High-frequency transformation of a methylotrophic yeast, Candida boidinii, with autonomously replicating plasmids which are also functional in Saccharomyces cerevisiae.

We have developed a transformation system which uses autonomous replicating plasmids for a methylotrophic yeast, Candida boidinii. Two autonomous replication sequences, CARS1 and CARS2, were newly cloned from the genome of C. boidinii. Plasmids having both a CARS fragment and the C. boidinii URA3 gene transformed C. boidinii ura3 cells to Ura+ phenotype at frequencies of up to 10(4) CFU/micrograms of DNA. From Southern blot analysis, CARS plasmids seemed to exist in polymeric forms as well as in monomeric forms in C. boidinii cells. The C. boidinii URA3 gene was overexpressed in C. boidinii on these CARS vectors. CARS1 and CARS2 were found to function as an autonomous replicating element in Saccharomyces cerevisiae as well. Different portions of the CARS1 sequence were needed for autonomous replicating activity in C. boidinii and S. cerevisiae. C. boidinii could also be transformed with vectors harboring a CARS fragment and the S. cerevisiae URA3 gene.     

Directed mutagenesis in Candida albicans: one-step gene disruption to isolate ura3 mutants.

A method for introducing specific mutations into the diploid Candida albicans by one-step gene disruption and subsequent UV-induced recombination was developed. The cloned C. albicans URA3 gene was disrupted with the C. albicans ADE2 gene, and the linearized DNA was used for transformation of two ade2 mutants, SGY-129 and A81-Pu. Both an insertional inactivation of the URA3 gene and a disruption which results in a 4.0-kilobase deletion were made. Southern hybridization analyses demonstrated that the URA3 gene was disrupted on one of the chromosomal homologs in 15 of the 18 transformants analyzed. These analyses also revealed restriction site dimorphism of EcoRI at the URA3 locus which provides a unique marker to distinguish between chromosomal homologs. This enabled us to show that either homolog could be disrupted and that disrupted transformants of SGY-129 contained more than two copies of the URA3 locus. The A81-Pu transformants heterozygous for the ura3 mutations were rendered homozygous and Ura- by UV-induced recombination. The homozygosity of a deletion mutant and an insertion mutant was confirmed by Southern hybridization. Both mutants were transformed to Ura+ with plasmids containing the URA3 gene and in addition, were resistant to 5-fluoro-orotic acid, a characteristic of Saccharomyces cerevisiae ura3 mutants as well as of orotidine-5'-phosphate decarboxylase mutants of other organisms.     

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.     

Transformation system for an asporogenous methylotrophic yeast, Candida boidinii: cloning of the orotidine-5''-phosphate decarboxylase gene (URA3), isolation of uracil auxotrophic mutants, and use of the mutants for integrative transformation.

An integrative transformation system was established for an asporogenous methylotrophic yeast, Candida boidinii. This system uses a uracil auxotrophic mutant of C. boidinii as the host strain in combination with its URA3 gene as the selectable marker. First, the C. boidinii URA3 gene coding for orotidine-5'-phosphate decarboxylase (ODCase) was cloned by using complementation of the pyrF mutation of Escherichia coli. Next, the host ODCase-negative mutant strains (ura3 strains) were isolated by mutagenesis and selection for 5-fluro-orotic acid (5-FOA) resistance. Five ura3 host strains that exhibited both a low reversion rate and good methylotrophic growth were obtained. All of these strains could be transformed to Ura+ phenotype with a C. boidinii URA3-harboring plasmid linearized within the Candida DNA. The transformants had a stable Ura+ phenotype after nonselective growth for 10 generations. These results and extensive Southern analysis indicated that the linearized plasmid was integrated into the host chromosomal DNA by homologous recombination at the URA3 locus in C. boidinii.     

Isolation of the URA5 gene from Cryptococcus neoformans var. neoformans and its use as a selective marker for transformation.

