The intron of the mitochondrial 21S rRNA gene: distribution in different yeast species and sequence comparison between Kluyveromyces thermotolerans and Saccharomyces cerevisiae

Bacterial group I introns: mobile RNA catalysts

Group I introns are intervening sequences that have invaded tRNA, rRNA and protein coding genes in bacteria and their phages. The ability of group I introns to self-splice from their host transcripts, by acting as ribozymes, potentially renders their insertion into genes phenotypically neutral. Some group I introns are mobile genetic elements due to encoded homing endonuclease genes that function in DNA-based mobility pathways to promote spread to intronless alleles. Group I introns have a limited distribution among bacteria and the current assumption is that they are benign selfish elements, although some introns and homing endonucleases are a source of genetic novelty as they have been co-opted by host genomes to provide regulatory functions. Questions regarding the origin and maintenance of group I introns among the bacteria and phages are also addressed.

A maturase-like coding sequence downstream of the OXI2 gene of yeast mitochondrial DNA is interrupted by two GC clusters and a putative end-of-messenger signal

By completing and correcting the sequence of a 1.8 kb DNA segment downstream of the oxi2 gene of Saccharomyces cerevisiae, a long, potentially coding sequence ("RF2") has been identified. The sequence is rather closely related to the RF1 open reading frame, downstream of the oxil gene, and, further, to the major family of intronic open reading frames. The RF2 open reading frame is not continuous, however, for it is interrupted by two GC clusters, both of which ultimately result in a -1 frameshift. Comparison with RF1 reveals a third insertion. This is centered on an oligo nucleotide, AATAATATTCTTA, which is found (sometimes in a slightly modified form) downstream of ten proven or suspected protein coding genes, including RF1 and RF2, and is known to terminate the apocytochrome b messenger RNA. It is suggested from the known distribution of this putative "end-of-messenger" signal, that it could play an essential part in controlling the expression of several minor proteins, both intronic and non-intronic. The possibility of the RF2 sequence being functional in spite of its interruptions is also discussed.

Comparative mitochondrial genomics within and among yeast species of the Lachancea genus

Yeasts are leading model organisms for mitochondrial genome studies. The explosion of complete sequence of yeast mitochondrial (mt) genomes revealed a wide diversity of organization and structure between species. Recently, genome-wide polymorphism survey on the mt genome of isolates of a single species, Lachancea kluyveri, was also performed. To compare the mitochondrial genome evolution at two hierarchical levels: within and among closely related species, we focused on five species of the Lachancea genus, which are close relatives of L. kluyveri. Hence, we sequenced the complete mt genome of L. dasiensis, L. nothofagi, L. mirantina, L. fantastica and L. meyersii. The phylogeny of the Lachancea genus was explored using these data. Analysis of intra- and interspecific variability across the whole Lachancea genus led to the same conclusions regarding the mitochondrial genome evolution. These genomes exhibit a similar architecture and are completely syntenic. Nevertheless, genome sizes vary considerably because of the variations of the intergenic regions and the intron content, contributing to mitochondrial genome plasticity. The high variability of the intergenic regions stands in contrast to the high level of similarity of protein sequences. Quantification of the selective constraints clearly revealed that most of the mitochondrial genes are under purifying selection in the whole genus.

Mitochondrial genome evolution in a single protoploid yeast species

Mitochondria are organelles, which play a key role in some essential functions, including respiration, metabolite biosynthesis, ion homeostasis, and apoptosis. The vast numbers of mitochondrial DNA (mtDNA) sequences of various yeast species, which have recently been published, have also helped to elucidate the structural diversity of these genomes. Although a large corpus of data are now available on the diversity of yeast species, little is known so far about the mtDNA diversity in single yeast species. To study the genetic variations occurring in the mtDNA of wild yeast isolates, we performed a genome-wide polymorphism survey on the mtDNA of 18 Lachancea kluyveri (formerly Saccharomyces kluyveri) strains. We determined the complete mt genome sequences of strains isolated from various geographical locations (in North America, Asia, and Europe) and ecological niches (Drosophila, tree exudates, soil). The mt genome of the NCYC 543 reference strain is 51,525 bp long. It contains the same core of genes as Lachancea thermotolerans, the nearest relative to L. kluyveri. To explore the mt genome variations in a single yeast species, we compared the mtDNAs of the 18 isolates. The phylogeny and population structure of L. kluyveri provide clear-cut evidence for the existence of well-defined geographically isolated lineages. Although these genomes are completely syntenic, their size and the intron content were found to vary among the isolates studied. These genomes are highly polymorphic, showing an average diversity of 28.5 SNPs/kb and 6.6 indels/kb. Analysis of the SNP and indel patterns showed the existence of a particularly high overall level of polymorphism in the intergenic regions. The dN/dS ratios obtained are consistent with purifying selection in all these genes, with the noteworthy exception of the VAR1 gene, which gave a very high ratio. These data suggest that the intergenic regions have evolved very fast in yeast mitochondrial genomes.

