Influence of non-homology between recombining DNA sequences on double-strand break repair in Saccharomyces cerevisiae

In this paper we study the influence of non-homology between plasmid and chromosomal DNA on the efficiency of recombinational repair of plasmid double-strand breaks and gaps in yeast. For this purpose we used different combinations of plasmids and yeast strains carrying various deletions within the yeast LYS2 gene. A 400 by deletion in plasmid DNA had no effect on recombinational plasmid repair. However, a 400 by deletion in chromosomal DNA dramatically reduced the efficiency of this repair mechanism, but recombinational repair of plasmids linearized by a double-strand break with cohesive ends still remained the dominant repair process. We have also studied the competition between recombination and ligation in the repair of linearized plasmids. Our experimental evidence suggests that recombinational repair is attempted but aborted if only one recombinogenic end with homology to chromosomal DNA is present in plasmid DNA. This situation results in a decreased probability of non-recombinational (i.e. ligation) repair of linearized plasmid DNA.     

Influence of non-homology between recombining DNA sequences on double-strand break repair in Saccharomyces cerevisiae

In this paper we study the influence of non-homology between plasmid and chromosomal DNA on the efficiency of recombinational repair of plasmid double-strand breaks and gaps in yeast. For this purpose we used different combinations of plasmids and yeast strains carrying various deletions within the yeast LYS2 gene. A 400 by deletion in plasmid DNA had no effect on recombinational plasmid repair. However, a 400 by deletion in chromosomal DNA dramatically reduced the efficiency of this repair mechanism, but recombinational repair of plasmids linearized by a double-strand break with cohesive ends still remained the dominant repair process. We have also studied the competition between recombination and ligation in the repair of linearized plasmids. Our experimental evidence suggests that recombinational repair is attempted but aborted if only one recombinogenic end with homology to chromosomal DNA is present in plasmid DNA. This situation results in a decreased probability of non-recombinational (i.e. ligation) repair of linearized plasmid DNA.     

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.     

The RecE recombination pathway mediates recombination between partially homologous DNA sequences: structural analysis of recombination products

Escherichia coli generalized recombination, utilizing the RecA RecB recombination pathway, requires large stretches (70-200 bp) of complete DNA sequence homology. In contrast, we have found that the RecE pathway can promote recombination between DNA with only short stretches of homology. A plasmid containing 10 partially homologous direct repeats was linearized by digestion with specific restriction enzymes. After transformation, a RecE+ (sbcA) host was able to circularize the plasmid by recombination between partially homologous direct repeat sequences. Recombination occurred in regions of as little as 6 bp of perfect homology. Recombination was enhanced in the regions adjacent to restriction sites used to linearize the plasmid, consistent with a role of double-strand breaks in promoting recombination. A mechanism is proposed in which the 5' exonuclease, ExoVIII, produces 3' single-stranded ends from the linearized plasmid. These pair with other sequences of partial homology. Partial homologies in the sequences flanking the actual join serve to stabilize this recombination intermediate. Recombination is completed by a process of "copy and join." This recombination mechanism requires less homology to stabilize intermediates than the degree of homology needed for mechanisms involving strand invasion. Its role in nature may be to increase genomic diversity, for example, by enhancing recombination between bacteriophages and regions of the bacterial chromosome.     

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.     

Chromosomal targeting of replicating plasmids in the yeast Hansenula polymorpha.

Using an optimized transformation protocol we have studied the possible interactions between transforming plasmid DNA and the Hansenula polymorpha genome. Plasmids consisting only of a pBR322 replicon, an antibiotic resistance marker for Escherichia coli and the Saccharomyces cerevisiae LEU2 gene were shown to replicate autonomously in the yeast at an approximate copy number of 6 (copies per genome equivalent). This autonomous behaviour is probably due to an H. polymorpha replicon-like sequence present on the S. cerevisiae LEU2 gene fragment. Plasmids replicated as multimers consisting of monomers connected in a head-to-tail configuration. Two out of nine transformants analysed appeared to contain plasmid multimers in which one of the monomers contained a deletion. Plasmids containing internal or flanking regions of the genomic alcohol oxidase gene were shown to integrate by homologous single or double cross-over recombination. Both single- and multi-copy (two or three) tandem integrations were observed. Targeted integration occurred in 1-22% of the cases and was only observed with plasmids linearized within the genomic sequences, indicating that homologous linear ends are recombinogenic in H. polymorpha. In the cases in which no targeted integration occurred, double-strand breaks were efficiently repaired in a homology-independent way. Repair of double-strand breaks was precise in 50-68% of the cases. Linearization within homologous as well as nonhomologous plasmid regions stimulated transformation frequencies up to 15-fold.     

