Ends-in vs. ends-out recombination in yeast

Unilateral ends-out gene targeting increases mistargeting through supporting extensive single-strand assimilation

Ends-out gene targeting enables the swapping of endogenous alleles with exogenous ones through homologous recombination which bears great implications both fundamental and applicable. To address the recombination mechanism(s) behind it, an experimental system was designed to distinguish between a possible (but rarely active) unilateral and the expected bilateral targeting in the yeast Saccharomyces cerevisiae in which the proportions of the two alternative genetic outcomes are conceived to mirror the probabilities of the two scenarios. The quantitative analysis showed that the bilateral targeting was expectedly predominant. However, an analogous comparative analysis on a different experimental set suggested a prevalence of unilateral targeting unveiling an uncertainty whether the extensively resected targeting modules only mimic unilateral invasion. Based on this, a comprehensive qualitative analysis was conducted revealing a single basic ends-out gene targeting mechanism composed of two intertwined pathways differing in the way how the homologous invasion is initiated and/or the production of the intermediates is conducted. This study suggests that bilateral targeting lowers mistargeting plausibly by limiting strand assimilation, unlike unilateral targeting which may initiate extensive strand assimilation producing intermediates capable of supporting multiple genetic outcomes which leads to mistargeting. Some of these outcomes can also be produced by mimicking unilateral invasion.

Heterologous expression of recombinant urate oxidase using the intein-mediated protein purification in Pichia pastoris

The potential of urate oxidase (uricase) for clinical use has been highlighted because of its role in lowering the blood uric acid levels for the treatment of tumor lysis syndrome. In the present study, the codon-optimized synthetic gene of Aspergillus flavus uricase was fused to the Mxe GyrA intein and chitin-binding domain. The construct was inserted into pPICZA and pPICZαA vectors and electroporated into Pichia pastoris GS115 for the cytosolic and secretory expression. Transformants were screened on gradients of Zeocin up to 2000 μg/ml to find multi-copy integrants. For both constructs, colonies with more resistance were screened for the highest uricase producers by enzyme assay. PCR analysis confirmed successful cassettes insertion into the genome and Mut + phenotype. The gene copy index was determined to be two and five for cytosolic and secretory strains, respectively. Productivity of the cytosolic and secretory strains was found to be 0.74 and 0.001 U/ml culture media in order while the cytosolic recombinant enzyme accounted for about 6% of total proteins. One-step purification of the expressed uricase was done with the aid of the chitin affinity column, followed by DTT induction for intein on-column cleavage. The yield of 40.8 mg/L and K m of 0.22 mM was obtained for intracellular expression. It seems that the intracellular production of uricase can indeed serve as an effective alternative to secretory expression. Moreover, this is the first report considering cytosolic production of uricase using the intein-mediated protein purification in the methylotrophic yeast, P. pastoris.

The XPF-ERCC1 Complex Is Essential for Genome Stability and Is Involved in the Mechanism of Gene Targeting in Physcomitrella patens

The XPF-ERCC1 complex, a highly conserved structure-specific endonuclease, functions in multiple DNA repair pathways that are pivotal for maintaining genome stability, including nucleotide excision repair, interstrand crosslink repair, and homologous recombination. XPF-ERCC1 incises double-stranded DNA at double-strand/single-strand junctions, making it an ideal enzyme for processing DNA structures that contain partially unwound strands. Here, we have examined the role of the XPF-ERCC1 complex in the model bryophyte Physcomitrella patens which exhibits uniquely high gene targeting frequencies. We undertook targeted knockout of the Physcomitrella ERCC1 and XPF genes. Mutant analysis shows that the endonuclease complex is essential for resistance to UV-B and to the alkylating agent MMS, and contributes to the maintenance of genome integrity but is also involved in gene targeting in this model plant. Using different constructs we determine whether the function of the XPF-ERCC1 endonuclease complex in gene targeting was removal of 3' non-homologous termini, similar to SSA, or processing of looped-out heteroduplex intermediates. Interestingly, our data suggest a role of the endonuclease in both pathways and have implications for the mechanism of targeted gene replacement in plants and its specificities compared to yeast and mammalian cells.

Effect of Plasmid Design and Type of Integration Event on Recombinant Protein Expression in Pichia pastoris

Pichia pastoris (syn. Komagataella phaffii) is one of the most common eukaryotic expression systems for heterologous protein production. Expression cassettes are typically integrated in the genome to obtain stable expression strains. In contrast to Saccharomyces cerevisiae, where short overhangs are sufficient to target highly specific integration, long overhangs are more efficient in P. pastoris and ectopic integration of foreign DNA can occur. Here, we aimed to elucidate the influence of ectopic integration by high-throughput screening of >700 transformants and whole-genome sequencing of 27 transformants. Different vector designs and linearization approaches were used to mimic the most common integration events targeted in P. pastoris Fluorescence of an enhanced green fluorescent protein (eGFP) reporter protein was highly uniform among transformants when the expression cassettes were correctly integrated in the targeted locus. Surprisingly, most nonspecifically integrated transformants showed highly uniform expression that was comparable to specific integration, suggesting that nonspecific integration does not necessarily influence expression. However, a few clones (<10%) harboring ectopically integrated cassettes showed a greater variation spanning a 25-fold range, surpassing specifically integrated reference strains up to 6-fold. High-expression strains showed a correlation between increased gene copy numbers and high reporter protein fluorescence levels. Our results suggest that for comparing expression levels between strains, the integration locus can be neglected as long as a sufficient numbers of transformed strains are compared. For expression optimization of highly expressible proteins, increasing copy number appears to be the dominant positive influence rather than the integration locus, genomic rearrangements, deletions, or single-nucleotide polymorphisms (SNPs).IMPORTANCE Yeasts are commonly used as biotechnological production hosts for proteins and metabolites. In the yeast Saccharomyces cerevisiae, expression cassettes carrying foreign genes integrate highly specifically at the targeted sites in the genome. In contrast, cassettes often integrate at random genomic positions in nonconventional yeasts, such as Pichia pastoris (syn. Komagataella phaffii). Hence, cells from the same transformation event often behave differently, with significant clonal variation necessitating the screening of large numbers of strains. The importance of this study is that we systematically investigated the influence of integration events in more than 700 strains. Our findings provide novel insight into clonal variation in P. pastoris and, thus, how to avoid pitfalls and obtain reliable results. The underlying mechanisms may also play a role in other yeasts and hence could be generally relevant for recombinant yeast protein production strains.

