Differential poisoning of topoisomerases by menogaril and nogalamycin dictated by the minor groove-binding nogalose sugar.

The effect of DNA binding on poisoning of human DNA TOP1 has been studied using a pair of related anthracyclines which differ only by a nogalose sugar ring. We show that the nogalose sugar ring of nogalamycin, which binds to the minor groove of DNA, plays an important role in affecting topoisomerase-specific poisoning. Using purified mammalian topoisomerases, menogaril is shown to poison topoisomerase II but not topoisomerase I. By contrast, nogalamycin poisons topoisomerase I but not topoisomerase II. Consistent with the biochemical studies, CEM/VM-1 cells which express drug-resistant TOP2alpha are cross-resistant to menogaril but not nogalamycin. The mechanism by which nogalamycin poisons topoisomerase I has been studied by analyzing a major topoisomerase I-mediated DNA cleavage site induced by nogalamycin. This site is mapped to a sequence embedded in an AT-rich region with four scattered GC base pairs (bps) (at -10, -6, +2, and +12 positions). GC bps embedded in AT-rich regions are known to be essential for nogalamycin binding. Surprisingly, DNase I footprinting analysis of nogalamycin-DNA complexes has revealed a drug-free region from -2 to +9 encompassing the major cleavage site. Our results suggest that nogalamycin, in contrast to camptothecin, may stimulate TOP1 cleavage by binding to a site(s) distal to the site of cleavage.

The biochemical pharmacology of nogalamycin and its derivatives.

This review assimilates up-to-date information on the biochemical pharmacology of nogalamycin and selected derivatives that have shown good biological activities and/or received a relatively detailed investigation. The structure and chemical preparation of these derivatives from nogalamycin is described and the nomenclature which has been rather perplexing in the literature is clarified. The interaction of this class of compounds, particularly nogalamycin, with DNA is extensively reviewed. The biochemical mechanism of action of nogalamycin and its structurally closely-related derivatives is described. Among nogalamycin derivatives, menogaril showed distinct biochemical effects as well as superior cytotoxicity and antitumor activity and also proved to be effective against breast cancer clinically.

Phase II trial of menogaril as initial chemotherapy for metastatic breast cancer.

Eighteen women with metastatic breast cancer previously untreated with chemotherapy were entered on a phase II trial of intravenous menogaril, a new anthracycline derivative. Treatment was given at 140 mg/m2 on days 1 and 8 of each 28 day cycle. The most common toxicities were leukopenia in all patients and burning and phlebitis at infusion sites in 72%. Serial assessment of cardiac function by resting and stress gated blood pool scans showed temporary decrements in ejection fraction in only 2 patients (11%). The response rate to the therapy was 19% [95% CI 0-38%] including 1 complete and 2 partial responses. The median time to relapse among responders was 6.5 months. Mean survival in all patients entered was 15.8 months from date of entry. Menogaril at this dose and schedule has modest activity as first line therapy for metastatic breast cancer but also has significant marrow and local toxicity.

A phase II study of menogaril (NSC-269148) in colorectal carcinoma. A Southwest Oncology Group study.

In this phase II trial, menogaril was administered to patients with metastatic colon cancer at a dose of 200 mg/m2 IV over one hour with cycles repeated every 28 days provided the absolute granulocyte count was greater than or equal to 2000 cells/microliters. Dose adjustments up or down were made depending upon nadir counts. Twenty-four patients were entered on this study with 21 eligible and evaluable for response. There was 1 CR lasting four and one-half months and 1 PR lasting three months for an overall CR + PR rate of 10% with a 95% confidence interval of 1% to 30%. Six patients (29%) had stable disease and 13 (62%) progressed. Median survival is 13.1 months. Toxicity was primarily hematologic with two cases of life-threatening leukopenia (less than 1000 cells/microliters) and one case of life-threatening granulocytopenia (less than 250 cells/microliters) among the 21 eligible patients, and one case of life-threatening leukopenia and granulocytopenia in one ineligible patient. There were no deaths due to treatment.

