Reaction of the antitumor antibiotic CC-1065 with DNA: structure of a DNA adduct with DNA sequence specificity.

Sequence-dependent variations in DNA revealed by x-ray crystallographic studies have suggested that certain DNA-reactive drugs may react preferentially with defined sequences in DNA. Drugs that wind around the helix and reside within one of the grooves of DNA have perhaps the greatest chance of recognizing sequence-dependent features of DNA. The antitumor antibiotic CC-1065 covalently binds through N-3 of adenine and resides within the minor groove of DNA. This drug overlaps with five base pairs for which a high sequence specificity exists.

Protection against anthramycin-induced toxicity in mice by coenzyme Q10.

Pretreatment of Swiss Webster mice with coenzyme Q10 (CoQ) markedly reduced the lethality of the antitumor antibiotic anthramycin as well as its ability to decrease ventricular weights. In tumor-bearing mice CoQ pretreatment did not produce any consistent alteration of radioactivity levels in blood, heart, tumor, lungs, kidneys, liver, muscles, brain, or spleen after [15-3H]anthramycin administration. Gross alterations in anthramycin distribution is probably not the mechanism by which CoQ alters the cardiotoxicity and lethality of anthramycin.

Mutagenic and recombinogenic effects of the antitumor antibiotic anthramycin.

Anthramycin, one of the pyrrolo(1,4)benzodiazepine antibiotics with potent antitumor activity, was tested for its effects on a number of genetic parameters. The results show that this antibiotic is nonmutagenic in the Ames strains of Salmonella typhimurium while mutagenic in only one and antimutagenic in the rest of the genes tested in the eukaryotic organism Saccharomyces cerevisiae. The antibiotic is, however, a potent recombinogen inasmuch as it induced mitotic crossing over, mitotic gene conversion, and possibly other chromosomal alterations in a diploid strain of S. cerevisiae. These studies emphasize the need for a battery of test systems including eukaryotic organisms to detect the genetic activity of certain antitumor drugs. The importance of considering data distinguishing between highly mutagenic and poorly mutagenic cancer chemotherapeutic agents is also discussed.

Mechanism of interaction of CC-1065 (NSC 298223) with DNA.

CC-1065 (NSC 298223), a potent new antitumor antibiotic produced by Streptomyces zelensis, interacts strongly with double-stranded DNA and appears to exert its cytotoxic effects through disruption of DNA synthesis. We undertook this study to elucidate the sites and mechanisms of CC-1065 interaction with DNA. The binding of CC-1065 to synthetic and native DNA was examined by differential circular dichroism or by Sephadex chromatography with photometric detection. The binding of CC-1065 with calf thymus DNA was rapid, being complete within 2 hr, and saturated at 1 drug per 7 to 11 base pairs. The interaction of CC-1065 with synthetic DNA polymers indicated a specificity for adenine- and thymine-rich sites. Agarose gel electrophoresis of CC-1065-treated supercoiled DNA showed that CC-1065 did not intercalate. Site exclusion studies using substitutions in the DNA grooves showed CC-1065 to bind primarily in the minor groove. CC-1065 did not cause DNA breaks; it inhibited susceptibility of DNA to nuclease S1 digestion. It raised the thermal melting temperature of DNA, and it inhibited the ethidium-induced unwinding of DNA. Thus, in contrast to many antitumor agents, CC-1065 stabilized the DNA helix. DNA helix overstabilization may be relevant to the mechanism of action of CC-1065.

Effects of cationic porphyrins as G-quadruplex interactive agents in human tumor cells.

