Differences in the stress response of prolactin in young and aged female rats

The drawing of blood by orbital sinus puncture (OSP) under ether anesthesia is known to produce a marked increase in serum prolactin (PRL levels in young cycling female rats. The effect of this stressful procedure on PRL release was compared in young and aged female rats. Nonstressed PRL levels were obtained from blood drawn by decapitation. Whereas OSP with a one-minute ether exposure induced a marked increase in PRL levels in young rats on all days of the estrus cycle, older cycling female rats on the day of diestrus -1 and aged rats exhibiting prolonged diestrus (PD) showed virtually no increase above nonstressed levels. However, increasing the ether exposure time to five minutes did produce a rise in PRL levels. Old cycling female rats on the day of estrus and aged rats exhibiting constant estrus (CE) did show a PRL increase comparable to that seen in young animals. Ovariectomy (OVX) completely abolished the stress response seen in aged CE rats. The response, though markedly decreased, was still present in young ovariectomized rats. These experiments show that the stress-induced rise in PRL promoted by OSP under either anesthesia is markedly diminished in aged rats exhibiting a diestrus state. The attenuated response seen in these rats is believed due to factors characteristic of the diestrous state of aging.     

Opiate antagonist treatment reinstates estrous cycles in middle-aged persistent-estrous rats

Middle-aged female rats display luteinizing hormone (LH) surge deficits and cycle irregularity followed by the onset of persistent estrus (PE). The central nervous system has been identified as a primary locus of failure in PE rats, but the particular neural elements involved have not been determined. The goal of the present study was to identify a role for endogenous opioid peptides (EOP) in age-related acyclicity by evaluating the effect of opiate antagonist treatment on vaginal cytology in PE rats. PE rats were administered, s.c., saline (SAL), naloxone (NAL) or naltrexone (NTX) once daily for 20 days, or repetitively on Day 1 and on successive proestrus days if cyclicity was resumed. Single NTX (50 mg/kg), but not NAL (2 mg/kg), treatment interrupted the PE state in almost half of treated animals. Daily or repetitive proestrus NTX (10 mg/kg) treatment interrupted PE more frequently, and many animals displayed repeated estrous cycles and ovulation. Afternoon LH surges were observed after initial NTX treatment in animals displaying PE interruption. This demonstration that LH surges and ovulatory cycles can be reinitiated in PE rats with NTX suggests that dysfunction in the 'brake' on EOP secretion during proestrus may be one of the neuroendocrine impairments mediating acyclicity in aging female rats.     

A secondary surge of prolactin on the estrus afternoon

It has been described that throughout the estrous cycle of the rat, plasma prolactin (PRL) is basal except on proestrus afternoon when a preovulatory surge occurs. However, there have been controversies about PRL levels on the estrus day. Thus, the aim of this study was to evaluate the existence of a secondary surge of PRL on estrus afternoon and correlate it with plasma estradiol levels. The jugular vein of cycling rats was cannulated at 14:00 h on proestrus and a blood sample was withdrawn at 17:00 h for plasma LH measurement and determination of the preovulatory LH surge occurrence. In order to exclude the regular cycling rats that do not present the gonadotropins preovulatory surge and do not ovulate, only rats showing the LH surge on proestrus were considered in this study. Blood samples were collected hourly during estrus from midnight to 9:00 h (group 1) and from 10:00 to 18:00 h (group 2). In group 1, PRL showed a descending profile from midnight to 9:00 h, whereas the estradiol concentrations were constant. In group 2, a secondary surge of PRL was observed in 20 of 25 (80%) rats and plasma estradiol remained constant, but was higher in animals with the PRL surge. Thus the present data suggest the occurrence of a secondary surge of PRL in the afternoon of estrus that seems to be related to plasma estradiol levels of estrus day, which might exert only a permissive role in this surge generation.     

