RNA splicing: group I intron crystal structures reveal the basis of splice site selection and metal ion catalysis

The group I intron has served as a model for RNA catalysis since its discovery 25 years ago. Four recently determined high-resolution crystal structures complement extensive biochemical studies on this system. Structures of the Azoarcus, Tetrahymena and bacteriophage Twort group I introns mimic different states of the splicing or ribozyme reaction pathway and provide information on splice site selection and metal ion catalysis. The 5'-splice site is selected by formation of a conserved G.U wobble pair between the 5'-exon terminus and the intron. The 3'-splice site is identified through stacking of three base triples, in which the middle triple contains the conserved terminal nucleotide of the intron, OmegaG. The structures support a two-metal-ion mechanism for group I intron splicing that might have corollaries to group II intron and pre-mRNA splicing by the spliceosome.     

A new synthetic protocol for labeled oligonucleotides, using a chemically cleavable universal linker

A two-step general method for labeling of synthetic oligonucleotides is described. The protocol employs a cleavable universal linker, 5'-O-(4,4'-dimethoxytrityl)-3'-O-benzoyl-2'-O-(2-cyanoethyl-N,N-diisopropyl)-uridine phosphoramidite, to effect coupling to polymer-bound oligonucleotide chains. Sequentially, coupling with commercially available phosphoramidite reagent of an appropriate label (Biotin, HEX etc.) in an automated DNA synthesizer is carried out. The labeled oligomers, obtained after cleavage and deprotection reactions, are analyzed on RP-HPLC. A distinctive feature of this protocol is the recovery of free oligomers from their labeled analogs under mild conditions. The oligomers obtained are comparable to the corresponding standard oligonucleotides (HPLC).     

Divalent metal ion binding to a conserved wobble pair defining the upstream site of cleavage of group I self-splicing introns.

The upstream site of cleavage of all group I self-splicing introns is identified by an absolutely conserved U.G base pair. Although a wobble C.A pair can substitute the U.G pair, all other combinations of nucleotides at this position abolish splicing, suggesting that it is an unusual RNA structure, rather than sequence, that is recognized by the catalytic intron core. RNA enzymes are metalloenzymes, and divalent metal ion binding may be an important requirement for splice site recognition and catalysis. The paramagnetic broadening of NMR resonances upon manganese binding at specific sites was used to probe the interaction between divalent metal ions and an oligonucleotide model of a group I intron ribozyme substrate. Unlike previous studies in which only imino proton resonances were monitored, we have used isotopically labelled RNA and a set of complete spectral assignments to identify the location of the divalent metal binding site with much greater detail than previously possible. Two independent metal binding sites were identified for this oligonucleotide. A first metal binding site is located in the major groove of the three consecutive G.C base pairs at the end of double helical stem. A second site is found in the major groove of the RNA double helix in the vicinity of the U.G base pair. These results suggest that metal ion coordination (or a metal bridge) and tertiary interactions identified biochemically, may be used by group I intron ribozymes for substrate recognition.     

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.     

Stacking of Crick Wobble pair and Watson-Crick pair: stability rules of G-U pairs at ends of helical stems in tRNAs and the relation to codon-anticodon Wobble interaction.

The occurrence of the noncomplementary G-U base pair at the end of a helix is found to be governed by stacking interactions. As a rule, a G-U pair with G on the 5'-side of a Watson-Crick base pair exhibits strikingly greater stacking overlap with the Watson-Crick base pair than a G-U pair on the 3'-side of a Watson-Crick base pair. The former arrangement is expected to be more stable and indeed is observed 29 times out of 32 in the known transfer RNA molecules. In accordance with this rule, the major wobble base pairs G-U or I-U in codon-anticodon interactions have G or I on the 5'-side of the anticodon. Similarly, in initiator tRNAs, this rule is obeyed where now the G is the first letter of the codon (5'-side). In the situation where U is in the wobble position of the anticodon, it is usually substituted at C(5) andmay also have a 2-thio group and it can read one to four codons depending on its modifications. A G at the wobble position of the anticodon can recognize the two codons ending with U or C and modification of G (unless it is I) does not change its reading properties.     

Mutagenesis and comparative sequence analysis of a base triple joining the two domains of group I ribozymes.

