The major mitomycin C-DNA monoadduct is cytotoxic but not mutagenic in Escherichia coli

Combination therapy delays antimicrobial resistance after adaptive laboratory evolution of Staphylococcus aureus

Antibiotic resistance, driven by misuse and overuse of antibiotics, is one of the greatest threats against human health. The antimicrobial pressure during prolonged antibiotic treatment of chronic bacterial infections selects for resistance. While antibiotic combinations may reduce resistance emergence, antibiotic-tolerant persister cells can serve as a reservoir for resistance development. Therefore, targeting these cells with anti-persister drugs might provide a novel strategy for resistance prevention. In this study, we conducted 42 days of adaptive laboratory evolution using Staphylococcus aureus exposed to rifampicin, ciprofloxacin, daptomycin, and vancomycin, alone or in combination with the anti-persister drug mitomycin C. We monitored antibiotic susceptibility daily and assessed phenotypic changes in growth and biofilm formation in evolved strains. Whole-genome sequencing revealed mutations linked to antibiotic resistance and phenotypic shifts. Rifampicin resistance developed within a few days, while ciprofloxacin and daptomycin emerged in approximately 3 weeks. Treatments with vancomycin or mitomycin C resulted in minimal changes in susceptibility. While combination therapy delayed resistance, it did not fully prevent it. Notably, the combination of rifampicin with mitomycin C maintained rifampicin susceptibility throughout the long-term evolution experiment. Sub-inhibitory antibiotic treatments selected for both previously characterized and novel mutations, including unprecedented alterations in the nucleotide excision repair system and azoreductase following mitomycin C exposure. The delayed resistance development observed with combination therapy, particularly mitomycin C's ability to suppress rifampicin resistance, suggests potential therapeutic applications. Future studies should evaluate the clinical efficacy of anti-persister drugs in preventing resistance across different bacterial pathogens and infection models.

Synthesis of Mitomycin C and decarbamoylmitomycin C N6 deoxyadenosine-adducts

Mitomycin C (MC), an anti-cancer drug, and its analog, decarbamoylmitomycin C (DMC), are DNA-alkylating agents. MC is currently used in the clinics and its cytotoxicity is mainly due to its ability to form Interstrand Crosslinks (ICLs) which impede DNA replication and, thereby, block cancer cells proliferation. However, both MC and DMC are also able to generate monoadducts with DNA. In particular, we recently discovered that DMC, like MC, can form deoxyadenosine (dA) monoadducts with DNA. The biological role played by these monoadducts is worthy of investigation. To probe the role of these adducts and to detect them in enzymatic digests of DNA extracted from culture cells treated by both drugs, we need access to reference compounds i.e. MC and DMC dA-mononucleoside adducts. Previous biomimetic methods used to generate MC and DMC mononucleoside adducts are cumbersome and very low yielding. Here, we describe the diastereospecific chemical synthesis of both C-1 epimers of MC and DMC deoxyadenosine adducts. The key step of the synthesis involves an aromatic substitution reaction between a 6-fluoropurine 2'-deoxyribonucleoside and appropriately protected stereoisomeric triaminomitosenes to form protected-MC-dA adducts with either an S or R stereochemical configuration at the adenine-mitosene linkage. Fluoride-based deprotection methods generated the final four reference compounds: the two stereoisomeric MC-dA adducts and the two stereoisomeric DMC-dA adducts. The MC and DMC-dA adducts synthesized here will serve as standards for the detection and identification of such adducts formed in the DNA of culture cells treated with both drugs.

