Transformation of the gene for hypoxanthine phosphoribosyltransferase

Serial induction of mutations by ethylnitrosourea in PC12 cells: a new model for a phenotypical characterization of the neurotoxic response to 6-hydroxydopamine

Here we show that the serial generation of allelic mutations by treatment with the mutagen ethylnitrosourea (ENU) in PC12 cells provides a new model for the phenotypical dissection of biological properties. We tested this approach in the neurotoxic 6-OHDA model of Parkinson's disease in PC12 cells which has been widely used as an in vitro model for the investigation of the molecular pathogenesis of neuronal cell death and for novel treatment approaches. ENU treatment at doses of 0.2 and 0.3 mg/ml for 1 h resulted in 35 and 25% surviving PC12 cells, respectively, which showed mutation frequencies of approximately 10 mutations per genome. Clones derived from single ENU treated PC12 cells showed marked differences in their resistance against 6-OHDA. The phenotypical analysis of resistant and sensitive clones showed a differential transcriptional regulation of multiple genes. The applicability of this approach could be demonstrated by the identification of the rat TM9SF1 gene coding for a transmembrane protein of the nonaspanin superfamily as a regulated gene in PC12 clones resistant against 6-OHDA. Our data demonstrate the suitability of this model for the investigation of the molecular pathogenesis of neurodegeneration and for high-throughput analysis, e.g. for drug discovery.

Selection based on the expression of antisense hypoxanthine-xanthine-guanine-phosphoribosyltransferase RNA in Toxoplasma gondii

We have previously shown that an antisense RNA strategy can be used to inhibit the expression of hypoxanthine-xanthine-guanine-phosphoribosyltransferase (HXGPRT) in Toxoplasma gondii [Nakaar et al., J. Biol. Chem. 1999;274:5083-5087]. Here, we report that parasites rendered deficient in HXGPRT by antisense RNA are resistant to high doses of 6-thioxanthine (6-TX). We have exploited this finding to develop a selection procedure. In this scheme, parasites transfected with a chimeric construct harboring the bacterial chloramphenicol acetyl transferase (CAT) reporter gene linked to antisense HXGPRT gene were selected in 6-TX to inhibit the growth of tachyzoites expressing endogenous HXGPRT. Concomitant with a reduction in HXGPRT levels by antisense RNA, 6-TX(R) parasites displayed reporter CAT activity. These data indicate that transfection of antisense HXGPRT gene provides a means to select for parasites expressing foreign or altered genes in T. gondii. These findings also suggest, in principle, that antisense RNA can be used as a strategy to generate selectable markers employing genes that encode enzymes with known subversive substrates.

High-frequency transfer of cloned herpes simplex virus type 1 sequences to mammalian cells by protoplast fusion

The protoplast fusion technique of Schaffner (W. Schaffner, Proc. Natl. Acad. Sci. U.S.A. 77:2163-2167, 1980) has been adapted to introduce cloned herpes simplex virus genes into cultured mammalian cells. The technique involves digesting bacterial cell walls with lysozyme to produce protoplasts and then fusing the protoplasts to mammalian cells by treatment with polyethylene glycol. For monitoring transfer, protoplasts were labeled with the fluorescent dye fluorescein isothiocyanate before fusion. After fusion, greater than 50% of the mammalian cells were fluorescent, demonstrating that bacterial material was transferred with high frequency. Transfer of plasmid pBR325 occurred at frequencies of 1 to 2%, as measured by in situ hybridization. Fusion transfer of a chimeric plasmid consisting of the herpes simplex virus type 1 (strain KOS) EcoRI fragment F in pBR325 resulted in expression of some viral genomic sequences in about 5% of the mammalian cells, as detected by indirect immunofluorescence. One Ltk- cell in 300 to 500 was transformed to the TK+ phenotype after fusion with protoplasts carrying the chimeric plasmid pX1, which consists of pBR322 and the BamHI fragment coding for the herpes simplex virus type 1 thymidine kinase gene.

An early history of gene transfer and therapy

The term "gene therapy" was coined to distinguish it from the Orwellian connotations of "human genetic engineering," which, in turn, was derived from the term "genetic engineering." Genetic engineering was first used at the Sixth International Congress of Genetics held in 1932 and was taken to mean "the application of genetic principles to animal and plant breeding." Once the basics of molecular genetics and gene transfer in bacteria were established in the 1960s, gene transfer into animals and humans using either viral vectors and/or genetically modified cultured cells became inevitable. Despite the early exposition of the concept of gene therapy, progress awaited the advent of recombinant DNA technology. The lack of trustworthy techniques did not stop many researchers from attempting to transfer genes into cells in culture, animals, and humans. Viral genomes were used for the development of the first relatively efficient methods for gene transfer into mammalian cells in culture. In the late 1970s, early transfection techniques were combined with selection systems for cultured cells and recombinant DNA technology. With the development of retroviral vectors in the early 1980s, the possibility of efficient gene transfer into mammalian cells for the purpose of gene therapy became widely accepted.

