Extra-ovarian expression and activity of growth differentiation factor 9.

Growth differentiation factor 9 (GDF9) produced within the ovary plays an essential role during follicle maturation through actions on granulosa cells, but extra-ovarian expression, signalling and actions of GDF9 are less well characterised. The present studies confirm GDF9 expression in the mouse testis, pituitary gland and adrenocortical cancer (AC) cells, and establish its expression in L beta T2 gonadotrophs, and in mouse adrenal glands, particularly foetal and neonatal cortical cells. AC, L beta T2, TM3 Leydig and TM4 Sertoli cells express the requisite GDF9 binding signalling components, particularly activin receptor-like kinase (ALK) 5 and the bone morphogenetic protein (BMP)/GDF type II receptor, BMPRII (BMPR2). We therefore compared GDF9 activation of these potential extra-ovarian target cell types with its activation of granulosa cells. Recombinant mouse GDF9 stimulated expression of activin/transforming growth factor-beta-responsive reporters, pGRAS-luc or pAR3-lux, in TM4 and AC cells (IC50=145 ng/ml in the latter case), and two granulosa cell lines, KGN and COV434. The ALK4/5/7 inhibitor, SB431542, blocked GDF9 activity in each case. By contrast, GDF9 lacked specific effects on TM3 cells and rat primary pituitary and mouse L beta T2 gonadotrophs. Our findings show that GDF9 regulates the expression of R-SMAD2/3-responsive reporter genes through ALK4, 5 or 7 in extra-ovarian (adrenocortical and Sertoli) cells with similar potency and signalling pathway to its actions on granulosa cells, but suggest that expression of BMPRII, ALK5 (TGFBR1) and R-SMADs 2 and 3 may not be sufficient for a cell to respond to GDF9.

Reducing betaglycan expression by RNA interference (RNAi) attenuates inhibin bioactivity in LbetaT2 gonadotropes.

Betaglycan is an inhibin-binding protein co-receptor, the forced expression of which confers inhibin responsiveness on cells previously non-responsive to inhibin. The present study determines whether removal of betaglycan expression in otherwise inhibin-responsive cells will render the cells insensitive to inhibin. Small interfering RNAs (siRNAs) designed to the betaglycan gene were transfected into LbetaT2 gonadotrope cells to 'knock-down' betaglycan expression. To control for non-specific effects, siRNAs corresponding to an unrelated sequence (BF-1) were used. Two activin-responsive promoter constructs were used to assess inhibin bioactivity; an ovine FSHbeta promoter (oFSHbeta-lux), and a construct containing three copies of the activin-responsive sequence from the GnRHR promoter (3XpGRAS-PRL-lux). Activin stimulated the activity of both promoters 5-8-fold. Inhibin suppressed these activin-stimulated promoter activities by 52+/-11% and 51+/-7%, respectively. Similar inhibin suppression was also seen for cells co-transfected with the control BF-1 siRNAs. In contrast, inhibin's ability to suppress activin-stimulated activity was significantly reduced (33+/-3%, p<0.005 and 24+/-4%, p<0.045, respectively) in cells co-transfected with betaglycan siRNAs. These results demonstrated that endocrine effects of inhibin as a negative feedback controller of FSH production in gonadotropes are dependent on betaglycan expression.

Loss of betaglycan contributes to the malignant properties of human granulosa tumor cells.

Betaglycan is a type III TGFbeta receptor that modulates cellular sensitivity to inhibins and TGFbeta. Previous studies have suggested that betaglycan acts as a tumor suppressor in certain human epithelial cancers. However, the roles of betaglycan in ovarian granulosa cell tumors (GCTs) are poorly understood. The objective of this study was to determine whether human GCTs exhibit betaglycan expression and, if so, what impact this receptor has on tumor biology. Real-time PCR was used to quantify betaglycan transcripts in human GCTs (n = 17) and normal premenopausal ovaries (n = 11). This analysis established that GCTs exhibited a significant 2-fold lower mean betaglycan mRNA level as compared with the normal ovary (P < 0.05). Similarly, two human GCT cell lines, KGN and COV434, exhibited low betaglycan expression and poor responsiveness to TGFbeta and inhibin A in luciferase reporter assays, which was restored by stable transfection of wild-type betaglycan. Betaglycan significantly increased the adhesion of COV434 (P < 0.05) and KGN (P < 0.0001) cells, decreased cellular invasion through Matrigel, and inhibited wound healing. Expression of mutant forms of betaglycan that are defective in TGFbeta and/or inhibin binding in each GCT cell line revealed that the inhibitory effects of betaglycan on wound healing were most strongly linked to the inhibin-binding region of betaglycan. Furthermore, knockdown of INHA mRNA expression abrogated the betaglycan-mediated inhibition of wound healing and invasion, whereas both INHA silencing and TGFbeta neutralization abolished the betaglycan-mediated increase in adhesion to substrate. These data suggest that loss of betaglycan contributes to the pathogenesis of GCTs.

