In vivo and in vitro ovarian steroidogenesis in the long term hypophysectomized rat

Expression of the clock genes Per1 and Bmal1 during follicle development in the rat ovary. Effects of gonadotropin stimulation and hypophysectomy

Daily oscillations of clock genes have recently been demonstrated in the ovaries of several species. Clock gene knockout or mutant mice demonstrate a variety of reproductive defects. Accumulating evidence suggests that these rhythms act to synchronise the expression of specific ovarian genes to hypothalamo-pituitary signals and that they are regulated by one or both of the gonadotropins. The aim of this study has been to examine the spatio-temporal expression of the clock genes Per1 and Bmal1 during gonadotropin-independent and gonadotropin-dependent follicle development in the rat ovary. We have examined the ovaries of prepubertal rats, of prepubertal rats stimulated with equine chorionic gonadotropin (eCG)/human chorionic gonadotropin (hCG) and of hypophysectomised adult animals. Using quantitative reverse transcription with the polymerase chain reaction, in situ hybridisation histochemistry and immunohistochemistry, we have demonstrated that the expression of the two clock genes is low and arrhythmic in ovarian cells during early gonadotropin-independent follicle development in prepubertal animals and in hypophysectomised animals. We have also demonstrated that the expression of the clock genes becomes rhythmic following eCG stimulation in the theca interna cells and the secondary interstitial cells and that, following additional hCG stimulation, the expression of the clock genes also becomes rhythmic in the granulosa cells of preovulatory follicles. These findings link the initiation of clock gene rhythms in the rat ovary to the luteinising hormone receptor and suggest a functional link to androgen and progesterone production. In hypophysectomised animals, rhythmic clock gene expression is also observed in the corpora lutea and in secondary interstitial cells demonstrating that, in these compartments, entrainment of clock gene rhythms is gonadotropin-independent.

The molecular control of corpus luteum formation, function, and regression

The corpus luteum (CL) is one of the few endocrine glands that forms from the remains of another organ and whose function and survival are limited in scope and time. The CL is the site of rapid remodeling, growth, differentiation, and death of cells originating from granulosa, theca, capillaries, and fibroblasts. The apparent raison d'etre of the CL is the production of progesterone, and all the structural and functional features of this gland are geared toward this end. Because of its unique importance for successful pregnancies, the mammals have evolved a complex series of checks and balances that maintains progesterone at appropriate levels throughout gestation. The formation, maintenance, regression, and steroidogenesis of the CL are among the most significant and closely regulated events in mammalian reproduction. During pregnancy, the fate of the CL depends on the interplay of ovarian, pituitary, and placental regulators. At the end of its life span, the CL undergoes a process of regression leading to its disappearance from the ovary and allowing the initiation of a new cycle. The generation of transgenic, knockout and knockin mice and the development of innovative technologies have revealed a novel role of several molecules in the reprogramming of granulosa cells into luteal cells and in the hormonal and molecular control of the function and demise of the CL. The current review highlights our knowledge on these key molecular events in rodents.

Actions of prostaglandin F2alpha and prolactin on intercellular adhesion molecule-1 expression and monocyte/macrophage accumulation in the rat corpus luteum

Expression of intercellular adhesion molecule-1 (ICAM-1) and the accumulation of monocytes/macrophages are inflammatory events that occur during PRL (PRL)-induced regression of the rat corpus luteum. Here we have compared the ability of prostaglandin F2alpha (PGF) and PRL to induce, in rat corpora lutea, inflammatory events thought to perpetuate luteal regression. Immature rats were ovulated with eCG-hCG and then hypophysectomized (Day 0), which resulted in a single cohort of persistent, functional corpora lutea. On Days 9-11, the rats received twice daily injections of saline, PGF (Lutalyse, 250 microg/injection), or PRL (312 microg/injection) to induce luteal regression. Surprisingly, luteal weight and plasma progestin concentrations (progesterone and 20alpha-dihydroprogesterone) did not differ between PGF-treated rats and controls; whereas both luteal weight and plasma progestins declined significantly in PRL-treated rats. Furthermore, corpora lutea of PGF-treated rats and controls contained relatively minimal ICAM-1 staining and few monocytes/macrophages. In contrast, but as expected, corpora lutea of PRL-treated rats stained intensely for ICAM-1 and contained numerous monocytes/macrophages. In an additional experiment, there was no indication that luteal prostaglandin F2alpha receptor mRNA diminished as a result of hypophysectomy. These findings suggest that prolactin, not PGF, induces the inflammatory events that accompany regression of the rat corpus luteum.

