Antagonism of activin by inhibin and inhibin receptors: a functional role for betaglycan-glycan

Activin and inhibin research has provided important insight into reproductive physiology as well as many areas involving regulation of cell growth, differentiation and function. Progress in understanding the roles of these hormones in various cell and tissue types has been complimented by novel discoveries at the molecular level that have shed light on ligand/receptor interactions, signaling mechanisms and regulation. While the receptors and signaling pathway for activin are now well characterized, the molecular basis for inhibin action has remained relatively unclear. Here we summarize recent advances in understanding inhibin's mode of action focusing on our recent identification of betaglycan-glycan as an inhibin co-receptor capable of mediating inhibin action.     

Properties of inhibin binding to betaglycan,InhBP/p120 and the activin type II receptors

Activin-stimulated FSH synthesis and release by the pituitary gonadotrope is antagonized by gonadally derived inhibins. The two isoforms of inhibin, inhibin A and B, bind to the activin type II receptors, though at a lower affinity than the activins, but do not stimulate intracellular signaling. Theoretically, therefore, inhibins can prevent activin signaling through competitive binding if present at higher concentrations than the activins. In reality, the inhibins have been shown to antagonize activin signaling when the two ligand types are present at equimolar concentrations. These observations led to the hypothesis that inhibin binding proteins or co-receptors exist that either increase the affinity of the inhibins for the activin receptors or propagate inhibin-specific intracellular signals. Two candidate inhibin co-receptors, betaglycan and InhBP/p120, interact with activin receptors and augment inhibin antagonism of activin action. Here, we report the effect of betaglycan and InhBP/p120 on both inhibin A and inhibin B binding to the activin receptors ActRIIA and ActRIIB2. InhBP/p120 did not bind inhibin A or B when expressed alone or in combination with activin receptors, requiring a re-examination of the role of this protein in inhibin biology. Both inhibins bound the activin type II receptor, ActRIIB2. Inhibin B had a higher affinity for this receptor than inhibin A but an approximately 10-fold lower affinity than that of activin A. Inhibin A and B bound betaglycan with high affinity; however, only inhibin A binding to ActRIIB2 was significantly enhanced in the presence of betaglycan. Both inhibin isoforms showed slight but significant binding to ActRIIA, yet this binding was potentiated in the presence of betaglycan. Additionally, the complex formed between the inhibins, ActRIIA, and betaglycan was resistant to disruption by activin A, whereas activin A potently competed for inhibin binding to ActRIIB2 and betaglycan. Collectively, these data show that the inhibin isoforms have different affinities for the activin type II receptors but bind betaglycan with high affinity. A recently developed model of inhibin action proposes that inhibins form a high affinity, activin-resistant ternary complex with activin type II receptors and betaglycan, thereby providing a mechanism for inhibin antagonism of activin signaling. Importantly, the results presented here clearly show that this model does not apply equally to both forms of inhibin nor to the different activin type II receptor isoforms. Thus, it appears that the mechanisms of inhibin action may vary depending on the ligand and receptor types involved.     

Variation in pituitary expression of mRNAs encoding the putative inhibin co-receptor (betaglycan) and type-I and type-II activin receptors during the chicken ovulatory cycle

