Infection of eucaryotic cells by helper-independent recombinant adenoviruses: early region 1 is not obligatory for integration of viral DNA

The Chinese hamster ovary adenine phosphoribosyl transferase gene (aprt) was reengineered to be flanked by sequences from the thymidine kinase (tk) gene of herpes simplex virus. This construct was cotransfected with DNA from herpes simplex virus type 1, and after 3 days, virus was harvested and Tk- plaques were selected after the virus was plated on Tk- cells in the presence of bromodeoxycytosine. Recombinant viruses were identified by dot-blot hybridization, and the arrangement of aprt and tk sequences were determined by Southern blot hybridization. Analysis of the recombinants revealed that acquisition of aprt sequences resulted from insertional inactivation of the tk locus as a consequence of homology-based recombination. Recombination was precise, as evidenced by the failure to detect plasmid sequences or the synthetic restriction endonuclease sites that bounded the mutant tk gene in the aprt-tk construct. Infection of Aprt- mouse or Chinese hamster ovary cells with UV-irradiated virus and selection in medium containing azaserine and adenine resulted in the survival of numerous colonies that stably express the aprt gene. Transformed cells synthesized an aprt mRNA that is identical to wild-type mRNA as determined by Northern blot and S1 nuclease analyses. Cells lytically infected with the recombinant virus do not appear to transcribe the aprt gene. Thus, infected cells differentiate between virus and foreign promoters even when a cellular gene is cis to the virus chromosome.     

The nature of ultraviolet light-induced mutations at the heterozygous aprt locus in Chinese hamster ovary cells

A system for studying mutational specificity at a heterozygous locus in Chinese hamster ovary (CHO) cells is described. The strategy employed is based on restriction fragment analysis and DNA sequencing of enzymatically amplified mutant adenine phosphoribosyltransferase (aprt) alleles. We have demonstrated the usefulness of this approach through the characterization of a collection of aprt- mutants with respect to the role played by loss of heterozygosity events in ultraviolet light (UV) induced mutagenesis. A similar strategy has also been applied to speculate on the identity of the premutational lesion responsible for a UV-induced mutational hotspot at the aprt locus.     

Metabolic consequences of adenine-phosphoribosyl transferase deficiency in V79 hamster fibroblasts.

Two APRT- clones (V79-E3 and V79-E1A) were isolated from V79 hamster fibroblasts treated with ethyl methanesulfonate. Selection involved sequential exposure of the mutagenized cells to the adenine analogues 8-azaadenine and 2,6-diaminopurine. To examine the influence of APRT deficiency on cell metabolism we determined the size and turnover of adenine ribonucleotide pools, the deoxyribonucleoside triphosphate pools, the rate of DNA synthesis, and the length of the cell cycle. Clone V79-E3 was hemizygous for aprt and carried a new chromosome, 3p-. Clone V79-E1A was quasi-tetraploid with a cell volume more than twice that of the WT cells. When the difference in size was taken into account, both clones behaved similarly. While WT V79 cells released no adenine into the medium, they excreted adenine at a rate of 6 pmol/min. This did not affect the size of the ATP pool. The main change in the deoxynucleotide pools was a marked decrease of the concentration of dCTP. The rate of DNA synthesis was the same in WT cells and in the diploid V79-E3 clone. APRT is known to recycle adenine produced during polyamine synthesis, but the enzyme apparently contributes little to the maintenance of adenine ribonucleotide pools of V79 fibroblasts.     

