Passive immunity modulates genetic reassortment between rotaviruses in mixedly infected mice.

Genetic reassortment between simian rotavirus SA11 and rhesus rotavirus (RRV) occurs with high frequency following mixed infection of nonimmune suckling mice (J. L. Gombold and R. F. Ramig, J. Virol. 57:110-116, 1986). We examined the effects of passively acquired homotypic or heterotypic immunity on reassortment in vivo. Passively immune suckling mice obtained from dams immune to either serotype 3 simian rotavirus (SA11) or serotype 6 bovine rotavirus (NCDV) were infected orally with either SA11 or RRV or a mixture of SA11 and RRV (both serotype 3 viruses). At various times postinfection, signs of disease were noted and the intestines of individual mice were removed and homogenized for titration of infectious virus and isolation of progeny plaques. Electrophoresis of genomic RNA was used to identify reassortants among the viral progeny isolated from infected animals. No reassortants (less than 0.45%) were detected among 224 clones examined from mixedly infected, homotypically immune mice. Twenty-nine reassortants (10.66%) were identified among 272 progeny clones from mixedly infected, heterotypically immune mice. Thus, reassortment was reduced more than 50-fold by homotypic immunity and approximately threefold by heterotypic immunity compared with prior data obtained from mixed infections of nonimmune mice. In addition, reassortment between SA11 and RRV in nonimmune mice was shown to be dependent on the virus dose. Taken together, these results suggest that immune responses may modulate the frequency of reassortment by reducing the effective multiplicity of infection (by neutralization or other immune mechanisms), thereby preventing efficient mixed infection of enterocytes.     

Rotavirus SA11 genome segment 11 protein is a nonstructural phosphoprotein.

We investigated properties of the rotavirus genome segment 11 protein. A rotavirus SA11 genome segment 11 cDNA which contains the entire coding region was sequenced and inserted into the baculovirus transfer vector pVL941. Recombinants containing gene 11 cDNA were selected, and the gene 11 product expressed in Spodoptera frugiperda cells infected with these recombinants was inoculated into guinea pigs to produce hyperimmune antiserum. Characterization of the antiserum showed that it recognized a primary translation product with a molecular weight of 26,000 (26K protein) in recombinant-infected insect cells, in SA11-infected monkey kidney cells, and in cell-free translation reactions programmed with SA11 mRNA. A modified 28K product was also detected but only in SA11-infected monkey kidney cells. The 26K 28K proteins were shown to be phosphorylated in infected monkey kidney cells, and the 26K protein was phosphorylated in insect cells. We were unable to identify what type of modification caused the molecular weight shift to 28,000 in infected monkey kidney cells. Large amounts of the gene 11 product were detected by immunofluorescence in discrete foci in the cytoplasm of infected monkey kidney cells. Viruses of all known serotypes were also detected by immunofluorescence by using hyperimmune antiserum to the SA11 gene 11 product. The antiserum reacted with particle-depleted cytosol fractions but did not react with purified virus particles by immunoprecipitation or immunoblotting; it also did not neutralize virus infectivity in plaque reduction neutralization assays. Therefore, we conclude that the primary gene 11 product is a nonstructural phosphoprotein which we designated NS26.     

Heterogeneity of genome rearrangements in rotaviruses isolated from a chronically infected immunodeficient child.

Rotaviruses with genome rearrangements, isolated from a chronically infected immunodeficient child, were adapted to growth in BSC-1 cells. Preparations of viral RNA from fecal extracts showed a mixed atypical rotavirus RNA profile, which was due to the presence of at least 12 subpopulations of viruses grossly differing in genotype. Besides various forms of genome rearrangements involving segment 8-, 10-, and 11-specific sequences, reassortment in vivo was likely to have occurred during the emergence of these viruses. The protein products of viral genomes with various forms of segmental rearrangements seemed to be largely unaltered. Genome rearrangement is proposed to be a third mechanism directing the evolution of rotaviruses.     

Isolation and characterization of a novel reassortant between avian Ty-1 and simian RRV rotaviruses.

A reassortant, TyRh, was isolated after coinfection of MA104 cells with avian Ty-1 and simian RRV rotaviruses. Hybridization and serological studies showed that the reassortant's 4th gene, which encodes Vp4, was derived from the simian RRV rotavirus parent, whereas the remaining 10 genes were derived from the avian Ty-1 rotavirus parent.     

