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.     

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.     

Mutant varicella-zoster virus thymidine kinase: correlation of clinical resistance and enzyme impairment.

Varicella-zoster virus (VZV) encodes a thymidine kinase (EC 2.7.2.21) which phosphorylates several antiviral nucleoside analogs, including acyclovir (ACV). A mutation in the VZV thymidine kinase coding sequence, resulting in an arginine-to-glutamine substitution at amino acid residue 130 (R130Q), is associated with clinical resistance to ACV. We have expressed the wild-type and the mutant enzymes in bacteria and have studied the kinetic characteristics of the purified enzymes. The arginine-to-glutamine substitution resulted in decreased catalytic activity and altered substrate specificity. The most striking effect was a decrease in the rates of nucleoside phosphorylation to less than 2% of the rates with the wild-type enzyme. This was accompanied by increased apparent Km values for thymidine and deoxycytidine. ACV was not detectably phosphorylated by the R130Q enzyme but still competed with thymidine for the enzyme. The inability of the R130Q enzyme to catalyze the phosphorylation of ACV correlates with resistance to ACV noted with a clinical isolate of VZV.     

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.     

Characterization of new regulatory mutants of bacteriophage T4. II. New class of mutants.

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.     

Thymidine incorporation in nucleoside transport-deficient lymphoma cells

Nucleoside transport deficiency in mammalian cells is associated with an inability to transport most nucleosides, growth resistance to a spectrum of cytotoxic nucleosides, and a loss of binding sites for 4-nitrobenzylthioinosine (NBMPR), a potent inhibitor of nucleoside transport. The nucleoside transport-deficient S49 T lymphoma cell line, AE1, however, was almost as capable of incorporating thymidine into TTP as the wild type parent provided thymidine was administered at a sufficiently high concentration. Consequently, AE1 cells were just as sensitive as wild type cells to the toxicity of high thymidine concentrations. In contrast, AE1 cells were highly resistant to almost all other cytotoxic nucleosides including the thymidine analogs, 5-bromodeoxyuridine and 5-fluoro-2'-deoxyuridine 5'-monophosphate. Despite having demonstrable ability to accumulate TTP, AE1 cells were unable to grow on hypoxanthine-amethopterin-thymidine (HAT)-containing medium. This was due to their inability to accumulate sufficient TTP from the low concentrations of thymidine present in HAT medium. AE1 cells possessed an incomplete thymidine transport deficiency, the extent of which was concentration dependent. The residual capacity for thymidine transport present in AE1 cells was insensitive to inhibition by 4-nitrobenzylthioinosine and could account both for their inability to grow on HAT medium and their sensitivity to cytotoxic concentrations of thymidine. Another nucleoside transport-deficient cell line, FURD-80-3-6, was similar to the AE1 cell line in its growth phenotype and NBMPR-binding site deficiency but differed in its decreased growth sensitivity to thymidine. That nucleoside transport deficiencies may vary in their completeness for different nucleosides has significance for the mechanism by which a single transporter can recognize a wide variety of nucleosides.     

Mapping and identification of the vaccinia virus thymidine kinase gene

The thymidine kinase gene of vaccinia virus (VV) was mapped on the viral genome by using cloned fragments of the viral DNA to hybridize to early viral mRNA. Individual DNA fragments that represented about half of the viral genome were assayed, both for their ability to arrest the cell-free synthesis of active VV thymidine kinase and for their ability to select functional mRNA for the viral enzyme. Both activities were located in HindIII fragment J, which maps near the middle of VV DNA and contains about 2.6% of the genome (4,800 base pairs). This DNA fragment encodes four known early polypeptides, and to determine which of these was thymidine kinase, early VV mRNA was fractionated by sucrose gradient centrifugation and used to direct cell-free synthesis of the active enzyme. The thymidine kinase mRNA cosedimented with several species that encoded polypeptides in the molecular weight range 15,000 to 25,000. Hybridization of these mRNAs to HindIII-J DNA selected a message that directed the synthesis of thymidine kinase and a single polypeptide with an apparent molecular weight of 19,000. The native molecular weight of VV thymidine kinase is about 80,000, so these data indicate that, unlike thymidine kinase from several other sources, the active VV enzyme is probably a tetramer of 19,000-molecular-weight subunits.     

In vitro transcription analysis of rpoD in Pseudomonas aeruginosa PAO1

Thymidine kinase type II is an important part of the pyrimidine salvage pathway. The thymidine kinase gene from the thermophilic eubacterium Rhodothermus marinus was cloned, sequenced and overexpressed. The gene is 639 bp and encodes a protein of 213 amino acids with a calculated molecular mass of 23.6 kDa. It shows homology to other thymidine kinase proteins from eukaryotic and prokaryotic organisms. The recombinant protein is inhibited by dNTPs but not by dNDPs. It is a tetramer in its native state. Its optimum temperature of activity is 65 degrees C and it has a half life of 15 min at 90 degrees C. This is the first thymidine kinase to be described from a thermophilic bacterium.     