Repeated exposure to prolactin is required to induce luteal regression in the hypophysectomized rat

We investigated whether prolactin (PRL) treatments resembling the intermittent PRL surges of estrous cycles could induce luteal regression in hypophysectomized rats. Immature female rats were stimulated to ovulate and form corpora lutea with exogenous gonadotropins, and were hypophysectomized following ovulation. A single s.c. injection of either vehicle (VEH) or PRL was administered to each rat on post-hypophysectomy Day 8 and again on Day 11. The four resulting treatment groups consisted of rats that received two injections of VEH, VEH followed by PRL, PRL followed by VEH, or two injections of PRL. Rats were killed 24 or 72 h following the second injection. Plasma 20alpha-dihydroprogesterone, luteal weight, and total luteal protein were determined. One ovary was sectioned for immunohistochemistry for monocytes/macrophages, apoptotic nuclei, and major histocompatibility class II (MHC II) molecules. No effect of time (following injection) was observed on any endpoint, indicating that PRL does not have an ongoing regressive action. Time groups from within each treatment group were therefore pooled for analysis. Significant declines (P: < 0.05) in plasma concentrations of 20alpha-dihydroprogesterone, luteal weight, and protein per corpus luteum occurred only after two injections of PRL. Numbers of luteal monocytes/macrophages, apoptotic nuclei, and MHC II-positive cells were low in all groups; numbers of luteal monocytes/macrophages increased following two injections of PRL (P: < 0.05). We conclude that PRL has a cumulative regressive effect on the corpus luteum of the hypophysectomized rat. Drawing a parallel with the estrous cycle, we suggest that continued exposure to PRL, over several cycles, is necessary to induce full luteal regression.

Prolactin-induced expression of intercellular adhesion molecule-1 and the accumulation of monocytes/macrophages during regression of the rat corpus luteum

Intercellular adhesion molecule-1 (ICAM-1) is thought to facilitate the recruitment and migration of monocytes/macrophages to sites of inflammation. Here we investigated whether the luteolytic effect of prolactin in the hypophysectomized rat is associated with the expression of ICAM-1. In addition, we examined the effect of exogenous testosterone (or its potential conversion to estradiol endogenously) on the corpus luteum to address recent speculation that ovarian steroids might augment luteal regression. Immature, 30-day-old rats were ovulated with eCG and hCG and then hypophysectomized; this resulted in a single cohort of persistent corpora lutea. The rats were assigned randomly into four treatment groups: vehicle treatment without or with testosterone (VEH-T4, VEH+T4) and prolactin treatment without or with testosterone (PRL-T4, PRL+T4). Corpora lutea of control rats exhibited minimal ICAM-1 staining and contained relatively few monocytes/macrophages. In contrast, corpora lutea of prolactin-treated rats exhibited prominent ICAM-1 staining and contained numerous monocytes/macrophages. Testosterone did not overtly affect ICAM-1 staining, numbers of monocytes/macrophages, or concentrations of plasma progestins (progesterone and 20alpha-dihydroprogesterone) in either VEH or prolactin treatment groups; notwithstanding, luteal weights increased significantly in response to testosterone in VEH+T4 rats compared to VEH-T4 rats and prolactin-treated rats. We conclude that ICAM-1 expression and monocyte/macrophage accumulation are associated with prolactin-induced luteal regression in the rat and that these aspects are not influenced by testosterone.

