Length variation of helix III in a hammerhead ribozyme and its influence on cleavage activity

The previously described HIV-1 directed hammerhead ribozyme 2as-Rz12 can form with its target RNA 2s helices I and III of 128 and 278 base pairs (bp). A series of derivatives was made in which helix III was truncated to 8, 5, 4, 3, and 2 nucleotides (nt). These asymmetric hammerhead ribozymes were tested for in vitro cleavage and for inhibition of HIV-1 replication in human cells. Truncation of helix III to 8 bp did not affect the in vitro cleavage potential of the parental catalytic antisense RNA 2as-Rz12. Further truncation of helix III led to decreased cleavage rates, with no measurable cleavage activity for the 2 bp construct. All catalytically active constructs showed complex cleavage kinetics. Three kinetic subpopulations of ribozyme-substrate complexes could be discriminated that were cleaved with fast or slow rates or not at all. Gel purification of preformed ribozyme-substrate complexes led to a significant increase in cleavage rates. However, the complex cleavage pattern remained. In mammalian cells, the helix III-truncated constructs showed the same but no increased inhibitory effect of the comparable antisense RNA on HIV-1 replication.     

Target sequence-specific inhibition of HIV-1 replication by ribozymes directed to tat RNA.

The structural motif formed between a hammerhead ribozyme and its substrate consists of three RNA double helices in which the sequence 5' to the XUY is termed helix I and the sequence 3' to the XUY helix III. Two hammerhead ribozymes targeted to the tat gene of HIV-1SF2 were designed to study target specificity and the potential effect of helix I mismatch on ribozyme efficacy both in vitro and in vivo. The first ribozyme (Rz1) targeted to the 5' splicing region of the tat gene was designed to cleave GUC*A. In HIV-1IIIB the A is changed to a G. The second ribozyme (Rz2) was targeted to the translational initiation region of the tat gene which is highly conserved among a variety of HIV-1 isolates, including both HIV-1SF2 and HIV-1IIIB. In vitro cleavage studies demonstrated that Rz1 efficiency cleaved HIV-1SF2 substrate RNA, but not HIV-1IIIB, presumably due to the base change from A to G. In contrast, Rz2 cleaved HIV-1SF2 or HIV-1IIIB substrate with equal efficiency. Both ribozymes were cloned into the 3' untranslated region of the neomycin gene (neo) within the pSV2neo vector and transfected into the SupT1 human CD4+ T cell line. Following selection, stable transfectants were challenged with either HIV-1SF2 or HIV-1IIIB virus. While Rz1-expressing cells were significantly protected from HIV-1SF2 infection, they exhibited no protection when infected with HIV-1IIIB virus. In contrast, Rz2 was effective in inhibiting the replication of both HIV-1SF2 and HIV-1IIIB in SupT1 cells. Expression of both ribozymes in these cells was demonstrated by Northern analysis. RT-PCR sequencing analysis confirmed the respective HIV-1 target sequence integrity. These data demonstrate the importance of the first base pair distal to the XUY within helix I of the hammerhead structure for both in vitro and in vivo ribozyme activities and imply that the effectiveness of the anti-HIV-1 ribozymes against appropriate target sequences is due to their catalytic activities rather than any antisense effect.     

The influence of imperfectly paired helices I and III on the catalytic activity of hammerhead ribozymes.

Several catalytic antisense RNAs directed against different regions of the genomic or antigenomic RNA of Sendai virus were constructed. All RNAs contained the same catalytic domain based on hammerhead ribozymes but some had deletions or mutations resulting in imperfect helices I and III. Pre-annealed substrate/ribozyme complexes were used to determine the rates of the cleavage process for the different ribozymes under single-turnover conditions. It was found that the sequence context surrounding the cleavable motif influenced the cleavage efficiencies. Deletions or mutations of nucleotides 2.1 or 15.1 and 15.2 according to the numbering system for hammerhead ribozymes of Hertel et al. destroyed catalytic activity. Deletions of nucleotide 2.2 or additional nucleotides in the helix I-forming region of the ribozyme did not destruct, but only reduced the cleavage efficiencies. Similar results were observed for a deletion of nucleotide 15.3. Simultaneous deletions within helices I and III resulted in alternative cleavage sites. The potential consequences for the specificity of the ribozyme reaction are discussed.     

