Effect of transient dopamine antagonism on thyrotropin-releasing hormone-induced prolactin secretion in the serotonin-blocked, estrogen-treated ovariectomized rats

Recent studies showed that a brief interruption of dopamine (DA) action markedly increased the thyrotropin-releasing hormone (TRH)-stimulated prolactin (PRL) release. It is thus of interest to delineate whether the estrogen-induced afternoon PRL surge involves the same mechanism. Long-term ovariectomized rats pretreated with polyestradiol phosphate (PEP, 0.1 mg/rat s.c.) for 6 days were used in this study. They also received either p-chlorophenylalanine (PCPA, 250 mg/kg i.p.) or ketanserin (Ket, 10 mg/kg i.p.), two serotonergic drugs known to inhibit the estrogen-induced afternoon PRL surge. Then the animals were either treated with a DA antagonist, domperidone (Domp, 0.01 mg/rat i.v.), or vehicle at 16.00 h on the sampling day. Ten minutes later, the ones receiving Domp were injected with a DA agonist, 2-bromo-alpha-ergocryptine (CB154, 0.5 mg/rat i.v.), followed 50 min later by the administration of TRH (1 microgram/rat i.v.). Plasma samples taken through indwelling intraatrial catheters were assayed for PRL by radioimmunoassay. The estrogen-induced afternoon PRL surges were completely blocked in both PCPA- and Ket-treated animals. A significant PRL surge with similar amplitude, however, was induced by either Domp or TRH, although pretreatment with Domp did not cause any potentiating effect on the action of TRH. On the other hand, Domp induced only a small rise of PRL secretion and TRH was totally ineffective in rats untreated with PEP. It is concluded that both DA antagonism and TRH stimulation can induce significant PRL release in the afternoon of estrogen-treated, serotonin-blocked rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

Developmental changes in the positive feedback effect of estrogen on luteinizing hormone release in ovariectomized female rhesus monkeys

To examine developmental changes in the LH response to estrogen, eight neonatally ovariectomized monkeys received repeated injections (sc) of 50 micrograms/kg estradiol benzoate (EB) at approximately 4-month intervals starting at age 8-12 months and ending at 49-52 months. Serum samples were obtained 24 before and 0, 6, 12, 24, 36, 48, 60, 72, 94, 108, and 120 h after each EB injection. Serum LH and estradiol levels were measured by RIA. The baseline LH level before EB injection during the prepubertal period (greater than 20 months of age) was 14.4 +/- 2.2 ng/ml, and it increased progressively to 115.3 +/- 13.5 ng/ml at 41-44 months, the age shortly before the first ovulation in our intact colony animals, then declined slightly. EB first induced a typical LH response, which consisted of a negative phase (suppression) followed by a positive phase (surge), at the average age of 29.3 +/- 1.9 months (n = 8). This is similar to the age of menarche in our colony animals. The baseline LH level before EB injection at the time of the first typical response (with negative and positive phases) was 36.7 +/- 6.7 ng/ml, a level 2.5 times higher than that of the prepubertal age. The magnitude of LH suppression by EB was significantly correlated with the baseline level of LH; the higher the baseline LH before EB injection, the greater the degree of LH decrease (r = 0.968; P less than 0.001). Similarly, the amplitude of the LH peak from the trough of the negative phase was significantly correlated with the baseline LH; the higher the LH level before EB injection, the higher the LH increase (r = 0.863; P less than 0.001). The latency to the LH peak was shortest when baseline LH was highest; the peak latency (34.4 +/- 1.6 h) of the LH surge at 41-44 months of age was significantly shorter than the latency (46.5 +/- 2.7 h) of the first LH response occurring at 29.3 +/- 1.9 months of age (P less than 0.001). Finally, the pattern of circulating levels of estradiol after EB injection did not differ across the developmental stages examined. These results are interpreted to mean that an increase in LH release, presumably LHRH release, starts at the onset of puberty and continues until the age of first ovulation, and that the levels of LHRH release during the pubertal period may determine the effectiveness of estrogen on the LH surge.(ABSTRACT TRUNCATED AT 400 WORDS)     

The effect of transient dopamine antagonism on thyrotropin-releasing hormone-induced prolactin release in ovariectomized rats treated with estradiol and/or progesterone

