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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
41

Novel approaches to enhance the protective immune responses of vaccines against Porcine Reproductive and Respiratory Syndrome Virus

Cao, Qian 08 February 2018 (has links)
Since late 1980s, porcine reproductive and respiratory syndrome virus (PRRSV) has emerged as the most economically important swine pathogen affecting pig industries worldwide. Vaccination is the principal means that have been used for prevention of PRRSV infection. However, the currently available vaccines for PRRSV are generally considered as not very effective. One of the major obstacles for developing an effective modified live-attenuated vaccine (MLV) with broad protection is the delayed and insufficient immune responses mounted by PRRSV, and the problem is further exacerbated by the antigenic variations of the constantly-evolving field strains of PRRSV. In order to boost the immune response induced by the MLV vaccine virus, we evaluated the immunogenicity and vaccine efficacy of recombinant PRRSV MLVs expressing porcine IL-15 or IL-18 as adjuvants. The cytokine genes were fused with a GPI modification signal so that they are anchored onto the cell surface upon infection with the recombinant MLV. Both cytokines are successfully expressed on the cell membrane of porcine alveolar macrophage (PAMs) after recombinant MLVs infection in vitro. Subsequently, pigs vaccinated with cytokine-expressing recombinant PRRSV MLVs had an improved antiviral response of cytotoxic lymphocytes including natural killer (NK) cells and T cells, characterized by increased IFN-γ secretion and/or enhanced CD107a expression. The results offer a novel strategy to incorporate cytokine genes into PRRSV genome as potent bio-active adjuvants expressed by the vaccine virus itself. Since we showed that PRRSV VR2385 down-regulated swine leukocyte antigen class I surface expression, naturally the next logical question is which viral protein is responsible for this down-regulation. To answer the question, we cloned and expressed all known PRRSV structural and non-structural proteins and examined which protein(s) is involved in SLA-I downregulation. Our results identified the newly-discovered nonstructural protein Nsp2TF of PRRSV as the main mediator in down-regulating SLA-I expression. We also demonstrated that the Nsp2TF-knockout mutant virus lost its function of negatively modulating SLA-I presentation compared to the wild-type virus. The results suggest that disruption of the Nsp2TF's ability to down-regulate SLA-I expression may improve the existing PRRSV vaccines towards a better CMI response against the virus. / PHD / Porcine reproductive and respiratory syndrome virus (PRRSV) is an important swine pathogen, causing enormous economical losses in the pork industry worldwide. However, the vaccine program is not satisfactory, with the insufficient protection against genetically divergent strains and newly emerged strains. One of the most important reasons is that PRRSV is able to suppress immune responses in the host, but the underlying mechanisms are not well known. Therefore, the first dissertation study is to investigate novel strategies of developing live-attenuated vaccines with improved efficacy against PRRSV. In this study, we successfully generated recombinant PRRSV live vaccines that are able to express immuno-activating cytokines as adjuvants. Subsequently, pigs vaccinated with cytokine-expressing PRRSVs had significantly improved anti-PRRSV immune repsonses when compared to pigs vaccinated with unmodified PRRSV. Those recombinant PRRSVs also provided cross-protection against a heterologous PRRSV challenge. The second part of disseration research is to understand the mechanism of immune modulation by PRRSV. Our results showed that one of PRRSV proteins- Nsp2TF contributes to the PRSV-induced down-regulation of swine leukocyte antigen (SLA) class I expression. Since SLA class I molecules are essential in the activation of the immune response and required for the clearance of viruses, Our study suggested that knocking-out Nsp2TF could be of great value to generate PRRSV vaccines with a better immune response.
42

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.
43

Création d'un modèle cellulaire des voies respiratoires du porc pour étudier les effets d'une co-infection virale au virus du syndrome reproducteur et respiratoire porcin et au circovirus porcin