Extension of helix II of an HIV-1-directed hammerhead ribozyme with long antisense flanks does not alter kinetic parameters in vitro but causes loss of the inhibitory potential in living cells.

When designed to cleave a target RNA in trans, the hammerhead ribozyme contains two antisense flanks which form helix I and helix III by pairing with the complementary target RNA. The sequences forming helix II are contained on the ribozyme strand and represent a major structural component of the hammerhead structure. In the case of an inhibitory 429 nucleotides long trans-ribozyme (2as-Rz12) which was directed against the 5'-leader/gag region of the human immunodeficiency virus type 1 (HIV-1), helix II was not pre-formed in the single-stranded molecule. Thus, major structural changes are necessary before cleavage can occur. To study whether pre-formation of helix II in the non-paired 2as-Rz12 RNA could influence the observed cleavage rate in vitro and its inhibitory activity on HIV-1 replication, we extended the 4 base pair helix II of 2as-Rz12 to 6, 10, 21, and 22 base pairs respectively. Limited RNase cleavage reactions performed in vitro at 37 degrees C and at physiological ion strength indicated that a helix II of the hammerhead domain was pre-formed when its length was at least six base pairs. This modification neither affected the association rate with target RNA nor the cleavage rate in vitro. In contrast to this, extension of helix II led to a significantly decreased inhibition of HIV-1 replication in human cells. Together with the finding of others that shortening of helix II to less than two base pairs reduces the catalytic activity in vitro, this observation indicates that the length of helix II in the naturally occurring RNAs with a hammerhead domain is already close or identical to the optimal length for catalytic activity in vitro and in vivo.     

HIV-1 TAR as anchoring site for optimized catalytic RNAs

Ribozymes have a great potential for developing specific gene silencing molecules. One of the main limitations to ensure the efficient application of ribozymes is to achieve effective binding to the target. Stem-loop domains support efficient formation of the kissing complex between natural antisense molecules and their target sequence. We have characterized catalytic antisense RNA hybrid molecules composed of a hammerhead ribozyme and a stem-loop antisense domain. A series of artificial RNA substrates containing the TAR-RNA stem-loop and a target for the hammerhead ribozyme were constructed and challenged with a catalytic antisense RNA carrying the TAR complementary stem-loop. The catalytic antisense RNA cleaves each of these substrates significantly more efficiently than the parental hammerhead ribozyme. Deletion of the TAR domain in the substrate abolishes the positive effect. These results suggest that the enhancement is due to the interaction of both complementary stem-loop motifs. A similar improvement was corroborated when targeting the LTR region of HIV-1 with either hammerhead- and hairpin-based catalytic antisense RNAs. Our results indicate that the TAR domain can be used as an anchoring site to facilitate the access of ribozymes to their specific target sequences within TAR-containing RNAs. Finally, we propose the addition of stable stem-loop motifs to the ribozyme domain as a rational way for constructing catalytic antisense RNAs.     

Generation and application of asymmetric hammerhead ribozymes.

Most researchers who intend to suppress a particular gene are interested primarily in the application of ribozyme technology rather than its mechanistic details. This article provides some background information and describes a straightforward strategy to generate and test a special design of a ribozyme: the asymmetric hammerhead ribozyme. This version of a hammerhead ribozyme carries at its 5' end the catalytic domain and at its 3' end a relatively long antisense flank that is complementary to the target RNA. Asymmetric hammerhead ribozymes can be constructed via polymerase chain reaction amplification, and rules are provided on how to select the DNA oligonucleotides required for this reaction. In addition to details on construction, we describe how to test asymmetric hammerhead ribozymes for association with the target RNA in vitro, so that RNA constructs can be selected and optimized for fast hybridization with their target RNA. This test can allow one to minimize association problems caused by the secondary structure of the target RNA. Additionally, we describe the in vitro cleavage assay and the determination of the cleavage rate constant. Testing for efficient cleavage is also a prerequisite for reliable and successful application of the technology. A carefully selected RNA will be more promising when eventually used for target suppression in living cells.     

