Yeast cell death during DNA damage arrest is independent of caspase or reactive oxygen species

CDC13 encodes a telomere-binding protein that prevents degradation of telomeres. cdc13-1 yeast grown at the nonpermissive temperature undergo G2/M arrest, progressive chromosome instability, and subsequent cell death. Recently, it has been suggested that cell death in the cdc13-1 mutant is an active process characterized by phenotypic hallmarks of apoptosis and caspase activation. In this work, we show that cell death triggered by cdc13-1 is independent of the yeast metacaspase Yca1p and reactive oxygen species but related to cell cycle arrest per se. Inactivating YCA1 or depleting reactive oxygen species does not increase viability of cdc13-1 cells. In turn, caspase activation does not precede cell death in the cdc13-1 mutant. Yca1p activity assayed by cell binding of mammalian caspase inhibitors is confounded by artifactual labeling of dead yeast cells, which nonspecifically bind fluorochromes. We speculate that during a prolonged cell cycle arrest, cdc13-1 cells reach a critical size and die by cell lysis.     

Morphogenesis beyond Cytokinetic Arrest in Saccharomyces cerevisiae

The budding yeast lyt1 mutation causes cell lysis. We report here that lyt1 is an allele of cdc15, a gene which encodes a protein kinase that functions late in the cell cycle. Neither cdc15-1 nor cdc15-lyt1 strains are able to septate at 37°C, even though they may manage to rebud. Cells lyse after a shmoo-like projection appears at the distal pole of the daughter cell. Actin polarizes towards the distal pole but the septins remain at the mother–daughter neck. This morphogenetic response reflects entry into a new round of the cell cycle: the preference for polarization from the distal pole was lost in bud1 cdc15 double mutants; double cdc15-lyt1 cdc28-4 mutants, defective for START, did not develop apical projections and apical polarization was accompanied by DNA replication. The same phenomena were caused by mutations in the genes CDC14, DBF2, and TEM1, which are functionally related to CDC15. Apical polarization was delayed in cdc15 mutants as compared with budding in control cells and this delay was abolished in a septin mutant. Our results suggest that the delayed M/G1 transition in cdc15 mutants is due to a septin-dependent checkpoint that couples initiation of the cell cycle to the completion of cytokinesis.     

The Dynamin-related GTPase,Dnm1p,Controls Mitochondrial Morphology in Yeast

The Saccharomyces cerevisiae Dnm1 protein is structurally related to dynamin, a GTPase required for membrane scission during endocytosis. Here we show that Dnm1p is essential for the maintenance of mitochondrial morphology. Disruption of the DNM1 gene causes the wild-type network of tubular mitochondrial membranes to collapse to one side of the cell but does not affect the morphology or distribution of other cytoplasmic organelles. Dnm1 proteins containing point mutations in the predicted GTP-binding domain or completely lacking the GTP-binding domain fail to rescue mitochondrial morphology defects in a dnm1 mutant and induce dominant mitochondrial morphology defects in wild-type cells. Indirect immunofluorescence reveals that Dnm1p is distributed in punctate structures at the cell cortex that colocalize with the mitochondrial compartment. These Dnm1p-containing structures remain associated with the spherical mitochondria found in an mdm10 mutant strain. In addition, a portion of Dnm1p cofractionates with mitochondrial membranes during differential sedimentation and sucrose gradient fractionation of wild-type cells. Our results demonstrate that Dnm1p is required for the cortical distribution of the mitochondrial network in yeast, a novel function for a dynamin-related protein.     

