Two currently licensed live oral rotavirus vaccines (Rotarix® and RotaTeq®) are highly efficacious against severe rotavirus diarrhea. However, the efficacy of such vaccines in selected low-income African and Asian countries is much lower than that in middle or high-income countries. Additionally, these two vaccines have recently been associated with rare case of intussusception in vaccinated infants. We developed a novel recombinant subunit parenteral rotavirus vaccine which may be more effective in low-income countries and also avert the potential problem of intussusception. Truncated recombinant VP8* (ΔVP8*) protein of human rotavirus strain Wa P[8], DS-1 P[4] or 1076 P[6] expressed in E. coli was highly soluble and was generated in high yield. Guinea pigs hyperimmunized intramuscularly with each of the ΔVP8* proteins (i.e., (P[8], P[4] or P[6]) developed high levels of homotypic as well as variable levels of heterotypic neutralizing antibodies. Moreover, the selected ΔVP8* proteins when administered to mice at a clinically relevant dosage, route and schedule, elicited high levels of serum anti-VP8* IgG and/or neutralizing antibodies. Our data indicated that the ΔVP8* proteins may be a plausible additional candidate as new parenteral rotavirus vaccines.
Previous studies of epithelial immune responses to rotavirus infection have been conducted in transformed cell lines. In this study, we evaluated a non-transformed porcine jejunum epithelial cell line (IPEC-J2) as an in-vitro model of rotavirus infection and probiotic treatment. Cell-culture-adapted porcine rotavirus (PRV) OSU strain, or human rotavirus (HRV) Wa strain, along with Lactobacillus acidophilus (LA) or Lactobacillus rhamnosus GG (LGG) were used to inoculate IPEC-J2 cells. LA or LGG treatment was applied pre- or post-rotavirus infection. We demonstrated that IPEC-J2 cells were productively infected by PRV. LA or LGG treatment of the cells did not reduce virus replication. PRV infection increased MUC3 mucin secretion. LGG treatment post-rotavirus infection reduced the mucin secretion response induced by PRV; LGG alone increased the production of membrane-associated MUC3 mucin. LA treatment prior to rotavirus infection significantly increased PRV replication and the IL-6 response to PRV infection, which is consistent with the adjuvant effect of LA. LGG treatment post-rotavirus infection downregulated the IL-6 response, confirming the anti-inflammatory effect of LGG. IPEC-J2 cells expressed toll-like receptor (TLR) 2, TLR3, and TLR9 constitutively. TLR2 expression was upregulated by LGG and peptidoglycan, corresponding to the decreased IL-6 response, indicating that the protective effect of LGG is associated with upregulation of TLR2 expression on intestinal epithelial cells. The IPEC-J2 cell model of PRV infection is a completely homologous system. It is a valuable model for studying the interactions among rotavirus-host-probiotics, and the mechanisms behind the immunomodulating effect of probiotic bacteria on innate immune responses.
Hepatitis E virus (HEV), a single-stranded, positive-sense RNA virus, is responsible for acute hepatitis E epidemics in many developing countries, and the virus is also endemic in some industrialized countries. Hepatitis E is a recognized zoonotic disease, and several animal species, including pigs, are potential reservoirs for HEV. The genome of HEV contains three open reading frames (ORFs). ORF1 encodes the nonstructural proteins, ORF2 encodes the capsid protein, and ORF3 encodes a small multifunctional protein. The ORF2 and ORF3 proteins are translated from a single, bicistronic mRNA. The coding sequences for these two ORFs overlap each other, but neither overlaps with ORF1. Whereas the mechanisms underlying HEV replication are poorly understood, the construction of infectious viral clones, the identification of cell lines that support HEV replication, and the development of small animal models have allowed for more detailed study of the virus. As result of these advances, recently, our understanding of viral entry, genomic replication and viral egress has improved. Furthermore, the determination of the T=1 and T=3 structure of HEV virus-like particles has furthered our understanding of the replication of HEV. This article reviews the latest developments in the molecular biology of HEV with an emphasis on the genomic organization, the expression and function of genes, and the structure and replication of HEV.
