Immunocytochemical localization of relaxin in the golden hamster (Mesocricetus auratus) during the last half of gestation

The objective of this study was to determine the tissue source of relaxin in pregnant hamsters by immunocytochemical techniques. Ovarian, uterine, and placental tissues were recovered from hamsters on Days 8, 10, 12, 14, and 15 of gestation and processed for light microscopy. Relaxin immunoreactivity was localized in tissue sections by the avidin-biotin-peroxidase technique using antiserum to porcine relaxin. On Day 8 of gestation, relaxin immunoreactivity was localized in primary giant trophoblast cells (GTC-1s) adjacent to the uterine decidua. On Day 10, relaxin immunoreactivity was localized in GTC-1s, secondary giant trophoblast cells (GTC-2s) adjacent to the ectoplacental cone, and endometrial granulocytes in the wall of sheathed arteries. On Day 12, relaxin immunoreactivity was observed primarily in GTC-2s interspersed among cells of the placental trophospongium but not in cells of the placental labyrinth. The intensity of staining and number of relaxin immunoreactive GTCs increased between Days 12 and 14 but was decreased by Day 15 PM. Relaxin was not localized in uterine glands or corpora lutea. These observations suggest that the placenta is the tissue source of relaxin in pregnant hamsters.     

Relaxin concentrations in endometrial, placental, and ovarian tissues and in sera from ewes during middle and late pregnancy

These studies were designed to determine the tissue source of ovine relaxin and to determine the feasibility of using the pregnant ewe for study of relaxin production and secretion. On Day 4 of gestation, ewes were laparotomized, the nonpregnant uterine horn was ligated, and the ovary not containing the corpus luteum was removed. During a second surgery at Day 45 (n = 8) or 140 (n = 9) of gestation, 10-ml blood samples were drawn from a uterine artery, the ovarian vein, and veins draining the pregnant and nonpregnant uterine horns. Endometrial, placental, and luteal tissues were obtained for immunocytochemistry and extraction. Relaxin was detected by a heterologous porcine radioimmunoassay (RIA) in 3 of 54 serum samples (701.3 +/- 25.4 pg/ml, mean +/- SEM). Relaxin was not detected in crude tissue extracts, but low quantities were detected by RIA following Sephadex G-50 column chromatography of tissue extracts. Total relaxin activity for all tissues was equivalent to 0.57 +/- 0.13 ng of porcine relaxin/g tissue (w.w.). Relaxin was not detected immunocytochemically by light or electron microscopy. These data indicate that low quantities of relaxin are present in tissues and sera of pregnant ewes.     

Relaxin activity in the pregnant cat

Plasma relaxin activity was measured by radioimmunoassay (RIA) in the domestic cat utilizing two different antisera developed against highly purified porcine relaxin. One was the 5858 antiserum from our laboratory and the other was the R6 antiserum of Dr. Bernard Steinetz. Relaxin activity could not be detected during the estrous cycle or during pseudopregnancy. Relaxin immunoactivity during early gestation was not detected by either antiserum. Plasma relaxin immunoactivity was first detected by both antisera on about Day 25 of gestation. Relaxin concentrations then increased rapidly, with a plateau reached between Days 30 and 35 that was maintained until 10-15 days prepartum. Relaxin concentrations then declined gradually until parturition. No prepartum increase was observed. Relaxin concentrations were undetectable within 24 h of delivery. Although amounts of immunoactivity measured with the R6 antiserum were consistently higher than measurements with the 5858 antiserum, the patterns of secretions observed were similar for both antisera.     