Alvarez, Fernando 08 1900 (has links)
Le circovirus porcin de type 2 (PCV2) est un pathogène majeur pour l’industrie porcine et est associé à une longue liste de maladies associées au circovirus porcin (MACVP). Les premières tentatives pour reproduire ces maladies ont montré que le virus doit être combiné à d’autres agents pathogènes du porc ou à différents stimulants du système immunitaire. De ces agents, le virus du syndrome reproducteur et respiratoire porcin (VSRRP) est celui qui est le plus souvent co-isolé avec le PCV dans les fermes. Une grande partie des efforts faits pour étudier les interactions entre ces deux virus ont été menés in vivo. Les interactions in vitro ont jusqu’à maintenant été peu étudiées du fait qu’il n’existe pas de modèle cellulaire permettant la réplication efficace des deux virus. L’objectif de ce projet était donc de développer un modèle cellulaire propice à la réplication des deux virus et d’étudier leur interaction en co-infection. Une lignée cellulaire provenant de la trachée d’un porcelet nouveau-né (NPTr), permissive au PCV, a été génétiquement modifiée pour exprimer la protéine CD163, un récepteur majeur du VSRRP. Ce projet a montré que cette nouvelle lignée cellulaire (NPTr-CD163) est permissive au VSRRP ainsi qu’à plusieurs génotypes de PCV (PCV1, PCV2a, PCV2b et PCV1/2a). De plus, les résultats obtenus lors d’infections mixtes suggèrent que la réplication du VSRRP et du PCV conditionne de façon génotype-dépendante celle du PCV puisque la réplication du PCV1 est inhibée en présence de VSRRP, alors que celle du PCV2b est significativement augmentée dans les mêmes conditions. Ni la mortalité cellulaire, ni la réponse cellulaire en cytokines n’a permis d’expliquer ces résultats. La modulation de la réplication du PCV par le VSRRP serait donc liée à un mécanisme spécifique qui demeure inconnu. De plus, cet effet varierait en fonction du génotype de PCV. / Porcine circovirus (PCV) type 2 (PCV2) is a major pathogen in the swine industry and has been described as the causative agent of a long list of conditions under the designation of porcine circovirus-associated diseases (PCVAD). Attempts to replicate PCVAD initially failed, as it was discovered that an immune trigger could facilitate the reproduction of clinical signs, either by co-infecting with other swine pathogens or using immune stimulants. Of these, porcine reproductive and respiratory syndrome virus (PRRSV) is the most frequently co-isolated agent in the field. Most effort has been made to understand this interaction in vivo since most in vitro cellular models lack the ability to efficiently replicate both viruses. To answer the lack of an in vitro model, we developed a cell line that allows the replication of both PRRSV and PCV. A neonate porcine tracheal cell line (NPTr) was genetically modified to stably express CD163 (NPTr-CD163), a major PRRSV receptor. NPTr-CD163 cells were able to replicate all PCV genotypes (PCV1, PCV1/2a, PCV2a and PCV2b) and PRRSV. A significant effect of PRRSV on PCV replication was found to be genotype dependent, as PCV1 replication was down regulated in the presence of PRRSV and PCV2b replication was up regulated in the same conditions. Neither cell mortality assays nor cytokine expression analysis were able to provide an explanation for these results. The effect of PRRSV on PCV1 and PCV2b replication is suggestive of a more specific, yet still unknown, mechanism. Furthermore, this effect is PCV-genotype dependant.
44

Interaction entre le virus SRRP et Actinobacillus pleuropneumoniae dans un modèle d'infection en culture cellulaire

