Plasminogen activator activity and thymidine incorporation in avian granulosa cells during follicular development and the periovulatory period

Transcriptomic analysis of granulosa cell populations proximal and distal to the germinal disc of chicken preovulatory follicles

Within the oocytes of chicken preovulatory follicles, the engulfed yolk constitutes 99% of the oocyte content, while the small germinal disc (GD) (which contains the nucleus and 99% ooplasm) occupies only less than 1%. Relative to the position of the GD, the single granulosa cell layer surrounding the oocyte can be sub-divided into two sub-populations: granulosa cells proximal (named Gp cells) and distal (Gd cells) to the GD. It was reported that Gp cells and Gd cells differ in their morphology, proliferative rate and steroidogenic capacity, however, the underlying mechanism controlling granulosa cell heterogeneity remains unclear. Here we analyzed the transcriptomes of Gd and Gp cells of preovulatory (F5 and F1) follicles in chicken ovaries. We found that: (1) genes associated with cell cycle and DNA replication (CDK1, CCNB3 etc.) have comparatively higher expression levels in Gp cells than in Gd cells, while genes associated with steroidogenesis (CYP51A1, DHCR24) are highly expressed in Gd cells, indicating that Gp cells are likely more mitotic and less steroidogenic than Gd cells; (2) genes associated with extracellular matrix remodeling, cell adhesion and sperm binding (ZP3, ZP2) are differentially expressed in Gp and Gd cells; (3) Furthermore, signaling molecules (WNT4/IHH) and receptors for NGF (NGFR), epidermal growth factor (EGFR), gonadotropins (FSHR/LHR) and prostaglandin (PTGER3) are abundantly but differentially expressed in Gp and Gd cells. Taken together, our data strongly supports the notion that Gp and Gd cells of preovulatory follicles differ in their proliferation rate, steroidogenic activity, ECM organization and sperm binding capacity, which are likely controlled by gonadotropins and local ovarian factors, such as GD-derived factors.

Transcriptomic Diversification of Granulosa Cells during Follicular Development in Chicken

Granulosa cells play important roles in ovarian follicular development. To better understand the molecular mechanisms involved in this physiological process in chicken, high-throughput transcriptome analyses were performed to study the expression profiles of granulosa cells harvested from 6 mm white follicles, F5 follicles and F1 follicles. The analyses elucidated a clear tendency of granulosa cells in shifting its expression profile from proliferation to differentiation during follicular development. Transcripts down-regulated during this process were mainly associated with cell division, cell cycle and DNA replication while the up-regulated transcripts were related to ribosomal function, lipid metabolism and protein synthesis. Our study for the first time provides the complete gene expression profiles along follicular development supporting the active involvement of many genes characterized in cell signaling (AMH, Inhibins, Activins, BMPs) and transcription factors (SMAD3, SMAD5, ID1, ID2, ID3). Their temporal expression profiles support the notion of continual cross-talk between granulosa cells and its neighboring cells and shed light on the mechanisms behind avian follicular selection and pave the way to the better understanding of reproductive efficiency.

Transcriptome analysis of the potential roles of FOXL2 in chicken pre-hierarchical and pre-ovulatory granulosa cells

Forkheadbox L2 (FOXL2) is a transcription factor involved in mammalian ovarian development, especially in granulosa cell differentiation. However, this factor's function in mature chicken ovary is unclear. To explore the function of FOXL2 in chicken granulosa cells, we performed RNA-seq to compare the transcriptomes of pre-hierarchical (phGCs) and pre-ovulatory granulosa cells (poGCs) by FOXL2 overexpression. We observed that focal adhesion might be one of the key pathways activated during the differentiation of granulosa cells, and FOXL2 might be involved in follicle selection by regulating the expression of cytokines and the concentration of cyclic adenosine monophosphate (cAMP). Interestingly, we observed that FOXL2 played different roles in phGCs and poGCs, which might contribute to homeostasis in the chicken follicle by inducing differentiation of granulosa cells in pre-hierarchal follicles and preventing premature ovulation in pre-ovulatory follicles. Taken together, the results of our study establish a framework for understanding the potential functions of FOXL2 in the chicken granulosa cell.

