Transfer RNA genes in the mitochondrial DNA of cytoplasmic petite mutants of Saccharomyces cerevisiae

Hybridization saturation analyses of mitochondrial DNA from 11 petite clones genetically characterized with respect to chloramphenicol and erythromycin resistance markers, have been carried out with 11 individual mitochrondrial transfer RNAs. Mitochondrial tRNA cistrons were lost, retained, or amplified in different petite strains. In some cases hybridization levels corrected for kinetic complexity of the mtDNA³ were two- to threefold greater than that for grande mtDNA indicating selective amplification, or increased number of copies, of the segment of mtDNA containing that tRNA cistron. Hybridization levels corrected for reduced kinetic complexity of petite mtDNAs in many cases were only 1 to 10% of that for grande mtDNA suggesting a low level of intracellular molecular heterogeneity of mtDNA with respect to tRNA cistrons. Some petite clones that retained tRNA genes continued to transcribe mitochondrial tRNAs, since tRNA isolated from these strains could be aminoacylated with Escherichia, coli synthetases and hybridized with mtDNA. Hybridization data allow us to order several of the tRNA cistrons on the mitochondrial genome with respect to the chloramphenicol and erythromycin antibiotic resistance markers.     

Site-specific recombination in “petite colony” mutants of Saccharomyces cerevisiae

Molecular Genetics and Genomics - We have studied the organization of parental and recombined repetitive molecules of mtDNA's from cytoplasmic petite mutants of S. cerevisiae. One parental...     

Electron microscopic and renaturation kinetic analysis of mitochondrial DNA of cytoplasmic petite mutants of Saccharomyces cerevisiae

Mitochondrial DNA isolated from a series of nine petite yeast strains and from the parent grande strain was characterized by electron microscopic and renaturation kinetic analysis. The mtDNA² from all strains contained a variety of branched molecules which may be intermediates of replication or recombination. Although no circles were observed in the grande mtDNA, all the petites contained circular mtDNA molecules. The size distribution of the circles conformed to an oligomeric series that was characteristic for each strain. In seven petites, the length series could be related to a single circle monomer size, ranging from 0.13 μm to 5.5 μm; and in two petites to two or more circular monomer lengths. In contrast to circular mtDNA, linear molecules showed no unique size distribution. Circle monomer lengths were linearly related to the kinetic complexity (κ₂ or $\text{C}{}_0\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$) of sheared total mtDNA in the seven petite strains that contained a predominant single series of circle lengths. Thus in each of these petite strains the circle monomer length defined the same DNA sequence present in the linear DNA molecules of non-unique length.     

Mitochondrial DNA inheritance in Saccharomyces cerevisiae

Respiratory metabolism depends on mitochondrial DNA, yet the mechanisms that ensure the inheritance of the mitochondrial genome are largely obscure. Recent studies with Saccharomyces cerevisiae suggest that distinct factors mediate the active segregation of mitochondrial DNA during mitotic growth. The identification of the proteins required for the maintenance of the mitochondrial genome provides clues to the mechanisms of, and molecular machinery involved in, mitochondrial DNA inheritance.     

Circular mitochondrial DNA molecules from petite mutants of Saccharomyces cerevisiae: resolution by polyacrylamide gel electrophoresis

Mitochondrial DNA (mtDNA) from petite strain K45 ofSaccharomyces cerevisiae contains about 7% circular DNA molecules which comprise a simple oligomeric series based on a monomeric size of 1.7 kilobase pairs. Electrophoresis of K45 mtDNA on a polyacrylamide-agarose slab gel fractionates the mtDNA into a major band (containing linear DNA) and several faster running minor bands each containing particular size class of circular DNA molecules. From study of mtDNA from K45 and two other simple petites it was found that the mobility of circles is inversely proportional to the logarithm of the circle size. Polyacrylamide gel electrophoresis thus permits the separation of circular mtDNA from the linear mtDNA of simple petites, and physically resolves circles of different size from one another.     

