Replication of DNA containing 5-bromouracil can be mutagenic in Syrian hamster cells.

A new protocol for inducing mutations in mammalian cells in culture by exposure to the thymidine analog 5-bromodeoxyuridine (BrdUrd) was established. This protocol, called "DNA-dependent" mutagenesis, involved the incorporation of BrdUrd into DNA under nonmutagenic conditions and the subsequent replication of the 5-bromouracil (BrUra)-containing DNA under mutagenic conditions but with no BrdUrd present in the culture medium. The mutagenic conditions were induced by allowing BrUra-containing DNA to replicate in the presence of high concentrations of thymidine. This generated high intracellular levels of dTTP and dGTP, causing nucleotide pool imbalance. The mutagenesis induced by this protocol was found to correlate with the level of BrUra substituted for thymine in DNA.     

Analysis of mutagenesis and sister-chromatid exchanges induced by 5-bromo-2′-deoxyuridine in somatic hybrids derived from Syrian hamster melanoma cells and Chinese hamster ovary cells

Somatic cell hybrids were derived from the fusion of Chinese hamster ovary (CHO) cells and Syrian hamster melanoma cells (2E). These two cell lines had previously been shown to differ in their response to the induction of mutations and sister-chromatid exchanges (SCEs) by 5-bromo-2′-deoxyuridine (BrdUrd) (Kaufman, 1987). The parental cells and a number of representative, independent hybrid clones were tested for their response to both the INC and REP mutagenesis protocols. INC mutagenesis involves the incorporation of BrdUrd into DNA under conditions of deoxyribonucleoside triphosphate (dNTP) pool imbalance, while REP mutagenesis involves the replication of 5-bromouracil-substituted DNA in the presence of dNTP pool imbalance. When tested for the toxic effects of high concentrations of BrdUrd and for the induction of mutations by the INC protocol, the hybrid clones all expressed the 2E phenotype, i.e., sensitivity to relatively low concentrations of BrdUrd and thymidine for the induction of mutations, dNTP pool perturbation, and the toxic effects of BrdUrd. When the hybrid clones were tested for the induction of mutations and SCEs by the REP protocol, it was found that they expressed the 2E phenotype for the induction of mutations and the CHO phenotype for the induction of SCEs. Thus, various aspects of the 2E phenotype, such as high mutation frequencies associated with large dNTP pool perturbations, appeared to be dominantly expressed in the cell hybrids, while the lack of induction of SCEs by these mutagenic conditions in 2E cells was found to be a recessive characteristic.     

Analysis of mutagenesis and sister-chromatid exchanges induced by 5-bromo-2'-deoxyuridine in somatic hybrids derived from Syrian hamster melanoma cells and Chinese hamster ovary cells

Somatic cell hybrids were derived from the fusion of Chinese hamster ovary (CHO) cells and Syrian hamster melanoma cells (2E). These two cell lines had previously been shown to differ in their response to the induction of mutations and sister-chromatid exchanges (SCEs) by 5-bromo-2'-deoxyuridine (BrdUrd) (Kaufman, 1987). The parental cells and a number of representative, independent hybrid clones were tested for their response to both the INC and REP mutagenesis protocols. INC mutagenesis involves the incorporation of BrdUrd into DNA under conditions of deoxyribonucleoside triphosphate (dNTP) pool imbalance, while REP mutagenesis involves the replication of 5-bromouracil-substituted DNA in the presence of dNTP pool imbalance. When tested for the toxic effects of high concentrations of BrdUrd and for the induction of mutations by the INC protocol, the hybrid clones all expressed the 2E phenotype, i.e., sensitivity to relatively low concentrations of BrdUrd and thymidine for the induction of mutations, dNTP pool perturbation, and the toxic effects of BrdUrd. When the hybrid clones were tested for the induction of mutations and SCEs by the REP protocol, it was found that they expressed the 2E phenotype for the induction of mutations and the CHO phenotype for the induction of SCEs. Thus, various aspects of the 2E phenotype, such as high mutation frequencies associated with large dNTP pool perturbations, appeared to be dominantly expressed in the cell hybrids, while the lack of induction of SCEs by these mutagenic conditions in 2E cells was found to be a recessive characteristic.     

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.     

