Evaluation of the genotoxicity of tamoxifen in the liver and kidney of F344 gpt delta transgenic rat in 3-week and 13-week repeated dose studies.

Transgenic rat gene mutation assays can be used to assess genotoxicity of chemicals in target organs for carcinogenicity. Mutations in transgenes are genetically neutral and accumulate during a treatment period; thus, the assays are suitable for assessment of the genotoxicity risk of chemicals using a repeated-dose treatment paradigm. However, few such studies have been conducted. To examine the utility of the transgenic rat assays in repeated-dose studies, we treated female F344 gpt delta rats with tamoxifen (TAM) at 20 and 40mg/kg, or toremifene (TOR) at 40mg/kg by gavage daily for 3 weeks. We also fed gpt delta rats with TAM at either 250ppm (15.4-17.6mg/kg) or 500ppm (30.0-32.9mg/kg) for 13 weeks. TAM is carcinogenic in the rat liver and TOR is not carcinogenic. TAM administration significantly increased gpt (point mutations) and Spi(-) (deletions) mutant frequencies (MFs) in the liver, the target organ of carcinogenesis; MFs were higher after treatment for 13 weeks than after treatment for 3 weeks. The MFs in the kidney did not increase in any of the TAM treatment groups. TOR had no effect on MFs (gpt and Spi(-)) in either the liver or the kidney. We conclude that the gpt delta rat assay in the repeated-dose treatment paradigm is sensitive enough to detect gene mutations induced by TAM in the target organ for carcinogenesis. Furthermore, the assay can be integrated into a 13-week dose-finding study for a 2-year cancer bioassay.

DNA damage and altered gene expression of enzymes for metabolism and DNA repair by tamoxifen and toremifene in the female rat liver.

Effects of hepatocarcinogenic TAM and non-hepatocarcinogenic TOR on the formation of hepatic DNA adducts and on the gene expression of hepatic drug-metabolizing enzymes and DNA repair enzymes/proteins were comparatively examined in female Sprague-Dawley rats treated with TAM (20 or 40 mg/kg/day, i.g.) or TOR (40 mg/kg/day, i.g.) for 1, 2 or 8 weeks. Hepatic TAM-DNA adducts were formed even after 1 week of treatment with TAM at either dose, and the adduct levels increased in a dose- and treatment period-dependent manner, whereas no DNA adducts were detected in any of the TOR-treated rats. Conversely, TAM and TOR showed almost the same capacity for increasing the gene expression of drug-metabolizing enzymes responsible for metabolic activation and detoxification, at least up to the 2-week treatment mark. Accordingly, differences in DNA adduct formation between TAM- and TOR-treated rats would not be primarily dependent on the capacity for inducing hepatic drug-metabolizing enzymes. In addition, a drastic increase in the gene expression of cytochrome P4503A2 (CYP3A2), an activation enzyme of TAM, by the 8-week treatment with TAM might have contributed to the increased formation of DNA adducts. Gene expressions of DNA repair enzymes/proteins responsible for a nucleotide excision repair system were not significantly changed in any of the rats treated with either drug. The present findings suggest that the difference between TAM and TOR in hepatocarcinogenic potency is dependent on the capacity to form DNA adducts rather than modulating the expression of drug-metabolizing enzymes and DNA repair enzymes/proteins.

Histopathology and histomorphometry of the urogenital tract in 15-month old male and female rats treated neonatally with SERMs and estrogens.

In this study, two selective estrogen receptor modulators (SERMs), tamoxifen (TAM) and toremifene (TOR) or two estrogens, ethinylestradiol (EE) and diethylstilbestrol (DES) were administered to newborn male and female Sprague-Dawley rats (days 1-5) to investigate the occurrence of developmental abnormalities in the adulthood. The compounds were dosed (s.c.) at an equimolar dose of 24.9 micromol/kg. During the follow-up period, mortality occurred mainly in DES-treated male rats (3/4), associated with obstructive urinary calculi and suppurative renal inflammation in 2/3 rats. Similar lesions were not evident in other groups. At the age of 15 months, the animals were necropsied and organs were collected for histopathology and histomorphometry. Treatment-related abnormalities were restricted to the reproductive organs. Chronic prostatitis and epithelial abnormalities in the vas deferens were observed in all treatment groups. The columnar epithelium of vas deferens showed hyperplasia and development of subepithelial glandular structures resembling epididymal cysts reported in humans exposed in utero to DES. Testicular atrophy was observed especially in estrogen-treated rats. Mainly in SERM-treated female rats, the uterus showed luminal dilation or obstruction, loss of endometrial glands and myometrium disorganization including foci of muscular disruption. TOR-treated female rats showed polyp-like nodules (incidence 4/15) and a high incidence (9/15) of a simple cuboidal epithelium in cervical regions normally occupied by multilayered epithelia. In conclusion, the vas deferens is a main target organ following neonatal administration of SERMs and estrogens. In addition, female rats were significantly more susceptible to SERM treatment than to treatment with estrogens.

