Immunocytochemical localization of cytochrome P450 aromatase in the testis of prepubertal, pubertal, and postpubertal horses

The large amount of testicular estrogens produced by the stallion is unique compared to the amounts found in other domestic species. Although the cellular locale of the cytochrome P450 aromatase (P450arom) enzyme that converts C19 androgens to C18 estrogens has been identified in the Leydig cell of adult equine testis, the location in the immature equine testis is not known. The goal of this work was to localize the enzyme in colts and stallions during sexual development. Testes were obtained from prepubertal (n=7), pubertal (n=6), and postpubertal (n=8) colts and stallions during both the breeding and non-breeding seasons. Tissue was fixed and prepared for immunocytochemistry (ICC), carried out with an antiserum against human placental P450arom. In prepubertal colts, there was distinct immunopositive staining of a similar degree within both the Leydig cell and the seminiferous tubule. Horses in the pubertal group had strong Leydig cell immunopositive staining and a slight degree of positive staining within the seminiferous tubules. Postpubertal stallions exhibited definitive immunopositive staining within Leydig cells but not within the seminiferous tubules. Therefore, P450arom is present within the Leydig cell throughout sexual development. In contrast, the presence of P450arom within the seminiferous tubule based upon ICC appeared to be gone by adulthood, suggesting that an age-dependent shift in the locale of this enzyme as the stallion matures.     

Expression of anti-Müllerian hormone, cyclin-dependent kinase inhibitor (CDKN1B), androgen receptor, and connexin 43 in equine testes during puberty

Sertoli cells are essential in development of a functional testis. During puberty, Sertoli cell maturation can be characterized by a number of markers, including anti-Müllerian hormone (AMH) and its receptor (AMHR2), androgen receptor (AR), cyclin-dependent kinase inhibitor (CDKN1B), and connexin 43 (Cx43). In the present study, immunohistochemistry (IHC) and real-time quantitative polymerase chain reaction (RT-qPCR) were used to characterize changes in expression of AMH, AMHR2, AR, CDKN1B, and Cx43 in prepubertal, postpubertal, and adult equine testes. During puberty, AMH expression decreased, and expression of AR as well as CDKN1B increased in Sertoli cells coinciding with the period of Sertoli cell maturation, arrest of cell proliferation, and presumptive AMH regulation by testosterone. Expression of AMHR2 appeared to decrease in Sertoli cells and increase in Leydig cells during pubertal maturation of the equine testis. In addition, expression and distribution of Cx43 changed during puberty in the stallion, suggesting a role for Cx43 in Sertoli cell signaling and maturation, hormone secretion, and blood-testis barrier formation. We concluded that Sertoli cell maturation during puberty in the stallion was accompanied by a reduced expression of AMH and its receptor, arrest of cell proliferation, increased expression of AR, and organization of gap-junctional communication.     

Kinetic and autoradiographic studies on binding of hCG to the testicular LH receptors of neonatal rats

The properties of hCG binding to LH receptors of the neonatal (5-day-old) rat testis were analysed and compared with those of the adult testis. The equilibrium association constants (Ka) of hCG-binding were similar at both ages, 2-4 X 10(10) M-1. In contrast, kinetic binding studies revealed that the association and dissociation rate constants of hCG binding were more rapid in the neonatal testis. Likewise, it was observed that the progression from loose (easily dissociable) to tight (non-dissociable) binding was less complete in the young than in the adult testis. Autoradiography of 125I-labelled hCG binding to interstitial cell suspensions at the two ages showed that the gonadotrophin binding per Leydig cell was about 50% lower in the neonatal testis. Conversely, since the surface area of adult Leydig cells was about 4-fold larger, the receptor density appeared to be higher in the neonatal Leydig cells. The rapid recovery of LH receptors after hCG stimulation, typical of the neonatal cells, was due to rapid replenishment of binding in the cells initially occupied by the injected hormone, rather than to an hCG-induced increase of Leydig cell number. Finally, in-vivo experiments with cycloheximide revealed that the rapid recovery of LH receptors was dependent on protein synthesis. These differences in the kinetics of neonatal testicular LH receptor turnover may be involved in the unique functional features of the fetal-neonatal growth phase of rat testicular Leydig cells.     

