Progesterone receptor-mediated effects on apoptosis in periovulatory granulosa cells /

Rung, Emilia,

January 2006

Diss. (sammanfattning) Göteborg : Göteborgs universitet, 2006. / Härtill 4 uppsatser.

The cellular composition of human follicular aspirates

Smith, Michael Paul

January 2001

No description available.

610

Basic fibroblast growth factor in the human ovary

Watson, Richard Henry

January 1995

No description available.

572

In vitro studies of potential modulatory factors involved in bovine follicular development

Glister, Claire

January 2001

No description available.

572.8

Alcohol Inhibits Epidermal Growth Factor‐Stimulated Progesterone Secretion from Human Granulosa Cells

McKenzie, Pamela P., McClaran, Joseph D., Caudle, Michael R., Fukuda, Aisaku, Wimalasena, Jay

01 January 1995

In this study, luteinized human granulosa cells (GC) obtained during in vitro fertilization procedures were used as a model system to evaluate the effects of ethanol (EtOH), a well‐known reproductive toxin, on epidermal growth factor (EGF) and gonadotropin‐stimulated steroidogenesis. Our results demonstrate that the basal progesterone (P4) and estradiol (E2) secretion by human GC in vitro was dependent on the ovarian stimulation protocol. EGF significantly enhanced P4, but not E2, secretion in human GC from clomiphene citrate (CC), human menopausal gonadotropin (hMG), and hMG/gonadotropin‐releasing hormone agonist (GnRH‐a)‐treated patients. The effects of EGF plus luteinizing hormone (LH) were additive in cells from the CC group, but less than additive in hMG and hMG/GnRH‐a groups. EtOH at 20 mM or more inhibited EGF stimulated P4 secretion in human GC from all three patient groups. EtOH inhibited P4 secretion stimulated by EGF and LH cotreatment in the CC and hMG/GnRH‐a groups, but not in human GC from the hMG‐treated patients. These results suggest that basal and EGF or LH‐stimulated P4 secretion by human GC, as well as the effects of EtOH, are profoundly influenced by the follicle's hormonal milieu.

epidermal growth factor

ethanol

granulosa cells

in vitro fertilization

steroids

Role of vascular endothelial growth factor (VEGF) in granulosa cell function : involvement of heterotrimeric G-protein signalling pathways