Cloning the complete human adenine phosphoribosyl transferase gene

We have isolated a clone from a human genomic lambda library which cross-hybridises with the cloned hamster adenine phosphoribosyl transferase gene (aprt). After restriction mapping and further hybridisation to the hamster gene, a series of putative human aprt-containing fragments has been isolated and tested for ability to transform adenine phosphoribosyl transferase-deficient (aprt-) strains of Chinese hamster ovary (CHO) cells to APRT proficiency. Transforming activity was detected in a 48-kb lambda clone, the 17.4-kb EcoRI insert, and an 8.6-kb HincII fragment. Smaller fragments have thus far shown no transforming activity. Transformants appear to be stable for the APRT+ phenotype, and human aprt DNA sequences are present in the hamster transformants. The 8.6-kb HincII fragment has been subcloned and the insert mapped. Nonrepetitive regions of this subclone have been identified, and should prove valuable for chromosome walking studies on human chromosome 16, familial studies of a human aprt- trait, the analysis of restriction fragment length polymorphisms (RFLPs) in the area surrounding the aprt gene, and the fine structure mapping of the mutations induced by chemical carcinogens and alkylating agents.     

Model involving gene inactivation in the generation of autosomal recessive mutants in mammalian cells in culture.

We present evidence for a two-step model for expression of the recessive phenotype at the diploid adenine phosphoribosyl transferase (aprt) locus in Chinese hamster ovary cells. This model proposes a high-frequency event leading to allelic inactivation and a low-frequency event leading to a structural alteration of the APRT protein. Either event can occur first, resulting in two types of heterozygous cells. The proposed model is based on analysis of Chinese hamster ovary presumptive aprt heterozygotes and APRT- mutants, derived by two different laboratories. The major class of heterozygotes (class 1) had approximately 50% parental APRT activity, 50% immunologically precipitable APRT protein, and only wild-type enzyme as based on two-dimensional gel electrophoresis and thermal inactivation studies. We propose that one allele at the aprt locus has been inactivated in these heterozygotes. APRT- mutants derived from any single class 1 heterozygote arose at a low frequency and contained either no immunologically detectable APRT protein or an APRT enzyme which was, in most cases, demonstrably altered. The second class of heterozygotes, consisting of two independent isolates, gave rise to APRT- cells at a high frequency (10(-3) to 10(-5). These heterozygous cell lines had 50% of parental APRT activity and only wild-type spot, or wild-type and an electrophoretic variant spot, on two-dimensional gels. These aprt heterozygotes appear to have arisen by mutation at one allele. APRT- mutants derived from either heterozygote of this class had all lost the wild-type activity, consistent with the proposed model.     

Mechanism of mutation at the aprt locus in Chinese hamster ovary cells: analysis of heterozygotes and hemizygotes.

A two-step model to explain the high frequency of mutation at the diploid adenine phosphoribosyltransferase (aprt) locus in CHO cells has been proposed previously (Simon et al., Mol. Cell. Biol. 2:1126-1133, 1982). This model indicates that two distinct classes of aprt heterozygotes can be isolated. Class 1 heterozygotes, the most abundant class, were defined as those which arose spontaneously and were capable of undergoing mutation to the APRT- phenotype only at a low frequency (putative point mutation). Class 2 heterozygotes arose from a mutation and gave rise at a high frequency to APRT- cells. This high-frequency event has been identified as a deletion of the wild-type allele (A. E. Simon and M. W. Taylor, Proc. Natl. Acad. Sci. U.S.A. 80:810-814, 1983). In this paper we report further analysis of class 1 heterozygotes with respect to genetic structure, gene products, and karyotype. Our study indicated that class 1 heterozygotes contain two different types of mutants. About half have only one copy of the aprt gene and an unaltered karyotype, indicating that a deletion (similar to the high-frequency second-step event observed for class 2 heterozygotes) rather than a loss of the chromosome was responsible for the generation of the aprt+/- genotype. The remainder of the previously designated class 1 heterozygotes still contained two copies of the aprt gene (within the limits of the quantitation technique used) and arose presumably by a point mutation. One of this group, D423, was characterized with respect to aprt gene products and found to produce an electrophoretic variant in addition to the wild-type protein. APRT- mutants derived from D423 retained the same number of aprt gene copies as D423 and still synthesized a protein that comigrated with wild type, unlike APRT- mutants derived from class 2 heterozygotes. D423 and the other heterozygotes with two aprt genes therefore did not fit into either class 1 or 2 and are now designated class 3. The model we present suggests that only one of the two aprt alleles present in wild-type cells can undergo the deletion.     

