Deoxyribozymes with 2'-5' RNA ligase activity

In vitro selection was used to identify deoxyribozymes that ligate two RNA substrates. In the ligation reaction, a 2'-5' RNA phosphodiester linkage is created from a 2',3'-cyclic phosphate and a 5'-hydroxyl group. The new Mg(2+)-dependent deoxyribozymes provide 50-60% yield of ligated RNA in overnight incubations at pH 7.5 and 37 degrees C, and they afford 40-50% yield in 1 h at pH 9.0 and 37 degrees C. Various RNA substrate sequences may be joined by simple Watson-Crick covaration of the DNA binding arms that interact with the two RNA substrates. The current deoxyribozymes have some RNA substrate sequence requirements at the nucleotides immediately surrounding the ligation junction (either UAUA GGAA or UAUN GGAA, where the arrow denotes the ligation site and N equals any nucleotide). One of the new deoxyribozymes was used to prepare by ligation the Tetrahymena group I intron RNA P4-P6 domain, a representative structured RNA. Nondenaturing gel electrophoresis revealed that a 2'-5' linkage between nucleotides A233 and G234 of P4-P6 does not disrupt its Mg(2+)-dependent folding (DeltaDeltaG degrees ' < 0.2 kcal/mol). This demonstrates that a 2'-5' linkage does not necessarily interfere with structure in a folded RNA. Therefore, these non-native linkages may be acceptable in modified RNAs when structure/function relationships are investigated. Deoxyribozymes that ligate RNA should be particularly useful for preparing site-specifically modified RNAs for studies of RNA structure, folding, and catalysis.     

Rational modification of a selection strategy leads to deoxyribozymes that create native 3'-5' RNA linkages

We previously used in vitro selection to identify several classes of deoxyribozymes that mediate RNA ligation by attack of a hydroxyl group at a 5'-triphosphate. In these reactions, the nucleophilic hydroxyl group is located at an internal 2'-position of an RNA substrate, leading to 2',5'-branched RNA. To obtain deoxyribozymes that instead create linear 3'-5'-linked (native) RNA, here we strategically modified the selection approach by embedding the nascent ligation junction within an RNA:DNA duplex region. This approach should favor formation of linear rather than branched RNA because the two RNA termini are spatially constrained by Watson-Crick base pairing during the ligation reaction. Furthermore, because native 3'-5' linkages are more stable in a duplex than isomeric non-native 2'-5' linkages, this strategy is predicted to favor the formation of 3'-5' linkages. All of the new deoxyribozymes indeed create only linear 3'-5' RNA, confirming the effectiveness of the rational design. The new deoxyribozymes ligate RNA with k(obs) values up to 0.5 h(-1) at 37 degrees C and 40 mM Mg2+, pH 9.0, with up to 41% yield at 3 h incubation. They require several specific RNA nucleotides on either side of the ligation junction, which may limit their practical generality. These RNA ligase deoxyribozymes are the first that create native 3'-5' RNA linkages, which to date have been highly elusive via other selection approaches.     

Deoxyribozymes that synthesize branched and lariat RNA

Branched RNA molecules with a 2',5'-phosphodiester linkage are important biochemical intermediates. Lariat RNA is a particular type of branched RNA that is formed during intron splicing in vivo. Synthesis of branched and lariat RNA is challenging, and there are few general approaches that are applicable in vitro. Here we report the identification of divalent metal-dependent deoxyribozymes (DNA enzymes) that synthesize branched and lariat RNA. In vitro selection was used to obtain deoxyribozymes that selectively join an internal RNA 2'-hydroxyl with a 5'-terminal triphosphate in a convenient "binding arms" format. At least 85% yield of 2',5'-branched RNA is obtained at 37 degrees C and 20 mM Mn2+, pH 7.5 in 相似文献   

Strong correlation between SHAPE chemistry and the generalized NMR order parameter (S2) in RNA

