Antigenomic RNA of human hepatitis delta virus can undergo self-cleavage.

The structure and replication of the single-stranded circular RNA genome of hepatitis delta virus (HDV) are unique relative to those of known animal viruses, and yet there are real similarities between HDV and certain infectious RNAs of plants. Therefore, since some of the latter RNAs have been shown to undergo in vitro site-specific cleavage and even ligation, we tested the hypothesis that similar events might also occur for HDV RNA. In partial confirmation of this hypothesis, we found that in vitro the RNA complementary to the HDV genome, the antigenomic RNA, could undergo a self-cleavage that was not only more than 90% efficient but also occurred only at a single location. This cleavage was found to produce junction fragments consistent with a 5'-hydroxyl and a cyclic 2',3'-monophosphate. Since the observed cleavage was both site-specific and occurred only once per genome length, we propose that the site may be relevant to the normal intracellular replication of the HDV genome. Because the site is located almost adjacent to the 3' end of the delta antigen-coding region, the only known functional open reading frame of HDV, we suggest that the cleavage may have a role not only in genome replication but also in RNA processing, helping to produce a functional mRNA for the translation of delta antigen.     

A nested double pseudoknot is required for self-cleavage activity of both the genomic and antigenomic hepatitis delta virus ribozymes.

The crystal structure of a genomic hepatitis delta virus (HDV) ribozyme 3' cleavage product predicts the existence of a 2 bp duplex, P1.1, that had not been previously identified in the HDV ribozymes. P1.1 consists of two canonical C-G base pairs stacked beneath the G.U wobble pair at the cleavage site and would appear to pull together critical structural elements of the ribozyme. P1.1 is the second stem of a second pseudoknot in the ribozyme, making the overall fold of the ribozyme a nested double pseudoknot. Sequence comparison suggests the potential for P1.1 and a similar fold in the antigenomic ribozyme. In this study, the base pairing requirements of P1.1 for cleavage activity were tested in both the genomic and antigenomic HDV ribozymes by mutagenesis. In both sequences, cleavage activity was severely reduced when mismatches were introduced into P1.1, but restored when alternative base pairing combinations were incorporated. Thus, P1.1 is an essential structural element required for cleavage of both the genomic and antigenomic HDV ribozymes and the model for the antigenomic ribozyme secondary structure should also be modified to include P1.1.     

Susceptibility of human hepatitis delta virus RNAs to small interfering RNA action

In animal cells, small interfering RNAs (siRNA), when exogenously provided, have been reported to be capable of inhibiting replication of several different viruses. In preliminary studies, siRNA species were designed and tested for their ability to act on the protein expressed in Huh7 cells transfected with DNA-directed mRNA constructs containing hepatitis delta virus (HDV) target sequences. The aim was to achieve siRNA specific for each of the three RNAs of HDV replication: (i) the 1,679-nucleotide circular RNA genome, (ii) its exact complement, the antigenome, and (iii) the less abundant polyadenylated mRNA for the small delta protein. Many of the 16 siRNA tested gave >80% inhibition in this assay. Next, these three classes of siRNA were tested for their ability to act during HDV genome replication. It was found that only siRNA targeted against HDV mRNA sequences could interfere with HDV genome replication. In contrast, siRNA targeted against genomic and antigenomic RNA sequences had no detectable effect on the accumulation of these RNAs. Reconstruction experiments with nonreplicating HDV RNA sequences support the interpretation that neither the potential for intramolecular rod-like RNA folding nor the presence of the delta protein conferred resistance to siRNA. In terms of replicating HDV RNAs, it is considered more likely that the genomic and antigenomic RNAs are resistant because their location within the nucleus makes them inaccessible to siRNA-mediated degradation.     

