Heterologous modules for efficient and versatile PCR-based gene targeting in Schizosaccharomyces pombe

We describe a straightforward PCR-based approach to the deletion, tagging, and overexpression of genes in their normal chromosomal locations in the fission yeast Schizosaccharomyces pombe. Using this approach and the S. pombe ura4⁺ gene as a marker, nine genes were deleted with efficiencies of homologous integration ranging from 6 to 63%. We also constructed a series of plasmids containing the kanMX6 module, which allows selection of G418-resistant cells and thus provides a new heterologous marker for use in S. pombe. The modular nature of these constructs allows a small number of PCR primers to be used for a wide variety of gene manipulations, including deletion, overexpression (using the regulatable nmt1 promoter), C- or N-terminal protein tagging (with HA, Myc, GST, or GFP), and partial C- or N-terminal deletions with or without tagging. Nine genes were manipulated using these kanMX6 constructs as templates for PCR. The PCR primers included 60 to 80 bp of flanking sequences homologous to target sequences in the genome. Transformants were screened for homologous integration by PCR. In most cases, the efficiency of homologous integration was ≥50%, and the lowest efficiency encountered was 17%. The methodology and constructs described here should greatly facilitate analysis of gene function in S. pombe. © 1998 John Wiley & Sons, Ltd.     

A vector system for efficient and economical switching of C-terminal epitope tags in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, one-step PCR-mediated modification of chromosomal genes allows fast and efficient tagging of yeast proteins with various epitopes at the C- or N-terminus. For many purposes, C-terminal tagging is advantageous in that the expression pattern of epitope tag is comparable to that of the authentic protein and the possibility for the tag to affect normal folding of polypeptide chain during translation is minimized. As experiments are getting complicated, it is often necessary to construct several fusion proteins tagged with various kinds of epitopes. Here, we describe development of a series of plasmids that allow efficient and economical switching of C-terminally tagged epitopes, using just one set of universal oligonucleotide primers. Containing a variety of epitopes (GFP, TAP, GST, Myc, HA and FLAG tag) and Kluyveromyces lactis URA3 gene as a selectable marker, the plasmids can be used to replace any MX6 module-based C-terminal epitope tag with one of the six epitopes. Furthermore, the plasmids also allow additional C-terminal epitope tagging of proteins in yeast cells that already carry MX6 module-based gene deletion or C-terminal epitope tag.     

Additional vectors for PCR-based gene tagging in Saccharomyces cerevisiae and Schizosaccharomyces pombe using nourseothricin resistance

The one-step PCR-mediated technique used for modification of chromosomal loci is a powerful tool for functional analysis in yeast. Both Saccharomyces cerevisiae and Schizosaccharomyces pombe are amenable to this technique. However, the scarce availability of selectable markers for Sz. pombe hampers the easy use of this technique in this species. Here, we describe the construction of new vectors deriving from the pFA6a family, which are suitable for tagging in both yeasts owing to the presence of a nourseothricin-resistance cassette. These plasmids allow various gene manipulations at chromosomal loci, viz. N- and C-terminal tagging with 3HA (haemagglutinin) or 13Myc epitopes, GST (glutathione S-transferase), 4TAP (tandem affinity purification) and several GFP (green fluorescent protein) isoforms. For N-terminal modifications, the use of different promoters allows constitutive (PADH1) or regulatable (PGAL1) promoters for S. cerevisiae and derivatives of Pnmt1 for Sz. pombe expression.     

N‐ICE plasmids for generating N‐terminal 3 × FLAG tagged genes that allow inducible,constitutive or endogenous expression in Saccharomyces cerevisiae

