Gonadotropin-releasing hormone, estradiol, and inhibin regulation of follicle-stimulating hormone and luteinizing hormone surges: implications for follicle emergence and selection in heifers.

Mechanisms regulating gonadotropin surges and gonadotropin requirements for follicle emergence and selection were studied in heifers. Experiment 1 evaluated whether follicular inhibins regulate the preovulatory luteinizing hormone (LH)/follicle-stimulating hormone (FSH) surges elicited by gonadotropin-releasing hormone (GnRH) injection (Hour = 0) and the subsequent periovulatory FSH surge. Treatments included control (n = 6), steroid-depleted bovine follicular fluid (bFF) at Hour -4 (n = 6), and bFF at Hour 6 (n = 6). Gonadotropins in blood were assessed hourly from Hours -6 to 36, and follicle growth tracked by ultrasound. Consistent with inhibin independence, bFF at Hour -4 did not impact the GnRH-induced preovulatory FSH surge, whereas treatment at Hour 6 delayed onset of the periovulatory FSH surge and impeded growth of a new follicular wave. Experiment 2 examined GnRH and estradiol (E2) regulation of the periovulatory FSH surge. Treatment groups were control (n = 8), GnRH-receptor antagonist (GnRHr-ant, n = 8), and E2 + GnRHr-ant (n = 4). GnRHr-ant (acyline) did not reduce the concentrations of FSH during the periovulatory surge and early follicle development (<7.0 mm) was unaffected, although subsequent growth of a dominant follicle (>8.0 mm) was prevented by GnRHr-ant. Addition of E2 delayed both the onset of the periovulatory FSH surge and emergence of a follicular wave. Failure to select a dominant follicle in the GnRHr-ant group was associated with reduced concentrations of LH but not FSH. Maximum diameter of F1 in controls (13.3 ± 0.5 mm) was greater than in both GnRHr-ant (7.7 ± 0.3 mm) and E2 + GnRHr-ant (6.7 ± 0.8 mm) groups. Results indicated that the periovulatory FSH surge stems from removal of negative stimuli (follicular E2 and inhibin), but is independent of GnRH stimulation. Emergence and early growth of follicles (until about 8 mm) requires the periovulatory FSH surge but not LH pulses. However, follicular deviation and late-stage growth of a single dominant follicle requires GnRH-dependent LH pulses.

Involvement of activin and inhibin in the regulation of food and water intake in the rat.

The expression of activin and inhibin has been demonstrated in the hypothalamus, but their physiological roles in the brain remain to be elucidated. In the present study, involvement of activin and inhibin in the regulation of food and water intake was examined. Male rats were deprived of food or water for 12 and 60 hr, and mRNA levels of activin/inhibin alpha, betaA and betaB subunits in the hypothalamus were estimated by RT-PCR. Gene expression of alpha subunit transiently decreased at 12 hr of food deprivation, while it did not change during water deprivation. Food and water deprivation for 60 hr increased mRNA levels of betaA and betaB subunits, respectively. These results indicated that gene expression of each subunit was independently regulated. Injection of activin A (0.5 and 4.0 microg) into the third ventricle decreased food intake. Water intake was suppressed by 4.0 microg, but not 0.5 microg, of activin A. Intracerebroventricular injection of inhibin A (0.5 and 4.0 microg) decreased water intake in a dose dependent manner without affecting food intake, suggesting that inhibin could act independently of activin. Taken together, it is suggested that activin and inhibin take part in the central regulation of nutrient and fluid balance, though further study is needed to determine precise molecular species involved.

Activin A-induced HepG2 liver cell apoptosis: involvement of activin receptors and smad proteins.

