Gonadotropin gene expression and secretion in gonadotropin-releasing hormone antagonist-treated male rats: effect of sex steroid replacement.

The possibility of direct pituitary effects of sex steroids on gonadotropin gene expression and synthesis was studied in male rats. The animals were treated with a potent GnRH antagonist, Ac-D-pClPhe-D-pClPhe-D-Trp-Ser-Tyr-D-Arg-Leu-Arg-Pro-D-Ala-+ ++NH2CH3COOH (Org 30276; 0.5 mg/kg BW, sc, twice daily) for 10 days. Groups of the antagonist-treated rats were implanted at the beginning of the injections with Silastic capsules containing testosterone (T), 5 alpha-dihydrotestosterone (DHT), or diethylstilbestrol (DES). Groups treated with the antagonist alone or vehicle served as controls. The antagonist treatment decreased unoccupied pituitary receptors of GnRH by 93% (P less than 0.001), serum LH by 34% (P less than 0.01), and serum FSH by 30% (P less than 0.05), and serum T became undetectable (less than 0.10 nmol/liter). Compared to antagonist treatment alone, no further effects on serum or pituitary LH levels found after steroid replacements. In contrast, the antagonist-induced decreases in serum and pituitary FSH (30% and 70%, respectively; P less than 0.05-0.01) were totally reversed by the T and DHT implants, but not by DES. Pituitary levels of the LH beta-subunit mRNA were decreased by 60% (P less than 0.01) after antagonist treatment. Combination treatment with androgens had no further effect on this mRNA, whereas DES partially reversed this suppression (P less than 0.05). In contrast, the pituitary mRNA level of the FSH beta-subunit, which decreased with antagonist treatment by 90% (P less than 0.01), returned to the control level with T and DHT replacements, but only partially with DES. The pituitary mRNA level of the common alpha-subunit was significantly suppressed only by combined antagonist plus DHT treatment (P less than 0.01). However, combination of DES with the antagonist increased alpha-subunit mRNA levels 2.4-fold (P less than 0.05) compared to antagonist treatment alone. It is concluded that the suppression of gonadotropin secretion by GnRH antagonist treatment is accompanied in male rats by a parallel reduction in mRNA levels of the gonadotropin beta-subunits. Sex steroid replacement of the antagonist-treated animals selectively reverses some of the mRNA changes. Androgens (T and DHT) increase the mRNA of FSH beta-subunit, but have no effect on the LH beta-subunit. Estrogen increases the mRNA levels of common alpha- and LH beta-subunits and slightly increases that of FSH beta.(ABSTRACT TRUNCATED AT 400 WORDS)     

Testosterone and dihydrotestosterone, but not estradiol, selectively maintain pituitary and serum follicle-stimulating hormone in gonadotropin-releasing hormone antagonist treated male rats

Recently it has been found that testosterone can maintain and restimulate serum and pituitary follicle-stimulating hormone (FSH) in the gonadotropin-releasing hormone (GnRH) antagonist treated adult male rat. The present investigation was undertaken to determine (1) which metabolite of testosterone, dihydrotestosterone (DHT), or estradiol accounts for the effects of testosterone in GnRH antagonist suppressed rats and (2) whether these effects of testosterone are influenced by other testicular factors. Eight groups of 6-8 adult male Sprague-Dawley rats were subjected to the following treatments: vehicle, GnRH antagonist (75 micrograms/day s.c.), testosterone-filled Silastic implants (3 x 5 cm, s.c.), DHT-filled Silastic implants (3 x 5 cm, s.c.), estradiol benzoate (15 micrograms/day s.c.), and combined administration of GnRH antagonist with either steroid. In addition, the GnRH antagonist/testosterone treatment regimen was applied to rats orchidectomized 72 h prior to initiation of treatments. After 3 weeks of treatment, serum was analyzed for concentrations of luteinizing-hormone (LH), FSH, testosterone, DHT, and estradiol. Pituitary extracts were analyzed for LH and FSH content. Except for the vehicle-treated groups, serum and pituitary LH concentrations were markedly suppressed by all treatments. In intact rats treated with GnRH antagonist alone and/or estradiol, the pituitary FSH level was reduced by more than 70% relative to controls, while both testosterone and DHT maintained pituitary FSH. Similarly, testosterone and DHT, but not estradiol, delayed the decline of serum FSH induced with GnRH antagonist alone. In orchidectomized animals, testosterone was also capable of preventing a reduction of pituitary FSH despite concomitant GnRH antagonist administration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Testosterone stimulates pituitary and serum FSH in GnRH antagonist-suppressed rats

Thirty days of continuous treatment of adult male rats with 35 micrograms/day of the potent GnRH antagonist, (N-Ac-D-Nal (2)1, D-pCl-Phe2, D-Trp3, D-hArg (Et2)6, D-Ala10)-GnRH (RS-68439) reduced serum FSH to values below the limit of detection of the assay. Testosterone supplementation in the form of subcutaneous testosterone-filled silastic capsule implants present during an additional 30 days of GnRH antagonist administration restored serum FSH to values comparable to those observed after vehicle treatment. Pituitary FSH content, which was substantially reduced after GnRH antagonist treatment, was completely restored after concurrent testosterone supplementation. These results show that, under conditions of GnRH receptor blockade, testosterone is capable of stimulating pituitary and serum FSH in adult male rats.     

