A human-mouse somatic hybrid line selected for human deoxycytidine deaminase.

A new selective medium has been developed for cells containing the enzyme deoxycytidine deaminase. This medium contains hypoxanthine, aminopterin, and 5-methyldeoxycytidine (HAM medium). To survive in the presence of the aminopterin, the cells must utilize deoxycytidine deaminase to convert the 5-methyldeoxycytidine to thymidine. The cells must also have thymidine kinase and hypoxanthine phosphoribosyltransferase. A mouse cell line deficient in deoxycytidine deaminase has been isolated from a deoxycytidine kinase-deficient line, using 5-bromodeoxycytidine as the selective agent. A hybrid line between this double mutant and a human diploid fibroblast was isolated in HAM medium. The hybrid line contains the chromosomes expected of a human-mouse hybrid. The deoxycytidine deaminase isozyme patterns on cellogel show that the human-mouse hybrid cell line produces an enzyme with an electrophoretic mobility intermediate between that of the human and that of the mouse.     

Characterization of hypoxanthine-guanine phosphoribosyl transferase in man-mouse somatic cell hybrids by an improved electrophoretic method

The hypoxanthine-guanine phosphoribosyl transferase (HGPRT) activity in a group of man-mouse somatic cell hybrids, produced by Sendai virus-mediated cell fusion and HAT selection, has been analyzed by a new electrophoretic technique. Evidence is presented which shows that the hybrid lines derived from fusion of a mouse fibroblast deficient in HGPRT with various human cell strains have an HGPRT activity that is characteristic of the human enzyme, whereas a hybrid line derived from a mouse fibroblast which is deficient in thymidine kinase has an HGPRT activity characteristic of the mouse. This new technique involves electrophoresis of cell extracts on cellulose acetate gel, followed by the localization of the enzyme activity by autoradiography.This research was supported in part by a research grant from the U.S. National Institutes of Health (No. GM-13415).     

The activities of thymidine metabolising enzymes during the cell cycle of a human lymphocyte cell line LAZ-007 synchronised by centrifugal elutriation

The activities throughout the cell cycle of thymidine kinase (EC 2.7.1.21), dihydrothymine dehydrogenase (EC 1.3.1.2), thymidine phosphorylase (EC 2.4.2.4) and dTMP phosphatase (EC 3.1.3.35) were measured in the Epstein-Barr virally transformed human B lymphocyte line LAZ-007. Cells were synchronised at different stages of the cell cycle using the technique of centrifugal elutriation. The degree of synchrony in each cycle-stage cell population was determined by flow microfluorimetric analysis of DNA content and by measurement of thymidine incorporation into DNA. The activity of the anabolic enzyme thymidine kinase was low in the G₁ phase cells, but increased many-fold during the S and G₂ phases, reaching a maximum after the peak of DNA synthesis, then decreasing in late G₂ + M phase. By contrast, the specific activities of the enzymes involved in thymidine and thymidylate catabolism, dihydrothymine dehydrogenase, thymidine phosphorylase and dTMP phosphatase remained essentially constant throughout the cell cycle, indicating that the fate of thymidine at different stages of the cell cycle is governed primarily by regulation of the level of the anabolic enzyme thymidine kinase and not by regulation of the levels of thymidine catabolising enzymes.     

Thymidine kinase activity in mouse embryo fibroblast cells infected with murine cytomegalovirus

Thymidine kinase activity was found in whole cell extracts of growing and stationary mouse embryo fibroblast cells after infection with murine cytomegalovirus. Determination of the kinetic constants and heat stability characteristics indicated that the enzyme activity from infected cells was different to that found in uninfected cells in the growth phase. The expression of thymidine kinase activity during virus replication was reflected by the incorporation of (6-³H) thymidine into acid precipitable fractions of infected cell cultures. Preliminary data from kinetic studies showed a reduction in the phosphorylation of thymidine by this enzyme activity in the presence of Acyclovir, a potent inhibitor of herpes virus replication.     