Activity of intravenous menogaril in patients with previously untreated metastatic breast cancer. A National Cancer Institute of Canada Clinical Trials Group study.

We have carried out a phase II study of intravenous menogaril given every four weeks in a group of patients with breast cancer who had received no prior chemotherapy for metastatic disease. Myelosuppression, nausea and vomiting and local reactions were seen frequently. Six partial responses (median duration 154 days) were seen in 24 eligible patients. We conclude menogaril is active in breast cancer and recommend that because it can be delivered in high doses orally, future trials in this disease should focus on intense oral schedule.

Evaluation of menogaril in renal cell carcinoma. A Southwest Oncology Group phase II study (8504).

The Southwest Oncology Group (SWOG) studied the response rate and toxicity of menogaril (200 mg/m2 i.v. q 28 days) in patients with advanced metastatic renal cell carcinoma. During the early stage of the trial two partial responses were seen in the first 20 treated patients, and an additional 36 evaluable patients were studied. Three of 56 (5%) evaluable patients achieved partial responses. Significant white cell toxicity was observed. Mild or moderate degrees of thrombocytopenia, gastrointestinal side effects, alopecia and phlebitis occurred. No cardiac toxicity was noted. The low response rate suggests that menogaril in this dose schedule has no role in the treatment of patients with advanced metastatic renal cancer.

The mouse bone marrow micronucleus test: evaluation of 21 drug candidates.

The mouse bone-marrow micronucleus test is one of the most widely used genetic toxicology assays. In this report the results of testing 21 compounds in the micronucleus test are presented. Of the 21 compounds tested, 3 potential chemotherapeutic agents were identified as strongly clastogenic. In addition, one compound was identified as a weak inducer of micronuclei in the assay. Further testing of this compound in an in vivo bone marrow metaphase analysis failed to confirm this material as clastogenic. The remaining 17 compounds were classified as negative in the assay. In general the results of the micronucleus test agreed with the results of other genetic toxicology assays on this group of compounds.

Phase I study and pharmacokinetics of menogaril (NSC 269148) in patients with hepatic dysfunction.

We performed a phase I study of menogaril to determine if dosage reduction was required in patients with hepatic dysfunction and if the relationship between pharmacokinetics and leukopenia, previously defined in patients with normal hepatic and renal function, was altered. Eighteen patients received 27 courses of menogaril, of which 26 were evaluable for toxicity. Patient characteristics were median age, 63 years (range, 28-80 years), 14 male/4 female, and median Karnofsky performance status 80% (range, 60-100%). Prior therapy included none, five; chemotherapy only, seven; radiotherapy only, two; and chemotherapy and radiotherapy, four. Menogaril was administered as a 2-h.i.v. infusion every 28 days at 62.5 (one patient), 125 (eight patients), 187.5 (seven patients), and 250 mg/m2 (six patients), based on pretreatment serum bilirubin, aspartate aminotransferase, alanine aminotransferase, and alkaline phosphatase. Patients also had indocyanine green and antipyrine clearances measured before menogaril treatment. Menogaril and metabolites were assayed by high performance liquid chromatography. Dose-limiting toxicity was leukopenia. WBC nadirs occurred between days 8 and 20 (median, 15). Three patients developed platelet nadirs below 100,000/microliters. Other toxicities included grade I nausea and vomiting in three patients and phlebitis at the site of drug infusion in six patients. Correlations were defined between pretreatment indocyanine green clearance and serum concentrations of alkaline phosphatase and total bilirubin. There were no correlations between pretreatment serum concentrations of bilirubin, aspartate aminotransferase, alanine aminotransferase, alkaline phosphatase, indocyanine green clearance or antipyrine and menogaril clearances. Menogaril pharmacokinetics in patients with elevated liver function tests was indistinguishable from that described in patients with normal liver function tests. There were excellent correlations between plasma area under the curve of menogaril and the percentage decreases in WBC and neutrophils. These were well described by two models previously used to study the same relationships in patients with normal hepatic and renal function. When compared to previous studies, patients with hepatic and renal dysfunction had a greater percentage decrease in WBC for any given area under the curve than did patients with normal hepatic and renal function. On the other hand, there was no difference in the relationship between percentage decrease in neutrophils and menogaril area under the curve in these two groups of patients.(ABSTRACT TRUNCATED AT 400 WORDS)