The proestrous prolactin surge is not the sole initiator of regressive changes in corpora lutea of normally cycling rats

During the estrous cycle, secretion of prolactin is largely restricted to a surge on proestrus. We investigated whether this proestrous prolactin surge initiates regression of the corpora lutea of the preceding cycle. Adult rats were killed prior to the prolactin surge (Proestrus group), following the prolactin surge (Estrus group), after chemical blockade of the prolactin surge with bromocryptine (Estrus+BRC group), and after blockade of the prolactin surge and administration of prolactin (Estrus+BRC+PRL group). Corpora lutea of the current (proestrus) or preceding (estrus) cycle were dissected out, weighed, and sectioned for immunohistochemistry or cultured for examination of in vitro progestin production. Numbers of luteal monocytes/macrophages, differentiated macrophages, and apoptotic nuclei per high-power field were greater for Estrus and Estrus+BRC+PRL than for Estrus+BRC, which in turn had greater numbers than Proestrus (P< 0.05). In contrast, BRC completely reversed the decline in luteal weight observed between Proestrus and Estrus (P<0.05). Number of major histocompatibility complex II-positive cells was not different between groups (P>0.05). Finally, progestin production by corpora lutea in vitro was lower for Proestrus than for the other groups (P<0.05). The results indicate that the prolactin surge alone is not responsible for initiation of apoptosis or immune cell infiltration in regressing corpora lutea of the estrous cycle, although prolactin increases these markers of regression. Prolactin does cause a decline in luteal weight; however, the corpora lutea retain the capacity for steroidogenesis. We conclude that although prolactin has a role in luteal regression, it is not solely responsible for the initiation of this process.

Glucocorticoids stimulate the accumulation of lipids in the rat corpus luteum

We investigated the physiological basis for the trophic effect of glucocorticoids in rat corpora lutea in the absence of pituitary gonadotropins. Immature (Day 29) Sprague-Dawley rats were given eCG and hCG to induce the development of corpora lutea and were hypophysectomized on Day 32. Beginning on Day 40, rats received twice-daily s.c. injections of either dexamethasone (dex; 200 microg/rat/day) or vehicle (controls) and then were killed on Day 44. Plasma 20alpha-dihydroprogesterone, a major steroid produced by the corpora lutea, was higher (p </= 0.01) in dex-treated than in control rats (44.5 +/- 2.3 vs. 23.0 +/- 5.6 ng/ml). Dexamethasone treatment increased lipid droplets and lipid in the corpora lutea as revealed by electron microscopy and oil red O staining. Cholesterol esters were higher in corpora lutea of dex-treated rats compared to controls (14.8 +/- 1.1 vs. 2.2 +/- 0.5 microg/mg corpora lutea wet tissue, respectively; p </= 0.05). Another group of hypophysectomized rats was treated with either a high or a lower dosage of corticosterone, both of which caused an elevation to > 2-fold of plasma 20alpha-dihydroprogesterone concentration compared to controls. Glucocorticoid receptor protein (about 92 kDa) was detected in both luteal and nonluteal ovarian tissues in this animal model. These effects of glucocorticoids and the presence of the glucocorticoid receptor raise the possibility of a physiological role for glucocorticoids in the rat corpus luteum.