Suppression and recovery of pituitary gonadotrophin secretion in intact and orchidectomized rats treated neonatally with a gonadotrophin-releasing hormone antagonist

Suppression of neonatal rat pituitary-testis function by gonadotrophin-releasing hormone (GnRH) antagonists results in delayed sexual maturation and infertility. Since the mechanism is not understood, the acute effects of a GnRH antagonist on gonadotrophin secretion in neonatal male rats has been studied in more detail. Treatment with a GnRH antagonist analogue, N-Ac-D-Nal(2)1,D-p-Cl-Phe2,D-Trp3,D-hArg(Et2)6,D-Ala10 -GnRH (2 mg/kg per day) on days 1-10 of life had prolonged effects on gonadotrophin secretion; serum LH and FSH recovered in 1 week, but the pituitary content took 2 weeks to recover. Likewise, LH and FSH responses to acute in-vivo stimulation with a GnRH agonist were still suppressed 1 week after the treatment. Interestingly, a rebound (86% increase) in basal serum FSH was found 16 days after treatment with the antagonist. Whether testis factors influence gonadotrophin secretion during treatment with the GnRH antagonist and/or in the subsequent recovery period was also assessed. Neonatal rats were castrated on days 1, 5 or 10 of the 10-day period of antagonist treatment. Orchidectomy on days 1 and 5 only marginally affected gonadotrophin secretion. When orchidectomy was performed at the beginning of the recovery period, no effects on pituitary recovery were seen within 1 week of castration. After 16 days, serum LH and FSH in the antagonist-treated and control castrated rats were equally increased but the pituitary contents of the antagonist-treated rats were still suppressed. Finally, the effect of testosterone treatment on the recovery of gonadotrophin secretion after antagonist suppression was studied in intact and orchidectomized animals.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of corticosterone and testosterone on pituitary gonadotropin content, secretion, bioactivity and messenger RNA levels in the presence or absence of GnRH in male rats

The effects of corticosterone (B) and testosterone (T) on pituitary and serum bioactive and immunoreactive gonadotropins and on gonadotropin hormone subunit messenger RNA levels were compared in the absence of GnRH. Male rats were implanted with pellets of either cholesterol, B or T. At implantation, 2 and 4 days later half of each group received GnRH antagonist and animals were killed 5 days after implantation. As expected, GnRH antagonist lowered bioactive and immunoreactive serum FSH and LH, pituitary FSH, LHβ and FSHβ mRNA. B treatment alone lowered bioactive and immunoreactive serum FSH and immunoreactive serum LH. B reversed the antagonist effect on bioactive and immunoreactive pituitary FSH and FSHβ mRNA. T alone lowered bioactive and immunoreactive serum FSH and LH levels. T reversed the antagonist effect on bioactive and immunoreactive pituitary FSH. T lowered bioactive and immunoreactive pituitary LH and LHβ mRNA and partially reversed the antagonist effect on FSHβ mRNA. The data suggest that either B or T enhance FSH synthesis by acting directly at the gonadotrope, but that B does not affect LH variables to the same extent as T. The results suggest that in stressed animals, when T levels are reduced, B can substitute for T in sustaining FSH synthesis.     

Both testosterone and follicle-stimulating hormone independently inhibit spermatogonial differentiation in irradiated rats

