Increased detection of G3P[9] and G6P[9] rotavirus strains in hospitalized children with acute diarrhea in Bulgaria

Rotavirus severe disease in children is now vaccine-preventable and the roll-out of vaccination programs globally is expected to make a significant impact in the reduction of morbidity and mortality in children <5 years of age. Rotavirus is also a pathogen of other mammals and birds, and its segmented RNA genome can lead to the emergence of new or unusual strains in human population via interspecies transmission and reassortment events. Despite the efficacy and impact of rotavirus vaccine in preventing severe diarrhea, the correlates of protection remain largely unknown. Therefore, rotavirus strain surveillance before, during and after the introduction of immunization programs remains a crucial for monitoring rotavirus vaccine efficacy and impact. In this context, molecular characterization of 1323 Bulgarian rotavirus strains collected between June 2010 and May 2013 was performed. A total of 17 strains of interest were analyzed by partial sequence analysis. Twelve strains were characterized as G3P[9] and G6P[9] of potential animal origin. Phylogenetic analysis and comparisons with the same specificity strains detected sporadically between 2006 and 2010 revealed the constant circulation of these unusual human strains in Bulgaria, although in low prevalence, and their increased potential for person-to-person spread.     

Rotavirus in diarrheal children in rural Burkina Faso: High prevalence of genotype G6P[6]

Group A rotavirus (RVA) is the most common cause of severe gastroenteritis in young children globally, and responsible for a significant number of deaths in African countries. While vaccines are available, trials have shown a lesser efficacy in Africa. One of the reasons could be the prevalence and/or emergence of unusual or novel RVA strains, as many strains detected in African countries remain uncharacterized.In this study, we characterized RVA positive specimens from two remote rural areas in Burkina Faso, West Africa. In total 56 RVA positive specimens were subgrouped by their VP6 gene, and G-and P typed by PCR and/or sequencing of the VP7 and VP4 genes, respectively.Notably, we found a high prevalence of the unusual G6P[6]SGI strains (23%). It was the second most common constellation after G9P[8]SGII (32%); and followed by G1P[8]SGII (20%) and G2P[4]SGI (9%). We also detected a G8P[6]SGI strain, for the first time in Burkina Faso. The intra-genetic diversity was high for the VP4 gene with two subclusters within the P[8] genotype and three subclusters within the P[6] genotype which were each associated with a specific G-type, thereby suggesting a genetic linkage. The G6P[6]SGI and other SGI RVA strains infected younger children as compared to SGII strains (p < 0.05).To conclude, in this study we observed the emergence of unusual RVA strains and high genetic diversity of RVA in remote rural areas of Burkina Faso. The results highlight the complexity of RVA epidemiology which may have implication for the introduction of rotavirus vaccines currently being evaluated in many African countries.     

Complete genetic characterization of human G2P[6] and G3P[6] rotavirus strains

During the 2008–2009 rotavirus season, 10 G3P[6] rotavirus strains were isolated for the first time in Belgium, while an outbreak of G2P[6] strains occurred in the USA in 2005–2006. Partial sequencing of the 11 genome segments of the 10 Belgian G3P[6] strains revealed a clonal origin. Two of these strains, and a G2P[6] strain representative of the American outbreak, were selected and sequenced completely to analyze their evolutionary relationships. Genetic analysis revealed that all strains possessed a DS-1-like genotype constellation. The 2 Belgian G3P[6] strains showed >99% sequence identity at the nucleotide level and the American G2P[6] strain was phylogenetically closely related to the Belgian P[6] strains. These data suggest that reassortment(s) involving VP7 occurred recently, and that the prevalence of DS-1-like P[6] rotavirus strains need to be closely monitored because the currently licensed RVA vaccines contain neither the P[6] genotype nor strains with a complete human DS-1 genotype constellation.     

Predominance of rotavirus P[4]G2 in a vaccinated population, Brazil

We identified 21 rotaviruses in 129 patients with diarrhea in a Brazilian city with high rotavirus vaccine coverage. All rotaviruses were genotype P[4]G2 with 1 mixed infection with P[NT]G9. Although virus predominance could have occurred randomly, the vaccine may be less protective against P[4]G2. Prospective surveillance is urgently needed.     

