The cloning and reintroduction into animal cells of a functional CAD gene, a dominant amplifiable genetic marker

A unique role of the DNA fragmentation factor in maintaining genomic stability

DNA fragmentation is a hallmark of apoptosis (programmed cell death). However, the biological function of apoptotic DNA fragmentation remains unclear. Here, we show that DNA fragmentation factor plays an important role for maintaining genomic stability. Inhibition or loss of the DNA fragmentation factor (DFF)/caspase-activated DNase (CAD), whose nuclease activity is responsible for digesting genomic DNA during apoptosis, led to significant increases in spontaneous or induced gene mutations, gene amplifications, and chromosomal instability in primary mouse cells and transformed human cell lines. The mechanism underlying genetic instability in DFF/CAD-deficient cells, at least in part, involves a small but significant elevation in the survival of cells exposed to ionizing radiation, suggesting that apoptotic DNA fragmentation factor contributes to genomic stability by ensuring the removal of cells that have suffered DNA damage. In support of this hypothesis are the observations of increased cellular transformation of mouse embryonic cells from the DFF/CAD-null mice and significantly enhanced susceptibility to radiation-induced carcinogenesis in these mice. These data, in combination with published reports on the existence of tumor-specific gene mutations/deletions in the DFF/CAD genes in human cancer samples, suggest that apoptotic DNA fragmentation factor is required for the maintenance of genetic stability and may play a role in tumor suppression.

Overview of protein expression by mammalian cells

This unit reviews the stages involved in protein production in mammalian cells using a stable-expression approach. Choice of cell type is discussed, as is transfection of the host cells, methods for selection and amplification of transformants, and growth of cells at appropriate scale for protein production. Since post-transcriptional modification and intracellular protein transportation are important features of recombinant-protein production in mammalian cells, some description of these mechanisms is included.

Identification of an origin of bidirectional DNA replication in the ubiquitously expressed mammalian CAD gene

Most DNA replication origins in eukaryotes localize to nontranscribed regions, and there are no reports of origins within constitutively expressed genes. This observation has led to the proposal that there may be an incompatibility between origin function and location within a ubiquitously expressed gene. The biochemical and functional evidence presented here demonstrates that an origin of bidirectional replication (OBR) resides within the constitutively expressed housekeeping gene CAD, which encodes the first three reactions of de novo uridine biosynthesis (carbamoyl-phosphate synthetase, aspartate carbamoyltransferase, and dihydroorotase). The OBR was localized to a 5-kb region near the center of the Syrian hamster CAD transcriptional unit. DNA replication initiates within this region in the single-copy CAD gene in Syrian baby hamster kidney cells and in the large chromosomal amplicons that were generated after selection with N-phosphonacetyl-L-aspartate, a specific inhibitor of CAD. DNA synthesis also initiates within this OBR in autonomously replicating extrachromosomal amplicons (CAD episomes) located in an N-phosphonacetyl-L-aspartate-resistant clone (5P20) of CHOK1 cells. CAD episomes consist entirely of a multimer of Syrian hamster CAD cosmid sequences (cCAD1). These data limit the functional unit of replication initiation and timing control to the 42 kb of Syrian hamster sequences contained in cCAD1. In addition, the data indicate that the origin recognition machinery is conserved across species, since the same OBR region functions in both Syrian and Chinese hamster cells. Importantly, while cCAD1 exhibits characteristics of a complete replicon, we have not detected autonomous replication directly following transfection. Since the CAD episome was generated after excision of chromosomally integrated transfected cCAD1 sequences, we propose that prior localization within a chromosome may be necessary to "license" some biochemically defined OBRs to render them functional.

Threonine synthesis from homoserine as a selectable marker in mammalian cells

The plasmid pSVthrBC expresses the Escherichia coli thrB (homoserine kinase) and thrC (threonine synthase) genes in mouse cells and enables them to synthesize threonine from homoserine. After transfection with pSVthrBC and culture in medium containing homoserine, only cells that have incorporated pSVthrBC survive. Homoserine at concentrations greater than 1 mM is toxic to mammalian cells. Mouse cells selected from medium containing 5 mM homoserine had incorporated 20-100 copies of the plasmid per cell and had homoserine kinase activities of 0.001-0.012 nmol/min per mg of protein per copy. Cells selected from medium containing 10 mM homoserine had incorporated one or two copies of the plasmid per cell and had homoserine kinase activities of 0.06-0.39 nmol/min per mg of protein per copy. By using high concentrations of homoserine, it is possible to use pSVthrBC to select and isolate cell lines that have one or two copies of the plasmid incorporated into an active region of chromatin. CHO and HeLa cells have also been successfully transfected with pSVthrBC. COS-7 cells are naturally resistant to homoserine as they are able to metabolize homoserine.

