Alkylation of individual genes in rat liver by the carcinogen N-nitrosodimethylamine

Intra- and intercellular variations in the repair efficiency of O6-methylguanine, and their contribution to kinetic complexity

Following administration to rats of various doses of N-nitrosodimethylamine (NDMA), O(6)-methylguanine (O(6)-meG) was lost from the DNA of four tissues (liver, white blood cells, lymph nodes, bone marrow) over two, sharply demarcated phases with substantially differing repair rates. Repair during each phase followed approximately first-order kinetics in O(6)-meG, even after a high dose of NDMA which caused substantial depletion of O(6)-alkylguanine-DNA alkyltransferase (AGT), a suicide repair protein. This is compatible with rate-determining adduct repair being brought about by a distinct, minor pool of AGT molecules which is rapidly replenished by de novo AGT synthesis. Similar biphasic repair kinetics were also observed in HepG2 cells treated in vitro with NDMA. In this case, the first phase of repair was inhibited by alpha-amanitin, an inhibitor of RNA polymerase II-mediated transcription. However, no dependence on transcriptional activity was found when O(6)-meG repair in specific gene sequences with different transcriptional status in rat liver was examined, suggesting that the effects of alpha-amanitin in HepG2 cells did not reflect inhibition of preferential repair of transcribed sequences. Repair was also examined in rat liver hepatocytes and non-parenchymal cells separately after administration of NDMA at non-AGT depleting doses. Within each cell-population, the repair followed single phase, first-order kinetics, with adduct loss from AGT-rich hepatocytes being significantly faster than from the relatively AGT-deficient non-parenchymal cells. In conclusion, differences in the AGT content of different cell subpopulations in the liver (and probably in other tissues), as well as additional cellular factors affecting repair efficiency, appear to determine the observed variation in the kinetics of repair of O(6)-meG. The additional cellular factors involved appear not to be related to the transcriptional state of the sequences being repaired, but may reflect different states of chromatin condensation.

Intragenomic heterogeneity of DNA damage formation and repair: a review of cellular responses to covalent drug DNA interaction

Chemical DNA interaction and its processing can now be studied at the level of specific genomic regions. Such investigations have revealed important new information about the molecular biology of the cellular responses to genomic insult and especially of the repair processes. They also have demonstrated that both the formation and repair of DNA damage display patterns of intragenomic heterogeneity. Therefore, mechanistic studies should involve examination of DNA damage formation and repair in specific genomic sequences besides in the overall genome to provide clues to the way in which specific modifications of DNA or chromatin could have specific biological effects. This review primarily focuses on studies done to elucidate the nature of DNA damage induction and intragenomic processing provoked by covalent drug-DNA modification in mammalian cells. The involvement of DNA damage formation and cellular processing as critical factors for genomic injury is exemplified by studies of the novel alkylating morpholinyl anthracyclines and the bifunctional alkylating agent nitrogen mustard as a prototype agent for covalent drug DNA interaction.

Age-related studies on the removal of 7-methylguanine from DNA of mouse kidney tissue following N-methyl-N-nitrosourea treatment

To investigate the effects of age on DNA repair of alkylation damage, C57BL/6NNia mice ranging from 9 months to 29 months of age were injected by the intraperitoneal route with single doses of N-methyl-N-nitrosourea (MNU). The rates of removal of 7-methylguanine (m7Gua) in nuclear DNA from kidney were determined at various intervals from 1 to 288 h after injection of either 25 mg or 50 mg MNU per kg body weight. Reversed phase HPLC with electrochemical detection was used to monitor adduct disappearance from DNA hydrolysates. The kinetics of m7Gua removal from DNA were at least biphasic. Evidence was obtained that there was a rapid removal of m7Gua occurring in the first 24 h after MNU administration, followed by a slow phase of removal with a t1/2 greater than 150 h. We assume that these two phases of m7Gua removal correspond to active repair of DNA by N-alkylglycosylases and to passive elimination via spontaneous hydrolysis, respectively. Young and old kidney tissues all exhibited significant repair of m7Gua (55-73% of the induced adducts were removed in the first 24 h), but a substantial fraction of m7Gua was removed slowly, indicating that there are methylated bases which were refractory to repair processes. At both doses of MNU studied, old tissues showed active repair of m7Gua that, within the limits of detection, had similar initial rates of removal as young tissues. However, old kidney did not remove this adduct with the same overall efficiency as young kidney. Therefore, the amount of m7Gua in the repair-resistant fraction was greater in the senescent tissues. The biochemical mechanisms responsible for the less efficient DNA repair in senescent kidney are not known, but we suggest that such differences are due in part to structural alterations in the chromatin.

