Transfer of the herpes simplex thymidine kinase gene from human cells to mouse cells by means of metaphase chromosomes.

Thymidine kinase (TK)-deficient human cells were infected with ultraviolet light-inactivated Herpes simplex virus type 1, and "transformed" cells that expressed Herpes TK activity were isolated. Purified metaphase chromosomes were isolated from the transformed human line and incubated with TK-deficient mouse cells. TK+ cells were selected, and it was shown that these cells were gene transferents which expressed Herpes TK activity, identical to that found in the transformed human cells. The gene transferents contained no intact human chromosomes. When removed from selective pressure, the gene transferents rapidly lost the TK+ phenotype. However, upon continued growth in nonselective medium, a subpopulation in which the TK+ phenotype had become more stabilized appeared. These results suggest that the Herpes gene for thymidine kinase has integrated into the genome of the HSV-transformed human cells and that it can be transferred to other cells by means of purified metaphase chromosomes.     

Transfer of a mutant viral thymidine kinase gene results in temperature-sensitive mouse cells.

Temperature-sensitive cell lines were obtained by DNA-mediated transfer of the thymidine kinase (TK) gene from a mutant, ts1117, of herpes simplex virus type 1. The cells died at 39 degrees C in selective medium which contained low levels (1 microgram/ml) of thymidine. In this lethal condition, no revertants were detected among 10(8) cells. It was shown by in vitro analysis of the TK activity that the temperature-sensitive cell line contains an enzyme whose activity is temperature sensitive and relatively unaffected by dTTP. The viral enzyme has these properties. The effect of the lethal growth conditions in the cell line was characterized by cell cycle analysis and rescue experiments which involved a shift to the permissive conditions. The successful transfer of the mutant viral TK activity to cells provides an additional selective marker for gene transfer.     

Characterization of an Epstein-Barr virus-induced thymidine kinase.

Previous work from our laboratory suggested that the selective inhibition of Epstein-Barr virus (EBV) replication by 1-beta-D-arabinofuranosylthymine in human lymphoid cell lines involved the induction of a new thymidine kinase (TK) able to phosphorylate the thymidine analog. We further characterized this enzyme induced in various EBV-positive cell lines after viral genome activation with a combination of sodium butyrate and 12-O-tetradecanoylphorbol-13-acetate. The following results confirmed the existence of an EBV-specific deoxypyrimidine kinase: induction of EBV-related TK was connected with the appearance of viral early antigens in EBV-carrying cells; unexpected behaviors of the enzyme activity upon different fractionating treatments led to the conclusion that EBV-induced TK was extracted as a complex molecular form, larger than other known cellular or viral isozymes; enzymatic properties distinguished EBV-induced TK from host lymphoid cell isozymes but made it resemble other herpesvirus-specific deoxypyrimidine kinases, i.e., by partial inhibition by dTTP or ammonium sulfate, insensitiveness to dCTP, and nonstringent specificity for normal TK substrates. Genetic evidence is required to definitively ensure that EBV-specific TK actually is virus coded in EBV-transformed human lymphoid cells.     

The regulation of thymidine secretion by macrophages.

The secretion of thymidine by mononuclear phagocytes was correlated with the activity of the enzyme thymidine kinase (TK). Macrophages cultured in regular tissue culture medium released thymidine and did not express TK. However, when macrophages were incubated with medium conditioned by L cells, they expressed TK, incorporated 3H thymidine into trichloroacetic acid precipitable material, and ceased to secrete the nucleotide. Furthermore, replicating P388/D1 cells were induced to secrete thymidine by inhibiting TK with d-glucosamine. These results have demonstrated an inverse relationship between thymidine secretion and the expression of TK. They suggest that thymidine secretion by macrophages may be attributed to their lack of TK activity.     

