Effect of prostaglandins on the steroidogenesis in human ovarian tissues

Although prostaglandins are luteolytic in some species, in conditions they stimulate progesterone production in the corpus luteum (1). Apart from this effect prostaglandins may also stimulate other steps in the steroidogenic sequence e.g. corticosteroidogenesis in superfused rat adrenal glands (2) and aromatization of testosterone by perfused human placenta (3). With this possibility in view and also because of paucity of data on the effect of prostaglandins on steroidogenesis in human ovarian tissues we have been studying under conditions the effect of prostaglandins on progesterone formation in human corpora lutea and on the utilization of C₂₁ steroids by the luteal and follicular compartments of the ovary. These studies are still in progress. However, the data obtained so far indicates that in addition to stimulating progesterone synthesis in the corpus luteum prostaglandins may also affect other steps in steroidogenesis in human ovarian tissues. We wish to report here in brief these preliminary results.     

Prostaglandins and in vitro ovarian progestin biosynthesis

Prostaglandin F_2α (PGF_2α) did not alter the $\text{in vitro}$ biosynthesis of progesterone by slices of luteinized rat ovaries when used in concentrations from 1 to 10,000 ng/ml of incubation medium; likewise, PGF_2α did not affect the incorporation of acetate-1-¹⁴C into progestins. PGF_1α, 15-keto PGF_2α, and PGE₁ did not alter the biosynthesis of progesterone by luteinized rat ovaries; PGE₂ inhibited the production of progesterone when used at a concentration of 10 μg/ml, but not at lower doses. PGF_2α in combination with luteinizing hormone (LH) enhanced the metabolism of progesterone to 20α-hydroxypregn-4-en-3-one in luteinized rat ovaries. Interestingly, PGF_2α, at a high concentration of 10 μg/ml, did stimulate progesterone biosynthesis by slices of ovarian tissue from immature rats hormonally primed to simulate “pseudopregnancy,” suggesting a steroidogenic action of prostaglandins on the ovarian follicular or interstitial cell. PGF_2α (10 μg/ml) did not stimulate the $\text{in vitro}$ biosynthesis of progesterone or 20α-hydroxypregn-4-en-3-one by slices of rabbit corpora lutea or rabbit ovarian interstitial tissue. It is concluded that prostaglandins do not stimulate progestin biosynthesis in rat luteal tissue.     

Interactions of prostaglandins with subpopulations of ovine luteal cells. I. Stimulatory effects of prostaglandins E1, E2 and I21

Preparations of small and large steroidogenic cells from enzymatically dispersed ovine corpora lutea were utilized to study the $\text{in}$$\text{vitro}$ effects of luteinizing hormone (LH) and prostaglandins (PG) E₁, E₂ and I₂. Cells were allowed to attach to culture dishes overnight and were incubated with either LH (100 ng/ml), PGE₂, PGE₂, or PGI₂ (250 ng/ml each). The secretion of progesterone by large cells was stimulated by all prostaglandins tested (P < 0.05) while the moderate stimulation observed after LH treatment was attributable to contamination of the large cell population with small cells. Prostaglandins E₁ and E₂ had no effect on progesterone secretion by small cells, while LH was stimulatory at all times (0.5 to 4 hr) and PGI₂ was stimulatory by 4 hr. Additional studies were conducted to determine if the effects of PGE₂ upon steroidogenesis in large cells were correlated with stimulated activity of adenylate cyclase. In both plated and suspended cells PGE₂ caused an increase (P < 0.05) in the rate of progesterone secretion but had no effect upon the activity of adenylate cyclase or cAMP concentrations within cells or in the incubation media. Exposure of luteal cells to forskolin, a nonhormonal stimulator of adenylate cyclase, resulted in marked increases in all parameters of cyclase activity but had no effect on progesterone secretion. These data suggest that the actions of prostaglandins E₁, E₂ and I₂ are directed primarily toward the large cells of the ovine corpus luteum and cast doubt upon the role of adenylate cyclase as the sole intermediary in regulation of progesterone secretion in this cell type.     

