Target frequency and integration pattern for insertion and replacement vectors in embryonic stem cells.

Gene targeting has been used to direct mutations into specific chromosomal loci in murine embryonic stem (ES) cells. The altered locus can be studied in vivo with chimeras and, if the mutated cells contribute to the germ line, in their offspring. Although homologous recombination is the basis for the widely used gene targeting techniques, to date, the mechanism of homologous recombination between a vector and the chromosomal target in mammalian cells is essentially unknown. Here we look at the nature of gene targeting in ES cells by comparing an insertion vector with replacement vectors that target hprt. We found that the insertion vector targeted up to ninefold more frequently than a replacement vector with the same length of homologous sequence. We also observed that the majority of clones targeted with replacement vectors did not recombine as predicted. Analysis of the recombinant structures showed that the external heterologous sequences were often incorporated into the target locus. This observation can be explained by either single reciprocal recombination (vector insertion) of a recircularized vector or double reciprocal recombination/gene conversion (gene replacement) of a vector concatemer. Thus, single reciprocal recombination of an insertion vector occurs 92-fold more frequently than double reciprocal recombination of a replacement vector with crossover junctions on both the long and short arms.     

High-frequency gene conversion between repeated C mu sequences integrated at the chromosomal immunoglobulin mu locus in mouse hybridoma cells.

The occurrence of mitotic recombination between repeated immunoglobulin mu gene constant (C mu) region sequences stably integrated at the haploid chromosomal immunoglobulin mu locus in murine hybridoma cells was investigated. Recombination events are detected as changes in hapten-specific immunoglobulin M production. Recombination occurs with high frequency (0.5 to 0.8%) by a mechanism consistent with gene conversion. A double-strand break repair-like mechanism is suggested by the finding that repair of a 2-bp deletion mutation and a 2-bp insertion mutation occurs with parity in a donor-directed manner. The results also suggest that the gene conversion process is directional in that the 5' C mu region sequence is preferentially converted.     

Extrachromosomal and chromosomal gene conversion in mammalian cells.

We constructed substrates to study gene conversion in mammalian cells specifically without the complication of reciprocal recombination events. These substrates contain both an insertion mutation of the neomycin resistance gene (neoX) and an internal, homologous fragment of the neo gene (neo-526), such that gene conversion from neo-526 to neoX restores a functional neo gene. Although two reciprocal recombination events can also produce an intact neo gene, these double recombination events occur much less frequently that gene conversion in mammalian cells, We used our substrates to characterize extrachromosomal gene conversion in recombination-deficient bacteria and in monkey COS cells. Chromosomal recombination was also studied after stable integration of these substrates into the genome of mouse 3T6 cells. All extrachromosomal and chromosomal recombination events analyzed in mammalian cells resulted from gene conversion. Chromosomal gene conversion events occurred at frequencies of about 10(-6) per cell generation and restored a functional neo gene without overall effects on sequence organization.     

An efficient method of selectable marker gene excision by Xer recombination for gene replacement in bacterial chromosomes

A simple, effective method of unlabeled, stable gene insertion into bacterial chromosomes has been developed. This utilizes an insertion cassette consisting of an antibiotic resistance gene flanked by dif sites and regions homologous to the chromosomal target locus. dif is the recognition sequence for the native Xer site-specific recombinases responsible for chromosome and plasmid dimer resolution: XerC/XerD in Escherichia coli and RipX/CodV in Bacillus subtilis. Following integration of the insertion cassette into the chromosomal target locus by homologous recombination, these recombinases act to resolve the two directly repeated dif sites to a single site, thus excising the antibiotic resistance gene. Previous approaches have required the inclusion of exogenous site-specific recombinases or transposases in trans; our strategy demonstrates that this is unnecessary, since an effective recombination system is already present in bacteria. The high recombination frequency makes the inclusion of a counter-selectable marker gene unnecessary.     

1,5-isoquinolinediol increases the frequency of gene targeting by homologous recombination in mouse fibroblasts.