Interdependent Sequence Selectivity and Diastereoselectivity in the Alkylation of DNA by Decarbamoylmitomycin C

Mitomycin C (MC), an antitumor drug, and decarbamoylmitomycin C (DMC), a derivative of MC, alkylate DNA and form deoxyguanosine monoadducts and interstrand crosslinks (ICLs). Interestingly, in mammalian culture cells, MC forms primarily deoxyguanosine adducts with a 1"-R stereochemistry at the guanine-mitosene bond (1"-α) whereas DMC forms mainly adducts with a 1"-S stereochemistry (1"-β). The molecular basis for the stereochemical configuration exhibited by DMC has been investigated using biomimetic synthesis. Here, we present the results of our studies on the monoalkylation of DNA by DMC. We show that the formation of 1"-β-deoxyguanosine adducts requires bifunctional reductive activation of DMC, and that monofunctional activation only produces 1"-α-adducts. The stereochemistry of the deoxyguanosine adducts formed is also dependent on the regioselectivity of DNA alkylation and on the overall DNA CG content. Additionally, we found that temperature plays a determinant role in the regioselectivity of duplex DNA alkylation by mitomycins: At 0 °C, both deoxyadenosine (dA) and deoxyguanosine (dG) alkylation occur whereas at 37 °C, mitomycins alkylate dG preferentially. The new reaction protocols developed in our laboratory to investigate DMC-DNA alkylation raise the possibility that oligonucleotides containing DMC 1"-β-deoxyguanosine adducts at a specific site may be synthesized by a biomimetic approach.

Comparative Error-Free and Error-Prone Translesion Synthesis of N(2)-2'-Deoxyguanosine Adducts Formed by Mitomycin C and Its Metabolite, 2,7-Diaminomitosene, in Human Cells

Mitomycin C (MC) is a cytotoxic and mutagenic antitumor agent that alkylates DNA upon reductive activation. 2,7-Diaminomitosene (2,7-DAM) is a major metabolite of MC in tumor cells, which also alkylates DNA. MC forms seven DNA adducts, including monoadducts and inter- and intrastrand cross-links, whereas 2,7-DAM forms two monoadducts. Herein, the biological effects of the dG-N(2) adducts formed by MC and 2,7-DAM have been compared by constructing single-stranded plasmids containing these adducts and replicating them in human embryonic kidney 293T cells. Translesion synthesis (TLS) efficiencies of dG-N(2)-MC and dG-N(2)-2,7-DAM were 38 ± 3 and 27 ± 3%, respectively, compared to that of a control plasmid. This indicates that both adducts block DNA synthesis and that dG-N(2)-2,7-DAM is a stronger replication block than dG-N(2)-MC. TLS of each adducted construct was reduced upon siRNA knockdown of pol η, pol κ, or pol ζ. For both adducts, the most significant reduction occurred with knockdown of pol κ, which suggests that pol κ plays a major role in TLS of these dG-N(2) adducts. Analysis of the progeny showed that both adducts were mutagenic, and the mutation frequencies (MF) of dG-N(2)-MC and dG-N(2)-2,7-DAM were 18 ± 3 and 10 ± 1%, respectively. For both adducts, the major type of mutation was G → T transversions. Knockdown of pol η and pol ζ reduced the MF of dG-N(2)-MC and dG-N(2)-2,7-DAM, whereas knockdown of pol κ increased the MF of these adducts. This suggests that pol κ predominantly carries out error-free TLS, whereas pol η and pol ζ are involved in error-prone TLS. The largest reduction in MF by 78 and 80%, respectively, for dG-N(2)-MC and dG-N(2)-2,7-DAM constructs occurred when pol η, pol ζ, and Rev1 were simultaneously knocked down. This result strongly suggests that, unlike pol κ, these three TLS polymerases cooperatively perform the error-prone TLS of these adducts.

Identification of Escherichia coli ygaQ and rpmG as novel mitomycin C resistance factors implicated in DNA repair

A genome-wide protein expression screen in Escherichia coli has identified new mitomycin C resistance factors, genes ygaQ and rpmG. These were characterized, revealing that ygaQ encodes a new nuclease enzyme and that RpmG is likely be an “idiosyncratic ribosomal protein” with a role in DNA repair by MutM.

Using the ASKA (A Complete Set of Escherichia coliK-12 ORF Archive) library for genome-wide screening of E. coli proteins we identified that expression of ygaQ and rpmG promotes mitomycin C resistance (MMC^R). YgaQ mediated MMC^R was independent of homologous recombination involving RecA or RuvABC, but required UvrD. YgaQ is an uncharacterized protein homologous with α-amylases that we identified to have nuclease activity directed to ssDNA of 5′ flaps. Nuclease activity was inactivated by mutation of two amino acid motifs, which also abolished MMC^R. RpmG is frequently annotated as a bacterial ribosomal protein, although forms an operon with MutM glycosylase and a putative deubiquitinating (DUB) enzyme, YicR. RpmG associated MMC^R was dependent on MutM. MMC^R from RpmG resembles DNA repair phenotypes reported for ‘idiosyncratic ribosomal proteins’ in eukaryotes.