Unusual aspects of human thymidylate synthase in mouse cells introduced by DNA-mediated gene transfer

Thymidylate synthase-negative mutants of mouse FM3A cells were transformed to thymidine prototrophs by human DNA. The stable transformants had only human thymidylate synthase and segments of human DNA. They grew normally but had unusually high levels of the human enzyme. In two transformants examined, however, neither was the dTTP pool elevated nor the dCTP pool decreased. DNA synthesis in permeabilized cells of a transformant was more efficient than that in the wild type with dATP, dGTP, dCTP, and dUMP as substrates, but this was not so when dUMP was replaced by dTTP. Unlike the mouse enzyme, the human enzyme in the transformants did not co-sediment with DNA polymerase alpha and thymidine kinase in a sucrose gradient, suggesting that the human enzyme is not incorporated into a multienzyme complex for DNA replication. The high levels of the human enzyme in the transformants were suppressed to various degrees by fusion with a wild type mouse line. No active hybrid dimer enzyme was found between the human and mouse enzymes, which each consist of two identical subunits. Thus, the human enzyme in the transformants seems to behave differently from the mouse enzyme and its overproduction seems to be necessary for supporting the normal growth of the transformants.     

Analyses of deoxycytidylate deaminase molecular forms in human-mouse and monkey-mouse somatic cell hybrids

Disc polyacrylamide gel electrophoresis (disc PAGE) analyses have revealed that mouse, human, and monkey cytosol deoxycytidylate (dCMP) deaminases differ in electrophoretic mobility, so that mixtures of mouse and human, mouse and monkey, and human and monkey enzymes can be separated. To learn whether the genes for dCMP deaminase and thymidine (dT) kinase are genetically linked, disc PAGE analyses of cytosol fractions from human-mouse and monkey-mouse somatic cell hybrids were carried out. The interspecific somatic cell hybrids were derived from the fusion of cytosol dT kinase deficient mouse cells with cytosol dT kinase-positive human and monkey cells: they contained mostly mouse chromosomes and a few primate chromosomes, including the determinant for primate cytosol dT kinase. The disc PAGE analyses demonstrated that the human-mouse and monkey-mouse somatic cell hybrids contained a dCMP deaminase activity with an electrophoretic mobility characteristic of mouse dCMP deaminase. Enzymes with electrophoretic mobilities characteristic of human and monkey dCMP deaminases were not demonstrable. These findings suggest that primate cytosol dT kinase and dCMP deaminase are coded on different chromosomes, or that the formation in hybrid cells of an active primate dCMP deaminase is suppressed. Chick-mouse somatic cell hybrids containing chick but not mouse cytosol dT kinase were also analyzed. The chick-mouse hybrid cells contained cytosol dCMP deaminase activity, but it was not possible to establish whether the enzyme was of murine or avian origin because of the similarity in electrophoretic mobility between the chick and mouse enzymes. Human and mouse cells contained low levels of mitochondrial dCMP deaminase activity. In contrast to dT kinase isozymes, however, mitochondrial and cytosol dCMP deaminases were electrophoretically indistinguishable.This investigation was aided by Grant Q-163 from the Robert A. Welch Foundation and by USPHS Grants CA-06656-12 and 1-K6-AI 2352 from the National Cancer Institute and the National Institute of Allergy and Infectious Diseases.     

GENETIC CONTROL OF MITOCHONDRIAL THYMIDINE KINASE IN HUMAN-MOUSE AND MONKEY-MOUSE SOMATIC CELL HYBRIDS

Distinctive thymidine (dT) kinase molecular forms are present in mouse, human, and monkey mitochondria. Disk polyacrylamide gel electrophoresis (disk PAGE) analyses have shown that the mitochondrial-specific dT kinases differ from cytosol dT kinases in relative electrophoretic mobilities (Rm). Furthermore, the mouse mitochondrial dT kinase differs in Rm value from primate mitochondrial dT kinases. The mouse and primate cytosol dT kinases can also be distinguished. Disk PAGE analyses have been carried out on the cytosol and mitochondrial dT kinases of human-mouse (WIL-8) and monkey-mouse (mK·CV^III) somatic cell hybrids in order to learn whether the mitochondria of the hybrid cells contained murine mitochondrial-specific, primate mitochondrial-specific, or both dT kinases. WIL-8 cells were derived from cytosol dT kinase-negative, mitochondrial dT kinase-positive mouse fibro blasts and from cytosol dT kinase-positive, mitochondrial dT kinase-positive human embryonic lung cells; they contained mostly mouse chromosomes and a few human chromosomes, including the determinant for human cytosol dT kinase. The mK·CV^III cells were derived from cytosol dT kinase-negative, mitochondrial dT kinase-positive mouse kidney cells and from cytosol dT kinase-positive, mitochondrial dT kinase-positive monkey kidney cells; they contained mostly mouse chromosomes and a few monkey chromosomes, including the determinant for monkey cytosol dT kinase. Disk PAGE analyses demonstrated that the mitochondria of human-mouse and monkey-mouse somatic cell hybrids contained the mouse-specific mitochondrial dT kinase but not the human- or monkey-specific mitochondrial dT kinase. These findings suggest that primate cytosol and mitochondrial thymidine kinase genes are coded on different chromosomes.     

