Trypsin cleavage stabilizes the rotavirus VP4 spike

Trypsin enhances rotavirus infectivity by an unknown mechanism. To examine the structural basis of trypsin-enhanced infectivity in rotaviruses, SA11 4F triple-layered particles (TLPs) grown in the absence (nontrypsinized rotavirus [NTR]) or presence (trypsinized rotavirus [TR]) of trypsin were characterized to determine the structure, the protein composition, and the infectivity of the particles before and after trypsin treatment. As expected, VP4 was not cleaved in NTR particles and was cleaved into VP5(*) and VP8(*) in TR particles. However, surprisingly, while the VP4 spikes were clearly visible and well ordered in the electron cryomicroscopy reconstructions of TR TLPs, they were totally absent in the reconstructions of NTR TLPs. Biochemical analysis with radiolabeled particles indicated that the stoichiometry of the VP4 in NTR particles was the same as that in TR particles and that the VP8(*) portion of NTR, but not TR, particles is susceptible to further proteolysis by trypsin. Taken together, these structural and biochemical data show that the VP4 spikes in the NTR TLPs are icosahedrally disordered and that they are conformationally different. Structural studies on the NTR TLPs after trypsin treatment showed that spike structure could be partially recovered. Following additional trypsin treatment, infectivity was enhanced for both NTR and TR particles, but the infectivity of NTR remained 2 logs lower than that of TR particles. Increased infectivity in these particles corresponded to additional cleavages in VP5(*), at amino acids 259, 583, and putatively 467, which are conserved in all P serotypes of human and animal group A rotaviruses and also corresponded with a structural change in VP7. These biochemical and structural results show that trypsin cleavage imparts order to VP4 spikes on de novo synthesized virus particles, and these ordered spikes make virus entry into cells more efficient.

Subunit rotavirus vaccine administered parenterally to rabbits induces active protective immunity

Virus-like particles (VLPs) are being evaluated as a candidate rotavirus vaccine. The immunogenicity and protective efficacy of different formulations of VLPs administered parenterally to rabbits were tested. Two doses of VLPs (2/6-, G3 2/6/7-, or P[2], G3 2/4/6/7-VLPs) or SA11 simian rotavirus in Freund's adjuvants, QS-21 (saponin adjuvant), or aluminum phosphate (AlP) were administered. Serological and mucosal immune responses were evaluated in all vaccinated and control rabbits before and after oral challenge with 10(3) 50% infective doses of live P[14], G3 ALA lapine rotavirus. All VLP- and SA11-vaccinated rabbits developed high levels of rotavirus-specific serum and intestinal immunoglobulin G (IgG) antibodies but not intestinal IgA antibodies. SA11 and 2/4/6/7-VLPs afforded similar but much higher mean levels of protection than 2/6/7- or 2/6-VLPs in QS-21. The presence of neutralizing antibodies to VP4 correlated (P < 0.001, r = 0.55; Pearson's correlation coefficient) with enhanced protection rates, suggesting that these antibodies are important for protection. Although the inclusion of VP4 resulted in higher mean protection levels, high levels of protection (87 to 100%) from infection were observed in individual rabbits immunized with 2/6/7- or 2/6-VLPs in Freund's adjuvants. Therefore, neither VP7 nor VP4 was absolutely required to achieve protection from infection in the rabbit model when Freund's adjuvant was used. Our results show that VLPs are immunogenic when administered parenterally to rabbits and that Freund's adjuvant is a better adjuvant than QS-21. The use of the rabbit model may help further our understanding of the critical rotavirus proteins needed to induce active protection. VLPs are a promising candidate for a parenterally administered subunit rotavirus vaccine.

Analysis of host range restriction determinants in the rabbit model: comparison of homologous and heterologous rotavirus infections

The main limitation of both the rabbit and mouse models of rotavirus infection is that human rotavirus (HRV) strains do not replicate efficiently in either animal. The identification of individual genes necessary for conferring replication competence in a heterologous host is important to an understanding of the host range restriction of rotavirus infections. We recently reported the identification of the P type of the spike protein VP4 of four lapine rotavirus strains as being P[14]. To determine whether VP4 is involved in host range restriction in rabbits, we evaluated infection in rotavirus antibody-free rabbits inoculated orally with two P[14] HRVs, PA169 (G6) and HAL1166 (G8), and with several other HRV strains and animal rotavirus strains of different P and G types. We also evaluated whether the parental rhesus rotavirus (RRV) (P5B[3], G3) and the derived RRV-HRV reassortant candidate vaccine strains RRV x D (G1), RRV x DS-1 (G2), and RRV x ST3 (G4) would productively infect rabbits. Based on virus shedding, limited replication was observed with the P[14] HRV strains and with the SA11 Cl3 (P[2], G3) and SA11 4F (P6[1], G3) animal rotavirus strains, compared to the homologous ALA strain (P[14], G3). However, even limited infection provided complete protection from rotavirus infection when rabbits were challenged orally 28 days postinoculation (DPI) with 10(3) 50% infective doses of ALA rabbit rotavirus. Other HRVs did not productively infect rabbits and provided no significant protection from challenge, in spite of occasional seroconversion. Simian RRV replicated as efficiently as lapine ALA rotavirus in rabbits and provided complete protection from ALA challenge. Live attenuated RRV reassortant vaccine strains resulted in no, limited, or productive infection of rabbits, but all rabbits were completely protected from heterotypic ALA challenge. The altered replication efficiency of the reassortants in rabbits suggests a role for VP7 in host range restriction. Also, our results suggest that VP4 may be involved in, but is not exclusively responsible for, host range restriction in the rabbit model. The replication efficiency of rotavirus in rabbits also is not controlled by the product of gene 5 (NSP1) alone, since a reassortant rotavirus with ALA gene 5 and all other genes from SA11 was more severely replication restricted than either parental rotavirus strain.

Genetics of the rotaviruses

Genetic analyses have contributed significantly to our understanding of the biology of the rotaviruses. The distinguishing feature of the virus is a genome consisting of 11 segments of double-stranded RNA. The segmented nature of the genome allows reassortment of genome segments during mixed infections, which is the major distinguishing feature of rotavirus genetics. Reassortment has been a powerful tool for mapping viral mutations and other determinants of biological phenotypes to specific genome segments. However, more detailed genetic analysis of rotaviruses is currently limited by the inability to perform reverse genetics. Development of a reverse genetic system will facilitate analysis of the molecular mechanisms involved in various genetic, biochemical, and biological phenomena of the virus.

