Prostaglandin release by slow reacting substance from guinea pig and human lung tissue.

Slow reacting substance (SRS) injected into the pulmonary artery released prostaglandins E (PGE) and F2alpha (PGF2alpha) and the 15-keto-13, 14-dihydro PG metabolites from non-sensitized and ovalbumin sensitized, isolated, perfused guinea pig lungs. PGs were also released from lungs incubated with SRS. Sensitized lungs released more PGs in both types of preparations. Indomethacin inhibited the effect of SRS. Passively sensitized human lung fragments, in parallel to guinea pig lung, released PGE, PGF2alpha and the metabolites when incubated with SRS or antigen. In in vivo experiments, SRS and arachidonic acid given intravenously increased the airway insufflation pressure in anesthetized quinea pigs. These effects, but not the action of injected PGF2alpha and histamine, were abolished by indomethacin. The results indicate that one of the modes of SRS action is by release of PGs, and are consistent with the hypothesis that PGs are predominantly "secondary" mediators (in the temporal sense) of the antigen-antibody reaction.     

Prostaglandin E2 and F2 alpha in mid-pregnant rat uterus and at parturition

Prostaglandin E2 (PGE2) and F2 alpha (PGF2 alpha) produced by 15 days pregnant rat myometrium, by parturient rat myometrium and myometrium plus endometrium were measured in vitro. The results showed that the PGs produced by parturient myometrium were higher than these obtained during mid-pregnancy. Myometrium with endometrium released more PGs than myometrium alone, and the addition of arachidonic acid (AA) at 10 DM did not show any significant effect. Exogenous progesterone or estradiol-17b at a concentration of 1 Dmol had no effect on parturient uterine PG secretions.     

Studies on the mechanism of action of antifertile PG in animal models

Antifertile effects of PGF2 alpha, PGE2, PGE1, sulprostone and other PGs were evaluated in different pregnancy models in rats, guinea pigs and rhesus monkeys and the underlying mechanisms of action were investigated. Quantitative and qualitative species differences and pregnancy stage dependency were recorded. Basic regulatory differences of the pregnant uterus seem to exist in these species. In early pregnant rats, abortifacient effects were based on luteolytic effects, independent of the PG used. The myometrium was found to be refractory to the injected PG as long as serum progesterone levels were kept high. By contrast, in guinea pigs after the luteoplacental shift of progesterone secretion (tested after day 40 p.c.) and in rhesus monkeys even before this shift (tested day 20 p.c.) abortifacient effects were found to be exerted by direct stimulation of the myometrium. Uterine stimulation was possible in the presence of any level of serum progesterone. The induction of uterine PG synthesis was probably of importance supporting the expulsion. The role of obvious tissue damage within the conceptus remained uncertain. In contrast to rats there seems to be a pre-existing PG-sensitivity of the pregnant myometrium in guinea pigs and primates. In guinea pigs sensitivity slightly increased for E- but not for F-type PG toward term. Oxytocin sensitivity was found to increase by a factor of more than 100 between days 23-63 of pregnancy. Time dependent changes in uterine receptivity to PG and oxytocin may be considered as a regulatory principle which might permit parturition to occur in the presence of progesterone as an evolutionary adaptation to a placental progesterone secretion which cannot be abolished. It was concluded that in the presence of already established gradual uterine responsiveness to PG (and Oxytocin) during gestation efficient blocking mechanisms for uterine PG-formation must exist in order to explain uterine quiescence. Almost complete resistance of pregnancy to oestrogen which exists in humans, monkeys and guinea pigs was considered as to be pharmacological evidence of such a mechanism. The principles of endocrine control of the myometrium and its pharmacology seem similar in guinea pig and primate pregnancy. The guinea pig might therefore provide a relevant model to study potential drug effects on the regulatory balance of the pregnant uterus and also to achieve a better understanding of human uterine physiology.     