The effect of structure in a long target RNA on ribozyme cleavage efficiency.

Inhibition of gene expression by catalytic RNA (ribozymes) requires that ribozymes efficiently cleave specific sites within large target RNAs. However, the cleavage of long target RNAs by ribozymes is much less efficient than cleavage of short oligonucleotide substrates because of higher order structure in the long target RNA. To further study the effects of long target RNA structure on ribozyme cleavage efficiency, we determined the accessibility of seven hammerhead ribozyme cleavage sites in a target RNA that contained human immunodeficiency virus type 1 (HIV-1) vif - vpr . The base pairing-availability of individual nucleotides at each cleavage site was then assessed by chemical modification mapping. The ability of hammerhead ribozymes to cleave the long target RNA was most strongly correlated with the availability of nucleotides near the cleavage site for base pairing with the ribozyme. Moreover, the accessibility of the seven hammerhead ribozyme cleavage sites in the long target RNA varied by up to 400-fold but was directly determined by the availability of cleavage sites for base pairing with the ribozyme. It is therefore unlikely that steric interference affected hammerhead ribozyme cleavage. Chemical modification mapping of cleavage site structure may therefore provide a means to identify efficient hammerhead ribozyme cleavage sites in long target RNAs.     

The antisense sequence of the HIV-1 TAR stem-loop structure covalently linked to the hairpin ribozyme enhances its catalytic activity against two artificial substrates

This work is an in vitro study of the efficiency of catalytic antisense RNAs whose catalytic domain is the wild-type sequence of the hairpin ribozyme, derived from the minus strand of the tobacco ringspot virus satellite RNA. The sequence in the target RNA recognized by the antisense molecule was the stem-loop structure of the human immunodeficiency virus-1 (HIV-1) TAR region. This region was able to form a complex with its antisense RNA with a binding rate of 2 x 10(4) M(-1)s(-1). Any deletion of the antisense RNA comprising nucleotides of the stem-loop resulted in a decrease in binding rate. Sequences 3' of the stem in the sense RNA also contributed to binding. This stem-loop TAR-antisense segment, covalently linked to a hairpin ribozyme, enhanced its catalytic activity. The highest cleavage rate was obtained when the stem-loop structure was present in both ribozyme and substrate RNAs and they were complementary. Similarly, an extension at the 5'-end of the hairpin ribozyme increased the cleavage rate when its complementary sequence was present in the substrate. Inclusion of the stem-loop at the 3'-end and the extension at the 5'-end of the hairpin ribozyme abolished the positive effect of both antisense units independently. These results may help in the design of hairpin ribozymes for gene silencing.     

Comparative analysis of cleavage rates after systematic permutation of the NUX consensus target motif for hammerhead ribozymes.

A trans-cleaving asymmetric hammerhead ribozyme directed against an AUC decreases target motif within an RNA specific for human immunodeficiency virus type 1 (HIV-1) was generated. The AUC decreases motif of the target RNA was permutated in order to generate all 12 variants of an NUX decreases consensus target motif, wherein N = A, C, G or U and X = A, C or U. Four asymmetric hammerhead ribozymes differing in the nucleotide that is complementary to N were generated, of which each was specific for three of the 12 target motifs. The residual sequence context within helices I and III remained unchanged. All 12 combinations resulted in cleavage of the target RNA. Using single-turnover conditions, the detectable cleavage rate constants at 37 degrees C were determined, which varied considerably depending on the NUX decreases motif. The NUC decreases motifs were cleaved more efficiently, with AUC decreases being cleaved best. Comparison with previous studies indicates that the sequence context of the NUX decreases motif plays a major role for the detectable cleavage activity.     

Probing RNA tertiary structure: interhelical crosslinking of the hammerhead ribozyme.

