Approximation of baseline and BrdU-induced SCE frequencies

In the present paper we have developed a new rationale and an experimental schedule to approximate the frequency of SCEs which occur independently of BrdU incorporation, namely, the baseline frequency of SCEs. The method used includes the analysis of SCE yields in second and third division chromosomes after BrdU-substitution for 1, 2, and/or 3 successive replication rounds in the presence of this thymidine analogue, leading to a set of ten different experimental results. As a result of formulating various mathematical equations and applying them to the data, an accurate estimation of the frequency of baseline (BrdU-independent) and BrdU-induced SCEs, can be made, thus avoiding the difficulties inherent in the current extrapolation methods. The conclusions are that 1) SCEs seem to be formed after DNA synthesis (by exchanging post-replicative DNA portions), but, obviously, very near to the replication fork and 2) that under our experimental conditions about 0.065 SCEs per picogram of DNA per cell cycle occur as a consequence of chromosome replication, this frequency being increased by BrdU-substitution. The methodology seems to be reliable enough to be used in other species and systems in order to compare baseline SCE frequencies.Abbreviations SCEs sister-chromatid exchanges - BrdU(BrdUrd) 5-bromodeoxyuridine - dTh(dThd) thymidine - ³H-dTh(³H-dThd) tritiated thymidine - FdU(FdUrd) 5-fluorodeoxyuridine - Urd uridine - FPG fluorescent plus Giemsa     

Disparate effects of 5-bromodeoxyuridine on sister-chromatid exchanges and chromosomal aberrations in Bloom syndrome fibroblasts

The existence of a high frequency of spontaneous sister-chromatid exchanges (SCEs) in Bloom syndrome (BS) has thus far been supported by data on a small number of BS cell lines. To examine the cause of baseline SCEs more broadly, the frequencies of SCEs, as well as chromosomal aberrations (CAs) in 4 additional BS fibroblast strains were compared, under different assay and cell culture conditions, with those of normal cells in the range of approximately 0.9-90% 5-bromodeoxyuridine (BrdUrd) substitution into template DNA. SCEs at low levels of BrdUrd substitution were detected by an extremely sensitive immunofluorescent technique. From approximately 0.9% to 4.5% BrdUrd substitution, the SCE frequency in BS cells remained constant, at a level (40/cell) 8 times higher than that of normal cells. As BrdUrd substitution increased further, the SCE frequency in BS cells increased almost linearly, reaching 70-100 per cell at approximately 90% substitution, while the SCE increment in control fibroblasts was less than 5 per cell. Analysis of SCEs in 3 successive replication cycles similarly revealed that the SCE increment in BS cells depended on BrdUrd only at a high BrdUrd substitution level. In contrast to data on SCEs, CA induction by incorporated BrdUrd in BS cells was only slightly higher than that in normal cells. Thus, BS cells are extremely sensitive to BrdUrd for SCE induction, but much less so for CA induction.     

Analysis of bromodeoxyuridine-induced single and twin sister chromatid exchanges in tetraploid Chinese hamster ovary cells

Culture of cells in high exogenous levels (>10^–4 M) of bromodeoxyuridine (BrdUrd) or thymidine will increase the baseline sister chromatid exchange (SCE) frequency. The effect is thought to be related to the balance of the DNA precursors thymidine and deoxycytidine. Exogenous addition of deoxycytidine will reverse this effect. Single and twin SCEs were analysed in Colcemid-induced tetraploid Chinese hamster ovary cells exposed to different concentrations of BrdUrd to determine at what stage SCEs are induced by high levels of BrdUrd. In cells exposed to low concentrations of BrdUrd (10^–5 M), equal numbers of SCEs were induced in each of the two cell cycles. With increasing concentrations of BrdUrd (10^–4 to 2×10^–4 M), SCE frequency increased in both cell cycles, but far more SCEs were induced in the second cell cycle. Deoxycytidine (2×10^–4 M) reduced the frequency of SCEs primarily by reducing the frequency of SCEs induced in the second cell cycle. Treatment with 3-aminobenzamide (3AB), a potent inhibitor of poly(ADP-ribose) polymerase, produced effects similar to exposure to high levels of BrdUrd including inducing SCEs in the second replication cycle. This suggests a similar mechanism of action. Deoxycytidine had no effect on 3AB-induced SCEs, however, and there was no interaction between 3AB and high exogenous levels of BrdUrd in SCE induction. Thus these two agents probably act through different mechanisms.     