Rapid transformant selection by human complement using HRF20 (CD59) cDNA as a selection marker

The 20 kDa homologous restriction factor (HRF20, CD59) prevents formation of membrane attack complexes of human complement. Transfection of the cDNA of HRF20 to heterologous cells, which are sensitive to human complement, thereby renders these cells resistant to human complement attack. This property can then be used as a selection marker of transfection. In addition, the procedure is short and can be performed within 8 h. Since only 1 h is required for incubation with complement, the damage to the transfected cells is limited compared with damage resulting from selection for drug resistance which requires 10 days or more of incubation in the presence of harmful agents.

Development of new cell lines for animal cell biotechnology

Mammalian cell culture has been an important technique in laboratory-scale experimentation for many decades. Developments in large-scale culture have been due to the need to grow large numbers of cells to support the growth of viruses for vaccine production, and more recently, for growing hybridoma cells as a source of monoclonal antibody. Increasingly, however, pharmaceutical products such as hormones, enzymes, growth factors, and clotting factors are being produced from cell lines which have been manipulated by recombinant DNA techniques. It is clear, therefore, that the high cost of growing mammalian cells on a large scale does not necessarily prohibit their use for biotechnology, and indeed there is considerable evidence to suggest that animal cell biotechnology will continue to be a major growth area in the future.

The effect of cell synchronization on the efficiency of stable gene transfer by electroporation

We synchronized thymidine kinase deficient mouse Ltk-cells by two different methods, hydroxyurea double-block treatment or aphidicolin single-block treatment and transformed them with the cloned herpes simplex virus thymidine kinase gene at various time intervals by the electroporation technique. Marked enhancement of stable transformation efficiency was observed at the time corresponding to the peak of G2/M phase. These results suggest that the G2/M phase is the most efficient period for stable gene transfer by electroporation.

The rat albumin gene promoter is appropriately regulated in transient but not in stable transfections

The tissue-specific expression of the liver-specific rat albumin gene promoter was examined after transfer to various hepatic and non-hepatic cell lines. A 402 base pair sequence from the albumin gene 5' flank enabled a fused reporter chloramphenicol acetyltransferase gene to be expressed in rat hepatoma cell lines but not in fibroblast lines or dedifferentiated hepatoma cells. However, when this same construct was analyzed in permanently transfected cell populations, it was expressed equally well in differentiated and dedifferentiated hepatoma cells and in two of three fibroblast lines tested. The inappropriate expression of the albumin promoter was also seen using the HSV tk gene and the E. coli gpt gene as reporters, and when assayed by colony formation in HAT medium (tk gene) or by S1 protection of transcripts in cotransfected populations (tk and gpt genes). These results show that gene regulatory elements can behave differently in transient vs. stable transfections, and suggest that chromosomal integration can provide long range positive influences on gene expression.

Deoxyribonucleic acid-mediated gene transfer in mammalian cells: molecular analysis of unstable transformants and their progression to stability

To elucidate mechanisms involved in deoxyribonucleic acid-mediated gene transfer, we transferred the herpes simplex virus thymidine kinase gene (TK) into mouse Ltk- cells. Independent TK+ clones (transformants) and derivatives of each were tested for phenotypic expression and the presence and arrangement of TK sequences. Initially, transformants expressed viral TK unstable, with 10% of the cells in each generation losing both the TK+ phenotype and virally derived TK sequences. After a prolonged period in culture, stable subpopulations arose from which the TK+ phenotype and viral sequences were no longer lost at detectable frequency. Analysis of unstable cell populations indicated that individual viral deoxyribonucleic acid molecules were reduced in size, but were linked to other deoxyribonucleic acid to form molecules large enough to be precipitated in a Hirt fractionation. We term these molecules transgenomes. Analysis of independent unstable subclones derived from the primary transformants demonstrated that individual transgenomes could contain multiple copies of the viral TK sequences. Recipient cell lines frequently possessed more than one type of transgenome and possibly multiple copies per cell of each type. Stable derivatives possessed only one of the transgenomes present in the unstable parent, and these sequences were associated with a recipient cell chromosome.

Cell transformation mediated by chromosomal deoxyribonucleic acid of polyoma virus-transformed cells

To study the mechanism of deoxyribonucleic acid (DNA)-mediated gene transfer, normal rat cells were transfected with total cellular DNA extracted from polyoma virus-transformed cells. This resulted in the appearance of the transformed phenotype in 1 X 10(-6) to 3 X 10(-6) of the transfected cells. Transformation was invariably associated with the acquisition of integrated viral DNA sequences characteristic of the donor DNA. This was caused not by the integration of free DNA molecules, but by the transfer of large DNA fragments (10 to 20 kilobases) containing linked cellular and viral sequences. Although Southern blot analysis showed that integration did not appear to occur in a homologous region of the recipient chromosome, the frequency of transformation was rather high when compared with that of purified polyoma DNA, perhaps due to "position" effects or to the high efficiency of recombination of large DNA fragments.

