Protection against cadmium toxicity in yeast by alcohol dehydrogenase.

A cDNA expression library from Schizosaccharomyces pombe was transformed into Saccharomyces cerevisiae to screen for genes capable of conferring cadmium resistance to S. cerevisiae cells. The cDNA library was cloned into the S. cerevisiae expression vector pDB20 which is designed to express cDNAs via the constitutively-expressed promoter of the gene for alcohol dehydrogenase I (ADH1). Terminator and polyadenylation signals are also provided by the ADH1 gene. Cadmium resistant colonies were shown to arise by a recombination event leading to the exchange of the S. pombe DNA with the chromosomal ADH1 gene and a consequent dramatic increase in the ADH1 gene expression due to the high copy number of the plasmid. The overexpression of ADH1 effectively buffered the cells for cadmium ions by formation of Cd-ADH.     

High-frequency cotransformation by copolymerization of plasmids in the fission yeast Schizosaccharomyces pombe.

We have developed a high-frequency cotransformation system which is useful in introducing nonreplicating circular DNA plasmids into the fission yeast Schizosaccharomyces pombe. This system depends on two factors: the ability of the ural-complementing helper plasmids pFYM2 and pFYM225 to propagate autonomously in S. pombe, and the intensive recombination activity intrinsic to this yeast. If cotransformed with a helper plasmid, plasmids such as YIp5 or YIp32, Escherichia coli-Saccharomyces cerevisiae shuttle vectors incapable of replication in S. pombe, can enter S. pombe and express the gene carried on them at a frequency comparable to that of autonomously replicating plasmids (10(3) to 10(4) transformants per microgram of DNA). Even if characters of the nonreplicating DNA are not selected directly, 50 to 70% of Ura+ cells transformed with the helper have also incorporated the nonreplicating plasmid. It is shown that these two plasmids have physically recombined at a site of common DNA sequence to form a heteropolymer in the fission yeast. Since any foreign DNA cloned in pBR322 or ColE1 derivatives can be incorporated into S. pombe by using pFYM2 or pFYM225 as a helper, this cotransformation system will serve as a convenient method to examine functional expression of such cloned DNA in S. pombe. This work also demonstrates that the kanamycin resistance gene carried by the bacterial transposon Tn903 can be expressed in S. pombe, as shown by its ability to inactivate the antibiotic G418.     

Copy number and the stability of 2-micron circle-based artificial plasmids of Saccharomyces cerevisiae

The copy number and stability of artificial 2-micron circle-based plasmids have been accurately measured in [Cir+] and [Cir0] strains of Saccharomyces cerevisiae. We conclude that (i) instability and copy number vary greatly from plasmid to plasmid; (ii) instability and copy number are negatively correlated--that is, high copy number is associated with low instability; (iii) it is difficult to reconcile this variability with a strict and direct system of copy number control; (iv) instabilities are much higher than expected from random partition and the observed copy numbers: this may imply partition which is less efficient than random. Even so, (v) the partitioning of 2-micron circle-like plasmids is more efficient than that of ARS-based plasmids, which hints at the existence of a system for the (inefficient) distribution of 2-micron circles.     

Yeast telomere repeat sequence (TRS) improves circular plasmid segregation, and TRS plasmid segregation involves the RAP1 gene product.

Telomere repeat sequences (TRSs) can dramatically improve the segregation of unstable circular autonomously replicating sequence (ARS) plasmids in Saccharomyces cerevisiae. Deletion analysis demonstrated that yeast TRSs, which conform to the general sequence (C(1-3)A)n, are able to stabilize circular ARS plasmids. A number of TRS clones of different primary sequence and C(1-3)A tract length confer the plasmid stabilization phenotype. TRS sequences do not appear to improve plasmid replication efficiency, as determined by plasmid copy number analysis and functional assays for ARS activity. Pedigree analysis confirms that TRS-containing plasmids are missegregated at low frequency and that missegregated TRS-containing plasmids, like ARS plasmids, are preferentially retained by the mother cell. Plasmids stabilized by TRSs have properties that distinguish them from centromere-containing plasmids and 2 microns-based recombinant plasmids. Linear ARS plasmids, which include two TRS tracts at their termini, segregate inefficiently, while circular plasmids with one or two TRS tracts segregate efficiently, suggesting that plasmid topology or TRS accessibility interferes with TRS segregation function on linear plasmids. In strains carrying the temperature-sensitive mutant alleles rap1grc4 and rap1-5, TRS plasmids are not stable at the semipermissive temperature, suggesting that RAP1 protein is involved in TRS plasmid stability. In Schizosaccharomyces pombe, an ARS plasmid was stabilized by the addition of S. pombe telomere sequence, suggesting that the ability to improve the segregation of ARS plasmids is a general property of telomere repeats.     