Absence of DNA adduct in the leukocytes from breast cancer patients treated with toremifene.

Tamoxifen (TAM) causes cancer in rat liver and human endometrium, whereas the carcinogenicity of its chlorinated analogue toremifene (TOR) has not been observed. To elucidate the genotoxicity of TOR, the capability of forming DNA adducts by TOR was examined in the leukocytes of patients treated with TOR. Leukocytes were collected from 27 breast cancer patients (57.7 +/- 11.4 years old) taking TOR (40 mg/day for 25 patients, 80 mg/day for one patient, and 120 mg/day for one patient; average duration, approximately 12 months) and 20 untreated breast cancer patients (58.2 +/- 12.3 years old). The DNA extracted was analyzed by (32)P-postlabeling/high-performance liquid chromatography. No DNA adducts were detected in the leukocytes of either TOR-treated or nontreated patients. Our results contrast to the previous observation detecting TAM-DNA adducts in several patients treated with TAM, indicating that TOR is less genotoxic to humans.

Toxicity of selected cationic drugs in retinoblastomal cultures and in cocultures of retinoblastomal and retinal pigment epithelial cell lines.

Tamoxifen and toremifene are antiestrogenic drugs successfully used in the therapy of breast cancer. Rheumatoid arthritis and malaria have been treated with chloroquine for decades. Unfortunately, tamoxifen and chloroquine are reported to induce retinal changes as a side effect. We now studied the effects of tamoxifen, toremifene, and chloroquine on the viability of the human retinoblastomal cell line Y79, using the WST-1 test or measurement of the cellular ATP content. The studies were made on Y79 cell cultures and on cocultures of Y79 cells and retinal pigment epithelial cell line ARPE-19. The cocultures were used to clarify the effect of retinal pigment epithelium on toxicity to Y79 cells. In the coculture, the drugs were applied to ARPE-19 cells growing in the culture inserts on top of Y79 cells and the viability of ARPE-19 and Y79 cells was assessed separately. Tamoxifen, toremifene, and chloroquine reduced dose-dependently the viability of Y79 cells after 24-h exposure. The ARPE-19 cells proved to be protective after chloroquine exposure in the coculture. The results shed light on the toxicity of tamoxifen and chloroquine in Y79 cells in vitro. With the coculture we were able to simulate the in vivo route of chloroquine to the retina via the retinal pigment epithelium.

Toxicity of antiestrogens.

The object of this article is to review briefly the preclinical and clinical safety of some antiestrogens. Tamoxifen, toremifene, droloxifene, and idoxifene are polyphenylethylene antiestrogens, whereas the pure antiestrogen, ICI 182,780 or faslodex, as well as raloxifene, is of a different structure. Tamoxifen has been shown to be genotoxic in several studies. It induces unscheduled DNA synthesis in rat hepatocytes and micronuclei in MCL-5 a cells in vitro. Tamoxifen also induces aneuploidy in rat liver in vivo and chromosome aberrations and micronuclei in mouse bone marrow. Toremifene has also shown to be genotoxic, but to a far lower extent, by inducing micronuclei in MCL-5 a cells in vitro and by inducing aneuploidy in rat liver in vivo. Tamoxifen has been shown to be hepatocarcinogenic in the rat in at least four independent long-term studies. The initiation of tumors in the rat is the result of metabolic activation by cytochrome P450 isoenzymes to an electrophile(s) that binds irreversibly to DNA. The other antiestrogens have not been shown to be carcinogenic in rodents. In several independent clinical studies, the risk of endometrial cancer has increased among tamoxifen-treated women. After reviewing the available data, the International Agency for Research on Cancer concluded that there was sufficient evidence to show that tamoxifen is a class I human carcinogen. The increased risk for endometrial cancer occurs predominantly among women who are 50 years old or older and who have been treated with tamoxifen. It is not yet clear whether the uterine tumor formation is a result of genetic mechanisms, analogous to those seen in the rat liver or due to the estrogen agonist action of tamoxifen. However, the other antiestrogens with a more or less similar intrinsic estrogenic potential have not been shown to be carcinogenic in humans.

