VP4 serotype of the Gottfried strain of porcine rotavirus.

The antigenic relationships of the VP4 serotype of porcine rotavirus Gottfried strain with other rotaviruses were determined by using antiserum to Gottfried VP4-baculovirus recombinant. This antiserum failed to react significantly with virus of serotypes P1A, P1B, P3, and OSU; however, it reacted with P2 strains. In the reciprocal assay, antiserum to VP4 of an asymptomatic strain (P2) failed to neutralize the Gottfried strain virus to a significant level. It thus appears that the Gottfried strain should be considered a subtype of P2.     

A porcine rotavirus strain with dual VP7 serotype specificity

Porcine rotavirus MDR-13, which on original isolation showed a two-way antigenic relationship with human rotavirus RV-3, shows VP7 relationships with serotype G5 as well as G3 viruses upon gene reassortment. Analysis of porcine MDR-13 and the MD-UK reassortant revealed marked nucleotide and amino acid similarity of VP7 genes of these viruses with those of both serotype G3 and G5 viruses. Evolution of such a strain, possibly by sequential mutations in the VP7 gene, is discussed.     

VP4 protein of porcine rotavirus strain OSU expressed by a baculovirus recombinant induces neutralizing antibodies

The complete VP4 gene of porcine rotavirus strain OSU has been inserted into a baculovirus expression vector under the control of the polyhedrin promoter. The VP4 outer capsid protein, which is a major neutralization antigen in rotavirus, was expressed in high yield in Spodoptera frugiperda cells. Reactivity with polyclonal and monoclonal antibodies suggested that neutralizing epitopes were functionally unaltered on the expressed VP4. The VP4 produced in this system also induced antibodies in guinea pigs which inhibited hemagglutination of OSU and neutralized its infectivity to high titer. The available evidence suggests that the VP4 expressed in insect cells maintained its antigenic configuration and may prove useful in elucidation of (1) the extent of VP4 polymorphism among human and animal rotaviruses and (2) the distribution of VP4 among these viruses.     

Nucleotide sequence of the cDNA for porcine rotavirus VP7 gene (strain K)

The nucleotide sequence of the cDNA encoding one of the neutralizing proteins VP7 of the new porcine strain K is determined. The deduced VP7 amino acid sequence of the K strain showed a high homology (93%) and a lower homology (75%) to those of the Gottfried and OSU strains, respectively. This finding suggests that strain K is more closely related to the Gottfried strain serotype 4.     

Preparation and characterization of a neutralizing monoclonal antibody directed to VP4 of rotavirus strain K8 which has unique VP4 neutralization epitopes

Summary For selecting the neutralizing monoclonal antibodies (N-MAbs) directed to VP4 of rotavirus strain K8, which has unique VP4 neutralization epitopes, we prepared several reassortant viruses by mixed infection of two different strains K8 (serotype 1) and P (serotype 3) in vitro: three reassortant clones having VP4 of K8 and VP7 of P and four clones having VP4 of P and VP7 of K8. By using these reassortants in screening hybridomas, a N-MAb (K8-2C12) directed to strain K8-specific VP4 was obtained. The MAb K8-2C12 neutralized only K8 when tested against numerous strains of different serotypes, while in enzyme-linked immunosorbent assay this MAb reacted also with simian rotavirus SA11 (serotype 3), bovine rotavirus NCDV (serotype 6), and human rotavirus (HRV) strain 69M (serotype 8). Neutralization-resistant mutants of K8 were selected by the K8-2C12 antibody and VP4 amino acid sequences of the mutants were determined. Single amino acid substitution was detected in the three mutant clones at position 394, which is included in the major cross-reactive neutralization region identified in other rotaviruses.     