PCR‐mediated homologous recombination is a powerful approach to introduce epitope tags into the chromosomal loci at the N‐terminus or the C‐terminus of targeted genes. Although strategies of C‐terminal epitope tagging of target genes at their loci are simple and widely used in yeast, C‐terminal epitope tagging is not practical for all proteins. For example, a C‐terminal tag may affect protein function or a protein may get cleaved or processed, resulting in the loss of the epitope tag. Therefore, N‐terminal epitope tagging may be necessary to resolve these problems. In some cases, an epitope tagging strategy is used to introduce a heterologous promoter with the epitope tag at the N‐terminus of a gene of interest. The potential issue with this strategy is that the tagged gene is not expressed at the endogenous level. Another strategy after integration is to excise the selection marker, using the Cre‐LoxP system, leaving the epitope tagged gene expressed from the endogenous promoter. However, N‐terminal epitope tagging of essential genes using this strategy requires a diploid strain followed by tetrad dissection. Here we present 14 new plasmids for N‐terminal tagging, which combines two previous strategies for epitope tagging in a haploid strain. These ‘N‐ICE’ plasmids were constructed so that non‐essential and essential genes can be N‐terminally 3 × FLAG tagged and expressed from an inducible promoter (GAL1), constitutive promoters (CYC1 or PYK1) or the endogenous promoter. We have validated the N‐ICE plasmid system by N‐terminal tagging two non‐essential genes (SET1 and SET2) and two essential genes (ERG11 and PKC1). Copyright © 2016 John Wiley & Sons, Ltd.     

‘Marker Swap’ Plasmids: Convenient Tools for Budding Yeast Molecular Genetics

One-step gene disruption constructs for disruption of HIS3, LEU2, TRP1 or URA3 with each of the other three markers have been constructed. All of these constructs have been tested and found to effectively convert markers either in gene disruptions or on plasmids. The ‘swapped’ strains allow the unambiguous genetic analysis of synthetic phenotypes with multiple genes, even if the original gene disruptions were made with the same marker. They also allow introduction of multiple plasmids in a single transformant, even if the original plasmids had the same marker, and allow transformation of plasmids into strains containing gene disruptions made with the same marker that is on the plasmids. These ‘marker-swap’ plasmids therefore eliminate the need for much subcloning to change markers. Marker-swapped alleles are acceptably stable mitotically and meiotically for most applications.© 1997 John Wiley & Sons, Ltd.     

Small epitope‐linker modules for PCR‐based C‐terminal tagging in Saccharomyces cerevisiae

PCR‐mediated gene modification is a powerful approach to the functional analysis of genes in Saccharomyces cerevisiae. One application of this method is epitope‐tagging of a gene to analyse the corresponding protein by immunological methods. However, the number of epitope tags available in a convenient format is still low, and interference with protein function by the epitope, particularly if it is large, is not uncommon. To address these limitations and broaden the utility of the method, we constructed a set of convenient template plasmids designed for PCR‐based C‐terminal tagging with 10 different, relatively short peptide sequences that are recognized by commercially available monoclonal antibodies. The encoded tags are FLAG, 3 × FLAG, T7, His‐tag, Strep‐tag II, S‐tag, Myc, HSV, VSV‐G and V5. The same pair of primers can be used to construct tagged alleles of a gene of interest with any of the 10 tags. In addition, a six‐glycine linker sequence is inserted upstream of these tags to minimize the influence of the tag on the target protein and maximize its accessibility for antibody binding. Three marker genes, HIS3MX6, kanMX6 and hphMX4, are available for each epitope. We demonstrate the utility of the new tags for both immunoblotting and one‐step affinity purification of the regulatory particle of the 26S proteasome. The set of plasmids has been deposited in the non‐profit plasmid repository Addgene ( http://www.addgene.org ). Copyright © 2009 John Wiley & Sons, Ltd.     

New constructs and strategies for efficient PCR-based gene manipulations in yeast

Gene disruption and tagging can be achieved by homologous recombination in the yeast genome. Several PCR-based methods have been described towards this end. However these strategies are often limited in their applications and/or their efficiencies and may be technically demanding. Here we describe two plasmids for C-terminal tagging of proteins with the IgG binding domain of the Staphyloccocus aureus protein A. We also present simple and reliable strategies based on PCR to promote efficient integration of exogenous DNA into the yeast genome. These simple methods are not limited to specific strains or markers and can be used for any application requiring homologous recombination such as gene disruption and epitope tagging. These strategies can be used for consecutive introduction of various constructs into a single yeast strain. © 1998 John Wiley & Sons, Ltd.     

