Morphofunctional modifications associated with the inhibition by estradiol of MtTF4 rat pituitary tumor growth.

The MtTF4 pituitary tumor has been induced in Fischer rats by chronic estrogen administration. Recently, we reported that sustained pharmacological treatment of Fischer rats with 17 beta-estradiol inhibited the growth of the MtTF4 tumor transplanted s.c. The present work describes the associated morphofunctional changes occurring in the tumor during 17 beta-estradiol inhibition. It is shown that a 7-day 17 beta-estradiol treatment resulted in an increase of the surface area of cells, nuclei, nucleoli, Golgi complexes, and rough endoplasmic reticulum and an increase in the number of euchromatin-rich nuclei. Flow cytometry analysis of DNA distribution suggested that estradiol affects the cell progression through the early S phase. The ratio of RNA to DNA increased significantly, reflecting cell hypertrophy. Moreover, there was a significant increase in tumor prolactin concentration and a marked enhancement in the intensity of the immunocyto-chemical reaction with rat prolactin antiserum. On the other hand, cell mitoses were dramatically decreased. These morphofunctional changes indicate that the inhibition of the tumor growth by estradiol is accompanied by an evolution of the tumor cell population towards a more differentiated state. However, it cannot be decided whether 17 beta-estradiol induces a shift from a proliferative state to a differentiated state or whether 17 beta-estradiol treatment results in a selection of a subpopulation of tumor cells that are slow growing and more differentiated.

Spontaneous prolactin transplantable tumor in the Wistar/Furth rat (SMtTW): a new animal model of human prolactinoma.

Two spontaneous prolactinomas, removed from 28-mo-old female Wistar/Furth rats, were grafted by serial passages under the kidney capsule and the skin in 117 females of the same consanguineous strain. The hosts, aged between 2 and 10 mo, were free of estrogen treatment. These transplantable tumors, named SMtTW1 and SMtTW2, were studied until the fifth serial passage. The percentage of success was 100% under the kidney capsule and 20% under the skin. From the radioimmunoassays of prolactin (PRL), growth hormone, and adrenocorticotropic hormone and the immunocytochemical results, the tumors secrete PRL only. The PRL tumoral secretion was detected after 3 to 5 mo of graft; at 8 mo, mean plasma PRL values reached 5150 ng/ml (normal value, 15.2 ng/ml). Plasma growth hormone and adrenocorticotropic hormone values remained normal. Like the primary tumors, the grafted tumors were benign, grew slowly, and were sparsely granulated well-differentiated prolactinomas with exocytosis. They remained identical during the first serial passages. The secretion and the growth of SMtTW2 were inhibited by bromocriptine. In the light of our knowledge of the human prolactinoma, the spontaneous transplantable prolactinoma of the rat may be considered to be an animal model closer to the human pathology than the estrogen-induced "tumors" and the induced transplantable tumors. It is easier to use than the spontaneous prolactinoma of the rat.

Estradiol stimulation and inhibition of cell growth in new estrogen-sensitive cell lines and tumors established from the MtTF4 tumor.