Gene targeting is a technique that allows the introduction of predefined alterations into chromosomal DNA. It involves a homologous recombination reaction between the targeted genomic sequence and an exogenous targeting vector. In theory, gene targeting constitutes the ideal method of gene therapy for single gene disorders. In practice, gene targeting remains extremely inefficient for at least two reasons: very low frequency of homologous recombination in mammalian cells and high proficiency of the mammalian cells to randomly integrate the targeting vector by illegitimate recombination. One known method to improve the efficiency of gene targeting is inhibition of poly(ADP-ribose)polymerase (PARP). It has been shown that PARP inhibitors, such as 3-methoxybenzamide, could lower illegitimate recombination, thus increasing the ratio of gene targeting to random integration. However, the above inhibitors were reported to decrease the absolute frequency of gene targeting. Here we show that treatment of mouse Ltk cells with 1,5-isoquinolinediol, a recent generation PARP inhibitor, leads to an increase up to 8-fold in the absolute frequency of gene targeting in the correction of the mutation at the stable integrated HSV tk gene.     

The bacteriophage T4 insertion/substitution vector system. A method for introducing site-specific mutations into the virus chromosome

A bacteriophage T4 insertion/substitution vector system has been developed as a means of introducing in vitro generated mutations into the T4 chromosome. The insertion/substitution vector is a 2638-base pair plasmid containing the pBR322 origin of replication and ampicillin resistance determinant, a T4 gene 23 promoter/synthetic supF tRNA gene fusion, and a polylinker with eight unique restriction enzyme recognition sites. A T4 chromosomal "target" DNA sequence is cloned into this vector and mutated by standard recombinant DNA techniques. Escherichia coli cells containing this plasmid are then infected with T4 bacteriophage that carry amber mutations in two essential genes. The plasmid integrates into the T4 chromosome by recombination between the plasmid-borne T4 target sequence and its homologous chromosomal counterpart. The resulting phage, termed "integrants," are selectable by the supF-mediated suppression of their two amber mutations. Thus, although the integrants comprise 1-3% or less of the total phage progeny, growth on a nonsuppressing host permits their direct selection. The pure integrant phage can be either analyzed directly for a possible mutant phenotype or transferred to nonselective growth conditions. In the latter case, plasmid-free phage segregants rapidly accumulate due to homologous recombination between the duplicated target sequences surrounding the supF sequence in each integrant chromosome. A major fraction of these segregants will retain the in vitro generated mutation within their otherwise unchanged chromosomes and are isolated as stable mutant bacteriophage. The insertion/substitution vector system thereby allows any in vitro mutated gene to be readily substituted for its wild-type counterpart in the bacteriophage T4 genome.     

Correction of a deletion mutant by gene targeting with an adenovirus vector.

The usefulness of adenovirus type 5 as a vector for homologous recombination was examined in CHO cells by using the adenine phosphoribosyltransferase (aprt) gene. Infection of a hemizygous CHO APRT- cell line containing a 3-bp deletion in exon 5 of the aprt gene with a recombinant adenovirus containing the wild-type gene resulted in restoration of the APRT+ phenotype at a frequency of 10(-5) to 10(-6) per infected cell. A relatively high frequency (approximately 6 to 20%) of the transductants appears to result from a homologous recombination event. The mutation on the chromosomal aprt gene is corrected in the homologous recombinants, and APRT expression is restored to a normal hemizygous level. Neither adenovirus nor exogenous promoter sequences are detected in the homologous recombinants. The remaining transductants result from random integration of the aprt gene with the adenovirus sequence. A number of adenovirus vectors containing different promoter sequences linked to the hamster aprt gene were constructed. A possible role for the promoter region in the homologous recombination event was indicated by the lack of homologous recombination in constructs lacking an active promoter.     

High-frequency homologous recombination between duplicate chromosomal immunoglobulin mu heavy-chain constant regions.