Gene protein products of SA11 simian rotavirus genome

When MA104 cells were infected with SA11 rotavirus, 12 protein classes, absent in mock-infected cells, could be distinguished by polyacrylamide gel electrophoresis. At least two of these proteins were glycosylated, and their synthesis could be blocked with tunicamycin. The oligosaccharides of both glycoproteins were cleaved by endo-beta-N-acetylglucosaminidase H, suggesting that they were residues of the "high-mannose" type. Of the 12 viral polypeptides observed in infected cells, 1 was probably the apoprotein of one of these glycoproteins; 5, including 1 glycoprotein, were structural components of the virions, whereas the other 6, including a second and possibly third glycoprotein, were nonstructural viral proteins. When the 11 double-stranded RNA genome segments of SA11 were translated, after denaturation, in an RNA-dependent cell-free translation system, at least 11 different polypeptides were synthesized. Ten of these polypeptides had electrophoretic migration patterns equal to those of viral proteins observed in tunicamycin-treated infected cells. Nine of the 11 double-stranded RNA genome segments were resolved by polyacrylamide gel electrophoresis and were translated individually. Two were not resolved from each other and therefore were translated together. Correlation of each synthesized polypeptide with an individual RNA segment allowed us to make a probable gene-coding assignment for the different SA11 genome segments.     

Genetic reassortment of mammalian reoviruses in mice.

Reassortments between type 1 (Lang) and type 3 (Dearing) reoviruses were isolated from suckling mice infected perorally with an inoculum containing both type 1 and type 3 viruses. A total of five distinct reassortants (designated as E1 through E5) were isolated from animals during the course of the experiment. Two reassortants (E1 and E2) represented the majority of the reassortants isolated. The majority of genes of types E1 and E2 were derived from type 1 (Lang). However, E1 had an M2 gene and an S1 gene derived from type 3 (Dearing), while E2 had M2 and S2 genes derived from type 3 (Dearing). Thus, nonrandom reassortment between mammalian reoviruses can be demonstrated in vivo.     

Reconciliation of rotavirus temperature-sensitive mutant collections and assignment of reassortment groups D, J, and K to genome segments

Four rotavirus SA11 temperature-sensitive (ts) mutants and seven rotavirus RRV ts mutants, isolated at the National Institutes of Health (NIH) and not genetically characterized, were assigned to reassortment groups by pairwise crosses with the SA11 mutant group prototypes isolated and characterized at Baylor College of Medicine (BCM). Among the NIH mutants, three of the RRV mutants and all four SA11 mutants contained mutations in single reassortment groups, and four RRV mutants contained mutations in multiple groups. One NIH mutant [RRVtsK(2)] identified the previously undefined 11th reassortment group (K) expected for rotavirus. Three NIH single mutant RRV viruses, RRVtsD(7), RRVtsJ(5), and RRVtsK(2), were in reassortment groups not previously mapped to genome segments. These mutants were mapped using classical genetic methods, including backcrosses to demonstrate reversion or suppression in reassortants with incongruent genotype and temperature phenotype. Once located to specific genome segments by genetic means, the mutations responsible for the ts phenotype were identified by sequencing. The reassortment group K mutant RRVtsK(2) maps to genome segment 9 and has a Thr280Ileu mutation in the capsid surface glycoprotein VP7. The group D mutant RRVtsD(7) maps to segment 5 and has a Leu140Val mutation in the nonstructural interferon (IFN) antagonist protein NSP1. The group J mutant RRVtsJ(5) maps to segment 11 and has an Ala182Gly mutation affecting only the NSP5 open reading frame. Rotavirus ts mutation groups are now mapped to 9 of the 11 rotavirus genome segments. Possible segment locations of the two remaining unmapped ts mutant groups are discussed.     

Coding assignments of double-stranded RNA segments of SA 11 rotavirus established by in vitro translation

The segmented double-stranded (ds) RNA genome of the simian rotavirus SA 11, after denaturation, can be translated in a cell-free protein synthesizing system. Of the 11 genome segments, 9 can be resolved on polyacrylamide gels and thus could be individually isolated and translated, providing a means of identifying the polypeptide encoded by each segment. On the basis of electrophoretic mobility of products in sodium dodecyl sulfate-polyacrylamide gels, the probable gene-coding assignments of dsRNA segments 1 to 6 were determined. RNA segments 1 to 4 code for polypeptides I1, I2, I3, and I4, respectively; segment 5 codes for a polypeptide very similar in mobility to a minor polypeptide present in SA 11-infected cells, O1A; and segment 6 codes for the major inner-capsid polypeptide I5.     

