Induction of petite yeast mutants by membrane-active agents

Ethanol proved to be a strong mutagenic agent of Saccharomyces mitochondrial DNA. Other active membrane solvents, such as tert-butanol, isopropanol, and sodium dodecyl sulfate, also turned out to be powerful petite mutation [rho-] inducers. Mutants defective in ergosterol synthesis (erg mutants) showed an extremely high frequency of spontaneous petite cells, suggesting that mitochondrial membrane alterations that were caused either by changes in its composition, as in the erg mutants, or by the effects of organic solvents resulted in an increase in the proportion of petite mutants. Wine yeast strains were generally more tolerant to the mutagenic effects of alcohols on mitochondrial DNA and more sensitive to the effect of sodium dodecyl sulfate than laboratory strains. However, resistance to petite mutation formation in laboratory strains was increased by mitochondrial transfer from alcohol-tolerant wine yeasts. Hence, the stability of the [rho+] mitochondrial DNA in either the presence or absence of solvents depends in part on the nature of the mitochondrial DNA itself. The low frequency of petite mutants found in wine yeast-laboratory yeast hybrids and the fact that the high frequency of petite mutants of a particular wine spore segregated meiotically indicated that many nuclear genes also play an important role in the mitochondrial genome in both the presence and absence of membrane solvents.     

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.     

Ethanol production using nuclear petite yeast mutants

Two respiratory-deficient nuclear petites, FY23Δpet191 and FY23Δcox5a, of the yeast Saccharomyces cerevisiae were generated using polymerase-chain-reaction-mediated gene disruption, and their respective ethanol tolerance and productivity assessed and compared to those of the parental grande, FY23WT, and a mitochondrial petite, FY23ρ⁰. Batch culture studies demonstrated that the parental strain was the most tolerant to exogenously added ethanol with an inhibition constant. K _i, of 2.3% (w/v) and a specific rate of ethanol production, q _p, of 0.90 g ethanol g dry cells⁻¹ h⁻¹. FY23ρ⁰ was the most sensitive to ethanol, exhibiting a K _i of 1.71% (w/v) and q _p of 0.87 g ethanol g dry cells⁻¹ h⁻¹. Analyses of the ethanol tolerance of the nuclear petites demonstrate that functional mitochondria are essential for maintaining tolerance to the toxin with the 100% respiratory-deficient nuclear petite, FY23Δpet191, having a K _i of 2.14% (w/v) and the 85% respiratory-deficient FY23Δcox5a, having a K _i of 1.94% (w/v). The retention of ethanol tolerance in the nuclear petites as compared to that of FY23ρ⁰ is mirrored by the ethanol productivities of these nuclear mutants, being respectively 43% and 30% higher than that of the respiratory-sufficient parent strain. This demonstrates that, because of their respiratory deficiency, the nuclear petites are not subject to the Pasteur effect and so exhibit higher rates of fermentation. Received: 22 September 1997 / Accepted: 7 December 1997     

Induction of cytoplasmic petite in yeast by guanidine hydrochloride: Combined treatment with other inducing agents

We have studied the induction of ?^? mutants by guanidine hydrochloride (GuHCl) in combination with other known inducers: ethidium bromide (EB), berenil and ultraviolet light. Competition was observed when cells were simultaneously treated with optimal concentrations of EB and GuHCl; on the other hand, treatment of cells with EB in the presence of non-inducing concentrations of GuHCl resulted in the stimulation of ?^? induction by EB. Furthermore, using a strain which upon treatment with high EB concentrations shows recovery of respiratory competence, the presence of GuHCl did not interfere either with the early phase of induction or with the recovery phase, but it did interfere in a competitive fashion with the final irreversible phase of EB induction. In the case of berenil, a synergistic effect was seen when cells were pretreated with GuHCl. A synergistic induction was also observed when cells were submitted to UV prior to GuHCl treatment. These results suggest that GuHCl, EB and berenil act via some common step in their ?^? induction pathways. Moreover, GuHCl may somehow be decreasing the efficiency of dark repair of ultraviolet lesions on mitochondrial DNA.     