Regional mapping of the gene encoding dihydroorotate dehydrogenase, an enzyme involved in UMP synthesis, electron transport, and superoxide generation, to human chromosome region 16q22

De novo UMP synthesis is a critical metabolic pathway for nucleic acid synthesis and for a variety of metabolic pathways. The pathway is a target for many widely used cancer chemotherapy agents, several of which are pyrimidine analogs. Humans and cattle have been described with mutations in UMP synthesis that lead to serious inborn errors of metabolism. Dihydroorotate dehydrogenase (EC 1.3.3.1) (DHODH) carries out the fourth committed step in the pathway and may also be important for mitochondrial electron transport and oxygen radical metabolism. We report here that the gene encoding this enzyme in humans is located in the chromosomal region 16q22. With the mapping of DHODH, the mapping of all the steps of UMP synthesis is complete. All three genes involved map to different human chromosomes. This information is important in consideration of regulation of UMP synthesis in mammals, including humans.

Recombination between separate MYC amplification structures in COLO320 cells

Cytogenetically visible gene amplification structures can consist of arrays of amplicons presumably formed by secondary "rearrangements" following amplicon formation. The structural evolution of gene amplification sites in tumor cells suggests that complex secondary structures may have some selective advantage in the tumor cell environment. Although secondary amplicon rearrangements are a hallmark of the gene amplification process, little is known about the mechanics of this process. COLO320 neuroendocrine tumor cells carry two different types of amplified MYC oncogene sequences, one type with an intact MYC gene and the other with a rearranged "chimeric" MYC gene. We have studied various clonal subpopulations of COLO320 cells and identified regions within and downstream of the MYC locus that are unique to each amplicon type. Using double-label fluorescence in situ hybridization with DNA probes unique to each amplicon type, we have observed that both chromosomal and extrachromosomal MYC amplicon arrays in COLO320 cells frequently consist of heterogeneous mixtures of each MYC amplicon type. Our results suggest that the two MYC amplicon types of COLO320 cells were formed simultaneously but independently, and that double minute chromosomes observed in COLO320 cells were formed by intermolecular homologous recombination secondary to amplicon formation.

Complete hamster CAD protein and the carbamylphosphate synthetase domain of CAD complement mammalian cell mutants defective in de novo pyrimidine biosynthesis

The mammalian CAD gene codes for a 240-kDa multifunctional protein that catalyzes the first three steps of de novo pyrimidine biosynthesis. Previously, the longest cDNA construct available was missing approximately 500 bp of coding sequence at the 5' end, thereby lacking the sequence to encode the entire carbamylphosphate synthetase (CPSase) domain. Here, a complete CAD hamster cDNA is constructed, placed into a mammalian expression vector, and transfected into hamster cells deficient in CAD. Transfectants show coordinately restored levels of all three enzyme activities and the presence of full-length CAD protein. A derivative construct of the CAD cDNA was generated that should encode only the CPSase domain. When transfected into mammalian cells, a protein was synthesized that had significant CPSase activity both in vivo and in vitro. The two constructs generated in this study will facilitate the study of CAD structure, function, and allosteric regulation.

Replication footprint analysis of cucumber mosaic virus electroporated into tomato protoplasts

Total RNA extracted from cucumber mosaic virus (CMV) strains WT, with its associated satellite CARNA 5 (CMV-associated RNA 5), was successfully electroporated into isolated tomato protoplasts. At various time intervals samples were extracted for total nucleic acids and analyzed by semidenaturing polyacrylamide gel electrophoresis (PAGE). Sequence-specific hybridization probes were used for the detection of viral and satellite RNAs following Northern transfer. The resulting PAGE patterns and/or autoradiographs depict the proportional presence of viral and satellite RNAs in the extracts over time and have been referred to as "replication footprint profiles" (RFPs) of specific CMV/CARNA 5 combinations. The effective isolation and infection of tomato protoplasts, combined with the ability to follow virus/satellite titers during the infection by RFP analysis, yield results similar to those of infected plants and reduces experiments of 21 or more days in whole plants to less than 72 h in protoplasts.

Positive selectable markers for use with mammalian cells in culture

As more complicated gene expression studies are necessary, the need for multiple positive selection schemes becomes critical. Numerous selectable markers have been described over the last 25 years. A hallmark of the most generally useful markers is easy selection in a wide number of cell types. This paper briefly reviews the spectrum of available selectable markers and describes some of the applications that have been found for these genes, particularly with respect to retrovirus-mediated gene transfer.

Replication timing control can be maintained in extrachromosomally amplified genes

Extrachromosomal elements are common early intermediates of gene amplification in vivo and in cell culture. The time at which several extrachromosomal elements replicate was compared with that of the corresponding amplified or unamplified chromosomal sequences. The replication timing analysis employed a retroactive synchrony method in which fluorescence-activated cell sorting was used to obtain cells at different stages of the cell cycle. Extrachromosomally amplified Syrian hamster CAD genes (CAD is an acronym for the single gene which encodes the trifunctional protein which catalyzes the first three steps of uridine biosynthesis) replicated in a narrow window of early S-phase which was approximately the same as that of chromosomally amplified CAD genes. Similarly, extrachromosomally amplified mouse adenosine deaminase genes replicated at a discrete time in early S-phase which approximated the replication time of the unamplified adenosine deaminase gene. In contrast, the multicopy extrachromosomal Epstein-Barr virus genome replicated within a narrow window in late S-phase in latently infected human Rajii cells. The data indicate that localization within a chromosome is not required for the maintenance of replication timing control.

