Genetic analysis of polyauxotrophy and early mitotic progeny of Saccharomyces cerevisiae zygotes. II. Spore-forming segregants in the mitotic and meiotic progeny of polyauxotrophic clones

This article continues the investigation of polyauxotrophic (PA) clones formed in early mitotic progeny of zygotes. Cloning and segregation analysis of PA progeny suggest an unusual state of diploid genome in these strains, which is expressed as elimination of the dominance effect of the wild allele and as suppression or conversion of either of two loci of mating type. In PA progeny, except for recombinant haploids, sporulating diploids and unstable clones were detected. The tetrad analysis of the diploids points to homozygotization for individual markers. Over-replication of diploid set of chromosomes, prior to meiosis, and replacement of the haploid nucleus (the product of meiosis) for the diploid nucleus may explain the appearance of sporulating segregants in the diploid meiotic progeny. Unstable segregants may be considered as heterokaryons with complex interaction of nuclei.     

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.     

Transfer of isolated nuclei into protoplasts ofSaccharomyces cerevisiae

Cell nuclei were prepared from protoplasts of an adenine-requiring strain ofSaccharomyces cerevisiae, then purified in a discontinuous sucrose gradient, and applied to protoplasts of a recipient strain auxotrophic for uracil, leucine, and histidine. The transfer of the isolated nuclei into protoplasts was induced with polyethylene glycol. The main products of nuclear transfer in young complemented colonies were heterokaryons giving rise to parental type spontaneuos segregants on nutritionally complete medium. After several passages in minimal medium, however, the prototrophic colonies consisted exclusively of stable heterozygous diploid cells.     

Concealed nuclei in Saccharomyces strains

We have found that cells derived from heterokaryons (HK) showing phenotypical traits, coded by the nucleus of one parental strain and by the cytoplasm of the other, may produce mitotic progeny in which the second nucleus is apparently present but not expressed. This 'concealed' nucleus can be forced to expression after growth of these cytoductants on proper selective media. Using a micromanipulator, the buds containing both parental nuclei were isolated in various crosses. Cloning these HK from a rich medium (YEPD) revealed that nearly all of them were composed of a mixture of hybrid cells and cells of one of the parents. Cells of the other parent were present in a very small proportion, if detectable at all. We showed that the percentage of concealed HK decreases when limiting the growth of the strain that serves as a donor of the concealed nucleus. Consequently, our explanation for the presence of concealed nuclei in HK is the low production rate of daughter cells containing both nuclei, which accounts for the lack of a visible phenotype in HK, together with the low replication rate (or fast nuclease degradation) of one of the nuclei. In homosexual crosses, selection allows us to switch the concealed nucleus to normal replication rate. Some abnormalities of meiosis due to hidden nuclei are shown.     

Characterization of the Heterokaryotic and Vegetative Diploid Phases of MAGNAPORTHE GRISEA

The heterokaryotic and vegetative diploid phases of Magnaporthe grisea, a fungal pathogen of grasses, have been characterized. Prototrophic heterokaryons form when complementary auxotrophs are paired on minimal medium. Hyphal tip cells and conidia (vegetative spores) taken from these heterokaryons are auxotrophs with phenotypes identical to one or the other of the parents. M. grisea heterokaryons thus resemble those of other fungi that have completely septate hyphae with a single nucleus per cell. Heterokaryons have been utilized for complementation and dominance testing of mutations that affect nutritional characteristics of the fungus. Heterokaryons growing on minimal medium spontaneously give rise to fast-growing sectors that have the genetic properties expected of unstable heterozygous diploids. In fast-growing sectors, most hyphal tip cells are unstable prototrophs. The conidia collected from fast-growing sectors include stable and unstable prototrophs, as well as auxotrophs that exhibit a wide range of phenotypes, including many recombinant classes. Genetic linkage in meiosis has been detected between two auxotrophic mutations that recombine in vegetatively growing unstable diploids. The appearance of recombinants suggests that homologous recombination occurs during vegetative growth of M. grisea. No interstrain barriers to heterokaryosis and diploid formation have been detected. The mating type of the strains that are paired does not influence the formation of heterokaryons or diploids.     

