Biochemical transformation of thymidine kinase (TK)-deficient mouse cells by herpes simplex virus type 1 DNA fragments purified from hybrid plasmids.

The thymidine kinase (TK) gene of HSV-1 has been cloned in Escherichia coli K12 plasmids, pMH1, pMH1A, and pMH4. These plasmids contain a 1,92Obp HSV-1 TK DNA sequence, which replaces a 2,067 bp EcoR I to Pvu II sequence of plasmid pBR322 DNA. Superhelical DNAs of plasmids pMH1, pMH1A, and pMH4 as well as plasmid DNAs cleaved by EcoR I, Hinc II, Bg1 II, Sma I, and Pvu II transformed TK-deficient LM(TK-) cells to the TK+ phenotype. A 1,230bp EcoR I-Sma I fragment purified from pMH1 DNA (and from plasmid pAGO, DNA, the parent of pMH1) also transformed LM(TK-) cells. Serological and disc PAGE studies demonstrated that the TK activity expressed in biochemically transformed cells were HSV-1-specific. The experiments suggest that the HSV-1 TK coding region may be contained within a l.1kbp DNA sequence extending from about the Hinc II (or Bgl II) cleavage site to the Sma I site. 35S-methionine labeling experiments carried out on cell lines transformed by Hinc II-cleaved pMH1 DNA and by the EcoR I-Sma I fragment showed that the TKs purified from the transformed cells consisted of about 39-40,000 dalton polypeptides.     

Expression of cotransferred genes in mouse L cells

The Herpes simplex virus (HSV) thymidine kinase (TK) gene was introduced into mouse L cells by cotransformation with the G418 resistance gene on plasmid pSV2neo.d5 and selection for antibiotic resistance. Fifty nanograms each of the TK gene and pSV2neo.d5 were mixed with 10 μg of carrier DNA and precipitated onto cells. Of 18 antibiotic-resistant colonies analyzed, 15 contained 1–5 copies of the TK gene and 13 of the 15 were phenotypically TK positive. These data demonstrate that it is possible to introduce small numbers of copies of cotransferred genes into cultured cells and that in most cases the genes are integrated in a manner compatible with expression.     

Rescue of marker phenotypes: effects of BUdR sensitization, hypoxia and high LET.

The survival curve of colony-forming ability of Chinese hamster wg3h cells has been compared with the dose-response curve for the expression of an active thymidine kinase (TK) gene from these cells. The TK+ phenotype was measured by hybrid colony formation after fusion of wg3h (TK+) cells with Chinese hamster A23 (TK-) cells. The TK+ survival data fitted a multi-target curve up to 3 krad of 137 Cs irradiation, when a highly resistant fraction of hybrid colonies was seen at about 1 per cent survival. The Do of TK+ survival for the multi-target region was 3.1-4.0 times greater, than that of wg3h survival, even when the Do for cell survival varied between 136 and 545 rad by 14 MeV neutrons and hypoxia respectively. This parallel modification of cell and TK+ sensitivities suggests that the lesions causing cell inactivation are of the same type as those that cause marker inactivation. Using 14 MeV neutron data the approximate target size for TK inactivation was calculated to be 0.54-0.91 per cent of the DNA content of the cell (or about one-fifth to one-tenth of a chromosome). The data support the idea that marker inactivation results primarily from damage occurring outside the marker gene. BUdR labelling of wg3h cells before irradiation caused slight toxicity (30 per cent reduction in plating efficiency) and a twofold increase in cell sensitivity. However, the sensitivity of the TK+ phenotype increases by only 30 per cent. The increased cell sensitivity thus appeared to result from synergism between increased sensitivity of DNA to strand breakage and metabolic toxicity, the latter being largely overcome by fusion with normal cells.     

Carrier DNA affects the integration of HSV-1 TK gene in the genome of L929TK- cells.

