Thymidine transport by cultured Novikoff hepatoma cells and uptake by simple diffusion and relationship to incorporation into deoxyribonucleic acid

The initial rate of thymidine-³H incorporation into the acid-soluble pool by cultured Novikoff rat hepatoma cells was investigated as a function of the thymidine concentration in the medium. Below, but not above 2 µM, thymidine incorporation followed normal Michaelis-Menten kinetics at 22°, 27°, 32°, and 37°C with an apparent K_m of 0.5 µM, and the V_max values increased with an average Q₁₀ of 1.8 with an increase in temperature. The intracellular acid-soluble ³H was associated solely with thymine nucleotides (mainly deoxythymidine triphosphate [dTTP]). Between 2 and 200 µM, on the other hand, the initial rate of thymidine incorporation increased linearly with an increase in thymidine concentration in the medium and was about the same at all four temperatures. Pretreatment of the cells with 40 or 100 µM p-chloromercuribenzoate for 15 min or heat-shock (49.5°C, 5 min) markedly reduced the saturable component of uptake without affecting the unsaturable component or the phosphorylation of thymidine. The effect of p-chloromercuribenzoate was readily reversed by incubating the cells in the presence of dithiothreitol. Persantin and uridine competitively inhibited thymidine incorporation into the acid-soluble pool without inhibiting thymidine phosphorylation. At concentrations below 2 µM, thymidine incorporation into DNA also followed normal Michaelis-Menten kinetics and was inhibited in an apparently competitive manner by Persantin and uridine. The apparent K_m and K_i values were about the same as those for thymidine incorporation into the nucleotide pool. The over-all results indicate that uptake is the rate-limiting step in the incorporation of thymidine into the nucleotide pool as well as into DNA. The cells possess an excess of thymidine kinase, and thymidine is phosphorylated as rapidly as it enters the cells and is thereby trapped. At low concentrations, thymidine is taken up mainly by a transport reaction, whereas at concentrations above 2 µM simple diffusion becomes the principal mode of uptake. Evidence is presented that indicates that uridine and thymidine are transported by different systems. Upon inhibition of DNA synthesis, net thymidine incorporation into the acid-soluble pool ceased rapidly. Results from pulse-chase experiments indicate that a rapid turnover of dTTP to thymidine may be involved in limiting the level of thymine nucleotides in the cell.     

Thymidine uptake, thymidine incorporation, and thymidine kinase activity in marine bacterium isolates.

One assumption made in bacterial production estimates from [3H]thymidine incorporation is that all heterotrophic bacteria can incorporate exogenous thymidine into DNA. Heterotrophic marine bacterium isolates from Tampa Bay, Fla., Chesapeake Bay, Md., and a coral surface microlayer were examined for thymidine uptake (transport), thymidine incorporation, the presence of thymidine kinase genes, and thymidine kinase enzyme activity. Of the 41 isolates tested, 37 were capable of thymidine incorporation into DNA. The four organisms that could not incorporate thymidine also transported thymidine poorly and lacked thymidine kinase activity. Attempts to detect thymidine kinase genes in the marine isolates by molecular probing with gene probes made from Escherichia coli and herpes simplex virus thymidine kinase genes proved unsuccessful. To determine if the inability to incorporate thymidine was due to the lack of thymidine kinase, one organism, Vibrio sp. strain D19, was transformed with a plasmid (pGQ3) that contained an E. coli thymidine kinase gene. Although enzyme assays indicated high levels of thymidine kinase activity in transformants, these cells still failed to incorporate exogenous thymidine into DNA or to transport thymidine into the cells. These results indicate that the inability of certain marine bacteria to incorporate thymidine may not be solely due to the lack of thymidine kinase activity but may also be due to the absence of thymidine transport systems.     

Thymidine uptake, thymidine incorporation, and thymidine kinase activity in marine bacterium isolates

One assumption made in bacterial production estimates from [3H]thymidine incorporation is that all heterotrophic bacteria can incorporate exogenous thymidine into DNA. Heterotrophic marine bacterium isolates from Tampa Bay, Fla., Chesapeake Bay, Md., and a coral surface microlayer were examined for thymidine uptake (transport), thymidine incorporation, the presence of thymidine kinase genes, and thymidine kinase enzyme activity. Of the 41 isolates tested, 37 were capable of thymidine incorporation into DNA. The four organisms that could not incorporate thymidine also transported thymidine poorly and lacked thymidine kinase activity. Attempts to detect thymidine kinase genes in the marine isolates by molecular probing with gene probes made from Escherichia coli and herpes simplex virus thymidine kinase genes proved unsuccessful. To determine if the inability to incorporate thymidine was due to the lack of thymidine kinase, one organism, Vibrio sp. strain D19, was transformed with a plasmid (pGQ3) that contained an E. coli thymidine kinase gene. Although enzyme assays indicated high levels of thymidine kinase activity in transformants, these cells still failed to incorporate exogenous thymidine into DNA or to transport thymidine into the cells. These results indicate that the inability of certain marine bacteria to incorporate thymidine may not be solely due to the lack of thymidine kinase activity but may also be due to the absence of thymidine transport systems.     