Evidence for the involvement of prostaglandins throughout the decidual cell reaction in the rat

Previous studies in which prostaglandin (PG) production was inhibited for a limited time by the s.c. administration of indomethacin have suggested that PGs are involved in the initiation of decidualization as well as the growth and differentiation of decidual cells. To reduce PG production during decidualization, in the present study indomethacin was infused from Alzet osmotic minipumps into the uterine lumen of ovariectomized rats with uteri sensitized for decidualization. To determine the effect of route of indomethacin administration on decidualization, rats received a single s.c. injection of indomethacin or its vehicle, and unilateral intrauterine infusion of indomethacin or its vehicle, in a factorial experiment. The inhibitory effects on decidualization, as assessed 5 days later by uterine weights, were greatest when both treatments were combined. Prostaglandins E and F concentrations 24 and 48 h after the insertion of the pumps were lower in the indomethacin-infused horns, suggesting that the indomethacin reduced uterine PG production. By contrast, subcutaneously administered indomethacin reduced uterine PG concentrations at 24 h but not at 48 h. Prostaglandin E2 and PGF2 alpha alone or combined, infused with indomethacin into the uterine lumen of rats treated subcutaneously with indomethacin, overrode the inhibitory effects of indomethacin. The dose-response relationships between these PGs and decidualization did not differ. These data suggest that PGs are required during the growth and differentiation of decidual cells from endometrial stromal cells.     

Prostaglandin translocation from the lumen of the rabbit uterus in vitro in relation to day of pregnancy or pseudopregnancy

Transport of 3H-labeled prostaglandins (PGs) E2 and F2 alpha from the uterine lumen across the uterine wall has been studied in rabbit uteri in vitro in incubations lasting up to 180 min, in relation to sexual state of the rabbit, incubation temperature, intraluminal PG concentration, addition of metabolic inhibitors and time of incubation. PG accumulation by the tissue increased rapidly up to 30 min and then remained relatively constant. By 30 min, radioactivity was found in the external incubation medium, and this increased linearly with time. The translocation of PGF2 alpha was significantly greater in pseudopregnant than in pregnant animals on Day 6, whereas that of PGE2 was significantly higher in pregnant than in pseudopregnant animals on Day 6.8. In pregnant animals, both PGF2 alpha and PGE2 were translocated to the exterior more rapidly on Day 6.8 than on Days 5 or 6. Transport of PGs was reduced by low temperature, unaffected by metabolic inhibitors and only that of PGE2 increased with increased (5 microM) intraluminal concentrations. During incubation, the tissue remained viable as judged by T/M ratios (dpm tissue/dpm medium) for 204 thallium. Transport of [14C] sucrose was much slower than that of [14C] urea, which was greater than the fastest rates exhibited by the PGs. In general, amounts of radioactivity found in antimesometrial, mesometrial and lateral portions of the uterine wall, or in implantation and interimplantation areas did not differ, but more was found in the endometrium than the myometrium. PGF2 alpha was translocated unmetabolized to the external medium, while only two-thirds of the PGE2 was translocated unchanged, and one-third converted to PGF2 alpha. It is concluded that the rabbit uterus shows some selectivity in handling PGs in relation to stage of pregnancy.     

Follicular and uterine prostaglandin levels in relation to uterine contraction and the first ovulation of a sequence in the hen

Changes in the concentration of progesterone, estrone, estradiol, prostaglandins (PG) E2, 6-keto F1 alpha and 13,14-dihydro-15-keto F2 alpha (PGFM) were measured in peripheral plasma, and in venous effluent from the shell gland and the largest (F1) and the second largest (F2) preovulatory follicles. Tissue concentrations in the F1, F2 and the most recently ruptured follicle and the shell gland also were determined. Changes in these criteria were compared to changes in uterine contraction before the first ovulation of a sequence. Significant increases of PGF2 alpha and PGFM in the peripheral plasma were observed when the frequency of uterine contraction reached a maximum, about 1 h before ovulation. Relative to peripheral plasma, the concentrations in F1 plasma of progesterone, PGF2 alpha and PGFM were increased 20-fold, 150-fold and 15-fold, respectively, at the time of the maximum frequency of uterine contraction. The highest tissue concentrations of PGs were also observed in the F1 follicle. These results suggest that the largest preovulatory follicle is the major source of PG synthesis and release. These PGs may stimulate uterine contraction and may also play a role in follicular rupture and release of the ovum.     

Morphine diminishes the constancy of spontaneous uterine contractions, antagonizes the positive inotropic effects of prostaglandin E2, but not of prostaglandin F2 alpha and inhibits prostaglandin E and F outputs from the uterus of ovariectomized rats

