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Gnotobiotic Pig Models for the Study of Enteric Pathogen Replication and PathogenesisNyblade, Charlotte June 09 October 2024 (has links)
Clostridioides difficile (C. difficile) and human rotavirus (HRV) are leading causes of bacterial and viral gastroenteritis worldwide. Treatment and vaccination options for both pathogens have significant limitations. C. difficile infections are treated with antibiotics, which is paradoxical as C. difficile itself is associated with antibiotic usage. In the United States, two live oral attenuated vaccines (Rotarix and RotaTeq) are licensed for protection against HRV. Since receiving approval from the World Health Organization (WHO), Rotarix and RotaTeq have been widely implemented into global national childhood immunization schedules, with one report finding 59 countries using Rotarix and 25 using RotaTeq. However, these vaccines have much lower efficacy rates in low- and middle-income countries. Because of these caveats, there is an urgent need to generate novel prophylaxes and treatments for C. difficile and HRV. In order to address this need, animal models that replicate the nuances of each infection are imperative. We have developed gnotobiotic (Gn) pig models for each pathogen. Gn pigs infected with spores of the hypervirulent UK1 strain of C. difficile develop classical signs of infection, including watery diarrhea and weight loss. Gross necropsy reveals colonic distention and discoloration, and histopathological evaluation shows volcano lesions, pseudo membrane formation, and epithelial cell erosion. Gn pigs infected with a G4P[6] strain of HRV also display pathogen specific signs of infection, including diarrhea, fecal rotavirus shedding, and damaged intestinal villi. A dose response study of the G4P[6] strain revealed diarrhea and virus shedding occurred at all tested doses, however the most severe diarrhea and virus shedding, measured by cumulative diarrhea score, area under the curve (AUC) of diarrhea, peak virus titer, and AUC of virus shedding, were all detected in the highest dose group. Based on the presentation of clinical signs of infection, 105 fluorescent focus units was selected as the optimal challenge dose for future studies. These models enable us to test candidate therapeutics, but also elucidate unique replicative features of the pathogens. For example, we found that HRV can replicate in the salivary glands and nasal cavity of Gn pigs in addition to the small intestine. HRV infection primed immune responses in the ileum, tonsils, and facial lymph nodes; infection also induced high levels of systemic and mucosal rotavirus specific antibody responses. Moving forward, we hope to expand upon this replication study to identify what cell types within the glands are infected as well as look at local cellular immune responses to HRV infection. Additional future directions include determining the protective efficacy of next generation HRV vaccines and evaluating effectiveness of an engineered probiotic yeast in reducing severity of C. difficile infection and disease. The Gn pig models of C. difficile and G4P[6] HRV are clinically relevant, and they will continue to serve as useful tools to better our understanding of pathogenesis, infection, and prevention of these pathogens. / Doctor of Philosophy / Clostridioides difficile (C. difficile) and human rotavirus (HRV) both cause gastrointestinal related symptoms when they infect humans. Treatments available for C. difficile and HRV all have significant drawbacks. This represents a gap in knowledge which we aimed to fill by developing germ-free (gnotobiotic [Gn]) pig models of C. difficile and HRV infection and disease. Animal models that mimic the outcomes of disease seen in humans are essential for evaluating protectiveness of new therapeutics. The more similar the disease presentation, the more likely the treatment results will be translational to humans. We began with C. difficile; pigs were orally fed C. difficile and monitored for a week post infection for development of signs of infection. Inoculated pigs lost weight and developed diarrhea. Bacterial cells and toxins were isolated from fecal samples collected on various days post infection. Multiple changes were observed in infected pigs’ large intestinal tissues, including severe bleeding, tissue distension, and fluid buildup. Infected pigs also had significant upregulation of pro-inflammatory cytokines, indicating activation of the immune response. We performed a similar procedure for the establishment of the HRV model. Gn pigs were orally challenged with differing doses of G4P[6] HRV and followed for several days post infection. Consistent with HRV infection in children, the pigs developed watery diarrhea that lasted for multiple days. Small intestinal tissues collected at necropsy had several signs of damage, including blunted villi, fluid buildup, and immune cell invasion. These lesions were also consistent with HRV infection in humans. Taken all together, these results indicated successful establishment of both C. difficile and HRV models. While the primary goal of generating these models was to evaluate new treatments, a secondary goal was to use them to better our understanding of pathogen replication dynamics. For example, the small intestine was thought to be the primary site of HRV infection. Using a pig model of HRV, we expanded on this knowledge to show that HRV can replicate in the nose and salivary glands as well. Additionally, we found HRV infection to induce immune responses near the sites of infection, including the intestine, the tonsils, and the facial lymph nodes. Overall, these studies demonstrate the utility of germ-free pig models and are an important first step in generating more effective treatments for bacterial and viral infections.
