Insights on chromosome structure from sister chromatid exchange ratios and the lack of both isolabelling and heterolabelling as determined by the FPG technique

Solution Radioactivated by Hadron Radiation Can Increase Sister Chromatid Exchanges

When energetic particles irradiate matter, it becomes activated by nuclear reactions. Radioactivation induced cellular effects are not clearly understood, but it could be a part of bystander effects. This investigation is aimed at understanding the biological effects from radioactivation in solution induced by hadron radiation. Water or phosphate buffered saline was activated by being exposed to hadron radiation including protons, carbon- and iron-ions. 1 mL of radioactivated solution was transferred to flasks with Chinese hamster ovary (CHO) cells cultured in 5 mL of complete media. The induction of sister chromatid exchanges (SCE) was used to observe any increase in DNA damage responses. The energy spectrum and the half-lives of the radioactivation were analyzed by NaI scintillation detector in order to identify generated radionuclides. In the radioactivated solution, 511 keV gamma-rays were observed, and their half-lives were approximately 2 min, 10 min, and 20 min. They respectively correspond to the beta+ decay of 15O, 13N, and 11C. The SCE frequencies in CHO cells increased depending on the amount of radioactivation in the solution. These were suppressed with a 2-hour delayed solution transfer or pretreatment with dimethyl sulfoxide (DMSO). Our results suggest that the SCE induction by radioactivated solution was mediated by free radicals produced by the annihilated gamma-rays. Since the SCE induction and DMSO modulation are also reported in radiation-induced bystander effects, our results imply that radioactivation of the solution may have some contribution to the bystander effects from hadron radiation. Further investigations are required to assess if radioactivation effects would attribute an additional level of cancer risk of the hadron radiation therapy itself.

Elevated sister chromatid exchange frequencies in New Zealand Vietnam War veterans

From July 1965 until November 1971, New Zealand Defence Force Personnel fought in the Vietnam War. During this time more than 76,500,000 litres of phenoxylic herbicides were sprayed over parts of Southern Vietnam and Laos, the most common being known as 'Agent Orange'. The current study aimed to ascertain whether or not New Zealand Vietnam War veterans show evidence of genetic disturbance arising as a consequence of their now confirmed exposure to these defoliants. A sample group of 24 New Zealand Vietnam War veterans and 23 control volunteers were compared using an SCE (sister chromatid exchange) analysis. The results from the SCE study show a highly significant difference (P < 0.001) between the mean of the experimental group (11.05) and the mean of a matched control group (8.18). The experimental group also has an exceptionally high proportion of HFCs (cells with high SCE frequencies) above the 95th percentile compared to the controls (11.0 and 0.07%, respectively). We conclude that the New Zealand Vietnam War veterans studied here were exposed to a clastogenic substance(s) which continues to exert an observable genetic effect today, and suggest that this is attributable to their service in Vietnam.

Molecular mechanisms of sister-chromatid exchange

Sister-chromatid exchange (SCE) is the process whereby, during DNA replication, two sister chromatids break and rejoin with one another, physically exchanging regions of the parental strands in the duplicated chromosomes. This process is considered to be conservative and error-free, since no information is generally altered during reciprocal interchange by homologous recombination. Upon the advent of non-radiolabel detection methods for SCE, such events were used as genetic indicators for potential genotoxins/mutagens in laboratory toxicology tests, since, as we now know, most forms of DNA damage induce chromatid exchange upon replication fork collapse. Much of our present understanding of the mechanisms of SCE stems from studies involving nonhuman vertebrate cell lines that are defective in processes of DNA repair and/or recombination. In this article, we present a historical perspective of studies spearheaded by Dr. Anthony V. Carrano and colleagues focusing on SCE as a genetic outcome, and the role of the single-strand break DNA repair protein XRCC1 in suppressing SCE. A more general overview of the cellular processes and key protein "effectors" that regulate the manifestation of SCE is also presented.

X-irradiation of G1 CHO cells induces SCE which are both true and false in BrdU-substituted cells but only false in biotin-dUTP-substituted cells

The SCE-test is widely used in genetic toxicology and therefore knowledge of the contribution of BrdU to the formation of spontaneous and induced SCE is of great importance. The present study was undertaken to analyse the role of BrdU in X-ray-induced SCE. If SCE resulted from inversions, rings and double minutes (RDM) would be the asymmetrical counterparts of SCE and should therefore have the same frequencies. Dose-effect relationships of SCE and RDM show that the frequencies of SCE are much higher than those of RDM. We conclude that only a few SCE may represent inversions. In a second set of experiments, endoreduplications were induced in cells irradiated either before or after labelling with BrdU. Analysis of SCE in endoreduplicated chromosomes allows the discrimination of the cell cycle in which they originated. The results show that SCE are only induced in the first cell cycle following irradiation of BrdU-substituted cells, indicating that labelling with BrdU is a necessary prerequisite for the formation of SCE. In order to test this directly, radiation-induced SCE frequencies were studied in cells prelabelled with BrdU or biotin-dUTP in a third set of experiments. The structure of biotin-dUTP suggests that, in contrast to BrdU, it does not give rise to radicals during irradiation. Significantly lower frequencies of SCE were observed in biotin-dUTP-substituted cells than in BrdU-labelled cells. Calculations show that nearly all SCE induced in biotin-dUTP-labelled chromosomes can be explained by chromosomal aberrations (false SCE). In contrast to this, most SCE induced by X-rays in BrdU-labelled cells are not due to chromosomal aberrations, but result from S-dependent lesions (true SCE). This clearly points towards radiation damage in BrdU-moieties as the source of DNA lesions leading to SCE.

