In 2006-07, 77 cases of gastroenteritis in Rochester, NY, USA were associated with rotavirus genotype G12P[8]. Sequence analysis identified a high degree of genetic relatedness among the VP7 and VP4 genes of the Rochester G12P[8] strains and between these strains and currently circulating human G12P[8] strains. Out of 77 samples, two and seven unique nucleotide sequences were identified for VP7 and VP4 genes, respectively. Rochester strain VP7 genes were found to occupy the G12-III lineage and VP4 genes clustered within the P[8]-3 lineage. Six strains contained non-synonymous nucleotide substitutions that produced amino acid changes at 6 sites in the VP8 * region of the VP4 gene. Two sites (amino acids 242 and 246) were located in or near a described trypsin cleavage site. Selection analyses identified one positively selected VP7 site (107) and strong purifying selection at 58 sites within the VP7 gene as well as 2 of the 6 variant sites (79 and 218) in VP4.

A real-time reverse transcription-polymerase chain reaction (qRT-PCR) assay using the recombinant thermostable Thermus thermophilus (rTth) enzyme was developed to detect and quantify rotavirus A (RVA). By using rTth polymerase, significant improvement was achieved over the existing real-time RT-PCR assays which require denaturation of the RVA double-stranded RNA (dsRNA) prior to assay set-up. Using a dsRNA transcript for segment 7 which encodes the assay target NSP3 gene, the limit of detection for the improved assay was calculated to be approximately 1 genome copy per reaction. The NSP3 qRT-PCR assay was validated using a panel of 1906 stool samples, 23 reference RVA strains, and 14 non-target enteric virus samples. The assay detected a diverse number of RVA genotypes and did not detect other enteric viruses demonstrating analytical sensitivity and specificity for RVA when testing stool samples. A XenoRNA internal process control was introduced and detected in a multiplexed qRT-PCR format. Because it does not require an antecedent dsRNA denaturation step, this assay reduces the possibility of sample cross-contamination and requires less hands-on time than other published qRT-PCR protocols for RVA detection.

Knowledge from early outbreaks is limited regarding the virus detection and illness duration of the 2009 pandemic influenza A (H1N1) infections. During the period from April to May 2009 in Texas, we collected serial nasopharyngeal (NP) and stool specimens from 35 participants, testing by real-time reverse transcriptase-polymerase chain reaction (rRT-PCR) and culture. The participants were aged 2 months to 71 years; 25 (71%) were under 18. The median duration of measured fever was 3.0 days and of virus detection in NP specimens was 4.2 days; however, few specimens were collected between days 5-9. The duration of virus detection (4.2 days) was similar to the duration of fever (3.5 days) (RR, 1.14; 95% CI, .66-1.95; P=.8), but was shorter than the duration of cough (11.0 days) (RR, .41; 95% CI, .24-.68; P.001). We detected viral RNA in two participants' stools. All cultures were negative. This investigation suggests that the duration of virus detection was likely similar to the seasonal influenza virus.

BACKGROUND: A live, attenuated rotavirus vaccine, RotaTeq(R), was approved in 2006 for immunization of infants in the United States. To monitor the distribution of rotavirus genotypes before and after vaccine introduction, the Centers for Disease Control and Prevention conducted strain surveillance with the National Rotavirus Strain Surveillance System. METHODS: Over 3 rotavirus seasons, 2005-2006, 2006-2007, and 2007-2008, National Rotavirus Strain Surveillance System laboratories collected rotavirus-positive stool specimens and submitted them to the Centers for Disease Control and Prevention. Rotavirus strains were G- and P-genotyped by multiplex reverse transcription-polymerase chain reaction or nucleotide sequencing. RESULTS: During 2005-2006 and 2006-2007 seasons, G1 was the dominant G-type but in the 2007-2008 season, G3 replaced G1 as the most frequently detected strain. Four genotypes, G1P[8], G2P[4], G3P[8], and G9P[8] were detected in every season. Uncommon strains observed during the study period were G2P[8], G1P[6], G2P[6], G4P[6], G1P[4], G3P[9], G12P [6], and G12P[8]. The mean age of rotavirus cases in the 2007-2008 season increased significantly in patients less than 3 years old compared with the 2 previous seasons. CONCLUSIONS: The increased overall prevalence of G3P [8] strains in 2007-2008, the first rotavirus season with reasonable rotavirus vaccine coverage, was consistent with Australian reports of G3 dominance following RotaTeq introduction. However, these strain changes in both countries have occurred in the context of large declines in severe rotavirus disease and we cannot rule out that they are simply the result of naturally occurring changes in rotavirus strain prevalence. These findings underscore the need for careful monitoring of strains to assess possible vaccine pressure-induced changes and vaccine effectiveness against various rotavirus genotypes.

The diversity of group A rotaviruses is generated by multiple mechanisms, mainly by accumulation of point mutations and genetic exchange of cognate genome segments (reassortment) between different strains.1 Reassortment may occur between rotaviruses of different host species, providing an opportunity for heterologous rotavirus strains to introduce and then stably sustain parts of their genome in populations of a particular host species. In contrast, the detection of a heterologous rotavirus strain without preceding reassortment with a homologous strain is a rare event. Rotaviruses of cattle have been shown to play a role in generation of human rotavirus strain diversity by reassortment, however, to the best of our knowledge no definitive evidence for direct interspecies transmission of a bovine strain can be found in the literature.[1], [2] In this report a zoonotic bovine rotavirus strain is described based on sequencing of fragments for each of its 11 genes (Fig. 1).

BACKGROUND: Rotavirus vaccine was recommended for routine use among US infants in 2006. To provide prevaccine data, we conducted strain surveillance for 9 consecutive seasons during 1996-2005. METHODS: Using reverse-transcriptase polymerase chain reaction genotyping and nucleotide sequencing, we determined P/G genotypes of >3100 rotavirus strains collected in up to 12 cities each year from different US regions. RESULTS: The most prevalent strain globally, P[8] G1, was the most prevalent each year in the United States (overall, 78.5% of strains; range, 60.0%-93.9%), and 9.2% of the samples were P[4] G2, 3.6% were P[8] G9, 1.7% were P[8] G3, and 0.8% were P[8] G4. Genotype P[6] G9, which emerged in 1995, was detected continuously for several seasons (from 1996-1997 to 2000-2001, 0.2%-5.4%) but was not identified in the subsequent 4 seasons. Single or a few detections of rare genotypes (eg, P[6] G12, P[9] G6, and P[9] G3) were observed during several rotavirus seasons at frequencies of 0.5%-1.7% and, overall, comprised 0.6% of all the samples from the entire surveillance period. Several globally common strains in addition to G1, especially G2 and G9, circulated at high prevalence (33%-62%) in some cities during certain years. CONCLUSIONS: Almost 85% of strains during 1996-2005 had either a G or P antigen that is present in both RotaTeq (Merck) and Rotarix (GlaxoSmithKline). Monitoring of strains after introduction of rotavirus vaccines is important.