The folding pathway of the genomic hepatitis delta virus ribozyme is dominated by slow folding of the pseudoknots

Hepatitis delta virus (HDV) replicates by a double rolling-circle mechanism that requires self-cleavage by closely related genomic and antigenomic versions of a ribozyme. We have previously shown that the uncleaved genomic ribozyme is subject to a variety of alternative (Alt) pairings. Sequence upstream of the ribozyme can regulate self-cleavage activity by formation of an Alt 1 ribozyme-containing structure that severely inhibits self-cleavage, or a P(-1) self-structure that permits rapid self-cleavage. Here, we test three other alternative pairings: Alt P1, Alt 2, and Alt 3. Alt P1 and Alt 3 contain primarily ribozyme-ribozyme interactions, while Alt 2 involves ribozyme-flanking sequence interaction. A number of single and double mutant ribozymes were prepared to increase or decrease the stability of the alternative pairings, and rates of self-cleavage were determined. Results of these experiments were consistent with the existence of the proposed alternative pairings and their ability to inhibit the overall rate of native ribozyme folding. Local misfolds are treated as internal equilibrium constants in a binding polynomial that modulates the intrinsic rate of cleavage. This model of equilibrium effects of misfolds should be general and apply to other ribozymes. All of the alternative pairings sequester a pseudoknot-forming strand. Folding of ribozymes containing Alt P1 and Alt 2 was accelerated by urea as long as the native ribozyme fold was sufficiently stable, while folding of mutants in which both of these alternative pairings had been removed were not stimulated by urea. This behavior suggests that the pseudoknots form by capture of an unfolded or appropriately rearranged alternative pairing by its complementary native strand. Fast-folding mutants were prepared by either weakening alternative pairings or by strengthening native pairings. A kinetic model was developed that accommodates these features and explains the position of the rate-limiting step for the G11C mutant. Implications of these results for structural and dynamic studies of the uncleaved HDV ribozyme are discussed.     

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.     

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.     

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.     

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.     

Mutagenesis analysis of the self-cleavage domain of hepatitis delta virus antigenomic RNA.

To determine the sequence requirements and structural features of the self-cleavage domain of hepatitis delta virus (HDV) antigenomic RNA, we constructed a series of mutants and measured the rate constant of the cleavage reaction for each. The self-cleavage activity of HDV RNA of antigenomic sense was found to reside in a region of less than 90 nucleotides in length. The catalytic domain contained a long complementary sequence which could be deleted to half of its original size. Moreover, this region could be replaced by other sequences as long as they could fold into a stem-and-loop structure. The catalytic domain also required a 6-basepair helix adjacent to the cleaving point for activity. The structural features of these two base-pairing regions are quite similar to those of the HDV genomic self-cleavage domain. The cleavage site as well as the the hinge region (the sequence between the two stems) requires specific sequences for activity.     

Properties of antigenomic hepatitis delta virus ribozyme cis- and trans- analogs

A series of permuted variants of antigenomic HDV ribozyme and trans-acting variants were constructed. The catalytic activity study of the ribozymes has shown that all the variants were capable of self-cleaving with equally biphasic kinetics. Ribonuclease and Fe(II)-EDTA cleavage have provided evidence that all designed ribozymes fold according to the pseudoknot model and the conformations of the initial and cleaved ribozyme are different. A scheme of HDV ribozyme self-cleavage reaction was suggested. The role of hydrogen bonds in the reaction was evaluated by substitution of ribose in the ribozyme for deoxyribose. It was found that the 2'-OH group of U23 and C27 is critical for the reaction to occur; the 2'-OH group of U32 and U39 is important, while 2'-OH groups of other nucleotides of loop 3, stem 4 and stem 1 are unimportant for the cleavage activity.     

A sequence element necessary for self-cleavage of the antigenomic hepatitis delta RNA in 20 M formamide.

The genomic and antigenomic RNAs of hepatitis delta virus are capable of self-cleavage and show no significant sequence similarities to other known self-cleaving RNAs. We have derived an antigenomic delta RNA which cleaves to completion in 15 s in 9 mM magnesium at 37 degrees C and is capable of efficient self-cleavage in concentrations of formamide as high as 20 M. Cleavage in high concentrations of denaturant is dependent upon the presence of a polypurine sequence element, GGAGA, located between 81 and 85 nucleotides downstream of the cleavage site. Mutation of the initial G81G82 to C81C82, or removal of the sequence element, results in a loss of the ability to cleave in high formamide concentrations. Changing the final U-2C-1 of a pyrimidine-rich region, UCUUC, just upstream of the cleavage site, to G-2G-1 severely affects the self-cleavage, but introducing the two mutations, GG to CC and UC to GG, into the same molecule, restoring potential base pairing, partially restores the formamide stability. Relocating the GGAGA sequence upstream of the cleavage site also results in partial restoration of the formamide cleavage. Although the GGAGA sequence is important for self-cleavage under denaturing conditions, it does not appear to be necessary for HDV RNA cleavage in normal buffer conditions.     