Differential toxicity of DNA adducts of mitomycin C

The clinically used antitumor agent mitomycin C (MC) alkylates DNA upon reductive activation, forming six covalent DNA adducts in this process. This review focuses on differential biological effects of individual adducts in various mammalian cell cultures, observed in the authors' laboratories. Evidence is reviewed that various adducts are capable of inducing different cell death pathways in cancer cells.This evidence is derived from a parallel study of MC and its derivatives 2,7-diaminomitosene (2,7-DAM) which is the main metabolite of MC and forms two mono-adducts with DNA, and decarbamoyl mitomycin C (DMC), which alkylates and cross-links DNA, predominantly with a chirality opposite to that of the DNA adducts of MC. 2,7-DAM is not cytotoxic and does not activate the p53 pathway while MC and DMC are cytotoxic and able to activate the p53 pathway. DMC is more cytotoxic than MC and can also kill p53-deficient cells by inducing degradation of Checkpoint 1 protein, which is not seen with MC treatment of the p53-deficient cells. This difference in the cell death pathways activated by the MC and DMC is attributed to differential signaling by the DNA adducts of DMC. We hypothesize that the different chirality of the adduct-to-DNA linkage has a modulating influence on the choice of pathway.

Synthesis of an oligodeoxyribonucleotide adduct of mitomycin C by the postoligomerization method via a triamino mitosene

The cancer chemotherapeutic agent mitomycin C (MC) alkylates and cross-links DNA monofunctionally and bifunctionally in vivo and in vitro, forming six major MC-deoxyguanosine adducts of known structures. The synthesis of one of the monoadducts (8) by the postoligomerization method was accomplished both on the nucleoside and oligonucleotide levels, the latter resulting in the site-specific placement of 8 in a 12-mer oligodeoxyribonucleotide 26. This is the first application of this method to the synthesis of a DNA adduct of a complex natural product. Preparation of the requisite selectively protected triaminomitosenes 14 and 24 commenced with removal of the 10-carbamoyl group from MC, followed by reductive conversion to 10-decarbamoyl-2,7-diaminomitosene 10. This substance was transformed to 14 or 24 in several steps. Both were successfully coupled to the 2-fluoro-O(6)-(2-trimethylsilylethyl)deoxyinosine residue of the 12-mer oligonucleotide. The N(2)-phenylacetyl protecting group of 14 after its coupling to the 12-mer oligonucleotide could not be removed by penicillinamidase as expected. Nevertheless, the Teoc protecting group of 24 after coupling to the 12-mer oligonucleotide was removed by treatment with ZnBr2 to give the adducted oligonucleotide 26. However, phenylacetyl group removal was successful on the nucleoside-level synthesis of adduct 8. Proof of the structure of the synthetic nucleoside adduct included HPLC coelution and identical spectral properties with a natural sample, and (1)H NMR. Structure proof of the adducted oligonucleotide 26 was provided by enzymatic digestion to nucleosides and authentic adduct 8, as well as MS and MS/MS analysis.

Biological properties of single chemical-DNA adducts: a twenty year perspective

The genome and its nucleotide precursor pool are under sustained attack by radiation, reactive oxygen and nitrogen species, chemical carcinogens, hydrolytic reactions, and certain drugs. As a result, a large and heterogeneous population of damaged nucleotides forms in all cells. Some of the lesions are repaired, but for those that remain, there can be serious biological consequences. For example, lesions that form in DNA can lead to altered gene expression, mutation, and death. This perspective examines systems developed over the past 20 years to study the biological properties of single DNA lesions.

