Prostaglandin-induced regression of porcine corpora lutea maintained by estrogen

Corpora lutea were marked with suture in 24 crossbred gilts on day 7 to 9 of the estrous cycle (first day of estrus = 0). All gilts were injected with 5 mg of estradiol benzoate (EB) daily from day 10 to 15 to extend the lifespan of corpora lutea, then the gilts were randomly assigned to two groups. On day 20, the 12 gilts of Group 1 were injected with 10 mg PGF_2α, and the 12 gilts of Group 2 were injected with saline. Ovaries were recovered 10 to 13 days after PGF_2α or saline injection. Ten gilts in Group 1 displayed estrus 5 ± 0.7 days after PGF_2α injection, but only two gilts in Group 2 displayed estrus during the experimental period. In gilts that displayed estrus, all marked CL had regressed. Marked CL were still present in all 12 gilts that failed to exhibit estrus during the experimental period. These results show that in the pig, PGF_2α caused regression of CL that were maintained beyond the normal luteal phase of the estrous cycle by EB treatment.     

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

Patterns of luteal lipid and arachidonic acid accumulation were examined in relation to luteal progesterone and prostaglandin F synthesis in 30 sows and gilts between days 8 and 18 of the estrous cycle. Net release of progesterone from luteal tissue declined from 722 ng/100 mg tissue at day 8 to 81 ng/100 mg tissue at day 18. Although statistical significance was not present, net prostaglandin F release increased slightly from 8.6 to 13.9 ng/100 mg tissue. Luteal free cholesterol, esterified cholesterol, and free fatty acid contents did not change between days 8 and 18 whereas triglycerides accumulated rapidly between days 14 and 18 of the estrous cycle. Phospholipids increased between days 8 and 12, plateaued at 20.2 mg/g between days 14 and 16, and decreased to 15.4 mg/g on day 18. Between days 12 and 18, arachidonic acid increased from 19.4 to 34.8% in cholesterol esters, from 10.1 to 22.5% in triglycerides, and from 12.3 to 27.2% in luteal free fatty acids. Arachidonic acid in luteal phospholipids increased from 21.3 to 25.1% between days 14 and 16 of the estrous cycle. Luteal regression was associated with conservation of arachidonic acid. Based on blood plasma lipid fatty acid compositions, the corpus luteum elongated and desaturated essential fatty acids. Within porcine corpora lutea, calculated free arachidonic acid content was adequate for maintenance of prostaglandin synthesis.     

Premature regression of the corpora lutea in superovulated cows

Morphological and functional regression of the CL was shown by $\text{15}\text{55}$ (27%) superovulated dairy cows at slaughter on D 14. Neither the routine injection of a PMSG-antiserum at the induced superovulatory oestrus, nor intrauterine infections proved to be responsible. Animals with regressed CL however had significantly lower progesterone levels in the peripheral blood at the time PMSG (D 10, P = 0,05) and prostaglandin (D 12, P = 0,02) were injected, as compared to superovulated animals with normal CL. At the induced superovulatory heat, the differences between the 2 groups disappeared. From D 4 after superovulation the differences in progesterone concentration between the 2 groups became significant again (P = 0,02 – 0,05). It is not yet clear whether the observed luteal dysfunction is due to an inadequate luteotrophic stimulus or to a premature luteolysis. The luteal regression could be caused either by a genuine luteal insufficiency of the midcyle CL or by poor heat detection.     

Stimulation of seasonally anovular merino ewes by rams. II. Premature regression of ram-induced corpora lutea

Ovulation was induced by rams in 74 of 91 seasonally anovular Merino ewes. The resulting corpora lutea (CL) were observed by laparoscopy and were found to either persist normally ($\text{38}\text{74}$), or regress prematurely ($\text{36}\text{74}$). In 32 of the latter ewes premature regression of the CL was followed by a second ovulation within 6 days of the introduction of rams.     

Absence of specific follicle stimulating hormone receptors in porcine corpora lutea

Crude cell membrane preparations of corpora lutea from 13 pigs in different phases of the estrous cycle or pregnancy were assayed for the presence of specific follicle stimulating hormone (FSH) receptors using highly purified ovine FSH. Testicular tissue from boars and granulosa cells from porcine follicles served as positive controls. Scatchard analysis was used to determine binding affinity of FSH to target tissues as well to study human chorionic gonadotropin (hCG) bindability to corpora lutea membranes. In contrast to testicular tissue and granulosa cells, no specific FSH binding was detected in luteal tissue during the estrous cycle or pregnancy in pigs.     

Lipid and arachidonic acid accumulation in naturally regressing porcine corpora lutea

Patterns of luteal lipid and arachidonic acid accumulation were examined in relation to luteal progesterone and prostaglandin F synthesis in 30 sows and gilts between days 8 and 18 of the estrous cycle. Net $\text{in vitro}$ release of progesterone from luteal tissue declined from 722 ng/100 mg tissue at day 8 to 81 ng/100 mg tissue at day 18. Although statistical significance was not present, net prostaglandin F release increased slightly from 8.6 to 13.9 ng/100 mg tissue. Luteal free cholesterol, esterified cholesterol, and free fatty acid contents did not change between days 8 and 18 whereas triglycerides accumulated rapidly between days 14 and 18 of the estrous cycle. Phospholipids increased between days 8 and 12, plateaued at 20.2 mg/g between days 14 and 16, and decreased to 15.4 mg/g on day 18. Between days 12 and 18, arachidonic acid increased from 19.4 to 34.8% in cholesterol esters, from 10.1 to 22.5% in triglycerides, and from 12.3 to 27.2% in luteal free fatty acids. Arachidonic acid in luteal phospholipids increased from 21.3 to 25.1% between days 14 and 16 of the estrous cycle. Luteal regression was associated with conservation of arachidonic acid. Based on blood plasma lipid fatty acid compositions, the corpus luteum elongated and desaturated essential fatty acids. Within porcine corpora lutea, calculated free arachidonic acid content was adequate for maintenance of prostaglandin synthesis.     

