Diversity and relationships of cocirculating modern human rotaviruses revealed using large-scale comparative genomics

Group A rotaviruses (RVs) are 11-segmented, double-stranded RNA viruses and are primary causes of gastroenteritis in young children. Despite their medical relevance, the genetic diversity of modern human RVs is poorly understood, and the impact of vaccine use on circulating strains remains unknown. In this study, we report the complete genome sequence analysis of 58 RVs isolated from children with severe diarrhea and/or vomiting at Vanderbilt University Medical Center (VUMC) in Nashville, TN, during the years spanning community vaccine implementation (2005 to 2009). The RVs analyzed include 36 G1P[8], 18 G3P[8], and 4 G12P[8] Wa-like genogroup 1 strains with VP6-VP1-VP2-VP3-NSP1-NSP2-NSP3-NSP4-NSP5/6 genotype constellations of I1-R1-C1-M1-A1-N1-T1-E1-H1. By constructing phylogenetic trees, we identified 2 to 5 subgenotype alleles for each gene. The results show evidence of intragenogroup gene reassortment among the cocirculating strains. However, several isolates from different seasons maintained identical allele constellations, consistent with the notion that certain RV clades persisted in the community. By comparing the genes of VUMC RVs to those of other archival and contemporary RV strains for which sequences are available, we defined phylogenetic lineages and verified that the diversity of the strains analyzed in this study reflects that seen in other regions of the world. Importantly, the VP4 and VP7 proteins encoded by VUMC RVs and other contemporary strains show amino acid changes in or near neutralization domains, which might reflect antigenic drift of the virus. Thus, this large-scale, comparative genomic study of modern human RVs provides significant insight into how this pathogen evolves during its spread in the community.     

Spike protein VP8* of human rotavirus recognizes histo-blood group antigens in a type-specific manner

Rotaviruses (RVs), an important cause of severe diarrhea in children, have been found to recognize sialic acid as receptors for host cell attachment. While a few animal RVs (of P[1], P[2], P[3], and P[7]) are sialidase sensitive, human RVs and the majority of animal RVs are sialidase insensitive. In this study, we demonstrated that the surface spike protein VP8* of the major P genotypes of human RVs interacts with the secretor histo-blood group antigens (HBGAs). Strains of the P[4] and P[8] genotypes shared reactivity with the common antigens of Lewis b (Le(b)) and H type 1, while strains of the P[6] genotype bound the H type 1 antigen only. The bindings between recombinant VP8* and human saliva, milk, or synthetic HBGA oligosaccharides were demonstrated, which was confirmed by blockade of the bindings by monoclonal antibodies (MAbs) specific to Le(b) and/or H type 1. In addition, specific binding activities were observed when triple-layered particles of a P[8] (Wa) RV were tested. Our results suggest that the spike protein VP8* of RVs is involved in the recognition of human HBGAs that may function as ligands or receptors for RV attachment to host cells.     

Rotavirus VP8*: Phylogeny, Host Range, and Interaction with Histo-Blood Group Antigens

The distal portion of rotavirus (RV) VP4 spike protein (VP8*) is implicated in binding to cellular receptors, thereby facilitating viral attachment and entry. While VP8* of some animal RVs engage sialic acid, human RVs often attach to and enter cells in a sialic acid-independent manner. A recent study demonstrated that the major human RVs (P[4], P[6], and P[8]) recognize human histo-blood group antigens (HBGAs). In this study, we performed a phylogenetic analysis of RVs and showed further variations of RV interaction with HBGAs. On the basis of the VP8* sequences, RVs are grouped into five P genogroups (P[I] to P[V]), of which P[I], P[IV], and P[V] mainly infect animals, P[II] infects humans, and P[III] infects both animals and humans. The sialic acid-dependent RVs (P[1], P[2], P[3], and P[7]) form a subcluster within P[I], while all three major P genotypes of human RVs (P[4], P[6], and P[8]) are clustered in P[II]. We then characterized three human RVs (P[9], P[14], and P[25]) in P[III] and observed a new pattern of binding to the type A antigen which is distinct from that of the P[II] RVs. The binding was demonstrated by hemagglutination and saliva binding assay using recombinant VP8* and native RVs. Homology modeling and mutagenesis study showed that the locations of the carbohydrate binding interfaces are shared with the sialic acid-dependent RVs, although different amino acids are involved. The P[III] VP8* proteins also bind the A antigens of the porcine and bovine mucins, suggesting the A antigen as a possible factor for cross-species transmission of RVs. Our study suggests that HBGAs play an important role in RV infection and evolution.     

