Biogenesis of mitochondria 44

Summary A comparative study of eight independently isolated mitochondrial oligomycin resistant mutants obtained from three laboratories show a variety of phenotypes based on cross resistance to venturicidin and sensitivity to low temperature. Analysis of recombination between pairs of markers indicate the existence of at least three genetic classes; class A, cross resistant to venturicidin and including the mutations O III, [oli1-r], [OLG1-R], [tso-r]; class B, mutations O _I, [oli17-r], [OLG2-R]; and class C, the mutation O _II. The recombination data is consistent with mutations of each class residing in three separate genes, although mutations of class A and B show very close linkage.Recombination in non-polar crosses has demonstrated that markers of all three classes are linked to the mik1 locus in the configuration (AB)-mik1-C. The mapping of this segment with respect to other markers of the mitochondrial genome and the order of classes A and B was established by analyses of co-retention frequencies of markers in primary petite isolates as well as by analysis of marker overlap of genetically and physically defined petite genomes. The unambiguous order ery1-A-B-mik1-C-par was obtained. DNA-DNA hybridization studies using mtDNA isolated from selected petites confirms this map and estimates the physical separation of markers. A reasonable correlation exists in this region of the genome between distances estimated physically by hybridization and genetically by frequency of recombination in non-polar crosses.It is postulated that the oligomycin-mikamycin linkage group represents a cluster of genes involved in determining a number of mitochondrial membrane proteins associated with the mitochondrial ATPase and respiratory complex III.This work was supported by the Australian Research Grants Committee, Project D65/15930     

Biogenesis of mitochondria 34

Summary Mutants of the yeast Saccharomyces cerevisiae have been isolated in this laboratory which show increased resistance to a number of structurally and functionally unrelated antibiotics such as mikamycin, chloramphenicol, oligomycin and tetracycline (Bunn et al., 3971). When a multiply resistant haploid strain was crossed to an antibiotic sensitive strain, the resultant diploid progeny were completely resistant to chloramphenicol and oligomycin. However, the progeny showed different responses to mikamycin depending upon the concentration of antibiotic, all showed resistance to 25 g/ml but only about half were resistant to high levels of mikamycin (>100 g/ml). Detailed genetic analyses has shown that resistance to high levels of mikamycin is the result of a phenotypic interaction between two mutations, one nuclear and the other mitochondrial. The nuclear mutation by itself confers resistance to a number of antibiotics including chloramphenicol, oligomycin and mikamycin at a level of 25 g/ml. The mitochondrial mutation increases cellular resistance to mikamycin from 3 g/ml to about 8 g/ml. When the two mutations occur together in a cell, resistance to mikamycin is increased to at least 800 g/ml, the limit of solubility. Thus, the phenotypie interaction between these two mutations is not additive but synergistic.When cells containing the cytoplasmic [mik1-r] mutation are treated with ethidium bromide to produce ^° cells (no mtDNA), the [mik1-r] determinant is lost, indicating that this mutation is located in the mitochondrial DNA. Recombination analyses with other mitochondrial markers indicates a marker order of [oli1-r mik1-r ery1-r] with [mik1-r] showing tighter linkage to the [oli1-r] marker.     

Biogenesis of Mitochondria: Analysis of Deletion of Mitochondrial Antibiotic Resistance Markers in Petite Mutants of Saccharomyces cerevisiae

Yeast strains carrying markers in several mitochondrial antibiotic resistance loci have been employed in a study of the retention and deletion of mitochondrial genes in cytoplasmic petite mutants. An assessment is made of the results in terms of the probable arrangement and linkage of mitochondrial genetic markers. The results are indicative of the retention of continuous stretches of the mitochondrial genome in most petite mutants, and it is therefore possible to propose a gene order based on co-retention of different markers. The order par, mik1, oli1 is suggested from the petite studies in the case of three markers not previously assigned an unambiguous order by analysis of mitochondrial gene recombination. The frequency of separation of markers by deletion in petites was of an order similar to that obtained by recombination in polar crosses, except in the case of the ery1 and cap1 loci, which were rarely separated in petite mutants. The deletion or retention of the locus determining polarity of recombination (ω) was also demonstrated and shown to coincide with deletion or retention of the ery1, cap1 region of the mitochondrial genome. Petites retaining this region, when crossed with rho⁺ strains, display features of polarity of recombination and transmission similar to the parent rho⁺ strain. By contrast a petite determined to have lost the ω⁺ locus did not show normal polarity of marker transmission. Differences were observed in the relative frequency of retention of markers in a number of strains and also when comparing petites derived spontaneously with those obtained after ultraviolet light mutagenesis. By contrast, a similar pattern of marker retention was seen when comparing spontaneous with ethidium bromide-induced petites.     

