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.     

The yeast 2 micron plasmid: strategies for the survival of a selfish DNA

Summary The designation of the yeast 2 circle as a selfish DNA molecule has been confirmed by demonstrating that the plasmid is lost with exponential kinetics from haploid yeast populations grown in continuous culture. We show that plasmid-free yeast cells have a growth rate advantage of some 1.5%–3% over their plasmid-containing counterparts. This finding makes the ubiquity of this selfish DNA in yeast strains puzzling. Two other factors probably account for its survival. First, the rate of plasmid loss was reduced by allowing haploid populations to enter stationary phase periodically. Second, it was not possible to isolate a plasmid-free segregant from a diploid yeast strain. Competition experiments demonstrated that stability in a diploid is conferred at the level of segregation and that plasmid-free diploid cells are at a selective advantage compared with their plasmid-containing counterparts. Yeast cells in nature are usually homothallic and must frequently pass through both diploid and stationary phases. The 2 plasmid appears to have evolved a survival strategy which exploits these two features of its host's life cycle.     

Stable yeast transformation with chimeric plasmids using a 2 micron-circular DNA-less strain as a recipient.

Summary By using two chimeric plasmids containing yeast URA3 gene as a selection marker and 2 m yeast DNA linked to the bacterial plasmid pCR1, a yeast strain devoid of any 2 m DNA sequence was transformed. Recovery in E. coli of plasmids from yeast transformants showed that the 2 m-less strain was able to maintain the chimeric plasmids as autonomous replicons, with very infrequent plasmid recombination. Hybridization experiments gave no evidence for integration of the URA3 DNA sequence in the chromosomal DNA. The transformed clones showed a high stability of the ura⁺ character during vegetative multiplication, even in the absence of selective pressure. The specific activity of orotidine 5 monophosphate decarboxylase (coded by the URA3 gene) was 5 to 10 fold higher than in the wild type.These features should offer new possibilities for cloning with yeast.     

Biotransformation of cholesterol by Micrococcus species mediated by plasmid DNA

A steroid-biotransforming strain RJ6 was identified as Micrococcus roseus. This bacterium has a 10kb plasmid pMQV10. Curing mediated through cultivation of the culture with a low concentration (200ng/ml) of mitomycin C is described. Loss of cholesterol degradation (chol⁺) and streptomycin resistance (Sm^r) phenotypes as a consequence of the loss of plasmid indicate the extrachromosomal location of these two genes in this strain. An electroporation procedure was developed for transformation of cured strain of Micrococcus (RJC6) by plasmids. Frequency of greater than 10⁵ transformants/g DNA was achieved, which is 100-fold higher than the standard transformation procedure that yielded 5.3×10³ transformants/g DNA in the same strain.     

Establishment of a gene transfer system for Rhodothermus marinus

Genetic manipulation of Rhodothermus marinus has been hampered by the lack of a selection system for gene transfer. We report construction of a Rhodothermus/Escherichia coli shuttle plasmid, containing the R. marinus trpB gene, based on pUC18 and the cryptic R. marinus plasmid pRM21. A plasmid-less R. marinus recipient strain was selected on the basis of growth characteristics and absence of restriction activity. The shuttle plasmid, pRM100, was successfully introduced into a TrpB^– mutant of the recipient strain using electroporation and was found to transform it to prototrophy. No loss or rearrangement of pRM100 was observed after growth for 80 generations in non-selective medium. The relative copy numbers of pRM100 and of the parental plasmid, pRM21, were determined as 7±1 and 42±4, respectively. The shuttle plasmid was used to optimize an electroporation protocol, and the maximal number of transformants obtained was 4.3±0.7×10⁶ cfu/g DNA at 22.5 kV/cm, 200 and 25 F. Transformation failed, however, after chemical preparation of cells according to several protocols. This is the first report of genetic transformation in the genus Rhodothermus.     