In. vitro evaluation of corpus luteum function of cycling and pregnant rhesus monkeys: Progesterone production by dispersed luteal cells

Corpus luteum function in the cycling and the pregnant rhesus monkey (Macaca mulatta) was evaluated through short term $\text{in vitro}$ studies of progesterone production by suspensions of collagenase-dispersed luteal cells in the presence and absence of exogenous gonadotropin (human chortonic gonadotropin, HCG). Cells from mid-luteal phase of the menstrual cycle secreted progesterone, as measured by accumulation of this hormone in the incubation medium, and responded to the addition of 100 ng HCG/ml with a marked increase in progesterone secretion above basal level ($\text{63.7 ± 13.1}\text{versus}\text{24.7 ± 5.5}\text{ng progesterone}\text{/}\text{ml}\text{/5 × 10}{}^4\text{cells}\text{/ 3}\text{hr}\text{,}\text{X}\text{± S.E.,}\text{n}\text{= 6;}\text{p}\text{< 0.05}$). However, luteal cells from early pregnancy (23–26 days after fertilization) secreted significantly less progesterone than cells of the non-fertile menstrual cycle (3.6 ± 2.4 versus 24.7 ± 5.5 ng/ml/5 × 10⁴ cells/3 hr, n = 3; p < 0.05) and did not respond to HCG with enhanced secretion. By mid-pregnancy (108–118 days gestation) luteal cells exhibited partially renewed function, and near the time of parturition (163–166 days gestation) basal and HCG-stimulated progesterone secretion (30.2 ± 5.6 and 63.0 ± 13.0 ng/ml/5 × 10⁴ cells/3 hr, respectively; n = 3) was equivalent to that of cells from the luteal phase of the non-fertile menstrual cycle. The data suggest that following a period around the fourth week of gestation, when steroidogenic activity is markedly diminished, the corpus luteum of pregnancy progressively reacquires its functional capacity and at term exhibits gonadotropin-sensitive steroidogenesis similar to that of the corpus luteum of the menstrual cycle.     

Lipid metabolism and in vitro production of progesterone and prostaglandin F during induced regression of porcine corpora lutea

The effects of Cloprostenol administration on porcine luteal lipid and arachidonic acid accumulation were examined in relation to luteal $\text{in vitro}$ progesterone and prostaglandin F synthesis in 18 mature gilts at day 12 of the estrous cycle. Basal and net $\text{in vitro}$ release of progesterone from luteal tissue was depressed at 8 hr after treatment whereas net $\text{in vitro}$ release of prostaglandin F was elevated at 8 hr. Inclusion of copper dithiothreitol or reduced glutathione in the incubation media resulted in minor alterations of $\text{in vitro}$ release of progesterone and prostaglandin F and no changes in composition of luteal lipids or fatty acids. Luteal contents of triglyceride had increased by 8 hr after treatment whereas contents of free and esterified cholesterols had increased by 32 hr after Cloprostenol administration. Luteal contents of phospholipid and free fatty acids were not affected by Cloprostenol administration. At 32 hr after treatment, percentages and content of arachidonic acid had increased in luteal cholesterol esters and triglycerides. Although arachidonic acid percentages increased in luteal free fatty acids and phospholipids, calculated arachidonic acid contents did not change following Cloprostenol administration. Induced luteal regression was associated with decreased $\text{in vitro}$ progesterone release, increased $\text{in vitro}$ prostaglandin F release, and accelerated lipid and arachidonic acid accumulation within the corpus luteum. The effects of altered lipid metabolism on release of prostaglandin F could not be defined. However, availability of arachidonic acid did not appear to be rate-limiting in relation to luteal $\text{in vitro}$ prostaglandin F synthesis.     

Effect on an antagonistic analog of gonadotropin releasing hormone upon ovarian granulosa cell function.

