Lauri Kangas

A new triphenylethylene compound, Fc-1157a

SummaryThe basic pharmacological and biochemical properties of a new antiestrogen, Fc-1157a, are described. Fc-1157a is bound specifically and with high affinity to estrogen receptors. The binding is competitive with estradiol. Fc-1157a treatment induces translocation of estrogen receptors from cytoplasm to nucleus. The turnover rate of nuclear estrogen receptors is markedly lower than with estradiol, but is more rapid than after tamoxifen.Fc-1157a is an almost pure antiestrogen in rat uterus, but has intrinsic estrogenic activity in mouse uterus. In animal experiments Fc-1157a has shown antitumor properties, which are described in the companion paper.

A phase III comparison of two toremifene doses to tamoxifen in postmenopausal women with advanced breast cancer

Efficacy and safety of toremifene 60 and 240mg daily (TOR60 and TOR240) are compared to40 mg tamoxifen daily (TAM40) in postmenopausal womenwith advanced estrogen receptor (ER) positive or ERunknown breast cancer. The study is randomized andopen label in three parallel groups. Primary efficacyvariables are response rate and time to progression.WHO and ECOG criteria were used for measurableand nonmeasurable disease assessment, respectively. Safety was reportedaccording to WHO criteria. Altogether 463 patients wererandomized (157 to TOR60, 157 to TOR240, and149 to TAM40). By data cut-off, after 20.5months median follow-up time, over 70% of thepatients had experienced disease progression. Response rates are20.4%, 28.7%, and 20.8% in TOR60, TOR240, andTAM40, respectively. TOR60 and TAM40 show statistically equivalentefficacy and the difference between TOR240 and TAM40is not significant (P=0.112). Median timesto progression are 4.9 (TOR60), 6.1 (TOR240), and5.0 (TAM40) months and the corresponding hazard ratios(TAM:TOR) 1.015 and 1.124. Again, TOR60 and TAM40are statistically equivalent and the difference between TOR240and TAM40 is not significant (P=0.374).All treatments were well tolerated. As a conclusion,TOR60 and TAM40 show equivalent clinical efficacy andtolerability. The higher dose of toremifene slightly butnot statistically significantly improves response rate and timeto progression. In postmenopausal women, toremifene 60 mgdaily is an effective and safe treatment ofadvanced ER-positive or ER-unknown breast cancer.

Review of the pharmacological properties of toremifene

New compounds were synthesized with the aim to develop new anti-estrogenic antitumor drugs. The biological properties of the molecules were screened by (1) estrogen receptor (ER) binding, (2) effect on MCF-7 cells, (3) uterotrophic effect and inhibition of estradiol induced uterotropic effect and (4) antitumor effect in DMBA induced rat mammary cancer. One of the molecules, Fc-1157a = toremifene, exhibited the following characteristics: competitive inhibition of [3H]estradiol binding to ER (IC50 = 0.3 mumol/l), inhibition of MCF-7 cell growth in a concentration-dependent manner and cell-killing effect at higher than 3 mumol/l concentrations. Minimal estrogenic dose of toremifene on rat uterus weight was about 40 times higher than that of tamoxifen. Toremifene had statistically significant effect against DMBA-induced rat mammary cancer. Further screening consisted of antitumor, pharmacokinetic and safety studies. Toremifene inhibited the growth of ER-negative, glucocorticoid sensitive, mouse uterine sarcoma in a dose-dependent manner. Pharmacokinetics and metabolism of toremifene resembled closely those of tamoxifen, but since the chlorine atom of the toremifene molecule was not metabolically cleaved tamoxifen and toremifene did not have chemically similar metabolites. Toremifene was well tolerated in animal toxicity studies. No hyperplastic or neoplastic nodules, which were seen in almost all high-dose (48 mg/kg for 24 weeks) tamoxifen-treated rats, were found in toremifene-treated rats (dose 48 mg/kg). In clinical phase I studies in healthy voluntary postmenopausal women, no side effects were reported, at doses less than or equal to 460 mg, neither after a single dose nor after five daily doses. At the dose of 680 mg two out of five persons experienced vertigo and headache. Toremifene, at the dose of 68 mg daily, had antiestrogenic effect on estradiol-induced human vaginal epithelial cells. Clinical phase II studies have confirmed that toremifene has a promising antitumor effect.