Seasonally Dependent Effect of Ectopic Pituitary Grafts on 24-Hour Rhythms in Serum Prolactin and Gonadotropins in Rats

To assess to what extent the presence of an ectopic pituitary differentially affected circulating prolactin (PRL) and gonadotropin levels at different times of the year, rats kept under 12h light, 12h dark (12:12 LD) photoperi-ods and receiving a pituitary graft or a sham operation in summer or winter were examined 3 months later. In both male and female sham-operated rats, a circadian variation in serum PRL levels was found, with an acrophase varying from 21:53h to 00:54h and the mesor and amplitude higher in spring than autumn in males and higher in autumn than in spring in females. After grafting a pituitary, changes in serum PRL related to time of day were no longer observed. In pituitary-grafted male rats killed during spring, serum PRL levels were higher than controls at only a few time points throughout the 24h cycle, whereas in rats killed during autumn, there were no significant differences in PRL levels between grafted and control rats. Pituitary-grafted female rats killed during spring showed serum PRL levels significantly higher than those of sham-operated rats, while in female rats killed in autumn, PRL levels of pituitary-grafted and sham-operated rats did not differ. Significant variations of luteinizing hormone (LH) related to time of day were found in sham-operated male rats only, with acrophases at 23:52h and 00:24h for spring and autumn, respectively, and the mesor and amplitude of the rhythm significantly higher in autumn. Pituitary transplants suppressed 24h variations in circulating LH and depressed its levels during the two seasons examined. As far as follicle-stimulating hormone (FSH), pituitary grafts decreased circulating levels, with the extent of decrease higher during autumn than in spring. The results indicate that some endocrine consequences of the grafting of an ectopic pituitary are dependent on time of year.     

Differential changes in the mechanisms controlling luteinizing hormone and prolactin secretion in middle-aged female rats

Serum luteinizing hormone (LH) and prolactin (PRL) concentrations were measured in young (3-4 month old) and middle-aged (10-12 month old) intact female rats on proestrus, in ovariectomized rats after two estrogen injections (estradiol benzoate; EB, 10 micrograms/100 g body weight, s.c.) or after preoptic stimulation in EB-primed ovariectomized rats. Only animals showing regular 4-day estrous cycles were selected for the experiment. The magnitude of proestrous LH surge was significantly smaller in middle-aged than in young rats. Two BE injections, at noon on Days 0 and 3, in ovariectomized middle-aged rats failed to induce surges in LH secretion on Day 4 whereas the same treatment produced LH surges in ovariectomized young rats. The preoptic electrochemical stimulation (50 microA for 60 sec) produced a prompt rise in serum LH levels in ovariectomized EB-primed young but not in middle aged rats. The preoptic stimulation with a larger current (200 microA) induced LH secretin in middle-aged rats. In none of these situations serum PRL concentrations were different between young and middle-age rats. These results suggest differential aging rates in the preoptic mechanisms governing LH and PRL secretion in the rat. The function of the preoptic ovulatory center in responding to the estrogen positive feedback action and inducing LH secretion may become impaired and independent of the PRL control mechanism, even before the regular estrous cycle terminates.     

Seasonally Dependent Effect of Ectopic Pituitary Grafts on 24-Hour Rhythms in Serum Prolactin and Gonadotropins in Rats

To assess to what extent the presence of an ectopic pituitary differentially affected circulating prolactin (PRL) and gonadotropin levels at different times of the year, rats kept under 12h light, 12h dark (12:12 LD) photoperi-ods and receiving a pituitary graft or a sham operation in summer or winter were examined 3 months later. In both male and female sham-operated rats, a circadian variation in serum PRL levels was found, with an acrophase varying from 21:53h to 00:54h and the mesor and amplitude higher in spring than autumn in males and higher in autumn than in spring in females. After grafting a pituitary, changes in serum PRL related to time of day were no longer observed. In pituitary-grafted male rats killed during spring, serum PRL levels were higher than controls at only a few time points throughout the 24h cycle, whereas in rats killed during autumn, there were no significant differences in PRL levels between grafted and control rats. Pituitary-grafted female rats killed during spring showed serum PRL levels significantly higher than those of sham-operated rats, while in female rats killed in autumn, PRL levels of pituitary-grafted and sham-operated rats did not differ. Significant variations of luteinizing hormone (LH) related to time of day were found in sham-operated male rats only, with acrophases at 23:52h and 00:24h for spring and autumn, respectively, and the mesor and amplitude of the rhythm significantly higher in autumn. Pituitary transplants suppressed 24h variations in circulating LH and depressed its levels during the two seasons examined. As far as follicle-stimulating hormone (FSH), pituitary grafts decreased circulating levels, with the extent of decrease higher during autumn than in spring. The results indicate that some endocrine consequences of the grafting of an ectopic pituitary are dependent on time of year.     

