Analysis of the cleavage reaction of a trans-acting human hepatitis delta virus ribozyme.

The cleavage reaction catalyzed by the trans -acting genomic ribozyme of human hepatitis delta virus (HDV) was analyzed with a 13mer substrate (R13) and thio-substituted [SR13(Rp) and SR13(Sp)] substrates under single-turnover conditions. The cleavage of RNA by the trans -acting HDV ribozyme proceeded as a first order reaction. The logarithm of the rate of cleavage (kclv) increased linearly (with a slope of approximately 1) between pH 4.0 and 6.0, an indication that a single deprotonation reaction occurred. This result suggests that kclv reflects the rate of the chemical cleavage step, at least around pH 5. The amount of active complex with the SR13(Sp) substrate was almost as large as with R13 (60-80%), whereas the amount of the corresponding active complex formed with the SR13(Rp) substrate was, at most, 20% of this value (with 0.5-100 mM Mg2+ions) at pH 5.0. Nonetheless, the value of kclv for all substrates was almost the same (0.4-0.5 min-1). Neither a 'thio effect' nor a 'Mn2+rescue effect' were observed. These results suggest that Mg2+ions do not interact with pro-R oxygen directly but are essential to the formation of the active complex of the ribozyme and its substrate.     

Detailed analysis of stem I and its 5' and 3' neighbor regions in the trans-acting HDV ribozyme.

To determine the stem I structure of the human hepatitis delta virus (HDV) ribozyme, which is related to the substrate sequence in the trans -acting system, we kinetically studied stem I length and sequences. Stem I extension from 7 to 8 or 9 bp caused a loss of activity and a low amount of active complex with 9 bp in the trans -acting system. In a previous report, we presented cleavage in a 6 bp stem I. The observed reaction rates indicate that the original 7 bp stem I is in the most favorable location for catalytic reaction among the possible 6-8 bp stems. To test base specificity, we replaced the original GC-rich sequence in stem I with AU-rich sequences containing six AU or UA base pairs with the natural +1G.U wobble base pair at the cleavage site. The cis -acting AU-rich molecules demonstrated similar catalytic activity to that of the wild-type. In trans -acting molecules, due to stem I instability, reaction efficiency strongly depended on the concentration of the ribozyme-substrate complex and reaction temperature. Multiple turnover was observed at 37 degreesC, strongly suggesting that stem I has no base specificity and more efficient activity can be expected under multiple turnover conditions by substituting several UA or AU base pairs into stem I. We also studied the substrate damaging sequences linked to both ends of stem I for its development in therapeutic applications and confirmed the functions of the unique structure.     

Specificity of the hairpin ribozyme. Sequence requirements surrounding the cleavage site.

Substrate sequence requirements of the hairpin ribozyme have been partially defined by both mutational and in vitro selection experiments. It was considered that the best targets were those that included the N downward arrowGUC sequence surrounding the cleavage site. In contrast to previous studies that failed to evaluate all possible combinations of these nucleotides, we have performed an exhaustive analysis of the cleavage of 64 substrate variants. They represent all possible sequence combinations of the J2/1 nucleotides except the well established G(+1). No cleavage was observed with 24 sequences. C(+2) variants showed little or no cleavage, whereas U(+2) substrates were all cleavable. The maximal cleavage rate was obtained with the AGUC substrate. Cleavage rates of sequences HGUC (H = A, C, or U), GGUN, GGGR (R = A or G), AGUU, and UGUA were up to 5 times lower than the AGUC one. This shows that other sequences besides NGUC could also be considered as good targets. A second group of sequences WGGG (W = A or U), UGUK (K = G or U), MGAG (M = A or C), AGUA, and UGGA were cleaved between 6 and 10 times less efficiently. Furthermore, the UGCU sequence of a noncleavable viral target was mutated to AGUC resulting in a proficiently cleavable substrate by its cognate hairpin ribozyme. This indicates that our conclusions may be extrapolated to other hairpin ribozymes with different specificity.     

