Physical and genetic organization of petite and grande yeast mitochondrial DNA.I. Studies by RNA-DNA hybridization

Mitochondrial and nuclear mutations that affect the biogenesis of the mitochondrial ribosomes of yeast. I. Genetics

We have isolated about five hundred temperature-sensitive mutants specific for the mitochondrial functions. Their growth on glycerol is defective at 36 degrees C and/or 20 degrees C. While most of the mutations were nuclearly inherited, about thirty were found to be of mitochondrial origin. 1) Four mitochondrial mutations (three cryosensitive, one thermosensitive) were localized close to chloramphenicol and erythromycin resistance loci of the mitochondrial DNA, that is in the region coding for the 23 S ribosomal RNA. One of the mutation interfered with the expression of the chloramphenicol resistance gene. 2) A dozen nuclear mutations were isolated from a strain which is labelled with mitochondrial drug resistance markers (chloramphenicol, erythromycin, and paromomycin). Among the temperature sensitive respiratory deficient mutants, we have selected the mutations that supress the resistant phenotypes. We describe two non allelic such mutations, one being cryosensitive, the other thermosensitive. Both supress the expression of the mitochondrial chloramphenicol resistance gene. The temperature sensitive growth on glycerol and the modified antibiotic phenotype segregated together as a single recessive mutation. A biochemical study of these mutants is presented in a joint paper, confirming their presumed ribosomal nature.

Mitochondrial and nuclear mutations that affect the biogenesis of the mitochondrial ribosomes of yeast. II. Biochemistry

1. Several nuclear mutants have been isolated which showed thermo- or cryo-sensitive growth on non-fermentable media. Although the original strain carried mitochondrial drug resistance mutations (CR, ER, OR and PR), the resistance to one or several drugs was suppressed in these mutants. Two of them showed a much reduced amount of the mitochondrial small ribosomal subunit (37S) and of the corresponding 16S ribosomal RNA. Two dimensional electrophoretic analysis did not reveal any change in the position of any of the mitochondrial ribosomal proteins. However one of the mitochondrial ribosomal proteins. However one of the mutants showed a striking decrease in the amounts of three ribosomal proteins S3, S4 and S15. 2. Four temperature-sensitive mitochondrial mutations have been localized in the region of the gene coding for the large mitochondrial ribosomal RNA (23S). These mutants all showed a marked anomaly in the mitochondrial large ribosomal subunit (50S) and/or the corresponding 23S ribosomal RNA.

The genetic map of transfer RNA genes of yeast mitochondria: correction and extension

Ninety five rho- mitochondrial DNA's of Saccharomyces cerevisiae were compared for their deletion structure by means of 15 genetic markers and 22 tRNA genes. The patterns of co-deletion and co-retention of different tRNA genes allowed us to determine their positions with respect to each other. The deduced order of tRNA genes was consistent with the order of the genetic markers established by independent genetic approaches. Our previously proposed mitochondrial tRNA gene map has been revised and extended. Transfer RNA genes, corresponding to all 20 aminoacids, and two isoacceptor tRNA genes were localized. The possible position of each tRNA gene has been indicated on the physical map of mitochondrial DNA. Seventeen tRNA genes are carried by a narrow region representing less than 20% of the wild type genome.

Inserted sequence in the mitochondrial 23S ribosomal RNA gene of the yeast Saccharomyces cerevisiae

The sequence organization of the yeast mit-DNA region carrying the large ribosomal RNA gene and the polar locus omega was examined. Hybridization studies using rho- deletion mutants and electron microscopy of the heteroduplexes formed between 23S rRNA and the appropriate restriction fragments, lead to the conclusion that the 23S rRNA1 gene of the omega+ strains is split by an insertion sequence of 1,000-1,100 bp. In contrast, no detactable insertion was found in the 23S rRNA gene of the omega- strains. The size and the location of the insert found in the 23S rRNA gene of the omega+ strains appear to be identical to those of the sequence delta which had previously been found to characterize the difference (at the omega locus) between the mitDNA of the wild type strains carrying the omega+ or omega- alleles (Jacq et al., 1977).