Transformation of Saccharomyces cerevisiae and Schizosaccharomyces pombe with linear plasmids containing 2 micron sequences.

Linear plasmids were constructed by adding telomeres prepared from Tetrahymena pyriformis rDNA to a circular hybrid Escherichia coli-yeast vector and transforming Saccharomyces cerevisiae. The parental vector contained the entire 2 mu yeast circle and the LEU gene from S. cerevisiae. Three transformed clones were shown to contain linear plasmids which were characterized by restriction analysis and shown to be rearranged versions of the desired linear plasmids. The plasmids obtained were imperfect palindromes: part of the parental vector was present in duplicated form, part as unique sequences and part was absent. The sequences that had been lost included a large portion of the 2 mu circle. The telomeres were approximately 450 bp longer than those of T. pyriformis. DNA prepared from transformed S. cerevisiae clones was used to transform Schizosaccharomyces pombe. The transformed S. pombe clones contained linear plasmids identical in structure to their linear parents in S. cerevisiae. No structural re-arrangements or integration into S. pombe was observed. Little or no telomere growth had occurred after transfer from S. cerevisiae to S. pombe. A model is proposed to explain the genesis of the plasmids.     

Plasmids pEMBLY: new single-stranded shuttle vectors for the recovery and analysis of yeast DNA sequences

We describe the construction and properties of pEMBLY plasmids. They belong to a new family of yeast shuttle vectors which are derived from plasmid vector pEMBL9 and offer the following improvement: relatively small size; large number of cloning sites; screening for insert-containing plasmids on indicator plates; different combinations of genes which complement auxotrophic deficiencies and sequences that support DNA replication in Saccharomyces cerevisiae; and ability to isolate the plasmid DNA in single-stranded (ss) form. The yeast S. cerevisiae can be efficiently transformed by these plasmids in both the ss and double-stranded (ds) forms. Finally, the presence of the phage f1 intergenic region allows one to obtain the cloned sequences in the ss form upon infection with the wild-type ss phage [Dotto et al., Virology 114 (1981) 463-473].     

Site-specific recombination promotes plasmid amplification in yeast

All stable, naturally occurring circular yeast DNA plasmids contain a pair of long, nontandem inverted repeats that undergo frequent reciprocal recombination. This yields two plasmid inversion isomers that exist in the cell in equal numbers. In the 2 mu circle plasmid of S. cerevisiae such inversion is catalyzed by a plasmid-encoded site-specific recombinase, FLP. We show that the site-specific recombination system of 2 mu circle enables the plasmid to increase its mean intracellular copy number in yeast cells growing under nonselective conditions. This apparently occurs by a FLP-induced transient shift in the mode of replication from theta to double rolling circle as initially proposed by Futcher. This capability may ensure stable maintenance of the plasmid by enabling it to correct downward deviations in copy number that result from imprecision of the plasmid-encoded partitioning system.     

Cloning of genes related to exo-beta-glucanase production in Saccharomyces cerevisiae: characterization of an exo-beta-glucanase structural gene

