Stimulation of phosphatidic acid and phosphatidylinositol labeling in luteal cells by luteinizing hormone releasing hormone

Luteinizing hormone-releasing hormone (LHRH) causes a rapid and marked increase of [32P]orthophosphate incorporation into phosphatidylinositol (PI) and phosphatidic acid (PA) in rat luteal cells in culture. The neurohormone exerts its stimulatory effect at an ED50 value of approximately 15 nM. Human chorionic gonadotropin (hCG) has no effect alone and does not interfere with the LHRH-induced PA-PI labeling. The rapidity and the specificity of the effect of LHRH suggest that the stimulation of the PA-PI cycle may well serve as a potent transducing mechanism responsible for the direct action of LHRH and its agonists at the ovarian level.     

Progesterone regulation of luteinizing hormone receptors on cultured bovine luteal cells.

During development of the corpus luteum (CL), the numbers of luteinizing hormone (LH) receptors increase. Cultured bovine luteal cells from developing and mature CL were used to examine the influence of progesterone (P4) on this receptor. CL were obtained from dairy cows during the early or middle phase of the estrous cycle. In early CL, the number of receptors per cell was increased by exogenous progesterone treatment but there was no effect on receptor numbers in cells from midcycle CL. Binding affinities did not change with respect to age or treatment. Forskolin elevated endogenous progesterone and also enlarged the receptor population. The action did not appear to be an unmasking of cryptic receptors since the effect was not seen in luteal particulates. Elevation of LH receptor numbers by progesterone in immature CL may be a form of intraluteal regulation contributing to the functional maturation of these steroidogenic cells.     

Estradiol inhibition of luteinizing hormone-stimulated progesterone synthesis in isolated bovine luteal cells.

The effects of several steroid hormones on progesterone synthesis and cAMP accumulation in isolated bovine corpora luteal cells were investigated in an attempt to determine if any of the steroids would affect the basal level of these processes or their response to gonadotropin. Isolated bovine corpora luteal cells responded to LH with a significant (P less than 0.05) increase in progesterone synthesis and cAMP accumulation when incubated at 37 C for up to 1 h. Exogenous cAMP and analogs of cAMP also significantly stimulated steroidogenesis in these incubated cells. Stimulation of progesterone synthesis by 1 microgram/ml LH was significantly suppressed (P less than 0.05) in the presence of 5--10 microgram/ml estradiol. This inhibition appeared to be largely specific for 17beta-estradiol, in that other steroids such as estrone, estriol, 17alpha-estradiol, cortisol, and dihydrotestosterone were not inhibitory. Testosterone was found to be inhibitory, but it is uncertain if this effect was due to the androgen itself or to its conversion to estradiol. Estradiol did not affect the increase in endogenous cAMP caused by LH in these cells, but did inhibit the effect of exogenous dibutyryl cAMP on progesterone synthesis. The magnitude of this inhibition of the effect of dibutyryl cAMP was not, however, equal to the estradiol inhibition of the stimulation of progesterone synthesis by LH. These data indicate that estradiol, a possible physiological luteolytic agent, has a direct inhibitory action on the corpus luteum and produces its suppression by blocking the stimulatory effect of LH at a step after cAMP.     

Direct inhibitory effect of gonadotropin-releasing hormone upon luteal luteinizing hormone receptor and steroidogenesis in hypophysectomized rats

