Characterization of deoxyribozymes that synthesize branched RNA

We recently reported deoxyribozymes (DNA enzymes) that synthesize 2',5'-branched RNA. The in vitro-selected 9F7 and 9F21 deoxyribozymes mediate reaction of a branch-site adenosine 2'-hydroxyl on one RNA substrate with the 5'-triphosphate of another RNA substrate. Here we characterize these DNA enzymes with respect to their branch-forming activity. Both 9F7 and 9F21 are much more active with Mn(2+) than with Mg(2+). The K(d,app)(Mg(2+)) > 400 mM but K(d,app)(Mn(2+)) approximately 20-50 mM, and the ligation rates k(obs) are orders of magnitude faster with Mn(2+) than with Mg(2+) (e.g., 9F7 approximately 0.3 min(-1) with 20 mM Mn(2+) versus 0.4 h(-1) with 100 mM Mg(2+), both at pH 7.5 and 37 degrees C). Of the other tested transition metal ions Zn(2+), Ni(2+), Co(2+), and Cd(2+), only Co(2+) supports a trace amount of activity. 9F7 is more tolerant than 9F21 of varying the RNA substrate sequences. For the RNA substrate that donates the adenosine 2'-hydroxyl, 9F7 requires YUA, where Y = pyrimidine and A is the branch site. The 3'-tail emerging from the branch-site A may have indefinite length, but it must be at least one nucleotide long for high activity. The 5'-triphosphate RNA substrate requires several additional nucleotides with varying sequence requirements (5'-pppGRMWR). Outside of these regions that flank the ligation site, 9F7 and 9F21 tolerate any RNA substrate sequences via Watson-Crick covariation of the DNA binding arms that interact directly with the substrates. 9F7 provides a high yield of 2',5'-branched RNA on the preparative nanomole scale. The ligation reaction is effectively irreversible; the pyrophosphate leaving group in the ligation reaction does not induce 2',5'-cleavage, and pyrophosphate does not significantly inhibit ligation except in 1000-fold excess. Deleting a specific nucleotide in one of the DNA binding arms near the ligation junction enhances ligation activity, suggesting an interesting structure near this region of the deoxyribozyme-substrate complex. These data support the utility of deoxyribozymes in creating synthetic 2',5'-branched RNAs for investigations of group II intron splicing, debranching enzyme (Dbr) activity, and other biochemical reactions.     

Adenosine is inherently favored as the branch-site RNA nucleotide in a structural context that resembles natural RNA splicing

We previously used in vitro selection to identify the 7S11 deoxyribozyme, which catalyzes formation of 2',5'-branched RNA using a branch-site adenosine nucleophile and a 5'-triphosphate electrophile. An unanswered question is whether the use of branch-site adenosine is inherently preferred or a chance event during the particular selection experiment. Here we have found that deoxyribozymes newly selected to use uridine as the branch-site RNA nucleotide in a structural context that resembles natural RNA splicing instead prefer a branch-site adenosine, although adenosine was never available during the selection itself. Our results support a chemical basis for nature's choice of the branch-site nucleotide, which is almost always adenosine in group II introns and the spliceosome.     

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.     

Directing the outcome of deoxyribozyme selections to favor native 3'-5' RNA ligation

Previous experiments have identified numerous RNA ligase deoxyribozymes, each of which can synthesize either 2',5'-branched RNA, linear 2'-5'-linked RNA, or linear 3'-5'-linked RNA. These products may be formed by reaction of a 2'-hydroxyl or 3'-hydroxyl of one RNA substrate with the 5'-triphosphate of a second RNA substrate. Here the inherent propensities for nucleophilic reactivity of specific hydroxyl groups were assessed using RNA substrates related to the natural sequences of spliceosome substrates and group II introns. With the spliceosome substrates, nearly half of the selected deoxyribozymes mediate a ligation reaction involving the natural branch-point adenosine as the nucleophile. In contrast, mostly linear RNA is obtained with the group II intron substrates. Because the two sets of substrates differ at only three nucleotides, we conclude that the location of the newly created ligation junction in DNA-catalyzed branch formation depends sensitively on the RNA substrate sequences. During the experiment that led primarily to branched RNA, we abruptly altered the selection strategy to demand that the deoxyribozymes create linear 3'-5' linkages by introducing an additional selection step involving the 3'-5'-selective 8-17 deoxyribozyme. Although no 3'-5' linkages (相似文献   