Uncoupling of the induction of mutations and sister-chromatid exchanges by the replication of 5-bromouracil-substituted DNA

The REP mutagenesis protocol, which involves the replication of 5-bromouracil (BrUra)-substituted DNA in the presence of deoxyribonucleoside triphosphate (dNTP) pool imbalance, has been shown to induce both mutations and sister-chromatid exchanges (SCEs) in Chinese hamster ovary (CHO) cells. However, when a Syrian hamster melanoma-derived cell line, called 2E, which was selected for its ability to replace all of the thymine residues in DNA with BrUra, was subjected to the REP mutagenesis protocol, the correlation between the induction of mutations and SCEs was no longer observed. The 2E cells were found to be much more sensitive to the induction of mutations by REP mutagenesis than were the CHO cells. This increased sensitivity to REP mutagenesis was found to correlate with increased perturbations of the dNTP pools that have been shown to be involved in the mutagenic mechanism of this protocol. In contrast, when the induction of SCEs by the REP protocol was measured, it was found that although a baseline level of SCEs was detected in 2E cells, no significant induction of SCEs due to dNTP pool perturbation was observed. It was shown that high levels of SCEs were readily induced in 2E cells by other agents, e.g. mitomycin C. A model, which discusses the fate of mismatched bases thought to be generated by the REP mutagenesis protocol as the determining factor for the induction of mutations of SCEs, is proposed to explain the uncoupling of mutagenesis and SCE induction in 2E cells.     

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.     

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.     

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     

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.     

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.     

DNA synthesis in cytokinin-autotrophic tobacco cells

DNA isolated from various Nicotiana tabacum cell types, differing in their degree of hormone autotrophy and incubated in the presence of bromodeoxyuridine (BrdUrd), was analyzed by isopycnic CsCl gradient centrifugation. All cell types incorporate BrdUrd into DNA in such a way that hybrid DNA is formed with 60–80% of thymine (Thy) residues replaced by bromouracil (BrUra) in the newly synthesized strand. This DNA is not replicated further under ordinary culture conditions. Whereas in normal hormone-dependent cells this state is final and cells necrotize, in tumor (cytokinin-auxin autotrophic) and cytokinin-autotrophic cells a mechanism is induced leading to the reduction of BrUra content in DNA. As a result a decrease in the buoyant density (in CsCl) of BrUra DNA can be observed. In the case of cytokinin-autotrophic cells supplemented with kinetin, the buoyant density of the whole DNA decreases gradually to the value of that of unsubstituted DNA, but specific radioactivities of different DNA fractions reflect the retention of the pyrimidine ring of BrUra in DNA. This is interpreted as debromination of DNA in situ. The process can be inhibited by fluorodeoxyuridine (FdUrd) and deoxycytidine (dCyd). Moreover, FdUrd (but not dCyd) allows replication of hybrid DNA in tumor cells in such a way that HH DNA with all Thy residues replaced by BrUra is formed. For cytokinin-autotrophic cells FdUrd and kinetin are required. In hormone-dependent cells replication of hybrid DNA cannot be induced under any conditions. Most of these conclusions complement our previous findings that BrdUrd tolerance in hormone-autotrophic tobacco cells in hormone controlled. It is postulated that a modulation of thymidylate synthetase specificity is one factor affecting the level of BrUra substitution in DNA. The possibility of cytokinins being involved in the control of DNA synthesis is discussed.Abbreviations BrdUrd 5-bromo-2-deoxyuridine - BrUra 5-bromouracil - dCyd 2-deoxycytidine - FdUrd 5-fluoro-2-deoxyuridine - dThd thymidine - Thy thymine - EDTA Na₂-ethylenedia-minotetraacetate - IAA idole-3-acetic acid (auxin) - SDS Na-dodecylsulphate - LL, HL, HH DNA light-light (unsubstituted), heavy-light (unifilarly BrUra substituted), heavy-heavy (bifilarly BrUra substituted) DNAs, respectively     

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.     