Mutagenicity of the 1-nitropyrene-DNA adduct N-(deoxyguanosin-8-yl)-1-aminopyrene in mammalian cells

The mutagenesis of the major DNA adduct N-(deoxyguanosin-8-yl)-1-aminopyrene (C8-AP-dG) formed by 1-nitropyrene was compared with the analogous C8-dG adducts of 2-aminofluorene (AF) and N-acetyl-2-aminofluorene (AAF) in simian kidney (COS-7) cells. The DNA sequence chosen for this comparison contained 5'-CCATC GCTACC-3' that has been used for solution NMR investigations. The structural and conformational differences among these lesions are well-established [Patel, D. J., Mao, B., Gu, Z., Hingerty, B. E., Gorin, A., Basu, A. K., and Broyde,S. (1998) NMR solution structures of covalent aromatic amine-DNA adducts and their mutagenic relevance. Chem. Res. Toxicol. 11, 391- 407.]. Accordingly, we found a notable difference in the viability of the progeny, which showed that the AAF adduct was most toxic and that the AF adduct was least toxic, with the AP adduct exhibiting intermediate toxicity. However, analysis of the progeny showed that translesion synthesis was predominantly error-free. Only low-level mutations (<3%) were detected with G-->T as the dominant type of mutation by all three DNA adducts. When C8-AP-dG was evaluated in a repetitive 5'-CGC GCG-3' sequence, higher mutational frequency ( approximately 8%) was observed. Again, G-->T was the major type of mutations in simian kidney cells, even though in bacteria CpG deletions predominate in this sequence [Hilario, P., Yan, S., Hingerty, B. E., Broyde, S., and Basu, A. K. (2002) Comparative mutagenesis of the C8-guanine adducts of 1-nitropyrene,and 1,6- and 1,8-dinitropyrene in a CpG repeat sequence: A slipped frameshift intermediate model for dinucleotide deletion. J. Biol. Chem. 277, 45068- 45074.]. Mutagenesis of C8-AP-dG in a 12-mer containing the local DNA sequence around codon 273 of the p53 tumor suppressor gene, where the adduct was located at the second base of this codon, was also investigated. In this 5'-GTGC GTGTTTGT-3' site, the mutations were slightly lower but not very different from the progeny derived from the 5'-CGC GCG-3' sequence. However, the mutational frequency increased by more than 50% when the 5'-C to the adduct was replaced with a 5-methylcytosine (5-MeC). With a 5-MeC, the most notable change in mutation was the enhancement of G-->A, which occurred 2.5 times relative to a 5'-C. The C8-AP-dG adduct in codon 273 dodecamer sequence with a 5'-C or 5-MeC was also evaluated in human embryonic kidney (293T) cells. Similar to COS cells, targeted mutations doubled with a 5-MeC 5' to the adduct. Except for an increase in G-->C transversions, the results in 293T were similar to that in COS cells. We conclude that C8-AP-dG mutagenesis depends on the type of cell in which it is replicated, the neighboring DNA sequence, and the methylation status of the 5'-C.

Genetic effects of oxidative DNA damages: comparative mutagenesis of the imidazole ring-opened formamidopyrimidines (Fapy lesions) and 8-oxo-purines in simian kidney cells

