Leaving group stabilization by metal ion coordination and hydrogen bond donation is an evolutionarily conserved feature of group I introns

To understand the behavior of group I introns on a biologically fundamental level, we must distinguish those traits that arise as the products of natural selection (selected traits) from those that arise as the products of neutral drift (non-selected traits). In practice, this distinction relies on comparing the similarities and differences among widely divergent introns to identify conserved traits. Here we address whether the strategies used by the eukaryotic group I intron from the Tetrahymena ciliate to stabilize the leaving group during splicing are maintained in the group I intron from the widely divergent Azoarcus bacterium. A substrate analogue containing a 3'-phosphorothiolate linkage, in which a sulfur atom replaces the bridging 3'-oxygen atom of the scissile phosphate, reacts 20-fold slower in the Azoarcus reaction than the corresponding unmodified substrate in the presence of Mg(II) as the only divalent cation. However, Mn(II) relieves this negative effect such that the 3'-S-P bond cleaves 21-fold faster than does the 3'O-P bond. Other thiophilic divalent metal ions such as Co(II), Cd(II), and Zn(II) similarly support cleavage of the S-P bond. These results indicate that a metal ion directly coordinates to the leaving group in the transition state of the Azoarcus ribozyme reaction. Additionally, the 3'-sulfur substitution eliminates the approximately 10(3)-fold contribution of the adjacent 2'-OH to transition state stabilization. Considering that sulfur accepts hydrogen bonds weakly compared to oxygen, this result suggests that the 2'-OH contributes to catalysis by donating a hydrogen bond to the 3'-oxygen leaving group in the transition state, presumably acting in conjunction with the metal ion to stabilize the developing negative charge. These same catalytic strategies of metal ion coordination and hydrogen bond donation operate in the Tetrahymena ribozyme reaction, suggesting that these features of catalysis have been conserved during evolution and thus extend to all group I introns. The two ribozymes also exhibit quantitative differences in their response to 3'-sulfur substitution. The Azoarcus ribozyme binds and cleaves the phosphorothiolate substrate more efficiently relative to the natural substrate than the Tetrahymena ribozyme under the same conditions, suggesting that the Azoarcus ribozyme better accommodates the phosphorothiolate at the active site both in the ground state and in the transition state. These differences may reflect either a less tightly knit Azoarcus structure and/or spatial deviations between backbone atoms in the two ribozymes that arise during divergent evolution, analogous to the well-documented relationship between protein sequence and structure.

Metal ion coordination by the AGC triad in domain 5 contributes to group II intron catalysis

Group II introns require numerous divalent metal ions for folding and catalysis. However, because little information about individual metal ions exists, elucidating their ligands, functional roles and relationships to each other remains challenging. Here we provide evidence that an essential motif at the catalytic center of the group II intron, the AGC triad within domain 5 (D5), provides a ligand for a crucial metal ion. Sulfur substitution of the pro-Sp oxygen of the adenosine strongly disrupts D5 binding to a substrate consisting of an exon and domains 1-3 of the intron (exD123). Cd2+ rescues this effect by enabling the sulfur-modified D5 to bind to exD123 with wild type affinity and catalyze 5'-splice site cleavage. This switch in metal specificity implies that a metal ion interacts with D5 to mediate packing interactions with D123. This new D5 metal ion rescues the disruption of D5 binding and catalysis with a thermodynamic signature different from that of the metal ion that stabilizes the leaving group during the first step of splicing, suggesting the existence of two distinct metal ions.

The tetrahymena ribozyme cleaves a 5'-methylene phosphonate monoester approximately 10(2)-fold faster than a normal phosphate diester: implications for enzyme catalysis of phosphoryl transfer reactions

