Site-specific RNA binding by a hepatitis B virus reverse transcriptase initiates two distinct reactions: RNA packaging and DNA synthesis.

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J Virol. 1994 September; 68(9): 5579-5587

Site-specific RNA binding by a hepatitis B virus reverse transcriptase initiates two distinct reactions: RNA packaging and DNA synthesis.

J R Pollack and D Ganem

Department of Biochemistry and Biophysics, University of California Medical Center, San Francisco 94143-0502.

ABSTRACT

Hepatitis B viruses encode a polymerase (P) protein with keyroles in both reverse transcription and genomic RNA encapsidation.Genetic analysis of cis-acting signals required for viral replicationimplicates an RNA stem-loop structure in both RNA packagingand the initiation of reverse transcription, a process in whichP protein also serves as the primer. We now show that duck hepatitisB virus (DHBV) polymerase binds specifically and with high affinityto this RNA stem-loop structure. Mutational analysis indicatesthat all mutations in the RNA target that inhibit the P protein-RNAinteraction inhibit both in vivo RNA packaging and in vitroDNA priming to comparable extents. However, certain mutationsin the loop region of the RNA have minimal impact on P protein-RNAbinding but are nonetheless severely defective for packagingand DNA synthesis. Thus, P protein-RNA complex formation isnecessary but not sufficient to initiate these activities. Inaddition, examination of RNA binding by truncated P proteinsindicates that the C terminus of the polymerase, although requiredfor RNA encapsidation in vivo, is dispensable for RNA bindingand DNA priming.

J Virol. 1994 September; 68(9): 5579-5587

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