Isolation and molecular characterization of a serotype 9 human rotavirus strain.

A human rotavirus strain, designated AU32, that belongs to serotype 9 was isolated and was compared by RNA-RNA hybridization with recently established two serotype 9 strains (WI61 and F45) as well as other prototype human strains. These three strains exhibited a very high degree of homology with one another and shared a high degree of homology with strains belonging to the Wa genogroup but not with strains belonging to either the DS-1 or AU-1 genogroup. These results suggest that genetic constellation of the serotype 9 strains is similar to that of the commonest human rotavirus despite the recent recognition of this serotype.     

Molecular Characterization of Human Rotavirus VP4 Genes by Polymerase Chain Reaction and Restriction Fragment Length Polymorphism Assay

A restriction fragment length polymorphism (RFLP) assay was developed to examine the genetic variability and similarity of the VP4 genes of human rotaviruses. The VP4 genes of 14 human rotavirus strains, including VP4 serotype P1A strains (Wa, P, VA70), serotype P1B strain (DS-1), serotype P2 strains (M37, 1076, McN, ST3) and serotype P3 strains (AU-1, AU228, K8, PA151, PCP5, MZ58), and those of 2 feline strains (FRV-1 and Cat2) were reverse-transcribed and amplified by the polymerase chain reaction (PCR). The amplified VP4 cDNAs were then digested with a panel of restriction endonucleases (HindIII, NruI, HaeIII, and EcoRI), resulting in the identification of at least one enzyme with which digestion produced an RFLP profile specific for a particular P serotype. Of interest was the presence of two distinct RFLP patterns within the serotype P3 VP4 genes: one corresponding to the VP4 gene carried by the members of the AU-1 genogroup and the other corresponding to the VP4 genes carried by naturally-occurring reassortants between members of the AU-1 and other genogroups.     

RNA-RNA hybridization identifies a human rotavirus that is genetically related to feline rotavirus.

A human rotavirus AU228 strain which resembled the AU-1 strain (O. Nakagomi, T. Nakagomi, Y. Hoshino, J. Flores, and A. Z. Kapikian, J. Clin. Microbiol. 25:1159-1164, 1987) in its novel characteristics (that it belonged to subgroup I yet possessed a long RNA pattern) was compared with various human and animal strains by RNA-RNA hybridization in solution. This strain showed a high degree of homology with the AU-1 strain but not with either the Wa (subgroup II, long pattern) or the KUN (subgroup I, short pattern) strain, indicating the presence of an additional group of human rotaviruses that do not belong to either of the two human rotavirus families previously identified by RNA-RNA hybridization. It is of particular interest that the AU228 strain showed an unexpectedly high degree of homology with a feline rotavirus isolated recently in Japan. These results indicate transmission of a feline rotavirus to humans and suggest a role of animal rotaviruses in the evolution of human rotaviruses.     

A candidate for a new serotype of human rotavirus

We investigated genetic and serological characteristics of a human rotavirus isolate from Indonesia which had a "super short" RNA electrophoretic pattern (A. Hasegawa, S. Inouye, S. Matsuno, K. Yamaoka, R. Eko, and W. Suharyono, Microbiol. Immunol. 28:719-722, 1984). This virus, strain 69M, was found by RNA-RNA hybridization to have a low degree of homology with the representative strains of all four human serotypes. Furthermore, it could not be classified by neutralization analysis into any of these serotypes. Therefore, this virus might belong to a new serotype.     

Genogroup characterization of reemerging serotype G9 human rotavirus strain 95H115 in comparison with earlier G9 and other human prototype strains

Serotype G9 human rotaviruses have emerged globally since the mid-1990s. The 95H115 strain was derived from a stool specimen collected in Japan in the 1994-95 season, thus it is the earliest of the globally reemerging G9 human rotaviruses that were adapted to cell culture. Genogrouping by RNA-RNA hybridization was performed to examine the genetic background of 95H115. The 95H115 strain belonged to the Wa genogroup, the most common human rotavirus genogroup, and it had a high degree of homology with AU32 and WI61, the prototype G9 isolates in the 1980s. However, the divergent genomic RNA constellation as indicated by the aberrant hybridization patterns between 95H115 and earlier G9 strains served as further evidence that 95H115 was not a direct descendant of the prototype strains in the '80s.     

Serological characterization of human reassortant rotaviruses.

