Mutation at the APRT locus in Friend erythroleukaemia cells 2. Sensitivity to mitomycin C induced cytogenetic damage

Clone 707 of the Friend cell was compared with an APRT-deficient subclone for sensitivity to cell killing and the induction of cytogenetic aberrations by mitomycin C (MMC). Two 16-h doses of MMC were used, 0.1 and 0.15 μg/ml and cells were scored for aberrations at 16, 33 and 44 h post-treatment. The APRT-deficient subclone showed increased cell killing, a higher frequency of aberrations and a higher frequency of cells with severe cytogenetic damage. It is proposed that APRT may play a role in balancing deoxyribonucleoside triphosphate pools for DNA-repair processes.     

Nucleotide pools and mutagenic effects of alkylating agents in wild-type and APRT-deficient Friend erythroleukaemia cells

Wild-type Friend mouse erythroleukaemia cells (clone 707) were compared with adenine phosphoribosyltransferase (APRT)-deficient mutant subclones (707DAP8 and 707DAP10) for sensitivity to cell killing and mutagenesis by ethyl methanesulphonate (EMS) and methyl methanesulphonate (MMS). Cells were exposed to 0-300 micrograms/ml EMS and to 0-20 micrograms/ml MMS for a period of 16 h. A slight difference was found between wild-type cells and the two APRT-deficient subclones in terms of sensitivity to cell killing by both mutagens. The APRT-deficient subclones were, however, significantly more sensitive than wild-type cells to mutagenesis to 5-bromo-2-deoxyuridine resistance and 6-thioguanine resistance by EMS and MMS. The APRT-deficient subclones were found to have significantly decreased levels of dATP and dTTP nucleotides and decreased levels of all four ribonucleoside triphosphates (ATP, GTP, CTP and UTP) relative to wild-type cells. Wild-type Friend cells were found to have insignificant levels O6-methylguanine-DNA methyl transferase and it is suggested that the increased mutagen sensitivity of APRT-deficient cells may be due to imbalance of deoxyribonucleoside triphosphate pools during DNA excision-repair processes, or more probably due to deficiency of ATP for ATP-dependent DNA excision-repair enzymes.     

X-ray induction of 6-thioguanine-resistant mutants in division arrested, G0/G1 phase Chinese hamster ovary cells

The cytotoxic and mutagenic effect of X-irradiation was determined with Chinese hamster ovary cells arrested in the G₀/G₁ phase of the cell cycle through 9 days incubation in serum-free medium. In comparison with exponential phase cultures, the arrested cells showed increased cytotoxicity and mutation induction over the dose range of 50–800 rad. Exponential cultures showed a linear mutant frequency-survival relationship while the arrested cells showed a biphasic linear relationship. A post irradiation holding period of 24 h does not result in any change in the mutant frequency. The increased sensitivity of the arrested cells to the mutagenic effects of X-rays appears to be a cell-cycle phase phenomenon. Upon readdition of serum, the arrested cells re-enter the cell cycle in a synchronous manner, reaching S phase at 10–12 h. Cells irradiated at 5 h after serum addition, i.e. in G₁, show a similar does response for mutant frequency, while those irradiated at 10 h or later, i.e. in late G₁, S or G₂, show lower mutation induction. These observations are consistent with a chromosome interchange mechanism of mutation induction by X-rays, possibly through interactions between repairing regions of the DNA. Irradiation of cells in the G₀/G₁ phase allow more time for such interactions in the absence of semiconservative DNA replication.     

G0 chromosomal radiosensitivity in ataxia telangiectasia lymphocytes

Contrary to an earlier report, peripheral lymphocytes from 4 AT patients were not found to exhibit higher yields of unequivocal chromosome type aberrations following irradiation in the G₀ phase of the cell cycle, providing that only first post-irradiation metaphases were included in the samples (ensured by 5-bromodeoxyuridine (BrdU) incorporation and differential fluorescence or Giemsa staining). We were able, however, to confirm the earlier-reported increase in chromatid-type aberrations in the G₀-irradiated cells. AT lymphocytes were found to experience more cell-cycle delay following G₀ irradiation than normal cells. These observations appear consistent with the damaged base excision DNA-repair defect reported for AT cells.     

Thermal sensitivity of chinese hamster V79 cells related to time after plating and cell-cycle redistribution

1. 1.|Cultured Chinese hamster V79 cells were trypsinized plated and grown attached or inoculated into spinner flasks and grown in suspension from exponnential growth to plateau-phase growth and their thermal sensitivity was measured after various growth times.

