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.     

A self-splicing RNA excises an intron lariat

We have investigated the in vitro self-splicing of a class II mitochondrial intron. A model pre-mRNA containing intron 5 gamma of the oxi 3 gene of yeast mitochondrial DNA undergoes an efficient intramolecular rearrangement reaction in vitro. This reaction proceeds under conditions distinct from those optimal for self-splicing of class I introns, such as the Tetrahymena nuclear rRNA intron. Intron 5 gamma is excised as a nonlinear RNA indistinguishable from the in vivo excised intron product by gel electrophoresis and primer extension analysis. Studies of the in vitro excised intron product strongly indicate that it is a branched RNA with a circular component joined by a linkage other than a 3'-5' phosphodiester. Two other products, the spliced exons and the broken form of the lariat, were also characterized. These results show that the class II intron products are similar to those of nuclear pre-mRNA splicing.     

Unexpected metal ion requirements specific for catalysis of the branching reaction in a group II intron

The splicing process catalyzed by group II intron ribozymes follows the same two-step pathway as nuclear pre-mRNA splicing. In vivo, the first splicing step of wild-type introns is a transesterification reaction giving rise to a branched lariat intron-3'-exon intermediate characteristic of this splicing mode. In the wild-type introns, the ribozyme core and the substrate intron-exon junctions are carried by the same precursor molecule, making it difficult to distinguish between RNA folding and catalysis under normal splicing reactions. To characterize the catalytic step of the first transesterification reaction, we studied the reversal of this reaction, reverse branching. In this reverse reaction, the excised lariat intron and the substrate 5'-exon can be preincubated and folded separately, allowing the measure of the catalytic rate of the reaction. To measure the catalytic rate of the second splicing step, purified lariat intron-3'-exon intermediate molecules were preincubated and folded prior to the addition of 5'-exon. Conditions could be found where chemistry appeared rate limiting for both catalytic steps. Study of the metal ion requirements under these conditions resulted in the unexpected finding that, for the intron studied, substitution of magnesium ions by manganese ions enhanced the rate of the first transesterification reaction by two orders of magnitude but had virtually no effect on the second transesterification reaction or the 5' splice site cleavage by hydrolysis. Finally, the catalytic rates measured under optimal conditions for both splicing steps were faster by three orders of magnitude in the branching pathway than in the hydrolytic pathway.     

Directing the outcome of deoxyribozyme selections to favor native 3'-5' RNA ligation

Previous experiments have identified numerous RNA ligase deoxyribozymes, each of which can synthesize either 2',5'-branched RNA, linear 2'-5'-linked RNA, or linear 3'-5'-linked RNA. These products may be formed by reaction of a 2'-hydroxyl or 3'-hydroxyl of one RNA substrate with the 5'-triphosphate of a second RNA substrate. Here the inherent propensities for nucleophilic reactivity of specific hydroxyl groups were assessed using RNA substrates related to the natural sequences of spliceosome substrates and group II introns. With the spliceosome substrates, nearly half of the selected deoxyribozymes mediate a ligation reaction involving the natural branch-point adenosine as the nucleophile. In contrast, mostly linear RNA is obtained with the group II intron substrates. Because the two sets of substrates differ at only three nucleotides, we conclude that the location of the newly created ligation junction in DNA-catalyzed branch formation depends sensitively on the RNA substrate sequences. During the experiment that led primarily to branched RNA, we abruptly altered the selection strategy to demand that the deoxyribozymes create linear 3'-5' linkages by introducing an additional selection step involving the 3'-5'-selective 8-17 deoxyribozyme. Although no 3'-5' linkages (相似文献   

Antifreeze protein pseudogenes.

Three members, 11-3, F2 and 5a, of the type-I antifreeze protein (AFP) multigene family in winter flounder were sequenced. All three belong to the subset of AFP genes that are linked, but irregularly spaced, and show significant differences from the functional genes in tandem repeats. 11-3 and F2 appear to be pseudogenes. Their intron, 3'-exon and 3'-flanking DNAs are similar to those of other AFP genes, but their 5'-exon is either missing or extensively modified, and has stop codons present in all three reading frames. Based on a comparison of intron sequences of family members, 11-3/F2 may represent a residual progenitor AFP gene which was duplicated after reaching pseudogene status. The third gene, 5a, is remarkable in having a 3'-exon that encodes an exceptionally long, Ala-rich sequence that lacks any semblance of the 11-amino acid repeats found in 11-3, F2 and functional AFP genes. 5a might also be a pseudogene, because its presumed TATA box appears to have mutated.     

Isolation and characterization of the gene encoding yeast debranching enzyme.