Growth differentiation factor 9 is a germ cell regulator of Sertoli cell function.

Oocyte-secreted growth differentiation factor (GDF) 9 and bone morphogenetic protein (BMP) 15 are critical regulatory factors in female reproduction. Together, they promote granulosa cell proliferation and stimulate the maturation of preovulatory follicles. Despite their importance in female fertility, GDF9 and BMP15 expression patterns and function during spermatogenesis have not been investigated. In this study we show that the expression and stage-specific localization of both factors are limited to the germ cells of the rat seminiferous epithelium, with GDF9 being principally localized in round spermatids and BMP15 in gonocytes and pachytene spermatocytes. To identify potential cellular targets for GDF9 actions, cells of the seminiferous tubule were isolated and screened for the expression of signaling receptors [activin-like kinase (ALK) 5, ALK6, and BMP receptor, type II)]. Individual receptor types were expressed throughout the seminiferous epithelium, but coexpression of ALK5 and BMP receptor, type II was limited to Sertoli cells and round spermatids. Based on the reproductive actions of related TGFbeta ligands in the ovary and testis, GDF9 was assessed for its ability to regulate tight junction function and inhibin B production in rat Sertoli cell cultures. When recombinant mouse GDF9 was added to immature Sertoli cell cultures, it inhibited membrane localization of the junctional proteins claudin-11, occludin, and zonula occludens-1, thereby disrupting tight junction integrity. Concomitantly, GDF9 up-regulated inhibin subunit expression and significantly stimulated dimeric inhibin B protein production. Together, these results demonstrate that GDF9 and BMP15 are germ cell-specific factors in the rat testis, and that GDF9 can modulate key Sertoli cell functions.

Transforming growth factor-beta blocks inhibin binding to different target cell types in a context-dependent manner through dual mechanisms involving betaglycan.

Inhibin antagonizes activin and bone morphogenetic protein actions by sequestering their type II receptors in high-affinity complexes with betaglycan, a coreceptor that inhibin shares with TGF-beta. To clarify the nature and extent of interactions between inhibin and TGF-beta, we therefore examined 1) the mutual competition between these ligands for binding, 2) the regulation of endogenous betaglycan expression by inhibin and TGF-beta isoforms, and 3) the consequences of such betaglycan regulation for subsequent inhibin binding in mouse Leydig (TM3), Sertoli (TM4), adrenocortical cancer (AC), and gonadotroph (LbetaT2) cell lines, chosen to model cellular targets for local and endocrine actions of inhibin. Recognized inhibin, activin, and TGF-beta binding proteins and TGF-beta/activin signaling components were expressed by all four cell types, but AC and LbetaT2 cells notably lacked the type II receptor for TGF-beta, TbetaRII. Overnight treatment of TM3 and TM4 cells with TGF-beta1 suppressed the levels of betaglycan mRNA by 73 and 46% of control and subsequent [(125)I]inhibin A binding by 64 and 41% of control (IC(50) of 54 and 92 pm), respectively. TGF-beta2 acted similarly. TGF-beta pretreatments commensurately decreased the [(125)I]inhibin A affinity labeling of betaglycan on TM3 and TM4 cells. TGF-beta isoforms as direct competitors blocked up to 60% of specific inhibin A binding sites on TM3 and TM4 cells but with 9- to 17-fold lower potency than when acting indirectly via regulation of betaglycan. Only the competitive action of TGF-beta was observed with TbetaRII-deficient AC and LbetaT2 cells. Neither inhibin A nor inhibin B regulated betaglycan mRNA or competed for binding of [(125)I]TGF-beta1 or -beta2. Thus, inhibin binding to its target cell types is controlled by TGF-beta through dual mechanisms of antagonism, the operation of which vary with cell context and display different sensitivities to TGF-beta. In contrast, TGF-beta binding is relatively insensitive to the presence of either inhibin A or inhibin B.

Inhibins differentially antagonize activin and bone morphogenetic protein action in a mouse adrenocortical cell line.

