Mechanism of 3' splice site selection by the catalytic core of the sunY intron of bacteriophage T4: the role of a novel base-pairing interaction in group I introns

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.

Crystal structure studies of RNA duplexes containing s(2)U:A and s(2)U:U base pairs

Structural studies of modified nucleobases in RNA duplexes are critical for developing a full understanding of the stability and specificity of RNA base pairing. 2-Thio-uridine (s²U) is a modified nucleobase found in certain tRNAs. Thermodynamic studies have evaluated the effects of s²U on base pairing in RNA, where it has been shown to stabilize U:A pairs and destabilize U:G wobble pairs. Surprisingly, no high-resolution crystal structures of s²U-containing RNA duplexes have yet been reported. We present here two high-resolution crystal structures of heptamer RNA duplexes (5′-uagcs²Ucc-3′ paired with 3′-aucgAgg-5′ and with 3′-aucgUgg-5′) containing s²U:A and s²U:U pairs, respectively. For comparison, we also present the structures of their native counterparts solved under identical conditions. We found that replacing O2 with S2 stabilizes the U:A base pair without any detectable structural perturbation. In contrast, an s²U:U base pair is strongly stabilized in one specific U:U pairing conformation out of four observed for the native U:U base pair. This s²U:U stabilization appears to be due at least in part to an unexpected sulfur-mediated hydrogen bond. This work provides additional insights into the effects of 2-thio-uridine on RNA base pairing.

Structural insights of non-canonical U*U pair and Hoogsteen interaction probed with Se atom

Unlike DNA, in addition to the 2′-OH group, uracil nucleobase and its modifications play essential roles in structure and function diversities of non-coding RNAs. Non-canonical U•U base pair is ubiquitous in non-coding RNAs, which are highly diversified. However, it is not completely clear how uracil plays the diversifing roles. To investigate and compare the uracil in U-A and U•U base pairs, we have decided to probe them with a selenium atom by synthesizing the novel 4-Se-uridine (^SeU) phosphoramidite and Se-nucleobase-modified RNAs (^SeU-RNAs), where the exo-4-oxygen of uracil is replaced by selenium. Our crystal structure studies of U-A and U•U pairs reveal that the native and Se-derivatized structures are virtually identical, and both U-A and U•U pairs can accommodate large Se atoms. Our thermostability and crystal structure studies indicate that the weakened H-bonding in U-A pair may be compensated by the base stacking, and that the stacking of the trans-Hoogsteen U•U pairs may stabilize RNA duplex and its junction. Our result confirms that the hydrogen bond (O4^…H-C5) of the Hoogsteen pair is weak. Using the Se atom probe, our Se-functionalization studies reveal more insights into the U•U interaction and U-participation in structure and function diversification of nucleic acids.

RNA reprogramming and repair based on trans-splicing group I ribozymes

While many traditional gene therapy strategies attempt to deliver new copies of wild-type genes back to cells harboring the defective genes, RNA-directed strategies offer a range of novel therapeutic applications. Revision or reprogramming of mRNA is a form of gene therapy that modifies mRNA without directly changing the transcriptional regulation or the genomic gene sequence. Group I ribozymes can be engineered to act in trans by recognizing a separate RNA molecule in a sequence-specific manner, and to covalently link a new RNA sequence to this separate RNA molecule. Group I ribozymes have been shown to repair defective transcripts that cause human genetic or malignant diseases, as well as to replace transcript sequences by foreign RNA resulting in new cellular functions. This review provides an overview of current strategies using trans-splicing group I ribozymes in RNA repair and reprogramming.

A Pneumocystis carinii group I intron-derived ribozyme utilizes an endogenous guanosine as the first reaction step nucleophile in the trans excision-splicing reaction

In the trans excision-splicing reaction, a Pneumocystis carinii group I intron-derived ribozyme binds an RNA substrate, excises a specific internal segment, and ligates the flanking regions back together. This reaction can occur both in vitro and in vivo. In this report, the first of the two reaction steps was analyzed to distinguish between two reaction mechanisms: ribozyme-mediated hydrolysis and nucleotide-dependent intramolecular transesterification. We found that the 3'-terminal nucleotide of the ribozyme is the first-reaction step nucleophile. In addition, the 3'-half of the RNA substrate becomes covalently attached to the 3'-terminal nucleotide of the ribozyme during the reaction, both in vitro and in vivo. Results also show that the identity of the 3'-terminal nucleotide influences the rate of the intramolecular transesterification reaction, with guanosine being more effective than adenosine. Finally, expected products of the hydrolysis mechanism do not form during the reaction. These results are consistent with only the intramolecular transesterification mechanism. Unexpectedly, we also found that ribozyme constructs become truncated in vivo, probably through intramolecular 3'-hydrolysis (self-activation), to create functional 3'-terminal nucleotides.

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.

