A relatively large body of evidence now appears to support the existence of the essential ingredients for novel intraovarian IGF-driven control mechanisms. Indeed, evidence presented in this communication is in keeping with the possibility that the granulosa cell may be the site of IGF production, reception, and action. Although the relevance of IGFs to ovarian cell types other than the granulosa cell is largely unknown, one cannot at the present time exclude the possibility of nongranulosa cell contributions to intraovarian IGF production, reception, and action. Indeed, preliminary affinity cross-linking studies (Adashi, Resnick, Svoboda, Van Wyk and D'Ercole; unpublished data) suggest the existence of type-I and type-II receptors in nongranulosa cell compartments. The above notwithstanding, IGFs of granulosa (and possibly circulatory) origins may interact with granulosa cell autoreceptors either independently or in synergy with other granulosa cell agonists. According to this view, IGFs may act in the autocrine mode to stimulate granulosa cell replication on the one hand and promote granulosa cell differentiation on the other. Although proliferation and terminal differentiation may prove mutually exclusive under some circumstances, coexistence of the two processes is being increasingly recognized. In this context, some studies of porcine granulosa cells support a dual role for IGFs in granulosa cell ontogeny. As such, the IGFs can be added to a growing list of growth factors known to modulate granulosa cell growth and function, including EGF, PDGF, and FGF. Our findings indicate that Sm-C/IGF-I synergizes with FSH in the induction of rat granulosa cell aromatase activity at nanomolar concentrations compatible with its granulosa cell receptor binding affinity (thus far studied only in porcine cells. A role for Sm-C/IGF-I in the regulation of this key granulosa cell function would be in keeping with the possibility that Sm-C/IGF-I may partake in the assertion and maintenance of dominance by the selected follicle(s) or in promoting juvenile and early follicular development. Moreover, the ability of Sm-C/IGF-I to potentiate this and other FSH-driven ovarian functions may also account, at least in part, for the puberty-promoting effect of growth hormone. This permissive action of growth hormone has been initially suggested by observation in growth hormone-deficient rats, mice (dwarf mutants, and humans (sporadic, hereditary or acquired growth hormone deficiency.(ABSTRACT TRUNCATED AT 400 WORDS)
We have recently observed that nanomolar concentrations of exogenously added somatomedin-C (Sm-C) are capable of synergizing with FSH in the induction of cultured rat granulosa cell progesterone biosynthesis and LH receptors without altering granulosa cell survival or replication. To further characterize the cytodifferentiative properties of Sm-C, we have undertaken to investigate whether the acquisition of granulosa cell aromatase activity is also subject to modulation by this intraovarian peptide. Granulosa cells from immature hypophysectomized diethylstilbestrol-treated rats were initially cultured for up to 3 days in an androstenedione-free medium, during which time aromatase activity was induced by FSH in the absence or presence of Sm-C (treatment interval). At the conclusion of this period, the cells were washed and reincubated for an additional 8-h test interval, during which time aromatase activity was estimated. Basal aromatase activity, as assessed by the conversion of unlabeled androstenedione (10(-7) M) to radioimmunoassayable estrogen, was negligible, remaining unaffected by treatment with highly purified Sm-C (50 ng/ml) alone. However, concurrent treatment with Sm-C (50 ng/ml) produced a 7.0-fold increase in the FSH (100 ng/ml; NIH FSH S14)-stimulated accumulation of estrogen. Similarly, Sm-C produced a 6.1-fold increase in FSH-induced aromatase activity, as assessed by the stereospecific generation of tritiated water from [1 beta-3H]androstenedione substrate. Sm-C-potentiated aromatase activity was dose and time dependent, with an apparent median effective dose of 5.0 +/- 1.9 (+/- SE) ng/ml and a minimal time requirement of 24 h or less, but was independent of the FSH dose employed. Although bovine insulin and multiplication-stimulating activity, like Sm-C, proved capable of augmenting aromatase activity (albeit at a substantially reduced potency), little or no effect was observed for either porcine or rat relaxin, a distantly related member of the insulin-like growth factor family. Examination of the apparent kinetic parameters of the aromatase enzyme revealed that the Sm-C-mediated potentiation of aromatase activity was due to enhancement of the apparent maximal reaction velocity, but not substrate affinity (Km = 2.8 X 10(-8) M). Our findings indicate that nanomolar concentrations of exogenously added Sm-C synergize with FSH in the enhancement of the maximal reaction velocity, but not Km, of granulosa cell aromatase in a dose- and time-dependent fashion.(ABSTRACT TRUNCATED AT 400 WORDS)
We have recently shown that nanomolar concentrations of somatomedin-C (Sm-C), are capable of enhancing the FSH-mediated (but not basal) accumulation of progesterone (Po) by cultured rat granulosa cells. To further characterize this direct cytodifferentiative effect of Sm-C, granulosa cells from immature, hypophysectomized, diethylstilbestrol-treated rats were cultured under serum-free conditions for up to 96 h. Concurrent treatment with highly purified Sm-C (50 ng/ml) produced 10.2- and 3.6-fold increments in the FSH (20 ng/ml)-stimulated accumulation of Po and 20 alpha-hydroxy-4-pregnen-3-one, respectively. Sm-C-augmented Po biosynthesis was dose- and time dependent, but was independent of the FSH dose employed. Significantly, this effect of Sm-C could not be accounted for by enhancement of cellular viability or plating efficiency, nor by an increase in the number of cells, or their DNA synthesis. Furthermore, specific inhibition of DNA synthesis with cytosine-1-beta-D-arabinofuranoside was without significant effect on the ability of SM-C to enhance FSH-supported Po biosynthesis. Insulin, like Sm-C, also synergized with FSH in the induction of Po biosynthesis. However, insulin [ED50 = 19.2 +/- 1.6 (SE) micrograms/ml] was approximately 4800-fold less potent than Sm-C [ED50 = 4.0 +/- 0.3 (SE) ng/ml] in this regard, and exerted little or no effect at concentrations presumed to saturate the putative high affinity granulosa cell insulin receptor. Although maximal stimulatory doses of Sm-C (75 ng/ml) or insulin (100 micrograms/ml) produced comparable increments in FSH-supported Po biosynthesis, combined treatment with maximal doses of both peptides did not prove additive. Pertinently, the direct cytodifferentiative effect of Sm-C is exerted at (nanomolar) concentrations compatible with its receptor-binding affinity as observed in all other cell types studied. Thus, Sm-C is not likely to be acting through the putative high affinity insulin receptor but rather through its own high affinity recognition sites. Similarly, the cytodifferentiative action of high dose insulin may reflect the consequences of its cross-interaction with the putative Sm-C, rather than the insulin receptor. These findings are in keeping with the suggestion that the granulosa cell may be the site of Sm-C reception and action and that Sm-C of intraovarian or circulatory origin may participate in the differentiation, as well as replication, of the developing granulosa cell.
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