Qualitative modeling identifies IL-11 as a novel regulator in maintaining self-renewal in human pluripotent stem cells.

Pluripotency in human embryonic stem cells (hESCs) and induced pluripotent stem cells (iPSCs) is regulated by three transcription factors-OCT3/4, SOX2, and NANOG. To fully exploit the therapeutic potential of these cells it is essential to have a good mechanistic understanding of the maintenance of self-renewal and pluripotency. In this study, we demonstrate a powerful systems biology approach in which we first expand literature-based network encompassing the core regulators of pluripotency by assessing the behavior of genes targeted by perturbation experiments. We focused our attention on highly regulated genes encoding cell surface and secreted proteins as these can be more easily manipulated by the use of inhibitors or recombinant proteins. Qualitative modeling based on combining boolean networks and in silico perturbation experiments were employed to identify novel pluripotency-regulating genes. We validated Interleukin-11 (IL-11) and demonstrate that this cytokine is a novel pluripotency-associated factor capable of supporting self-renewal in the absence of exogenously added bFGF in culture. To date, the various protocols for hESCs maintenance require supplementation with bFGF to activate the Activin/Nodal branch of the TGFβ signaling pathway. Additional evidence supporting our findings is that IL-11 belongs to the same protein family as LIF, which is known to be necessary for maintaining pluripotency in mouse but not in human ESCs. These cytokines operate through the same gp130 receptor which interacts with Janus kinases. Our finding might explain why mESCs are in a more naïve cell state compared to hESCs and how to convert primed hESCs back to the naïve state. Taken together, our integrative modeling approach has identified novel genes as putative candidates to be incorporated into the expansion of the current gene regulatory network responsible for inducing and maintaining pluripotency.