Structure of the ribozyme substrate hairpin of Neurospora VS RNA: a close look at the cleavage site

The cleavage site of the Neurospora VS RNA ribozyme is located in a separate hairpin domain containing a hexanucleotide internal loop with an A-C mismatch and two adjacent G-A mismatches. The solution structure of the internal loop and helix la of the ribozyme substrate hairpin has been determined by nuclear magnetic resonance (NMR) spectroscopy. The 2 nt in the internal loop, flanking the cleavage site, a guanine and adenine, are involved in two sheared G.A base pairs similar to the magnesium ion-binding site of the hammerhead ribozyme. Adjacent to the tandem G.A base pairs, the adenine and cytidine, which are important for cleavage, form a noncanonical wobble A+-C base pair. The dynamic properties of the internal loop and details of the high-resolution structure support the view that the hairpin structure represents a ground state, which has to undergo a conformational change prior to cleavage. Results of chemical modification and mutagenesis data of the Neurospora VS RNA ribozyme can be explained in context with the present three-dimensional structure.     

Mutational analysis of the antigenomic trans-acting delta ribozyme: the alterations of the middle nucleotides located on the P1 stem

Our previous report on delta ribozyme cleavage using a trans -acting antigenomic delta ribozyme and a collection of short substrates showed that the middle nucleotides of the P1 stem, the substrate binding site, are essential for the cleavage activity. Here we have further investigated the effect of alterations in the P1 stem on the kinetic and thermodynamic parameters of delta ribozyme cleavage using various ribozyme variants carrying single base mutations at putative positions reported. The kinetic and thermodynamic values obtained in mutational studies of the two middle nucleotides of the P1 stem suggest that the binding and active sites of the delta ribozyme are uniquely formed. Firstly, the substrate and the ribozyme are engaged in the formation of a helix, known as the P1 stem, which may contain a weak hydrogen bond(s) or a bulge. Secondly, a tertiary interaction involving the base moieties in the middle of the P1 stem likely plays a role in defining the chemical environment. As a con-sequence, the active site might form simultaneously or subsequently to the binding site during later steps of the pathway.     

Core sequences and a cleavage site wobble pair required for HDV antigenomic ribozyme self-cleavage.

The secondary structures proposed for the cis-acting hepatitis delta virus (HDV) ribozymes contain four duplex regions, three sequences joining the duplexes and two hairpin loops. The core and active site of the ribozyme could be formed by portions of the joining sequences, J1/4 and J4/2, together with one of the hairpin loops, L3. To establish the core region and define essential bases within this putative active site 28 single base changes at 15 positions were made and tested for effects on ribozyme cleavage. At 14 of the 15 positions all of the changes resulted in detectable decreased rates of cleavage. At seven of the positions one or more of the changes resulted in a 500-fold or greater decrease in the observed rate constant for cleavage. Mutations that resulted in 10(3)-fold effects were found in all three regions hypothesized to form the core. At the cleavage site substitutions of the cytosine 5' of the site of cleavage did not provide strong support for a sequence-specific interaction involving this nucleotide. In contrast, an A-C combination was the most effective substitution for a potential G-U pair 3' of the cleavage site, suggesting a requirement for a wobble pair at that position.     

Catalysis of RNA cleavage by the Tetrahymena thermophila ribozyme. 2. Kinetic description of the reaction of an RNA substrate that forms a mismatch at the active site

