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.     

Measurement of plasma and tissue relaxin concentrations in the pregnant hamster and fetus using a homologous radioimmunoassay

A homologous hamster relaxin RIA was developed to evaluate plasma and tissue concentrations of relaxin in the latter half of pregnancy in this species. Relaxin protein and mRNA were localized using antibodies developed to synthetic hamster relaxin and gene-specific molecular probes, respectively. Molecular weight and isoelectric point of the synthetic and native hormones were identical by electrophoretic methods, and synthetic hamster relaxin was active in the mouse interpubic ligament bioassay. Synthetic hormone was used as tracer and standard with rabbit antiserum to the synthetic hormone in the RIA. Relaxin was assayed in blood samples recovered from the retro-orbital plexus on Days 6, 8, 10, 12, 14, 15, and 16 of gestation and on Days 1 and 5 postpartum. Relaxin was first detected on Day 8 of gestation (3.7 +/- 0.6 ng/ml), increased to reach a maximum in the evening of Day 15 (826.0 +/- 124.0 ng/ml), and decreased by Day 16 (day of parturition). Relaxin concentrations were assayed in aqueous extracts of implantation sites (Days 6, 8, and 10) and chorioallantoic placentae (Days 12, 14, and 15). Concentrations were low on Day 6 (0.02 +/- 0.001 microg/g tissue), increased to Day 15 (6.96 +/- 0.86 microg/g tissue), and subsequently declined by the evening of Day 15. Relaxin protein and mRNA were localized to primary and secondary giant trophoblast cells in the chorioallantoic placental trophospongium. However, relaxin protein was not localized in ovaries of pregnant animals or oviductal tissues of cycling animals. Significant quantities of relaxin were detected in the serum of fetal hamsters recovered on Day 15.     

Evidence for a switch in the site of relaxin production from small theca-derived cells to large luteal cells during early pregnancy in the pig

The presence of immunoreactive relaxin was studied in corpora lutea of sows during the oestrous cycle and early pregnancy by immunohistochemistry and radioimmunoassay using three different anti-relaxin sera. Sections were immunostained using the peroxidase-anti-peroxidase or the immunogold-silver technique. Before Day 14, staining in corpora lutea from non-pregnant and pregnant animals was indistinguishable. With all antisera, no immunostaining was seen on Day 3, but was detected on Days 5-7 in cells from the theca interna. In non-pregnant animals, this immunostaining decreased and by Day 15 only an occasional large cell in the centre of the corpus luteum was stained. No staining was seen by Day 22. The relaxin content of corpora lutea measured by radioimmunoassay remained low throughout the luteal phase. In contrast, the amount of immunoreactive relaxin in corpora lutea rose dramatically (140-fold) between Days 11 and 14 of pregnancy and by Day 14 of pregnancy immunostaining was seen in the majority of large luteal cells. By Day 20 of pregnancy the concentrations of immunoreactive relaxin had further increased. Histochemical staining for alkaline phosphatase suggested that, while the relaxin-immunoreactive cells seen in the early luteal phase may be theca-derived, those during early pregnancy may be derived from the granulosa. The results are compatible with the suggestion that relaxin is produced by theca-derived cells during the early luteal phase and that between Days 11 and 14 there is a switch in the site of relaxin synthesis from theca-derived cells to granulosa-derived large luteal cells. In the absence of luteolysis, as during pregnancy, this switch is accompanied by a dramatic increase in relaxin synthesis.     

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.     

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.     