Yeast transcripts cleaved by an internal ribozyme provide new insight into the role of the cap and poly(A) tail in translation and mRNA decay

It has been proposed that the 7-methylguanosine cap and poly(A) tail of mRNAs have important functions in translation and transcript stability. To directly test these roles of the cap and poly(A) tail, we have constructed plasmids with a ribozyme within the coding region or 3' UTR of reporter genes. We show that the unadenylated 5' cleavage product is translated and is rapidly degraded by the cytoplasmic exosome. This exosome-mediated decay is independent of the nonstop mRNA decay pathway, and, thus, reveals an additional substrate for exosome-mediated decay that may have physiological equivalents. The rapid decay of this transcript in the cytoplasm indicates that this unadenylated cleavage product is rapidly exported from the nucleus. We also show that this cleavage product is not subject to rapid decapping; thus, the lack of a poly(A) tail does not always trigger rapid decapping of the transcript. We show that the 3' cleavage product is rapidly degraded by Xrn1p in the cytoplasm. We cannot detect any protein from this 3' cleavage product, which supports previous data concluding that the 5' cap is required for translation. The reporter genes we have utilized in these studies should be generally useful tools in studying the importance of the poly(A) tail and 5' cap of a transcript for export, translation, mRNA decay, and other aspects of mRNA metabolism in vivo.

RNA aptamers: from basic science towards therapy

The SELEX technique (systematic evolution of ligands by exponential enrichment) provides a powerful tool for the in vitro selection of nucleic acid ligands (aptamers) from combinatorial oligonucleotide libraries against a target molecule. In the beginning of the technique's use, RNA molecules were identified that bind to proteins that naturally interact with nucleic acids or to small organic molecules. In the following years, the use of the SELEX technique was extended to isolate oligonucleotide ligands (aptamers) for a wide range of proteins of importance for therapy and diagnostics, such as growth factors and cell surface antigens. These oligonucleotides bind their targets with similar affinities and specificities as antibodies do. The in vitro selection of oligonucleotides with enzymatic activity, denominated aptazymes, allows the direct transduction of molecular recognition to catalysis. Recently, the use of in vitro selection methods to isolate protein inhibitors has been extended to complex targets, such as membrane-bound receptors, and even entire cells. RNA aptamers have also been expressed in living cells. These aptamers, also called intramers, can be used to dissect intracellular signal transduction pathways. The utility of RNA aptamers for in vivo experiments, as well as for diagnostic and therapeutic purposes, is considerably enhanced by chemical modifications, such as substitutions of the 2'-OH groups of the ribose backbone in order to provide resistance against enzymatic degradation in biological fluids. In an alternative approach, Spiegelmers are identified through in vitro selection of an unmodified D-RNA molecule against a mirror-image (i.e. a D-peptide) of a selection target, followed by synthesis of the unnatural nuclease-resistant L-configuration of the RNA aptamer that recognizes the natural configuration of its selection target (i.e. a L-peptide). Recently, nuclease-resistant inhibitory RNA aptamers have been developed against a great variety of targets implicated in disease. Some results have already been obtained in animal models and in clinical trials.

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

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

Ribozymes: the characteristics and properties of catalytic RNAs

Ribozymes, or catalytic RNAs, were discovered a little more than 15 years ago. They are found in the organelles of plants and lower eukaryotes, in amphibians, in prokaryotes, in bacteriophages, and in viroids and satellite viruses that infect plants. An example is also known of a ribozyme in hepatitis delta virus, a serious human pathogen. Additional ribozymes are bound to be found in the future, and it is tempting to regard the RNA component(s) of various ribonucleoprotein complexes as the catalytic engine, while the proteins serve as mere scaffolding--an unheard-of notion 15 years ago! In nature, ribozymes are involved in the processing of RNA precursors. However, all the characterized ribozymes have been converted, with some clever engineering, into RNA enzymes that can cleave or modify targeted RNAs (or even DNAs) without becoming altered themselves. While their success in vitro is unquestioned, ribozymes are increasingly used in vivo as valuable tools for studying and regulating gene expression. This review is intended as a brief introduction to the characteristics of the different identified ribozymes and their properties.

Crystals by design: a strategy for crystallization of a ribozyme derived from the Tetrahymena group I intron

Recently, the 2.8 A crystal structure of one domain of the self-splicing Tetrahymena group I intron was reported. Although it revealed much about RNA tertiary interactions, it contained only half of the active site. We have now designed a series of larger molecules that contain about 70% of the intron and all of the catalytic core. These RNAs were efficient in cleavage of a substrate RNA, consisting of the approximately 100 nucleotides from the 5' end of the intron, at a site corresponding to the 5' splice site. A sparse matrix was designed specifically for large RNAs and used to screen for preliminary crystallization conditions. Of the six RNAs initially tested, five were crystallized in this initial trial. Two of these crystals were further examined. The first diffracted X-rays to only approximately 16 A resolution, even when the crystal were very large. The second diffracted as high as 3.5 A, but the crystals were twinned and therefore unusable for structural studies. Site-specific mutagenesis was performed on the latter RNA to disrupt interactions that might have been responsible for the twinning. One of these mutant RNAs produced large, single, diffraction-quality crystals. The crystals belong to the tetragonal space group P42212 and have large unit cell dimensions, a=b=178 A and c=199 A. Thus, by variation of both sequence elements and crystallization conditions, crystals of a 247 nucleotide catalytic RNA were obtained.