Gene Editing with Helper-Dependent Adenovirus Can Efficiently Introduce Multiple Changes Simultaneously over a Large Genomic Region

Helper-dependent adenoviral vectors (HDAds) possess long homology arms that mediate high-efficiency gene editing. These long homology arms may permit simultaneous introduction of multiple modifications into a large genomic region or may permit a single HDAd to correct many different individual mutations spread widely across a gene. We investigated this important potential using an HDAd bearing 13 genetic markers in the region of homology to the target CFTR locus in human iPSCs and found that all markers can be simultaneously introduced into the target locus, with the two farthest markers being 22.2 kb apart. We found that genetic markers closer to the HDAd’s selectable marker are more efficiency introduced into the target locus; a marker located 208 bp from the selectable marker was introduced with 100% efficiency. However, even markers 11 kb from the selectable marker were introduced at a relatively high frequency of 21.7%. Our study also revealed extensive heteroduplex DNA formation of up to 10 kb with no bias toward vector or chromosomal repair. However, mismatches escape repair at a frequency of up to 15%, leading to a genetically mixed colony and emphasizing the need for caution, especially if the donor and target sequences are not 100% homologous.

DNA repair mechanisms and their biological roles in the malaria parasite Plasmodium falciparum

Research into the complex genetic underpinnings of the malaria parasite Plasmodium falciparum is entering a new era with the arrival of site-specific genome engineering. Previously restricted only to model systems but now expanded to most laboratory organisms, and even to humans for experimental gene therapy studies, this technology allows researchers to rapidly generate previously unattainable genetic modifications. This technological advance is dependent on DNA double-strand break repair (DSBR), specifically homologous recombination in the case of Plasmodium. Our understanding of DSBR in malaria parasites, however, is based largely on assumptions and knowledge taken from other model systems, which do not always hold true in Plasmodium. Here we describe the causes of double-strand breaks, the mechanisms of DSBR, and the differences between model systems and P. falciparum. These mechanisms drive basic parasite functions, such as meiosis, antigen diversification, and copy number variation, and allow the parasite to continually evolve in the contexts of host immune pressure and drug selection. Finally, we discuss the new technologies that leverage DSBR mechanisms to accelerate genetic investigations into this global infectious pathogen.

Lambda red mediated gap repair utilizes a novel replicative intermediate in Escherichia coli

The lambda phage Red recombination system can mediate efficient homologous recombination in Escherichia coli, which is the basis of the DNA engineering technique termed recombineering. Red mediated insertion of DNA requires DNA replication, involves a single-stranded DNA intermediate and is more efficient on the lagging strand of the replication fork. Lagging strand recombination has also been postulated to explain the Red mediated repair of gapped plasmids by an Okazaki fragment gap filling model. Here, we demonstrate that gap repair involves a different strand independent mechanism. Gap repair assays examining the strand asymmetry of recombination did not show a lagging strand bias. Directly testing an ssDNA plasmid showed lagging strand recombination is possible but dsDNA plasmids did not employ this mechanism. Insertional recombination combined with gap repair also did not demonstrate preferential lagging strand bias, supporting a different gap repair mechanism. The predominant recombination route involved concerted insertion and subcloning though other routes also operated at lower frequencies. Simultaneous insertion of DNA resulted in modification of both strands and was unaffected by mutations to DNA polymerase I, responsible for Okazaki fragment maturation. The lower efficiency of an alternate Red mediated ends-in recombination pathway and the apparent lack of a Holliday junction intermediate suggested that gap repair does not involve a different Red recombination pathway. Our results may be explained by a novel replicative intermediate in gap repair that does not involve a replication fork. We exploited these observations by developing a new recombineering application based on concerted insertion and gap repair, termed SPI (subcloning plus insertion). SPI selected against empty vector background and selected for correct gap repair recombinants. We used SPI to simultaneously insert up to four different gene cassettes in a single recombineering reaction. Consequently, our findings have important implications for the understanding of E. coli replication and Red recombination.

Results of multicenter double-blind placebo-controlled phase II clinical trial of Panagen preparation to evaluate its leukostimulatory activity and formation of the adaptive immune response in patients with stage II-IV breast cancer

Background

We performed a multicenter, double-blind, placebo-controlled, phase II clinical trial of human dsDNA-based preparation Panagen in a tablet form. In total, 80 female patients with stage II-IV breast cancer were recruited.

Methods

Patients received three consecutive FAC (5-fluorouracil, doxorubicin and cyclophosphamide) or AC (doxorubicin and cyclophosphamide) adjuvant chemotherapies (3 weeks per course) and 6 tablets of 5 mg Panagen or placebo daily (one tablet every 2–3 hours, 30 mg/day) for 18 days during each chemotherapy course. Statistical analysis was performed using Statistica 6.0 software, and non-parametric analyses, namely Wilcoxon-Mann–Whitney and paired Wilcoxon tests. To describe the results, the following parameters were used: number of observations (n), median, interquartile range, and minimum-maximum range.

Results

Panagen displayed pronounced leukostimulatory and leukoprotective effects when combined with chemotherapy. In an ancillary protocol, anticancer effects of a tablet form of Panagen were analyzed. We show that Panagen helps maintain the pre-therapeutic activity level of innate antitumor immunity and induces formation of a peripheral pool of cytotoxic CD8+ perforin + T-cells. Our 3-year follow-up analysis demonstrates that 24% of patients who received Panagen relapsed or died after the therapy, as compared to 45% in the placebo cohort.

Conclusions

The data collected in this trial set Panagen as a multi-faceted “all-in-one” medicine that is capable of simultaneously sustaining hematopoiesis, sparing the innate immune cells from adverse effects of three consecutive rounds of chemotherapy and boosting individual adaptive immunity. Its unique feature is that it is delivered via gastrointestinal tract and acts through the lymphoid system of intestinal mucosa. Taken together, maintenance of the initial levels of innate immunity, development of adaptive cytotoxic immune response and significantly reduced incidence of relapses 3 years after the therapy argue for the anticancer activity of Panagen.

Trial registration

ClinicalTrials.gov NCT02115984 from 04/07/2014.

Electronic supplementary material

The online version of this article (doi:10.1186/s12885-015-1142-z) contains supplementary material, which is available to authorized users.

High-throughput plasmid construction using homologous recombination in yeast: its mechanisms and application to protein production for X-ray crystallography

Homologous recombination is a system for repairing the broken genomes of living organisms by connecting two DNA strands at their homologous sequences. Today, homologous recombination in yeast is used for plasmid construction as a substitute for traditional methods using restriction enzymes and ligases. This method has various advantages over the traditional method, including flexibility in the position of DNA insertion and ease of manipulation. Recently, the author of this review reported the construction of plasmids by homologous recombination in the methanol-utilizing yeast Pichia pastoris, which is known to be an excellent expression host for secretory proteins and membrane proteins. The method enabled high-throughput construction of expression systems of proteins using P. pastoris; the constructed expression systems were used to investigate the expression conditions of membrane proteins and to perform X-ray crystallography of secretory proteins. This review discusses the mechanisms and applications of homologous recombination, including the production of proteins for X-ray crystallography.

