Identification of phosphate groups important to self-splicing of the Tetrahymena rRNA intron as determined by phosphorothioate substitution

Snapshots of the second-step self-splicing of Tetrahymena ribozyme revealed by cryo-EM

Group I introns are catalytic RNAs that coordinate two consecutive transesterification reactions for self-splicing. To understand how the group I intron promotes catalysis and coordinates self-splicing reactions, we determine the structures of L-16 Tetrahymena ribozyme in complex with a 5'-splice site analog product and a 3'-splice site analog substrate using cryo-EM. We solve six conformations from a single specimen, corresponding to different splicing intermediates after the first ester-transfer reaction. The structures reveal dynamics during self-splicing, including large conformational changes of the internal guide sequence and the J5/4 junction as well as subtle rearrangements of active-site metals and the hydrogen bond formed between the 2'-OH group of A261 and the N2 group of guanosine substrate. These results help complete a detailed structural and mechanistic view of this paradigmatic group I intron undergoing the second step of self-splicing.

Exploring purine N7 interactions via atomic mutagenesis: the group I ribozyme as a case study

Atomic mutagenesis has emerged as a powerful tool to unravel specific interactions in complex RNA molecules. An early extensive study of analogs of the exogenous guanosine nucleophile in group I intron self-splicing by Bass and Cech demonstrated structure-function relationships analogous to those seen for protein ligands and provided strong evidence for a well-formed substrate binding site made of RNA. Subsequent functional and structural studies have confirmed these interacting sites and extended our understanding of them, with one notable exception. Whereas 7-methyl guanosine did not affect reactivity in the original study, a subsequent study revealed a deleterious effect of the seemingly more conservative 7-deaza substitution. Here we investigate this paradox, studying these and other analogs with the more thoroughly characterized ribozyme derived from the Tetrahymena group I intron. We found that the 7-deaza substitution lowers binding by ~20-fold, relative to the cognate exogenous guanosine nucleophile, whereas binding and reaction with 7-methyl and 8-aza-7-deaza substitutions have no effect. These and additional results suggest that there is no functionally important contact between the N7 atom of the exogenous guanosine and the ribozyme. Rather, they are consistent with indirect effects introduced by the N7 substitution on stacking interactions and/or solvation that are important for binding. The set of analogs used herein should be valuable in deciphering nucleic acid interactions and how they change through reaction cycles for other RNAs and RNA/protein complexes.

Multiple metal-binding cores are required for metalloregulation by M-box riboswitch RNAs

Riboswitches are regulatory RNAs that control downstream gene expression in response to direct association with intracellular metabolites or metals. Typically, riboswitch aptamer domains bind to a single small-molecule metabolite. In contrast, an X-ray crystallographic structural model for the M-box riboswitch aptamer revealed the absence of an organic metabolite ligand but the presence of at least six tightly associated magnesiums. This observation agrees well with the proposed role of the M-box riboswitch in functioning as a sensor of intracellular magnesium, although additional nonspecific metal interactions are also undoubtedly required for these purposes. To gain greater functional insight into the metalloregulatory capabilities of M-box RNAs, we sought to determine whether all or a subset of the RNA-chelated magnesium ions were required for riboswitch function. To accomplish this task, each magnesium-binding site was simultaneously yet individually perturbed through random incorporation of phosphorothioate nucleotide analogues, and RNA molecules were investigated for their ability to fold in varying levels of magnesium. These data revealed that all of the magnesium ions observed in the structural model are important for magnesium-dependent tertiary structure formation. Additionally, these functional data revealed a new core of potential metal-binding sites that are likely to assist formation of key tertiary interactions and were previously unobserved in the structural model. It is clear from these data that M-box RNAs require specific binding of a network of metal ions for partial fulfillment of their metalloregulatory functions.

Mapping of the functional phosphate groups in the catalytic core of deoxyribozyme 10-23

The RNA phosphodiester bond cleavage activity of a series of 16 thio-deoxyribozymes 10-23, containing a P-stereorandom single phosphorothioate linkage in predetermined positions of the catalytic core from P1 to P16, was evaluated under single-turnover conditions in the presence of either 3 mM Mg(2+) or 3 mM Mn(2+). A metal-specificity switch approach permitted the identification of nonbridging phosphate oxygens (proR(P) or proS(P)) located at seven positions of the core (P2, P4 and P9-13) involved in direct coordination with a divalent metal ion(s). By contrast, phosphorothioates at positions P3, P6, P7 and P14-16 displayed no functional relevance in the deoxyribozyme-mediated catalysis. Interestingly, phosphorothioate modifications at positions P1 or P8 enhanced the catalytic efficiency of the enzyme. Among the tested deoxyribozymes, thio-substitution at position P5 had the largest deleterious effect on the catalytic rate in the presence of Mg(2+), and this was reversed in the presence of Mn(2+). Further experiments with thio-deoxyribozymes of stereodefined P-chirality suggested direct involvement of both oxygens of the P5 phosphate and the proR(P) oxygen at P9 in the metal ion coordination. In addition, it was found that the oxygen atom at C6 of G(6) contributes to metal ion binding and that this interaction is essential for 10-23 deoxyribozyme catalytic activity.

Backbone and nucleobase contacts to glucosamine-6-phosphate in the glmS ribozyme

The glmS ribozyme resides in the 5' untranslated region of glmS mRNA and functions as a catalytic riboswitch that regulates amino sugar metabolism in certain Gram-positive bacteria. The ribozyme catalyzes self-cleavage of the mRNA and ultimately inhibits gene expression in response to binding of glucosamine-6-phosphate (GlcN6P), the metabolic product of the GlmS protein. We have used nucleotide analog interference mapping (NAIM) and suppression (NAIS) to investigate backbone and nucleobase functional groups essential for ligand-dependent ribozyme function. NAIM using GlcN6P as ligand identified requisite structural features and potential sites of ligand and/or metal ion interaction, whereas NAIS using glucosamine as ligand analog revealed those sites that orchestrate recognition of ligand phosphate. These studies demonstrate that the ligand-binding site lies in close proximity to the cleavage site in an emerging model of ribozyme structure that supports a role for ligand within the catalytic core.