DMR1 (CCM1/YGR150C) of Saccharomyces cerevisiae encodes an RNA-binding protein from the pentatricopeptide repeat family required for the maintenance of the mitochondrial 15S ribosomal RNA

Pentatricopeptide repeat (PPR) proteins form the largest known RNA-binding protein family and are found in all eukaryotes, being particularly abundant in higher plants. PPR proteins localize mostly in mitochondria and chloroplasts, where they modulate organellar genome expression on the post-transcriptional level. The Saccharomyces cerevisiae DMR1 (CCM1, YGR150C) encodes a PPR protein that localizes to mitochondria. Deletion of DMR1 results in a complete and irreversible loss of respiratory capacity and loss of wild-type mtDNA by conversion to rho(-)/rho(0) petites, regardless of the presence of introns in mtDNA. The phenotype of the dmr1Delta mitochondria is characterized by fragmentation of the small subunit mitochondrial rRNA (15S rRNA), that can be reversed by wild-type Dmr1p. Other mitochondrial transcripts, including the large subunit mitochondrial rRNA (21S rRNA), are not affected by the lack of Dmr1p. The purified Dmr1 protein specifically binds to different regions of 15S rRNA in vitro, consistent with the deletion phenotype. Dmr1p is therefore the first yeast PPR protein, which has an rRNA target and is probably involved in the biogenesis of mitochondrial ribosomes and translation.

Complete nucleotide sequence of the mitochondrial DNA from Kluyveromyces lactis

The total nucleotide sequence of the mitochondrial genome of the yeast Kluyveromyces lactis was determined. The DNA is a circular molecule of 40,291 base pairs, with 26.1% GC. It contains a set of protein- and RNA-coding genes equivalent to those of the Saccharomyces cerevisiae mitochondrial genome. The genome size is about one half of that of S. cerevisiae mitochondrial DNA. The difference in size is due essentially to a reduced proportion of intergenic and intronic sequences. The coding sequences occupy about one third of the genome, the rest being composed of AT-rich sequences and numerous short GC-rich clusters that are dispersed mostly in the non-coding regions and a few within coding sequences. The presence of these GC clusters is a characteristic feature common to K. lactis and S. cerevisiae mitochondrial DNA, although their sequence patterns are different. The absence of the NADH dehydrogenase subunit genes distinguishes this yeast and S. cerevisiae from the typically aerobic species. The genetic code appears to be that of the standard fungal mitochondrial genomes, with UGA as a tryptophan codon. There are only 22 transfer RNA genes, those corresponding to CUN and CGN codons being missing. CUN codons are absent in the protein-coding sequences. There are five CGN codons within the open reading frames, but they are located exclusively in the introns, rendering them untranslatable. Introns are found only the genes in KlCOX1 and LrRNA. The transcription promoter motif known in S. cerevisiae and several other yeast species is also present. All genes are transcribed from the same strand, except those on a single 7-kilobase pairs segment (EMBL Accession No. AY654900).

The complete mitochondrial genome of the yeast Kluyveromyces thermotolerans

We report here the complete nucleotide sequence of the 23.5-kb mitochondrial genome from the yeast Kluyveromyces thermotolerans. It encodes, all on the same DNA strand, three subunits of cytochrome oxidase (COX1, COX2 and COX3), three subunits of ATP synthetase (ATP6, ATP8 and ATP9), the apocytochrome b (COB), the ribosomal protein VAR1, 24 tRNAs, the small and large ribosomal RNAs, and the RNA subunit of RNase P. Three intronic ORFs are present within the COX1 gene group I introns. The K. thermotolerans mitochondrial genome is very similar to the Candida glabrata mitochondrial genome, as judged from clusters of gene order, gene transcription units and sequence similarities. Interestingly, the predicted secondary structure of the abnormal tRNAThr1 contains 10 nucleotides in its anticodon loop. This sequence is available under EMBL Accession No. AJ634268.

The SUV3 gene from Saccharomyces douglasii is a functional equivalent of its Saccharomyces cerevisiae orthologue and is essential for respiratory growth

In the yeast Saccharomyces cerevisiae the product of the nuclear gene SUV3 has been shown to be involved in a variety of mitochondrial post-transcriptional processes. We have cloned and sequenced the SUV3 gene from Saccharomyces douglasii, a close relative of S. cerevisiae which has important changes in the organization of its mitochondrial genome and concomitant changes in nucleo-mitochondrial interactions. We show that the S. douglasii SUV3 gene shares considerable structural homology (92% amino acid sequence identity) with its S. cerevisiae counterpart and that their nucleotide sequences display evidence of recent divergence. To determine the function of the S. douglasii SUV3 gene we have constructed a strain carrying an inactive SUV3 gene and analyzed the effect of this inactivation on the integrity of the mitochondrial genome and on the stability of mitochondrial transcripts. We have demonstrated that the S. douglasii SUV3 gene, like the S. cerevisiae gene, is essential for respiratory growth and for stability of the intron-containing mitochondrial transcripts, thus the two genes are functionally equivalent. Also the S. douglasii and S. cerevisiae SUV3 genes are completely interchangeable, despite the differences in the structure of the mitochondrial chromosome in the two yeasts.