Single-atom substrate modifications have revealed an intricate network of transition state interactions in the Tetrahymena ribozyme reaction. So far, these studies have targeted virtually every oxygen atom near the reaction center, except one, the 5'-bridging oxygen atom of the scissile phosphate. To address whether interactions with this atom play any role in catalysis, we used a new type of DNA substrate in which the 5'-oxygen is replaced with a methylene (-CH2-) unit. Under (kcat/Km)S conditions, the methylene phosphonate monoester substrate dCCCUCUT(mp)TA4 (where mp indicates the position of the phosphonate linkage) unexpectedly reacts approximately 10(3)-fold faster than the analogous control substrates lacking the -CH2- modification. Experiments with DNA-RNA chimeric substrates reveal that the -CH2- modification enhances docking of the substrates into the catalytic core of the ribozyme by approximately 10-fold and stimulates the chemical cleavage by approximately 10(2)-fold. The docking effect apparently arises from the ability of the -CH2- unit to suppress inherently deleterious effects caused by the thymidine residue that immediately follows the cleavage site. To analyze the -O- to -CH2- modification in the absence of this thymidine residue, we prepared oligonucleotide substrates containing methyl phosphate or ethyl phosphonate at the reaction center, thereby eliminating the 3'-terminal TA4 nucleotidyl group. In this context, the -O- to -CH2-modification has no effect on docking but retains the approximately 10(2)-fold effect on the chemical step. To investigate further the stimulatory influence on the chemical step, we measured the "intrinsic" effect of the -O- to -CH2- modification in nonenzymatic reactions with nucleophiles. We found that in solution, the -CH2- modification stimulates chemical reactivity of the phosphorus center by <5-fold, substantially lower in magnitude than the stimulatory effect in the catalytic core of the ribozyme. The greater stimulatory effect of the -CH2- modification in the active site compared to in solution may arise from fortuitous changes in molecular geometry that allow the ribozyme to accommodate the phosphonate transition state better than the natural phosphodiester transition state. As the -CH2- unit lacks lone pair electrons, its effectiveness in the ribozyme reaction suggests that the 5'-oxygen of the scissile phosphate plays no role in catalysis via hydrogen bonding or metal ion coordination. Finally, we show by analysis of physical organic data that such interactions in general provide little catalytic advantage to RNA and protein phosphoryl transferases because the 5'-oxygen undergoes only a small buildup of negative charge during the reaction. In addition to its mechanistic significance for the Tetrahymena ribozyme reaction and phosphoryl transfer reactions in general, this work suggests that phosphonate monoesters may provide a novel molecular tool for determining whether the chemical step limits the rate of an enzymatic reaction. As methylene phosphonate monoesters react modestly faster than phosphate diesters in model reactions, a similarly modest stimulatory effect on an enzymatic reaction upon -CH2- substitution would suggest rate-limiting chemistry.

Defining the catalytic metal ion interactions in the Tetrahymena ribozyme reaction

Divalent metal ions play a crucial role in catalysis by many RNA and protein enzymes that carry out phosphoryl transfer reactions, and defining their interactions with substrates is critical for understanding the mechanism of biological phosphoryl transfer. Although a vast amount of structural work has identified metal ions bound at the active site of many phosphoryl transfer enzymes, the number of functional metal ions and the full complement of their catalytic interactions remain to be defined for any RNA or protein enzyme. Previously, thiophilic metal ion rescue and quantitative functional analyses identified the interactions of three active site metal ions with the 3'- and 2'-substrate atoms of the Tetrahymena group I ribozyme. We have now extended these approaches to probe the metal ion interactions with the nonbridging pro-S(P) oxygen of the reactive phosphoryl group. The results of this study combined with previous mechanistic work provide evidence for a novel assembly of catalytic interactions involving three active site metal ions. One metal ion coordinates the 3'-departing oxygen of the oligonucleotide substrate and the pro-S(P) oxygen of the reactive phosphoryl group; another metal ion coordinates the attacking 3'-oxygen of the guanosine nucleophile; a third metal ion bridges the 2'-hydroxyl of guanosine and the pro-S(P) oxygen of the reactive phosphoryl group. These results for the first time define a complete set of catalytic metal ion/substrate interactions for an RNA or protein enzyme catalyzing phosphoryl transfer.

2'-C-branched ribonucleosides. 2. Synthesis of 2'-C-beta-trifluoromethyl pyrimidine ribonucleosides

[structure: see text]. The first synthesis of 2'-C-beta-trifluoromethyl pyrimidine ribonucleosides is described. 1,2,3,5-Tetra-O-benzoyl-2-C-beta-trifluoromethyl-alpha-D-ribofuranose (3) is prepared from 1,3,5-tri-O-benzoyl-alpha-D-ribofuranose (1) in three steps and converted to 3,5-di-O-benzoyl-2-C-beta-trifluoromethyl-alpha-D-1-ribofuranosyl bromide (5). The 1-bromo derivative (5) is found to be a powerful reaction intermediate for the synthesis of ribonucleosides. The reaction of silylated pyrimidines with (5) in the presence of HgO/HgBr2 affords exclusively the beta-anomers (6-8). Deprotection of (6-8) with ammonia in methanol yields the 2'-C-beta-trifluoromethyl nucleosides (9-11).