Pregnant mouse corpora lutea: immunocytochemical localization of relaxin and ultrastructure

Relaxin was localized in corpora lutea of pregnant mouse ovaries by using the unlabeled antibody peroxidase-antiperoxidase technique and a highly specific rabbit antirat relaxin serum. Relaxin immunostaining was first observed in luteal cells located at the periphery of corpora lutea on Day 10 of gestation. The number of relaxin immunostained cells and the intensity of the stain gradually increased to reach a maximum between Days 16 and 18 of gestation. While a few luteal cells were specifically stained for relaxin on Day 1 postpartum, no luteal cells were stained on Day 2 postpartum. Ultrastructural studies of luteal cells from pregnant mouse ovaries revealed the presence of a distinct electron-dense, membrane-bound granule population, which was first observed on Day 12 of gestation. The granules increased in number to reach a maximum between Days 16 and 18 of gestation, and were absent by Day 2 postpartum. The appearance and disappearance of this granule population closely paralleled the relaxin immunostaining in the luteal cells. We suggest that the granules may be the subcellular sites of relaxin storage in the pregnant mouse ovary.     

Determination of the source of immunoreactive relaxin in the cat

We have recently reported the secretory profile of relaxin throughout gestation in the cat. Because the appearance of relaxin begins at about Day 20 (Day O = ovulation) and because implantation begins shortly before this at Days 13-14, we hypothesized that relaxin was of feto-placental origin. To test this hypothesis, we used 4 experimental groups: 1) Control (laparotomy-only at Day 23 or 42, n = 4); 2) Early Ovariectomy (Ovx, bilateral ovariectomy between Days 23 and 26, n = 4); 3) Late Ovx (bilateral ovariectomy between Days 40 and 44, n = 4); 4) Tissue Removal (removal of feto-placental units, uterus, and one ovary on Days 16, 21, 28 and 35, n = 1 per day). Pregnancies were maintained in both Ovx groups by progesterone administration. Relaxin secretory patterns in Ovx groups were similar to the Control data. Relaxin was detectable in plasma beginning at about Day 20, with maximum concentrations reached by Day 30. Relaxin concentrations were highest (immunoactivity per mg tissue) in homogenates of placental tissues as compared to luteal, fetal, or uterine tissues. Altogether, these data indicate that the feto-placental unit is the source of relaxin in the cat.     

Rabbit relaxin: the influence of pregnancy and ovariectomy during pregnancy on the plasma profile.

A porcine relaxin radioimmunoassay was developed to evaluate the profile of immunoreactive relaxin in rabbit plasma. Relaxin was nondetectable in pseudopregnant (Days 1, 4, 5-8, 12, and 16), nonpregnant, and male rabbits. However, in pregnant rabbits, relaxin was detected during the peri-implantation period (Days 4-9). Peak concentrations were reached on Day 15 and were maintained until parturition (Day 32). Relaxin concentrations abruptly decreased on Day 1 postpartum to low but detectable concentrations that were unchanged during the first week postpartum. In contrast, progesterone concentrations peaked earlier (Day 13), decreased after Day 25, and were not detectable on Day 1 postpartum. The effect of ovariectomy on the profile of plasma relaxin was evaluated. Four pregnant rabbits were ovariectomized (Day 13) and treated with medroxyprogesterone acetate to maintain pregnancy. As in normal pregnant rabbits, relaxin was observed initially during the peri-implantation period (Days 4-9) and increased to peak concentrations by Day 16. These concentrations were maintained until parturition and abruptly decreased on Day 1 postpartum to low yet detectable concentrations during the first week postpartum. The concentrations of relaxin in the plasma of ovariectomized medroxyprogesterone-treated rabbits were not different from those in three sham controls. These results indicate that the ovary is not a significant source of relaxin in pregnant rabbits. The unique observation of the presence of relaxin during the peri-implantation period suggests that this hormone has a role in preparing the rabbit uterus for implantation. The continued presence of relaxin during the first week postpartum may represent residual hormone, or it may suggest a physiological role during the early postpartum period.     

