Neocarzinostatin abstracts a hydrogen during formation of nucleotide 5'-aldehyde on DNA

Neocarzinostatin as a probe for DNA protection activity--molecular interaction with caffeine

Neocarzinostatin (NCS), a potent mutagen and carcinogen, consists of an enediyne prodrug and a protein carrier. It has a unique double role in that it intercalates into DNA and imposes radical-mediated damage after thiol activation. Here we employed NCS as a probe to examine the DNA-protection capability of caffeine, one of common dietary phytochemicals with potential cancer-chemopreventive activity. NCS at the nanomolar concentration range could induce significant single- and double-strand lesions in DNA, but up to 75 ± 5% of such lesions were found to be efficiently inhibited by caffeine. The percentage of inhibition was caffeine-concentration dependent, but was not sensitive to the DNA-lesion types. The well-characterized activation reactions of NCS allowed us to explore the effect of caffeine on the enediyne-generated radicals. Postactivation analyses by chromatographic and mass spectroscopic methods identified a caffeine-quenched enediyne-radical adduct, but the yield was too small to fully account for the large inhibition effect on DNA lesions. The affinity between NCS chromophore and DNA was characterized by a fluorescence-based kinetic method. The drug-DNA intercalation was hampered by caffeine, and the caffeine-induced increases in DNA-drug dissociation constant was caffeine-concentration dependent, suggesting importance of binding affinity in the protection mechanism. Caffeine has been shown to be both an effective free radical scavenger and an intercalation inhibitor. Our results demonstrated that caffeine ingeniously protected DNA against the enediyne-induced damages mainly by inhibiting DNA intercalation beforehand. The direct scavenging of the DNA-bound NCS free radicals by caffeine played only a minor role.

Ultraviolet light-induced cleavage of DNA in the presence of iodoHoechst 33258: the sequence specificity of the reaction

IodoHoechst 33258 sensitizes DNA to cleavage by near ultraviolet light (UV-A). Following an earlier study which showed that the UV-induced cleavage is at discrete locations corresponding to the ligand binding sites, this paper reports a more extensive analysis of the sequence specificity of cleavage. The experiments involved use of double-stranded DNA synthesised on primed M13 templates. Analysis of cleavage in a 280bp sequence in M13mp18 and a 310bp sequence in three M13mp9 clones ('alpha-32', 'alpha-82' and 'alpha-22') derived from human alpha-DNA, showed that for all of the twenty-nine strong and very strong damage sites, cleavage was at the 3' end of a run of three or more consecutive AT base pairs. The extent of cleavage was higher for sites with consecutive Ts than for consecutive As, and greatest for the sequence cTTTTca. Comparison of three closely-related alpha-DNA clones enabled assessment of single bp changes and essentially confirmed the results of detailed analysis of binding cleavage sites in mp18 and alpha-32. Decreasing the input ratio of iodoHoechst/per bp DNA from 0.13 to 0.013 altered the sequence specificity, and sites possessing only three consecutive AT bps were generally not cleaved. The contributions of both the strength of ligand binding and the efficiency of photolytic cleavage to the overall extent of cleavage by UV/iodoHoechst are discussed, in view of the potential utility of the ligand as a probe of DNA conformation.

Enhancement of radiosensitivity of cultured mammalian cells by neocarzinostatin. I. Inhibition of the repair of sublethal damage

The enhancement of radiosensitivity by neocarzinostatin (NCS), an antitumour drug, was studied using three strains of cultured mammalian cells with different repair capabilities for sublethal damage. NCS enhanced the radiosensitivity of the cells when applied both during and after X-irradiation under aerobic conditions. The enhancement ratios of NCS during X-irradiation were 1.25, 1.27 and 1.38 for mouse lymphoma L5178Y, Chinese hamster V79 and mouse mammary tumour FM 3A cells, respectively. The corresponding ratios after X-irradiation were 1.18, 1.27 and 1.38, respectively. These ratios were proportional to the repair capabilities of the cells for sublethal damage. NCS completely inhibited the repair of sublethal damage regardless of the repair capabilities of the cells for sublethal damage. NCS was equally effective for hypoxic cells. These results suggested that NCS enhanced the radiosensitivity of the cells probably by interacting with the residual damage after X-irradiation, thereby converting the sublethal damage or potentially lethal damage into lethal damage.

Radiation sensitization by an iodine-labelled DNA ligand

An iodinated DNA ligand, iodo Hoechst 33258, which binds in the minor groove of DNA, enhances DNA strand breakage and cell killing by UV-A irradiation. The sites of UV-induced strand breaks reflect the known sequence specificity of the ligand.

