CARDIOLIPIN CONTENT OF WILD TYPE AND MUTANT YEASTS IN RELATION TO MITOCHONDRIAL FUNCTION AND DEVELOPMENT

The phospholipid composition of various strains of the yeast, Saccharomyces cerevisiae, and several of their derived mitochondrial mutants grown under conditions designed to induce variations in the complement of mitochondrial membranes has been examined. Wild type and petite (cytoplasmic respiratory deficient) yeasts were fractionated into various subcellular fractions, which were monitored by electron microscopy and analyzed for cytochrome oxidase (in wild type) and phospholipid composition. 90% or more of the phospholipid, cardiolipin was found in the mitochondrial membranes of wild type and petite yeast. Cardiolipin content differed markedly under various growth conditions. Stationary yeast grown in glucose had better developed mitochondria and more cardiolipin than repressed log phase yeast. Aerobic yeast contained more cardiolipin than anaerobic yeast. Respiration-deficient cytoplasmic mitochondrial mutants, both suppressive and neutral, contained less cardiolipin than corresponding wild types. A chromosomal mutant lacking respiratory function had normal cardiolipin content. Log phase cells grown in galactose and lactate, which do not readily repress the development of mitochondrial membranes, contained as much cardiolipin as stationary phase cells grown in glucose. Cytoplasmic mitochondrial mutants respond to changes in the glucose concentration of the growth medium by variations in their cardiolipin content in the same way as wild type yeast does under similar growth conditions. It is concluded that cardiolipin content of yeast is correlated with, and is a good indicator of, the state of development of mitochondrial membrane.     

Size-separation of yeast mitochondria in the zonal centrifuge

Mitochondria, released from yeast spheroplasts and subjected to rate separation through sorbitol gradients in the zonal centrifuge, migrated in a wide symmetrical zone. Electron micrographs showed that the mitochondria had been resolved within the zone according to size. The mean mitochondrial diameter at the leading edge was approximately twice that at the trailing edge of the particle zone. Activities of the enzymes cytochrome oxidase, malate dehydrogenase, and reduced nicotinamide adenine dinucleotide- and d-lactate cytochrome c reductases were essentially uniform throughout the mitochondrial zone. Mitochondria from a vegetative-petite mutant had almost the same size distribution as the isogenic wild type, but with somewhat larger mean diameter and either absent or markedly reduced enzyme activities. Mixtures of wild-type and petite mitochondria produced sedimentation profiles showing overlap of particle populations with respect to mean sedimentation rates and mitochondrial diameters, as well as intermediate levels of enzyme activities. Both cristate and noncristate organelles were present throughout the mitochondrial zone from these mixtures. Mitochondria centrifuged in sorbitol density gradients were well-preserved and yielded consistent sedimentation profiles, whereas particles in sucrose density gradients migrated more slowly, produced varied sedimentation profiles, and often showed spurious peaks, presumably due to particle aggregations.     

Cytoplasmic inheritance in Saccharomyces cerevisiae: Comparison of zygotic mitochondrial inheritance patterns

Summary Mitochondrial movements in Saccharomyces cerevisiae (Sc) zygotes were monitored with phase-contrast microscopy and compared to known mitochondrial inheritance systems. The mitochondria of Sc were convincingly identified by integrated use of phase-contrast, cytochemical and electron microscopic observations. Mitochondria in Sc appear to move by saltatory jumps, which appear to be oriented towards movement of mitochondria into developing buds. Tracking of mitochondria of different genotypes was made possible by positive identification of each mitochondrial population before zygosis, and by the low degree of mixing (<10%) of mitochondrial populations before first bud septation.A grande by grande cross demonstrated equal numbers of mitochondria from each haploid moving into the first zygotic bud. A grande by neutral petite cross gave a 2:1 ratio of grande to petite mitochondria. However, a grande by suppressive petite cross gave equal numbers of grande and petite mitochondria. Using drug resistance systems, a comparison was made of highly biased (97%) and moderately biased (71%) chloramphenicol resistant inheritance patterns. In both cases, the ratios of drug resistant to sensitive mitochondria were 1:1. When numbers of mitochondria moving into an individual bud were compared to the phenotypic content of the clone of that bud, no model could be constructed which could predict the latter from the former. The data indicate (with the exception of the neutral petite by grande cross) that the numbers of each mitochondrial type inserted into the first zygotic bud are equal, regardless of the degree of asymmetry of inheritance of mitochondrial markers.     