Presence of a Base Line Level of Sister Chromatid Exchanges in Somatic Cells of DROSOPHILA MELANOGASTER IN VIVO and IN VITRO

Sister chromatid exchanges (SCEs) under in vivo and in vitro conditions were examined in ganglion cells of third-instar larvae of Drosophila melanogaster (Oregon-R). In the in vivo experiment, third-instar larvae were fed on synthetic media containing 5-bromo-2'-deoxyuridine (BrdUrd). After two cell cycles, ganglia were dissected and treated with colchicine. In the in vitro experiment, the ganglia were also incubated in media containing BrdUrd for two cell cycles, and treated with colchicine. SCEs were scored in metaphase stained with Hoechst 33258 plus Giemsa. The frequencies of SCEs stayed constant in the range of 25-150 micrograms/ml and 0.25-2.5 micrograms/ml of BrdUrd in vivo and in vitro, respectively. SCEs gradually increased at higher concentrations, strongly suggesting that at least a fraction of the detected SCEs are spontaneous. The constant levels of SCE frequency were estimated, on the average, at 0.103 per cell per two cell cycles for females and 0.101 for males in vivo and at 0.096 for females and 0.091 for males in vitro. No difference was found in the SCE frequency between sexes at any of the BrdUrd concentrations. The analysis for the distribution of SCEs within chromosomes revealed an extraordinarily high proportion of the SCEs at the junctions between euchromatin and heterochromatin; the remaining SCEs were preferentially localized in the euchromatic regions of the chromosomes and in the heterochromatic Y chromosome. These results were largely inconsistent with those of Gatti et al. (1979).     

Presence of abnormally high incidences of sister chromatid exchanges in three successive cell cycles in Bloom's syndrome lymphocytes

The frequencies of sister chromatid exchanges (SCEs) were examined in phytohaemagglutinin-stimulated blood lymphocytes of a normal individual, a Bloom's syndrome heterozygote (bl/+), and two Bloom's syndrome homozygotes (bl/bl). To determine the baseline SCE frequencies, lymphocytes were cultured with various concentrations of 5-bromodeoxyuridine (BrdUrd) for two cell cycles. The incidence of SCEs per two cell cycles inbl/bl lymphocytes levelled off at BrdUrd concentrations below 10 g/ml while that in normal andbl/+ lymphocytes stayed constant below 7.5 g/ml. The baseline SCE frequency in bl/bl cells was ten times higher than that in normal andbl/+ cells. At BrdUrd concentrations above 15 g/ml, SCEs inbl/bl cells were induced more frequently than in normal andbl/+ cells. These results indicate that at low concentrations BrdUrd has a minimal effect on the induction of SCEs in all individuals, while at higher concentrations the BrdUrd incorporated inbl/bl cells has a larger effect than that in normal andbl/+ cells. To elucidate the effect of BrdUrd incorporated into the daughter and parental DNA strands on SCE induction, SCEs occurring during each cell cycle were examined separately in three-way or two-way differentially stained, third-cycle metaphases. The incidence of SCEs detected in each cell cycle at 5 g/ml BrdUrd was constant in all individuals and the rates of SCEs in each cell cycle inbl/bl cells were remarkably higher than those observed in normal andbl/+ cells. These findings strongly indicate that most of the abnormally increased SCEs in thebl/bl cells used in our study occurred independently of any effect of BrdUrd incorporated into both the daughter and parental DNA strands. In addition, an abnormal response ofbl/bl cells to BrdUrd was not found for cell cycle progression or chromosomal aberration induction. Thus, the bl/bl cells did not exhibit an abnormal hypersensitivity to BrdUrd. From these results, it seems quite probable that the abnormally increased SCEs in thebl/bl lymphocytes used here were spontaneous.     