Structural Basis of Glycan Recognition in Globally Predominant Human P[8] Rotavirus

Rotavirus(RV)causes acute gastroenteritis in infants and children worldwide.Recent studies showed that glycans such as histo-blood group antigens(HBGAs)function as cell attachment factors affecting RV host susceptibility and prevalence.P[8]is the predominant RV genotype in humans,but the structural basis of how P[8]RVs interact with glycan ligands remains elusive.In this study,we characterized the interactions between P[8]VP8~*s and glycans which showed that VP8~*,the RV glycan binding domain,recognized both mucin core 2 and H type 1 antigens according to the ELISA-based oligosaccharide binding assays.Importantly,we determined the structural basis of P[8]RV-glycans interaction from the crystal structures of a Rotateq P[8]VP8~*in complex with core 2 and H type 1 glycans at 1.82.3 ?,respectively,revealing a common binding pocket and similar binding mode.Structural and sequence analysis demonstrated that the glycan binding site is conserved among RVs in the P[Ⅱ]genogroup,while genotype-specific amino acid variations determined different glycan binding preference.Our data elucidated the detailed structural basis of the interactions between human P[8]RVs and different host glycan factors,shedding light on RV infection,epidemiology,and development of anti-viral agents.     

Binding Patterns of Rotavirus Genotypes P[4], P[6], and P[8] in China with Histo-Blood Group Antigens

Rotaviruses (RVs) are an important cause of severe gastroenteritis in children. It has been found that RV may recognize the histo-blood group antigens (HBGAs) as ligands or receptors and bind HBGAs in a type-dependent manner. In this study, we investigated the binding specificity of VP8* proteins from human rotaviruses (RV) that are prevalent in China including genotypes P[4], P[6], and P[8]. Through the saliva- and oligosaccharide-based binding assays, we found that the VP8* proteins of P[4] and P[8] RV showed similar reactivity with the Le^b and H type 1 antigens, while P[6] RV weakly bound the Le^b antigen. These findings may facilitate further research into RV host specificity and vaccine development.     

Poly-LacNAc as an Age-Specific Ligand for Rotavirus P[11] in Neonates and Infants

Rotavirus (RV) P[11] is an unique genotype that infects neonates. The mechanism of such age-specific host restriction remains unknown. In this study, we explored host mucosal glycans as a potential age-specific factor for attachment of P[11] RVs. Using in vitro binding assays, we demonstrated that VP8* of a P[11] RV (N155) could bind saliva of infants (60.3%, N = 151) but not of adults (0%, N = 48), with a significantly negative correlation between binding of VP8* and ages of infants (P<0.01). Recognition to the infant saliva did not correlate with the ABO, secretor and Lewis histo-blood group antigens (HBGAs) but with the binding of the lectin Lycopersicon esculentum (LEA) that is known to recognize the oligomers of N-acetyllactosamine (LacNAc), a precursor of human HBGAs. Direct evidence of LacNAc involvement in P[11] binding was obtained from specific binding of VP8* with homopolymers of LacNAc in variable lengths through a glycan array analysis of 611 glycans. These results were confirmed by strong binding of VP8* to the Lec2 cell line that expresses LacNAc oligomers but not to the Lec8 cell line lacking the LacNAc. In addition, N155 VP8* and authentic P[11] RVs (human 116E and bovine B223) hemagglutinated human red blood cells that are known to express poly-LacNAc. The potential role of poly-LacNAc in host attachment and infection of RVs has been obtained by abrogation of 116E replication by the PAA-conjugated poly-LacNAc, human milk, and LEA positive infant saliva. Overall, our results suggested that the poly-LacNAc could serve as an age-specific receptor for P[11] RVs and well explained the epidemiology that P[11] RVs mainly infect neonates and young children.     