Secretion of LH and FSH from the anterior pituitary is regulated primarily by hypothalamic GnRH and ovarian steroid hormones. More recent evidence indicates regulatory roles for certain members of the transforming growth factor beta (TGFbeta) superfamily including inhibin and activin. The aim of this study was to identify expression of mRNAs encoding key receptors and ligands of the inhibin/activin system in the hen pituitary gland and to monitor their expression throughout the 24-25-h ovulatory cycle. Hens maintained on long days (16 h light/8 h dark) were killed 20, 12, 6 and 2 h before predicted ovulation of a midsequence egg (n = 8 per group). Anterior pituitary glands were removed, RNA extracted and cDNA synthesized. Plasma concentrations of LH, FSH, progesterone and inhibin A were measured. Real-time quantitative PCR was used to quantify pituitary expression of mRNAs encoding betaglycan, activin receptor (ActR) subtypes (type I, IIA), GnRH receptor (GnRH-R), LH beta subunit, FSH beta subunit and GAPDH. Levels of mRNA for inhibin/activin betaA and betaB subunits, inhibin alpha subunit, follistatin and ActRIIB mRNA in pituitary were undetectable by quantitative PCR (<2 amol/reaction). Significant changes in expression (P<0.05) of ActRIIA and betaglycan mRNA were found, both peaking 6 h before ovulation just prior to the preovulatory LH surge and reaching a nadir 2 h before ovulation, just after the LH surge. There were no significant changes in expression of ActRI mRNA throughout the cycle although values were correlated with mRNA levels for both ActRIIA (r = 0.77; P<0.001) and beta-glycan (r = 0.45; P<0.01). Expression of GnRH-R mRNA was lowest 20 h before ovulation and highest (P<0.05) 6 h before ovulation; values were weakly correlated with betaglycan (r = 0.33; P = 0.06) and ActRIIA (r = 0.34; P = 0.06) mRNA levels. Expression of mRNAs encoding LH beta and FSH beta subunit were both lowest (P<0.05) after the LH surge, 2 h before ovulation. These results are consistent with an endocrine, but not a local intrapituitary, role of inhibin-related proteins in modulating gonadotroph function during the ovulatory cycle of the hen, potentially through interaction with betaglycan and ActRIIA. In contrast to mammals, intrapituitary expression of inhibin/activin subunits and follistatin appears to be extremely low or absent in the domestic fowl.     

Effect of activin A and inhibin A on expression of the inhibin/activin beta-B-subunit and gonadotropin receptors in granulosa cells of the hen

Activin A has been shown to be abundant in the theca layer of the large pre-ovulatory follicles of the hen whereas inhibin A is produced in the granulosa layer. The purpose of this study was to investigate the effects of activin A and inhibin A on granulosa cell expression of inhibin beta-B-subunit, FSH receptor (FSHR), and LH receptor (LHR). Granulosa cells were isolated from the F1, F3+F4, and small yellow follicles (SYF; 6-12 mm diameter) of laying hens and pooled according to size. The cells were dispersed and plated in the presence of 0, 10, or 50 ng/ml recombinant human activin A (n=5 replicate cultures). RNA was subsequently extracted from the cells and Northern blots performed. Cell proliferation was determined for all treatments. An identical set of experiments was performed in which the granulosa cells were treated with recombinant human inhibin A (n=4 replicate cultures). Treatment with activin A at 50 ng/ml significantly (p<0.05) increased expression of beta-B-subunit for granulosa cells from all follicles. This dose also significantly increased expression of FSHR in granulosa cells from all follicles (p<0.05) and increased expression of LHR in cells from F1 and F3+F4 follicles (p<0.01) with no significant effect on cells from the SYF. Overall, activin A treatment significantly (p<0.05) decreased cell proliferation at the 50 ng/ml dose. Inhibin A had no significant effect on expression of beta-B-subunit, FSHR or LHR at any dose. There was a moderate stimulatory effect of inhibin A on granulosa cell proliferation. These results suggest that activin A may have an important role in regulating granulosa cell responsiveness to gonadotropins while also modulating follicle development by attenuating cell proliferation.     

Differential expression of mRNAs encoding the putative inhibin co-receptor (betaglycan) and activin type-I and type-II receptors in preovulatory and prehierarchical follicles of the laying hen ovary

