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Complete Genome Sequence and Pathogenicity of Two Swine Parainfluenzaviruses Isolated from Pigs in the United StatesQiao, Dan 14 July 2009 (has links)
Members of the family Paramyxoviridae are non-segmented, negative-strand RNA viruses. A large and diverse host species are infected by paramyxoviruses, including avian, porcine, canine, bovine, equine, ovine, reptiles, aquatic species and humans. In the last few decades, many novel paramyxoviruses have emerged causing catastrophic illnesses in different aquatic and terrestrial species of animals and some of them also made the species jump to humans. Two novel paramyxoviruses 81-19252 (Texas81) and 92-7783 (ISU92) were isolated in the 1980s and 1990s from the brain of pigs that experienced respiratory and central nervous system disease from South and North Central United States. To understand their importance as swine pathogens, molecular characterization and pathogenicity studies were undertaken. The complete genome of Texas81 virus was 15456 nucleotides (nt) and ISU92 was 15480 nt in length consisting of six non-overlapping genes coding for the nucloeo- (N), phospho- (P), matrix (M, fusion (F), hemagglutinin-neuraminidase (HN) and large polymerase (L) proteins in the order 3'-N-P/C/V-M-F-HN-L-5'. The features related to virus replication and found to be conserved in most members of Paramyxoviridae were also found in swine viruses. These include: conserved and complementary 3â leader and 5â trailer regions, trinucleotide intergenic sequences, highly conserved gene start and gene stop signal sequences. The length of each gene of these two viruses was similar except for the F gene, in which ISU92 had an additional 24 nt "U" rich 3â untranslated region (UTR). The P gene of these viruses were predicted to express the P protein from the primary transcript and edit a portion of its mRNA to encode V and D proteins and the C protein was expected to be expressed from alternate translation initiation from the P gene as in Respiroviruses. Sequence specific features related to virus replication and host specific amino acid signatures in P, F, HN and L proteins indicated that these viruses probably originated from bovine parainfluenzavirus 3. Pairwise comparisons of deduced amino acid sequences of swine viral proteins with members of Paramyxoviridae and phylogenetic analysis based on individual genes as well as predicted amino acid sequences suggested that these viruses were novel members of the genus Respirovirus of the Paramyxovirinae subfamily and genotype A of bovine parainfluenzavirus type 3. The mild clinical signs and undetectable gross and microscopic lesions observed in swine parainfluenzavirus (sPIV3)-infected pigs indicate the inapparent nature of these viruses in pigs. Limited seroprevalence studies in serum samples collected from pig farms in Minnesota and Iowa in 2007-2008 by indirect ELISA revealed that sPIV3 are not circulating in these farms. The mild pathogenicity of sPIV3 can facilitate its development as a vaccine vector. The screening ELISA developed by us could be used to detect seroprevalence of sPIV3 in animal and human populations. / Master of Science
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Characterization of Cross-Species Transmission Potential for Porcine Deltacoronaviruses Expressing Sparrow Coronavirus Spike Protein in Commercial PoultryAbdulhameed, Moyasar January 2021 (has links)
No description available.
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Cross-Species Infection and Characterization of Avian Hepatitis E VirusSun, Zhifeng 28 January 2005 (has links)
As novel or variant strains of HEV continue to evolve rapidly both in humans and other animals, it is important to develop a rapid pre-sequencing screening method to select field isolates for further molecular characterization. Two heteroduplex mobility assays (HMA) were developed to genetically differentiate field strains of swine HEV and avian HEV from known reference strains. It was shown that the HMA profiles generally correlate well with nucleotide sequence identities and with phylogenetic clustering between field strains and the reference swine HEV or avian HEV strains. Therefore, by using different HEV isolates as references, the HMA developed in this study can be used as a pre-sequencing screening tool to identify variant HEV isolates for further molecular epidemiological studies.
Our previous study showed that avian HEV antibody is prevalent in apparently healthy chickens. A prospective study was conducted on a known seropositive but healthy chicken farm. Avian HEV was identified from the healthy chicken flock. Avian HEV isolates recovered from the healthy chicken share 70-97% nucleotide sequence identities with those isolates which cause hepatitis-splenomegaly (HS) syndrome based on partial helicase and capsid gene regions. Recovery of identical viruses from the experimentally inoculated chickens in the subsequent transmission study further confirmed our field results. The capsid gene of avian HEV isolates from chickens with HS syndrome were also characterized and found to be heterogeneic, with 76-100% nucleotide sequence identities to each other. The study indicates that avian HEV is enzootic in chicken flocks and spread subclinically among chicken populations, and that the virus is heterogeneic.