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.

A small insertion in the SSU rDNA of the lichen fungus Arthonia lapidicola is a degenerate group-I intron

Insertions of less than 100 nt occurring in highly conserved regions of the small subunit ribosomal DNA (SSU rDNA) may represent degenerate forms of the group-I introns observed at the same positions in other organisms. A 63-nt insertion at SSU rDNA position 1512 (relative to the Escherichia coli SSU rDNA) of the lichen-forming fungus Arthonia lapidicola can be folded into a secondary structure with two stem loops and a pairing of the insertion and flanking sequences. The two stem loops may correspond to the P1 and P2, and the insertion-flanking pairing to the P10, of a group-I intron. Considering these small insertions as degenerate introns provides important clues to the evolution and catalytic function of group-I introns. Keywords Ribosomal DNA middle dot Small subunit middle dot 18s middle dot Degenerate introns middle dot Ascomycetes

An RNA fragment consisting of the P7 and P9.0 stems and the 3'-terminal guanosine of the Tetrahymena group I intron

On the basis of the nucleotide sequence of Tetrahymena group I intron, we constructed a 31 residue RNA that has the P7 stem and the 3'-terminal guanosine residue (3'-G) with a putative stem-loop structure (P9.0) intervening between them. For this model RNA (P7/P9.0/G), four residues around the guanosine binding site (GBS) in the P7 stem were found to exhibit much lower sensitivities to ribonuclease V1 than those of a variant RNA having adenosine in place of the 3'-G, suggesting that the 3'-G contacts around the GBS. NMR analyses of the imino proton resonances of the P7/P9.0/G RNA indicated that the base pairing in the GBS is retained on the interaction with the 3'-G, and that the two base pairs of the putative P9.0 stem-loop are definitely formed. Comparison of the RNA with its variants with either A (3'-A) or a deletion in place of the 3'-G suggested that the stability of the P9.0 stem-loop is affected by the GBS-3'-G interaction. The melting temperatures of the P9.0 stem-loop were determined from the UV absorbances of these RNAs, which quantitatively indicated that the P9.0 stem-loop is significantly stabilized by the interaction of the GBS with the 3'-G, rather than the 3'-A, and also by direct interaction with divalent cations (Mg2+, Ca2+ or Mn2+). Upon replacement of the G-C base pair by C-G in the GBS of the P7/P9.0/G RNA, the specificity was switched from 3'-G to 3'-A, as in the case of the intact intron.

Functionally redundant interactions between U2 and U6 spliceosomal snRNAs

Base-pairing between U2 and U6 snRNAs to form intermolecular helix II has been demonstrated previously as a requirement for pre-mRNA splicing in mammalian cells. In contrast, deletion and substitution mutation experiments in yeast have indicated that helix II is not essential; instead, other regions of U2 and U6 have been proposed to pair, forming a helix called Ib. To investigate the importance of U2/U6 helices in yeast, we have systematically mutagenized the regions proposed to form helices II and Ib. Allele-specific suppression of certain U6 mutations by complementary substitutions in U2 show that helix II indeed form in yeast but that it is essential only in the presence of additional mutations that disrupt U2 stem I and the proposed helix Ib. Similarly, the proposed helix Ib is essential only when helix II is disrupted. These observations provide an explanation for apparently conflicting data in yeast and mammalian experimental systems, and identify synergistic or functionally redundant interactions between U2 and U6 snRNAs.

Protein facilitation of group I intron splicing by assembly of the catalytic core and the 5' splice site domain

The yeast mitochondrial group I intron b15 undergoes self-splicing at high Mg2+ concentrations, but requires the splicing factor CBP2 for reaction under physiological conditions. Chemical accessibility and UV cross-linking experiments now reveal that self-processing is slow because functional elements are not properly positioned in an active tertiary structure. Folding energy provided by CBP2 drives assembly of two RNA domains that comprise the catalytic core and meditates association of an approximately 100 nt 5' domain that contains the 5' splice site. Thus, the protein assembles RNA secondary structure elements into a specific three-dimensional array while the RNA provides the catalytic center. The division of labor between RNA and protein illustrated by this simple system reveals principles applicable to complex ribonucleoprotein assemblies such as the spliceosome and ribosome.