Deletion of internal sequence on the HDV-ribozyme: elucidation of functionally important single-stranded loop regions.

In elucidating functionally important single-stranded loop regions derived mainly from three models in genomic hepatitis delta virus (HDV) ribozyme possessing self-cleavage activity, we have constructed several internal deletion variants of the HDV133 molecule (654-786 nt on genomic RNA) by oligonucleotide-directed mutagenesis. When self-cleavage activities were compared among variants, the HDV133DI-1 (deletion of 701-718 nt) and HDV133DI-3 (deletion of 740-752 nt) ribozyme could maintain their self-cleavage activity, despite at reduced level. However, the activity could be regained in both mutants by some extent under partially denaturing conditions. These results suggest that the above two single-stranded RNA loop regions in HDV ribozyme are not part of the catalytic core but might be involved in the stability of the molecule. In contrast, deletion mutants such as HDV133DI-2 (deletion of 696-722 nt), HDV88DI-1 (deletion of 701-718 nt), HDV88DI-2 (deletion of 696-722 nt), and HDV88DI-4 (deletion of 733-760 nt) abolished catalytic activity. These results suggest that the remaining single-stranded regions of bases between 726-731 and 762-766 in the HDV88 ribozyme may be the potential regions to interact with Mg2+ ions.     

Self-cleavage activity of the genomic HDV ribozyme in the presence of various divalent metal ions.

To identify the divalent metal ions that can support the self-cleavage activity of the genomic ribozyme of human hepatitis delta virus (HDV), we tested the activity of various divalent metal ions in the ribozyme reactions catalyzed by HDV88 (683-770 nt) and 88DI3 (HDV88 with the sequence from 740-752 nt deleted). Among various metal ions tested, Mg2+, Mn2+, Ca2+ and Sr2+ efficiently supported the self-cleavage reactions of the HDV88 and 88DI3 ribozymes. In the case of the 88DI3 ribozyme, other divalent metal ions, such as Cd2+, Ba2+, Co2+, Pb2+ and Zn2+, were also able to support the self-cleavage reaction to some extent (< 10%). In the presence of spermidine (0.5 mM), the cleavage reaction was promoted at lower concentrations of effective divalent metal ions. The HDV ribozyme represents the only example of ribozyme to date of a ribozyme that catalyzes the self-cleavage reaction in the presence of Ca2+ ions as efficiently as it does in the presence of Mg2+ ions.     

Optimal self-cleavage activity of the hepatitis delta virus RNA is dependent on a homopurine base pair in the ribozyme core.

A non-Watson-Crick G.G interaction within the core region of the hepatitis delta virus (HDV) antigenomic ribozyme is required for optimal rates of self-cleavage activity. Base substitutions for either one or both G's revealed that full activity was obtained only when both G's were replaced with A's. At those positions, substitutions that generate potential Watson-Crick, G.U, heteropurine, or homopyrimidine combinations resulted in dramatically lower cleavage activity. A homopurine symmetric base pair, of the same type identified in the high-affinity binding site of the HIV RRE, is most consistent with this data. Additional features shared between the antigenomic ribozyme and the Rev binding site in the vicinity of the homopurine pairs suggest some structural similarity for this region of the two RNAs and a possible motif associated with this homopurine interaction. Evidence for a homopurine pair at the equivalent position in a modified form of the HDV genomic ribozyme was also found. With the postulated symmetric pairing scheme, large distortions in the nucleotide conformation, the sugar-phosphate backbone, or both would be necessary to accommodate this interaction at the end of a helix; we hypothesize that this distortion is critical to the structure of the active site of the ribozyme and it is stabilized by the homopurine base pair.     

A pH-sensitive RNA tertiary interaction affects self-cleavage activity of the HDV ribozymes in the absence of added divalent metal ion

Self-cleavage of the genomic and antigenomic ribozymes from hepatitis delta virus (HDV) requires divalent cation for optimal activity. Recently, the HDV genomic ribozyme has been shown to be active in NaCl in the absence of added divalent metal ion at low pH (apparent pKa 5.7). However, we find that the antigenomic ribozyme is 100 to 1000-fold less active under similar conditions. With deletion of a three-nucleotide sequence (C41-A42-A43) unique to the genomic ribozyme, the rate constant for cleavage decreased substantially, while activity of the antigenomic ribozyme was enhanced by introducing a CAA sequence. From the crystal structure, it has been proposed that C41 in this sequence is protonated. To investigate a possible connection between activity at low pH and protonation of C41, mutations were made that were predicted to either eliminate protonation or alter the nature of the tertiary interaction upon protonation. In the absence of added Mg2+, these mutations reduced activity and eliminated the observed pH-rate dependence. Thermal denaturation studies revealed a pH-sensitive structural feature in the genomic ribozyme, while unfolding of the mutant ribozymes was pH-independent. We propose that, in the absence of added Mg2+, protonation of C41 contributes to enhanced activity of the HDV genomic ribozyme at low pH.     

