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Basic Fibroblast Growth Factor and N-Cadherin Maintain Rat Granulosa Cell and Ovarian Surface Epithelial Cell Viability by Stimulating the Tyrosine Phosphorylation of the Fibroblast Growth Factor Receptors

Department of Obstetrics and Gynecology, University of Connecticut Health Center, Farmington, Connecticut 06030

Address all correspondence and requests for reprints to: John J. Peluso, Ph.D., Department of Obstetrics/Gynecology, University of Connecticut Health Center, Farmington, Connecticut 06030.

	Abstract

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Both granulosa cells (GCs) and ovarian surface epithelial cells undergo apoptosis in vivo. Although basic fibroblast growth factor (bFGF) and N-cadherin-mediated cell contact inhibit GC apoptosis, little is known about the factors that influence rat ovarian surface epithelial (ROSE) cell apoptosis. The present studies were designed to determine whether bFGF and N-cadherin maintain the viability of both GC and ROSE cells by stimulating separate signaling pathways. For the GC studies, large GCs were collected from immature rat ovaries after Percoll gradient centrifugation and placed in serum-free culture for 24 h. These studies confirmed that about 10% of the aggregated GCs and more than 50% of single GCs were apoptotic after culture. bFGF reduced the percentage of apoptotic single GCs, but did not influence aggregated GCs. A neutralizing antibody to bFGF blocked bFGF’s antiapoptotic action, but did not alter the percentage of apoptotic aggregated GCs. The antibody to N-cadherin not only increased the percentage of aggregated apoptotic GCs, but also blocked bFGF’s ability to maintain the viability of single GCs. The effect of the FGF receptor antibody was similar to that of the N-cadherin antibody. Like GCs, ROSE cells also undergo apoptosis in serum-free medium. Exposure to either the N-cadherin or FGF receptor antibody, even in the presence of serum, increased the percentage of apoptotic aggregated ROSE cells.

As tyrosine kinase activity is involved in maintaining cell viability, the pattern of tyrosine-phosphorylated proteins was examined after culture in control (ascites) or N-cadherin antibody-supplemented medium. Exposure to the N-cadherin antibody altered the pattern of tyrosine-phosphorylated proteins, decreasing the tyrosine phosphorylation of proteins in the 130- to 180-kDa range and increasing the tyrosine phosphorylation of one or more proteins of about 50 kDa. The identity of the 50-kDa protein is unknown. However, immunoprecipitation studies demonstrated that the N-cadherin antibody reduced the amount of tyrosine-phosphorylated FGF receptor in both GCs and ROSE cells by 50%. This decrease corresponds to an increase in apoptosis among aggregated cells. Taken together, these data suggest that homophilic N-cadherin binding and bFGF-FGF receptor binding activate signal transduction pathways that converge at the level of the FGF receptor and subsequently promote the viability of both GC and ROSE cells.

	Introduction

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OVER THE COURSE of the reproductive life span, more than 90% of ovarian follicles undergo a degenerative process referred to as atresia (1). Ovarian follicular atresia is a complex process involving the death of granulosa cells (GCs) by an apoptotic mechanism (2, 3). The hallmark of apoptosis is the presence of a distinctive DNA ladder composed of 180- to 220-bp oligonucleosomal fragments (4, 5). The presence of the DNA ladder coincides with morphological indicators of apoptosis such as nuclear condensation and fragmentation (6).