A cDNA encoding Cryptococcus neoformans orotidine monophosphate pyrophosphorylase (OMPPase) has been isolated by complementation of the cognate Escherichia coli pyrE mutant. The cDNA was used as a probe to isolate a genomic DNA fragment encoding the OMPPase gene (URA5). By using electroporation for the introduction of plasmid DNA containing the URA5 gene, C. neoformans ura5 mutants could be transformed at low efficiency. Ura+ transformants obtained with supercoiled plasmids containing the URA5 gene showed marked mitotic instability and contained extrachromosomal URA5 sequences, suggesting limited ability to replicate within C. neoformans. Transformants obtained with linear DNA were of two classes: stable transformants with integrated URA5 sequences, and unstable transformants with extrachromosomal URA5 sequences.     

Isolation of telomerelike sequences from Cryptococcus neoformans and their use in high-efficiency transformation.

Development of a transformation system for the fungal human pathogen Cryptococcus neoformans is an important prerequisite for the identification of genes involved in virulence. It has previously been reported that low-efficiency transformation can be achieved by using the cloned C. neoformans URA5 gene and ura5 mutants. The introduction of linearized URA5 vectors into C. neoformans resulted in unstable transformants which apparently harbored linear extrachromosomal DNA molecules. In this paper, the nature of these molecules is confirmed to be linear by exonuclease digestion. Recovery of the extrachromosomal DNA in Escherichia coli and sequence analysis demonstrates that repeats characteristic of telomeric DNA have been added to the ends of the introduced DNA. The recovered plasmids are capable of transforming at much higher efficiencies either in the supercoiled state (up to 200 transformants per microgram) or the linear state (up to 90,000 transformants per microgram).     

Development of an integrative DNA transformation system for the yeast Candida tropicalis.

We developed the alkane and fatty-acid utilizing yeast Candida tropicalis as a host for DNA transformations. The system is based on an auxotrophic mutant host of C. tropicalis which is defective in orotidine monophosphate decarboxylase (ura3). The ura3 host was isolated by mutagenesis and a double-selection procedure that combined nystatin enrichment selection and 5-fluoro-orotic acid resistance selection. As a selectable marker, we isolated and characterized the C. tropicalis URA3 gene. Plasmid vectors that contained the C. tropicalis URA3 gene transformed the C. tropicalis mutant host at a frequency of 10(3) to 10(4) transformants per micrograms of plasmid DNA. Vectors that contained the Saccharomyces cerevisiae URA3 gene could not transform C. tropicalis. DNA transfer was accomplished by modified versions of either spheroplast generation (CaCl2-polyethylene glycol)-fusion or cation (LiCl) procedures developed for S. cerevisiae. Plasmid vectors that had been cut within the C. tropicalis URA3 fragment integrated by homologous recombination at the URA3 locus.     

Directed mutagenesis in an asporogenous methylotrophic yeast: cloning, sequencing, and one-step gene disruption of the 3-isopropylmalate dehydrogenase gene (LEU2) of Candida boidinii to derive doubly auxotrophic marker strains.

A model system for one-step gene disruption for an asporogenous methylotrophic yeast, Candida boidinii, is described. In this system, the 3-isopropylmalate dehydrogenase gene (C. boidinii LEU2) was selected as the target gene for disruption to derive new host strains for transformation. First, the C. boidinii LEU2 gene was cloned, and its complete nucleotide sequence was determined. Next, the LEU2 disruption vectors, which had the C. boidinii URA3 gene as the selectable marker, were constructed. Of the Ura+ transformants obtained with these plasmids, more than half showed a Leu- phenotype. Finally, the double-marker strains of C. boidinii were derived. When vectors with repeated flanking sequences of the C. boidinii URA3 gene were used for gene disruption, Leu- Ura+ transformants changed spontaneously to a Leu- Ura- phenotype ca. 100 times more frequently than they did when plasmids without the repeated sequences were used. Southern analysis showed that these events included a one-step gene disruption and a subsequent popping out of the C. boidinii URA3 sequence from the transformant chromosome.     

