Isolation and molecular characterization of a naturally occurring non-structural protein 5 (NSP5) gene reassortant of group A rotavirus of serotype G2P[4] with a long RNA pattern

We report here two unusual strains of group A rotavirus, AU85 and AU102, isolated from children with diarrhea. These strains showed an unusual combination of serotype G2 and a long RNA pattern. RNA-RNA hybridization assays showed that these strains are reassortants in which a single genome segment 11 (the NSP5 gene) was derived from a Wa genogroup strain, while other 10 genome segments from a DS-1 genogroup strain. Phylogenetic analysis showed that the NSP5 gene of strain AU85 did not form cluster with Wa strain, while it belonged to the cluster of YM and other porcine strains. Phylogenetic analysis also showed that NSP5 and VP7 genes of AU85 were derived from the rotavirus circulating in the area. Both co-electrophoresis and RNA-RNA hybridization showed that AU85 and AU102 are identical strains. Moreover, the nucleotide sequence comparison between these two strains revealed that they had 100% identical NSP4, NSP5, and VP7 genes. These results suggest that AU85 was a reassortant formed relatively recently between rotaviruses belonging to the Wa and the DS-1 genogroup.     

Characterization of genotype P[9]G12 rotavirus strains from argentina: High similarity with Japanese and Korean G12 strains

The circulation of the unusual P[9]G12 strains was previously reported in suburban Buenos Aires, Argentina and in Far Eastern Asian countries. To examine genetic relationships of these strains the genes coding VP7, VP4, and NSP1 from two Argentine, one Japanese and one Korean P[9]G12 isolates were sequenced and their overall genome relatedness was determined by liquid hybridization. In addition, liquid hybridization was used to compare this group of strains to the previous G12 isolates L26 and Se585, and prototype Wa, DS‐1, and AU‐1 strains. The genomes of the Argentinean, Japanese and Korean strains were virtually indistinguishable by hybridization assays, suggesting very high sequence relatedness for all 11 segments. Hybridization assays also demonstrated that these four strains belong to the AU‐1 genogroup and that their genetic relationship with rotaviruses L26 and Se585 is limited to the VP7 gene. The VP7, VP4, and NSP1 genes of the Argentinean, Japanese and Korean strains were highly homologous to each other and to Thai strain T152 (～99% identity). These results together with the report of a similar strain detected during 2003 in Brazil are consistent with a recent importation and dissemination of the G12 strains from Far Eastern countries into South America. Increasing reports from several regions of the world demonstrating a variety of different G12 reassortant strains suggests that routine surveillance for this serotype should be conducted to determine its potential for global emergence. J. Med. Virol. 81:371–381, 2009. © 2008 Wiley‐Liss, Inc.     

我国各血清型轮状病毒非结构蛋白NSP4基因特征的初步分析

目的 对我国血清学调查中发现的四型（G型）轮状病毒NSP4序列进行测定和分析,了解NSP4的基因类型和变异状况。方法 利用银染测离方法对G1、G2、G3、G9型毒株NSP4 cDNA序列进行测定。结果 四个血清型毒株NSP4的核苷酸和氨基酸序列的同源性分别为78.8%,93.5%;83.0%,95.5%。G1、G3、G9型标本多属Wa组;G2型标本多属KUN组。NSP4的变异主要位于VP4结合域内的135－145位氨基酸。结论 Wa组和KUN组是我国主要的两种NSP4基因型。     

Sequence Analysis of the NSP4 Gene from Human Rotavirus Strains Isolated in the United States

Two major and one minor genotype of the rotavirus NSP4 gene have been described. The sequences of 29 NSP4 genes from rotavirus isolates obtained in the United States during the 1996–1997 rotavirus season (types P[8]G1, P[8]G9, P[4]G2 and P[6]G9) and 10 strains isolated during previous rotavirus seasons (types P[8]G1 and P[4]G2) were determined. All NSP4 genes from strains with short E types (6 P[4]G2, 4 P[6]G9) belonged to genotype NSP4A, whereas all 19 strains with long E types (16 P[8]G1, 3 P[8]G9) had NSP4 genes of genotype NSP4B. Genetic variation within genotypes was low (2.3% for both NSP4A and NSP4B), confirming that the NSP4 genes are highly conserved. Nonetheless, at least two distinct sub-lineages could be detected within each genotype: strains isolated in the same year, regardless of geographic location, were more closely related or even identical at the deduced amino acid level; strains isolated in different years were more distinct. Thus, geographic distance did not affect genetic distance. Northern hybridization analysis with NSP4A and NSP4B total gene probes failed to detect any unusual combinations of the VP6 and NSP4 genes in 31 additional isolates from the 1996–1997 rotavirus season.     