The 3'-terminal consensus sequence of rotavirus mRNA is the minimal promoter of negative-strand RNA synthesis

We used an in vitro template-dependent replicase assay (D. Chen, C. Zeng, M. Wentz, M. Gorziglia, M. Estes, and R. Ramig. J. Virol. 68:7030-7039, 1994) to identify the cis-acting signals required for replication of a genome segment 9 template from the group A rotavirus strain OSU. The replicase phenotypes for a panel of templates with internal deletions or 3'-terminal truncations indicated that no essential replication signals were present within the open reading frame and that key elements were present in the 5' and 3' noncoding regions. Chimeric constructs containing portions of viral sequence ligated to a nonviral backbone were generated to further map the regions required for in vitro replication of segment 9. The data from these constructs showed that the 3'-terminal seven nucleotides of the segment 9 mRNA provided the minimum requirement for replication (minimal promoter). Analysis of additional chimeric templates demonstrated that sequences capable of enhancing replication from the minimal promoter were located immediately upstream of the minimal promoter and at the extreme 5' terminus of the template. Mutational analysis of the minimal promoter revealed that the 3'-terminal -CC residues are required for efficient replication. Comparison of the replication levels for templates with guanosines and uridines at nucleotides -4 to -6 from the 3' terminus compared with levels for templates containing neither of these residues at these positions indicated that either or both residues must be present in this region for efficient replication in vitro.

cis-Acting signals that promote genome replication in rotavirus mRNA

A previous study has shown that rotavirus cores have an associated replicase activity which can direct the synthesis of double-stranded RNA from viral mRNA in a cell-free system (D. Y. Chen, C. Q.-Y. Zeng, M. J. Wentz, M. Gorziglia, M. K. Estes, and R. F. Ramig, J. Virol. 68:7030-7039, 1994). To define the cis-acting signals in rotavirus mRNA that are important for RNA replication, gene 8 transcripts which contained internal and terminal deletions and chimeric transcripts which linked gene 8-specific 3'-terminal sequences to the ends of nonviral sequences were generated. Analysis of these RNAs in the cell-free system led to the identification of a cis-acting signal in the gene 8 mRNA which is essential for RNA replication and two cis-acting signals which, while not essential for replication, serve to enhance the process. The sequence of the essential replication signal is located at the extreme 3' end of the gene 8 mRNA and, because of its highly conserved nature, is probably a common feature of all 11 viral mRNAs. By site-specific mutagenesis of the gene 8 mRNA, residues at positions -1, -2, -5, -6, and -7 of the 3' essential signal were found to be particularly important for promoting RNA replication. One of the cis-acting signals shown to enhance the replication in the cell-free system was located near the 5' end of the 3' untranslated region (UTR) of the gene 8 mRNA, while remarkably the other was located in the 5' UTR of the message. The existence of an enhancement signal in the 5' UTR raises the possibility that the 5' and 3' ends of the rotavirus mRNA may interact with each other and/or with the viral replicase during genome replication.

Characterization and replicase activity of double-layered and single-layered rotavirus-like particles expressed from baculovirus recombinants

Rotavirus has a capsid composed of three concentric protein layers. We coexpressed various combinations of the rotavirus structural proteins of single-layered (core) and double-layered (single-shelled) capsids from baculovirus vectors in insect cells and determined the ability of the various combinations to assemble into viruslike particles (VLPs). VLPs were purified by centrifugation, their structure was examined by negative-stain electron microscopy, their protein content was determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and GTP binding assays, and their ability to support synthesis of negative-strand RNAs on positive-sense template RNAs was determined in an in vitro replication system. Coexpression of all possible combinations of VP1, VP2, VP3, and VP6, the proteins of double-layered capsids, resulted in the formation of VP1/2/3/6, VP1/2/6, VP2/3/6, and VP2/6 double-layered VLPs. These VLPs had the structural characteristics of empty rotavirus double-layered particles and contained the indicated protein species. Only VPI/2/3/6 and VP1/2/6 particles supported RNA replication. Coexpression of all possible combinations of VPl, VP2, and VP3, the proteins of single-layered capsids, resulted in the formation of VP1/2/3, VP1/2, VP2/3, and VP2 single-layered VLPs. These VLPs had the structural characteristics of empty single-layered rotavirus particles and contained the indicated protein species. Only VP1/2/3 and VP1/2 VLPs supported RNA replication. We conclude that (i) the assembly of VP1 and VP3 into VLPs requires the presence of VP2, (ii) the role of VP2 in the assembly of VP1 and VP3 and in replicase activity is most likely structural, (iii) VP1 is required and VP3 is not required for replicase activity of VLPs, and (iv) VP1/2 VLPs constitute the minimal replicase particle in the in vitro replication system.

Identification of the minimal replicase and the minimal promoter of (-)-strand synthesis, functional in rotavirus RNA replication in vitro

An in vitro replication system supporting the initiation and synthesis of complete rotavirus (-)-strands on (+)-strand template RNA (Chen et al., J Virol 68: 7030, 1994) was used to examine several parameters related to rotavirus RNA replication. Coexpression of VP1/2/3 in all possible combinations from baculovirus vectors revealed: [i] Virus-like particles (VLPs) were formed only if VP2 was present, and [ii] VP1/2 and VP1/2/3 VLPs had replicase activity in the in vitro system whereas VP2/3 and VP2 VLPs did not. Thus, the minimal replicase is composed of VP1 and VP2 and replicase activity is associated with VP1. In vitro replication reactions, using T7 transcripts of porcine rotavirus OSU genome segment 9 as reporter template, were performed to map cis-acting elements that regulate replication. Internal deletions and terminal truncations of the reporter RNA localized a replication signal, conferring full template activity, to the 5'-terminal 27 nucleotides (nt 1-27) and the 3'-terminal 26 nucleotides (nt 1037-1062). Further analysis showed that a minimal promoter of (-)-strand synthesis was contained in the 3'-terminal 7 nucleotides (nt 1056-1062); the sequence conserved at the 3'-terminus of all rotavirus genes. Hybrid constructs with this promoter had minimal, but detectable, template activity. This result indicated that upstream sequences between nucleotides 1037-1055 positively regulate the activity of the minimal promoter.

Rotavirus structure: interactions between the structural proteins

Structural studies on rotavirus using electron cryomicroscopy and computer image analysis have permitted visualization of each shell in the triple-layered rotavirus structure. Biochemical results have aided our interpretation of the structural organization of these layers and protein interactions seen in the three-dimensional structure, and have provided a better understanding of the structure-function relationships of the rotavirus structural proteins.

Template-dependent, in vitro replication of rotavirus RNA

A template-dependent, in vitro rotavirus RNA replication system was established. The system initiated and synthesized full-length double-stranded RNAs on rotavirus positive-sense template RNAs. Native rotavirus mRNAs or in vitro transcripts, with bona fide 3' and 5' termini, derived from rotavirus cDNAs functioned as templates. Replicase activity was associated with a subviral particle containing VP1, VP2, and VP3 and was derived from native virions or baculovirus coexpression of rotavirus genes. A cis-acting signal involved in replication was localized within the 26 3'-terminal nucleotides of a reporter template RNA. Various biochemical and biophysical parameters affecting the efficiency of replication were examined to optimize the replication system. A replication system capable of in vitro initiation has not been previously described for Reoviridae.

Temperature-sensitive lesions in the capsid proteins of the rotavirus mutants tsF and tsG that affect virion assembly

The SA11 rotavirus mutants tsF and tsG contain temperature sensitive (ts) lesions in the capsid proteins VP2 and VP6, respectively, that interfere with their ability to assemble. To understand the nature of their lesions, full-length cDNAs of tsF gene 2 and tsG gene 6 were prepared from viral mRNA by reverse transcription and polymerase chain reaction. Comparative sequence analysis indicated that the ts phenotype of tsF VP2 is due to an Ala-->Asp substitution at position 387. The mutation falls outside of those regions of VP2 previously suggested to be of functional significance and therefore points to a previously unidentified site in VP2 that is important for the assembly of viral cores. Comparative sequence analysis showed that tsG VP6 contains two mutant amino acids, i.e., Thr-10 and His-13, and therefore one or both of these mutations are responsible for the ts phenotype of the mutant VP6. In the case of other group A and group C VP6 sequences, these residues are Ser and Asp, respectively. Characterization of tsG-infected cells by indirect immunofluorescence staining showed that while viroplasmic inclusions are formed at the nonpermissive temperature, the mutant VP6 accumulates in these structures only at the permissive temperature. While influencing intracellular accumulation, the Thr-10-->Ser and His-13-->Asp mutations in tsG VP6 are probably not directly involved in the interaction of VP6 with VP2, as VP6 deletion mutants lacking residues 10 and 13 retain the ability to bind VP2 in vitro. Analysis of VP6 failed to confirm previous reports that the protein was myristylated and thus excludes the possibility that this cotranslational modification is temperature-dependent for tsG VP6. Together, these data suggest that the amino terminus of VP6 plays an essential role in virus assembly in vivo, perhaps by being necessary for the movement of the protein to viroplasmic inclusions, the site of core and single-shelled particle formation.

