Sequence of the intron and flanking exons of the mitochondrial 21S rRNA gene of yeast strains having different alleles at the omega and rib-1 loci

Ribosomal RNA introns in archaea and evidence for RNA conformational changes associated with splicing

The single 23S rRNA gene of the archaeon Staphylothermus marinus exhibits two introns which, at the RNA level, are located in highly conserved regions of domains IV and V. The RNA introns, which are 56 and 54 nucleotides long, respectively, can form single hairpin structures. In vivo, RNA splicing occurs efficiently, whereas in vitro pre-rRNA transcripts containing each intron were cleaved efficiently when incubated with archaeal cell extracts but were poorly ligated. The introns are cleaved by a mechanism which differs from the mechanisms of eukaryotic rRNA introns but resembles those of the rRNA intron of Desulfurococcus mobilis and the archaeal tRNA introns. The cleavage enzyme recognizes and cuts a putative bulge-helix-bulge structure that can form at the archaeal exon-intron junctions. Using a phylogenetic sequence comparison approach, we define the parts of this structural feature that are essential for cleavage. We also provide evidence for conformational changes occurring in the S. marinus 23S RNA, after cleavage, at both exon-exon junctions, which may account for the low yields of ligation observed in vitro.

The apocytochrome b gene of Chlamydomonas smithii contains a mobile intron related to both Saccharomyces and Neurospora introns

The mitochondrial DNA of the two interfertile algal species Chlamydomonas smithii and Chlamydomonas reinhardtii are co-linear with the exception of ca. 1 kb insertion (the alpha insert) present in C. smithii DNA only. In vegetative diploids resulting from interspecific crosses, mitochondrial genomes are transmitted biparentally except for the alpha insert which is transmitted to all C. reinhardtii molecules in a manner reminiscent of the intron-mediated conversion event that occurs at the omega locus in yeast mitochondria, under the action of the I-SceI endonuclease. Here we report that the alpha insert corresponds to a typical group I intron of 1075 bp, inserted within the gene for apocytochrome b and containing a 237 codon open reading frame (ORF). We also report the complete sequence of the apocytochrome b gene of C. smithii. Comparison with the sequence of the same gene in C. reinhardtii reveals the precise intron insertion site. These data, together with the previous genetic data provide the first example of intron mobility in mitochondria of the plant kingdom. The product of the intronic ORF shows 36% amino acid identity with the I-SceI endonuclease whereas the intron ribozyme shows a 60% identity at the nucleotide level with the Neurospora crassa cob.1 intron. The possibility of a recent horizontal transfer of introns between fungi and algae is discussed.

Intron mobility in phage T4 is dependent upon a distinctive class of endonucleases and independent of DNA sequences encoding the intron core: mechanistic and evolutionary implications

Although mobility of the phylogenetically widespread group I introns appears to be mechanistically similar, the phage T4 intron-encoded endonucleases that promote mobility of the td and sunY introns are different from their eukaryotic counterparts. Most notably, they cleave at a distance from the intron insertion sites. The td enzyme was shown to cleave 23-26 nt 5' and the sunY endonuclease 13-15 nt 3' to the intron insertion site to generate 3-nt or 2-nt 3'-OH extensions, respectively. The absolute coconversion of exon markers between the distant cleavage and insertion sites is consistent with the double-strand-break repair model for intron mobility. As a further critical test of the model we have demonstrated that the mobility event is independent of DNA sequences that encode the catalytic intron core structure. Thus, in derivatives in which the lacZ or kanR coding sequences replace the intron, these marker genes are efficiently inserted into intron-minus alleles when the cognate endonuclease is provided in trans. The process is therefore endonuclease-dependent, rather than dependent on the intron per se. These findings, which imply that the endonucleases rather than the introns themselves were the primordial mobile elements, are incorporated into a model for the evolution of mobile introns.

Purification and characterization of the in vitro activity of I-Sce I, a novel and highly specific endonuclease encoded by a group I intron

Group I intron encoded proteins represent a novel class of site specific double strand endonucleases. The endonuclease activity of this class of proteins has been first demonstrated in vivo for I-Sce I which is encoded by a mitochondrial intron of Saccharomyces cerevisiae. Assays using crude cell extracts have shown that I-Sce I can be used in vitro as a restriction endonuclease potentially useful for recombinant DNA technology owing to its large recognition sequence (18 nucleotides). We report here the purification and the first detailed analysis of the in vitro activity and properties of I-Sce I.

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.

