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.     

Construction of a host-vector system in Candida maltosa by using an ARS site isolated from its genome.

To construct a host-vector system in an n-alkane-assimilating yeast, Candida maltosa, the isolation of an ARS site from its genome which replicates autonomously in C. maltosa was attempted. Leu- mutants of C. maltosa were transformed with a gene library prepared by using YEp13 (LEU2+) as a vector, and Leu+ transformants were obtained at a high frequency. A plasmid named pCS1 was isolated from the recipient cells. pCS1 contained a 6.3-kilobase (kb) fragment of the C. maltosa genome, and a 3.8-kb fragment with ARS activity was subcloned and designated the TRA (transformation ability) region. Vectors (pTRA1 and pTRA11) for C. maltosa J288 were constructed that contained this 3.8-kb fragment, pBR322, and the LEU2 gene of Saccharomyces cerevisiae. Transformation of C. maltosa J288 with these plasmids was successful by both spheroplast and lithium acetate methods. Southern blot analysis suggested that the copy number of pTRA1 in C. maltosa was between 10 and 20, and it was stably maintained during growth without selective pressure in the medium. It was also found that these vectors could transform S. cerevisiae leu2- to LEU2+, suggesting that the TRA region contained an ARS site(s) that was specific not only for C. maltosa but also for S. cerevisiae.     

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.     

Yeast 2μm vectors replicate and undergo recombination in Torulaspora delbrueckii

In order to develop a procedure for transformation of the industrial yeast Torulaspora delbrueckii, we have constructed a set of recombinant plasmids carrying Saccharomyces cerevisiae ARS and 2 microns origin of replication and kanamycin-G418 resistance gene of Tn903(601) as a selective marker. In this paper we show that S. cerevisiae ARS vectors can replicate autonomously and that vectors bearing the whole S. cerevisiae 2 microns sequence yield stable transformants. We also present evidence to show that 2 microns vectors undergo an FLP-mediated inter- and intramolecular recombination, which suggests that T. delbrueckii can support the amplification and partition mechanisms of these plasmids.     

非常规酵母基因工程表达系统

非常规酵母系指除了酿酒酵母与粟裂殖酵母之外的酵母曹。非常规酵母可利用其自主复制序列构建载体,但整合载体是进行外源基因导入的主要方式。非常规酵母的转化有一定的宿主范围,可采用与酿酒酵母相同的方法,最常用的仍为化学法。高效表达元件可利用酿酒酵母的强启动子,也可以根据非常规酵母菌的代谢特点寻找强启动子．本文综述了近年来应用非常规酵母基因表达系统表达外源基因的一些实例。     

Construction of an effective host-vector system for the yeast Saccharomyces exiguus Yp74L-3.

An effective host-vector system specific to the yeast Saccharomyces exiguus Yp74L-3 was constructed to promote the molecular genetic analyses for the yeast. To obtain a stable reversionless host strain, we constructed an S. exiguus strain carrying leu2::ScURA3 by disrupting the S. exiguus LEU2 gene with the S. cerevisiae URA3 gene. A vector plasmid unique to S. exiguus was subsequently developed by inserting both the LEU2 gene and an ARS cloned from S. exiguus into an Escherichia coli phagemid, pUC119. The vector constructed, pTH119 was able to transform the S. exiguus leu2::ScURA3 strain to Leu+ efficiently. The stability of the vector in the S. exiguus host cells resembled that of a YRp-type vector in S. cerevisiae.     

Mechanism of high-copy-number integration of pMIRY-type vectors into the ribosomal DNA of Saccharomyces cerevisiae

Targeted integration of the yeast plasmid pMIRY2 into the ribosomal DNA (rDNA) of Saccharomyces cerevisiae by homologous recombination results in transformants carrying 100-200 copies of the plasmid per cell which are stably maintained over a large number of generations [Lopes et al., Gene 79 (1989) 199-206]. These properties make pMIRY2 an attractive vector for high-level production of (heterologous) proteins by yeast cells. We have investigated the mechanism underlying high-copy-number (hcn) integration of pMIRY-type plasmids and show that either targeting to a location outside the rDNA locus or use of the wild-type LEU2, instead of the deficient LEU2d gene, as selection marker reduces the copy number to the low value characteristic of standard integrating (YIp-type) yeast plasmids. Further experiments demonstrate that the hcn of pMIRY-type plasmids is achieved by amplification of a small number of copies initially integrated into the rDNA locus. Amplification depends upon the strong selection pressure created by the extremely low expression of the deficient LEU2d gene, but not on the presence of this gene per se. The hcn integration also occurs when either the TRP1 or URA3 gene is used as the selection marker, provided expression of the marker gene is severely curtailed, e.g., by removal of most of its 5'-flanking region.     

