The mosaic organization of the mitochondrial introns of Saccharomyces cerevisiae: features and evolutionary origins.

The introns of three genes (oxi3, cob and 21S) from the mitochondrial (mt) genome of Saccharomyces cerevisiae contain closed reading frames (CRFs). In the present work, we have analyzed these sequences in their oligodeoxyribonucleotide (oligo; isostich) patterns. We have shown that the relative amounts of di- to hexanucleotides, when compared to random sequences having the same sizes and compositions, exhibit the same deviations as the intergenic noncoding sequences of the mt genome (except for the CRFs from 21S intron). In contrast, intronic open reading frames (ORFs) showed oligo patterns which were generally quite distinct from those of CRFs, although some similarities could be detected in some cases (especially for aI5 alpha). The mt introns of yeast, therefore, are endowed with a mosaic structure, in which CRFs derive from mt intergenic sequences, whereas ORFs have a different origin (indicated as exogenous by other evidences) yet show, in some cases, the effects of 'sequence assimilation' with CRFs.     

Maturase and endonuclease functions depend on separate conserved domains of the bifunctional protein encoded by the group I intron aI4 alpha of yeast mitochondrial DNA.

Intron 4 alpha (aI4 alpha) of the yeast mitochondrial COXI gene is a mobile group I intron that contains a reading frame encoding both the homing endonuclease I-SceII and a latent maturase capable of splicing both aI4 alpha and the fourth intron of the cytochrome b (COB) gene (bI4). The aI4 alpha reading frame is a member of a large gene family recognized by the presence of related dodecapeptide sequence motifs called P1 and P2. In this study, missense mutations of P1 and P2 were placed in mitochondrial DNA by biolistic transformation. The effects of the mutations on intron mobility, endonuclease I-SceII activity and maturase function were tested. The mutations of P1 strongly affected mobility and endonuclease I-SceII activity, but had little or no effect on maturase function; mutations of P2 affected splicing but not mobility or endonuclease I-SceII activity. Surprisingly, the conditional (temperature-sensitive) mutations at P1 and P2 block one or the other function of the protein but not both. This study indicates that the two functions depend on separate domains of the intron-encoded protein.     

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.     

Characterization of products derived from self-splicing of intron aI5 alpha which is located in the mitochondrial COX I gene of Saccharomyces cerevisiae.

We have characterized the in vitro self-splicing of intron aI5 alpha containing precursor RNA from the yeast mitochondrial gene coding for cytochrome oxidase subunit I. This intron follows the rules for group I self-splicing introns and all the characteristic products have been identified. In addition we have detected abnormal RNA products with features that indicate that the self-splicing behaviour of this intron is more complex. Two intron circles are formed by use of a major and minor intron-internal site for circle closure. A cryptic 5'-splice site located in the 3' exon results in guanosine nucleotide mediated opening at a position 30 nt downstream of the normal 3' splice site. The reactions can all be explained on the basis of the "splice guide" model proposed by Davies et al (1982 Nature 300 719-724). Although the sequence motifs at cyclization and splice sites occur more often in this intron, only some of them are allowed to interact with the internal guide sequence, suggesting that both primary structure and spatial folding of the RNA are involved in formation of productive reaction sites.     

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.     

Determination of functional domains in intron bI1 of yeast mitochondrial RNA by studies of mitochondrial mutations and a nuclear suppressor.