The functions of most RNA molecules are critically dependent on the distinct local dynamics that characterize secondary structure and tertiary interactions and on structural changes that occur upon binding by proteins and small molecule ligands. Measurements of RNA dynamics at nucleotide resolution set the foundation for understanding the roles of individual residues in folding, catalysis, and ligand recognition. In favorable cases, local order in small RNAs can be quantitatively analyzed by NMR in terms of a generalized order parameter, S2. Alternatively, SHAPE (selective 2'-hydroxyl acylation analyzed by primer extension) chemistry measures local nucleotide flexibility in RNAs of any size using structure-sensitive reagents that acylate the 2'-hydroxyl position. In this work, we compare per-residue RNA dynamics, analyzed by both S2 and SHAPE, for three RNAs: the HIV-1 TAR element, the U1A protein binding site, and the Tetrahymena telomerase stem loop 4. We find a very strong correlation between the two measurements: nucleotides with high SHAPE reactivities consistently have low S2 values. We conclude that SHAPE chemistry quantitatively reports local nucleotide dynamics and can be used with confidence to analyze dynamics in large RNAs, RNA-protein complexes, and RNAs in vivo.     

Sequence- and regioselectivity in the montmorillonite-catalyzed synthesis of RNA

The possible role of catalysis in forming a limited number of RNAs from activated monomers is investigated by examining the sequence- and regioselectivity in the montmorillonite-catalyzed formation of RNA dimers and trimers. The reactivity of A was similar to that of G, and C was comparable in reactivity to U. Yet the reactivity of the purine nucleotides differed from that of the pyrimidines. In the reaction of nucleotides (pN) with activated monomers (ImpN), the sequence- and regioselectivity was Pu(3')Py > Pu(3')Pu = Pu(2')Py > Pu(2')Pu. The 5'-pyrimidine initiated dimers formed less efficiently than the 5'-purine initiated dimers. Trimer formation was investigated by the synthesis of 8 dimers (pNpN) and measuring the yields of trimers formed in the reaction of each dimer with a mixture of equal molar amounts of four activated monomers. The reactivity of the dimers depended on the nucleotide attached to the 3'-end of the RNA and the regiochemistry of the phosphodiester bond. Rules based on these studies are proposed to predict the sequence- and regioselectivity of the RNAs formed in montmorillonite-catalyzed reactions. These rules are consistent with the structures of the 2-5-mers formed in the reaction of equimolar amounts of ImpA and ImpC. This research establishes that the montmorillonite catalyst limits the number of RNA oligomer isomers formed. The potential significance of these findings to the origins of life is discussed.     

The size of RNA as an ideal branched polymer

Because of the branching arising from partial self-complementarity, long single-stranded (ss) RNA molecules are significantly more compact than linear arrangements (e.g., denatured states) of the same sequence of monomers. To elucidate the dependence of compactness on the nature and extent of branching, we represent ssRNA secondary structures as tree graphs which we treat as ideal branched polymers, and use a theorem of Kramers for evaluating their root-mean-square radius of gyration, ?R(g)=√R(g)(2). We consider two sets of sequences--random and viral--with nucleotide sequence lengths (N) ranging from 100 to 10,000. The RNAs of icosahedral viruses are shown to be more compact (i.e., to have smaller ?R(g)) than the random RNAs. For the random sequences we find that ?R(g) varies as N(1/3). These results are contrasted with the scaling of ?R(g) for ideal randomly branched polymers (N(1/4)), and with that from recent modeling of (relatively short, N ≤ 161) RNA tertiary structures (N(2/5)).     

