Transforming growth factor-alpha and epidermal growth factor receptor gene expression and action during pubertal development of the seminiferous tubule.

The potential role of transforming growth factor-alpha (TGF-alpha) as a mediator of cell-cell interactions in the growth and development of the testis was examined. Developing rat testes were collected, and preparations of mesenchymal-derived peritubular cells and epithelial-like Sertoli cells were isolated from prepubertal, midpubertal, and late pubertal rat testes. The developmental expression of TGF-alpha and its receptor, the epidermal growth factor receptor (EGFR), in whole testis and isolated cell types was determined using a nuclease protection assay. TGF-alpha and EGFR gene expression were predominant early in testis development and decreased during pubertal development. TGF-alpha expression was greatest in prepubertal peritubular cells. Sertoli cell TGF-alpha expression remained relatively constant during development, with a slight decline at the later pubertal stages. EGFR gene expression was predominant in peritublar cells throughout development. A low level of EGFR expression was detected in Sertoli cells. Scatchard analysis confirmed the presence of high affinity receptors on peritubular cells; however, no functional receptors were detected on Sertoli cells from any stage of development examined. Interestingly, low-level EGFR gene expression was also detected in pachytene spermatocytes and round spermatids. TGF-alpha was found to stimulate [3H] thymidine incorporation into DNA and increase cellular proliferation of peritubular cells from each developmental stage, while having no effect on Sertoli cells. The in vivo physiological significance of TGF-alpha was evaluated in a line of transgenic mice which overexpress TGF-alpha in the mature testis. These transgenic animals had no abnormal testicular morphology or alterations in spermatogenesis. Observations demonstrate that gene expression of TGF-alpha and its receptor is high during early pubertal stages when somatic cell growth is predominant and low at late pubertal stages when somatic cell proliferation is reduced. TGF-alpha can act as an autocrine/paracrine mitogen for the mesenchymal-derived peritubular cell, while actions on the Sertoli cell population are not evident. The observation that spermatogenic cells express the EGFR gene, although the protein remains to be identified, implies that TGF-alpha may potentially mediate Sertoli-germinal cell interactions.     

Age-dependent changes in the in-vitro response of a pig Sertoli cell-enriched population to FSH

The response of pig Sertoli cell-enriched cultures to FSH was investigated by measuring plasminogen activator (PA) secretion in culture, throughout the nonpubertal and prepubertal periods. Sertoli cell-enriched populations could be isolated from birth until a testicular weight of 56 g. FSH elicited a dose-dependent increase in PA secretion by pig Sertoli cell-enriched cultures. The ED50 was minimal for cells coming from testes weighing 10-22 g, and increased more than 2-fold for cells from heavier testes. This suggests that, at the end of the non-pubertal period, an increased FSH sensitivity is important for initiation of spermatogenesis in this species, and that during the prepubertal period Sertoli cells become less sensitive to FSH. The FSH-stimulated PA secretion increased about 10-fold from a testicular weight of 25 g onwards, i.e. when primary spermatocytes appear in seminiferous tubules.     

Follicle-stimulating hormone-induced aromatase in immature rat Sertoli cells requires an active phosphatidylinositol 3-kinase pathway and is inhibited via the mitogen-activated protein kinase signaling pathway

Postnatal development and function of testicular Sertoli cells are regulated primarily by FSH. During this early period of development, estrogens play a role in proliferation of somatic cells, which contributes significantly to testicular development. Growth factors like epidermal growth factor (EGF) are produced in the testis and play a role in regulation of estradiol production and male fertility. Although these divergent factors modulate gonadal function, little is known about their mechanism of action in Sertoli cells. The present study investigates the intracellular events that take place down-stream of FSH and EGF receptors in Sertoli cells isolated from immature (10-d-old) rats, and examines which intracellular signals may be involved in their effects on aromatase activity and estradiol production in immature rat Sertoli cells. Primary cultures of rat Sertoli cells were treated with FSH in combination with EGF and signaling pathway-specific inhibitors. Levels of estradiol production, aromatase mRNA (Cyp19a1), and aromatase protein (CYP19A1) were determined. Western blot analysis was performed to determine the effects of FSH and EGF on levels of activated (phosphorylated) AKT1 and p42 ERK2 and p44 ERK1, also named MAPK1 and MAPK3, respectively. The stimulatory actions of FSH on aromatase mRNA, aromatase protein, and estradiol production were blocked by inhibition of the phosphatidylinositol 3-kinase/AKT1 signaling pathway. In contrast, inhibition of ERK signaling augmented the stimulatory effects of FSH on estradiol production, aromatase mRNA, and protein levels. Furthermore, EGF inhibited the expression of aromatase mRNA and protein in response to FSH, and these inhibitory effects of EGF were critically dependent on the activation of the ERK signaling pathway. We conclude that an active phosphatidylinositol 3-kinase /AKT signaling pathway is required for the stimulatory actions of FSH, whereas an active ERK/MAPK pathway inhibits estradiol production and aromatase expression in immature Sertoli cells.     

