Fine structure of the 21S ribosomal RNA region on yeast mitochondrial DNA. II. The organization of sequences in petite mitochondrial DNAs carrying genetic markers from the 21S region.

We have investigated the organization of sequences in ten rho- petite mtDNAs by restriction enzyme analysis and electron microscopy. From the comparison of the physical maps of the petite mtDNAs with the physical map of the mtDNA of the parental rho+ strain we conclude that there are at least three different classes of petite mtDNAs: I. Head-to-tail repeats of an (almost) continuous segment of the rho+ mtDNA. II. Head-to-tail repeats of an (almost) continuous segment of the rho+ mtDNA with a terminal inverted duplication. III. Mixed repeats of an (almost) continuous rho+ mtDNA segment. In out petite mtDNAs of the second type, the inverted duplications do not cover the entire conserved rho+ mtDNA segment. We have found that the petite mtDNAs of the third type contain a local inverted duplication at the site where repeating units can insert in two orientations. At least in one case this local inverted duplication must have arisen by mutation. The rearrangements that we have found in the petite mtDNAs do not cluster at specific sites on the rho+ mtDNA map. Large rearrangements or deletions within the conserved rho+ mtDNA segment seem to contribute to the suppressiveness of a petite strain. There is also a positive correlation between the retention of certain segments of the rho+ mtDNA and the suppressiveness of a petite strain. We found no correlation between the suppressiveness of a petite strain and its genetic complexity. The relevance of these findings for the mechanism of petite induction and the usefulness of petite strains for the physical mapping of mitochondrial genetic markers and for DNA sequence analysis are discussed.     

Biogenesis of mitochondria: XXV. Studies on the mitochondrial genomes of petite mutants of yeast using ethidium bromide as a probe

This paper describes investigations into the effects of ethidium bromide on the mitochondrial genomes of a number of different petite mutants derived from one respiratory competent strain of Saccharomyces cerevisiae. It is shown that the mutagenic effects of ethidium bromide on petite mutants occur by a similar mechanism to that previously reported for the action of this dye on grande cells. The consequences of ethidium bromide action in both cases are inhibition of the replication of mitochondrial DNA, fragmentation of pre-existing mitochondrial DNA, and the induction, often in high frequency, of cells devoid of mitochondrial genetic information (ρ ° cells).The susceptibility of the mitochondrial genomes to these effects of ethidium bromide varies in the different clones studied. The inhibition of mitochondrial DNA replication requires higher concentrations of ethidium bromide in petite cells than in the parent grande strain. Furthermore, the susceptibility of mitochondrial DNA replication to inhibition by ethidium bromide varies in different petite clones.It is found that during ethidium bromide treatment of the suppressive petite clones, the over-all suppressiveness of the cultures is reduced in parallel with the reduction in the over-all cellular levels of mitochondrial DNA. Furthermore, ethidium bromide treatment of petite clones carrying mitochondrial erythromycin resistance genes (ρ^?ER^r) leads to the elimination of these genes from the cultures. The rates of elimination of these genes are different in two ρ^?ER^r clones, and in both the gene elimination rate is slower than in the parent ρ⁺ ER^r strain. It is proposed that the rate of elimination of erythromycin resistance genes by ethidium bromide is related to the absolute number of copies of these genes in different cell types. In general, the more copies of the gene in the starting cells, the slower is the rate of elimination by ethidium bromide. These concepts lead us to suggest that petite mutants provide a system for the biological purification of particular regions of yeast mitochondrial DNA and of particular relevance is the possible purification of erythromycin resistance genes.     

Elevated Levels of Petite Formation in Strains of SACCHAROMYCES CEREVISIAE Restored to Respiratory Competence. I. Association of Both High and Moderate Frequencies of Petite Mutant Formation with the Presence of Aberrant Mitochondrial DNA