The sequence of intron 1 in the cob gene in mtDNA (bI1) of the yeast strain 777-3A has been determined. Furthermore, we have performed a systematic search for complementary sequence stretches within this intron RNA, and within the RNA of intron 5 gamma of the oxi3 gene (aI5 gamma) which shares distinctive sequences with bI1. Possible secondary structure models derived from this analysis show nearly identical core structures for bI1 and aI5 gamma RNA with conserved sequence stretches in prominent positions. These core structures are similar to those previously reported for RNAs of introns having very limited sequence homology with bI1 and aI5 gamma. In two mutants which are defective in bI1 excision from cob pre-mRNA, nucleotide sequence alterations in bI1 have been determined. One mutation (G5049) apparently affects the stability of a hybrid stretch in the proposed secondary structure of bI1 RNA whereas the other one (M1301), a deletion of one A in a run of five As, affects a sequence which is conserved in bI1 and aI5 gamma and is involved in the formation of a distinct secondary structure. Out of seven revertants of M1301, three were found to have restored the wild-type bI1 sequence AAAAA, three others had the related sequence AAAAG which is functionally indistinguishable from wild-type, whereas one revertant had a nuclear mutation which suppresses the splicing defect exerted by the mitochondrial mutation M1301. This nuclear suppressor (SUP-101) is allele specific and dominant. The possible role of the sequence affected by M1301 in terms of a recognition site for a nuclear gene product will be discussed.     

Cleavage and recognition pattern of a double-strand-specific endonuclease (I-creI) encoded by the chloroplast 23S rRNA intron of Chlamydomonas reinhardtii.

Several group-I introns have been shown to specifically invade intron-minus alleles of the genes that contain them. This type of intron mobility is referred to as 'intron homing', and depends on restriction endonucleases (ENases) encoded by the mobile introns. The ENase cleaves the intron-minus allele near the site of intron insertion, thereby initiating gene conversion. The 23S (LSU) rRNA-encoding gene (LSU) of the chloroplast genome of Chlamydomonas reinhardtii contains a self-splicing group-I intron (CrLSU) that has a free-standing open reading frame (ORF) of 163 codons. Translation of CrLSU intron RNA in cell-free systems produces a polypeptide of approx. 18 kDa, the size expected for correct translation of the ORF. The in vitro-synthesized 18-kDa protein cleaves plasmid DNA that contains a portion of LSU where the intron normally resides, but lacking the intron itself. Cleavage by the intron-encoded enzyme (I-CreI) occurs 5 bp and 1 bp 3' to the intron insertion site (in the 3'-exon) in the top (/) and bottom (,) strands, respectively, resulting in 4-nt single-stranded overhangs with 3'-OH termini. We also show that the recognition sequence of I-CreI spans the cleavage site and is 24 bp in length (5'-CAAAACGTC,GTGA/GACAGTTTGGT).     

Purification of a site-specific endonuclease, I-Sce II, encoded by intron 4 alpha of the mitochondrial coxI gene of Saccharomyces cerevisiae

We have purified to near homogeneity a site-specific, double-stranded DNA endonuclease (I-Sce II) encoded by intron 4 alpha (aI4 alpha) of the yeast mitochondrial coxI gene. Our purification starts with a high salt extract of mitochondria isolated from a yeast strain that overproduces the enzyme because of a block in splicing of aI4 alpha. The final step of purification is an affinity column consisting of covalently bound double-stranded DNA multimers of a synthetic sequence, 5'-TTGGTCATCCAGAAGTAT-3', which contains the I-Sce II cleavage/recognition site. Typical yields of enzyme are 3-5% with a specific activity of approximately 500,000 units/mg, where 1 unit of activity cleaves 50 ng of DNA substrate/h at 30 degrees C. I-Sce II has a monomer molecular mass of 31 kDa as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Active enzyme purifies as a 55-kDa species, which we presume to be a homodimer. I-Sce II monomer comigrates with an in vivo synthesized mitochondrial translation product made in the strain that overproduces the enzyme. We conclude that I-Sce II is derived by proteolytic processing of a precursor polypeptide, p62, encoded by an in-frame fusion of coxI exons 1-4 with the downstream aI4 alpha reading frame. I-Sce II is most active at pH 7.5 and at 20-30 degrees C. Endonuclease activity is sensitive to salt and is dependent upon Mg2+ or Mn2+, but is unaffected by inclusion of ATP or GTP. I-Sce II is the first intron-encoded protein to be purified and characterized from yeast mitochondria.     

