Correlation of the sister chromatid exchange level with chromosome aberrations induced by chemical mutagens in vivo

The data on the dose dependencies of the induction of sister chromatid exchanges (SCE) and chromosomal aberrations during exposure of mouse bone marrow cells in vivo to 5 alkylating substances are provided. The efficacy of SCE induction was found to be higher than that of chromosomal aberrations. It was established that SCE induced by chemical mutagens in vivo and in vitro are more sensitive and stable tests than chromosomal aberrations.     

Spontaneous and mitomycin-C induced sister-chromatid exchanges : Comparison of in vivo and in vitro systems

Frequencies of sister-chromatid exchanges (SCE) were measured in vitro in mouse fibroblasts and in vivo in mouse bone-marrow cells. SCE levels in these cell systems were measured in response to varying concentrations of bromodeoxyuridine (BrdU) and mitomycin-C (MMC). Although BrdU was found to induce SCE in both cellular systems, baseline SCE levels were 2- to 3-fold higher in vitro than in vivo. SCE induction was found to be a linear function of MMC concentration in vivo and in vitro; however the slope of the in vivo curve was 5-fold higher. The interaction of BrdU substituted DNA and MMC was examined by administering a fixed dose of MMC with increasing concentrations of BrdU. The induced SCE frequencies appeared to be additive. In addition to measuring drug-induced SCE, the BrdU differential staining technique allows concomitant measurement of the inhibition of cellular replication by the test drugs.     

In vivo sister-chromatid exchange: A sensitive measure of DNA damage

A variety of chemical agents and X-irradiation were examined for their abilities to induced sister-chromatid exchanges (SCE) in vivo. In addition to demonstrating the several known mutagens and carcinogens are capable of inducing SCE in vivo, our studies indicate that the suspected carcinogen, tris-bromophosphate, can significantly elevate SCE levels. Comparison of the effects of these agents on SCE levels, chromosomal-aberration frequencies and cell-replication kinetics reveals that no consistent relationship exists between SCE levels and other indicators of cellular DNA damage.

It is proposed that analysis of SCE induction in vivo may provide a useful technique for the screening of mutagenic and carcinogenic compounds.     

Bimodal distribution of sensitivity to SCE induction by diepoxybutane in human lymphocytes. II. Relationship to baseline SCE frequency

Environmental and genetic factors have been implicated as important sources of individual variation in baseline sister-chromatid exchange (SCE) frequency in humans. The current study was designed to test whether the frequency of baseline SCEs in 58 normal blood donors is associated with previously observed variations in SCE frequencies induced by diepoxybutane (DEB). Because 12 subjects were current cigarette smokers and smoking is known to be an in vivo inducer of baseline SCE frequencies, we specifically tested whether higher baseline SCE frequencies in smokers would be associated with in vitro sensitivity to SCE induction by DEB. Analysis of variance showed that DEB-induced SCE frequencies were significantly associated with baseline SCE frequencies; those who were sensitive to SCE induction by DEB were more likely to have higher baseline SCE frequencies. This effect, however, was independent of in vivo induction of SCE by smoking. Chromosomal sensitivity to the induction of SCE by DEB explained approx. 15-20% of the variation in baseline SCE. This was similar in magnitude to the effect of cigarette smoking. Because increased sensitivity to DEB-induced SCEs is common in normal blood donors (approx. 24%) and is associated with an increase in baseline SCEs, it should be investigated as a source of bias and/or a potential marker of sensitivity to environmental mutagens in future cytogenetic studies.     