Aphidicolin-Resistant Mutants of Mouse Lymphoma L5178y Cells with a High Incidence of Spontaneous Sister Chromatid Exchanges

Two aphidicolin-resistant cell mutants (AC 12 and AC 41) with a fourfold increase in spontaneous frequency of sister chromatid exchanges (SCEs) were obtained out of over 400 aphidicolin-resistant mutants isolated from mouse lymphoma L5178Y cells. They also exhibited three- to fourfold increases in spontaneous frequency of chromosome aberrations (CAs). To determine whether the high level of SCE frequency in AC 12 is caused by 5-bromodeoxyuridine (BrdUrd) used for visualizing SCEs, the effect of BrdUrd incorporated into DNA on SCE induction was analyzed. The SCE frequencies in AC 12 remained constant at BrdUrd incorporation levels corresponding to 2-90% substitution for thymidine in DNA. In addition, the small amount of BrdUrd incorporated into both daughter and parenteral DNA strands in AC 12 had minimal effect on SCE induction. Furthermore, AC 12 and AC 41 were slightly resistant to BrdUrd with respect to the induction of CAs, the inhibition of cell-cycle progression and the decrease in mitotic activity. These findings suggest that the high incidence of SCEs in AC 12 and AC 41 is formed by their intrinsic defects, not by the effects of BrdUrd used. The analysis of SCE frequencies in hybrid cells between these mutants and the parental L5178Y revealed that the genetic defects in AC 12 and AC 41 appear to be recessive, and that these two mutants belong to the same complementation group. Furthermore, AC 12 belonged to a different complementation group from ES 4, which was isolated previously from L5178Y as an SCE mutant with a twofold higher frequency of spontaneous SCEs. This finding indicates that at least two different genetic defects participate in the formation of the high incidence of spontaneous SCEs in mouse cells. These SCE mutants would provide valuable cell materials for studying the molecular mechanism of SCE formation.     

Incorporated bromodeoxyuridine enhances the sister-chromatid exchange and chromosomal aberration frequencies in an EMS-sensitive Chinese hamster cell line

The mutant Chinese hamster cell line, EM9, is characterized by a high baseline sister-chromatid exchange (SCE) frequency, increased sensitivity to cell killing, and a defect in DNA strand-break repair. The molecular basis for this pleotrophic phenotype is not known. We examined, at the chromosomal level, the increased sensitivity of this mutant to incorporated BrdUrd. By varying the amount of BrdUrd in template DNA and measuring the frequency of SCEs and chromosomal aberrations, we demonstrated the enhanced sensitivity of EM9 to BrdUrd present in the template strand of DNA. Our results show that a 6-fold increase in SCEs occurs due to DNA replication over a BrdUrd-substituted template relative to a dThd-substituted template. With regard to aberration production in EM9, there is a significant enhancement of aberrations and a specific bias toward damage for the chromatid with Brdurd in the template strand. While these cells share some phenotypic properties with cells from patients with Bloom's syndrome, the genotypic similarities have not yet been established.     

Characterization of the enhancing effect of caffeine on sister-chromatid exchanges induced by ultraviolet radiation in excision-proficient xeroderma pigmentosum lymphoblastoid cells

Cells of some excision-proficient xeroderma pigmentosum (XP) cell lines are highly sensitive to post-UV caffeine treatment in terms of sister-chromatid exchange (SCE) induction as well as cell lethality. In the present study, we conducted a detailed investigation of the enhancing effect of caffeine on SCE frequency induced by UV in excision-proficient XP cells, and obtained the following results. (1) Continuous post-UV treatment with 1 mM caffeine markedly enhances UV-induced SCEs and such enhanced SCEs occur with similar frequency during either the 1st or the 2nd cell cycle in the presence of caffeine and 5-bromodeoxyuridine (BrdUrd). (2) The high sensitivity of the cells to post-UV caffeine treatment persists for at least 2 days after UV when irradiated cells are held in either the proliferating or the nonproliferating state prior to the addition of BrdUrd. (3) Caffeine exerts its effect on cells in S phase. (4) Neither BrdUrd in the medium nor the incorporated 5-bromodeoxyuridine monophosphate (BrdUMP) in DNA plays an appreciable role in the expression of the enhancing effect of caffeine. The most likely explanation for our findings is as follows. In excision-proficient XP cells, the cause of SCE formation such as UV-induced lesions or resulting perturbations of DNA replication persists until the 2nd round or more of post-UV DNA replication. If caffeine is given as post-UV treatment, such abnormalities may be amplified, resulting in a synergistic increase in SCE frequency.     

