Genes that act before conjugation to prepare the Saccharomyces cerevisiae nucleus for caryogamy

Mutations in four nuclear genes, kar1 cdc4, 28, and 37, block or impair nuclear fusion during conjugation of Saccharomyces cerevisiae. Mutations in all four genes are recessive for the caryogamy defect; in matings between diploid cells both of which are heterozygous for any one of the four mutations (-/+ X -/+), caryogamy occurs with normal proficiency. However, mutations in all four genes are "nuclear dominant"; that is, both parent nuclei must contribute one wild-type allele of each gene for successful caryogamy. In order to discriminate between two possible models to explain nuclear dominance, we have examined the caryogamy proficiency of mutant nuclei after they had passed through a heterocaryotic cytoplasm. The kar1, cdc28, and cdc37 caryogamy defects are all phenotypically suppressed in this experiment (cdc4 could not be tested). We conclude from our results that the KAR1, CDC28, and CDC37 gene products can diffuse between nuclei in a heterocaryon and that they probably perform their function for caryogamy prior to cell fusion. One simple model consistent with the roles of CDC28 and CDC37 in mitosis as well as in caryogamy is that these gene products are structural components of the nucleus that must be built into it during one cell cycle in order to permit successful caryogamy at the next G1.     

Genetic interactions between KAR7/SEC71, KAR8/JEM1, KAR5, and KAR2 during nuclear fusion in Saccharomyces cerevisiae

During mating of Saccharomyces cerevisiae, two nuclei fuse to produce a single diploid nucleus. Two genes, KAR7 and KAR8, were previously identified by mutations that cause defects in nuclear membrane fusion. KAR7 is allelic to SEC71, a gene involved in protein translocation into the endoplasmic reticulum. Two other translocation mutants, sec63-1 and sec72Delta, also exhibited moderate karyogamy defects. Membranes from kar7/sec71Delta and sec72Delta, but not sec63-1, exhibited reduced membrane fusion in vitro, but only at elevated temperatures. Genetic interactions between kar7 and kar5 mutations were suggestive of protein-protein interactions. Moreover, in sec71 mutants, Kar5p was absent from the SPB and was not detected by Western blot or immunoprecipitation of pulse-labeled protein. KAR8 is allelic to JEMI, encoding an endoplasmic reticulum resident DnaJ protein required for nuclear fusion. Overexpression of KAR8/JEM1 (but not SEC63) strongly suppressed the mating defect of kar2-1, suggesting that Kar2p interacts with Kar8/Jem1p for nuclear fusion. Electron microscopy analysis of kar8 mutant zygotes revealed a nuclear fusion defect different from kar2, kar5, and kar7/sec71 mutants. Analysis of double mutants suggested that Kar5p acts before Kar8/Jem1p. We propose the existence of a nuclear envelope fusion chaperone complex in which Kar2p, Kar5p, and Kar8/Jem1p are key components and Sec71p and Sec72p play auxiliary roles.     

Two-hybrid cloning and characterization of OSH3, a yeast oxysterol-binding protein homolog

We identify Osh3p, one of seven yeast oxysterol-binding protein (OSBP) homologs, by its protein-protein interactions with a DEAD-box RNA helicase, Rok1p. The ROK1 gene was initially identified by its ability on a high-copy number plasmid to suppress the nuclear fusion defect caused by the kem1 null mutation. Our results show that OSH3 also affects nuclear fusion in a kem1-specific manner; the nuclear fusion defect of kem1 was intensified by the multicopy expression of OSH3. The Osh3p synthesis was highly induced by alpha-mating pheromone. We also found that OSH3 overexpression promoted filamentation growth of the Sigma1278b wild-type strain and suppressed the filamentation growth defect of the ste12 mutation. These results lead us to a new understanding of cellular functions of the yeast OSBPs.     

Identification of an exoribonuclease homolog, CaKEM1/CaXRN1, in Candida albicans and its characterization in filamentous growth

KEM1/XRN1 and RAT1 are two known exoribonuclease genes in Saccharomyces cereivsiae and encode a cytoplasmic and nuclear exoribonuclease, respectively. CaKEM1/CaXRN1 and CaRAT1, the Candida albicans homologs of 5'-->3' exoribonuclease genes, were identified by protein sequence comparisons and by functional complementation of the S. cerevisiae kem1/xrn1 null mutation. The deduced amino acid sequences of CaKEM1 and CaRAT1 show 51% and 55% identities to those of the S. cerevisiae KEM1 and RAT1, respectively. The exonuclease motifs were found to be highly conserved in CaKem1p and CaRat1p. We disrupted two chromosomal copies of CaKEM1 in a diploid C. albicans strain and demonstrate that C. albicans kem1/kem1 mutants are defective in filamentous growth on filamentous-inducing media. These results imply that CaKEM1 is involved in filamentous growth of C. albicans.     

