In vitro cytotoxicity of imidazolyl-1,3,5-triazine derivatives.

We examined in vitro cytotoxic activity of imidazolyl-1,3,5-triazine derivatives using human breast cancer cell lines (MCF-7, R-27, T-47D and ZR-75-1) and murine leukemia cell line (P388). The percentage of viable cells was determined by the 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazorium bromide (MTT) assay. Hexamethylmelamine (HMM), a 1,3,5-triazine derivative has previously been recognized as an antitumor agent effective against lung, ovarian and breast cancer, but failed to show a significant cytotoxic activity in the present study. In contrast, four imidazolyl-1,3,5-triazine derivatives, 2-(1-imidazolyl)-4,6-bis(morpholino)-1,3,5-triazine, 2-(1-imidazolyl)-4-morpholino-6-(3-thiazolidinyl)-1,3,5-triazine, 2-(4-cyano-4-phenylpiperidino)-4-(1-imidazolyl)-6-morpholino-1,3,5-triaz ine and 2-(1-imidazolyl)-4-(N-methyl-N-phenylamino)-6-morpholino-1,3,5-triazine showed cytotoxic activity for most cell lines, which was significantly greater than the activity of hydroxymethylpentamethylmelamine (HMPMM), a major metabolite of HMM.

Antitumor activity of hexamethylmelamine on human tumor xenografts serially transplanted in nude mice.

The antitumor activity of hexamethylmelamine (HMM) was evaluated using four human tumor xenografts serially transplanted in nude mice. HMM was dissolved in 0.2 ml of 1% hydroxypropyl cellulose per mouse and administered perorally daily, except on Sunday, for 4 weeks, giving an estimated maximum tolerated dose (MTD) of HMM of 75 mg/kg. The MX-1 cell line showed dose-dependent sensitivity to HMM and was completely eradicated by treatment at the MTD. The minimum effective dose of HMM against MX-1 was calculated to be 22.1 mg HMM/kg, resulting in the chemotherapeutic index of 3.4. The demethylated derivatives of HMM, pentamethylmelamine and tetramethylmelamine, were also effective against MX-1, whereas trimethylmelamine was ineffective. The effect of HMM was more marked when the drug was administered on day 1 after tumor inoculation, compared with administration during the exponential growth phase. HMM is thought to be a promising agent for the treatment of several types of human carcinoma, producing active metabolites in vivo after peroral administration.

Prodrugs of hydroxymethylpentamethylmelamine: a principal active metabolite of the antineoplastic agent hexamethylmelamine.

Hexamethylmelamine is in clinical use as an antineoplastic agent. Derivatives and prodrugs of two of its biologically-active metabolites were prepared in an effort to alter its solubility and to enhance bioavailability. In this study prodrugs of pentamethylmelamine and hydroxymethylpentamethylmelamine were synthesized. Among the compounds prepared were N-(methoxymethyl)pentamethylmelamine, N-(ethylthiomethyl)pentamethylmelamine, and several N'-alkyl-N'-methyl-N-(aminomethyl)pentamethylmelamine and N'-aryl-N'-methyl-N-(aminomethyl)pentamethylmelamine derivatives. The aqueous solubility of these prodrugs relative to hexamethylmelamine was compared. The half-lives of these prodrugs were also determined at pH 7.4. The more stable derivatives were assayed at pH 6.4. These prodrugs represent a novel approach for the delivery of the suspect active metabolite of hexamethylmelamine, hydroxymethylpentamethylmelamine.

A newly developed hexamethylmelamine derivative, SAE9 with both antitumor and aromatase-inhibitory activity.