Genetic and biochemical studies with the adenosine analogs toyocamycin and tubercidin: mutation at the adenosine kinase locus in Chinese hamster cells.

The pyrrolopyrimidine nucleosides toyocamycin and tubercidin show several unique features of growth inhibition in Chinese hamster ovary (CHO) cells. Stable mutants which are more than 600-fold resistant to these drugs are obtained in CHO cells at a strikingly high frequency of approximately 10(-3), in the absence of mutagenesis. The mutants resistant to toyocamycin (Toyr) and tubercidin (Tubr) exhibit similar cross-resistance patterns to the two selective drugs as well as to adenosine and 6-methyl mercaptopurine riboside, indicating that the same lesion is probably involved in all cases. The mutants examined were found to be deficient in the enzyme adenosine kinase (AK), indicating that the phosphorylation of these analogs is an essential first step in their toxic action. The above mutants (AK-) behaved recessively in cell hybrids, and segregation studies indicate that the AK locus is not linked to the X chromosome. The frequencies of similar Toyr mutants in other Chinese hamster lines, e.g., V79, CHW, M3-1, GM7, and CHO-K1, varied from similar to more than three logs less than that observed for CHO cells, indicating that various cell lines probably differ in the number of functional gene copies for this locus.     

Heritable alterations at the adenine phosphoribosyltransferase (APRT) locus in human lymphoblastoid cell lines.

Human lymphoblastoid cell lines derived from WI-L2 exhibit unexpected frequencies of diaminopurine (DAP) resistant mutants. The background mutant fractions of 10(-7) to 10(-8) in untreated cultures are much lower than the frequencies expected for loss of a heterozygous autosomal locus (10(-5) to 10(-6), yet much higher than expected for a homozygous locus (10(-10) to 10(-12). We used aminopterin, adenine and thymidine (AAT) to select DAP-sensitive (DAPS) revertants from one resistant line. The background frequency of DAPR in these revertant cell lines ranged from 3.5 to 6.5 x 10(-4), approximately the square root of 10(-7). Thus these data suggest that both alleles of aprt are inactivated at similarly high frequencies. They also indicate that the DAPS revertants were heterozygotes (aprt +/-) or hemizygotes (aprt +/0) and that WI-L2 was homozygous (aprt+/+). Mutational dose-response studies with X-rays, ethyl methanesulfonate (EMS), and ICR-191 were conducted in 4 of these revertant cell lines. EMS and ICR-191, which induce mainly point mutations, did not induce an increase in mutant fraction. A dose of 200 cGy X-rays, however, induced a frequency of 10(-3). Treatment of DAPR cells with 5-azacytidine induced a significant increase in reversion to DAPS. Southern blot analysis of the aprt gene after digestion with MspI or HpaII also suggests that differential methylation changes may play a major role in the generation of DAP sensitivity and resistance.     

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.     

Segregation of recessive phenotypes in somatic cell hybrids: role of mitotic recombination, gene inactivation, and chromosome nondisjunction.

Somatic cell hybrids heterozygous at the emetine resistance locus (emtr/emt+) or the chromate resistance locus (chrr/chr+) are known to segregate the recessive drug resistance phenotype at high frequency. We have examined mechanisms of segregation in Chinese hamster cell hybrids heterozygous at these two loci, both of which map to the long arm of Chinese hamster chromosome 2. To follow the fate of chromosomal arms through the segregation process, our hybrids were also heterozygous at the mtx (methotrexate resistance) locus on the short arm of chromosome 2 and carried cytogenetically marked chromosomes with either a short-arm deletion (2p-) or a long-arm addition (2q+). Karyotype and phenotype analysis of emetine- or chromate-resistant segregants from such hybrids allowed us to distinguish four potential segregation mechanisms: (i) loss of the emt+- or chr+-bearing chromosome; (ii) mitotic recombination between the centromere and the emt or chr loci, giving rise to homozygous resistant segregants; (iii) inactivation of the emt+ or chr+ alleles; and (iv) loss of the emt+- or chr+-bearing chromosome with duplication of the homologous chromosome carrying the emtr or chrr allele. Of 48 independent segregants examined, only 9 (20%) arose by simple chromosome loss. Two segregants (4%) were consistent with a gene inactivation mechanism, but because of their rarity, other mechanisms such as mutation or submicroscopic deletion could not be excluded. Twenty-one segregants (44%) arose by either mitotic recombination or chromosome loss and duplication; the two mechanisms were not distinguishable in that experiment. Finally, in hybrids allowing these two mechanisms to be distinguished, 15 segregants (31%) arose by chromosome loss and duplication, and none arose by mitotic recombination.     