Ferreira Barbosa, Jérémy A. 08 1900 (has links)
Le virus du syndrome reproducteur et respiratoire porcin (VSRRP) est un pathogène d’importance dans l’industrie porcine et est responsable d’importantes pertes économiques. Il n’existe pas d’antiviral efficace contre celui-ci. Il a récemment été mis en évidence que le surnageant de culture d’Actinobacillus pleuropneumoniae, l’agent étiologique de la pleuropneumonie porcine, possédait une activité antivirale in vitro contre le VSRRP dans la lignée cellulaire SJPL. Les objectifs de mon projet sont (i) d’étudier les mécanismes cellulaires menant à l’activité antivirale causée par le surnageant de culture d’A. pleuropneumoniae, et (ii) de caractériser les molécules actives présentes dans le surnageant de culture d’A. pleuropneumoniae. Dans un premier temps, des analyses de protéome ont été effectuées et ont permis d’observer que le surnageant de culture modulait la régulation du cycle cellulaire. Dans le but d’analyser le cycle cellulaire des cellules SJPL, la cytométrie en flux a été utilisée et a permis de démontrer que le surnageant de culture induisait un arrêt du cycle cellulaire en phase G2/M. Deux inhibiteurs de la phase G2/M ont alors été utilisé. Il s'est avéré que ces inhibiteurs avaient la capacité d’inhiber le VSRRP dans les cellules SJPL. Enfin, la spectrométrie de masse a été utilisée dans le but de caractériser les molécules actives présentes dans le surnageant de culture d’A. pleuropneumoniae et d’identifier deux molécules. Ce projet a permis de démontrer pour la première fois qu’A. pleuropneumoniae est capable de perturber le cycle cellulaire et que ce dernier était un élément important dans l’effet antiviral contre le VSRRP. / Porcine reproductive and respiratory syndrome virus (PRRSV) is the most important pathogen in the swine industry and causes important economic losses. No effective antiviral drugs against it exist. It was recently reported that the culture supernatant of Actinobacillus pleuropneumoniae, the causative agent of porcine pleuropneumonia, possesses an antiviral activity in vitro against PRRSV in SJPL cells. The objectives of this project were (i) to identify the mechanism behind the antiviral activity displayed by A. pleuropneumoniae, and (ii) to characterize the active molecules present in the culture supernatant. Proteomic analyses were first conducted and demonstrated the culture supernatant ability to induce modulations of the cell cycle regulation. In order to determine the SJPL cell cycle, flow cytometry analyses were performed and demonstrated that the culture supernatant induced a G2/M-phase cell cycle arrest. Two G2/M-phase cell cycle inhibitors were then used and their ability to inhibit PRRSV infection in SJPL cells was demonstrated. Finally, in order to characterize the active molecules present in the A. pleuropneumoniae culture supernatant, mass spectrometry was used and two molecules were identified. This is the first study demonstrating the A. pleuropneumoniae ability to disrupt cell cycle and the cell cycle importance to the inhibitory activity against PRRSV.
45

Identification of a new cell line permissive to porcine reproductive and resporatory syndrome virus replication

Jian-Jun, Jia 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.
46

Création d'un modèle cellulaire des voies respiratoires du porc pour étudier les effets d'une co-infection virale au virus du syndrome reproducteur et respiratoire porcin et au circovirus porcin

