Characteristics of mutagenesis induced by nitrosomethylurea in a mammalian multilocus system in vitro

The mutagenic effect of short- and long-term MNU exposition causing alkylation and that combined with carbamoylation, correspondingly, at the four specific gene loci of the CHO-AT3-2 Chinese hamster line was studied. The increase both in MNU mutagenic effects and in the range of induced changes resulted from intensification of carbamoylating processes. True point mutations occurred mainly on alkylation. When carbamoylation is increased, the quantity and variety of mutations change towards accumulation of the number of other genetic lesions, for example, frameshift mutations and deletions.     

Effect of alkylation and carbamoylation on the characteristics of genetic damage to mammalian somatic cells cultured in vitro

Genetic effects of alkylation alone and combined with carbamoylation were studied following treatment of CHO-AT3-2 Chinese hamster cell line with N-nitroso-N-methylurea for 7 and 60 min. Gene mutations at HGPRT and Na+/K+-ATPase loci, micronuclei, cells with fragmented nuclei and lethality caused by NMU were recorded. Prolonged exposure to the mutagen made these effects more pronounced, particularly the fragmented nuclei and cell death. The combined action of the two mechanisms, therefore, enhanced the mutagenic effects of alkylation and expanded the range of DNA lesions towards greater incidence of gross damage to chromosomes and chromatids.     

Comparison of the DNA-alkylating properties and mutagenic responses of a series of S-(2-haloethyl)-substituted cysteine and glutathione derivatives

The mutagenicity of 1,2-dibromoethane is highly dependent upon its conjugation to glutathione by the enzyme glutathione S-transferase. The conjugates thus formed can react with DNA and yield almost exclusively N7-guanyl adducts. We have synthesized the S-haloethyl conjugates of cysteine and glutathione, as well as selected methyl ester and N-acetyl derivatives, and compared them for ability to produce N7-guanyl adducts with calf thymus DNA. The cysteine compounds were found to be more reactive toward calf thymus DNA and yielded higher adduct levels than did the glutathione compounds. Adduct levels tended to be suppressed when there was a net charge on the compound and were not affected by substitution of bromine for chlorine, as expected for a mechanism known to involve an intermediate episulfonium ion. Sequence-selective alkylation of fragments of pBR322 DNA was investigated. The compounds produced qualitatively similar patterns of alkylation, with higher levels of alkylation at runs of guanines. The compounds were also tested for their ability to act as direct mutagens in Salmonella typhimurium TA98 and TA100. None of the compounds caused mutations in the TA98 frameshift mutagenesis assay. In the strain TA100, where mutation of a specific guanine by base-pair substitution produces reversion, all compounds were found to produce mutations, but the levels of mutagenicity did not correlate at all with the levels of DNA alkylation. The ratio of mutations to adducts varied at least 14-fold among the various N7-guanyl adducts examined.(ABSTRACT TRUNCATED AT 250 WORDS)     

Killing and mutagenic actions of dacarbazine, a chemotherapeutic alkylating agent, on human and mouse cells: effects of Mgmt and Mlh1 mutations

Among various types of drugs designed for use in cancer chemotherapy, some have the potential for alkylation. After metabolic activation, these chemicals attack DNA and alkylate their bases, thereby preventing multiplication of rapidly growing tumor cells. Some of alkylated bases cause mutations, leading to untoward induction of tumors. To search for the rationale to separate lethal and mutagenic effects of alkylation drugs, we investigated actions of dacarbazine, a monofunctional triazene, on mouse and human cell lines defective in the Mgmt and/or the Mlh1 gene, the former encoding a DNA repair methyltransferase and the latter a protein involved in mismatch repair and induction of apoptosis. Mgmt-deficient cells are hypersensitive to the killing action of dacarbazine. On the other hand, cells defective in both Mgmt and Mlh1 genes are as resistant to the drug as are wild-type cells, in terms of survival, but do have many mutations after dacarbazine treatment. Thus, the killing and mutagenic actions of dacabazine can be dissociated by manipulating actions of these gene products.     