Putative target sites for mobile G + C rich clusters in yeast mitochondrial DNA: single elements and tandem arrays

GC clusters constitute the major repetitive elements in the mitochondrial (mt) genome of the yeast Saccharomyces cerevisiae. Many of these clusters are optional and thus contribute much to the polymorphism of yeast mtDNAs. We have made a systematic search for polymorphic sites by comparing mtDNA sequences of various yeast strains. Most of the 26 di- or polymorphic sites found differ by the presence or absence of a GC cluster of the majority class, here referred to as the M class, which terminate with an AGGAG motif. Comparison of sequences with and without the GC clusters reveal that elements of the subclasses M1 and M2 are inserted 3' to a TAG, flanked by A + T rich sequences. M3 elements, in contrast, only occur in tandem arrays of two to four GC clusters; they are consistently inserted 3' to the AGGAG terminal sequence of a preexisting cluster. The TAG or the terminal AGGAG, therefore, are regarded as being part of the target sites for M1 and M2 or M3 elements, respectively. The dinucleotide AG is in common to both target sites; it also occurs at the 3' terminus (AGGAG). This suggests its duplication during GC cluster insertion. This notion is supported by the observation that GC clusters of the minor classes G and V similarily repeat at their 3' terminus a GT or an AA dinucleotide, respectively, from their putative target sites.

Functional expression of a yeast mitochondrial intron-encoded protein requires RNA processing at a conserved dodecamer sequence at the 3' end of the gene

All mRNAs of yeast mitochondria are processed at their 3' ends within a conserved dodecamer sequence, 5'-AAUAAUAUUCUU-3'. A dominant nuclear suppressor, SUV3-I, was previously isolated because it suppresses a dodecamer deletion at the 3' end of the var1 gene. We have tested the effects of SUV3-1 on a mutant containing two adjacent transversions within a dodecamer at the 3' end of fit1, a gene located within the 1,143-base-pair intron of the 21S rRNA gene, whose product is a site-specific endonuclease required in crosses for the quantitative transmission of that intron to 21S alleles that lack it. The fit1 dodecamer mutations blocked both intron transmission and dodecamer cleavage, neither of which was suppressed by SUV3-1 when present in heterozygous or homozygous configurations. Unexpectedly, we found that SUV3-1 completely blocked cleavage of the wild-type fit1 dodecamer and, in SUV3-1 homozygous crosses, intron conversion. In addition, SUV3-1 resulted in at least a 40-fold increase in the amount of excised intron accumulated. Genetic analysis showed that these phenotypes resulted from the same mutation. We conclude that cleavage of a wild-type dodecamer sequence at the 3' end of the fit1 gene is essential for fit1 expression.

Substitution of an invariant nucleotide at the base of the highly conserved '530-loop' of 15S rRNA causes suppression of yeast mitochondrial ochre mutations

We have determined the nucleotide sequence alteration in the 15S rRNA gene of a Saccharomyces cerevisiae strain carrying the previously described mitochondrial ochre suppressor, MSUI. The suppressor contains an A residue at position 633 of the yeast mitochondrial sequence, in place of the wild-type G. This position, located in the highly conserved region forming the stem of the '530-loop', corresponds to G517 of the Escherichia coli 16S rRNA and is occupied by G in all other known small rRNA sequences. This finding strongly supports the previous conclusions of others that the 530-loop region plays an important role in enhancing translational accuracy.

Sequence analysis of mouse mitochondrial chloramphenicol-resistant mutants

The nucleotide sequences of the 3' halves of the mitochondrial 16S rRNA genes from four independent mouse chloramphenicol-resistant (CAP-R) mutants were determined. Each contained a different, single base change that encodes the mutational phenotype. The mitochondrial rRNA gene from the SVA31 CAP-R mutant contains a G-to-A transition at nucleotide 2161 of the noncoding strand; the SVIS CAP-R mutant, a G-to-A transition at position 2375; the LA9 CAP-R mutant, an A-to-T transversion at position 2379; and the SVT2 CAP-R mutant, a T-to-C transition at position 2433. Three of these CAP-R mutants appear to be heteroplasmic as the mtDNA populations contain both wild-type and mutant copies of the rRNA gene. The SVIS CAP-R mutation has not been observed in other mammalian CAP-R mutants, although it occurs at a site homologous to one of the yeast mitochondrial CAP-R mutations. Based upon the locations of the mutated sites within the 16S rRNA, and their proximity to previously analyzed sites of mutations conferring increased inhibitor resistance, all these mutations occur within the ribosomal RNA peptidyltransferase domain. These results provide an explanation for the pleiotropic nature of mitochondrial CAP-R mutations in mammalian cells, particularly the observations that some of the mutant lines are partially respiration deficient.

