Nucleotide sequence of gene 5 encoding the inner capsid protein (VP6) of bovine group C rotavirus: comparison with corresponding genes of group C, A, and B rotaviruses

Intragenic recombination influences rotavirus diversity and evolution

Because of their replication mode and segmented dsRNA genome, homologous recombination is assumed to be rare in the rotaviruses. We analyzed 23,627 complete rotavirus genome sequences available in the NCBI Virus Variation database, and found 109 instances of homologous recombination, at least eleven of which prevailed across multiple sequenced isolates. In one case, recombination may have generated a novel rotavirus VP1 lineage. We also found strong evidence for intergenotypic recombination in which more than one sequence strongly supported the same event, particularly between different genotypes of segment 9, which encodes the glycoprotein, VP7. The recombined regions of many putative recombinants showed amino acid substitutions differentiating them from their major and minor parents. This finding suggests that these recombination events were not overly deleterious, since presumably these recombinants proliferated long enough to acquire adaptive mutations in their recombined regions. Protein structural predictions indicated that, despite the sometimes substantial amino acid replacements resulting from recombination, the overall protein structures remained relatively unaffected. Notably, recombination junctions appear to occur nonrandomly with hot spots corresponding to secondary RNA structures, a pattern seen consistently across segments. In total, we found strong evidence for recombination in nine of eleven rotavirus A segments. Only segments 7 (NSP3) and 11 (NSP5) did not show strong evidence of recombination. Collectively, the results of our computational analyses suggest that, contrary to the prevailing sentiment, recombination may be a significant driver of rotavirus evolution and may influence circulating strain diversity.

Canine rotavirus C strain detected in Hungary shows marked genotype diversity

Species C rotaviruses (RVC) have been identified in humans and animals, including pigs, cows and ferrets. In dogs, RVC strains have been reported anecdotally on the basis of visualization of rotavirus-like virions by electron microscopy combined with specific electrophoretic migration patterns of the genomic RNA segments. However, no further molecular characterization of these viruses was performed. Here, we report the detection of a canine RVC in the stool of a dog with enteritis. Analysis of the complete viral genome uncovered distinctive genetic features of the identified RVC strain. The genes encoding VP7, VP4 and VP6 were distantly related to those of other RVC strains and were putatively classified as G10, P8 and I8, respectively. The new strain was named RVC/Dog-wt/HUN/KE174/2012/G10P[8]. Phylogenetic analyses revealed that canine RVC was most closely related to bovine RVC strains with the exception of the NSP4 gene, which clustered together with porcine RVC strains. These findings provide further evidence for the genetic diversity of RVC strains.

Phylogenetic characterization of VP6 gene (inner capsid) of porcine rotavirus C collected in Japan

Porcine rotavirus C (RVC) has been often detected in sporadic cases or outbreaks of diarrhea in suckling and weaned pigs. Previous surveillance studies using both enzyme-linked immunosorbent assays and reverse-transcription polymerase chain reaction in some countries including Japan and the United States have demonstrated a high prevalence of porcine RVCs. In order to understand the phylogenetic relatedness of RVCs, we performed genetic analysis of VP6 gene encoding inner capsid protein by using 22 porcine RVC strains collected in Japan from 2002 to 2010. Comparative analyses of the VP6 nucleotide and amino acid sequences from these porcine RVCs exhibited lower sequence identities than those from human and bovine RVCs. The phylogenetic analysis of VP6 gene of RVC indicated the presence of seven clusters (tentatively assigned I1-I7) according to host species with cut-off values of 87% at the nucleotide level, and VP6 genes of porcine RVCs were divided into five genotypes. These findings indicate that multiple porcine RVC strains with distinctive genotypes are broadly spreading and circulating among farms in Japan. Our data may provide important insights in understanding evolutionary dynamics of RVCs.

