Inosine(15.1) hammerhead ribozymes for targeting the transthyretin-30 mutation.

The most common cause of hereditary amyloidosis (HA) is the val30met mutation in the transthyretin protein (TTR-met30). The mutation is caused by a mononucleic substitution from G to A (GUC to AUC) in the transthyretin gene resulting in the exchange for the amino acids valine to methionine in the corresponding protein sequence. The aim of our work was the development of a specific cleavage of TTR-30 mRNA using hammerhead ribozymes. We chemically modified nuclease stable hammerhead ribozymes to target the TTR-30 mRNA with high specificity. The exchange of adenosine(15.1) with inosine(15.1) in the catalytic core of the hammerhead ribozyme resulted in a change of the cleavable target sequence from N(16.2)U(16.1)H(17) to N(16. 2)C(16.1)H(17) without loss in ribozymal activity (Nucleic Acids Res. 26, 2279-2285, 1998). This modification allowed a specific cleavage of the TTR-30 mutation ("gCC Gug" to "gCC Aug"). In vitro experiments with TTR-30 mRNA demonstrated that the RNase stable inosine(15.1) hammerhead ribozyme cleaved the TTR-30 mRNA with 100% specificity and with a velocity of 0.23 min(-1), whereas no cleavage occured in the wildtype mRNA of TTR. In conclusion, the development of this NCH specific hammerhead ribozyme represents a promising tool for future in vivo therapeutic application for TTR-met30 induced hereditary amyloidosis.     

特异切割马铃薯卷叶病毒复制酶基因负链的核酶研究

根据锤头状核酶的作用模式,设计、合成并克隆了特异性切割马铃薯地病毒中国分离株（ＰＬＲＶ－Ｃｈ）复制酶基因负链ＲＮＡ的核酶序列,以体外转录的ＰＬＲＶ－Ｃｈ复制酶基因负链ＲＮＡ作为底物,与转录的核酶ＲＮＡ共同保温,以检测核酶对底和的体外切割作用。实验结果表明,核酸疼 ＲＮＡ对ＰＬＲＶ－Ｃｈ复制酶基因负锭ＲＮＡ具有特异切割作用。     

A method for prediction of accessible sites on an mRNA sequence for target selection of hammerhead ribozymes.

Hammerhead ribozymes are short RNA molecules endowed with endoribonucleolytic activity. Their use as molecular tools for specific inhibition of gene translation is affected by many factors including the target accessibility. A method for the prediction of accessible target sites for hammerhead ribozymes within a given RNA sequence is described. This method maps all putative NUH cleavage sites (N = A, C, G, U and H = A, C, U) and picks out short flanking regions as the binding domain for the corresponding ribozyme. The probabilistic level of unfolding, accessibility score (AS), is then calculated for each target region on the basis of a comparison of all folding structures obtained for the target RNA and arranged according to the Boltzmann's distribution. At the end, a series of imposed limits gives the best target sequences endowed with highly probable accessibility and with a potentially active catalytic structure of the hammerhead sequence. A successive experimental approach to verify the effective accessibility of selected targets was used. For that, antisense oligonucleotides addressed to the coding region of bcl2 mRNA were synthesized and administered to the MCF7 human cell line. The inhibition of gene expression, as measured by western analysis of the BCL2 protein, demonstrated that all target sites selected on the basis of their putative accessibility were actually sensitive to antisense treatments while the inaccessible ones were not. The application of this target discovery method to ribozyme design is proposed in order to satisfy a crucial condition.     

Selection of a novel class of RNA-RNA interaction motifs based on the ligase ribozyme with defined modular architecture

To develop molecular tools for the detection and control of RNA molecules whose functions rely on their 3D structures, we have devised a selection system to isolate novel RNA motifs that interact with a target RNA structure within a given structural context. In this system, a GAAA tetraloop and its specific receptor motif (11-ntR) from an artificial RNA ligase ribozyme with modular architecture (the DSL ribozyme) were replaced with a target structure and random sequence, respectively. Motifs recognizing the target structure can be identified by in vitro selection based on ribozyme activity. A model selection targeting GAAA-loop successfully identified motifs previously known as GAAA-loop receptors. In addition, a new selection targeting a C-loop motif also generated novel motifs that interact with this structure. Biochemical analysis of one of the C-loop receptor motifs revealed that it could also function as an independent structural unit.     