The yeast Coq4 polypeptide organizes a mitochondrial protein complex essential for coenzyme Q biosynthesis

Coenzyme Q is a redox active lipid essential for aerobic respiration. The Coq4 polypeptide is required for Q biosynthesis and growth on non-fermentable carbon sources, however its exact function in this pathway is not known. Here we probe the functional roles of Coq4p in a yeast Q biosynthetic polypeptide complex. A yeast coq4-1 mutant harboring an E226K substitution is unable to grow on nonfermentable carbon sources. The coq4-1 yeast mutant retains significant Coq3p O-methyltransferase activity, and mitochondria isolated from coq4-1 and coq4-2 (E₁₂₁K) yeast point mutants contain normal steady state levels of Coq polypeptides, unlike the decreased levels of Coq polypeptides generally found in strains harboring coq gene deletions. Digitonin-solubilized mitochondrial extracts prepared from yeast coq4 point mutants show that Coq3p and Coq4 polypeptides no longer co-migrate as high molecular mass complexes by one- and two-dimensional Blue Native-PAGE. Similarly, gel filtration chromatography confirms that O-methyltransferase activity, Coq3p, Coq4p, and Coq7p migration are disorganized in the coq4-1 mutant mitochondria. The data suggest that Coq4p plays an essential role in organizing a Coq enzyme complex required for Q biosynthesis.     

Minichromosome maintenance protein 5 homologue in Caenorhabditis elegans plays essential role for postembryonic development

Genome duplication is tightly controlled in multicellular organisms to ensure the genome stability. Studies in Saccharomyces cerevisiae and Xenopus show that minichromosome maintenance (MCM) proteins are essential for genome duplication. However, the development role of MCM proteins in multicellular organisms is not well known. MCM5 encodes a member of the MCM2-7 protein family involved in the initiation of DNA replication. The sequences of all Mcm5 homologues from yeast to human are highly conserved and suggest that their functions are also conserved. Here, we isolated the first mutant allele of mcm-5 (fw7) in Caenorhabditis elegans. Homozygous mcm-5 (fw7) mutants from heterozygous parents exhibited variable larval lethality and adult sterility. The postembryonically born neuron number was decreased and also showed aberrant axon morphology. Our study revealed that the losses of neurons in mcm-5 (fw7) mutants were caused by cell cycle defects not by programmed cell death. The examination showed that mcm-5 was widely used for postembryonic development in multiple cells such as seam cells, gonad and intestinal cells. Knockdown of mcm-5 by RNAi caused 98.1% embryonic arrest, suggesting that mcm-5 was also required for embryonic development. After RNAi treatment of the other MCM2-7 family members, we found that they all exhibited similar phenotypes as mcm-5, suggesting that the MCM2-7 family in C. elegans might function associated with cell division as its homologues in S. cerevisiae.     

Candida albicans PHO81 is required for the inhibition of hyphal development by farnesoic acid

Farnesoic acid is a signaling molecule that inhibits the transition from budding yeast to filament formation in Candida albicans, but the molecular mechanism regulated by this substance is unknown. In this study, we analyzed the function of CaPHO81, which is induced by farnesoic acid. The pho81Δ mutant cells existed exclusively as filaments under favorable yeast growth conditions. Furthermore, the inhibition of hyphal growth and repression of CPH1, EFG1, HWP1, and GAP1 mRNA expression in response to farnesoic acid were defective in pho81Δ mutant cells. These data suggest a role for CaPHO81 in the inhibition of hyphal development by farnesoic acid.     

Affinity purification of Candida albicans CaCdc4-associated proteins reveals the presence of novel proteins involved in morphogenesis

Candida albicans CDC4 is nonessential and plays a role in suppressing filamentous growth, in contrast to its evolutionary counterparts involved in the G1-S transition of the cell cycle. Genetic epistasis analysis has indicated that proteins besides Sol1 are targets of C. albicans Cdc4. Moreover, no formal evidence suggests that C. albicans Cdc4 functions through the ubiquitin E3 ligase of the Skp1-Cul1/Cdc53-F-box complex. To elucidate the role of C. albicans CDC4, C. albicans Cdc4-associated proteins were sought by affinity purification. A 6×His epitope-tagged C. albicans Cdc4 expressed from Escherichia coli was used in affinity purifications with the cell lysate of C. albicans cdc4 homozygous null mutant. Candida albicans Cdc4 and its associated proteins were resolved by SDS-PAGE and visualized by silver staining. The candidate proteins were recovered and trypsin-digested to generate MALDI-TOF spectra profiles, which were used to search against those of known proteins in the database to reveal their identities. Two out of four proteins encoded by GPH1 and THR1 genes were further verified to interact with C. albicans Cdc4 using a yeast two-hybrid assay. We conclude that in vitro affinity purification using C. albicans Cdc4 generated from E. coli as the bait and proteins from cell lysate of C. albicans cdc4 homozygous null mutant as a source of prey permit the identification of novel proteins that physically interact and functionally associate with C. albicans Cdc4.     