Inhibin, a member of the TGF-beta superfamily, has been proposed to act as an inhibitor of activin and bone morphogenetic protein (BMP) by sequestering their type II receptors in nonsignaling complexes with betaglycan. This mechanism of inhibin action was tested in a mouse adrenocortical (AC) cell line by examining the effects of inhibins A and B on cytochrome P450 17alpha-hydroxylase 17,20-lyase (Cyp17) expression and 17alpha-hydroxylase activity, measured by progesterone 17alpha-hydroxylation, in the absence and presence of activin or BMP isoforms. Cyp17 mRNA endogenously expressed by AC cells was suppressed by activins A and B and BMP-2, -6, and -7, and each ligand accordingly inhibited 17alpha-hydroxyprogesterone production (IC(50) of 0.24, 0.27, 0.4, 0.51, and 2.2 nm, respectively). Neither inhibin A nor inhibin B alone affected Cyp17 expression or 17alpha-hydroxyprogesterone production. Both inhibin A and inhibin B blocked the inhibitory actions of activins A and B in AC cells, supporting the antiactivin model of inhibin action. Inhibin A provided more potent and effective antagonism of both activins than did inhibin B, and activin A was less subject to antagonism by either inhibin than was activin B. In contrast to the major antagonism of activin by both inhibins, only inhibin A antagonized the actions of BMP-2, BMP-6, and BMP-7, whereas inhibin B was ineffective against all tested BMP isoforms except BMP-7 at high concentrations. These results provide limited support for the anti-BMP model of inhibin action and reveal that, relative to inhibin A, inhibin B essentially behaves as a selective activin antagonist in AC cells. In conclusion, inhibins A and B differentially antagonize the actions of activins and BMPs to control adrenocortical C(19) steroid production.

Rodent adrenocortical cells display high affinity binding sites and proteins for inhibin A, and express components required for autocrine signalling by activins and bone morphogenetic proteins.

Inhibins are expressed in the adrenal cortex, but little is known of their binding or role in the adrenal. The aims of the present study were, first, to establish whether a mouse adrenocortical (AC) cell line expresses inhibins/activins and bone morphogenetic proteins (BMP), along with proteins required for inhibin to antagonise activin and BMP actions and, secondly, to characterise and compare inhibin binding sites and proteins in the rat adrenal gland and AC cells. AC cells were found to: (1) express mRNA for multiple BMPs (BMP-2, -3, -4, -6, -8a), growth/differentiation factors (GDF-1, -3, -5, -9), Lefty A and B, and the inhibin alpha, beta(A) and beta(B) subunits (2) secrete inhibin A and inhibin B and (3) express mRNA encoding the inhibin co-receptor, betaglycan, along with activin and BMP type I (ALK2-7) and type II (ActRII, ActRIIB, BMPRII) receptors, and binding proteins (follistatin, BAMBI, gremlin). When applied to sections of rat adrenal glands, [(125)I]inhibin A specifically bound to cells of the adrenal cortex, mainly in the zona reticularis. Scatchard analyses of in vitro [(125)I]inhibin A binding to dispersed rat adrenal cells and AC cells revealed sites of high affinity (K(d)(1) of 0.18 and 0.15 nM, respectively) and low affinity (K(d)(2) of 2.6 and 1.3 nM, respectively. Competition for [(125)I]inhibin A binding by activin A or B (30 nM) was negligible, whereas BMP-2, -6 and -7 competed for between 21 and 33% of specific inhibin A binding (IC(50) between 0.2 and 0.3 nM). Inhibin B crossreaction with inhibin A binding sites was < 8%. Multiple binding protein complexes (molecular weight ranging from 35 to > 220 kDa) were affinity labelled by [(125)I]inhibin A on both the primary rat adrenal and AC cells. The species of > 220 kDa were shown by immunoprecipitation to include betaglycan, the species of 105 kDa is consistent in size with type II receptors for activin/BMP, and that of 62 kDa co-migrates with the inhibin-follistatin complex. In summary, the results show that inhibin A binds selectively and with both high and low affinity to AC cells via multiple binding proteins, including a single betaglycan-like species. The results support the role of glycosylated betaglycan in the high affinity binding of inhibin A, but provide consistent evidence from two independent sources of adrenal cells that inhibin A interacts with several membrane proteins in addition to those currently understood to mediate the anti-activin/BMP actions of inhibin.

Activin A and inhibin A differentially regulate human uterine matrix metalloproteinases: potential interactions during decidualization and trophoblast invasion.

