A unique paclitaxel-mediated modulation of the catalytic activity of topoisomerase IIalpha.

Paclitaxel (Taxol) is known to act by polymerizing and stabilizing microtubules. In spite of a known target, the existence of additional targets is suggested by a poor understanding of the mechanism(s) underlying eventual cell death by paclitaxel and by the drug's high efficacy, as compared to other spindle poisons. Based on the enhanced sensitivity of a mutant DNA double-strand break repair-deficient Chinese hamster ovary cell line to paclitaxel as well as to various topoisomerase (Topo) II poisons, it was hypothesized that paclitaxel, in addition to having an effect on microtubules, may also alter the activity of Topo II. This study demonstrates the unique, in vitro effects of paclitaxel on Topo II activity as investigated by monitoring the decatenation of kinetoplast DNA and relaxation of supercoiled plasmid DNA by Topo II. Unlike classical anti-topoisomerase drugs, low concentrations of paclitaxel (0.02-500 nM) stimulated Topo II catalytic activity, while higher concentrations over 5 microM inhibited the activity of Topo II. Furthermore, these effects of paclitaxel appear to be mediated through a direct interaction of paclitaxel with Topo II rather than an interaction with DNA or DNA-Topo II complexes. Collectively, the evidence presented suggests the existence of an atypical interaction between Topo II and paclitaxel that may disrupt the normal functioning of the enzyme.

Growth inhibitory effect of L-canavanine against MIA PaCa-2 pancreatic cancer cells is not due to conversion to its toxic metabolite canaline.

L-Canavanine (CAV) is an arginine (ARG) analog isolated from the jack bean, Canavalia ensiformis. CAV becomes incorporated into cellular proteins of MIA PaCa-2 human pancreatic cancer cells and the aberrant, canavanyl proteins are not preferentially degraded. Hydrolytic cleavage of CAV to canaline (CAN) and urea is mediated by arginase. CAN is a potent metabolite that inactivates vitamin B6-containing enzymes and may inhibit cell growth. To determine the presence of arginase and its specificity for ARG and CAV in MIA PaCa-2 cells, a radiometric assay, which quantifies the 14C released from the hydrolytic cleavage of L-[guanidino-14C]ARG or L-[guanidinooxy-14C]CAV mediated by arginase, was employed. Insignificant amounts of 14CO2 were released when cells were exposed to [14C]CAV or to [14C]ARG. Pancreatic cancer cells secrete a negligible amount of arginase. Cytotoxic effects of CAN and CAV were compared on cells exposed to varying concentrations of ARG. These studies provide evidence that CAV's cytotoxic effects on MIA PaCa-2 cells cannot be attributed to conversion to the active metabolite CAN. A slower and decreased hydrolysis of CAV by arginase allows CAV to persist and increases its chances of incorporating into proteins in these cells. Lack of considerable amounts of arginase in the pancreas makes CAV a worthy candidate for further studies in pancreatic cancer.

Combination therapy with 5-fluorouracil and L-canavanine: in vitro and in vivo studies.

L-Canavanine (CAV) is a potent L-arginine antagonist, produced by legumes such as the jack bean, Canavalia ensiformis. CAV is cytotoxic to MIA PaCa-2 human pancreatic cancer cells. We sought to determine whether CAV's efficacy as an anticancer agent might be increased in combination with 5-fluorouracil (5-FU), a pyrimidine antimetabolite with activity against solid tumors. Using optimal conditions for the expression of CAV's cytotoxicity against MIA PaCa-2 cells, CAV was more cytotoxic to the cells than 5-FU. The combination of both drugs at a fixed molar ratio of 1:1 exhibited synergistic effects in the cells as determined by combination index analysis. The combination of 5-FU:CAV was tested at a ratio of 5:1 and exhibited antagonism at lower effect levels, additivity at 50% effect levels and slight synergism at higher effect levels. A 10:1 combination of both drugs (5-FU:CAV) exhibited antagonistic effects at all levels. When the drugs were combined at a molar ratio of 20:1, increased antagonism was observed. When CAV (1.0 or 2.0 g/kg daily) and/or 5-FU (35 mg/kg daily) was administered to colonic tumor-bearing rats for five consecutive days, the antitumor activity of the drug combination was significantly greater than the combined effects of either drug alone. However, the body weight loss experienced by CAV-treated rats was increased in those rats exposed to a combination of both drugs. These studies using different tumors provide in vitro and in vivo evidence that combination therapy offers a viable means of improving CAV's intrinsic efficacy while decreasing the concentration of 5-FU required to produce the same cytotoxic effect.(ABSTRACT TRUNCATED AT 250 WORDS)

Inhibition of the growth of human pancreatic cancer cells by the arginine antimetabolite L-canavanine.