Cytochrome c1 of bakers' yeast. II. Synthesis on cytoplasmic robosomes and influence of oxygen and heme on accumulation of the apoprotein.

In the preceding paper (Ross, E., and Schatz, G. (1976) J. Biol. Chem. 251, 1991-1996) yeast cytochrome c1 was characterized as a 31,000 dalton polypeptide with a covalently bound heme group. In order to determine the site of translation of this heme-carrying polypeptide, yeast cells were labeled with [H]leu(be under the following conditions: (a) in the absence of inhibitors, (b) in the presence of acriflavin (an inhibitor of mitochondrial translation), or (c) in the presence of cycloheximide (an inhibitor of cytoplasmic translation). The incorporation of radioactivity into the hemeprotein was measured by immunoprecipitating it from mitochondrial extracts and analyzing it by dodecyl sulfate-polyacrylamide gel electrophoresis. Label was incorporated into the cytochrome c1 apoprotein only in the presence of acriflavin or in the absence of inhibitor, but not in the presence of cycloheximide. Cytochrome c1 is thus a cytoplasmic translation product. This conclusion was further supported by the demonstration that a cytolasmic petite mutant lacking mitochondrial protein synthesis still contained holocytochrome c1 that was indistinguishable from cytochrome c1 of wild type yeast with respect to molecular weight, absorption spectru, the presence of a covalently bound heme group, and antigenic properties. Cytochrome c1 in the mitochondria of the cytoplasmic petite mutant is firmly bound to the membrane, and its concentration approaches that typical of wild type mitochondria. However, its lability to proteolysis appeared to be increased. A mitochondrial translation product may thus be necessary for the correct conformation or orientation of cytochrome c1 in the mitochondrial inner membrane. Accumulation of cytochrome c1 protein in mitochondria is dependent on the abailability of heme. This was shown with a delta-aminolevulinic acid synthetase-deficient yeast mutant which lacks heme and any light-absorbing peaks attributable to cytochromes. Mitochondria from mutant cells grown without added delta-aminolevulinic acid contained at least 20 times less protein immunoprecipitable by cytochrome c1-antisera than mitochondria from cells grown in the presence of the heme precursor. Similarly, the respiration-deficient promitochondria of anaerobically grown wild type cells are almost completely devoid of material cross-reacting with cytochrome c1-antisera. A 105,000 X g supernatant of aerobically grown wild type cells contains a 29,000 dalton polypeptide that is precipitated by cytochrome c1-antiserum but not by nonimmune serum. This polypeptide is also present in high speed supernatants from the heme-deficient mutant or from anaerobically gorwn wild type cells. The possible identity of this polypeptide with soluble apocytochrome c1 is being investigated.     

Nuclear fusion during yeast mating occurs by a three-step pathway

In Saccharomyces cerevisiae, mating culminates in nuclear fusion to produce a diploid zygote. Two models for nuclear fusion have been proposed: a one-step model in which the outer and inner nuclear membranes and the spindle pole bodies (SPBs) fuse simultaneously and a three-step model in which the three events occur separately. To differentiate between these models, we used electron tomography and time-lapse light microscopy of early stage wild-type zygotes. We observe two distinct SPBs in ~80% of zygotes that contain fused nuclei, whereas we only see fused or partially fused SPBs in zygotes in which the site of nuclear envelope (NE) fusion is already dilated. This demonstrates that SPB fusion occurs after NE fusion. Time-lapse microscopy of zygotes containing fluorescent protein tags that localize to either the NE lumen or the nucleoplasm demonstrates that outer membrane fusion precedes inner membrane fusion. We conclude that nuclear fusion occurs by a three-step pathway.     