The effects of morphine on the constancy of spontaneous contractions (isometric developed tension = IDT and contractile frequency = CF), in uterine strips isolated from ovariectomized rats and the influence of naloxone, were explored. The inotropic responses to added prostaglandins (PGs) E2 and F2 alpha and the influences of morphine and of morphine in the presence of naloxone on PG actions, were also determined. Moreover, the synthesis and outputs of PGs E and F from uteri and the effects of morphine alone and of morphine plus naloxone, were studied. Morphine (10(-6) M) significantly depressed uterine constancy of IDT during the first hours following delivery, but its action on CF did not differ from controls. Naloxone, neither at 10(-8) M nor at 10(-6) M, altered the negative inotropic influence of morphine on IDT. Exogenous PGs E2 and F2 alpha, stimulated uterine inotropism in a concentration-dependent fashion. Morphine altered dose-response curves for exogenous PGE2, evoking a parallel surmountable shift to the right, but did not affect the inotropic action of added PGF2 alpha. This antagonistic effect of the opioid was not altered by preincubation with naloxone. Basal synthesis and outputs of PGs E and F in uteri from ovariectomized rats were significantly depressed by morphine (10(-6) M) but not altered by incubating tissues with morphine in presence of naloxone. Results are discussed in terms of a presumptive dual action of morphine on uterine motility, i.e., antagonizing PGE2 receptors and inhibiting the synthesis of some PGs by the uterus. These influences of morphine do not appear to be subserved by the activation of mu opioid receptors.(ABSTRACT TRUNCATED AT 250 WORDS)     

Expression of enzymes of cyclooxygenase pathway and secretion of prostaglandin E2 and F2alpha by porcine myometrium during luteolysis and early pregnancy

Past studies of uterine prostaglandin (PGs) and pig reproduction have focused on endometrial rather than myometrial PGs. This study documents the synthesis and secretion of myometrial prostaglandins (PGs) in pigs and the involvement of oxytocin (OT) in these processes. Cyclooxygenase-2 (COX-2) expression was similar in myometrial explants from cyclic and pregnant pigs (days 14-16) and OT (10(-7) M) in vitro significantly increased COX-2 protein regardless of reproductive state. Basal expression of prostaglandin E2 synthase (PGES) was higher during pregnancy than during luteolysis. Conversely, prostaglandin F synthase (PGFS) was highest during luteolysis and lower in myometrium from gravid animals. OT had no influence on the expression of PGES and PGFS. In another tissue culture experiment, myometrial slices produced more PGE2 than PGF2alpha regardless of reproductive state of the female. OT stimulated PGE2 production in myometrium harvested during luteolysis and increased PGF2alpha production in all tissues examined. Progesterone (P4; 10(-5) M) blocked stimulatory effect of OT on myometrial PG release. Myometrial OTr mRNA was higher (P=0.03) during luteolysis than during pregnancy. In conclusion: (1) oxytocin increases myometrial COX-2 expression, but does not influence the expression of terminal enzymes of PGs synthesis (PGES and PGFS); (2) porcine myometrium preferentially produces PGs during early pregnancy and secretes more PGE2 than PGF2alpha; (3) myometrial OT and OTr support secretion of PGs from myometrium during luteolysis.     

Discriminating analysis of "in vitro" prostaglandin release by myometrial and luminal sides of the ewe endometrium

An original perifusion device which allows a discrimination between the 30 mn releases of prostaglandins F2 alpha and E2 by the luminal and the myometrial faces of sheep endometrium is described. Tissue was sampled on day 4, 14, 16 or 17 of the cycle and on day 14 or 17 of pregnancy. Total prostaglandin (PG) release measured with this device was in good agreement with PG's concentrations in media of in vitro endometrium incubations already described. Discrimination analysis of the PGs release by each side of the endometrial tissue during the 30 mn perifusion time revealed that PGF2 alpha concentrations of the perifusion medium issued from the lumen compartment were higher than those of the myometrial compartment in all physiological status where corpus luteum is active (including early pregnancy). Therefore in the ewe, it seems that luteal structure maintenance during early pregnancy is not due, as in the gilt, to a shift in PGF2 alpha secretion towards the uterine lumen.     

Alterations in uterine and placental prostaglandin F and E with gestational age in the rat