In vitro interactions between Sertoli cells and steroidogenic cells

Both the cell and the species specificities of the steroidogenic potentiating activity (SPA) of Sertoli cells on Leydig cells were studied using a coculture system. Coculture of purified pig Leydig cells with rat or pig Sertoli cells in the presence of FSH led in both cases, to a significant increase in hCG receptor number and in hCG-stimulated testosterone production. Similarly, coculture of bovine adrenal cells with rat or pig Sertoli cells enhanced the steroidogenic response of adrenal cells to ACTH and angiotensin II. Such effects were not observed when pig Leydig cells or bovine adrenal cells were cocultured with bovine aortic endothelial cells. Coculture of Sertoli and Leydig cells in the presence of hCG, resulted in a significant increase in FSH receptor number and in FSH-induced plasminogen activator activity. Such effects did not occur when Sertoli cells were cocultured with either adrenal or aortic endothelial cells.     

Retinoid modulation of plasminogen activator production in rat Sertoli cells

Tissue type (t) and urokinase type (u) plasminogen activators (PAs) have been shown to be secreted by Sertoli cells in the seminiferous tubules in a cyclic fashion and to be dependent upon FSH stimulation or upon the presence of adjacent spermatogenic cells. In the present study we have analyzed the production of PAs by retinoid-treated rat Sertoli cells. In addition, because retinoids modulate the response of Sertoli cells to FSH either potentiating or antagonizing its action, we have investigated a possible modulation of FSH-stimulated PA production. Under basal conditions, Sertoli cells, isolated from prepubertal rats, secrete predominantly uPA. A significant dose-dependent inhibition of uPA activity was observed after treatment with retinol, while no significant effect was detected upon tPA secretion. When Sertoli cells were cultured in the presence of 0.25 microM retinol, a significant inhibition of uPA activity was evident after 16 h of treatment and reached approximately 80% after 48 h of treatment. The analysis of the mRNA levels revealed that retinol induces an inhibition of the steady-state levels of uPA mRNA without affecting those of tPA. Moreover, retinol affected uPA mRNA levels by increasing mRNA turnover. The effect of retinoids on Sertoli cells isolated from older animals was less evident, possibly due to the reduced production of uPA with the increase of age of the donor animals. Our results on the effect of retinoids upon Sertoli cell uPA production reinforce the importance of retinoids in the control of postnatal testis development.     

Study of the superactivity of equine follicle-stimulating hormone in in vitro stimulation of rat Sertoli cells

We have previously shown that equine follicle-stimulating hormone (FSH) stimulates plasminogen activator secretion in Sertoli cells at much lower concentrations than would be expected from its relative binding activity. We have introduced the term 'superactivity' to designate this particular behavior. In the present study, we show that equine FSH triggers a long-lasting (20 h) plasminogen activator secretion, whereas rat, porcine and ovine FSH as well as equine LH and equine choriogonadotropin (CG) provoke a short-term response (2.5 h). Moreover, equine FSH was also shown to be superactive in the stimulation of estradiol secretion and cyclic AMP production. This indicates that the step responsible for the long-term stimulation by equine FSH is not located beyond cAMP accumulation. Equine and porcine FSH were found to be equally stable during incubation with the cells demonstrating that equine FSH superactivity was not due to higher stability. Besides, phosphodiesterase inhibition led to a similar increase in the responses to both hormones. This rules out the possibility that equine FSH superactivity is due to less stimulation of phosphodiesterase activity. All these data strongly suggest that equine FSH exhibits superactivity in rat Sertoli cells by stimulating adenylate cyclase activity for a much longer period of time than do all other gonadotropins. The molecular mechanism of this outstanding behavior remains to be elucidated.     