PRL release was studied in ovariectomized (OVX) rats pretreated with estradiol benzoate (EB), progesterone (P), or a combination of both steroids using a protocol that was selected to mimic ovarian steroid changes that have been observed during the female rat 4-day estrous cycle and early pregnancy. On the morning of the experiment, the animals received injections of either the dopamine (DA) antagonist domperidone (0.01 mg/rat iv) or vehicle (acetic acid in saline). Five minutes later, all animals received injections of the DA agonist 2-bromo-alpha-ergocryptine (CB-154; 0.5 mg/rat, iv) followed 60 min later by the administration of TRH (1.0 microgram/rat, iv). Plasma obtained from blood samples taken during the experiment was assayed for PRL by RIA. In OVX or P-treated OVX rats, a transient blockade of DA by domperidone did not alter the sensitivity of the pituitary to TRH administration, as measured by an increase in plasma PRL. However, such an effect of DA blockade was induced by 2 days of EB treatment and was maintained and amplified by P administration after EB injections. We conclude that enhancement of the PRL-releasing effect of TRH by DA antagonism, a mechanism we previously observed in female rats during midlactation, proestrus, estrus, and metestrus using the present drug protocol, can be induced by estrogen and maintained by P. Further, our data suggest that the previously observed loss of this secretory mechanism on the morning of diestrus may be due to the decrease in plasma P that takes place between metestrus and diestrus.     

The effect of transient dopamine antagonism on thyrotropin-releasing hormone-induced prolactin release in pregnant rats

The effect of transient dopamine (DA) antagonism on the sensitivity of pituitary lactotrophs to the PRL-releasing effect of TRH was investigated in rats on days 3, 9, 15, and 21 of pregnancy. Each animal, bearing an indwelling intraatrial catheter, received injections of either the DA antagonist domperidone (0.01 mg/rat, iv) or saline at 0930 h on the day of the experiment. Five minutes later, all animals were given the DA agonist 2-bromo-alpha-ergocryptine maleate (CB-154; 0.5 mg/rat, iv), followed 60 min later by the administration of TRH (1.0 microgram/rat iv). Plasma samples obtained during the experiment were assayed by RIA for PRL and progesterone (P). The results showed that transient DA antagonism increased the sensitivity to TRH as a PRL-releasing stimulus on the morning of day 3 of pregnancy, but not on days 9 and 15. However, the response was present on day 9 in animals that were hysterectomized (HS) on day 6 of pregnancy. The increase in sensitivity of lactotrophs to TRH after DA blockade was observed on day 21 of pregnancy. Plasma levels of P were high on days 3, 9, and 15, but decreased markedly by day 21. In a second experiment, the anterior pituitary (AP) PRL content was determined on days 3, 9, 15, and 21 of pregnancy. The results demonstrated that AP PRL significantly decreased between days 3 and 9 of pregnancy in both intact and HS animals. However, AP PRL concentrations in animals killed on days 15 and 21 were significantly greater than that on day 9 but were not different from that observed on day 3 of pregnancy. We conclude that the ability to transform AP PRL to a TRH-releasable pool by the transient blockade of DA is present in early and late pregnancy, but is absent in midpregnancy. Since this secretory mechanism is retained on day 9 after hysterectomy on day 6 of pregnancy, it appears that the secretory products of the uterine-placental unit are inhibitory to transformation. Further, this inhibitory effect at midpregnancy cannot simply be the result of decreased AP PRL content or changes in plasma P. Finally, the return of the transformation mechanism on the day before parturition (day 21) may be due to the increase in estrogen secretion that occurs in late pregnancy, since we have previously shown that estrogen can induce this AP secretory mechanism.     