L929TK- cells were cotransfected with DNA mixtures containing tk gene of HSV-1, plasmids carrying LTR of MoMLV or RSV and carrier DNA of salmon sperm or chromosomal DNA of recipient cells. Selection of TK+ transformants was conducted in DMEM supplemented with HAT. Plasmids carrying LTR sequences of MoMLV or RSV retroviruses showed enhancing effect on the frequency of TK+ transformation. Southern blot analysis of chromosomal DNA of TK+ transformants demonstrated in clones deriving from cotransfections of tk gene and carrier DNA of L929TK- cells multiple copies of tk gene integrated into several genomic sites of host. Single copies of tk gene integrated into different sites of host genome occurred in chromosomal DNA of TK+ clones deriving from cotransfections of tk gene and carrier DNA of salmon sperm. Cells cotransfected with tk gene and plasmids carrying LTR sequences of MoMLV or RSV formed three dimensional colonies in semisolid agar medium. No effect of carrier DNA on the morphology of TK+ transformant clones was noticed.     

Homologous recombination between overlapping thymidine kinase gene fragments stably inserted into a mouse cell genome.

We have constructed a substrate to study homologous recombination between adjacent segments of chromosomal DNA. This substrate, designated lambda tk2 , consists of one completely defective and one partially defective herpes simplex virus thymidine kinase (tk) gene cloned in bacteriophage lambda DNA. The two genes have homologous 984-base-pair sequences and are separated by 3 kilobases of largely vector DNA. When lambda tk2 DNA was transferred into mouse LMtk- cells by the calcium phosphate method, rare TK+ transformants were obtained that contained many (greater than 40) copies of the unrecombined DNA. Tk- revertants, which had lost most of the copies of unrecombined DNA, were isolated from these TK+-transformed lines. Two of these Tk- lines were further studied by analysis of their reversion back to the Tk+ phenotype. They generated ca. 200 Tk+ revertants per 10(8) cells after growth in nonselecting medium for 5 days. All of these Tk+ revertants have an intact tk gene reconstructed by homologous recombination; they also retain various amounts of unrecombined lambda tk2 DNA. Southern blot analysis suggested that at least some of the recombination events involve unequal sister chromatid exchanges. We also tested three agents, mitomycin C, 12-O-tetradecanoyl-phorbol-13-acetate, and mezerein, that are thought to stimulate recombination to determine whether they affect the reversion from Tk- to Tk+. Only mitomycin C increased the number of Tk+ revertants.     

Efficient correction of mismatched bases in plasmid heteroduplexes injected into cultured mammalian cell nuclei.

Heteroduplexes were prepared from two plasmids, pRH4-14/TK and pRH5-8/TK, containing different amber mutations in the neomycin resistance gene (Neor). The Neor gene was engineered to be expressed in both bacterial and mammalian cells. A functional Neor gene conferred kanamycin resistance to bacteria and resistance to the drug G418 to mammalian cells. In addition, the plasmids contained restriction site polymorphisms which did not confer a selectable phenotype but were used to follow the pattern of correction of mismatched bases in the heteroduplexes. In a direct comparison of the efficiency of transforming mouse LMtk- cells to G418r, the injection of heteroduplexes of pRH4-14/TK-pRH5-8/TK was 10-fold more efficient than the coinjection of pRH4-14/TK and pRH5-8/TK linear plasmid DNA. In fact, injection of 5 to 10 molecules of heteroduplex DNA per cell was as efficient in transforming LMtk- cells to G418r as the injection of 5 to 10 molecules of linear plasmid DNA per cell containing a wild-type Neor gene. To determine the pattern of mismatch repair of the injected heteroduplexes, plasmids were "rescued" from the G418r cell lines. From this analysis we conclude that the generation of wild-type Neor genes from heteroduplex DNA proceeds directly by correction of the mismatched bases, rather than by alternative mechanisms such as recombination between the injected heteroduplexes. Our finding that a cell can efficiently correct mismatched bases when confronted with preformed heteroduplexes suggests that this experimental protocol could be used to study a wide range of DNA repair mechanisms in cultured mammalian cells.     