Replication timing control can be maintained in extrachromosomally amplified genes

Extrachromosomal elements are common early intermediates of gene amplification in vivo and in cell culture. The time at which several extrachromosomal elements replicate was compared with that of the corresponding amplified or unamplified chromosomal sequences. The replication timing analysis employed a retroactive synchrony method in which fluorescence-activated cell sorting was used to obtain cells at different stages of the cell cycle. Extrachromosomally amplified Syrian hamster CAD genes (CAD is an acronym for the single gene which encodes the trifunctional protein which catalyzes the first three steps of uridine biosynthesis) replicated in a narrow window of early S-phase which was approximately the same as that of chromosomally amplified CAD genes. Similarly, extrachromosomally amplified mouse adenosine deaminase genes replicated at a discrete time in early S-phase which approximated the replication time of the unamplified adenosine deaminase gene. In contrast, the multicopy extrachromosomal Epstein-Barr virus genome replicated within a narrow window in late S-phase in latently infected human Rajii cells. The data indicate that localization within a chromosome is not required for the maintenance of replication timing control.

An unusual Alu repeat sequence within the CAD gene

There are several hundred thousand members of the Alu repeat family in the human genome. Those Alu elements sequenced to date appear to fit into subfamilies. A novel Alu has been found in an intron of the human CAD gene: it appears to be due to rearrangement between Alu repeats belonging to two different subfamilies. Further sequence data from this intron suggest that the Alu element may have rearranged prior to its entry into the CAD gene. Such findings indicate that, in addition to single nucleotide substitutions and deletions, DNA rearrangements may be a factor in generating the diversity of Alu repeats found in primate genomes.

High Level Expression of Tissue Inhibitor of Metalloproteinases in Chinese Hamster Ovary Cells Using Glutamine Synthetase Gene Amplification

We have used a glutamine synthetase (GS) gene as an amplifiable marker in Chinese hamster ovary (CHO) cells. GS was combined with an efficient transcription unit to produce tissue inhibitor of metalloproteinases (TIMP). Initial transfectant cell-lines selected using a GS gene secreted up to 9 micrograms TIMP/10(6) cells/24h. After one round of GS gene amplification expression levels of 110 micrograms TIMP/10(6) cells/24h were achieved. These GS gene amplified CHO cells, when adapted to grow in suspension, accumulated 180mg/l in shake flask culture. This system therefore provides a rapid method of achieving high level gene expression in mammalian cells.

DNA transfection of mouse lymphoid cells by the combination of DEAE-dextran-mediated DNA uptake and osmotic shock procedure

Several mouse lymphoid cell lines were efficiently transfected with plasmid DNA by a novel method combining DEAE-dextran-mediated DNA uptake and osmotic shock procedure. The cells were first incubated with DNA-DEAE-dextran complex, treated with hypertonic Tris-HCl buffer containing 0.5 M sucrose and 10% poly(ethylene glycol), and then exposed to hypotonic RPMI 1640 medium. This transfection protocol exhibited maximal frequencies of 0.3% and 3.10(-5) for transient gene expression and stable transformation in P3-NSI/1-Ag4-1 cells, respectively.

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 dihydrofolate reductase amplicons in different methotrexate-resistant Chinese hamster cell lines share at least a 273-kilobase core sequence, but the amplicons in some cell lines are much larger and are remarkably uniform in structure

We have previously cloned and characterized two different dihydrofolate reductase amplicon types from a methotrexate-resistant Chinese hamster ovary cell line (CHOC 400). The largest of these (the type I amplicon) is 273 kilobases (kb) in length. In the present study, we utilized clones from the type I amplicon as probes to analyze the size and variability of the amplified DNA sequences in five other independently isolated methotrexate-resistant Chinese hamster cell lines. Our data indicated that the predominant amplicon types in all but one of these cell lines are larger than the 273-kb type I sequence. In-gel renaturation experiments as well as hybridization analysis of large SfiI fragments separated by pulse-field gradient gel electrophoresis showed that two highly resistant cell lines (A3 and MK42) have amplified very homogeneous core sequences that are estimated to be at least 583 and 653 kb in length, respectively. Thus, the sizes of the major amplicon types can be different in different drug-resistant Chinese hamster cell lines. However, there appears to be less heterogeneity in size and sequence arrangement within a given methotrexate-resistant Chinese hamster cell line than has been reported for several other examples of DNA sequence amplification in mammalian systems.