Detection, frequency, and stability of cotransformants expressing nonselectable human enzymes

We cotransformed mouse 3T3 cells with total genomic human DNA and the dominant selectable bacterial gene Neo and analyzed 121 NeoR clones for expression of 15 human "housekeeping" enzymes which can be distinguished from their murine homologs. The estimated frequency of expression of unlinked human genes was 1 in 360 NeoR clones and at least three different human enzymes (peptidase D, phosphoglucomutase 1, and acid alpha glucosidase) were detected. We further examined the frequency and stability of cotransformation for one of these enzymes, acid alpha glucosidase (GAA). We tested approximately 4000 NeoR clones and found 25 clones expressing human GAA, as determined by rocket immunoelectrophoresis (RIE) specific for human GAA. Transformants progressively became negative on continued growth and retesting by RIE, with only two clones still expressing GAA at the eighth testing. This apparent loss of expression was not due to nonclonality of the original isolates. In one subclone examined, loss of expression was accompanied by loss of both Neo-derived pBR322 and human Alu repetitive sequence DNA. Thus, under the conditions utilized, cotransformants expressing homomeric housekeeping enzymes were found at relatively high frequency but were progressively lost even under conditions selective for expression of the dominant vector.

Unstable expression and amplification of a transfected oncogene in confluent and subconfluent cells

NIH 3T3 cells were transfected with a plasmid containing the transforming gene, v-src, from Rous sarcoma virus. One of the transformed cell lines isolated reverted to a flat, nontransformed morphology after cloning through soft agar. This cell line did not express the src gene and could no longer grow in soft agar. When these cells were held at confluence, spontaneous foci appeared which eventually covered the dish. The appearance of foci correlated with an increase in v-src gene expression, ability to grow in soft agar, and tumorigenicity in mice. When these transformed cells were trypsinized and held at subconfluence, both v-src expression and the transformed phenotype were progressively lost. Whereas rearrangement of the transfected gene was not detected, the gene copy number in the transformed cells was markedly increased (greater than 50-fold). Confluence-dependent gene amplification and deamplification have been retained after several cycles of growth alternately at high and low density, in cells recloned through soft agar, and after cells had been maintained continuously at high or low density. The results suggest that, in this cell line, reversible gene amplification plays a central role in expression of the transfected gene.

Unstable expression and amplification of a transfected oncogene in confluent and subconfluent cells

NIH 3T3 cells were transfected with a plasmid containing the transforming gene, v-src, from Rous sarcoma virus. One of the transformed cell lines isolated reverted to a flat, nontransformed morphology after cloning through soft agar. This cell line did not express the src gene and could no longer grow in soft agar. When these cells were held at confluence, spontaneous foci appeared which eventually covered the dish. The appearance of foci correlated with an increase in v-src gene expression, ability to grow in soft agar, and tumorigenicity in mice. When these transformed cells were trypsinized and held at subconfluence, both v-src expression and the transformed phenotype were progressively lost. Whereas rearrangement of the transfected gene was not detected, the gene copy number in the transformed cells was markedly increased (greater than 50-fold). Confluence-dependent gene amplification and deamplification have been retained after several cycles of growth alternately at high and low density, in cells recloned through soft agar, and after cells had been maintained continuously at high or low density. The results suggest that, in this cell line, reversible gene amplification plays a central role in expression of the transfected gene.

Cotransfer of syntenic human genes into mouse cells using isolated metaphase chromosomes or cellular DNA

Chromosome-mediated gene transfer (CMGT) of the human genes for hypoxanthine phosphoribosyl transferase (HPRT) and cytosol thymidine kinase (TK1) into HPRT deficient mouse A9 cells or TK deficient Swiss mouse 3T3TK- cells was found to occur at frequencies at least one order of magnitude higher than DNA-mediated gene transfer (DMGT). The frequency of CMGT into 3T3TK- cells was reduced by more than an order of magnitude by a posttreatment of the recipient cells with dimethyl sulphoxide (DMSO). After CMGT, expression of the non-selected genes coding for galactokinase (GALK) and acid alpha-glucosidase (GAA), both syntenic with TK1, was observed in a number of transformants. From the pattern of cotransfer, a tentative gene ordering of CENTROMERE-GALK-TK1-GAA on human chromosome 17 was deduced. Chromosome-mediated cotransfer of X-linked human phosphoglycerate kinase (PGK) with HPRT was observed in two out of 33 A9 transformants analysed. DNA-mediated cotransfer of a syntenic gene was only observed for GALK, cotransferred with TK1 in two out of 18 TK+ transformants of mouse LTK- cells. Therefore, with murine cells as recipients of human donor genetic material, CMGT results in a higher frequency of transfer and a higher incidence of cotransfer of syntenic genes than DMGT using cellular DNA in the same cell system.

DNA-mediated gene transfer into human diploid fibroblasts derived from normal and ataxia-telangiectasia donors: parameters for DNA transfer and properties of DNA transformants

We investigate the feasibility of DNA-mediated gene transfer into human diploid fibroblasts derived from patients with the radiation sensitive syndrome ataxia-telangiectasia (A-T) and from a normal donor. Although they are markedly different in their growth characteristics, both normal and A-T strains give similar frequencies for DNA transfer in a model system using the recombinant plasmid pSV2 -gpt. pSV2 -gpt DNA transformants arise with a frequency between 10(-5) and 10(-4) per viable cell. Analysis of such transformants, although possible, is severely handicapped by the limited clonal life span of diploid human cells. Despite these problems it may be concluded that diploid human fibroblasts are competent recipients for DNA-mediated gene transfer and the putative repair deficiency of A-T does not markedly effect the efficiency of this process.