Non-ribozyme sequences enhance self-cleavage of ribozymes derived from Hepatitis delta virus.

Analysis of the self-cleavage of ribozymes derived from the genomic RNA of Hepatitis delta virus (HDV) has revealed that certain co-transcribed vector sequences significantly affect the activity of the ribozyme. Specifically, the t1/2 of self-cleavage for a 135 nucleotide HDV RNA varied, at 42 degrees C, from 5 min to 88 min, depending on the vector-derived sequences flanking the 5' end of the ribozyme. Further analysis suggested that this phenomenon was most likely due to the interaction of vector-derived sequences with a 16 nucleotide region found at the 3' end of the ribozyme. These findings have implications for studies of ribozymes transcribed from cDNA templates, and may provide information regarding the catalytic structure of the HDV ribozyme.     

Identification of important bases for the self-cleavage activity at two single-stranded regions of genomic HDV ribozyme.

In order to determine important bases at two single-stranded regions [SSrA (726-731 nt) and SSrB (762-766)] derived mainly from secondary structure models in genomic hepatitis delta virus (HDV) ribozyme possessing self-cleavage activity, we have constructed several point mutants at these two regions on the HDV88 molecule (683-770). Among the bases at SSrA and SSrB regions C763 was found to play an essential role during self-cleavage process since substitutions to any other bases viz. A or G or U completely abolished the activity.     

Detailed analysis of base preferences at the cleavage site of a trans-acting HDV ribozyme: a mutation that changes cleavage site specificity.

In our previous attempt at in vitro selection of a trans - acting human hepatitis delta virus (HDV) ribozyme, we found that one of the variants, G10-68-725G, cleaved a 13 nt substrate, HDVS1, at two sites [Nishikawa,F., Kawakami,J., Chiba,A., Shirai,M., Kumar,P.K.R. and Nishikawa,S. (1996) Eur. J. Biochem., 237, 712-718]. One site was the normal cleavage site and the other site was shifted 1 nt toward the 3'-end. To clarify the interactions between nucleotides around the cleavage site of the trans -acting HDV ribozyme, we analyzed the efficiency of the reaction for every possible base pair between the substrate and the ribozyme at positions -1 (-1N:726N) and +1 (+1N:725N) relative to the cleavage site using the genomic HDV ribozyme, TdS4(Xho), and derivatives of the most active variant, G10-68. These mutagenesis analyses revealed that the +1 base of the substrate affects the structure of the catalytic core in the complex with G10-68-725G, substrate and divalent metal ions, and it shifts the cleavage site. In a comparison with other variants of the trans -acting HDV ribozyme, we found that this cleavage site shift occurred only with G10-68-725G.     

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.     

Interaction between RNA molecules of a two-componet trans-analog of antigenomic HDV-ribozyme

Association of RNA molecules forming a two-component B:LS trans-analog of antigenomic HDV ribozyme was studied. From previously synthesized trans-ribozymes the B:LS ribozyme differs by length and sequence of its RNA molecules (33 and 34 bp, respectively), topology of functional parts and the absence of very short reaction product. The ribozyme displays a biphasic kinetics of self-cleavage similar to that of cis-ribozyme. Our original kinetic scheme for the B:LS trans-ribozyme self-cleavage (www.cardio.ru\labgen\RZ_e.html)describes a possible cause of biphasic nature of the reaction curve, namely, variation of the rate-limiting stage in the series of successive conformational transformations which coincide with the ribozyme self-cleavage. Interactions between the molecules involved in the reaction, i.e., "multimerization" of entire ribozyme and its components can be regarded as another cause of the biphasic kinetics. B:LS trans-ribozyme is a convenient model for the investigation of this process, since the binding of LS and B allows the formation of complexes with 1B:2LS or 2B:1LS stoichiometry and complexes with the cleavage products. We examined the factors determining dissociation-association of the ribozyme components using a series of electrophoreses under nondenaturing conditions. The possibility of interaction between cis- and transribozyme components was confirmed experimentally. In the presence of LS excess over B the ribozyme can form multimeres. These findings suggest the involvement of intermolecular interactions in native cis-ribozyme self-cleavage.