Using a genetic screen aimed at identifying cellular factors involved in Ty1 transposition, we have identified a mutation in a host gene that reduces Ty1 transposition frequency. The mutant, dbr1, is also defective in the process of intron turnover. In dbr1 cells, excised introns derived from a variety of pre-mRNAs are remarkably stable and accumulate to levels exceeding that of the corresponding mRNA. The stable excised introns accumulate in the form of a lariat that is missing the linear sequences 3' of the branchpoint. The DBR1 gene has been isolated by complementation of the transposition phenotype. DBR1 is shown to encode debranching enzyme, an RNA processing activity that hydrolyzes the 2'-5' phosphodiester linkage at the branchpoint of excised intron lariats. In Saccharomyces cerevisiae, debranching enzyme plays a requisite role in the rapid turnover of excised introns, yet its function is not essential for viability.     

An alternative intron-exon pairing scheme implied by unexpected in vitro activities of group II intron RmInt1 from Sinorhizobium meliloti

RmInt1 is a mobile group II intron which interrupts ISRm2011-2, another mobile element from the bacterium Sinorhizobium meliloti. Ribozyme constructs derived from intron RmInt1 self-splice in vitro when incubated under permissive conditions, but the excised intron and ligated exons are largely replaced by unconventional products. These include a slightly shorter, 5'-end truncated 3' exon, truncated variants of the linear and lariat forms of the intron-3' exon reaction intermediate, as well as presumably circular molecules derived from the latter. Two factors explain the abundance of these products: (i) nucleotides 5-11 of the 3' exon (IBS1*) provide a better match to the EBS1 5'-exon-binding site than the authentic IBS1 sequence in the 5' exon; (ii) exon ligation is unusually inefficient, and especially so when the 5' exon is truncated close to the second (IBS2) intron-binding site. We propose that reactions at the IBS1* site play a part in the regulation of the intron ISRm2011-2 host in vivo.     

A base triple in the Tetrahymena group I core affects the reaction equilibrium via a threshold effect

Previous work on group I introns has suggested that a central base triple might be more important for the first rather than the second step of self-splicing, leading to a model in which the base triple undergoes a conformational change during self-splicing. Here, we use the well-characterized L-21 ScaI ribozyme derived from the Tetrahymena group I intron to probe the effects of base-triple disruption on individual reaction steps. Consistent with previous results, reaction of a ternary complex mimicking the first chemical step in self-splicing is slowed by mutations in this base triple, whereas reaction of a ternary complex mimicking the second step of self-splicing is not. Paradoxically, mechanistic dissection of the base-triple disruption mutants indicates that active site binding is weakened uniformly for the 5'-splice site and the 5'-exon analog, mimics for the species bound in the first and second step of self-splicing. Nevertheless, the 5'-exon analog remains bound at the active site, whereas the 5'-splice site analog does not. This differential effect arises despite the uniform destabilization, because the wild-type ribozyme binds the 5'-exon analog more strongly in the active site than in the 5'-splice site analog. Thus, binding into the active site constitutes an additional barrier to reaction of the 5'-splice site analog, but not the 5'-exon analog, resulting in a reduced reaction rate constant for the first step analog, but not the second step analog. This threshold model explains the self-splicing observations without the need to invoke a conformational change involving the base triple, and underscores the importance of quantitative dissection for the interpretation of effects from mutations.     

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.     

Novel splicing mechanism for the ribosomal RNA intron in the archaebacterium Desulfurococcus mobilis

The intron of the 23S rRNA gene of D. mobilis is excised from the pre-23S RNA at specific sites in vivo and subsequently ligated to form a stable circular RNA, with a normal 5'-3' phosphodiester bond, containing the entire intron sequence; 95% of this RNA codes for a protein of 194 amino acids that can be expressed in E. coli. Crude cell extracts from D. mobilis also induce a two-step slicing reaction in vitro, producing the same circular intron RNA but a low yield of ligated exons. Cleavage depends on the RNA structure adjacent to the cleavage site and yields a 3'-terminal phosphate. Splicing is enhanced by GTP, but does not require divalent metal ions. The cleavage and exon-splicing reactions resemble those found for tRNA introns in eukaryotes and a possible structural rationale for this similarity is considered together with its possible implications for the origin of eukaryotic rRNA and tRNA introns.     

A complex twintron is excised as four individual introns.

Twintrons are introns-within-introns excised by sequential splicing reactions. A new type of complex twintron comprised of four individual group III introns has been characterized. The external intron is interrupted by an internal intron containing two additional introns. This 434 nt complex twintron within a Euglena gracilis chloroplast ribosomal protein gene is excised by four sequential splicing reactions. Two of the splicing reactions utilize multiple 5'- and/or 3'-splice sites. These findings are evidence that introns with multiple active splice sites can be formed by the repeated insertion of introns into existing introns.     