The site-specific endonuclease reaction catalyzed by the ribozyme from the Tetrahymena pre-rRNA intervening sequence has been characterized with a substrate that forms a "matched" duplex with the 5' exon binding site of the ribozyme [G2CCCUCUA5 + G in equilibrium with G2CCCUCU + GA5 (G = guanosine); Herschlag, D., & Cech, T.R. (1990) Biochemistry (preceding paper in this issue)]. The rate-limiting step with saturating substrate is dissociation of the product G2CCCUCU. Here we show that the reaction of the substrate G2CCCGCUA5, which forms a "mismatched" duplex with the 5' exon binding site at position -3 from the cleavage site, has a value of kcat that is approximately 10(2)-fold greater than kcat for the matched substrate (50 degrees C, 10 mM MgCl2, pH 7). This is explained by the faster dissociation of the mismatched product, G2CCCGCU, than the matched product. With subsaturating oligonucleotide substrate and saturating G, the binding of the oligonucleotide substrate and the chemical step are each partially rate-limiting. The rate constant for the chemical step of the endonuclease reaction and the rate constant for the site-specific hydrolysis reaction, in which solvent replaces G, are each within approximately 2-fold with the matched and mismatched substrates, despite the approximately 10(3)-fold weaker binding of the mismatched substrate. This can be described as "uniform binding" of the base at position -3 in the ground state and transition state [Albery, W.J., & Knowles, J. R. (1976) Biochemistry 15, 5631-5640]. Thus, the matched substrate does not use its extra binding energy to preferentially stabilize the transition state.(ABSTRACT TRUNCATED AT 250 WORDS)     

Addition of an Extra Substrate Binding Site and Partial Destabilization of Stem Structures in HDV Ribozyme Give Rise to High Sequence-Specificity for its Target RNA

Because the substrate binding site (P1) of HDV ribozyme consists of only seven nucleotides, cleavage of undesired RNA is likely to occur when applied for a specific long RNA target such as mRNA. To overcome this problem, we designed modified trans-acting HDV ribozymes with an extra substrate-binding site (P5) in addition to the original binding site (P1). By inserting an additional seven base-pair stem (P5 stem) into the J1/2 single-stranded region of the ribozyme core system and partial destabilization of the P2 or P4 stem, we succeeded in preparation of new HDV ribozymes that can cleave the target RNA depending on the formation of P5 stem. Moreover, the ribozyme with a six-nucleotide P1 site was able to distinguish the substrate RNA with a complete match from that with a single mismatch in the P1 region. These results suggest that the HDV ribozyme system is useful for the application in vivo.     

Addition of an extra substrate binding site and partial destabilization of stem structures in HDV ribozyme give rise to high sequence-specificity for its target RNA

Because the substrate binding site (P1) of HDV ribozyme consists of only seven nucleotides, cleavage of undesired RNA is likely to occur when applied for a specific long RNA target such as mRNA. To overcome this problem, we designed modified trans-acting HDV ribozymes with an extra substrate-binding site (P5) in addition to the original binding site (P1). By inserting an additional seven base-pair stem (P5 stem) into the J1/2 single-stranded region of the ribozyme core system and partial destabilization of the P2 or P4 stem, we succeeded in preparation of new HDV ribozymes that can cleave the target RNA depending on the formation of P5 stem. Moreover, the ribozyme with a six-nucleotide P1 site was able to distinguish the substrate RNA with a complete match from that with a single mismatch in the P1 region. These results suggest that the HDV ribozyme system is useful for the application in vivo.     

The A730 loop is an important component of the active site of the VS ribozyme

The core of the VS ribozyme comprises five helices, that act either in cis or in trans on a stem-loop substrate to catalyse site-specific cleavage. The structure of the 2-3-6 helical junction indicates that a cleft is formed between helices II and VI that is likely to serve as a receptor for the substrate. Detailed analysis of sequence variants suggests that the base bulges of helices II and VI play an architectural role. By contrast, the identity of the nucleotides in the A730 loop is very important for ribozyme activity. The base of A756 is particularly vital, and substitution by any other nucleotide or ablation of the base leads to a major reduction in cleavage rate. However, variants of A756 bind substrate efficiently, and are not defective in global folding. These results suggest that the A730 loop is an important component of the active site of the ribozyme, and that A756 could play a key role in catalysis.     

NMR analysis of tertiary interactions in HDV ribozymes.

