Phylogenetic analysis of spring virema of carp virus reveals distinct subgroups with common origins for recent isolates in North America and the UK.

Genetic relationships between 35 spring viremia of carp virus (SVCV) genogroup Ia isolates were determined based on the nucleotide sequences of the phosphoprotein (P) gene and glycoprotein (G) genes. Phylogenetic analysis based on P gene sequences revealed 2 distinct subgroups within SVCV genogroup Ia, designated SVCV Iai and Iaii, and suggests at least 2 independent introductions of the virus into the USA in 2002. Combined P- and G-sequence data support the emergence of SVCV in Illinois, USA, and in Lake Ontario, Canada, from the initial outbreak in Wisconsin, USA, and demonstrate a close genetic link to viruses isolated during routine import checks on fish brought into the UK from Asia. The data also showed a genetic link between SVCV isolations made in Missouri and Washington, USA, in 2004 and the earlier isolation made in North Carolina, USA, in 2002. However, based on the close relationship to a 2004 UK isolate, the data suggest than the Washington isolate represents a third introduction into the US from a common source, rather than a reemergence from the 2002 isolate. There was strong phylogenetic support for an Asian origin for 9 of 16 UK viruses isolated either from imported fish, or shown to have been in direct contact with fish imported from Asia. In one case, there was 100% nucleotide identity in the G-gene with a virus isolated in China.

Characterization and mutational studies of equine infectious anemia virus dUTPase.

The macrophage tropic lentivirus, equine infectious anemia virus (EIAV), encodes a dUTPase in the pol gene that is required for efficient replication in macrophages. Two naturally occurring variants of the enzyme were expressed as recombinant proteins in Escherichia coli; metal chelate affinity chromatography was used to purify histidine-tagged recombinant enzymes to greater than 80% homogeneity in a single chromatographic step. Biochemical and enzymatic analyses of these preparations suggest that this method yields dUTPase that is suitable for detailed mutational analysis. Specific activities of preparations ranged from 4 x 10(3) to 5 x 10(4) units/mg. Recombinant EIAV dUTPase was highly specific for dUTP with a Km in the range of 3 to 8 microM. The enzyme was sensitive to inhibition by dUDP with little inhibition by other nucleotides or the reaction products, dUMP and PPi. The subunit organization of recombinant EIAV dUTPase was probed by gel filtration, glycerol gradient centrifugation, and chemical cross-linking, and is a trimer. We have begun mutational analyses by targeting a conserved domain present at the carboxyl terminus of all dUTPases that shares high homology to the phosphate binding loops (P-loops) of a number of ATP- and GTP-binding phosphatases. The P-loop-like motif of dUTPases is glycine rich but lacks the invariant lysine found in authentic P-loops. Deletion of this motif leads to loss of dUTPase activity; a series of point mutations that have been shown to inactivate authentic P-loops also abolish EIAV dUTPase activity.

Sequence analysis of the turkey coronavirus nucleocapsid protein gene and 3' untranslated region identifies the virus as a close relative of infectious bronchitis virus.

The 3' end of the turkey coronavirus (TCV) genome (1740 bases) including the nucleocapsid (N) gene and 3' untranslated region (UTR) were sequenced and compared with published sequences of other avian and mammalian coronaviruses. The deduced sequence of the TCV N protein was determined to be 409 amino acids with a molecular mass of approximately 45 kDa. The TCV N protein was identical in size and had greater than 90% amino acid identity with published N protein sequences of infectious bronchitis virus (IBV); less than 21% identity was observed with N proteins of bovine coronavirus and transmissible gastroenteritis virus. The 3' UTR showed some variation among the three TCV strains examined, with two TCV strains, Minnesota and Indiana, containing 153 base segments which are not present in the NC95 strain. Nucleotide sequence identity between the 3' UTRs of TCV and IBV was greater than 78%. Similarities in both size and sequence of TCV and IBV N proteins and 3' UTRs provide additional evidence that these avian coronaviruses are closely related.

Comparison of virologic and serologic responses of lambs and calves infected with bluetongue virus serotype 10.