Factors affecting the frequency of concealed heterokaryosis in Saccharomyces cerevisiae

In this work, studies on the phenomenon of concealed heterokaryosis that we previously detected in the saccharomycetes yeast strains were continued. New approaches to high effectiveness of isolation of cytoductants carrying the concealed nucleus were implemented, and the composition of individual concealed heterokaryons, zygotic clones, and the first zygotic buds was analyzed by a micromanipulator. The relationship between a delay in the growth of the parental strain (a potential donor of the concealed nucleus) and a decline in the frequency of the appearance of concealed heterokaryons (HKC) was observed. It is assumed that different replication rates of two nuclei of the heterokaryon probably underlie the appearance of HKC. A drastically decreased level of replication of one of the parental nuclei may be connected with the fact that binuclear buds appear extremely rarely and give rise to the rapidly "purified" progeny consisting of cells carrying the second nucleus with normal replication. A lack of the phenotype allows rare binuclear cells to persist as concealed heterokaryons. HKC may be detected only when cells of either parental type are isolated on the corresponding selective media.     

Genetic Properties of Mutations at the PEP4 Locus in SACCHAROMYCES CEREVISIAE

Yeast cells that inherit mutations at the PEP4 locus exhibit a pronounced phenotypic lag in the expression of the mutant phenotype imparted by these mutations. This lag appears to extend to all of the enzymes that are affected by the pep4-3 mutation. For at least two of the enzymatic activities, phenotypic lag shows mitotic cosegregation. Phenotypic lag is found for meiotic progeny and for mitotic segregants from heterokaryons. The phenotypic lag in the expression of the carboxypeptidase Y deficiency is abolished by nonsense mutations in either PRC1, the structural gene for carboxypeptidase Y, or PRB1, the structural gene for proteinase B. Models to explain these observations are proposed.     

Vegetative compatibility and parasexual segregation in Colletotrichum lindemuthianum, a fungal pathogen of the common bean

The heterokaryotic and vegetative diploid phases of Colletotrichum lindemuthianum are described using nutritional and biochemical markers. Nitrate non-utilizing mutants (nit), derived from R2047, R89, R73, R65, and R23 isolates, were paired in all possible combinations to obtain heterokaryons. Although pairings R2047/R89, R2047/R73, R65/R73, and R73/R23 showed complete vegetative incompatibility, prototrophic heterokaryons were obtained from pairings R2047/R65, R2047/R23, R65/R89, R65/R23, R73/R89, R89/R23, R2047/R2047, R65/R65, R89/R89, R73/R73, and R23/R23. Heterokaryons gave rise to spontaneous mitotic segregants which carried markers corresponding to one or the other of the parental strains. Heterokaryons spontaneously produced prototrophic fast-growing sectors too, characterized as diploid segregants. Diploids would be expected to yield auxotrophic segregants following haploidization in basal medium or in the presence of benomyl. Parental haploid segregants were in fact recovered from diploid colonies growing in basal medium and basal medium containing the haploidizing agent. Although barriers to the formation of heterokaryons in some crosses were detected, the results demonstrate the occurrence of parasexuality among vegetative compatible mutants of C. lindemuthianum.     

Alternative reproduction pathway inAspergillus nidulans

Recombinant haploid segregants were recovered in filamentous fungus Aspergillus nidulans (Eidam) G. Winter directly from the heterokaryons instead of diploid segregants (process described earlier as parameiosis). In spite of the reproductive complexity of A. nidulans, parameiosis has only now been observed in this fungus. Since parameiosis was characterized by the occurrence of genetic recombination inside heterokaryotic hyphae, master strains (uvs+) and uvs mutants with high rate of both mitotic exchanges or chromosome nondisjunction were used to form heterokaryons. Two groups of mitotic segregants were recovered directly from heterokaryons--aneuploids and stable haploids. Heterokaryons formed with uvs mutants produced a higher number of parameiotic segregants compared to the heterokaryons formed with uvs+ strains. Segregants were analyzed by nutritional markers, acriflavine resistance and conidial color. Normal meiotic behavior of haploid recombinants was observed.     

