The response of plasma prolactin to suckling during normal and prolonged lactation in the rat

In dams which had been kept isolated from pups for 8-10 h, the magnitude of the suckling-induced prolactin rise in the plasma was studied in relation to intensity of suckling stimulus and lactational age of the mother. At midlactation the response of prolactin evoked by suckling was enhanced as litter size increased. Suckling of 2 pups induced a greater prolactin rise in dams adjusted to 2 pups than in dams adjusted to 8 pups. Suckling of 8 pups caused a greater prolactin rise in dams which had been adjusted to an 8-pup litter, than in rats with a 2-pup litter. At late and prolonged lactation the rise of prolactin in the plasma induced by the suckling stimulus of 8 pups was significantly lower than at midlactation. Injection of perphenazine after a period of suckling induced a moderate increase of plasma prolactin in dams at midlactation, and a similar increase in dams at late lactation and at day 42 of lactation. It is concluded that in the first half of lactation the number of pups, i.e. the intensity of the suckling stimulus, is an important factor in determining the magnitude of the prolactin response to suckling. The lower response of plasma prolactin to suckling in late lactation is neither caused by a decrease in suckling stimulus from the pups nor by an increase in prolactin clearance; it is probably due to a gradual reduction in prolactin synthesizing and releasing capacity of the pituitary, brought on by a desensitization of the neural or neuroendocrine system to suckling stimuli as lactation proceeds.     

Somatosensory Contributions to c-fosActivation within the Caudal Periaqueductal Gray of Lactating Rats: Effects of Perioral, Rooting, and Suckling Stimuli from Pups

In lactating rats, the immediate-early gene c-foswas previously shown to be highly activated in several brain sites by physical interaction with either suckling or nonsuckling pups but not by distal stimuli from pups, a nonpup stimulus, or no stimulation. Further, even greater levels of Fos-immunoreactivity (ir) occurred following suckling versus nonsuckling contact with pups in only 1 of over 25 sites—the caudal periaqueductal gray (cPAG) at an intercollicular level, lesions of which severely reduced the typical suckling-induced kyphotic nursing posture. Herein we further evaluated the effects and site-specificity of various somatosensory cues received from pups during 60 min on Fos-ir in the PAG of day 7 postpartum rats after a 48-h dam–litter separation. Dams interacting with suckling versus nonsuckling pups showed relatively high numbers of Fos-ir cells in the intercollicular cPAG site identified earlier, but not in three other rostrocaudal planes of the PAG. Elimination of rooting on the dam's ventrum by use of fully anesthetized pups did not further diminish Fos-ir in maternally behaving, nonsuckled dams. Perioral anesthesia of dams prior to reunion with the litter prevented retrieval and licking of pups but not pup-initiated nursing behavior, the duration of which was positively correlated with Fos-ir levels within the intercollicular cPAG. Thus, various somatosensory stimuli from pups activate c-fosin a discrete region of the cPAG but only interactions that include suckling and its behavioral consequences elicit maximal expression, consistent with a role for this midbrain site in the sensorimotor control of kyphotic nursing in rats.     

Suckling-induced prolactin release potentiates mifepristone-induced lactogenesis in pregnant rats

Suckling, starting at 19:00 h on Day 18 of pregnancy, induced a significant increase in serum prolactin concentration at 20:00 h on Day 19 of pregnancy, but no increase in mammary gland casein or lactose content. Mifepristone (2 mg/kg) injection at 08:00 h on Day 19 of pregnancy induced significant increases in casein, but not in lactose, 24 h after administration. Mifepristone alone did not induce prolactin secretion, indicating that lactogenesis was induced by placental lactogen in the absence of progesterone action. When mifepristone was injected into suckling rats, serum prolactin concentrations were higher than in the untreated suckling rats. Casein in these rats increased significantly 12 h after mifepristone administration and lactose at 24 h after. If the suckling mifepristone-treated rats were given two injections of bromocriptine (1.5 mg/kg) at 12:00 h on Days 18 and 19 of pregnancy, serum prolactin concentrations were not increased by suckling, but casein and lactose concentrations in the mammary gland showed values similar to those obtained in the mifepristone-treated non-suckling rats. Mifepristone can therefore potentiate suckling-induced prolactin release in pregnant rats, demonstrating a direct central inhibitory action of progesterone on prolactin secretion. This suckling-induced prolactin secretion, unable to induce casein or lactose synthesis in the presence of progesterone, enhanced significantly synthesis of these milk components in the absence of progesterone action (rats treated with mifepristone). Fatty acid synthase, which is stimulated by the suckling stimulus in lactating rats, was not modified by mifepristone or suckling in pregnant rats.     