Structure, expression, and mutation of the hypoxanthine phosphoribosyltransferase gene

The wild-type mouse hypoxanthine phosphoribosyltransferase (HPRT; IMP:pyrophosphate phosphoribosyltransferase, EC 2.4.2.8) gene has been isolated from genomic libraries and its structure has been determined. This X chromosome-linked gene is greater than 33 kilobases long and is split into nine exons. All the exon sequences have been determined, and a single-base substitution in the HPRT cDNA coding sequence from a mouse neuroblastoma cell line that overproduces a mutant HPRT protein has been identified. The 5' end of the gene has been defined, both by nuclease S1 protection and primer extension studies and by a functional assay in which an HPRT minigene, capable of expression in cultured cells, was created by ligating the 5' end of the gene onto wild-type human HPRT cDNA. Sequences normally associated with eukaryotic promoters are not present in the immediate 5'-flanking region of the HPRT gene, which is instead highly G+C rich. This observation is discussed in relation to the possible link between DNA methylation and X-chromosome inactivation.

Efficient DNA-mediated transfer of selectable genes and unselected sequences into differentiated and undifferentiated mouse melanoma clones

We have found that three phenotypically dissimilar mouse B16 melanoma subclones are competent recipients for DNA-mediated gene transfer. Two of these approach and a third, amelanotic clone B78H1, surpasses mouse LTK cells in frequencies of transferent colony formation after treatment with either of two codominantly selectable plasmid vectors, pSV2gpt or pGCcos3neo. Melanoma transferents incorporate both selectable plasmid-homologous sequences and substantial amounts of unselected donor DNA into their cellular DNAs. In addition they retain the distinctive states of differentiation characteristic of the untreated clones. Frequencies of pGCcos3neo-mediated transfer of neo gene-encoded antibiotic resistance into B78H1 can reach 10(-2) in response to treatment with as little as 15 ng plasmid/ml coprecipitate/dish. B78H1 cells readily give rise to "secondary" transferents for the neo gene after treatment with DNA from a "primary" B78H1 neo transferent. This gene transfer system has potential applications for study of regulation of melanoma and neural crest differentiation and malignancy.

Introduction of purified genes into mammalian cells

There are a number of methods to introduce genes into mammalian cells. These include cell hybridization, chromosome-mediated and DNA-mediated gene transfer. DNA-mediated transfer can be achieved by direct microinjection methods or by indirect methods. The DNA enters the nucleus and is expressed in a high proportion of cells transiently. The DNA then becomes integrated into host cell DNA at random sites resulting in more stably expressing transformants. A number of genes for which selection systems exist can be introduced into mammalian cells. Nonselectable genes can also be introduced into cells by either ligating them to a selectable gene or by mixing them with carrier DNA and a selectable gene. If an amplifiable gene sequence is introduced into cells, it and other genes in its proximity can be coamplified. Amplification of the genes can also be achieved by the use of appropriate viral vectors and recipient cells. The foreign genes are expressed in the recipient cells if they contain the appropriate recognition signals for initiation and termination of transcription. Transfection systems are thus permitting identification of DNA sequences which have a regulatory role in gene expression. The identification of transcriptional signal sequences has formed the basis for construction of appropriate molecules which would permit expression of genes which cannot normally be expressed in mammalian cells (e.g., bacterial genes). The foreign genes are not only expressed in the recipient cells but they can also be subject to regulation in the appropriate environment. This observation is paving the way for identification of regulatory sequences. The foreign DNA sequences integrated into the host genome can be recovered by a variety of methods. Such methods permit isolation of genes which code for a selectable gene product.

DNA-mediated restoration of phenylalanine hydroxylase gene expression in enzyme-deficient derivatives of enzyme-constitutive mouse cell hybrids

Phenylalanine hydroxylase (PH) gene expression is not extinguished in hybrids between PH- mouse A9 cells, or its neomycin-resistant derivative A9Neo-3, and PH+ mouse erythroleukemia (MEL) cells, PHC-3A, in contrast to its extinction in hybrids between A9Neo-3 and PH+ rat hepatoma cells, FT-2. Two different types of 6-thioguanine (TG) -resistant derivatives of these A9 X PHC-3A hybrids (LP), are generated in regard to PH gene expression. In regular growth medium supplemented with 10(-4) M TG (Tyr+/TG), TGr derivatives, all of which continue to express PH, occur with high frequency (approximately equal to 10(-3). In contrast, in tyrosine-deficient selective medium, supplemented with 10(-4) M TG (Tyr-/TG), no actively growing colonies are observed. Nevertheless, small colonies containing quiescent cells can be rescued by supplementing the medium with tyrosine. The rescued TGr clones do not express any detectable level of PH. Biochemical, hybridization, and cybridization analyses of one such rescued clone, LPTG-3, showed that these cells lack the regulatory factor capable of activating PH gene in PH- MEL cells. The PH- phenotype of LPTG-3 cells can be converted to the PH+ phenotype by transfection with restriction enzyme-digested or -undigested PHC-3A or mouse liver DNA. Therefore, these cells could be used to clone a fragment of DNA involved in PH gene regulation through DNA-mediated gene transfer methods.