The effects of gonadotropin-releasing hormone (GnRH) and its potent agonist [des-Gly10, D-Leu6-N alpha Me) Leu7, Pro9,NHEt-GnRH (GnRH-A)] on ovarian luteal functions maintained by PRL were studied in vivo and in vitro. Hypophysectomized, diethylstilbestrol-treated female rats were primed with FSH for 2 days, followed by an ovulating dose of LH or hCG. Two days later, ovarian luteal functions were maintained by daily injections of 250 microgram PRL for 3 days. PRL treatment increased the serum progesterone level from 13.0 +/- 0.5 to 298 +/- 24 ng/ml and increased the ovarian hCG-binding capacity from 5.8 +/- 1.3 to 584 +/- 86 ng bound hCG/ovary. In contrast, concomitant treatment with GnRH or GnRH-A resulted in dose-dependent decreases in the PRL-induced increase of serum progesterone and ovarian LH/hCG receptor content. GnRH at 100 microgram/day caused a 60% decrease in serum progesterone and an 80% decrease in ovarian LH receptor content, whereas GnRH-A was effective at a 1-microgram dose level. Neither GnRH nor GnRH-A affected the binding affinity (Kd) of ovarian LH receptor. The direct inhibitory effects of GnRH and GnRH-A upon granulosa-luteal cell function were also tested in vitro. FSH treatment for 2 days induced functional LH and PRL receptors in cultured PRL, increased (by approximately 3-fold) progesterone production by these granulosa-luteal cells, whereas concomitant treatment with GnRH-A inhibited progesterone production in a dose-dependent manner. Thus, these studes demonstrated that GnRH and GnRH-A exert direct inhibition on ovarian luteal functions by decreasing LH receptor and progesterone production in vivo as well as inhibiting progesterone production by cultured granulosa-luteal cells in vitro.     

Selective amplification of luteinizing hormone by adenosine in rat luteal cells

Adenosine amplification of LH-stimulated cAMP accumulation in rat luteal cells is rapid and dependent on mitochondrial ATP production. The objective of the present studies was to determine if this effect of adenosine is specific for LH and to gain information on the mechanism of the ATP-dependent amplification of LH action in rat luteal cells. Adenosine significantly amplified maximum cAMP accumulation in response to LH, isoproterenol, forskolin, and cholera toxin. However, amplification of this response by adenosine was significantly greater for LH than for the other agonists. The relative order of amplification by adenosine was LH greater than isoproterenol greater than forskolin greater than cholera toxin; the relative magnitudes of amplification by adenosine were 1, 0.6, 0.2, and 0.2, respectively. Neither LH, isoproterenol, forskolin, nor cholera toxin had any effect on cellular levels of ATP, and adenosine produced a similar rate of increase and maximal levels of ATP in the presence of all agonists. Ionomycin, a calcium ionophore, inhibited LH- and cholera toxin-stimulated cAMP accumulation and produced a dose-dependent depletion of ATP. Adenosine reversed the inhibitory effect of ionomycin on LH-stimulated cAMP accumulation and cellular levels of ATP. However, adenosine did not reverse the inhibitory effect of ionomycin on cholera toxin-stimulated cAMP accumulation, although its effects on cellular ATP levels were identical to those on LH. Thus, the selective amplification of LH by adenosine is not merely a substrate effect on adenylate cyclase activity. The nature of adenylate cyclase activation by cholera toxin and forskolin and the weak amplification by adenosine of these agonists compared to that of LH indicate that the site of the ATP-dependent action of adenosine appears to be before or on the G-protein of adenylate cyclase. We suggest that adenosine, by an ATP-dependent process, either increases the availability of functional LH receptors or increases coupling between the LH receptor and adenylate cyclase.     

Varying response to luteinizing hormone of two luteal cell types isolated from bovine corpus luteum.

Luteal cell suspensions obtained by enzymatic digestion of pregnant cow corpus luteum were found to be heterogenous and mainly made up of two types of cells of different sizes. The large cells (37 micrometers, average diameter) could be separated from the small ones (18 micrometers, average diameter) by sedimentation at unit gravity in a gradient of Ficoll-bovine serum albumin. A comparative in-vitro study of the synthesis of progesterone by the two types of cells indicated striking differences between them. The average content and the synthesis of progesterone in the absence and presence of a saturating dose of bovine LH after incubation for 2 h were 0.07, 0.12 and 6.9 pg/cell for the small cells and 0.65, 2 and 10 pg/cell for the large ones. Moreover, the sensitivity to low concentrations of LH was 100 to 1000 times higher for the small cells than for the large ones. Oestradiol-17 beta at concentrations ranging from 5 X 10(-10) to 5 X 10(-4) mol/l exerted a dose-dependent inhibition on the stimulation of LH in both cell types. These results suggest a possible involvement of both cell types in the synthesis of progesterone in vivo with a greater contribution by the small cells to stimulation induced by LH. Moreover, it appears that small cell suspensions could be a useful model system for in-vitro studies of the control of the synthesis of progesterone in cow corpus luteum.     