Experiments were designed to determine the chronological alterations in placental and uterine prostaglandin F and E (PGF and PGE) during pregnancy in the rat. Pregnant rats (sperm in the vagina = day 0) were sacrified at days 15, 18,19, 20, 21 and delivery (day 21 ) and placental and uterine tissues assayed (RIA) for PGF and PGE immediately (“ ”) or after 1 hour incubation (“ ”). Uterine content of PGF and PGE (ng PG/mg DNA) was increased significantly by day 19 and further increases were seen through delivery. Incubation of uterine tissue resulted in enhanced net production of PGF and PGE (p <.05) per mg DNA (as judged by tissue content and release into the incubation medium) by day 18 of pregnancy vs. day 15. Net production peaked around the time of delivery thus paralleling the alterations in tissue content .By contrast, no differences with gestational age were found in placental content of PGF and PGE , the concentrations throughout late gestation remaining in the range of uterine PGs at day 15. However, production of PGs per mg placental DNA increased markedly during incubation with significant enhancement detected by day 19 vs. 15, achieving levels even greater than the uterus .The and findings for the uterus are consistent with the hypothesis that increases in uterine PGs levels at the end of pregnancy may play an important role in parturition. The experiences with placental tissue suggest that the potential for PG production per placental cell may also increase in late gestation and thereby contribute to the augmented intrauterine availability of PGs at that time.     

The output of uterine prostaglandins and the activity of 15-hydroxy-prostaglandin dehydrogenase are enhanced in chronic ethanol fed rats

The generation and output of prostaglandins (PGs) E2 and F2 alpha into the solution suspending uterine segments from ethanol (ETOH)-fed diestrous rats and the activity of 15-OH-PG-dehydrogenase (PGDH) in uteri at diestrus, were explored and compared with normal-fed controls. Animals were fed with ETOH (35% of the total calories in a liquid diet) during 20 days before sacrifice. Paired normal-fed controls were given isocaloric quantities of dextrimaltose. It was observed that the uterine outputs of PGE2 and of PGF2 alpha into the suspending solution, were significantly greater in the ETOH group. On the other hand, the PGDH activity for PGE2 in control uterine tissue, was significantly smaller than the activity detected in preparations from animals fed with the chronic ETOH diet. Results are discussed in terms of possible mechanisms for the action of ethanol, either on the release of PG fatty acid precursors (activation of phospholipase A2) or on the activity of PG synthesizing enzymes. Inasmuch as in the ETOH-fed group uterine PGDH activity was greater, rather than diminished, the possibility of a reduced catabolism accounting for the augmentation of PGs in the suspending medium, does not appear feasible. In fact, results suggest that the real magnitude of higher PG generation and release is even greater than that disclosed by the present study. The finding that chronic ethanol consumption augments PG production, appears relevant, in view of the unique roles played by these eicosanoids in parturition and in the development of fetuses.     

In vitro production of prostaglandins E and F by the guinea pig ovarian tissue

The ability of guinea pig ovarian tissue to biosynthesize prostaglandins E and F from endogenous precursors has been investigated in vitro. Estimations of prostaglandins were carried out using a sensitive radioimmuno assay during seven days preceding, and up to one day, following oestrous. Prostaglandins E and F were present in the ovarian tissue throughout the period investigated. Prostaglandin concentrations in samples incubated without enzymic inhibition were significantly higher than in samples incubated after enzymic inhibition with ethanol. This indicates that guinea pig ovarian tissue is able to synthesize prostaglandins from endogenous precursors.     

Prostaglandin release by slow reacting substance from guinea pig and human lung tissue

Slow reacting substance (SRS) injected into the pulmonary artery released prostaglandin E (PGE) and F_2α (PGF_2α) and the 15-keto-13, 14-dihydro PG metabolites from non-sensitized and ovalbumin sensitized, isolated, perfused guinea pig lungs. PGs were also released from lungs incubated with SRS. Sensitized lungs released more PGs in both types of preparations. Indomethacin inhibited the effect of SRS. Passively sensitized human lung fragments, in parallel to guinea pig lung, released PGE, PGF_2α and the metabolites when incubatted with SRS or antigen. In experiments, SRS and arachidonic acid given intravenously increased the airway insufflation pressure in anesthetized guinea pigs. These effects, but not the action of injected PGF_2α and histamine, were abolished by indomethacin. The results indicate that one of the modes of SRS action is by release of PGs, and are consistent with the hypothesis that PGs are predominantly “secondary” mediators (in the temporal sense) of the antigen-antibody reaction.     

Reversal of indomethacin-induced inhibition of implantation in the mouse by epidermal growth factor.

In the mouse, estriol (E3) can induce implantation as a phase I of estrogen action. E3-induced implantation was attenuated by indomethacin(INDO), an inhibitor of prostaglandin (PG) synthesis. The inhibitory effect of INDO was reversed by administration of epidermal growth factor (EGF), and this EGF effect was dose-dependent. These results suggest that one of the functions of estrogen could be to activate the EGF ligand-receptor signalling in the uterus in generating PGs required for initiation of implantation. This is consistent with the results of EGF stimulation of synthesis of PGs in uterine stromal cells in culture.     

