Comparison of dose-response relationships for ethyl methanesulfonate and 1-ethyl-1-nitrosourea in Drosophila melanogaster spermatozoa

The relative importance of different sites of alkylation on DNA was determined by comparing two ethylating agents. 1-Ethyl-1-nitrosourea (ENU) ethylates DNA with a higher proportion of total adducts on ring oxygens than ethyl methanesulfonate, which ethylates with a higher proportion of total adducts on the N-7 of guanine. Research with somatic cells in culture and prokaryotes strongly suggests that O6-guanine (O6-G) is the principal genotoxic site. To determine the importance in germ-line mutagenesis of the O6-G site relative to the N-7 of guanine, dose-response curves were constructed for both ENU and EMS, where dose was measured as total adducts per deoxynucleotide (APdN) and response as sex-linked recessive lethals (SLRL) induced in Drosophila melanogaster spermatozoa. For both mutagens the dose response curve was linear and extrapolated to the origin. The dose-response curve for ENU was fit to an equation m = 6.2D, and the dose response curve for EMS, from this and previous experiments, was m = 3.2D where m = %SLRL and D = APdN X 10(-3). Therefore, ENU is 1.9 times more efficient per adduct in inducing SLRL mutations than EMS. In vitro studies showed that ENU induced 9.5% of its total adducts on O6-G while EMS induced 2.0% of its adducts on O6-G. If O6-G was the sole genotoxic site, then ENU should be 4.8 times more efficient per adduct than EMS. In contrast, if N-7 G was the sole genotoxic site, ENU would be only 0.19 as effective as EMS. It was concluded that while O6-G was the principal genotoxic site, N-7 G made a significant contribution to germ-line mutagenesis.     

Methyl methanesulphonate (MMS) is clearly mutagenic in S. typhimurium strain TA1535; a comparison with strain TA100

No mutagenicity or an uncertain mutagenic response has been reported in the literature for methyl methanesulphonate (MMS) in S. typhimurium strain TA1535 when using the plate assay. In our studies we found a reproducible mutagenic activity of 62 revertants/mumole and plate for MMS in strain TA1535 when using the preincubation assay. A dose-dependent increase in revertants was, however, observed only at fairly high doses (exceeding 4 mumole). Two different slopes were observed in the dose-response curve when testing MMS with strain TA100. Slope A is dependent on the error-prone response, possible only in strain TA100 due to the pKm101 plasmid (R factor) but not possible in strain TA1535 due to its umuDC deficiency. Slope B observed at higher doses (as in strain TA1535) could be explained through a GC----AT transition initiated by the O6-methylation of guanine. Our findings demonstrate that MMS induces back mutation in S. typhimurium strains carrying the hisG46 missense mutation due to the formation of O6-methylguanine. In the case of strain TA100 the pKm101 plasmid-mediated error-prone mechanism is, however, the predominant process in MMS mutagenesis which leads to a higher mutagenic response at much lower doses than the GT----AT transition in strain TA1535.     

Involvement of separate pathways in the repair of mutational and lethal lesions induced by a monofunctional sulfur mustard.