Doyle, Lynsey Kerr

January 2009

Vascular Endothelial Growth Factor (VEGF) has been shown to be an absolute requirement for ovarian follicle development. Although VEGF is commonly regarded primarily as an angiogenic factor, granulosa cells are a major site of VEGF synthesis in the follicle and they express VEGF receptors (VEGFR1 and VEGFR2). Further, the development of the dominant follicle is characterised by a substantial increase in granulosa cell expression of VEGF and its receptors. In spite of this, potential non-angiogenic effects of VEGF in these follicles have not been elucidated. The objective of the three studies described in this thesis was to use an in vitro bovine granulosa cell model to investigate the roles of VEGF during development of the dominant follicle. In addition, in light of evidence in other cell types, potential interactions between VEGF signalling and heterotrimeric protein signalling in these follicles were also investigated. In the first study, granulosa cells were obtained from healthy follicles with diameters of 4 to 8 mm (corresponding to just before the selection of a dominant follicle during a follicular wave) or 9 to 14 mm (encompassing all developmental stages of a dominant follicle) and exposed to a range of VEGF concentrations (1 to 100 ng/ml) encompassing concentrations found naturally in bovine dominant follicles. VEGF at 1 ng/ml, but not at higher concentrations (P > 0.1), induced significant proliferation of bovine granulosa cells from 4 to 8 mm follicles (P = 0.024) and increased the proliferative response of these cells to FSH (P = 0.045). VEGF also induced a dose-dependent increase in ERK1/2 activation by granulosa cells from 4 to 8 mm follicles (P < 0.03) but did not have any effect on expression of the steroidogenic enzyme, CYP11A1, by these cells (P > 0.1). VEGF, at a dose of 1 ng/ml (P = 0.003), but not at higher doses (P > 0.1), induced an increase in COX-2 expression by granulosa cells from 9 to 14 mm follicles. In addition, LH stimulation of both ERK phosphorylation (P < 0.05) and COX-2 expression (P < 0.05) in granulosa cells from 9 to 14 mm follicles were prevented (P > 0.1) by specific inhibition of VEGFR2, indicating that VEGF may mediate COX-2 responses to LH in these cells. The second study sought to examine the expression of heterotrimeric G-protein á subunits and PLCâ isoforms by real-time PCR and westen blotting in bovine granulosa cells throughout follicle development to identify specific molecular components of heterotrimeric G-protein pathways that may functionally interact with intracellular VEGF signals. Results showed that GNAS, GNA11 and GNAI2 were all expressed at significantly (P < 0.05) higher levels in granulosa cells of pre-ovulatorysize follicles (10.0 to 13.9 mm) than in cells from smaller follicles (2.0 to 5.9 mm and 6.0 to 9.9 mm). In addition, all PLCB isoforms except PLCB2 were expressed in bovine granulosa cells with PLCB3 being more abundant than PLCB1 and -4. Levels of PLCB3 in granulosa cells from pre-ovulatory-size follicles were much higher (>16-fold; P < 0.005) than in smaller follicles. Immunocytochemical analysis revealed that PLCB3 was located primarily in the cytoplasm, whereas PLCB1 was distributed primarily in the nucleus. These results identified Gs, Gq/11, Gi2 and PLCâ3 as candidates for cross-talk between VEGF and heterotrimeric G-protein signalling during the development of the dominant follicle. The potential involvement of these molecules on VEGF-induced responses in granulosa cells from 9-14 mm follicles was investigated in the third study by determining the effects of specific inhibitors of Gi (pertussis toxin, PTX) or Gq/11 (YM-25489) or PLCB3 siRNAs on VEGF-induced p-ERK. Results showed a 2.3 fold mean increase in p-ERK in response to VEGF in the absence of G protein inhibitors (P < 0.0001) but a VEGF response that was completely or partially abolished, respectively, in the presence of PTX (P > 0.8) or YM-25489 (1.6-fold mean increase relative to untreated controls; P = 0.039). LH induced a 1.6 fold increase in p-ERK1/2 (P < 0.02) and this response was prevented by pre-incubation with PTX (P > 0.4) or YM-25489 (P > 0.5). In contrast, similar EGF-induced phosphorylation of ERK (about 5-fold relative to controls) occurred in the absence (P < 0.003) or presence of PTX (P < 0.003) or YM-25489 (P < 0.003). Transfection of granulosa cells with 3 siRNAs targeting PLCB3 that had been previously validated by western blotting and immunocytochemistry had no effect (P = > 0.7) on phosphorylation of ERK in response to VEGF, LH or EGF in granulosa cells. In conclusion, taken together, these results suggest novel roles of VEGF in stimulating granulosa cell proliferation and expression of COX-2 in bovine dominant follicles and implicate VEGF in synergising and/or mediating the effects of gonadotrophins in these cells. In addition, these results indicate a requirement for Gi2 and Gq/11 in VEGF activation of ERK1/2 and induction of the above responses in granulosa cells.

636.089

Etude de nouveaux acteurs de la physiopathologie ovarienne / Study of Few Factors in Ovarian Pathophysiology