Efficient transfection of mammalian cells with viral DNA in optimal culture conditions

Standard or newly developed DNA transfection procedures were compared for both innocuity and efficiency using simian virus 40 (SV40) DNA and monkey kidney (Vero) cells as an indicator system. Optimal results have been obtained by treating the delicate cell monolayers with a solution of glycerol before infection with DNA-calcium phosphate complexes.

Chromosome-mediated gene transfer of hydroxyurea resistance and amplification of ribonucleotide reductase activity

Metaphase chromosomes purified from a hydroxyurea-resistant Chinese hamster cell line were able to transform recipient wild-type cells to hydroxyurea resistance at a frequency of 10(-6). Approximately 60% of the resulting transformant clones gradually lost hydroxyurea resistance when cultivated for prolonged periods in the absence of drug. One transformant was subjected to serial selection in higher concentrations of hydroxyurea. The five cell lines generated exhibited increasing relative plating efficiency in the presence of the drug and a corresponding elevation in their cellular content of ribonucleotide reductase. The most resistant cell line had a 163-fold increase in relative plating efficiency and a 120-fold increase in enzyme activity when compared with the wild-type cell line. The highly hydroxyurea-resistant cell lines had strong electron paramagnetic resonance signals characteristic of an elevated level of the free radical present in the M2 subunit of ribonucleotide reductase. Two-dimensional electrophoresis of cell-free extracts from one of the resistant cell lines indicated that a 53,000-dalton protein was present in greatly elevated quantities when compared with the wild-type cell line. These data suggest that the hydroxyurea-resistant cell lines may contain an amplification of the gene for the M2 subunit of ribonucleotide reductase.

Chromosome-mediated gene transfer of hydroxyurea resistance and amplification of ribonucleotide reductase activity

Metaphase chromosomes purified from a hydroxyurea-resistant Chinese hamster cell line were able to transform recipient wild-type cells to hydroxyurea resistance at a frequency of 10(-6). Approximately 60% of the resulting transformant clones gradually lost hydroxyurea resistance when cultivated for prolonged periods in the absence of drug. One transformant was subjected to serial selection in higher concentrations of hydroxyurea. The five cell lines generated exhibited increasing relative plating efficiency in the presence of the drug and a corresponding elevation in their cellular content of ribonucleotide reductase. The most resistant cell line had a 163-fold increase in relative plating efficiency and a 120-fold increase in enzyme activity when compared with the wild-type cell line. The highly hydroxyurea-resistant cell lines had strong electron paramagnetic resonance signals characteristic of an elevated level of the free radical present in the M2 subunit of ribonucleotide reductase. Two-dimensional electrophoresis of cell-free extracts from one of the resistant cell lines indicated that a 53,000-dalton protein was present in greatly elevated quantities when compared with the wild-type cell line. These data suggest that the hydroxyurea-resistant cell lines may contain an amplification of the gene for the M2 subunit of ribonucleotide reductase.

Isolation and expression of an altered mouse dihydrofolate reductase cDNA

We have constructed a cDNA library from a murine cell line expressing high levels of a dihydrofolate reductase (tetrahydrofolate dehydrogenase; 5,6,7,8-tetrahydrofolate:NADP+ oxidoreductase, EC 1.5.1.3) that displays an abnormally low affinity for methotrexate. From this library we have isolated a cDNA clone similar to, but distinguishable from, a cDNA clone previously demonstrated to encode the wild-type enzyme. Analysis of the nucleotide sequence of this cDNA clone allows us to predict that the altered dihydrofolate reductase differs from the wild-type enzyme at a single amino acid, reflecting the substitution of an arginine for a leucine residue in a region of the polypeptide thought to form a hydrophobic pocket essential for inhibitor binding. To confirm that this substitution was responsible for the altered properties of the enzyme, we genetically localized the region of the cDNA that specified resistance to methotrexate by in vitro recombination. These results reveal that a single nucleotide change in the codon specifying amino acid 22 of the enzyme was sufficient to alter the methotrexate sensitivity of the enzyme. We demonstrate that this altered gene can be employed as a dominant selectable marker in cultured cells expressing normal levels of wild-type dihydrofolate reductase.

Construction and use of a dominant, selectable marker: a Harvey sarcoma virus-dihydrofolate reductase chimera

The transcriptional promoter of the Harvey sarcoma virus long terminal repeat has been used to construct a biologically active dihydrofolate reductase chimera. The construction placed the long terminal repeat at the 5' end of a dihydrofolate reductase cDNA. This chimera mediated methotrexate resistance when introduced into wild-type NIH3T3 mouse cells by transfection. The chimeric sequences were expressed in the form of polyadenylated RNA and dihydrofolate reductase protein and were amplified when the methotrexate-resistant transfectants were selected to grow in increasing methotrexate concentrations. This chimera was dominant acting and able to confer a methotrexate-resistant phenotype on wild-type NIH3T3 cells. It has been used in cotransfection experiments with DNA from human tumor cells to obtain foci of methotrexate-resistant transformed NIH3T3 cells resulting from uptake of exogenous DNA. The transfected methotrexate-resistant cells carried double minute chromosomes that appeared to contain DNA acquired during transfection.