Demonstration of distinct forms of testicular adenylate cyclases associated with germinal and Leydig cell fractions

Decapsulated testes from adult rats were digested with collagenase, and the fraction enriched in germinal and Leydig cells was applied to a 0-4% continuous metrizamide gradient and centrifuged. This leads to separation of a germinal cell fraction and two putative Leydig cell populations that bind human choriogonadotropin, but only one of which responds to the gonadotropin with marked increase in testosterone production. Adenylate cyclase activity was present in these three fractions, and Mn2+ was more effective than Mg2+ as a divalent cation. The adenylate cyclase activity associated with the germinal cell fraction was just marginally stimulated by fluoride and by the non-hydrolyzable GTP analog 5'-guanylimidodiphosphate, while that associated with the Leydig cell populations was stimulated to a greater degree depending upon the type of divalent cation. Only the Leydig cell populations exhibited marked human choriogonadotropin-sensitive stimulation of adenylate cyclase activity in the presence of 5'-guanylimidodiphosphate above that observed with the GTP analog alone. These results suggest the presence of distinct adenylate cyclases in adult rat testis and indicate that both populations of Leydig cells are capable of producing cyclic AMP in response to gonadotropins such as human choriogonadotropin.     

Percoll-gradient separation of Leydig cells from postnatal rat testes

The characteristics of the fetal and adult populations of Leydig cells from postnatal rat testes were compared by Percoll gradient centrifugation. A single peak of hCG binding, due to the presence of fetal Leydig cells, was obtained after purification of intertubular cells from 8-day-old animals. Two peaks of specific hCG binding were obtained after purification of intertubular cells from 15-day-old rats: it was confirmed by autoradiographic techniques that the hCG was bound by adult-like Leydig cells in one peak and fetal Leydig cells in the other. Similarly, intertubular cell preparations from 21- and 25-day-old rats resolved into two peaks of hCG binding; adult-like Leydig cells were observed in the first peak, but fetal Leydig cells were rarely observed in the second of these peaks. These results demonstrate the separation of two Leydig cell populations from intertubular cells obtained from animals aged up to 15 days. Thereafter the pattern of the hCG binding profile is similar but is not due to the presence of the same cell types. Therefore these results emphasize the necessity for morphological identification of cell types to permit the correct interpretation of the corresponding biochemical data.     

An enzymatic method for the isolation of mouse Leydig cells

Mouse Leydig cells were obtained by dispersion of testes of adult animals (aged 6-15 months) with a neutral protease from B. polymxa (dispase; EC 3.4.24.4). The crude Leydig cell suspension was purified by centrifugation on a discontinuous Percoll gradient using a special centrifugation procedure similar to elutriation. The crude cell suspension obtained from 50 testes could be processed in one run. The combination of these two methods yielded 320000 +/- 53000 Leydig cells/testis (n = 554 testes). The purity of the Leydig cell fraction was greater than or equal to 95% (nucleated cells) based on morphological and histochemical (staining for naphthyl esterase) identification. The purified Leydig cells showed an excellent ultrastructural appearance. More than 98% excluded trypan blue. In the presence of NADPH, testosterone biosynthesis was increased only 1.15 +/- 0.1-fold yielding a "quality factor" of 34.8. Maximal hCG doses induced 10(6) purified Leydig cells to produce 5 nmol testosterone/hr. (40-fold stimulation in comparison to basal values). The Leydig cells showed 43100 +/- 2500 LH/hCG receptors and an association constant of Ka = 1.95 x 10(9) M-1. Due to the reproducibility of the method, to the yield as well as to the morphological and functional state of the purified Leydig cells at least 25% of laboratory animals could be saved.     