Ovarian follicle development is primarily regulated by an interplay between the pituitary gonadotrophins, LH and FSH, and ovary-derived steroids. Increasing evidence implicates regulatory roles of transforming growth factor-beta (TGFbeta) superfamily members, including inhibins and activins. The aim of this study was to identify the expression of mRNAs encoding key receptors of the inhibin/activin system in ovarian follicles ranging from 4 mm in diameter to the dominant F1 follicle (approximately 40 mm).Ovaries were collected (n = 16) from mid-sequence hens maintained on a long-day photoschedule (16 h of light:8 h of darkness). All follicles removed were dissected into individual granulosa and thecal layers. RNA was extracted and cDNA synthesized. Real-time quantitative PCR was used to quantify the expression of mRNA encoding betaglycan, activin receptor (ActR) subtypes (type-I, -IIA and -IIB) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH); receptor expression data were normalized to GAPDH expression. Detectable levels of ActRI, -IIA and -IIB and the inhibin co-receptor (betaglycan) expression were found in all granulosa and thecal layers analysed. Granulosa ActRI mRNA peaked (P < 0.05) in 8-9.9 mm follicles, whereas ActRIIA rose significantly from 6-7.9 mm to 8-9.9 mm, before falling to F3/2; levels then rose sharply (3-fold) to F1 levels. Granulosa betaglycan mRNA expression rose 3-fold from 4-5.9 mm to 8-9.9 mm, before falling 4-fold to F3/2; levels then rose sharply (4-fold) to F1 levels. ActRIIB levels did not vary significantly during follicular development. Thecal ActRI mRNA expression was similar from 4-7.9 mm then decreased significantly to a nadir at the F4 position, before increasing 2-fold to the F1 (P < 0.05). Although thecal ActRIIB and -IIA expression did not vary significantly from 4 mm to F3, ActRIIB expression increased significantly (2-fold) from F3 to F1 and ActRIIA increased 2-fold from F2 to F1 (P < 0.05). Thecal betaglycan fell to a nadir at F6 after follicle selection; levels then increased significantly to F2, before falling approximately 50% in the F1.In all follicles studied expression of betaglycan and ActRI (granulosa: r = 0.65, P < 0.001, n = 144/group; theca: r = 0.49, P < 0.001, n = 144/group) was well correlated. No significant correlations were identified between betaglycan and ActRIIA or -IIB. Considering all follicles analysed, granulosa mRNA expression of betaglycan, ActRI, ActRIIA and ActRIIB were all significantly lower than in corresponding thecal tissue (betaglycan, 11.4-fold; ActRIIB, 5.1-fold; ActRI, 3.8-fold; ActRIIA, 2.8-fold). The co-localization of type-I and -II activin receptors and betaglycan on granulosa and thecal cells are consistent with a local auto/paracrine role of inhibins and activins in modulating ovarian follicle development, selection and progression in the domestic fowl.     

In vivo regulation of FSH synthesis by inhibin and activin

The effect of a single sc injection of the gonadal peptide, recombinant human activin A (rhActivin A), on gonadotropin synthesis and secretion was examined in adult and immature male and female rats and the effect of recombinant human inhibin A (rhInhibin A) was examined in adult male rats. Pituitary FSH beta, LH beta and alpha messenger RNA (mRNA) levels were determined by blot hybridization. Trunk blood was collected to measure serum FSH levels. Treatment with rhInhibin A (100 micrograms/kg) resulted in a decrease in FSH beta mRNA to 2% of controls levels 6 h after injection. FSH beta mRNA levels started to rebound at 10 h, but were still significantly lower than vehicle-treated controls. Serum FSH levels were significantly reduced at 2 h and were reduced further at 6 and 10 h. There were no significant changes in alpha and LH beta mRNA levels. RhActivin A, at the highest dose (500 micrograms/kg), in immature male rats had only a modest effect (1.2- and 1.3-fold increase) on FSH beta mRNA levels and FSH secretion, respectively, at 2 h. No increase in FSH synthesis and FSH secretion was observed in adult male rats. In contrast, both immature and adult-ovariectomized E2 implanted females showed a robust response to rhActivin A. In immature females, 2 h after rhActivin A (100 and 500 micrograms/kg) administration, FSH beta mRNA levels were elevated 2.0- and 2.2-fold. At this time serum FSH was also elevated. At 6 and 10 h rhActivin A significantly reduced FSH beta mRNA levels from vehicle-treated controls. In contrast, FSH secretion was elevated at 6 h and returned to baseline at 10 h. Administration of rhActivin A (500 micrograms/kg) to adult, ovariectomized-E2 females resulted in a significant increase in FSH beta mRNA levels and FSH secretion at 2 and 6 h. There were no significant changes in alpha and LH beta mRNA levels in either males or females. Thus, these in vivo studies have shown that rhInhibin A can inhibit FSH beta mRNA levels and FSH secretion in the adult male rat. RhActivin A stimulates FSH synthesis and secretion in the immature and adult ovariectomized-E2 females, but has little or no effect in immature and adult males. Hence, there is a sexual dimorphic response to rhActivin A in vivo in the rat.     