Temperature-sensitive respiratory-deficient mitochondrial mutations: isolation and genetic mapping

In order to find new genetic loci and functions on the yeast mitochondrial DNA, especially mutations affecting the mitochondrial protein synthesis apparatus, temperature sensitive mutants have been isolated after MnCl2 mutagenesis and mitochondrial and nuclear mutants classified according to their pattern of recombination with three rho- tester strains. Eighteen cold- and heat-sensitive respiratory deficient mitochondrial mutants have been isolated and localized on the mitochondrial genome by deletion mapping using 113 rho- strains. Eight of them appear to represent new loci, among which some are probably mutations of the tRNA and rRNA genes.

Recombined molecules of mitochondrial DNA obtained from crosses between cytoplasmic petite mutants of Saccharomyces cerevisiae: the stoichiometry of parental DNA repeats within the recombined molecule

We have studied recombination between repetitive mitochondrial DNAs from cytoplasmic petite mutants of Saccharomyces cerevisiae. Mitochondrial DNA was isolated from two parental p- mutants, carrying respectively the CR and the ER mitochondrial genetic markers, and from two p- CRER diploid genetic recombinants. These two recombinants, obtained from the same parental petites, differ in their degrees of suppressiveness. The p- mitochondrial DNAs were analyzed by DNA-DNA hybridization, high resolution melting and reassociation kinetics. It was found that the repeating unit of the CR parental p- DNA is 3 to 4 times longer than that of the ER parent. There is very little sequence homology between these two p- mitochondrial DNAs and almost all parental sequences are integrated into the recombined molecules. Mitochondrial DNA from both types of recombinants seems to contain the two parental repeating units in the ratio 1:1.

Modified recombination and transmission of mitochondrial genetic markers in rho minus mutants of Saccharomyces cerevisiae

A large number of primary petite (rho-) clones were isolated after ethidium bromide mutagenesis of various grande (rho+) strains of S. cerevisiae that contained the mitochondrial genetic markers, CR, ER, OIR (or OIIR), and PR. From the frequency of coretention of markers in the petites, we have deduced a probable circular order of the markers in the grande mitochondrial genome. From these primary clones several series of pure and stable petite clones were obtained and analyzed genetically. (a) In general, the omega allele is retained or lost together with the region carrying both CR and ER markers. (b) The petites that have retained only the CR marker fall into two classes: some have kept the omega allele of the grande strain they issued from; others exhibit a new omega expression. (c) The proportion of diploid petites in petite X grande crosses is independent of the presence of the omega allele. (d) In most cases, the coordinated transmission of markers observed so far in all grande X grande nonpolar corsses does not exist anymore in petites.

Mapping of mitochondrial genes in Saccharomyces cerevisiae. Populations and pedigree analysis of retention or loss of four genetic markers in Rho-cells