Translational compensation of a frameshift mutation affecting herpes simplex virus thymidine kinase is sufficient to permit reactivation from latency

Herpes simplex virus thymidine kinase is important for reactivation of virus from its latent state and is a target for the antiviral drug acyclovir. Most acyclovir-resistant isolates have mutations in the thymidine kinase gene; however, how these mutations confer clinically relevant resistance is unclear. Reactivation from explanted mouse ganglia was previously observed with a patient-derived drug-resistant isolate carrying a single guanine insertion within a run of guanines in the thymidine kinase gene. Despite this mutation, low levels of active enzyme were synthesized following an unusual ribosomal frameshift. Here we report that a virus, generated from a pretherapy isolate from the same patient, engineered to lack thymidine kinase activity, was competent for reactivation. This suggested that the clinical isolate contains alleles of other genes that permit reactivation in the absence of thymidine kinase. Therefore, to establish whether thymidine kinase synthesized via a ribosomal frameshift was sufficient for reactivation under conditions where reactivation requires this enzyme, we introduced the mutation into the well-characterized strain KOS. This mutant virus reactivated from latency, albeit less efficiently than KOS. Plaque autoradiography revealed three phenotypes of reactivating viruses: uniformly low thymidine kinase activity, mixed high and low activity, and uniformly high activity. We generated a recombinant thymidine kinase-null virus from a reactivating virus expressing uniformly low activity. This virus did not reactivate, confirming that mutations in other genes that would influence reactivation had not arisen. Therefore, in strains that require thymidine kinase for reactivation from latency, low levels of enzyme synthesized via a ribosomal frameshift can suffice.     

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.     

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.     

Purification of thymidine kinase by affinity chromatography with an enzyme inhibitor as the ligand

An affinity column for the purification of thymidine kinase is described. The ligand in this column is a glycoprotein isolated from rat kidney. This glycoprotein inhibits phosphorylation of thymidine in cultured cells and in a cell-free assay system. With an affinity column containing the glycoprotein as a ligand, a 24-fold purification of thymidine kinase from an ammonium sulfate fraction of a crude tissue extract can be obtained. Thymidine kinase eluted from the affinity column migrates as one major band on polyacrylamide and as one diffuse major band on sodium dodecyl sulfate-polyacrylamide. The affinity column, with thymidine kinase bound to the inhibitor, can also be used as an assay system. When the glycoprotein is covalently attached to Sepharose, it retains its binding capacity for thymidine kinase but has apparently lost its ability to inhibit the enzyme. Thymidine kinase eluted from the affinity column is again sensitive to the glycoprotein. It seems to be a carbohydrate moiety of the glycoprotein that is responsible for the inhibition.     

Human thymidine kinase gene: molecular cloning and nucleotide sequence of a cDNA expressible in mammalian cells.

A cDNA containing the entire coding region of the human thymidine kinase gene has been molecularly cloned. The cDNA is under the control of a simian virus 40 promoter and is expressible in mammalian cells. The complete nucleotide sequence of the human thymidine kinase cDNA has been determined. The cDNA is 1,421 base pairs in length and has a large open reading frame of 702 base pairs capable of specifying a protein with a molecular weight of 25,504. Genomic Southern blotting experiments show that sequences homologous to the human thymidine kinase cDNA are conserved among many vertebrates, including prosimians (lemur), tree shrews, rats, mice, and chickens. Direct comparison of the nucleotide sequences of the human thymidine kinase cDNA and the chicken thymidine kinase gene reveals ca. 70% overall homology. This homology is extended further at the amino acid sequence level, with greater than 74% amino acid residues matched between the human and chicken thymidine kinase proteins.     

Identification of true thymidine kinase in Tetrahymena pyriformis ST.

Thymidine kinase is present in the cytoplasm (outside mitochondria) of Tetrahymena pyriformis. Previous workers have been unable to find a specific thymidine kinase activity in this organism. The cytoplasm of Tetrahymena contained a thymidine phosphorylating activity which was ATP dependent, was stimulated by Mg²⁺, and was inhibited by dTTP. This activity was also partly inhibited by dCTP. Although the mitochondrial fraction also exhibited ATP-dependent phosphorylation, it is not stimulated by Mg²⁺ and not significantly inhibited by dTTP. Nucleoside phosphotransferase activity is detectable both in cytoplasmic and mitochondrial fractions, although it is not clear whether they represent separate enzymes. Nucleoside phosphotransferase activity is inhibited both by NaF and by ATP. Thymidine kinase and nucleoside phosphotransferase activities were separated by polyacrylamide gel electrophoresis, establishing the presence of both enzymes in this organism. Both crude mitochondrial lysate and postmitochondrial supernatant samples exhibited similar gel electrophoretic patterns for thymidine kinase and nucleoside phosphotransferase activities. The former, however, exhibited a relatively small peak of thymidine kinase migrating at the same rate as that of the postmitochondrial supernatant. A separate peak of thymidine kinase was not found in the mitochondria of Tetrahymena.     

