Double-strand gap repair results in homologous recombination in mouse L cells

Editing plant genomes with CRISPR/Cas9

CRISPR/Cas9 is a rapidly developing genome editing technology that has been successfully applied in many organisms, including model and crop plants. Cas9, an RNA-guided DNA endonuclease, can be targeted to specific genomic sequences by engineering a separately encoded guide RNA with which it forms a complex. As only a short RNA sequence must be synthesized to confer recognition of a new target, CRISPR/Cas9 is a relatively cheap and easy to implement technology that has proven to be extremely versatile. Remarkably, in some plant species, homozygous knockout mutants can be produced in a single generation. Together with other sequence-specific nucleases, CRISPR/Cas9 is a game-changing technology that is poised to revolutionise basic research and plant breeding.

Homologous recombination-mediated double-strand break repair in mouse testicular extracts and comparison with different germ cell stages

Homologous recombination (HR) is established as a significant contributor to double-strand break (DSB) repair in mammalian somatic cells; however, its role in mammalian germ cells has not been characterized, although being conservative in nature it is anticipated to be the major pathway in germ cells. The germ cell system has inherent limitations by which intact cell approaches are not feasible. The present study, therefore, investigates HR-mediated DSB repair in mouse germ cell extracts by using an in vitro plasmid recombination assay based on functional rescue of a neomycin (neo) gene. A significantly high-fold increase in neo+ (Kan(R)) colonies following incubation of two plasmid substrates (neo delta1 and neo delta2) with testicular extracts demonstrated the extracts' ability to catalyze intermolecular recombination. A significant enhancement in recombinants upon linearization of one of the plasmids suggested the existence of an HR-mediated DSB repair activity. Comparison of the activity at sequential developmental stages, spermatogonia, spermatocytes and spermatids revealed its presence at all the stages; spermatocyte being the most proficient stage. Further, restriction analysis of recombinant plasmids indicated the predominance of gene conversion in enriched spermatocytes (mostly pachytenes), in contrast to gonial and spermatid extracts that showed higher reciprocal exchange. In conclusion, this study demonstrates HR repair activity at all stages of male germ cells, suggesting an important role of HR-mediated DSB repair during mammalian spermatogenesis. Further, the observed preference of gene conversion over reciprocal exchange at spermatocyte stage correlates with the close association of gene conversion with the meiotic recombination program.

Attempted base excision repair of ionizing radiation damage in human lymphoblastoid cells produces lethal and mutagenic double strand breaks

A significant proportion of cellular DNA damages induced by ionizing radiation are produced in clusters, also called multiply damaged sites. It has been demonstrated by in vitro studies and in bacteria that clustered damage sites can be converted to lethal double strand breaks by oxidative DNA glycosylases during attempted base excision repair. To determine whether DNA glycosylases could produce double strand breaks at radiation-induced clustered damages in human cells, stably transformed human lymphoblastoid TK6 cells that inducibly overexpress the oxidative DNA glycosylases/AP lyases, hNTH1 and hOGG1, were assessed for their radiation responses, including survival, mutation induction and the enzymatic production of double strand breaks post-irradiation. We found that additional double strand breaks were generated during post-irradiation incubation in uninduced TK6 control cells. Moreover, overproduction of either DNA glycosylase resulted in significantly increased double strand break formation, which correlated with an elevated sensitivity to the cytotoxic and mutagenic effects of ionizing radiation. These data show that attempted repair of radiation damage, presumably at clustered damage sites, by the oxidative DNA glycosylases can lead to the formation of potentially lethal and mutagenic double strand breaks in human cells.

A system for rapid generation of coat color-tagged knockouts and defined chromosomal rearrangements in mice

Gene targeting in mouse embryonic stem (ES) cells can be used to generate single gene mutations or defined multi-megabase chromosomal rearrangements when applied with the Cre- loxP recombination system. While single knockouts are essential for uncovering functions of cloned genes, chromosomal rearrangements are great genetic tools for mapping, mutagenesis screens and functional genomics. The conventional approach to generate mice with targeted alterations of the genome requires extensive molecular cloning to build targeting vectors and DNA-based genotyping for stock maintenance. Here we describe the design and construction of a two-library system to facilitate high throughput gene targeting and chromo-somal engineering. The unique feature of these libraries is that once a clone is isolated, it is essentially ready to be used for insertional targeting in ES cells. The two libraries each bear a complementary set of genetic markers tailored so that the vector can be used for Cre- loxP -based chromosome engineering as well as single knockouts. By incorporating mouse coat color markers into the vectors, we illustrate a widely applicable method for stock maintenance of ES cell-derived mice with single gene knockouts or more extensive chromosomal rearrangements.

Subtle mutagenesis by ends-in recombination in malaria parasites

The recent advent of gene-targeting techniques in malaria (Plasmodium) parasites provides the means for introducing subtle mutations into their genome. Here, we used the TRAP gene of Plasmodium berghei as a target to test whether an ends-in strategy, i.e., targeting plasmids of the insertion type, may be suitable for subtle mutagenesis. We analyzed the recombinant loci generated by insertion of linear plasmids containing either base-pair substitutions, insertions, or deletions in their targeting sequence. We show that plasmid integration occurs via a double-strand gap repair mechanism. Although sequence heterologies located close (less than 450 bp) to the initial double-strand break (DSB) were often lost during plasmid integration, mutations located 600 bp and farther from the DSB were frequently maintained in the recombinant loci. The short lengths of gene conversion tracts associated with plasmid integration into TRAP suggests that an ends-in strategy may be widely applicable to modify plasmodial genes and perform structure-function analyses of their important products.

Rescue of polyomavirus DNA after co-transfection of recombinant plasmids with viral DNA fragments

Plasmid DNA bearing a single copy of the mouse polyomavirus (Py) genome (template A) was transfected into murine cells together with another DNA (template B) carrying intact the viral sequence interrupted in template A. Rescue of unit-length Py DNA including markers from both templates was observed as long as the viral DNA in B overlapped that split in A by one kbp or more. Such rescue was not detectably enhanced by linearizing either or both template(s), and occurred in the absence of template replication. These findings are suggestive of an intermolecular recombination process taking place soon after transfection and starting with homologous pairing between A and B. Such pairing would facilitate removal of vector DNA from one template (A), followed by closure of the resulting break or gap through recombination with the other template (B). Since B may consist of a PCR-synthesized DNA fragment, these observations could conceivably serve as the basis for a method of generating mutant viral genomes.

Extrachromosomal recombination occurs efficiently in cells defective in various DNA repair systems

A series of different frameshift mutations of a firefly luciferase reporter plasmid was created so that no activity was obtained when they were transfected into mammalian cells. Co-transfection of these constructs with short fragments of the original sequence resulted in luciferase activity in different cell lines (A-549, NIH 3T3 and Jurkat). The level of this activity was dependent on the length of the fragment, regardless of cell line examined. Two different transfection techniques (lipofection and adenovirus-enhanced gene transfer) gave similar results. It was shown by polymerase chain reaction that expression of detectable luciferase required recombination of the transfected molecules. Cells with defined defects in DNA repair pathways were examined for their ability to perform this extrachromosomal recombination. Cells lacking normal Ku p80, (ADP-ribosyl)transferase, MLH1 or XP-C were all capable of restoring expression to the frameshifted constructs. Given the pivotal roles of the above molecules in the pathways of DNA repair, it seems that this recombination derives from a different activity.

