Group I Ribozymes: Substrate Recognition, Catalytic Strategies, and Comparative Mechanistic Analysis. In: Eckstein F, Lilley DMJ, editors. Catalytic RNA. Berlin: Springer Berlin Heidelberg; 1996. pp. 1-17. [DOI: 10.1007/978-3-642-61202-2_1]

Integrated evolution of ribosomal RNAs, introns, and intron nurseries

The initial components of ribosomes first appeared more than 3.8 billion years ago during a time when many types of RNAs were evolving. While modern ribosomes are complex molecular machines consisting of rRNAs and proteins, they were assembled during early evolution by the association and joining of small functional RNA units. Introns may have provided the means to ligate many of these pieces together. All four classes of introns (group I, group II, spliceosomal, and archaeal) are present in many rRNA gene loci over a broad phylogenetic range. A survey of rRNA intron sequences across the three major life domains suggests that some of the classes of introns may have diverged from one another within rRNA gene loci. Analyses of rRNA sequences revealed self-splicing group I and group II introns are present in ancestral regions of the SSU (small subunit) and LSU (large subunit), whereas spliceosomal and archaeal introns appeared in sections of the rRNA that evolved later. Most classes of introns increased in number for approximately 1 billion years. However, their frequencies are low in the most recently evolved regions added to the SSU and LSU rRNAs. Furthermore, many of the introns appear to have been in the same locations for billions of years, suggesting an ancient origin for these sequences. In this Perspectives paper, I reviewed and analyzed rRNA intron sequences, locations, structural characteristics, and splicing mechanisms; and suggest that rRNA gene loci may have served as evolutionary nurseries for intron formation and diversification.

A kinetic and thermodynamic framework for the Azoarcus group I ribozyme reaction

Determination of quantitative thermodynamic and kinetic frameworks for ribozymes derived from the Azoarcus group I intron and comparisons to their well-studied analogs from the Tetrahymena group I intron reveal similarities and differences between these RNAs. The guanosine (G) substrate binds to the Azoarcus and Tetrahymena ribozymes with similar equilibrium binding constants and similar very slow association rate constants. These and additional literature observations support a model in which the free ribozyme is not conformationally competent to bind G and in which the probability of assuming the binding-competent state is determined by tertiary interactions of peripheral elements. As proposed previously, the slow binding of guanosine may play a role in the specificity of group I intron self-splicing, and slow binding may be used analogously in other biological processes. The internal equilibrium between ribozyme-bound substrates and products is similar for these ribozymes, but the Azoarcus ribozyme does not display the coupling in the binding of substrates that is observed with the Tetrahymena ribozyme, suggesting that local preorganization of the active site and rearrangements within the active site upon substrate binding are different for these ribozymes. Our results also confirm the much greater tertiary binding energy of the 5'-splice site analog with the Azoarcus ribozyme, binding energy that presumably compensates for the fewer base-pairing interactions to allow the 5'-exon intermediate in self splicing to remain bound subsequent to 5'-exon cleavage and prior to exon ligation. Most generally, these frameworks provide a foundation for design and interpretation of experiments investigating fundamental properties of these and other structured RNAs.

Splicing and evolution of an unusually small group I intron

Introns are common in the rRNA gene loci of fungal genomes, but biochemical studies to investigate splicing are rare. Here, self-splicing of a very small (67 nucleotide) group I intron is demonstrated. The PaSSU intron (located within the rRNA small subunit gene of Phialophora americana) splices in vitro under group I intron conditions. Most group I ribozymes contain pairing regions P1-P10, with a conserved G.U pair at the 5' splice site, and a G at the 3' intron border. The PaSSU intron contains only P1, P7, and P10. While it contains the G.U pair at the 5' splice, a U is found at the 3' end of the intron instead of a G. Phylogenetic analysis places it within subgroup IC1, whose members are found in the nuclear rRNA genes of fungi. The structural elements are similar to those in the centermost regions of other group I introns. Its size can be explained by a single large deletion that removed P2 through much of P9. Part of the original P9 region has assumed the function of P7. Its small size and genealogy makes it an excellent model to study RNA catalysis and evolution.

