Differential response of two derivatives of the BHK21 hamster cell to thymidine

Attempts to synchronize the BHK21 hamster cell C-13 and its polyoma-transformed derivative P-183 with excess thymidine resulted in the observation that the parent cell line could be readily synchronized but the transformed derivative could not. Differences in the growth pattern indicate that excess thymidine (10 mM) stops progress of the virus-transformed derivative at all stages in the life cycle rather than exclusively in S. The data are suggestive but do not establish that the difference is a result of the presence of the virus genome.     

Thymidine as a synchronizing agent. II. Partial recovery of HeLa cells from unbalanced growth

Randomly growing cultures of HeLa-S3 cells were subjected to synchronizing treatment with excess thymidine. Unbalanced growth occurred during the thymidine treatment, but the abnormal cellular composition was found to revert to control levels so that at the time of the first mitosis following a 12–24 hour treatment with the inhibitor the cellular DNA, RNA and protein content and cell size were close to control values. However, an alkaline deoxyribonuclease which attacks denatured DNA was still found to be significantly elevated at this time. The results argue against the use of thymidine as a synchrony producing agent.     

Incorporation of deoxyribonucleosides into DNA of coryneform bacteria and the relevance of deoxyribonucleoside kinases

In order to obtain basic knowledge of the salvage pathways for DNA synthesis, the ability of Brevibacterium ammoniagenes ATCC 6872 and Micrococcus luteus ATCC 15932 for incorporation of nucleobases and nucleosides was investigated. Only adenine and uracil are incorporated by B. ammoniagenes, whereas M. luteus additionally can utilize deoxyadenosine and, less efficiently, thymidine. In M. luteus, the demonstration of deoxyadenosine kinase and thymidine kinase explains the incorporation data. Uptake of thymidine is of short duration because of rapid breakdown of exogenously supplied thymidine to thymine. At a 540-fold excess pyrimidine deoxyribonucleosides inhibit 14C incorporation from thymidine nearly totally and purine deoxyribonucleosides cut by half the uptake rate, probably by interfering with transport of thymidine. However, as no cessation of thymidine incorporation occurs at these concentrations of purine deoxyribonucleosides, incorporation is finally enhanced. During the initial period of this reduced uptake considerable protection of thymidine from breakdown to thymine is provided by deoxyguanosine, but not by deoxyadenosine. At a 108-fold excess there is actually no inhibition of thymidine uptake by deoxyguanosine and only an insignificant impairment by deoxyadenosine resulting in an ultimate enhancement of 14C incorporation up to 20% of the exogenously supplied thymidine. As there is no salvage pathway for thymidine in B. ammoniagenes due to the absence of thymidine kinase, labelling with adenine and hydrolyzing of the 'contaminated' RNA fraction with 1 M KOH is recommended for measurements of overall DNA synthesis in this strain.     

ERK1/2 mediates unbalanced growth leading to senescence induced by excess thymidine in human cells

Excess thymidine induces unbalanced growth by delaying DNA replication and subsequently induces senescence in every human cell type. Our previous studies with use of inhibitors suggested that ERK1/2 has a major role in these processes. Here we directly assessed the roles of ERK1 and ERK2 in unbalanced growth induced by excess thymidine. Knockdown of ERK2 and ERK1 by vector-based RNA interference prevented loss of colony forming ability and appearance of senescence markers induced by excess thymidine in HeLa and TIG-7 cells, respectively. Such cells continued growing in the presence of excess thymidine. Double knockdown of ERK1 and ERK2 did not improve the effects of single knockdowns of ERK1 and ERK2 in either cell types. These results demonstrate that ERK1 or ERK2 has a major role in manifestation of unbalanced growth in human cells.     

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.     

Regulation of the synthesis and activity of thymidine phosphorylase in Lactobacillus casei

Abstract: Lactobacillus casei cells grown on excess thymine or on folic acid contained low levels of thymidine phosphorylase. On the other hand, thymine starved cells and also cells of a thymidine-monophosphate-kinase-defective mutant grown on excess thymine, possessed derepressed levels. These results suggest that the synthesis of thymidine phosphorylase is regulated by the end product of the thymidine-triphosphate-biosynthetic pathway. L. casei cells lacked 2-deoxyribose-1-phosphate-mutase activity and did not grow on 2-deoxyribose or thymidine as the sole-carbon source. Growth in the presence of thymidine did not result in induction of thymidine-phosphorylase synthesis, probably due to the inability of the cell to convert it to 2-deoxyribose-5-phosphate, which is known to act as an inducer in E. coli cells. Thymidine triphosphate inhibited non-competitively the activity of thymidine phosphorylase. It was also inhibited by dihydrofolic acid.     