Sgs1 and Exo1 suppress targeted chromosome duplication during ends-in and ends-out gene targeting

Gene targeting is extremely efficient in the yeast Saccharomyces cerevisiae. It is performed by transformation with a linear, non-replicative DNA fragment carrying a selectable marker and containing ends homologous to the particular locus in a genome. However, even in S. cerevisiae, transformation can result in unwanted (aberrant) integration events, the frequency and spectra of which are quite different for ends-out and ends-in transformation assays. It has been observed that gene replacement (ends-out gene targeting) can result in illegitimate integration, integration of the transforming DNA fragment next to the target sequence and duplication of a targeted chromosome. By contrast, plasmid integration (ends-in gene targeting) is often associated with multiple targeted integration events but illegitimate integration is extremely rare and a targeted chromosome duplication has not been reported. Here we systematically investigated the influence of design of the ends-out assay on the success of targeted genetic modification. We have determined transformation efficiency, fidelity of gene targeting and spectra of all aberrant events in several ends-out gene targeting assays designed to insert, delete or replace a particular sequence in the targeted region of the yeast genome. Furthermore, we have demonstrated for the first time that targeted chromosome duplications occur even during ends-in gene targeting. Most importantly, the whole chromosome duplication is POL32 dependent pointing to break-induced replication (BIR) as the underlying mechanism. Moreover, the occurrence of duplication of the targeted chromosome was strikingly increased in the exo1Δ sgs1Δ double mutant but not in the respective single mutants demonstrating that the Exo1 and Sgs1 proteins independently suppress whole chromosome duplication during gene targeting.

The mechanism of gene targeting in human somatic cells

Gene targeting in human somatic cells is of importance because it can be used to either delineate the loss-of-function phenotype of a gene or correct a mutated gene back to wild-type. Both of these outcomes require a form of DNA double-strand break (DSB) repair known as homologous recombination (HR). The mechanism of HR leading to gene targeting, however, is not well understood in human cells. Here, we demonstrate that a two-end, ends-out HR intermediate is valid for human gene targeting. Furthermore, the resolution step of this intermediate occurs via the classic DSB repair model of HR while synthesis-dependent strand annealing and Holliday Junction dissolution are, at best, minor pathways. Moreover, and in contrast to other systems, the positions of Holliday Junction resolution are evenly distributed along the homology arms of the targeting vector. Most unexpectedly, we demonstrate that when a meganuclease is used to introduce a chromosomal DSB to augment gene targeting, the mechanism of gene targeting is inverted to an ends-in process. Finally, we demonstrate that the anti-recombination activity of mismatch repair is a significant impediment to gene targeting. These observations significantly advance our understanding of HR and gene targeting in human cells.

Gene targeting is important for basic research and clinical applications. In the laboratory, gene targeting is used to knockout genes so that loss-of-function phenotypes can be assessed. In the clinic, gene targeting is the gold standard to which most gene therapy approaches aspire. One of the most promising tools for gene targeting in humans is recombinant adeno-associated virus (rAAV). The mechanism by which rAAV performs gene targeting has, however, remained obscure. Here, we surprisingly demonstrate that the normally single-stranded rAAV performs gene targeting via double-stranded intermediates, which are mechanistically indistinguishable from standard plasmid-mediated gene targeting. Moreover, we establish the double-strand break (DSB) repair model as the paradigm to describe human gene targeting, and delineate the dynamics of crossovers in this model. Most unexpectedly, we demonstrate that when a meganuclease is used to introduce a chromosomal DSB to augment gene targeting, the mechanism of gene targeting is inverted such that the chromosome becomes the “attacker” instead of the “attackee”. Finally, we confirm that the anti-recombination activity of mismatch repair is a significant impediment to gene targeting. These observations advance our understanding of the mechanism of human gene targeting and should readily lend themselves to developing improvements to existing methodologies.

Homologous recombination in the archaeon Sulfolobus acidocaldarius: effects of DNA substrates and mechanistic implications

Although homologous recombination (HR) is known to influence the structure, stability, and evolution of microbial genomes, few of its functional properties have been measured in cells of hyperthermophilic archaea. The present study manipulated various properties of the parental DNAs in high-resolution assays of Sulfolobus acidocaldarius transformation, and measured the impact on the efficiency and pattern of marker transfer to the recipient chromosome. The relative orientation of homologous sequences, the type and position of chromosomal mutation being replaced, and the length of DNA flanking the marked region all affected the efficiency, linkage, tract continuity, and other parameters of marker transfer. Effects predicted specifically by the classical reciprocal-exchange model of HR were not observed. One analysis observed only 90 % linkage between markers defined by adjacent bases; in another series of experiments, sequence divergence up to 4 % had no detectable impact on overall efficiency of HR or on the co-transfer of a distal non-selected marker. The effects of introducing DNA via conjugation, rather than transformation, were more difficult to assess, but appeared to increase co-transfer (i.e. linkage) of relatively distant non-selected markers. The results indicate that HR events between gene-sized duplex DNAs and the S. acidocaldarius chromosome typically involve neither crossing over nor interference from a mismatch-activated anti-recombination system. Instead, the donor DNA may anneal to a transient chromosomal gap, as in the mechanism proposed for oligonucleotide-mediated transformation of Sulfolobus and other micro-organisms.

The segregation of Escherichia coli minichromosomes constructed in vivo by recombineering

Circularized regions of the chromosome containing the origin of replication, oriC, can be maintained as autonomous minichromosomes, oriC plasmids. We show that oriC plasmids containing precise, pre-determined segments of the chromosome can be generated by a simple in vivo recombineering technique. We generated two such plasmids carrying fluorescent markers. These were transferred to a recipient strain with a different fluorescent marker near the chromosomal copy of oriC. Thus the fates of the oriC plasmid and chromosomal origins could be followed independently in living cells by fluorescence microscopy. In contrast to a previous report, we show that there is a strong tendency of oriC plasmid copies to accumulate at the cell center as a single or double focus at the plane of cell division. This is not simply due to exclusion from the nucleoid space but rather appears to be a specific recognition and retention of the plasmid by some central-located cell site.