Autonomously replicating episomes contain mdr1 genes in a multidrug-resistant human cell line

Gene amplification in human tumor cells is frequently mediated by extrachromosomal elements (e.g., double minute chromosomes [DMs]). Recent experiments have shown that DMs can be formed from smaller, submicroscopic circular precursors referred to as episomes (S. M. Carroll, M. L. DeRose, P. Gaudray, C. M. Moore, D. R. Needham-Vandevanter, D. D. Von Hoff and G. M. Wahl, Mol. Biol. 8:1525-1533, 1988). To investigate whether episomes are generally involved as intermediates in gene amplification, we determined whether they mediate the amplification of the mdr1 gene, which when overexpressed engenders cross resistance to multiple lipophilic drugs. A variety of methods including electrophoresis of undigested DNAs in high-voltage gradients, NotI digestion, and production of double-strand breaks by gamma irradiation were used to distinguish between mdr1 sequences amplified on submicroscopic circular molecules and those amplified within DMs or chromosomal DNA. The gamma-irradiation procedure provides a new method for detecting and determining the size of circular molecules from 50 kilobases (kb) to greater than 1,000 kb. These methods revealed that some of the amplified mdr1 genes in vinblastine-resistant KB-V1 cells are contained in supercoiled circular molecules of approximately 600 and approximately 750 kb. Analysis of the replication of these molecules by a Meselson-Stahl density shift experiment demonstrated that they replicate approximately once in a cell cycle. The data lend further support to a model for gene amplification in which DMs are generally formed from smaller, autonomously replicating precursors.

Autonomously replicating episomes contain mdr1 genes in a multidrug-resistant human cell line

Gene amplification in human tumor cells is frequently mediated by extrachromosomal elements (e.g., double minute chromosomes [DMs]). Recent experiments have shown that DMs can be formed from smaller, submicroscopic circular precursors referred to as episomes (S. M. Carroll, M. L. DeRose, P. Gaudray, C. M. Moore, D. R. Needham-Vandevanter, D. D. Von Hoff and G. M. Wahl, Mol. Biol. 8:1525-1533, 1988). To investigate whether episomes are generally involved as intermediates in gene amplification, we determined whether they mediate the amplification of the mdr1 gene, which when overexpressed engenders cross resistance to multiple lipophilic drugs. A variety of methods including electrophoresis of undigested DNAs in high-voltage gradients, NotI digestion, and production of double-strand breaks by gamma irradiation were used to distinguish between mdr1 sequences amplified on submicroscopic circular molecules and those amplified within DMs or chromosomal DNA. The gamma-irradiation procedure provides a new method for detecting and determining the size of circular molecules from 50 kilobases (kb) to greater than 1,000 kb. These methods revealed that some of the amplified mdr1 genes in vinblastine-resistant KB-V1 cells are contained in supercoiled circular molecules of approximately 600 and approximately 750 kb. Analysis of the replication of these molecules by a Meselson-Stahl density shift experiment demonstrated that they replicate approximately once in a cell cycle. The data lend further support to a model for gene amplification in which DMs are generally formed from smaller, autonomously replicating precursors.

Efficient simplified cosmid cloning: construction and characterization of cosmid vectors that carry the two cohesive end sites of lambda phages arrayed in tandem

We constructed a series of cosmid vectors that carry the two cohesive end sites (cos) of lambda phage, arrayed in tandem, which enabled us to clone fragments of genomic DNA of up to 50 kb without a vector background. An equimolar mixture of the left and right vector arms of equal length was prepared from the vector DNA, simply by treating the DNA sequentially with three enzymes, restriction enzyme PvuII, alkaline phosphatase, and restriction enzyme BamHI (or BglII), without purification by agarose gel electrophoresis. After phenol extraction and ethanol precipitation, the equimolar mixture of the vector arms, which carried a single cos oriented from left to right, was directly ligated with insert DNA without further manipulation. We established conditions for cosmid cloning, using two kinds of DNA fragment of 40-50 kb, prepared from mouse L cell genomic DNA, as insert DNAs, namely, three cloned BamHI fragments and Sau3AI fragments, size-selected on a sucrose density gradient. The most important parameters affecting the cloning efficiency were the quality of the insert DNA and the molar ratio of the insert and vector arms. We achieved cloning efficiencies of 3.6 X 10(6)-1.3 X 10(7) colony forming units (cfu)/micrograms of insert DNA and 1.7 X 10(5)-1.0 X 10(6) cfu/micrograms of insert DNA, using the cloned BamHI fragments and the Sau3AI fragments, respectively. We examined more than 5000 clones and found that they all contained insert DNA.

The dihydrofolate reductase amplicons in different methotrexate-resistant Chinese hamster cell lines share at least a 273-kilobase core sequence, but the amplicons in some cell lines are much larger and are remarkably uniform in structure

We have previously cloned and characterized two different dihydrofolate reductase amplicon types from a methotrexate-resistant Chinese hamster ovary cell line (CHOC 400). The largest of these (the type I amplicon) is 273 kilobases (kb) in length. In the present study, we utilized clones from the type I amplicon as probes to analyze the size and variability of the amplified DNA sequences in five other independently isolated methotrexate-resistant Chinese hamster cell lines. Our data indicated that the predominant amplicon types in all but one of these cell lines are larger than the 273-kb type I sequence. In-gel renaturation experiments as well as hybridization analysis of large SfiI fragments separated by pulse-field gradient gel electrophoresis showed that two highly resistant cell lines (A3 and MK42) have amplified very homogeneous core sequences that are estimated to be at least 583 and 653 kb in length, respectively. Thus, the sizes of the major amplicon types can be different in different drug-resistant Chinese hamster cell lines. However, there appears to be less heterogeneity in size and sequence arrangement within a given methotrexate-resistant Chinese hamster cell line than has been reported for several other examples of DNA sequence amplification in mammalian systems.