Structure-function relationships in RNA and RNP enzymes: recent advances

The structural biology of ribozymes and ribonucleoprotein (RNP) enzymes is now sufficiently advanced that a true dialogue between structural and functional studies is possible. In this review, we consider three important systems in which an integration of structural and biochemical data has recently led to major advances in mechanistic understanding. In the hammerhead ribozyme, application-driven biochemical studies led to the discovery of a key structural interaction that had been omitted from previously-studied constructs. A new crystal structure of the resulting, tertiary-stabilized hammerhead has resolved a remarkable number of longstanding paradoxes in the structure-function relationship of this ribozyme. In the Group I intron ribozyme, a flurry of high-resolution structures has largely confirmed, but in some cases refined or challenged, a detailed model of a metalloenzyme active site that had previously been derived by meticulous quantitative metal ion rescue experiments. Finally, for the peptidyl transferase center of the ribosome, recent biochemical and chemical results motivated by the pioneering crystal structures have suggested a picture of a catalytic mechanism dominated by proximity and orientation effects and substrate-assisted catalysis. These results refocus attention on catalysis as a property of the integrated RNP machinery as a whole, as opposed to a narrow concern with the RNA functional groups in immediate contact with the reactive center.

Unusual metal specificity and structure of the group I ribozyme from Chlamydomonas reinhardtii 23S rRNA

Group I intron ribozymes require cations for folding and catalysis, and the current literature indicates that a number of cations can promote folding, but only Mg2+ and Mn2+ support both processes. However, some group I introns are active only with Mg2+, e.g. three of the five group I introns in Chlamydomonas reinhardtii. We have investigated one of these ribozymes, an intron from the 23S LSU rRNA gene of Chlamydomonas reinhardtii (Cr.LSU), by determining if the inhibition by Mn2+ involves catalysis, folding, or both. Kinetic analysis of guanosine-dependent cleavage by a Cr.LSU ribozyme, 23S.5 Delta Gb, that lacks the 3' exon and intron-terminal G shows that Mn2+ does not affect guanosine binding or catalysis, but instead promotes misfolding of the ribozyme. Surprisingly, ribozyme misfolding induced by Mn2+ is highly cooperative, with a Hill coefficient larger than that of native folding induced by Mg2+. At lower Mn2+ concentrations, metal inhibition is largely alleviated by the guanosine cosubstrate (GMP). The concentration dependence of guanosine cosubstrate-induced folding suggests that it functions by interacting with the G binding site, perhaps by displacing an inhibitory Mn2+. Because of these and other properties of Cr.LSU, the tertiary structure of the intron from 23S.5 Delta Gb was examined using Fe2+-EDTA cleavage. The ground-state structure shows evidence of an unusually open ribozyme core: the catalytic P3-P7 domain and the nucleotides that connect it to the P4-P5-P6 domain are exposed to solvent. The implications of this structure for the in vitro and in vivo properties of this intron ribozyme are discussed.

Universal initiator nucleotides for the enzymatic synthesis of 5'-amino- and 5'-thiol-modified RNA

We report the chemical synthesis of 5'-amino- and 5'-thiol-hexaethylene glycol guanosine nucleotides and their enzymatic incorporation into RNA, followed by chemical modifications at their nucleophilic ends. By using two similar routes, the conjugates of guanosine-5'-monophosphate and hexaethylene glycol with attached reactive groups (SH or NH(2)) were synthesized using phosphoramidite chemistry, and characterized by MALDI TOF mass spectrometry. These initiator molecules were efficiently incorporated into RNA at the 5'-end by run-off transcription using T7 RNA polymerase. The potential of these RNA conjugates for a broad reaction range with electrophiles is shown here, thereby enabling their use for diverse biochemical applications.

The molecular evolution and structural organization of self-splicing group I introns at position 516 in nuclear SSU rDNA of myxomycetes

Group I introns are relatively common within nuclear ribosomal DNA of eukaryotic microorganisms, especially in myxomycetes. Introns at position S516 in the small subunit ribosomal RNA gene are particularly common, but have a sporadic occurrence in myxomycetes. Fuligo septica, Badhamia gracilis, and Physarum flavicomum, all members of the family Physaraceae, contain related group IC1 introns at this site. The F. septica intron was studied at the molecular level and found to self-splice as naked RNA and to generate full-length intron RNA circles during incubation. Group I introns at position S516 appear to have a particularly widespread distribution among protists and fungi. Secondary structural analysis of more than 140 S516 group I introns available in the database revealed five different types of organization, including IC1 introns with and without His-Cys homing endonuclease genes, complex twin-ribozyme introns, IE introns, and degenerate group I-like introns. Both intron structural and phylogenetic analyses indicate a multiple origin of the S516 introns during evolution. The myxomycete introns are related to S516 introns in the more distantly related brown algae and Acanthamoeba species. Possible mechanisms of intron transfer both at the RNA- and DNA-levels are discussed in order to explain the observed widespread, but scattered, phylogenetic distribution.