Internuclear transfer of genetic information in kar1-1/KAR1 heterokaryons in Saccharomyces cerevisiae.

Heterokaryons of Saccharomyces cerevisiae have been constructed utilizing the kar1-1 mutation, which prevents nuclear fusion during conjugation (J. Conde and G. Fink, Proc. Natl. Acad. Sci. U.S.A. 73:3651-3655, 1976). Each heterokaryon contained two haploid nuclei that were marked on several chromosomes. They segregated haploid progeny (cytoductants), most of which have the nuclear genotype of one or the other of the heterokaryon parents, but they occasionally segregated progeny having a recombinant genotype (exceptional cytoductants). Exceptional cytoductants receive the majority of their genome from one parent (the recipient) and a minority from the other (the donor). Transfer of two markers from the donor nucleus to the recipient is rarely coincident for markers located on different chromosomes but is nearly always coincident for those markers located on the same chromosome, suggesting that whole chromosomes are transferred from the donor nucleus to the recipient. In crosses of kar1-1 X KAR1 parents, either nucleus may act as a recipient or donor with equal probability. Recipient nuclei acquired 9 of the 10 chromosomes examined, with frequencies which were inversely correlated with the size of the chromosome. When a chromosome is acquired by the recipient nucleus, it either replaces its homolog or exists in a disomic condition. Haploid progeny emanating from kar1 X KAR1 crosses are frequently inviable. I tested whether this inviability might be the result of chromosome loss by donor nuclei. Viability of progeny from kar1 X KAR1 heterokaryons was improved when the parental nuclei were diploid to an extent consistent with the hypothesis, and diploid progeny which had become monosomic were recovered from these heterokaryons. The following sequence of events accounts for chromosome transfer in kar1 X KAR1 heterokaryons. After cell fusion, each nucleus in the heterokaryon has a probability of about 0.38 of losing one or more chromosomes. A nucleus sustaining such a loss can become a donor in a chromosome transfer event. If the other nucleus does not sustain a mortal chromosome loss, it can become a recipient in a transfer event. The chance of acquiring a chromosome lost by the donor is greater for smaller chromosomes than for larger ones and is about 0.05 for the average chromosome.     

Bud selection and apoptosis-like degradation of nuclei in yeast heterokaryons: a KAR1 effect

It has been shown that defects in cell fusion during mating can trigger programmed cell death in the yeast Saccharomyces cerevisiae. We wished to test whether defects in nuclear migration during cell fusion have the same effect. A partial pedigree analysis of nine kar1 × KAR1 crosses of two different types (four α KAR1 × a kar1 and five α kar1 × a KAR1 crosses) was carried out, and quantitative estimates of the frequencies of different mother/daughter (m/d) classes were obtained. The kar1 mutation affects nuclear congression and delays nuclear fusion. In each cross tested, the nucleus that entered the first bud tended to be the one contributed by the cell that carried the wild-type allele of KAR1. If budding was delayed by nutrient limitation, the kar1 nucleus could be rescued, indicating that the primary effect of the kar1 mutation is that it slows spindle action. Many m/d classes appear as a result of the degradation of one of the nuclei in the heterokaryon. Loss of nuclei in heterokaryons was accompanied by an accumulation of reactive oxygen species (ROS), and by abnormalities in nuclear structure revealed by TUNEL (terminal transferase-mediated dUTP nick end-labeling) analysis, DAPI staining and by histone-GFP fluorescence patterns which suggested an apoptosis-like process. Often only one nucleus was degraded, and ROS accumulation was restricted to one half of the zygote. We therefore suggest that the data obtained can be explained by apoptosis-like death of a half-cell (cell body).     