Genetic transformation of somatic cells. V. Inheritability of the rate of loss of the trait and the stabilization of the transformant phenotype

Subclones were isolated both on selective and nonselective medium from the Chinese hamster cells transformed by thymidine kinase gene (TK-gene) of Herpes simplex virus (HSV-1) and varying in the rate of the loss of transformant phenotype. The study of the stability of thymidine kinase-positive (TK+) phenotype in cell populations the subclones shows that the nonstability and the rate of the loss of transformant phenotype are the characters that are inherited in the cell generations. Durable cultivation on a HAT-selective medium may lead to a complete or partial (expressed as a reduced rate of the loss of the character) stabilization of TK+-phenotype of the cells of transformant clones. The rate of stabilization of TK+-phenotype may differ depending on the structure of transforming DNA introduced into cells of transformant clones.     

Selective assay for herpes simplex viruses expressing thymidine kinase.

A technique for selecting herpes simplex viruses expressing the viral thymidine kinase (TK+) from a population of predominantly TK- viruses was developed. This was accomplished by infecting TK- cells and incubating the cultures under a liquid overlay medium containing methotrexate. Since the TK- cells survive in this medium for only a limited period of time, it was necessary to add fresh uninfected TK- cells 48 h after infection. The technique allowed the detection and quantitation of the TK+ virus fraction in mixtures of TK+ and TK- viruses where the TK+ fraction was present in frequencies as low as 10(-5). It was also used to estimate reversion frequencies and to obtain and analyze TK+ revertants from TK- mutant strains of herpes simplex virus type 1.     

Substrate binding is a prerequisite for stabilisation of mouse thymidine kinase in proliferating fibroblasts

Thymidine kinase (TK) expression in mammalian cells is strictly growth regulated, with high levels of the enzyme present in proliferating cells and low levels in resting cells. We have shown that mouse TK expressed from a constitutive promoter is still subject to this regulation. The drastic decline in TK enzyme levels in resting cells is largely due to a pronounced reduction in the half-life of the protein. Deletion of the 30 C-terminal amino acid residues from TK abrogates growth regulation, rendering the enzyme very stable. Moreover, the substrate thymidine was sufficient to stabilise the labile TK protein in quiescent cells. Here, we report that the ability of TK to bind substrates is essential for both growth-dependent regulation and stabilisation by the substrate. By mutation or elimination of the binding sites for either of the two substrates, ATP and thymidine, we expressed TK proteins lacking enzymatic activity which abolished growth-regulated expression in both cases. Mutant TK proteins impaired in substrate binding were subject to rapid degradation in exponentially growing cells and thymidine was no longer sufficient to inhibit this rapid decay. A C-terminal truncation known to stabilise the TK wild-type protein in resting cells did not affect the rapid turnover of enzymatically inactive TK proteins. Proteasome inhibitors also failed to stabilise these substrate-binding mutants. By cross-linking experiments, we show that TK proteins with mutated substrate-binding sites exist only as monomers, whereas active TK enzyme forms dimers and tetramers. Our data indicate that, In addition to the C terminus intact substrate-binding sites are required for growth-dependent regulation of TK protein stability.     

Herpes simplex virus thymidine kinase enzymatic assay in transient transfection experiments using thymidine kinase-deficient cells.

An enzymatic assay for herpes virus simplex type 1 thymidine kinase (HSV-TK) that was sensitive enough to quantitate intracellular levels of enzyme transiently expressed after transfection of HSV-TK vectors into TK-deficient cells using the DNA-calcium phosphate coprecipitation technique is described. TK activity in extracts of transfected cells was determined by binding of [methyl-3H]thymidylate product to thin layers of polyethyleneimine (PEI)-impregnated cellulose. The assay used high-specific-activity [methyl-3H]thymidine as substrate, which required removal of anionic material on a column of PEI-cellulose to enhance the signal-to-noise ratio. The assay was linear over a wide range with respect to the amount of HSV-TK plasmid transfected or content of HSV-TK enzyme in cell extracts. To validate the assay in transient expression experiments, HSV-TK and chloramphenicol acetyltransferase (CAT) plasmids were cotransfected into NIH/3T3 tk- fibroblasts. Transient TK and CAT levels were concordant in cell extracts prepared from replicate plates of transfected cells. Normalizing the transient TK activity for CAT activity from the cotransfected "internal standard" CAT plasmid improved precision significantly, reducing the sample-to-sample coefficient of variation from 41 to 19%. CAT normalization reduced experimental variability mostly by correcting outlying results in transfection efficiency. The HSV-TK reporter gene system based on TK enzymatic assay was thus subject to experimental variation similar to that of the well-established CAT reporter function, demonstrating its utility in transient gene expression analysis.     