Characterization of rotavirus VP2 particles

Rotavirus particles consist of three concentric proteinaceous capsid layers. The innermost capsid (core) is made of VP2. The genomic RNA and the two minor proteins VP1 and VP3 are encapsidated within this layer. Empty rVP2 particles are produced when insect cells are infected with a recombinant baculovirus which contains the bovine Rf rotavirus gene 2 (Labbé et al., 1991, J. Virol. 65, 2946-2952). Analysis of expressed rVP2 particles by SDS-PAGE showed these particles were composed of three major VP2-related proteins, called bands A, B, and C, with apparent molecular weights of 94K, 85K, and 77K, respectively. N-Terminal amino acid sequence analysis of each band showed that band A and band B were blocked, and band C lacked 92 amino acids from the N terminus. Bands B and C were predicted to also lack an approximately 10K peptide fragment from the C terminus. Electron microscopy (EM) showed negatively stained rVP2 particles to be spherical with icosahedral symmetry, 520 +/- 20 A in diameter. Highly concentrated rVP2 particles were converted to unusual forms, including elongated bristly structures, helix-like structures, and sheet-like helix structures. These unusual forms apparently resulted from a structural conversion of individual rVP2 particles. This conversion was reversible both in solution or on a collodion-carbon-coated grid support. The reconstituted rVP2 particles possessed normal morphology and reacted with purified VP6 to form rVP2/6 empty double-layered (previously called single-shelled) virus-like particles with an association constant Ka approximately 10(11) M-1. Native viral core particles lacking RNA were obtained by dialysis of full cores prepared from purified SA11-4F rotavirus double-layered particles against a hypotonic buffer in the presence of EDTA. EM showed both the full and empty native viral cores to be spherical with icosahedral symmetry. Highly concentrated SA11-4F full and empty cores also were converted into elongated and bead-like structures. However, in contrast to rVP2 particles, the conversion of SA11-4F cores was not reversible. These results provide some helpful clues to understanding VP2 functions, the assembly of VP2 particles, the assembly of VP2/6 double-layered particles, and the transport of metabolites inside and outside of the core particle.

Three-dimensional visualization of the rotavirus hemagglutinin structure

Three-dimensional structures of a native simian and reassortant rotavirus have been determined by electron cryomicroscopy and computer image processing. The structural features of the native virus confirm that the hemagglutinin spike is a dimer of VP4, substantiated by in vivo radiolabeling studies. Exchange of native VP4 with a bovine strain equivalent results in a poorly infectious reassortant. No VP4 spikes are detected in the three-dimensional reconstruction of the reassortant. The difference map between the two structures reveals a novel large globular domain of VP4 buried within the virion that interacts extensively with the intermediate shell protein, VP6. Our results suggest that assembly of VP4 precedes that of VP7, the major outer shell protein, and that VP4 may play an important role in the receptor recognition and budding process through the rough endoplasmic reticulum during virus maturation.

Rescue of infectivity by sequential in vitro transcapsidation of rotavirus core particles with inner capsid and outer capsid proteins

We recently developed an in vitro transcapsidation system in which infectivity of single-shelled (ss) rotavirus particles was successfully rescued (Chen and Ramig, Virology [1993]). Here, we report the rescue of infectivity of rotavirus core particles using virus strain B223 (G serotype 10) as the core donor and strain SA11-4F (G3) as the capsid donor. Core particles of B223 were obtained by CaCl2 treatment of B223 ss-particles followed by isopycnic CsCl gradient centrifugation. Inner capsid protein VP6 of SA11-4F was prepared by CaCl2 treatment of SA11-4F ss-particles, followed by removal of core particles by two rounds of centrifugation. Outer capsid proteins VP4 and VP7 of SA11-4F were prepared by EDTA treatment of ds-particles, followed by three rounds of centrifugation to remove ss-particles and minimize residual infectivity. No infectivity (< 3 PFU/ml) was detectable in any of the donor preparations. Transcapsidated ss-particles were obtained by mixing B223 core particles and a 5-fold excess of SA11-4F VP6 at neutral pH. The formation of transcapsidated ss-particles was confirmed by electron microscopy, protein composition analysis, and density determination. Along with the formation of ss-particles by in vitro transcapsidation, some infectivity was also detected and transcriptase activity was reconstituted. Semi-purified transcapsidated ss-particles were then mixed with SA11-4F outer capsid proteins VP4 and VP7 at acidic pH to obtain transcapsidated ds-particles, as described previously. The formation of ds-like particles was also confirmed by electron microscopy, protein composition, and density determination. As the result of formation of transcapsidated ds-like particles, viral infectivity increased significantly (80-fold) relative to that of transcapsidated ss-particles. The infectivity of transcapsidated ds-particles was neutralized by polyclonal anti-SA11 serum, but not by polyclonal anti-B223 serum. The transcapsidated particles formed small plaques like B223 (core donor), and all the progeny plaques contained B223 genomes. These results demonstrate that the infectivity of rotavirus core particles can be rescued by sequential addition of inner and outer capsid proteins in vitro.

Characterization of avian reovirus-induced cell fusion: the role of viral structural proteins

Cell fusion induced by avian reovirus was analyzed using virus strain FC and Vero cells. One-step growth curves showed that cell fusion was directly associated with viral replication. Cell fusion occurred most efficiently at basic pH (8.0-8.5) and fusion from without could not be demonstrated. Actinomycin D, at low concentrations, increased cell fusion, and cycloheximide prevented cell fusion, indicating that viral protein(s) were responsible for the induction of cell fusion. Immunofluorescence tests indicated that viral proteins were present on the infected cell surface. Radioimmuno-precipitation identified structural proteins mu 2C and sigma 2 as predominant viral protein species present on the infected cell surface. Cell fusion was inhibited by virus-specific antisera, suggesting that mu 2C and/or sigma 2 present on the infected cell surface were involved in the induction of cell fusion. Trypsin and chymotrypsin treatment of purified viruses cleaved both mu 2C and sigma 2 proteins, but generated different cleavage products with each protein. The addition of trypsin to the culture media following infection increased cell fusion, whereas chymotrypsin treatment decreased cell fusion. The opposite effects of trypsin and chymotrypsin on the cell fusion, together with the different specificities of these two proteases in cleavage of mu 2C and sigma 2 proteins, further suggest that the cell surface-associated mu 2C and/or sigma 2 are involved in the syncytium formation.