Fapy.dG and 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxo-dG) are formed in DNA by hydroxyl radical damage. In order to study replication past these lesions in cells, we constructed a single-stranded shuttle vector containing the lesion in 5'-TGT and 5'-TGA sequence contexts. Replication of the modified vector in simian kidney (COS-7) cells showed that Fapy.dG is mutagenic inducing primarily targeted Fapy.G-->T transversions. In the 5'-TGT sequence mutational frequency of Fapy.dG was approximately 30%, whereas in the 5'-TGA sequence it was approximately 8%. In parallel studies 8-oxo-dG was found to be slightly less mutagenic than Fapy.dG, though it also exhibited a similar context effect: 4-fold G-->T transversions (24% versus 6%) occurred in the 5'-TGT sequence relative to 5'-TGA. To investigate a possible structural basis for the higher G-->T mutations induced by both lesions when their 3' neighbor was T, we carried out a molecular modeling investigation in the active site of DNA polymerase beta, which is known to incorporate both dCTP (no mutation) and dATP (G-->T substitution) opposite 8-oxo-G. In pol beta, the syn-8-oxo-G:dATP pair showed greater stacking with the 3'-T:A base pair in the 5'-TGT sequence compared with the 3'-A:T in the 5'-TGA sequence, whereas stacking for the anti-8-oxo-G:dCTP pair was similar in both 5'-TGT and 5'-TGA sequences. Similarly, syn-Fapy.G:dATP pairing showed greater stacking in the 5'-TGT sequence compared with the 5'-TGA sequence, while stacking for anti-Fapy.G:dCTP pairs was similar in the two sequences. Thus, for both lesions less efficient base stacking between the lesion:dATP pair and the 3'-A:T base pair in the 5'-TGA sequence might cause lower G-->T mutational frequencies in the 5'-TGA sequence compared to 5'-TGT. The corresponding lesions derived from 2'-deoxyadenosine, Fapy.dA and 8-oxo-dA, were not detectably mutagenic in the 5'-TAT sequence, and were only weakly mutagenic (<1%) in the 5'-TAA sequence context, where both lesions induced targeted A-->C transversions. To our knowledge this is the first investigation using extrachromosomal probes containing a Fapy.dG or Fapy.dA site-specifically incorporated, which showed unequivocally that in simian kidney cells Fapy.G-->T substitutions occur at a higher frequency than 8-oxo-G-->T and that Fapy.dA is very weakly mutagenic, as is 8-oxo-dA.

DNA adduct of the mitomycin C metabolite 2,7-diaminomitosene is a nontoxic and nonmutagenic DNA lesion in vitro and in vivo

Mitomycin C (MC) is a cytotoxic and mutagenic antitumor agent that alkylates and cross-links DNA. These effects are dependent on reductive bioactivation of MC. 2,7-Diaminomitosene (2,7-DAM) is the major metabolite of MC in tumor cells, generated by the reduction of MC. 2,7-DAM alkylates DNA in the cell in situ, forming an adduct at the N7 position of 2'-deoxyguanosine (2,7-DAM-dG-N7). To determine the biological effects of this adduct, we have synthesized an oligonucleotide containing a single 2,7-DAM-dG-N7 adduct and inserted it into an M13 bacteriophage genome. Replication of this construct in repair-competent Escherichia coli showed that the adduct was only weakly toxic and generated approximately 50% progeny as compared to control. No mutant was isolated after analysis of more than 4000 progeny phages from SOS-induced or uninduced host cells; therefore, we estimate that the mutation frequency of 2,7-DAM-dG-N7 was less than 2 x 10(-4) in E. coli. Subsequently, to determine if this adduct might be mutagenic in mammalian cells, it was incorporated into a single-stranded shuttle phagemid vector, pMS2, and replicated in simian kidney (COS-7) cells. Analysis of the progeny showed that mutational frequency of a site specific 2,7-DAM-dG-N7 was not higher than the spontaneous mutation frequency in simian kidney cells. In parallel experiments in cell free systems, template oligonucleotides containing a single 2,7-DAM-dG-N7 adduct directed selective incorporation of cytosine in the 5'-32P-labeled primer strands opposite the adducted guanine, catalyzed by Klenow (exo-) DNA polymerase. The adducted templates also supported full extension of primer strands by Klenow (exo-) and T7 (exo-) DNA polymerases and partial extension by DNA polymerase eta. The innocuous behavior of the 2,7-DAM-dG-N7 monoadduct in vivo and in vitro is in sharp contrast to that of the toxic MC-dG-N2 monoadduct reported earlier.

Mutagenesis of 8-Oxoguanine Adjacent to an Abasic Site in Simian Kidney Cells: Tandem Mutations and Enhancement of G→T Transversions