Interaction of hCG and Lutalyse on steroidogenesis of bovine luteal cells

This study was designed to examine the ability of in vivo administration of human chorionic gonadotropin (hCG, 4000 IU) to alter the effects of Lutalyse (PGF2 alpha, 10 mg) in the cow. hCG significantly increased plasma progesterone concentration in midcycle cows (P less than 0.01), but these elevated levels were not maintained in the presence of Lutalyse (P less than 0.05). Responsiveness of luteal cells in vitro to luteinizing hormone (LH) (100 ng/ml), prostaglandin F2 alpha (PGF2 alpha) (1 microgram/ml), dibutyryl cyclic AMP (dbcAMP) (10 mM) and PGF2 alpha (1 microgram/ml) + dbcAMP (10 mM) during a 2 h incubation was significantly reduced following in vivo treatment with Lutalyse when compared to in vivo untreated animals. In conclusion, the luteotropic effects of hCG were incapable of preventing Lutalyse-induced regression of the corpus luteum, and treatment of animals with hCG prior to Lutalyse administration could not prevent the significant decrease in responsiveness of luteal cells in vitro.     

Mitochondria mediate amplification of luteinizing hormone action by adenosine in luteal cells

Adenosine markedly amplifies the response of isolated rat and human luteal cells to LH via an intracellular site of action that is associated with an increase in cell ATP levels. This effect of adenosine is maximal in midstage cells and minimal at the onset of functional regression in late stage luteal cells. The objective of the present studies was to evaluate the role of mitochondria in mediating the action of adenosine in isolated rat luteal cells and to assess whether mitochondrial function may be compromised in regressing luteal cells. The present studies show that adenosine produced a significant increase in luteal cell levels of ADP and ATP, but had no effect on cell levels of GTP. Since ADP stimulates oxidative phosphorylation, we evaluated the role of mitochondria in mediating the amplification of LH action by adenosine in luteal cells with two mitochondrial inhibitors, oligomycin and dinitrophenol. Both inhibitors markedly reduced, in a dose-dependent manner, LH-stimulated cAMP accumulation in the presence or absence of adenosine. In parallel, both inhibitors decreased basal and adenosine-elevated ATP levels in a dose-related manner. Although late stage luteal cells showed a marked reduction in adenosine amplification of LH-stimulated cAMP accumulation, no change in adenosine-dependent elevation of cell levels of ATP was seen. We conclude that amplification of LH action and elevation of ATP levels in midstage cells by adenosine requires an increase in oxidative phosphorylation that is stimulated by an increase in cell levels of ADP. However, attenuation of adenosine amplification of LH action in late stage luteal cells is not due to impaired ATP production.     

Effects of serum and lipoproteins on steroidogenesis in cultured bovine luteal cells

The effects of serum and lipoproteins on the function of bovine luteal cells in tissue culture were examined. Corpora lutea from regularly cycling dairy cows were dissociated with collagenase and cultured in Ham's F-12 medium with or without serum. The serum-free medium was supplemented with insulin, transferrin and hydrocortisone. Addition of LH to the serum-containing medium did not increase progesterone (P4) production. When the luteal cells were cultured in serum-free medium. LH produced a dose-dependent increase (P less than 0.001) in P4 production during the first 24 h of culture. The responsiveness of the cells to LH then gradually declined, and remained low until days 9-11 of culture, at which time the cells regained their ability to respond to LH. The luteal cells were responsive to dibutyryl cAMP in both serum-containing and serum-free medium. Serum lipoproteins (low and high density) were able to produce a 150-260% increase in progesterone production by the luteal cells cultured in serum-free medium. The results indicate that the presence of serum in the cell culture medium inhibits the responsiveness of luteal cells to LH at a step prior to the increase in cellular cAMP, and that serum lipoproteins can be used to increase progesterone production by cultured bovine luteal cells.     

Stimulation of luteinizing hormone release from chicken pituitary cells by analogues of luteinizing hormone-releasing hormone.

