Periodicities in introns.

The sequence information for the splicing process of introns is found in the consensus sequences at the two splice sites. For long introns, of 300 or more nucleotides, the middle regions may provide additional specificity for splicing which can be investigated by defining an adequate quantitative parameter. This methodology permits to retrieve the coding periodicity in the viral and mitochondrial introns and to identify with a statistical significance, a surprising alternating purine-pyrimidine base sequence -i.e. a modulo 2 periodicity- in the eukaryotic introns, and particularly in the vertebrate introns. This alternating structure suggests that the vertebrate introns do not have the genetic information to code for proteins, they carry structural and regulatory functions.     

Identification of a family of group II introns encoding LAGLIDADG ORFs typical of group I introns

Group I and group II introns are unrelated classes of introns that each encode proteins that facilitate intron splicing and intron mobility. Here we describe a new subfamily of nine introns in fungi that are group II introns but encode LAGLIDADG ORFs typical of group I introns. The introns have fairly standard group IIB1 RNA structures and are inserted into three different sites in SSU and LSU rRNA genes. Therefore, introns should not be assumed to be group I introns based solely on the presence of a LAGLIDADG ORF.     

RNA splicing in Neurospora mitochondria. Defective splicing of mitochondrial mRNA precursors in the nuclear mutant cyt18-1

cyt18-1 (299-9) is a nuclear mutant of Neurospora crassa that has been shown to have a temperature-sensitive defect in splicing the mitochondrial large rRNA intron. In the present work, we investigate the effect of the cyt18-1 mutation on splicing of mitochondrial mRNA introns. Two genes were studied in detail; the cytochrome b (cob) gene, which contains two introns, and a "long form" of the cytochrome oxidase subunit I (coI) gene, which contains four introns. We found that splicing of both cob introns and splicing of at least two of the coI introns are strongly inhibited in the mutant, whereas splicing of coI intron 1, which is excised as a 2.6 X 10(3) base circle, is relatively unaffected. The rRNA intron and both cob introns are group I introns, whereas the circular coI intron may belong to another structural class. Control experiments showed that the degree of inhibition of splicing is greater in the mutant than can be accounted for by severe inhibition of mitochondrial protein synthesis. Finally, experiments in which mutant cells were shifted from 25 degrees C to 37 degrees C showed that splicing of the large rRNA precursor and splicing of the coI mRNA precursor are inhibited with similar kinetics. Considered together, our results suggest that the cyt18 gene encodes a trans-acting component that is required for the splicing of group I mitochondrial DNA introns or some subclass thereof. Since Neurospora cob intron 1 has been shown to be self-splicing in vitro, defective splicing of this intron in cyt18-1 indicates that an essentially RNA-catalyzed splicing reaction must be facilitated by a trans-acting factor, presumably a protein, in vivo.     

Pentamidine inhibits mitochondrial intron splicing and translation in Saccharomyces cerevisiae

Pentamidine inhibits in vitro splicing of nuclear group I introns from rRNA genes of some pathogenic fungi and is known to inhibit mitochondrial function in yeast. Here we report that pentamidine inhibits the self-splicing of three group I and two group II introns of yeast mitochondria. Comparison of yeast strains with different configurations of mitochondrial introns (12, 5, 4, or 0 introns) revealed that strains with the most introns were the most sensitive to growth inhibition by pentamidine on glycerol medium. Analysis of blots of RNA from yeast strains grown in raffinose medium in the presence or absence of pentamidine revealed that the splicing of seven group I and two group II introns that have intron reading frames was inhibited by the drug to varying extents. Three introns without reading frames were unaffected by the drug in vivo, and two of these were inhibited in vitro, implying that the drug affects splicing by acting directly on RNA in vitro, but on another target in vivo. Because the most sensitive introns in vivo are the ones whose splicing depends on a maturase encoded by the intron reading frames, we tested pentamidine for effects on mitochondrial translation. We found that the drug inhibits mitochondrial but not cytoplasmic translation in cells at concentrations that inhibit mitochondrial intron splicing. Therefore, pentamidine is a potent and specific inhibitor of mitochondrial translation, and this effect explains most or all of its effects on respiratory growth and on in vivo splicing of mitochondrial introns.     

