Influences of dihydrotestosterone, testosterone, estradiol, progesterone, or prolactin on the cell kinetics of human hyperplastic prostatic tissue in organ culture.

In an effort to characterize the hormone sensitivity of human benign prostatic hyperplasia (BPH) maintained in organ cultures for 12-72 h, the influence of 5-alpha-dihydrotestosterone (DHT), testosterone (T), 17-beta-estradiol (E2), progesterone (Pg), or prolactin (PRL) was assessed on the cell proliferation rate of 25 BPH specimens by the use of tritiated thymidine incorporation followed by autoradiography. Significant increases in the thymidine-labeling index (TLI: percentage of labeled nuclei) were observed in glandular tissue after a 36-h incubation period in presence of DHT, E2, Pg, or PRL in 52%, 44%, 28%, and 60% of BPH cases, respectively. Nonparametric statistics (Spearman and Kendall rank correlation tests) have shown that 1) the steroid-induced TLI increases are dependent on the basal rate of cell proliferation, while the PRL-induced effect is independent of it, and 2) all the steroid-mediated effects on BPH TLI are correlated together, whereas they seem to be independent of the PRL-induced TLI increase. When T was compared with DHT on nine BPH specimens, three were found to be sensitive to both hormones, and two responded to DHT only. We propose that our study methods are suitable as a means to assess the hormone sensitivity of individual cases of BPH and possibly prostatic tumors.

Effect of prolactin and estradiol on cell proliferation in the uterus and the MXT mouse mammary neoplasm.

With the use of an in vivo tritiated thymidine [( 3H]dThd) nuclear labeling followed by autoradiography, the effects at different times before sacrifice of prolactin (PRL) and/or 17 beta-estradiol (E2) were studied in C57BL X DBA/2f)F1 mice given transplants of the MXT hormone-sensitive mammary tumor whose growth was previously shown to be influenced by E2 and/or progesterone. Uteri were chosen as controls for the methodology. Experiments were conducted on ovariectomized mice submitted to endocrine manipulation to achieve plasma PRL modifications. In addition to E2, the proliferation of cancer cells, assessed by the measurement of thymidine labeling indices (TLIs), was demonstrated to be enhanced by ovine prolactin (oPRL) and Sulpiride and strongly slowed down by castration and 2-bromo-alpha-ergokryptin treatment, thus emphasizing the great importance of PRL in mammary cancer development. Moreover, a pulse of 1 mg oPRL/animal produced a marked TLI rise in tumors, lasting from the 6th to the 48th hour after its injection and reaching a maximum at 24 hours. PRL had no proliferative effect on the uterine luminal epithelium. When PRL and E2 were injected concomitantly, the profile of stimulation was quite similar to that obtained with E2 alone; i.e., a maximum stimulation was observed at the 24th and 36th hours after hormonal pulse. From these data it is concluded that, in spayed mice, not only E2 but also PRL is of major importance leading to enhanced proliferation of MXT mammary neoplastic cells. Further investigations are needed to throw light on the cellular events presiding over the action of PRL and E2 at the cancer cell level.

Synergism or antagonism between estradiol and progesterone on the cell kinetic parameters of the MXT mouse mammary tumor.