We have recently demonstrated that gonadotropin releasing hormone (GnRH) acts directly on ovarian granulosa cells to inhibit the follicle stimulating hormone (FSH)-induced increase in granulosa cell steroidogenesis $\text{in}$$\text{vitro}$. A GnRH antagonist, [D-pGlu¹, D-Phe², D-Trp^3,6] GnRH (A), which is known to antagonize GnRH-stimulated gonadotropin release by cultured pituitary cells, was tested in the granulosa cell system. GnRH (10^?8M) inhibited estrogen and progesterone production by FSH-treated granulosa cells $\text{in}$$\text{vitro}$, whereas the antagonist A (10^?6M) did not affect FSH stimulation of steroidogenesis. Antagonist A, when added together with GnRH and FSH, blocked the GnRH inhibition of FSH-induced steroidogenesis. Estrogen and progesterone production by granulosa cells was increased by 50% at a molar ratio (IDR₅₀) of $\text{20}\text{1}\text{and}\text{12}\text{1}$ ([antagonist]/[GnRH]), respectively. At 10^?6M, antagonist A completely prevented the GnRH (10^?8M) inhibition. A similar effect of antagonist A was seen in FSH-induced increase of luteinizing hormone (LH) receptor content. FSH treatment for 2 days $\text{in}$$\text{vitro}$ induced an 8-fold increase in LH receptor content in cultured granulosa cells; concomitant treatment with 10^?8M GnRH completely inhibited the FSH effect. Antagonist A (10^?6M), by itself, had no effect on the FSH action. However, when added together with FSH and GnRH, antagonist A completely abolished the inhibitory effect of GnRH. These results demonstrate that the direct inhibitory effect of GnRH on granulosa cell function can be prevented by a GnRH antagonist and that the GnRH action at the ovarian level may require stringent stereospecific interactions of these peptides with putative GnRH recognition sites.     

The effects of prostacyclin (PGI2) and 6-keto-PGF1α on bovine plasma progesterone and LH concentrations

Injections of 1 mg PGI₂ directly into the bovine corpus luteum significantly increased peripheral plasma progesterone concentrations within 5 min. Concentrations were higher in the PGI₂-treated heifers than in saline-injected controls between 5 and 150 min and at 3.5, 4, 5, and 7 h post-treatment. Levels tended to remain elevated through 14 h. Saline and 6-keto-PGF_1α were without effect on plasma progesterone levels. The luteotrophic effect of PGI₂ was not due to alterations in circulating LH concentrations. An $\text{in vitro}$ experiment assessed the effects of either PGI₂ alone or in combination with LH on progesterone production by dispersed luteal cells. Progesterone accumulation over 2 h for control, 5 ng LH, 1 μg PGI₂, 10 μg PGI₂, and 10 μg PGI₂ plus 5 ng LH averaged 99 ± 42, 353 ± 70, 152 ± 35, 252 ± 45, and 287 ± 66 ng/ml (n=4), respectively. Thus PGI₂ has luteotrophic effects on the bovine CL both $\text{in vivo}$ and $\text{in vitro}$.     

Effects of prostaglandins on the affinity of hemoglobin for oxygen in human whole blood in vitro

The effect of prostaglandin on the affinity of hemoglobin for oxygen was tested on human blood $\text{in vitro}$, using six different prostaglandins at several dosage levels in fresh heparinized blood from normal donors and in stored citrated blood, and using prostaglandin E₂ on the blood from four seriously ill patients. No significant alterations in the affinity of hemoglobin for oxygen were dtected. A very small decrease in oxygen affinity in stored blood with high doses of prostaglandin was not statistically significant and would be of no physiologic significance even if real.We conclude that under the circumstances of this experiment prostaglandins do not alter the affinity of hemoglobin for oxygen in human whole blood $\text{in vitro}$.     