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.     

Molecular gene organisation and secondary structure of the mitochondrial large subunit ribosomal RNA from the cultivated Basidiomycota Agrocybe aegerita: a 13 kb gene possessing six unusual nucleotide extensions and eight introns

The complete gene sequence and secondary structure of the mitochondrial LSU rRNA from the cultivated Basidiomycota Agrocybe aegerita was derived by chromosome walking. The A.aegerita LSU rRNA gene (13 526 nt) represents, to date, the longest described, due to the highest number of introns (eight) and the occurrence of six long nucleotidic extensions. Seven introns belong to group I, while the intronic sequence i5 constitutes the first typical group II intron reported in a fungal mitochondrial LSU rDNA. As with most fungal LSU rDNA introns reported to date, four introns (i5-i8) are distributed in domain V associated with the peptidyl-transferase activity. One intron (i1) is located in domain I, and three (i2-i4) in domain II. The introns i2-i8 possess homologies with other fungal, algal or protozoan introns located at the same position in LSU rDNAs. One of them (i6) is located at the same insertion site as most Ascomycota or algae LSU introns, suggesting a possible inheritance from a common ancestor. On the contrary, intron i1 is located at a so-far unreported insertion site. Among the six unusual nucleotide extensions, five are located in domain I and one in domain V. This is the first report of a mitochondrial LSU rRNA gene sequence and secondary structure for the whole Basidiomycota division.     

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.     

A maturase-encoding group IIA intron of yeast mitochondria self-splices in vitro.

Intron 1 of the coxI gene of yeast mitochondrial DNA (aI1) is a group IIA intron that encodes a maturase function required for its splicing in vivo. It is shown here to self-splice in vitro under some reaction conditions reported earlier to yield efficient self-splicing of group IIB introns of yeast mtDNA that do not encode maturase functions. Unlike the group IIB introns, aI1 is inactive in 10 mM Mg2+ (including spermidine) and requires much higher levels of Mg2+ and added salts (1M NH4Cl or KCl or 2M (NH4)2SO4) for ready detection of splicing activity. In KCl-stimulated reactions, splicing occurs with little normal branch formation; a post-splicing reaction of linear excised intron RNA that forms shorter lariat RNAs with branches at cryptic sites was evident in those samples. At low levels of added NH4Cl or KCl, the precursor RNA carries out the first reaction step but appears blocked in the splicing step. AI1 RNA is most reactive at 37-42 degrees C, as compared with 45 degrees C for the group IIB introns; and it lacks the KCl- or NH4Cl-dependent spliced-exon reopening reaction that is evident for the self-splicing group IIB introns of yeast mitochondria. Like the group IIB intron aI5 gamma, the domain 4 of aI1 can be largely deleted in cis, without blocking splicing; also, trans-splicing of half molecules interrupted in domain 4 occurs. This is the first report of a maturase-encoding intron of either group I or group II that self-splices in vitro.     

Group I introns as mobile genetic elements: facts and mechanistic speculations--a review

Group I introns form a structural and functional group of introns with widespread but irregular distribution among very diverse organisms and genetic systems. Evidence is now accumulating that several group I introns are mobile genetic elements with properties similar to those originally described for the omega system of Saccharomyces cerevisiae: mobile group I introns encode sequence-specific double-strand (ds) endoDNases, which recognize and cleave intronless genes to insert a copy of the intron by a ds-break repair mechanism. This mechanism results in: the efficient propagation of group I introns into their cognate sites; their maintenance at the site against spontaneous loss; and, perhaps, their transposition to different sites. The spontaneous loss of group I introns occurs with low frequency by an RNA-mediated mechanism. This mechanism eliminates introns defective for mobility and/or for RNA splicing. Mechanisms of intron acquisition and intron loss must create an equilibrium, which explains the irregular distribution of group I introns in various genetic systems. Furthermore, the observed distribution also predicts that horizontal transfer of intron sequences must occur between unrelated species, using vectors yet to be discovered.     