Conceptus-mediated integrity of endometrial epithelial cells and maintenance of relaxin synthesis in pregnant rabbits: effects of unilateral oviduct ligation

A previous study indicated rabbit endometrial relaxin synthesis is stimulated by blastocyst (Lee VH, Fields PA, Biol Reprod 1990; 40:737-745). To evaluate this hypothesis, unilateral oviduct ligations were placed (A) at the oviduct isthmus on Day 1 post-copulation and (B), in a separate group of rabbits, at the infundibulum before copulation. Blastocysts migrate into and implant in the uterine horn contralateral to the ligated oviduct only (conceptus-bearing uterus). The uterine horn ipsilateral to the ligated oviduct will be referred to as the non-conceptus-bearing uterus. Uteri and ovaries were removed on Days 4-28 of pregnancy and were evaluated for relaxin using guinea pig anti-porcine relaxin serum and avidin-biotin light microscopy immunohistochemistry. Results were identical for both models. Blastocysts first attach to the antimesometrial uterine surface by Day 7 post-copulation. Implantation on the mesometrial surface occurs on Days 8-11. Relaxin was observed in antimesometrial endometrial glands of both conceptus and non-conceptus-bearing uteri on Days 4-7 of pregnancy. Beyond Day 7, relaxin was observed in antimesometrial and mesometrial endometrial glandular and luminal epithelial cells at implantation sites of the conceptus-bearing uterus only. Relaxin was not found between implantation sites. Endometrial epithelial cells of the non-conceptus-bearing uterus were regressing by Day 9. These data indicate a conceptus-mediated maintenance of endometrial epithelial cells. Furthermore, the data suggest a paracrine maintenance of epithelial cell integrity and relaxin synthesis since these parameters are preserved only in the conceptus-bearing uterus. Cell-cell communication between conceptus and endometrium appears to be specific since endometrium between implantation sites does not contain relaxin. Uterine tissue from pseudopregnant rabbits (Days 1-16) was evaluated. Relaxin was observed in the antimesometrial glands on Day 7 only. Like the endometrium in the ligation model, endometrial epithelial cells of the pseudopregnant rabbit uterus were regressing by Day 9. These results indicate that pregnancy is not required for, but may enhance, relaxin synthesis. In addition, endometrial epithelial cells regress in the absence of pregnancy. Regression of endometrial epithelial cells on Day 9 suggests that maternal recognition of pregnancy occurs during the preimplantation period (Days 4-8).     

Immunocytochemical localization of relaxin in corpora lutea of sows throughout the estrous cycle

Porcine relaxin has been sought by localization in the corpus luteum of sows on Days 3, 7, 9, 11, 12, 15, 18, 19, and 21 of the estrous cycle, using the avidin-biotin immunoperoxidase method and an antiserum to purified porcine relaxin. Simultaneous localization of relaxin in corpora lutea from sows on Days 108 and 113 of pregnancy was used to compare the intensity of immunostaining with that of corpora lutea of cyclic animals. However, the antiserum dilution necessary for optimal localization differed considerably in these two states (1:10,000 in pregnancy and 1:750 in the cycle), suggesting that lower levels of antigen are present in the luteal cells of the cycle. Relaxin immunostaining was undetectable on Day 3 of the cycle but became evident by Days 7 and 9. At Day 11 staining intensity increased and persisted through Day 15. On Day 18 some stain was still evident, but by Days 19, 20, and 21 there was complete absence of immunostain. Relaxin immunostaining appeared to be located throughout the cytoplasm of the luteal cell, as clear areas in the nuclear region were often observed. The results suggest that relaxin is produced in low amounts by the luteal cells of the cyclic sow and that the levels fluctuate with stage of the cycle. Lack of evidence from radioimmunoassay for a surge of relaxin secretion into the systemic circulation prior to luteolysis in the pig estrous cycle suggests that the relaxin localized in the luteal cells of the cycle may have an intraovarian function.     

