Cell cycle effects of the novel topoisomerase I inhibitor NU/ICRF 505 in a panel of Chinese hamster ovary cell lines.

The effect of the novel topoisomerase I inhibitor NU/ICRF 505 (20 microM, approximate IC50 concentration) on the cell cycle was studied by flow cytometry in four Chinese hamster ovary (CHO) cell lines. Postdrug treated cells were incubated with optimal concentrations of cytochalasin B to prevent re-entry of daughter cells into the cell cycle. NU/ICRF 505 had no significant effect on cell cycle distribution in the parent cell line (CHO-K1) and two mutants hypersensitive to topo II inhibitors (ADR-1, ADR-3), all of which express similar levels of topo I protein. In the drug-resistant variant ADR-r, which overexpresses topo I 2-fold, a significant accumulation of cells in G1 phase was recorded. These results are broadly consistent with the cell cycle effects expected in CHO cells by a classic topo I poison (camptothecin) and add weight to the view that NU/ICRF 505 induces cell death primarily through topo I inhibition.

Development of anthracenyl-amino acid conjugates as topoisomerase I and II inhibitors that circumvent drug resistance.

Anthracenyl-amino acid conjugates (AAC) represent a novel class of topoisomerase (topo) inhibitor. The relationship between mechanism of enzyme inhibition and in vitro cytotoxicity has been investigated in a panel of 5 Chinese hamster ovary (CHO) and 2 human ovarian cancer cell lines (A2780) shown to possess different drug resistance phenotypes associated with altered expression of topo I and topo II. From a total of 13 compounds, 4 displayed broad-spectrum activity (IC50 ranging from 3.5-29.7 microM). NU/ICRF 500 (topo II catalytic inhibitor) was 1.4-fold more active against CHO ADR-1, which overexpresses topo II and was essentially noncross-resistant in CHO ADR-r (13.9-fold resistant to doxorubicin (DOX)) and 2780AD (1,460-fold resistant to DOX). NU/ICRF 505, which stabilises topo I cleavable complexes, was noncross-resistant in CHO ADR-3 (3,4-fold resistant to camptothecin) and only 1.8-fold cross-resistant in 2780AD. Hypersensitivity was recorded in ADR-r that overexpresses topo I. The most active compound was NU/ICRF 506, a dual catalytic inhibitor of topo I and II. Hypersensitivity was observed in ADR-r (1.4-fold) but not ADR-1, indicating that topo I is the likely nuclear target, and a low level of resistance was seen in the CHO ADR-6 drug transport mutant and 2780AD. The topo II catalytic inhibitor NU/ICRF 513 only produced hypersensitivity in ADR-r. These data suggest that NU/ICRF 500, 505, and 506 induce cell death, at least partly, through topo inhibition. NU/ICRF 513 appears to be cytotoxic via a nontopo mechanism of action. In addition, NU/ICRF 505 significantly inhibited the growth of two human xenografts (HT-29 colon cancer and NX002 nonsmall-cell lung cancer) in nude mice after i.p. administration at a dose of 25 mg/kg. The important properties of noncross-resistance and in vivo antitumour activity merit further development of AAC as potential new anticancer drugs.

Determination of the novel topoisomerase I inhibitor NU/ICRF 505 and its major metabolite in plasma, tissue and tumour by high-performance liquid chromatography.

A high-performance liquid chromatographic technique is presented for the determination of the novel topoisomerase I inhibitor NU/ICRF 505 (a tyrosine conjugate of anthraquinone), its major metabolite (NU/ICRF 505/M) and an internal standard (NU/ICRF 513, dihydroxyphenylalanine conjugate). The method uses a reversed-phase (Apex ODS-2) stationary phase and a mobile phase consisting of 0.25 M ammonium acetate adjusted to pH 3 with 25% (v/v) trifluoroacetic acid and methanol with gradient elution. Between-day variation in retention times were less than 1% for NU/ICRF 505 and 513 and 2.4% for the metabolite. Selective detection was achieved at a wavelength of 545 nm giving a limit of detection of 2 ng on column and 50 ng/ml after sample preparation for all three components. Chromatograms were free from interfering peaks even at very high detector sensitivity. Sample preparation was based on incubation of biological specimens (0.5 ml plasma or homogenate) with dimethylsulphoxide and acetonitrile at 4 degrees C for 30 min followed by centrifugation. Liver and tumour were homogenised in phosphate buffered saline. Recoveries were consistently high (81.7-106.7% for NU/ICRF 505; 88.7-103.3% for NU/ICRF 513 and 83.7-98.7% for NU/ICRF 505/M) with between day coefficients of variation of normally less than 10%. The method will contribute significantly to the preclinical evaluation of NU/ICRF 505.

