Loretta S. Gawron

Netropsin and bis-netropsin analogs as inhibitors of the catalytic activity of mammalian DNA topoisomerase II and topoisomerase cleavable complexes

This study examined the ability of netropsin and related minor groove binders to interfere with the actions of DNA topoisomerases II and I. We evaluated a series of netropsin dimers linked with flexible aliphatic chains of different lengths. These agents are potentially able to occupy longer stretches of DNA than the parental drug as a result of bidentate binding. Both netropsin and its dimers were found: (i) to inhibit the catalytic activity of isolated topoisomerase II and (ii) to interfere with the stabilization of the cleavable complexes of topoisomerase II and I in nuclei. Dimers with linkers consisting of 0-4 and 6-9 methylene groups (n) were far more inhibitory than netropsin against isolated enzyme and in the nuclear system. The compound with n = 5 was less active than netropsin in both assays while the dimer with n = 10 inhibited only the isolated enzyme. The comparison of dimers with fixed linker length (n = 2) but varying number of N-methylpyrrole residues (from 1 to 3) revealed that the inhibitory properties were enhanced with increasing number of N-methylpyrrole units. For dimers with varying linker length, drug ability to inhibit catalytic activity of isolated topoisomerase II was positively correlated with calf thymus DNA association constants. In contrast, no such correlation existed in nuclei. However, the inhibitory effects in the nuclear system were correlated with the association constants for poly(dAdT). The results indicate that bidentate binding can significantly enhance anti-topoisomerase activity of netropsin related dimeric minor groove binders. However, other factors such as the length of the linker, the number of pyrrole moieties and the nature of the target (isolated enzyme/DNA versus chromatin in nuclei) also contribute to these activities.

C-1027, A Radiomimetic Enediyne Anticancer Drug, Preferentially Targets Hypoxic Cells

The hypoxic nature of cells within solid tumors limits the efficacy of anticancer therapies such as ionizing radiation and conventional radiomimetics because their mechanisms require oxygen to induce lethal DNA breaks. For example, the conventional radiomimetic enediyne neocarzinostatin is 4-fold less cytotoxic to cells maintained in low oxygen (hypoxic) compared with normoxic conditions. By contrast, the enediyne C-1027 was nearly 3-fold more cytotoxic to hypoxic than to normoxic cells. Like other radiomimetics, C-1027 induced DNA breaks to a lesser extent in cell-free, or cellular hypoxic, compared with normoxic environments. However, the unique DNA interstrand cross-linking ability of C-1027 was markedly enhanced under the same hypoxic conditions that reduced its DNA break induction. Although the unique chemistry of C-1027 allows it to concurrently generate both DNA breaks and cross-links in normoxic cells, a low oxygen environment represses the former and promotes the latter. Thus, treatment with C-1027 offers a facile approach for overcoming the radioresistance associated with poorly oxygenated cells.

The Antitumor Enediyne C-1027 Alters Cell Cycle Progression and Induces Chromosomal Aberrations and Telomere Dysfunction

This study examined the extent of chromosome instability induced in cultured human colon carcinoma HCT116 cells by the antitumor radiomimetic enediyne antibiotic C-1027. Spectral karyotype analysis showed frequent intrachromosomal fusions and fragmentations 26 hours after addition of as little as 0.035 nmol/L C-1027. When the concentration was increased to 0.14 nmol/L C-1027, 92% of cells showed chromosomal aberrations compared with only 2.9% after treatment with an equivalent growth inhibitory dose of ionizing radiation (20 Gy). Thus, chromosome misrejoining was associated to a much greater extent with C-1027-induced than with ionizing radiation-induced cell growth inhibition. Despite these aberrations, a large fraction of C-1027-treated cells progressed into G1. Comet analysis showed that these extensive chromosomal anomalies were not due to increased induction or reduced repair of C-1027-induced compared with ionizing radiation-induced strand breaks. Fluorescence in situ hybridization analysis showed that misrejoining of telomere repeats (i.e., chromosomes joined end to end at their telomeres or fused together after complete loss of telomere sequences) was observed within 26 hours of C-1027 addition. The extreme cytotoxicity of C-1027 may reflect both induction and erroneous repair of DNA double-strand break in the whole genome and/or in subgenomic targets such as telomere sequences.