A balance between cell proliferation and apoptosis is important for regulating normal liver function. Proteins of the transforming growth factor-beta superfamily are known to be important mediators of apoptosis in the liver. In this study we demonstrate that activin A potently induces apoptotic cell death in a hepatoma cell line, HepG2 cells. To determine the roles of activin receptors and downstream signaling proteins in activin A-induced apoptosis in these cells, the activin signaling pathway was analyzed using the transcription of an activin-responsive reporter gene, p3TP-Lux, as an assay. Although individual activin receptors had little effect on transcriptional activity, coexpression of an activin type I receptor and a type II receptor significantly increased both basal and activin-induced transcriptional activation, with the combination ofreceptors IB and IIB being the most potent. Similarly, expression of individual Smad proteins had only a modest effect on reporter gene activity, but the combination of Smad2 and Smad4 strongly stimulated transcription. Activin signaling induced a rapid relocation of Smad2 to the nucleus, as determined using a green fluorescence protein-Smad2 fusion protein. In contrast, green fluorescence protein-Smad4 remained localized to the cytoplasm unless it was coexpressed with Smad2. In agreement with the transcriptional response assays, overexpression or suppression of activin signaling components in HepG2 cells altered apoptosis. Overexpression of receptors IB and IIB or Smad proteins 2 and 4 stimulated apoptosis, whereas dominant negative mutant forms of the activin type IIB receptor or Smad2 blocked activin-stimulated apoptosis. These studies suggest that signaling from the cell surface to the nucleus through Smad proteins is a required component of the activin A-induced cell death process in liver cells.

Activin A regulation of gonadotropin-releasing hormone synthesis and release in vitro.

Activin is essential for the regulation of normal mammalian reproductive function at both the pituitary and gonadal levels. However, its central actions in the control of the hypothalamic-pituitary-gonadal axis remain largely unexplored. The present study aims to determine whether activin could regulate the reproductive axis at the level of the hypothalamus, through control of the GnRH neuroendocrine system. Using the GnRH-secreting GT1-7 neuronal cell line as a model system, we demonstrate expression of mRNAs encoding activin receptor types I, IB, and II. We examined the effects of activin A on GnRH protein secretion and mRNA levels in GT1-7 cells. Treatment with rh-activin A regulated both GnRH protein secretion and GnRH mRNA expression in the GT1-7 cells in a time-dependent fashion. Using transient transfection assays, we explored a potential transcriptional basis for these changes. Activin A increased reporter gene activity driven by minimal GnRH enhancer and promoter elements, suggesting that activin may regulate GnRH gene expression at the level of transcription. Lastly, activin A treatment of male rat hypothalami, in vitro, increased GnRH protein secretion. Collectively, molecular and physiological evidence support the presence of an activin system which might act at a hypothalamic site to regulate mammalian reproduction via activation of GnRH synthesis and release.

Growth of HPV-18 immortalized human prostatic intraepithelial neoplasia cell lines. Influence of IL-10, follistatin, activin-A, and DHT.

Cultures from high grade prostatic intraepithelial neoplasia (HGPIN) have been established and immortalized by HPV-18 infection. The cultures were identified as PIN by Western blotting with anti-cytokeratin (34betaE12) and prostate specific antigen (PSA) antibodies. We examined the growth capabilities of the cultures in the presence of TGF-beta1, activin-A, follistatin (FS), androgens (DHEA, DHT) and several cytokines (IL-10, IL-2, IL-4). IL-10, FS, and DHT stimulated cell proliferation and colony forming ability, while the other cytokines and growth factors had no discernable effect. In addition, DHT and to a lesser extent IL-10 both stimulated PSA production. Activin-A blocked IL-10, FS, and DHT stimulated growth and PSA production. We interpret the data to mean that IL-10 induction of FS secretion (and FS binding of activin A) restores the normal growth capabilities of HGPIN cultures.

Activin A stimulates meiotic maturation of human oocytes and modulates granulosa cell steroidogenesis in vitro.

OBJECTIVE: To test the hypothesis that activin A promotes in vitro human oocyte meiotic maturation while inhibiting steroid secretion by nonluteinized antral granulosa cells. DESIGN: Prospective randomized controlled study. SETTING: A university medical center. PATIENT(S): Nine women ranging in age from 31-44 years who were undergoing oophorectomy for nonovarian pathology. INTERVENTION(S): Analysis of meiotic maturation of oocytes and steroid secretion by granulosa cells cultured in the presence or absence of activin A. MAIN OUTCOME MEASURE(S): Germinal vesicle breakdown (GVBD) and attainment of metaphase II (MII) in oocytes, and progesterone and E2 secretion by granulosa cells. RESULT(S): Activin A significantly enhanced GVBD (91% vs. 65%) for control and maturation to MII (56% vs. 35% for control) of immature oocytes. Activin A significantly suppressed basal, and inhibin A-and FSH-stimulated progesterone and E2 secretion by nonluteinized granulosa cells. CONCLUSION(S): Activin A is a promoter of oocyte maturation in vitro and a modulator of granulosa cell steroidogenesis in culture.

