Mesenchymal entactin-1 (nidogen-1) is required for adhesion of peritubular cells of the rat testis in vitro.

Epithelial-like Sertoli cells isolated from immature rat testis aggregate to form tubule-like structures when cultured on a monolayer of mesenchyme-derived peritubular cells. At the end of this morphogenetic process both cell types are separated by a basement membrane. In this study the gene expression of monocultures and direct cocultures of peritubular cells and Sertoli cells was examined using DD-RT-PCR. One of the isolated cDNA clones showed high homology to the cDNA encoding the basement membrane component entactin-1 (nidogen-1). Even though the entactin-1 (nidogen-1) gene is transcribed in peritubular cells, Sertoli cells, and in direct cocultures, the mRNA is translated only by the peritubular cells. No entactin-1 (nidogen-1) was detected in the Sertoli cells by Western blotting. Moreover, peritubular cell monocultures and cocultures showed the presence of one single band at 152 kDa in the supernatant, whereas in cell lysates two bands were detectable at 152 kDa and 150 kDa. Perturbation experiments using monoclonal antibodies directed against entactin-1 (nidogen-1) were performed with peritubular cells and Sertoli cells, respectively, and demonstrated loss of cell adhesion of the peritubular cells, while the Sertoli cells remained adherent. From these data we conclude that entactin-1 is exclusively produced and secreted by mesenchymal peritubular cells, and affects adhesion of peritubular cells in an autocrine manner.

Heregulins or neu differentiation factors and the interactions between peritubular myoid cells and Sertoli cells.

Interactions between (mesenchymal) peritubular myoid cells and (epithelial) Sertoli cells play an important role in the control of Sertoli cell function and spermatogenesis. The factors involved, however, have only partially been identified. Heregulins or neu differentiation factors (NDFs) mediate mesenchymal-epithelial interactions in a variety of tissues, but their role in the testis has not been investigated. Here we demonstrate that recombinant human heregulin-alpha (Her-alpha) and Her-beta stimulate transferrin and androgen-binding protein production by cultured rat Sertoli cells up to 2.5-fold. These effects are more pronounced than those of previously identified growth factors active in this assay, such as insulin-like growth factor I and basic fibroblast growth factor. Combination with these factors results in additive effects and in marked morphological changes in the Sertoli cell cultures, including formation of tubule-like structures. Stimulation of androgen-binding protein secretion is paralleled by increased levels of the corresponding messenger RNA. This parallelism was less consistent for transferrin. Semiquantitative RT-PCR indicates that the expression of NDF-alpha and NDF-beta is more pronounced in peritubular cells than in Leydig or Sertoli cells. Conversely, the main receptors for heregulins/NDFs, HER-3 and HER-4, are predominantly expressed in Sertoli cells. A displacement assay confirms the presence of high-affinity binding sites for [125I]Her-beta on intact Sertoli cells and reveals parallel displacement curves for Her-beta, Her-alpha, and concentrated peritubular cell-conditioned medium (PTCM; estimated ED50 values: 1 ng/ml, 50 ng/ml, and 130 microg protein/ml, respectively), indicating that peritubular cells secrete one or more factors able to compete for heregulin receptors. It is concluded that heregulins/NDFs may play a role in mesenchymal-epithelial interactions in the testis. Estimates of the concentrations of heregulins in PTCM, however, make it unlikely that they contribute significantly to the effects observed with low concentrations of PTCM and ascribed to the putative mediator PModS (peritubular factor that modulates Sertoli cell function). Further investigations will be required to define the exact role of heregulins in the testis.

Cytokines derived from activated human mononuclear cells markedly stimulate transferrin secretion by cultured Sertoli cells.