Bouilly, Justine

21 November 2014

Les données bibliographiques décrivent un nombre croissant de modèles murins caractérisés sur le plan de la fertilité permettant une meilleure compréhension du phénomène de la croissance folliculaire. Certains de ces modèles animaux, invalidés pour des facteurs de transcription reproduisent un phénotype d’infertilité, telle que l’insuffisance ovarienne primaire (IOP). La compréhension des mécanismes moléculaires des facteurs de transcription essentiels à la fonction ovarienne n’est pas clairement établie. Les protéines contenant des domaines liant l’ADN, tels que les homéodomaines ou les domaines forkhead jouent un rôle-Clé dans le développement ovarien. NOBOX (Newborn Ovary Homeobox) est un facteur de transcription essentiel à la mise en place du stock folliculaire, et dont les mutations sont responsables d’IOP. La fonction exacte de NOBOX n’est pas connue, s’il est présent dans l’ovocyte, nous montrons pour la première fois une forte expression de cette protéine dans les cellules de la granulosa des follicules primordiaux jusqu’au stade secondaire. De plus, par différentes techniques moléculaires, nous mettons en évidence une interaction entre NOBOX et un autre acteur important de la folliculogenèse FOXL2 (Forkhead box l2), contribuant à la régulation de leurs gènes cibles respectifs. Cette étude permet de mettre en lumière le rôle de NOBOX dans les cellules de granulosa. L’IOP est une pathologie touchant 1 % des femmes âgées de moins de 40 ans. Sur le plan ovarien, il y a une déplétion du stock des follicules ou un blocage de la maturation folliculaire. De ce fait, la stérilité est le plus souvent définitive. Une origine génétique de cette maladie est parfois retrouvée avec des mutations des autosomes et/ou du chromosome X, mais dans plus de 80% des cas l’IOP est idiopathique. L’enjeu est donc d’identifier de nouveaux gènes candidats pour cette pathologie. Dans cette étude nous validons la prévalence des mutations du gène NOBOX faisant de ce facteur un des gènes clés de l’IOP. Puis, à l’aide d’une nouvelle technologie : le séquençage multiplex par puces PGMTM ION TORRENT, nous mettons en évidence dans 26% de la cohorte étudiée (100 femmes atteintes d’IOP sporadique primaire ou secondaire) un défaut génétique de 10 gènes, dont 4 nouveaux candidats à l’IOP. De façon intéressante, la présence d’au moins deux gènes mutés chez 9 patientes induit un phénotype plus précoce. Cette étude contribue à une meilleure compréhension de l’origine génétique de l’IOP et met pour la première fois en évidence le phénomène d’oligogénisme chez des patientes en IOP. / Single germline mutations found in women with primary ovarian insufficiency (POI), besides mouse models have provided substantial understanding into the factors involved in differentiation and ovarian development. POI is characterized by amenorrhea with elevated gonadotropin levels, and affects 1% of women before the age of 40 years.Several transcription factors involved in ovary development and folliculogenesis are mutated in reproductive disorders. We have shown a high prevalence of POI cases harboring mutations in the Newborn oogenesis homeobox (NOBOX) gene, which encodes a homeodomain-Containing transcription factor expressed preferentially in oocyte. NOBOX plays a critical role in early folliculogenesis and its absence leads to sterility. In addition to its oocyte localization, we show here that NOBOX is also expressed in granulosa cells (GCs), those surrounding the germ cell. Since NOBOX and FOXL2, a master regulator of GC development (belonging to forkhead family), are co-Expressed in GCs. Here, using several molecular approaches, we have demonstrated that NOBOX and FOXL2 indeed physically interact leading to a down-Regulation of their transactivation capacity. Altogether, these observations highlight a novel role for NOBOX in interaction with FOXL2, and suggest that they may be antagonistic transcription regulators. POI encompasses a heterogeneous spectrum of conditions, through two major mechanisms, follicle dysfunction and follicle depletion. Genetic component such as X chromosome abnormalities, deletions, FMR1 premutations, BMP15 variants, were identified as the first genetic causes of the pathophysiology. Today, the genetic origin of POI is supported by the existence of monogenic forms in humans and animal models but the relevance of several loci for POI pathogenesis should not be ruled out. By means of a next-Generation sequencing , a multiplex (PGM-Ion Torrent technology) sequencing of 19 genes was undertaken in a cohort of 100 nonsyndromic women with POI. In 26 patients, we reported 10 gene defects, among them, missense mutations in 4 new candidates were detected. Our aggregate data suggest that point mutations in these candidate genes are causative of the disease by prediction analysis assays. Two to three gene defects can synergize to produce a more severe phenotype in POI patients than either alone. This study identifies for the first time in a large proportion of POI patients specific sets of germline mutations that, together, may account for this disease. Thus, oligogenicity also has implications for genetic counseling regarding POI.