Four lambs and 3 calves, seronegative to bluetongue virus (BTV), were inoculated intravenously with a highly plaque-purified strain of BTV Serotype 10. A single calf and lamb served as controls and were inoculated with uninfected cell culture lysate. All BTV-inoculated lambs exhibited mild clinical manifestations of bluetongue, whereas infected calves were asymptomatic. Viremia persisted in BTV-infected lambs for 35-42 days, and for 42-56 days in BTV-infected calves. Neutralizing antibodies were first detected in sera collected at Day 14 post-inoculation (PI) from 2 BTV-infected calves and all 4 infected lambs, and at Day 28 PI in the remaining calf. The appearance of neutralizing antibody in serum did not coincide with clearance of virus from blood; BTV and specific neutralizing antibody coexisted in peripheral blood of infected lambs and calves for as long as 28 days. The sequential development, specificity and intensity of virus protein-specific humoral immune responses of lambs and calves were evaluated by immunoprecipitation of [35S]-labelled proteins in BTV-infected cell lysates by sera collected from inoculated animals at bi-weekly intervals PI. Sera from infected lambs and calves reacted most consistently with BTV structural proteins VP2 and VP7, and nonstructural protein NS2, and less consistently with structural protein VP5, and nonstructural protein NS1. Lambs developed humoral immune responses to individual BTV proteins more rapidly than calves, and one calf had especially weak virus protein-specific humoral immune responses; viremia persisted longer in this calf than any other animal in the study. The clearance of virus from the peripheral blood of BTV-infected lambs and calves is not caused simply by the production of virus-specific neutralizing antibody, however the intensity of humoral immune responses to individual BTV proteins might influence the duration of viremia in different animals.

Phorbol ester stimulation of equine macrophage cultures alters expression of equine infectious anemia virus.

Equine infectious anemia virus (EIAV) is a lentivirus that replicates predominantly in mature tissue macrophages. Viral expression is strongly influenced by the state of differentiation of the host cell. While blood monocytes can be infected, viral transcription is limited until the cell differentiates into a mature macrophage. Activation of mature macrophages infected with EIAV might also alter viral expression, presumably through binding of cellular transcription factors to viral nucleic acid sequences within the long terminal repeat (LTR). Using DNA amplification techniques, we compared LTR sequences of U.S. field strains of EIAV to sequences of a laboratory adapted strain of the virus. All field strain sequences were more closely related to Wyoming strain than to the Malmquist laboratory adapted strain or a previously sequenced infectious molecular clone of EIAV. Primary equine monocyte-derived macrophage cultures were infected with virulent and avirulent strains of EIAV and the effects of macrophage stimulation on EIAV expression were determined. Stimulation of macrophages with phorbol ester activated the cells to secrete tumor necrosis factor alpha (TNF alpha). This activation signal also resulted in a significant downregulation of viral expression as determined by supernatant reverse transcriptase activity. This effect occurred independent of the virulence of the virus strain used or the nucleic acid sequence of the viral LTR. This may represent an adaptive response of EIAV to evade the host immune response and establish a persistent infection.

Production and characterization of a monoclonal antibody recognizing a cytoplasmic antigen of equine mononuclear phagocytes.

An IgG1 mouse monoclonal antibody, designated 1.646, is described which recognizes a cytoplasmic antigen of equine mononuclear phagocytes. Indirect fluorescent antibody staining of peripheral blood leukocytes reveals a granular cytoplasmic staining, predominantly in adherent blood mononuclear cells. Indirect fluorescent antibody staining is positive for alveolar and peritoneal macrophages. In some horses, a few neutrophils are also stained. In equine tissue samples stained by immunohistochemistry, the distribution of positive cells is consistent with the distribution of tissue macrophages. The most intense and reliable staining occurs with splenic and lymph node macrophages. Hepatic Kupffer cells also stain with antibody 1.646, although the intensity of that staining is somewhat variable between horses. A granular pattern of staining typical of lipofuscin deposition is also seen in liver sections. There is also pale staining of some biliary and renal tubular epithelium. Equine erythrocytes, platelets and lymphocytes are not recognized by this antibody, and neither are monocyte/macrophages of human, canine or feline origin. Antibody 1.646 recognizes two proteins (150 and 30 kDa) of equine monocyte-derived macrophages when assayed by Western immunoblot. Because of the distribution of staining (tissue mononuclear phagocytes, lipofuscin-containing storage granules, biliary and renal tubular epithelium, and some neutrophils) we hypothesize that antibody 1.646 recognizes a cytoplasmic antigen that is closely associated with lysosomal membranes.

Nucleotide sequence and vaccinia expression of the nucleoprotein of a highly virulent, neurotropic strain of Newcastle disease virus.