Differences in sensitivity of murine spermatogonia and somatic cells in vivo to sister-chromatid exchange induction by nitrosoureas

Previously published data indicate that spermatogonia (SPG) are less sensitive to a sister-chromatid exchange (SCE) induction for different mutagens. In an earlier study, we have observed that bromodeoxyuridine (BrdU) substituted murine SPG are less sensitive to SCE induction by gamma ray in cells, than bone marrow (BM) and salivary gland (SG) cells in vivo. This was interpreted to mean that SPG are more efficient in DNA repair or are less prone to SCE induction. That the lower induction of SCE could be due to a reduced accessibility of mutagens to the SPG by virtue of a physiological barrier, was discarded by using gamma radiation. The aim of the present study was to establish whether or not there are differences in SCE induction by nitrosoureas among SPG, SG and BM cells with BrdU substituted or unsubstituted DNA. It was observed that SCE induction by methylnitrosourea (MNU) or by ethylnitrosourea (ENU) in SPG was, respectively, five and two times lower than in SG, and ten and three times lower than in BM. In SPG after BrdU incorporation, there was no increase in efficiency of SCE induction; in fact, there was even a slight decrease by exposure to MNU or ENU. BM and SG cells showed an increased efficiency in SCE induction after BrdU incorporation. This implies that SPG are also less sensitive to SCE induction by nitrosoureas, which cause a different kind of damage from previously assayed mutagens.     

小鼠体内脾脏,骨髓及精原细胞姐妹染色单体交换的比较研究

本文对几种化学诱变剂诱发小鼠体内脾脏、骨髓和精原细胞的SCE进行了比较研究,同时分析了几类常见化合物在小鼠脾脏细胞中诱发SCE的活力。结果显示诱变剂在脾脏细胞中诱发SCE比骨髓和精原细胞敏感。几类化合物都能显著地诱发小鼠脾脏SCE的增加,与对照相比差异显著(P<0.05)或极显著(P<0.01),说明利用小鼠脾脏细胞检测环境诱变物是相当灵敏的。     

The use of sister-chromatid exchange in Chinese hamster primary lung cell cultures to measure genotoxicity

Primary cell cultures derived from Chinese hamster lung (CHL) were established, and their response for the induction of sister-chromatid exchange (SCE) by direct- and indirect-acting mutagens was characterized. An increase in SCE frequency was induced in CHL cells by 3-methylcholanthrene (MCA), benzo[a]pyrene (BaP), and 2-aminoanthracene (2AA). The SCE frequency increased slightly after exposure to cyclophosphamide, but did not respond to the hepatocarcinogen dimethylnitrosamine (DMN). A slight increase in SCE frequency by DMN was observed in the CHL system with use of Aroclor-1254-induced rat liver homogenate fraction (S9). This response to DMN in CHL cells was lower than that seen when CHO cells were the target in the presence of S9. At low (1) and high (20) passages, the CHL cells responded with a similar dose-related increase in SCE frequency to direct- (ethyl methanesulfonate, EMS) and indirect- (MCA) acting mutagens. This response indicates that even after prolonged culturing in vitro, the cells retained the ability to metabolically activate xenobiotic promutagens. The induction of SCE by MCA occurred at concentrations that also induced macromolecular binding. SCE induction was also examined in primary lung cell cultures from animals exposed by nose-only inhalation to MCA aerosol. A significant increase in SCE frequency above controls was observed in cells from animals after a single exposure to MCA. No detectable increase in SCE frequency was observed after repeated inhalation exposures. Because CHL cells are of lung origin and showed metabolic activity, the CHL system appears to be appropriate for study of the genotoxic potential of inhaled compounds.     

Induction of sister chromatid exchanges in human cells by fluorescent light.

