Interactions between immature porcine Leydig and Sertoli cells in vitro

Summary Interactions between Leydig and Sertoli cells, as well as a stimulatory effect of FSH on Leydig cell activity, have been reported in many studies. In order to investigate these interactions, the ultrastructure of immature pig Leydig cells under different culture conditions has been studied. When cultured alone in a chemically defined medium, there is a marked regression of the Leydig cell smooth endoplasmic reticulum and a swelling of the mitochondria. Addition of FSH or hCG does not prevent these phenomena. Co-culturing of Leydig cells with Sertoli cells from the same animal maintains the smooth endoplasmic reticulum at the level seen in vivo and in freshly isolated Leydig cells. The addition of FSH to the co-culture stimulates its development and increases Leydig cell activity, as assessed by an increase in hCG binding sites and an increased steroidogenic response to hCG. These results suggest that Sertoli cells exert a trophic effect on Leydig cells, and that the stimulatory effect of FSH on Leydig cell function is mediated via the Sertoli cells. These results reinforce the concept of a local regulatory control of Leydig cell steroidogenesis.Post-Doctoral fellow supported by CIRIT, Generalitat de Catalunya, Spain     

Catecholamine stimulation of androgen production by rat Leydig cells. Interactions with luteinizing hormone and luteinizing hormone-releasing hormone

The mechanism(s) of the development of response to catecholamines (CA) by Leydig cells in culture was investigated with the use of primary culture of purified Leydig cells of adult rats. The interactions of a CA agonist, isoproterenol (ISOP), with luteinizing hormone (LH) and a luteinizing hormone-releasing hormone agonist analog (LHRHa) on production of androgen by the Leydig cells were also studied. Cells incubated with ISOP for 3 h increased release of cyclic adenosine 3',5'-monophosphate (cAMP) to similar extents at 0, 3, and 24 h of culture. The beta-agonist did not increase androgen release at 0 h but had a concentration-dependent effect at 3, 24, and 48 h of culture, with maximal effects at 24 h. LH stimulated high increases in production of cAMP and androgen by the cells at 0-24 h of culture. Leydig cell beta-receptors decreased with culture time. Low concentrations but not high levels of LH had additive effects with ISOP on androgen release. ISOP showed a complex interaction with LHRHa on androgen release. Chronic exposure of Leydig cells to LHRHa reduced basal androgen release as well as release of androgen stimulated by ISOP, forskolin, and LH. These studies suggest that the development of response to CA by rat Leydig cells is a postreceptor, postcAMP event and showed that CA can interact with LH or LHRH to regulate Leydig cell function.     

Changes of oestrogen receptor levels in Leydig cells from mice and rats during culture

Two functional properties of Leydig cells in culture, i.e. LH-stimulated steroidogenesis and nuclear oestrogen receptor levels have been investigated. Leydig cells isolated from testes of immature rats and mature mice maintained their responsiveness to LH during 48-72 h of cell culture, although the mouse Leydig cells appeared to be less responsive to LH after 72 h of culture. In contrast, nuclear oestrogen receptor levels in both types of Leydig cells declined to 10-20% of the initial value after 24 h in culture. In the 48-72 h culture period nuclear oestrogen receptor levels recovered to 75% of the initial value only in Leydig cells from immature rats, whereas the nuclear oestrogen receptor levels in Leydig cells from mature mice remained low. These data demonstrate that during in vitro culture of Leydig cells, preservation of LH responsiveness does not necessarily warrant that other Leydig cell parameters e.g. nuclear oestrogen receptors also remain unaltered.     

The morphogenic effect of gonadotropic hormones on the Leydig cells of the boar testis. II. Effects of administration of chorionic gonadotropin after hypophysectomy. Effects in vivo and in organ culture

