Antiovulatory doses of antagonists of LH-RH inhibit LH and progesterone but not FSH and estradiol release

Structure-activity study on the LH- and FSH-releasing and anticancer effects of gonadotropin-releasing hormone (GnRH)-III analogs

GnRH-III was reported to have selective FSH-releasing activity in rats and significant anticancer potency on human breast cancer cells. To improve either of these effects, 14 analogs were synthesized and investigated for FSH/LH stimulation and breast cancer inhibition. Analogs with single amino acid changes in positions 5-7 or 10 showed small or no difference in the FSH- or LH-releasing activity compared with GnRH-III but their anticancer potency decreased significantly. Modification of the terminal amino acids, side chain cyclization at the 6-8 regions, or combined amino acid changes at positions 4, 6 and/or 8 resulted in the decrease of both effects. Gonadotropin-releasing activity of Arg(8)-GnRH-III was improved 3-11-fold. A copolymer conjugate of GnRH-III showed 2-3-fold anticancer activity while losing endocrine potency.

CONCLUSION

The activation of GnRH-receptors on pituitary and breast cancer cells requires a specific structure and/or conformation that makes possible to improve the anticancer selectivity of GnRH analogs.

Evidence that lamprey GnRH-III does not release FSH selectively in cattle

Experiments were performed to test the hypothesis that lamprey GnRH-III (lGnRH-III) selectively releases FSH. Primary cultures of bovine adenohypophyseal cells were treated with mammalian GnRH (mGnRH) and lGnRH-III (10−9, 10−8, 10−7 and 10−6 M) or control media in Experiment 1. All doses of mGnRH and the two highest doses of lGnRH-III stimulated (P < 0.001) a non-selective release of LH and FSH. In Experiments 2–4, Latin Square designs were utilized in vivo to examine whether physiological and hormonal milieu regulate putative selective effects of lGnRH-III. In Experiments 2 and 3, ovariectomized cows with basal levels of estradiol only (Experiment 2) or in combination with luteal phase levels of progester-one (Experiment 3) were injected with mGnRH and lGnRH-III (0.055, 0.11, 0.165 and 1.1 μg/kg body weight (BW) and saline. All doses of mGnRH released (P < 0.001) LH and FSH, but only the highest dose of lGnRH-III stimulated (P < 0.001) a non-selective release of both LH and FSH (Experiment 3). For Experiments 4A and 4B, intact, mid-luteal phase cows were injected with mGnRH and lGnRH-III (1.1 μg/kg BW; Experiment 4A), lGnRH-III (1.1 and 4.4 μg/kg BW; Experiment 4B) and saline. As before, mGnRH released (P < 0.001) both LH and FSH at all doses. In contrast, lGnRH-III at the highest dose released (P < 0.001) LH but not FSH. These findings suggest that lGnRH-III may act as a weak competitor for the mGnRH receptor and do not support the hypothesis that it selectively releases FSH in cattle.

Effectiveness of an antagonist to gonadotrophin releasing hormone on the FSH and LH response to GnRH in perifused equine pituitary cells, and in seasonally acyclic mares

We wish to use a gonadotrophin-releasing hormone (GnRH) antagonist in the mare as a tool for investigating the control of the oestrous cycle. The aim of this study was to test the effectiveness of the antagonist cetrorelix by testing both in vitro, using perifused equine anterior pituitary cells, and in vivo in seasonally acyclic mares. Pituitary cells were prepared and after 3-4 days incubation, loaded onto columns and given four pulses of GnRH (at 0, 30, 60 and 90 min; dose-response study). After the second GnRH pulse, infusion of cetrorelix began (0, 100, 1000 and 2000 pmol/l) and continued until the end of the experiment. To mimic luteal phase conditions, cells were pre-incubated and perifused with progesterone (25 nmol/l) and GnRH pulses given at 0, 90, 180 and 270 min. Cetrorelix (0 or 1000 pmol/l) began after the second GnRH pulse. Follicle stimulating hormone (FSH) and luteinizing hormone (LH) concentrations were measured in 5 min fractions. Both FSH and LH response areas (above baseline) after GnRH were inhibited by 1000 pmol/l cetrorelix (P < 0.01, P < 0.01, respectively) but not by 100 pmol/l cetrorelix. Similarly, in the presence of progesterone, cetrorelix inhibited the FSH (P < 0.001) and LH (P = 0.0002) response area. Seasonally acyclic mares, pre-treated for 3 days with progesterone (150 mg i.m. per day) were given cetrorelix as (i) a loading dose of 1 microg/kg then infusion at 2.2 ng/(kg min) for 90 min, (ii) a s.c. injection at 20 microg/kg, (iii) infusion at 2.2 ng/(kg min) for 48 h, and (iv) no cetrorelix (control mares). At 90 min, 6, 24 and 48 h after cetrorelix was first administered, mares were given a bolus injection of GnRH (22.2 ng/kg i.v.) and the FSH and LH responses measured. All doses of cetrorelix inhibited the FSH response at 90 min. The response was no longer suppressed at 6 h in the 90 min infusion group, showing a rapid recovery from inhibition. At 24 h, the FSH responses in the injected and 48 h infusion group were suppressed. The LH concentrations were low and showed no significant changes. This study has defined the time course and dose of cetrorelix with respect to its effect on FSH in the horse. It is concluded that cetrorelix could be used to elucidate the role of FSH in follicular development in cyclic mares.