2. 2.|For attached cells, cultures were trypsinized and replated either 2 h before or after heating and the results were qualitatively the same: the thermal sensitivity remained approximately the same for the first 20 h and then increased and reached a maximum at 40–70 h. During this time, cells were in an exponential growth phase, and little or no change was observed in the cell-cycle age distribution as measured by flow cytometry (FMF) or [³H]thymidine pulse ([³H]Tdr) labelling.

3. 3.|At longer times after plating, cells grew into plateau phase, and thermal sensitivity decreased and became less than for the cells in exponential growth phase at the beginning of the experiment.

4. 4.|FMF and [³H]Tdr labelling showed that cells were accumulating in G₁ phase as the population density increased and that this accumulation was maximum at about 120–140 h as cells grew into plateau phase. This would account for the decrease in heat sensitivity and the increase in radiosensivity observed in plateau-phase cells.

5. 5.|For cells cultured in suspension there was no change in thermal sensitivity while cells were in exponential growth phase, As cell entered plateau phase, thermal resistance increased and most of the cell population had accumulated in G₁ as measured by FMF.

Inter- and intra-chromosomal distribution of chromatid breaks induced by X-rays during G2 in human lymphocytes

Cultures of blood from healthy adults were irradiated 48 h after stimulation with 240 R of X-rays and fixed after various time intervals (0–2 h, 2–4 h, 4–6 h). ³HTdR was added to several cultures after irradiation. Mitotic and labelling indices were used to distinguish between two cell samples inside the irradiated G₂ population: D − cells reaching mitosis without mitotic delay and a high frequency of chromatic breaks and D + cells with mitotic delay and which, during the delay, repair most of the damage produced. After R banding 450 chromatid deletions were located in each of the two cell samples. The D + cells showed a higher frequency of breaks than the D − cells with decreasing chromosome size, in the telomeric and centromeric region and in the junction between the R + and R − bands. These results can be interpreted as indicative of a non-random distribution of repair processes both between and within chromosomes.     

Dose-response relations for dicentric yields in GO lymphocytes of man and crab-eating monkey following acute and chronic gamma-irradiations.

A comparison has been made of dicentric yields in G₀ lymphocytes between man and crab-eating monkey, Macaca fascicularis, after acute and chronic γ-irradiations. With acute irradiation (49.6 rad/min) there was no significant difference between them, but for the chronic irradiation (17.1 rad/h) a significant difference was observed between the species. When the dose-response relations were fitted to the linear-quadratic model (Y = D + βD²), the species-difference observed for chronic irradiation was almost entirely due to change in the value of β. In addition, after chronic irradiation the β-value for monkey was almost negligible, but that for man was significant. Post-irradiation incubation experiment showed that cells with dicentrics were partly eliminated during the course of chronic irradiation, because there were appreciable reductions of dicentric yields (ca. 25% for both man and monkey at 400 rad) together with mitotic indices (ca. 30% and 60% for man and monkey, respectively, at 400 rad). Accordingly, it would be reasonable to postulate that G₀ repair for dicentrics other than selection mechanism must play a major role in the effects of low dose rate. It can be further suggested that G₀-repair capacity for chromosal damages leading to dicentrics may be different among different primate species.     

Cyclin gene expression and growth control in normal and neoplastic human breast epithelium

Recent advances in defining the molecular mechanisms of cell cycle control in eukaryotes provide a basis for beter understanding the hormonal control of cell proliferation in normal and neoplastic breast epithelium. It is now clear that a number of critical steps in cell cycle progression are controlled by families of serine/threonine kinases, the cdks. These kinases are activated by interactions with various cyclin gene products which form the regulatory subunits of the kinase complexes. Several families of cyclins control cell cycle progression in G₁ phase, cyclins C, D and E, or in S, G₂ and mitosis, cyclins A and B. Recent studies have defined the expression and regulation of cyclin genes in normal breast epithelial cells and in breast cancer cell lines. Following growth arrest of T-47D breast cancer cells by serum deprivation restimulation with insulin results in sequential induction of cyclin genes. Cyclin D1 mRNA increases within 1 h of mitogenic stimulation and is followed by increased expression of cyclins D3 and E in G₁ phase, cyclin A in late G₁/early S phase and cyclin B1 in G₂. Similar results were observed following epidermal growth factor stimulation of normal breast epithelial cells. Other hormones—oestrogens and progestins—and growth factors—insulin-like investigated for their effects on G₁ cyclin gene expression. In all cases there was an excellent correlation between the induction of cyclin D1 mRNA and subsequent entry into S phase. Furthermore, growth inhibition by antioestrogens and concurrent G₁ arrest were preceded by an acute decrease in cyclin D1 gene expression. These observations suggest a likely role for cyclin D1 in mediating many of the known hormonal effects on cell proliferation in breast epithelial cells.     