Kinetic characterization of the second step of group II intron splicing: role of metal ions and the cleavage site 2'-OH in catalysis

The ai5gamma group II intron from yeast excises itself from precursor transcripts in the absence of proteins. When a shortened form of the intron containing all but the 3'-terminal six nucleotides is incubated with an exon 1 oligonucleotide and a 3' splice site oligonucleotide, a nucleotidyl transfer reaction occurs that mimics the second step of splicing. As this tripartite reaction provides a means to identify important functional groups in 3' splice site recognition and catalysis, we establish here a minimal kinetic framework and demonstrate that the chemical step is rate-limiting. We use this framework to characterize the metal ion specificity switch observed previously upon sulfur substitution of the 3'-oxygen leaving group and to elucidate by atomic mutagenesis the role of the neighboring 2'-OH in catalysis. The results suggest that both the 3'-oxygen leaving group and the neighboring 2'-OH are important ligands for metal ions in the transition state but not in the ground state and that the 2'-OH may play an additional role in transition state stabilization by donating a hydrogen bond. Metal specificity switch experiments combined with quantitative analysis show that the Mn(2+) that interacts with the leaving group binds to the ribozyme with the same affinity as the metal ion that interacts with the neighboring 2'-OH, raising the possibility that a single metal ion mediates interactions with the 2'- and 3'-oxygen atoms at the 3' splice site.

Investigation of the proposed interdomain ribose zipper in hairpin ribozyme cleavage using 2'-modified nucleosides

The hairpin ribozyme achieves catalytic cleavage through interaction of essential nucleotides located in two distinct helical domains that include internal loops. Initial docking of the two domains is ion dependent and appears to be followed by a structural rearrangement that allows the ribozyme to achieve a catalytically active state that can undergo cleavage. The proposed structural rearrangement may also be ion dependent and is now of increased importance due to recent evidence that docking is not rate limiting and that metal ions are unlikely to be involved in the chemical cleavage step. An initial structural model of the docked hairpin ribozyme included a proposal for a ribose zipper motif that involves two pairs of hydroxyl groups at A(10) and G(11) in domain A pairing with C(25) and A(24) in domain B, respectively. We have used a chemical functional group substitution technique to study whether this proposed ribose zipper is likely to be present in the active, conformationally rearranged ribozyme that is fit for cleavage. We have chemically synthesized a series of individually modified hairpin ribozymes containing 2'-analogues of nucleosides, that include 2'-deoxy and 2'-deoxy-2'-fluoro at each of the four nucleoside positions, 2'-amino-2'-deoxy, 2'-deoxy-2'-thio, and 2'-arabino at position C(25), and 2'-oxyamino at position A(10), as well as some double substitutions, and we studied their cleavage rates under both single- and multiple-turnover conditions. We conclude that at least some of the hydrogen-bonding interactions in the ribose zipper motif, either as originally proposed or in a recently suggested structural variation, are unlikely to be present in the active rearranged form of the ribozyme that undergoes cleavage. Instead, we provide strong evidence for a very precise conformational positioning for the residue C(25) in the active hairpin. A precise conformational requirement would be expected for C(25) if it rearranges to form a base-triple with A(9) and the essential residue neighboring the cleavage site G(+1), as recently proposed by another laboratory. Our results provide further support for conformational rearrangement as an important step in hairpin ribozyme cleavage.