Clustered DNA damages are well-established characteristics of ionizing radiation. As a model clustered lesion in the same strand of DNA, we have evaluated the mutagenic potential of 8-oxoguanine (8-oxoG) adjacent to a uracil in simian kidney cells using a phagemid vector. The uracil residue would be excised by the enzyme uracil DNA glycosylase in vivo generating an abasic site (AP site). A solitary uracil in either GUGTC or GTGUC sequence context provided >60% progeny containing GTGTC indicating that dAMP incorporation opposite the AP site or uracil occurred, but a >30% population showed replacement of U by A, C, or G, which suggests that dTMP, dGMP, or dCMP incorporation also occurred, respectively, opposite the AP site. While the preference for targeted base substitutions at the GUG site was T >> C > A > G, the same at the GUC site was T >> A > C > G. We conclude that base incorporation opposite an AP site is sequence-dependent. For 8-oxoG, as compared to 23-24% G-->T mutants from a single 8-oxoG in a TG(8-oxo)T sequence context, the tandem lesions UG(8-oxo)T and TG(8-oxo)U generated approximately 60 and >85% progeny, respectively, that did not contain the TGT sequence. A significant fraction of tandem mutations were detected when uracil was adjacent to 8-oxoG. What we found most interesting is that the total targeted G(8-oxo)-->T transversions that included both single and tandem mutations at the TG(8-oxo)U site was nearly 60% relative to about 30% at the UG(8-oxo)T site. A higher mutational frequency at the TG(8-oxo)U sequence may arise from a change in DNA polymerase that is more error prone. Thermal melting experiments showed that the Tm for the 8-oxoG:C pair in the TG(8-oxo)(AP*) sequence in a 12-mer was lower than the same in a (AP*)G(8-oxo)T 12-mer with deltadeltaG 0.8 kcal/mol (where AP* represents tetrahydrofuran, the model abasic site). When the 8-oxoG:C pair in each sequence was compared with a 8-oxoG:A pair, the former was found to be more stable than the latter. The preference for C over A opposite 8-oxoG for the (AP*)G(8-oxo)T 12-mer duplex with a deltadeltaG of 1.6 kcal/mol dropped to 0.4 kcal/mol in the TG(8-oxo)(AP*) 12-mer duplex. This suggests that the polymerase discrimination to incorporate dCMP over dAMP would be less efficient in the TG(8-oxo)(AP*) sequence relative to (AP*)G(8-oxo)T. Additionally, the efficiency of recognition and excision of A opposite 8-oxoG by a mismatch repair protein may be impaired in the TG(8-oxo)(AP*) sequence context.

Site-specifically located 8-amino-2'-deoxyguanosine: thermodynamic stability and mutagenic properties in Escherichia coli

2-Nitropropane (2-NP), an important industrial solvent and a component of cigarette smoke, is mutagenic in bacteria and carcinogenic in rats. 8-Amino-2'-deoxyguanosine (8-amino-dG) is one of the types of DNA damage found in liver, the target organ in 2-NP-treated rats. To investigate the thermodynamic properties of 8-amino-dG opposite each of the four DNA bases, we have synthesized an 11mer, d(CCATCG*CTACC), in which G* represents the modified base. By annealing a complementary DNA strand to this modified 11mer, four sets of duplexes were generated each containing one of the four DNA bases opposite the lesion. Circular dichroism studies indicated that 8-amino-dG did not alter the global helical properties of natural right-handed B-DNA. The thermal stability of each duplex was examined by UV melting measurements and compared with its unmodified counterpart. For the unmodified 11mer, the relative stability of the complementary DNA bases opposite G was in the order C > T > G > A, as determined from their -DeltaG degrees values. The free energy change of each modified duplex was lower than its unmodified counterpart, except for the G*:G pair that exhibited a higher melting transition and a larger -DeltaG degrees than the G:G duplex. Nevertheless, the stability of the modified 11mer duplex also followed the order C > T > G > A when placed opposite 8-amino-dG. To explore if 8-amino-dG opposite another 8-amino-dG has any advantage in base pairing, a G*:G* duplex was evaluated, which showed that the stability of this duplex was similar to the G*:G duplex. Mutagenesis of 8-amino-dG in this sequence context was studied in Escherichia coli, which showed that the lesion is weakly mutagenic (mutation frequency approximately 10(-3)) but still can induce a variety of targeted and semi-targeted mutations.