Reverse self-splicing of the tetrahymena group I intron: implication for the directionality of splicing and for intron transposition

Using short oligoribonucleotides as ligated exon substrates, we show that splicing of the Tetrahymena rRNA group I intron is fully reversible in vitro. Incubation of ligated exon RNA with linear intron produces a molecule in which the splice site sequences of the precursor are reformed. Reversal of self-splicing is favored by high RNA concentration, high magnesium and temperature, and the absence of guanosine. 5' exon sequences that can pair with the internal guide sequence of the intron are required, whereas 3' exon sequences are not essential. Integration of the intron into ligated exon substrates that have the ability to form stem-loop structures is reduced at least one order of magnitude over short, unstructured substrates. We propose that the formation of these structures helps drive splicing in the forward direction. We also show that the Tetrahymena intron can integrate into a beta-globin transcript. This has implications for transposition of group I introns.

Functional expression of a yeast mitochondrial intron-encoded protein requires RNA processing at a conserved dodecamer sequence at the 3' end of the gene

All mRNAs of yeast mitochondria are processed at their 3' ends within a conserved dodecamer sequence, 5'-AAUAAUAUUCUU-3'. A dominant nuclear suppressor, SUV3-I, was previously isolated because it suppresses a dodecamer deletion at the 3' end of the var1 gene. We have tested the effects of SUV3-1 on a mutant containing two adjacent transversions within a dodecamer at the 3' end of fit1, a gene located within the 1,143-base-pair intron of the 21S rRNA gene, whose product is a site-specific endonuclease required in crosses for the quantitative transmission of that intron to 21S alleles that lack it. The fit1 dodecamer mutations blocked both intron transmission and dodecamer cleavage, neither of which was suppressed by SUV3-1 when present in heterozygous or homozygous configurations. Unexpectedly, we found that SUV3-1 completely blocked cleavage of the wild-type fit1 dodecamer and, in SUV3-1 homozygous crosses, intron conversion. In addition, SUV3-1 resulted in at least a 40-fold increase in the amount of excised intron accumulated. Genetic analysis showed that these phenotypes resulted from the same mutation. We conclude that cleavage of a wild-type dodecamer sequence at the 3' end of the fit1 gene is essential for fit1 expression.

Evolution of mushroom mitochondrial DNA: Suillus and related genera

Mapping studies were performed with 18 cloned probes on mitochondrial DNA (mtDNA) from 15 species of Suillus and four species from three related genera of fleshy pore mushrooms (Boletaceae). Within Suillus, mtDNAs vary in size from 36 to 121 kb, differ in gene order by only one major rearrangement, and have diverged in nucleotide sequence within the large subunit ribosomal RNA gene region by up to 2.9%. Three additional gene orders exist in related genera. Two of the three can be transformed into the predominant Suillus order by either one or two rearrangements. The fourth requires two to three rearrangements to be converted to any of the others. The minimum estimates of nucleotide divergence within the large subunit ribosomal RNA gene region vary from 8.3% to 11% in comparisons between Suillus and these related species. Trees based on restriction-site and size differences within the mitochondrial ribosomal RNA genes were consistent with the hypothesized sequence of genome rearrangements and provide suggestive evidence for a major expansion of the mitochondrial genome within Suillus. Structural and sequence changes in mtDNA provided information about phylogenetic relationships within the Boletaceae.

DNA sequence and secondary structures of the large subunit rRNA coding regions and its two class I introns of mitochondrial DNA from Podospora anserina

DNA sequence analysis has shown that the gene coding for the mitochondrial (mt) large subunit ribosomal RNA (rRNA) from Podospora anserina is interrupted by two class I introns. The coding region for the large subunit rRNA itself is 3715 bp and the two introns are 1544 (r1) and 2404 (r2) bp in length. Secondary structure models for the large subunit rRNA were constructed and compared with the equivalent structure from Escherichia coli 23S rRNA. The two structures were remarkably similar despite an 800-base difference in length. The additional bases in the P. anserina rRNA appear to be mostly in unstructured regions in the 3' part of the RNA. Secondary structure models for the two introns show striking similarities with each other as well as with the intron models from the equivalent introns in Saccharomyces cerevisiae, Neurospora crassa, and Aspergillus nidulans. The long open reading frames in each intron are different from each other, however, and the nucleotide sequence similarity diverges as it proceeds away from the core structure. Each intron is located within regions of the large subunit rRNA gene that are highly conserved in both sequence and structure. Computer analysis showed that the open reading frame for intron r1 contained a common maturase-like polypeptide. The open reading frames of intron r2 appeared to be chimeric, displaying high sequence similarity with the open reading frames in the r1 and ATPase 6 introns of N. crassa.

