Heterogeneity and common features of defective hepatitis B virus genomes derived from spliced pregenomic RNA.

Defective hepatitis B virus (HBV) genomes derived from packaging and reverse transcription of spliced RNA pregenomes were reported to be associated with progression to chronic infection. Since only two types with similarly spliced regions were characterized so far we reasoned that additional "spliced" genome variants may exist. Therefore, we isolated a large number of defective HBV genomes from sera of seven chronic carriers by full-length PCR. Forty-eight were found to contain deletions caused by splicing as identified by cloning, subgenomic PCR, and sequencing. In total, 11 types of spliced genomes derived from excision of 10 different introns were present in various combinations in each serum. This diversity resulted from alternative usage of five splice donor and four acceptor sites present in most but not all HBV genotypes. All spliced genomes shared sequence elements essential for replication as well as for transcription of the pre-C and pregenome/C mRNAs and the X mRNA. Moreover, all contained the coding regions for the X protein and for precore/core or precore/ core fusion proteins but lacked the pre-S/S gene promoters. These data demonstrate substantial and HBV genotype-dependent diversity of spliced genomes from which a variety of aberrant precore/core fusion proteins and normal X protein but no functional envelope and P proteins could be expressed. These genomes and the encoded proteins may play a role in the viral life cycle, persistence, and pathogenesis.

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