Prevalence of G2P[4] and G12P[6] rotavirus, Bangladesh

Approximately 20,000 stool specimens from patients with diarrhea visiting 1 urban and 1 rural hospital in Bangladesh during January 2001-May 2006 were tested for group A rotavirus antigen, and 4,712 (24.0%) were positive. G and P genotyping was performed on a subset of 10% of the positive samples (n = 471). During the 2001-2005 rotavirus seasons, G1P[8] (36.4%) and G9P[8] (27.7%) were the dominant strains, but G2[4] and G12P[6] were present in 15.4% and 3.1% of the rotavirus-positive patients, respectively. During the 2005-06 rotavirus season, G2P[4] (43.2%) appeared as the most prevalent strain, and G12P[6] became a more prevalent strain (11.1%) during this season. Because recently licensed rotavirus vaccines include only the P[8] specificity, it is unknown how the vaccines will perform in settings where non-P[8] types are prevalent.     

Whole genome characterisation of G11P[25] and G9P[19] rotavirus A strains from adult patients with diarrhoea in Nepal

Rotavirus A (RVA) causes acute diarrhoea in children and less frequently in adults. However, the knowledge about the genotype distribution of RVA strains circulating in adults is limited particularly in developing countries. This study aimed to characterise the RVA strains detected from adult patients with diarrhoea in Nepal. A total of 47 RVA positive stool samples from adult patients with diarrhoea in Kathmandu, Nepal during 2007–2008 were examined for the G and P genotypes by sequencing. Nearly half (49%) of the samples were genotyped as G9P[8] (n = 23), G1P[8], G2P[4] (n = 5 each), G12P[8] (n = 4), G12P[6] (n = 3), G1P[6] (n = 2), G3P[8] and G9P[6] (n = 1 each). Interestingly, two G11P[25] and one G9P[19] strains detected were further subjected to Illumina MiSeq next generation sequencing to determine their whole genome sequences. The genotype constellations of RVA/Human-wt/NPL/TK2615/2008/G11P[25] and RVA/Human-wt/NPL/TK2620/2008/G11P[25] were I12-R1-C1-M1-A1-N1-T1-E1-H1, whereas that of RVA/Human-wt/NPL/TK1797/2007/G9P[19] was I5-R1-C1-M1-A8-N1-T1-E1-H1. The 11 genes of TK2615 and TK2620 were virtually identical, and they were either porcine-like or unique except the VP2 and NSP1 genes which were of human RVA origin. The two G11P[25] strains were also very similar to KTM368, another G11P[25] isolated from a child in Nepal in 2004. On the other hand, no gene of TK1797 was likely to be of human RVA origin. The observation that porcine-like RVAs were detected from adult patients justifies further studies to explore the role of adults in the interspecies transmission of animal RVA to humans.     

A DS-1 like G9P[6] human strain CDC-6 as a new rotavirus vaccine candidate

Human rotavirus vaccine Rotarix® (G1P[8]) has shown broad cross protection against homotypic and heterotypic Wa-like human rotavirus strains among children worldwide. This vaccine, however, appears to induce slightly less or non-consistent protection against DS-1 like rotavirus P[4] strains in some settings. In addition, children who are secretor or Lewis-negative and are vaccinated with Rotarix® often experience breakthrough infection with P[6] strains. By contrast, P[6] strains infect all children, irrespective of their secretor or Lewis status. In the present study, we report successful adaptation of a DS-1 like human rotavirus G9P[6] strain (CDC-6) to high growth in Vero cells and identify sequence changes that may be critical for enhanced growth in vitro and attenuation in vivo. This human G9P[6] strain could serve as a promising new and potential low-cost vaccine candidate for global use, particularly in targeted population with secretor or Lewis-negative status and high prevalent DS-1 like P[6] strains.     

Clinical and genetic characteristics of unusual G12P[11] rotavirus strains recovered from neonates: A study from Pune,Western India