Immunodominant neutralizing antigens depend on the virus strain during a primary immune response in calves to bovine rotaviruses

Sera obtained from gnotobiotic calves (GC antisera) infected with bovine rotavirus strain NCDV or B223 from a previous study (Woode et al., 1987), which have different G (G6 and G10 respectively) and P serotypes, were compared for their neutralization (NT) properties to a number of human and animal rotaviruses (representing G serotype 1-6, 8-10). Two distinct patterns of neutralization were identified from these GC antisera. Of all the serotypes tested, NCDV GC antisera neutralized only B641 to a relatively high titer compared with the homologous titer, implying a narrow pattern of NT response. Analysis with reassortants indicated that the response was primarily to VP4. In contrast, B223 GC antisera neutralized most of the G serotypes tested to titers within 3-7 fold of the homologous titer, demonstrating a broad pattern of NT response. In the earlier study B223 was shown to induce a heterotypic protection against bovine rotavirus B641 (G serotype 6), and the serologic data obtained from this study indicates that a B223 vaccine might provide broad protection against several different serotypes of human and animal rotaviruses.

Identification of proteins encoded by avian reoviruses and evidence for post-translational modification

Twelve avian reovirus strain 176 proteins, 10 structural (lambda 1, lambda 2, lambda 3, mu 1, mu 2/mu 2C, sigma 1, sigma 2, sigma 3, and sigma 4), and 2 nonstructural (mu NS and sigma NS) were identified and characterized by electrophoretic analysis of purified virions and infected cell lysates. Three of the identified proteins (mu 1, mu NS, and sigma 4) have not been previously described. In pulse-chase experiments, 10 of the proteins (lambda 1, lambda 2, lambda 3, mu 1, mu 2, mu NS, sigma 1, sigma 2, sigma NS, sigma 3) were shown to be primary translation products, whereas mu 2C was shown to be a post-translational cleavage product of mu 2.

Rescue of infectivity by in vitro transcapsidation of rotavirus single-shelled particles

We investigated the possibility of rescuing the infectivity of noninfectious single-shelled rotavirus particles by in vitro transcapsidation. The soluble outer capsid proteins VP4 and VP7 were prepared by EDTA treatment of double-shelled (ds) particles of SA11-4F (G serotype 3), followed by removal of single-shelled (ss) particles by three sequential rounds of centrifugation. Ss-particles of B223 (G serotype 10) were prepared by two cycles of EDTA treatment of ds-particles followed by iospycnic CsCl gradient purification. A trace of infectivity (< 1000 PFU/ml) was always detected in the preparations of ss-particles, while no detectable infectivity (< 5 PFU/ml) was present in the preparations of outer capsid proteins. By mixing soluble outer capsid proteins VP4 and VP7 purified from SA11-4F and ss-particles of B223 at acidic pH (5.4), ds-like, transcapsidated particles were obtained. The transcapsidated particles were indistinguishable from genuine ds-particles by negative stain electron microscopy. However, the particles had a density intermediate between that of ds- and ss-particles. Protease-resistance studies revealed that VP7 was assembled onto transcapsidated particles in a resistant (native) form, but VP4 associated with the particles was completely protease sensitive. Viral infectivity was rescued by in vitro transcapsidation as indicated by a 500- to 1000-fold increase over background. The increased infectivity was neutralized by antiserum against SA11 (outer capsid donor), but not by antiserum against B223 (ss-particle donor). The transcapsidated particles formed small plaques like the B223 parent, and all the infectious progeny viruses contained the B223 genome. These results strongly indicate that the observed increase of infectivity was the result of in vitro transcapsidation.

Specific interactions between rotavirus outer capsid proteins VP4 and VP7 determine expression of a cross-reactive, neutralizing VP4-specific epitope

We previously reported that the expression of rotavirus phenotypes by reassortants was affected by recipient genetic background and proposed specific interactions between the outer capsid proteins VP4 and VP7 as the basis for the phenotypic effects (D. Chen, J. W. Burns, M. K. Estes, and R. F. Ramig, Proc. Natl. Acad. Sci. USA 86:3743-3747, 1989). A neutralizing, cross-reactive VP4-specific monoclonal antibody (MAb), 2G4, was used to probe the protein-protein interactions. The VP4 specificity of 2G4 was confirmed by immunoblot analysis. MAb 2G4 reacted with both standard (SA11-C13) and variant rotavirus SA11 (SA11-4F) but did not react with bovine rotavirus B223 as determined by plaque reduction neutralization (PRN) and enzyme-linked immunosorbent assay (ELISA). When a panel of SA11-4F/B223 and SA11-Cl3/B223 reassortants in purified or crude lysate form that had been grown in the presence or absence of trypsin was analyzed with MAb 2G4 by PRN and ELISA, the results with some reassortants were unexpected. That is, MAb 2G4 reacted with VP4 of SA11 parental origin (4F or C13) when it was assembled into capsids with the homologous SA11 VP7 but failed to react with VP4 of SA11 assembled into capsids with heterologous B223 VP7. Conversely, MAb 2G4 failed to react with VP4 of B223 parental origin when it was assembled into capsids with homologous B223 VP7 but did react with B223 VP4 assembled into capsids with the heterologous SA11 VP7. Similar reactivity was observed when 2G4 was used to immunoprecipitate purified double-shelled virions. When soluble unassembled viral proteins were analyzed by ELISA, the 2G4 reactive pattern was as predicted from the parental origin of VP4. That is, 2G4 reacted with the soluble VP4 of reassortants having VP4 from SA11-Cl3 or SA11-4F and failed to react with VP4 of B223 origin, regardless of the origin of VP7. PRN and ELISA results obtained with nonglycosylated viruses revealed that the unexpected reactivity of 2G4 with virus particles was not the result of differential glycosylation of VP7 and epitope masking. These results indicate that the 2G4 epitope existed in the soluble form of VP4 encoded by SA11-Cl3 or SA11-4F but not in soluble B223 VP4. On the other hand, in assembled virions, the presentation of the 2G4 epitope on VP4 was unexpected in some reassortants and was affected by the specific interactions between VP4 and VP7 of heterologous parental origin.

Determinants of rotavirus stability and density during CsCl purification

The stability of rotavirus infectivity during CsCl gradient purification and subsequent storage was examined using our standard SA11 wild type (SA11-Cl3), the SA11 4F variant (SA11-4F), bovine rotavirus B223, and a panel of bi- and triparental reassortants derived from these parental viruses. Viral stability was determined by the recovery of infectivity at each step during a standard CsCl purification protocol. SA11-4F was the most stable parent (91-93% recovery), SA11-Cl3 had intermediate stability (10-21% recovery), and B223 was least stable (0.5-7% recovery). Among the reassortants, the recovery varied from 0.5 to 88.6% of the initial infectivity and was determined primarily by the parental origin of genome segment 4. The greatest loss of infectivity occurred during Freon extraction, with smaller losses during the CsCl gradient, and the smallest loss during the virus pelleting step. Comparison of the stability of viruses grown in the presence or absence of exogenous trypsin revealed that, in general, viruses grown in the absence of trypsin were more stable during purification. During 4-5 months storage at 4 degrees, the differences in stability of parental and reassortant viruses were not as dramatic as during purification and were not significantly affected by the presence or absence of trypsin during growth. However, survival during storage was as low as 4% and as high as 100% and was also primarily dependent on the parental origin of genome segment 4. It was noted that bovine rotavirus B223 had higher density in CsCl than either SA11-Cl3 or SA11-4F. The observation of heterogeneity in density was investigated using reassortants. These results indicated that all reassortants had intermediate density and suggested that physical interactions among the structural proteins were responsible for the heterogeneity in density. The possible roles of viral structural proteins in rotavirus stability and the relationship between the stability and the density are discussed.

