Limonoids showing selective toxicity to DNA repair-deficient yeast and other constituents of Trichilia emetica.

Bioactivity-directed fractionation of the MeCOEt extract of Trichilia emetica (Meliaceae) resulted in the isolation of the limonoids nymania 1 (1), drageana 4 (3), trichilin A (4), rohituka 3 (5), and Tr-B (7) and the novel seco-A protolimonoid 8. Of these, nymania 1 and Tr-B showed selective inhibitory activity toward DNA repair-deficient yeast mutants. The isolation, structure elucidation, 13C NMR spectral assignments, and biological activities of these compounds are reported.

Bioactive and other sesquiterpenes from Chiloscyphus rivularis.

Bioassay-directed fractionation of the methyl ethyl ketone extract of Chiloscyphus rivularis yielded five new sesquiterpenes, 12-hydroxychiloscyphone (2), chiloscypha-2,7-dione (3), 12-hydroxychiloscypha-2,7-dione (4), chiloscypha-2,7,9-trione (5), and rivulalactone (6) in addition to the known sesquiterpenes, 4-hydroxyoppositan-7-one (7), chiloscyphone (1), and isointermedeol (8). The structure and stereochemistry of rivulalactone, a novel trinorsesquiterpene, was confirmed by its synthesis starting from 1. Compound 2 showed selective bioactivity in our yeast-based DNA-damaging assay and cytotoxicity to human lung carcinoma cells.

Comparative activity of oral and parenteral topotecan in murine tumor models: efficacy of oral topotecan.

Studies were performed using several tumor models to determine the oral efficacy of topotecan. These studies were direct comparisons of oral administration with parenteral treatment by the intravenous, intraperitoneal, or subcutaneous routes. Treatment schedules included bolus treatments at 4- or 7-day intervals and a split-dose regimen (q3hx4) repeated at 4- or 7-day intervals. On the various schedules, the maximally tolerated dose of topotecan was either equivalent to or at most 1.7-fold that of parenteral administration, indicative of excellent oral bioavailability in the mouse. Orally administered topotecan was comparable in efficacy to parenteral treatment in four of five tumor models tested (i.v. L1210 leukemia, i.v. B16 melanoma, i.v. and s.c. Lewis lung carcinoma). The M5076 reticulum cell sarcoma implanted i.p. responded to i.p. and s.c. but not to orally administered topotecan. These studies provide convincing support for the clinical evaluation of orally administered topotecan.

In vitro and in vivo effects of clinically important camptothecin analogues on multidrug-resistant cells.

The cytotoxic alkaloid camptothecin (CPT) and several of its analogues, including the clinically relevant topotecan (TPT), irinotecan (CPT-11), and 9-aminocamptothecin, were evaluated for differential cytotoxic effect and DNA damage induction in multidrug-sensitive (AuxB1) and multidrug-resistant (MDR) (CHRC5) Chinese hamster ovary cells. CPT, 10-hydroxycamptothecin, and 10,11-methylenedioxycamptothecin produced equivalent amounts of cell growth inhibition and/or DNA single-strand breakage in the two cell lines. TPT, SN-38 (the active metabolite of CPT-11), and 9-aminocamptothecin were 12-, 9-, and 10-fold, respectively, less toxic to the MDR than to the wild-type cells. These findings are consistent with differences in yields of DNA single-strand breaks produced in AuxB1 and CHRC5 cells by 2-hr incubations with the various compounds. In both assays, the resistance ratios of the topoisomerase I inhibitors were approximately one-tenth those of known MDR drugs such as vinblastine or amsacrine. Thus, cultured cells that overexpress P-glycoprotein have the potential to develop some level of cross-resistance to all three topoisomerase I inhibitors currently in the clinic. The chemical basis for cross-resistance of cultured MDR cell lines to certain CPT analogues is not yet understood, but is likely more complex than positive charge alone. TPT had a reasonable therapeutic effect on B6D2F1 female mice implanted with MDR sublines of P388 leukemia, compared with its effect on mice implanted with wild-type P388 cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Pharmacokinetics and pharmacodynamics of topotecan in patients with advanced cancer.