Mutagenic action of hydrostatic pressure on yeast: a cell cycle analysis.

Pressure-treated log growth cultures (14,000 psi equivalent to 966 x 10(5) N/m2 for 4 h) of Saccharomyces cerevisiae were fractionated across a linear Ficoll gradient by zonal rotor centrifugation. This procedure separated the yeast cells on the basis of size and volume into a continuum of cell cycle ages. Cell survival and petite mutation frequency were determined for several zonal fractions. Survival of yeast cells after pressure treatment was maximal in zonal fractions obtained from either the top (single cells in G1) or the botton ("doublets") of the gradient. Intermediate zonal fractions showed more lethality, with minimal survival occurring in zonal fractions containing a large proportion of yeast cells in which buds were just beginning to emerge (initiation of S phase). The petite mutation frequency was minimal in zonal fractions from the top (single cells in G1) and bottom ("doublets") of the gradient. Induction increased to a maximum in those fractions containing cells in S phase.     

Mitochondrial Genetic Analysis by Zygote Cell Lineages in SACCHAROMYCES CEREVISIAE

Yeast strains were constructed carrying multiple mitochondrial markers conferring resistance to the inhibitors erythromycin, chloramphenicol, paromomycin and oligomycin. A pedigree analysis of two crosses was made by micromanipulating buds from zygotes. The first few daughter buds isolated from the zygotes sometimes gave rise to diploid clones which had a mixture of mitochondrial types. All possible classes of mitochondrial parental and recombinant types were found although they never appeared all together as the progeny from a single zygote. It was inferred that multiple recombination events took place in zygotes and in some of the buds derived from them. After removal of the first four or so daughter buds, subsequent buds from the zygote carried one mitochondrial type only. In cross I in which three markers were analyzed this was most frequently one of the parental types. In cross II (involving four mitochondrial markers) the later buds from the zygotes were frequently of recombinant mitochondrial type.     

Induction of the cytoplasmic 'petite' mutation by chemical and physical agents in Saccharomyces cerevisiae.

A range of physical and chemical agents induce the mitochondrial 'petite' mutation in the yeast Saccharomyces cerevisiae. DNA intercalating agents as well as chemicals which can interfere with DNA synthesis induce this mutation, but only in growing cells. Many chemical or physical agents that produce a DNA lesion which is not simply reversed can induce various levels of the petite mutation, and may be more effective in non-growing cells. A limited number of chemicals act like ethidium bromide, inducing a high frequency of petites which is partially reversible with increasing concentration or time. The ability of a specific compound to be transported into mitochondria or its affinity for AT base pairs in DNA may determine whether it acts primarily as a nuclear or mitochondrial mutagen. In mammalian cells, some neoplastic changes occur at the mitochondrial level. Analogies between yeast and mammalian mitochondria suggest that agents which increase petite mutagenesis in yeast may have some carcinogenic potential. Although some types of petite inducer may have potential as antitumour drugs, those which are very effective antimitochondrial agents appear to be too toxic for therapeutic use. A process comparable to early stages in petite mutagensis occurs in human degenerative diseases and it seems possible that a consequence of exposure to petite mutagens could be an increase in the rate of degenerative diseases or of the aging process.     

The effect of zygotic bud position on the transmission of mitochondrial genes in Saccharomyces cerevisiae.