Lamprey gonadotropin hormone-releasing hormone-III has no selective follicle-stimulating hormone-releasing effect in rats

Lamprey gonadotropin releasing-hormone (LGnRH)-III, a hypothalamic neurohormone recently isolated from sea lamprey, was reported to have a selective stimulatory effect on follicle-stimulating hormone (FSH) release in rats and suggested to be the mammalian FSH-releasing factor. In this study, we determined the relative luteinizing hormone (LH)- and FSH-releasing potency of LGnRH-III compared to mammalian gonadotropin-releasing hormone (LHRH) in normal female rats, ovariectomized (OVX) and oestrogen/progesterone substituted rats and the superfused rat-pituitary cell system. The specificity of LGnRH-III for the mammalian LHRH receptor was investigated by blocking the receptor with an LHRH antagonist, MI-1544. In vitro, LGnRH-III dose-dependently stimulated both LH and FSH secretion from rat pituitary cells at 10(-7) to 10(-5) M concentrations, while LHRH stimulated gonadotropin secretion at a 1000-fold lower doses (10(-10) to 10(-8) M). The difference between its LH- and FSH-releasing potency was similar to that of LHRH. LGnRH-III bound to high affinity binding sites on rat pituitary cells with a Kd of 6.7 nM, B(max)=113 +/- 27 fmol/mg protein. In vivo, LGnRH-III also stimulated both LH and FSH secretion in a dose-dependent manner and, similar to LHRH, induced a greater rise in the serum LH than the FSH level. In normal cycling rats, it showed 180-650-fold weaker potency than LHRH in stimulating LH secretion and 70-80-fold weaker effect in stimulating FSH secretion. In OVX rats, LGnRH-III demonstrated a similarly weak effect on both gonadotropins. It was found to be 40-210-fold less potent than LHRH regarding LH release and 50-160-fold weaker regarding FSH release. LHRH-receptor antagonist MI-1544 prevented both the LH- and the FSH-releasing effect of LGnRH-III both in vitro and in vivo. These results do not support the hypothesis that LGnRH-III might be the mammalian FSH-releasing factor but demonstrate that it is a weak agonist for the pituitary LHRH receptor and stimulates both gonadotropins in a dose-dependent fashion.

Effects of paint thinner exposure on serum LH, FSH and testosterone levels and hypothalamic catecholamine contents in the male rat

We have investigated the effects of thinner inhalation on serum LH, FSH and testosterone levels together with changes in hypothalamic catecholaminergic system in the male rat. A control group inhaled normal air ventilation. The remaining animals were divided into two groups and exposed to paint thinner in a glassy cage for 15 or 30 d. Toluene concentration (the largest constituent in thinner, 66%) was set at 3000 ppm in the inhalation air. At the end, all animals were decapitated and blood samples obtained. Serum LH and FSH levels were measured by RIA and testosterone by enzyme immunoassay. Following removal of brains on dry ice, medial preoptic area, suprachiasmatic nucleus, median eminence and arcuate nucleus were isolated by micropunch technique. Noradrenaline, 3,4-dihydroxyphenylglycol (DHPG) and dopamine concentrations of these hypothalamic areas were determined by HPLC-ECD. Fifteen-day thinner inhalation significantly suppressed serum LH and testosterone levels in parallel (p<0.001) compared to control group values (LH: 0.77+/-0.07; testosterone: 2.67+/-0.39). Thirty-day exposure markedly decreased LH levels (p<0.001), but surprisingly had no significant effect on testosterone. Serum FSH levels were not significantly altered in either group. Thinner inhalation for 15 or 30 d did not cause any significant change in noradrenaline, DHPG or dopamine concentrations in the hypothalamic regions examined (except in the arcuate nucleus). These results suggest that paint thinner has an anti-gonadotropic effect and may cause long-term endocrine disturbances in the male. It is thought that the hypothalamic catecholaminergic system is not involved in thinner inhibition of LH and testosterone secretion.