Distributional map of the terminal and sub-terminal sugar residues of the glycoconjugates in the prepubertal and postpubertal testis of a subject affected by complete androgen insensitivity syndrome (Morris's syndrome): lectin histochemical study

In the present research we have investigated the distribution of the sugar residues of the glycoconjugates in the prepubertal and postpubertal testes of a subject with Morris's syndrome (CAIS, Complete Androgen Insensitivity Syndrome). For this purpose a battery of six horseradish peroxidase-conjugated lectins was used (SBA, PNA, WGA, ConA, LTA and UEAI). We have obtained a complete distributional map of the terminal and sub-terminal oligosaccharides in the tunica albuginea, interstitial tissue, lamina propria of the seminiferous tubules, Leydig cells, Sertoli cells, spermatogonia, mastocytes and endothelial cells. Furthermore the present study has shown that a large amount of sugar residues were detectable in the prepubertal and postpubertal testes but that some differences exist with particular regard to the Sertoli cells. The Sertoli cells and the Leydig cells of the retained prepubertal testis of the patient affected by Morris's syndrome were characterized by the presence of alpha-L-fucose, which was absent in the retained prepubertal testis of the normal subjects. Comparing the results on the postpubertal testis with those obtained on the same aged testis of healthy subjects we have demonstrated that alpha-L-fucose in the Sertoli and Leydig cells and D-galactose-N-acetyl-D-galactosamine in the Leydig cells are a unique feature of the subject affected by Morris's syndrome. D-galactose (ss1,3)-N-acetyl-D-galactosamine and sialic acid, which are present in the Leydig cells of the normal testis were never observed in the same cells of the postpubertal testis of the CAIS patient.     

Histochemical location of 17 beta-hydroxysteroid oxidoreductase in the adult and infantile human testis

17 beta-Hydroxysteroid oxidoreductase in the human testis was investigated histochemically using tissues obtained from seven patients with undescended testis or varicocele at the time of orchiopexy or high ligation of spermatic vein. Formazan precipitates were formed from nitro-blue tetrazolium in the tissue utilizing hydrogen released by oxidation of testosterone, which is catalyzed by the reductase function of 17 beta-hydroxysteroid oxidoreductase. The precipitates were formed specifically in the presence of 17 beta-hydroxy-C19-steroids under the conditions employed in the present study. In infantile testes, the precipitates were formed in cytoplasm of immature Sertoli cells, while in pubertal or adult testes, marked formazan precipitates were found in cytoplasm of both Sertoli and Leydig cells. The results indicate the presence of two distinct 17 beta-hydroxysteroid oxidoreductases in the human testis; one in Sertoli cells and detectable independent of age and the other only in functional Leydig cells.     

Luteinizing hormone receptor-mediated effects on initiation of spermatogenesis in gonadotropin-deficient (hpg) mice are replicated by testosterone

Testosterone (T) is an absolute requirement for spermatogenesis and is supplied by mature Leydig cells stimulated by LH. We previously showed in gonadotropin-deficient hpg mice that T alone initiates qualitatively complete spermatogenesis bypassing LH-dependent Leydig cell maturation and steroidogenesis. However, because maximal T effects do not restore testis weight or germ cell number to wild-type control levels, additional Leydig cell factors may be involved. We therefore examined 1). whether chronic hCG administration to restore Leydig cell maturation and steroidogenesis can restore quantitatively normal spermatogenesis and testis development and 2). whether nonandrogenic Leydig cell products are required to initiate spermatogenesis. Weanling hpg mice were administered hCG (0.1-100 IU i.p. injection three times weekly) or T (1-cm subdermal Silastic implant) for 6 weeks, after which stereological estimates of germinal cell populations, serum and testicular T content, and testis weight were evaluated. Human CG stimulated Leydig cell maturation and normalized testicular T content compared with T treatment where Leydig cells remained immature and inactive. The maximal hCG-induced increases in testis weight and serum T concentrations were similar to those for T treatment and produced complete spermatogenesis characterized by mature, basally located Sertoli cells (SCs) with tripartite nucleoli, condensed haploid sperm, and lumen development. Compared with T treatment, hCG increased spermatogonial numbers, but both hCG and T had similar effects on numbers of spermatocytes and round and elongated spermatids per testis as well as per SC. Nevertheless, testis weight and germ cell numbers per testis and per SC remained well below phenotypically normal controls, confirming the involvement of non-Leydig cell factors such as FSH for quantitative normalization of spermatogenesis. We conclude that hCG stimulation of Leydig cell maturation and steroidogenesis is not required, and that T alone mostly replicates the effects of hCG, to initiate spermatogenesis. Because T is both necessary and sufficient for initiation of spermatogenesis, it is likely that T is the main Leydig cell secretory product involved and that additional LH-dependent Leydig cell factors are not essential for induction of murine spermatogenesis.     

