Interaction of structural modules in substrate binding by the ribozyme from Bacillus subtilis RNase P.

The ribozyme from bacterial ribonuclease P recognizes two structural modules in a tRNA substrate: the T stem-loop and the acceptor stem. These two modules are connected through a helical linker. The T stem-loop binds at a surface confined in a folding domain away from the active site. Substrates for the Bacillus subtilis RNase P RNA were previously selected in vitro that are shown to bind comparably well or better than a tRNA substrate. Chemical modification of P RNA-substrate complexes with dimethylsulfate and kethoxal was performed to determine how the P RNA recognizes three in vitro selected substrates. All three substrates bind at the surface known to interact with the T stem-loop of tRNA. Similar to a tRNA, the secondary structure of these substrates contains a helix around the cleavage site and a hairpin loop at the corresponding position of the T stem-loop. Unlike a tRNA, these two structural modules are connected through a non-helical linker. The two structural modules in the tRNA and in the selected substrates bind to two different domains in P RNA. The properties of substrate recognition exhibited by this ribozyme may be exploited to isolate new ribozyme-substrate pairs with interactive structural modules.     

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.     

Anchoring hairpin ribozymes to long target RNAs by loop-loop RNA interactions

Efficient ribozyme-mediated gene silencing requires the effective binding of a ribozyme to its specific target sequence. Stable stem-loop domains are key elements for efficiency of natural antisense RNAs. This work tests the possibility of using such naturally existing structural motifs for anchoring hairpin ribozymes when targeting long RNAs. Assays were performed with four catalytic antisense RNAs, based on the hairpin ribozyme (HP), that carried a stable stem-loop motif at their 3' end. Extensions consisted of one of the following motifs: the stem-loop II of the natural antisense RNA-CopA, its natural target in CopT, the TAR-RNA motif, or its complementary sequence alphaTAR. Interestingly, the presence of any of these antisense motifs resulted in an enhancement of catalytic performance against the ribozyme's 14-nucleotide-long target RNA (Swt). A series of artificial, long RNA substrates containing the Swt sequence and the natural TAR-RNA stem-loop were constructed and challenged with a catalytic antisense RNA carrying the TAR-complementary stem-loop. This cleaves each of these substrates significantly more efficiently than HP. The deletion of the TAR domain in the substrate, or its substitution by its complementary counterpart alphaTAR, abolishes the positive effect. These results suggest that the enhancement is owed to the interaction of both complementary stem-loop domains. Moreover, they demonstrate that the TAR domain can be used as an anchoring site to facilitate the access of hairpin ribozymes to their specific target sequences within TAR-containing RNAs.     

Design and isolation of ribozyme-substrate pairs using RNase P-based ribozymes containing altered substrate binding sites.

Substrate recognition and cleavage by the bacterial RNase P RNA requires two domains, a specificity domain, or S-domain, and a catalytic domain, or C-domain. The S-domain binds the T stem-loop region in a pre-tRNA substrate to confer specificity for tRNA substrates. In this work, the entire S-domain of the Bacillus subtilis RNase P RNA is replaced with an artificial substrate binding module. New RNA substrates are isolated by in vitro selection using two libraries containing random regions of 60 nt. At the end of the selection, the cleavage rates of the substrate library are approximately 0.7 min(-1)in 10 mM MgCl(2)at 37 degrees C, approximately 4-fold better than the cleavage of a pre-tRNA substrate by the wild-type RNase P RNA under the same conditions. The contribution of the S-domain replacement to the catalytic efficiency is from 6- to 22 000-fold. Chemical and nuclease mapping of two ribozyme-product complexes shows that this contribution correlates with direct interactions between the S-domain replacement and the selected substrate. These results demonstrate the feasibility of design and isolation of RNase P-based, matching ribozyme-substrate pairs without prior knowledge of the sequence or structure of the interactive modules in the ribozyme or substrate.     

Nuclease footprint analyses of the interactions between RNase P ribozyme and a model mRNA substrate.