The effects of transient dopamine antagonism on thyrotropin-releasing hormone-induced prolactin release in pseudopregnant rats

The effectiveness of TRH in releasing PRL after transient dopamine (DA) blockade was investigated in female rats between days 3 and 11 of pseudopregnancy (PSP). At 0930 h on the morning of the experiment, each animal was injected with the DA antagonist domperidone (0.01 mg/rat, iv) or vehicle (acetic acid in saline); 5 min later, the DA agonist 2-bromo-alpha-ergocryptine maleate (CB-154; 0.5 mg/rat, iv) was administered. Sixty minutes later, TRH (1.0 micrograms/rat, iv) was administered. Blood samples were withdrawn via indwelling catheters before, 5, 20, 40, and 70 min after domperidone or vehicle administration, and 5 and 10 min after TRH administration. On day 3 of PSP, TRH-induced PRL release was significantly enhanced by the domperidone-CB154 treatment compared to that in vehicle-treated control rats. By day 9 of PSP, the effectiveness of TRH in stimulating PRL release after domperidone treatment was decreased by 50% compared to that on day 3 of PSP. This reduction in PRL response to TRH was not due to decreased progesterone levels, as no difference was observed in plasma progesterone between days 3 and 9. Rats that were given domperidone on day 11 of PSP did not exhibit a significant increase in sensitivity to TRH; however, the effectiveness of TRH was enhanced by domperidone on day 11 of PSP in animals that were hysterectomized on day 2 of PSP. Since DA receptor blockage increased the sensitivity to a putative PRL-releasing factor (TRH) and this mechanism was eliminated around the time that the PRL surges of PSP disappear, we suggest that this pituitary mechanism is a critical component of the PRL release mechanism during the surges of PSP. Further, the observed loss of the mechanism between days 9 and 11 of PSP may be due to the direct influence at the anterior pituitary of a uterine PRL inhibitory factor which has been recently described.     

Progesterone induced acute release of prolactin in estrogen primed ovariectomized women.

Progesterone (10 mg) administered intramuscularly induces a concurrent release of prolactin as well as gonadotropin in estrogen-primed women. The time course of pituitary release of all three of these hormones appears to include a latent phase of 4 hrs and is maintained for at least 5 hrs. It is considered that this effect of progesterone may be mediated through a reduction of hypothalamic dopamine.     

Developmental changes in the luteinizing hormone secretory pattern in peripubertal female rhesus monkeys: comparisons between gonadally intact and ovariectomized animals

Developmental changes in LH release patterns were observed longitudinally in female rhesus monkeys at 10-65 months of age. The average ages of menarche and first ovulation in this experiment (n = 14) were 31.1 +/- 2.6 and 47.0 +/- 2.6 months (mean +/- SE), respectively. To assess the ovarian influence on developmental changes in LH, data were simultaneously obtained from neonatally ovariectomized animals at similar ages. The estimation of circulating LH was made with RIA as well as biological assay. During the prepubertal period (10-20 months of age), basal LH was very low, and there was no circadian fluctuation of LH in gonadally intact monkeys. During the early pubertal stage (20-30 months of age), before menarche, basal LH levels started to increase, and a circadian LH rhythm (nocturnal increases) appeared. At the midpubertal stage (30-50 months of age), a period between menarche and first ovulation, basal LH levels further increased, and the circadian LH rhythm was maximal. At the late pubertal stage (50-60 months of age), a period after the first ovulation during which the animals were not able to reproduce fully as adults, basal LH declined, and the circadian rhythm diminished. Similar but more exaggerated developmental changes in basal LH and the circadian fluctuation of LH were observed in females ovariectomized neonatally. Basal LH levels at 10-20 months were as low as those in intact animals with no circadian rhythm present. During the early pubertal period, a circadian fluctuation appeared at the time when a slight increase in the basal LH level occurred. Furthermore, the amplitude of circadian fluctuation (the difference between morning and evening LH values) increased linearly with the increase in basal LH during the midpubertal stage. These LH parameters in ovariectomized animals reached their peaks at 40-44 months, an age before the first ovulation in intact animals. As basal LH levels declined during the late pubertal stage to postpubertal stage, circadian fluctuation disappeared. The results suggest that the increase in LH output and concomitant circadian fluctuations occur in close association with the pubertal process, and this change in LH release is not dependent on the presence of the ovary. Therefore, we suggest that alteration of the LHRH release pattern during maturation, as reflected by LH release, rather than resetting of the gonadostat, is the key factor involved in the mechanism of the onset of puberty.     