Comparative analysis of the VP3 gene of divergent strains of the rotaviruses simian SA11 and bovine Nebraska calf diarrhea virus.

The gene encoding outer capsid protein VP3 of subpopulations of two animal rotaviruses, simian SA11 and Nebraska calf diarrhea virus (NCDV), was analyzed. Two laboratory strains of simian SA11 rotavirus (SA11-SEM and SA11-FEM) differed with respect to VP3. This dimorphism was indicated by a difference in electrophoretic mobility and a difference in reactivity with anti-VP3 monoclonal antibodies. The overall VP3 amino acid homology between the two SA11 VP3 proteins was 82.7%, whereas the VP3 protein of SA11-FEM was 98.5% homologous in amino acid sequence to NCDV VP3, suggesting that SA11-FEM VP3 was derived by gene reassortment in the laboratory during contamination with a bovine rotavirus. A comparison of the deduced amino acid sequence of the VP3 of two virulent NCDV strains and an attenuated NCDV strain (RIT 4237), revealed only five amino acid differences which were scattered throughout the protein but did not involve the trypsin cleavage sites. Of interest, the VP3 of the standard strain of NCDV which is virulent for cows differed in only one amino acid (position 23, Gln to Lys) from the VP3 of an NCDV mutant which was attenuated both for cows and for children.     

Use of antisera against bovine (NCDV) and simian (SA11) rotaviruses in ELISA to detect different types of human rotavirus.

Two ELISA systems for the detection of human rotaviruses were developed. In the first system antibodies to Nebraska calf diarrhea virus (NCDV) were used for coating the solid matrix and for the preparation of the enzyme conjugate. In the second system antibodies to human rotavirus and antibodies to simian rotavirus (SA11) were used for coating the solid matrix and for the preparation of the enzyme conjugate respectively. The second ELISA system proved to have a broader spectrum for the detection of human rotaviruses. By using the two ELISA systems, the different types of human rotavirus could be distinguished. The ELISA tests developed were 8 to 64 times as sensitive as electron microscopy (EM) and (or) counterimmunoelectrophoresis (CIEP). The antigen detected by ELISA was shown to be different from that detected by the hemagglutination test.     

Simian rotavirus SA11 replication in cell cultures.

Understanding the basic virology of rotavirus infections has been hampered by the fastidiousness of most isolates and by the lack of a rapid quantitative assay method. The growth characteristics of the simian rotavirus SA11 were studied because it grows to high titers in tissue culture and infectivity can be quantitated by plaque assay. SA11 replication was analyzed in a variety of primary cell cultures or continuous cell lines derived from both homologous and heterologous hosts. Viral replication was observed in each of the cell cultured examined. The individual cell cultures demonstrated marked variability in their susceptibility to rotavirus infection. The highest titers were obtained with MA104, BSC-1, CV-1, and BGM cells. Observable cytopathic effect was found to correlate with the percentage of infected cells in the culture. This study presents growth curves of the simian rotavirus in a variety of cell cultures.     

Completion of the gene coding assignments of SA11 rotavirus: gene products of segments 7, 8, and 9.

Improved fractionation of double-stranded RNA segments 7, 8, and 9 of simian rotavirus SA11 has permitted their isolation and individual translation in vitro. Segment 7 codes for p31 (NS2), segment 8 codes for p33 (NS1), and the segment 9 gene product resembles the gp34 precursor observed in SA11 virus-infected cells. In vitro glycosylation of translation products of segments 5 and 10 was also observed.     

Association of viral particles and viral proteins with membranes in SA11-infected cells.

Electron microscopy after negative staining of SA11-infected cell homogenates revealed that most of the viral particles are associated with membrane-like material. Many of the particles seemed to be fully enveloped in a membrane. This association could also be detected by the observed cosedimentation of viral proteins and cell membranes. Pulse-chase experiments showed that viral glycoproteins rapidly associate with membranes, whereas most of the structural proteins appearing in the soluble fraction immediately after the pulse were slowly chased into the membrane fraction. The membranes could be further fractionated into at least four fractions differing in density and containing a different distribution of viral proteins. Also, the distribution of label into each of these membrane fractions changed after long chase periods. The inhibition of glycosylation with tunicamycin yielded viral particles without an outer layer, but did not affect the described association with membranes. The possible relationship of this finding to the maturation of the virion is discussed.