The longer ago the hypophysectomy has been performed, the more marked is Leydig cell atrophy in the testis. The effects of HCG on cellular morphology have been observed in vivo and in organ culture; qualitative quantitative and ultrastructural aspects were studied. In vivo, the effects of a daily injection of gonadotropin on the testis of 2 boars hypophysectomized 3 1/2 months ago are shown. Markedly atrophied cells are strongly stimulated by HCG during the 15 first days (the cell and nucleus recover nearly to standard size, with the typical histological and ultrastructural appearance with all the cell organelles which characterize a functional steroid cell). Then after 1 1/2 month injection it decreases again to the initial state (very small size cytoplasm strongly reduced with very low organelle content). The number of the Leydig cells is maintained during the first 15 days, then it progressively decreases. The effects of HCG on the testicular tissue of 4 boars were studied in organ culture. Interstitial tissue with a greater or lesser degree of atrophy was examined experimentally (1 month, 3 months and 4 months after hypophysectomy) in order to prove a possible irreversibility of the effects of hypophysectomy. In each case, cell changes were studied according to the duration of the culture. Control cultures without HCG in the medium were set up simultaneously. 1 month and/or 3 months after hypophysectomy, the Leydig cells in culture progressively recover the size and the histological and ultrastructural appearances of a typical Leydig cell. After 16 days of culture, the stimulation is highest, as in vivo. The number of Leydig cells is maintained. From the 17th day stimulation decreases and the cell enters a new atrophy phase. In the anhormonal control medium the atrophy continues as long as the culture is maintained, and the number of Leydig cells decreases. 4 months after hypophysectomy, stimulation in culture is still possible during the first 10 days (proved by the same tests); however the size of the cell remains small compared to the normal; then it atrophies again quickly. In this case the hormone does not maintain the number of the Leydig cells. In the control cultures, slight response of the cell is observed, but this effect is limited and disappears a few days later; the number of the cells rapidly decreases. It has been shown that markedly atrophied Leydig cells can highly be stimulated during the first 2 weeks under the influence of HCG as well in vivo as in organ culture. The lability of the effect is not yet explained. 4 months after hypophysectomy, stimulation is not so effective.     

Hormonal regulation of differentiation of human fetal prostate and Leydig cells in vitro

Trowell type of organ culture was used for correlative study of the human fetal prostate and Leydig cell differentiation at the ultrastructural level. Androgens accelerated the differentiation of human urethral epithelial cells into secretory prostatic cells and the ultrastructure resembled that in vivo. Also Leydig cells retained in organ culture the same ultrastructural features as in vivo and human chorionic gonadotropin (hCG) accelerated their differentiation. It is concluded that this type of culture technic can be used in the study of early differentiation of human genital organ and androgenes and hCG take part of human prostatic and Leydig cell differentiation.     

Regulation of tissue-type plasminogen activator and plasminogen activator inhibitor type-1 in cultured rat Sertoli and Leydig cells

New data are provided to show that (i) rat Sertoli cells produce two types of plasminogen activators, tissue type (tPA) and urokinase type (uPA), and a plasminogen activator inhibitor type-1 (PAI-1); (ii) both tPA (but not uPA) and PAI-1 secretion in the culture are modified by FSH, forskolin, dbcAMP, GnRH, PMA and growth factors (EGF and FGF), but not by hCG and androstenedione (△4); (iii) in vitro secretion of tPA and PA-PAI-1 complexes of Sertoli cells are greatly enhanced by presence of Leydig cells which produce negligible tPA but measurable PAI-1 activity;(iv) combination culture of Sertoli and Leydig cells remarkably increases FSH-induced PAI-1 activity and decreases hCG- and forskolin-induced inhibitor activity as compared with that of two cell types cultured alone. These data suggest that rat Sertoli cells, similar to ovarian granulosa cells, are capable of secreting both tPA and uPA, as well as PAI-1. The interaction of Sertoli cells and Leydig cells is essential for the cells to response to     

Differences between the regulation of cholesterol side-chain cleavage in Leydig cells from mice and rats

A Leydig cell culture system has been used to study the in vitro modulation by luteinizing hormone (LH) of steroidogenesis in Leydig cells isolated from mice and immature rats. Mouse Leydig cells precultured for 24 h in the presence of increasing concentrations of LH (1 ng-1 microgram/ml) showed a dose-dependent decrease of the maximal LH-stimulated testosterone production. After pretreatment with 1 microgram LH/ml, maximal LH-stimulated testosterone production. After production in the presence of excess 20 alpha-hydroxycholesterol (a cholesterol side-chain cleavage substrate) were reduced to approx. 50% of control values. The possible site of action of LH is probably prior to pregnenolone, because testosterone production in the presence of excess pregnenolone was not affected by the LH pretreatment. Immature rat Leydig cells showed no decrease of maximal steroid production after 24 h culture in the presence of 1 microgram LH/ml. These results indicate that the regulation of the cholesterol side-chain cleavage activity during long-term LH action is different in mouse and rat Leydig cells. The properties of the cholesterol side-chain cleavage enzyme in mouse and rat Leydig cells were further investigated with different hydroxylated cholesterol derivatives as substrates. Steroid production by mouse Leydig cells in the presence of (22R)-22 hydroxycholesterol was similar as in the presence of LH. In contrast, steroidogenesis in rat Leydig cells in the presence of (22R)-22 hydroxycholesterol was at least 10-fold higher than in the presence of LH. It is concluded that the cholesterol side-chain cleaving enzyme in the mouse Leydig cell operates at its maximal capacity during short-term LH stimulation and can be inhibited after long-term LH action, whereas in the rat Leydig cell only a fraction of the potential activity is used during short-term LH stimulation, which is not affected during long-term LH action.     