Site-specific DNA endonuclease and RNA maturase activities of two homologous intron-encoded proteins from yeast mitochondria

Two introns of the mitochondrial genome 777-3A of S. cerevisiae, bl4 in cob and al4 in coxl genes, contain ORFs that can be translated into two homologous proteins. We changed the UGA, AUA, and CUN codons of these ORFs to the universal genetic code, in order to study the functions of their translated products in E. coli and in yeast, by retargeting the nuclear encoded protein into mitochondria. The p27bl4 protein has been shown to be required for the splicing of both introns bl4 and al4. The homologous p28al4 protein is highly toxic to E. coli. It can specifically cleave double-stranded DNA at a sequence representing the junction of the two fused flanking exons. We present evidence that this system is a good model for studying the role of mitochondrial intron-encoded proteins in the rearrangement of genetic information at both the RNA (RNA splicing-bl4 maturase) and DNA levels (intron transposition-al4 transposase).

Protein encoded by the third intron of cytochrome b gene in Saccharomyces cerevisiae is an mRNA maturase. Analysis of mitochondrial mutants, RNA transcripts proteins and evolutionary relationships

We have established the nucleotide sequence of the wild-type and that of a trans-acting mutant located in the third (bi3) intron of the Saccharomyces cerevisiae mitochondrial cytochrome b gene. The intron, 1691 base-pairs long, has an open reading frame 1045 base-pairs long, in phase with the preceding exon and the mutation replaces the evolutionarily conserved Gly codon of the second consensus motif by an Asp codon and blocks the formation of mature cytochrome b mRNA. Splicing intermediates of 5300 and 3900 bases with unexcised bi3 intron and a characteristic novel polypeptide (p50), the size of which corresponds to the chimeric protein encoded by upstream exons and the bi3 intronic open reading frame (ORF), accumulate in this and other bi3 splicing-deficient mutants. We conclude that the protein encoded by the bi3 ORF is a specific mRNA maturase involved in the splicing of the cytochrome b mRNA. The open reading frame of the third intron is remarkably similar to that of the unique intron of the cytochrome b gene (cob A) of Aspergillus nidulans. Both are located in exactly the same position and possibly derive from a recent common ancestor by a horizontal transfer. We have established the nucleotide sequence of an exonic mutant located in the B3 exon. This missense mutation changes the Phe codon 151 into a Cys codon and leads to the absence of functional cytochrome b but does not affect splicing. Finally, we have studied the splicing pathway leading to the synthesis of cytochrome b mRNA by analysing, in a comprehensive manner, the 22 splicing intermediates of several mutants located in bi3.

Molecular genetics of group I introns: RNA structures and protein factors required for splicing--a review

In vivo and in vitro genetic techniques have been widely used to investigate the structure-function relationships and requirements for splicing of group-I introns. Analyses of group-I introns from extremely diverse genetic systems, including fungal mitochondria, protozoan nuclei, and bacteriophages, have yielded results which are complementary and highly consistent. In vivo genetic studies of fungal mitochondrial systems have served to identify cis-acting sequences within mitochondrial introns, and trans-acting protein products of mitochondrial and nuclear genes which are important for splicing, and to show that some mitochondrial introns are mobile genetic elements. In vitro genetic studies of the self-splicing intron within the Tetrahymena thermophila nuclear large ribosomal RNA precursor (Tetrahymena LSU intron) have been used to examine essential and nonessential RNA sequences and structures in RNA-catalyzed splicing. In vivo and in vitro genetic analysis of the intron within the bacteriophage T4 td gene has permitted the detailed examination of mutant phenotypes by analyzing splicing in vivo and self-splicing in vitro. The genetic studies combined with phylogenetic analysis of intron structure based on comparative nucleotide sequence data [Cech 73 (1988) 259-271] and with biochemical data obtained from in vitro splicing experiments have resulted in significant advances in understanding the biology and chemistry of group-I introns.

Point mutations in the 23 S rRNA genes of four lincomycin resistant Nicotiana plumbaginifolia mutants could provide new selectable markers for chloroplast transformation

Experiments designed to establish stable chloroplast transformation require selectable marker genes encoded by the chloroplast genome. The antibiotic lincomycin is a specific inhibitor of chloroplast ribosomal activity and is known to bind to the large ribosomal subunit. We have investigated a defined region of the chloroplast 23 S rRNA genes from four lincomycin resistant Nicotiana plumbaginifolia mutants and from wild-type N. plumbaginifolia. The mutants LR415, LR421 and LR446 have A to G transitions at positions equivalent to the nucleotides 2058 and 2059 in the Escherichia coli 23 S rRNA. The mutant, LR400, possesses a G to A transition at a position corresponding to nucleotide 2032 of the E. coli 23 S rRNA.

