DNA conformation-induced activation of an enediyne for site-specific cleavage.

Neocarzinostatin chromophore (NCS chrom) was found to induce site-specific cleavage at the 3' side of a bulge in single-stranded DNA in the absence of thiol. This reaction involved the oxidative formation of a DNA fragment with a nucleoside 5'-aldehyde at its 5' terminus and generated an ultraviolet light-absorbing and fluorescent species of post-activated drug containing tritium abstracted from the carbon at the 5' position of the target nucleotide. The DNAs containing point mutations that disrupt the bulge were not cleavage substrates and did not generate this drug product. Thus, DNA is an active participant in its own destruction, and NCS chrom may be useful as a probe for bulged structures in nucleic acids.

Solution structure of a two-base DNA bulge complexed with an enediyne cleaving analog.

Nucleic acid bulges have been implicated in a number of biological processes and are specific cleavage targets for the enediyne antitumor antibiotic neocarzinostatin chromophore in a base-catalyzed, radical-mediated reaction. The solution structure of the complex between an analog of the bulge-specific cleaving species and an oligodeoxynucleotide containing a two-base bulge was elucidated by nuclear magnetic resonance. An unusual binding mode involves major groove recognition by the drug carbohydrate unit and tight fitting of the wedge-shaped drug in the triangular prism pocket formed by the two looped-out bulge bases and the neighboring base pairs. The two drug rings mimic helical DNA bases, complementing the bent DNA structure. The putative abstracting drug radical is 2.2 +/- 0.1 angstroms from the pro-S H5' of the target bulge nucleotide. This structure clarifies the mechanism of bulge recognition and cleavage by a drug and provides insight into the design of bulge-specific nucleic acid binding molecules.

DNA damage and repair in relation to cell killing in neocarzinostatin-treated HeLa cells.

To elucidate the mechanism of the cell killing activity of neocarzinostatin on mammalian cells, the drug-induced damage of DNA and its repair were examined. Very low doses of neocarzinostatin, at which high survival of cells was observed, clearly produced single-strand breaks of DNA and decomposition of the 'DNA complex', but these damages appeared to be repaired almost completely. At higher doses of neocarzinostatin, single-strand breaks were repaired to a considerable extent while double-strand breaks seemed not to be repaired. The number of non-repairable single-strand breaks was about twice that of double-strand breaks. This implies that single-strand breaks are repaired except for those constituting double-strand breaks. Although at low levels of neocarzinostatin repair of double-strand breaks may occur, the correlation existing between the colony-forming ability of cells treated with neocarzinostatin and non-repairable DNA breakage suggests that production of a small number of critical non-repairable double-strand breaks per cell may be responsible for the cell killing activity of the drug.

Neocarzinostatin induction of DNA repair synthesis in HeLa cells and isolated nuclei.

The antitumor antibiotic neocarzinostatin that causes DNA strand breaks in vivo and in vitro is shown to induce DNA repair synthesis in HeLa S3 cells. In the repair assay, the parental DNA was prelabeled with 32P and a density label (bromodeoxyuridine) was introduced into the new synthesized DNA. Quantitation of the repair synthesis as measured by the incorporation of [3H]thymidine into the light parental DNA at varying doses of the drug indicate that there is a significant repair response at low levels of the drug (0.2--0.5 microgram/ml) which cause DNA strand breakage and inhibition of DNA synthesis. In isolated HeLa nuclei neocarzinostatin stimulates the incorporation of dTMP many-fold. This enhancement of dTMP incorporation, which requires the presence of a sulfhydryl agent, is a consequence of the drug-induced DNA strand breakage and is in the parental DNA. These results suggest that an intact cell membrane is not required for DNA strand breakage and its subsequent repair.

The relationship between DNA strand-scission and DNA synthesis inhibition in HeLa cells treated with neocarzinostatin.

Neocarzinostatin inhibits DNA synthesis in HeLa S3 cells and induces the rapid limited breakage of cellular DNA. The fragmentation of cellular DNA appears to precede the inhibition of DNA synthesis. Cells treated with drug at 37 degrees C for 10 min and then washed free of drug show similar levels of inhibition of DNA synthesis or cell growth, or of strand-scission of DNA as when cells were not washed. If cells are preincubated with neocarzinostatin at 0 degrees C before washing, the subsequent incubation of 37 degrees C results in no inhibition of DNA synthesis or cell growth, or cutting of DNA. Isolated nuclei or cell lysates derived from neocarzinostatin-treated HeLa S3 cells are inhibited in DNA synthesis but this can be overcome in cell lysates by adding activated DNA. A cytoplasmic fraction from drug-treated cells can stimulate DNA synthesis by nuclei isolated from untreated cells, whereas nuclei from drug-treated cells are not stimulated by the cytoplasmic fraction from untreated cells. By contrast, neocarzinostatin does not inhibit DNA synthesis when incubated with isolated nuclei, but it can be shown that under these conditions the DNA is already degraded and is not further fragmented by the drug. These data suggest that the drug's ability to induce breakage of cellular DNA in HeLa S3 cells is an essential aspect of its inhibition of DNA replication and may be responsible for the cytotoxic and growth-inhibiting actions of neocarzinostatin.

Single-strand nicking of DNA in vitro by neocarzinostatin and its possible relationship to the mechanism of drug action.