Thymidine transport by Novikoff rat hepatoma cells synchronized by double hydroxyurea treatment

Suspension cultures of Novikoff rat hepatoma cells were synchronized by a double hydroxyurea block. About 80% of the cells of the population doubled 5 to 8 h after the reversal of the second hydroxyurea block. At all stages of the cell cycle, thymidine was rapidly incorporated into the acid-soluble pool of the cells (mainly dTTP) and the rate of incorporation was limited by the rate of thymidine transport. The rate of thymidine transport per cell roughly doubled during the S or late S phase and decreased again to the base level during cell division. This was reflected by corresponding changes in V_max for thymidine transport, whereas the apparent K_m remained constant throughout the cell cycle.     

Thymidine metabolism and DNA synthesis in Newcastle disease virus-infected cells.

The inhibition of thymidine incorporation into DNA in Newcastle disease virus-infected cells has been studied. At 6 h after infection of L-929 cells at high multiplicity, transport of exogenous thymidine across the cell membrane was inhibited. The kinetics of this inhibition, decreased Vmax with no change in Km, suggest that there are fewer sites available for transport in infected cells. The conversion of thymidine to dTTP was not inhibited. Equilibrium of exogenous thymidine with the acid-soluble pool occurred more slowly and at a lower level of radioactivity than in uninfected cells, and there was a reduction in the rate of incorporation of exogenous thymidine into DNA. The reduction of incorporation into the pool and into DNA was proportionate. The size of total cellular dTTP pools was changed very little in infected cells. DNA synthesized in infected cells in the presence of [3H]BrdUrd had reduced incorporation of tritium but similar buoyant density to that from uninfected cells. The results show that Newcastle disease virus inhibits DNA synthesis directly and, in addition, decreases thymidine transport. Together these account for the overall decrease in thymidine incorporation into DNA of infected cells.     

Histone protein and DNA synthesis in HeLa cells after thermal shock

Exposure of suspension-cultured HeLa cells to a 45° thermal shock resulted in cell inactivation and inhibition of both protein and DNA synthesis. DNA synthesis was inhibited in a biphasic manner with a more sensitive (D₀ = 7 min) and a less sensitive (D₀ = 20 min) phase. The less sensitive process was demonstrated to be DNA chain elongation. Transport of thymidine into intracellular pools was significantly less sensitive to thermal shock (D₀ in excess of 200 min). When HeLa cells were heated at 45° for 15 min there was an 80% inhibition of incorporation of precursors into both DNA and protein with little effect on precursor transport into cellular pools. While the rate of synthesis of whole cell and histone protein (H2a, H2b, H3, and H4) and DNA chain elongation recovered by 6 h after cell heating, total precursor incorporation into DNA was only 0.4 of control levels. The long-term depression of the DNA synthetic rate could not be explained by a cell cycle redistribution, a depression in the total fraction of S phase cells synthesizing DNA, or by a depression in the rate of DNA chain elongation. We conclude that thermal shock results in a long-term depression in the fraction of cell replicons involved in DNA replication.     

Acquisition of thymidylate by the obligate intracytoplasmic bacterium Rickettsia prowazekii.