Repurposing Antiviral Drugs for Orthogonal RNA‐Catalyzed Labeling of RNA

In vitro selected ribozymes are promising tools for site‐specific labeling of RNA. Previously known nucleic acid catalysts attached fluorescently labeled adenosine or guanosine derivatives through 2′,5′‐branched phosphodiester bonds to the RNA of interest. Herein, we report new ribozymes that use orthogonal substrates, derived from the antiviral drug tenofovir, and attach bioorthogonal functional groups, as well as affinity handles and fluorescent reporter units through a hydrolytically more stable phosphonate ester linkage. The tenofovir transferase ribozymes were identified by in vitro selection and are orthogonal to nucleotide transferase ribozymes. As genetically encodable functional RNAs, these ribozymes may be developed for potential cellular applications. The orthogonal ribozymes addressed desired target sites in large RNAs in vitro, as shown by fluorescent labeling of E. coli 16S and 23S rRNAs in total cellular RNA.     

Fingerprinting Noncanonical and Tertiary RNA Structures by Differential SHAPE Reactivity

Many RNA structures are composed of simple secondary structure elements linked by a few critical tertiary interactions. SHAPE chemistry has made interrogation of RNA dynamics at single-nucleotide resolution straightforward. However, de novo identification of nucleotides involved in tertiary interactions remains a challenge. Here we show that nucleotides that form noncanonical or tertiary contacts can be detected by comparing information obtained using two SHAPE reagents, N-methylisatoic anhydride (NMIA) and 1-methyl-6-nitroisatoic anhydride (1M6). Nucleotides that react preferentially with NMIA exhibit slow local nucleotide dynamics and usually adopt the less common C2'-endo ribose conformation. Experiments and first-principles calculations show that 1M6 reacts preferentially with nucleotides in which one face of the nucleobase allows an unhindered stacking interaction with the reagent. Differential SHAPE reactivities were used to detect noncanonical and tertiary interactions in four RNAs with diverse structures and to identify preformed noncanonical interactions in partially folded RNAs. Differential SHAPE reactivity analysis will enable experimentally concise, large-scale identification of tertiary structure elements and ligand binding sites in complex RNAs and in diverse biological environments.     

The mechanisms of RNA SHAPE chemistry

The biological functions of RNA are ultimately governed by the local environment at each nucleotide. Selective 2'-hydroxyl acylation analyzed by primer extension (SHAPE) chemistry is a powerful approach for measuring nucleotide structure and dynamics in diverse biological environments. SHAPE reagents acylate the 2'-hydroxyl group at flexible nucleotides because unconstrained nucleotides preferentially sample rare conformations that enhance the nucleophilicity of the 2'-hydroxyl. The critical corollary is that some constrained nucleotides must be poised for efficient reaction at the 2'-hydroxyl group. To identify such nucleotides, we performed SHAPE on intact crystals of the Escherichia coli ribosome, monitored the reactivity of 1490 nucleotides in 16S rRNA, and examined those nucleotides that were hyper-reactive toward SHAPE and had well-defined crystallographic conformations. Analysis of these conformations revealed that 2'-hydroxyl reactivity is broadly facilitated by general base catalysis involving multiple RNA functional groups and by two specific orientations of the bridging 3'-phosphate group. Nucleotide analog studies confirmed the contributions of these mechanisms to SHAPE reactivity. These results provide a strong mechanistic explanation for the relationship between SHAPE reactivity and local RNA dynamics and will facilitate interpretation of SHAPE information in the many technologies that make use of this chemistry.     

Slow conformational dynamics at C2'-endo nucleotides in RNA

RNA molecules undergo local conformational dynamics on timescales spanning picoseconds to minutes. Slower local motions have the greater potential to govern RNA folding, ligand recognition, and ribonucleoprotein assembly reactions but are difficult to detect in large RNAs with complex structures. RNA SHAPE chemistry employs acylation of the ribose 2'-hydroxyl position to measure local nucleotide flexibility in RNA and is well-characterized by a mechanism in which each nucleotide samples unreactive (closed) and reactive (open) states. We monitor RNA conformational dynamics over distinct time domains by varying the electrophilicity of the acylating reagent. Select C2'-endo nucleotides are nonreactive toward fast reagents but reactive toward slower SHAPE reagents in both model RNAs and in a large RNA with a tertiary fold. We conclude, first, that the C2'-endo conformation by itself does not govern SHAPE reactivity. However, some C2'-endo nucleotides undergo extraordinarily slow conformational changes, on the order of 10(-4) s(-1). Due to their distinctive local dynamics, C2'-endo nucleotides have the potential to function as rate-determining molecular switches and are likely to play central, currently unexplored, roles in RNA folding and function.     