Terbium-mediated footprinting probes a catalytic conformational switch in the antigenomic hepatitis delta virus ribozyme

The two forms of the hepatitis delta virus ribozyme are derived from the genomic and antigenomic RNA strands of the human hepatitis delta virus (HDV), where they serve a crucial role in pathogen replication by catalyzing site-specific self-cleavage reactions. The HDV ribozyme requires divalent metal ions for formation of its tertiary structure, consisting of a tight double-nested pseudoknot, and for efficient self- (or cis-) cleavage. Comparison of recently solved crystal structures of the cleavage precursor and 3' product indicates that a significant conformational switch is required for catalysis by the genomic HDV ribozyme. Here, we have used the lanthanide metal ion terbium(III) to footprint the precursor and product solution structures of the cis-acting antigenomic HDV ribozyme. Inhibitory Tb(3+) binds with high affinity to similar sites on RNA as Mg(2+) and subsequently promotes slow backbone scission. We find subtle, yet significant differences in the terbium(III) footprinting pattern between the precursor and product forms of the antigenomic HDV ribozyme, consistent with differences in conformation as observed in the crystal structures of the genomic ribozyme. In addition, UV melting profiles provide evidence for a less tight tertiary structure in the precursor. In both the precursor and product we observe high-affinity terbium(III) binding sites in joining sequence J4/2 (Tb(1/2) approximately 4 microM) and loop L3, which are key structural components forming the catalytic core of the HDV ribozyme, as well as in several single-stranded regions such as J1/2 and the L4 tetraloop (Tb(1/2) approximately 50 microM). Sensitized luminescence spectroscopy confirms that there are at least two affinity classes of Tb(3+) binding sites. Our results thus demonstrate that a significant conformational change accompanies catalysis in the antigenomic HDV ribozyme in solution, similar to the catalytic conformational switch observed in crystals of the genomic form, and that structural and perhaps catalytic metal ions bind close to the catalytic core.     

Energetic contribution of non-essential 5' sequence to catalysis in a hepatitis delta virus ribozyme

Hepatitis delta virus (HDV) ribozymes employ multiple catalytic strategies to achieve overall rate enhancement of RNA cleavage. These strategies include general acid-base catalysis by a cytosine side chain and involvement of divalent metal ions. Here we used a trans-acting form of the antigenomic ribozyme to examine the contribution of the 5' sequence in the substrate to HDV ribozyme catalysis. The cleavage rate constants increased for substrates with 5' sequence alterations that reduced ground-state binding to the ribozyme. Quantitatively, a plot of activation free energy of chemical conversion versus Gibb's free energy of substrate binding revealed a linear relationship with a slope of -1. This relationship is consistent with a model in which components of the substrate immediately 5' to the cleavage site in the HDV ribozyme-substrate complex destabilize ground-state binding. The intrinsic binding energy derived from the ground-state destabilization could contribute up to 2 kcal/mol toward the total 8.5 kcal/mol reduction in activation free energy for RNA cleavage catalyzed by the HDV ribozyme.     

The poly(A) site sequence in HDV RNA alters both extent and rate of self-cleavage of the antigenomic ribozyme

The ribozyme self-cleavage site in the antigenomic sequence of hepatitis delta virus (HDV) RNA is 33-nt downstream of the poly(A) site for the delta antigen mRNA. An HDV antigenomic ribozyme precursor RNA that included the upstream poly(A) processing site was used to test the hypothesis that nonribozyme sequence near the poly(A) site could affect ribozyme activity. Relative to ribozyme precursor without the extra upstream sequences, the kinetic profile for self-cleavage of the longer precursor was altered in two ways. First, only half of the precursor RNA self-cleaved. The cleaved fraction could be increased or decreased with mutations in the upstream sequence. These mutations, which were predicted to alter the relative stability of competing secondary structures within the precursor, changed the distribution of alternative RNA structures that are resolved in native-gel electrophoresis. Second, the active fraction cleaved with an observed rate constant that was higher than that of the ribozyme without the upstream sequences. Moreover, the higher rate constants occurred at lower, near-physiological, divalent metal ion concentrations (1–2 mM). Modulation of ribozyme activity, through competing alternative structures, could be part of a mechanism that allows a biologically significant choice between maturation of the mRNA and processing of replication intermediates.     

Polyadenylation of the mRNA of hepatitis delta virus is dependent on the structure of the nascent RNA and regulated by the small or large delta antigen.