The site-specific DNA endonuclease encoded by a group I intron in the Chlamydomonas pallidostigmatica chloroplast small subunit rRNA gene introduces a single-strand break at low concentrations of Mg2+

Two group I introns (CpSSU.1 and CpSSU.2) that each potentially encode a protein with two copies of the LAGLI-DADG motif were identified in the Chlamydomonas pallidostigmatica chloroplast small subunit rRNA gene. They both belong to subgroup IA3 and represent novel insertion positions in this gene (sites 508 and 793 in the Escherichia coli 16S rRNA). The proteins encoded by the two introns were synthesized in vitro and tested for their ability to cleave the homing site of their respective introns. Only the CpSSU.1-encoded protein (I-CpaII) was found to display specific DNA endonuclease activity. At 0.1 mM MgCl2, I-CpaII nicks only the bottom (transcribed) DNA strand, but at concentrations ranging from 0.5 to 5.0 mM, it cleaves both DNA strands (leaving a 4 nucleotide single-stranded extension with 3'-OH overhangs) while preferentially nicking the bottom strand. The rate of cleavage of the top strand increases with increasing concentration of MgCl2. The preliminary data derived from these endonuclease assays suggest that the mode of DNA cleavage by I-CpaII is directed by the availability of Mg2+ and the affinity of different binding sites for this cation.

Novel system for analysis of group I 3' splice site reactions based on functional trans-interaction of the P1/P10 reaction helix with the ribozyme's catalytic core

A group I intron from a bacterial tRNA precursor has been converted into an RNA enzyme that catalyzes the efficient polymerization of oligoribonucleotide analogs of tRNA exons using a reaction scheme consisting of multiple cycles of reverse and forward exon ligation reactions. Here, we present results showing that this system represents a novel and useful tool for the analysis of 3' splice site reactions of group I ribozymes. First, analysis of variant substrates containing base substitutions in group I secondary structure elements P1, P9.0 and P10 confirms that exon polymerization is dependent on these structures, and therefore constitutes an appropriate and relevant model system for studying the exon ligation step of splicing. Second, to probe interactions between the intron's catalytic core and the bases and backbone of the P1/P10 reaction helix, two successful strategies for separating the internal guide sequence from the intron core were devised. One such strategy uses a construct in which the reaction helix interacts functionally with the catalytic core using only tertiary contacts. Further stabilization of this interaction through the inclusion of a 7 bp intermolecular P2 helix generates increased reaction efficiency. Third, when provided with two reaction helices, the ribozyme synthesizes mixed polymers through a mechanism that involves sequential binding and release of the duplexes. Fourth, in these reactions, turnover of the external guide sequence requires unwinding and annealing of the P2 helix, suggesting that P2 unwinding may occur during group I splicing. These results provide novel experimental tools to probe the relatively poorly understood 3' splice site reactions of group I introns, and may be relevant to ribozyme-catalyzed assembly and recombination of oligomers in prebiotic scenarios.

A modified group I intron can function as both a ribozyme and a 5' exon in a trans-exon ligation reaction

Here, we show that a single RNA molecule derived from a group-I intron can provide the catalytic activity, the substrate recognition domain and the attacking nucleophile in a reaction that mimics the exon ligation step of splicing. To accomplish this reaction, we have linked a 5' exon sequence to the 3' end of an attenuated form of the self-splicing Tetrahymena rRNA intron. The ribozyme (I-E1) attacks an oligoribonucleotide analog of the 3' splice site (I'-E2) to generate a product containing ligated exons (I-E1-E2) and a small intron fragment (I'). Two modified introns were constructed and tested for activity. A construct designed to interact with the 3' splice site through intermolecular P9.0 and P10 helices was found to be inactive due to failure to form a stable ribozyme-substrate complex. A second modified intron and substrate combination was engineered, in which the complex was further stabilized by an intermolecular P9.2 helix. In this case, stable complexes and reaction products were identified. The reaction efficiency was low compared to splicing of the unmodified intron-containing precursor, and will be optimized in future experiments. Following optimization, we believe that this system may be exploited to examine the functional consequences of a wide variety of 3' splice-site modifications, and may provide the basis for development of highly selective trans-acting ribozymes.

RNA sequence analysis using covariance models

We describe a general approach to several RNA sequence analysis problems using probabilistic models that flexibly describe the secondary structure and primary sequence consensus of an RNA sequence family. We call these models 'covariance models'. A covariance model of tRNA sequences is an extremely sensitive and discriminative tool for searching for additional tRNAs and tRNA-related sequences in sequence databases. A model can be built automatically from an existing sequence alignment. We also describe an algorithm for learning a model and hence a consensus secondary structure from initially unaligned example sequences and no prior structural information. Models trained on unaligned tRNA examples correctly predict tRNA secondary structure and produce high-quality multiple alignments. The approach may be applied to any family of small RNA sequences.

Evolutionary optimization of the catalytic properties of a DNA-cleaving ribozyme

In a previous study [Beaudry, A. A., & Joyce, G. F. (1992) Science 257, 635-641], an in vitro evolution procedure was used to obtain variants of the Tetrahymena ribozyme with 100-fold improved ability to cleave a target single-stranded DNA under physiologic conditions. Here we report continuation of the in vitro evolution process to achieve 10(5)-fold overall improvement in DNA-cleavage activity. In addition, we demonstrate that, by appropriate manipulation of the selection constraints, one can optimize specific catalytic properties of the evolved ribozymes. We first reduced the concentration of the DNA substrate 50-fold to favor ribozymes with improved substrate binding affinity. We then reduced the reaction time 12-fold to favor ribozymes with improved catalytic rate. In both cases, the evolving population responded as expected, first improving substrate binding 25-fold, and then improving catalytic rate about 50-fold. The population of ribozymes has undergone 27 successive generations of in vitro evolution, resulting in, on average, 17 mutations relative to the wild type that are responsible for the improved DNA-cleavage activity.