GCs also undergo apoptosis in serum-free medium within 24 h (6, 7). In vitro GC apoptosis is suppressed by a diverse array of hormonal factors, including epidermal growth factor (6, 7), insulin-like growth factor I (8), insulin (8), basic fibroblast growth factor (bFGF) (6), and progesterone (7, 9). In addition to hormonal regulators, cell to cell contact inhibits GC apoptosis (9, 10). This antiapoptotic pathway is dependent on N-cadherin (10). N-Cadherin is a membrane-bound protein (11) that is expressed by GCs and ovarian surface epithelial cells (10, 12, 13, 14, 15) and is involved in specific cell to cell adhesion and tissue morphogenesis (11). N-Cadherin also appears to participate in signal transduction events, as evidenced by the ability to influence various cellular functions (16, 17). Because of the structural similarities between regions of the extracellular domains of N-cadherin and the receptors for bFGF (18), Walsh and Doherty proposed that N-cadherin interacts with the FGF receptor to regulate neurite outgrowth (19). As bFGF and N-cadherin are involved in maintaining GC viability, the present study was designed to determine whether bFGF and N-cadherin inhibit GC apoptosis by activating separate signaling pathways or converge at the level of the FGF receptor.

In addition to GCs, the ovarian surface epithelial cells associated with the stigmata of the ovulatory follicle undergo apoptosis as part of the ovulatory process, thereby creating an opening for the release of the oocyte (20). However, very little is known about the factors that regulate ovarian surface epithelial cell apoptosis. As GCs and ovarian surface epithelial cells both undergo apoptosis in vivo, experiments were also designed to investigate the putative role for N-cadherin in regulating surface epithelial cell apoptosis.

	Materials and Methods

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Animals
Immature female Wistar rats (22 days of age) were obtained from Charles River Breeding Laboratories (Wilmington, MA) and housed under controlled conditions of temperature, humidity, and photoperiod (12 h of light, 12 h of darkness; lights on at 0700 h). Rats were anesthetized with CO₂ and then cervically dislocated between 0930–1000 h when they were between 23–28 days of age. This protocol was approved by the animal care committee of the University of Connecticut Health Center.

Preparation of culture medium
RPMI 1640 without phenol red (Life Technologies, Grand Island, NY) was used in all culture experiments involving GCs. It was supplemented with penicillin (0.14 g/liter), streptomycin (0.27 g/liter), HEPES (4.76 g/liter), BSA (fraction V; 2 g/liter), sodium selenite (5 ng/ml), transferrin (5 µg/ml), and sodium bicarbonate (2.2 g/liter). The pH was adjusted to 7.4, and the medium was filtered through a 0.2-µm filter. Depending on the experimental design, bFGF (5 ng/ml), a goat antihuman bFGF antibody (100 µg/ml), a rabbit antibody to bFGF receptor (3.75 µg/ml), and a mouse monoclonal antibody to N-cadherin (144 µg/ml) were added to the cultures. bFGF and its antibody were purchased from R&D (Minneapolis, MN); the N-cadherin antibody was obtained from Sigma Chemical Co. (St. Louis, MO). The neutralizing FGF receptor antibody was a rabbit antibody directed against the chicken FGF receptor (Upstate Biotechnology, Lake Placid, NY). For studies involving the N-cadherin antibody, the control culture medium was supplemented with the appropriate amount of mouse ascites fluid.

GC isolation and culture
GCs were isolated according to the procedure of Luciano et al. (7). Briefly, follicles were punctured with 20-gauge needles and then incubated in EGTA-supplemented medium 199 for 5 min at 37 C in a 5% CO₂-air atmosphere. The ovaries were then incubated with EGTA-sucrose-supplemented medium 199 for 10 min at 37 C in a 5% CO₂-air atmosphere. The ovaries were washed, resuspended in fresh medium 199 containing 0.2% BSA, and then pressed to release GCs. The cells were loaded onto the top of a 15–45% Percoll gradient. Large GCs were collected from fractions 6–7, plated in either 60-mm glass petri dishes at 1 x 10⁶ GCs/2 ml for Western blot procedures or glass eight-chamber Lab-Tek slides (Nunc, Naperville, IL) at 7.5 x 10⁴/400 µl for assessment of apoptotic nuclei. GCs were subsequently cultured for 24 h in a 5% CO₂-air atmosphere.