When recently arisen spontaneous petite mutants of Saccharomyces cerevisiae are crossed, respiratory competent diploids can be recovered. Such restored strains can be divided into two groups having sectored or unsectored colony morphology, the former being due to an elevated level of spontaneous petite mutation. On the basis of petite frequency, the sectored strains can be subdivided into those with a moderate frequency (5–16%) and those with a high frequency (>60%) of petite formation. Each of the three categories of restored strains can be found on crossing two petites, suggesting either that the parental mutants contain a heterogeneous population of deleted mtDNAs at the time of mating or that different interactions can occur between the defective molecules. Restriction endonuclease analysis of mtDNA from restored strains that have a wild-type petite frequency showed that they had recovered a wild-type mtDNA fragmentation pattern. Conversely, all examined cultures from both categories of sectored strains contained aberrant mitochondrial genomes that were perpetuated without change over at least 200 generations. In addition, sectored colony siblings can have different aberrant mtDNAs. The finding that two sectored, restored strains from different crosses have identical but aberrant mtDNAs provides evidence for preferred deletion sites from the mitochondrial genome. Although it appears that mtDNAs from sectored strains invariably contain duplications, there is no apparent correlation between the size of the duplication and spontaneous petite frequency.     

Mitochondrial genetics

Summary Cytoplasmic petite mutants of Saccharomyces cerevisiae carrying the gene conferring the resistance to chloramphenicol on one hand and the gene conferring the resistance to erythromycin on the other, have been crossed with each other. The two types of petites differed in the buoyant densities of their mitochondrial DNA. A novel type of evidence has been adduced, that the two genes are indeed located on mitochondrial DNA. Diploid petite recombinants were found, carrying both genes and containing not a mixture of the two parental DNAs but a new species of mitochondrial DNA of intermediate buoyant density. Recombination of mitochondrial genes involves therefore breakage and reunion of DNA molecules. New suppressiveness, different from the two parental ones, can result from the recombination of mitochondrial DNA. Recombination between petite mutants implies that the mitochondrial recombination enzymes have to be synthesized on cytosol ribosomes.     

Mitochondrial DNA and suppressiveness of petite mutants in Saccharomyces cerevisiae

Ethidium bromide is known to be a powerful mutagen for the induction of cytoplasmically inherited petite mutations in yeast. The effect of ethidium bromide on the degree of suppressiveness of the induced mutants as a function of exposure time is described. The mitochondrial DNA of 20 ethidium bromide-induced petite mutants has been studied to determine its absence or presence and its buoyant density. Ten mutants, in which we were not able to detect any mitochondrial DNA, were neutral petites. The 10 remaining mutants with mitochondrial DNA simultaneously showed a measurable degree of suppressiveness. It was not possible to correlate the buoyant density of the mutant mitochondrial DNA with the degree of suppressiveness.This study was supported in part by USPHS grant GM 10017. G.M. received a Fulbright Travel Grant.     

Replication and preferential inheritance of hypersuppressive petite mitochondrial DNA

Wild-type yeast mitochondrial DNA (mtDNA) is inherited biparentally, whereas mtDNA of hypersuppressive petite mutants is inherited uniparentally in crosses to strains with wild-type mtDNA. Genomes of hypersuppressive petites contain a conserved ori sequence that includes a promoter, but it is unclear whether the ori confers a segregation or replication advantage. Fluorescent in situ hybridization analysis of wild-type and petite mtDNAs in crosses reveals no preferential segregation of hypersuppressive petite mtDNA to first zygotic buds. We identify single-stranded DNA circles and RNA-primed DNA replication intermediates in hypersuppressive petite mtDNA that are absent from non-hypersuppressive petites. Mutating the promoter blocks hypersuppressiveness in crosses to wild-type strains and eliminates the distinctive replication intermediates. We propose that promoter-dependent RNA-primed replication accounts for the uniparental inheritance of hypersuppressive petite mtDNA.     

Induction of ϱ− mutants in Saccharomyces cerevisiae by guanidine hydrochloride: I. Genetic analysis

Guanidine hydrochloride (GuHCl) induced in Saccharomyces cerevisiae cytoplasmic petite mutants (ϱ⁻) of the suppressive type. However, it was unable to induce the neutral type, even after prolonged incubation or increased drug concentration. No correlation was found between the degree of suppressiveness and the time of incubation of yeast cells with guanidine hydrochloride. The suppressiveness of ϱ⁻ induced was not altered by further treatment with GuHCl, whereas it was reduced upon treatment with ethidium bromide (EtBr). Some mitochondrial genetic information was lacking in the ϱ⁻ mutants induced by GuHCl, as demonstrated by the loss of the gene for erythromycin resistance and by reduced buoyant density of mitochondrial DNA of some ϱ⁻. There was no correlation between the degree of suppressiveness of the ϱ⁻ induced by GuHCl and the bouyant density of the mutant mitochondrial DNA.     