1. Retention or loss of mitochondrial markers CR321, OR1, PR454, TR (gene loci RIB1, OLI1, PAR1, TSM1 respectively has been analysed in a large number of ethidium bromide induced primary rho-clones. Retention of one or more of the four markers with a single clone was observed frequently, only 20 to 25% of clones were found to be (TOCOOOPO). Primary clones retaining two or more of the four markers were found to be mixed, i.e. the primary rho- cell contained a heterogeneous population of variously deleted mitDNA molecules which segregated into different cell lines in the corresponding primary clone. 2. A representative sample of the population of ethidium bromide induced rho- mutants has been analysed by a first subcloning performed after some 30 cell generations of vegetative multiplication in the abscence of the drug. At this level the heterogeneous population of mitDNA molecules, generated by the mutagenic treatment in the primary cell, has been sorted out. The cells forming secondary clones are thus essentially homoplasmic. In contrast to primary clones, genotypes of secondary clones therefore could be determined unambiguously, and the frequency of cell types can be regarded as a faithful representation of the frequency of mitDNA molecules. Retention of markers was low, in less than 2% of secondary clones one or several markers have been found. This observation has been interpreted as indicating that induction of rho-mutants by ethidium bromide is accompanied by deletion of very large sequences of mitDNA in a very large fraction of mitDNA molecules. 3. Five individual rho-clones retaining the four markers TRCRORPR have been isolated and analysed for spontaneous deletion of one or several of these markers during successive subclonings (pedigree analysis). High genetic stability (98-99.5% per cell generation) has been observed in these clones. 4. A method has been developed allowing an unambiguous determination of the order of the four markers on a circular map. It is based on the concomitant loss of two markers and retention of the other two markers (double loss/double retention analysis). The results of four out of five pedigrees of individual rho-clones analysed (spontaneous deletion) and the results of the analysis of populations of secondary rho-clones (ethidium bromide induced deletion) were in full agreement and the order of genes has been determined as being P-T-C-O-P. In the fifth pedigree results suggest an inversion of the T and C markers. 5. Relative distances between pairs of markers have been derived from the frequencies of separation of markers by deletion and were found to be C-T less than C-O less than T-O less than T-P less than C-P less than O-P. Linkage of the four markers could be established, and distances calculated are additive. 6. The general relevance of this approach of mapping by deletion and the methods used for the determination of order and distances of mitochondrial genes has been discussed. (ABSTRACT TRUNCATED)

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.

Nuclear origin of specific yeast mitochondrial aminoacyl-tRNA synthetases

Hydroxylapatite chromatographies of mitochondrial and total enzymes from a rho+ yeast, or from the related rho degrees mitochondrial DNA-less mutant, show the occurrence in the mitochondrial enzyme of one Phe-, one Met-, one Leu-tRNA synthetase peak which elutes distinctly from the cytoplasmic counterpart and charges well mitochondrial tRNA, whereas the cytoplasmic enzyme does not. The measurement of the mitochondrial synthetases activities in various enzymatic extracts shows that they are not repressed in rho+ cells grown on 10% glucose and that they are concentrated in the mitochondria (Phe- and Met- tRNA synthetases) but are also present outside the mitochondria. It is concluded that yeast mitochondrial protein biosynthesis involves the nuclear coded mitochondrial specific Phe-, Met- and Leu-tRNA synthetases and that the entrance of the synthetases into the mitochondria needs no factor depending on the mitochondrial DNA.

Deletion mapping of mitochondrial transfer RNA genes in Saccharomyces cerevisiae by means of cytoplasmic petite mutants

Mitochondrial transfer RNA genes have been ordered relative to the position of five mitochondrial drug resistance markers, namely, chloramphenicol (C),1 erythromycin (E), oligomycin I and II (OI, OII), and paromomycin (P). Forty-six petite yeast clones that were genetically characterized with respect to these markers were used for a study of these relationships. Different regions of the mitochondrial genome are deleted in these individual mutants, resulting in variable loss of genetic markers. Mitochondrial DNA was isolated from each mutant strain and hybridized with eleven individual mitochondrial transfer RNAs. The following results were obtained: i) Of the seven petite clones that retained C, E, and P resistance markers (but not O1 or O11), four carried all eleven transfer RNA genes examined; the other three clones lost several transfer RNA genes, probably by secondary internal deletion; ii) Prolyl and valyl transfer RNA genes were located close to the P marker, whereas the histidyl transfer RNA gene was close to the C marker; iii) Except for a glutamyl transfer RNA gene that was loosely associated with the O1 region, no other transfer RNA genes were found in petite clones retaining only the O1 and/or the OII markers; and iv) Two distinct mitochondrial genes were found for glutamyl transfer RNA, they were not homologous in DNA sequence and were located at two separate loci. The data indicate that the petite mitochondrial genome is the result of a primary deletion followed by successive additional deletions. Thus an unequivocal gene arrangement cannot be readily established by deletion mapping with petite mutants alone. Nevertheless, we have derived a tentative circular map of the yeast mitochondrial genome from the data; the map indicates that all but one of the transfer RNA genes are found between the C and P markers without forming a tight cluster. The following arrangement is suggested: -P-pro-val-ile-(phe, ala, tyr, asp)-glu2- (lys-leu)-his-C-E-O1-glu1-OII-P-.

