This study aimed to improve, using the zebrafish model, our understanding of the distinct roles of pituitary gonadotropins FSH and LH in regulating testis functions in teleost fish. We report, for the first time in a vertebrate species, that zebrafish Leydig cells as well as Sertoli cells express the mRNAs for both gonadotropin receptors (fshr and lhcgr). Although Leydig cell fshr expression has been reported in other piscine species and may be a common feature of teleost fish, Sertoli cell lhcgr expression has not been reported previously and might be related to the undifferentiated gonochoristic mode of gonadal sex differentiation in zebrafish. Both recombinant zebrafish (rzf) gonadotropins (i.e. rzfLH and rzfFSH) stimulated androgen release in vitro and in vivo, with rzfFSH being significantly more potent than rzfLH. Forskolin-induced adenylate cyclase activation mimicked, whereas the protein kinase A inhibitor H-89 significantly reduced, the gonadotropin-stimulated androgen release. Therefore, we conclude that both FSH receptor and LH/choriogonadotropin receptor signaling are predominantly mediated through the cAMP/protein kinase A pathway to promote steroid production. Despite this similarity, other downstream mechanisms seem to differ. For example, rzfFSH up-regulated the testicular mRNA levels of a number of steroidogenesis-related genes both in vitro and in vivo, whereas rzfLH or human chorionic gonadotropin did not. Although not fully understood at present, these differences could explain the capacity of FSH to support both steroidogenesis and spermatogenesis on a long-term basis, whereas LH-stimulated steroidogenesis might be a more acute process, possibly restricted to periods during which peak steroid levels are required.
This report aimed to establish, using African catfish, Clarias gariepinus, as model species, a basis for understanding a well-known, although not yet clarified, feature of male fish reproductive physiology: the strong steroidogenic activity of FSHs. Assays with gonadotropin receptor-expressing cell lines showed that FSH activated its cognate receptor (FSHR) with an at least 1000-fold lower EC50 than when challenging the LH receptor (LHR), whereas LH stimulated both receptors with similar EC50s. In androgen release bioassays, FSH elicited a significant response at lower concentrations than those required to cross-activate of the LHR, indicating that FSH stimulated steroid release via FSHR-dependent mechanisms. LHR/FSHR-mediated stimulation of androgen release was completely abolished by H-89, a specific protein kinase A inhibitor, pointing to the cAMP/protein kinase A pathway as the main route for both LH- and FSH-stimulated steroid release. Localization studies showed that intratubular Sertoli cells express FSHR mRNA, whereas, as reported for the first time in a vertebrate, catfish Leydig cells express both LHR and FSHR mRNA. Testicular FSHR and LHR mRNA expression increased gradually during pubertal development. FSHR, but not LHR, transcript levels continued to rise between completion of the first wave of spermatogenesis at about 7 months and full maturity at about 12 months of age, which was associated with a previously recorded approximately 3-fold increase in the steroid production capacity per unit testis weight. Taken together, our data strongly suggest that the steroidogenic potency of FSH can be explained by its direct trophic action on FSHR-expressing Leydig cells.
The gene and cDNA encoding a putative follicle-stimulating hormone beta subunit (cfFSHbeta) from African catfish (Clarias gariepinus) were cloned. Similar to other FSHbeta genes, the cfFSHbeta gene consisted of three exons interrupted by two introns. The cfFSHbeta cDNA coded for a mature protein of 115 amino acids. The 12 cysteines that are required for the typical tertiary folding of glycoprotein hormone beta subunits were positionally conserved in cfFSHbeta. The cfFSHbeta mRNA expression was exclusively detected in the pituitary and was detectable before pubertal development was initiated. The cfFSHbeta transcript levels increased in particular during early stages of puberty and reached constantly high levels after the first appearance of spermatids in the testis. The cfFSHbeta mRNA-positive cells were localized in the proximal pars distalis. Castration of mature males caused elevated cfFSHbeta mRNA levels that were decreased by steroid replacement. Previous work indicated that the African catfish is an interesting model to study the regulation of gonadal functions because cfLH is able to activate both the catfish luteinizing hormone receptor (cfLH-R) and follicle-stimulating hormone receptor (cfFSH-R). Because cfFSH purification has failed so far, ongoing studies are directed toward the production of recombinant cfFSH. After all, the developmental and hormonal regulation of cfFSHbeta transcript levels opens the possibility for physiologically relevant actions of the putative cfFSH, next to the presumptive bifunctionally acting cfLH.