The Brd-U differential staining technique was utilized to examine the induction of sister-chromatid exchanges (SCE) by fluorescent ligt in human fetal lung fibroblasts (IMR-90). Exposure of these cells in media to fluorescent light resulted in an increase in SCE frequencies from a background level of 8.5 SCE/cell to 20.5 SCE/cell. Cellular replication kinetics were also inhibited by fluorescent light exposure. Exposure of cells to fluorescent light in phosphate buffered saline (PBS) resulted in a two-fold increase in SCE levels and incresed inhibition of cell replication, indicating that culture media may have a protective effect. Determinations of SCE frequencies with blocking filters indicated that the fluorescent light wavelengths responsible for SCE induction were in the near-ultraviolet spectrum between 300 and 390 nm. Culturing cell sin media that had been exposed to fluorescent light resulted in a significant increase in SCE levels, 14.5 ± 1.5 vs. 7.5 ± 0.65, demonstrating the contribution of media photoproducts to SCE induction. The role of media photoproducts was further reinforced by finding a significant decline in fluorescent light induced SCE in cells cultured in medium deficient in three known photosensitizers (phenol red, tetracycline and riboflavin) for 2–3 weeks prior to exposure.Since SCE have been shown to be a sensitive indicator of DNA damage, these results indicate that fluorescent light can induce genetic damage in human cells. These findings are also of importance to investigators culturing cells in laboratories with fluorescent illumination.     

Some factors affecting optimal differential staining of sister-chromatids in vivo in the fish Nothobranchius rachowi

In the past few years, routine studies of SCE induction in vivo in fish have been hampered by unreliable SCD techniques. This paper presents a number of modifications of the SCD technique in vivo in Nothobranchius rachowi. Major improvements were obtained by BrdU incorporation from aqueous solutions, short intervals between preparation and staining of slides and post-treatment with HCl. These improvements resulted in a highly reliable SCD procedure in Nothobranchius with a low level base-line SCE frequency (0.90 SCE/metaphase, 0.059 SCE/chromosome). Further research is now directed at gathering additional data on base-line SCE frequencies, establishing the sensitivity of the assay for aqueous solutions of known mutagens, and defining an experimental set-up for optimal statistical evaluation.     

Chromosomal instability in mutagen-sensitive mutants isolated from mouse lymphoma L5178Y cells. II. Abnormal induction of sister-chromatid exchanges and chromosomal aberrations by mutagens in an ionizing radiation-sensitive mutant (M10) and an alkylating agent-sensitive mutant (MS1)

To determine the mutual relationships between cell survival and induction of sister-chromatid exchanges (SCEs) as well as chromosomal aberrations (CAs), mutagen-induced SCEs and CAs were analyzed in an ionizing radiation-sensitive mutant (M10) and an alkylating agent-sensitive mutant (MS 1) isolated from mouse lymphoma L5178Y cells. The levels of CA induction in both mutants strictly corresponded to the sensitivity to lethal effects of mutagens, except that caffeine-induced CAs in M10 are considerably lower than those in L5178Y. The results clearly indicate that except for caffeine-induced CAs in M10, mutagen-induced lethal lesions are responsible for CA induction. In contrast, SCE induction in mutants was complicated. In M10, hypersensitive to killing by gamma-rays, methyl methanesulfonate (MMS), and 4-nitroquinoline 1-oxide (4NQO), but not sensitive to UV or caffeine, the frequency of SCEs induced by gamma-rays was barely higher than that in L5178Y, and the frequencies of MMS- and UV-induced SCEs were similar to those in L5178Y, but 4NQO- and caffeine-induced SCEs were markedly lower than those in L5178Y. MS 1, which is hypersensitive to MMS and caffeine, but not sensitive to UV or 4NQO, responded to caffeine with an enhanced frequency of SCEs and had a normal frequency of MMS-induced SCEs, but a reduced frequency of UV- and 4NQO-induced SCEs. Thus, susceptibility to SCE induction by mutagens is not necessarily correlated with sensitivity of mutants to cell killing and/or CA induction by mutagens. Furthermore, the spontaneous levels of SCEs are lower in M10 and higher in MS 1 than that in L5178Y (Tsuji et al., 1987). Based on these results, we speculate that M10 may be partially defective in the processes for the formation of SCEs caused by mutagens. On the other hand, MS 1 may modify SCE formation-related lesions induced by UV and 4NQO to some repair intermediates that do not cause SCE formation. In addition, MMS-induced lethal lesions in MS 1 may not be responsible for SCE induction whereas caffeine-induced lethal lesions are closely correlated with SCE induction. Thus, the lesions or mechanisms involved in SCE production are in part different from those responsible for cell lethality or CA production.     