Twelve Group I introns in the same pre-rRNA transcript of the myxomycete Fuligo septica: RNA processing and evolution

The ribosomal DNA region of the myxomycete Fuligo septica was investigated and found to contain 12 group I introns (four in the small subunit and eight in the large subunit ribosomal RNAs). We have performed molecular and phylogenetic analyses to provide insight into intron structure and function, intron-host biology, and intron origin and evolution. The introns vary in size from 398 to 943 nt, all lacking detectable open reading frames. Secondary structure models revealed considerable structural diversity, but all, except one (subclass IB), represent the common group IC1 intron subclass. In vitro splicing analysis revealed that 10 of the 12 introns were able to self-splice as naked RNA, but all 12 introns were able to splice out from the precursor rRNA in vivo as evaluated by reverse transcription PCR analysis on total F. septica RNA. Furthermore, RNA processing analyses in vitro and in vivo showed that 10 of 12 introns perform hydrolytic cleavage at the 3' splice site, as well as intron circularization. Full-length intron RNA circles were detected in vivo. The order of splicing was analyzed by a reverse transcription PCR approach on cellular RNA, but no strict order of intron excision could be detected. Phylogenetic analysis indicated that most Fuligo introns were distantly related to each other and were independently gained in ribosomal DNA during evolution.

The Varkud satellite ribozyme

The VS ribozyme is the largest nucleolytic ribozyme, for which there is no crystal structure to date. The ribozyme consists of five helical sections, organized by two three-way junctions. The global structure has been determined by solution methods, particularly FRET. The substrate stem-loop binds into a cleft formed between two helices, while making a loop-loop contact with another section of the ribozyme. The scissile phosphate makes a close contact with an internal loop (the A730 loop), the probable active site of the ribozyme. This loop contains a particularly critical nucleotide A756. Most changes to this nucleotide lead to three-orders of magnitude slower cleavage, and the Watson-Crick edge is especially important. NAIM experiments indicate that a protonated base is required at this position for the ligation reaction. A756 is thus a strong candidate for nucleobase participation in the catalytic chemistry.

Challenges in enzyme mechanism and energetics

Since the discovery of enzymes as biological catalysts, study of their enormous catalytic power and exquisite specificity has been central to biochemistry. Nevertheless, there is no universally accepted comprehensive description. Rather, numerous proposals have been presented over the past half century. The difficulty in developing a comprehensive description for the catalytic power of enzymes derives from the highly cooperative nature of their energetics, which renders impossible a simple division of mechanistic features and an absolute partitioning of catalytic contributions into independent and energetically additive components. Site-directed mutagenesis has emerged as an enormously powerful approach to probe enzymatic catalysis, illuminating many basic features of enzyme function and behavior. The emphasis of site-directed mutagenesis on the role of individual residues has also, inadvertently, limited experimental and conceptual attention to the fundamentally cooperative nature of enzyme function and energetics. The first part of this review highlights the structural and functional interconnectivity central to enzymatic catalysis. In the second part we ask: What are the features of enzymes that distinguish them from simple chemical catalysts? The answers are presented in conceptual models that, while simplified, help illustrate the vast amount known about how enzymes achieve catalysis. In the last section, we highlight the molecular and energetic questions that remain for future investigation and describe experimental approaches that will be necessary to answer these questions. The promise of advancing and integrating cutting edge conceptual, experimental, and computational tools brings mechanistic enzymology to a new era, one poised for novel fundamental insights into biological catalysis.

