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.     

Altered thymidine metabolism due to defects of thymidine phosphorylase.

Mitochondrial neurogastrointestinal encephalomyopathy (MNGIE) is an autosomal recessive human disease due to mutations in the thymidine phosphorylase (TP) gene. TP enzyme catalyzes the reversible phosphorolysis of thymidine to thymine and 2-deoxy-D-ribose 1-phosphate. We present evidence that thymidine metabolism is altered in MNGIE. TP activities in buffy coats were reduced drastically in all 27 MNGIE patients compared with 19 controls. All MNGIE patients had much higher plasma levels of thymidine than normal individuals and asymptomatic TP mutation carriers. In two patients, the renal clearance of thymidine was approximately 20% that of creatinine, and because hemodialysis demonstrated that thymidine is ultrafiltratable, most of the filtered thymidine is likely to be reabsorbed by the kidney. In vitro, fibroblasts from controls catabolized thymidine in medium; by contrast, MNGIE fibroblasts released thymidine. In MNGIE, severe impairment of TP enzyme activity leads to increased plasma thymidine. In patients who are suspected of having MNGIE, determination of TP activity in buffy coats and thymidine levels in plasma are diagnostic. We hypothesize that excess thymidine alters mitochondrial nucleoside and nucleotide pools leading to impaired mitochondrial DNA replication, repair, or both. Therapies to reduce thymidine levels may be beneficial to MNGIE patients.     

Effect of chloramphenicol and cycloheximide on the formation of mitochondrial-specific thymidine kinase isozymes in HeLa(BU25) cells.

HeLa(BU25) cells, though deficient in cytosol thymidine kinase-F activity, contain 2 mitochondrial thymidine kinase molecular forms, designated thymidine kinase A and thymidine kinase B. The formation of thymidine kinase A activity is cycloheximide-sensitive and chloramphenicol-resistant, while the reverse applies to the formation of thymidine kinase B. Formation of cytosol thymidine kinase F in wild-type and chloramphenicol-resistant HeLa S3 cells is also cycloheximide-sensitive and chloramphenicol-resistant.     

Incorporation of thymidine into the DNA of actinomycetes. I. Incorporation of exogenous thymidine into the DNA of Thermoactinomyces vulgaris]

The incorporation of exogenous thymidine and thymine into acid-insoluble material of Thermoactinomyces vulgaris has been studied during germination and subsequent growth. Thymine is not incorporated. The incorporation of thymidine stops after a short time due to the rapid breakdown of thymidine to thymine and deoxyribose-1-phosphate by the inducible thymidine phosphorylase. Deoxyadenosine enhances the incorporation of thymidine as well as of thymine and prolongs the tine of uptake. Uridine stimulates only the incorporation of thymidine but not of thymine. These effects can be explained by the function of these substances within the salvage pathway. Deoxyadenosine acts as donor of deoxyribosyl groups being necessary for the conversion of thymine to thymidine by thymidine phosphorylase and uridine inhibits thymidine phosphorylase, and thereby it prevents the degradation of thymidine to thymine. Thymidine is incorporated into alkali-, RNase-and protease-stable, hot TCA-soluble and DNase-sensitive material. That means that the cellular DNA of T. vulgaris can be specifically labelled by radioactive thymidine in the presence of deoxyadenosine and uridine, respectively.     

Susceptibility tests for sulfamethoxazole-trimethoprim by a broth microdilution procedure

Most media used for susceptibility testing contain sulfonamide inhibitors that make them unacceptable for testing sulfonamides. The major substance that inhibits sulfonamides has been identified as thymidine, and recent efforts to remove it from Mueller-Hinton medium have made it possible to perform susceptibility tests with sulfamethoxazole-trimethoprim by broth microdilution. Some lots of Mueller-Hinton broth are thymidine free, but some contain small amounts of thymidine and require the addition of thymidine phosphorylase or lysed horse blood which contains thymidine phosphorylase. Some lots may contain too much thymidine so that its activity cannot be reversed by adding the recommended amont of thymidine phosphorylase. Therefore the suitability of a medium must be determined by testing with control strains. Some organism, for example enterococci, cannot be tested in thymidine phosphorylase-treated media because thymine works in the same way thymidine does to inhibit the action of sulfamethoxazole-trimethoprim.     

