Targeted gene replacement at the endogenous APRT locus in CHO cells

Use of gene targeting to study recombination in mammalian cell DNA repair mutants

The study of gene function has been greatly facilitated by the development of strategies to modify genomic DNA. Gene targeting is one of the most successfully applied techniques used to examine the roles of specific genes in a wide variety of model systems from yeast to mammals. Our laboratory has pioneered the use of the Chinese hamster ovary (CHO) cell culture model system to study pathways of DNA repair and recombination at the hemizygous CHO APRT locus. By using a simple and effective gene targeting method, we have generated a number of DNA repair-deficient cell lines that have been used in targeted recombination experiments to investigate pathways of recombinational repair in somatic mammalian cells. These methods can be readily customized to generate a variety of cell lines deficient in specific genes of interest and can be applied to study the roles of other DNA repair proteins in pathways of mammalian recombinational repair.

A caveat in mouse genetic engineering: ectopic gene targeting in ES cells by bidirectional extension of the homology arms of a gene replacement vector carrying human PARP-1

Here we report an approach to generate a knock-in mouse model using an 'ends-out' gene replacement vector to substitute the murine Parp-1 (mParp-1) coding sequence (32 kb) with its human orthologous sequence (46 kb). Unexpectedly, examination of mutant ES cell clones and mice revealed that site-specific homologous recombination was mimicked in three independently generated ES cell clones by bidirectional extension of the vector homology arms using the endogenous mParp-1-flanking sequences as templates. This was followed by adjacent integration of the targeting vector, thus leaving the endogenous mParp-1 locus functional. A related phenomenon termed 'ectopic gene targeting' has so far only been described for 'ends-in' integration-type vectors in non-ES cell gene targeting. We provide reliable techniques to detect such ectopic gene targeting which represents an unexpected caveat in mouse genetic engineering that should be considered in the design and validation strategy of future gene knock-in approaches.

Efficient recruitment of transfected DNA to a homologous chromosomal target in mammalian cells

A Chinese hamster ovary cell line hemizygous for a defective adenine phosphoribosyltransferase (aprt) gene was transfected with a plasmid, pAG100, capable of correcting the endogenous aprt mutation by targeted homologous recombination. In some experiments, pAG100 was transfected in combination with one of two 'competitor' plasmids. Competitor pCOMP-A was identical to pAG100 except that the aprt sequence on pCOMP-A had the same mutation as the endogenous aprt gene. Competitor pCOMP-B was identical to pAG100 except for a 763 bp deletion in the aprt sequence encompassing the site of mutation in the endogenous gene. Neither pCOMP-A nor pCOMP-B was capable of correcting the defect in the endogenous aprt gene via gene targeting. We asked whether cotransfection of a 4-fold excess of either competitor DNA molecule with pAG100 would reduce the efficiency of targeted correction of the endogenous aprt gene. We report that while plasmid pCOMP-B did not influence the efficiency of gene targeting by pAG100, plasmid pCOMP-A reduced the number of gene targeting events about 5-fold. These observations indicate that the initial homologous interaction between transfected DNA and a genomic target sequence occurs rapidly and that targeting efficiency is limited by a step subsequent to homologous pairing.

Enrichment for gene targeting in mammalian cells by inhibition of poly(ADP-ribosylation)

Inhibition of poly(ADP-ribosylation) reduces random genomic integration of transfected DNA and mildly stimulates intrachromosomal homologous recombination in mammalian cells. We investigated the effect of inhibition of poly(ADP-ribosylation) on the efficiency of gene targeting in Chinese hamster ovary (CHO) cell line ATS-49tg. This cell line is hemizygous for a defective adenine phosphoribosyltransferase (aprt) gene and is hypoxanthine phosphoribosyltransferase (hprt) deficient. Plasmid pAG100 contains a portion of the CHO aprt gene sufficient to correct the defect in ATS-49tg cells via gene targeting; pAG100 also contains an Escherichia coli guanine phosphoribosyltransferase (gpt) gene. Following transfection of ATS-49tg cells with pAG100, selection for gpt-positive transfectants allowed recovery of cells that had randomly integrated pAG100 while selection for aprt-positive cells allowed recovery of cells that had undergone gene targeting at the endogenous aprt locus. Treatment of cells with 3 mM 3-methoxybenzamide (3-MB), an inhibitor of poly(ADP-ribose) polymerase, decreased random integration and gene targeting of electroporated pAG100 about 5-fold. In contrast, treatment with 3 mM 3-MB during calcium phosphate transfection could reduce random integration more than 150-fold while reducing gene targeting less than two-fold. Therefore, as much as a 100-fold enrichment for gene targeting was achieved with calcium phosphate transfection.