Reversal of DNA polarity as revealed by sister chromatid exchanges in ring chromosomes

DNA polarity at sister chromatid exchange (SCE) sites were studied in ring chromosomes from Chinese hamster cells. If the polarity of DNA strands was conserved. a double-length, symmetric dicentric ring chromosome with symmetric twin SCEs appeared after two cell cycles when a SCE occurred in S1. Indeed, approximately two-thirds of double-length. symmetric ring chromosomes belonged to this class. One-third of them, however, did not show symmetric SCEs, suggesting that polarity was not always conserved. SCE counts at centromeric regions were not high enough to account the frequency (about 1/3) of apparently inverted rejoining sites. The hypothesis that the polarity of rejoining sites is either conserved or inverted and that illegitimate rejoinings are partially repaired could explain the results. Telomere-like structures or intermediate structures during double-strand repair processes may contribute to the inverted polarity.

The diplochromosome of endoreduplicated cells: a new approach to highlight the mechanism of sister chromatid exchange

Chinese hamster lung embryonic cells (CL1) were treated with colchicine in order to induce endoreduplication and subsequently with mitomycin-C (MMC) to induce exchanges within the diplochromosome. The use of chromosomal differential staining through incorporation of 5-bromodeoxyuridine, resulting in only one stained chromatid, has allowed the analysis of all classes of exchanges among the four chromatids of the diplochromosome. Three classes of exchanges may occur: intradiplochromatid exchanges (ICEs) between the two inner chromatids, cousin chromatid exchanges (CCEs) between one inner and one outer chromatid, and sister chromatid exchanges (SCEs) between the two sister chromatids of the diplochromosome. The results show that MMC treatment, in the last cell cycle of endoreduplication, as expected, significantly increases only the frequency of SCEs, whereas the frequency of ICEs and CCEs remains unchanged. This result supports replication models of formation of SCEs. Furthermore the fact that the number of ICEs does not increase means that the molecular mechanism of somatic crossing over is not related to that of SCE formation, or very rarely. The results also indicate a statistically significant lower induction of SCEs in endoreduplicated metaphases as compared with diploid ones both in control and MMC-treated cells. Such a result may be due to structural restrictions within the diplochromosome.

Uncorrected SCE levels of Bloom syndrome cells by cell hybridization with malignant cells with 14q32 structural abnormalities

Because 14q markers were frequently observed in lymphoid malignancies, we have done cell hybridization between Bloom syndrome (BS) cell lines and various malignant cell lines with and without 14q abnormalities, and noticed that BS cell hybrids which had been fused with cell lines involving 14q32 abnormalities did not decrease high SCE values in BS cells, as was observed in those of hybrids between homozygote BS. A constant fragile site was observed at 14q23 in bromodeoxyuridine (BrdU)-labeled hetero and homo BS cells. We considered the possible linkage of BrdU-induced fragility and SCE in BS cells.

Influence of low doses of BrdU and estimation of spontaneous SCE in CHO chromosomes: three-way differential staining and an immunoperoxidase method

The influence of low doses of 5-bromodeoxyuridine (BrdU) on the occurrence of sister chromatid exchanges (SCEs) during the first cell cycle, when unsubstituted DNA templates replicate in the presence of the halogenated nucleoside (SCE1) has been assessed in third mitosis (M3) Chinese hamster ovary (CHO) cells showing three-way differential (TWD) staining. In addition, lower concentrations of BrdU, not detectable by Giemsa staining, have been tested by a high resolution immunoperoxidase method (anti-BrdU monoclonal antibody) and SCEs were scored in second mitosis (M2) cells. Our findings was a dose-response curve for SCE1 that allows an estimated mean spontaneous yield of 1.32/cell per cell cycle by extrapolation to zero concentration of BrdU. On the other hand, when the total SCE frequency corresponding to the first and second rounds of replication (SCE1 + SCE2) found in M3 chromosomes was compared with the yield of SCEs scored in M2 cells grown in BrdU at doses lower than 1 microM no further reduction was achieved. This seems to indicate that SCEs can occur spontaneously in this cell line, though the estimated frequency is higher than that reported in vivo.

Enhanced expression of stomach cancer antigen derived from malignantly transformed bloom syndrome cells previously labeled with bromodeoxyuridine