Reverse genetics in eukaryotes

Reverse genetics consists in the modification of the activity of a target gene to analyse the phenotypic consequences. Four main approaches are used towards this goal and will be explained in this review. Two of them are centred on genome alterations. Mutations produced by random chemical or insertional mutagenesis can be screened to recover only mutants in a specific gene of interest. Alternatively, these alterations may be specifically targeted on a gene of interest by HR (homologous recombination). The other two approaches are centred on mRNA. RNA interference is a powerful method to reduce the level of gene products, while MO (morpholino) antisense oligonucleotides alter mRNA metabolism or translation. Some model species, such as Drosophila, are amenable to most of these approaches, whereas other model species are restricted to one of them. For example, in mice and yeasts, gene targeting by HR is prevalent, whereas in Xenopus and zebrafish MO oligonucleotides are mainly used. Genome-wide collections of mutants or inactivated models obtained in several species by these approaches have been made and will help decipher gene functions in the post-genomic era.

Saccharomyces cerevisiae-based system for studying clustered DNA damages

DNA-damaging agents can induce clustered lesions or multiply damaged sites (MDSs) on the same or opposing DNA strands. In the latter, attempts to repair MDS can generate closely opposed single-strand break intermediates that may convert non-lethal or mutagenic base damage into double-strand breaks (DSBs). We constructed a diploid S. cerevisiae yeast strain with a chromosomal context targeted by integrative DNA fragments carrying different damages to determine whether closely opposed base damages are converted to DSBs following the outcomes of the homologous recombination repair pathway. As a model of MDS, we studied clustered uracil DNA damages with a known location and a defined distance separating the lesions. The system we describe might well be extended to assessing the repair of MDSs with different compositions, and to most of the complex DNA lesions induced by physical and chemical agents.

An improved strategy for tandem affinity purification-tagging of Schizosaccharomyces pombe genes

Tandem affinity purification (TAP) is a method that allows rapid purification of native protein complexes. We developed an improved technique to fuse the fission yeast genes with a TAP tag. Our technique is based on tagging constructs that contain regions homologous to the target gene cloned into vectors carrying a TAP tag. We used this technique to design strategies for TAP-tagging of predicted Schizosaccharomyces pombe genes (http://mendel.imp.ac.at/Pombe_tagging/). To validate the approach, we purified the proteins, which associated with two evolutionarily conserved proteins Swi5 and Sfr1 as well as three protein kinases Ksg1, Orb6 and Sid1.

The pol3-t hyperrecombination phenotype and DNA damage-induced recombination in Saccharomyces cerevisiae is RAD50 dependent

The DNA polymerase delta (POL3/CDC2) allele pol3-t of Saccharomyces cerevisiae has previously been shown to be sensitive to methylmethanesulfonate (MMS) and has been proposed to be involved in base excision repair. Our results, however, show that the pol3-t mutation is synergistic for MMS sensitivity with MAG1, a known base excision repair gene, but it is epistatic with rad50Delta, suggesting that POL3 may be involved not only in base excision repair but also in a RAD50 dependent function. We further studied the interaction of pol3-t with rad50Delta by examining their effect on spontaneous, MMS-, UV-, and ionizing radiation-induced intrachromosomal recombination. We found that rad50Delta completely abolishes the elevated spontaneous frequency of intrachromosomal recombination in the pol3-t mutant and significantly decreases UV- and MMS-induced recombination in both POL3 and pol3-t strains. Interestingly, rad50Delta had no effect on gamma-ray-induced recombination in both backgrounds between 0 and 50 Gy. Finally, the deletion of RAD50 had no effect on the elevated frequency of homologous integration conferred by the pol3-t mutation. RAD50 is possibly involved in resolution of replication forks that are stalled by mutagen-induced external DNA damage, or internal DNA damage produced by growing the pol3-t mutant at the restrictive temperature.

Knockout of the DNA ligase IV homolog gene in the sphingoid base producing yeast Pichia ciferrii significantly increases gene targeting efficiency

The yeast Pichia ciferrii produces large quantities of the sphingoid base tetraacetyl phytosphingosine (TAPS) and is an interesting platform organism for the biotechnological production of sphingolipids and ceramides. Ceramides have attracted great attention as a specialty ingredient for moisture retention and protection of the skin in the cosmetics industry. First attempts have been started to metabolically engineer P. ciferrii for improved production of TAPS and other sphingoid bases. However, rational metabolic engineering of P. ciferrii is difficult due to a low gene targeting efficiency. In eukaryotes, two major pathways coexist, which are responsible for genomic DNA integration, homologous recombination (HR) and non-homologous end joining (NHEJ). Integration via HR is targeted, while NHEJ involves ectopic (non-targeted) integration depending on a ligation step mediated by DNA ligase IV (Lig4). Here, we demonstrate a dramatical increase in gene targeting efficiency in a P. ciferrii lig4 knockout strain, deficient in NHEJ. Furthermore, a quick and easy to use freeze-thaw method was developed to transform P. ciferrii with high efficiency. Owing to the ability of targeting genomic DNA integration our results pave the way for further genetic and metabolic engineering approaches with P. ciferrii by means of knocking out or overexpressing predestinated genes.

Ends-in vs. ends-out targeted insertion mutagenesis in Saccharomyces castellii

Gene replacement (knock-out) is a major tool for the analysis of gene function. However, the efficiency of correct targeting varies between species, and is dependent on the structure of the DNA construct. We analyzed the targeted insertion mutagenesis method in the budding yeast Saccharomyces castellii, phylogenetically positioned after the whole genome duplication event in the Saccharomyces lineage. We compared the targeting efficiency for target DNA constructs in the respective ends-in and ends-out form. For some of the constructs S. castellii showed a similar high degree of homologous recombination as S. cerevisiae. In agreement with S. cerevisiae, a higher targeting efficiency was seen for the diploid strain than for the haploid. Surprisingly, a higher degree of targeting efficiency was seen for ends-out constructs compared to ends-in constructs. This result may have been influenced by the difference in the length of the homologous target sequences used, although long homology regions of 300 bp-1 kb were used in all constructs. Remarkably, very short regions of cohesive heterologous sequences at the ends of the constructs highly stimulated random illegitimate integration, suggesting that the pathway of non-homologous end joining is highly active in S. castellii.