In vitro evolution of the hammerhead ribozyme to a purine-specific ribozyme using mutagenic PCR with two nucleotide analogues

The conventional hammerhead ribozyme cleaves RNA 3' to nucleotide triplets with the general formula NUH, where N is any nucleotide, U is uridine and H is any nucleotide except guanosine. In order to isolate hammerhead ribozyme sequences capable of cleaving 3' to the GUG triplet, we performed a mutagenic selection protocol starting with the conventional sequence of an NUH-cleaving ribozyme. The 22 nucleotides in the core and the stem-loop II region were subjected to mutagenic PCR using the two nucleotide analogues 6-(2-deoxy-beta-d-ribofuranosyl)-3,4-dihydro-8H-pyrimido-[4,5-C)][1, 2] oxazin-7-one and of 8-oxo-2'-deoxyguanosine. After five repetitions of the selection cycle, several clones showed cleavage activity. One sequence, having one deletion, showed at least a 90 times higher in trans cleavage rate than the starting ribozyme. It cleaved 3' to GUG and GUA. The sequence of this ribozyme is essentially identical with that obtained previously by selection for AUG cleavage starting with a randomised core and stem-loop II region. This identical result of two independent selection procedures supports the notion that sequences for NUR cleavage, where R is a purine nucleotide, are not compatible with the classical hammerhead structure, and that the sequence space for this cleavage specificity is very limited. The cleavage of NUR triplets is not restricted to the sequence of the substrate that was used for selection but is sequence-independent for in trans cleavage, although the sequence context influences the value for the cleavage rate somewhat. Analysis of cleavage activities indicates the importance of A at position L2.5 in loop II.     

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.     

Enhanced RNA cleavage within bulge-loops by an artificial ribonuclease

Cleavage of phosphodiester bonds by small ribonuclease mimics within different bulge-loops of RNA was investigated. Bulge-loops of different size (1–7 nt) and sequence composition were formed in a 3′ terminal fragment of influenza virus M2 RNA (96 nt) by hybridization of complementary oligodeoxynucleotides. Small bulges (up to 4 nt) were readily formed upon oligonucleotide hybridization, whereas hybridization of the RNA to the oligonucleotides designed to produce larger bulges resulted in formation of several alternative structures. A synthetic ribonuclease mimic displaying Pyr–Pu cleavage specificity cleaved CpA motifs located within bulges faster than similar motifs within the rest of the RNA. In the presence of 10 mM MgCl₂, 75% of the cleavage products resulted from the attack of this motif. Thus, selective RNA cleavage at a single target phosphodiester bond was achieved by using bulge forming oligonucleotides and a small ribonuclease A mimic.     

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.     

Improved Computational Target Site Prediction for Pentatricopeptide Repeat RNA Editing Factors

Pentatricopeptide repeat (PPR) proteins with an E domain have been identified as specific factors for C to U RNA editing in plant organelles. These PPR proteins bind to a unique sequence motif 5′ of their target editing sites. Recently, involvement of a combinatorial amino acid code in the P (normal length) and S type (short) PPR domains in sequence specific RNA binding was reported. PPR proteins involved in RNA editing, however, contain not only P and S motifs but also their long variants L (long) and L2 (long2) and the S2 (short2) motifs. We now find that inclusion of these motifs improves the prediction of RNA editing target sites. Previously overlooked RNA editing target sites are suggested from the PPR motif structures of known E-class PPR proteins and are experimentally verified. RNA editing target sites are assigned for the novel PPR protein MEF32 (mitochondrial editing factor 32) and are confirmed in the cDNA.     

