Global ETD Search

1	The Role of PIDD in Apoptosis and Innate Antiviral Immunity Kim, Ira 18 January 2012 (has links) PIDD has previously been described as a death domain (DD)-containing protein that is inducible upon p53 activation and plays a role in programmed cell death. It has previously been shown that PIDD interacts with RAIDD (RIP-associated ICE/CED3 homologous protein with a death domain) in a cytoplasmic complex known as the PIDDosome, which results in the activation of capsase-2 and ultimately in cell death in response to DNA damage. Despite earlier studies on PIDD, however, the physiological role of PIDD has not been elucidated. Thus, we have generated PIDD-deficient mice and examined its in vivo functions particularly in cell death and in antiviral innate immunity. The first major aim of the thesis is to determine whether or not PIDD is required in cell death. PIDD mice are developmentally normal and do not display a pronounced phenotype. Surprisingly, PIDD deficiency perturbed neither DNA damage-induced nor stress-induced cell death in a variety of cell types, suggesting that PIDD may not play a critical role in cell death. In addition, caspase-2 processing occurred normally in the absence of PIDD in response to ionizing irradiation or etoposide treatment, indicating that PIDD is dispensable in the cleavage of caspase-2. The second major aim is to examine the role of PIDD and RAIDD in LCMV-induced innate immunity. To study the role of PIDD and RAIDD in antiviral immune responses, I have generated PIDD/RAIDD double-deficient mice and challenged them with lymphocytic choriomeningitis virus (LCMV). Interestingly, I observed that ablation of both PIDD and RAIDD together resulted in defective viral clearance in the spleen, but not in other organs including the lung, liver, and kidney. In addition, the production of type I IFN was also decreased in the mice deficient in both PIDD and RAIDD. However, the cytotoxicity of the T lymphocytes was largely intact in the absence of both PIDD and RAIDD. Collectively, our results suggest that PIDD is dispensable in cell death, yet PIDD and RAIDD together have a synergistic effect in LCMV-induced antiviral innate immunity. The findings presented in this thesis provide a better understanding of the physiological role of PIDD and may ultimately contribute to the novel therapeutic strategies for the proper control of viral infection. PIDD apoptosis Innate antiviral immunity caspase-2 death domain leucine-rich repeats 0982
2	Porcine innate antiviral immunity: host defense peptides and toll-like receptors Sang, Yongming January 1900 (has links) Doctor of Philosophy / Department of Anatomy and Physiology / Chris R. Ross / The immediate antiviral defense residing in the innate immune system of multicellular organisms critically determines the outcome of viral infection. This dissertation presents a study of the "effectors" and "receptors" of porcine innate immunity in infection caused by porcine reproductive and respiratory syndrome virus (PRRSV), which is the most devastating pathogen impacting the swine industry. In the first investigation, eleven novel porcine host defense peptides (HDPs), [Beta]-defensins (pBDs), were identified and characterized. All of these peptides have a consensus [Beta]-defensin motif and phylogenetically are similar to orthologs from other species. A differential expression pattern for these 11 newly identified genes was found. For example, pBD-2 and pBD-3 were expressed in bone marrow, lung, skin and other lymphoid tissues. pBD-2 and pBD-3 were further characterized for their gene structure, and antimicrobial activity of synthetic peptides. The second study was conducted to evaluate PRRSV-induced differential expression of porcine HDPs and direct antiviral activity of selected HDPs against PRRSV. In vitro incubation of PRRSV with synthetic pBD-3 or protegrin-4 (PG-4) significantly inhibited viral infectivity. Using nine protegrin-derived peptides, it was determined that cyclization of PG-4 increased anti-PRRSV activity and mutation of some residues in PG-4 diminished some of the activity. These findings suggest the potential role of porcine HDPs as a group of innate antiviral effectors. In the third and fourth investigations, porcine Toll-like receptor (TLR) 3 and TLR7 were identified and functionally expressed. Increased expression of TLR3 was observed in PRRSV-infected porcine lungs. Stimulation of porcine alovelar macrophages with poly (I:C), a synthetic TLR3 ligand, increased expression of interferon-[Beta] and suppressed PRRSV infectivity. Activation of porcine TLR3 overexpressed in a PRRSV-sensitive cell line, elicited antiviral responses to PRRSV infection. Partial silencing of TLR3 in PAMs resulted in increased PRRSV infection. In summary, these data provide molecular information on porcine TLR3 and TLR7, and their involvement in PRRSV pathogenesis, which may elicit new strategies to prevent this costly swine disease. Innate antiviral immunity Host defense peptides Toll-like receptors PRRSV Biology, Molecular (0307) Biology, Veterinary Science (0778) Health Sciences, Immunology (0982)
3	Rôle de la CTNNB1 et de ses nouveaux partenaires dans la régulation de l'immunité antivirale innée et de la voie WNT Es-Saad, Salwa 11 1900 (has links) No description available. Criblage aux ARNi Immunité antivirale innée Signalisation WNT/CTNNB1 Spectrométrie de masse DDB1 NKRF ARNi screen Innate antiviral immunity WNT/CTNNB1 signaling Mass spectrometry