Comparative growth of different rotavirus strains in differentiated cells (MA104, HepG2, and CaCo-2)

The production of viral antigen after infection of MA104, HepG2 (derived from human liver), and CaCo-2 (derived from human colon) cells with various cultivatable human and animal rotavirus strains was compared using immunofluorescence tests. All rotavirus strains examined expressed antigen in CaCo-2 cells and MA104 cells, but only some virus strains, namely, SA11-Cl3 (simian), RRV (simian), CU-1 (canine), and Ty1 (turkey), produced antigen in numbers of infected HepG2 cells comparable to infections in MA104 and CaCo-2 cells. Fl-14 (equine), OSU (porcine), NCDV (bovine), and Ch2 (chicken) strains were found to infect moderate numbers of HepG2 cells. Most human rotaviruses (representing viruses in serotypes 1, 2, 3, 4, 8, and 9), a simian rotavirus variant (SA11-4F), lapine (Ala, C-11 and R-2) viruses and porcine (Gottfried) virus infections resulted either in no detectable antigen or antigen synthesis in a low percentage of HepG2 cells. Human rotavirus isolates obtained from the stool specimens of an immunocompromised child with rotavirus antigen in his liver showed two different patterns of replication in HepG2 cells. Examination of the replication of a subset of viruses in the liver and intestinal tissues of orally infected suckling mice showed the CU-1 and Ty1 strains replicated well, while the OSU and human rotavirus strains did not. These results indicate that growth restriction in HepG2 cells is not serotype-specific, and growth of a virus in HepG2 cells does not necessarily correlate with the hepatotropic potential of a virus strain. Factors that may influence these differences of virus infectivity in HepG2 cells are discussed.

Rotavirus temperature-sensitive mutants are genetically stable and participate in reassortment during mixed infection of mice

Mixed and single infections of 7-day-old suckling mice with SA11 temperature-sensitive (ts) mutants and RRV wild-type were examined to determine if selection against ts mutations occurred in the suckling mouse model. Single infections with ts mutants indicated that mutant replication was restricted relative to wild-type and that disease was similarly reduced. Revertant (ts+) progeny did not appear to be selected during infection. Mixed infection with ts mutant and RRV wild-type revealed a reduction in the replication of RRV suggesting that the ts mutants displayed an interference phenotype in vivo similar to that observed in vitro. However, reduced replication of the RRV parent in mixed infection did not result in a significant reduction in disease relative to RRV infection. When progeny from the mixed infections were isolated at the permissive temperature both ts and ts+ progeny were observed, and the genome segments of these progeny segregated in a manner consistent with the temperature phenotype of each progeny clone and the location of the ts mutation determined in vitro. Selection of ts+ progeny from mixed infected mice at nonpermissive temperature yielded either the RRV parent or ts+ reassortants. The segregation of genome segments in these ts+ reassortant progeny was consistent with the location of the ts lesion determined previously in vitro. These results indicate the following with respect to infection of suckling mice with ts mutants: (1) ts lesions are genetically stable and are not selected against during in vivo infection, (2) ts mutants cause disease with reduced severity, (3) ts mutants interfere with the replication of wild-type virus in vivo but not with the severity of disease, and (4) mixed infection of suckling mice may be useful in genetic studies with rotaviruses not adapted to growth in cultured cells.

Intracellular RNA synthesis directed by temperature-sensitive mutants of simian rotavirus SA11

The kinetics of intracellular synthesis of single-stranded (ss) RNA and double-stranded (ds) RNA directed by prototype temperature-sensitive (ts) mutants representing the 10 mutant groups of rotavirus SA11 were examined. Cells were infected with individual mutants or wild type under one-step growth conditions and maintained at permissive temperature (31 degrees) or nonpermissive temperature (39 degrees). At various times postinfection, infected cells were pulse-labeled, ssRNA and dsRNA were purified, RNA species were resolved by electrophoresis and autoradiography, and RNA synthesis was quantitated by computer-assisted densitometry. The mutants representing all groups synthesized significantly less ssRNA and dsRNA at both 31 degrees and 39 degrees, when compared to wild type. When the ratio of synthesis at 39 degrees/31 degrees was determined for ssRNA and dsRNA of each mutant, three RNA synthesis phenotypes were evident. The tsB(339), tsC(606), and tsE(1400) mutants synthesized both ssRNA and dsRNA in a temperature-dependent manner. The group G mutant, tsG(2130), synthesized ssRNA in temperature-independent fashion but was temperature-dependent for the synthesis of dsRNA. The remaining mutants, tsA(778), tsD(975), tsF(2124), tsH(2384), tsI(2403), and tsJ(2131), synthesized both ssRNA and dsRNA in a temperature-independent fashion. The RNA synthesis phenotypes of the ts mutants are discussed in terms of what is known of the function(s) of the protein species to which ts lesions have been assigned.

Superinfecting rotaviruses are not excluded from genetic interactions during asynchronous mixed infections in vitro

Asynchronous infections of MA104 cells with temperature-sensitive (ts) mutants of simian rotavirus SA11 were performed to determine if the superinfecting ts mutant could contribute to the formation of reassortant progeny. Significant yields of ts+ reassortant progeny were obtained in crosses where infection with the first and second ts mutant was separated by as much as 24 hr, indicating that superinfecting viruses were not excluded from participation in genetic interactions. The practical and theoretical implications of this result are discussed.

Rotavirus genome segment 4 determines viral replication phenotype in cultured liver cells (HepG2)

One-step growth determinations were performed with five strains of rotavirus in HepG2, a cell line derived from human liver. Three virus strains (SA11-C13, SA11-C14, and RRV) replicated in HepG2 cells and attained yields 10- to 100-fold above input titers. Two virus strains (B223 and SA11-4F) failed to replicate above input titer. Analysis of reassortants that segregated the genes of parental virus pairs able and unable to replicate revealed that the HepG2 cell growth phenotype segregated with genome segment 4. Immunofluorescence analysis of infected HepG2 cells showed that the production of detectable antigen correlated with the growth phenotype and also segregated with genome segment 4. Thus, we conclude that (i) some virus strains were capable of replication in cultured liver cells while other strains could not replicate under identical conditions and that (ii) the inability of some virus strains to replicate resulted from a segment 4-associated block in replication before protein synthesis. These results are discussed in terms of what is known of the functions of VP4.

Asynchronous mixed infection of Culicoides variipennis with bluetongue virus serotypes 10 and 17

Culicoides variipennis (Diptera: Ceratopogonidae) the primary vector of bluetongue virus (BTV) in the U.S.A. were asynchronously mixedly infected with two BTV serotypes (BTV-10 and BTV-17); flies first ingested a blood meal that contained BTV-17 and 1, 3, 5, 7, and 9 days later selected flies ingested a second blood meal that contained BTV-10. Control flies ingested each parental virus separately, or both viruses simultaneously, in a single blood meal. Electrophoretic analysis of progeny virus clones indicated that superinfection with BTV-10 occurred when the flies ingested the second virus 1, 3 and 5 days post-initial infection. Parental BTV-17 and reassortant virus clones were isolated from these flies, but parental BTV-10 virus was not isolated from any flies. Reassortant clone frequencies were 67%, 71% and 17% when superinfection occurred on days 1, 3 and 5 after initial infection, respectively, as compared to 48% for simultaneously infected flies. Only parental BTV-17 clones were isolated from flies that ingested the second virus on days 7 and 9 after initial BTV-17 infection. The results indicated that interference to superinfection occurred in C. variipennis by 5 days and flies were refractory to superinfection by 7 days post-initial infection. Analysis of segregation of the parental origin of genome segments in the reassortant clones indicated selection against most segments of BTV-10 parental origin. This occurred both in individual flies and in individual groups. The fact that C. variipennis readily fed on a second blood meal and their ability to produce new viral genotypes suggested that these vectors are highly permissive hosts for evolution of BTV by genome reassortment.

