NAM9 nuclear suppressor of mitochondrial ochre mutations in Saccharomyces cerevisiae codes for a protein homologous to S4 ribosomal proteins from chloroplasts, bacteria, and eucaryotes.

We report the genetic characterization, molecular cloning, and sequencing of a novel nuclear suppressor, the NAM9 gene from Saccharomyces cerevisiae, which acts on mutations of mitochondrial DNA. The strain NAM9-1 was isolated as a respiration-competent revertant of a mitochondrial mit mutant which carries the V25 ochre mutation in the oxi1 gene. Genetic characterization of the NAM9-1 mutation has shown that it is a nuclear dominant omnipotent suppressor alleviating several mutations in all four mitochondrial genes tested and has suggested its informational, and probably ribosomal, character. The NAM9 gene was cloned by transformation of the recipient oxi1-V25 mutant to respiration competence by using a gene bank from the NAM9-1 rho o strain. Orthogonal-field alternation gel electrophoresis analysis and genetic mapping localized the NAM9 gene on the right arm of chromosome XIV. Sequence analysis of the NAM9 gene showed that it encodes a basic protein of 485 amino acids with a presequence that could target the protein to the mitochondrial matrix. The N-terminal sequence of 200 amino acids of the deduced NAM9 product strongly resembles the S4 ribosomal proteins from chloroplasts and bacteria. Significant although less extensive similarity was found with ribosomal cytoplasmic proteins from lower eucaryotes, including S. cerevisiae. Chromosomal inactivation of the NAM9+ gene is not lethal to the cell but leads to respiration deficiency and loss of mitochondrial DNA integrity. We conclude that the NAM9 gene product is a mitochondrial ribosomal counterpart of S4 ribosomal proteins found in other systems and that the suppressor acts through decreasing the fidelity of translation.

Purification and characterization of the DNA cleavage and recognition site of I-ScaI mitochondrial group I intron encoded endonuclease produced in Escherichia coli.

The second intron in the mitochondrial cytb gene of Saccharomyces capensis, belonging to group I, encodes a 280 amino acid protein containing two LAGLIDADG motifs. Genetic and molecular studies have previously shown that this protein has a dual function in the wild-type strain. It acts as a specific homing endonuclease I- Sca I promoting intron mobility and as a maturase promoting intron splicing. Here we describe the synthesis of a universal code equivalent to the mitochondrial sequence coding for this protein and the in vitro characterization of I- Sca I endonuclease activity, using a truncated mutant form of the protein p28bi2 produced in Escherichia coli. We have also determined the cleavage pattern as well as the recognition site of p28bi2. It was found that p28bi2 generates a double-strand cleavage downstream from the intron insertion site with 4 nt long 3'-overhangs. Mutational analysis of the DNA target site shows that p28bi2 recognizes a 16-19 bp sequence from positions -11 to +8 with respect to the intron insertion site.

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.

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.

Two homologous introns from related Saccharomyces species differ in their mobility.

We have studied gene conversion initiated by the ai3 intron of the Saccharomyces cerevisiae mitochondrial (mt) COXI gene and its homologous intron (S.cap.ai1) from Saccharomyces capensis. The approach used involved the measurement of intron transmission amongst the progeny of crosses between constructed recipient and donor strains. We found that the S. cerevisiae ai3 intron is extremely active as a donor in gene conversion, whereas its homologous S. capensis intron is not. We have established the sequence of S.cap.ai1 and compared its open reading frame (ORF) with that of I-SceIII encoded by the homologous S. cerevisiae intron. The two protein-coding intron sequences are almost identical, except that the S. capensis ORF contains an in-frame stop codon. This finding provides a strong indication that the 3' part of the S. cerevisiae intron ORF encoding I-SceIII (which should not be translated in the S. capensis intron) must be critical for function of mtDNA endonucleases to mediate intron mobility.

Sequence of the mitochondrial gene encoding subunit I of cytochrome oxidase in Saccharomyces douglasii.

We have determined the complete sequence of the mitochondrial (mt) gene (COXI) coding for cytochrome oxidase subunit I of Saccharomyces douglasii. This gene is 7238 bp long and includes four introns. The salient feature of the S. douglasii COXI gene is the presence of two introns, Sd.ai1 and Sd.ai2, which have not been observed in S. cerevisiae genes. Both are group-I introns and are located at novel positions compared with the S. cerevisiae COXI. Interestingly, one of these introns (the second one) is inserted at the same position as intron 2 of COXI of Kluyveromyces lactis and also as intron 8 of the same gene in Podospora anserina. The ORFs contained in these three introns display a high degree of similarity. Comparisons of exonic and intronic sequences of the COXI of two Saccharomyces species reinforces our previous conclusions: the evolution of mt genes in yeast obeys different rules to those found in vertebrates.

The C-terminal domain of yeast cytochrome b is essential for a correct assembly of the mitochondrial cytochrome bc1 complex.