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.     

Isolation of the thymidylate synthetase gene (TMP1) by complementation in Saccharomyces cerevisiae.

The structural gene (TMP1) for yeast thymidylate synthetase (thymidylate synthase; EC 2.1.1.45) was isolated from a chimeric plasmid bank by genetic complementation in Saccharomyces cerevisiae. Retransformation of the dTMP auxotroph GY712 and a temperature-sensitive mutant (cdc21) with purified plasmid (pTL1) yielded Tmp+ transformants at high frequency. In addition, the plasmid was tested for the ability to complement a bacterial thyA mutant that lacks functional thymidylate synthetase. Although it was not possible to select Thy+ transformants directly, it was found that all pTL1 transformants were phenotypically Thy+ after several generations of growth in nonselective conditions. Thus, yeast thymidylate synthetase is biologically active in Escherichia coli. Thymidylate synthetase was assayed in yeast cell lysates by high-pressure liquid chromatography to monitor the conversion of [6-3H]dUMP to [6-3H]dTMP. In protein extracts from the thymidylate auxotroph (tmp1-6) enzymatic conversion of dUMP to dTMP was barely detectable. Lysates of pTL1 transformants of this strain, however, had thymidylate synthetase activity that was comparable to that of the wild-type strain.     

Thymidine 5′-Monophosphate-Requiring Mutants of Saccharomyces cerevisiae Are Deficient in Thymidylate Synthetase

Thymidylate synthetase activity was measured in crude extracts of the yeast Saccharomyces cerevisiae by a sensitive radiochemical assay. Spontaneous non-conditional mutants auxotrophic for thymidine 5'-monophosphate (tmp1) lacked detectable thymidylate synthetase activity in cell-free extracts. In contrast, the parent strains (tup1, -2, or -4), which were permeable to thymidine 5'-monophosphate, contained levels of activity similar to those found in wild-type cells. Specific activity of thymidylate synthetase in crude extracts of normal cells or of cells carrying tup mutations was essentially unaffected by the ploidy or mating type of the cells, by the medium used for growth, by the respiratory capacity of the cells, by concentrations of exogenous thymidine 5'-monophosphate as high as 50 mug/ml, or by subsequent removal of thymidine 5'-monophosphate from the medium. Extracts of a strain bearing the temperature-sensitive cell division cycle mutation cdc21 lacked detectable thymidylate synthetase activity under all conditions tested. Its parent and another mutant (cdc8), which arrests with the same terminal phenotype under restrictive conditions, had normal levels of the enzyme. Cells of a temperature-sensitive thymidine 5'-monophosphate auxotroph arrested with a morphology identical to the cdc21 strain at the nonpermissive temperature and contained demonstrably thermolabile thymidylate synthetase activity. Tetrad analysis and the properties of revertants showed that the thymidylate synthetase defects were a consequence of the same mutation causing, in the auxotrophs, a requirement for thymidine 5'-monophosphate and, in the conditional mutants, temperature sensitivity. Complementation tests indicated that tmp1 and cdc21 are the same locus. These results identify tmp1 as the structural gene for yeast thymidylate synthetase.     