Artificial modules for enhancing rate constants of a Group I intron ribozyme without a P4-P6 core element

In this paper we report newly selected artificial modules that enhance the kcat values comparable with or higher than those of the wild-type ribozyme with broad substrate specificity. The elements required for the catalysis of Group I intron ribozymes are concentrated in the P3-P7 domain of their core region, which consists of two conserved helical domains, P4-P6 and P3-P7. Previously, we reported the in vitro selection of artificial modules residing at the peripheral region of a mutant Group I ribozyme lacking P4-P6. We found that derivatives of the ribozyme containing the modules performed the reversal of the first step of the self-splicing reaction efficiently by using their affinity to the substrate RNA, although their kcat values and substrate specificity were uninfluenced and limited, respectively. The results show that it is possible to add a variety of new domains at the peripheral region that play a role comparable with that of the conserved P4-P6 domain.

2'-mercaptonucleotide interference reveals regions of close packing within folded RNA molecules

The 2'-hydroxyl group makes essential contributions to RNA structure and function. As an approach to assess the ability of a mercapto group to serve as a functional analogue for the 2'-hydroxyl group, we synthesized 2'-mercaptonucleotides for use in nucleotide analogue interference mapping. To correlate the observed interference effects with tertiary structure, we used the independently folding DeltaC209 P4-P6 domain from the Tetrahymena group I intron. We generated populations of DeltaC209 P4-P6 molecules containing 2'-mercaptonucleotides located randomly throughout the domain and separated the folded molecules from the unfolded molecules by nondenaturing gel electrophoresis. Iodine-induced cleavage of the RNA molecules revealed the sites at which 2'-mercaptonucleotides interfere with folding. These interferences cluster in the most densely packed regions of the tertiary structure, occurring only at sites that lack the space and flexibility to accommodate a sulfur atom. Interference mapping with 2'-mercaptonucleotides therefore provides a method by which to identify structurally rigid and densely packed regions within folded RNA molecules.

Modular engineering of a Group I intron ribozyme

All Group I intron ribozymes contain a conserved core region consisting of two helical domains, P4-P6 and P3-P7. Recent studies have demonstrated that the elements required for catalysis are concentrated in the P3-P7 domain. We carried out in vitro selection experiments by using three newly constructed libraries on a variant of the T4 td Group I ribozyme containing only a P3-P7 domain in its core. Selected variants with new peripheral elements at L7.1, L8 or L9 after nine cycles efficiently catalyzed the reversal reaction of the first step of self-splicing. The variants from this selection contained a short sequence complementary to the substrate RNA without exception. The most active variant, which was 3-fold more active than the parental wild-type ribozyme, was developed from the second selection by employing a clone from the first selection. The results show that the P3-P7 domain can stand as an independent catalytic module to which a variety of new domains for enhancing the activity of the ribozyme can be added.

Relationship between the self-splicing activity and the solidity of the master domain of the Tetrahymena group I ribozyme

The highly conserved P3-P7 domain of the Group I intron ribozymes is known to contain essential elements, such as the binding site for the cofactor guanosine, required for conducting the splicing reaction. We investigated the domain of the Tetrahymena intron ribozyme and its variants in order to clarify the relationship between its stability and function. We found that the destabilization of the P3-P7 domain facilitates the active structure formation at high magnesium ion concentrations where the formation is retarded for the wild type. The destabilized domain also increases K(GTP)(m) although this can be compensated by increasing the concentration of Mg(2+), indicating that the stable domain is required for establishing a tight guanosine binding site. The results suggest that the stability of the domain affects the rate-limiting step in the RNA folding pathway and also regulates the efficiency of the splicing reaction.

Conserved base-pairings between C266-A268 and U307-G309 in the P7 of the Tetrahymena ribozyme is nonessential for the in vitro self-splicing reaction

P7 is highly conserved in Group I self-splicing intron ribozymes. This region is known to coordinate metal ions and bind a cofactor guanosine required for the self-splicing. To further investigate the fundamental role of the corresponding region in the Tetrahymena ribozyme, we attempted to identify minimal requirements for the base-paired region excluding the guanosine binding site. We discovered that a variety of sequences are eligible and its derivatives possessing extra nucleotide(s) can still conduct the first step of splicing, indicating that no particular base-pairing is essential in this region for conducting the reaction in vitro. The results provide two hypotheses for the fundamental role of this region: (i) if the region contains element(s) that are strictly required in the catalysis, they are not necessarily tightly fixed in the ribozyme and (ii) if not, its fundamental role may simply be to coordinate neighboring regions that are directly involved in the catalysis.

Self-splicing of the Tetrahymena group I ribozyme without conserved base-triples

BACKGROUND

Group I introns share a conserved core region consisting of two domains, P8-P3-P7 and P4-P6, joined by four base-triples. We showed previously that the T4 td intron can perform phosphoester transfer reactions at two splice sites in the absence of both P4-P6 and the conserved base-triples, whereas it is barely able to perform the intact splicing reaction due to the difficulty of conducting the sequential reactions.

RESULTS

Based on previous findings, we constructed a bimolecular ribozyme lacking a large portion of P4-P6 and the base-triples from the Tetrahymena intron, on the assumption that the long-range interactions of the peripheral regions in the two RNAs can compensate for the deteriorated core. The bimolecular ribozyme performed the intact splicing reaction.

CONCLUSION

The present analysis indicates that the base-triples are nonessential, but that L4 and the distal part of P4 in P4-P6 are important for conducting the splicing reaction. The reconstituted self-splicing ribozyme provides an amenable system for analysing the role(s) of elements in the core region in the self-splicing reaction mechanism.