Tertiary interactions are important in the higher-order folding of catalytic RNAs. Recently, a base triple, joining the two major domains of the catalytic core, was determined in group I introns from the cyanobacterium Anabaena PCC7120 and the eukaryote Tetrahymena thermophila. This base triple involves the fifth base pair of P4 and the fifth base of the single-stranded region J8/7. We made base pair and single-nucleotide substitutions in the fifth base pair of P4, a G-C in the wild-type Anabaena intron, and tested them for self-splicing activity. The results suggest a hydrogen bonding model in which only the C of the base pair interacts directly with the fifth base of J8/7. Comparative sequence analysis was used to determine the different combinations of base triples that occur in approximately 450 natural group I introns identified to date. About 94% of the base triples analyzed are compatible with the proposed hydrogen bonding model. Disrupting this base triple in the Tetrahymena intron resulted in the disappearance of splicing intermediates (intron 3' exon and 5' exon), even though the first step of splicing was not affected. Restoration of the base triple by a compensatory mutation reverted the intermediates to wild-type levels. These results suggest that disruption of the base triple increases the rate of the second step of splicing or of a conformational change preceding the second step. Repositioning of the base triple to form a new set of interactions may be required for the second step of splicing.     

Mutations at the guanosine-binding site of the Tetrahymena ribozyme also affect site-specific hydrolysis.

Self-splicing group I introns use guanosine as a nucleophile to cleave the 5' splice site. The guanosine-binding site has been localized to the G264-C311 base pair of the Tetrahymena intron on the basis of analysis of mutations that change the specificity of the nucleophile from G (guanosine) to 2AP (2-aminopurine ribonucleoside) (F. Michel et al. (1989) Nature 342, 391-395). We studied the effect of these mutations (G-U, A-C and A-U replacing G264-C311) in the L-21 ScaI version of the Tetrahymena ribozyme. In this enzymatic system (kcat/Km)G monitors the cleavage step. This kinetic parameter decreased by at least 5 x 10(3) when the G264-C311 base pair was mutated to an A-U pair, while (kcat/Km)2AP increased at least 40-fold. This amounted to an overall switch in specificity of at least 2 x 10(5). The nucleophile specificity (G > 2AP for the G-C and G-U pairs, 2AP > G for the A-U and A-C pairs) was consistent with the proposed hydrogen bond between the nucleotide at position 264 and N1 of the nucleophile. Unexpectedly, the A-U and A-C mutants showed a decrease of an order of magnitude in the rate of ribozyme-catalyzed hydrolysis of RNA, in which H2O or OH- replaces G as the nucleophile, whereas the G-U mutant showed a decrease of only 2-fold. The low hydrolysis rates were not restored by raising the Mg2+ concentration or lowering the temperature. In addition, the mutant ribozymes exhibited a pattern of cleavage by Fe(II)-EDTA indistinguishable from that of the wild type, and the [Mg2+]1/2 for folding of the A-U mutant ribozyme was the same as that of the wild type. Therefore the guanosine-binding site mutations do not appear to have a major effect on RNA folding or stability. Because changing G264 affects the hydrolysis reaction without perturbing the global folding of the RNA, we conclude that the catalytic role of this conserved nucleotide is not limited to guanosine binding.     

Solid-phase syntheses of oligodeoxyribonucleoside methylphosphonates

Oligodeoxyribonucleoside methylphosphonates of defined sequence of the type d-Np(NP)nN, where n is 6-13, are readily prepared on insoluble polystyrene supports by use of protected 5'-(dimethoxytrityl)deoxyribonucleoside 3'-(methylphosphonic imidazolides) as synthetic intermediates. The imidazolides are prepared in situ by reaction of protected 5'-(dimethoxytrityl)deoxyribonucleoside with methylphosphonic bis(imidazolide) and can be stores in the reaction solution for up to 2 weeks at 4 degrees C with no loss in activity. The condensation reaction is accelerated by the presence of tetrazole, which appears to act as an acid catalyst. The half-life for dimer formation on the polystyrene support is 5 min, and the reaction is 95% complete after 60 min. Although similar kinetics are observed when controlled pore glass is used as the support, the extent of the reaction does not go beyond 78%, even after prolonged incubation. In order to simplify purification and sequence analysis of the oligomer, the 5'-terminal nucleoside unit is linked via a phosphodiester bond. This linkage may be introduced by either an o-chlorophenyl phosphotriester method or a cyanoethyl phosphoramidite method. The latter procedure simplifies the deprotection step, since the cyanoethyl group is readily cleaved by ethylenediamine, which also removes the base protecting groups and cleaves the oligomer from the support. The singly charged oligomers are easily purified by affinity chromatography on DEAE-cellulose. The chain lengths of the oligomers were confirmed after 5'-end labeling with polynucleotide kinase by partial hydrolysis of the methylphosphonate linkages with 1 M aqueous piperidine followed by polyacrylamide gel electrophoresis of the hydrolysate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Microbiology of Saturated Salt Solutions and Other Harsh Environments. IV. New Observations of Ribonucleotide-Induced Recovery of KCl-Habituated Penicillium notatum