Rat ovarian surface epithelial (ROSE) cell culture
ROSE cells were generously provided by Dr. Robert Burghardt, Texas A&M University (College Station, TX). These cells were maintained in DMEM-Ham’s F-12 medium supplemented with 5% FBS (21). For experimental procedures, ROSE cells were plated in either 60-mm glass petri dishes at 1 x 10⁶ cells/ml or glass eight-chamber Lab-Tek slides at 1 x 10⁵ cells/400 µl. The cultures were incubated in a 5% CO₂/air atmosphere for 30 min in serum-free medium supplemented with ascites (control) or an antibody to either N-cadherin or the FGF receptor. After 30 min, serum was added to a final concentration of 5%, and the cultures were incubated for 24 h. This protocol was selected so that the cells could be exposed to the antibody and then treated with serum to facilitate their attachment to the culture dish.

Detection of N-cadherin antibody after 24 h of culture
To determine whether the antibody to N-cadherin could be detected between adjacent surfaces of aggregated cells after culture, both GCs and ROSE cells were plated with the N-cadherin antibody or ascites fluid. After 24 h of culture, these cells were fixed in formalin and then incubated with FITC-labeled goat antimouse IgG. The cells were then observed under epifluorescent optics with the fluorescein isothiocyanate filter set. The presence of the N-cadherin antibody was revealed by bright green fluorescence. Cells not cultured with the N-cadherin antibody were also processed as described above and served as negative controls.

Assessment of apoptosis
The nuclear structure of GCs and ROSE cells was assessed after 24 h of culture by staining the DNA with hydroethidine (Polysciences, Warrington, PA) as previously described (7). For each treatment at least 100 cells were examined, and those cells that possessed condensed and fragmented nuclei were considered apoptotic. The percentage of apoptotic cells was then calculated. ROSE cells were also examined under the electron microscope according to procedures outlined previously (10).

Western blot analysis of tyrosine-phosphorylated proteins and FGF receptors
Cell lysate was prepared according to the protocol provided by Transduction Laboratories (Lexington, KY) with slight modifications. Cells were rinsed in PBS and then lysed with the addition of 150 µl boiling 2% SDS, 12.5 mM Tris-HCl buffer (pH 6.8), 20% glycerol, and 0.005% 2-mercaptoethanol. The cells were placed on ice, scraped from the dish using a cell scraper, and aspirated two or three times into a syringe using a 26-gauge needle. The lysate was then centrifuged in a microfuge at 13,000 x g at 4 C for 15 min. The supernatant was stored at -70 C.

To determine the profile of tyrosine-phosphorylated proteins; equal amounts of cell lysate from each treatment group were loaded onto a 10% polyacrylamide gel and electrophoresed at 100 V. Proteins were then transferred to nitrocellulose and incubated with Tris-buffered saline with 0.1% Tween-20 and 5% dry milk for 1 h as previously described (10). The nitrocellulose was probed with an antibody to tyrosine-phosphorylated proteins at a dilution of 1:1000 (Upstate Biotechnology), washed twice with Tris-buffered saline, and incubated with a 1:25,000 dilution of a peroxidase-labeled goat antimouse IgG (Kirkegaard and Perry, Gaithersburg, MD). Tyrosine-phosphorylated proteins were detected by chemiluminescence using the detection system of Kirkegaard and Perry.