Biochemical and pharmacological effects of toremifene metabolites

SummaryToremifene, a new antiestrogenic antitumor compound, has several biologically active metabolites. The hormonal effects of the main metabolites resemble those of unchanged toremifene. The main metabolite in humans,N-demethyltoremifene, is bound to estrogen receptors (ER), inhibits the growth of MCF-7 cells, and exerts an antiestrogenic effect similar to that of toremifene. However, its antitumor effect in vivo against dimethyl-benz(a)anthracene (DMBA)-induced rat mammary cancers is weaker than that of toremifene. Didemethyltoremifene has antiestrogenic actions in mouse and rat uterus at high doses. 4-Hydroxytoremifene is bound to ER with higher affinity and inhibits MCF-7 growth at concentrations lower than those of toremifene. It has a weaker intrinsic estrogenic effect than does toremifene. The efficacy of 4-hydroxytoremifene against DMBA-induced cancers is weak except at very high doses. Oxidations ofN-demethylated metabolites to (deamino)hydroxylated compounds and carboxylic acids are the detoxification routes of toremifene. (deaminohydroxy)Toremifene has only weak hormonal actions at high doses and carboxylated metabolites have no estrogenic/antiestrogenic effects. The antitumor effect of toremifene in vivo is mainly due to unchanged toremifene, but hormonal effects (which may have a role in antitumor actions) are partly attributable to metabolitesN-demethyltoremifene, didemethyl-toremifene, (deaminohydroxy)toremifene, 4-hydroxy-N-demethyltoremifene, and 4-hydroxytoremifene, which have pharmacological properties similar to those of toremifene.

Agonistic and Antagonistic Effects of Antiestrogens in Different Target Organs

Antiestrogens block by definition specifically the actions of estrogens. In the classical uterotropic assay in immature rodents, where estrogens cause fluid retention and cell proliferation, triphenylethylenes have also species-specific estrogen-like (agonistic) effects. 4-hydroxylated triphenylethylenes have in general less estrogenic properties than unhydroxylated ones, and ICI 164,384 has no estrogenic activity in this model. Uterus responds to estrogens by stimulation of cell proliferation. Some other tissues, like breast, liver, and bone respond by regulation of specific protein synthesis. Some of the proteins act as growth factors, and some have unknown functions. The regulation of gene expression is a complex phenomenon: estrogens may turn the responsive gene on or off. Similarly antiestrogens may participate in the gene regulation by mimicking or antagonising estrogen-like actions. This paper summarizes the estrogenic and antiestrogenic effects of classical and new antiestrogens in different tissues.

Expression of type IV collagen α1(IV)–α6(IV) polypeptides in normal and developing human kidney and in renal cell carcinomas and oncocytomas

Type IV collagen trimer is a major component of basement membranes (BMs). It is composed of polypeptides named α1(IV)–α6(IV) chains. Chains α1,2(IV) are widely expressed in BMs while α3(IV)–α6(IV) are more restricted in human tissues. We have now studied by immunohistochemical means the distribution of collagen IV chains in fetal and adult human kidney, in oncocytomas, in renal cell carcinomas (RCCs) and their metastases and in experimental xenografts of human tumors. α1,2(IV) chains were found in all BMs of fetal and adult kidney as well as of renal tumors, while α3(IV)–α6(IV) chains were found in BMs of distal segments of developing and mature tubules. α3(IV)–α5(IV) chains were seen also in BMs of developing fetal glomeruli after the capillary loop stage. Most of the RCCs and their metastases showed occasional expression of α3(IV)–α6(IV) with papillary variants showing only expression of α5(IV) chain. There was a distinct expression of α3(IV)–α5(IV) chains in BMs of 3 oncocytomas. In 2 of them a variable expression of the α6(IV) chain was seen. In 3 of 4 xenografts, immunoreactivity for human‐specific monoclonal antibody (MAb) for α1,2(IV) was seen in the BM‐like structures. No α3–α6(IV) was seen in any of the xenografts, while polyclonal antiserum for type IV collagen presented immunoreactivity in BMs of all xenografts. Our results show that oncocytomas and most of the RCCs express scarce variants of type IV collagen containing α3(IV)–α6(IV) chains. In experimental xenograft tumors, both implanted RCC cells and host stromal cells have a capacity to produce type IV collagen. Int. J. Cancer 72:43–49, 1997.