Ovaire

NOBOX

FOXL2

Cellules de la granulosa

Insuffisance ovarienne primaire

Ovary

FOXL2

NOBOX

Granulosa cells

Primary ovarian insufficiency

Effects of follicular aging and duration of superstimulation on oocyte competence and granulosa cell gene expression in cattle

2013 June 1900

A prolonged growth phase of the ovulatory follicle results in follicular aging. Whether follicular aging is detrimental or beneficial to oocyte competence is not fully known. The objective of this thesis is to investigate the effects of follicular aging on oocyte competence and granulosa cell gene expression in cattle. Four sets of experiments were designed to address the objective. The following hypotheses were tested during the course of these studies: 1) oocyte competence will improve by the longer growing phase but will be adversely affected by FSH starvation, 2) follicles that undergo superstimulation will have different gene expression than dominant follicles from a natural cycle, 3) extending the superstimulation protocol by 3 days will allow follicles to mature better and 4) markers of maturity, cellular health and survival will be turned off by FSH starvation. The objective of the first study (Chapter 3) was to determine the effects of extending the length of superstimulation and follicular aging on oocyte competence by in vitro embryo production. Multiple follicles were allowed to grow for 4 (Short FSH) or 7 days (Long FSH) under the treatment of 8 or 14 injections of FSH (at 12-hour intervals), respectively. Multiple follicles in the FSH starvation group were allowed to grow for 7 days but FSH was provided for only the first 4 days of superstimulation. Extending the duration of follicular growth by superstimulation resulted in a greater number of ≥9 mm follicles and in 2.5 more transferable embryos per animal (morulae+blastocysts) at Day 9 of in vitro embryo culture. The FSH starvation resulted in a greater proportion of poor quality oocytes lower cleavage rate and lower embryonic development. Microarray analysis was used to assess the effect of superstimulation (Chapter 4), follicular aging (Chapter 5) and FSH starvation (Chapter 6) on the gene expression profile of superstimulated granulosa cells. Gene expression of granulosa cells from the post-LH preovulatory dominant follicle was compared (Chapter 4) with those from follicles of the same status after a standard 4-day superstimulation (same protocol as Short FSH group from Chapter 3). A total of 190 genes were down-regulated and 280 genes were upregulated in the superstimulated group when compared with the reference (non-superstimulated control). Data analysis showed that superstimulated follicles are still in a growing phase compared to untreated dominant follicles (most of the upregulated genes are related to matrix remodeling due to tissue proliferation) and did not respond to LH properly (down regulation of LH gene markers). Four-day superstimulation also disturbed genes related to angiogenesis and activated oxidative stress response genes. Extending the superstimulation protocol (7 days; same protocol as Long FSH from Chapter 3) allowed more time for follicles to leave the growing stage and properly respond to LH surge (most of the upregulated genes in the Long FSH group are markers of post LH surge) when compared to the standard 4 day superstimulation protocol (Short FSH; reference group) (Chapter 5). Moreover, the follicles from Long FSH show proximity to ovulation. The continuous FSH support during the extended superstimulation protocol is crucial for follicular health since FSH starvation disturbed genes markers of oocyte quality and embryo development (Chapter 6). Granulosa cells that underwent FSH starvation do not respond to LH surge, which could be detrimental to ovulation (Chapter 6). Therefore, follicles from Short FSH are delayed in maturation and differentiation but the oocyte competence is not compromised. Extending superstimulation protocol by 3 d enhanced the ovarian response to FSH treatment and allowed more time for follicles to mature and properly respond to the LH stimulus. A period of FSH starvation after superstimulatory treatment compromised follicular health, ability to respond to LH and ovulate, oocyte quality and the fertilization process.

cattle

FSH

follicle dynamics

follicular aging

gene expression

granulosa cells

oocyte competence

superstimulation

Functional characterisation of the cumulus oocyte matrix during maturation of oocytes.