Phase I and II agents in cancer therapy: I. Anthracyclines and related compounds.

Anthracycline antibiotics remain among the most potent anticancer drugs, but their efficacy is limited by the development of a dose-dependent irreversible cardiomyopathy and by the emergence of clones of tumor cells resistant to the effects of the drug. Modifications of the basic anthracycline structure have resulted in molecules that may share the activity of the parent compound, with amelioration of some toxicities, absence of cross-resistance, or activity against tumors insensitive to the parent drug. Epirubicin has a unique metabolic pathway, glucuronidation, that may result in more rapid plasma clearance and reduced toxicity as compared with doxorubicin. Epirubicin has demonstrated comparable activity to doxorubicin in breast cancer, with possibly reduced toxicity. Idarubicin is of interest because of its cytotoxic activity when given orally. Idarubicin has prolonged retention in the plasma and has equal cytotoxic activity to the parent compound. Idarubicin has demonstrated activity against acute leukemia and breast cancer; in the latter tumor category, some doxorubicin-resistant tumors have responded. Esorubicin is of interest because of its nearly absent cardiac toxicity. This agent has some activity against solid tumors and is currently being clinically tested. Aclacinomycin A is an anthracycline in which a trisaccharide is substituted for the aminosugar. Aclacinomycin A and the related compound marcellomycin are of interest as both cytotoxic and differentiating agents. Menogaril is an anthracycline with the aminosugar on the D ring; it does not exhibit cross-resistance with doxorubicin or cardiotoxicity. Mitoxantrone is a compound that is related to the anthracyclines but has a different mechanism of action. This agent has significant activity against acute leukemia and breast cancer and is currently being compared with doxorubicin. Amsacrine is another compound related to the anthracyclines that possesses major activity against acute leukemias. Minor modifications of the anthracycline molecule have had major impact on the biologic activity of these drugs. New anthracycline analogues with up to 100 times the potency of currently available anthracyclines are being developed for clinical testing, and these complex molecules retain a nearly unlimited potential for structural modification.

Human pharmacokinetics, excretion, and metabolism of the anthracycline antibiotic menogaril (7-OMEN, NSC 269148) and their correlation with clinical toxicities.

In a Phase I study, menogaril (7-OMEN) was administered daily for 5 days/course, every 21-28 days. Dosages of 3.5, 7, 11.5, 17, and 31.5 mg/m2 were infused over 1 h, and dosages of 42, 50, and 56 mg/m2 were infused over 2 h. Pharmacokinetics was studied at all dosages. Plasma and urine samples were collected from 24 patients, and bile samples were also collected from 2 patients. 7-OMEN and metabolites were measured by high performance liquid chromatography. 7-OMEN was the major plasma fluorescent species at all times, with only trace amounts of N-demethyl menogaril observed. 7-OMEN disappeared from plasma biexponentially with t1/2 alpha 0.19 +/- 0.04 (mean +/- SE) h and t1/2 beta 13.22 +/- 1.54 h. Plasma pharmacokinetics of 7-OMEN was linear from 3.5-56 mg/m2; area under the curve increased proportionally with dosage. Total body clearance of 7-OMEN was 28.18 +/- 3.33 liter/m2/h, Vc was 224 +/- 30.8 liter/m2, and Vss was 370 +/- 25.7 liter/m2. Plasma pharmacokinetics of 7-OMEN studied on multiple days of a given course were similar. Urinary excretion of 7-OMEN and fluorescent metabolites accounted for 5.4 +/- 0.4% of the daily dose. Parent compound still represented greater than or equal to 80% of urinary drug fluorescence after 24 h. N-demethyl menogaril was the only other fluorescent drug species detected in urine. In two patients with biliary tract drains, biliary excretion of drug fluorescence accounted for 2.2-4.2% of the daily dose. Only 7-OMEN and N-demethyl menogaril were detected in bile by high performance liquid chromatography and thin layer chromatography. 7-OMEN was the major fluorescent biliary species, but, by 24 h, N-demethyl menogaril accounted for approximately 40% of biliary drug fluorescence. When considered in light of each patient's observed toxicities, excellent relationships were observed between the plasma area under the curve of 7-OMEN and the percentage of decreases in WBC and absolute neutrophil count. These latter findings should be useful in developing more precise and intelligent dosing schemes for 7-OMEN.