Cell lines were established from the MtTF4 tumor, growth of which is inhibited by estradiol, in order to determine whether the effect observed in vivo was due to a direct action on tumor cells. Two different cell lines were obtained according to the medium in which tumor cells were dispersed and cultured. The F4P cells were obtained when the culture medium contained charcoal-treated fetal calf serum. The growth rate of these cells was slowed down by 17 beta-estradiol in animals and also in culture during the early passages. Thereafter, they became insensitive to 17 beta-estradiol in culture but remained negatively controlled in vivo. These cells, whatever their sensitivity to 17 beta-estradiol, secrete prolactin and carry functional D2 dopamine binding sites. The F4Z cells were established in medium containing fetal calf serum not treated with charcoal. The growth rate of these cells was stimulated by 17 beta-estradiol in animals but was 17 beta-estradiol insensitive in culture up to subculture 26. At this time, the growth rate of the subline also became stimulated by 17 beta-estradiol in culture, and this phenotype was still found at passage 108 (50% effective dose, 5 to 10 pmol; maximum stimulation, 180 to 300% of control). These cells neither secrete measurable amounts of prolactin nor have dopamine binding sites. Thus, according to the medium in which cells were dispersed and cultured, two different cell strains were derived from a tumor in which growth is inhibited by 17 beta-estradiol. The point of interest is that the growth rate of one strain was inhibited by 17 beta-estradiol, while the other was stimulated. Convergent data suggest that MtTF4 tumor was heterogeneous and that selection had occurred during the dispersion or the culture of cells. Since the growth of one of these cell lines was slowed down transiently in culture we conclude that the inhibition of tumor growth could be due to a direct action of 17 beta-estradiol on tumor cells. However, the dissociation between the response to 17 beta-estradiol in culture and in the animal observed at some time of cell evolution suggests that environment affects the sensitivity of cells to 17 beta-estradiol.

Antiestrogens prevent the stimulatory effects of L-triiodothyronine on cell proliferation.

This paper studies the modulatory effects of two antiestrogens, the steroid ICI 164 384 and the nonsteroidal compound 4-hydroxytamoxifen (4-OH-tam), on the proliferation of L-T3-stimulated cell lines. Three cell lines known to be stimulated by thyroid hormones and to contain estrogen receptors but to have a different estradiol sensitivity to estradiol were used; F4Z2 and MCF-7 cells were stimulated, whereas GH3 cells were insensitive. Cells were counted 6-7 days after hormones and antihormones were added to the culture medium, separately or in association (a fixed hormone concentration and increasing antihormone concentrations and vice versa). In F4Z2 and MCF-7 cells, antiestrogens prevented noncompetitively the stimulatory effect of L-T3 and, as expected, competitively the stimulatory effect of estradiol. In GH3 cells, antiestrogens had proper inhibitory effects, but they did not prevent significantly the proliferative effect of L-T3. To investigate the mechanisms of the modulatory effects in F4Z2 cells we examined the consequences of antiestrogens on thyroid hormone receptors (nuclear binding of L-T3 and mRNAs of thyroid hormone receptors, i.e. c-erbA alpha and -beta) and insulin-like growth factor-I (IGF-I; secretion and mRNAs). Antiestrogens neither competed with L-[125I]T3 nor reproducibly decreased the number and affinity of thyroid hormone-binding sites. While 4-OH-tam frequently decreased the amount of c-erbA beta transcripts, ICI 164 384 did not alter the distribution of alpha and beta cDNA transcripts. Further, neither antiestrogen prevented the increases in IGF-I accumulation in conditioned medium and IGF-I mRNA concentrations induced by L-T3 (0.1 nM). In conclusion, 1) antiestrogens are potent noncompetitive inhibitors of the action of L-T3 on the proliferation of cells whose growth is responsive to estradiol (F4Z2 and MCF-7), but not of the action on a cell line whose growth is insensitive to estradiol (GH3). 2) The loss of L-T3 sensitivity is not due to a loss of thyroid receptors or a decrease in IGF-I production. 3) In addition to estrogen receptors, factors involved in the estradiol control of cell proliferation appear to be required for the antiestrogen inhibition of L-T3 action.

Multihormonal control of cell proliferation: opposite effects of two stimulators (17 beta-estradiol and L-triiodothyronine) and one inhibitor (dexamethasone) on F4Z2 pituitary tumor cells.