Brca2 (XRCC11) Deficiency Results in Radioresistant DNA Synthesis and a Higher Frequency of Spontaneous Deletions

We show here that the radiosensitive Chinese hamster cell mutant (V-C8) of group XRCC11 is defective in the breast cancer susceptibility gene Brca2. The very complex phenotype of V-C8 cells is complemented by a single human chromosome 13 providing the BRCA2 gene, as well as by the murine Brca2 gene. The Brca2 deficiency in V-C8 cells causes hypersensitivity to various DNA-damaging agents with an extreme sensitivity toward interstrand DNA cross-linking agents. Furthermore, V-C8 cells show radioresistant DNA synthesis after ionizing radiation, suggesting that Brca2 deficiency affects cell cycle checkpoint regulation. In addition, V-C8 cells display tremendous chromosomal instability and a high frequency of abnormal centrosomes. The mutation spectrum at the hprt locus showed that the majority of spontaneous mutations in V-C8 cells are deletions, in contrast to wild-type V79 cells. A mechanistic explanation for the genome instability phenotype of Brca2-deficient cells is provided by the observation that the nuclear localization of the central DNA repair protein in homologous recombination, Rad51, is reduced in V-C8 cells.     

Differential efficiency of mutagenesis at three genetic loci in CHO cells by a benzo[a]pyrene diol epoxide

The formation of DNA adducts by the ultimate carcinogen 7r,8t-dihydroxy-9t,10t-oxy-7,8,9,10-tetrahydrobenzo[alpha]pyrene (BPDE-I) has been implicated in the process of carcinogenesis. In a line of Chinese hamster ovary (CHO) cells designated AT3-2 and in two derivative mutant lines, UVL-1 and UVL-10, originally selected for hypersensitivity to UV-irradiation, we have measured the formation of BPDE-I: DNA adducts and the production of biological damage. The quantity and quality of BPDE-I: DNA adducts formed initially in the 3 cell lines are identical over a wide range of BPDE-I doses. However, the UVL lines are unable to remove adducts from their DNA, while the AT3-2 cells remove about 50% of the BPDE-I: DNA adducts in a 24-h incubation. Correlated with this, the UVL lines are more sensitive to the lethal effects of BPDE-I than are the AT3-2 cells. Mutant frequencies were measured at the aprt, hprt and oua loci and were found to increase linearly with BPDE-I: DNA adduct formation at doses which gave greater than 50% survival. At the hprt and oua loci, the efficiency of mutation induction was similar for AT3-2 and UVL-10 cells. UVL-1 cells showed slightly higher (within a factor of 2-3) mutant frequencies in response to BPDE-I compared to AT3-2 at these two loci. However, at the aprt locus the repair-deficient cells were much more highly mutable (9-15-fold) than the repair-proficient AT3-2 cells. Based on the measured average level of adduct formation, it is calculated that 15% of the BPDE-I: DNA adducts in the aprt gene are converted into mutations. However, the possibility exists that the aprt locus is subject to higher levels of modification by BPDE-I than is the bulk DNA, which would lead to an artifactually high apparent conversion frequency.     

DNA amplification--deletion in a spontaneous mutation of the hamster aprt locus: structure and sequence of the novel joint.