A CRM domain protein functions dually in group I and group II intron splicing in land plant chloroplasts

The CRM domain is a recently recognized RNA binding domain found in three group II intron splicing factors in chloroplasts, in a bacterial protein that associates with ribosome precursors, and in a family of uncharacterized proteins in plants. To elucidate the functional repertoire of proteins with CRM domains, we studied CFM2 (for CRM Family Member 2), which harbors four CRM domains. RNA coimmunoprecipitation assays showed that CFM2 in maize (Zea mays) chloroplasts is associated with the group I intron in pre-trnL-UAA and group II introns in the ndhA and ycf3 pre-mRNAs. T-DNA insertions in the Arabidopsis thaliana ortholog condition a defective-seed phenotype (strong allele) or chlorophyll-deficient seedlings with impaired splicing of the trnL group I intron and the ndhA, ycf3-int1, and clpP-int2 group II introns (weak alleles). CFM2 and two previously described CRM proteins are bound simultaneously to the ndhA and ycf3-int1 introns and act in a nonredundant fashion to promote their splicing. With these findings, CRM domain proteins are implicated in the activities of three classes of catalytic RNA: group I introns, group II introns, and 23S rRNA.     

Group I permuted intron-exon (PIE) sequences self-splice to produce circular exons.

Circularly permuted group I intron precursor RNAs, containing end-to-end fused exons which interrupt half-intron sequences, were generated and tested for self-splicing activity. An autocatalytic RNA can form when the primary order of essential intron sequence elements, splice sites, and exons are permuted in this manner. Covalent attachment of guanosine to the 5' half-intron product, and accurate exon ligation indicated that the mechanism and specificity of splicing were not altered. However, because the exons were fused and the order of the splice sites reversed, splicing released the fused-exon as a circle. With this arrangement of splice sites, circular exon production was a prediction of the group I splicing mechanism. Circular RNAs have properties that would make them attractive for certain studies of RNA structure and function. Reversal of splice site sequences in a context that allows splicing, such as those generated by circularly permuted group I introns, could be used to generate short defined sequences of circular RNA in vitro and perhaps in vivo.     

Self-splicing of the Chlamydomonas chloroplast psbA introns.

We used alpha-32P-GTP labeling of total RNA preparations to identify self-splicing group I introns in Chlamydomonas. Several RNAs become labeled with alpha-32P-GTP, a subset of which is not seen with RNA from a mutant that lacks both copies of the psbA gene. Hybridization of the GTP-labeled RNAs to chloroplast DNA indicates that they originate from the psbA and rrn 23S genes, respectively, the only genes known to contain group I introns in this organism. Introns 1, 2, and 3 of psbA (with flanking exon sequences) were subcloned and transcribed in vitro. The synthetic RNAs were found to self-splice; splicing required Mg2+, GTP, and elevated temperature. In addition, the accuracy of self-splicing was confirmed for introns 1 and 2, and intermediates in the splicing reactions were detected. These results, together with our recent data on the 23S intron, indicate that the ability to self-splice is a general feature of Chlamydomonas group I introns. These findings have significant implications for the mechanism of group I intron splicing and evolution in Chlamydomonas and other chloroplast genomes.     

CRS1, a chloroplast group II intron splicing factor, promotes intron folding through specific interactions with two intron domains