Three-way differential staining of sister chromatids in M3 chromosomes : Evidence for spontaneous sister chromatid exchanges in vitro

Three types of Giemsa differential staining of sister chromatids were observed in HeLa cells when they were exposed continuously to 5-bromodeoxyuridine (BrdUrd) for three replication cycles. In type-1, about a half set of chromosome complements were composed of pairs of darkly-stained and intermediately-stained chromatids; the other half consisted of pairs of intermediately-stained and lightly-stained chromatids. In type-2, one fourth of chromatids was stained darkly and the remaining ones were stained lightly. In type-3, about a half set of chromosomes consisted of the pairs of darkly-stained and lightly-stained chromatids and the rest of pairs of intermediately-stained and lightly-stained chromatids. Cells showing each differentiation pattern at the third mitotic phase were dependent on the stages of the first DNA synthetic (S) phase at which BrdUrd treatments were initiated. Type-1 cells were observed, when BrdUrd treatment was initiated anywhere from G1 to early S phase, type-2 when treatments were begun in middle S stage, and type-3 when treatments were initiated in the late stages of the first S phase. The appearance of the three types seems to be caused by a different amount of BrdUrd incorporated into DNA between the first (S1) and the second S period (S2). The amount of BrdUrd incorporated is as follows: in type-1 S1>S2, in type-2 S1 S2 and in type-3 S2>S1.By analysing type-1 cells, all of the sister chromatid exchanges (SCEs) occurring during each replication cycle can be accurately counted and distinguished from one another. In cells exposed to BrdUrd above 5 μg/ml, the frequencies of SCEs occurring during S1, S2, and S3 are higher than those detected at lower BrdUrd concentrations. On the other hand, at lower concentrations (0.1–1.0 μg/ml) they occurred at the same frequency during S1, S2, and S3. Thus, SCEs detected at low concentrations are free from the incremental effect of BrdUrd incorporated, and enable us to estimate the spontaneous level of SCE frequency.     

The incorporation of deoxyuridine monophosphate into DNA increases the sister-chromatid exchange yield

The effect of a treatment with 5-fluoro-2'-deoxyuridine (FdUrd) in combination with 2'-deoxyuridine (dUrd) on cell proliferation, incorporation of DNA precursors into DNA and sister-chromatid exchanges (SCEs) has been analyzed in Allium cepa meristem cells. FdUrd in the range 10(-9)-5 X 10(-7) M produced a dose- and time-dependent decrease in the amount of cells in mitosis. This inhibitory effect could be reversed by 70-80% in short-term (6 h) experiments, by exogenously supplied dUrd at a concentration of 10(-4) M. However, at the highest FdUrd dose tested (10(-7) M), 10(-4) M dUrd could not reverse the FdUrd effect in long-term experiments (20 h, about one cell cycle interval), as shown by analyzing the kinetics of synchronous cell populations. DNA extracted from cells pulsed with [6-3H]dUrd in the presence of FdUrd and 6-amino-uracil (6-AU), an inhibitor of uracil-DNA glycosylase, contained a small amount of label (at least 3% of the total radioactivity incorporated into DNA) in the form of [6-3H]dUMP. Thus, we conclude that, under our experimental conditions, exogenously supplied dUrd may be metabolized intracellularly to 2'-deoxyuridine triphosphate (dUTP) and that this deoxynucleotide may eventually be mis-incorporated into DNA. As far as the formation of SCEs is concerned, analysis of second division chromosomes showed that 2'-deoxyuridine monophosphate (dUMP) residues present in newly-synthesized DNA strands are probably not relevant to SCE formation. However, by analyzing SCE levels in third division chromosomes of cells treated with FdUrd and dUrd during their second cycle, we have scored a 6-fold increase in the reciprocal SCE level which demonstrates that the replication of a dUMP-containing DNA template leads to a higher SCE yield.     

Sister-chromatid exchanges and cell-cycle kinetics in human lymphocyte cultures exposed to alkylating mutagens: apparent deformity in dose-response relationships

