Effect of atropine sulfate on the phenomena of follicular growth induced by a total anterior pituitary gonadotropic preparation during the estrus cycle in the rat

The question whether atropine inhibits follicular growth in rats induced by Gonadormone Byla was tested. 52 rats of strain WI, and 48 WII rats about 20 gm heavier, were injected at 1700 in diestrous I with 2.5 mouse units of gonadotropin per 100 gm body weight and 28 of each group also with 70 mg atropine sulfate sc, then serial ovarian sections were prepared at 1700 of proestrus. Atropine reduced the mean number of follicles 400 mcm in diameter or above (p less than .02), but did not affect their size distribution. A 2nd series of 48 rats were injected at 1700 of diestrous II with 1.5 units of gonadotropin per 100 gm body weight and half the rats with atropine. Again, atropine reduced the number of developing follicles (p less than .05) without affecting their mean diameter or size distribution.     

New data on the factors of ovarian competence in the immature and mature guinea pigs

The effects of follicle-stimulating hormone (FSH) and luteinizing hormone (LH) on ovulation and luteinization in premature and in mature female guinea pigs in different states of the estrous cycle were compared histologically. FSH and LH were administered in a horse pituitary extract (gonadormone, Byla) injected sc, and results were assessed from hematoxylin and eosin-stained serial sections of the ovaries, removed 24 hours later. In premature guinea pigs (mean weight 233 gm) the threshold dose of gonadormone was .1-1 U for luteinization, and results from different seasons did not differ, so experiments were pooled. At .5 U, 17 of 32 (53%) animals had luteinized follicles, compared to 44 of 56 (79%) given 1 U (p.02). Of these luteinized follicles 2 of 17 (12%) animals had ovulated, or .25 (coefficient of ovulation) of luteinized follicles at .1 U, while 10 of 44 (23%) animals ovulated, or .61 of luteinized follicles ovulated at 1 U. 35 or 70 mg atropine S04 per 100 gm body weight did not affect luteinization induced by 1 U gonadormone. In mature guinea pigs (mean weight 415 gm), 2 of 5 U gonadormone at the beginning of vaginal closure caused luteinization, usually with eggs enclosed (pseudopregnancy), or atresia, in more than 1/2 of the animals. On Day 8 after vaginal closure, 7 of 9 (78%) animals had corpora lutea with enclosed eggs, after receiving 1 U gonadormone. On Day 12, 18 of 51 (35%) animals had corpora lutea with enclosed eggs, 12 of 51 (24%) had postovulatory corpora lutea, and 9 of 51 (18%) had both. Atropine S04 again had no effect on luteinization. If the young guinea pigs given .1 U and the mature guinea pigs given 1 U were compared, the frequency of luteinization was 53% and 76%, respectively (p.05); the frequency of ovulation among animals with luteinization was 12% and 23%, respectively (p.01); and the coefficient of ovulation among luteinized follicles was .25 and .78, respectively (p.05). Therefore, degrees of competence can be assigned since mature follicles at the end of the cycle were more responsive than follicles from premature guinea pigs, whose follicles in turn were more responsive than early follicles of mature guinea pigs.     

Qualitative and quantitative data on experimental luteinization in the female rat

The dose-effect of 1.5-16 mcg luteinizing hormone (LH) per 100 gm body weight injected in rats at 1100-1200 on proestrus was compared with 30 mg meprobamate given to controls at the same time, on luteinization and ovulation seen in serial ovarian sections. The WII Wistar rats were killed. Luteinization with or without ovulation increased with dose (1.5, 3, 5, 8, and 16 mcg) of LH to a plateau (90%) above the 5 mcg dose, compared with 18% in controls. 2-5 animals in each dose group had preluteinized follicles, characterized by a dissociation of the cumulus oophorus from the granulosa. The absolute frequency of ovulation increased linearly with LH dose, but the frequency of ovulation among rats that luteinized was invariant. The coefficient of ovulation, calculated as the mean incidence of ovulation in relation to the total number of luteinized or preluteinized follicles in each rat, decreased from .769 in controls to .580 in the 3 mcg group, then rose to .916 in the 16 mcg group. Thus, in proestrous rats, low doses of LH induce corpora lutea with retained ova. The threshold dose of LH for luteinization and for ovulation is lower in proestrus than in diestrus II, but varies slightly in different strains of rats.     