Plasmids with E2 epitope tags: tagging modules for N‐ and C‐terminal PCR‐based gene targeting in both budding and fission yeast,and inducible expression vectors for fission yeast

A single‐step PCR‐based epitope tagging enables fast and efficient gene targeting with various epitope tags. This report presents a series of plasmids for the E2 epitope tagging of proteins in Saccharomyces cerevisiae and Schizosaccharomyces pombe. E2Tags are 10‐amino acids (epitope E2a: SSTSSDFRDR)‐ and 12 amino acids (epitope E2b: GVSSTSSDFRDR)‐long peptides derived from the E2 protein of bovine papillomavirus type 1. The modules for C‐terminal tagging with E2a and E2b epitopes were constructed by the modification of the pYM‐series plasmid. The N‐terminal E2a and E2b tagging modules were based on pOM‐series plasmid. The pOM‐series plasmids were selected for this study because of their use of the Cre–loxP recombination system. The latter enables a marker cassette to be removed after integration into the loci of interest and, thereafter, the tagged protein is expressed under its endogenous promoter. Specifically for fission yeast, high copy pREP plasmids containing the E2a epitope tag as an N‐terminal or C‐terminal tag were constructed. The properties of E2a and E2b epitopes and the sensitivity of two anti‐E2 monoclonal antibodies (5E11 and 3F12) were tested using several S. cerevisiae and Sz. pombe E2‐tagged strains. Copyright © 2009 John Wiley & Sons, Ltd.     

Use of polymerase chain reaction epitope tagging for protein tagging in Saccharomyces cerevisiae

Epitope tagging is the insertion of a short stretch of amino acids constituting an epitope into another protein. Tagged proteins can be identified by Western, immunoprecipitation and immunofluorescence assays using pre-existing antibodies. We have designed vectors containing the URA3 gene flanked by direct repeats of epitope tags. We use the polymerase chain reaction (PCR) to amplify the tag-URA3-tag cassette such that the ends of the PCR fragments possess homology to the gene of interest. In vivo recombination is then used to direct integration of the fragment to the location of interest, and transformants are selected by their Ura⁺ phenotype. Finally, selection for Ura^? cells on 5-fluoro-orotic acid plates yields cells where recombination between the repeated epitopes has ‘popped out’ the URA3 gene, leaving a single copy of the epitope at the desired location. PCR epitope tagging (PET) provides a rapid and direct technique for tagging that does not require any cloning steps. We have used PET to tag three Saccharomyces cerevisiae proteins, Cln1, Sic1 and Est1.     

A versatile toolbox for PCR-based tagging of yeast genes: new fluorescent proteins, more markers and promoter substitution cassettes

Tagging of genes by chromosomal integration of PCR amplified cassettes is a widely used and fast method to label proteins in vivo in the yeast Saccharomyces cerevisiae. This strategy directs the amplified tags to the desired chromosomal loci due to flanking homologous sequences provided by the PCR-primers, thus enabling the selective introduction of any sequence at any place of a gene, e.g. for the generation of C-terminal tagged genes or for the exchange of the promoter and N-terminal tagging of a gene. To make this method most powerful we constructed a series of 76 novel cassettes, containing a broad variety of C-terminal epitope tags as well as nine different promoter substitutions in combination with N-terminal tags. Furthermore, new selection markers have been introduced. The tags include the so far brightest and most yeast-optimized version of the red fluorescent protein, called RedStar2, as well as all other commonly used fluorescent proteins and tags used for the detection and purification of proteins and protein complexes. Using the provided cassettes for N- and C-terminal gene tagging or for deletion of any given gene, a set of only four primers is required, which makes this method very cost-effective and reproducible. This new toolbox should help to speed up the analysis of gene function in yeast, on the level of single genes, as well as in systematic approaches.     

Expanding the repertoire of plasmids for PCR-mediated epitope tagging in yeast

Epitope tagging of yeast proteins provides a convenient means of tracking proteins of interest in Western blots and immunoprecipitation experiments without the need to raise and test specific antibodies. We have constructed four plasmids for use as templates in PCR-based epitope tagging in the yeast Saccharomyces cerevisiae. These plasmids expand the range of epitopes available in a tag-URA3-tag context to include the FLAG, HSV, V5 and VSV-G epitopes. The cloning strategy used would be easily applicable to the construction of a similar tag-URA3-tag molecule for essentially any desired epitope. Oligonucleotides designed for PCR from one plasmid may be used interchangeably with any of the other template molecules to allow tagging with different epitopes without the need for new primer synthesis. We have tagged Tfc6 with each of the triple epitope tags and assessed the efficiency of these epitopes for chromatin immunoprecipitation (ChIP). For all the tagged alleles, ChIP occupancy signals are easily detectable at known Tfc6 target genes. These new tags provide additional options in experimental schemes requiring multiple tagged proteins.     