Active site constraints in the hydrolysis reaction catalyzed by bacterial RNase P: analysis of precursor tRNAs with a single 3'-S-phosphorothiolate internucleotide linkage

Endonucleolytic processing of precursor tRNAs (ptRNAs) by RNase P yields 3'-OH and 5'-phosphate termini, and at least two metal ions are thought to be essential for catalysis. To determine if the hydrolysis reaction catalyzed by bacterial RNase P (RNAs) involves stabilization of the 3'-oxyanion leaving group by direct coordination to one of the catalytic metal ions, ptRNA substrates with single 3'- S -phosphorothiolate linkages at the RNase P cleavage site were synthesized. With a 3'- S -phosphorothiolate-modified ptRNA carrying a 7 nt 5'-flank, a complete shift of the cleavage site to the next unmodified phosphodiester in the 5'-direction was observed. Cleavage at the modified linkage was not restored in the presence of thiophilic metal ions, such as Mn(2+)or Cd(2+). To suppress aberrant cleavage, we also constructed a 3'- S -phosphorothiolate-modified ptRNA with a 1 nt 5'-flank. No detectable cleavage of this substrate was seen in reactions catalyzed by RNase P RNAs from Escherichia coli and Bacillus subtilis, independent of the presence of thiophilic metal ions. Ground state binding of modified ptRNAs was not impaired, suggesting that the 3'- S -phosphorothiolate modification specifically prevents formation of the transition state, possibly by excluding catalytic metal ions from the active site.

The role of the cleavage site 2'-hydroxyl in the Tetrahymena group I ribozyme reaction

BACKGROUND

The 2'-hydroxyl of U preceding the cleavage site, U(-1), in the Tetrahymena ribozyme reaction contributes 10(3)-fold to catalysis relative to a 2'-hydrogen atom. Previously proposed models for the catalytic role of this 2'-OH involve coordination of a catalytic metal ion and hydrogen-bond donation to the 3'-bridging oxygen. An additional model, hydrogen-bond donation by the 2'-OH to a nonbridging reactive phosphoryl oxygen, is also consistent with previous results. We have tested these models using atomic-level substrate modifications and kinetic and thermodynamic analyses.

RESULTS

Replacing the 2'-OH with -NH(3)(+) increases the reaction rate approximately 60-fold, despite the absence of lone-pair electrons on the 2'-NH(3)(+) group to coordinate a metal ion. Binding and reaction of a modified oligonucleotide substrate with 2'-NH(2) at U(-1) are unaffected by soft-metal ions. These results suggest that the 2'-OH of U(-1) does not interact with a metal ion. The contribution of the 2'-moiety of U(-1) is unperturbed by thio substitution at either of the nonbridging oxygens of the reactive phosphoryl group, providing no indication of a hydrogen bond between the 2'-OH and the nonbridging phosphoryl oxygens. In contrast, the 10(3)-fold catalytic advantage of 2'-OH relative to 2'-H is eliminated when the 3'-bridging oxygen is replaced by sulfur. As sulfur is a weaker hydrogen-bond acceptor than oxygen, this effect suggests a hydrogen-bonding interaction between the 2'-OH and the 3'-bridging oxygen.

CONCLUSIONS

These results provide the first experimental support for the model in which the 2'-OH of U(-1) donates a hydrogen bond to the neighboring 3'-bridging oxygen, thereby stabilizing the developing negative charge on the 3'-oxygen in the transition state.

Metal ion catalysis during the exon-ligation step of nuclear pre-mRNA splicing: extending the parallels between the spliceosome and group II introns

Mechanistic analyses of nuclear pre-mRNA splicing by the spliceosome and group II intron self-splicing provide insight into both the catalytic strategies of splicing and the evolutionary relationships between the different splicing systems. We previously showed that 3'-sulfur substitution at the 3' splice site of a nuclear pre-mRNA has no effect on splicing. We now report that 3'-sulfur substitution at the 3' splice site of a nuclear pre-mRNA causes a switch in metal specificity when the second step of splicing is monitored using a bimolecular exon-ligation assay. This suggests that the spliceosome uses a catalytic metal ion to stabilize the 3'-oxyanion leaving group during the second step of splicing, as shown previously for the first step. The lack of a metal-specificity switch under cis splicing conditions indicates that a rate-limiting conformational change between the two steps of splicing may mask the subsequent chemical step and the metal-specificity switch. As the group II intron, a true ribozyme, uses identical catalytic strategies for splicing, our results strengthen the argument that the spliceosome is an RNA catalyst that shares a common molecular ancestor with group II introns.