Homologous recombination was used in a previous study to correct a 2-base-pair deletion in the third constant domain (Cmu3) of the haploid chromosomal mu gene in a mutant hybridoma cell line by transfer of a pSV2neo vector bearing a subfragment of the normal Cmu region (M.D. Baker, N. Pennell, L. Bosnoyan, and M.J. Shulman, Proc. Natl. Acad. Sci. USA 85:6432-6436, 1988). In these experiments, both gene replacement and single reciprocal crossover events were found to restore normal, cytolytic 2,4,6-trinitrophenyl-specific immunoglobulin M production to the mutant cells. In the cases of single reciprocal recombination, the structure of the recombinant mu gene is such that the normal Cmu region, in its correct position 3' of the expressed 2,4,6-trinitrophenyl-specific heavy-chain variable region, is separated from the mutant Cmu region by the integrated vector sequences. I report here that homologous recombination occurs with high frequency between the duplicate Cmu regions in mitotically growing hybridoma cells. The homologous recombination events were easily detected since they generated hybridomas that were phenotypically different from the parental cells. Analysis of the recombinant cells suggests that gene conversion is the most frequent event, occurring between 60 and 73% of the time. The remaining events consisted of single reciprocal crossovers. Intrachromatid double reciprocal recombination was not detected. The high frequency of recombination, the ability to isolate and analyze the participants in the recombination reactions, and the capacity to generate specific modifications in the immunoglobulin Cmu regions by gene targeting suggest that this system will be useful for studying mammalian chromosomal homologous recombination. Moreover, the ability to specifically modify the chromosomal immunoglobulin genes by homologous recombination should facilitate studies of immunoglobulin gene regulation and expression and provide a more convenient of engineering specifically modified antibody.     

End extension repair of introduced targeting vectors mediated by homologous recombination in mammalian cells.

We have studied the mechanism of targeted recombination in mammalian cells using a hemizygous adenine phosphoribosyltransferase-deficient (APRT-) Chinese hamster ovary (CHO) cell mutant as a recipient. Three structurally different targeting vectors with a 5' or a 3', or both, end-deleted aprt sequence, in either a closed-circular or linear form, were transfected to the cells with a mutated aprt gene by electroporation. APRT-positive (APRT+) recombinant clones were selected and analyzed to study the gene correction events of the deletion mutation. Some half of 58 recombinant clones obtained resulted from corrections of the deleted chromosomal aprt gene by either gene replacement or gene insertion, a mechanism which is currently accepted for homologous recombination in mammalian cells. However, the chromosomal sequence in the remaining half of the recombinants remained uncorrected but their truncated end of the aprt gene in the incoming vectors was corrected by extending the end beyond the region of homology to the target locus; the corrected vector was then randomly integrated into the genome. This extension, termed end extension repair, was observed with all three vectors used and was as far as 4.6-kilobase (kb) or more long. It is evident that the novel repair reaction mediated by homologous recombination, in addition to gene replacement and gene insertion, is also involved in gene correction events in mammalian cells. We discuss the model which may account for this phenomenon.     

Effects of varying gene targeting parameters on processing of recombination intermediates by ERCC1-XPF

The ERCC1-XPF structure-specific endonuclease is necessary for correct processing of homologous recombination intermediates requiring the removal of end-blocking nonhomologies. We previously showed that targeting the endogenous CHO APRT locus with plasmids designed to generate such intermediates revealed defective recombination phenotypes in ERCC1 deficient cells, including suppression of targeted insertion and vector correction recombinants and the generation of a novel class of aberrant recombinants through a deletogenic mechanism. In the present study, we examined some of the mechanistic features of ERCC1-XPF in processing recombination intermediates by varying gene targeting parameters. These included altering the distance between the double-strand break (DSB) in the targeting vector and the inactivating mutation in the APRT target gene, and changing the position of the target gene mutation relative to the DSB to result in target mutations that were either upstream or downstream from the DSB. Increasing the distance from the DSB in the targeting vector to the chromosomal target gene mutation resulted in an ERCC1 dependent decrease in the efficiency of gene targeting from intermediates presenting lengthy end-blocking nonhomologies. This decrease was accompanied by a shift in the distribution of recombinant classes away from target gene conversions to targeted insertions in both wild-type and ERCC1 deficient cells, and a dramatic increase in the proportion of aberrant recombinants in ERCC1 deficient cells. Changing the position of the target gene mutation relative to the DSB in the plasmid also altered the distribution of targeted insertion subclasses recovered in wild-type cells, consistent with two-ended strand invasion followed by resolution into crossover-type products and vector integration. Our results confirm expectations from studies of Rad10-Rad1 in budding yeast that ERCC1-XPF activity affects conversion tract length, and provide evidence for the mechanism of generation of the novel, aberrant recombinant class first described in our previous study.     