Tolerogenic dendritic cells and their role in induction of immune tolerance

Les cellules dendritiques sont des cellules du système immunitaire qui permettent d'instruire les lymphocytes T, autres cellules de ce système, pour mettre en place une réponse immunitaire adaptée afin de combattre et vaincre une infection. Ces cellules dendritiques vont reconnaître des motifs spécifiquement exprimés par des pathogènes par l'intermédiaire de récepteurs exprimés à leur surface. En détectant ces molécules, elles vont s'activer et subir diverses modifications pour pouvoir activer les lymphocytes T. Elles vont alors interagir avec les lymphocytes Τ et transférer les informations nécessaires pour que ces cellules s'activent à leur tour et produisent différentes protéines de façon à éliminer le pathogène. En fonction du type de pathogène, les informations transférées entre les cellules dendritiques et les lymphocytes seront différentes de manière à produire la réponse immunitaire la mieux adaptée pour supprimer l'élément infectieux. Dans le corps, les cellules dendritiques circulent continuellement afin de détecter les éléments étrangers. Quand elles reconnaissent une protéine étrangère, elles la phagocytent, c'est-à-dire qu'elles la mangent afin de pouvoir la présenter aux lymphocytes T. Mais quand elles phagocytent un élément étranger, elles peuvent également prendre des éléments du soi, comme par exemple quand elles phagocytent une cellule infectée par un virus. Les cellules dendritiques doivent alors être capables de différentier les molécules du soi et du non-soi de façon à ne pas induire une réponse en présentant un antigène du soi aux lymphocytes T. D'autant plus que lors de leur développement, les lymphocytes Τ qui sont capables de reconnaître le soi sont éliminés mais ce système n'est pas parfait et donc certains lymphocytes Τ auto-reactifs peuvent se trouver dans le corps. Il existe ainsi d'autres mécanismes en périphérie du site de développement pour inhiber ces lymphocytes Τ auto-reactifs. Ce sont les mécanismes de tolérance. Quand les lymphocytes Τ induisent une réponse aux antigènes du soi, cela résulte à des maladies auto-immunes. Dans mon projet de recherche, nous avons travaillé avec des lignées de cellules dendritiques, c'est-à-dire des cellules dendritiques semblables à celles que l'on peut trouver in vivo mais qui sont immortalisées, elles peuvent donc être cultiver et manipuler in vitro. Nous avons génétiquement modifiées ces lignées cellulaires pour qu'elles expriment des molécules immunosuppressives afin d'étudier comment induire une tolérance immunitaire, c'est-à-dire si l'expression de ces molécules permet d'éviter de générer une réponse immunitaire. Pour cela, nous avons utilisé des modèles murins de tumeurs et de maladies auto-immunes. Nous avons démontré que ces lignées de cellules dendritiques peuvent être un grand outil de recherche pour étudier les bénéfices de différentes molécules immuno-modulatrices afin d'induire une tolérance immunitaire à différents antigènes. - Les cellules dendritiques sont responsables de l'induction des réponses immunitaires adaptatives. Suite à une infection microbienne, les cellules dendritiques s'activent, elles induisent l'expression de molécules de costimulation à leur surface, sécrètent des cytokines et induisent la différentiation des cellules Τ effectrices et mémoires. De plus, les cellules dendritiques ont un rôle important dans l'induction et la maintenance de la tolérance immunitaire au niveau du thymus et en périphérie, en induisant l'anergie, la délétion ou la conversion des cellules Τ naïves en cellules régulatrices. Dans notre groupe, une nouvelle lignée de cellules dendritiques appelée MuTu a été crée par la culture de cellules dendritiques tumorales isolées à partir d'une rate d'une souris transgénique, dans laquelle l'expression de l'oncogène SV40 et du GFP sont sous le contrôle du promoteur CD1 le, et sont ainsi spécifiquement exprimés dans les cellules dendritiques. Ces nouvelles lignées appartiennent au sous-type des cellules dendritiques conventionnelles exprimant CD8a. Elles ont conservé leur capacité d'augmenter l'expression des marqueurs de costimulation à leur surface ainsi que le production de cytokines en réponse à des ligands des récepteurs Toll, ainsi que leur capacité à présenter des antigènes associés aux molécules du complexe majeur d'histocompatibilité (CMH) de classe I ou II pour activer la prolifération et la différentiation des lymphocytes T. En utilisant un système de transduction de lentivirus de seconde génération, ces nouvelles lignées de cellules dendritiques ont été génétiquement modifiées pour sur-exprimer des molécules immunosuppressives (IL-10, TGFP latent, TGFp actif, Activin A, Arginase 1, IDO, B7DC et CTLA4). Ces lignées permettent d'étudier de manière reproductible le rôle de ces molécules potentiellement tolérogènes sur les réponses immunitaires in vitro et in vivo. Ces lignées potentiellement tolérogènes ont été testées, tout d'abord, in vitro, pour leur capacité à inhiber l'activation des cellules dendritiques, à bloquer la prolifération des cellules Τ ou à modifier leur polarisation. Nos résultats démontrent qu'en réponse à une stimulation, la sur-expression des molécules costimulatrices et la sécrétion de molécules pro- inflammatoires est réduite quand les cellules dendritiques sur-expriment l'IL-10. La sur¬expression de TGFp sous sa forme active induit le développement de cellules régulatrices CD4+ CD25+ Foxp3+ et bloque la réponse CD8 cytotoxique tandis que la sur-expression de CTLA4 à la surface des cellules dendritiques inhibe une réponse Thl et induit des lymphocytes Τ anergiques. Ces lignées ont également été utilisées pour étudier l'induction de tolérance in vivo. Tout d'abord, nous avons étudié l'induction de tolérance dans un modèle de développement de tumeurs. En effet, quand les lignées tumorales sont transférées dans les lignées de souris C57BL/6, elles sont reconnues comme du non-soi du à l'expression de l'oncogène SV40 et du GFP et sont éliminées. Ce mécanisme d'élimination a été étudié en utilisant une lignée de cellules dendritiques modifiée pour exprimer la luciférase et qui a permis de suivre le développement des tumeurs par de l'imagerie in vivo dans