Corpus luteum regression induced by ultra-low pulses of prostaglandin F2α

In view of the pulsatile nature of PGF_2α secretion from the ovine uterus at the time of luteolysis, experiments were designed to examine the effect of pulsed infusions of PGF_2α on luteal function and to re-examine the minimal effective levels of PGF_2α required to induce luteolysis. To mimic physiological conditions, hour-long infusions of PGF_2α in increasing concentrations were given either 4 times in 19 h or 5 times in 25 h into the arterial supply of the autotransplanted ovary in conscious sheep on day 12 of an induced cycle. Blood flow and progesterone secretion rate from the ovary were used to monitor directly the luteolytic effect of administered PGF_2α. The concentration of LH in peripheral plasma was measured throughout each infusion experiment and the presence of a preovulatory peak of LH was used as an indicator of the permanence of luteal regression. Four pulses of PGF_2α in 19 h caused complete corpus luteum regression in only 1 of 4 animals whereas the addition of a fifth pulse (5 pulses in 25 h) caused permanent regression in 4 out of 4 animals. Infusion of 5 hour-long pulses of saline or PGF_2α at a rate of <0.04 μg/h did not induce permanent suppression of progesterone secretion. The average total effective dose of PGF_2α required to induced luteal regression when given as 5 pulses was 1/40th of the amount currently regarded as the minimal effective one when given by constant infusion into the ovarian artery. In another series of experiments the luteolytic effect of a single hour-long pulse of 0.1 μg/h PGF_2α given daily for either 3 or 4 days was investigated. A significant fall (ANOVA, F_0.01) in progesterone secretion rate, which reached a nadir at $\text{5.3 ± 2.2}\text{h (}\text{x}\text{±}\text{S.D.}\text{, n=15)}$, was followed by a recovery of progesterone secretion rate. Permanent luteal regression did not occur with this protracted regimen, suggesting that a relatively short pulse frequency of PGF_2α over a minimal period of 24 h is a necessary condition for physiological regression of the corpus luteum in sheep.     

Effect of ovarian hormone pretreatment on gallbladder motility in vitro

Adult male guinea pigs were pretreated with estrogen, progesterone, or estrogen plus progesterone and the $\text{in vitro}$ contractile response of the gallbladder to cholinergic stimulation examined. The data were compared with results obtained from control animals. Progesterone pretreatment was associated with a significant decrease in the maximal contractile response of the tissues and with a significant increase in the dose of acetylcholine needed to produce a threshold response. Estrogen pretreatment significantly decreased the threshold dose requirements but had no effect on maximum tension development. In addition, estrogen pretreatment antagonized the inhibitory effect of progesterone pretreatment. The data support the hypothesis that the ovarian steroid hormones can affect gastrointestinal smooth muscle. Furthermore, the hormones appear to exert independent and opposite effects on gallbladder motility. Additional studies will be required to determine the physiological significance of these observations.     

Prostaglandins and inflammation: Enhancement of monocyte chemotactic responsiveness by prostaglandin E2

The effects of prostaglandins on human monocyte chemotaxis were studied $\text{in vitro}$. None of the prostaglandins tested, including members of the A, B, E or F series, were chemotactic for monocytes. Prostaglandin E₂ however, enhanced the chemotactic responsiveness of monocytes to complement - activated human serum by almost 200%. The enhancement of chemotaxis was not directly related to the ability of PGE₂ to raise intracellular cyclic AMP levels. These studies support a role for prostaglandins as modulators of the inflammatory response.     

Prostaglandin-induced enhancement of the in vitro anamnestic response

The ability of various prostaglandins (PGs) to affect the $\text{in vitro}$ anamnestic immune response of keyhole limpet hemocyanin (KLH)-primed rabbit popliteal lymph node cells was investigated. Of the four PGs studied (PGA₁, PGE₂ and PGF_2α), PGE₁ was found to have a stimulatory effect, whereas PGA₁, PGE₂ and PGF_2α were ineffective in stimulating or inhibiting the $\text{in vitro}$ anamnestic response. Under the conditions studied, a 3.5-fold increase in antibody production was obtained in PGE₁-treated, KLH-stimulated cultures. Maximum enhancement was obtained when 0.2 μg of PGE₁ were added at the time of culture initiation and were allowed to remain in contact with the lymph node cells for 24 hours.     