Identification of a nuclear gene (FMC1) required for the assembly/stability of yeast mitochondrial F(1)-ATPase in heat stress conditions

We have identified a yeast nuclear gene (FMC1) that is required at elevated temperatures (37 degrees C) for the formation/stability of the F(1) sector of the mitochondrial ATP synthase. Western blot analysis showed that Fmc1p is a soluble protein located in the mitochondrial matrix. At elevated temperatures in yeast cells lacking Fmc1p, the alpha-F(1) and beta-F(1) proteins are synthesized, transported, and processed to their mature size. However, instead of being incorporated into a functional F(1) oligomer, they form large aggregates in the mitochondrial matrix. Identical perturbations were reported previously for yeast cells lacking either Atp12p or Atp11p, two specific assembly factors of the F(1) sector (Ackerman, S. H., and Tzagoloff, A. (1990) Proc. Natl. Acad. Sci. U. S. A. 87, 4986--4990), and we show that the absence of Fmc1p can be efficiently compensated for by increasing the expression of Atp12p. However, unlike Atp12p and Atp11p, Fmc1p is not required in normal growth conditions (28--30 degrees C). We propose that Fmc1p is required for the proper folding/stability or functioning of Atp12p in heat stress conditions.

Genomic exploration of the hemiascomycetous yeasts: 10. Kluyveromyces thermotolerans

A genomic exploration of Kluyveromyces thermotolerans was performed by random sequence tag (RST) analysis. We sequenced 2653 RSTs corresponding to inserts sequenced from both ends. We performed a systematic comparison with a complete set of proteins from Saccharomyces cerevisiae, other completely sequenced genomes and SwissProt. We identified six mitochondrial genes and 1358-1496 nuclear genes by comparison with S. cerevisiae. In addition, 25 genes were identified by comparison with other organisms. This corresponds to about 24% of the estimated gene content of this organism. A lower level of conservation is observed with orthologues to genes of S. cerevisiae previously classified as orphans. Gene order was found to be conserved between S. cerevisiae and K. thermotolerans in 56.5% of studied cases.

Molecular typing demonstrates homogeneity of Saccharomyces uvarum strains and reveals the existence of hybrids between S. uvarum and S. cerevisiae, including the S. bayanus type strain CBS 380

PCR/RFLP of the NTS2 sequence of rDNA was shown to be suitable for differentiating Saccharomyces sensu stricto species. We previously showed that, within the presently accepted S. bayanus taxon, strains formerly classified as S. uvarum represented a distinct subgroup (Nguyen and Gaillardin, 1997). In this study, we reidentified 43 more strains isolated recently from wine, cider and various fermentation habitats, and confirmed by karyotyping, hybridization and mtDNA analysis the homogeneity of strains from the S. uvarum subspecies. Molecular typing of nuclear and mitochondrial genomes of strains preserved in collections, and often originating from beer like S. pastorianusNT, revealed the existence of hybrids between S. uvarum and S. cerevisiae. Surprisingly, S. bayanusT CBS380 appeared itself to be a hybrid between S. uvarum and S. cerevisiae. This strain has a mitochondrial genome identical to that of S. uvarum, and a very similar karyotype with 13 isomorphic chromosomes, six of which at least hybridize strongly with S. uvarum chromosomes or with a S. uvarum specific sequence. However, four of the chromosome bands of S. bayanusT bear Y' sequences indistinguishable from those of S. cerevisiae, a feature that is not observed among presently isolated S. uvarum strains. Because of the hybrid nature of S. bayanus(T) and of the scarcity of similar hybrids among present days isolates, we propose to reinstate S. uvarum as a proper species among the Saccharomyces sensu stricto complex.

Recurrent invasion and extinction of a selfish gene

Homing endonuclease genes show super-Mendelian inheritance, which allows them to spread in populations even when they are of no benefit to the host organism. To test the idea that regular horizontal transmission is necessary for the long-term persistence of these genes, we surveyed 20 species of yeasts for the omega-homing endonuclease gene and associated group I intron. The status of omega could be categorized into three states (functional, nonfunctional, or absent), and status was not clustered on the host phylogeny. Moreover, the phylogeny of omega differed significantly from that of the host, strong evidence of horizontal transmission. Further analyses indicate that horizontal transmission is more common than transposition, and that it occurs preferentially between closely related species. Parsimony analysis and coalescent theory suggest that there have been 15 horizontal transmission events in the ancestry of our yeast species, through simulations indicate that this value is probably an underestimate. Overall, the data support a cyclical model of invasion, degeneration, and loss, followed by reinvasion, and each of these transitions is estimated to occur about once every 2 million years. The data are thus consistent with the idea that frequent horizontal transmission is necessary for the long-term persistence of homing endonuclease genes, and further, that this requirement limits these genes to organisms with easily accessible germ lines. The data also show that mitochondrial DNA sequences are transferred intact between yeast species; if other genes do not show such high levels of horizontal transmission, it would be due to lack of selection, rather than lack of opportunity.

PetCR46, a gene which is essential for respiration and integrity of the mitochondrial genome

In the frame of the European Pilot Project for the functional analysis of newly discovered open reading frames (ORFs) from Saccharomyces cerevisiae chromosome III, we have deleted entirely the YCR46C ORF by a one-step polymerase chain reaction method and replaced it by the HIS3 marker in the strain W303. The deletion has been checked by meiotic segregation and Southern blot analyses. Characterization of the deleted strain indicates that YCR46C is essential for respiration and maintenance of the mitochondrial genome since its deletion leads to the appearance of 100% of cytoplasmic petites. Hybridization with molecular probes from mtDNA of individual clones of such petites showed that about 50% did hybridize (rho- clones) while others did not (possibly rho degrees clones). The wild-type gene has been cloned and shown to complement the deletion. The gene, which probably codes for a mitochondrial ribosomal protein, has been called petCR46.