An improved method of electroporation for introducing biologically active foreign genes into cultured mammalian cells

We have developed a modified, reproducible, and efficient method for introducing cloned genes into mammalian cells by using an electric field followed by treatment with sodium butyrate. Transfection frequencies with plasmid pSV2-neo, consisting of an antibiotic (G418) resistance gene and simian virus 40 (SV40) early promoter, by electroporation were higher than those by calcium phosphate DNA precipitation. Treatment with sodium butyrate following electroporation significantly increased the frequency of transfection in various types of cell lines and primary cultured cells including human skin fibroblasts. Treatment with sodium butyrate also increased the transient expression of the gene for chloramphenicol acetyltransferase (acetyl-CoA; chloramphenicol O3-acetyltransferase, CAT, EC 2.3.1.28) when the gene was introduced into BALB/c 3T3 cells by electroporation. Electroporation combined with sodium butyrate treatment is an improved method for stable and transient biochemical transformation of foreign genes in cultured mammalian cells.

Escherichia coli Spheroplast-Mediated Transfer of pBR322 Carrying the Cloned Ruminococcus albus Cellulase Gene into Anaerobic Mutant Strain FEM29 by Protoplast Fusion

Intergeneric protoplast fusion between Escherichia coli HB101 with pBR322 carrying the cloned o -(carboxymethyl)cellulase (CMCase) gene of Ruminococcus albus (Pro - Leu - Ap r Km s ) and an anaerobic mutant strain, FEM29 (Trp - His - Ap s Km r ), with dehydrodivanillin-degrading activity was performed in the presence of 40% polyvinyl alcohol 300 under aerobic and anaerobic conditions to transfer the cloned cellulase gene into the mutant. The mutant FEM29 had a unique property. When it was incubated in liquid medium with 1% glucose and sucrose, protoplasts could be produced autogenously and regenerated on the agar slant. E. coli spheroplasts formed from a plasmid-amplified overnight culture after 10 min of treatment with lysozyme (20 μg/ml) in a hypertonic solution (0.01 M Tris hydrochloride [pH 7.5], 0.4 M mannitol). Protoplast regeneration rates of FEM29 and HB101 were 30 and 83%, respectively, on the agar-yeast extract medium. Ap r Km r fusants were obtained at high frequency: 1.7 × 10 −2 anaerobically and 8.2 × 10 −3 aerobically. These fusants showed 23 to 57% of CMCase and dehydrodivanillin-degrading activities, respectively, as compared with parental strains. All the fusants isolated were gram-negative rods with main phenotypes such as urease and catalase activities as in HB101 and esterase and chymotrypsin activities as in FEM29. Southern hybridization experiments suggested that pBR322 with the cloned CMCase gene existed autonomously in the fusant cells. This is the first report describing transfer of pBR322 with a cloned cellulase gene into an anaerobic mutant by polyvinyl alcohol-mediated fusion with an E. coli spheroplast.

Double minute chromosomes can be produced from precursors derived from a chromosomal deletion

Recent experiments have shown that gene amplification can be mediated by submicroscopic, autonomously replicating, circular extrachromosomal molecules. We refer to those molecules as episomes (S. Carroll, P. Gaudray, M. L. DeRose, J. F. Emery, J. L. Meinkoth, E. Nakkim, M. Subler, D. D. Von Hoff, and G. M. Wahl, Mol. Cell. Biol. 7:1740-1750, 1987). The experiments reported in this paper explore the way episomes are formed and their fate in the cell over time. The data reveal that in our system the episomes are initially 250 kilobases, but gradually enlarge until they become double minute chromosomes. In addition, we show that episomes or double minute chromosomes can integrate into chromosomes. Our results also suggest that episomes can be produced by deletion of the corresponding sequences from the chromosome.

Amplified human MYC oncogenes localized to replicating submicroscopic circular DNA molecules

Amplification of genes can sometimes be detected by molecular hybridization but not by cytogenetic methods, suggesting that in some cases the units of amplification may be too small to be detected by light microscopy. The experiments reported here investigate whether submicroscopic amplification units are present in early passages of the human tumor cell lines HL-60 and COLO 320. The results show that such cells do contain submicroscopic, extrachromosomal, supercoiled circular molecules harboring MYC genes. The molecules in HL-60 are approximately 250 kilobase pairs (kbp), while those in COLO 320 are 120-160 kbp. The extrachromosomal molecules in HL-60 are shown to replicate semiconservatively and approximately once in one cell cycle. We propose that these submicroscopic elements are precursors of double-minute chromosomes, the usual extrachromosomal manifestation of gene amplification, since both are structurally similar and replicate autonomously.