Induction of petite mutants in yeast Saccharomyces cerevisiae by the anticancer drug dequalinium

Dequalinium (DEQ), a drug with both antimicrobial and anticancer activity, induced the formation of petite (respiration-deficient) mutants in the yeast Saccharomyces cerevisiae. DEQ was found to be approximately 50-fold more potent than ethidium bromide (EB) at inducing petites. Analysis of the DEQ-induced petite mutants indicated a complete loss of mitochondrial DNA (<1 copy/cell). Prior to the loss of mtDNA, DEQ caused cleavage of the mtDNA into a population of fragments 30-40kbp in size suggesting that this drug causes petites by inducing a breakdown of mtDNA. The selective effect of DEQ on yeast mtDNA may underlie the antifungal activity of this chemotherapeutic agent.     

Mitochondrial DNA ligase function in Saccharomyces cerevisiae

The Saccharomyces cerevisiae CDC9 gene encodes a DNA ligase protein that is targeted to both the nucleus and the mitochondria. While nuclear Cdc9p is known to play an essential role in nuclear DNA replication and repair, its role in mitochondrial DNA dynamics has not been defined. It is also unclear whether additional DNA ligase proteins are present in yeast mitochondria. To address these issues, mitochondrial DNA ligase function in S.cerevisiae was analyzed. Biochemical analysis of mitochondrial protein extracts supported the conclusion that Cdc9p was the sole DNA ligase protein present in this organelle. Inactivation of mitochondrial Cdc9p function led to a rapid decline in cellular mitochondrial DNA content in both dividing and stationary yeast cultures. In contrast, there was no apparent defect in mitochondrial DNA dynamics in a yeast strain deficient in Dnl4p (Deltadnl4). The Escherichia coli ECO:RI endonuclease was targeted to yeast mitochondria. Transient expression of this recombinant ECO:RI endonuclease led to the formation of mitochondrial DNA double-strand breaks. While wild-type and Deltadnl4 yeast were able to rapidly recover from this mitochondrial DNA damage, clones deficient in mitochondrial Cdc9p were not. These results support the conclusion that yeast rely upon a single DNA ligase, Cdc9p, to carry out mitochondrial DNA replication and recovery from both spontaneous and induced mitochondrial DNA damage.     

Mitochondrial DNA synthesis in cell cycle mutants of saccharomyces cerevisiae

Mitochondrial DNA replication was examined in mutants for seven different Saccharomyces cerevisiae genes which are essential for nuclear DNA replication. In cdc8 and cdc21, mutants defective in continued replication during the S phase of the cell cycle, mitochondrial DNA replication ceases at the nonpermissive temperature. Replication is temperature sensitive even when these mutants are arrested in the G1 phase of the cell cycle with α factor, a condition where mitochondrial DNA replication continues for the equivalent of several generations at the permissive temperature. Therefore the cessation of replication results from a defect in mitochondrial replication per se, rather than from an indirect consequence of cells being blocked in a phase of the cell cycle where mitochondrial DNA is not normally synthesized. Since the temperature-sensitive mutations are recessive, the products of genes cdc8 and cdc21 must be required for both nuclear and mitochondrial DNA replication. In contrast to cdc8 and cdc21, mitochondrial DNA replication continues for a long time at the nonpermissive temperature in five other cell division cycle mutants in which nuclear DNA synthesis ceases within one cell cycle: cdc4, cdc7, and cdc28, which are defective in the initiation of nuclear DNA synthesis, and cdc14 and cdc23, which are defective in nuclear division. The products of these genes, therefore, are apparently not required for the initiation of mitochondrial DNA replication.     

The size of mitochondrial DNA from a cytoplasmic petite mutant of Saccharomyces cerevisiae

Summary Mitochondrial DNA has been isolated from a cytoplasmic petite mutant of Saccharomyces cerevisiae which has retained only about 2% of the mitochondrial wild type genome. The denatured DNA was analyzed by agarose gel electrophoresis and a homogeneous, single band of DNA was found. Petite and wild type mitochondrial DNAs exhibited similar gel electrophoretic mobilities. Using denatured DNA from the E. coli phages T4 and T3 for comparison a molecular weight of 55×10⁶ daltons has been calculated for the double-stranded petite mitochondrial DNA. On the basis of this observation most of the mitochondrial DNA of this petite mutant appeared to consist of a polymer of about 50 repeats to account for a size similar to that of the wild type molecule. Thus a regulatory mechanism might exist which keeps constant the physical size of the mitochondrial DNA molecule in spite of the elimination of large fractions of the wild type genome.Dedicated to Dr. Dr. h. c. Peter Michaelis on the occasion of his 75th birthday