Experiments have been carried out using human whole-blood cultures to determine the effects of sampling times and of the duration of 5-bromodeoxyuridine (BrdUrd) treatment before fixation on sister-chromatid exchange (SCE) frequencies following exposure to mitomycin C (MMC). Cells were pulse treated for 1 h with 3 X 10(-6) M MMC at G1, and then sampled at 4-h intervals up to 88 h after stimulation of cultures with phytohemagglutinin (PHA). Results showed that this MMC treatment induced a 5-6 h proliferation delay per cell cycle, and that SCE frequencies first increased with time of fixation, peaking at 68 h, and then decreased. When cells were similarly treated with MMC, but subsequently exposed to BrdUrd for various times before fixation of cultures at 72 h, the SCE frequencies markedly increased with increasing durations of BrdUrd incubation times. These data indicate that, in mutagen-treated cultures, lymphocytes having relatively longer cell-cycle times show a higher mean frequency of SCEs. In a subsequent experiment, cells were treated for 1 h with increasing doses of MMC or 4-nitroquinoline 1-oxide (4NQO) at 0, 24, or 48 h, and then fixed at 72 h after PHA stimulation. Results showed that the optimal treatment times at which the agents could most efficiently produce SCEs were different for MMC and 4NQO, and that the dose-response curves tended to 'bend down' at very high doses; that is, treatments with very high doses induced smaller than expected numbers of SCEs. However, cells similarly treated with very high doses showed a higher, expected frequency of SCEs when sampled at 84 h, but again had a lower than expected SCE frequency when fixed at 96 h. The results indicate that there is an optimal time for sampling at which one can observe the maximum increase in SCE frequencies following mutagen exposure, and strongly suggest that the higher the dose, the later the optimal sampling time. Because of the apparent deformity of dose-response curves obtained after various treatments and sampling times, it seems necessary that extra fixation-time points be included in test protocols so as to avoid false negatives or confirm possible positives.     

Influence of incorporated 5-bromodeoxyuridine on the frequencies of spontaneous and induced sister-chromatid exchanges, detected by immunological methods

We have utilized monoclonal antibody against BrdUrd to detect sister-chromatid exchanges in CHO cells. This technique allows detection of SCEs at very low levels of BrdUrd incorporation. At incorporation level of 0.5%, a frequency of about 2 SCEs/cell/cycle was found. In a UV-sensitive mutant (43-3B) which has an increased spontaneous frequency of SCEs, it is found that this increase is due to incorporated BrdUrd. In MMS- and MMC-treated cells, an influence of BrdUrd on the frequencies of induced SCEs was found only when high concentrations of mutagens were employed.     

The effect of chlorpromazine on SCE frequency in human chromosomes: An in vitro and in vivo study

Schizophrenic patients who were receiving, or who had received chlorpromazine showed SCE levels similar to those in a normal control population. Of 8 normal individuals whose lymphocytes were exposed in vitro to chlorpromazine (0.05–2.00 μg/ml) for two cell cycles, 4 showed a significant increase in SCE, 3 showed no increase and 1 a decrease compared with untreated lymphocytes. Lymphocytes from a further 8 donors treated with 2.0 μg/ml chlorpromazine prior to mitogen stimulation (G₀ lymphocytes) showed a similar SCE response. Only 3 of the 8 donors showed a significant increase in SCEs over the baseline level. When proliferating lymphocytes were exposed to chlorpromazine 38 h after culture initiation and prior to the addition of BrdUrd to the culture medium, metaphase chromosomes from only 3 of the 8 individuals studied showed increased levels of exchange. These results indicate that chlorpromazine can induce SCEs in vitro but that there is considerable variation in SCE response among individuals. Furthermore, our data emphasises the importance of using more than 1 or 2 donors when analysing SCE response in human chromosomes.     

Induction of sister-chromatid exchanges in cultured human cells by an organophosphorous insecticide: malathion.

Because malathion is a widely used organophosphorous insecticide, the effects of non-toxic concentrations (2.5--40 micrograms/ml) on sister-chromatid exchange (SCE) frequencies were determined. Human fetal fibroblasts were exposed once or twice to malathion, with 20 h between exposures. A single exposure to a concentration of 40 micrograms/ml resulted in a highly significant increase in the number of SCEs. After a double exposure, a concentration of 20 micrograms/ml induced an even greater increase in SCE frequencies. Comparison of Sce frequencies after single and double exposures indicated a cumulative effect; the number of exchanges at concentrations of 5 micrograms/ml or higher was significantly greater after the double exposure. An analysis of SCEs by chromosome group showed that exchanges were distributed approximately according to chromosome length.     