Chromosome-mediated gene transfer with the Chinese hamster ovary cell line

Using an improved method of chromosome-mediated gene transfer, we have investigated transfer of the codominantly expressed methotrexate-resistant dihydrofolate reductase (MtxRIIIdhfr) gene into Chinese hamster ovary (CHO) cell recipients. The frequency of dhfr gene transfer with CHO cells varied considerably from clone to clone, ranging from 4 X 10(-7) to 5 X 10(-5). Using appropriate cell recipients we were able to test for linkage of several genetic markers available in the CHO cell line. For example, the mutation resulting in the auxotrophic glyB-CHO cell line has been reported by others to be linked to the dhfr gene. However, we could not demonstrate cotransfer of these two markers when glyB- recipient cells were treated with MtxRIII chromosomes and transformant clones were selected for either methotrexate-resistance (MtxR) or glycine prototrophy. We conclude that these two genes are not closely linked in the hamster genome. However, the genes for thymidine kinase (tk) and galactokinase (gk), which are known to be linked in mammalian genomes, were found to cotransfer into CHO recipients with a frequency of about 50%.

Construction and use of a dominant, selectable marker: a Harvey sarcoma virus-dihydrofolate reductase chimera

The transcriptional promoter of the Harvey sarcoma virus long terminal repeat has been used to construct a biologically active dihydrofolate reductase chimera. The construction placed the long terminal repeat at the 5' end of a dihydrofolate reductase cDNA. This chimera mediated methotrexate resistance when introduced into wild-type NIH3T3 mouse cells by transfection. The chimeric sequences were expressed in the form of polyadenylated RNA and dihydrofolate reductase protein and were amplified when the methotrexate-resistant transfectants were selected to grow in increasing methotrexate concentrations. This chimera was dominant acting and able to confer a methotrexate-resistant phenotype on wild-type NIH3T3 cells. It has been used in cotransfection experiments with DNA from human tumor cells to obtain foci of methotrexate-resistant transformed NIH3T3 cells resulting from uptake of exogenous DNA. The transfected methotrexate-resistant cells carried double minute chromosomes that appeared to contain DNA acquired during transfection.

High-efficiency transfer of DNA into eukaryotic cells by protoplast fusion

Protoplast fusion is a highly efficient method for effecting gene transfer to cells in culture resulting in stable transformation at high frequency. A number of cell lines have been used successfully as recipients. There is no need to isolate and purify the DNA, which not only saves time and effort but eliminates steps that cause nicking or breaking of large cloned inserts. The high-frequency transformation achievable by protoplast fusion should make this procedure useful for studies on gene expression and for screening cloned genomic libraries for genes that can be expressed in recipient cells.

DNA-mediated gene transfer in Chinese hamster ovary cells: clonal variation in transfer efficiency

Thymidine kinase-deficient Chinese hamster ovary (CHO) cells were genetically transformed with the BamHI restriction fragment encoding the thymidine kinase gene of herpes simplex virus (HSV-tk). We have observed considerable clonal variation among independent CHO sublines with respect to transformation competence for the DNA-mediated gene transfer of HSV-tk. Transformation frequencies greater than or equal to 3 X 10(-4) were observed consistently in one subline, with a transformation efficiency of approximately 1 transformant per ng viral gene. The frequency and efficiency of transformation we observed in this system are at least 10-fold greater than those previously reported for DNA-mediated transformation of CHO cells by HSV-tk. All of the CHO HSV-tk+ transformants examined were stable for the transferred genotype in the absence of selection, and all showed evidence of co-transformation by unselected plasmid pBR322 sequences.

Isolation of a genomic clone partially encoding human hypoxanthine phosphoribosyltransferase

Mouse cells deficient in the enzyme hypoxanthine phosphoribosyltransferase (HPRT; EC 2.4.2.8) have been transfected with total human DNA, and cells producing human enzyme were isolated by growth in selective medium. DNA from several such cell lines has been used to generate secondary transfectants that make human HPRT. Blots of the DNA of these secondary cells have been hybridized with total human DNA probes or with cloned human Alu sequences, and one of several common bands has been cloned in pBR322. Colonies of transformed Escherichia coli containing human sequences were detected by their homology with human DNA, and subclones of resulting recombinant plasmids were prepared. Two subclones free of Alu sequences were found to contain human sequences that hybridized to human X chromosome DNA. One of these, pBR1.5, also hybridized to a single RNA band on gel blots of human and secondary transfectant cytoplasmic poly(A)+RNA but not to RNA from the parent mouse cell line. These results indicate that these clones represent human HPRT gene fragments. This has been confirmed by using pBR1.5 as a probe to isolate an authentic and expressible human HPRT cDNA clone from a library prepared by H. Okayama and P. Berg.