Molecular modeling of the interaction of anthracenyl-amino acid topoisomerase inhibitors with the DNA sequence d(CGTACG).

Anthracenyl-amino acid and dipeptide conjugates represent new classes of topoisomerase (topo) inhibitors. To investigate the structural basis for their different selectivity against topo I and II and varying potency, the binding of six compounds to d(CGTACG) was studied by molecular modeling. Modeling data were in good agreement with physical data showing that five compounds intercalated DNA with the anthraquinone chromophore orientated in parallel to the long dimension of the d(CpG) base pairs and the amino acid placed in the minor groove. Differences in binding modes emerged which correlated to different biological properties. The amino acid chain of the topo I inhibitor (NU/ICRF 600, gly-phe) extended significantly out from the helical axis horizontal. The amino acid side chains of two topo II inhibitors (NU/ICRF 510, arginine and NU/ ICRF 512, methionine) were inserted into the minor groove, whereas the C-terminal groups (hydrazide) of two potent topo II inhibitors (NU/ICRF 500 and 506, serine) were placed into the minor groove while the amino acid side chains pointed away from the minor groove. These data provide structural information which may prove valuable in rational design of second generation analogs.

Induction of apoptosis in human cancer cell lines by the novel anthracenyl-amino acid topoisomerase I inhibitor NU/ICRF 505.

Anthracenyl-amino acid conjugates represent a novel chemical class of topoisomerase (topo) inhibitor. NU/ICRF 505 is a lead compound that stabilises topo I cleavable complexes and is actively cytotoxic at low microM concentrations. In this study, endonucleolytic DNA cleavage was used as a marker of apoptosis to investigate mechanisms of cell death produced by this compound. NU/ICRF 505 (5 microM) induced a substantial increase in the level of DNA fragmentation in HL60 cells (up to 30% of total extracted DNA) but only after a 48 and 72 h drug exposure (compared with 6 h after treatment with camptothecin), as determined qualitatively by conventional gel electrophoresis and quantitatively by spectrofluorimetry. This effect was substantially reversed by co-treatment with zinc (1 mM). Subsequent studies with the human lung (NX002), ovarian (A2780) and colon (HT29) cancer cell lines yielded evidence of formation of higher molecular weight DNA fragments in NX002 and A2780 cells in response to NU/ICRF 505 (5 microM). Co-treatment with zinc (1 mM) caused a small decrease in DNA fragmentation. These data suggest that the induction of apoptosis may play an important role in the mechanism of cytotoxicity of NU/ICRF 505 in HL60 cells and that other pathways of cell death may also be operative in NX002 and A2780 in conjunction with apoptosis.

Characterization of the major metabolite of the novel topoisomerase I inhibitor NU/ICRF 505.

NU/ICRF 505 is a tyrosine conjugate of anthraquinone modified at the C terminus of the amino acid as an ethyl ester and it stabilizes topoisomerase I (topo I)-cleavable complexes. It is active in vitro against a panel of human cell lines, including drug-resistant variants, and possesses in vivo antitumour activity. NU/ICRF 505 was rapidly metabolized in nude mice to a product which represented the sole detectable form of the drug present in plasma and a chemosensitive human xenograft (HT-29 colon cancer). The metabolite (codenamed NU/ICRF 505/M) was purified, characterized by mass spectrometry and UV-visible spectroscopy, and shown to be the free amino acid produced by hydrolysis of the ethyl ester bond. NU/ICRF 505/M stabilized topo I-cleavable complexes in assays with human enzyme and was equipotent to the parent drug. Nonetheless, the metabolite was inactive in vitro against a panel of human tumour cell lines (including HT-29) and was not significantly taken up into cells in drug-uptake studies. Levels of the metabolite measured in the HT-29 xenograft after administration of a therapeutic dose of NU/ICRF 505 (25 mg/kg i.p.) remained above 1 microM for 6 h, and exceeded 10 microM at 10 min and 2 h. These data suggest that NU/ICRF 505 is a prodrug in nude mice for its topo-active metabolite NU/ICRF 505/M which accumulates in the tumour.

Identification of anthracenyl-dipeptide conjugates as novel topoisomerase I and II inhibitors and their evaluation as potential anticancer drugs.