The suv3 nuclear gene product is required for the in vivo processing of the yeast mitochondrial 21s rRNA transcripts containing the r1 intron

We have constructed a yeast mitochondrial genome containing only one group-I intron, r1, from the 21s rRNA gene and introduced this genome into a strain bearing a disruption of the suv3 gene. The presence of the r1 intron alone causes a block in respiration, while the isogenic strain containing the intronless genome is respiratory competent. Northern analysis indicates that the functional suv3 protein is necessary for the yeast cell in order to process the r1-containing transcripts: in the absence of the suv3 protein the hybridization pattern of the excised r1 intron is altered and the amount of mature 21s rRNA is 50-fold lower. We suggest that the multifunctional suv3 protein, which displays motifs of ATP-dependent RNA helicases, is necessary for the in vivo pathway leading to formation of mature 21s rRNA from the transcripts containing the r1 intron in mitochondria of Saccharomyces cerevisiae.

Identification of group-I introns in the 28s rDNA of the entomopathogenic fungus Beauveria brongniartii

The length of the 28s ribosomal DNA differs significantly between two strains (Bt102 and Bt114) of the entomopathogenic fungus Beauveria brongniartii. RFLP analysis on PCR products revealed the presence of three insertional elements of 350-450 bp in strain Bt114. One of the insertions has been cloned and sequenced and shown to possess all the characteristic sequences and secondary structures of a group-IC intron. Its length is 428 bp and it is devoid of any long open reading frame. The distribution of this intron elsewhere in the genome of Bt114, as well as in the chromosomal ribosomal DNA, was studied. It seems to be present as seven copies in different genes not corresponding to the mitochondrial DNA. The presence of the intron in other strains of B. brongniartii was examined by the hybridization method. Some of them seemed to possess introns with a similar core although others presented no homology with the cloned fragment.

Homologous maturase-like proteins are encoded within the group I introns in different mitochondrial genes specifying Yarrowia lipolytica cytochrome c oxidase subunit 3 and Saccharomyces cerevisiae apocytochrome b

A mitochondrial cox3 gene in the alkane yeast, Yarrowia lipolytica, encodes a subunit-3 protein of cytochrome c oxidase, and contains a 1044 base-pair-long intron, as compared with the corresponding intronless gene in Saccharomyces cerevisiae. The intron belongs to a group I intron as determined by the cDNA sequence for the splicing sites as well as the predicted RNA secondary structure. Remarkably, this intron could code for a protein of 206 amino-acid residues which showed 63% similarity with an RNA maturase encoded by the second intron of the mitochondrial apocytochrome b gene in S. cerevisiae. Both introns occurred within the conserved exon sequence, 5'-TT(G/C)AGGTGC-3', suggesting the possible transposition of a common ancestral intron.

A comparative database of group I intron structures

We have created a database of comparatively derived group I intron secondary structure diagrams. This collection currently contains a broad sampling of phylogenetically and structurally similar and diverse structures from over 200 publicly available intron sequences. As more group I introns are sequenced and added to the database, we anticipate minor refinements in these secondary structure diagrams. These diagrams are directly accessible by computer as well as from the authors.

Small subunit rDNA variation in a population of lichen fungi due to optional group-I introns

A natural population of the lichen-forming ascomycetous fungus, Cladonia chlorophaea, contained individuals with small subunit ribosomal DNA (SSU rDNA) of at least four different size classes and nine restriction-site patterns. The source of these differences was the variable occurrence of 200-400-nucleotide insertions, previously identified as small group-I introns, at five different positions within the SSU coding region. By specific amplification of the sequences flanking these five intron positions with the polymerase chain reaction (PCR), a minimum of nine types of rDNA repeats were defined that differ in number, position, restriction pattern and size of introns. The positions of the introns were verified by sequence analysis. The variable distribution of these introns suggests that they are currently mobile--either by intron insertion, deletion or both--within this species complex.

The NAM1/MTF2 nuclear gene product is selectively required for the stability and/or processing of mitochondrial transcripts of the atp6 and of the mosaic, cox1 and cytb genes in Saccharomyces cerevisiae

The NAM1/MTF2 gene was firstly isolated as a multicopy suppressor of mitochondrial splicing deficiencies and independently as a gene of which a thermosensitive allele affects mitochondrial transcription in organello. To determine which step in mitochondrial RNA metabolism is controlled in vivo by the NAM1 gene, mitochondrial transcripts of seven transcription units from strains carrying an inactive nam1::URA3 gene disruption in various mitochondrial genetic backgrounds were analysed by Northern blot hybridisations. In a strain carrying an intron-containing mitochondrial genome, the inactivation of the NAM1 gene led to a strong decrease in (or total absence of) the mosaic cytb and cox1 mRNAs and in transcripts of the atp6-rf3/ens2 genes, which are co-transcribed with cox1. Neither the accumulation of unspliced cytb or cox1 pre-mRNAs, nor that of excised circular intron molecules of ai1 or ai2 were observed, but the abundance of the bi1 and ai7 lariats was comparable to that observed in the wild-type strain, thus demonstrating that transcription of the cytb and cox1 genes does occur. In strains carrying the intron-less mitochondrial genome with or without the rf3/ens2 sequence, wild-type amounts of cytb and cox1 mRNAs were detected while the amount of the atp6 mRNA was always strongly decreased. The abundance of transcripts from five other genes was either slightly (21S rRNA) or not at all (cox2, cox3, atp9 and 15S rRNA) affected by the nam1 inactivation.(ABSTRACT TRUNCATED AT 250 WORDS)