Bromodeoxyuridine (BrdU) greatly enhanced expression of stomach (ST) cancer antigen (CA) that originated from a malignantly transformed Bloom syndrome (BS) cell line (BS-SHI-4M), although the expression was suppressed with a decrease in sister chromatid exchange (SCE) in the presence of deoxythymidine (dT) or deoxycytidine (dC) and enhanced with an increase in SCE with deoxyguanosine (dG) or deoxyadenosine (dA). Although the exact mechanisms for enhancing CA by BrdU treatment are unknown, these findings appeared to be of special interest because of the parallelism of CA expression and SCE alterations. The finding that BrdU enhancement of the ST CA was effective not only in the immunofluorescence (IF) protocol but also in the band appearance of Western blotting would be worthwhile as a sensitive serodiagnosis of cancer. The 118-kd band obtained from proteins of ST CA cells previously labeled with BrdU was clearly more darkly stained than that from nonlabeled cells and enabled eight weak-positive ST CA to show strong-positive levels retaining complete negativity to nonmalignant sera. Some ST cancer sera (advanced cancer), which originally gave a negative reaction in the nonlabeled condition, still inhibited negative reaction even in BrdU-labeled ST CA cells, however. The inability to detect cancer antibody in our assay might be due to immunocomplexes. Acid dissociation and ultrafiltration of sera from six of seven advanced ST cancers (originally IF negative) have allowed detection of antibody responses to ST CA by Western blot assay with enhanced reactivity as compared with the negativity under native serum conditions. This technique provides a reasonable avenue for study of the mechanisms of CA expression and serodiagnosis.

The genetic toxicology of 5-bromodeoxyuridine in mammalian cells

The thymidine analog, BrdUrd, induces many biological responses which are of importance to the field of genetic toxicology and related disciplines. These include the induction of SCE, specific-locus mutations, and toxicity, inhibition of cell proliferation, and the expression of fragile sites in the human genome. In early models which addressed the mechanisms of the biological effects of BrdUrd exposure, two pathways were proposed to account for the induction of the biological responses. Incorporation of the enol form of BrdUrd into the nascent DNA strand after pairing with deoxyguanosine was proposed as one pathway, whereas the incorporation of BrdUrd opposite adenosine in place of thymidine was proposed as the second pathway. Many novel and sophisticated techniques have been applied to the study of the mechanism of the induction of biological effects by BrdUrd leading to a substantial increase in our understanding of these mechanisms. However, the experimental evidence clearly supports the contention that BrdUrd exerts its effects on eukaryotic cells through mechanisms similar to those originally proposed to explain the genotoxicity of BrdUrd.

Chromosome and SCE analysis in peripheral lymphocytes of persons occupationally exposed to cytostatic drugs handled with and without use of safety covers

The frequency of structural chromosome aberrations and sister-chromatid exchanges in peripheral blood lymphocytes of nurses handling cytostatic drugs without a safety cover is compared with that of individuals doing this work exclusively under a safety cover and with that of nurses working under similar conditions but not handling cytostatics. The mean yield of dicentric chromosomes, (4.3 +/- 0.7)/1000 cells, and acentric fragments, (15.4 +/- 1.4)/1000 cells, in the occupationally exposed group is significantly increased in comparison to individuals working with protection (dic: (1.1 +/- 0.4)/1000 cells, ace: (11.2 +/- 1.2)/1000 cells) and nurses not handling cytostatics (dic: (2.1 +/- 0.5)/1000 cells, ace: (9.9 +/- 1.1)/1000 cells). The frequency of chromatid breaks and SCE is not significantly different between these groups (p greater than 0.05).

Chromosome reproduction: units of DNA for segregation

Evidence is summarized which indicates that the DNA loop anchoring proteins in chromosomes are effectively heterodimers that stack and are fastened into a bilaterally symmetrical array along the chromonemal axis. The evidence consists primarily of the observations made twenty five to thirty years ago on the pattern of sister chromatid exchanges and the way the DNA chains are sorted in the formation of diplochromosomes in cells that have undergone endoreduplication. The evidence indicates that each chain of DNA in the single duplex, which is assumed to run the length of a chromosome, is anchored to a bilaterally symmetrical axis of heterodimers that sort the two original chains among the four derived chromatids of each diplochromosome in a very precise way. These observations are considered in the context of investigations on the nature of scaffold proteins and the loop anchorage sequences, as well as the advances being made on the nature of DNA binding proteins and the roles of topoisomerase II.

Levels of sister-chromatid exchanges in hybrids between Bloom syndrome B-lymphoblastoid cells and various cell lines with lymphoid malignancy

The present study has been undertaken to examine the effect of cell hybridization of Bloom syndrome (BS) B-lymphoblastoid cell lines (LCLs) and various cell lines from lymphoid malignancies in order to clarify the relationship between sister-chromatoid exchange (SCE) and malignant conditions. Cell hybridization studies have shown that though BS high-SCE frequencies were completed by fusion with normal cells, fusion with various malignant cell lines did not result in complete normalization of BS SCEs, with 15-30 SCEs remaining per hybrid cell, demonstrating possibly common defects in DNA of BS and malignant cells. These findings strongly support the idea that the characteristic high SCE frequency in BS cells has some connection with the malignant condition, and that at least one step in carcinogenesis is either accompanied by the production of SCEs, or that SCEs themselves cause such a step to occur.

Scoring of SCE frequency per cell cycle in CHO chromosomes by means of a standardized 3-way-differential staining method

We have developed 2 alternative protocols to obtain 3-way differentiation (TWD) in Chinese hamster ovary (CHO) cells, in order to analyze the sister-chromatid exchange (SCE) frequency on a per-generation basis. In protocol A, 5-bromodeoxyuridine (BrdU) substitution into DNA was low during the first S period (S1) and high during the next 2 (S2 and S3). In protocol B, on the other hand, BrdU substitution was high during S1 and low during S2 and S3. The main advantage of our procedures is the high efficiency and reproducibility reached by controlling the relative incorporation of BrdU and deoxythymidine (dT) into replicating DNA in the presence of 5-fluorodeoxyuridine (FdU) throughout 3 consecutive S periods. The comparison of the results obtained for both protocols allowed us to evaluate the role of BrdU in the induction of SCEs in each cell cycle. Our results from M3 chromosomes seem to indicate that, under our experimental conditions, neither the concentration of BrdU in the medium nor the rate of BrdU incorporation into nascent DNA is the basic feature responsible for SCE formation. Indeed, the experiments reported here seem to demonstrate that the nature of parental DNA is crucial for the formation of the BrdU-induced SCEs.