Preovulatory secretion of progesterone, luteinizing hormone, and prolactin in 4-day and 5-day cycling rats

Timing of ovulation and changes in plasma progesterone, luteinizing hormone (LH), and prolactin (PRL) during periovulatory stages were determined in Holtzman rats exhibiting regular 4- or 5-day cycles under a daily artificial illumination from 0500 to 1900 h. The 5-day cycling rats ovulated between 0130 and 0930 h on estrus, whereas some of the 4-day cycling animals ovulated as early as about 0130 h and others as late as 1130 h on estrus. Onset time of preovulatory LH and progesterone surges was about 1500 h on proestrus in both the 4- and the 5-day cycling rats. Peak levels of plasma LH and progesterone were measured at 1700 to 1900 h on proestrus, while the first rises and peak values of plasma PRL were evident a few hours earlier than those of plasma LH in the rats with two cycle lengths. Plasma LH levels at 1900 h on proestrus as well as plasma progesterone levels at 1600 and 2300 h on proestrus and at 0130 and 0330 h on estrus were significantly lower in the 5-day cycling rats than in the 4-day cycling animals (p less than 0.05). In contrast, PRL levels from 1500 through 2300 h on proestrus remained consistently higher in 5-day cycling rats than in 4-day cycling rats, and significant differences in PRL levels between these rats were apparent at 1500, 1600, and 2100 h (p less than 0.05-0.01). Thus, these results demonstrate that the 5-day cycling rats exhibit the attenuated magnitude of LH surge accompanied by the augmented preovulatory PRL release, and that plasma progesterone levels reflect the magnitude of LH surge. A tentative working hypothesis concerning the etiology of the 5-day cycle has been proposed.     

Depressed pituitary prolactin mRNA, prolactin synthesis, and prolactin storage after light-deprivation in female hamsters is not due to loss of estrous cyclicity alone

Pituitary prolactin (PRL) cell activity (i.e. PRL messenger ribonucleic acid [mRNA] levels, PRL synthesis, and radioimmunoassayable [RIA]-PRL), and serum RIA-PRL were measured in female golden Syrian hamsters that were (1) light-deprived and then ovariectomized before loss of estrous cyclicity, (2) light-deprived but not yet acyclic, and (3) light-deprived and ovariectomized simultaneously. The results indicate that light-deprivation can decrease PRL cell activity in ovariectomized hamsters but not in animals that continue to cycle. Thus, estrous cyclicity can be said to largely protect PRL cell activity from depressions due to light deprivation. After acyclicity/ovariectomy, however, PRL cell activity is no longer protected and light-deprivation leads to large depressions in PRL mRNA levels, PRL synthesis, and RIA-PRL beyond that caused by acyclicity/ovariectomy alone. As seen in previous studies of total light-deprivation in nonovariectomized female hamsters, we found that removing the pineal gland in conjunction with light-deprivation in ovariectomized hamsters can completely, partially, or fail to restore various measures of PRL cell activity.     

Immunohistochemical localization of prolactin in functioning and regressing corpus luteum of pituitary autotransplanted rats