Age-related differences in the spontaneous and thyrotropin-releasing hormone-stimulated release of prolactin and thyrotropin in ovariectomized rats

Effect of estradiol on the spontaneous and thyrotropin-releasing hormone (TRH)-stimulated release of prolactin (PRL) and thyrotropin (TSH) in young and aged ovariectomized (Ovx) rats was investigated. Old (22-26 months) and young (3 months) female rats were Ovx 3 weeks before use. They were injected subcutaneously with estradiol benzoate (EB, 25 micrograms/kg) or sesame oil for 3 days and were catheterized via the right jugular vein. Twenty hours after the last administration of EB, rats were injected with TRH (10 micrograms/kg) through the catheter. Blood samples were collected before and 5, 10, 20, 40 and 60 min after TRH injection. On the day following blood sampling, all rats were decapitated. The anterior pituitary glands (APs) were excised, and incubated with or without TRH (10 ng/ml) at 37 degrees C for 30 min. The basal level of PRL concentration in plasma samples was 5-fold higher in old Ovx rats than in young Ovx rats. Five min after TRH injection, the increase in plasma PRL was greater in old animals than in young animals. Plasma PRL remained higher in old animals than in young animals at 10, 20, 40 and 60 min following TRH challenge. Administration of EB to old and to young Ovx rats produced increases in both basal and TRH-stimulated secretions of PRL, but did not affect the difference in plasma PRL patterns between old and young animals. The release of PRL from APs was increased significantly in all rats after a 30-min incubation with TRH. In Ovx rats injected with oil, the basal release of PRL in vitro was increased with age.(ABSTRACT TRUNCATED AT 250 WORDS)     

Posterior hypothalamic lesions advance the time of the pubertal changes in luteinizing hormone release in ovariectomized female rhesus monkeys

To examine further the relationship between developmental changes in LH release and the onset of puberty, effects of posterior hypothalamic lesions were tested in ovariectomized (OVX), sexually immature female monkeys. In OVX females (n = 3) with sham hypothalamic lesions basal LH levels were suppressed during the prepubertal period until 25 months of age, when LH levels started to increase. The increase in basal LH continued; a 100% elevation from prepubertal levels was attained at 26.0 +/- 0 months of age, and a 200% elevation was attained at 31.0 +/- 3.2 months of age. A consistent appearance of LH circadian fluctuation (nocturnal LH increase) with a large amplitude accompanied the initial LH increase. Lesions of the posterior hypothalamus (PH) in OVX animals (n = 6) at 17-18 months of age, which we previously reported to be effective in advancing the onset of puberty by several months in ovarian intact monkeys, resulted in an early 100% increase in basal LH levels and the circadian LH fluctuation (19.5 +/- 1.0 months of age). Basal LH levels in these animals further increased, reaching a 200% elevation of prelesion levels at 24.2 +/- 0.7 months of age. All of these LH changes with PH lesions occurred significantly (P less than 0.01) earlier than those in sham-lesioned animals. Lesion of the PH in OVX animals (n = 4) at 13-14 months of age resulted in an increase in LH and the circadian LH fluctuation within 1 month postoperatively. However, 100% and 200% LH elevations did not occur until 20.8 +/- 1.0 and 24.8 +/- 1.4 months of age, respectively. These ages were similar to those of animals receiving lesions at 17-18 months of age, but much younger than those of sham controls (P less than 0.01). PH lesions in animals at 13-14 months of age also advanced the time of the first positive feedback effects of estrogen. In animals (n = 4) with PH lesions, estradiol benzoate induced a first LH response at 21.5 +/- 1.6 months of age, when basal LH was 276 +/- 83% increased from prelesion levels. This age was significantly (P less than 0.05) younger than that (29.3 +/- 1.9 months; n = 6) of the first LH surge induced by estrogen in control animals when basal LH levels attained 248 +/- 18% of prepubertal levels.(ABSTRACT TRUNCATED AT 400 WORDS)     

Different prolactin, thyrotropin, and thyroxine responses after prolonged intermittent or continuous infusions of thyrotropin-releasing hormone in rhesus monkeys