Characterization of RAD51-independent break-induced replication that acts preferentially with short homologous sequences

Repair of double-strand breaks by gene conversions between homologous sequences located on different Saccharomyces cerevisiae chromosomes or plasmids requires RAD51. When repair occurs between inverted repeats of the same plasmid, both RAD51-dependent and RAD51-independent repairs are found. Completion of RAD51-independent plasmid repair events requires RAD52, RAD50, RAD59, TID1 (RDH54), and SRS2 and appears to involve break-induced replication coupled to single-strand annealing. Surprisingly, RAD51-independent recombination requires much less homology (30 bp) for strand invasion than does RAD51-dependent repair (approximately 100 bp); in fact, the presence of Rad51p impairs recombination with short homology. The differences between the RAD51- and RAD50/RAD59-dependent pathways account for the distinct ways that two different recombination processes maintain yeast telomeres in the absence of telomerase.     

Homologous recombination and the repair of double-strand breaks during cotransformation of Dictyostelium discoideum.

We examined the ability of unlinked nonreplicating plasmid molecules to undergo homologous recombination during cotransformation of Dictyostelium amoebae. The transformation vector B10S confers resistance to the antibiotic G418 and was always presented to amoebae as a closed circle. Cotransforming DNA, containing a slime mold cDNA and sequences homologous to the primary vector, was presented either as a closed circle or as a linear molecule after digestion with restriction endonucleases which cut within one of three distinct regions of the plasmid. Remarkably, homologous recombination occurred in every clone examined. Moreover, the products of recombination were identical in all instances, irrespective of the presence or position of linearized ends. The ends of the linear templates were not recombinogenic. Repair of the introduced double-strand break occurred frequently during recombination. The repair could occur intermolecularly or, more likely, intramolecularly, i.e., by recircularization. Many of the recombination events were of a nonreciprocal nature. Despite the startlingly frequent level of homologous recombination, the use of cotransforming DNA which contains no homology to the selected vector established that such recombination was not required for cotransformation.     

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.     

Homologous, homeologous, and illegitimate repair of double-strand breaks during transformation of a wild-type strain and a rad52 mutant strain of Saccharomyces cerevisiae.

Different modes of in vivo repair of double-strand breaks (DSBs) have been described for various organisms: the recombinational DSB repair (DSBR) mode, the single-strand annealing (SSA) mode, and end-to-end joining. To investigate these modes of DSB repair in Saccharomyces cerevisiae, we have examined the fate of in vitro linearized replicative plasmids during transformation with respect to several parameters. We found that (i) the efficiencies of both intramolecular and intermolecular linear plasmid DSB repair are homology dependent (according to the amount of DNA used during transformation [100 ng or less], recombination between similar but not identical [homeologous] P450s sequences sharing 73% identity is 2- to 18-fold lower than recombination between identical sequences); (ii) the RAD52 gene product is not essential for intramolecular recombination between homologous and homeologous direct repeats (as in the wild-type strain, recombination occurs with respect to the overall alignment of the parental sequences); (iii) in contrast, the RAD52 gene product is required for intermolecular interactions (the rare transformants which are obtained contain plasmids resulting from deletion-forming intramolecular events involving little or no sequence homology); (iv) similarly, sequencing data revealed examples of intramolecular joining within the few terminal nucleotides of the transforming DNA upon transformation with a linear plasmid with no repeat in the wild-type strain. The recombinant junctions of the rare illegitimate events obtained with S. cerevisiae are very similar to those observed in the repair of DSB in mammalian cells. Together, these and previous results suggest the existence of alternative modes for DSB repair during transformation which differ in their efficiencies and in the structure of their products. We discuss the implications of these results with respect to the existence of alternative pathways and the role of the RAD52 gene product.     