Chromosome aberrations associated with CAD gene amplification in Chinese hamster cultured cells

Eleven sublines with increasing resistance to N-phosphonacetyl-L-aspartate (PALA) were isolated from the V79,B7 Chinese hamster cell line. Aspartate transcarbamylase activity and CAD gene copy number increased with increasing resistance of sublines. In situ hybridization with a DNA probe for the CAD gene showed that the amplified sequences resided in the terminal region of a marker chromosome with elongated q arms. This region stained homogeneously after G-banding. A high incidence of both numerical and structural chromosome aberrations was found in PALA-resistant cells. In hyperdiploid and polyploid cells, containing 2 copies of the marker chromosome, dicentrics were found at a very high frequency. As indicated by in situ hybridization and G-banding, they originated from a rearrangement involving 2 homologous marker chromosomes.

Phleomycin resistance as a dominant selectable marker in CHO cells

The Tn5 and the Streptoalloteichus hindustanus (Sh) ble genes conferring resistance to bleomycin-phleomycin antibiotics have been cloned into a mammalian vector under the RSV-LTR promoter. The resulting plasmids, pUT506 and pUT507 respectively, were used to transfect CHO cells by either the calcium phosphate or the recently described polybrene-DMSO method. Phleomycin- or bleomycin-resistant clones arose with a higher frequency after transfection with pUT507, and pUT507 transfectants were more resistant to both antibiotics than pUT506 transfectants. Phleomycin resistance in pUT507 transfectants was stable and associated with integration of plasmid sequences in genomic DNA. The Sh ble gene, which confers a dominant phleomycin-resistance phenotype, should provide a useful transferable selectable marker in CHO cells as well as in other animal cell lines.

Double minute chromosomes can be produced from precursors derived from a chromosomal deletion

Recent experiments have shown that gene amplification can be mediated by submicroscopic, autonomously replicating, circular extrachromosomal molecules. We refer to those molecules as episomes (S. Carroll, P. Gaudray, M. L. DeRose, J. F. Emery, J. L. Meinkoth, E. Nakkim, M. Subler, D. D. Von Hoff, and G. M. Wahl, Mol. Cell. Biol. 7:1740-1750, 1987). The experiments reported in this paper explore the way episomes are formed and their fate in the cell over time. The data reveal that in our system the episomes are initially 250 kilobases, but gradually enlarge until they become double minute chromosomes. In addition, we show that episomes or double minute chromosomes can integrate into chromosomes. Our results also suggest that episomes can be produced by deletion of the corresponding sequences from the chromosome.

Characterization of an episome produced in hamster cells that amplify a transfected CAD gene at high frequency: functional evidence for a mammalian replication origin

In a previous study (G. M. Wahl, B. Robert de Saint Vincent, and M. L. De Rose, Nature (London) 307:516-520, 1984), we used gene transfer of a CAD cosmid to demonstrate that gene position profoundly affects amplification frequency. One transformant, T5, amplified the donated CAD genes at a frequency at least 100-fold higher than did the other transformants analyzed. The CAD genes in T5 and two drug-resistant derivatives were chromosomally located. In this report, we show that a subclone of T5 gives rise to an extrachromosomal molecule (CAD episome) containing the donated CAD genes. Gel electrophoresis indicated that the CAD episome is approximately 250 to 300 kilobase pairs, and a variety of methods showed that it is a covalently closed circle. We show that the CAD episome replicates semiconservatively and approximately once per cell cycle. Since the CAD cosmid, which comprises most of the CAD episome, does not replicate autonomously when transfected into cells, our results indicate that either the process which generated the episome resulted in a cellular origin of DNA replication being linked to the CAD sequences or specific rearrangements within the episome generated a functional origin. The implications of these results for mechanisms of gene amplification and the genesis of minute chromosomes are discussed.

Intranuclear uptake and persistence of biologically active DNA after electroporation of mammalian cells

Radiolabeled or biologically functional DNA molecules were introduced into cells by electroporation in a variety of forms: double stranded circles, linearized double stranded fragments and single stranded circular molecules. Molecules rapidly entered cells after exposure to a high field-strength electric pulse and then redistributed between the cytoplasm and the nucleus. Maximal intranuclear levels approximated 10(4) molecules per cell. Introduced DNA persisted in a biologically active form with a half-life of 15-24 h. There was no evidence for biologically significant alteration of two double stranded gene sequences. Single stranded DNA molecules also retained biological activity.