des animaux vivants. Ces lignées de cellules dendritiques MuTu sont éliminées dans la souris C57BL/6 par les lymphocytes CD8 et l'action cytotoxique de la perforine. Après plusieurs injections, les cellules dendritiques sur-exprimant CTLA4 ou l'actif TGFp peuvent casser cette réponse immunitaire inhérente aux antigènes de la lignée et induire le développement de la tumeur dans la souris C57BL/6. Le développement tumoral a pu être suivi en mesurant la bioluminescence émise par des cellules dendritiques modifiées pour exprimer à la fois l'actif TGFp et la luciférase. Ces tumeurs ont pu se développer grâce à la mise en place d'un microenvironnement suppressif pour échapper à l'immunité en recrutant des cellules myéloïde suppressives, des lymphocytes CD4 régulateurs et en induisant l'expression d'une molécule inhibitrice PD-1 à la surface des lymphocytes CD8 infiltrant la tumeur. Dans un deuxième temps, ces lignées tolérogènes ont également été testées dans un modèle murin de maladies auto-immunes, appelé l'encéphalomyélite auto-immune expérimental (EAE), qui est un modèle pour la sclérose en plaques. L'EAE a été induite dans la souris par le transfert de cellules de ganglions prélevées d'une souris donneuse préalablement immunisée avec une protéine du système nerveux central, la glycoprotéine myéline oligodendrocyte (MOG) émulsifiée dans de l'adjuvant complet de Freund. La vaccination des souris donneuses et receveuses avec les cellules sur-exprimant l'actif TGFP préalablement chargées avec la protéine MOG bloque l'induction de l'EAE. Nous sommes actuellement en train de définir les mécanismes qui permettent de protéger la souris du développement de la maladie auto-immune. Dans cette étude, nous avons ainsi démontré la possibilité d'induire la tolérance in vivo et in vitro à différents antigènes en utilisant nos nouvelles lignées de cellules dendritiques et en les modifiant pour exprimer des molécules immunosuppressives. En conséquence, ces nouvelles lignées de cellules dendritiques représentent un outil pour explorer les bénéfices de différentes molécules ayant des propriétés immuno-modulatrices pour manipuler le système immunitaire vers un phénotype tolérogène. - Dendritic cells (DC) are widely recognized as potent inducers of the adaptive immune responses. Importantly, after microbial infections, DC become activated, induce co- stimulation, secrete cytokines and induce effector and memory Τ cells. DC furthermore play an important role in inducing and maintaining central and peripheral tolerance by inducing anergy, deletion or commitment of antigen-specific naïve Τ cells into regulatory Τ cells. In our group, stable MuTu DC lines were generated by culture of splenic DC tumors from transgenic mice expressing the SV40 large Τ oncogene and the GFP under DC-specific CDllc promoter. These transformed DC belong to the CD8a+ conventional DC subtype and have fully conserved their capacity to upregulate co-stimulatory markers and produce cytokines after activation with Toll Like Receptors-ligands, and to present Major Histocompatibility class-I or MHCII-restricted antigens to activate Τ cell expansion and differentiation. Using a second- generation lentiviral transduction system, these newly developed MuTu DC lines were genetically modified to overexpress immunosuppressive molecules (IL-10, latent TGFp, active TGFp, Activin A, Arginase 1, IDO, B7DC and CTLA4). This allows to reproducibly investigate the role of these potentially tolerogenic molecules on in vitro and in vivo immune responses. These potentially tolerogenic DC were tested in vitro for their ability to inhibit DC activation, to prevent Τ cell proliferation and to modify Τ cell polarization. Our results show that the upregulation of costimulatory molecules and the secretion of pro-inflammatory cytokines were reduced upon stimulation of DC overexpressing IL-10. The overexpression of active TGFP induced the development of CD4+ CD25+ Foxp3+ regulatory Τ cells and inhibited the cytotoxic CD8 Τ cell response as shown by using the OT-II Τ cell system whereas the surface expression of CTLA-4 on DC prevented the Thl response and prompted an anergic antigen-specific Τ cell response. These MuTu DC lines were also used in vivo in order to study the induction of tolerance. First we addressed the induction of tolerance in a model of tumorogenesis. The adoptively transferred tumor cell lines were cleared in C57BL/6 mice due to the foreign expression of SV40 LargeT and GFP. The mechanism of clearance of MuTu DC line into C57BL/6 mice was investigated by using luciferase-expressing DC line. These DC line allowed to follow, by in vivo imaging, the tumor development in living animals and determined that MuTu DC lines were eliminated in a perforin-mediated CD8 Τ cell dependent and CD4 Τ cell independent response. After multiple injections, DC overexpressing CTLA4 or active TGFp could break the immune response to these inherent antigens and induced DC tumorogenesis in wild type mice. The tumor outgrowth in C57BL/6 mice was nicely observed by double-transduced DC lines to express both luciferase and active TGFp. actTGFp-DC tumor was shown to recruit myeloid-derived suppressor cells, induce CD4+ CD25+ Foxp3+ regulatory Τ cells and induce the expression of the inhibitory receptor PD-1 on tumor- infiltrating CD8+ Τ cells in order to escape tumor immunity. Tolerogenic DC lines were also tested for the induction of tolerance in a murine model of autoimmune disease, the experimental autoimmune encephalitis (EAE) model for human multiple sclerosis. EAE was induced in C57BL/6 mice by the adoptive transfer of lymph node cells isolated from donor mice previously immunized by a protein specific to the central nervous system, the myelin oligodendrocyte glycoprotein (MOG) emulsified in the complete freund adjuvant. The vaccination of donor and recipient mice with MOG-pulsed actTGFP-DC line prevented EAE induction. We are still investigating how the active TGFP protect mice from EAE development. We generated tolerogenic DC lines inducing tolerance in vitro and in vivo. Thereby these MuTu DC lines represent a great tool to explore the benefits of various immuno-modulatory molecules to manipulate the immune system toward a tolerogenic phenotype.

