Adenosine facilitates the response to HCG, PGE1 or PGE2 and inhibits the response to PGF2 alpha by HCG-stimulated ovine luteal cells in vitro.

Dispersed ovine luteal cells collected on day 7 or 16 postestrus were incubated in vitro with hCG, PGE1 or PGE2 in the presence or absence of adenosine, dipyridamole (inhibitor of adenosine uptake) or PGF2 alpha in two separate experiments. Secretion of progesterone was increased by hCG, PGE1 or PGE2 when incubated with day 7 luteal cells (P less than or equal to 0.05) which was increased further when co-incubated with adenosine (P less than or equal to 0.05). PGF2 alpha alone or in the presence of hCG decreased (P less than or equal to 0.05) the secretion of progesterone by day 7 luteal cells, PGF2 alpha decreased post treatment cell viability with or without hCG (P less than or equal to 0.05) and adenosine reduced (P less than or equal to 0.05) the inhibitory effect of PGF2 alpha on hCG actions and luteal cell viability. Day 16 luteal cells were not functional based on jugular progesterone (P less than or equal to 0.05) and did not respond to hCG, PGE1, or PGE2 in the presence of adenosine or PGF2 alpha (P greater than or equal to 0.05). It is concluded that adenosine enhances the response of functional luteal cells to the luteotropins hCG, PGE1 or PGE2 and adenosine reduces the luteolytic response to PGF2 alpha by hCG-stimulated ovine luteal cells in vitro.     

Differential steroidogenic responses of ovine luteal cells to ovine luteinizing hormone and human chorionic gonadotropin

Experiments were conducted in vitro on ovine small luteal cells to evaluate their steroidogenic response to ovine luteinizing hormone (oLH) and human chorionic gonadotropin (hCG) administered continuously throughout the experimental period or as a 15-min pulse. Both oLH and hCG stimulated a significant increase in progesterone secretion (P less than 0.001) by small luteal cells. Human chorionic gonadotropin administered continuously or as a pulse maintained progesterone secretion at 40-55% of experimental maximum at least 6 hr while oLH-stimulated progesterone secretion declined to basal levels by 4 hr after a 15-min pulse or declined to 25% of the experimental maximum within 6 hr under constant stimulation. The responses of small luteal cells to oLH and hCG were found to differ (P less than 0.001). The sustained progesterone secretion of luteal cells in response to a pulse of hCG may be due to longer residence of occupied receptor complex on the cell membrane. In contrast, the decline in oLH stimulated progesterone secretion, even when hormone is continuously present in the medium, may be related to a rapid internalization of receptor-hormone complexes and down-regulation of receptors.     

The effects of prostaglandins PGE1, PGE2, PGF1a, and PGF2alpha on canine synovial perfusion.

In these experiments we have examined the effects of PGE1, PGE2, PGF1alpha and PGF2alpha on synovial perfusion in the normal canine synovial microcirculation. The effects of the drugs on synovial perfusion were determined indirectly from the changes produced in the rate of clearance of 133Xenon from the joint by their intra-articular injection. Prostaglandins PGE1 and PGE2 were found to be strongly vasodilator with PGE1 being the more active. PGF1alpha appeared to have little or no vasoactive properties in doses up to 1 ugm. (2.8 times 10(-5M)) in our preparation while PGF2alpha was vasodilator at this high dosage only. Neither SC19920 nor diphloretin phosphate antagonished the effects of PGE1 in these experiments.     

Prostaglandin E1 (PGE1), but not prostaglandin E2 (PGE2), alters luteal and endometrial luteinizing hormone (LH) occupied and unoccupied LH receptors and mRNA for LH receptors in ovine luteal tissue to prevent luteolysis