In an attempt to shed light on the intimate mechanism by which prolactin (PRL) switches from supporting corpus luteum (CL) progesterone secretion (P) to promote structural regression of the CL, day 2 (metestrous) autopituitary transplanted (APTr) rats were used. In APTr rats the CL is under the only control of PRL since an almost complete absence of LH and FSH exist. The experimental group was given bromocriptine (CB-154: 0.4 mg/day) on days 12, 13 and 14 of the cycle and 0.25 ml of ethanol from day 15 to day 21. The control group was given CB-154 from day 12 to day 21. Rats were hemiovariectomized on day 12 to assess the morphological characteristics of the active CL. PRL and P were determined by RIA on days 12, 15 and 22. On day 12, both PRL and P levels were higher than 80 ng/ml (luteotrophic action of PRL). On day 15, due to treatment with CB-154, the levels of both hormones had fallen below 7 ng/ml (functional luteolysis). On day 22, PRL levels were again high (greater than 50 ng/ml) in the shortly CB-154-treated rats and low (less than 5 ng/ml) in the controls; the P levels were lower than 5 ng/ml in both groups. PRL-induced structural luteolysis in the experimental group (hyperprolactinemic) was assessed by the structural characteristics and by the CL weight loss on day 22 in comparison with that exhibited by control rats. The immunohistochemical staining of both endogenous and total PRL in the lutein cells showed that the internalization of PRL is not modified by the functional state of the CL, nevertheless the intracellular redistribution of the internalized hormone varied in relation with the PRL action on the CL (luteotrophic, day 12 vs luteolytic, day 22). These results seem to indicate that intracellular mechanisms rather than receptor content determine CL response to PRL.     

Effects of treatment of normal and hyperprolactinemic rats with cyclosporine in vivo on the release of gonadotropins and prolactin from their pituitaries in vitro.

Cyclosporine (CyA) is extremely useful as an immunosuppressant and it is believed that at least some of its actions are due to antagonizing PRL effects. To determine whether the reported ability of CyA to inhibit gonadotropin release can be modified by PRL, we have examined the effects of treatment of normal and hyperprolactinemic rats with CyA in vivo on the release of LH, FSH and PRL from their pituitaries in vitro. Hyperprolactinemia was induced by implantation of capsules containing diethylstilbestrol (DES) and the animals were examined while the capsules were still in place (DES-IN) or after they had been removed (DES-OUT). Treatment with CyA significantly reduced plasma LH levels in control DES-IN rats without reducing basal LH release from the pituitaries of these animals in vitro. In the DES-IN rats, CyA exposure in vivo did not modify plasma PRL levels, but reduced PRL release in vitro, and interfered with the inhibitory action of dopamine (DA) on PRL release. The effect of DA on gonadotropin release in vitro was modified by CyA treatment. Administration of CyA failed to antagonize the suppressive effects of hyperprolactinemia on plasma LH and FSH levels or on the basal rates of gonadotropin release by incubated pituitaries. We conclude that CyA can reduce PRL release but does not interfere with the actions of PRL on anterior pituitary function.     

The effect of medial preoptic area lesions on sexually stimulated hormone release in the male rat

Male rats were subjected to bilateral electrolytic lesions in the medial preoptic area (mPOA). These lesions disrupted sexual behavior without affecting basal levels of luteinizing hormone (LH), prolactin (PRL), or testosterone (T). During exposure to an estrous female, intact and sham-operated rats mated; these rats showed elevations in LH, PRL, and T levels. Lesioned rats, which did not mate, showed elevations in LH but not PRL or T levels. These results demonstrate that the mPOA is not required for sexually stimulated LH release. The failure of lesioned rats to release PRL and T may be secondary to their failure to mate. Alternatively, the mPOA may participate in sexually stimulated PRL release, while T release may depend on prior elevations in both LH and PRL levels. LH release may be related to arousal, and PRL release to consummation, providing a hormonal analogy for the dual mechanism theory of sexual behavior.     

Prolactin involvement in the regulation of the hypothalamic-pituitary-ovarian axis during the early luteal phase of the porcine estrous cycle.