Luteinizing hormone-independent luteinization and ovulation in the hypophysectomized rat: a possible role for the oocyte?

Immature hypophysectomized, estrogen-treated rats were used to study the regulation of luteinization. Particular attention was focused on the potential role of the oocyte in this process. Rats were injected for 2 days with follicle-stimulating hormone (FSH) to stimulate follicular development. Within 48 h following FSH treatment, many follicles became luteinized, as determined by morphometric analysis. This luteinization occurred in the absence of detectable levels of luteinizing hormone (LH). The number of follicles undergoing luteinization was dependent on the FSH dose. In addition, ovulation occurred in some of the animals receiving the highest doses of FSH (3-micrograms or 5-micrograms injections). The majority of follicles undergoing luteinization or ovulation were greater than 400 microns in diameter. Luteinized follicles exhibited positive reactivity for cholesterol side-chain cleavage enzyme, 3 beta-hydroxysteroid dehydrogenase, lipid, and alkaline phosphatase, which was similar to that found in corpora lutea of the cycle. Serum progesterone (P0) and 20 alpha-hydroxypregn-4-en-one levels were elevated in animals with luteinized follicles, especially in those animals that also underwent ovulation. Morphological evaluation of oocytes showed that the majority of luteinized follicles contained a degenerating oocyte. Oocyte degeneration was highly correlated (r = 0.94) to luteinization. These results demonstrate that luteinization and ovulation can occur in the FSH/estrogen-primed hypophysectomized rats in the absence of detectable serum LH. Furthermore, LH-independent luteinization was strongly correlated to degenerative changes in the oocyte. These results provide new evidence to support the concept that the oocyte may be an intraovarian regulator of luteinization.     

Olfactory environment and coitus-induced ovulation and/or luteinization in the cyclic female rat

The role of pheromones in the process of ovulation and/or luteinization induced by coitus was studied in female rats primed with estradiol benzoate (EB) and early mated during 4-day cycles. The effects of coitus were evaluated by using 1) the proportion of females displaying postovulatory corpora lutea (POCL) and/or luteinized unruptured follicles (LUF), and 2) the ovulation coefficient (OC) computed in each female by dividing the number of POCL by the total number of POCL and LUF. A greater proportion of females displayed ovulation and/or luteinization following coitus than those given EB only. This proportion was slightly but significantly increased when females were exposed to bedding soiled with 5 ml of male urine prior to mating, an effect prevented by complete olfactory bulbectomy. However, in the females given EB only, the pheromonal stimulus remained inefficient. Weak ovulatory effects of coitus, as assessed by low OC values, were noted whether the females were exposed or not to male urine. An increase in the frequency of lordosis occurred after olfactory bulbectomy, but no significant changes in OC values were observed in this experimental group. It was concluded that pheromones, act as a primer on the neuroendocrine mechanisms governing ovulation in the cyclic female rat, as in other species of rodents.     

The critical period in which splenectomy causes functional disorder of the ovary in adult rats

On account of recent reports suggesting that ovulation and luteinization involve immunological reactions, we examined the effect of splenectomy in rats on the recurrence of an estrous cycle. The spleen was removed from adult female rats at various times during an estrous cycle. A delay in ovulation was specifically induced in the rats splenectomized on the metestrous morning between 0700 and 0900 h. This delay in ovulation was reversed by an injection of splenocytes obtained either from estrous or metestrous donors, but not from diestrous or proestrous donors. The isolated splenic macrophage preparation mimicked the effect of splenocytes. Measurement of progestin levels throughout the estrous cycle suggested that the delay in ovulation was caused primarily by a delay in luteolysis; progesterone levels in ovulation delayed rats were higher and 20 alpha-dihydroprogesterone levels were lower than those of intact rats on the diestrous day. These results suggest that the macrophages in the spleen under the influence of endocrine milieu probably play a role in the recurrence of an estrous cycle by controlling luteolysis. The specific time of splenectomy to cause delay in ovulation will afford a new approach in analyzing the function of immunocytes in the ovary.     