Germination of Yeast Spores Lacking Mitochondrial Deoxyribonucleic Acid

A population of petite ascospores (mitochondrial deoxyribonucleic acid [mtDNA]-less), produced by brief ethidium bromide (EthBr) mutagenesis prior to transfer to sporulation medium, was used to examine the role of the mitochondrial genetic system on germination and outgrowth in Saccharomyces cerevisiae. Petite ascospores, which are morphologically indistinguishable by phase-contrast microscopy from wild-type spores, germinate and proceed through outgrowth at a rate and extent only slightly less than that of wild-type spores. Both developmental processes occurred in the absence of mtDNA synthesis and measurable cytochrome oxidase activity. These results indicate that neither respiration nor a functional mitochondrial genome are required for germination and outgrowth. The properties of the petite clones were typical of petites formed during vegetative growth. Individual sporal clones differed markedly from each other in suppressiveness. Petite sporal clones which exhibited a high degree of supressiveness also contained a reduced but detectable amount of mtDNA of altered buoyant density. One clone contained a unique mtDNA with a buoyant density higher than that of wild-type mtDNA.     

Physicochemical characterization of mitochondrial DNA from soybean

Mitochondrial DNA (mtDNA) of soybean (Glycine max L.) was isolated and its buoyant density was contrasted with that of nuclear (nDNA) and chloroplast (ctDNA) DNA. Each of the three DNAs banded at a single, characteristic buoyant density when centrifuged to equilibrium in a CsCl gradient. Buoyant densities were 1.694 g/cm³ for nDNA and 1.706 g/cm³ for mtDNA. These values correspond to G-C contents of 34.7 and 46.9%, respectively. Covalently closed, circular mtDNA molecules were isolated from soybean hypocotyls by ethidium bromide-cesium chloride density gradient centrifugation. Considerable variation in mtDNA circle size was observed by electron microscopy. There were seven apparent size classes with mean lengths of 5.9 μm (class 1), 10 μm (class 2), 12.9 μm (class 3), 16.6 μm (class 4), 20.4 μm (class 5), 24.5 μm (class 6), and 29.9 μm (class 7). In addition, minicircles were observed in all preparations. Partially denatured, circular mtDNA molecules with at least one representative from six of the seven observed size classes were mapped. In class 4, there appear to be at least three distinct denaturation patterns, indicating heterogeneity within this class. It is proposed that the mitochondrial genome of soybean is distributed among the different size circular molecules, several copies of the genome are contained within these classes and that the majority of the various size molecules may be a result of recombination events between circular molecules.     

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 oril 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.     

Mechanism of Mitochondrial Mutation in Yeast

THE yeast Saccharomyces cerevisiae can mutate to the respiratory-incompetent petite colony form. The mutation is probably caused by damage to, or loss of, the yeast's mitochondrial DNA, for petite mutants often lack mitochondrial DNA, possess it in abnormal amounts or with abnormal buoyant density¹. Some of the agents, such as acrifiavine or ethidium bromide, which induce the petite mutation interfere with mitochondrial DNA synthesis^2,3 whereas ethidium bromide also causes or permits degradation of Saccharomyces cerevisiae mitochondrial DNA^2,3. We have observed that nalidixate (50 µg/ml.), an inhibitor of DNA synthesis, can prevent or delay petite mutation induced by ethidium bromide⁴. A similar effect has been observed by Hollenberg and Borst using a higher nalidixate concentration⁵. We have investigated the mechanism of this effect. A diploid prototrophic strain of Saccharomyces cerevisiae (NCYC 239) was used throughout.     

Maintenance and Integrity of the Mitochondrial Genome: a Plethora of Nuclear Genes in the Budding Yeast

Instability of the mitochondrial genome (mtDNA) is a general problem from yeasts to humans. However, its genetic control is not well documented except in the yeast Saccharomyces cerevisiae. From the discovery, 50 years ago, of the petite mutants by Ephrussi and his coworkers, it has been shown that more than 100 nuclear genes directly or indirectly influence the fate of the rho⁺ mtDNA. It is not surprising that mutations in genes involved in mtDNA metabolism (replication, repair, and recombination) can cause a complete loss of mtDNA (rho⁰ petites) and/or lead to truncated forms (rho⁻) of this genome. However, most loss-of-function mutations which increase yeast mtDNA instability act indirectly: they lie in genes controlling functions as diverse as mitochondrial translation, ATP synthase, iron homeostasis, fatty acid metabolism, mitochondrial morphology, and so on. In a few cases it has been shown that gene overexpression increases the levels of petite mutants. Mutations in other genes are lethal in the absence of a functional mtDNA and thus convert this petite-positive yeast into a petite-negative form: petite cells cannot be recovered in these genetic contexts. Most of the data are explained if one assumes that the maintenance of the rho⁺ genome depends on a centromere-like structure dispensable for the maintenance of rho⁻ mtDNA and/or the function of mitochondrially encoded ATP synthase subunits, especially ATP6. In fact, the real challenge for the next 50 years will be to assemble the pieces of this puzzle by using yeast and to use complementary models, especially in strict aerobes.     