Evidence of the co‐circulation of enteric viruses in sewage and in the population of Greater Cairo

Aims: To characterize major enteric viruses (enterovirus, rotavirus, norovirus, astrovirus and adenovirus) in the sewage of Greater Cairo and to compare the results with clinical data collected during the same period. Methods and Results: Seventy‐two sewage samples from two waste water treatment plants were collected from April 2006 through February 2007. Enteroviruses, noroviruses (NoVs) and rotaviruses (RVs) were detected by RT‐PCR in 22%, 18% and 8·3% of the samples, respectively. No adenovirus and astrovirus was detected. G2P[8], G9P[8], G1P[8], G2P[4] and rare G12 RV isolates were detected in the environment as well as a bovine RV. The environmental NoV strains mostly belonged to genogroup I (84%). Rotaviruses and some of the NoVs were similar to those found in the clinical samples at the same time. Conclusions: The comparison of environmental and clinical data suggests that similar RV and NoV isolates were circulating in the environment and in the population during the same period. Significance and Impact of the Study: Few studies have investigated the prevalence and the epidemiology of RVs and NoVs in Cairo. This work is the first to establish a correlation between viral gastroenteritis and the concomitant presence of enteric viruses in the environment for Greater Cairo where combined environmental and clinical surveys should help to prevent infections caused by these major pathogens.     

Simian Rotaviruses Possess Divergent Gene Constellations That Originated from Interspecies Transmission and Reassortment