Alvarez, Fernando 08 1900 (has links)
Le circovirus porcin de type 2 (PCV2) est un pathogène majeur pour l’industrie porcine et est associé à une longue liste de maladies associées au circovirus porcin (MACVP). Les premières tentatives pour reproduire ces maladies ont montré que le virus doit être combiné à d’autres agents pathogènes du porc ou à différents stimulants du système immunitaire. De ces agents, le virus du syndrome reproducteur et respiratoire porcin (VSRRP) est celui qui est le plus souvent co-isolé avec le PCV dans les fermes. Une grande partie des efforts faits pour étudier les interactions entre ces deux virus ont été menés in vivo. Les interactions in vitro ont jusqu’à maintenant été peu étudiées du fait qu’il n’existe pas de modèle cellulaire permettant la réplication efficace des deux virus. L’objectif de ce projet était donc de développer un modèle cellulaire propice à la réplication des deux virus et d’étudier leur interaction en co-infection. Une lignée cellulaire provenant de la trachée d’un porcelet nouveau-né (NPTr), permissive au PCV, a été génétiquement modifiée pour exprimer la protéine CD163, un récepteur majeur du VSRRP. Ce projet a montré que cette nouvelle lignée cellulaire (NPTr-CD163) est permissive au VSRRP ainsi qu’à plusieurs génotypes de PCV (PCV1, PCV2a, PCV2b et PCV1/2a). De plus, les résultats obtenus lors d’infections mixtes suggèrent que la réplication du VSRRP et du PCV conditionne de façon génotype-dépendante celle du PCV puisque la réplication du PCV1 est inhibée en présence de VSRRP, alors que celle du PCV2b est significativement augmentée dans les mêmes conditions. Ni la mortalité cellulaire, ni la réponse cellulaire en cytokines n’a permis d’expliquer ces résultats. La modulation de la réplication du PCV par le VSRRP serait donc liée à un mécanisme spécifique qui demeure inconnu. De plus, cet effet varierait en fonction du génotype de PCV. / Porcine circovirus (PCV) type 2 (PCV2) is a major pathogen in the swine industry and has been described as the causative agent of a long list of conditions under the designation of porcine circovirus-associated diseases (PCVAD). Attempts to replicate PCVAD initially failed, as it was discovered that an immune trigger could facilitate the reproduction of clinical signs, either by co-infecting with other swine pathogens or using immune stimulants. Of these, porcine reproductive and respiratory syndrome virus (PRRSV) is the most frequently co-isolated agent in the field. Most effort has been made to understand this interaction in vivo since most in vitro cellular models lack the ability to efficiently replicate both viruses. To answer the lack of an in vitro model, we developed a cell line that allows the replication of both PRRSV and PCV. A neonate porcine tracheal cell line (NPTr) was genetically modified to stably express CD163 (NPTr-CD163), a major PRRSV receptor. NPTr-CD163 cells were able to replicate all PCV genotypes (PCV1, PCV1/2a, PCV2a and PCV2b) and PRRSV. A significant effect of PRRSV on PCV replication was found to be genotype dependent, as PCV1 replication was down regulated in the presence of PRRSV and PCV2b replication was up regulated in the same conditions. Neither cell mortality assays nor cytokine expression analysis were able to provide an explanation for these results. The effect of PRRSV on PCV1 and PCV2b replication is suggestive of a more specific, yet still unknown, mechanism. Furthermore, this effect is PCV-genotype dependant.
47

Modélisation de la réponse immunitaire au virus du Syndrome Dysgénésique et Respiratoire Porcin / Modelling the immune response to the Porcine Reproductive and Respiratory Syndrome virus