Rotavirus infections in neonates are generally nosocomial, and differ from pediatric infections both clinically and epidemiologically. These infections are predominantly asymptomatic and often associated with unusual strains. Globally, so far limited data is available on rotavirus infections in neonates admitted at Neonatal Intensive Care Unit. The aim of the present study is to determine the prevalence of rotavirus among neonates and to study their genetic characteristics. Stool specimens (n = 701) collected from neonates (n = 621) admitted during April 2016 to March 2018 mainly for prematurity, low birth weight and associated respiratory distress syndrome from two hospitals from Pune were tested for rotavirus, genotyped and representative strains were sequenced for the genes encoding outer capsid proteins, VP7 and VP4. Rotavirus was detected in 24.31% neonates. Majority of rotavirus infected neonates (98.68%) were asymptomatic. Peak rotavirus antigen detection (91.38%) occurred during the first 2 weeks of admission. Low, very low and normal birth weight neonates with gestational age ≥28 weeks had significantly higher rotavirus infection than those with extreme low birth weight with gestational age <28 weeks. Rotaviral infections occurred almost evenly throughout the year without an apparent peak in colder months. Predominance of unusual G12P[11] strains (97.1%) was observed. Phylogenetic analysis of the partial VP7 coding gene revealed all G12 strains clustered in lineage III and shared 96.94%–100% (nucleotide) and 96.26%–100% (amino acid) identities among themselves, and 95.69%–98.98% (nucleotide) and 94.77%–98.98% (amino acid) with other lineage III G12 strains respectively. Similarly VP4 partial gene sequences of P[11] study strains shared 97.5%–100% (nucleotide and amino acid) identities among themselves and highest 93.34%–94.53% (nucleotide) and 93.57%–94.64% (amino acid) identity with vaccine strain 116E, G9P[11]. The study highlights high frequency of unusual G12P[11] strains among neonates for the first time in western India and reaffirms limited strain diversity in this population. The knowledge of neonatal strains is important for estimating the efficacies of rotavirus vaccines.     

Dynamics of G2P[4] strain evolution and rotavirus vaccination: A review of evidence for Rotarix

Rotavirus (RV) gastroenteritis is a vaccine-preventable disease that creates high medical and economic burden in both developed and developing countries. Worldwide, more than 100 countries have introduced RV vaccines in their national immunization programs, and the remarkable impact of reducing the burden of severe childhood gastroenteritis has been unequivocally demonstrated. Currently, 2 oral vaccines (Rotarix, GSK and RotaTeq, Merck) are widely utilized. Recent temporary increases in the relative prevalence of G2P[4] RV strains have been observed in countries implementing RV vaccination. This comprehensive literature review aims to provide an insight on RV genotype evolution in the context of mass vaccination with Rotarix, particularly in the case of G2P[4]. In the post-vaccine era, strain surveillance data indicated temporal and spatial changes in countries both with and without RV vaccination programs. Annual fluctuations in G2P[4] prevalence seem to occur naturally, with no substantial differences between countries using Rotarix, RotaTeq or mixed vaccination programs. Moreover, Rotarix has been shown to be efficacious and effective against gastroenteritis caused by non-vaccine strains, including G2P[4]. These data indicate that shifts in RV genotype distribution are likely to constitute an inherent process of virus evolution to infect the human gut. Following RV vaccine introduction, incidences of RV gastroenteritis declined dramatically and mass vaccination will likely maintain this status, despite possible fluctuations in the relative distribution of genotypes. There is no conclusive evidence of unusual burst of new or vaccine-escape strains since global RV vaccines use. The emergence of strains with a potential to increase the current burden of RV disease should be continuously monitored and can only be established by exhaustive characterization of strains, including whole genomic sequencing. Given the natural fluctuations in RV strains over time, caution is advised when interpreting temporal changes in RV strain dynamics, as they could mistakenly be attributed to vaccination.     

Detection of the first G6P[14] human rotavirus strain from a child with diarrhea in Egypt

We report the first detection of a G6P[14] rotavirus strain in Egypt from the stool of a child participating in a hospital-based diarrhea surveillance study conducted throughout the year 2004. Rotavirus infection was initially detected using a rotavirus group A VP6 enzyme immunoassay; the P (VP4) and G (VP7) genotypes of the strain were identified by RT-PCR. We sequenced the VP7 gene and the VP8* portion of the VP4 gene and the strain displayed the strongest identity to the VP7 [>94% nucleotides (nt), >97% amino acids (aa)] and VP4 (>93% nt, >98% aa) sequences of PA169, a novel G6P[14] strain first isolated from a child in Italy during the winter of 1987. Additional sequencing and analysis of the other remaining structural (VP1–VP3, VP6) and non-structural (NSP1–NSP5) proteins support this animal-to-human reassortment theory. According to the full genome classification system, the G6P[14] strain (EGY3399) was assigned to G6-P[14]-I2-R2-C2-M2-A11-N2-T6-E2-H3 genotypes. The greatest similarity of EGY3399 NSP4 and NSP5 gene sequences were to those of ovine and simian origin, respectively. Coupled with other observations, our results suggest G6P[14] isolates rarely cause severe diarrhea in Egyptian children, and support other studies that indicate animal rotavirus contribute to the genetic diversity of rotavirus detected from humans through interspecies transmission and single or multiple segments reassortment.     