Embryo implantation and trophoblast invasion are tightly regulated processes, involving sophisticated communication between maternal decidual and fetal trophoblast cells. Decidualization is a prerequisite for successful implantation and is promoted by a number of paracrine agents, including activin A. To understand the downstream mechanisms of activin-promoted decidualization, the effects of activin on matrix metalloproteinases (MMPs) (important mediators of decidualization) were investigated. Activin A stimulated endometrial production of proMMPs-2, -3, -7, -9, and active MMP-2. In contrast, inhibin A was a potent inhibitor of proMMP-2, and antagonized the effect of activin on MMPs. Activin is up-regulated with decidualization, and MMPs-2, -3, and -9 increase in parallel. Furthermore, proMMP-2 production is stimulated when decidualization is accelerated with activin, and suppressed when activin is neutralized, attenuating decidualization. These data support that activin A promotes decidualization through up-regulating MMPs. Previous in vitro evidence proposes further roles for activin and MMPs in promoting trophoblast invasion; therefore, we examined their interrelationships in early human implantation sites. MMPs-7 and -9 were produced by static cytotrophoblast subpopulations, whereas MMP-2 was strikingly up-regulated in invasive extravillous cytotrophoblasts (EVT). Maternal decidua is the primary source of activin, where a role in stimulating MMP-2 in iEVTs can be envisaged. Inhibin was absent from cytotrophoblast populations, except for a dramatic up-regulation in endovascular EVT plugs, coinciding with a down-regulation of MMP-2. This suggests that inhibin may have a role in the cessation of vascular invasion. These data support that activin, via effects on MMPs, is an important factor in the maternal-fetal dialog regulating implantation.

Proliferative phase sertoli cells display a developmentally regulated response to activin in vitro.

We have used cultures of highly purified, proliferating rat Sertoli cells collected from d 3, 6, and 9 rat pups to investigate the role of activin A on Sertoli cell division. These studies demonstrate that activin A acts directly on d 6 and 9, but not d 3, Sertoli cells to induce proliferation, both alone and synergistically with FSH. In addition to stimulating proliferation, activin A induces secretion of inhibins A and B as determined by specific ELISAs. We demonstrate that the synergy between activin A and FSH is not due to local actions of secreted inhibin or follistatin. We have used real-time fluorometric RT-PCR to demonstrate that activin regulates expression of activin receptor and follistatin mRNA by Sertoli cells. Saturation binding studies using (125)I-activin A indicate that synergy between activin and FSH may be due to increased numbers of activin receptors on the Sertoli cell. Finally, we show that activin A was secreted at high levels by cultured peritubular cells but was undetectable in high purity proliferating Sertoli cell cultures, suggesting that activin A functions as a paracrine factor during postnatal testis development.

Transforming growth factor-beta modulates inhibin A bioactivity in the LbetaT2 gonadotrope cell line by competing for binding to betaglycan.

Activin stimulates expression of GnRH receptor (GnRHR) and FSH beta-subunit in gonadotropes. Inhibin antagonizes activin actions on the gonadotropes, but its molecular mechanism of action remains poorly understood. It has been suggested that inhibin exerts its antagonistic effects by competing with activin for the binding of the activin receptor complex. Betaglycan has recently been identified as an inhibin-binding accessory protein in this process. Because both inhibin and TGFbeta bind betaglycan, we examined whether TGFbeta can modify inhibin's antagonism of activin-induced transcription in gonadotrope cells. Two activin-responsive reporter constructs were used, the first containing 5.5 kb of the ovine FSHbeta promoter (oFSHbetaluc), and the second containing three copies of the activin-responsive sequence of the GnRHR promoter (3XGRAS-PRL-lux). These constructs were transfected into the gonadotrope cell line LbetaT2. The oFSHbetaluc and 3XGRAS-PRL-lux activities stimulated by 0.5 nM activin A were decreased by up to 50% in a dose-dependent manner by inhibin A. TGFbeta(1) and TGFbeta(2) (0-4 nM), alone or in the presence of activin A, did not significantly affect the promoter elements. However, with increasing doses of TGFbeta(1) or TGFbeta(2), inhibin A antagonism of activin A activity was partly or completely reversed. Competition studies with radiolabeled inhibin A showed that TGFbeta(1) and TGFbeta(2) competed with [(125)I]inhibin for the binding to LbetaT2 cells (IC(50) = 280 pM and 72 pM, respectively). Immunoprecipitation studies of [(125)I]inhibin A cross-linked receptor complexes confirmed that TGFbeta(1) and TGFbeta(2) competed with inhibin A for the binding of betaglycan. These results suggest that TGFbeta competition with inhibin for binding to betaglycan interferes with inhibin's suppression of activin-induced FSHbeta and GnRHR promoters in LbetaT2 cells. We propose that under certain circumstances, TGFbeta may facilitate activin biological activity by hindering the access of inhibin to its coreceptor betaglycan.