Bone morphogenetic proteins: from structure to clinical use

Bone morphogenetic proteins (BMPs) are multi-functional growth factors belonging to the transforming growth factor ß superfamily. Family members are expressed during limb development, endochondral ossification, early fracture, and cartilage repair. The activity of BMPs was first identified in the 1960s but the proteins responsible for bone induction were unknown until the purification and cloning of human BMPs in the 1980s. To date, about 15 BMP family members have been identified and characterized. The signal triggered by BMPs is transduced through serine/threonine kinase receptors, type I and II subtypes. Three type I receptors have been shown to bind BMP ligands, namely: type IA and IB BMP receptors and type IA activin receptors. BMPs seem to be involved in the regulation of cell proliferation, survival, differentiation and apoptosis, but their hallmark is their ability to induce bone, cartilage, ligament, and tendon formation at both heterotopic and orthotopic sites. This suggests that, in the future, they may play a major role in the treatment of bone diseases. Several animal studies have illustrated the potential of BMPs to enhance spinal fusion, repair critical-size defects, accelerate union, and heal articular cartilage lesions. Difficulties in producing and purifying BMPs from bone tissue have prompted the attempts made by several laboratories, including ours, to express these proteins in the recombinant form in heterologous systems. This review focuses on BMP structure, molecular mechanisms of action and significance and potential applications in medical, dental and veterinary practice for the treatment of cartilage and bone-related diseases.

Evidence for an inhibitory role of bone morphogenetic protein(s) in the follicular-luteal transition in cattle

Bone morphogenetic proteins (BMPs) and their receptors are expressed in ovarian theca cells (TC) and granulosa cells (GC) and BMPs have been implicated in the regulation of several aspects of follicle development including thecal androgen production and granulosal oestrogen production. Their potential involvement in luteal function has received less attention. in this study, we first compared relative abundance of mRNA transcripts for BMPs, activin-beta A and BMP/activin receptors in bovine corpus luteum (CL) and follicular theca and granulosa layers before undertaking functional in vitro experiments to test the effect of selected ligands (BMP6 and activin A) on luteinizing bovine TC and GC. Relative to P-actin transcript abundance, CL tissue contained more BMP4 and -6 mRNA than granulosa, more BMP2 mRNA than theca but much less activin-beta A mRNA than both granulosa and theca. Transcripts for all seven BMP/activin receptors were readily detected in each tissue and two transcripts (BMPRII, ActRIIA) were more abundant in CL than either theca or granulosa, consistent with tissue responsiveness. In vitro luteinization of TC and GC from antral follicles (4-6 mm) was achieved by culturing with 5% serum for 6 days. Treatment with BMP6 (0, 2, 10, and 50 ng/ml) and activin A (0, 2, 10 and 50 ng/ml) under these conditions dose-dependently suppressed forskolin-induced progesterone (P-4) secretion from both cell types without affecting cell number. BMP6 reduced forskolin-stimulated upregulation of STAR mRNA and raised 'basal' CYP17A1 mRNA level in theca-lutein cells without affecting expression of CYP11A1 or hydroxy-Delta-5-steroid dehydrogenase, 3 beta- and steroid Delta-isomerase 1 (HSD3B1). In granulosa-lutein cells, STAR transcript abundance was not affected by BMP6, whereas forskolin-induced expression of CYP11A1, HSD3B1, CYP19A1 and oxytocin transcripts was reduced. In both cell types, follistatin attenuated the suppressive effect of activin A and BMP6 on forskolin-induced P4 secretion but had no effect alone. Granulosa-lutein cells secreted low levels of endogenous activin A (similar to 1 ng/ml); BMP6 reduced this, while raising follistatin secretion thus decreasing activin A:follistatin ratio. Collectively, these findings support inhibitory roles for BMP/activin signalling in luteinization and steroidogenesis in both TC and GC.

Functional significance of the signal transduction pathways Akt and Erk in ovarian follicles: in vitro and in vivo studies in cattle and sheep

BACKGROUND: The intracellular signalling mechanisms that regulate ovarian follicle development are unclear; however, we have recently shown differences in the Akt and Erk signalling pathways in dominant compared to subordinate follicles. The aim of this study was to investigate the effects of inhibiting Akt and Erk phosphorylation on IGF- and gonadotropin- stimulated granulosa and theca cell function in vitro, and on follicle development in vivo. METHODS: Bovine granulosa and theca cells were cultured for six days and stimulated with FSH and/or IGF, or LH in combination with PD98059 (Erk inhibitor) and/or LY294002 (Akt inhibitor) and their effect on cell number and hormone secretion (estradiol, activin-A, inhibin-A, follistatin, progesterone and androstenedione) determined. In addition, ovarian follicles were treated in vivo with PD98059 and/or LY294002 in ewes on Day 3 of the cycle and follicles were recovered 48 hours later. RESULTS: We have shown that gonadotropin- and IGF-stimulated hormone production by granulosa and theca cells is reduced by treatment with PD98059 and LY294002 in vitro. Furthermore, treatment with PD98059 and LY294002 reduced follicle growth and oestradiol production in vivo. CONCLUSION: These results demonstrate an important functional role for the Akt and Erk signalling pathways in follicle function, growth and development.