Topotecan, a semisynthetic water-soluble analog of camptothecin, is the first topoisomerase I-directed drug to enter clinical trial in the United States in over 20 yr. In this study, 30-min infusions of topotecan were administered daily for 5 days every 3 weeks at doses ranging from 0.5 to 2.5 mg/m2. Topotecan is reversibly hydrolyzed in a pH-dependent reaction in aqueous solutions to the ring-open hydroxy acid. The disposition of the closed ring lactone has been studied in 26 patients, and the disposition of both lactone and hydroxy acid has been studied in 12 patients. The clearance rate for topotecan lactone was 1220 ml/min/m2, with a range of 300-4760 ml/min/m2. The clearance rate for total topotecan (lactone and hydroxy acid) was 493 ml/min/m2, with a range of 163-815 ml/min/m2. A model for the disposition of lactone and hydroxy acid incorporating both reversible hydrolysis and elimination was developed. We have shown that topotecan is partially hydrolyzed prior to administration in parenteral solutions, and that clearance of the parent compound proceeds in vivo by conversion to hydroxy acid and elimination. Renal clearance accounted for 30 +/- 18% of drug elimination in patients. The relationship between topotecan dose and myelotoxicity is well fit by a sigmoidal Emax model, as is the relationship between total topotecan area under the concentration-time curve and myelotoxicity. The disposition of topotecan was also studied in mice. The clearance rate for total topotecan in mice was 330 ml/min/m2 after administration of topotecan lactone.(ABSTRACT TRUNCATED AT 250 WORDS)

Camptothecin hyper-resistant P388 cells: drug-dependent reduction in topoisomerase I content.

A subline of P388 leukemia made 10-fold resistant to camptothecin (CPT) by serial passage in drug-treated mice was adapted to growth in tissue culture and made hyper-resistant to CPT by passage in the presence of increasing concentrations of the drug. Cells were obtained that were 1,000-fold resistant to CPT, compared to wild-type P388 cells. Neither topoisomerase I mRNA nor 100 kDa topoisomerase I enzyme was detectable in these cells, and topoisomerase I activity extracted from nuclei was less than 4% of that extracted from nuclei of wild-type cells. An immunoreactive 130 kDa protein that could be an altered, inactive form of topoisomerase I was evident in the hyper-resistant cells. In addition, the cells deficient in topoisomerase I contained enhanced topoisomerase II activity. Maintenance of the hyper-resistant phenotype required continued exposure to CPT; growth in its absence led to loss of hyper-resistance, increased topoisomerase I content and activity, and decreased topoisomerase II activity. The sensitivity of the cells to killing by a number of inhibitors of topoisomerases I and II was consistent with these observations. Thus, P388 cells have the potential to become highly resistant to CPT by severely curtailing topoisomerase I expression; in these circumstances, topoisomerase I and II activities are regulated coordinately.

Synergistic cell killing by ionizing radiation and topoisomerase I inhibitor topotecan (SK&F 104864).

