The gene coding for small ribosomal subunit RNA in the basidiomycete Ustilago maydis contains a group I intron.

The nucleotide sequence of the gene coding for small ribosomal subunit RNA in the basidiomycete Ustilago maydis was determined. It revealed the presence of a group I intron with a length of 411 nucleotides. This is the third occurrence of such an intron discovered in a small subunit rRNA gene encoded by a eukaryotic nuclear genome. The other two occurrences are in Pneumocystis carinii, a fungus of uncertain taxonomic status, and Ankistrodesmus stipitatus, a green alga. The nucleotides of the conserved core structure of 101 group I intron sequences present in different genes and genome types were aligned and their evolutionary relatedness was examined. This revealed a cluster including all group I introns hitherto found in eukaryotic nuclear genes coding for small and large subunit rRNAs. A secondary structure model was designed for the area of the Ustilago maydis small ribosomal subunit RNA precursor where the intron is situated. It shows that the internal guide sequence pairing with the intron boundaries fits between two helices of the small subunit rRNA, and that minimal rearrangement of base pairs suffices to achieve the definitive secondary structure of the 18S rRNA upon splicing.     

Association of a group I intron with its splice junction in 50S ribosomes: implications for intron toxicity.

The effect of genetic context on splicing of group I introns is not well understood at present. The influence of ribosomal RNA conformation on splicing of rDNA introns in vivo was investigated using a heterologous system in which the Tetrahymena group I intron is inserted into the homologous position of the Escherichia coli 23S rRNA. Mutations that block splicing in E. coli result in accumulation of unspliced 23S rRNA that is assembled into 50S complexes, but not 70S ribosomes. The data indicate that accommodation of the intron structure on the surface of the 50S subunit inhibits interactions with the small ribosomal subunit. Spliced intron RNA also remains noncovalently bound to 50S subunits on sucrose gradients. This interaction appears to be mediated by base pairing between the intron guide sequence and the 23S rRNA, because the fraction of bound intron RNA is reduced by point mutations in the IGS or deletion of the P1 helix. Association of the intron with 50S subunits correlates with slow cell growth. The results suggest that group I introns have the potential to inhibit protein synthesis in prokaryotes by direct interactions with ribosomes.     

Unwinding by Local Strand Separation Is Critical for the Function of DEAD-Box Proteins as RNA Chaperones

The DEAD-box proteins CYT-19 in Neurospora crassa and Mss116p in Saccharomyces cerevisiae are broadly acting RNA chaperones that function in mitochondria to stimulate group I and group II intron splicing and to activate mRNA translation. Previous studies showed that the S. cerevisiae cytosolic/nuclear DEAD-box protein Ded1p could stimulate group II intron splicing in vitro. Here, we show that Ded1p complements mitochondrial translation and group I and group II intron splicing defects in mss116Δ strains, stimulates the in vitro splicing of group I and group II introns, and functions indistinguishably from CYT-19 to resolve different nonnative secondary and/or tertiary structures in the Tetrahymena thermophila large subunit rRNA-ΔP5abc group I intron. The Escherichia coli DEAD-box protein SrmB also stimulates group I and group II intron splicing in vitro, while the E. coli DEAD-box protein DbpA and the vaccinia virus DExH-box protein NPH-II gave little, if any, group I or group II intron splicing stimulation in vitro or in vivo. The four DEAD-box proteins that stimulate group I and group II intron splicing unwind RNA duplexes by local strand separation and have little or no specificity, as judged by RNA-binding assays and stimulation of their ATPase activity by diverse RNAs. In contrast, DbpA binds group I and group II intron RNAs nonspecifically, but its ATPase activity is activated specifically by a helical segment of E. coli 23S rRNA, and NPH-II unwinds RNAs by directional translocation. The ability of DEAD-box proteins to stimulate group I and group II intron splicing correlates primarily with their RNA-unwinding activity, which, for the protein preparations used here, was greatest for Mss116p, followed by Ded1p, CYT-19, and SrmB. Furthermore, this correlation holds for all group I and group II intron RNAs tested, implying a fundamentally similar mechanism for both types of introns. Our results support the hypothesis that DEAD-box proteins have an inherent ability to function as RNA chaperones by virtue of their distinctive RNA-unwinding mechanism, which enables refolding of localized RNA regions or structures without globally disrupting RNA structure.     

Reverse splicing of the Tetrahymena IVS: evidence for multiple reaction sites in the 23S rRNA.