Thymine and Thymidine Uptake by Haemophilus influenzae and the Labeling of Deoxyribonucleic Acid

The influence of ribo- and deoxyribonucleosides and ribo- and deoxyribonucleotides on the uptake of radiolabeled thymidine and thymine by Haemophilus influenzae during growth was investigated. A nucleoside-degrading enzyme similar to that reported in Escherichia coli was found to break down thymidine unless other nucleosides were present to divert its action. The presence of other nucleosides permitted a nearly quantitative uptake of even low levels of thymidine. This quantitative uptake of thymidine in the presence of an excess of other nucleosides suggests that the uptake mechanism for thymidine is specific in this organism. Under optimal conditions, as much as 50% of the deoxyribonucleic acid (DNA) thymine was derived from exogenous thymidine. Thymine was not taken up by H. influenzae but, in the presence of purine deoxynucleosides, labeled thymine entered the cells, presumably as thymidine. Ribonucleosides or ribonucleotides inhibited thymine conversion to thymidine, but, as noted above, they were degraded by a cellular enzyme. Thus, unless the ribonucleoside level was excessively high, a cell level of growth was reached at which the inhibiting ribonucleoside was broken down and labeled thymine appeared in the cells at an increasing rate. Twenty-five per cent of the DNA thymine of this organism was labeled with exogenous thymine. The information noted above serves as the basis for isotopically labeling the DNA.     

EFFECTS OF HYPOTHYROIDISM AND UNDERNUTRITION ON DNA CONTENT AND THYMIDINE KINASE ACTIVITY DURING CEREBELLAR DEVELOPMENT IN THE RAT1,2

—The effects of hypothyroidism and several degrees of undernutrition on the development of cerebellar weight, DNA, and thymidine kinase activity were studied in young rats ranging in age from 2 to 22 days. Early propylthiouracil treatment caused a delayed cerebellar cell multiplication. The activity of cerebellar thymidine kinase was suppressed at ages 2 and 5 days and was in excess of control values on days 15 and 22, thus resulting in a delay in the developmental spectrum for thymidine kinase, and extending the time span of activity beyond that of controls. Undernutrition led to varying degrees of reduced cell proliferation at experimental ages 5, 12, and 19 days. Cerebella from the most undernourished animals showed significant differences from controls in thymidine kinase activity at ages 5 and 12 days. Comparisons between sub-groups from within the oversized litters at 5 and 12 days suggested that changes in thymidine kinase activity relate to the degree of undernutrition to which the sub-group is subjected and that during development there may be a critical degree of undernutrition at which a particular essential enzyme becomes affected. This study emphasizes the biochemical similarities and differences between neonatal hypothyroidism and undernutrition, while pointing out the difficulties which exist in biochemical separation of components of the two conditions. Further evidence is presented that thymidine kinase is responsive to hormonal stimuli during cerebellar development and may play an important role in the regulation of DNA biosynthesis in brain as well as other organs.     

Demonstration of sister chromatid differentiation in human amniotic fluid cells after partial synchronization with BrdU or dT surplus

Summary Protocols are compared demonstrating sister chromatid differentiation (SCD) in human amniotic fluid (AF) cells with and without partial synchronization. Partial synchronization both with an excess of 5-bromodeoxyuridine (BrdU) and an excess of thymidine leads to an increase of metaphases with SCD. Compared with unsynchronized cells, the rate of sister chromatid exchanges (SCE) is not increased. Studies on the late replicating X chromosome of female cells showed that the addition of mitomycin C (MMC) after releasing the thymidine block preferentially induces SCEs in late replicating regions. The partial synchronization with thymidine surplus provides a good basis for SCE experiments with AF cells and facilitates the prenatal diagnosis of diseases characterized by changes in the SCE rate.     

Mitochondrial DNA depletion and thymidine phosphate pool dynamics in a cellular model of mitochondrial neurogastrointestinal encephalomyopathy

