Large deletion mutations involving the first pyrimidine-rich tract of the 5' nontranslated RNA of human hepatitis A virus define two adjacent domains associated with distinct replication phenotypes.

The 5' nontranslated RNA (5'NTR) of the HM175 strain of human hepatitis A virus contains several pyrimidine-rich regions, the largest and most 5' of which (pY1) is an almost pure polypyrimidine tract located between nucleotides (nt) 99 and 138, which includes five tandem repeats of the sequence motif (U)UUCC(C). Previous modeling of the RNA secondary structure suggested that this region was likely to be single-stranded, but repetitive RNase V1 cleavage sites within these (U)UUCC(C) motifs indicated that pY1 possesses an ordered structure. To assess the role of this domain in replication of the virus, a series of large deletion mutations were created which involved the pY1 domain of an infectious cDNA clone. Deletion of 44 nt between nt 96 and 139, including the entire pY1 domain, did not reduce the capacity of the virus to replicate in BS-C-1 or FRhK-4 cells, as assessed by the size of replication foci in radioimmunofocus assays or by virus yields under one-step growth conditions. In contrast, viable virus could not be recovered from transfected RNAs in which the deletion was extended in a 5' direction by an additional 3 nt (delta 93-134), most likely because of the destabilization of a predicted stem-loop structure upstream of pY1. Deletion mutations extending in a 3' fashion to nt 140, 141, or 144 resulted in moderately (delta 96-140 and delta 96-141) or strongly (delta 99-144, delta 116-144, and delta 131-144) temperature-sensitive replication phenotypes. Although deletion of the pY1 domain did not by itself affect the replication phenotype of virus, the additional deletion of sequence elements within the pY1 domain (nt 99 to 130) substantially enhanced the temperature-sensitive phenotype of delta 131-144 virus. These data suggest that the (U)UUCC(C) motifs within the pY1 domain are conserved among wild-type viruses in order to serve a function required during infection in vivo but not in cell culture. In contrast, the single-stranded region located immediately downstream of pY1 (nt 140 to 144) is essential for efficient replication in cultured cells at physiological temperature. Viruses with deletion mutations involving nt 140 to 144 and viruses with large pY1 deletions but normal replication phenotypes in cell culture may have attenuation properties which could be exploited for vaccine development.