Summary Segregation of mitochondrial genomes in yeast zygotes has been investigated by partial pedigree analysis of crosses involving the markers cap, ery, oli1 and par. The results demonstrate that the segregation pattern of markers is non-random during the first zygote generation and is directly related to slow mixing of the zygote cytoplasm. We have observed that a first bud may be formed at the center or either end of the dumbbell-shaped zygote. Cytoplasmic mixing is particularly slow in those zygotes producing first end buds.Clones derived from first end buds are usually pure (or nearly so) for a parental genotype and so detectable recombination of mitochondrial markers is reduced in these zygotes. Cells derived from a zygote after removal of a first end bud are predominantly of the other parental genotype. This observation suggests that a large fraction of the available segregating units enters each first bud and illustrates one means of obtaining complete segregation (even in multi-factor crosses) at the first generation. First center buds generally receive mitochondrial markers from both parents and the recombination frequency in such clones (and the clones derived from isolated first center buds) is significantly higher than in similar clones from zygotes with first end buds. Therefore, the distribution of first bud positions within a population of zygotes can influence the recombination frequency between mitochondrial loci. The delay in cytoplasmic mixing in combination with certain patterns of zygotic budding can distort the relationship between input of mitochondrial genomes and the output of a cross.The phage analogy model of yeast mitochondrial genetics has been re-examined in light of these data. The assumption of rapid panmixis is not supported by the data from any of the crosses analyzed here. Since panmixis is most closely approximated in zygotes with first center buds, crosses with predominantly zygotes of that type may be the ones where the model is most applicable.     

Selective loss of mitochondrial genome can be caused by certain unsaturated fatty acids

Various unsaturated fatty acids had different effectiveness for maintaining the continued replication of functional mitochondria in an unsaturated fatty acid auxotroph of Saccharomyces cerevisiae (KD115). Certain isomers of octadecenoic acid (i.e., cis-9) and eicosatrienoic acid (i.e.,cis-8,11,14) permitted continued replication of mitochondria and provided cultures that contained only 4 to 5% cells that formed petite colonies. On the other hand, cultures grown with cis-12- or cis-13-octadecenoic acid or cis-11,14,17-eicosatrienoic acid, produced a 12- to 16-fold greater frequency of petite mutants (50-60%) after 8 to 10 generations of growth. The production of the petite mutants occurred despite adequate incorporation of these unsaturated fatty acids into cellular phospholipids and an apparently normal ability to undergo the initial steps in the induction of cellular respiration. The evidence suggests that some cellular processes necessary for continued mitochondrial replication depend on the structural features of the fatty acyl chains as well as the overall content of unsaturated fatty acids in membrane phospholipids. Impairment of that process by certain inadequate fatty acids or by an inadequate supply of a suitable fatty acid leads to a permanent loss of the mitochondrial genome from the cells of subsequent generations.     

The cytology of the gametes and fertilization of Allomyces macrogynus

The gametes and the process of fertilization were examined by light and electron microscopy in the lower eukaryote Allomyces macrogynus. Differences in gamete morphology included the overall larger size and the presence of a larger nuclear apparatus, along with the association of a side-body complex and many more mitochondria in the female gamete. In this species of Allomyces, fertilization was initiated by contact and fusion of specialized regions of the gamete plasma membranes resulting in a binucleate fusion cell surrounded by plasma membrane contributed by both partners. Following plasmogamy, nuclear fusion was initiated by multiple nuclear membrane contacts between adjacent outer membranes. Following inner membrane fusion, small nucleoplasmic bridges were observed which presumably fused with one another and resulted in a single bridge which widened, forming the mature diploid nucleus. After karyogamy, fusion of the nuclear caps did not always occur and zygotes with and without fused caps were observed. Coalescence of the nucleoli completed the events of fertilization, forming a zygote with a single nuclear apparatus (sometimes with two caps) and two flagella. These observations are discussed in relation to fertilization mechanisms and compared to fertilization in other organisms.     