Although few simian rotaviruses (RVs) have been isolated, such strains have been important for basic research and vaccine development. To explore the origins of simian RVs, the complete genome sequences of strains PTRV (G8P[1]), RRV (G3P[3]), and TUCH (G3P[24]) were determined. These data allowed the genotype constellations of each virus to be determined and the phylogenetic relationships of the simian strains with each other and with nonsimian RVs to be elucidated. The results indicate that PTRV was likely transmitted from a bovine or other ruminant into pig-tailed macaques (its host of origin), since its genes have genotypes and encode outer-capsid proteins similar to those of bovine RVs. In contrast, most of the genes of rhesus-macaque strains, RRV and TUCH, have genotypes more typical of canine-feline RVs. However, the sequences of the canine and/or feline (canine/feline)-like genes of RRV and TUCH are only distantly related to those of modern canine/feline RVs, indicating that any potential transmission of a progenitor of these viruses from a canine/feline host to a simian host was not recent. The remaining genes of RRV and TUCH appear to have originated through reassortment with bovine, human, or other RV strains. Finally, comparison of PTRV, RRV, and TUCH genes with those of the vervet-monkey RV SA11-H96 (G3P[2]) indicates that SA11-H96 shares little genetic similarity to other simian strains and likely has evolved independently. Collectively, our data indicate that simian RVs are of diverse ancestry with genome constellations that originated largely by interspecies transmission and reassortment with nonhuman animal RVs.Group A rotaviruses (RVs) are a major cause of acute dehydrating diarrhea in infants and children under the age of 5 years worldwide. These infections lead to approximately 527,000 deaths each year, the vast majority occurring in developing countries (33). RVs are also responsible for gastroenteritis in many other animal species, notably mammals and birds (16, 38). RVs are members of the family Reoviridae and possess a genome consisting of 11 segments of double-stranded RNA (dsRNA). The prototypic genome of a group A RV encodes six structural proteins (VP) and six nonstructural proteins (NSP) (5). The mature RV virion is a nonenveloped triple-layered icosahedral particle. The inner most protein layer is formed by the core lattice protein VP2. Attached to the interior surface of the VP2 layer near the fivefold axes are complexes of the viral RNA-dependent RNA polymerase VP1 and the RNA capping enzyme VP3. Collectively, VP1, VP2, VP3, and the dsRNA genome form the core of the virion (5, 11). The core is surrounded by VP6, the sole constituent of the intermediate protein layer of the virion. The antigenic properties of VP6 are used in classifying RV isolates into groups. The outer protein layer of the virion is composed of trimers of the VP7 glycoprotein penetrated by spikes of the VP4 attachment protein (50). The properties of VP7 and VP4 form the basis of a dual classification system defining RV G types (glycosylated) and P types (protease sensitive), respectively. At present, 23 G genotypes and 31 P genotypes have been recognized in the literature based on sequence analyses (17, 39, 42, 45, 47). Recently, a comprehensive sequence-based classification system was established for the RVs which, together with a uniform nomenclature, allows each genome segment of the virus to be assigned to a particular genotype. In the comprehensive classification system, the acronym Gx-P[x]-Ix-Rx-Cx-Mx-Ax-Nx-Tx-Ex-Hx defines the genotypes of VP7-VP4-VP6-VP1-VP2-VP3-NSP1-NSP2-NSP3-NSP4-NSP5 encoding genome segments (17, 18).Several years ago, Nakagomi et al. provided evidence by RNA-RNA hybridization assays that RVs originating from different animal species could be resolved into genogroups based upon the existence of unique species-specific genome constellations (29-31). More recently, the concept that RVs preferentially retain certain species-related genome constellations has been further supported by whole-genome sequencing (8, 24). For human RVs, two major genogroups (Wa-like genogroup 1 and DS-1-like genogroup 2) and one minor genogroup (AU-1-like genogroup 3) have been described (8, 17, 30). Although these genogroups are generally species specific, it is believed that the human AU-1 genogroup is of feline origin (31) and that the human Wa and DS-1 genogroups share common ancestor with porcine and bovine RVs, respectively (17). Another recent study based on full genome sequence data has indicated that the rarely seen human G3P[3] RVs are of feline or canine origin (46). Two additional sequence-based studies have indicated that human RVs with P[14] specificity may have originated after interspecies transmission from rabbit RVs and RVs from hosts belonging to the order Artiodactyla (i.e., hoofed mammals with even toes, including ruminants and pigs) (19, 20). These examples indicate that interspecies transmission of entire RV gene constellations from one host species to another may contribute significantly to viral evolution. In addition to interspecies transmission, complete genome sequencing of RVs have revealed multiple examples of naturally occurring inter- and intragenogroup reassortment (17, 19, 21-23, 37, 41).The simian RV strains, notably RRV and the SA11 derivatives (e.g., SA11-Cl3 and SA11-4F), have been used extensively as models in the study of all aspects of RV biology, including characterizing genome replication and virion assembly, delineating high-resolution structures of viral proteins and the virion capsid, and describing the functions of viral proteins. Moreover, the RRV strain was used to create a set of human-simian reassortant viruses that formed the basis of the first commercially licensed RV vaccine (Rotashield; Wyeth Laboratories) (10). Serological analyses have indicated that simian RVs are probably endemic in wild nonhuman primate (NHP) species in Africa (32). However, whether or not unique genogroups or preferred genome constellation exist for the simian RVs has not been determined, because of the lack of comprehensive genetic data. Most simian RVs isolated to date (e.g., rhesus macaque viruses RRV [43] and TUCH [25] and the pig-tailed macaque virus PTRV [9]) have been recovered from monkeys kept in captivity in the United States. An important exception is the SA11 isolate, which was recovered from a vervet monkey in South Africa (15). Simian RV infections occur mostly in young monkeys, similar to human RV infections in children (32, 40).To gain further insight into the origins and properties of simian RVs, we sequenced and contrasted the genomes of PTRV, RRV, and TUCH with other RVs, including SA11-H96 (G3P[2]), the only previously fully sequenced simian RV (41). Our results reveal that these four simian RVs are of divergent ancestry and have evolved by combinations of interspecies transmission and reassortment with RVs naturally occurring in other animal species. Thus, the simian RVs do not possess a common genome constellation nor define a unique genogroup. Although frequently used as disease models, the simian RVs show limited genetic similarity with the human RVs (genogroups 1 and 2) responsible for most human disease.     