A standardized method for the three-way differential staining of plant chromosomes and the scoring of SCEs per cell cycle

We have made use of 2 alternative methodologies to obtain 3-way differential staining (TWD) in third-mitosis (M3) chromosomes of Allium cepa, which involve different uptakes of bromodeoxyuridine (BrdU) through 3 cell divisions, in order to evaluate the sister-chromatid exchanges (SCE) frequency on a per-cell-cycle basis. The main innovation introduced by us to the original protocols previously reported has been the use of 5-fluorodeoxyuridine (FdU) to inhibit endogenous thymidine (dT) synthesis. By using different [BrdU]:[dT] ratios in the presence of FdU the relative incorporation of BrdU into replicating DNA can be controlled. The use of 2 different approaches to obtain 3-way differentiation of sister chromatids allowed us to evaluate the role of BrdU in the induction of SCEs in our system. Both procedures rendered nearly 100% of M3 chromosomes showing TWD. An additional advantage of our methodologies is their high degree of reproducibility.

Effect of exogenous thymidine on sister-chromatid exchange frequency in Chinese hamster ovary cells with bromodeoxyuridine- and chlorodeoxyuridine-substituted chromosomes

There are conflicting reports on the effect of exogenous thymidine (dThd) on the frequency of sister-chromatid exchanges (SCEs) in Chinese hamster ovary (CHO) cells. Thymidine has been reported either to increase or to have no effect on SCE frequency under similar experimental conditions. To resolve this controversy, we have carried out a series of experiments to examine the effect of dThd on CHO cells cultured with 5-bromodeoxyuridine (BrdUrd). In addition, we have examined the effect of dThd on CHO cells cultured with 5-chlorodeoxyuridine (CldUrd), a much more potent inducer of SCEs than BrdUrd. The addition of 100 microM dThd to the culture medium caused a consistent decrease in the yield of SCEs in cells grown in BrdUrd for two cell cycles. The decrease was even greater when cells were grown in dThd and CldUrd. Analysis of twin and single SCEs indicated that dThd must be present during the first cell cycle to reduce the frequency of SCEs. Because excess dThd is thought to have an effect when DNA replicates on a template substituted with a halogenated nucleoside, dThd at concentrations from 100 microM to 9 mM was added to cultures for the second cell cycle after a first cell cycle in BrdUrd. In this experiment, the presence of dThd increased SCE frequency in a dose-dependent manner. The results suggest that if dThd competes with halogenated nucleosides and thus decreases their incorporation into DNA, SCEs are suppressed in the subsequent cell cycle, whereas if excess dThd creates a dNTP pool imbalance, SCEs can be increased.

Cadmium sulfate does not induce sister chromatid exchanges in human lymphocytes in vitro

Mutagenic properties of cadmium sulfate were analyzed by the method of sister chromatid exchanges (SCEs) in lymphocytes of human peripheral blood taken from 4 donors. No significant increase was found in the mean frequency of SCEs in lymphocytes exposed to 1.6 X 10(-3) mM, 3.1 X 10(-3) mM and 6.2 X 10(-3) mM CdSO4 in culture.

SCE levels in Bloom-syndrome cells at very low bromodeoxyuridine (BrdU) concentrations: monoclonal anti-BrdU antibody

A stable staining procedure of sister-chromatid differentiation (SCD) using a monoclonal antibromodeoxyuridine (BrdU) antibody was newly established by combining it with the immunoperoxidase reaction (3,3'-diaminobenzidine, DAB reaction). This procedure permitted detection of SCD and SCE at very low BrdU concentrations. SCD was not usually observed below 2.0 micrograms/ml BrdU with flame-dried chromosome slides. When chromosome slides were prepared by air-drying over 37 degrees C warm water, SCD was detected at 10.0, 5.0, 1.0, 0.5, 0.3 and 0.2 micrograms/ml BrdU with FPG and even at 0.1 microgram/ml BrdU with the antibody technique. SCE levels were evaluated using the antibody technique and endomitotic analysis with FPG at low BrdU concentrations (1.0, 0.5, 0.3, 0.2 microgram/ml) in two BS B-lymphoblastoid cell lines (LCLs). Even though the BS SCE level was approximately 70 per cell at 10 micrograms/ml, the value decreased to the level of 20-30 SCE per cell at 0.1 microgram/ml with the antibody technique. In BrdU-labelled BS endomitoses, single SCEs highly decreased with BrdU concentrations (130-140 level at 10 micrograms/ml: 38-60 level at 0.2 microgram/ml), when compared to the rare twin SCE values (3-6 SCE level) at all BrdU concentrations. These findings conclusively indicate that the spontaneous baseline SCE in BS B-lymphoblastoid cells is low and most BS SCEs are caused by BrdU.