Identification of a novel mammalian post-translational modification, phosphocholine, on placental secretory polypeptides

Placental neurokinin B appears to be post-translationally modified by phosphocholine (PC) attached to the aspartyl side chain at residue 4 of the mature peptide. Corticotrophin releasing factor (CRF) was found to be expressed by the rat placenta with the main secreted forms being phosphocholinated proCRF+/- one or two polysaccharide moieties. A combination of high-pressure liquid chromatography (HPLC) and two-site immunometric analysis suggested that PC was also attached to the placental precursors of adrenocorticotrophin, hemokinin, activin and follistatin. However, the fully processed forms of rat placental activin and CRF were free of PC. Formerly, the parasitic filarial nematodes have used PC as a post-translational modification, attached via the polysaccharicle moiety of certain secretory glycoproteins to attenuate the host immune system allowing parasite survival, but it is the PC group itself which endows the carrier with the biological activity. The fact that treatment of proCRF peptides with phospholipase C but not endoglycosidase destroyed PC immunoreactivity suggested a simpler mode of attachment of PC to placental peptides than that used by nematodes. Thus, it is possible that by analogy the placenta uses its secreted phosphocholinated hormones to modulate the mother's immune system and help protect the placenta from rejection.

TGF-beta superfamily members and ovarian follicle development

In recent years, exciting progress has been made towards unravelling the complex intraovarian control mechanisms that, in concert with systemic signals, coordinate the recruitment, selection and growth of follicles from the primordial stage through to ovulation and corpus luteum formation. A plethora of growth factors, many belonging to the transforming growth factor-beta (TGF-beta) superfamily, are expressed by ovarian somatic cells and oocytes in a developmental, stage-related manner and function as intraovarian regulators of folliculogenesis. Two such factors, bone morphogenetic proteins, RMP-4 and BMP-7, are expressed by ovarian stromal cells and/or theca cells and have recently been implicated as positive regulators of the primordial-to-primary follicle transition. In contrast, evidence indicates a negative role for anti-Mullerian hormone (AMH, also known as Mullerian-inhibiting substance) of pre-granulosa/granulosa cell origin in this key event and subsequent progression to the antral stage. Two other TGF-beta superfamily members, growth and differentiation factor-9 (GDF-9) and BMP-15 (also known as GDF-9B) are expressed in an oocyte-specific manner from a very early stage and play key roles in promoting follicle growth beyond the primary stage; mice with null mutations in the gdf-9 gene or ewes with inactivating mutations in gdf-9 or bmp-15 genes are infertile with follicle development arrested at the primary stage. Studies on later stages of follicle development indicate positive roles for granulosa cell-derived activin, BMP-2, -5 and -6, theca cell-derived BMP-2, -4 and -7 and oocyte-derived BMP-6 in promoting granulosa cell proliferation, follicle survival and prevention of premature luteinization and/or atresia. Concomitantly, activin, TGF-beta and several BMPs may exert paracrine actions on theca cells to attenuate LH-dependent androgen production in small to medium-size antral follicles. Dominant follicle selection in monovular species may depend on differential FSH sensitivity amongst a growing cohort of small antral follicles. Changes in intrafollicular activins, GDF-9, AMH and several BMPs may contribute to this selection process by modulating both FSH- and IGF-dependent signalling pathways in granulosa cells. Activin may also play a positive role in oocyte maturation and acquisition of developmental competence. in addition to its endocrine role to suppress FSH secretion, increased output of inhibin by the selected dominant follicle(s) may upregulate LH-induced androgen secretion that is required to sustain a high level of oestradiol secretion during the pre-ovulatory phase. Advances in our understanding of intraovarian regulatory mechanisms should facilitate the development of new approaches for monitoring and manipulating ovarian function and improving fertility in domesticated livestock, endangered species and man.

Bone morphogenetic protein (BMP) ligands and receptors in bovine ovarian follicle cells: actions of BMP-4,-6 and-7 on granulosa cells and differential modulation of Smad-1 phosphorylation by follistatin