Mapping of chloroplast mutations conferring resistance to antibiotics in Chlamydomonas: evidence for a novel site of streptomycin resistance in the small subunit rRNA

A major obstacle to our understanding of the mechanisms governing the inheritance, recombination and segregation of chloroplast genes in Chlamydomonas is that the majority of antibiotic resistance mutations that have been used to gain insights into such mechanisms have not been physically localized on the chloroplast genome. We report here the physical mapping of two chloroplast antibiotic resistance mutations: one conferring cross-resistance to erythromycin and spiramycin in Chlamydomonas moewusii (er-nM1) and the other conferring resistance to streptomycin in the interfertile species C. eugametos (sr-2). The er-nM1 mutation results from a C to G transversion at a well-known site of macrolide resistance within the peptidyl transferase loop region of the large subunit rRNA gene. This locus, designated rib-2 in yeast mitochondrial DNA, corresponds to residue C-2611 in the 23 S rRNA of Escherichia coli. The sr-2 locus maps within the small subunit (SSU) rRNA gene at a site that has not been described previously. The mutation results from an A to C transversion at a position equivalent to residue A-523 in the E. coli 16 S rRNA. Although this region of the E. coli SSU rRNA has no binding affinity for streptomycin, it binds to ribosomal protein S4, a protein that has long been associated with the response of bacterial cells to this antibiotic. We propose that the sr-2 mutation indirectly affects the nearest streptomycin binding site through an altered interaction between a ribosomal protein and the SSU rRNA.

Recognition and cleavage site of the intron-encoded omega transposase

The optional group I intron of the mitochondrial 21S rRNA gene of Saccharomyces cerevisiae contains a 235-codon-long open reading frame the translation product of which (the omega transposase) catalyzes the formation of a double-strand break within the intron-minus (omega-) copies of the same gene. Purified omega transposase generates in vitro a 4-base-pair staggered cut with 3' hydroxyl overhangs at the exact position where the intron eventually inserts in the gene. Using randomly mutagenized synthetic oligonucleotides, single-base mutants were produced at 21 positions around the cleavage site. Experiments with these oligonucleotides show that the recognition site extends over an 18-base pair-long sequence within which minimal sequence degeneracy is tolerated. The intron-encoded omega transposase is, therefore, one of the most specific restriction endonucleases known to date.

Identification of defined sequences in domain V of E. coli 23S rRNA in the 50S subunit accessible for hybridization with complementary oligodeoxyribonucleotides

The accessibility of specific sequences in domain V of E. coli 23s rRNA in the 50S subunit to complementary oligodeoxyribonucleotides (cDNA) has been investigated. The apparent percentage of subunits engaged in complex formation was determined by incubation of radiolabeled cDNA probe with 50S subunits, followed by nitrocellulose membrane filtration of the reaction mixtures and measurement of the bound radiolabeled cDNA probes by liquid scintillation counting of the filters. The site(s) of hybridization were determined by digestion of the RNA in the RNA/DNA heteroduplex by RNase H. The results of this study indicated that single-stranded sequences, 2058-2062, 2448-2454, 2467-2483, and 2497-2505 were available for hybridization to cDNA probes. Bases 2489-2496, which have been postulated to be base paired with 2455-2461 were also accessible for hybridization.

The self-splicing intron in the Neurospora apocytochrome b gene contains a long reading frame in frame with the upstream exon

We have determined the DNA sequence of intron 1 and flanking exons in the mitochondrial apocytochrome b gene of the Neurospora laboratory strain 74A and the natural isolate North Africa. In contrast to a previous report, we find that this intron contains an open reading frame (ORF) of 951 bases in frame with the upstream exon. The putative intron-encoded protein resembles those of other intron ORFs with respect to length, calculated isoelectric point, and proportion of basic, acidic, polar, and non-polar amino acids; however, no amino acid sequences resembling the "decapeptides" characteristic of maturase-like ORFs were found. Coupled with the previous finding that this intron is capable of self-splicing in vitro in the absence of proteins, the observations discussed here raise the possibility that other introns with long, in-frame ORFs may also be capable of RNA-catalyzed splicing in vitro.

The mitochondrial genome of the fission yeast, Schizosaccharomyces pombe. Sequence of the large-subunit ribosomal RNA gene, comparison of potential secondary structure in fungal mitochondrial large-subunit rRNAs and evolutionary considerations