From the MtTF4 tumor of rat pituitary origin we established the F4Z2 cell line whose growth is stimulated by 17 beta-estradiol (E2). Taking E2 actions as references we investigated actions of other effectors on the proliferation, protein, and insulin growth factor-I (IGF-I) secretions of F4F2 cells. Dexamethasone (Dex) and L-T3 were chosen because they have also intracellular receptors and they act in pituitary cells. Cells were cultured in 96-well plates in RPMI 1640 medium supplemented either with charcoal-treated fetal calf serum (CT-FCS) or with BSA and transferrin. Hormones were added at the time of seeding and cells were counted 2-10 days later without renewing the culture medium. The accumulation of immunoreactive IGF-I in conditioned medium was used as an index of IGF-I secretion. For studies on protein secretion, cells were incubated for 24 h with [35S]methionine and labeled proteins were separated by polyacrylamide gel electrophoresis. We found that: 1) L-T3, like E2, stimulated in a dose-dependent and specific manner the proliferation of F4Z2 cells cultured in the presence of 5% CT-FCS; EC50 was: 1 X 10(-11) M and 0.2 X 10(-11) M for L-T3 and E2, respectively. In contrast, L-T3 but not E2 remained active in serum-free medium; 2) Dex was a strong inhibitor of cell proliferation in serum-free medium and in medium supplemented with 5% CT-FCS (EC50: 5 X 10(-9) M). The antiglucocorticoid RU 38 486 prevented this inhibitory effect; 3) when a stimulator (E2 or L-T3) was simultaneously incubated with the inhibitor (Dex) the number of cells depended on the ratio of hormone concentrations. When there was no large excess of one effector this number was intermediary between those counted in the presence of each hormone separately and L-T3 was more potent than E2 in preventing Dex inhibition; 4) Dex, E2, and L-T3 modified the electrophoretic patterns of secreted proteins but there was no evidence for a correlation between these modifications and the inhibition or the stimulation of cell proliferation, and 5) the accumulation of immunoreactive IGF-I was insensitive to E2, increased by L-T3, and markedly decreased by Dex. L-T3 but not E2 prevented the effect of Dex.(ABSTRACT TRUNCATED AT 400 WORDS)

The control by estradiol of pituitary tumor and cell growth is not correlated with that of kallikrein gene expression.

From an MtTF4 pituitary tumor we established new cell lines and tumors whose growth is sensitive (stimulation or inhibition) or insensitive to estradiol (Cancer Res., 1991, 50, 3786-3794). The main objective of the present work was to determine whether such a diversity of responses is correlated with the estradiol control of kallikrein gene expression. From kallikrein mRNA analyses and from kallikrein activity assays in conditioned medium it appears highly probable that the diversity of responses to estradiol of pituitary tumors and cell growth is not due to a differential regulation of kallikrein gene expression. In addition, prolactin gene expression and estrogen receptor mRNA have been studied to further characterize this experimental model.

Flow cytometry analysis of cells dispersed from the MtTF4 tumor whose growth is inhibited by estradiol treatment.

The aim of this work was to determine whether treatments of rats with estradiol (E) in conditions known to decrease the proliferation rate, the mitotic index and the thymidine incorporation into the DNA of the MtTF4 tumor act at a specific point in the cell cycle. Two weeks after grafting a piece of tumor under the kidney capsule, adult male Fischer rats were treated or not treated with E. Tumors were collected between 12 h and 11 days later. Cells were dispersed by collagenase-DNAse treatment and fixed with ethanol. DNA content, cell size, cell granularity and protein content were analyzed, alone or in combination with a flow cytometer. E treatments did not apparently modify the distribution of cells according to their DNA content whereas they did increase dramatically cell size, cell granularity and cell protein content. Simultaneous analysis of DNA content and light scattering or protein content allowed us to demonstrate that there was an increase of a population of large granular and protein-rich cells regardless of the phase of the division cycle considered. These effects are time-dependent, dose-dependent and hormone-specific. This work shows both the interest of flow cytometry to describe the consequences of E treatment at any phase of the cycle of cells dispersed from a solid tumor and the limits of this method in the conditions used to specify the E target points: at the present time, it cannot be decided whether E acts at one or several points of the cell cycle for inhibiting tumor growth.

Control of the proliferation of prostate cancer cells by an androgen and two antiandrogens. Cell specific sets of responses.