RNase P ribozyme cleaves an RNA helix substrate which resembles the acceptor stem and T-stem structures of its natural tRNA substrate. By linking the ribozyme covalently to a sequence (guide sequence) complementary to a target RNA, the catalytic RNA can be converted into a sequence-specific ribozyme, M1GS RNA. We have previously shown that M1GS RNA can efficiently cleave the mRNA sequence encoding thymidine kinase (TK) of herpes simplex virus 1. In this study, a footprint procedure using different nucleases was carried out to map the regions of a M1GS ribozyme that potentially interact with the TK mRNA substrate. The ribozyme regions that are protected from nuclease degradation in the presence of the TK mRNA substrate include those that interact with the acceptor stem and T-stem, the 3' terminal CCA sequence and the cleavage site of a tRNA substrate. However, some of the protected regions (e.g. P13 and P14) are unique and not among those protected in the presence of a tRNA substrate. Identification of the regions that interact with a mRNA substrate will allow us to study how M1GS RNA recognizes a mRNA substrate and facilitate the development of mRNA-cleaving ribozymes for gene-targeting applications.     

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.     

Interaction between hammerhead ribozyme and RNA substrates measured by a surface plasmon resonance biosensor

Dynamic interactions between hammerhead ribozymes and RNA substrates were measured using the surface plasmon resonance (SPR) technology. Two in vitro transcribed substrates (non-cleavable and cleavable) were immobilised on streptavidin-coated dextran matrices and subsequently challenged with non-related yeast tRNA or two hammerhead ribozymes, both of which had previously been shown to exhibit functional binding and cleavage of complementary target RNAs. The target-binding domain of one of the ribozymes was fully complementary to a 16-ribonucleotide stretch on the immobilised substrates, while the other ribozyme had a nine-ribonucleotide complementarity. The two ribozymes could readily be differentiated with regard to affinity. Cleavage could be measured, using the ribozyme with full target complementarity to the cleavable substrate. In contrast, the ribozyme with lower affinity lacked cleavage activity. We suggest that SPR will be useful for investigations of ribozyme-substrate interactions.     

Substrate Shape Preference of Escherichia coli Ribonuclease P Ribozyme and Holo Enzyme Using Bottom-Half Part-Shifting Variants of Pre-tRNA

We showed previously that the bacterial ribonuclease P (RNase P) ribozyme has substrate shape preference depending on the concentrations of catalytically important magnesium ions. The ribozyme discriminates a canonical cloverleaf precursor tRNA from a hairpin RNA with a CCA-tag sequence at low concentrations of magnesium ions. By detailed analysis of the shape preference using the bottom-half part-shifting variants of a tRNA precursor, we showed that the RNAs in a T-shape structure can be substrates for the ribozyme reactions even at low concentrations of magnesium ions, and that the RNA in a natural L-shape is the best substrate for both the ribozyme and the holo enzyme. The results also showed that the position of the bottom-half part did not affect the cleavage site selection of a substrate by the enzyme. Our results are the first kinetic evidence to show the importance of the bottom-half part of tRNA molecule, and our result also showed that the holo enzyme can discriminate substrate shape as well as the ribozyme at low concentrations of metal ions.     

Substrate shape preference of Escherichia coli ribonuclease P ribozyme and holo enzyme using bottom-half part-shifting variants of pre-tRNA

We showed previously that the bacterial ribonuclease P (RNase P) ribozyme has substrate shape preference depending on the concentrations of catalytically important magnesium ions. The ribozyme discriminates a canonical cloverleaf precursor tRNA from a hairpin RNA with a CCA-tag sequence at low concentrations of magnesium ions. By detailed analysis of the shape preference using the bottom-half part-shifting variants of a tRNA precursor, we showed that the RNAs in a T-shape structure can be substrates for the ribozyme reactions even at low concentrations of magnesium ions, and that the RNA in a natural L-shape is the best substrate for both the ribozyme and the holo enzyme. The results also showed that the position of the bottom-half part did not affect the cleavage site selection of a substrate by the enzyme. Our results are the first kinetic evidence to show the importance of the bottom-half part of tRNA molecule, and our result also showed that the holo enzyme can discriminate substrate shape as well as the ribozyme at low concentrations of metal ions.     

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.     

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.     