The mutagenic and lethal effects of a monofunctional sulfur mustard, 2-chloro-ethylethylsulfide (CEES), have been studied in a number of repair deficient variants of Escherichia coli K12, B/r and B. The results indicate that CEES induces a (pre)mutational lesion which is subject to Uvr+-excision-repair. Extensive CEES-induced mutagenesis can occur in exrA- uvrA- and recA- uvrB- variants suggesting that the majority of the mutations in Uvr-bacteria do not arise from error-prone repair. These findings are similar to results previously reported with a volatile degradation product of captan and with ethyl methanesulfonate (EMS) but differ from those reported with methyl methanesulfonate (MMS). It is hypothesized that CEES alkylates guanine at the O-6 position (R-O-6-G) and that this R-O-6-G which is Uvr+-excisable is directly mutagenic by producing G-C to A-T transitions during replication. Reduced levels of induced mutation frequencies observed in an endonuclease II-deficient variant lead us to postulate that, in constrast to Uvr- bacteria, CEES-induced mutation in wild-type cells arise from error-prone repair of apurinic sites. Analysis of the lethal actions of CEES indicates that the lesion produced is largely unexcisable by the Uvr+ system. Host-cell reactivation of CEES-treated TI bacteriophage shows that the production of the (pre)ethal lesion is dependent on both the initial dose and post-treatment incubation. The efficient repair of the (pre)ethal lesion requires both endonuclease II and polymerase I. Moreover, deficiencies of these two enzymes rendered bacteria more sensitive to the cytotoxic action of CEES. It is postulated that the lethal mechanism of CEES involves: (I) alkylation at the N-3 position of adenine and the N-7 position of guanine; (2) spontaneous depurination of these alkylated bases; and (3) production of apurinic sites which are lethal unless repaired by the endonuclease II-polymerase I excision-repair system.     

Slow loss of deoxyribose from the N7deoxyguanosine adducts of estradiol-3,4-quinone and hexestrol-3',4'-quinone. Implications for mutagenic activity

A variety of evidence has been obtained that estrogens are weak tumor initiators. A major step in the multi-stage process leading to tumor initiation involves metabolic formation of 4-catechol estrogens from estradiol (E2) and/or estrone and further oxidation of the catechol estrogens to the corresponding catechol estrogen quinones. The electrophilic catechol quinones react with DNA mostly at the N-3 of adenine (Ade) and N-7 of guanine (Gua) by 1,4-Michael addition to form depurinating adducts. The N3Ade adducts depurinate instantaneously, whereas the N7Gua adducts depurinate with a half-life of several hours. Only the apurinic sites generated in the DNA by the rapidly depurinating N3Ade adducts appear to produce mutations by error-prone repair. Analogously to the catechol estrogen-3,4-quinones, the synthetic nonsteroidal estrogen hexestrol-3',4'-quinone (HES-3',4'-Q) reacts with DNA at the N-3 of Ade and N-7 of Gua to form depurinating adducts. We report here an additional similarity between the natural estrogen E2 and the synthetic estrogen HES, namely, the slow loss of deoxyribose from the N7deoxyguanosine (N7dG) adducts formed by reaction of E2-3,4-Q or HES-3',4'-Q with dG. The half-life of the loss of deoxyribose from the N7dG adducts to form the corresponding 4-OHE2-1-N7Gua and 3'-OH-HES-6'-N7Gua is 6 or 8 h, respectively. The slow cleavage of this glycosyl bond in DNA seems to limit the ability of these adducts to induce mutations.     

Repair of Alkylation Damage: Stability of Methyl Groups in Bacillus subtilis Treated with Methyl Methanesulfonate

Bacillus subtilis was not inactivated and was able to replicate even though approximately 3 x 10(4) methyl groups added by methyl methanesulfonate (MMS) were bound to the deoxyribonucleic acid (DNA) of each organism. No significant loss of methyl groups from the DNA occurred for several generations upon incubation of methylated wild-type or MMS-sensitive cells. Single-strand breaks were not observed in the DNA from cells treated at this low MMS dose. Higher doses of MMS resulted in significant killing of both wild-type and MMS-sensitive strains, and the DNA extracted from such treated cells sedimented more slowly than control DNA through alkaline sucrose gradients, indicating the presence of breaks or apurinic sites (or both). These breaks were repaired upon incubation of wild-type but not of MMS-sensitive strains. Repair of damage induced by alkylating agents is probably the repair of breaks which occur as a consequence of high levels of alkylation.     