A deoxyribozyme that synthesizes 2',5'-branched RNA with any branch-site nucleotide

RNA molecules with internal 2′,5′-branches are intermediates in RNA splicing, and branched RNAs have recently been proposed as retrotransposition intermediates. A broadly applicable in vitro synthetic route to branched RNA that does not require self-splicing introns or spliceosomes would substantially improve our ability to study biochemical processes that involve branched RNA. We recently described 7S11, a deoxyribozyme that was identified by in vitro selection and has general RNA branch-forming ability. However, an important restriction for 7S11 is that the branch-site RNA nucleotide must be a purine (A or G), because a pyrimidine (U or C) is not tolerated. Here, we describe the compact 6CE8 deoxyribozyme (selected using a 20 nt random region) that synthesizes 2′,5′-branched RNA with any nucleotide at the branch site. The Mn²⁺-dependent branch-forming ligation reaction is between an internal branch-site 2′-hydroxyl nucleophile on one RNA substrate with a 5′-triphosphate on another RNA substrate. The preference for the branch-site nucleotide is U > C A > G, although all four nucleotides are tolerated with useful ligation rates. Nearly all other nucleotides elsewhere in both RNA substrates allow ligation activity, except that the sequence requirement for the RNA strand with the 5′-triphosphate is 5′-pppGA, with 5′-pppGAR (R = purine) preferred. These characteristics permit 6CE8 to prepare branched RNAs of immediate practical interest, such as the proposed branched intermediate of Ty1 retrotransposition. Because this branched RNA has two strands with identical sequence that emerge from the branch site, we developed strategies to control which of the two strands bind with the deoxyribozyme during the branch-forming reaction. The ability to synthesize the proposed branched RNA of Ty1 retrotransposition will allow us to explore this important biochemical pathway in greater detail.     

Purification of a RNA debranching activity from HeLa cells

The splicing of messenger RNA precursors (pre-mRNA) of eukaryotic cells involves the formation of a branched RNA intermediate known as a RNA lariat. This structure is formed in the first step of the reaction when a cleavage at the 5' splice site generates the 5' exon and a RNA species containing the intron and 3' exon in which the phosphate moiety at the 5' end of the intron is forming a 2'-5' phosphodiester bond with the 2'-hydroxyl moiety of a specific adenine residue near the 3' end of the intron forming a RNA branch with the following structure: -pA2'-pX-3'-pZ-. We have purified a debranching activity approximately 700-fold from the cytosolic fraction of HeLa cells. This activity catalyzes the hydrolysis of the 2'-5' phosphodiester bond of branched RNA structures yielding a 5'-phosphate end and a 2'-hydroxyl group at the branch attachment site. The activity possessed a sedimentation coefficient of 3.5 S. The reaction catalyzed by the purified fraction requires a divalent cation and is optimal at pH 7.0. The purified activity can efficiently hydrolyze triester trinucleotide structures (pY2'-pX-3'-pZ-) prepared by digestion of RNA lariats with nuclease P1. In contrast, a 2' phosphate monoester product (-pG2'-p 3'-pC-), formed by the wheat germ RNA ligase, was not attacked.     

A ribozyme selected from variants of U6 snRNA promotes 2',5'-branch formation

In vitro selection was used to sample SnRNA-related sequences for ribozyme activities, and several 2',5'-branch-forming ribozymes were isolated. One such ribozyme is highly dependent upon an 11-nt motif that contains a conserved U6 snRNA sequence (ACAGAGA-box) known to be important for pre-mRNA splicing. The ribozyme reaction is similar to the first step of splicing in that an internal 2'-hydroxyl of an unpaired adenosine attacks at the 5'-phosphate of a guanosine. It differs in that the leaving group is diphosphate rather than a 5' exon. The finding that lariat formation can be accomplished by a small RNA with sequences related to U6 snRNA indicates that the RNA available in the spliceosome may be involved in RNA-catalyzed branch formation.     