Dynamics of avian ovarian follicle development: cellular mechanisms of granulosa cell differentiation

In vertebrate species that ovulate one or a limited number of ovarian follicles per reproductive cycle, the cellular processes by which follicle selection (cyclic recruitment) is mediated and final differentiation is initiated remain largely unknown. In the hen ovary, the selection of a single follicle into the preovulatory hierarchy on an approximate daily basis occurs from a small cohort of prehierarchal follicles measuring approximately 6- to 8-mm in diameter. Given that the granulosa layer undergoes a dramatic alteration in phenotype subsequent to follicle selection, of particular interest are the cell signaling and associated transcriptional mechanisms that regulate this transition. Recent studies suggest that granulosa cells from prehierarchal follicles are normally maintained in an undifferentiated state by inhibitory MAP kinase (MAPK) signaling mediated by epidermal growth factor receptor ligands (EGFRLs). One of the earliest markers for differentiating granulosa cells is elevated expression of FSH receptor (fshr) mRNA and enhanced FSH-induced cyclic adenosine monophosphate (cAMP) production. EGFRL/MAPK signaling is proposed to inhibit fshr transcription via its ability to induce Inhibitor of differentiation/DNA binding (Id) protein isoforms, Id1, Id3 and Id4. Subsequent to follicle selection, cAMP-induced Id2 expression is considered both sufficient and necessary for fshr transcription. Two working models are proposed which predict that enhanced FSHR expression and the progression of granulosa cell differentiation occurs as a result of a decline in MAPK signaling from within granulosa cells (internal model for differentiation) and/or elevated cAMP signaling promoted by an endocrine, neuroendocrine or neuronal factor (external model).

Intra-ovarian growth factors regulating ovarian function in avian species: a review

There is now overwhelming evidence that the avian ovary is a site of production and action of several growth factors that have also been implicated in the functioning of the mammalian ovary. Several members of the Insulin-like growth factor family (IGF), the Epidermal growth factor family (EGF), the Transforming growth factor-beta family (TGF-beta), Fibroblast growth factors (FGF), the Tumour necrosis factor-alpha (TNF-alpha), and others, have been identified either in the granulosa and/or theca compartments of ovarian follicles and in the embryonic and juvenile ovary. Some have been specifically localized to the germinal disc area containing the oocyte. The mRNAs and proteins of the growth factors, receptor proteins and binding proteins of some of the members of each group have been reported in the chicken, turkey, quail and duck. The intra-ovarian roles reported for the different growth factors include regulation of cell proliferation, steroidogenesis, follicle selection, modulation of gonadotrophin action, control of ovulation rate, cell differentiation, production of growth factors, etc. The aim of this paper is to provide a review of the current knowledge of avian ovarian growth factors and their biological activity in the ovary. The review covers the detection of the growth factor proteins, the receptor proteins, binding proteins, their spatial and temporal distribution in embryonic, juvenile and adult ovaries and their regulation. The paper also discusses their roles in each follicular compartment during follicular development. Greater emphasis is given to the major growth factors that have been studied to greater detail and others are discussed very briefly.

Role for inhibitor of differentiation/deoxyribonucleic acid-binding (Id) proteins in granulosa cell differentiation

Recent studies in the hen ovary have linked the initiation of granulosa cell differentiation at follicle selection to the alleviation of inhibitory MAPK signaling. The present studies assessed a role for individual inhibitor of differentiation (Id) protein isoforms as modulators of key transcriptional events occurring within granulosa cells at or immediately subsequent to differentiation. Findings from freshly collected granulosa cells collected at different stages of follicle development demonstrated a negative association between expression levels for Id2 mRNA compared with levels of Id1, Id3, and Id4. Elevated levels of Id2 are related to a differentiating/differentiated phenotype, whereas elevated Id1, Id3, and Id4 are associated with an undifferentiated phenotype. This negative relationship extends to cell signal transduction, because factors that promote inhibitory MAPK signaling (TGF-alpha and betacellulin) block expression of Id2 mRNA but increase levels of Id1, Id3, and Id4. Furthermore, overexpression of Gallus Id2 in cultured granulosa was found to significantly decrease levels of Id1, Id3, and Id4 mRNA but facilitate FSHR mRNA expression and, importantly, initiate LHR mRNA expression plus LH-induced progesterone production. Finally, knockdown studies using small interfering RNA specific for Id2 revealed reduced expression of FSHR and LHR mRNA and attenuated FSH- and LH-induced levels of StAR and p450 cholesterol side-chain cleavage enzyme mRNA plus progesterone production. Collectively, these data demonstrate that Id2 expression is both sufficient and necessary for increasing LHR expression and, as a result, promoting gonadotropin-induced differentiation in hen granulosa cells subsequent to follicle selection.