Structural features and evolutionary considerations of group IB introns in SSU rDNA of the lichen fungus Teloschistes

Different species of the lichen-forming ascomycete fungus Teloschistes were found to contain group IB introns at position S1506 in the small subunit ribosomal RNA gene. We have characterized the structural organization and phylogeny of the Teloschistes introns Tco.S1506, Tla.S1506, and Tvi.S1506. Common features to all the introns are a small size, a compact RNA structure, and an atypical catalytic ribozyme core sequence motif. Variations in intron sizes, due to sequence extensions in the P1 and P8 loop segments, were observed in different species and isolates. Phylogenetic analyses based on the ITS1-5.8S-ITS2 region as well as the introns show that the Teloschistes S1506 introns represent a distinct evolutionary isolated cluster among the nuclear group I introns. Furthermore, introns from different lineages of Teloschistes villosus appear not strictly vertically inherited probably due to horizontal transfer in one of the lineages.

Molecular diversity and phylogenetic affinities of symbiotic root-associated ascomycetes of the Helotiales in burnt and metal polluted habitats

•  The diversity and phylogenetic affinities of symbiotic root-associated ascomycetes of the Helotiales are reported here based on ITS1-5.8S-ITS2 (internal transcribed spacer, ITS) nrDNA sequences. •  Mycobionts were obtained from roots of ericoid plants and grasses and from Piceirhiza bicolorata ectomycorrhizas (pbECM) on conifers and hardwoods, predominantly in burnt and metal-polluted habitats. The mycobionts were sequenced through the ITS and compared with sequences of known helotialean taxa. •  We recognized 132 fungal ITS-sequences with affinity to the Helotiales, of which 75% (54 different ITS-genotypes) grouped within the Hymenoscyphus ericae aggregate including Phialophora finlandia. This aggregate showed stronger affinity to members of the Hyaloscyphaceae and Dermateaceae than to Hymenoscyphus fructigenus (genus-type species; Helotiaceae). Most of the pbECM mycobionts grouped with P. finlandia, although some grouped with H. ericae. Two genotypes co-occurred in ericoid and ectomycorrhizal roots. •  The H. ericae aggregate may be referable to a generic unit, and includes a diverse group of closely related, more or less darkly pigmented, root-associated ascomycetes where the borders between intra- and interspecific ITS-sequence variation, as well as different mycorrhizal and nonmycorrhizal root-symbioses, remains unclear.

Characterization of the self-splicing products of two complex Naegleria LSU rDNA group I introns containing homing endonuclease genes

The two group I introns Nae.L1926 and Nmo.L2563, found at two different sites in nuclear LSU rRNA genes of Naegleria amoebo-flagellates, have been characterized in vitro. Their structural organization is related to that of the mobile Physarum intron Ppo.L1925 (PpLSU3) with ORFs extending the L1-loop of a typical group IC1 ribozyme. Nae.L1926, Nmo.L2563 and Ppo.L1925 RNAs all self-splice in vitro, generating ligated exons and full-length intron circles as well as internal processed excised intron RNAs. Formation of full-length intron circles is found to be a general feature in RNA processing of ORF-containing nuclear group I introns. Both Naegleria LSU rDNA introns contain a conserved polyadenylation signal at exactly the same position in the 3' end of the ORFs close to the internal processing sites, indicating an RNA polymerase II-like expression pathway of intron proteins in vivo. The intron proteins I-NaeI and I-NmoI encoded by Nae.L1926 and Nmo.L2563, respectively, correspond to His-Cys homing endonucleases of 148 and 175 amino acids. I-NaeI contains an additional sequence motif homologous to the unusual DNA binding motif of three antiparallel beta sheets found in the I-PpoI endonuclease, the product of the Ppo.L1925 intron ORF.

5'-sulfhydryl-modified RNA: initiator synthesis, in vitro transcription, and enzymatic incorporation

The detailed syntheses of the sulfhydryl-modified guanosine monophosphates 5'-deoxy-5'-thioguanosine-5'-monophosphorothioate (GSMP), O-[omega-sulfhydryl-tetra(ethylene glycol)]-O-(5'-guanosine) monophosphate (5'-HS-PEG4-GMP), and O-[omega-sulfhydryl-di(ethylene glycol)]-O-(5'-guanosine) monophosphate (5'-HS-PEG2-GMP) are reported. Transcription reactions employing GSMP, 5'-HS-PEG4-GMP, or 5'-HS-PEG2-GMP as the initiator nucleotide for T7 RNA polymerase introduce a thiol group at the 5'-end of RNA. The efficiency of thiol incorporation at the 5'-terminus of modified RNA compounds was assayed with three different thiol-reactive biotinylated reagents followed by streptavidin gel-shift methods. The transcription efficiency with various ratios of GTP to 5'-HS-PEG2-GMP was explored by reaction with a sulfhydryl-reactive maleimide-conjugated protein. This is an efficient method to incorporate enzymatically a thiol group into the 5'-end of RNA.