Efficient homologous recombination of linear DNA substrates after injection into Xenopus laevis oocytes.

When DNA molecules are injected into Xenopus oocyte nuclei, they can recombine with each other. With bacteriophage lambda DNAs, it was shown that this recombination is stimulated greatly by introduction of double-strand breaks into the substrates and is dependent on homologous overlaps in the recombination interval. With plasmid DNAs it was shown that little or no recombination occurs between circular molecules but both intra- and intermolecular events take place very efficiently with linear molecules. As with the lambda substrates, homology was required to support recombination; no simple joining of ends was observed. Blockage of DNA ends with nonhomologous sequences interfered with recombination, indicating that ends are used directly to initiate homologous interactions. These observations are combined to evaluate possible models of recombination in the oocytes. Because each oocyte is capable of recombining nanogram quantities of linear DNA, this system offers exceptional opportunities for detailed molecular analysis of the recombination process in a higher organism.     

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.     

Insertion of nonhomologous DNA into the yeast genome mediated by homologous recombination with a cotransforming plasmid

Bacterial plasmids containing no detectable homology with yeast DNA sequences were inserted into the yeast genome by cotransforming with a plasmid containing a yeast gene. Analysis of the yeast transformants confirmed that recombination events occurred between the prokaryotic sequences shared by the two plasmids and between the yeast sequences common to the cotransforming plasmid and to the genome. Multiple copies of the two plasmids, in both tandem and interspersed arrays, are inserted by this method. Populations of cells grown from individual transformants are heterogenous for the number of integrated sequences. The number of integrated bacterial sequences is greatly reduced after 100 generations of growth in the populations that initially contained large numbers of sequences, while it is stable in those populations that initially contained either a single or a small number of copies.     

Nonhomologous DNA end joining in Schizosaccharomyces pombe efficiently eliminates DNA double-strand-breaks from haploid sequences.

Cells of higher eucaryotes are known to possess mechanisms of illegitimate recombination which promote the joining between nonhomologous ends of broken DNA and thus may serve as basic tools of double-strand-break (DSB) repair. Here we show that cells of the fission yeast Schizosaccharomyces pombe also contain activities of nonhomologous DNA end joining resembling the ones found in higher eucaryotes. Nonhomologous end joining activities were detected by transformation of linearized self-replicating plasmids in yeast cells employing a selection procedure which only propagates transformants carrying recircularized plasmid molecules. Linear plasmid substrates were generated by duplicate restriction cuts carrying either blunt ends or 3' or 5' protruding single strands (PSS) of 4 nt which were efficiently joined in any tested combination. Sequence analysis of joined products revealed that junctional sequences were shortened by 1 to 14 nt. Two mechanisms may account for junction formation (i) loss of terminal nucleotides from PSS tails to produce blunt ends which can be joined to abutting ends and (ii) interactions of DNA termini at patches of sequence homologies (1-4 bp) by formation of overlap intermediates which are subsequently processed. A general feature of the yeast joining system is that end joining can only be detected in the absence of sequence homology between the linear substrate and host genome. In the presence of homology, nonhomologous DNA end joining is efficiently competed by activities of homologous recombination.     