Immunocytochemical studies of relaxin in ovaries of pregnant and cycling mice

Immunocytochemical staining for relaxin in ovarian sections of pregnant mice from day 11 through day 18 of gestation revealed that only corpora lutea (CL) of pregnancy are stained. Evaluation of serial sections of ovaries from a day 16 pregnant mouse revealed that the only luteal structures present are CL of pregnancy. The number of CL present in each ovary equaled the number of implantation sites in each related horn (7 on the right side and 8 on the left side). These large CL varied in shape, being round in some profiles to very elongate in others. All CL were immunochemically stained for relaxin using the peroxidase-antiperoxidase method of L. Sternberger (Immunocytochemistry, 2nd ed. Wiley, New York, 1979). The intensity of the strain varied from cell to cell within each CL. Small luteal structures that were observed to be immunochemically stained for relaxin were demonstrated to represent the periphery of CL of pregnancy. No luteinized follicles were observed and interstitial cells and follicles were not immunochemically stained in any of the day 16 serial ovarian sections or in any of the ovarian sections from pregnant mice on the other days of gestation studied. CL of previous cycles were not observed to be present in the ovaries at days 15, 16, or 18 of gestation. However on day 14 and before, CL of previous cycles were observed and they did not exhibit any relaxin immunostaining. Immunocytochemical studies using the biotin-avidin system revealed that no relaxin immunostaining could be demonstrated in the ovaries of cycling mice at any stage of the estrous cycle. In conclusion, this study revealed that the only ovarian structures demonstrating relaxin immunocytochemical staining in the mouse were CL of pregnancy.     

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.     

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.     

Expression of monocyte chemoattractant protein-1 and distribution of immune cell populations in the bovine corpus luteum throughout the estrous cycle.

This study characterizes the expression of monocyte chemoattractant protein-1 (MCP-1) and the relative distribution of immune cell populations in the bovine corpus luteum throughout the estrous cycle. Immunodetectable MCP-1 was evident in corpora lutea of cows at Days 6, 12, and 18 postovulation (Day 0 = ovulation, n = 4 cows/stage). Day 6 corpora lutea contained minimal MCP-1 that was confined primarily to blood vessels. In contrast, relatively intense staining for MCP-1 was observed in corpora lutea from Days 12 and 18 postovulation. MCP-1 was again most evident in the cells of the vasculature, but it was also observed surrounding individual luteal cells, particularly by Day 18. An increase in immunohistochemical expression of MCP-1 on Days 12 and 18 postovulation corresponded with increases in MCP-1 mRNA and protein in corpora lutea as determined by Northern blot analysis and ELISA. Monocytes and macrophages were the most abundant immune cells detected in the bovine corpus luteum, followed by CD8+ and CD4+ T lymphocytes. In all instances, Day 6 corpora lutea contained fewer immune cells than corpora lutea from Days 12 and 18. In conclusion, increased expression of MCP-1 was accompanied by the accumulation of immune cells in the corpora lutea of cows during the latter half of the estrous cycle (Days 12-18 postovulation). These results support the hypothesis that MCP-1 promotes immune cell recruitment into the corpus luteum to facilitate luteal regression. These results also raise a provocative issue, however, concerning the recruitment of immune cells several days in advance of the onset of luteal regression.     

Immunocytochemical localization of neurophysin and oxytocin in ovine corpora lutea

The cellular distribution of neurophysin and oxytocin within ovine corpora lutea obtained on Days 4, 10 and 16 of the estrous cycle was examined immunocytochemically. Serial sections (8-10 micron-thick) prepared from corpora lutea that had been fixed in Bouin's solution and embedded in paraffin were immunostained for neurophysin or oxytocin using the peroxidase-antiperoxidase (PAP) procedure. Irrespective of the day of the cycle examined, immunoreactivity was restricted to large luteal cells. However, on Days 4 and 10 of the cycle, the intensity of staining in large luteal cells was highly variable; and, within the same section some cells were heavily stained, others were only lightly stained, and still others were not stained at all. In contrast, on Day 16 of the cycle, the intensity of staining was uniform and essentially all of the large luteal cells were immunoreactive. Based on the results obtained, it is evident that immunoreactive neurophysin and oxytocin can be detected as early as Day 4 of the cycle, persists through Day 15, and is restricted to large luteal cells.     