Activin-A stimulates hypothalamic gonadotropin-releasing hormone release by the explanted male rat hypothalamus: interaction with inhibin and androgens.

The presence of activins in those hypothalamic regions containing gonadotropin-releasing hormone (GnRH)-secreting neurons suggests that these peptides may regulate the reproductive function modulating not only pituitary FSH release and biosynthesis, but also hypothalamic GnRH release. The purpose of this study was to evaluate the effects of activin-A, a homodimer of inhibin beta A subunit, on hypothalamic GnRH release in vitro and, because of their well known antithetical effects, to evaluate its interaction with inhibin. In addition, since androgens modulate the release of GnRH from male rat hypothalami, we thought it of interest to study the possible interplay between these steroids and activin on GnRH release. To accomplish this, we employed a hypothalamic organ culture system which enabled us to evaluate GnRH release from individually incubated hemi-hypothalami explanted from male rats. Activin-A stimulated GnRH release in a biphasic manner. The maximal effect was reached at a concentration of 10 ng/ml which increased GnRH output by about 75%. Inhibin abolished the stimulatory effect of a maximally effective concentration of activin-A in a dose-dependent manner, whereas alone it had no effect on GnRH output. As previously shown, testosterone (1 nmol/l) and dihydrotestosterone (DHT, 0.1 nmol/l) suppressed basal GnRH release, but only testosterone was able to inhibit the release of GnRH stimulated by activin-A. Since DHT is a non-aromatizable androgen, we evaluated whether the inhibitory effect of testosterone was due to its in vitro conversion into 17 beta-estradiol. The addition of 4-hydroxyandrostenedione, a steroidal aromatase inhibitor, did not influence the suppressive effect of testosterone on GnRH release stimulated by activin-A. In conclusion, activin-A stimulated hypothalamic GnRH release in vitro and this effect was abolished by inhibin and was blunted by testosterone. These findings suggest that activins may participate in the regulation of the hypothalamic-pituitary-gonadal axis by modulating GnRH release. The ability of testosterone to suppress the release of GnRH stimulated by activin-A indicates that this steroid has a potent negative feedback influence on GnRH release.

Human growth-differentiation factor 3 (hGDF3): developmental regulation in human teratocarcinoma cell lines and expression in primary testicular germ cell tumours.

We describe the cloning and initial characterization of a novel cDNA from human embryonal carcinoma (EC) cells. This cDNA, which we named human growth differentiation factor 3 (hGDF3), encodes the homologue of mouse GDF3, a TGFbeta superfamily member belonging to the Growth/Differentiation Factors. We have analysed the expression of hGDF3 in human embryonal carcinoma cell lines and in primary testicular germ cell tumours of adolescents and adults (TGCTs). Expression of hGDF3 in human EC cell lines is stem cell-specific, is down-regulated upon RA-mediated differentiation and is increased upon culture of the cells in the presence of activin A. In TGCTs, hGDF3 expression is low in seminomas, while expression in non-seminomas is readily detectable and appears to be associated with the EC and yolk sac components in the tumours. We have also mapped the hGDF3 locus to the short arm of human chromosome 12, a region consistently overrepresented in human testicular germ cell tumours. Thus, hGDF3 represents an embryonal carcinoma stem cell-associated marker both in vitro and in vivo.

Expression of activin and follistatin in the rat hypothalamus: anatomical association with gonadotropin-releasing hormone neurons and possible role of central activin in the regulation of luteinizing hormone release.