Development, validation, and application of a urinary relaxin radioimmunoassay for the diagnosis and monitoring of pregnancy in felids

Many nondomestic felids are highly endangered, and captive breeding programs have become essential components of holistic conservation efforts for these species. The ability to diagnose pregnancy early in gestation is fundamental to developing effective breeding programs. The purpose of this study was to develop a radioimmunoassay (RIA) for the detection of urinary relaxin in felids and assess its applicability for early, noninvasive pregnancy diagnosis in domestic cats (Felis silvestris catus) and leopards (Panthera pardus). Urine was collected from pregnant and nonpregnant domestic cats and leopards at mating, and then weekly thereafter for the duration of gestation. Paired serum samples were also collected from the domestic cats. A RIA for relaxin that uses an antiserum against synthetic canine relaxin was validated for felid urine and shown to detect relaxin immunoreactivity in pregnant cat urine subjected to acid-acetone extraction. In the cat, urinary relaxin was first detected between Days 21 and 28 of gestation; levels peaked at 42-49 days, and the concentrations then declined over 2 wk prior to parturition. The urinary relaxin profiles of the cat mirrored those in serum. In the leopard, urinary relaxin was first detected at Day 25-28 of gestation; levels peaked at Day 60-64 and declined in the last 3-4 wk of pregnancy. These results indicate that measurement of urinary relaxin in the cat and leopard provides a reliable method for pregnancy determination from as early as 3-4 wk of gestation. This method of pregnancy diagnosis and monitoring may prove useful in the breeding management of domestic cats and other felid and canid species, and provides a foundation for future studies on pregnancy in captive exotic carnivores.     

Endocrine parameters associated with disruption of parturition after bilateral pelvic neurectomy.

Bilateral lesions of the pelvic nerve (BLPN) result in dystocia, but the processes which control this effect are not fully understood. Plasma progesterone, relaxin, and luteinizing hormone (LH) concentrations were measured in blood samples taken in the morning (AM) and evening (PM) of Days 20-23 of gestation from rats with BLPN or sham neurectomy. Ten of 11 sham-operated control animals delivered their entire litters by Day 23 of gestation, but animals with BLPN did not complete parturition by Day 23 when they were sacrificed. Progesterone concentrations were greater in rats with BLPN than in sham-operated rats on Day 20 PM and Day 21 AM, but hormone concentrations declined to minimal values by Day 22 in both groups. Relaxin concentrations were greater in rats with BLPN than in sham-operated rats on Day 21 PM. Thereafter, relaxin concentrations decreased to reach minimum values on Day 23 in both groups. LH concentrations were low throughout the period of study in rats with BLPN; however, a postpartum LH surge was detected in all sham-operated animals. Data from this study indicate that the pelvic nerve does not control parturition by modulating serum relaxin and progesterone concentrations; however, these data suggest that impulses carried by the pelvic nerve influence ovarian secretion of these hormones. In addition, these data indicate that the pelvic nerve transmits stimuli from the cervix to the hypothalamus to facilitate the postpartum LH surge.     

Rabbit endometrial relaxin: immunohistochemical localization during preimplantation, pregnancy, and lactation

Relaxin was localized in rabbit endometrium (but not ovary) on Days 4-30 of pregnancy and Days 2-5 of lactation. The hormone was not observed on Days 2 and 3 post coitus. Relaxin was found in endometrial glands throughout the length of the uterus on Days 4-9 post coitus. Later, on Days 11-23, relaxin was localized in both uterine endometrial gland cells and luminal epithelial cells. At this time, staining was observed only in the endometrium directly associated with implantation sites. Areas between implantation sites were devoid of staining. On Days 25-30 of pregnancy, relaxin was found mainly in uterine luminal epithelial cells. Few glands were observed with relaxin. During the first week of lactation, the staining profile was the same as that observed on Days 25-30. Relaxin was not found in the endometrium of pseudopregnant rabbits (Days 1, 4, 8, 12, and 16). The early appearance of uterine relaxin at the time the blastocyst migrates into the uterine cavity coupled with the hormone's later confinement to implantation sites suggests that the blastocyst initiates and the conceptus maintains uterine relaxin.     