Topotecan (SK&F 104864), a water-soluble analogue of the topoisomerase I inhibitor camptothecin, is currently in Phase II clinical trial for solid tumors. We have characterized topotecan in terms of its effect upon gamma-radiation-induced cell killing. In colony formation experiments, subtoxic concentrations of topotecan (2 microM) potentiated radiation-induced killing of exponentially growing Chinese hamster ovary or P388 murine leukemia cultured cells. Survival curve shoulders were reduced; the slopes of the exponential portions of the curves were decreased to a small extent. D37 and D10 (radiation dose resulting in 37 and 10% survival of colony-forming ability) values were reduced by approximately 60 and 50%, respectively, in the case of Chinese hamster ovary cells. In P388 cells, topotecan reduced D37 by 35 to 40% and D10 by 20 to 25%. Potentiation of radiation-induced cell killing by topotecan was absolutely dependent upon the presence of the topoisomerase I inhibitor during the first few (less than 30) min after irradiation. Association of topoisomerase I with this effect was confirmed in studies of Chinese hamster ovary cells previously made resistant to camptothecin (and cross-resistant to topotecan), resulting in decreased cellular content of topoisomerase I. These cells were found to be 2- to 3-fold hypersensitive to gamma-radiation-induced killing. P388 camptothecin-resistant cells were further sensitized to the lethal effects of ionizing radiation by nontoxic treatment with the topoisomerase II inhibitor novobiocin, consistent with increased dependence of topoisomerase I-deficient cells upon topoisomerase II.

In vivo development and in vitro characterization of a subclone of murine P388 leukemia resistant to bis(diphenylphosphine)ethane.

Bis(diphenylphosphine)ethane (DPPE) and its gold coordination complexes have demonstrated antitumor activity in transplantable tumor models. This report describes the development of a P388 cell line (P388/DPPEc) that is resistant to DPPE and its analogues and the in vitro characterization of the cross-resistance of this subline to various antitumor and cytotoxic agents. The P388/DPPE tumor cell line was developed by serial transplantation in DPPE-treated mice. Resistance to DPPE was phenotypically stable. The P388/DPPE subline was cross-resistant to DPPE analogues and metal coordination complexes of DPPE. In addition, P388/DPPE cells were resistant to several mitochondrial uncouplers, including rhodamine-123, tetraphenylphosphonium, and carbonylcyanide-p-trifluro-methoxyphenyl hydrazone. P388/DPPE cells were less capable of sequestering and retaining 123Rh than were sensitive (P388/S) cells. Exposure to Au(DPPE)2+, a gold complex of DPPE with increased antitumor activity, resulted in a depletion of cellular ATP; the depletion was more rapid in the sensitive than the resistant cells. The rate of mitochondrial respiration, as measured by 14CO2 evolution from [6-14C]glucose, was greater in P388/S than in P388/DPPE. As with that evidenced for 123Rh, the cellular uptake of radiolabeled DPPE was decreased in P388/DPPEc cells. The results suggest that the basis for the resistance of this cell line may be an alteration in mitochondrial membrane potential. These data and the striking cross-resistance of P388/DPPE to mitochondrial uncouplers support the hypothesis that mitochondria may be one target involved in the cytotoxic or antitumor activities of these compounds. Mitochondria may also be causally related to the cytotoxic or antitumor activities, in that DPPE may be concentrated in cells via the presence of the inner mitochondrial membrane potential. Thus, P388/DPPE cells can serve as a tool to screen for and evaluate drugs that rely on affecting mitochondrial function, either mechanistically or causally, for their antitumor efficacy.

Synthesis of water-soluble (aminoalkyl)camptothecin analogues: inhibition of topoisomerase I and antitumor activity.

Water-soluble analogues of the antitumor alkaloid camptothecin (1) were prepared in which aminoalkyl groups were introduced into ring A or B. Most of the analogues were prepared by oxidation of camptothecin to 10-hydroxycamptothecin (2) followed by a Mannich reaction to give N-substituted 9-(aminomethyl)-10-hydroxycamptothecins (4-12) or by subsequent modification of Mannich product 4 (13, 15, 17, 19, 21). Others were obtained by modification of the hydroxyl group of 2 (25,26) or by total synthesis (35,42,43). These analogues, as well as some of their synthetic precursors, were evaluated for inhibition of topoisomerase I, cytotoxicity, and antitumor activity. Although there was not a quantitative correlation between these assays, compounds that inhibited topoisomerase I were also cytotoxic and demonstrated antitumor activity in vivo. Further evaluation of the most active water-soluble analogue led to the selection of 9-[(dimethylamino)methyl]-10-hydroxycamptothecin (4, SK&F 104864) for development as an antitumor agent. In addition to its water solubility, ease of synthesis from natural camptothecin, and high potency, 4 demonstrated broad-spectrum activity in preclinical tumor models and is currently undergoing Phase I clinical trials in cancer patients.