With the use of an in vivo tritiated thymidine ([3H]dThd) nuclear labeling followed by autoradiography, the effects at different times before sacrifice of single or paired injections of 17 beta-estradiol (E2) and/or progesterone (Pg), at different concentrations, were studied in (C57BL x DBA/2f)F1 (B6D2F1) mice transplanted with the MXT hormone-sensitive mammary tumor. Uteri were chosen as controls for the methodology. With regard to MXT tumors, E2 (0.25, 2.50, or 25.00 micrograms/animal) or Pg (125, 600, or 5,000 micrograms/animal) exerts almost a similar mitogenic influence that is dose related to the former and nor for the later, at least within the range of concentrations studied here; and the mitogenic effect of Pg seems to appear earlier than that of E2. When these steroids are concomitantly given, no obvious synergistic or antagonistic effect can be observed. A second E2 administration seems to have a less pronounced effect on cell proliferation as compared to that exerted by the first injection performed 12 or 24 hours earlier. On the contrary, the repetition of a Pg treatment would rather exert an additive or even a synergistic effect on the tumoral dThd labeling indices with regard to the total duration of stimulation. When one of these two steroids is administered first, it blocks totally the mitogenic effect of the second, provided the latter is given 24 hours later. It is concluded that E2 and Pg have almost a similar mitogenic effect on the MXT tumor and that these hormones exert complex interactions that are probably very important for the growth regulation of this cancer. Further investigations are needed to better understand the precise biochemical mechanisms involved in the modulating actions of these steroids on the MXT mammary growth.

Effect of progesterone on cell proliferation in the MXT mouse hormone-sensitive mammary neoplasm.

The transplantable MXT mouse mammary tumor is an experimental model for which the growth is modulated by ovarian hormones; because of scant knowledge about the effects of progesterone (Pg) alone on cancer cells, the present investigation was made. By measuring the percentage of cells with labeled nuclei after tritiated thymidine ([3H]dThd) injection 1 hour prior to sacrifice [dThd labeling index (TLI)], a study was made of the effect (in vivo) of a near physiologic dose of Pg (125 micrograms ip) on cell proliferation in uteri (as the control Pg target organ) and on tumors of spayed (C57BL female X DBA/2F male)F1 mice. Pg induced a significant and transient rise in TLI, which increased from the 12th to the 24th hour after its injection. This mitogenic effect on tumors was comparable to that elicited by 0.25 microgram 17 beta-estradiol injected under similar conditions. In vivo brief exposure of castrated mice to Pg induced a significant mitogenic effect on MXT tumors. These observations might have important consequences for a better understanding of the endocrine mechanisms involved in human hormone-dependent breast cancer.

Effect of castration and 17 beta-estradiol pulse on cell proliferation in the uterus and the MXT mouse mammary tumor.

The effects of a single 17 beta-estradiol (E2) injection on cell proliferation were studied in 3 groups of 30 mice transplanted with the MXT ovary-dependent mammary tumor. In group A, all animals were castrated prior to tumor implantation; groups B and C had intact ovaries at the time of transplantation, but group B was left intact throughout the experiment, while group C underwent castration 4 weeks later. On day 40 in groups B and C and on day 80 in group A, in which tumor development was significantly delayed, the same procedure for testing the effects of E2 was applied: Ten controls received 0.1 ml saline ip and were killed on the next day; 4 lots of 5 mice received 0.25 micrograms E2 ip and were killed one by one at 12-hour intervals. Exactly 1 hour prior to sacrifice, each animal received 25 microCi [methyl-3H]thymidine ip. Histologic sections of tumors and uteri were processed for autoradiography, and nuclear thymidine (dThd) labeling indices (LI) were determined. All tumors of group A grafted under unfavorable hormonal conditions were poorly differentiated, and E2 injection induced no appreciable changes in their dThd LI. Tumors B and C were well-differentiated adenocarcinomas, in which E2 induced significant modifications of cell proliferation. In group B, complex changes in dThd LI occurred in tumors as well as in uteri, probably due to interferences with the ovarian hormonal production. In group C, E2 produced a marked rise in dThd LI in tumors, lasting from the 12th to the 36th hour after its injection. Stimulation was maximum at the 24th hour, representing a 2.8-fold increase over mean basal dThd LI. It is concluded that the presence of an intact ovarian function at the time of transplantation is critical for maintaining the properties of hormone dependence in MXT tumors. In mice castrated after tumor implantation, a single E2 injection induces a marked and partially synchronous proliferation of neoplastic cells. The hypothesis that such hormonal manipulation might amplify the killing effect of cell cycle- or phase-specific cytotoxic drugs could be adequately tested with this model.