Immunocytochemical localization of relaxin in human corpora lutea: cellular and subcellular distribution and dependence on reproductive state

Relaxin is one of the hormones present during pregnancy and it is synthesized primarily by corpora lutea (CL). Other reproductive tissues including CL of the menstrual cycle may also synthesize this hormone. Very little is known, however, about the cellular and subcellular distribution of relaxin in human CL and dependence of luteal relaxin on the reproductive state. The light and electron microscope immunocytochemical studies described here were undertaken to obtain this information using antisera to porcine and human relaxin. Immunostaining was found in large luteal cells (17-30 microns) but not in small luteal cells (7-16 microns) or in nonluteal cells in any of the reproductive states or in human hepatocytes. Luteal immunostaining was low in early luteal phase; it increased progressively, reaching the highest level in late luteal phase, and then decreased greatly in corpora albicantia. Term pregnancy CL contained similar immunostaining as early luteal phase CL. Mid luteal phase CL contained more immunostained cells than late luteal phase CL, but the late luteal phase CL contained a greater amount of immunostaining per cell than mid luteal phase CL. The immunogold particles due to relaxin were primarily present in secretory granules and to a small extent in rough endoplasmic reticulum. Quantitation revealed that secretory granules contained a much higher number of gold particles than did rough endoplasmic reticulum. These two organelles from late luteal phase CL contained greater numbers of gold particles than those from mid luteal phase.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Changes in lipid contents and fatty acid compositions in ovine corpora lutea during the estrous cycle and early pregnancy

Changes in lipid contents and fatty acid compositions of each lipid fraction were examined in corpora lutea from 34 unmated ewes between Days 8 and 16 of the estrous cycle and from 6 ewes at Day 16 of pregnancy. Four patterns were observed during advancement of the estrous cycle. Luteal concentrations of free cholesterol and triglyceride (neutral lipids) increased between Days 14 and 16, during luteal regression, in a manner approximated by exponential functions of time, whereas luteal concentrations of phospholipid (polar lipids) increased and then decreased between Days 8 and 16 in a manner approximated by a sin function of time. Likewise, within the various lipid class component fatty acids, changes in palmitic acid weight percentages were approximated by sin functions of time, whereas arachidonic acid weight percentages increased between Days 14 and 16 in a manner approximated by exponential functions of time. Pregnancy either inhibited or reversed the changes in luteal lipid profiles, especially arachidonic acid percentages, between Days 14 and 16 of the estrous cycle. Luteal lipid profiles of corpora lutea from Day 16 pregnant sheep approximated lipid profiles of corpora lutea recovered from sheep between Days 12 and 14 of the estrous cycle. Comparison of luteal lipid profiles after tissue incubations at either 0 or 37 degrees C for 2 h revealed an effect of reproductive status on fatty acid metabolisms at Day 16. Changes observed in luteal lipid contents and fatty acid compositions during advancement of the estrous cycle represent aspects of lutein cell maturation and impending senescence that can be inhibited or reversed by pregnancy.     

Immunohistochemical localization of androgen receptor and aromatase in the ovary of the pregnant pig

The distribution of androgen receptor (AR) and cytochrome P450 aromatase was investigated in paraffin sections of pregnant pig ovary. Ovarian follicles and corpora lutea were isolated from ovaries obtained on Days 10, 18, 32, 71 and 90 post coitum (p.c.). Androgen receptor was localized in the nuclei of granulosa cells of follicles of various sizes. In addition, some follicles demonstrated staining in the nuclei of theca interna cells. Stroma cells also exhibited a positive immunostaining. At early and mid pregnancy (up to Day 71) AR was expressed in the nuclei of luteal cells. Corpora lutea of Day 71 showed mainly cytoplasmic staining while on Day 90 almost all luteal cells showed staining exclusively in the cytoplasm. Immuno-staining for the presence of cytochrome P450 aromatase was very faint in all investigated ovarian structures. The results could suggest that the process of androgen aromatization plays a negligible role in the ovary of the pregnant pig.     

