Mutational analysis of conserved nucleotides in a self-splicing group I intron.

We have constructed all single base substitutions in almost all of the highly conserved residues of the Tetrahymena self-splicing intron. Mutation of highly conserved residues almost invariably leads to loss of enzymatic activity. In many cases, activity could be regained by making additional mutations that restored predicted base-pairings; these second site suppressors in general confirm the secondary structure derived from phylogenetic data. At several positions, our suppression data can be most readily explained by assuming non-Watson-Crick base-pairings. In addition to the requirements imposed by the secondary structure, the sequence of the intron is constrained by "negative interactions", the exclusion of particular nucleotide sequences that would form undesirable secondary structures. A comparison of genetic and phylogenetic data suggests sites that may be involved in tertiary structural interactions.     

CBP2 protein promotes in vitro excision of a yeast mitochondrial group I intron.

The terminal intron (bI2) of the yeast mitochondrial cytochrome b gene is a group I intron capable of self-splicing in vitro at high concentrations of Mg2+. Excision of bI2 in vivo, however, requires a protein encoded by the nuclear gene CBP2. The CBP2 protein has been partially purified from wild-type yeast mitochondria and shown to promote splicing at physiological concentrations of Mg2+. The self-splicing and protein-dependent splicing reactions utilized a guanosine nucleoside cofactor, the hallmark of group I intron self-splicing reactions. Furthermore, mutations that abolished the autocatalytic activity of bI2 also blocked protein-dependent splicing. These results indicated that protein-dependent excision of bI2 is an RNA-catalyzed process involving the same two-step transesterification mechanism responsible for self-splicing of group I introns. We propose that the CBP2 protein binds to the bI2 precursor, thereby stabilizing the catalytically active structure of the RNA. The same or a similar RNA structure is probably induced by high concentrations of Mg2+ in the absence of protein. Binding of the CBP2 protein to the unspliced precursor was supported by the observation that the protein-dependent reaction was saturable by the wild-type precursor. Protein-dependent splicing was competitively inhibited by excised bI2 and by a splicing-defective precursor with a mutation in the 5' exon near the splice site but not by a splicing-defective precursor with a mutation in the core structure. Binding of the CBP2 protein to the precursor RNA had an effect on the 5' splice site helix, as evidenced by suppression of the interaction of an exogenous dinucleotide with the internal guide sequence.     

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.     

Mne1 is a novel component of the mitochondrial splicing apparatus responsible for processing of a COX1 group I intron in yeast

Saccharomyces cerevisiae cells lacking Mne1 are deficient in intron splicing in the gene encoding the Cox1 subunit of cytochrome oxidase but contain wild-type levels of the bc(1) complex. Thus, Mne1 has no role in splicing of COB introns or expression of the COB gene. Northern experiments suggest that splicing of the COX1 aI5β intron is dependent on Mne1 in addition to the previously known Mrs1, Mss116, Pet54, and Suv3 factors. Processing of the aI5β intron is similarly impaired in mne1Δ and mrs1Δ cells and overexpression of Mrs1 partially restores the respiratory function of mne1Δ cells. Mrs1 is known to function in the initial transesterification reaction of splicing. Mne1 is a mitochondrial matrix protein loosely associated with the inner membrane and is found in a high mass ribonucleoprotein complex specifically associated with the COX1 mRNA even within an intronless strain. Mne1 does not appear to have a secondary function in COX1 processing or translation, because disruption of MNE1 in cells containing intronless mtDNA does not lead to a respiratory growth defect. Thus, the primary defect in mne1Δ cells is splicing of the aI5β intron in COX1.     

Bidirectional effectors of a group I intron ribozyme.

The group I self-splicing introns found in many organisms are competitively inhibited by L-arginine. We have found that L-arginine acts stereoselectively on the Pc1. LSU nuclear group I intron of Pneumocystis carinii, competitively inhibiting the first (cleavage) step of the splicing reaction and stimulating the second (ligation) step. Stimulation of the second step is most clearly demonstrated in reactions whose first step is blocked after 15 min by addition of pentamidine. The guanidine moiety of arginine is required for both effects. L-Canavanine is a more potent inhibitor than L-arginine yet it fails to stimulate. L-Arginine derivatized on its carboxyl group as an amide, ester or peptide is more potent than L-arginine as a stimulator and inhibitor, with di-arginine amide and tri-arginine being the most potent effectors tested. The most potent peptides tested are 10,000 times as effective as L-arginine in inhibiting ribozyme activity, and nearly 400 times as effective as stimulators. Arginine and some of its derivatives apparently bind to site(s) on the ribozyme to alter its conformation to one more active in the second step of splicing while competing with guanosine substrate in the first step. This phenomenon indicates that ribozymes, like protein enzymes, can be inhibited or stimulated by non-substrate low molecular weight compounds, which suggests that such compounds may be developed as pharmacological agents acting on RNA targets.     

Intron 5 alpha of the COXI gene of yeast mitochondrial DNA is a mobile group I intron.