Go, Natacha 08 December 2014 (has links)
Le SDRPv est responsable de pertes économiques mondiales et son contrôle est un enjeu majeur pour la production porcine. La vaccination, principale mesure de contrôle, ne permet pas d'éradiquer l'infection et confère seulement une protection partielle de l'hôte. Ce manque d'efficacité est principalement due à grande variabilité de virulence des souches du SDRPv, induisant des dynamiques intra-hôte très variables. L'objectif de cette thèse est de mieux comprendre les interactions entre le virus et la réponse immunitaire, dans l'optique d'améliorer le contrôle de cette maladie. Pour cela, une approche de modélisation dynamique et déterministe a été choisie. Nous avons développé un modèle immunitaire original qui consiste en une représentation intégrative de la dynamique intra-hôte. Il décrit les mécanismes immunitaires à l'échelle inter-cellulaire, incluant la réponse innée, l'activation et l'orientation de la réponse adaptative, ainsi que leurs régulations complexes par les principales cytokines. Nos premiers résultats montrent que des durées d'infection similaires mais associées à des dynamiques immunitaires contrastées s'expliquent par la prise en compte des mécanismes immunitaires impactés par la virulence. Cela apporte de nouvelles pistes pour expliquer les incohérences apparentes entre résultats expérimentaux. Nous avons ensuite montré que l'exposition, dont l'effet est souvent négligé, a un impact sur la dynamique intra-hôte qui varie en fonction de la virulence. Finalement, nous avons exploré la dynamique intra-hôte induite par l'infection d'animaux vaccinés, ouvrant des pistes pour améliorer l'efficacité des vaccins. Cette thèse apporte également de nouvelles pistes pour guider les approches futures, aussi bien expérimentales que par modélisation, ainsi que des perspectives prometteuses pour le contrôle du SDRPv à l'échelle du troupeau. / PRRSv is responsible for significant worldwide production losses and its control is a major challenge for the swine industry. Vaccination, the main control measure, does not allow to eradicate the infection and only confers a partial protection to the host. This lack of efficiency is mainly due to the strong variability in PRRSv strain virulence, which induces highly variable within-host dynamics. This thesis aims at better understanding the interactions between the virus and the immune response in order to improve PRRSv control. To tackle this issue, a dynamic and deterministic modelling approach was chosen. We developed an original immunological model consisting in an integrative representation of the within-host dynamics. It describes the immune mechanisms at the between-cell scale, including the innate response, the activation and orientation of the adaptive response and their complex regulations by the major cytokines. Our first results show that similar infection durations associated with contrasted immune dynamics are explained by the consideration of the immune mechanisms affected by the strain virulence. They provide new insights to explain apparent inconsistencies between experimental data. We then showed that the exposure, whose effect is often neglected, has an impact on the within-host dynamics, which varies depending on the virulence level. Finally, the within-host dynamics induced by the infection of a vaccinated pig was explored, providing new insights to improve vaccine efficiency. This thesis also provides new insights to guide further experimental and modelling approaches and promising prospects for PRRSv control at the herd level.
48

Decoding protein networks during porcine reproductive and respiratory syndrome virus infection through proteomics

Sanchez Mendoza, Laura 08 1900 (has links)