Simultaneous suppression of both testosterone and FSH with GnRH antagonists (GnRH-ant) reverses the radiation-induced block in spermatogonial differentiation in F1 hybrids of Lewis and Brown-Norway rats. Although addition of exogenous testosterone restores the block, it also raises FSH, and hence it had not been possible to conclusively determine which hormone was inhibiting spermatogonial differentiation. In the present study, we establish the relative roles of testosterone and FSH in this inhibition using three different approaches. The first approach involved the treatment of irradiated rats, in which differentiation was stimulated by GnRH-ant plus flutamide, with FSH for 2 wk; the FSH reduced the percentage of tubules that were differentiated (TDI) by about 2-fold, indicating that FSH does have an inhibitory role. The second approach involved treatment of irradiated, hypophysectomized rats with exogenous testosterone for 10 wk; testosterone also reduced the TDI, demonstrating that testosterone had a definite inhibitory effect, independent of pituitary hormones. Furthermore, in this protocol we showed that TDI in the hypophysectomized testosterone-treated group, which had higher intratesticular testosterone levels but lacked FSH, was slightly higher than the TDI in a GnRH-antagonist-testosterone-treated group of irradiated rats, which had normal physiological levels of FSH; this result supports a role for endogenous FSH in suppressing spermatogonial differentiation in the latter group. The third approach involved injection of an active anti-FSH antibody for 10 d in untreated, GnRH-ant plus flutamide-treated, or GnRH-ant plus testosterone-treated irradiated rats. This was not sufficient to increase the TDI. However, flutamide given in a similar treatment schedule did increase the TDI in GnRH-ant plus testosterone-treated rats. We conclude that both testosterone and FSH individually inhibit spermatogonial differentiation after irradiation, but testosterone is a more highly potent inhibitor than is FSH.     

Human follicle-stimulating hormone exerts a stimulatory effect on spermatogenesis, testicular size, and serum inhibin levels in the gonadotropin-releasing hormone antagonist-treated nonhuman primate (Macaca fascicularis)

The role of FSH in spermatogenesis was investigated in nonhuman primates depleted of testosterone by GnRH antagonist treatment. The GnRH antagonist antide (Nal-Lys; [N-acetyl-D-2-naphthyl-Ala1,D-4-chloro-Phe2,D-pyridyl-Ala3, nicotinyl-Lys5,D-nicotinyl-Lys6,isopropyl-Lys8,D-Ala10 ]-GnRH) was used at a daily dose of 450 micrograms/kg to suppress endogeneous gonadotropin and androgen production. Four groups of five cynomolgus monkeys (Macaca fascicularis) were subjected to the following treatment throughout a 16-week period: vehicle (group 1), GnRH antagonist (group 2), and GnRH antagonist plus human FSH (Fertinorm; 2 x 15 IU/day.animal; hFSH) during weeks 0-8 (group 3) or 8-16 (group 4). Testicular biopsies were performed before and after 4, 8, and 16 weeks of treatment. The tissue was analyzed by light microscopy and flow cytometry. Serum testosterone levels were suppressed into the range of orchidectomized animals in all GnRH antagonist-treated groups. In the absence of hFSH, serum inhibin levels were also markedly lowered. Concomitant administration of hFSH attenuated the GnRH antagonist-induced reduction of testicular size, while delayed treatment with hFSH failed to restimulate testicular volume. Numbers of A-dark spermatogonia, the reserve stem cells, were not altered by any of the treatments. hFSH either fully maintained or increased the counts for A-pale spermatogonia (renewing stem cells). The development of pachytene spermatocytes and round and elongated spermatids was markedly reduced or inhibited by the GnRH antagonist within 6-18 weeks. In contrasts, hFSH maintained these cell types at about 50% of baseline for 8 weeks. After 8 weeks of GnRH antagonist administration, hFSH stimulated A-pale spermatogonia and spermatocytes 2- to 3-fold with only minor effects on spermatid numbers. By means of flow cytometry, testicular cells were quantified according to DNA content. Within 8-16 weeks of GnRH antagonist treatment the percentage of 4C (mainly primary spermatocytes), 1C (round spermatids), and 1CC cells (elongated spermatids) had fallen from 65-75% to 5-25%. hFSH completely maintained the relative number of these cells, but failed to significantly restimulate the formation of 1CC cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Gonadotropin-releasing hormone analogs stimulate and testosterone inhibits the recovery of spermatogenesis in irradiated rats

We investigated the effects of GnRH analogs, different doses of testosterone (T), an androgen receptor antagonist (flutamide), and combinations of these on the recovery of spermatogenesis after irradiation. Treatment with a GnRH agonist (Lupron) for 10 weeks after irradiation reduced the intratesticular T concentration (ITT) to 4% of that in irradiated rats and serum FSH to undetectable levels without altering serum LH levels. Injection of a GnRH antagonist (Cetrorelix) at 3 weeks after irradiation suppressed LH, FSH, and ITT to <7%, 32%, and 10%, respectively, of levels in irradiated-only rats within 2 weeks; suppression was maintained for approximately 3 to 4 weeks. The percentage of tubules with differentiated germ cells (repopulation index, RI) was <0.6% at weeks 10 to 20 after irradiation. Spermatogenic recovery was induced by both the GnRH agonist (RI = 58% at week 10; 91% at week 20) and antagonist (RI = 70% at week 13). There was a dose-dependent suppression of testicular germ cell repopulation when T was combined with GnRH analogs. The ability of T to abolish the spermatogenic stimulatory effect of the GnRH antagonist was evident by the similar RI obtained for irradiated rats given antagonist + T or T alone. This suppression of GnRH-induced recovery of spermatogenesis by T could be reversed by flutamide. The RI best correlated with the degree of ITT suppression. In ITT-suppressed rats, the RI also showed an inverse correlation with serum T levels. Thus, T and/or its androgenic metabolites either directly or indirectly inhibit spermatogenic recovery after irradiation through an androgen receptor-mediated process. In addition, there was a close negative correlation between RI and FSH levels, and hence, a spermatogenic inhibitory role for FSH in the irradiated rats cannot be ruled out.     