Our previous in vivo and in vitro studies revealed that prolactin (PRL) affected luteal function during the first days of the porcine estrous cycle. Since the mechanism by which the luteotrophic action of PRL might be mediated was not elucidated, the goal of the present study is to investigate the effects of short term, in vivo administration of PRL on in vitro functions of hypothalamic explants, adenohypophyseal cells and luteal cells of sows. Injections of PRL or saline (performed every 2h) started shortly after the preovulatory LH surge and lasted for 2 or 3 days. Peripheral blood plasma for determination of LH, PRL and progesterone (P(4)) was sampled at 4h intervals. Ovaries, pituitaries and the stalk median eminence (SME) dissected after slaughter were used for in vitro studies. Luteal and adenohypophysial cells as well as hypothalamic tissue were incubated/cultured with different treatments. Medium and plasma levels of GnRH, LH and P(4) were quantified by radioimmunoassays (RIAs). Corpora lutea (CL) were used for LH/human chorionic gonadotrophin (hCG) receptor analysis. In vivo and in vitro treatment with PRL increased the in vitro GnRH release by hypothalamic explants (P<0.05). GnRH-stimulated LH production was enhanced in PRL-treated sows compared to that of control sows (P<0.05). PRL injections had no effect on plasma P(4) concentrations during the treatment period. However, luteal secretion of P(4) (P=0.06) and LH/hCG receptor concentration (P=0.079) tended to be higher in PRL-treated sows in comparison to those of controls. The results indicate that PRL may be involved in the regulation of the hypothalamic-pituitary-ovarian axis at the beginning of the luteal phase of the porcine estrous cycle.     

Effects of prolactin on the morphology and function of rat Leydig cells: short-term versus long-term administration

Summary The bolus administration of prolactin (PRL) to adult rats did not cause any apparent change in the basal and luteinizing hormone (LH)-stimulated blood levels of testosterone (as estimated by radioimmune assay). Prolonged PRL infusion did not affect either basal testosterone plasma concentration or the morphology of Leydig cells (as evaluated by electron microscopy and stereology). Conversely, prolonged PRL treatment notably increased the gonadotrophic effects of chronic LH administration; this mainly consisted of a rise in the blood concentration of testosterone and a conspicuous hypertrophy of Leydig cells. The LH-induced increase in the volume of Leydig cells was the result of an increase in the volumes of all the organelles involved in steroid synthesis (i.e., smooth endoplasmic reticulum, peroxisomes and mitochondria). However, the trophic effects of PRL infusion exclusively concerned smooth endoplasmic reticulum and peroxisomes. In the light of these findings, the hypothesis is advanced that the mechanism underlying the gonadotrophic action of PRL involves an enhancement of the endogenous cholesterol synthesis, which could provide an abundance of precursors for testosterone synthesis, the post-cholesterol steps of which, in turn, would be exclusively controlled by LH.     

Effects of a long-acting LHRH agonist preparation on plasma gonadotropin and prolactin levels in castrated male rats and on the release of prolactin from ectopic pituitaries

We have examined the effects of a single subcutaneous injection of an LHRH agonist, D-Trp-6-LHRH, in biodegradable microcapsules of poly(DL-lactide-co-glycolide) on plasma gonadotropin and prolactin (PRL) levels in castrated and in castrated-hypophysectomized-pituitary grafted (CAST-APX-GRAFT) male rats. The results were compared to the effects of daily injections of the same LHRH agonist dissolved in saline. In castrated rats, there were no significant alterations in plasma LH or PRL levels during the 10 days following the injection of LHRH agonist microcapsules, while FSH levels were generally reduced. In castrated males given daily injections of 6 micrograms of LHRH agonist in saline, plasma LH levels were significantly reduced while plasma PRL levels were not changed. In CAST-APX-GRAFT rats, both D-Trp-6-LHRH microcapsules and daily LHRH agonist injections appeared to increase plasma PRL levels. The pattern of changes in PRL release in both groups was similar, with levels on day 6 being significantly higher than those measured on days 1, 3 and 10 after onset of treatment. As expected, LH and FSH levels in these animals were extremely low. Immunoreactive D-Trp-6-LHRH was consistently detectable in the plasma of CAST-APX-GRAFT animals after microcapsule administration, whereas in animals given daily injections of this agonist in saline, its plasma concentrations were often below the detectability limit of the employed assay. These findings suggest that the LHRH agonist, D-Trp-6-LHRH, is capable of causing a short term stimulation of PRL release from ectopic pituitaries. Elevation of plasma LH levels is apparently not required for this effect.     