Gene conversion during vector insertion in embryonic stem cells

Recombination of an insertion vector into its chromosomal homologue is a conservative event in that both the chromosomal and the vector sequences are preserved. However, gene conversion may accompany homologous recombination of an insertion vector. To examine gene conversion in more detail we have determined the targeting frequencies and the structure of the recombinant alleles generated with a series of vectors which target the hprt gene in embryonic stem cells. We demonstrate that gene conversion of the introduced mutation does not significantly limit homologous recombination and that gene conversion occurs without a sequence specific bias for five different mutations. The frequency of the loss of a vector mutation and the gain of a chromosomal sequence is inversely proportional to the distance between the vector mutation and the double-strand break. The loss of a chromosomal sequence and the gain of a vector mutation occurs at a low frequency.

Identification of mismatch repair genes and their role in the development of cancer

Mismatched base pairs are generated by damage to DNA, by damage to nucleotide precursors, by errors that occur during DNA replication, and during the formation of intermediates in genetic recombination. Enzyme systems that faithfully repair these DNA aberrations have been identified in a wide variety of organisms. At lease some of the components of these repair systems have been conserved, both structurally and functionally, throughout evolutionary time. In humans, defective mismatch repair genes have been linked to hereditary nonpolyposis colon cancer as well as to sporadic cancers that exhibit length polmorphisms in simple repeat (microsatellite) DNA sequences. The involvement of mismatch repair defects in microsatellite instability and tumorigenesis suggests that a generalized mutator phenotype is responsible for the large number of genetic alterations observed in tumors.

Induction of homologous recombination in mammalian chromosomes by using the I-SceI system of Saccharomyces cerevisiae

The mitochondrial intron-encoded endonuclease I-SceI of Saccharomyces cerevisiae has an 18-bp recognition sequence and, therefore, has a very low probability of cutting DNA, even within large genomes. We demonstrate that double-strand breaks can be initiated by the I-SceI endonuclease at a predetermined location in the mouse genome and that the breaks can be repaired with a donor molecule homologous regions flanking the breaks. This induced homologous recombination is approximately 2 orders of magnitude more frequent than spontaneous homologous recombination and at least 10 times more frequent than random integration near an active promoter. As a consequence of induced homologous recombination, a heterologous novel sequence can be inserted at the site of the break. This recombination can occur at a variety of chromosomal targets in differentiated and multipotential cells. These results demonstrate homologous recombination involving chromosomal DNA by the double-strand break repair mechanism in mammals and show the usefulness of very rare cutter endonucleases, such as I-SceI, for designing genome rearrangements.

Efficiency of insertion versus replacement vector targeting varies at different chromosomal loci

We have analyzed the targeting frequencies and recombination products generated with isogenic vectors at the fah and fgr loci in embryonic stem cells. A single vector which could be linearized at different sites to generate either a replacement or an insertion vector was constructed for each locus. A replacement event predominated when the vectors were linearized at the edge of the homologous sequences, while an insertion event predominated when the vectors were linearized within the homologous sequences. However, the ratio of the targeting frequencies exhibited by the different vector configurations differed for the two loci. When the fgr vector was linearized as an insertion vector, the ratio of targeted to random integrations was four- to eightfold greater than when the vector was linearized as a replacement vector. By contrast, the ratio of targeted to random integrations at the fah locus did not vary with the linearization site of the vector. The different relationships between the targeting frequency and the vector configuration at the fgr and fah loci may indicate a DNA sequence or chromatin structure preference for different targeting pathways.

Efficiency of insertion versus replacement vector targeting varies at different chromosomal loci

We have analyzed the targeting frequencies and recombination products generated with isogenic vectors at the fah and fgr loci in embryonic stem cells. A single vector which could be linearized at different sites to generate either a replacement or an insertion vector was constructed for each locus. A replacement event predominated when the vectors were linearized at the edge of the homologous sequences, while an insertion event predominated when the vectors were linearized within the homologous sequences. However, the ratio of the targeting frequencies exhibited by the different vector configurations differed for the two loci. When the fgr vector was linearized as an insertion vector, the ratio of targeted to random integrations was four- to eightfold greater than when the vector was linearized as a replacement vector. By contrast, the ratio of targeted to random integrations at the fah locus did not vary with the linearization site of the vector. The different relationships between the targeting frequency and the vector configuration at the fgr and fah loci may indicate a DNA sequence or chromatin structure preference for different targeting pathways.

Different capacities for recombination in closely related human lymphoblastoid cell lines with different mutational responses to X-irradiation

WIL2-NS and TK6 are two distinct human lymphoblast cell lines derived from a single male donor. WIL2-NS cells are significantly more resistant to the cytotoxic effects of X-irradiation but considerably more sensitive to induced mutation. In an effort to determine the mechanistic basis for these differences, we analyzed the physical structures of thymidine kinase (tk)-deficient mutants isolated after X-ray treatment of tk heterozygotes derived from TK6 and the more mutable WIL2-NS. Southern analysis showed that while 84% of TK6-derived mutants had arisen by loss of heterozygosity (LOH), all 106 mutants from WIL2-NS derivatives arose with LOH at tk and all but one showed LOH at other linked loci on chromosome 17. We adapted a fluorescence in situ hybridization technique to distinguish between LOH due to deletion, which results in retention of only one tk allele, and LOH due to a mechanism involving the homologous chromosome (e.g., recombination), which results in the retention of two alleles. Among the LOH mutants derived that were analyzed in this way, 9 of 26 from WIL2-NS and 11 of 17 from TK6 cell lines arose by deletion. The remaining mutants retained two copies of the tk gene and thus arose by a mechanism involving the homologous allele. Since many of these mutants arising by a homologous mechanism retained partial heterozygosity of chromosome 17, they must have arisen by recombination or gene conversion, and not chromosome loss and reduplication. Finally, the recombinational capacities of WIL2-NS and TK6 were compared in transfection assays with plasmid recombination substrates. Intermolecular recombination frequencies were greater in WIL2-NS than in TK6. These data are consistent with a model suggesting that a recombinational repair system is functioning at a higher level in WIL2-NS than in TK6; the greater mutability of the tk locus in WIL2-NS results from more frequent inter- and intramolecular recombination events.