Efficient modification of the APRT gene by FLP/FRT site-specific targeting

The FLP/FRT site-specific recombination system was established and characterized at the APRT gene in CHO cells. Targeting frequencies with FLP-stimulation were about 1 to 5 X 10(-5), which were 6-22-fold above gene targeting frequencies in the absence of FLP. Fifty two APRT+ cell lines were analyzed by Southern blotting: 56% were FLP-targeted integrants; 33% were APRT target convertants; 11% gave undefined patterns. In separate experiments we first enriched for integrants by screening for two additional markers carried on the targeting vector; 18 of 19 (95%) of the resulting cell lines were integrants. Intrachromosomal site-specific recombination was tested by reexposing integrants to FLP. Intrachromosomal popouts were stimulated over 200-fold, while homologous recombination in an adjacent interval was unchanged. The utility of this system was demonstrated by one-step FLP targeting to generate chromosomal substrates for homologous recombination, and by a two-step, FLP-and-run procedure to construct a chromosomal substrate for illegitimate recombination.

Homology dependence of targeted recombination at the Chinese hamster APRT locus

Using simple linear fragments of the Chinese hamster adenine phosphoribosyltransferase (APRT) gene as targeting vectors, we have investigated the homology dependence of targeted recombination at the endogenous APRT locus in Chinese hamster ovary (CHO) cells. We have examined the effects of varying either the overall length of targeting sequence homology or the length of 5' or 3' flanking homology on both the frequency of targeted homologous recombination and the types of recombination events that are obtained. We find an exponential (logarithmic) relationship between length of APRT targeting homology and the frequency of targeted recombination at the CHO APRT locus, with the frequency of targeted recombination dependent upon both the overall length of targeting homology and the length of homology flanking each side of the target gene deletion. Although most of the APRT+ recombinants analyzed reflect simple targeted replacement or conversion of the target gene deletion, a significant fraction appear to have arisen by target gene-templated extension and correction of the targeting fragment sequences. APRT fragments with limited targeting homology flanking one side of the target gene deletion yield proportionately fewer target gene conversion events and proportionately more templated extension and vector correction events than do fragments with more substantial flanking homology.

Homology dependence of targeted recombination at the Chinese hamster APRT locus

Using simple linear fragments of the Chinese hamster adenine phosphoribosyltransferase (APRT) gene as targeting vectors, we have investigated the homology dependence of targeted recombination at the endogenous APRT locus in Chinese hamster ovary (CHO) cells. We have examined the effects of varying either the overall length of targeting sequence homology or the length of 5' or 3' flanking homology on both the frequency of targeted homologous recombination and the types of recombination events that are obtained. We find an exponential (logarithmic) relationship between length of APRT targeting homology and the frequency of targeted recombination at the CHO APRT locus, with the frequency of targeted recombination dependent upon both the overall length of targeting homology and the length of homology flanking each side of the target gene deletion. Although most of the APRT+ recombinants analyzed reflect simple targeted replacement or conversion of the target gene deletion, a significant fraction appear to have arisen by target gene-templated extension and correction of the targeting fragment sequences. APRT fragments with limited targeting homology flanking one side of the target gene deletion yield proportionately fewer target gene conversion events and proportionately more templated extension and vector correction events than do fragments with more substantial flanking homology.

Effect of vector topology on homologous recombination at the CHO aprt locus

The Chinese hamster ovary aprt gene was used as a model for studying the effect of vector topology on gene targeting frequency. A single recombination vector containing 2.7 kb of isogenic DNA homologous to the aprt gene was digested with eight separate restriction enzymes to generate a variety of both replacement- and insertion-type recombination substrates. The frequency of homologous recombination, normalized by cotransfection with a linearized neo' marker, was assayed by the correction of a mutant hemizygous aprt allele and was not found to reflect vector topology. Southern analysis of representative recombination products suggests that the gene targeting events occurred predominantly by double crossover/gene conversion.

The use of human repetitive DNA to target selectable markers into only the human chromosome of a human-hamster hybrid cell line (AL)

We used the plasmid BLUR-8 that contains an 800-base pair (bp) sequence of human repetitive Alu DNA in a cotransfection protocol to target the plasmids pSV2neo or EBO-pcD-leu-2 (hygro) into a single site of the sole human chromosome, number 11, of a Chinese hamster-human hybrid cell line (AL). The neo and hygro plasmids confer resistance to the antibiotics G418 and hygromycin, respectively. Of the 33 cotransfected clones with single-site insertions, 1/13 without BLUR-8 and 6/20 with BLUR-8 were only in human chromosome 11. A frequency of insertion of 1/13 is not different than expected by chance (rho = 0.3512). On the other hand, the probability that 6/20 insertions, as seen with BLUR-8, occurred by chance is low (rho = 0.0003). We suggest that the human DNA sequences contained in BLUR-8 targeted insertions into only the human chromosome.