The central role of activin in the regulation of the reproductive axis remains largely unexplored. Evidence suggests that activin may play a role in control-linggonadotropin-releasing hormone (GnRH) release. We assessed potential neuroanatomical associations between activin- and GnRH-neuronal systems via examination of the distribution of activin betaA-subunit and activin binding protein (follistatin) protein and mRNA signals relative to GnRH neurons in the adult rat brain. Activin betaA-subunit-immunostained fibers were distributed throughout the hypothalamus and GnRH-positive perikarya, and fibers were in close association with betaA-subunit-immunoreactive fibers. Follistatin mRNA-expressing cells were also identified throughout the hypothalamus with GnRH fibers often observed juxtaposed to follistatin cell bodies. Colocalization of either the betaA-subunit or follistatin within GnRH neurons was not detected. The functional significance of central activin in the regulation of the reproductive axis was also demonstrated. The intracerebroventricular infusion of rh-activin A significantly increased luteinizing hormone, but not follicule-stimulating hormone, serum levels in adult male rats. Taken together, the present results support an interaction between activin and GnRH neuronal systems in the rat hypothalamus, and suggest activin may act within the brain to regulate the reproductive axis.

Level of nutrition modulates the dynamics of oestradiol feedback on plasma FSH in ovariectomized ewes.

The frequency of multiple ovulations in mature, cyclic ewes is strongly influenced by the level of nutrition, but it is difficult to demonstrate concurrent changes in plasma concentrations of gonadotropins. The failure to do so might be a consequence of rapid compensation by the homeostatic feedback mechanism linking secretion by the hypothalamus/pituitary gland and ovarian hormones. Most experimental models have examined the components of the homeostatic feedback system after steady state relationships had been established. We hypothesised that the effects of nutrition might be observed more readily if the system were disrupted and then examined while equilibrium was being re-established. This hypothesis was tested in three experiments in Merino ewes by allowing gonadotropin secretion to escape feedback for 5 days after ovariectomy and then replacing ovarian hormones and examining effects of feeding regimen on the return of plasma concentrations of FSH to baseline values. In all three experiments, oestrogen replacement caused plasma concentrations of FSH to decline more rapidly (P < 0.05) in ewes fed at 0.5x maintenance, than in ewes fed at 1.4x maintenance, with groups fed at maintenance being intermediate. No effect of diet was observed on plasma FSH concentrations in the absence of oestradiol, and neither progesterone nor charcoal-treated bovine follicular fluid influenced the effect of nutrition. Plasma concentrations of oestradiol were 9.8% lower on average (NS) in ewes fed above maintenance than in the sheep fed below maintenance over the three experiments, suggesting that there may have been a reduced clearance of oestradiol which contributed to the result. We conclude that feeding regimen affects the secretion or clearance of gonadotropins in mature ewes, as in the mature ram, and that this is one mechanism by which ovulation rate may be affected.

Characterization and determination of the biological activities of noncleavable high molecular weight forms of inhibin A and activin A.

Recombinant expression of human alpha- and beta A-inhibin subunit cDNAs in mammalian 293 cells results in the secretion of 20-53K free alpha-subunit-derived products, 30-105K alpha beta A-inhibin dimers, and 24-110K beta A-activin dimers. The present study verifies that the wide variation in the size of these products is due to incomplete cleavage of the proteolytic processing sites and the differential glycosylation of the N-linked glycosylation site at amino acid number 302 in the alpha C-subunit. The identity of each of these products was established by mutagenesis of proteolytic processing sites and N-linked glycosylation sites, combined with the analysis of transfection products by immunoprecipitation and one- and two-dimensional SDS-PAGE (SDS/SDS-beta-ME). Transient expression of processing site mutants of the alpha- and beta A-subunits in 293 cells was used to generate microgram quantities of noncleavable 55K and 65K inhibin dimers, and noncleavable 110K activin A dimers. The 55K and 65K inhibin A forms were purified and found to be fully biologically active in a rat pituitary cell bioassay. The 110K high molecular weight (HMW) form of human activin A failed to show any FSH-releasing activity in the pituitary assay. Since radioactively labeled 55K and 65K inhibin A and 110K activin A remained intact after incubation with rat pituitary cells for 72 h, there appears to be no conversion of these dimers to lower molecular weight forms by proteolytic cleavage at additional sites. These results show for the first time that 55K and 65K inhibit A are intrinsically biologically active and do not require cleavage to the 32K form for activation. In contrast, cleavage of the 110K activin A precursor to the 24K form would appear to be necessary for activity.