The relative amount of tyrosine-phosphorylated FGF receptor was assessed by first immunoprecipitating the FGF receptor using a monoclonal mouse antibody directed against the human FGF receptor (Upstate Biotechnology). Briefly, 100 µl cell lysate were mixed with 400 µl distilled water, 500 µl 2 x immunoprecipitation buffer [1% Triton X-100, 150 mM NaCl, 10 mM Tris (pH 7.4), 1 mM EDTA, 1 mM EGTA, 0.2 mM sodium vanadate, 0.5% Nonidet P-20, and 0.2 mM phenylmethylsulfonylfluoride] and 10 µg of an antibody to FGF receptor and then incubated on ice for 1 h. After this, 5 µg rabbit antimouse IgG were added, and the incubation was continued for an additional 30 min. Fifty microliters of a solution of 10% protein A-Sepharose in 0.1 M phosphate buffer (pH 7.4) were added to the mixture, and the incubation was continued for a final 30 min with agitation. This mixture was then centrifuged at 13,000 x g for 5 min and washed three times with immunoprecipitation buffer. The pellet was resuspended in 30 µl loading buffer, boiled for 5 min, centrifuged, and loaded onto a 10% polyacrylamide gel. After electrophoresis, the proteins were then transferred to nitrocellulose, and the presence of tyrosine-phosphorylated FGF receptor was detected as described previously.

Statistical analysis
All experiments in which apoptosis was assessed by nuclear morphology were conducted in duplicate, and the entire experiment was repeated two or three times. The data from these studies were pooled. After determining that the percentages were normally distributed, the data were analyzed by either a two- or one-way ANOVA followed by the Student-Newman-Keuls multiple range test. Regardless of the statistical test, only P 0.05 was considered significant. For experiments involving tyrosine phosphorylations, cell lysates from each treatment group were electrophoresed as a single sample. These experiments were repeated three to five times. The relative densities of the bands obtained after detecting the tyrosine-phosphorylated FGF receptors were determined by image densitometry using the imaging and quantitation software of IP lab gel (Signal Analytics Corp., Vienna, VA).

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Greater than 50% of all single GCs were apoptotic after 24 h of culture in serum-free medium, whereas the percentage of apoptotic aggregated GCs ranged between 10–20%. bFGF suppressed single GC apoptosis in a dose-dependent manner, with the maximal effect observed at 5 ng/ml (P < 0.05; Fig. 1). The percentage of aggregated apoptotic GCs was not reduced by the bFGF at doses up to 10 ng/ml (Fig. 1). A neutralizing antibody directed against bFGF did not alter the percentage of single apoptotic GCs compared to that in the control group, but attenuated bFGF’s antiapoptotic action (P < 0.05). The percentage of apoptotic aggregated GCs remained relatively low even in the presence of the bFGF antibody (Fig. 2). Exposure to the N-cadherin antibody prevented bFGF from maintaining the viability of single GCs (P < 0.05) and increased the rate of apoptosis of aggregated GCs (P < 0.05; Fig. 3). The N-cadherin antibody was detected on the cell surface of single GCs and predominately at the junctional interface of aggregated GCs after 24 h of exposure (Fig. 3, inset). The detection of N-cadherin antibody was specific, as GCs not previously treated with the N-cadherin antibody did not fluoresce after incubation with FITC-labeled goat antimouse IgG.

View larger version (29K): [in this window] [in a new window]   Figure 1. The effect of bFGF and GC aggregation on the percentage of GCs undergoing apoptosis. After 24 h of culture, apoptotic cells were identified by the presence of apoptotic nuclei. The values shown in this and subsequent graphs represent the mean ± SE. After determining that the values for each treatment group were normally distributed, the data were analyzed by an ANOVA.

View larger version (34K): [in this window] [in a new window]   Figure 2. The effect of bFGF, an antibody to bFGF (Ab-bFGF), and cell aggregation on the percentage of apoptotic GCs. Control medium was supplemented with the appropriate amount of IgG.

View larger version (65K): [in this window] [in a new window]   Figure 3. The effect of bFGF, N-cadherin antibody (Ab-N-cad), and cell aggregation on the percentage of apoptotic GCs. In this study freshly isolated GCs (i.e. single GCs) were allowed to aggregate in the presence of the N-cadherin antibody and/or bFGF. Control medium was supplemented with the appropriate amount of ascites fluid. Although the N-cadherin antibody reduced aggregation to some extent, some GCs formed aggregates. After 24 h of culture with the N-cadherin antibody, the antibody was detected between adhering GC, as shown in the inset (x400).