The luteinizing hormone (LH) releasing activities of luteinizing hormone-releasing hormone (LH-RH) and four related analogues were compared using isolated chicken anterior pituitary cells. The analogues, des-Gly¹⁰-LH-RH and Phe⁵-LH-RH, exhibited a greater potency than LH-RH (150 and 237%, respectively), whereas LH-RH(OH) was much less active (1.1%). The potency of Phe⁵-LH-RH was reduced to 0.9% by the insertion of a tyrosine molecule at position 11, indicating that chain length is a significant feature of the biological activity of the molecule. des-Gly¹⁰-LH-RH and Phe⁵-LH-RH were more active in the present system, than is indicated by available information for the rat.     

Differential effects of luteinizing hormone on intracellular free Ca2+ in small and large bovine luteal cells

The effect of LH on the intracellular free Ca2+ concentration ([Ca2+]i) was investigated in highly purified small and large bovine luteal cell populations. Luteal cells were obtained from midcycle corpora lutea dispersed with collagenase and separated by flow cytometry into large and small cells. Resting levels of Ca2+ were higher (P less than 0.05) in the large than small cells [314 +/- 25 nM (n = 5) vs. 186 +/- 13 nM (mean +/- SE; n = 13) for large and small cells, respectively]. LH rapidly increased [Ca2+]i in both small and large cells loaded with the fluorescent Ca2+ probe fura-2. In the small cells, [Ca2+]i was immediately increased 2- to 6-fold (from 176 +/- 8 to 468 +/- 8 nM; n = 5) after adding LH. The LH induced [Ca2+]i rise occurred in two phases: an initial peak due to intracellular Ca2+ mobilization and a secondary rise due to Ca2+ influx from extracellular sources. Preincubation of the small cells with EGTA reduced the initial phase and abolished the secondary rise in [Ca2+]. Both forskolin and 8-bromo-cAMP increased [Ca2+]i in the small cells. In contrast, only a single phase of [Ca2+]i rise was observed in LH-treated large cells, and the response was 1.5- to 2-fold greater than the resting Ca2+ levels [314 +/- 25 vs. 435 +/- 60 nM (n = 4), for resting vs. LH-treated values, respectively]. The addition of both LH and prostaglandin F2 alpha (PGF2 alpha) to the large cells resulted in increases in [Ca2+]i that were greater than those induced by each hormone separately (2.0-fold for LH and 2.7-fold for PGF2 alpha vs. 7- to 9-fold in the presence of both hormones). These findings demonstrate that LH induces rapid increases in intracellular [Ca2+]i that differ in magnitude and profile between the small and large bovine luteal cells. Furthermore, LH and PGF2 alpha interacted to promote increases in [Ca2+]i in the large cells, that were higher than the sum of [Ca2+]i induced by each hormone separately.     

Phorbol ester stimulates progesterone production by isolated bovine luteal cells

The tumor promoter, phorbol 12-myristate-13-acetate (PMA), is known to modulate the response of several steroidogenic tissues presumably by activating a Ca++- and phospholipid-dependent protein kinase (protein kinase C). The presence of this kinase has been demonstrated in bovine corpus luteum, although its role in steroidogenesis by these cells is unknown. We report here the effects of PMA on progesterone production by the enzymically dispersed bovine luteal cells in vitro. PMA (1-50 nM) produced a dose- and time-related increase in progesterone production by the luteal cells. The maximum stimulation was achieved with 10 nM PMA. Higher concentrations of PMA led to a decline of steroidogenesis close to the basal level. A nonpromoting derivative, 4 alpha-phorbol 12,13-didecanoate had no effect. The PMA-induced stimulation of progesterone production was not associated with a change in the cAMP level. PMA added together with suboptimal doses of human CG, 8Br-cAMP, cholera toxin, or forskolin significantly increased the amount of progesterone produced. PMA as well as human CG-induced steroidogenesis was sensitive to cycloheximide inhibition. The conversion of exogenous pregnenolone or 25-hydroxycholesterol to progesterone was not altered by PMA. We conclude that PMA at nanomolar concentrations is able to stimulate progesterone production by bovine luteal cells and that the site of action of PMA is distal to the formation of cAMP but before the formation of pregnenolone. The observed effects of PMA in luteal cells are probably linked to its ability to activate protein kinase C, since a diacylglycerol could mimic the steroidogenic action of PMA.     