Localization of activin and inhibin subunits,receptors and SMADs in the mouse mammary gland

Activin and inhibin, two closely related protein hormones, are members of the transforming growth factor beta (TGF beta) superfamily of growth factors. Activin and TGF beta have been associated with mouse mammary gland development and human breast carcinogenesis. TGF beta expression in the mammary gland has been previously described, and was found to be expressed in nonparous tissue and during pregnancy, down-regulated during lactation, and then up-regulated during involution. The expression pattern of activin subunits, receptors and cytoplasmic signaling molecules has not been thoroughly described in post-natal mammary gland development. We hypothesize that activin signaling components are dynamically regulated during mammary gland development, thereby permitting activin to have distinct temporal growth regulatory actions on this tissue. To examine the activin signal transduction system in the mammary gland, tissue from CD1 female mice was dissected from nonparous, lactating day 1, 10, and 20 and post-weaning day 4 animals. The expression of the activin receptors (ActRIIA, ActRIIB and ActRIB), the inhibin co-receptor (betaglycan), and ligand subunit (alpha, beta A and beta B), mRNA was measured by semi-quantitative RT-PCR in these tissues. In addition, the cellular compartmentalization of the activin signaling proteins, including the cytoplasmic signaling co-activators, Smads 2, 3 and 4, were examined by immunohistochemistry. Generally, mRNA abundance of activin signaling components was greatest in the nonparous tissue, and then decreased, whereas protein immunoreactivity for activin signaling components increased during lactation and decreased during involution. The alpha-subunit protein was detected in nonparous and lactating day 1 tissue only. Importantly, Smad 3, but not Smad 2, was detected in epithelial cell nuclei during all time points examined, indicating that activin signaling is mediated by Smad 3 at these times. These findings suggest that activin's growth regulatory role during lactation may be distinguished from that of TGF beta during post-natal mammary development. Future studies will focus on determining the exact role this ligand plays in mammary tissue differentiation and neoplasia.     

Inhibin alpha-subunit and the inhibin coreceptor betaglycan are downregulated in endometrial carcinoma

OBJECTIVE: In the present study we evaluated the protein distribution and mRNA levels of inhibin alpha-subunit and its coreceptor betaglycan in endometrial adenocarcinoma. DESIGN: Two groups of postmenopausal women were studied: the first group had recently diagnosed endometrial adenocarcinoma (n = 16; age range 61-79 years), and the second group (n = 12; age range 64-78 years) had undergone hysterectomy for uterine prolapse and served as control. METHODS: Inhibin alpha-subunit and betaglycan gene expression and tissue distribution were evaluated by semiquantitative RT-PCR and immunohistochemistry respectively. RESULTS: Inhibin alpha-subunit and betaglycan mRNAs were expressed by both healthy and tumoral endometria, but their expression was significantly lower in endometrial carcinoma (P < 0.001, based on Student's t test). Inhibin alpha-subunit expression was much weaker in the glands of tumours than in non-neoplastic specimens. Betaglycan protein was identified in the epithelial cells lining non-tumoral endometrium, and in endothelial cells of both normal and tumoral endometria. Well-differentiated neoplastic cells had a faint and scarce betaglycan staining, and poorly differentiated cells did not express betaglycan at all. CONCLUSIONS: The lower inhibin alpha and betaglycan expression in endometrial adenocarcinoma suggests that the inhibin action may be disrupted. However, the expression of betaglycan in the endothelia of the tumour vasculature suggests that a selective vascular response to inhibin may be possible in these tumours.     