Abnormal Mitochondrial Genomes in Yeast Restored to Respiratory Competence

When crosses are performed between newly arisen, spontaneous petite mutants of Saccharomyces cerevisiae, respiratory competent (restored) colonies can form. Some of the restored colonies are highly sectored and produce large numbers of petite mutants. The high-frequency petite formation trait is inherited in a non-Mendelian manner, and elimination of mitochondrial DNA from these strains results in the loss of the trait. These results indicate that abnormal mitochondrial genomes are sometimes formed during restoration of respiratory competence. It is hypothesized that these abnormalities result either from recombination between mitochondrial DNA fragments to produce molecules having partial duplications contained on inverted or transposed sequences, or else recombinational "hot spots" have been expanded.     

Physical and genetic organization of Petite and Grande yeast mitochondrial DNA. II. DNA-DNA hybridization studies and buoyant density determinations

Buoyant density of mitochondrial DNA from 14 cytoplasmic petite mutants issued from the same grande yeast Saccharomyces cerevisiae was determined. Mutants that have retained the mitochondrial gene conferring resistance to erythromycin displayed higher buoyant density, while mutants that have retained the mitochondrial gene conferring resistance to chloramphenicol displayed lower buoyant density. It is inferred that the segment which carries the E^R gene has a higher G + C content than the segment which carries the C^R gene. DNA-DNA filter hybridizations were carried out systematically in different reciprocal pair-wise combinations between mtDNAs purified from various mutants and from the grande. All petites were found to be deleted in 42 to 93% of the grande sequence, depending on the mutant studied. Sequence homology between petite mtDNAs was greatest in mutants retaining common genetic markers and was least when different genetic markers were retained. Practically no hybridization was found between some C^RE^O and C^OE^R mutants. Correlations established between the extent of DNA-DNA hybridization, kinetic and genetic complexity show that a selective enrichment of gene specific sequences occurs in mtDNA of petites.     

Incompatibility of linear DNA killer plasmids pGKL1 and pGKL2 from Kluyveromyces lactis with mitochondrial DNA from Saccharomyces cerevisiae.

Two linear killer plasmids (pGKL1 and pGKL2) from Kluyveromyces lactis stably replicated and expressed the killer phenotype in a neutral petite mutant [( rho0]) of Saccharomyces cerevisiae. However, when cytoplasmic components were introduced by cytoduction from a wild-type [( rho+]) strain of S. cerevisiae, the linear plasmids became unstable and were frequently lost from the cytoductant cells during mitosis, giving rise to nonkiller clones. The phenomenon was ascribed to the incompatibility with the introduced S. cerevisiae mitochondrial DNA (mtDNA), because the plasmid stability was restored by [rho0] mutations in the cytoductant cells. Incompatibility with mtDNA was also apparent for the transmission of plasmids into diploid progeny in crosses between killer cells carrying the pGKL plasmids and [rho+] nonkiller cells lacking the plasmids. High-frequency transmission of the plasmids was observed in crosses lacking mtDNA [( rho0] by [rho0] crosses) and in crosses involving mutated mtDNA with large deletions of various regions of mitochondrial genome. In contrast, mutated mtDNA from various mit- mutations also exerted the incompatibility effect on the transmission of plasmids. Double-stranded RNA killer plasmids were stably maintained and transmitted in the presence of wild-type mtDNA and stably coexisted with pGKL killer plasmids in [rho0] cells of S. cerevisiae.     

Mitochondrial genetics in perspective: the derivation of a genetic and physical map of the yeast mitochondrial genome.

