Design, synthesis, and evaluation of a novel sequence-selective epoxide-containing DNA cross-linking agent based on the pyrrolo[2, 1-c][1,4]benzodiazepine system.

Synthetic routes have been investigated to prepare a novel C8-epoxide-functionalized pyrrolo[2,1-c][1,4]benzodiazepine 6 as a potential sequence-selective DNA cross-linking agent (Wilson et al. Tetrahedron Lett. 1995, 36, 6333-6336). A successful synthesis was accomplished via a 10-step route involving a pro-N10-Fmoc cleavage method that should have general applicability to other pyrrolobenzodiazepine (PBD) molecules containing acid- or nucleophile-sensitive groups. During the course of this work, a one-pot reductive cyclization procedure for the synthesis of PBD N10-C11 imines from nitro dimethyl acetals was also discovered, although this method results in C11a racemization which can reduce DNA binding affinity and cytotoxicity. The target epoxide 6 was shown by thermal denaturation studies to have a significantly higher DNA-binding affinity than the parent DC-81 (3) or the C8-propenoxy-PBD (15), which is structurally similar but lacks the epoxide moiety. The time course of effects upon thermal denaturation indicated a rapid initial binding phase followed by a slower phase consistent with the stepwise cross-linking of DNA observed for a difunctional agent. This was confirmed by an electrophoretic assay which demonstrated efficient induction of interstrand cross-links in plasmid DNA at concentrations >1 microM. Higher levels of interstrand cross-linking were observed at 24 h compared to 6 h incubation. A Taq polymerase stop assay indicated a preference for binding to guanine-rich sequences as predicted for bis-alkylation in the minor groove of DNA by epoxide and imine moieties. The pattern of stop sites could be partly rationalized by molecular modeling studies which suggested low-energy models to account for the observed binding behavior. The epoxide PBD 6 was shown to have significant cytotoxicity (45-60 nM) in the A2780, CH1, and CH1cis(R) human ovarian carcinoma cell lines and an IC(50) of 0.2 microM in A2780cis(R). The significant activity of 6 in the cisplatin-resistant CH1cis(R) cell line (IC(50) = 47 nM) gave a resistance factor of 0.8 compared to the parent cell line, demonstrating no cross-resistance with the major groove cross-linking agent cisplatin.

The effect of AT and GC sequence specific minor groove-binding agents on restriction endonuclease activity.

The ability of the naturally occurring A/T specific DNA minor groove binders netropsin and diastamycin A and two synthetic G/C selective oligopeptide analogues (1 and 2), to interfere with the catalytic activity of restriction endonucleases has been investigated. Enzymes were chosen to have A/T rich (EcoRI, EcoRV) or G/C rich (BalI, NruI) recognition sequences. An agarose gel assay was used to measure the cleavage of 32P-labelled DNA and ligand-DNA binding data was obtained using methidium-propyl EDTA footprinting. Netropsin and distamycin bind at the recognition sites, and dose-dependently inhibited cleavage by, EcoRI and EcoRV, (EcoRI > EcoRV). They were also more effective at inhibiting the catalytic activity of BalI than either 1 or 2. NruI was inhibited by distamycin and 2, but not by netropsin or 1. DNA footprinting revealed that neither 1 or 2 bound to the BalI or NruI recognition sequences under the conditions used whereas netropsin and distamycin footprint at adjacent sites. 1 binds to two of the three recognition sequences for the enzyme Fnu4HI (GCNGC) in the fragment studied and was shown to inhibit DNA cleavage only at these two sites. 2 binds strongly to two GGGCTC sequences which are recognition sites for the enzyme BanII. In this case a pronounced stimulation of cleavage was observed in the presence of 2 over a wide dose range. The results indicate that enzyme inhibition does not necessarily result from simultaneous occupancy of a common site, or at nearby flanking sequences, and in some circumstances, a pronounced stimulation of enzyme cleavage can occur.