Different capacities for recombination in closely related human lymphoblastoid cell lines with different mutational responses to X-irradiation

WIL2-NS and TK6 are two distinct human lymphoblast cell lines derived from a single male donor. WIL2-NS cells are significantly more resistant to the cytotoxic effects of X-irradiation but considerably more sensitive to induced mutation. In an effort to determine the mechanistic basis for these differences, we analyzed the physical structures of thymidine kinase (tk)-deficient mutants isolated after X-ray treatment of tk heterozygotes derived from TK6 and the more mutable WIL2-NS. Southern analysis showed that while 84% of TK6-derived mutants had arisen by loss of heterozygosity (LOH), all 106 mutants from WIL2-NS derivatives arose with LOH at tk and all but one showed LOH at other linked loci on chromosome 17. We adapted a fluorescence in situ hybridization technique to distinguish between LOH due to deletion, which results in retention of only one tk allele, and LOH due to a mechanism involving the homologous chromosome (e.g., recombination), which results in the retention of two alleles. Among the LOH mutants derived that were analyzed in this way, 9 of 26 from WIL2-NS and 11 of 17 from TK6 cell lines arose by deletion. The remaining mutants retained two copies of the tk gene and thus arose by a mechanism involving the homologous allele. Since many of these mutants arising by a homologous mechanism retained partial heterozygosity of chromosome 17, they must have arisen by recombination or gene conversion, and not chromosome loss and reduplication. Finally, the recombinational capacities of WIL2-NS and TK6 were compared in transfection assays with plasmid recombination substrates. Intermolecular recombination frequencies were greater in WIL2-NS than in TK6. These data are consistent with a model suggesting that a recombinational repair system is functioning at a higher level in WIL2-NS than in TK6; the greater mutability of the tk locus in WIL2-NS results from more frequent inter- and intramolecular recombination events.

Mismatch repair of heteroduplex DNA intermediates of extrachromosomal recombination in mammalian cells

Previous work indicated that extrachromosomal recombination in mammalian cells could be explained by the single-strand annealing (SSA) model. This model predicts that extrachromosomal recombination leads to nonconservative crossover products and that heteroduplex DNA (hDNA) is formed by annealing of complementary single strands. Mismatched bases in hDNA may subsequently be repaired to wild-type or mutant sequences, or they may remain unrepaired and segregate following DNA replication. We describe a system to examine the formation and mismatch repair of hDNA in recombination intermediates. Our results are consistent with extrachromosomal recombination occurring via SSA and producing crossover recombinant products. As predicted by the SSA model, hDNA was present in double-strand break-induced recombination intermediates. By placing either silent or frameshift mutations in the predicted hDNA region, we have shown that mismatches are efficiently repaired prior to DNA replication.

Mismatch repair of heteroduplex DNA intermediates of extrachromosomal recombination in mammalian cells

Previous work indicated that extrachromosomal recombination in mammalian cells could be explained by the single-strand annealing (SSA) model. This model predicts that extrachromosomal recombination leads to nonconservative crossover products and that heteroduplex DNA (hDNA) is formed by annealing of complementary single strands. Mismatched bases in hDNA may subsequently be repaired to wild-type or mutant sequences, or they may remain unrepaired and segregate following DNA replication. We describe a system to examine the formation and mismatch repair of hDNA in recombination intermediates. Our results are consistent with extrachromosomal recombination occurring via SSA and producing crossover recombinant products. As predicted by the SSA model, hDNA was present in double-strand break-induced recombination intermediates. By placing either silent or frameshift mutations in the predicted hDNA region, we have shown that mismatches are efficiently repaired prior to DNA replication.

The role and fate of DNA ends for homologous recombination in embryonic stem cells

We have analyzed the gene-targeting frequencies and recombination products generated by a series of vectors which target the hprt locus in embryonic stem cells and found the existence of alternative pathways that depend on the location of the double-strand break within the vector. A double-strand break in the targeting homology was found to increase the targeting frequency compared with a double-strand break at the edge of or outside the target homology; this finding agrees with the double-strand break repair model proposed for Saccharomyces cerevisiae. Although a double-strand break in the homology is important for efficient targeting, observations reported here suggest that the terminal ends are not always directly involved in the initial recombination event. Short terminal heterologous sequences which block the homologous ends of the vector may be incorporated into the target locus. A modification of the double-strand break repair model is described to account for this observation.

Mechanisms of intermolecular homologous recombination in plants as studied with single- and double-stranded DNA molecules

To elucidate the mechanism for intermolecular homologous recombination in plants we cotransformed Nicotiana tabacum cv Petit Havana SR1 protoplasts with constructs carrying different defective derivatives of the NPTII gene. The resulting kanamycin resistant clones were screened for possible recombination products by PCR, which proved to be a valuable technique for this analysis. Our results show that the double-stranded circular DNA molecules used in this study recombine predominantly via a pathway consistent with the single-strand annealing (SSA) model as proposed for extrachromosomal recombination in mammalian cells. In the remaining cases recombination occurred via a single reciprocal recombination, gene conversion and possibly double reciprocal recombination. Since single-stranded DNA is considered to be an important intermediate in homologous recombination we also established the recombination ability of single-stranded DNA in intermolecular recombination. We found that single-stranded DNA enters in recombination processes more efficiently than the corresponding double-stranded DNA. This was also reflected in the recombination mechanisms that generated the functional NPTII gene. Recombination between a single-stranded DNA and the complementing DNA duplex occurred at similar rates via a single reciprocal recombination and the SSA pathway.

The role and fate of DNA ends for homologous recombination in embryonic stem cells

We have analyzed the gene-targeting frequencies and recombination products generated by a series of vectors which target the hprt locus in embryonic stem cells and found the existence of alternative pathways that depend on the location of the double-strand break within the vector. A double-strand break in the targeting homology was found to increase the targeting frequency compared with a double-strand break at the edge of or outside the target homology; this finding agrees with the double-strand break repair model proposed for Saccharomyces cerevisiae. Although a double-strand break in the homology is important for efficient targeting, observations reported here suggest that the terminal ends are not always directly involved in the initial recombination event. Short terminal heterologous sequences which block the homologous ends of the vector may be incorporated into the target locus. A modification of the double-strand break repair model is described to account for this observation.

Two alternative pathways of double-strand break repair that are kinetically separable and independently modulated

HO endonuclease-induced double-strand breaks in Saccharomyces cerevisiae can undergo recombination by two distinct and competing pathways. In a plasmid containing a direct repeat, in which one repeat is interrupted by an HO endonuclease cut site, gap repair yields gene conversions while single-strand annealing produces deletions. Consistent with predictions of the single-strand annealing mechanism, deletion formation is not accompanied by the formation of a reciprocal recombination product. Deletions are delayed 60 min when the distance separating the repeats is increased by 4.4 kb. Moreover, the rate of deletion formation corresponds to the time at which complementary regions become single stranded. Gap repair processes are independent of distance but are reduced in rad52 mutants and in G1-arrested cells.

