Catalysis of RNA cleavage by the Tetrahymena thermophila ribozyme. 2. Kinetic description of the reaction of an RNA substrate that forms a mismatch at the active site

The site-specific endonuclease reaction catalyzed by the ribozyme from the Tetrahymena pre-rRNA intervening sequence has been characterized with a substrate that forms a "matched" duplex with the 5' exon binding site of the ribozyme [G2CCCUCUA5 + G in equilibrium with G2CCCUCU + GA5 (G = guanosine); Herschlag, D., & Cech, T.R. (1990) Biochemistry (preceding paper in this issue)]. The rate-limiting step with saturating substrate is dissociation of the product G2CCCUCU. Here we show that the reaction of the substrate G2CCCGCUA5, which forms a "mismatched" duplex with the 5' exon binding site at position -3 from the cleavage site, has a value of kcat that is approximately 10(2)-fold greater than kcat for the matched substrate (50 degrees C, 10 mM MgCl2, pH 7). This is explained by the faster dissociation of the mismatched product, G2CCCGCU, than the matched product. With subsaturating oligonucleotide substrate and saturating G, the binding of the oligonucleotide substrate and the chemical step are each partially rate-limiting. The rate constant for the chemical step of the endonuclease reaction and the rate constant for the site-specific hydrolysis reaction, in which solvent replaces G, are each within approximately 2-fold with the matched and mismatched substrates, despite the approximately 10(3)-fold weaker binding of the mismatched substrate. This can be described as "uniform binding" of the base at position -3 in the ground state and transition state [Albery, W.J., & Knowles, J. R. (1976) Biochemistry 15, 5631-5640]. Thus, the matched substrate does not use its extra binding energy to preferentially stabilize the transition state.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of substrate RNA sequence on the cleavage reaction by a short ribozyme.

Leadzyme is a ribozyme that requires Pb2+. The catalytic sequence, CUGGGAGUCC, binds to an RNA substrate, GGACC downward arrowGAGCCAG, cleaving the RNA substrate at one site. We have investigated the effect of the substrate sequence on the cleavage activity of leadzyme using mutant substrates in order to structurally understand the RNA catalysis. The results showed that leadzyme acted as a catalyst for single site cleavage of a C5 deletion mutant substrate, GGAC downward arrowGAGCCAG, as well as the wild-type substrate. However, a mutant substrate GGACCGACCAG, which had G8 deleted from the wild-type substrate, was not cleaved. Kinetic studies by surface plasmon resonance indicated that the difference between active and inactive structures reflected the slow association and dissociation rate constants of complex formation induced by Pb2+rather than differences in complex stability. CD spectra showed that the active form of the substrate-leadzyme complex was rearranged by Pb2+binding. The G8 of the wild-type substrate, which was absent in the inactive complex, is not near the cleavage site. Thus, these results show that the active substrate-leadzyme complex has a Pb2+binding site at the junction between the unpaired region (asymmetric internal loop) and the stem region, which is distal to the cleavage site. Pb2+may play a role in rearranging the bases in the asymmetric internal loop to the correct position for catalysis.     

A pH controlled conformational switch in the cleavage site of the VS ribozyme substrate RNA

The VS ribozyme is a 154 nucleotide sequence found in certain natural strains of Neurospora. The RNA can be divided into a substrate and a catalytic domain. Here we present the solution structure of the substrate RNA that is cleaved in a trans reaction by the catalytic domain in the presence of Mg2+. The 30 nucleotide substrate RNA forms a compact helix capped by a flexible loop. The cleavage site bulge contains three non-canonical base-pairs, including an A+.C pair with a protonated adenine. This adenine (A622) is a pH controlled conformational switch that opens up the internal loop at higher pH. The possible significance of this switch for substrate recognition and cleavage is discussed.     

Structure of the ribozyme substrate hairpin of Neurospora VS RNA: a close look at the cleavage site

The cleavage site of the Neurospora VS RNA ribozyme is located in a separate hairpin domain containing a hexanucleotide internal loop with an A-C mismatch and two adjacent G-A mismatches. The solution structure of the internal loop and helix la of the ribozyme substrate hairpin has been determined by nuclear magnetic resonance (NMR) spectroscopy. The 2 nt in the internal loop, flanking the cleavage site, a guanine and adenine, are involved in two sheared G.A base pairs similar to the magnesium ion-binding site of the hammerhead ribozyme. Adjacent to the tandem G.A base pairs, the adenine and cytidine, which are important for cleavage, form a noncanonical wobble A+-C base pair. The dynamic properties of the internal loop and details of the high-resolution structure support the view that the hairpin structure represents a ground state, which has to undergo a conformational change prior to cleavage. Results of chemical modification and mutagenesis data of the Neurospora VS RNA ribozyme can be explained in context with the present three-dimensional structure.     