Three metal ions at the active site of the Tetrahymena group I ribozyme

Metal ions are critical for catalysis by many RNA and protein enzymes. To understand how these enzymes use metal ions for catalysis, it is crucial to determine how many metal ions are positioned at the active site. We report here an approach, combining atomic mutagenesis with quantitative determination of metal ion affinities, that allows individual metal ions to be distinguished. Using this approach, we show that at the active site of the Tetrahymena group I ribozyme the previously identified metal ion interactions with three substrate atoms, the 3'-oxygen of the oligonucleotide substrate and the 3'- and 2'-moieties of the guanosine nucleophile, are mediated by three distinct metal ions. This approach provides a general tool for distinguishing active site metal ions and allows the properties and roles of individual metal ions to be probed, even within the sea of metal ions bound to RNA.

Metal ion catalysis during group II intron self-splicing: parallels with the spliceosome

The identical reaction pathway executed by the spliceosome and self-splicing group II intron ribozymes has prompted the idea that both may be derived from a common molecular ancestor. The minimal sequence and structural similarities between group II introns and the spliceosomal small nuclear RNAs, however, have left this proposal in question. Mechanistic comparisons between group II self-splicing introns and the spliceosome are therefore important in determining whether these two splicing machineries may be related. Here we show that 3'-sulfur substitution at the 5' splice site of a group II intron causes a metal specificity switch during the first step of splicing. In contrast, 3'-sulfur substitution has no significant effect on the metal specificity of the second step of cis-splicing. Isolation of the second step uncovers a metal specificity switch that is masked during the cis-splicing reaction. These results demonstrate that group II intron ribozymes are metalloenzymes that use a catalytic metal ion for leaving group stabilization during both steps of self-splicing. Furthermore, because 3'-sulfur substitution of a spliceosomal intron has precisely the same effects as were observed during cis-splicing of the group II intron, these results provide striking parallels between the catalytic mechanisms employed by these two systems.

A new metal ion interaction in the Tetrahymena ribozyme reaction revealed by double sulfur substitution

The Tetrahymena ribozyme is a metalloenzyme that catalyzes cleavage of oligonucleotide substrates by phosphoryl transfer. Thiophilic metal ions such as Mn2+, Zn2+ or Cd2+ rescue the >10(3)-fold inhibitory effect of sulfur substitution of the 3'-oxygen leaving group but do not effectively rescue the effect of sulfur substitution of the nonbridging pro-Sp phosphoryl oxygen. We now show that the latter effect can be fully rescued by Zn2+ or Cd2+ using a phosphorodithioate substrate, in which both the 3'-oxygen and the pro-Sp oxygen are simultaneously substituted with sulfur. These results provide the first functional evidence that metallophosphotransferases can mediate catalysis via metal ion coordination to both the leaving group and a nonbridging oxygen of the scissile phosphate.

Do enzymes obey the Baldwin rules? A mechanistic imperative in enzymatic cyclization reactions

It is commonly assumed that enzymes have evolved to abide by the same energetic and stereoelectronic principles that govern reactions in solution. The principles formulated for organic ring-closure reactions can be used to develop a hypothesis for analysis of enzyme-catalyzed cyclization reactions.

Structures of normal single-stranded DNA and deoxyribo-3'-S-phosphorothiolates bound to the 3'-5' exonucleolytic active site of DNA polymerase I from Escherichia coli

The interaction of a divalent metal ion with a leaving 3' oxygen is a central component of several proposed mechanisms of phosphoryl transfer. In support of this are recent kinetic studies showing that thiophilic metal ions (e.g., Mn2+) stimulate the hydrolysis of compounds in which sulfur takes the place of the leaving oxygen. To examine the structural basis of this phenomenon, we have solved four crystal structures of single-stranded DNA's containing either oxygen or sulfur at a 3'-bridging position bound in conjunction with various metal ions at the 3'-5' exonucleolytic active site of the Klenow fragment (KF) of DNA polymerase I from Escherichia coli. Two structures of normal ssDNA bound to KF in the presence of Zn2+ and Mn2+ or Zn2+ alone were refined at 2.6- and 2.25-A resolution, respectively. They serve as standards for comparison with other Mn2+- and Zn2+-containing structures. In these cases, Mn2+ and Zn2+ bind at metal ion site B in a nearly identical position to Mg2+ (Brautigam and Steitz (1998) J. Mol. Biol. 277, 363-377). Two structures of KF bound to a deoxyoligonucleotide that contained a 3'-bridging sulfur at the scissile phosphate were refined at 2.03-A resolution. Although the bridging sulfur compounds bind in a manner very similar to that of the normal oligonucleotides, the presence of the sulfur changes the metal ion binding properties of the active site such that Mn2+ and Zn2+ are observed at metal ion site B, but Mg2+ is not. It therefore appears that the ability of the bridging sulfur compounds to exclude nonthiophilic metal ions from metal ion site B explains the low activity of KF exonuclease on these substrates in the presence of Mg2+ (Curley et al. (1997) J. Am. Chem. Soc. 119, 12691-12692) and that the 3'-bridging atom of the substrate is influencing the binding of metal ion B prior to catalysis.