Comparative Study on the Influence of Two 2-Chloroethylnitrosoureas with Different Carbamoylating Potential Towards Glutathione and Glutathione-Related Enzymes in Different Organs of the Rat

The influence of two CNUs with similar alkylating but strongly different carbamoylating activity towards the glutathione system was investigated in different organs. Both CNUs influence the glutathione system of the bone marrow in a similar manner, irrespective of their carbamoylating potential. In contrast, glutathione reductase activity in the other organs was strongly decreased by the potent carbamoylator BCNU, whereas no or only minor effects were produced by its weakly carbamoylating counterpart HECNU.

The results confirm that bone marrow toxicity of CNUs primarily results from alkylation and not from carbamoylation. Other organ-related toxic effects, however, are probably a result of carbamoylating reactions exerted by BCNU. This applies especially to lung toxicity that has been observed frequently as a major side effect in clinical trials with BCNU.     

Cell division transforms mutagenic lesions into deletion-recombinagenic lesions in yeast cells.

Cell proliferation has been recognized as an important factor in human and experimental carcinogenesis. Point mutations as well as larger chromosomal rearrangements are involved in the initiation of cancer. In this paper we compared the relative potencies of radiation and chemical carcinogens for inducing point mutations vs. deletions in cell cycle arrested with dividing cells of Saccharomyces cerevisiae. Point mutation substrates and deletion (DEL) recombination substrates were constructed with the genes CDC28 and TUB2 that are required for cell cycle progression through G1 and G2, respectively. The carcinogens ionizing radiation, UV, MMS, EMS and 4-NQO induced point mutations in G1 and in G2 arrested as well as in dividing cells. UV, MMS, EMS and 4-NQO caused very weak if any increases in DEL recombination in G1 or G2 arrested cells, but large increases in dividing cells. When cells treated with carcinogen either in G1 or G2 were allowed to progress through the cell cycle, a time-dependent increase in DEL recombination was seen. Ionizing radiation and the site-specific endonuclease I-SceI, which both directly create double-strand breaks, induced DEL recombination in G1 as well as in G2 arrested cells. In conclusion, UV-, MMS-, EMS- and 4-NQO-induced DNA damage was converted during DNA replication to a lesion capable of inducing DEL recombination which is probably a DNA strand break. Thus, cell proliferation is not necessary to turn DNA alkylation or UV damage into a mutagenic lesion but to convert the damage into a lesion that induces DNA deletions. These results are discussed with respect to mechanisms of carcinogenesis.     

Role of the carbamoylation reaction in the biological activity of methyl nitrosourea

Study of the mutagenic action of methyl nitrosourea (MNU) on the CHO-AT3-2 Chinese hamster cell at 2 regimes of cell treatment (a short-term regime and prolonged 1-h treatment) revealed that increase in the duration of treatment enhanced both cell lethality and clastogenic and mutagenic effects at the TK locus and did not influence the mutation frequency at the OUAr locus. On the basis of kinetic considerations it can be concluded that the base-pair substitution-type mutants (e.g., OUAr) appear as a result of DNA alkylation and the mutants at loci with a wide spectrum of registered mutants (the TK locus) are related to a greater extent to the carbamoylating activity of MNU. This conclusion is confirmed by measurements of the effects of sequential treatment with MNU (7 min) and KNCO (1 h). A synergistic increase in lethality, clastogenicity and mutagenicity at the TK locus was found in experiments with the combined treatment of cells with ethyl methanesulfonate (EMS) and KNCO. Besides, pretreatment of cells with potassium cyanate and subsequent exposure to MNU, EMS and benzopyrene (BP) produced synergistic effects in all the tests: lethality, clastogenicity and mutation frequency at the OUAr and TK loci. Posttreatment of cells with KNCO also led to a synergistic increase in the effects of MNU, EMS and BP treatment in several tests, but not in the OUAr locus. The possible mechanism and levels of interactions between alkylation and carbamoylation and the possibility that potassium cyanate causes supramolecular lesions are discussed.     