The roles of conserved nucleotides on the stem-loop (SL) structure in the intergenic region of the hepatitis E virus (HEV) genome in virus replication were determined by using Huh7 cells transfected with HEV SL mutant replicons containing reporter genes. One or two nucleotide mutations of the AGA motif on the loop significantly reduced HEV replication, and three or more nucleotide mutations on the loop abolished HEV replication. Mutations on the stem and of the subgenome start sequence also significantly inhibited HEV replication. The results indicated that both the sequence and the SL structure in the junction region play important roles in HEV replication.Hepatitis E virus (HEV) is the causative agent of hepatitis E, and at least four major genotypes have been recognized in mammalian species: genotypes 1 and 2 are restricted to humans, whereas genotypes 3 and 4 are zoonotic (1-3, 9, 21, 26-29). The genome is a single-strand, positive-sense RNA molecule (12) consisting of a 5Ј noncoding region (NCR), open reading frame 1 (ORF1) encoding the nonstructural proteins, ORF2 encoding the capsid protein, ORF3 encoding a small multifunctional protein (6,22,23,31,32,(38)(39)(40)42), and a 3Ј NCR. ORF2 and ORF3 are translated from a single bicistronic mRNA and overlap each other, but neither overlaps ORF1 (15,19). The HEV genome contains two cis-reactive elements (CRE): the first CRE overlaps the 3Ј end of ORF2 and the 3Ј NCR and is essential for virus replication (13), and the second CRE may be the promoter for synthesis of the 2.0-kb subgenomic (SG) mRNA (14, 15). Graff et al. showed that neither ORF2 expression nor ORF3 expression was detectable when 6-nucleotide (nt) or 4-nt mutations were introduced into the junction region of the HEV genome; however, the roles of individual nucleotides in the junction region and its surrounding sequences in virus replication remain unknown (14).We identified a region within the junction region (Fig. 1) of the HEV genome that shares nucleotide sequence identity with rubella virus and with the conserved alphavirus subgenomic promoter sequence. A highly conserved stem-loop (SL) structure was predicted to occur in the alphavirus junction region with sequences homologous to those of the HEV antigenome RNA in the junction region of the HEV genome (7,19). The objective of this study was to determine the effect of mutations of the conserved nucleotides in the SL and its RNA structure on HEV replication.Analyses of the RNA SL structure and its surrounding sequences in the junction region of the HEV genome. RNA secondary structures often play important roles in viral replication, SG RNA synthesis, and translation efficiency (24,36). It is believed that the complementary negative strand of the HEV SG promoter is recognized by RdRp or another viral component or host factor that interacts with RdRp, which then initiates the SG RNA synthesis in a primer-independent fashion at the SG start site (30). Using the mfold program (43), we identified two highly conserved SL structures in the intergenic...
Syndecans have three highly conserved sites available for heparan sulfate attachment. To determine if all three sites are required for normal function, a series of mutated syndecans having two, one, or no heparan sulfate chains were expressed in ARH-77 cells. Previously, we demonstrated that expression of wild-type syndecan-1 on these myeloma cells mediates cell-matrix and cell-cell adhesion and inhibits cell invasion into collagen gels. Here we show that to optimally mediate each of these activities, all three sites of heparan sulfate attachment are required. Generally, an increasing loss of syndecan-1 function occurs as the number of heparan sulfate attachment sites decreases. This loss of function is not the result of a decrease in either the total amount of cell surface heparan sulfate or syndecan-1 core protein. In regard to cell invasion, cells expressing syndecan-1 bearing a single heparan sulfate attachment site exhibit a hierarchy of function based upon the position of the site within the core protein; the presence of an available attachment site at serine 47 confers the greatest level of activity, while serine 37 contributes little to syndecan-1 function. However, when all three heparan sulfate chains are present, significantly greater biological activity is observed than is predicted by the sum of the activities occurring when the chains act individually. This synergy provides a functional basis for the evolutionary conservation of the three heparan sulfate attachment sites on syndecans and supports the idea that molecular heterogeneity, which is characteristic of proteoglycans, contributes to their functional diversity.Heparan sulfate is the most ubiquitous glycosaminoglycan (GAG) 1 on cell surfaces. These long, highly diverse carbohydrate polymers are negatively charged and are most often found covalently linked to protein in the form of proteoglycans. Heparan sulfate binds to many extracellular effector proteins including insoluble extracellular matrix molecules, soluble peptide growth factors, and cell adhesion molecules (1). It is through these interactions that heparan sulfate mediates or assists in diverse biological responses including cell-cell and cell-matrix adhesion, apoptosis, growth factor regulation, proteolysis, and angiogenesis. Thus, heparan sulfate influences cell behaviors that are critical during development, homeostasis, and disease progression.The syndecans, a multigene family of proteoglycans, constitute the predominant source of heparan sulfate at the cell surface. On SDS-polyacrylamide gels, the syndecans run as broad smears indicating extensive molecular heterogeneity (2, 3). Detailed analysis of syndecan-4 expressed in L cells demonstrates that it is present in several isoforms, as pure heparan sulfate proteoglycans, as various mixtures of heparan sulfate/ chondroitin sulfate hybrids, and as pure chondroitin sulfate proteoglycans (4). In addition, a molecular polymorphism has been described between simple and stratified epithelial tissues due to differences in the number an...