Mutagenicity of the 1-nitropyrene-DNA adduct N-(deoxyguanosin-8-yl)-1-aminopyrene in Escherichia coli located in a nonrepetitive CGC sequence

1-Nitropyrene, a common environmental pollutant, forms a major DNA adduct, N-(deoxyguanosin-8-yl)-1-aminopyrene (dG(AP)). Mutational spectra of randomly introduced dG(AP) in Escherichia coli included many different types of mutations. However, a prior site-specific study in a CGCG(AP)CG sequence showed only CpG deletions and +1 frame shifts. To further explore the context effects of dG(AP) in mutagenesis, in this work this adduct was incorporated into a nonrepetitive CGC sequence in single-stranded M13mp7L2 DNA. Upon replication of this construct in repair-competent E. coli, one-base deletions and base substitutions were detected. The -1 frame shifts, whose frequency increased 3-6-fold with SOS (to an average frequency of 1.5%), involved deletion of the adjacent C residues. The base substitutions ( approximately 2.2%) included targeted G-to-T and G-to-C transversions, whose frequencies did not increase with SOS. This suggests that dG(AP) mutagenesis is highly dependent on the local DNA sequence.

Iminium ion chemistry of mitosene DNA alkylating agents. Enriched 13C NMR and isolation studies

Described herein is a study of the reductive alkylation chemistry of mitosene antitumor agents. We employed a 13C-enriched electrophilic center to probe the fate of the iminium ion resulting from reductive activation. The 13C-labeled center permitted the identification of complex products resulting from alkylation reactions. In the case of DNA reductive alkylation, the type and number of alkylation sites were readily assessed by 13C NMR. Although there has been much excellent work done in the area of mitosene chemistry and biochemistry, the present study provides a number of new findings: (1) The major fate of the iminium ion is head-to-tail polymerization, even in dilute solutions. (2) Dithionite reductive activation results in the formation of mitosene sulfite esters as well as the previously observed sulfonate adducts. (3) The mitosene iminium ion alkylates the adenosine 6-amino group as well as the guanosine 2-amino group. The identification of the latter adduct was greatly facilitated by the 13C-label at the electrophilic center. (4) The mitosene iminium ion alkylates DNA at both nitrogen and oxygen centers without any apparent base selectivity. The complexity of mitosene reductive alkylation of DNA will require continued adduct isolation studies.

A mitomycin-N6-deoxyadenosine adduct isolated from DNA

A minor N6-deoxyadenosine adduct of mitomycin C (MC) was isolated from synthetic oligonucleotides and calf thymus DNA, representing the first adduct of MC and a DNA base other than guanine. The structure of the adduct (8) was elucidated using submilligram quantities of total available material. UV difference spectroscopy, circular dichroism, and electrospray mass spectroscopy as well as chemical transformations were utilized in deriving the structure of 8. A series of synthetic oligonucleotides was designed to probe the specificities of the alkylation of adenine by MC. The nature and frequency of the oligonucleotide-MC adducts formed under conditions of reductive activation of MC were determined by their enzymatic digestion to the nucleoside level followed by quantitative analysis of the products by HPLC. The analyses indicated the following: (i) (A)n sequence is favored over (AT)n for adduct formation; (ii) the alkylation favors the duplex structure; (iii) at adenine sites only monofunctional alkylation occurs; (iv) the adenine-to-alkylation frequency in the model oligonucleotides was 0.3-0.6 relative to guanine alkylation at the 5'-ApG sequence but only 0.02-0.1 relative to guanine alkylation at 5'-CpG. The 5'-phosphodiester linkage of the MC-adenine adduct is resistant to snake venom diesterase. The overall ratio of adenine to guanine alkylation in calf thymus DNA was 0.03, indicating that 8 is a minor MC-DNA adduct relative to MC-DNA adducts at guanine residues in the present experimental residues in the present experimental system. However, the HPLC elution time of 8 coincides with that of a major, unknown MC adduct detected previously in mouse mammary tumor cells treated with radiolabeled MC [Bizanek, R., Chowdary, D., Arai, H., Kasai, M., Hughes, C. S., Sartorelli, A. C., Rockwell, S., and Tomasz, M. (1993) Cancer Res. 53, 5127-5134]. Thus, 8 may be identical or closely related to this major adduct formed in vivo. This possibility can now be tested by further comparison.