Differential gene expression between normal and tumor-derived ovarian epithelial cells.

The majority of ovarian tumors arise from the transformation of the ovarian surface epithelial cells, a single layer of cells surrounding the ovary. To identify genes that may contribute to the malignant phenotype of ovarian cancers, cDNA representational difference analysis was used to compare expressed genes in primary cultures of normal human ovarian surface epithelium (HOSE) and ovarian tumor-derived epithelial cells from the Cedars-Sinai Ovarian Cancer (CSOC) repository. A total of 255 differentially expressed genes were identified, of which 160 and 95 were specifically expressed in HOSE and CSOC cells, respectively. Using cDNA array hybridization, the expression profiles of the genes identified by cDNA-representational difference analysis were examined in an additional 5 HOSE and 10 CSOC lines. The comparison of average signal of each gene revealed 44 HOSE-specific and 16 CSOC-specific genes that exhibited at least a 2.5-fold difference in expression. A large number of genes identified in this study encode membrane-associated or secreted proteins and, hence, may be useful as targets in the development of serum-based diagnostic markers for ovarian cancer. Very few genes associated with protein synthesis or metabolism were identified in this study, reflecting the lack of observable differences in phenotypic or growth characteristics between HOSE and CSOC cells. Northern blot analysis on a subset of these genes demonstrated comparable levels of gene expression as observed in the cDNA array hybridization.

Transforming growth factor-beta regulates Kit ligand expression in rat ovarian surface epithelial cells.

In preparation for ovulation, paracrine communication between the preovulatory follicle and overlying theca/stromal cells and ovarian surface epithelium (OSE) must take place to facilitate the degradative and apoptotic events associated with ovulation. Kit tyrosine kinase receptors and their ligand, kit ligand (KL) are expressed within ovarian follicles, and ligand-induced receptor activation appears to account for some of the cell - cell interactions important for oocyte development. We investigated the expression of Kit receptors and KL in OSE cells and the possibility that modulation of their expression could affect OSE cell activity. KL mRNA and protein were detected in the OSE cell layer of rat ovaries, and primary cultures of rat OSE as well as the immortalized rat OSE cell line, ROSE 199, expressed KL, but not Kit receptors. Both primary and immortalized OSE cells preferentially expressed KL-1, rather than KL-2, transcripts, suggesting that these cells produce predominantly the soluble form of KL. Activation of the cAMP signalling pathway using dibutyryl cAMP decreased proliferation of ROSE 199 cells and elicited a threefold increase in KL expression. TGF-beta similarly inhibited ROSE 199 cell proliferation, but strongly inhibited dibutyryl cAMP-induced KL expression, indicating that changes in KL expression were not directly associated with OSE cell proliferation. The expression of mostly soluble KL in the surface epithelium suggests that this cytokine may be acting in a paracrine fashion, perhaps interacting with nearby Kit receptor-bearing theca cells.

Hormonally regulated expression and alternative splicing of kit ligand may regulate kit-induced inhibition of meiosis in rat oocytes.

Mutations in the genes encoding the Kit tyrosine kinase receptor or kit ligand (KL) cause numerous phenotypic defects, including sterility. In the postnatal ovary, Kit is expressed on the oocyte surface and KL is produced by the surrounding granulosa cells, but its function in these cells is still unknown. The purpose of this study was to determine the role KL/Kit interactions play in the regulation of oocyte meiosis. Here, we demonstrate that meiotically arrested rat oocytes that are microinjected with Kit antisense oligonucleotides have decreased Kit expression. This decreased expression is associated with an increased ability of these oocytes to resume meiosis compared with those microinjected with missense oligonucleotides or buffer alone. In addition, oocytes cultured in the presence of KL were delayed in their resumption of meiosis, but KL could not enhance the meiosis inhibitory effects of dibutyryl cAMP, suggesting that KL operates through a mechanism that is independent of cAMP. Human chorionic gonadotropin-induced meiotic resumption in oocytes was accompanied by a shift in follicular granulosa cell KL expression from membrane-bound to soluble forms and a loss of expression of both forms of KL in cumulus cells. Thus, KL-activated Kit inhibits meiotic progression, and the in vivo luteinizing hormone-stimulated resumption of meiosis may negate Kit activity by a localized decrease in KL expression and by altering the form of KL produced within the follicle.

Hormonal regulation of the ligand for c-kit in the rat ovary and its effects on spontaneous oocyte meiotic maturation.

Kit ligand (KL, c-kit ligand) mRNA was detected in the ovaries of 26-day-old prepubertal rats using in situ hybridization. In antral follicles there was a gradient in the intensity of the hybridization signal across the layers of granulosa cells, with greatest intensity observed in the cumulus granulosa cells enclosing the oocyte, and less signal occurring in the granulosa cells furthest from the oocyte. In age-matched rats 40 hr after injection of pregnant mare serum gonadotropin (PMSG), the pattern of distribution of KL resembled that in the untreated ovaries, although the intensity of the hybridization signal was greater in the PMSG-primed ovaries. This morphological observation was confirmed using Northern blot analysis, which indicated that granulosa cells of PMSG-treated rats had 3.5-fold greater abundance of KL mRNA compared to untreated rats. The abundance of KL mRNA further increased to 7-fold over control levels at 6 hr after PMSG-primed rats were treated with human chorionic gonadotropin (hCG). By contrast, treatment of rats with diethylstilbestrol to stimulate follicular growth did not cause any change in the abundance of KL transcripts. To investigate a potential role for KL in oocyte meiotic maturation, fully grown oocytes were cultured for 24 hr with or without KL (50 or 500 ng/ml). The presence of KL resulted in a significant, albeit transient, delay in the progression of spontaneous meiotic maturation, using the indices of germinal vesicle breakdown and polar body formation. The inhibitory effects of KL were specifically blocked by ACK2, an antibody to the extracellular domain of the c-kit receptor. These results indicate that KL is produced in rat granulosa cells at particularly high levels in the cells closest to the oocyte and that this production may be regulated directly by gonadotropic hormones. Furthermore, KL inhibits the progression of meiosis in cultured oocytes, which suggests a possible role in the maintenance of meiotic arrest that occurs throughout oocyte growth.