Hexamethylmelamine (HMM) has previously been shown to be active against ovarian, breast and small cell lung cancer. However HMM dose not have aromatase-inhibitory activity. A newly developed HMM derivative, 2-N,N-dimethylamino-4, 6-bis (1-H-imidazol-1-yl)-1,3,5-triazine (SAE9), was found to have direct antitumor activity as well as aromatase-inhibitory activity. The direct antitumor activity on breast carcinoma cell lines (MCF-7, R-27 and MDA-MB-231) was assessed using the 3-(4,5-dimethylthiazol-2yl)-2, 5-diphenyl tetrazolium bromide (MTT) on cells growing in monolayer culture. The 50% inhibitory concentrations (IC50) of SAE9 were found to be approximately 10(-4) M for each cell line, roughly equivalent to those of HMM. When the aromatase-inhibitory effect was assessed using a human placental aromatase-inhibitory assay, the IC50 of SAE9 was 5.5 x 10(-7) M, which was superior to that of aminoglutethimide (AG) (3.8 x 10(-5) M). In a rat uterine growth model treated with androstenedione as the in vivo aromatase inhibition assay, SAE9 had an effect equivalent to that of AG. Since SAE9 has both antitumor and aromatase-inhibitory activity on breast carcinoma cell lines with estrogen dependency, this and similar non-steroidal aromatase inhibitors are thought to be promising for further study.

In vitro cytotoxicity of hexamethylmelamine (HMM) and its derivatives.

The cytotoxicity of hexamethylmelamine (HMM) and its metabolites was investigated in three murine cell lines: one in vitro naturally sensitive to HMM (RC) and two in vivo naturally resistant (P388 and P388D1). The percentage of viable cells was determined both by the in situ reduction of a tetrazolium salt (MTT assay) and by the uptake of labelled thymidine into DNA (3HTdR assay). Short (1h) and long (48h) exposures of cells to drugs were considered. In all experimental conditions used, HMM was found to be inactive, whereas its hydroxylated metabolite hydroxymethylpentamethylmelamine (HMPMM) and one analog N, N 'dihydroxymethyltetramethylmelamine (DHTMM) were found to be cytotoxic. The results further indicated that HMM must be metabolized before it can exert its cytotoxic effect. The activity of HMPMM and DHTMM was found unlikely to be related to extracellular or intracellular release of formaldehyde.

Changes in serum copper and zinc during treatment with anticancer drugs interfering with pyridoxal phosphate.

Hexamethylmelamine, pentamethylmelamine and procarbazine are anticancer drugs known to interfere with pyridoxal phosphate. This paper presents results on copper and zinc serum levels during the treatment with each of these drugs used as single agents. Six NZW rabbits weighing 2.7-4.5 kg were used in these experiments. Hexamethylmelamine and procarbazine were administered by gastric gavage and pentamethylmelamine by intravenous route at the daily doses of 100 mg, 30 mg and 50 mg/kg of body weight respectively for up to four days. Blood samples were collected in metal free tubes at fasting state before and during the treatment. Student's paired t-test was used for statistical analysis. The pretreatment serum copper concentration significantly (p = 0.05) increased and conversely the serum zinc concentration significantly (p = 0.05) decreased during each drug treatment. Consequently the copper/zinc ration significantly increased from 0.32, 0.33 and 0.27 to 1.16, 0.63 and 1.13 for hexamethylmelamine, pentamethylmelamine and procarbazine respectively. These results indicate, that daily administration of three anticancer drugs interfering with pyridoxal phosphate causes changes in serum copper and zinc levels with inversed relationship between both changes.

The geometry of N-hydroxymethyl compounds. Part 2: Crystal structures of 1-(4-carbethoxyphenyl)-3-hydroxymethyl-3-methyltriazene, N-hydroxymethylpentamethylmelamine and N-hydroxymethylbenzamide.

Of the three N-hydroxymethyl compounds in the title, the first two have pronounced antineoplastic activity while the latter is biologically inactive. Crystals of the triazene have monoclinic symmetry with a = 8.540(1), b = 6.346(4), c = 22.460(5)A, beta = 98.75(2) degrees, and space group P21/c. The melamine forms disordered crystals of orthorhombic symmetry with a = 11.957(3), b = 17.267(3), c = 5.769(3)A. Of the symmetry elements in the observed space group Pnma, a mirror plane bisects the average molecule, implying that the hydroxymethyl group has equal probability of lying either side of this plane. Crystals of the benzamide show orthorhombic symmetry with a = 10.045(6), b = 7.763(3), c = 19.409(8)A, and space group Pbca. All three compounds are intermediates along biochemical demethylation pathways. The observed N-CH2OH distances, which are 1.469(5), 1.452(4), and 1.438(4)A respectively for the three compounds, correlate with the stability of this bond as measured by half-life. It is suggested that the correct degree of lability is important for biological activity, short strong bonds being too unreactive and excessively long ones being too unstable.