There is considerable evidence that Sertoli cell function is controlled not only by hormones, but also by locally produced growth factors and cytokines. To gain more insight into the nature and effects of cytokines potentially involved in the control of Sertoli cell function, we incubated rat Sertoli cells with media conditioned by activated human peripheral blood mononuclear cells. Such media (PBMC-CM) are known to be an extremely rich source of a variety of cytokines. It was demonstrated that PMBC-CM and protein fractions derived from them stimulate Sertoli cell transferrin secretion and messenger RNA production more potently then peritubular cell-conditioned medium or FIRT (a combination of FSH, insulin, retinol, and testosterone). Transferrin secretion expressed per mg cell DNA was stimulated approximately 5-fold by peritubular cell-conditioned medium or FIRT and nearly 20-fold by PBMC-CM. The effects of PBMC-CM were accompanied by a limited increase in cAMP and a noticeable rise in cGMP. Affinity chromatography on a column coated with an antiserum directed against interleukin-1 beta (IL-1 beta) showed that part of the activity in the PBMC-CM was related to IL-1 beta. The remainder of the activity was largely retained by an affinity column coated with an antiserum that recognizes IL-6 and a number of other known and unknown cytokines. Purified IL-1 beta provoked a 2- to 3-fold stimulation of Sertoli cell transferrin secretion. More limited stimulatory effects were observed with IL-6. Neither of these cytokines or their combination approached the degree of stimulation observed with crude PBMC-CM, suggesting that other cytokines are involved. It is concluded that the mixture of cytokines present in PBMC-CM is a more powerful stimulator of Sertoli cell transferrin secretion than any other agonist known at the present time. IL-1 and IL-6 may be responsible for part of the observed effects, but one or more other cytokines are probably involved.

Characterization of newly established testicular peritubular and prostatic stromal cell lines: potential use in the study of mesenchymal-epithelial interactions.

Testicular peritubular and prostatic stromal cells produce extracellular matrix elements and paracrine factors that modulate the cytodifferentiation and function of the corresponding epithelial cells. The present paper describes the establishment and characterization of five rat testicular cell lines with peritubular characteristics and one prostatic stromal cell line. Four peritubular cell lines were isolated after transfection of a mixed peritubular-Sertoli cell culture with a v-myc-containing plasmid. The same immortalization procedure applied to prostatic stromal cells yielded one cell line. An additional testicular cell line arose by spontaneous immortalization during serial subculture. Except for one testicular cell line (RTC-8T1), the morphology of all of the immortalized cell lines strongly resembled that of primary cultures of peritubular and stromal cells. Flow cytometric analysis demonstrated that all cell lines scored positive for alpha-smooth muscle isoactin and negative for cytokeratins, confirming their myofibroblast-like nature. None of the cell lines, however, stained positive for alkaline phosphatase, and androgen receptor expression was also lost. Typical Leydig cell characteristics, such as steroidogenesis, and Sertoli cell markers, such as transferrin secretion, were absent. Coculture of the cell lines with Sertoli cells resulted in the formation of tubular structures. A cell attachment assay and an enzyme-linked immunosorbent assay for fibronectin confirmed the production of extracellular matrix elements by all of the established cell lines. Media conditioned by the cell lines stimulated Sertoli cell transferrin production. The active principle was partially purified and resembled the P-MOD-S-like factors produced by primary cultures of peritubular and stromal cells. It is concluded that the immortalized cell lines have retained several of the characteristics of primary cultures of peritubular and stromal cells and may be useful for further studies on mesenchymal-epithelial interactions in testis and prostate.

Identification of IL-6 as one of the important cytokines responsible for the ability of mononuclear cells to stimulate Sertoli cell functions.