Two alternative pathways of double-strand break repair that are kinetically separable and independently modulated

HO endonuclease-induced double-strand breaks in Saccharomyces cerevisiae can undergo recombination by two distinct and competing pathways. In a plasmid containing a direct repeat, in which one repeat is interrupted by an HO endonuclease cut site, gap repair yields gene conversions while single-strand annealing produces deletions. Consistent with predictions of the single-strand annealing mechanism, deletion formation is not accompanied by the formation of a reciprocal recombination product. Deletions are delayed 60 min when the distance separating the repeats is increased by 4.4 kb. Moreover, the rate of deletion formation corresponds to the time at which complementary regions become single stranded. Gap repair processes are independent of distance but are reduced in rad52 mutants and in G1-arrested cells.

Extrachromosomal recombination is deranged in the rec2 mutant of Ustilago maydis

Transformation of a leu1 auxotroph of Ustilago maydis to prototrophy with an autonomously replicating plasmid containing the selectable LEU1 gene was found to be efficient regardless of whether the transforming DNA was circular or linear. When pairs of autonomously replicating plasmids bearing noncomplementing leu1 alleles were used to cotransform strains deleted entirely for the genomic copy of the LEU1 gene, Leu+ transformants were observed to arise by extrachromosomal recombination. The frequency of recombination increased severalfold when one plasmid of the pair was made linear by cleavage at one end of the leu1 gene, but increased 10-100-fold when both plasmids were first made linear. The increase in recombination noted in wild-type and rec1 strains was not apparent in the rec2 mutant unless the members of the pair of plasmids were cut at opposite ends of the leu1 gene to yield linear molecules offset in only one of the two possible configurations. Use of a pair of plasmid substrates designed to measure nonreciprocal and multiple exchange events revealed only a minor fraction of the total events arise through these modes, and further that no stimulation occurred when the plasmid DNA was linear. It is unlikely that the defect in rec2 lies in a mismatch correction step since a high yield of Leu+ recombinants was obtained from the rec2 mutant when it was transformed with heteroduplex DNA constructed from plasmids with the two different leu1 alleles.

The mechanism of extrachromosomal homologous DNA recombination in plant cells

By cotransfecting plasmids carrying particular mutations in the beta-glucuronidase (GUS) gene into Nicotiana plumbaginifolia protoplasts and by monitoring the recombination rates using a recently developed transient assay, we were able to obtain insights into the mechanism of extrachromosomal recombination operating in plant cells. An exchange of flanking markers takes place in over 90% of the recombination events. In most of the remaining cases two consecutive, independent single crossover events occur. These events involve the same DNA substrate and lead to two successive exchanges of flanking markers, thus mimicking a presumed double crossover intermediate. A comparison of the outcome of our experiments with the predictions of two recombination models originally proposed for mammalian cells indicates that extrachromosomal recombination in plant cells is best described by the single strand annealing model. According to this model all recombination events result in an exchange of flanking markers. Our results rule out the double strand break repair model which predicts that flanking markers are exchanged in only half of all events.

Double-strand gap repair in a mammalian gene targeting reaction

To better understand the mechanism of homologous recombination in mammalian cells that facilitates gene targeting, we have analyzed the recombination reaction that inserts a plasmid into a homologous chromosomal locus in mouse embryonic stem cells. A partially deleted HPRT gene was targeted with various plasmids capable of correcting the mutation at this locus, and HPRT+ recombinants were directly selected in HAT medium. The structures of the recombinant loci were then determined by genomic Southern blot hybridizations. We demonstrate that plasmid gaps of 200, 600, and 2,500 bp are efficiently repaired during the integrative recombination reaction. Targeting plasmids that carry a double-strand break or gap in the region of DNA homologous to the target locus produce 33- to 140-fold more hypoxanthine-aminopterin-thymidine-resistant recombinants than did these same plasmids introduced in their uncut (supercoiled) forms. Our data suggest that double-strand gaps and breaks may be enlarged prior to the repair reaction since sequence heterologies carried by the incoming plasmids located close to them are often lost. These results extend the known similarities between mammalian and yeast recombination mechanisms and suggest several features of the insertional (O-type) gene targeting reaction that should be considered when one is designing mammalian gene targeting experiments.

Double-strand gap repair in a mammalian gene targeting reaction

To better understand the mechanism of homologous recombination in mammalian cells that facilitates gene targeting, we have analyzed the recombination reaction that inserts a plasmid into a homologous chromosomal locus in mouse embryonic stem cells. A partially deleted HPRT gene was targeted with various plasmids capable of correcting the mutation at this locus, and HPRT+ recombinants were directly selected in HAT medium. The structures of the recombinant loci were then determined by genomic Southern blot hybridizations. We demonstrate that plasmid gaps of 200, 600, and 2,500 bp are efficiently repaired during the integrative recombination reaction. Targeting plasmids that carry a double-strand break or gap in the region of DNA homologous to the target locus produce 33- to 140-fold more hypoxanthine-aminopterin-thymidine-resistant recombinants than did these same plasmids introduced in their uncut (supercoiled) forms. Our data suggest that double-strand gaps and breaks may be enlarged prior to the repair reaction since sequence heterologies carried by the incoming plasmids located close to them are often lost. These results extend the known similarities between mammalian and yeast recombination mechanisms and suggest several features of the insertional (O-type) gene targeting reaction that should be considered when one is designing mammalian gene targeting experiments.

Reciprocal homologous junctions generated in mouse cells

We analysed pairs of reciprocal homologous junctions resulting from intermolecular conservative homologous recombination in mouse cells. The assay used did not rely on the reconstitution of a selectable gene. This permitted the introduction of multiple markers in the parental homologous sequences which in turn enabled us to compare the contribution of each parent to the reciprocal products of a given recombination event. In all recombinants analysed we found, when comparing the reciprocal junctions, a middle segment originating from only one parent. This segment of uniparental origin occurred randomly throughout the region of homology and could extend over a thousand base pairs. These results are consistent with a gap repair process like the one proposed for homologous recombination in yeast. However, introducing a double-strand break in the region of homology did not enhance but rather decreased the proportion of recombinants with reciprocal homologous junctions relative to other types of recombinants.

Repair of deletions and double-strand gaps by homologous recombination in a mammalian in vitro system

We have designed an in vitro system using mammalian nuclear extracts, or fractions derived from them, that can restore the sequences missing at double-strand breaks (gaps) or in deletions. The recombination substrates consist of (i) recipient DNA, pSV2neo with gaps or deletions ranging from 70 to 390 bp in the neo sequence, and (ii) donor DNAs with either complete homology to the recipient (pSV2neo) or plasmids whose homology with pSV2neo is limited to a 1.0- to 1.3-kbp neo segment spanning the gaps or deletions. Incubation of these substrates with various enzyme fractions results in repair of the recipient DNA's disrupted neo gene. The recombinational repair was monitored by transforming recA Escherichia coli to kanamycin resistance and by a new assay which measures the extent of DNA strand transfer from the donor substrate to the recipient DNA. Thus, either streptavidin- or antidigoxigenin-tagged beads are used to separate the biotinylated or digoxigeninylated recipient DNA, respectively, after incubation with the isotopically labeled donor DNA. In contrast to the transfection assay, the DNA strand transfer measurements are direct, quantitative, rapid, and easy, and they provide starting material for the characterization of the recombination products and intermediates. Accordingly, DNA bound to beads serves as a suitable template for the polymerase chain reaction. With appropriate pairs of oligonucleotide primers, we have confirmed that both gaps and deletions are fully repaired, that deletions can be transferred from the recipient DNA to the donor's intact neo sequence, and that cointegrant molecules containing donor and recipient DNA sequences are formed.

