Mapping of the two mitochondrial antimycin A resistance loci in Saccharomyces cerevisiae.

Summary Retention or loss of the two new mitochondrial antimycin A resistance loci A_I and A_II has been analyzed in a large number of stable cytoplasmic petite mutants. Using these deletion mutants it was possible to localize the two antimycin A resistance loci in the O_I-O_II region of mitochondrial DNA. The genetic loci are mapped in the following order: O_II-A_I-A_II-cobl-O_I. The mapping relationship of mutants resistant to antimycin A or funiculosin to various cob mutants is described.     

Allelism relationships between diuron-resistant, antimycin-resistant and funiculosin-resistant loci of the mitochondrial map in Saccharomyces cerevisiae.

Summary Using allelism tests, two diuron (DIU1, DIU2), one funiculosin (FUN1), and two antimycin (ANA1, ANA2) resistance loci are resolved into two mitochondrial drug-resistant genetic loci. DIU1 is allelic to ANA2 and FUN1. DIU2 is allelic to ANA1.Chercheur qualifié du Fonds National de la Recherche Scientifique     

Assembly of the mitochondrial membrane system. Genetic complementation of mit- mutations in mitochondrial DNA of Saccharomyces cerevisiae.

A method has been devised to test intergenic complementation of mutations in the mitochondrial DNA of Saccharomyces cerevisiae. The test is based on the observation that diploids issued from pairwise crosses of certain mit- mutants with deficiencies in cytochrome oxidase, or coenzyme QH2-cytochrome c reductase, acquire high levels of respiratory activity shortly after zygote formation. Under our experimental conditions neither biochemical complementation, interallelic complementation, nor recombination has been found to contribute to any significant extent toward the respiration measured in the diploids at early times. The test has been used to study the number of complementation groups represented by a large number of mit- mutants. Results of pairwise crosses of mutants in the oxi 1, oxi 2, oxi 3, cob 1, and cob 2 loci indicate that complementation occurs between the oxi and cob loci between different oxi loci but not between the two cob loci. The five loci have, therefore, been assigned to four different complementation groups.     

Kinetic and segregational analysis of mitochondrial DNA recombination in yeast

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

Isolation of Aneuploid-Generating Mutants of ASPERGILLUS NIDULANS, One of Which Is Defective in Interphase of the Cell Cycle

A method is described for isolating mutants potentially defective in loci involved in mitotic chromosome segregation. Conditional lethal, heat-sensitive (42°) mutants were assayed at a subrestrictive temperature of 37° for an inflated production of colonies displaying phenotypes and behavior patterns of whole chromosome aneuploids. Of 14 mutants, three showed specificity for one disomic phenotype, whereas 11 generated colonies mosaic for different aneuploid phenotypes. This latter group is designated hfa ( high frequency of aneuploid). For ten of the 11 mutants temperature sensitivity and aneuploid production cosegregated, indicating a single mutation in each. These mutations were recessive and nonallelic. Analysis was concentrated on the hfaB3 mutation which is mapped to chromosome VI tightly linked to the methB and tsB loci. The disruptive influence of hfaB3 on mitosis at 37° was shown by (1) ploidy and whole chromosome-type segregation of markers in the breakdown sectors of phenotypically aneuploid colonies obtained from multiply marked homozygous hfaB3 disploids; (2) a high frequency of haploid and nondisjunctional diploid segregants among spontaneous yellow-spored parasexual recombinants taken from green-spored homozygous hfaB3 diploids. The mutation had no effect on meiotic chromosome segregation at 37°. The single interphase nucleus in germlings at 42°, coupled with changes in the mitotic index in temperature exchange experiments, showed hfaB3 to arrest the cell cycle in interphase at restrictive temperature. A conclusion drawn is that the hfaB gene product is required both for entry into mitosis and for normal chromosome segregation in dividing nuclei.     

Detection and characterization of naturally occuring plasmids in Bacillus subtilis

Summary A rapid procedure has been employed to isolate a large number of mitochondrial mutants resistant to antimycin A or funiculosin. A total of 15 antimycin A resistance mutations has been mapped by allelism tests. The mutations belong to two new mitochondrial loci, designated A_I and A_II. All funiculosin resistance mutations studied up to now map at locus A_II. Thus mitochondrial funiculosin resistance might allow the specific selection of mutations in A_II. Recombination between the two antimycin A resistance loci A_I and A_II occurs at frequencies from 8 to 21%. Apparently the two loci are not linked to PAR1, RIB1, RIB3, OLI1, and OLI2. Mutants of the two loci A_I and A_II have been characterized by measurements of oxygen consumption. Analysis of cytochrome spectra indicates that the mutations affect the cytochrome bc₁ complex of the mitochondrial respiratory chain.     