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

Culture of cells in high exogenous levels (greater than 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 X 10(-4) M), SCE frequency increased in both cell cycles, but far more SCEs were induced in the second cell cycle. Deoxycytidine (2 X 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.

Induction of sister-chromatid exchanges (SCEs) by 5-fluorodeoxyuridine. The role of 5-bromodeoxyuridine incorporated into parental DNA

The effect of thymidine (dT) and 5-fluorodeoxyuridine (FdU) on the frequency of sister-chromatid exchanges (SCEs) was examined in root-tip cells of Allium cepa. dT was unable to induce SCEs at all the concentrations tested. In contrast, FdU was efficient in the induction of SCEs. A nearly 3-fold increase in the frequency of SCEs was obtained with 5 X 10(-7) M FdU when it was given simultaneously with 5-bromodeoxyuridine (BrdU) for 2 consecutive cell cycles. Also, when FdU was present only for the first round of replication, the rate of SCEs in M2 chromosomes was notably higher than when it was given only during the second replication round. By analyzing M3 chromosomes treated during the second replication round with FdU the results also supported the hypothesis that the majority of the FdU-induced SCEs arise as a consequence of a higher rate of BrdU incorporation, and that most of them are formed when BrdU-containing strands are used as template for DNA synthesis.

Do the frequencies of sister chromatid exchanges in endoreduplicated mitoses provide a measure for lesion persistence and repair?

Endoreduplication was induced in V 79 cells using Colcemid. The concentration of Colcemid necessary to induce endoreduplication is about 1000 times higher than that needed to arrest mitoses or to induce ordinary tetraploid cells. Diplochromosomes with sister chromatid differentiation were obtained by adding BrdU for the duration of one cell cycle prior to the induction of endoreduplication. The induction of endoreduplication with Colcemid had no influence on the frequency of sister chromatid exchanges (SCEs). Treating the cultures with mitomycin C (MMC) before adding BrdU increased the percentage of endoreduplicated mitoses and also led to marked SCE induction. In the diplochromosomes, the frequencies of both twin SCEs (first cycle) as well as single SCEs (second cycle) were increased. It was also found that the SCE frequencies in mitoses after endoreduplication were lower than the values found in diploid and ordinary tetraploid metaphases of the same preparation. The possible conclusions concerning the lifetime of SCE-inducing lesions and the influence of repair processes are discussed.

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 in bl/bl lymphocytes levelled off at BrdUrd concentrations below 10 micrograms/ml while that in normal and bl/+ lymphocytes stayed constant below 7.5 micrograms/ml. The baseline SCE frequency in bl/bl cells was ten times higher than that in normal and bl/+ cells. At BrdUrd concentrations above 15 micrograms/ml, SCEs in bl/bl cells were induced more frequently than in normal and bl/+ 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 in bl/bl cells has a larger effect than that in normal and bl/+ 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 micrograms/ml BrdUrd was constant in all individuals and the rates of SCEs in each cell cycle in bl/bl cells were remarkably higher than those observed in normal and bl/+ cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Induction of mutations and chromosome aberrations in lung cells following in vivo exposure of rats to nitrogen oxides

In order to investigate the mutagenic effects of nitrogen oxides ( NOx ), induced mutations and chromosome aberrations were examined using primary lung cells obtained from rats exposed in vivo to NO2 and NO. Rats were exposed to nitrogen oxide gases at concentrations of 8-27 ppm for 3 h in a stainless steel chamber. Over the range 15-27 ppm, NO2 significantly increased mutation to ouabain resistance. Over a similar dose range, NO significantly increased mutation only at the highest concentration (27 ppm). Following NO2 exposure, chromosome aberrations (mainly chromatid type) were induced in chromatid breaks, 2.5-11.6-fold over the control at 8 and 27 ppm, respectively.

SCEs are induced by replication of BrdU-substituted DNA templates, but not by incorporation of BrdU into nascent DNA

After 3 rounds of DNA replication in the presence of BrdU, third-division metaphase cells can be scored for the frequencies of SCEs that occurred during cycles 1 and 2, and also for the frequency of SCE during cycle 3. This procedure was used to resolve the issue of SCE induction by replication of BrdU-substituted DNA templates versus induction by BrdU incorporation into nascent DNA. It was observed that third-cycle SCE frequencies in CHO are dependent upon the amount of BrdU that was present during cycles 1 and 2 and are independent of the BrdU concentration during the third cycle. It is therefore BrdU serving as a template, rather than BrdU being incorporated, that initiates the SCE event. A model is proposed that produces reasonable fits to the observed data. It also predicts a true background or spontaneous SCE frequency of 3 per cell per cycle as previously reported by Heartlein et al. (Mutation Res., 107 (1983) (103-109). The predicted single twin ratio is higher than that reported by Wolff and Perry (Exp. Cell Res., 93 (1975) 23-30), and possible explanations for this discrepancy are discussed.