Development of a stable camptothecin-resistant subline of P388 leukemia with reduced topoisomerase I content.

A camptothecin-resistant subline of P388 leukemia (P388/CPT) was developed by repeated transplantation of P388 cells in mice treated with therapeutic doses of camptothecin. In mice bearing the resistant tumor, a maximally tolerated dose of camptothecin produced no net reduction in tumor cell burden, in contrast to a 5-log cell kill in the parental P388 (P388/S). The IC50 of camptothecin, as determined by colony formation assays of cultured cells, was 8 times greater for the cloned P388/CPT cell line than for P388/S. P388/CPT cells were not cross-resistant to other antineoplastic agents, including topoisomerase II inhibitors. The type I topoisomerases purified from P388/CPT and P388/S cells were identical with respect to molecular weight, specific activity, in vitro camptothecin sensitivity, and DNA cleavage specificity. Camptothecin induced fewer protein-associated DNA single-strand breaks in the resistant cells than in the wild-type P388 cells. Topoisomerase I mRNA, immunoreactivity, and extractable enzymatic activity were 2-4 times lower for P388/CPT cells than for P388/S cells. As resistance to camptothecin developed, topoisomerase I extractable activity decreased, concomitant with an increase in topoisomerase II extractable activity. Furthermore, the appearance of camptothecin resistance was associated with specific rearrangements of the topoisomerase I gene. These results suggest that development of resistance to inhibitors of topoisomerase I can occur by down-regulation of the target enzyme, thus reducing the production of lethal enzyme-mediated DNA damage. The enhanced topoisomerase II activity in these cells suggests that resistance to camptothecin may be overcome by co-treatment with topoisomerase II inhibitors.

Nonproductive rearrangement of DNA topoisomerase I and II genes: correlation with resistance to topoisomerase inhibitors.

Topoisomerase inhibitors comprise an important group of agents that is used in cancer treatment. Because the development of resistance to cancer chemotherapeutic agents represents a major limitation of cancer chemotherapy, we investigated the mechanism of resistance by murine P388 leukemia to camptothecin (topoisomerase I inhibitor) or amsacrine (topoisomerase II inhibitor). The resistant cells contained reduced levels of topoisomerase activity and messenger RNA. The topoisomerase gene of these cells was rearranged (only in one allele) and hypermethylated. These topoisomerase gene alterations probably resulted in reduced transcription and, thus, enzyme production, which was correlated with resistance to the topoisomerase inhibitor.

Synthesis, tubulin binding, antineoplastic evaluation, and structure-activity relationship of oncodazole analogues.

In an attempt to identify a soluble oncodazole analogue that could be easily formulated, a series of substituted oncodazoles was synthesized and evaluated for tubulin binding affinity, in vitro cytotoxicity against cultured mouse B-16 cells, and ability to prolong lifespan at the maximally tolerated dose in the P388 mouse leukemia model. Biological evaluation of all the isomeric methyloncodazoles demonstrated the thiophene 4'-position to be the only site of significant bulk tolerance, although substitution of this position with polar or charged functional groups abolished biological activity. Simple esters of the 4'-carboxymethyloncodazole were shown to have enhanced antitumor activity and tubulin binding affinity relative to oncodazole. Despite a failure of this study to identify a water-soluble oncodazole with antitumor activity, the structure-activity relationship developed led to a derivative with enhanced activity in the P388 leukemia model and facilitated the preparation of a biologically active photolabile analogue.

A murine model to evaluate the ability of in vitro clonogenic assays to predict the response to tumors in vivo.

