Plasmid-Mediated Induction of Recombination in Yeast

Diploid yeast cells heteroallelic at the HIS3 locus were transformed with a minichromosome (centromeric plasmid) carrying homology to the HIS3 region and containing the same two mutations as were present in the chromosomes. When a double-strand break (DSB) was introduced in the region of homology, an increase in the recombination frequency between heteroalleles (leading to His(+) cells) was observed, although the plasmid was unable to donate wild-type information. This induction of recombination was dependent on the presence of homology between the plasmid sequences and the chromosomes. We show evidence for the physical involvement of the plasmid in tripartite recombination events, and we propose models that can explain the interactions between the plasmid-borne and chromosomal-borne alleles. Our results suggest that the mitotic induction of recombination by DNA damage is due to localized initiation of recombination events, and not to a general induction of recombination enzymes in the cell.     

Construction of a novel kind of expression plasmid by ho-mologous recombination in Saccharomyces cerevisiae

Saccharomyces cerevisiae is one of the most im- portant heterologous expression systems. The stability and copy number of expression plasmid in the host are the important factors to affect the expression levels of foreign genes[1―3]. pHC11 is a yeast episomal plasmid constructed by our laboratory[4]. It contains the entire sequence of the 2μ plasmid without disrupting its coding elements and other functional regions. The stability and copy number of pHC11 are relatively high. Making use of…     

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.     

Transformation of yeast with linearized plasmid DNA. Formation of inverted dimers and recombinant plasmid products

The molecular products of DNA double strand break repair were investigated after transformation of yeast (Saccharomyces cerevisiae) with linearized plasmid DNA. DNA of an autonomous yeast plasmid cleaved to generate free ends lacking homology with the yeast genome, when used in transformation along with sonicated non-homologous carrier DNA, gave rise to transformants with high frequency. Most of these transformants were found to harbor a head-to-head (inverted) dimer of the linearized plasmid. This outcome of transformation contrasts with that observed when the carrier DNA is not present. Transformants occur at a much reduced frequency and harbor either the parent plasmid or a plasmid with deletion at the site of the cleavage. When the linearized plasmid is introduced along with sonicated carrier DNA and a homologous DNA restriction fragment that spans the site of plasmid cleavage, homologous recombination restores the plasmid to its original circular form. Inverted dimer plasmids are not detected. This relationship between homologous recombination and a novel DNA transaction that yields rearrangement could be important to the cell, as the latter could lead to a loss of gene function and lethality.     

Characterization of a centromere-linked recombination hot spot in Saccharomyces cerevisiae.

A 1.5-kilobase-pair SalI-HindIII (SH) restriction fragment from the region of Saccharomyces cerevisiae chromosome XIV immediately adjacent to the centromere appears to contain sequences that act as a hot spot for mitotic recombination. The presence of SH DNA on an autonomously replicating plasmid stimulates homologous genetic exchange between yeast genomic sequences and those present on the plasmid. In all recombinants characterized, exchange occurs in plasmid yeast sequences adjacent to rather than within the SH DNA. Hybridization analyses reveal that SH-containing plasmids are present in linear as well as circular form in S. cerevisiae and that linear forms are generated by cleavage at specific sites. Presumably, it is the linear form of the plasmid that is responsible for the stimulation of genetic exchange. Based on these observations, it is proposed that this DNA fragment contains a centromere-linked recombination hot spot and that SH-stimulated recombination occurs via a mechanism similar to double-strand-gap repair (J. W. Szostak, T. Orr-Weaver, J. Rothstein, and F. Stahl, Cell 33:25-35 1983).     

Generation of disruption cassettes in vivo using a PCR product and Saccharomyces cerevisiae

A method to obtain disruption cassettes based on the homologous recombination in Saccharomyces cerevisiae is described. The disruption marker is amplified by PCR using oligonucleotides containing 50 bp homologous to the disruptable gene and 20 bp from the marker. The PCR product is cotransformed into yeast with a plasmid containing the gene. After recombination, a plasmid that carries the disruption cassette for the gene is produced.     

High frequency excision of Ty elements during transformation of yeast.