Ribonucleoprotein complex formation during pre-mRNA splicing in vitro.

The ribonucleoprotein (RNP) structures of the pre-mRNA and RNA processing products generated during in vitro splicing of an SP6/beta-globin pre-mRNA were characterized by sucrose gradient sedimentation analysis. Early, during the initial lag phase of the splicing reaction, the pre-mRNA sedimented heterogeneously but was detected in both 40S and 60S RNP complexes. An RNA substrate lacking a 3' splice site consensus sequence was not assembled into the 60S RNP complex. The two splicing intermediates, the first exon RNA species and an RNA species containing the intron and the second exon in a lariat configuration (IVS1-exon 2 RNA species), were found exclusively in a 60S RNP complex. These two splicing intermediates cosedimented under a variety of conditions, indicating that they are contained in the same RNP complex. The products of the splicing reaction, accurately spliced RNA and the excised IVS1 lariat RNA species, are released from the 60S RNP complex and detected in smaller RNP complexes. Sequence-specific RNA-factor interactions within these RNP complexes were evidenced by the preferential protection of the pre-mRNA branch point from RNase A digestion and protection of the 2'-5' phosphodiester bond of the lariat RNA species from enzymatic debranching. The various RNP complexes were further characterized and could be distinguished by immunoprecipitation with anti-Sm and anti-(U1)RNP antibodies.     

Yeast mRNA splicing in vitro

Synthetic actin and CYH2 pre-mRNAs containing a single intron are accurately spliced in a soluble whole cell extract of yeast. Splicing in vitro requires ATP. The excised intron is released as a lariat in which an RNA branch connects the 5' end of the molecule to the last A in the "intron conserved sequence" UACUAAC. Two other discrete RNA species produced during splicing in vitro may represent reaction intermediates: free, linear exon 1 and a form of the intron lariat extending beyond the 3' splice site to include exon 2. Both lariat forms correspond to molecules previously shown to be produced during yeast pre-mRNA splicing in vivo.     

New RNA-mediated reactions by yeast mitochondrial group I introns.

The group I self-splicing reaction is initiated by attack of a guanosine nucleotide at the 5' splice site of intron-containing precursor RNA. When precursor RNA containing a yeast mitochondrial group I intron is incubated in vitro under conditions of self-splicing, guanosine nucleotide attack can also occur at other positions: (i) the 3' splice site, resulting in formation of a 3' exon carrying an extra added guanosine nucleotide at its 5' end; (ii) the first phosphodiester bond in precursor RNA synthesized from the SP6 bacteriophage promoter, leading to substitution of the first 5'-guanosine by a guanosine nucleotide from the reaction mixture; (iii) the first phosphodiester bond in already excised intron RNA, resulting in exchange of the 5' terminal guanosine nucleotide for a guanosine nucleotide from the reaction mixture. An identical sequence motif (5'-GAA-3') occurs at the 3' splice site, the 5' end of SP6 precursor RNA and at the 5' end of excised intron RNA. We propose that the aberrant reactions can be explained by base-pairing of the GAA sequence to the Internal Guide Sequence. We suggest that these reactions are mediated by the same catalytic centre of the intron RNA that governs the normal splicing reactions.     

The structure of precursor mRNAs and of excised intron RNAs in chloroplasts of Euglena gracilis

Partially spliced precursor mRNAs (pre-mRNAs) in the steady-state population of RNA from chloroplasts of Euglena gracilis were found by electron microscopy. The structure and the frequency of the pre-mRNAs of the psbA gene (the gene for the 32-kd protein of photosystem II), which is split by four introns in Euglena chloroplasts was analysed by electron microscopy. A chloroplast DNA (cpDNA) fragment containing the psbA gene from Euglena, was cloned into a pEMBL vector. The single-stranded recombinant phage DNA of the coding strand was prepared and hybridized with cpRNA. The majority of hybrids were formed with mature mRNA, but approximately 8% of the hybrids were formed with pre-mRNAs. The pre-mRNAs were either unspliced or incompletely spliced. A detailed analysis of the structure and the frequency of the pre-mRNAs of the psbA gene showed that the four introns are neither spliced out in a strictly random way, nor in a 5'-3' or 3'-5' direction. Introns 2 and 3 are preferentially spliced out first, intron 1 intermediately and intron 4 is generally spliced out last. However, this sequence is not a strict rule. We conclude that the introns can be spliced independently, each one at a different rate. The coding strand from a fragment of the psbA gene was separated and annealed with low mol. wt. cpRNA, which was isolated from an agarose gel. Small circular hybrids were found at the positions of the four introns, demonstrating for the first time covalently closed circular excised intron RNAs (iRNAs) in chloroplasts.     

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

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