The PINK1-Parkin pathway is involved in the regulation of mitochondrial remodeling process

The two Parkinson’s disease (PD) genes, PTEN-induced kinase 1 (PINK1) and parkin, are linked in a common pathway which affects mitochondrial integrity and function. However, it is still not known what this pathway does in the mitochondria. Therefore, we investigated its physiological function in Drosophila. Because Drosophila PINK1 and parkin mutants show changes in mitochondrial morphology in both indirect flight muscles and dopaminergic neurons, we here investigated whether the PINK1-Parkin pathway genetically interacts with the regulators of mitochondrial fusion and fission such as Drp1, which promotes mitochondrial fission, and Opa1 or Marf, which induces mitochondrial fusion. Surprisingly, DrosophilaPINK1 and parkin mutant phenotypes were markedly suppressed by overexpression of Drp1 or downregulation of Opa1 or Marf, indicating that the PINK1-Parkin pathway regulates mitochondrial remodeling process in the direction of promoting mitochondrial fission. Therefore, we strongly suggest that mitochondrial fusion and fission process could be a prominent therapeutic target for the treatment of PD.     

Isolation and characterization of cDNA clones encoding cdc2 homologues from Oryza sativa: a functional homologue and cognate variants.

Summary Using probes obtained by PCR amplification, we have isolated two cognate rice cDNAs (cdc2Os-1 andcdc2Os-2) encoding structural homologues of thecdc2 ⁺/CDC28(cdc2) protein kinase from a cDNA library prepared from cultured rice cells. Comparison of the deduced amino acid sequences of cdc2Os-1 and cdc2Os-2 showed that they are 83 % identical. They are 62 % identical toCDC28 ofSaccharomyces cerevisiae and much more similar to the yeast and mammalian p34^cdc2 kinases than to riceR2, acdc2-related kinase isolated previously by screening the same rice cDNA library with a different oligonucleotide probe. Southern blot analysis indicated that the three rice clones (cdc2Os-1,cdc2Os-2 andR2) are derived from distinct genes and are each found in a single copy per rice haploid genome. RNA blot analysis revealed that these genes are expressed in proliferating rice cells and in young rice seedlings.cdc2Os-1 could complement a temperature-sensitive yeast mutant ofcdc28. However, despite the similarity in structure, bothcdc2Os-2 andR2 were unable to complement the same mutant. Thus, the present results demonstrate the presence of structurally related, but functionally distinct cognates of thecdc2 cell cycle kinase in rice.The nucleotide sequence data in this paper have been deposited in the EMBL database under accession number X60374 (cdc2Os-1) and X60375 (cdc2Os-2)     

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.     

Apoptosis as a mechanism for removal of mutated cells of Saccharomyces cerevisiae: The role of Grx2 under cadmium exposure

Cadmium is a strong mutagen that acts by inhibiting DNA mismatch repair, while its toxic effect seems to be related to an indirect oxidative stress that involves glutathione (GSH) mobilization. Among the roles of GSH is the protection of proteins against oxidative damage, by forming reversible mixed disulfides with cysteine residues, a process known as protein glutathionylation and catalyzed by glutaredoxins (Grx). In this current study, Saccharomyces cerevisiae cells deficient in GRX2, growing in 80 μM CdSO₄, showed high mitochondrial mutagenic rate, determined by frequency of mutants that had lost mitochondrial function (petite mutants), high tolerance and lower apoptosis induction. The mutant strain also showed decreased levels of glutathionylated-protein after cadmium exposure, which might difficult the signaling to apoptosis, leading to increased mutagenic rates. Taken together, these results suggest that Grx2 is involved with the apoptotic death induced by cadmium, a form of cellular suicide that might lead of removal of mutated cells.     

cdc12p, a Protein Required for Cytokinesis in Fission Yeast, Is a Component of the Cell Division Ring and Interacts with Profilin