Effect of auxotrophic starvation on mitochondrial marker transmission in the cdc8 mutant of Saccharomyces cerevisiae

Summary Crosses were made using strains of S. cerevisiae which carried mitochondrial markers conferring resistance to erythromycin and chloramphenicol. The effect of auxotrophic starvation of one parent prior to mating on the transmission of its mitochondrial markers was studied in different crosses relative to the presence of the cdc8 nuclear mutation (a temperature-sensitive DNA replication).In crosses between two cdc8 mutant strains, auxotrophic starvation of one of the haploid parental strains prior to mating caused a marked decrease of its mitochondrial marker transmission to the diploid progeny of the cross. The transmission decreased as a function of the time of starvation. This effect was not observed in the cross between two wild type strains and in crosses of starved cdc8 phenotypic revertants with cdc8 mutant strains. Only a small, if any, effect of starvation on mitochonrial marker transmission was observed when starved cdc8 mutant strains were crossed either with their phenotypic revettants or with the wild-type strains.In one of the haploid parental strains the starvation increased the frequency of petites as a function of starvation time, while in the other this effect was not observed.In the progeny of cdc8xcdc8 crosses (both in starvation experiments and in control crosses) an increased frequency of diploid petite cells accompanied by a decreased frequency of recombination between mitochondrial markers was noticed.The influence of the cdc8 mutation on the transmission of mitochondrial markers is discussed in terms of high frequency of ^– molecule formation in cdc8 strains.     

The bivious suppressiveness of cytoplasmic petites of S. cerevisiae lacking in mitochondrial DNA

Summary When crossed to strain GR25 [rho+], petites lacking in mtDNA were neutral, but when crossed to a related [rho+] strain (GR25a) they were found to be suppressive (Table 1). Likewise, crosses of GR25 [rho+] and GR25a [rho+] to a common [rho+] parent were, respectively, neutral and suppressive (Table 1). The suppressive phenotype observed in these crosses was attributed to a factor in the [rho+] strain GR25a. Strain GR25a also differed from strain GR25 in having a decreased [rho+] stability (Table 2) and a decreased transmission of its cytoplasmically-inherited erythromycin-resistance marker to zygote progeny (Table 4). These three phenotypes of GR25a are, discussed in terms of a nuclear mutation in a gene responsible for the maintenance of the [rho+] state.     

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.     

Assembly of the mitochondrial membrane system: mutations in the pho2 locus of the mitochondrial genome of Saccharomyces cerevisiae.

Two mutants of Saccharomyces cerevisiae which show a loss of mitochondrial rutamycin-sensitive ATPase activity are described. Although phenotypically similar to mutants of the mitochondrial locus pho1 [F. Foury and A. Tzagoloff (1976) Eur. J. Biochem. 68, 113-119], these mutants define a second ATPase locus on the mitochondrial DNA (designated pho2), which is genetically unlinked to pho1. Analysis of recombination in crosses involving multiple antibiotic resistance markers indicates that the locus is in the segment of the genome between ery1 and oli2, very close to oli1. In fact it is proposed that the oli1 and pho2 mutations are in the same gene. Supporting evidence for this proposal includes: 1. The analysis of marker retention in petite mutants shows that the oli1 and pho2 loci were either retained or lost together in all cases. 2. Recombination frequencies of 0.05% or less are observed in crosses between the oli1 and pho2 loci. 3. When rho+ revertants are isolated from the pho2 mutants they frequently are oligomycin resistant. 4. pho2 mutants have an altered subunit 9 of the ATPase complex.     

Mitochondrial mutants of the yeast Saccharomyces cerevisiae showing resistance in vitro to chloramphenicol inhibition of mitochondrial protein synthesis

Two cytoplasmic genetic mutants of yeast, genetically separable by recombination, displaying high levels of chloramphenicol resistance have been isolated. Protein synthesis in isolated mitochondria of mutant [$\text{cap 2-r}$] is almost completely resistant to chloramphenicol inhibition while that in mitochondria of mutant [$\text{cap 1-r}$] is partially resistant. Biochemical differences between the two mutants were confirmed by studies of chloramphenicol inhibition of aerobic adaptation of anaerobically grown cells. The mutants appear to contain altered mitochondrial ribosomes.     