The presence of a defective LEU2 gene on 2 mu DNA recombinant plasmids of Saccharomyces cerevisiae is responsible for curing and high copy number.

The copy number of 2 mu DNA-derived plasmids in CIR+ Saccharomyces cerevisiae transformants is determined by its selective marker and is usually much lower than that of the endogenous plasmid. Only plasmids containing the leu2 allele of pJDB219, designated as leu2-d, under selective conditions displayed a higher copy number than did endogenous 2 mu DNA and by displacement generated cured cells. Spontaneous loss of 2 mu DNA occurred with a frequency of about 0.02% per generation. Curing plasmids, like pMP78, have copy numbers of 35; noncuring plasmids, like pDB248 or YEp6, have copy numbers of 4 to 8. The 2 mu DNA copy number in strains AH22 and YNN27 were determined to be 40 and 100, respectively. The high copy number of leu2-d-containing plasmids can be explained by its weak expression of less than 5% that of the wild-type LEU2 gene. The leu2-d allele has a deletion of the 5'-end sequence starting from 29 base pairs before the ATG initiation codon, but surprisingly, its expression is still regulated. On YRp7, which contains the chromosomal autonomic replication sequence ARS1, the defective leu2-d allele could not complement a leu2 host strain. This suggests a more stringent control of replication of ARS1-containing plasmids than of 2 mu-containing plasmids.     

High-efficiency transformation of Pichia stipitis based on its URA3 gene and a homologous autonomous replication sequence, ARS2.

This paper describes the first high-efficiency transformation system for the xylose-fermenting yeast Pichia stipitis. The system includes integrating and autonomously replicating plasmids based on the gene for orotidine-5'-phosphate decarboxylase (URA3) and an autonomous replicating sequence (ARS) element (ARS2) isolated from P. stipitis CBS 6054. Ura- auxotrophs were obtained by selecting for resistance to 5-fluoroorotic acid and were identified as ura3 mutants by transformation with P. stipitis URA3. P. stipitis URA3 was cloned by its homology to Saccharomyces cerevisiae URA3, with which it is 69% identical in the coding region. P. stipitis ARS elements were cloned functionally through plasmid rescue. These sequences confer autonomous replication when cloned into vectors bearing the P. stipitis URA3 gene. P. stipitis ARS2 has features similar to those of the consensus ARS of S. cerevisiae and other ARS elements. Circular plasmids bearing the P. stipitis URA3 gene with various amounts of flanking sequences produced 600 to 8,600 Ura+ transformants per micrograms of DNA by electroporation. Most transformants obtained with circular vectors arose without integration of vector sequences. One vector yielded 5,200 to 12,500 Ura+ transformants per micrograms of DNA after it was linearized at various restriction enzyme sites within the P. stipitis URA3 insert. Transformants arising from linearized vectors produced stable integrants, and integration events were site specific for the genomic ura3 in 20% of the transformants examined. Plasmids bearing the P. stipitis URA3 gene and ARS2 element produced more than 30,000 transformants per micrograms of plasmid DNA. Autonomously replicating plasmids were stable for at least 50 generations in selection medium and were present at an average of 10 copies per nucleus.     

Development of a transformation system for the flavinogenic yeast Candida famata

Riboflavin-overproducing mutants of the flavinogenic yeast Candida famata are used for industrial riboflavin production. This paper describes the development of an efficient transformation system for this species. Leucine-deficient mutants have been isolated from C. famata VKM Y-9 wild-type strain. Among them leu2 mutants were identified by transformation to leucine prototrophy with plasmids YEp13 and PRpL2 carrying the Saccharomyces cerevisiae LEU2 gene. DNA fragments (called CfARSs) conferring increased transformation frequencies and extrachromosomal replication were isolated from a C. famata gene library constructed on the integrative vector containing the S. cerevisiae LEU2 gene as a selective marker. The smallest cloned fragment (CfARS16) has been sequenced. This one had high adenine plus thymine (A+T) base pair content and a sequence homologous to the S. cerevisiae ARS Consensus Sequence. Methods for spheroplast transformation and electrotransformation of the yeast C. famata were optimized. They conferred high transformation frequencies (up to 10(5) transformants per microg DNA) with a C. famata leu2 mutant using replicative plasmids containing the S. cerevisiae LEU2 gene as a selective marker. Riboflavin-deficient mutants were isolated from the C. famata leu2 strain and their biochemical identification was carried out. Using the developed transformation system, several C. famata genomic fragments complementing mutations of structural genes for riboflavin biosynthesis (coding for GTP cyclohydrolase, reductase, dihydroxybutanone phosphate synthase and riboflavin synthase, respectively) have been cloned.     

