Benzo[f]azino[2,1-a]phthalazinium cations: novel DNA intercalating chromophores with antiproliferative activity.

New azaquinolizinium-type cations have been obtained from isochromane. The synthesis was completed over seven steps and included as the key feature an intramolecular Westphal condensation. This first example of the intramolecular process allowed the preparation of benzo[f]pyrido[2,1-a]phthalazinium and benzo[f]quino[2,1-a]phthalazinium salts, which were evaluated as DNA intercalators, DNA topoisomerase I inhibitors, and antiproliferative compounds. Both cationic systems behave as DNA intercalators and exhibit antiproliferative activity. The pentacyclic benzo[f]quino[2,1-a]phthalazinium cations also have an inhibitory effect on the catalytic activity of DNA topoisomerase I, without trapping of cleavage complexes. Structural characterization using density functional theory indicates that the fused ring systems are slightly nonplanar, and additional molecular modeling studies suggest a preferred orientation for the intercalating chromophores within a typical CpG or TpG intercalation site.

Assessment by molecular dynamics simulations of the structural determinants of DNA-binding specificity for transcription factor Sp1.

The DNA-binding domain (DBD) of the ubiquituous transcription factor Sp1 consists of three consecutive zinc fingers that recognize a number of nucleotide sequences different from, but related to and sometimes overlapping, those recognized by the structurally better characterized early growth response protein 1 (EGR1, also known as Zif268, Krox-24, and NGFI-A). The accepted consensus binding sequence for Sp1 is usually defined by the asymmetric hexanucleotide core GGGCGG but this sequence does not include, among others, the GAG (=CTC) repeat that constitutes a high-affinity site for Sp1 binding to the wt1 promoter. Since no 3D structure of the whole DBD of Sp1 is available, either alone or in complex with DNA, a homology-based model was built and its interaction with two DNA 14-mers was studied using nanosecond molecular dynamics simulations in the presence of explicit water molecules. These oligonucleotides represent Sp1 target sites that are present in the promoters of the mdr1 and wt1 genes. For comparative purposes and validation of the protocol, the complex between the DBD of EGR1 and its DNA target site within the proximal mdr1 promoter was simulated under the same conditions. Some water molecules were seen to play an important role in recognition and stabilization of the protein-DNA complexes. Our results, which are supported by the available experimental evidence, suggest that the accuracy in the prediction of putative Sp1-binding sites can be improved by interpreting a set of rules, which are a blend of both stringency and tolerance, for the juxtaposed triplet subsites to which each zinc finger binds. Our approach can be extrapolated to WT1 and other related natural or artificial zinc-finger-containing DNA-binding proteins and may aid in the assignment of particular DNA stretches as allowed or disallowed-binding sites.

A 3.(ET743)-DNA complex that both resembles an RNA-DNA hybrid and mimicks zinc finger-induced DNA structural distortions.

The antitumor ecteinascidin ET743 has been shown to inhibit the transcriptional activation of a number of genes at nanomolar concentrations. Cell sensitivity to subnanomolar concentrations of the drug has also been shown to specifically depend on the transcription-coupled nucleotide excision repair system. ET743 is known to bind covalently to the minor groove of a DNA double helix in regions comprising selected sets of three consecutive base pairs. Following alkylation of a central guanine, the minor groove is widened and the DNA is bent toward the major groove. We have previously shown that in the resulting adduct the DNA triplet containing the covalently modified guanine bears a strong resemblance to a DNA triplet recognized by a C(2)H(2) zinc finger. We now expand this earlier finding and use simulation methods to show that head-to-tail binding of three ET743 molecules to three adjacent optimal binding sites stabilizes a DNA structure whose conformation is intermediate between A- and B-form DNA. Furthermore, despite the increase in roll at the sites of covalent attachment, no net curvature is apparent in this complex due to cancellation of the localized bends over virtually one turn of the helix. Both observations are in good analogy to findings in zinc finger-DNA complexes. Triplets are virtually superimposable both directly and upon shifting the register one base pair. In this latter case, the central guanine in a triplet alkylated by ET743 corresponds to the third nucleic base in the triplet recognized by a zinc finger of transcription factors such as EGR1 or Sp-1. The DNA conformation found in the ET743-DNA complex is also strongly reminiscent of an RNA-DNA hybrid, as found in the RNA polymerase II elongation complex. The possible biological implications of these findings in relation to the antitumor action of ET743 are discussed.