Redesigning nucleic acids

A research program has applied the tools of synthetic organic chemistry to systematically modify the structure of DNA and RNA oligonucleotides to learn more about the chemical principles underlying their ability to store and transmit genetic information. Oligonucleotides (as opposed to nucleosides) have long been overlooked by synthetic organic chemists as targets for structural modification. Synthetic chemistry has now yielded oligonucleotides with 12 replicatable letters, modified backbones, and new insight into why Nature chose the oligonucleotide structures that she did.

Synthesis of 3'-thioribonucleosides and their incorporation into oligoribonucleotides via phosphoramidite chemistry

Oligoribonucleotides containing 3'-S-phosphorothiolate linkages are valuable probes in nucleic acid biochemistry, but their accessibility has been limited because 3'-thioribonucleoside phosphoramidites have not been available. We synthesized 3'-thioribonucleoside derivatives (C, G, and U) via glycosylations of nucleoside bases with 3-S-thiobenzoyl-5-O-toluoyl-1,2-O-diacetylfuranose 5, which was obtained from 1 ,2-O-isopropylidene-5-O-toluoyl-3-trifluoromethane-sulfonyl-alpha-D-x ylofuranose 2 by SN2 displacement with sodium thiobenzoate. Additionally, a 3'-thioinosine derivative was prepared from inosine via direct modification of the ribose, analogous to the previously reported synthesis of 3'-thioadenosine, except that the intermediate 2',3'-epoxide 9 was first protected as the 5'-O-tert-butyldiphenylsilyl ether prior to subsequent synthetic steps. This hydrophobic silyl group facilitated extraction and isolation of synthetic intermediates. After removal of the protecting groups, the 3'-thionucleosides (C, G, U, and I) were treated with 2,2'-dipyridyl disulfide to protect the free thiol group as a disulfide. The 3'-thionucleosides were converted to the corresponding phosphorothioamidites using procedures analogous to those for standard phosphoramidites. The amino groups of 3'-thiocytidine and 3'-thioguanosine were protected as benzoyl and isobutyryl amides, respectively, and the 5'- and 2'-hydroxyl groups of each nucleoside were protected as dimethoxytrityl and tert-butyldimethylsilyl ethers, respectively. The 3'-thiol group was deprotected by reduction with DTT and phosphitylated to afford analytically pure 3'-S-phosphorothioamidites 15, which were incorporated into oligoribonucleotides by solid-phase synthesis. Chemical assays and mass spectrometry of the synthetic RNA showed that ribose-3'-S-phosphorothiolate linkages were installed correctly and efficiently into RNA oligonucleotides using phosphoramidite chemistry.

Metal ion catalysis during splicing of premessenger RNA

The removal of intervening sequences from premessenger RNA is essential for the expression of most eukaryotic genes. The spliceosome ribonucleoprotein complex catalyses intron removal by two sequential phosphotransesterification reactions, but the catalytic mechanisms are unknown. It has been proposed that two divalent metal ions may mediate catalysis of both reaction steps, activating the 2'- or 3'-hydroxyl groups for nucleophilic attack and stabilizing the 3'-oxyanion leaving groups by direct coordination. Here we show that in splicing reactions with a precursor RNA containing a 3'-sulphur substitution at the 5' splice site, interaction between metal ion and leaving group is essential for catalysis of the first reaction step. This establishes that the spliceosome is a metalloenzyme and demonstrates a direct parallel with the catalytic strategy used by the self-splicing group I intron from Tetrahymena. In contrast, 3'-sulphur substitution at the 3' splice site provides no evidence for a metal ion-leaving group interaction in the second reaction step, suggesting that the two steps of splicing proceed by different catalytic mechanisms and therefore in distinct active sites.