Loss of luteal progesterone secretion at the end of the ovine estrous cycle is via uterine PGF₂α secretion. However, uterine PGF₂α secretion is not decreased during early pregnancy in ewes. Instead, the embryo imparts a resistance to PGF₂α. Prostaglandins E (PGE; PGE₁ + PGE₂) are increased in endometrium and uterine venous blood during early pregnancy in ewes to prevent luteolysis. Chronic intrauterine infusion of PGE₁ or PGE₂ prevents spontaneous or IUD, estradiol-17β, or PGF₂α-induced premature luteolysis in nonbred ewes. The objective was to determine whether chronic intrauterine infusion of PGE₁ or PGE₂ affected mRNA for LH receptors, occupied and unoccupied receptors for LH in luteal and caruncular endometrium, and luteal function. Ewes received Vehicle, PGE₁, or PGE₂ every 4 h from days 10 to 16 of the estrous cycle via a cathether installed in the uterine lumen ipsilateral to the luteal-containing ovary.Jugular venous blood was collected daily for analysis of progesterone and uterine venous blood was collected on day-16 for analysis of PGF₂α and PGE. Corpora lutea and caruncular endometrium were collected from day-10 preluteolytic control ewes and day-16 ewes treated with Vehicle, PGE₁ or PGE₂ for analysis of the mRNA for LH receptors and occupied and unoccupied receptors for LH. Luteal weights on day-16 in ewes treated with PGE₁ or PGE₂ and day-10 control ewes were similar (P ≥ 0.05), but were greater (P ≤ 0.05) than in day-16 Vehicle-treated ewes. Progesterone profiles on days 10–16 differed (P ≤ 0.05) among treatment groups: PGE₁ > PGE₂ > Vehicle-treated ewes. Concentrations of PGF₂α and PGE in uterine venous plasma on day-16 were similar (P ≥ 0.05) in the three treatment groups. Luteal mRNA for LH receptors and unoccupied and occupied LH receptors were similar (P ≥ 0.05) in day-10 control ewes and day-16 ewes treated with PGE₂ and were lower (P ≤ 0.05) in day-16 Vehicle-treated ewes. PGE₂ prevented loss (P ≤ 0.05) of day-16 luteal mRNA for LH receptors and occupied and unoccupied LH receptors. Luteal and caruncular tissue mRNA for LH receptors and occupied and unoccupied LH receptors were greater (P ≤ 0.05) on day-16 of PGE₁-treated ewes than any treatment group. mRNA for LH receptors and occupied and unoccupied receptors for LH in caruncules were greater (P ≤ 0.05) in day-16 Vehicle or PGE₂-treated ewes than in day-10 control ewes. It is concluded that PGE₁ and PGE₂ share some common mechanisms to prevent luteolysis; however, only PGE₁ increased luteal and endometrial mRNA for LH receptors and occupied and unoccupied LH receptors. PGE₂ prevents a decrease in luteal mRNA for LH receptors and occupied and unoccupied receptors for LH without altering endometrial mRNA for LH receptors or occupied and unoccupied receptors for LH.     

Receptor binding in various tissues of PGE2, PGF2 alpha and sulprostone, a novel PGE2-derivative.

Sulprostone is a tissue-specific PGE2-derivative with high abortifacient activity in various species including man. The dissociation constant KD of the receptor binding of this compound was compared with PGE2 and PGF2 alpha in various tissue preparations of different species. A structure-binding relationship was developed from competition curves after a logit/log transformation. It is demonstrated that the relative affinities of Sulprostone, PGE2 and PGF2 alpha remain essentially constant in all the tissues investigated. It is concluded that the tissue-specificity of Sulprostone cannot be ascribed to structural differences of the receptor molecule.     

Conversion of PGE2 to PGF2alpha by fetal sheep blood

In an attempt to explain the differences in the concentration of primary prostaglandins in the circulation of adult and fetal sheep, we have examined the ability of whole blood from adult and fetal sheep to reduce PGE2 to PGF2alpha in vitro. PGF2alpha was the principal radioactive product formed from 3H PGE2 by both adult and fetal blood. The enzyme initial reaction velocity was significantly higher (P = 0.02) per ml of fetal than adult blood. The optimum enzyme pH (7.0 - 7.5) was similar for both adult and fetal blood. The Km of the enzyme in fetal and adult blood were 3.59 x 10(-7) M and 5.02 x 10(-7) M respectively (P greater than 0.05). There was no detectable metabolism of PGF2alpha by either adult or fetal sheep blood. The results indicate that prostaglandin 9-ketoreductase is present in both adult and fetal sheep blood. Differences in the activity of this enzyme are unlikely to explain the higher concentrations of PGE reported in the plasma of fetal lambs.     