Molecular characterization of VP4, VP6, VP7, NSP4, and NSP5/6 genes identifies an unusual G3P[10] human rotavirus strain

An unusual strain of human rotavirus G3P[10] (CMH079/05) was detected in a stool sample of a 2‐year‐old child admitted to the hospital with severe diarrhea in Chiang Mai, Thailand. Analysis of the VP7 gene sequence revealed highest identities with unusual human rotavirus G3 strain CMH222 at 98.7% on the nucleotide and 99.6% on the amino acid levels. Phylogenetic analysis of the VP7 sequence confirmed that the CMH079/05 strain formed a cluster with G3 rotavirus reference strains and showed the closest lineage with the CMH222 strain. Analysis of partial VP4 gene of CMH079/05 revealed highest degree of sequence identities with P[10] rotavirus prototype strain 69M at nucleotide and amino acid levels of 92.9% and 94.6%, respectively. Phylogenetic analysis of the VP4 sequence revealed that CMH079/05 and 69M clustered closely together in a monophyletic branch separated from other rotavirus genotypes. To our knowledge, this is a novel G–P combination of G3 and P[10] genotypes. In addition, analyses of VP6, NSP4, and NSP5/6 genes revealed these uncommon genetic characteristics: (i) the VP6 gene differed from the four other known subgroups; (ii) the NSP4 gene was identified as NSP4 genetic group C, an uncommon group in humans; and (iii) the NSP5/6 gene was most closely related with T152, a G12P[9] rotavirus previously isolated in Thailand. The finding of uncommon G3P[10] rotavirus in this pediatric patient provided additional evidence of the genetic diversity of human group A rotaviruses in Chiang Mai, Thailand. J. Med. Virol. 81:176–182, 2009. © 2008 Wiley‐Liss, Inc.     

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. This revised version was published online in July 2006 with corrections to the Cover Date.     

Nucleotide Sequence Analysis of Rotavirus Gene 11 from Two Tissue Culture-adapted ATCC Strains,RRV and Wa

We report here nucleotide sequence and characterization of gene 11 from two tissue culture-adapted ATCC¹ rhesus (RRV) and human (Wa) strains of rotavirus. Gene 11 sequence encodes a nonstructural protein, NSP5 and also encodes NSP6, from an out of phase open reading frame. Sequence of RRV^ATCC gene 11 represents the first report from a rhesus rotavirus which has more than 90% homology at the nucleotide and deduced amino acid sequence level with that of its closely related simian SA11 strain. The Wa^ATCC gene sequence differed from that of published Wa (Wa^Pub) at three nucleotide positions, one at 264 (G^Wa-Pub to A^ATCC-Wa), another a nucleotide insertion (A) at position 388 and the third, a deletion (A) at 416. The latter two changes in Wa^ATCC NSP5 resulted in drastic amino acid changes within a 10-residue region (123–132) from VHVYQFQLTN in Wa^Pub to DSCVSISTNH in Wa^ATCC NSP5 protein. In this region, Wa^ATCC NSP5 is closer to published sequences from other strains, suggesting the authenticity of the present sequence. The nucleotide difference between Wa^Pub and Wa^ATCC NSP5 sequences, however, did not affect the NSP6 deduced amino acid sequence, which is overall highly conserved among all the strains compared. Sequence-based phylogenetic analysis of gene 11 identified a high degree of conservation within the Group A rotaviruses. In addition, it also separated RRV^ATCC and Wa^ATCC, suggesting rotavirus segregation by genogroup. An anti-NSP5 monoclonal antibody of SA11 recognized RRV NSP5 protein but not Wa^ATCC NSP5 from the infected cells, further supporting the phylogenetic segregation of RRV^ATCC and Wa^ATCC strains based on their NSP5 coding sequence.     