BK virus-plasmid expression vector that persists episomally in human cells and shuttles into Escherichia coli.

We describe a novel expression vector, pBK TK-1, that persists episomally in human cells that can be shuttled into bacteria. This vector includes sequences from BK virus (BKV), the thymidine kinase (TK) gene of herpes simplex virus type 1, and plasmid pML-1. TK+-transformed HeLa and 143 B cells contained predominantly full-length episomes. There were typically 20 to 40 (HeLa) and 75 to 120 143 B vector copies per cell, although some 143 B transformants contained hundreds. Low-molecular-weight DNA from TK+-transformed cells introduced into Escherichia coli were recovered as plasmids that were indistinguishable from the input vector. Removal of selective pressure had no apparent effect upon the episomal status of pBK TK-1 molecules in TK+-transformed cells. BKV T antigen may play a role in episomal replication of pBK TK-1 since this viral protein was expressed in TK+ transformants and since a plasmid that contained only the BKV origin of replication was highly amplified in BKV-transformed human cells that synthesize BKV T antigen.     

Expression of the Viral Thymidine Kinase Gene in Herpes Simplex Virus-Transformed L Cells

In these studies, the expression of thymidine kinase (TK) in normal and herpes simplex virus (HSV)-transformed L cells has been compared. In asynchronously dividing cultures of L cells, the TK activity rose and declined rapidly and coordinately with DNA synthesis. When net cell increase stopped, TK activity was at a minimum. In contrast, TK activity of HSV-transformed cells remained at a minimum during rapid DNA synthesis and gradually increased as the rate of DNA synthesis decreased. When net cell increase stopped, TK activity was at a maximum. In synchronous cultures of L cells, TK activity rose and fell coordinately with the rate of DNA synthesis. In synchronous cultures of HSV-transformed cells, no increase in TK activity was observed during the period of rapid DNA synthesis, i.e., the S phase. These findings indicated that the viral TK gene in HSV-transformed cells was not placed under the control of the cellular mechanisms which normally modulate the host cell TK gene. Lytic infection of HSV-transformed cells with a TK(-) mutant of HSV-1 induced a four-to fivefold increase in viral TK. The TK of HSV-1 was induced in the HSV-1-transformed cells and HSV-2 in the HSV-2-transformed cells by this TK(-) mutant. The same infection of normal L cells decreased the cellular TK activity by 80%. This stimulation, rather than inhibition, suggest that the viral gene in HSV-transformed cells retain some of its original viral characteristics.     

Genetic transformation of somatic cells. II. An analysis of the status of the plasmid nucleotide sequences in chromosomal DNA and the thymidine kinase activity in transformant clone cells

Chinese hamster A238 TK- -cells were transformed with plasmids (derivatives of pBR325) containing thymidine kinase (TK) gene of Herpes simplex virus type 1 (HSV1). The results of dot- and blot-hybridization indicate the presence of pBR325 sequences in the chromosomal fractions of DNA in the transformant clones. These sequences are probably tandemly arranged, and each cluster contains 25--50 copies. SV40 sequences cloned in pBR325 were introduced into the Chinese hamster cells by co-transformation with TK-gene of HSV1-containing plasmid DNA, and all the co-transformant clones selected for TK+-phenotype were shown by hydridization to contain 3V40 DNA fragments. Isoelectrofocusing in polyacrylamide gel shows that thymidine kinase from TK+-transformant clones is of viral type (isoelectric point 7), in contrast to the cellular enzyme (coded by chromosomal gene) having alkaline isoelectric point (pH 9). The results suggest that the true TK+-transformant cells are selected by the procedure used in this study.     

Regulation of thymidine kinase protein levels during myogenic withdrawal from the cell cycle is independent of mRNA regulation.