Synthesis and reactivity of potential toxic metabolites of tamoxifen analogues: droloxifene and toremifene o-quinones.

Tamoxifen remains the endocrine therapy of choice in the treatment of all stages of hormone-dependent breast cancer. However, tamoxifen has been shown to increase the risk of endometrial cancer which has stimulated research for new effective antiestrogens, such as droloxifene and toremifene. In this study, the potential for these compounds to cause cytotoxic effects was investigated. One potential cytotoxic mechanism could involve metabolism of droloxifene and toremifene to catechols, followed by oxidation to reactive o-quinones. Another cytotoxic pathway could involve the oxidation of 4-hydroxytoremifene to an electrophilic quinone methide. Comparison of the amounts of GSH conjugates formed from 4-hydroxytamoxifen, droloxifene, and 4-hydroxytoremifene suggested that 4-hydroxytoremifene is more effective at formation of a quinone methide. However, all three substrates formed similar amounts of o-quinones. Both the tamoxifen-o-quinone and toremifene-o-quinone reacted with deoxynucleosides to give corresponding adducts. However, the toremifene-o-quinone was shown to be considerably more reactive than the tamoxifen-o-quinone in terms of both kinetic data as well as the yield and type of deoxynucleoside adducts formed. Since thymidine formed the most abundant adducts with the toremifene-o-quinone, sufficient material was obtained for characterization by (1)H NMR, COSY-NMR, DEPT-NMR, and tandem mass spectrometry. Cytotoxicity studies with tamoxifen, droloxifene, 4-hydroxytamoxifen, 4-hydroxytoremifene, and their catechol metabolites were carried out in the human breast cancer cell lines S30 and MDA-MB-231. All of the metabolites tested showed cytotoxic effects that were similar to the parent antiestrogens which suggests that o-quinone formation from tamoxifen, droloxifene, and 4-hydroxytoremifene is unlikely to contribute to their cytotoxicity. However, the fact that the o-quinones formed adducts with deoxynucleosides in vitro implies that the o-quinone pathway might contribute to the genotoxicity of the antiestrogens in vivo.

Delayed effects of tamoxifen in hepatocarcinogenesis-resistant Fischer 344 rats as compared with susceptible strains.

The anti-oestrogenic drug tamoxifen has been under investigation as a breast cancer chemopreventive agent for at least a decade. However, its use for this purpose is still debatable since it is able to induce liver tumours in rats via a mechanism involving metabolic activation to a DNA adduct-forming electrophilic intermediate. The metabolic activation and adduct-forming properties of tamoxifen are now well characterized but less is known about its ability to induce hepatic cell proliferation, which is also essential for the carcinogenic process. The effects of tamoxifen on liver weight and cell proliferation were compared in female Fischer 344 (F344), Wistar and Lewis rats given the drug in the diet for up to 26 weeks. The onset and duration of hepatic cell proliferation varied between the strains of rat. In Wistar and Lewis but not F344 rats there was a marked increase in hepatocellular proliferation during the first 4 weeks of tamoxifen administration. In the Wistar strain this was associated with an increase in DNA adduct levels; no such increase was observed in the F344 strain. The onset of the proliferative response was delayed until the 13 week time point in the F344 strain. By the 13 and 26 week time points, cell proliferation in tamoxifen-treated Wistar and Lewis rat liver had returned to normal, but the amount of apoptotic activity in these livers was elevated. This suggests that excess cells generated during the proliferative phase of tamoxifen treatment were being eliminated by apoptosis. In the F344 strain, however, increased proliferative activity was associated with relatively low apoptotic activity at the 26 week time point, suggesting that the delayed proliferative response had yet to be balanced by apoptotic deletion. This is consistent with the fact that tamoxifen-induced hepatocellular tumours develop very late, towards the end of the lifespan, in this strain. The cell proliferative activity of tamoxifen in the Wistar rat liver was compared with that of a non-mutagenic analogue, toremifene. Tamoxifen induced increased cell cycle activity in the livers of rats following gavage dosing at all sampling times (1-12 weeks), whereas toremifene had no effect on the incidence of cycling in hepatic cells, demonstrating that the hepatic cell proliferation is not a general response to anti-oestrogen treatment. These observations suggest that the rate of promotion of liver tumours by tamoxifen is a function of the rate, time of onset and duration of increased cell replication. The susceptibility of rat strains to the hepatocarcinogenic effects of tamoxifen appears to depend upon the balance between initiation via DNA adduct formation, promotion via increased cell proliferation and cell deletion via apoptosis. Our findings suggest that an early proliferative response to tamoxifen is important in this process.