Paracrine control of Leydig cell activity by FSH dependent proteins from Sertoli cells: an in vitro study

The regulating effect of follicle-stimulating hormone (FSH) on Leydig cell function was studied using a model of immature porcine Leydig and Sertoli cells cultured in a hormone supplemented defined medium. FSH pretreatment for 2 days of Leydig cells cultured alone was with no effect. FSH pretreatment of Leydig cells cocultured with Sertoli cells increases Leydig cell activity in an FSH dose-dependent manner with a maximal effect observed at 50 ng/ml porcine FSH (pFSH). Leydig cells cultured for 2 days in conditioned medium (CM) by FSH stimulated (FSH-CM) Sertoli cells, as compared to CM by unstimulated (control) (C-CM) Sertoli cells show an increase of their activity with a maximal effect observed at 50 ng/ml pFSH. Leydig cells cultured in CM as compared to non CM, show a marked development of organelles (smooth endoplasmic reticulum and mitochondria) involved in the steroidogenic activity. The activity of FSH-CM as compared to C-CM on Leydig cell function was non dialyzable and trypsin sensitive. These data suggest that Sertoli cells exert a regulatory action on Leydig cell steroidogenic activity via FSH dependent secreted proteins.     

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.     

Developmental stages of fetal-type Leydig cells in prepubertal rats

Fetal Leydig cells were studied in rats during and after the perinatal-neonatal period by comparing changes in morphology, number and volume with changes in testicular steroids and serum luteinizing hormone (LH) concentration. Stereologic examination indicated regression of fetal Leydig cells in testis by showing that their total volume as well as the average cell volume decreased between prenatal day 20 and postnatal day 3. The total number and total volume of cells both increased between postnatal days 3 and 11 but the average cell volume did not change during the same time period. Determination of serum LH showed a close correlation between an increase in LH concentration and increases in total number and volume of cells. The combined number of fetal- and adult-type Leydig cells on day 20 was more than 20 times the number of fetal cells at 3 days of age. Electron microscopic analysis showed that fetal Leydig cells after birth formed conspicuous clusters, which were surrounded by a layer of envelope cells and extracellular material. Occasional dividing fetal Leydig cells and possible precursors of fetal or adult Leydig cells were observed. Mitoses of spindle-shaped pericordal cells were frequent during the neonatal period. During and after the second postnatal week fetal Leydig cells again showed signs of regression, indicated by disintegration of the cell clusters, a decrease in cell size, accumulation of collagen between the cells and a decrease in steroid content per cell.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stress hormone and male reproductive function

The Leydig cell is the primary source of testosterone in males. Levels of testosterone in circulation are determined by the steroidogenic capacities of individual Leydig cells and the total numbers of Leydig cells per testis. Stress-induced increases in serum glucocorticoid concentrations inhibit testosterone-biosynthetic enzyme activity, leading to decreased rates of testosterone secretion. It is unclear, however, whether the excessive glucocorticoid stimulation also affects total Leydig cell numbers through induction of apoptosis and thereby contributes to the stress-induced suppression of androgen levels. Exposure of Leydig cells to high concentrations of corticosterone (CORT, the endogenously secreted glucocorticoid in rodents) increases their frequency of apoptosis. Studies of immobilization stress indicate that stress-induced increases in CORT are directly responsible for Leydig cell apoptosis. Access to glucocorticoid receptors in Leydig cells is modulated by oxidative inactivation of glucocorticoid by 11β-hydroxysteroid dehydrogenase (11βHSD). Under basal levels of glucocorticoid, sufficient levels of glucocorticoid metabolism occur and there is likely to be minimal binding of the glucocorticoid receptor. We have established that Leydig cells express type 1 11βHSD, an oxidoreductase, and type 2, a unidirectional oxidase. Generation of redox potential through synthesis of the enzyme cofactor NADPH, a byproduct of glucocorticoid metabolism by 11βHSD-1, may potentiate testosterone biosynthesis, as NADPH is the cofactor used by steroidogenic enzymes such as type 3 17β-hydroxysteroid dehydrogenase. In this scenario, inhibition of steroidogenesis will only occur under stressful conditions when high input amounts of CORT exceed the capacity of oxidative inaction by 11βHSD. Changes in autonomic catecholaminergic activity may contribute to suppressed Leydig cell function during stress, and may explain the rapid onset of inhibition. However, recent analysis of glucocorticoid action in Leydig cells indicates the presence of a fast, non-genomic pathway that will merit further investigation.     