Serum PRL, TSH, and T4 secretion during prolonged continuous or intermittent iv infusions of TRH were studied in 14 adult ovariectomized rhesus monkeys (Macaca mulatta). For 9 days, TRH was administered intermittently at 0.33 or 3.3 micrograms/min for 6 of every 60 min and continuously at 0.33 micrograms/min. With both modes, the PRL levels and responsiveness to TRH simulation peaked on day 1 and then fell to levels that were still higher than the preinfusion values; levels for the intermittently treated group on days 3-9 were 2- to 4-fold above prestimulation levels and significantly (P less than 0.01) higher than levels for the continuously treated group. Elevated basal levels and PRL responses to TRH pulses were similar during the 0.33 and 3.3 micrograms/min pulses of the 9-day treatment period. For both TRH modes, TSH levels were elevated significantly (P less than 0.001) on day 1 [this increase was higher with continuous infusion (P less than 0.001)] and then fell to preinfusion levels by day 3. Serum T4 also increased during both continuous and intermittent TRH stimulations. However, serum T4 levels were significantly lower (P less than 0.01) after intermittent TRH (both 0.33 and 3.3 micrograms/min) than after continuous (0.33 micrograms) TRH (8 +/- 1.1 and 10 +/- 1.8 micrograms T4/dl vs. 18 +/- 3.1 micrograms, respectively). These PRL and T4 responses were replicated when the mode of administering 0.33 micrograms/min TRH was reversed after 9 days. An iv bolus of TRH (20 micrograms) after 9 days of continuous or intermittent TRH infusion caused significant release of PRL and TSH, an indication that neither mode of administration resulted in pituitary depletion of releasable hormone. We have concluded that intermittent TRH is more effective in elevating serum PRL, and continuous TRH is more effective in raising TSH and T4 levels. Thus, the manner of TRH secretion by the hypothalamus may determine its relative physiological importance in the stimulation of lactotropes and thyrotropes.     

Gonadal status influences developmental patterns of serum prolactin in female rhesus monkeys housed outdoors

Although estradiol (E2) is thought to facilitate PRL secretion under certain conditions in female primates, the role of E2 or other ovarian products in the control of PRL secretion during puberty is unknown. The present study examined the influence of gonadal status on serum PRL levels in prepubertal monkeys housed in an outdoor environment. Basal levels of PRL were examined in three groups of spring-born females that were studied from 12 to 28 months of age (May 1982 to September 1983): gonadally intact (INT; n = 8), ovariectomized (OVX; n = 5), and ovariectomized and treated chronically with E2 (E2OVX; n = 5). All groups exhibited a significant annual rhythm in PRL levels with peaks (10-20 ng/ml) at 14 and 26 months (June to July) and a nadir (less than 2 ng/ml) at 19 months (November to December). Basal PRL levels were significantly higher from 12 to 15 months (May to August) in E2OVX subjects, with OVX having significantly greater concentrations than INT females. Group differences were not evident during the period of minimal secretion from 16 to 20 months (September to January). Finally, levels were again significantly higher in both E2OVX and OVX subjects during the subsequent period from 21 to 27 months (February to August). Although serum levels of E2 were lower in INT (30.9 +/- 2.3 pg/ml) than E2OVX females (51.4 +/- 4.0 pg/ml), group differences in PRL could not be attributed to E2 since OVX females, with no measurable levels of E2 (less than 15 pg/ml), had intermediate levels of PRL. These data suggest that during primate maturation serum PRL levels are dampened by some product of the ovary. Furthermore, whether age specific or environmentally mediated, this rhythm indicates an annual alteration in PRL release, with absolute levels enhanced by E2 replacement after ovariectomy, for prepubertal monkeys housed outdoors. In addition, a significant maturational increase in PRL levels was observed only in INT females when serum levels of PRL were compared for the ages 12-16 months to 24-28 months corresponding to the period between May and September for 2 successive years. These changes in PRL were not related to age-dependent changes in serum E2. Acute treatment of both E2OVX and OVX females with a single injection of E2-benzoate at three different ages did not induce any changes in serum PRL.(ABSTRACT TRUNCATED AT 400 WORDS)     

Aging-related changes in release of growth hormone and luteinizing hormone in female rhesus monkeys

A decline in somatic function with aging in women is associated with a decrease in GH release and a loss of estrogen after menopause. As an initial step to establish a monkey model for the neuroendocrine mechanisms underlying somatopause and menopause, we have conducted three experiments in unrestrained aged (approximately 25.7-yr-old) and young (approximately 5.4-yr-old) female rhesus monkeys. GH release was pulsatile, and mean GH release and pulse amplitude were significantly lower in aged monkeys than in young monkeys. Injection of GHRH alone, GH-releasing peptide-2 alone, or the combination of both induced an increase in GH release in both age groups. The mean LH level, pulse amplitude, and baseline LH levels were significantly higher in aged animals than in young animals. Both estrogen and IGF-I levels were lower in aged than young monkeys. These results suggest that in female rhesus monkeys 1) there is a clear decline in circulating GH and IGF-I levels with aging; 2) GHRH and GH-releasing peptide-2 stimulate GH release synergistically; and 3) circulating LH levels increase as estrogen decreases with aging. These results indicate that the rhesus monkey is an excellent model for studies of the neuroendocrine mechanisms of aging.     