Metal ion catalysis in the Tetrahymena ribozyme reaction

All catalytic RNAs (ribozymes) require or are stimulated by divalent metal ions, but it has been difficult to separate the contribution of these metal ions to formation of the RNA tertiary structure from a more direct role in catalysis. The Tetrahymena ribozyme catalyses cleavage of exogenous RNA or DNA substrates with an absolute requirement for Mg2+ or Mn2+ (ref. 6). A DNA substrate, in which the bridging 3' oxygen atom at the cleavage site is replaced by sulphur, is cleaved by the ribozyme about 1,000 times more slowly than the corresponding unmodified DNA substrate when Mg2+ is present as the only divalent metal ion. But addition of Mn2+ or Zn2+ to the reaction relieves this negative effect, with the 3' S-P bond being cleaved nearly as fast as the 3' O-P bond. Considering that Mn2+ and Zn2+ coordinate sulphur more strongly than Mg2+ does, these results indicate that the metal ion contributes directly to catalysis by coordination to the 3' oxygen atom in the transition state, presumably stabilizing the developing negative charge on the leaving group. We conclude that the Tetrahymena ribozyme is a metalloenzyme, with mechanistic similarities to several protein enzymes.

Aminoacyl esterase activity of the Tetrahymena ribozyme

Several classes of ribozymes (catalytic RNA's) catalyze reactions at phosphorus centers, but apparently no reaction at a carbon center has been demonstrated. The active site of the Tetrahymena ribozyme was engineered to bind an oligonucleotide derived from the 3' end of N-formyl-methionyl-tRNA(fMet). This ribozyme catalyzes the hydrolysis of the aminoacyl ester bond to a modest extent, 5 to 15 times greater than the uncatalyzed rate. Catalysis involves binding of the oligonucleotide to the internal guide sequence of the ribozyme and requires Mg2+ and sequence elements of the catalytic core. The ability of RNA to catalyze reactions with aminoacyl esters expands the catalytic versatility of RNA and suggests that the first aminoacyl tRNA synthetase could have been an RNA molecule.

Abortive products as initiating nucleotides during transcription by T7 RNA polymerase

The kinetics of formation of abortive initiation products during transcription of a synthetic template (encoding the transcript GAUGGC) by T7 RNA polymerase have been determined. This study revealed that while total RNA was formed in the reaction as expected, the levels of the dinucleoside tetraphosphate guanylyl-3',5'-adenosine-5'-triphosphate (pppGpA) and trinucleoside pentaphosphate guanylyl-3',5'-adenosine-3',5'-uridine-5'-triphosphate (pppGpApU) formed by premature termination of transcription reached a maximum after 10 min, and then decreased. Transcription of the same template, in the presence of either [gamma-32P]GTP and ATP, or GTP and [alpha-32P]ATP, gave the 32P-labeled dinucleotides *pppGpA and pppG*pA. Incorporation of each of these substrates into longer RNA transcripts in the same enzyme-template system was demonstrated. The incorporation was shown to require the presence of template in the reaction mixture. The requirement for base complementarity restricts the position of incorporation to that of initiating (5') nucleotide. Transcription of a second template, which encodes an RNA transcript having the partial sequence GpA at two internal positions, in the presence of each of the labeled dinucleoside tetraphosphates, failed to bring about the synthesis of significant yields of any longer radiolabeled transcripts. It is concluded that dinucleoside tetraphosphate (and perhaps trinucleoside pentaphosphate) can function as initiating nucleotides when complementary to the nucleotide sequence at promoter regions. However, a dinucleotide is not used as substrate for subsequent chain elongation in T7 RNA polymerase catalyzed transcription reactions.