Le virus du syndrome reproducteur et respiratoire porcin (VSRRP) est un pathogène de grande importance dans l'industrie porcine car il peut entraîner des pertes économiques. L'une des lignées cellulaires couramment utilisée pour la recherche et la production de vaccins est MARC-145 (cellules rénales de singe vert africain). Les interactions moléculaires entre les cellules hôtes et le virus sont essentielles pour comprendre le mécanisme par lequel le virus utilise la machinerie cellulaire pour se répliquer et infecter les cellules voisines. Notre objectif était d'analyser les changements protéomiques produits lors de l'infection par le VSRRP chez les cellules MARC-145, y compris la composition des virions et des exosomes produits par les cellules infectées. Les surnageants des cellules infectées et non infectées ont été purifiés pour obtenir les virions et exosomes des cellules hôtes. Par la suite, les protéines extraites ont été analysées par spectrométrie de masse à haute résolution quadripolaire-hybride-Orbitrap, et classées selon la fonction moléculaire et la localisation subcellulaire. Le besoin d'obtenir des données protéomiques fiables a conduit au prochain objectif : optimiser l'infection des cellules MARC-145 par le VSRRP. Pour évaluer l'efficacité de l'infection, nous avons synchronisé l'infection en utilisant un virus marqué avec une protéine fluorescente verte améliorée (eGFP) et en ajoutant des polycations à différentes concentrations pour stimuler la liaison des particules virales à la cellule. Pour vérifier le pourcentage de cellules infectées, nous avons utilisé la microscopie à fluorescence et la cytométrie en flux. Nos résultats suggèrent que les protéines cellulaires affectées au cours de l'infection par le VSRRP pourraient jouer un rôle important dans la réponse immunitaire de l'hôte et / ou le cycle de vie viral. L’efficacité de l'utilisation de polycations pour augmenter l'infection par le VSRRP a été démontrée. / Porcine reproductive and respiratory virus (PRRSV) is a pathogen of high importance in the porcine industry because it can lead to significant economic losses. One of the cell lines routinely used for research and vaccine production is MARC-145 (African green monkey kidney cells). Molecular interactions between the host cells and the virus are essential to understand how the virus uses the cell machinery to replicate and infect neighbouring cells. Our goal was to analyze the proteomic changes involved during the PRRSV infection in MARC-145 cells, including the composition of the infected cells' virions and exosomes. The infected and non-infected cells' supernatants were purified to obtain the host cells' virions and exosomes. Extracted proteins were further analyzed by High-Resolution-Quadrupole-Hybrid-Orbitrap mass spectrometry and classified according to molecular function and subcellular localization. The need for obtaining reliable proteomics data led to the next goal of optimizing the infection of MARC-145 cells with PRRSV. To assess the efficiency of the infection, we synchronized the infection, used a virus tagged with an enhanced green fluorescent protein (EGFP) and added polycations at different concentrations to stimulate the binding of the viral particles to the cell. To verify the percentage of infected cells, we used fluorescence microscopy and flow cytometry. Our findings suggest the cellular proteins affected during the PRRSV infection could play important roles in host immune response and/or the viral life cycle. The efficiency of the use of polycations was demonstrated to be effective in increasing PRRSV infection.
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Novel approaches towards vaccine developments against porcine circovirus type 2 and porcine reproductive and respiratory syndrome virus

