Cell type-specific proteins which interact with the 5' nontranslated region of hepatitis A virus RNA

Abstract

The 5' nontranslated region (5'NTR) of hepatitis A virus (HAV) RNA contains structural elements which facilitate 5' cap-independent initiation of virus translation and are likely to interact with cellular proteins functioning as translation initiation factors. To define these interactions, we characterized the binding of ribosome-associated proteins from several cell types to synthetic RNAs representing segments of the 5'NTR by using a UV cross-linking/label transfer assay. Four major proteins (p30, p39, p57, and p110) were identified. p30 and p39 were present in ribosomal salt washes prepared only from HAV-permissive BS-C-1 and FRhK-4 cells, while p57 was found only in HeLa cells and rabbit reticulocyte lysates. p110 was present in all cell types. Both p30 and p39 bound to multiple sites within the 5'NTR. Efficient transfer of label to p30 occurred with minimal RNA probes representing nucleotides (nt) 96 to 155, 151 to 354, and, to a much lesser extent, 634 to 744, while label transfer to p39 occurred with probes representing nt 96 to 155 and 634 to 744. All of these probes represent regions of the 5'NTR which are rich in pyrimidines. Competitive inhibition studies indicated that both p30 and p39 bound with greater affinity to sites in the 5' half of the NTR (a probe representing nt 1 to 354) than to the more 3' site (nt 634 to 744). Binding of p39 to the probe representing nt 96 to 155 was inhibited in the presence of an equal amount of proteins derived from HeLa cells, suggesting that p39 shares binding site specificity with one or more HeLa cell proteins. A 57-kDa protein in HeLa cell protein extracts reacted with antibody to polypyrimidine tract-binding protein in immunoblots, but no immunoreactive protein was identified in a similar BS-C-1 protein fraction. These results demonstrate that ribosome-associated proteins which bind to the 5'NTR of HAV vary substantially among different mammalian cell types, possibly accounting for differences in the extent to which individual cell types support growth of the virus. Mutations in the 5'NTR which enhance the growth of HAV in certain cell types may reflect specific adaptive responses to these or other proteins.