New yeast vectors containing the autonomously replicating sequences from Candida maltosa genome

Two different DNA sequences from the yeast Candida maltosa confer the ability to replicate autonomously to the yeast integrative vector pLD700 on which they are cloned. The recombinant plasmids pLD701 and pLD702 with autonomously replicating sequences (ARS) from Candida maltosa and LEU2 gene from Saccharomyces cerevisiae transform the auxotrophic strain S. cerevisiae DC5 with the efficiency 3-5 x 10(3) per microgram of DNA. Like other yeast vectors harbouring ARS, these plasmids are not stable in yeast cells. Restriction and hybridization analyses have revealed the pLD701 plasmid to contain ARS from chromosomal DNA of C. maltosa. Plasmid pLD701 appears to be a useful vector for yeast transformation.     

Identification of autonomously replicating circular subtelomeric Y'' elements in Saccharomyces cerevisiae.

We marked a large number of yeast telomeres within their Y' regions by transforming strains with a fragment of Y' DNA into which the URA3 gene had been inserted. A few of the Ura+ transformants obtained were very unstable and were found to contain autonomously replicating URA3-marked circular Y' elements in high copy number. These marked extrachromosomal circles were capable of reintegrating into the chromosome at other telomeric locations. In contrast, most of the Ura+ transformants obtained were quite stable mitotically and were marked at bona fide chromosomal ends. These stable transformants gave rise to mitotically unstable URA3-marked circular Y' elements at a low frequency (up to 2.5%). The likelihood that such excisions and integrations represent a natural process in Saccharomyces cerevisiae is supported by our identification of putative Y' circles in untransformed strains. The transfer of Y' information among telomeres via a circular intermediate may be important for homogenizing the sequences at the ends of yeast chromosomes and for generating the frequent telomeric rearrangements that have been observed in S. cerevisiae.     

Cloned mouse DNA fragments can replicate in a simian virus 40 T antigen-dependent system in vivo and in vitro.

Mouse liver DNA was cut out with BamHI and cloned into YIp5, which contained the URA3 gene of Saccharomyces cerevisiae in pBR322. Of the several plasmids isolated, two plasmids, pMU65 and pMU111, could transform S. cerevisiae from the URA- to the URA+ phenotype and could replicate autonomously within the transformant, indicating that mouse DNA fragments present in pMU65 or pMU111 contain autonomously replicating sequences (ARS) for replication in S. cerevisiae. Furthermore, to determine the correlation between ARS function in yeast cells and that in much higher organisms, we tried to challenge these plasmids with the simian virus 40 (SV40) DNA replication system. Of the two plasmids tested, the EcoRI-BglII region of pMU65 could be hybridized with a chemically synthesized 13-nucleotide fragment corresponding to the origin region of SV40 DNA. Both pMU65 (the EcoRI-BglII region cloned in pBR322) and its subclone pMU65EB could replicate semiconservatively, and initiation of DNA replication started from the EcoRI-BglII region when the replicating activity of these plasmids was tested in the in vitro SV40 DNA replication system we have established before. Furthermore, pMU65 and pMU65EB could replicate autonomously within monkey Cos cells which produce SV40 T antigen constitutively. These results show that a 2.5-kilobase fragment of the EcoRI-BglII region in pMU65 contains the ARS needed for replication in the SV40 DNA replication system.     

Development of a transformation system for gene knock-out in the flavinogenic yeast Pichia guilliermondii