Gonadotropin-releasing hormone stimulates phospholipid labeling in cultured granulosa cells

Cultured ovarian granulosa cells from preantral and preovulatory follicles were incubated with [32P]Pi to label endogenous phospholipids. Labeled cells were then incubated with FSH, GnRH, or a GnRH agonist analog [D-Ala6]GnRH (GnRHa), cellular phospholipids were separated by two-dimensional thin layer chromatography, and the radioactivity was determined. Phosphatidylcholine was the major labeled phospholipid accounting for 64% of the total radioactivity. The remaining labeling was distributed among choline plasmalogen (8.4%), phosphatidylinositol (6.3%), lyso phosphatidylcholine (3.7%), phosphatidylethanolamine (3.4%), phosphatidic acid (1.75%), phosphatidylserine (1.65%), and cardiolipin (1.3%). GnRH and its agonist analog GnRHa, but not FSH, increased 32P incorporation into phospholipids by 2-fold. Analysis of the several phospholipids revealed that GnRHa (10(-7) M) increased 32P labeling of phosphatidylcholine and lyso phosphatidylcholine by 1.5- and 2.5-fold respectively, and that of phosphatidic acid and phosphatidylinositol by 5- and 7-fold, respectively, during 60 min of incubation. The natural decapeptide GnRH was 30 times less potent than its agonist analog. Labeling of other phospholipids was not affected by GnRHa treatment, and FSH had no effect on 32P incorporation under similar conditions. The stimulatory effect of GnRHa was blocked by the potent GnRH antagonist [D-pGlu1,pClPhe2, D-Trp3,6]GnRH. The minimal stimulating dose of GnRHa was 10(-12) M, and increased phospholipid labeling could be detected after 10 min of incubation with the analog. These results indicate that phospholipids, in particular phosphatidylinositol and phosphatidic acid, might be involved in the mechanism by which GnRH exerts its gonadal effects.     

Phorbol ester- and luteinizing hormone-induced phosphorylation of membrane proteins in bovine luteal cells

In this study we have investigated the protein phosphorylation pattern in the membrane fraction prepared from bovine luteal cells. The phosphorylation reaction was carried out in vitro, under defined conditions, using either [gamma-32P]ATP or [gamma-35S]ATP as the phosphate donor. The results obtained show that [gamma-35S]ATP was a suitable phosphate donor for performing in vitro phosphorylation studies, and that thiophosphorylation of at least eight protein bands (120 kDa to 18 kDa) was observed. The extent of phosphorylation was dependent upon the duration of incubation and the amount of membrane protein used. The presence of Ca2+ was obligatory for phosphorylation and an enhanced phosphorylation was observed in the presence of Ca2+, phosphatidyl serine and phorbol 12-myristate 13-acetate (PMA), agents known to activate protein kinase C. Interestingly, when phosphorylation was carried out in the presence of luteinizing hormone (LH), a phosphorylation pattern was obtained which was similar to that obtained in the presence of calcium and phospholipid. Furthermore, in the case of two protein bands corresponding to 80-82 and 44-46 kDa, an additive phosphorylation was observed when the phosphorylation reaction was carried out for 5 min in the presence of both LH and Ca2+, phosphatidyl serine and PMA. To conclude, we have demonstrated a calcium- and phospholipid-dependent endogenous protein phosphorylation in the membrane fraction prepared from bovine luteal cells and the data obtained suggest that LH is able to stimulate this endogenous protein phosphorylation via a protein kinase C-mediated mechanism.     

Modulation of luteinizing hormone-stimulated inositol phosphate accumulation by phorbol esters in bovine luteal cells.