Magnesium ions mediate contacts between phosphoryl oxygens at positions 2122 and 2176 of the 23S rRNA and ribosomal protein L1

The complex of ribosomal protein L1 with 23S rRNA from Escherichia coli is of great interest because of the unique structural and functional aspects of this ribonucleoprotein domain. We have minimized the binding site for protein L1 on the 23S rRNA to nt 2120-2129, 2159-2162, and 2167-2178. This RNA fragment consists of two helices as well as an interconnecting loop of unknown structure. RNA molecules corresponding to the minimized L1 binding site, in which G, A, U, or C were individually replaced by their deoxyribo- (dN) or alpha-thio- (rNaS) analogs have been synthesized by T7 transcription in vitro and analyzed for their ability to bind protein L1. It has been demonstrated that the substitution of rNaS at position 2122 or 2176 decreases the affinity of the RNA for the protein in the presence of magnesium five- to tenfold, whereas the same changes have little effect on binding in the presence of manganese. This suggests that Rp oxygens in the phosphates preceding positions 2122 and 2176 are coordinated with Mg2+ and may participate in L1-23S rRNA interaction via magnesium bridges. We have also shown that this interaction is impaired by the presence of dC at position 2122 coupled with the presence of deoxyribonucleotide(s) at other positions in the RNA. This study demonstrates that the ribose-phosphate backbone of the helix encompassing nt 2120-2124/2174-2178 is intimately involved in the interaction of protein L1 with the 23S rRNA. In particular, we suggest that this helix is positioned in the cleft between the two domains of protein L1.

Ribozyme chemogenetics

In this review I will outline several chemogenetic approaches used to determine the chemical basis of large ribozyme function and structure. The term chemogenetics was first used to describe site-specific functional group modification experiments in the analysis of DNA-protein interactions. Within the past few years equivalent experiments have been performed on large catalytic RNAs using both single-site substitution and interference mapping techniques with nucleotide analogues. While functional group mutagenesis is an important aspect of a chemogenetic approach, chemical correlates to genetic revertants and suppressors must also be realized for the genetic analogy to be intellectually valid and experimentally useful. Several examples of functional group revertants and suppressors have now been obtained within the Tetrahymena group I ribozyme. These experiments define an ensemble of tertiary hydrogen bonds that have made it possible to construct a detailed model of the ribozyme catalytic core. The model includes a functionally important monovalent metal ion binding site, a wobble-wobble receptor motif for helix-helix packing interactions, and a minor groove triple helix.

Characterization of P8 and J8/7 elements in the conserved core of the tetrahymena group I intron ribozyme

The universally conserved core region in the group I intron ribozymes is responsible for its catalytic activity. The structural elements in this region have been known to organize the active site of this class of ribozymes. However, it has been unclear whether all elements are requisite or some elements are dispensable for conducting the catalysis. To investigate the necessity of these elements in the catalysis, we prepared and examined a series of mutants having a nick or deletion in these elements. In this report, we show that two elements, P8 and 5' portion of J8/7, are nonessential for activity.

Modified oligonucleotides: synthesis and strategy for users

Synthetic oligonucleotide analogs have greatly aided our understanding of several biochemical processes. Efficient solid-phase and enzyme-assisted synthetic methods and the availability of modified base analogs have added to the utility of such oligonucleotides. In this review, we discuss the applications of synthetic oligonucleotides that contain backbone, base, and sugar modifications to investigate the mechanism and stereochemical aspects of biochemical reactions. We also discuss interference mapping of nucleic acid-protein interactions; spectroscopic analysis of biochemical reactions and nucleic acid structures; and nucleic acid cross-linking studies. The automation of oligonucleotide synthesis, the development of versatile phosphoramidite reagents, and efficient scale-up have expanded the application of modified oligonucleotides to diverse areas of fundamental and applied biological research. Numerous reports have covered oligonucleotides for which modifications have been made of the phosphodiester backbone, of the purine and pyrimidine heterocyclic bases, and of the sugar moiety; these modifications serve as structural and mechanistic probes. In this chapter, we review the range, scope, and practical utility of such chemically modified oligonucleotides. Because of space limitations, we discuss only those oligonucleotides that contain phosphate and phosphate analogs as internucleotidic linkages.

Identification of phosphate groups involved in metal binding and tertiary interactions in the core of the Neurospora VS ribozyme

We have used ethylation protection experiments and modification interference using phosphorothioate nucleosides to identify phosphate groups involved in the magnesium-dependent tertiary structure and function of the VS ribozyme, a small, self-cleaving RNA. Phosphorothioate interference-rescue experiments in the presence of the thiophilic manganese ion implicate four phosphate groups in direct metal ion binding. Phosphorothioate substitution also creates a new manganese binding site that increases the cis cleavage rate of the ribozyme, possibly by disrupting an inhibitory structure. Interpreting these data in the context of a recently developed structural model shows that almost all of the important phosphate groups are located in the central core of the ribozyme. The model suggests roles for certain phosphate groups in particular steps of RNA folding and identifies a candidate region for the active site of the ribozyme.