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Immune responses to human norovirus and human norovirus virus-like particles in gnotobiotic pigs and calvesDias e Souza, Menira B. L. 22 June 2007 (has links)
No description available.
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Mechanisms of Immunomodulation By Probiotics: Influence of Lactobacilli On Innate and T Cell Immune Responses Induced By Rotavirus Infection and VaccinesWen, Ke 23 November 2011 (has links)
My dissertation research focused on studying mechanisms of immunomodulation by probiotic lactobacilli on innate and T cell immune responses induced by rotavirus infection and vaccines in a gnotobiotic pig model of human rotavirus (HRV) infection and vaccination. We first studied the effects of probiotics on antigen-presenting cells (APCs) through TLR activation. We found that a mixture of Lactobacilli acidophilus strain NCFM (LA) and L. reuteri (ATCC# 23272) induced strong TLR2-expressing APC responses and virulent HRV induced a TLR3 response. Probiotics and HRV had an additive effect on TLR2- and TLR9-expressing APC responses, consistent with the adjuvant effect of lactobacilli.
Dose effects of LA on T cell immune responses were investigated. We found that low dose LA significantly enhanced frequencies of HRV-specific IFN-γ producing CD4⁺ and CD8+ T cells whereas high dose LA reduced frequencies of HRV-specific IFN-γ producing CD4+ T cells. Low dose LA reduced frequencies of induced regulatory (iTreg) cells and TGF-β expression in the iTreg cells whereas high dose LA increased frequencies of iTreg cells and IL-10 expression in the iTreg cells. The dose effects of LA were independent of HRV infection/vaccination.
In addition, we demonstrated that TCR-γδ T cells play an important role in modulating immune responses to rotavirus infections. All three γδ T cell subsets showed evidence of activation after HRV infection by increasing TLR2, TLR3, TLR9 expression and IFN-γ production during the acute phase of infection. There was an additive effect between lactobacilli and HRV in inducing total γδ T cell expansion in ileum and in recruiting the cells from blood. HRV infection induced a significant expansion of the CD2+CD8+ γδ T cell subset in the ileum. This subset mainly exerts regulatory functions as evident by expressing FoxP3, secreting TGF-β and IL-10 or increasing production of the anti-inflammatory cytokines by CD4+ and/or CD8+ αβ T cells in the co-cultures. CD2+CD8- and CD2-CD8- γδ T cell subsets have mainly pro-inflammatory and anti-viral functions as evident by secreting IFN-γ or promoting CD4+ αβ T cell proliferation and IFN-γ production.
This knowledge will facilitate the development of more effective vaccination and therapeutic strategies to protect children and young animals against rotavirus gastroenteritis. / Ph. D.