Yeast mutants modifying the C-terminal region of mitochondrial cytochrome b were isolated and characterized. A nonsense mutation of the leucine codon 335 (TTA-->TAA), 50 residues before the normal C-terminus, blocks incorporation of heme into the apocytochrome b and prevents growth on non-fermentable substrates. The same defects were observed in a frameshift mutant (after codon 348, TAT-->TATT) in which the last 37 C-terminal residues are predicted to be replaced by a novel sequence of 33 amino acids. Function was regained in the nonsense mutant only by true back mutations restoring a protein of the wild-type sequence. The respiratory capacity was restored to wild-type levels in the frameshift mutant by a variety of single base subtractions located within a window of 24 bases before or after the original +T addition, these pseudo-reversions resulted in single or multiple (up to five) consecutive amino acid replacements between positions 346 and 354 and restored the wild-type sequence from position 355 to 385. These data, combined with hydropathy calculations and sequence comparisons, suggest that the C-terminal domain of cytochrome b forms a transmembrane segment essential for the correct assembly of the cytochrome bc1 complex.

A human putative Suv3-like RNA helicase is conserved between Rhodobacter and all eukaryotes.

We have cloned and sequenced a cDNA of the human homologue of the Saccharomyces cerevisiae Suv3 putative RNA helicase which is indispensable for mitochondrial function in yeast. The human Suv-3-like protein has a typical mitochondrial leader sequence. Northern blot data and analysis of ESTs in the data banks indicate that this human gene (SUPV3L1) is expressed in practically all tissues, though at different levels. Sequence homology analysis has shown a strong conservation of the protein in a number of eukaryotic organisms -- plants, mammals and fungi, but no close homologues exist in bacteria with the exception of the purple bacterium Rhodobacter sphaeroides. This gene is thus ubiquitously present in all eukaryotic organisms.

The MRS1 gene of S. douglasii: co-evolution of mitochondrial introns and specific splicing proteins encoded by nuclear genes.

We have developed a rapid and simple methodology to locate yeast genes within cloned inserts, obtain partial sequence information, and construct chromosomal disruptions of these genes. This methodology has been used to study a nuclear gene from the yeast S. douglasii (a close relative of S. cerevisiae), which is essential for the excision of the mitochondrial intron aI1 of S. douglasii (the first intron in the gene encoding subunit I of cytochrome oxidase), an intron which is not present in the mitochondrial genome of S. cerevisiae. We have shown that this gene is the homologue of the S. cerevisiae MRS1 gene, which is essential for the excision of the mitochondrial introns bI3 and aI5 beta of S. cerevisiae, but is unable to assure the excision of the intron aI1 from the coxI gene of S. douglasii. The two genes are very similar, with only 13% nucleotide substitutions in the coding region, transitions being 2.5 times more frequent than transvertions. At the protein level there are 86% identical residues and 7% conservative substitutions. The divergence of the MRS1 genes of S. cerevisiae and S. douglasii, and the concomitant changes in the structure of their mitochondrial genomes is an interesting example of the co-evolution of nuclear and mitochondrial genomes.

Electron microscopic analysis of the yeast mitochondrial DNA segment conferring chloramphenicol resistance.

Mitochondrial DNAs from six p- mutants carrying the genetic locus Rib1 and deleted for the rest of the genome were analyzed. Distribution of circular molecules from one mutant followed exactly the frequency rule, l/n, for multimers with discreet classes n, 2n, 3n, etc. Another, genetically unstable mutant displayed a continuous spectrum of circular molecules of various lengths. Four other mutants contained multiple series of circular molecules. Partial denaturation maps show that the mutants analyzed show a common segment ca. 1.0 micron long and differ by characteristic deletions of extremites of this segment. Short terminal deletions of the right i.e. pointing towards the Rib3 locus, terminus of this segment are correlated with modifications of the recombination properties related to the omega locus.

Intragenic suppressors that restore the splicing and homing activities of the protein encoded by the second intron of the Saccharomyces capensis cyt b gene.

The second (bi2) intron of the mitochondrial cyt b gene from Saccharomyces capensis encodes a bifunctional protein which acts both as a maturase, promoting intron splicing, and as a homing-endonuclease, I-ScaI, promoting intron mobility. In this work we isolated and characterized revertants from a respiratory-deficient mutant in which both functions of the protein have been lost. Intragenic revertants resulted mainly from monosubstitutions in the mutated codon and in one case from a distant second site mutation. All novel variants of the S. capensis bi2 intron-encoded protein are competent for the maturase activity but only two of them can partially complement the homing function.

Replacement of two non-adjacent amino acids in the S.cerevisiae bi2 intron-encoded RNA maturase is sufficient to gain a homing-endonuclease activity.

Two homologous group I introns, the second intron of the cyt b gene, from related Saccharomyces species differ in their mobility. The S.capensis intron is mobile and encodes the I-ScaI endonuclease promoting intron homing, whilst the homologous S.cerevisiae intron is not mobile, but functions as an RNA maturase promoting splicing. These two intron-encoded proteins differ by only four amino acid substitutions. Taking advantage of the remarkable similarity of the two intron open reading frames and using biolistic transformation of mitochondria, we show that the replacement of only two non-adjacent residues in the S.cerevisiae maturase carboxy-terminal sequence is sufficient to induce a homing-endonuclease activity without losing the splicing function. Also, we demonstrate that these two activities reside in the S.capensis bi2-encoded protein which functions in both splicing and intron mobility in the wild-type cells. These results provide new insight into our understanding of the activity and the evolution of group I intron-encoded proteins.