Pharmacokinetics and metabolism of hexamethylmelamine in mice bearing renal cell tumors.

The pharmacokinetics of hexamethylmelamine (HMM) and its main metabolites hydroxymethylpentamethylmelamine (HMPMM), pentamethylmelamine (PMM), and 2,2,4,6, tetramethylmelamine (2,2,4,6 TetrMM) were studied in renal cell (RC) tumor tissues and plasma of CDF1 mice that had received IP bolus injections of the maximally tolerated dose (200 mg/kg) of HMM. HMM, PMM, and 2,2,4,6 TetrMM concentrations determined in RC tissues were much higher than the plasma values, as indicated by the pharmacokinetic parameters (Cmax and AUC). On the other hand, very low levels of HMPMM, generally considered to be a potentially active antitumor compound, were detected in the target tissues, whereas this hydroxylated metabolite was stable and easily determined in plasma. High HMM concentrations in RC tissues could correlate with the high sensitivity of the tumor to this drug. However, the behavior of HMPMM remains unclear; related hypotheses are presented in this paper.

Low central nervous system penetration of N2,N4,N6,-trihydroxymethyl-N2,N4,N6,-trimethylmelamine (Trimelamol): a cytotoxic s-triazine with reduced neurotoxicity.

Trimelamol (N2,N4,N6-trihydroxymethyl-N2,N4,N6-trimethylmelamine) is an analogue of pentamethylmelamine (PMM). In early clinical trials PMM failed to show significant anti-tumour activity in man which was attributed to poor metabolic activation. Trimelamol does not require activation and is therefore expected to be more active in man. PMM caused dose-limiting emesis and sedation whereas Trimelamol is much less neurotoxic in rodents. The relative penetration of PMM and Trimelamol into mouse brain has therefore been examined. Mice receiving PMM at 90 mg kg-1 i.p. were found to have high concentrations of the drug in the CNS compared to plasma (mean brain/plasma ratio 1.04) whereas animals receiving Trimelamol had consistently low CNS concentrations (mean brain/plasma ratio 0.08). This difference did not correlate with plasma protein binding which is greater for PMM (68.2%) than for Trimelamol (17.5%). However, it does appear to be related to lipophilicity. In Phase I clinical trial Trimelamol has proved much less emetic than PMM and causes no acute sedation. It is likely that this reduction in toxicity may be explained by the relatively poor ability of Trimelamol to enter the CNS.

Pentamethylmelamine: review of an aqueous analog of hexamethylmelamine.

The s-triazine derivatives have shown preclinical antitumor activity against several histologic types. The most widely used compound of this class in the clinic, hexamethylmelamine, has been largely restricted to oral use because of its low solubility and lack of stability in solutions suitable for parenteral administration. New analogs were sought which were soluble and stable and retained antitumor activity. Pentamethylmelamine (PMM), the monodemethylated derivative, showed these promising characteristics. Preclinical toxicology studies of PMM in mice, dogs, and monkeys showed toxic manifestations that involved the hematopoietic, lymphatic, renal, male reproductive, gastrointestinal, and nervous systems; these changes were both infusion-rate- and dose-dependent. Clinical phase I trials of PMM were performed using a variety of infusion durations and frequency schedules. The dose-limiting toxic effect common to all of these trials was protracted nausea and vomiting. In addition, some studies reported dose-limiting central nervous system manifestations in the form of agitation, drowsiness, somnolence, and even coma. Mild to moderate hematologic changes were noted. Because of the severity and frequency of the gastrointestinal and central nervous system toxic effects observed in the completed trials, no new clinical trials of PMM sponsored by the National Cancer Institute are planned. However, the interest in finding a clinically useful parenteral triazine continues.