DNA polymerase mutagenic bypass and proofreading of endogenous DNA lesions

DNA polymerases differentiate between correct and incorrect substrates during synthesis on undamaged DNA templates through the biochemical steps of base incorporation, primer-template extension and proofreading excision. Recent research examining DNA polymerase processing of abasic, alkylation and oxidative lesions is reviewed in light of these discrimination mechanisms. Inhibition of DNA synthesis results from correct polymerase discrimination against utilization of geometrically incorrect template bases or 3' terminal basepairs. The efficiency of translesion synthesis is thus related to the physical structure of the lesion containing DNA. However, variations in enzyme structure and kinetics result in translesion synthesis efficiencies that are also dependent upon the DNA polymerase. With a low probability, polymerase misinsertion events create a 3' lesion terminus which is geometrically favored over the correct lesion basepair, resulting in mutagenic translesion synthesis. For example, both polymerase alpha and polymerase beta appear to require the formation of a stable 3' primer-template structure for efficient abasic site translesion synthesis. However, the enzymes differ as to the precise molecular make-up of the stable DNA structure, resulting in different mutational specificities. Similar mechanisms may be applicable to oxidative damage, where mutational specificities dependent upon the DNA polymerase also have been observed. In vitro reaction conditions also influence DNA polymerase processing of lesions. Using an in vitro herpes simplex virus thymidine kinase (HSV-tk) gene forward mutation assay, we demonstrate that high dNTP substrate concentrations affect the mutagenic specificity of translesion synthesis using alkylated templates. The exonuclease-deficient Klenow polymerase error frequency for G-->A transition mutations using templates modified by N-ethyl-N-nitrosourea (ENU) was four-fold higher at 1000 microM [dNTP], relative to 50 microM [dNTP], consistent with an increased efficiency of extension of the etO6G.T mispair. Moreover, the frequency of other ENU-induced polymerase errors was suppressed when polymerase reactions contained 50 microM dNTP, relative to 1000 microM dNTP. The efficiency of proofreading as a polymerase error discrimination mechanism reflects a balance between the competing processes of 3'-->5' exonuclease removal of mispairs and polymerization of the next correct nucleotide. Polymerases that are devoid of a proofreading exonuclease generally display enhanced abasic site translesion synthesis relative to proofreading-proficient enzymes. In addition, the proofreading exonucleases of Escherichia coli Pol I and T4 DNA polymerases have been found to remove mispairs caused by abasic sites and oxidative lesions, respectively, resulting in lowered polymerase error rates. However, the magnitude of the exonuclease effect is small (less than 10-fold), and highly dependent upon the DNA polymerase-exonuclease. We have studied proofreading exonuclease removal of alkylation damage in the HSV-tk forward assay. We observed no significant reduction in the magnitude of the mutant frequency vs. dose-response curves when N-methyl-N-nitrosourea or ENU-treated templates were used in exonuclease-proficient Klenow polymerase reactions, as compared to the exonuclease-deficient polymerase reactions. Thus, available data suggest that proofreading excision of endogenous lesion mispairs does occur, but the efficiency is dependent upon the lesion and the DNA polymerase-exonuclease studied.     

Chemical modification of an antineoplastic antibiotic bleomycetin by the C-end fragment]

Bleomycetin, an antitumor antibiotic, was subjected to chemical modification by the C-end fragment i.e. the residue of 3-[(4-aminobutyl)amino]propylamine (spermidine++) with acylation, carbamoylation and reducing alkylation, which yielded its new semisynthetic derivatives. The use of physicochemical methods showed that the chemical modification involved the primary and secondary amino groups++ of spermidine++ and gave rise to N,N'-diacyl, N,N'-dicarbamoyl and N,N'-dialkyl bleomycetins. The biological properties of the derivatives, i.e. their cytotoxic activity, acute and pulmonary toxicities were studied. The transformation of bleomycetin by the C-end fragment lowered the antibiotic toxicity and was believed to be a promising approach to modifying its molecule.     

Alkylation and carbamoylation intermediates from the carcinostatic 1-(2-chloroethyl)-3-cyclohexyl -1-nitrosourea (CCNU)

Evidence is presented which shows that 1-(2-chloroethyl) -3-cyclohexyl-1-nitrosourea (CCNU) upon degradation provides a 2-chloroethyl alkylating intermediate, possibly 2-chloroethyl carbonium ion, and 2-chloroethanol. Thiol alkylation occurs $\text{in vivo}$ and a major urinary metabolite of CCNU is thiodiacetic acid. A rapid microsomal hydroxylation of the cyclohexyl ring occurs which yields varying ratios of at least five metabolites: cis or trans 2-hydroxy, trans- 3-hydroxy, cis-3-hydroxy, cis-4-hydroxy and trans-4- hydroxy-CCNU. $\text{In vivo}$ carbamoylation appears to not be due to cyclohexylisocyanate but to the various hydroxy-cyclohexylisocyanates which are formed from hydroxy CCNU metabolites.     