Replication-dependent changes in levels of enzymes involved in DNA precursor biosynthesis are accompanied frequently by changes in levels of cognate mRNA. We tested the common assumption that changes in mRNA levels are responsible for growth-dependent expression of these enzymes using a line of mouse muscle cells that irreversibly withdraws from the cell cycle as part of its terminal differentiation program. Thymidine kinase (TK) mRNA, activity, and protein levels were quantitated in cells transformed with multiple copies of the chicken TK gene. The decline in TK mRNA (both whole cell and cytoplasmic) during myogenesis was poor (2-fold average) and variable (1.2 to 8-fold). In contrast, TK activity always was regulated efficiently (20-fold), even in cells which regulated TK mRNA very poorly. Thus, regulation of TK activity was independent of TK mRNA regulation as myoblasts withdrew from the cell cycle. A TK/beta-galactosidase fusion protein was used to derive an antibody against chicken TK. Immunoblot and immunoprecipitation analyses demonstrated TK protein levels, like TK activity levels, declined to a greater extent than TK mRNA levels. Thus, TK activity likely was regulated by a mechanism involving either decreased translation of TK mRNA or increased degradation of TK protein in committed muscle cells.     

Patterns of integration of DNA microinjected into cultured mammalian cells: evidence for homologous recombination between injected plasmid DNA molecules.

We examined the fate of DNA microinjected into nuclei of cultured mammalian cells. The sequence composition and the physical form of the vector carrying the selectable gene affected the efficiency of DNA-mediated transformation. Introduction of sequences near the simian virus 40 origin of DNA replication or in the long terminal repeat of avian sarcoma provirus into a recombinant plasmid containing the herpes simplex virus thymidine kinase gene. (pBR322/HSV-tk) enhanced the frequency of transformation of LMtk- and RAT-2tk- cells to the TK+ phenotype 20- to 40-fold. In cells receiving injections of only a few plasmid DNA molecules, the transformation frequency was 40-fold higher after injection of linear molecules than after injection of supercoiled molecules. By controlling the number of gene copies injected into a recipient cell, we could obtain transformants containing a single copy or as many as 50 to 100 copies of the selectable gene. Multiple copies of the transforming gene were not scattered throughout the host genome but were integrated as a concatemer at one or a very few sites in the host chromosome. Independent transformants contained the donated genes in different chromosomes. The orientation of the gene copies within the concatemer was not random; rather, the copies were organized as tandem head-to-tail arrays. By analyzing transformants obtained by coinjecting two vectors which were identical except that in one a portion of the vector was inverted, we were able to conclude that the head-to-tail concatemers were generated predominantly by homologous recombination. Surprisingly, these head-to-tail concatemers were found in transformants obtained by injecting either supercoiled or linear plasmid DNA. Even though we demonstrated that cultured mammalian cells contain the enzymes for ligating two DNA molecules very efficiently irrespective of the sequences or topology at their ends, we found that even linear plasmid DNA was recruited into the concatemer by homologous recombination.     

Genetic transformation of somatic cells. IX. The loss of the transformant phenotype is accompanied by rearrangements in the plasmid DNA containing the thymidine kinase gene of the herpes virus

As demonstrated by dot-hybridization, the cells of HT-subclones isolated from the cells of transformant clones cultured on a non-selective medium differ significantly in the number of copies of thymidine kinase gene (tk-gene) of Herpes simplex virus (HSV1). Since the cells of transformant clones lose thymidine kinase-positive (TK+) phenotype during cultivation, this data are indicative of high frequence rearrangements in the region of transforming DNA as responsible for the transformant phenotype nonstability. These rearrangements, among other things, induce alterations in the number of copies of tk gene of HSV1. The analysis of cells of subclones isolated on a medium containing 5-bromodeoxyuridine (BrdU) shows that the number of copies of tk gene of HSV1 decreases as compared to the cells of parental clones. The decrease in the number of copies of tk gene of HSV1 in a row of BrdU-resistant subclones is accompanied by simultaneous increase in the number of sequences of pBR325 plasmide DNA to which tk gene of HSV1 is linked covalently in the pST826 plasmide introduced into cells of transformant clones. This evidence implies a most complex nature of transforming DNA rearrangements reducing the number of copies of tk gene of HSV1 due possibly to a genetic correction. The analysis of results permits a hypothesis that instability of cells in transformant phenotype may be determined by the genetic instability of insertion type. The rate of the loss of transformant phenotype depends on the frequency of rearrangements in the transforming DNA locus.     