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Evaluation of the novel P particle vaccine candidate against human norovirus using the gnotobiotic pig challenge modelKocher, Jacob 10 December 2014 (has links)
Noroviruses (NoVs) are a cause of nonbacterial acute gastroenteritis affecting all ages. NoV infections result in over 200,000 pediatric deaths in developing countries annually. Vaccine development has been hindered by the lack of cell culture systems and small animal models; thus, vaccine development has relied upon recombinant VP1 capsid proteins, such as virus-like particles (VLPs) and P particles. P particles are a novel vaccine candidate derived from expression of the VP1 protruding (P) domain, while VLPs require expression of the full-length VP1. My studies utilize a gnotobiotic (Gn) pig model of human NoV infection and diarrhea to evaluate the protective efficacy and T cell responses induced by P particles and to compare them with prior NoV infection (NoVPO) and VLPs. Gn pigs received 100 µg of P particles (LoPP) or VLPs, 250 µg P particles (HiPP), or adjuvants only intranasally at post-inoculation day (PID) 0, 10, and 21. Monophosphoryl lipid A and chitosan were used as mucosal adjuvants. At PID 28, a subset of pigs were orally challenged with 10 median infectious doses (ID50) NoV. NoVPO, LoPP, HiPP, and VLPs provided partial protection from diarrhea (83%, 47%, 60%, and 60% protection rates, respectively). Only NoVPO and HiPP provided protection from shedding (49% and 60% protection rates, respectively) and also reduced the number of CD25- regulatory T cells (Tregs) in duodenum following challenge. NoV primary infection induced an overall pro-Treg and low, transient Th1 response. LoPP induced stronger overall T cell responses compared to VLPs, including activated CD4+ T cells and duodenal CD8+IFN-γ+ T cells, suggesting that P particles are more immunogenic than VLPs. I also evaluated the effects of simvastatin, a cholesterol-reducing drug that increases NoV infectivity, on P particle vaccine efficacy. Simvastatin abolished P particle-induced protection and significantly increased diarrhea severity. Simvastatin reduced total numbers of duodenal mononuclear cells, IFN-γ+ T cells pre-challenge, and Tregs post-challenge, indicating that simvastatin impairs development of immune system and immune responses. Findings from these studies elucidate potential mechanisms behind P particle-induced immunity and reveal the negative effects of simvastatin on NoV-induced protective immunity. The knowledge will facilitate the development of effective NoV vaccines. / Ph. D.
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Rotavirus vaccines and impact of maternal antibodies and cytokines on neonatal immune responses in swineNguyen, Trang Van 24 August 2005 (has links)
No description available.
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Study of enteric virus infection and parenteral vaccines in the gnotobiotic pig modelRamesh, Ashwin Kumar 29 January 2020 (has links)
Human rotavirus (HRV) and human norovirus (HuNoV) are the most common causative agents of acute gastroenteritis- (AGE) related morbidity and mortality around the world. Gnotobiotic (Gn) pigs are the ideal large-animal model that allows for accurate, and precise, preclinical evaluation of vaccine efficacy. Similarities in gastrointestinal anatomy, physiology, and immune system allows for direct translation of results from Gn pigs to humans. Commercially available HRV vaccines perform significantly poorer in low- and middle- income countries as compared with developed countries. Non-replicating rotavirus vaccines (NRRVs) have been proposed as a viable solution to the problems facing currently available live-, attenuated oral vaccines and evaluation of a NRRV was the first research project in this dissertation. Three doses of a novel parenterally administered nanoparticle-based RV vaccine, P24-VP8*, adjuvanted with Al(OH)3 adjuvant, was able to prime VP8*-specific mucosal and systemic T cell responses (IFN-γ producing CD4+ and CD8+ T cells), and to induce strong systemic B cell responses (IgA, IgG and serum neutralizing antibodies). A significant reduction in the mean diarrhea duration, fecal virus shedding titers, and significantly lower fecal cumulative consistency scores was observed among vaccinated pigs demonstrating the efficacy of the vaccine against RV infection and diarrhea.
Next, we determined the median infectious dose (ID50) and median diarrhea dose (DD50) of the GII.4/2003 Cin-1 variant of HuNoV in Gn pigs to better standardize the pig model for HuNoV vaccine evaluation. Gn pigs were inoculated with 7 different doses of Cin-1 at 33-34 days of age. Pigs were monitored daily from post-inoculation day (PID) 1 to 7, for fecal virus shedding and fecal consistency to evaluate the virus infectiousness and associated diarrhea. The Log10 ID50 and DD50 were determined based on various mathematical models to be between 3.11 to 3.76, and 3.37 to 4.87 RNA copies, respectively. The Beta-Poisson was identified to be the best-fitting statistical model for estimating both the ID50 and DD50 of Cin-1. Determining the ID50 of the challenge virus strain is crucial for identifying the true infectiousness of HuNoVs and for accurate evaluation of protective efficacies in pre-clinical studies of therapeutics, vaccines and other prophylactics using this reliable animal model.