Targeted deletion of mouse Rad1 leads to deficient cellular DNA damage responses

The Rad1 gene is evolutionarily conserved from yeast to human. The fission yeast Schizosaccharomyces pombeRad1 ortholog promotes cell survival against DNA damage and is required for G₂/M checkpoint activation. In this study, mouse embryonic stem (ES) cells with a targeted deletion of Mrad1, the mouse ortholog of this gene, were created to evaluate its function in mammalian cells. Mrad1^-/- ES cells were highly sensitive to ultraviolet-light (UV light), hydroxyurea (HU) and gamma rays, and were defective in G₂/M as well as S/M checkpoints. These data indicated that Mrad1 is required for repairing DNA lesions induced by UV-light, HU and gamma rays, and for mediating G₂/M and S/M checkpoint controls. We further demonstrated that Mrad1 plays an important role in homologous recombination repair (HRR) in ES cells, but a minor HRR role in differentiated mouse cells.     

Nucleoside analog cytotoxicity and bystander cell killing of cancer cells expressing Drosophila melanogaster deoxyribonucleoside kinase in the nucleus or cytosol.

We have recently shown that the overexpression of Drosophila melanogaster multisubstrate deoxyribonucleoside kinase (Dm-dNK) in cancer cell lines increases the cells' sensitivity to several cytotoxic nucleoside analogs and the enzyme may accordingly be used as a suicide gene in combined gene/chemotherapy treatment of cancer. To further characterize the enzyme for possible use as a suicide gene, we constructed a replication-deficient retroviral vector that expressed either the wild-type enzyme that localizes to the cell nucleus or a mutant (arg247ser) that localizes to the cytosol. A thymidine kinase-deficient osteosarcoma cell line was transduced with the recombinant virus and we compared the sensitivity and bystander cell killing when the cell lines were incubated with the pyrimidine nucleoside analogs (E)-5-(2-bromovinyl)-2'-deoxyuridine and 1-beta-D-arabinofuranosylthymine. In summary, we showed that the cells' sensitivity and the efficiency of bystander cell killing were not dependent on whether Dm-dNK was located in the nucleus or cytosol.     

Radiosensitization of human T-cell leukemia by thymidine and 41.8 degrees C hyperthermia in vitro

This study tested whether thymidine, a naturally occurring nucleoside metabolite, could increase the sensitivity of human T-cell neoplasms to ionizing irradiation and whether adding 41.8 degrees C hyperthermia (X 1 h) to the combination of thymidine and irradiation would further enhance killing of cells by radiation. The magnitude of cytotoxicity induced directly by thymidine was also evaluated. Finally, the ability of 2'-deoxycytidine to prevent thymidine-induced cytotoxicity and radiosensitization was studied. Using JM and MOLT3, two human T-cell acute lymphoblastic leukemias, it was found that thymidine itself was cytotoxic and the toxicity appeared rapidly upon exposure to the drug (i.e., at 4 h). Thymidine caused significant radiosensitization, and thymidine plus 1 h of 41.8 degrees C hyperthermia enhanced radiation-induced killing significantly more than did thymidine or hyperthermia separately. The addition of 2'-deoxycytidine only partly reversed thymidine-induced killing and did not prevent thymidine-induced radiosensitization. The applicability of these results to the clinical management of T- and null-cell malignancies is discussed, as is the presumed mechanistic basis for these observations relative to deoxyribonucleoside metabolism, NAD metabolism, and inhibition of poly(ADP-ribose) polymerase.     