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.

Metabolism of toremifene in the rat

Toremifene was labelled to a specific activity of about 20 microCi/mmol with tritium at positions 3 and 5 in the para-substituted phenyl ring. At these positions tritium is not eliminated within the metabolic pathways. A mixture of unlabelled and labelled toremifene (5 or 10 mg/kg, 5 microCi/mg) was given i.v. or p.o. to Sprague-Dawley rats. The elimination of radioactivity was followed up by collecting urine and feces daily for 13 days. The elimination of toremifene which was similar after p.o. and i.v. administration took place mainly in the feces. About 70% of the total radioactivity was eliminated within 13 days, of this amount more than 90% in the feces. All applied radioactivity could be detected in three separate fractions according to the oxidative state of the side chain when counted by Berthold TLC Linear Analyzer. Each fraction was further separated into single metabolites by TLC or HPLC. Altogether 9 metabolites were identified and almost all methanol-extractable components were identified. The main metabolic pathways in the rat were 4-hydroxylation and N-demethylation. The side chain was further oxidized to alcohols and carboxylic acids. Small amounts of unchanged toremifene were found in the feces both after p.o. and i.v. administration indicating biliary secretion.

Estrogen and the selective estrogen receptor modulator (SERM) protection against cell death in estrogen receptor alpha and beta expressing U2OS cells

In the current work, we compared the ability of 17beta-estradiol (E2) and the selective estrogen receptor modulators (SERMs), tamoxifen (Tam), raloxifene (Ral) and ospemifene (Osp) to promote the survival of osteoblast-derived cells against etoposide-induced apoptosis. In order to compare the roles of the two estrogen receptor (ER) isotypes, we created a U2OS human osteosarcoma cell line stably expressing either ERalpha (ERalpha) or ERbeta (ERbeta). Transfection with either of the ERs was able to render the U2OS cells sensitive to E2. We show that E2 opposed etoposide-induced apoptosis and that the effect was mediated via both ER isotypes. The ER isotype selective agonists propyl-pyrazole-triol (PPT) and diarylpropionitrile (DPN) had the same effect in U2OS/ERalpha and U2OS/ERbeta cells, respectively. Osp also opposed apoptosis at least in U2OS/ERalpha cells. Tam and Ral were not able to protect against etoposide-induced cell death. In order to evaluate the protective effects of E2 and Osp upon etoposide challenge, we studied the expression of two E2-regulated, osteoblast-produced cytokines, IL-6 and OPG in E2 and SERM-treated U2OS/ERalpha and U2OS/ERbeta cells. Etoposide strongly increased expression of IL-6 and decreased that of OPG. E2 opposed IL-6 increase only in U2OS/ERalpha cells and OPG decrease primarily in ERbeta cells. Osp opposed the effect of etoposide on OPG primarily in U2OS/ERbeta cells but interestingly, it had little effect on IL-6 expression. E2, PPT, DNP and Osp also inhibited etoposide-induced death and cytokine changes in SAOS-2 osteosarcoma cells expressing endogenous ERalpha and ERbeta. Collectively, our results suggest that the osteoblast protective anti-apoptotic effects of E2 are mediated by both ERalpha and ERbeta but those of Osp primarily by ERalpha. In addition, E2 and Osp opposed the etoposide-induced increase of IL-6 and decrease of OPG which changes would increase osteoclastic activity. These anti-resorptive effects of E2 and Osp upon etoposide challenge differed from each other and they seemed to be differentially mediated in ERalpha and ERbeta expressing osteoblast-derived U2OS cells.

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 1 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.