Hammerhead ribozyme mechanism: a ribonucleotide 5' to the substrate cleavage site is not essential.

Three hammerhead ribozymes with triplet specificities for cleavage 3' of CUC, GUC, and GUA have been evaluated for their sensitivity to the substitution of thymidine or 2'-deoxyuridine at central nucleotide position 16.1 in the substrate triplet. All three ribozymes cleaved their respective substrates, containing uridine or the modifications, with comparable rates. This indicates that the 2'-hydroxy group at position 16.1 is not essential for activity even though X-ray structure analysis shows it participates in H-bonding interactions. These H-bonds were considered to be of functional significance because an earlier report had provided data that thymidine at position 16.1 is deleterious for catalytic activity [Yang, J.-H., Perreault, J.-P., Labuda, D., Usman, N., and Cedergren, R. (1990) Biochemistry 29, 11156-11160].     

Nucleotides -1 to -4 of hepatitis delta ribozyme substrate increase the specificity of ribozyme cleavage

In the past, the use of delta ribozyme as a therapeutic tool was limited because substrate specificity was thought to be determined by only 8 nucleotides. Recently, we have accumulated evidence suggesting that the substrate sequence upstream of the cleavage site, which is not involved in the binding with the delta ribozyme, appears to be essential in the selection of an appropriate cleavage site. To understand the role of this region in efficient cleavage, we synthesized a collection of small substrates that possessed single and multiple mutations in positions -1 to -4 and determined the kinetic parameters of their cleavage using a model antigenomic delta ribozyme. Some substrates were found to be uncleavage, whereas others showed >60-fold difference in relative specificity between the least and most efficiently cleaved substrates. The base at each position from -1 to -4 contributes differently to the ability of a substrate to be cleaved. An optimal sequence for positions -1 to -4 was determined to be -1HRHY(-4) (H = U, C, or A). These results shed light on new features that contribute to the substrate requirement of delta ribozyme cleavage and should increase interest in the use of this unique ribozyme.     

Kinetic pathway for folding of the Tetrahymena ribozyme revealed by three UV-inducible crosslinks.

The kinetics of RNA folding were examined in the L-21 ribozyme, an RNA enzyme derived from the self-splicing Tetrahymena intron. Three UV-inducible crosslinks were mapped, characterized, and used as indicators for the folded state of the ribozyme. Together these data suggest that final structures are adopted first by the P4-P6 independently folding domain and only later in a region that positions the P1 helix (including the 5' splice site), a region whose folding is linked to that of a portion of the catalytic core. At intermediate times, a non-native structure forms in the region of the triple helical scaffold, which connects the major folding domains. At 30 degrees C, the unfolded ribozyme passes through these stages with a half-life of 2 min from the time magnesium cations are provided. At higher temperatures, the half-life is shortened but the order of events is unchanged. Thermal melting of the fully folded ribozyme also revealed a multi-stage process in which the steps of folding are reversed: the kinetically slowest structure is the least stable and melts first. These structures of the ribozyme also bind Mg2+ cooperatively and their relative affinity for binding seems to be a major determinant in the order of events during folding. Na+ can also substitute for Mg2+ to give rise to the same crosslinkable structures, but only at much higher concentrations. Specific binding sites for Mg2+ may make this cation particularly efficient at electrostatic stabilization during folding of these ribozyme structures.     

Sequence requirements for self-splicing of the Tetrahymena thermophila pre-ribosomal RNA.

The sequence requirements for splicing of the Tetrahymena pre-rRNA have been examined by altering the rRNA gene to produce versions that contain insertions and deletions within the intervening sequence (IVS). The altered genes were transcribed and the RNA tested for self-splicing in vitro. A number of insertions (8-54 nucleotides) at three locations had no effect on self-splicing activity. Two of these insertions, located at a site 5 nucleotides preceding the 3'-end of the IVS, did not alter the choice of the 3' splice site. Thus the 3' splice site is not chosen by its distance from a fixed point within the IVS. Analysis of deletions constructed at two sites revealed two structures, a hairpin loop and a stem-loop, that are entirely dispensable for IVS excision in vitro. Three other regions were found to be necessary. The regions that are important for self-splicing are not restricted to the conserved sequence elements that define this class of intervening sequences. The requirement for structures within the IVS for pre-rRNA splicing is in sharp contrast to the very limited role of IVS structure in nuclear pre-mRNA splicing.     

Methylation of ribosomal RNA genes in the macronucleus of Tetrahymena thermophila.

