Sensitivity to ethidium bromide during meiosis in Saccharomyces cerevisiae

Summary Ethidium bromide was found to inhibit nuclear and mitochondrial DNA synthesis during meiosis which resulted in the inhibition of meiotic gene conversion and sporulation and was also lethal. Protection from the effects of ethidium bromide on meiotic gene conversion and survival was found to coincide with DNA synthesis, but it is possible that protection from sporulation inhibition occurs only later in meiosis.     

Amphimeric mitochondrial genomes of petite mutants of yeast. I. Flip-flop amphimers make up the mitochondrial genomes of ``palindromic' petite mutants of yeast

 The mitochondrial (mt) genomes of three spontaneous cytoplasmic ``palindromic' petite mutants of yeast were studied by restriction-enzyme analysis. These mt genomes were shown to be made up of an amplified ``master basic unit' consisting of two inverted segments (a and A) and of two different unique segments (d and t) separating them. The basic unit was called ``amphimeric', this term having been first proposed for certain lambda-phage mutants. We propose that in the mt genomes of the petite mutants studied, the four possible variants of the amphimeric basic unit form two – ``flip' and ``flop' – tetra-amphimeric repeat units datA-datA-DaTA-DaTA and DatA-DatA-daTA-daTA, respectively. These repeat units make two types of ``amphimeric' mt genomes which exist in equal proportions in the cell. In each mt genome, the duplicated segment regularly alternates in its direct and inverted orientation (a…A…a…A…), whereas the unique segments are arranged twice in tandem fashion and twice in inverted fashion (d…d…D…D…d…d… and t…t…T…T…t…t….). The only difference between flip and flop amphimeric mt petite genomes is the different relative orientation of the unique segments in the mono-amphimers. In the mono-amphimers of flip mt genomes, both unique segments are arranged in the same direction (d…t and D…T), whereas in the mono-amphimers of flop mt genomes, both unique segments are arranged in opposite directions (D…t and d…T). Control experiments on one spontaneous petite mutant (which was an ancestor of the mutants studied here) and on three independent, previously investigated, EtBr-induced mutants showed that all of them were, in fact, organized in the same way. Analysing our experimental data and the results published by others, we conclude that amphimeric organization is a general feature of mt petite genomes of yeast previously called ``palindromic' or ``rearranged'. Received: 2 November 1995     

Recombination of yeast mitochondrial DNA does not require mitochondrial protein synthesis

Summary Mitochondrial genes recombine extensively in yeast zygotes. In heteropolar crosses (⁺ × ^–) in which the ^– allele consists of an insertion, there is preferential recovery of ⁺ and markers closely linked to it. This polarity has been postulated to be a consequence of one-way gene conversion beginning at the locus (- to ⁺). We have shown that most or all mitochondrial recombination in homopolar and heteropolar crosses, and the phenomenon of polarity itself, does not require products of protein synthesis on mitochondrial ribosomes. (i) Yeast strains were grown and mated, and the zygotes plated and grown, on glucose medium with erythromycin to inhibit and dilute out the products of mitochondrial protein synthesis. Recombination frequencies and polarity at the cap1 and oli1 loci were normal compared to controls in some homopolar (⁺ × ^–) and heteropolar crosses. Apparent changes in recombination frequencies and polarity were seen in other crosses but are attributable to locus-specific petite induction by erythromycin. (ii) Homopolar (⁺ × ⁺) and heteropolar crosses between pairs of petite mutants retaining the cap1, ery1, and oli1 loci also showed nearly normal recombination at the cap1 and oli1 loci, as determined by test-crossing the petite progeny. The petite mutants and zygotes cannot do mitochondria) protein synthesis. These results support the recombinational model of polarity.     