Group II introns are ribozymes that catalyze a splicing reaction with the same chemical steps as spliceosome-mediated splicing. Many group II introns have lost the capacity to self-splice while acquiring compensatory interactions with host-derived protein cofactors. Degenerate group II introns are particularly abundant in the organellar genomes of plants, where their requirement for nuclear-encoded splicing factors provides a means for the integration of nuclear and organellar functions. We present a biochemical analysis of the interactions between a nuclear-encoded group II splicing factor and its chloroplast intron target. The maize (Zea mays) protein Chloroplast RNA Splicing 1 (CRS1) is required specifically for the splicing of the group II intron in the chloroplast atpF gene and belongs to a plant-specific protein family defined by a recently recognized RNA binding domain, the CRM domain. We show that CRS1's specificity for the atpF intron in vivo can be explained by CRS1's intrinsic RNA binding properties. CRS1 binds in vitro with high affinity and specificity to atpF intron RNA and does so through the recognition of elements in intron domains I and IV. These binding sites are not conserved in other group II introns, accounting for CRS1's intron specificity. In the absence of CRS1, the atpF intron has little uniform tertiary structure even at elevated [Mg2+]. CRS1 binding reorganizes the RNA, such that intron elements expected to be at the catalytic core become less accessible to solvent. We conclude that CRS1 promotes the folding of its group II intron target through tight and specific interactions with two peripheral intron segments.     

Sequence specificity of in vivo reverse splicing of the Tetrahymena group I intron.

Reverse splicing of group I introns is proposed to be a mechanism by which intron sequences are transferred to new genes. Integration of the Tetrahymena intron into the Escherichia coli 23S rRNA via reverse splicing depends on base pairing between the guide sequence of the intron and the target site. To investigate the substrate specificity of reverse splicing, the wild-type and 18 mutant introns with different guide sequences were expressed in E. coli. Amplification of intron-rRNA junctions by RT-PCR revealed partial reverse splicing at 69 sites and complete integration at one novel site in the 23S rRNA. Reverse splicing was not observed at some potential target sites, whereas other regions of the 23S rRNA were more reactive than expected. The results indicate that the frequency of reverse splicing is modulated by the structure of the rRNA. The intron is spliced 10-fold less efficiently in E. coli from a novel integration site (U2074) in domain V of the 23S rRNA than from a site homologous to the natural splice junction of the Tetrahymena 26S rRNA, suggesting that the forward reaction is less favored at this site.     

nMAT1, a nuclear-encoded maturase involved in the trans-splicing of nad1 intron 1, is essential for mitochondrial complex I assembly and function

Mitochondrial genomes (mtDNAs) in angiosperms contain numerous group II-type introns that reside mainly within protein-coding genes that are required for organellar genome expression and respiration. While splicing of group II introns in non-plant systems is facilitated by proteins encoded within the introns themselves (maturases), the mitochondrial introns in plants have diverged and have lost the vast majority of their intron-encoded ORFs. Only a single maturase gene (matR) is retained in plant mtDNAs, but its role(s) in the splicing of mitochondrial introns is currently unknown. In addition to matR, plants also harbor four nuclear maturase genes (nMat 1 to 4) encoding mitochondrial proteins that are expected to act in the splicing of group II introns. Recently, we established the role of one of these proteins, nMAT2, in the splicing of several mitochondrial introns in Arabidopsis. Here, we show that nMAT1 is required for trans-splicing of nad1 intron 1 and also functions in cis-splicing of nad2 intron 1 and nad4 intron 2. Homozygous nMat1 plants show retarded growth and developmental phenotypes, modified respiration activities and altered stress responses that are tightly correlated with mitochondrial complex I defects.     

DiGIR1 and NaGIR1: naturally occurring group I-like ribozymes with unique core organization and evolved biological role

The group I-like ribozyme GIR1 is a unique example of a naturally occurring ribozyme with an evolved biological function. GIR1 generates the 5'-end of a nucleolar encoded messenger RNA involved in intron mobility. GIR1 is found as a cis-cleaving ribozyme within two very different rDNA group I introns (twin-ribozyme introns) in distantly related organisms. The Didymium GIR1 (DiGIR1) and Naegleria GIR1 (NaGIR1) share fundamental features in structural organization and reactivity, and display significant differences when compared to the related group I splicing ribozymes. GIR1 lacks the characteristic P1 segment present in all group I splicing ribozymes, it has a novel core organization, and it catalyses two site-specific hydrolytic cleavages rather than splicing. DiGIR1 and NaGIR1 appear to have originated from eubacterial group I introns in order to fulfil a common biological challenge: the expression of a protein encoding gene in a nucleolar context.