Dynamic guide-target interactions contribute to sequential 2'-O-methylation by a unique archaeal dual guide box C/D sRNP

Assembly and guide-target interaction of an archaeal box C/D-guide sRNP was investigated under various conditions by analyzing the lead (II)-induced cleavage of the guide RNA. Guide and target RNAs derived from Haloferax volcanii pre-tRNA(Trp) were used with recombinant Methanocaldococcus jannaschii core proteins in the reactions. Core protein L7Ae binds differentially to C/D and C'/D' motifs of the guide RNA, and interchanging the two motifs relative to the termini of the guide RNA did not affect L7Ae binding or sRNA function. L7Ae binding to the guide RNA exposes its D'-guide sequence first followed by the D guide. These exposures are reduced when aNop5p and aFib proteins are added. The exposed guide sequences did not pair with the target sequences in the presence of L7Ae alone. The D-guide sequence could pair with the target in the presence of L7Ae and aNop5p, suggesting a role of aNop5p in target recruitment and rearrangement of sRNA structure. aFib binding further stabilizes this pairing. After box C/D-guided modification, target-guide pairing at the D-guide sequence is disrupted, suggesting that each round of methylation may require some conformational change or reassembly of the RNP. Asymmetric RNPs containing only one L7Ae at either of the two box motifs can be assembled, but a functional RNP requires L7Ae at the box C/D motif. This arrangement resembles the asymmetric eukaryal snoRNP. Observations of initial D-guide-target pairing and the functional requirement for L7Ae at the box C/D motif are consistent with our previous report of the sequential 2'-O-methylations of the target RNA.     

GNRA tetraloops make a U-turn.

The U-turn (uridine turn) is an RNA structural motif that contains a change in backbone direction stabilized by specific interactions across the bend. It was first identified in the anticodon loop and the T-loop of yeast tRNA(Phe) (Quigley & Rich, 1976, Science 194:796-806) and has recently also been found in the crystal structure of the hammerhead ribozyme (Pley HW, Flaherty KM, McKay DB, 1994a, Nature 372:68-74). These U-turn motifs follow a UNR consensus sequence (where N is any nucleotide and R is G or A). Here we report that the frequently occurring GNRA tetraloops also contain a U-turn motif, and we discuss the role of U-turns as abundant tertiary structural motifs in RNA.     

The C‐terminal portion of the cleaved HT motif is necessary and sufficient to mediate export of proteins from the malaria parasite into its host cell

The malaria parasite exports proteins across its plasma membrane and a surrounding parasitophorous vacuole membrane, into its host erythrocyte. Most exported proteins contain a Host Targeting motif (HT motif) that targets them for export. In the parasite secretory pathway, the HT motif is cleaved by the protease plasmepsin V, but the role of the newly generated N‐terminal sequence in protein export is unclear. Using a model protein that is cleaved by an exogenous viral protease, we show that the new N‐terminal sequence, normally generated by plasmepsin V cleavage, is sufficient to target a protein for export, and that cleavage by plasmepsin V is not coupled directly to the transfer of a protein to the next component in the export pathway. Mutation of the fourth and fifth positions of the HT motif, as well as amino acids further downstream, block or affect the efficiency of protein export indicating that this region is necessary for efficient export. We also show that the fifth position of the HT motif is important for plasmepsin V cleavage. Our results indicate that plasmepsin V cleavage is required to generate a new N‐terminal sequence that is necessary and sufficient to mediate protein export by the malaria parasite.     

Comparative single-turnover kinetic analyses of trans-cleaving hammerhead ribozymes with naturally derived non-conserved sequence motifs

trans-Cleaving hammerhead ribozyme variants were generated with mimicked non-conserved internal loop motifs derived from five structurally diverse natural cis-cleaving ribozymes. Most modified trans-cleaving variants showed enhanced single-turnover cleavage rates relative to minimal counterparts that lack tertiary interactions between internal loop motifs I and II, and relative to controls with sequence changes in loop I. The trans-cleaving ribozyme derived from the positive strand of peach latent mosaic viroid had the highest observed cleavage rate, suggesting a structurally optimized motif that facilitates rapid formation of the ribozyme catalytic center in a trans-reaction.     

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.     

Identification of a 67 kDa protein that binds specifically to the pre-rRNA primary processing site in a higher plant.