Species-specific but not genotype-specific primary and secondary isotype-specific NSP4 antibody responses in gnotobiotic calves and piglets infected with homologous host bovine (NSP4[A]) or porcine (NSP4[B]) rotavirus

Using recombinant baculoviruses expressing rotavirus NSP4 [A], [B], [C], and [D] genotypes of bovine, porcine, human, simian, or murine origin, we analyzed serum antibody responses to NSP4s in gnotobiotic calves and piglets infected by the oral/alimentary or intraamniotic route with bovine (NSP4[A]) (Wyatt, R.G., Mebus, C.A., Yolken, R.H., Kalica, A.R., James, H.D., Jr., Kapikian, A.Z., Chanock, R.M., 1979. Rotaviral immunity in gnotobiotic calves: heterologous resistance to human virus induced by bovine virus. Science 203(4380), 548-550) or porcine (NSP4[B]) (Hoshino, Y., Saif, L.J., Sereno, M.M., Chanock, R.M., Kapikian, A.Z., 1988. Infection immunity of piglets to either VP3 or VP7 outer capsid protein confers resistance to challenge with a virulent rotavirus bearing the corresponding antigen. J. Virol. 62(3), 744-748) rotaviruses. Following primary infection and challenge with virulent rotaviruses, the animals developed higher or significantly higher antibody titers to homologous host homotypic NSP4s than to heterologous host homotypic or heterologous host heterotypic NSP4s, indicating that antibody responses were species specific rather than genotype specific. Antibody responses to NSP4s corresponded closely with the phylogenetic relationships of NSP4s within a species-specific region of amino acids (aa) 131-141. In contrast, NSP4 genotypes determined by amino acid full-length sequence identity predicted poorly their "serotypes". In piglets, antibodies to NSP4 induced by previous oral infection failed to confer protection against challenge from a porcine rotavirus bearing serotypically different VP4 and VP7 but essentially identical NSP4 to the porcine rotavirus in primary infection. Thus, in an approach to immunization with a live oral rotavirus vaccine, the NSP4 protein does not appear to play an important role in protection against rotavirus disease and infection.     

新成人腹泻轮状病毒J19株NSP1、NSP2和NSP3基因序列分析

目的 克隆新成人腹泻轮状病毒J19株三个非结构蛋白NSP1、NSP2和NSP3基因，并分析其基因序列。方法 利用一种改进的非依赖核酸序列的单引物扩增方法扩增J19株三个基因，克隆到pMD18-T载体中并进行测序。在此基础上，将J19株的NSP1、NSP2和NSP3的蛋白序列与其他轮状病毒蛋白序列进行比较分析和种系进化分析。结果J19株的NSP1、NSP2和NSP3基因为基因5、7和8，它们的全长1307个、1004个和932个核苷酸，编码395个、297个和262个氨基酸。与J19株的NSP1、NSP2和NSP3蛋白序列一致性较高的分别是B组轮状病毒KB63株（26．3％）、WH1株（46．6％）和IDIR株（29．6％）。对J19株的NSP1、NSP2和NSP3的遗传进化分析表明，J19株在进化树上的位置都靠近A、B和C组轮状病毒分支的根部，而且它比较偏向于B组轮状病毒的分支。结论 J19株的NSPI、NSP2和NSP3与其他轮状病毒的相应蛋白序列存在显著差异。J19株NSP1、NSP2、NSP3的蛋白序列比较和遗传进化分析表明新成人腹泻轮状病毒与成人腹泻轮状病毒可能有共同起源；但是新成人腹泻轮状病毒与成人腹泻轮状病毒存在显著差异。     

Non-structural protein NSP2 induces heterotypic antibody responses during primary rotavirus infection and reinfection in children

Rotaviruses are the single most important causes of severe acute diarrhoea in children worldwide. Despite success in developing vaccines, there is still a lack of knowledge about many components of the immune response, particularly those to non-structural proteins. This study established radioimmunoprecipitation (RIP) assays using labeled G1P[8], G2P[4], and G4P[6] human rotaviruses to examine the spectrum and duration of rotavirus antibodies in sera collected sequentially for 18-36 months from 27 children after hospitalization for primary rotavirus gastroenteritis. Five children experienced rotavirus re-infections. Primary responses detected to non-structural protein NSP2 declined to baseline after 100-150 days. Responses were heterotypic between NSP2 of G1P[8] and G4P[8] rotaviruses. Re-infections after 465-786 days boosted antibody levels to NSP2of both serotypes, together with the appearance of anti-NSP2 to G2P[4], even though there was no evidence of infection with this serotype. We developed an enzyme-immunoassay to measure sequential levels of anti-NSP2 IgG and IgA, using recombinant (heterotypic) NSP2 derived from SA11 (G3P[2]). Anti-NSP2 IgG and IgA were detected in sera from 23/23 (100%) and 18/24 (75%) of children after primary infection, declined to baseline after 100-150 days, were boosted after rotavirus re-infections, and again declined to baseline 150 days later. Anti-NSP2 IgA was also detected after primary infection, in duodenal juice from 14/16 (87%), and faecal extract from 11/19 (57%) of children. Sequential estimation of anti-NSP2 EIA levels in sera could be a sensitive index of rotavirus infection and re-infection. The potential of anti-NSP2 to limit viral replication after re-infection deserves further study.     