Leydig cell development

This review is about the study of the testis Leydig cells formation and development in prenatal and postnatal periods. Leydig cells of testis are the main place of synthesis and secretion of androgens including testosterone--the main male sexual hormone. Testosterone plays an important role in male reproduction regulation. There are two types (two populations) of Leydig cells during ontogenesis. The first type is fetal Leydig cells, which appear and function in the prenatal masculinization period of the male urogenital system. Another type is adult Leydig cells, which originate during sexual maturation postnatally. Fetal and adult Leydig cells pass the same stages both in the prenatal and postnatal periods. They are Leydig cell progenitors, immature Leydig cells and adult Leydig cells.     

The fate of fetal Leydig cells during the development of the fetal and postnatal rat testis

The ultrastructure and developmental fate of the fetal generation of Leydig cells of the rat testis was studied from the 17th day of fetal life up to 100 days after birth. The number of fetal Leydig cells per testis was determined by light microscopic morphometric analysis of semithin plastic sections. In fetal testes (days 17-22 postconception), Leydig cells exhibited a characteristic ultrastructure, containing smooth endoplasmic reticulum, many lipid inclusions and glycogen. Testes of 17-day-old fetuses contained about 25 x 10(3) fetal Leydig cells, rapidly increasing to 90 x 10(3) per testis in 21-day-old fetuses. After birth, fetal Leydig cells per testis remained relatively constant up to 2 weeks (80-90 x 10(3) per testis) and were identified by light and electron microscopy which showed their numerous lipid inclusions, their tendency for clustering and their association with interstitial tissue fibroblasts which partly encapsulated the fetal Leydig cells. From 21-100 days after birth, fetal Leydig cell numbers were quite variable with a mean of 45-60 x 10(3) per testis. These results are the first to show that the fetal generation of Leydig cells persist in the adult testis and do not undergo early postnatal degeneration or dedifferentiation into other interstitial cells. The simultaneous occurrence of the fetal Leydig cells and the adult population of Leydig cells indicates that these cells are distinct cell generations which are developmentally unrelated.     

Immunolocalization of PTHrP in prepubertal and pubertal testis of European bison

The present study deals with immunohistochemical localization of PTHrP in prepubertal and pubertal testis of European bison. PTHrP immunoreactivity was observed in germinal cells in the testis of both prepubertal and pubertal animals. In calves, PTHrP was found in germinal cells, in seminiferous tubules lacking the lumen. The reaction was strong and regularly distributed within the cytoplasm. In adult animals, the reaction showed differentiation in spermatogenic cells. Some cells were strongly and diffusely stained, others exhibited weaker reaction of granular pattern. Sertoli cells and Leydig cells were PTHrP-negative in calves and adult animals.     