Characterization of an episome produced in hamster cells that amplify a transfected CAD gene at high frequency: functional evidence for a mammalian replication origin

In a previous study (G. M. Wahl, B. Robert de Saint Vincent, and M. L. De Rose, Nature (London) 307:516-520, 1984), we used gene transfer of a CAD cosmid to demonstrate that gene position profoundly affects amplification frequency. One transformant, T5, amplified the donated CAD genes at a frequency at least 100-fold higher than did the other transformants analyzed. The CAD genes in T5 and two drug-resistant derivatives were chromosomally located. In this report, we show that a subclone of T5 gives rise to an extrachromosomal molecule (CAD episome) containing the donated CAD genes. Gel electrophoresis indicated that the CAD episome is approximately 250 to 300 kilobase pairs, and a variety of methods showed that it is a covalently closed circle. We show that the CAD episome replicates semiconservatively and approximately once per cell cycle. Since the CAD cosmid, which comprises most of the CAD episome, does not replicate autonomously when transfected into cells, our results indicate that either the process which generated the episome resulted in a cellular origin of DNA replication being linked to the CAD sequences or specific rearrangements within the episome generated a functional origin. The implications of these results for mechanisms of gene amplification and the genesis of minute chromosomes are discussed.

Use of electroporation to introduce biologically active foreign genes into primary rat hepatocytes

A method is described for introducing and expressing cloned genes in isolated hepatocytes. Primary rat hepatocytes isolated by collagenase perfusion were transfected in suspension with plasmid pSV2CAT by electroporation. Forty-eight hours later, soluble extracts from transfected hepatocytes showed chloramphenicol acetyltransferase activity comparable to that obtained in rat hepatoma cell line H4AzC2 by calcium phosphate or DEAE-dextran transfection. The latter two methods could not be used successfully for primary hepatocytes because of cytotoxicity of these reagents. This indicates that electroporation is a useful method to obtain transient expression of foreign genes in primary epithelial cells, such as rat hepatocytes, which are difficult to maintain in cell culture.

The rudimentary gene of Drosophila melanogaster encodes four enzymic functions

We have determined the 7168 nucleotide DNA sequence corresponding to the messenger RNA of the rudimentary gene of Drosophila melanogaster. By sequence comparison with genes involved in the pyrimidine pathway of prokaryotes and lower eukaryotes, we conclude that the rudimentary gene encodes four enzymically different functions. Each function is restricted to a specific coding domain but in an order different from that previously defined by genetic data. We have found that the corresponding mammalian gene, the CAD gene, exhibits a similar functional organization, and we propose schemes for the evolution of the corresponding coding sequences.

In vivo expression of a nonselected gene transferred into murine hematopoietic stem cells by electroporation

Mouse bone marrow cells were subjected to electroporation in the presence of RSVCAT and SV2NEO plasmids. CAT activity was detected in the G-418 resistant granulocyte-macrophage colonies. RSVCAT electroporated into primary bone marrow cells, repopulated lethally irradiated mice as demonstrated by the persistence of CAT activity in the hematopoietic tissues showing that electroporation can offer a powerful mode of gene transfer into bone marrow cells.

Systemic resistance to methotrexate in transgenic mice carrying a mutant dihydrofolate reductase gene

A full-length cDNA coding for a mutant dihydrofolate reductase (DHFR; 5,6,7,8-tetrahydrofolate: NADP+ oxidoreductase, EC 1.5.1.3), cloned from a mouse fibroblast cell line grown in high concentrations of methotrexate (MTX), was microinjected into mouse embryos to produce transgenic mice. The DHFR cDNA product is 270-fold more resistant to MTX than the wild-type enzyme. Seventeen transgenic mouse lines, identified by Southern blotting of tail or spleen DNA, carried between 1 and 400 copies of the foreign gene per cell. Eight lines have thus far been tested for resistance to MTX. Control mice were treated until death; MTX was withdrawn from transgenic mice when a cumulative MTX dose uniformly fatal for controls was reached. The major site of MTX toxicity was the gastrointestinal tract, with death of controls resulting from fluid and weight loss. Transgenic animals were relatively resistant to these symptoms and tolerated significantly more MTX than control animals. These results show that genes conferring resistance to chemotherapeutic agents can, after transfer into intact organisms, produce systemic drug resistance.

New RNA species is produced by alternate polyadenylation following rearrangement associated with CAD gene amplification

Mammalian cells selected to resist N-(phosphonacetyl)-L-aspartate (PALA) contain amplified copies of the CAD gene. While a single 7.9-kb mRNA species is detected in PALA-sensitive and most PALA-resistant cell lines, two RNA species (7.9 and 10.2 kb) are detected in two related drug-resistant mutants presumably derived from the same parental cell. In this report we show that the 10.2-kb RNA is produced as a direct consequence of a sequence rearrangement adjacent to the 3' end of the CAD gene in these cell lines. A CAD gene containing the sequence rearrangement was cloned from one of these lines and found to produce both RNA species when transfected into CAD-deficient cells. DNA sequencing and S1 analysis demonstrate that the 10.2-kb RNA is produced by alternative polyadenylation rather than by alternative splicing. Sequence analysis also reveals that several consensus poly(A) addition signals (AATAAA) were brought into close proximity to the CAD gene by virtue of the rearrangement. While sequences adjacent to each of the polyadenylation signals contain additional features postulated to be important for the selection of the site of poly(A) addition, S1 mapping analysis indicates that only one of the polyadenylation signals is used. A comparison of all of these sites suggests that multiple sequence motifs are required to form a functional polyadenylation and cleavage signal.