Whole genomic analyses of asymptomatic human G1P[6], G2P[6] and G3P[6] rotavirus strains reveal intergenogroup reassortment events and genome segments of artiodactyl origin

Although P[6] group A rotaviruses (RVA) cause diarrhoea in humans, they have been also associated with endemics of predominantly asymptomatic neonatal infections. Interestingly, strains representing the endemic and asymptomatic P[6] RVAs were found to possess one of the four common human VP7 serotypes (G1–G4), and exhibited little antigenic/genetic differences with the VP4 proteins/VP4 encoding genome segments of P[6] RVAs recovered from diarrhoeic children, raising interest on their complete genetic constellations. In the present study, we report the overall genetic makeup and possible origin of three such asymptomatic human P[6] RVA strains, RVA/Human-tc/VEN/M37/1982/G1P2A[6], RVA/Human-tc/SWE/1076/1983/G2P2A[6] and RVA/Human-tc/AUS/McN13/1980/G3P2A[6]. G1P[6] strain M37 exhibited an unusual genotype constellation (G1-P[6]-R1-C1-M1-A1-N1-T2-E1-H1), not reported previously, and was found to originate from possible intergenogroup reassortment events involving acquisition of a DS-1-like NSP3 encoding genome segment by a human Wa-like RVA strain. On the other hand, G2P[6] strain 1076 exhibited a DS-1-like genotype constellation, and was found to possess several genome segments (those encoding VP1, VP3, VP6 and NSP4) of possible artiodactyl (ruminants) origin on a human RVA genetic backbone. The whole genome of G3P[6] strain McN13 was closely related to that of asymptomatic human Wa-like G3P[6] strain RV3, and both strains shared unique amino acid changes, which might have contributed to their attenuation. Taken together, the present study provided insights into the origin and complex genetic diversity of P[6] RVAs possessing the common human VP7 genotypes. This is the first report on the whole genomic analysis of a G1P[6] RVA strain.     

Canine-origin G3P[3] rotavirus strain in child with acute gastroenteritis

Infection by an animal-like strain of rotavirus (PA260/97) was diagnosed in a child with gastroenteritis in Palermo, Italy, in 1997. Sequence analysis of VP7, VP4, VP6, and NSP4 genes showed resemblance to a G3P[3] canine strain identified in Italy in 1996. Dogs are a potential source of human viral pathogens.     

Full genome characterization of a porcine-like human G9P[6] rotavirus strain isolated from an infant in Belgium

Interspecies transmissions of group A rotavirus (RVA) strains among animals and humans are thought to take place frequently. During a RVA surveillance study in Belgium we isolated an unusual G9P[6] RVA strain, RVA/human-wt/BEL/BE2001/2009/G9P[6], from a 1month old boy, which did not cluster with other G9 or P[6] strains isolated in Belgium. In this study we sequenced and characterized the complete genome of this unusual G9P[6] strain BE2001. Phylogenetic analyses of all 11 genes revealed a unique genotype constellation: G9-P[6]-I5-R1-C1-M1-A8-N1-T7-E1-H1. The VP6 and NSP1 genotypes I5 and A8 are genotypes commonly found in porcine RVA strains, while the VP7 and VP4 genes clustered only distantly to human lineages of G9 and P[6], respectively. The VP1, VP2, VP3, NSP2, NSP4 and NSP5 genes all belonged to Wa-like genotypes, but clustered more closely to porcine strains than to human strains. NSP3 belonged to the rare T7 genotype. Thus far, T7 genotypes have only been detected in one porcine-like human strain (RVA/human-tc/CHN/R479/2004/G4P[6]), one bovine-like human strain (RVA/human-xx/IND/mani-265/2007/G10P[6]) and one bovine RVA strain (RVA/cow-tc/GBR/UK/1973/G6P7[5]). Sequence analysis of the BE2001 NSP5 gene segment revealed a 300 nucleotide duplication in the 3' end non-coding region. BE2001 is most likely a direct interspecies transmission between a pig and a human. Inquiry with the patient's physician revealed that the father of the patient had been working on a pig farm in the week the patient became ill, providing a plausible route of transmission.     