The DNA sequence of the mitochondrial large subunit (LSU) rRNA gene of Schizosaccharomyces pombe has been determined. In the direction of transcription, this gene is located between the gene coding for subunit II of cytochrome oxidase and a cluster of three tRNA genes. Both the 5' and 3' ends of the LSU rRNA have been mapped precisely: whereas the 5' end can be assigned unambiguously to a single nucleotide position, multiple 3' ends occur within a run of eight U residues. Based on these results, the S. pombe LSU rRNA is between 2818 and 2826 nucleotides long. A sequence motif immediately upstream of the 5' end of the gene resembles that of the mitochondrial promoter motif of Saccharomyces cerevisiae; however, the sequence at the 3' end of the gene is not similar to any of the motifs implicated as processing signals in other mitochondrial systems. Unlike its counterparts in S. cerevisiae and Aspergillus nidulans, the mitochondrial LSU rRNA gene of S. pombe does not contain an intron. Comparison of potential secondary structure among the three fungal mitochondrial and Escherichia coli LSU rRNAs has defined a common secondary structure core, held together by long-range hydrogen-bonding interactions. A 5.8S-like structure is present within the 5'-terminal region of all three fungal mitochondrial LSU rRNAs; in contrast, no 4.5S-like structure is evident at the 3' end of these molecules. An evolutionary evaluation of highly conserved regions of a small set of LSU rRNA sequences suggests that S. pombe mitochondria diverged from a mitochondrial proto-fungal branch earlier than either A. nidulans or S. cerevisiae mitochondria. This result, considered in conjunction with the patterns of genome organization and codon usage in fungal mitochondria, points to a slower evolutionary clock speed in the mitochondrial genome of S. pombe.

RNA processing and expression of an intron-encoded protein in yeast mitochondria: role of a conserved dodecamer sequence

The 3' ends of most Saccharomyces cerevisiae mitochondrial mRNAs terminate at a conserved dodecamer sequence, 5'-AAUAAUAUUCUU-3', of unknown function. We have studied the consequences of mutations within a dodecamer found in an 1,143-base-pair optional intron of the mitochondrial large (21S) rRNA gene on RNA processing. The dodecamer is situated at the 3' end of an expressed open reading frame (ORF) within that intron, and the mutations are two adjacent transversions that extend the intron ORF by 51 nucleotides. The strain harboring these mutations, L5-10-1, is defective in biased intron transmission in crosses to strains that lack the intron, as are other mutants which contain nucleotide changes within the ORF (I. G. Macreadie, R. M. Scott, A. R. Zinn, and R. A. Butow, Cell 41:395-402, 1985). However, unlike these other mutants, wild-type strains, or petites which retain the intron allele, L5-10-1 is defective in processing at the intron dodecamer. In addition, L5-10-1 lacks a prominent 2.7-kilobase RNA containing both intron and exon sequences and at least two of four RNAs that correspond to various forms of the excised intron. We propose that these RNAs, missing in L5-10-1 but present in all other strains examined, arise in part by processing at the intron dodecamer. In addition, in all strains examined, we have detected a novel processing activity in which precursor 21S rRNA transcripts are cleaved in the upstream exon, about 1,500 nucleotides from the 5' end of the RNA. This activity, together with 3' intron dodecamer cleavage, probably accounts for the 2.7-kilobase RNA species, a candidate for the mRNA for the intron-encoded protein.

Spectinomycin resistance at site 1192 in 16S ribosomal RNA of E. coli: an analysis of three mutants

Three different single base substitutions were constructed at residue C-1192 in 16S rRNA on a plasmid-coded rrnB operon of E. coli using site-directed mutagenesis. All 3 mutants conferred different levels of resistance to spectinomycin in transformed cells but none affected the growth rate in the absence of the antibiotic. The G-1192 mutant conferred remarkable resistance, permitting growth in 40 mg/ml of spectinomycin.

On the nature of antibiotic binding sites in ribosomes

The ribosome is an enzyme and enzymes have active sites. Antibiotics that affect ribosomal function can be considered as enzyme inhibitors (or regulators) and it is therefore pertinent to identify their molecular targets as a means of studying the active sites of the particle. The methods available for doing this are considered and, in general terms, the data are evaluated. The conclusion is reached that there exists virtually no compelling evidence that antibiotics bind primarily to ribosomal proteins. Rather, studies of antibiotic resistance in various systems strongly suggest that ribosomal RNA is the primary target for a number of drugs. Moreover, in at least one case (relating to the antibiotic thiostrepton), such an effect can be demonstrated directly. These conclusions imply a fundamental role for RNA in ribosomal function.

RNA processing and expression of an intron-encoded protein in yeast mitochondria: role of a conserved dodecamer sequence

The 3' ends of most Saccharomyces cerevisiae mitochondrial mRNAs terminate at a conserved dodecamer sequence, 5'-AAUAAUAUUCUU-3', of unknown function. We have studied the consequences of mutations within a dodecamer found in an 1,143-base-pair optional intron of the mitochondrial large (21S) rRNA gene on RNA processing. The dodecamer is situated at the 3' end of an expressed open reading frame (ORF) within that intron, and the mutations are two adjacent transversions that extend the intron ORF by 51 nucleotides. The strain harboring these mutations, L5-10-1, is defective in biased intron transmission in crosses to strains that lack the intron, as are other mutants which contain nucleotide changes within the ORF (I. G. Macreadie, R. M. Scott, A. R. Zinn, and R. A. Butow, Cell 41:395-402, 1985). However, unlike these other mutants, wild-type strains, or petites which retain the intron allele, L5-10-1 is defective in processing at the intron dodecamer. In addition, L5-10-1 lacks a prominent 2.7-kilobase RNA containing both intron and exon sequences and at least two of four RNAs that correspond to various forms of the excised intron. We propose that these RNAs, missing in L5-10-1 but present in all other strains examined, arise in part by processing at the intron dodecamer. In addition, in all strains examined, we have detected a novel processing activity in which precursor 21S rRNA transcripts are cleaved in the upstream exon, about 1,500 nucleotides from the 5' end of the RNA. This activity, together with 3' intron dodecamer cleavage, probably accounts for the 2.7-kilobase RNA species, a candidate for the mRNA for the intron-encoded protein.