L-Canavanine (CAV), the L-2-amino-4-guanidinooxy structural analogue of L-arginine (ARG), is a potent ARG antagonist which occurs in the jack bean, Canavalia ensiformis. This ARG antimetabolite is active against L1210 murine leukemia and a solid colonic tumor in the rat. Our initial studies using a microtiter assay show that CAV exhibits a 50% inhibitory concentration of approximately 2 mM against the human pancreatic adenocarcinoma cell line, MIA PaCa-2, when these cells are grown in Dulbecco's modified Eagle's medium containing 0.4 mM ARG. When the ARG concentration is reduced to 0.4 microM, the 50% inhibitory concentration for CAV falls precipitously to 0.01 mM. The pronounced increase in the ability of CAV to inhibit MIA PaCa-2 cell growth at the lower ARG concentration may result from enhanced CAV competition with ARG for incorporation into newly synthesized cellular proteins. At 0.4 microM ARG, 30 mM CAV almost completely inhibits cell growth by 6 h. In contrast, with 0.4 mM ARG, complete inhibition does not occur until after 48 h. A dramatic reversal of growth inhibition caused by a very high concentration of CAV was observed when cells treated with CAV were replenished with a high concentration of ARG. Our results suggest that CAV has real potential as a lead compound for the development of analogues with enhanced activity against human pancreatic cancer.

A rapid mechanism-based screen to detect potential anti-cancer agents.

Several mutant Chinese hamster ovary (CHO) cell lines have been adapted to the microtiter tetrazolium assay in order to obtain useful mechanistic information relevant to the cytotoxic activity of marine natural products. The sensitivity of a DNA double-strand break repair deficient CHO line, xrs-6, was compared with that of a DNA repair competent CHO line, BR1, to several known drugs. The deficiency of the xrs-6 cells makes them overly sensitive to compounds [e.g. topoisomerase II (topo II) inhibitors] that produce DNA double-strand breaks. Described here is the validation of this unique cellular screen to detect such compounds. Those drugs thought to produce their effects by the inhibition of topo II, produced the largest differential cytotoxicity against the mutant CHO pair. Other agents that are known to either produce single-strand breaks, cross-links or to inhibit the synthesis of DNA did not possess appreciably enhanced cytotoxicity to the xrs-6 line. The usefulness of the screen was shown by its ability to detect topo II inhibitory activity in several new marine natural products. This activity was confirmed by an in vitro enzyme inhibition assay. In contrast, the screen predicted a lack of topo II inhibitory activity in some other structurally related marine natural products and this lack of activity was confirmed by an in vitro enzyme inhibition assay.

Makaluvamines, marine natural products, are active anti-cancer agents and DNA topo II inhibitors.

The makaluvamines were isolated from a sponge of the genus Zyzzya by following bioactivity against the human colon carcinoma cell line, HCT 116. These compounds have considerable cytotoxic activity. The makaluvamines appear to be acting through inhibition of DNA topoisomerase II. The compounds show enhanced toxicity toward a topoisomerase II-cleavable complex-sensitive cell line, they inhibit topoisomerase II decatenation of kinetoplast DNA in vitro. Makaluvamine C was shown to produce protein-linked DNA double-strand breaks, and makaluvamine A produced DNA double-strand breaks by neutral filter elution in a dose-dependent fashion similar to 4'-(9-acridinylamino)methanesulfon-m-anisidide (m-AMSA). The makaluvamines also increased the life span of nude mice bearing solid tumors of human ovarian cancer cells.

Isolation, purification, and characterization of two new chemical decomposition products of methylazoxyprocarbazine.