Three variants of minimized hepatitis delta virus (HDV) RNA ribozyme systems designed on the basis of the "pseudoknot" model were synthesized and their tertiary interactions were analyzed by NMR spectroscopy. Rz-1 is a cis-acting ribozyme system (the cleaved form, 56-mer) in which stem IV is deleted from the active domain of genomic HDV RNA. Rz-1 was uniformly labeled with stable isotopes, 13C and 15N. Rz-2 is a trans-acting ribozyme system (substrate: 8-mer, the cytidine residue at the cleavage site is replaced by 2'-O-methylcytidine; enzyme: 16-mer plus 35-mer). Rz-2 was partially labeled with stable isotopes in guanosine residues of enzyme 35mer. Rz-4 is a trans-acting ribozyme system (substrate: 8mer, the cytidine residue at the cleavage site is replaced by 2'-O-methylcytidine; enzyme 53mer) which was designed by Perrotta and Been. Rz-4 has the same sequence and an extra loop closing stem IV. From 2D-NOESY and 2D-HSQC (except for Rz-4) spectra, it was suggested each ribozyme forms "pseudoknot" type structure in solution. Additionally, it was found that G38 of Rz-1, G28 and G29 of Rz-2 and Rz-4 form base-pairs. These novel base-pairs are observed in the crystal structure of a modified genomic HDV RNA. From temperature change experiment of Rz-2, the imino proton signal of G28 disappeared at 50 degrees C earlier than the other corresponding signals. Upon MgCl2 titration of Rz-2, this signal showed the largest shift.     

Ribozyme cleavage of a 2,5-phosphodiester linkage: mechanism and a restricted divalent metal-ion requirement.

The natural substrate cleaved by the hepatitis delta virus (HDV) ribozyme contains a 3',5'-phosphodiester linkage at the cleavage site; however, a 2',5'-linked ribose-phosphate backbone can also be cleaved by both trans-acting and self-cleaving forms of the HDV ribozyme. With substrates containing either linkage, the HDV ribozyme generated 2',3'-cyclic phosphate and 5'-hydroxyl groups suggesting that the mechanisms of cleavage in both cases were by a nucleophilic attack on the phosphorus center by the adjacent hydroxyl group. Divalent metal ion was required for cleavage of either linkage. However, although the 3',5'-linkage was cleaved slightly faster in Ca2+ than in Mg2+, the 2',5'-linkage was cleaved in Mg2+ (or Mn2+) but not Ca2+. This dramatic difference in metal-ion specificity is strongly suggestive of a crucial metal-ion interaction at the active site. In contrast to the HDV ribozymes, cleavage at a 2',5'-phosphodiester bond was not efficiently catalyzed by the hammerhead ribozyme. The relaxed linkage specificity of the HDV ribozymes may be due in part to lack of a rigid binding site for sequences 5' to the cleavage site.     

Characterization of the trans Watson-Crick GU base pair located in the catalytic core of the antigenomic HDV ribozyme

The HDV ribozyme's folding pathway is, by far, the most complex folding pathway elucidated to date for a small ribozyme. It includes 6 different steps that have been shown to occur before the chemical cleavage. It is likely that other steps remain to be discovered. One of the most critical of these unknown steps is the formation of the trans Watson-Crick GU base pair within loop III. The U(23) and G(28) nucleotides that form this base pair are perfectly conserved in all natural variants of the HDV ribozyme, and therefore are considered as being part of the signature of HDV-like ribozymes. Both the formation and the transformation of this base pair have been studied mainly by crystal structure and by molecular dynamic simulations. In order to obtain physical support for the formation of this base pair in solution, a set of experiments, including direct mutagenesis, the site-specific substitution of chemical groups, kinetic studies, chemical probing and magnesium-induced cleavage, were performed with the specific goal of characterizing this trans Watson-Crick GU base pair in an antigenomic HDV ribozyme. Both U(23) and G(28) can be substituted for nucleotides that likely preserve some of the H-bond interactions present before and after the cleavage step. The formation of the more stable trans Watson-Crick base pair is shown to be a post-cleavage event, while a possibly weaker trans Watson-Crick/Hoogsteen interaction seems to form before the cleavage step. The formation of this unusually stable post-cleavage base pair may act as a driving force on the chemical cleavage by favouring the formation of a more stable ground state of the product-ribozyme complex. To our knowledge, this represents the first demonstration of a potential stabilising role of a post-cleavage conformational switch event in a ribozyme-catalyzed reaction.     