The single group-I intron in the chloroplast rrnL gene of Chlamydomonas humicola encodes a site-specific DNA endonuclease (I-ChuI)

The single group-I intron (ChLSU.1) in the chloroplast (cp) large subunit rRNA-encoding gene (rrnL) of the green alga Chlamydomonas humicola is located at a position at which no introns have previously been characterized in other systems. In the present study, the nucleotide (nt) sequence of this 1118-bp intron was found to contain an internal open reading frame (ORF) that potentially encodes a basic protein of 218 amino acid residues. The putative C. humicola protein features two copies of the LAGLI-DADG motif and is part of the family of intron-encoded proteins comprising the endonucleases (ENases), I-SceI, I-SceIV and I-CsmI. Expression of the ChLSU.1 intron ORF in vitro in the presence of a 260-bp DNA fragment containing the exon 1-2 junction of an intronless version of the C. humicola rrnL resulted in specific cleavage of the DNA fragment very close to the intron insertion site. This novel intron-encoded ENase, designated I-ChuI, was also shown to generate a staggered cut with 4-nt (CTCG) 3'-OH overhangs 2 bp downstream from the intron insertion site.

Mitochondrial genes in the colourless alga Prototheca wickerhamii resemble plant genes in their exons but fungal genes in their introns

The mitochondrial DNA from the colourless alga Prototheca wickerhamii contains two mosaic genes as was revealed from complete sequencing of the circular extranuclear genome. The genes for the large subunit of the ribosomal RNA (LSUrRNA) as well as for subunit I of the cytochrome oxidase (coxI) carry two and three intronic sequences respectively. On the basis of their canonical nucleotide sequences they can be classified as group I introns. Phylogenetic comparisons of the coxI protein sequences allow us to conclude that the P.wickerhamii mtDNA is much closer related to higher plant mtDNAs than to those of the chlorophyte alga C.reinhardtii. The comparison of the intron sequences revealed several unusual features: (1) The P.wickerhamii introns are structurally related to mitochondrial introns from various ascomycetous fungi. (2) Phylogenetic analyses indicate a close relationship between fungal and algal intronic sequences. (3) The P. wickerhamii introns are located at positions within the structural genes which can be considered as preferred intron insertion sites in homologous mitochondrial genes from fungi or liverwort. In all cases, the sequences adjacent to the insertion sites are very well conserved over large evolutionary distances. Our finding of highly similar introns in fungi and algae is consistent with the idea that introns have already been present in the bacterial ancestors of present day mitochondria and evolved concomitantly with the organelles.

Imported sequences in the mitochondrial yeast genome identified by nucleotide linguistics

In addition to universally appearing mitochondrial (mt) genes, origins of replication and transcription start regions typical of all mt genome variants of the yeast Saccharomyces cerevisiae, the mt genomes of some of the strains contain variable sequences. These sequences are apparently largely dispensable. They are mainly composed of group-I and -II introns and intergenic open reading frames (ORFs). Many of the introns contain ORFs, some of which were shown by genetic and biochemical means to be involved in splicing and transposition of the mt introns. Some of the optional sequences are hypothesized to be mobile genetic elements. Nucleotide (nt) sequences of the mt genome of S. cerevisiae were examined by analyzing occurrences of oligodeoxyribonucleotide (oligo) 'words'. This linguistic technique had been found to be sensitive to both function and origin of the sequence [Pietrokovski et al., J. Biomol. Struct. Dyn. 7 (1990) 1251-1268]. A clear difference is found between the oligo vocabularies of the optional and basic yeast mt sequences. The difference is mainly located in protein coding segments of the optional sequences which contain conserved amino acid motifs, characteristic of intronic and intergenic ORFs. The use of nt linguistics to detect the sequence dissimilarity and its causes in yeast mitochondria provides fast and straightforward results, identifying the intronic and intergenic ORFs as DNA sequences of foreign, non-mt origin.

Nucleotide sequence of the COX1 gene in Kluyveromyces lactis mitochondrial DNA: evidence for recent horizontal transfer of a group II intron

