Metabolism of tibolone and its metabolites in uterine and vaginal tissue of rat and human origin.

In postmenopausal women, tibolone shows clear tissue differences in its stimulatory effects on the vagina and uterus. In rats, however, it has stimulatory effects on both tissues, with a different, more estrogenic, effect on the uterus than in humans. This may be due to differences in local metabolism. Therefore, in the present study, the metabolism of tibolone was analyzed in incubations of uterine and vaginal tissue from postmenopausal women and ovariectomized rats using radiolabeled tibolone in order to understand the tissue- and species-specific metabolism. In the rat, tibolone (50 nM) was mainly 3alpha-reduced to the estrogenic 3alpha-OH-tibolone in the uterus and vagina. The 3beta-OH tibolone can be isomerized to 3alpha-OH-tibolone with tibolone as intermediate. In contrast, in the same tissues from postmenopausal women, the progestagenic Delta4-isomer and estrogenic 3beta-OH-tibolone were the major metabolites of tibolone. The formation of the Delta4-isomer was higher in uterine tissue. The 3beta-hydroxysteroid dehydrogenase (HSD) inhibitor epostane had no effect on tibolone metabolism in human uterine and vaginal tissue microsomes and HEK293 cells expressing the human 3beta-HSD types 1 and 2 isoforms did not metabolize tibolone. Moreover, the 3beta-reduction of tibolone to 3beta-OH-tibolone was NADPH dependent, while the isomerization of tibolone to the Delta4-isomer did not require a cofactor. It was therefore concluded that human 3beta-HSD isoforms are not involved in the metabolism of tibolone, and that the 3beta-reduction and the Delta5-10 to Delta4 isomerization may be catalyzed by different enzymes. In conclusion, we showed that, in hormone therapy target tissues of the rat as compared with the human, different metabolic pathways for tibolone exist and therefore result in metabolites with different pharmacological properties. The rat is therefore a poor model to predict the effects of tibolone on the uterus in postmenopausal women.

Hypocorticism and interrenal hyperplasia are not directly related to masculinization in XX mas(-1)/mas(-1) carp, Cyprinus carpio.

This study reports on a homozygous XX male strain of common carp (E5), which fail to mount a normal cortisol stress response. Earlier classical genetic analysis had indicated that masculinization of E5 fish was caused by a putative recessive mutation (mas(-1)/mas(-1)). Hypocorticism in E5 fish was studied to investigate if it was related to masculinization. Head-kidney tissues isolated from E5 fish showed a low cortisol-producing capacity in vitro, and also demonstrated a reduced sensitivity to stimulation with ACTH, when compared with an isogenic XY male carp strain (STD). There was no strain difference in androgen production by head-kidney tissues in vitro. E5 fish exhibited significant hyperplasia of the interrenal tissue (adrenal homologue of teleost fish) located in the head-kidney. Conversion of pregnenolone was significantly lower in E5 head-kidney homogenates, compared to STD homogenates, however, no strain difference was found in the conversion of 17alpha-hydroxyprogesterone into cortisol. Gonad homogenates incubated with pregnenolone showed no strain difference in conversion to corticosteroids and androgens. Results indicate that the interrenal hyperplasia and hypocorticism in this strain of carp may be due to a dysfunction of the 17alpha-hydroxylase activity of the enzyme P450c17 in the interrenal, but that this defect may not be the primary factor resulting in masculinization of these XX genotypes.

Stress adaptation, cortisol and pubertal development in the male common carp, Cyprinus carpio.

This paper reviews a series of recent studies on the effect of adaptation to chronic stress on pubertal development in the common carp. In pre-pubertal male common carp adaptation to temperature stress caused a retardation of testicular development. Stress-induced delay of the first wave of spermatogenesis could be prevented by treatment with a cortisol antagonist, indicating that the stress effect is mediated by cortisol. Chronically elevated cortisol levels affected all parts of the brain-pituitary-gonad (BPG)-axis. In the hypothalamus lower levels of sGnRH were observed, in the pituitary the steady state levels of FSHbeta-m RNA were decreased, while the testicular production of especially the 11-oxygenated androgens 11-ketoandrostenedione (OA) and 11keto-testosterone (11KT) was strongly diminished. OA and 11KT have been shown to promote testicular development in fish. The LH-induced androgen synthesis in vitro was strongly inhibited by cortisol and its agonist dexamethasone. Although cortisol was shown also to interfere with the synthesis of the 11-oxygenated androgens in vivo, the lower androgen levels induced by cortisol were mainly due to the reduced testicular mass. Restoration of the plasma concentrations of these androgens by implantation could not prevent the cortisol-induced retardation of testicular growth and the first wave of spermatogenesis. Therefore, it is suggested that cortisol acts directly on Sertoli cells and/or on germ cells, which is supported by the demonstration of GRs on germ cells. We have little indication that the cortisol-induced retardation of testicular development is mediated by a decreased secretion of LH, but a crucial role for FSH can not be excluded.