Novel NSP1 genotype characterised in an African camel G8P[11] rotavirus strain

Animal–human interspecies transmission is thought to play a significant role in influencing rotavirus strain diversity in humans. Proving this concept requires a better understanding of the complete genetic constellation of rotaviruses circulating in various animal species. However, very few whole genomes of animal rotaviruses, especially in developing countries, are available. In this study, complete genetic configuration of the first African camel rotavirus strain (RVA/Camel-wt/SDN/MRC-DPRU447/2002/G8P[11]) was assigned a unique G8-P[11]-I2-R2-C2-M2-A18-N2-T6-E2-H3 genotype constellation that has not been reported in other ruminants. It contained a novel NSP1 genotype (genotype A18). The evolutionary dynamics of the genome segments of strain MRC-DPRU447 were rather complex compared to those found in other camelids. Its genome segments 1, 3, 7–10 were closely related (>93% nucleotide identity) to those of human–animal reassortant strains like RVA/Human-tc/ITA/PA169/1988/G6P[14] and RVA/Human-wt/HUN/Hun5/1997/G6P[14], segments 4, 6 and 11 shared common ancestry (>95% nucleotide identity) with bovine rotaviruses like strains RVA/Cow-wt/CHN/DQ-75/2008/G10P[11] and RVA/Cow-wt/KOR/KJ19-2/XXXX/G6P[7], whereas segment 2 was closely related (94% nucleotide identity) to guanaco rotavirus strain RVA/Guanaco-wt/ARG/Rio_Negro/1998/G8P[1]. Its genetic backbone consisted of DS-1-like, AU-1-like, artiodactyl-like and a novel A18 genotype. This suggests that strain MRC-DPRU447 potentially emerged through multiple reassortment events between several mammalian rotaviruses of at least two genogroups or simply strain MRC-DPRU447 display a unique progenitor genotypes. Close relationship between some of the genome segments of strain MRC-DPRU447 to human rotaviruses suggests previous occurrence of reassortment processes combined with interspecies transmission between humans and camels. The whole genome data for strain MRC-DPRU447 adds to the much needed animal rotavirus data from Africa which is limited at the moment.     

A rare G1P[6] super-short human rotavirus strain carrying an H2 genotype on the genetic background of a porcine rotavirus

Rotavirus strains with a rearranged 11th genome segment may show super-short RNA electropherotypes. Examples from human strains were limited to seven strains, 69M, 57M, B37, Mc345, AU19, B4106 and BE2001, which have a variety of G and P genotypes. AU19 is a rare G1P[6] human rotavirus strain detected in a Japanese infant with severe acute gastroenteritis. This study was undertaken to better understand the origin of AU19 by determining the genotype constellation of AU19. Upon nearly-full genome sequencing, AU19 had a G1-P[6]-I5-R1-C1-M1-A8-N1-T1-E1-H2 genotype constellation. Possession of I5 and A8 genotypes is indicative of its porcine rotavirus origin, whereas possession of H2 genotype is indicative of its DS-1 like human rotavirus origin. At the phylogenetic lineage level for the genome segments that share the genotype between porcine and human rotaviruses, the VP1-4, VP7, NSP3-4 genes were most closely related to those of porcine rotaviruses, but the origin of the NSP2 gene was inconclusive. As to the NSP5 gene, the lineage containing AU19 and the other three super-short human strains, 69M, 57M and B37, carrying the H2 genotype (H2b) clustered with the lineage to which DS-1- like short strains belonged (H2a) albeit with an insignificant bootstrap support. Taken all these observations together, AU19 was likely to emerge as a consequence of interspecies transmission of a porcine rotavirus to a child coupled with the acquisition of a rare H2b genotype by genetic reassortment probably from a co-circulating human strain. The addition of the AU19 NSP5 sequence to much homogeneous H2b genotypes shared by previous super-short rotavirus strains made the genetic diversity of H2b genotypes as diverse as that of the H2a genotype, lending support to the hypothesis that super-short strains carrying H2b genotype have long been circulating unnoticed in the human population.     

Detection of rare reassortant G5P[6] rotavirus,Bulgaria

During the ongoing rotavirus strain surveillance program conducted in Bulgaria, an unusual human rotavirus A (RVA) strain, RVA/Human/BG/BG620/2008/G5P[6], was identified among 2200 genotyped Bulgarian RVAs. This strain showed the following genomic configuration: G5–P[6]–I1–R1–C1–M1–A8–N1–T1–E1–H1. Phylogenetic analysis of the genes encoding the neutralization proteins and backbone genes identified a probable mixture of RVA genes of human and porcine origin. The VP1, VP6 and NSP2 genes were more closely related to typical human rotavirus strains. The remaining eight genes were either closely related to typical porcine and unusual human–porcine reassortant rotavirus strains or were equally distant from reference human and porcine strains. This study is the first to report an unusual rotavirus isolate with G5P[6] genotype in Europe which has most likely emerged from zoonotic transmission. The absence of porcine rotavirus sequence data from this area did not permit to assess if the suspected ancestral zoonotic porcine strain already had human rotavirus genes in its genome when transmitted from pig to human, or, the transmission was coupled or followed by gene reassortment event(s). Because our strain shared no neutralization antigens with rotavirus vaccines used for routine immunization in children, attention is needed to monitor if this G–P combination will be able to emerge in human populations. A better understanding of the ecology of rotavirus zoonoses requires simultaneous monitoring of rotavirus strains in humans and animals.     