Studies on the induction of petite mutants in yeast by analogues of berenil

Summary Compound Hoe 15 030 is an analogue of berenil which is as effective as berenil in inducing petite mutants in Saccharomyces cerevisiae. Hoe 15 030 has greater stability than berenil in aqueous solution, and is less toxic to yeast at high drug concentrations. Mutants of S. cerevisia strain J69-1B have been isolated which are resistant to the petite inducing effects of Hoe 15 030. Three mutant strains (HR7, HR8 and HR10) were characterized and each was shown to carry a recessive nuclear mutation determining resistance to Hoe 15 030. The degree of resistance to Hoe 15 030 is different for each mutant, and each was found to be co-ordinately cross-resistant both to berenil and to another analogue of berenil, Hoe 13 548. However, the three mutants show no cross-resistance to other unrelated petite inducing drugs, including ethidium bromide, euflavine and 1-methyl phenyl neutral red.Further studies on the mutants revealed that each strain exhibits characteristic new properties indicative of changes in mitochondrial membrane functions concerned with the replication (and probably also repair) of mitochondrial DNA. Thus, mutant HR7 is hypersensitive to petite induction by the detergent sodium dodecyl sulphate under conditions where the parent J69-1B is unaffected by this agent. Mutant HR8 is even more sensitive to sodium dodecyl sulphate than is HR7, and additionally shows a markedly elevated spontaneous petite frequency. Isolated mitochondria from strains HR8 and HR10 (but not HR7) show resistance to the inhibitory effects of Hoe 15 030 on the replication of mitochondrial DNA in vitro.     

The conditions required for the induction of petite yeast mutants by fluorinated pyrimidines

Summary Newly magnified bobbed loci, combined with bb⁺ or bb^o loci, are in certain cases unstable. This may lead either to a reversion to the original bobbed mutation, or to lethal bobbed mutations. We name this instability modification. Modification occurs very early during the first divisions following fecondation of eggs, in embryos heterozygous for a magnified bobbed locus and a bb⁺ or bb^o locus. The phenomenon of modification is consistent with the model proposed by Ritossa (1972) to account for the phenomenom of magnification.     

Surrogate origins of replication in the mitochondrial genomes of ori-zero petite mutants of yeast.

We have investigated the mitochondrial genome of eight ori-zero spontaneous petite mutants of Saccharomyces cerevisiae. The tandem repeat units of these genomes do not contain any of the seven canonical ori sequences of the wild-type genome. Instead, they contain one, or more, ori-S sequences. These 44-nucleotide long surrogate origins of replication are a subset of GC clusters characterized by a potential secondary fold with two sequences ATAG and GGAG , inserted in AT spacers, two AT base pairs just following them, a GC stem (broken in the middle, and, in most cases also near the base, by non-paired nucleotides), and a terminal loop. This structure is reminiscent of that of GC clusters A and B from canonical ori sequences and supports the view (Bernardi, 1982a ) that the GC clusters of the mitochondrial genome arose, by an expansion process, from the canonical ori sequences. Like the latter, ori-S sequences are present in both orientations, are located in intergenic regions, and can be used as excision sequences when tandemly oriented. Again as in the case of canonical ori sequences, the density of ori-S sequences on the repeat units of petite genomes are correlated with the replication efficiency of the latter, as assessed by the outcome of crosses with wild-type or petite tester strains.     

Stimulation of cell division by membrane-active agents

Agents that decrease membrane stability (e.g. dimethyl sulfoxide, lysolecithin, sodium oleate, and short-chain alcohols) stimulate multinucleoid, serpentine filaments of Agmenellum quadruplicatum strains SN12 and SN29 to divide into cellular equivalents within approximately one generation time. Agents that increase membrane stability (e.g. long-chain alcohols) antagonize this timulation. Thus, the physical properties of the cell membrane appear to be involved in the regulation of cell division. These observations suggest that the invagination of the cell wall may be regulated by agents that interact with the plasma membrane and with enzymes involved in peptidoglycan synthesis.