The present studies were conducted to evaluate the effects of protein kinase C activators on the inositol phospholipid-phospholipase C second messenger system in isolated bovine luteal cells. This report describes the effects of phorbol esters on inositol phosphate accumulation in LH- and prostaglandin F2 alpha (PGF2 alpha)-stimulated bovine luteal cells. Corpora lutea of early pregnancy were dispersed with collagenase and luteal cells were prelabelled for 3 h with [3H]inositol. Inositol phosphates produced in response to LH or PGF2 alpha were analyzed by ion exchange column chromatography. The tumor promoter and protein kinase C activator 12-O-tetradecanolyphorbol 13-acetate (TPA) had no effect on basal levels of inositol phosphates but inhibited LH-stimulated accumulation of inositol mono-, bis-, and trisphosphates by 72%, 68%, and 65%, respectively. TPA reduced the response to maximally effective concentrations of LH and tripled the concentrations of LH required to evoke half-maximal accumulation of inositol mono-, bis-, trisphosphates. The inhibitory effects of TPA were rapid (5 min) whether added before or after treatment with LH. Treatment with TPA also reduced (58%) the initial phase of intracellular calcium mobilization in LH-treated cells. The inhibitory effects of TPA were not associated with acute reductions in [3H]inositol incorporation, [3H]inositol phospholipid levels, cAMP levels, or progesterone accumulation in control or LH-stimulated luteal cells. The effects of phorbol esters were concentration dependent and specific for active tumor promoters with 10-50 nM TPA producing maximal inhibitory effects. A synthetic diacylglycerol, 1-oleyl-2-acetylglycerol, mimicked the inhibitory effects of TPA. In contrast, pretreatment with a physiological activator of protein kinase C, PGF2 alpha, had no effect on LH-stimulated inositol phosphate accumulation. The inhibitory effects of TPA could not be explained by a generalized inhibition of phospholipase C or G-proteins since the accumulation of inositol phosphates in PGF2 alpha- and NaF-treated cells was not inhibited by TPA. These results demonstrate that tumor promoting phorbol esters modulate the inositol phospholipid-phospholipase C transmembrane signaling system in LH-stimulated bovine luteal cells. The results suggest that phorbol esters may alter the coupling of the LH-receptor complex to phospholipase C. These findings implicate protein kinase C in the regulation of transmembrane signaling in the bovine corpus luteum.     

The morphological transformation and inhibition of growth of bovine luteal cells in tissue culture induced by luteinizing hormone and dibutyryl cyclic AMP.

The luteal cells obtained from bovine corpus luteum by enzymatic treatment have been maintained in tissue culture. When the cells were maintained in the absence of luteinizing hormone or dibutyryl cyclic AMP, they grew parallel to one another and were elongated, thus giving to the culture a fibroblastic appearance. No contact inhibition was observed and the progestin secretion rate was low (3 pg per cell per day). In contrast, when luteinizing hormone or dibutyryl cyclic AMP was present, the cells became polygonal, growing as a monolayer and taking the appearance of epithelial cells. In this case contact inhibition was observed. The rate of progestin secretion was 250 pg per cell per day. As soon as luteinizing hormone or dibutyryl cyclic AMP was removed from the media, the cells reverted to a fibroblastic appearance. Agents such as colcemid, vinblastin or cytochalasin B inhibited the morphological effect of luteinizing hormone or dibutyryl cyclic AMP. Since those agents are known to inhibit the assembly of microtubules, the data suggest that LH and dibutyryl cyclic AMP act by promoting the organization of microtubules from protein monomers. This microtubular system (cytoskeleton) is responsible for the morphological appearance of the cells. Concomitant with the morphological changes induced by luteinizing hormone and dibutyryl cyclic AMP an inhibition in the growth rate of luteal cells was observed. It suggests that by raising the intracellular level of cyclic AMP the luteinizing hormone inhibits the division of luteal cells and is not, for that reason, a mitogenic agent. A similar effect was obtained with other agents known to stimulate cyclic AMP production such asthe prostaglandins. Steroids such as glucocorticoids and testosterone but not progesterone also inhibited the growth rate. It is concluded that luteinizing hormone by controlling the level of cyclic AMP within the luteal cells is responsible for the expression of the phenotype of the cells and the maintenance of differentiation.     

Stimulation of chick adrenal steroidogenesis by avian parathyroid hormone

Dispersed chick adrenocortical cells were incubated with avian parathyroid hormone (aPTH) or ACTH. Accumulation of cyclic AMP (cAMP), activity of cAMP-dependent protein kinase and the secretion of corticosterone and aldosterone, in response to these hormones, were measured. Accumulation of cAMP and activity of cAMP-dependent protein kinase were stimulated by both aPTH and ACTH as well as by cholera toxin. Cyclic AMP production followed a similar time-course when stimulated by either peptide hormone. Stimulation of steroid hormone secretion was detectable after 20 min of incubation with ACTH, but only after 40 min with aPTH. The maximal steroid hormone secretion by adrenocortical cells was similar when induced by either peptide hormone. The aPTH concentrations needed for half-maximal response of corticosterone and aldosterone secretion were higher than those for ACTH (2.5- and 2-fold respectively), but still within the physiological range. The 11 beta-hydroxylase inhibitor metyrapone inhibited the secretion of both corticosterone and aldosterone when induced by either aPTH or ACTH. The results suggest that aPTH is almost as potent as ACTH in stimulating the secretion of corticosterone and aldosterone from chick adrenocortical cells and utilizes a cAMP-dependent pathway similar to that of ACTH.     

