David W. Schomberg scite author profile

Targeted disruption of the mouse estrogen receptor-alpha gene (estrogen receptor-alpha knockout; ERKO) results in a highly novel ovarian phenotype in the adult. The ERKO mouse model was used to characterize ER alpha-dependent processes in the ovary. Visualization of the ovaries of 10-, 20-, and 50-day-old wild-type (WT) and ERKO mice showed that the ERKO phenotype developed between 20 and 50 days of age. Developmental progression through the primordial, primary, and antral follicle stages appeared normal, but functional maturation of preovulatory follicles was arrested resulting in atresia or in anovulatory follicles, which in many cases formed large, hemorrhagic cysts. Corpora lutea were absent, which also indicates that the normal biochemical and mechanical processes that accomplish ovulation were compromised. Northern and ribonuclease protection analyses indicated that ERKO ovary FSH receptor (FSHR) messenger RNA (mRNA) expression was approximately 4-fold greater than in WT controls. Ovarian LH receptor (LHR) mRNA expression was also higher in the ERKO animals. Cellular localization studies by in situ hybridization analysis of ERKO ovaries showed a high level of LHR mRNA expression in the granulosa and thecal layers of virtually all the antral follicles. Ribonuclease protection analyses showed that ovarian progesterone receptor and androgen receptor mRNA expression were similar in the two groups. These results indicated that ER alpha action was not a prerequisite for LHR mRNA expression by thecal or granulosa cells or for ovarian expression of progesterone receptor mRNA. Ovarian estrogen receptor beta (ER beta) was detected immunohistochemically, was sharply compartmentalized to the granulosa cells, and was expressed approximately equally in the ERKO animals and the WT controls. In contrast, ER alpha staining was present in the thecal cells but not the granulosa cells of the WT animals. The summary findings indicate that in the adult the major cause of the ERKO phenotype is high circulating LH interacting with functional LHR of the theca and granulosa cells. These features result in a failure of the normal maturational events leading to successful ovulation and luteinization and presumably involve both hypothalamic-pituitary and intraovarian mechanisms dependent upon ER alpha action. The presence of ER beta in the granulosa cells did not rescue the phenotype of the ovary.

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Apoptosis in atretic ovarian follicles is associated with selective decreases in messenger ribonucleic acid transcripts for gonadotropin receptors and cytochrome P450 aromatase.

Tilly

et al. 1992

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Although atresia of ovarian follicles is of critical importance during preovulatory follicle selection as well as during normal and premature menopause, the mechanisms underlying atresia remain poorly understood. To study molecular events associated with atresia, we evaluated changes in mRNA levels for cytochrome P450 aromatase, FSH receptor, LH receptor, and a structural protein, beta-actin, during atresia in small (3-mm diameter) and large (6-mm diameter) porcine follicles. In addition, internucleosomal fragmentation of DNA characteristic of apoptosis ("programmed cell death") was assessed in individual healthy and atretic follicles using a sensitive autoradiographic method. Follicles were classified as morphologically healthy or atretic based on the absence or presence of follicular haemorrhagia and the degree of follicular clarity. Morphological signs of atresia in individual follicles were correlated with the occurrence of internucleosomal DNA fragmentation in granulosa cells as well as in thecal cells during advanced stages of atresia. The presence of apoptosis in atretic follicles was also associated with significant decreases in follicular fluid estrogen concentrations compared to those in healthy follicles of the same size. The decline in estrogen synthesis in degenerating follicles was further correlated with decreased levels of a predominant 2.6-kilobase aromatase mRNA. Moreover, substantial declines in both FSH receptor and LH receptor mRNAs were found in atretic follicles, consistent with previous reports of their decreased responsiveness to gonadotropins. The observed decreases in mRNAs for aromatase and gonadotropin receptors could not be attributed to a generalized degradation of cellular RNA during atresia, as evidenced by the presence of intact 18S and 28S ribosomal RNA as well as constitutive expression of beta-actin mRNA in atretic follicles. These data indicate that apoptotic cell death is initiated in both granulosa and thecal cells of porcine follicles during atresia. Associated with internucleosomal DNA fragmentation, decreased transcription of specific ovarian genes or destabilization of their transcripts leads to selective decreases in aromatase and gonadotropin receptor mRNAs. The atresia of ovarian follicles provides an interesting model to further study the molecular events associated with DNA fragmentation and selective mRNA down-regulation during apoptosis.

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The Effect of Transforming Growth Factor-β on Follicle-Stimulating Hormone-Induced Differentiation of Cultured Rat Granulosa Cells*

1987

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Growth factors have been shown to modulate differentiation of cultured ovarian granulosa cells. Transforming growth factors (TGFs) constitute a family of polypeptide growth factors capable of reversibly inducing anchorage-independent growth in normal cells. Epidermal growth factor (EGF), which has significant structural homology with TGF alpha, has been shown to modulate differentiation of granulosa cells in vitro. Similarly, TGF beta (TGFB) has been found to have significant structural homology with ovarian follicular fluid inhibin. To examine whether TGFB might affect granulosa cell growth or differentiation, rat granulosa cells were cultured in serum-free medium containing insulin for up to 3 days with varying concentrations of TGFB in the presence or absence of FSH. TGFB caused a dose-dependent increase in FSH-stimulated LH/hCG receptor binding, but had no effect on binding in the absence of FSH; TGFB (10.0 ng/ml) further increased FSH-stimulated LH/hCG receptor binding by 48 +/- 8% (P less than 0.02). Similarly, FSH-stimulated progesterone production was increased by TGFB in a dose-dependent manner; TGFB (1.0-10.0 ng/ml) increased FSH-stimulated progesterone production 2- to 3-fold (P less than 0.02). In contrast, EGF (10.0 ng/ml) decreased FSH-stimulated LH/hCG receptor binding by 93 +/- 1% (P less than 0.02). Neither FSH-stimulated intracellular nor extracellular cAMP accumulations were affected by TGFB treatment. However, EGF (10.0 ng/ml) diminished extracellular and intracellular FSH-stimulated cAMP accumulation at 48 and 72 h of culture. Culture protein and DNA content were not significantly affected by TGFB. These results suggest that TGFB may enhance FSH-stimulated LH receptor induction and steroidogenesis by mechanisms that do not further increase net cellular cAMP accumulation; TGFB and EGF can have opposite effects on gonadotropin-dependent differentiation; and products of the TGFB/inhibin gene family may have a capacity for autocrine or paracrine modulation of granulosa cell differentiation.

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