Whole-genome analysis of two bovine rotavirus C strains: Shintoku and Toyama

Rotavirus C (RVC) has been detected frequently in epidemic cases and/or outbreaks of diarrhoea in humans and animals worldwide. Because it is difficult to cultivate RVCs serially in cell culture, the sequence data available for RVCs are limited, despite their potential economical and epidemiological impact. Although whole-genome sequences of one porcine RVC and seven human RVC strains have been analysed, this has not yet been done for a bovine RVC strain. In the present study, we first determined the nucleotide sequences for five as-yet underresearched genes, including the NSP4 gene, from a cultivable bovine RVC, the Shintoku strain, identified in Hokkaido Prefecture, Japan, in 1991. In addition, we elucidated the ORF sequences of all segments from another bovine RVC, the Toyama strain, detected in Toyama Prefecture, Japan, in 2010, in order to investigate genetic divergence among bovine RVCs. Comparison of segmental nucleotide and deduced amino acid sequences among RVCs indicates high identity among bovine RVCs and low identity between human and porcine RVCs. Phylogenetic analysis of each gene showed that the two bovine RVCs belong to a cluster distinct from human and porcine RVCs. These data demonstrate that RVCs can be classified into different genotypes according to host species. Moreover, RVC NSP1, NSP2 and VP1 amino acid sequences contain a unique motif that is highly conserved among rotavirus A (RVA) strains and, hence, several proteins from bovine RVCs are suggested to play important roles that are similar to those of RVAs.

Detection of Group C Rotavirus in Juvenile Ferrets (Mustela putorius furo) with Diarrhea by Reverse Transcription Polymerase Chain Reaction: Sequencing and Analysis of the Complete Coding Region of the VP6 Gene

Nine juvenile ferrets ( Mustela putorius furo) with a history of diarrhea were severely dehydrated and had distended abdomens and thin-walled small intestines that contained gas and fluid. Histologically, small intestines exhibited acute superficial atrophic enteritis. Transmission electron microscopy of the small intestine showed rotavirus-like particles within apical vacuoles. Reverse transcription polymerase chain reaction (RT-PCR) was negative for group A rotavirus. A group C rotavirus-specific RT-PCR assay was developed using consensus primers designed from the alignment of VP6 gene sequences of porcine, bovine, and human strains. A 182-bp product of the VP6 gene was sequenced and showed significant similarity to group C rotavirus VP6 sequences. This strain was designated “Ferret Rota C-MSU.” The entire coding sequence of VP6 was determined and compared with other rotaviruses. Ferret Rota C-MSU virus was found to be most closely related to Shintoku group C rotavirus. This is the first definitive identification of a group C rotavirus in ferrets, based upon RT-PCR, sequencing, and genetic analysis.

Detection of a bovine group C rotavirus from adult cows with diarrhea and reduced milk production

Only two strains (Shintoku and porcine-like WD534tc) of group C rotavirus (GCR) from cattle have been reported to date. A GCR designated the Yamagata strain was the only pathogen detected in an outbreak of adult cow diarrhea accompanied by a decrease in milk production. The nucleotide sequences of the VP6 and VP7 genes from strain Yamagata were determined. Comparative sequence analysis showed that the sequence identities between strains Yamagata and Shintoku were markedly high in both VP6 gene (98.1%) and VP7 gene (93.5%), and that these strains belonged to the same clusters which were distinguished from GCRs from different host species in phylogenetic trees of these genes. These results suggested strongly that cattle species is one of the natural hosts of GCR infection, and that GCRs are a cause of adult cow diarrhea.