The nucleoprotein (NP) of Newcastle disease virus (NDV) was selected to study the relative importance of an internal structural protein in the avian immune response. The NP gene of the virulent, neurotropic NDV Texas GB (TGB) strain was cloned and sequenced. Nucleotide sequence data for the NP gene allowed comparison of the deduced amino acid sequences for the NP genes of NDV-TGB and the avirulent duck isolate NDV-D26. These comparisons demonstrated an 89% nucleotide sequence homology and a 97% homology between the deduced amino acid sequences. The NDV-TGB NP expressed in recombinant vaccinia virus (rVAC) was electrophoretically and immunologically identical to the wild-type NDV-TGB. Although inoculation of chickens with the recombinant vaccinia virus expressing the NDV NP gene elicited anti-NDV antibodies in higher titers than in birds inoculated with live LaSota NDV, this strong anti-NDV response did not protect against lethal challenge with NDV-TGB.

Turkey coryza: lack of correlation between plasmids and pathogenicity of Bordetella avium.

Plasmids were removed from pathogenic Bordetella avium using a variety of treatments. The plasmid-cure rates depended on the treatment and isolate. Pathogenicity of B. avium in turkey poults was not altered by removal of plasmids.

Genetic stability in calves of a single strain of bluetongue virus.

Newborn calves were inoculated IV with highly plaque-purified bluetongue virus (BTV), serotype 10. The electrophoretic migration patterns of RNA segments and proteins of viruses isolated from calves at intervals after inoculation were compared. In addition, sera collected from calves at intervals after inoculation were compared for their abilities to neutralize several virus isolates from the same calf. Viremia persisted in calves for up to 56 days. Differences were not detected in the electrophoretic migration pattern of RNA segments or proteins of any of the BTV isolates. All calves produced high titers of neutralizing antibody to the original BTV inoculum by 28 days after inoculation, and significant (greater than or equal to 4-fold) differences were not detected in the neutralizing titers of sera to viruses collected at intervals after inoculation. The plaque-purified strain of BTV appeared to be stable genetically in infected calves, and failure to demonstrate antigenic variation among isolates indicated that antigenic shift was not the mechanism that allowed viremia to persist in BTV-infected calves.

Detection of pseudorabies viral DNA in tonsillar epithelial cells of latently infected pigs.

The Rice strain of pseudorabies virus (PRV) was intranasally instilled in pigs that were seronegative to PRV. Cells were scraped or brushed from tonsillar surfaces biweekly until pigs were euthanatized at either 10 or 16 weeks after infection. The DNA extracted from tonsillar cells or parenchyma were subjected to polymerase chain reaction analysis, using either a single set of oligonucleotide primers or nested primers from the PRV gII glycoprotein gene. Pigs became seropositive to PRV by 3 weeks after infection. The virus was isolated from the trigeminal ganglia and tonsils of pigs that were euthanatized or died 1 to 2 weeks after infection, but not from pigs that were euthanatized 10 or 16 weeks after infection. The PRV gene products were consistently detected in trigeminal ganglia and tonsils of all pigs at 1, 10, and 16 weeks after infection, and sporadically in the nasal mucosa, lymph nodes, and lungs of pigs that were euthanatized or died during the first 2 weeks after infection. Cells collected biweekly from tonsillar surfaces were mostly nucleated, squamous epithelial cells with fewer lymphocytes and neutrophils. Polymerase chain reaction analysis of DNA extracted from these cells revealed PRV DNA in a large proportion of the samples when sufficient cells were collected to provide 1 microgram of extracted DNA for use in the reaction mixtures. A second group of pigs had PRV strain 4892 intranasally instilled. The virus was isolated from tonsillar swab specimens until 3 weeks after infection. Tonsillar brushing specimens were collected biweekly until 14 weeks after infection.(ABSTRACT TRUNCATED AT 250 WORDS)

Humoral immune response of calves to bluetongue virus infection.

Humoral immune responses of 7 calves to bluetongue virus (BTV) infection were evaluated by plaque-reduction assay and immunoblotting. Most readily interpretable results were obtained with the immunoblot assay when colostrum-deprived calves were used, and sera were reacted with proteins in partially purified extracts of BTV. Viremia persisted in calves for 35 to 56 days, and BTV coexisted in blood for several weeks with virus-specific neutralizing antibody. Calves developed antibody to virus protein 2, the major determinant of virus neutralization, at 14 to 28 days after inoculation; this time interval also coincided with the appearance of neutralizing antibody in serum. Virus clearance in BTV-infected calves did not coincide with humoral immune responses to protein 2 or other virion proteins.