Mechanism of lower genotoxicity of toremifene compared with tamoxifen.

An increased incidence of endometrial cancer has been reported in breast cancer patients taking tamoxifen (TAM) and in healthy women participating in the TAM chemoprevention trials. Because TAM-DNA adducts are mutagenic and detected in the endometrium of women treated with TAM, TAM adducts are suspected to initiate the development of endometrial cancer. Treatment with TAM has been known to promote hepatocarcinoma in rats, but toremifene (TOR), a chlorinated TAM analogue, did not. TAM adducts are primarily formed via sulfonation of the alpha-hydroxylated TAM metabolites. To explore the mechanism of the lower genotoxicity of TOR, the formation of DNA adducts induced by TOR metabolites was measured using (32)P-postlabeling/ high-performance liquid chromatography analysis and compared with that of TAM metabolites. When alpha-hydroxytoremifene was incubated with DNA, 3'-phosphoadenosine 5'-phosphosulfate, and either rat or human hydroxysteroid sulfotransferase, the formation of DNA adducts was two orders of magnitude lower than that of alpha-hydroxytamoxifen. alpha-hydroxytoremifene was a poor substrate for rat and human hydroxysteroid sulfotransferases. In addition, the reactivity of alpha-acetoxytoremifene, a model activated form of TOR, with DNA was much lower than that of alpha-acetoxytamoxifen. Thus, TOR is likely to have lower genotoxicity than TAM. TOR may be a safer alternative by avoiding the development of endometrial cancer.

Comparison of the effects of tamoxifen and toremifene on rat hepatocarcinogenesis.

The hepatoproliferative and cytochrome P450 enzyme inducing effects of two antiestrogens, tamoxifen and toremifene, were compared in female Sprague-Dawley rats using immunohistochemical staining methods. Equimolar doses of the antiestrogens (tamoxifen 45 mg/kg and toremifene 48 mg/kg) were given by oral administration to 6-week-old rats for 12 months including a 3-month recovery period. Controls received the vehicle carboxymethylcellulose. Altogether 90 rats were used in the study. Five rats per dose group were killed after 14 days, 5 weeks, 3, 6 and 12 months of treatment as well as after the 3-month recovery period. Hepatocellular carcinoma was found in four out of five rats after 12 months of tamoxifen treatment. After the 3-month recovery period all tamoxifen-treated rats had large liver tumors (diameter up to 3 cm). No tumors were observed in toremifene-treated rats. Liver cell proliferation was measured by the index of proliferating cell nuclear antigen (PCNA) expression. Immunohistochemical staining with the placental form of glutathione S-transferase (GST-P) was used as a marker for preneoplastic foci. Cytochrome P450 induction was measured using specific antibodies to isoenzymes. Tamoxifen increased the incidence of GST-P-positive foci significantly by 3 months of treatment but toremifene did not as compared with the controls. Liver cell proliferation increased significantly only in the liver tumors of tamoxifen-treated rats after 12 months of treatment and during the recovery period. Both antiestrogens induced the isoenzymes CYP2B1/2 and CYP3A1 within 14 days although tamoxifen was a more powerful inducer. Immunohistochemistry of rat liver sections showed a centrilobular localization of these induced enzyme proteins. The expression of CYP2B1/2 and 3A1 could also be observed in foci after 3 and 6 months of administration and in liver adenomas and in some carcinomas after 12 months of administration with tamoxifen. The results show that tamoxifen, but not toremifene, has the potential to induce and promote the development of rat hepatocarcinogenesis in this experimental model.