Mitochondrial recombination in crosses of iso- and anisomitochondrial saccharomyces cerevisiae

Summary Mitochondrial mutants resistant to erythromycin, neomycin and monomycin were isolated. Mitochondria were transmitted from different natural strains to the cells of the same nuclear genotype. In bifactorial crosses of such isochromosomal and anisomitochondrial yeasts we tested random samples of diploid colonies. The distribution of mitochondrial markers in parent and recombinant classes has been shown to occur unequally. The asymmetry of parent and the polarity of recombinant classes were observed to differ in different mitochondrial mutants.Anisomitochondrial strain crosses proved that mitochondrial origin essentially influenced both the parent and recombinant classes distribution and the susceptibility of the transmission to the effect of mating type locus. One can distinguish between homo- and heterosexual cross combinations in terms of recombination polarity.The new type of mitochondria was found to occur with high frequency of transmission to the zygote progeny of markers resistant to erythromycin but not of markers resistant to neomycin. The problem of sex in mitochondria is discussed.     

Biogenesis of mitochondria 49 identification and mapping of a new mitochondrial locus (tsr1) which maps within polar region of yeast mitochondrial genome.

Summary An enrichment procedure which facilitates the isolation of conditional respiratory-deficient mutants of Saccharomyces cerevisiae is reported. Detailed genetic analysis of one mutant which exhibits a respiratory deficient phenotype at low temperature (18°C) is also presented. The phenotype is due to a single lesion at a new locus, tsr1, located on the mitochondrial DNA. By analysis of locus retention patterns in a set of physically characterized petite strains, the tsr1 mutation has been mapped within the segment 0–5 map units on the physical map of the yeast mitochondrial genome. This segment of the mitochondrial DNA also contains the cap1 and ery1 loci and the cistron for the mitochondrial 21S rRNA. Studies of the frequencies of co-retention of markers in petite populations, and of the frequencies of recombination of markers in non-polar crosses (⁺ × ⁺), demonstrate linkage of the tsr1 locus to both the cap1 and ery1 loci. The degree of linkage indicates that tsr1 is closer to the ery1 locus. Comparison of pairwise recombination frequencies for these three markers indicate the order cap1-tsr1-ery1. The tsr1 locus lies within the segment of the mitochondrial genome which is influenced by the polarity locus , and analysis of transmission and recombination frequencies and polarities in a polar (⁺ × ^-) cross show that the behaviour of the tsr1 locus is similar to that of ery1. However striking features of this cross are that the recombination frequency between tsr1 and ery1 is comparable to that observed in non-polar crosses, and that the polarity for recombination between tsr1 and cap1 or ery1 is extremely low.     

Genetic mapping of mitochondrial markers by recombinational analysis in Chlamydomonas reinhardtii

The mitochondrial genome of Chlamydomonas reinhardtii is a 15.8 kb linear DNA molecule present in multiple copies. In crosses, the meiotic products only inherit the mitochondrial genome of the mating type minus (paternal) parent. In contrast mitotic zygotes transmit maternal and paternal mitochondrial DNA copies to their diploid progeny and recombinational events between molecules of both origins frequently occur. Six mitochondrial mutants unable to grow in the dark (dk^– mutants) were crossed in various combinations and the percentages of wild-type dk⁺ recombinants were determined in mitotic zygotes when all progeny cells had become homoplasmic for the mitochondrial genome. In crosses between strains mutated in the COB (apocytochrome ) gene and strains mutated in the COX1 (subunit 1 of cytochrome oxidase) gene, the frequency of recombination was 13.7% (± 3.2%). The corresponding physical distance between the mutation sites was 4.3 kb. In crosses between strains carrying mutations separated by about 20 bp, a recombinational frequency of 0.04% (± 0.02%) was found. Two other mutants not yet characterized at the molecular level were also used for recombinational studies. From these data, a linear genetic map of the mitochondrial genome could be drawn. This map is consistent with the positions of the mutation sites on the mitochondrial DNA molecule and thereby validates the method used to generate the map. The frequency of recombination per physical distance unit (3.2% ± 0.7% per kilobase) is compared with those obtained for other organellar genomes in yeasts and Chlamydomonas.     