Synthesis of 5'-deoxy-5'-thioguanosine-5'-monophosphorothioate and its incorporation into RNA 5'-termini

[figure: see text] 5'-Deoxy-5'-thioguanosine-5'-monophosphorothioate (GSMP) was synthesized in four steps with 35% overall yield. GSMP serves as a good substrate for in vitro transcription with T7 RNA polymerase to yield 5'-GSMP-RNA, which was converted to 5'-HS-RNA by dephosphorylation with alkaline phosphatase. The thiol-reactive agents can be efficiently introduced into the 5'-terminus of RNA.

Multiple folding pathways for the P4-P6 RNA domain

We recently described site-specific pyrene labeling of RNA to monitor Mg(2+)-dependent equilibrium formation of tertiary structure. Here we extend these studies to follow the folding kinetics of the 160-nucleotide P4-P6 domain of the Tetrahymena group I intron RNA, using stopped-flow fluorescence with approximately 1 ms time resolution. Pyrene-labeled P4-P6 was prepared using a new phosphoramidite that allows high-yield automated synthesis of oligoribonucleotides with pyrene incorporated at a specific 2'-amino-2'-deoxyuridine residue. P4-P6 forms its higher-order tertiary structure rapidly, with k(obs) = 15-31 s(-1) (t(1/2) approximately 20-50 ms) at 35 degrees C and [Mg(2+)] approximately 10 mM in Tris-borate (TB) buffer. The folding rate increases strongly with temperature from 4 to 45 degrees C, demonstrating a large activation enthalpy DeltaH(double dagger) approximately 26 kcal/mol; the activation entropy DeltaS(double dagger) is large and positive. In low ionic strength 10 mM sodium cacodylate buffer at 35 degrees C, a slow (t(1/2) approximately 1 s) folding component is also observed. The folding kinetics are both ionic strength- and temperature-dependent; the slow phase vanishes upon increasing [Na(+)] in the cacodylate buffer, and the kinetics switch completely from fast at 30 degrees C to slow at 40 degrees C. Using synchrotron hydroxyl radical footprinting, we confirm that fluorescence monitors the same kinetic events as hydroxyl radical cleavage, and we show that the previously reported slow P4-P6 folding kinetics apply only to low ionic strength conditions. One model to explain the fast and slow folding kinetics postulates that some tertiary interactions are present even without Mg(2+) in the initial state. The fast kinetic phase reflects folding that is facilitated by these interactions, whereas the slow kinetics are observed when these interactions are disrupted at lower ionic strength and higher temperature.

A kinetically efficient form of the Chlamydomonas self-splicing ribosomal RNA precursor

The 23S rRNA gene of Chlamydomonas reinhardtii contains a group IA3 intron, Cr.LSU, whose splicing is essential for cell growth. To better understand Cr.LSU splicing, kinetic analyses were undertaken with 23S.3, a preRNA previously shown to self-splice. Self-splicing of 23S.3 showed biphasic kinetics, with only approximately 33% reacting efficiently. Removal of a region of the 5' exon that could potentially interfere with the intron core (i.e., P3) increased the size (53%) of the active fraction. Replacement of the large P6a-extension by a 20-nt stem-loop further increased the active fraction to approximately 80%. The k(cat) and K(G)(M) for self-splicing (first step) by these latter RNAs were approximately 1 min(-1) and approximately 20 microM, respectively. These results indicate that Cr.LSU is a highly efficient ribozyme whose folding in vitro is impeded by exonic and/or intronic sequences. The implications for in vivo splicing of Cr.LSU are discussed.

A single-molecule study of RNA catalysis and folding

Using fluorescence microscopy, we studied the catalysis by and folding of individual Tetrahymena thermophila ribozyme molecules. The dye-labeled and surface-immobilized ribozymes used were shown to be functionally indistinguishable from the unmodified free ribozyme in solution. A reversible local folding step in which a duplex docks and undocks from the ribozyme core was observed directly in single-molecule time trajectories, allowing the determination of the rate constants and characterization of the transition state. A rarely populated docked state, not measurable by ensemble methods, was observed. In the overall folding process, intermediate folding states and multiple folding pathways were observed. In addition to observing previously established folding pathways, a pathway with an observed folding rate constant of 1 per second was discovered. These results establish single-molecule fluorescence as a powerful tool for examining RNA folding.