Menogaril: a new anthracycline agent entering clinical trials.

Menogaril [menogarol, 7(R)-O-methylnogarol, 7-OMEN] is a new anthracycline agent which was chosen for clinical trials based on: broad spectrum activity against a panel of murine tumors, lower cardiotoxicity than doxorubicin in the chronic rabbit model, differences in biochemical effects from other anthracyclines suggesting a possible difference in mechanism of action, murine antitumor activity by oral as well as parenteral routes. Biochemical studies indicated that, in comparison to doxorubicin, menogaril is bound weakly to DNA, inhibits RNA synthesis less, and has different cell cycle phase-specific cytotoxicity. Pharmacology studies in the mouse and dog using HPLC analytical methodology have shown multiexponential clearance from plasma and metabolism of menogaril to a material which co-chromatographs with N-demethylmenogaril in addition to at least two other metabolites of unknown structure. Oral bioavailability studies in the mouse showed significant absorption of menogaril from the gastrointestinal tract followed by first-pass metabolism. In acute toxicity studies in the rat, the dog, and the monkey, dose-related myelosuppression and gastrointestinal toxicity predominated. Phase I clinical trails on menogaril are currently in progress on a variety of schedules.

Comparative genotoxicity of adriamycin and menogarol, two anthracycline antitumor agents.

Adriamycin and menogarol are anthracyclines which cause more than 100% increase in life span of mice bearing P388 leukemia and B16 melanoma. Unlike Adriamycin, menogarol does not bind strongly to DNA, and it minimally inhibits DNA and RNA synthesis at lethal doses. Adriamycin is a clinically active drug, and menogarol is undergoing preclinical toxicology at National Cancer Institute. In view of the reported mutagenicity of Adriamycin, we have compared the genotoxicity of the two drugs. Our results show that, although Adriamycin and menogarol differ significantly in their bacterial mutagenicity (Ames assay), they have similar genotoxic activity in several mammalian systems. Adriamycin is strongly mutagenic in the Ames assay with TA98 and TA100. Menogarol is nonmutagenic to TA98 and TA100. For the mammalian cell culture systems, V79 (Chinese hamster) cells are exposed for 2 hr to drug, following which cell survival, induction of sister chromatid exchanges, chromosome damage, and production of mutants resistant to 6-thioguanine are measured. The percentage of survival obtained with the two drugs ranges between 25 and 50% at 0.15 microgram/ml and 5 to 15% at 0.3 microgram/ml. At 0.15 microgram/ml, Adriamycin and menogarol increase the percentage of cells with chromosome damage from a background level of 8.8 to 30 and 22.5%, respectively. The same drug concentration causes a small but significant increase in sister chromatid exchange rate. Both drugs are equally active (increase mutation frequency about 3- to 6-fold above background) in producing 6-thioguanine-resistant mutants. The induction of micronuclei in polychromatic erythrocytes of rats is the most sensitive assay system. Both drugs cause 10- to 15-fold increase in micronuclei at nontoxic doses.