Antigenic immunostaining patterns in somatic hybrids of human HeLa cells and mouse fibroblasts 3T3.4E propagated in conventional medium and delipidized serum

Somatic cell hybrids were obtained with electric pulse by fusion of human epithelial HeLa cells derived from a carcinoma of the uterine cervix and mouse fibroblasts 3T3.4E, deficient in thymidine kinase. Hybrids were selected and propagated in HAT media; some experiments were carried out in medium with delipidized serum. The hybrid cells were characterized by indirect immunofluorescence with a biotin-streptavidin system using a panel of nine monoclonal antibodies specific for membrane and cytoplasmic antigens of parental cells: intermediate filaments (keratins and vimentin), HLA class 1 (β₂-microglobulin), cell activation (EGF and transferrin receptors) and cellular adhesion (fibronectin and laminin).     

A method to generate microcells from human lymphoblasts for use in microcell mediated chromosome transfer

Summary A method is described to generate microcells from human lymphobalsts for use in microcell-mediated chromosome transfer (MMCT). Micronuclei were induced in cells from a human lymphoblastic cell line by prolonged colcemid treatment, and were separated from these lymphoblasts by: (a) attaching the cells to Concanvalin A coated plastic slides designed for enucleation, and (b) centrifuging the slides in medium containing cytochalasin B. Microcells of less than 3 μm in diameter were fused with thymidine kinase negative mouse fibroblast (LMTK⁻). HAT medium (hypoxanthine, aminopterin and thymidine) was used to select microcell hybrids expressing thymidine kinase activity. Positive clones were isolated and Q-banded for chromosome analysis. Unlike previous methods this procedure permits microcells to be easily generated from lymphoid cells. This methodology of enucleation of microcells may be extended to a variety of other donor cell types which can be micronucleated but which do not adhere tightly to enucleation slides and do not exhibit extrusion subdivision. This feature makes our methodology particularly useful for constructing a library of hybrid clones containing one or a few human chromosomes.     

Thymidine Kinase from Normal, Simian Virus 40-Transformed and Simian Virus 40-Lytically Infected Cells

Simian virus 40 (SV40) infection of human diploid cells failed to cause an enhanced production of thymidine kinase during the first 10 days after infection. Thymidine kinase activities from extracts of SV40-transformed cultures (human or simian) were considerably higher than the activity levels in extracts from the normal cells of origin. In addition, whereas the kinase activities obtained for human diploid cultures decreased as the cell sheet became confluent, the kinase activities for SV40-transformed human cells remained high after confluence was reached. Antisera obtained from hamsters bearing SV40 or adeno-7-SV40 hybrid virus tumors selectively inhibited enzyme from transformed sources (human or simian). Also, the antisera selectively inhibited enzyme extracted from SV40-lytically infected monkey cells. Sera from normal animals or from hamsters bearing polyoma tumors failed to inhibit enzymes from normal, SV40-transformed, or SV40-lytically infected cells. The Michaelis constant of partially purified enzyme from SV40-transformed cells was two to five times as high as that obtained for partially purified enzyme from human diploid cell cultures.     

Stabilization of SV40 transformed human fibroblast cytoplasmic thymidine kinase by ATP

Summary Human fibroblast cytoplasmic thymidine kinase is stabilized by ATP. Sedimentation in sucrose gradients shows that in the presence of ATP, cytoplasmic thymidine kinase has a higher molecular weight (54 000) than in the absence of ATP (28 000). Removal of ATP by dialysis results in the loss of enzyme activity. The subsequent addition of ATP restores activity following a second order time course. These results are interpreted to indicate that in a human fibroblast cell line, transformed by SV₄₀ virus, cytoplasmic thymidine kinase is a dimer in the presence of ATP, but a less active monomer in its absence. Mitochondrial thymidine kinase from the same cell line is not affected by ATP.     