Changes of 8-OH-dG levels in DNA and its base excision repair activity in rat lungs after inhalation exposure to hexavalent chromium

The co-genotoxic effects of cadmium are well recognized and it is assumed that most of these effects are due to the inhibition of DNA repair. We used the comet assay to analyze the effect of low, non-toxic concentrations of CdCl2 on DNA damage and repair-induced in Chinese hamster ovary (CHO) cells by UV-radiation, by methyl methanesulfonate (MMS) and by N-methyl-N-nitrosourea (MNU). The UV-induced DNA lesions revealed by the comet assay are single-strand breaks which are the intermediates formed during nucleotide excision repair (NER). In cells exposed to UV-irradiation alone the formation of DNA strand breaks was rapid, followed by a fast rejoining phase during the first 60 min after irradiation. In UV-irradiated cells pre-exposed to CdCl2, the formation of DNA strand breaks was significantly slower, indicating that cadmium inhibited DNA damage recognition and/or excision. Methyl methanesulfonate and N-methyl-N-nitrosourea directly alkylate nitrogen and oxygen atoms of DNA bases. The lesions revealed by the comet assay are mainly breaks at apurinic/apyrimidinic (AP) sites and breaks formed as intermediates during base excision repair (BER). In MMS treated cells the initial level of DNA strand breaks did not change during the first hour of recovery; thereafter repair was detected. In cells pre-exposed to CdCl2 the MMS-induced DNA strand breaks accumulated during the first 2h of recovery, indicating that AP sites and/or DNA strand breaks were formed but that further steps of BER were blocked. In MNU treated cells the maximal level of DNA strand breaks was detected immediately after the treatment and the breaks were repaired rapidly. In CdCl2 pre-treated cells the formation of MNU-induced DNA single-strand breaks was not affected, while the repair was slower, indicating inhibition of polymerization and/or the ligation step of BER. Cadmium thus affects the repair of UV-, MMS- and MNU-induced DNA damage, providing further evidence, that inhibition of DNA repair is an important mechanism of cadmium induced mutagenicity and carcinogenicity.     

Homologous recombination protects mammalian cells from replication-associated DNA double-strand breaks arising in response to methyl methanesulfonate

DNA-methylating agents of the S_N2 type target DNA mostly at ring nitrogens, producing predominantly N-methylated purines. These adducts are repaired by base excision repair (BER). Since defects in BER cause accumulation of DNA single-strand breaks (SSBs) and sensitize cells to the agents, it has been suggested that some of the lesions on their own or BER intermediates (e.g. apurinic sites) are cytotoxic, blocking DNA replication and inducing replication-mediated DNA double-strand breaks (DSBs). Here, we addressed the question of whether homologous recombination (HR) or non-homologous end-joining (NHEJ) or both are involved in the repair of DSBs formed following treatment of cells with methyl methanesulfonate (MMS). We show that HR defective cells (BRCA2, Rad51D and XRCC3 mutants) are dramatically more sensitive to MMS-induced DNA damage as measured by colony formation, apoptosis and chromosomal aberrations, while NHEJ defective cells (Ku80 and DNA-PK_CS mutants) are only mildly sensitive to the killing, apoptosis-inducing and clastogenic effects of MMS. On the other hand, the HR mutants were almost completely refractory to the formation of sister chromatid exchanges (SCEs) following MMS treatment. Since DSBs are expected to be formed specifically in the S-phase, we assessed the formation and kinetics of repair of DSBs by γH2AX quantification in a cell cycle specific manner. In the cytotoxic dose range of MMS a significant amount of γH2AX foci was induced in S, but not G1- and G2-phase cells. A major fraction of γH2AX foci colocalized with 53BP1 and phosphorylated ATM, indicating they are representative of DSBs. DSB formation following MMS treatment was also demonstrated by the neutral comet assay. Repair kinetics revealed that HR mutants exhibit a significant delay in DSB repair, while NHEJ mutants completed S-phase specific DSB repair with a kinetic similar to the wildtype. Moreover, DNA-PKcs inhibition in HR mutants did not affect the repair kinetics after MMS treatment. Overall, the data indicate that agents producing N-alkylpurines in the DNA induce replication-dependent DSBs. Further, they show that HR is the major pathway of protection of cells against DSB formation, killing and genotoxicity following S_N2-alkylating agents.     