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.

Analysis of reassortment and superinfection during mixed infection of Vero cells with bluetongue virus serotypes 10 and 17

The reassortment of genome segments during mixed infection of Vero cells with bluetongue virus (BTV) serotypes 10 and 17 was investigated, using non-selective conditions for analysis of the progeny of mixed infections. Reassortment was found to be an early event in the BTV replication cycle, indicating that progeny BTV genomes undergo a single round of reassortment. Non-random segregation of individual genome segments was observed in crosses at equal multiplicity of infection, and was confirmed in crosses performed at unequal multiplicity. Asynchronous infections showed that superinfection exclusion resulted in the failure of the superinfecting virus to contribute genome segments to reassortants if the second virus followed the first by more than 4 h. The significance of these results for the evolution and epidemiology of BTV is discussed.

Comparative studies of the antigenic polypeptide species VP4, VP6, and VP7 of three strains of bovine rotavirus

Three bovine rotavirus strains belonging to two distinct serotype groups, serotype 6 (NCDV and B641) and B223, distinct from the other six mammalian rotavirus serotypes but not yet assigned to a serotype group, were compared with each other and with canine rotavirus (K9, serotype 3) by studying the properties of their cognate polypeptide species VP4, VP6, and VP7. The three viruses showed distinct differences in the polyacrylamide gel electrophoretic migration rates of protein species VP4 and VP7, with minor differences in VP6. Differences were also observed among the migration patterns of genome segments 4, 6, and the 7-8-9 triplet, which encode VP4, VP6, and VP7, respectively. Monoclonal antibodies (MAbs) to B223, which were directed against VP4 or VP7, showed homologous specificity for neutralization and immunofluorescence (IF), although one MAb reactive with VP4 also reacted by IF and by immunoprecipitation (IP) with all four viruses and weakly neutralized B641 and K9. This MAb may react with the epitope responsible for the B223-induced one-way neutralizing and protection response of calves against B641 observed in earlier studies. MAbs reactive with VP6 by IP showed enzyme-linked immunosorbent assay and IF reactivity with all three bovine viruses and the canine virus. The two serotype 6 viruses could be distinguished by the two B641 MAbs, B641-N2b reacting by neutralization and IF with both viruses and B641-N1 reacting with B641 and the serotype 3 canine rotavirus but not with NCDV. One nonneutralizing B641 MAb reacted by IP and IF with VP7 of all four rotaviruses examined, and one B223 MAb neutralized B223 and, to low titer, B641 and K9 although reacting by IP and IF with all four viruses. Three MAb-resistant mutants were selected by passage of B223 in the presence of one of three selected B223 MAbs at concentrations which only neutralized approximately 90% of the infectious virions. The resulting mutants were 100% resistant to neutralization with their respective MAb but remained neutralizable by the same selection of MAbs as the parent B223 virus.

Phenotypes of rotavirus reassortants depend upon the recipient genetic background

We have previously characterized the biological and immunological properties of a simian rotavirus SA11 variant (4F) with an altered genome segment 4. The SA11-4F variant formed large plaques in the presence of protease, formed small clear plaques in the absence of protease, and grew to high titer in the presence of protease when compared to our standard wild type (SA11 clone 3). To determine the genome segment of the rotavirus SA11 variant 4F that encoded the unique protease-associated phenotypes of the variant, reassortants were generated that segregated the outer capsid genes of 4F onto a genetic background derived from either the bovine rotavirus B223 or our standard SA11 wild type (clone 3), both of which have contrasting protease-associated phenotypes. The parental and reassortant viruses were examined to determine which genes from the 4F variant encoded the ability (i) to form large plaques in the presence of protease, (ii) to form small clear plaques in the absence of exogenous protease, and (iii) to grow to significantly higher titer in the presence of protease. These phenotypes could be transferred to a clone 3 genetic background by a single genome segment from the 4F variant segment 4. However, in the 4F/B223 reassortants a different and unexpected situation was found. On a B223 genetic background the same phenotypes segregated with a combination of a minimum of two 4F genome segments, segments 4 and 9. These results indicate that the recipient genetic background onto which the genes of a donor rotavirus are reassorted can affect the phenotypes conferred by the presence of the donor segments. Thus, the results of segregation mapping experiments using reassortant viruses should be interpreted with caution.

Biological and immunological characterization of a simian rotavirus SA11 variant with an altered genome segment 4

We have studied a variant virus isolated from a stock of SA11 virus (H. G. Pereira, R. S. Azeredo, A. M. Fialho, and M. N. P. Vidal, 1984, J. Gen. Virol. 65, 815-818). This virus, designated 4F, was initially identified by its faster electrophoretic mobility for genome segment 4. The variant was analyzed to determine if the altered electrophoretic mobility of genome segment 4 could be correlated with phenotypic changes. Comparison of our standard laboratory SA11 virus (clone 3) with the 4F variant showed the following: (i) The 4F variant possesses a viral hemagglutinin (VP4) with a higher apparent molecular weight than clone 3. (ii) The 4F variant produces large plaques when assayed in vitro, as compared to clone 3. (iii) The 4F variant produces plaques in the absence of proteolytic enzymes, whereas clone 3 does not. (iv) The 4F variant reacts with serotype-specific neutralizing monoclonal antibodies to VP7, but fails to react with several neutralizing anti-VP4 monoclonal antibodies generated to SA11 clone 3. (v) The 4F variant grows to a higher titer and is more stable than clone 3. (vi) The 4F variant produces a VP4 that appears to be more susceptible to cleavage by trypsin than is the VP4 of clone 3. Further analyses with the 4F variant may lead to an understanding of the molecular basis for these altered phenotypes that appear to be related, at least in part, to the product of genome segment 4.

Studies on rotavirus homologous and heterologous active immunity in infant mice

Homologous and heterologous active immunity was studied in mice with mammalian group A rotaviruses. One day old mice were vaccinated with one of the following rotaviruses: bovine B641 (serotype 6), bovine B223 (untyped), simian SA11 (serotype 3) and murine EDIM (untyped). At 10 days of age they were challenged with EDIM virulent virus or SA11 virus. All the vaccines induced a serological antibody response in the mice but only the homologous immune response was protective.