Dunning, Kylie Renee

January 2008

Female gametes, or oocytes grow and mature in a niche environment maintained by the somatic cells of the ovarian follicle. At ovulation ovarian follicle cells respond to the luteinising hormone (LH) surge coordinating the final maturation, meiotic resumption and release of oocytes. Simultaneously, production of a unique “mucified” extracellular matrix surrounding the oocyte through synthesis of Hyaluronan (HA) and HA cross-linking proteins produces an “expanded” and stabilised cumulus oocyte matrix with a specific composition, structure and function. In vitro maturation (IVM) of oocytes is a procedure by which cumulus oocyte complexes (COCs) are stimulated to produce cumulus matrix and undergo oocyte maturation ex vivo. In vitro maturation is a useful procedure for studying oocyte competence as well as offering health benefits for patients undergoing assisted reproduction. Oocytes derived from IVM have much lower developmental competence than in vivo matured oocytes, likely as a result of altered environmental conditions and gene expression leading to suboptimal maturation and/or inappropriate metabolic control in oocytes. Cumulus matrix expansion is widely used as an indicator of good oocyte developmental potential, however, the mechanism(s) that endow oocyte quality and how these may be influenced by the cumulus matrix are poorly understood. To better understand the process by which cumulus matrix is linked to the final stages of oocyte maturation, I undertook investigation of mouse COC matrix composition and function after in vivo maturation in comparison to IVM. The gene responsible for Hyaluronan synthesis, Has2, was not impaired under IVM conditions. In contrast, two key extracellular matrix proteins; Versican and Adamts1, which are normally selectively incorporated into periovulatory COCs in vivo, were greater than 10-fold reduced in IVM whether stimulated with Egf and/or FSH. This work is the first to show that commonly used IVM conditions result in altered gene expression in cumulus cells. Furthermore, the absence of Adamts1 and Versican suggest that COC matrix may be functionally insufficient. Although associated with good developmental potential, the function of the COC matrix in oocyte maturation is unknown. I assessed the properties of COC matrix that control metabolite supply to oocytes by examining transport of fluorescently labelled glucose and cholesterol across mouse COCs. Profound differences in the control of metabolite supply to oocytes in IVM were observed. In vivo matured complexes were capable of excluding glucose from the entire COC and cholesterol was excluded from oocytes. Conversely IVM COCs were more permissive to rapid equilibration of glucose and cholesterol concentrations across the complex and in oocytes. In fact both metabolites accumulated rapidly in IVM oocytes resulting in inverse gradient patterns of glucose and cholesterol abundance with highest concentrations accumulating in the oocyte after IVM vs highest concentrations surrounding the COC after in vivo maturation conditions. As oocytes are highly sensitive to high glucose my results indicate that metabolic balance in IVM may be disrupted due to impaired molecular filtration properties of the mucified COC matrix that controls supply of hydrophilic and lipophylic substrates. Importantly these novel findings can explain the glucose sensitivity of IVM oocytes and identifies a mechanism by which IVM may lead to poorer oocyte developmental competence. To translate these findings into the improvement of IVM I generated recombinant expression plasmid constructs for several Adamts1 and Versican functional domains. The efficacy of Versican as an IVM supplement that activates cumulus cell signal transduction was proved in principle, by showing enhanced COC matrix expansion when added to mouse IVM cultures. Similar mechanisms are likely to be functional in human COCs since I demonstrated VERSICAN and ADAMTS1 expression in human in vivo matured cumulus and granulosa cells. This work has advanced our understanding of oocyte maturation and will lead to improvements in IVM and healthier outcomes from reproductive therapies. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1342419 / Thesis (Ph.D.) -- University of Adelaide, School of Paediatrics and Reproductive Health, 2008

Functional characterisation of the cumulus oocyte matrix during maturation of oocytes.