Purification of wheat germ RNA ligase. I. Characterization of a ligase-associated 5'-hydroxyl polynucleotide kinase activity

An RNA ligase that catalyzes the formation of a 2'-phosphomonoester-3',5'-phosphodiester bond in the presence of ATP and Mg2+ was purified approximately 6000-fold from raw wheat germ. A 5'-hydroxyl polynucleotide kinase activity copurified with RNA ligase through all chromatographic steps. Both activities cosedimented upon glycerol gradient centrifugation even in the presence of high salt and urea. RNA ligase and kinase activities sedimented as a single peak on glycerol gradients with a sedimentation coefficient of 6.2 S. The purified polynucleotide kinase activity required dithiothreitol and a divalent cation for activity and was inhibited by pyrophosphate and by ADP. The kinase phosphorylated a variety of 5'-hydroxyl-terminated polynucleotide chains including some that were substrates for the RNA ligase (e.g. 2',3'-cyclic phosphate-terminated poly(A)) and others that were not ligase substrates (e.g. DNA or RNA containing 3'-hydroxyl termini). RNA molecules containing either 5'-hydroxyl or 5'-phosphate and 2',3'-cyclic or 2'-phosphate termini were substrates for the purified RNA ligase activity. The rate of ligation of 5'-hydroxyl-terminated RNA chains was greater than that of 5'-phosphate-terminated molecules, suggesting that an interaction between the wheat germ kinase and ligase activities occurs during the course of ligation.     

Selective 2'-hydroxyl acylation analyzed by protection from exoribonuclease (RNase-detected SHAPE) for direct analysis of covalent adducts and of nucleotide flexibility in RNA

RNA SHAPE chemistry yields quantitative, single-nucleotide resolution structural information based on the reaction of the 2'-hydroxyl group of conformationally flexible nucleotides with electrophilic SHAPE reagents. However, SHAPE technology has been limited by the requirement that sites of RNA modification be detected by primer extension. Primer extension results in loss of information at both the 5' and 3' ends of an RNA and requires multiple experimental steps. Here we describe RNase-detected SHAPE that uses a processive, 3'→5' exoribonuclease, RNase R, to detect covalent adducts in 5'-end-labeled RNA in a one-tube experiment. RNase R degrades RNA but stops quantitatively three and four nucleotides 3' of a nucleotide containing a covalent adduct at the ribose 2'-hydroxyl or the pairing face of a nucleobase, respectively. We illustrate this technology by characterizing ligand-induced folding for the aptamer domain of the Escherichia coli thiamine pyrophosphate riboswitch RNA. RNase-detected SHAPE is a facile, two-day approach that can be used to analyze diverse covalent adducts in any RNA molecule, including short RNAs not amenable to analysis by primer extension and RNAs with functionally important structures at their 5' or 3' ends.     

The enzymatic conversion of 3'-phosphate terminated RNA chains to 2',3'-cyclic phosphate derivatives