Given the paucity of information on the potential roles of bone morphogenetic proteins (BMPs) in the ruminant ovary we conducted immunolocalization and functional studies on cells isolated from bovine antral follicles. Immunocytochemistry revealed expression of BMP-4 and -7 in isolated theca cells whereas granulosa cells and oocytes selectively expressed RMP-6. All three cell types expressed a range of BMP-responsive type-I (BMPRIB, ActRI) and type-II (BMPRII, ActRII, ActRIIB) receptors supporting autocrine/paracrine roles within the follicle. This was reinforced by functional experiments on granulosa cells which showed that BMP-4, -6 and -7 promoted cellular accumulation of phosphorylated Smad-1 but not Smad-2 and enhanced 'basal' and IGF-stimulated secretion of oestradiol (E2), inhibin-A, activin-A and follistatin (FS). Concomitantly, each BMP suppressed 'basal' and IGF-stimulated progesterone secretion, consistent with an action to prevent or delay atresia and/or luteinization. BMPs also increased viable cell number under 'basal' (BMP-4 and -7) and IGF-stimulated (BMP-4, -6 and -7) conditions. Since FS, a product of bovine granulosa cells, has been shown to bind several BMPs, we used the Biacore technique to compare its binding affinities for activin-A (prototype FS ligand) and BMP-4, -6 and -7. Compared with activin-A (K-d 0.28 +/- 0.02 nM; 100%), the relative affinities of FS for BMP-4, -6 and -7 were 10, 5 and 1% respectively. Moreover, studies on granulosa cells showed that preincubation of ligand with excess FS abolished activin-A-induced phosphorylation of Smad-2 and BMP-4-induced phosphorylation of Smad-1. However, FS only partially reversed BMP-6-induced Smad-1 phosphorylation and had no inhibitory effect on BMP-7-induced Smad-1 phosphorylation. These findings support functional roles for BMP-4, -6 and -7 as paracrine/autocrine modulators of granulosa cell steroidogenesis, peptide secretion and proliferation in bovine antral follicles. The finding that FS can differentially modulate BMP-induced receptor activation and that this correlates with the relative binding affinity of FS for each BMP type implicates FS as a potential modulator of BMP action in the ovary.

Oocyte-mediated suppression of follicle-stimulating hormone- and insulin-like growth factor-induced secretion of steroids and inhibin-related proteins by bovine granulosa cells in vitro: Possible role of transforming growth factor alpha

The objective was to investigate the potential role of the oocyte in modulating proliferation and basal, FSH-induced and insulin-like growth factor (IGF)-induced secretion of inhibin A (inh A), activin A (act A), follistatin (FS), estradiol (E-2), and progesterone (P-4) by mural bovine granulosa cells. Cells from 4- to 6-mm follicles were cultured in serum-free medium containing insulin and androstenedione, and the effects of ovine FSH and IGF analogue (LR3-IGF-1) were tested alone and in the presence of denuded bovine oocytes (2, 8, or 20 per well). Medium was changed every 48 h, cultures were terminated after 144 h, and viable cell number was determined. Results are based on combined data from four independent cultures and are presented for the last time period only when responses were maximal. Both FSH and IGF increased (P < 0.001) secretion of inh A, act A, FS, E-2, and P-4 and raised cell number. In the absence of FSH or IGF, coculture with oocytes had no effect on any of the measured hormones, although cell number was increased up to 1.8-fold (P < 0.0001). Addition of oocytes to FSH-stimulated cells dose-dependently suppressed (P < 0.0001) inh A (6-fold maximum suppression), act A (5.5-fold), FS (3.6-fold), E-2 (4.6-fold), and P-4 (2.4-fold), with suppression increasing with FSH dose. Likewise, oocytes suppressed (P < 0.001) IGF-induced secretion of inh A, act A, FS, and E-2 (P < 0.05) but enhanced IGF-induced P-4 secretion (1.7-fold; P < 0.05). Given the similarity of these oocyte-mediated actions to those we observed previously following epidermal growth factor (EGF) treatment, we used immunocytochemistry to determine whether bovine oocytes express EGF or transforming growth factor (TGF) alpha. Intense staining with TGFalpha antibody (but not with EGF antibody) was detected in oocytes both before and after coculture. Experiments involving addition of TGFalpha to granulosa cells confirmed that the peptide mimicked the effects of oocytes on cell proliferation and on FSH- and IGF-induced hormone secretion. These experiments indicate that bovine oocytes secrete a factor(s) capable of modulating granulosa cell proliferation and responsiveness to FSH and IGF in terms of steroidogenesis and production of inhibin-related peptides, bovine oocytes express TGFalpha but not EGF, and TGFalpha is a prime candidate for mediating the actions of oocytes on bovine granulosa cells.

Local roles of TGF-beta superfamily members in the control of ovarian follicle development