Identification of rotavirus VP6 residues located at the interface with VP2 that are essential for capsid assembly and transcriptase activity

Rotavirus has a complex triple-layered icosahedral capsid. The external layer consists of VP7 and VP4, the intermediate layer consists of VP6 trimers, and the internal layer consists of VP2. Double-layered particles (DLP) derived from the virus by solubilization of VP4 and VP7 are transcriptionally competent and extrude capped mRNA from their vertices. Analysis of the pseudoatomic model of the VP6 layer, obtained by placing the atomic structure of VP6 into electron microscopy reconstructions of the DLP, has identified the regions of the protein involved in interactions with the internal layer. To study the role of VP6 both in the assembly of DLP and in transcription, 13 site-specific substitution mutations of VP6, targeting the contacts between the two inner layers, were constructed and expressed in the baculovirus system. The effects of these mutations on VP6 expression, trimerization, and formation of macromolecular assemblies were investigated. Using either in vitro reconstituted DLP derived from purified viral cores and recombinant VP6 or in vivo self-assembled virus-like particles resulting from the coexpression of VP2 and VP6 in the baculovirus-Sf9 system (VLP2/6), we have identified the amino acids essential for recovery of transcription or assembly. All VP6 mutants formed stable trimers which, like wild-type VP6, assembled into tubular structures. The ability of VP6 to interact with VP2 was examined by several assays, including electron microscopy, coimmunoprecipitation, purification of VLP2/6, and monitoring of the transcriptase activity of reconstituted DLP. Of the 13 VP6 mutants examined, 3 were unable to assemble with VP2 and 3 others partially assembled. These mutants either did not rescue the transcriptase activity of core particles or did so only marginally. Four mutants as well as the wild-type VP6 assembled and transcribed very well. Three mutants assembled well on cores but, surprisingly, did not rescue the transcriptase activity of reconstituted DLP. Our results indicate that hydrophobic interactions between VP6 and VP2 residues are responsible for the stability of the DLP. They also show that subtle electrostatic interactions between VP6 and the underlying transcriptase machinery can be essential for mRNA synthesis.

Dual infection of gnotobiotic calves with bovine strains of group A and porcine-like group C rotaviruses influences pathogenesis of the group C rotavirus

There is serological evidence that bovine group C rotaviruses exist in the United States, but there are no reports of their isolation. Ninety fecal samples from calves with diarrhea, 81 samples from adult cows with diarrhea (winter dysentery), and 20 fecal samples from healthy adult cows were tested for group C rotaviruses by polyacrylamide gel electrophoresis, immune electron microscopy, and reverse transcription-PCR (RT-PCR). Three samples from adult cow diarrhea cases were positive only by RT-PCR, and a group C rotavirus was isolated from a positive sample in monkey kidney (MA104) cells (WD534tc/C). Genetically and serologically, the WD534tc/C strain was more closely related to the Cowden porcine group C strain than to the Shintoku bovine strain. Because the original cow feces also contained a group A rotavirus (detected after passage in cell culture), we hypothesized that such dual-rotavirus infections might play a role in the pathogenesis and host adaptation of rotaviruses. Thus, we examined the pathogenesis of WD534tc/C alone or combined with virulent (IND/A) or attenuated (NCDV/A) bovine group A rotaviruses in gnotobiotic calves. WD534tc/C alone induced diarrhea without (or with limited) virus shedding in inoculated calves (n = 3). In contrast, all calves coinfected with WD534tc/C and IND/A (n = 2) developed diarrhea and shed both viruses, whereas calves coinfected with WD534tc/C and NCDV/A (n = 3) developed diarrhea but did not shed either virus. Infection with WD534tc/C or NCDV/A alone caused only mild villous atrophy (jejunum and/or ileum), whereas dual infection with both viruses induced lesions throughout the small intestine. Although IND/A alone caused villous atrophy, more-widespread small intestinal lesions occurred in calves coinfected with WD534tc/C and IND/A. In conclusion, coinfection of calves with group A rotaviruses enhanced fecal shedding of a bovine group C rotavirus and the extent of histopathological lesions in the small intestines. Thus, our findings suggest a potential novel hypothesis involving dual infections for the adaptation of heterologous rotaviruses to new host species.