Chromosomal instability in mutagen-sensitive mutants isolated from mouse lymphoma L5178Y cells. I. Five different genes participate in the formation of baseline sister-chromatid exchanges and spontaneous chromosomal aberrations

In a search for cell mutants that show an increase or a decrease in the frequency of baseline sister-chromatid exchanges (SCEs) or spontaneous chromosomal aberrations (CAs), large numbers of mutagen-sensitive clones previously isolated from mouse lymphoma L5178Y cells were analyzed. In addition to two SCE mutants (ES 4 and AC 12) previously reported, three other mutants were identified as an SCE mutant. An ethyl methanesulfonate-sensitive mutant ES 2 and an alkylating agent-sensitive mutant MS 1 exhibited, respectively, 1.4-fold and 1.8-fold higher baseline SCE frequencies than did the parental L5178Y. In contrast, M10, which is sensitive to X-ray and 4-nitroquinoline 1-oxide, showed a reduced frequency of baseline SCEs (0.65-fold). These 5 mutants including ES 4 and AC 12 had 3--9-fold increases in spontaneous CA frequencies. Measurement of baseline SCE formation in inter-mutant hybrids revealed that M10 mutation is dominant, MS 1 and ES 4 mutations are semidominant, and ES 2 and AC 12 mutations are recessive. Because SCE frequencies in hybrids formed between pairs of 4 mutants (ES 2, MS 1, ES 4 and AC 12) were significantly lower than those in the tetraploid mutant cells, these 4 mutants probably belong to different complementation groups. Since M10 behaved dominantly with respect to SCE phenotype, it was not possible to determine by complementation test whether it belongs to a different group from the other mutants. However, the finding that M10 is complemented by other mutants for EMS sensitivity indicates that the M10 mutation is different from the other mutations. From these results, it is concluded that at least 4 different genes participate in the formation of high levels of baseline SCEs. The defects in ES 2, MS 1, ES 4, and AC 12 produce common lesions responsible for the formation of both SCEs and CAs. In contrast, the defect in M10 is associated with a high increase in spontaneous CA frequency, but conversely associated with a decrease in baseline SCE frequency. This suggests that M10 is defective in the process involved in the formation of baseline SCEs.     

Increased sister-chromatid exchanges (SCEs) and chromosomal fragilities by BrdU in a human mutant B-lymphoblastoid cell line

From an X-irradiated human B-lymphoblastoid cell line (CCRF-SB), we have isolated a unique mutant clone (CCRF-SB-T1) which reveals high frequencies of sister-chromatid exchanges (SCEs) and chromosomal fragilities in the C-band regions of chromosomes Nos. 1, 9 and 16, when exposed to high concentrations of bromodeoxyuridine (BrdU). A clear BrdU dose-dependent increase of SCEs (9.6 SCEs/cell at 0.05 mM, 40 SCEs/cell at 0.37 mM on average) in this mutant was observed. Relative contributions of nucleoside and a thymidine (dT) analog of BrdU to high SCEs were studied, since an unusual SCE response to BrdU led us to suspect the significance of BrdU incorporation into DNA and dT pool disturbances. Addition of deoxycytidine (dC), dT or both dC and dT causes an increase of SCEs. On the other hand, deoxyadenosine (dA) and deoxyguanosine (dG) did not have significant effects on SCEs in SB-T1 cells. These results suggest that disturbances of pyrimidine-nucleotide synthesis, including gross imbalance of nucleotide pools, play a pivotal role in the high SCE induction of SB-T1 cells by BrdU.     

Metabolism of 5-fluorouracil in sensitive and resistant Novikoff hepatoma cells.

N1-S1/FdUrd Novikoff hepatoma cells, which lack thymidine kinase activity, are resistant to 5-fluorouracil (FUra) as well as 5-fluorodeoxyuridine (FdUrd), suggesting that the pathway, FUra leads to FdUrd leads to FdUMP, is utilized for the conversion of FUra to FdUMP. However, the inhibition of thymidylate synthetase activity, the presumed target of FdUMP, by 1 X 10(-4) M FUra in intact N1-S1 Novikoff hepatoma cells, which have significant levels of thymidine kinase activity, is completely eliminated by 5 X 10(-4) M hydroxyurea, which is a potent inhibitor of ribonucleotide reductase. These results imply that the formation of ribonucleotides and does not involve thymidine kinase. This apparent dichotomy can be explained by the fact that, in addition to the well known lack of thymidine kinase activity, [14C]FUra conversion to ribonucleotides is greatly depressed in the N1-S1/FdUrd cells. Hence, the formation of FdUMP from FUra in Novikoff hepatoma cells apparently proceeds primarily via the intermediate formation of ribonucleotides. The decreased conversion of FUra to ribonucleotides in N1-S1/FdUrd cells decreases not only the ability of the analog to inhibit DNA synthesis, but also its effect on RNA metabolism. FUra, at a concentration of 1 X 10(-5) M, inhibits rRNA maturation in N1-S1 cells, but not in N1-S1/FdUrd cells. Since N1-S1/FdUrd cells are completely resistant to 1 X 10(-5) M FUra, whereas N1-S1 cells are completely inhibited by 1 X 10(-5) M FUra, even in the presence of 1 X 10(-4) M thymidine, the effects of FUra on RNA metabolism appear to contribute significantly to the cytotoxicity of the analog at higher drug concentrations.     