Pubertal development was studied in male African catfish by immunocytochemical examination of pituitary gonadotrophs and by monitoring the responsiveness of gonadotropin (GTH) secretion to salmon GnRH analogue (sGnRHa) in vitro. Experiments were carried out with fish from 9 to 28 wk of age. Fish were assigned to four groups, according to the stage of spermatogenesis: I, spermatogonia alone; II, spermatogonia and spermatocytes; III, spermatogonia, spermatocytes, and spermatids; IV, all germ cell stages, including spermatozoa. Basal and sGnRHa-stimulated secretion of the LH-like GTH II increased 3- to 4-fold from stage I to II and from stage II to III, whereas a 15-fold increase was recorded from stage III to IV. The ED50 values of sGnRHa varied between 0.08 and 0.49 nM, stages II and III being less sensitive. The highest dosage of sGnRHa (100 nM) led to a reduction of GTH secretion. In the first three stages, the pituitary secreted large amounts of free alpha-subunit while free GTH II beta-subunit was not detected at any stage of development. Antisera against GTH II and its alpha- and beta-subunits were used for immunocytochemical studies. In stages I and II, two subtypes of gonadotrophs, which differed in the size and labeling intensity of their secretory granules, were present. Both types of granules were immunopositive for the two subunits of GTH II. In stages III and IV, only gonadotrophs of the subtype with the larger granules were found. Globules and irregular, membrane-bound masses (IMs), probably arising through fusion of secretory granules, appeared in the gonadotrophs in stage III and became more prominent in stage IV. Globules and IMs were immunopositive for the beta-subunit but negative for the alpha-subunit. We conclude that the two subtypes of gonadotrophs represent different developmental stages of GTH II-producing cells, as they shared immunolabeling for the alpha- and the beta-subunits of GTH II. The scarcity of GTH II beta-subunit may be rate-limiting for the amount of intact GTH II available for secretion, particularly at early stages of development. In contrast, at more advanced stages when the readily releasable pool of GTH II has greatly increased, the amount of GTH II also appears to be controlled by modification or elimination of the alpha-subunit from globules and IMs.
Pituitary gonadotrophs were studied in male African catfish between 1 and 37 wk of age using antisera against the LH subunits for immunohistological and radioimmunological purposes, and cRNA probes for in situ hybridization. Immunoreactive material was already detectable at the earliest age examined. In juveniles, the signal for the common glycoprotein alpha subunit (GP alpha) was stronger than that for the LH beta subunit. Accordingly, an excess of radioimmunoassayable GP alpha 100 times that of LHbeta was recorded in the pituitary. Using in situ hybridization, the mRNAs were detected 7 (GP alpha) and 13 (LHbeta) wk after hatching. Detection of LHbeta mRNA coincided with a 300-fold increase in the pituitary content of LHbeta and intact LH, whereas GP alpha increased only 15-fold. The number of gonadotrophs per pituitary and the amount of LH per gonadotroph also increased strongly. The strong, initial increase in pituitary LH levels was always associated with the presence of spermatocytes. However, in a limited number of cases (3 out of 12 fish), the pituitary LH content was low despite the presence of spermatocytes. The number of gonadotrophs, the staining intensities (reflecting protein and mRNA), and the pituitary LH content kept increasing, although at a reduced rate, until completion of the first wave of spermatogenesis. In view of the excess of GP alpha over LHbeta, we conclude that expression of the two subunits is regulated in part by different mechanisms, and that expression of LHbeta is rate-limiting for the amount of intact LH. The strong activation of the gonadotrophs shortly after meiosis opens the possibility that a signal of testicular origin stimulates LH expression, in particular its beta subunit. In the absence of a FSH-like gonadotropin in catfish, we propose that LH covers all functions requiring gonadotropic regulation in the African catfish.
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