Genomic characterization of a novel group A lamb rotavirus isolated in Zaragoza, Spain

An ovine rotavirus (OVR) strain, 762, was isolated from a 30-day-old lamb affected with severe gastroenteritis, in Zaragoza, Spain, and the VP4, VP7, VP6, NSP4, and NSP5/NSP6 genes were subsequently characterized molecularly. Strain OVR762 was classified as a P[14] rotavirus, as the VP4 and VP8* trypsin-cleavage product of the VP4 protein revealed the highest amino acid (aa) identity (94% and 97%, respectively) with that of the P11[14] human rotavirus (HRV) strain PA169, isolated in Italy. Analysis of the VP7 gene product revealed that OVR762 possessed G8 serotype specificity, a type common in ruminants, with the highest degree of aa identity (95-98%) shared with serotype G8 HRV, bovine rotavirus, and guanaco (Lama guanicoe) rotavirus strains. Moreover, strain OVR762 displayed a bovine-like NSP4 (genotype E2) and NSP5/NSP6 (genotype H3), and a VP6 genotype I2, as well as a long electropherotype pattern. This is the first report of a lamb rotavirus with P[14] and G8 specificities, providing additional evidence for the wide genetic and antigenic diversity of group A rotaviruses.     

Characterization of human symptomatic rotavirus isolates MP409 and MP480 having ‘long’ RNA electropherotype and subgroup I specificity, highly related to the P6[1],G8 type bovine rotavirus A5, from Mysore, India

Summary.  In an epidemiological study of symptomatic human rotaviruses in Mysore, India during 1993 and 1994, isolates MP409 and MP480 were isolated from two children suffering from severe, acute dehydrating diarrhea. Both isolates exhibited ‘long’ RNA pattern and subgroup I specificity suggesting the likelihood of their animal origin. Both isolates did not react with monoclonal antibodies (MAbs) specific for serotypes G1 to G6 as well as G10. To determine the genetic origin of these isolates, complete nucleotide sequences of genes encoding the outer capsid proteins VP4 and VP7, nonstructural proteins NSP1 and NSP3 and viral enterotoxin protein NSP4 from MP409 and partial sequences of genes from MP480 were determined. Comparison of the 5′ and 3′ terminal sequences of 250 nucleotides revealed complete identity of the gene sequences in both strains suggesting that MP409 and MP480 are two different isolates of a single strain. Comparison of the nucleotide and deduced amino acid sequences of VP4, VP7, NSP1 and NSP3 of MP409 with published sequences of strains belonging to different serotypes revealed that both outer capsid proteins VP4 and VP7 and NSP1 are highly related to the respective proteins from the P6[1], G8 type bovine rotavirus A5 isolated from a calf with diarrhoea in Thailand and that the NSP3 is highly homologous to that of bovine rotaviruses. The NSP4 protein showed greatest sequence identity with NSP4s belonging to the KUN genetic group to which NSP4s from human G2 type strains and bovine rotaviruses belong. MP409 and MP480 likely signify interspecies transmission of P6[1], G8 type strains from cattle to humans and represent the first P6[1] type rotaviruses isolated in humans. These and our previous studies on the asymptomatic neonatal strain I321 are of evolutionary and epidemiological significance in the context of close association of majority of the Indian population with cattle. Received September 29, 1999 Accepted February 4     

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.     

