ABSTRACT
Pregenomic RNA (pgRNA) plays two major roles in the hepadnavirus life cycle. It is the mRNA for two proteins required for DNA replication, C and P, and it is the template for reverse transcription. pgRNA is a terminally redundant transcript whose synthesis does not involve RNA splicing. For duck hepatitis B virus (DHBV), a spliced RNA is derived from pgRNA by removal of a single intron. The mechanism for the simultaneous cytoplasmic accumulation of unspliced (pgRNA) and spliced RNA was not known. We found that mutations within two regions of the DHBV genome reduced the level of pgRNA while increasing the level of spliced RNA. One region is near the 5′ end of pgRNA (region A), while the second is near the middle of pgRNA (region B). Inspection of the DHBV nucleotide sequence indicated that region A could base pair with region B. The 5′ and 3′ splice sites of the intron of the spliced RNA are within regions A and B, respectively. Substitutions that disrupted the predicted base pairing reduced the accumulation of pgRNA and increased the accumulation of spliced RNA. Restoration of base pairing, albeit mutant in sequence, resulted in restoration of pgRNA accumulation with a decrease in the level of spliced RNA. Our data are consistent with a model in which splicing of the pgRNA is suppressed by a secondary structure between regions A and B that occludes the splicing machinery from modifying pgRNA.
Mutations in the pre-core region of hepatitis B virus serve to enhance the stability of the secondary structure of the pre-genome encapsidation signal.