Emergence of unusual G6P[6] rotaviruses in children, Burkina Faso, 2009-2010

To obtain more information about rotavirus (ROTAV) genotypes in Burkina Faso, we characterized 100 ROTAVs isolated from fecal samples of children with acute gastroenteritis in the capital city of Ouagadougou, during December 2009-March 2010. Of note, 13% of the ROTAV-positive samples, including those with mixed infections, were positive for the unusual G6 genotype ROTAV strain. The genotypes identified were G9P[8], G6P[6], G1P[6], G3P[6], G1P[8], and G2P[4]. G9P[8] subgroup (SG)II strains dominated during the beginning of the ROTAV season, but later in the season, other G types associated with P[6] and SGI specificity emerged. This emergence was related to a shift in the overall age of infected children; ROTAV SGII infected younger children and induced more severe symptoms. The finding of a high incidence of G6P[6] strains highlights the need for long-term surveillance of ROTAV strains in Burkina Faso, especially when ROTAV vaccination is being considered in several African countries.     

Genetic diversity of G9 rotavirus strains circulating among diarrheic children in North India: A comparison with 116E rotavirus vaccine strain

The parental rotavirus strain 116E (G9P[11]) used to generate Rotavac® vaccine was isolated in 1986 in New Delhi. Thenceforward, there is no comprehensive report on diversity of G9 rotavirus strains from 116E; therefore, the present study evaluates the VP7 gene sequence diversity of G9 strains (retrieved from GenBank) from different geographical regions (1987–2016). Additionally, 22 recently collected G9 strains from Himachal Pradesh and Delhi (2013–2016) were included in the phylogenetic analysis. Interestingly, unlike 116E which belong to lineage-II all other G9 rotavirus including these 22 samples clustered together in a separate lineage (III). Further, six amino acid substitutions including one novel, K143M (epitope 7-2) different from 116E were detected mostly in the neutralization epitopes of VP7 protein (neutralization escape mutants). Overall, the accumulation of identified substitutions in VP7 epitopes and evolution of G9 strains in India may have impact on Rotavac® efficacy.     

Whole genome sequence analysis of bovine G6P[11] rotavirus strain found in a child with gastroenteritis

During the rotavirus strain surveillance in Slovenia, G6P[11] bovine rotavirus strain was detected in a 5 months old boy with gastroenteritis. The strain was enrolled in a whole genome sequence analysis to determine its genome segment composition and genetic characteristics. Genotype composition for the whole genome was G6-P[11]-I2-R2-C2-M2-A13-N2-T6-E2-H3, reflecting similarities with bovine rotavirus strains. The bovine origin of the strain was confirmed in all genome segments, showing the highest nucleotide identity with bovine rotavirus strains and clustering of the RVA/Human-wt/SVN/SI-R56/07/2007/G6P[11] together with bovine rotavirus strains in phylogenetic analysis. This is the first bovine G6P[11] rotavirus strain with the whole genome analysis and the first report on rotavirus G6P[11] genotype detected in humans.     

Molecular characterization of the first G24P[14] rotavirus strain detected in humans

Here we report the genome of a novel rotavirus A (RVA) strain detected in a stool sample collected during routine surveillance by the Centers for Disease Control and Prevention's New Vaccine Surveillance Network. The strain, RVA/human-wt/USA/2012741499/2012/G24P[14], has a genomic constellation of G24-P[14]-I2-R2-C2-M2-A3-N2-T9-E2-H3. The VP2, VP3, VP7 and NSP3 genes cluster phylogenetically with bovine strains. The other genes occupy mixed clades containing animal and human strains. Strain RVA/human-wt/USA/2012741499/2012/G24P[14] most likely is the product of interspecies transmission and reassortment events. This is the second report of the G24 genotype and the first report of the G24P[14] genotype combination in humans.