The enzyme, RNA cyclase, has been purified from cell-free extracts of HeLa cells approximately 6000-fold. The enzyme catalyzes the conversion of 3'-phosphate ends of RNA chains to the 2',3'-cyclic phosphate derivative in the presence of ATP or adenosine 5'-(gamma-thio)triphosphate (ATP gamma S) and Mg2+. The formation of 1 mol of 2',3'-cyclic phosphate ends is associated with the disappearance of 1 mol of 3'-phosphate termini and the hydrolysis of 1 mol of ATP gamma S to AMP and thiopyrophosphate. No other nucleotides could substitute for ATP or ATP gamma S in the reaction. The reaction catalyzed by RNA cyclase was not reversible and exchange reactions between [32P]pyrophosphate and ATP were not detected. However, an enzyme-AMP intermediate could be identified that was hydrolyzed by the addition of inorganic pyrophosphate or 3'-phosphate terminated RNA chains but not by 3'-OH terminated chains or inorganic phosphate. 3'-[32P](Up)10Gp* could be converted to a form that yielded, (Formula: see text) after degradation with nuclease P1, by the addition of wheat germ RNA ligase, 5'-hydroxylpolynucleotide kinase, RNA cyclase, and ATP. This indicates that the RNA cyclase had catalyzed the formation of the 2',3'-cyclic phosphate derivative, the kinase had phosphorylated the 5'-hydroxyl end of the RNA, and the wheat germ RNA ligase had catalyzed the formation of a 3',5'-phosphodiester linkage concomitant with the conversion of the 2',3'-cyclic end to a 2'-phosphate terminated residue.     

Zn2+-dependent deoxyribozymes that form natural and unnatural RNA linkages

We report Zn(2+)-dependent deoxyribozymes that ligate RNA. The DNA enzymes were identified by in vitro selection and ligate RNA with k(obs) up to 0.5 min(-)(1) at 1 mM Zn(2+) and 23 degrees C, pH 7.9, which is substantially faster than our previously reported Mg(2+)-dependent deoxyribozymes. Each new Zn(2+)-dependent deoxyribozyme mediates the reaction of a specific nucleophile on one RNA substrate with a 2',3'-cyclic phosphate on a second RNA substrate. Some of the Zn(2+)-dependent deoxyribozymes create native 3'-5' RNA linkages (with k(obs) up to 0.02 min(-)(1)), whereas all of our previous Mg(2+)-dependent deoxyribozymes that use a 2',3'-cyclic phosphate create non-native 2'-5' RNA linkages. On this basis, Zn(2+)-dependent deoxyribozymes have promise for synthesis of native 3'-5'-linked RNA using 2',3'-cyclic phosphate RNA substrates, although these particular Zn(2+)-dependent deoxyribozymes are likely not useful for this practical application. Some of the new Zn(2+)-dependent deoxyribozymes instead create non-native 2'-5' linkages, just like their Mg(2+) counterparts. Unexpectedly, other Zn(2+)-dependent deoxyribozymes synthesize one of three unnatural linkages that are formed upon the reaction of an RNA nucleophile other than a 5'-hydroxyl group. Two of these unnatural linkages are the 3'-2' and 2'-2' linear junctions created when the 2'-hydroxyl of the 5'-terminal guanosine of one RNA substrate attacks the 2',3'-cyclic phosphate of the second RNA substrate. The third unnatural linkage is a branched RNA that results from attack of a specific internal 2'-hydroxyl of one RNA substrate at the 2',3'-cyclic phosphate. When compared with the consistent creation of 2'-5' linkages by Mg(2+)-dependent ligation, formation of this variety of RNA ligation products by Zn(2+)-dependent deoxyribozymes highlights the versatility of transition metals such as Zn(2+) for mediating nucleic acid catalysis.     

Ribozyme inhibitors: deoxyguanosine and dideoxyguanosine are competitive inhibitors of self-splicing of the Tetrahymena ribosomal ribonucleic acid precursor

The intervening sequence (IVS) of the Tetrahymena rRNA precursor catalyzes its own splicing. During splicing the 3'-hydroxyl of guanosine is ligated to the 5' terminus of the IVS. One catalytic strategy of the IVS RNA is to specifically bind its guanosine substrate. Deoxyguanosine (dG) and dideoxyguanosine (ddG) are found to be competitive inhibitors of self-splicing. Comparison of the kinetic parameters (Ki = 1.1 mM for dG; Ki = 5.4 mM for ddG; Km = 0.032 mM for guanosine) indicates that the ribose hydroxyls are necessary for optimal binding of guanosine to the RNA. dG is not a substrate for the reaction even at very high concentrations. Thus, in addition to aiding in binding, the 2'-hydroxyl is necessary for reaction of the 3'-hydroxyl. A second catalytic strategy of the IVS RNA is to enhance the reactivity of specific bonds. For example, the phosphodiester bond at the 3' splice site is extremely labile to hydrolysis. We find that dG and ddG, as well as 2'-O-methylguanosine and 3'-O-methylguanosine, reduce hydrolysis at the 3' splice site. These data are consistent with an RNA structure that brings the 5' and 3' splice sites proximal to the guanosine binding site.     