Opposing actions of TGFβ and MAP kinase signaling in undifferentiated hen granulosa cells

The present studies were conducted to establish interactions between transforming growth factor (TGF)-beta and the epidermal growth factor (EGF) family members, TGFalpha and betacellulin (BTC), relative to proliferation and differentiation of granulosa cells in hen ovarian follicles. Results presented demonstrate expression of TGFbeta isoforms, plus TGFalpha, BTC, and ErbB receptors in prehierarchal follicles, thus establishing the potential for autocrine/paracrine signaling and cross-talk within granulosa cells at the onset of differentiation. Treatment with TGFalpha or BTC increases levels of TGFbeta1 mRNA in undifferentiated granulosa cells, while the selective inhibitor of mitogen activated protein kinase signaling, U0126, reverses these effects. Moreover, TGFbeta1 attenuates c-myc mRNA expression and granulosa cell proliferation, while TGFalpha blocks both these inhibitory effects. Collectively, these data provide evidence that EGF family ligands regulate both the expression and biological actions of TGFbeta1 in hen granulosa cells, and indicate that the timely interaction of these opposing factors is an important modulator of both granulosa cell proliferation and differentiation.

Limited effect of intense genetic selection for broiler traits on ovarian function and follicular sensitivity in broiler breeders at the onset of lay

Female chicks from 6 pure lines of broiler breeders were obtained from international broiler breeder companies. The lines were from three female and two male lines and a relaxed selection line derived from one of the male lines (M2) and maintained without selection for 25 years (generations). Replicate groups from each line were reared in floor pens and fed ad libitum. An additional group of the M2 male line was feed restricted and housed in similar pens. Twenty birds from each group were photostimulated after housing them in individual cages at 14 weeks of age. Ovarian follicular dynamics and follicular sensitivity were determined after the onset of lay. Female lines had a greater proportion of atretic follicles and more groups of multiple follicles than male lines. Body weights, fatness and age at puberty were similar in male and female lines. The relaxed selection line had more abdominal fat than any of the selected lines and the ovary contained a similar number of normal yellow follicles as the selected male line. Feed restriction decreased body weight, the numbers of yellow follicles, multiple yellow follicles and the proportion of atretic yellow follicles, and increased the age at onset of lay. The response of ovarian follicles of three different sizes to exogenous gonadotrophin stimulation with PMSG was similar in small yellow follicles, 5 to 6 and 2 to 3 mm white follicles in a female line, a male line and its relaxed line fed ad libitum. The results suggest that the original lines from which modern male-line broiler stocks are derived had a relatively large number of yellow follicles and a high propensity for multiple ovulation at the onset of lay. Separate selection for different traits in male and female lines has not had a dramatic effect on ovarian function or sensitivity to gonadotrophin stimulation.

Survivin as a cell cycle-related and antiapoptotic protein in granulosa cells

Survivin is a relatively unique member of the inhibitor of apoptosis protein (IAP) family in that it contains a single baculovirus IAP repeat (BIR) domain combined with a COOH-terminal alpha-helix coiled-coil domain instead of the more common zinc-binding RING finger. Results from a variety of transformed or continuous mammalian cell lines suggest that, due to the combination of these features, Survivin is capable of regulating both cell proliferation and apoptotic cell death. However, to date there is essentially no information regarding Survivin expression, regulation or function within the ovary, or in any nonmammalian vertebrate species. In the present studies, cDNAs for chicken (ch) Survivin-142 (homologous to human Survivin-142) plus three alternatively spliced variants (ch Survivin-short, -gamma, and -delta) are described, and of these, transcripts for ch Survivin-142 and -short are expressed in granulosa cells from the hen ovary. Highest levels of Survivin mRNA during follicle development occur in mitotically active granulosa cells from undifferentiated, prehierarchal follicles. Cell cycle analysis determined that Survivin mRNA expression is elevated specifically during the G2/M phase of mitosis. Significantly, transient transfection with ch Survivin-142 in primary cultures of hen granulosa cells attenuates taxol- and N-octanoylsphingosine- (C8-ceramide-) induced caspase-3 activity, whereas overexpression of ch Survivin-short (a truncated variant that lacks much of the functional BIR domain plus the entire alpha-helix coil domain) lacks this antiapoptotic activity. Taken together, these data provide evidence for Survivin in granulosa cells acting as a bifunctional protein associated with regulation of the cell cycle and the inhibition of apoptosis.

Regulation of follicle differentiation by gonadotropins and growth factors

The rate of ovulation is determined by, among other things, the availability of small follicles that can be recruited into the follicular hierarchy. A decrease in the rate of lay with, for instance, aging has been attributed to both an increase in the rate of atresia and a decrease in the number of small, growing follicles that provide the pool from which follicles are selected into the final growth phase (the preovulatory hierarchy). Among the most important endocrine, paracrine, and autocrine factors that mediate follicle growth and differentiation are the gonadotropins and growth factors. A better understanding of gonadotropin-growth factor interactions that occur during follicle selection and differentiation should lead to the development of management practices or genetic manipulations (Mendelian or molecular) that will enhance the rate of lay at times during the production cycle when egg production is suboptimal.