Transcriptional regulation of Sertoli cell differentiation (transferrin promoter activation) during testicular development

Previously testicular peritubular cells have been shown to produce a paracrine factor PModS that promotes Sertoli cell differentiation. This mesenchymal-epithelial cell interaction appears to regulate a number of Sertoli cell differentiated functions including transferrin gene expression. The current study was designed to identify PModS-activated response elements in the transferrin promoter and correlate this with Sertoli cell differentiation that occurs during testis development. The 3-kb transferrin promoter was digested down to approximately 200-bp fragments. Nuclear extracts from Sertoli cells stimulated with PModS were used in gel mobility shift assays. Two promoter regions located at ?2.4 kb and ?1.9 kb were designated SE1 and SE2. PModS promoted the presence of factors in Sertoli cell nuclear extracts that bind SE1 and SE2. Displacement studies demonstrated that SE1 and SE2 are distinct. A transferrin promoter-reporter construct containing these apparent response elements was activated by PModS, while a minimal transferrin promoter of 600bp excluding SE1 and SE2 was only partially stimulated by PModS. Therefore, PModS appears to in part activate the transferrin promoter through SE1 and/or SE2. Gel shift assays with Sertoli cell nuclear extracts and 20-day-old testis extracts were the same. Interestingly, the nuclear extract from a new-born testis also had a gel shift. Therefore, some of the nuclear factors stimulated by PModS in Sertoli cells and present in mid-pubertal testis were also present at birth upon completion of embryonic development. Previously transferrin expression has been shown to increase significantly at the onset of puberty. Observations indicate that PModS appears to in part promote transferrin expression through two newly identified response elements designated SE1 and SE2 and that the nuclear factors that bind these elements are present after embryonic development and mid-pubertally. © 1995 Wiley-Liss, Inc.     

The pubertal-related decline in cellular proliferation and neurogenesis in the dentate gyrus of male rats is independent of the pubertal rise in gonadal hormones

Pubertal development is marked by significant decreases in cellular proliferation and neurogenesis in the dentate gyrus of the hippocampal formation. Although it is unclear what mediates these developmental changes in the dentate gyrus, gonadal hormones have been implicated in modulating many neurobiological processes during puberty and various parameters of neurogenesis in adulthood. Thus, it is possible that the gradual and sustained increase in gonadal hormones experienced during puberty plays a role in these changes in neurogenesis. In this experiments, we first quantified cellular proliferation and neurogenesis using 5-bromo-2'-deoxyuridine (BrdU) and doublecortin (DCX) immunohistochemistry, respectively, in the dentate gyrus of prepubertal (30 d), midpubertal (45 d), and adult (90 d) male rats. We found the decline in BrdU and DCX cell numbers throughout these ages was coincident with increases in their plasma testosterone levels. We next tested whether exposure to the pubertal rise in gonadal hormones was necessary for this decrease in hippocampal neurogenesis to occur. Thus, we examined cellular proliferation and neurogenesis in intact 30 day (prepubertal) and 60-day-old (late-pubertal) rats, as well as 60-day-old rats that had previously been gonadectomized or sham-gonadectomized at 30 days of age. Although we again found the expected decline in BrdU and DCX cell numbers between 30 and 60 days of age in the intact groups, there were no differences among the 60-day-old animals, regardless of gonadal status. These data indicate that the pubertal-related decline in hippocampal cellular proliferation and neurogenesis is independent of the pubertal change in gonadal hormones.     

Rat testis 17 beta-estradiol: identification by gas chromatography-mass spectrometry and age related cellular distribution

The aromatization of testosterone into 17 beta-estradiol (E2) was assessed in purified Leydig and Sertoli cells from rats aged 10-80 days. E2 was identified by gas chromatography-mass spectrometry (GC-MS) and measured both by radioimmunoassay (RIA) and GC-MS associated with stable isotope dilution. A potent competitive inhibitor of the aromatase activity, 4-hydroxyandrostenedione (4-OH-A) was used to test the enzymatic specificity. The basal aromatase activity was present in both cell types whatever the age of the animals. The basal E2 levels did not vary in Sertoli cells while a gradual increase was noted in Leydig cells until day 40, followed by a slight decrease in mature rats. In 10-day old animals, the aromatase activity was localized in Sertoli cells and highly stimulated by FSH; on day 20, both Sertoli and Leydig cells synthesized E2 although E2 from Sertoli cell origin was still predominant. Starting on day 20 until adulthood, the aromatase activity was under LH control in Leydig cells with a maximum around 40 days. The FSH and LH effects were mediated by cyclic AMP.     