Regulation of Leydig cell function in primary culture by inhibin and activin

Inhibin and activin are gonadal glycoproteins that selectively inhibit and stimulate FSH release, respectively. Previously we have reported that transforming growth factor-beta inhibited hCG-stimulated testosterone formation in mature Leydig cells. In the present study we evaluated the effects of other members of the transforming growth factor-beta family, inhibin and activin, on Leydig cell function. We found that activin (0.1-10 ng/ml) had no effect on basal testosterone formation, but inhibited hCG-stimulated testosterone formation in a dose-dependent manner. Activin (10 ng/ml) inhibited hCG-stimulated testosterone formation by 42%. Activin also inhibited hCG-stimulated cAMP formation. In the presence of activin (5 ng/ml), forskolin (10 microM)- and 8-bromo-cAMP (0.1 mM)-induced testosterone formation were reduced about one third. Conversions of pregnenolone and progesterone to testosterone were also blocked by activin. Interestingly, [125I]hCG binding to Leydig cells and forskolin-induced cAMP formation were not affected by the addition of activin. In contrast to activin, inhibin (0.1-10 ng/ml) had no effect on hCG-induced testosterone formation at any concentration used. However, the inhibitory effects of activin on Leydig cell function were reversed by the concomitant addition of inhibin. Our results suggest that activin inhibits testosterone formation by the Leydig cells derived from normal mature rats. Multiple steps of the steroidogenic pathway are affected by testosterone. Inhibin alone has no effect, but reverses the inhibitory action of activin.     

Regulation of activin and inhibin in the adult testis and the evidence for functional roles in spermatogenesis and immunoregulation

Activin A provides a unique link between reproduction and immunity, which is especially significant in the adult testis. This cytokine, together with inhibin B and follistatin acting as regulators of activin A activity, is fundamentally involved in the regulation of spermatogenesis and testicular steroidogenesis. However, activin A also has a much broader role in control of inflammation, fibrosis and immunity. In the Sertoli cell, activin A is regulated by signalling pathways that normally regulate stress and inflammation, signalling pathways that intersect with the classical hormonal regulatory pathways mediated by FSH. Modulation of activin A production and activity during spermatogenesis is implicated in the fine control of the cycle of the seminiferous epithelium. The immunoregulatory properties of activin A also suggest that it may be involved in maintaining testicular immune privilege. Consequently, elevated activin A production within the testis during inflammation and infection may contribute to spermatogenic failure, fibrosis and testicular damage.     

Cell-type specific modulation of pituitary cells by activin, inhibin and follistatin

Activins are multifunctional proteins and members of the TGF-β superfamily. Activins are expressed locally in most tissues and, analogous to the actions of other members of this large family of pleiotropic factors, play prominent roles in the regulation of diverse biological processes in both differentiated and embryonic stem cells. They have an essential role in maintaining tissue homeostasis in the adult and are known to contribute to the developmental programs in the embryo. Activins are further implicated in the growth and metastasis of tumor cells. Through distinct modes of action, inhibins and follistatins function as antagonists of activin and several other TGF-β family members, including a subset of BMPs/GDFs, and modulate cellular responses and the signaling cascades downstream of these ligands. In the pituitary, the activin pathway is known to regulate key aspects of gonadotrope functions and also exert effects on other pituitary cell types. As in other tissues, activin is produced locally by pituitary cells and acts locally by exerting cell-type specific actions on gonadotropes. These local actions of activin on gonadotropes are modulated by the autocrine/paracrine actions of locally secreted follistatin and by the feedback actions of gonadal inhibin. Knowledge about the mechanism of activin, inhibin and follistatin actions is providing information about their importance for pituitary function as well as their contribution to the pathophysiology of pituitary adenomas. The aim of this review is to highlight recent findings and summarize the evidence that supports the important functions of activin, inhibin and follistatin in the pituitary.     