Mitogenic factors of corpora lutea

The mammalian corpus luteum (CL), which plays a central role in the reproductive process because of its production of hormones such as progesterone, appears to be an exceptionally dynamic organ. Its rate of growth and development are extremely rapid and, even when the CL is functionally mature, its rate of cell turnover remains relatively high. Associated with this high rate of cell turnover, the mature CL receives the greatest blood supply per unit tissue of any organ, and also exhibits a relatively high metabolic rate. Although numerous growth factors have been identified in luteal tissue, their role in growth and differentiation of this dynamic organ remains unclear. Recently, while attempting to identify mitogenic factors of ovine and bovine CL, we have found that they produce several mitogens during the estrous cycle as well as pregnancy. The majority of these luteal-derived mitogenic factors are heparin-binding, and although some may represent previously identified factors, several appear to be novel heparin-binding growth factors. Isolation and purification of mitogenic factors produced by the CL will enable us to determine their roles in luteal growth, development and differentiated function, which will contribute to our understanding not only of the regulation of fertility but also of tissue growth and development in general.     

Inactivation of porcine corpus luteum lutropin receptors by a microsomal enzyme. Activation in ageing and regressing corpora lutea

The binding of 125I-labelled human choriogonadotropin (hCG) to homogenates of porcine corpora lutea showed a marked departure from ideal behaviour, due to a time- and temperature-dependent inactivation of both free hormone and unoccupied receptors. Occupied receptors were not affected. Lutropin (LH)-receptor-inactivating activity was detected after preincubation of homogenates, particulate fractions and microsomes, but little activity could be demonstrated in cytosol fractions. Inactivation was dependent on the temperature and pH of preincubation, and on tissue concentration: LH-receptor inactivation was first-order with respect to preincubation time. Lutropin-receptor-inactivating activity was low in early-luteal and mid-luteal phase in pig corpora lutea, but was increased significantly in late-luteal and regressing corpora lutea.     

Formation and regression of capillary sprouts in corpora lutea of immature superstimulated golden hamsters

The ultrastructure of developing and regressing capillary sprouts was studied in corpora lutea of immature golden hamsters between days 4 and 7 after the application of serum gonadotrophin of pregnant mares (PMSG). Horseradish peroxidase (HRP), an endothelial tracer, was localized by ultrahistochemistry. The vascular permeability of HRP was quantified by an enzyme assay in ovarian homogenates. Sprouting endothelial cells looked activated. They showed micropinocytotic vesicles in a high endothelium surrounded by basal laminae. Early capillary growth was at its maximum on day 4 after PMSG. Advanced capillary growth was seen on days 4 and 5 after PMSG. The vascular lumina were formed by dilatation of the interendothelial space. Regression of capillary sprouts started on day 5, was most intense on day 6 and negligible on day 7. Two processes of regression were observed. One led to a complete destruction, the other to an incomplete one. Vascular permeability decreased between days 5 and 6 after PMSG. It is concluded that the corpus luteum can be viewed as a physiological model of angiogenesis.     

Induction of peroxidase in corpora lutea of rat ovary by lutropin.

The lutropin-induced depletion of ascorbate in corpora lutea of albino-rat ovary is shown to be associated with the induction of peroxidase in corpora lutea. An inverse relationship between ascorbate depletion and peroxidase activity was established in a time-course study with lutropin. Analyses made at different phases of the reproductive cycle are in accord with this relationship. It is suggested that ascorbate, which is a well-established donor in peroxidase reactions, undergoes rapid oxidation in the presence of this enzyme, producing an intermediate free radical which, if coupled with pregnenolone, might produce progesterone in the corpora lutea. The exact role of peroxidase in steroidogenesis, however, remains to be elucidated and established.     

In vivo oxytocin release from microdialyzed bovine corpora lutea during spontaneous and prostaglandin-induced regression

The release of luteal oxytocin during spontaneous and prostaglandin-induced luteolysis was investigated in cows. A continuous-flow microdialysis system was used in 11 cows to collect dialysates of the luteal extracellular space between Days 12 and 24 postestrus. Seven cows were untreated and were expected to exhibit spontaneous luteolysis during sampling, whereas 4 cows received prostaglandin F(2alpha) (PGF(2alpha)) systemically between Days 13 and 15 to induce luteolysis during sampling. Oxytocin was detectable in the dialysate of all cows before Day 16 postestrus and occurred as 2 or 3 discrete pulses per 12-h sampling period. For non-PGF(2alpha)-treated cows, dialysate oxytocin content began to decline spontaneously on Day 15 postestrus and was undetectable by Day 17 postestrus. Oxytocin decay curves preceded onset of serum progesterone decline by at least 72 h and were not related temporally with onset of progesterone decline within cow. Exogenous PGF(2alpha) (25 mg, i.m.) produced a 10-fold increase in dialysate oxytocin within 1 h (1.9 +/- 0.3 pg/ml to 20.8 +/- 3.0 pg/ml; P < 0. 01). Dialysate oxytocin then declined to pretreatment concentrations within 2 h and was undetectable within 8 h posttreatment. A second PGF(2alpha) injection given 20 h after the first did not result in a measurable increase in dialysate oxytocin, probably because luteolysis was underway. Although robust luteal oxytocin release was observed after treatment with a pharmacological dose of PGF(2alpha), the lack of detectable oxytocin secretion during spontaneous luteolysis suggests that the contribution of luteal oxytocin in the cow may be less than that proposed for the ewe.