A change in the steroid metabolic pathway in human testes showing deteriorated spermatogenesis.

During androgen biosynthesis, the human testes normally produce only small quantities of Δ4-C21 steroids as these are products of the Δ4-pathway and healthy human testes preferentially use the Δ5-pathway. However, the Δ4-C21 steroid progesterone accumulates in the thickened lamina propria of the seminiferous tubules in testes with deteriorated spermatogenesis. The objectives of this study were to analyse the pregnenolone metabolites in testes with deteriorated spermatogenesis and to establish whether the androgen biosynthesis pathway changes in this condition. Biopsied or orchiectomised testicular samples were obtained from patients with varicocele, non-obstructive azoospermia, obstructive azoospermia, testicular cancer, and cryptorchidism. The samples were segregated into spermatogenesis related Johnsen's score groups: Low-JS (< 5.0) and High-JS (> 7.8). Higher levels of progesterone and 17α-hydroxyprogesterone were metabolised under in vitro conversion in the Low-JS testes than the High-JS testes when cell-free homogenates from each group were separately incubated with 14C-labelled pregnenolone. Nevertheless, the serum hormone levels did not differ between groups. Two novel pregnenolone metabolites 5ß-pregnan-3ß-ol-20-one and 5α-pregnan-3α, 21diol-20-one were identified from in vitro conversion in Low-JS testes and by recrystallisation. Immunohistochemistry revealed the higher ßHSD expression in the Low-JS than the High-JS testes. However, the CYP17A1 expression levels did not differ between groups. Infertile testes increase the relative ßHSD levels in their Leydig cells and synthesised testosterone from pregnenolone via the Δ4- rather than the Δ5-pathway. A new insight into a change of metabolites in Low-JS testes will be relevant to understand the mechanism of the deteriorated spermatogenesis under the normal range of testosterone level.

Molecular cloning and histological localization of LH-like substances in a bottlenose dolphin (Tursiops truncatus) placenta.

All mammals exhibit pituitary-specific expression of LH and FSH, whereas placental expression of gonadotropins has been reported only in primates and equids. Some cetaceans, such as dolphins, have a long gestational period and a sexual cycle of about 27 days almost comparable with that of humans. Histologically, dolphins have an epitheliochorial placentae that resembles placentas of Perissodactyla including horses. In the present study, we cloned cDNAs encoding gonadotropins and observed their immunohistochemical localization in the placenta of bottlenose dolphin. The cDNAs obtained encoded 120 amino acids for the alpha-subunit (including 96 amino acids of mature proteins), and 141 amino acids for the beta-subunit (including 121 amino acids of mature proteins). The sequence of the alpha-subunit was similar to that in the pig (Artiodactyla) pituitary glycoprotein hormone [96.7% homology at amino acids (aa) level], and the sequence of the beta-subunit was similar to that of luteinizing hormone (LH) in the pig [94.3% homology at aa level] and white rhinoceros (Perissodactyla) [93.3% homology at aa level]. Of interest, dolphin LHbeta lacks carboxyl-terminal-peptides (CTP). This fact suggests that CTP are not essential for placental expression of gonadotropin in dolphins. Immunohistochemical observations employing anti-ovine LHbeta antibody revealed positive staining in the villositycal tissue. Our observations suggest placental expression of gonadotropin homologues in cetaceans and possible evolutionary conservation of placentae-derived hormonal control of ovarian functions during pregnancy.