Strands hybridize in postreplicative adenovirus overlap recombination

We describe a postreplicative mechanism for adenovirus overlap recombination. An adenovirus minichromosome system was used to study overlap recombination driven by adenovirus DNA replication. Crossing-over appeared to occur equally at, but not within, the borders of the overlap between partner molecules. We propose that recombination in the minichromosome system proceeds through an intermediate formed by direct hybridization of complementary sequences on displaced strands generated by adenovirus-specific DNA replication. Some, but not all, heterologous regions in the intermediate are susceptible to mismatch correction. This pathway is intrinsically nonreciprocal and differs significantly from other adenovirus recombinational mechanisms that have been described previously.

Repair of deletions and double-strand gaps by homologous recombination in a mammalian in vitro system

We have designed an in vitro system using mammalian nuclear extracts, or fractions derived from them, that can restore the sequences missing at double-strand breaks (gaps) or in deletions. The recombination substrates consist of (i) recipient DNA, pSV2neo with gaps or deletions ranging from 70 to 390 bp in the neo sequence, and (ii) donor DNAs with either complete homology to the recipient (pSV2neo) or plasmids whose homology with pSV2neo is limited to a 1.0- to 1.3-kbp neo segment spanning the gaps or deletions. Incubation of these substrates with various enzyme fractions results in repair of the recipient DNA's disrupted neo gene. The recombinational repair was monitored by transforming recA Escherichia coli to kanamycin resistance and by a new assay which measures the extent of DNA strand transfer from the donor substrate to the recipient DNA. Thus, either streptavidin- or antidigoxigenin-tagged beads are used to separate the biotinylated or digoxigeninylated recipient DNA, respectively, after incubation with the isotopically labeled donor DNA. In contrast to the transfection assay, the DNA strand transfer measurements are direct, quantitative, rapid, and easy, and they provide starting material for the characterization of the recombination products and intermediates. Accordingly, DNA bound to beads serves as a suitable template for the polymerase chain reaction. With appropriate pairs of oligonucleotide primers, we have confirmed that both gaps and deletions are fully repaired, that deletions can be transferred from the recipient DNA to the donor's intact neo sequence, and that cointegrant molecules containing donor and recipient DNA sequences are formed.

Transcription stimulates homologous recombination in mammalian cells

Transcription stimulates homologous recombination in Saccharomyces cerevisiae and has been implicated in the control of recombinational events during the development of mammalian immune systems. Here, we describe a plasmid-based system in which an inducible promoter from the mouse mammary tumor virus is located upstream of heteroallelic neomycin genes carried on two plasmids. Pairs of plasmids are introduced into Chinese hamster ovary cells by electroporation, and recombination is monitored by scoring colonies resistant to the aminoglycoside G418. When transcription is induced with dexamethasone, a synthetic glucocorticoid hormone, and double-strand breaks are introduced at mutation sites, recombination is stimulated sixfold over noninduced levels. Inducing transcription in circular substrates or in substrates cleaved at sites distant from the mutations has no detectable effect on recombination between neomycin genes. Results are presented that are consistent with the observed stimulation of recombination occurring before plasmids integrate into the cellular DNA. Our results are discussed in relation to molecular models for extrachromosomal recombination in mammalian cells.

Induced rates of mitotic crossing over and possible mitotic gene conversion per wing anlage cell in Drosophila melanogaster by X rays and fission neutrons

As a model for chromosome aberrations, radiation-induced mitotic recombination of mwh and flr genes in Drosophila melanogaster strain (mwh +/+ flr) was quantitatively studied. Fission neutrons were five to six times more effective than X rays per unit dose in producing either crossover-mwh/flr twins and mwh singles-or flr singles, indicating that common processes are involved in the production of crossover and flr singles. The X-ray-induced rate/wing anlage cell/Gy for flr singles was 1 X 10(-5), whereas that of crossover was 2 x 10(-4); the former and the latter rate are of the same order of magnitude as those of gene conversion and crossover in yeast, respectively. Thus, we conclude that proximal-marker "flr" singles induced in the transheterozygote are gene convertants. Using the model based on yeast that recombination events result from repair of double-strand breaks or gaps, we propose that mitotic recombination in the fly is a secondary result of recombinational DNA repair. Evidence for recombinational misrepair in the fly is given. The relative ratio of radiation-induced mitotic crossover to spontaneous meiotic crossover is one order of magnitude higher in the fly than in yeast and humans.

Transcription stimulates homologous recombination in mammalian cells

Transcription stimulates homologous recombination in Saccharomyces cerevisiae and has been implicated in the control of recombinational events during the development of mammalian immune systems. Here, we describe a plasmid-based system in which an inducible promoter from the mouse mammary tumor virus is located upstream of heteroallelic neomycin genes carried on two plasmids. Pairs of plasmids are introduced into Chinese hamster ovary cells by electroporation, and recombination is monitored by scoring colonies resistant to the aminoglycoside G418. When transcription is induced with dexamethasone, a synthetic glucocorticoid hormone, and double-strand breaks are introduced at mutation sites, recombination is stimulated sixfold over noninduced levels. Inducing transcription in circular substrates or in substrates cleaved at sites distant from the mutations has no detectable effect on recombination between neomycin genes. Results are presented that are consistent with the observed stimulation of recombination occurring before plasmids integrate into the cellular DNA. Our results are discussed in relation to molecular models for extrachromosomal recombination in mammalian cells.

Targeted gene modification for gene therapy of stem cells

Ideally, gene therapy would correct the specific gene defect without adding potentially harmful extraneous DNA sequences. Such correction can be obtained with homologous recombination between input DNA sequences and identical (homologous) sequences in the genomic target gene. The development of techniques for obtaining virtually pure populations of hematopoietic stem cells should permit the use of the highly efficient nuclear microinjection methods for transfer of DNA. These techniques combined with new highly sensitive methods for detecting cells with the specified genetic modification of nonexpressed genes would make homologous recombination-mediated gene therapy feasible for hematopoietic stem cells. These advances are reviewed with particular emphasis on approaches to targeted gene modification of hematopoietic stem cells and speculation on directions for future research.