The use of the human tumor cloning assay as a predictor of clinical response of human tumors to drugs is predicated on the hypothesis that the in vivo response of a tumor to a drug can be correlated with the in vitro response of cells derived from the tumor. To test this hypothesis, we utilized a murine tumor model in which the in vivo and in vitro responses of a tumor can be accurately and reproducibly compared. Drug activity was assessed in P388 leukemia with the standard in vivo antitumor assay (i.p. tumor/i.p. drug administration) and an in vitro assay wherein the ascites tumor cells are removed from mice, treated with a drug, and directly cloned in soft agar to measure clonogenic capacity. The response of P388 cells to analogues within four separate classes of antitumor agents, anthracyclines, anthraquinones, platinum(II) coordination complexes, and phosphinogold(I) complexes was evaluated. The clonogenic assay failed to discriminate between highly active in vivo antitumor agents and analogues with only marginal in vivo efficacy (i.e., doxorubicin and daunorubicin versus rhodomycins A and B, ametantrone versus NSC 276740, cisplatin versus transplatin, [Au(dppe)2]Cl versus [Au(depe)2]PF6. Furthermore, the in vitro clonogenic assay failed to detect carboplatin which was a highly active agent in vivo. The basis for these discrepancies was explored by a more detailed comparison of doxorubicin and rhodomycin B. In vivo or in vitro drug exposure with subsequent measurement of cell kill by the in vitro clonogenic and in vivo tumorigenic assay demonstrated that the in vitro assay overestimated the cytotoxic potency of the drugs relative to the tumorigenic assay. Treatment of tumors in vivo with doxorubicin at doses below the maximally tolerated dose in mice resulted in multiple log cell kill as measured in vitro or in vivo, whereas rhodomycin B was cytotoxic only at dose levels exceeding its maximally tolerated dose. The results indicate that a subset of tumor stem cells capable of forming colonies in soft agar are significantly more sensitive to the cytotoxic effects of anthracyclines than are in vivo tumorigenic stem cells. Cytotoxic potency as measured by an in vitro soft agar clonogenic assay is not an accurate predictor of in vivo antitumor efficacy even in a model in which ascites tumor cells are directly exposed to i.p. drug. The in vitro cytotoxicity assay is useful only as a nonselective prescreen and must be used in combination with other indicators of tumor cell selectivity and dose-limiting organ toxicity.

Biological characterization and oncogene expression in human colorectal carcinoma cell lines.

To establish well-characterized cellular reagents for the study of colon carcinoma, we have examined 19 human colorectal carcinoma cell lines with regard to morphology, ultrastructure, expression of tumor-associated antigens, proliferative capacity in vitro, anchorage-independent growth, oncogene expression, tumorigenicity and malignant potential. Cell lines examined were cultured under identical conditions, and in vitro and in vivo analyses were performed in parallel on replicate cultures. Three classes of colorectal cell lines were defined according to their tumorigenicity in nude mice. Class-1 lines formed rapidly progressing tumors in nearly all mice at an inoculum of 10(6) cells. Cell lines belonging to class-2 were less tumorigenic, producing tumors later and at a slower growth rate. Class-3 lines were non-tumorigenic under all experimental conditions tested. By Northern analysis, the oncogenes c-myc, H-ras, K-ras, N-ras, myb, fos and p53 were expressed in nearly all cell lines examined. In contrast, transcripts for abl, src and ros were not detected. The best in vitro predictor of tumorigenicity was colony formation in soft agar. There was no detectable correlation between tumorigenicity and metastatic potential, doubling time in vitro, production of tumor-associated markers, xenograft histology or expression of specific oncogenes.

Tumorigenicity of the cyc- variant of the S49 murine lymphoma deficient in the Gs-alpha subunit of adenylate cyclase.