View larger version (84K): [in this window] [in a new window]   Figure 4. The morphology of ROSE cells after 24 h of culture under serum-free conditions. In A, cells were stained with hydroethidine and observed under fluorescent optics to visualize the nuclei. Numerous apoptotic cells are observed as evidenced by their condensed and fragmented nuclei. These cells are also shrunken and have reduced cell contact. The nuclei of normal cells are lightly stained and are evident in the background. As can be seen in the electron micrograph shown in B, these apoptotic ROSE cells possess fragmented nuclei, large cytoplasmic vacuoles, and cytoplasmic blebs (A, x300; B, x4800).

View larger version (34K): [in this window] [in a new window]   Figure 5. Western blot of N-cadherin within ROSE cells is presented in the upper panel. As can be seen, ROSE cells express N-cadherin (Mr = 130 kDa). Nonspecific staining is shown in the lane marked with a minus sign. The effect of the N-cadherin antibody (Ab-N-cad) on the percentage of aggregated apoptotic ROSE cells is shown in the lower panel.

View larger version (25K): [in this window] [in a new window]   Figure 6. The effects of bFGF, FGF receptor antibody (Ab-FGFr), and cell aggregation on the percentage of apoptotic GC (A) and ROSE cells (B).

View larger version (74K): [in this window] [in a new window]   Figure 7. The profile of tyrosine-phosphorylated proteins present within ROSE cells cultured for 24 h with either control ascites-supplemented medium or medium supplemented with the antibody to N-cadherin (N-cad Ab; left panel). Negative controls did not reveal any nonspecific bands within the 45- to 200-kDa range (data not shown). Shown in the right panel are the results obtained from a single ROSE cell lysate that was processed to reveal the profile of tyrosine-phosphorylated proteins (Tyr-PO4) or immunoprecipitated with the FGF receptor antibody and then probed with an antiphosotyrosine antibody (FGFR-PPT). Notice that the FGFR-PPT lane is overexposed; as a result, distinct bands cannot be resolved.

View larger version (24K): [in this window] [in a new window]   Figure 8. The effect of N-cadherin antibody (N-cad Ab) on the amount of tyrosine-phosphorylated FGF receptors present 24 h after culture within granulosa cells (Gran Cell) or ROSE cells. In these preparations, two distinct bands with molecular masses of 150 and 140 kDa were detected in both granulosa cells and ROSE cells. These proteins represent the tyrosine-phosphorylated FGF receptor. Note that exposure to N-cadherin antibody reduced the amount of tyrosine-phosphorylated FGF receptor by about 50%.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

bFGF functions as a survival factor for GCs (6) as well as several other cell types (26, 27, 28, 29), including ROSE cells (Peluso, J. J., unpublished data). Interestingly, bFGF only maintains the viability of single and not aggregated GCs. Although GCs synthesize bFGF (22, 23), it is unlikely that endogenous bFGF accounts for the viability of aggregated GCs. This is supported by the observations that 1) bFGF does not enhance the viability of aggregated GCs; and 2) a neutralizing antibody to bFGF blocks bFGF’s action on single cells, but does not influence the viability of aggregated GCs. Rather, the viability of aggregated cells appears to be due to the homophilic binding of N-cadherin molecules, as both GCs and ROSE cells express N-cadherin, and N-cadherin antibody increases apoptosis of aggregated cells. These results as well as previous studies (9, 10) suggest that N-cadherin-mediated cell contact activates a signal transduction pathway that inhibits apoptosis. Although not dependent on hormones, serum, or growth factors, the N-cadherin-mediated signal transduction pathway may converge with the bFGF pathway.