Expression of activin/inhibin receptor and binding protein genes and regulation of activin/inhibin peptide secretion in human adrenocortical cells

Activins and inhibins are glycoprotein hormones produced mainly in gonads but also in other organs. They are believed to be important para/autocrine regulators of various cell functions. We investigated activin/inhibin receptor and binding protein gene expression and the regulation of activin/inhibin secretion in human adrenal cells. RT-PCR revealed inhibin/activin alpha-, betaA/B-subunit, follistatin, activin type I/II receptor, and inhibin receptor (betaglycan and inhibin-binding protein) mRNA expression in fetal and adult adrenals and cultured adrenocortical cells. Cultured cells secreted activin A and inhibin A/B as determined by specific ELISAs. ACTH stimulated inhibin A/B secretion in fetal (1.8- and 1.8-fold of control, respectively) and in adult cells (3.4- and 1.7-fold of control, respectively) without significant effect on activin A. 8-bromoadenosine cAMP (protein kinase A activator) increased activin A and inhibin A/B secretion in the human adrenocortical NCI-H295R cell line (32-, 17-, and 3-fold of control, respectively). 12-O-tetradecanoyl phorbol-13-acetate (protein kinase C activator) stimulated both activin A and inhibin A secretion (764- and 32-fold of control, respectively), and activin treatment increased inhibin B secretion in these cells (25-fold of control). In conclusion, human adrenocortical cells produce dimeric activins and inhibins. ACTH stimulates inhibin secretion and decreases activin/inhibin secretion ratio, probably via the protein kinase A signal transduction pathway. This, together with the adrenocortical activin/ inhibin receptor and binding protein expression, suggests a physiological role for activins and inhibins in the human adrenal gland.     

Production and purification of recombinant human inhibin and activin.

Inhibin and activin are protein hormones with diverse physiological roles including the regulation of pituitary FSH secretion. Like other members of the transforming growth factor-beta gene family, they undergo processing from larger precursor molecules as well as assembly into functional dimers. Isolation of inhibin and activin from natural sources can only produce limited quantities of bioactive protein. To purify large-scale quantities of recombinant human inhibin and activin, we have utilized stably transfected cell lines in self-contained bioreactors to produce protein. These cells produce approximately 200 microg/ml per day total recombinant human inhibin. Conditioned cell media can be purified through column chromatography resulting in dimeric mature 32-34 kDa inhibin A and 28 kDa activin A. The purified recombinant proteins maintain their biological activity as measured by traditional in vitro assays including the regulation of FSH in rat anterior pituitary cultures and the regulation of promoter activity of the activin-responsive promoter p3TP-luc in tissue culture cells. These proteins will be valuable for future analysis of inhibin and activin function and have been distributed to the US National Hormone and Peptide Program.     

The inhibin/activin family and ovarian cancer.

Ovarian cancer is the most common fatal malignancy of the female reproductive tract and frequently presents at an advanced stage. There is, thus, a great need for more sensitive and accurate methods of diagnosis, including better tumor markers. A rapidly emerging technique is the application of assays for the inhibin peptide family in patients with various forms of ovarian cancer. Currently, in assays that detect molecules containing the inhibin a subunit, more than 80% of postmenopausal patients with mucinous epithelial ovarian tumors, and virtually all with granulosa-cell tumors, have elevated inhibin levels. The detection of activin in some tumor tissues suggests that this peptide may also prove to be of interest once satisfactory and specific assays for the circulating peptide are available. It is likely that significant progress will be made in this field within the next 5 years.     