Pichia guilliermondii is a representative of a yeast species, all of which over-synthesize riboflavin in response to iron deprivation. Molecular genetic studies in this yeast species have been hampered by a lack of strain-specific tools for gene manipulation. Stable P. guilliermondii ura3 mutants were selected on the basis of 5'-fluoroorotic acid resistance. Plasmid carrying Saccharomyces cerevisiae URA3 gene transformed the mutant strains to prototrophy with a low efficiency. Substitution of a single leucine codon CUG by another leucine codon CUC in the URA3 gene increased the efficiency of transformation 100 fold. Deletion cassettes for the RIB1 and RIB7 genes, coding for GTP cyclohydrolase and riboflavin synthase, respectively, were constructed using the modified URA3 gene and subsequently introduced into a P. guilliermondii ura3 strain. Site-specific integrants were identified by selection for the Rib(-) Ura(+) phenotype and confirmed by PCR analysis. Transformation of the P. guilliermondii ura3 strain was performed using electroporation, spheroplasting or lithium acetate treatment. Only the lithium acetate transformation procedure provided selection of uracil prototrophic, riboflavin deficient recombinant strains. Depending on the type of cassette, efficiency of site-specific integration was 0.1% and 3-12% in the case of the RIB1 and RIB7 genes, respectively. We suggest that the presence of the ARS element adjacent to the 3' end of the RIB1 gene significantly reduced the frequency of homologous recombination. Efficient gene deletion in P. guilliermondii can be achieved using the modified URA3 gene of S. cerevisiae flanked by 0.8-0.9 kb sequences homologous to the target gene.     

Direct Cloning of Yeast Genes from an Ordered Set of Lambda Clones in Saccharomyces Cerevisiae by Recombination in Vivo

We describe a technique that facilitates the isolation of yeast genes that are difficult to clone. This technique utilizes a plasmid vector that rescues lambda clones as yeast centromere plasmids. The source of these lambda clones is a set of clones whose location in the yeast genome has been determined by L. Riles et al. in 1993. The Esherichia coli-yeast shuttle plasmid carries URA3, ARS4 and CEN6, and contains DNA fragments from the lambda vector that flank the cloned yeast insert. When yeast is cotransformed with linearized plasmid and lambda clone DNA, Ura(+) transformants are obtained by a recombination event between the lambda clone and the plasmid vector that generates an autonomously replicating plasmid containing the cloned yeast DNA sequences. Genes whose genetic map positions are known can easily be identified and recovered in this plasmid by testing only those lambda clones that map to the relevant region of the yeast genome for their ability to complement the mutant phenotype. This technique facilitates the isolation of yeast genes that resist cloning either because (1) they are underrepresented in yeast genomic libraries amplified in E. coli, (2) they provide phenotypes that are too marginal to allow selection of the gene by genetic complementation or (3) they provide phenotypes that are laborious to score. We demonstrate the utility of this technique by isolating three genes, GAL83, SSN2 and MAK7, each of which presents one of these problems for cloning.     

Identification of the Orotidine-5′-Phosphate Decarboxylase Gene and Development of a Transformation System in the Yeast Saccharomyces exiguus Yp74L-3

To investigate the uracil biosynthetic pathway of the yeast Saccharomyces exiguus Yp74L-3, uracil auxotrophic mutants were isolated. Using conventional genetic techniques, four mutant genes concerned in uracil biosynthesis were identified and denoted as ura1, ura2, ura3, and ura4. Mutations in the URA3 and URA4 genes were specifically selected with 5-fluoroorotic acid (5-FOA). Vector plasmids containing the URA3 gene and an autonomously replicating sequence (ARS) of S. cerevisiae produced sufficient amounts of Ura⁺ transformants from the ura4 mutant of S. exiguus. This fact indicates that the S. exiguus URA4 gene encodes orotidine-5′-phosphate decarboxylase (OMP decarboxylase) and demonstrates that vector plasmids for S. cerevisiae are also usable in S. exiguus.     

Construction of a new yeast cloning vector containing autonomous replication sequences from Candida utilis.