Interference with the preovulatory luteinizing hormone surge and blockade of ovulation in immature pregnant mare's serum gonadotropin-primed rats with the anti-androgenic drug, hydroxyflutamide

The involvement of androgens in the control of ovulation has been assessed by administration of the androgen antagonist, hydroxyflutamide, to prepubertal rats treated with pregnant mare's serum gonadotropin (PMSG) to induce first estrus and ovulation. Without human chorionic gonadotropin (hCG) injection, only 46% of rats that received six 5-mg, s.c. injections of hydroxyflutamide at 12-h intervals, beginning an hour before s.c. injection of 4 IU PMSG on Day-2 (Day 0 = the day of proestrus), had ovulated a mean of 1.3 +/- 0.4 oocytes per rat when killed on the morning of Day 1, whereas 92% of sesame oil-treated controls had ovulated a mean of 6.9 +/- 0.6 oocytes. After i.p. injection of hCG at 1600 h on Day 0, 92% of hydroxyflutamide-treated rats ovulated a mean of 8.3 +/- 1.2 oocytes compared to 100% of controls, which ovulated 7.3 +/- 0.4 oocytes per rat: these groups were not significantly different from each other, nor from control rats that received no hCG. Thus, exogenous hCG completely overcame the inhibitory effect of hydroxyflutamide on ovulation. Rats treated with PMSG and hydroxyflutamide without hCG were killed either on the morning of Day 0 to determine serum and ovarian steroid levels or on the afternoon of Day 0 to determine serum LH levels. Serum levels of estradiol-17 beta and testosterone in hydroxyflutamide-treated rats were significantly higher (178% and 75%, respectively; p less than 0.01) than levels observed in controls on the morning of Day 0. Ovarian concentrations of the steroids were also elevated in hydroxyflutamide-treated rats (p less than 0.01 for testosterone only).(ABSTRACT TRUNCATED AT 250 WORDS)     

Inhibition of ovulation in rabbits by intrafollicular injection of indomethacin and prostaglandin F antiserum

Indomethacin, an inhibitor of prostaglandin biosynthesis, was 100% effective in blocking luteinizing hormone (LH)-induced ovulation when administered via microinjection directly into 22 follicles in twelve rabbits, 5 hours after intravenous injection of the gonadotropin. Ovulation was similarly blocked in 24 of 25 follicles injected with antiserum prepared against prostaglandin F_2α. Antiserum against prostaglandin E₂, at the same dosage (100 μg lyophilized serum per follicle), was considerably less effective, preventing ovulation in only 6 of 14 follicles. Control follicles injected with the phosphate buffer vehicle, or with normal rabbit serum, underwent normal ovulation and luteinization. LH injection caused a striking increase in concentration of F-type prostaglandins in follicles shortly before ovulation, an increase which was prevented by i.v. or intrafollicular injection of ovulation-blocking blocking dosages of indomethacin. These findings provide evidence in support of a role for prostaglandins, acting at the follicular level, in the process of ovulation.     

Gonadotropin and steroid control of granulosa cell proliferation during the periovulatory interval in rhesus monkeys

Progesterone produced in response to the midcycle gonadotropin surge is essential for ovulation and luteinization of the primate follicle. Because cell-cycle arrest is associated with the initiation of luteinization, this study was designed to determine the dynamics and regulation of granulosa cell proliferation by gonadotropin and progesterone during the periovulatory interval in the primate follicle. Granulosa cells or ovaries were obtained from macaques undergoing controlled ovarian stimulation either before (0 h) or as long as 36 h following the administration of an ovulatory hCG bolus with or without a 3beta-hydroxysteroid dehydrogenase inhibitor with or without a nonmetabolizable progestin. The percentage of cells staining positive for Ki-67, a nuclear marker for cell proliferation, decreased (P < 0.05) within 12 h of hCG administration in a steroid-independent manner. Levels of cyclin D2 and E mRNA did not decline during the periovulatory interval; however, cyclin B1 mRNA was reduced significantly by 12 h. Steroid depletion increased (P < 0.05) cyclin B1 mRNA at both 12 and 36 h post-hCG and was reversible by progestin replacement at 36 h. The cyclin-dependent kinase inhibitor p21(Cip1) was transiently increased 12 h post-hCG, whereas p27(Kip1) mRNA levels increased at 36 h in a steroid-independent fashion. These data suggest that a gonadotropin bolus inhibits mitosis in granulosa cells early (12 h) in the periovulatory interval, whereas progesterone may play a later, antiproliferative role in luteinized cells of primates.     