In radish pre-rRNA primary processing cleavage occurs at a UUUUCGCGC element (motif P) mapped in the 5'-external transcribed spacer (Delcasso-Tremousaygue et al., 1988). Significantly, motif P is part of a cluster of homologous elements including three UUUUCCGG elements (motifs A123) and a single UUUUGCCCC element (motif B). Here we used the EMSA to identify in radish extracts an RNA-binding activity, NF C, that specifically interacts with the pre-rRNA A123BP sequence. Using different RNA probes and competitors we show that NF C recognises a 38 base RNA sequence including the 3'-end of motif A3 and motifs B and P. NF C binds to poly U, but not to poly A, poly C or poly G. Therefore we used poly (U) Sepharose chromatography as a final step to obtain pure NF C fractions. These, analysed by SDS-PAGE, revealed two major polypeptides of 67 and 60 kDa. According to UV cross-linking analysis the 67 kDa polypeptide corresponds to NF C activity, while the 60 kDa species is a proteolysed form of this protein. We also showed that NF C is enriched in nuclear extracts. Based on its stringent RNA substrate specificity and its nuclear localisation we propose that NF C is involved in pre-rRNA primary processing in plants.     

The genomic HDV ribozyme utilizes a previously unnoticed U-turn motif to accomplish fast site-specific catalysis

The genome of the human hepatitis delta virus (HDV) harbors a self-cleaving catalytic RNA motif, the genomic HDV ribozyme, whose crystal structure shows the dangling nucleotides 5′ of the cleavage site projecting away from the catalytic core. This 5′-sequence contains a clinically conserved U − 1 that we find to be essential for fast cleavage, as the order of activity follows U − 1 > C − 1 > A − 1 > G − 1, with a >25-fold activity loss from U − 1 to G − 1. Terbium(III) footprinting detects conformations for the P1.1 stem, the cleavage site wobble pair and the A-minor motif of the catalytic trefoil turn that depend on the identity of the N − 1 base. The most tightly folded catalytic core, resembling that of the reaction product, is found in the U − 1 wild-type precursor. Molecular dynamics simulations demonstrate that a U − 1 forms the most robust kink around the scissile phosphate, exposing it to the catalytic C75 in a previously unnoticed U-turn motif found also, for example, in the hammerhead ribozyme and tRNAs. Strikingly, we find that the common structural U-turn motif serves distinct functions in the HDV and hammerhead ribozymes.     

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.     

Design of hairpin ribozyme variants with improved activity for poorly processed substrates

Application of ribozymes for knockdown of RNA targets requires the identification of suitable target sites according to the consensus sequence. For the hairpin ribozyme, this was originally defined as Y?2 N?1 *G+1 U+2 Y+3 B+?, with Y = U or C, and B = U, C or G, and C being the preferred nucleobase at positions -2 and +4. In the context of development of ribozymes for destruction of an oncogenic mRNA, we have designed ribozyme variants that efficiently process RNA substrates at U?2 G?1 *G+1 U+2 A+3 A+? sites. Substrates with G?1 *G+1 U+2 A+3 sites were previously shown to be processed by the wild-type hairpin ribozyme. However, our study demonstrates that, in the specific sequence context of the substrate studied herein, compensatory base changes in the ribozyme improve activity for cleavage (eight-fold) and ligation (100-fold). In particular, we show that A+3 and A+? are well tolerated if compensatory mutations are made at positions 6 and 7 of the ribozyme strand. Adenine at position +4 is neutralized by G? →U, owing to restoration of a Watson-Crick base pair in helix 1. In this ribozyme-substrate complex, adenine at position +3 is also tolerated, with a slightly decreased cleavage rate. Additional substitution of A? with uracil doubled the cleavage rate and restored ligation, which was lost in variants with A?, C? and G?. The ability to cleave, in conjunction with the inability to ligate RNA, makes these ribozyme variants particularly suitable candidates for RNA destruction.     

The ubiquitous hammerhead ribozyme

The hammerhead ribozyme is a small catalytic RNA motif capable of endonucleolytic (self-) cleavage. It is composed of a catalytic core of conserved nucleotides flanked by three helices, two of which form essential tertiary interactions for fast self-scission under physiological conditions. Originally discovered in subviral plant pathogens, its presence in several eukaryotic genomes has been reported since. More recently, this catalytic RNA motif has been shown to reside in a large number of genomes. We review the different approaches in discovering these new hammerhead ribozyme sequences and discuss possible biological functions of the genomic motifs.     

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.