The intricate world of riboswitches.

Riboswitches are segments of the 5'-untranslated region of certain bacterial mRNAs that upon recognition of specific ligands modify the expression of a protein(s) encoded in the message. These proteins are responsible for the biosynthesis or transport of ligands, which are typically organic molecules but could also be metal ions. Riboswitch-mediated control of gene expression might be thermodynamic or kinetic, depending on the rate of transcription elongation by RNA polymerase and the structures adopted by the riboswitch RNA. Certain 5'-untranslated regions harbor two riboswitches in tandem that bind to different ligands. Thus, RNA sensors can respond to metabolic changes by modifying gene expression in ways previously thought to be exclusive of proteins.

Mimicking the first step of RNA splicing: an artificial DNA enzyme can synthesize branched RNA using an oligonucleotide leaving group as a 5'-exon analogue.

The 7S11 deoxyribozyme synthesizes 2',5'-branched RNA by mediating the nucleophilic attack of an internal 2'-hydroxyl group of one RNA substrate into the 5'-triphosphate of a second RNA substrate, with pyrophosphate as the leaving group. Here we comprehensively examined the role of the leaving group in the 7S11-catalyzed reaction by altering the 5'-phosphorylation state and the length of the second RNA substrate. When the leaving group is the less stabilized phosphate or hydroxide anion as provided by a 5'-diphosphate or 5'-monophosphate, the same 2',5'-branched product is formed as when pyrophosphate is the leaving group, but with an approximately 50- or approximately 1000-fold lower rate (Brønsted beta(LG) = -0.40). When the 5'-end of the RNA substrate that bears the leaving group is longer by one or more nucleotides, either the new 5'-terminal alpha-phosphate or the original alpha-phosphate can be attacked by the branch-site 2'-hydroxyl group; in the latter case, the leaving group is an oligonucleotide. The choice between these alpha-phosphate reaction sites is determined by the subtle balance between the length of the single-stranded 5'-extension and the stability of the leaving group. Because the branch-site adenosine is a bulged nucleotide flanked by Watson-Crick duplex regions, we earlier concluded that 7S11 structurally mimics the first step of natural RNA splicing. The observation of 7S11-catalyzed branch formation with an oligonucleotide leaving group strengthens this resemblance to natural RNA splicing, with the oligonucleotide playing the role of the 5'-exon in the first step. These findings reinforce the notion that splicing-related catalysis can be achieved by artificial nucleic acid enzymes that are much smaller than the spliceosome and group II introns.

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.

A deoxyribozyme that forms a three-helix-junction complex with its RNA substrates and has general RNA branch-forming activity.

We recently used in vitro selection to identify 7S11, a deoxyribozyme that synthesizes 2',5'-branched RNA. The 7S11 DNA enzyme mediates the nucleophilic attack of an adenosine 2'-hydroxyl group at a 5'-triphosphate, forming 2',5'-branched RNA in a reaction that resembles the first step of in vivo RNA splicing. Here, we describe 7S11 characterization experiments that have two important implications for nucleic acid chemistry and biochemistry. First, on the basis of a comprehensive analysis of its substrate sequence requirements, 7S11 is shown to be generally applicable for the synthesis of a wide range of 2',5'-branched RNAs. Strict substrate sequence requirements are found at the two RNA nucleotides that directly form the branched linkage, and these requirements correspond to those nucleotides found most commonly at these two positions in natural spliced RNAs. Outside of these two nucleotides, most substrate sequences are tolerated with useful ligation activity, although rates and yields vary. Because chemical synthesis approaches to branched RNA are extremely limited in scope, the deoxyribozyme-based route using 7S11 will enable many experiments that require branched RNA. Second, comprehensive nucleotide covariation experiments demonstrate that 7S11 and its RNA substrates adopt a three-helix-junction structure in which the branch-site nucleotide is located at the intersection of the three helices. Because many natural ribozymes have multi-helix junctions, 7S11 is an interesting model system for catalytic nucleic acids.

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.

A DNA enzyme that mimics the first step of RNA splicing.

We have discovered an artificial DNA enzyme that mimics the first step of RNA splicing. In vitro selection was used to identify DNA enzymes that ligate RNA. One of the new DNA enzymes carries out splicing-related catalysis by specifically recognizing an unpaired internal adenosine and facilitating attack of its 2'-hydroxyl onto a 5'-triphosphate. This reaction forms 2',5'-branched RNA and is analogous to the first step of in vivo RNA splicing, in which a ribozyme cleaves itself with formation of a branched intermediate. Unlike a natural ribozyme, the new DNA enzyme has no 2'-hydroxyl groups to aid in the catalytic mechanism. Our finding has two important implications. First, branch-site adenosine reactivity seems to be mechanistically favored by nucleic acid enzymes. Second, hydroxyl groups are not obligatory components of nucleic acid enzymes that carry out biologically related catalysis.

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.