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.

Characterization of the Azoarcus ribozyme: tight binding to guanosine and substrate by an unusually small group I ribozyme

We report novel chemical properties of the ribozyme derived from the smallest group I intron (subgroup IC3) that comes from the pre-tRNA(Ile) of the bacterium Azoarcus sp. BH72. Despite the small size of the Azoarcus ribozyme (195 nucleotides (nt)), it binds tightly to the guanosine nucleophile (Kd = 15 +/- 3 microM) and exhibits activity at high temperatures (approximately 60-70 degrees C). These features may be due to the two GA3 tetraloop interactions postulated in the intron and the high GC content of the secondary structure. The second order rate constant for the Azoarcus ribozyme, ((k(cat)/Km)S = 8.4 +/- 2.1 x 10(-5) M(-1) min(-1)) is close to that found for the related ribozyme derived from the pre-tRNA(Ile) of the cyanobacterium Anabaena PCC7120. pH dependence studies and kinetic analyses of deoxy-substituted substrates suggest that the chemical cleavage step is the rate-determining process in the Azoarcus ribozyme. This may be due to the short 3-nt guide sequence-substrate pairing present in the Azoarcus ribozyme. Finally, the Azoarcus ribozyme shares features conserved in other group I ribozymes including the pH profile, the stereospecificity for the Rp-phosphorothioate at the cleavage site and the 1000-fold decrease in cleavage rate with a deoxyribonucleoside leaving group.

RNA hairpin loops repress protein synthesis more strongly than hammerhead ribozymes

A general study has been carried out to determine how well hammerhead ribozymes might reduce levels of specific protein synthesis in living cells, compared with RNA hairpin loops as stable but noncleaving controls. Four different experiments are described. First, a wide variety of hammerhead ribozymes, as well as hairpin loops, was cloned into a gene-expression cassette for beta-galactosidase, upstream of the coding sequences for that reporter gene, and expressed from plasmids in several strains of Escherichia coli. The results show that ribozymes, when acting intramolecularly in E. coli, do not significantly reduce the amount of protein synthesized from any construct. As a control, long RNA hairpin loops do greatly reduce the amount of protein made. Secondly, we studied the transcription-translation of these same plasmids in a cell extract from E. coli. Once again, hammerhead ribozymes show no effect on levels of beta-galactosidase, whereas long RNA hairpin loops produce a strong reduction, by apparent attentuation at the level of translation. Thirdly, we added an SV40 promoter to each plasmid, in order to study the effects of these gene-regulators on protein synthesis in Chinese hamster ovary cells. Here active intramolecular ribozymes produce a slight reduction in beta-galactosidase, whereas long RNA hairpin loops produce an even stronger reduction than before. Those hairpin loops apparently induce degradation of their own mRNA in Chinese hamster ovary cells, by a mechanism not seen in E. coli. Finally, analyses of total RNA by S1-trimming show that hammerhead ribozymes will self-cleave a mRNA by a total of no more than 45-50% in E. coli, compared with 70-80% in vitro. Other analyses using Northern blotting were unable to detect any ribozyme cleavage in E. coli or Chinese hamster ovary cells. In summary, the ability of hammerhead ribozymes to reduce protein synthesis appears weak or nonexistent in all the cellular systems tested. By comparison, long RNA hairpin loops reduce protein synthesis strongly: by an apparent attentuation mechanism in E. coli or by a novel degradation of their own mRNA in Chinese hamster ovary cells.