There is increasing evidence that locally produced cytokines may play an important role in the control of testicular function. In a previous report we demonstrated that medium conditioned by activated human peripheral blood mononuclear cells (PBMC-CM), which is a rich source of cytokines, has extremely potent effects on Sertoli cell transferrin and cGMP secretion. Part of this activity could be explained by interleukin-1beta (IL-1beta) but additional cytokines were evidently involved. In the present study we tried to characterize and purify additional components active on Sertoli cells from PBMC-CM. To this end PBMC-CM was subjected to a purification procedure involving successively: adsorption to silicic acid, affinity chromatography with an antiserum recognizing a mixture of cytokines except IL-1beta, gel-filtration, reversed-phase HPLC and cation-exchange FPLC. Throughout this protocol a Sertoli cell bioassay was used to monitor the effects on transferrin and cGMP production. After cation-exchange FPLC, SDS-PAGE using silver staining showed a single protein band in the bioactive fractions. NH2-terminal amino-acid sequencing revealed that the active principle(s) in this band corresponded to four truncated forms of IL-6 missing the first 13, 14, 17 and 18 N-terminal amino-acids, respectively. The truncated IL-6 molecules were as active as intact IL-6 in the Sertoli cell bioassay. Since neither IL-1beta nor IL-6 alone or in combination could account for the extremely potent effect of PBMC-CM, we tested a series of additional cytokines (IL-1alpha, INF-alpha, IL-4, TGF-beta, IFN-gamma) alone and in combination with IL-1beta and IL-6. These data suggest that IL-1beta, IL-6 and TNF-alpha display more than additive effects on Sertoli cell transferrin and cGMP secretion and that the combination of these cytokines may explain the major part of the effects observed with crude PBMC-CM. The observation that the latter effects could be observed with murine as well as human IL-1beta, IL-6 and TNF-alpha further supports the potential physiological relevance of these findings.

Different cells and cell lines produce factors that modulate Sertoli cell function.

Peritubular myoid cells derived from immature rat testes produce factors that modulate Sertoli cell function (P-Mod-S). The secretion of these factors is controlled in part by androgens. Cultured prostatic stromal cells strongly resemble peritubular myoid cells and produce mediators with similar activity. Here we investigated whether myoid cell lines can be used as a source of P-Mod-S-like factors. Rat kidney fibroblast (NRK) and mouse fibroblast (3T3) cell lines were used as non-myoid controls. Surprisingly, serum-free media conditioned by all cell lines studied modulated Sertoli cell function in a similar fashion as media conditioned by peritubular cells (PTCM) or stromal cells (STCM). Using Sertoli cell transferrin secretion as an endpoint for P-Mod-S-like activity, the nature of the active principles involved was further explored. The observed activity could not be explained by residual contamination with fetal calf serum. Moreover, the effects of the conditioned media could not be mimicked by classical growth factors (IGF-I, bFGF, EGF, TGF-beta, NGF, PDGF-BB) added singly or in combination with submaximally effective concentrations of PTCM. Finally, the possibility that conditioned media might indirectly enhance Sertoli cell function by promoting the production or deposition of extracellular matrix elements was made unlikely by the demonstration that the observed effects were not mimicked by Matrigel and were unaffected when Sertoli cells were seeded on Matrigel. Superdex 75 chromatography after analytical reversed-phase chromatography indicates that the factors from different origin have a similar size (45-50 kDa). It is concluded that mediators with P-Mod-S-like activity are produced by various cells and cell lines both with and without smooth muscle cell characteristics. Whether the active principles involved are really identical requires further investigation.

Gelatinase A secretion and its control in peritubular and Sertoli cell cultures: effects of hormones, second messengers and inducers of cytokine production.

Extracellular matrix components as well as enzymes and enzyme-inhibitors controlling the turn-over of these components play an important role in the local control of testicular function. Zymographic analysis was used to study the secretion and the control of the secretion of gelatinase A (MMP-2) and B (MMP-9) by primary cultures of rat Sertoli cells and by subcultures of peritubular cells. Data on gelatinase A were complemented by measurement of the corresponding mRNA by Northern blot analysis. The agonists investigated included hormones (FSH, testosterone), second messengers (dbcAMP, phorbolester and a Ca(2+)- ionophore), interleukin-1 beta (IL-1 beta) and inducers of cytokine production (Concanavalin A: ConA; lipopolysaccharide: LPS; double stranded RNA: PIC). It is demonstrated that Sertoli cells originally secrete both gelatinase A and B. When maintained in serum-free medium, however, they rapidly lose the ability to secrete gelatinase B. After 3 days of culture gelatinase A remains the only measurable gelatinase in both Sertoli and peritubular cell cultures. The production in peritubular cells, however, exceeds that in Sertoli cells some 25-fold. This was confirmed by a 30-fold difference in the level of steady-state gelatinase A mRNA levels. Gelatinase A secretion and gelatinase A mRNA were stimulated by ovine FSH in Sertoli cells and by dbcAMP and ConA in both Sertoli and peritubular cells. IL-1 beta displayed measurable but limited stimulatory effects in both cell types. Interestingly, in peritubular cells but not in Sertoli cells, ConA stimulated the production of a lower MW species probably representing an activated form of gelatinase A. It is concluded that both the amounts of gelatinase A produced, the levels of the corresponding mRNA and the regulation differ in cultured peritubular cells and Sertoli cells. The lectin concanavalin A is a novel and potent inducer of gelatinase A. It resembles cytochalasin D in selectively inducing an activated form of gelatinase A in peritubular cells. The mechanism responsible for this selective effect warrants further investigation.

