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An Analysis of Signaling Processes Leading to a Defense Response in SoybeanMcNeece, Brandon Trey 08 December 2017 (has links)
Plant-parasitic nematodes are the cause of devastating yield loss in vital agricultural crops around the world. Heterodera glycines, also referred to as soybean cyst nematode, is the main pathogen of Glycine max (soybean) causing more loss than all other pathogens of G. max combined. The resultant economic impact due to H. glycines in United States soybean production alone is estimated to account for an annual one-billion-dollar loss. Natural resistant genotypes have been found in trials to combat this pathogen. Of the resistant varieties identified, G. max[Peking/PI 548402] and G. max[PI 88788] are the major sources of resistance. Identification of genes expressed in the cells of which the nematode parasitizes, the syncytia, exclusively undergoing the resistant/incompatible reaction from the two major sources of resistance mentioned previously have identified a number of candidate genes presumed to function in defense to H. glycines parasitism. Prior to this work, success has been obtained by selection of a number of these candidate genes in functional analysis to show involvement in defense. This work is aimed at functionally identifying signaling components involved in the defense reaction. Reverse genetic studies of NON-RACE SPECIFIC DISEASE RESISTANCE 1 Glycine max homolog, Gm-NDR1-1, has confirmed a functional role in the defense to H. glycines to G. max. Gene expression studies revealed both effector-triggered immunity (ETI) and pattern-triggered immunity (PTI) components to be regulated by Gm-NDR1-1. Furthermore, induction in the heterologous expression of Gm-NDR1-1 in Gossypium hirsutum (cotton) suppressed Meloidogyne incognita parasitism. Harpin treatment has been evaluated due to the knowledge of NDR1’s capability of being harpin-induced (HIN1). Expression studies of the harpin treatment did in fact induce Gm-NDR1-1. The analysis further provides evidence of NDR1 role in defense by displaying the harpin-induced response of NDR1 in resistance to infection of Rotylenchulus reniformis. Receptors are known to function through signaling components in plant defense. Therefore, the conserved downstream signaling component of multiple diverse stimuli, mitogen-activated protein kinases (MAPKs) were functionally characterized in G. max for their role in resistance to H. glycines via the reverse genetic parasitism assays and evaluated to observe the effect on defense gene expression.
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Identification of Transmembrane and Extracellular Host Proteases that Promote Human CoV Entry and Syncytium FormationMulloy, Rory 16 September 2021 (has links)
Coronaviruses (CoVs) comprise a family of enveloped viruses that cause respiratory disease in humans, including CoV disease 2019 (COVID-19), caused by severe-acute respiratory syndrome CoV-2 (SARS-CoV-2). For CoV infection to occur, the CoV spike (S) protein must mediate fusion between the viral and host membranes. This entry process can also be repurposed during infection to promote cell-to-cell fusion, further contributing to viral spread. To trigger fusion, S must bind its cognate receptor and be cleaved by host proteases. Identifying cellular proteases capable of triggering CoV fusion is critical to understand CoV entry, tropism, and cell-cell spread, however the range of proteases capable of promoting CoV fusion has not been fully explored. Here, using fusion and entry assays, I provide evidence implicating matrix metalloproteinase-9 (MMP-9) as a fusion trigger for SARS-CoV-2 and HCoV-229E. Additionally, I show MMP-9 expression is upregulated during CoV infection, highlighting its potential relevance as a CoV triggering factor.
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Étude de l'autophagie lors d'une co-infection par le virus de la rougeole et Salmonella typhimurium / Study of autophagy during co-infection between Measles virus and Salmonella typhimuriumClaviere, Mathieu 25 June 2018 (has links)
Le virus de la rougeole est un agent pathogène responsable d’immunosuppressions transitoires mais sévères chez les individus infectés. L’infection par ce virus peut ainsi mener à l’établissement d’infections secondaires opportunistes, souvent décrites chez les patients rougeoleux. Cependant, la contribution du virus de la rougeole sur des infections secondaires à l’échelle de la cellule co-infectée n’a jamais fait l’objet d’études. Notre équipe à précédemment démontré que le virus de la rougeole induit une autophagie productive dans les cellules infectées, requise pour une réplication optimale du virus. À l’opposé, certains pathogènes comme la bactérie Salmonella typhimurium sont restreints par l’autophagie. Le but de cette thèse est d’étudier la contribution de l’autophagie sur la prolifération bactérienne en condition de co-infection avec le virus de la rougeole. Au cours du projet, nous avons identifié que dans les cellules co-infectées avec le virus de la rougeole, la bactérie Salmonella typhimurium hyperprolifère. Cette prolifération intense prend place essentiellement dans des cellules multinucléées géantes (syncytia) formées par le virus. En outre, la bactérie, normalement localisée dans une vacuole cellulaire, se localise dans le cytosol de ces syncytia et semble insensible à l’autophagie. Au cours de cette thèse, nous avons identifié que le facteur antimicrobien TBK1 pourrait être détourné par l’infection virale, contribuant ainsi à l’échappement de la bactérie à l’autophagie. Ce travail de thèse met ainsi en évidence une nouvelle possibilité d’échappement de bactéries à l’autophagie lors d’une co-infection virale. / Measles virus is a pathogenic agent responsible for transient but severe immunosuppression in infected individuals. The infection can lead to the establishment of secondary infections, frequently described in measles virus infected patients. Nevertheless, Measles virus contribution to secondary infection at cell scale level have never been studied yet. Our team has previously described that Measles virus induce a fully functional autophagy in infected cells, which is mandatory for an efficient viral replication. On the opposite, some pathogens, as the bacteria Salmonella typhimurium are restricted by autophagy. The aim of this PhD project is to study the contribution of autophagy on bacterial proliferation upon Measles virus co-infection at cell level. During this project, we have identified that in Measles virus coinfected cells, Salmonella typhimurium hyperproliferates. This exacerbated proliferation takes place in multinucleated giant cells induced by the virus, which are called syncytia. In addition, the bacteria, which is normally localized in cellular vacuole, is localized directly inside the cytosol of syncytia. Furthermore, cytosolic bacteria appears to be insensitive to autophagy. During this PhD project, we have identified that the cellular factor TBK1 could be hijack by the viral infection. Thus, this could allow the auophagic escape of the bacteria. This study highlight a new opportunity of autophagic escape of bacteria during a viral co-infection.