The EXG1 gene of Saccharomyces cerevisiae was cloned and identified by complementation of a mutant strain (exg1-2) with highly reduced extracellular exo-beta-1,3-glucanase (EXG) activity. Two recombinant plasmids containing an overlapping region of 5.2 kb were isolated from a genomic DNA library and characterized by restriction mapping. The coding region was located by subcloning the original DNA inserts in a 2.7-kb HindIII-XhoI fragment. Exg+ strains and Exg- mutants transformed with yeast multicopy plasmids containing this DNA fragment showed an EXG activity 5- to 20-fold higher than for the untransformed Exg+ wild-type (wt) strains. The overproduced EXG had the same enzymic activity on different substrates, and showed the same electrophoretic behaviour on polyacrylamide gels and identical properties upon filtration through Sephacryl S-200 as those of the main EXG from Exg+ wt strains. The EXG1 gene transformed Schizosaccharomyces pombe, yielding extracellular EXG activity which showed cross-reactivity with anti-S. cervisiae EXG antibodies. A fragment including only a part of the EXG1 region was subcloned into the integrating vector YIp5, and the resulting plasmid was used to transform an Exg+ strain. Genetic and Southern analysis of several stable Exg- transformants showed that the fragment integrated by homology with the EXG1 locus. The chromosomal DNA fragment into which the plasmid integrated has a restriction pattern identical to that of the fragment on which we had previously identified the putative EXG1 gene. Only one copy of the EXG1 gene per genome was found in several strains tested by Southern analysis. Furthermore, two additional recombinant plasmids sharing a yeast DNA fragment of about 4.1 kb, which partially complements the exg1-2 mutation but which shows no homology with the 2.7-kb fragment containing the EXG1 gene, were also identified in this study. This 4.1-kb DNA fragment does not appear to contain an extragenic suppressor and could be related in some way to EXG production in S. cerevisiae.     

Nuclear plasmids in the Dictyostelium slime molds

Cellular slime molds are one of only three types of eukaryotes known to contain circular nuclear plasmids. Unlike the 2-microns circle in Saccharomyces, different strains of Dictyostelium can carry different, nonhomologous plasmids. Covalently closed, circular DNA plasmids have been identified in D. discoideum, D. mucoroides, D. giganteum, and D. purpureum. These plasmids range in size from 1.3-27 kb and in copy number from 50-300 molecules per cell. Plasmids have been identified in approximately one-fifth of all isolates examined. The organization of their DNA in nucleosomes establishes their presence in the nucleus. We have successfully cotransformed endogenous Dictyostelium plasmids into D. discoideum using the G418 resistance shuttle vector B10S. Transformants carrying D. discoideum plasmids are recovered at much higher frequency than those carrying plasmids from the other Dictyostelium species. We have constructed recombinant plasmids based on the D. discoideum plasmid Ddp2 and the G418 resistance gene. With these extrachromosomal vectors, transformed cells are recovered at frequencies of up to 10(-4) per input cell, the vectors are stably maintained at high copy number in the absence of selection, and the vectors can be used to introduce foreign DNA sequences into D. discoideum cells.     

Linear- and circular-plasmid copy numbers in Borrelia burgdorferi.

Borrelia burgdorferi, the Lyme disease agent, and other members of the spirochetal genus Borrelia have double-stranded linear plasmids in addition to supercoiled circular plasmids. The copy number relative to the chromosome was determined for 49- and 16-kb linear plasmids and a 27-kb circular plasmid of the type strain, B31, of B. burgdorferi. All three plasmids were present in low copy number, about one per chromosome equivalent, as determined by relative hybridizations of replicon-specific DNA probes. The low copy number of Borrelia plasmids suggests that initiation of DNA replication and partitioning are carefully controlled during the cell division cycle. The copy numbers of these three plasmids of strain B31 were unchanged after approximately 7,000 generations in continuous in vitro culture. A clone of B. burgdorferi B31 that did not contain the 16-kb linear plasmid was obtained after exposure of a culture to novobiocin, a DNA gyrase inhibitor. The plasmid-cured strain contains only one linear plasmid, the 49-kb plasmid, and thus has the smallest genome reported to date for B. burgdorferi.     

Cloning ofCandida boidinii DNA fragments promoting autonomous replication of plasmids inSaccharomyces cerevisiae

Fragments of Candida boidinii chromosomal DNA were inserted into the integrative vector YIp-kanr and examined for the presence of sequences promoting autonomous replication of plasmids in Saccharomyces cerevisiae. Restriction maps of two plasmids, designated S6/4 and S6/5, originating from the same S. cerevisiae transformant, were constructed. Southern hybridization data confirmed that the plasmids carry sequences from the C. boidinii chromosome. Both plasmids transform S. cerevisiae strains at 4-5-fold higher frequency than cloning vectors based on the replication origin of the 2 microns plasmid. Mitotic stability of the constructed plasmids is similar to that of the 2 mu-based vector pNF2 in S. cerevisiae.     