As in many other eukaryotic cells, cell division in fission yeast depends on the assembly of an actin ring that circumscribes the middle of the cell. Schizosaccharomyces pombe cdc12 is an essential gene necessary for actin ring assembly and septum formation. Here we show that cdc12p is a member of a family of proteins including Drosophila diaphanous, Saccharomyces cerevisiae BNI1, and S. pombe fus1, which are involved in cytokinesis or other actin-mediated processes. Using indirect immunofluorescence, we show that cdc12p is located in the cell division ring and not in other actin structures. When overexpressed, cdc12p is located at a medial spot in interphase that anticipates the future ring site. cdc12p localization is altered in actin ring mutants. cdc8 (tropomyosin homologue), cdc3 (profilin homologue), and cdc15 mutants exhibit no specific cdc12p staining during mitosis. cdc4 mutant cells exhibit a medial cortical cdc12p spot in place of a ring. mid1 mutant cells generally exhibit a cdc12p spot with a single cdc12p strand extending in a random direction. Based on these patterns, we present a model in which ring assembly originates from a single point on the cortex and in which a molecular pathway for the functions of cytokinesis proteins is suggested. Finally, we found that cdc12 and cdc3 mutants show a syntheticlethal genetic interaction, and a proline-rich domain of cdc12p binds directly to profilin cdc3p in vitro, suggesting that one function of cdc12p in ring assembly is to bind profilin.     

Introduction of cytochrome b mutations in Saccharomyces cerevisiae by a method that allows selection for both functional and non-functional cytochrome b proteins

We have previously used inhibitors interacting with the Qn site of the yeast cytochrome bc₁ complex to obtain yeast strains with resistance-conferring mutations in cytochrome b as a means to investigate the effects of amino acid substitutions on Qn site enzymatic activity [M.G. Ding, J.-P. di Rago, B.L. Trumpower, Investigating the Qn site of the cytochrome bc1 complex in Saccharomyces cerevisiae with mutants resistant to ilicicolin H, a novel Qn site inhibitor, J. Biol. Chem. 281 (2006) 36036-36043.]. Although the screening produced various interesting cytochrome b mutations, it depends on the availability of inhibitors and can only reveal a very limited number of mutations. Furthermore, mutations leading to a respiratory deficient phenotype remain undetected. We therefore devised an approach where any type of mutation can be efficiently introduced in the cytochrome b gene. In this method ARG8, a gene that is normally encoded by nuclear DNA, replaces the naturally occurring mitochondrial cytochrome b gene, resulting in ARG8 expressed from the mitochondrial genome (ARG8^m). Subsequently replacing ARG8^m with mutated versions of cytochrome b results in arginine auxotrophy. Respiratory competent cytochrome b mutants can be selected directly by virtue of their ability to restore growth on non-fermentable substrates. If the mutated cytochrome b is non-functional, the presence of the COX2 respiratory gene marker on the mitochondrial transforming plasmid enables screening for cytochrome b mutants with a stringent respiratory deficiency (mit⁻). With this system, we created eight different yeast strains containing point mutations at three different codons in cytochrome b affecting center N. In addition, we created three point mutations affecting arginine 79 in center P. This is the first time mutations have been created for three of the loci presented here, and nine of the resulting mutants have never been described before.     

High-quality genome sequence of Pichia pastoris CBS7435

The methylotrophic yeast Pichia pastoris (Komagataella phaffii) CBS7435 is the parental strain of commonly used P. pastoris recombinant protein production hosts making it well suited for improving the understanding of associated genomic features. Here, we present a 9.35 Mbp high-quality genome sequence of P. pastoris CBS7435 established by a combination of 454 and Illumina sequencing. An automatic annotation of the genome sequence yielded 5007 protein-coding genes, 124 tRNAs and 29 rRNAs. Moreover, we report the complete DNA sequence of the first mitochondrial genome of a methylotrophic yeast. Fifteen genes encoding proteins, 2 rRNA and 25 tRNA loci were identified on the 35.7 kbp circular, mitochondrial DNA. Furthermore, the architecture of the putative alpha mating factor protein of P. pastoris CBS7435 turned out to be more complex than the corresponding protein of Saccharomyces cerevisiae.     