Yeast (Saccharomyces cerevisiae) transposons (Ty elements) are excised from up to 20% of supercoiled plasmids during transformation of yeast cells. The excision occurs by homologous recombination across the direct terminal repeats (deltas) of the Ty element, leaving behind a single delta in the transforming plasmid. Only the initial transforming plasmid is susceptible to excision, and no high frequency excision is observed in plasmids that have become established in transformed cells or in plasmids that are resident in cells undergoing transformation. High frequency excision from plasmids during yeast transformation is not specific for Ty elements and can be observed with other segments of plasmid DNA bounded by direct repeats. The frequency of Ty excision from supercoiled plasmids is greatly reduced when the host yeast cells contain the rad52 mutation, a defect in double-strand DNA repair. When linear or ligated-linear plasmid DNAs containing a Ty element are used for transformation, few or no excision plasmids are found among the transformant colonies. These results suggest that when a yeast cell is transformed with a supercoiled plasmid, the plasmid DNA is highly susceptible to homologous recombination for a short period of time.     

Cloning of industrial Saccharomyces 2-microns plasmid variants by in vivo site-specific recombination

Southern analyses defined several industrial Saccharomyces yeast strains with extensive 2-microns DNA polymorphism. Variants included insertions and deletions up to several hundred base pairs. To facilitate the investigation of yeast plasmid evolution we developed a novel method of cloning 2-microns plasmids by taking advantage of 2-microns circle in vivo site-specific recombination and an SMRI gene as a dominant selectable marker. This method can be applied to other organisms for the isolation of plasmid variants and provides a new approach to in vivo plasmid construction.     

Homologous recombination in plant cells is enhanced by in vivo induction of double strand breaks into DNA by a site-specific endonuclease.

Induction of double strand breaks (DSBs) is coupled to meiotic and mitotic recombination in yeast. We show that also in a higher eukaryote induction of DSBs is directly correlated with a strong enhancement of recombination frequencies. We cotransfected Nicotiana plumbaginifolia protoplasts with a plasmid carrying a synthetic I-SceI gene, coding for a highly sequence specific endonuclease, together with recombination substrates carrying an I-SceI-site adjacent to their homologous sequences. We measured efficiencies of extrachromosomal recombination, using a well established transient beta-glucuronidase (GUS) assay. GUS enzyme activities were strongly increased when a plasmid carrying the I-SceI gene in sense but not in antisense orientation with respect to the promoter was included in the transfections. The in vivo induced DSBs were detected in the recombination substrates by Southern blotting, demonstrating that the yeast enzyme is functional in plant cells. At high ratios of transfected I-SceI-genes to I-SceI-sites the majority of the I-SceI-sites in the recombination substrates are cleaved, indicating that the induction of the DSBs is the rate limiting step in the described recombination reaction. These results imply that in vivo induction of transient breaks at specific sites in the plant genome could allow foreign DNA to be targeted to these sites via homologous recombination.     

Plasmid construction by homologous recombination in yeast

We describe a convenient method for constructing new plasmids that relies on interchanging parts of plasmids by homologous recombination in Saccharomyces cerevisiae. A circular recombinant plasmid of a desired structure is regenerated after transformation of yeast with a linearized plasmid and a DNA restriction fragment containing appropriate homology to serve as a substrate for recombinational repair. The free ends of the input DNA molecules need not be homologous in order for efficient recombination between internal homologous regions to occur. The method is particularly useful for incorporating into or removing from plasmids selectable markers, centromere or replication elements, or particular alleles of a gene of interest. Plasmids constructed in yeast can subsequently be recovered in an Escherichia coli host. Using this method, we have constructed an extended series of new yeast centromere, episomal and replicating (YCp, YEp, and YRp) plasmids containing, in various combinations, the selectable yeast markers LEU2, HIS3, LYS2, URA3 and TRP1.     

Construction of a novel kind of expression plasmid by homologous recombination in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

Based on a previously used plasmid pHC11, a new plasmid pHC11R was constructed. Cutting plasmid pHC11R with proper restriction enzymes, the resulting larger DNA fragment pHC11R’ was co-transformed with a PCR amplified expression cassette of human IFNα2b into yeast. By means of the homologous sequences at both ends of two DNA fragments, a novel expression plasmid pHC11R-IFNα2b was formed via homologous recombination in the yeast. Compared with pHC11-IFNα2b, the expression plasmid pHC11R-IFNα2b was smaller in size and in absence of antibiotic resistant gene. The stability and copy number of pHC11R-IFNα2b were greatly increased and the expression level of heterologous protein was improved. As the derivatives of pHC11R, a series of recombination expression vectors pHRs containing different combination of expression elements were developed. This led to a rapid and powerful method for cloning and expressing of different genes in yeast.     