The effects of host age, virus dose, and virus strain on heterologous rotavirus infection of suckling mice

Seven-day-old suckling CD-1 mice, born to seronegative dams, were orally inoculated with a number of animal and human rotaviruses. Simian (SA11), rhesus (RRV), and bovine (B223) rotaviruses were found to replicate and cause severe disease. Canine (K9), bovine (B641), and human (Wa) rotaviruses either replicated minimally and caused minimal disease (K9, B641) or failed to replicate or cause disease (Wa). The features of SA11 infection of mice were examined in greater detail. Suckling mice were susceptible to infection and disease from 1 day of age to 13-15 days of age. Restriction of disease occurred at an earlier age (13 days) than restriction of replication (15 days). Dose-response studies in seven-day-old mice showed that virus replication and disease could be induced with doses as low as 1 x 10(2) pfu/mouse; however, both intestinal virus titers and severity of disease increased in parallel with virus dose. Intestinal virus replication appeared to be restricted in SA11 infections. Only at very low doses (1 x 10(2) pfu/mouse) did virus replication occur to levels above the inoculated dose. While light microscopic examination showed classical features of rotavirus infection in the ileum, electron microscopic examination revealed only the accumulation of large numbers of electron-lucent vacuoles in the ileal enterocytes of infected mice. Structures typical of rotavirus morphogenesis were not detected in enterocytes from mice infected with rotavirus SA11.

Assignment of simian rotavirus SA11 temperature-sensitive mutant groups A, C, F, and G to genome segments

Crosses were performed between prototype temperature-sensitive (ts) mutants of simian rotavirus SA11 representing reassortment groups A, C, F, and G and ts mutants of rhesus rotavirus RRV that belonged to different reassortment groups. Wild-type (ts+) reassortant progeny were identified by plaque formation at nonpermissive temperature (39 degrees), picked, and grown to high titer. The ts+ phenotype of the resulting progeny clones was verified by titration at 39 degrees and 31 degrees. The electropherotypes of the ts+ clones were determined by electrophoresis, and parental origin of each genome segment was assigned by comparison of segment mobility to parental markers. Analysis of the parental origin of genome segments in the ts+ reassortants derived from SA11 ts X RRV ts crosses revealed the following map locations of the SA11 prototype ts mutants: tsA(778), segment 4; tsC(606), segment 1; tsF(2124), segment 2; and tsG(2130), segment 6. The assignment of tsA was made on the basis of genome segment segregation in two independent crosses with each of two independent RRV ts mutants. The assignment of tsC was made on the basis of segregation in only a single cross with an RRV ts mutant; however, a larger number of progeny clones were examined from this cross. The lesion of tsF was mapped with data from three independent crosses using two different RRV ts mutants. The assignment of tsG was made on the basis of segregation in three independent crosses, two with RRV ts mutants and one with Wa. The assignments of tsA, tsC, and tsF were confirmed in crosses between RRV ts mutants representing those reassortment groups, and SA11 ts mutants in other reassortment groups.

Mixed infection of Culicoides variipennis with bluetongue virus serotypes 10 and 17: evidence for high frequency reassortment in the vector

The primary vector species for bluetongue virus (BTV) in the United States, Culicoides variipennis, was orally infected with BTV serotype 10, BTV serotype 17, or a mixture of the two viruses. The recovery of virus from the infected flies was low following a period of extrinsic incubation. Electrophoretic analysis of progeny virus from singly infected flies revealed that only the parental electropherotype could be isolated from those flies. In contrast, electrophoretic analysis of virus from mixedly infected flies revealed that eight of the 11 virus-positive flies produced virus progeny with reassortant electropherotypes. The proportion of reassortant progeny varied from 7 to 78% (mean 42%), depending on the individual fly. Analysis of segregation of the parental origin of genome segments in the reassortant progeny virus suggested that, while reassortment of most segments was random, selection for genome segment 8 from the type 17 parent may have occurred. Analysis of segregation in individual mixedly infected flies showed that each fly yielded a relatively unique set of reassortants, but that specific electropherotypes were isolated repeatedly from individual flies. These data indicated that the vector species C. variipennis was a permissive host for high frequency reassortment of genome segments of BTV.

Protection between different serotypes of bovine rotavirus in gnotobiotic calves: specificity of serum antibody and coproantibody responses

In a previous study, different U.S. isolates of bovine rotavirus were studied for their serotypes and cross-protective properties (G. N. Woode, N. E. Kelso, T. F. Simpson, S. K. Gaul, L. E. Evans, and L. Babiuk, J. Clin. Microbiol. 18:358-364, 1983). Three viruses belonging to two different serotype groups were used as vaccines in gnotobiotic calves, which were subsequently challenged with B641 or B223, representing the two bovine serotypes. In the present work, the experiments were repeated with more calves and the specificity of their antibody responses was measured and compared with the results of the protection studies. Protection between different serotypes occurred under both homologous and heterologous conditions but was not directly serotype dependent. B223 virus showed both homologous and heterologous protection against B223 and B641 challenge viruses. This was a one-way reaction, as B641 did not induce protection against B223. Neonatal calf diarrhea virus vaccine produced neither homologous (against B641) nor heterologous (against B223) protection. The plaque reduction neutralization titers of serum antibody and coproantibody did not predict a state of protection against the challenge virus. Calves vaccinated with neonatal calf diarrhea virus or B641 developed neutralizing antibodies to their respective heterologous challenge viruses but were not protected. After challenge, the boosted coproantibody plaque reduction neutralization response to the original vaccine virus was greater than that to the challenge virus.

Analysis of mixed infection of sheep with bluetongue virus serotypes 10 and 17: evidence for genetic reassortment in the vertebrate host

Two seronegative sheep were infected intravenously with 10(9) PFU each of bluetongue virus (BTV) serotype 10 and BTV serotype 17. One animal experienced a mild bluetongue-like disease, and both experienced a short-duration viremia and developed neutralizing immune responses to both virus serotypes. Progeny virus was isolated from venous blood from each animal by using conditions in which reassortment could not have occurred during isolation. Electropherotypes were determined for the progeny viruses from the infected sheep, yielding strikingly similar results for the two animals. In both sheep, serotype 10 dominated among the progeny, accounting for 92% of the progeny. Serotype 17 was rarely isolated and accounted for 3% of the progeny analyzed. The remaining 5% of the progeny clones were reassortant and derived genome segments from both serotypes 10 and 17. Analysis of the parental origin of genome segments in the small number of reassortant progeny analyzed suggested that selection of specific genome segments may have occurred in the infected sheep. These data indicate that reassortment of genome segments occurs, at low frequency, in sheep mixedly infected with BTV.

Analysis of reassortment of genome segments in mice mixedly infected with rotaviruses SA11 and RRV

Seven-day-old CD-1 mice born to seronegative dams were orally inoculated with a mixture of wild-type simian rotavirus SA11 and wild-type rhesus rotavirus RRV. At various times postinfection, progeny clones were randomly isolated from intestinal homogenates by limiting dilution. Analysis of genome RNAs by polyacrylamide gel electrophoresis was used to identify and genotype reassortant progeny. Reassortment of genome segments was observed in 252 of 662 (38%) clones analyzed from in vivo mixed infections. Kinetic studies indicated that reassortment was an early event in the in vivo infectious cycle; more than 25% of the progeny clones were reassortant by 12 h postinfection. The frequency of reassortant progeny increased to 80 to 100% by 72 to 96 h postinfection. A few reassortants with specific constellations of SA11 and RRV genome segments were repeatedly isolated from different litters or different animals within single litters, suggesting that these genotypes were independently and specifically selected in vivo. Analysis of segregation of individual genome segments among the 252 reassortant progeny revealed that, although most segments segregated randomly, segments 3 and 5 nonrandomly segregated from the SA11 parent. The possible selective pressures active during in vivo reassortment of rotavirus genome segments are discussed.