Gonadotropin-releasing hormone regulates follicle-stimulating hormone beta-subunit gene expression in the male rat

Since the role of GnRH in the control of FSH release and synthesis is controversial, we have examined the effect of elimination of GnRH action on gonadotropes on FSH beta gene expression, FSH release, and synthesis. GnRH stimulation of the pituitary was abolished by continuous infusion of either a GnRH antagonist or a GnRH antiserum. We also examined the effects of gonadotrope desensitization, using a continuous infusion of GnRH or GnRH agonist analog. FSH beta mRNA levels were determined by dot blot hybridization using rat FSH beta cDNA, and changes were related to pituitary and serum FSH concentrations. FSH beta mRNA levels increased after orchidectomy and correlated well with serum FSH concentrations. Overall FSH synthesis was increased after castration, as judged by elevated serum FSH and unchanged pituitary FSH content. In orchidectomized rats, continuous GnRH antagonist infusion prevented the postcastration rise in FSH beta mRNA levels and serum FSH. Pituitary FSH content was reduced at 7 days, but not at 14 days. In intact rats, GnRH antagonist infusion for 7 days had no effect on FSH beta mRNA levels, but after 14 days, there was a 33% reduction, and serum FSH was suppressed. Pituitary FSH content was decreased after GnRH antagonist treatment for 7 or 14 days. Daily injection of GnRH antiserum for 6 days abolished the increases in FSH beta mRNA levels and serum FSH in orchidectomized rats, but pituitary FSH content was unaffected. In intact rats, GnRH antiserum treatment reduced FSH beta mRNA levels by 38%, suppressed serum FSH, and decreased pituitary FSH content. When gonadotropes were desensitized by a continuous infusion of GnRH for 14 days or GnRH agonist analog for 28 days, FSH beta mRNA levels and pituitary FSH content were markedly reduced, and serum FSH was suppressed to undetectable levels. We concluded that 1) endogenous GnRH is required for the maintenance of FSH beta mRNA levels in both intact and orchidectomized rats; 2) FSH beta mRNA levels are coupled to the level of FSH biosynthesis, indicating the physiological importance of this pretranslational regulation; 3) desensitization is more effective at inhibiting FSH beta gene expression and FSH synthesis than preventing gonadotrope stimulation using the GnRH antagonist or antiserum; and 4) the actions of GnRH on FSH beta mRNA levels are paralleled by its effects on LH beta mRNA levels, suggesting that GnRH provides a common primary stimulus for the induction of both beta-subunit genes in vivo. These data provide further evidence for the crucial stimulatory role of GnRH in the control of FSH synthesis.     

Effect of dihydrotestosterone on pituitary follicle-stimulating hormone isoforms in adult male rats treated with a gonadotropin-releasing hormone antagonist

The effect of androgens on the oligosaccharide structure of follicle-stimulating hormone (FSH) isoforms was studied in adult male rats treated with a potent gonadotropin-releasing hormone (GnRH) antagonist. Animals were castrated (Cx), and 24 h later were treated with physiological doses of either testosterone propionate (T) or dihydrotestosterone propionate (DHT) (0.25 mg/rat in corn oil, daily, s.c.) for 7 days. The antiandrogen flutamide (F; 5 mg/day/rat, twice a day, s.c.) was administered to either Cx-T or Cx-DHT rats to block androgen action. The GnRH antagonist Org 30276 (Ant; 1 mg/kg/day, s.c.) was injected to both Cx- and Cx-DHT treated rats. FSH serum levels reached normal values in Cx rats treated with either T or DHT, whereas those treated with F retained Cx conditions. Both Cx-Ant and Cx-Ant-DHT treated animals presented normal serum FSH levels. Concanavalin A affinity chromatography was used to isolate pituitary FSH isoforms according to their carbohydrate inner structure. An increased proportion of FSH isoforms bearing complex-type oligosaccharides was observed in Cx rats treated with T or DHT, whereas the proportion of these isoforms was reduced in Cx and Cx-T-F or Cx-DHT-F rats. These results demonstrate that functional androgens are needed to complete the oligosaccharide processing of FSH. In addition, the proportion of the different pituitary FSH isoforms after DHT replacement was equivalent to that found when GnRH action was blocked, indicating that androgens are involved in the regulation of carbohydrate incorporation to the FSH molecule by acting mainly at the pituitary level, independently of GnRH action.     