The cytochrome oxidase subunit 1 gene (COX1) in K. lactis K8 mtDNA spans 8,826 bp and contains five exons (termed E1-E5) totalling 1,602 bp that show 88% nucleotide base matching and 91% amino acid homology to the equivalent gene in S. cerevisiae. The four introns (termed K1 cox1.1-1.4) contain open reading frames encoding proteins of 786, 333, 319 and 395 amino acids respectively that potentially encode maturase enzymes. The first intron belongs to group II whereas the remaining three are group I type B. Introns K1 cox1.1, 1.3, and 1.4 are found at identical locations to introns Sc cox1.2, 1.5 a, and 1.5 b respectively from S. cerevisiae. Horizontal transfer of an intron between recent progenitors of K. lactis and S. cerevisiae is suggested by the observation that K1 cox1.1 and Sc cox1.2 show 96% base matching. Sequence comparisons between K1 cox1.3/Sc cox1.5 a and K1 cox1.4/Sc cox1.5 b suggest that these introns are likely to have been present in the ancestral COX1 gene of these yeasts. Intron K1 cox1.2 is not found in S. cerevisiae and appears at an unique location in K. lactis. A feature of the DNA sequences of the group I introns K1 cox1.2, 1.3, and 1.4 is the presence of 11 GC-rich clusters inserted into both coding and noncoding regions. Immediately downstream of the COX1 gene is the ATPase subunit 8 gene (A8) that shows 82.6% base matching to its counterpart in S. cerevisiae mtDNA.

Incipient mitochondrial evolution in yeasts. I. The physical map and gene order of Saccharomyces douglasii mitochondrial DNA discloses a translocation of a segment of 15,000 base-pairs and the presence of new introns in comparison with Saccharomyces cerevisiae

We have determined the physical and genetic map of the 73,000 base-pair mitochondrial genome of a novel yeast species Saccharomyces douglasii. Most of the protein and RNA-coding genes known to be present in the mitochondrial DNA of Saccharomyces cerevisiae have been identified and located on the S. douglasii mitochondrial genome. The nuclear genomes of the two species are thought to have diverged some 50 to 80 million years ago and their nucleo-mitochondrial hybrids are viable but respiratorily deficient. The mitochondrial genome of S. douglasii displays many interesting features in comparison with that of S. cerevisiae. The three mosaic genes present in both genomes are quite different with regard to their structure. The S. douglasii COXI gene has two new introns and is missing the five introns of the S. cerevisiae gene. The S. douglasii cytochrome b gene has one new intron and lacks two introns of the S. cerevisiae gene. Finally, the L-rRNA gene of S. douglasii, like that of S. cerevisiae, has one intron of which the structure is different. Another salient feature of the S. douglasii mitochondrial genome reported here is that the gene order is different in comparison with S. cerevisiae mitochondrial DNA. In particular, a segment of approximately 15,000 base-pairs including the genes coding for COXIII and S-rRNA has been translocated to a position between the genes coding for varl and L-rRNA.

Incipient mitochondrial evolution in yeasts. II. The complete sequence of the gene coding for cytochrome b in Saccharomyces douglasii reveals the presence of both new and conserved introns and discloses major differences in the fixation of mutations in evolution

We have determined the complete sequence of the mitochondrial gene coding for cytochrome b in Saccharomyces douglasii. The gene is 6310 base-pairs long and is interrupted by four introns. The first one (1311 base-pairs) belongs to the group ID of secondary structure, contains a fragment open reading frame with a characteristic GIY ... YIG motif, is absent from Saccharomyces cerevisiae and is inserted in the same site in which introns 1 and 2 are inserted in Neurospora crassa and Podospora anserina, respectively. The next three S. douglasii introns are homologous to the first three introns of S. cerevisiae, are inserted at the same positions and display various degrees of similarity ranging from an almost complete identity (intron 2 and 4) to a moderate one (intron 3). We have compared secondary structures of intron RNAs, and nucleotide and amino acid sequences of cytochrome b exons and intron open reading frames in the two Saccharomyces species. The rules that govern fixation of mutations in exon and intron open reading frames are different: the relative proportion of mutations occurring in synonymous codons is low in some introns and high in exons. The overall frequency of mutations in cytochrome b exons is much smaller than in nuclear genes of yeasts, contrary to what has been found in vertebrates, where mitochondrial mutations are more frequent. The divergence of the cytochrome b gene is modular: various parts of the gene have changed with a different mode and tempo of evolution.

Mitochondrial genome of Saccharomyces douglasii: genes coding for components of the protein synthetic apparatus

Mitochondrial genes coding for some components of the protein synthetic apparatus in S. douglasii have been studies in detail. A region containing stretches of high homology to the S. cerevisiae tRNA synthesis locus (TSL) and the tRNA(fmet) gene has been identified and sequenced. The organization of this region was very similar to that present in S. cerevisiae, including the presence of a possible transcription starting signal. The S. douglasii TSL gene is shorter due to several deletions which, however, do not involve the regions coding for RNA domains know to be required for the catalytic activity of mitochondrial RNAse P. The S. douglasii LSU rRNA gene has been shown to contain a typical group I intron highly homologous to its S. cerevisiae counterpart, except for the absence of the open reading frame which in S. cerevisiae codes for I-SceI endonuclease.

Distribution of mitochondrial r1-type introns and the associated open reading frame in the yeast genus Kluyveromyces

We have sequenced the intron in the large subunit ribosomal RNA gene from the mitochondrion of Kluyveromyces lactis. It is a typical group I intron but, unlike the corresponding intron (r1) in Saccharomyces cerevisiae, it does not contain an open reading frame. This intron is widespread in the genus Kluyveromyces although intron-less strains were also found in some species of this genus. Sequences homologous to the open reading frame of the S. cerevisiae ribosomal intron were detected in some strains of K. waltii, K. thermotolerans and K. africanus.