Representation of the secondary and tertiary structure of group I introns

Group I introns, which are widespread in nature, carry out RNA self-splicing. The secondary structure common to these introns was for the most part established a decade ago. Information about their higher order structure has been derived from a range of experimental approaches, comparative sequence analysis, and molecular modelling. This information now provides the basis for a new two-dimensional structural diagram that more accurately represents the domain organization and orientation of helices within the intron, the coaxial stacking of certain helices, and the proximity of key nucleotides in three-dimensional space. It is hoped that this format will facilitate the detailed comparison of group I intron structures.

The in vivo use of alternate 3'-splice sites in group I introns

Alternative splicing of group I introns has been postulated as a possible mechanism that would ensure the translation of proteins encoded into intronic open reading frames, discontinuous with the upstream exon and lacking an initiation signal. Alternate splice sites were previously depicted according to secondary structures of several group I introns. We present here strong evidence that, in the case of Podospora anserina nad 1-i4 and cox1-i7 mitochondrial introns, alternative splicing events do occur in vivo. Indeed, by PCR experiments we have detected molecules whose sequence is precisely that expected if the predicted alternate 3'-splice sites were used.

Small subunit rDNA variation in a population of lichen fungi due to optional group-I introns

A natural population of the lichen-forming ascomycetous fungus, Cladonia chlorophaea, contained individuals with small subunit ribosomal DNA (SSU rDNA) of at least four different size classes and nine restriction-site patterns. The source of these differences was the variable occurrence of 200-400-nucleotide insertions, previously identified as small group-I introns, at five different positions within the SSU coding region. By specific amplification of the sequences flanking these five intron positions with the polymerase chain reaction (PCR), a minimum of nine types of rDNA repeats were defined that differ in number, position, restriction pattern and size of introns. The positions of the introns were verified by sequence analysis. The variable distribution of these introns suggests that they are currently mobile--either by intron insertion, deletion or both--within this species complex.

Group I introns interrupt the chloroplast psaB and psbC and the mitochondrial rrnL gene in Chlamydomonas

The polymerase chain reaction was used to identify novel IAI subgroup introns in cpDNA-enriched preparations from the interfertile green algae Chlamydomonas eugametos and Chlamydomonas moewusii. These experiments along with sequence analysis disclosed the presence, in both green algae, of a single IA1 intron in the psaB gene and of two group I introns (IA2 and IA1) in the psbC gene. In addition, two group I introns (IA1 and IB4) were found in the peptidyltransferase region of the mitochondrial large subunit rRNA gene at the same positions as previously reported Chlamydomonas chloroplast introns. The 188 bp segment preceding the first mitochondrial intron revealed extensive sequence similarity to the distantly spaced rRNA-coding modules L7 and L8 in the Chlamydomonas reinhardtii mitochondrial DNA, indicating that these two modules have undergone rearrangements in Chlamydomonas. The IA1 introns in psaB and psbC were found to be related in sequence to the first intron in the C. moewusii chloroplast psbA gene. The similarity between the former introns extends to the immediate 5' flanking exon sequence, suggesting that group I intron transposition occurred from one of the two genes to the other through reverse splicing.

The single group-I intron in the chloroplast rrnL gene of Chlamydomonas humicola encodes a site-specific DNA endonuclease (I-ChuI)

The single group-I intron (ChLSU.1) in the chloroplast (cp) large subunit rRNA-encoding gene (rrnL) of the green alga Chlamydomonas humicola is located at a position at which no introns have previously been characterized in other systems. In the present study, the nucleotide (nt) sequence of this 1118-bp intron was found to contain an internal open reading frame (ORF) that potentially encodes a basic protein of 218 amino acid residues. The putative C. humicola protein features two copies of the LAGLI-DADG motif and is part of the family of intron-encoded proteins comprising the endonucleases (ENases), I-SceI, I-SceIV and I-CsmI. Expression of the ChLSU.1 intron ORF in vitro in the presence of a 260-bp DNA fragment containing the exon 1-2 junction of an intronless version of the C. humicola rrnL resulted in specific cleavage of the DNA fragment very close to the intron insertion site. This novel intron-encoded ENase, designated I-ChuI, was also shown to generate a staggered cut with 4-nt (CTCG) 3'-OH overhangs 2 bp downstream from the intron insertion site.

