Saccharomyces cerevisiae Shuttle vectors

Yeast shuttle vectors are indispensable tools in yeast research. They enable cloning of defined DNA sequences in Escherichia coli and their direct transfer into Saccharomyces cerevisiae cells. There are three types of commonly used yeast shuttle vectors: centromeric plasmids, episomal plasmids and integrating plasmids. In this review, we discuss the different plasmid systems and their characteristic features. We focus on their segregational stability and copy number and indicate how to modify these properties. Copyright © 2017 John Wiley & Sons, Ltd.     

In vivo cloning by homologous recombination in yeast using a two-plasmid-based system

In order to reduce the number of classical DNA manipulation and ligation steps in the generation of yeast expression plasmids, a series of vectors is described which facilitate the assembly of such plasmids by the more efficient ‘recombination in vivo’ technique. Two sets of vectors were developed. The first set, called ‘expression vectors’, contains an expression cassette with a yeast promoter and the PGK terminator separated by a polylinker, and an Escherichia coli replicon. Subcloning in these vectors of a DNA fragment generates a ‘transfer vector’ which is compatible with the second set of E. coli–yeast shuttle vectors. This set of ‘recombination vectors’ contains a cassette for a functional copy of a gene complementing a host strain auxotrophy or a bacterial gene conferring an antibiotic resistance to the plasmid-bearing host. Plasmid copy numbers can be modulated through the use of URA3 or URA3-d as the selective marker together with an ARS/CEN and the 2 μm replicon. Integration of the cloned DNAs into the yeast linearized replicative vectors occurs by recombination between homologous flanking sequences during transformation in yeast or E. coli. All the vectors contain the origin of replication of phage f1 and allow the generation of single-stranded DNA in E. coli for sequencing or site-directed mutagenesis. The sequence presented (Figure 1a) has been entered in the EMBL data library under Accession Number Z48747.     

Integrating after CEN Excision (ICE) Plasmids: Combining the ease of yeast recombination cloning with the stability of genomic integration

Yeast recombination cloning is a straightforward and powerful method for recombining a plasmid backbone with a specific DNA fragment. However, the utility of yeast recombination cloning is limited by the requirement for the backbone to contain an CEN/ARS element, which allows for the recombined plasmids to propagate. Although yeast CEN/ARS plasmids are often suitable for further studies, we demonstrate here that they can vary considerably in copy number from cell to cell and from colony to colony. Variation in plasmid copy number can pose an unacceptable and often unacknowledged source of phenotypic variation. If expression levels are critical to experimentation, then constructs generated with yeast recombination cloning must be subcloned into integrating plasmids, a step that often abrogates the utility of recombination cloning. Accordingly, we have designed a vector that can be used for yeast recombination cloning but can be converted into the integrating version of the resulting vector without an additional subcloning. We call these “ICE” vectors, for “Integrating after CEN Excision.” The ICE series was created by introducing a “rare-cutter” NotI-flanked CEN/ARS element into the multiple cloning sites of the pRS series yeast integration plasmids. Upon recovery from yeast, the CEN/ARS is excised by NotI digest and subsequently religated without need for purification or transfer to new conditions. Excision by this approach takes ~3 hr, allowing this refinement in the same time frame as standard recombination cloning.     

Yeast/E. coli shuttle vectors with multiple unique restriction sites

Two yeast/E. coli shuttle vectors have been constructed. The two vectors, YEp351 and YEp352, have the following properties: (1) they can replicate autonomously in Saccharomyces cerevisiae and in E. coli; (2) they contain the beta-lactamase gene and confer ampicillin resistance to E. coli; (3) they contain the entire sequence of pUC18; (4) all ten restriction sites of the multiple cloning region of pUC18 including EcoRI, SacI, KpnI, SmaI, BamHI, XbaI, SalI, PstI, SphI and HindIII are unique in YEp352; these sites are also unique in YEp351 except for EcoRI and KpnI, which occur twice; (5) recombinant plasmids with DNA inserts in the multiple cloning region of YEp351 and YEp352 can be recognised by loss of beta-galactosidase function in appropriate E. coli hosts; (6) YEp351 and YEp352 contain the yeast LEU2 and URA3 genes, respectively, allowing for selection of these auxotrophic markers in yeast and E. coli; (7) both plasmids are retained with high frequency in yeast grown under non-selective conditions indicative of high plasmid copy number. The above properties make the shuttle vectors suitable for construction of yeast genomic libraries and for cloning of DNA fragments defined by a large number of different restriction sites. The two vectors have been further modified by deletion of the sequences necessary for autonomous replication in yeast. The derivative plasmids YIp351 and YIp352 can therefore be used to integrate specific sequences into yeast chromosomal DNA.     