S49 cyc- lymphoma cells contain a mutation resulting in loss of a functional guanine nucleotide regulatory protein rendering their adenylate cyclase refractory to most stimuli. S49 wild-type and cyc- clones were used in the present study to investigate the possible association of altered cAMP metabolism with tumorigenicity and metastatic potential. The S49 clones were implanted i.v., i.p., and intracerebrally in both athymic nude mice and syngeneic, immunocompetent BALB/c mice. Both S49 clones gave rise to tumors when inoculated into athymic mice, and no differences were observed in the tumorigenicity or metastatic potential of S49 wild-type and cyc- cells. Implantation of S49 clones in syngeneic BALB/c mice gave rise to few tumors except when administered intracerebrally, where wild-type cells were more tumorigenic than cyc- cells. This raises the possibility of differences in immunogenicity between the S49 clones. Analysis of cell lines derived from tumors grown in athymic mice showed that they retained the phenotype of the S49 clones used for inoculations. The results indicate that, despite differences in adenylate cyclase responsiveness, S49 wild-type and cyc- cells are both highly tumorigenic and metastatic.

Antitumor activity of bis(diphenylphosphino)alkanes, their gold(I) coordination complexes, and related compounds.

Bisphosphines related to bis(diphenylphosphino)ethane (dppe) and their gold complexes are described that are active in a spectrum of transplantable tumor models. When administered ip on days 1-5 at its maximally tolerated dose (MTD) of 40 mumol/kg, dppe reproducibly gives 100% increase in life span (ILS) in mice bearing ip P388 leukemia. Coordination of chlorogold(I) to each phosphine in dppe gave a complex that had similar activity but at a much lower dose level than dppe; the MTD for the gold(I) complex was 7 mumol/kg. Among other metal complexes of dppe, the Au(III) complex was active (greater than 50% ILS) whereas Ag(I), Ni(II), Pt(II), Pd(II), and Rh(I) complexes were inactive. Among dppe analogues, replacement of phenyl groups with ethyl or benzyl groups resulted in inactivity for both ligands and the corresponding gold complexes whereas substitution with cyclohexyl or heterocyclic ring systems yielded ligands and/or gold complexes with antitumor activity. Among substituted-phenyl dppe and dppe(AuCl)2 analogues, 3-fluoro, 4-fluoro, perdeuterio, 4-methylthio, and 2-methylthio analogues were active; 4-methyl, 3-methyl, 4-methoxy, 4-dimethylamino, and 4-trifluoromethyl analogues were marginal or inactive. Analogues in which the ethane bridge of dppe or dppe(AuCl)2 was varied between one and six carbons, unsaturated or substituted, revealed that activity was maximal with ethane or cis-ethylene. Compounds with good P388 activity were also active in other animal tumor models.

Purification of topoisomerase II from amsacrine-resistant P388 leukemia cells. Evidence for two forms of the enzyme.

Topoisomerase II was purified from an amsacrine-resistant mutant of P388 leukemia. A procedure has been developed which allows the rapid purification of nearly homogeneous enzyme in quantities sufficient for enzyme studies or production of specific antisera. The purified topoisomerase II migrated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis as two bands with apparent molecular masses of 180 (p180) and 170 kDa (p170); both proteins unknotted P4 DNA in an ATP-dependent manner and displayed amsacrine-stimulated covalent attachment to DNA. Staphylococcus V8 protease cleavage patterns of p170 and p180 showed distinct differences. Specific polyclonal antibodies to either p170 or p180 recognized very selectively the form of the enzyme used to generate the antibodies. Immunoblotting with these specific antibodies showed that both p180 and p170 were present in cells lysed immediately in boiling sodium dodecyl sulfate. Comparison of the purified topoisomerase II from amsacrine-resistant P388 with that from amsacrine-sensitive P388 demonstrated that each cell type contained both p180 and p170; however, the relative amounts of the two proteins were consistently different in the two cell types. The data strongly suggest that p170 is not a proteolytic fragment of p180. Thus, P388 cells appear to contain two distinct forms of topoisomerase II.