Group I introns in rRNA genes are clustered in highly conserved regions that include tRNA and mRNA binding sites. This pattern is consistent with insertion of group I introns by direct interaction with exposed regions of rRNA. Integration of the Tetrahymena group I intron (or intervening sequence, IVS) into large subunit rRNA via reverse splicing was investigated using E. coli 23S rRNA as a model substrate. The results show that sequences homologous to the splice junction in Tetrahymena are the preferred site of integration, but that many other sequences in the 23S rRNA provide secondary targets. Like the original splice junction, many new reaction sites are in regions of stable secondary structure. Reaction at the natural splice junction is observed in 50S subunits and to a lesser extent in 70S ribosomes. These results support the feasibility of intron transposition to new sites in rRNA genes via reverse splicing.     

Self-splicing of yeast mitochondrial ribosomal and messenger RNA precursors

We have previously shown linear and circular splicing intermediates resembling intermediates that result from self-splicing of ribosomal precursor RNA of Tetrahymena to be present in mitochondrial RNA. Here we show that splicing of yeast mitochondrial precursor RNA also occurs in vitro in the absence of mitochondrial proteins. The large ribosomal RNA gene, consisting of the intron and part of the flanking exon regions, was inserted behind the SP6 promoter in a recombinant plasmid and was transcribed in vitro. The resulting RNA shows self-catalyzed splicing via incorporation of GTP at the 5'-end of the excised intron, 5'- to 3'-exon ligation, and intron circularization. When purified mitochondrial RNA is incubated under similar conditions with alpha-32P-GTP, the excised ribosomal intron RNA is also labeled, as well as several other RNA species. Some of these RNAs are derived from excised introns from the multiply split gene coding for cytochrome oxidase subunit I.     

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

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

Long-term evolution of the S788 fungal nuclear small subunit rRNA group I introns

More than 1000 group I introns have been identified in fungal rDNA. Little is known, however, of the splicing and secondary structure evolution of these ribozymes. Here, we use a combination of comparative and biochemical methods to address the evolution and splicing of a vertically inherited group I intron found at position 788 in the fungal small subunit (S) rRNA. The ancestral state of the S788 intron contains a highly conserved core and an extended P5 domain typical of IC1 introns. In contrast, the more derived introns have lost most of P5, and have an accelerated divergence rate within the core region with three functionally important substitutions that unambiguously separate them from the ancestral pool. Of 14 S788 group I introns that were tested for splicing, five, all of the ancestral type, were able to self-splice and produced intron RNA circles in vitro. The more derived S788 introns did not self-splice, and potentially rely on fungal-specific factors to facilitate splicing. In summary, we demonstrate one possible fate of vertically inherited group I introns, the loss of secondary structure elements, lessened selective constraints in the intron core, and ultimately, dependence on host-mediated splicing.     

The Neurospora crassa CYT-18 protein C-terminal RNA-binding domain helps stabilize interdomain tertiary interactions in group I introns

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) promotes the splicing of group I introns by stabilizing the catalytically active RNA structure. To accomplish this, CYT-18 recognizes conserved structural features of group I intron RNAs using regions of the N-terminal nucleotide-binding fold, intermediate alpha-helical, and C-terminal RNA-binding domains that also function in binding tRNA(Tyr). Curiously, whereas the splicing of the N. crassa mitochondrial large subunit rRNA intron is completely dependent on CYT-18's C-terminal RNA-binding domain, all other group I introns tested thus far are spliced efficiently by a truncated protein lacking this domain. To investigate the function of the C-terminal domain, we used an Escherichia coli genetic assay to isolate mutants of the Saccharomyces cerevisiae mitochondrial large subunit rRNA and phage T4 td introns that can be spliced in vivo by the wild-type CYT-18 protein, but not by the C-terminally truncated protein. Mutations that result in dependence on CYT-18's C-terminal domain include those disrupting two long-range GNRA tetraloop/receptor interactions: L2-P8, which helps position the P1 helix containing the 5'-splice site, and L9-P5, which helps establish the correct relative orientation of the P4-P6 and P3-P9 domains of the group I intron catalytic core. Our results indicate that different structural mutations in group I intron RNAs can result in dependence on different regions of CYT-18 for RNA splicing.     