Slow growth phenotype - A possible approach to improved plasmid maintenance in Saccharomyces cerevisiae

Summary Transformation-induced slow growth phenotype (SGP) in yeast is repressed in the presence of 2m plasmids. A full 2m-sequence-based recombinant plasmid (pJB502) was found to be more stable in a 2m-free- [cir] strain of Saccharomyces cerevisiae than in a cir⁺ strain. This could not be attributed to differences in growth rate calculated from kinetic analysis of plasmid loss, but transformed [cir] isolates, which had lost the recombinant plasmid, exhibited varying degrees of SGP in batch culture. One of these isolates was outcompeted in chemostat culture by the recombinant-plasmid-containing strain, suggesting that improved plasmid maintenance can result from SGP in cir hosts.     

Enhanced stability of a 2μ-based recombinant plasmid in diploid yeast

Summary The stability of a 2-based recombinant plasmid, pJDB219, has been compared in glucose-limited chemostat cultures of two haploid strains ofSaccharomyces cerevisiae and a diploid derived from them. The stability of the recombinant plasmid differed in the two haploid hosts but was greatest in the diploid. Enhanced stability in the diploid is probably a function of both the increased copy number and reduced selective burden of the plasmid.     

Escherichia coli plasmid pBR313 insertion into plant protoplasts and into their nuclei

Summary Cowpea mesophyll protoplasts were shown to bind irreversibly up to 3% input radioactive pBR313 plasmid DNA after 15 min of contact. Maximum uptake occurred in the presence of 5mM ZnSO₄ and 5 g/ml poly-L-ornithine. Under these conditions about one half of the TCA precipitable radioactivity was associated with the nuclear fraction and behaved as linear plasmid molecules. These could not be chased from the protoplasts upon further incubation with unlabeled plasmid DNA. The presence of donor DNA within the nuclear fraction is most probably not due to an artifactual redistribution of adsorbed plasmid DNA. Prolonged incubation periods resulted in extensive degradation of plasmid in the incubation medium but little degradation occurred in the protoplasts. The donor DNA was not covalently associated with the protoplast nuclear DNA.     

High-frequency transformation ofLactobacillus casei with plasmid pHY300PLK by electroporation

To optimize the conditions for transformation ofLactobacillus casei ATCC 27092 cells with plasmid pHY300PLK, a shuttle vector forEscherichia coli andBacillus subtilis, by electroporation, we investigated the effects of the electrical parameters (voltage and resistance), the concentration of plasmid DNA, the cell age and density, the electroporation buffer, and other factors. Under optimal conditions of 2.0 kV, 100 ohm, and 25F, a transformation efficiency as high as 1.4×10⁷ transformants per g of plasmid DNA was obtained, with a survival rate of about 50%.L. casei YIT 9021, one of the PL-1 phage mutants of the ATCC 27092 strain, was also transformed with the same plasmid under optimal conditions. The transformants were confirmed to harbor the same intact plasmid molecules by agarose gel electrophoretic analysis.     

Integrative transformation of the ascomycete Podospora anserina: identification of the mating-type locus on chromosome VII of electrophoretically separated chromosomes

Summary Protoplasts of wild-type strain s and a long-lived extrachromosomal mutant (AL2) of the ascomycete Podospora anserina were transformed using a plasmid (pAN7-1) which contains the hygromycin B phosphotransferase gene (hph) of Escherichia coli under the control of Aspergillus nidulans regulatory sequences. After optimizing the transformation procedure, transformation efficiencies of 15–21 transformants/ plasmid DNA were obtained. Using a second selectable vector (pBT3), which contains the -tubuline gene of a benomyl-resistant Neurospora crassa mutant, the cotransformation rate was determined. Southern blot hybridization experiments revealed that the transforming plasmid became integrated into the genome of the recipient either as a single copy or as multiple copies. In addition, the data from molecular as well as from classical genetic analyses indicated that in independent transformants vector integration occurred at different positions. The mitotic and meiotic stability of transformants proved to be dependent on the number of integrated plasmid copies. Genetic analyses revealed a transformant in which the integrated vector is closely linked to the mating-type locus. Fractination of whole chromosomes by pulsed field gel electrophoresis and subsequent hybridization of the immobilized DNAs against radiolabelled vector sequences indicated the largest of seven chromosomes as the chromosome containing the integrated vector and thus the mating-type locus. Offprint requests to: K. Esser