In vitro effects of Celiptium and MR 14504 on mature rat Leydig cell testosterone production

Percoll-purified mature rat Leydig cells have been used to evaluate the testicular toxicity of two highly potent intercalating agents (Celiptium and MR 14505). Testosterone secretion in the absence and in the presence of human chorionic gonadotropin (hCG) was measured to assess Leydig cell function. Celiptium and MR 14504 induce time- and dose-related inhibitory effects on the production of testosterone by Leydig cells, both in the presence and in the absence of hCG, whatever the concentration of hCG used. We have observed that MR 14504 is about 5 times more potent as an inhibitor of rat Leydig cell steroidogenesis than Celiptium without inducing any cell toxicity. The present study indicates that the Leydig cell is an additional potential site for the primary toxic effects of these drugs in the adult rat testis.     

Differentiation of the adult Leydig cell population in the postnatal testis

Five main cell types are present in the Leydig cell lineage, namely the mesenchymal precursor cells, progenitor cells, newly formed adult Leydig cells, immature Leydig cells, and mature Leydig cells. Peritubular mesenchymal cells are the precursors to Leydig cells at the onset of Leydig cell differentiation in the prepubertal rat as well as in the adult rat during repopulation of the testis interstitium after ethane dimethane sulfonate (EDS) treatment. Leydig cell differentiation cannot be viewed as a simple process with two distinct phases as previously reported, simply because precursor cell differentiation and Leydig cell mitosis occur concurrently. During development, mesenchymal and Leydig cell numbers increase linearly with an approximate ratio of 1:2, respectively. The onset of precursor cell differentiation into progenitor cells is independent of LH; however, LH is essential for the later stages in the Leydig cell lineage to induce cell proliferation, hypertrophy, and establish the full organelle complement required for the steroidogenic function. Testosterone and estrogen are inhibitory to the onset of precursor cell differentiation, and these hormones produced by the mature Leydig cells may be of importance to inhibit further differentiation of precursor cells to Leydig cells in the adult testis to maintain a constant number of Leydig cells. Once the progenitor cells are formed, androgens are essential for the progenitor cells to differentiate into mature adult Leydig cells. Although early studies have suggested that FSH is required for the differentiation of Leydig cells, more recent studies have shown that FSH is not required in this process. Anti-Müllerian hormone has been suggested as a negative regulator in Leydig cell differentiation, and this concept needs to be further explored to confirm its validity. Insulin-like growth factor I (IGF-I) induces proliferation of immature Leydig cells and is associated with the promotion of the maturation of the immature Leydig cells into mature adult Leydig cells. Transforming growth factor alpha (TGFalpha) is a mitogen for mesenchymal precursor cells. Moreover, both TGFalpha and TGFbeta (to a lesser extent than TGFalpha) stimulate mitosis in Leydig cells in the presence of LH (or hCG). Platelet-derived growth factor-A is an essential factor for the differentiation of adult Leydig cells; however, details of its participation are still not known. Some cytokines secreted by the testicular macrophages are mitogenic to Leydig cells. Moreover, retarded or absence of Leydig cell development has been observed in experimental models with impaired macrophage function. Thyroid hormone is critical to trigger the onset of mesenchymal precursor cell differentiation into Leydig progenitor cells, proliferation of mesenchymal precursors, acceleration of the differentiation of mesenchymal cells into Leydig cell progenitors, and enhance the proliferation of newly formed Leydig cells in the neonatal and EDS-treated adult rat testes.     

Gonadotropin induction of a regulatory mechanism of steroidogenesis in fetal Leydig cell cultures