Detection of a porcine rotavirus strain with VP4, VP7 and NSP4 genes of different animal origins

A new rotavirus strain, sh0902, was detected in diarrheic piglets on a farm in Shanghai, China, and its genotype was characterized as G1P[7]. Analysis of the VP4, VP7 and NSP4 genes demonstrated VP4 homology to bovine and swine rotavirus strains; the nucleotide (nt) and amino acid (aa) identities were 99.7% and 99.5%, respectively. The VP7 gene was highly homologous to that of a giant panda rotavirus strain, with 98.5% similarity at the nt level and 99% similarity at the aa level. The nucleotide sequence of the NSP4 gene displayed high homology to human rotavirus strain R479, with 99.7% identity at the nt level and 99.3% identity at the aa level. This is the first report of an unusual porcine rotavirus strain with VP4, VP7 and NSP4 genes that are highly homologous to bovine, swine, giant panda and human strains isolated at geographically distant sites (South Korea, China and India). Our data indicate that rotaviruses have circulated among humans and animals and undergone genome reassortment.     

A novel type of VP4 carried by a porcine rotavirus strain

The gene encoding the VP8* trypsin-cleavage product of the VP4 protein of porcine rotavirus strain A34 was sequenced, and the predicted amino acid (aa) sequence was compared to the homologous region of all known P genotypes. The aa sequence of the VP8* of strain A34 shared low identity, ranging from 39% (bovine strain B223, P8[11]) to 76% (human strain 69M, P4[10]), with the homologous sequences of representative strains of the remaining 21 P genotypes. Phylogenetic relationships showed that the VP8* of strain A34 shares a common evolutionary lineage with those of human 69M (P4[10]) and equine H-2 (P4[12]) strains. Hyperimmune sera raised to strain A34 and to a genetic reassortant strain containing the VP4 gene from strain A34, both with high homologous neutralization titer via VP4, failed to neutralize strains representative of 15 different P genotypes. These results indicate that strain A34 should be considered as prototype of a new P genotype and serotype (P14[23]) and provide further evidence for the vast genetic and antigenic diversity of group A rotaviruses.     

轮状病毒结构蛋白VP7 HLA-A2.1限制性CTL表位的初步鉴定

目的 预测并初步鉴定轮状病毒Wa株结构蛋白VP7 HLA—A2．1限制性CTL表位。方法 用BIMAS软件预测VP7 HLA—A2．1限制性CTL表位;分子模拟技术对分值最高的4条肽进行分子模建;最后测定候选肽与HLA-A2．1分子的亲和力及结合稳定性。结果 结合BIMAS及分子模拟的预测结果,选择4条肽QLYCDYNLV（132—140）、LLNYILKSV（18—26）、VLMKYDQSL（140—148）及VNWKKWWQV（287—295）作为候选表位肽;4条肽与HLA—A2．1结合的荧光系数（FI）值分别为2．58、3．83、3．19及0．82,肽-HLA-A2．1复合物半数解离时间（DC50）分别为2-4、6-8、8及2h。结论 QLYCDYNLV（132—140）、LLNYILKSV（18—26）及VLMKYDQSL（140—148）为潜在的HLA-A2．1限制性CTL表位。     

Cross-reactive,serotype- and monotype-specific neutralization epitopes on VP7 of serotype G3 and G5 porcine rotavirus strains

Summary VP7 specific monoclonal antibodies raised against serotype G5 porcine rotavirus strains isolated in Venezuela showed either a serotype G5- or monotype-specific pattern of reactivity by neutralization against a panel of 53 group A rotavirus isolates representative of all established G serotypes. Monoclonal antibodies raised against two G3 porcine strains were either specific for a subset of porcine G3 strains or reactive with another subset of porcine G3 strains and with most G5 strains. Neither were reactive with G3 strains from other species. Analysis of neutralization resistant mutants selected with these monoclonal antibodies indicated that epitopes defined by cross-reactive, serotype-and monotype-specific monoclonal antibodies overlap functionally and that binding and neutralization by these antibodies depended on specific amino acid residues in the region A or C of VP7. Results indicate that a high degree of monotypic variation occurs among G5 and G3 porcine rotavirus strains and the existence of at least one common epitope shared by G5 and G3 porcine strains, in the major neutralization domain of these VP7s.     

Neutralizing epitopes on herpes simplex virus-1-expressed rotavirus VP7 are dependent on coexpression of other rotavirus proteins.