RNase P ribozymes selected in vitro to cleave a viral mRNA effectively inhibit its expression in cell culture

An in vitro selection procedure was used to select RNase P ribozyme variants that efficiently cleaved the sequence of the mRNA encoding thymidine kinase of herpes simplex virus 1. Of the 45 selected variants sequenced, 25 ribozymes carried a common mutation at nucleotides 224 and 225 of RNase P catalytic RNA from Escherichia coli (G(224)G(225) --> AA). These selected ribozymes exhibited at least 10 times higher cleavage efficiency (k(cat)/K(m)) than that derived from the wild type ribozyme. Our results suggest that the mutated A(224)A(225) are in close proximity to the substrate and enhance substrate binding of the ribozyme. When these ribozyme variants were expressed in herpes simplex virus 1-infected cells, the levels of thymidine kinase mRNA and protein were reduced by 95-99%. Our study provides the first direct evidence that RNase P ribozyme variants isolated by the selection procedure can be used for the construction of gene-targeting ribozymes that are highly effective in tissue culture. These results demonstrate the potential for using RNase P ribozymes as gene-targeting agents against any mRNA sequences, and using the selection procedure as a general approach for the engineering of RNase P ribozymes.     

Developing RNase P ribozymes for gene-targeting and antiviral therapy

RNase P, a tRNA processing enzyme, contains both RNA and protein subunits. M1 RNA, the catalytic RNA subunit of RNase P from Escherichia coli, recognizes its target RNA substrate mainly on the basis of its structure and cleaves a double stranded RNA helix at the 5' end that resembles the acceptor stem and T-stem structure of its natural tRNA substrate. Accordingly, a guide sequence (GS) can be covalently attached to the M1 RNA to generate a sequence specific ribozyme, M1GS RNA. M1GS ribozyme can target any mRNA sequence of choice that is complementary to its guide sequence. Recent studies have shown that M1GS ribozymes efficiently cleave the mRNAs of herpes simplex virus 1 and human cytomegalovirus, and the BCR-ABL oncogenic mRNA in vitro and effectively reduce the expression of these mRNAs in cultured cells. Moreover, an in vitro selection scheme has been developed to select for M1 GS ribozyme variants with more efficient catalytic activity in cleaving mRNAs. When expressed in cultured cells, these selected ribozymes also show an enhance ability to inhibit viral gene expression and growth. These recent results demonstrate the feasibility of developing the M1GS ribozyme-based technology as a promising gene targeting approach for basic research and clinical therapeutic application.     

Optimizing the substrate specificity of a group I intron ribozyme

Group I ribozymes can repair mutant RNAs via trans-splicing. Unfortunately, substrate specificity is quite low for the trans-splicing reaction catalyzed by the group I ribozyme from Tetrahymenathermophila. We have used a systematic approach based on biochemical knowledge of the function of the Tetrahymena ribozyme to optimize its ability to discriminate against nonspecific substrates in vitro. Ribozyme derivatives that combine a mutation which indirectly slows down the rate of the chemical cleavage step by weakening guanosine binding with additional mutations that weaken substrate binding have greatly enhanced specificity with short oligonucleotide substrates and an mRNA fragment derived from the p53 gene. Moreover, compared to the wild-type ribozyme, reaction of a more specific ribozyme with targeted substrates is much less sensitive to the presence of nonspecific RNA competitors. These results demonstrate how a detailed understanding of the biochemistry of a catalytic RNA can facilitate the design of customized ribozymes with improved properties for therapeutic applications.     

Efficient trans-cleavage of a stem-loop RNA substrate by a ribozyme derived from neurospora VS RNA.

We have constructed a ribozyme containing 144 nucleotides of Neurospora VS RNA that can catalyze the cleavage of a separate RNA in a true enzymatic manner (Km approximately 0.13 microM, kcat approximately 0.7/min). Comparison of the rates of cis- and trans-cleavage, as well as the lack of effect of pH on the rate of cleavage, suggest that a rate-limiting step, possibly a conformational change, occurs prior to cleavage. The minimum contiguous substrate sequence required for cleavage consists of one nucleotide upstream and 19 nucleotides downstream of the cleavage site. Unlike most other ribozymes which interact with long single-stranded regions of their substrates, the minimal substrate for the VS ribozyme consists mostly of a stable stem-loop, which would appear to preclude its recognition simply via extensive Watson-Crick base pairing.     