Sex steroids and their involvement in the cortisol-induced inhibition of pubertal development in male common carp, Cyprinus carpio L.

The onset and regulation of puberty is determined by functional development of the brain-pituitary-gonad (BPG) axis. Sex steroids produced in the gonads play an important role in the onset of puberty. Stress interferes with reproduction and the functioning of the BPG axis, and cortisol has frequently been indicated as a major factor mediating the suppressive effect of stress on reproduction. Prolonged elevated cortisol levels, implicated in stress adaptation, inhibited pubertal development in male common carp (Cyprinus carpio). Cortisol treatment caused a retardation of pubertal testis development and reduced the LH pituitary content and the salmon GnRHa-stimulated LH secretion in vitro. A reduced synthesis of androgens also was observed. These findings suggest that the cortisol-induced inhibition of testicular development and the maturation of pituitary gonadotrophs are mediated by an effect on testicular androgen secretion. In this study, we combined cortisol treatment with a replacement of the testicular steroid hormones (testosterone and 11-oxygenated androgens) to investigate the role of these steroids in the cortisol-induced suppression of pubertal development. The effect of cortisol on spermatogenesis was independent of 11-ketotestosterone, whereas the effect on the pituitary was an indirect one, involving the testicular secretion of testosterone.

Gonadotropin-releasing hormone does not directly stimulate luteinizing hormone biosynthesis in male African catfish.

Besides gonadotropin release, GnRH stimulates gonadotropin subunit gene transcription and translation in gonadotrophs. In the African catfish, Clarias gariepinus, chicken GnRH-II (cGnRH-II: [His5,Trp7,Tyr8]-GnRH) and catfish GnRH (cfGnRH: [His5,Asn8]-GnRH) are two endogenous forms of GnRH. Studying their effects on LH subunit steady-state mRNA levels, LH de novo synthesis, and LH release in primary pituitary cell cultures of adult males, we found that cGnRH-II hardly influenced the steady-state levels of LH subunit mRNAs or LH de novo synthesis, although it stimulated LH release. Although cfGnRH stimulated LH secretion as well, high concentrations-although apparently still within the physiologic range-reduced LH transcript levels and de novo synthesis in primary pituitary cell cultures. In vivo experiments demonstrated a biphasic response of LH subunit transcript levels after a single GnRH injection: a decrease after 2 h was followed by an increase at 8 h. When the testes were removed before GnRH treatment, however, LH transcript levels remained depressed at 8 h after GnRH injection, indicating that the secondary increase in LH transcript levels depends on the presence of the testes. We conclude that the up-regulation of LH production subsequent to GnRH stimulation in adult male African catfish is mediated by factors originating from the testis. Previous work suggests that aromatizable androgens may play an important role in this context. Under the present experimental conditions, however, GnRHs had no, or an inhibitory, direct effect on LH production in catfish gonadotrophs.

Evolutionary development of three gonadotropin-releasing hormone (GnRH) systems in vertebrates.

Gonadotropin-releasing hormone (GnRH) is the neuropeptide that links the brain to the reproductive system. Most vertebrate species express two forms of GnRH, which differ in amino acid sequence, localization, distribution, and embryological origin. The GnRH system in the ventral forebrain produces a species-specific GnRH form and projects toward the gonadotropic cell in the pituitary. The GnRH neurons of this system originate from the olfactory placode and migrate into the brain during early development. The other GnRH system is localized in a nucleus in the midbrain, where large cells express chicken-GnRH-II, of which the function is still unclear. In modern teleosts, a third GnRH system is present in the terminal nerve, which contains salmon GnRH. The three GnRH systems appear at different times during fish evolution. Besides the two accepted lineages in GnRH evolution (of conserved chicken GnRH-II in the midbrain and of mammalian GnRH or species-specific GnRH in the hypophysiotropic system), we propose a third lineage: of salmon GnRH in the terminal nerve.