In vivo construction of linear vectors based on killer plasmids from Kluyveromyces lactis: selection of a nuclear gene results in attachment of telomeres.

Linear vectors based on plasmids pGKL1 and pGKL2 from Kluyveromyces lactis were obtained by in vivo recombination in Saccharomyces cerevisiae and selected for integration of the nuclear LEU2 gene. The linear hybrid molecules obtained had no proteins attached to their 5' ends, as is found for native pGKL plasmids. However, telomere-specific sequences were added to the ends of pGKL1. In contrast to the cytoplasmically localized pGKL plasmids, the newly obtained linear hybrid vectors probably replicate within the nucleus and provide evidence that the nuclear LEU2 gene cannot be expressed in the cytoplasm.     

Mutational analysis of the mitochondrial Rieske iron-sulfur protein of Saccharomyces cerevisiae. I. Construction of a RIP1 deletion strain and isolation of temperature-sensitive mutants

A protocol has been devised to permit mutational analysis of the Rieske iron-sulfur protein of the mitochondrial cytochrome bc1 complex of Saccharomyces cerevisiae. The gene for this iron-sulfur protein (RIP1) has recently been cloned and sequenced (Beckmann, J. D., Ljungdahl, P. O., Lopez, J. L., and Trumpower, B. L. (1987) J. Biol. Chem. 262, 8901-8909). We have constructed a stable yeast deletion strain, JPJ1, in which the chromosomal copy of RIP1 was displaced by the yeast LEU2 gene by homologous recombination. A linear DNA fragment containing the LEU2 gene was inserted at the breakpoints of an 800-base pair deletion of the iron-sulfur protein gene and used to transform a leu- yeast strain. Leu+ transformants were obtained which were unable to grow on nonfermentable carbon sources. Southern analysis of the transformant, JPJ1, confirmed that the chromosomal copy of the RIP1 gene was deleted and replaced by the LEU2 gene. The genotype of JPJ1 was confirmed by genetic crosses. JPJ1 cannot grow on nonfermentable carbon sources but can be complemented to respiratory competence and transformed by yeast vectors containing the wild type RIP1 gene. The ability to complement strain JPJ1 with episomally encoded iron-sulfur protein provided the basis of a selection protocol by which mutagenized plasmids containing the RIP1 gene were assayed for mutations affecting respiratory growth. Five mutants of RIP1 were identified by their ability to complement JPJ1 to temperature-sensitive respiratory growth. DNA sequence analysis demonstrated that temperature-sensitive respiratory growth resulted from single point mutations within the protein coding region of RIP1. These mutations altered a single amino acid residue in each case. Mutations were dispersed throughout the terminal two-thirds of the protein. Each mutation was recessive and did not affect fermentative growth on dextrose. However, each mutation exerted unique temperature-sensitive growth characteristics on media containing the nonfermentable carbon source glycerol.     

A family of yeast expression vectors containing the phage f1 intergenic region

The construction and characterization of a family of yeast expression vectors is described. They have the following features: plasmid replication and selection (ApR) in Escherichia coli, packaging of single-stranded (ss) DNA upon infection of E. coli with a filamentous helper phage, replication in Saccharomyces cerevisiae based on the 2 mu plasmid origin of replication (ori), selection in yeast by complementation of LEU2 (pVT-L series, size 6.3 kb) or URA3 gene (pVT-U series, size 6.9 kb) and seven unique restriction sites for cloning within an 'expression cassette' which includes the promoter and 3' sequence of the ADH1 gene. The multiple cloning site as well as the ori and intergenic region of the phage f1 have been cloned in two orientations for convenient gene cloning and ssDNA strand selection. As a result any of these eight vectors can be chosen for cloning, expressing genes in yeast, sequencing and mutagenesis without the need for recloning into specialized vectors.     

Replication in yeasts of plasmid pE194 from Staphylococcus aureus

The ability of the plasmid pE194 from S. aureus to serve as an autonomously replicating sequence (ARS) in yeast was shown. The hybrid plasmid pLD744 that contains pE194 and the yeast LEU2 gene sequences is unstable in yeast like other YRp-vectors: the mitotic stability of the pLD744 was as much as 1%. The plasmid pLD712 that differs from pLD744 by the existence of a centromeric sequence from the chromosome III of yeast Saccharomyces cerevisiae reveals about one order greater stability. The observation that there are some sequences in the primary structure of the pE194 which strongly conform to the ARS consensus in yeast inclines us to infer that the existence of ARS consensus on pE194 DNA is not sufficient for its effective replication in yeast.     