Role of pup age, estradiol-17 beta and pituitary responsiveness in the differences in the suckling-induced prolactin response during early and late lactation

The suckling-induced prolactin (Prl) response was studied in 10- and 20-day postpartum female rats. The response in 20-day postpartum mothers has a slower onset, has markedly reduced peak values and returns to baseline somewhat sooner than the response in 10-day postpartum mothers. The blunted response of late lactation was seen in mothers suckled for 30 min and was maintained over a longer interval in mothers continuously suckled for 120 min. This refractory phenomenon was not due to decreased suckling intensity provided by 20-day relative to 10-day-old pups. Pituitary gland Prl release in response to thyrotropin releasing hormone (TRH) and haloperidol challenges also did not distinguish 10- from 20-day postpartum mothers. Significantly higher estradiol-17 beta levels were found in 20-day compared with 10-day postpartum mothers, a finding which cannot account for the blunted response. Pup separation from 10-day postpartum mothers for 4, 24, 48 or 72 h did not produce a blunted response like that seen in late lactation. It is suggested that the hypothalamic mechanism mediating suckling-induced Prl release becomes refractory to the suckling stimulus during the preweaning period.     

Suckling ability and maternal prolactin levels in hypothyroid rats

Long-Evans rats and their offspring were made hypothyroid by addition of the antithyroid goitrogen 6-N-propylthiouracil (PTU) to the drinking water (0.1%) from the day of parturition. Serum concentrations of prolactin (PRL), thyroid-stimulating hormone (TSH) and thyroxine (T4) were determined by double radioimmunoassay (RIA). From the fifth postnatal day, body weight of PTU-treated pups was significantly lower than that of control rats, and a strikingly elevated serum TSH level and nondetectable amount of T4 were measured both in PTU-exposed mothers and their offspring at Day 10 postpartum. To test the youngs' suckling capability and the amount of maternal milk production, 10- and 15-day-old normal and PTU-treated pups were separated from their mothers for 4 hr in the morning and then reunited and allowed to suckle. Normal pups gained body weight at the end of both the first and second hour postreunion, while PTU pups gained only during the first hour and lost weight in the second hour of testing. When the pups were exchanged between normal and PTU mothers, opposite results were obtained, indicating that the reduced gain in hypothyroid rats was not due to impaired suckling capability, or insufficient sensory stimulation for milk secretion but to a decreased milk production of PTU mothers. In accordance with this, in lactating hypothyroid rats both the basal (presuckling) level and the suckling-induced rise of serum PRL were found significantly depressed.     

The suckling-induced rise of plasma prolactin in lactating rats: its dependance on stage of lactation and litter size

The response of plasma prolactin in vigorous suckling was measured in lactating rats which had been isolated for 10-12 h from their offspring. Plasma prolactin was investigated during suckling at various stages of lactation. The results demonstrate that prolactin responds maximally to suckling already in the first days of lactation. In the second half of the lactation period, the prolactin rise in the plasma induced by suckling decreases gradually; this is not due to a reduced suck-intensity of older pups. A relationship is found between the height of the suckling-induced prolactin rise and litter size. The data suggest that during suckling in the first weeks of lactation the pituitary secretes large amounts of prolactin at a constant rate. It is speculated that in the first minutes of suckling, receptors may clear considerable amounts of released prolactin from the circulation.     

Changes in pituitary prolactin responsiveness to TRH during pregnancy

Prolactin plasma concentration during pregnancy was determined in rats treated with thyrotropin-releasing hormone (TRH). Day 0 of pregnancy was defined as the day sperm were first found in the vagina. All blood samples were obtained in unanesthetized rats which had previously received a cannula in the right common carotid. On Day 8 of pregnancy, plasma prolactin concentrations reached a peak between 2400 and 0800 hr (lights on from 0600 to 1800 hr). Injection of TRH (1 microgram/kg body wt) via the carotid artery increased plasma prolactin levels within 5 min. The largest increase occurred when TRH was given during the prolactin surge, whereas much smaller effects were found when TRH was given at the beginning or after the end of the surge period. Thus, the sensitivity of the prolactin cell to TRH appears to be the greatest when the secretory activity of the cell is high. It was then determined whether there was any change in the sensitivity of the prolactin cell to TRH after the prolactin surges had disappeared at midpregnancy. Injection of TRH between 1100 and 1200 hr increased prolactin less on Day 12 than on Day 8 of pregnancy. Since placental lactogen (PL) levels in the plasma are high on Day 12 compared to Day 8, and are inhibitory to prolactin secretion, it was reasoned that PL may be the factor which caused the reduced sensitivity to TRH. However, hysterectomy on Day 11 failed to increase the pituitary responsiveness to TRH the next day. In summary, these data indicate that the pituitary responsiveness to factors that stimulate prolactin, such as TRH, varies with relation to the time of pregnancy or presence of the nocturnal surge. What cellular mechanism is responsible for these sensitivity changes is not known.     