Analysis of IS1236-mediated gene amplification events in Acinetobacter baylyi ADP1

Recombination between insertion sequence copies can cause genetic deletion, inversion, or duplication. However, it is difficult to assess the fraction of all genomic rearrangements that involve insertion sequences. In previous gene duplication and amplification studies of Acinetobacter baylyi ADP1, an insertion sequence was evident in approximately 2% of the characterized duplication sites. Gene amplification occurs frequently in all organisms and has a significant impact on evolution, adaptation, drug resistance, cancer, and various disorders. To understand the molecular details of this important process, a previously developed system was used to analyze gene amplification in selected mutants. The current study focused on amplification events in two chromosomal regions that are near one of six copies of the only transposable element in ADP1, IS1236 (an IS3 family member). Twenty-one independent mutants were analyzed, and in contrast to previous studies of a different chromosomal region, IS1236 was involved in 86% of these events. IS1236-mediated amplification could occur through homologous recombination between insertion sequences on both sides of a duplicated region. However, this mechanism presupposes that transposition generates an appropriately positioned additional copy of IS1236. To evaluate this possibility, PCR and Southern hybridization were used to determine the chromosomal configurations of amplification mutants involving IS1236. Surprisingly, the genomic patterns were inconsistent with the hypothesis that intramolecular homologous recombination occurred between insertion sequences following an initial transposition event. These results raise a novel possibility that the gene amplification events near the IS1236 elements arise from illegitimate recombination involving transposase-mediated DNA cleavage.     

An Efficient Method of Selectable Marker Gene Excision by Xer Recombination for Gene Replacement in Bacterial Chromosomes

A simple, effective method of unlabeled, stable gene insertion into bacterial chromosomes has been developed. This utilizes an insertion cassette consisting of an antibiotic resistance gene flanked by dif sites and regions homologous to the chromosomal target locus. dif is the recognition sequence for the native Xer site-specific recombinases responsible for chromosome and plasmid dimer resolution: XerC/XerD in Escherichia coli and RipX/CodV in Bacillus subtilis. Following integration of the insertion cassette into the chromosomal target locus by homologous recombination, these recombinases act to resolve the two directly repeated dif sites to a single site, thus excising the antibiotic resistance gene. Previous approaches have required the inclusion of exogenous site-specific recombinases or transposases in trans; our strategy demonstrates that this is unnecessary, since an effective recombination system is already present in bacteria. The high recombination frequency makes the inclusion of a counter-selectable marker gene unnecessary.     

Estimating the contribution of mutation, recombination and gene conversion in the generation of haplotypic diversity

Recombination occurs through both homologous crossing over and homologous gene conversion during meiosis. The contribution of recombination relative to mutation is expected to be dramatically reduced in inbreeding organisms. We report coalescent-based estimates of the recombination parameter (rho) relative to estimates of the mutation parameter (theta) for 18 genes from the highly self-fertilizing grass, wild barley, Hordeum vulgare ssp. spontaneum. Estimates of rho/theta are much greater than expected, with a mean rho/theta approximately 1.5, similar to estimates from outcrossing species. We also estimate rho with and without the contribution of gene conversion. Genotyping errors can mimic the effect of gene conversion, upwardly biasing estimates of the role of conversion. Thus we report a novel method for identifying genotyping errors in nucleotide sequence data sets. We show that there is evidence for gene conversion in many large nucleotide sequence data sets including our data that have been purged of all detectable sequencing errors and in data sets from Drosophila melanogaster, D. simulans, and Zea mays. In total, 13 of 27 loci show evidence of gene conversion. For these loci, gene conversion is estimated to contribute an average of twice as much as crossing over to total recombination.     

Correlation between umuC induction and Salmonella mutagenicity assay for quinolone antimicrobial agents

Abstract A novel genetic procedure is described to identify stress genes in Bacillus subtilis by insertion mutagenesis. In addition, this method allows the rapid mapping of the mutation and the establishment of the DNA sequence of the gene impaired by the mutation. Small restriction fragments of chromosomal DNA of B. subtilis are inserted into a pBR322-based vector, the recombinant plasmids are transformed into B. subtilis , and integrants are selected which arise by recombination between the insert and its homologous region within the bacterial chromosome. About two dozen heat-, cold- and salt-sensitive mutants were isolated. Four mutations were mapped using PBS1 transduction, and the physiology of one salt-sensitive mutant was analysed.     