The luteinizing hormone receptor activates phospholipase C via preferential coupling to Gi2.

Binding of lutropin/choriogonadotropin (LH/CG) to its cognate receptor results in the activation of adenylyl cyclase and phospholipase C. This divergent signaling of the LH receptor is based on the independent activation of distinct G protein subfamilies, i.e. , Gs, Gi, and potentially also Gq. To examine the selectivity of LH receptor coupling to phospholipase C beta-activating G proteins, we used an in vivo reconstitution system based on the coexpression of the LH receptor and different G proteins in baculovirus-infected insect cells. In this paper, we describe a refined expression strategy for the LH receptor in insect cells. The receptor protein was inserted into the cell membrane at an expression level of 0.8 pmol/mg of membrane protein. Sf9 cells expressing the LH receptor responded to hCG challenge with a concentration-dependent accumulation of intracellular cAMP (EC50 = 630 nM) but not of inositol phosphates, whereas stimulation of the histamine H1 receptor in Sf9 cells led to increased phospholipase C (PLC) activity. Immunoblotting experiments using G protein-specific antisera revealed the absence of quantitative amounts of alpha i in Sf9 cells, whereas alpha s and alpha q/11 were detected. We therefore attempted to restore the hCG-dependent PLC activation by infection of Sf9 cells with viruses encoding the LH receptor and different G protein alpha subunits. HCG stimulation of cells coexpressing the LH receptor and exogenous alpha i2 resulted in stimulation of PLC activity. In cells coinfected with an alpha i3-baculovirus, hCG challenge led to a minor activation of PLC, whereas no hCG-dependent PLC stimulation was observed in cells coexpressing alpha i1. Most notably, coinfection with baculoviruses encoding alpha q or alpha 11 did not reproduce the PLC activation by the LH receptor. Thus, the murine LH receptor activates adenylyl cyclase via Gs and PLC via selective coupling to Gi2.     

Role of phospholipase C in mediating oxytocin-induced release of prostaglandin F2 alpha from ovine endometrial tissue

Two experiments were conducted to determine if the ability of oxytocin to stimulate release of prostaglandin (PG)F2 alpha from ovine uterine tissue involved activation of phospholipase C (PLC). In the first experiment, 9 ewes were injected with progesterone for 11 d (12 mg/d, im). On days 11 and 12, ewes received an injection of estradiol (100 micrograms, im). Caruncular endometrial tissue was collected on d 13 and incubated in the presence or absence of oxytocin (10(-6) M). Concentrations of PGF2 alpha and its metabolite, 13,14-dihydro-15-keto-PGF2 alpha (PGFM), in culture media were determined by radioimmunoassay. PLC activity was determined by measuring the intracellular accumulation of 3H-inositol phosphates after preincubation with 3H-inositol. Concentrations of PGF2 alpha and total PGF (PGF2 alpha + PGFM) in culture media were greater for explants treated with oxytocin than for controls (p. less than .02, p less than .06, respectively). A similar effect of oxytocin on intracellular concentrations of 3H-inositol phosphates was observed (p less than .01). A second experiment was conducted to determine if agonists of second messengers, produced by activation of PLC, could stimulate release of PGF2 alpha from ovine endometrial tissue. Seven ewes were treated with progesterone and estradiol as in experiment 1. Explants of caruncular tissue from each ewe were incubated with 1) control medium, 2) A23187 (10(-5) M), 3) oxytocin (10(-6) M), 4) phorbol 12-myristate 13-acetate (PMA, 10(-7) M), 5) PMA + A23187 and 6) PMA + oxytocin. Significant stimulatory effects of oxytocin, PMA and A23187 on concentrations of PGF2 alpha and total PGF in culture media were observed (p. less than .05, p less than .1, p less than .1, respectively). In conclusion, oxytocin stimulated release of PGF2 alpha and activity of PLC in explants of ovine endometrial tissue in vitro. Second messengers associated with activation of PLC enhanced release of PGF2 alpha from ovine endometrial tissue.     

Acute suppression by PGF2 alpha on LH, epinephrine and fluoride stimulation of adenylate cyclase in rat luteal tissue.