Role of prostaglandin F2α in modulation of LH-stimulated steroidogenesis in vitro in different types of rat and ewe corpora lutea

An inhibitory effect of PGF_2α at a dose of 7 × 10^?7 M on LH stimulated synthesis of progesterone was observed $\text{in vitro}$ after incubation of pseudopregnant rat ovaries for a period of 2 hours. A similar effect was seen with cyclic and gestant ewe corpora lutea at the same dose of PGF_2α. This effect was observed both in the secretion of progesterone and on the amount of progesterone present in the tissue. This inhibitory effect of PGF_2α on LH stimulated progesterone synthesis may explain the modification in the time course for gonadotropin action in luteal tissue at high and low doses.     

Trilostane,an orally active inhibitor of steroid biosynthesis

Trilostane is a competitive inhibitor of 3β-hydroxysteroid dehydrogenase. $\text{In}$$\text{vitro}$, the drug inhibits conversion of pregnenolone to progesterone but does not alter conversion of cholesterol to pregnenolone nor progesterone to corticoid hormones. When given orally to rats, trilostane inhibits corticosterone and aldosterone production and elevates circulating levels of pregnenolone at doses lower than those that produce adrenal hypertrophy or inhibit gonadal steroidogenesis.     

Conversion of cholesterol to progesterone by turtle corpus luteum

Homogenates of corpora lutea from the snapping turtle, $\text{Chelydra}$$\text{serpentina serpentina}$ were capable of converting small (< 1%) amounts of cholesterol-³H to progesterone-³H. There was about twice as much steroidogenic activity in corpora lutea taken from animals still carrying oviducal eggs as in those from animals that had laid their eggs. However, the latter showed up to an 80% increase in conversion of cholesterol to progesterone when turtle pituitary homogenate was incubated along with the luteal homogenate. Approximately 4 and 9 mg/g of free and esterified sterol, respectively, were found in the turtle corpus luteum. These results suggest that the corpus luteum of the oviparous turtle functions as a steroidogenic organ.     

Assessment of possible luteolytic effect of intra-ovarian injection of prostaglandin F2α in the human

A group of five patients awaiting laparoscopic tubal diathermy were followed by daily assay of luteinising hormone (LH) and progesterone. Between five and eight days after the LH peak, prostaglandin F_2α (PGF_2α) was injected into either the corpus luteum or the ovarian stroma. Doses of 100 μg into the corpus luteum, 1000 μg into the adjacent stroma and 500 μg into an indeterminate ovarian structure had no effect on peripheral plasma progesterone levels or uterine bleeding.An injection of 500 μg or 1000 μg given unequivocally into the corpus luteum produced a rapid and profound fall in plasma progesterone levels, the nadir coinciding with the onset of uterine bleeding which commenced 24 hours after the injection and persisted for more than seven days. Injection of 100 μg in the same volume of saline had no such effect. Despite continued bleeding plasma progesterone levels returned to normal luteal levels for three days and then fell again.     

Interactions of prostaglandins with subpopulations of ovine luteal cells. I. Stimulatory effects of prostaglandins E1, E2 and I2