The responses, in terms of cell proliferation and c-myc messenger RNA content, of human prostate cancer cells to androgen-receptor ligands were investigated. Experiments were performed with three types of cells (LNCaP, R2 and MOP) and three compounds (the androgen R 1881 and two anti-androgens: cyproterone acetate, CYPA, and RU 56187). MOP cells were established in the laboratory and the effects of RU 56187 had not been studied in culture. In terms of proliferation, LNCaP was stimulated by the three compounds, R2 was inhibited by R 1881 and RU 56187 but was stimulated by CYPA while MOP was inhibited by the three compounds. In the three types of cells, c-myc messenger RNAs were down regulated by R 1881 and RU 56187 but not by CYPA. The conclusions are: (1) the sets of responses of cell proliferation to three androgen-receptor ligands are cell specific; (2) the control of c-myc messenger RNA by R 1881 and RU 56187 may be related to the inhibition of cell proliferation by these compounds but not to their stimulatory effect on cell proliferation; (3) if prostate tumor cells would respond in vivo to androgens and antiandrogens like in culture, patients with prostate cancer could take benefits of reversible medical castration and sequential prescription of various antiandrogens.

Interference between estradiol and L-triiodothyronine in the control of the proliferation of a pituitary tumor cell line.

We showed that the proliferation of F4Z2 cells, established from a rat pituitary tumor, was stimulated by L-triiodothyronine (LT3) in the presence of 3 or 0.1% charcoal treated-fetal calf serum (CT-FCS), and by estradiol (E2) in the presence of 3% CT-FCS only (Cancer Res., 50, 1990, 3786). Here we report on the consequences of the simultaneous addition of these hormones. In the presence of 0.1% CT-FCS, E2, and with a lower potency, estrone and estriol inhibited dose-dependently stimulation by LT3. The results were more complex with 3% CT-FCS: the LT3 effect was blunted by E2 > 0.1 nM (and vice versa) and the hormone effects were additive at lower concentrations. E2, at concentrations antagonistic to the effects of LT3, decreased LT3 binding and LT3 receptor mRNA without modifying the effect of LT3 on these mRNAs. In addition, E2 blocked both the LT3-induced increases of insulin-like growth factor-I (IGF-I) secretion and IGF-I mRNA concentration, and the LT3-induced decrease of IGF-binding proteins in conditioned culture medium. We propose that E2 prevents LT3 stimulation of F4Z2 cell proliferation by blunting the LT3-induced accumulation of unbound IGF-I in the culture medium.

Possible involvement of transforming growth factor-beta in the inhibition of rat pituitary tumor growth by estradiol.

We have shown that growth of F4Z2 cells and F4Z2 tumors was stimulated by estradiol, that of MtTF4 and F4P tumors was inhibited and that of F4P cells remained insensitive. In the present work we explore the possible role of transforming growth factor-beta (TGF-beta) as a mediator of estradiol action in these pituitary tumors and cell lines. In vivo, estradiol treatment increased the concentration of TGF-beta 1 mRNAs in tumors whose growth was inhibited by estradiol (MtTF4 and F4P) but not in tumors whose growth was stimulated (F4Z2). F4Z2 and F4P cell lines also contained TGF-beta 1 transcripts. These cells and tumors differed by two points: the level of TGF-beta 1 transcript was higher in F4Z2 than in F4P cells while the opposite situation was observed in vivo and the concentration of TGF-beta 1 mRNA in cultured cells was insensitive to estradiol (1 or 100 x 10(-9) M). Moreover, the secretion of TGF-beta like activity assayed by two different methods was estradiol insensitive and the growth of both cell lines was dose-dependently inhibited by TGF-beta 1 (ED50:2 x 10(-11) M). Since estradiol increases TGF-beta 1 mRNA in the tumors MtTF4 and F4P whose growth is inhibited by estradiol and that TGF-beta 1 inhibits the proliferation of F4P cells it is proposed as a working hypothesis that TGF-beta 1 is one of the mediators of the inhibitory effect of estradiol in pituitary tumors. No data favor the hypothesis that estradiol stimulates pituitary tumor proliferation by decreasing TGF-beta production.