Rad52 promotes second-end DNA capture in double-stranded break repair to form complement-stabilized joint molecules

Saccharomyces cerevisiae Rad52 performs multiple functions during the recombinational repair of double-stranded DNA (dsDNA) breaks (DSBs). It mediates assembly of Rad51 onto single-stranded DNA (ssDNA) that is complexed with replication protein A (RPA); the resulting nucleoprotein filament pairs with homologous dsDNA to form joint molecules. Rad52 also catalyzes the annealing of complementary strands of ssDNA, even when they are complexed with RPA. Both Rad51 and Rad52 can be envisioned to promote "second-end capture," a step that pairs the ssDNA generated by processing of the second end of a DSB to the joint molecule formed by invasion of the target dsDNA by the first processed end. Here, we show that Rad52 promotes annealing of complementary ssDNA that is complexed with RPA to the displaced strand of a joint molecule, to form a complement-stabilized joint molecule. RecO, a prokaryotic homolog of Rad52, cannot form complement-stabilized joint molecules with RPA-ssDNA complexes, nor can Rad52 promote second-end capture when the ssDNA is bound with either human RPA or the prokaryotic ssDNA-binding protein, SSB, indicating a species-specific process. We conclude that Rad52 participates in second-end capture by annealing a resected DNA break, complexed with RPA, to the joint molecule product of single-end invasion event. These studies support a role for Rad52-promoted annealing in the formation of Holliday junctions in DSB repair.

DNA bridging of yeast chromosomes VIII leads to near-reciprocal translocation and loss of heterozygosity with minor cellular defects

Loss of heterozygosity (LOH) of tumor suppressor genes in somatic cells is a major process leading to several types of cancer; however, its underlying molecular mechanism is still poorly understood. In the present work, we demonstrate that a linear DNA molecule bridging two homologous chromosomes in diploid yeast cells via homologous recombination produce LOH-generating regions of hemizygosity by deletion. The result is a near-reciprocal translocation mutant that is characterized by slight cell cycle defects and increased expression of the multidrug-resistant gene VMR1. When the distance between target regions is approximately 40 kb, the specificity of gene targeting becomes less stringent and an ensemble of gross chromosomal rearrangements arises. These heterogeneous genomic events, together with the low frequency of specific translocation, confirm that several pathways contribute to the healing of a broken chromosome and suggest that uncontrolled recombination between parental homologs is actively avoided by the cell. Moreover, this work demonstrates that the common laboratory practice of making targeted gene deletions may result in a low, but not negligible, frequency of LOH due to the recombination events triggered between homologous chromosomes in mitosis.

Ku70, an essential gene, modulates the frequency of rAAV-mediated gene targeting in human somatic cells

Gene targeting has two important applications. One is the inactivation of genes ("knockouts"), and the second is the correction of a mutated allele back to wild-type ("gene therapy"). Central to these processes is the efficient introduction of the targeting DNA into the cells of interest. In humans, this targeting is often accomplished through the use of recombinant adeno-associated virus (rAAV). rAAV is presumed to use a pathway of DNA double-strand break (DSB) repair termed homologous recombination (HR) to mediate correct targeting; however, the specifics of this mechanism remain unknown. In this work, we attempted to generate Ku70-null human somatic cells by using a rAAV-based gene knockout strategy. Ku70 is the heterodimeric partner of Ku86, and together they constitute an end-binding activity that is required for a pathway [nonhomologous end joining (NHEJ)] of DSB repair that is believed to compete with HR. Our data demonstrated that Ku70 is an essential gene in human somatic cells. More importantly, however, in Ku70(+/-) cells, the frequency of gene targeting was 5- to 10-fold higher than in wild-type cells. RNA interference and short-hairpinned RNA strategies to deplete Ku70 phenocopied these results in wild-type cells and greatly accentuated them in Ku70(+/-) cell lines. Thus, Ku70 protein levels significantly influenced the frequency of rAAV-mediated gene targeting in human somatic cells. Our data suggest that gene-targeting frequencies can be significantly improved in human cells by impairing the NHEJ pathway, and we propose that Ku70 depletion can be used to facilitate both knockout and gene therapy approaches.

Yeast vectors for the integration/expression of any sequence at the TYR1 locus

We have constructed new yeast vectors for targeted integration and conditional expression of any sequence at the Saccharomyces cerevisiae TYR1 locus which becomes disrupted. We show that vector integration is not neutral, causing prototrophy for tyrosine and auxotrophy for the vector's selectable marker (uracil or leucine, depending on the vector used). This feature allows a double screening of transformed yeast cells, improving the identification of colonies with the desired chromosomal structure. The GAL10 gene promoter has been added to drive conditional expression of cloned sequences. Using these vectors, chromosomal structure verification of recombinant clones is no longer necessary, since the noise of non-homologous recombination, as well as spontaneous reversion of the selected phenotype, can easily be identified. The ability of the vector to conditionally control gene expression has been confirmed using the gene for the green fluorescent protein (GFP) as a reporter.

Synthesis-dependent strand annealing in meiosis

Recent studies led to the proposal that meiotic gene conversion can result after transient engagement of the donor chromatid and subsequent DNA synthesis-dependent strand annealing (SDSA). Double Holliday junction (dHJ) intermediates were previously proposed to form both reciprocal crossover recombinants (COs) and noncrossover recombinants (NCOs); however, dHJs are now thought to give rise mainly to COs, with SDSA forming most or all NCOs. To test this model in Saccharomyces cerevisiae, we constructed a random spore system in which it is possible to identify a subset of NCO recombinants that can readily be accounted for by SDSA, but not by dHJ-mediated recombination. The diagnostic class of recombinants is one in which two markers on opposite sides of a double-strand break site are converted, without conversion of an intervening heterologous insertion located on the donor chromatid. This diagnostic class represents 26% of selected NCO recombinants. Tetrad analysis using the same markers provided additional evidence that SDSA is a major pathway for NCO gene conversion in meiosis.

Genetic side effects accompanying gene targeting in yeast: the influence of short heterologous termini

We investigated the influence of short terminal heterologies on recombination between transforming linear DNA fragments and the yeast Saccharomyces cerevisiae genome. The efficiency of plasmid integration to the CYC1 locus (ends-in assay) was decreased more than five-fold when the size of terminal heterology exceeded 28 nucleotides (nt) and a similar inhibitory effect was also observed in the ends-out assay (replacement of the ura3-52 allele by the URA3 gene). Plasmid integration occurred almost exclusively in the target homology and was accompanied by excessive degradation of the heterologous termini. Illegitimate integrations were much more frequent in the ends-out transformation in both the absence (8.9%) and the presence (23.7%) of 45/46 heterologous nucleotides at the ends of the transforming fragment. Interestingly, only about 60% of transformants arose by simple gene replacement, regardless of the presence of heterologous ends, whereas more complex interactions resulted in gene or whole chromosome duplications. Our results warn that different genetic alterations may be introduced in the host strain during ends-out transformation but also indicate possible mechanisms for formation of duplications in the genome.