SELF-STERILE AND MATURATION-DEFECTIVE MUTANTS OF THE HOMOTHALLIC ALGA,CHLAMYDOMONAS MONOICA (CHLOROPHYCEAE).1

Homothallic sexual reproduction in Chlamydomonas monoica Strehlow culminated in the formation of mature, chloroform-resistant zygospores (zygotes) in clonal culture. Early in the zygote maturation process, a distinctive “primary zygote wall” was released into the culture medium where it remained stable for at least several days. This wall appeared as a rigid, darkly-outlined, and often multilayered structure, as viewed by phase contrast microscopy. From a sample, of 2500 individual clones isolated after ethyl methanesulfonate mutagenesis, five maturation-defective strains (zym) produced abnormal zygotes which failed to release a primary zygote wall, failed to develop the normal reticulate zygospore wall, and disintegrated within five days. These strains were utilized to identify additional mutants which were sexually competent, but self-sterile (het). Mixed cultures of the zym and het mutant strains were found to contain numerous, fully-matured, chloroform-resistant zygospores and discarded primary zygote walls. In combination, the two types of mutants provided a useful system for the selective recovery of heterozygous zygospores, thus facilitating genetic studies on a homothallic Chlamydomonas.     

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 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.     

Mitochondrial fusion in Chlamydomonas reinhardtii zygotes

Mitochondria are dynamic organelles that were found to fuse and divide in many different cell types. Mitochondrial fusion plays important roles in maintenance of respiratory capacity, dissipation of metabolic energy, and inheritance of mitochondrial DNA. While the molecular machinery of mitochondrial fusion has been characterized in great detail in yeast and mammals, only little is known about mitochondrial fusion in higher plants and algae. We asked whether mitochondrial fusion can be observed in the unicellular green alga Chlamydomonas reinhardtii. Mitochondria were stained with fluorescent dyes in gametes, and mixing of fluorescent markers was detected by fluorescence microscopy in zygotes indicating fusion. Mitochondrial fusion was observed in wild type zygotes, and also in respiratory mutants, albeit with less efficiency. We conclude that mitochondria readily fuse in green algae.     

THE PRESENCE OF CALLOSE IN THE PRIMARY ZYGOTE WALL OF CHLAMYDOMONAS MONOICA AND THE EFFECTS OF ITS DEGRADATION ON ZYGOTE DEVELOPMENT

Chlamydomonas monoica constructs a temporary primary wall around its developing zygotes. This study aimed to confirm callose as a component of the primary wall, as well as to note the effects of primary wall degradation on zygote development. Glucanase, specific for the β-1,3 glycosidic bonds comprising callose, was added to mating media at concentrations ranging from 5 to 1 mg ml⁻¹ and light microscope observations were made as the zygotes developed. The overall health of the zygotes was assessed by comparing their ability to germinate after exposure to chloroform vapors. The bright staining of the primary wall with aniline blue, specific for β-1,3 polysaccharides, suggested the presence of callose. This was further supported by the adverse effects of glucanase on zygote development. After mating, declining levels of intact zygotes were found as their maturation continued, and dead immature zygotes accumulated in the treated cultures. Twelve days after mating, when the zygotes were plated for germination, fully mature zygotes were identified in only the lowest of the six enzyme concentrations. In addition, germinating zygotes from the treated cultures showed increased sensitivity to killing by chloroform vapors relative to untreated zygotes. These results suggest that callose is a key component in the primary zygote wall, and that its degradation negatively affects zygote maturation. Electron microscopy will be used to help determine whether structural defects in the primary wall occur as a result of glucanase treatment, and whether such defects affect secondary zygospore wall assembly.     