An Examination of the Effects of Double-Strand Breaks on Extrachromosomal Recombination in Mammalian Cells

We studied the effects of double-strand breaks on intramolecular extrachromosomal homologous recombination in mammalian cells. Pairs of defective herpes thymidine kinase (tk) sequences were introduced into mouse Ltk- cells on a DNA molecule that also contained a neo gene under control of the SV40 early promoter/enhancer. With the majority of the constructs used, gene conversions or double crossovers, but not single crossovers, were recoverable. DNA was linearized with various restriction enzymes prior to transfection. Recombination events producing a functional tk gene were monitored by selecting for tk-positive colonies. For double-strand breaks placed outside of the region of homology, maximal recombination frequencies were measured when a break placed the two tk sequences downstream from the SV40 early promoter/enhancer. We observed no relationship between recombination frequency and either the distance between a break and the tk sequences or the distance between the tk sequences. The quantitative effects of the breaks appeared to depend on the degree of homology between the tk sequences. We also observed that inverted repeats recombined as efficiently as direct repeats. The data indicated that the breaks influenced recombination indirectly, perhaps by affecting the binding of a factor(s) to the SV40 promoter region which in turn stimulated or inhibited recombination of the tk sequences. Taken together, we believe that our results provide strong evidence for the existence of a pathway for extrachromosomal homologous recombination in mammalian cells that is distinct from single-strand annealing. We discuss the possibility that intrachromosomal and extrachromosomal recombination have mechanisms in common.     

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.     

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.     

Chi sites in combination with RecA protein increase the survival of linear DNA in Escherichia coli by inactivating exoV activity of RecBCD nuclease.

In Escherichia coli, unprotected linear DNA is degraded by exoV activity of the RecBCD nuclease, a protein that plays a central role in the repair of double-strand breaks. Specific short asymmetric sequences, called chi sites, are hotspots for RecBCD-promoted recombination and are shown in vitro to attenuate exoV activity. To study RecBCD-chi site interactions in vivo we used phage lambda's terminase to introduce a site-specific double-strand break at lambda's cos site inserted into a plasmid. We show that after terminase has cut cos in vivo, nucleases degrade linearized DNA only from the end that does not have a strong terminase binding site. Linearized cosmid DNA containing chi sites in the proper orientation to the unprotected end is degraded more slowly in rec+ E. coli than is chi-less DNA. Increased survival of chi-containing DNA is a result of partial inactivation of exoV activity and is dependent on RecA and SSB proteins. The linearization of chi-containing DNA molecules leads to RecA-dependent formation of branched structures which have been proposed as intermediates in the RecBCD pathway of double-strand break repair.     

Intermolecular homologous recombination in plants.

To study DNA topological requirements for homologous recombination in plants, we have constructed pairs of plasmids that contain nonoverlapping deletions in the neomycin phosphotransferase gene [APH(3')II], which, when intact, confers kanamycin resistance to plant cells. Protoplasts isolated from Nicotiana tabacum were cotransformed with complementary pairs of plasmids containing these truncated gene constructs. Homologous recombination or gene conversion within the homologous sequences (6 to 405 base pairs) of the protein-coding region of the truncated genes led to the restoration of the functional APH(3')II gene, rendering these cells resistant to kanamycin. Circular plasmid DNAs recombined very inefficiently, independent of the length of the homologous region. A double-strand break in one molecule only slightly increased the recombination frequency. The most favorable substrates for recombination were linear molecules. In this case, the recombination frequency was positively correlated with the length of the homologous regions. The recombination frequency of plasmids linearized at sites proximal to the deletion-homology junction was significantly higher than when linearization was distal to the homologous region. Vector homology within cotransformed plasmid sequences also increased the recombination frequency.     

Nonhomologous DNA end rejoining in chromosomal aberration formation

The role of recombination of nonhomologous DNA ends in chromosomal aberration formation was investigated in Chinese hamster ovary cells. Restriction enzymes that produce blunt, 3′ overhanging, or 5′ overhanging DNA double-strand breaks were electroporated into cells in various combinations, and chromosomal aberrations were analyzed at metaphase. For all enzyme combinations tested, there was a significant increase in the frequency of aberrations whose formation requires two breaks in the DNA over the sum obtained when each of the enzymes was tested separately and the aberration frequencies were totaled. No such pattern existed for terminal deletions, which presumably require only one DNA break. The extent of interaction did not depend on the homology in the overhanging sequences or on the combination of ends used, although the largest effect was seen with a combination of two blunt ends. This study shows that nonhomologous DNA double-strand breaks can interact to increase chromosomal aberration formation significantly.