The lack of an easily reproducible cell culture model for HuNoV has significantly delayed the development of effective vaccines. There is still no HuNoV vaccine available. Currently, the vaccine development efforts are mostly based on genetically engineered virus-like particles (VLPs) comprised of the major HuNoV capsid protein VP1. We tested the immunogenicity of a novel tetravalent VLP vaccine containing 4 major HuNoV genotypes (GI.1, GII.3, GII.4 and GII.17) using Gn pigs and evaluated its protective efficacy when challenged with GII.4 Cin-1 HuNoV. Three doses of the VLP vaccine with Al(OH)3 adjuvant administered to Gn pigs intramuscularly (IM), induced high levels of VLP-specific serum IgA and IgG antibody and hemagglutination inhibition antibody responses in the vaccinated pigs. VLP-specific IFN-γ producing CD4+ and CD8+ T cells were also elevated among vaccinated pigs at post-challenge day (PCD) 7 in the spleen and blood, but not in the ileum. However, the vaccinated pigs were not protected from infection and diarrhea when challenged with any one of the three different doses (2 x 105, 8 x 104, and 2 x 104 genome RNA copies) of Cin-1 HuNoV. These results indicated that the IM tetravalent VLP vaccine was highly immunogenic, but the presence of high levels of immune effectors induced by the vaccine were not sufficient for protecting the Gn pigs from Cin-1 challenge. Amino acid (aa) sequence analysis showed that the GII.4 Sydney 2012 strain which was included in the VLP vaccine, had 23 aa substitutions in the major receptor binding domain (P2) compared to the Cin-1, a GII.4 Farmington Hills 2002 strain. Our findings, for the first time, provided in vivo experimental evidence for the total lack of cross-genogroup, cross-genotype and cross-variant protection among HuNoV. This finding has importance implications for HuNoV vaccine development. HuNoV vaccines have to include multiple variants and have to be routinely updated in order to ensure sustained protection among the population.
Together these three studies in this dissertation demonstrate the versatility of Gn pigs as a reliable large animal model for studying the pathogenesis and immunity of enteric viruses and the evaluation of immunogenicity and protective efficacy of novel enteric viral vaccines. / Doctor of Philosophy / People of all age groups are susceptible to acute gastroenteritis (AGE), a condition characterized by sudden onset of diarrhea, nausea and abdominal cramps. The two most important viral pathogens responsible for causing AGE are rotavirus (RV) and norovirus (NoV). Gnotobiotic (Gn) pigs have been valuable in helping us understand the mechanism of infection, pathogenesis, immunity and have played a key role in the expediting development of novel vaccines and therapeutics against both of these viruses. Live oral RV vaccines are available but they are not very effective in low income countries where the vaccines are needed the most. Next generation parenteral vaccines are proposed to improve the RV vaccine efficacy. Our first study showed that a nanoparticle-based intramuscular (IM) RV vaccine effectively reduced the duration and severity of human RV infection and diarrhea in Gn pigs. Secondly, we examined in detail the infectivity of HuNoV and identified accurately using different mathematical models on how much virus would be required to infect and cause diarrhea in naïve Gn pigs. This knowledge would greatly help in the accurate assessment of the efficacy of NoV vaccines. Third, we evaluated the immunogenicity and protective efficacy of a tetravalent IM NoV vaccine in Gn pigs. Although the vaccine was highly immunogenic, it did not confer any protection against infection and diarrhea upon challenge with the NoV at different doses. NoVs are so diverse that one year we might be infected with one strain and a few years later, we might be infected again with another strain, even though they belong to the same genotype, and experience the same symptoms. This is because, changes brought about due to mutation in the virus capsid protein allow the viruses to hide from neutralizing antibodies induced by previous infection or vaccination as we have revealed in this study. NoV diversity and lack of cross protection need to be taken into consideration during vaccine development. This thesis shows how Gn pigs can be used to study these components in order to further maximize our ability to understand and combat enteric viral diseases.