Blockade of the preovulatory release of gonadotropins and prolactin by spinal transections in female rats

The effect of spinal transections on the preovulatory release of gonadotropins and PRL was investigated in female rats. A preovulatory rise in serum LH, FSH and PRL and subsequent ovulation were prevented by complete spinal transections (CST) at high thoracic levels (T3-T7), but not at low thoracic and lumbar levels (T8-L5), performed at 1000-1230 h on proestrus. Norepinephrine (NE) concentrations in the preoptic-anterior hypothalamic area at 1700-1800 h on proestrus were also significantly reduced by CST at high thoracic levels, but not at lumbar levels. Either electrochemical stimulation of the suprachiasmatic part of the preoptic area or NE injection into the third ventricle at 1400-1500 h on proestrus restored ovulation in animals with CST at high thoracic levels. Animals with CST at lumbar levels exhibited relatively regular 4-day cycles, but those with CST at high thoracic levels showed prolonged periods of diestrous (8-20 days) before they resumed cyclicity. In the case of partial transections, bilateral transections of the lateral columns, but not transections of the dorsal or medial columns, of the spinal cord at T4-T5 significantly blocked the preovulatory gonadotropin release and the occurrence of ovulation. Unilateral transections of the lateral columns of the spinal cord or unilateral electrolytic lesions of the ventrolateral part of the medulla oblongata (VLMO) failed to block ovulation. When combinations of them were performed ipsilaterally, ovulation occurred, but when they were performed contralaterally, the incidence of ovulation was significantly decreased.(ABSTRACT TRUNCATED AT 250 WORDS)     

Deslorelin on Day 8 or 12 postovulation does not luteinize follicles during an artificially maintained diestrous phase in the mare

Practical estrus synchronization schemes are needed for mares. The Ovsynch synchronization protocol for cattle involves the administration of gonadotropin-releasing hormone (GnRH) to induce ovulation or luteinization of dominant follicles during the luteal phase and prostaglandin 7 days later to cause regression of any luteal tissue and development of a preovulatory follicle. An Ovsynch-type synchronization program potentially could be developed for horses if luteinization or ovulation of diestrous follicles occurred in response to GnRH treatment. The objective of this study was to determine if administration of the GnRH agonist, deslorelin acetate, on Day 8 or 12 postovulation would induce luteinization or ovulation of diestrous follicles in the mare. The model used was cycling mares maintained in an artificial luteal phase by administration of a synthetic progestin following prostaglandin-induced luteal regression. On the day of ovulation, 21 light horse mares were randomly assigned to one of three groups: (1) no GnRH, altrenogest from Days 5 to 15 postovulation with prostaglandin on Day 15; (2) GnRH on Day 8, altrenogest from Days 5 to 15 with prostaglandin given on Day 6 to induce luteolysis of the primary corpus luteum, an implant containing 2.1mg of deslorelin acetate inserted on Day 8 and removed on Day 10, with a second prostaglandin treatment on Day 15; (3) GnRH on Day 12, altrenogest from Days 9 to 19, prostaglandin on Day 10, a deslorelin acetate implant injected on Day 12 (subsequently removed on Day 14), and a second dose of prostaglandin administered on Day 19. Follicular development was monitored every other day from Day 5 until a 30-mm sized follicle was observed, and then daily to detection of ovulation. Serum progesterone concentrations were determined daily for 12 consecutive days. Progesterone concentrations in Group 1 remained elevated until approximately Day 12 postovulation. Prostaglandin administration on Day 15 resulted in complete luteolysis in all seven mares. In Group 2, progesterone concentrations in six of seven mares declined to baseline after prostaglandin treatment. No increase in serum progesterone was noted in any of the six mares that were given GnRH on Day 8, including three mares that had diestrous follicles > or =30mm in diameter at the time of treatment. Similarly, progesterone concentrations in six of seven mares in Group 3 declined to baseline after prostaglandin and there was no increase in progesterone after administration of GnRH on Day 12. No ultrasound evidence of luteinization or ovulation of diestrous follicles were noted after GnRH administration in any mares of Group 2 or 3. In conclusion, administration of the GnRH agonist deslorelin acetate to mares failed to induce luteinization or ovulation of diestrous follicles. Consequently, the Ovsynch program (as used in cattle) has little efficacy for synchronization of estrus in mares.     