The pathway for the acquisition of thymidylate in the obligate bacterial parasite Rickettsia prowazekii was determined. R. prowazekii growing in host cells with or without thymidine kinase failed to incorporate into its DNA the [3H]thymidine added to the culture. In the thymidine kinase-negative host cells, the label available to the rickettsiae in the host cell cytoplasm would have been thymidine, and in the thymidine kinase-positive host cells, it would have been both thymidine and TMP. Further support for the inability to utilize thymidine was the lack of thymidine kinase activity in extracts of R. prowazekii. However, [3H]uridine incorporation into the DNA of R. prowazekii was demonstrable (973 +/- 57 dpm/3 x 10(8) rickettsiae). This labeling of rickettsial DNA suggests the transport of uracil, uridine, uridine phosphates (UXP), or 2'-deoxyuridine phosphates, the conversion of the labeled precursor to thymidylate, and subsequent incorporation into DNA. This is supported by the demonstration of thymidylate synthase activity in extracts of R. prowazekii. The enzyme was determined to have a specific activity of 310 +/- 40 pmol/min/mg of protein and was inhibited greater than or equal to 70% by 5-fluoro-dUMP. The inability of R. prowazekii to utilize uracil was suggested by undetectable uracil phosphoribosyltransferase activity and by its inability to grow (less than 10% of control) in a uridine-starved mutant cell line (Urd-A) supplemented with 50 microM to 1 mM uracil. In contrast, the rickettsiae were able to grow in Urd-A cells that were uridine starved and supplemented with 20 microM uridine (117% of control). However, no measurable uridine kinase activity could be measured in extracts of R. prowazekii. Normal rickettsial growth (92% of control) was observed when the host cell was blocked with thymidine so that the host cell's dUXP pool was depressed to a level inadequate for growth and DNA synthesis in the host cell. Taken together, these data strongly suggest that rickettsiae transport UXP from the host cell's cytoplasm and that they synthesize TTP from UXP.     

Inhibition of cell division by interferons. The relationship between changes in utilization of thymidine for DNA synthesis and control of proliferation in Daudi cells.

Inhibition of the proliferation of Daudi cells by exposure to human lymphoblastoid interferons is associated with an early and marked decrease in the incorporation into DNA of exogenous [3H]thymidine when cells are incubated with trace amounts of this precursor. In contrast, incorporation of exogenous deoxyadenosine into DNA is unchanged under the same conditions. Interferon treatment results in a lowering of thymidine kinase activity, an effect which may be largely responsible for the inhibition of incorporation of labelled thymidine into DNA. At higher concentrations of exogenous thymidine, which minimize the contribution of intracellular sources to the dTTP pool, the inhibition of thymidine incorporation is abolished. Under conditions in which exogenous thymidine is rigorously excluded from the medium or, conversely, in which cells are entirely dependent on exogenous thymidine for growth, the magnitude of the inhibition of cell proliferation by interferons is the same as under normal culture conditions. We conclude that, even though cell growth is impaired, the rate of DNA synthesis is not grossly inhibited up to 48 h after commencement of interferon treatment. Furthermore, changes in neither the utilization of exogenous thymidine nor the synthesis of nucleotides de novo are responsible for the effect on cell proliferation.     

Thymidine metabolism in cells treated with DNA-suppressing factor (DSF)

Inhibition of thymidine incorporation into DNA in cells treated with DNA-suppressing factor (DSF) has been studied. After 16 hr treatment with DSF, transport of labeled thymidine across the cell membrane was not inhibited, since equilibrium of labeled thymidine with the acid-soluble pool occurred at the same rate and the radioactivity was at the same level as in untreated cells. The values of Vmax and Km in the kinetics of transport of exogenous thymidine were not changed by DSF. Phosphorylation of labeled thymidine to deoxythymidine triphosphate (dTTP) was not inhibited by DSF. After a chase of labeled thymidine, radioactivity of the acid-soluble fraction in DSF-treated cells decreased more rapidly but that of the acid-insoluble fraction remained at a lower level than in untreated cells. It was assumed that DSF might block the entry of dTTP into DNA.     

Use of mutant cells to localize thymidine kinase in a mammalian cell-free system

The ability of nuclei preparations of Chinese hamster cell lines Don-C and B14I50 (the latter having greatly reduced thymidine kinase activity) to incorporate radioactive thymidine into DNA was measured. By placing the nuclei of one cell line in the cytoplasmic extract of the other cell, we were able to demonstrate that the thymidine kinase activity was largely restricted to the cytoplasm of the Don-C cells. The kinetics of isotope incorporation also suggested that the B14I50 nuclei contained a greatly reduced pool of thymidine triphosphate, compared with the Don-C nuclei.     

Growth rate of cultured Novikoff rat hepatoma cells as a function of the rate of thymidine and hypoxanthine transport.