Protooncogene junB as a target for activin actions.

Activin, a member of the transforming growth factor-beta family of peptides, is implicated in the regulation of cell growth and differentiation in a variety of biological systems. We have sought to identify immediate early genes whose altered expression may provide a common nuclear event involved in activin-regulated phenotypic changes in many cell types. In both human K562 myelogenous leukemia and rat PC12 pheochromocytoma cells, activin treatment caused transient transcription-dependent and protein synthesis-independent increases of junB messenger RNA (mRNA) within 1 h, whereas neither c-jun nor c-fos mRNA were inducible. In K562 cells, this selective junB mRNA induction was synergistically augmented by treatment with 12-O-tetradecanoyl phorbol-13-acetate but not affected by forskolin. Furthermore, in PC12 cells, the up-regulation of junB mRNA by activin was observable even after high-dose treatment with 12-O-tetradecanoyl phorbol-13-acetate for 48 h, indicating that junB mRNA expression by activin is independent of both A- and C-kinases. Our report suggests that induction of this ubiquitous gene product may be a critical event shared by a set of activin-responsive tissues.

Hypothalamic infusion of activin A increases water consumption and urine volume in the rat.

Activin A immunoreactivity has been localized within the nucleus tractus solitarius and its projections into regions of the hypothalamus such as the paraventricular nucleus. However, the function of activin within the central nervous system is unclear. Because these regions of the brain are involved in the regulation of a variety of metabolic processes, we have measured body weight, food and water consumption, fecal mass, and urine volume in adult rats that received bilateral infusions of activin A into the dorsal hypothalamus near the paraventricular nuclei. Activin caused marked, parallel increases in water consumption and urine volume that were first apparent on days 3-4 and were maintained for the duration of the week-long infusions. There was no effect on water consumption or urine volume when the same doses of inhibin A or cytochrome c were infused, indicating that the effects of activin were specific and not due simply to infusion of protein into the hypothalamus. Furthermore, the effects of activin were selective for water consumption and urine volume, as neither activin, inhibin, nor cytochrome c had any effect on weight gain, food consumption, or fecal mass. Our results demonstrate that an activin A-containing neuronal system within the hypothalamus may have a role in the central regulation of fluid balance.

Development-related effects of recombinant activin on steroid synthesis in rat granulosa cells.

Activin is structurally related to polypeptide growth factors such as transforming-growth factor-beta, which may have paracrine and/or autocrine functions in the ovaries. We have investigated the action of activin on granulosa cell steroidogenesis in vitro in relation to preovulatory follicular development in vivo. Estrogen-primed immature female rats received no other treatment (nondifferentiated granulosa cells), treatment with ovine (o) FSH (differentiated granulosa cells), or treatment with oFSH followed by human (h) CG (preovulatory granulosa cells) to stimulate preovulatory follicular development. Granulosa cells were isolated and cultured in the presence and absence of recombinant human activin-A using serum-free medium supplemented with 1.0 microM testosterone as an aromatase substrate and hFSH, hLH, forskolin, or 8-bromo-cAMP to stimulate steroid synthesis in vitro. After 48 h, medium was collected for measurement of estradiol (aromatase activity), progesterone, and cAMP. Basal steroid synthesis in nondifferentiated granulosa cells was unaffected by activin, but both aromatase activity and progesterone production induced by treatment with FSH in vitro were dosedependently enhanced up to 10-fold by the presence of activin. FSH-stimulated cAMP production was not measurably altered by activin; however, steroidogenesis induced by forskolin or 8-bromo-cAMP was significantly enhanced by the factor. Thus the effect of activin on steroidogenesis includes action at a subcellular level(s) distal to the production of cAMP. After gonadotropin treatment in vivo, granulosa cell aromatase activity and progesterone production showed divergent responses to activin in vitro. Basal-, FSH-, and LH-stimulated aromatase activity were all enhanced by activin in cultures of differentiated and preovulatory granulosa cells. However, whereas basal progesterone production was stimulated by activin in cultures of differentiated granulosa cells, in preovulatory granulosa cells it was inhibited. Moreover, in vitro stimulation of progesterone production by treatment of both differentiated and preovulatory granulosa cells with FSH or LH was suppressed by the presence of activin. Thus rat granulosa cells display development-related steroidogenic responses to activin, aromatase production becoming enhanced and progesterone production suppressed as follicular maturation progresses. These results further implicate activin as a local modulator of granulosa cell steroid synthesis in the ovaries, although its functional significance has yet to be established.

