Mark Cranfield

Growth Differentiation Factor 9 and Bone Morphogenetic Protein 15 Are Essential for Ovarian Follicular Development in Sheep

Abstract The aim of this study was to test the hypothesis that both growth differential factor 9 (GDF9) and bone morphogenetic protein (BMP15; also known as GDF9B) are essential for normal ovarian follicular development in mammals with a low ovulation rate phenotype. Sheep (9–10 per group) were immunized with keyhole limpet hemocyanin (KLH; control), a GDF9-specific peptide conjugated to KLH (GDF9 peptide), a BMP15-specific peptide conjugated to KLH (BMP15 peptide), or the mature region of oBMP15 conjugated to KLH (oBMP15 mature protein) for a period of 7 mo and the effects of these treatments on various ovarian parameters such as ovarian follicular development, ovulation rate, and plasma progesterone concentrations evaluated. Also in the present study, we examined, by immunohistochemistry, the cellular localizations of GDF9 and BMP15 proteins in the ovaries of lambs. Both GDF9 and BMP15 proteins were localized specifically within ovarian follicles to the oocyte, thereby establishing for the sheep that the oocyte is the only intraovarian source of these growth factors. Immunization with either GDF9 peptide or BMP15 peptide caused anovulation in 7 of 10 and 9 of 10 ewes, respectively, when assessed at ovarian collection. Most ewes (7 of 10) immunized with oBMP15 mature protein had a least one observable estrus during the experimental period, and ovulation rate at this estrus was higher in these ewes compared with those immunized with KLH alone. In both the KLH-GDF9 peptide- and KLH-BMP15 peptide-treated ewes, histological examination of the ovaries at recovery (i.e., ∼7 mo after the primary immunization) showed that most animals had few, if any, normal follicles beyond the primary (i.e., type 2) stage of development. In addition, abnormalities such as enlarged oocytes surrounded by a single layer of flattened and/or cuboidal granulosa cells or oocyte-free nodules of granulosa cells were often observed, especially in the anovulatory ewes. Passive immunization of ewes, each given 100 ml of a pool of plasma from the GDF9 peptide- or BMP15 peptide-immunized ewes at 4 days before induction of luteal regression also disrupted ovarian function. The ewes given the plasma against the GDF9 peptide formed 1–2 corpora lutea but 3 of 5 animals did not display normal luteal phase patterns of progesterone concentrations. The effect of plasma against the BMP15 peptide was more dramatic, with 4 of 5 animals failing to ovulate and 3 of 5 ewes lacking surface-visible antral follicles at laparoscopy. By contrast, administration of plasma against KLH did not affect ovulation rate or luteal function in any animal. In conclusion, these findings support the hypothesis that, in mammals with a low ovulation rate phenotype, both oocyte-derived GDF9 and BMP15 proteins are essential for normal follicular development, including both the early and later stages of growth.

Immunoneutralization of Growth Differentiation Factor 9 Reveals It Partially Accounts for Mouse Oocyte Mitogenic Activity

Abstract Paracrine factors secreted by oocytes play a pivotal role in promoting early ovarian follicle growth and in defining a morphogenic gradient in antral follicles, yet the exact identities of these oocyte factors remain unknown. This study was conducted to determine the extent to which the mitogenic activity of mouse oocytes can be attributed to growth differentiation factor 9 (GDF9). To do this, specific anti-human GDF9 monoclonal antibodies were generated. Based on epitope mapping and bioassays, a GDF9 neutralizing antibody, mAb-GDF9-53, was characterized with very low cross-reactivity with related transforming growth factor (TGF)β superfamily members, including BMP15 (also called GDF9B). Pep-SPOT epitope mapping showed that mAb-GDF9-53 recognizes a short 4-aa sequence, and three-dimensional peptide modeling suggested that this binding motif lies at the C-terminal fingertip of mGDF9. As predicted by sequence alignments and modeling, the antibody detected recombinant GDF9, but not BMP15 in a Western blot and GDF9 protein in oocyte extract and oocyte-conditioned medium. In a mouse mural granulosa cell (MGC) bioassay, mAb-GDF9-53 completely abolished the mitogenic effects of GDF9, but had no effect on TGFβ1 or activin A-stimulated MGC proliferation. An unrelated IgG at the same dose had no effect on GDF9 activity. This GDF9 neutralizing antibody was then tested in an established oocyte-secreted mitogen bioassay, where denuded oocytes cocultured with granulosa cells promote cell proliferation in a dose-dependent manner. The mAb-GDF9-53 dose dependently (0–160 μg/ml) decreased the mitogenic activity of oocytes but only by ∼45% at the maximum dose of mAb. Just 5 μg/ml of mAb-GDF9-53 neutralized 90% of recombinant mGDF9 mitogenic activity, but only 15% of oocyte activity. Unlike mAb-GDF9-53, a TGFβ pan-specific neutralizing antibody did not affect the mitogenic capacity of the oocyte, but completely neutralized TGFβ1-induced DNA synthesis. This study has characterized a specific GDF9 neutralizing antibody. Our data provide the first direct evidence that the endogenous GDF9 protein is an important oocyte-secreted mitogen, but also show that GDF9 accounts for only part of total oocyte bioactivity.