A comparison of sister-chromatid exchange in mouse peripheral blood lymphocytes exposed in vitro and in vivo to phosphoramide mustard and 4-hydroxycyclophosphamide

Cyclophosphamide (CP) and two of its known metabolites, 4-hydroxycyclophosphamide (4-OHCP) and phosphoramide mustard (PAM), were analyzed for their ability to induce sister-chromatid exchanges (SCEs) in mouse peripheral blood lymphocytes (PBLs) in vitro and in vivo. At equimolar concentrations, CP is a more potent SCE inducer in vivo than PAM and PAM and 4-OHCP induce equal numbers of SCEs in a dose-dependent manner. The present study also shows that these metabolites of CP are more potent SCE inducers than CP itself in vitro. This relationship might be explained by the differences in pharmacokinetics of these compounds.     

Antagonizing effect of 3-aminoharman on induction of sister-chromatid exchanges by mutagens

3-Aminoharman (3AH, 3-amino-1-methyl-9H-pyrido[3,4-b]indole), which has been reported as a novel substance with an antagonistic effect on induction of sister-chromatid exchange (SCE) by polycyclic mutagens in the presence of the metabolic activation system, was examined with a cultured human lymphoblastoid cell line, NL3, for its effect on SCE induction by direct-acting mutagens such as mitomycin C (MMC), nitrogen mustard N-oxide (NMO), methyl methanesulfonate (MMS), N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), 4-nitroquinoline 1-oxide (4NQO) and 3-hydroxyamino-1-methyl-5H-pyrido[4,3-b]indole (OH-Trp-P-2), and also by ultraviolet light (UV) irradiation. The results obtained on simultaneous treatment with 3AH and mutagens were as follows: (1) 3AH suppressed more than 50% of SCEs induced by MMC, NMO and OH-Trp-P-2; (2) 4NQO- and MNNG-induced SCEs were also suppressed by 3AH but to a lesser degree; (3) MMS-induced SCEs were not, however, altered by 3AH; and (4) the suppression of SCE by 3AH was dose-dependent. Treatment of cells with 3AH for 2 h immediately before MMC exposure suppressed SCE induction to a significant degree similar to the simultaneous treatment, but post-treatment with 3AH was much less effective. 3AH inhibited SCE induction by NMO when 3AH treatment was carried out either before or after NMO treatment, to an extent similar to the simultaneous treatment. Treatments with 3AH either before or after UV exposure did not change the UV-induced SCEs. Results with these direct-acting mutagens ruled out the relevance of metabolic activation as a necessary step for the antagonizing effect of 3AH.     

Genotype- and age-associated in vivo cytogenetic alterations following mutagenic exposures in mice

We studied mice from eight genetic strains at two ages (young, 10 weeks; and old, more than 80 weeks) for cytogenetic alterations (sister chromatid exchange (SCE), micronuclei, and metaphase indices) following challenges by two known mutagens: N-nitrosoethyl urea (ENU, 17 mg/kg) and cyclophosphamide (CP, 4.5 mg/kg) on bone marrow cells in vivo. The data were used to evaluate the effect of age, genotype, and differential aging patterns of genotypes in relative susceptibility to chromosomal breakage and instability in otherwise normal individuals. The older animals had a higher frequency of micronuclei, reduced metaphase indices, and lower SCE/cell as compared with their younger counterparts. Treatment with both mutagens significantly increased micronuclei and SCEs/cell in almost all strains at both ages but had little effect on the frequency of cells in metaphase. Among individual differences for SCEs/cell at most treatment combinations were not significant. In general, the induced SCEs (treatment-control) are significantly higher in older animals, variable among strains, and relatively higher as a result of CP than the ENU treatment. When the age effect was evaluated as the difference of SCE/cell in old and SCE/cell in young animals of each genotype-treatment combination, an age-dependent pattern was evident. In the presence of a mutagen the pattern in aging response was highly variable and strain (genotype) dependent. This variability may be viewed as subtle inherent genetic predisposition of sensitivity to mutagens that could be evaluated only using sensitive measures (e.g., SCE and not micronuclei) following more than one mutagenic challenges. These subtle differences could become pronounced when these parameters are evaluated at different ages on the same genotype.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of caffeine on sister-chromatid exchanges (SCE) in vivo.