Characteristics of somatic cell hybrids (mouse x Chinese hamster) with a different ratio of chromosome sets from the parent species. II. Thymidine kinase activity]

The activity of thymidine kinase (TK) was studied in series of somatic cell hybrids between the mouse cell line 3T3-4E (TK-) and Chinese hamster cells M-15-1 (HGPRT-). Four groups of hybrid lines with different ratio of parental chromosome sets have been investigated: 1) three lines containing one hamster and one mouse chromosome set (1 hs+1 ms); 2) one line with 2 hs+1 ms; 3) one line containing 3 hs+1 ms and 4) one line containing 1 hs+2 ms. Mixtures of extracts from the parental cells were shown to possess the expected TK activity. The calculation of the activity per cell revealed that the 1 hs+1 ms and 2 hs+1 ms hybrid lines possessed about 50% of the initial hamster cell TK activity. The decreased TK activity in these hybrids might be due either to a loss of hamster chromosomes or to some inhibitory effect of mouse genome in cells with the studied ratio of parental sets. The enzyme activity in the 3 hs+1 ms hybrid was as expected, about three times greater than that of hamster cells.     

Investigations of the mechanism of decreased tumorigenicity of cells grown in BrdU

Transplantable SV40-transformed hamster cells cultivated in the presence of low concentrations of BrdU for prolonged periods of time and cells made deficient in the enzyme thymidine kinase (dTK) by continued exposure to BrdU became less tumorigenic. In both instances, when grown in BrdU the cells contained analog substituted DNA. The tumorigenicity of dTK⁺ cells exposed to low concentrations of BrdU, but not the dTK^? cells, returned to control values when the cells were grown in medium devoid of BrdU. A tumorigenic mouse cell line made dTK deficient also had diminished oncogenicity. However, transformed hamster cells made deficient in another salvage pathway enzyme, hypoxanthineguanine phosphoribosyl-transferase by growth in eight azaguanine, retained their tumorigenicity. Two of five revertant cell lines, in which thymidine kinase activity was restored, transplanted more readily to hamsters than the dTK^? cells from which they were derived. It is concluded that there is a relative loss of tumorigenicity when BrdU is incorporated into the DNA of tumorigenic cell lines, or when there is a genetic modification of thymidine kinase activity.     

Association of thymidylate kinase activity with pyrimidine deoxyribonucleoside kinase induced by herpes simplex virus.

Thymidine kinase derived from LMTK+ does not exhibit thymidylate kinase activity. However, protein isolated by affinity column chromatography from thymidine kinase-deficient mouse cells (LMTK-) infected by herpes simplex virus type 1 shows thymidylate kinase activity in addition to thymidine kinase and deoxycytidine kinase activities. The virus-induced multifunctional enzyme has a molecular weight of 85,000, whereas the molecular weight of thymidylate kinase from uninfected LMTK- mouse cells is 71,000. The virus-induced enzyme has a Km for thymidine of 0.8 micromolar, and for thymidylate of 25 micromolar, and for thymidylate of 25 micromolar; the ratio of Vmax for thymidylate kinase to thymidine kinase is 1.7. When subjected to isoelectric focusing, thymidylate kinase activity is not separated from thymidine kinase activity, and even though four peaks of activity are observed they have a constant ratio of thymidylate kinase to thymidine kinase activity. The isoelectric points (pI) of these four peaks are 4.8, 5.8, 6.2, and 6.6, respectively. Thymidylate kinase, derived from uninfected cells when subjected to isoelectric focusing, separates into a major component with an isoelectric point at pH 8.2 and a minor component at pH 7.7. Although thymidine and thymidylate kinase activities derived from the virus-infected cells cannot be separated either by affinity column chromatography, glycerol density gradient centrifugation, or isoelectric focusing, there is a differential rate of inactivation when the enzyme is subjected to incubation at 37 degrees, with thymidylate kinase activity being more labile than thymidine kinase activity.     

Role of the promoter in the regulation of the thymidine kinase gene.

To identify the regulatory elements of the human thymidine kinase (TK) gene, we have established stable cell lines carrying different chimeric constructs of the TK gene. Our results can be summarized as follows. (i) When the TK coding sequence is under the control of the calcyclin promoter (a promoter that is activated when G0 cells are stimulated by growth factors), TK mRNA levels are higher in G1-arrested cells than in proliferating cells; (ii) when the TK coding sequence is under the control of the promoter of heat shock protein HSP70, steady-state levels of TK mRNA are highest after heat shock, regardless of the position of the cells in the cell cycle; (iii) the bacterial CAT gene under the control of the human TK promoter is maximally expressed in the S phase; (iv) the TK cDNA driven by the simian virus 40 promoter is also maximally expressed in the S phase; and (v) TK enzyme activity is always at a maximum in the S phase, even when the levels of TK mRNA are highest in nonproliferating cells. We conclude that although the TK coding sequence may also play some role, the TK promoter has an important role in the cell cycle regulation of TK mRNA levels.     