We have previously reported that the antineoplastic agent, procarbazine, in aqueous solutions was chemically oxidized to its azoxy metabolites (methylazoxy and benzylazoxy). To determine if there was additional metabolism of the most active metabolite, methylazoxyprocarbazine, it was incubated in the presence and absence of CCRF-CEM human leukemia cells. Incubations were extracted, and potential metabolites were detected by HPLC with UV detection and by combined HPLC and thermospray mass spectrometric analysis. The major metabolite identified by HPLC with UV detection of the extracts was N-isopropyl-p-formylbenzamide; this was identified by comparison of its retention time with that of a synthesized standard. This identification was further corroborated by HPLC/thermospray mass spectrometry (LC/MS). Analysis of the extracts by LC/MS also showed the presence of a closely eluting peak that had a protonated molecular ion at m/z 207. This new metabolite was identified as N-isopropyl-(benzene-1,4-bis-carboxamide) by 1H NMR and gas chromatography/ion trap mass spectrometry. This metabolite is postulated to arise from breakage of the N-N bond in the hydrazine portion of the molecule. Reconstructed ion (m/z 236) current profiles from the analysis of the cell extracts indicated that there was only a trace amount of methylazoxyprocarbazine left after a 72-hr incubation. Interestingly, a peak with the same molecular weight as the parent compound (methylazoxyprocarbazine) was observed in the cellular incubations and also in extracts of control incubations in which methylazoxyprocarbazine was incubated in medium without cells. This unknown was silylated and identified as a hydroxyazo compound by an ion trap mass spectrometer operated under both single and multiple-stage mass analysis. Formation of this decomposition product appears to involve a novel intramolecular rearrangement of methylazoxyprocarbazine in solution. This pathway may be responsible for the formation of the ultimate cytotoxic species by chemical decomposition of procarbazine.

Non-enzymatic activation of procarbazine to active cytotoxic species.

The cellular cytotoxicity of procarbazine is thought to result from bioactivation of the parent compound through reactive intermediates to an ultimate alkylating species. Procarbazine is converted initially to azoprocarbazine, which is then N-oxidized through a cytochrome P-450-mediated process to a mixture of the positional isomers, benzylazoxyprocarbazine and methylazoxyprocarbazine. In order to define the bioactivation events that lead to the cytotoxic species, the in vitro cytotoxicities of the purified azoxy isomers as well as of the parent compound, procarbazine, were evaluated with the human leukemia cell line, CCRF-CEM. The methylazoxy isomer was found to be the most active species. Procarbazine inhibited the growth of CCRF-CEM cells but at a concentration much higher than that required for the methylazoxy isomer. Since procarbazine must be metabolized to form the cytotoxic species, we sought to determine if the active metabolite, methylazoxyprocarbazine, was being formed in the incubations. Solutions of procarbazine incubated with and without cells at 37 degrees C were analyzed by combined liquid chromatography-mass spectrometry with a thermospray interface. The azoxy metabolites of procarbazine appeared rapidly in cellular incubations and in the aqueous solutions without cells. More of the methylazoxy isomer was formed initially, but by 72 hr the benzylazoxy isomer was the predominant species. Thus, in these studies it appears that procarbazine was benzylazoxy isomer was the predominant species. Thus, in these studies it appears that procarbazine was non-enzymatically oxidized to the two azoxyprocarbazine isomers and that the methylazoxy compound was the most cytotoxic to CCRF-CEM cells.

Methylazoxyprocarbazine, the active metabolite responsible for the anticancer activity of procarbazine against L1210 leukemia.

Procarbazine is a 1,2-disubstituted hydrazine derivative that is used to treat human leukemias. The anticancer activity of procarbazine results from bioactivation to reactive intermediates. It is first oxidized to azoprocarbazine and further N-oxidized to a mixture of methylazoxyprocarbazine and benzylazoxyprocarbazine isomers. In this study the azoxyprocarbazine isomers were synthesized and purified. The cytotoxic effect of the metabolites on the L1210 murine leukemia cell line were then evaluated in vitro by use of a colorimetric assay using 3-(4,5-dimethyl-thiazol-2-yl)-2,5-diphenyl-tetrazolium bromide. The results of this study showed that the methylazoxyprocarbazine isomer was the most cytotoxic metabolite (IC50, 0.2 mM). The benzylazoxy isomer had an insignificant cytotoxic effect, and a mixture of the two isomers was intermediate in effectiveness. This assay, however, could not be used to determine the cytotoxicity of procarbazine since the drug itself (not the live cells) reduced the dye. A soft-agar clonogenic assay demonstrated that procarbazine was cytotoxic only at higher concentrations (IC50, 1.5 mM) than methylazoxyprocarbazine (IC50, 0.15 mM). The effect of procarbazine and its metabolites on the survival of L1210 tumor-bearing mice was determined, and methylazoxyprocarbazine was again the most effective compound. These studies demonstrate that the methylazoxyprocarbazine metabolite is probably the major cytotoxic intermediate involved in the mechanism of anticancer action of procarbazine.