Cell cycle dependence of cytotoxicity and clastogenicity induced by treatment of synchronized human diploid fibroblasts with sodium fluoride

To study the cell cycle dependence of cytotoxicity and clastogenicity of sodium fluoride (NaF), synchronized human diploid fibroblasts were treated with NaF during different phases of the cell cycle and analyzed. Exponentially growing cells were synchronized by the following two procedures. (1) The cells were synchronized at G₀/G₁ phase by a period of growth in medium containing 1% serum (low serum medium). (2) The cells were synchronized at the G₁/S boundary by growth in low serum medium, followed by hydroxyurea treatment (Tsutsui et al., 1984a). Synchronized cells were treated with NaF for 3 h during the G₁ phase or G₂ phase, and for each of three 3-h periods during the S phase which lasted 9 h. Cytotoxicity, as determined by a decrease in colony-forming ability, was dependent upon the phase of the cell cycle during which NaF treatment was administered. The highest lethality was induced in when the cultures were treated with NaF during the second or third 3 h of S phase (middle or late S phase, respectively), or G₂ phase. Little lethality was observed in cultures in G₁ phase. Inducibility of chromosome aberrations of the cells following treatment with NaF was also dependent upon the phase of the cell cycle. A significant increase in the incidence of chromosome aberrations was observed only in cultures treated with NaF during early and / or middle S phases of cell cycle. These results suggest that cytotoxicity and clastogenicity of NaF to cultured human diploid fibroblasts are cell cycle dependent, and that the cells in early and middle S phases are more sensitive to the effects.     

Control of thymidine kinase synthesis in IHD vaccinia virus-infected thymidine kinase-deficient LM cells.

The synthesis of vaccinia virus-induced thymidine kinase is normally arrested several hours after infection. In thymidine kinase-deficient LM cells infected with IHD strain of vaccinia virus, arrest occurs whether or not viral DNA synthesis is inhibited. With virus inactivated by UV irradiation, enzyme synthesis takes place, but arrest is abolished. It is suggested that an early viral genetic function is responsible for the cessation of thymidine kinase synthesis.     

Comparison of two aposymbiotic ciliate clones of Climacostomum virens by their ability for reinfection

The ability of two aposymbiotic (algae-free) subclones of the same green clone of C. virens to establish a stable symbiotic association with Chlorella sp. has been studied by light and electron microscopy. Alga-free subclone No. 1 was obtained from the original green clone by a long-term cultivation in darkness, while subclone No. 2 originated from one cell that spontaneously lost the algae and was found among normal green cells during daily inspection. For infection, algae isolated from ciliates with chlorellae of parental clone of C. virens were used. 5-10 minutes after feeding with Chlorella, specimens of both subclones show numerous algae mostly inside food vacuoles, but some rare algae (3-4 per cell) may occur in individual perialgal vacuoles. Later on, the number of symbiotic chlorellae in ciliates of subclone No. 1 increased, and a stable symbiotic association was reestablished. Unlike, in specimens of subclone No. 2 all newly ingested algae were seen digested within food vacuoles. Within 24-28 h all the ciliates investigated appeared free of algae. However, obviously stable symbiotic ciliate-algae systems in this subclone were obtained after improving the microinjection technique. Injection of algae into alga-free ciliates resulted in maintenance of intact chlorellae in these ciliates. The algae were seen to be located individually within perialgal vacuoles, being presumably protected against host lytic enzyme attack. The endosymbiont population in ciliates was established from as many as 3-5 originally injected algae. The number of symbiotic chlorellae increased steadily reaching the value equal to that in the parental clone 28-30 days after the start of experiment.     

Interaction of low-dose irradiation with subsequent mutagenic treatment: role of mitotic delay

Experiments were carried out with human lymphocytes to test whether there was any relation between the changes that conditioning treatment can produce in cell progression or in mitotic delay induced by the challenge dose and the presence of an ‘adaptive response’ (AR). In experiments in which the cells were successively fixed after the challenge dose, the interaction between conditioning treatment and challenge was of the same sign for all the fixation times: therefore it is likely that modifications of the cytogenetic damage in primed cells is not a mere reflection of stage sensitivity. In experiments in which using 1 Gy as conditioning treatment we induced a drastic extension of G₂, we did not observe any AR; therefore, even if conditioning treatment can induce modifications in the cell-cycle phases before and/or after challenge, there is probably no link between these modifications and the presence of an AR.     

Azacytidine induces reversion of thymidine kinase deficiency in Friend erythroleukemia cells

Cells of the Friend erythroleukemia cell line show a high frequency of variants which have lost thymidine kinase activity. We have exposed a thymidine kinase-deficient clone of this cell line to a series of concentrations of azacytidine and found a dose-dependent induction of thymidine kinase-positive revertants. Maximum reversion occurred with 0.9 micrograms/ml azacytidine where the frequency of revertants amongst survivors was increased by a factor of 10(6) compared to that of control cultures. Revertants were found to have varying levels of thymidine kinase activity. We conclude that DNA methylation of one or both alleles of the thymidine kinase gene is largely responsible for the instability of this gene in Friend erythroleukemia cells.     