Exogenously administered testosterone maintains spermatogenesis quantitatively in adult rats actively immunized against gonadotropin-releasing hormone.

The administration of testosterone via Silastic capsules has been shown previously to maintain advanced spermatid number quantitatively in intact rats in which LH but not FSH was suppressed, but not in hypophysectomized rats, indicating that pituitary factors in addition to LH are required for the quantitative maintenance of spermatogenesis in the rat. The objective of the present study was to examine whether testosterone is capable of maintaining quantitatively normal spermatogenesis in rats in which both LH and FSH are suppressed. Intact adult male rats were actively immunized against GnRH by intradermal injection of GnRH conjugated to human serum globulin; control rats received intradermal injections of saline and adjuvant. Four weeks after the primary immunization, GnRH-immunized rats received the first booster injection and, at the same time, received testosterone-filled polydimethylsiloxane (PDS) implants of 4, 8, 12, or 24 cm or empty implants. Booster injections were repeated every 2 weeks for 8 weeks. At that time, rats were killed, and serum levels of LH, FSH, and testosterone, testicular advanced spermatid number, and seminiferous tubule fluid testosterone concentrations were determined. Four weeks after the initial administration of GnRH immunogen, i.e. before the first booster injection, serum levels of testosterone, LH, and FSH and the number of advanced spermatids per testis were not different from those in controls. Eight weeks after the first booster injection, serum LH and FSH and advanced spermatids were undetectable in all GnRH-immunized rats. The administration of testosterone-filled PDS implants of 4 and 8 cm to GnRH-immunized rats for 8 weeks resulted in the maintenance of 105 +/- 6 and 161 +/- 5 x 10(6) advanced spermatid/testis, respectively, significantly less than the control value (237 +/- 19 x 10(6)). In GnRH-immunized rats that received testosterone-filled PDS implants of 12 or 24 cm, the advanced spermatid numbers per testis (228 +/- 4 and 229 +/- 8 x 10(6), respectively) were not significantly different from those in controls. These results indicate that testosterone is capable of maintaining spermatogenesis quantitatively in the adult rats testis, in the absence of both radioimmunoassayable LH and FSH.     

Comparative effects of chronic administration of the non-steroidal antiandrogens flutamide and Casodex on the reproductive system of the adult male rat.

The effects of chronic blockade of androgen action by the antiandrogens flutamide and Casodex on serum and pituitary concentrations of LH and FSH, serum and testicular androgen levels, reproductive organ weights, and on spermatogenesis were compared in the adult rat. Animals were treated for 3 and 8 weeks with vehicle, Casodex (20 mg.kg-1.(day)-1, flutamide (20 mg.kg-1.(day)-1) and GnRH antagonist (150 micrograms/day, Detirelix). Treatment with GnRH antagonist suppressed gonadotropin and testosterone production, reduced the weights of testes, epididymides and seminal vesicles, and inhibited germ cell development. Flutamide administration markedly elevated serum and pituitary levels of gonadotropins as well as serum and testicular androgen concentrations. Casodex-induced elevation of gonadotropin concentrations was less pronounced and serum and testicular levels of androgens did not change significantly. The reduction of seminal vesicle weights was similar after Casodex and GnRH antagonist treatment, whereas flutamide was less effective. Testicular weight and spermatogenesis (assessed by light microscopical and flow-cytometric analysis) remained unaffected by Casodex and flutamide. It is concluded, that 1. Casodex, in contrast to flutamide, is a peripherally selective antiandrogen, and 2. Casodex influences release of gonadotropins into circulation less than flutamide. Therefore this antiandrogen might be useful clinically for selectively blocking androgen actions in the accessory sex glands.     

Effects of androgens on bioactivity and immunoreactivity of pituitary FSH in GnRH antagonist-treated male rats