Members of the transforming growth factor-beta (TGF-beta) superfamily have wide-ranging influences on many tissue and organ systems including the ovary. Two recently discovered TGF-beta superfamily members, growth/differentiation factor-9 (GDF-9) and bone morphogenetic protein-15 (BMP-15; also designated as GDF-9B) are expressed in an oocyte-specific manner from a very early stage and play a key role in promoting follicle growth beyond the primary stage. Follicle growth to the small antral stage does not require gonadotrophins but appears to be driven by local autocrine/paracrine signals from both somatic cell types (granulosa and theca) and from the oocyte. TGF-beta superfamily members expressed by follicular cells and implicated in this phase of follicle development include TGF-beta, activin, GDF-9/9B and several BMPs. Acquisition of follicle-stimulating hormone (FSH) responsiveness is a pre-requisite for growth beyond the small antral stage and evidence indicates an autocrine role for granulosa-derived activin in promoting granulosa cell proliferation, FSH receptor expression and aromatase activity. Indeed, some of the effects of FSH on granulosa cells may be mediated by endogenous activin. At the same time, activin may act on theca cells to attenuate luteinizing hormone (LH)-dependent androgen production in small to medium-size antral follicles. Dominant follicle selection appears to depend on differential FSH sensitivity amongst a growing cohort of small antral follicles. Activin may contribute to this selection process by sensitizing those follicles with the highest "activin tone" to FSH. Production of inhibin, like oestradiol, increases in selected dominant follicles, in an FSH- and insulin-like growth factor-dependent manner and may exert a paracrine action on theca cells to upregulate LH-induced secretion of androgen, an essential requirement for further oestradiol secretion by the pre-ovulatory follicle. Like activin, BMP-4 and -7 (mostly from theca), and BMP-6 (mostly from oocyte), can enhance oestradiol and inhibin secretion by bovine granulosa cells while suppressing progesterone secretion; this suggests a functional role in delaying follicle luteinization and/or atresia. Follistatin, on the other hand, may favor luteinization and/or atresia by bio-neutralizing intrafollicular activin and BMPs. Activin receptors are expressed by the oocyte and activin may have a further intrafollicular role in the terminal stages of follicle differentiation to promote oocyte maturation and developmental competence. In a reciprocal manner, oocyte-derived GDF-9/9B may act on the surrounding cumulus granulosa cells to attenuate oestradiol output and promote progesterone and hyaluronic acid production, mucification and cumulus expansion.(C) 2003 Elsevier Science B.V. All rights reserved.

Changes in expression of bone morphogenetic proteins (BMPs), their receptors and inhibin co-receptor betaglycan during bovine antral follicle development: inhibin can antagonize the suppressive effect of BMPs on thecal androgen production

We reported previously that bone morphogenetic proteins (BMPs) potently suppress CYP17 expression and androgen production by bovine theca interna cells (TC) in vitro. In this study, real-time PCR was used to analyse gene expression in TC and granulosa cell (GC) layers from developing bovine antral follicles (1-18 mm). Abundance of mRNA transcripts for four BMPs (BMP2, BMP4, BMP6, and BMP7) and associated type I (BMPR1A, BMPR1B, ACVR1 and ACVR1B) and type II (BMPR2, ACVR2A and ACVR2B) receptors showed relatively modest, though significant, changes during follicle development. BMP2 was selectively expressed in GC, while BMP6, BMP7 and betaglycan (TGFBR3) were more abundant in TC. Abundance of betaglycan mRNA (inhibin co-receptor) in TC increased progressively (fivefold; P<0.001) as follicles grew from 1-2 to 9-10 mm. This suggests a shift in thecal responsiveness to GC-derived inhibin, produced in increasing amounts as follicles achieve dominance. This prompted us to investigate whether inhibin can function as a physiological antagonist of BMP action on bovine TC in vitro, in a manner comparable to that for activin signalling. BMP4, BMP6 and BMP7 abolished LH-induced androstenedione secretion and suppressed CYP17 mRNA >200-fold (P<0.001), while co-treatment with inhibin-A reversed the suppressive action of BMP in each case (P<0.001). Results support a physiological role for granulosa-derived inhibin as an antagonist of BMP action on thecal androgen synthesis. A shift in intrafollicular balance between thecal BMP signalling (inhibitory for androgen synthesis) and betaglycan-dependent inhibin signalling (stimulatory for androgen synthesis) accords with the physiological requirement to deliver an adequate supply of aromatase substrate to GC of developing follicles.

Intra-ovarian roles of activins and inhibins

Granulosa cells are the main ovarian source of inhibins, activins and activin-binding protein (follistatin) while germ (oogonia, oocytes) and somatic (theca, granulosa, luteal) cells express activin receptors, signaling components and inhibin co-receptor (betaglycan). Activins are implicated in various intra-ovarian roles including germ cell survival and primordial follicle assembly; follicle growth from preantral to mid-antral stages; suppression of thecal androgen production; promotion of granulosa cell proliferation, FSHR and CYP19A1 expression; enhancement of oocyte developmental competence; retardation of follicle luteinization and/or atresia and involvement in luteolysis. Inhibins (primarily inhibin A) are produced in greatest amounts by preovulatory follicles (and corpus luteum in primates) and suppress FSH secretion through endocrine negative feedback. Together with follistatin, inhibins act locally to oppose auto-/paracrine activin (and BMP) signaling thus modulating many of the above processes. The balance between activin-inhibin shifts during follicle development with activin signalling prevailing at earlier stages but declining as inhibin and betaglycan expression rise.

