Sequence analysis of rotavirus YM VP6 and NS28 proteins

Avian-to-mammal transmission of an avian rotavirus: analysis of its pathogenicity in a heterologous mouse model

It has been suggested that group A avian rotaviruses can be transmitted to mammals, but there is no direct evidence that such viruses induce disease in mammals. Suckling mice were orally inoculated with two avian rotaviruses. A pigeon rotavirus, PO-13, was found to induce diarrhea, but a turkey rotavirus, Ty-3, did not. The diarrhea induced by PO-13 was dependent on the age of the mouse. In histopathological examinations, antigens of PO-13 were sporadically detected in absorptive cells in the ileum, and lesions were observed as ballooning degenerations of absorptive cells in a region from the duodenum to the ileum. However, the rotavirus antigen was not detected in the majority of these degenerative cells. These results indicated that PO-13 could infect and induce diarrhea in suckling mice. This is the first evidence of an avian rotavirus being experimentally transmissible to a mammal.

Antigenic and molecular analyses reveal that the equine rotavirus strain H-1 is closely related to porcine, but not equine, rotaviruses: interspecies transmission from pigs to horses?

We have sequenced the genes encoding the inner capsid protein VP6 and the outer capsid glycoprotein VP7 of the subgroup (SG) I equine rotavirus strain H-1 (P9[7], G5). The VP6 and VP7 proteins of the equine rotavirus strain H-1 shared a high degree of sequence and deduced amino acid identity with SG I porcine strains and serotype G5 porcine strains, respectively. Previous sequence analyses of the genes encoding the outer capsid spike protein VP4 and the nonstructural proteins NSP1 and NSP4 of equine H-1 strain also revealed a high degree of sequence and deduced amino acid homology with the prototype porcine rotavirus strain OSU (P9[7], G5). We have also confirmed and extended the VP4 and VP7 antigenic relatedness of equine rotavirus strain H-1 to porcine strains of P9[7] and G5 serotype specificities isolated in the United States, Venezuela, Argentina, and Australia based on cross-neutralization studies. In addition, the pathogenicity of tissue culture-adapted equine H-1, H-2, FI-14, FI-23, and L338, and porcine OSU rotavirus strains was compared in the neonatal mouse model. The 50% diarrhea dose (DD50) of equine H-1 was similar to that of porcine OSU and equine H-2 and L338 strains, while the DD50 of equine H-2 was > or = 50 or 315-fold lower than those of equine FI-14 or FI-23, respectively. Our sequence comparison of NSP4 of the rotavirus strains tested potentially identified amino acid residue 136, within the variable region spanning amino acids 130 to 141, as playing a role in virulence. Taken together, there is strong support to suggest that the equine rotavirus strain H-1 may represent an example of interspecies transmission from pigs to horses.

Diarrhea induction by rotavirus NSP4 in the homologous mouse model system

Comparison of the NSP4 amino acid sequences from 31 strains of mammalian rotaviruses revealed the presence of four distinct NSP4 alleles; i.e., the Wa, KUN, AU-1, and EW alleles. The EW allele consists only of NSP4s from murine rotavirus strains and is divergent from other NSP4 alleles from the evolutionary perspective. There have been conflicting reports regarding the enterotoxigenic activity of NSP4 in the mouse model system; heterologous simian and porcine rotavirus NSP4s function as an enterotoxin in mice, while a homologous EC NSP4 does not play a dominant role as an enterotoxin in the cystic fibrosis conductance regulator knockout mice. To further examine the enterotoxigenic activity of NSP4, we expressed in Escherichia coli a recombinant protein consisting of glutathione S-transferase and amino acid residues 86-175 of the EW NSP4. We found that this fusion protein caused diarrhea in the majority (8/14) of 5- to 6-day-old CD1 mice. This study confirmed and extended that group A rotavirus NSP4s were able to induce diarrhea in neonatal mice and had an enterotoxigenic activity.