Mitochondrial (mt) neurogastrointestinal encephalomyopathy (MNGIE) is an autosomal recessive disease associated with depletion, deletions, and point mutations of mtDNA. Patients lack a functional thymidine phosphorylase and their plasma contains high concentrations of thymidine and deoxyuridine; elevation of the corresponding triphosphates probably impairs normal mtDNA replication and repair. To study metabolic events leading to MNGIE we used as model systems skin and lung fibroblasts cultured in the presence of thymidine and/or deoxyuridine at concentrations close to those in the plasma of the patients, a more than 100-fold excess relative to controls. The two deoxynucleosides increased the mt and cytosolic dTTP pools of skin fibroblasts almost 2-fold in cycling cells and 8-fold in quiescent cells. During up to a two-month incubation of quiescent fibroblasts with thymidine (but not with deoxyuridine), mtDNA decreased to approximately 50% without showing deletions or point mutations. When we removed thymidine, but maintained the quiescent state, mtDNA recovered rapidly. With thymidine in the medium, the dTTP pool of quiescent cells turned over rapidly at a rate depending on the concentration of thymidine, due to increased degradation and resynthesis of dTMP in a substrate (=futile) cycle between thymidine kinase and 5'-deoxyribonucleotidase. The cycle limited the expansion of the dTTP pool at the expense of ATP hydrolysis. We propose that the substrate cycle represents a regulatory mechanism to protect cells from harmful increases of dTTP. Thus MNGIE patients may increase their consumption of ATP to counteract an unlimited expansion of the dTTP pool caused by circulating thymidine.     

A model of cell cycle control: effects of thymidine on synchronous cell cultures.

Further evidence is presented in support of a model for growth control in which commitment for cell division is determined by an event in the preceding cell cycle. A study was made of conditions affecting synchronous growth following treatment of murine mastocytoma cells with excess thymidine at different phases of the cell cycle. Cells were synchronized by a physical procedure involving velocity sedimentation in a zonal rotor. Pulse treatment of such cultures with thymidine at times corresponding to the S, G2, and M periods had no effect on further growth. However, addition at G1, although having no immediate effect, arrested cell growth in the next cell cycle. This temporal effect may account for the decay of synchrony observed during double thymidine blockade or thymidine-FUdR blockade. When the time interval between two such blocks was 7 hr or less, P815Y cells were arrested after one synchronous division. At this critical time a majority of cells were at, or near, G1. It is suggested that thymidine exerts a hitherto unrecognized effect at the G1 interval.     

Thymidine kinase not required for antiviral activity of acyclovir against mouse cytomegalovirus.

Previous studies of herpesvirus infections have indicated that a virus-specified thymidine kinase is required for the initial phosphorylation of acyclovir [acycloguanosine or 9-(2-hydroxyethoxymethyl)guanine] in the formation of acycloguanosine triphosphate. The latter compound accumulates in infected cells and competitively inhibits the viral DNA polymerase. We found that mouse cytomegalovirus, which does not express a thymidine kinase, was sensitive to the antiviral effects of acyclovir at a 50% inhibitory dose of approximately 0.23 microM. Acyclovir was equally effective against mouse cytomegalovirus in normal 3T3 cells and in 3T3 cells deficient in cellular thymidine kinase. Furthermore, the activity of acyclovir could not be reversed by excess thymidine, which easily reversed the antiviral activity of acyclovir against herpes simplex virus. Using a high-pressure liquid chromatography technique that easily detected acycloguanosine triphosphate in cells infected with herpes simplex virus, we could not detect acycloguanosine triphosphate in mouse cytomegalovirus-infected cells. These experiments demonstrated that the activity of acyclovir against mouse cytomegalovirus is not dependent on a thymidine phosphorylation pathway. Additional experiments are underway to determine whether acycloguanosine triphosphate is produced by another pathway in concentrations sufficient to inhibit mouse cytomegalovirus DNA polymerase.     

Cell type-dependent difference in the distribution and frequency of excess thymidine-induced common fragile sites: T lymphocytes and skin fibroblasts

Summary Common fragile sites were induced by excess thymidine in phytohemagglutin-stimulated T lymphocytes from 4 normal individuals, and skin fibroblasts from 4 normal and 5 fra(X) positive individuals. The results indicate that the frequency and distribution of excess thymidine-induced fragile sites are different between these two types of cells. The sites at 1p13 and 2p11.2, induced in both types of cells, have not previously been described, and are thus considered to be excess thymidine-specific fragile sites. These findings extend and support our previous studies on cell type-dependent difference in aphidicolin-induced common fragile sites.     

Phospholipid synthesis and degradation during the life-cycle of P815Y mast cells synchronized with excess of thymidine

1. P815Y cells synchronized with excess of thymidine incorporate choline, proline and uridine throughout the cell cycle; the rate increases two- to four-fold during the S phase, when thymidine incorporation increases more than 15-fold. 2. Choline incorporated at any stage of the cell cycle turns over in a biphasic manner; stable and unstable components are each labelled maximally during the S phase. Total phospholipid also doubles predominantly during the S phase. 3. It is concluded that, despite turnover, choline incorporation is a useful measure of net phospholipid formation during the cell cycle.     

