Assembly of the mitochondrial membrane system: mutations in the pho2 locus of the mitochondrial genome of Saccharomyces cerevisiae.

Two mutants of Saccharomyces cerevisiae which show a loss of mitochondrial rutamycin-sensitive ATPase activity are described. Although phenotypically similar to mutants of the mitochondrial locus pho1 [F. Foury and A. Tzagoloff (1976) Eur. J. Biochem. 68, 113-119], these mutants define a second ATPase locus on the mitochondrial DNA (designated pho2), which is genetically unlinked to pho1. Analysis of recombination in crosses involving multiple antibiotic resistance markers indicates that the locus is in the segment of the genome between ery1 and oli2, very close to oli1. In fact it is proposed that the oli1 and pho2 mutations are in the same gene. Supporting evidence for this proposal includes: 1. The analysis of marker retention in petite mutants shows that the oli1 and pho2 loci were either retained or lost together in all cases. 2. Recombination frequencies of 0.05% or less are observed in crosses between the oli1 and pho2 loci. 3. When rho+ revertants are isolated from the pho2 mutants they frequently are oligomycin resistant. 4. pho2 mutants have an altered subunit 9 of the ATPase complex.     

Assembly of the mitochondrial membrane system: two separate genes coding for threonyl-tRNA in the mitochondrial DNA of Saccharomyces cerevisiae.

1. Mitochondria of Saccharomyces cerevisiae contain two tRNA's that are acylated with threonine. The two isoaccepting species (tRNA1Thr and tRNA2Thr) can be separated by reversed-phase chromatography on RPC-5. 2. A cytoplasmic mutant has been isolated which lacks tRNA1Thr but has normal levels of tRNA2Thr. This mutation was previously shown to map between the oxi 1 and oxi 2 loci on mitochondrial DNA. 3. tRNA1Thr and tRNA2Thr hybridize to wild type mitochondrial but not nuclear DNA and are capable of partially competing with each other. Hybridization of each species to different segments of mitochondrial DNA isolated from p- clones indicate that there are two threonyl tRNA genes. One gene is located between oxi 1 and oxi 2 and codes for tRNA1Thr. The second gene codes for tRNA2Thr and is near the cap locus. 4. Binding assays to E. coli ribosomes indicate that tRNA2Thr recognizes the threonine triplet ACA and may also recognize the other three triplets but with a much lower efficiency. None of the four codons for threonine stimulate the binding of tRNA1Thr to the ribosomes.     

Sporulation of mitochondrial respiratory deficient mit- mutants of Saccharomyces cerevisiae.

Summary The role of mitochondrial protein synthesis, electron transport, and four specific mitochondrial gene products on sporulation were studied in respiratory deficient mit ^- mutants. These mutants were isolated in an op1 strain and localized on the mitochondrial genome by petite deletion mapping. All 153 mutations studied could be assigned to the four mitochondrial regions OXI1, OXI2, OXI3 and COB, known to affect cytochrome c oxidase and cytochrome b. The specific loss of one mitochondrially translated polypeptide was found in some mutants of each locus: OXI1—cytochrome c oxidase subunit 2, OXI2 — subunit 3, OXI3 — subunit 1, and COB — cytochrome b.The ability of diploid mit ^- mutants to sporulate was systematically investigated. About one third of the mutants, representing three loci, were incapable of forming spores. All other cultures produced either respiratory competent mit ⁺ tetrads, both mit ⁺ and mit ^- tetrads, or only mit ^- tetrads. Mutants forming mit ^- tetrads mapped in all four loci. These results demonstrate that in contrast to petite mutants some mit ^- mutants have retained the ability to perform meiosis and sporulation.     

Biogenesis of mitochondria: DNA sequence analysis of mit- mutations in the mitochondrial oli2 gene coding for mitochondrial ATPase subunit 6 in Saccharomyces cerevisiae.

A series of yeast mitochondrial mit- mutants with defects in the oli2 gene, coding for subunit 6 of the mitochondrial ATPase complex, has been analyzed at the DNA sequence level. Fifteen of sixteen primary mit- mutants were shown to contain frameshift or nonsense mutations predicting truncated subunit 6 polypeptides, in various strains ranging from about 20% to 95% of the wild-type length of 259 amino acids. In only one strain could the defect in subunit 6 function be assigned to amino acid substitution in an otherwise full-length subunit 6. Many mutants carried multiple base substitutions or insertions/deletions, presumably arising from the manganese chloride mutagenesis treatment. Revertants from three of the mit- mutants were analyzed: all contained full-length subunit 6 proteins with one or more amino acid substitutions. The preponderance of truncated proteins as opposed to substituted full-length proteins in oli2 mit- mutants is suggested to reflect the ability of subunit 6 to accommodate amino acid substitutions at many locations, with little or no change in its functional properties in the membrane FO-sector of the ATPase complex.     