The attainment of the map of functions coded in the yeast mitochondrial genome represents the end of an era of development in mitochondrial genetics. Following the earliest genetic studies, where first the respiration-deficient petite mutants, then subsequently the other types of mitochondrial mutants, were characterized, it was realized that a genetic approach to the questions of mitochondrial biogenesis and the genetic function of mtDNA would yield much useful information. A period of intensive investigation into the behavior of mitochondrial genes in genetic crosses followed, and it was concluded that the purely genetic techniques of transmissional and recombinational analysis could not yield a map of the genetic loci, although basic rules for mitochondrial genetic manipulation were established. The concurrent studies of the nature of the deletions in petite mtDNA led to the recognition that an analysis of the behavior of genetic loci in petite mutants would provide the method for genetically mapping the positions of loci in mtDNA where conventional genetic crosses between grande strains had failed. This thesis was first confirmed by our studies of the frequencies of coretention and loss of individual loci in large populations of petite isolates, which produced the first circular genetic map of drug resistance loci on mtDNA. Subsequent to this genetic mapping phase, we established a general procedure for determining the physical map position of any mitochondrial genetic locus or mtDNA sequence by introducing the use of a molecular library of petite mutants carrying physically and genetically defined segments of mtDNA. These petites can be tested for the retention or loss of genetic loci or particular nucleotide sequences. This general solution to the mapping problem and the physical map of the Saccharomyces cerevisiae mitochondrial genome obtained, which has been confirmed by studies using restriction enzymes, has provided the field with a molecular point of reference for the many current genetic and biochemical investigations into the structure and function of mtDNA in yeast.     

The mitochondrial genome of wild-type yeast cells. VII. Recombination in crosses.

Two Saccharomyces cerevisiae wild-type strains were crossed, and 26 diploid clones were obtained from (1) mass mating; (2) individual buds in zygote lineages; (3) individual zygotes. The mitochondrial DNAs from these diploids were investigated in their recombination and segregation by analyzing their restriction fragment patterns.Recombinant mitochondrial genomes were present in 75% of the diploid clones. Such recombinant genomes had unit sizes different from, yet within ± 5% of, the parental ones and showed EcoRI and HindII + III fragment patterns of parental types, two strong indications that both the gene complement and the gene order were very largely preserved in the progeny.Fragment patterns produced by HpaII and HaeIII were characterized by (1) fragments originating from the DNAs of both parents; and (2) new fragments, namely fragments absent in either parent. The new fragments appear to arise from unequal crossing-over events occurring in the spacers of allelic parental genetic units and usually have preferential localizations in the genome.These results provide the first evidence for physical recombinations of mitochondrial DNA in crosses of wild-type yeast cells, indicate that recombination is very frequent in crosses, and shed some light on mitochondrial segregation. They also have interesting implications for recombination phenomena in interspersed systems of unique and repetitive nucleotide sequences.     

Transformation of Saccharomyces cerevisiae with yeast mitochondrial DNA linked to two micron circular yeast plasmid

Mitochondrial DNA from a petite mutant of yeast carrying an oligomycin resistance determinant has been ligated in vitro to 2 μm yeast plasmid DNA. The recombinant DNA so produced has been used to transform an oligomycin sensitive strain of Saccharomyces cerevisiae to oligomycin resistance at a frequency approaching 50 times the spontaneous mutation rate to oligomycin resistance. The majority of transformants showed genetic properties suggesting that recombination between the transforming DNA and the resident mtDNA has occurred. The properties of a subclass of oligomycin resistance transformants suggested that in these cells the transforming DNA has not become stably integrated into the mitochondrial genome of the recipient cell.     

The transmission disadvantage of yeast mitochondrial intergenic mutants is eliminated in the mgt1 (cce1) background.

A trans-acting element, MGT1 (also called CCE1), has previously been shown to be required in Saccharomyces cerevisiae for the preferential transmission of petite mitochondrial DNA (mtDNA) molecules over wild-type mtDNA molecules. In the present study a possible role of this nuclear gene in the transmission of mtDNA from various respiration-competent mutants was studied. Several of these mutants, lacking one or the other of two biologically active mitochondrial intergenic sequences, were employed in genetic crosses. When these deletion mutants were crossed to the parental wild-type strain in the MGT1/CCE1 background, the progeny contained predominantly wild-type mtDNA molecules. When crosses were performed in the mgt1/cce1 background, the parental molecules interacted in zygotes and underwent homologous recombination but wild-type and intergenic-deletion alleles were transmitted with equal frequencies.