Copy number control by a yeast centromere

Plasmids containing a cloned yeast (Saccharomyces cerevisiae) centromere (CEN3) in combination with a suitable DNA replication system are maintained in yeast at the low copy number typical of a chromosome. In composite plasmids containing CEN3 plus the yeast 2 mu plasmid, the CEN3 copy number control is dominant over the amplification system that normally drives the 2 mu plasmids to high copy number. The CEN3-2 mu composite plasmids are relatively stably maintained in yeast at a copy number of about one per haploid genome, and segregate through meiosis in a typical Mendelian pattern. Some of the CEN3-2 mu composite plasmids isolated from yeast contain deletions of variable size that remove the functional centromere, resulting in loss of the CEN3 control and reversion to high copy number. Formation of the CEN3 deletions requires the specialized recombination system (inverted repeat sequences and FLP gene) of the yeast 2 mu plasmid.     

Replicative transformation of the filamentous fungus Ashbya gossypii with plasmids containing Saccharomyces cerevisiae ARS elements.

We have developed a transformation system for the filamentous ascomycete fungus Ashbya gossypii. Mycelial protoplasts were transformed to geneticin-resistance with plasmids containing the Escherichia coli kanamycin-resistance gene as a selectable marker and autonomously replicating sequences (ARS) from Saccharomyces cerevisiae (ARS1, 2 mu ARS). Transformation frequencies of up to 63 transformants per microgram of plasmid DNA were obtained. The transformants were unstable under nonselective conditions. Southern analysis of DNA separated by conventional and pulsed-field-gel electrophoresis showed that the transforming DNA was present as autonomously replicating plasmid. Plasmid integration into chromosomal DNA was not detected. We concluded that the S. cerevisiae ARS elements are functional in A. gossypii, since vectors lacking such elements did not yield transformants.     

Versatile use of Schizosaccharomyces pombe plasmids in Saccharomyces cerevisiae

The two model yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe appear to have diverged 1000 million years ago. Here, we describe that S.?pombe vectors can be propagated efficiently in S.?cerevisiae as pUR19 derivatives, and the pREP and pJR vector series carrying the S.?cerevisiae LEU2 or the S.?pombe ura4(+) selection marker are maintained in S.?cerevisiae cells. In addition, genes transcribed from the S.?pombe nmt1(+) promoter and derivatives are expressed in budding yeast. Thus, S.?pombe vectors can be used as shuttle vectors in S.?cerevisiae and S.?pombe. Our finding greatly facilitates the testing for functional orthologs of protein families and simplifies the cloning of new S.?pombe plasmids by using the highly efficient in vivo homologous recombination activity of S.?cerevisiae.     

Expression inEscherichia coliof Y5-Mutant and N-terminal Domain-Deleted DNA Gyrase B Proteins Affects Strongly Plasmid Maintenance

Escherichia coliDNA gyrase B subunit (GyrB) is composed of a 43-kDa N-terminal domain containing an ATP-binding site and a 47-kDa C-terminal domain involved in the interaction with the gyrase A subunit (GyrA). Site-directed mutagenesis was used to substitute, in both the entire GyrB subunit and its 43-kDa N-terminal fragment, the amino acid Y5 by either a serine (Y5S) or a phenylalanine residue (Y5F). Under standard conditions, cells bearing Y5S or Y5F mutant GyrB expression plasmids produced significantly less recombinant proteins than cells transformed with the wild-type plasmid. This dramatic decrease in expression of mutant GyrB proteins was not observed when the corresponding N-terminal 43-kDa mutant plasmids were used. Examination of the plasmid content of the transformed cells after induction showed that the Y5F and Y5S GyrB protein level was correlated with the plasmid copy number. By repressing tightly the promoter activity encoded by these expression vectors during cell growth, it was possible to restore the normal level of the mutant GyrB encoding plasmids in the transformed bacteria. Treatment with chloramphenicol before protein induction enabled large overexpression of the GyrB mutant Y5F and Y5S proteins. In addition, the decrease in plasmid copy number was also observed when the 47-kDa C-terminal fragment of the GyrB subunit was expressed in bacteria grown under standard culture conditions. Analysis of DNA supercoiling and relaxation activities in the presence of GyrA demonstrated that purified Y5-mutant GyrB proteins were deficient for ATP-dependent gyrase activities. Taken together, these results show that Y5F and Y5S mutant GyrB proteins, but not the corresponding 43-kDa N-terminal fragments, competein vivowith the bacterial endogenous GyrB subunit of DNA gyrase, thereby reducing the plasmid copy number in the transformed bacteria by probably acting on the level of negative DNA supercoilingin vivo.This competition could be mediated by the presence of the intact 47-kDa C-terminal domain in the Y5F and Y5S mutant GyrB subunits. This study demonstrates also that the amino acid Y5 is a crucial residue for the expression of the gyrase B activityin vivo.Thus, ourin vivoapproach may also be useful for detecting other important amino acids for DNA gyrase activity, as mutations affecting the ATPase activity or the GyrB/GyrB or GyrB/GyrA protein interactions.     