X rays induce interallelic homologous recombination at the human thymidine kinase gene

We have developed a human lymphoblast cell line for the study of interchromosomal homologous recombination at the endogenous thymidine kinase (tk) gene on chromosome 17 (M. B. Benjamin, H. Potter, D. W. Yandell, and J. B. Little, Proc. Natl. Acad. Sci. USA 88:6652-6656, 1991). This cell line (designated 6:86) carries unique heterozygous frameshift mutations in exons 4 and 7 of its endogenous tk alleles and can revert to TK+ by frame-restoring mutations, gene conversion, or reciprocal recombination. Line 6:86 reverts spontaneously to TK+ at a frequency of 10(-7) to 10(-8), and exposures to X-irradiation or the frameshift mutagen ICR-191 induce increased reversion frequencies in a dose-dependent manner. Another cell line (designated 4:2) carries a homozygous exon 7 frameshift and is not expected to revert through mechanisms other than frame-restoring mutation. Line 4:2 reverts to TK+ at a lower spontaneous frequency than does 6:86 but can be induced with similar kinetics by ICR-191. In contrast to line 6:86, however, X rays did not induce detectable reversion of line 4:2. We have characterized a number of 6:86-derived revertants by means of restriction fragment length polymorphism analysis at tk and linked loci, single-strand conformation polymorphisms, and direct transcript sequencing. For X rays, most revertants retain both original mutations in the genomic DNA, and a subset of these frameshift-retaining revertants produce frameshift-free message, indicating that reversion is the result of reciprocal recombination within the tk gene. Frame-restoring point mutations, restoration of original sequences, and phenocopy reversion by acquisition of aminopterin resistance were also found among X-ray-induced revertants, whereas the ICR-191-induced revertants examined show only loss of the exon 7 frameshift.

X rays induce interallelic homologous recombination at the human thymidine kinase gene

We have developed a human lymphoblast cell line for the study of interchromosomal homologous recombination at the endogenous thymidine kinase (tk) gene on chromosome 17 (M. B. Benjamin, H. Potter, D. W. Yandell, and J. B. Little, Proc. Natl. Acad. Sci. USA 88:6652-6656, 1991). This cell line (designated 6:86) carries unique heterozygous frameshift mutations in exons 4 and 7 of its endogenous tk alleles and can revert to TK+ by frame-restoring mutations, gene conversion, or reciprocal recombination. Line 6:86 reverts spontaneously to TK+ at a frequency of 10(-7) to 10(-8), and exposures to X-irradiation or the frameshift mutagen ICR-191 induce increased reversion frequencies in a dose-dependent manner. Another cell line (designated 4:2) carries a homozygous exon 7 frameshift and is not expected to revert through mechanisms other than frame-restoring mutation. Line 4:2 reverts to TK+ at a lower spontaneous frequency than does 6:86 but can be induced with similar kinetics by ICR-191. In contrast to line 6:86, however, X rays did not induce detectable reversion of line 4:2. We have characterized a number of 6:86-derived revertants by means of restriction fragment length polymorphism analysis at tk and linked loci, single-strand conformation polymorphisms, and direct transcript sequencing. For X rays, most revertants retain both original mutations in the genomic DNA, and a subset of these frameshift-retaining revertants produce frameshift-free message, indicating that reversion is the result of reciprocal recombination within the tk gene. Frame-restoring point mutations, restoration of original sequences, and phenocopy reversion by acquisition of aminopterin resistance were also found among X-ray-induced revertants, whereas the ICR-191-induced revertants examined show only loss of the exon 7 frameshift.

Gene targeting in Chinese hamster ovary cells is conservative

Two fundamentally different pathways for homologous recombination have been identified in mammalian cells. For most chromosomal recombination events, two copies of a homologous sequence recombine to yield two copies in the products; such events are said to be conservative because the number of copies is preserved. By contrast, virtually all extrachromosomal recombination events are nonconservative; two copies recombine to give a product containing a single intact copy (the other copy is destroyed in the mechanism). Since gene targeting involves an introduced (extrachromosomal) plasmid and a chromosomal target, it was not clear which pathway would apply. We used a marked vector to determine whether targeted integrants were products of recombination events that involved two copies (the conservative pathway) or three copies (the nonconservative pathway) of the homologous sequence. Among 51 gene targeting events, we identified 17 homologous integrants and analyzed their structures. All match the predictions for a conservative pathway. We conclude that the principal pathway for gene targeting in mammalian cells is conservative.

Characterization of Chinese hamster ovary cells stably transformed by a plasmid with an inducible APRT gene

A plasmid was constructed by fusion of a selectable mammalian gene, hamster adenine phosphoribosyltransferase (APRT), to the Zn(2+)-inducible sheep metallothionein I (MT I) promoter. This plasmid was used to produce stable Chinese hamster ovary (CHO) cell transformants by electroporation to study the effects of induced gene expression on DNA-mediated transformation. The sheep MT Ia promoter was chosen for these experiments because it regulates gene expression differently than murine MT promoters, exhibiting low basal levels of gene expression in uninduced conditions. We have shown that in the absence of Zn2+, there is very low expression of a sheep MT I-APRT fusion gene in stable CHO cells transformants; induction of APRT mRNA and enzyme activity by Zn2+ produced a "threshold" response, from low basal levels to high induced levels, in Zn2+ responsive stable transformant clones. In electroporation experiments, transformation frequencies were unaffected by Zn2+ treatments during a preselection period, but the presence of Zn2+ during selection increased the recovery of stable transformant clones 8- to 10-fold. All stable transformants analyzed displayed Zn(2+)-inducible APRT enzyme activity. Our results indicate that stable mammalian cell transformants with inducible genes under regulation of the sheep MT I promoter should be useful, because of low basal and high induced expression, for studies in which modulation of transcriptional activity is required.