Chinese hamsters were twice treated with caffeine via stomach tube. The single doses were either 20, 100, 200 or 400 mg per kg body weight. A dose-dependent increase was observed in the frequencies of SCE induced in vivo in bone-marrow cells. Two intraperitoneal injections of the chemical mutagens, cyclophosphamide or benzo[a]pyrene, led to a pronounced increase of the frequency of SCE. Simultaneous applications of the chemical mutagens and caffeine decreased the rate of SCE. The effect of caffeine per se to induce SCE, and the mechanisms by which caffeine reduces the level of SCE induced by chemical mutagens are discussed.     

Caffeine induces sister-chromatid exchanges during the whole S-phase of the cell cycle

The capacity of caffeine to induce sister chromatid exchanges (SCEs) in different cell cycle stages and the proliferation kinetics were studied. Continuous treatment with this xanthine during the whole second cycle significantly increased the baseline SCE frequency. Pulse-treatment experiments showed that the induction of SCEs by caffeine, which was dose-dependent, was restricted to the S-phase of the cell cycle without effect on G1 or G2 cells. Moreover, unlike other SCE-inducing agents, such as DNA-synthesis inhibitors and DNA-damaging agents, caffeine produced similar SCE increases in cells treated at different times throughout the S-phase. In the light of Painter's model for SCE formation and the known effects of caffeine on the DNA replication pattern, the most likely mechanism of SCE induction by caffeine is an increase in the number of DNA-replication sites.     

Influence of beta-myrcene on sister-chromatid exchanges induced by mutagens in V79 and HTC cells

The influence of beta-myrcene (MC) on sister-chromatid exchanges (SCE) in V79 cells induced by 4 S9 mix-activated indirect mutagens was studied. The mutagens used were cyclophosphamide (CP), benzo[a]pyrene (BP), aflatoxin B1 (AFB) and 9,10-dimethyl-1,2-benz[a]anthracene (DMBA). MC effectively inhibited SCEs induced by CP and AFB in a dose-dependent manner, but it had no effect on SCE induction by BP and DMBA. MC also reduced CP-induced SCE frequencies in a hepatic tumor cell line (HTC). These cells are metabolically competent and activate CP into its biologically active metabolites. Our results support the suggestion that MC modulates the genotoxicity of indirect-acting mutagens by inhibiting certain forms of the cytochrome P-450 enzymes required for activation of premutagens like CP and AFB.     

In vivo and in vivo/in vitro kinetics of cyclophosphamide-induced sister-chromatid exchanges in mouse bone marrow and spleen cells

In several acute and chronic exposures to various chemicals in vivo and in vitro, the average sister-chromatid exchange (SCE) frequencies in human, mouse, rat, and rabbit lymphocytes generally decrease with time following treatment. The rate of this decline varies, but little data have been published pertaining to the comparative kinetics of SCEs both in vivo and in vivo/in vitro (exposure of animals to the test compound and culturing of cells) simultaneously in the same tissues. In this study, a single dose of cyclophosphamide (40 mg/kg) was injected for varying periods (6-48 h) and its effects, as assessed by the induction of SCEs, were analyzed under both in vivo and in vivo/in vitro conditions in mouse bone marrow and spleen cells. In vivo, the cyclophosphamide-induced SCEs increased with increasing time up to 12 h, stayed at approximately the same level until 24 h, and then decreased with increase in post-exposure time. However, the SCE levels remained significantly higher than controls at 48 h post-exposure time in both bone marrow and spleen cells. Under in vivo/in vitro conditions, the SCEs in bone marrow decreased with increase in post-exposure time until reaching control values by 48 h post exposure. However, in spleen cells, the decrease in SCE level was gradual, and by 48 h post-exposure time, the cells still had approximately 6 times higher SCEs than the control values. These results suggest that there are pharmacokinetic differences for cyclophosphamide in mouse bone marrow and spleen. Also, there is a differential SCE response to cyclophosphamide under in vivo and in vivo/in vitro conditions.     