Influence of chronic morphine exposure on serum LH, FSH, testosterone levels, and body and testicular weights in the developing male rat

Opiate abuse has been a matter of serious concern in male adolescents. This study investigates the effects of chronic morphine administration on serum luteinizing hormone (LH), follicle-stimulating hormone (FSH), testosterone levels, testicular histology, and body and testes weight in developing male rats. Animals were subcutaneously injected with morphine (5 mg/kg) or saline (1 mL/kg) twice daily for 30 days. Body weight determinations and injections were carried out under light ether anesthesia. At the end of the experiments, the rats were decapitated and blood samples were collected. Serum levels of LH and FSH were measured. Chronic morphine administration significantly decreased decreased serum testosterone (p < .02) and LH (p < .01) levels, but not FSH release compared to controls. Morphine exposure reduced body weight (p < .01), but had no significant effect on the testicular weight. When the testicular tissue was histologically examined, structural features of the seminiferous tubules and Leydig cells were similar in both saline and morphine-treated animals. The results suggest that opiates affect testosterone release through the hypothalamo-hypophyseal-gonadal axis rather than by a local testicular mechanism. Chronic morphine exposure during sexual maturation may have long-term endocrine disturbances in male rats.

Electrochemical stimulation of the median eminence evokes FSH but not LH release after LHRH antagonist treatment in vivo and in vitro

Experimental data suggest that a follicle stimulating hormone-releasing factor (FSH-RF) distinct from luteinizing hormone-releasing hormone (LHRH) exists. In the present study, we investigated, in short-term ovariectomized (OVX) rats, whether FSH-RF(s) can be released from nerve terminals by electrochemical stimulation (ECS) of the median eminence. To prevent the effect of LHRH liberated by ECS, 100 microg of a potent LHRH antagonist (MI-1544) was administered to one group of OVX rats 60 min before ECS. Two groups of OVX rats were used as controls. One group was treated with the solvent of the LHRH antagonist 60 min before the ECS; the other group received sham-ECS only. In-vitro experiments using a hypothalamus-pituitary coperifusion system were also performed to investigate the direct effect of ECS of the median eminence on LH and FSH release from pituitary cells. ECS in vivo induced 4.6-fold (P<0.01) and 10.2-fold (P<0.01) elevation of serum LH concentration, measured by RIA at 10 min and 60 min after ECS, respectively. Serum FSH concentrations increased 1.35-fold at 10 min (P<0.01) and 1.50-fold at 60 min (P<0.01) after ECS, compared with sham-stimulated controls. Administration of LHRH antagonist attenuated the ECS-induced release of LH by 44% at 10 min and prevented it entirely at 60 min after ECS. However, the ECS-induced release of FSH was not modified by the antagonist at 10 min and was diminished by only 17% at 60 min after ECS, compared with solvent-treated and stimulated controls. Immunohistological examination of the hypothalami showed that LHRH-immunoreactivity was depleted in the region of ECS. In the study in vitro, substances released from the fragments of mediobasal hypothalami bearing ECS in the median eminence induced significant release of both LH and FSH, and the induced release of LH, but not FSH, was prevented by the LHRH antagonist. The present study suggests that FSH-releasing factor(s) different from LHRH can be released from the median eminence and that a significant portion of FSH secretion is independent of the control of LHRH.

Antitumour effect of a gonadotropin-releasing-hormone antagonist (MI-1544) and its conjugate on human breast cancer cells and their xenografts

Our gonadotropin-releasing hormone (GnRH) antagonist analogue MI-1544 ([Ac-D-Trp1,3,D-Cpa2,D-Lys6,D-Ala10]GnRH) was developed as a potential contraceptive material, because it decreased the luteinizing hormone level without unfavourable side-effects. The antagonist was covalently bound to poly[Lys-(Ac-Glu0.96-DL-Ala3.1)] (AcEAK)-a branched polypeptide having a polylysine backbone--resulting in a MI-1544-AcEAK conjugate. According to our in vitro experiments the MI-1544 induced a 33%-35% decrease in cell numbers of MCF-7 and MDA-MB-231 human breast cancer cell lines at a dose of 30 microM. The biodegradable polymeric carrier, AcEAK, alone inhibited cell proliferation by only 13%-15%, while the MI-1544-AcEAK conjugate, applied at the same dose, was capable of producing 45%-50% inhibition of cell proliferation. Our in vivo experiments using immunosuppressed mice showed that MI-1544, applied twice daily s.c., inhibited the growth of oestrogensensitive and -insensitive xenografts by 65% and 30% respectively. This effect was potentiated (70%) in both types of xenografts by the presence of the polymeric carrier in the conjugate; however, the carrier by itself did not cause tumour growth inhibition. The polymeric polypeptide carrier is supposed to increase the stability of the GnRH antagonist and to prevent the rapid excretion of the covalently bound peptide molecule. The antagonist and its conjugate may have various direct and indirect effects on breast cancer cells and, as a consequence, the new GnRH antagonist conjugates are suitable for treating an extended range of breast cancers.