Genotoxic effects of the novel mixed antiestrogen FC-1271a in comparison to tamoxifen and toremifene.

Tamoxifen has been used for the treatment of breast cancer since the 1970s, but is considered a carcinogen because it has been linked to liver cancer in rats and an increased risk of endometrial cancer in patients. In rats, DNA adducts appear to be responsible for carcinogenesis, but their contribution to carcinogenesis in humans is not clear. FC-1271a and toremifene are mixed antiestrogens similar to tamoxifen. In order to compare the genotoxicity of these different triphenylethylenes, we treated mice for 28 days with 50 mg/kg of either tamoxifen, toremifene, FC- 1271 a or vehicle control. DNA from liver and uterus was assayed by standard 32P-postlabeling and thin layer chromatography for the presence of DNA adducts. Two methods of drug administration (oral and subcutaneous) and two strains of mice were compared and the plasma and tissue concentrations of the drugs and three metabolites of tamoxifen and toremifene were determined. Regardless of the conditions, only tamoxifen-treated mice showed DNA adducts in the liver. Adduct levels did not correlate with drug or metabolite levels and adducts were present even when drug was not detectable. Mice were also treated orally with either 50, 100, or 200 mg/kg of drug for 7 days. Again, adducts were found only in liver tissue of mice treated with tamoxifen, and adduct levels were dose-dependent. In conclusion, the chlorinated triphenylethylene FC-1271a did not cause DNA adducts under various conditions in mice, suggesting a low carcinogenic potential.

The proliferation in uterine compartments of intact rats of two different strains exposed to high doses of tamoxifen or toremifene.

Uterine Cell proliferation was studied in intact Sprague-Dawley (SD) and Fischer 344 (F344) rats exposed to the antiestrogens tamoxifen (TAM; 5, 10, 20, or 40 mg/kg) and toremifene (TOR: 21.2 or 42.4 mg/kg). The antiestrogens were administered to animals via gavage daily for 2 or 12 wk. Uterine proliferation was assessed using markers for the proliferating cell nuclear antigen (PCNA) and by the bromodeoxyuridine (BrdU) method. Diethylstilbestrol (DES) was used as an estrogenic reference compound. The antiestrogens either reduced or prevented changes of myometrial and stromal proliferation indices (PI). TAM and TOR caused a time-dependent reduction of endometrial glands without an associated decrease in cell proliferation. In the luminal columnar epithelium, the antiestrogens depressed PCNA PI but enhanced BrdU PI, indicating a low continuous DNA synthesis in otherwise quiescent cells. The antiestrogens induced focal hyperplastic multilayered epithelia with PCNA-positive basal cells along segments of the luminal uterine epithelium. We suggest that this hyperplastic epithelium represents remnants from the glandular epithelium. DES was less efficient in inducing these changes but induced squamous metaplasias in the F344 rats. Uterine effects of the 2 antiestrogens were comparable with the exception of I TAM-exposed (40 mg/kg) SD rat that showed squamous metaplasia. F344 rats were more sensitive to the estrogenic action of DES than were the SD rats.

Genotoxicity studies with the antiestrogen toremifene.

Toremifene, a second-generation triphenylethylene antiestrogen used clinically in the chemotherapy of breast cancer and some other cancers, differs in its nonclinical toxicology from its first-generation congener tamoxifen. Tamoxifen produces DNA adducts and tumors in rat liver, whereas assays for DNA adduct formation with toremifene have been negative to weakly positive, and toremifene does not produce liver tumors in rats. To evaluate further toremifene for possible genotoxicity, it was tested in three standard, in vitro assay--reversion of bacterial point mutations, unscheduled DNA synthesis in cultured hepatocytes from two rat strains, and cytogenetics of human lymphocytes in primary culture--and in one in vivo assay, the mouse, erythrocyte micronucleus assay. The three in vitro assays were conducted with toremifene at up to the limit of cytotoxicity (100 to 250 micrograms/ml, depending on the system). The bacterial mutagenicity and lymphocyte chromosome aberration assays were performed both in the presence and absence of metabolic activation by Araclor-induced, rat liver S-9, while the hepatocyte unscheduled DNA synthesis assay provides intrinsic bioactivation. To test for chromosome damage in vivo, mice were administered up to 2g/kg toremifene once by gavage, and bone marrow was harvested daily, for three days. Normochromatic and polychromatic bone marrow erythrocytes were examined for micronuclei. Toremifene lacked genotoxicity or myelotoxicity detectable by any of the above assays. These findings, together with the reported absence of DNA binding in rat liver, provide evidence that toremifene is not genotoxic.