We have investigated the occurrence of methylated adenine residues in the macronuclear ribosomal RNA genes of Tetrahymena thermophila. It has been shown previously that macronuclear DNA, including the palindromic ribosomal RNA genes (rDNA), of Tetrahymena thermophila contains the modified base N-6-methyladenine, but no 5-methylcytosine. Purified rDNA was digested with restriction enzymes Sau 3AI, MboI and DpnI to map the positions and levels of N-6-methyladenine in the sequence 5' GATC 3'. A specific pattern of doubly methylated GATC sequences was found; hemimethylated sites were not detected. The patterns and levels of methylation of these sites did not change significantly in different physiological states. A molecular form of the rDNA found in the newly developing macronucleus and for several generations following the sexual process, conjugation, contained no detectably methylated GATC sites. However, both the bulk macronuclear DNA and palindromic rDNA from the same macronuclei were methylated. Possible roles for N-6-methyladenine in macronuclear DNA are discussed in light of these findings.     

Structure of the Tetrahymena ribozyme: base triple sandwich and metal ion at the active site

The Tetrahymena intron is an RNA catalyst, or ribozyme. As part of its self-splicing reaction, this ribozyme catalyzes phosphoryl transfer between guanosine and a substrate RNA strand. Here we report the refined crystal structure of an active Tetrahymena ribozyme in the absence of its RNA substrate at 3.8 A resolution. The 3'-terminal guanosine (omegaG), which serves as the attacking group for RNA cleavage, forms a coplanar base triple with the G264-C311 base pair, and this base triple is sandwiched by three other base triples. In addition, a metal ion is present in the active site, contacting or positioned close to the ribose of the omegaG and five phosphates. All of these phosphates have been shown to be important for catalysis. Therefore, we provide a picture of how the ribozyme active site positions both a catalytic metal ion and the nucleophilic guanosine for catalysis prior to binding its RNA substrate.     

Restricted active site docking by enzyme-bound substrate enforces the ordered cleavage of prothrombin by prothrombinase

The preferred pathway for prothrombin activation by prothrombinase involves initial cleavage at Arg(320) to produce meizothrombin, which is then cleaved at Arg(271) to liberate thrombin. Exosite binding drives substrate affinity and is independent of the bond being cleaved. The pathway for cleavage is determined by large differences in V(max) for cleavage at the two sites within intact prothrombin. By fluorescence binding studies in the absence of catalysis, we have assessed the ability of the individual cleavage sites to engage the active site of Xa within prothrombinase at equilibrium. Using a panel of recombinant cleavage site mutants, we show that in intact prothrombin, the Arg(320) site effectively engages the active site in a 1:1 interaction between substrate and enzyme. In contrast, the Arg(271) site binds to the active site poorly in an interaction that is approximately 600-fold weaker. Perceived substrate affinity is independent of active site engagement by either cleavage site. We further show that prior cleavage at the 320 site or the stabilization of the uncleaved zymogen in a proteinase-like state facilitates efficient docking of Arg(271) at the active site of prothrombinase. Therefore, we establish direct relationships between docking of either cleavage site at the active site of the catalyst, the V(max) for cleavage at that site, substrate conformation, and the resulting pathway for prothrombin cleavage. Exosite tethering of the substrate in either the zymogen or proteinase conformation dictates which cleavage site can engage the active site of the catalyst and enforces the sequential cleavage of prothrombin by prothrombinase.     

Guiding ribozyme cleavage through motif recognition: the mechanism of cleavage site selection by a group ii intron ribozyme

The mechanism by which group II introns cleave the correct phosphodiester linkage was investigated by studying the reaction of mutant substrates with a ribozyme derived from intron ai5gamma. While fidelity was found to be quite high in most cases, a single mutation on the substrate (+1C) resulted in a dramatic loss of fidelity. When this mutation was combined with a second mutation that induces a bulge in the exon binding site 1/intron binding site 1 (EBS1/IBS1) duplex, the base-pairing register of the EBS1/IBS1 duplex was shifted and the cleavage site moved to a downstream position on the substrate. Conversely, when mismatches were incorporated at the EBS1/IBS1 terminus, the duplex was effectively truncated and cleavage occurred at an upstream site. Taken together, these data demonstrate that the cleavage site of a group II intron ribozyme can be tuned at will by manipulating the thermodynamic stability and structure of the EBS1/IBS1 pairing. The results are consistent with a model in which the cleavage site is not designated through recognition of specific nucleotides (such as the 5'-terminal residue of EBS1). Instead, the ribozyme detects a structure at the junction between single and double-stranded residues on the bound substrate. This finding explains the puzzling lack of phylogenetic conservation in ribozyme and substrate sequences near group II intron target sites.     

Evidence for processivity and two-step binding of the RNA substrate from studies of J1/2 mutants of the Tetrahymena ribozyme.