Preparations of small and large steroidogenic cells from enzymatically dispersed ovine corpora lutea were utilized to study the effects of luteinizing hormone (LH) and prostaglandins (PG) E₁, E₂ and I₂. Cells were allowed to attach to culture dishes overnight and were incubated with either LH (100 ng/ml), PGE₂, PGE₂, or PGI₂ (250 ng/ml each). The secretion of progesterone by large cells was stimulated by all prostaglandins tested (P < 0.05) while the moderate stimulation observed after LH treatment was attributable to contamination of the large cell population with small cells. Prostaglandins E₁ and E₂ had no effect on progesterone secretion by small cells, while LH was stimulatory at all times (0.5 to 4 hr) and PGI₂ was stimulatory by 4 hr. Additional studies were conducted to determine if the effects of PGE₂ upon steroidogenesis in large cells were correlated with stimulated activity of adenylate cyclase. In both plated and suspended cells PGE₂ caused an increase (P < 0.05) in the rate of progesterone secretion but had no effect upon the activity of adenylate cyclase or cAMP concentrations within cells or in the incubation media. Exposure of luteal cells to forskolin, a nonhormonal stimulator of adenylate cyclase, resulted in marked increases in all parameters of cyclase activity but had no effect on progesterone secretion. These data suggest that the actions of prostaglandins E₁, E₂ and I₂ are directed primarily toward the large cells of the ovine corpus luteum and cast doubt upon the role of adenylate cyclase as the sole intermediary in regulation of progesterone secretion in this cell type.     

Danazol inhibits human adrenal 21-and 11β-hydroxylation invitro

The effects of danazol on steroidogenesis $\text{in}$$\text{vitro}$ in the 16–20 week old human fetal adrenal were examined by studying: 1) danazol binding to adrenal microsomal and mitochondrial cytochrome P-450, and 2) enzyme kinetics of danazol inhibition of the adrenal microsomal 21-hydroxylase and the mitochondrial llβ-hydroxylase. The addition of danazol to preparations of adrenal microsomes or mitochondria elicited a type I cytochrome P-450 binding spectrum. Danazol bound to microsomal cytochrome P-450 with a high affinity apparent spectral dissociation constant (Kg) of 1 μM and with a lower affinity K's of 10 μM. Danazol bound to mitochondrial cytochrome P-450 with a Kg of 5 μM. In addition, danazol competitively inhibited the microsomal 21-hydroxylase (apparent enzymatic inhibition constant K_I = 0.8 μM) and the mitochondrial 11β-hydroxylase (K_I = 3 μM). These findings demonstrate that low concentrations of danazol directly inhibit steroidogenesis in the human fetal adrenal $\text{in}$$\text{vitro}$.     

Biosynthesis of prostaglandins in human ovarian tissues

Experiments in vitro demonstrate, that there are different patterns of PG-biosynthesis in the corpus luteum and in the follicles containing cortical substance of the human ovary. In the follicles 6-keto-F₁α. the transformation product of prostacyclin, is the main fraction; prostaglandins F₂α and E 2 being of inferior importance with regard to their amounts. The formation of the corpus luteum is in close correlation with a strongly increased prostaglandin E₂ and a diminished prostacyclin biosynthesis; prostaglandin F₂α hardly seems to be involved in this process.By means of indomethacin the formation of all three examined prostaglandins can be prevented almost completely, in the cortical substance as well as in the corpus luteum. LH (or HCG) at concentrations ranging from 2 ng to 20 μg per ml homogenate produce no stimulating effect of statistical significance on the rate of biosynthesis in both tissues.     

Effect of prostaglandin E2 on vascular responses of the rabbit kidney to nerve stimulation and noradrenaline, in vitro and in situ

The effect of prostaglandin E₂ on vascular responses of the rabbit kidney to renal nerve stimulation and noradrenaline was examined $\text{in}$$\text{vitro}$ and $\text{in}$$\text{situ}$ as a test of the hypthesis that prostaglandins of the E series may be involved in the regulation of adrenergic neuroeffector transmission. Intraarterial administration of prostaglandin E₂ to the $\text{in}$$\text{vitro}$ kidney caused marked inhibition of vascular responses to nerve stimulation whereas the responses to noradrenaline were not significantly altered. In the $\text{in}$$\text{situ}$ preparation, vascular responses to both nerve stimulation and noradrenaline were inhibited by prostaglandin E₂ infusion, although its effect on responses to nerve stimulation was approximately twice that observed on responses to noradrenaline.It is concluded that prostaglandin E₂ acts primarily at a prejunctional level of adrenergic neuroeffector transmission in the kidney, although a postjunctional effect has also been observed.