Luteal regression in the normally cycling rat: apoptosis, monocyte chemoattractant protein-1, and inflammatory cell involvement

In hypophysectomized rats, prolactin induces regression of the corpora lutea. Luteal regression is accompanied by infiltration of monocytes/macrophages, declines in luteal mass and plasma progestins, and increased staining for monocyte chemoattractant protein-1 (MCP-1). We investigated whether similar events are induced during the estrous cycle, after the proestrous prolactin surge. Rats were killed on proestrus or on estrus, and one ovary was frozen for immunohistochemical detection of MCP-1, monocytes/macrophages (ED1-positive), and differentiated macrophages (ED2-positive) and for in situ detection of apoptotic nuclei. Corpora lutea of the current (proestrus) or preceding (estrus) cycle were dissected from the ovaries of additional rats and frozen for the same analyses and for determination of total protein content. In sections of whole ovaries, intensity and distribution of MCP-1 staining were increased in corpora lutea of multiple ages on estrus as compared to proestrus, as were numbers of differentiated macrophages and apoptotic nuclei per high-power field. Sections of isolated corpora lutea showed these increases on estrus, and the number of monocytes/macrophages per high-power field was also significantly increased. Accompanying these inflammatory/immune events, the corpora lutea on estrus showed decreased weight and total protein per corpus luteum, as compared to corpora lutea on proestrus. These changes are consistent with a proposed role for prolactin in the initiation of luteal apoptosis and of a sequence of inflammatory/immune events that accompany regression of the rat corpus luteum during the normal estrous cycle.

Steroid synthesis in ovarian homogenates from hypophysectomized adult female mice treated with diethylstilbestrol in neonatal life

Eight-week-old female NMRI-mice treated with 5 micrograms diethylstilbestrol (DES) or vehicle (olive oil) from d 1 to 5 after birth were hypophysectomized or sham operated. Thirty days after the operation, homogenates were prepared from the ovaries and incubated at 37 degrees C in the presence of [3H]pregnenolone for 1 h. In parallel experiments ovaries were taken for histology. In control ovaries regressing corpora lutea were still present 4 wk after hypophysectomy (Hx). Ovaries from DES females had no corpora lutea, but showed degeneration of the pre-Hx hypertrophic interstitial tissue. Steroids synthesized during the incubation were extracted and separated in a two-dimensional thin-layer chromatography system. After Hx, the amount of extractable [3H]testosterone, [3H]progesterone, and [3H]androstenedione recovered from homogenates of vehicle-treated females increased, but the amount of recovered [3H]-17 alpha-hydroxyprogesterone was not significantly altered. In contrast, in DES-treated females Hx significantly decreased levels of [3H]androstenedione and [3H]-17 alpha-hydroxyprogesterone, but did not affect [3H]progesterone or [3H]testosterone. The persistent difference in steroid synthetic activity after Hx could be linked to the difference in morphology between different ovarian tissue compartments of control and DES-treated females.

Evidence for rapid loss of spare hCG receptors in the corpora lutea of the hypophysectomized rat

In pregnant mare serum gonadotropin treated immature rats hypophysectomized on the day of ovulation (day 1) the corpora lutea (CL) persist as normal morphological structures and produce steroids, especially 20 alpha-dihydroprogesterone (20 alpha-DHP), for at least 40 days (Taya and Greenwald, 1982), although there is a rapid decline in human chorionic gonadotropin (hCG) binding sites (Kim and Greenwald, 1984). In this study the number of occupied and non-occupied hCG receptors in CL from hypophysectomized rats decreased to 14% and 36%, respectively, compared to intact day 5 pseudopregnant animals, but the binding affinity was unchanged. Decreased concentration of occupied hCG receptors paralleled hormonal levels of serum luteinizing hormone (LH) which were measurable in only 9 out of 20 animals and were near the lower limits of the assay (40 pg/ml). Luteal progesterone (P4) production in response to LH was markedly decreased after hypophysectomy, but the maximal P4 response to LH and 20 alpha-DHP production in response to LH and 8-Br-cAMP were the same in hypophysectomized and intact animals. Although hCG receptor concentration in CL decreased significantly after hypophysectomy, LH-stimulated luteal production of cAMP was almost the same in both groups. These results indicate that LH spare receptors which are uncoupled from cAMP exist in the CL of the intact pseudopregnant rat and that after hypophysectomy they quickly disappear within 4 days.