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.     

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).     

Hdf1, a yeast Ku-protein homologue, is involved in illegitimate recombination, but not in homologous recombination.

Hdf1 is the yeast homologue of the mammalian 70 kDa subunit of Ku-protein, which has DNA end-binding activity and is involved in DNA double-strand break repair and V(D)J recombination. To examine whether Hdf1 is involved in illegitimate recombination, we have measured the rate of deletion mutation caused by illegitimate recombination on a plasmid in an hdf1 disruptant. The hdf1 mutation reduced the rate of deletion formation by 20-fold, while it did not affect mitotic and meiotic homologous recombinations between two heteroalleles or homologous recombination between direct repeats. Hence Hdf1 participates in illegitimate recombination, but not in homologous recombination, in contrast to Rad52, Rad50, Mre11 and Xrs2, which are involved in both homologous and illegitimate recombination. The illegitimate recombination in the hdf1 disruptant took place between recombination sites that shared short regions of homology (1-4 bp), as was observed in the wild-type. Based on the DNA end-binding activity of Hdf1, we discuss models in which Hdf1 plays an important role in the late step of illegitimate recombination.     

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.     

Expression of cancer related BRCA1 missense variants decreases MMS-induced recombination in Saccharomyces cerevisiae without altering its nuclear localization

BRCA1 tumor suppressor gene is found mutated in familial breast and ovarian cancer. Most cancer related mutations were found located at the RING (Really Interesting New Gene) and at the BRCT (BRca1 C-Terminal) domain. However, 20 y after its identification, the biological role of BRCA1 and which domains are more relevant for tumor suppression are still being elucidated. We previously reported that expression of BRCA1 cancer related variants in the RING and BRCT domain increases spontaneous homologous recombination in yeast indicating that BRCA1 may interact with yeast DNA repair/recombination. To finally demonstrate whether BRCA1 interacts with yeast DNA repair, we exposed yeast cells expressing BRCA1wt, the cancer-related variants C-61G and M1775R to different doses of the alkylating agent methyl methane-sulfonate (MMS) and then evaluated the effect on survival and homologous recombination. Cells expressing BRCA1 cancer variants were more sensitive to MMS and less inducible to recombination as compared to cell expressing BRCA1wt. Moreover, BRCA1-C61G and -M1775R did not change their nuclear localization form as compared to the BRCA1wt or the neutral variant R1751Q indicating a difference in the DNA damage processing. We propose a model where BRCA1 cancer variants interact with the DNA double strand break repair pathways producing DNA recombination intermediates, that maybe less repairable and decrease MMS-induced recombination and survival. Again, this study strengthens the use of yeast as model system to characterize the mechanisms leading to cancer in humans carrying the BRCA1 missense variant.     

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.     

Transfer region of IncI1 plasmid R64 and role of shufflon in R64 transfer.

To locate the transfer region of the 122-kiloase plasmid R64drd-11 belonging to incompatibility group I1, a series of deletion derivatives was constructed by in vitro recombinant DNA techniques followed by double homologous recombination in vivo. A plasmid designated pKK609 and bearing a 56.7-kilobase R64 sequence was the smallest transferable plasmid. A plasmid designated pKK610 and no longer possessing the 44-base-pair sequence of the R64 transfer system is located at one end. The other end of the R64 transfer region comprises a DNA segment of about 19 kilobases responsible for pilus formation. Shufflon, DNA with a novel rearrangement in R64, was found to be involved in pilus formation.     

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).     

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.     

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.     

Use of interplasmid recombination to generate stable selectable markers for yeast transformation: application to studies of actin gene control

A plasmid recombination system has been developed that relies upon interplasmid exchanges for yeast cell viability. Two types of plasmids, one carrying the LEU2 allele inserted within yeast actin gene sequences and the other carrying 2-microns plasmid DNA and an intact actin gene, were constructed. Neither plasmid alone yielded transformants in the haploid Leu- strain AH22, but when cotransformed, a number of colonies were obtained. Southern blot analysis revealed that transformants arose because of recombination events within the homologous actin sequences that transferred the LEU2 gene to the actin gene on the 2-microns plasmid. The recombinant plasmids could be recovered, and sequence analysis of one recombination site revealed that the exchange event was faithful at the nucleotide level. The resulting recombinant plasmids carried a defective actin gene and presumably arose because of a double-crossover event. Deletion mutations that prevented actin gene expression on one donor plasmid enabled the recovery at a high frequency of transformants resulting primarily from single-crossover events between the two plasmids. This was presumably because such events no longer generated an intact actin gene on a multicopy plasmid. Infrequently a transformant from a plasmid with an intact gene was recovered, but in these cases the plasmid was not present in multiple copies. These cells exhibited a slower growth rate, and Northern blot analysis revealed an elevated level of actin mRNA.     