Uterine and placental prostaglandins and their modulation of oxytocin sensitivity and contractility in the parturient uterus

The parturient uterus develops a markedly enhanced sensitivity to the uterotonic action of oxytocin (OT). The mechanism leading to this enhanced OT sensitivity is not known. Our previous work suggested that prostaglandins (PGs) may be involved. To define the relationship between OT sensitivity and uterine PG production, we measured uterine sensitivity to OT by a quantitative dose-response procedure in rats on Days 19, 20, 21 and 22 of pregnancy and monitored uterine and placental tissue concentrations of PGF2 alpha and PGE2. In addition, we determined the effects of inhibition of endogenous PG synthesis on OT sensitivity and uterine contractility. We found that both OT sensitivity and spontaneous contractility are positively related to uterine PGF2 alpha production. An abrupt increase in OT sensitivity was observed on Days 21 and 22 of pregnancy. The increase in OT sensitivity was coincidental with the marked increase in PGF2 alpha production in the uterus on Days 21 and 22 of pregnancy. Suppression of in vivo PG synthesis caused a reduction in both spontaneous uterine contractility and OT-induced contractions. Uterine PGE2 concentrations and release were 3-5 times lower than PGF2 alpha. There were no significant fluctuations of uterine PGE2 concentration measured on these last 4 days of gestation. Placental PG levels were also found not to be related to uterine contractility. Placental PGE2 levels were higher than PGF2 alpha and may play a regulatory role in placental perfusion. However, placental PGs did not vary with gestational age.     

The effect of the antioxidant, butylated hydroxy anisole, on peroxide-induced and spontaneous activity of the uterus from the pregnant rat

Chorioamnionitis is associated with preterm labor. Leukocytes infiltrate infected tissue and secrete hydrogen peroxide (H2O2) and other reactive oxygen products as part of their bactericidal activity. We have therefore investigated the effect of H2O2 on activity of in vitro uteri from pregnant rats. Uteri from 18-day pregnant rats exposed to H2O2 showed a dose-dependent increase in both contractile activity and production of prostaglandins (PG) E2 and F2 alpha compared to untreated controls. The antioxidant butylated hydroxy anisole (BHA) inhibited the H2O2-induced uterine activity. Furthermore, BHA inhibited contractions and PG production from spontaneously contracting uteri from 21-day pregnant rats. H2O2 increased chemiluminescence of uterine tissue, an index of oxygen or lipid radical formation, whereas BHA inhibited this effect. The BHA inhibition of uterine activity was reversed by addition of PGE2 to the incubation chamber. These data support the hypothesis that reactive oxygen can regulate PG production by the uterus and suggests a role for reactive oxygen in infection-induced labor and perhaps normal term labor as well.     

Acetylcholine Releases Prostaglandins from Brain Slices Incubated In Vitro

A variety of neurotransmitters elicit a phosphoinositide response in the CNS; however, their effects on prostaglandin (PG) formation in the brain are not well characterized. In the present study, we investigated the effect of acetylcholine (ACh) on the synthesis of PGs E and F in slices from various regions of guinea pig brain incubated in glucose-fortified Krebs-Henseleit bicarbonate saline. Slices were prewashed in the presence of 1% albumin to reduce basal PG levels followed by incubation for 30 min at 37 degrees C in the presence or absence of ACh. Under these conditions, 5 mM ACh significantly increased the efflux of PGE and PGF from brain regions enriched in muscarinic cholinergic receptors, i.e., cerebral cortex, temporal cortex, corpus striatum, and hippocampus. Depolarization by 45 mM KCl also significantly enhanced PG synthesis, and the relative magnitude of the effect was similar to that of ACh. The stimulation of PG synthesis by ACh was inhibited by 20 microM atropine, whereas the K+-induced stimulation was not. The effects of potassium and ACh were additive at maximally effective ACh concentrations, an observation that suggests that ACh and K+ increase PG efflux through independent mechanisms. Norepinephrine, histamine, and serotonin, three other neurotransmitters that evoke a phosphoinositide response in the brain, were ineffective in stimulating PG release from brain cortex slices.     

Effect of prostaglandins on milk ejection.