Development and characterization of a vector set with regulated promoters for systematic metabolic engineering in Saccharomyces cerevisiae

A set of vectors was constructed that enable combined and systematic testing of metabolic pathway genes in Saccharomyces cerevisiae. The vectors are available as CEN/ARS and 2 µ‐based plasmids with a choice of three inducible promoters, P_GAL1, P_CUP1 and P_ADH2. These features offer control over the initiation and level of gene expression. In addition, the vectors can be used as templates to generate PCR fragments for targeted chromosomal integration of gene expression cassettes. Selection markers are flanked by loxP elements to allow efficient CreA‐mediated marker removal and recycling after genomic integration. For each promoter, expression of a bacterial lacZ reporter gene was characterized from plasmid‐based and integrated chromosomal cassettes, and compared to that of the glycolytic P_PGK1 promoter. Plasmid stabilities were also determined. The promoters showed distinct activity profiles useful for modulating expression of metabolic pathway genes. This series of plasmids with inducible promoters extends our previous vector set carrying the constitutive promoters P_PGK1, P_TEF1 and P_HXT7‐391. Copyright © 2012 John Wiley & Sons, Ltd.     

A novel kanamycin/G418 resistance marker for direct selection of transformants in Escherichia coli and different yeast species

We have developed a set of cloning vectors possessing a modified Tn903 kanamycin resistance gene that enables the selection of both kanamycin‐resistant transformants in Escherichia coli and G418‐resistant transformants in the yeasts Saccharomyces cerevisiae, Hansenula polymorpha and Pichia pastoris. Expression of this gene in yeast is controlled by the H. polymorpha glyceraldehyde‐3‐phosphate dehydrogenase promoter, while expression in E. coli is governed by an upstream E. coli lacZ promoter. Applicability of the vectors for gene disruption in H. polymorpha and S. cerevisiae was demonstrated by inactivation of the HpMAL1 and URA3 genes, respectively. One of the vectors possesses a H. polymorpha ARS allowing plasmid maintenance in an episomal state. The small size of the vectors (2–2.5 kb) makes them convenient for routine DNA cloning. In addition, we report a novel approach for construction of gene disruption cassettes. Copyright © 2009 John Wiley & Sons, Ltd.     

A shuttle vector series for precise genetic engineering of Saccharomyces cerevisiae

Shuttle vectors allow for an efficient transfer of recombinant DNA into yeast cells and are widely used in fundamental research and biotechnology. While available shuttle vectors are applicable in many experimental settings, their use in quantitative biology is hampered by insufficient copy number control. Moreover, they often have practical constraints, such as limited modularity and few unique restriction sites. We constructed the pRG shuttle vector series, consisting of single‐ and multi‐copy integrative, centromeric and episomal plasmids with marker genes for the selection in all commonly used auxotrophic yeast strains. The vectors feature a modular design and a large number of unique restriction sites, enabling an efficient exchange of every vector part and expansion of the series. Integration into the host genome is achieved using a double‐crossover recombination mechanism, resulting in stable single‐ and multi‐copy modifications. As centromeric and episomal plasmids give rise to a heterogeneous cell population, an analysis of their copy number distribution and loss behaviour was performed. Overall, the shuttle vector series supports the efficient cloning of genes and their maintenance in yeast cells with improved copy number control. Copyright © 2015 John Wiley & Sons, Ltd.     

