechanism is believed to work in parallel with the already defined directed degradation pathway to promote complete exclusion of Apobec3G from the virion. The data presented here provide insight into two areas of HIV research. First, the work on the naturally occurring Vif mutant isolated from a long-term non-progress or confirms the importance of Vif in in vivo pathogenesis and points to Vif as a potentially useful gene for manipulation in vaccine or therapy design due to its critical contributions to in vivo virus replication. Additionally, the work done to address the subcellular localization of Vif led to the proposal of a second pathway for Vif function. This could have implications in the field of basic Vif research in terms of completely understanding and defining the functions of Vif. Again, a more complete knowledge about Vif can help in the development of novel therapies aimed at disrupting Vif function and abrogating HIV-1 replication. HIV-1 Gene Expression Regulation Developmental Virus Replication Gene Products vif Virus Assembly Cytidine Deaminase Environmental Public Health Enzymes and Coenzymes Genetic Phenomena Investigative Techniques Therapeutics Viruses
59	Investigation of the C-Terminal Helix of HIV-1 Matrix: A Region Essential for Multiple Functions in the Viral Life Cycle: A Dissertation Brandano, Laura A 10 July 2011 (has links) Since the first cases were reported over thirty years ago, great strides have been made to control disease progression in people living with HIV/AIDS. However, current estimates report that there are about 34 million individuals infected with HIV worldwide. Critical in the ongoing fight against this pandemic is the continuing development of highly active anti-retroviral therapies, ideally those with novel mechanisms of action. Currently, there are no medications approved for use that exploit the HIV-1 MA protein, despite its central role in multiple stages of the virus life cycle. This thesis sought to examine whether a highly conserved glutamate residue at position 99 in the understudied C-terminal helix of MA is required for HIV-1 replication. I characterized a panel of mutant viruses that contain different amino acid substitutions at this position using viral infectivity studies, virus-cell fusion assays, and immunoblotting. In doing so, I found that substitution of this glutamate with either a valine (E99V) or lysine (E99K) residue disrupted Env incorporation into nascent HIV particles, and abrogated their ability to fuse with target-cell membranes. In determining that the strain of HIV could affect the magnitude of E99V-associated defects, I identified a compensatory substitution at MA residue 84 that rescued both E99V- and E99K-associated impairments. I further characterized the MA E99V and E99K mutations by truncating HIV Env and pseudotyping with heterologous envelope proteins in an attempt to overcome the Env incorporation defect. Unexpectedly, I found that facilitating fusion at the plasma membrane was not sufficient to reverse the severe impairments in virus infectivity. Using quantitative PCR, I determined that an early post-entry step is disrupted in these particles that contain the E99V or E99K MA substitutions. However, allowing entry of mutant virus particles into cells through an endosomal route conferred a partial rescue in infectivity. As the characterization of this post-entry defect was limited by established virological methods, I designed a novel technique to analyze post-fusion events in retroviral infection. Thus, I present preliminary data regarding the development of a novel PCR-based assay that monitors trafficking of the viral reverse transcription complex (RTC) in an infected cell. The data presented in this thesis indicate that a single residue in MA, E99, has a previously unsuspected and key role in multiple facets of HIV-1 MA function. The pleiotropic defects that arise from specific substitutions of this amino acid implicate a hydrophobic pocket in MA in Env incorporation and an early post-entry function of the protein. These findings suggest that this understudied region of MA could be an important target in the development of a novel antiretroviral therapy. HIV-1 HIV Antigens gag Gene Products Human Immunodeficiency Virus Virus Replication Biological Factors Genetic Phenomena Immunology and Infectious Disease Therapeutics Virology Virus Diseases Viruses