Infection with group C rotavirus in a suburban community in Brazil

Group C rotaviruses are associated with sporadic outbreaks of gastroenteritis worldwide. Age-specific seroprevalence of group C rotavirus antibodies was investigated in sera, randomly collected and representative of a suburban community in Brazil which had previously been screened for group A rotavirus antibodies. Antibody prevalence to group C rotavirus was low in children under 5 years and increased slowly with age to 36% seropositivity in adults, reflecting continuous exposure to primary infection in all age groups. This suggests a higher incidence of infection than disease might predict. Adult antibody prevalence was similar to that in other geographical settings. No obvious patterns of infection with group A and group C rotavirus were found within individuals, which suggests independent transmission. However, further epidemiological studies are required to understand group C rotavirus dynamics and possible interactions with group A rotavirus transmission and immunity.

Seroepidemiology of human group C rotavirus in the UK

The gene coding for the major inner capsid protein VP6 of human group C rotavirus was cloned into baculovirus using the pBlueBac2 vector and expressed in insect cells. When cultured in High Five cells, VP6 was expressed at a high level and exported to the cell culture medium. Purified VP6 was used to immunise rabbits. Hyperimmune rabbit serum, which reacted with native human group C rotavirus in infected cells, was used to develop and optimise an EIA for the detection of antibodies to group C rotavirus using the recombinant VP6 as a source of antigen. In a local epidemiological survey of 1000 sera grouped by age, an average of 43% of samples were found to have antibodies to human group C rotavirus with the highest proportion (66%) in the 71-75 year age group. In comparison, 97% of adults and 85% of children had antibodies to recombinant VP6 from the bovine RF strain of group A rotavirus. These results suggest that infection with human group C rotavirus is a common occurrence despite the apparent rarity of reports of human group C rotavirus in clinical samples from patients with gastroenteritis.

Sequence comparison of the VP7 gene encoding the outer capsid glycoprotein among animal and human group C rotaviruses

The nucleotide sequences of the outer capsid glycoprotein (VP7) genes from the Shintoku bovine and the HF and WH porcine group C rotaviruses were determined and compared with those of the published corresponding genes from the Cowden porcine and Ehime human group C rotaviruses. The VP7 genes of all 5 strains were 1063 nucleotides in length and possess one open reading frame encoding a polypeptide of 332 amino acids. Comparative analysis of the deduced amino acid sequences indicated that 85.2-97.0% identity was observed for the VP7 of the serotypically related strains of group C rotaviruses (Cowden, WH and Ehime) whereas 69.9-74.7% identity was observed among the serotypically distinct strains (Shintoku; Cowden, WH and Ehime; and HF). At least 8 variable regions in the VP7 were recognized among serotypically distinct strains, and these locations were similar to those of the variable regions in the VP7 of group A rotaviruses.

Sequence conservation and expression of the gene encoding the outer capsid glycoprotein among human group C rotaviruses of global distribution

Group C rotaviruses have been identified recently from fecal samples of children with diarrhea in the United States. Using reverse transcriptasepolymerase chain reaction and sequence analysis, we sequenced gene 8s encoding VP7 from two U.S. strains (RI-1 and RI-2), and eight other strains isolated from patients on four continents, and compared these with the sequences of four published strains. The gene 8s of the 14 strains were remarkably conserved in size and in predicted primary and secondary structures. When the sequences of the human VP7s were compared with that of the prototype porcine Cowden strain, six regions were found variable in both deduced primary and predicted secondary structures, four of which were predicted to be hydrophilic and might determine serotype specificity. Gene 8 of the human S-1 strain was further characterized by expression in recombinant baculoviruses. The expressed product was immunogenic but failed to elicit neutralizing antibodies. Our sequence analysis indicates that all the human strains characterized to date belong to a single G genotype, which may constitute a single G serotype, pending further antigenic analysis. Whether the human strains and the Cowden strain are the same serotype remains to be determined.