Bone morphogenetic protein 15 and growth differentiation factor 9 expression in the ovary of European sea bass (Dicentrarchus labrax): cellular localization, developmental profiles, and response to unilateral ovariectomy

Vertebrate oocytes actively contribute to follicle development by secreting a variety of growth factors, among which bone morphogenetic protein 15 (BMP15/Bmp15) and growth differentiation factor 9 (GDF9/Gdf9) have been paid particular attention. In the present study, we describe the cellular localization, the developmental profiles, and the response to unilateral ovariectomy (a procedure implying the surgical removal of one of the ovaries) of protein and mRNA steady-state levels of Bmp15 and Gdf9 in the ovary of European sea bass, an important fish species for marine aquaculture industry. In situ hybridization and immunohistochemistry demonstrated that the oocyte is the main production site of Bmp15 and Gdf9 in European sea bass ovary. During oocyte development, Bmp15 protein expression started to be detected only from the lipid vesicle stage onwards but not in primary pre-vitellogenic (i.e. perinucleolar) oocytes as the bmp15 mRNA already did. Gdf9 protein and gdf9 mRNA expression were both detected in primary perinucleolar oocytes and followed similar decreasing patterns thereafter. Unilateral ovariectomy induced a full compensatory growth of the remaining ovary in the 2-month period following surgery (Á. García-López, M.I. Sánchez-Amaya, C.R. Tyler, F. Prat 2011). The compensatory growth elicited different changes in the expression levels of mRNA and protein of both factors, although the involvement of Bmp15 and Gdf9 in the regulatory network orchestrating such process remains unclear at present. Altogether, our results establish a solid base for further studies focused on elucidating the specific functions of Bmp15 and Gdf9 during primary and secondary oocyte growth in European sea bass.     

Oocyte-expressed genes affecting ovulation rate

From examination of inherited patterns of ovulation rate in sheep, several breeds have been identified with point mutations in two growth factor genes (BMP15 and GDF9) and a related receptor (ALK6) that are expressed in oocytes. Five different point mutations have been identified in the BMP15 gene, one in GDF9 and one in ALK6. Animals heterozygous for these mutations or heterozygous for two of these mutations or homozygous for the ALK6 mutation have higher ovulation rates (i.e. +0.6-10) than their wild-type contemporaries. Animals homozygous for the BMP15 or GDF9 mutations are sterile due to arrested follicular development from the primary stage of growth. The BMP15 and GDF9 mutations are thought to result in reduced levels of mature protein or altered binding to cell-surface receptors. In sheep, GDF9 mRNA is present in germ cells before and after ovarian follicular formation as well as throughout follicular growth, whereas BMP15 mRNA is found in oocytes only from the primary stage of growth. Also ALK6 together with related cell-surface receptors such as ALK5 and BMPRII mRNA are present in oocytes at most, if not all, stages of follicular growth. Both GDF9 and BMP15 proteins are present in follicular fluid indicating that they are secreted products. Immunisation of sheep with GDF9 or BMP15 peptides shows that both growth factors are essential for follicular development, ovulation and/or corpus luteum formation. In animals with the ALK6 mutation, ovarian follicles undergo precocious maturation leading to three to seven follicles ovulating at smaller diameters without any increase above wild-types in the ovarian secretions of steroid or inhibin. One important consequence of the ALK6 mutation appears to be a decreased ability of some BMPs to inhibit differentiation of follicular cells. Current findings in sheep suggest that BMP15, GDF9 and ALK6 are targets for new methods of fertility regulation in some mammals.     