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Pathogenesis, immunity, and prevention of human norovirus infection in gnotobiotic pigsLei, Shaohua 23 April 2018 (has links)
Human noroviruses (HuNoVs) are the leading cause of viral epidemic acute gastroenteritis and responsible for the deaths of over 200,000 children each year worldwide. HuNoV research has been hampered by the long absence of a readily reproducible cell culture system and a suitable small animal model, while gnotobiotic (Gn) pigs have been a unique animal model for understanding HuNoV pathogenesis and immunity, as well as evaluating vaccine and therapeutics. Recent reports of HuNoVs infection and replication in B cells supplemented with commensal bacteria Enterobacter cloacae and in Blab/c mice deficient in RAG/IL2RG have gained extensive attention, and my studies utilized the well-established Gn pig model to investigate the effects of these two interventions on HuNoV infection. Surprisingly, the colonization of E. cloacae inhibited HuNoV infectivity in Gn pigs, evidenced by the significantly reduced HuNoV shedding in feces and HuNoV titers in intestinal tissues and blood compared to control pigs. Moreover, HuNoV infection of enterocytes but not B cells was observed with or without E. cloacae colonization, indicating B cells were not a target cell type for HuNoV in Gn pigs. On the other hand, using RAG2/IL2RG deficient pigs generated by CRISPR/Cas9 system, with confirmed severe combined immunodeficiency, I evaluated the effects of host immune responses on HuNoV infection. Compared to wild-type Gn pigs, longer HuNoV shedding was observed in RAG2/IL2RG deficient pigs (16 versus 27 days), and higher HuNoV titers were detected in intestinal tissues and contents and in blood, indicating increased and prolonged HuNoV infection in RAG2/IL2RG deficient pigs. In addition, I evaluated dietary interventions including probiotics and rice bran using Gn pig model of HuNoV infection and diarrhea. While the colonization of probiotic bacteria Lactobacillus rhamnosus GG (LGG) and Escherichia coli Nissle 1917 (EcN) in Gn pigs completely inhibited HuNoV fecal shedding, the two cocktail regimens, in which rice bran feeding started either 7 days prior to or 1 day after viral inoculation in the LGG+EcN colonized Gn pigs, exhibited dramatic anti-HuNoV effects, including reduced incidence and shorter duration of diarrhea, as well as shorter duration of virus fecal shedding. The anti-HuNoV effects of the cocktail regimens were associated with the enhanced IFN-𝛾⁺ T cell responses, increased production of intestinal IgA and IgG, and longer villus length. Taken together, my dissertation work improves our understanding of HuNoV infection and immunity, and further supports for Gn pigs as a valuable model for future studies of human enteric virus infection, host immunity, and interventions. / Ph. D. / Human noroviruses (HuNoVs) are the leading cause of viral epidemic acute gastroenteritis. Using the gnotobiotic pig model of HuNoV infection and diarrhea, we found that (1) the colonization of a commensal bacterium E. cloacae inhibited HuNoV infectivity, and B cells were not a target cell type for HuNoV in gnotobiotic pigs. (2) Increased and prolonged HuNoV infection in RAG2/IL2RG deficient pigs, which had severe combined immunodeficiency. (3) The dietary supplementation of rice bran and colonization of two probiotic bacteria significantly reduced HuNoV infectivity and diarrhea, and the beneficial effects were associated with enhanced intestinal immunity and health. Taken together, the dissertation work improves our understanding of HuNoV infection and immunity, and further supports for gnotobiotic pigs as a valuable model for future studies of human enteric virus infection, host immunity, and interventions.
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Studies of pathogenesis, innate immunity and therapeutics of human enteric viruses in gnotobiotic pigsCastellucci, Tam Bui 26 May 2017 (has links)
Norovirus and rotavirus are the most common viral causes of acute gastroenteritis among all age groups and in children under 5 years of age, respectively. Understanding the pathogenesis of the virus and correlates of protective immunity is fundamental to developing effective prevention and treatment strategies. Gnotobiotic (Gn) pigs are an attractive animal model for studying enteric viruses due to their similarities to humans, particularly in regards to the immune system and gastrointestinal anatomy and physiology. Here, to establish a reliable Gn pig model of human norovirus (HuNoV) infection and disease, we determined the median infectious dose (ID50) of a GII.4 2006b variant in pigs. We also evaluated the effects of age and administration of the cholesterol-lowering drug simvastatin on susceptibility to NoV infection. In neonatal pigs (4-5 days of age, the ID50 was determined to be 2.74 x 103 viral RNA copies. The ID50 was increased in 33-34 day old pigs (6.43 x 104), but decreased to <2.74 x 103 following simvastatin treatment in the same age group. Overall, the development of diarrhea, fecal virus shedding and small intestinal cytopathological changes confirmed the usefulness of the Gn pig as an