Interlocked circle formation by group I introns: structural requirements and mechanism

Precursor RNA transcribed from the yeast mitochondrial gene coding for the large ribosomal RNA contains a group I intron that can excise itself in vitro. Apart from group I specific sequence elements the intron also contains a gene encoding a DNA endonuclease involved in intron dispersal. A precursor RNA derivative from which this gene has been removed self-splices efficiently, but due to activation of cryptic opening sites located in the 5' exon, the 3' part of this exon is sometimes co-excised with the intron. Upon further reaction, this enlarged intron molecules give rise to interlocked circles, comprising small circles derived from 5' exon parts and large circles of the intron. Sequence comparison between cryptic opening sites and authentic splice sites reveals in most cases homology with the 3' exon part that is capable of interacting with the Internal Guide Sequence. The role of the IGS was further substantiated by replacing the cryptic opening sites with well defined sequences of authentic splice sites: one corresponding to the 3' splice site and its mutant derivatives, the other to a fragment containing the natural 5'-3' exon junction. Precursor RNAs derived from these constructs give rise to interlocked circles, and mutation studies confirm that the 3' exon nucleotides flanking a 3' splice site are essential for their formation. The results underline the crucial role of the IGS in interlocked circle formation which behaves similarly as in the normal self-splicing reactions. It has been proposed that the two short helices formed by basepairing of the IGS with the 5' and 3' exon can co-axially stack on top of each other forming a quasi continuous RNA double helix or pseudoknot. We present a model explaining how transesterification reactions of a mutant precursor RNA in such a pseudoknot can lead to interlocked circles. The experiments support the notion that a similar structure is also operative in splicing of wild type precursor RNA.

Mutational analysis of the yeast U2 snRNA suggests a structural similarity to the catalytic core of group I introns

We have used an in vitro reconstitution system to determine the effects of a large number of mutations in the highly conserved 5' terminal domain of the yeast U2 snRNA on pre-mRNA splicing. Whereas many mutations have little or no functional consequence, base substitutions in two regions were found to have drastic effects on pre-mRNA splicing. A previously unrecognized function for the U2 snRNA in the second step of splicing was found by alteration of the absolutely conserved sequence AGA upstream of the branch point recognition sequence. The effects of these mutations suggest the formation of a structure involving the U2 snRNA similar to the guanosine-binding site found in the catalytic core of group I introns.

Numerous group I introns with variable distributions in the ribosomal DNA of a lichen fungus

The length of the small subunit ribosomal DNA (SSU rDNA) differs significantly among individuals from natural populations of the ascomycetous lichen complex Cladonia chlorophaea. The sequence of the 3' region of the SSU rDNA from two individuals, chosen to represent the shortest and longest sequences, revealed multiple insertions within a region that otherwise aligned with a 520-nucleotide sequence of the SSU rDNA in Saccharomyces cerevisiae. The high degree of variability in SSU rDNA size can be accounted for by different numbers of insertions; one individual had two group I introns and the second had five introns, two of which were clearly related to introns at identical positions in the other individual. Yet, introns in different positions, whether within an individual or between individuals, were not similar in sequence. The distribution of introns at three of the positions is consistent with either intron loss or acquisition, and clearly indicates the dynamic variability in this region of the nuclear genome. All seven insertions, which ranged in size from 210 to 228 nucleotides, had the conserved sequence and secondary structural elements of group I introns. The variation in distribution and sequence of group I introns within a short highly conserved region of rDNA presents a unique opportunity for examining the molecular evolution and mobility of group I introns within a systematics framework.

Non-competitive inhibition of group I intron RNA self-splicing by aminoglycoside antibiotics

Aminoglycoside antibiotics inhibit self-splicing of group I intron RNA in vitro at concentrations as low as 10(-6) M. The sites of interaction and the mechanism of inhibition have yet to be determined. A comparative study of inhibition by different 2-deoxystreptamine analogues reveals structural features of the aminoglycoside antibiotics required for their interaction and effect on group I introns. Complete antibiotic inhibition of the two steps of splicing was not reversed at high concentrations of guanosine, indicating a non-competitive inhibition. A mutant group I intron in which the conserved guanosine nucleotide of the G-binding site had been replaced by an adenosine, was sensitive to the antibiotics providing direct evidence that the antibiotics do not interact with the G-binding site in the same way as the guanine base. In addition kinetic analyses of the self-splicing process in the presence of antibiotic inhibitors supported a non-competitive mechanism of the mixed type for inhibition of the ribozyme.

Activation of the catalytic core of a group I intron by a remote 3' splice junction

Over 1000 nucleotides may separate the ribozyme core of some group I introns from their 3' splice junctions. Using the sunY intron of bacteriophage T4 as a model system, we have investigated the mechanisms by which proximal splicing events are suppressed in vitro, as well as in vivo. Exon ligation as well as cleavage at the 5' splice site are shown to require long-range pairing between one of the peripheral components of the ribozyme core and some of the nucleotides preceding the authentic 3' splice junction. Consistent with our three-dimensional modeling of the entire sunY ribozyme, we propose that this novel interaction is necessary to drive 5' exon-core transcripts into an active conformation. A requirement for additional stabilizing interactions, either RNA-based or mediated by proteins, appears to be a general feature of group I self-splicing. A role for these interactions in mediating putative alternative splicing events is discussed.