我国1998～1999年流行的婴幼儿腹泻轮状病毒的分型研究

轮状病毒是世界范围内引起婴幼儿腹泻的主要病原。根据病毒外壳蛋白VP4和VP7抗原性的不同可区分为不同型：P（VP4,protease sensitive）型和G（VP7,glycoprotein）型。1998－1999年在中国8个城市（长春、秦皇岛、北京、杭州、福州、广州、成都、昆明）采集了急性腹泻患儿的1093份非细菌性腹泻粪便标本,先进行A组轮状病毒（HRV）的筛选,其中阳性标本433份（39.6％）,电泳型长型占优势（96％）。对HRV标本,再利用血清型特异的MAbELISA和／或RT－PCR进行G分型。结果表明,在1998－1999年,在上述8城市非细菌性腹泻行季节,以HRV G1型为主要流行株,占阳性的83.4％,其次为G3（12.0%）、G4（3.5%)和G2(3.2%）。此外,有3份（0.7％）HRV标本未能分型,12（2.8％）份标本为混合感染,还结合1982－1996年全国12个地区1382份HRV标本的分型资料,分析了我国HVR G血清型的流行规律。实验中又抽样选取了124份GHRV标本,用RT－PCR进行P分型,其中P[8]型76份（61.3％）,P[4]型14份（11.3%）,P[6]型12份(9.7%),P[9]型8份(6.4%)。另外15份（12.1%)未能分出P型,有待进一步检定,实验中HRV分离株除了觉见的P[8]G1(51.4%)、P[4]G2(4.6%)毒株外,还检测到P[8]G3(11.0%)、P[8]G4(6.4%) 和其它较少见的病毒型。以上结果为我国轮状病毒疫苗的应用和开发提供了较系统、清晰的流行病学背景资料。     

Generation of recombinant rotavirus with an antigenic mosaic of cross-reactive neutralization epitopes on VP4

Recombinant rotavirus (RV) with cDNA-derived chimeric VP4 was generated using recently developed reverse genetics for RV. The rescued virus, KU//rVP4(SA11)-II(DS-1), contains SA11 (simian RV strain, G3P[2])-based VP4, in which a cross-reactive neutralization epitope (amino acids 381 to 401) on VP5* is replaced by the corresponding sequence of a different P-type DS-1 (human RV strain, G2P[4]). Serological analyses with a panel of anti-VP4- and -VP7-neutralizing monoclonal antibodies revealed that the rescued virus carries a novel antigenic mosaic of cross-reactive neutralization epitopes on its VP4 surface. This is the first report of the generation of a recombinant RV with artificial amino acid substitutions.     

Reassortant DS‐1‐like G1P[4] Rotavirus A strains generated from co‐circulating strains in Vietnam, 2012/2013

One major mechanism by which Rotavirus A (RVA) evolves is genetic reassortment between strains with different genotype constellations. However, the parental strains of the reassortants generated have seldom been identified. Here, the whole genome of two suspected reassortants, RVA/Human‐wt/VNM/SP127/2013/G1P[4] and RVA/Human‐wt/VNM/SP193/2013/G1P[4], with short RNA electropherotypes were examined by Illumina MiSeq sequencing and their ancestral phylogenies reconstructed. Their genotype constellation, G1‐P[4]‐I2‐R2‐C2‐M2‐A2‐N2‐T2‐E2‐H2, indicated that they were G1 VP7 mono‐reassortants possessing DS‐1‐like genetic backbones. The two strains were ≧99.7% identical across the genome. While their VP7 genes were ≧99.7 identical to that of a Wa‐like strain RVA/Human‐wt/VNM/SP110/2012/G1P[8] which co‐circulated during the 2012/2013 season, 10 genes were ≧99.8% identical to that of the DS‐1‐like strains RVA/Human‐wt/VNM/SP015/2012/G2P[4] (and SP108) that co‐circulated during the season. The identities were consistent with the phylogenetic relationships observed between the genes of the reassortants and those of the afore‐mentioned strains. Consequently, the G1P[4] strains appear to have been generated by genetic reassortment between SP110‐like and SP015‐like strains. In conclusion, this study provides robust molecular evidence for the first time that G1P[4] strains detected in Hanoi Vietnam were generated by inter‐genogroup reassortment between co‐circulating G1P[8] and G2P[4] strains within the same place and season.

     