Critical base substitutions that affect the splicing and/or homing activities of the group I intron bi2 of yeast mitochondria.

The second intron (bi2) of the cyt b gene from related Saccharomyces species has an extraordinarily conserved sequence and can have different functions in wild-type cells. The protein encoded by the S. cerevisiae intron functions as a maturase to promote intron splicing, while the homologous S. capensis intron encodes a bifunctional protein that acts both as a maturase and as a homing endonuclease (I-ScaI) promoting intron mobility. The protein encoded by intron bi2 belongs to a large gene family characterized by the presence of two conserved LAGLIDADG motifs (P1 and P2). In this study, we analysed a set of splicing-deficient mutants of the S. cerevisiae intron bi2 that carry non-directed mutations affecting the maturase activity, and a set of directed missense mutations introduced into the bifunctional protein encoded by the S. capensis intron. Analysis of these mutations has allowed identification of the residues in the conserved P1 and P2 motifs which are crucial for splicing and homing activities. Moreover, several mutations which are located in the C-terminal part of the protein have been found to affect both functions.

Homing of a group II intron in yeast mitochondrial DNA is accompanied by unidirectional co-conversion of upstream-located markers.

Group II introns ai1 and ai2 of the Saccharomyces cerevisiae mitochondrial COXI gene encode proteins having a dual function (maturase and reverse transcriptase) and are mobile genetic elements. By construction of adequate donor genomes, we demonstrate that each of them is self-sufficient and practises homing in the absence of homing-type endonucleases encoded by either group I introns or the ENS2 gene. Each of the S. cerevisiae group II self-mobile introns was tested for its ability to invade mitochondrial DNA (mtDNA) from two related Saccharomyces species. Surprisingly, only ai2 was observed to integrate into both genomes. The non-mobility of ai1 was clearly correlated with some polymorphic changes occurring in sequences flanking its insertion sites in the recipient mtDNAs. Importantly, studies of the behaviour of these introns in interspecific crosses demonstrate that flanking marker co-conversion accompanying group II intron homing is unidirectional and efficient only in the 3' to 5' direction towards the upstream exon. Thus, the polar co-conversion and dependence of the splicing proficiency of the intron reported previously by us are hallmarks of group II intron homing, which significantly distinguish it from the strictly DNA-based group I intron homing and strictly RNA-based group II intron transposition.

Electron microscopy of analysis of circular repetitive mitochondrial DNA molecules from genetically characterized rho- mutants of Saccharomyces cerevisiae.

1. We have studied mtDNA purified from nine p- petite mutants in which most of the wild type sequence has been deleted but the genetic markers conferring resistance to erythromycin of oligomycin or paromomycin have been retained. 2. All mtDNA contained numerous circular molecules. The size distribution of the circles conformed to a multimeric series which was characteristic for each mutant. We conclude that any one region of the wild type mtDNA molecule, when maintained in a p- clone, while other regions are deleted, can give rise to a multimeric series of circles. 3. In tandem straight repetitive mtDNAs the circles contain odd and even number of unit sequence repeats. In palindrome repetitive mtDNAs the circles contain mostly even number of unit sequence repeats. Thus, one straight or two inverted repeats constitute the monomeric unit of circularization. 4. We found that the frequency distribution of circles follows on a number basis a simple rule: frequency of numeric circles = 1/n frequency of monomeric circles, for n = 2, 3 and 4. Thus, on a mass basis each class represents the same fraction of total mtDNA and the mitochondrial genome has the same probability to constitute one monomeric circle or to be a part of n-meric circle. We interpret this finding that in vivo all molecules are circular. 5. Four mutants displayed a single multimeric series of circles ranging from 0.3 mum to 2.4 mum monomer circle length. Five mutants displayed multiple different multimeric series. In the latter case, the longest unit sequence repeat length was equal to the sum of the two shorter unit sequence repeat lengths. Sorting out, recombination and internal deletions of circular repetitive p- mtDNA molecules are discussed.

Sequence of introns and flanking exons in wild-type and box3 mutants of cytochrome b reveals an interlaced splicing protein coded by an intron.

We have determined the DNA sequence of the wild type and mutated introns as well as their flanking exons in the yeast mitochondrial gene specifying cytochrome b. The second intron (box3) encodes a trans-acting protein "mRNA maturase" responsible for splicing and maturation of cytochrome b mRNA. This protein is interlaced with cytochrome b exon sequences. Its biosynthesis is subject to a negative feedback which may constitute a regulatory mechanism for the expression of split genes.

[New mechanism for regulation of genetic expression]. / Sur un nouveau mécanisme de la régulation de l'expression génétique.

DNA sequence studies of mutated and wild type alleles of an intron in the mosaic mitochondrial gene for cytochrome b have revealed the possible existence of a protein coded in the intron and involved in RNA splicing. This protein would be endowed with properties of intrinsic autotomy of its own messenger RNA.