Genetic analysis of mitochondrial biogenesis and function in Saccharomyces cerevisiae

Different mitochondrial mutants have been isolated that affect mitochondrial ribosome function. These mutants were used to establish most of the known methods and principles of mitochondrial genetics in yeast. Another class of mitochondrial mutants have been shown to affect mitochondrial ATPase and, more specifically, the "membrane factor" of mitochondrial ATPase. These mutants might be very useful in studying the energy-conserving function, and the interaction between the hydrophobic and hydrophylic parts, of the ATPase complex. New types of mitochondrial point mutations, concerning cytochrome a-a3 or b, will soon open up new fields of investigation. The biochemical and genetic analysis of numerous mutants belonging to that category and recently obtained [31] is being currently pursued in Tzagoloff's and Slonimski's laboratories.

Localization in yeast mitochondrial DNA of mutations expressed in a deficiency of cytochrome oxidase and/or coenzyme QH2-cytochrome c reductase

1. Three methods are described for the genetic analysis of yeast cytoplasmic mutants (mit- mutants) lacking cytochrome oxidase or coenzyme QH2-cytochrome c reductase. The procedures permit mutations in mitochondrial DNA to be mapped relative to each other and with respect to drug-resistant markers. The first method is based upon the finding that crosses of mit- mutants with some but not other isonuclear q- mutants lead to the restoration of respiratory functions. Thus a segment of mitochondrial DNA corresponding to a given mit- mutation or to a set of mutations can be delineated. The second method is based on the appearance of wild-type progeny in mit- X mit- crosses. The third one is based on the analysis of various recombinant classes issued from crosses between mit-, drug-sensitive and mit+, drug-resistant mutants. Representative genetic markers of the RIBI, OLII, OLI2 and PAR1 loci were used for this purpose. 2. The three methods when applied to the study of 48 mit- mutants gave coherent results. At least three distinct regions on mitochondrial DNA in which mutations cause loss of functional cytochrome oxidase have been established. A fourth region represented by closely clustered mutants lacking coenzyme QH2-cytochrome c reductase and spectrally detectable cytochrome b has also been studied. 3. The three genetic regions of cytochrome oxidase and the cytochrome b region were localized by the third method on the circular map, in spans of mitochondrial DNA defined by the drug-resistant markers. The results obtained by this method were confirmed by analysis of the crosses between selected mit- mutants and a large number of q- clones whose retained segments of mitochondrial DNA contained various combinations of drug-resistant markers. 4. All the genetic data indicate that the various regions studied are dispersed on the mitochondrial genome and in some instances regions or clusters of closely linked mutations involved in the same respiratory function (cytochrome oxidase) are separated by other regions which code for entirely different functions such as ribosomal RNA.

Coding origin of isoaccepting tRNA in yeast mitochondria

Valyl-, leucyl- and tyrosyl-tRNA of yeast mitochondria were fractionated by reversed phase chromatography. Each of the tRNA contained multiple isofunctional species. Some of them specifically hybridized to mitochondrial DNA from (see article) strain. These species were absent in a petite colonie mutant lacking mitochondrial DNA. Three valyl-, one leucyl- and one tyrosyl tRNA were found to be products of mitochondrial genes.

