Sequencing and phylogenetic analysis of the coding region of six common rotavirus strains: evidence for intragenogroup reassortment among co-circulating G1P[8] and G2P[4] strains from the United States.

The segmented genome of rotaviruses provides an opportunity for rotavirus strains to generate a large genetic diversity through reassortment; however, this mechanism is considered to play little role in the generation of mosaic gene constellations between Wa-like and DS-1-like strains in genes other than the neutralization antigens. A pilot study was undertaken to analyze these two epidemiologically important strains at the genomic level in order to (i) identify intergenogroup reassortment and (ii) to make available additional reference genome sequences of G1P[8] and G2P[4] for future genomics analyses. The full or nearly complete coding region of all 11 genes for 3 G1P[8] (LB2719, LB2758, and LB2771) and 3 G2P[4] (LB2744, LB2764, and LB2772) strains isolated from children hospitalized with severe diarrhea in Long Beach, California, where these strains were circulating at comparable rates during 2005-2006 are described in this study. Based on the full-genome classification system, all G1P[8] strains had a conserved genomic constellation: G1-P[8]-I1-R1-C1-M1-A1-N1-T1-E1-E1-H1 and were mostly identical to the few Wa-like strains whose genome sequences have already been determined. Similarly, the genome sequences of the 3 G2P[4] strains were highly conserved: G2-P[4]-I2-R2-C2-M2-A2-N2-T2-E2-E2-H2 and displayed an overall lesser genetic divergence with reference DS-1-like strains. While intergenogroup reassortment was not seen between the G1P[8] and G2P[4] strains studied here, evidence for intragenogroup reassortment events was identified. Similar studies in the post-rotavirus genomic era will help uncover whether intergenogroup reassortment affecting the backbone genes could play a significant role in any potential vaccine breakthrough events by evading immunity of vaccinated children.

Human G9P[8] rotavirus strains circulating in Cameroon, 1999-2000: Genetic relationships with other G9 strains and detection of a new G9 subtype.

Group A rotaviruses (RV-A) are the leading cause of viral gastroenteritis in children worldwide and genotype G9P[8] is one of the five most common genotypes detected in humans. In order to gain insight into the degree of genetic variability of G9P[8] strains circulating in Cameroon, stool samples were collected during the 1999-2000 rotavirus season in two different geographic regions in Cameroon (Southwest and Western Regions). By RT-PCR, 15 G9P[8] strains (15/89=16.8%) were identified whose genomic configurations was subsequently determined by complete or partial gene sequencing. In general, all Cameroonian G9 strains clustered into current globally-spread sublineages of the VP7 gene and displayed 86.6-100% nucleotide identity amongst themselves and 81.2-99.5% nucleotide identity with global G9 strains. The full genome classification of all Cameroonian strains was G9-P[8]-I1-R1-C1-M1-A1-N1-T1-E1-H1 but phylogenetic analysis of each gene revealed that the strains were spread across 4 or more distinct lineages. An unusual strain, RVA/Human-wt/CMR/6788/1999/G9P[8], which shared the genomic constellation of other Cameroonian G9P[8] strains, contained a novel G9 subtype which diverged significantly (18.8% nucleotide and 19% amino acid distance) from previously described G9 strains. Nucleotide and amino acid alignments revealed that the 3' end of this gene is highly divergent from other G9 VP7 genes suggesting that it arose through extensive accumulation of point mutations. The results of this study demonstrate that diverse G9 strains circulated in Cameroon during 1999-2000.

Genome sequence based molecular epidemiology of unusual US Rotavirus A G9 strains isolated from Omaha, USA between 1997 and 2000.

After discovery in the early 1980s, Rotavirus A serotype G9 was detected infrequently for almost a decade. Since the mid-1990s, however, serotype G9 has emerged to become a globally common strain linked to the introduction of a single, new genetic variant of G9 VP7 gene. Studies have demonstrated that genetically divergent G9 strains co-circulated at low frequency with the emerging variants. Examples include unique U.S. G9 strains Om46/Hu/USA/1998 and Om67/Hu/USA/1998, isolated in Omaha during the 1997-1998 rotavirus season, that are more closely related phylogenetically to reference strains from the 1980s than to most emerging G9 strains from the U.S. and globally. Here, we sequenced the VP7 full open reading frame for all available G9 strains (n=12) identified in Omaha during 1996-2000 seasons to investigate their epidemiology and evolution. In addition, the full or partial length open reading frames of the remaining 10 genes for five divergent Om46-like strains and one modern G9 variant were sequenced to evaluate their potential origin. Our findings suggest that Om46-like G9 strains may have been introduced into humans recently, perhaps in 1997-1998 when it was first detected, and the presumed original host of this VP7 gene variant may have been an animal species based on the unexpected detection of porcine rotavirus related NSP2 gene in the genome. The relatively high fitness of Om46-like strains during the 1997-1998 rotavirus season, 1 year after the globally important G9 variant was documented to be already spreading in the study area and other sites of the United States, appears to parallel findings on seasonal replacement of various genetic and antigenic variants of other common human rotavirus antigen specificities.

Genomic characterization of human rotavirus G10 strains from the African Rotavirus Network: relationship to animal rotaviruses.

Global rotavirus surveillance has led to the detection of many unusual human rotavirus (HRV) genotypes. The aim of this study was to elucidate the genetic and evolutionary relationships of short fragments of all 11 gene segments of G10 HRV strains identified in West Africa through the African Rotavirus Network (ARN) system. During 1998-2004 surveillance within the ARN, we identified 5 G10 P[8] HRV strains. Fragments of all 11 gene segments of these G10 strains were sequenced. Phylogenetic and sequence analyses of each gene segment revealed high nucleotide similarities amongst the ARN strains (97-100%) except in the case of the VP1(85-96%) and NSP2 genes (87.8-99.7%) where some strains were divergent. All genes of the ARN strains were classified as Wa-like (genotype 1) with the exception of their VP7 gene of all strains (genotype G10) and the VP6 gene of a single strain, 6755/2002/ARN (DS-1 like, genotype 2). While classified as Wa-like, the NSP2 genes of four of the ARN strains occupied a distinct sub-lineage related to simian strain Tuch, while the NSP2 of strain 6755/2002/ARN and NSP5 genes of all strains were closely related to the cognate genes of both human and animal strains belonging to the Wa-like genogroup. Although these findings help to elucidate the evolution of ARN G10 strains, additional sequence studies of cognate animal rotavirus genes are needed to determine irrefutably the specific origin of those genes relative to both human and animal rotavirus strains.