Directed evolution of an RNA enzyme

An in vitro evolution procedure was used to obtain RNA enzymes with a particular catalytic function. A population of 10(13) variants of the Tetrahymena ribozyme, a group I ribozyme that catalyzes sequence-specific cleavage of RNA via a phosphoester transfer mechanism, was generated. This enzyme has a limited ability to cleave DNA under conditions of high temperature or high MgCl2 concentration, or both. A selection constraint was imposed on the population of ribozyme variants such that only those individuals that carried out DNA cleavage under physiologic conditions were amplified to produce "progeny" ribozymes. Mutations were introduced during amplification to maintain heterogeneity in the population. This process was repeated for ten successive generations, resulting in enhanced (100 times) DNA cleavage activity.

Circle reopening in the Tetrahymena ribozyme resembles site-specific hydrolysis at the 3' splice site

The Tetrahymena intron, after splicing from its flanking exons, can mediate its own circularization. This is followed by site-specific hydrolysis of the phosphodiester bond formed during the circularization reaction. The structural components involved in recognition of this bond for hydrolysis have not been established. We have made base substitutions to the P9.0 pairing and at the 3'-terminal guanosine residue (G414) of the intron to investigate their effects on circle formation and reopening. We have found that disruption of either P9.0 pairing or binding of the terminal nucleotide result in the formation of a large circle, C-413:5E23 from precursor RNA molecules that have undergone hydrolysis at the 3' splice site. This circle is formed at the phosphodiester bond of the 5'-terminal guanosine residue of the upstream exon via nucleophilic attack by the 3'-terminal nucleotide of the intron. The large circle is novel since it can reopen eight bases downstream from the original circularization junction at a site resembling the normal 3' splice site, restoring a guanosine to the 3' terminus and re-establishing P9.0 pairing. The new 3' terminus of the intron is capable of recircularization at any of the three normal wild-type sites. We conclude that both P9.0 and the 3'-terminal guanosine residue are required for the selection of the phosphodiester bond hydrolysed during circle reopening.

In vitro self-splicing reactions of the chloroplast group I intron Cr.LSU from Chlamydomonas reinhardtii and in vivo manipulation via gene-replacement

The group I intron from the chloroplast rRNA large subunit of Chlamydomonas reinhardtii (Cr.LSU) undergoes autocatalytic splicing in vitro. Cr.LSU displays a range of reactions typical of other group I introns. Under optimal conditions, the 5' cleavage step proceeds rapidly, but the exon-ligation step is relatively slow, and no pH dependent hydrolysis of the 3' splice site occurs. A requirement for high temperature and high [Mg2+] suggests involvement of additional splicing factors in vivo. The positions of three cyclization sites of the free intron have been mapped; two of these sites represent reactions analogous to 5'-splice site cleavage, whereas the third is an example of G-exchange. Cr.LSU contains an open reading frame (ORF) potentially encoding an 163 amino acid polypeptide. ORF function has been investigated by using chloroplast gene replacement via particle bombardment. We have shown that the ORF can be deleted from Cr.LSU without affecting splicing in vivo and it thus does not encode an essential splicing factor.

The antiquity of group I introns

The recent discovery of self-splicing introns in cyanobacteria has given renewed interest to the question of whether introns may have been present in the ancestor of all living things. The properties of introns in genes of bacteria and bacteriophages are discussed in the context of their possible origin and biological function.

Antibiotic inhibition of group I ribozyme function

The discovery of catalytically active RNA has provided the basis for the evolutionary concept of an RNA world. It has been proposed that during evolution the functions of ancient catalytic RNA were modulated by low molecular weight effectors, related to antibiotics, present in the primordial soup. Antibiotics and RNA may have coevolved in the formation of the modern ribosome. Here we report that a set of aminoglycoside antibiotics, which are known to interact with the decoding region of the 16S ribosomal RNA of Escherichia coli, inhibit the second step of splicing of the T4 phage-derived td intron. Thus catalytic RNA seems to interact not only with a mononucleotide and an amino acid, but also with another class of biomolecules, the sugars. Splicing of other group I introns but not group II introns was inhibited. The similarity in affinity and specificity of these antibiotics for group I introns and rRNAs may result from recognition of evolutionarily conserved structures.

The phage T4 nrdB intron: a deletion mutant of a version found in the wild

Bacteriophage T4 possesses three self-splicing group I introns. Two of the three introns are mobile elements; the third, in the gene encoding a subunit of the phage nucleotide reductase (nrdB), is not mobile. Because intron mobility offers a reasonable explanation for the paradoxical occurrence of large intervening sequences in a space-efficient eubacterial phage, it is puzzling that the nrdB intron is not mobile like its compatriots. We have discovered a larger nrdB intron in a closely related phage, and we infer from comparative sequence data that the T4 intron is a deletion mutant derived from this larger intron. This larger nrdB intron encodes an open reading frame of 269 codons, which we have cloned and overexpressed. The overexpressed protein shows a dsDNA endonuclease activity specific for the intronless nrdB gene, typical of mobile introns. Thus, we believe that all three introns of T4 are or were mobile "infectious introns" and that they have entered into and been maintained in the phage population by virtue of this efficient mobility.