Evaluation of radiation dose resulting from the ingestion of [3H]- and [14C]thymidine in the rat

Average doses to rat tissues from the ingestion of 2-[14C]thymidine were compared with those from methyl-[3H]thymidine or 6-[3H]thymidine. Among the three precursors, [14C]thymidine gave the highest dose to spleen and small intestine. The doses to other tissues from [14C]thymidine were almost the same or lower as compared with those from [3H]thymidine, irrespective of the 9 times higher beta-ray energy of 14C than that of 3H. In the case of [14C]thymidine, most of the dose was given by radioactivity incorporated into the organic tissue constituents (non-volatile radioactivity). In the case of [3H]thymidine, however, the dose contributions by non-volatile radioactivity were very small and the major contributions were rather from volatile radioactivity (3HHO), formed by degradation of [3H]thymidine. No significant difference in their total doses was found between the two [3H]precursors, but the dose from non-volatile radioactivity alone was 2-3 times higher with methyl-[3H]thymidine than with 6-[3H]thymidine. Estimates of the dose to cell nuclei in various tissues after the ingestion of [3H]thymidine were also made in order to predict more precisely possible radiation hazards.     

In vivo labeling of fission yeast DNA with thymidine and thymidine analogs

In vivo labeling of DNA with thymidine and thymidine analogs has long been a cornerstone of replication studies. Unfortunately, yeast lack a thymidine salvage pathway and thus do not incorporate exogenous thymidine. Specifically, yeast neither efficiently take up exogenous thymidine from their growth media nor phosphorylate it to thymidylate, the precursor of dTTP. We have overcome these problems in fission yeast by expressing the human equilibrative nucleoside transporter 1 (hENT1) along with herpes simplex virus thymidine kinase (tk). hENT1 tk cells are healthy and efficiently incorporate exogenous thymidine and thymidine analogs. We present protocols for labeling DNA with tritiated thymidine, for in situ detection of incorporated BrdU by immunofluorescence, for double labeling with CldU and IdU, for CsCl gradient separation of IdU-labeled DNA, and for using hENT1 and tk as both positive and negative selection markers.     

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.     

Thymidine salvage in Pseudomonas stutzeri and Pseudomonas aeruginosa provided by heterologous expression of Escherichia coli thymidine kinase gene.

Unlike enteric bacteria, Pseudomonas spp. generally lack thymidine phosphorylase and thymidine kinase activities, thus preventing their utilization of exogenous thymine or thymidine and precluding specific radioactive labeling of their DNA in vivo. To overcome this limitation, a DNA fragment encoding thymidine kinase (EC 2.7.1.21) from Escherichia coli was cloned into pKT230, a small, broad-host-range plasmid derived from plasmid RSF1010. From transformed E. coli colonies, the recombinant plasmid bearing the thymidine kinase gene was conjugally transferred to Pseudomonas stutzeri, Pseudomonas aeruginosa, Pseudomonas mendocina, Pseudomonas alcaligenes, and Pseudomonas pseudoalcaligenes. Thymidine kinase activity was expressed in all of these species, and all gained the ability to incorporate exogenous [2-14C]thymidine into their DNA. Thymidine incorporation into P. stutzeri was enhanced 12-fold more in mutants lacking thymidylate synthetase activity. These mutants produced higher levels of thymidine kinase and were thymidine auxotrophs; thymineless death resulted from removal of thymidine from a growing culture.     

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.     

Artificial mutants generated by the insertion of random oligonucleotides into the putative nucleoside binding site of the HSV-1 thymidine kinase gene.

We have obtained 42 active artificial mutants of HSV-1 thymidine kinase (ATP:thymidine 5'-phosphotransferase, EC 2.7.1.21) by replacing codons 166 and 167 with random nucleotide sequences. Codons 166 and 167 are within the putative nucleoside binding site in the HSV-1 tk gene. The spectrum of active mutations indicates that neither Ile166 nor Ala167 is absolutely required for thymidine kinase activity. Each of these amino acids can be replaced by some but not all of the 19 other amino acids. The active mutants can be classified as high activity or low activity on two bases: (1) growth of Escherichia coli KY895 (a strain lacking thymidine kinase activity) in the presence of thymidine and (2) uptake of thymidine by this strain, when harboring plasmids with the random insertions. E. coli KY895 harboring high-activity plasmids or wild-type plasmids can grow in the presence of low amounts of thymidine (less than 1 microgram/mL), but are unable to grow in the presence of high amounts of thymidine. On the other hand, E. coli KY895 harboring low-activity plasmids can grow at a high concentration of thymidine (greater than 50 microgram/mL) in the media. The high-activity plasmids also have an enhanced [3H]dT uptake. The amounts of thymidine kinase activity in vitro in unfractionated extracts do not correlate with either growth at low thymidine concentration or the rate of thymidine uptake. Heat inactivation studies indicate that the mutant enzymes are without exception more temperature-sensitive than the wild-type enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thymidine uptake in bacteria: the effect of purine nucleosides.