Sequence-specific endoribonuclease activity of the Tetrahymena ribozyme: enhanced cleavage of certain oligonucleotide substrates that form mismatched ribozyme-substrate complexes

A shortened form of the self-splicing intervening sequence RNA of Tetrahymena acts as a sequence-specific endoribonuclease. Specificity of cleavage is determined by Watson-Crick base pairing between the active site of the RNA enzyme (ribozyme) and its RNA substrate [Zaug, A. J., Been, M. D., & Cech, T. R. (1986) Nature (London) 324, 429-433]. Surprisingly, single-base changes in the substrate RNA 3 nucleotides preceding the cleavage site, giving a mismatched substrate-ribozyme complex, enhance the rate of cleavage. Mismatched substrates show up to a 100-fold increase in kcat and, in some cases, in kcat/Km. A mismatch introduced by changing a nucleotide in the active site of the ribozyme has a similar effect. Addition of 2.5 M urea or 3.8 M formamide or decreasing the divalent metal ion concentration from 10 to 2 mM reverses the substrate specificity, allowing the ribozyme to discriminate against the mismatched substrate. The effect of urea is to decrease kcat and kcat/Km for cleavage of the mismatched substrate; Km is not significantly affected at 0-2.5 M urea. Thus, progressive destabilization of ribozyme-substrate pairing by mismatches or by addition of a denaturant such as urea first increases the rate of cleavage to an optimum value and then decreases the rate.     

Design and NMR analysis of HDV ribozymes for structural investigation.

Three variants of minimized hepatitis delta virus (HDV) RNA ribozyme systems (Rz-1 to approximately Rz-3) (Fig. 1) were designed on the basis of the "pseudoknot" structure model and synthesized. Rz-1 is a cis-acting ribozyme system (a cleaved form, 56-mer) in which stem IV is deleted from the active domain of genomic HDV RNA. Rz-1 was uniformly labeled with stable isotopes, 13C and 15N. The 2D-NOESY and 2D-HSQC data for Rz-1 suggest that Rz-1 forms the pseudoknot structure and G38 which is opposite to the cleavage site makes a base-pair. Rz-2 is a trans-acting ribozyme system which consists of three RNA oligomer strands (substrate: 8-mer, the cytidine residue at the cleavage site is replaced by 2'-O-methylcytidine; enzyme: 16-mer plus 35-mer). Rz-3 is a ribozyme in which the three RNA strands of Rz-2 are connected. It turns out that Rz-3 forms an inactive structure with low cleavage activity (k(obs) = 0.009) and final cleavage yield (6%). Rz-3 has the highest cleavage activity at pH 5.5. The optimal activity at acidic pH is similar to that of the wild type ribozyme. We also synthesized and examined the activity and structure of Rz-4 (designed by Perrotta and Been) which consists of two RNA strands (1).     

Disparate HDV ribozyme crystal structures represent intermediates on a rugged free-energy landscape

The hepatitis delta virus (HDV) ribozyme is a member of the class of small, self-cleaving catalytic RNAs found in a wide range of genomes from HDV to human. Both pre- and post-catalysis (precursor and product) crystal structures of the cis-acting genomic HDV ribozyme have been determined. These structures, together with extensive solution probing, have suggested that a significant conformational change accompanies catalysis. A recent crystal structure of a trans-acting precursor, obtained at low pH and by molecular replacement from the previous product conformation, conforms to the product, raising the possibility that it represents an activated conformer past the conformational change. Here, using fluorescence resonance energy transfer (FRET), we discovered that cleavage of this ribozyme at physiological pH is accompanied by a structural lengthening in magnitude comparable to previous trans-acting HDV ribozymes. Conformational heterogeneity observed by FRET in solution appears to have been removed upon crystallization. Analysis of a total of 1.8 µsec of molecular dynamics (MD) simulations showed that the crystallographically unresolved cleavage site conformation is likely correctly modeled after the hammerhead ribozyme, but that crystal contacts and the removal of several 2′-oxygens near the scissile phosphate compromise catalytic in-line fitness. A cis-acting version of the ribozyme exhibits a more dynamic active site, while a G-1 residue upstream of the scissile phosphate favors poor fitness, allowing us to rationalize corresponding changes in catalytic activity. Based on these data, we propose that the available crystal structures of the HDV ribozyme represent intermediates on an overall rugged RNA folding free-energy landscape.     