The Use of Duplication-Generating Rearrangements for Studying Heterokaryon Incompatibility Genes in Neurospora

Heterokaryon (vegetative) incompatibility, governing the fusion of somatic hyphal filaments to form stable heterokaryons, is of interest because of its widespread occurrence in fungi and its bearing on cellular recognition. Conventional investigations of the genetic basis of heterokaryon incompatibility in N. crassa are difficult because in commonly used stocks differences are present at several het loci, all with similar incompatibility phenotypes. This difficulty is overcome by using duplications (partial diploids) that are unlikely to contain more than one het locus. A phenotypically expressed incompatibility reaction occurs when unlike het alleles are present within the same somatic nucleus, and this parallels the heterokaryon incompatibility reaction that occurs when unlike alleles in different haploid nuclei are introduced into the same somatic hypha by mycelial fusion.—Nontandem duplications were used to confirm that the incompatibility reactions in heterokaryons and in duplications are alternate expressions of the same genes. This was demonstrated for three loci which had previously been established by conventional heterokaryon tests—het-e, het-c and mt. These were each obtained in duplications as recombinant meiotic segregants from crosses heterozygous for duplication-generating chromosome rearrangements. The particular method of producing the duplications is irrelevant so long as the incompatibility alleles are heterozygous.—The duplication technique has made it possible to determine easily the het-e and het-c genotypes of numerous laboratory and wild strains of unknown constitution. In laboratory strains both loci are represented simply by two alleles. Analysis of het-c is more complicated in some wild strains, where differences have been demonstrated at one or more additional het loci within the duplication used and multiple allelism is also possible.—The results show that the duplication method can be used to identify and map additional vegetative incompatibility loci, without the necessity of heterokaryon tests.     

产黄青霉ds RNA病毒通过原生质体融合的转移

将国内青霉素产生菌(Penicillium chrysogenum)的黄孢子系统及绿孢子(包括淡绿,灰绿)系统的十多个菌株,经过病毒提取、电镜观察、奥氏免疫双扩散、凝胶电泳及放射免疫测定,证明黄孢子系统的菌株含有不同滴定度的、直径40nm的球形病毒,而绿孢子系统中检查不出病毒。从营养要求、孢子颜色不同的带病毒和无病毒菌体中分离原生质体,进行不同组合的原生质体的融合杂交,获得营养互补融合的异核体。异核体1中,病毒通过胞质融合转移到原来无病毒的灰绿孢子菌株及细胞核融合后的杂合二倍体中。灰绿孢子的病毒量接近二倍体的1/3。二倍体菌落生长稳定,低温保存二年后经0.01—0.02M对氟苯丙氨酸(PFA)诱发和分离,产生亲本类型的分离子,分离子及二倍体仍然含有病毒。异核体2作亲本性分离,黄孢子仍有病毒,淡绿孢子及细胞核融合后产生的二倍体均无病毒,表明非感染性为显性。此种淡绿孢子的突变体中存在非感病菌系,它不支持病毒的复制。提取各杂交组二倍体内的病毒所特有的dsRNA时,可看出dsRNA的存在和病毒的存在一致。多数杂合二倍体的青霉素产量比亲本高。     

Factors Affecting the Frequency of Concealed Heterokaryosis in Saccharomyces cerevisiae

In this work, studies on the phenomenon of concealed heterokaryosis that we previously detected in the Saccharomycetes yeast strains were continued. New approaches to high effectiveness of isolation of cytoductants carrying the concealed nucleus were implemented, and the composition of individual concealed heterokaryons, zygotic clones, and the first zygotic buds was analyzed by a micromanipulation technique. The relationship between a delay in the growth of the parental strain (a potential donor of the concealed nucleus) and a decline in the frequency of the appearance of concealed heterokaryons (HK_C) was observed. It is assumed that different replication rates of two nuclei of the heterokaryon probably underlie the appearance of HK_C. A drastically decreased level of replication of one of the parental nuclei may be connected with the fact that binuclear buds appear extremely rarely and give rise to the rapidly purified progeny consisting of cells carrying the second nucleus with normal replication. A lack of the phenotype allows rare binuclear cells to persist as concealed heterokaryons. HK_C may be detected only when cells of either parental type are isolated on the corresponding selective media.     