Assignment of simian rotavirus SA11 temperature-sensitive mutant groups B and E to genome segments

Recombinant (reassortant) viruses were selected from crosses between temperature-sensitive (ts) mutants of simian rotavirus SA11 and wild-type human rotavirus Wa. The double-stranded genome RNAs of the reassortants were examined by electrophoresis in Tris-glycine-buffered polyacrylamide gels and by dot hybridization with a cloned DNA probe for genome segment 2. Analysis of replacements of genome segments in the reassortants allowed construction of a map correlating genome segments providing functions interchangeable between SA11 and Wa. The reassortants revealed a functional correspondence in order of increasing electrophoretic mobility of genome segments. Analysis of the parental origin of genome segments in ts+ SA11/Wa reassortants derived from the crosses SA11 tsB(339) X Wa and SA11 tsE(1400) X Wa revealed that the group B lesion of tsB(339) was located on genome segment 3 and the group E lesion of tsE(1400) was on segment 8.

Extragenic suppression of temperature-sensitive phenotype in reovirus: mapping suppressor mutations

Independently isolated, spontaneous pseudorevertants of temperature-sensitive (ts) mutants of reovirus type 3 have previously been genetically characterized (R. F. Ramig and B. N. Fields, 1979, Virology 92, 155-167). Eighteen of these pseudorevertants were backcrossed to wild-type reovirus type 1 and reassortant progeny expressing the parental ts phenotype were selected. Analysis of segregation of genome segments in the reassortant, parental ts, progeny clones allowed the determination of the genome segment bearing the suppressor mutation of four pseudorevertants. The suppressor of tsA(201) phenotype mapped to segment S4 in the pseudorevertants RtsA(201)101 and RtsA(201)121 and to segment L3 in pseudorevertant RtsA(201)122. The suppressor of tsB(352) phenotype mapped to segment S1 in the pseudorevertant RtsB(352)b. In two other pseudorevertants the suppressor could not be mapped to a single genome segment due to the small number of progeny clones examined. These genetic results indirectly support the "compensating protein interactions" hypothesis for the mechanism of suppression.

Characterization of temperature-sensitive mutants of simian rotavirus SA11: protein synthesis and morphogenesis

The synthesis of viral polypeptides, distribution of viral antigens, and morphogenesis of viral structures have been examined in cells infected with temperature-sensitive (ts) mutants of SA11 representing 10 recombination groups. At the permissive temperature (31 degrees C) the synthesis of viral polypeptides and the distribution of viral antigens did not differ significantly from those of the wild type. At the nonpermissive temperature (39 degrees C) some mutants (tsB, -C, -E, -F, and -G) synthesized significantly smaller amounts of viral polypeptides and had a very diffuse distribution of viral antigen. Several of the mutants synthesized one or more electrophoretically aberrant polypeptide species at both 31 and 39 degrees C. All of the mutants, except tsF, assembled morphogenetic intermediates at 39 degrees C. Aberrant intermediates were assembled in all mutants at 31 and 39 degrees C. No specific morphogenic defect could be associated with any of the ts mutants.

Isolation and genetic characterization of temperature-sensitive mutants that define five additional recombination groups in simian rotavirus SA11

Nineteen independent temperature-sensitive (ts) mutants were isolated from SA11 following mutagenesis with proflavin or 5-azacytidine. Fourteen of the ts mutants fell into one or another of five mutant groups previously defined by recombination. Five of the ts mutants defined five recombination groups (F, G, H, I, and J) that had not been previously identified. Thus, 10 of the 11 expected mutant groups have been identified in SA11. The prototype mutants of the 10 mutant groups were tested for recombination at nonpermissive temperature to determine if any group had a lesion affecting recombination. Most mutant pairs recombined efficiently; however, the tsH mutant was restricted in its recombination with the tsB and tsI mutants and the tsG and tsJ mutants failed to recombine at detectable levels at nonpermissive temperature. The mutants of groups F-J did not complement, or did so inefficiently, and interfered with the growth of wild type at both permissive and nonpermissive temperatures. The growth properties of the mutants of groups F-J are described.

Factors that affect genetic interaction during mixed infection with temperature-sensitive mutants of simian rotavirus SA11

A number of factors that affect genetic interaction during mixed infection with temperature-sensitive mutants of simian rotavirus SA11 have been examined. (1) Statistical analyses of recombination frequency (RF) indicated that (a) the variability noted in RF was not related to variations in experimental conditions and (b) a linear map of the mutations could not be drawn. (2) The wild phenotype of recombinant progeny was stable on passage. (3) Aggregates of progeny virus or heterozygous progeny virus particles did not contribute significantly to the observed RF. (4) RF increased in parallel with multiplicity of infection. (5) A maximal, or near maximal, RF was obtained at the earliest time significant recombinants could be detected. (6) Recombination was efficient at nonpermissive temperature. (7) Complementation did not occur or was inefficient. (8) Mutants from all recombination groups interfered with the growth of wild-type virus at both permissive and nonpermissive temperatures.

A genetic map of reovirus: assignment of the newly defined mutant groups H, I, and J to genome segments

Mutants representing three previously undefined reovirus type 3 mutant groups have been isolated following backcross of suppressed pseudorevertants to wild type (R.F. Ramig and B.N. Fields, 1979, Virology 92, 155-167; R. Ahmed, P.R. Chakraborty, A.F. Graham, R.F. Ramig, and B.N. Fields, 1980, J. Virol. 34, 383-389). The prototype mutant of each of the three new mutant groups was mapped by analysis of genome segment segregation in intertypic recombinants derived from crosses between the type 3 ts mutants and ts mutants of type 1 or type 2. Segregation analysis revealed the location of the group H prototype mutant tsH(26/8) to be genome segment M1, that of the group I prototype mutant tsI(138) to be segment L3, and that of the group J prototype mutant tsJ(128) to be segment S1. Mapping of the group I and J lesions required the identification of suppressed ts lesions in some of the intertypic rcombinant clones.

Genetic variation during persistent reovirus infection: presence of extragenically suppressed temperature-sensitive lesions in wild-type virus isolated from persistently infected L cells

Persistent reovirus infection of L cells was established with a serially passaged stock of temperature-sensitive (ts) mutant C(447) containing greater than 90% defective interfering particles. Within a month after establishment of the carrier culture, the ts mutant was replaced by virus that expressed the wild-type (ts(+)) temperature phenotype (R. Ahmed and A. F. Graham, J. Virol. 23:250-262, 1977). To determine whether the ts(+) phenotype of the virus was due to intragenic reversion or to the presence of an extragenic mutation suppressing the original ts defect, several clones were backcrossed to wild-type reovirus, and the progeny of each cross were screened for temperature sensitivity. The results indicated that the original tsC lesion had reverted. However, in two of the seven clones examined, new ts lesions were found. These new ts lesions appeared phenotypically as ts(+) due to the presence of extragenic suppressor mutations. Temperature-sensitive mutants representing three different groups were rescued from one suppressed clone, indicating that this ts(+) clone contained multiple ts lesions. Among the ts mutants rescued were the initial isolates of a new recombination group which we have designated H. Some of the ts mutants rescued from the suppressed clones are capable of interfering with the growth of wild-type reovirus and may play a role in maintaining the carrier state. The results of this study show that persistently infected L cells contain a genetically heterogeneous population of reovirus even though all virus clones express the ts(+) phenotype. It is thus critical to distinguish between genotype and phenotype when analyzing viruses that emerge during persistent infection.