Injection of PGF2 alpha (250 microgram/rat) 15 min prior to isolation of corpora lutea (CL) from PMSG treated immature rats significantly reduced the LH stimulation of adenylate cyclase in CL membranes. The LH stimulation did not return to normal even 24 h after PGF2 alpha injection. A transient decrease in epinephrine and fluoride stimulation of AC was also observed, the response returning to normal 6-12 h after PGF2 alpha treatment. In vitro incubation of whole isolated CL with 0.005 micrometer or higher concentrations of PGF2 alpha markedly reduced the LH and fluoride stimulation of AC in the CL membranes. Exposure of CL to PGF2 alpha for 15 min in vitro reduced the LH and fluoride response. The results are discussed in relation to the suppressive action of PGF2 alpha on LH receptors in CL, and a mechanism is proposed to explain the discrepancy in time relation between our results and the LH receptor studies. The proposed mechanism might also explain the transient decrease in epinephrine and fluoride stimulation of AC.     

Effects of indomethacin, luteinizing hormone (LH), prostaglandin E2 (PGE2), trilostane, mifepristone, ethamoxytriphetol (MER-25) on secretion of prostaglandin E (PGE), prostaglandin F2alpha (PGF2alpha) and progesterone by ovine corpora lutea of pregnancy or the estrous cycle

Two experiments were conducted to determine the luteotropin of pregnancy in sheep and to examine autocrine and paracrine roles of progesterone and estradiol-17 beta on progesterone secretion by the ovine corpus luteum (CL). Secretion of progesterone per unit mass by day-8 or day-11 CL of the estrous cycle was similar to day-90 CL of pregnancy (P > or = 0.05). In experiment 1, secretion of progesterone in vitro by slices of CL from ewes on day-8 of the estrous cycle was increased (P < or = 0.05) by LH or PGE2. Secretion of progesterone in vitro by CL slices from day-90 pregnant ewes was not affected by LH (P > or = 0.05) while PGE2 increased (P < or = 0.05) secretion of progesterone. Day 8 ovine CL of the estrous cycle did not secrete (P > or = 0.05) detectable quantities of PGF2alpha or PGE while day-90 ovine CL of pregnancy secreted PGE (P < or = 0.05) but not PGF2alpha. Secretion of progesterone and PGE in vitro by day-90 CL of pregnancy was decreased (P < or = 0.05) by indomethacin. The addition of PGE2, but not LH, in combination with indomethacin overcame the decreases in progesterone by indomethacin (P < or = 0.05). In experiment 2, secretion of progesterone in vitro by day-11 CL of the estrous cycle was increased at 4-h (P < or = 0.05) in the absence of treatments. Both day-11 CL of the estrous cycle and day-90 CL of pregnancy secreted detectable quantities of PGE and PGF2alpha (P < or = 0.05). In experiment 1, PGF2alpha secretion by day-8 CL of the estrous cycle and day-90 ovine CL of pregnancy was undetectable, but was detectable in experiment 2 by day-90 CL. Day 90 ovine CL of pregnancy also secreted more PGE than day-11 CL of the estrous cycle (P < or = 0.05), whereas day-8 CL of the estrous cycle did not secrete detectable quantities of PGE (P > or = 0.05). Trilostane, mifepristone, or MER-25 did not affect secretion of progesterone, PGE, or PGF2alpha by day- 11 CL of the estrous cycle or day-90 CL of pregnancy (P > or = 0.05). It is concluded that PGE2, not LH, is the luteotropin at day-90 of pregnancy in sheep and that progesterone does not modify the response to luteotropins. Thus, we found no evidence for an autocrine or paracrine role for progesterone or estradiol-17 36 on luteal secretion of progesterone, PGE or PGF2alpha.     