Repair of double-stranded DNA breaks by homologous DNA fragments during transfer of DNA into mouse L cells

To test the validity of various models for recombination between extrachromosomal DNAs in mammalian cells, we measured recombination between a plasmid containing a herpesvirus thymidine kinase (tk) gene with an internal BamHI linker insertion mutation (ptkB8) and a tk gene deleted at both ends (tk delta 3' delta 5'). The two DNAs shared 885 base pairs of perfect tk homology except for the interruption at the linker insertion site. Recombination events that restored the mutated insertion site to wild type were monitored by the generation of hypoxanthine-aminopterine-thymidine-resistant colonies after cotransformation of Ltk- cells with the two DNAs. We found that cleavage of the ptkB8 DNA at the linker insertion site was essential for gene restoration. If the tk delta 3' delta 5' DNA was ligated into mp10 vector DNA, then recombination with the cleaved ptkB8 DNA was inefficient. In contrast, if it was excised from that vector by cleavage at flanking restriction sites, then recombination was stimulated about 150-fold. Using restriction site polymorphisms, we showed that most of the recombination events leading to restoration of the tk gene with the excised tk delta 3' delta 5' fragment involved three double-strand duplexes: two ptkB8 DNAs and one tk delta 3' delta 5' fragment. These results are much more readily explained by the single-strand annealing model of recombination than by the double-strand break repair model, and they suggest that the deficiency of the latter pathway for extrachromosomal mammalian recombination may be due, at least in part, to the obligate tripartite nature of the reaction. Finally, we measured the effect of DNA homology on the efficiency of the ptkB8-tk delta 3' delta 5' reaction. Our results showed a near-linear relationship between the efficiency of recombination and the amount of homology flanking either side of the linker insertion site. Moreover, we could detect thymidine kinase-positive transformants with as little as 10 base pairs of homology.

Intermolecular recombination between DNAs introduced into mouse L cells is mediated by a nonconservative pathway that leads to crossover products

We describe experiments designed to measure the efficiency of intermolecular recombination between mutant herpesvirus thymidine kinase (tk) genes introduced into mouse L cells. Recombinants were scored as stable transformants containing a functional tk gene. The two recombination substrates used were ptkB8, a pBR322-based plasmid containing a mutant tk gene, with a BamHI linker in an SphI restriction site that is centrally located within the gene, and mp10tk delta 3' delta 5', an mp10 vector with a tk gene deleted at both the 3' and 5' ends. The only homology shared by the two DNAs is 885 base pairs within the tk gene. To determine whether the double-strand break repair model that has been used to explain recombination in yeast cells (J. W. Szostak, T. L. Orr-Weaver, R. J. Rothstein, and F. W. Stahl, Cell 33:25-35, 1983) can account for recombination during the introduction of these DNAs into mammalian cells, we transformed cells with BamHI-linearized ptkB8 and supercoiled mp10tk delta 3' delta 5' replicative-form DNA. These two DNAs should recombine efficiently according to that model and should generate gene conversion products. In this reaction, the supercoiled DNA acts as the donor of information to repair the cleaved tk gene. Our results indicated that the efficiency of this reaction was very low (less than 10 transformants were obtained per 0.1 microgram of each DNA used in the reaction per 10(6) cells). In contrast, if BamHI-cleaved ptkB8 DNA was cotransformed into cells along with a circular DNA molecule containing a tk gene deleted only at its 3' end or only at its 5' end (mp10tk delta 3' or mp10tk delta 5'), then the efficiency of recombination could be more than 4 orders of magnitude higher than it was with circular mp10tk delta 3' delta 5' DNA. Recombination frequencies were highest when the tk delta 3' or tk delta 5' DNA used was cleaved at the tk deletion junction. Southern analyses of DNA from TK+ transformants generated with BamHI-cleaved ptkB8 and BamHI-cleaved mp10tk delta 3' DNAs indicated that recombination was almost always associated with the reassortment of markers flanking the reconstructed tk DNA. Together, these results are more consistent with the nonconservative single-strand annealing model for recombination that we proposed several years ago (F.-L. Lin, K. Sperle, and N. Sternberg, Mol. Cell. Biol. 4:1020-1034, 1984) than they are with the double-strand break repair model.

Recombination between irradiated shuttle vector DNA and chromosomal DNA in African green monkey kidney cells

An autonomously replicating shuttle vector was used to investigate enhancement of plasmid-chromosome recombination in mammalian host cells by gamma irradiation and UV light. Sequences homologous to the shuttle vector were stably inserted into the genome of African green monkey kidney cells to act as the target substrate for these recombination events. The shuttle vector molecules were irradiated at various doses before transfection into the mammalian host cells that contained the stable insertions. The homologous transfer of the bacterial ampicillin resistance gene from the inserted sequences to replace a mutant ampicillin sensitivity gene on the shuttle vector was identified by the recovery of ampicillin-resistant plasmids after Hirt extraction and transformation into Escherichia coli host cells. Gamma irradiation increased homologous shuttle vector-chromosome recombination, whereas UV light did not increase the frequency of recombinant plasmids detected. Introducing specific double-strand breaks in the plasmid or prolonging the time of plasmid residence in the mammalian host cells also enhanced plasmid-chromosome recombination. In contrast, plasmid mutagenesis was increased by UV irradiation of the plasmid but did not change with time. The ampicillin-resistant recombinant plasmid molecules analyzed appeared to rise mostly from nonconservative exchanges that involved both homologous and possibly nonhomologous interactions with the host chromosome. The observation that similar recombinant structures were obtained from all the plasmid treatments and host cells used suggests a common mechanism for plasmid-chromosome recombination in these mammalian cells.

Recombination between irradiated shuttle vector DNA and chromosomal DNA in African green monkey kidney cells

An autonomously replicating shuttle vector was used to investigate enhancement of plasmid-chromosome recombination in mammalian host cells by gamma irradiation and UV light. Sequences homologous to the shuttle vector were stably inserted into the genome of African green monkey kidney cells to act as the target substrate for these recombination events. The shuttle vector molecules were irradiated at various doses before transfection into the mammalian host cells that contained the stable insertions. The homologous transfer of the bacterial ampicillin resistance gene from the inserted sequences to replace a mutant ampicillin sensitivity gene on the shuttle vector was identified by the recovery of ampicillin-resistant plasmids after Hirt extraction and transformation into Escherichia coli host cells. Gamma irradiation increased homologous shuttle vector-chromosome recombination, whereas UV light did not increase the frequency of recombinant plasmids detected. Introducing specific double-strand breaks in the plasmid or prolonging the time of plasmid residence in the mammalian host cells also enhanced plasmid-chromosome recombination. In contrast, plasmid mutagenesis was increased by UV irradiation of the plasmid but did not change with time. The ampicillin-resistant recombinant plasmid molecules analyzed appeared to rise mostly from nonconservative exchanges that involved both homologous and possibly nonhomologous interactions with the host chromosome. The observation that similar recombinant structures were obtained from all the plasmid treatments and host cells used suggests a common mechanism for plasmid-chromosome recombination in these mammalian cells.