Origin of the Thymidine Kinase Induced by Polyoma Virus in Productively Infected Cells

Cells of the 3T3 mouse line efficiently supported the multiplication of polyoma virus, and the infectious process was accompanied by a marked increase in thymidine kinase (TK) activity. Two lines of 5-bromodeoxyuridine-resistant 3T3 cells have been isolated. As expected, these cells incorporated practically no exogenous thymidine into their deoxyribonucleic acid (DNA) and contained negligible TK activity. Like the parental 3T3 cells, TK(-) lines were susceptible to productive infection by polyoma virus, but infection did not lead to an increase in TK activity. Since kinase activity did appear after infection with another virus (vaccinia) known to contain the gene(s) for that enzyme, it is concluded that TK is not one of the gene products of polyoma virus. As induction of cellular DNA synthesis by polyoma virus occurs normally when the TK(-) cells are infected in the stationary phase, TK cannot play a role in the determination of this phenomenon.     

Lack of site specific recombination of exogenous DNA in mouse L cells

Plasmids were constructed containing the HSV thymidine kinase gene and two copies of X. borealis 5S rDNA. Mouse L TK- cells were transformed with these DNAs, with selection for the TK+ gene. Transformed cells were then analyzed by Southern blot hybridization and hybridization in situ to determine whether integration of the exogenous DNA occurred at regions of chromosomal homology i.e., at the 5S rDNA regions. Four cell lines were analyzed by Southern blots. Differences in restriction endonuclease specificity strongly suggested that integration was at a different site in each cell line. Two cell lines were further analyzed by hybridization in situ; each showed a single integration site, both different from each other and different from the mouse L cell 5S rDNA sites. Therefore, the presence of two copies of the 5S rDNA gene in the DNA introduced by gene transfer and approximately 300-350 copies of the mouse 5S rDNA gene was not sufficient in these experiments to produce homologous integration into a specific site.     

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.     

Satellite DNA induces unstable expression of the adjacent herpes simplex virus tk gene cotransfected in mouse cells.

To study the influence of clustered highly repetitive DNA sequences on the expression of adjacent genes, LTK- cells were cotransfected with the herpes simplex virus thymidine kinase (tk) gene and mouse satellite DNA. TK+ transformants containing a few copies of the tk genes flanked by satellite DNA were isolated. In situ hybridization on the metaphase chromosomes indicated that in each cell line the TK sequences resided at a single chromosomal site and that integration occurred preferentially into regions of the cellular DNA rich in highly repetitive sequences. The prominent feature of these cell lines was their phenotypic instability. Suppression and reexpression of the tk gene occurred at high frequency (greater than 3%) and did not correlate with any significant change in the organization of foreign DNA or with the presence of selective agents. These results indicate that satellite DNA, the major component of constitutive heterochromatin, may influence the expression of adjacent genes by affecting the chromatin structure.     

Gene transfer into mouse lyoma cells by electroporation in high electric fields.