Breakage of Parental DNA Strands in Haemophilus influenzae by 313 nm Radiation after Replication in the Presence of 5-Bromodeoxyuridine

Haemophilus influenzae was labeled with thymidine-³H (dThd), then grown in the presence of 5-bromodeoxyuridine (BrdUrd), and then irradiated with 313 nm light (a wavelength that selectively photolyzes DNA containing 5-bromouracil [BrUra]). Irradiation with 313 nm light induced breaks in the ³H-labeled strands in cells grown with BrdUrd at a much higher frequency than in ¹⁴C-labeled DNA of cells not exposed to BrdUrd. Breakage of the ³H-labeled strands was about 0.6% as efficient as that of fully BrUra-substituted DNA. During growth in the presence of BrdUrd, susceptibility to 313 nm-induced breakage of the ³H-labeled DNA strands increased, reaching a maximum in about one generation, and it decreased to zero during subsequent growth for one generation in medium containing dThd instead of BrdUrd. Heat denaturation of DNA extracted from dThd-³H-labeled cells grown in the presence of BrdUrd eliminated 313 nm-induced breakage of the ³H-labeled strands. It is concluded that breakage of the ³H-labeled DNA strands resulted from reaction with photoproducts in the base-paired, BrUra-containing strands, rather than from photolysis of BrdUrd incorporated into parental strands. It may be possible to utilize the phenomenon of interstrand breakage in physical studies of DNA replication.     

On the mechanism of 5-bromodeoxyuridine induction of prolactin synthesis in rat pituitary tumor cells

GH12C1, a clonal strain of rat pituitary tumor cells in culture (GH cells), does not produce detectable amounts of prolactin. 5-Bromodeoxyuridine (BrdUrd), the thymidine analogue, at sublethal concentrations (3-5 microgram/ml) induces prolactin synthesis in these cells. BrdUrd also induces prolactin synthesis in F1BGH12C1 cells, a BrdUrd resistant (BrdUrdr) substrain isolated from GH12C1 cells. The F1BGH12C1 strain is not drug dependent, but its resistance to BrdUrd is a stable phenotype. The significant features of the induction of prolactin synthesis in the BrdUrdr strain are the increased net synthesis of prolactin and the shortening of the lag period of prolactin induction. As BrdUrd concentration in the growth medium is increased, the rise in prolactin synthesis parallels the increased incorporation of BrdUrd into DNA. Prolactin synthesis is first detected when BrdUrd replaces 20-25% of the thymidine in DNA. BrdUrd can replace up to 75-80% of the thymidine within 2 d of treatment. Partial starvation of these cells under specified growth conditions does not affect the general growth pattern of the cells, general protein synthesis, and thymidine uptake, but does affect DNA synthesis. When cells are cultured under conditions in which DNA synthesis is preferentially inhibited, BrdUrd does not induce prolactin synthesis, suggestive of a DNA-mediated mechanism of action for the drug.     

Influence of incorporated bromodeoxyuridine on the induction of chromosomal alterations by ionizing radiation and long-wave UV in CHO cells

Incorporation of BrdUrd into nuclear DNA sensitizes CHO cells (1) to the induction of chromosomal aberrations by X-rays and 0.5 MeV neutrons and (2) to induction of chromosomal aberrations and SCEs by lw-UV. We have attempted to establish a correlation between induced chromosomal alterations and induced single- or double-strand breaks in DNA. The data show that while DSBs correlate very well with X-ray-induced aberrations, no clear correlation could be established between lw-UV induced SSBs (including alkali-labile sites) and chromosomal alterations.

In addition the effect of 3-aminobenzamide (3AB) on the induction of chromosomal aberrations and SCEs induced by lw-UV has been determined. It is shown that 3AB is without any effect when lw-UV-irradiated cells are posttreated with this inhibitor.

The significance of these results is discussed.     

DNA crosslinking, sister-chromatid exchange and specific-locus mutations

Chinese hamster ovary cells were treated with the DNA-crosslinking chemicals, mitomycin C (MMC) and porfiromycin (POR), and their monofunctional derivative decarbamoyl mitomycin C (DCMMC). After exposure, the cells were studied for the induction of sister-chromatid exchanges (SCEs) and mutations at the hypoxanthine phosphoribosyltransferase and adenine phosphoribosyltransferase loci. The frequency of SCEs varied significantly in successive sampling intervals, requiring the weighting of each interval by the percentage of second-division mitosis in that interval to obtain the mean SCE frequency for each dose. All 3 compounds were potent inducers of SCEs but weakly mutagenic. All 3 chemicals by concentration were approximately equally effective in inducing SCEs or mutations. When the induced SCEs and mutations were compared at equal levels of survival, DCMMC was slightly more effective than MMC or POR in inducing SCEs and somewhat less mutagenic. These results indicate that the DNA interstrand crosslink is not the major lesion responsible for the induction of SCE or mutation by these compounds.