We analyzed the serological properties of two human wild-type cell culture-adapted rotaviruses (strains 308 and 46) and of 308 X 46 reassortants which were previously obtained and genetically characterized. Strain 308, exhibiting a so-called long RNA pattern, was found to belong to human rotavirus subgroup II, serotype 1, whereas strain 46, exhibiting a so-called short RNA pattern, represented subgroup I, serotype 2. Among the 308 X 46 reassortants we analyzed, two belonged to subgroup II, serotype 1, and exhibited short RNA patterns. This showed that the correlation observed between human subgroups I and II rotaviruses and the short and long electrophoretic patterns is not supported by any molecular basis (i.e., gene segment 10 or 11 was not involved in the subgroup specificity).     

轮状病毒RNA基因图谱变异分析

用聚丙烯酰胺凝胶电泳法对轮状病毒(RV)标准株进行RNA基因图谱分析,发现人轮状病毒(HRV)Wa株在MA104细胞上连续传5代后,其RNA基因图谱由原来的4:2:3:2模式变为4:3:3:2模式。继续分别在CV-1、MA104细胞上传代后,基因图谱进一步演变为4:3:4:2模式。经比较电泳、病毒空斑纯化,初步证实RVWa有变异林存在。目前尚未见RV标准株变异的报告,有待进一步研究。同时对多个RV标准株及1939年南京市区婴幼儿秋季腹泻的RV流行株进行基因图谱分析,发现不同的人RV及牛RV标准株有相同的基因图谱;不同实验室来源的同一标准株有不同的基因图谱。此外,尚证实HRV是1989年南京市区婴幼儿秋季腹泻的主要病源,总检出率45.1％,电泳长型为流行优势株89.2％。本文尚对RV RNA基因图谱变异的原因及意义进行了讨论。     

Group A human rotavirus genomics: evidence that gene constellations are influenced by viral protein interactions

Group A human rotaviruses (HRVs) are the major cause of severe viral gastroenteritis in infants and young children. To gain insight into the level of genetic variation among HRVs, we determined the genome sequences for 10 strains belonging to different VP7 serotypes (G types). The HRVs chosen for this study, D, DS-1, P, ST3, IAL28, Se584, 69M, WI61, A64, and L26, were isolated from infected persons and adapted to cell culture to use as serotype references. Our sequencing results revealed that most of the individual proteins from each HRV belong to one of three genotypes (1, 2, or 3) based on their similarities to proteins of genogroup strains (Wa, DS-1, or AU-1, respectively). Strains D, P, ST3, IAL28, and WI61 encode genotype 1 (Wa-like) proteins, whereas strains DS-1 and 69M encode genotype 2 (DS-1-like) proteins. Of the 10 HRVs sequenced, 3 of them (Se584, A64, and L26) encode proteins belonging to more than one genotype, indicating that they are intergenogroup reassortants. We used amino acid sequence alignments to identify residues that distinguish proteins belonging to HRV genotype 1, 2, or 3. These genotype-specific changes cluster in definitive regions within each viral protein, many of which are sites of known protein-protein interactions. For the intermediate viral capsid protein (VP6), the changes map onto the atomic structure at the VP2-VP6, VP4-VP6, and VP7-VP6 interfaces. The results of this study provide evidence that group A HRV gene constellations exist and may be influenced by interactions among viral proteins during replication.     

Nucleotide sequence of VP4 and VP7 genes of human rotaviruses with subgroup I specificity and long RNA pattern: implication for new G serotype specificity.

We sequenced the genes coding for the two neutralization proteins, VP4 and VP7, of human rotavirus strains L26 and L27 with subgroup I specificity but the long RNA pattern. The deduced VP7 amino acid sequence of strains L26 and L27 showed a low homology (73.6 to 81.9%) to those of rotavirus strains of the established serotypes. This finding, together with the previous serological characterizations, suggests that the VP7 (G) serotype of the L26 and L27 strains is distinct from those of strains of the previously established serotypes. In contrast, the VP4 sequences of the L26 and L27 strains were quite similar to those of virulent serotype 2 strains (DS-1, S2, and RV-5).     