Currently available live oral rotavirus vaccines, Rotarix® and RotaTeq®, are highly efficacious in developed countries. However, the immunogenicity and efficacy of such vaccines in some developing countries are low. We reported previously that bacterially-expressed rotavirus ΔVP8* subunit vaccine candidates with P[8], P[4] or P[6] specificity elicited high-titer virus neutralizing antibodies in animals immunized intramuscularly. Of note was the finding that antibodies induced with the P[8]ΔVP8* vaccine neutralized both homotypic P[8] and heterotypic P[4] rotavirus strains to high titer. To further improve its vaccine potential, a tetanus toxoid universal CD4+ T cell epitope P2 was introduced into P[8] or P[6]ΔVP8* construct. The resulting recombinant fusion proteins expressed in Escherichia coli were of high solubility and were produced with high yield. Two doses (10 or 20μg/dose) of the P2-P[8]ΔVP8* vaccine or P2-P[6]ΔVP8* vaccine with aluminum phosphate adjuvant elicited significantly higher geometric mean homologous neutralizing antibody titers than the vaccines without P2 in intramuscularly immunized guinea pigs. Interestingly, high levels of neutralizing antibody responses induced in guinea pigs with 3 doses of the P2-P[8]ΔVP8* vaccine persisted for at least 6 months. Furthermore, in the gnotobiotic piglet challenge study, three intramuscular doses (50μg/dose) of the P2-P[8]ΔVP8* vaccine with aluminum phosphate adjuvant significantly delayed the onset of diarrhea and significantly reduced the duration of diarrhea and the cumulative diarrhea score after oral challenge with virulent human rotavirus Wa (G1P[8]) strain. The P2-P[8]ΔVP8* vaccine induced serum virus neutralizing antibody and VP4-specific IgG antibody production prechallenge, and primed the pigs for higher antibody and intestinal and systemic virus-specific IFN-γ producing CD4+ T cell responses postchallenge. These two subunit vaccines could be used at a minimum singly or preferably in bivalent formulation to provide antigenic coverage of most of the G types of global importance.
Chronic hepatitis E virus (HEV) infection is a significant clinical problem in immunocompromised individuals such as organ transplant recipients, although the mechanism remains unknown because of the lack of an animal model. We successfully developed a pig model of chronic HEV infection and examined immune correlates leading to chronicity. The conditions of immunocompromised patients were mimicked by treating pigs with an immunosuppressive regimen including cyclosporine, azathioprine, and prednisolone. Immunocompromised pigs infected with HEV progressed to chronicity, because 8/10 drug-treated HEV-infected pigs continued fecal virus shedding beyond the acute phase of infection, whereas the majority (7/10) of mock-treated HEV-infected pigs cleared fecal viral shedding at 8 wk postinfection. During chronic infection, serum levels of the liver enzyme γ-glutamyl transferase and fecal virus shedding were significantly higher in immunocompromised HEV-infected pigs. To identify potential immune correlates of chronic infection, we determined serum levels of cytokines and cell-mediated immune responses in pigs. Results showed that HEV infection of immunocompromised pigs reduced the serum levels of Th1 cytokines IL-2 and IL-12, and Th2 cytokines IL-4 and IL-10, particularly during the acute phase of infection. Furthermore IFN-γ-specific CD4 T-cell responses were reduced in immunocompromised pigs during the acute phase of infection, but TNF-α-specific CD8 T-cell responses increased during the chronic phase of infection. Thus, active suppression of cell-mediated immune responses under immunocompromised conditions may facilitate the establishment of chronic HEV infection. This pig model will aid in delineating the mechanisms of chronic HEV infection and in developing effective therapeutics against chronic hepatitis E.
Since May 2013, outbreaks of porcine epidemic diarrhea have devastated the U.S. swine industry, causing immense economic losses. Two different swine enteric coronaviruses (porcine epidemic diarrhea virus and Delta coronavirus) have been isolated from the affected swine population. The disease has been reported from at least 32 states of the United States and other countries, including Mexico, Peru, Dominican Republic, Canada, Columbia, Ecuador, and Ukraine, with repeated outbreaks in previously infected herds. Here we report the isolation and characterization of a novel mammalian orthoreovirus 3 (MRV3) from diarrheic feces of piglets from these outbreaks in three states and ring-dried swine blood meal from multiple sources. MRV3 could not be isolated from healthy or pigs that had recovered from epidemic diarrhea from four states. Several MRV3 isolates were obtained from chloroform-extracted pig feces or blood meal in cell cultures or developing chicken embryos. Biological characterization of two representative isolates revealed trypsin resistance and thermostability at 90°C. NextGen sequencing of ultrapurified viruses indicated a strong homology of the S1 segment to mammalian and bat MRV3. Neonatal piglets experimentally infected with these viruses or a chloroform extract of swine blood meal developed severe diarrhea and acute gastroenteritis with 100% mortality within 3 days postinfection. Therefore, the novel porcine MRV3 may contribute to enteric disease along with other swine enteric viruses. The role of MRV3 in the current outbreaks of porcine epidemic diarrhea in the United States remains to be determined, but the pathogenic nature of the virus warrants further investigations on its epidemiology and prevalence. IMPORTANCE Porcine orthoreoviruses causing diarrhea have been reported in China and Korea but not in the UnitedStates. We have isolated and characterized two pathogenic reassortant MRV3 isolates from swine fecal samples from porcine epidemic diarrhea outbreaks and ring-dried swine blood meal in the United States. These fecal and blood meal isolates or a chloroform extract of blood meal induced severe diarrhea and mortality in experimentally infected neonatal pigs. Genetic and phylogenetic analyses of two MRV3 isolates revealed that they are identical but differed significantly from nonpathogenic mammalian orthoreoviruses circulating in the United States. The present study provides a platform for immediate development of suitable vaccines and diagnostics to prevent and control porcine orthoreovirus diarrhea.
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