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

Biogenesis of mitochondria. XLII. Genetic analysis of the control of cellular mitochondrial DNA levels in Saccharomyces cerevisiae

The proportion of total cell DNA which is mitochondrial DNA was measured in haploid, diploid and tetraploid strains of S. cerevisiae grown under a standard set of conditions. For all strains tested the mitochondrial DNA level was in the range 16%-25% of total cell DNA. Repeated measurements of the cellular level of mitochondrial DNA in two haploid strains showed that these strains have measurably different cellular mitochondrial DNA levels (17% and 24% of total DNA, respectively) under our conditions. These two grande strains were used to investigate the role of the mitochondrial and nuclear genomes in the regulation of the mitochondrial DNA level. We have shown by genetic analysis that the difference between these two strains is determined by at least two nuclear genes. The mitochondrial genome is not involved in the regulation of cellular mitochondrial DNA levels. A number of purified petite clones derived from independent spontaneous petite isolates of the grande strain which contained 24% mitochondrial DNA were also studied. The mitochondrial DNA levels in all but one of these petites fell in the range 20-25% of total cell DNA. From these results we conclude that, in general, the mitochondrial DNA level in petite strains is controlled by the same mechanism as operates in grande strains. We propose a general model for the control of the cellular mitochondrial DNA level, in which the amount of mitochondrial DNA per cell is determined by regulation of the number of mitochondrial DNA molecules per cell. This regulation is mediated through the availability of a set of nuclear coded components, possibly a mitochondrial membrane site, which are required for the replication of mitochondrial DNA.

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.

Rearrangement of mitochondrial DNA molecules during the differentiation of mitochondria in yeast. I.-Electron microscopic studies of size and shape

Size and shape of purified mitochondrial DNA was analyzed by electron microscopy as a function of mitochondrial differentiation. The mitochondrial DNA was extracted at fourth growth stages corresponding to different steps of mitochondria repression and depression. It was heterogeneous both in form and length. The size of linear molecules ranged from 1 mu to 25 mu but most of the molecules could be assigned into four Gaussian subpopulations with mean lengths of 2.2 mu to 4.0 mu, 6.0 mu and 10.0 mu. The circular molecules were all open and sized varied from 0.5 mu to 10 mu. Their length repartition was congruent with a logarithmic Gaussian distribution. The relative proportion of the different classes of molecules changed according to the stage of the growth cycle: during the repression most of the mitochondrial DNA molecules were short: the population of 2.2 mu was predominant. The longest linear molecules were observed during derepression where the populations of 4.0 mu and 10.0 mu were only found as well as the highest proportion of circular molecules. At the stationary phase the mitochondrial DNA became short again and the circles disappeared completely. The mitochondrial DNA extracted from a cytoplasmic "petite" was composed of linear and circular molecules. The linear molecules ranged from 0.1 mu to 32 mu and most of them could be assigned to two subpopulations of 1.3 mu and 4.2 mu. The circular molecules which accounted for 11 percent had contour lengths of 0.7 mu and 1.5 mu. The physiological meaning of the change in the relative proportion of different classes of mitochondrial DNA is discussed.