We have found that intron 5 alpha of the COXI gene (al5 alpha) of yeast mtDNA is a mobile group I intron in crosses between strains having or lacking the intron. We have demonstrated the following hallmarks of that process: 1) co-conversion of flanking optional intron markers; 2) mutations that truncate the intron open reading frame block intron mobility; and 3) the intron open reading frame encodes an endonuclease activity that is required for intron movement. The endonuclease activity, termed I-Sce IV, cleaves the COXI allele lacking al5 alpha near the site of intron insertion, making a four-base staggered cut with 3' OH overhangs. Three cloned DNAs derived from different forms of the COXI gene, which differ in primary sequence at up to seven nucleotides around the cleavage site, are all good substrates for in vitro I-Sce IV cleavage activity. Two of the strains from which these substrates were derived were tested in crosses and are comparably efficient as al5 alpha recipients. When compared with omega mobility occurring simultaneously in one cross, al5 alpha is less efficient as a mobile element.     

Structure and thermodynamics of metal binding in the P5 helix of a group I intron ribozyme.

The solution structure of an RNA hairpin modelling the P5 helix of a group I intron, complexed with Co(NH3)63+, has been determined by nuclear magnetic resonance. Co(NH3)63+, which possesses a geometry very close to Mg(H2O)62+, was used to identify and characterize a Mg2+binding site in the RNA. Strong and positive intermolecular nuclear Overhauser effect (NOE) cross-peaks define a specific complex in which the Co(NH3)63+molecule is in the major groove of tandem G.U base-pairs. The structure of the RNA is characterized by a very low twist angle between the two G.U base-pairs, providing a flat and narrowed major groove. The Co(NH3)63+, although highly localized, is free to rotate to hydrogen bond in several ways to the O4 atoms of the uracil bases and to N7 and O6 of the guanine bases. Negative and small NOE cross-peaks to other protons in the sequence reveal a non-specific or delocalized interaction, characterized by a high mobility of the cobalt ion. Mn2+titrations of P5 show specific broadening of protons of the G.U base-pairs that form the metal ion binding site, in agreement with the NOE data from Co(NH3)63+. Binding constants for the interaction of Co(NH3)63+and of Mg2+to P5 were determined by monitoring imino proton chemical shifts during titration of the RNA with the metal ions. Dissociation constants are on the order of 0.1 mM for Co(NH3)63+and 1 mM for Mg2+. Binding studies were done on mutants with sequences corresponding to the three orientations of tandem G.U base-pairs. The affinities of Co(NH3)63+and Mg2+for the tandem G.U base-pairs depend strongly on their sequences; the differences can be understood in terms of the different structures of the corresponding metal ion-RNA complexes. Substitution of G.C or A.U for G.U pairs also affected the binding, as expected. These structural and thermodynamic results provide systematic new information about major groove metal ion binding in RNA.     

Multiple acquisitions via horizontal transfer of a group I intron in the mitochondrial cox1 gene during evolution of the Araceae family.

A group I intron has recently been shown to have invaded mitochondrial cox1 genes by horizontal transfer many times during the broad course of angiosperm evolution. To investigate the frequency of acquisition of this intron within a more closely related group of plants, we determined its distribution and inferred its evolutionary history among 14 genera of the monocot family Araceae. Southern blot hybridizations showed that 6 of the 14 genera contain this intron in their cox1 genes. Nucleotide sequencing showed that these six introns are highly similar in sequence (97.7%-99.4% identity) and identical in length (966 nt). Phylogenetic evidence from parsimony reconstructions of intron distribution and phylogenetic analyses of intron sequences is consistent with a largely vertical history of intron transmission in the family; the simplest scenarios posit but one intron gain and two losses. Despite this, however, striking differences in lengths of exonic co-conversion tracts, coupled with the absence of co-conversion in intron-lacking taxa, indicate that the six intron-containing Araceae probably acquired their introns by at least three and quite possibly five separate horizontal transfers. The highly similar nature of these independently acquired introns implies a closely related set of donor organisms.     

Requirements for self-splicing of a group I intron from Physarum polycephalum.

The third intron from Physarum polycephalum (Pp LSU 3) is one of the closest known relatives to the well-studied Tetrahymena group I intron. Both introns are located at the same position in the 26S rRNA gene, and with the exception of an open reading frame in Pp LSU 3, are highly homologous. While Pp LSU 3 has been shown to self splice, little is known about its activity in vitro. We have examined the requirements for self splicing in greater detail. Despite its similarity to the Tetrahymena intron, Pp LSU 3 is 1500-fold less reactive, demonstrates a preference for high salt, and exhibits a low Km for GTP. Removal of the open reading frame results in a modest increase of activity. This system provides an opportunity to understand how sequence variations in two related introns alter the efficiency of autoexcision, and how this relates to adaptation of group I introns to their particular sequence context.     