Restriction fragment length polymorphisms and sequence analysis: an approach for genotyping infectious pancreatic necrosis virus reference strains and other aquabirnaviruses isolated from northwestern Spain

Reference strains of infectious pancreatic necrosis virus resembling the 10 recognized serotypes and local isolates of aquabirnaviruses isolated in northwestern Spain from reservoirs (mollusks) and from asymptomatic and carrier cultured fish were genotyped by restriction fragment length polymorphism (RFLP) and nucleic acid sequence analyses. The RFLP analysis yielded seven genogroups, each of which was clearly correlated with a serotype. Sequence analysis of the three open reading frames provided quite similar results in terms of genogrouping. Based on the results of this study and in order to unify the two types of assays, we propose placing aquabirnaviruses into six genogroups, four of which can be subdivided into two genotypes based on a two-step restriction analysis. The genotyping corresponds with serotyping as follows: genogroup I includes two genotypes corresponding to serotypes A9 (genotype I.1) and A1 (genotype I.2); genogroup II corresponds to serotype A3; genogroup III includes genotypes III.1 (serotype A2) and III.2 (serotype B1); genogroups IV and V include two genotypes, each corresponding to serotypes A5, A6, A7, and A8 (genotypes IV.1, IV.2, V.1, and V.2, respectively);and genogroup VI corresponds to serotype A4. As expected, most local isolates belonged to genotype III.1 and genogroup II. However, a few local isolates corresponded to the American types of genogroup I. Finally, based on the results of this study and due to its simplicity, the two-step restriction analysis assay is proposed as a method for typing new isolates of aquabirnaviruses, and the results correspond to the results of conventional serotyping.     

Restriction Fragment Length Polymorphisms and Sequence Analysis: an Approach for Genotyping Infectious Pancreatic Necrosis Virus Reference Strains and Other Aquabirnaviruses Isolated from Northwestern Spain

Reference strains of infectious pancreatic necrosis virus resembling the 10 recognized serotypes and local isolates of aquabirnaviruses isolated in northwestern Spain from reservoirs (mollusks) and from asymptomatic and carrier cultured fish were genotyped by restriction fragment length polymorphism (RFLP) and nucleic acid sequence analyses. The RFLP analysis yielded seven genogroups, each of which was clearly correlated with a serotype. Sequence analysis of the three open reading frames provided quite similar results in terms of genogrouping. Based on the results of this study and in order to unify the two types of assays, we propose placing aquabirnaviruses into six genogroups, four of which can be subdivided into two genotypes based on a two-step restriction analysis. The genotyping corresponds with serotyping as follows: genogroup I includes two genotypes corresponding to serotypes A9 (genotype I.1) and A1 (genotype I.2); genogroup II corresponds to serotype A3; genogroup III includes genotypes III.1 (serotype A2) and III.2 (serotype B1); genogroups IV and V include two genotypes, each corresponding to serotypes A5, A6, A7, and A8 (genotypes IV.1, IV.2, V.1, and V.2, respectively);and genogroup VI corresponds to serotype A4. As expected, most local isolates belonged to genotype III.1 and genogroup II. However, a few local isolates corresponded to the American types of genogroup I. Finally, based on the results of this study and due to its simplicity, the two-step restriction analysis assay is proposed as a method for typing new isolates of aquabirnaviruses, and the results correspond to the results of conventional serotyping.     

Diarrheal response of gnotobiotic pigs after fetal infection and neonatal challenge with homologous and heterologous human rotavirus strains.

Pigs exposed in utero to human rotavirus (HRV) strain Wa serotype 1 from 15 to 36 days prior to birth responded immunologically by modifying their clinical response to neonatal oral challenge with a pathogenic dose of homologous Wa or heterologous M serotype 3 HRV. In these cases, diarrhea was prevented in 12 of 14 pigs and greatly reduced in the other two. However, fecal virus shedding was not significantly modified, since it was detected in 12 of 14 pigs. These results suggest the existence of a closer antigenic relationship between these two different HRV serotypes which may only be expressed in an in vivo test system. Exposure of fetal pigs to HRV DS-1 serotype 2 failed to cause infection or to induce any protection when pigs were challenged at birth with HRV Wa. This model for cross-protection studies in gnotobiotic piglets offers good possibilities for the evaluation of potential HRV vaccine candidates, for the in vivo study of antigenic similarities between rotavirus serotypes, and for the understanding of protective immune responses against diarrhea and virus shedding.     

Distribution of conserved and specific epitopes on the VP8 subunit of rotavirus VP4.