Growth differentiation factor 9 (Gdf9) was localized in the female as well as male germ cells in a protogynous hermaphroditic teleost fish, ricefield eel Monopterus albus

Growth differentiation factor 9 (GDF9) is a member of the transforming growth factor beta (TGFb) superfamily. As an oocyte-derived growth factor, GDF9 plays key roles in regulating follicle development. In the present study, we identified a gdf9 homologue from the ovary of ricefield eel, and analyzed its expression both at the mRNA and protein levels. Ricefield eel Gdf9 showed high homologies with those of other teleosts, especially perciformes fish. RT-PCR analysis revealed that ricefield eel gdf9 was expressed exclusively in the ovary and testis. The mRNA levels of gdf9 in the ovary were increased significantly at the pre-vitellogenic (PV) stage and then decreased significantly along with vitellogenesis. During the natural sex change, expression of ricefield eel gdf9 was peaked at the intersexual stages. The immunoreactivity for Gdf9 was localized exclusively in the cytoplasm of the oocytes in the ovary, particularly the oocytes at early stages, but not in the oogonia. Interestingly, strong immunoreactive signals were also detected in the degenerating oocytes in the intersexual gonad. Furthermore, the Gdf9 immunoreactivity was demonstrated for the first time to be localized in the cytoplasm of spermatogonia and spermatocytes of ricefield eel, a teleost fish. Taken together, the results of present study suggested that Gdf9 may play important roles in the folliculogenesis as well as spermatogenesis in ricefield eels.     

Growth differentiation factor 9:bone morphogenetic protein 15 heterodimers are potent regulators of ovarian functions

The TGF-β superfamily is the largest family of secreted proteins in mammals, and members of the TGF-β family are involved in most developmental and physiological processes. Growth differentiation factor 9 (GDF9) and bone morphogenetic protein 15 (BMP15), oocyte-secreted paralogs of the TGF-β superfamily, have been shown genetically to control ovarian physiology. Although previous studies found that GDF9 and BMP15 homodimers can modulate ovarian pathways in vitro, the functional species-specific significance of GDF9:BMP15 heterodimers remained unresolved. Therefore, we engineered and produced purified recombinant mouse and human GDF9 and BMP15 homodimers and GDF9:BMP15 heterodimers to compare their molecular characteristics and physiological functions. In mouse granulosa cell and cumulus cell expansion assays, mouse GDF9 and human BMP15 homodimers can up-regulate cumulus expansion-related genes (Ptx3, Has2, and Ptgs2) and promote cumulus expansion in vitro, whereas mouse BMP15 and human GDF9 homodimers are essentially inactive. However, we discovered that mouse GDF9:BMP15 heterodimer is ∼10- to 30-fold more biopotent than mouse GDF9 homodimer, and human GDF9:BMP15 heterodimer is ∼1,000- to 3,000-fold more bioactive than human BMP15 homodimer. We also demonstrate that the heterodimers require the kinase activities of ALK4/5/7 and BMPR2 to activate SMAD2/3 but unexpectedly need ALK6 as a coreceptor in the signaling complex in granulosa cells. Our findings that GDF9:BMP15 heterodimers are the most bioactive ligands in mice and humans compared with homodimers explain many puzzling genetic and physiological data generated during the last two decades and have important implications for improving female fertility in mammals.Ligands of the TGF-β superfamily, the largest family of secreted proteins in mammals, are synthesized as dimers and bind transmembrane type 1 and type 2 serine-threonine kinase receptors to activate downstream signaling cascades (e.g., the SMADs) in many developmental, physiological, and pathophysiological processes (1, 2). Growth differentiation factor 9 (GDF9) and bone morphogenic protein 15 (BMP15) are key oocyte-secreted members of the TGF-β superfamily and can regulate female fertility in several mammals (2, 3). Although GDF9 and BMP15 are closely related paralogs, they have been shown in vitro to signal through divergent SMAD2/3 and SMAD1/5/8 pathways, respectively (4–6).By studying gene knockouts and mutant models, putative roles of GDF9 and BMP15 in female reproduction have been described in mice, sheep, and humans. Our group previously discovered that Gdf9-null female mice are sterile (7), and Gdf9^+/−Bmp15^−/− double-mutant mice had more severe fertility defects than subfertile Bmp15^−/− mice (8, 9). BMP15 or GDF9 heterozygous mutant sheep have increased litter size, whereas homozygous mutants are sterile and phenocopy Gdf9^−/− mice (10, 11). In humans, mutations in GDF9 and BMP15 have been associated with premature ovarian failure and dizygotic twinning (12–14). These data suggest synergistic functions of the two gene products and potential species-specific differences in the bioactivity of these proteins. Although an in vitro study has detected the GDF9:BMP15 heterodimer by immunoprecipitation (15), and cooperative effects of the two homodimers were studied by other groups (16–18), the functions of GDF9:BMP15 heterodimers in any species remain largely unknown.In the present study, we demonstrate that GDF9:BMP15 heterodimers are the most bioactive ligands in the regulation of cumulus expansion genes. These heterodimers signal through a unique BMP receptor type 2 (BMPR2)-ALK4/5/7-ALK6 receptor complex to induce the phosphorylation of SMAD2/3 in human and mouse granulosa cells. Our findings open up prospects for the understanding of the synergistic roles of GDF9 and BMP15 proteins in ovarian functions and have important implications for improving female reproductive productivity in mammals.     