Cripto forms a complex with activin and type II activin receptors and can block activin signaling

Activin, nodal, Vg1, and growth and differentiation factor 1 are members of the transforming growth factor beta superfamily and signal via the activin type II (ActRII/IIB) and type I (ALK4) serine/threonine kinase receptors. Unlike activins, however, signaling by nodal, Vg1, and growth and differentiation factor 1 requires a coreceptor from the epidermal growth factor-Cripto-FRL1-Cryptic protein family such as Cripto. Cripto has important roles during development and oncogenesis and binds nodal or related ligands and ALK4 to facilitate assembly of type I and type II receptor signaling complexes. Because Cripto mediates signaling via activin receptors and binds directly to ALK4, we tested whether transfection with Cripto would affect the ability of activin to signal and/or interact with its receptors. Here we show that Cripto can form a complex with activin and ActRII/IIB. We were unable to detect activin binding to Cripto in the absence of ActRII/IIB, indicating that unlike nodal, activin requires type II receptors to bind Cripto. If cotransfected with ActRII/IIB and ALK4, Cripto inhibited crosslinking of activin to ALK4 and the association of ALK4 with ActRII/IIB. In addition, Cripto blocked activin signaling when transfected into either HepG2 cells or 293T cells. We have also shown that under conditions in which Cripto facilitates nodal signaling, it antagonizes activin. Inhibition of activin signaling provides an additional example of a Cripto effect on the regulation of signaling by transforming growth factor-beta superfamily members. Because activin is a potent inhibitor of cell growth in multiple cell types, these results provide a mechanism that may partially explain the oncogenic action of Cripto.     

Autocrine/paracrine regulation of pituitary function by activin, inhibin and follistatin

The precise regulation of the anterior pituitary is achieved by the cell-specific and combined actions of central, peripheral and local factors. Activins, inhibins, and follistatins were first discovered as gonadal factors with actions on FSH production from pituitary gonadotropes. With the realization that these factors are expressed in a wide array of tissues, including the pituitary, it became apparent that the functional importance of activins, inhibins, and follistatins extends beyond the reproductive axis and that they often exert their effects by autocrine/paracrine mechanisms. As members of the TGF-beta superfamily, activins and inhibins control and orchestrate many physiological processes and are vital for the development, the growth, and the functional integrity of most tissues, including the pituitary. Activins exert effects on multiple pituitary cell types but the best-characterized pituitary targets of the autocrine/paracrine function of activins are the gonadotropes. The autocrine/paracrine function of the activin-binding proteins, follistatins, constitutes an important local mechanism to modulate activin bioactivity while the restricted actions of gonadal inhibins to betaglycan-expressing gonadotropes provides a secondary mode of regulation of cell-specific actions of activins. The aim of this review is to highlight and evaluate experimental evidence that supports the roles of activins, inhibins, and follistatins as autocrine, paracrine, and/or endocrine modulators of the pituitary.     

The distribution of betaglycan protein and mRNA in rat brain, pituitary, and gonads: implications for a role for betaglycan in inhibin-mediated reproductive functions

Betaglycan was reported by our laboratory to serve as an inhibin binding protein and to facilitate the antagonism of activin signaling. Although an accessory receptor for TGFbeta and inhibin, its distribution within reproductive tissues remains largely unexplored. Histochemical analyses reveal betaglycan protein and mRNA distributed throughout the rat reproductive axis. In the brain, betaglycan mRNA is localized in discrete regions of the forebrain and brain stem, including olfactory, septal, and hypothalamic nuclei. In the pituitary, moderate levels of betaglycan protein and mRNA were observed in the anterior and intermediate lobes. Betaglycan immunoreactivity was colocalized with all the pituitary cell subtypes, to the greatest extent with the gonadotrope population. In the gonads, betaglycan mRNA was localized in cellular compartments, coinciding with its protein for the most part. Moderate levels of mRNA were observed in ovarian granulosa cells, with lower expression in the thecal layer and the oocyte. In the testes, betaglycan mRNA was observed in the Leydig and tubule-specific germ cells. This is the first comprehensive report detailing the distribution of betaglycan in mammalian reproductive tissues. The present findings illustrate and support the hypothesis of a modulatory role for betaglycan in TGFbeta and/or inhibin effects in these tissues.