Unequal homologous recombination of human DNA on a yeast artificial chromosome.

We examined unequal homologous DNA recombination between human repetitive DNA elements located on a yeast artificial chromosome (YAC) and transforming plasmid molecules. A plasmid vector containing an Alu element, as well as a sequence identical to a unique site on a YAC, was introduced into yeast and double recombinant clones analyzed. Recombination occurs between vector and YAC Alu elements sharing as little as 74% identity. The physical proximity of an Alu element to the unique DNA segment appears to play a significant role in determining the frequency with which that element serves as a recombination substrate. In addition, cross-over points of the recombination reaction are largely confined to the ends of the repetitive element. Since a similar distribution of crossover sites occurs during unequal homologous recombination in human germ and somatic tissue, we propose that similar enzymatic processes may be responsible for the events observed in our system and in human cells. This suggests that further examination of the enzymology of unequal homologous recombination of human DNA within yeast may yield a greater understanding of the molecular events which control this process in higher eukaryotes.     

Synapsis-Mediated Fusion of Free DNA Ends Forms Inverted Dimer Plasmids in Yeast

When yeast (Saccharomyces cerevisiae) is transformed with linearized plasmid DNA and the ends of the plasmid do not share homology with the yeast genome, circular inverted (head-to-head) dimer plasmids are the principal product of repair. By measurements of the DNA concentration dependence of transformation with a linearized plasmid, and by transformation with mixtures of genetically marked plasmids, we show that two plasmid molecules are required to form an inverted dimer plasmid. Several observations suggest that homologous pairing accounts for the head-to-head joining of the two plasmid molecules. First, an enhanced frequency of homologous recombination is detected when genetically marked plasmids undergo end-to-end fusion. Second, when a plasmid is linearized within an inverted repeat, such that its ends could undergo head-to-tail homologous pairing, it is repaired by intramolecular head-to-tail joining. Last, in the joining of homologous linearized plasmids of different length, a shorter molecule can acquire a longer plasmid end by homologous recombination. The formation of inverted dimer plasmids may be related to some forms of chromosomal rearrangement. These might include the fusion of broken sister chromatids in the bridge-breakage-fusion cycle and the head-to-head duplication of genomic DNA at the sites of gene amplifications.     

FLP recombinase of the 2 microns circle plasmid of Saccharomyces cerevisiae bends its DNA target. Isolation of FLP mutants defective in DNA bending

The FLP recombinase is encoded by the yeast plasmid 2 microns circle and catalyses a site-specific recombination reaction that results in inversion of a segment of the 2 micron plasmid. We describe a method for the isolation of inactivating mutations in the FLP gene. The analysis of the recombination and binding activity of defective FLP proteins in vitro resulted in the identification of two classes of mutations: those that completely abolish FLP function by interfering with DNA binding and others that block recombination after the binding step. We have shown that FLP-mediated recombination is accompanied by bending of the DNA target and that mutations in the FLP recombinase that block bending also eliminate recombination.     

Meiotic Recombination between Duplicated Genetic Elements in SACCHAROMYCES CEREVISIAE

We have studied the meiotic recombination behavior of strains carrying two types of duplications of an 18.6-kilobase HIS4 Bam HI fragment. The first type is a direct duplication of the HIS4 Bam HI fragment in which the repeated sequences are separated by Escherichia coli plasmid sequences. The second type, a tandem duplication, has no sequences intervening between the repeated yeast DNA. The HIS4 genes in each region were marked genetically so that recombination events between the duplicated segments could be identified. Meiotic progeny of the strains carrying the duplication were analyzed genetically and biochemically to determine the types of recombination events that had occurred. Analysis of the direct vs. tandem duplication suggests that the E. coli plasmid sequences are recombinogenic in yeast when homozygous. In both types of duplications recombination between the duplicated HIS4 regions occurs at high frequency and involves predominantly interchromosomal reciprocal exchanges (equal and unequal crossovers). The striking observation is that intrachromosomal reciprocal recombination is very rare in comparison with interchromosomal reciprocal recombination. However, intrachromosomal gene conversion occurs at about the same frequency as interchromosomal gene conversion. Reciprocal recombination events between regions on the same chromatid are the most infrequent exchanges. These data suggest that intrachromosomal reciprocal exchanges are suppressed.     