Restriction endonuclease analysis of mitochondrial DNA from grande and genetically characterized cytoplasmic petite clones of Saccharomyces cerevisiae

Digestion of grande mitochondrial DNA (mtDNA) BY EcoRI restriction endonuclease gives rise to nine fragments with a total molecular weight of 51.8 x 10(6). HindIII digestion yields six fragments with a similar total molecular weight. Specific restriction fragments can be detected despite the fact that yeast mtDNA consists of a heterogeneous distribution of randomly broken molecules. Digestion patterns of 10 genetically characterized petite clones containing various combinations of five antiobiotic resistance markers indicate that the petite mtDNA predominantly represents deletion of the grande genome. The petite mtDNAs contained up to seven EcoRI restriction fragments which comigrate with grande restriction fragments, and at least one fragment that did not correspond to any in the grande. Some strains contained multiple fragments with mobility different from that of grande; these fragments were usually present in less than molar concentrations. The genetic markers were associated with individual sets of restriction fragments. However, several internal inconsistencies prevent the construction of a definitive genetic fragment map. These anomalies, together with the digestion patterns, provide strong evidence that, in addition to single contiguous deletion, other changes such as multiple deletion and heterogeneity of mtDNA populations are present in some of the petite mtDNAs.

Number of genes and base composition of mitochondrial tRNA from Saccharomyces cerevisiae

Increasing amounts of mitochondrial [32P] tRNA (4S fraction), were hybridized with mitochondrial DNA OF Saccharomyces cerevisiae. At saturation, the calculated number of genes for 4S mitochondrial RNA was 20. Mitochondrial [32P] tRNA eluted from the hydrids obtained either with an excess of tRNA or an excess of DNA showed, after alkaline hydrolysis and chromatography, a G+C content of 28 and 35 p. cent respectively. This last value is similar to that found with the total 4S fraction. The odd nucleotides T (about 1T per sequence), U, hU are present in mitochondrial tRNA. Some sequence may begin with pG.

Mitochondrial genetics. VII. Allelism and mapping studies of ribosomal mutants resistant to chloramphenicol, erythromycin and spiramycin in S. cerevisiae

We have isolated 15 spontaneous mutants resistant to one or several antibiotics like chloramphenicol, erythromycin and spiramycin. We have shown by several criteria that all of them result from mutations localized in the mitochondrial DNA. The mutations have been mapped by allelism tests and by two- and three-factor crosses involving various configurations of resistant and sensitive alleles associated in cis or in trans with the mitochondrial locus omega which governs the polarity of genetic recombination. A general mapping procedure based on results of heterosexual (omega(+)x omega(-)) crosses and applicable to mutations localized in the polar segment is described and shown to be more resolving than that based on results of homosexual crosses. Mutations fall into three loci which are all linked and map in the following order: omega-R(I)-R(II)-R(III). The first locus is very tightly linked with omega while the second is less linked to the first. Mutations of similar resistance phenotype can belong to different loci and different phenotypes to the same locus. Mutations confer antibiotic resistance on isolated mitochondrial ribosomes and delineate a ribosomal segment of the mitochondrial DNA. Homo- and hetero-sexual crosses between mutants of the ribosomal segment and those belonging to the genetically unlinked ATPase locus, O(I), have been performed in various allele configurations. The polarity of recombination between R(I), R(II), R(III) and O(I) decreases as a function of the distance of the R locus from the omega locus rather than as a function of the distance of the R locus from the O(I) locus.

Mitochondrial genetics in Bakers' yeast: a molecular mechanism for recombinational polarity and suppressiveness

Recombinational polarity and suppressiveness are two well-known but puzzling cytoplasmic genetic phenomena in bakers' yeast, Saccharomyces cerevisiae. Little progress has been made in characterizing the underlying molecular mechanisms of these phenomena. In this paper we describe a molecular model for recombinational polarity that is compatible with the available genetic evidence. The model stresses the role of small deletions and excision/repair processes in otherwise canonical recombinational events. According to the model, both phenomena require recombination and may share mechanistic elements.