Prolactin release following electrical stimulation of the brain in ovarectomized and ovariectomized estrogen-treated rhesus monkeys.

Selected areas in the medial basal (MBH) and rostral (RH) hypothalamus and in the amygdala (AMYG) of long-term ovariectomized rhesus monkeys were electrically stimulated for 30 min through permanently implanted bilateral stainless steel electrodes. Stimulation of an area in the MBH extending from the dorsal part of the ventromedial nucleus through the arcurate nucleus to the upper median eminence resulted in a 200 to 400% increase within 5 min in 8 monkeys. In one monkey the elevated serum prolactin levels persisted after termination of stimulation and in 2 monkeys prolactin remained unchanged during the 30-min stimulation but increased after stimulation was discontinued. Stimulation of the paraventricular-dorsomedial nuclear area in one monkey had no effect on prolactin release. Prolactin responses to stimulation in the RH varied. In 2 monkeys the electrode tips extended into the optic chiasm but part of the uninsulated tips remained in contact with the RH; only one of these monkeys released prolactin in response to stimulation. In 4 monkeys the electrode tips were located in the suprachiasmatic-anterior hypothalamus area. Serum prolactin increased by 200 to 300% in response to stimulation in 2 of these monkeys but increased only slightly in the remaining 2 monkeys. Prolactin responses to stimulation of the AMYG varied with the location of the electrodes. Stimulation in the corticomedial region produced no change in serum prolactin but stimulation in the basal or basolateral area produced marked elevations. An increase in circulating levels of estradiol-17beta (E2) to 100 pg/ml by SC implantation of E2 capsules 72 h before stimulation had no significant effect on basal prolactin levels, but markedly enhanced the prolactin release induced by stimulation in both the MBH and RH. Sham-stimulation did not affect serum prolactin. We conclude that prolactin release in rhesus monkeys can be triggered by electrical stimulation of selected hypothalamic and amygdaloid areas and that stimulation-induced prolactin release in the RH and MBH can be enhanced by E2 pretreatment.     

Effect of specific acute stressors on luteinizing hormone release in ovariectomized and ovariectomized estrogen-treated female rats

In order to ascertain the influence of gonadal steroid hormones on the secretory response of the hypothalamic-hypophyseal luteinizing hormone (LH) axis to acute stress, the effects of four specific stressors on LH release were compared in ovariectomized versus ovariectomized steroid-treated rats. Groups of adult female Copenhagen-Fischer 344 rats were ovariectomized for either 1 or 2 weeks and exposed for specific intervals to one of the following stressors: novel environment, strobe light, restraint, or swim. Additional groups of animals were ovariectomized for 2 weeks and injected with 10 micrograms estradiol benzoate 24 and 48 h prior to exposure to the same stress stimuli. Multiple blood samples were obtained from these and nonstressed experimental controls at specific time points before, during, and after stress exposure. Transfer of 1-week ovariectomized rats to a novel environment, followed by a return to their original quarters 30 min later, resulted in a well-defined pattern of increased LH release. Novel environment stress also stimulated LH release in 2-week ovariectomized rats, as indicated by the comparison of mean LH values from the pre-stress versus post-stress sampling periods by paired test. Strobe light stress, on the other hand, had no effect on circulating LH in 1-week ovariectomized rats, but significantly increased mean post-stress plasma LH levels compared to mean pre-stress values in 2-week ovariectomized rats. While exposure to either 15 min of restraint or 10 min of swim stress had no effect on LH in rats ovariectomized for 1 week, both of these stressors resulted in a marked decline in LH release in 2-week ovariectomized animals.(ABSTRACT TRUNCATED AT 250 WORDS)