The effects of androgens on the bioactivity and molecular composition of pituitary FSH were examined in intact and GnRH antagonist-suppressed male rats. Eight groups of adult Sprague-Dawley rats were subjected to the following treatments: antagonist (75 micrograms/day by osmotic minipumps; sc), testosterone-filled Silastic implants (3 X 5 cm, sc), dihydrotestosterone-filled Silastic implants (3 X 5 cm, sc), E2 benzoate (15 micrograms/day, sc), and combined administration of antagonist with either steroid for 3 weeks. At the end of the treatment period, pituitaries were dissected out and homogenised. FSH content was determined in the pituitary extracts by an in vitro bioassay and a radioimmunoassay. Individual pituitary extracts from rats treated with vehicle, testosterone and testosterone + antagonist were subjected to isoelectric-focusing on sucrose density gradients performed in the pH range from 3.5 to 7.0. Individual isoelectric-focusing fractions (100-120) were analysed for bioactive and immunoreactive FSH. Treatment with antagonist, E2 or antagonist + E2 caused a significant decrease in pituitary FSH, whereas testosterone and dihydrotestosterone alone or in combination with antagonist prevented the decrease in pituitary FSH. The effects of all treatments on both bioactive and immunoreactive FSH were similar. Testosterone treatment not only maintained FSH synthesis but also altered the molecular composition of pituitary FSH. Following treatment with testosterone there was a shift of maximal FSH bioactivity to the more acidic pH range. On the other hand, less bioactivity was recovered than corresponding immunoreactivity in the higher pH region, resulting in significantly reduced ratios of bioactivity to immunoreactivity of FSH.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differential effects of FSH and testosterone on the maintenance of spermatogenesis in the adult hypophysectomized rat

In order to clarify further the role of FSH in the maintenance of spermatogenesis, adult rats were treated with purified human FSH (2 X 5 IU/day per rat), testosterone (1.5 cm silicone elastomer implant) or a combination of both hormones for 2 weeks following hypophysectomy. After hypophysectomy alone, no elongate spermatids were observed and the numbers of pachytene spermatocytes and round spermatids observed were reduced when compared with untreated controls. Testosterone supplementation alone qualitatively maintained the formation of elongate spermatids in most seminiferous tubules, whilst in FSH-treated rats increased numbers of round spermatids and pachytene spermatocytes were observed when compared with hypophysectomized animals. Formation of elongate spermatids, however, did not occur under FSH treatment alone. A combination of FSH and testosterone treatment maintained spermatogenesis in an almost quantitative fashion. Numbers of pachytene spermatocytes and round spermatids were maintained at about 80% of levels seen in intact control animals. Treatment with FSH or testosterone alone maintained testis weights at significantly higher levels than those seen in hypophysectomized controls (FSH, 0.79 +/- 0.05 g; testosterone, 0.81 +/- 0.07 g; hypophysectomized, 0.50 +/- 0.04 g). Animals treated with FSH and testosterone showed testis weights 20% below control values (1.22 +/- 0.05 vs 1.51 +/- 0.06 g; P less than 0.05). No increases in intratesticular or intratubular androgen concentrations or in testosterone: dihydrotestosterone ratios were observed in any of the hormone-treated groups when compared with hypophysectomized controls. In all hypophysectomized animals testicular androgen concentrations were reduced to less than 5% of control values. The results obtained in this study suggest that FSH is involved in the maintenance of spermatogenesis in the adult rat and that the effects of FSH are not mediated through changes in intratesticular androgens. Low levels of testosterone in combination with FSH can almost quantitatively maintain spermatogenesis in adult rats.     

Hormonal regulation of androgen-binding protein in the rat

Effects of gonadotropins and gonadal steroids on androgen-binding protein (ABP) production by the testis and its secretion into the blood and transport into the epididymis were studied in 20- and 30-day-old rats. These animals had been treated with hCG, FSH, the Nal-Glu GnRH antagonist [Ac-D2Nal1,D4ClDPhe2,D3Pal3,Arg5,DGlu6(AA) ,DAla10]LHRH (antagonist), testosterone propionate, or estradiol benzoate, alone or in combination, for 10 days before assessment of ABP. Antagonist administration suppressed the testicular content (nanograms per organ) of ABP to below control (untreated) levels in both age groups. When hCG or testosterone was given along with the antagonist, they overcame the effect of the antagonist, and the resultant ABP values exceeded untreated control levels in both the 20- and 30-day-old rats. Treatment of rats with these hormones in the absence of the GnRH antagonist also elevated the ABP content of the testis above that of untreated controls. FSH administered with antagonist was able to prevent the antagonist-induced suppression of testicular ABP content. When rats were treated with FSH alone, the content of ABP in the testis was increased above untreated control levels in the 30-day-old group, but not in the 20-day-old group. The simultaneous administration of FSH and hCG did not result in an increase in testicular ABP content above that caused by hCG or testosterone alone. The increase in the ABP content of the testis caused by FSH administration was only about one sixth that caused by hCG or testosterone. Since testosterone or hCG, even in the presence of antagonist, was able to maximally stimulate ABP production by the testis of both age groups, we conclude that testosterone is the major in vivo regulator of its synthesis. Only combined treatment with hCG and FSH was able to increase transport of ABP into the epididymis of 20-day-old rats. All treatments that increased the testicular content of ABP in the 30-day-old rats also increased its transport into the epididymis. Treatments that drastically reduced the content of ABP in the testis of 20-day-old rats (antagonist, estradiol, estradiol plus antagonist) also reduced ABP secretion into the serum. Only treatment with estradiol reduced the secretion of ABP into the serum of 30-day-old rats. None of the treatments increased the ABP secretion into the bloodstream above untreated control levels.     

