Molecular epidemiology of rotaviruses among healthy calves in Japan: isolation of a novel bovine rotavirus bearing new P and G genotypes

Full genomic analysis of a porcine-bovine reassortant G4P[6] rotavirus strain R479 isolated from an infant in China

During the 2004 surveillance of rotaviruses in Wuhan, China, a G4P[6] rotavirus strain R479 was isolated from a stool specimen collected from a 2-year-old child with diarrhea. The strain R479 had an uncommon subgroup specificity I + II, and analysis of the VP6 gene suggested that it was related to porcine rotaviruses. In the present study, full-length nucleotide sequences of all the RNA segments of R479 were determined and analyzed phylogenetically to identify the origin of individual RNA segments. According to the rotavirus genotyping system based on 11 RNA segments, the genotype of R479 was expressed as G4-P[6]-I5-R1-C1-M1-A1-N1-T7-E1-H1. This genotype includes the porcine-like VP6 genotype (I5) and bovine-like NSP3 genotype (T7). Phylogenetic analysis revealed that R479 genes encoding VP1, VP2, VP3, VP6, VP7, VP8*, NSP1, NSP4, and NSP5 were more closely related to those of porcine rotaviruses than human or other animal rotaviruses. In contrast, it was remarkable that the NSP3 gene of R479 was genetically closely related to only a bovine rotavirus strain UK. The NSP2 gene of R479 was also unique and clustered with only the G5P[8] human strain IAL28 and G3P[24] simian strain TUCH. These results suggested that R479 may be a reassortant virus having the NSP3 gene from a bovine rotavirus in the genetic background of a porcine rotavirus, with an NSP2 gene related to the porcine-human reassortant strain IAL28. To our knowledge, R479 is the first porcine-bovine reassortant rotavirus isolated from a human.

Concentration of acrylamide in a polyacrylamide gel affects VP4 gene coding assignment of group A equine rotavirus strains with P[12] specificity

BACKGROUND

It is universally acknowledged that genome segment 4 of group A rotavirus, the major etiologic agent of severe diarrhea in infants and neonatal farm animals, encodes outer capsid neutralization and protective antigen VP4.

RESULTS

To determine which genome segment of three group A equine rotavirus strains (H-2, FI-14 and FI-23) with P[12] specificity encodes the VP4, we analyzed dsRNAs of strains H-2, FI-14 and FI-23 as well as their reassortants by polyacrylamide gel electrophoresis (PAGE) at varying concentrations of acrylamide. The relative position of the VP4 gene of the three equine P[12] strains varied (either genome segment 3 or 4) depending upon the concentration of acrylamide. The VP4 gene bearing P[3], P[4], P[6], P[7], P[8] or P[18] specificity did not exhibit this phenomenon when the PAGE running conditions were varied.

CONCLUSIONS

The concentration of acrylamide in a PAGE gel affected VP4 gene coding assignment of equine rotavirus strains bearing P[12] specificity.

Detection and characterisation of group A rotavirus in asymptomatic piglets in southern Ireland

Porcine group A rotaviruses (GARV) are causative agents of enteritis in piglets and are a large reservoir of genetic material for the diversification of human GARVs. Accumulation of information on the genetic heterogeneity of porcine viruses is pivotal for readily characterising unusual human strains. Screening of 292 fecal samples, collected from 4-5- to 8-9-week-old asymptomatic pigs from four herds in Ireland between 2005 and 2007 resulted in 19 (6.5%) samples testing positive by reverse-transcription PCR (RT-PCR) for GARV. The strains were molecularly characterized to collate data on the VP7 and partial VP4 outer capsid genes. By sequence analysis of the VP7 gene, the Irish strains were identified as G2, G4, G5, G9 and G11 viruses. The G11 strains were closely related to other human and porcine G11 strains, while the G2 strains resembled porcine G2 viruses detected recently in Europe and southern Asia. The G4 strains were distantly related to other G4 human and animal strains, constituting a separate G4 VP7 lineage. Analysis of the G5 strains revealed that they were similar to a selection of G5 human and porcine strains, while the G9 strains resembled other porcine G9 viruses. By sequence analysis of the VP8* fragment of the VP4, the Irish viruses were characterised as P[6], P[7], P[13], P[13]/[22], P[26] and P[32].