Effects of luteinizing hormone on superovulatory and steroidogenic responses of rat ovaries to infusion with follicle-stimulating hormone

Immature female rats were infused s.c. continuously over a 60-h period with a partially purified porcine pituitary follicle-stimulating hormone (FSH) preparation having FSH activity 4.2 x NIH-FSH-S1 and luteinizing hormone (LH) activity 0.022 x NIH-LH-S1. High rates of superovulation were observed in rats receiving 1 U FSH/day, with 69 +/- 11 oocytes/rat recovered as cumulus-enclosed oocytes from oviducts on Day 1 (equivalent to the day of estrus). Addition of LH to the FSH, at dosages equivalent to 2.5-100 micrograms/day NIH-LH-S1 equivalents (2.5-100 mU) resulted in a dose-related inhibition of superovulation, reaching a nadir of 15 +/- 7 oocytes recovered from rats receiving 50 mU LH/day together with 1 U FSH/day. At the two highest LH doses, 50 and 100 mU/day, ovulation was advanced so that 12 +/- 3 and 15 +/- 4 oocytes, respectively, were recovered from oviducts of these rats flushed on the morning of Day 0, compared to none in rats infused with FSH alone. Ovarian steroid concentrations (ng/mg) observed on the morning of Day 0 in rats infused with FSH alone were progesterone, 0.50 +/- 0.13; testosterone, 0.16 +/- 0.08; androstenedione, 0.06; and estradiol, 0.23 +/- 0.05. On the morning of Day 1, ovarian progesterone concentrations in rats infused with FSH alone had risen to 3.30 +/- 0.33 ng/mg, whereas concentrations of testosterone, androstenedione, and estradiol, had fallen to essentially undetectable levels. Addition of LH to the FSH infusion resulted in dose-related increases, on Day 0, of all four steroids up to a dosage of 25 mU LH/day. At higher LH dosages, Day 0 ovarian concentrations of androgens and estradiol fell markedly, while progesterone concentrations continued to increase. Histological examination of ovaries revealed increases in the extent of luteinization of granulosa cells in follicles with retained oocytes on both Days 0 and 1 in rats infused with 25 and 50 mU LH/day together with 1 U FSH/day, compared to those observed in rats receiving FSH alone. These findings indicate that the elevated progesterone levels on Day 0 and inhibition of ovulation observed at these LH doses were due to premature luteinization of follicles, thus preventing ovulation. At lower LH doses, no sign (based on histologic or steroidogenic criteria) of premature luteinization was evident, suggesting that the decreased superovulation in these rats was due to decreased follicular maturation and/or increased atresia rather than to luteinization of follicles without ovulation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Regulation of follicular luteinization by a gonadotropin-releasing hormone agonist: Relationship between steroidogenesis and apoptosis

The purpose of this study was to evaluate the effects of GnRH-analog (Leuprolide acetate, LA) administration on follicular luteinization in equine chorionic gonadotropin plus human chorionic gonadotropin (eCG + hCG)-superovulated prepubertal treated rats. Results indicate that LA treatment decreases circulating levels of progesterone (P) and P accumulation in collagenase-dispersed ovarian cell cultures, though estradiol(E₂) production is increased. These data suggest that cells from the LA group may be less luteinized following gonadotropin treatment. Studies performed on histological ovarian sections after different times of eCG administration showed that LA injections produce lower amounts of corpora lutea and antral follicles, and a greater number of atretic and preantral follicles. The basal and LH-stimulated P and progestagen accumulations are decreased in incubations of corpora lutea isolated from the LA group. In addition, the mitochondrial cholesterol side-chain cleavage (P450_SCC) levels in corpora lutea from LA-treated rats are reduced, indicating that the decrease in P production observed is due in part to an alteration in the steroidogenic luteal capability. Immunocytochemical localization of nuclei exhibiting DNA fragmentation by the technique of terminal deoxynucleotidyl transferase end-labeling showed that LA treatment causes an increase in the number of apoptotic cells in preantral and antral follicles at all times studied (1, 2, 4, or 7 days of LA administration). A similar effect, though less pronounced, was observed in corpora lutea. It is concluded that LA treatment produces a failure in the steroidogenic luteal capability and an increase of apoptotic mechanisms in the ovary, producing as a consequence an interference in the follicular recruitment, growth, and luteinization induced by gonadotropins. Mol. Reprod. Dev. 51:287–294, 1998. © 1998 Wiley-Liss, Inc.     