New drug-resistant cassettes for gene disruption and epitope tagging in Schizosaccharomyces pombe

We describe new heterologous modules for PCR-based gene targeting in the fission yeast Schizosaccharomyces pombe. Two bacterial genes, hph and nat, which display dominant drug-resistance phenotypes, are used as new selectable markers in these modules. Both genes have been used successfully in the budding yeast Saccharomyces cerevisiae, in which hph confers resistance to hygromycin B, while nat confers nourseothricin resistance (Goldstein and McCusker, 1999). Vector modules for gene disruption and C-terminal tagging with 3HA, 13Myc and GFP(S65T) are constructed using previously constructed pFA6a-MX6-derived plasmids (B?hler et al., 1998; Wach et al., 1997). In combination with the existing systems that are based upon the G418-resistance gene (kan), triple gene deletions or tags could be constructed. In addition a vector for one-step integration of a monomeric RFP (mRFP) to the C-terminus of proteins of interest is developed. Finally, oligonucleotides that allow a simple marker switch from kan to hph or nat, and vice versa, are described. The new constructs developed here should facilitate post-genomic molecular analysis of protein functions in fission yeast.     

Designer deletion and prototrophic strains derived from Saccharomyces cerevisiae strain W303‐1a

We report the construction of Saccharomyces cerevisiae strains isogenic to W303‐1a that are designed to allow efficient genetic analysis. To facilitate the generation of null alleles of target genes by PCR‐mediated gene disruption, we constructed designer deletion alleles of the ARG4, TRP1 and URA3 genes. In addition, a single pair of oligonucleotide primers were designed that can be used to amplify any of several marker genes for use in PCR‐mediated gene disruption. A new version of the ‘reusable’ hisG‐URA3‐hisG cassette was constructed for use in PCR‐mediated gene disruption. Finally, to facilitate the formation of isogenic diploids by selection, we constructed strains that contain combinations of wild‐type alleles of ADE2, HIS3, LEU2, TRP1 and URA3. Copyright © 1999 John Wiley & Sons, Ltd.     

Consideration of the evolution of the Saccharomyces cerevisiae MEL gene family on the basis of the nucleotide sequences of the genes and their flanking regions

Analysis of the DNA sequences of new members of the Saccharomyces cerevisiae MEL1-MEL10 gene family showed high homology between the members. The MEL gene family, α-galactosidase-coding sequences, have diverged into two groups; one consisting of MEL1 and MEL2 and the other of MEL3-MEL10. In two S. cerevisiae strains containing five or seven MEL genes each, all the genes are nearly identical, suggesting very rapid distribution of the gene to separate chromosomes. The sequence homology and the abrupt change to sequence heterogeneity at the centromere-proximal 3′ end of the MEL genes suggest that the distribution of the genes to new chromosomal locations has occurred partly by reciprocal recombination at solo delta sequences. We identified a new open reading frame sufficient to code for a 554 amino acid long protein of unknown function. The new open reading frame (Accession number Z37509) is located in the 3′ non-coding region of MEL3-MEL10 genes in opposite orientation to the MEL genes (Accession numbers Z37508, Z37510, Z37511). Northern analysis of total RNA showed no hybridization to a homologous probe, suggesting that the gene is not expressed efficiently if at all.     