Effects of prostaglandin E1 or E2 (PGE1; PGE2) on luteal function and binding of luteinizing hormone in nonpregnant ewes

Two studies were conducted to determine the effects of PGE1 or PGE2 on luteal function and binding of luteinizing hormone (LH) to luteal cell membranes in nonpregnant ewes. In Study I, ewes (n=5 per group) received an injection of vehicle (VEH) or 333 micrograms of PGE1 or PGE2 into the tissue surrounding the ovarian vascular pedicle (intrapedicle) on day 7 postestrus. Systemic progesterone concentrations of PGE1-treated ewes were greater (P less than 0.01) than those of VEH-treated ewes at 24 and 48 hr after injection. For PGE2-treated ewes, progesterone concentrations were greater (P less than 0.01) than for VEH-treated ewes only at 24 hr. Neither PGE1 nor PGE2 affected luteal weights or LH binding capacity at 48 hr. Treatment with PGE1, however, increased (P less than 0.10) endogenously bound LH at this time. In Study II, ewes (n=5 per group) received an intrapedicle injection of VEH, or 10 mg of PGE1 or PGE2 on day 8 postestrus. Systemic progesterone concentrations in PGE1-treated ewes were less (P less than 0.01) than for VEH-treated ewes at 24 hr, but by 72 hr were not different from those of VEH-treated ewes. For PGE2-treated ewes, systemic progesterone declined steadily to reach low values by 72 hr. Prostaglandin E2 had no effect on luteal binding of LH at 72 hr, whereas PGE1 increased (P less than 0.05) LH binding capacity and endogenously bound LH. Although PGE2 had no apparent affect on luteal binding of LH in these studies, PGE1 may enhance the function of ovine corpora lutea by stimulating an increase in their binding of LH and capacity to bind LH when the CL receives a luteolytic signal.     

PGE2 and PGF2alpha biosynthesis in stimulated and nonstimulated peritoneal preparations containing macrophages

The biosynthesis of PGE2 and PGF2alpha was measured in intact peritoneal exudate preparations obtained from C. parvum-treated and control C3H mice. Although both the control and stimulated preparations biosynthesized PGF2alpha and PGE2 from [1-14C] arachidonic acid, the stimulated preparations generated more of both prostaglandins than did nonstimulated preparations, probably as a result of increased synthesis within macrophages. Increased transformation of PGE2 into PGF2alpha by PGE2 9-ketoreductase was noted in stimulated preparations when compared to that in control cells. The data suggest that stimulated macrophages are capable of generating increased quantities of PGF2alpha and therefore might function as one source of this substance in resolving inflammatory reactions.     

Expression of alpha subunit and luteinizing hormone beta genes in the ovine anterior pituitary. Estradiol suppresses accumulation of mRNAS for both alpha subunit and luteinizing hormone beta

Bovine cDNA clones containing coding sequences for growth hormone, prolactin, alpha subunit, and luteinizing hormone beta (LH beta) have been used to quantitate their respective mRNA concentrations in anterior pituitary glands isolated from ovariectomized ewes, or from ovariectomized ewes treated for three weeks with estradiol. Concentrations of mRNAs for prolactin or growth hormone remained unchanged in either physiological state. In contrast, treatment with estradiol resulted in a 98% decrease of mRNA for LH beta, relative to untreated animals. This change in mRNA was associated with a similar decrease in the concentrations of pituitary and serum LH. Administration of estradiol also led to a reduction (86%) of alpha subunit mRNA. These results suggest that estrogen regulates the expression of the genes encoding both the alpha and LH beta subunit prior to translation. Furthermore, the pronounced effect of estradiol on the concentrations of mRNAs for alpha subunit and LH beta suggest that the assembly of mature glycoprotein hormones may not be limited solely by the rate of accumulation of the beta subunit.     

Ultrasound and endocrine evaluation of the ovarian response to PGF2alpha given at different stages of the luteal phase in ewes