Partial pedigree analysis of the segregation of yeast mitochondrial genes during vegetative reproduction

Summary A three-factor cross of Saccharomyces cerevisiae involving the cap1, ery1, and oli1 loci was done, with partial pedigree analyses of 117 zygotes. First, second, and third buds were removed and the genotypes of their diploid progeny determined, along with those of the residual zygote mother cell. Results were analyzed in terms of frequencies of individual alleles and of recombinant genotypes in the dividing cells. There is a gradual increase in the frequency of homoplasmic cells and in gene frequency variance during these three generations, as would result from stochastic partitioning of mtDNA molecules between mother and bud, probably coupled with random drift of gene frequencies in interphase cells. These phenomena are more pronounced for buds than for mothers, suggesting that buds receive a smaller sample of molecules. End buds are more likely to be homoplasmic and have a lower frequency of recombinant genotypes than do central buds; an end bud is particularly enriched in alleles contributed by the parent that formed that end of the zygote. Zygotes with first central buds produce clones with a higher recombination frequency than do those with first end buds. These results confirm previous studies and suggest that mixing of parental genotypes occurs first in the center of the zygote. If segregation were strictly random, the number of segregating units would have to be much smaller than the number of mtDNA molecules in the zygote. On the other hand, there is no evidence for a region of the molecule (attachment point) which segregates deterministically.     

A mitochondrial frameshift suppressor maps in the tRNASer-var1 region of the mitochondrial genome of the yeast S. cerevisiae

Summary A polypeptide chain-terminating mutation (M5631) previously has been shown to be a +1T insertion in the yeast mitochondrial gene oxi1, coding for subunit II of the cytochrome c oxidase. A spontaneously arisen frameshift suppressor (mfs-1) that is mitochondrially inherited suppresses this mutation to a considerable extent. The suppressor mutation was mapped by genetic and molecular analyses in the mitochondrial tRNA^Ser-var1 region of the mitochondrial genome of the yeast S. cerevisiae. Genetic analyses show that the suppressor mfs-1 does not suppress other known mitochondrial frameshift mutations, or missense and nonsense mutations.     

Second-site antibiotic resistance mutations in the ribosomal region of yeast mitochondrial DNA

Summary A large proportion of the spontaneous erythromycin resistant mutants isolated from a strain carrying a previously-induced chloramphenicol resistance mutation at cap3 do not map at ery1, the locus most often associated with mitochondrial erythromycin resistance. Most of the new mutations are also nonallelic at spil, spi2, and other known antibiotic resistance loci within the 21S rRNA gene; they are allelic with each other and define the new locus, ery2. Induced second-site erythromycin resistant mutants from the cap ^r3 strain, as well as spontaneous or induced mutants from strains carrying a cap ^r 1 mutation, all tend to map at eryl. The cap ^r3 mutation is apparently necessary for the expression of erythromycin resistance resulting from a second mutation at ery2.     

Assembly of the mitochondrial membrane system. Organization of yeast mitochondrial DNA in the Oli1 region

Summary The mitochondrial DNA (mtDNA) of a cytoplasmic petite mutant (DS401) of Saccharomyces cerevisiae genetically marked for the ATPase proteolipid, serine tRNA and varl genes has been characterized by restriction endonuclease analysis and DNA sequencing. The DS401 mtDNA segment is 5.3 kb long spanning the region between 79.1 and 86.8 units of the wild type genome. Most of the DS401 mtDNA consists of A+T rich sequences. In addition, however, there are ten short sequences with a high content of G+C and two sequences that have been identified as the ATPase proteolipid and the serine tRNA genes. The two genes map at 81 and 83 units and are transcribed from the same DNA strand. Even though there are other possible coding sequences in the DNA segment, none are sufficiently long to code for a gene product of the size of the varl protein. Based on the relative organization of the G+C rich clusters and genes, a model has been proposed for the processing of mitochondria) RNA. This model postulates the existence of mitochondrial double strand specific RNases that cleave the RNA at the G+C clusters.     

A mitochondrial frameshift-suppressor (+) of the yeast S. cerevisiae maps in the mitochondrial 15S rRNA locus

Summary The first case of a +1 extrageneic frameshift suppressor (MF1), mapping in the yeast mitochondrial 15S rRNA gene is reported. The suppressor was identified by genetic analyses in a leaky mitochondrial oxi1 frameshift mutant and the respective wild-type strain 777-3A of the yeast S. cerevisiae. This is in accordance with the finding that all mitochondrial frameshift mutants isolated from this strain tend to be leaky to a variable degree. MF1 does not suppress known nonsense mutations created by a direct basepair exchange in strain 777-3A. These mutants exhibit a non-leaky phenotype (Weiss-Brummer et al. 1984).     

