Field Distribution of END Phenomenon-Negative Bovine Viral Diarrhea Virus
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Field isolates of BVDV which do not show the exaltation of Newcastle disease virus (END) phenomenon (END–) are rarely reported. In this study, 45 BVDV field isolates from cattle in Hokkaido prefecture in Japan were analyzed by the reverse plaque formation method, the END method and observation of cytopathic effects. END– virus was detected in 34 of 45 isolates (75.6%), although 35 of 45 field isolates contained END phenomenon positive virus as the predominant virus population. We propose that END– viruses are widely distributed in the field and that it is possible that the mixture of biologically distinct BVDV correlates with the appearance of disease in infected animals.Keywords:
Phenomenon
Mice immunized with recombinant vaccinia virus (VACC) expressing Venezuelan equine encephalitis (VEE) virus capsid protein and glycoproteins E1 and E2 or with attenuated VEE TC-83 virus vaccine developed VEE-specific neutralizing antibody and survived intraperitoneal challenge with virulent VEE virus strains including Trinidad donkey (subtype 1AB), P676 (subtype 1C), 3880 (subtype 1D), and Everglades (subtype 2). However, unlike immunization with TC-83 virus, immunization with the recombinant VACC/VEE virus did not protect mice from intranasal challenge with VEE Trinidad donkey virus. These results suggest that recombinant VACC/VEE virus is a vaccine candidate for equines and humans at risk of mosquito-transmitted VEE disease but not for laboratory workers at risk of accidental exposure to aerosol infection with VEE virus.
Poxviridae
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Recombinant virus
Attenuated vaccine
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Poxviridae
Medical microbiology
Veterinary virology
Orthopoxvirus
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The haemagglutinin (HA) of influenza A virus consists of two glycopolypeptides designated HA1 and HA2. Antibodies recognizing HA1 inhibit virus haemagglutination, neutralize virus infectivity and provide good protection against infection, but do not cross-react with the HA of other subtypes. Little is known regarding the biological activities of antibodies against HA2. To study the role of antibodies directed against HA2 during influenza virus infection, two vaccinia virus recombinants (rVVs) were used expressing chimeric molecules of HA, in which HA1 and HA2 were derived from different HA subtypes. The KG-11 recombinant expressed HA1 from A/PR/8/34 (H1N1) virus and HA2 from A/NT/60 (H3N2) virus, whilst KG-12 recombinant expressed HA1 from A/NT/60 virus and HA2 from A/PR/8/34 virus. Immunization of BALB/c mice with rVV expressing HA2 of the HA subtype homologous to the challenge virus [A/PR/8/34 (H1N1) or A/Mississippi/1/85 (H3N2)] did not prevent virus infection, but nevertheless resulted in an increase in mice survival and faster elimination of virus from the lungs. Passive immunization with antibodies purified from mice immunized with rVVs confirmed that antibodies against HA2 were responsible for the described effect on virus infection. Based on the facts that HA2 is a rather conserved part of the HA and that antibodies against HA2, as shown here, may moderate virus infection, future vaccine design should deal with the problem of how to increase the HA2 antibody response.
Infectivity
Recombinant virus
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Pestivirus
Cytopathic effect
Classical swine fever
Newcastle Disease
Viral culture
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SUMMARY The xenotropic (X-tropic) mouse type C virus (MuLV) and its pseudotype of murine sarcoma virus (MSV) were inoculated into several fertilized developing Pekin duck eggs. The development of the duck embryos was substantially reduced in those receiving the X-tropic viruses compared to eggs inoculated only with tissue culture medium. Infectious virus was isolated from some of the adult animals; in others, evidence for integrated virus sequences in the tissues was noted. No specific pathology was found in the ducks that received X-tropic MuLV alone, but one duck developed multiple fibrosarcomas when inoculated at birth with the X-tropic virus pseudotype of MSV. Two ducks receiving X-tropic MuLV had signs of haematopoietic disorders. In addition, more virus-inoculated animals had evidence of hepatitis and encephalitis than control ducks. Antibody production to X-tropic MuLV was present in several ducks inoculated with virus either in embryo or at birth. Absence of antiviral antibodies was noted in those animals whose tissues contained replicating virus. These studies confirm the observations with X-tropic virus in tissue culture. They demonstrate in vivo that avian species are susceptible to infection by the mouse X-tropic virus and that their fibroblasts can be transformed by the X-tropic MuLV pseudotype of MSV.