DNA sequences from the Candida utilis genome which, when cloned into a yeast integration plasmid (YIp5), confer on YIp5 the ability to replicate autonomously in Saccharomyces cerevisiae are described. Several recombinant plasmids which transform S. cerevisiae YNN27 to Ura3+ with an efficiency of 2 X 10(3) transformants per microgram of DNA were obtained. One of the recombinant plasmids, pHMR22 (6.6 kilobases) contains ars (autonomous replication sequence), which is homologous with two different DNA fragments of the C. utilis genome but has no detectable homology to total DNA from Candida albicans, Pachysolen tannophilus, or S. cerevisiae. Restriction and subcloning analyses of pHMR22 showed that Sau3A destroys the functions of cloned ars whereas there are no BamHI, PstI, SalI, HindIII, EcoRI, or PvuII sites in the region of ars which is required for its functional integrity. Thus, pHMR22 appears to be a useful vector for cloning desired genes in S. cerevisiae.     

A reorganized Candida albicans DNA sequence promoting homologous non-integrative genetic transformation

In order to develop plasmids adequate for non-integrative genetic transformation of Candida albicans, a DNA fragment of 15.3 kb was cloned from this organism on the basis of its capacity to convert the integrative Saccharomyces cerevisiae vector YIp5 into a non-integrative one. Southern hybridization analysis, carried out with a labelled DNA probe of 3.6 kb derived from the cloned fragment, showed that it consisted of C. albicans DNA, the hybridization pattern indicating that the corresponding sequences were homologous to several chromosomal regions. The size of the C. albicans DNA promoting autonomous replication in S. cerevisiae was substantially reduced by subcloning. A 5.1 kb subfragment, defined by BamHI and SalI restriction sites, retained autonomous replication sequences (ARS) functional in the heterologous S. cerevisiae system and in C. albicans, when inserted in plasmid constructions that carried a S. cerevisiae trichodermin-resistance gene (tcm1) as selection marker. C. albicans transformants were both of the integrative and the non-integrative type and the plasmids recovered from the latter very often carried a reorganized ARS, indicating that recombination of the inserted ARS DNA had occurred in the homologous host. Successive reorganizations of the ARS insert in C. albicans eventually led to a more stable and much smaller fragment of 687 bp that was subsequently recovered unchanged from transformants. Sequence analysis of the 687 bp fragment revealed four 11-base blocks, rich in A+T, that carried the essential consensus sequence considered relevant for yeast ARS elements in addition to other features also described as characteristic of yeast replication origins.     

Random AT library: autonomously replicating sequence (ARS) activity of chemically synthesized random sequences for transformation of nonconventional yeast species

In a search for sequences that confer on bacterial plasmids the capacity of autonomous replication in yeast cells, we chemically synthesized polynucleotides 80 bp in length from an equimolar mixture of A and T. The random AT-polymer population, W80, was inserted into the plasmid YIp5-Kan1 (which carries the markers URA3 and G418(R), but does not replicate in yeast) and amplified in Escherichia coli. This library, representing 10 000 different AT sequences, was transformed into three species of yeast: Saccharomyces cerevisiae, Kluyveromyces lactis and Torulaspora delbrueckii. The aim was to evaluate the frequency, if any, of autonomously replicating sequences (ARSs) in the random sequences. A large number of transformants were obtained from each species. Many of them showed a stable transformed phenotype. Several W80 sequences were found many times for a given species, suggesting that each species preferred particular sequences for ARS function, although they are diverse in their primary sequence. In view of the high frequency and stability of the replicative plasmids found in the different hosts, this small random AT library may be conveniently used as a source of replicative gene vectors for genetic manipulation of many nonconventional yeast species, in place of searching for species-specific chromosomal ARSs.     

Interaction between phosphatidylserine vesicles and rat brain synaptosomes

Five different DNA sequences of Phanerochaete chrysosporium capable of supporting autonomous replication of yeast integration plasmid (YIp5) in Saccharomyces cerevisiae were isolated. These hybrid plasmids with the autonomous replication sequences from P. chrysosporium are maintained extra-chromosomally, are mitotically unstable and transform Ura3 deletion mutant of S. cerevisiae to Ura+ phenotype with high frequency. The autonomous replication sequence in pRR2, one of the recombinant plasmids, was further characterized and was shown to be homologous to P. chrysosporium genomic DNA. Restriction analyses showed that this plasmid has unique PvuII and SalI restriction sites for cloning.