Function of the Neurospora crassa mitochondrial tyrosyl-tRNA synthetase in RNA splicing. Role of the idiosyncratic N-terminal extension and different modes of interaction with different group I introns

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (CYT-18 protein) promotes the splicing of group I introns by helping the intron RNA fold into the catalytically active structure. The regions required for splicing include an idiosyncratic N-terminal extension, the nucleotide-binding fold domain, and the C-terminal RNA-binding domain. Here, we show that the idiosyncratic N-terminal region is in fact comprised of two functionally distinct parts: an upstream region consisting predominantly of a predicted amphipathic alpha-helix (H0), which is absent from bacterial tyrosyl-tRNA synthetases (TyrRSs), and a downstream region, which contains predicted alpha-helices H1 and H2, corresponding to features in the X-ray crystal structure of the Bacillus stearothermophilus TyrRS. Bacterial genetic assays with libraries of CYT-18 mutants having random mutations in the N-terminal region identified functionally important amino acid residues and supported the predicted structures of the H0 and H1 alpha-helices. The function of N and C-terminal domains of CYT-18 was investigated by detailed biochemical analysis of deletion mutants. The results confirmed that the N-terminal extension is required only for splicing activity, but surprisingly, at least in the case of the N. crassa mitochondrial (mt) large ribosomal subunit (LSU) intron, it appears to act primarily by stabilizing the structure of another region that interacts directly with the intron RNA. The H1/H2 region is required for splicing activity and TyrRS activity with the N. crassa mt tRNA(Tyr), but not for TyrRS activity with Escherichia coli tRNA(Tyr), implying a somewhat different mode of recognition of the two tyrosyl-tRNAs. Finally, a CYT-18 mutant lacking the N-terminal H0 region is totally defective in binding or splicing the N. crassa ND1 intron, but retains substantial residual activity with the mt LSU intron, and conversely, a CYT-18 mutant lacking the C-terminal RNA-binding domain is totally defective in binding or splicing the mt LSU intron, but retains substantial residual activity with the ND1 intron. These findings lead to the surprising conclusion that CYT-18 promotes splicing via different sets of interactions with different group I introns. We suggest that these different modes of promoting splicing evolved from an initial interaction based on the recognition of conserved tRNA-like structural features of the group I intron catalytic core.     

The neurospora CYT-18 protein suppresses defects in the phage T4 td intron by stabilizing the catalytically active structure of the intron core.

The Neurospora CYT-18 protein, a tyrosyl-tRNA synthetase, which functions in splicing group I introns in mitochondria, promotes splicing of mutants of the distantly related bacteriophage T4 td intron. In an in vivo assay, wild-type CYT-18 protein expressed in E. coli suppressed mutations in the td intron's catalytic core. CYT-18-suppressible mutations were also suppressed by high Mg2+ or spermidine in vitro, suggesting they affect intron structure. Both the N- and C-terminal domains of CYT-18 are required for efficient splicing, but CYT-18 with a large C-terminal truncation retains some activity. Our results indicate that CYT-18 interacts with conserved structural features of group I introns, and they provide direct evidence that a protein promotes splicing by stabilizing the catalytically active structure of the intron RNA.     

Trans-activation of the Tetrahymena group I intron ribozyme via a non-native RNA-RNA interaction

The peripheral P2.1 domain of the Tetrahymena group I intron ribozyme has been shown to be non-essential for splicing. We found, however, that separately prepared P2.1 RNA efficiently accelerates the 3' splice-site-specific hydrolysis reaction of a mutant ribozyme lacking both P2.1 and its upstream region in trans. We report here the unusual properties of this trans-activation. Compensatory mutational analysis revealed that non-native long-range base-pairings between the loop region of P2.1 RNA and L5c region of the mutant ribozyme are needed for the activation in spite of the fact that P2.1 forms base-pairings with P9.1 in the Tetrahymena ribozyme. The trans -activation depends on the non-native RNA-RNA interaction together with the higher order structure of P2.1 RNA. This activation is unique among the known trans-activations that utilize native tertiary interactions or RNA chaperons.     

NMR Structure of the C-terminal domain of a tyrosyl-tRNA synthetase that functions in group I intron splicing

The mitochondrial tyrosyl-tRNA synthetases (mt TyrRSs) of Pezizomycotina fungi are bifunctional proteins that aminoacylate mitochondrial tRNA(Tyr) and are structure-stabilizing splicing cofactors for group I introns. Studies with the Neurospora crassa synthetase (CYT-18 protein) showed that splicing activity is dependent upon Pezizomycotina-specific structural adaptations that form a distinct group I intron-binding site in the N-terminal catalytic domain. Although CYT-18's C-terminal domain also binds group I introns, it has been intractable to X-ray crystallography in the full-length protein. Here, we determined an NMR structure of the isolated C-terminal domain of the Aspergillus nidulans mt TyrRS, which is closely related to but smaller than CYT-18's. The structure shows an S4 fold like that of bacterial TyrRSs, but with novel features, including three Pezizomycontia-specific insertions. (15)N-(1)H two-dimensional NMR showed that C-terminal domains of the full-length A. nidulans and Geobacillus stearothermophilus synthetases do not tumble independently in solution, suggesting restricted orientations. Modeling onto a CYT-18/group I intron cocrystal structure indicates that the C-terminal domains of both subunits of the homodimeric protein bind different ends of the intron RNA, with one C-terminal domain having to undergo a large shift on its flexible linker to bind tRNA(Tyr) or the intron RNA on either side of the catalytic domain. The modeling suggests that the C-terminal domain acts together with the N-terminal domain to clamp parts of the intron's catalytic core, that at least one C-terminal domain insertion functions in group I intron binding, and that some C-terminal domain regions bind both tRNA(Tyr) and group I intron RNAs.     