Nuclear suppressors of the [poky] cytoplasmic mutant in Neurospora crassa. III. Effects on other cytoplasmic mutants and on mitochondrial ribosome assembly in [poky].

Summary We have previously isolated six non-allelic, nuclear mutations (su ^I loci) that partially suppress the growth, respiratory and cytochrome abnormalities of the extranuclear [poky] mutant.A comparison of the mitochondrial ribosome profiles of suppressed and unsuppressed [poky] strains revealed that five of the six suppressors alleviate at least partially the deficiency of mitochondrial small ribosomal subunits that is associated with the [poky] genotype.Six independently isolated Group I extranuclear mutants, namely [exn-1], [exn-2], [exn-4], [stp-B ₁], [SG-1] and [SG-3], which have growth and cytochrome phenotypes similar to [poky], also were found to be deficient in small subunits of mitochondrial ribosomes. Using cytochrome aa ₃ and b production as a criterion for mitochondrial protein synthesis, it could be shown that the nuclear su ^I suppressors of [poky] also suppress the other six Group I extranuclear mutants. However, differences in the efficiencies of suppression by su ^I suppressors suggest that at least some of Group I extrachromosomal mutants are not simply re-isolates of [poky], but represent distinct extranuclear mutations.     

Generation and mapping of Mus spretus strain-specific markers for rapid genomic scanning

We describe here a set of genetic markers, based on IRS–PCR amplification difference, that are specifically designed for efficient, high throughput genetic mapping in [(M. domesticus× wild-derived) F₁×M. domesticus] interspecific backcrosses. 146 new genetic loci have been mapped, and strain distribution for these markers has been determined in 96 mouse strains. 103 (81%) of 127 tested markers are present only in one or more wild-derived strains, but absent in 76 other commonly used strains, demonstrating their utility in a variety of mouse pair combinations. Because of the ease of genotyping with this marker set, rapid genome scans for complex genetic trait loci involving crosses between wild-derived strains and other commonly used strains can now be carried out efficiently with large numbers of animals. Received: 2 October 1995 / Accepted: 12 December 1995     

Genetic Analysis of Petite Mutants of SACCHAROMYCES CEREVISIAE : Transmissional Types

We have studied a number of petite [rho^- ] mutants of Saccharomyces cerevisiae induced in a wild-type strain of mitochondrial genotype [ome^- CHL ^R ERY^S OLI^S_1,2,3 PAR^S] by Berenil and ethidium bromide, all of which have retained two mitochondrial genetic markers, [CHL^R] and [ERY^S], but have lost all other known markers. Though stable in their ability to retain these markers in their genome, these mutants vary widely among themselves in suppressiveness and in the extent to which the markers are transmitted on crossing to a common wild-type tested strain. In appropriate crosses all of the strains examined in this study demonstrate mitochondrial polarity, and thus have also retained the [ome^-] locus in a functional form; however, five different transmissional types were obtained, several of them quite unusual, particularly among the strains originally induced by Berenil. One of the most interesting types is the one that appears to reverse the parental genotypes with [CHL^R ERY^S] predominating over [CHL^S ERY^R] in the diploid [rho+] progeny, rather than the reverse, which is characteristic of analogous crosses with [rho+] or other petites. Mutants in this class also exhibited low or no suppressiveness. Since all of the petites reported here are derived from the same wild-type parent, and so have the same nuclear background, we have interpreted the transmissional differences as being due to different intramolecular arrangements of largely common retained sequences.     

Genetic mapping of mitochondrial markers by recombinational analysis in Chlamydomonas reinhardtii