Effect of recombinant activin on androgen synthesis in cultured human thecal cells.

The effect of activin-A on ovarian androgen synthesis was tested in vitro using serum-free monolayer cultures of human thecal cells. Maximal rates of androgen (androstenedione and dehydroepiandrosterone) production were induced by treating the cells for 4 days with LH (10 ng/mL) in the presence of insulin-like growth factor-I (greater than or equal to 30 ng/mL). The additional presence of recombinant activin-A (1-100 ng/mL) in culture medium caused dose-dependent suppression of thecal cell androgen production, with 50% maximal inhibition occurring at an activin-A concentration of about 10 ng/mL. Progesterone production was only suppressed by high dose (100 ng/mL) activin-A, and inhibition of steroid production occurred without inhibition of DNA synthesis (tritiated thymidine uptake). These results reveal a potent and selective inhibitory action of activin-A on thecal cell androgen synthesis, consistent with a paracrine function for activin(s) in modulating follicular androgen biosynthesis in the human ovary.

Central activin administration modulates corticotropin-releasing hormone and adrenocorticotropin secretion.

A broad and diffuse neuronal network conveys information reflecting the state of the internal and external environment to the neurosecretory hypothalamus. Recently, we identified an inhibin-beta A- (I beta A) immunoreactive terminal field within the CRF-rich portion of the dorsomedial paraventricular nucleus which originates from a cell group in the commissural portion of the nucleus of the solitary tract (NTS). The NTS receives baroreceptor input, somatosensory input via the spinosolitary tract, and sensory information from the oral, thoracic, and abdominal cavities and, thus, is positioned to serve as a primary relay for visceral sensory inputs to neurons critical to the function of the hypothalamic-pituitary-adrenal (HPA) axis. Although these NTS cells contain multiple putative transmitters, we present evidence that activin, an inhibin-beta A dimer, plays a modulatory role in HPA axis function via facilitation of CRF release. First, intraventricular injection of activin-A (0-3 nmol), but not the related inhibin heterodimer, evoked dose-related 1.7- to 2.8-fold elevations of circulating ACTH levels in male rats. Second, analysis of hypophysial-portal plasma after bilateral paraventricular nucleus microinfusion of activin-A revealed a dose-related facilitation of CRF secretion up to 4-fold above preinjection levels which was unaccompanied by changes in arginine vasopressin levels. Finally, activin-A also enhanced CRF secretion from neonatal hypothalamic cells in primary culture with an EC50 dose of approximately 0.25 nM. Overall, these observations provide evidence of both an anatomical and a pharmacological substrate for activin-mediated central modulation of HPA axis function.

Preliminary evidence for a CNS site of action for ovarian inhibin.

The ovariectomized rat bearing estrogen-containing silastic capsules underwent a primary FSH rise at 1700 hrs on all days studied. A more prolonged secondary FSH rise also occurs beginning at 2100 hrs. The primary FSH rise was attenuated or blocked by injection of charcoal-extracted porcine follicular fluid (pFF) or an extract of pFF (pFFX) limited to substances having molecular weights between 10,000 and 30,000 d. Application of pFFX directly to the dorsal anterior hypothalamic area (dAHA) by means of chronically implanted cannulas resulted in attenuation of the primary FSH rise. Similar application to medial preoptic area (mPOA) was without effect. These findings suggest that an active FSH suppressing agent, presumably ovarian inhibin, may be acting at least in part at the level of the central nervous system.