Gene conversion associated with site-specific recombination in yeast plasmid pSR1.

A circular DNA plasmid, pSR1, isolated from Zygosaccharomyces rouxii has a pair of inverted repeats consisting of completely homologous 959-base pair (bp) sequences. Intramolecular recombination occurs frequently at the inverted repeats in cells of Saccharomyces cerevisiae, as well as in Z. rouxii, and is catalyzed by a protein encoded by the R gene of its own genome. The recombination is, however, independent of the RAD52 gene of the host genome. A site for initiation of the intramolecular recombination in the S. cerevisiae host was delimited into, at most, a 58-bp region in the inverted repeats by using mutant plasmids created by linker insertion. The 58-bp region contains a pair with 14-bp dyad symmetry separated by a 3-bp spacer sequence. The recombination initiated at this site was accompanied by a high frequency of gene conversion (3 to 50% of the plasmid clones examined). Heterogeneity created by the linker insertion or by a deletion (at most 153 bp so far tested) at any place on the inverted repeats was converted to a homologous combination by the gene conversion, even in the rad52-1 mutant host. A mechanism implying branch migration coupled with DNA replication is discussed.     

Multiple pathways for repair of DNA double-strand breaks in mammalian chromosomes

To study repair of DNA double-strand breaks (DSBs) in mammalian chromosomes, we designed DNA substrates containing a thymidine kinase (TK) gene disrupted by the 18-bp recognition site for yeast endonuclease I-SceI. Some substrates also contained a second defective TK gene sequence to serve as a genetic donor in recombinational repair. A genomic DSB was induced by introducing endonuclease I-SceI into cells containing a stably integrated DNA substrate. DSB repair was monitored by selection for TK-positive segregants. We observed that intrachromosomal DSB repair is accomplished with nearly equal efficiencies in either the presence or absence of a homologous donor sequence. DSB repair is achieved by nonhomologous end-joining or homologous recombination, but rarely by nonconservative single-strand annealing. Repair of a chromosomal DSB by homologous recombination occurs mainly by gene conversion and appears to require a donor sequence greater than a few hundred base pairs in length. Nonhomologous end-joining events typically involve loss of very few nucleotides, and some events are associated with gene amplification at the repaired locus. Additional studies revealed that precise religation of DNA ends with no other concomitant sequence alteration is a viable mode for repair of DSBs in a mammalian genome.     

Epstein–Barr Virus Plasmid Model System for Analyzing Recombination in Human Cells

Homologous recombination stimulated by a double-strand break at a desired target site offers a method to achieve site-specific integration useful for gene therapy and other genetic engineering. To test parameters needed for this strategy, we developed an Epstein-Barr virus shuttle vector model system as a genetic tool. This extrachromosomal plasmid assay system has several advantages over a chromosomal assay. The system detects all classes of recombination events without selection and allows rapid analysis of the frequency and nature of recombination events. We found that a double-strand break at the target site stimulated a large increase in recombination frequency. The resulting recombinants included one-sided insertion events, as well as two-sided or gene conversion events. A circular donor substrate was more effective in recombination than linearized donor DNA.     

Chromosomal Translocations Generated by High-Frequency Meiotic Recombination between Repeated Yeast Genes

We have examined meiotic and mitotic recombination between repeated genes on nonhomologous chromosomes in the yeast Saccharomyces cerevisiae. The results of these experiments can be summarized in three statements. First, gene conversion events between repeats on nonhomologous chromosomes occur frequently in meiosis. The frequency of such conversion events is only 17-fold less than the analogous frequency of conversion between genes at allelic positions on homologous chromosomes. Second, meiotic and mitotic conversion events between repeated genes on nonhomologous chromosomes are associated with reciprocal recombination to the same extent as conversion between allelic sequences. The reciprocal exchanges between the repeated genes result in chromosomal translocations. Finally, recombination between repeated genes on nonhomologous chromosomes occurs much more frequently in meiosis than in mitosis.