Transmission and expression of mutations to nalidixic acid resistance among products of protoplast fusion crosses of Candida albicans

Earlier studies suggested that heritable resistance to nalidixic acid (Nal) induced in the asexual, pathogenic yeast Candida albicans by growth on Nal results from mitochondrial mutation. To determine conclusively whether mutations to Nal resistance are cytoplasmic or nuclear, several stable Nal-resistant (Nalr) mutants exhibiting distinctive differences in degrees of Nal resistance were obtained from each of two doubly auxotrophic strains (Ade-, Thr- and Arg-, His-), both derived from the same wild-type stock. Inheritance of Nal resistance was then assessed in a series of protoplast fusion crosses between complementing auxotrophs. The initial, intact cellular products of a fusion cross are prototrophic heterokaryons which frequently assort single parental nuclei into monokaryotic blastospores containing biparental cytoplasms. Occasional karyogamy within heterokaryons also yields prototrophic hybrid monokaryons which can undergo recombinations for chromosomal markers through spontaneous or induced mitotic crossing-over. Segregation and expression of Nal resistance among non-hybrid, parental-type monokaryons from Nalr X Nals heterokaryons showed that Nalr mutations are nuclear and that their expressions are not noticeably affected by admixture of cytoplasms of sensitive and resistant parental strains. Analyses of heterokaryons and hybrid monokaryons from Nalr X Nals and Nalr X Nalr crosses demonstrated that Nal resistance is recessive to sensitivity, and that independent Nalr mutations arise at one gene in the Ade-, Thr- strain and at a separate, complementing single gene in the Arg-, His- strain. Prior work demonstrated that induction of Nalr mutations in wild-type C. albicans depends profoundly on the (i) carbon and nitrogen, (ii) growth temperature, (iii) contact with particular metabolic inhibitors and (iv) division stage of cells during exposure to Nal. The present observations indicate that the character of cellular auxotrophies can determine the genetic loci at which Nalr mutations can be recovered.     

Function of Cryptococcus neoformans KAR7 (SEC66) in karyogamy during unisexual and opposite-sex mating

The human basidiomycetous fungal pathogen Cryptococcus neoformans serves as a model fungus to study sexual development and produces infectious propagules, basidiospores, via the sexual cycle. Karyogamy is the process of nuclear fusion and an essential step to complete mating. Therefore, regulation of nuclear fusion is central to understanding sexual development of C. neoformans. However, our knowledge of karyogamy genes was limited. In this study, using a BLAST search with the Saccharomyces cerevisiae KAR genes, we identified five C. neoformans karyogamy gene orthologs: CnKAR2, CnKAR3, CnKAR4, CnKAR7 (or CnSEC66), and CnKAR8. There are no apparent orthologs of the S. cerevisiae genes ScKAR1, ScKAR5, and ScKar9 in C. neoformans. Karyogamy involves the congression of two nuclei followed by nuclear membrane fusion, which results in diploidization. ScKar7 (or ScSec66) is known to be involved in nuclear membrane fusion. In C. neoformans, kar7 mutants display significant defects in hyphal growth and basidiospore chain formation during both a-α opposite and α-α unisexual reproduction. Fluorescent nuclear imaging revealed that during kar7 × kar7 bilateral mutant matings, the nuclei congress but fail to fuse in the basidia. These results demonstrate that the KAR7 gene plays an integral role in both opposite-sex and unisexual mating, indicating that proper control of nuclear dynamics is important. CnKAR2 was found to be essential for viability, and its function in mating is not known. No apparent phenotypes were observed during mating of kar3, kar4, or kar8 mutants, suggesting that the role of these genes may be dispensable for C. neoformans mating, which demonstrates a different evolutionary trajectory for the KAR genes in C. neoformans compared to those in S. cerevisiae.     

Distinct Roles for Key Karyogamy Proteins during Yeast Nuclear Fusion

During yeast mating, cell fusion is followed by the congression and fusion of the two nuclei. Proteins required for nuclear fusion are found at the surface (Prm3p) and within the lumen (Kar2p, Kar5p, and Kar8p) of the nuclear envelope (NE). Electron tomography (ET) of zygotes revealed that mutations in these proteins block nuclear fusion with different morphologies, suggesting that they act in different steps of fusion. Specifically, prm3 zygotes were blocked before formation of membrane bridges, whereas kar2, kar5, and kar8 zygotes frequently contained them. Membrane bridges were significantly larger and occurred more frequently in kar2 and kar8, than in kar5 mutant zygotes. The kinetics of NE fusion in prm3, kar5, and kar8 mutants, measured by live-cell fluorescence microscopy, were well correlated with the size and frequency of bridges observed by ET. However the kar2 mutant was defective for transfer of NE lumenal GFP, but not diffusion within the lumen, suggesting that transfer was blocked at the NE fusion junction. These observations suggest that Prm3p acts before initiation of outer NE fusion, Kar5p may help dilation of the initial fusion pore, and Kar2p and Kar8p act after outer NE fusion, during inner NE fusion.     