Nucleotide sequence of the tick-borne orthomyxo-like Dhori/India/1313/61 virus membrane protein gene.

The complete nucleotide sequence of the sixth largest segment of ssRNA (RNA-6) of the tick-borne orthomyxo-like Dhori/India/1313/61 virus was determined by using cloned cDNA derived from infected cell mRNA and dideoxynucleotide sequencing of viral RNA. RNA-6 contains 962 nucleotides and is predicted to encode a protein of 270 amino acids with an M(r) of 30,498 in its first open reading frame (ORF). This protein is likely to represent the viral membrane (M1) protein, based on its predicted M(r) of 29,000 (estimated by PAGE), its relatively high abundance in infected cells and amino acid composition analysis. In addition, a second ORF was found which overlaps the M1 protein gene sequence by 327 nucleotides. This additional reading frame, in the +3 frame, potentially can encode a protein of 141 amino acids. However, S1 nuclease analysis of RNA-6 mRNA from infected cells indicated that there was only a single abundant RNA species corresponding in size to the full-length genomic RNA (0.96 kb). Further studies are needed to determine whether expression of the second ORF occurs and how that expression might arise.

Interferon induction by viruses. IV. Sindbis virus: early passage defective-interfering particles induce interferon.

We have shown that a single defective-interfering (DI) particle of early (5th) passage Sindbis virus induces maximal amounts of interferon in an 'aged' primary chick embryo cell. The capacity of such DI particles to induce interferon is inactivated by small amounts of u.v. radiation (i/e dose = 232 ergs/mm2). The I/e dose for inactivation of the interferon-inducing capacity of infectious virus particles is 399 ergs/mm2 and for infectivity is 101 ergs/mm2. Pre-treatment with interferon blocks formation of interferon in response to either DI or infectious virus particles. Our results suggest that Sindbis virus genes must be expressed to form the interferon inducer, which is presumably a molecule of double-stranded (ds)RNA. We postulate that for interferon induction, the genomic RNA which codes for genes G and A must be translated into products whose concerted action produces a dsRNA molecule upon synthesis of a segment of RNA complementary to the genome. The RNA from early passage DI particles is sufficiently large (25S, 1.6 x 10(6) mol. wt.) to accommodate these genes, whereas the RNA from the late passage DI particles (20S, 1.0 x 10(6) mol. wt.) is not. Late (15th) passage DI particles do not induce interferon formation.

Interferon induction by viruses. Sindbis virus: defective-interfering particles temperature-sensitive for interferon induction.

A defective-interfering (DI) particle of Sindbis virus was generated from a ts mutant of RNA-complementation group A by serially undiluted passages at 30 degrees C. This mutant induced interferon at a permissive temperature (30 degrees C), but not at a non-permissive temperature (40.5 degrees C); it also expressed homotypic interference throughout the range 30 to 40.5 degrees C. This demonstrates for the first time in a DI particle a ts function, namely, the ability to induce interferon. In addition, our data provide further evidence that the RNA genome of a Sindbis DI particle can be translated within the cell. We postulate that the products of translation function to produce the putative inducer of interferon, namely a molecule of dsRNA.

Interferon induction by viruses. II. Sindbis virus: interferon induction requires one-quarter of the genome--genes G and A.

We have measured the amounts of interferon formed by chick cells 'aged' in vitro in response to different amounts of infectious wild-type Sindbis virus. Our results suggest that one plaque-forming unit is enough to induce maximum interferon formation. With higher m.o.i. the yield of interferon is less. To inactivate the interferon-inducing activity of Sindbis virus, four times more u.v.-radiation was needed than to inactivate the infectivity of the virus. This suggests that only 25% of the virus genome need be intact in order to induce interferon. Temperature-sensitive Sindbis virus mutants from the three RNA+ complementation groups, C. D and E, gave rise to interferon in chick cells incubated at a non-permissive temperature, Similarly, mutants from two of the RNA- groups, B and F, gave rise to interferon, but not mutants from groups G and A. We conclude that no pre-formed inducer of interferon is present in Sindbis virus. It appears, however, that genes G and A represent a special one-quarter of the genome which must be functional in order to synthesize an interferon-inducing moiety. We suggest that this moiety is a double-stranded RNA molecule formed after synthesis of a segment of RNA complementary to the genome.