Effect of chronic administration of mestranol, tamoxifen, and toremifene on hepatic ploidy in rats.

The nonsteroidal antiestrogen tamoxifen increases the incidence of rat liver cancer through a variety of mechanisms. To compare the effects of tamoxifen (TAM) and a structurally similar analog toremifene (TOR) on rat liver, we determined the ploidy distribution for hepatocytes isolated from rats treated for 18 months with these antiestrogens or the estrogenic compound mestranol (MS). Female Sprague-Dawley rats were subjected to a 70% partial hepatectomy and administered the solvent, trioctanoin, or diethylnitrosamine (10 mg DEN/kg). After a 2-week recovery from the surgery, the rats were administered a basal diet or one containing TAM (250 or 500 ppm), TOR (250, 500, or 750 ppm), or MS (0.2 ppm) for 18 months. Pathologic changes in the liver were examined in the 15-22 rats per treatment group at the 18-month time point. An increased incidence of hepatocellular carcinomas (HCC) was detected in the 500 ppm TAM group, but not with the other treatments that did not include DEN. Both TOR and TAM promoted formation of DEN-initiated HCCs. At sacrifice, four to five rats per group were perfused and the hepatocytes isolated and cultured. Karyotypic analysis was performed on colcemid-blocked cells after 2 days in culture. The hepatic ploidy distribution was characterized in Giemsa-stained metaphase spreads. These studies indicated that chronic treatment with TAM alone resulted in a shift from tetraploid to diploid, as was also observed for rats treated once with DEN. TOR and MS alone did not cause this change in hepatic ploidy at the doses examined. A shift toward an increased content of diploid hepatocytes occurred in all rats treated once with DEN followed by TAM, TOR, or MS. These results indicate that tamoxifen administration results in a shift toward growth of diploid hepatocytes, thus contributing to its carcinogenic action in the rat liver.

Initiating activity of the anti-estrogen tamoxifen, but not toremifene in rat liver.

A striking difference between two structurally related anti-estrogen medicines is that tamoxifen is strongly hepatocarcinogenic in the rat, whereas toremifene lacks such activity. To study the basis for this difference, the initiating potential of tamoxifen and toremifene were studied by measurement of rapid induction of hepatocellular altered foci (HAF) that express placental-type glutathione S-transferase in the livers of female Sprague-Dawley (S-D) rats and female Fischer 344 (F344) rats. Both agents were administered by gavage at equimolar doses up to a dose that produced marked weight gain suppression. In rats given the high dose of 40 mg/kg per day tamoxifen continuously for 36 weeks, 75% of S-D rats developed liver neoplasms, in contrast to only 10% of F344 rats. In the S-D strain, tamoxifen produced a tendency to increased HAF at 2 weeks at the dose of 40 mg/kg per day and by 12 weeks, a dose-related increase was evident. In contrast, toremifene induced no HAF even at the equimolar high dose of 42.4 mg/kg per day for 12 weeks. The induction of HAF by tamoxifen was less in the F344 rats. Neither agent elicited increases in hepatocellular proliferation in S-D or F344 rats. When phenobarbital was administered for 24 weeks as a promoting agent after the anti-estrogens, S-D rats given tamoxifen at 20 mg/kg per day for 12 weeks, developed liver neoplasms, but not F344 rats or rats of either strain given even a higher dose (42.4 mg/kg) of toremifene. Thus, tamoxifen has initiating activity in these rat strains whereas toremifene does not.

Clastogenic and aneugenic effects of tamoxifen and some of its analogues in hepatocytes from dosed rats and in human lymphoblastoid cells transfected with human P450 cDNAs (MCL-5 cells).