Mutational analysis of human bone morphogenetic protein 15 in Chinese women with polycystic ovary syndrome

Polycystic ovary syndrome (PCOS) is one of the common defects that cause ovary dysfunction and link to the aberrant process of folliculogenesis. Bone morphogenetic protein 15 (BMP15) is expressed in human oocytes and functions importantly to regulate early follicle growth and fertility. Previous studies have discovered several mutations in the screening of BMP15 in premature ovarian failure but none in PCOS. In this current study, we focused on the mutational analysis of the coding region of BMP15 among 216 Chinese PCOS patients. Five novel missense mutations in BMP15 were discovered, namely, c.34C>G, c.109G>C, c.169C>G, c.288G>C, and c.598C>T. These results are the first to indicate that BMP15 gene mutations may be potentially associated with PCOS patients.     

Pregnancy-associated plasma protein-a production in rat granulosa cells: stimulation by follicle-stimulating hormone and inhibition by the oocyte-derived bone morphogenetic protein-15

Pregnancy-associated plasma protein-A (PAPP-A) is the major IGF binding protein-4 (IGFBP-4) protease in follicular fluid, consistent with its proposed role in folliculogenesis. Despite growing interest, almost nothing is known about how PAPP-A expression is regulated in any tissue. Here we show that FSH and oocytes regulate PAPP-A expression in granulosa cells (GCs). By in situ hybridization, ovary PAPP-A mRNA was markedly increased by pregnant mare serum gonadotropin treatment, and the message was localized to the membrana GCs but not cumulus GCs (CGCs) of dominant follicles. To explore the mechanism, we used primary cultures of rat GCs. Control (untreated) cells produced little or no PAPP-A spontaneously. Conversely, FSH markedly stimulated PAPP-A mRNA and protein in a dose- and time-dependent fashion. Interestingly, PAPP-A expression in isolated CGCs was also strongly induced by FSH, and the induction was inhibited by added oocytes. To investigate the nature of the inhibition, we tested the effect of oocyte-derived bone morphogenetic protein-15 (BMP-15). BMP-15 alone had no effect on basal levels of PAPP-A expression by cultures of membrana GCs or CGCs. However, BMP-15 markedly inhibited the FSH stimulation of PAPP-A production in a dose-dependent manner. The cleavage of IGFBP-4 by conditioned media from FSH-treated GCs was completely inhibited by anti-PAPP-A antibody, indicating the IGFBP-4 protease secreted by GCs is PAPP-A. These results demonstrate stimulatory and inhibitory roles for FSH and BMP-15, respectively, in regulating PAPP-A production by GCs. We propose that FSH and oocyte-derived BMP-15 form a controlling network that ensures the spatiotemporal pattern of GC PAPP-A expression in the dominant follicle.     