Separation of transfer RNA and 5S ribosomal RNA using capillary electrophoresis

Capillary gel electrophoresis and capillary electrophoresis using entangled polymer solutions was investigated for their applicability for the separation of low-molecular-mass RNAs (transfer RNA and 5S ribosomal RNA), with a size range of 70–135 nucleotides, from bacteria. Cross-linked polyacrylamide gel-filled capillaries (3 and 5%) were used for capillary gel electrophoresis. Good resolution was obtained suing gel-filled capillaries only for small tRNAs with lengths to 79 nucleotides, larger tRNAs and 5S rRNA could not be resolved using this method. Buffers containing sieving additives were employed to improve separations of RNA by capillary electrophoresis using entangled polymer solutions. The use of linear sieving polymers in buffers resolved 5S rRNA and tRNAs, even when they possessed only different secondary structure or small differences in length (1–5 nucleotides).     

Locked nucleic acid (LNA) recognition of RNA: NMR solution structures of LNA:RNA hybrids

Locked nucleic acids (LNAs) containing one or more 2'-O,4'-C-methylene-linked bicyclic ribonucleoside monomers possess a number of the prerequisites of an effective antisense oligonucleotide, e.g. unprecedented helical thermostability when hybridized with cognate RNA and DNA. To acquire a detailed understanding of the structural features of LNA giving rise to its remarkable properties, we have conducted structural studies by use of NMR spectroscopy and now report high-resolution structures of two LNA:RNA hybrids, the LNA strands being d(5'-CTGAT(L)ATGC-3') and d(5'-CT(L)GAT(L)AT(L)GC-3'), respectively, T(L) denoting a modified LNA monomer with a thymine base, along with the unmodified DNA:RNA hybrid. In the structures, the LNA nucleotides are positioned as to partake in base stacking and Watson-Crick base pairing, and with the inclusion of LNA nucleotides, we observe a progressive change in duplex geometry toward an A-like duplex structure. As such, with the inclusion of three LNA nucleotides, the hybrid adopts an almost canonical A-type duplex geometry, and thus it appears that the number of modifications has reached a saturation level with respect to structural changes, and that further incorporations would furnish only minute changes in the duplex structure. We attempt to rationalize the conformational steering induced by the LNA nucleotides by suggesting that the change in electronic density at the brim of the minor groove, introduced by the LNA modification, is causing an alteration of the pseudorotational profile of the 3'-flanking nucleotide, thus shifting this sugar equilibrium toward N-type conformation.     

Branched RNA nanostructures for RNA interference

Branched RNAs with three- or four-way junctions were designed by assembling single-stranded RNA for RNA interference. Human Dicer transformed branched RNAs into about 20 base pairs of double-stranded RNA, which is a standard siRNA species. Our tetramer design provides a potent silencing effect over a period of 5 days.     

RNA-catalyzed RNA ligation on an external RNA template

Variants of the hc ligase ribozyme, which catalyzes ligation of the 3' end of an RNA substrate to the 5' end of the ribozyme, were utilized to evolve a ribozyme that catalyzes ligation reactions on an external RNA template. The evolved ribozyme catalyzes the joining of an oligonucleotide 3'-hydroxyl to the 5'-triphosphate of an RNA hairpin molecule. The ribozyme can also utilize various substrate sequences, demonstrating a largely sequence-independent mechanism for substrate recognition. The ribozyme also carries out the ligation of two oligonucleotides that are bound at adjacent positions on a complementary template. Finally, it catalyzes addition of mononucleoside 5'-triphosphates onto the 3' end of an oligonucleotide primer in a template-dependent manner. The development of ribozymes that catalyze polymerase-type reactions contributes to the notion that an RNA world could have existed during the early history of life on Earth.     