Tamoxifen and its analogues 4-hydroxytamoxifen, toremifene, 4-hydroxytoremifene, clomifene and droloxifene were tested for clastogenic effects in a human lymphoblastoid cell line (MCL-5) expressing elevated native CYP1A1 and containing transfected CYP1A2, CYP2A6, CYP2E1 and CYP3A4 and epoxide hydrolase and in a cell line containing only the viral vector (Ho1). MCL-5 or Ho1 cells were incubated with 4-hydroxytamoxifen, 4-hydroxytoremifene, clomifene or droloxifene and the incidence of micronuclei estimated. With MCL-5 cells there was an increase in micronuclei with 4-hydroxytamoxifen, 4-hydroxytoremifene and clomifene but not with droloxifene. With Ho1 cells only 4-hydroxytamoxifen and 4-hydroxytoremifene caused an increase in micronuclei. MCL-5 cells were incubated with tamoxifen, 4-hydroxytamoxifen, toremifene, droloxifene, clomifene or diethylstilbestrol (0.25-10 microg/ml) for 48 h and subjected to 3 h treatment with vinblastine (0.25 microg/ml) to arrest cells in metaphase. The incidence of cells with chromosomal numerical aberrations (aneuploidy) was increased in cells treated with tamoxifen, 4-hydroxytamoxifen, toremifene, clomifene and diethylstilbestrol but not droloxifene. The frequency of cells with structural abnormalities (excluding gaps) was increased in cells treated with tamoxifen and toremifene but not 4-hydroxytamoxifen, clomifene, droloxifene or diethylstilbestrol. The clastogenic activities of tamoxifen (35 mg/kg), toremifene (36.3 mg/kg), droloxifene (35.2 mg/kg) and diethylstilbestrol (25 mg/kg) were compared in groups of four female Wistar rats. Each chemical was dissolved in glycerol formal, administered as a single dose by gavage and hepatocytes isolated by collagenase perfusion 24 h later. The cells were cultured in the presence of epidermal growth factor (40 ng/ml) for 48 h, colchicine (10 microg/ml) being added for the final 3 h of incubation. At least 100 chromosomal spreads were examined from each animal for the presence of numerical and structural abnormalities. The incidences of aneuploidy following treatment were: tamoxifen 81%, toremifene 46%, droloxifene 9.6%, diethylstilbestrol 45.7%, vehicle control 5.3%. The incidences of chromosomal structural abnormalities excluding gaps were: tamoxifen 4.3%, toremifene 0.8%, droloxifene 0.5%, diethylstilbestrol 0.8%, control 0.5%. The incidence of chromosomal structural aberrations excluding gaps in the treated animals was not statistically significantly different from controls except in the tamoxifen-treated group. Tamoxifen (35 mg/kg per os) and toremifene (36.3 mg/kg per os) were dosed to rats for 4 weeks and chromosomal spreads made from hepatocytes. The incidences of aneuploidy were: tamoxifen 94%, toremifene 57%, control 6.5%. The incidences of chromosomal aberrations excluding gaps were: tamoxifen 12%, toremifene 1%, control 0.5%. The incidence of tamoxifen-induced chromosomal structural abnormalities was significantly elevated compared with control levels. The results demonstrate that tamoxifen and toremifene are the only two drugs tested in the study that cause chromosomal structural and numerical aberrations in vitro and tamoxifen is the only drug that induces both these effects in rat liver cells stimulated to divide in culture following oral dosing. Since chromosomal mutations require cell division for their manifestation and tamoxifen is the only compound of those tested that causes hyperplasia in the rat liver, chromosomal aberrations and aneuploidy in the rat liver would only be expected to occur following treatment with tamoxifen alone, although aneuploidy could be induced by toremifene in conjunction with a promoter such as phenobarbitone.

17beta-estradiol, diethylstilbestrol, tamoxifen, toremifene and ICI 164,384 induce morphological transformation and aneuploidy in cultured Syrian hamster embryo cells.