Plasma glucagon, insulin and glucose responses to intravenous arginine infusion in the rat

Plasma glucagon (IRG), insulin and glucose responses to intravenous arginine infusion in the rat were studied. Three doses of arginine hydrochloride were infused into fasted rats: 0.2 gm/kg b.w., 0.5 gm/kg b.w., and 1 gm/kg b.w. The 0.2 gm/kg dose did not result in significant elevation of plasma IRG or insulin. Both the 0.5 and 1 gm/kg doses produced a significant increase in glucagon and insulin levels within 5 minutes of starting the infusion. The 1 gm/kg dose was most effective in stimulating secretion of both hormones. This dose produced a 250% rise in the plasma IRG compared to 80% peak rise with the 0.5 gm/kg dose (p less than .01) and 1055% rise in insulin levels compared to a peak level of 225% above baseline with the 0.5 gm/kg dose (p less than .001). These results demonstrate the effectiveness of intravenous arginine in the stimulation of glucagon and insulin secretion in the rat.     

Human chorionic gonadotropin and luteinizing hormone-releasing hormone reverse the blockade of ovulation in pregnant mare's serum gonadotropin-primed immature rats by the anti-androgenic drug, hydroxyflutamide

The present study was designed to examine mechanism(s) of the anti-ovulatory action of the anti-androgen, hydroxyflutamide (OH-F). Prepubertal rats were treated with 4 IU pregnant mare's serum gonadotropin (PMSG) (day -2) to induce first estrus and ovulation. They received OH-F in sesame oil or oil alone at 08:00 and 20:00 h on day 0 (the day of proestrus) and ovulations were assessed on the morning of day 1. Eighty-three percent of control animals ovulated with a mean of 7.7 +/- 1.1 corpora lutea per rat. Hydroxyflutamide blocked ovulation in all but 2 of the 12 rats receiving this drug alone. All of OH-F treated rats that received 5 and 25 IU human chorionic gonadotropin (hCG) ovulated with means +/- SEM of 9.1 +/- 0.1 and 7.3 +/- 1.4 corpora lutea per rat, respectively. The dose of 0.2 IU hCG was essentially ineffective, while the effect of 1.0 IU hCG was intermediate. At the dose of 20 ng and above (100 and 500 ng) luteining hormone-releasing hormone (LHRH) completely overcame the ovulation blockade in the OH-F treated animals, while a 4-ng dose was ineffective. At 18:00 h on the day of proestrus, serum LH levels in control animals were 17.56 +/- 2.60 ng/mL, which were 920% above basal levels (1.90 +/- 0.13) indicating a spontaneous LH surge. This surge was suppressed in OH-F treated rats. Injection of LHRH, at the dose of 20 ng and above, reinstated the LH release in OH-F treated animals. Thus, the anti-androgen, OH-F, inhibits ovulation in PMSG-treated immature rats through its interference with the preovulatory LH surge; the inhibition can be reversed by hCG or LHRH. Hydroxyflutamide does not appear to interfere at the level of the pituitary, but may have direct action at the hypothalamic and (or) extrahypothalamic sites involved in the generation of positive feedback signals that control LH release.     

Luteinizing and ovulatory action of oestradiol in the pregnant rat

Oestradiol injection on Day 10 of pregnancy in rats, resulted in either ovulation or luteinization in 50% of cases on Day 12. Cytological data showed that the number of pituitary LH cells decreased significantly on Day 11 in all oestradiol-treated animals whether responsive or not to oestrogen by ovarian modifications, while the number of pituitary FSH cells only decreased significantly in females with characteristic ovarian signs of preovulation. Bioassay of pituitary FSH confirmed the cytological data. It is concluded that ovulation and luteinization only occurred in the pregnant rat when oestradiol triggered off a synchronous release of LH and FSH.     