HpaII methyltransferase is mutagenic in Escherichia coli.

A genetic reversion assay to study C-to-T mutations within CG sites in DNA is described. It was used to demonstrate that the presence of HpaII methyltransferase (MTase) in Escherichia coli causes a substantial increase in C-to-T mutations at CG sites. This is similar to the known mutagenic effects of E. coli MTase Dcm within its own recognition sequence. With this genetic system, a homolog of an E. coli DNA repair gene in Haemophilus parainfluenzae was tested for antimutagenic activity. Unexpectedly, the homolog was found to have little effect on the reversion frequency. The system was also used to show that HpaII and SssI MTases can convert cytosine to uracil in vitro. These studies define 5-methylcytosine as an intrinsic mutagen and further elaborate the mutagenic potential of cytosine MTases.     

Acetylcholinesterase engineering for detection of insecticide residues

To detect traces of insecticides in the environment using biosensors, we engineered Drosophila acetylcholinesterase (AChE) to increase its sensitivity and its rate of phosphorylation or carbamoylation by organophosphates or carbamates. The mutants made by site-directed mutagenesis were expressed in baculovirus. Different strategies were used to obtain these mutants: (i) substitution of amino acids at positions found mutated in AChE from insects resistant to insecticide, (ii) mutations of amino acids at positions suggested by 3-D structural analysis of the active site, (iii) Ala-scan analysis of amino acids lining the active site gorge, (iv) mutagenesis at positions detected as important for sensitivity in the Ala-scan analysis and (v) combination of mutations which independently enhance sensitivity. The results highlighted the difficulty of predicting the effect of mutations; this may be due to the structure of the site, a deep gorge with the active serine at the bottom and to allosteric effects between the top and the bottom of the gorge. Nevertheless, the use of these different strategies allowed us to obtain sensitive enzymes. The greatest improvement was for the sensitivity to dichlorvos for which a mutant was 300-fold more sensitive than the Drosophila wild-type enzyme and 288 000-fold more sensitive than the electric eel enzyme, the enzyme commonly used to detect organophosphate and carbamate.     

The correlation between mutation frequency and cell survival following different mutagenic treatments

Summary A direct mathematical relationship between mutation frequency per survivor and cell survival is derived from theoretical considerations of the molecular effects of radiation in a cell. It is shown that the relationship is satisfied by analysis of the various data on radiation induced mutations available in the literature. The analysis implies that a common type of lesion may lead to mutation and cell death and is derived on the assumption that radiation-induced double strand breaks in DNA are the critical lesions. The mathematical relationship is independent of the way in which the lesion which leads to mutations and cell death is induced, so the analysis has consequently been applied to other mutagenic treatments such as UV light and chemicals. It is concluded that, although the lesions induced by chemicals may not be the same as those induced by radiation, it is probable that for the chemicals considered common basic damage to the DNA molecule is implicated as the critical lesion.     

Action of chemical and physical mutagenic factors on the tetracycline producer Streptomyces aureofaciens

The mutagenic effects of N-nitrozomethylbiuret (N-NMB), N-nitrozomethylurea (N-NMU), N-nitrozodimethylurea (N-NDMU), ethylene imine and UV light on Str. aureofacients producing tetracycline was studied comparatively. It was shown that N-NMU and N-NMB had a higher toxicity and mutagenic activity as compared to N-NDMU. The toxicity levels of N-NMU and N-NMB were similar. Still, by the number of the morphological mutations induced by them N-NMU was more effective.     

Effects of carbamoylation with alkyl isocyanates on the assay of proteins by dye binding

The effect of carbamoylation with alkyl isocyanate was used both to monitor the stability of the isocyanates and to study the influence of charge modification on protein assay. Carbamoylation of poly (L-lysine) with methyl isocyanate, ethyl isocyanate and 2-chloroethyl isocyanate was observed to decrease binding of methyl orange. The data emphasized the lability of alkyl isocyanates and indicated the importance of preparing aqueous solutions at low temperatures for studies on protein carbamoylation. After carbamoylation of several proteins, there was decreased metachromasia on binding to Coomassie Blue G. Poly (L-lysine) and H1 histone showed anomalous behavior in that with low concentrations of Coomassie Blue G the metachromasia was increased by carbamoylation, but at high concentrations of the dye the metachromasia was decreased by carbamoylation. In contrast to some reports in the literature, the data indicated that there is not always a simple relationship between the positive charge on a protein and the interaction with anionic dyes.     