Promotion of uniparental inheritance of mitochondrial drug resistance by delayed division of yeast zygotes

Summary Uniparental inheritance of mitochondrial markers conferring resistance to 3 (3,4-dichlorphenyl)-1,1-dimethylurea (diuron or DCMU) and antimycin in the fission yeast Schizosaccharomyces pombe is promoted by delaying first division of zygotes.     

Mucidin resistance in yeast. Isolation, characterization and genetic analysis of nuclear and mitochondrial mucidin-resistant mutants of Saccharomyces cerevisiae.

Mutants of Saccharomyces cerevisiae resistant to the antibiotic mucidin, a specific inhibitor of electron transport between cytochrome b and c, were isolated and divided into three phenotypic groups, as follows. Class 1 mutants were cross-resistant to a variety of mitochondrial inhibitors and exhibited no resistance at the mitochondrial level. Class 2 mutants were specifically resistant to mucidin exhibiting resistance also at the level of isolated mitochondria. Biochemical studies indicated that the mucidin resistance in class 2 mutants involved a modification of mucidin binding of inhibitory sites on the mitochondrial inner membrane without a significance change in the sensitivity of mitochondrial oxygen uptake to antimycin A, 2-heptyl-4-hydroxyquinoline-N-oxide, and 2,3-dimercaptopropanol. Class 3 was represented by a mutant which showed a high degree of resistance to mucidin and was cross-resistant to a variety of mitochondrial inhibitors at the cellular level but exhibited only a resistance to mucidin at the mitochondrial level. Genetic analysis of mucidin-resistant mutants revealed the presence of both nuclear and mitochondrial genes determining mucidin resistance/sensitivity in yeast. Resistance to mucidin in class 1 mutants was due to a single-gene nuclear recessive mutation (mucPR) whereas that in class 2 mutants was caused by mutations of mitochondrial genes. Resistance in class 3 mutant was determined both by single-gene nuclear and mitochondrial mutations. In the mitochondrial mutants the mucidin resistance segregated mitotically and the resistance determinant was lost upon induction of petite mutation by ethidium bromide. Allelism tests indicated that the mucidin resistance mutations fell into two genetic loci (MUC1 and MUC2) which were apparently not closely linked in the mitochondrial genome. Recombination studies showed that the two mitochondrial mucidin loci were not allelic with other mitochondrial loci RIB1, RIB2 and OLI1. An extremely high mucidin resistance at the cellular level was shown to arise from synergistic interaction of the nuclear gene mucPR and the mitochondrial mucidin-resistance gene (MR) in a cell. The results suggest that at least two mitochondrial gene products, responsible for mucidin resistance/sensitivity in yeast, take part in the formation of the cytochrome bc1 region of the mitochondrial respiratory chain.     

Genetic determination of ubiquinol-cytochromec reductase

Summary In order to find new genetic loci on the yeast mitochondrial DNA, especially mutations affecting the structure and function of ubiquinol-cytochrome c reductase, 45 independently arisen mutants resistant to mucidin have been isolated after MnCl₂ mutagenesis. The majority of the mutants exhibited increased sensitivity to chloramphenicol, diuron and antimycin A, respectively. it was shown by several criteria that all mutants resulted from mutations localized on the mitochondrial DNA.The allelism tests revealed that these mutations fall into three distinct loci muc1, muc2 and muc3. Mutations at a new locus muc3 were correlated with the changes in the binding or inhibitory sites on the inner mitochondrial membrane. Multifactorial crosses involving the mucidin resistance mutations and mitochondrial mutations conferring resistance to chloramphenicol, erythromycin, oligomycin and diuron revealed that the studied mutations at the loci muc1, muc2 and muc3 did not significantly influence the process of mitochondrial recombination and its control by the mitochondrial locus . The locus muc1 was found to be allelic to the locus diu2. The locus muc2 which was found to be allelic to cob1 locus appears to be linked to the locus oli1 but unlinked to the loci , cap1, ery1 and muc1. The new locus muc3 appears to be weakly linked to the locus diu1 but unlinked to the loci , cap1, ery1, oli1 and muc1.The results are consistent with the gene order oli1-muc2-muc3-diu1-muc1-oli2 and suggest the participation of at least three mucidin resistance loci and one diuron resistance locus in the biogenesis of the bc ₁ complex of the mitochondrial respiratory chain.     

Mitochondrial cytochrome b genes with a six-nucleotide deletion or single-nucleotide substitutions confer resistance to antimycin A in the yeast Kluyveromyces lactis

Extrachromosomal mutants resistant to antimycin, from the yeast Kluyveromyces lactis, have been isolated, genetically characterized, and assigned to two specific genetic loci (Brunner et al., 1987). In the present work the cytochrome b nucleotide sequence from six of these mutants was determined. Five mutants had single point mutations, corresponding to transversions. In one mutant, a six-base-pair deletion, beginning at nucleotide 689, was observed. The amino acid sequence derived from the coding strand showed that, in three independent antimycin-resistant mutants, a change of asparagine 31 into lysine took place (two of these mutants are also resistant to diuron). Two other mutants showed a change from lysine 228 into isoleucine (or methionine). Leucine 230, isoleucine 231, and threonine 232, were lost in the deletion mutant and were replaced by serine.     