We constructed a recombinant thymidine kinase-negative herpes simplex virus type 1 (HSV-1) that expressed the rotavirus major outer capsid glycoprotein, VP7. In the recombinant HSV-1, a promoter from the 5' noncoding region of the HSV-1 glycoprotein B locus regulated the expression of VP7 as a HSV-1 gamma 1 gene product. HSV-1-expressed VP7 resembled rotavirus-expressed VP7 in its SDS-PAGE mobility, high mannose-type glycosylation, disulfide bonding, perinuclear to cytoplasmic localization, intracellular retention, and reactivity with polyclonal antisera and nonneutralizing antibodies. Unlike rotavirus-expressed VP7, HSV-1-expressed VP7 lacked several neutralizing epitopes by immuno-histochemical staining and by ELISA. One neutralizing epitope identified on HSV-1-expressed VP7 by ELISA was masked by paraformaldehyde fixation of recombinant HSV-1- but not rotavirus-infected cells. Neutralizing epitopes were restored to HSV-1-expressed VP7 by coinfection of cells with the HSV-1 recombinant and a heterologous rotavirus that lack the neutralizing epitopes. The recovered neutralizing epitopes were detected on double-shelled rotavirus particles produced in the coinfected cells. This study indicates that the formation of several neutralizing epitopes on rotavirus VP7 requires interaction of VP7 with other rotavirus proteins. In addition, HSV-1 was a useful vector for studying the localization, processing, and antigenicity of an RNA virus glycoprotein.     

Antibody response to serotype-specific and cross-reactive neutralization epitopes on VP4 and VP7 after rotavirus infection or vaccination.

By using a competitive solid-phase immunoassay with serotype-specific and cross-reactive neutralizing monoclonal antibodies directed at VP4 and VP7, we tested the antibody responses to some neutralization epitopes on VP4 and VP7 in individuals infected or vaccinated with rotavirus. Antibody responses to VP7 epitopes of the infecting serotype of virus were found at a high frequency in both infants and children. In contrast, antibody responses to VP4 and heterotypic VP7 were observed only when the individuals possessed antibodies to any serotype of rotavirus in their acute-phase or prevaccination sera.     

Neutralization of rotavirus and recognition of immunologically important epitopes on VP4 and VP7 by human IgA

Summary.  Rotavirus is an important cause of gastroenteritis in young children. Locally produced antibodies in the intestinal mucosa are proposed to play an important role in the defence against rotavirus infection, but it is not established whether IgA alone can neutralize rotavirus, nor if IgA antibodies recognize epitopes involved in protective immunity. To evaluate whether human IgA plays a role in virus neutralization, serum IgA was purified from nineteen rotavirus seropositive individuals and examined for its neutralizing capacity by a peroxidase focus reduction test. In all nineteen sera IgA neutralizing antibodies against serotype 3 (rhesus rotavirus) were demonstrated. Purified IgA was further investigated and shown not only to neutralize rotavirus in solution but also to neutralize rotavirus already pre-bound to epithelial cells (MA-104). IgA epitope blocking assays with monoclonal antibodies directed against heterotypic epitopes on VP4 and VP7, revealed that IgA antibodies from 4/16 sera recognized epitopes on VP4, while 5/16 sera recognized a VP7 epitope. When whole sera were investigated for comparison 7 and 9/16 sera recognized epitopes on VP4 and VP7 respectively. Accepted January 22, 1997; Received October26, 1996     

A porcine G9 rotavirus strain shares neutralization and VP7 phylogenetic sequence lineage 3 characteristics with contemporary human G9 rotavirus strains

Of five globally important VP7 (G) serotypes (G1-4 and 9) of group A rotaviruses (the single most important etiologic agents of infantile diarrhea worldwide), G9 continues to attract considerable attention because of its unique natural history. Serotype G9 rotavirus was isolated from a child with diarrhea first in the United States in 1983 and subsequently in Japan in 1985. Curiously, soon after their detection, G9 rotaviruses were not detected for about a decade in both countries and then reemerged in both countries in the mid-1990s. Unexpectedly, however, such reemerged G9 strains were distinct genetically and molecularly from those isolated in the 1980s. Thus, the origin of the reemerged G9 viruses remains an enigma. Sequence analysis has demonstrated that the G9 rotavirus VP7 gene belongs to one of at least three phylogenetic lineages: lineage 1 (strains isolated in the 1980s in the United States and Japan), lineage 2 (strains first isolated in 1986 and exclusively in India thus far), and lineage 3 (strains that emerged/reemerged in the mid-1990s). Currently, lineage 3 G9 viruses are the most frequently detected G9 strains globally. We characterized a porcine rotavirus (A2 strain) isolated in the United States that was known to belong to the P[7] genotype but had not been serotyped by neutralization. The A2 strain was found to bear serotype G9 and P9 specificities as well as NSP4 [B] and subgroup I characteristics. By VP7-specific neutralization, the porcine G9 strain was more closely related to lineage 3 viruses than to lineage 1 or 2 viruses. Furthermore, by sequence analysis, the A2 VP7 was shown to belong to lineage 3 G9. These findings raise intriguing questions regarding possible explanations for the emergence of variations among the G9 strains.     