Repair synthesis and induction of thymidine-resistant variants in mouse lymphoma cells of different radiosensitivity

An assay system has been characterised using excess thymidine (TdR) as a selective agent, and the dose-response curve for X-ray induced variants resistant to thymidine has been compared with that for X-ray induced variants resistant to 5-iodo-2-deoxyuridine (IUdR) in P388 lymphoma cells. Dose-response curves showed a linear and a dose squared component in this cell line and were similar in both selective systems. A comparison has been mae of the dose-response curves for X-ray induced thymidine resistant (TdR⁺) variants in four other lymphoma cell lines of differing radiosensitivity. When induced frequencies were compared either at the same dose or at the same survival level the most sensitive line L5178YS was found to be most mutable.Repair replication levels were measured in all cell lines but no correlation between observed levels of repair replication and mutability in the 5 cell lines was found. The data are discussed in relation to the possible involvement of repair processes in mutation induction by X-rays in mammalian cells.     

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.     

Coexpression of two thermosensitive defects in a Chinese hamster cell line : Manifestation of a G1 block associated with a mitosis defect

Asynchronous cultures of ts12, an anchorage-dependent derivative of the thermosensitive Chinese hamster cell line ts111, show a rapid drop in [3H]thymidine incorporation with accumulation of the cells in the G1 and in the G2 phases of the cycle, when shifted from 34.5 to 39.4 degrees C. Shift-up experiments carried out after either isoleucine deprivation or synchronization at 39.4 degrees C, locate the execution point of a ts function in late G1 (2.5-3 h before S). However, stimulation of proliferation of a high density-arrested population allows a fraction of the cells to enter S. In addition to the G1 ts defect, ts12 expresses a slight cytokinesis defect at 39.4 degrees C (8-15% binucleate cells). The results suggest that altered processes are taking place at a post-metaphasic stage during the first hours after the shift-up. When populations are synchronized by a thymidine block and released at 39.4 degrees C, multinucleate cells in addition to binucleate cells are observed. Part of these multinucleate cells result from abnormal karyokinesis without inhibition of cytokinesis. Evidence is presented suggesting that excess thymidine allows the re-expression of the multinucleation phenotype of ts111.     

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

Summary Novikoff rat hepatoma cells were propagated in suspension culture in the presence of 1m 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 m hypoxanthine and 30 m thymidine. The results illustrate a dependence of the growth rate of mammalian cells on the rate of transport of essential nutrients into the cell.     

Aryl hydrocarbon hydroxylase induction in mouse liver cells--relationship to position in the cell cycle

The inducibility of aryl hydrocarbon hydroxylase (AHH) by benzo[a]-pyrene (BaP) has been studied in synchronously grown cultures of mouse liver cells. These cells (NMuLi cl 8) have low basal levels of AHH which can be induced greater than 100-fold by BaP. Cells were synchronized in G1(G0) by serum starvation and in S by release from serum starvation in combination with excess thymidine. When released from G1(G0) by replating at lower cell density in fresh medium with 20% serum, cells began entering S with a lag of 12 h. Addition of BaP (1 microgram/ml) 8 h before serum stimulation, at the time of stimulation or 7.5 h after stimulation all gave similar induction kinetics: the AHH activity peaked as the cells began entering S regardless of when the BaP was added. Cells blocked in various parts of S by excess thymidine were inducible for AHH activity as efficiently as cells moving through S and into G2. These results indicate that the inducibility of AHH is greater when cells are actively proliferating and may be a contributing factor to why growing cells are more sensitive to mutagenesis and transformation than quiescent cells.     

Ethyl methanesulphonate mutagenesis with L5178Y mouse lymphoma cells: a comparison of ouabain, thioguanine and excess thymidine resistance.

Complete inhibition of growth of sensitive L5178Y mouse lymphoma cells in culture was obtained with 10(-3)M ouabain, 1.65 X 10(-3)M thymidine, 1.8 X 10(-4)M thioguanine and 10(-6)M cytosine arabinoside. The toxicity of methotrexate was dependent upon cell density and this compound was excluded from further study. The expression time before addition of the selective agent was important for detecting EMS induced resistant variants. Ouabain-resistant variants appeared immediately after treatment and were present over a broad time span. No excess thymidine- or thioguanine-resistant variants were seen initially; a peak in variant numbers was seen for excess thymidine resistance at 48-96 h and for thioguanine resistance at 144-192 h. Using induced mutation frequencies at optimum expression times, equal EMS treatments yielded substantially more variants resistant to thioguanine than to ouabain. It is suggested that this difference may have origin in possible constraints in the classes of mutants which are permissible in a vital function, maintenance of the Na+/K+ balance, when compared with a non-vital function, salvage purine biosynthesis. Some data are presented on the stability in culture of resistant variants. A limited number of observations were made following treatment in the peritoneal cavity of the mouse which were in broad agreement with the above results.