A series of cationic porphyrins has been identified as G-quadruplex interactive agents (QIAs) that stabilize telomeric G-quadruplex DNA and thereby inhibit human telomerase; 50% inhibition of telomerase activity was achieved in HeLa cell-free extract at porphyrin concentrations in the range < or = 50 microM. Cytotoxicity of the porphyrins in vitro was assessed in normal human cells (fibroblast and breast) and human tumor cells representing models selected for high telomerase activity and short telomeres (breast carcinoma, prostate, and lymphoma). In general, the cytotoxicity (EC50, effective concentration for 50% inhibition of cell proliferation) against normal and tumor cells was > 50 microM. The porphyrins were readily absorbed into tumor cell nuclei in culture. Inhibition of telomerase activity in MCF7 cells by subcytotoxic concentrations of TMPyP4 showed time and concentration dependence at 1-100 microM TMPyP4 over 15 days in culture (10 population doubling times). The inhibition of telomerase activity was paralleled by a cell growth arrest in G2-M. These results suggest that relevant biological effects of porphyrins can be achieved at concentrations that do not have general cytotoxic effects on cells. Moreover, the data support the concept that a rational, structure-based approach is possible to design novel telomere-interactive agents with application to a selective and specific anticancer therapy.

Telomere maintenance mechanisms as a target for drug development.

The shortening of the telomeric DNA sequences at the ends of chromosomes is thought to play a critical role in regulating the lifespan of human cells. Since all dividing cells are subject to the loss of telomeric sequences, cells with long proliferative lifespans need mechanisms to maintain telomere integrity. It appears that the activation of the enzyme telomerase is the major mechanism by which these cells maintain their telomeres. The proposal that a critical step in the process of the malignant transformation of cells is the upregulation of expression of telomerase has made this enzyme a potentially useful prognostic and diagnostic marker for cancer, as well as a new target for therapeutic intervention for the treatment of patients with cancer. It is now clear that simply inhibiting telomerase may not result in the anticancer effects that were originally hypothesized. While telomerase may not be the universal target for cancer therapy, we certainly believe that targeting the telomere maintenance mechanisms will be important in future research aimed toward a successful strategy for curing cancer.

Pyrrolo(1,4)benzodiazepine antitumor antibiotics. In vitro interaction of anthramycin, sibiromycin and tomaymycin with DNA using specifically radiolabelled molecules.

Anthramycin, tomaymycin and sibiromycin are pyrrolo(1,4)benzodiazepine antitumor antibiotics. These compounds react with DNA and other guanine-containing polydeoxynucleotides to form covalently bound antibiotic - polydeoxynucleotide complexes. Experiments utilizing radiolabelled antibiotics have led to the following conclusions: 1. Sibiromycin reacts much faster than either anthramycin or tomaymycin with DNA. 2. At saturation binding the final antibiotic to base ratios for sibiromycin, anthramycin and tomaymycin are 1 : 8.8,1: 12.9, and 1 : 18.2, respectively. 3. No reaction with RNA or protein occurs with the pyrrolo(1,4)benzodiazepine antibiotics. 4. Sibiromycin effectively competes for the same DNA binding sites as anthramycin and tomaymycin; however, there is only partial overlap for the same binding sites between anthramycin and tomaymycin. 5. Whereas all three pyrrolo(1,4)benzodiazepine antibiotic-DNA complexes are relatively stable to alkaline conditions, their stability under acidic conditions increases in the order tomaymycin, anthramycin and sibiromycin. 6. No loss of non-exchangeable hydrogens in either the pyrrol ring or the side chains of these antibiotics occurs upon formation of their complexes with DNA. 7. Unchanged antibiotic has been demonstrated to be released upon acid treatment of the anthramycin-DNA and tomaymycin-DNA complexes. 8. A Schiff base linkage between the antibiotics and DNA has been eliminated. The comparative reactivity of the three antibiotics towards DNA and the stability of their DNA complexes is discussed in relation to their structures. A working hypothesis for the formation of the antibiotic-DNA covalent complexes is proposed based upon the available information.

G-quadruplex DNA: a potential target for anti-cancer drug design.

In addition to the familiar duplex DNA, certain DNA sequences can fold into secondary structures that are four-stranded; because they are made up of guanine (G) bases, such structures are called G-quadruplexes. Considerable circumstantial evidence suggests that these structures can exist in vivo in specific regions of the genome including the telomeric ends of chromosomes and oncogene regulatory regions. Recent studies have demonstrated that small molecules can facilitate the formation of, and stabilize, G-quadruplexes. The possible role of G-quadruplex-interactive compounds as pharmacologically important molecules is explored in this article.