Gonadotropin-releasing hormone antagonist plus testosterone: a potential male contraceptive

No effective hormonal contraceptive has yet been devised for men. Through their suppressive effect on gonadotropin secretion, GnRH antagonists inhibit both testosterone (T) production and spermatogenesis in animals. Long term administration of an antagonist alone would result in androgen deficiency; this would cause unacceptable physiological and behavioral sequellae in men. Therefore, androgen replacement must be included in any GnRH antagonist regimen used in human male contraception. We tested the hypothesis that the combination of a GnRH antagonist plus T would suppress spermatogenesis in the male primate to azoospermic levels while maintaining normal serum T levels. We examined the effects of the GnRH antagonist Deterelix [N-Ac-DNal(2)1-DpCl-Phe2-DTrp3-DhArg(Et2)6 -DAla10-GnRH], alone and with simultaneous T replacement, on sperm production and serum T levels in adult male monkeys (n = 22). After 12 weeks of daily sc antagonist injection, all animals that received antagonist alone (n = 5) and those that 750 micrograms/kg.day antagonist plus T (n = 5) were azoospermic. After 16 weeks, four of five animals that received 250 micrograms/kg.day antagonist plus T became azoospermic. Control animals (n = 7) received daily injections of vehicle; sperm counts increased somewhat during the study period in that group. Castrate range T levels were achieved in animals receiving antagonist alone. T levels in the groups that received T supplementation and in the control group were in the normal male range throughout the treatment period. Sperm counts returned to the pretreatment range in all animals during the recovery period. We conclude that the combination of a GnRH antagonist plus T can induce azoospermia reversibly in this nonhuman primates species, and that a similar combination may be an effective contraceptive regimen in men. The GnRH antagonist alone may be an effective treatment for androgen-dependent neoplasia.     

Acute and chronic effects of a gonadotrophin-releasing hormone antagonist on pituitary and testicular function in monkeys

The effects of a potent gonadotrophin-releasing hormone (GnRH) antagonist, (N-Ac-D-rho-Cl-Phe1,2,D-Trp3-D-Arg6-D-Ala10)-GnRH (Org 30276), on pituitary and testicular function of adult macaque monkeys were investigated. After a study to find the correct dose in castrated monkeys, five intact adult male animals were treated with daily s.c. injections of 5 mg antagonist for 9 weeks. The treatment resulted in an immediate decline in serum LH and testosterone in three out of five animals. The two hormones remained suppressed during the 9-week treatment period. Testosterone and LH responses to a bolus injection of GnRH (50 micrograms i.v.) were blunted or abolished during the antagonist treatment. Testicular volumes decreased markedly and ejaculates obtained at the end of treatment were azoospermic or contained only few dead sperm. Histological examination of the testes showed complete disruption of seminiferous epithelium in these animals. A decrease of body weight was observed in the treated animals. When the treatment was ceased, all inhibitory effects of GnRH antagonists were reversible. In the other two animals no consistent suppression of pituitary or testicular function could be observed during this period, nor was a doubling of the treatment dose for a further 8 weeks capable of fully suppressing endocrine and seminal parameters in these monkeys. It is concluded that GnRH antagonist treatment is capable of rapidly decreasing serum LH and testosterone and disrupting spermatogenesis in this primate species. Suppression effected by antagonist treatment is more rapid than that caused by GnRH agonists. The individual responses to the tested doses, however, vary markedly.     

Pituitary gonadotropin-releasing hormone (GnRH) receptor responses to GnRH in hypothalamus-lesioned rats: inhibition of responses by hyperprolactinemia and evidence that testosterone and estradiol modulate gonadotropin secretion at postreceptor sites