As HEV can not be propagated <i>in vitro</i>, in order to further characterize avian HEV, an infectious viral stock with a known infectious titer must be generated. Bile and feces collected from specific-pathogen-free (SPF) chickens experimentally infected with avian HEV were used to prepare an avian HEV infectious stock. The infectivity titer of this infectious stock was determined, by intravenously inoculating one-week old SPF chickens, to be 5 x 10<sup>4.5</sup> 50% chicken infectious doses (CID₅₀) per ml. Seroconversion, viremia as well as fecal virus shedding were observed in the inoculated chickens. Contact control chickens also became infected via direct contact with inoculated ones. Avian HEV infection in chickens was found to be dose-dependent. To determine if avian HEV can infect across species, one-week old SPF turkeys were intravenously inoculated each with 10<sup>4.5</sup>(CID₅₀) of avian HEV. The inoculated turkeys seroconverted to avian HEV antibodies at 4-8 weeks postinoculation (WPI). Viremia was detected at 2-6 WPI, and fecal virus shedding at 4-7 WPI in inoculated turkeys. This is the first demonstration of cross-species infection by avian HEV.
Little is known regarding the characteristics of the small ORF3 protein largely due to the lack of a cell culture system for HEV. To characterize the small protein, the ORF3 proteins of avian HEV and swine HEV were expressed in <i>Escherchia coli</i>, and purified by BugBuster His-Bind Purification System. Western blot analysis showed that avian HEV ORF3 protein is unique and does not share common antigenic epitopes with those of swine HEV and human HEV. However, swine HEV (genotype 3) and human HEV (genotype 1) ORF3 proteins cross-react with each other antigenically. To determine if the ORF3 protein is a virion protein, infectious stocks of avian HEV and swine HEV were first generated in SPF chickens and pigs, respectively. Virions were subsequently purified by sucrose density gradient centrifugation and virion proteins were characterized by SDS-PAGE and Western blot analysis. Two major forms of ORF2 proteins of avian HEV were identified: a 56 kDa and an 80 kDa proteins. Multiple immunoreactive forms of ORF2 proteins of swine HEV were also observed: 40 kDa, 53 kDa, 56 kDa and 72 kDa. However, the ORF3 protein was not detected from the native virions of avian HEV or swine HEV. These findings provide direct evidence that ORF2 indeed encodes a structural protein of HEV, whereas ORF3 does not.
To search for other potential animal reservoirs for HEV, the prevalence of IgG anti-HEV antibody was determined in field mice caught in chicken farms to assess the possibility of mice as a potential reservoir for HEV infection in chickens. Three different recombinant HEV antigens derived from avian HEV, swine HEV, and human HEV were used in the ELISA assays. The anti-HEV seropositive rates in wild field mice (<i>Mus musculus</i>), depending upon the antigen used, are 15/76 (20%), 39/74 (53%), and 43/74 (58%), respectively. HEV RNA was also detected from 29 fecal and/or serum samples of mice. The HEV sequences recovered from field mice shared 72-100% nucleotide sequence identities with each other, 73-99% sequence identities with avian HEV isolates, and 51-60% sequence identities with representative strains of swine and human HEVs. However, attempts to experimentally infect laboratory mice (Mus musculus) with the PCR-positive fecal materials recovered from the wild field mice were unsuccessful. We also attempted to experimentally infect 10 Wistar rats each with avian HEV, swine HEV, and an US-2 strain of human HEV, respectively. However, the inoculated rats did not become infected as evidenced by the lack of viremia, virus shedding in feces or seroconversion. These data suggest that mice caught in chicken farms are infected by a HEV-like virus, but additional work is needed to determine the origin of the mouse virus as well as the potential role of rodents in HEV transmission.