Effects of mutations of the bulged nucleotide in the conserved P7 pairing element of the phage T4 td intron on ribozyme function

The P7 element of group I introns contains a semiconserved "bulged" nucleotide, a C in group IA introns (nt 870 in the td intron) and an A in group IB introns [Cech, T.R. (1988) Gene 73, 259-271]. Variants U870, G870, and A870, isolated by a combination of in vitro and in vivo genetic strategies, indicate that C and A at position 870 are consistent with splicing whereas U and G are not. Although mutants G870 and U870 could be activated in vitro by increasing the Mg2+ concentration, their Km for GTP at pH 7 was 20-100-fold elevated, and they were unable to undergo site-specific hydrolysis. The dependence of the mutants on high guanosine concentrations could be substantially overcome by an increase in pH, suggesting that a tautomeric change, which makes U and G mimic C and A, is responsible for restoring function. In contrast to the striking Km effect, Vmax for the mutants differed by less than a factor of 2 from the wild type. Furthermore, streptomycin, an aminoglycoside antibiotic that competes with guanosine for its binding site, inhibited splicing of the U870 and G870 constructs at least as well as of the C870 and A870 variants, indicating that the guanosine-binding site of the mutants is proficient at interacting with a guanidino group. While our experiments argue against a hydrogen-bonding interaction between the C6-O of the cofactor and C4-NH2 of the bulged nucleotide, they are consistent with other models in which the C4-NH2 and/or N3 groups of the bulged C are involved in establishing an active ribozyme.

Six group I introns and three internal transcribed spacers in the chloroplast large subunit ribosomal RNA gene of the green alga Chlamydomonas eugametos

The chloroplast large subunit rRNA gene of Chlamydomonas eugametos and its 5' flanking region encoding tRNA(Ile) (GAU) and tRNA(Ala) (UGC) have been sequenced. The DNA sequence data along with the results of a detailed RNA analysis disclosed two unusual features of this green algal large subunit rRNA gene: (1) the presence of six group I introns (CeLSU.1-CeLSU.6) whose insertion positions have not been described previously, and (2) the presence of three short internal transcribed spacers that are post-transcriptionally excised to yield four rRNA species of 280, 52, 810 and 1720 nucleotides, positioned in this order (5' to 3') in the primary transcript. Together, these RNA species can assume a secondary structure that is almost identical to that proposed for the 23 S rRNA of Escherichia coli. All three internal transcribed spacers map to variable regions of primary sequence and/or potential secondary structure, whereas all six introns lie within highly conserved regions. The first three introns are inserted within the sequence encoding the 810 nucleotide rRNA species and map within domain II of the large subunit rRNA structure; the remaining introns, found in the sequence encoding the 1720 nucleotide rRNA species, lie within either domain IV or V, as is the case for all other large subunit rDNA introns that have been documented to date. CeLSU.5 and CeLSU.6 each contain a long open reading frame (ORF) of more than 200 codons. While the CeLSU.6 ORF is not related to any known ORFs, the CeLSU.5 ORF belongs to a family of ORFs that have been identified in Podospora and Neurospora mitochondrial group I introns. The finding that a polymorphic marker showing unidirectional gene conversion during crosses between C. eugametos and Chlamydomonas moewusii is located within the CeLSU.5 ORF makes it likely that this intron is a mobile element and that its ORF encodes a site-specific endonuclease promoting the transfer of the intron DNA sequence.

Bacterial origin of a chloroplast intron: conserved self-splicing group I introns in cyanobacteria

A self-splicing group I intron has been found in the gene for a leucine transfer RNA in two species of Anabaena, a filamentous nitrogen-fixing cyanobacterium. The intron is similar to one that is found at the identical position in the same transfer RNA gene of chloroplasts of land plants. Because cyanobacteria were the progenitors of chloroplasts, it is likely that group I introns predated the endosymbiotic association of these eubacteria with eukaryotic cells.

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.

Phylogenetic and genetic evidence for base-triples in the catalytic domain of group I introns

Understanding the mechanisms by which ribozymes catalyse chemical reactions requires a detailed knowledge of their structure. The secondary structure of the group I introns has been confirmed by comparison of over 70 published sequences, by chemical protection studies, and by genetic experiments involving compensatory mutations. Phylogenetic data can also be used to identify tertiary interactions in RNA molecules. This was first done by Levitt, who predicted tertiary interactions in transfer RNA, which were subsequently confirmed by X-ray crystallography. More recently, sequence comparison data have been used to predict tertiary interactions in ribosomal RNA. We have searched a complete alignment of the core regions of group I introns for evolutionary covariations that could not be ascribed to classical Watson-Crick or wobble base pairings. Here we describe two examples of phylogenetic covariation that are most simply explained by postulating hydrogen-bonded base-triples similar to those found in tRNA. Genetic experiments with the Tetrahymena and sunY introns confirm the importance of these interactions for the structure of the ribozyme.