Effect of 5-bromodeoxyuridine substitution on sister chromatid exchange induction by chemicals

The fluorescence-plus-Giemsa (FPG) technique for analysis of sister chromatid exchange (SCE) is widely used as an assay for mutagenic carcinogens. There is very little information, however, on whether incorporation of the bromodeoxyuridine (BrdU) necessary for visualization of SCEs affects the sensitivity of the SCE test system to different chemical agents. We have investigated the effect of BrdU incorporation on SCE induction by labeling cells with BrdU for either the first cell cycle or the first and second cell cycles. The cells were then treated with bleomycin, which produces DNA strand breakage; proflavine, which intercalates into DNA; mitomycin C, which produces monoadducts and DNA crosslinks; or aphidicolin, which inhibits DNA polymerase alpha. Chemicals were added before BrdU exposure or during the first, second, or both cell cycles. Only mitomycin C, which induces long-lived lesions, elevated the SCE frequency when cells were treated before BrdU labeling. When bleomycin, proflavine, or mitomycin C was present concurrently with BrdU, the frequency of SCEs was increased independently of the BrdU labeling protocol. Aphidicolin, on the other hand, induced more SCEs when present for the second cell cycle, when DNA replicates on a template DNA strand containing BrdU. We also examined the induction of SCEs in the first cell cycle (twins) and in the second cell cycle (singles) after continuous treatment of cells with BrdU and the test chemicals. Only aphidicolin increased SCE frequency in the second cell cycle. These results indicate that aphidicolin, but not bleomycin, proflavine, or mitomycin C, affects BrdU-substituted DNA and unsubstituted DNA differently. This type of interaction should be taken into consideration when the SCE test is used as an assay system.

Effect of bromodeoxyuridine on induced sister chromatid exchanges

Analysis of sister chromatid exchanges (SCEs) is widely used as an assay for mutagenic carcinogens. Visualization of SCEs generally requires that the cells be cultured for 2 cycles of replication with the thymidine analog bromodeoxyuridine (BrdUrd). To see if incorporation of BrdUrd into chromosomal DNA influences the SCE response after treatment with chemical compounds, we have studied the effect of BrdUrd incorporation on SCEs induced by 5 different chemicals: bleomycin (BLM), which causes DNA single- and double-strand breakage; proflavine (PF), which intercalates into DNA; mitomycin C (MMC), a polyfunctional alkylating agent that cross-links DNA and also forms monoadducts; and 2 chemicals that do not appear to interact with DNA directly, aphidicolin (APC), an inhibitor of DNA polymerase alpha; and 3-aminobenzamide (3AMB), an inhibitor of poly-(ADP-ribose)-polymerase. Chemical treatment was for the first, second, or both cell cycles, and BrdUrd was present for the first or both cell cycles. All treatments with BLM, PF, or MMC increased the SCE frequency independently of the BrdUrd labeling protocol. With APC and 3AMB, on the other hand, only small increases in SCE frequency were observed when treatment was for the first cell cycle, but there were far greater increases when the chemical was present for the second or for both successive cell cycles. To further determine at which cycle SCEs were formed after continuous treatment of cells with BrdUrd and a test chemical, we also examined the induction of SCEs in the first cell cycle (twins) and in the second cell cycle (singles) in tetraploid cells. Bleomycin, PF, and APC induced almost equal numbers of SCEs in both cell cycles, but MMC appeared to induce more SCEs in the second cycle than in the first. This is probably caused by long-lived lesions that induce SCEs. 3-Aminobenzamide, which does not form persisting lesions, also induced more single than twin SCEs, suggesting that this compound affects BrdUrd-substituted DNA differently than it does unsubstituted DNA. This type of interaction between a chemical and BrdUrdsubstituted DNA should be taken into consideration when SCE analysis is used as an assay system.

Induction of endoreduplication by hydrazine in Chinese hamster V 79 cells and reduced incidence of sister chromatid exchanges in endoreduplicated mitoses

Hydrazine in high concentrations very effectively induces endoreduplication in Chinese hamster V79 cells. The addition of 5-bromodeoxyuridine (BrdU) for the duration of one cell cycle prior to the induction of endoreduplication produces diplochromosomes with sister chromatid differentiation (SCD) after differential chromatid staining. The fact that diplochromosomes with complete SCD are obtained shows that endoreduplication was induced in cells that were in G2-phase. The analysis of sister chromatid exchanges (SCEs) showed that hydrazine treatment rarely led to increased SCE frequencies in mitoses after endoreduplication, but that it caused a strong SCE induction in diploid second division metaphases in the same culture. Neither catalase nor cysteine had an effect on the induction of endoreduplication or the incidence of SCEs. Treatment of the cells with mitomycin C prior to addition of BrdU led to increased SCE frequencies. Compared with the normal mitoses from the same preparation, the mitoses after endoreduplication showed a significantly reduced induction of SCEs. In contrast to these findings, SCE induction was not reduced in the common tetraploid V 79 cells after colcemid-induced polyploidization.

Studies on mammalian chromosome replication. III. Organization and replication of diplochromosomes

The process of DNA synthesis in normal and endoreduplicating mammalian cells are very similar. Both types of chromosomes are replicated in defined units termed chromosomal replicons, and in the same sequences along their lengths. The sister chromosomes of the diplochromosomes are replicated synchronously in identical patterns. The present observations suggest that organization and sequences of chromosome replication are genetically programmed.