BMP9 and BMP10 are critical for postnatal retinal vascular remodeling

ALK1 is a type I receptor of the TGF-β family that is involved in angiogenesis. Circulating BMP9 was identified as a specific ligand for ALK1 inducing vascular quiescence. In this work, we found that blocking BMP9 with a neutralizing antibody in newborn mice significantly increased retinal vascular density. Surprisingly, Bmp9-KO mice did not show any defect in retinal vascularization. However, injection of the extracellular domain of ALK1 impaired retinal vascularization in Bmp9-KO mice, implicating another ligand for ALK1. Interestingly, we detected a high level of circulating BMP10 in WT and Bmp9-KO pups. Further, we found that injection of a neutralizing anti-BMP10 antibody to Bmp9-KO pups reduced retinal vascular expansion and increased vascular density, whereas injection of this antibody to WT pups did not affect the retinal vasculature. These data suggested that BMP9 and BMP10 are important in postnatal vascular remodeling of the retina and that BMP10 can substitute for BMP9. In vitro stimulation of endothelial cells by BMP9 and BMP10 increased the expression of genes involved in the Notch signaling pathway (Jagged1, Dll4, Hey1, Hey2, Hes1) and decreased apelin expression, suggesting a possible cross-talk between these pathways and the BMP pathway.     

Expression of mRNA encoding growth differentiation factor 9 and bone morphogenetic protein 15 during follicular formation and growth in a marsupial,the brushtail possum (Trichosurus vulpecula)

The oocyte derived growth differentiation factor (GDF) 9 and bone morphogenetic protein 15 (BMP15; also known as GDF9b) are essential for normal follicular growth. However, little is known about expression of these factors during ovarian development. Therefore, we determined the ontogeny of expression of GDF9 and BMP15 mRNA in the developing ovary of the brushtail possum. Ovaries were collected from pouch young (n=3-5 per group) around times of key developmental events namely: (1) morphological sexual differentiation (i.e. days 1-5 following birth), (2) after sexual differentiation (i.e. days 10-15), (3) before and during initiation of germ-cell meiosis (i.e. days 22-45), (4) shortly after initiation of follicular growth (i.e. days 78-85), (5) during preantral follicular growth (i.e. days 96-113) and (6) during antral follicular growth (i.e. days 155-190). Ovaries were also collected from three juvenile and four adult animals and gene expression was determined by in situ hybridization. The mRNAs encoding GDF9 and BMP15 were first observed in oocytes of newly-formed primordial follicles (i.e. days 78-85). Expression of both mRNAs was restricted to the oocyte and was present in follicles irrespective of whether they were non-growing primordial follicles or undergoing preantral or antral development. Thus, since the mRNAs encoding GDF9 and BMP15 were not observed until follicular formation, it is unlikely that these proteins have any role in early germ cell development. Nevertheless, the findings that the mRNAs encoding both proteins were observed in oocytes from the primordial stage of follicular formation suggest a possible role for these proteins in the maintenance of primordial follicles as well as a key role during follicular development. These results highlight important species differences in the ontogeny of expression of GDF9 and BMP15 between possums and other species such as the human, sheep or rat.     

Mutations and sequence variants in GDF9 and BMP15 in patients with premature ovarian failure

BACKGROUND AND OBJECTIVE: Mutations in bone morphogenic protein 15 (BMP15) and growth/differentiation factor 9 (GDF9) lead to altered fertility in animal models. In the human, a heterozygous point mutation of BMP15 has been associated with premature ovarian failure (POF). SUBJECT AND METHODS: We have directly sequenced both genes in a cohort of 203 POF patients presenting with primary or secondary amenorrhea and high FSH levels and in a control population including 54 women with regular menstrual cycles who had at least one child. RESULTS: We have identified several heterozygous variants. One alteration in GDF9 (S186Y) and one in BMP15 (L148P) may have pathogenic effects as both positions are conserved in vertebrate species, ranging from the chicken to mammals. These variants were absent in the control samples. We also found synonymous and neutral substitutions. CONCLUSIONS: We propose that although mutations in BMP15 and GDF9 are not a major cause of ovarian insufficiency, they may be involved in POF.     