In a collection of spontaneous mutants of Chinese hamster ovary cells selected for deficiency in adenine phosphoribosyl transferase (aprt) activity, one was detected having not only a deletion of aprt coding sequences but also an apparent amplification of remaining sequences. The HindIII fragment bearing the novel joint was cloned and sequenced revealing a complex gene rearrangement. A deletion of at least 9 kb extending upstream from the aprt locus is accompanied by an inverted duplication of flanking sequences 672 bp downstream from the novel joint. This unit is amplified three to four times with the net result of some sequences being increased as much as eight fold in copy number because of the duplication. The fidelity of the sequences involved is preserved. We propose a model which could account for this inverted duplication.     

Human chromosome 11 complements ataxia-telangiectasia cells but does not complement the defect in AT-like Chinese hamster cell mutants

It has been shown that the X-ray-sensitive Chinese hamster V79 mutants (V-E5, V-C4 and V-G8) are similar to ataxia-telangiectasia (A-T) cells. To determine whether the AT-like rodent cell mutants are defective in the gene homologous to A-T (group A, C or D), human chromosome 11 was introduced to the V-E5 and V-G8 mutant cells by microcell-mediated chromosome transfer. Forty independent hybrid clones were obtained in which the presence of chromosome 11 was determined by in situ hybridization. The presence of the region of chromosome 11q22–23 was shown by molecular analysis using polymorphic DNA markers specific for the ATA, ATC and ATD loci. Seventeen of the obtained monochromosomal Chinese hamster hybrids contained a cytogenetically normal human chromosome 11, but only twelve hybrid cell lines were shown to contain an intact 11q22–23 region. Despite the complementation of the X-ray sensitivity by a normal chromosome 11 introduced to A-T cells (complementation group D), these twelve Chinese hamster hybrid clones showed lack of complementation of X-ray and streptonigrin hypersensitivity. The observed lack of complementation does not seem to be attributable to hypermethylation of the human chromosome 11 in the rodent cell background, since 5-azacytidine treatment had no effect on the streptonigrin hypersensitivity of the hybrid cell lines. These results indicate that the gene defective in the AT-like rodent cell mutants is not homologous to the ATA, ATC or ATD genes and that the human gene complementing the defect in the AT-like mutants seems not to be located on human chromosome 11.     

Nucleotide ectoenzyme activities of human and Chinese hamster fibroblasts in tissue culture

We have previously assigned human ecto-5'-nucleotidase (NT) to chromosome 6 on the basis of conversion of exogenously supplied [14C]AMP to adenosine by whole cells of human and Chinese hamster hybrids carrying chromosome 6. In this paper we demonstrate that the activity on human MRC-5 fibroblasts is typical of previously described and purified ecto-5'-nucleotidases. In contrast to MRC-5 cells, Chinese hamster V79A2 cells weakly express an AMPase activity that is not NT. The cytosolic form of NT in human and hybrid fibroblasts is similar to the ectoenzyme in substrate specificity. Hybrids that lack chromosome 6 express neither the ecto- nor the cytosolic enzyme, suggesting that both forms may be coded by the same gene on chromosome 6. Ecto-ATPase, ecto-ADPase, and ecto-ADP kinase activities are each expressed at similar levels in MRC-5 and V79A2. The ATPase, ADPase and NT activities of MRC-5 cells act sequentially to generate adenosine. A similar cascade acts on V79A2 cells but the lack of NT causes the accumulation of AMP.     

Structure of mutant alleles at the aprt locus of Chinese hamster ovary cells

To determine the types of gene structural alterations causing deficiency of adenine phosphoribosyl transferase (aprt) activity in spontaneous and chemically induced mutations of cultured somatic cells, we analyzed the restriction enzyme cleavage patterns of aprt gene sequences in mutant strains selected from Chinese hamster ovary cells. Patterns of aprt-containing fragments in Southern blots were mostly unchanged in our collection of 280 ethyl methane sulfonate-induced and spontaneous aprt- mutants, suggesting that base-pair changes or other alterations below our limit of resolution on agarose gels (approximately 50 base-pairs) are responsible for the great majority of mutations at the aprt locus. Occasionally, these mutations could be localized when they resulted in the loss or gain of a restriction enzyme site and the generation of new fragments of predictable size. Deletions of aprt-containing sequences were detected in only eight of 119 spontaneous mutants and in only one ethyl methane sulfonate-induced mutant. An insertion of 300 base-pairs near the 5' end of the aprt structural gene was found in one spontaneous aprt- strain. This insertion mutant was stable with a reversion frequency of less than 2 X 10(-7). Several unstable aprt- mutants were detected in our collection, but these had no observable alterations of aprt coding or flanking sequences.     