Sister-chromatid exchanges and gene mutations are induced by the replication of 5-bromo- and 5-chloro-deoxyuridine substituted DNA

The thymidine (dT) analogue 5-chlorodeoxyuridine (CldU) induces 7-8-fold more sister-chromatid exchanges (SCE) than does 5-bromodeoxyuridine (BrdU) at equal substitution for dT in Chinese hamster ovary cells in culture. This difference facilitates study of the mechanism of induction of SCE by these analogues. Cultures were incubated with either BrdU or CldU for one cell cycle, followed by incubation in the presence of dT alone or BrdU or CldU for the second cell cycle and the SCE frequency determined in M2 cells. The results suggest that the induction of SCE is dependent only on the replication of the analogue-substituted DNA during the second cell cycle. Additional studies employed cultures grown in the presence of BrdU or CldU for 7 days to obtain mainly bifilarly substituted DNA, followed by 2 rounds of replication in the presence of dT alone. The SCE frequencies were approximately twice those found in cultures which had undergone the usual 2 rounds in the presence of the analogue; this is consistent with the replication of twice the amount of analogue-substituted DNA. Furthermore, such long-term growth in the presence of BrdU or CldU also results in concentration-dependent increases in the frequency of 6-thioguanine-resistant mutants, suggesting that gene mutations also result from the replication of analogue-substituted DNA.

Analysis of single and twin sister chromatid exchanges in endoreduplicated normal and Bloom syndrome B-lymphoid cells

Single and twin sister chromatid exchanges (SCEs) were analysed in the colcemid-induced endoreduplicated normal and Bloom syndrome (BS) B-lymphoid cells with diplochromosomes. In normal cells, an equal number of SCEs occur in each of the two cell cycles; the ratio of single (= 5.51 SCEs/cell) to twins (= 2.64 SCEs/cell) was 2:1 on the endoreduplicated-cell basis, and it was 1:1 on the diploid-cell basis. In contrast, in 29 endomitoses from one BS B-lymphoid line, a manyfold increase of single SCEs was detected and 139.4 single SCEs on the average were counted, whereas twin SCEs were rare and only 4.9 twin SCEs were countable. In BS cells, the ratio of single (= 139.4 SCEs/cell) to twins (4.9 SCEs/cell) was 28:1 on the endoreduplicated-cell basis, and it was 14:1 on the diploid cell-basis; the rates of S1 and S2 exchanges were 4.9 and 69.7 SCEs/cell, respectively. The present study strongly indicates that most of BS SCEs occur during the second cell cycle when BrdU-containing DNA is used as template for replication and that BrdU enhances BS SCEs.

Induction of sister chromatid exchanges in Chinese hamster ovary cells by 5-bromodeoxyuridine

Sister chromatid exchange (SCE) induction in established cell lines has become a widely used criterion for the assessment of genotoxicity. Detection of SCE is only possible if a base-analogue such as bromodeoxyuridine (BrdU) is incorporated into the DNA; it is not known to what extent the observed background level of SCE is a consequence of the presence of the base-analogue, and to what extent it represents a 'natural' background. In this paper, experiments are described in which a number of different BrdU incorporation schemes are compared. The results suggest that under the normal SCE-test conditions, e.g. 5-10 microM BrdU the majority of the spontaneous SCE are of the natural (non-BrdU) origin. The remaining (BrdU-dependent) SCE seems to be a consequence of greater number of spontaneous lesions in the BrdU-containing DNA.

Origin of symmetrical triradial chromosomes in human cells

We have collected 23 sporadic symmetrical triradial chromosomes (plus one D with duplicate satellites), 22 from cultured lymphocytes and one from a bone marrow cell. Fifteen triradials were from patients with Bloom's syndrome, and two from a Fanconi's anemia patient. The following chromosomes and chromosome groups were involved: 1, 2, 3, 4, 5, C(11 identified), D, and 17. The branchpoints were localized nonrandomly. Regions in or near centric heterochromatin were often involved. Some of the branchpoints are regions which also contain a high number of mitotic chiasmata. When the present sporadic triradials combined with those from the literature were compared with triradials with branchpoints in the "fragile regions", the localized branchpoints were different in these two groups. Our conclusion that most -- possibly all -- symmetrical triradials are caused by partial endoreduplication is based on the following observations: the shape of the triradials which shows that the extra segments are paired with their intact sister chromatids and not with each other; the failure of X-rays in G2 to increase the incidence of symmetrical triradials; the fact that in some cases the end of the extra segment is joined to its intact sister chromatid; and the occurrence of duplicate satellites.

Higher inductions of twin and single sister chromatid exchanges by cross-linking agents in Fanconi's anemia cells

Twin and single sister chromatid exchanges (SCEs) induced by short treatments with mitomycin C (MC) and 4,5',8-trimethylpsoralen (TMP)-plus-near ultraviolet light (NUV) were analyzed in colcemid-induced endoreduplicated normal human and typical Fanconi's anemia (FA) fibroblasts with diplochromosomes. The induction rate of twin SCEs that had occurred in the first cycle (S1) after the treatment was 1.7--2.4 times higher in FA cells than in normal cells. The induction rate of single SCEs that had arisen during the second cycle (S2) long after the treatment was also much higher, though less than the twin SCE rate, in FA cells than the almost negligible rate after repair of cross-links and monoadducts in normal cells. These results in FA cells, which specifically lack the first half-excision step of the two-step cross-link repair but retain the normal monoadduct repair, indicate that MC or TMP cross-links remaining unrepaired are indeed responsible for higher inductions of twin (S1 exchange) and single SCEs (S2 exchange). Thus, these findings indicate that Shafer's model of replication bypass for cross-link-induced SCE, which predicts greatly reduced twin SCE formation in FA cells due to half cancellation, is apparently inadequate as such. We present three plausible models, incorporating the ordinary replication model, random unilateral cross-link transfer, and chromatid breakage/reunion, that can account for the probabilistic inductions of single and twin SCEs and even for no SCE formation.