G-quadruplexes as targets for drug design.

G-quadruplexes are a family of secondary DNA structures formed in the presence of monovalent cations that consist of four-stranded structures in which Hoogsteen base-pairing stabilizes G-tetrad structures. These structures are proposed to exist in vivo, although direct confirmatory evidence is lacking. Guanine-rich regions of DNA capable of forming G-quadruplex structures are found in a variety of chromosomal regions, including telomeres and promoter regions of DNA. In this review, we describe the design of three separate groups of G-quadruplex-interactive compounds and their interaction with G-quadruplex DNA. Using the first group of compounds (anthraquinones), we describe experiments that provide the proof of concept that a G-quadruplex is required for inhibition of telomerase. Using the second group of compounds (perylenes), we describe the structure of a G-quadruplex-ligand complex and its effect on the dynamics of formation and enzymatic unwinding of the quadruplex. For the third group of compounds (porphyrins), we describe the experiments that relate the biological effects to their interactions with G-quadruplexes.

Solution conformation of a bizelesin A-tract duplex adduct: DNA-DNA cross-linking of an A-tract straightens out bent DNA.

The DNA cross-linker bizelesin has been previously shown to form interhelical interstrand cross-links with adenine residues six base-pairs apart (including the modified adenine residues). Sequence specificity studies have shown that the ligand has a high affinity for the intrinsically bent A-tract sequence [d(CGTTTTTACG):d(CGTAAAAACG)]. However, gel retardation studies have shown that the cross-linked duplex retains none of the characteristic A-tract bending observed within the unmodified duplex. Two-dimensional 1H-NMR experiments have not only confirmed the sites of cross-linking into the duplex, but have also shown the loss of inherent A-tract characteristics, including reduced crosspeak intensities between the H2s of the central adenine residues and the cross-strand H1' of the base one base removed to the 3' side. This observation suggests loss of propeller twisting within these central adenine residues and provides insight into the controversial origin of A-tract bending. This study is important because it validates the use of bizelesin as a probe for determining the importance of A-tract-induced bending in transcriptional and replicational elements.

Repair of helix-stabilizing anthramycin-N2 guanine DNA adducts by UVRA and UVRB proteins.

The transfectivity of anthramycin (Atm)-modified phi X174 replicative form (RF) DNA in Escherichia coli is lower in uvrA and uvrB mutant cells but much higher in uvrC mutant cells compared to wild-type cells. Pretreatment of the Atm-modified phage DNA with purified UVRA and UVRB significantly increases the transfectivity of the DNA in uvrA or uvrB mutant cells. This pretreatment greatly reduces the UVRABC nuclease-sensitive sites (UNSS) and Atm-induced absorbance at 343 nm in the Atm-modified DNA without producing apurinic sites. The reduction of UNSS is proportional to the concentrations of UVRA and UVRB and the enzyme-DNA incubation time and requires ATP. We conclude that there are two different mechanisms for repairing Atm-N2 guanine adducts by UVR proteins: (1) UVRA and UVRB bind to the Atm-N2 guanine double-stranded DNA region and consequently release the Atm from the adducted guanine; (2) UVRABC makes an incision at both sides of the Atm-DNA adduct. The latter mechanism produces potentially lethal double-strand DNA breaks in Atm-modified phi X174 RF DNA in vitro.

TBP binding to the TATA box induces a specific downstream unwinding site that is targeted by pluramycin.