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.     

Genetic transformation of Saccharomyces cerevisiae with single-stranded circular DNA vectors

We asked if single-stranded vector DNA molecules could be used to reintroduce cloned DNA sequences into a eukaryotic cell and cause genetic transformation typical of that observed using double-stranded DNA vectors. DNA was presented to Saccharomyces cerevisiae following a standard transformation protocol, genetic transformants were isolated, and the physical state of the transforming DNA sequence was determined. We found that single-stranded DNA molecules transformed yeast cells 10- to 30-fold more efficiently than double-stranded molecules of identical sequence. More cells were competent for transformation by the single-stranded molecules. Single-stranded circular (ssc) DNA molecules carrying the yeast 2 μ plasmid-replicator sequence were converted to autonomously replicating double-stranded circular (dsc) molecules, suggesting their efficient utilization as templates for DNA synthesis in the cell. Single-stranded DNA molecules carrying 2 μ plasmid non-replicator sequences recombined with the endogenous multicopy 2 μ plasmid DNA. This recombination yielded either the simple molecular adduct expected from homologous recombination (40% of the transformants examined) or aberrant recombination products carrying incomplete transforming DNA sequences, endogenous 2 μ plasmid DNA sequences, or both (60% of the transformants examined). These aberrant recombination products suggest the frequent use of a recombination pathway that trims one or both of the substrate DNA molecules. Similar aberrant recombination products were detected in 30% of the transformants in cotransformation experiments employing single-stranded and double-stranded DNA molecules, one carrying the 2 μ plasmid replicator sequence and the other the selectable genetic marker. We conclude that single-stranded DNA molecules are useful vectors for the genetic transformation of a eukaryotic cell. They offer the advantage of high transformation efficiency, and yield the same intracellular DNA species obtained upon transformation with double-stranded DNA molecules. In addition, single-stranded DNA molecules can participate in a recombination pathway that trims one or both DNA recombination substrates, a pathway not detected, at least at the same frequency, when transforming with double-stranded DNA molecules     

Induction of multiple plasmid recombination in Saccharomyces cerevisiae by psoralen reaction and double strand breaks.

DNA damage-induced multiple recombination was studied by cotransforming yeast cells with pairs of nonreplicating plasmids carrying different genetic markers. Reaction of one of the plasmids with the interstrand crosslinking agent, psoralen, stimulated cellular transformation by the undamaged plasmid. The cotransformants carried copies of both plasmids cointegrated in tandem arrays at chromosomal sites homologous to either the damaged or the undamaged DNA. Plasmid linearization, by restriction endonuclease digestion, was also found to stimulate the cointegration of unmodified plasmids. Disruption of the RAD1 gene reduced the psoralen damage-induced cotransformation of intact plasmid, but had no effect on the stimulation by double strand breaks. Placement of the double strand breaks within yeast genes produced cointegration only at sequences homologous to the damaged plasmids, while digestion within vector sequences produced integration at chromosomal sites homologous to either the damaged or the undamaged plasmid molecules. These observations suggest a model for multiple recombination events in which an initial exchange occurs between the damaged DNA and homologous sequences on an undamaged molecule. Linked sequences on the undamaged molecule up to 870 base pairs distant from the break site participate in subsequent exchanges with other intact DNA molecules. These events result in recombinants produced by reciprocal exchange between three or more DNA molecules.     