Genetic manipulation of Aspergillus nidulans: heterokaryons and diploids for dominance, complementation and haploidization analyses

The haploid microbial eukaryote Aspergillus nidulans is a powerful genetic system, which allows analysis of a broad range of biological phenomena. In addition to conventional analysis of meiotic progeny in a single generation, parasexual analysis affords a rapid and convenient method for genetic analysis. We describe the construction of A. nidulans heterokaryons and diploids for use in genetic analysis to determine dominance and conduct complementation tests. We also describe the rapid mapping of mutations to chromosomes by haploidization of diploids carrying marked chromosomes. Balanced heterokaryons may be established within 10 days and diploids may be constructed in 2-3 weeks. Dominance tests and complementation tests using balanced heterokaryons or diploids may be completed in 2-3 days. Haploidization analysis of heterozygous diploids can be achieved within 10 days. These protocols should be adaptable for use in related Aspergilli and Penicillia, which lack a known meiotic cycle.     

Restoration of metabolic cooperation in heterokaryons between HGPRT-deficient mouse A9 fibroblasts and chick embryo erythrocytes

Genetic determinants of metabolic cooperation were studied by fusing chick erythrocytes to HGPRT- mammalian cells. Heterokaryons were then tested for their ability to incorporate [3H]hypoxanthine and to transfer radioactive material to HGPRT- recipient cells. Chick erythrocytes (CE) have nuclei which are inactive but contain the HGPRT gene and some cytoplasmic HGPRT enzyme activity. They are unable, however, to cooperate with HGPRT- cells. Of the two mammalian cell lines used, the human GM29 line is HGPRT- and capable of functioning as a receptor cell in cooperation experiments with HGPRT+ cells. The HGPRT- mouse A9 line on the other hand is unable to cooperate. Immediately after fusion, both types of heterokaryons incorporated [3H]hypoxanthine, indicating the presence of some chick HGPRT enzyme contributed by the erythrocyte partner at the time of fusion. While the CE-GM29 heterokaryons participated in metabolic cooperation shortly after fusion, the CE-A9 heterokaryons did not. However, four days after fusion, i.e., at a time when the erythrocyte nucleus had been reactivated, the CE-A9 heterokaryons did cooperate. This suggests that in CE-A9 heterokaryons the genes required for metabolic cooperation are expressed by the previously dormant chick erythrocyte nucleus.     

A note on crossing experiments with Aspergillus niger for the production of calcium gluconate

A strong calcium gluconate-producing strain of Aspergillus niger (MN181) was obtained by way of mutagenic treatment. Its growth was very slow with moderate sporulation. The strain was treated with N-methyl-N'nitro-N-nitrosoguanidine (MNNG) and some auxotrophic mutants were obtained. All were less productive than the parent strain in producing calcium gluconate. The reduced yield was corrected in the heterokaryons and diploids derived by crossing sister strains. One diploid strain (D4), heterozygous for auxotrophy and conidial colour markers was grown in the presence of 4% alcohol and 31 segregants were isolated which included both haploid and diploid strains. Their yields were studied and some recombinants were obtained which, in spite of the same yield of MN181, showed improvement in giving fast growth and abundant sporulation.     

Genetic Analysis of the Reciprocal Translocation T2(I;VIII) of Aspergillus Using the Technique of Mitotic Mapping in Homozygous Translocation Diploids

A UV-induced sulphite-requiring mutant (sD50) consistently shows mitotic linkage to groups I and VIII in haploids from heterozygous mapping diploids. This linkage was found to be due to a reciprocal translocation T2(I;VIII) which could not be separated from the sulphite requirement in about 100 tested progeny from heterozygous crosses, and both may well have been induced by the same mutational event. T2(I;VIII) is the first case of a reciprocal translocation in Aspergillus which showed meiotic linkages between markers of different linkage groups, and, in addition, involved chromosome arms containing markers suitable for complete mapping by the technique of mitotic recombination in homozygous translocation diploids.-Using various selective markers, haploid segregants and diploid crossovers of all possible types were isolated from homozygous translocation diploids. (1) Haploid segregants showed new linkage relationships in T/T diploids: all available markers of VIII now segregated as a group with the majority of the markers of I, except for the markers of the left tip of I. These formed a separate linkage group and are presumably translocated to VIII. (2) Diploid mitotic crossovers confirmed this information and showed that the orientation of the translocated segments was unchanged. These findings conclusively demonstrate that T2(I;VIII) is a reciprocal translocation due to an exchange of the left tip of group I with the long right arm of group VIII.-Since the position of the break on VIIIR was found to be at sD50 this marker could be used to map the break on IL by meiotic recombination in heterozygous crosses. In addition, such crosses showed reduced recombination around the breaks, so that it was possible to sequence markers which normally are barely linked.     