Estrogen regulation of steroidogenesis in rabbit luteal cells

Estradiol is a potent modifier of gonadotropin-stimulated steroidogenesis. By the seventh day after ovulation, estradiol is the only agent required for the stimulation of progesterone synthesis by corpora lutea of superovulated pseudo-pregnant rabbits. To learn which control points in steroidogenesis are susceptible to regulation by estradiol alone, we have studied the production of pregnenolone, progesterone, and 20 alpha-hydroxy-4-pregnen-3-one by corpora lutea of estradiol-stimulated and estradiol-deprived pseudopregnant rabbits. In previous investigations, we learned that estradiol deprivation in vivo, on day 9 of pseudopregnancy, causes an abrupt cessation of progesterone and 20 alpha-hydroxy-4-pregnen-3-one production, which is associated with accumulation of cholesterol and cholesteryl ester in the luteal tissue. We now report that production of pregnenolone, measured as its concentration in serum, also decreases abruptly by 84% within 48 h when the estradiol stimulus is removed on day 9 of pseudopregnancy. In addition, short term incubations of luteal tissue demonstrate that corpora lutea from estradiol-deprived rabbits do not use stores of luteal intracellular cholesterol for production of pregnenolone and progestin. These findings suggest that upon estradiol deprivation, rabbit luteal cells lose their capacity for using stored cholesteryl ester, or cholesterol synthesized de novo, for the production of pregnenolone and progestins. We, therefore, tested the hypothesis that a blockade of steroidogenesis caused by estrogen deprivation occurs at the point of cytochrome P-450 cholesterol side-chain cleavage (P-450scc), a principal rate-limiting step in the conversion of cholesterol to hormonal steroid products. To this end, we assayed the P-450scc activity in mitochondria-rich fractions of corpora lutea from rabbits that were deprived of estradiol for 24 and 48 h beginning on day 9 after induction of superovulation. Surprisingly, withdrawal of the estradiol stimulus did not cause loss of luteal P-450scc activity, measured as the amount of aminoglutethimide-inhibitable conversion of 25-hydroxycholesterol to pregnenolone by mitochondria-rich preparations. From these results, we infer that the luteotropic action of estradiol is probably not effected at P-450scc in the rabbit corpus luteum, but, presumably, occurs at control points that regulate the availability of stored cholesterol and/or its movement to or within the mitochondria for conversion to pregnenolone.     

Stimulation of luteinizing hormone release by melittin and phospholipase A2 in rat pituitary cells

Gonadotropin release in rat pituitary monolayer cultures was stimulated by phospholipase A2, as well as by its activator melittin. A dose-dependent stimulation of luteinizing hormone secretion by melittin was observed in a dose range of 10(-8) to 10(-4) M. A higher dose (1 mM) melittin had a sub-optimal effect. The stimulatory action of melittin was calcium-dependent and blocked by phospholipase A2 inhibitors, chloroquine and quinacrine. Similar to melittin, phospholipase A2 enhanced the effect of LH release in a dose range of 0.1-100 units/ml. The effect of this enzyme was also calcium-dependent with optimal calcium concentrations at 1.5 mM, as obtained also for melittin. In superfusion experiments, the stimulatory action of melittin and phospholipase A2 was reproducible in their effects on LH release in gonadotrophs. In addition, melittin (10(-7) M) stimulated LH and 3H-arachidonic acid efflux in superfused pituicytes following prelabelling with radiolabelled arachidonate. These data suggest that phospholipase A2, which releases arachidonic acid from phospholipids, may participate in controlling gonadotropin secretion in gonadotrophs, since arachidonic acid and its metabolites have previously been found to enhance gonadotropin release.