As part of an ongoing rational drug design programme aiming to develop monosubstituted anthracenyl-peptides as potential anticancer drugs, three novel dipeptide conjugates have been synthesized and evaluated as inhibitors of topoisomerase (topo) I and II. Each of the three conjugates (designated NU/ICRF 600-602) was shown to inhibit the catalytic activity of both topoisomerase I and II, of which NU/ICRF 602 was the most active [100% inhibition of both enzymes at 5 micrograms/ml (approximately 15 microM) or less]. In a topo I/DNA unwinding assay, none of the compounds bound to DNA, suggesting genuine inhibition of catalytic activity. NU/ICRF 600 stabilized topo I cleavable complexes, although none of the compounds induced topo II-mediated DNA cleavage. Using a panel of Chinese hamster ovary cell lines along with the human ovarian cancer cell line, A2780, none of the three compounds were actively cytotoxic at concentrations < 100 microM. Subsequent drug uptake studies with NU/ICRF 600 and 602, using a method developed to correlate the chemosensitivity of A2780 cells with the uptake of anthracenyl-amino acid conjugates, revealed a lack of cellular uptake for both dipeptide conjugates. The significance of this finding in relation to drug design and the future development of this series of compounds is discussed.

Cytogenetic evaluation of the mechanism of cell death induced by the novel anthracenyl-amino acid topoisomerase II catalytic inhibitor NU/ICRF 500.

Anthracenyl-amino acid/dipeptides are novel topoisomerase (topo) inhibitors which can be actively cytotoxic in the low microM range. The present studies have been performed to determine whether cells treated with the topo II catalytic inhibitor NU/ICRF 500 (serine derivative) would manifest cytogenetic lesions consistent with its proposed mechanism of enzyme inhibition. Three other compounds were included for comparison: NU/ICRF 505 (tyrosine) which stabilises topo I cleavable complexes, NU/ICRF 602 (gly-gly) a non-cytotoxic catalytic inhibitor of topo I and II and NU/ICRF 502 (alanine) a non-cytotoxic non-topo inhibitor. Chromosomal damage was measured using the micronucleus test. NU/ICRF 500 (7.5-30 microM) induced an increase in CREST negative micronuclei (11-15 per 500 cells) in human lymphocytes (HL) and blocked the traverse of HL through the cell cycle, with cells accumulating in G2/M at 15 microM drug and G1/S at 30 microM drug. NU/ICRF 502 was without effect in the micronucleus test. NU/ICRF 500 and 602 (90-150 microM) caused no block in passage of synchronised metaphase Chinese hamster ovary cells through mitosis whereas NU/ICRF 505 produced a significant delay. DNA measurements of post-mitotic cells revealed that after NU/ICRF 500 treatment nuclei had a 4C DNA content, indicative of a lack of chromosomal segregation. Normal (2C) DNA content was observed with NU/ICRF 505 and 602. Overall, the data for NU/ICRF 500 are consistent with the cytogenetic modifications expected after catalytic inhibition of topo II and suggest that cell death may be mediated, at least in part, through this mechanism.

Biochemistry of topoisomerase I and II inhibition by anthracenyl-amino acid conjugates.

Mono-conjugation of an anthraquinone nucleus with a range of naturally occurring amino acids chemically modified at their C-terminus has been adopted as a synthetic approach in the rational design of novel topoisomerase (topo) inhibitors. The biochemistry of topo I and II inhibition has been investigated for a series of 16 new compounds (NU/ICRF 500-515) from which structure-activity relationships have been investigated. Only three compounds could be demonstrated to bind to DNA: two serine derivatives (NU/ICRFs 500 and 506) and an arginine derivative (NU/ICRF 510). In decatenation and relaxation assays with purified enzyme, several compounds were shown to be potent catalytic inhibitors of topo II (100% inhibition at 5 micrograms/mL (10-15 microM) or less) without stabilizing cleavable complex formation. These included the three DNA binding species (of which NU/ICRF 506 was the most active) and a dihydroxyphenylalanine analogue (NU/ICRF 513). Both NU/ICRFs 500 and 506 were further shown to antagonize DNA cleavage induced by amsacrine. Only NU/ICRF 506 unequivocally inhibited the catalytic activity of topo I without induction of DNA cleavage, and was the only combined topo I and II catalytic inhibitor. One compound, NU/ICRF 505 (tyrosine conjugate), stabilized topo I cleavable complexes without inhibiting the catalytic activity of topo I and II. Modifications to the structure of NU/ICRF 505 revealed that the presence of an unhindered hydroxyl on the tyrosine ring and a more hydrophobic ethyl ester at the amino acid C-terminal were both essential, suggesting a highly specific interaction between drug, enzyme and DNA in the ternary complex. Molecular modelling studies suggested that the observed differences in topo inhibition are a consequence of major conformational alterations brought about by small changes in the amino acid substituent, and confirmed a rigid structural requirement for the induction of topo I cleavage, in addition to a less rigid structural requirement for topo II inhibition. A strong correlation was observed between topo inhibition and in vitro cytotoxicity against the human ovarian cancer cell line A2780 (IC50 range 3.4-11.6 microM), suggesting a mechanism of cell kill, at least in part, involving topo inhibition.