Ultrastructural morphology and relaxin immunolocalization in giant trophoblast cells of the golden hamster placenta

Relaxin immunoreactivity was previously demonstrated in three cell types within the hamster placenta; fetal primary and secondary giant trophoblast cells (GTCs) and maternal endometrial granulocytes. The objectives of the present research were to examine the ultrastructure of the GTCs and identify the intracellular relaxin storage site. Primary GTCs, first present on day 8 of gestation, were characterized by numerous polyribosomes and large heterogeneous cytoplasmic inclusions suggesting phagocytic activity. Primary and secondary GTCs from days 10, 14, and 15 of gestation contained numerous polyribosomes, mitochondria with tubular cristae, and extensive Golgi complex, and abundant rough endoplasmic reticulum, all characteristics of a cell actively involved in protein synthesis. Membrane-bound secretory granules were not present. Relaxin was immunolocalized within the Golgi complex of primary and secondary GTCs using the avidin-biotin-peroxidase method. Following differential centrifugation of hamster placental homogenates and radioimmunoassay (RIA) of subcellular fractions, the majority of relaxin immunoactivity was detected in the postmicrosomal fraction; however, the majority of relaxin immunoactivity from similarly treated pig corpora lutea was present in the mitochondrial/granule fraction. These data indicate that hamster placental relaxin is not stored in membrane-bound secretory granules but is contained within the extensive Golgi complex of the GTC.     

Immunohistochemical co-localization of placental lactogen II and relaxin in the golden hamster (Mesocricetus auratus)

Two hormones with lactogenic activity are produced by the hamster placenta during the second half of pregnancy. One of these hormones, hamster placental lactogen II (haPL-II), has been well characterized; however, its cellular source is not known. In the present study, haPL-II was localized in placental tissues using a specific antibody and the avidin-biotin-peroxidase immunohistochemical technique. Because relaxin has been localized in the hamster placenta, it was of interest to determine if haPL-II and relaxin are localized in the same cells. haPL-II immunoactivity was observed in primary and secondary giant trophoblast cells of the placenta on Days 12, 14, and 15 of pregnancy. On Day 15 positive staining was also observed in large cells located within mesometrial arteries and in eosinophilic bodies associated with degenerating sheathed arteries of the decidua basalis. haPL-II-positive staining was not observed in placentae from Days 8 or 10 of pregnancy. On Day 14, haPL-II was colocalized with relaxin in 75% of the giant trophoblast cells observed. Therefore, it is probable that these hormones are synthesized and secreted by the same cell.     

Ultrastructural localization of relaxin in the corpus luteum of the nonpregnant, pseudopregnant, and pregnant pig

Relaxin was localized in luteal cells of ovaries from nonpregnant, pseudopregnant, and pregnant pigs using porcine relaxin antiserum and peroxidase-antiperoxidase light microscopy immunohistochemistry. The number of immunoreactive cells seemed to increase from Days 17 to 106 of gestation. Luteal cells from pseudopregnant (Day 110) and nonpregnant (Day 14 of the estrous cycle) pigs were also positive for relaxin. However, less than 3% of the luteal cells in the nonpregnant animals were immunoreactive. Electron microscopy immunocytochemistry using porcine relaxin antiserum and goat antirabbit immunoglobulin G-colloidal gold demonstrated that relaxin was packaged in the small membrane-bound granules in luteal cells of pregnant as well as pseudopregnant and nonpregnant pigs. The intensity of labeling (number of gold particles) of the granules increased with pregnancy. There was a 10-fold increase in labeling of granules with the 10-nm versus 25-nm diameter gold. The goat antirabbit labeled with the smaller 10-nm gold particles was necessary to demonstrate the apparent low levels of relaxin in the luteal cells of the nonpregnant pigs. These data further indicate that pregnancy is not required for relaxin synthesis. However, physiologic significance of relaxin in corpora lutea of nonpregnant pigs has not been determined.     

Effect of oestradiol-17 beta on ovarian and serum concentrations of relaxin during the second half of pregnancy in the rat

Immunoactivity concentrations of ovarian relaxin, serum relaxin and serum progesterone were determined from Day 12 through Day 18 of pregnancy in rats treated with oil or oestradiol-17 beta after hysterectomy or hypophysectomy and hysterectomy on Day 12. Relaxin and progesterone concentrations increased between Days 12 and 18 in sham-operated rats but failed to increase or declined in oil-treated hysterectomized or hypophysectomized-hysterectomized animals. Oestradiol treatment increased serum concentrations of relaxin and progesterone in hypophysectomized-hysterectomized rats on Day 15 and increased the concentrations of ovarian and serum relaxin and serum progesterone in hysterectomized rats on Day 18. These data are consistent with the concept that placental support for the promotion and maintenance of relaxin and progesterone concentrations from Day 12 through Day 18 may be mediated, at least in part, through a common mechanism(s) which involves oestradiol.     