The mitochondrial genome of Chlamydomonas reinhardtii is a 15.8 kb linear DNA molecule present in multiple copies. In crosses, the meiotic products only inherit the mitochondrial genome of the mating type minus (paternal) parent. In contrast mitotic zygotes transmit maternal and paternal mitochondrial DNA copies to their diploid progeny and recombinational events between molecules of both origins frequently occur. Six mitochondrial mutants unable to grow in the dark (dk^? mutants) were crossed in various combinations and the percentages of wild-type dk⁺ recombinants were determined in mitotic zygotes when all progeny cells had become homoplasmic for the mitochondrial genome. In crosses between strains mutated in the COB (apocytochrome ) gene and strains mutated in the COX1 (subunit 1 of cytochrome oxidase) gene, the frequency of recombination was 13.7% (± 3.2%). The corresponding physical distance between the mutation sites was 4.3 kb. In crosses between strains carrying mutations separated by about 20 bp, a recombinational frequency of 0.04% (± 0.02%) was found. Two other mutants not yet characterized at the molecular level were also used for recombinational studies. From these data, a linear genetic map of the mitochondrial genome could be drawn. This map is consistent with the positions of the mutation sites on the mitochondrial DNA molecule and thereby validates the method used to generate the map. The frequency of recombination per physical distance unit (3.2% ± 0.7% per kilobase) is compared with those obtained for other organellar genomes in yeasts and Chlamydomonas.     

Effect of hydroxyurea treatment on transmission and recombination of mitochondrial genes in Saccharomyces cerevisiae: a new method to modify the input of mitochondrial genes in crosses.

Summary The effects of hydroxyurea, an inhibitor of DNA synthesis, on the transmission and recombination of mitochondrial genes conferring resistance to different antibiotics in Saccharomyces cerevisiae have been studied.Under the conditions used hydroxyurea does not induce respiratory deficient mutants in treated cultures. Homosexual and heterosexual crosses have been performed in which one of the parents was grown for several generations in a medium containing 10^-1 M hydroxyurea prior to mating and the other parent was untreated. In all cases, the transmission of mitochondrial alleles originating from the hydroxyurea treated parent increased. In homosexual crosses the increase of transmission is coordinated for all the alleles. In heterosexual crosses, there is a differential increase of transmission of the different alleles depending on the distance of the marker considered from .All the observed effects can be easily interpreted according to the predictions of the model proposed by Dujon et al. (1974), if one assumes that hydroxyurea treatment increases the input of mitochondrial alleles of the treated parent without major modifications of the frequency of recombination. For each cross the relative copy number of mitDNA of the treated parent has been calculated and the increase so found is in good agreement with the modification of the overall frequency of recombinants observed. Effects of hydroxyurea on input can be interpreted if one assumes that hydroxyurea has a differential effect on mitochondrial and nuclear DNA synthesis: nuclear DNA synthesis would be inhibited while mitochondrial DNA synthesis would still continue.In conclusion, we propose a new powerful genetic tool for the study of the transmission and recombination of mitochondrial genes which offers the possibility of experimentally controlling input, without inducing rho^- mutation.     

Transmission of yeast mitochondrial loci to progeny is reduced when nearby intergenic regions containing ori sequences are deleted

Summary Mitochondrial DNAs (mtDNA) from four stable revertant strains generated from high frequency petite forming strains of Saccharomyces cerevisiae have been shown to contain deletions which have eliminated intergenic sequences encompassing ori1, ori2 and ori7. The deleted sequences are dispensable for expression of the respiratory phenotype and mutant strains exhibit the same relative amount of mtDNA per cell as the wild-type (wt) parental strain. These deletion mutants were also used to study the influence of particular intergenic sequences on the transmission of closely linked mitochondrial loci. When the mutant strains were crossed with the parental wt strains, there was a strong bias towards the transmission into the progeny of mitochondrial genomes lacking the intergenic deletions. The deficiency in the transmission of the mutant regions was not a simple function of deletion length and varied between different loci. In crosses between mutant strains which had non-overlapping deletions, wt mtDNA molecules were formed by recombination. The wt recombinants were present at high frequencies among the progeny of such crosses, but recombinants containing both deletions were not detected at all. The results indicate that mitochondrial genomes can be selectively transmitted to progeny and that two particular intergenic regions positively influence transmission. Within these regions other sequences in addition to ori/rep affect transmission.This paper is dedicated to colleagues J. Jana, D. Tasi, I. Bortner, and F. Zavrl     