KAR1, a gene required for function of both intranuclear and extranuclear microtubules in yeast

Molecular analysis of the KAR1 gene of yeast has shown that it is required for both mitosis and conjugation. The gene was originally identified by mutations that prevent nuclear fusion. By in vitro mutagenesis and gene replacement we have demonstrated that the gene is an essential cell division cycle gene. Temperature-sensitive mutant strains show defects in spindle pole body duplication and chromosome disjunction. Overproduction of the gene product blocks spindle pole body duplication, producing a cell cycle arrest phenotype similar to that of the Kar- temperature-sensitive mutations. Long, aberrant extranuclear microtubules are formed in the temperature-sensitive mutants arrested at the nonpermissive temperature as well as in kar1-1 during conjugation. These observations suggest that the KAR1 gene is required for the normal function of both the intranuclear and extranuclear microtubules.     

Two Cell Division Cycle Mutants of SACCHAROMYCES CEREVISIAE Are Defective in Transmission of Mitochondria to Zygotes

Mutations in CDC genes of S. cerevisiae disrupt the cell cycle at specific stages. The experiments reported here demonstrate that two CDC genes, CDC5 and CDC27, are necessary for mitochondrial segregation as well as for nuclear division. The defect in the transmission of mitochondria was revealed by the examination of uninucleate and binucleate progeny of transient heterokaryons generated by using the kar1-1 mutation that disrupts nuclear fusion. One of the parents lacked mitochondrial DNA (ρ⁰) whereas the other parent had functional mitochondria (ρ⁺). When the parents of the heterokaryon were both wild-type (CDC), nearly all progeny received mitochondria at 21° and at 34°. Thirty-four of the 36 cdc mutations tested had no defect in transmission of mitochondria to zygotic progeny in crosses in which one parent was a cdc mutant and the other parent was not (CDC). However, the cdc5 and cdc27 mutations prevented the transmission of mitochondria to cdc progeny at 34° but not at 21°; CDC progeny received mitochondria at either temperature. This defect was observed in crosses of cdc5 or cdc27 by wild-type cells regardless of which parent donated mitochondria to the zygote. The defect in mitochondrial transmission cosegregated in meiotic tetrads with the defect in mitosis demonstrating that both are likely to be caused by the same temperature-sensitive mutation. These results indicate that the CDC5 and CDC27 gene products are essential in two motility-related processes: mitochondrial movement from the zygote to the progeny and in mitosis.—Furthermore, the results suggest that the function performed by the CDC5 and CDC27 gene products for mitochondrial transmission differ in some fundamental way from the function performed for mitosis. The function necessary for mitosis can be supplied to the cdc5 (or cdc27) nucleus by the CDC5 (or CDC27) nucleus in the same heterokaryon but the function necessary for mitochondrial transmission cannot. Perhaps the function needed for mitochondrial transmission must be performed in the cell cycle preceding the actual segregation of mitochondria whereas the function needed for nuclear segregation can be performed at the time that mitosis occurs.     

Dependence of endoplasmic reticulum-associated degradation on the peptide binding domain and concentration of BiP

ER-associated degradation (ERAD) removes defective and mis-folded proteins from the eukaryotic secretory pathway, but mutations in the ER lumenal Hsp70, BiP/Kar2p, compromise ERAD efficiency in yeast. Because attenuation of ERAD activates the UPR, we screened for kar2 mutants in which the unfolded protein response (UPR) was induced in order to better define how BiP facilitates ERAD. Among the kar2 mutants isolated we identified the ERAD-specific kar2-1 allele (Brodsky et al. J. Biol. Chem. 274, 3453-3460). The kar2-1 mutation resides in the peptide-binding domain of BiP and decreases BiP's affinity for a peptide substrate. Peptide-stimulated ATPase activity was also reduced, suggesting that the interdomain coupling in Kar2-1p is partially compromised. In contrast, Hsp40 cochaperone-activation of Kar2-1p's ATPase activity was unaffected. Consistent with UPR induction in kar2-1 yeast, an ERAD substrate aggregated in microsomes prepared from this strain but not from wild-type yeast. Overexpression of wild-type BiP increased substrate solubility in microsomes obtained from the mutant, but the ERAD defect was exacerbated, suggesting that simply retaining ERAD substrates in a soluble, retro-translocation-competent conformation is insufficient to support polypeptide transit to the cytoplasm.     