Mitochondrial thymidine kinase and the enzymatic network regulating thymidine triphosphate pools in cultured human cells

In non-proliferating cells mitochondrial (mt) thymidine kinase (TK2) salvages thymidine derived from the extracellular milieu for the synthesis of mt dTTP. TK2 is a synthetic enzyme in a network of cytosolic and mt proteins with either synthetic or catabolic functions regulating the dTTP pool. In proliferating cultured cells the canonical cytosolic ribonucleotide reductase (R1-R2) is the prominent synthetic enzyme that by de novo synthesis provides most of dTTP for mt DNA replication. In non-proliferating cells p53R2 substitutes for R2. Catabolic enzymes safeguard the size of the dTTP pool: thymidine phosphorylase by degradation of thymidine and deoxyribonucleotidases by degradation of dTMP. Genetic deficiencies in three of the participants in the network, TK2, p53R2, or thymidine phosphorylase, result in severe mt DNA pathologies. Here we demonstrate the interdependence of the different enzymes of the network. We quantify changes in the size and turnover of the dTTP pool after inhibition of TK2 by RNA interference, of p53R2 with hydroxyurea, and of thymidine phosphorylase with 5-bromouracil. In proliferating cells the de novo pathway dominates, supporting large cytosolic and mt dTTP pools, whereas TK2 is dispensable, even in cells lacking the cytosolic thymidine kinase. In non-proliferating cells the small dTTP pools depend on the activities of both R1-p53R2 and TK2. The activity of TK2 is curbed by thymidine phosphorylase, which degrades thymidine in the cytoplasm, thus limiting the availability of thymidine for phosphorylation by TK2 in mitochondria. The dTTP pool shows an exquisite sensitivity to variations of thymidine concentrations at the nanomolar level.     

Phenotypic switching in cells transformed with the herpes simplex virus thymidine kinase gene

Biochemical transformation of Ltk- cells with the herpes simplex virus thymidine kinase (tk) gene resulted in numerous TK+ colonies that survived selection in hypoxanthine-aminopterin-thymidine medium. Many of these TK+ cell lines switched phenotypes and reverted to the TK- state. In this report, we describe the biological and biochemical characteristics of three TK- revertant lines. One (K1B5) transiently expressed TK in the presence of bromodeoxyuridine, which selects for the TK- phenotype. Another TK- sibling (K1B6n) expressed TK only after removal from bromodeoxyuridine-containing medium. The last variant (K1B6me) lost the ability to switch to the TK+ phenotype, although it maintained the herpes simplex virus sequences coding for TK. Loss of the ability of K1B6me cells to express TK was correlated with extensive methylation of the sequence recognized by the restriction endonuclease HpaII (pCpCpGpG). After these cells were treated with 5-azacytidine, they regained the ability to clone in hypoxanthine-aminopterin-thymidine medium and reexpressed virus tk mRNA and enzyme. In addition, the HpaII sites that were previously shown to be refractile to enzyme digestion were converted to a sensitive state, demonstrating that they were no longer methylated.     

Highly purified recombinant varicella Zoster virus thymidine kinase is a homodimer

Recombinant varicella zoster virus (VZV) thymidine kinase (TK) was isolated in a fast and gentle two-step procedure from Escherichia coli. The TK was expressed as a PreScission-cleavable fusion protein and purified by glutathione and ATP affinity chromatography, yielding homogeneous, highly pure VZV TK. The purified enzyme displays enzymatic activities with K(m) values of 0.3 +/- 0.06 microM for the natural substrate thymidine and 11.6 +/- 3.2 microM for ATP, indicating the biochemical equivalence with the viral VZV TK expressed in infected cells. Determinations of the native molecular weight by size exclusion chromatography and native polyacrylamide gel electrophoresis revealed that the pure enzyme is biologically active as a homodimer.     