Determination of the mutagenic potential of an environmental pollutant, mercuric chloride

The effect of mercury chloride on the culture of rat fibroblast cells was studied for the test of DNA-breaks formation, for the survival and mutability of pox-virus vaccine and for the formation of dominant mutations in rats. The preparation had generally toxic, embryotoxic and mutagenic effects. To determine the genetic effects of environmental pollutants it was necessary to use some special methodological approaches.     

DNA-binding mechanism of O6-alkylguanine-DNA alkyltransferase. Effects of protein and DNA alkylation on complex stability

The mutagenic and cytotoxic effects of many endogenous and exogenous alkylating agents are mitigated by the actions of O(6)-alkylguanine-DNA alkyltransferase (AGT). In humans this protein protects the integrity of the genome, but it also contributes to the resistance of tumors to DNA-alkylating chemotherapeutic agents. Here we report properties of the interaction between AGT and short DNA oligonucleotides. We show that although AGT sediments as a monomer in the absence of DNA, it binds cooperatively to both single-stranded and double-stranded deoxyribonucleotides. This strong cooperative interaction is only slightly perturbed by active site mutation of AGT or by alkylation of either AGT or DNA. The stoichiometry of complex formation with 16-mer oligonucleotides, assessed by analytical ultracentrifugation and electrophoretic mobility shift assays, is 4:1 on single-stranded and duplex DNA and is unchanged by several active site mutations or by protein or DNA alkylation. These results have significant implications for the mechanisms by which AGT locates and interacts with repairable alkyl lesions to effect DNA repair.     

Spectrum of chemically induced mutations from a large-scale reverse-genetic screen in Arabidopsis

Chemical mutagenesis has been the workhorse of traditional genetics, but it has not been possible to determine underlying rates or distributions of mutations from phenotypic screens. However, reverse-genetic screens can be used to provide an unbiased ascertainment of mutation statistics. Here we report a comprehensive analysis of approximately 1900 ethyl methanesulfonate (EMS)-induced mutations in 192 Arabidopsis thaliana target genes from a large-scale TILLING reverse-genetic project, about two orders of magnitude larger than previous such efforts. From this large data set, we are able to draw strong inferences about the occurrence and randomness of chemically induced mutations. We provide evidence that we have detected the large majority of mutations in the regions screened and confirm the robustness of the high-throughput TILLING method; therefore, any deviations from randomness can be attributed to selectional or mutational biases. Overall, we detect twice as many heterozygotes as homozygotes, as expected; however, for mutations that are predicted to truncate an encoded protein, we detect a ratio of 3.6:1, indicating selection against homozygous deleterious mutations. As expected for alkylation of guanine by EMS, >99% of mutations are G/C-to-A/T transitions. A nearest-neighbor bias around the mutated base pair suggests that mismatch repair counteracts alkylation damage.     

Tubulin carbamoylation. Functional amino groups in microtubule assembly.

The characteristics of the carbamoylation of pig brain tubulin were examined by using the modification conditions with cyanate described previously [Mellado, Slebe + Maccioni (1980) Biochem. Int. I, 584--590]. The carbamoylation reaction resulted in an inhibition of microtubule assembly, which was dependent on the concentration of the modifying agent. This tubulin modification appears to inhibit the growth of microtubules. The presence of GTP did not protect tubulin against this inhibition. Electron microscopy showed a marked decrease in the number of tubules after carbamoylation, but no alterations were observed in the microtubule morphology. The incorporation of KN14CO into alpha- and beta-subunits with similar kinetics was also shown, and the carbamoylated residues were identified as epsilon-N-carbamoyl-lysine residues.     

Mechanism of the mutagenic action of the decay of incorporated phosphorus-32]

The experimental material concerning that physico-chemical consequences of 32P decay in the molecular structure of DNA, their reparation mechanism as well, and resulting mutagenic effects have been analysed. The reparation of the single-strand break of the DNA chain does not cause the changes of microdeletion and microinsertion type but instead of the changes observed are of the nucleic bases conversion type. It is concluded that the mutations caused by the decay of 32P incorporated appear as a result of errors in the selection of nucleic bases during the reparative replication of the non-conservative type.