The kinetics of thymidine uptake by Escherichia coli and Bacillus subtilis cells in the presence of adenine and guanine nucleosides was investigated. The initial concentration of thymidine in the growth medium was 0.35 microng/ml while the initial concentration of purine nucleosides ranged from 25 to 250 microng/ml. Adenine nucleosides when present at a concentration more than 50 microng/ml strongly inhibit thymidine uptake by the bacteria. The duration of the inhibition depends on the initial concentration of adenine nucleoside in the growth medium. At an initial concentration of deoxyadenosine (or adenosine) of 250 microng/ml the time of inhibition of thymidine uptake was about 60 min. During this period thymidine is almost completely preserved from the action of bacterial thymidine phosphorylase. Guanine nucleosides (guanosine or deoxyguanosine) do not markedly inhibit thymidine uptake by bacteria even at a concentration of 250 microng/ml. It is shown that they do protect thymidine from the phosphorolytic action of the thymidine phosphorylase although much less effectively than adenine nucleosides. It is suggested that some areas in the bacterial membrane where thymidine phosphorylase is located are not available to guanine nucleosides.     

Inhibition of thymidine uptake in asynchronous HeLa cells by nitrobenzylthioinosine

Nitrobenzylthioinosine (NBMPR), an inhibitor of nucleoside transport by human erythrocytes, was found to be a potent inhibitor of thymidine uptake by asynchronous monolayer cultures of HeLa cells. Rates of thymidine uptake by the cultures at 20 °C were constant between 10 and 40 sec after thymidine addition and were assayed during this interval; TTP was the principal metabolite of thymidine and the thymidine phosphates accumulated at constant rates which extrapolated through time zero. The lack of an effect of NBMPR on thymidine kinase activity, or on the relative proportions of thymidine metabolites in cell extracts, indicated that NBMPR inhibited thymidine transport. When mediated entry (transport) was eliminated by 2 μM NBMPR, a significant diffusional component of thymidine entry was apparent. The mediated component of thymidine uptake exhibited Michaelis-Menten kinetics and apparent K_m and V_max values of 0.5 μM and 10–21 pmoles/min/10⁶ cells were obtained. When NBMPR-treated cells were transferred to NBMPR-free medium, inhibition of thymidine uptake persisted, suggesting that NBMPR was firmly bound to the transport inhibitory sites.     

代谢工程方法改造大肠杆菌生产胸苷

胸苷是抗艾滋病药物司他夫定(3′-脱氧-2′,3′-双脱氢胸苷)和叠氮胸苷的重要前体物质。应用代谢工程方法对大肠杆菌Escherichia coli BL21(DE3)生物合成胸苷进行了研究。通过敲除E.coli BL21嘧啶回补途径的deo A、tdk和udp三个基因,BS03工程菌株能够积累21.6 mg/L胸苷。为了增加合成胸苷前体物核糖-5-磷酸和NADPH的供给,进一步敲除pgi和pyr L使工程菌BS05胸苷的产量提高到90.5 mg/L。而通过过表达胸苷合成途径的ush A、thy A、dut、ndk、nrd A和nrd B六个基因,菌株BS08胸苷的产量能达到272 mg/L。通过分批补料发酵,BS08最终可以积累1 248.8 mg/L的胸苷。本研究结果表明经过代谢工程改造的E.coli BL21具有良好的胸苷合成能力和应用潜力。     

Lack of specific correlation of the deoxycytidine triphosphate pool level with rate of DNA synthesis.

The levels of the four deoxyribonucleoside triphosphate pools and the distribution of cells in the various phases of the cell cycle have been examined in Chinese hamster cells as thymidine, present as a regular constituent in the growth medium, was removed in stages. The results indicate that: 1. Duration of the DNA synthetic phase was lengthened when thymidine was removed from the growth medium. 2.Temporally correlated with lengthening of the DNA synthetic phase upon thymidine removal was a 7-fold increase in level of the dCTP pool, reduction in the dGTP pools, and little or no change in dATP pool. 3.Radioactive labeling procedures indicated that expansion of the dCTP pool could be completely accounted for by increased ribonucleotide reductase activity and that the dTTP pool switched from a largely exogenous thymidine source to endogenous dTTP synthesis as the extracellular thymidine concentration was reduced. 4.Deoxyuridine and thymidine were apparently transported by the same system in Chinese hamster cells, while deoxycytidine was transported by a different system. Although deoxycytidine transport was unaffected by thymidine, phosphorylation of intracellular deoxycytidine compounds to the triphosphate level was stimulated by thymidine. Cytidine transport was not significantly affected by thymidine.     