Cloning and expression of the 3-isopropylmalate dehydrogenase gene from Candida albicans

Abstract A variety of Saccharomyces cerevisiae genes e.g. HIS3, LEU2, TRP1, URA3 , are expressed in Escherichia coli and have been isolated by complementation of mutations in the corresponding E. coli genes [1]. The LEU2 gene was one of the first S. cerevisiae genes to be isolated in this way [2], and its isolation led to the development of transformation systems for S. cerevisiae [3,4]. The leuB gene in E. coli [5] and the LEU2 gene in S. cerevisiae [6] both code for 3-isopropylmalate dehydrogenase (3-IMDH; EC 1.1.1.85) which is essential for the biosynthesis of leucine in both organisms. This paper describes the cloning of a fragment of C. albicans DNA carrying the gene for 3-IMDH which will be useful in the development of transformation methods in C. albicans .     

AT-rich sequences from the arbuscular mycorrhizal fungus Gigaspora rosea exhibit ARS function in the yeast Saccharomyces cerevisiae

Autonomous replicating sequences are DNA elements that trigger DNA replication and are widely used in the development of episomal transformation vectors for fungi. In this paper, a genomic library from the mycorrhizal fungus Gigaspora rosea was constructed in the integrative plasmid YIp5 and screened in the budding yeast Saccharomyces cerevisiae for sequences that act as ARS and trigger plasmid replication. Two genetic elements (GrARS2, GrARS6) promoted high-rates of yeast transformation. Sequence analysis of these elements shows them to be AT-rich (72-80%) and to contain multiple near-matches to the yeast autonomous consensus sequences ACS and EACS. GrARS2 contained a putative miniature inverted-repeat transposable element (MITE) delimited by 28-bp terminal inverted repeats (TIRs). Disruption of this element and removal of one TIR increased plasmid stability several fold. The potential for palindromes to affect DNA replication is discussed.     

Construction of hybrid plasmids containing the yeast replicator

In Saccharomyces cerevisiae strain 6-1G-P188 about 10 per cent of rRNA genes exist as extrachromosomal copies of rDNA repeating units. These extrachromosomal copies can be isolated as covalently closed molecules with lengths around 3mu. We have constructed a set of hybrid plasmids containing the bacterial vector pBR325, the LEU2 gene of yeast encoding beta-isopropylmalatedehydrogenase and various EcoRI restriction fragments of the 3mu DNA. We have tested the ability of our hybrid plasmids to transform LEU2 strain DC5 to leucine prototrophy. One of the plasmids Rcp21/11 transforms DC5 at the frequency comparable with that obtained with YEp13, containing the 2mu DNA replication origin. The 2400 bp EcoRI-B fragment of the 3mu DNA in Rcp21/11 carries a gene for 5S rRNA and two spacers. Our results on transformation experiments allow un to suggest that this EcoRI fragment also carries the 3mu DNA replication origin. Yeast transformants containing this plasmid are highly unstable but during the prolonged growth in selective conditions the stabilization of the LEU+ phenotype is observed being most likely a result of integration of Rcp21/11 into the yeast chromosome.     

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.     

System of centromeric, episomal, and integrative vectors based on drug resistance markers for Saccharomyces cerevisiae

Integrative, centromeric, and episomal plasmids are essential for easy, fast, and reliable genetic manipulation of yeast. We constructed a system of shuttle vectors based on the widely used plasmids of the pRS series. We used genes conferring resistance to Geneticin (kanMX4), nourseothricin (natNT2), and hygromycin B (hphNT1) as markers. The centromeric and episomal plasmids that we constructed can be used the same way as the traditional auxotrophic marker-based shuttle vectors (pRS41x and pRS42x series). Additionally, we created a set of nine yeast integrative vectors with the three dominant markers. These plasmids allow for direct integration in the LEU2, URA3, and HIS3 locus of any yeast strain and the concomitant partial deletion of the gene. This prevents multiple integrations and allows for the rapid identification of correct integrants. The set of new vectors considerably enhances the flexibility of genetic manipulations and gene expression in yeast. Most notably, the new vectors allow one to work with natural yeast isolates, which do not contain auxotrophic markers.