Neocarzinostatin, a protein antibiotic with anti-tumor activity was found to place single-strand scissions in DNA in an in vitro reaction. The drug's cutting activity was strongly dependent on the presence of 2-mercaptoethanol or dithiothreitol but some cutting did take place in the absence of reducing agent at very high drug levels and prolonged incubation. The requirement for reducing agents could not be replaced with NAD+, FAD, NADH or H2O2 and the strand-scission reaction was not affected by Mg2+, EDTA or intercalating agents. Similar profiles of heat-inactivation of neocarzinostatin were found whether activity was measured by the scission of DNA strand either in vitro or in HeLa cells treated with the drug. Furthermore, both of these parameters corresponded closely with the ability of the modified drug to inhibit DNA synthesis and growth of HeLa cells. By column isoelectric focusing it was shown that all four activities are associated with the same protein band (pH 3.28). From these data we conclude that the cytotoxic activity of neocarzinostatin and the nicking of DNA strands in vitro appear to reside in the same protein.

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.

A role of oxidative DNA sugar damage in mutagenesis by neocarzinostatin and bleomycin.

The anti-tumor antibiotics neocarzinostatin and bleomycin specifically oxidize deoxyribose in DNA at the C-5' and C-4' positions, respectively. The resulting DNA lesions include strand breaks and apyrimidinic sites. Both agents are broad specificity mutagens, inducing, in various systems, base substitutions, frameshifts and deletions. Sequencing studies in bacterial systems have suggested that the base substitutions may result primarily from replicative bypass of the oxidized apyrimidinic sites.

Synthesis and DNA binding of spirocyclic model compounds related to the neocarzinostatin chromophore.

[formula: see text] Spirocyclic model compounds which mimic the molecular architecture of one of the decomposition products of the antitumor agent NCS-chrom have been synthesized. These readily accessible molecules bind with remarkable efficiency to bulged DNA oligonucleotides, offering potential for the design of therapeutic agents.

Binding specificity of post-activated neocarzinostatin chromophore drug-bulged DNA complex studied using electrospray ionization mass spectrometry.

Electrospray ionization mass spectrometry (ESI-MS) was employed to characterize the binding specificity of a bulged 22-mer DNA hairpin with a post-activated neocarzinostatin chromophore (NCS-Chrom) having two similar forms, where 2a has an H in a location for which 2b has it replaced by a CH2OH group. Specific binding of 2a to the bulged 22-mer DNA was observed whereas little binding was detected for 2a to non-bulged DNA 19-mer and 12-mer duplexes. The stoichiometry of the 22-mer DNA complex with 2a was determined to be predominantly 1:1. Substitution of hydrogen in 2a for the hydroxymethylene group in 2b dramatically reduced the binding strength to the 22-mer DNA. Little complex formation was observed for 2b and 22-mer DNA based upon the ESI-MS data, consistent with earlier fluorescence studies. The results indicate that ESI-MS can be a sensitive technique for probing conformational specificity in studies of biomolecular binding.

Mechanism of activation of the antitumor antibiotic neocarzinostatin by mercaptan and sodium borohydride.

The structures of mercaptan and sodium borohydride reaction products of neocarzinostatin chromophore A (NCS Chrom A) are compared. Implications on the mechanism of activation of NCS are discussed.

Molecular mechanism of novel DNA sugar damage by an antitumour protein antibiotic.

Neocarzinostatin (NCS) belongs to a family of antitumour protein antibiotics that selectively inhibit DNA synthesis. Replicon initiation in mammalian cells is selectively inhibited by NCS, and cells defective in DNA repair, such as ataxia telangiectasia fibroblasts, are especially sensitive to NCS as they are to X-ray. The holoantibiotic consists of a nonprotein chromophore (Mr = 659), tightly and specifically bound to an apoprotein (Mr = 10,700). The apoprotein protects the highly labile chromophore from degradation in aqueous solution; all the activity resides in the nonprotein chromophore. The latter binds specifically to DNA, especially to regions rich in T and A residues, with a tight binding site consisting of four base pairs. NCS chromophore consists of three main structural subunits: a naphthoic acid derivative, an amino-sugar and a connecting highly unsaturated middle component (C12H5) with a strained ether (probably epoxide) and cyclic carbonate. The authors have proposed that the naphthoic acid subunit intercalates DNA and the positively charged amino sugar binds electrostatically to the negatively charged sugar phosphate backbone of DNA; these two anchors serve to juxtapose the middle piece with the deoxyribose of mainly thymidylate residues in DNA. Upon activation of the drug by a thiol (which forms an adduct with the middle piece) and in the presence of O2, there is a selective oxidation of the 5'-C of deoxyribose to produce a DNA strand break with a phosphate at the 3'-end and a nucleoside 5'-aldehyde at the other. Kinetic analysis shows that one molecule of thiol adds to DNA-bound NCS chromophore even in the absence of oxygen; this is rapidly followed by the consumption of 1 mol of O2 and then another mol of thiol. The oxygen of the 5'-aldehyde is derived from O2, not H2O. Even in the absence of O2 the NCS chromophore abstracts a hydrogen from C-5' of deoxyribose in DNA, presumably generating a carbon-centred radical intermediate in the DNA (other mechanisms have not been eliminated) which can add O2 to form a peroxy derivative. The second molecule of thiol may be involved in the cleavage of this complex to form the 5'-aldehyde at the strand break. There is no evidence for the involvement of metals or a diffusible form of reduced oxygen.(ABSTRACT TRUNCATED AT 400 WORDS)

Mode of reversible binding of neocarzinostatin chromophore to DNA: base sequence dependency of binding.

The reversible binding of neocarzinostatin chromophore to polynucleotides was studied in order to understand the molecular basis of its base sequence-specificity in DNA damage production. Studies of the spectroscopic and thermodynamic properties of chromophore-polynucleotide interactions reveal that the binding of the chromophore to poly(dA-dT) is qualitatively and quantitatively different from that to poly(dG-dC) (and poly(dI-dC]. From these and other experiments using double-stranded mixtures of homopolynucleotides, it is proposed that the observed A T specific intercalation might result from differential recognition of minor variations in the B-DNA type structure by the chromophore.