Explanation by a putative triester-like mechanism for the thio effects and Mn2+ rescues in reactions catalyzed by a hammerhead ribozyme

Divalent metal ion-dependent hammerhead ribozymes can cleave any RNA with a NUX triplet, wherein the N can be any residue and X can be C, U or A. In recent literature on the mechanism of action of hammerhead ribozymes, one important role of divalent metal ions is generally suggested to be an electrophilic catalyst by directly coordinating with the pro-Rp oxygen of the scissile phosphate to stabilize the transition state. This proposal was made on the basis of thio effects and the proposed electrophilic catalyst is very attractive as an explanation for the catalytic activity of metalloenzymes. Reexamination of thio effects with substrates having a GUA triplet at the cleavage site shows that, in agreement with the previous finding, the cleavage rate, in the presence of Mg2+ ions, is significantly reduced in the case of the phosphorothioate substrate (RpS), wherein the pro-Rp oxygen at the scissile phosphate is replaced by sulfur, while the cleavage rate is reduced to a much lesser extent for the other isomer (SpS), wherein the pro-Sp oxygen at the scissile phosphate is replaced by sulfur. However, more careful examination of the rescue ability of Mn2+ ions with these isomers demonstrates that more thiophilic Mn2+ ions rescue the reaction not only with the RpS isomer but also with the SpS isomer and, importantly, to a greater extent for the SpS isomer. These results argue against the previous conclusion that a metal ion is directly coordinating with the pro-Rp oxygen of the scissile phosphate to stabilize the transition state. In this paper we try to elucidate the possible origin of the thio effects and propose a 'triester-like' mechanism in reactions catalyzed by hammerhead ribozymes.

The chemical basis of adenosine conservation throughout the Tetrahymena ribozyme

Adenosines are present at a disproportionately high frequency within several RNA structural motifs. To explore the importance of individual adenosine functional groups for group I intron activity, we performed Nucleotide Analog Interference Mapping (NAIM) with a collection of adenosine analogues. This paper reports the synthesis, transcriptional incorporation, and the observed interference pattern throughout the Tetrahymena group I intron for eight adenosine derivatives tagged with an alpha-phosphorothioate linkage for use in NAIM. All of the analogues were accurately incorporated into the transcript as an A. The sites that interfere with the 3'-exon ligation reaction of the Tetrahymena intron are coincident with the sites of phylogenetic conservation, yet the interference patterns for each analogue are different. These interference data provide several biochemical constraints that improve our understanding of the Tetrahymena ribozyme structure. For example, the data support an essential A-platform within the J6/6a region, major groove packing of the P3 and P7 helices, minor groove packing of the P3 and J4/5 helices, and an axial model for binding of the guanosine cofactor. The data also identify several essential functional groups within a highly conserved single-stranded region in the core of the intron (J8/7). At four sites in the intron, interference was observed with 2'-fluoro A, but not with 2'-deoxy A. Based upon comparison with the P4-P6 crystal structure, this may provide a biochemical signature for nucleotide positions where the ribose sugar adopts an essential C2'-endo conformation. In other cases where there is interference with 2'-deoxy A, the presence or absence of 2'-fluoro A interference helps to establish whether the 2'-OH acts as a hydrogen bond donor or acceptor. Mapping of the Tetrahymena intron establishes a basis set of information that will allow these reagents to be used with confidence in systems that are less well understood.

In vitro selection for altered divalent metal specificity in the RNase P RNA

The ribozyme RNase P absolutely requires divalent metal ions for catalytic function. Multiple Mg2+ ions contribute to the optimal catalytic efficiency of RNase P, and it is likely that the tertiary structure of the ribozyme forms a specific metal-binding pocket for these ions within the active-site. To identify base moieties that contribute to catalytic metal-binding sites, we have used in vitro selection to isolate variants of the Escherichia coli RNase P RNA with altered specificities for divalent metal. RNase P RNA variants with increased activity in Ca2+ were enriched over 18 generations of selection for catalysis in the presence of Ca2+, which is normally disfavored relative to Mg2+. Although a wide spectrum of mutations was found in the generation-18 clones, only a single point mutation was common to all clones: a cytosine-to-uracil transition at position 70 (E. coli numbering) of RNase P. Analysis of the C70U point mutant in a wild-type background confirmed that the identity of the base at position 70 is the sole determinant of Ca2+ selectivity. It is noteworthy that C70 lies within the phylogenetically well conserved J3/4-P4-J2/4 region, previously implicated in Mg2+ binding. Our finding that a single base change is sufficient to alter the metal preference of RNase P is further evidence that the J3/4-P4-J2/4 domain forms a portion of the ribozyme's active site.

Single substitutions of phosphorothioates in the HDV ribozyme G73 define regions necessary for optimal self-cleaving activity

Phosphorothioate (NTPalphaS) analogues were incorporated into the HDV genomic ribozyme by transcription with T7 polymerase. The introduction of a sulfur in place of the pro-Rp oxygen at the phosphate 5'to positions A64, A63, A43, U27, G62, C61, C44, C41, C22and C21appeared to inhibit self-cleavage activity of the G73 genomic ribozyme. Except for position C22, elevated levels of Mg2+rescued the reaction to various extents. When the sites were identified in the RNA sequence, they were clustered in three distinct regions that, in the secondary structure models, are predicted to be primarily single-stranded. Two of these regions have been proposed to form extensive interactions that are thought to involve a homopurine base pair. The third region is thought to be directly associated with assembly of the cleavage site.

Identification of specific Rp-phosphate oxygens in the tRNA anticodon loop required for ribosomal P-site binding

tRNA binding to the ribosomal P site is dependent not only on correct codon-anticodon interaction but also involves identification of structural elements of tRNA by the ribosome. By using a phosphorothioate substitution-interference approach, we identified specific nonbridging Rp-phosphate oxygens in the anticodon loop of tRNA(Phe) from Escherichia coli which are required for P-site binding. Stereospecific involvement of phosphate oxygens at these positions was confirmed by using synthetic anticodon arm analogues at which single Rp- or Sp-phosphorothioates were incorporated. Identical interference results with yeast tRNA(Phe) and E. coli tRNA(fMet) indicate a common backbone conformation or common recognition elements in the anticodon loop of tRNAs. N-ethyl-N-nitrosourea modification-interference experiments with natural tRNAs point to the importance of the same phosphates in the loop. Guided by the crystal structure of tRNA(Phe), we propose that specific Rp-phosphate oxygens are required for anticodon loop ("U-turn") stabilization or are involved in interactions with the ribosome on correct tRNA-mRNA complex formation.