To examine the ability of estrogens and anti-estrogens to induce cellular transformation and genetic effects, Syrian hamster embryo (SHE) cells were treated with estrogens, 17beta-estradiol (E2) or diethylstilbestrol (DES), or with anti-estrogens, tamoxifen (TAM), toremifene (TOR) or ICI 164,384. Treatment with each substance for 1-3 days suppressed cellular growth in a dose-dependent manner. Colony-forming efficiency (CFE) increased following treatment of cells with E2 or DES for 48 hr at 3 or 10 microM but decreased at 20 or 30 microM. In contrast, CFE was increased by treatment with TAM, TOR or ICI 164,348 over the concentration range examined (1-30 microM). Treatment with each chemical at 1-30 microM for 48 hr caused morphological transformation of SHE cells in a dose-related fashion. The highest frequency was exhibited in SHE cells treated with DES at 20 microM and was 2 times higher than that induced by treatment with benzo[alpha]pyrene (B[alpha]P) at 4 microM. Transformation frequencies induced by other substances (E2, TAM, TOR and ICI 164,348) did not exceed that induced by the B[alpha]P treatment. TOR showed a higher transforming ability over all concentrations examined when compared to the other anti-estrogens (TAM and ICI 164,348). No significant increases in the frequencies of chromosomal aberrations were observed in SHE cells that were treated with any of the chemicals. However, treatment of SHE cells with each chemical induced a dose-dependent increase of aneuploid cells in the near diploid range. Our results indicate that the ability of the estrogens and anti-estrogens to induce numerical chromosomal abnormality may be involved in their cell transformation activity and potential carcinogenicity.

A two-year dietary carcinogenicity study of the antiestrogen toremifene in Sprague-Dawley rats.

The carcinogenic potential of the nonsteroidal triphenylethylene antiestrogen toremifene (Fareston) was evaluated in a standard 104-week rat dietary carcinogenicity study. The doses were 0, 0.12, 1.2, 5.0 and 12 mg/kg/day and the number of animals 50/sex/dose group. The body weight gain and food consumption were monitored once weekly (study weeks 1-16) or once every four weeks thereafter (study weeks 17-104). Blood samples were taken at weeks 34, 52 and 104 and the plasma concentrations of toremifene, as well as the two main metabolites (deaminohydroxy)toremifene and N-demethyltoremifene, were measured. All doses of toremifene reduced food intake and body weight gain. Toremifene caused a significant reduction in mortality, which was mainly due to reduced incidences of pituitary tumors. This was evident in all dose groups. Drug-related decrease of mammary tumors in females (at all doses) and testicular tumors in male rats (doses > or = 1.2 mg/kg/day) were also evident. The incidence of the preneoplastic foci of basophilic hepatocytes were significantly decreased in treated female groups. Toremifene induced no preneoplastic or neoplastic lesions. Based on histopathology, no obvious toxicity could be observed. Drug-related changes were observed in the genital organs, thyroid, spleen, mammary gland, adrenal, kidney, stomach and lung. These changes were due to hormonal disturbances or as a result of reduced food consumption or reduced incidences of pituitary, mammary or testicular tumors. This study indicates that toremifene is an efficient antiestrogen in long-term treatment, is well tolerated and has no tumorigenic potential in rats.

Induction of hepatic aneuploidy in vivo by tamoxifen, toremifene and idoxifene in female Sprague-Dawley rats.

Since tamoxifen is efficacious for the prevention of second primary breast neoplasms in humans and has a low reported incidence of acute side effects, several structurally related compounds have been developed for the treatment of breast cancer including toremifene and idoxifene. We have compared the karyotypic alterations that occur after a single per os administration of 35 mg/kg of tamoxifen, toremifene or idoxifene to female Sprague-Dawley rats. One day following treatment, the rats were sacrificed and the hepatocytes isolated and cultured. After 47 h in culture, colcemid was added for 3 h prior to harvest of the hepatocytes for karyotypic evaluation. At least 100 metaphase spreads were examined for each of five rats per treatment. Toremifene resulted in aneuploidy in 50 +/- 7% of the cells examined and idoxifene induced a 57 +/- 4% aneuploidy compared with the 85 +/- 7% level induced by tamoxifen. Since the level of aneuploidy in solvent-treated rats was 3 +/- 3 %, the induction of aneuploidy in at least 50% of the cells from rats treated with tamoxifen, toremifene or idoxifene was highly significant. Analysis of electron micrographs of cultures treated with these antiestrogens demonstrated a range of phenotypes including multipolar spindles in toremifene-treated rats and condensed chromosomes in the presence of an intact nuclear envelope in occasional idoxifene-treated rat hepatocytes. The exclusion of chromosomes from the spindle apparatus and the lagging of some chromosomes on the metaphase plate correlate with the high rate of induction of aneuploidy in the rat liver as determined by karyotypic analysis of hepatocytes from rats treated with these triphenylethylenes.