Biogenesis of mitochondria: DNA sequence analysis of mit- mutations in the mitochondrial oli1 gene coding for mitochondrial ATPase subunit 9 in Saccharomyces cerevisiae.

The nucleotide sequence of the yeast mitochondrial olil gene has been obtained in a series of mit- mutants with mutations in this gene, which codes for subunit 9 of of the mitochondrial ATPase complex. Subunit 9 is the proteolipid, 76 amino acids in length, necessary for the proton translocation function of the membrane Fo-sector. These mutants were classified on the basis of their rescue by a petite strain shown here to retain the entire wild-type olil gene. The mutation in one mit- strain removes a positively charged residue (Arg39----Met) which is likely to be located in a segment of subunit 9 that protrudes from the inner mitochondrial membrane. In a second mit- mutant, a negatively charged residue replaces a conserved glycine residue (Gly18----Asp) in a glycine-rich segment of the protein that is most likely embedded within the membrane. Other mit- mutations result in frameshifts with predicted products 7, 65 and 68 amino acid residues long. In each mit- mutant, there is the loss of one or more of the amino acid residues that are highly conserved among diverse species. The location and nature of specific changes pinpoint amino acid residues in subunit 9 essential to the activity of the mitochondrial ATPase complex.     

A petite mitochondrial DNA segment arising in exceptionally high frequency in a mit- mutant of Saccharomyces cerevisiae

In cultures of the mit- mutant strain Mb12 of Saccharomyces cerevisiae (carrying a mutation in the oli2 gene), 70% of the cells are petite mutants. More than 80% of the petites from Mb12 contain a particular mtDNA segment, denoted BB5, that is 880 bp long and carries a single MboI site. Thus, in cultures of Mb12, about 56% of the cells are petites containing the defective BB5 mtDNA genome, and only 30% are mit- cells containing parental Mb12 mtDNA. The BB5 mtDNA segment is also found in petites arising from the wild-type strain J69-1B (from which Mb12 was derived), but in this case mtDNA from only five out of 24 petites produced an 880 bp band after MboI digestion. Since J69-1B cultures carry a petite frequency of about 5%, approximately 1% of cells in J69-1B cultures contain the BB5 mtDNA segment. The difference between Mb12 and J69-1B cultures is reflected in the MboI digestion patterns of the respective mtDNAs. While Mb12 mtDNA contains a grossly superstoicheiometric 880 bp MboI fragment, the corresponding fragment in J69-1B mtDNA cannot be seen on stained gels, but can be readily visualized in Southern blots hybridized to a 32P-labelled DNA probe obtained from the 880 bp MboI fragment. The BB5 mtDNA segment was shown to contain the ori1 sequence (one of several very similar sequences in wild-type mtDNA thought to act as origins of replication of mtDNA) which confers the genetic property of very high suppressiveness on petites carrying this mtDNA. The efficient replication of BB5 mtDNA may contribute to its abundance in Mb12 cultures. Nevertheless, other factors must operate to influence the abundance of the BB5 mtDNA segment in cultures of different strains, the most important of which is likely to be the rate of excision of this mtDNA segment from the parental mtDNA genome.     

Assembly of the mitochondrial membrane system. Characterization of nuclear mutants of Saccharomyces cerevisiae with defects in mitochondrial ATPase and respiratory enzymes.

Mutants of Saccharomyces cereviaiae showing defects in cytochrome oxidase, coenzyme QH2-cytochrome c reductase, and rutamycin-sensitive ATPase are described. The mutations have been established to be nuclear, based on complementation with a cytoplasmic petite tester strain and 2:2 segregation of tetrads. Genetic analysis indicate the coenzyme QH2-cytochrome c reductase and cytochrome oxidase mutants fall into 9 and 10 different complementation groups, respectively. The mutants also form distinct classes based on absorption spectra of the mitochondrial cytochromes. Two of the ATPase mutants lack detectable F1 ATPase, while the third synthesizes F1 but does not integrate it into a membrane complex. The latter mutant is missing one of the mitochondrially synthesized subunits of the rutamycin-sensitive ATPase complex.     