Antisuppressor mutations in Aspergillus nidulans: cold-resistant revertants of suppressor suaC109

Cold-resistant revertants of the cold-sensitive, ribosomal suppressorsuaC109have been isolated, with a view to obtaining mutations in new ribosomal protein genes. Many revertants had reduced suppressor activity and were classified as antisuppressor mutants. Both intragenic and extragenic reversions were found. In seven strains the extragenic reversion to cold resistance segregated with the antisuppressor phenotype, and these were designatedasumutations. Three of the fiveasugenes, C, B and D were mapped to linkage groups, I, II and V respectively. The antisuppressors are not gene-specific, although they mainly antagonize the activity of ribosomal suppressors. The antisuppressors altered all aspects of the phenotype of suppressorsuaC109including sensitivity to aminoglycoside antibiotics, and are therefore thought to be mutations in ribosomal protein genes.

Kinetic and segregational analysis of mitochondrial DNA recombination in yeast

A pair of yeast strains of opposite mating type was constructed to contain polymorphisms at three loci on the mitochondrial genome--the 21 S rRNA gene, var1, and cob--such that parental and recombinant forms of these genes could be easily detected by Southern blot analysis. These polymorphisms were used to measure in a single cross gene conversions at the 21 S rRNA and var1 loci and a reciprocal recombination at cob. For all three loci, recombination initiates at about the same time, 4 to 6 h after mixing cells, and increases with similar kinetics over a 24-h period. The segregation of parental and recombinant forms of these genes was then followed by pedigree analysis. The results, which show a high variance in the distribution of parental and recombinant forms of all three genes in cells derived from both the first bud and the mother zygote, are consistent with the segregation of a small number of mitochondrial DNA molecules from the zygote to diploid buds. Based on these results and previous experiments of this type, a limited "zone of mixing" of parental mitochondrial DNA molecules probably exists in the zygote. The extent of sampling from this zone, together with the intrinsic properties of the recombination events themselves, is likely to determine the observed pattern of recombination of mitochondrial DNA sequences at the population level.

Transmission of mitochondrial and chloroplast genomes in crosses of Chlamydomonas

Physical differences between organelle genomes of the interfertile species Chlamydomonas reinhardtii and Chlamydomonas smithii have been used to demonstrate that sexual zygotes transmit chloroplast and mitochondrial DNA from opposite mating types. Processes responsible can be separated functionally and genetically, although both are controlled by mating type. In vegetative diploids, chloroplast and mitochondrial genomes are transmitted biparentally, but a 1-kilobase insert present in the C. smithii mitochondrial genome spreads unidirectionally to all C. reinhardtii genomes in a manner reminiscent of the intron found in the mitochondrial 21S rRNA gene of omega + strains of yeast.

Three class I introns in the ND4L/ND5 transcriptional unit of Neurospora crassa mitochondria

The overlapping ND4L and ND5 genes of Neurospora crassa mitochondria are interrupted by one and two intervening sequences, respectively, of about 1,490, 1,408 and 1,135 bp in length. All three intervening sequences are class I introns and as such have the potential to fold into the conserved secondary structure that has been proposed for the majority of fungal mitochondrial introns. They contain long open reading frames (ORFs; from 306 to 425 codons long) that are continuous and in frame with the upstream exon sequences. These ORFs contain the conserved decapeptide-encoding sequences that are characteristic of the ORFs present in most class I introns. Extensive homology exists among the ORFs encoded by the ND4L intron, ND5 intron 1, and the second intron of the N. crassa oli2 gene. Also, internal repeats of about 130 amino acid residues are present twice in each of these three ORFs, suggesting that a duplication event may have occurred in the formation of these ORFs. The ND4L intron shares extensive homology (at the levels of both primary and proposed secondary structures) with the self-splicing intervening sequence present in the Tetrahymena nuclear rRNA gene. This homology includes but is not limited to the core secondary structure, as peripheral structural elements are also conserved in the two introns.