Genes involved in the control of nuclear fusion during the sexual cycle of Saccharomyces cerevisiae

Summary Mutants of Saccharomyces cerevisiae defective for nuclear fusion have been isolated. Their mutations have been characterized by meiotic analysis, dominance-recessivity and complementation. Twelve of the mutations are allelic to the previously described kar 1–1; five affect a second gene designated KAR 2 and three affect a third gene designated KAR 3. There is evidence suggesting that other two mutants are affected in a gene different from the three mentioned.Mutations in KAR 1 and KAR 2 genes are recessive and do not cause obvious effects other than the failure of the karyogamy. Mutations in KAR 3 are semidominant and do cause pleiotropic effects affecting both mitosis and meiosis.     

Kar9p Is a Novel Cortical Protein Required for Cytoplasmic Microtubule Orientation in Yeast

kar9 was originally identified as a bilateral karyogamy mutant, in which the two zygotic nuclei remained widely separated and the cytoplasmic microtubules were misoriented (Kurihara, L.J., C.T. Beh, M. Latterich, R. Schekman, and M.D. Rose. 1994. J. Cell Biol. 126:911–923.). We now report a general defect in nuclear migration and microtubule orientation in kar9 mutants. KAR9 encodes a novel 74-kD protein that is not essential for life. The kar9 mitotic defect was similar to mutations in dhc1/dyn1 (dynein heavy chain gene), jnm1, and act5. kar9Δ dhc1Δ, kar9Δ jnm1Δ, and kar9Δ act5Δ double mutants were synthetically lethal, suggesting that these genes function in partially redundant pathways to carry out nuclear migration. A functional GFP-Kar9p fusion protein localized to a single dot at the tip of the shmoo projection. In mitotic cells, GFP-Kar9p localized to a cortical dot with both mother–daughter asymmetry and cell cycle dependence. In small-budded cells through anaphase, GFP-Kar9p was found at the tip of the growing bud. In telophase and G1 unbudded cells, no localization was observed. By indirect immunofluorescence, cytoplasmic microtubules intersected the GFP-Kar9p dot. Nocodazole experiments demonstrated that Kar9p's cortical localization was microtubule independent. We propose that Kar9p is a component of a cortical adaptor complex that orients cytoplasmic microtubules.     

Sec3 Mutations Are Synthetically Lethal with Profilin Mutations and Cause Defects in Diploid-Specific Bud-Site Selection

Replacement of the wild-type yeast profilin gene (PFY1) with a mutated form (pfy1-111) that has codon 72 changed to encode glutamate rather than arginine results in defects similar to, but less severe than, those that result from complete deletion of the profilin gene. We have used a colony color-sectoring assay to identify mutations that cause pfy1-111, but not wild-type, cells to be inviable. These profilin synthetic lethal (psl) mutations result in various degrees of abnormal growth, morphology, and temperature sensitivity in PFY1 cells. We have examined psl1 strains in the most detail. Interestingly, these strains display a diploid-specific defect in bud-site selection; haploid strains bud normally, while homozygous diploid strains show a dramatic increase in random budding. We discovered that PSL1 is the late secretory gene, SEC3, and have found that mutations in several other late secretory genes are also synthetically lethal with pfy1-111. Our results are likely to reflect an interdependence between the actin cytoskeleton and secretory processes in directing cell polarity and growth. Moreover, they indicate that the secretory pathway is especially crucial for maintaining budding polarity in diploids.     

