Growth Differentiation Factor 9 (GDF9) Suppresses Follistatin and Follistatin-Like 3 Production in Human Granulosa-Lutein Cells

We have demonstrated that growth differentiation factor 9 (GDF9) enhances activin A-induced inhibin β(B)-subunit mRNA levels in human granulosa-lutein (hGL) cells by regulating receptors and key intracellular components of the activin signaling pathway. However, we could not exclude its effects on follistatin (FST) and follistatin-like 3 (FSTL3), well recognized extracellular inhibitors of activin A.hGL cells from women undergoing in vitro fertilization (IVF) treatment were cultured with and without siRNA transfection of FST, FSTL3 or GDF9 and then treated with GDF9, activin A, FST, FSTL3 or combinations. FST, FSTL3 and inhibin β(B)-subunit mRNA, and FST, FSTL3 and inhibin B protein levels were assessed with real-time RT-PCR and ELISA, respectively. Data were log transformed before ANOVA followed by Tukey's test.GDF9 suppressed basal FST and FSTL3 mRNA and protein levels in a time- and dose-dependent manner and inhibited activin A-induced FST and FSTL3 mRNA and protein expression, effects attenuated by BMPR2 extracellular domain (BMPR2 ECD), a GDF9 antagonist. After GDF9 siRNA transfection, basal and activin A-induced FST and FSTL3 mRNA and protein levels increased, but changes were reversed by adding GDF9. Reduced endogenous FST or FSTL3 expression with corresponding siRNA transfection augmented activin A-induced inhibin β(B)-subunit mRNA levels as well as inhibin B levels (P values all <0.05). Furthermore, the enhancing effects of GDF9 in activin A-induced inhibin β(B)-subunit mRNA and inhibin B production were attenuated by adding FST.GDF9 decreases basal and activin A-induced FST and FSTL3 expression, and this explains, in part, its enhancing effects on activin A-induced inhibin β(B)-subunit mRNA expression and inhibin B production in hGL cells

‘Free’ inhibin α subunit is expressed by bovine ovarian theca cells and its knockdown suppresses androgen production

Inhibins are ovarian dimeric glycoprotein hormones that suppress pituitary FSH production. They are synthesised by follicular granulosa cells as α plus βA/βB subunits (encoded by INHA, INHBA, INHBB, respectively). Inhibin concentrations are high in follicular fluid (FF) which is also abundant in ‘free’ α subunit, presumed to be of granulosal origin, but its role(s) remains obscure. Here, we report the unexpected finding that bovine theca cells show abundant INHA expression and ‘free’ inhibin α production. Thus, theca cells may contribute significantly to the inhibin α content of FF and peripheral blood. In vitro, knockdown of thecal INHA inhibited INSL3 and CYP17A1 expression and androgen production while INSL3 knockdown reduced INHA and inhibin α secretion. These findings suggest a positive role of thecal inhibin α on androgen production. However, exogenous inhibin α did not raise androgen production. We hypothesised that inhibin α may modulate the opposing effects of BMP and inhibin on androgen production. However, this was not supported experimentally. Furthermore, neither circulating nor intrafollicular androgen concentrations differed between control and inhibin α-immunized heifers, casting further doubt on thecal inhibin α subunit having a significant role in modulating androgen production. Role(s), if any, played by thecal inhibin α remain elusive

The Cellular Mechanism for Water Detection in the Mammalian Taste System

Initiation of drinking behavior relies on both internal state and peripheral water detection. While central neural circuits regulating thirst have been well studied, it is still unclear how mammals recognize external water. Here we show that acid-sensing taste receptor cells (TRCs) that were previously suggested as the sour taste sensors also mediate taste responses to water. Genetic silencing of these TRCs abolished water-evoked responses in taste nerves. Optogenetic self-stimulation of acid-sensing TRCs in thirsty animals induced robust drinking responses toward light even without water. This behavior was only observed when animals were water-deprived but not under food- or salt-depleted conditions, indicating that the hedonic value of water-evoked responses is highly internal-state dependent. Conversely, thirsty animals lacking functional acid-sensing TRCs showed compromised discrimination between water and nonaqueous fluids. Taken together, this study revealed a function of mammalian acid-sensing TRCs that provide a cue for external water

Activin regulates betaA-subunit and activin receptor messenger ribonuclic acid and cellular proliferation in activin-responsive testicular tumor cells