During the hepatitis delta virus (HDV) RNA replication, synthesis of either the mRNA for the delta antigen (HDAg) or the full-length antigenomic RNA is determined by selective usage of the potent poly(A) signal on the antigenome. To elucidate the regulatory mechanism, HDV cDNA cotransfection system was used to examine the potential effect of the secondary structure of the nascent RNA and that of the HDAg on HDV polyadenylation in transfected cells. We found that when the nascent RNA species could fold itself to form the rodlike structure, the HDV polyadenylation was suppressed 3 to 5 fold by the HDAg. In addition, we observed that the small and the large HDAg exerted a similar suppressive effect on the HDV polyadenylation, though they played different roles in HDV replication. We concluded that the HDV polyadenylation could be regulated by the structure of the nascent antigenomic RNA and by either the small or large HDAg.     

Antigenomic Hepatitis delta virus ribozymes self-cleave in 18 M formamide.

The ribozymes derived from Hepatitis delta virus (HDV) RNA appear unique in their sequence requirements for self-cleavage. While truncating the 1679 nucleotide antigenomic HDV RNA, we have characterized the cleavage requirements of a number of ribozymes of intermediate length. Two of these, containing 186 and 106 HDV nucleotides respectively, cleaved to completion in the presence of 18 M formamide. The 186 nucleotide ribozyme also cleaved to completion in 10 M urea. Removal of an additional 10 nts from the 3' terminus of the 106 nt ribozyme resulted in a loss of the ability to cleave in high concentrations of the denaturants. The interaction of nucleotides near the cleavage site with a sequence within this 10 base region may confer unusual stability on these ribozymes.     

Assessment of disparate structural features in three models of the hepatitis delta virus ribozyme.

Three models for the secondary structure of the hepatitis delta virus (HDV) antigenomic self-cleaving RNA element were tested by site-directed mutagenesis. Two models in which bases 5' to the cleavage site are paired with sequence at the 3' end of the element were both inconsistent with the data from the mutagenesis. Specifically, mutations in the 3' sequence which decrease self-cleavage activity could not be compensated by base changes in the 5' sequence as predicted by these models. The evidence was consistent with a third model in which the 3' end pairs with a portion of a loop within the ribozyme sequence to generate a pseudoknot structure. This same pairing was also required to generate higher rates of cleavage in trans with a 15-mer ribozyme, thus ruling out a proposed hammerhead-like 'axehead' model for the HDV ribozyme.     

Genomic but not antigenomic hepatitis delta virus RNA is preferentially exported from the nucleus immediately after synthesis and processing

Hepatitis delta virus (HDV) contains a viroid-like circular RNA that replicates via a double rolling circle replication mechanism. It is generally assumed that HDV RNA is synthesized and remains exclusively in the nucleus until being exported to the cytoplasm for virion assembly. Using a [32P]orthophosphate metabolic labeling procedure to study HDV RNA replication (T. B. Macnaughton, S. T. Shi, L. E. Modahl, and M. M. C. Lai. J. Virol. 76:3920-3927, 2002), we unexpectedly found that a significant amount of newly synthesized HDV RNA was detected in the cytoplasm. Surprisingly, Northern blot analysis revealed that the genomic-sense HDV RNA is present almost equally in both the nucleus and cytoplasm, whereas antigenomic HDV RNA was mostly retained in the nucleus, suggesting the specific and highly selective export of genomic HDV RNA. Kinetic studies showed that genomic HDV RNA was exported soon after synthesis. However, only the monomer and, to a lesser extent, the dimer HDV RNAs were exported to the cytoplasm; very little higher-molecular-weight HDV RNA species were detected in the cytoplasm. These results suggest that the cleavage and processing of HDV RNA may facilitate RNA export. The export of genomic HDV RNA was resistant to leptomycin B, indicating that a cell region maintenance 1 (Crm1)-independent pathway was involved. The large form of hepatitis delta antigen (L-HDAg), which is responsible for virus packaging, was not required for RNA export, as a mutant HDV RNA genome unable to synthesize L-HDAg was still exported. The proportions of genomic HDV RNA in the nucleus and cytoplasm remained relatively constant throughout replication, indicating that export of genomic HDV RNA occurred continuously. In contrast, while antigenomic HDV RNA was predominantly in the nucleus, there was a proportionally large fraction of antigenomic HDV RNA in the cytoplasm at early time points of RNA replication. These findings uncover a previously unrecognized presence of HDV RNA in the cytoplasm, which may have implications for viral RNA synthesis and packaging.