Comparison of the Escherichia coli umu+-encoded function with plasmid R46-mediated error-prone repair in DNA-damaged cells

Escherichia coli strain TK701 umu+ was more resistant than strain TK702 umu when tested against bleomycin (BLM), cis-platinum(II) diamminodichloride (PDD), ultraviolet light and methyl methanesulphonate (MMS), which produce single-strand DNA damage. However, the umu mutant was no more sensitive to mitomycin C (MTC) or proflavine (PF), which cause double-strand DNA binding. Strain TK702 umu was nonmutable by any of the agents, whereas mutations were induced in the wild-type strain by PDD, UV, MMS and MTC. The E. coli umu+ function therefore mimics plasmid R46-mediated error-prone repair in protecting only against single-strand DNA damage, whilst enhancing mutagenesis by both single- and double-strand damaging agents. Comparison of plasmid R46-mediated protection and mutagenesis in umu+ and umu strains indicated that the plasmid confers a greater error-prone DNA-repair activity in the mutant. Results are discussed in terms of analogy between host umu+ and plasmid muc+ functions.     

The formation and repair of single-strand breaks in DNA of cultured mammalian cells treated with UV-light, methylating agents or 4-nitroquinoline-1-oxide.

The technique of sedimentation in alkaline sucrose was used to examine the formation and repair of single-strand (SS) breaks in cultured mammalian cells that were treated with methyl methanesulfonate (MMS), methyl nitrosourea (MNUA), 4-nitroquinoline-1-oxide (4NQO) or UV-light. The SS breaks induced by MMS and 4NQO were largely repaired by HeLa cells during a 5-h post-treatment incubation. The SS breaks induced by MNUA and UV-light were not repaired by HeLa cells. L-cells were not able to repair the SS breaks induced by any of the agents, which correlates with the deficiency of these cells for repair synthesis of DNA. The following conclusions are discussed. MNUA and UV-light produce modifications in DNA which are not repaired but are translated into SS breaks in alkali. MMS produces SS breaks intracellularly but these are not derived from a simple depurination of methylated purines. 4NQO produces a modification in DNA which is translated into an SS break in alkali but which can be removed by an intracellular process.     

Homologous recombination prevents methylation-induced toxicity in Escherichia coli

Methylating agents such as N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) and methyl methane sulfonate (MMS) produce a wide variety of N- and O-methylated bases in DNA, some of which can block replication fork progression. Homologous recombination is a mechanism by which chromosome replication can proceed despite the presence of lesions. The two major recombination pathways, RecBCD and RecFOR, which repair double-strand breaks (DSBs) and single-strand gaps respectively, are needed to protect against toxicity with the RecBCD system being more important. We find that recombination-deficient cell lines, such as recBCD recF, and ruvC recG, are as sensitive to the cytotoxic effects of MMS and MNNG as the most base excision repair (BER)-deficient (alkA tag) isogenic mutant strain. Recombination and BER-deficient double mutants (alkA tag recBCD) were more sensitive to MNNG and MMS than the single mutants suggesting that homologous recombination and BER play essential independent roles. Cells deleted for the polA (DNA polymerase I) or priA (primosome) genes are as sensitive to MMS and MNNG as alkA tag bacteria. Our results suggest that the mechanism of cytotoxicity by alkylating agents includes the necessity for homologous recombination to repair DSBs and single-strand gaps produced by DNA replication at blocking lesions or single-strand nicks resulting from AP-endonuclease action.     

The repair of methyl methanesulphonate-induced lesions in the DNA of a murine lymphoma cell

The introduction of single-strand breaks into the DNA of a murine lymphoma (L5178Y) cell treated in vivo with methyl methanesulphonate (MMS) and the behaviour of these breaks on post-treatment incubation were studied. A large proportion of single-strand breaks present after MMS treatment could be repaired as shown by sedimentation in alkaline sucrose. Two inhibitors of DNA synthesis, hydroxyurea and cytosine arabinoside affected the repair process differently-hydroxyurea had only a small effect while cytosine arabinoside blocked repair and at some doses allowed further degradation of the DNA. It was also found that the level of ‘repair replication’ in the presence of cytosine arabinoside was lower than that found in the presence of hydroxyurea.     