Multiple regulation of testicular steroidogenesis

One single injection of ethylene dimethane sulfonate (EDS) to mature rats causes specific degeneration of testicular Leydig cells which is complete after 3 days. At this time no steroidogenic activities can be detected, indicating that Leydig cells are the source of steroids. The mechanism of this cytotoxic effect of EDS has been investigated with isolated cells. Extensive protein alkylation has been shown to occur in Leydig cells, Sertoli cells and hepatocytes. Steroid production by Leydig cells is always inhibited by EDS, but cytotoxic effects of EDS could only be demonstrated in Leydig cells from mature rats or tumour tissue and not in Leydig cells from immature rats. A new population of Leydig cells develops during the next 2-5 weeks after EDS treatment. In hypophysectomized rats this repopulation only occurs when hCG is given daily. FSH has no effects. The proliferative activity in the interstitial tissue increases within 2 days after administration of hCG or EDS and there are indications that LH and locally produced factors are involved in the proliferation of Leydig cells or Leydig cell precursor cells. Inhibition of cAMP production with inhibitors of adenylate cyclase results in an enhancement of the LH-stimulated steroid production similar to that observed with an LHRH agonist and phospholipase C (PLC). Since the effects of LHRH and PLC on protein phosphorylation and steroid production are similar and different from LH or active phorbol esters, it is proposed that LHRH and PLC may stimulate steroid production via liberation of calcium from a specific intracellular pool. Sterol carrier protein2 (SCP2) which is specifically localized in Leydig cells and regulated by LH probably plays a role in the delivery of cholesterol to the mitochondria although the mechanism of this carrier function is not clear. The results indicate that regulation of Leydig cell development and the steroidogenic activities by gonadotrophins and locally produced factors occur via different transducing systems and regulatory pathways.     

Adhesion, shape, proliferation, and gene expression of mouse Leydig cells are influenced by extracellular matrix in vitro

Interactions between Leydig cells and the extracellular matrix (ECM) within the interstitial compartment of the mammalian testis have not been characterized. We have examined the influence of ECM on adult mouse Leydig cells by culturing the cells on different ECM substrates. Leydig cells adhere weakly to hydrated gels of type I collagen (including those supplemented with collagen types IV, V, or VIII), or to air-dried films of collagen types I, V, or VIII. In contrast, the cells attach firmly to substrates of purified type IV collagen, fibronectin, or laminin. Leydig cells also attach rapidly and adhere strongly to gelled basement membrane matrix derived from the murine Englebreth-Holm-Swarm sarcoma (Matrigel). Leydig cells assume spherical shapes and form aggregates on thick (1.5-mm) layers of Matrigel; however, on thin (0.1-mm) layers, networks of cell clusters linked by cords of elongated cells are formed within 48 h. Similar networks are formed on thick layers of Matrigel that are supplemented with type I collagen. On substrates with high ratios of collagen I to Matrigel or on untreated tissue culture plastic, Leydig cells flatten and do not aggregate. On substrates that induce rounded shapes, proliferation is inhibited and the cells maintain the steroidogenic enzyme 3 beta-hydroxysteroid dehydrogenase for as long as 2 wk. Under conditions where Leydig cells are flattened, they divide and cease expressing the enzyme. Proliferating Leydig cells also exhibit elevated levels of mRNA for SPARC (Secreted Protein, Acidic and Rich in Cysteine), a Ca2(+)-binding glycoprotein associated with changes in cell shape that accompany morphogenesis and tissue remodeling. Our results indicate that the shape, association, proliferation, and expression of gene products by Leydig cells can be significantly affected in vitro by altering the composition of the extracellular substratum.     

