Effects of 1,2-naphthoquinones on human tumor cell growth and lack of cross-resistance with other anticancer agents.

The sensitivity of human tumor and rat prostate tumor cells to a series of naphthoquinones, including tricyclic compounds of the beta-lapachone and dunnione families as well as 4-alkoxy-1,2-naphthoquinones, was evaluated. To better understand the mechanism of cytotoxicity of 1,2-naphthoquinones, the roles of various resistance mechanisms including P-glycoprotein, multidrug resistant associated protein, glutathione (GSH) and related enzymes, altered topoisomerase activity, and overexpression of genes that control apoptosis (bcl-2 and bc-xL) were studied. MCF7 cells were most sensitive to the naphthoquinones with IC50 values ranging from 1.1 to 10.8 microM, as compared to 2.5 to >32 microM for HT29 human colon, A549 human lung, CEM leukemia and AT3.1 rat prostate cancer cells. MCF7 ADR cells, selected for resistance to adriamycin (ADR), displayed cross-resistance to the tricyclic 1,2-naphthoquinones. Drug efflux via a P-glycoprotein mechanism was ruled out as a mechanism of resistance to 1,2-naphthoquinones, since KB-V1 cells expressing high levels of P-glycoprotein and the KB-3.1 parent line were equally sensitive to these compounds. Any resistance of the tricyclic naphthoquinones noted in ADR-resistant cells appeared to relate to the GSH redox cycle and could be circumvented by exposure to buthionine sulfoximine or by changing the structure from a tricyclic derivative to a 4-alkoxy-1,2-naphthoquinone. The 1,2-naphthoquinones were found to be cytotoxic against CEM/VM-1 and CEM/M70-B1 cells that were selected for resistance to teniposide or merbarone, respectively. In addition, cells overexpressing bcl-2 or bcl-xL proteins were as sensitive to 1,2-naphthoquinones as were control cells. Because of their effectiveness in drug-resistant cells, these agents appear to hold promise as effective chemotherapeutic agents.

O6-alkylguanine-DNA alkyltransferase inactivation by ester prodrugs of O6-benzylguanine derivatives and their rate of hydrolysis by cellular esterases.

To modulate the bioavailability and perhaps improve the tumor cell selectivity of O6-alkylguanine-DNA alkyltransferase (AGT) inactivators, pivaloyloxymethyl ester derivatives of O6-benzylguanine (BG) were synthesized and tested as AGT inactivators and as substrates for cellular esterases. The potential prodrugs examined were the 7- and 9-pivaloyloxymethyl derivatives of O6-benzylguanine (7- and 9-esterBG), and of 8-aza-O6-benzylguanine (8-aza-7-esterBG and 8-aza-9-esterBG) and the 9-pivaloyloxymethyl derivative of 8-bromo-O6-benzylguanine (8-bromo-9-esterBG). The benzylated purines were all potent inactivators of the pure AGT and of the AGT activity in HT29 cells and cell extracts. Each ester was at least 75 times less potent than the corresponding benzylated purine against the pure human AGT. In contrast, the activities of esters and their respective benzylated purine were similar in crude cell extracts and in intact cells. The increase in potency of esters in cellular extracts could be explained by a conversion of the respective prodrug to the more potent benzylated purine in the presence of cellular esterases. The apparent catalytic activity (Vmax/Km) of liver microsomal esterase for 8-azaBG ester prodrugs was 70-130 times greater than for BG prodrugs and 10-20 times greater than for 8-bromo-9-esterBG. Tumor cell hydrolysis of the esters varied considerably as a function of cell type and prodrug structure. These data suggest that these or related prodrugs may be advantageous for selective AGT inactivation in certain tumor types.

Sequence specificity of alkylation for a series of nitrogen mustard-containing analogues of distamycin of increasing binding site size: evidence for increased cytotoxicity with enhanced sequence specificity.

The covalent sequence specificity of a series of nitrogen mustard-containing analogues of distamycin was determined using modified sequencing techniques. The analogues tether benzoic acid mustard (BAM) and possess either one, two, or three pyrrole-amide units. Previous characterization of the biological profile of the series revealed an increase in cytotoxicity for each corresponding increase in the number of pyrrole units, while showing poor cross-link formation in isolated and cellular DNA. Examination of the sequence specificity revealed that BAM produced guanine-N7 lesions in similar manner to other conventional nitrogen mustards. The monopyrrole BAM conjugate also produced guanine-N7 alkylation in a similar pattern to BAM. However, alkylation of adenines was also seen that was found to be minor groove adenine-N3 lesions. The dipyrrole and tripyrrole conjugates did not produce detectable guanine-N7 alkylation but only alkylated in AT tracts. In addition, the tripyrrole conjugate preferentially alkylated only a subset of those sites alkylated by the monopyrrole and dipyrrole conjugates. Two sites, 5'-TTTTGG and 5'-TTTTGA, confirmed as guanine-N3 and adenine-N3 lesions, respectively, were strongly alkylated by the tripyrrole conjugate in preference to other similar sites including three occurrences of 5'-TTTTAA. Footprinting studies comparing distamycin and the tripyrrole conjugate showed identical non-covalent recognition of AT-rich sites. Hence, the drug that possessed the most enhanced sequence specificity for alkylation was also the most cytotoxic of this series.

Structure-activity relationship of a series of nitrogen mustard- and pyrrole-containing minor groove-binding agents related to distamycin.

Two series of tethered nitrogen mustards based on the minor groove-binding and A/T sequence-specific natural product distamycin have been synthesized and evaluated. The conjugates, which have a modified dimethylamino C-terminus, are comprised of one, two or three pyrrole carboxamide units linked to either benzoic acid mustard (BAM) or chlorambucil (CHL). The DNA binding properties, in vitro cytotoxicities and DNA cross-linking abilities were determined for each of the conjugates. The conjugates were found to bind preferentially to poly(dA.dT) compared to poly(dG.dC) DNA by ethidium displacement and circular dichroism. The di- and tripyrrole conjugates had higher binding affinities than the monopyrrole conjugates. All the conjugates were more cytotoxic than the nitrogen mustards themselves. Cytotoxicity increased with the increase from one to three pyrrole units and the CHL conjugates were more cytotoxic than the corresponding BAM analogues. The CHL conjugates were able to cross-link plasmid DNA at a 10-fold lower dose than CHL itself. The BAM conjugates showed < 10% cross-linking at doses which gave 100% cross-linking with the CHL conjugates. In cells, the CHL conjugates showed significant cross-linking at the IC50 values, while the BAM conjugates showed no evidence of cross-link formation even at 10 times the IC50 value. These results are discussed in reference to a series of previously reported GC-recognizing imidazole analogues possessing the same nitrogen mustard groups.