General deoxyribozyme-catalyzed synthesis of native 3'-5' RNA linkages

An elusive goal for nucleic acid enzymology has been deoxyribozymes that ligate RNA rapidly, sequence-generally, with formation of native 3'-5' linkages, and in preparatively useful yield. Using in vitro selection, we have identified Mg2+- and Zn2+-dependent deoxyribozymes that simultaneously fulfill all four of these criteria. The new deoxyribozymes operate under practical incubation conditions and have modest RNA substrate sequence requirements, specifically D downward arrowRA for 9DB1 and A downward arrowR for 7DE5 (D = A, G, or U; R = A or G). These requirements are comparable to those of deoxyribozymes such as 10-23 and 8-17, which are already widely used as biochemical tools for RNA cleavage. We anticipate that the 9DB1 and 7DE5 deoxyribozymes will find immediate practical application for RNA ligation.     

In vitro selection of a novel nuclease-resistant RNA phosphodiesterase

BACKGROUND: Ribonucleotide-based enzymes (ribozymes) that cleave pathological RNAs are being developed as therapeutic agents. Chemical modification of the hammerhead ribozyme has produced nuclease-resistant catalysts that cleave targeted mRNAs in cell culture and exhibit antitumor activity in animals. Unfortunately, stabilizing modifications usually reduce the catalytic rate in vitro. An alternative to rationally designed chemical modifications of existing ribozymes is to identify novel motifs through in vitro selection of nuclease-stable sequence space. This approach is desirable because the catalysts can be optimized to function under simulated physiological conditions. RESULTS: Utilizing in vitro selection, we have identified a nuclease-stable phosphodiesterase that demonstrated optimal activity at simulated physiological conditions. The initial library of 10(14) unique molecules contained 40 randomized nucleotides with all pyrimidines in a nuclease-stabilized 2'-deoxy-2'-amino format. The selection required trans-cleaving activity and base-pairing specificity towards a resin-bound RNA substrate. Initial selective pressure was permissive, with a 30 min reaction time and 25 mM Mg(2+). Stringency of selection pressure was gradually increased until final conditions of 1 mM Mg(2+) and less than 1 min reaction times were achieved. The resulting 61-mer catalyst required the 2'-amino substitutions at selected pyrimidine positions and was stable in human serum (half-life of 16 h). CONCLUSIONS: We demonstrated that it is possible to identify completely novel, nuclease-resistant ribozymes capable of trans-cleaving target RNAs at physiologically relevant Mg(2+) concentrations. The new ribozyme motif has minimal substrate requirements, allowing for a wide range of potential RNA targets.     

Chemical synthesis of an artificially branched hairpin ribozyme variant with RNA cleavage activity

Due to the development in the field of RNA synthesis over the past decade of years, preparation of RNA oligonucleotides longer than 50 nucleotides is possible today. In this report, we describe the chemical preparation of a branched RNA molecule with RNA cleavage activity consisting of 81 nucleotides. It is derived from the hairpin ribozyme, a small catalytic RNA occurring in nature. The hairpin ribozyme consists of two separately folded domains (loop A and loop B domain), which can be joined in a number of different ways without loss of activity. In the construct presented here, 2′-deoxy-N4-(6-hydroxyhexyl)-5-methylcytidine was introduced to connect the loop B domain with the loop A domain via an artificial branch. The synthesized branched RNA is able to catalyze the cleavage of a number of suitable substrates. Compared with the corresponding non-branched reverse-joined ribozyme it cleaves its substrates only 5-fold slower. Surprisingly, no ligation activity could be detected.