Vegetative segregation of mitochondria in yeast: Estimating parameters using a random model

Summary Yeast zygotes which are heteroplasmic for mitochondrial genes reproduce vegetatively to form clones of diploid progeny which are homoplasmic. This vegetative segregation of mitochondrial genes has been interpreted in terms of a random distribution of mitochondria or mitochondrial genomes between mother and bud at cell division. We have developed equations which permit calculation of the number of segregating units in the zygote and the number of those units which enter the bud, assuming that segregation of the units is genetically random and numerically variable or equal. Use of the equations requires data from partial pedigree analyses: we isolate zygotes, separate the first bud, then determine the frequency of mitochondrial alleles among the progeny of mother cells whose first buds were homoplasmic. Application of this method to data from five crosses suggests that most zygotes have a small number of segregating units (usually less than a dozen) and only one or two enter the first bud. Analysis of the frequency of buds which are nearly but not quite homoplasmic indicates that the segregating units may be mitochondria or portions thereof which include many mitochondrial genomes, all the genomes in a unit being genetically identical in most but not all cases. These results are compatible with, but do not prove, the hypothesis of random vegetative segregation of mitochondria.     

The dynamic behaviour of mitochondria in living zygotes during maturation and meiosis in Chlamydomonas reinhardtii

To understand fully the function of mitochondria during the development of cells and organs, it is important to elucidate the dynamics of their morphology. However, the detailed morphology of mitochondria during meiosis has not yet been studied in algae. We examined the mitochondrial morphology of Chlamydomonas reinhardtii and classified zygotes into seven types by mitochondrial morphology in order to analyse the morphological change in mature and meiotic zygotes. We also investigated the oxygen consumption of living zygotes and the effects of tubulin and actin polymerization inhibitors on mitochondria, using fluorescence microscopy and oxygen electrodes. During zygote maturation, mitochondria fragmented into small particles, with a large decrease in oxygen consumption. When mature zygotes were exposed to light, mitochondria became tubular and formed a network, and oxygen consumption gradually recovered. At the same time, particle-like mitochondrial nucleoids became stringy and produced new nucleoid particles. Tubular mitochondria accumulated around the cell nucleus and then spread throughout the cell. Cell division followed (first and second rounds), and the resultant daughter cells had tubular mitochondria in a mesh-like arrangement. An inhibitor of tubulin polymerization, demecolcine, inhibited the assembly of mitochondria around the cell nucleus, whereas an inhibitor of actin polymerization, latrunculin B, inhibited the formation of tubular mitochondria. These results suggest that microtubules are probably involved in mitochondrial accumulation around the cell nucleus, whereas microfilaments may maintain the tubular network of mitochondria.     

Import of proteins into mitochondria. The precursor of cytochrome c1 is processed in two steps, one of them heme-dependent

The apoprotein of yeast cytochrome c1 is made outside the mitochondria as a larger precursor which is then processed in at least two steps. In the first step, it is transported across both mitochondrial membranes and converted by a matrix-localized protease to an intermediate form whose molecular weight is between that of the precursor and the mature form. The intermediate form is bound to the outer face of the inner membrane. This first step requires an energized mitochondrial inner membrane, but no heme. In the second step, the intermediate form is converted to the mature cytochrome. This second step requires heme; it is blocked in a heme-deficient mutant or in wild type cells treated with an inhibitor of heme synthesis. Import of cytochrome c1 into mitochondria thus proceeds via two distinct heme-free precursors and at least two maturation steps, one of them dependent on heme.     

Localization of a cruciform cutting endonuclease to yeast mitochondria

We have found a cruciform cutting endonuclease in the yeast, Saccharomyces cerevisiae, which localizes to the mitochondria. This activity apparently is associated with the mitochondrial inner membrane since the activity is not released into solution by osmolysis, in contrast to the matrix enzyme, isocitrate dehydrogenase. The cruciform cutting activity appears to be encoded by CCE1. This gene has been shown to encode one of the major cruciform cutting endonucleases present in a yeast cell. In ccel strains, which lack CCE1 endonuclease activity, the mitochondrial cruciform cutting endonucleolytic activity is also absent. Since CCE1 is allelic to MGT1, a gene required for the highly biased transmission of petite mitochondrial DNA in crosses between ⁺ and hypersuppressive ^– cells, it seems likely that the CCE1 endonuclease functions within mitochondria.