An intron in the 23S rRNA gene of the Chlorella chloroplasts: complete nucleotide sequence of the 23S rRNA gene

A 243 bp intron was found within the 23S rRNA gene of the unicellular green alga Chlorella ellipsoidea. This intron is A+T-rich (63.7%) compared with the 23S rRNA (50.5%) and is located in domain II of the 23S rRNA. In contrast to rRNA introns so far known, this intron is considerably small and does not possess features of group I introns in spite of its possible folded secondary structure; this is a new type rRNA intron. The complete nucleotide sequence of the 23S rRNA gene (2,965 bp) was also compared with that of tobacco chloroplasts and E. coli.

New reactions of the ribosomal RNA precursor of Tetrahymena and the mechanism of self-splicing

The availability of Tetrahymena pre-rRNA of discrete size, produced by transcription of recombinant plasmids with bacteriophage SP6 RNA polymerase, has permitted a more detailed investigation of the self-splicing reaction. The predicted splicing intermediate, the product of cleavage by guanosine at the 5' splice site, was identified. This intermediate was tested in the intermolecular exon ligation reaction and found to be competent to undergo the second step of splicing. These results and others that evaluated the reactivity of the 5' and 3' splice sites independently show that splicing occurs in two separable steps. The 3' splice site was found to be susceptible to site-specific hydrolysis leaving a hydroxyl terminus. This is interpreted as an indication that the 3' splice site is activated for nucleophilic attack in general and for exon ligation in particular. Preliminary evidence for specific hydrolysis at the 5' splice site was also obtained. All of the newly characterized intervening sequence RNA-mediated reactions as well as those found previously are divided into three categories: transesterification by guanosine at sites following two or three pyrimidine nucleotides (and, as a minor reaction, at sites following other guanosine residues); transesterification by oligopyrimidines or by the 5' exon (which terminates with C-U-C-U-C-UOH) at the site following the 3'-terminal guanosine residue of the intervening sequence; and specific hydrolysis at the splice sites. One of the products of the reactions at the 3' splice site is a molecule that contains the 5' exon still attached to the intervening sequence. It has a 3'-terminal GOH and undergoes cyclization both at the normal cyclization site within the intervening sequence and at the 5' splice site. The finding that the splice site can act as a cyclization site, combined with the earlier observation that the normal cyclization site is subject to attack by guanosine mononucleotide, leads us to propose that all these reactions may be occurring in the same active site. Translocation (a conformational change) would then bring different oligopyrimidine sequences into the active site for attack by guanosine. On the basis of the experimental results, a model for the local structure at the active site is described. A key feature of the model is the interaction between the U at the end of the oligopyrimidine sequence, a G residue within the internal guide sequence in the intervening sequence, and another G residue that can be either the attacking group for transesterification or the 3'-terminal G of the intervening sequence.

Universal code equivalent of a yeast mitochondrial intron reading frame is expressed into E. coli as a specific double strand endonuclease

The intron of the mitochondrial 21S rRNA gene of Saccharomyces cerevisiae (r1 intron) possesses a 235 codon long internal open reading frame (r1 ORF) whose translation product determines the duplicative transposition of that intron during crosses between intron-plus strains (omega+) and intron-minus ones (omega-). Using site-directed mutagenesis, we have constructed a universal code equivalent of the r1 ORF that, under appropriate promoter control, allows the overexpression in E. coli of a protein identical to the mitochondrial intron encoded "transposase". This protein exhibits a double strand endonuclease activity specific for the omega- site. This finding demonstrates, for the first time, the enzymatic activity of an intron encoded protein whose function is to promote the spreading of that intron by generating double strand breaks at a specific sequence within a gene.

The GC clusters of the mitochondrial genome of yeast and their evolutionary origin

We have studied the primary and secondary structures, the location and the orientation of the 196 GC clusters present in the 90% of the mitochondrial genome of Saccharomyces cerevisiae which have already been sequenced. The vast majority of GC clusters is located in intergenic sequences (including ori sequences, intergenic open reading frames and the gene varl which probably arose from an intergenic spacer) and in intronic closed reading frames (CRF's); most of them can be folded into stem-and-loop systems; both orientations are equally frequent. The primary structures of GC clusters permit to group them into eight families, seven of which are related to the family formed by clusters A, B and C of the ori sequences. On the basis of the present work, we propose that the latter derive from a primitive ori sequence (probably made of only a monomeric cluster C and its flanking sequences r* and r) through (i) a series of duplication inversions generating clusters A and B; and (ii) an expansion process producing the AT stretches of ori sequences. Most GC clusters apparently originated from primary clusters also derived from the primitive ori sequence in the course of its evolution towards the present ori sequences. Finally, we propose that the function of GC clusters is predominantly, or entirely, associated with the structure and organization of the mitochondrial genome of yeast and, indirectly, with the regulation of its expression.