The yeast mitochondrial leucyl-tRNA synthetase is a splicing factor for the excision of several group I introns

The Saccharomyces cerevisiae nuclear gene NAM2 codes for mitochondrial leucyl-tRNA synthetase (mLRS). Herbert et al. (1988, EMBO J 7:473-483) proposed that this protein is involved in mitochondrial RNA splicing. Here we present the construction and analyses of nine mutations obtained by creating two-codon insertions within the NAM2 gene. Three of these prevent respiration while maintaining the mitochondrial genome. These three mutants: (1) display in vitro a mLRS activity ranging from 0%-50% that of the wild type: (2) allow in vivo the synthesis of several mitochondrially encoded proteins; (3) prevent the synthesis of the COXII protein but not of its mRNA; (4) abolish the splicing of the group I introns bI4 and aI4; and (5) affect significantly the excision of the group I introns bI2, bI3 and aI3. Importation of the bI4 maturase from the cytoplasm into mitochondria in a nam2- mutant strain does not restore the excision of the introns bI4 and aI4 implying that the splicing deficiency does not result from the absence of the bI4 maturase. We conclude that the mLRS is a splicing factor essential for the excision of the group I introns bI4 and aI4 and probably important for the excision of other group I introns.

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.

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.

Stable maintenance of a 35-base-pair yeast mitochondrial genome

Small deletion variants ([rho-] mutants) derived from the wild-type ([ rho+]) Saccharomyces cerevisiae mitochondrial genome were isolated and characterized. The mutant mitochondrial DNAs (mtDNAs) examined retained as little as 35 base pairs of one section of intergenic DNA, were composed entirely of A.T base pairs, and were stably maintained. These simple mtDNAs existed in tandemly repeated arrays at an amplified level that made up approximately 15% of the total cellular DNA and, as judged by fluorescence microscopy, had a nearly normal mitochondrial arrangement throughout the cell cytoplasm. The simple nature of these [rho-] genomes indicates that the sequences required to maintain mtDNA must be extremely simple.

Stable maintenance of a 35-base-pair yeast mitochondrial genome

Small deletion variants ([rho-] mutants) derived from the wild-type ([ rho+]) Saccharomyces cerevisiae mitochondrial genome were isolated and characterized. The mutant mitochondrial DNAs (mtDNAs) examined retained as little as 35 base pairs of one section of intergenic DNA, were composed entirely of A.T base pairs, and were stably maintained. These simple mtDNAs existed in tandemly repeated arrays at an amplified level that made up approximately 15% of the total cellular DNA and, as judged by fluorescence microscopy, had a nearly normal mitochondrial arrangement throughout the cell cytoplasm. The simple nature of these [rho-] genomes indicates that the sequences required to maintain mtDNA must be extremely simple.

Cloning and sequencing of the gene for apocytochrome b of the yeast Kluyveromyces lactis strains WM27 (NRRL Y-17066) and WM37 (NRRL Y-1140)

The apocytochrome b genes from two strains of the yeast Kluyveromyces lactis, have been isolated and sequenced. The coding sequences in strains WM27 (NRRL Y-17066) and WM37 (NRRL Y-1140) were identical but the upstream noncoding regions were slightly different. The sequences demonstrated the presence of a continuous open reading frame with no introns. The amino acid sequence, derived from the coding strand, showed 82% homology to the apocytochrome b of Saccharomyces cerevisiae strain D273-10B and only 58% homology to the protein from Schizosaccharomyces pombe strain 50. CUN and CGN codon families were absent from the K. lactis gene. Codon usage was very similar to that of other mitochondrial genomes with mostly U or A in the third position. There were two unusual features. All threonines were coded by ACA(U) and all arginines by AGA.

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.

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.

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.

Mitochondrial DNAs of Suillus: three fold size change in molecules that share a common gene order

We constructed restriction-site and gene maps for mitochondrial DNAs from seven isolates of five species of Suillus (Boletaceae, Basidiomycotina). Each mitochondrial genome exists as a single circular chromosome, ranging in size from 36 to 121 kb. Comparisons within species and between two closely related species revealed that insertions and deletions are the major form of genome change, whereas most restriction sites are conserved. Among more distantly related species, size and restriction-site differences were too great to allow precise alignments of maps, but small clusters of putatively homologous restriction sites were found. Two mitochondrial gene orders exist in the five species. These orders differ only by the relative positions of the genes for ATPase subunit 9 and the small ribosomal RNA and are interconvertible by a single transposition. One of the two gene arrangements is shared by four species whose mitochondrial DNAs span the entire size range of 36 to 121 kb. The conservation of gene order in molecules that vary over three-fold in size and share few restriction sites demonstrates a low frequency of rearrangements relative to insertions, deletions, and base substitutions.

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.

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.