Transfer of genes to Chinese hamster ovary cells by DNA-mediated transformation

We have transferred DNa to Chinese hamster ovary (CHO) cells by DNA-mediated transformation. CHO tk- cells were transformed with the clones gene for herpes simplex virus thymidine kinase (HSV-tk) and were found to have a 50-fold lower frequency of transformation than mouse Ltk- cells at the same DNA dosage. By altering the amount of tk gene and carrier DNA present, frequencies of up to 5 x 10(-5) were obtained. CHO HSV-tk+ transformants were very stable, and in several clones the HSV-tk gene copies integrated in higher-molecular-weight DNA. These cells also exhibited cotransformation for unselected markers. CHO lines were also transformed at a frequency of 10(-4) with the bacterial gene Ecogpt in a SV40-pBR322 vector. CHO tk-cells could be transformed at a frequency of 10(-7) with cellular DNA isolated from CHO tk+ cells. CHO cells offer a well-defined genetic system within which to transfer either cloned or whole cellular DNAs.

Microinjection of a rabbit beta-globin gene into zygotes and its subsequent expression in adult mice and their offspring

We have transferred a gene coding for rabbit beta-globin into the male pronucleus of mouse zygotes by direct microinjection. Some of these zygotes developed into mature mice which contained this gene and appeared to be producing a rabbit globin. Evidence for the presence of the gene in these animals was provided by Southern blot hybridization analysis. Evidence for the expression of the rabbit gene in these transformed mice and their offspring was provided by hemoglobin isoelectric focusing analysis and specific serological reactivity between mouse anti-rabbit hemoglobin antiserum and a hemolysate from the mice that developed from the microinjected zygotes. The use of this zygote transformation may allow the introduction and expression of a broad range of genetic elements in mammals.

DNA-mediated gene transfer without carrier DNA

DNA-mediated gene transfer is a procedure which uses purified DNA to introduce new genetic elements into cells in culture. The standard DNA-mediated gene transfer procedure involves the use of whole cell DNA as carrier DNA for the transfer. We have modified the standard DNA-mediated gene transfer procedure to transfer the Herpes simplex virus type 1 thymidine kinase gene (TK) into TK- murine recipient cells in the absence of whole cell carrier DNA. The majority (8/10) of carrier-free transformant lines expressed the TK+ phenotype stably, in sharp contrast to our results with carrier-containing DNA-mediated gene transfer. There was a wide range in donor DNA content among independent transformants. Further analysis on one transformant line using DNA restriction digests and in situ hybridization provided evidence that, in the absence of whole cell carrier DNA, multiple donor DNA sequences became integrated at a single chromosomal site.

Competence for DNA transfer of ouabain resistance and thymidine kinase: clonal variation in mouse L-cell recipients

We have used the calcium phosphate precipitation technique to study the competence of mammalian cell recipients for transformation with genomic mammalian cell DNA. The transformation efficiency for thymidine kinase (tk) varies 10- to 20-fold (up to 10(-4) transformants/recipient) among different subclones of the LM tk- CL 1D mouse fibroblast cell line. Analysis of this phenotype among second-generation subclones indicates that subclones exhibiting high competence tend to breed true, whereas those with low competence do not. Isolation of Tk- revertants from TK+ transformants results in the selection of cells with a high-competence phenotype as measured by their subsequent transformation for tk. This phenotype appears to be a general characteristic of such cells because recipients more competent for transfer of a second marker, ouabain resistance (ouaR). This codominant marker coding for the Na K+-ATPase can be transferred at frequencies of 10(-5) in the high-competence recipients. These results indicate that competence for DNA-mediated gene transfer can be determined in part by genetic factors.

DNA-mediated gene transfer of beta-aspartylhydroxamate resistance into Chinese hamster ovary cells

Cell lines that have high levels of resistance to beta-aspartylhydroxamate and elevated levels of asparagine synthetase activity were selected in two steps from Chinese hamster ovary cells. Resistance to beta-aspartylhydroxmate was transferred into sensitive cells by using total genomic DNA derived from the dominant two-step mutants. The surviving colonies were characterized as transferants on the basis of transfer frequency, degree of resistance to beta-aspartylhydroxamate, increased level of asparagine synthetase activity, expression of the donor form of asparagine synthetase, codominance in hybrids, and instability of the phenotype in the absence of selection.

Enhancing the efficiency of DNA-mediated gene transfer in mammalian cells

We have investigated several of the experimental factors that affect calcium phosphate-DNA-mediated gene transfer of thymidine kinase (tk) into mouse LM tk- Cl 1D cells using unfractionated DNA from both Chinese hamster ovary cells and L6 rat myoblasts. Increases in the length of exposure to DNA (24 h) and the expression time (48 h) before selection result in a 20-fold enhancement in the efficiency of transformation. These modifications yield frequencies up to 35 HATR colonies/20 microgram tk"NA/10(6) recipient cells. Exposure to dimethyl sulfoxide enhances transformation efficiencies slightly for short DNA exposure times, but has no effect when optimal DNA exposure times are used. Several other variations in our standard transformation protocol were also examined: these include the concentration and size of the DNA and exposure to low concentrations of the nonionic detergent, Tween-80. We have also isolated and characterized a subclone of Cl 1D that is a high-efficiency recipient for the tk+ marker. Segregation analysis reveals that the majority of the TK+ transformants derived from this subclone are stable, in contrast to those derived from the DL 1D parent. The combination of improved methodology and the high-efficiency recipient subclone permits DNA-mediated transformation for tk at frequencies on the order of 10(-4) transformants per recipient cell.