Molecular characterization of a human rotavirus reveals porcine characteristics in most of the genes including VP6 and NSP4

Summary. Long electropherotype with Subgroup I specificity is a common feature of animal rotaviruses. In an epidemic of infantile gastroenteritis in Manipur, India, long but SG I strains predominated in the outbreak in the year 1987–88. One such strain isolated from that region, following the outbreak had G9P [19] specificity. As this is a rare combination, the gene sequences encoding VP4, VP6, VP7, NSP1, NSP2, NSP3, NSP4 and NSP5 of this strain were analyzed. All these genes except VP7 were closely related to porcine rotaviruses (95–99% identity at amino acid level) and clustered with the porcine strains in phylogenetic analysis. In addition, it had subgroup I nature and belonged to NSP4 genotype B which is characteristic of animal rotaviruses. This is the first report of a rotavirus with VP6 and NSP4, two crucial proteins thought to be involved in host range restriction and pathogenicity, were of porcine origin and caused diarrhoea in a human host. Among the genes of this strain sequenced so far, only VP7 had highest identity to human strains at amino acid level. This study suggests reassortment may be occurring between human and other animal strains and some of the reassortant viruses may be virulent to humans.     

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.     

Molecular characterization of a human rotavirus reveals porcine characteristics in most of the genes including VP6 and NSP4

Long electropherotype with Subgroup I specificity is a common feature of animal rotaviruses. In an epidemic of infantile gastroenteritis in Manipur, India, long but SG I strains predominated in the outbreak in the year 1987-88. One such strain isolated from that region, following the outbreak had G9P [19] specificity. As this is a rare combination, the gene sequences encoding VP4, VP6, VP7, NSP1, NSP2, NSP3, NSP4 and NSP5 of this strain were analyzed. All these genes except VP7 were closely related to porcine rotaviruses (95-99% identity at amino acid level) and clustered with the porcine strains in phylogenetic analysis. In addition, it had subgroup I nature and belonged to NSP4 genotype B which is characteristic of animal rotaviruses. This is the first report of a rotavirus with VP6 and NSP4, two crucial proteins thought to be involved in host range restriction and pathogenicity, were of porcine origin and caused diarrhoea in a human host. Among the genes of this strain sequenced so far, only VP7 had highest identity to human strains at amino acid level. This study suggests reassortment may be occurring between human and other animal strains and some of the reassortant viruses may be virulent to humans.     

Serologic and genomic characterization of a G12 human rotavirus in Thailand

The G and P type specificity of the human rotavirus strain T-152 (G12P[9]) isolated in Thailand was serologically confirmed with G12-specific monoclonal antibodies prepared in this study by using a reference G12 strain, L26, as an immunizing antigen and a P[9]-specific monoclonal antibody, respectively. The genomic relationship of strain T-152 with representative human rotavirus strains was examined by means of Northern blot analysis. The results showed that T152 is closely related to strain AU-1 (G3P[9]). Gene 5 (NSP1 gene) of T152, which did not hybridize with those of any other strains examined, was characterized by sequence determination. The T152 NSP1 gene is 1,652 nucleotides in length, encodes 493 amino acids, and exhibits low identity to those of representative human and animal rotaviruses.     

Species-specific and interspecies relatedness of NSP1 sequences in human,porcine, bovine,feline, and equine rotavirus strains

Summary We have sequenced gene 5 encoding NSP1 for three human, two porcine, two bovine, one feline, and five equine rotavirus strains, and compared the nucleotide and deduced amino acid sequences with the published sequences for other various strains. Subgroup I human strains L26, 69M, and DS-1 were found to have a similar NSP1 sequence despite their different G serotypes, VP4 genotypes, and RNA patterns. The NSP1 sequence of the human strain K8 showed a high degree of homology to those of porcine strains OSU and YM. A high degree of homology was found among three equine strains (H2, FI-14, and FI23), but they differed from the other equine strains L338 and H1. The strain H1 was similar to the porcine strains. The feline strain Cat2 showed a high homology to bovine strains UK, RF, and A44. Thus, species-specific and interspecies relatedness of NSP1 sequences among human, porcine, bovine, feline and equine rotaviruses was found. Overall genomic relatedness of strains L26 and YM to various human and animal strains was also examined by RNA-RNA hybridization assay. The present and previous hybridization results showed that there is a good correlation in most strains between overall genomic property (or genogroup) and NSP1 sequence homology.Sequence data from this article have been deposited with the GSDB, DDBJ, EMBL and NCBI Data Libraries under Accession Nos. D38150 (strain L26), D38151 (strain 69M), D38152 (strain K8), D38153 (strain OSU), D38154 (strain YM), D38155 (strain FI-14), D38156 (strain FI23), D38157 (strain H2), D38158 (strain L338), U23726 (strain A44), D38148 (strain A5-13), U23727 (strain Cat2), and U23728 (strain H1).