Opioid inhibition of luteinizing hormone secretion in the postpartum lactating sow

Twelve lactating sows were used at 22.4 +/- 0.8 days postpartum to determine whether endogenous opioid peptides (EOP) are involved in the suckling-induced inhibition of luteinizing hormone (LH) secretion. Four sows each received either 1, 2, or 4 mg/kg body weight of naloxone (NAL), an opiate antagonist, in saline i.v. Blood was collected at 15-min intervals for 2 h before and 4 h after NAL treatment. All sows were then given 100 micrograms gonadotropin-releasing hormone (GnRH) in saline i.v., and blood samples were collected for an additional h. Pigs were weaned after blood sampling. At 40 h after weaning, sows were treated and blood samples collected as during suckling. Serum concentrations of LH after treatment with NAL were similar for all doses; therefore, the data were pooled across doses. During suckling, serum concentrations of LH were 0.41 +/- 0.04 ng/ml before NAL treatment, increased to 0.65 +/- 0.08 ng/ml at 30 min after NAL treatment, and remained elevated above pretreatment concentrations for 120 min (p less than 0.05). Naloxone failed to alter serum concentrations of LH after weaning. These data indicate that EOP may be involved in the suckling-induced suppression of LH secretion and that weaning may either decrease opioid inhibition of LH secretion or decrease pituitary LH responsiveness to endogenous GnRH released by NAL.     

Effect of passive immunization against substance P in rats with hyperprolactinemia

Substance P, an undecapeptide isolated from gut and brain tissues, was reported to stimulate prolactin release. It was suggested that substance P may play a role in the control of prolactin secretion. In this investigation we studied the effects of the blockade of endogenous substance P by the administration of a specific anti-substance P serum on serum prolactin levels in rats in the evening of proestrus, in lactating rats after suckling, and in male rats with hyperprolactinemia induced by grafting 2 anterior pituitary glands under the kidney capsule. The injection of the anti-substance P serum was followed by a significant decrease of the prolactin surge induced by 30 min suckling in lactating rats, when the antiserum was administered 24 hr but not 5.30 hr earlier. Anti-substance P serum also induced a significant decrease in serum prolactin levels in pituitary grafted rats, but induced no change in the proestrous surge of prolactin and LH. These results show that substance P may be involved in the release of prolactin induced by suckling and that this peptide may have an intrapituitary role in the process of prolactin release. On the other hand, substance P does not seem to play a significant role in the proestrous peak of prolactin and LH.     

Exercise training and the differential prolactin response in male and female rats

Adult male and female Sprague-Dawley rats were trained on a horizontal treadmill for 0, 1, 3, 5, or 7 days/wk for 10 wk. Speed and duration were progressively increased over 5 wk to a maximum of 20 m/min for 1 h. Between weeks 9 and 10 of training, animals were placed on the nonmoving treadmill, and blood (500 microliters) was sampled via chronic venous cannulas 30 min before, 0, 10, 20, 30, 45, and 60 min during exercise, and 15, 30, 60, 90, and 120 min after exercise. In another study, resting animals in the various groups were injected with thyrotropin-releasing hormone (TRH; 2 micrograms/kg for males and 0.4 microgram/kg for females) to determine pituitary prolactin responsiveness. In males, exercise induced a significant increase in plasma prolactin levels, with the greatest increase observed in the least trained and the smallest increase in the most highly trained animals. Female rats displayed the opposite trend with the greatest increase in prolactin secretion observed in the highest trained and the smallest increase observed in the least trained animals. TRH induced similar increases in plasma prolactin in all male groups, whereas TRH-induced prolactin release was greatest in the highest trained and smallest in the least trained females. The reduced prolactin response in highly trained males may reflect their acclimation to repetitive exercise stress, whereas the enhanced response in the highly trained female rats appears to result from increased pituitary sensitivity to prolactin-releasing factors.     

Inhibition of nocturnal prolactin surges in the pregnant rat by incubation medium containing placental lactogen

Rats hysterectomized on Day 7 or 8 of pregnancy continued to have nocturnal prolactin surges 1 day later. Conditioned medium obtained from incubation of Day 11 placentas infused via the jugular vein completely blocked this nocturnal surge, indicating a negative feedback of placental secretions on prolactin. Infusion of an ultrafiltrate of the conditioned medium which only contained molecules with Mr above 10,000 also blocked the prolactin surge. Next, it was determined whether this feedback of placental secretions on prolactin may work by way of hypothalamic dopamine. Levels of dopamine in hypophysial stalk blood from pregnant rats on Day 12, a time when secretion of placental lactogen is high, were not different from those in rats in which placental lactogen was absent. It is concluded that termination of prolactin surges at midpregnancy may be due to feedback of placental secretions, possibly placental lactogen, on the hypothalamus and/or pituitary. However, these experiments do not support the hypothesis that this inhibition is mediated by alteration in hypothalamic dopamine secretion.     