Sister chromatid exchange induced by short-lived monoadducts produced by the bifunctional agents mitomycin C and 8-methoxypsoralen

To see if DNA crosslinks are involved in the induction of sister chromatid exchange (SCE), Chinese hamster ovary cells were exposed to two bifunctional alkylating agents, mitomycin C and 8-methoxypsoralen, and their monofunctional derivatives, decarbamoyl mitomycin C and angelicin. The data indicate that monoadducts, rather than crosslinks, are responsible for SCE formation. Furthermore, all agents but angelicin produced short-lived lesions that led to SCEs in the first period of DNA replication after treatment (twin SCEs), but not in the second (single SCEs). In contrast, angelicin, like methyl methanesulfonate and N-acetoxyacetylaminofluorene, produced lesions that lasted more than one cycle, indicating that several different types of DNA lesions are capable of SCE induction.

An attempt to use the Tc-99m-thiodisuccinic acid (TDSA) complex in renoscintigraphy. II. In vivo studies

In the study the usefulness of Tc-99m-TDSA complex for renoscintigraphy was investigated. The results suggest that the complex undergoes elimination primarily via glomerular filtration similarly to Cr-51-EDTA and Tc-99-DTPA. Respective renoscintigraphic curves were obtained.

Spontaneous sister-chromatid exchanges in Chinese hamster cells in vivo and in vitro

The incidence of sister-chromatid exchanges (SCEs) was studied in Chinese hamster cells. The cells used were an established cell line (Don), an aneuploid secondary culture still exhibiting contact inhibition of growth, a primary culture, bone-marrow cells in vivo, a Don-derived clone having ring chromosomes, and endoreduplicated Don cells. The frequency of SCEs in the presence of bromodeoxyuridine (BUdR) increased in the following order: bone-marrow cells less than Don less than secondary culture cells less than primary culture cells. Marked increases in BUdR concentration induced only slight increases of SCEs. Some ring chromosomes showed Moebius strip and concatenated ring structures, indicating spontaneous occurrence of SCEs in the absence of BUdR. The incidence of spontaneous SCEs observed in ring chromosomes approximates that of SCEs observed in ordinary rod chromosomes in the presence of low dose levels of BUdR. SCEs occurring in the first and second cell cycles were separately counted in endoreduplicated cells. The ratio of single SCEs, which occurred in the second cell cycle, to twin SCEs, which occurred in the first cell cycle, was about 2, when the count of single SCEs was corrected for the induction effect. This implies that uninemy chromatids retain the polarity of DNA when SCEs occur, that bifilarly and trifilarly BUdR-substituted DNA strands give equal numbers of SCEs and that incidence of SCEs is independent of the length of S in the Don cells used here.

Sister chromatid differentiation and isolabeling of chromosomes

Isolabeling observed during sister chromatid differentiation (SCD) was studied from human skin fibroblasts by the fluorescence-plus-Giemsa (FPG) technique. Bromodeoxyuridine (BrdU) was fed to exponentially dividing cells for 52 h to enable completion of two consecutive cycles of DNA replication. During this period, the late-replicating regions of some chromosomes were able to go through three replication cycles. These chromosome regions had evidently incorporated BrdU bifiliarly in both chromatids and hence, on staining with FPG, appeared isostained (isolabeled). Thus, incubation of exponentially dividing cells with BrdU for a period longer than that required for two cell cycles appears to be a suitable method for revealing the late-replicating regions of the genome, such as the X chromosome in a human female, as isolabeled. In another experiment with Indian muntjac chromosomes, isolabeled segments were darkly stained, which suggested unifilar incorporation of BrdU. In this case, unequal crossing-over or an unequal distribution of thymine residues probably is responsible for the isolabel.

X-ray sensitization of chromatids with unifilarly and bifilary substituted DNA

When cells are grown for two rounds of DNA replication in the presence of the thymidine analogue 5-bromodeoxyuridine, chromosomes containing one chromatid with unifilarly substituted DNA and one with bifilarly substituted DNA are found. These can be distinguished by harlequin staining techniques that stain one chromatid dark and one light. When the degree of substitution is 60% or greater, 3 times as many X-ray-induced chromatid breaks are produced as in unsubstituted chromatids. This represents maximal sensitization. The unifilarly substituted (dark) chromatid is as sensitive as its bifilarly substituted (light) sister chromatid. If cells are grown in low concentrations of 5-bromo-deoxyuridine (BrdUrd), then the amount of substitution is less and the bifilarly substituted chromatid is more sensitive than the unifilarly substituted one. When large numbers of cells are grown in very low concentrations of BrdUrd, the analogue is almost completely depleted during the first round of replication leading to harlequin chromosomes containing one unsubstituted (dark) and one unifilarly substituted (light) chromatid. Under these conditions a maximal sensitization between light-staining and dark-staining chromatids can occur. This can be confused with the differential sensitivity between unifilarly and bifilarly substituted chromatids. The apparent discrepant results obtained by different investigators are most likely caused by the use of very low levels of BrdUrd in some of the experiments.