tRNA ligase catalyzes the GTP-dependent ligation of RNA with 3'-phosphate and 5'-hydroxyl termini

The RNA ligase RtcB is conserved in all domains of life and is essential for tRNA maturation in archaea and metazoa. Here we show that bacterial and archaeal RtcB catalyze the GTP-dependent ligation of RNA with 3'-phosphate and 5'-hydroxyl termini. Reactions with analogues of RNA and GTP suggest a mechanism in which RtcB heals the 3'-phosphate terminus by forming a 2',3'-cyclic phosphate before joining it to the 5'-hydroxyl group of a second RNA strand. Thus, RtcB can ligate RNA cleaved by RNA endonucleases, which generate 2',3'-cyclic phosphate and then 3'-phosphate termini on one strand, and a 5'-hydroxyl terminus on another strand.     

Structural insights into mechanisms of catalysis and inhibition in Norwalk virus polymerase

Crystal structures of Norwalk virus polymerase bound to an RNA primer-template duplex and either the natural substrate CTP or the inhibitor 5-nitrocytidine triphosphate have been determined to 1.8A resolution. These structures reveal a closed conformation of the polymerase that differs significantly from previously determined open structures of calicivirus and picornavirus polymerases. These closed complexes are trapped immediately prior to the nucleotidyl transfer reaction, with the triphosphate group of the nucleotide bound to two manganese ions at the active site, poised for reaction to the 3'-hydroxyl group of the RNA primer. The positioning of the 5-nitrocytidine triphosphate nitro group between the alpha-phosphate and the 3'-hydroxyl group of the primer suggests a novel, general approach for the design of antiviral compounds mimicking natural nucleosides and nucleotides.     

Donor activation in the T4 RNA ligase reaction

T4 RNA ligase catalyzes the adenylation of donor oligonucleotide substrates. These activated intermediates react with an acceptor oligonucleotide which results in phosphodiester bond formation and the concomitant release of AMP. Adenylation of the four common nucleoside 3',5'-bisphosphates as catalyzed by T4 RNA ligase in the absence of an acceptor oligonucleotide has been examined. The extents of product formation indicate that pCp is the best substrate in the reaction and pGp is the poorest. Kinetic parameters for the joining reaction between the preadenylated nucleoside 3',5'-bisphosphates, A(5')pp(5')Cp or A(5')pp(5')Gp, and a good acceptor substrate (ApApA) or a poor acceptor substrate (UpUpU) have been determined. The apparent Km values for both preadenylated donors in the joining reaction are similar, and the reaction velocity is much faster than observed in the overall joining reaction. The nonnucleotide adenylated substrate P1-(5'-adenosyl) P2-(o-nitrobenzyl) diphosphate also exhibits a similar apparent Km but reacts with a velocity 80-fold slower than the adenylated nucleoside 3',5'-bisphosphates. By use of preadenylated donors, oligonucleotide substrates can be elongated more efficiently than occurs with the nucleoside 3',5'-bisphosphates.     

The receptor for branch-site docking within a group II intron active site

The distinguishing feature of group II introns, and the property that links them with spliceosomal catalysis, is their ability to undergo splicing through branching. In this reaction, the 2'-hydroxyl group of a specific adenosine within intron domain 6 serves as the nucleophile for attack on the 5' splice site. We know less about branching than any other feature of group II intron catalysis, largely because the receptor structure for activating the branch site is unknown. Here, we identify the intronic region that binds the branch site of a group IIB intron. Located in domain 1, close to receptors for intron domain 5 and both splice sites, we demonstrate that the branch-site receptor is a functional element required for transesterification. Furthermore, we show that crosslinked branch sites can carry out both steps of splicing, suggesting that the conformational state of the intron core is set early and that it persists throughout the entire splicing process.     