共生菌Hebeloma sp.的线形质粒DNA的分子克隆及测序的研究

共生担子菌滑菇 H ebeloma circinas携带两个线形的染色体外 DNA分子 .全部的菌丝 DNA经蛋白酶 K处理后 ,通过琼脂凝胶电泳观察到 :在染色体 DNA旁有两个大小不等的 DNA带 ,命名为 p HCl和 p HC2 ,其分子量分别为 1 0 .3kb和 9.1 kb.用核酸外切酶处理 p HC DNA,确认其 5′端被保护 .对 p HC2用不同的内切酶处理并确定其内切酶图谱 ,对其 3.2 kb H ind 片段进行克隆 ,亚克隆和测序 .结果表明 :其片段有两个开读框 ( open reading frames) ,携带类似于病毒 B型的DNA和 RNA多聚酶基因编码 .p HC2为该菌携带的一个典型的线形质粒 ,这也是首次在共生担子菌中发现的线形质粒 .     

Recombination-mediated PCR-directed plasmid construction in vivo in yeast.

We have extended the technique of PCR-directed recombination in Saccharomyces cerevisiae to develop a simple method for plasmid or gene construction in the absence of suitable restriction sites. The DNA to be cloned is PCR-amplified with 30-40 bp of homology to a linearized yeast plasmid. Co-transformation into yeast results in homologous recombination at a position directed by the PCR oligonucleotides.     

Advanced method for high-throughput expression of mutated eukaryotic membrane proteins in Saccharomyces cerevisiae

Crystallization of eukaryotic membrane proteins is a challenging, iterative process. The protein of interest is often modified in an attempt to improve crystallization and diffraction results. To accelerate this process, we took advantage of a GFP-fusion yeast expression system that uses PCR to direct homologous recombination and gene cloning. We explored the possibility of employing more than one PCR fragment to introduce various mutations in a single step, and found that when up to five PCR fragments were co-transformed into yeast, the recombination frequency was maintained as the number of fragments was increased. All transformants expressed the model membrane protein, while the resulting plasmid from each clone contained the designed mutations only. Thus, we have demonstrated a technique allowing the expression of mutant membrane proteins within 5 days, combining a GFP-fusion expression system and yeast homologous recombination.     

Nuclear factories for signalling and repairing DNA double strand breaks in living fission yeast

In mammalian and budding yeast cells treated with genotoxic agents, different proteins implicated in detecting, signalling or repairing DNA lesions form nuclear foci. We studied foci formed by proteins involved in these processes in living fission yeast cells, which is amenable to genetic and molecular analysis. Using fluorescent tags, we analysed subnuclear localisations of the DNA damage checkpoint protein Rad9, of the homologous recombination protein Rad22 and of PCNA, which are implicated in many aspects of DNA metabolism. After inducing double strand breaks (DSBs) with ionising radiations, Rad22, Rad9 and PCNA form a low number of nuclear foci. Rad9 recruitment to foci depends on the presence of Rad1, Hus1 and Rad17, but is independent of downstream checkpoint effectors and of homologous recombination proteins. Likewise, Rad22 and PCNA form foci despite inactive homologous recombination repair and impaired DNA damage checkpoint. Rad22 and Rad9 foci co-localise completely, whereas PCNA co-localises with Rad22 and Rad9 only partially. Foci do not disassemble in cells unable to repair DNA by homologous recombination. Thus, in fission yeast, DSBs are detected by the DNA damage checkpoint and are repaired by homologous recombination at a few spatially confined subnuclear compartments where Rad22, Rad9 and PCNA concentrate independently.     

Association of reciprocal exchange with gene conversion between the repeated segments of 2-micron circle

The occurrence of reciprocal exchange of flanking DNA during gene conversion between the repeated segments of the yeast plasmid, 2-micron circle has been examined. The conversion event is induced by making a double-stranded gap within one of the repeats in vitro and allowing the gap to be repaired in vivo. The repair takes place with frequent recombination of flanking markers. Neither the topology of the plasmid substrates (linear or circular) nor the relative orientation of the repeats affects the association rule significantly. These events are reminiscent of meiotic gene conversion between homologous chromosomes but contrast sharply with mitotic or meiotic intrachromosomal gene conversion. It would appear that the difference between the outcomes of intramolecular gene conversion on a chromosome and on a plasmid gapped in vitro does not result from the different physical states of intracellular versus transformed DNA. A gene conversion event in a 2-micron circle : : Tn5 plasmid mediated by the 2-micron circle recombinase (FLP) in vivo, which is formally analogous to the yeast mating type interconversion, often results in recombination of flanking markers. The reaction can be mimicked, in the absence of FLP, by gapping the plasmid within one of the 2-micron circle repeats in vitro and carrying out gap repair in vivo.