Accumulation of anthracenyl-amino acid topoisomerase I and II inhibitors in drug-sensitive and drug-resistant human ovarian cancer cell lines determined by high-performance liquid chromatography.

Anthracenyl amino acid/dipeptide conjugates (AADC) represent novel structures rationally designed for their DNA-binding properties. A high-performance liquid chromatography method is described for simultaneous determination of five compounds that exhibit novel mechanisms of action as topoisomerase I and II inhibitors. The method uses an Apex ODS-2 column and a mobile phase of 0.25 M ammonium acetate/trifluoroacetic acid (pH 3) in methanol with gradient elution. Selective detection is achieved by monitoring at 545 nm, with limits of detection ranging between 2 and 4 ng on the column. AADC are recovered from cell sonicates by solid-phase extraction using C2 cartridges, with extraction efficiencies ranging from 84% to 95%. Drug uptake studies were performed with three active compounds in the human ovarian cancer cell line A2780 and its multi-drug-resistant counterpart 2780AD. Marked differences were observed in the pattern of cellular accumulation produced by each compound. NU/ICRF 505 (tyrosine derivative) was taken up most avidly, reaching plateau levels of 4000 pmol/10(6) cells after 2 h, with no difference being apparent between A2780 and 2780AD. NU/ICRF 510 (arginine derivative) accumulated slowly in A2780, failing to achieve an equilibrium after 4 h, and appeared to be completely excluded from 2780AD. NU/ICRF 500 (serine derivative) was most rapidly taken up by A2780, producing a plateau of 800 pmol/10(6) cells after only 30 min with approximately 3-fold less accumulation in 2780AD. These results are correlated to the chemosensitivity of the two cell lines to the three compounds.

Expression of an abundant alpha-class glutathione S-transferase in bovine and human adrenal cortex tissues.

Bovine adrenal cortex tissue expresses high levels of glutathione S-transferase (GST) from each of the alpha, mu and pi gene families. We describe the purification and characterization of an abundant alpha-class GST from this tissue that has not been identified previously because of its failure to bind to S-hexylglutathione-Sepharose 6B (S-hexG-Ag). This enzyme has been affinity purified on glutathione-Sepharose 6B (GSH-Ag) and was obtained in a highly purified form by employing S-hexG-Ag to remove the bulk of GST before chromatography on GSH-Ag. The purified GST eluted from GSH-Ag was found to exhibit marked peroxidase and delta 5-ketosteroid isomerase activities (19.2 and 1.67 U/mg respectively). The bovine enzyme also showed high GST activity towards 4-hydroxynonenal (5.09 U/mg). Sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis revealed that the bovine GST contains two distinct polypeptides, one with an Mr of 25,900 and the other with an Mr of 26,500. An abundant alpha-class GST was also purified from human adrenal cortex that possessed properties which were similar to the bovine alpha-class GST described above; however, unlike the bovine enzyme, the corresponding human alpha-class GST bound to S-hexG-Ag. As with the bovine enzyme, the purified human GST displayed marked peroxidase and isomerase activities (27 and 4.02 U/mg respectively). Further analysis on SDS-PAGE (Mr 25,800) and reverse-phase high-performance liquid chromatography established that this abundant alpha-class GST in human adrenal cortex is equivalent to the human liver GST B1B1 enzyme. As both human and bovine adrenal cortex contain high levels of alpha-class GST with similar catalytic properties, we discuss the possible functions of these enzymes in this tissue.

Angiotensin II-stimulated cortisol secretion is mediated by a hormone-sensitive phospholipase C in bovine adrenal fasciculata/reticularis cells.

Conditions have been established for the incorporation of [3H]inositol ([3H]Ins) into the phosphoinositides of cultured bovine adrenal zona fasciculata/reticularis (ZFR) cells. Stimulation of these prelabelled cells with angiotensin II (10(-11)-10(-7) M AII) resulted in the dose-dependent (max. 16-fold at 10(-7) M AII), time-dependent formation of water-soluble radiolabelled products which show the same chemical and chromatographic properties as [3H]InsP, [3H]InsP2 and [3H]InsP3 standards. The results of the time-course studies of the changes in these products are consistent with the view that AII rapidly (less than 15 s) induces the activation of a polyphosphoinositide-specific phospholipase C. The action of this phospholipase on the polyphosphoinositides is sustained throughout 15 min of stimulation. The dose dependency of this response correlates closely with cortisol output and is reduced (to 52%, P less than 0.00005), but not abolished, in the absence of extracellular Ca2+. To our knowledge these results are the first clear demonstration that AII stimulates a polyphosphoinositide-specific phospholipase C in bovine ZFR cells.