Preclinical toxicology, pharmacokinetics and formulation of N2,N4,N6-trihydroxymethyl-N2,N4,N6-trimethylmelamine (trimelamol), a water-soluble cytotoxic s-triazine which does not require metabolic activation.

N2,N4,N6-Trihydroxymethyl-N2,N4,N6-trimethylmelamine (Trimelamol) is a water-soluble synthetic s-triazine which, unlike hexamethylmelamine (HMM) and pentamethylmelamine (PMM), does not require metabolic activation. The physico-chemical characteristics of Trimelamol were studied with the aim of overcoming the problems of chemical instability, low solubility and polymerisation which had hindered the development of the drug for clinical use. Trimelamol had similar activity to PMM against the murine PC6 plasmacytoma, but enhanced activity with respect to PMM against the Walker 256 carcinosarcoma in the rat, a species which metabolizes PMM less efficiently. Pharmacokinetic studies in mouse, rat and man did not show the major species differences characteristic of PMM. The drug exhibited similar toxicity to PMM against rodents, but had virtually no neurotoxicity. The potential advantages of Trimelamol over previously tested melamines are discussed.

Pharmacokinetics and metabolism of hexamethylmelamine in mice after IP administration.

The pharmacokinetics of hexamethylmelamine (HMM) and its first metabolite (hydroxymethylpentamethylmelamine: HMPMM) following IP bolus dose of 200 mg/kg were studied in mice. The drug concentrations were determined by a sensitive reversed-phase HPLC assay. Thus, for the first time, HMM major hydroxylated and demethylated metabolite plasma levels canbedetermined at the same time. Pharmacokinetic data were analyzed by an original method using a nonlinear cost function minimized by a simplex algorithm. An important property of this computer program is that convergence is ensured in contrast to linear or nonlinear least-square regression analysis, which leads to lack of convergence or to false convergence. Both HMM and HMPMM data fit a one-compartment open model. The parameters obtained indicate that the parent drug would probably be rapidly and completely transformed by the human body into HMPMM.

Absorption and metabolism of hexamethylmelamine and pentamethylmelamine in rat everted perfused gut segments: correlation with in-vivo data.

The intestinal oxidative metabolism of hexamethylmelamine (HMM) and pentamethylmelamine (PMM) has been studied in microsomes, isolated mucosal cells and intestinal perfused segments. (sub) Cellular systems revealed an almost equal Km (53-65 microM) and Vmax (5.6-7.0 nmol min-1 g-1 intestine) for both compounds. Detailed studies in everted intestinal perfused segments, showed that HMM is metabolized to a far greater extent than PMM (e.g. 11-times, at 80 microM substrate concentration) while PMM transport was 3 times greater than the transport of unchanged HMM. Only when perfused segments were used as an in-vitro tool was a good correlation observed between the in-vivo and in-vitro rate of intestinal metabolism of HMM and PMM. It is concluded that this is due to preservation of structural integrity of the mucosa for both absorptive and metabolic processes.

First-pass metabolism of pentamethylmelamine in the rat liver.

The disposition of pentamethylmelamine (PMM) was studied in the male Wistar rat. PMM (5 mg/kg) was administered intraarterially, i.v. (5 and 10 mg/kg), via the portal vein, and into the duodenum to cannulated and unanesthetized rats (n greater than or equal to 4) via infusion. Parent compound and metabolites were quantified by gas chromatography. The areas under the plasma concentration-time curves of PMM after intraarterial and i.v. administration were equal and twice as large as the areas after portal vein and intraduodenal administration. This indicated insignificant lung metabolism for PMM; the low bioavailability of PMM when given via the portal vein or intraduodenally (in both cases, some 50% of an i.v. dose) was the result of presystemic metabolism in the liver. PMM was completely absorbed after intraduodenal administration, and no intestinal metabolism was observed. Linear kinetic behavior of i.v. PMM was observed in the 5- to 10-mg/kg dose range. The area under the plasma concentration-time curve of the first metabolite N2,N2,N4,N6-tetramethylmelamine was significantly greater when PMM was given via the portal vein or intraduodenally than when given intraarterially or i.v. This indicated either extrahepatic elimination/renal excretion of PMM or the existence of an additional metabolic pathway. However, experiments with adrenalectomized rats and rats with ligated blood flow to the kidneys did not alter the area for the first metabolite. These findings may be explained by the formation of unknown metabolites and/or reactive intermediates of PMM.