Novikoff rat hepatoma cells were propagated in suspension culture in the presence of 1 micron methotrexate and various concentrations of hypoxanthine (or adenosine plus guanosine) and thymidine and with or without the inhibitor of nucleoside and purine transport, Persantin (dipyridamole). Methotrexate-treated cells failed to replicate and died even if the medium was supplemented with either thymidine or a purine source, but normal replication occurred when both were present. The additional presence of Persantin reduced the rate of transport of thymidine or hypoxanthine and thus their incorporation into the nucleotide pool and decreased the rate of cell replication. The growth rate of the cells was directly proportional to the rate of incorporation of thymidine (in the presence of excess hypoxanthine) or of hypoxanthine (in the presence of excess thymidine) until the normal maximum growth rate was obtained. Normal cell replication in the presence of methotrexate and Persantin occurred only when the medium was supplemented with 500 micron hypoxanthine and 30 micron thymidine. The results illustrate a dependence of the growth rate of mammalian cells on the rate of transport of essential nutrients into the cell.     

Thymidine and Thymine Incorporation into Deoxyribonucleic Acid: Inhibition and Repression by Uridine of Thymidine Phosphorylase of Escherichia coli

Thymidine is poorly incorporated into deoxyribonucleic acid (DNA) of Escherichia coli. Its incorporation is greatly increased by uridine, which acts in two ways. Primarily, uridine competitively inhibits thymidine phosphorylase (E.C.2.4.4), and thereby prevents the degradation of thymidine to thymine which is not incorporated into normally growing E. coli. Uridine also inhibits induction of the enzyme by thymidine. It prevents the actual inducer, probably a deoxyribose phosphate, from being formed rather than competing for a site on the repressor. The inhibition of thymidine phosphorylase by uridine also accounts for inhibition by uracil compounds of thymine incorporation into thymine-requiring mutants. Deoxyadenosine also increases the incorporation of thymidine, by competitively inhibiting thymidine phosphorylase. Deoxyadenosine induces the enzyme, in contrast to uridine. But this is offset by a transfer of deoxyribose from deoxyadenosine to thymine. Thus, deoxyadenosine permits incorporation of thymine into DNA, even in cells induced for thymidine phosphorylase. This incorporation of thymine in the presence of deoxyadenosine did not occur in a thymidine phosphorylase-negative mutant; thus, the utilization of thymine seems to proceed by way of thymidine phosphorylase, followed by thymidine kinase. These results are consistent with the data of others in suggesting that wild-type E. coli cells fail to utilize thymine because they lack a pool of deoxyribose phosphates, the latter being necessary for conversion of thymine to thymidine by thymidine phosphorylase.     

Differences in the incorporation of thymidine into DNA of normal and cystic fibrosis fibroblasts in vitro.

Although similar fractions of cells were in the S phase of the cell cycle, normal human skin fibroblasts were shown to incorporate more than twice the 3HTdR into their DNA in vitro than did cells obtained from individuals with cystic fibrosis (CF). Obligate heterozygotes incorporated an intermediate amount of the DNA precursor. Studied were initiated to determine the basis of the differential incorporation of 3HTdR among the genotypes. An analog of thymidine, BUdR, produced varied effects on the growth kinetics of the three genotypes. The growth of cells in BUdR resulted in a 50% increase in the population doubling times of all three genotypes, and caused the cell morphology to change from a spindle shape to one in which the cells became broadened and flat, with numerous cytoplasmic projections extending for distances of several cell diameters. The activities of thymidine kinase and the participation of the exogenous and de novo pathways in the synthesis of TMP were found to be approximately the same in all three genotypes. The data suggest that an alteration in the transport of thymidine into the cells may account for the differences in TdR incorporation into DNA, and this may be associated with other changes in cystic fibrosis that are apparently membrane associated.     

Rapid decrease in thymidine kinase activity of mouse cell temperature-sensitive mutants at a non-permissive temperature.

A rapid decrease in the incorporation of [3H]thymidine into DNA at a non-permissive temperature was observed in two temperature-sensitive mutants that were isolated from mouse FM3A cells. This change was not due to a decrease in the rate of DNA replication, but was closely associated with a decrease in thymidine kinase activity of these cells. Experiments to test thermolability of thymidine kinase in extracts showed that there are two components of the thymidine kinase, but there was no alteration in the sensitivity of the enzyme to high temperature. Also, the decrease in enzyme activity in the temperature-sensitive mutants at the non-permissive temperature occurred much faster than expected from the half-life of the enzyme in wild-type cells, which was measured in the presence of cycloheximide. These results suggested that the enzyme was somehow rapidly inactivated, or degraded, in the cells at the non-permissive temperature.     