2018–2020年人轮状病毒锦州地方株VP4及VP7基因特征

【背景】人A组轮状病毒(Rotavirus Group A,RVA)是婴幼儿胃肠炎的主要病原体及发展中国家婴幼儿死亡的重要原因,目前无特效药物治疗,疫苗预防是唯一可行的预防感染方法。外衣壳蛋白VP7和VP4是疫苗设计的主要靶点,针对该基因加强RVA地方株分子流行病学监测十分必要。【目的】对锦州地方流行RVA株VP7和VP4基因进行型别鉴定和序列特征分析。【方法】收集锦州地区2018-2020年RVA感染腹泻患儿的粪便标本,提取病毒RNA,通过RT-PCR扩增VP7、VP4基因片段并测序,得到7株RVA VP7和VP4序列。使用在线基因分型工具Rota C V2.0对测序结果进行分型分析。应用BLAST、DNAStar、MEGA X、Bio Edit等生物软件与临床流行株及疫苗株进行系统发育分析及氨基酸序列比对分析。【结果】分型结果表明7株锦州地方株均为G9P[8]型,系统发育分析证实其VP7和VP4基因分别属于G9-Ⅵ和P[8]-3谱系,核苷酸序列相似性分别为99.32%-100%与99.41%-100%。JZ株VP7与疫苗株Rotavac和Rotasiil相比,在抗原表位区7-1a、7-1b、7-2中分别存在4个和3个氨基酸替换。JZ株VP4与疫苗株Rotarix和Rota Teq VP4氨基酸序列相比,发现7个和4个氨基酸替换,位于抗原表位区8-1和8-3。【结论】2018-2020年在辽宁锦州地区检测到7株G9P[8]型RVA株,VP7和VP4序列相似性高于99%,G9P[8]型可能是辽宁省锦州地区2018-2020年婴幼儿轮状病毒腹泻的主要流行基因型之一。与同基因型疫苗株比较,位于JZ株VP7和VP4抗原表位区的氨基酸位点差异对于野毒株免疫逃逸机制的研究具有意义。     

Frequent reassortments may explain the genetic heterogeneity of rotaviruses: analysis of Finnish rotavirus strains

The predominant rotavirus electropherotypes (e-types) during 17 epidemic seasons (1980 through 1997) in Finland were established, and representative virus isolates were studied by nucleotide sequencing and phylogenetic analysis. The virus isolates were either P[8]G1 or P[8]G4 types. The G1 and G4 strains formed one G1 lineage (VP7-G1-1) and one G4 lineage, respectively. Otherwise, they belonged to two P[8] lineages (VP4-P[8]-1 and -2) unrelated to their G types. Phylogenetic analysis of partial sequences of all 11 RNA segments obtained from the strains also revealed genetic diversity among gene segments other than those defining P and G types. With the exception of segments 1, 3, and 10, the sequences of the other segments could be assigned to 2 to 4 different genetic clusters. The results of this study suggest that, in addition to the RNA segments encoding VP4 and VP7, the other RNA segments may segregate independently as well. In total, the 9 predominant e-types represented 7 different RNA segment combinations when the phylogenetic clusters of their 11 genes were determined. The extensive genetic diversity and number of e-types among rotaviruses are best explained by frequent genetic reassortment.     

Cross-Serotype Immunity Induced by Immunization with a Conserved Rhinovirus Capsid Protein

Human rhinovirus (RV) infections are the principle cause of common colds and precipitate asthma and COPD exacerbations. There is currently no RV vaccine, largely due to the existence of ∼150 strains. We aimed to define highly conserved areas of the RV proteome and test their usefulness as candidate antigens for a broadly cross-reactive vaccine, using a mouse infection model. Regions of the VP0 (VP4+VP2) capsid protein were identified as having high homology across RVs. Immunization with a recombinant VP0 combined with a Th1 promoting adjuvant induced systemic, antigen specific, cross-serotype, cellular and humoral immune responses. Similar cross-reactive responses were observed in the lungs of immunized mice after infection with heterologous RV strains. Immunization enhanced the generation of heterosubtypic neutralizing antibodies and lung memory T cells, and caused more rapid virus clearance. Conserved domains of the RV capsid therefore induce cross-reactive immune responses and represent candidates for a subunit RV vaccine.     

Reassortment of Human and Animal Rotavirus Gene Segments in Emerging DS-1-Like G1P[8] Rotavirus Strains