Improved gap‐repair cloning method that uses oligonucleotides to target cognate sequences

In vivo or gap‐repair cloning in yeast has been widely recognized as one of the most efficient means for error‐free construction of plasmids. A protocol is described here that allows easy and efficient gap‐repair cloning that is based on two major modifications. Instead of subcloning, the targeting plasmids are constructed using oligonucleotides from sequences derived from the upstream and downstream sequences of the fragment to be cloned. These sequences are selected so that they can lead to the generation of recognition sites for restriction enzymes that produce blunt ends. Accordingly, this procedure can be applied to any DNA fragment, regardless of whether these include unique restriction sites to generate the targeting ends. With the strategy described, ～50 bp upstream and downstream targeting ends are generated that allow efficient cloning. Further, to allow easy identification of the positive clones, the annealed oligonucleotides are cloned in frame with the lacZ fragment present in the plasmid. Accordingly, these plasmids produce blue Escherichia coli colonies on media containing X‐Gal. On the other hand, plasmids rescued from yeast that have acquired the respective cognate sequences produce white colonies. To demonstrate the efficiency of the method, this report includes the cloning of fragments harbouring the CDC28, CAK1, CIN5 and CLB2 genes. We found that 30–100% of the analysed plasmids carried the expected inserts. Copyright © 2009 John Wiley & Sons, Ltd.     

Expression and in vivo determination of firefly luciferase as gene reporter in Saccharomyces cerevisiae

The LUC gene coding for Photinus pyralis firefly luciferase was cloned in different yeast episomal plasmids in order to assess its possibilities as an in vivo reporter gene. Activity of the enzyme in transformed cells in vivo was measured by following light emission and assay conditions optimized in intact cells, with regard to oxygen concentration, temperature, cell concentration in assay mixtures and external ATP concentration. Among the factors tested, light emission was drastically influenced by the external pH in the assay (which resulted in a ten-fold amplification signal) and by substrate permeability. The growth phase of the cells was also important for the level of activity detected. Cloning of firefly luciferase gene under the control of different yeast-regulated promoters (ADH1, GAL1–10) enabled us to measure their strength which correlated well with previously described data. We conclude that firefly luciferase is an adequate gene reporter for the in vivo sensitive determination of gene expression and promoter strength in yeast.     

New vectors for combinatorial deletions in yeast chromosomes and for gap-repair cloning using ‘split-marker’ recombination

New tools are needed for speedy and systematic study of the numerous genes revealed by the sequence of the yeast genome. We have developed a novel transformation strategy, based on ‘split-marker’ recombination, which allows generation of chromosomal deletions and direct gene cloning. For this purpose, pairs of yeast vectors have been constructed which offer a number of advantages for large-scale applications such as one-step cloning of target sequence homologs and combinatorial use. Gene deletions or gap-repair clonings are obtained by cotransformation of yeast by a pair of recombinant plasmids. Gap-repair vectors are based on the URA3 marker. Deletion vectors include the URA3, LYS2 and kanMX selection markers flanked by I-SceI sites, which allow their subsequent elimination from the transformant without the need for counter-selection. The application of the ‘split-marker’ vectors to the analysis of a few open reading frames of chromosome XI is described.     

Non‐homologous end joining‐mediated functional marker selection for DNA cloning in the yeast Kluyveromyces marxianus

The cloning of DNA fragments into vectors or host genomes has traditionally been performed using Escherichia coli with restriction enzymes and DNA ligase or homologous recombination‐based reactions. We report here a novel DNA cloning method that does not require DNA end processing or homologous recombination, but that ensures highly accurate cloning. The method exploits the efficient non‐homologous end‐joining (NHEJ) activity of the yeast Kluyveromyces marxianus and consists of a novel functional marker selection system. First, to demonstrate the applicability of NHEJ to DNA cloning, a C‐terminal‐truncated non‐functional ura3 selection marker and the truncated region were PCR‐amplified separately, mixed and directly used for the transformation. URA3⁺ transformants appeared on the selection plates, indicating that the two DNA fragments were correctly joined by NHEJ to generate a functional URA3 gene that had inserted into the yeast chromosome. To develop the cloning system, the shortest URA3 C‐terminal encoding sequence that could restore the function of a truncated non‐functional ura3 was determined by deletion analysis, and was included in the primers to amplify target DNAs for cloning. Transformation with PCR‐amplified target DNAs and C‐terminal truncated ura3 produced numerous transformant colonies, in which a functional URA3 gene was generated and was integrated into the chromosome with the target DNAs. Several K. marxianus circular plasmids with different selection markers were also developed for NHEJ‐based cloning and recombinant DNA construction. The one‐step DNA cloning method developed here is a relatively simple and reliable procedure among the DNA cloning systems developed to date. Copyright © 2013 John Wiley & Sons, Ltd.     