Repair of double-stranded DNA breaks by homologous DNA fragments during transfer of DNA into mouse L cells

To test the validity of various models for recombination between extrachromosomal DNAs in mammalian cells, we measured recombination between a plasmid containing a herpesvirus thymidine kinase (tk) gene with an internal BamHI linker insertion mutation (ptkB8) and a tk gene deleted at both ends (tk delta 3' delta 5'). The two DNAs shared 885 base pairs of perfect tk homology except for the interruption at the linker insertion site. Recombination events that restored the mutated insertion site to wild type were monitored by the generation of hypoxanthine-aminopterine-thymidine-resistant colonies after cotransformation of Ltk- cells with the two DNAs. We found that cleavage of the ptkB8 DNA at the linker insertion site was essential for gene restoration. If the tk delta 3' delta 5' DNA was ligated into mp10 vector DNA, then recombination with the cleaved ptkB8 DNA was inefficient. In contrast, if it was excised from that vector by cleavage at flanking restriction sites, then recombination was stimulated about 150-fold. Using restriction site polymorphisms, we showed that most of the recombination events leading to restoration of the tk gene with the excised tk delta 3' delta 5' fragment involved three double-strand duplexes: two ptkB8 DNAs and one tk delta 3' delta 5' fragment. These results are much more readily explained by the single-strand annealing model of recombination than by the double-strand break repair model, and they suggest that the deficiency of the latter pathway for extrachromosomal mammalian recombination may be due, at least in part, to the obligate tripartite nature of the reaction. Finally, we measured the effect of DNA homology on the efficiency of the ptkB8-tk delta 3' delta 5' reaction. Our results showed a near-linear relationship between the efficiency of recombination and the amount of homology flanking either side of the linker insertion site. Moreover, we could detect thymidine kinase-positive transformants with as little as 10 base pairs of homology.

Intermolecular recombination between DNAs introduced into mouse L cells is mediated by a nonconservative pathway that leads to crossover products

We describe experiments designed to measure the efficiency of intermolecular recombination between mutant herpesvirus thymidine kinase (tk) genes introduced into mouse L cells. Recombinants were scored as stable transformants containing a functional tk gene. The two recombination substrates used were ptkB8, a pBR322-based plasmid containing a mutant tk gene, with a BamHI linker in an SphI restriction site that is centrally located within the gene, and mp10tk delta 3' delta 5', an mp10 vector with a tk gene deleted at both the 3' and 5' ends. The only homology shared by the two DNAs is 885 base pairs within the tk gene. To determine whether the double-strand break repair model that has been used to explain recombination in yeast cells (J. W. Szostak, T. L. Orr-Weaver, R. J. Rothstein, and F. W. Stahl, Cell 33:25-35, 1983) can account for recombination during the introduction of these DNAs into mammalian cells, we transformed cells with BamHI-linearized ptkB8 and supercoiled mp10tk delta 3' delta 5' replicative-form DNA. These two DNAs should recombine efficiently according to that model and should generate gene conversion products. In this reaction, the supercoiled DNA acts as the donor of information to repair the cleaved tk gene. Our results indicated that the efficiency of this reaction was very low (less than 10 transformants were obtained per 0.1 microgram of each DNA used in the reaction per 10(6) cells). In contrast, if BamHI-cleaved ptkB8 DNA was cotransformed into cells along with a circular DNA molecule containing a tk gene deleted only at its 3' end or only at its 5' end (mp10tk delta 3' or mp10tk delta 5'), then the efficiency of recombination could be more than 4 orders of magnitude higher than it was with circular mp10tk delta 3' delta 5' DNA. Recombination frequencies were highest when the tk delta 3' or tk delta 5' DNA used was cleaved at the tk deletion junction. Southern analyses of DNA from TK+ transformants generated with BamHI-cleaved ptkB8 and BamHI-cleaved mp10tk delta 3' DNAs indicated that recombination was almost always associated with the reassortment of markers flanking the reconstructed tk DNA. Together, these results are more consistent with the nonconservative single-strand annealing model for recombination that we proposed several years ago (F.-L. Lin, K. Sperle, and N. Sternberg, Mol. Cell. Biol. 4:1020-1034, 1984) than they are with the double-strand break repair model.

Homologous recombination of SV40 DNA in COS7 cells occurs with high frequency in a gene dose independent fashion

Homologous recombination between microinjected SV40 DNA fragments and endogenous SV40 DNA in COS7 cells was analysed by immunofluorescence staining and DNA blotting. Time course experiments revealed that recombination between the transferred (trans) DNA and the chromosomal DNA occurred about 8 hours after microinjection with high efficiency in a gene dose independent fashion. Deletions of up to 1018 basepairs (bp) within the early or the late SV40 region were efficiently repaired after the transfer of linear but not of circular DNA molecules. A 22 bp homology between the trans DNA and the endogenous DNA was sufficient to initiate recombination but 14 nonhomologous bp at one open end of the SV40 DNA fragments hindered gap repair.

Carcinogens can induce homologous recombination between duplicated chromosomal sequences in mouse L cells

The ability of a series of DNA-damaging agents to induce homologous intrachromosomal recombination between duplicated genes in the chromosome of mouse cells was investigated. The target cells were the thymidine kinase-deficient mouse L-cell strain 333M, which contains a single integrated copy of a plasmid with two herpes simplex virus thymidine kinase (Htk) genes, each containing an 8-base-pair XhoI linker inserted at a unique site. Expression of a functional Htk enzyme requires a productive recombinational event between the two nonfunctional genes. The spontaneous rate of recombination in this strain is 3 per 10(6) cells per generation. The agents tested represent physical carcinogens (UV and ionizing radiation), a simple alkylating agent (N-methyl-N'-nitro-N-nitrosoguanidine), an alkylating cross-linking agent (mitomycin C), and a reactive metabolite of a polycyclic aromatic hydrocarbon ((+/-)-7 beta,8 alpha-dihydroxy-9 alpha,10 alpha-epoxy-7,8,9,10- tetrahydrobenzo[a]pyrene [BPDE] ). The background frequency of tk+ recombinants in the untreated population averaged 18 X 10(-6) +/- 5 X 10(-6). Ionizing radiation had little or no effect on recombination; exposure to mitomycin C, N-methyl-N'-nitro-N-nitrosoguanidine, BPDE, or UV, at doses that lowered the survival to between 90 and 10% of the control, caused a dose-dependent increase in frequency of recombinants, reaching 50 X 10(-6) to 100 X 10(-6). No tk+ cells could be generated with a control cell line that contained only one mutant copy of the Htk gene. Molecular hybridization analysis showed that 85 to 90% of the tk+ recombinants retained the Htk gene duplication, consistent with nonreciprocal transfer of wild-type genetic information, gene conversion. In the rest, only a single copy of the Htk gene remained, reflecting a single reciprocal exchange within a chromatid or a single unequal exchange between sister chromatids. Each recombinant tested contained an XhoI-resistant (wild-type) Htk gene.