The purpose of this study was to evaluate the ovarian response of ewes to two treatments with PGF2alpha using transrectal ovarian ultrasonography and hormone measurements. Fifteen milligrams of PGF2alpha was given to six cyclic Western White Face (WWF) ewes early in the estrous cycle (Days 4 to 7) and to six late in the cycle (Days 10 to 12 after ovulation), and a second treatment was given 9 days after the first. Ultrasound scanning and blood sampling started 7 days prior to the first PGF2alpha treatment and ended 10 days (scanning) or 19 days (blood sampling) after the second PGF2alpha treatment, for both groups of ewes. Mean ovulation rate (2.6 +/- 0.7) did not differ significantly between the ewes first treated early or late in the cycle, or after the first or second treatments with PGF2alpha. The time from treatment to ovulation was longer in ewes first treated early (4.0 +/- 0.3 days) compared to late (2.8 +/- 0.4 days) in the cycle (P < 0.05). Both the number of ovulations (range: 0-7) and time from treatment to ovulation (range: 1-9 days) were highly variable. This variability appeared to be due to the extension of the life span of ovulating follicles that emerged prior to PGF2alpha administration and also ovulation of some follicles that emerged after treatment. When results for first and second treatments were pooled, the total number of follicles > 5 mm in diameter on the day of treatment that failed to ovulate in response to PGF2alpha was higher in ewes first treated early (0.8 +/- 0.2/ewe) compared to late (0.3 +/- 0.2/ewe) in the cycle (P < 0.05). The proportion of detected luteal structures relative to the number of ovulations was lower in ewes first treated early compared to late in the cycle (60 and 86%, respectively; P < 0.05). Disruption of ovulatory follicle dynamics and normal luteogenesis, and variability in the timing of ovulation after PGF2alpha treatments could all contribute to poor or variable fertility when prostaglandins are used for estrus synchronization.     

Biophysical studies on molecular mechanism of abortifacient action of prostaglandins. VI. Conformation energy calculation on PGE2, PGF2 alpha and 15-(s)-methyl PGF2 alpha

This paper reports the conformation energy (CE) calculations on PGE2, PGE2 alpha and 15-(s)-methyl PGE2 alpha on the basis of empirical potential energy functions for the simultaneous rotations around C7-C8 (psi), C12-C13 (theta) and C14-C15 (phi) bonds. The variation of the minimum conformation energy E for each isoenergy map in the psi theta plane with respect to phi gives two minima around 90 degrees and 240 degrees in PGE2, 60 degrees and 245 degrees in PGF2 alpha, and 60 degrees and 150 degrees in 15-(s)-methyl PGF2 alpha. The latter two forms also have a small dip at 270 degrees. The pattern of allowed low energy conformations of PGF2 alpha and 15-(s)-methyl PGF2 alpha is quite similar and is characterized by the existence of six low energy regions.     

Prostaglandin F2 alpha, oxytocin and progesterone secretion by bovine luteal cells at several stages of luteal development: effects of oxytocin, luteinizing hormone, prostaglandin F2 alpha and estradiol-17 beta

Bovine luteal cells from Days 4, 8, 14 and 18 of the estrous cycle were incubated for 2 h (1 x 10(5) cells/ml) in serum-free media with one or a combination of treatments [control (no hormone), prostaglandin F2 alpha (PGF), oxytocin (OT), estradiol-17 beta (E) or luteinizing hormone (LH)]. Luteal cell conditioned media were then assayed by RIA for progesterone (P), PGF, and OT. Basal secretion of PGF on Days 4, 8, 14 and 18 was 173.8 +/- 66.2, 111.1 +/- 37.8, 57.7 +/- 15.4 and 124.3 +/- 29.9 pg/ml, respectively. Basal release of OT and P was greater on Day 4 (P less than 0.01) than on Day 8, 14 and 18 (OT: 17.5 +/- 2.6 versus 5.6 +/- 0.7, 6.0 +/- 1.4 and 3.1 +/- 0.4 pg/ml; P: 138.9 +/- 19.5 versus 23.2 +/- 7.5, 35.4 +/- 6.5 and 43.6 +/- 8.1 ng/ml, respectively). Oxytocin increased (P less than 0.01) PGF release by luteal cells compared with control cultures irrespective of day of estrous cycle. Estradiol-17 beta stimulated (P less than 0.05) PGF secretion on Days 8, 14 and 18, and LH increased (P less than 0.01) PGF production only on Day 14. Prostaglandin F2 alpha, E and LH had no effect on OT release by luteal cells from any day. Luteinizing hormone alone or in combination with PGF, OT or E increased (P less than 0.01) P secretion by cells from Days 8, 14 and 18. However on Day 8, a combination of PGF + OT and PGF + E decreased (P less than 0.05) LH-stimulated P secretion. These data demonstrate that OT stimulates PGF secretion by bovine luteal cells in vitro. In addition, LH and E also stimulate PGF release but effects may vary with stage of estrous cycle.