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HIV-1-Induced Cell-Cell Fusion: Host Regulation And Consequences For Viral SpreadSymeonides, Menelaos 01 January 2016 (has links)
Human immunodeficiency virus type 1 (HIV-1) is a human retrovirus of the lentivirus subgroup which primarily infects T cells and macrophages, and causes acquired immune deficiency syndrome (AIDS). Since its emergence in the early 1980s, HIV-1 has caused a global pandemic which is still responsible for over one million deaths per year, primarily in sub-Saharan Africa.
HIV-1 has been the subject of intense study for over three decades, which has resulted not only in major advances in cell biology, but also in numerous drug treatments that effectively control the infection. However, cessation of treatment always results in reemergence of the infection due to the ability of HIV-1 (and other lentiviruses) to establish a persistent quiescent infection known as latency. The elimination of latently-infected cells is the primary goal of current research towards a cure for HIV-1, alongside efforts to develop vaccines, which have thus far been fruitless.
The spread of HIV-1 to susceptible target cells (which express the receptor CD4 and a co-receptor; CXCR4 or CCR5) can take place when antigen-presenting cells, such as dendritic cells, capture virus particles and then pass them on to target cells, without themselves becoming infected. Alternatively, productively infected T cells or macrophages can spread HIV-1 either by shedding virus particles to the milieu, which are then stochastically acquired by target cells, or through transient contacts between infected and uninfected cells known as virological synapses (VSs). VS-mediated cell-to-cell transmission is thought to be highly efficient due to the release of virus directly onto (or very near to) a target cell, and some evidence suggests that the VS is a privileged site which allows the virus to evade neutralizing antibodies and drugs. However, and most importantly, it is of central interest to us because the same transient cell adhesions that facilitate virus transfer can also result in the fusion of the two cells to form a syncytium, due to the presence of the viral fusogen Env and its receptor and co-receptor on either side of the VS. While T cell syncytia can be found in vivo, they remain small, and it appears that the majority of VSs resolve without fusion.
The regulation of HIV-1-induced cell-cell fusion and the fate of those syncytia are the focus of the work presented here. A family of host transmembrane proteins, the tetraspanins, which regulate cell-cell fusion in other contexts (e.g. the fusion of myoblasts to form and maintain myotubes), were found to inhibit HIV-1-induced cell-cell fusion. Our investigations have further characterized this regulation, concluding that tetraspanins allow cells to reach the fusion intermediate known as hemifusion before their ability to repress fusion takes effect. In parallel, because syncytia are nevertheless found both in infected individuals and in a humanized mouse model for HIV-1, we also became interested in whether small T cell-based syncytia were able to participate in HIV-1 spread by transmitting virus to target cells. Using a simple three dimensional in vitro culture system which closely recapitulates those in situ observations, we found that small syncytia can contact target cells and transmit virus without fusing with them. Overall, these studies further our understanding of HIV-1-induced syncytia and reveal a previously unrecognized role for these entities as active participants in HIV-1 spread.
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Investigation of an Oncolytic MeV Cell-Cell Fusion Phenomenon Induced by an siRNABarkley, Russell 02 December 2020 (has links)
Oncolytic measles virus is a promising cancer therapeutic in clinical trials which
possesses multiple characteristics that are advantageous over traditional therapies.
Currently, clinical oncolytic measles virus vectors are unmodified or express reporter
transgenes that benefit its therapeutic efficacy. The next phase in its development will
see genetically engineered vectors encoding transgenes that enhance its antineoplastic effects. To this end, preclinical research has focused on studying novel transgenes which favour viral replication, cytotoxicity, and the anti-cancer immune response. We sought to encode artificial micoRNAs targeting RIG-I as a strategy to interfere with innate immunity. Silencing RIG-I with multiple siRNAs yielded one which promotes measles virus syncytia formation through a mechanism that appears to be independent of RIG-I. The mechanism caused by the siRNA leads to enhanced measles virus cell-cell fusion and has peculiar characteristics which are not fully understood.
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L’étude de la glycoprotéine gM du virus Herpès simplex de type 1 (HSV-l) : identification de ses partenaires viraux et cellulaires et leur rôle dans la régulation de l’infection viraleEl Kasmi, Imane 04 1900 (has links)
No description available.
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