Hypoxanthine and thymidine compete for transport in Chinese hamster fibroblasts

The transport of thymidine and hypoxanthine was investigated in mutant Chinese hamster lung fibroblasts deficient in both thymidine kinase and hypoxanthine-guanine phosphoribosyltransferase. Kinetic data from rapid uptake experiments (0.5–4.5 s) indicate that thymidine is transported by a monophasic saturable system (K_m = 0.29 mM, V = 6.7 nmol/min · mg) which is competitively inhibited by hypoxanthine (K_i = 3.3 mM). The cells displayed a single transport system for hypoxanthine (K_m = 2.0 mM, V = 8.9 nmol/min · mg) that is inhibited competitively by thymidine (K_i = 0.43 mM). Both hypoxanthine and thymidine entry were noncompetively inhibited by nitrobenzylthioinosine, but thymidine transport was more sensitive. A kinetic model in which hypoxanthine and thymidine share a common transporter can account for the competitive inhibition and the observation that the inhibition constants are similar to the Michaelis constants.     

Thymidine kinase, thymidylate synthase, and endothelial cell growth under hyperoxia

To determine the respective role of thymidine kinase and thymidylate synthase activities in the hyperoxia-induced decrease in DNA synthesis and their relationship with cell replication, we measured these two enzyme activities in primary cultures of porcine aortic endothelial cells under different O2 concentrations for various durations. In confluent cells, exposure to 95% O2 for 5 days reduced thymidine kinase activity to 15% of control values; thymidylate synthase activity was unaffected. In preconfluent cells exposed to 95% O2 for 2 days, similar results were obtained, together with evidence for arrest in cell proliferation. Thymidylate synthase activity could therefore not be related to decreased cell proliferation under hyperoxia. [3H]thymidine incorporation into DNA, thymidine kinase activity, and cell proliferation were all similarly affected under exposure to graded O2 concentration for 2 days. Thymidine kinase appears to be a key enzyme in the modulation of DNA synthesis from thymidine and in its replication in endothelial cells.     

Interferon inhibition of thymidine incorporation into DNA through effects on thymidine transport and uptake

Replenishment of medium after 72 hr of growth of HeLa-S3 cells in dense suspension cultures increased [³H]-thymidine uptake into cells and incorporation into DNA, with the levels reaching a peak ～ 12 hr following medium change; β interferon inhibits the enhanced uptake of [³H]-thymidine and labeling of DNA in a dose-dependent manner. Some reduction in these processes is observed at a concentration as low as 1 u/ml, and ～ 75% inhibition at 640 u/ml. Kinetic analysis has revealed that the rate of labeling of the acid-soluble pool with [³H]-thymidine, measured either at 22°C, or 37°C, is reduced in interferon-treated (640 u/ml, 24 hr) HeLa-S3 cells. At 22°C, the initial rate of thymidine transport at a high (500 μM) thymidine concentration, determined within the first 30 sec of [³H]-thymidine addition was depressed by 44% in interferon-treated HeLa cells. At 37°C, labeled precursors accumulate in acid-soluble material for ～ 8 min after the addition of [³H]-thymidine, after which an apparent equilibrium level is attained. At this temperature, the rate of thymidine uptake and the apparent equilibrium level attained were depressed by 70% in interferon-treated HeLa cells. The reduced incorporation of [³H]-thymidine into DNA in interferon-treated HeLa-S3 cells can be largely explained by interferon inhibition of thymidine transport and phosphorylation.     

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.     

Uptake of thymidine into isolated rat hepatocytes. Evidence for two transport systems

Thymidine transport was studied in isolated rat hepatocytes. In these cells no phosphorylation of the substrate by thymidine kinase occurred subsequent to transport. Results from studies of the concentration-dependent uptake of thymidine indicated two transport systems with about 80-fold differences in their kinetic constants. These systems were denoted as high affinity [Km = 5.3 micron, V = 0.47 pmol/(10(6) cells X s)] and low affinity systems [Km = 480 micron, V = 37.6 pmol/(10(6) cells X s)]. From intracellular to extracellular distribution ratios of [3H]thymidine it could be concluded that the uptake by the high affinity system was a concentrative process while the transport by the low affinity system was non-concentrative. The uptake of [3H]-thymidine by the high affinity system could only be inhibited by unlabeled thymidine. In contrast, all other nucleosides tested (uridine, 2'-deoxycytidine, and 2'-deoxyguanosine) were equally effective in inhibiting the low affinity system competitively. The results would suggest that in hepatocytes lacking phosphorylation by thymidine kinase, thymidine is taken up by a high and a low affinity system working in tandem. The high affinity system seems to be an active transport process with narrow substrate specificity. Thymidine uptake by the low affinity system is a facilitated diffusion process. This system is considered to be a common transport route for nucleosides of different structures.