Three different human tumor cell lines contain different oncogenes

We have obtained foci of transformed mouse cells after transfection of human DNA from colon and bladder carcinoma cell lines and a promyelocytic leukemia cell line. These foci can be shown to contain a large number of human DNA sequences by use of highly repetitive human DNA sequence probes. Cell DNA from primary foci can be used in a subsequent cycle of transfection resulting in secondary foci that contain relatively little human DNA. Secondary foci appear to contain only the human sequences proximal to those responsible for the transformed phenotype. A set of characteristic DNA restriction fragments is found in common among secondary foci derived from each tumor cell line DNA. Comparison of the common DNA fragments found in secondary foci derived from three different human tumor cell lines indicates that these three cell lines contain three different transforming genes.

High-frequency transfer of cloned herpes simplex virus type 1 sequences to mammalian cells by protoplast fusion

The protoplast fusion technique of Schaffner (W. Schaffner, Proc. Natl. Acad. Sci. U.S.A. 77:2163-2167, 1980) has been adapted to introduce cloned herpes simplex virus genes into cultured mammalian cells. The technique involves digesting bacterial cell walls with lysozyme to produce protoplasts and then fusing the protoplasts to mammalian cells by treatment with polyethylene glycol. For monitoring transfer, protoplasts were labeled with the fluorescent dye fluorescein isothiocyanate before fusion. After fusion, greater than 50% of the mammalian cells were fluorescent, demonstrating that bacterial material was transferred with high frequency. Transfer of plasmid pBR325 occurred at frequencies of 1 to 2%, as measured by in situ hybridization. Fusion transfer of a chimeric plasmid consisting of the herpes simplex virus type 1 (strain KOS) EcoRI fragment F in pBR325 resulted in expression of some viral genomic sequences in about 5% of the mammalian cells, as detected by indirect immunofluorescence. One Ltk- cell in 300 to 500 was transformed to the TK+ phenotype after fusion with protoplasts carrying the chimeric plasmid pX1, which consists of pBR322 and the BamHI fragment coding for the herpes simplex virus type 1 thymidine kinase gene.

Fluctuation analyses of spontaneous mutations to 6-thioguanine resistance in Chinese hamster ovary cells in culture

Fluctuation analyses of the spontaneous appearance of 6-thioguanine (TG)-resistant mutants in cultured Chinese hamster ovary (CHO) cells were performed to investigate (1) whether the resistance is induced by the selective agent or is the result of a mutation which occurs prior to the TG selection and (2) to estimate the spontaneous mutation rate at the hypoxanthine--guanine phosphoribosyl transferase (hgprt) locus. The potential problem of phenotypic delay was minimized by allowing an adequate expression time through maintenance of the cultures in a division-arrested, viable state. The results demonstrate that the TG-resistant (TGr) cells arise randomly in the cultures, independently of the selective agent, which is consistent with spontaneous mutations. The average values for mutation rate +/- standard deviation, based on 4 independent determinations and 2 methods of calculation, are 3.4 +/- 1.2 X 10(-7) (median method) and 5.1 +/- 1.8 X 10(-7) (mean method) mutants/cell/generation.

Mechanisms and applications of DNA-mediated gene transfer in mammalian cells - a review

The ability of mammalian cells to take up exogenously added DNA and to express genes included on that DNA has been well documented. DNA-mediated gene transfer (DMGT) potentially is a useful technique for the elucidation of many of the factors that control gene expression, and for the purification and isolation of mammalian genes. Before many of the benefits can be realized, however, a more detailed understanding of the organization, intracellular location, and expression of transferred genes will be needed. Recent studies have begun to characterize the DMGT process. Selected genes become linked to other exogenously added DNA during or subsequent to transfer and persist in the nuclei of recipient cells as part of large molecules called transgenomes. Transgenomes initially are maintained unstably and are lost from the population with first order kinetics. After a variable number of generations in culture, subpopulations arise that maintain the transferred genes stably. In these "stable" cells the transgenome is associated with a recipient cell chromosome, although the particular chromosome differs in independent "stable" lines. Mixture of an excess of specific nonselectable genes with the selected gene prior to transfer results in the inclusion of the nonselected genes in the transgenomes present in most cells that survive selection. This finding demonstrates the feasibility of introducing virtually any purified gene into mammalian cells. Recently microinjection of DNA directly into the nuclei of cells has been demonstrated. This technique greatly increases the frequency of gene transfer and significantly expands the number of cell types that can be genetically transformed.

Cell fusion-induced mouse neuroblastomas HPRT revertants with variant enzyme and elevated HPRT protein levels

Fusion of 6-thioguanine-resistant mouse neuroblastoma to HeLa whole and minicells generated neuroblastoma HPRT revertants in addition to true cell hybrids. All revertants contained HPRT with decreased electrophoretic mobility and heat stability relative to wild-type mouse enzyme. Revertant HPRT expression was dependent on continuous HAT selection. Quantitative immunoadsorption experiments showed that revertants with low HPRT specific activity had wild-type levels of HPRT protein while a revertant with high apparent activity (NBR4) contained elevated levels of variant protein. HPRT extracted from NBR4 had decreased affinity of both hypoxanthine and PRPP relative to wild type. Evidence is presented that HPRT elevation is dependent on the reversion process itself.