appropriate animal model for studying HuNoVs. We also utilized the well-established Gn pig model of human rotavirus (HRV) infection and disease to evaluate adjunctive treatment options for HRV-induced diarrhea. We demonstrated that the anti-secretory drug racecadotril was capable of diminishing clinical signs of HRV infection and shortening duration of illness. Reduced dehydration in the racecadotril-treated pigs was evident by the significant gain in body weight compared to controls during the course of the study. We also determined that a high dose of the probiotic Lactobacillus acidophilus NCFM (LA) was able to reduce RV diarrhea severity and duration compared to a low dose. The difference in therapeutic potential was attributed to divergent effects in innate immunity pre- and post-challenge. High dose of LA (HiLA) induced an anti-inflammatory dendritic cell (DC) profile, characterized primarily by upregulation of TLR2 expression and production of cytokine IL-10. Conversely, low dose of LA (LoLA) upregulated TLR3 and TLR9 and increased secretion of cytokine IL-6. Additionally, HiLA induced both IFN-alpha and TNF-alpha responses in DCs, but LoLA was only able to increase the frequency of TNF-alpha-producing DCs. These results provide further support of Gn pigs as a highly applicable animal model for studying pathogenesis, innate immunity and therapeutics of human enteric viruses. / Ph. D. / Norovirus and rotavirus are the most common viral causes of acute gastroenteritis among all age groups and in children under 5 years of age, respectively. Understanding the pathogenesis of the virus and correlates of protective immunity is fundamental to developing effective prevention and treatment strategies. Gnotobiotic (Gn) pigs are an attractive animal model for studying enteric viruses due to their similarities to humans, particularly in regards to the immune system and gastrointestinal anatomy and physiology. Here, we established a reliable Gn pig model of human norovirus (HuNoV) infection and disease. Overall, the development of diarrhea, fecal virus shedding and small intestinal cytopathological changes confirmed the usefulness of the Gn pig as an appropriate animal model for studying HuNoVs. We also utilized the well-established Gn pig model of human rotavirus (HRV) infection and disease to evaluate adjunctive treatment options for HRV-induced diarrhea. We demonstrated that the anti-secretory drug racecadotril was capable of diminishing clinical signs of HRV infection and shortening duration of illness. We also determined that a high dose of the probiotic <i>Lactobacillus acidophilus</i> NCFM (LA) was able to reduce RV diarrhea severity and duration compared to a low dose. These results provide further support of Gn pigs as a highly applicable animal model for studying pathogenesis, innate immunity and therapeutics of human enteric viruses.
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Investigation of Novel Prophylactics Against Human Rotavirus Using Gnotobiotic Pig ModelsHensley, Casey 22 June 2023 (has links)
Human rotavirus (HRV) is a major causative agent of acute gastroenteritis (AGE), which causes severe dehydrating diarrhea in children under the age of five and results in up to 215,000 deaths worldwide each year. There are two live oral attenuated vaccines licensed for use in the United States that are highly effective in high-income countries but much less so in low-and middle-income countries (LMICs). Several factors contributing to decreased efficacy in these areas include chronic malnutrition, gut dysbiosis, and concurrent viral infection. Along with this, currently used vaccines require constant cold-chain storage to maintain vaccine stability, and those resources can be scarce in LMICs. These areas continue to maintain a high burden of HRV morbidity and mortality, and more efficacious vaccines are needed. The gnotobiotic (Gn) pig model of HRV infection and diarrhea has long been used in the evaluation of novel HRV vaccines due to Gn pigs' susceptibility to HRV infection, development of clinical signs, histopathological changes in the intestine, and the infection kinetics that mimic those seen in human infants. The first project in this dissertation used the Gn pig model to evaluate a thermostable live oral attenuated vaccine administered as a dissolvable film. Two doses of the tetravalent dissolvable film vaccine conferred significant protection from virus shedding by delaying its onset and reducing peak titers in feces. It also significantly delayed the onset of diarrhea and reduced the duration and area under the curve (AUC) of diarrhea. The dissolvable film was highly immunogenic, inducing high titers of serum virus neutralizing (VN) antibodies specific to each of the four G-types included in the vaccine formulation, HRV-specific serum IgA and IgG, and intestinal IgA. These data confirm the thermostable platform as a useful alternative to liquid vaccines that require cold-chain. The second project evaluated three mRNA-based nonreplicating vaccine candidates in the Gn pig model. All three mRNA candidates encoded a universal CD4+ T cell epitope, P2, derived from tetanus toxoid, fused with the encoded VP8* from P[4], P[6], and