In vivo antitumor activity and in vitro cytotoxic properties of bis[1,2-bis(diphenylphosphino)ethane]gold(I) chloride.

We have previously reported the cytotoxicity and antitumor activity of bis(diphenylphosphino)ethane (DPPE) and a variety of its transition metal complexes. During studies of the chemistry of a gold complex of this group [(AuCl)2(DPPE)], it was observed that this complex readily underwent ring closure on reaction with DPPE to form the tetrahedral complex [Au(DPPE)2]+. Various counterion forms (e.g., Cl-) of this cation were isolated and were found to exhibit a remarkably high stability in solution. Evaluation of [Au(DPPE)2]Cl in mice bearing i.p. P388 leukemia demonstrated that the compound produced an average of 87% increase in life span at its maximally tolerated dose (2-3 mumol/kg/day for 5 days). Activity was also seen in i.p. M5076 reticulum cell sarcoma (60% increase in life span) and s.c. mammary adenocarcinoma 16/c. Modest activity was evident in i.p. B16 melanoma and L1210 leukemia. A subline of P388 leukemia resistant to cisplatin was not cross-resistant to [Au(DPPE)2]Cl. In addition, combination therapy of [Au(DPPE)2]Cl and cisplatin against i.p. P388 demonstrated an advantage over single-agent therapy. In vitro studies of [Au(DPPE)2]Cl showed that the compound: is cytotoxic to tumor cell lines; is only minimally inhibited in its cytotoxic activity by the presence of serum; produces DNA protein cross-links and DNA strand breaks in cells; and inhibits macromolecular synthesis with a preferential inhibitory effect on protein synthesis relative to DNA and RNA synthesis. 31P nuclear magnetic resonance spectroscopy indicated that the compound is stable in the presence of serum proteins, thiols, or disulfides and that it reacts with Cu(II) resulting in the formation of a Cu(I)DPPE complex. The results of these in vivo and in vitro experiments suggest that the contrasting pharmacological profile of [Au(DPPE)2]Cl with respect to other gold(I) phosphine complexes may be related to both the kinetic stability of the complex and its stability in the presence of thiols.

Modulation of the antitumor and biochemical properties of bis(diphenylphosphine)ethane with metals.

Bis(diphenylphosphine)ethane (DPPE) and its bis[chlorogold(I)] [DPPE(Au2Cl2)], and bis[trichlorogold(III)] [DPPE(Au2Cl6)], complexes have in vivo antitumor activity. To determine if interaction with metals in situ can play a role in the antitumor activity of DPPE, we have studied the effects of DPPE, DPPE(Au2Cl2), DPPE(Au2Cl6) and mixtures of DPPE with metal salts on in vitro and in vivo biological systems. The in vitro cytotoxic potencies of the two DPPE-gold complexes were approximately 10-fold greater than that of DPPE. In addition, the cytotoxic potency of DPPE was increased when incubated with cells in the presence of Au(III) and Cu(II) salts, whereas Mg(II), Zn(II), Mn(II), Fe(II), Co(II), and Cd(II) had no effect. The effects of DPPE, DPPE(Au2Cl2) and mixtures of DPPE and metal salts on the activity of a model enzyme system, DNA polymerase alpha were measured. While DPPE did not inhibit the activity of DNA polymerase alpha, the DPPE(Au2Cl2) complex and mixtures of DPPE and Cu(II) salts inhibited the activity of the enzyme. Consistent with the effects observed in vitro, coadministration of Cu(II) or Au(III) increased the in vivo potency of DPPE in mice bearing i.p. P388 leukemia. Fifteen other DPPE analogues were evaluated for in vivo antitumor activity and for the effect of Cu(II) on their in vitro cytotoxic potency; there was a relationship between the ability of Cu(II) to potentiate the cytotoxic activities of DPPE analogues and their having in vivo antitumor activity.