Mechanisms of mitochondrial DNA escape to the nucleus in the yeast Saccharomyces cerevisiae

The transfer of organelle nucleic acid to the nucleus has been observed in both plants and animals. Using a unique assay to monitor mitochondrial DNA escape to the nucleus in the yeast Saccharomyces cerevisiae, we previously showed that mutations in several nuclear genes, collectively called yme mutants, cause a high rate of mitochondrial DNA escape to the nucleus. Here we demonstrate that mtDNA escape occurs via an intracellular mechanism that is dependent on the composition of the growth medium and the genetic state of the mitochondrial genome, and is independent of an RNA intermediate. Isolation of several unique second-site suppressors of the high rate of mitochondrial DNA-escape phenotype of yme mutants suggests that there are multiple independent pathways by which this nucleic acid transfer occurs. We also demonstrate that the presence of centromeric plasmids in the nucleus can reduce the perceived rate of DNA escape from the mitochondria. We propose that mitochondrial DNA-escape events are manifested as unstable nuclear plasmids that can interact with centromeric plasmids resulting in a decrease in the number of observed events. Received: 21 April / 7 June 1999     

ARS activity along the yeast mitochondrial apocytochrome b region: correlation with the location of petite genomes and consensus sequences

Summary Seven MboI fragments spanning the mitochondrial apocytochrome b gene in Saccharomyces cerevisiae strain D273-10B were cloned in the BamHI site of the integrative yeast vector YIp5 and the capacity for autonomous replication was subsequently assayed in yeast. The positive correlation found between the ars-like activity in four fragments and the presence of regions common to multiple ethidium bromide-induced petite (rho^–) genomes suggests that the mitochondrial sequences possibly active as origins of replication in low-complexity neutral or weakly suppressive rho^– mutants could be functionally related to the yeast nuclear replicator 11 nucleotide motif defined by Broach et al. (1983).Abbreviations mtDNA mitochondrial DNA - bp base pairs - kbp kilobase pairs     

Distribution of mitochondrial intron sequences among 21 yeast species

Summary The mitochondrial and nuclear genomes of 21 yeast species belonging to 12 genera have been tested for the presence of sequences similar to seven S. cerevisiae mitochondrial introns (Sc cox1.1,2,3,4,5c, Sc cob.4 and Sc LSU.1) and one K. lactis mitochondrial intron (Kl cox1.2). Some introns, (Sc cox1.4, Sc cob.4, Sc LSU.1 and Kl cox1.2-all group I type), are widely distributed and are found in species with either basidiomycete or ascomycete affinities. This distribution is suggestive of recent sequence transfer between species. The remaining S. cerevisiae introns cross react with an additional species but with no set pattern. Pulsed field gel electrophoretic studies confirm that none of the tested mitochondrial introns cross react with nuclear DNA. These introns are, therefore, mitochondria-specific. Seven strains of K. lactis exhibit striking variability in intron content. In contrast to all mitochondrial introns tested, two introns of nuclear genes (the K. lactis actin gene and the S. cerevisiae RP29B gene) are not detected beyond their source species.     

Isolation of a nuclear yeast gene involved in the mitochondrial import of cytoplasmically synthesized precursor proteins

Summary Several nuclear mutants of the yeast, Saccharomyces cerevisiae, have been characterized which synthesize only the higher-molecular weight precursor but not the mature subunit VI of the mitochondrial ubiquinol cytochrome c oxidoreductase. The mutants belong to different complementation groups and vary in the extent of their being simultaneously deficient in other components of the mitochondrial inner membrane. From a yeast genomic DNA library the plasmid pTS2326 was isolated which complements the defect in one of these mutants, ts2326. The cloned DNA fragment, 2.3 kilobases in length, was sequenced. It contains two open reading frames, ORF1 and ORF2, consisting of 723 and 417 base pairs, respectively. By selective deletion of either reading frame it was shown that only ORF1 containes the information necessary to complement the ts2326 mutation. The ORF1 coding sequence is not the structural gene of subunit VI. The postulated gene product of ORF1 has a molecular weight of 27.114 daltons. It exhibits several sequence characteristics typical of proteins which are internalized by the mitochondrial membrane systems. It is proposed that ORF1 is involved in the import and processing of cytoplasmically synthesized mitochondrial precursors.Abbreviations ts temperature-sensitive - YEP yeast extract/peptone/sucrose media - ORF open reading frame - bc ₁-complex ubiquinol cytochrome c oxidoreductase Dedicated to Prof. Dr. Fritz Kaudewitz on the occasion of his 65th birthday     