Evaluating group I intron catalytic efficiency in mammalian cells

Recent reports have demonstrated that the group I ribozyme from Tetrahymena thermophila can perform trans-splicing reactions to repair mutant RNAs. For therapeutic use, such ribozymes must function efficiently when transcribed from genes delivered to human cells, yet it is unclear how group I splicing reactions are influenced by intracellular expression of the ribozyme. Here we evaluate the self-splicing efficiency of group I introns from transcripts expressed by RNA polymerase II in human cells to directly measure ribozyme catalysis in a therapeutically relevant setting. Intron-containing expression cassettes were transfected into a human cell line, and RNA transcripts were analyzed for intron removal. The percentage of transcripts that underwent self-splicing ranged from 0 to 50%, depending on the construct being tested. Thus, self-splicing activity is supported in the mammalian cellular environment. However, we find that the extent of self-splicing is greatly influenced by sequences flanking the intron and presumably reflects differences in the intron's ability to fold into an active conformation inside the cell. In support of this hypothesis, we show that the ability of the intron to fold and self-splice from cellular transcripts in vitro correlates well with the catalytic efficiency observed from the same transcripts expressed inside cells. These results underscore the importance of evaluating the impact of sequence context on the activity of therapeutic group I ribozymes. The self-splicing system that we describe should facilitate these efforts as well as aid in efforts at enhancing in vivo ribozyme activity for various applications of RNA repair.

Probing the role of metal ions in RNA catalysis: kinetic and thermodynamic characterization of a metal ion interaction with the 2'-moiety of the guanosine nucleophile in the Tetrahymena group I ribozyme

Deciphering the role of individual metal ions in RNA catalysis is a tremendous challenge, as numerous metal ions coat the charged backbone of a folded RNA. Metal ion specificity switch experiments combined with quantitative analysis may provide a powerful tool for probing specific metal ion-RNA interactions and for delineating the role of individual metal ions among the sea of metal ions bound to RNA. We show herein that Mn(2+) rescues the deleterious effect of replacing the 2'-OH of the guanosine nucleophile (G) by -NH(2) (G(NH)()2) in the reaction catalyzed by the Tetrahymena group I ribozyme (E), and the Mn(2+) concentration dependence suggests that a single metal ion is responsible for rescue. This provides strong evidence for a metal ion interaction with the 2'-moiety of G in this ribozyme (referred to as M(C)), confirming and extending previous results in a bacteriophage group I intron [Sjögren, A.-S., Pettersson, E., Sjöberg, B.-M., and Strömberg, R. (1997) Nucleic Acids Res. 25, 648-654]. Toward understanding the >10(6)-fold catalytic contribution of the 2'-OH of G, we have determined the individual reaction steps affected by M(C) and quantitated these effects. has only a small effect on binding of G(NH)()2 to the free ribozyme or ribozyme.oligonucleotide complexes that lack the reactive phosphoryl group. In contrast, increases the binding of G(NH)()2 to the ribozyme.oligonucleotide substrate (E.S) complex 20-fold and increases the binding of S to the E.G(NH)()2 complex by the same amount. These and other observations suggest that M(C) plays an integral role in the coupled binding of the oligonucleotide substrate and the guanosine nucleophile. This metal ion may be used to align the nucleophile within the active site, thereby facilitating the reaction. Alternatively or in addition, M(C) may act in concert with an additional metal ion to coordinate and activate the 3'-OH of G. Finally, these experiments have also allowed us to probe the properties of this metal ion site and isolate the energetic effects of the interaction of this specific metal ion with the 2'-moiety of G.

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

We have probed the electrostatic environment of the active site of the Tetrahymena group I ribozyme (E) using protonated 2'-aminoguanosine (), in which the 2'-OH of the guanosine nucleophile (G) is replaced by an group. At low concentrations of divalent metal ion (2 mM Mg(2+)), binds at least 200-fold stronger than G or G(NH)()2, with a dissociation constant of </=1 microM from the ribozyme. oligonucleotide substrate. complex (). This strong binding suggests that the group interacts with negatively charged phosphoryl groups within the active site. Increasing the concentration of divalent metal ion weakens the binding of to E. S more than 10(2)-fold. The Mn(2+) concentration dependence suggests that M(C), the metal ion that interacts with the 2'-moiety of G in the normal reaction, is responsible for this effect. M(C) and compete for binding to the active site; this competition could arise from electrostatic repulsion between the positively charged and M(C) and, possibly, from their competition for interaction with active site phosphoryl groups. The reactive phosphoryl group of S increases the competition between M(C) and, consistent with a network of interactions involving M(C) that help position the reactive phosphoryl group and the guanosine nucleophile with respect to one another. The chemical step with bound is at least 10(4)-fold slower than with G or G(NH)()2. These results provide additional support for an integral role of M(C) in catalysis by the Tetrahymena ribozyme, and demonstrate the utility of the moiety as an electrostatic probe within a structured RNA.