60	Identification of a new cell line permissive to porcine reproductive and resporatory syndrome virus replication Jia, Jian Jun 08 1900 (has links) Le syndrome reproducteur et respiratoire porcin (SRRP) est une des maladies les plus dévastatrices économiquement pour l'industrie mondiale du porc. L'agent étiologique du SRRP est le virus du SRRP (VSRRP) lequel est connu pour avoir une spécificité d'hôte très restreinte et pour sa transmission par voie aerosol. Les antigènes et les ARN du VSRRP ont été trouvés dans des cellules épithéliales du tractus respiratoire de porcs infectés par le virus. L’interaction entre les macrophages alvéolaires porcins (PAMs) et le VSRRP a été démontrée comme jouant un rôle important dans l’infection causée par le virus. Malgré cela, l’interaction prenant place entre les cellules épithéliales du tractus respiratoire porcin et le virus ne devrait pas être négligée. Jusqu’à présent, la réplication du VSRRP in vitro dans des cellules épithéliales du tractus respiratoire porcin n’a pas été conduite avec succès et les tentatives pour le faire ont échoué. Une nouvelle lignée de cellules épithéliales de poumon de porc (SJPL) est maintenant disponible et sera utilisée dans cette étude afin de déterminer si elle est permissive à la réplication du VSRRP et si elle peut être un modèle approprié pour l’étude de la pathogénèse virale du VSRRP. L’expérimentation a démontré que cette nouvelle lignée cellulaire était permissive à l’infection et à la réplication du VSRRP. Afin de corroborer ces résultats, la cinétique de réplication du virus à été effectuée avec les cellules MARC-145 et SJPL. Aucune différence significative dans la production virale totale n’a été trouvée entre les deux lignées cellulaires. Les cellules SJPL ont permis la réplication de plusieurs souches Nord-Américaines du VSRRP, quoiqu’elles sont légèrement moins efficaces que les cellules MARC-145 pour l’isolement du virus. De plus, les cellules SJPL sont phénotypiquement différentes des cellules MARC-145. Plus précisément, les cellules SJPL sont plus sensibles à l’activation par le VSRRP des pro-caspases 3/7 et plusieurs inducteurs apoptotiques. Elles ont également montré de 8 à 16 fois plus de sensibilité à l’effet antiviral causé par l’IFN-α sur la réplication du virus contrairement aux cellules MARC-145. Ces résultats démontrent que les cellules SJPL pourraient représenter un substitut intéressant aux cellules MARC-145 pour la production d’antigènes pour un vaccin anti-VSRRP. Également, dû à leurs origines (poumon de l’hôte naturel), elles pourraient s’avérer être un modèle in vitro plus approprié pour l’étude de la pathogénèse du VSRRP. / Porcine reproductive and respiratory syndrome (PRRS) is one of the most economically devastating diseases for the pig industry worldwide. The etiological agent of PRRS is the PRRS virus (PRRSV), which is known to have a very restricted host specifity and to be airborne transmitted. PRRSV RNAs and antigens were found in epithelial cells of the respiratory tract of swine in PRRSV-infected pigs. Even if the interaction between porcine alveolar macrophages (PAMs) and PRRSV plays an important role in the PRRSV infection, the role of the interaction between epithelial cells of the swine respiratory tract and PRRSV should not been neglected. However, no epithelial cells of the swine respiratory tract have been demonstrated to allow PRRSV replication in vitro and attempts to generate such a cell line have failed. The goal of this study is to determine whether epithelial cells of the swine respiratory tract are permissive to PRRSV replication and are a suitable model for studying the viral pathogenesis of PRRSV. We have discovered that the SJPL cell line, an epithelial cell line of the respiratory tract of swine, is permissive to PRRSV infection and replication. To corroborate these results, PRRSV replication kinetics were evaluated in a subclone of the African green monkey kidney MA104 cells (MARC-145), which has been known to be fully permissive to PRRSV infection and replication, and in SJPL cells. No significant difference was found between the two cell lines for overall viral production. Moreover, the SJPL cells were able to permit the replication of several PRRSV North-American strains but they were slightly less efficient for virus isolation than MARC-145 cells. In addition, SJPL is phenotypically different from MARC-145. Specifically, the SJPL cells were more sensitive to procaspases 3/7 activation by PRRSV and several apoptotic inducers compared to MARC-145 cells. In addition, the SJPL cells showed 8 to 16 times more sensitivity to the antiviral effect of IFN-α against PRRSV replication than MARC-145 cells. Altogether, the SJPL cells could be an interesting substitute to MARC-145 cells for PRRSV vaccine antigen production, and could be a more relevant in vitro model, because of their origin (lung of the natural host), to study the pathogenesis of PRRSV. VSRRP Cellule épithéliale de poumon de porc SJPL Réplication virale Cellule permissive PRRSV Porcine lung epithelial cell SJPL Virus replication Cell permissiveness

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