Electric impulses (8 kV/cm, 5 microseconds) were found to increase greatly the uptake of DNA into cells. When linear or circular plasmid DNA containing the herpes simplex thymidine kinase (TK) gene is added to a suspension of mouse L cells deficient in the TK gene and the cells are then exposed to electric fields, stable transformants are formed that survive in the HAT selection medium. At 20 degrees C after the application of three successive electric impulses followed by 10 min to allow DNA entry there result 95 (+/- 3) transformants per 10(6) cells and per 1.2 micrograms DNA. Compared with biochemical techniques, the electric field method of gene transfer is very simple, easily applicable, and very efficient. Because the mechanism of DNA transport through cell membranes is not known, a simple physical model for the enhanced DNA penetration into cells in high electric fields is proposed. According to this ' electroporation model' the interaction of the external electric field with the lipid dipoles of a pore configuration induces and stabilizes the permeation sites and thus enhances cross membrane transport.     

Preparation of a "functional library" of African green monkey DNA fragments which substitute for the processing/polyadenylation signal in the herpes simplex virus type 1 thymidine kinase gene.

Fragments of African green monkey (Cercopithecus aethiops) DNA (3.5 to 18.0 kilobases) were inserted downstream from the thymidine kinase (TK, tk) coding region in pTK206/SV010, a gene construct which lacks both copies of the hexanucleotide 5'-AATAAA-3' and contains a simian virus 40 origin of replication, allowing it to replicate in Cos-1 cells. No polyadenylated tk mRNA was detected in Cos-1 cells transfected by pTK206/SV010. The ability of simian DNA fragments to restore tk gene expression was examined by measuring the incorporation of [125I]iododeoxycytidine into DNA in Cos-1 cells transfected by pTK206/SV010 insertion derivatives. tk gene expression was restored by the insertion in 56 of the 67 plasmids analyzed, and the level of expression equaled or exceeded that obtained with the wild-type tk gene in 30 of these. In all plasmids examined that showed restoration of tk gene expression, polyadenylated tk mRNA of discrete size was detected. The sizes of these tk mRNAs were consistent with the existence of processing and polyadenylation signals within the inserted DNA fragments. The frequency with which inserted fragments restored tk gene expression suggests that the minimal signal for processing and polyadenylation is a hexanucleotide (AAUAAA or a similar sequence). LTK- cells were biochemically transformed to TK+ with representative insertion constructs. pTK206/SV010 transformed LTK- cells at a very low frequency; the frequency of transformation with insertion derivatives was 40 to 12,000 times higher.     

De novo methylation as major event in the inactivation of transfected herpesvirus thymidine kinase genes in human cells

Spontaneous inactivation of integrated thymidine kinase genes was studied in three human cell lines, one with multiple copies and two with a single copy of a transfected shuttle plasmid containing two selectable genes: the HSV tk gene and the Eco gpt gene. Selection for gpt expression prevented the isolation of TK- mutants which are the result of plasmid loss. Under these conditions TK- clones were isolated with a frequency of 5.10(-6) both with the cell line containing 5 or 6 copies of the tk gene and with one of the two cell lines containing one copy of this gene. This inactivity of the tk gene was associated with de novo methylation as the number of HAT-resistant (TK+) clones strongly increased after growth of the TK- derivatives in the presence of the demethylating agent, 5-azacytidine. Digestion with methylation-sensitive restriction enzymes revealed two different patterns of DNA methylation in the genomic DNA of TK- variants. In the TK- derivatives of the cell line containing multiple copies of the tk gene many HpaII restriction sites in the gene copies were insensitive to digestion. These HpaII sites were, however, not methylated in TK- variants of the cell line containing one copy of the plasmid, and methylated CpGs could be detected only with EcoRI which recognizes the cGAATTCg sequence in the tk promoter region. With the other of the two single-copy TK+ cell lines no TK- mutants were obtained, suggesting that the position of a gene in the genome is an important factor in determining the frequency and the extent of de novo methylation. Additionally, we observed that remethylation is an even more efficient process of gene inactivation as TK+ clones reactivated with 5-azacytidine can become TK- again at a 100-fold higher rate than the original TK+ cell line.