Galactose-inducible Expression Systems in Candida maltosa using Promoters of Newly-isolated GAL1 and GAL10 Genes

The GAL1 and GAL10 gene cluster encoding the enzymes of galactose utilization was isolated from an asporogenic yeast, Candida maltosa. The structure of the gene cluster in which both genes were divergently transcribed from the central promoter region resembled those of some other yeasts. The expression of both genes was strongly induced by galactose and repressed by glucose in the medium. Galactose-inducible expression vectors in C. maltosa were constructed on low- and high-copy number plasmids using the promoter regions of both genes. With these vectors and the β-galactosidase gene from Kluyveromyces lactis as a reporter, galactose-inducible expression was confirmed. Homologous overexpression of members of the cytochrome P-450 gene family in C. maltosa was also successful by using a high-copy-number vector under the control of these promoters. © 1997 by John Wiley & Sons, Ltd.     

New vectors for simple and streamlined CRISPR–Cas9 genome editing in Saccharomyces cerevisiae

Clustered regularly interspaced short palindromic repeats (CRISPR)–Cas9 technology is an important tool for genome editing because the Cas9 endonuclease can induce targeted DNA double‐strand breaks. Targeting of the DNA break is typically controlled by a single‐guide RNA (sgRNA), a chimeric RNA containing a structural segment important for Cas9 binding and a 20mer guide sequence that hybridizes to the genomic DNA target. Previous studies have demonstrated that CRISPR–Cas9 technology can be used for efficient, marker‐free genome editing in Saccharomyces cerevisiae. However, introducing the 20mer guide sequence into yeast sgRNA expression vectors often requires cloning procedures that are complex, time‐consuming and/or expensive. To simplify this process, we have developed a new sgRNA expression cassette with internal restriction enzyme sites that permit rapid, directional cloning of 20mer guide sequences. Here we describe a flexible set of vectors based on this design for cloning and expressing sgRNAs (and Cas9) in yeast using different selectable markers. We anticipate that the Cas9–sgRNA expression vector with the URA3 selectable marker (pML104) will be particularly useful for genome editing in yeast, since the Cas9 machinery can be easily removed by counter‐selection using 5‐fluoro‐orotic acid (5‐FOA) following successful genome editing. The availability of new vectors that simplify and streamline the technical steps required for guide sequence cloning should help accelerate the use of CRISPR–Cas9 technology in yeast genome editing. Vectors pT040, pJH001, pML104 and pML107 have been deposited at Addgene ( www.addgene.org ). Copyright © 2015 John Wiley & Sons, Ltd.     

Characterization of different promoters for designing a new expression vector in Saccharomyces cerevisiae

The widely used pESC vector series (Stratagene, La Jolla, CA, USA) with the bidirectional GAL1/GAL10 promoter provides the possibility of simultaneously expressing two different genes from a single vector in Saccharomyces cerevisiae. This system can be induced by galactose and is repressed by glucose. Since S. cerevisiae prefers glucose as a carbon source, and since its growth rate is higher in glucose than in galactose‐containing media, we compared and evaluated seven different promoters expressed during growth on glucose (pTEF1, pADH1, pTPI1, pHXT7, pTDH3, pPGK1 and pPYK1) with two strong galactose‐induced promoters (pGAL1 and pGAL10), using lacZ as a reporter gene and measuring LacZ activity in batch and continuous cultivation. TEF1 and PGK1 promoters showed the most constant activity pattern at different glucose concentrations. Based on these results, we designed and constructed two new expression vectors which contain the two constitutive promoters, TEF1 and PGK1, in opposite orientation to each other. These new vectors retain all the features from the pESC–URA plasmid except that gene expression is mediated by constitutive promoters. Copyright © 2010 John Wiley & Sons, Ltd.