Mutations at the smo genetic locus affect the shape of diverse cell types in the rice blast fungus

Teflon film surfaces are highly conducive to the formation of infection structures (appressoria) in the plant pathogenic fungus, Magnaporthe grisea. We have utilized Teflon films to screen and select for mutants of M. grisea that are defective in appressorium formation. This approach and several others yielded a group of 14 mutants with a similar phenotype. All the mutant strains make abnormally shaped conidia and appressoria. When two mutant strains are crossed, abnormally shaped asci are formed. Ascus shape is normal when a mutant strain is crossed with a wild-type strain. Despite dramatic alterations in cell shape these strains otherwise grow, form conidia, undergo meiosis, and infect plants normally. This mutant phenotype, which we have termed Smo(-), for abnormal spore morphology, segregates in simple Mendelian fashion in crosses with wild-type strains. Some ascospore lethality is associated with smo mutations. In genetic crosses between mutants, smo mutations fail to recombine and do not demonstrate complementation of the abnormal ascus shape phenotype. We conclude that the smo mutations are alleles of a single genetic locus and are recessive with regard to the the ascus shape defect. Mutations at the SMO locus also permit germinating M. grisea conidia to differentiate appressoria on surfaces that are not normally conducive to infection structure formation. A number of spontaneous smo mutations have been recovered. The frequent occurrence of this mutation suggests that the SMO locus may be highly mutable.     

Genetic and Molecular Analysis of a Long-Lived Strain of Podospora Anserina

A genetic and molecular analysis of a long-lived strain of Podospora anserina, Mn19, was undertaken to detect mutations in genes responsible for senescence. In crosses between Mn19 and wild type about 15% of the progeny were long-lived, regardless of the female parent. Molecular analysis of the long-lived progeny showed that none of the strains inherited a mtDNA rearrangement characteristic of the Mn19 parent. Instead, all long-lived strains initially inherited wild-type mtDNA. Over time the mtDNA of most long-lived strains underwent rearrangements, deletions and amplifications. The change over time in the presence of two previously characterized plasmids associated with either senescence or longevity was monitored. Crosses between Mn19 and its long-lived progeny also yielded only a small percent of individuals recovering from senescence. Analysis of mtDNA from crosses suggests that wild-type mtDNA from the paternal parent can be selected over mtDNA from the maternal parent. The life span phenotypes of progeny were not consistent with the hypothesis that mutations in a few nuclear genes were responsible for longevity.     

Lrg1p Is a Rho1 GTPase-activating protein required for efficient cell fusion in yeast

To identify additional cell fusion genes in Saccharomyces cerevisiae, we performed a high-copy suppressor screen of fus2Delta. Higher dosage of three genes, BEM1, LRG1, and FUS1, partially suppressed the fus2Delta cell fusion defect. BEM1 and FUS1 were high-copy suppressors of many cell-fusion-defective mutations, whereas LRG1 suppressed only fus2Delta and rvs161Delta. Lrg1p contains a Rho-GAP homologous region. Complete deletion of LRG1, as well as deletion of the Rho-GAP coding region, caused decreased rates of cell fusion and diploid formation comparable to that of fus2Delta. Furthermore, lrg1Delta caused a more severe mating defect in combination with other cell fusion mutations. Consistent with an involvement in cell fusion, Lrg1p localized to the tip of the mating projection. Lrg1p-GAP domain strongly and specifically stimulated the GTPase activity of Rho1p, a regulator of beta(1-3)-glucan synthase in vitro. beta(1-3)-glucan deposition was increased in lrg1Delta strains and mislocalized to the tip of the mating projection in fus2Delta strains. High-copy LRG1 suppressed the mislocalization of beta(1-3) glucan in fus2Delta strains. We conclude that Lrg1p is a Rho1p-GAP involved in cell fusion and speculate that it acts to locally inhibit cell wall synthesis to aid in the close apposition of the plasma membranes of mating cells.     

Isolation and characterization of temperature-sensitive mak mutants of Saccharomyces cerevisiae.

The K1 killer plasmid of Saccharomyces cerevisiae is a 1.5-megadalton linear double-stranded ribonucleic acid molecule. Using simplified screening and complementation procedures, we have isolated mutants in three chromosomal genes that are temperature sensitive for killer plasmid maintenance or replication. One of these genes, mak28-1, was located on chromosome X. Two of the temperature-sensitive mutants rapidly lost the wild-type killer plasmid of A364A during spore germination and outgrowth at nonpermissive temperatures, but during vegetative growth, they only lowered the plasmid copy number. These two mutants did not lose two other wild-type K1 killer plasmids, indicating a heterogeneity of the killer plasmids in laboratory yeast strains.