Prostaglandins (PGs) of type F2 alpha, E1, and E2 have been reported both, to inhibit or to facilitate posterior pituitary oxytocin release in lactating animals and women, and to suppress or to stimulate the mammary myoepithelium. Prostaglandin-induced milk ejection in women and cows has been attributed to central oxytocin release, but no oxytocin blood levels were determined. Moreover, for lactating cows, sows, rabbits, guinea pigs, and rats a direct PG effect on the mammary myoepithelium resulting in milk ejection has been suggested. On the other hand, PGs were found to antagonize the milk-ejection response to oxytocin in rabbits and rats. The mechanisms involved in PG synergism or antagonism of oxytocin-induced milk ejection are not understood. Studies in lactating rats showed that blood pressure active PG doses of F2 alpha, E1, and E2 largely inhibited the intramammary pressure response to oxytocin. Whereas the oxytocin-antagonistic action of PGF2 alpha was not affected by adrenergic blockers (phenoxybenzamine, propranolol), the anti-oxytocin effects of PGE1 and E2 were eliminated after alpha-receptor blockade while the activity of oxytocin increased. Under beta-receptor or alpha- plus beta-receptor blockade, the oxytocin-inhibitory effects of PGE1 and E2 were almost abolished. Mechanisms of PG-induced inhibition of the oxytocin response may involve mammary vascular changes and/or alterations in myoepithelial activity of cyclic adenosine-3,5-monophosphate (c-AMP), cyclic guanosine-3,5-monophosphate (c-GMP), and phosphodiesterase (PDE). It seems unlikely that PGs bring about significant posterior pituitary oxytocin release in rats.     

Effects of progesterone on the oestrogen-stimulated uterus: a comparative study of the mouse, guinea pig, rabbit and sheep.

To examine more closely the anti-oestrogenic action of progesterone (P), its effect on various parameters in the 17 beta-oestradiol (E2)-primed uterus of the mouse, guinea pig, rabbit and ewe was studied. Changes in uterine wet weight, rate of in vitro protein synthesis, protein : DNA and RNA : DNA ratios, peroxidase activity and the level of cytosol receptors for E2 and P were measured. Considerable between-species differences in the effect of P on these parameters were observed. The anti-uterotrophic action was greater in the mouse than in the guinea pig and was not seen in the rabbit or ewe. P inhibited protein synthesis in the mouse, was without significant effect in the guinea pig and was mildly stimulatory in the rabbit and ewe. Inhibitory effects on protein : DNA and RNA : DNA ratios were substantial in the mouse, minor in the guinea pig and absent in the rabbit and ewe. Peroxidase activity was decrease in the mouse and guinea pig, essentially lacking in the rabbit and not detectable in the ewe. In all species the level of both oestrogen and progesterone cytosol receptors was decreased, although the effect on the E2 receptor was less marked in the ewe. The results indicate that in the species studied an effect of P on the replenishment of the E2 receptor is not necessarily associated with other anti-oestrogenic actions of P and argue against the concept that initial anti-oestrogenic actions of P are mediated via a specific effect on such replenishment.     

Contributions of the fetoplacental unit to augmented uterine prostaglandin levels periparturition in the rat

The purpose of the present study was to determine if the acute alterations in uterine prostanoid levels at the end of pregnancy are influenced locally by the fetoplacental unit (FPU). Unilaterally pregnant rats were killed on Days 20 and 21 of pregnancy (delivery = Day 21.5) and uterine tissue was removed and analyzed for prostaglandin (PG) E, PGF, thromboxane B2 (TxB2), and 6-keto-PGF1 alpha (6KF) by radioimmunoassay. A significant (P less than 0.05) main effect of Day (20 vs. 21) and Uterine Horn (nonpregnant vs. pregnant), but no interaction for PGE, PGF, and TxB2 was detected. In contrast, a significant interaction (P less than 0.05) of Day with Uterine Horn was found for uterine 6KF levels. Examination of the simple main effects indicated an enhanced level (P less than 0.05) of 6KF in uterine tissue adjacent compared to opposite the FPU at Days 20 and 21. However, uterine 6KF levels in the nonpregnant, but not pregnant, uterine horn were greater at Day 21 compared to Day 20 of pregnancy. The lack of a significant interaction of the main effects for PGE, PGF, and TxB2 suggests that the increased levels of these PGs between Days 20 and 21 were proportional in the nonpregnant and pregnant uterine horn. Therefore, the factor(s) responsible for the augmentation in these uterine PG levels between Days 20 and 21 is(are) most likely arriving via systemic circulation. In addition, the proportionate increases in uterine PGs imply that the FPU is not conferring upon adjacent uterine tissue any unique ability to respond to systemic factors.(ABSTRACT TRUNCATED AT 250 WORDS)