Defining the chemical groups essential for Tetrahymena group I intron function by nucleotide analog interference mapping

Improved atomic resolution biochemical methods are needed to identify the chemical groups within an RNA that are essential to its activity. As a step toward this goal, we report the use of 5'-O-(1-thio)inosine monophosphate (IMP alphaS) in a nucleotide analog interference mapping (NAIM) assay that makes it possible to simultaneously, yet individually, determine the contribution of almost every N2 exocyclic amine of G within a large RNA. Using IMP alphaS, we identified the exocyclic amines that are essential for 5' or 3' exon ligation by the Tetrahymena group I intron. We report that the amino groups of three phylogenetically conserved guanosines (G111, G112, and G303) are important for 3' exon ligation. The amine of G22, as well as the amines of the other four guanosines within the P1 helix, are essential for ligation of the 5' exon. Previous work has shown that point mutation of either G22 or G303 to an adenosine (A) substantially reduces activity. Like inosine, adenosine lacks an N2 amino group. Interference rescue of the G22A and G303A point mutations was detected at the site of mutation by NAIM using 5'-O-(1-thio)diaminopurine riboside monophosphate (DMP alphaS), an adenosine analog that has an N2 exocyclic amine. The G22A point mutant could also be rescued by incorporation of DMP alphaS at A24. By analogy to genetics, there are interference phenotypes comparable to loss of function, reversion, and suppression. This method can be readily extended to other nucleotide analogs for the analysis of chemical groups essential to a variety of RNA and DNA activities.

Mechanistic aspects of enzymatic catalysis: lessons from comparison of RNA and protein enzymes

A classic approach in biology, both organismal and cellular, is to compare morphologies in order to glean structural and functional commonalities. The comparative approach has also proven valuable on a molecular level. For example, phylogenetic comparisons of RNA sequences have led to determination of conserved secondary and even tertiary structures, and comparisons of protein structures have led to classifications of families of protein folds. Here we take this approach in a mechanistic direction, comparing protein and RNA enzymes. The aim of comparing RNA and protein enzymes is to learn about fundamental physical and chemical principles of biological catalysis. The more recently discovered RNA enzymes, or ribozymes, provide a distinct perspective on long-standing questions of biological catalysis. The differences described in this review have taught us about the aspects of RNA and proteins that are distinct, whereas the common features have helped us to understand the aspects that are fundamental to biological catalysis. This has allowed the framework that was put forth by Jencks for protein catalysts over 20 years ago (1) to be extended to RNA enzymes, generalized, and strengthened.

An RNA conformational change between the two chemical steps of group II self-splicing

As for nuclear pre-mRNA introns, the splicing pathway of group II self-splicing introns proceeds by two successive transesterifications involving substrates with different chemical configurations. These two reactions have been proposed to be catalysed by two active sites, or alternatively by a single active site rearranging its components to accommodate the successive substrates. Here we show that the structural elements specific for the second splicing step are clustered in peripheral structures of domains II and VI. We show that these structures are not required for catalysis of the second chemical step but, instead, take part in a conformational change that occurs between the two catalytic steps. This rearrangement involves the formation of a tertiary contact between part of domain II and a GNRA tetraloop at the tip of domain VI. The fact that domain VI, which carries the branched structure, is involved in this structural rearrangement and the fact that modifications affecting the structures involved have almost no effect when splicing proceeds without branch formation, suggest that the conformational change results in the displacement of the first-step product out of the active site. These observations give further support to the existence of a single active site in group II introns.

The environment of two metal ions surrounding the splice site of a group I intron

Several divalent metal ions (Ca2+, Sr2+ and Pb2+) do not promote splicing, but instead induce cleavage at a single site in the conserved group I intron core in the absence of the guanosine cofactor at elevated pH, generating products with 5'-OH and 3'-phosphate ends. The reaction is competed by Mg2+, which does not cleave at this position, but hydrolyses the splice sites producing 3'-OH and 5'-phosphate ends. Mn2+ promotes both core cleavage and splice site hydrolysis under identical conditions, suggesting that two different metal atoms are involved, each responsible for one type of cleavage, and with different chemical and geometric requirements. Based on the core cleavage position and on the previously proposed coordination sites for Mg2+, we propose a structural location for two metal ions surrounding the splice site in the Michel-Westhof three-dimensional model of the group I intron core. The proposed location was strengthened by a first mutational analysis which supported the suggested interaction between one of the metal ions and the bulged residue in P7.

Identification of phosphate oxygens that are important for self-cleavage activity of the HDV ribozyme by phosphorothioate substitution interference analysis

A phosphorothioate substitution interference assay was used to investigate the role of the pro-Rp oxygens of phosphate groups in the self-cleavage reaction of the genomic human hepatitis delta virus (HDV) ribozyme. Incorporation of several different phosphorothioates (NTP alpha S) into the HDV ribozyme inhibited the self-cleavage activity. Incorporation of uridine 5' phosphorothioate or adenosine 5' phosphorothioate maintained 72% of the original self-cleavage activity whereas incorporation of guanosine 5' phosphorothioate or cytosine 5' phosphorothioate into the precursor reduced self-cleavage activity to about 20% in each case. Using partially substituted phosphorothioate-modified transcripts, we identified the pro-Rp oxygens that are important for the ribozyme activity, and they are located at positions 0, 1, 4, 5, 21, 24, 25, 27, 28, 30-34, 40, 43 and 75. In particular, the pro-Rp oxygens at positions 0, 1 and 21 are appear to be critical for the self-cleavage activity of the HDV ribozyme.