J1/2 of the Tetrahymena ribozyme, a sequence of three A residues, connects the RNA-binding site to the catalytic core. Addition or deletion of bases from J1/2 improves turnover and substrate specificity in the site-specific endonuclease reaction catalyzed by this ribozyme: G2CCCUCUA5 (S) + G in-equilibrium G2CCCUCU (P) + GA5. These paradoxical enhancements are caused by decreased affinity of the ribozyme for S and P [Young, B., Herschlag, D., & Cech, T.R. (1991) Cell 67, 1007]. An additional property of these mutant ribozymes, decreased fidelity of RNA cleavage, is now analyzed. (Fidelity is the ability to cleave at the correct phosphodiester bond within a particular RNA substrate.) Introduction of deoxy residues to give "chimeric" ribo/deoxyribooligonucleotides changes the positions of incorrect cleavage. Previous work indicated that S is bound to the ribozyme by both base pairing and teritary interactions involving 2'-hydroxyl groups of S. The data herein strongly suggest that the P1 duplex, which consists of S base-paired with the 5' exon binding site of the ribozyme, can dock into tertiary interactions in different registers; different 2'-hydroxyl groups of S plug into tertiary contacts with the ribozyme in the different registers. It is concluded that the mutations decrease fidelity by increasing the probability of docking out of register relative to docking in the normal register, thereby giving cleavage at different positions along S. These data also show that the contribution of J1/2 to the teritiary interactions is indirect, not direct. Thus, a structural role of the nonconserved J1/2 is indicated: this sequence positions S to optimize tertiary binding interactions and to ensure cleavage at the phosphodiester bond corresponding to the 5' splice site. Substitution of sulfur for the nonbridging pro-RP oxygen atom at the normal cleavage site has no effect on (kcat/Km)S but decreases the fraction of cleavage at the normal site in reactions catalyzed by the -3A mutant ribozyme, which has all three A residues of J1/2 removed. Thus, the ribozyme chooses where to cleave S after rate-limiting binding of S, indicating that docking can change after binding and suggesting that the ribozyme could act processively. Indeed, it is shown that the +2A ribozyme cleaves at one position along an RNA substrate and then, before releasing that RNA product, cleaves it again.(ABSTRACT TRUNCATED AT 400 WORDS)     

Specificity of the hairpin ribozyme. Sequence requirements surrounding the cleavage site.

Substrate sequence requirements of the hairpin ribozyme have been partially defined by both mutational and in vitro selection experiments. It was considered that the best targets were those that included the N downward arrowGUC sequence surrounding the cleavage site. In contrast to previous studies that failed to evaluate all possible combinations of these nucleotides, we have performed an exhaustive analysis of the cleavage of 64 substrate variants. They represent all possible sequence combinations of the J2/1 nucleotides except the well established G(+1). No cleavage was observed with 24 sequences. C(+2) variants showed little or no cleavage, whereas U(+2) substrates were all cleavable. The maximal cleavage rate was obtained with the AGUC substrate. Cleavage rates of sequences HGUC (H = A, C, or U), GGUN, GGGR (R = A or G), AGUU, and UGUA were up to 5 times lower than the AGUC one. This shows that other sequences besides NGUC could also be considered as good targets. A second group of sequences WGGG (W = A or U), UGUK (K = G or U), MGAG (M = A or C), AGUA, and UGGA were cleaved between 6 and 10 times less efficiently. Furthermore, the UGCU sequence of a noncleavable viral target was mutated to AGUC resulting in a proficiently cleavable substrate by its cognate hairpin ribozyme. This indicates that our conclusions may be extrapolated to other hairpin ribozymes with different specificity.     

Protonated 2'-aminoguanosine as a probe of the electrostatic environment of the active site of the Tetrahymena group I ribozyme.

We have probed the electrostatic environment of the active site of the Tetrahymena group I ribozyme (E) using protonated 2'-aminoguanosine (), in which the 2'-OH of the guanosine nucleophile (G) is replaced by an group. At low concentrations of divalent metal ion (2 mM Mg(2+)), binds at least 200-fold stronger than G or G(NH)()2, with a dissociation constant of 相似文献   

Suppression of mutations in the core of the Tetrahymena ribozyme by spermidine, ethanol and by substrate stabilization.

We have previously described a collection of mutations in conserved residues of the core of the Tetrahymena self-splicing intron. Most of these single base substitutions have less than 10% of the activity of their parental intron derivative [Couture, S., et al., (1990) J. Mol. Biol., 215, 345-358]. We examined the effect of two agents known to stabilize RNA structure, spermidine and ethanol, on the activity of many of these mutant RNAs. In the presence of either 5 mM spermidine or 20% ethanol most substitution mutations were partially or completely suppressed. These conditions also increased the temperature optima of both wild-type and mutant ribozymes. In addition, we find that mutations are also suppressed by a high concentration of GTP, a substrate in the reaction which is bound specifically by the intron. Thus we observe a general suppression of mutations in an RNA enzyme (ribozyme) by spermidine, ethanol and by substrate stabilization. These results are consistent with the idea that most mutations destabilize the folded structure of the ribozyme and can be suppressed by any of a variety of stabilizing influences.