Chromosome engineering in Saccharomyces cerevisiae by using a site-specific recombination system of a yeast plasmid.

We have developed an effective method to delete or invert a chromosomal segment and to create reciprocal recombination between two nonhomologous chromosomes in Saccharomyces cerevisiae, using the site-specific recombination system of pSR1, a circular cryptic DNA plasmid resembling 2 microns DNA of S. cerevisiae but originating from another yeast, Zygosaccharomyces rouxii. A 2.1-kilobase-pair DNA fragment bearing the specific recombination site on the inverted repeats of pSR1 was inserted at target sites on a single or two different chromosomes of S. cerevisiae by using integrative vectors. The cells were then transformed with a plasmid bearing the R gene of pSR1, which encodes the site-specific recombination enzyme and is placed downstream of the GAL1 promoter. When the transformants were cultivated in galactose medium, the recombination enzyme produced by expression of the R gene created the modified chromosome(s) by recombination between two specific recombination sites inserted on the chromosome(s).     

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.     

FLP-mediated recombination in the vector mosquito, Aedes aegypti.

The activity of a yeast recombinase, FLP, on specific target DNA sequences, FRT, has been demonstrated in embryos of the vector mosquito, Aedes aegypti. In a series of experiments, plasmids containing the FLP recombinase under control of a heterologous heat-shock gene promoter were co-injected with target plasmids containing FRT sites into preblastoderm stage mosquito embryos. FLP-mediated recombination was detected between (i) tandem repeats of FRT sites leading to the excision of specific DNA sequences and (ii) FRT sites located on separate plasmids resulting in the formation of heterodimeric or higher order multimeric plasmids. In addition to FRT sites originally isolated from the yeast 2 microns plasmid, a number of synthetic FRT sites were also used. The synthetic sites were fully functional as target sites for recombination and gave results similar to those derived from the yeast 2 microns plasmid. This successful demonstration of yeast FLP recombinase activity in the mosquito embryo suggests a possible future application of this system in establishing transformed lines of mosquitoes for use in vector control strategies and basic studies.     

Genetic control of plasmid recombination in the cotransformation of Saccharomyces cerevisiae: the role of RAD52 and FLP genes

In our earlier works we observed high frequency of recombination between two chimeric plasmids of different types, when they were introduced into yeast cells via cotransformation. Incapability of one of these plasmids to replicate autonomously in yeast cell is the necessary condition for such recombination. The high efficiency of this process point to the differences between interplasmid recombination and other types of yeast recombination. In this work, we studied the participation of two genes in the control of interplasmid exchanges. These are RAD52 responsible for normal processes of meiotic and mitotic recombination and highly specific gene FLP located on 2 mkm DNA which specifies site-specific recombination in the region of inverted sequences of this plasmid. The mutation rad52 in the recipient strain was shown to sharply decrease the efficiency of recombination between integrative and episome plasmids during cotransformation. The absence of FLP gene in the recipient strain (cirO) has no influence on this process.     

High-throughput construction of expression system using yeast Pichia pastoris, and its application to membrane proteins

The well-established method for high-throughput construction of an expression system of the yeast Saccharomyces cerevisiae uses homologous recombination between an expression plasmid and a target gene (with homologous regions of the plasmid on both ends added by PCR). This method has been widely used for membrane proteins using plasmids containing GFP, and has been successfully used to investigate the cellular localization and solubilization conditions of the proteins. Although the methanol-utilizing yeast Pichia pastoris is known as an excellent expression host, a method for high-throughput construction of an expression system like that in S. cerevisiae has not been reported. In this study, we have attempted to construct expression systems via homologous recombination in P. pastoris. The insertion of genes into a plasmid could be easily checked by colony-PCR. Expression systems for seven membrane proteins of medaka fish (Oryzias latipes) and yeast (S. cerevisiae) were constructed, and the expression of proteins was analyzed by fluorescence spectra, fluorescence microscopy, and SDS-PAGE (in-gel fluorescence detection).