Genotoxicity of 2,4,6-trichlorophenol in V79 Chinese hamster cells.

The genotoxicity of the rodent carcinogen 2,4,6-trichlorophenol (TCP) was studied without exogenous metabolic activation in V79 Chinese hamster cells. TCP did not induce mutation at the hprt locus to 6-thioguanine resistance or structural chromosome aberrations. However, it produced statistically significant, dose-related increases in hyperdiploidy and micronuclei. From these results it appears that TCP causes chromosome malsegregation as its major mode of genotoxic action.     

Localization of enolases 1 and 2 on chromosomes 1 and 12 respectively by the analysis of human-mouse hybrids]

The study of enolase in man-mouse somatic hybrids confirms synteny between ENO1 and the markers on human chromosome 1 (AK2, PGM1, Pep-C) and synteny between ENO2 and the markers on human chromosome 12 (LDHB, Pep-B). The study also shows that the different enolase bands observed in mouse cell strains (Cl1D, R4, A9, 3T3), in hamster cell strains (CH, V79/4, A3), and in 3 of the different bands observed in human fibroblasts have a dimeric structure. The formation of these enolase bands depends on genes at two different loci alpha and beta. The hamster cell line CH (HGPRT) showed a rare enolase phenotype with a two-banded pattern in the intermediate region, a triple-banded pattern in the slow region, and one single isozyme in the fast region. This hamster strain is heterozygous for the first locus and homozygous for the second one. The relationship between these different enolase bands is as follow: in the slow "a" zone, alpha1alpha1,alpha1 alpha2,alpha2alpha2; in the intermediate "i" zone, alpha1beta1, alpha2beta1; and, in the fast "b" zone, beta1beta1. It appears that the frequency of heterozygotes for the alpha or beta loci in man is very low. Of 32 unrelated fibroblast strains investigated, none was found to be heterozygous for the alpha or beta locus.     

Deletion formation in mammalian cells: molecular analysis of breakpoints and junctions in the hamster aprt locus

To examine the mechanisms governing deletion formation in mammalian cells, we have analyzed the breakpoints and junction fragments produced by seven such mutations at the aprt locus of Chinese hamster ovary cells at the base sequence level. The deletions were heterogeneous both in size, varying from 38 bp to 170 kb, and in sequence in that no recurring sequence or structural motifs were evident. Most were simple exchanges at overlapping di- or trinucleotides, but one was the result of a complex rearrangement in which breakpoints approximately 34 kb apart were joined by 16- and 398-bp inserted fragments originating some distance from the target. Unlike many human germ line deletions, few of the breakpoints fell within hamster repetitive elements. The directionality of the deletions at aprt indicates that an essential gene or structure may determine the pattern of such mutations.     

Tyrosyltubulin ligase and colchicine binding activity in synchronized Chinese hamster cells

Tyrosyltubulin ligase (TTL) was found to be present in CHO and V79 Chinese hamster cells grown in tissue culture. The enzyme is soluble and requires potassium, magnesium, and ATP for maximum activity and requires tubulin as a substrate. TTL was analyzed through the cell cycle of V79 and CHO Chinese hamster cells. The enzyme showed two peaks of activity in V79 cells at 4 h and 7 h after mitotic selection, corresponding to the early S and mid to late S phases of the cell cycle. In CHO cells the enzyme displayed a major peak of activity at mid S and a minor peak or plateau during early S. Tubulin, as measured by (3H)colchicine binding, was shown to increase through S phase and reach a maximum late in the cycle during G2 approx. 3 h after maximum TTL activity.