Peritubular cell-Sertoli cell interactions: factors involved in PmodS activity.

The widespread occurrence of peritubular myoid cells in mammalian and other species suggests that they form an integral and functional component of the testis. Peritubular cells contribute to the contractile activity of testicular tubules and maintain mesenchymal-epithelial interactions with Sertoli cells both by cooperation in the deposition of extracellular matrix elements and by secretion of paracrine agonists. One of the most intriguing of these paracrine agonists is known as PModS (Peritubular factor that Modulates Sertoli cell function). The demonstration that, at least under some conditions, PModS production may be stimulated by androgens has led to the hypothesis that PModS may mediate part or all of the effects of androgens on Sertoli cells. The identity of PModS, however, remains elusive. Here we summarize data showing: (1) that production of PModS (-like factors) may not be limited to peritubular cells; (2) that the role of androgens in the control of PModS production remains controversial; (3) that other known mediators including IGF-I, bFGF, cytokines and heregulins mimic some or all of the effects of PModS; (4) that combinations of such growth factors have potent effects. It is concluded that, until PModS has been identified unambiguously, the hypothesis that it acts as an essential andromedin in the testis should be regarded with caution.

Effect of androgens on the germ cell-depleted testes of prenatally irradiated rats.

To study the effect of androgens on somatic testicular cells, rats were rendered germ cell depleted by prenatal irradiation (RX). Adult RX rats were treated with a desensitizing dose of a GnRH agonist (GnRHa; Zoladex), combined with an antiandrogen (Nilutamide) to preclude all androgen effects, or combined with testosterone or hCG to restore androgen action. The effect of these treatments for 3 weeks on the weight of testes and accessory sex glands, hormones (LH, FSH, testosterone, inhibin), testicular proteins, the pattern of incorporation of [35S]-methionine into testicular proteins (studied by two dimensional gel electrophoresis) and steady state mRNA levels for transferrin and androgen-binding protein (ABP) were evaluated. Combined treatment with GnRHa and antiandrogen virtually eliminated gonadotrophins, androgens and androgen effects. Testicular weight was reduced to 50% of that observed in RX controls. Treatment with GnRHa and testosterone resulted in supraphysiological levels of testosterone and testicular weights comparable to those observed in RX controls. FSH levels in these animals, however, were in the normal range. A low dose of hCG also restored testicular weight in the presence of low concentrations of serum testosterone and low normal levels of FSH. Neither polyacrylamide gel electrophoresis of total testicular proteins nor two dimensional gel electrophoresis of [35S]-methionine labelled proteins revealed striking changes in distinct testicular proteins as a result of androgen withdrawal or androgen treatment. Dot blot hybridization showed a three-fold increase in the mRNA level for ABP (expressed per microgram total RNA) in the Sertoli cell enriched testes of RX rats. This level was barely influenced by androgen withdrawal or androgen administration. The mRNA level for transferrin was increased six-fold in RX rats. A 50% reduction of this level was observed after combined treatment with GnRHa and antiandrogen. It is concluded that, in the germ cell-depleted testis, the major effect of androgens is an overall increase in protein and RNA synthesis rather than a very important and selective increase of a few gene products.