Relative biological effectiveness of tritiated water to gamma radiation for germ line mutations

The relative biological effectiveness was determined using sex-linked recessive lethals induced in Drosophila spermatozoa as the biological effect. The sex-linked recessive lethal test, a measure of mutations induced in germ cells and transmitted through successive generations, yields a linear dose-response curve in the range used in these experiments. A dose-response curve was determined from three exposures to tritiated water and three exposures to 60Co gamma radiation. The ratio of the slopes of these two response curves is 2.7 +/- 0.3, yielding a relative biological effectiveness that suggests the tritium beta particle is 2.7 times more effective per unit of energy absorbed in inducing gene mutations transmitted to successive generations than 60Co gamma radiation. The increase in relative biological effectiveness with higher linear energy transfer for tritium beta radiation strongly suggests that single-strand breaks are repaired by a nearly error-free repair mechanism. Ion tracks with a high density of ions (high linear energy transfer) are more efficient than tracks with a low ion density (low linear energy transfer) in inducing transmissible mutations, suggesting interaction among products of ionization. Since most transmitted mutations induced by ionizing radiation result from strand breakage, interaction probably occurs at this level with double-strand breaks being repaired by an error-prone mechanism yielding transmissible mutations.     

A comparison of mutation induction by 14 MeV fast neutrons and 137 Cs -rays in meiotic spermatocytes in the silkworm

Barley seeds were treated with methyl methanesulphonate (MMS) and ethyl methanesulphonate (EMS), stored at 15% water content and washed for 16–24 h. These treatments resulted in an increase of toxic and genetic effects. In teh DNA of embryos of such stored MMS- and EMS-treated seeds, a strong enhancement of the amount of single-strand breaks and/or alkali-labile sites took place. In contrast, the amount of alkylated sites, particularly of 7-methylguanine, was somewhat lower. It can be that the depurination and/or backbone breakage, which proceeds during the storage period, is responsible for the enhancement of toxic and genetic effects, whereas the influence of the alkylation of DNA during the storage period by the unreacted residual mutagen is negligible.     

Selectivity of the excision of alkylation products in a xeroderma pigmentosum-derived lymphoblastoid line.

Lymphoblastoid cell derived from a complementation group C xeroderma patient were unable to remove 06-methyl guanine residues formed in DNA by treatment of cells with low concentration of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). The xeroderma cells were competent in their ability to excise 3-methyl adenine adducts. MNNG treatment induced excision repair in the xeroderma line and in addition the treatment resulted in the presence of numerous single-strand breaks in the DNA. The single gene, UV-excision-defective mutants of Escherichia coli, uvrA and uvrB, are able to excise MNNG-induced 06-methyl guanine adducts indicating that excision of this compound is not due to operation of UV endonuclease system.     

Human cancer, carcinogenic exposures and mutation spectra

Exposure of mammalian cells to alkylating agents causes transfer of alkyl groups to N- as well as O-atoms of DNA bases. Especially the O-alkylated G and T bases have strong mutagenic properties, since they are capable of mispairing during replication. The mutagenic potential of N-alkylbases is less clear although specific base excision repair (BER) pathways exist which remove those lesions from the DNA. We investigated the relative contribution of N-alkylations to mutation induction at the Hprt gene in cultured Chinese hamster ovary cells (CHO). To this end BER activity in CHO cells was modulated by introduction of an expression vector carrying the rat N-alkylpurine-DNA glycosylase (APDG) gene, which codes for a glycosylase that is able to remove 3-methyladenine and 7-methylguanine from DNA thereby generating apurinic sites. Upon selection of a CHO clone which 10 times overproduced APDG compared to control CHO cells, mutation induction, the mutational spectrum, and cell survival were determined in both cell lines following treatment with methyl methanesulfonate (MMS). The results show that over-expression of APDG renders CHO cells more sensitive for mutation induction as well as cytotoxicity induced by MMS. The involvement of apurinic sites in induction of base pair changes at positions where 3-methyladenine was induced is inferred from the observation that the mutational spectrum of MMS-induced mutations in APDG-CHO cells showed twice as much base pair changes at AT base pairs (33.3%) compared to the spectrum of MMS-induced mutations in CHO-control cells (15.8%).     