Designed construction of recombinant DNA at the ura3Δ0 locus in the yeast Saccharomyces cerevisiae

Recombinant DNAs are traditionally constructed using Escherichia coli plasmids. In the yeast Saccharomyces cerevisiae, chromosomal gene targeting is a common technique, implying that the yeast homologous recombination system could be applied for recombinant DNA construction. In an attempt to use a S. cerevisiae chromosome for recombinant DNA construction, we selected the single ura3Δ0 locus as a gene targeting site. By selecting this single locus, repeated recombination using the surrounding URA3 sequences can be performed. The recombination system described here has several advantages over the conventional plasmid system, as it provides a method to confirm the selection of correct recombinants because transformation of the same locus replaces the pre‐existing selection marker, resulting in the loss of the marker in successful recombinations. In addition, the constructed strains can serve as both PCR templates and hosts for preparing subsequent recombinant strains. Using this method, several yeast strains that contained selection markers, promoters, terminators and target genes at the ura3Δ0 locus were successfully generated. The system described here can potentially be applied for the construction of any recombinant DNA without the requirement for manipulations in E. coli. Interestingly, we unexpectedly found that several G/C‐rich sequences used for fusion PCR lowered gene expression when located adjacent to the start codon. Copyright © 2013 John Wiley & Sons, Ltd.     

Dicistronic regulation of fluorescent proteins in the budding yeast Saccharomyces cerevisiae

Fluorescent proteins are convenient tools for measuring protein expression levels in the budding yeast Saccharomyces cerevisiae. Co‐expression of proteins from distinct vectors has been seen by fluorescence microscopy; however, the expression of two fluorescent proteins on the same vector would allow for monitoring of linked events. We engineered constructs to allow dicistronic expression of red and green fluorescent proteins and found that expression levels of the proteins correlated with their order in the DNA sequence, with the protein encoded by the 5′‐gene more highly expressed. To increase expression levels of the second gene, we tested four regulatory elements inserted between the two genes: the IRES sequences for the YAP1 and p150 genes, and the promoters for the TEF1 gene from both S. cerevisiae and Ashbya gossypii. We generated constructs encoding the truncated ADH1 promoter driving expression of the red protein, yeast‐enhanced Cherry, followed by a regulatory element driving expression of the green protein, yeast‐enhanced GFP. Three of the four regulatory elements successfully enhanced expression of the second gene in our dicistronic construct. We have developed a method to express two genes simultaneously from one vector. Both genes are codon‐optimized to produce high protein levels in yeast, and the protein products can be visualized by microscopy or flow cytometry. With this method of regulation, the two genes can be driven in a dicistronic manner, with one protein marking cells harbouring the vector and the other protein free to mark any event of interest. Copyright © 2009 John Wiley & Sons, Ltd.     

Cloning and characterization of the Hansenula polymorpha homologue of the Saccharomyces cerevisiae PMR1 gene

A gene homologous to Saccharomyces cerevisiae PMR1 has been cloned in the methylotrophic yeast Hansenula polymorpha. The partial DNA fragment of the H. polymorpha homologue was initially obtained by a polymerase chain reaction and used to isolate the entire gene which encodes a protein of 918 amino acids. The putative gene product contains all ten of the conserved regions observed in P-type ATPases. The cloned gene product exhibits 60·3% amino acid identity to the S. cerevisiae PMR1 gene product and complemented the growth defect of a S. cerevisiae pmr1 null mutant in the EGTA-containing medium. The results demonstrate that the H. polymorpha gene encodes the functional homologue of the S. cerevisiae PMR1 gene product, a P-type Ca²⁺-ATPase. The DNA sequence of the H. polymorpha homologue has been submitted to GenBank with the Accession Number U92083. © 1998 John Wiley & Sons, Ltd.     

Isolation and nucleotide sequence of the gene encoding phosphoenolpyruvate carboxykinase from Kluyveromyces lactis

The KlPCK1 gene encoding phosphoenolpyruvate carboxykinase (PEPCK; ATP-dependent) was cloned from the Kluyveromyces lactis genome using a PCR amplicon from Saccharomyces cerevisiae PCK1 gene as a probe. A DNA fragment of about 4·8 kb containing KlPCK1 complemented PEPCK activity of the mutant of S. cerevisiae defective in PEPCK. The KlPCK1 gene has an open reading frame of 1629 bp (543 amino acids). The KlPCK1 nucleotide sequence and deduced amino acid sequence showed 76% and 84% homologies to those of S. cerevisiae PCK1, respectively. Multiple alignment of ATP-dependent PEPCK genes shows highly conserved regions. The nucleotide sequence of KlPCK1 has been submitted to the DDBJ/GenBank/EMBL data bank with Accession Number U88575. © 1998 John Wiley & Sons, Ltd.