Stimulation of TM3 Leydig cell proliferation via GABA<Subscript>A</Subscript> receptors: A new role for testicular GABA

The neurotransmitter gamma-aminobutyric acid (GABA) and subtypes of GABA receptors were recently identified in adult testes. Since adult Leydig cells possess both the GABA biosynthetic enzyme glutamate decarboxylase (GAD), as well as GABA_A and GABA_B receptors, it is possible that GABA may act as auto-/paracrine molecule to regulate Leydig cell function. The present study was aimed to examine effects of GABA, which may include trophic action. This assumption is based on reports pinpointing GABA as regulator of proliferation and differentiation of developing neurons via GABA_A receptors. Assuming such a role for the developing testis, we studied whether GABA synthesis and GABA receptors are already present in the postnatal testis, where fetal Leydig cells and, to a much greater extend, cells of the adult Leydig cell lineage proliferate. Immunohistochemistry, RT-PCR, Western blotting and a radioactive enzymatic GAD assay evidenced that fetal Leydig cells of five-six days old rats possess active GAD protein, and that both fetal Leydig cells and cells of the adult Leydig cell lineage possess GABA_A receptor subunits. TM3 cells, a proliferating mouse Leydig cell line, which we showed to possess GABA_A receptor subunits by RT-PCR, served to study effects of GABA on proliferation. Using a colorimetric proliferation assay and Western Blotting for proliferating cell nuclear antigen (PCNA) we demonstrated that GABA or the GABA_A agonist isoguvacine significantly increased TM3 cell number and PCNA content in TM3 cells. These effects were blocked by the GABA_A antagonist bicuculline, implying a role for GABA_A receptors. In conclusion, GABA increases proliferation of TM3 Leydig cells via GABA_A receptor activation and proliferating Leydig cells in the postnatal rodent testis bear a GABAergic system. Thus testicular GABA may play an as yet unrecognized role in the development of Leydig cells during the differentiation of the testicular interstitial compartment.     

A synergistic effect of insulin-like growth factor (IGF-I) on equine luteinizing hormone (eLH)-induced testosterone production from cultured Leydig cells of horses

Localization of IGF-I and IGF-IR were observed in Leydig cells of horses using immunohistochemistry (IHC), suggesting IGF-I may play a role in equine Leydig cell steroidogenesis. Previous studies in other species have indicated that IGF-I increases basal and/or LH/hCG-induced testosterone production. The objectives of this study were to (1) test the synergistic effect of IGF-I on eLH-induced testosterone production in cultured equine Leydig cells and (2) determine if this effect is reproductive stage-dependent. Testes were collected from five pubertal (1.1±0.1 year; 1-1.5 year) and eight post-pubertal (2.88±0.35 years; 2-4 years) stallions during routine castrations at the UC Davis Veterinary Hospital. Leydig cells were isolated using validated enzymatic and mechanical procedures. Leydig cells were treated without (control) or with increasing concentrations of purified pituitary-derived eLH and/or recombinant human IGF-I (rhIGF-I) and incubated under 95% air: 5% CO(2) at 32°C for 24h. After 24h, culture media was collected and frozen at -20°C until analyzed for testosterone by a validated radioimmunoassay (RIA). In pubertal stallions, treatment with both increasing concentrations of rhIGF-I and 5ng/ml of eLH failed to demonstrate a significant difference in testosterone production compared with 5ng/ml of eLH only. However, in post-pubertal stallions, a significant increase in the concentration of testosterone in culture media was observed from Leydig cells treated with various concentrations of rhIGF-I and 1 or 5ng/ml of eLH compared with 1 or 5ng/ml of eLH only. In conclusion, IGF-I has a synergistic effect on eLH-induced testosterone production in cultured equine Leydig cells from post-pubertal but not pubertal stallions.     

Gonadotropin-induced changes in the luteinizing hormone receptors of cultured Leydig cells. Evidence of up-regulation in vitro

Previous in vivo studies have demonstrated that gonadotropic desensitization of luteinizing hormone/human chorionic gonadotropin (hCG) receptors and steroid responses is preceded by an early phase of receptor up-regulation. Hormonal desensitization has been recently reproduced in an in vitro Leydig cell culture, which has now been applied to studies on the early up-regulation of receptors. We performed comparative studies on the binding of 125I-hCG in isolated Leydig cells in plated culture and in suspension. In plated cells the total binding was up to 200% higher than that measured in suspension. This difference was not due to differential internalization. Preincubation with hCG in plated culture for 2 to 6 h increased the number of binding sites measured in suspension. The kinetics of the binding of labeled hCG to plated cells showed a secondary increase which reached its maximum after 3 h of incubation. This increase in hCG binding was not prevented by preincubation with inhibitors of protein synthesis and steroidogenesis or of microtubule or microfilament function. The sensitivities of the testosterone and cAMP responses to hCG in the plated cells were lower than those observed in suspension. These differences were maintained in the presence of a phosphodiesterase inhibitor. These results demonstrated that the cell interaction with a solid substratum is required for the acute up-regulation of the luteinizing hormone receptor and can induce changes in the Leydig cell responsiveness to gonadotropin stimulation.