Measurement of the sequence specificity of covalent DNA modification by antineoplastic agents using Taq DNA polymerase.

A polymerase stop assay has been developed to determine the DNA nucleotide sequence specificity of covalent modification by antineoplastic agents using the thermostable DNA polymerase from Thermus aquaticus and synthetic labelled primers. The products of linear amplification are run on sequencing gels to reveal the sites of covalent drug binding. The method has been studied in detail for a number of agents including nitrogen mustards, platinum analogues and mitomycin C, and the sequence specificities obtained accord with those obtained by other procedures. The assay is advantageous in that it is not limited to a single type of DNA lesion (as in the piperidine cleavage assay for guanine-N7 alkylation), does not require a strand breakage step, and is more sensitive than other primer extension procedures which have only one cycle of polymerization. In particular the method has considerable potential for examining the sequence selectivity of damage and repair in single copy gene sequences in genomic DNA from cells.

Effect of ionic strength and cationic DNA affinity binders on the DNA sequence selective alkylation of guanine N7-positions by nitrogen mustards.

Large variations in alkylation intensities exist among guanines in a DNA sequence following treatment with chemotherapeutic alkylating agents such as nitrogen mustards, and the substituent attached to the reactive group can impose a distinct sequence preference for reaction. In order to understand further the structural and electrostatic factors which determine the sequence selectivity of alkylation reactions, the effect of increased ionic strength, the intercalator ethidium bromide, AT-specific minor groove binders distamycin A and netropsin, and the polyamine spermine on guanine N7-alkylation by L-phenylalanine mustard (L-Pam), uracil mustard (UM), and quinacrine mustard (QM) was investigated with a modification of the guanine-specific chemical cleavage technique for DNA sequencing. For L-Pam and UM, increased ionic strength and the cationic DNA affinity binders dose dependently inhibited the alkylation. QM alkylation was less inhibited by salt (100 mM NaCl), ethidium (10 microM), and spermine (10 microM). Distamycin A and netropsin (100 microM) gave an enhancement of overall QM alkylation. More interestingly, the pattern of guanine N7-alkylation was qualitatively altered by ethidium bromide, distamycin A, and netropsin. The result differed with both the nitrogen mustard (L-Pam less than UM less than QM) and the cationic agent used. The effect, which resulted in both enhancement and suppression of alkylation sites, was most striking in the case of netropsin and distamycin A, which differed from each other. DNA footprinting indicated that selective binding to AT sequences in the minor groove of DNA can have long-range effects on the alkylation pattern of DNA in the major groove.

Photosensitization of human leukemic cells by anthracenedione antitumor agents.

1,4-Diamino-substituted anthraquinone antitumor agents (mitoxantrone and ametantrone) and structurally related 1,5- and 1,8-diamino-substituted compounds (AM1 and AM2) were tested for their ability to photosensitize human leukemic cells in culture. Viability was measured using the 3,4,5-dimethylthiazol-2,5-diphenyl tetrazolium bromide assay, and DNA and membrane damage were assessed. Following a 1-h exposure to AM2, a dose of drug required to give 50% loss of cell viability (53 microM) was obtained in the dark, which was reduced to approximately 2.4 microM following illumination for 2 min (lambda greater than 475 nm), a dose of light that was completely nontoxic to the cells in the absence of drug. A shift in the cell viability curve was also observed for AM1 but, under identical conditions, the dose modification was only 8.9. In contrast, neither ametantrone nor mitoxantrone gave a decreased viability upon illumination. DNA single-strand breaks as measured by alkaline elution correlated with cell viability. Frank DNA single-strand breaks were produced by AM2 and light, suggesting the production of free radicals. The strand breaks produced by AM2 in the dark and by mitoxantrone (with or without illumination) were protein concealed. No evidence of photo-induced membrane damage, as determined by transport of the model amino acid cycloleucine, could be observed even at supralethal doses.