Profiles of oestradiol-17 beta and progesterone and follicular development during the reproductive season in mink (Mustela vison).

Plasma concentrations of oestradiol-17 beta and progesterone were studied in yearling mink females. The blood samples were collected from 2 March until 13 April in females not subjected to mating and in females mated on two consecutive days, early or late in the breeding season, or with 8-9 days between matings. Peaks in oestradiol-17 beta were recorded on the day of first mating, in relation to the second wave of growing follicles, and in early April, around the time when implantation should have occurred. Significant rises in progesterone were recorded from 17 to 21 March and were slightly later in females mated late in the season. Histological studies of ovaries from unmated females revealed that the number of 'active' follicles exceeded the number of degenerated or luteinized follicles until 7 April, after which the number of degenerated follicles increased rapidly. Degeneration was followed by luteinization. On 15 April, ovaries were collected from two females having 15 luteinized follicles each. These females had increased plasma concentrations of progesterone. These studies indicate that, in female mink, peaks in oestradiol-17 beta coincide with the first mating as a result of the copulatory act and that unmated females appear to experience a luteal phase in the absence of ovulation.     

Delta-9-tetrahydrocannabinol attenuates luteinizing hormone release induced by electrochemical stimulation of the medial preoptic area.

Despite diverse pharmacological actions, drugs commonly used for blocking ovulation in the rat have not been observed to exert differential effects on the LH response to preoptic stimulation, thus suggesting blocking action above the final hypothalamic GnRH pathway. To determine if ovulatory blockade by delta-9-tetrahydrocannabinol (THC) is consistent with that scheme, LH surges evoked by preoptic stimulation were contrasted with those elicited during blockade by atropine (ATR), a classic ovulation-blocking agent with which other drugs have been compared. THC (10 mg/kg) or ATR (350 mg/kg) treatment before the proestrous critical period uniformly blocked LH release and ovulation in sham-stimulated rats. Preoptic stimulation evoked LH surges after both drug treatments (p less than 0.001), peak levels increasing with the intensity of stimulation (p less than 0.05). However, both maximum LH concentration (p less than 0.05) and total integrated LH release (p less than 0.01) were lower in THC-blocked rats. Inspection of the oviducts revealed no difference in the incidence of ovulation or the number of ova discharged. The reduced LH response during THC blockade was not attributable to variation in the extent or locus of histologically determined stimulation sites. These results distinguish THC from ATR and, by extension, other blocking drugs that do not overtly affect the LH response to preoptic stimulation. Thus, ovulatory blockade by THC may involve a different mechanism, which likely includes inhibitory action within the preoptic-to-tuberal GnRH pathway.     

Effect of p-chlorophenylalanine on LH, FSH, prolactin and ovulation in the rat

The effect of p-chlorophenylalanine (PCPA: 300 mg/kg) on the rate of ovulation and plasma LH, FSH and prolactin secretion has been studied in rats at preovulatory periods (18th hour of diestrus) and post-ovulatory periods (9th hour of metaestrus). In both experimental groups, results showed that administration of PCPA caused an increase in both prolactin concentration and number of mature ovarian follicles (p less than 0.001). No changes were observed in FSH levels. LH concentration, however, decreased (p less than 0.001) and ovulation became totally inhibited. Rats treated at the 9th hour of metaestrus exhibited a marked luteinization as well as an increased number of corpus luteum in the ovaric tissue (p less than 0.001), whereas those treated at the 18th hour of diestrus underwent no luteinization and merely showed a greater number of mature ovarian follicles (p less than 0.001). PCPA, therefore, seems not to have a double effect on ovulation, LH, FSH, and prolactin secretion regardless of the pre or post-ovulatory periods. Changes observed in the ovaric tissue might be due to an increase in plasma prolactin concentration which appears earlier in the preovulatory than in the post-ovulatory treated animals. This difference may explain the double effect that has been attributed to the ovaric cycle and reproductive behavior.