Salt-tolerant mutant Penicillium notatum sub-cultured in a glucose-peptone broth saturated with KCl shows continued attenuated growth when transferred to salt-free broth. Additional tests have shown E. coli S-RNA to be inferior to yeast RNA preparations, that base-free phosphate sources are inactive, but that nicotinamide adenine dinucleotide and flavine adenine dinucleotide are moderately active. All phosphate derivatives of adenine, cytosine and guanosine and inosine were active including 5'-polyphosphates, 3'(2')-monophosphates 5'-monophosphates, and adenine 3', 5'-cyclic monophosphate. Uracil derivatives were of low activity at best.Among base precursors, orotic acid was moderately active whereas imidazoles were not. The high activity of inosine 5'-phosphate a precursor of other purine nucleotides suggested that one mode of KCl action might involve a block in conversion of 4-amino-5-imidazole carboxamide ribonucleoside to the hypoxanthine nucleotide.     

Three Tetrahymena tRNA(Gln) isoacceptors as tools for studying unorthodox codon recognition and codon context effects during protein synthesis in vitro.

Three glutamine tRNA isoacceptors are known in Tetrahymena thermophila. One of these has the anticodon UmUG which reads the two normal glutamine codons CAA and CAG, whereas the two others with CUA and UmUA anticodons recognize UAG and UAA, respectively, which serve as termination codons in other organisms. We have employed these tRNA(Gln)-isoacceptors as tools for studying unconventional base interactions in a mRNA- and tRNA-dependent wheat germ extract. We demonstrate here (i) that tRNA(Gln)UmUG suppresses the UAA as well as the UAG stop codon, involving a single G:U wobble pair at the third anticodon position and two simultaneous wobble base pairings at the first and third position, respectively, and (ii) that tRNA(Gln)CUA, in addition to its cognate codon UAG, reads the UAA stop codon which necessitates a C:A mispairing in the first anticodon position. These unorthodox base interactions take place in a codon context which favours readthrough in tobacco mosaic virus (TMV) or tobacco rattle virus (TRV) RNA, but are not observed in a context that terminates zein and globin protein synthesis. Furthermore, our data reveal that wobble or mispairing in the middle position of anticodon-codon interactions is precluded in either context. The suppressor activities of tRNAs(Gln) are compared with those of other known naturally occurring suppressor tRNAs, i.e., tRNA(Tyr)G psi A and tRNA(Trp)CmCA. Our results indicate that a 'leaky' context is neither restricted to a single stop codon nor to a distinct tRNA species.     

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.     

Probing the role of a secondary structure element at the 5'- and 3'-splice sites in group I intron self-splicing: the tetrahymena L-16 ScaI ribozyme reveals a new role of the G.U pair in self-splicing

Several ribozyme constructs have been used to dissect aspects of the group I self-splicing reaction. The Tetrahymena L-21 ScaI ribozyme, the best studied of these intron analogues, catalyzes a reaction analogous to the first step of self-splicing, in which a 5'-splice site analogue (S) and guanosine (G) are converted into a 5'-exon analogue (P) and GA. This ribozyme preserves the active site but lacks a short 5'-terminal segment (called the IGS extension herein) that forms dynamic helices, called the P1 extension and P10 helix. The P1 extension forms at the 5'-splice site in the first step of self-splicing, and P10 forms at the 3'-splice site in the second step of self-splicing. To dissect the contributions from the IGS extension and the helices it forms, we have investigated the effects of each of these elements at each reaction step. These experiments were performed with the L-16 ScaI ribozyme, which retains the IGS extension, and with 5'- and 3'-splice site analogues that differ in their ability to form the helices. The presence of the IGS extension strengthens binding of P by 40-fold, even when no new base pairs are formed. This large effect was especially surprising, as binding of S is essentially unaffected for S analogues that do not form additional base pairs with the IGS extension. Analysis of a U.U pair immediately 3' to the cleavage site suggests that a previously identified deleterious effect from a dangling U residue on the L-21 ScaI ribozyme arises from a fortuitous active site interaction and has implications for RNA tertiary structure specificity. Comparisons of the affinities of 5'-splice site analogues that form only a subset of base pairs reveal that inclusion of the conserved G.U base pair at the cleavage site of group I introns destabilizes the P1 extension >100-fold relative to the stability of a helix with all Watson-Crick base pairs. Previous structural data with model duplexes and the recent intron structures suggest that this effect can be attributed to partial unstacking of the P1 extension at the G.U step. These results suggest a previously unrecognized role of the G.U wobble pair in self-splicing: breaking cooperativity in base pair formation between P1 and the P1 extensions. This effect may facilitate replacement of the P1 extension with P10 after the first chemical step of self-splicing and release of the ligated exons after the second step of self-splicing.     