Methylated DNA Causes a Physical Block to Replication Forks Independently of Damage Signalling, O-Methylguanine or DNA Single-Strand Breaks and Results in DNA Damage

Even though DNA alkylating agents have been used for many decades in the treatment of cancer, it remains unclear what happens when replication forks encounter alkylated DNA. Here, we used the DNA fibre assay to study the impact of alkylating agents on replication fork progression. We found that the alkylator methyl methanesulfonate (MMS) inhibits replication elongation in a manner that is dose dependent and related to the overall alkylation grade. Replication forks seem to be completely blocked as no nucleotide incorporation can be detected following 1 h of MMS treatment. A high dose of 5 mM caffeine, inhibiting most DNA damage signalling, decreases replication rates overall but does not reverse MMS-induced replication inhibition, showing that the replication block is independent of DNA damage signalling. Furthermore, the block of replication fork progression does not correlate with the level of DNA single-strand breaks. Overexpression of O⁶-methylguanine (O6meG)-DNA methyltransferase protein, responsible for removing the most toxic alkylation, O6meG, did not affect replication elongation following exposure to N-methyl-N′-nitro-N-nitrosoguanidine. This demonstrates that O6meG lesions are efficiently bypassed in mammalian cells. In addition, we find that MMS-induced γH2AX foci co-localise with 53BP1 foci and newly replicated areas, suggesting that DNA double-strand breaks are formed at MMS-blocked replication forks. Altogether, our data suggest that N-alkylations formed during exposure to alkylating agents physically block replication fork elongation in mammalian cells, causing formation of replication-associated DNA lesions, likely double-strand breaks.     

Alkylating agent and chromatin structure determine sequence context-dependent formation of alkylpurines

We determined the adduct maps of S(N)1 and S(N)2 alkylating agents in cultured human cells (in vivo) and in vitro to probe DNA-protein interactions along sequences of the promoter and exon 1 of the Fragile-X mental retardation 1 (FMR1) gene. Using ligation-mediated polymerase chain reaction (LMPCR), we compared the piperidine-sensitive alkylpurines sites generated by treating cultured cells (in vivo) and naked DNA (in vitro) with S(N)1 (N-methyl-N-nitrosourea, N-nitroso(acetoxymethyl)methylamine and 1-methyl-3-nitro-1-nitrosoguanidine) and S(N)2 alkylating agents (dimethyl sulfate (DMS), methane sulfonic acid methyl ester, iodo methane, diethyl sulfate, methane sulfonic acid ethyl ester and iodo ethane). The FMR1 promoter has four sites where DNA-protein interactions are observed. In these regions, the S(N)1 methylating agent reactions produced only hypo-reactive sites. In contrast, iodoalkane S(N)2 alkylating agents (MeI and EtI) reactions generated only hyper-reactive sites. Although there are hyper-reactive sites for the other S(N)2 reagents, the hyper-reactive site at +14 on the FMR1 map is more pronounced for the sulfate and sulfonate-derived alkylating agents than for the iodoalkanes. However, DMS modification in the presence of methyl sulfone, a compound that does not alkylate DNA, eliminates the hyper-reactive site observed at +14. This suggests that the electron-rich oxygen atoms of the sulfate and sulfonate-derived S(N)2 alkylating agent structure position the alkylating moiety to the neighboring N-7-guanine position to favor alkyl transfer to the guanine. Using KMnO(4) to probe for single-strand DNA, an unpaired cytosine base was detected at the 5'-side of the hyper- reactive guanine base at position +14, consistent with the formation of a local DNA single-strand bulge. In conclusion, we show that the sequence context-dependent formation of alkylpurines is determined by the chemical nature of the alkylating agent, the DNA sequence context, chromatin structure, and the presence of other non-reactive molecules that can inhibit alkylation.     

