Representative strains possessing distinct electropherotypes were examined further by nucleotide sequencing and RNA–RNA hybridization following cell-culture adaptation. Partial or full-length genes encoding VP7, VP4, VP6, and NSP4 were amplified by RT-PCR and the products were used directly for nucleotide sequencing (Cogenics, Essex, UK). Primers Beg9 and End9 were used to amplify a 1062 bp VP7 fragment [24]; primers con2 and con3 were Venetoclax purchase used to amplify a 877 bp VP4 fragment [25]; primers GEN_VP6F and GEN_VP6R were used to amplify a 1356 bp VP6 fragment [26];
and primers BegG10 and EndG10 were used to amplify a 750 bp NSP4 fragment [27]. Genotype assignment was undertaken according to the criteria established by the Rotavirus Classification Working Group [12]. Phylogenetic analysis of the genome segments of the strains representing each of the major genotype combination was carried out using MEGA ver. 4.0 [28] by
drawing trees using the neighbour-joining method [29]. Bootstrap analysis of 2000 replicates was conducted to identify the significance of branching of the constructed tree. Rotavirus strains subjected to RNA–RNA hybridization assays were adapted to cell SAR405838 in vitro culture according to the method of Kutsuzawa et al. [30]. RNA–RNA hybridization was carried out as previously described [18]. Briefly, the genomic RNA was transcribed into 11 positive-sense RNAs (i.e., transcription probes) in the presence of [32P]-labelled GTP using endogenous viral RNA polymerase present in purified double-layered particles. Thus, three different probes were prepared from RIX4414 (G1P[8], long RNA pattern), MAL60 (G8P[4], short RNA pattern) Sitaxentan and MAL88 (G12P[6], short RNA pattern). Hybridization was allowed to occur at high stringency conditions (at 65 °C, for 16 h) between the genomic RNAs from various Malawian strains as well as Wa (G1P[8], long RNA pattern) and KUN (G2P[4], short RNA pattern), and each of the three probes. Hybrids were then separated by electrophoresis on a 10% polyacrylamide gel, and the dried gels were
exposed to imaging plates and read with BAS5000 (Fuji film, Tokyo, Japan). Of 88 rotavirus-positive faecal specimens, 43 (49%) showed identifiable RNA migration patterns upon polyacrylamide gel electrophoresis. These comprised genotypes G8P[4] (N = 19), G12P[6] (N = 11), G9P[8] (N = 4), G1P[8] (N = 3), G12P[8] (N = 2), G1P[6] (N = 1), G8P[6] (N = 1), G8P[8] (N = 1), and G2P[4] (N = 1). All G8P[4], G8P[6] and G2P[4] strains showed short RNA patterns with slower-moving genome segments 10 and 11, while all G9P[8], G1P[8], G12P[8], G8P[8] and G1P[6] strains showed long RNA patterns ( Fig. 1). Among 11 G12P[6] strains with identifiable electropherotypes, 8 showed short RNA patterns whereas 3 showed long RNA patterns.