Localization of Activin βA-,β B-, andβ C-Subunits in Human Prostate and Evidence for Formation of New Activin Heterodimers ofβ C-Subunit1

Activin ligands are formed by dimerization of activin ss(A)- and/or ss(B)-subunits to produce activins A, AB, or B. These ligands are members of the transforming growth factor-ss superfamily and act as growth and differentiation factors in many cells and tissues. New additions to this family include activin ss(C)-, ss(D)-, and ss(E)-subunits. The aim of this investigation was to examine the localization of and dimerization among activin subunits; the results demonstrate that activin ss(C) can form dimers with activin ss(A) and ss(B) in vitro, but not with the inhibin alpha-subunit. Using a specific antibody, activin ss(C) protein was localized to human liver and prostate and colocalized with ss(A)- and ss(B)-subunits to specific cell types in benign and malignant prostate tissues. Activin C did not alter DNA synthesis of the prostate tumor cell line, LNCaP, or the liver tumor cell line, HepG2, in vitro when added alone or with activin A. Therefore, the capacity to form novel activin heterodimers (but not inhibin C) resides in the human liver and prostate. Activin A, AB, and B have diverse actions in many tissues, including liver and prostate, but there is no known biological activity for activin C. Thus, the evidence of formation of activin AC or BC heterodimers may have significant implications in the regulation of levels and/or biological activity of other activins in these tissues.

Cell-specific expression of βC-activin in the rat reproductive tract, adrenal and liver

betaC-activin expression was assessed in rat tissues, using reverse transcription and real-time polymerase chain reaction, Western blotting and immunohistochemistry with a specific monoclonal antibody. betaC-activin mRNA was predominantly expressed in liver, but significant amounts were found in rat whole pituitary extracts (n = 5), and in three of five extracts of ovary, testis, and adrenal gland. Specific betaC-activin immunoreactivity was demonstrated in the cytoplasm of hepatocytes, neurosecretory cell terminals in posterior pituitary, ovarian primordial follicles, theca interna, large luteal cells and rete ovarii, spermatogonia, pachytene spermatocytes and Leydig cells of the testis, uterine endometrium, oviduct epithelium and zona glomerulosa of the adrenal. The observation of stage-specific expression in gonadal cells suggests this activin subunit has specific roles, different from those of other activin/inhibin subunits. Small amounts of mRNA in the presence of significant betaC-activin protein highlights the importance of examining betaC-activin expression at both the mRNA and protein level.

Changes in activin and activin receptor subunit expression in rat liver during the development of CCl4-induced cirrhosis

Amounts of betaA-activin, betaC-activin, activin receptor subunits ActRIIA and ActRIIB mRNA, and betaA- and betaC-activin subunit protein immunoreactivity were investigated in male Lewis rats, either untreated or after 5 or 10 weeks of CCl(4) treatment to induce cirrhosis. Apoptosis was assessed histologically and with an in situ cell death detection kit (TUNEL). Reverse transcription and polymerase chain reaction were used to evaluate mRNA levels. Activin betaA- and betaC-subunit immunoreactivity was studied by immunohistochemistry using specific monoclonal antibodies. Hepatocellular apoptosis (P<0.001), increased betaA- and betaC-activin mRNAs (three- to fourfold; P<0.01) and increased betaA- and betaC-activin tissue immunoreactivity were evident, whereas ActRIIA mRNA concentrations fell (30%; P<0.01) after 5 weeks of CCl(4) treatment. The mRNA concentrations at 10 weeks were not significantly different from controls, despite extensive hepatic nodule formation. We conclude that the increased activin subunit expression is associated with apoptosis, rather than hepatic fibrosis and nodule formation.

Enzyme immunoassays for inhibins, activins and follistatins

In this short review, the authors summarise the inhibin, activin and follistatin assays developed by the Oxford group and collaborators, and some of the main purposes for which they have been applied. Over 500 research publications have used these assays. We also discuss new assays recently developed at the request of our collaborators for particular applications, and comment on outstanding assay problems.

93. Immunoneutralization of growth differentiation factor-9 reveals it partially accounts for oocyte mitogenic activity

REVEALS IT PARTIALLY ACCOUNTS FOR OOCYTE MITOGENIC ACTIVITY R.B. Gilchrist, L.J. Ritter, M. Cranfield, L. Jeffery, F. Amato, S. Myllymaa, H. Lankinen, D.G. Mottershead, N.P. Groome and O. Ritvos Reproductive Medicine Unit, Department of Obstetrics & Gynaecology, University of Adelaide, Australia. School of Biological & Molecular Sciences, Oxford Brookes University, Headington, UK. Programme for Developmental & Reproductive Biology, Biomedicum Helsinki, and Department of Bacteriology & Immunology, and Peptide & Protein Laboratory, Department of Virology, Haartman Institute, University of Helsinki, Finland.

Localization of Activin βA-,βB-, andβC-Subunits in Human Prostate and Evidence for Formation of New Activin Heterodimers ofβC-Subunit1

Activin ligands are formed by dimerization of activin ss(A)- and/or ss(B)-subunits to produce activins A, AB, or B. These ligands are members of the transforming growth factor-ss superfamily and act as growth and differentiation factors in many cells and tissues. New additions to this family include activin ss(C)-, ss(D)-, and ss(E)-subunits. The aim of this investigation was to examine the localization of and dimerization among activin subunits; the results demonstrate that activin ss(C) can form dimers with activin ss(A) and ss(B) in vitro, but not with the inhibin alpha-subunit. Using a specific antibody, activin ss(C) protein was localized to human liver and prostate and colocalized with ss(A)- and ss(B)-subunits to specific cell types in benign and malignant prostate tissues. Activin C did not alter DNA synthesis of the prostate tumor cell line, LNCaP, or the liver tumor cell line, HepG2, in vitro when added alone or with activin A. Therefore, the capacity to form novel activin heterodimers (but not inhibin C) resides in the human liver and prostate. Activin A, AB, and B have diverse actions in many tissues, including liver and prostate, but there is no known biological activity for activin C. Thus, the evidence of formation of activin AC or BC heterodimers may have significant implications in the regulation of levels and/or biological activity of other activins in these tissues.