Involvement of DEAD-box proteins in group I and group II intron splicing. Biochemical characterization of Mss116p, ATP hydrolysis-dependent and -independent mechanisms, and general RNA chaperone activity

The RNA-catalyzed splicing of group I and group II introns is facilitated by proteins that stabilize the active RNA structure or act as RNA chaperones to disrupt stable inactive structures that are kinetic traps in RNA folding. In Neurospora crassa and Saccharomyces cerevisiae, the latter function is fulfilled by specific DEAD-box proteins, denoted CYT-19 and Mss116p, respectively. Previous studies showed that purified CYT-19 stimulates the in vitro splicing of structurally diverse group I and group II introns, and uses the energy of ATP binding or hydrolysis to resolve kinetic traps. Here, we purified Mss116p and show that it has RNA-dependent ATPase activity, unwinds RNA duplexes in a non-polar fashion, and promotes ATP-independent strand-annealing. Further, we show that Mss116p binds RNA non-specifically and promotes in vitro splicing of both group I and group II intron RNAs, as well as RNA cleavage by the aI5gamma-derived D135 ribozyme. However, Mss116p also has ATP hydrolysis-independent effects on some of these reactions, which are not shared by CYT-19 and may reflect differences in its RNA-binding properties. We also show that a non-mitochondrial DEAD-box protein, yeast Ded1p, can function almost as efficiently as CYT-19 and Mss116p in splicing the yeast aI5gamma group II intron and less efficiently in splicing the bI1 group II intron. Together, our results show that Mss116p, like CYT-19, can act broadly as an RNA chaperone to stimulate the splicing of diverse group I and group II introns, and that Ded1p also has an RNA chaperone activity that can be assayed by its effect on splicing mitochondrial introns. Nevertheless, these DEAD-box protein RNA chaperones are not completely interchangeable and appear to function in somewhat different ways, using biochemical activities that have likely been tuned by coevolution to function optimally on specific RNA substrates.     

A shared RNA-binding site in the Pet54 protein is required for translational activation and group I intron splicing in yeast mitochondria

The Pet54p protein is an archetypical example of a dual functioning (‘moonlighting’) protein: it is required for translational activation of the COX3 mRNA and splicing of the aI5β group I intron in the COX1 pre-mRNA in Saccharomyces cerevisiae mitochondria (mt). Genetic and biochemical analyses in yeast are consistent with Pet54p forming a complex with other translational activators that, in an unknown way, associates with the 5′ untranslated leader (UTL) of COX3 mRNA. Likewise, genetic analysis suggests that Pet54p along with another distinct set of proteins facilitate splicing of the aI5β intron, but the function of Pet54 is, also, obscure. In particular, it remains unknown whether Pet54p is a primary RNA-binding protein that specifically recognizes the 5′ UTL and intron RNAs or whether its functional specificity is governed in other ways. Using recombinant protein, we show that Pet54p binds with high specificity and affinity to the aI5β intron and facilitates exon ligation in vitro. In addition, Pet54p binds with similar affinity to the COX3 5′ UTL RNA. Competition experiments show that the COX3 5′UTL and aI5β intron RNAs bind to the same or overlapping surface on Pet54p. Delineation of the Pet54p-binding sites by RNA deletions and RNase footprinting show that Pet54p binds across a similar length sequence in both RNAs. Alignment of the sequences shows significant (56%) similarity and overlap between the binding sites. Given that its role in splicing is likely an acquired function, these data support a model in which Pet54p's splicing function may have resulted from a fortuitous association with the aI5β intron. This association may have lead to the selection of Pet54p variants that increased the efficiency of aI5β splicing and provided a possible means to coregulate COX1 and COX3 expression.     