Binding and cleavage of nucleic acids by the "hairpin" ribozyme

The "hairpin" ribozyme derived from the minus strand of tobacco ringspot virus satellite RNA [(-)sTRSV] efficiently catalyzes sequence-specific RNA hydrolysis in trans (Feldstein et al., 1989; Hampel & Triz, 1989; Haseloff & Gerlach, 1989). The ribozyme does not cleave DNA. An RNA substrate analogue containing a single deoxyribonucleotide residue 5' to the cleavage site (A-1) binds to the ribozyme efficiently but cannot be cleaved. A DNA substrate analogue with a ribonucleotide at A-1 is cleaved; thus A-1 provides the only 2'-OH required for cleavage. These results support cleavage via a transphosphorylation mechanism initiated by attack of the 2'-OH of A-1 on the scissile phosphodiester. The ribozyme discriminates between DNA and RNA in both binding and cleavage. Results indicate that the 2'-OH of A-1 functions in complex stabilization as well as cleavage. The ribozyme efficiently cleaves a phosphorothioate diester linkage, suggesting that the pro-Rp oxygen at the scissile phosphodiester does not coordinate Mg2+.     

Imino proton NMR analysis of HDV ribozymes: nested double pseudoknot structure and Mg2+ ion-binding site close to the catalytic core in solution

Minimized trans-acting HDV ribozyme systems consisting of three (Rz-3) and two (Rz-2) RNA strands were prepared and their folding conformations were analyzed by NMR spectroscopy. The guanosine residues in one of the enzyme components of Rz-3 were labeled with ¹³C and ¹⁵N. Imino proton signals were assigned by analysis of NOESY and HSQC spectra. The results are consistent with the nested double pseudoknot model, which contains novel base pairs (P1.1), as observed in the crystal structure of a genomic HDV ribozyme. The NOE connectivities suggest an additional G:G pair at the bottom of P1.1 and at the top of P4. The effects of temperature and Mg²⁺ ions on base pairs for Rz-3 were examined. The temperature variation experiment on Rz-3 showed that P3 is the most stable and that P1.1 is as stable as P1 and P2. The imino proton signals of the G:U pair at the bottom of P1 and the top of P1.1, which are close to the cleavage site, showed the largest changes upon Mg²⁺ titration of Rz-3. The results suggest that the catalytic Mg²⁺ ion binds to the pocket formed by P1 and L3.     

Delta ribozyme has the ability to cleave in transan mRNA.

We report here the first demonstration of the cleavage of an mRNA in trans by delta ribozyme derived from the antigenomic version of the human hepatitis delta virus (HDV). We characterized potential delta ribozyme cleavage sites within HDV mRNA sequence (i.e. C/UGN6), using oligonucleotide binding shift assays and ribonuclease H hydrolysis. Ribozymes were synthesized based on the structural data and then tested for their ability to cleave the mRNA. Of the nine ribozymes examined, three specifically cleaved a derivative HDV mRNA. All three active ribozymes gave consistent indications that they cleaved single-stranded regions. Kinetic characterization of the ability of ribozymes to cleave both the full-length mRNA and either wild-type or mutant small model substrate suggests: (i) delta ribozyme has turnovers, that is to say, several mRNA molecules can be successively cleaved by one ribozyme molecule; and (ii) the substrate specificity of delta ribozyme cleavage is not restricted to C/UGN6. Specifically, substrates with a higher guanosine residue content upstream of the cleavage site (i.e. positions -4 to -2) were always cleaved more efficiently than wild-type substrate. This work shows that delta ribozyme constitutes a potential catalytic RNA for further gene-inactivation therapy.