Cytoplasmic inheritance of antimycin A resistance in Saccharomyces cerevisiae

Summary Three antimycin resistant mutants of Saccharomyces cerevisiae are characterized genetically. The mutations have been shown to be cytoplasmically inherited by four criteria. The phenotype persists in diploids formed by a cross with a ⁰ strain of yeast of the opposite mating type. Diploids heterozygous for the antimycin marker, however, show segregation of the resistance and sensitivity during mitosis. Tetrad analysis indicated a non-Mendelian segregation (4:0 and 0:4) of the mutations. The antimycin marker can be eliminated by ethidium bromide treatment under conditions that should have deleted all of the mitochondrial DNA.     

Genetic mapping of mitochondrial markers by recombinational analysis in Chlamydomonas reinhardtii

The mitochondrial genome of Chlamydomonas reinhardtii is a 15.8 kb linear DNA molecule present in multiple copies. In crosses, the meiotic products only inherit the mitochondrial genome of the mating type minus (paternal) parent. In contrast mitotic zygotes transmit maternal and paternal mitochondrial DNA copies to their diploid progeny and recombinational events between molecules of both origins frequently occur. Six mitochondrial mutants unable to grow in the dark (dk^? mutants) were crossed in various combinations and the percentages of wild-type dk⁺ recombinants were determined in mitotic zygotes when all progeny cells had become homoplasmic for the mitochondrial genome. In crosses between strains mutated in the COB (apocytochrome ) gene and strains mutated in the COX1 (subunit 1 of cytochrome oxidase) gene, the frequency of recombination was 13.7% (± 3.2%). The corresponding physical distance between the mutation sites was 4.3 kb. In crosses between strains carrying mutations separated by about 20 bp, a recombinational frequency of 0.04% (± 0.02%) was found. Two other mutants not yet characterized at the molecular level were also used for recombinational studies. From these data, a linear genetic map of the mitochondrial genome could be drawn. This map is consistent with the positions of the mutation sites on the mitochondrial DNA molecule and thereby validates the method used to generate the map. The frequency of recombination per physical distance unit (3.2% ± 0.7% per kilobase) is compared with those obtained for other organellar genomes in yeasts and Chlamydomonas.     

Expression of the "split gene" cob in yeast mtDNA. Nuclear mutations specifically block the excision of different introns from its primary transcript

Five nuclear mutants falling into five different complementation groups are shown to block the maturation of long form mitochondrial cob RNA at five different processing steps. At the same time they prevent complete processing of the oxi 3 RNA, thus exhibiting the same phenotype as mitochondrial box mutants (cyt b- and oxi 3-). The different nuclear factors in question have varying ranges of specificity for the removal of introns from cob RNA, from only one to at the most three introns. Two mutated nuclear elements are shown to be specific for the processing of introns present only in the long form cob gene. One such mutation shows, as expected, no deleterious effect on the processing of the short form cob RNA exchanged into the mutant via cytoduction. The role of nuclear coded factors in the possible translation or activity of introncoded products ("maturases") is discussed for two mutants. Striking parallels are found between diverse polypeptide products, presumably translated from accumulated cob RNA intermediates, in pet- and mit- mutants blocked in the excision of the same intron.     

Inheritance of mating factors in nocardial recombinants

The segregation of mating loci with other unselected genes was analyzed in recombinants obtained from matings of Nocardia canicruria and N. erythropolis. The loci C/c and E/e control nocardial compatibility. Four mating genotype combinations were observed: cE, Ce, CE, and ce. Strains of N. erythropolis bear the genotype cE and strains of N. canicruria bear the Ce alleles. The CE recombinant mating type is capable of mating with both organisms, whereas the ce-containing recombinant is nonfertile. The E locus was found to segregate with StrA1 (streptomycin-resistance gene) on the N. erythropolis linkage group. The C locus appeared linked to PurB2 (purine-requiring gene) on the N. canicruria linkage group. A few observed recombinants were capable of further segregation of unselected characters after colonial purification, suggesting a possible heterogenomic condition or multiple rounds of mating. Prior treatment of recombinants with acriflavine failed to alter their compatibility or the frequency at which recombinants were recovered. The segregation pattern of the mating loci allowed for specific recombinant class types to be compatible.     