A minor groove RNA triple helix within the catalytic core of a group I intron

Close packing of several double helical and single stranded RNA elements is required for the Tetrahymena group I ribozyme to achieve catalysis. The chemical basis of these packing interactions is largely unknown. Using nucleotide analog interference suppression (NAIS), we demonstrate that the P1 substrate helix and J8/7 single stranded segment form an extended minor groove triple helix within the catalytic core of the ribozyme. Because each triple in the complex is mediated by at least one 2'-OH group, this substrate recognition triplex is unique to RNA and is fundamentally different from major groove homopurine-homopyrimidine triplexes. We have incorporated these biochemical data into a structural model of the ribozyme core that explains how the J8/7 strand organizes several helices within this complex RNA tertiary structure.

Order, dynamics and metal-binding in the lead-dependent ribozyme

The in vitro selected lead-dependent ribozyme is among the smallest and simplest of the known catalytic RNA motifs and has a unique metal ion specificity for divalent lead. The conformation and dynamics of this ribozyme are analyzed here by NMR and chemical probing experiments. Complete assignments of the 1H, 13C, and 15N resonances have been made, and the NMR chemical shift changes in the presence of Pb2+, Mg2+ or high concentrations of Na+ show that there is no significant structural change upon addition of either activating (Pb2+) or inhibitory (Mg2+) divalent ions. The 13C NMR relaxation data indicate substantial dynamic fluctuations on various time-scales for active-site residues in this ribozyme. The combination of chemical probing and NMR experiments reveals a picture of the active site for the lead-dependent ribozyme that has both ordered and dynamic features.

Group I twintrons: genetic elements in myxomycete and schizopyrenid amoeboflagellate ribosomal DNAs

Protists are unicellular eukaryotes which represent a significant fraction of the global biodiversity. The myxomycete Didymium and the schizopyrenid amoeboflagellate Naegleria are distantly related protists. However, we have noted several striking similarities in life cycle, cell morphology, and ribosomal DNA organization between these organisms. Both have multicopy nuclear extrachromosomal ribosomal DNAs. Here the small subunit ribosomal RNA genes are interrupted by an optional group I twintron, a novel category among the group I introns. Group I twintrons are mobile self-splicing introns of 1.3-1.4 kb in size, with a complex organization at the RNA level. A group I twintron consists of two distinct ribozymes (catalytic RNAs) with different functions in RNA processing, and an open reading frame encoding a functional homing endonuclease--all with prospects of application as molecular tools in biotechnology. Updated RNA secondary structure models of group I twintrons, as well as an example of in vitro ribozyme activity, are presented. We suggest that the group I twintrons have been independently established in myxomycetes and schizopyrenid amoeboflagellates by horizontal gene transfer due to a combination of the phagocytotic behavior in natural environments and the extrachromosomal multicopy nature of ribosomal DNA.

Unveiling two distinct ribonuclease activities and a topoisomerase activity in a site-specific DNA recombinase

The site-specific DNA recombinase Flp shows two types of RNA cleavage activities on hybrid DNA-RNA substrates. One targets the phosphodiester position involved in DNA recombination and follows a related mechanistic path. In this two-step reaction, first-strand scission is mediated by a nucleophilic attack of the scissile phosphodiester bond by the active site tyrosine of Flp. The resultant 3'-O-phosphoryl tyrosine bond is then attacked by the adjacent 2'-hydroxyl group. The second activity targets the immediately adjacent phosphodiester bond to the 3' side using a distinct mechanism. In this reaction, the vicinal 2'-hydroxyl directly attacks the phosphate group in a manner that is reminiscent of the pancreatic RNase mechanism. The Flp protein can also be shown to possess a topoisomerase-like activity.

Hierarchy and dynamics of RNA folding

The evidence showing that the self-assembly of complex RNAs occurs in discrete transitions, each relating to the folding of sub-systems of increasing size and complexity starting from a state with most of the secondary structure, is reviewed. The reciprocal influence of the concentration of magnesium ions and nucleotide mutations on tertiary structure is analyzed. Several observations demonstrate that detrimental mutations can be rescued by high magnesium concentrations, while stabilizing mutations lead to a lesser dependence on magnesium ion concentration. Recent data point to the central controlling and monitoring roles of RNA-binding proteins that can bind to the different folding stages, either before full establishment of the secondary structure or at the molten globule state before the cooperative transition to the final three-dimensional structure.