Sequence analysis demonstrates that VP6, NSP1 and NSP4 genes of Indian neonatal rotavirus strain 116E are of human origin

We have sequenced the genes encoding the inner capsid protein VP6 and the nonstructural proteins NSP1 and NSP4 of the Indian neonatal serotype P8[11]G9 human/bovine reassortant candidate vaccine rotavirus strain 116E. These three genes share a high degree of sequence and deduced amino acid homology with human prototype strain Wa. Our results confirm and extend those of previous RNA-RNA hybridization studies which suggested that these genes are of human origin, and will facilitate examination of the host immune response to 116E induced by natural infection and vaccination.

Comparison of the rotavirus gene 6 from different species by sequence analysis and localization of subgroup-specific epitopes using site-directed mutagenesis

The nucleotide sequence of gene 6 encoding the rotavirus major capsid protein VP6 of EDIM strain (EW) was determined and compared to that of 20 previously reported strains with known subgroup specificities. Multiple alignments of amino acid sequences exhibited a high level of sequence conservation (87 to 99.2%). Site-specific mutagenesis experiments were undertaken to localize regions involved in subgroup specificity. Amino acid positions 305, 315, and a region 296-299 (or 301 for equine strain H-2) were identified as contributing to subgroup epitopes. A single amino acid mutation at position 305 or 315 was sufficient to change the subgroup specificity of EW VP6 protein from non I/II to subgroup I- or subgroup II-like, respectively. Mutation at these sites may be another important mechanism for subgroup variation, along with gene reassortment.

Genetic characterization of the rotavirus nonstructural protein, NSP4

The rotavirus nonstructural protein NSP4 plays a role in viral assembly by acting as an intracellular receptor for single-shelled particles and assisting in the translocation of these particles across the endoplasmic reticulum. Recently, NSP4 has been implicated in rotavirus virulence and is thought to act as an enterotoxin which triggers chloride secretion by a calcium-dependent signal transduction pathway. Limited sequence analysis of NSP4 shows a well-conserved protein. To define the extent of sequence variation in the gene coding for NSP4, we have sequenced this gene from nine human rotavirus strains. These data and the analysis of additional human strains and various animal rotaviruses (bovine, simian, equine, and porcine) by Northern blot hybridization suggested that three NSP4 genotypes were present among rotavirus strains. A correlation between NSP4 genotype and VP6 subgroup was also implied. Two different NSP4 genes (which encoded distinct types of NSP4 proteins) were found among standard human rotaviruses and in strains circulating in the local community and these showed homology to cognate genes in some animal strains.

Attenuation of a human rotavirus vaccine candidate did not correlate with mutations in the NSP4 protein gene

The NSP4 protein of a simian rotavirus was reported to induce diarrhea following inoculation of mice. If NSP4 is responsible for rotavirus diarrhea in humans, attenuation of a human rotavirus may be reflected in concomitant mutations in the NSP4 gene. After 33 passages in cultured monkey kidney cells, a virulent human rotavirus (strain 89-12) was found to be attenuated in adults, children, and infants. Nucleotide sequence analysis of the NSP4 protein gene revealed only one base pair change between the virulent (unpassaged) and attenuated 89-12 viruses, which resulted from a substitution of alanine for threonine at amino acid 45 of the encoded NSP4 protein. Because both threonine and alanine have been found at position 45 of NSP4 in symptomatic and asymptomatic human rotaviruses, neither amino acid in this position could be established as a marker of virulence. Therefore, attenuation of rotavirus strain 89-12 appears to be unrelated to mutations in the NSP4 gene.

