Relativistic density-dependent Hartree-Fock approach for finite nuclei

Two precore predominant mutations of human hepatitis B virus (HBV) at either nucleotide (nt) 1896 or nt 1899 often occur in combination. At nt 1896, a G to A mutation creates a TAG stop codon at codon 28 of precore protein. At nt 1899, a G to A mutation changes glycine at codon 29 to aspartic acid. To assess the effect of each individual mutation as well as any interaction between these two mutations, HBV derivatives bearing one or both precore predominant mutations have been constructed. HBV e-Ag-negative mutants bearing a TAG stop codon mutation at codon 28 uniformly replicate at least 20-fold better than mutants bearing a TGA stop codon at the same amino acid position, irrespective of the sequence context at nt 1899. A single mutation at nt 1899, changing the wild-type G to a pyrimidine (T or C) is deleterious to viral RNA encapsidation and DNA replication. Our results explain in part why only a purine (G or A) at nt 1899, never a pyrimidine, is observed in natural HBV genomes. The effects caused by these two closely linked mutations on viral replication are not independent of each other. The stringent selection for a highly efficient RNA encapsidation element may play a crucial role in the natural occurrence of these two closely linked precore mutations. The putative 27-amino-acid peptide resulting from the truncation of precore by the nt 1896 mutation has no apparent effect on viral replication. The preferential occurrence of the G to A mutation at nt 1896 and 1899, instead of at other nonpredominant positions, is likely to be a combined consequence of both selection and higher intrinsic mutation frequency at these positions.