Analysis of low concentrations of 5-bromo-2-deoxyuridine on sister chromatid exchanges in human lymphocytes

To determine a concentration of 5-bromo-2-deoxyuridine (BrdU) sufficient for sister chromatid differentiation (SCD), and yet having a minimal effect on the number of sister chromatid exchanges (SCEs), we assessed the effect produced on the number of SCEs by low concentrations (1, 3, and 10 micrograms/mL) of BrdU. SCD was not obtained in 19% of the 31 subjects with 1 microgram/mL of BrdU, while the differentiation was adequate for all samples treated with 3 and 10 micrograms/mL. We statistically analysed the effects of these three different doses and found no significant difference in the number of SCEs obtained with the doses of 1 and 3 micrograms/mL, but a significant difference was observed between these two concentrations and 10 micrograms/mL. We therefore suggest that the dose of 3 micrograms/mL, while sufficient to produce reliable differential staining, still permits an adequate evaluation of the base line of SCEs and appears to enhance the sensitivity of the test to evaluate between-individual variations. Our experiments also underline that SCE counts should include the centromere exchanges.     

The role of deoxyribonucleotide metabolism in 5-bromo-2′-deoxyuridine mutagenesis in mammalian cells

The effects of deoxyribonucleoside triphosphate (dNTP) pool imbalance on the induction of mutations and siste-chromatid exchanges (SCEs) by 5-bromo-2′-deoxyuridine (BrdUrd) in mammalian cells is reviewed. The INC BrdUrd mutagenesis protocol involves the incorporation of BrdUrd into DNA under conditions of specific dNTP pool imbalance, while the REP BrdUrd mutagenesis protocol involves the replication of 5-bromouracil (BrUra)-substituted DNA in the presence of specific (but different) dNTP pool imbalance. Biochemical and genetic analyses of both the INC and REP mutagenesis protocols provided evidence that (1) INC mutagenesis resulted from errors of incorporation due to the mispairing of BrdUTP with a guanine residue in replicating DNA leading to GC to AT transitions and (2) REP mutagenesis resulted from errors of replication due to the mispairing of dGTP with a BrURA residue in replicating DNA leading to AT to GC transitions. Further analyses involving different cell lines has led to an hypothesis describing the role of mismatch repair in the induction of mutations and SCEs.     

5-Bromodeoxycytidine in the study of sister chromatid exchanges in human lymphocytes

Summary When [³H]dC was added with a high dose (4x10^-1 mM) of dT to human blood lymphocyte cultures, much heavier labeling of interphase nuclei and metaphase chromosomes was observed compared with that in cultures treated with [³H]dC alone. This observation indicates that in the presence of excess dT, exogenous dC is included into cytosine bases of DNA, releasing the cells from the thymidine block.BrdC 5x10^-2 mM added with a high dose of dT (4x10^-1 to 1.0 mM) to the cultures did not relieve the thymidine block as determined from the percentage of metaphases of the first to third divisions. It is concluded that BrdC, in contrast to dC, is not utilized as a cytosine DNA precursor even in the presence of high concentrations of dT.The frequency of SCEs per cell was the same when studied with the aid of BrdC and BrdU used under similar conditions. The distribution of SCEs among chromosomes was also identical for both analogues: The number of SCEs was significantly higher than expected in chromosomes of group B and lower than expected in chromosomes of groups E, F, and G.     