Selection of novel forms of a functional domain within the Tetrahymena ribozyme

P5abc is an RNA structure within the self-splicing Tetrahymena group I intron that provides an activation function to the remainder of the ribozyme, either when present in cis or when added in trans. This 69-nucleotide activator domain was replaced with randomized sequence of 20 or 40 nt in length, and individuals among these pools with sequences that could functionally replace P5abc were selected. The basis of selection was a reaction in which two separate halves of the ribozyme became joined; selection was completed by reverse transcription and the polymerase chain reaction, using primers with sequence from either side of the ligation junction. Selectant sequences fell into three families that appear unrelated to P5abc; for example they lack the A-rich bulge thought to be a important feature of P5abc. Thus, rather than defining some consensus sequence for activator domains, this result reveals a certain tolerance in the ribozyme in its ability to derive activation function from diverse sequence types. In the context of splicing precursor RNA, the new sequences supported self-splicing, but failed to activate a related reaction, hydrolysis of the 3' splice site, implying that this region of the intron can differentially control two related reactions.

In vitro genetic analysis of the hinge region between helical elements P5-P4-P6 and P7-P3-P8 in the sunY group I self-splicing intron

Modeling of the group I intron RNA suggests that its catalytic core is primarily composed of two extended structural elements (stacked helices P5-P4-P6 and P7-P3-P8) whose relative orientation is partially determined by base-triple interactions between paired regions P4 and P6, and single-stranded joining regions J6/7 and J3/4, respectively. In vitro genetic selection was used to isolate functional sequence variants of the proposed triple helical domain of the sunY intron. Comparative sequence analysis of the selected variants provided supporting evidence for the two previously established base-triples between P4 and J6/7 and provided the first experimental evidence for an interaction between P6(1) and J3/4(3). Sequence covariations also indicated that a simple relationship exists between the length of a single-stranded joining region, J3/4, and the identity of a particular base-pair, P4(1). Selected variants based on a core structure with an extra nucleotide inserted in J3/4 revealed two different responses to this structural perturbation: a base-triple interaction and an intrahelical bulged pyrimidine. Chemical modification analysis supported the existence of these alternative structures. The function of this region of the ribozyme can therefore be fulfilled by at least three different structures.

Substrate-assisted catalysis in the cleavage of DNA by the EcoRI and EcoRV restriction enzymes

The crystal structure analyses of the EcoRI-DNA and EcoRV-DNA complexes do not provide clear suggestions as to which amino acid residues are responsible for the activation of water to carry out the DNA cleavage. Based on molecular modeling, we have proposed recently that the attacking water molecule is activated by the negatively charged pro-Rp phosphoryl oxygen of the phosphate group 3' to the scissile phosphodiester bond. We now present experimental evidence to support this proposal. (i) Oligodeoxynucleotide substrates lacking this phosphate group in one strand are cleaved only in the other strand. (ii) Oligodeoxynucleotide substrates carrying an H-phosphonate substitution at this position in both strands and, therefore, lacking a negatively charged oxygen at this position are cleaved at least four orders of magnitude more slowly than the unmodified substrate. These results are supported by other modification studies: oligodeoxynucleotide substrates with a phosphorothioate substitution at this position in both strands are cleaved only if the negatively charged sulfur is in the RP configuration as shown for EcoRI [Koziolkiewicz, M. & Stec, W.J. (1992) Biochemistry 31, 9460-9466] and EcoRV (B. A. Connolly, personal communication). As the phosphate residue 3' to the scissile phosphodiester bond is not needed for strong DNA binding by both enzymes, these findings strongly suggest that this phosphate group plays an active role during catalysis. This proposal, furthermore, gives a straightforward explanation of why in the EcoRI-DNA and EcoRV-DNA complexes the DNA is distorted differently, but in each case the 3' phosphate group closely approaches the phosphate group that is attacked. Finally, an alternative mechanism for DNA cleavage involving two metal ions is unlikely in the light of our finding that both EcoRI and EcoRV need only one Mg2+ per active site for cleavage.

Metal coordination sites that contribute to structure and catalysis in the group I intron from Tetrahymena

We have used nucleoside phosphorothioates (NTP alpha S) and a substitution-interference method to identify phosphate oxygens that appear to be important to guanosine cofactor addition in the self-splicing group I intron from Tetrahymena thermophila. For the majority of these phosphate oxygens, however, the effect of NTP alpha S substitution is significantly reduced in reactions containing the added presence of manganese ion (Mn2+) relative to magnesium ion (Mg2+) alone. The observed "rescue" of the NTP alpha S effect at these positions is thought to be due to the larger affinity of Mn2+ for sulfur. These data suggest the direct coordination of divalent metal ions within the highly conserved catalytic core of the Tetrahymena intron. Because many of these metal binding sites appear to be in positions of close backbone-backbone approach, and adjacent to the guanosine binding site the splice junction, we suggest roles for the corresponding ions in stabilizing tertiary structure and substrate recognition and as participants in catalysis.

Lead cleavage sites in the core structure of group I intron-RNA

Self-splicing of group I introns requires divalent metal ions to promote catalysis as well as for the correct folding of the RNA. Lead cleavage has been used to probe the intron RNA for divalent metal ion binding sites. In the conserved core of the intron, only two sites of Pb2+ cleavage have been detected, which are located close to the substrate binding sites in the junction J8/7 and at the bulged nucleotide in the P7 stem. Both lead cleavages can be inhibited by high concentrations of Mg2+ and Mn2+ ions, suggesting that they displace Pb2+ ions from the binding sites. The RNA is protected from lead cleavage by 2'-deoxyGTP, a competitive inhibitor of splicing. The two major lead induced cleavages are both located in the conserved core of the intron and at phosphates, which had independently been demonstrated to interact with magnesium ions and to be essential for splicing. Thus, we suggest that the conditions required for lead cleavage occur mainly at those sites, where divalent ions bind that are functionally involved in catalysis. We propose lead cleavage analysis of functional RNA to be a useful tool for mapping functional magnesium ion binding sites.