The role of blood platelets in nucleoside metabolism: assay, cellular location and significance of thymidine phosphorylase in human blood

The enzyme thymidine phosphorylase (thymidine: orthophosphate deoxyribosyltransferase, EC 2.4.2.4.), which plays a crucial role in nucleic acid metabolism in both prokaryotic and eukaryotic cells by regulating the availability of thymidine, is present in mammalian blood. Here we describe a simple, rapid HPLC-based micromethod for the assay of blood thymidine phosphorylase. We have arbitarily defined 1 unit of blood thymidine phosphorylase activity as the activity required to produce a 1-nM increment in the plasma concentration of thymine after incubation for 1 h at 37°C with a saturating concentration of exogenous thymidine.

In normal adults, whole (peripheral venous) blood thymidine phosphorylase activity with blood cells intact was 64 ± 11 units (mean ± S.D., n =20, range 45–89). The apparent Michaelis constant for thymidine was of the order to 10⁻⁴ M but varied nearly 5-fold between different individuals. Activity increased when blood cells were permeabilised or lysed with non-ionic detergents, implying that thymidine phosphorylase is an intracellular enzyme which may be influenced by exogenous as well as intracellular factors. When blood from normal donors was fractionated, thymidine phosphorylase activity consistently co-isolated with platelets. Whole-blood thymidine phosphorylase activity correlated well with platelet parameters. Although thymidine phosphorylase activity was also detected in plasma and serum, the small size and notorious fragility of platelets suggest its platelet origin.

Blood from leukaemic donors showed significantly increased thymidine phosphorylase activity compared to normal controls (mean activity ± S.D. was 96 ± 27 units; range 58–140, n = 8).

Thymine formation from thymidine was temperature- and pH-depdendent in whole blood. 2′-Deoxyuridine and 3 of its 5-halogenated analogues (but not 3′-azido-3′-deoxythymidine (AZT), were catabolised by blood thymidine phosphorylase, even during blood clotting at room temperature. Assumptions about in vivo concentrations of these compounds should therefore be interpreted cautiously.

In the presence of high concentrations of thymine and suitable deoxyribose donors, small amounts of thymidine were formed in some blood samples, so it is conceivable that thymidine catabolism may be reversible in vivo under some circumstances.     

Isolation of mutants of bacteriophage T4 unable to induce thymidine kinase activity. II. Location of the structural gene for thymidine kinase.

Amber mutants of bacteriophage T4 have been isolated that induce thymidine kinase activity only after infection of a strain of Escherichia coli carrying a suppressor mutation. The activity induced when one of these mutants infected this suppressor strain is much more heat sensitive than the activity induced by wild-type T4. This indicates that this amber mutation lies within the structural gene for thymidine kinase. This gene is between fI and v on the standard T4 genetic map. A mutant of tt4 that is unable to induce thymidine kinase activity incorporates only about one-eighth as much thymidine into its DNA as phage that do induce thymidine kinase. This contrasts to the findings that the total thymidine kinase activity in extracts prepared from cells infected with phage able to induce thymidine kinase in only twice as great as the activity in cells infected with the mutant unable to induce the enzyme.     

Independent characterization of thymidine transport and subsequent metabolism in Hymenolepis diminuta--II. Purification and preliminary analysis of thymidine kinase

1. An affinity column for the purification of thymidine kinase (TK) from the cestode Hymenolepis diminuta is described. Using an epoxy-activated Sepharose 6B affinity column containing thymidine as a ligand, a 698-fold purification of thymidine kinase was obtained. 2. Thymidine kinase eluted from this affinity column was partially characterized as having an apparent Km value of 3.94 microM thymidine. This value is very similar to those observed in mammalian systems. 3. Thymidine kinase appears to be an extremely active and ubiquitous enzyme, whose primary function is to rapidly phosphorylate incoming thymidine and thus "trap" it for the cell's use, reducing efflux to a minimum. 4. The apparent Km for TK is two orders of magnitude lower than the Kt for thymidine transport. Thus, theories postulating that long-term (2 min) uptake kinetics for thymidine actually represent subsequent metabolism must look further along the thymidine phosphorylating pathway, beyond TK and its very active role.     

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.