At least two nuclear-encoded factors are involved together with a mitochondrial factor (MR1) in spontaneous mitochondrial frameshift-suppression of the yeast S. cerevisiae

Summary Earlier genetic analyses have identified a mitochondrial +1 frameshift suppressor (MF1) in the 15S rRNA region of a leaky mitochondrial frameshift mutant and the respective wild-type strain 777-3A (Weiss-Brummer et al. 1987). Further genetic analyses revealed that for the observed spontaneous frameshift suppression in M5631 the mitochondrial factor (MF1) must act together with at least two dominant nuclear-encoded factors.     

Nuclear suppressors of mitochondrial chloramphenicol resistance in Baker's yeast: their use for the isolation of novel mutants

Summary Strains that are genotypically sensitive to chloramphenicol and also contain one of the nuclear suppressors of mitochondrial chloramphenicol resistance (Waxman et al. 1979) were constructed. A manganese mutagenesis on such a strain produced chloramphenicol resistant mutants, most of which resulted from mutations in nuclear genes. These mutants may be either dominant or recessive, and they probably do not code for membrane proteins. The few mitochondrial mutants fall into several classes, but all result from mutations in the 21S rRNA gene. The suppressor allele effectively prevents the appearance of the most common group of mitochondrial mutants (those that map at cap1), and thereby enhances the selection of novel mutants in the region.     

Pheromone-induced meiosis in P-specific mutants of fission yeast

Summary Diploid strains of Schizosaccharomyces pombe defective in P-specific pheromone production and response provided cytological evidence that the induction of meiosis as such (and not only conjugation) depends upon an initial stimulation by sexual pheromones.     

Comparative analysis of the mitochondrial genomes of Chlamydomonas eugametos and Chlamydomonas moewusii

Summary We report the cloning and physical mapping of the mitochondrial genome of Chlamydomonas eugametos together with a comparison of the overall sequence structure of this DNA with the mitochondrial genome of Chlamydomonas moewusii, its closely related and interfertile relative. The C. eugametos mitochondrial DNA (mtDNA) has a 24 kb circular map and is thus 2 kb larger than the 22 kb circular mitochondrial genome of C. moewusii. Restriction mapping and heterologous fragment hybridization experiments indicate that the C. eugametos and C. moewusii mtDNAs are colinear. Nine cross-hybridizing restriction fragments common to the C. eugametos and C. moewusii mtDNAs, and spanning the entirety of these genomes, show length differences between homologous fragments which vary from 0.1 to 2.3 kb. A 600 bp subfragment of C. moewusii mtDNA, within one of these conserved fragments, showed no hybridization with the C. eugametos mtDNA. Of the 73 restriction sites identified in the C. eugametos and C. moewusii mtDNAs, five are specific to C. moewusii, eight are specific to C. eugametos and 30 are common to both species. Hybridization experiments with gene probes derived from protein-coding and ribosomal RNA-coding regions of wheat and Chlamydomonas reinhardtii mtDNAs support the view that the small and large subunit ribosomal RNA-coding regions of the C. eugametos and C. moewusii mtDNAs are interrupted and interspersed with each other and with protein-coding regions, as are the ribosomal RNA-coding regions of C. reinhardtii mtDNA; however, the specific arrangement of these coding elements in the C. eugametos and C. moewusii mtDNAs appears different from that of C. reinhardtii mtDNA.     

The Iml3 protein of the budding yeast is required for the prevention of precocious sister chromatid separation in meiosis I and for sister chromatid disjunction in meiosis II

The mitotic kinetochore of the budding yeast contains a number of proteins which are required for chromosome transmission but are non-essential for vegetative growth. We show that one such protein, Iml3, is essential for meiosis, in that the absence of this protein results in reduced spore viability, precocious sister chromatid segregation of artificial and natural chromosomes in meiosis I and chromosome non-disjunction in meiosis II.