N-methyl-N-nitrosourea-induced mutations in human cells. Effects of the transcriptional activity of the target gene

In this study we addressed the question as to whether the mutagenesis by methylating agents is affected by the transcriptional activity of the damaged gene. An Epstein-Barr virus (EBV)-derived shuttle vector system was developed where the genetic target for mutation analysis, the bacterial gpt gene, is under the control of an eukaryotic inducible promoter in plasmid pF1-EBV and lacks the eukaryotic promoter in plasmid pF2-EBV. Two human cell lines that episomically maintain these shuttle vectors were established. In clone 6NT cells, which contain pF1-EBV plasmid, the gpt gene is actively transcribed and the transcription rate is regulated by zinc ions. In clone 3 cells, which harbor pF2-EBV plasmid, the gpt gene is not transcribed. Following treatment of both cell lines with the potent alkylating carcinogen N-methyl-N-nitrosourea (MNU), G.C to A.T transitions were the major mutagenic event, consistent with the miscoding potential of O6-methylguanine. The mutations were predominantly generated in the non-transcribed DNA strand of the active gpt gene. The same strand-bias was observed when the gpt gene was transcriptionally inactive, indicating that MNU-induced strand-specific formation of mutations is not due to transcription. Our data identify as major determinants of this phenomenon the sequence-specificity of MNU mutagenesis and the conformational properties of the target protein. Differences in mutation distribution were observed between the transcriptionally active and inactive gpt gene. This finding suggests that the organization of active genes in chromatin might modulate DNA alkylation and/or DNA repair.

Effects of N-methyl-N-nitrosourea on transcriptionally active and inactive nucleosomes: macromolecular damage and DNA repair

We previously reported a separation, on an organomercurial column, of transcriptionally inactive nucleosomes (class 1) from those containing active gene sequences (classes 2 and 3). In this paper, we analyzed nucleosomal damage caused by exposure of HeLa S3 cells in suspension culture to the directly alkylating carcinogen N-methyl-N-nitrosourea (MNU). The extent and site of methylation induced by the compound in nucleosomal DNA and RNA were determined by cell incubation in the presence of [3H]MNU. The highest amount of damage was detected in DNA of class 3 nucleosomes, while RNA alkylation was comparable in all nucleosomal classes. Cellular capacity for repair of MNU-induced DNA strand breaks (estimated after a short pulse with [3H]thymidine) was found to be higher in active nucleosomal fractions (classes 2 and 3) than in the inactive fraction (class 1). Our data support the postulate that chromatin primary structure plays a role in modulating carcinogen damage to chromosomal macromolecules and in DNA strand breakage and repair mechanisms. Some of these initial steps are believed to be critical in the process of carcinogenesis.

Two expressed human genes sustain slightly more DNA damage after alkylating agent treatment than an inactive gene

Alkylating agent damage was quantified in human T-lymphocytes by calculating gene-specific lesion frequencies and repair rates. At 3 time points after exposure to methyl methanesulfonate (0, 6, and 24 h), T-lymphocyte DNA was extracted, digested with HindIII, and divided into 2 aliquots. Apurinic sites were formed in the DNA fragments of both aliquots by heat-induced liberation of the N-methylpurines. The methoxyamine-treated aliquot provided gene fragments which were refractory to alkaline hydrolysis (full-length fragments), while the fragments in the untreated aliquot were cleaved at apurinic sites by hydroxide. After Southern blotting, lesion frequencies were calculated by comparing the band intensity of the full-length fragment to its unprotected counterpart. The restriction fragments analyzed were from the constitutively active dihydrofolate reductase (dhfr) plus hypoxanthine phosphoribosyltransferase (hprt) genes and from the transcriptionally inactive Duchenne muscular dystrophy gene (dmd). In decreasing order, the fragments containing the most lesions per kb of DNA were: hprt greater than dhfr greater than dmd. T-Lymphocytes from 2 females had 30% more heat-labile N-methylpurines in the active X-linked hprt gene than in the inactive X-linked dmd gene. The lesion frequency found in the male's lone hprt allele was the highest observed. These lesion frequency differences are discussed in terms of chromatin structure. After 6 and 24 h, no significant repair rate differences were observed among the 3 genes.