Spontaneous and bleomycin-induced genomic alterations in the progeny of Drosophila treated males depends on the Msh2 status. DNA fingerprinting analysis

Deficiency in DNA mismatch repair (MMR) confers instability of simple repeated sequences and increases susceptibility to cancer. Some of the MMR genes are also implicated in other repair and cellular processes related to DNA damage response. Supposedly, lack of their function can lead to a global genomic instability, besides microsatellite instability (MSI). To study the spontaneous and induced genomic instability in germ cells, related to the Msh2 status, DNA alterations in the progeny of individual crosses of Drosophila deficient in one or two copies of the Msh2 gene, were analysed by the arbitrarily primed polymerase chain reaction (AP-PCR). The results indicate that the progeny of homozygous parents for the normal Msh2 allele (+/+) presents a significantly lower frequency of genomic alterations than those from heterozygous (+/-) or mutant homozygous (-/-) parents. In addition, the DNA damage transmitted to the progeny, after the adult parental males were exposed to bleomycin, indicates that whereas the induction of mutations related to MSI depends on the lack of the Msh2 function, the induction of other mutational events may require at least one functional Msh2 allele. Thus, the results obtained with heterozygous individuals may have special relevance for cancer development since they show that a disrupted Msh2 allele is enough to generate genomic instability in germ cells, increasing the genomic damage in the progeny of heterozygous individuals. This effect is enhanced by mutagenic stress, such as occurs after bleomycin exposure.     

Asexual recombination in a uvsH mutant of Aspergillus nidulans

Mutations in the gene uvsH of Aspergillus nidulans result in increased spontaneous chromosome instability and increased intragenic and intergenic mitotic recombination in homozygous diploids. The aim of the present work was to obtain a uvs mutant of A. nidulans and to use it for the isolation of asexual recombinants (parameiotic segregants). The mutant uvsH, named B511, showed normal frequency of meiotic recombination in sexual crosses and high frequency of parameiotic segregants in the parasexual crossings with master strains (B511//A757 and B511//A288). Asexual haploid recombinants (parameiotic segregants), diploid and aneuploid segregants were recovered directly from the uvs//uvs+ heterokaryons (B511//A757 and B511// A288). Parameiotic segregants originated through mitotic crossing-over and independent assortment of chromosomes.     

Suppressive effect of protease inhibitors on heterokaryons containing chick erythrocyte nuclei

Nuclei of active cells (HeLa, mouse fibroblasts) partnered with chick erythrocyte nuclei in heterokaryons are suppressed, as judged by a decreased rate of ³H-uridine incorporation and diminished nuclear binding of ³H-actinomycin D. The extent to which active partner nuclei are suppressed, the extent to which erythrocyte nuclei are reactivated, and the degree of sensitivity of heterokaryons towards certain inhibitors of proteolytic enzymes, all correlate strongly with the ratios of erythrocyte nuclei to active nuclei. Thus, reactivation of individual erythrocyte nuclei is reduced progressively and active nuclei are suppressed progressively as the ratio of erythrocyte nuclei per active nucleus in heterokaryons increases. This erythrocyte nuclear-dose dependent suppression is markedly amplified when heterokaryons are grown in the presence of protease inhibitors. The protease inhibitors found to affect heterokaryons are low molecular weight (<400) inhibitors of trypsin-like enzymes: -1-tosylamide-2-leucyl chloromethyl ketone (TLCK), N-α-tosyl- -arginine methyl ester (TAME) and N-benzoyl- -arginine amide (BAA). They affect heterokaryons at concentrations comparable to the minimal concentrations at which they inhibit trypsin. Nonfused HeLa cells, mouse fibroblasts, or their homokaryons are refractory to protease inhibitors at these concentrations.Reactivation of chick erythrocyte nuclei in a heterokaryon may involve release of suppressors ordinarily confined to the erythrocyte nucleus, with subsequent redistribution of suppressor among all the nuclei of the heterokaryon. Under these circumstances the state of nuclear activity will depend on the quantity of suppressor per individual nucleus; within the erythrocyte nucleus the suppressors will decrease its rate of reactivation, when they migrate into an active nucleus they will suppress it. These suppressors, either in transit between the nuclei, or within the nuclei, may be hydrolysed by intracellular proteases.