Hepatitis delta virus genomic and antigenomic RNAs contain a self-cleavage site hypothesized to function in processing the viral RNA during replication. Self-cleavage requires only a divalent cation and is mediated at the genomic site by a sequence of less than 85 nucleotides. We propose that the genomic self-cleaving sequence element and a corresponding sequence from the anti-genomic RNA could generate related secondary structures. The region of the antigenomic sequence, predicted from the proposed structure, was synthesized and shown to be sufficient for self-cleavage. Evidence for two stems which form a tertiary interaction was obtained by site-specific mutagenesis of the antigenomic sequence. Efficient self-cleavage in 10 M formamide or 5 M urea, also a property of the genomic sequence, was dependent on base-pairing in both stems. But in the absence of denaturants, the stem distal to the site of cleavage was not required, suggesting that the tertiary interaction stabilizes the structure required for self-cleavage.
Ribozymes use a number of the same catalytic strategies as protein enzymes. However, general base catalysis by a ribozyme has not been demonstrated. In the hepatitis delta virus antigenomic ribozyme, imidazole buffer rescued activity of a mutant with a cytosine-76 (C76) to uracil substitution. In addition, a C76 to adenine substitution reduced the apparent pKa (where Ka is the acid constant) of the self-cleavage reaction by an amount consistent with differences in the pKa values of these two side chains. These results suggest that, in the wild-type ribozyme, C76 acts as a general base. This finding has implications for potential catalytic functions of conserved cytosines and adenines in other ribozymes and in ribonuclear proteins with enzymatic activity.
Hepatitis delta virus (HDV) is a small single-stranded RNA satellite of hepatitis B virus. Although it is a human pathogen, it shares a number of features with a subset of the small plant satellite RNA viruses, including self-cleaving sequences in the genomic and antigenomic sequences of the viral RNA. The selfcleaving sequence is critical to viral replication and is thought to function as a ribozyme in vivo to process the products of rolling-circle replication to unit-length molecules. A divalent cation is required for cleavage and while a structural role is implicated for metal ions, a more direct role for a metal ion in catalysishas not yet been proven. A minimal natural ribozyme sequence with proficient in viiro self-cleavage activity is about 85 nucleotides long and adopts a secondary structure with four paired regions (Pl-P4).The two pairings that define the 5' and 3' boundaries of the ribozyme, PI and P2, form an atypical pseudoknot arrangement. This secondary structure places a number of constraints on the possible tertiary folding of the sequence, which together with chemical probing, photo-cross-linking, mutagenesis and computer-assisted modeling provides clues to the three-dimensional structure. The data are consistent with a model in which the cleavage site, located at the 5' end of PI, is in close proximity to three singlestranded regions, consisting of a hairpin loop at the end of P3 and two sequences joining P1 to P4 and P4 to P2. While the natural forms of the HDV ribozymes appear to be prone to misfolding, biochemical and mutagenesis studies from a number of laboratories has allowed the production of trans-acting ribozymes and smaller more active cis-acting ribozymes, both of which will aid in further mechanistic and structural studies of this RNA.
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