Three cDNA clones comprising the VP8 subunit of the VP4 of human rotavirus strain KU (VP7 serotype G1; VP4 serotype P1A) G1 were constructed. The corresponding encoded peptides were designated according to their locations in the VP8 subunit as A (amino acids 1 to 102), B (amino acids 84 to 180), and C (amino acids 150 to 246 plus amino acids 247 to 251 from VP5). In addition, cDNA clones encoding peptide B of the VP8 subunit of the VP4 gene from human rotavirus strains DS-1 (G2; P1B) and 1076 (G2; P2) were also constructed. These DNA fragments were inserted into plasmid pGEMEX-1 and expressed in Escherichia coli. Western immunoblot analysis using antisera to rotavirus strains KU (P1A), Wa (P1A), DS-1 (P1B), 1076 (P2), and M37 (P2) demonstrated that peptides A and C cross-reacted with heterotypic human rotavirus VP4 antisera, suggesting that these two peptides represent conserved epitopes in the VP8 subunit. In contrast, peptide B appears to be involved in the VP4 serotype and subtype specificities, because it reacted only with the corresponding serotype- and subtype-specific antiserum. Antiserum raised against peptide A, B, or C of strain KU contained a lower level of neutralizing activity than did that induced by the entire VP8 subunit. In addition, the serotype-specific neutralizing activity of anti-KU VP8 serum was ablated after adsorption with the KU VP8 protein but not with a mixture of peptides A, B, and C of strain KU, suggesting that most of the serotype-specific epitopes in the VP8 subunit are conformational and are dependent on the entire amino acid sequence of VP8.     

Similarity of the outer capsid protein VP4 of the Gottfried strain of porcine rotavirus to that of asymptomatic human rotavirus strains.

Genomic segment 4 of the porcine Gottfried strain (serotype 4) of porcine rotavirus, which encodes the outer capsid protein VP4, was sequences, and its deduced amino acid sequence was analyzed. Amino acid homology of the porcine rotavirus VP4 to the corresponding protein of asymptomatic or symptomatic human rotaviruses representing serotypes 1 to 4 ranged from 87.1 to 88.1% for asymptomatic strains and from 77.5 to 77.8% for symptomatic strains. Amino acid homology of the Gottfried strain to simian rhesus rotavirus, simian SA11 virus, bovine Nebraska calf diarrhea virus, and porcine OSU strains ranged from 71.5 to 74.3%. Antigenic similarities of VP4 epitopes between the Gottfried strain and human rotaviruses were detected by a plaque reduction neutralization test with hyperimmune antisera produced against the Gottfried strain or a Gottfried (10 genes) x human DS-1 rotavirus (VP7 gene) reassortant which exhibited serotype 2 neutralization specificity. In addition, a panel of six anti-VP4 monoclonal antibodies capable of neutralizing human rotaviruses belonging to serotype 1, 3, or 4 was able to neutralize the Gottfried strain. These observations suggest that the VP4 outer capsid protein of the Gottfried rotavirus is more closely related to human rotaviruses than to animal rotaviruses.     

Reassortant rotaviruses as potential live rotavirus vaccine candidates.

A series of reassortants was isolated from coinfection of cell cultures with a wild-type animal rotavirus and a "noncultivatable" human rotavirus. Wild-type bovine rotavirus (UK strain) was reassorted with human rotavirus strains D, DS-1, and P; wild-type rhesus rotavirus was reassorted with human rotavirus strains D and DS-1. The D, DS-1, and P strains represent human rotavirus serotypes 1, 2, and 3, respectively. Monospecific antiserum (to bovine rotavirus, NCDV strain) or a set of monoclonal antibodies to the major outer capsid neutralization glycoprotein, VP7 (of the rhesus rotavirus), was used to select for reassortants with human rotavirus neutralization specificity. This selection technique yielded many reassortants which received only the gene segment coding for the major neutralization protein from the human rotavirus parent, whereas the remaining genes were derived from the animal rotavirus parent. Single human rotavirus gene substitution reassortants of this sort represent potential live vaccine strains.     

Genetic variation in the VP4 and NSP4 genes of human rotavirus serotype 3 (G3 type) isolated in China and Japan

Sequence analyses of the VP4 and NSP4 genes were performed on twenty human isolates of serotype G3 rotavirus obtained from China and Japan. One isolate from China, CHW17, possessed P[4] genotype VP4 and KUN group NSP4 genes which are associated with G2. One isolate (02/92) from Japan, which was shown to have a wider spacing between RNA segments 10 and 11 by RNA polyacrylamide gel electrophoretic analysis like AU-1, possessed P[9] genotype VP4 and AU-1 group NSP4 genes. The other isolates had P[8] genotype VP4 and Wa group NSP4 genes. While the nucleotide sequence conservation among the G3 VP7 genes was more than 79% (Wen et al, Arch. Virol., 1997, 142: 1481-1489), the conservation of VP4 and NSP4 genes in the same genotypes or groups was more than 85%.