Dissimilarity of corpora lutea within the same ovaries or those from right and left ovaries of pigs during the oestrous cycle

A total of 48 corpora lutea from the right and left ovaries of 2 gilts on Day 9 and 2 gilts on Day 13 of the oestrous cycle were analysed for gonadotrophin binding, progesterone concentration and 3 enzyme activities. The weights of corpora lutea from the right and left ovaries on Days 9 and 13 did not differ, but the values on Day 13 were lower than those on Day 9. The specific binding of 125I-labelled hCG, progesterone concentration, and activities of cytochrome c oxidase (a mitochondrial enzyme), beta-N-acetyl-D-glucosaminidase (a lysosomal enzyme) and glucose 6-phosphate dehydrogenase (a cytosol enzyme) differed, with some exceptions, among the corpora lutea within the same ovaries and those from the right and left ovaries on Days 9 and 13 of the cycle. The gonadotrophin binding differences amongst the corpora lutea appeared to be due to the differences in the total number of available receptors rather than in the receptor affinities. There was no strict correspondence between the magnitude of gonadotrophin binding and luteal progesterone concentration. These data show that porcine corpora lutea within the same ovaries, and those from the right and the left ovary, are quite dissimilar.     

Receptors for prostaglandins F2 alpha and E2 in ovine corpora lutea during maternal recognition of pregnancy.

Plasma membrane receptors for prostaglandins (PG) F2 alpha and E2 were quantified in ovine corpora lutea obtained from nonpregnant and pregnant ewes on Days 10, 13, and 15 post-estrus, and from additional ewes on Days 25 and 40 of pregnancy. Regardless of reproductive status or day post-estrus, concentrations of luteal receptors for PGF2 alpha were 7- to 10-fold greater than those for PGE2. In pregnant ewes the concentration of receptors for PGF2 alpha was highest on Day 10 (35.4 +/- 2.8 fmol/mg) and lowest on Day 25 (22.3 +/- 2.5 fmol/mg). A difference in the concentration of luteal receptors for PGF2 alpha between pregnant and nonpregnant ewes was apparent only on Day 15 post-estrus, at which time the concentration of receptors for PGF2 alpha was higher in pregnant ewes than in nonpregnant ewes (27.1 +/- 2.7 vs. 17.7 +/- 2.7 fmol/mg). Concentrations of receptors for PGE2 in pregnant ewes were similar (p > 0.05; 2.8 +/- 0.3 to 3.7 +/- 0.2 fmol/mg) between Days 13 and 40 but were higher (p < 0.05) than in corpora lutea obtained from nonpregnant ewes on Days 10 (5.0 +/- 0.4 vs. 4.1 +/- 0.2 fmol/mg) and 15 (3.7 +/- 0.2 vs. 2.0 +/- 0.4 fmol/mg) post-estrus. Although concentrations of receptors for both PGF2 alpha and PGE2 were lowest in corpora lutea obtained from nonpregnant ewes on Day 15, this was not due to luteal regression since the weights and concentrations of progesterone in corpora lutea on Day 15 were not lower than those for corpora lutea obtained on Days 10 and 13.(ABSTRACT TRUNCATED AT 250 WORDS)     

Immunocytochemical localization of aromatase in immature rat ovaries treated with PMSG and hCG,and in pregnant rat ovaries