Regulation of homologous integration in yeast by the DNA repair proteins Ku70 and RecQ

The product of the BLM gene, which is mutated in Bloom syndrome in humans, and the Saccharomyces cerevisiae protein Sgs1 are both homologous to the Escherichia coli DNA helicase RecQ, and have been shown to be involved in the regulation of homologous recombination. Mutations in these genes result in genome instability because they increase the incidence of deletions and translocations. We present evidence for a genetic interaction between SGS1 and YKU70, which encodes the S. cerevisiae homologue of the human DNA helicase Ku70. In a yku70 mutant background, sgs1 mutations increased sensitivity to DNA breakage induced either by treatment with camptothecin or by the expression of the restriction enzyme EcoRI. The yku70 mutation caused a fourfold increase in the rate of double-strand break (DSB)-induced target integration as that seen in the sgs1 mutant. The combination of yku70 and sgs1 mutations additively increased the rate of the targeted integration, and this effect was completely suppressed by deletion of RAD51. Interestingly, an extra copy of YKU70 partially suppressed the increase in targeted integration seen in the sgs1 single mutant. These results suggest that Yku70 modulates the repair of DSBs associated with homologous recombination in a different way from Sgs1, and that the inactivation of RecQ and Ku70 homologues may enhance the frequency of gene targeting in higher eukaryotes.

Gene targeting in yeast is initiated by two independent strand invasions

To study the mechanism of gene targeting, we examined heteroduplex DNA (hDNA) formation during targeting of two separate chromosomal locations in Saccharomyces cerevisiae. We examined both replacement of the entire gene with a heterologous selectable marker and correction of a single base pair insertion mutation by gene targeting, and in all cases our results were consistent with separate strand invasion/resolution at the two ends of the targeting fragment as the dominant mechanism in wild-type cells. A small subset of transformants was consistent with assimilation of a single strand of targeting DNA encompassing both flanking homology regions and the marker into hDNA. hDNA formation during correction of a point mutation by targeted integration was conspicuously altered in a mismatch repair-deficient background and was consistent with single-strand invasion/assimilation without mismatch correction, confirming that gene targeting by this pathway is actively impeded in wild-type yeast. Finally, inversion of one targeted locus and mutation of an active origin of DNA replication at the other locus affected hDNA formation significantly, suggesting that formation of productive interactions between the targeting DNA and the targeted site in the chromosome is sensitive to local DNA dynamics.

New insights into the mechanism of homologous recombination in yeast

Genome stability is of primary importance for the survival and proper functioning of all organisms. Double-strand breaks (DSBs) arise spontaneously during growth, or can be created by external insults. Repair of DSBs by homologous recombination provides an efficient and fruitful pathway to restore chromosomal integrity. Exciting new work in yeast has lately provided insights into this complex process. Many of the proteins involved in recombination have been isolated and the details of the repair mechanism are now being unraveled at the molecular level. In this review, we focus on recent studies which dissect the recombinational repair of a single broken chromosome. After DSB formation, a decision is made regarding the mechanism of repair (recombination or non-homologous end-joining). This decision is under genetic control. Once committed to the recombination pathway, the broken chromosomal ends are resected by a still unclear mechanism in which the DNA damage checkpoint protein Rad24 participates. At this stage several proteins are recruited to the broken ends, including Rad51p, Rad52p, Rad55p, Rad57p, and possibly Rad54p. A genomic search for homology ensues, followed by strand invasion, promoted by the Rad51 filament with the participation of Rad55p, Rad57p and Rad54p. DNA synthesis then takes place, restoring the resected ends. Crossing-over formation depends on the length of the homologous recombining sequences, and is usually counteracted by the activity of the mismatch repair system. Given the conservation of the repair mechanisms and genes throughout evolution, these studies have profound implications for other eukaryotic organisms.

Genetic aspects of targeted insertion mutagenesis in yeasts

Targeted insertion mutagenesis is a main molecular tool of yeast science initially applied in Saccharomyces cerevisiae. The method was extended to fission yeast Schizosaccharomyces pombe and to "non-conventional" yeast species, which show specific properties of special interest to both basic and applied research. Consequently, the behaviour of such non-Saccharomyces yeasts is reviewed against the background of the knowledge of targeted insertion mutagenesis in S. cerevisiae. Data of homologous integration efficiencies obtained with circular, ends-in or ends-out vectors in several yeasts are compared. We follow details of targeted insertion mutagenesis in order to recognize possible rate-limiting steps. The route of the vector to the target and possible mechanisms of its integration into chromosomal genes are considered. Specific features of some yeast species are discussed. In addition, similar approaches based on homologous recombination that have been established for the mitochondrial genome of S. cerevisiae are described.

Site-specific genomic (SSG) and random domain-localized (RDL) mutagenesis in yeast

Background

A valuable weapon in the arsenal available to yeast geneticists is the ability to introduce specific mutations into yeast genome. In particular, methods have been developed to introduce deletions into the yeast genome using PCR fragments. These methods are highly efficient because they do not require cloning in plasmids.

Results

We have modified the existing method for introducing deletions in the yeast (S. cerevisiae) genome using PCR fragments in order to target point mutations to this genome. We describe two PCR-based methods for directing point mutations into the yeast genome such that the final product contains no other disruptions. In the first method, site-specific genomic (SSG) mutagenesis, a specific point mutation is targeted into the genome. In the second method, random domain-localized (RDL) mutagenesis, a mutation is introduced at random within a specific domain of a gene. Both methods require two sequential transformations, the first transformation integrates the URA3 marker into the targeted locus, and the second transformation replaces URA3 with a PCR fragment containing one or a few mutations. This PCR fragment is synthesized using a primer containing a mutation (SSG mutagenesis) or is synthesized by error-prone PCR (RDL mutagenesis). In SSG mutagenesis, mutations that are proximal to the URA3 site are incorporated at higher frequencies than distal mutations, however mutations can be introduced efficiently at distances of at least 500 bp from the URA3 insertion. In RDL mutagenesis, to ensure that incorporation of mutations occurs at approximately equal frequencies throughout the targeted region, this region is deleted at the same time URA3 is integrated.

Conclusion

SSG and RDL mutagenesis allow point mutations to be easily and efficiently incorporated into the yeast genome without disrupting the native locus.

Homologous gene targeting in Caenorhabditis elegans by biolistic transformation

Targeted homologous recombination is a powerful approach for genome manipulation that is widely used for gene alteration and knockouts in mouse and yeast. In Caenorhabditis elegans, several methods of target-selected mutagenesis have been implemented but none of them provides the opportunity of introducing exact predefined changes into the genome. Although anecdotal cases of homologous gene targeting in C.elegans have been reported, no practical technique of gene targeting has been developed so far. In this work we demonstrate that transformation of C.elegans by microparticle bombardment (biolistic transformation) can result in homologous recombination between introduced DNA and the chromosomal locus. We describe a scaled up version of biolistic transformation that can be used as a method for homologous gene targeting in the worm.