A C-nucleotide base pair: methylpseudouridine-directed incorporation of formycin triphosphate into RNA catalyzed by T7 RNA polymerase

With templates containing 2'-deoxy-1-methylpseudouridine (dm psi), T7 RNA polymerase catalyzes the incorporation of either adenosine triphosphate (ATP) or formycin triphosphate (FTP) into a growing chain of RNA with the same efficiency as with templates containing thymidine (dT). In each case, the overall rate of synthesis of full-length products containing formycin is about one-tenth of the rate of synthesis of analogous products containing adenosine. Analysis of the products of abortive initiation shows that incorporation of FMP into the growing oligonucleotide by T7 RNA polymerase is more likely to lead to premature termination of transcription than is incorporation of AMP. Nevertheless, the results demonstrate that T7 RNA polymerase tolerates the formation of a C-nucleotide transcription complex in which the nucleoside bases on both the template and the incoming nucleotide are joined to the ribose by a carbon-carbon bond. This result increases the prospects for further expanding the genetic alphabet via incorporation of new base pairs with novel hydrogen-bonding schemes (Piccirilli et al., 1990).

Ribozyme-catalyzed and nonenzymatic reactions of phosphate diesters: rate effects upon substitution of sulfur for a nonbridging phosphoryl oxygen atom

The L-21 ScaI ribozyme derived from the intervening sequence of Tetrahymena thermophila pre-rRNA catalyzes a guanosine-dependent endonuclease reaction that is analogous to the first step in self-splicing of this intervening sequence. We now describe pre-steady-state kinetic experiments, with sulfur substituting for the pro-RP (nonbridging) phosphoryl oxygen atom at the site of cleavage, that test aspects of a kinetic model proposed for the ribozyme reaction (Herschlag, D., & Cech, T. R. (1990) Biochemistry 29, 10159-10171). Thio substitution does not affect the reaction with subsaturating oligonucleotide substrate and saturating guanosine ((kcat/Km)S), consistent with the previous finding that binding of the oligonucleotide substrate limits this rate constant. In contrast, there is a significant decrease in the rate of single-turnover reactions of ribozyme-bound (i.e., saturating) oligonucleotide substrate upon thio substitution, with decreases of 2.3-fold for the reaction with guanosine ((kcat/Km)G) and 7-fold for hydrolysis [i.e., with solvent replacing guanosine; kc(-G)]. These "thio effects" are consistent with rate-limiting chemistry, as shown by comparison with model reactions. Nonenzymatic nucleophilic substitution reactions of the phosphate diester, methyl 2,4-dinitrophenyl phosphate monoanion, are slowed 4-11-fold by thio substitution for reactions with hydroxide ion, formate ion, fluoride ion, pyridine, and nicotinamide. In addition, we have confirmed that thio substitution has no effect on the nonenzymatic alkaline cleavage of RNA (Burgers, P. M. J., & Eckstein, F. (1979) Biochemistry 18, 592-596). Considering the strong preference of Mg2+ for binding to oxygen rather than sulfur, the modest thio effect on the chemical step of the ribozyme-catalyzed reaction and the absence of a thio effect on the equilibrium constant for binding of the oligonucleotide substrate suggest that the pro-RP oxygen atom is not coordinated to Mg2+ in the E.S complex or in the transition state. General implications of thio effects in enzymatic reactions of phosphate diesters are discussed.

Enzymatic incorporation of a new base pair into DNA and RNA extends the genetic alphabet

A new Watson-Crick base pair, with a hydrogen bonding pattern different from that in the A.T and G.C base pairs, is incorporated into duplex DNA and RNA by DNA and RNA polymerases and expands the genetic alphabet from 4 to 6 letters. This expansion could lead to RNAs with greater diversity in functional groups and greater catalytic potential.

Natural selection, protein engineering, and the last riboorganism: rational model building in biochemistry

A detailed study of the chemical behavior of modern catalysts (here, exemplified by dehydrogenases dependent on NAD+) allows us to construct models that distinguish between selected and drifting behaviors in biological macromolecules. These models enable us to manipulate rationally the properties of enzymes, here to design an "acetaldehyde reductase" dependent on NAD+ that is faster than any given us by nature. When applied to the origin of protein catalysis, models that explain the structures of ribo-cofactors (e.g., NAD+) must postulate a metabolically complex breakthrough organism. This means that: (1) The view from the present day back to the truly primeval organism is obscured; it is futile to try to deduce the detailed structure of the first life by examining the behaviors of modern organisms. (2) Riboorganisms dominated life on earth for a long time before translation evolved; indeed, fossils of riboorganisms might already be known. (3) Using organic synthesis, we have expanded the number of bases available for making RNA and making accessible RNA molecules that are likely to be intrinsically better catalysts.