Use of electroporation to introduce biologically active foreign genes into primary rat hepatocytes

A method is described for introducing and expressing cloned genes in isolated hepatocytes. Primary rat hepatocytes isolated by collagenase perfusion were transfected in suspension with plasmid pSV2CAT by electroporation. Forty-eight hours later, soluble extracts from transfected hepatocytes showed chloramphenicol acetyltransferase activity comparable to that obtained in rat hepatoma cell line H4AzC2 by calcium phosphate or DEAE-dextran transfection. The latter two methods could not be used successfully for primary hepatocytes because of cytotoxicity of these reagents. This indicates that electroporation is a useful method to obtain transient expression of foreign genes in primary epithelial cells, such as rat hepatocytes, which are difficult to maintain in cell culture.

Identification and localization of DNA alteration in Chinese hamster ovary cell mutants (Urd-) defective in the first three enzymes of de novo pyrimidine synthesis

In animals, the first three enzymatic steps of de novo pyrimidine synthesis, carbamyl phosphate synthetase, aspartate transcarbamylase, and dihydroorotase, comprise the multifunctional protein known as the CAD protein. Mutants of Chinese hamster ovary cells (CHO-K1, pro-) deficient in CAD protein activities require uridine for growth and are designated Urd-A mutants. To examine further the nature of the genetic alterations in Urd-A mutants and revertants, we have performed a detailed Southern blot hybridization analysis of DNA from wild-type, Urd-A, and revertant cells using as hybridization probes cDNAs complementary to CAD mRNA isolated from Syrian hamster. This has allowed us to identify an apparent alteration in the CAD gene in DNA from Urd-A cells. This alteration is in a region of the gene which appears to correspond to the region of the protein which is hypersensitive to proteases and which seems to be altered in the mutants. Only one of the two CAD alleles present appears to be altered in this way. Study of certain revertants of Urd-A strongly suggests that in some cases reversion has occurred by amplification of the mutant CAD allele.

Modulation of nonglobin mRNA levels in erythropoiesis

During erythropoiesis, the decrease of complexity of a RNA population is an important process as is globin mRNA accumulation. To determine the sequential control process of gene expression, many genomic clones which express in mouse reticulocytes were obtained and used for the titration of each mRNA level in the different stages of erythroid cells. The level of mRNAs of rt-clones decreases depending on the maturation of erythroid cells, and the coordinated and sequential control of this level is likely to be one of the factors affecting this process.

Selective isolation of cosmid clones by homologous recombination in Escherichia coli

A procedure for selection of specific cosmid clones by homologous recombination between cosmid clones from a library and sequences cloned into a plasmid has been developed. Cosmid libraries constructed in a rec- host strain are packaged in vivo into lambda particles. Appropriate aliquots are then introduced into a rec+ host containing the sequence used for selection cloned into a plasmid vector without sequence homology to the cosmid vector. After a short time for recombination, the cosmids are packaged in vivo. Cosmids that have taken up the plasmid by homologous recombination are isolated by plating under conditions selecting for the antibiotic resistance markers carried by both vectors. The recombined cosmids can lose the inserted sequence by another homologous recombination event and, after packaging in vivo, these revertants can be identified on appropriate indicator plates.

Preparation of ligation intermediates and related polynucleotide pyrophosphates

Unprotected oligonucleotides and oligodeoxynucleotides terminated with an unhindered 5'-phosphate group react with nucleoside 5'- phosphorimidazolides in aqueous solution to give 'capped' pyrophosphates in at least 70% yield. If adenosine 5'- phosphorimidazolide is used as a substrate in the reaction, ligase intermediates are obtained as products.

Expression of an immunoglobulin heavy chain gene transfected into lymphocytes

We determined that mouse lymphoid cell lines can be transfected at high efficiencies (10-70%) by a polyoma virus shuttle vector. With this vector, we obtained expression of a cloned mouse alpha heavy chain gene transfected into cell lines representative of all stages in B-lymphocyte development, a T-cell lymphoma line, and 3T3 fibroblasts. Heavy chain gene expression in transfected light chain-producing myeloma cells occurred at levels comparable to those in IgA-secreting myeloma cells. Heavy chains produced in transfected myeloma cells were associated with light chains in membrane-bound IgA. While T-lymphoma cells and fibroblasts were transfected at similar efficiencies to B cells, significantly lower levels of alpha heavy chains were produced. This immunoglobulin gene transfection system provides a powerful approach for defining important regulatory regions in immunoglobulin genes and for identifying lymphoid cell factors involved in immunoglobulin gene expression in B-lymphocyte development.

Gene therapy

A number of techniques are available for insertion of new genetic information into mammalian cells. some of these have been used successfully for genetic modification of germ line cells and somatic cells of living animals. Some of these techniques may be applicable to treatment of some of the genetic diseases of man, once problems related to the control of expression of introduced genes are solved.