Dependency of the yield of sister-chromatid exchanges induced by alkylating agents on fixation time. Possible involvement of secondary lesions in sister-chromatid exchange induction

Chinese hamster V79 cells were pulse-treated (for 60 min) with various mutagens three, two or one cell cycles before fixation (treatment variants A, B and C, respectively) and the frequencies of induced SCEs were analysed and compared. The degree of increase in frequency of SCEs with dose in the treatment variants depended on the mutagen used. For the methylating agents MNU, MNNG and DMPNU, high yields of SCEs were obtained in the treatment variants A and B, and there was no difference in the efficiency with which these agents induced SCEs in these treatment variants. In the treatment variant C, however, no SCEs were induced with mutagen doses yielding a linear increase in SCE frequency in treatment variants A and B. A slight increase in SCE frequency in treatment variant C was observed only when relatively high doses of MNU or MNNG were applied. Like the above agents, EMS, ENU and MMS induced more SCEs in treatment variants A and B than in C, but for these agents treatment variant B was most effective and SCEs were induced over the entire dose range, also in treatment variant C. As opposed to the methylating and ethylating agents, MMC induced SCEs with high efficiency when treatment occurred one or two generations prior to fixation. There was no difference in SCE frequency between these treatment variants. MMC was completely ineffective for the induction of SCEs when treatment occurred three generations before fixation. The unexpectedly low SCE frequencies induced by the methylating and ethylating agents when treatment occurred one generation before fixation were not due to the exposure of cells to BrdU prior to mutagen treatment. From the results obtained, it is concluded that DNA methylation and ethylation lesions give rise to SCEs only with very low probability during the replication cycle after the lesion's induction, and that subsequent lesions produced during or after replication of the methylated or ethylated template (secondary lesions) are of prime importance for SCE formation after alkylation. For MMC, however, primary lesions seem to be most important for SCE induction.     

Genotoxic effects of triphenyltin acetate and triphenyltin hydroxide on mammalian cells in vitro and in vivo.

Two organotin pesticides, triphenyltin acetate (TPTA) and triphenyltin hydroxide (TPTH), were evaluated for their ability to induce micronuclei (MN) and sister chromatid exchange (SCE) in vitro using cultured Chinese hamster ovary (CHO) cells and in vivo BALB/c mouse erythrocytes. Both pesticides induced a dose-dependent increase but only TPTH induced a significant increase in MN at the highest dose (150 ng/ml) tested in CHO cells. With adding S9 microsomal fractions, both pesticides induced a meaningful MN induction at 150 ng/ml and a dose-dependent significant increase in SCE. In vivo MN induction in erythrocytes was conducted by treating BALB/c mice orally or intraperitoneally with these pesticides either in a single or triple treatments. Oral gavage (p.o.) of TPTA resulted in a dose-related significant increase of MN induction in peripheral blood and of TPTH induced a significant increase in micronucleated reticulocyte (MNRETs) only in a single treatment. Intraperitoneal administration of TPTA or TPTH, however, resulted in meaningless random increases in MN though these increases might be attributable to toxic effects. The MNRETs levels in the treatment with both pesticides were independent to the sampling time. This study demonstrated that TPTA and TPTH was potential chromosome mutagens.     

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.