Intermolecular homologous recombination between transfected sequences in mammalian cells is primarily nonconservative

Intermolecular recombination in mammalian cells was studied by coinfecting African green monkey cells in culture with two shuttle vector plasmids, each carrying an incomplete but overlapping portion of the gene for neomycin resistance. The region of homology between the two plasmids was about 0.6 kilobases. Recombination between the homology regions could reconstruct the neomycin resistance gene, which was monitored by analysis of progeny plasmids in bacteria. The individual plasmids carried additional markers which, in combination with restriction analysis, allowed the determination of the frequency of formation of the heterodimeric plasmid which would be formed in a conservative recombination reaction between the homologous sequences. Reconstruction of the neomycin resistance gene was readily observed, but only 1 to 2% of the neomycin resistance plasmids had the structure of the conservative heterodimer. Treatment of the plasmids which enhanced the frequency of the neomycin resistance gene reconstruction reaction did not significantly increase the relative frequency of conservative product plasmids. The results support nonconservative models for recombination of these sequences.

Carcinogens can induce homologous recombination between duplicated chromosomal sequences in mouse L cells

The ability of a series of DNA-damaging agents to induce homologous intrachromosomal recombination between duplicated genes in the chromosome of mouse cells was investigated. The target cells were the thymidine kinase-deficient mouse L-cell strain 333M, which contains a single integrated copy of a plasmid with two herpes simplex virus thymidine kinase (Htk) genes, each containing an 8-base-pair XhoI linker inserted at a unique site. Expression of a functional Htk enzyme requires a productive recombinational event between the two nonfunctional genes. The spontaneous rate of recombination in this strain is 3 per 10(6) cells per generation. The agents tested represent physical carcinogens (UV and ionizing radiation), a simple alkylating agent (N-methyl-N'-nitro-N-nitrosoguanidine), an alkylating cross-linking agent (mitomycin C), and a reactive metabolite of a polycyclic aromatic hydrocarbon ((+/-)-7 beta,8 alpha-dihydroxy-9 alpha,10 alpha-epoxy-7,8,9,10- tetrahydrobenzo[a]pyrene [BPDE] ). The background frequency of tk+ recombinants in the untreated population averaged 18 X 10(-6) +/- 5 X 10(-6). Ionizing radiation had little or no effect on recombination; exposure to mitomycin C, N-methyl-N'-nitro-N-nitrosoguanidine, BPDE, or UV, at doses that lowered the survival to between 90 and 10% of the control, caused a dose-dependent increase in frequency of recombinants, reaching 50 X 10(-6) to 100 X 10(-6). No tk+ cells could be generated with a control cell line that contained only one mutant copy of the Htk gene. Molecular hybridization analysis showed that 85 to 90% of the tk+ recombinants retained the Htk gene duplication, consistent with nonreciprocal transfer of wild-type genetic information, gene conversion. In the rest, only a single copy of the Htk gene remained, reflecting a single reciprocal exchange within a chromatid or a single unequal exchange between sister chromatids. Each recombinant tested contained an XhoI-resistant (wild-type) Htk gene.

Intermolecular homologous recombination between transfected sequences in mammalian cells is primarily nonconservative

Intermolecular recombination in mammalian cells was studied by coinfecting African green monkey cells in culture with two shuttle vector plasmids, each carrying an incomplete but overlapping portion of the gene for neomycin resistance. The region of homology between the two plasmids was about 0.6 kilobases. Recombination between the homology regions could reconstruct the neomycin resistance gene, which was monitored by analysis of progeny plasmids in bacteria. The individual plasmids carried additional markers which, in combination with restriction analysis, allowed the determination of the frequency of formation of the heterodimeric plasmid which would be formed in a conservative recombination reaction between the homologous sequences. Reconstruction of the neomycin resistance gene was readily observed, but only 1 to 2% of the neomycin resistance plasmids had the structure of the conservative heterodimer. Treatment of the plasmids which enhanced the frequency of the neomycin resistance gene reconstruction reaction did not significantly increase the relative frequency of conservative product plasmids. The results support nonconservative models for recombination of these sequences.

Promotion of double-strand break repair by human nuclear extracts preferentially involves recombination with intact homologous DNA

Parameters of DNA double strand break (dsb) repair catalysed by human nuclear extract were analysed using, as substrate, the replicative form (RF) of M13 mp8 in which a single double strand break (dsb) was introduced by restriction. After incubation with the extract, the dsb repair was estimated by the ability of the incubated RF to produce plaques following transfection into JM 109 (Rec A-) bacteria. The possibility of recombination with a purified fragment from M13 mp8 RF enhances up to 20 times the plaquing ability of the RF. The repair by recombination occurs under several conditions: i) the break in the RF must be located in the region of homology with the fragment. ii) the fragment has to be intact in the region corresponding to the break in the RF. iii) a minimal length of homology between the region surrounding the dsb in the RF, and the fragment is required. The in vitro reaction is ATP dependent and dNTP's partially dependent. Dephosphorylation of the free ends in the RF decreases the repair by ligation but is without effect on the recombination.

Intramolecular recombination between partially homologous sequences in Escherichia coli and Xenopus laevis oocytes

We describe a system to analyze the individual contribution of a single physical DNA end on intramolecular recombination between partially homologous sequences. We took advantage of this partial sequence divergence to measure the distance separating the DNA end from the final recombination event. We show that a single physical DNA end stimulates recombination when located in a region of homology. Recombination frequency decreases gradually with the distance from the DNA end. A recombinational hot spot is found at the end of the region of homology. A large insertion of unrelated DNA interferes asymmetrically with this process, suggesting that a recombinogenic signal propagates along the region of homology.

Recombination of selectable marker DNA in Nicotiana tabacum

A chimeric neomycin phosphotransferase II (NPT II) gene, which normally provides kanamycin resistance to transformed plant cells, was inactivated by in vitro deletions. Repair plasmids not containing plant-specific transcription signals but containing only the NPT II coding region (or parts of it) were used in co-transformation experiments involving direct DNA uptake into protoplasts isolated from Nicotiana tabacum. Recombination, or gene conversion mediated by homologous sequences produced active NPT II genes in about 1% of transformants, rendering these cells resistant to kanamycin. Analysis of the size of the active enzyme indicated that recombination had occurred producing an NPT II gene indistinguishable from the wild-type gene. Southern blot analysis revealed that the bulk of co-transformed donor plasmid DNA had suffered structural modifications; however, kanamycin resistance was inherited in a Mendelian fashion, indicating that at least one functional and structurally intact copy of the regenerated NPT II gene is integrated into the host genome.

Correction of deletions in mammalian cells by gene conversion

We have constructed substrates to study the conversion of deletions in mammalian cells both extrachromosomally and after the stable integration of the substrates into the chromosome. These substrates were designed to study gene conversion without the complication of reciprocal recombination events. The substrates contain insertion or deletion mutations of the neomycin resistance gene (neo) and an internal, homologous fragment of the neo gene (neo-526), such that gene conversion from neo-526 to the mutated neo gene restores a functional neo gene. We have shown that extrachromosomally insertions of 10 bp or deletions of 22 or 167 bp are converted to wild-type at similar frequencies (1-6 X 10(-4)). Chromosomal gene conversion occurred at frequencies of about 10(-6)-10(-7) per cell generation. As expected from the experimental design, all recombination events analyzed in mammalian cells using these substrates appear to be due to gene conversion.