Activity of chimeric RNAs of U6 snRNA and (-)sTRSV in the cleavage of a substrate RNA.

U6 small nuclear RNA is one of the spliceosomal RNAs essential for pre-mRNA splicing. Discovery of mRNA-type introns in the highly conserved region of the U6 snRNA genes led to the hypothesis that U6 snRNA functions as a catalytic element during pre-mRNA splicing. The highly conserved region of U6 snRNA has a structural similarity with the catalytic domain of the negative strand of the satellite RNA of tobacco ring spot virus [(-)sTRSV], suggesting that the highly conserved region of U6 snRNA forms the catalytic center. We examined whether synthetic RNAs consisting of the sequence of the highly conserved region of U6 snRNA or various chimeric RNAs between the U6 region and the catalytic RNA of (-)sTRSV could cleave a substrate RNA that can partially base-pair with them and have a GU sequence. Chimeric RNAs with 70 to 83% sequence identity with the conserved region of S. pombe U6 snRNA cleaved the substrate RNA at the 5' side of the GU sequence, which is shared by the 5' end of an intron in a pre-mRNA. We found that the highly conserved region of U6 snRNA and the catalytic domain of (-)sTRSV are strikingly similar in structure to the catalytic core region of the group I self-splicing intron in cyanobacteria. These results suggest that U6 snRNA, (-)sTRSV and the group I self-splicing intron originated from a common ancestral RNA, and support the hypothesis that U6 snRNA catalyzes pre-mRNA splicing reaction.     

Self-splicing RNA and an RNA enzyme in Tetrahymena

The RNA molecules transcribed from many eukaryotic genes are interrupted by intervening sequences, which are removed by a process called RNA splicing. One structurally related group of intervening sequences, the group I intervening sequences, are found in a variety of microorganisms. Some of these, including the group I intervening sequence from the ribosomal RNA precursor of Tetrahymena thermophila, have been shown to mediate their own splicing in an RNA-catalyzed reaction. Following its excision from the ribosomal RNA precursor, the Tetrahymena intervening sequence acts as an enzyme, cutting and rejoining RNA substrates.     

In vivo facilitation of Tetrahymena group I intron splicing in Escherichia coli pre-ribosomal RNA.

The observation that the large ribosomal RNA intron of Tetrahymena is spliced 20-50-fold more rapidly in vivo than in vitro (Brehm SL, Cech TR, 1983, Biochemistry 22:2390-2397; Bass BL, Cech TR, 1984, Nature 308:820-826) suggests facilitation of RNA folding in vivo. To determine whether a specific group I splicing factor is required in Tetrahymena, the intron was inserted into the analogous position of the Escherichia coli 23S rRNA. We report that the intron is rapidly excised from pre-rRNA in bacteria and that the magnitude of the in vivo rate enhancement is similar to that in Tetrahymena. These results demonstrate that a species-specific protein is not required. Instead, a common mechanism of assisting RNA folding is sufficient to accelerate the removal of self-splicing introns from ribosomal RNA.     

Interlocked RNA circle formation by a self-splicing yeast mitochondrial group I intron

RNA containing the aI3 group I intron of the yeast mitochondrial gene encoding cytochrome oxidase subunit I shows self-splicing in vitro. The excised intron, comprising 1514 nucleotides, is partially split into an upstream portion, containing the intronic reading frame, and a downstream portion, containing the typical group I conserved sequence elements. Full-length intron RNA and intron parts occur in linear and circular form. In the transesterification reactions leading to circle formation, only the guanosine nucleotide added during splicing is removed. Reincubation of isolated, complete circular intron RNA under self-splicing conditions leads to formation of free subintronic RNA circles. Under similar conditions, purified linear intron RNA gives rise to a number of circular and linear products, one of which consists of interlocked subintronic RNA circles. These observations suggest that the intron RNA possesses a dynamic structure in which subtle alterations in folding result in the formation of RNA products with different topology.