Pineyro Pineiro, Pablo Enrique 06 November 2015 (has links)
Porcine circovirus type 2 (PCV2) is the causative agent of porcine circovirus-associated disease (PCVAD). Porcine reproductive and respiratory syndrome (PRRS) is caused by PRRS virus (PRRSV). Both PCV2 and PRRSV have caused devastating diseases in the swine industry worldwide, resulting in immense economic losses. One of the most common co-infections in the swine industry is PCV2 and PRRSV. The aim of this dissertation research is to explore different experimental approaches to develop novel vaccines against the two major pathogens affecting swine production and study the basic mechanisms that may be involved in viral pathogenesis. Two types of porcine circovirus (PCV), PCV1 and PCV2, have been identified thus far. PCV1, first identified as a contaminant of the PK-15 cell line, is non-pathogenic and has a low prevalence in swine herds. PCV2 is highly prevalent in most swine-producing countries and is associated with clinical PCVAD. The non-pathogenic PCV1 shares similar genomic organization with PCV2. Previously, it has been demonstrated that a genetically modified infectious chimeric PCV1-2a virus can tolerate up to a 27 aa insertion in the C-terminus of the ORF2 without affecting infectivity and produce a dual immune response against PCV2cap and the inserted epitope tag. Therefore, we evaluated the use of the non-pathogenic PCV1 wild-type (wt) virus and chimeric PCV1-2a vaccine virus (vs) to express four known B-cell epitopes of PRRSV. Peptide epitopes of PRRSV-VR2385, including GP2II (aa 40–51, ASPSHVGWWSFA), GP3I (aa 61–72, QAAAEAYEPGRS), GP5I (aa 35–46, SSSNLQLIYNLT), and GP5IV (aa 187–200, TPVTRVSAEQWGRP) were inserted in frame into the C-terminus of the ORF2 of PCV1wt as well as the PCV1-2avs. Four PCV1-PRRSVEPI chimeric viruses and four PCV1-2a-PRRSVEPI chimeric viruses were successfully rescued and shown to be infectious in vitro and co-expressed PCV1cap or PCV2cap with each specific PRRSV epitope. Two independent animal studies were conducted to evaluate whether the non-pathogenic PCV1 can serve as a vaccine delivery vector and whether the PCV1-2a vaccine virus can be used to develop a bivalent vaccine against both PCV2 and PRRSV. We demonstrated that three PCV1-PRRSVEPI chimeric viruses and two PCV1-2a-PRRSVEPI chimeric viruses were infectious in pigs. Importantly, we demonstrated that the PCV1-PRRSVEPI and PCV1-2a-PRRSVEPI chimeric viruses not only induced specific PCV1 or PCV2 IgG antibody but also specific anti-PRRSV epitope antibody responses as well. Regardless of the PCV backbone used, we showed that the PCV-PRRSV chimeric viruses elicited neutralizing antibodies against PRRSV-VR2385. These results provided a proof of concept for the potential use of the non-pathogenic PCV1 as a vaccine delivery system for PRRSV or other swine pathogens and the use of PCV1-2a vaccine virus to generate a bivalent vaccine against both PCV2 and PRRSV. PRRSV causes a persistent infection and immunosuppression. Immunomodulation of the host immune system is caused by modulation of numerous interleukins, such as type I interferons, tumor necrosis factor alpha (TNF-α), interleukin-1 (IL-1), interleukin-6 (IL-6), and interleukin-12 (IL-12) in infected pigs. Antigen-presenting cells (APCs) are the first line of defense, and their infection plays an important role in innate-mediated immune regulation during early immune responses. Among the APCs, pulmonary alveolar macrophages (PAMs), pulmonary interstitial macrophages (PIMs), and dendritic cells (DCs) are the main targets for PRRSV replication. The role of PRRSV-DCs interaction is not fully understood, and current research focuses on the production and regulation of interferons through DC-SIGN receptors. In this study, we evaluated the immunomodulation of MoDCs by PRRSV through interactions with the pDC-SIGN receptor, by blocking pDC-SIGN with recombinant hICAM-3-Fc or anti-pDC-SIGN mAb. Our results indicate that recombinant hICAM-3-Fc enhances mRNA expression of proinflammatory cytokines and that anti-pDC-SIGN mAb inhibits mRNA expression of TNF-α and IL-1α and enhances the expression of IL-12 induced by PRRSV in MoDCs. The results will help understand the molecular mechanisms of PRRSV pathogenesis. / Ph. D.
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<b>Ontological changes in the swine fetus and placenta from mid- to late-gestation</b>