Dunning, Kylie Renee

January 2008

Female gametes, or oocytes grow and mature in a niche environment maintained by the somatic cells of the ovarian follicle. At ovulation ovarian follicle cells respond to the luteinising hormone (LH) surge coordinating the final maturation, meiotic resumption and release of oocytes. Simultaneously, production of a unique “mucified” extracellular matrix surrounding the oocyte through synthesis of Hyaluronan (HA) and HA cross-linking proteins produces an “expanded” and stabilised cumulus oocyte matrix with a specific composition, structure and function. In vitro maturation (IVM) of oocytes is a procedure by which cumulus oocyte complexes (COCs) are stimulated to produce cumulus matrix and undergo oocyte maturation ex vivo. In vitro maturation is a useful procedure for studying oocyte competence as well as offering health benefits for patients undergoing assisted reproduction. Oocytes derived from IVM have much lower developmental competence than in vivo matured oocytes, likely as a result of altered environmental conditions and gene expression leading to suboptimal maturation and/or inappropriate metabolic control in oocytes. Cumulus matrix expansion is widely used as an indicator of good oocyte developmental potential, however, the mechanism(s) that endow oocyte quality and how these may be influenced by the cumulus matrix are poorly understood. To better understand the process by which cumulus matrix is linked to the final stages of oocyte maturation, I undertook investigation of mouse COC matrix composition and function after in vivo maturation in comparison to IVM. The gene responsible for Hyaluronan synthesis, Has2, was not impaired under IVM conditions. In contrast, two key extracellular matrix proteins; Versican and Adamts1, which are normally selectively incorporated into periovulatory COCs in vivo, were greater than 10-fold reduced in IVM whether stimulated with Egf and/or FSH. This work is the first to show that commonly used IVM conditions result in altered gene expression in cumulus cells. Furthermore, the absence of Adamts1 and Versican suggest that COC matrix may be functionally insufficient. Although associated with good developmental potential, the function of the COC matrix in oocyte maturation is unknown. I assessed the properties of COC matrix that control metabolite supply to oocytes by examining transport of fluorescently labelled glucose and cholesterol across mouse COCs. Profound differences in the control of metabolite supply to oocytes in IVM were observed. In vivo matured complexes were capable of excluding glucose from the entire COC and cholesterol was excluded from oocytes. Conversely IVM COCs were more permissive to rapid equilibration of glucose and cholesterol concentrations across the complex and in oocytes. In fact both metabolites accumulated rapidly in IVM oocytes resulting in inverse gradient patterns of glucose and cholesterol abundance with highest concentrations accumulating in the oocyte after IVM vs highest concentrations surrounding the COC after in vivo maturation conditions. As oocytes are highly sensitive to high glucose my results indicate that metabolic balance in IVM may be disrupted due to impaired molecular filtration properties of the mucified COC matrix that controls supply of hydrophilic and lipophylic substrates. Importantly these novel findings can explain the glucose sensitivity of IVM oocytes and identifies a mechanism by which IVM may lead to poorer oocyte developmental competence. To translate these findings into the improvement of IVM I generated recombinant expression plasmid constructs for several Adamts1 and Versican functional domains. The efficacy of Versican as an IVM supplement that activates cumulus cell signal transduction was proved in principle, by showing enhanced COC matrix expansion when added to mouse IVM cultures. Similar mechanisms are likely to be functional in human COCs since I demonstrated VERSICAN and ADAMTS1 expression in human in vivo matured cumulus and granulosa cells. This work has advanced our understanding of oocyte maturation and will lead to improvements in IVM and healthier outcomes from reproductive therapies. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1342419 / Thesis (Ph.D.) -- University of Adelaide, School of Paediatrics and Reproductive Health, 2008