Ends-out, or replacement, gene targeting in Drosophila

Ends-in and ends-out refer to the two arrangements of donor DNA that can be used for gene targeting. Both have been used for targeted mutagenesis, but require donors of differing design. Ends-out targeting is more frequently used in mice and yeast because it gives a straightforward route to replace or delete a target locus. Although ends-in targeting has been successful in Drosophila, an attempt at ends-out targeting failed. To test whether ends-out targeting could be used in Drosophila, we applied two strategies for ends-out gene replacement at the endogenous yellow (y) locus in Drosophila. First, a mutant allele was rescued by replacement with an 8-kb y(+) DNA fragment at a rate of approximately 1/800 gametes. Second, a wild-type gene was disrupted by the insertion of a marker gene in exon 1 at a rate of approximately 1/380 gametes. The I-SceI endonuclease component alone is not sufficient for targeting: the FLP recombinase is also needed to generate the extrachromosomal donor. When both components are used we find that ends-out targeting can be approximately as efficient as ends-in targeting, and is likely to be generally useful for Drosophila gene targeting.

Recombination at double-strand breaks and DNA ends: conserved mechanisms from phage to humans

The recombination mechanisms that deal with double-strand breaks in organisms as diverse as phage, bacteria, yeast, and humans are remarkably conserved. We discuss conservation in the biochemical pathways required to recombine DNA ends and in the structure of the DNA products. In addition, we highlight that two fundamentally distinct broken DNA substrates exist and describe how they are repaired differently by recombination. Finally, we discuss the need to coordinate recombinational repair with cell division through DNA damage response pathways.

The mechanism of mammalian gene replacement is consistent with the formation of long regions of heteroduplex DNA associated with two crossing-over events

In this study, the mechanism of mammalian gene replacement was investigated. The system is based on detecting homologous recombination between transferred vector DNA and the haploid, chromosomal immunoglobulin mu-delta region in a murine hybridoma cell line. The backbone of the gene replacement vector (pCmuCdeltapal) consists of pSV2neo sequences bounded on one side by homology to the mu gene constant (Cmu) region and on the other side by homology to the delta gene constant (Cdelta) region. The Cmu and Cdelta flanking arms of homology were marked by insertions of an identical 30-bp palindrome which frequently escapes mismatch repair when in heteroduplex DNA (hDNA). As a result, intermediates bearing unrepaired hDNA generate mixed (sectored) recombinants following DNA replication and cell division. To monitor the presence and position of sectored sites and, hence, hDNA formation during the recombination process, the palindrome contained a unique NotI site that replaced an endogenous restriction enzyme site at each marker position in the vector-borne Cmu and Cdelta regions. Gene replacement was studied under conditions which permitted the efficient recovery of the product(s) of individual recombination events. Analysis of marker segregation patterns in independent recombinants revealed that extensive hDNA was formed within the Cmu and Cdelta regions. In several recombinants, palindrome markers in the Cmu and Cdelta regions resided on opposite DNA strands (trans configuration). These results are consistent with the mammalian gene replacement reaction involving two crossing-over events in homologous flanking DNA.

Gene targeting by homologous recombination in Drosophila

Drosophila offers many advantages as an experimental organism. However, in comparison with yeast and mouse, two other widely used eukaryotic model systems, Drosophila suffers from an inability to perform homologous recombination between introduced DNA and the corresponding chromosomal loci. The ability to specifically modify the genomes of yeast and mouse provides a quick and easy way to generate or rescue mutations in genes for which a DNA clone or sequence is available. A method is described that enables analogous manipulations of the Drosophila genome. This technique may also be applicable to other organisms for which gene-targeting procedures do not yet exist.

Multiple pathways of recombination induced by double-strand breaks in Saccharomyces cerevisiae

The budding yeast Saccharomyces cerevisiae has been the principal organism used in experiments to examine genetic recombination in eukaryotes. Studies over the past decade have shown that meiotic recombination and probably most mitotic recombination arise from the repair of double-strand breaks (DSBs). There are multiple pathways by which such DSBs can be repaired, including several homologous recombination pathways and still other nonhomologous mechanisms. Our understanding has also been greatly enriched by the characterization of many proteins involved in recombination and by insights that link aspects of DNA repair to chromosome replication. New molecular models of DSB-induced gene conversion are presented. This review encompasses these different aspects of DSB-induced recombination in Saccharomyces and attempts to relate genetic, molecular biological, and biochemical studies of the processes of DNA repair and recombination.

Multiple pathways of recombination induced by double-strand breaks in Saccharomyces cerevisiae

The budding yeast Saccharomyces cerevisiae has been the principal organism used in experiments to examine genetic recombination in eukaryotes. Studies over the past decade have shown that meiotic recombination and probably most mitotic recombination arise from the repair of double-strand breaks (DSBs). There are multiple pathways by which such DSBs can be repaired, including several homologous recombination pathways and still other nonhomologous mechanisms. Our understanding has also been greatly enriched by the characterization of many proteins involved in recombination and by insights that link aspects of DNA repair to chromosome replication. New molecular models of DSB-induced gene conversion are presented. This review encompasses these different aspects of DSB-induced recombination in Saccharomyces and attempts to relate genetic, molecular biological, and biochemical studies of the processes of DNA repair and recombination.

Nonhomologous end joining during restriction enzyme-mediated DNA integration in Saccharomyces cerevisiae

The BamHI restriction enzyme mediates integration of nonhomologous DNA into the Saccharomyces cerevisiae genome (R. H. Schiestl and T. D. Petes, Proc. Natl. Acad. Sci. USA 88:7585-7589, 1991). The present study investigates the mechanism of such events: in particular, the mediating activity of various restriction enzymes and the processing of resultant fragment ends. Our results show that in addition to BamHI, BglII and KpnI increase DNA integration efficiencies severalfold, while Asp718, HindIII, EcoRI, SalI, SmaI, HpaI, MscI, and SnaBI do not. Secondly, the three active enzymes stimulated integrations only of fragments containing 5' or 3' overhangs but not of blunt-ended fragments. Thirdly, integrations mediated by one enzyme and utilizing a substrate created by another required at least 2 bp of homology. Furthermore, an Asp718 fragment possessing a 5' overhang integrated into a KpnI (isoschizomer) site possessing a 3' overhang, most likely by filling of the 5' overhang followed by 5' exonuclease digestion to produce a 3' end. We classified and analyzed the restriction enzyme-mediated integration events in the context of their genomic positions. The majority of events integrated into single sites. In the remaining 6 of 19 cases each end of the plasmid inserted into a different sequence, producing rearrangements such as duplications, deletions, and translocations.