Kaylyn G Rudy (19832829) 11 October 2024 (has links)
<p dir="ltr">Porcine reproductive and respiratory syndrome virus (PRRSV) is a devastating virus that is endemic to the swine industry. This virus has little direct effect on the dam but results in abortions, stillborn, and delivery of viremic piglets. PRRSV is unable to cross the swine placenta in early gestation but as gestation progresses, the placenta becomes permissible during late gestation. The mechanisms that allow the virus to cross the late gestation placenta are not well understood, but several theories have been presented regarding changes in placental morphology or enzymatic changes. Additionally, piglets who experience IUGR due to uterine crowding have been found to be more resistant to PRRSV infection, having lower viral levels than their normal litter mates. When vertical transmission from the dam to fetus occurs not only can the effects previously mentioned occur, but PRRSV is also known to cause suppression of maternal and fetal thyroid hormone. Thyroid hormone plays numerous roles in fetal development such as accretion of fetal mass, appetite regulation, and coincidently follows a similar increase trajectory to that of fetal growth during mid- to late-gestation. Consequently, any dysregulation of thyroid hormone has the potential to cause severe side-effects and may alter fetal growth. The relationship between thyroid hormone and fetal growth and development is not well understood. Chapter 2 investigates the potential cause-and-effect relationship between fetal growth and thyroid hormone through the induction of fetal hypothyroidism. Pregnant gilts (n=24) were given a sham treatment (CON; n=12) or treated with methimazole (MMI; n=12), a goitrogen capable of crossing the placenta. These gilts were then further subdivided across four gestational timepoints spanning mid- to late-gestation, these being days 55, 66, 76, and 86. Treatment started 21 days prior to these desired dates. Upon completion of treatment the gilts were humanely euthanized, and fetuses were extracted (resulting populations of n=174 MMI and n=166 CON) and fetal body and organ weights were recorded. Collected tissues included heart, liver, lung, kidneys, spleen, brain and thyroid. Fetuses were imaged in the left and right lateral recumbency for phenotypic analysis, including novel head measurements. Placental sample were also taken. Additionally fore- and hind limbs were taken from the centermost male and female from each litter so that radiographs could be taken to analyze bone growth. Statistical analysis of all phenotypic differences was carried out using a linear mixed effect model including gestational age and treatment as fixed effects and gilt as a random effect. The data revealed that the left and right phenotypic parameters are highly correlated (R2>0.9). Upon extraction, goiters were present in the MMI fetuses and there was a significant increase in both absolute and relative thyroid weights. Thus, the use of MMI during this period of gestation was successful in inducing hypothyroidism. Additionally, the MMI treated thyroids had a significant treatment by time interaction with 0.014g and 0.21g increase at day 55 and 66 respectively indicating reduced compensatory action within the fetal hypothalamic-pituitary-thyroid axis during this earliest period. Liver weight as a percentage of body weight decreased from 6.06% to 2.56% between days 55 and 86 in the CON group but, was significantly increased at all time points in response to MMI induced hypothyroidism (P<0.01). Thus, the in brain to liver weight ratio decreases over time, in MMI fetuses (P<0.05). While all other phenotypic parameters were significantly altered by gestation age, there was no significant impact of fetal hypothyroidism. This indicates that fetal thyroid hormone is not the driving factor for the exponential fetal growth seen in mid- to late-gestation. PRRSV virus is a complex and devastating virus to the swine industry, especially when it infects pregnant gilts and sows. PRRSV is unable to cross the swine placenta during mid-gestation but as gestation progresses the virus readily crosses the placenta and is able to infect piglets during this late gestation period. The mechanisms by which PRRSV crosses the highly restrictive porcine placenta are not clear. Additionally, piglets who experience intrauterine growth retardation experience lower virus levels than their normal counterparts. Chapter 3 investigates the changes in three genes of interest that we hypothesized, had the potential to fluctuate throughout gestation and facilitate PRRSV transfer, as well as the morphological changes that occur in the maternal-fetal interface through mid- to late-gestation and how these aspects may vary between IUGR and normal piglets. Placental samples were collected from pregnant gilts (n=12) equally divided across days 55, 66, 76, and 86 of gestation. Samples were taken of each fetus’s placenta adjacent to the umbilical cord. A portion of the sample was cut into 1 cm2 and placed into a mold with optimal cutting temperature media (OCT) for later cryo-sectioning and histology. The remaining portion had the fetal placenta peeled from the endometrium and flash frozen in liquid nitrogen for RNA extraction. A subset of samples was chosen based on fetus’s brain to liver weight ratios (n=96). From each litter two males and two females with the most extreme case of IUGR, based on z-scores, were chosen and the same was done for the two males and females with lowest brain to liver weight ratios, the later were classified as large for gestational age (LGA). 56 of the original 64 had acceptable levels of placental RNA for analysis. A total of 3 genes were chosen for analysis based on their function and previous literature. These included CD163, SIGLEC1 and IL-10. No significant up or down regulation was seen in any of the selected genes and there was no variation between IUGR and LGA fetuses. Additionally, placenta histology was conducted to evaluate populations of CD163 positive macrophages throughout the maternal fetal interface across mid- to late-gestation. Populations of CD163 positive macrophages were found on both the maternal and fetal sides of the maternal fetal interface at all timepoints. Collectively these results show there is no fluctuation in CD163, SIGLEC1, or IL-10 among timepoints or between IUGR and LGA fetuses. Additionally, the histology samples confirm the presence of resident populations of CD163 positive macrophages on maternal and fetal sides of the MFI. Collectively these results indicate that more research needs to be done to determine the underlying mechanisms of PRRSV transmission during late gestation.</p>

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