Ovulation-inhibiting properties of Org OD 14

Org OD 14 has recently been shown to be an interesting new steroid for the treatment of menopausal women. In view of the importance of treatment of perimenopausal women, in whom ovulation might occur, the aim of the present study was to assess whether or not Org OD 14, administered orally in a daily dose of 2.5 mg for 21 days, inhibits ovulation. Sixteen healthy female volunteers, aged 20-34 years and with established ovulatory cycles, were studied during a control cycle and a treatment cycle. Daily measurements of the plasma levels of FSH, LH, E2, P and PRL were made. Endometrial specimens were obtained from nine of the volunteers between 23rd and 25th day of both cycles. The criteria for an ovulatory cycle were: (1) mid-cycle FSH, LH and E2 peaks; (2) criteria (1) followed by a rise in the P levels of greater than 10 ng/ml; (3) a luteal phase of at least 12 days; (4) biphasic behaviour of E2; and, (5) secretory endometrium on days 23-25 of the cycle. All control cycles were ovulatory. During the treatment the mid-cycle FSH, LH and E2 peaks disappeared, and P levels remained very low. PRL levels showed an occasional moderate rise in some of the volunteers. Endometrial specimens showed a secretory pattern during the control cycle, and different degrees of proliferation during the treatment cycle in all nine volunteers. It was concluded that Org OD 14 inhibited ovulation in all 16 volunteers.     

Puberty and ovulatory release of gonadotropins in spontaneously hypertensive rats

The age at vaginal opening, estrous cyclicity, serum levels of luteinizing hormone (LH), follicle stimulating hormone (FSH) and prolactin (PRL) on the day of proestrus, and number of ova and ovarian weight as measured on the day of estrus in spontaneously hypertensive (SH) and genetically matched normotensive Wistar Kyoto (WKY) female rats were compared. In SH rats, there was a significant delay in the vaginal opening, but the regular 4-day estrous cycle followed afterwards. No significant changes were observed in the afternoon increase in serum LH, FSH and PRL on the day of proestrus in SH and WKY rats, although the basal levels of LH and PRL in the morning (11:00 h) were lower in SH rats than in WKY rats. The mean number of ova in SH rats was also less than in WKY rats, whereas the ovarian relative weight was similar in both species of rats. It can be said that SH rats undergo certain, but not critical, endocrine and/or neuroendocrine changes related to reproduction.     

Sex differences in acute luteinizing hormone responses to gonadectomy remain after progesterone antagonist and dopamine agonist treatment.

In male rats, LH pulse frequency and amplitude increase dramatically by 24 h after gonadectomy; in females they increase only slightly by this time. Mean FSH levels increase significantly in both sexes by 24 h after gonadectomy. The objectives of the present studies were to compare pulsatile LH, FSH, and prolactin (PRL) secretion in intact versus gonadectomized and in male versus female rats, and to determine whether the acute postovariectomy lag in LH rise is due to a lingering effect of the higher PRL and/or progesterone (P) levels seen in intact females. LH pulse amplitude, frequency, and mean levels increased significantly by 24 h after gonadectomy in both sexes, but the increases were greater in the males. FSH mean levels, but not pulse amplitude or frequency, increased similarly in both sexes by 24 h after gonadectomy. PRL did not change with gonadectomy. Treatment with CB-154 (a dopamine agonist), with or without RU486 (a P antagonist), 1 h before gonadectomy significantly suppressed pulsatile PRL secretion 1 day later in both sexes. There was no effect of either treatment on LH secretion. We have demonstrated that there is a sex difference in LH, but not FSH or PRL, pulsatility at 24 h after gonadectomy, and that female rats' higher PRL and P levels do not account for their slow rate of LH rise after ovariectomy.     