bFGF enhances GC survival via a tyrosine kinase-dependent mechanism (6). However, several proteins, including the FGF receptors, are tyrosine-phosphorylated in the absence of bFGF or serum. The presence of these tyrosine-phosphorylated proteins is probably due to the homophilic binding of N-cadherin between adjacent cells. This hypothesis is based on the following observations. First, in both GCs and ROSE cells, exposure to an N-cadherin antibody reduces the level of tyrosine-phosphorylated FGF receptor by 50%. This is associated with a corresponding increase in the rate of apoptosis among aggregated cells. Second, the N-cadherin antibody is detected at the junctional interface between cell contacts, demonstrating that this antibody does not completely block cell aggregation but, rather, specifically interferes with the homophilic binding of N-cadherin molecules of adjacent cells. Taken together, these data support the concept that homophilic binding of N-cadherin promotes the tyrosine phosphorylation of FGF receptors, thereby triggering a signal transduction pathway that prevents apoptosis. Further, homophilic N-cadherin binding and bFGF-FGF receptor binding appear to stimulate signal transduction cascades that ultimately activate FGF receptors. This concept is supported by the tyrosine phosphorylation studies and the FGF receptor antibody studies that demonstrate that FGF receptor is required for bFGF, serum, and N-cadherin to prevent apoptosis.

The concept that N-cadherin-mediated cell contact controls various cellular functions by activating FGF receptors is important and may be relevant to other cellular systems. For example, Walsh and Doherty (19) were the first to propose that FGF receptors are an essential part of the mechanism through which cell contact mediates neurite growth. Their hypothesis is based in part on blocking antibody studies similar to ours. In addition, Walsh and Doherty showed that cell contact stimulates neurite growth by a tyrosine kinase-dependent process, but reagents that inhibit nonreceptor cytoplasmic tyrosine kinases do not prevent neurite growth. This suggests that the tyrosine kinase involved in signaling the response to cell adhesion is more closely related to the transmembrane receptor tyrosine kinases (for review, see Ref.17). Although antibody and pharmacological studies support the concept that homophilic binding of N-cadherin molecules stimulates FGF receptor function, the results of the present study are the first to demonstrate a direct link between N-cadherin and the activation (i.e. tyrosine phosphorylation) of FGF receptors.

Although it was anticipated that the N-cadherin antibody would reduce the viability of aggregated cells, it is surprising that N-cadherin antibody interferes with bFGF’s ability to maintain single GCs. Several different mechanisms could account for this observation. First, the N-cadherin antibody could inhibit bFGF from binding to its receptor. This is unlikely because a synthetic N-cadherin peptide that also attenuates N-cadherin-mediated cell survival (10) does not influence bFGF binding (19). Rather, recent studies have proposed that ligand binding results in the FGF receptor forming a complex with N-cadherin molecules within the same cell (30). This putative interaction may be required for bFGF to activate the receptor tyrosine kinase activity of its receptor. The N-cadherin antibody and synthetic N-cadherin peptide are likely to interfere with the formation of the putative FGF receptor/N-cadherin complex. This would account for the ability of these reagents to prevent bFGF from maintaining the viability of single GCs. This type of N-cadherin/FGF receptor interaction could also be induced by N-cadherin-mediated cell contact.

Finally, exposure to N-cadherin antibody induces an approximately 50-kDa protein(s) that is tyrosine phosphorylated in both GCs (31) and ROSE cells. The identity of this protein(s) is unknown, but it may represent an important step in the process of apoptosis. This protein could be an src-related tyrosine kinase such as blk or the cytoskeletal protein, cytokeratin. Both of these proteins are about 50 kDa and are tyrosine phosphorylated in apoptotic cells (32). A more complete biochemical and molecular biological approach will be required to determine both the identity of this protein(s) and its potential role in regulating GC and ROSE cell apoptosis.

	Acknowledgments

 
The authors are grateful to Dr. Bruce A. White for his thoughtful advice throughout the course of this study, and to Dr. Art Hand for his help in evaluating the electron micrographs. The authors also thank Dr. Robert Burghardt of Texas A&M University for providing the ROSE cells.

Received June 26, 1996.

	References

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