Linkage relationship between the genes for thymidine kinase and galactokinase in different primates.

In this study we investigated the expression of primate galactokinase in somatic cell hybrids between a thymidine kinase-deficient mouse cell line and two different primate cell lines, one of which was derived from African green monkey kidney cells and the other from chimpanzee fibroblasts. All the African green monkey-mouse hybrid clones, selected in HAT medium, expressed monkey galactokinase activity and contained a monkey chromosome similar to a human E-group chromosome. When these clones were backselected in medium containing 5-bromodeoxyuridine, both this chromosome and the monkey galactokinase activity were lost. All the hybrid clones between mouse and chimpanzee cells, which were selected in HAT medium, contained the chimpanzee chromosome 17 and expressed chimpanzee galactokinase activity. These results indicate that the linkage relationship between galactokinase and thymidine kinase has been maintained in 3 divergent primate species--man, chimpanzee, and Old World monkey.     

Deoxypyrimidine nucleoside metabolism in varicella-zoster virus-infected cells.

Noninfected and varicella-zoster virus (VZV)-infected human foreskin fibroblasts were examined for thymidine kinase activity. The specific activity of VZV-infected cell extracts was approximately 7.5-fold greater than that of mock-infected cells and 3-fold greater than that of actively growing cells. The pH optimum of VZV-infected cell thymidine kinase activity was found to be 8.0, whereas thymidine kinase activity in noninfected cells exhibited a sharp pH optimum at 7.4. Electrophoretic analysis of cellular enzymes involved in pyrimidine nucleoside phosphorylation revealed at least three enzymes distinguishable by electrophoretic mobility and substrates used. These enzymes were presumed to be thymidine kinase, deoxycytidine kinase, and uridine kinase. The relative mobilities of these enzymes on 5% polyacrylamide gels were 0.18, 0.91, and 0.54, respectively. In VZV-infected cells, a single band of activity catalyzing the phosphorylation of thymidine, deoxyuridine, deoxycytidine, and cytidine was observed with a relative mobility of 0.48. Cellular pyrimidine-phosphorylating enzymes were not detected in VZV-infected cells. The molecular weight of the VZV-induced enzyme was determined to be 72,000 +/- 7%.     

Comparative study of the transformation of various thymidine kinase-deficient human and animal cell lines with the thymidine kinase gene of the Herpes simplex virus

The comparative study of transformation of four thymidine kinase deficient cell lines (mouse mammary carcinoma cell line FS tk-; rat cell line Rat-2tk-; mouse cell line Ltk-, clone D1; human cell line 143tk-) with the thymidine kinase cloned gene of Herpes simplex virus 1 was undertaken. The differences in efficiency and optimal conditions of transformation were shown for these cell lines. The advantages and disadvantages of the cell systems examined for the use in experiments for transformation and cotransformation of cultured cells with isolated genes are discussed.     

Human Thymidine Kinase Can Functionally Replace Herpes Simplex Virus Type 1 Thymidine Kinase for Viral Replication in Mouse Sensory Ganglia and Reactivation from Latency upon Explant

Herpes simplex virus type 1 thymidine kinase exhibits a strikingly broad substrate specificity. It is capable of phosphorylating deoxythymidine and deoxyuridine as does human thymidine kinase, deoxycytidine as does human deoxycytidine kinase, the cytosolic kinase whose amino acid sequence it most closely resembles, and thymidylate as does human thymidylate kinase. Following peripheral inoculation of mice, viral thymidine kinase is ordinarily required for viral replication in ganglia and for reactivation from latency following ganglionic explant. To determine which activity of the viral kinase is important for replication and reactivation in mouse ganglia, recombinant viruses lacking viral thymidine kinase but expressing individual human kinases were constructed. Each recombinant virus expressed the appropriate kinase activity with early kinetics following infection of cultured cells. The virus expressing human thymidine kinase exhibited thymidine phosphorylation activity equivalent to ~5% of that of wild-type virus in a quantitative plaque autoradiography assay. Nevertheless, it was competent for ganglionic replication and reactivation following corneal inoculation of mice. The virus expressing human thymidylate kinase was partially competent for these activities despite failing to express detectable thymidine kinase activity. The virus expressing human deoxycytidine kinase failed to replicate acutely in neurons or to reactivate from latency. Therefore, it appears that low levels of thymidine phosphorylation suffice to fulfill the role of the viral enzyme in ganglia and that this role can be partially fulfilled by thymidylate kinase activity alone.