Theca cells and the regulation of ovarian androgen production

Theca cells are essential for female reproduction being the source of androgens that are precursors for follicular oestrogen synthesis and also signal through androgen receptors (AR) in the ovary and elsewhere. Theca cells arise from mesenchymal cells around the secondary follicle stage. Their recruitment, proliferation and cytodifferentiation are influenced, directly or indirectly, by paracrine signals from granulosa cells and oocyte although uncertainty remains over which are the critically important signals at particular stages. In a reciprocal manner, theca cells secrete factors that influence granulosa cell proliferation and differentiation at different follicle stages. Differentiated theca interna cells acquire responsiveness to luteinizing hormone (LH) and other endocrine signals and express components of the steroidogenic machinery required for androgen biosynthesis. They also express insulin-like peptide 3 (INSL3) and its receptor (RXFP2), levels of which increase during bovine antral follicle development. INSL3 signaling may play a role in promoting androgen biosynthesis since knockdown of either INSL3 or its receptor (RXFP2) in bovine theca cells inhibits androgen biosynthesis while exogenous INSL3 can raise androgen secretion. Bone morphogenetic proteins (BMPs) of thecal or granulosal origin suppress thecal production of both INSL3 and androgen. Inhibin, produced in greatest amounts by granulosa cells of preovulatory follicles, reverses these BMP actions. Thus, BMP-induced inhibition of thecal androgen production may be mediated by reduced INSL3-RXFP2 signaling. Activins also inhibit androgen production in an inhibin-reversible manner and recent evidence in sheep indicates that theca cells synthesize and secrete activin, implying an autocrine role in suppressing androgen biosynthesis in smaller follicles, akin to that envisaged for BMPs.

Comparison of bioactivities, binding properties and intra-follicular levels of bovine follistatins

Five isoforms of follistatin (FST) (Mr 31, 33, 35, 37, 41kDa) were purified from bovine follicular fluid (bFF). Comparison of their activin- and heparan sulphate proteoglycan (HSP)-binding properties and bio-potencies in neutralization of activin-A action in vitro revealed that all five isoforms bound activin-A, but with different affinities. Only the 31kDa isoform (FST-288) bound to HSP. FST-288 also showed the greatest biopotency with 35 and 41kDa isoforms being least potent. To determine whether bovine follicle development is associated with changing intrafollicular FST and activin profiles, we analyzed bFF from dominant (DF) and subordinate (SF) follicles collected at strategic times during a synchronized estrous cycle. Total FST, activin-A and activin-AB were measured by immunoassay while individual FST isoforms were quantified by immunoblotting. Follicle diameter was positively correlated with estrogen:progesterone ratio (r=0.56) in bFF but negatively correlated with activin-A (r=-0.34), activin-AB (r=-0.80) and ‘total’ FST (r=-0.70) levels. Follicle diameter was positively correlated with abundance of the 41 kDa isoform (r=0.59) but negatively correlated with abundance of 33 and 31 kDa isoforms (r=-0.56, -0.41). Both follicle status (DF vs SF) and cycle stage affected total FST, activin-A, activin-B levels while follicle status, but not cycle stage, affected abundance of 41, 37, 33 and 31kDa FST isoforms. Collectively, these findings indicate that intrafollicular FST isoforms that differ in their ability to bind and neutralise activins and associate with cell-surface proteoglycans, show divergent changes during follicle development. Enhanced FST production may have an important negative role, either directly or via inhibition of the positive effects of activins, on follicle growth and function during follicular waves.

Blockade of ActRIIB signaling triggers muscle fatigability and metabolic myopathy

Myostatin regulates skeletal muscle size via the activin receptor IIB (ActRIIB). However, its effect on muscle energy metabolism and energy dependent muscle function remains largely unexplored. This question needs to be solved urgently since various therapies for neuromuscular diseases based on blockade of ActRIIB signaling are being developed. Here we show in mice that four months of pharmacological abrogation of ActRIIB signaling by treatment with soluble ActRIIB-Fc triggers extreme muscle fatigability. This is associated with elevated serum lactate levels and a severe metabolic myopathy in the mdx mouse, an animal model of Duchenne muscular dystrophy. Blockade of ActRIIB signaling down-regulates Porin, a crucial ADP/ATP shuttle between cytosol and mitochondrial matrix leading to a consecutive deficiency of oxidative phosphorylation as measured by in vivo Phophorus Magnetic Resonance Spectroscopy (31P-MRS). Further, ActRIIB blockade reduces muscle capillarization, which further compounds the metabolic stress. We show that ActRIIB regulates key determinants of muscle metabolism, such as Pparβ, Pgc1α, and Pdk4 thereby optimizing different components of muscle energy metabolism. In conclusion, ActRIIB signaling endows skeletal muscle with high oxidative capacity and low fatigability. The severe metabolic side effects following ActRIIB blockade caution against deploying this strategy, at least in isolation, for treatment of neuromuscular disorders.