Molecular characterization of rotaviruses in a Japanese raccoon dog (Nyctereutes procyonoides) and a masked palm civet (Paguma larvata) in Japan

Group A rotaviruses infect and cause diarrhea in humans and a wide range of mammals. Previous studies have suggested that some strains can cross the species barrier to infect humans (Martella et al., 2010). However, there are few reports on infection and characterization of rotaviruses in wild animals. To estimate what types of rotaviruses infect wild animals, we investigated infection of rotaviruses in wild animals living in urban areas in Japan between 2003 and 2008. Of 145 fecal specimens obtained, we detected rotaviruses in one sample from a Japanese raccoon dog (Nyctereutes procyonoides) (RAC-DG5) and in one sample from a masked palm civet (Paguma larvata) (MP-CIVET66) by RT-semi-nested PCR. Sequence analyses of the VP4 and VP7 genes of RAC-DG5 and MP-CIVET66 strains revealed that these strains belong to G3bP[9] genotype. Furthermore, phylogenetic analyses showed that RAC-DG5 and MP-CIVET66 strains were closely related to human and feline rotaviruses, suggesting interspecies transmission from humans or cats. To our knowledge, this is the first report on the detection and characterization of rotaviruses in a Japanese raccoon dog and masked palm civet. These findings show that wild animals constitute a potential zoonotic risk of rotaviruses.

Reassortment of human rotavirus gene segments into G11 rotavirus strains

G11 rotaviruses are believed to be of porcine origin. However, a limited number of G11 rotaviruses have been recently isolated from humans in combination with P[25], P[8], P[6], and P[4]. To investigate the evolutionary relationships of these strains, we analyzed the complete genomes of 2 human G11P[25] strains, 2 human G11P[8] strains, and 3 porcine reference strains. Most of the 11 gene segments of these 7 strains belonged to genotype 1 (Wa-like). However, phylogenetic clustering patterns suggested that an unknown G11P[25] strain with a new I12 VP6 genotype was transmitted to the human population, in which it acquired human genotype 1 gene segments through reassortment, resulting in a human G11P[8] rotavirus strain with an entire human Wa-genogroup backbone. This Wa-like backbone is believed to have caused the worldwide spread of human G9 and G12 rotaviruses. G11 human rotavirus strains should be monitored because they may also become major human pathogens.

Identification of G8 rotavirus strains determined as G12 by rotavirus genotyping PCR: updating the current genotyping methods

BACKGROUND

Rotaviruses are classified into G- and P-types, which are determined by the reactivity with antibodies to the outer viral proteins, VP7 and VP4, respectively, or sequence variation in the genes encoding these proteins. There are presently a number of different rotavirus strains co-circulating within the UK, with the common human strains G1P[8], G2P[4] and G9P[8] being the most prevalent. As part of strain surveillance for the European Rotavirus Network (EuroRotaNet) a cluster (n=29) of G8 strains was detected in the UK between February and May 2009.

OBJECTIVES

G8 strains were initially mistyped as G12 through multiplex RT-PCR, therefore further investigation was performed to ascertain the reasons behind this mistyping.

STUDY DESIGN

The genes encoding the VP7 of these G8 strains were sequenced and aligned with the existing G8- and G12-specific oligonucleotide primers.

RESULTS

Multiple alignment of sequences derived from these strains and the G8- and G12-specific oligonucleotide primers revealed a series of point mutations which resulted in mismatches at the 3' end of the G8-specific primer binding site that prevented amplification with the G8-specific primer, whilst a close homology with the G12-specific primer allowed mis-priming. Both the G8 and G12 primers were redesigned and their ability to correctly identify G8 and G12 strains was evaluated and confirmed.

CONCLUSION

These findings highlight the importance of monitoring the specificity and sensitivity of the genotyping methods in order to detect changes in the genotype distribution and changes associated with genetic drift of common or uncommon genotypes.

Detection and genotyping of Korean porcine rotaviruses

Porcine group A rotavirus (GARV) is considered to be an important animal pathogen due to their economic impact in the swine industry and its potential to cause heterologous infections in humans. This study examined 475 fecal samples from 143 farms located in 6 provinces across South Korea. RT-PCR and nested PCR utilizing primer pairs specific for the GARV VP6 gene detected GARV-positive reactions in 182 (38.3%) diarrheic fecal samples. A total of 98 porcine GARV strains isolated from the GARV-positive feces were analyzed for G and P genotyping. Based on the sequence and phylogenetic analyses, the most predominant combination of G and P genotypes was G5P[7], found in 63 GARV strains (64.3%). The other combinations of G and P genotypes were G8P[7] (16 strains [16.3%]), G9P[7] (7 strains [7.1%]), G9P[23] (2 strains [2.0%]), and G8P[1] (1 strain [1.0%]). The counterparts of G or P genotypes were not determined in three G5, five P[7], and one P[1] strains. Interestingly, phylogenetic analysis indicated that all Korean G9 strains were more closely related to lineage VI porcine and human viruses than to other lineages (I–V) of GARVs and to Korean human G9 strains (lineage III). These results show that porcine GARV infections are common in diarrheic piglets in South Korea. The infecting strains are genetically diverse, and include homologous (G5P[7]), heterologous (G8P[1]), and reassortant (G8P[7]), as well as emerging G9 GARV strains.