Biogenesis of mitochondria. 52

Summary The characteristics of recombination of several petite (rho ^-) mutants of S. cerevisiae that retain the -influenced region of the mitochondrial genome, identified by the markers cap1-r, ery1-r and tsr1, are described. The petites were derived from an ^– grande (rho ⁺) strain and those petites which retain all three markers show recombination properties similar to those of the ^- parental strain. However, other rho ^- mutants that retain the cap1 and ery1 loci but have lost the tsr1 locus, which is located between cap1 and ery1, show markedly different properties of mitochondrial transmission and recombination, consistent with the presence of ⁺ alleles. The association of an internal deletion between the cap1 and ery1 loci with a change in phenotype provides additional evidence for the location of between these two loci.Although the petites deleted for the tsr1 locus exhibited the recombination properties of ⁺ strains, it was not possible to transmit this characteristic to rho ⁺ recombinant cells. Experiments on the kinetics of elimination by ethidium bromide of the cap1 and eryl markers from the petites and measurements of the buoyant densities of their mtDNA species did not indicate major changes (such as selective sequence repetition) in the sequences of the mtDNAs. The possible nature of the changes in the mtDNAs of these petites is discussed in light of recent studies on the physical nature of the alleles.     

The genetic map of the mitochondrial genome in yeast

Summary An approach for the screening of mit ^- mutants, the isolation and preliminary classification of a series of such mutants is reported. Loss and retention of 8 mit ^- and 6 drug ^r markers in mitDNA was analyzed in populations of rho^- clones derived from four yeast strains. The populations studied constitute a representative fraction of the rho^- petites formed during growth at 35° C under the influence of mutation tsp-25 which is in common to the four strains. The majority of the rho^- clones retained several of the markers studied. Depending on the marker regarded retention frequencies between 15% (oxi3) and 45% (oli1, cob) were observed. Loss of one and retention of the other of a pair of markers was determined in all rho^- clones of the four populations. The frequencies of marker separation by rho^- deletion thus obtained are assumed to reflect the distance between markers on the mitochondrial genome: the higher the frequency of separation the longer the distance between two markers. Based on these frequencies a unique order of markers on a circular map was determined. Positions of markers on a scale from 0 to 100 were found to be: cap/ery (0) — olil (16) — cob1-1354 (21) — ana101 (22) — cob2-1625 (24) — oli2 (35) — pho1 (40) — oxi3-2501 (44) — oxi3-3771 (47) — par (65) — oxi2 (79) — oxil (87) tms8 (93) —cap (100). The relevance of this map as to the faithful representation of the topology of gene loci on mitDNA is discussed. Correlation of retention frequencies of markers to their map positions reveals a pronounced polarity: mitDNA segments carrying the cob-oli1 segment prevail whereas segments retaining oxi3 are the least frequent.     

Effects of elevation of strain-ploidy on transmission and recombination of mitochondrial drug resistance genes in Saccharomyces cerevisiae

Summary In order to study the effects of strainploidy on the transmission and recombination of the mitochondrial genes C, E and O conferring the resistance to chloramphenicol, erythromycin and oligomycin, respectively, haploids were crossed to diploids and the results of genetic analysis were compared with those from haploidxhaploid crosses. All haploidx diploid crosses showed an increased transmission of diploid derived alleles, relative to haploid derived ones, but the pattern of increase differed between homosexual and heterosexual crosses. In ^– haploid x ^– diploid homosexual crosses, the increase was of roughly equal magnitude at the C, E and O loci: there was a polar co-transmission of the diploid derived alleles. In ⁺ haploid x ^– diploid heterosexual crosses, on the contrary, a differential increase was observed at the different loci, the magnitude being the smallest at the C locus and the largest at the O locus. As a result, there was a preferential transmission in favor of the haploid derived C alleles and of the diploid derived O alleles. A near equal transmission from both parents was observed for the E alleles. A decrease and an increase in the recombination frequency were noticed in the above haploidxdiploid homosexual and heterosexual crosses, respectively.The above phenomena were ascribed to different dosages of mitochondrial genomes from parents. Experimental data were well accorded with the theoretical expectations which were obtained on the assumptions that diploids contain twice as many mitochondrial genomes as haploids, and that random pairing and recombination would occur among mitochondrial genomes from parents. The elevation of strain-ploidy did not affect the recombination polarity which is under the control of the gene.It was theoretically predicted that a preferential transmission in favor of diploid derived alleles at all the C, E and O loci would be seen in ^– haploid x ⁺ diploid heterosexual crosses as well as in ^+; haploid x ^+; diploid homosexual crosses, but that the magnitude of the polar transmission would vary depending upon the loci in the former crosses, while it would be the same at all the loci in the latter ones. The recombination frequency was predicted to decrease in both of these crosses.