Survival and the repair of single-stranded DNA breaks in gamma-irradiated Escherichia coli cells adapted to methylmethane sulfonate]

The survival and repair of single-strand breaks of DNA in gamma-ray-irradiated E. coli adapted to MMS (20 mkg/ml during 3 hours) have been investigated. It is shown that the survival of adapted bacteria of radioresistant strains B/r, H/r30, AB1157 and W3110 pol+ increases with DMF (dose modification factor) ranging within 1.4-1.8 and in radiosensitive strains Bs-1, AB1157 recA13 and AB1157 lexA3 with DMF ranging within 1.3-1.4, and does not change in strains with mutation in polA gene P3478 polA1 and 016 res-3. There is no increase in radioresistance during the adaptation to MMS under the action of the protein synthesis inhibitor chloramphenicol. The increase in radioresistance during the adaptation to MMS correlates with the acceleration of repair of gamma-ray-induced single-strand breaks in the radioresistant strains B/r and W3110 pol+ and with the appearance of the ability to repair some part of DNA single-strand breaks in the mutant Bs-1, which beyond the adaptation to MMS does not repair these damages. The incomplete reparability of DNA single-strand breaks in P3478 polA1 strain cells, both adapted and non-adapted to MMS, is equal.     

Mammalian DNA single-strand break repair: an X-ra(y)ted affair

The genetic stability of living cells is continuously threatened by the presence of endogenous reactive oxygen species and other genotoxic molecules. Of particular threat are the thousands of DNA single-strand breaks that arise in each cell, each day, both directly from disintegration of damaged sugars and indirectly from the excision repair of damaged bases. If un-repaired, single-strand breaks can be converted into double-strand breaks during DNA replication, potentially resulting in chromosomal rearrangement and genetic deletion. Consequently, cells have adopted multiple pathways to ensure the rapid and efficient removal of single-strand breaks. A general feature of these pathways appears to be the extensive employment of protein-protein interactions to stimulate both the individual component steps and the overall repair reaction. Our current understanding of DNA single-strand break repair is discussed, and testable models for the architectural coordination of this important process are presented.     

Molecular Analysis of Mutations Induced in the Vermilion Gene of Drosophila Melanogaster by Methyl Methanesulfonate

The nature of DNA sequence changes induced by methyl methanesulfonate (MMS) at the vermilion locus of Drosophila melanogaster was determined after exposure of postmeiotic male germ cell stages. MMS is a carcinogen with strong preference for base nitrogen alkylation (s = 0.86). The spectrum of 40 intralocus mutations was dominated by AT----GC transitions (23%), AT----TA transversions (54%) and deletions (14%). The small deletions were preferentially found among mutants isolated in the F1 (8/18), whereas the AT----GC transitions exclusively occurred in the F2 (6/22). The MMS-induced transversions and deletions are presumably caused by N-methyl DNA adducts, which may release apurinic intermediates, known to be a time-related process. Furthermore, MMS produces multilocus deletions, i.e., at least 30% of the F1 mutants analyzed were of this type. A comparison of the mutational spectra of MMS with that produced by ethylnitrosourea (ENU), also in the vermilion locus of Drosophila, reveals major differences: predominantly transition mutations (61% GC----AT and 18% AT----GC) were found in both the F1 and F2 spectrum induced by ENU. It is concluded that the mutational spectrum of MMS is dominated by nitrogen DNA adducts, whereas with ENU DNA sequence changes mainly arose from modified oxygen in DNA.