Summary Immunocytochemical localization of aromatase cytochrome P-450 was examined in immature rat ovaries treated with pregnant mare serum gonadotropin (PMSG) and human chorionic gonadotropin (hCG), and in pregnant rat ovaries. It is well known that PMSG and hCG treatments induce ovulation about 12 h after hCG injection.At 24 h after hCG injection, many antral follicles were recognized in immature rat ovaries and only the granulosa cells in the antral follicles were stained weakly with the anti-aromatase antibody. At 0 to 9 h after hCG injection, in addition to the antral follicles, some large Graafian follicles could be observed in the rat ovaries, and the granulosa cells of these follicles were positively stained for aromatase. Each follicle was surrounded by the basal lamina which shows lineally distinct positive reaction against anti-laminin antibody. At 12 h after hCG injection, some large Graafian follicles without oocyte were weakly positive to the anti-aromatase antisera, and the outline of their basal lamina stained with anti-laminin antibody became irregular in shape and fragmentous. At 15 to 18 h after hCG injection, the luteinized cysts could be seen, and the granulosa-lutein cells of these cysts were almost negative for aromatase. Fragmentous reaction to the anti-laminin antibody was observed around the luteinized cysts.In the ovaries of day 4 in pregnancy, only the granulosa cells of the large antral follicles were weakly stained, but corpora lutea negatively reacted to the anti-aromatase antibody. At 7 to 19 days in gestation, both the granulosa cells of antral follicles and pregnant luteal cells were positively stained against aromatase antisera. The luteal cells were increased in size during pregnancy. And weakly positive reaction was detected on day 7 of pregnancy, then the immunoreaction became stronger in the corpora lutea on day 15 and 19 of pregnancy.The localization of aromatase was immunocytochemically examined in immature rat ovaries treated with PMSG and hCG injection, and the reaction of the granulosa cells of the antral follicles against anti-aromatase antibody became strongly positive about 12 h before ovulation and the became very weak suddenly after ovulation. In rat-ovaries, the pregnant corpora lutea was positively stained for aromatase after day 7 of pregnancy.This study was supported by Grants from the Ministry of Education, Science and Culture, Japan, and from USPHS Research Grants HD04945, USA     

Characterization of large luteal cells and their secretory granules during the estrous cycle of the cow.

Large steroidogenic cells of the bovine corpora lutea were evaluated for morphological changes on Days 3, 7, 11, 14, 17, and 19 of the estrous cycle. Large cells were readily identified by size (25-50 microns diameter), numerous mitochondria, and the presence of dense secretory granules (150-300 nm in diameter). These granules were found in a discrete cluster and were not dispersed throughout the cytoplasm. Only 3% of the large cells contained a cluster of granules on Day 3. The percentage was highest during midcycle (Day 7, 84%; Day 11, 64%), dropped on Day 14 (26%), and was lowest on Days 17 (16%) and 19 (8%). Electron microscopic immunocytochemistry showed that oxytocin and neurophysin were co-localized in these granules on all days evaluated. As early as Day 14, large cells were observed with characteristics typical of regressing corpora lutea, i.e., a reduction in cells with secretory granules, large cytoplasmic lipid droplets, and swollen mitochondria with dense inclusions. However, since this was a time of the cycle when plasma concentrations of progesterone were very high, this corpus luteum is referred to as involutive rather than regressive. Our results may be summarized as follows: 1) from Day 7 to Day 14 there was a 69% decline in the number of large cells containing oxytocin-laden secretory granules. This occurred prior to the rise in uterine oxytocin receptors and the large luteolytic pulses of prostaglandin that reportedly occur after Day 14. The role of this apparent early release of oxytocin is not known. 2) Large steroidogenic luteal cells of the estrous cycle have morphological characteristics similar to those of large luteal cells during pregnancy. However, large luteal cells of the estrous cycle contain oxytocin whereas those of pregnancy are devoid of oxytocin.     

Variations in oxytocin, vasopressin and neurophysin concentrations in the bovine ovary during the oestrous cycle and pregnancy

Bovine ovaries were obtained from the abattoir and corpora lutea were classified as: (1) early luteal phase (approximately Days 1-4); (2) mid-luteal phase (Days 5-10); (3) late luteal phase (Days 11-17); (4) regressing (Days 18-20) and (5) pregnant (Days 90-230). In addition, preovulatory follicles and whole ovaries without luteal tissue were collected. Concentrations of oxytocin, vasopressin, bovine neurophysin I and progesterone were measured in each corpus luteum by radioimmunoassay. Progesterone and neurophysin I levels increased from Stage 1 to Stage 2, plateaued during Stage 3 and declined by Stage 4. Oxytocin and vasopressin concentrations increased from Stage 1 to Stage 2 but declined during Stage 3 and were low (oxytocin) or undetectable (vasopressin) in follicles, whole ovaries and pregnancy corpora lutea. Therefore the concentrations of both peptide hormones were maximal during the first half of the cycle and declined before those of progesterone. The high concentration of oxytocin within the corpus luteum coupled with the presence of bovine neurophysin I suggests that oxytocin is synthesized locally.