In summary, we developed two HMAs which are useful for differentiation and identification of variant strains of swine and avian HEVs. We genetically identified and characterized an avian HEV strain from apparently healthy chickens in seropositive flocks. We showed that avian HEV can cross species barriers and infect turkeys. Our data indicated that avian and swine HEV ORF2 genes encode structural proteins, whereas ORF3 genes do not. Evidence in this study also showed that HEV or HEV-like agent exists in field mice on a chicken farm. / Ph. D.
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Pathogenesis and Cross-species Infection of Hepatitis E VirusYugo, Danielle Marie 18 January 2019 (has links)
Hepatitis E Virus (HEV), the causative agent of hepatitis E, is a zoonotic pathogen of worldwide significance. The genus Orthohepevirus A of the family Hepeviridae includes all mammalian strains of HEV and consists of 8 recognized genotypes. Genotypes 1 and 2 HEVs only infect humans and genotypes 3 and 4 infect humans and several other animal species including pigs and rabbits. An ever-expanding host range of genetically-diversified strains of HEV now include bat, fish, rat, ferret, moose, wild boar, mongoose, deer, and camel. Additionally, the ruminant species goats, sheep, and cattle have been implicated as potential reservoirs as well.
My dissertation research investigates a novel animal model for HEV, examines the immune dynamics during acute infection, and evaluates the possibility of additional animal reservoirs of HEV. The first project established an immunoglobulin (Ig) heavy chain knock-out JH (-/-) gnotobiotic piglet model that mimics the course of acute HEV infection observed in humans and evaluated the pathogenesis of HEV infection in this novel animal model. The dynamics of acute HEV infection in gnotobiotic pigs were systematically determined with a genotype 3 human strain of HEV. We also investigated the potential role of immunoglobulin heavy-chain JH in HEV pathogenesis and immune dynamics during the acute stage of virus infection. This novel gnotobiotic pig model will aid in future studies into HEV pathogenicity, an aspect which has thus far been difficult to reproduce in the available animal model systems.
The objective of the second project for my PhD dissertation was to determine if cattle in the United States are infected with a bovine strain of HEV. We demonstrated serological evidence of an HEV-related agent in cattle populations with a high level of IgG anti-HEV prevalence. We demonstrated that calves from a seropositive cattle herd seroconverted to IgG binding HEV during a prospective study. We also showed that the IgG anti-HEV present in cattle has an ability to neutralize genotype 3 human HEV in vitro. However, our exhaustive attempts to detect HEVrelated sequence from cattle in the United States failed, suggesting that one should be cautious in interpreting the IgG anti-HEV serological results in bovine and other species. Collectively, the work from my PhD dissertation delineated important mechanisms in HEV pathogenesis and established a novel animal model for future HEV research. / Ph. D. / Hepatitis E Virus (HEV), the causative agent of hepatitis E, is a zoonotic pathogen of worldwide significance. According to the World Health Organization, there are approximately 20 million HEV infections annually, which result in 3.3 million cases of acute hepatitis E and >44,000 HEV-related deaths. Hepatitis E is a self-limiting acute disease in general, but carries the ability to cause high mortality in pregnant women and chronic hepatitis in immunocompromised individuals. The underlying mechanisms of HEV host tropism and progression of disease to chronicity are unknown.
My dissertation work investigates a novel animal model for HEV, evaluates the possibility of additional animal reservoirs of HEV, and examines the immune dynamics during acute infection. The first project established an immunoglobulin (Ig) heavy chain knock-out JH (-/-) gnotobiotic piglet model that mimics the course of acute HEV infection observed in humans. The dynamics of acute HEV infection were determined in both the knock-out and wild-type piglets with a genotype 3 strain of human HEV. We also investigated the potential role of immunoglobulin heavy-chain JH in HEV pathogenesis and virus infection. In the second project, we determined if cattle in the United States are infected with a bovine strain of HEV. We showed serological evidence of an HEV-related agent in cattle as well as calves born in a seropositive herd. Despite the detection of specific antibodies recognizing HEV in cattle, definitive evidence of virus infection could not be demonstrated. Our exhaustive attempts to detect HEV-related sequence from cattle in the United States failed, suggesting that one should be cautious in interpreting the IgG anti-HEV serological results in bovine and other species. Collectively, the work from my PhD dissertation research delineated important mechanisms in HEV pathogenesis and established a novel animal model for future HEV research.
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