Systemic relaxin in pregnant pony mares grazed on endophyte-infected fescue: effects of fluphenazine treatment

Tall fescue is one of the most widely grown forage grasses for horses in the United States. However, it is frequently infected with the endophyte Neotyphodium coenophialum which produces ergot alkaloids that cause severe adverse effects in the pregnant mare. The objectives of this study were to determine the effects of fescue toxicosis and fluphenazine on circulating relaxin in pregnant pony mares and evaluate the usefulness of relaxin as a monitor of treatment efficacy. Twelve mares were maintained on endophyte-infected tall fescue pasture. Group TRT (n = 6), received 25 mg of fluphenazine decanoate (i.m.) on Day 320 of gestation while Group UTRT served as untreated controls. Daily blood samples were collected from Day 300 of gestation until Day 3 post partum and analyzed for plasma relaxin concentrations using a homologous equine radioimmunoassay. Mean gestation lengths were 330 +/- 0.7 and 336.5 +/- 3.2 days for TRT and UTRT mares, respectively (P = 0.07). Mean plasma relaxin concentrations in both groups of mares during the week before treatment (Day 313 to 319) were not different (UTRT, 53.4 +/- 11.3 ng/mL; TRT, 61.4 +/- 9.3 ng/mL). In the week after treatment (Day 320 to 326), mean plasma relaxin tended to be higher (P = 0.1) in TRT mares (66.7 +/- 6.2 ng/mL) when compared with UTRT mares (49.6 +/- 6.6 ng/mL), representing a 17.1 ng/mL difference in circulating relaxin between the two groups. Systemic relaxin during the last week before delivery (days relative to parturition) for UTRT and TRT mares was 45.7 +/- 6.7 and 64.7 +/- 6.4 ng/mL (P = 0.06), respectively. At Day -8 and Day -5 relative to parturition, systemic relaxin in TRT mares was significantly higher (P < 0.05) than in UTRT mares. Three of the six UTRT mares and one TRT mare showed clinical symptoms of fescue toxicosis. In the week before delivery, circulating relaxin in mares with problematic pregnancies (39.9 +/- 7.8 ng/mL) was significantly lower than concentrations measured in mares with normal pregnancies (63.4 +/- 5.4 ng/mL; P = 0.03). Clinical observations suggest that a one-time injection with fluphenazine improved pregnancy outcome by reducing the adverse effects of fescue toxicosis concomitant with a stabilization of plasma relaxin concentrations. These data support the hypothesis that systemic relaxin may be a useful biochemical means of monitoring placental function and treatment efficacy in the mare.     

Metabolism of testosterone in vivo in the pregnant rat

The metabolism of testosterone (T) was examined during the second half of pregnancy in the rat to determine whether utilization of T for estradiol (E2) synthesis occurs via conversion of T to androstenedione (A). On Days 11, 16, and 21 of gestation (term = Day 23), rats (n = 7-9/group) were anesthetized and a constant infusion of [3H]T was initiated. At 60 min, blood was obtained from a jugular vein and the ovaries (Days 11, 16, and 21), and placentae and uterine tissue (Day 16 only) were removed. In a second study performed in rats on Day 16 of gestation (n = 8-10/group), the ovaries and/or gravid uterus were removed 15 min after initiation of [3H]T infusion, and blood was taken from a jugular vein 60 min later. Radiolabeled T and A were purified from serum and tissues by paper chromatography. In a third group of rats (n = 6), jugular vein samples were obtained sequentially on Days 11, 16 and 21 of gestation and serum concentrations of T were measured by radioimmunoassay. The metabolic clearance rate of T was constant during the study period (overall mean = 31 1/day). In contrast, the serum concentration of T (pg/ml) on Day 16 of gestation (863 +/- 108) exceeded (p less than 0.02) that on Day 11 (445 +/- 74); the latter was similar to that measured on Day 21 (592 +/- 109). Thus, the estimated production rate of T was greatest on Day 16 of gestation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of relaxin in the placenta of the ewe