Lithium-induced changes in the plasma and pituitary levels of luteinizing hormone,follicle stimulating hormone and prolactin in rats

Adult male Sprague-Dawley rats, maintained under a controlled photoperiod of LD 14:10 (white lights on at 06:00 h, CST), were injected with lithium chloride and changes in the levels of plasma and pituitary homogenates of luteinizing hormone (LH), follicle-stimulating hormone (FSH) and prolactin (PRL) were examined to evaluate the effects of this anti-manic drug on reproductive function. Two groups of rats were injected with lithium chloride intraperitoneally, twice daily at 09:00 and 16:00 h, for 2 and 7 days at a dosage of 2.5 meg/Kg body weight. Plasma and pituitary levels of LH, FSH and PRL were measured by radioimmunoassay. Plasma levels of LH were significantly (P<0.05) increased after 2 days of lithium treatment. In contrast, a significant (P<0.005) reduction in plasma levels of LH was evident when lithium injections were continued for 7 days. The plasma levels of FSH remained unaffected by lithium treatment by either time period. Lithium administered for 2 days did not bring about any significant alteration in the plasma levels of PRL, although there was a significant (P<0.002) reduction in plasma PRL levels after 7 days treatment. The concentrations of pituitary LH, FSH and PRL remained unchanged after 2 and 7 days of lithium treatment.     

Splenic macrophages enhance prolactin and luteinizing hormone action in rat luteal cell cultures.

We have reported that splenic macrophages play a role in the regulation of progestin secretion in rats. In this study, splenic macrophages were obtained from cycling rats at different estrous cycle stages and co-cultured with luteal cells from mid-pseudopregnant rats in the absence/presence of prolactin (PRL) or luteinizing hormone (LH). The effect of macrophages on the luteotropic action of PRL and LH was evaluated with 2 parameters, i.e. an increase in total progestin output (progesterone plus 20 alpha-hydroxyprgn-4-en-one [20 alpha-OHP]), and an increase in the progesterone to 20 alpha-OHP (P/20 alpha-OHP) secretion ratio. Splenic macrophages obtained from proestrous or metestrous rats enhanced the PRL action to increase the P/20 alpha-OHP secretion ratio, but those from estrous or diestrous donors did not. Only macrophages from proestrous donors enhanced the PRL action to increase the total progestin output. In contrast, the LH action increasing the P/20 alpha-OHP secretion ratio was enhanced by splenic macrophages regardless of the donors' estrous cycle stages. The LH action increasing the total progestin output was enhanced only by proestrous or metestrous macrophages. Therefore, if luteal cells are co-cultured with proestrous macrophages, the luteotropic actions of PRL and LH can be fully expressed. These results indicate that splenic macrophages directly act on luteal cells and enhance the luteotropic action of PRL and LH, and that this function of splenic macrophages is modified somehow according to the donors' estrous cycle stages.     

Effect of estradiol 17-beta on LH subunits and prolactin mRNAs expression in the pituitary of old female rats

OBJECTIVES: The aim of the study was to examine susceptibility of the pituitary gland to estrogenic impulse in old, noncycling rats by measurement of steady state level of mRNAs encoding LH subunits a and b and mRNA for PRL. METHODS: 22-month-old rats were ovariectomized and after one week they were subcutaneously implanted with silastic tubing filled with oil or with estradiol 17-beta. Pituitary alpha, LHbeta and PRL mRNAs content and serum LH and PRL concentration was determined. RESULTS: The effect of E (2)treatment was manifested by the significant increase in the weight of the uterus and pituitary gland as well as by elevation of total pituitary RNA (109%, 60% and 78%, respectively; p<0.001). No significant changes (p>0.05) in serum LH concentration were observed, while levels of mRNAs encoding alpha and LH-beta subunits were lowered by 54% (p<0.05) and 96% (p<0.01), respectively, in the rats subjected to E(2) stimuli. No direct correlation between synthesis and release of LH in E(2) treated old rats was observed. The blood PRL concentration and the pituitary level of PRL mRNA increased up to 2,000% and 1,300%, respectively (p<0.001). Spontaneous pituitary adenoma was observed in about 30% of the rats, irrespective of treatment. CONCLUSIONS: These data show that in old rats estrogenic stimulus can effectively diminish both pituitary LH subunits mRNAs as well as stimulate pituitary PRL mRNA level indicating that the E(2)-dependent processes involved in the regulation of corresponding genes are still functional.