Sequence analysis of the VP6 gene in group A turkey and chicken rotaviruses

cDNAs corresponding to the VP6 gene of the turkey rotavirus strains Ty-1 and Ty-3, and the chicken rotavirus strain Ch-1, were cloned and sequenced. The nucleotide and deduced amino acid sequence homology in the coding region of the VP6 gene in avian rotaviruses ranged from 78.1 to 93.9% and 86.1 to 98.7%, respectively. Both sequences of VP6 from avian rotaviruses exhibited a low degree of sequence homology (67.8-70.7% and 69.8-74.6%, respectively) compared with mammalian rotaviruses. Phylogenetic tree analysis showed that all avian rotaviruses were included in a single cluster and have separated early or from mammalian rotaviruses during evolution. The chicken rotavirus strain Ch-1 was a distant relative of other avian rotaviruses.

Identification of a T-helper cell epitope on the rotavirus VP6 protein

In this work, we have studied the T-helper (Th)-cell response against rotavirus, in a mouse model. Adult BALB/c mice were inoculated parenterally with porcine rotavirus YM, and the Th-cell response from spleen cells against the virus and two overlapping fragments of the major capsid protein VP6 (VP6(1-192) and VP6(171-397)) were evaluated in vitro. The Th cells recognized the YM virus and the two protein fragments, suggesting that there are at least two Th-cell epitopes on the VP6 molecule. To study the specificity of Th cells against VP6 at the clonal level, we established two Th-cell hybridomas cross-reactive for the VP6 protein of rotavirus strains YM and SA11. Both hybridomas recognized the VP6(171-397) polypeptide, and a synthetic peptide comprising the amino acids 289 to 302 (RLSFQLVRPPNMTP) of YM VP6 in the context of the major histocompatibility complex class II IEd molecule. The Th-cell hybridomas recognized rotavirus VP6 in a highly cross-reactive fashion, since they could be stimulated by eight different strains of rotavirus, including the murine rotavirus EDIM, that represent five G serotypes and at least two subgroups. The amino acid sequence of the VP6 epitope is highly conserved in most group A rotavirus strains sequenced so far. On the other hand, it was found that Th cells specific for the VP6 epitope may constitute an important proportion of the total polyclonal Th-cell response against rotavirus YM in spleen cells. These results demonstrate that VP6 can be a target for highly cross-reactive Th cells.

Molecular characterization of the 11th RNA segment from human group C rotavirus

The complete nucleotide sequence of genome segment 11 from the noncultivatable, human group C rotavirus (Bristol strain) was determined. Comparison of the nucleotide sequence of the segment termini with the consensus 5' and 3' terminal noncoding sequences of the human group C rotavirus genome revealed characteristic 5' and 3' sequences. Human group C rotavirus genome segment 11 is 613 bp long and encodes a single open reading frame of 450 nucleotides (150 amino acids) starting at nucleotide 39 and terminating at nucleotide 489, leaving a long 3' untranslated region of 124 nucleotides. The predicted translation product has a calculated molecular weight of 17.7 kD and contains four potential N-linked glycosylation sites. No significant homologies to other viral proteins were found in database searches. Hydropathy analysis predicted the human group C rotavirus genome segment 11 translation product has a hydrophilic carboxy terminus (amino acids 54-150) and a hydrophobic amino terminus (amino acids 1-53) that can be further subdivided into three short hydrophobic sequences--H1, H2, and H3. These features are analogous to the integral membrane glycoprotein NSP4 encoded by group A rotavirus gene 10.

Sequence analysis of cDNA for the VP6 protein of group A avian rotavirus: a comparison with group A mammalian rotaviruses

cDNA corresponding to the genomic segment 6 of avian rotavirus strain PO-13, which has group A common and subgroup I antigens, but does not hybridize in Northern blots with RNA probes from group A mammalian rotaviruses, was cloned and sequenced. When the deduced amino acid sequence was compared between strain PO-13 and eight group A mammalian rotaviruses, the extent of homology ranged from 73-75%. An alignment of the amino acid sequences allowed us to identify three amino acids (Positions 120, 317 and 350) that may contribute to determining the subgroup epitopes. A phylogenetic tree constructed on the basis of nucleotide substitutions in the VP6 gene of nine rotaviruses strongly suggests that the avian rotavirus is an ancestral prototype of mammalian rotaviruses.