Assembly of the mitochondrial membrane system. DNA sequence and organization of the cytochrome b gene in Saccharomyces cerevisiae D273-10B

The mitochondrial genomes of cytoplasmic "petite" (rho-) mutants of Saccharomyces cerevisiae have been used to sequence the cytochrome b gene. A continuous sequence of 6.2 kilobase pairs has been obtained from 71.4 to 80.2 units of the wild type map. This region contains all the cytochrome b mutations previously assigned to the cob1 and cob2 genetic loci. Analysis of the DNA sequence has revealed that in the strain D273-10B, the cytochrome b gene is composed of three exons. The longest exon (b1) codes for the first 252 to 253 amino acids from the NH2-terminal end of the protein. The next two exons (b2 and b3) code for 16 to 18 and 115 to 116 amino acids, respectively. The complete cytochrome b polypeptide chain consists of 385 amino acids. Based on the amino acid composition, the yeast protein has a molecular weight of 44,000. The three exon regions of the cytochrome b gene are separated by two introns. The intron between b1 and b2 is 1414 nucleotides long and contains a reading frame that is continuous with the reading frame of exon b1. This intron sequence is potentially capable of coding for another protein of 384 amino acid residues. The second intron is 733 nucleotides long. This sequence is rich in A + T and includes a G + C cluster that may be involved in processing of the cytochrome b messenger. The organization of the cytochrome b region in S. cerevisiae D273-10B is somewhat less complex than has been reported for other yeast strains i which exon b1 appears to be further fragmented into three smaller exons.     

Nuclear mutations in Saccharomyces cerevisiae which increase the spontaneous mutation frequency in mitochondrial DNA.

Summary Fourteen mutants have been identified in which the frequency of spontaneous mutations in mitochondrial DNA is increased. As well as increasing the frequency of mutations to resistance to erythromycin, oligomycin and spiramycin, all the mutants also show changes in the frequency of spontaneous petite induction. None of the mutants has any effect on the frequency of spontaneous nuclear mutations. Nine of the mutants are in one complementation group and five are in another. The phenotype of both groups is caused by a single nuclear mutation.     

Assembly of the mitochondrial membrane system: isolation of nuclear and cytoplasmic mutants of Saccharomyces cerevisiae with specific defects in mitochondrial functions.

A selection procedure is described which permits a large number of Saccharomyces cerevisiae mutants to be screened for specific lesions in mitochondrial respiratory enzymes and the adenosine triphosphatase. The method has been used to isolate nuclear mutant strains with specific lesions in coenzyme QH2-cytochrome c reductase, cytochrome oxidase, and adenosine triphosphatase. In addition, two cytoplasmic mutants have been found whose primary defect is in cytochrome oxidase, and others have been found that show variable degrees of abnormalities in their mitochondrial translation products.     

Assembly of the mitochondrial membrane system. Cytoplasmic mutants of Saccharomyces cerevisiae with lesions in enzymes of the respiratory chain and in the mitochondrial ATPase.

Mutants of Saccharomyces cervisiae with defects in enzymes of the electron transfer chain and in the rutamycin-sensitive ATPase have been isolated. Some of the mutants are specifically affected in either cytochrome oxidase, coenzyme QH2-cytochrome c reductase or ATPase. Other strains are deficient in both cytochrome oxidase and coenzyme QH2-cytochrome c reductase but still have rutamycin-sensitive ATPase. All the mutants reported in this study fail to be complemented by a rho0 tester derived from a respiratory competent strain. The meiotic spore progeny obtained by mating the mutants to a respiratory competent haploid yeast, when scored for growth on glycerol, show a non-Mendelian segregation of the phenotype. These two genetic tests indicate the mutations to be cytoplasmically inherited.     

Pleiotropic plasma membrane ATPase mutations of Saccharomyces cerevisiae.

We isolated a large number of mutations in the structural gene for the plasma membrane ATPase (PMA1) of Saccharomyces cerevisiae. These mutations were selected by their resistance to the aminoglycoside antibiotic hygromycin B. Biochemical analysis of purified membrane preparations showed that the plasma membrane ATPase activity of the mutants was reduced as much as 75%. Intragenic complementation of pma1 mutants suggested that the yeast plasma membrane ATPase was a multimeric enzyme. The pma1 mutants were apparently defective in maintaining internal pH; more than half of the mutants were unable to grow either at a low pH or in the presence of a weak acid. Most pma1 mutants were also osmotic pressure sensitive. At a very low temperature (5 degrees C) many pma1 mutants were unable to grow and were arrested as unbudded cells. The three most severely affected mutants were also unable to grow in the presence of NH4+. The most extreme mutant exhibited a severe defect in progression through the cell cycle; on synthetic medium, the cells progressively accumulated nucleus-containing small buds that generally failed to complete bud enlargement and cytokinesis. Most of the pleiotropic phenotypes of pma1 mutants could be suppressed by the addition of 50 mM KCl but not NaCl to the medium.