Early vegetative segregation of mitochondrial genes in Saccharomyces cerevisiae

The vegetative segregation of seven mitochondrial gene loci was studied in yeast. At various times after mating antibiotic resistant and sensitive strains, samples of the diploid progeny were examined to determine the segregation rates of the alleles at each locus in three- and four-factor crosses. The rate of segregation was approximately the same for the cap1, ery1, oli1, oli2, and par1 loci, which are scattered over about two-thirds of the mitochondrial DNA molecule. Differences in segregation rates were found but showed no consistent relationship to the map positions of the loci. This is in contrast to the segregation of chloroplast genes in Chlamydomonas, where loci segregate at rates proportional to their distance from an “attachment point” which appears to govern the partitioning of chloroplast DNA molecules between daughter chloroplasts when the chloroplast divides. Our data are compatible with a model in which the mitochondrial DNA molecules in a cell occur in a small number of groups corresponding to individual nucleoids or mitochondria. Most or all of the molecules in a group carry the same allele at any given locus. These genetically homogeneous groups of molecules may thus be the units of segregation, and may be partitioned randomly between mother cell and bud at each division.     

Genetic mapping of mitochondrial markers by recombinational analysis in Chlamydomonas reinhardtii

The mitochondrial genome of Chlamydomonas reinhardtii is a 15.8 kb linear DNA molecule present in multiple copies. In crosses, the meiotic products only inherit the mitochondrial genome of the mating type minus (paternal) parent. In contrast mitotic zygotes transmit maternal and paternal mitochondrial DNA copies to their diploid progeny and recombinational events between molecules of both origins frequently occur. Six mitochondrial mutants unable to grow in the dark (dk^– mutants) were crossed in various combinations and the percentages of wild-type dk⁺ recombinants were determined in mitotic zygotes when all progeny cells had become homoplasmic for the mitochondrial genome. In crosses between strains mutated in the COB (apocytochrome ) gene and strains mutated in the COX1 (subunit 1 of cytochrome oxidase) gene, the frequency of recombination was 13.7% (± 3.2%). The corresponding physical distance between the mutation sites was 4.3 kb. In crosses between strains carrying mutations separated by about 20 bp, a recombinational frequency of 0.04% (± 0.02%) was found. Two other mutants not yet characterized at the molecular level were also used for recombinational studies. From these data, a linear genetic map of the mitochondrial genome could be drawn. This map is consistent with the positions of the mutation sites on the mitochondrial DNA molecule and thereby validates the method used to generate the map. The frequency of recombination per physical distance unit (3.2% ± 0.7% per kilobase) is compared with those obtained for other organellar genomes in yeasts and Chlamydomonas.     

Studies on energy-linked reactions: isolation, characterisation and genetic analysis of trialkyl-tin-resistant mutants of Saccharomyces cerevisiae.

Mutants of Saccharomyces cerevisiae resistant to triethyl tin sulphate have been isolated and are cross-resistant to other trialkyl tin salts. Triethyl-tin-resistant mutants fall into two general phenotypic classes: class 1 and class 2. Class 1 mutants are cross-resistant to a variety of inhibitors and uncoupling agents which affect mitochondrial membranes (oligomycin, ossamycin, valinomycin, antimycin, erythromycin, chloramphenicol, '1799', tetrachlorotrifluoromethyl benzimidazole carbonylcyanide-m-chlorophenylhydrazone and cycloheximide). Class 2 mutants are specifically resistant to trithyl tin and the uncoupling agent "1799' [bis-(hexafluoroacetonyl)-acetone]. Triethyl tin at neutral pH values is a specific inhibitor of mitochondrial energy conservation reactions and prevents growth on oxidisable substrates such as glycerol and ethanol. Triethyl-tin-resistant mutants grow normally on glucose and ethanol in the presence of triethyl tin (10 muM). Biochemical studies indicate that the mutation involves a modification of the triethyl tin binding site on the mitochondrial inner membrane, probably the ATP-synthetase complex. Triethyl tin resistance/sensitivity in yeast is determined by cytoplasmic (mitochondrial) and nuclear genes. The mutants fall into a nuclear and a cytoplasmic (mitochondrial) class corresponding to the phenotypic cross-resistance classes 1 and 2. In the cytoplasmic mutants the triethyl tin resistance segregates mitotically and the resistance determinat is deleted by the action of ethidium bromide during petite induction. Recombination studies indicate that the triethyl tin mutations are not allelic with the other mitochondrial mutations at the loci RI, RIII and OLI. This indicates that the binding or inhibitory sites of oligomycin and triethyl tin are not identical and that the triethyl tin binding site is located on a different mitochondrial gene product to those which are involved in oligomycin binding. Interaction and cooperative effects between different binding sites on the mitochondrial inner membrane have been demonstrated in studies of the effect of the insertion of the TETr phenotype into mitochondrial oligomycin-resistant mutants and provide an experimental basis for complementation studies at the ATP-synthetase level.