Incongruence between primary sequence data and the distribution of a mitochondrial atp1 group II intron among ferns and horsetails

Using DNA sequence data from multiple genes (often from more than one genome compartment) to reconstruct phylogenetic relationships has become routine. Augmenting this approach with genomic structural characters (e.g., intron gain and loss, changes in gene order) as these data become available from comparative studies already has provided critical insight into some long-standing questions about the evolution of land plants. Here we report on the presence of a group II intron located in the mitochondrial atp1 gene of leptosporangiate and marattioid ferns. Primary sequence data for the atp1 gene are newly reported for 27 taxa, and results are presented from maximum likelihood-based phylogenetic analyses using Bayesian inference for 34 land plants in three data sets: (1) single-gene mitochondrial atp1 (exon+intron sequences); (2) five combined genes (mitochondrial atp1 [exon only]; plastid rbcL, atpB, rps4; nuclear SSU rDNA); and (3) same five combined genes plus morphology. All our phylogenetic analyses corroborate results from previous fern studies that used plastid and nuclear sequence data: the monophyly of euphyllophytes, as well as of monilophytes; whisk ferns (Psilotidae) sister to ophioglossoid ferns (Ophioglossidae); horsetails (Equisetopsida) sister to marattioid ferns (Marattiidae), which together are sister to the monophyletic leptosporangiate ferns. In contrast to the results from the primary sequence data, the genomic structural data (atp1 intron distribution pattern) would seem to suggest that leptosporangiate and marattioid ferns are monophyletic, and together they are the sister group to horsetails--a topology that is rarely reconstructed using primary sequence data.     

Compensatory mutations demonstrate that P8 and P6 are RNA secondary structure elements important for processing of a group I intron.

Compensatory mutations have been constructed which demonstrate that P8 and P6, two of nine proposed base-pairing interactions characteristic of group I introns, exist within the folded structure of the Tetrahymena thermophila rRNA intervening sequence, and that these secondary structure elements are important for splicing in E. coli and self-splicing in vitro. Two-base mutations in the 5' and 3' segments of P8 are predicted to disrupt P8 and a strong splicing-defective phenotype is observed in each case. A compensatory four-base mutation in P8 is predicted to restore pairing, and results in the restoration of splicing activity to nearly wild type levels. Thus, we conclude that P8 exists and is essential for splicing. In contrast to the strong phenotypes generally exhibited by mutations which disrupt RNA secondary structure, a two-base mutation in L8, the loop between P8[5'] and P8[3'], results in only a slight decrease in splicing activity. We also tested P6, a pairing which is proposed to consist of only two base-pairs in this intron. A two-base mutation in P6[3'] reduces splicing activity to a greater extent than does a two-base mutation in P6[5']. Comparison of the activities of these mutants and a compensatory P6 four-base mutant support the existence of P6, and suggest that the P6 pairing may be particularly important in the exon ligation step of splicing.     

Loss of the mitochondrial cox2 intron 1 in a family of monocotyledonous plants and utilization of mitochondrial intron sequences for the construction of a nuclear intron

The intron content of plant organellar genes is a useful marker in molecular systematics and evolution. We have tested representatives of a wide range of monocotyledonous plant families for the presence of an intron (cox2 intron 1) in one of the most conservative mitochondrial genes, the cox2 locus. Almost all species analyzed were found to harbor a group II intron at a phylogenetically conserved position. The only exceptions were members of a single monocot family, the Ruscaceae: representatives of all genera in this family were found to lack cox2 intron 1, but instead harbor an intron in the 3' portion of the cox2 coding region (cox2 intron 2). The presence of cox2 intron 1 in families of monocotyledonous plants that are closely related to the Ruscaceae suggests that loss of the intron is specific to this family and may have accompanied the evolutionary appearance of the Ruscaceae. Interestingly, sequences that are highly homologous to cox2 intron 2 are found in a nuclear intron in a lineage of monocotyledonous plants, suggesting that the originally mitochondrial group II intron sequence was transferred to the nuclear genome and reused there to build a spliceosomal intron.     

A common group I intron between a plant parasitic fungus and its host

The self-splicing RNAs known as group I introns exist in many organisms, but their distribution is difficult to explain. We hypothesize that group I introns have been transferred between a parasite and its host. We describe here the discovery of a common group I intron sequence between a plant-parasitic fungus, Protomyces inouyei, and its host, Youngia japonica. It strongly supports our theory that the group I intron had been transferred from the host plant to the parasitic fungus in the course of evolution.      

Extensive mis-splicing of a bi-partite plant mitochondrial group II intron

Expression of the seed plant mitochondrial nad5 gene involves two trans-splicing events that remove fragmented group II introns and join the small, central exon c to exons b and d. We show that in both monocot and eudicot plants, extensive mis-splicing of the bi-partite intron 2 takes place, resulting in the formation of aberrantly spliced products in which exon c is joined to various sites within exon b. These mis-spliced products accumulate to levels comparable to or greater than that of the correctly spliced mRNA. We suggest that mis-splicing may result from folding constraints imposed on intron 2 by base-pairing between exon a and a portion of the bi-partite intron 3 downstream of exon c. Consistent with this hypothesis, we find that mis-splicing does not occur in Oenothera mitochondria, where intron 3 is further fragmented such that the predicted base-pairing region is not covalently linked to exon c. Our findings suggest that intron fragmentation may lead to mis-splicing, which may be corrected by further intron fragmentation.