A phosphorothioate at the 3' splice-site inhibits the second splicing step in a group I intron

RNA polymerases can synthesize RNA containing phosphorothioate linkages in which a sulfur replaces one of the nonbridging oxygens. Only the Rp isomer is generated during transcription. A Rp phosphorothioate at the 5' splice-site of the Tetrahymena group I intron does not inhibit splicing (McSwiggen, J.A. and Cech, T.R. (1989) Science 244, 679). Transcription of mutants in which the first base of the 3' exon, U+1, was mutated to C or G, in the presence, respectively, of either cytosine or guanosine thiotriphosphate, introduced a phosphorothioate at the 3' splice-site. In both cases exon ligation was blocked. In the phosphorothioate substituted U+1G mutant, a new 3' splice-site was selected one base downstream of the correct site; despite the fact that the correct site was selected with very high fidelity in unsubstituted RNA. In contrast, the exon ligation reaction was successfully performed in reverse using unsubstituted intron RNA and ligated exons containing an Rp phosphorothioate at the exon junction site. Chirality was reversed during transesterification as in 5' splice-site cleavage (vide supra). This suggests that one non-bridging oxygen is particularly crucial for both splicing reactions.

Analysis of the role of phosphate oxygens in the group I intron from Tetrahymena

We have developed a quantitative substitution interference technique to examine the role of Pro-Rp oxygens in the phosphodiester backbone of RNA, using phosphorothioates as a structural probe. This approach is generally applicable to any reaction involving RNA in which the precursor and reaction products can be separated. We have applied the technique to identity structural requirements in the group I intron from Tetrahymena thermophila for catalysis of hydrolysis at the 3' splice site; 44 phosphate oxygens are important in 3' splice site hydrolysis. These include four or five oxygens previously observed to be important in exon ligation. Although phosphate oxygens having a functional significance can be found throughout the intron, the strongest phosphorothioate effects are closely associated with positions in the highly conserved intron core, which are likely to be involved in tertiary interactions, substrate recognition and catalysis.

Extensive phosphorothioate substitution yields highly active and nuclease-resistant hairpin ribozymes

The catalytic function of the hairpin ribozyme has been investigated by modification-interference analysis of both ribozyme and substrate, using ribonucleoside phosphorothioates. Thiophosphate substitutions in two ribozyme domains were examined by using a novel and highly efficient two-piece ribozyme assembled from two independently synthesized oligoribonucleotides. The catalytic proficiency of the two-piece construct (KM = 48 nM, kcat = 2.3 min-1) is nearly identical to that of the one-piece ribozyme. The two-piece ribozyme is essentially unaffected by substitution with thiophosphates 5' to all guanosines, cytidines, and uridines. In contrast, incorporation of multiple adenosine phosphorothioates in the 5' domain of the ribozyme decreases ribozyme activity by a factor of 25. Modification-interference experiments using ribozymes partially substituted with adenosine phosphorothioate suggest that thiophosphates 5' to A7, A9 and A10 interfere with cleavage to a greater extent than substitutions at other sites within the molecule, but the effect is modest. Within the substrate, phosphorothioate substitution does not directly interfere with cleavage, rather, increasing thiophosphate content decreases the stability of the ribozyme-substrate complex. We describe the construction of a hairpin ribozyme containing dinucleotide extensions at its 5' and 3' ends. Full substitution of this molecule with G and C phosphorothioates results in a ribozyme with greatly enhanced stability against cellular ribonucleases without significant loss of catalytic efficiency.

Phosphorothioate substitution identifies phosphate groups important for pre-mRNA splicing

Substitution of pre-mRNA in vitro splicing substrates with alpha-phosphorothioate ribonucleotide analogs has multiple effects on the processes of spliceosome formation and splicing. A major effect of substitution is on the splicing cleavage/ligation reactions. Substitution at the 5' splice junction blocks the first cleavage/ligation reaction while substitution at the 3' splice junction blocks the second cleavage/ligation reaction. A second effect of phosphorothioate substitution is the inhibition of spliceosome formation. A substitution/interference assay was used to determine positions where substitution inhibits spliceosome formation or splicing. Substitution in the 3' splice site polypyrimidine tract was found to inhibit spliceosome formation and splicing. This effect was enhanced with multiple substitutions in the region. No sites of substitution within the exons were found which affected spliceosome formation or splicing.

RNA structure and NMR spectroscopy

RNA molecules perform a wide variety of biological functions, from enzymic activity to storage and propagation of genetic information.

The rate and specificity of a group I ribozyme are inversely affected by choice of monovalent salt

The fifth intron of the COB gene of yeast mitochondria splices autocatalytically. The rate of splicing is increased by high concentrations of monovalent salts, but the choice of both cation and anion is significant: The smaller the cation in solution, the faster the reaction (the rate in K+ greater than NH4+ greater than Na+ greater than Li+). Chloride, bromide, iodide and acetate salts enhance autocatalytic processing, but sulfate salts do not and fluoride salts are inhibitory. The choice of monovalent salt affects the KM of the intron for guanosine nucleotide, implying an alteration in the affinity of the RNA for that substrate. Under optimal conditions (1M KCl, 50 mM MgCl2) the catalytic efficiency of this intron exceeds that reported for the ribosomal intron from Tetrahymena, but several side reactions occur, including guanosine-addition within the downstream exon. The site of addition resembles the 5' splice junction, but selection of this site does not involve the internal guide sequence of the intron.