The area under the curve of metabolites for drugs and metabolites cleared by the liver and extrahepatic organs. Its dependence on the administration route of precursor drug.

The venous equilibrium model (or well-stirred model) is used to determine the area under the blood concentration vs. time curve of a metabolite formed from a precursor drug. It will be shown that the AUC of a metabolite will change according to the route of precursor drug administration(whether intraarterially, intravenously, via the portal vein, or orally) when the drug and/or metabolite is eliminated by more than one organ. Elimination includes hepatic and extrahepatic metabolism and renal excretion. The validity of the model is probed by using literature data for drug and metabolite areas. Finally, the use of metabolite areas for evaluating the complete/incomplete absorption or orally administered precursor drug is discussed.

Central side effects of pentamethylmelamine: biochemical and behavioural studies.

The central side effects of pentamethylmelamine (PMM), an antitumoral agent, were studied on brain neurotransmitters from the biochemical and behavioural points of view. PMM causes a dose-related reduction in the body temperature and motility of mice. 100 mg/kg of PMM lowers the levels of noradrenaline (NA) and raises 3-methoxy-4-hydroxyphenylethyleneglycol (MHPG) in the telencephalon. A similar dose increased striatal levels of dopamine (DA) metabolites, homovanillic acid (HVA) and dihydroxyphenylacetic acid (DOPAC), at earlier times (30 min), reducing their levels at 2 hr. These effects disappear at longer times (4 hr). No changes were observed in the levels of 3-methoxytyramine (3-MT), the extraneuronal metabolite of DA. The serotonin metabolite 5-hydroxyindolacetic acid (5HIAA) was almost not affected. PMM and its metabolites do not displace [3H]-spiroperidol from mouse striatal binding sites. These data show that some of the neurological effects induced by PMM are associated with changes in the metabolism and/or release of brain catecholamines but are not mediated by direct action on DA receptors.

Biochemical studies on the ability of pentamethylmelamine to interact in vivo with DNA and proteins in a sensitive murine ovarian reticular cell sarcoma.

The metabolism of 14C-PMM and its irreversible interaction with DNA and proteins were studied in M5076/73A reticular cell sarcoma, a murine solid tumor previously shown to be sensitive to the drug. Metabolism and irreversible binding were determined 0.25, 1, 8 and 104 hours after a single i.p. injection of radiolabelled PMM, tumor and liver macromolecular binding were compared with two differently 14C-labelled PMM, i.e. ring- and methyl-PMM. Ring-PMM derived macromolecular binding appeared to have more relevance in vivo and had a similar time profile in both liver and tumor. Ring-PMM derived DNA binding was then related to metabolic steps between PMM and 2,2,4,6 TMM and 2,2,4,6 TMM itself and 2,4,6 TriMM.

The chemosensitivity of a new experimental model--the M5076 reticulum cell sarcoma.

The M5076 reticulum cell sarcoma is a murine tumour of potential value in experimental chemotherapy. Experiments were conducted to ascertain the growth characteristics and chemosensitivity of this neoplasm in the BDF1 mouse. The intramuscular tumour proved to be responsive to the alkylating agents, nitrosoureas, procarbazine, DTIC and treosulphan, yet insensitive to the antimetabolites and only weakly responsive to adriamycin. Analogues of the antitumour agents hexamethylmelamine and N-methylformamide were tested against this neoplasm. The patterns of activity determined for these analogues against this tumour were identical to those previously reported against other model systems.