Solid phase synthesis of mRNA by the phosphoramidite approach using 2'-O-1-(2-chloroethoxy)ethyl protection and its stability in E. coli system.

The decaoligoribonucleotides containing initiation codon AUG of the phage O beta-A protein mRNA were synthesized on a solid phase by the phosphoramidite approach using 2'-O-1-(2-chloroethoxy)ethyl (Cee) protection. The Cee group is completely stable under the acidic conditions required to remove the 5'-terminal protecting groups in oligoribonucleotide synthesis on a solid support, and yet is easily removable at pH 2.0 for the final unblocking step. Stabilization of the synthetic mRNA to in the cell-free translation system from E. coli A19 was measured. It was found that the oligomers with selected 2'-O-methylation were degraded completely in the translation system.     

The guanosine binding mechanism of the Tetrahymena group I intron.

The Tetrahymena group I intron catalyzes self-splicing through two consecutive transesterification reactions, using a single guanosine-binding site (GBS). In this study, we constructed a model RNA that contains the GBS and a conserved guanosine nucleotide at the 3'-terminus of the intron (omegaG). We determined by NMR the solution structure of this model RNA, and revealed the guanosine binding mechanism of the group I intron. The G22 residue, corresponding to omegaG, participates in a base triple, G22 xx G3 x C12, hydrogen-bonding to the major groove edge of the Watson-Crick G3 x C12 pair. The G22 residue also interacts with A2, which is semi-conserved in all sequenced group I introns.     

Configuration of wobble base pairs having pyrimidines as anticodon wobble bases: significance for codon degeneracy

Degeneracy of the genetic code was attributed by Crick to imprecise hydrogen-bonded base-pairing at the wobble position during codon–anticodon pairing. The Crick wobble rules define but do not explain the RNA base pair combinations allowed at this position. We select six pyrimidine bases functioning as anticodon wobble bases (AWBs) to study their H-bonded pairing properties with the four major RNA bases using density functional theory at the B3LYP/6-31G(d,p) level. This is done to assess the extent to which the configuration of a solitary RNA wobble base pair may in itself determine specificity and degeneracy of the genetic code by allowing or disallowing the given base pair during codon–anticodon pairing. Calculated values of select configuration markers for the base pairs screen well between allowed and disallowed base pairs for most cases examined here, where the base pair width emerges as an important factor. A few allowed wobble pairs invoke the involvement of RNA nucleoside conformation, as well as involvement of the exocyclic substituent in H-bonding. This study, however, cannot explain the disallowed status of the Ura?Gua wobble pair on the basis of configuration alone. Explanation of the allowed status of the V?Ura pair requires further study on the mediatory role of water molecules. Apart from these two cases, these computational results are sufficient, on the basis of base pair configuration alone, to account for the specificity and degeneracy of the genetic code for all known cases of codon–anticodon pairing which involve the pyrimidine AWBs studied here.     

Thermodynamics and kinetics for base-pair opening in the P1 duplex of the Tetrahymena group I ribozyme

The thermodynamics and kinetics for base-pair opening of the P1 duplex of the Tetrahymena group I ribozyme were studied by NMR hydrogen exchange experiments. The apparent equilibrium constants for base pair opening were measured for most of the imino protons in the P1 duplex using the base catalysts NH3, HPO4(2-) or TRIS. These equilibrium constants were also measured for several modified P1 duplexes, and the C-2.G23 base pair was the most stable base pair in all the duplexes. The conserved U-1*G22 base pair is required for activity of the ribozyme and the data here show that this wobble base pair destabilizes neighboring base pairs on only one side of the wobble. A 2'-OMe modification on the U-3 residue stabilized its own base pair but had little effect on the neighboring base pairs. Three base pairs, U-1*G22, C-2*G23 and A2*U21 showed unusual equilibrium constants for opening and possible implications of the opening thermodynamics of these base pairs on the undocking rates of the P1 helix with catalytic core are discussed.