Phosphorothioate-containing RNAs show mRNA activity in the prokaryotic translation systems in vitro

Phosphorothioate-containing RNAs were generated by transcription of coliphage T7 DNA using the Sp diastereomers of ribonucleoside 5'-O-(1-thiotriphosphates) and T7 RNA polymerase. RNAs in which a single nucleotide was substituted by the corresponding nucleoside phosphorothioate functioned as mRNA in the cell-free translation systems prepared from Escherichia coli and from an extreme thermophilic bacterium, Thermus thermophilus. This substitution increased the efficiency of protein synthesis by stabilizing the mRNAs in these systems. As the proportion of substituted nucleotides was increased, their mRNA activity was decreased accordingly. As judged from the analysis by SDS-polyacrylamide gel-electrophoresis, the proteins synthesized using phosphorothioate-containing mRNAs as template were identical to those obtained with unsubstituted mRNAs. However, larger proteins which were barely detectable when unsubstituted mRNA was used were well represented when phosphorothioate-RNA was used instead. The advantages in using the phosphorothioate-mRNAs in the in vitro translation systems are discussed.

Modelling of the three-dimensional architecture of group I catalytic introns based on comparative sequence analysis

Alignment of the 87 available sequences of group I self-splicing introns reveals numerous instances of covariation between distant sites. Some of these covariations cannot be ascribed to historical coincidences or the known secondary structure of group I introns, and are, therefore, best explained as reflecting tertiary contacts. With the help of stereochemical modelling, we have taken advantage of these novel interactions to derive a three-dimensional model of the conserved core of group I introns. Two noteworthy features of that model are its extreme compactness and the fact that all of the most evolutionarily conserved residues happen to converge around the two helices that constitute the substrate of the core ribozyme and the site that binds the guanosine cofactor necessary for self-splicing. Specific functional implications are discussed, both with regard to the way the substrate helices are recognized by the core and possible rearrangements of the introns during the self-splicing process. Concerning potential long-range interactions, emphasis is put on the possible recognition of two consecutive purines in the minor groove of a helix by a GAAA or related terminal loop.

Thiophosphate interference experiments locate phosphates important for the hammerhead RNA self-cleavage reaction

A hammerhead domain of less than 50 nucleotides is responsible for a self-cleavage reaction in the replication of plant RNA pathogens. The hammerhead is composed of three helices joining at a central conserved core of 11 single stranded nucleotides. The core is believed to fold into a tertiary structure that provides functional groups for catalysis and to coordinate one or more divalent metal ions. In this study we use a phosphorothioate substitution interference assay to identify four phosphates in the conserved core which also play a role in the self-cleavage reaction.

Identification of a non-junction phosphodiester that influences an autolytic processing reaction of RNA

Oligoribonucleotides with specific sequences derived from the satellite RNA of tobacco ringspot virus undergo autolytic cleavage at the CpA phosphodiester that is the junction between unit sequences of multimeric satellite RNA. Buzayan et al. (Nucleic Acids Res., 16, 4009-4023 (1988)) showed that an oligoribonucleotide with 97 satellite RNA-derived nucleotide residues self-cleaved with greatly reduced efficiency when it was synthesized in vitro from adenosine-5'-O-(1-thiotriphosphate) (abbreviated rATP alpha S) and three rNTPs. No other substitution of one rNTP by the corresponding rNTP alpha S had this effect, suggesting that a phosphorothioate CpA junction inhibits self-cleavage. Here, we replaced the usual CpA junction of a small self-cleaving oligoribonucleotide with a CpU junction. Self-cleavage of this molecule was reduced not only by rUTP alpha S-substitution, as expected, but also by partial and complete rATP alpha S-substitution. By analysis of the locations of rAMPS residues in cleavage products derived from partially rATP alpha S-substituted oligoribonucleotides, we identified A26 as the residue contributing the non-junction phosphorothioate diester that most strongly inhibited self-cleavage. Manganese ions strongly stimulated the self-cleavage of the rATP alpha S-substituted, CpU-junction oligoribonucleotide but was less effective when the junction was CpA.

Base pairing between the 3' exon and an internal guide sequence increases 3' splice site specificity in the Tetrahymena self-splicing rRNA intron

It has been proposed that recognition of the 3' splice site in many group I introns involves base pairing between the start of the 3' exon and a region of the intron known as the internal guide sequence (R. W. Davies, R. B. Waring, J. Ray, T. A. Brown, and C. Scazzocchio, Nature [London] 300:719-724, 1982). We have examined this hypothesis, using the self-splicing rRNA intron from Tetrahymena thermophila. Mutations in the 3' exon that weaken this proposed pairing increased use of a downstream cryptic 3' splice site. Compensatory mutations in the guide sequence that restore this pairing resulted in even stronger selection of the normal 3' splice site. These changes in 3' splice site usage were more pronounced in the background of a mutation (414A) which resulted in an adenine instead of a guanine being the last base of the intron. These results show that the proposed pairing (P10) plays an important role in ensuring that cryptic 3' splice sites are selected against. Surprisingly, the 414A mutation alone did not result in activation of the cryptic 3' splice site.

Base pairing between the 3' exon and an internal guide sequence increases 3' splice site specificity in the Tetrahymena self-splicing rRNA intron

It has been proposed that recognition of the 3' splice site in many group I introns involves base pairing between the start of the 3' exon and a region of the intron known as the internal guide sequence (R. W. Davies, R. B. Waring, J. Ray, T. A. Brown, and C. Scazzocchio, Nature [London] 300:719-724, 1982). We have examined this hypothesis, using the self-splicing rRNA intron from Tetrahymena thermophila. Mutations in the 3' exon that weaken this proposed pairing increased use of a downstream cryptic 3' splice site. Compensatory mutations in the guide sequence that restore this pairing resulted in even stronger selection of the normal 3' splice site. These changes in 3' splice site usage were more pronounced in the background of a mutation (414A) which resulted in an adenine instead of a guanine being the last base of the intron. These results show that the proposed pairing (P10) plays an important role in ensuring that cryptic 3' splice sites are selected against. Surprisingly, the 414A mutation alone did not result in activation of the cryptic 3' splice site.