Distinct structural models for the hammerhead ribozyme derived from single-crystal X-ray diffraction and fluorescence resonance energy transfer (FRET) measurements have been compared. Both models predict the same overall geometry, a wishbone shape with helices II and III nearly colinear and helix I positioned close to helix II. However, the relative orientations of helices I and II are different. To establish whether one of the models represents a kinetically active structure, a new crosslinking procedure was developed in which helices I and II of hammerhead ribozymes were disulfide-crosslinked via the 2' positions of specific sugar residues. Crosslinking residues on helices I and II that are close according to the X-ray structure did not appreciably reduce the catalytic efficiency. In contrast, crosslinking residues closely situated according to the FRET model dramatically reduced the cleavage rate by at least three orders of magnitude. These correlations between catalytic efficiencies and spatial proximities are consistent with the X-ray structure.     

Effects of variations in length of hammerhead ribozyme antisense arms upon the cleavage of longer RNA substrates.

The efficacy of intracellular binding of hammerhead ribozyme to its cleavage site in target RNA is a major requirement for its use as a therapeutic agent. Such efficacy can be influenced by several factors, such as the length of the ribozyme antisense arms and mRNA secondary structures. Analysis of various IL-2 hammerhead ribozymes having different antisense arms but directed to the same site predicts that the hammerhead ribozyme target site is present within a double-stranded region that is flanked by single-stranded loops. Extension of the low cleaving hammerhead ribozyme antisense arms by nucleotides that base pair with the single-stranded regions facilitated the hammerhead ribozyme binding to longer RNA substrates (e.g. mRNA). In addition, a correlation between the in vitro and intracellular results was also found. Thus, the present study would facilitate the design of hammerhead ribozymes directed against higher order structured sites. Further, it emphasises the importance of detailed structural investigations of hammerhead ribozyme full-length target RNAs.     

Design, characterization and testing of tRNA3Lys-based hammerhead ribozymes

A hammerhead ribozyme targeted against the HIV-1 env coding region was expressed as part of the anticodon loop of human tRNA3Lys without sacrificing tRNA stability or ribozyme catalytic activity. These tRNA-ribozymes were isolated from a library which was designed to contain linkers (sequences connecting the ribozyme to the anticodon loop) of random sequence and variable length. The ribozyme target site was provided in cis during selection and in trans during subsequent characterization. tRNA-ribozymes that possessed ideal combinations of linkers were expected to recognize the cis target site more freely and undergo cleavage. The cleaved molecules were isolated, cloned and characterized. Active tRNA-ribozymes were identified and the structural features conducive to cleavage were defined. The selected tRNA-ribozymes were stable, possessed cleavage rates lower or similar to the linear hammerhead ribozyme, and could be transcribed by an extract containing RNA polymerase III. Retroviral vectors expressing tRNA-ribozymes were tested in a human CD4+ T cell line and were shown to inhibit HIV-1 replication. These tRNA3Lys-based hammerhead ribozymes should therefore prove to be valuable for both basic and applied research. Special application is sought in HIV-1 or HIV-2 gene therapy.     

The tolerance to exchanges of the Watson Crick base pair in the hammerhead ribozyme core is determined by surrounding elements

Tertiary interacting elements are important features of functional RNA molecules, for example, in all small nucleolytic ribozymes. The recent crystal structure of a tertiary stabilized type I hammerhead ribozyme revealed a conventional Watson-Crick base pair in the catalytic core, formed between nucleotides C3 and G8. We show that any Watson-Crick base pair between these positions retains cleavage competence in two type III ribozymes. In the Arabidopsis thaliana sequence, only moderate differences in cleavage rates are observed for the different base pairs, while the peach latent mosaic viroid (PLMVd) ribozyme exhibits a preference for a pyrimidine at position 3 and a purine at position 8. To understand these differences, we created a series of chimeric ribozymes in which we swapped sequence elements that surround the catalytic core. The kinetic characterization of the resulting ribozymes revealed that the tertiary interacting loop sequences of the PLMVd ribozyme are sufficient to induce the preference for Y3-R8 base pairs in the A. thaliana hammerhead ribozyme. In contrast to this, only when the entire stem-loops I and II of the A. thaliana sequences are grafted on the PLMVd ribozyme is any Watson-Crick base pair similarly tolerated. The data provide evidence for a complex interplay of secondary and tertiary structure elements that lead, mediated by long-range effects, to an individual modulation of the local structure in the catalytic core of different hammerhead ribozymes.     