BACKGROUND: The TATA-binding protein (TBP) is one of the major components of the human TFIID multiprotein complex. It is important in directing the initiation of RNA transcription at a site immediately downstream of the TATA sequence (TATA box) found in many eukaryotic promoters. The crystal structure of TBP complexed with an oligonucleotide containing the TATA box revealed a protein with an approximate two-fold symmetry which apparently has symmetrical interactions with DNA. It is not known how an asymmetric effect involving downstream activation can be produced by an apparent symmetric complex. We set out to examine the state of DNA in the TBP-DNA complex using pluramycin, a small molecular weight probe of DNA accessibility. RESULTS: Binding of TBP to the TATA box facilitates intercalation of pluramycin at a defined site immediately downstream of the TATA sequence through an apparent transient unwinding of the DNA. Pluramycin adducts are detected by the production of DNA strand breakage products upon heating. Incubation of pluramycin with the TBP-DNA complex facilitates the trapping of the specific complex by intercalation. Gel mobility shift and circularization assays reveal that the binding of pluramycin on the 3'-side of the TATA box region considerably stabilizes the TBP-DNA complex. CONCLUSIONS: We propose that the TBP-DNA-pluramycin ternary complex is a 'specific' binding mode in which TBP and pluramycin make compensatory alterations in DNA, accounting for the improved stability of the ternary complex. We also propose a model of the ternary complex that explains the observed asymmetric effect of TBP binding to the TATA box.

The inefficiency of incisions of ecteinascidin 743-DNA adducts by the UvrABC nuclease and the unique structural feature of the DNA adducts can be used to explain the repair-dependent toxicities of this antitumor agent.

BACKGROUND: Ecteinascidin 743 (Et 743), a natural product derived from a marine tunicate, is a potent antitumor agent presently in phase II clinical trials. Et 743 binds in the minor groove of DNA and alkylates N2 of guanine via a unique mechanism involving catalytic activation. The sequence selectivity of Et 743 is governed by different patterns of hydrogen-bonding to DNA, which results in differential reversibility of the covalent adducts. As determined by nuclear magnetic resonance spectroscopy, the preferred sequences 5'-PuGC and 5'-PyGG are stabilized by a hydrogen-bonding network, while the non-preferred sequences 5'-NG(A/T) are much less stabilized due to the lack of a key hydrogen bond to the GC base pair on the 3'-side of the alkylated guanine. RESULTS: Mammalian cell lines (XPB, XPD, XPF, XPG, and ERCC1) deficient in the nucleotide excision repair (NER) gene products show resistance to Et 743. The recognition and subsequent incision of Et 743-DNA adducts by the bacterial multisubunit endonuclease UvrABC were used to evaluate DNA repair-mediated toxicity as a rationale for the resistance of NER-defective cell lines and the antitumor activity of Et 743. The Et 743-DNA adducts are indeed recognized and incised by the UvrABC repair proteins; however, the pattern of incision indicated that the non-preferred, and less stable, sequences (i.e. 5'-NG(A/T)) modified with Et 743 are generally incised at a much higher efficiency than the preferred, more stable sequences (i.e. 5'-PuGC or 5'-PyGG). In addition, within the same Et 743 recognition sequence, the level of incision varies, indicating that flanking regions also contribute to the differential incision frequency. CONCLUSIONS: The inefficient repair incision by the UvrABC nuclease of Et 743-DNA adducts provides a basis for rationalizing the observed repair-dependent cytotoxicities of these DNA adducts, if other associated structural properties of Et 743-DNA adducts are taken into account. In particular, the wedge-shaped Et 743, which forces open the minor groove of DNA, introducing a major groove bend, and the extrahelical protrusion of the C-subunit of Et 743 provide unique characteristics alongside the hydrogen-bonding stabilization of a covalent DNA adduct, which we propose traps an intermediate in NER processing of Et 743-DNA adducts. This trapped intermediate protein-Et 743-DNA adduct complex can be considered analogous to a poisoned topoisomerase I- or topoisomerase II-DNA complex. In the absence of an intact NER nuclease complex, this toxic lesion is unable to form, and the Et 743-DNA adducts, although not repaired by the NER pathway, are less toxic to cells. Conversely, elevated levels of either of these nucleases should lead to enhanced Et 743 toxicity.

Design and synthesis of fluoroquinophenoxazines that interact with human telomeric G-quadruplexes and their biological effects.