Secreted metalloproteinases in testicular cell culture

It is well known that cultured Sertoli cells secrete plasminogen activators (Lacroix et al., Mol Cell Endocrinol 1977; 9:227-236; Hettle et al., Biol Reprod 1986; 34:895-904). We now show that testicular cells in culture also secrete gelatinolytic metalloproteinases. Gelatin zymographic analysis of concentrated culture medium proteins reveals that Sertoli cells secrete gelatinases of 185 kDa, 110 kDa, 83 kDa, 76 kDa, and 72 kDa in addition to plasminogen activators (PAs). Gelatinase 185 kDa is induced by FSH. Media from Sertoli (epithelial)/peritubular (mesenchymal) cell cocultures contain the Sertoli cell gelatinases and one FSH-stimulated gelatinase of 50 kDa, indicating that gelatinase 50 kDa is regulated by both FSH and cell-cell interactions. A 50-kDa fibronectinolytic activity is also present in the coculture medium from cells grown in the presence of FSH. Casein zymography demonstrates a prominent 30-kDa protease only in media from cocultures. Peritubular cells secrete urokinase-type plasminogen activator (u-PA) and exhibit slight degrading activity at 86 kDa and 74 kDa. The gelatinases are most active in the pH range 7.3-8.5 and are completely or partially inhibited by metal ion chelators indicating that they are metalloproteinases. Our data demonstrate that testicular cells in culture secrete several gelatinases in addition to PAs, and that FSH and coculture conditions regulate some of these secreted proteases. We suggest that the highly regulated secretion of these proteases may well be of physiological importance during testicular development and spermatogenesis.     

In vitro regulation of pig Sertoli cell growth and function: effects of fibroblast growth factor and somatomedin-C

The effects of insulin, somatomedin-C (Sm-C), epidermal growth factor (EGF), fibroblast growth factor (FGF), vitamin E, and retinoic acid on growth and function of immature cultured pig Sertoli cells were investigated. All these factors, except vitamin E, stimulated Sertoli cell DNA synthesis and proliferation. The mitogenic effects of insulin observed only at micromolar concentrations were similar to those induced by nanomolar concentrations of Sm-C or EGF, but significantly less than those induced by FGF. The effects of EGF and Sm-C were almost additive, whereas those of Sm-C and FGF were synergistic. After a 6-day treatment, FGF and retinoic acid induced a significant increase in the number of follicle-stimulating hormone (FSH) receptors per cell, and in FSH-induced cyclic adenosine 3',5'-monophosphate (cAMP) production. Sm-C, which alone had no effect on these two parameters, potentiated FGF action. Basal plasminogen activator activity was enhanced after the 6-day treatment with EGF plus insulin and, particularly, with FGF plus insulin. Similarly, the response of the latter group to FSH was significantly higher than in any other group of cells. FGF was also able to stimulate cell multiplication and enhanced the FSH receptor number of Sertoli cells isolated from 15- and 26-day-old rats. Thus, FGF is the most potent known mitogenic factor for cultured Sertoli cells, and it stimulates the phenotypic expression of these cells.     

Paracrine role of Sertoli cells

Data from several experimental approaches strongly suggest that Sertoli cells exert a paracrine control of the two main testicular functions, androgen secretion and spermatogenesis. Further evidence supporting this role of Sertoli cells was obtained by coculture of Sertoli cells with other testicular cells. Coculture of pig or rat Sertoli cells with pig Leydig cells produces an increase in the hCG receptor number and an increase in the steroidogenic activity of Leydig cells. Pretreatment with FSH further increases the values of these two parameters. These biochemical changes were associated with ultrastructural changes in Leydig cells. The effects of Sertoli cells on Leydig cells depend upon the ratio of the two cells and on the substrate in which the cells are cultured. Moreover, Leydig cells produce an increase in the FSH receptor number and in the FSH stimulation of plasminogen activator production by Sertoli cells. Coculture of rat or pig Sertoli cells with rat germ cells, induces an increase in the RNA and DNA biosynthetic activities of germ cells. Most of the stimulatory effects seemed to be mediated by diffusible factors, secreted by Sertoli cells, but full expression of the stimulatory action was observed when germ cells were in contact with other cells. In this coculture system, a fraction of rat germ cells containing mainly mature forms of spermatocytes inhibited rat Sertoli cell RNA and DNA synthesis, but had no effect on pig Sertoli cells. On the contrary, a fraction of rat germ cells richer in spermatogonias and preleptotene spermatocytes, stimulated rat Sertoli cell DNA synthesis but was without effect on pig Sertoli cells. These results clearly show that the stimulatory effects of Sertoli cells on Leydig and on germ cells which are not species specific are mediated mainly by diffusible factors, the secretion of which is regulates by FSH.     