Transformation systems of non-Saccharomyces yeasts

This review describes the transformation systems including vectors, replicons, genetic markers, transformation methods, vector stability, and copy numbers of 13 genera and 31 species of non-Saccharomyces yeasts. Schizosaccharomyces pombe was the first non-Saccharomyces yeast studied for transformation and genetics. The replicons of non-Saccharomyces yeast vectors are from native plasmids, chromosomal DNA, and mitochondrial DNA of Saccharomyces cerevisiae, non-Saccharomyces yeasts, protozoan, plant, and animal. Vectors such as YAC, YCp, YEp, YIp, and YRp were developed for non-Saccharomyces yeasts. Forty-two types of genes from bacteria, yeasts, fungi, and plant were used as genetic markers that could be classified into biosynthetic, dominant, and colored groups to construct non-Saccharomyces yeasts vectors. The LEU2 gene and G418 resistance gene are the two most popular markers used in the yeast transformation. All known transformation methods such as spheroplast-mediating method, alkaline ion treatment method, electroporation, trans-kingdom conjugation, and biolistics have been developed successfully for non-Saccharomyces yeasts, among which the first three are most widely used. The highest copy number detected from non-Saccharomyces yeasts is 60 copies in Kluyveromyces lactis. No general rule is known to illustrate the transformation efficiency, vector stability, and copy number, although factors such as vector composition, host strain, transformation method, and selective pressure might influence them.     

Expression of the cloned uracil permease gene of Saccharomyces cerevisiae in a heterologous membrane

A piece of DNA of the yeast Saccharomyces cerevisiae complementing the uracil permease gene was introduced into a plasmid able to replicate autonomously in Schizosaccharomyces pombe. A strain of S. pombe lacking uracil transport activity was transformed with this new plasmid carrying the gene of S. cerevisiae. The behaviour of the transformant shows not only an expression of the uracil permease gene in the heterologous membrane but also that the transport of uracil is active and coupled to the energy furnishing system of the heterologous host.     

The 2-micron plasmid as a nonselectable, stable, high copy number yeast vector

The endogenous 2-microns plasmid of Saccharomyces cerevisiae has been used extensively for the construction of yeast cloning and expression plasmids because it is a native yeast plasmid that is able to be maintained stably in cells at high copy number. Almost invariably, these plasmid constructs, containing some or all 2-microns sequences, exhibit copy number levels lower than 2-microns and are maintained stably only under selective conditions. We were interested in determining if there was a means by which 2-microns could be utilized for vector construction, without forfeiting either copy number or nonselective stability. We identified sites in the 2-microns plasmid that could be used for the insertion of genetic sequences without disrupting 2-microns coding elements and then assessed subsequent plasmid constructs for stability and copy number in vivo. We demonstrate the utility of a previously described 2-microns recombination chimera, pBH-2L, for the manipulation and transformation of 2-microns as a pure yeast plasmid vector. We show that the HpaI site near the STB element in the 2-microns plasmid can be utilized to clone yeast DNA of at least 3.9 kb with no loss of plasmid stability. Additionally, the copy number of these constructs is as high as levels reported for the endogenous 2-microns.