Ribozymes that cleave an RNA sequence from human immunodeficiency virus: the effect of flanking sequence on rate

Ribozymes designed to cleave sequences specific to viral RNA may be better antiviral agents than simple antisense oligonucleotides. High catalytic activity with the lowest possible chain length is desired for this purpose. We have synthesized several hammerhead ribozymes that cleave sequences from HIV-1 RNA. On reducing from 20 to 12 the base pairs formed with the substrate, the rate of cleavage at 37 degrees C increased 10-fold. Deletions from the stem/loop structure in the ribozyme also increased the initial rate of reaction.     

Incorporation of the catalytic domain of a hammerhead ribozyme into antisense RNA enhances its inhibitory effect on the replication of human immunodeficiency virus type 1.

The catalytic domain of a hammerhead ribozyme was incorporated into a 413 nucleotides long antisense RNA directed against the 5'-leader/gag region of the human immunodeficiency virus type 1 (HIV-1) (pos. +222 to +634). The resulting catalytic antisense RNA was shown to cleave its target RNA in vitro specifically at physiological ion strength and temperature. We compared the antiviral effectiveness of this catalytic antisense RNA with that of the corresponding unmodified antisense RNA and with a mutated catalytic antisense RNA, which did not cleave the substrate RNA in vitro. Each of these RNAs was co-transfected into human SW480 cells together with infectious complete proviral HIV-1 DNA, followed by analysis of HIV-1 replication. The presence of the catalytically active domain resulted in 4 to 7 fold stronger inhibition of HIV-1 replication as compared to the parental antisense RNA and the inactive mutant. Kinetic and structural studies performed in vitro indicated that the ability for double strand formation was not changed in catalytic antisense RNA versus parental antisense RNA. Together, these data suggest that the ability to cleave target RNA is a crucial prerequisite for the observed increase of inhibition of the replication of HIV-1.     

Unexpected anisotropy in substrate cleavage rates by asymmetric hammerhead ribozymes.

RNA substrates which form relatively short helices I and III with hammerhead ribozymes are generally cleaved more rapidly than substrates which create longer binding helices. We speculated that for optimum cleavage rates, one of the helices needed to be relatively weak. To identify this helix, a series of ribozymes and substrates of varying lengths were made such that in the complex, helices I and III consisted of 5 and 10 bp respectively or vice versa. In two independent systems, substrates in the complexes with the shorter helix I and longer helix III were cleaved one to two orders of magnitude more rapidly than those in the complexes with the longer helix I and shorter helix III. Similar results were obtained whether the numbers of base pairs in helices I and III were limited either by the length of the hybridizing arms of the ribozyme or the length of the substrate. The phenomenon was observed for both all-RNA and DNA armed ribozymes. Thus, a relatively short helix I is required for fast cleavage rates in pre-formed hammer-head ribozyme-substrate complexes. When helix III has 10 bp, the optimum length for helix I is approximately 5 bp.     

Expression of a chimeric ribozyme gene results in endonucleolytic cleavage of target mRNA and a concomitant reduction of gene expression in vivo.

The subclass of catalytic RNAs termed ribozymes cleave specific target RNA sequences in vitro. Only circumstantial evidence supports the idea that ribozymes may also act in vivo. In this study, ribozymes with a hammerhead motif directed against a target sequence within the mRNA of the neomycin phosphotransferase gene (npt) were embedded into a functional chimeric gene. Two genes, one containing the ribozyme and the other producing the target, were cotransfected into plant protoplasts. Following in vivo expression, a predefined cleavage product of the target mRNA was detected by ribonuclease protection. Expression of both the ribozyme gene and the target gene was driven by the CaMV 35S promoter. Concomitant with the endonucleolytic cleavage of the target mRNA, a complete reduction of NPT activity was observed. An A to G substitution within the ribozyme domain completely inactivates ribozyme-mediated hydrolysis but still shows a reduction in NPT activity, albeit less pronounced. Therefore, the reduction of NPT activity produced by the active ribozyme is best explained by both hydrolytic cleavage and an antisense effect. However, the mutant ribozyme--target complex was more stable than the wildtype ribozyme--target complex. This may result in an overestimation of the antisense effect contributing to the overall reduction of gene expression.