Increased peripheral aromatase activity in prepubertal children with partial androgen insensitivity syndrome

It has been suggested that rate of estrogen formation was higher in patients with androgen insensitivity syndrome (AIS). This work was designed to find out if peripheral aromatase activity could be related to a defect in androgen action in prepubertal children with male pseudohermaphroditism. Fibroblast estrogen production was assayed by a highly specific enzymatic determination. Foreskin fibroblast strains were raised from 17 children with partial androgen insensitivity (PAIS) as defined by dihydrotestosterone binding activity in cells. Results are expressed as pmol estrogens/mg proteins synthetized/day when cultured fibroblasts are incubated with D4-androstenedione. In normal prepubertal boys (n = 19), aromatase activity ranged between 5 and 10 pmol estrogens/mg proteins/day, while in postpubertal boys it varied between 15 and 34 pmol estrogens/mg proteins/day. In prepubertal boys with PAIS (n = 17) aromatase activity is highly elevated: 19.4 +/- 8.4 pmol/mg proteins/day. These results show that (a) peripheral aromatase activity is low before puberty and (b) fibroblast estrogen synthesis is significantly (p less than 0.001) increased in prepubertal children with PAIS. Our data suggest that low utilization of androgens by target cells stimulates the production of estrogen. Peripheral aromatase activity can thus be considered as a 'marker' of androgen insensitivity in prepubertal children with male pseudohermaphroditism.     

Spent media from immature seminiferous tubules and Sertoli cells inhibit adult rat Leydig cell aromatase activity

Adult rat Leydig cell aromatase activity is stimulated 2.5 fold by LH or dbcAMP. Spent media prepared from seminiferous tubules or Sertoli cells of immature rats depress both the basal and the LH stimulated estradiol syntheses (25 and 20% decreases, respectively). These inhibitory effects are further enhanced when FSH is added to the culture medium of seminiferous tubules or Sertoli cells. Rat serum as well as culture media from other cell lines are ineffective while seminiferous tubule media from other immature animals (mouse, guinea-pig, calf) inhibit the aromatase activity. This Sertoli cell factor is a heat stable protein (molecular weight greater than 10 kDa), different from the LHRH-like Sertoli cell compound, which acts on the aromatase activity at a step beyond the adenylate cyclase.     

Hormonal stimulation alters the type of plasminogen activator produced by Sertoli cells

Primary cultures of immature rat Sertoli cells, maintained in serum-free medium, secrete two types of plasminogen activator (PA). When cultured under basal conditions, the preparations predominantly produce PA having a relative molecular weight (Mr) of 45,000 to 48,000. This PA activity is inactivated by antiserum against urokinase-type PA. When Sertoli cells are stimulated by follicle-stimulating hormone (FSH) or by dibutyryl cyclic adenosine 3',5'-monophosphate (dbcAMP), PA secretion is increased. The PA produced under these conditions has an Mr of 70,000, and is inactivated by antiserum against tissue-type PA but not by antiserum against urokinase-type PA. We conclude that, under basal conditions, Sertoli cells primarily secrete PA having the characteristics of urokinase-like PA (mu PA), and that Sertoli cells stimulated by FSH or by dbcAMP predominantly produce PA having the properties of tissue-type PA (tPA). Segments of adult rat seminiferous tubules, at defined stages of the cycle of the seminiferous epithelium, also produce and secrete two types of PA into the medium when maintained in organ culture. Segments at all stages examined release primarily mu PA in preparations cultured under basal conditions. In contrast, segments cultured in the presence of FSH synthesize larger amounts of PA, predominantly of the tPA type. An additional protease, which is independent of plasminogen, is secreted by tubule segments stimulated by FSH. The activity of this novel protease is not detectable in cultures maintained under basal conditions. We discuss the data in relation to the possible role of proteases in the restructuring of the seminiferous tubule during spermatogenesis.