Genetic determinants of growth phase-dependent and adenovirus 5-responsive expression of the Chinese hamster thymidine kinase gene are contained within thymidine kinase mRNA sequences.

We have constructed a chimeric thymidine kinase (TK) minigene, pHe delta 6Ha, which combines the complete coding and 3' noncoding regions of a Chinese hamster TK cDNA with the promoter region and 5' untranslated region of the TK gene of herpes simplex virus type 1. We have transformed rat 4 cells to Tk+ with this gene and analyzed the pattern of TK gene expression in these transformants under various conditions of in vitro cell culture. We find that TK gene expression in these Tk+ transformants is growth phase dependent, responsive to adenovirus 5 infection, and indistinguishable in character under a variety of cell culture conditions from the pattern of TK gene expression in rat 4 cells transformed to Tk+ with the genomic Chinese hamster TK gene clone lambda HaTK.5. We are led to the conclusion that the genetic elements which mediate growth phase-dependent TK gene expression are contained entirely within the sequences of the mature cytoplasmic hamster TK mRNA.     

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.     

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.     

Valine, not methionine, is amino acid 106 in human cytosolic thymidine kinase (TK1). Impact on oligomerization, stability, and kinetic properties

Cytosolic thymidine kinase (TK1) cDNA from human lymphocytes was cloned, expressed in Escherichia coli, purified, and characterized with respect to the ATP effect on thymidine affinity and oligomerization. Sequence analysis of this lymphocyte TK1 cDNA and 21 other cDNAs or genomic TK1 DNAs from healthy cells or leukemic or transformed cell lines revealed a valine at amino acid position 106. The TK1 sequence in NCBI GenBank(TM) has methionine at this position. The recombinant lymphocyte TK1(Val-106) (rLy-TK1(Val-106)) has the same enzymatic and oligomerization properties as endogenous human lymphocyte TK1 (Ly-TK1); ATP exposure induces an enzyme concentration-dependent reversible transition from a dimer to a tetramer with 20-30-fold higher thymidine affinity (K(m) about 15 and 0.5 microm, respectively). Substitution of Val-106 with methionine to give rLy-TK1(Met-106) results in a permanent tetramer with the high thymidine affinity (K(m) about 0.5 microm), even without ATP exposure. Furthermore, rLy-TK1(Met-106) is considerably less stable than rLy-TK1(Val-106) (t(12) at 15 degrees C is 41 and 392 min, respectively). Because valine with high probability is the naturally occurring amino acid at position 106 in human TK1 and because this position has high impact on the enzyme properties, the Val-106 form should be used in future investigations of recombinant human TK1.     

Utilization of exogenous thymidine by Chlamydia psittaci growing in the thymidine kinase-containing and thymidine kinase-deficient L cells.

The incorporation of [3H]thymidine into the deoxyribonucleic acid (DNA) of Chlamydia psittaci (strain 6BC) growing in thymidine kinase (adenosine 5'-triphosphate-thymidine 5'-phosphotransferase, EC 1.7.1.21)-containing L cells, L(TK+), and thymidine kinase-deficient L cells, LM(TK-), was examined by autoradiography. Label was detected over C. psittaci inclusions in L(TK+) but not LM(TK-) cells. No evidence for a chlamydia-specific thymidine kinase activity in either L(TK+) or LM(TK-) cells was obtained. Entry of [3H]thymidine into the DNA of C. psittaci growing in L(TK+) cells was quantitated by measuring label in purified C. psittaci. It was 265 times less efficient than entry into infected host cell DNA. It is concluded that low levels of exogenous thymidine are incorporated into the DNA of C. psittaci and that this incorporation is dependent on a fully competent host thymidine kinase activity. Evidence also is presented that L cells possess at least two thymidine kinase activities, both of which are capable of supplying thymidylate precursors for nuclear DNA synthesis.