P[8] HRVs. Two candidates also encoded for a lumazine synthase (LS) domain fused with the P2-VP8*. A dose response study of the LS-P2-VP8* candidates was conducted simultaneously. Significant protection against virus shedding was induced by all three candidates, with LS-P2-VP8* candidates inducing significantly higher VP8*-specific serum IgG. All three candidates induced significantly higher numbers of P[8]-VP8*-specific IgG antibody-secreting cells (ASCs) and IFN-γ-producing T cells in the ileum, spleen and blood. These data provide guidance for further development of the relatively new mRNA-based technology for use in HRV vaccine development. In the final study of this dissertation, we used the Gn pig model of both P[8] and P[6] HRV infection to evaluate a cocktail nanoparticle-based HRV vaccine. This vaccine was made up of an S60 nanoparticle, self-assembled from the S domain of the human norovirus capsid protein. The exposed C-termini on the S60 nanoparticle were utilized as an antigen display platform, where VP8* from P[4], P[6] and P[8] HRVs was fused. This vaccine was tested as both a two-dose intramuscular (IM) regimen, or as an IM booster preceded by an oral priming immunization with commercial monovalent Rotarix®. Pigs were challenged with either P[6] or P[8] HRV to evaluate cross-protection of the nanoparticle vaccine. Both regimens were highly immunogenic, inducing high titers of serum VN, IgG and IgA antibodies. Furthermore, the prime-boost regimen conferred significant protection against virus shedding in P[8] HRV-challenged pigs as evidenced by the shortened duration of fecal virus shedding. There was also significant protection in P[6] HRV-challenged pigs vaccinated with the prime-boost regimen, as evidenced by the shortened duration, reduced mean peak titer and AUC of virus shedding. Prime-boost-vaccinated pigs challenged with P[8] HRV had significantly higher P[8]-specific IgG ASCs in the spleen post-challenge. Prime-boost-vaccinated pigs challenged with P[6] HRV had significantly higher numbers of P[6] and P[8]-specific IgG ASCs in the ileum, as well as significantly higher numbers of P[8]-specific IgA ASCs in the spleen post-challenge. Oral priming followed by parenteral boosting appears to be a promising vaccination strategy for HRV and these data warrant further investigation into this regimen. Through these studies, we improved our understanding of the effect of different vaccination routes and formulations in the effectiveness of conferring protection against an enteric virus. The knowledge will facilitate the development of more effective vaccination strategies against HRV, the leading cause of infantile diarrhea in LMICs, as well as other enteric viruses. / Doctor of Philosophy / Human rotavirus (HRV) is a major causative agent of acute gastroenteritis (AGE) in children under the age of five. Acute gastroenteritis is characterized by nausea, vomiting, and potentially deadly dehydrating diarrhea. There are two highly effective vaccines licensed for use in the United States; however, these vaccines are much less effective in low- and middle-income countries (LMICs), where HRV disease burden is the highest. There are several reasons thought to be responsible for the decrease in effectiveness seen in these areas, including chronic malnutrition and gut dysbiosis. Non-biological reasons for decreased efficacy may include the breakdown of cold-chain storage for these vaccines, which require constant low temperature storage that is often unavailable in LMICs. Thermostable vaccines are necessary for increasing vaccine distribution and efficacy in these areas. Because many of the biologic factors thought to interfere with the effectiveness of these vaccines appear to be confined to the gastrointestinal tract, development of next generation HRV vaccines has focused on the parenteral route of administration. The gnotobiotic (Gn) pig model is a highly relevant animal model that has been used for decades to evaluate novel HRV vaccine efficacy. Our first study evaluated a thermostable, dissolvable live oral vaccine administered as a dissolvable film in our Gn pig model. Two doses of this vaccine significantly reduced the severity of diarrhea and virus shedding in the stool. Our second study evaluated three mRNA-based intramuscular (IM) vaccines in the Gn pig model. Three doses of all mRNA candidates provided significant protection from virus shedding in the stool, as well as inducing the production of strong HRV-specific antibodies in the serum and high numbers of virus-specific T cells in the tissues. In our final study, we evaluated a nanoparticle-based vaccine as a two-dose IM regimen or as an IM booster preceded by an oral immunization using the commercially available Rotarix® vaccine. The prime-boost regimen significantly shortened the duration and severity of virus shedding in the stool. We also detected more cross-strain HRV-specific antibody-secreting cells in the tissues. All three vaccines evaluated in this dissertation offer differing novelty in the field of HRV vaccine development, and the Gn pig model has been instrumental in the evaluation of these vaccines.
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