In this study we have identified a new structural motif for a ligand with G-quadruplex interaction that results in biological effects associated with G-quadruplex-interactive compounds. Fluoroquinolones have been reported to possess weak telomerase inhibitory activity in addition to their better known bacterial gyrase poisoning. Starting with a fluoroquinobenzoxazine, which has modest potency in a human topoisomerase II assay, we have designed a more potent inhibitor of telomerase that has lost its topoisomerase II poisoning activity. This fluoroquinophenoxazine (FQP) interacts with G-quadruplex structures to inhibit the progression of Taq polymerase in a G-quadruplex polymerase stop assay. In addition, we demonstrate by 1H NMR studies that this compound interacts with telomeric G-quadruplex structures by external stacking to the G-tetrad with both the unimolecular fold-over and the parallel G-quadruplex structures. A photocleavage assay confirms the FQP interaction site, which is located off center of the external tetrad but within the loop region. Molecular modeling using simulated annealing was performed on the FQP-parallel G-quadruplex complex to determine the optimum FQP orientation and key molecular interactions with the telomeric G-quadruplex structure. On the basis of the results of these studies, two additional FQP analogues were synthesized, which were designed to test the importance of these key interactions. These analogues were evaluated in the Taq polymerase stop assay for G-quadruplex interaction. The data from this study and the biological evaluation of these three FQPs, using cytotoxicity and a sea urchin embryo system, were in accord with the predicted more potent telomeric G-quadruplex interactions of the initial lead compound and one of the analogues. On the basis of these structural and biological studies, the design of more potent and selective telomeric G-quadruplex-interactive compounds can be envisaged.

Binding of Sp1 to the 21-bp repeat region of SV40 DNA: effect of intrinsic and drug-induced DNA bending between GC boxes.

The effect of the antitumor antibiotic (+)-CC-1065 on the binding of Sp1 to the 21-bp repeats of SV40 DNA has been investigated. (+)-CC-1065 alkylates N3 of adenine in DNA and resides in the minor groove. As a consequence of alkylation of the two 5'-AGTTA* sequences (* indicates covalent modification site), which reside between GC boxes III and IV, and boxes V and VI, protein binding to the 3' sites is completely abolished and there is a significant decrease in Sp1 binding to the other regions. The effect of substituting A5 tracts for the (+)-CC-1065-bonding sequence was intermediate between the unmodified 5'-AGTTA* and the drug-modified sequences. It is proposed that a structural distortion of DNA associated with stiffening of the helix induced by the drug-adduct formation is primarily responsible for the inhibition of binding of Sp1 molecules to 21-bp repeats, rather than steric hindrance due to the occupancy by drug molecules of the minor groove within that region.

Structure-activity relationships of (+)-CC-1065 analogues in the inhibition of helicase-catalyzed unwinding of duplex DNA.

(+)-CC-1065 is a potent antitumor antibiotic produced by Streptomyces zelensis. Previous studies have shown that the potent cytotoxic and antitumor activities of (+)-CC-1065 are due to the ability of this compound to covalently modify DNA. (+)-CC-1065 reacts with duplex DNA to form a (N3-adenine)-DNA adduct which lies in the minor groove of DNA overlapping with a five base-pair region. As a consequence of covalent modification with (+)-CC-1065, the helix bends into the minor groove and also undergoes winding and stiffening. In the studies described here, we have constructed templates for helicase-catalyzed unwinding of DNA that contain site-directed (+)-CC-1065 and analogue DNA adducts. Using these templates we have shown that (+)-CC-1065 and select synthetic analogues, which have different levels of cytotoxicity, all produce a significant inhibition of unwinding of a 3'-tailed oligomer duplex by helicase II when the displaced strand is covalently modified. However, the extent of helicase II inhibition is much more significant for (+)-CC-1065 and an analogue which also produced DNA winding when the winding effects are transmitted in the opposite direction to the helicase unwinding activity. This observed pattern of inhibition of helicase-catalyzed unwinding of drug-modified templates was the same for a 3'-T-tail, for different duplex region sequences, and with the Escherichia coli rep protein. Unexpectedly, the gel mobility of the displaced drug-modified single strand was dependent on the species of drug attached to the DNA. Last, strand displacement by helicase II coupled to primer extension by E. coli DNA polymerase I showed the same pattern of inhibition when the lagging strand was covalently modified. In addition, the presence of helicase II on single-stranded regions of templates caused the premature termination of primer extension by DNA polymerase. These results are discussed from the perspective that (+)-CC-1065 and its analogues have different effects on DNA structure, and these resulting structural changes in DNA molecules are related to the different in vivo biological consequences caused by these drug molecules.