Purification and characterization of herpes simplex virus (type 1) thymidine kinase produced in Escherichia coli by a high efficiency expression plasmid utilizing a lambda PL promoter and cI857 temperature-sensitive repressor

The structural gene for herpes simplex virus (type 1) thymidine kinase was cloned downstream from the lambda phage high efficiency leftward promotor in a plasmid (pHETK2) also containing the gene for the lambda cI857 temperature-sensitive repressor. Thymidine kinase is synthesized as a run-on product containing the NH2 terminus of the lambda N protein. Heat inactivation of the lambda repressor by growth at 42 degrees C results in the accumulation of thymidine kinase as approximately 4% of the total soluble cellular protein. Thymidine kinase has been purified to greater than 95% homogeneity by high speed centrifugation, ammonium sulfate fractionation, and Sephadex G-100 and hydroxylapatite column chromatography. Thymidine kinase has a subunit Mr = 42,000 determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and behaves as a dimer during Sephadex G-100 chromatography and glycerol gradient centrifugation. Thymidine kinase is enzymatically active from pH 6 to 10 with maximum activity at pH 8.5. The enzyme is protected from heat inactivation by thymidine and has a half-life at 40 degrees C of 30 min in the presence of thymidine and 3 min in its absence. Thymidine kinase displays Michaelis-Menten kinetics with apparent Michaelis constants of 0.6 and 118 microM for thymidine and ATP, respectively. Iododeoxycytidine is a competitive inhibitor of thymidine with an apparent Ki of 14 microM. The anti-herpes drug acyclovir (9-[(2-hydroxyethoxy)methyl]guanine) also appears to be a competitive inhibitor of thymidine (Ki of approximately 300 microM) but requires 3,000-fold higher concentrations than thymidine to give 50% inhibition. Other nucleoside triphosphates can substitute for ATP in the kinase reaction with the exception of dTTP which appears to inhibit thymidine kinase activity by about 50% when present in concentrations equal to that of thymidine.     

Lipid peroxidation in regenerating rat liver

Rats entrained to a strictly regulated lighting and feeding schedule have been subjected to partial hepatectomy or a sham operation. In the partially hepatectomised animals the period of liver regeneration is characterised by regular bursts of thymidine kinase activity. Liver microsomes from rats, at times corresponding to maximum thymidine kinase activity, have much reduced rates of lipid peroxidation compared to control preparations: this is due in part to increased levels of lipid-soluble antioxidant at times of maximal DNA synthesis. This temporal relationship between thymidine kinase and lipid peroxidation is consistent with the view that lipid peroxidation is decreased prior to cell division.     

Thymidine phosphorylation in synchronous cultures of Tetrahymena pyriformis GL

Recently it has been established that thymidine can be phosphorylated in two ways in Tetrahymena pyriformis

1. 1. by action of thymidine kinase

2. 2. by action of nucleoside phosphotransferase.

The present report confirms that thymidine kinase is a peak enzyme during S phase. It is suggested that a different thymidine concentration in the thymidine kinase assay might explain why previous workers have been unable to find thymidine kinase in Tetrahymena.     

Regulation of mitosis onset and thymidine kinase activity during the cell cycle of Physarum polycephalum plasmodia: effect of hydroxyurea

The effects of hydroxyurea have been investigated on three events of the cell cycle, S-phase, mitosis, and the cyclic synthesis of thymidine kinase, in the synchronous plasmodium of the myxomycete Physarum. DNA synthesis was slowed down with limited action on other macromolecular syntheses and any increase of thymidine kinase that had already been triggered was indistinguishable from that of the control. When DNA synthesis was inhibited, the onset of the following cyclic increase of thymidine kinase synthesis occurred at the same time as in the control, but mitosis was delayed in a very early prophase stage. The arrest of thymidine kinase synthesis occurred after completion of the delayed mitosis. All these effects were suppressed when the action of hydroxyurea was prevented by the addition, to the medium, of the four deoxyribonucleosides. These observations show that (1). The blockage of S-phase does not prevent the nuclei from entering a very early prophase stage but does prevent them from proceeding through metaphase. (2) The transient blockage of DNA synthesis does not perturb the normal timing of the triggering of thymidine kinase synthesis. (3) The signal which triggers the arrest of thymidine kinase synthesis is postmitotic but does not require extensive DNA synthesis. The effect of hydroxyurea is not limited to an inhibition of S-phase. The blockage of DNA replication also led to the dissociation of the normal coordination between two other events of the cell cycle, mitosis and thymidine kinase synthesis. This observation could have strong implications in cell synchronization with chemical agents.