Sites in the diyne-ene bicyclic core of neocarzinostatin chromophore responsible for hydrogen abstraction from DNA

The antitumor antibiotic neocarzinostatin exhibits its main drug action by abstracting hydrogen from DNA deoxyribose with consequent strand breakage or related lesions. All biological activities of the drug derive solely from a nonprotein chromophoric substance (NCS-chrom) consisting of a novel epoxy-bicyclo-diyne-ene system. Thiol or sodium borohydride activates NCS-chrom into a labile, reactive species that induces DNA damage but causes inactivation of the drug in the absence of the target DNA. Mass spectrometric studies indicate that the isolated thiol-activated NCS-chrom product in the presence of DNA has the same molecular weight as the thiol-inactivated NCS-chrom product in the absence of DNA. No deuterium is incorporated into the chromophore from the deuterium-labeled sulfhydryl group. Since three deuterium atoms can be incorporated into the drug by treatment with sodium borodeuteride without DNA, adding an unlabeled DNA under parallel conditions permitted the ready identification of the activated NCS-chrom product that abstracted hydrogen from the DNA. Not only does the activated NCS-chrom product have the same structure as the inactivated drug without DNA, but two of the incorporated deuterium atoms have been substituted by hydrogen. With the aid of NMR spectrometry, the two replaced hydrogen atoms are found to be incorporated into the C-2 and C-6 positions of the bicyclo-diyne-ene ring of NCS-chrom and are derived neither from borodeuteride nor from the hydroxyl functions of the solvents. In accord with current proposals, the two hydrogens incorporated into the drug may come from closely opposed sites on the complementary strands of the DNA at which the drug is bound.(ABSTRACT TRUNCATED AT 250 WORDS)

Free radical mechanisms in neocarzinostatin-induced DNA damage

The molecular mechanisms by which the antitumor protein antibiotic, neocarzinostatin, interacts with DNA and causes DNA sugar damage is discussed. Physical binding of the nonprotein chromophore of neocarzinostatin to DNA, involving an intercalative process and dependent on the microheterogeneity of DNA structure, is followed by thiol activation of the drug to a probable radical species. The latter attacks the deoxyribose, especially at thymidylate residues, by abstracting a hydrogen atom from C-5' to generate a carbon-centered radical on the DNA. This nascent form of DNA damage either reacts with dioxygen to form a peroxyl radical derivative, which eventuates in a strand break with a nucleoside 5'-aldehyde at the 5'-end or reacts with the bound drug to form a novel drug-deoxyribose covalent adduct. Nitroaromatic radiation sensitizers can substitute for dioxygen, but the DNA damage products are different. Similarities between the various biological effects of neocarzinostatin and ionizing radiation are reviewed.

Mode of reversible binding of neocarzinostatin chromophore to DNA: evidence for binding via the minor groove

Two general approaches have been taken to understand the mechanism of the reversible binding of the nonprotein chromophore of neocarzinostatin to DNA: (1) measurement of the relative affinity of the chromophore for various DNAs that have one or both grooves blocked by bulky groups and (2) studies on the influence of adenine-thymine residue-specific, minor groove binding agents such as the antibiotics netropsin and distamycin on the chromophore-DNA interaction. Experiments using synthetic DNAs containing halogen group (Br, I) substituents in the major groove or natural DNAs with glucosyl moieties projecting into the major groove show that obstruction of the major groove does not decrease the binding stoichiometry or the binding constant for the DNA-chromophore interaction. Chemical methylation of bases in both grooves of calf thymus DNA, resulting in 13% methylation of N-7 of guanine in the major groove and 7% methylation of N-3 of adenine in the minor groove, decreases the binding affinity and increases the size of the binding site for neocarzinostatin chromophore. Similar results were obtained whether binding parameters were determined directly by spectroscopic measurements or indirectly by measuring the ability of the DNA to protect the chromophore against degradation. On the other hand, netropsin and distamycin compete with neocarzinostatin chromophore for binding to the minor groove of DNA, as shown by their decrease in the ability of poly(dA-dT) to protect the chromophore against degradation and their reduction in chromophore-induced DNA damage as measured by thymine release.(ABSTRACT TRUNCATED AT 250 WORDS)

Activation of neocarzinostatin chromophore and formation of nascent DNA damage do not require molecular oxygen

Thiol-activated neocarzinostatin chromophore abstracts tritium from the 5', but not from the 1' or 2' positions of deoxyribose in DNA and incorporates it into a stable, non-exchangeable form. The abstracted tritium remains covalently associated with the chromophore or its degradation product after treatment with acid or alkali, respectively. Drug activation and the consequent hydrogen abstraction reaction, presumably generating a carbon-centered radical at C-5', do not require molecular oxygen but have a dose-dependent relation with thiol. Under aerobic conditions, where base release and DNA strand breaks with nucleoside 5'-aldehyde at the 5'-ends are produced, hydrogen abstraction from C-5' parallels these parameters of DNA damage. It is possible to formulate a reaction scheme in which the carbon- centered radical at C-5' is an intermediate in the formation of the various DNA damage products found under both aerobic and anaerobic conditions.

Poly(deoxyadenylic-deoxythymidylic acid) damage by radiolytically activated neocarzinostatin

The anaerobic reaction of poly(deoxyadenylic-deoxythymidylic acid) with neocarzinostatin activated by the carboxyl radical CO2-, an electron donor generated from gamma-ray radiolysis of nitrous oxide saturated formate buffer, has been characterized. DNA damage includes base release and strand breaks. Few strand breaks are formed prior to alkaline treatment; they bear 3'-phosphoryl termini. In contrast, most (66%) of the base release occurs spontaneously. DNA damage is highly (95%) specific for thymidine sites. Neither DNA-drug covalent adduct nor nucleoside 5'-aldehyde, which are major products in the DNA-nicking reaction initiated by mercaptans and oxygen, is formed in this reaction. Data are presented to show that the CO2(-)-activated neocarzinostatin intermediate is a short-lived free radical able to abstract hydrogen atoms from the C-1' and C-5' positions of deoxyribose. Attack occurs mostly (68%) at the C-1' position, producing a lesion whose properties are consistent with those of (oxidized) apyrimidinic sites.