4	The nuclear pore complex and its transporters : from virus-host interactors to subverting the innate antiviral immunity Gagné, Bridget 05 1900 (has links) Les virus ont besoin d’interagir avec des facteurs cellulaires pour se répliquer et se propager dans les cellules d’hôtes. Une étude de l'interactome des protéines du virus d'hépatite C (VHC) par Germain et al. (2014) a permis d'élucider de nouvelles interactions virus-hôte. L'étude a également démontré que la majorité des facteurs de l'hôte n'avaient pas d'effet sur la réplication du virus. Ces travaux suggèrent que la majorité des protéines ont un rôle dans d'autres processus cellulaires tel que la réponse innée antivirale et ciblées pas le virus dans des mécanismes d'évasion immune. Pour tester cette hypothèse, 132 interactant virus-hôtes ont été sélectionnés et évalués par silençage génique dans un criblage d'ARNi sur la production interferon-beta (IFNB1). Nous avons ainsi observé que les réductions de l'expression de 53 interactants virus-hôte modulent la réponse antivirale innée. Une étude dans les termes de gène d'ontologie (GO) démontre un enrichissement de ces protéines au transport nucléocytoplasmique et au complexe du pore nucléaire. De plus, les gènes associés avec ces termes (CSE1L, KPNB1, RAN, TNPO1 et XPO1) ont été caractérisé comme des interactant de la protéine NS3/4A par Germain et al. (2014), et comme des régulateurs positives de la réponse innée antivirale. Comme le VHC se réplique dans le cytoplasme, nous proposons que ces interactions à des protéines associées avec le noyau confèrent un avantage de réplication et bénéficient au virus en interférant avec des processus cellulaire tel que la réponse innée. Cette réponse innée antivirale requiert la translocation nucléaire des facteurs transcriptionnelles IRF3 et NF-κB p65 pour la production des IFNs de type I. Un essai de microscopie a été développé afin d'évaluer l’effet du silençage de 60 gènes exprimant des protéines associés au complexe du pore nucléaire et au transport nucléocytoplasmique sur la translocation d’IRF3 et NF-κB p65 par un criblage ARNi lors d’une cinétique d'infection virale. En conclusion, l’étude démontre qu’il y a plusieurs protéines qui sont impliqués dans le transport de ces facteurs transcriptionnelles pendant une infection virale et peut affecter la production IFNB1 à différents niveaux de la réponse d'immunité antivirale. L'étude aussi suggère que l'effet de ces facteurs de transport sur la réponse innée est peut être un mécanisme d'évasion par des virus comme VHC. / Viruses interact with cellular factors in order to successfully replicate and propagate in host cells. Germain et al. (2014) performed a proteomics analysis to elucidate viral-host interactors of hepatitis C virus (HCV). They found that the majority of host factors did not have an effect on viral replication, suggesting that these host proteins may be beneficial to the virus by affecting other cellular processes such as evading the innate antiviral immunity. To test that hypothesis, 132 virus-host interactors were selected and silenced by RNAi for their effect on inteferon-beta (IFNB1) production as a readout of the innate antiviral response. 53 were found to modulate the response with enrichment in the gene ontology (GO) terms related to nucleocytoplasmic transport and the nuclear pore complex. An interesting point is that the genes associated with these terms (CSE1L, KPNB1, RAN, TNPO1, and XPO1) were previously elucidated as HCV NS3/4A interactors by Germain et al. (2014), as well as positive regulators of the innate antiviral response. Although it is surprising that a cytoplasmic-replicating virus like HCV would interact with proteins associated with the nucleus, we proposed that viruses interact with these proteins for their benefit to interfere with the innate immune response. The innate antiviral response requires the nuclear translocation of IRF3 and NF-κB p65 for the production of type I interferons. As it is unclear which transporters or nucleoporins are involved, 60 genes associated with the nuclear pore complex and nucleocytoplasmic transport were studied for their effect on the nuclear translocation of IRF3 and NF-κB p65 via a microscopy-based RNAi screen during a 10-hour viral infection time course. Overall, the study revealed that many of these proteins are involved in the trafficking of these transcription factors during a viral infection, and can affect the production of IFNB1 at different levels of the innate antiviral response. The study also suggests that the effect of these transport factors on the immune response may be an evasion mechanism for viruses such as HCV. Hepatitis C virus virus-host interactors innate antiviral immunity nuclear pore complex nucleocytoplasmic transport RNAi screen nuclear translocation IRF3 p65 microscopy time course kinetic Virus d’hépatite C interactants virus-hôte immunité innée antivirale complexe du pore nucléaire transport nucléocytoplasmique criblage ARNi translocation nucléaire microscopie cinétique
5	Spliceosome SNRNP200 promotes viral RNA sensing and IRF3 activation of antiviral response Tremblay, Nicolas 11 1900 (has links) No description available. Criblage pangénomique Immunité innée Virus de Sendai Interféron de type I RIG-I Voie de signalisation RLR SNRNP200 IRF3 TBK1 Senseur d’ARN viral Protéine adaptatrice Rétinite pigmentaire RNAi screen Innate Antiviral Immunity Sendai Virus Type I Interferon RLR Pathway Signalling Viral RNA Sensor Adaptor Protein Retinitis Pigmentosa

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