Excised group II introns in yeast mitochondria are lariats and can be formed by self-splicing in vitro

Excised group II introns in yeast mitochondria appear as covalently closed circles under the electron microscope. We show that these circular molecules are branched and resemble the lariats arising through splicing of nuclear pre-mRNAs in yeast and higher eukaryotes. One member of this intron class (aI5c in the gene for cytochrome c oxidase subunit I) is capable of self-splicing in vitro, giving correct exon-exon ligation and resulting in the appearance of both linear and lariat forms of the excised intron. Nuclease digestion of the latter molecules reveals the presence of a complex oligonucleotide with the probable structure AGU, which thus resembles the branch point formed in the spliceosome-dependent reactions undergone by nuclear pre-mRNAs. Unlike group I introns, this group II intron is not demonstrably dependent on GTP for self-splicing and circularization of the isolated, linear intron is not observed. A model accounting for these observations is presented.     

The mitochondrial tyrosyl-tRNA synthetase of Podospora anserina is a bifunctional enzyme active in protein synthesis and RNA splicing.

The Neurospora crassa mitochondrial tyrosyl-tRNA synthetase (mt tyrRS), which is encoded by the nuclear gene cyt-18, functions not only in aminoacylation but also in the splicing of group I introns. Here, we isolated the cognate Podospora anserina mt tyrRS gene, designated yts1, by using the N. crassa cyt-18 gene as a hybridization probe. DNA sequencing of the P. anserina gene revealed an open reading frame (ORF) of 641 amino acids which has significant similarity to other tyrRSs. The yts1 ORF is interrupted by two introns, one near its N terminus at the same position as the single intron in the cyt-18 gene and the other downstream in a region corresponding to the nucleotide-binding fold. The P. anserina yts1+ gene transformed the N. crassa cyt-18-2 mutant at a high frequency and rescued both the splicing and protein synthesis defects. Furthermore, the YTS1 protein synthesized in Escherichia coli was capable of splicing the N. crassa mt large rRNA intron in vitro. Together, these results indicate that YTS1 is a bifunctional protein active in both splicing and protein synthesis. The P. anserina YTS1 and N. crassa CYT-18 proteins share three blocks of amino acids that are not conserved in bacterial or yeast mt tyrRSs which do not function in splicing. One of these blocks corresponds to the idiosyncratic N-terminal domain shown previously to be required for splicing activity of the CYT-18 protein. The other two are located in the putative tRNA-binding domain toward the C terminus of the protein and also appear to be required for splicing. Since the E. coli and yeast mt tyrRSs do not function in splicing, the adaptation of the Neurospora and Podospora spp. mt tyrRSs to function in splicing most likely occurred after the divergence of their common ancestor from yeast.     

Photocrosslinking of 4-thio uracil-containing RNAs supports a side-by-side arrangement of domains 5 and 6 of a group II intron

Previous studies suggested that domains 5 and 6 (D5 and D6) of group II introns act together in splicing and that the two helical structures probably do not interact by helix stacking. Here, we characterized the major Mg2+ ion- and salt-dependent, long-wave UV light-induced, intramolecular crosslinks formed in 4-thiouridine-containing D56 RNA from intron 5gamma (aI5gamma) of the COXI gene of yeast mtDNA. Four major crosslinks were mapped and found to result from covalent bonds between nucleotides separating D5 from D6 [called J(56)] and residues of D6 near and including the branch nucleotide. These findings are extended by results of similar experiments using 4-thioU containing D56 RNAs from a mutant allele of aI5gamma and from the group IIA intron, aI1. Trans-splicing experiments show that the crosslinked wild-type aI5gamma D56 RNAs are active for both splicing reactions, including some first-step branching. An RNA containing the 3-nt J(56) sequence and D6 of aI5gamma yields one main crosslink that is identical to the most minor of the crosslinks obtained with D56 RNA, but in this case in a cation-independent fashion. We conclude that the interaction between J(56) and D6 is influenced by charge repulsion between the D5 and D6 helix backbones and that high concentrations of cations allow the helices to approach closely under self-splicing conditions. The interaction between J(56) and D6 appears to be a significant factor establishing a side-by-side (i.e., not stacked) orientation of the helices of the two domains.