Kinetics of Cleavage of Intra- and Extracellular Simian Virus 40 DNA with the Enediyne Anticancer Drug C- 1027

A kinetic analysis of cleavage of simian virus DNA (SV40 DNA) inside and outside green monkey BSC-1 cells by the enediyne-protein antibiotic C-1027 and its free chromophore is described. Information on rate constants was obtained by fitting populations of forms I (closed circular DNA), II (nicked circular DNA) and III (linear DNA) SV40 DNA as a function of drug concentration to a kinetic model which includes: cutting of form I to give form II with rate constant k1, cutting of form I to give form III with rate constant K4, and cutting of form II to give form III with rate constant k2. The ratio of single-strand (ss) to double-strand (ds) cutting for the holoantibiotic and the free chromophore, k1/k4, is approximately 1.8 for extracellular SV40 DNA. For intracellular DNA and extracellular DNA which has been post-treated with putrescine, ds cutting is much more probable, with k4 about four times as large as k1. This observation suggests that amine groups present in the cell are able to convert abasic sites opposite an ss break into a ds break in SV40 chromatin. The overall rate of cleavage of form-I DNA inside the cell is much larger than the rate outside, the sum k1 + k4 being about three times as large for intracellular DNA as for extracellular DNA.

Inhibiting transcription factor/DNA complexes using fluorescent microgonotropens (FMGTs).

Fluorescent microgonotropens (FMGTs) are A/T selective, minor groove-binding bisbenzimidazole ligands. Basic side chains extending from these agents electrostatically contact the major groove side of the phosphodiester backbone of DNA, endowing them with high binding affinity. Here, we evaluate the potential of these agents as inhibitors of transcription factor (TF) binding to DNA and explore whether their ability to contact both grooves enhances their inhibitory activity. A series of FMGTs (L2-L5), with polyamine tails of varying lengths and degrees of branching, were compared to an analog lacking these basic side chains (L1), and the classical bisbenzimidazole Hoechst 33342 for effects on TF complex formation on the c-fos serum response element (SRE). Although L1 could not inhibit TF/SRE interactions, L2-L5 did so at submicromolar concentrations. Moreover, the FMGTs were up to 50 times more potent than Hoechst 33342 in inhibiting TF complex formation in electrophoretic mobility shift assays. The FMGTs also inhibited c-fos promoter-driven cell-free transcription and topoisomerase II activity in nuclei. These studies establish the potential of FMGTs as TF/DNA complex inhibitors in cell-free systems, provide insight into the relationship between their structure and biological activities, and demonstrate the benefits of functionalizing minor groove binding-agents with major groove-contacting groups.

Bleomycin-induced aggregation of presolubilized and nuclear chromatin from L1210 cells

These studies have identified a new activity of bleomycin (in addition to the well-known DNA cleavage): drug-induced chromatin aggregation. Bleomycin treatment of presolubilized chromatin from L1210 nuclei resulted in two types of effect as shown by sedimentation analysis of intact nucleoprotein. The first effect was a dose-dependent fragmentation of chromatin to mononucleosomes (12 S) and subnucleosomal fragments (under 5 S). The second effect was aggregation manifested by the generation of large chromatin particles (over 120 S) that sedimented faster than the original material (20-40 S). Bleomycin treatment of nuclei from L1210 cells resulted in a similar, almost bimodal, size distribution of drug-released chromatin fragments. Increasing levels of bleomycin produced a gradual enhancement of the amount of small fragments (under 5 S) accompanied by generation of large, aggregated particles. Aggregation caused by high drug concentrations significantly reduced the overall extent of chromatin solubilization and allowed only the release of the most degraded fragments from nuclei. The aggregation required intact nucleoprotein, since it was not detected after high-salt deproteinization of bleomycin-treated presolubilized or nuclear chromatin. The aggregation phenomenon reflects a novel activity of bleomycin which may contribute to the drugs antiproliferative properties.