Production of reassortant viruses containing human rotavirus VP4 and SA11 VP7 for measuring neutralizing antibody following natural infection.

The outer capsid proteins VP4 and VP7 of group A rotaviruses are both targets of neutralizing antibody produced following natural infection in humans. Of interest is the relative importance and immunodominance of each protein in the generation of a protective immune response. In order to measure neutralizing antibody responses to VP4 and VP7 separately, reassortants bearing VP4 of each of the major human rotavirus P types with VP7 of SA11 origin were successfully produced by neutralizing monoclonal antibody selection. The resulting reassortants, together with reassortants representing each of the major VP7 types, were antigenically characterized with serotype-specific neutralizing monoclonal antibodies and hyperimmune sera. The neutralization proteins of human rotavirus origin were found to be unaffected antigenically by reassortment. The abilities of these reassortants to discriminate between VP4 and VP7 immune responses were evaluated with postinfection sera collected from three patients infected with either a P1A[8],G1, a P1B[4],G2, or a P1A[8],G4 rotavirus strain. The reassortants were shown to be capable of separating the neutralizing antibody responses to VP4 and VP7, with each patient showing a different immune response with respect to VP4 or VP7 immunodominance. These reassortants can now be applied to analyses of individual immune responses to VP4 and VP7 proteins after primary rotavirus infections and reinfections in humans.     

Characterization of homotypic and heterotypic VP7 neutralization sites of rhesus rotavirus

The gene 9 nucleotide sequence was determined for rhesus rotavirus and each of 14 viral variants selected for their resistance to neutralizing monoclonal antibodies. Each variant contains a single gene 9, VP7, mutation which permits viral growth in the presence of the antibody. Variant mutations were identified in two distinct neutralization regions. Region A was identified by monoclonal antibodies that are involved in both serotype-specific and serotype cross-reactive neutralization. Region C was identified by serotype-specific neutralizing monoclonal antibodies. Heterotypic neutralizing monoclonal antibody 57-8 selected variants with a mutation at amino acid 94 in the A region, the same amino acid location selected by serotype-specific monoclonal antibodies. Monoclonal antibody 3 selected a VP7 mutation at amino acid 99 resulting in additional N-linked glycosylation of the VP7 protein. Despite the added VP7 glycosylation, variant v3 was not broadly resistant to additional VP7-specific neutralizing monoclonal antibodies.     

Operational overlapping of cross-reactive and serotype-specific neutralization epitopes on VP7 of human rotavirus serotype 3

Summary VP7-specific neutralizing monoclonal antibodies (N-MAbs) to serotype 3 human rotavirus were produced to analyze serotype 3-specific and cross-reactive neutralization epitopes on VP7. On the basis of the reactivity patterns in neutralization tests with various human and animal strains, a total of 10 N-MAbs could be classified into four groups; five antibodies specific to serotype 3 were divided into two groups, and five antibodies consisted of two groups which are cross-reactive with strain 69M (serotype 8) or strain WI61 (serotype 9). Seven N-MAbs showed the same reactivity patterns to the virus strains in both neutralization tests and enzyme-linked immunosorbent assay (ELISA), while three N-MAbs specific to serotype 3 in neutralization showed a cross-reactivity with the serotype 8 strain in ELISA. Neutralization-resistant mutants of serotype 3 strains P and YO were selected by the N-MAbs. Cross-neutralization tests between the mutants and the MAbs indicated the presence of two serotype-specific (S1 and S2) and three cross-reactive (C1, C2, and C3) epitope groups. S1, S2, and C3 epitope groups overlapped operationally each other, and the S1 epitope group had an overlapping with the C1 epitope group. However, C2 epitope group identified by the MAbs which neutralized serotypes 3 and 9, had no operational overlapping with any other epitope groups.     