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Newcastle Disease
Veterinary virology
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The definition and structure of a professional pedagogical phenomenon are defined more precisely in the article. On the basis of different points of view the characteristic features of the phenomenon are viewed upon. The pedagogical phenomenon is correlated with practicability, reality and mode of life. A target interrelation between a teacher and a student, means of education and educational environment are singled out in the structure of a pedagogical phenomenon. It is emphasised that it is impossible to get the authentic results of the research without all the components of the pedagogical phenomenon regularity being taken into account.
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Abstract The hemagglutinin (HA) protein of influenza virus mediates essential viral functions including the binding to host receptor and virus entry. It also has the antigenic sites required for virus neutralization by host antibodies. Here, we characterized an H3N2 triple reassortant (TR) influenza virus (A/turkey/Ohio/313053/04) with a mutation at the receptor binding domain (Asp190Ala) that occurred upon virus transmission from turkeys to pigs in an experimental infection study. The mutant virus replicated less efficiently than the parental virus in human, pig and turkey primary tracheal/bronchial epithelial cells, with more than 3-log 10 difference in virus titer at 72 hours post infection. In addition, the mutant virus demonstrated lower binding efficiency to plasma membrane preparations from all three cell types compared to the parental virus. Antisera raised against the parental virus reacted equally to both homologous and heterlogous viruses, however, antisera raised against the mutant virus showed 4-8 folds lower reactivity to the parental virus.
H5N1 genetic structure
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Veterinary virology
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SummarySpider monkeys and chimpanzees were given a series of three injections consisting of 17D yellow fever virus, followed by living West Nile virus, followed by a third injection which consisted of formalin-inactivated Russian spring-summer virus vaccine. On the basis of neutralizing antibody responses, the limitation of viremia, or both, developing when the animals were challenged with virulent viruses, these primates were judged to be protected to a considerable extent against Japanese B encephalitis, West Nile virus, St. Louis encephalitis, Murray Valley encephalitis virus, dengue types 1, 2, 3, and 4, two antigenic types of the Russian spring-summer virus complex, and Wesselsbron virus.An isolate of West Nile virus was passed a number of times in chick embryo tissue cultures and purified by the plaque technique. The progeny of two virus plaques, in a concentration of 106 mouse intracerebral lethal doses, did not produce encephalitis in intracerebrally inoculated rhesus monkeys. These attenuated viral preparations, on the basis of intracerebral titrations in mice, had at least 1,000 times the virus concentration that was necessary to produce encephalitis with the parent type. One of these attenuated isolates still produced homologous and heterologous neutralizing antibodies comparable to those of the parent strain. The data indicate that this attenuated West Nile virus did not revert to a more virulent form after alternate intracerebral passages in rhesus monkeys and suckling mice.The TP-21 strain of the Russian spring-summer virus complex was passed a number of times in chick embryo tissue cultures and purified by the plaque technique. The progeny from one of the virus plaques, in a concentration of approximately 300,000 mouse i.c. LD50, did not produce encephalitis when inoculated intracerebrally into rhesus monkeys. When this purified virus isolate of TP-21 was substituted for the formalin-inactivated Russian spring-summer vaccine in the triple vaccination procedure, considerable protection was noted in spider monkeys challenged with four members of the Russian spring-summer group of viruses.
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Flavivirus
Attenuated vaccine
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Abstract T’Ho virus is a poorly characterized orthoflavivirus most closely related to Rocio virus and Ilheus virus, two orthoflaviviruses associated with human disease, suggesting that T’Ho virus could also be a human pathogen. The genome of T’Ho virus has been sequenced but an isolate has never been recovered, impeding its phenotypic characterization. In an attempt to generate recombinant T’Ho virus, the entire viral genome was synthesized as three overlapping DNA fragments, joined by Gibson assembly, and transfected into mosquito cells. Several cell culture passages were performed, but virus was not recovered. Subsequent experiments focused on the development of a chimeric orthoflavivirus that contains the premembrane and envelope protein genes of T’Ho virus in the genetic background of Zika virus. The chimeric virus replicated in mosquito (C6/36) and vertebrate (Vero) cells, demonstrating that the major structural glycoproteins of T’Ho virus permit entry into both cell types. The chimeric virus produced plaques in Vero cells that were significantly smaller than those produced by Zika virus. The chimeric virus can potentially be used as a surrogate diagnostic reagent in place of T’Ho virus in plaque reduction neutralization tests, allowing T’Ho virus to be considered in the differential diagnosis.
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Zika Virus
Flavivirus
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