Dynamcis of the thymidine triphosphate pool during the cell cycle of synchronized 3T3 mouse fibroblasts

To investigate whether resting cells of 3T3 mouse fibroblasts carry out de novo synthesis of deoxyribonucleoside triphosphates, we determined the turnover of the thymidine triphosphate pool of G₀ cells obtained by starvation of cultures for platelet-derived growth factor. These cells were contaminated by less than 1% S-phase cells. In the absence of deoxyribonucleosides in the medium one million G₀ cells contained 5 pmole of dTTP with a turnover of 0.09 pmole/min. S-phase cells in comparison contained a 20 times larger dTTP pool with a more than 200-fold faster turnover. Our results suggest that G₀ cells carry out a slow but finite de novo synthesis of deoxyribonucleoside triphosphates to satisfy the cells' requirement for DNA repair and mitochondrial DNA synthesis.     

Static Cytofluorometry and Fluorescence Morphology of Mitochondria and DNA in Proliferating Fibroblasts

The shape, distribution, and content of mitochondria in individual cells were examined during the cell cycle phases (G₀/G₁, S, G₂ mitosis) in living human fibroblasts by static cytofluorometry and fluorescence microscopy. The morphocytochemical evaluations were performed in cell cultures submitted to double supravital fluorochrome staining with Hoechst 33342 and DiOC₆ to label DNA and mitochondria, respectively. The staining modalities were based on the stability of mitochondrial labeling. The G₁ to early S phases were characterized by the presence of filamentous mitochondria, except during the early postmitotic period. During late S, G₂, and mitotic phases, mitochondrial mass reached its highest value and mitochondria became short and numerous. During the last stage of mitosis, mitochondria were distributed among daughter cells through a cytoplasmic bridge.     

Effect of pyridoxine on tumor necrosis factor activitiesin vitro

Clinical trials with tumor necrosis factor (TNF) as an antitumor agent have so far given rather disappointing results. In this study we show that the naturally occuring vitamin B₆ compound, pyridoxine, enhances TNF-induced cytolysis of three subclones of a mouse fibrosarcoma cell line (WEHI 164). The degree of pyridoxine-induced enhancement of TNF cytotoxicity seems to be dependent on the cells sensitivity to TNF, as the enhancement was much more pronounced in the relatively TNF resistant subclone act-R(cl.12)-WEHI 164, than in the very TNF sensitive subclone WEHI 164 clone 13. Furthermore, our study shows that pyridoxine, in contrast to its enhancing effect on TNF-induced cytotoxicity, rather inhibits TNF-induced growth of human FS-4 fibroblasts. Pyridoxine also enhances lymphotoxin (LT)-induced tumor cell killing and inhibits LT-induced fibroblast growth. Pyridoxine is a relatively non-toxic agentin vivo. Our results suggest that a combination of TNF and pyridoxine may be more efficient than TNF alone, in the treatment of cancer patients.     

Radiation induced chromosomal instability in human T-lymphocytes

Chromosomal instability in proliferating mammalian cells is characterized by a persistent increase of chromosomal aberrations and rearrangements occurring de novo during successive cell generations. Recent results from many laboratories using a variety of cells and cytogenetic end points show that this phenotype can be induced by low as well as high LET irradiation. A typical feature of chromosomal instability in primary human G₀-lymphocytes exposed to γ-irradiation at both high dose rate (45 Gy h⁻¹) and low dose rate (0.024 Gy h⁻¹) is the appearance of novel aberrations in the clonal progeny of the irradiated cell, many generations after the exposure. The same phenotype was observed in lymphocytes that were allowed to recover for 5 days in G₀ after the radiation exposure, as well as in hprt-mutant T cell clones. These results demonstrate that neither the acute genotoxic stress caused by high dose rate as compared to low dose rate irradiation, nor a hypothesized conflict between mitogen induced growth stimulation and growth arrest due to radiation damage, seem to be critical conditions for the development chromosomal instability in these cells. In contrast to observations in other cells, no evidence of a persistent decrease of cloning ability was observed in the progeny of radiation-exposed human lymphocytes, and no alteration was observed in their sensitivity to a second radiation exposure. Furthermore, the frequency of CA-repeat length variation at three loci was not increased in the progeny of X-irradiated T cells as compared to non-irradiated cells, which indicates that microsatellite instability is not part of the chromosomal instability phenotype in human T-lymphocytes.