Characterization of an antigenically distinct porcine rotavirus.

A porcine virus with rotavirus morphology, which was antigenically unrelated to previously described rotaviruses, is described. Particles with an outer capsid layer measured 75 nm and those lacking the outer layer were 63 nm in diameter. Particles which resembled cores were also identified. The virus was shown to be antigenically distinct from other rotaviruses as judged by immunofluorescence and immune electron microscopy, and it failed to protect piglets from challenge with porcine rotavirus. Analysis of the genome indicated that it was composed of 11 segments of double-stranded RNA with the same overall size range as other rotaviruses but with an unusual segment pattern.     

Characterization of novel VP7, VP4, and VP6 genotypes of a previously untypeable group A rotavirus

Rotavirus is the most common cause of acute gastroenteritis among infants and young children throughout the world, but rotavirus cases in developing countries account for nearly all of the ∼ 600,000 annual deaths. We studied the epidemiology of rotavirus in 22 rural communities in northern coastal Ecuador over a five-year period. From 250 rotavirus positive stool specimens, the percentage that could not be RT-PCR genotyped for VP4 and VP7 was 77% and 63%, respectively. The possibility of sample degradation was considered but discounted after an experimental examination of rotavirus stability and EM visualization of rotavirus-like particles in several untypeable samples. Finally, alternate primers were used to amplify Ecu534, a sample that was untypeable using most published VP4 and VP7 primers. Characterization of the VP7, VP4, and VP6 full gene segments revealed novel genotypes and nucleotide mismatches with most published primer sequences. When considered with other findings, our results suggest that primer mismatch may be a widespread cause of genotyping failure, and might be particularly problematic in countries with greater rotavirus diversity. The novel sequences described in this study have been given GenBank accession numbers EU805775 (VP7), EU805773 (VP4), EU805774 (VP6) and the RCWG has assigned them novel genotypes G20P[28]I13, respectively.     

Identification of two subtypes of serotype 4 human rotavirus by using VP7-specific neutralizing monoclonal antibodies

Two distinct subtypes of human rotavirus serotype 4 were identified by using neutralizing monoclonal antibodies directed to the major outer capsid glycoprotein, VP7, of strains ST3 (subtype 4A) and VA70 (subtype 4B). Specimens containing serotype 4 rotavirus, obtained from different countries, were examined for subtyping by using solid-phase immune electron microscopy, enzyme-linked immunosorbent assay, and, for cell culture-adapted strains, neutralization assay. All 59 human rotavirus strains identified as serotype 4 by using animal antisera were classified into either subtype by monoclonal antibodies. This suggests that the antigenic difference between the two subtypes is a consequence of critical variations within the immunodominant serotype 4-specific neutralization site of rotavirus VP7. Subtype 4A (ST3-like) strains were predominant and were detected in stools from patients with gastroenteritis, as well as from healthy infants and young children.     

A组轮状病毒广州地方株VP7基因序列的比较分析

目的 了解我国轮状病毒G1型广州地方株与标准株及北京G1型地方株VP7基因序列的差异，为我国轮状病毒疫苗的研制提供资料。方法 通过逆转录—聚合酶链反应(RT—PCR)获得了轮状病毒广州地方株R97—196 VP7全基因的cDNA片段，将其克隆入T—A克隆质粒pUCm—T中，构建成重组质粒pUCmT—VP7，对克隆的VP7基因进行序列测定。结果 该地方株的基因核苷酸全长为1062nt，读码框架和以往的研究一致，和北京G1型地方株173的VP7氨基酸序列具有高度同源性(98％)，而与不同血清型标准株间则变异较大(73％—81％)，氨基酸序列中存在的一些高变区和保守功能区与已报道的研究结果一致。从进化角度分析，与轮状病毒标准株Wa株，相距较远。结论 轮状病毒广州地方株R97—196 VP7基因片段属G1型，轮状病毒VP7基因的变异与地域有一定关系。