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

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

Rearrangement of substrate secondary structure facilitates binding to the Neurospora VS ribozyme

The Neurospora VS ribozyme differs from other small, naturally occurring ribozymes in that it recognizes for trans cleavage or ligation a substrate that consists largely of a stem-loop structure. We have previously found that cleavage or ligation by the VS ribozyme requires substantial rearrangement of the secondary structure of stem-loop I, which contains the cleavage/ligation site. This rearrangement includes breaking the top base-pair of stem-loop I, allowing formation of a kissing interaction with loop V, and changing the partners of at least three other base-pairs within stem-loop I to adopt a conformation termed shifted. In the work presented, we have designed a binding assay and used mutational analysis to investigate the contribution of each of these structural changes to binding and ligation. We find that the loop I-V kissing interaction is necessary but not sufficient for binding and ligation. Constitutive opening of the top base-pair of stem-loop I has little, if any, effect on either activity. In contrast, the ability to adopt the shifted conformation of stem-loop I is a major determinant of binding: mutants that cannot adopt this conformation bind much more weakly than wild-type and mutants with a constitutively shifted stem-loop I bind much more strongly. These results implicate the adoption of the shifted structure of stem-loop I as an important process at the binding step in the VS ribozyme reaction pathway. Further investigation of features near the cleavage/ligation site revealed that sulphur substitution of the non-bridging phosphate oxygen atoms immediately downstream of the cleavage/ligation site, implicated in a putative metal ion binding site, significantly altered the cleavage/ligation equilibrium but did not perturb substrate binding significantly. This indicates that the substituted oxygen atoms, or an associated metal ion, affect a step that occurs after binding and that they influence the rates of cleavage and ligation differently.     

Modular construction of a tertiary RNA structure: the specificity domain of the Bacillus subtilis RNase P RNA

The structure of the specificity domain (S-domain) of the Bacillus subtilis RNase P RNA has been proposed to be composed of a core and a buttress module, analogous to the bipartite structure of the P4-P6 domain of the Tetrahymena group I ribozyme. The core module is the functional unit of the S-domain and contains the binding site for the T stem-loop of a tRNA. The buttress module provides structural stability to the core module and consists of a GA3 tetraloop and its receptor. To explicitly test the hypothesis that modular construction can describe the structure of the S-domain and is a useful RNA design strategy, we analyzed the equilibrium folding and substrate binding of three classes of S-domain mutants. Addition or deletion of a base pair in the helical linker region between the modules only modestly destabilizes the tertiary structure. tRNA binding selectivity is affected in one but not in two other mutants of this class. Elimination of the GA3 tetraloop-receptor interactions significantly destabilizes the core module and results in the loss of tRNA binding selectivity. Replacing the buttress module with that of a homologous RNase P RNA maintains the tRNA binding selectivity. Overall, we have observed that the linker regions between the two modules can tolerate moderate structural changes and that the buttress modules can be shuffled between homologous S-domains. These results suggest that it is feasible to design an RNA using a buttress module to stabilize a functional module.     

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.     

Broadening the mission of an RNA enzyme

The “RNA World” hypothesis suggests that life developed from RNA enzymes termed ribozymes, which carry out reactions without assistance from proteins. Ribonuclease (RNase) P is one ribozyme that appears to have adapted these origins to modern cellular life by adding protein to the RNA core in order to broaden the potential functions. This RNA‐protein complex plays diverse roles in processing RNA, but its best‐understood reaction is pre‐tRNA maturation, resulting in mature 5' ends of tRNAs. The core catalytic activity resides in the RNA subunit of almost all RNase P enzymes but broader substrate tolerance is required for recognizing not only the diverse sequences of tRNAs, but also additional cellular RNA substrates. This broader substrate tolerance is provided by the addition of protein to the RNA core and allows RNase P to selectively recognize different RNAs, and possibly ribonucleoprotein (RNP) substrates. Thus, increased protein content correlated with evolution from bacteria to eukaryotes has further enhanced substrate potential enabling the enzyme to function in a complex cellular environment. J. Cell. Biochem. 108: 1244–1251, 2009. © 2009 Wiley‐Liss, Inc.