Activin, a member of the transforming growth factor-beta superfamily of growth and differentiation factors, has a number of actions in embryonic as well as adult tissues. These actions are mediated via a family of receptors containing two subtypes and at least two members of each subtype. Recent evidence demonstrates that activin-responsive cell lines containing different subsets of these receptors are valuable models for dissecting functional relationships among receptor subtype, signal transduced, and response obtained. TT cells, derived from a p53(-/-)/alpha-inhibin(-/-) mouse testicular tumor, respond to activin by proliferating, a response that can be inhibited by follistatin (FS) treatment. Using semiquantitative RT-PCR methods, we characterized steady state messenger RNA (mRNA) levels for the inhibin/activin subunits, FS, and activin receptor subtypes under basal conditions and in the presence of activin or FS. These cells produced ample immunoreactive activin A and FS, necessitating higher treatment doses to observe any modulation of cellular proliferation. Furthermore, in the presence of exogenous activin, mRNA levels for activin receptor type IIA (ACTRIIA) and betaA were significantly and profoundly suppressed. In addition, both ACTR1B and ACTRIIB were detectable and down-regulated by exogenous activin, although not to the degree observed for ACTRIIA and betaA. Finally, activin treatment at the higher doses, which decreased activin receptor mRNA levels, resulted in inhibition of cellular proliferation. Taken together with previous observations, our results support the model that these tumor cells respond to an autocrine activin signal by proliferating, whereas exogenous or excess activin results in down-regulation of activin receptor and activin biosynthesis, suggesting a potential autocrine/paracrine mechanism by which activin can modulate its own signa

Characterization of inhibin/activin subunit, follistatin, and activin type II receptors in human ovarian cancer cell lines: a potential role in autocrine growth regulation

Although ovarian cancer is the most common gynecological malignancy with a relatively poor 5-yr survival record, the mechanism(s) by which these tumors arise is not well understood. A role for inhibins and activins in regulating this transformation is suggested by the detection of circulating alpha or dimeric inhibin in some patients with ovarian cancer and by the alpha inhibin knockout mouse, in which development of gonadal tumors in 100% of homozygotes is associated with greatly elevated activin levels. To develop diagnostic tools with greater specificity for ovarian cancers, the present study was targeted at characterizing the biosynthetic capacity of the epithelial ovarian cancer cell lines from the American Type Culture Collection with respect to inhibin, activin, the related activin-binding protein follistatin (FS), and activin receptor type II. In addition, the functional capacity of this system was investigated by examining the ability of activin and FS to modulate cellular proliferation. All six cell lines contained abundant messenger RNA (mRNA) for activin receptor type II, but no inhibin alpha-subunit mRNA was detected in any cell line. Two cell lines contained mRNA for activin beta B-subunit (CaOV4 and SKOV3), one cell line contained beta A-subunit mRNA (SW626), and one cell line contained both (ES2); the latter also contained FS mRNA. FS mRNA was detected in another cell line (PA-1) that contained no detectable activin beta-subunit mRNA. Finally, one cell line (CaOV3) contained neither beta-subunit nor FS mRNA. Protein secretion was also examined. Consistent with the mRNA studies, the two cell lines containing FS mRNA secreted FS (PA-1 and ES2 cells), whereas three of the remaining lines secreted activin (A or B). In the cell line containing neither FS nor beta-subunit mRNA, no FS or activin could be detected. Finally, none of the cell lines secreted detectable immunoreactive inhibin. The effects of exogenous activin and FS on cellular proliferation were examined in these cell lines. No response was detected in the two cell lines that secreted FS (PA-1 and ES2). For the four cell lines not synthesizing FS, treatment with activin (1-100 ng/ml) resulted in an increase, whereas FS treatment (1-100 ng/ml) resulted in a decrease in cellular proliferation, as determined by [3H]thymidine incorporation. The response to activin correlated negatively with endogenous activin production, suggesting that autocrine activin production may be involved with cell proliferation. The differential expression and production of inhibin/activin subunits, activin receptors, and follistatin as well as the range of responses to exogenous activin among six ovarian epithelial cancer cell lines suggest that this family of hormones may be important in regulating cell proliferation in the ovary. Whether primary tumors have the same profile and the degree to which these results can be generalized to additional forms of ovarian cancer remain to be determine