Studies were conducted to define further the development of the gonadotropin induced, E2 mediated steroidogenic lesion (17-alpha-hydroxylase/17,20-desmolase) in fetal Leydig cell cultures. Analysis of dispersed fetal testes purified by centrifugal elutriation demonstrated a group of cells with sedimentation velocity 12 less than to less than 16.8 mm/h.g containing a small population of adult like "transitional" Leydig cells and homogeneous "fetal" Leydig cell population collected at greater than 19.3 mm/h.g. After cells were cultured for 3 days with addition of 1 microgram oLH at 3 day intervals, the transitional cells showed testosterone accumulation comparable to the fetal cells. In contrast, transitional cells had 10-fold higher basal and hCG-stimulated aromatase activity than fetal cells, and a lack of testosterone response to acute (3 h) hCG stimulation. At day 6, transitional cells steroidogenic ability declined markedly. The fetal population maintained in culture with LH additions every 3 days, showed typical immature Leydig cell response, with enhancement of acute testosterone response to hCG at 3 day (1-fold) and at 6 day of culture (5-fold). Higher doses of LH (5 micrograms/day) or daily treatment of 1 microgram to fetal cultures, induced a lesion of 17 alpha-hydroxylase/17,20-desmolase with reduction of enzymatic activities (P less than 0.01) and impaired testosterone production (P less than 0.01) in response to acute hCG stimulation. Also aromatase was stimulated by hCG + 140% and 50% and E2 receptors were increased by 100 and 180% at 3 days and 6 days of cultures with daily or high dose LH addition, findings consistent with the observation of the E2-mediated lesion during LH action. In conclusion, the cultured fetal Leydig cell provides a useful model to elucidate molecular mechanisms involved in the development of gonadotropin-induced estradiol-mediated desensitization. Treatment of fetal Leydig cell cultures with multiple or frequent doses of LH elevate aromatase activity to necessary levels for the induction of desensitization. We have isolated small population of transitional Leydig cells with morphological characteristics of cells found in 15 day post-natal testis but functional capabilities of adult cells. We have also demonstrated the emergence of a functional adult-like population from the fetal Leydig cell.     

Morphological and functional variations of Leydig cells in testis of the domestic pig during the different biological stages of development

The relationship of morphometrical and androgen receptor evaluations of the main testicular interstitium cellular element (Leydig cells) in the domestic pig provided interesting numerical and morphological features during the different aging stages. As early as 25 days (a period in which the pig is sexually immature) there was a low number of Leydig cells (1.46 x 10(8)) with respect to a 78% and 35% increase in the adult (2.48 x 108) and aged (1.78 x 10(8)) animal, respectively. Interestingly, when the volume density of Leydig cells was considered, the average volume of these cells seemed to be high (75%) in the aged pig with respect to the young immature animal whereas a lower increase (27%) was observed for the adult animal. Moreover, the evaluation of testosterone receptor binding sites in the testis at the various stages of development also displayed a differentiated pattern since elevated testosterone receptor binding levels of the high dissociation affinity type were obtained for the adult pig. Thus, from the combined morphological variations of Leydig cells and testosterone receptor binding activity, it appears that this androgenic receptor component exerts distinct autocrine effects on the different functional features of some testicular tissue constituents at the different aging stages of the domestic pig.     

Differentiation of adult Leydig cells

Adult Leydig cells originate within the testis postnatally. Their formation is a continuous process involving gradual transformation of progenitors into the mature cell type. Despite the gradual nature of these changes, studies of proliferation, differentiation and steroidogenic function in the rat Leydig cell led to the recognition of three distinct developmental stages in the adult Leydig cell lineage: Leydig cell progenitors, immature Leydig cells and adult Leydig cells. In the first stage, Leydig cell progenitors arise from active proliferation of mesenchymal-like stem cells in the testicular interstitium during the third week of postnatal life and are recognizable by the presence of Leydig cell markers such as histochemical staining for 3β-hydroxysteroid dehydrogenase (3β-HSD) and the present of luteinizing hormone (LH) receptors. They proliferate actively and by day 28 postpartum differentiate into immature Leydig cells. In the second stage, immature Leydig cells are morphologically recognizable as Leydig cells. They have an abundant smooth endoplasmic reticulum and are steroidogenically active, but primarily produce 5-reduced androgens rather than testosterone. Immature Leydig cells divide only once, giving rise to the total adult Leydig cell population. In the third and final stage, adult Leydig cells are fully differentiated, primarily produce testosterone and rarely divide. LH and androgen act together to stimulate differentiation of Leydig cell progenitors into immature Leydig cells. Preliminary data indicate that insulin like growth factor-1 (IGF-1) acts subsequently in the transformation of immature Leydig cells into adult Leydig cells.