Increased hypothalamic GnRH secretion appears to influence positively the number of pituitary GnRH receptors (GnRH-R). GnRH-R increase after castration in male rats, and this rise can be prevented by testosterone (T), anti-GnRH sera, or hypothalamic lesions. GnRH also increases serum LH and GnRH-R in hypothalamus-lesioned rats, and these animals injected with exogenous GnRH are, therefore, a good model in which to study the site of steroid feedback at the pituitary level. Adult male and female rats were gonadectomized, and radiofrequency lesions were placed in the hypothalamus. Males received T implants, and females received estradiol implants at the time of surgery. Empty capsules were placed in the control animals. Beginning 3-5 days later, animals in each group were injected every 8 h with vehicle (BSA) or GnRH (0.002-200 micrograms/day) for 2 days. After these GnRH injections, all rats received 6.6 micrograms GnRH, sc, 1 h before decapitation to determine acute LH and FSH responses. GnRH-R were determined by saturation analysis using 125I-D-Ala6-GnRH ethylamide as ligand. In males, GnRH injections increased GnRH-R. T inhibited acute LH and FSH responses to GnRH in all groups, but had little effect on GnRH-R, indicating that T inhibits gonadotropin secretion at a post-GnRH receptor site. In females, the GnRH-R response to GnRH was less marked, and only the 200 micrograms/day dose of GnRH increased GnRH-R, indicating that the positive feedback effects of estradiol at the pituitary level are also exerted at a site distal to the GnRH receptor. There was no positive correlation between the number of GnRH-R and GnRH-stimulated gonadotropin release in males or females. Female rats with hypothalamic lesions had markedly elevated serum PRL levels (greater than 300 ng/ml). Suppression of PRL secretion by bromocryptine resulted in augmented GnRH-R responses to GnRH, and GnRH-R concentrations rose to the same values induced in males. This suggests that hyperprolactinemia inhibits GnRH-R responses to GnRH in females by a direct action on the pituitary gonadotroph.     

Suppression of the intratesticular testosterone is associated with quantitative changes in spermatogonial populations in intact adult rats

To investigate the interactions between testosterone and FSH on quantitative aspects of spermatogenesis, intact adult rats were implanted sc with 0.5- to 50-cm long testosterone-filled silastic capsules (TC) for 8 weeks. Serum testosterone levels were suppressed slightly in rats bearing 1-cm TC implants but were elevated 6- to 30-fold when 5 cm or longer TC implants were used. These changes in serum testosterone were associated with a biphasic, dose-dependent response in testicular testosterone concentrations, reaching a minimum of 10-15% of the control values in rats bearing the 1- or 5-cm TC implants, but rebounding to 80% when 50-cm long TC implants were used. Meanwhile, serum FSH was comparably suppressed by 40-70%. Complete spermatogenesis was observed in all experimental animals with the exception of three rats with 1-cm TC implants in which elongated spermatids were absent or reduced in number. Enumeration of various cell types in the basal compartment of whole mounted seminiferous tubules revealed a 20% increase in type A1 spermatogonia in rats with the 1-cm TC implants. On the other hand, a 15-20% reduction in type B spermatogonia and preleptotene spermatocytes was noted in rats receiving 5-cm or longer TC implants. These results demonstrate that complete spermatogenesis can be maintained in intact animals in the presence of 10-15% of the normal testicular testosterone concentration. Failure to maintain normal testis weight, testicular testosterone concentration, or germ cell number at a 30-fold increase in serum testosterone demonstrates that high levels of serum testosterone may not be beneficial for quantitative spermatogenesis. Furthermore, both quantitative and qualitative differences were observed in different phases of spermatogenesis in the presence of comparable serum FSH and testicular testosterone concentrations. These results suggest that factors other than these two hormones are also involved in the regulation of spermatogenesis.     

Effect of administration of testosterone and gonadotrophin-releasing hormone (GnRH) antagonist on basal and GnRH-stimulated gonadotrophin secretion in orchidectomized monkeys

The aim of the present investigation was to investigate the effects of testosterone on basal and gonadotrophin-releasing hormone (GnRH)-stimulated gonadotrophin secretion in the presence and absence of a GnRH antagonist in a non-human primate model (Macaca fascicularis). Orchidectomized animals were used in order to avoid interference by testicular products other than testosterone involved in gonadotrophin feedback. Concomitant and delayed administration of testosterone at doses that provided serum levels either within the intact range (study 1) or markedly above that range (study 2) did not influence the suppression of basal gonadotrophin release induced by the GnRH antagonist during a 15-day period. To assess the possible effects of testosterone treatment at the pituitary level (study 3) GnRH stimulation tests (500 micrograms) were performed before and on days 8 and 15 of treatment with high-dose testosterone and GnRH antagonist alone or in combination. Testosterone alone abolished the gonadotrophin responses to exogenous GnRH observed under pretreatment conditions. With GnRH antagonist alone, an increased responsiveness (P less than 0.05) to GnRH was seen on day 8 and a similar response compared with pretreatment on day 15. Following combined treatment with GnRH antagonist and testosterone, GnRH-induced gonadotrophin secretion was consistently lower compared with that after GnRH antagonist alone (P less than 0.05), but was increased compared with that after testosterone alone (P less than 0.05). Thus, in the presence of a GnRH antagonist the feedback action of testosterone on LH and FSH was diminished.(ABSTRACT TRUNCATED AT 250 WORDS)