Effect of 5-fluoro-2'-deoxyuridine (FdUrd) on 5-bromo-2'-deoxyuridine (BrdUrd) incorporation into DNA measured with a monoclonal BrdUrd antibody and by the BrdUrd/Hoechst quenching effect

The purpose of this study was to improve the application of bromodeoxyuridine (BrdUrd) for the flow cytometric analysis of cell kinetics. In order to obtain a quantitative measure of the DNA synthesis rate (or the number of divided cells), BrdUrd should replace thymidine (dThd) completely in the newly synthesized DNA strands. The de novo synthesis of dThd monophosphate competing with BrdUrd incorporation was stopped by fluorodeoxyuridine (FdUrd). Cells of a human leukemic cell line (REH) were exposed to BrdUrd for either 20 min, 8 h, or 24 h. Bromodeoxyuridine incorporation was determined by a monoclonal antibody as well as by the BrdUrd/Hoechst (H) technique. Counterstaining of the DNA was performed with propidium iodide or ethidium bromide. DNA fluorescence was measured in both techniques with a two-parameter flow cytometer, the histograms being analyzed by computer. It was found that FdUrd is required in the BrdUrd/H technique for replacement of dThd at low BrdUrd concentrations and long incubation times. With short incubation periods, as used for detection by the monoclonal anti-BrdUrd antibody, FdUrd increases the incorporated BrdUrd amount when BrdUrd concentrations of 10 microM or less are applied.     

The relationship between sister-chromatid exchange and perturbations in DNA replication in mutant EM9 and normal CHO cells

The majority of the high (12-fold elevated) baseline sister-chromatid exchanges (SCEs) that occur in the CHO mutant line EM9 appear to be a consequence of incorporated BrdUrd, and they arise during replication of DNA containing BrdUrd in a template strand. In normal CHO cells the alkaline elution patterns of DNA newly replicated on a BrdUrd-containing template are significantly altered compared with those seen during the replication on an unsubstituted template. The nascent DNA synthesized on such an altered template is delayed in reaching mature size, possibly because replication forks are temporarily blocked at sites occurring randomly along the template. Transient blockage of replication forks may be a prerequisite for SCE. The delay in replication on BrdUrd-substituted templates was greater in EM9 cells than in parental AA8 cells and was also greater in AA8 cells treated with benzamide, an inhibitor of poly(ADPR) polymerase, than in untreated AA8 cells. Under these conditions, treatment with benzamide also produced a 7-fold increase in SCEs in AA8. An EM9-derived revertant line that has a low baseline SCE frequency showed less delay in replication on BrdUrd-substituted templates than did EM9. However, under conditions where the template strand contained CldUrd, which was shown to produce 4-fold more SCEs than BrdUrd in AA8 cells, the replication delay in AA8 was not any greater in the CldUrd-substituted cells. Thus, other factors besides the delay appear to be involved in the production of SCEs by the template lesions resulting from incorporation of the halogen-substituted pyrimidine molecules.     

Lack of Spontaneous Sister Chromatid Exchanges in Somatic Cells of DROSOPHILA MELANOGASTER

Neural ganglia of wild type third-instar larvae of Drosophila melanogaster were incubated for 13 hours at various concentrations of BUdR (1, 3, 9, 27 micrograms/ml). Metaphases were collected with colchicine, stained with Hoechst 33258, and scored under a fluorescence microscope. Metaphases in which the sister chromatids were clearly differentiated were scored for the presence of sister-chromatid exchanges (SCEs). At the lowest concentration of BUdR (1 microgram/ml), no SCEs were observed in either male or female neuroblasts. The SCEs were found at the higher concentrations of BUdR (3, 9, And 27 micrograms/ml) and with a greater frequency in females than in males. Therefore SCEs are not a spontaneous phenomenon in D. melanogaster, but are induced by BUdR incorporated in the DNA. A striking nonrandomness was found in the distribution of SCEs along the chromosomes. More than a third of the SCEs were clustered in the junctions between euchromatin and heterochromatin. The remaining SCEs were preferentially localized within the heterochromatic regions of the X chromosome and the autosomes and primarily on the entirely heterochromatic Y chromosome.--In order to find an alternative way of measuring the frequency of SCEs in the Drosophila neuroblasts, the occurrence of double dicentric rings was studied in two stocks carrying monocentric ring-X chromosomes. One ring chromosome, C(1)TR94--2, shows a rate of dicentric ring formation corresponding to the frequency of SCEs observed in the BUdR-labelled rod chromosomes. The other ring studied, R(1)2, exhibits a frequency of SCEs higher than that observed with both C(1) TR94--2 and rod chromosomes.