An approach to yeast classification by mapping mitochondrial DNA from Dekkera/Brettanomyces and Eeniella genera

Sequences hybridizing to mitochondrial DNA probes from Saccharomyces cerevisiae have been mapped in six mitochondrial genomes from the Dekkera/Brettanomyces yeasts and in mtDNA from the closely related Eeniella nana. Sequence order for the 34.5 kbp mtDNA of E. nana is identical to that for mtDNAs from B. custersianus (28.5 kbp) and B. naardenensis (41.7 kbp) thereby suggesting that the former yeast is affiliated with the latter two species. A closer relationship is suggested for D. intermedia and D. bruxellensis as mtDNAs from these yeasts, 73.2 and 85.0 kbp respectively, have the same sequence order and mostly common restriction endonuclease sites. Differences between the two molecules are reminiscent of those found in mtDNA polymorphisms of S. cerevisiae strains thereby suggesting that the two Dekkera yeasts are variants of a single species. An unusual feature of the Dekkera species mtDNA is an inversion of the cytochrome b hybridizable region relative to the LrRNA sequence. Likewise mtDNA from B. anomalus (57.7 kbp) has an inversion of the cytochrome oxidase subunit 1 sequence with respect to the LrRNA sequence. By contrast the largest mtDNA (101.1 kbp) from B. custersii has the cytochrome b and LrRNA sequences in the same orientation. In addition hybridizable regions in this mtDNA are found in three clusters that are separated by several thousand base pairs of sequence deficient in restriction endonuclease sites. This observation together with the low guanine and cytosine content of the mtDNA suggests that the regions separating the sequence clusters are mostly adenine and thymine residues.

Mitochondrial introns as mobile genetic elements: the role of intron-encoded proteins

Introns of organelle genes share distinctive RNA secondary structures that allow their classification into two known families. These structures are believed to play an essential role in splicing, and members of both structural classes have recently been shown to perform self-splicing reactions in vitro. In lower eukaryotes, many structured introns also contain long internal open reading frames (ORFs), which are able to code for hydrophilic proteins. Several properties of self-splicing structured introns suggest that they resemble mobile genetic elements, even though no actual transposition event involving these introns has yet been found. We report here on the characterization of two intron-encoded proteins that strongly support this attractive idea. First, we show that the class I intron of the 21S ribosomal RNA (rRNA) gene of Saccharomyces cerevisiae omega+ strains (rl intron) encodes a specific transposase. This protein has been partially purified from Escherichia coli cells that overexpress it from an artificial universal code equivalent to the rl intronic ORF. The omega transposase shows a double-strand endonuclease activity in vitro. This activity creates a 4-bp staggered cut with 3' OH overhangs within a specific sequence of the 21S rRNA gene of omega- strains. It is precisely within this sequence that the rl intron inserts by a duplicative transposition. Second, we report on the synthesis, in E. coli, of a putative reverse transcriptase encoded by the class II intron of the cytochrome b gene of Schizosaccharomyces pombe. This synthesis was obtained from E. coli expression vectors, using the class II intronic ORF linked to an artificial initiator sequence. As further support of the idea that structured introns are mobile, we show, from a systematic screening of introns in various yeast species, that the rl intron has transposed into the ATPase subunit 9 gene of Kluyveromyces fragilis. Structural features observed at the new intron homing site may be relevant to the transposition event.

Analysis of class I introns in a mitochondrial plasmid associated with senescence of Podospora anserina reveals extraordinary resemblance to the Tetrahymena ribosomal intron

Recently, the nucleotide sequences for three "mitochondrial plasmids" associated with senescence of Podospora anserina were determined (Cummings et al. 1985). One of these sequences, corresponding to the plasmid termed epsilon senDNA, contains three class I introns, all within a protein coding sequence equivalent to the mammalian "URF1" gene. Here, we present primary and secondary structure analyses for two of these introns as well as a partial analysis for the third, which extends beyond the DNA sequence determined. With regard to both primary and secondary structure, the closest known relative of intron 1 is the self-splicing intron in the large ribosomal RNA gene of Tetrahymena. One secondary structure domain at the periphery of intron 1 and Tetrahymena models is also present in intron 2. The latter intron is the longest known class I member and contains remnants of two protein-coding sequences, one of which is split by the other. Evolutionary processes that might be responsible for the unusual structure of introns 1 and 2 are discussed.

The pho1 mutation. A frameshift, and its compensation, producing altered forms of physiologically efficient ATPase in yeast mitochondria

The pho1 mutation belongs to the OL12 gene on mitochondrial DNA of Saccharomyces cerevisiae, which codes for a membrane factor subunit of the mitochondrial ATPase (apparent molecular mass 20 kDa). We analysed the ATPase complex from the pho1 mutant and from three revertants, after immunoprecipitation from mitochondrial extracts, by dodecyl sulphate/acrylamide gel electrophoresis. In two revertants the OL12 gene product appeared as an abundant slower migrating peptide, while in the pho mutant, two bands appeared in very low amounts. For the third revertant, a strong band appeared at the normal level. Sequencing of the OL12 gene from these strains gave the following results: the pho1 mutation is a frameshift, arising by insertion of an extra thymidine into a group of three. Two of the revertants contain the same group of four thymidines, but genetic compensation of the frameshift occurs 24 base pairs downstream by the loss of four bases, implying a deficit of one codon. The third revertant has recovered the normal three-thymidine sequence. There is excellent correlation between the modified sequences and electrophoretic migration of the peptide product. Owing to the leakiness of the pho1 phenotype (reduced but not nil growth rate on oxidizable carbon sources, 5-10% highly oligomycin-sensitive ATPase complex, low amounts of OL12 gene product peptides), some translational correction of the frameshift is bound to occur. Based on these results, the compatibility of abnormal ATPase architecture with modified energetic efficiency is discussed.