Context-dependent signaling defines roles of BMP9 and BMP10 in embryonic and postnatal development

Many important signaling pathways rely on multiple ligands. It is unclear if this is a mechanism of safeguard via redundancy or if it serves other functional purposes. In this study, we report unique insight into this question by studying the activin receptor-like kinase 1 (ALK1) pathway. Despite its functional importance in vascular development, the physiological ligand or ligands for ALK1 remain to be determined. Using conventional knockout and specific antibodies against bone morphogenetic protein 9 (BMP9) or BMP10, we showed that BMP9 and BMP10 are the physiological, functionally equivalent ligands of ALK1 in vascular development. Timing of expression dictates the in vivo requisite role of each ligand, and concurrent expression results in redundancy. We generated mice (Bmp10^9/9) in which the coding sequence of Bmp9 replaces that of Bmp10. Surprisingly, analysis of Bmp10^9/9 mice demonstrated that BMP10 has an exclusive function in cardiac development, which cannot be substituted by BMP9. Our study reveals context-dependent significance in having multiple ligands in a signaling pathway.     

Effect of growth hormone receptor gene disruption and PMA treatment on the expression of genes involved in primordial follicle activation in mice ovaries

The activation of the Pi3k-Akt1-FOXO pathway seems to be involved in the extended longevity observed in growth hormone receptor/growth hormone binding protein knockout (GHRKO) mice and is related to the growth of primordial ovarian follicles. The aim of this work was to measure the expression of genes in the ovaries of GHRKO and normal (N) mice treated with phorbol 12-myristate 13-acetate (PMA), an inhibitor of GH and IRS1 signaling. For this study, a group of N (n = 10) and GHRKO (n = 10) mice, N mice treated (n = 10) or not (n = 10) with PMA, and GHRKO mice treated (n = 10) or not (n = 10) with PMA were used. All were 6-month-old female mice. After the last PMA injection, the ovaries were collected for gene expression analysis. Expression of Amh, Gdf9, and Bmp15 was higher in GHRKO than N mice (P < 0.05), but was not different between PMA-treated N mice (P > 0.10). Expression of Amh and Gdf9 was higher (P < 0.05) for GHRKO PMA-treated mice. In addition, we observed a higher expression of Socs3 (P < 0.001) in GHRKO than N mice and a tendency for increased expression of Foxo3a (P = 0.07). For GHRKO PMA-treated mice, Foxo3a mRNA expression was higher (P = 0.02) and a tendency for higher expression of Mtor (P = 0.06) and Socs3 (P = 0.10) in GHRKO PMA-treated mice was observed. To summarize, the present data further confirm the previous histological observations that GHRKO mice have an ovarian phenotype characteristic of younger mice indicated by higher expression of Amh, Gdf9, and Bmp15 mRNA. In addition, we have shown a higher expression of Socs3 in GHRKO mice and higher Foxo3a expression in PMA-treated GHRKO mice, suggesting a role for these mediators in the process of ovarian aging.     

GDF-9 and BMP-15: Oocyte Organizers

It has been long known that oocyte-secreted factors play key roles in development and differentiation of ovarian follicles, but the factors involved in folliculogenesis are not well characterized to date. The recent studies on two novel TGF superfamily members, GDF-9 and BMP-15, have dramatically changed our view of ovarian physiology. GDF-9 has been shown to be obligatory for fertility in female mice by loss-of-function studies; in vitro studies further determined that GDF-9 is essential at multiple steps in the process of female reproduction. BMP-15, which shares high homology with GDF-9, seems not as essential as GDF-9 in fertility of female mice, though its expression pattern resembles GDF-9 quite closely. However, studies on sheep carrying natural mutations in the Bmp15 gene, FecX^I and FecX^H, show that BMP-15 is associated with infertility and super-fertility in a dosage-sensitive manner. Evidence from recent in vitro experiments also indicates that BMP-15 inhibits major FSH actions that are obligatory for follicle development and ovulation by suppressing FSH receptor expression in rats. Taken together, GDF-9 and/or BMP-15 may play dominant roles in female fertility in a species-dependent manner. Further studies to clarify the mechanisms by which GDF-9 and BMP-15 function will help us understand whether GDF-9, BMP-15, or both are essential for human fertility.     