Nucleotide sequence of the tick-borne, orthomyxo-like Dhori/Indian/1313/61 virus envelope gene.

The complete nucleotide sequence of the fourth largest segment of single-stranded RNA of the tick-borne, orthomyxo-like Dhori/Indian/1313/61 virus was determined by using cloned cDNA derived from infected cell mRNA. The fourth RNA contains 1586 nucleotides and can code for a protein of 521 amino acids with a molecular weight of 58,675 Da. The predicted polypeptide possesses an amino-terminal hydrophobic region that may function as a signal sequence to initiate translocation across the endoplasmic reticulum membrane and a carboxyl-terminal hydrophobic region that could serve as a stop transfer sequence for anchoring this protein in the membrane. The envelope protein of Dhori virus does not display significant amino acid sequence homology with any of the envelope proteins (hemagglutinin or neuraminidase) of the influenza virus family members (or any other virus group) suggesting that the Dhori envelope protein is unique and may at least in part account for its divergent biological properties with other orthomyxoviruses.

Evolutionary relatedness of the predicted gene product of RNA segment 2 of the tick-borne Dhori virus and the PB1 polymerase gene of influenza viruses.

The complete nucleotide sequence of the second largest RNA segment of Dhori/India/1313/61 virus was determined and the deduced amino acid sequence was compared with the polymerase (P) proteins of influenza A, B, and C viruses. RNA segment 2 (2224 nucleotides) of Dhori virus contains a single long open reading frame that can encode a 716-amino acid polypeptide (81.3 kDa). The predicted polypeptide shares between 27 and 31% sequence identities with the PB1 polypeptides of influenza A, B, and C viruses. Among the regions most highly conserved are the sequences around the Asp-Asp motif common to many RNA polymerases. In spite of the high level of sequence identity between the Dhori RNA segment 2 gene product and the influenza A, B, and C virus PB1 proteins the amino acid composition of the Dhori protein indicates an acidic charge feature at pH 7.0 in contrast to the basic nature of the PB1 proteins of the influenza viruses. We suggest that the Dhori PB1-like protein be designated the P alpha protein of this virus.

Wild-type equine infectious anemia virus replicates in vivo predominantly in tissue macrophages, not in peripheral blood monocytes.

In situ hybridization of tissues from two horses infected with the wild-type Wyoming strain of equine infectious anemia virus (EIAV) identified the liver, spleen, lymph nodes, kidney, lung, and adrenal gland as the primary host tissue sites for viral transcription during acute infection. Combined immunohistochemistry, with a monoclonal antibody recognizing a cytoplasmic antigen of equine mononuclear phagocytes, and in situ hybridization for viral RNA identified most infected cells as mature tissue macrophages. In contrast, in situ hybridization of adherent peripheral blood mononuclear cells collected from horses on various days during the first 2 weeks postinfection with the Wyoming strain of EIAV failed to detect any viral RNA in these cells. For the two horses described here, serum reverse transcriptase activity correlated directly with the degree of replication detected in tissue macrophages on the day of sacrifice. These results suggest that unlike other lentivirus infections in which mature tissue macrophages accumulate cytoplasmic viral RNA to a high level but fail to produce infectious virions, mature tissue macrophages are the likely primary source of the high titer of viremia present during acute infection with EIAV. No significant posttranscriptional block of viral replication in tissue macrophages appears to occur with EIAV.

Sequence analysis of the matrix/nucleocapsid gene region of turkey coronavirus.

A reverse transcriptase, polymerase chain reaction (RT-PCR) procedure was used to amplify a segment of the genome of turkey coronavirus (TCV) spanning portions of the matrix and nucleocapsid (MN) protein genes (approximately 1.1 kb). The MN gene region of three epidemiologically distinct TCV strains (Minnesota, NC95, Indiana) was amplified, cloned into pUC19, and sequenced. TCV MN gene sequences were compared with published sequences of other avian and mammalian coronaviruses. A high degree of similarity (>90%) was observed between the nucleotide, matrix protein, and nucleocapsid protein sequences of TCV strains and published sequences of infectious bronchitis virus (IBV). The matrix and nucleocapsid protein sequences of TCV had limited homology (<30%) with MN sequences of mammalian coronaviruses. These results demonstrate a close genetic relationship between the avian coronaviruses, IBV and TCV.