Double-strand break-induced recombination in eukaryotes

Genetic recombination is of fundamental importance for a wide variety of biological processes in eukaryotic cells. One of the major questions in recombination relates to the mechanism by which the exchange of genetic information is initiated. In recent years, DNA double strand breaks (DSBs) have emerged as an important lesion that can initiate and stimulate meiotic and mitotic homologous recombination. In this review, we examine the models by which DSBs induce recombination, describe the types of recombination events that DSBs stimulate, and compare the genetic control of DSB-induced mitotic recombination in budding and fission yeasts.

High frequency cDNA recombination of the saccharomyces retrotransposon Ty5: The LTR mediates formation of tandem elements

Retroelement cDNA can integrate into the genome using the element-encoded integrase or it can recombine with preexisting elements using the recombination system of the host. Recombination is a particularly important pathway for the yeast retrotransposon Ty5 and accounts for approximately 30% of the putative transposition events when a homologous substrate is carried on a plasmid and approximately 7% when the substrate is located at the chromosomal URA3 locus. Characterization of recombinants revealed that they are either simple replacements of the marker gene tandem elements. Using an assay system in which the donor element and recombination substrates are separated, we found that the long terminal repeats (LTRs) are critical for tandem element formation. LTR-containing substrates generate tandem elements at frequencies more than 10-fold higher than similarly sized internal Ty5 sequences. Internal sequences, however, facilitate tandem element formation when associated with an LTR, and there is a linear relationship between frequencies of tandem element formation and the length of LTR-containing substrates. We propose that recombination is initiated between the LTRs of the cDNA and substrate and that internal sequences promote tandem element formation by facilitating sequence alignment. Because of its location in subtelomeric regions, recombinational amplification of Ty5 may contribute to the organizations of chromosome ends.

Gene targeting by linear duplex DNA frequently occurs by assimilation of a single strand that is subject to preferential mismatch correction

To study targeted recombination, a single linear 2-kb fragment of LEU2 DNA was liberated from a chromosomal site within the nucleus of Saccharomyces cerevisiae, by expression of the site-specific HO endonuclease. Gene targeting was scored by gene conversion of a chromosomal leu2 mutant allele by the liberated LEU2 fragment. This occurred at a frequency of only 2 x 10(-4), despite the fact that nearly all cells successfully repaired, by single-strand annealing, the chromosome break created by liberating the fragment. The frequency of Leu+ recombinants was 6- to 25-fold higher in pms1 strains lacking mismatch repair. In 70% of these cases, the colony was sectored for Leu+/Leu-. Similar results were obtained when a 4. 1-kb fragment containing adjacent LEU2 and ADE1 genes was liberated, to convert adjacent leu2 and ade1 mutations on the chromosome. These results suggest that a linear fragment is not assimilated into the recipient chromosome by two crossovers each close to the end of the fragment; rather, heteroduplex DNA between the fragment and the chromosome is apparently formed over the entire region, by the assimilation of one of the two strands of the linear duplex DNA. Moreover, the recovery of Leu+ transformants is frequently defeated by the cell's mismatch repair machinery; more than 85% of mismatches in heteroduplex DNA are corrected in favor of the resident, unbroken (mutant) strand.

Enhancement of somatic intrachromosomal homologous recombination in Arabidopsis by the HO endonuclease

The HO endonuclease promotes gene conversion between mating-type alleles in yeast by a DNA double-strand break at the site of conversion (the MAT-Y/Z site). As a first step toward understanding the molecular basis of homologous recombination in higher plants, we demonstrate that expression of HO in Arabidopsis enhances intrachromosomal recombination between inverted repeats of two defective beta-glucuronidase (gus) genes (GUS- test construct). One of these genes has the Y/Z site. The two genes share 2.5 kb of DNA sequence homology around the HO cut site. Somatic recombination between the two repeats was determined by using a histochemical assay of GUS activity. The frequency of Gus+ sectors in leaves of F1 plants from a cross between parents homozygous for the GUS- test construct and HO, respectively, was 10-fold higher than in F1 plants from a cross between the same plant containing the GUS- test construct and a wild-type parent. Polymerase chain reaction analysis showed restoration of the 5' end of the GUS gene in recombinant sectors. The induction of intrachromosomal gene conversion in Arabidopsis by HO reveals the general utility of site-specific DNA endonucleases in producing targeted homologous recombination in plant genomes.

Integration of an insertion-type transferred DNA vector from Agrobacterium tumefaciens into the Saccharomyces cerevisiae genome by gap repair

Recently, it was shown that Agrobacterium tumefaciens can transfer transferred DNA (T-DNA) to Saccharomyces cerevisiae and that this T-DNA, when used as a replacement vector, is integrated via homologous recombination into the yeast genome. To test whether T-DNA can be a suitable substrate for integration via the gap repair mechanism as well, a model system developed for detection of homologous recombination events in plants was transferred to S. cerevisiae. Analysis of the yeast transformants revealed that an insertion type T-DNA vector can indeed be integrated via gap repair. Interestingly, the transformation frequency and the type of recombination events turned out to depend strongly on the orientation of the insert between the borders in such an insertion type T-DNA vector.

Effects of terminal nonhomology and homeology on double-strand-break-induced gene conversion tract directionality

Double-strand breaks (DSBs) greatly enhance gene conversion in the yeast Saccharomyces cerevisiae. In prior plasmid x chromosome crosses, conversion tracts were often short ( < 53 bp) and usually extended in only one direction from a DSB in an HO recognition sequence inserted into ura3. To allow fine-structure analysis of short and unidirectional tracts, phenotypically silent markers were introduced at 3- and 6-bp intervals flanking the HO site. These markers, which created a 70-bp homeologous region (71% homology), greatly increased the proportion of bidirectional tracts. Among products with short or unidirectional tracts, 85% were highly directional, converting markers on only one side (the nearest marker being 6 bp from the HO site). A DSB in an HO site insertion creates terminal nonhomologies. The high degree of directionality is a likely consequence of the precise cleavage at homology/nonhomology borders in hybrid DNA by Rad1/10 endonuclease. In contrast, terminal homeology alone yielded mostly unidirectional tracts. Thus, nonhomology flanked by homeology yields primarily bidirectional tracts, but terminal homeology or nonhomology alone yields primarily unidirectional tracts. These results are inconsistent with uni- and bidirectional tracts arising from one- and two-ended invasion mechanisms, respectively, as reduced homology would be expected to favor one-ended events. Tract spectra with terminal homeology alone with similar in RAD1 and rad1 cells, indicating that the high proportion of bidirectional tracts seen with homeology flanking nonhomology is not a consequence of Rad1/10 cleavage at homology/homeology boundaries. Instead, tract directionality appears to reflect the influence of the degree of broken-end homology on mismatch repair.