BAX-mediated cell death affects early germ cell loss and incidence of testicular teratomas in Dnd1 mice

A homozygous nonsense mutation (Ter) in murine Dnd1 (Dnd1^Ter/Ter) results in a significant early loss of primordial germ cells (PGCs) prior to colonization of the gonad in both sexes and all genetic backgrounds tested. The same mutation also leads to testicular teratomas only on the 129Sv/J background. Male mutants on other genetic backgrounds ultimately lose all PGCs with no incidence of teratoma formation. It is not clear how these PGCs are lost or what factors directly control the strain-specific phenotype variation. To determine the mechanism underlying early PGC loss we crossed Dnd1^Ter/Ter embryos to a Bax-null background and found that germ cells were partially rescued. Surprisingly, on a mixed genetic background, rescued male germ cells also generated fully developed teratomas at a high rate. Double-mutant females on a mixed background did not develop teratomas, but were fertile and produced viable off-spring. However, when Dnd1^Ter/Ter XX germ cells developed in a testicular environment they gave rise to the same neoplastic clusters as mutant XY germ cells in a testis. We conclude that BAX-mediated apoptosis plays a role in early germ cell loss and protects from testicular teratoma formation on a mixed genetic background.     

Genetic analysis of human p34CDC2 function in fission yeast

The p34^cdc2 protein kinase plays a key role in the control of the mitotic cell cycle of fission yeast, being required for both entry into S-phase and for entry into mitosis in the mitotic cell cycle, as well as for the initiation of the second meiotic nuclear division. In recent years, structural and functional homologues of p34^cdc2, as well as several of the proteins that interact with and regulate p34^cdc2 function in fission yeast, have been identified in a wide range of higher eukaryotic cell types, suggesting that the control mechanisms uncovered in this simple eukaryote are likely to be well conserved across evolution. Here we describe the construction and characterisation of a fission yeast strain in which the endogenous p34^cdc2 protein is entirely absent and is replaced by its human functional homologue p34^CDC2, We have used this strain to analyse aspects of the function of the human p34^CDC2 protein genetically. We show that the function of the human p34^CDC2 protein in fission yeast cells is dependent upon the action of the protein tyrosine phosphatase p80^cdc25 that it responds to altered levels of both the mitotic inhibitor p107²³³¹ and the p34^cdc2-binding protein p13^suc1, and is lethal in combination with the mutant B-type cyclin p56^cdc13-117. In addition, we demonstrate that the human p34^CDC2 protein is proficient for fission yeast meiosis, and examine the behaviour of two mutant p34^CDC2 proteins in fission yeast.     

Biogenesis of mitochondria: XLI. Physical mapping of mitochondrial genetic markers in yeast

This paper describes the physical mapping of five antibiotic resistance markers on the mitochondrial genome of Saccharomyces cerevisiae. The physical separations between markers were derived from studies involving a series of stable spontaneous petite strains which were isolated and characterized for the loss or retention of combinations of the five resistance markers. DNA-DNA hybridization using ³²P-labelled grande mitochondrial DNA was employed to determine the fraction of grande mitochondrial DNA sequences retained by each of the defined petite strains.One petite clone retaining four of the markers in a segment comprising 36% of the grande genome was then chosen as a reference petite. The sequence homology between the mitochondrial DNA of this petite and that of the other petites was measured by DNA-DNA hybridization. For each petite, the total length of its genome derived by hybridization with grande mitochondrial DNA and the fraction of the grande genome retained in common with the reference petite, together with the genetic markers retained in common, were used to position the DNA segment of each petite relative to the reference petite genome. At the same time the relative physical location of the five markers on a circular genome was established. On the basis of the grande mitochondrial genome being defined as 100 units of DNA, the positions of the markers were determined to bo as follows, measuring from one end of the reference petite genome. chloramphenicol (cap1) ~ 0 units erythromycin (ery1) 0 to 15 units oligomycin (oli1) 18 to 19 units mikamycin (mik1) 22 to 25 units paromomycin (par1) 61 to 73 unitsThe general problems of mapping mitochondrial genetic markers by hybridizations involving petite mitochondrial DNA are discussed. Two very important features of petite genomes which could invalidate the interpretation of DNA-DNA hybridization experiments between petite mitochondrial DNAs are the possible presence in the reference petite of differentially amplified DNA sequences, and/or “new” sequences which are not present in the parent grande genome. A general procedure, which overcomes errors of interpretation arising from these two features is described.