Ecteinascidin 743: a minor groove alkylator that bends DNA toward the major groove.

The ecteinascidins (Ets), which are natural products derived from marine tunicates, exhibit potent antitumor activity. Of the numerous Ets isolated, Et 743 is presently being evaluated in phase II clinical trials. Et 743 binds in the minor groove of DNA and alkylates N2 of guanine. Although structurally similar to saframycin, which exhibits poor activity in cellular assays, Et 743 has shown good efficacy as an antitumor agent. In this study, DNA structural distortions induced by Et 743 were examined to provide insight into the molecular basis for the antitumor activity of Et 743. Electrophoretic mobility shifts of ligated oligomers containing site-directed adducts were used to examine the extent and direction of the Et 743-induced bend. Surprisingly, we find that Et 743 bends DNA toward the major groove, which is a unique feature among DNA-interactive agents that occupy the minor groove.

Template-directed design of a DNA-DNA cross-linker based upon a bis-tomaymycin-duplex adduct.

A template-directed approach to the design of a DNA-DNA interstrand cross-linker based upon the structure of a bis-tomaymycin-duplex adduct has been carried out. Tomaymycin is a member of the pyrrolo[1,4]benzodiazepines antitumor antibiotics. In a previous study (F.L. Boyd et al., Biochemistry 1990, 29, 2387-2403), we have shown that two tomaymycin molecules can be covalently bound to a 12-mer duplex molecule, where the drug molecules are on opposite strands six base-pairs apart, and the stereochemistry at the drug bonding site, and orientation in the minor groove, was defined by high-field NMR. This bis-tomaymycin 12-mer duplex adduct maintains the self-complementarity of the duplex and a B-type structure. In the present study we have shown using high-field NMR that this same 12-mer sequence can be truncated by two base pairs so that the two tomaymycin-modified guanines are now only four base-pairs apart, the two species of tomaymycin molecules are still bound with the same stereochemistry and orientation, and the 10-mer duplex adduct maintains its self-complementarity. In a second 10-mer duplex we have shown that changing the bonding sequence from 5'CGA to 5'AGC does not significantly affect the structure of the bis-tomaymycin-duplex adduct. However, when the sequence is rearranged so that the drugs point in a tail-to-tail orientation rather than in the previous head-to-head configuration, there are more than one species of tomaymycin bound to DNA, and, as a consequence, the bis-tomaymycin 10-mer duplex adduct loses its self-complementarity. Last, we have used the 10-mer duplex containing the 5'CGA sequence, in which the tomaymycin molecules are oriented head to head, to design an interstrand cross-linking species in which the two drug molecules are linked together with a flexible linker molecule.

Quadruplex-interactive agents as telomerase inhibitors: synthesis of porphyrins and structure-activity relationship for the inhibition of telomerase.

The cationic porphyrin 5,10,15,20-tetra-(N-methyl-4-pyridyl)porphyrin (TMPyP4) binds to quadruplex DNA and is thereby an inhibitor of human telomerase (Wheelhouse et al. J. Am. Chem. Soc. 1998, 120, 3261-3262). Herein the synthesis and telomerase-inhibiting activity of a wide range of analogues of TMPyP4 are reported, from which rules for a structure-activity relationship (SAR) have been discerned: (1) stacking interactions are critical for telomerase inhibition, (2) positively charged substituents are important but may be interchanged and combined with hydrogen-bonding groups, and (3) substitution is tolerated only on the meso positions of the porphyrin ring, and the bulk of the substituents should be matched to the width of the grooves in which they putatively lie. This SAR is consistent with a model presented for the complexation of TMPyP4 with human telomeric quadruplex DNA.