The emergence and rapid spread of novel DS-1-like G1P[8] human rotaviruses in Japan were recently reported. More recently, such intergenogroup reassortant strains were identified in Thailand, implying the ongoing spread of unusual rotavirus strains in Asia. During rotavirus surveillance in Thailand, three DS-1-like intergenogroup reassortant strains having G3P[8] (RVA/Human-wt/THA/SKT-281/2013/G3P[8] and RVA/Human-wt/THA/SKT-289/2013/G3P[8]) and G2P[8] (RVA/Human-wt/THA/LS-04/2013/G2P[8]) genotypes were identified in fecal samples from hospitalized children with acute gastroenteritis. In this study, we sequenced and characterized the complete genomes of strains SKT-281, SKT-289, and LS-04. On whole genomic analysis, all three strains exhibited unique genotype constellations including both genogroup 1 and 2 genes: G3-P[8]-I2-R2-C2-M2-A2-N2-T2-E2-H2 for strains SKT-281 and SKT-289, and G2-P[8]-I2-R2-C2-M2-A2-N2-T2-E2-H2 for strain LS-04. Except for the G genotype, the unique genotype constellation of the three strains (P[8]-I2-R2-C2-M2-A2-N2-T2-E2-H2) is commonly shared with DS-1-like G1P[8] strains. On phylogenetic analysis, nine of the 11 genes of strains SKT-281 and SKT-289 (VP4, VP6, VP1-3, NSP1-3, and NSP5) appeared to have originated from DS-1-like G1P[8] strains, while the remaining VP7 and NSP4 genes appeared to be of equine and bovine origin, respectively. Thus, strains SKT-281 and SKT-289 appeared to be reassortant strains as to DS-1-like G1P[8], animal-derived human, and/or animal rotaviruses. On the other hand, seven of the 11 genes of strain LS-04 (VP7, VP6, VP1, VP3, and NSP3-5) appeared to have originated from locally circulating DS-1-like G2P[4] human rotaviruses, while three genes (VP4, VP2, and NSP1) were assumed to be derived from DS-1-like G1P[8] strains. Notably, the remaining NSP2 gene of strain LS-04 appeared to be of bovine origin. Thus, strain LS-04 was assumed to be a multiple reassortment strain as to DS-1-like G1P[8], locally circulating DS-1-like G2P[4], bovine-like human, and/or bovine rotaviruses. Overall, the great genomic diversity among the DS-1-like G1P[8] strains seemed to have been generated through reassortment involving human and animal strains. To our knowledge, this is the first report on whole genome-based characterization of DS-1-like intergenogroup reassortant strains having G3P[8] and G2P[8] genotypes that have emerged in Thailand. Our observations will provide important insights into the evolutionary dynamics of emerging DS-1-like G1P[8] strains and related reassortant ones.     

G and P genotypes of rotavirus circulating among children with diarrhea in the Colombian northern coast.

A study on the prevalence of rotavirus G and P genotypes was carried out based on 253 stool specimens obtained from children living in the Colombia northern coast region who were less than 3-years-old and who suffered from acute diarrhea. A previous study had detected the presence of rotavirus A in 90 (36.5%) of the 246 samples tested by enzyme immunoassay (EIA), and these strains were investigated in the present study. Of these, 50 strains yielded an RNA electropherotype, most of which (80.0%) had long profiles and 20.0% of which had short profiles. Genotyping of 84 positive samples indicated that 67.9% of the strains could be typed. G1 (57.9%), was the most predominant VP7 genotype, followed by G3 (21.1%), G9 (15.8%) and G2 (5.3%). Among the VP4 genotypes, P[4] (49.1%) was the most prevalent, followed by P[6] 36.4% and P[8] (14.5%). Neither G4 nor G8 nor P[9] types were detected. The most common G-P combinations were G3 P[4] (8.8%) and G9 P[6] (7.0%), followed by G1 P[4] and G1 P[8] (5.3% each). All G1 P[8] strains showed long RNA profiles, whereas G3 P[4] and G9 P[6] displayed both long and short patterns. Mixed infections involved 21.0% of strains. There was a marked diversity among strains collected, and novel strains, including G9, as well as other atypical combinations of G and P genotypes, such as G9 P[6] and G3 P[4], were found.     

Longitudinal analysis of VP7 gene of group A human rotavirus G2P[4] strains circulating in the pre‐vaccine era in Sapporo,Japan from 1991 to 2011

Sequence analysis of the VP7 gene in 23 group A human rotavirus G2P[4] strains obtained during 1991–2011, that is, the pre‐vaccine era, in Sapporo, Japan showed considerable genetic diversity, mainly in variable regions. Recent G2P[4] epidemic strains were located in sublineage IVa with a distinctive substitution of D96N. This study provides background data on the genetic variability of G2P[4] rotavirus‐VP7 gene prior to the widespread use of rotavirus vaccines in Japan.