Chemical synthesis of the 5'-terminal part bearing cap structure of messenger RNA of cytoplasmic polyhedrosis virus (CPV): m7G5'pppAmpG and m7G5'pppAmpGpU.

The 5'-terminal structures of mRNA bearing the so-called 'cap' from cytoplasmic polyhedrosis virus (CPV), m7G5' pppAmpG and m7G5' pppAmpGpU, were first chemically synthesized. S,S-Di(4-methoxyphenyl) N6-benzoyl-2'-O-methyladenosine 5'-phosphorodithioate ((ArS) 2pAbmz) was prepared by phosphorylation of the 5'-hydroxyl group of N6-benzoyl-2'-O-methyladenosine with S,S-di(4-methoxyphenyl) phosphorodithioate by TPS. By the triester approach using (ArS) 2pAbmz as starting material, the protected dinucleotide and trinucleotide bearing 5'-phosphate group were synthesized. The protective groups of the dinucleotide and trinucleotide were removed to obtain pAmpG and pAmpGpU, respectively. By the reaction of a capping agent ((PhS) ppm7G) with pAmpG and pAmpGpU in the presence of silver nitrate or iodine. The 5'-terminal structure of the messenger RNA strand of CPV which was labelled isotopically, was confirmed completely as m7G5' pppAmGpU by cochromatography with the materials chemically synthesized here.     

Origin of the phosphate at the ligation junction produced by self-splicing of Tetrahymena thermophila pre-ribosomal RNA

The exons of the self-splicing pre-ribosomal RNA of Tetrahymena thermophila are joined accurately in vitro, even when only 33 nucleotides of the natural 5' exon and 38 nucleotides of the natural 3' exon remain. RNA fingerprint analysis was used to identify the unique ribonuclease T1 oligonucleotide generated by exon ligation. Secondary digests of the ligation junction oligonucleotide with ribonuclease A confirmed the identity of the fragment and demonstrated that the phosphate group that forms the phosphodiester bond at the ligation junction is derived from the 5' position of a uridine nucleotide in the RNA. This observation supports the prediction that the splice junction phosphate is derived from the 3' splice site. These results emphasize the mechanistic similarities of RNA splicing reactions of the group I introns, group II introns and nuclear pre-mRNA introns.     

Crystal structure of the 2'-5' RNA ligase from Thermus thermophilus HB8

The 2'-5' RNA ligase family members are bacterial and archaeal RNA ligases that ligate 5' and 3' half-tRNA molecules with 2',3'-cyclic phosphate and 5'-hydroxyl termini, respectively, to the product containing the 2'-5' phosphodiester linkage. Here, the crystal structure of the 2'-5' RNA ligase protein from an extreme thermophile, Thermus thermophilus HB8, was solved at 2.5A resolution. The structure of the 2'-5' RNA ligase superimposes well on that of the Arabidopsis thaliana cyclic phosphodiesterase (CPDase), which hydrolyzes ADP-ribose 1",2"-cyclic phosphate (a product of the tRNA splicing reaction) to the monoester ADP-ribose 1"-phosphate. Although the sequence identity between the two proteins is remarkably low (9.3%), the 2'-5' RNA ligase and CPDase structures have two HX(T/S)X motifs in their corresponding positions. The HX(T/S)X motifs play important roles in the CPDase activity, and are conserved in both the CPDases and 2'-5' RNA ligases. Therefore, the catalytic mechanism of the 2'-5' RNA ligase may be similar to that of the CPDase. On the other hand, the electrostatic potential of the cavity of the 2'-5' RNA ligase is positive, but that of the CPDase is negative. Furthermore, in the CPDase, two loops with low B-factors cover the cavity. In contrast, in the 2'-5' RNA ligase, the corresponding loops form an open conformation and are flexible. These characteristics may be due to the differences in the substrates, tRNA and ADP-ribose 1",2"-cyclic phosphate.