Functional analysis of oocyte-expressed genes using transgenic models

An oocyte's journey is highly distinct from the vast majority of cells in the body. As one of the largest and rarest cells, oocytes express unique genes required for the genesis of healthy and competent eggs. The function of only a handful of oocyte-specific genes is beginning to be unraveled. Transgenic mouse models have proven to be extremely valuable in studying the effects of gene deletions on oocytes and surrounding somatic cells. Growth differentiation factor 9 (Gdf9), bone morphogenetic protein 15 (Bmp15), zona pellucida genes (Zp1, Zp2 and Zp3), factor in the germline alpha (Figla), and the c-mos protooncogene (c-mos) are some of the genes preferentially expressed in oocytes which play important roles during folliculogenesis. In order to identify other novel genes preferentially expressed in oocytes, we have utilized subtractive hybridization and in silico subtraction. The combination of these identification approaches, coupled with the use of knockout mice, will lead to many future functional studies of genes uniquely devoted to oogenesis and folliculogenesis.     

Conservation of early odontogenic signaling pathways in Aves

Teeth have been missing from birds (Aves) for at least 60 million years. However, in the chick oral cavity a rudiment forms that resembles the lamina stage of the mammalian molar tooth germ. We have addressed the molecular basis for this secondary loss of tooth formation in Aves by analyzing in chick embryos the status of molecular pathways known to regulate mouse tooth development. Similar to the mouse dental lamina, expression of Fgf8, Pitx2, Barx1, and Pax9 defines a potential chick odontogenic region. However, the expression of three molecules involved in tooth initiation, Bmp4, Msx1, and Msx2, are absent from the presumptive chick dental lamina. In chick mandibles, exogenous bone morphogenetic protein (BMP) induces Msx expression and together with fibroblast growth factor promotes the development of Sonic hedgehog expressing epithelial structures. Distinct epithelial appendages also were induced when chick mandibular epithelium was recombined with a tissue source of BMPs and fibroblast growth factors, chick skin mesenchyme. These results show that, although latent, the early signaling pathways involved in odontogenesis remain inducible in Aves and suggest that loss of odontogenic Bmp4 expression may be responsible for the early arrest of tooth development in living birds.     

Aberrant expression of growth differentiation factor-9 in oocytes of women with polycystic ovary syndrome

Polycystic ovary syndrome (PCOS) is a major cause of female infertility. Despite substantial effort, the etiology and pathogenesis of PCOS and polycystic ovaries (PCO) in women remain unknown. Recent studies in laboratory animals have documented a link between dysfunction of two oocyte growth factors, growth differentiation factor-9 (GDF-9) and bone morphogenetic factor-15 (BMP-15), and aberrant folliculogenesis. Because aberrant follicle development is a hallmark of PCOS, we wondered whether the expression patterns of these growth factors might be disrupted in PCOS and PCO oocytes. To address this issue, we compared the pattern and level of expression of GDF-9 and BMP-15 mRNA in ovaries from normal cycling (n = 12), PCOS (n = 5), and PCO (n = 7) patients. In situ hybridization studies showed that the expression of GDF-9 and BMP-15 is restricted to the oocytes in all ovaries examined. Interestingly, a decreased level of GDF-9 signal was observed in developing PCOS and PCO oocytes, compared with normal. This difference was evident throughout folliculogenesis, beginning at recruitment initiation and continuing through the small Graafian follicle stage. By contrast, there were no qualitative or quantitative changes in the expression of BMP-15 mRNA in PCOS oocytes during folliculogenesis. There were also no significant differences between normal and PCOS and PCOs in the levels of the mRNA encoding the housekeeping gene, cyclophilin. Together, these results indicate that the expression of GDF-9 mRNA is delayed and reduced in PCOS and PCO oocytes during their growth and differentiation phase. Because oocyte-derived GDF-9 is crucial for normal folliculogenesis and female fertility, we suggest that a dysregulation of oocyte GDF-9 expression may contribute to aberrant folliculogenesis in PCOS and PCO women.