Sheep placentomes were collected at the abattoir and the stage of gestation was estimated from the crown-rump length and appearance of the fetus. Samples were extracted and either freeze dried (crude extracts) or fractionated on Sephadex G-50 and CM-cellulose. Relaxin immunoreactivity (RXN-IR) was detected in all samples by a pig relaxin RIA and diluted in parallel with the standard curve. Two patterns of RXN-IR were seen after Sephadex G50 purification: (a) a single main peak of RXN-IR eluting at a position similar to pig relaxin; or (b) a 3-peak pattern with additional higher (void volume) and lower (approximately 1000) molecular weight peaks. These peaks were all found with 4 different and specific antisera. The 6000 molecular weight peak eluted at a similar position to pig relaxin on CM cellulose and inhibited electrically stimulated rat uterine contractions in vitro. The amount of relaxin measured in crude extracts of placentomes from different ewes was very variable. Most samples were within the range 0.05-11.2 ng/g wet weight of tissue (3.0 +/- 0.45 (s.e.m.), n = 44) but a few contained much higher concentrations (25.5-61.4 ng/g, n = 3). There was no obvious variation in concentration with stage of pregnancy (20 days to term). Samples of intercotyledonary endometrium, allantochorion and whole ovaries from pregnant ewes were also extracted. All contained low concentrations of RXN-IR (0.6 +/- 0.13 ng/g, n = 4; 0.6 +/- 0.29 ng/g, n = 3; 1.0 +/- 0.66 ng/g, n = 7, respectively). We conclude that relaxin-like peptides are present in the pregnant ewe and that, as the placentomes are the largest component by weight, they represent the major source.     

Relaxin, oxytocin, and prostaglandin effects on progesterone secretion from bovine luteal cells during different stages of gestation

To determine the effects of relaxin, oxytocin, and prostaglandin F2 alpha on progesterone secretion, bovine luteal cells from different stages of gestation were dispersed in Medium 199 with 200 units/ml penicillin, 1.0% kanamycin, 0.5% bovine serum albumin, and 400 units/ml collagenase. Cells (10(5) were cultured in 400 microliters of Dulbecco's modified Eagle's medium and Ham's F-12 medium containing fetal bovine serum and antibiotics, in Falcon multiwell plates, in a humidified environment of 95% O2 and 5% CO2 at 37 degrees C. Cells were cultured for 24 hr without treatment and thereafter with medium-hormone replacement every 24 hr. Progesterone was quantified from unextracted media by radioimmunoassay. Basal progesterone secretion after 24 hr was 1.81 +/- 0.14, 1.76 +/- 0.17, 0.54 +/- 0.49, and 0.57 +/- 0.21 pg/ml per viable luteal cell from 145-, 165-, 185-, and 240-day-old corpora lutea, respectively. Basal progesterone secretion increased (P less than 0.05) with time in culture. Relaxin induced a dose-dependent (greater than 100 ng/ml) increase in progesterone release, compared with the controls. Oxytocin and prostaglandin F2 alpha induced greater release (P less than 0.05) of progesterone than relaxin at all stages of gestation, but progesterone release was dependent on the stage of gestation and the duration in culture. Luteinizing hormone (100 ng/ml) stimulated whereas 17 beta-estradiol (50 ng/ml) inhibited progesterone secretion by luteal cells at all stages of gestation examined. Relaxin obliterated the prostaglandin- and oxytocin-induced progesterone secretion by bovine luteal cells from 145 to 214 days of gestation. Thus, relaxin, cloprostenol, and oxytocin regulate progesterone production by cultured bovine luteal cells, but hormone secretion was dependent on the stage of gestation.