Monoclonal antibody-based, selective isolation of DNA fragments containing an alkylated base to be quantified in defined gene sequences

We have established a sensitive, monoclonal antibody (Mab)-based procedure permitting the selective enrichment of sequences containing the miscoding alkylation product O6-ethylguanine (O6-EtGua) from mammalian DNA. H5 rat hepatoma cells were reacted with the N-nitroso carcinogen N-ethyl-N-nitrosourea in vitro, to give overall levels of greater than or equal to 25 O6-EtGua residues per diploid genome (corresponding to O6-EtGua/guanine molar ratios of greater than or equal to 10(-8). For analysis, enzymatically restricted DNA from these cells is incubated with an antibody specific for O6-ethyl-2'-deoxyguanosine, the resulting Mab-DNA complexes are separated from (O6-EtGua)-free fragments by filtration through a nitrocellulose (NC) membrane, and the DNA is recovered from the filter-bound complexes quantitatively. The efficiency of Mab binding to DNA fragments containing O6-EtGua is constant over a range of O6-EtGua/guanine molar ratios between 10(-5) and 10(-8). (O6-EtGua)-containing restriction fragments encompassing known gene sequences (e.g., the immunoglobulin E heavy chain gene of H5 rat hepatoma cells used as a model in this study) are subsequently amplified by PCR and quantified by slot-blot hybridisation. The content and distribution of a specific carcinogen-DNA adduct in defined sequences of genomic DNA can thus be analyzed as well as the kinetics of intragenomic (toposelective) repair of any DNA lesion for which a suitable Mab is available.

Preferential methylation of the Ha-ras proto-oncogene by methylnitrosourea in rat mammary glands

Activation of the Ha-ras proto-oncogene, but not the Ki-ras or N-ras genes, has been found in mammary gland carcinomas induced in female rats by a single dose of methylnitrosourea (MNU). Here we show that a 10-kb restriction fragment containing the Ha-ras gene was extensively methylated by MNU in DNA isolated from mammary glands of female rats 4 h after carcinogen treatment. Fragments of similar size containing either the Ki-ras or N-ras genes were methylated less extensively. The extent of methylation of the three ras genes by MNU correlated with their transcriptional activity. These results suggest that the extent of interaction of a carcinogen with an oncogene, which depends on its transcriptional activity, may be a factor in determining whether the gene is mutated during the initiation of carcinogenesis.

Stimulation and inhibition of 1,3-bis(2-chloroethyl)-1-nitrosourea-induced strand breaks and interstrand cross-linking in Col E1 plasmid deoxyribonucleic acid by polyamines and inorganic cations

The influence of various polyamines and metallic cations on 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU)-induced DNA single-strand breaks and DNA interstrand cross-linking was in Col E1 plasmid using electrophoretic techniques. Spermidine and spermine (0.4 to 1.5 mM concentration range) markedly stimulated BCNU-induced DNA nicking, whereas putrescine had no effect on the nicking process. In contrast to the polyamines, BCNU-induced DNA nicking was decreased by the three inorganic cations, Na+ (100 and 200 mM), Mg2+ (0.5 and 1.5 mM), and Co3+ (NH3)6 (0.2 and 0.4 mM), with the trivalent hexamminecobalt ions being most inhibitory. When the monofunctional N-methyl-N-nitrosourea (MNU) was used (instead of the bifunctionally active BCNU) to alkylate Col E1 DNA, nicking of the DNA was inhibited by spermidine. Furthermore, the ability of chloroethylated Col E1 DNA to form interstrand cross-links after treatment with BCU was inhibited by 0.5 mM spermidine and 0.5 mM spermine, both concentrations within the intracellular range. Putrescine at 3-6 mM only marginally stimulated DNA cross-linking. In comparison, the inorganic cations all enhanced Col E1 DNA cross-linking by BCNU, with the rank order of cross-link stimulation being Mg2+, Na+, and Co3+ (NH3)6. These results provide evidence that polyamines can interact with DNA to modulate chloroethylnitrosourea-induced DNA damage and that the interaction is not only a function of the charge on the polyamine molecule but also of the chemical structure of the polyamine.