Prolactin release and milk removal induced by suckling and milking in lactating ewes is prevented by L-dopa treatment

The effect of L-DOPA on milk removal and on prolactin release during suckling or milking was studied in lactating ewes. Various doses of L-DOPA (25, 50, 100 and 200 mg per animal) were injected iv 30 min before the suckling or milking period. Control ewes were injected with 0.9% NaCl solution only. Milking induced a significant long-lasting release of prolactin. An inhibition of milk removal was obtained with the dose of 200 mg of L-DOPA. An inhibition of prolactin secretion was observed related to the dose of drug administered. The inhibitory effect of 200 mg of L-DOPA on the secretion of prolactin after milking lasted for about 120 min, and thereafter a significant increase in serum prolactin level occurred. This increase in serum prolactin was not due to a "rebound" effect of L-DOPA, since the milking stimulus had to be present to induce the delayed increase in prolactin. Doses of 25 or 50 mg of L-DOPA prevented the surge of prolactin observed immediately after milking, but a long-lasting release of prolactin was obtained thereafter. The inhibitory effect of L-DOPA on prolactin release could be overridden by the suckling or milking stimuli according to the dose administered. The suckling stimulus was more effective than milking in overriding the inhibitory effect of the low dose of L-DOPA. The results indicate that milk removal and prolactin release induced by milking or suckling in lactating ewes is inhibited by an increase in monoamines at the hypothalamic-hypophyseal level.     

Maternal essential fatty acid deficiency depresses serum leptin levels in suckling rat pups

Dietary lipid quantity and quality have recently been shown to affect serum leptin levels in adult rats. Moreover, suckling pups from dams fed a high fat diet had increased serum leptin levels. The aim of the present study was to analyze the influence of essential fatty acid (EFA) deficiency on serum leptin levels in dams and their pups during the suckling period. For the last 10 days of gestation and throughout lactation, pregnant rats were fed a control or an EFA-deficient (EFAD) diet. The levels of leptin and EFA in the serum of the dams and pups were analyzed 1, 2, and 3 weeks after delivery. In parallel, serum levels of glucose and corticosterone were analyzed in the pups. Low serum leptin levels were found in the control lactating dams during the entire lactation period compared with the age-matched nonlactating animals. The leptin concentrations in the lactating dams fed the EFAD diet were lower compared with those fed the control diet. The serum leptin levels of suckling pups from dams on the EFAD diet were markedly decreased compared with controls (P < 0.05). The reduced serum leptin levels could not be explained by nutritional restriction as evaluated by serum levels of glucose and corticosterone. These results indicate the importance of the EFA composition of the maternal diet for serum leptin levels in both dams and pups. EFA deficiency in lactating dams may cause long-term effects on the pups through dysregulation of leptin and leptin-dependent functions. -- Korotkova, M., B. Gabrielsson, L. A. Hanson, and B. Strandvik. Maternal essential fatty acid deficiency depresses serum leptin levels in suckling rat pups. J. Lipid Res. 2001. 42: 359--365.     

Mechanism of prolactin release by 5-hydroxytryptophan

Male Wistar rats were intraperitoneally administered 300 mg/kg b.w. of α-methyl-p-tyrosine methyl ester(α-MT). These α-MT pretreated rats were anesthetized with urethane and then 5% glucose or dopamine (1 μg/kg b.w./min) was infused for 45 min. At 1 min before or 15 min after dopamine infusion, 10 or 50 mg/kg of 5-hydroxytryptophan (5-HTP) was injected intraperitoneally, and blood samples were taken from the jugular vein for prolactin determination. In rats treated with α-MT, the administration of 5-HTP increases the serum prolactin level in a dose-related manner. Dopamine infusion caused a marked decrease in serum prolactin level. The concomitant administration of dopamine and 5-HTP prevented the dopamine-induced decrease of serum prolactin in α-MT treated rats. These results indicate that the serotonergic stimulus enhanced prolactin release, not by inhibiting the dopaminergic activity, but by stimulating a prolactin-releasing factor or by activating other neurotransmitter systems.     

Lactation in mice fed endophyte-infected tall fescue seed

This study was conducted to assess the effects of endophyte-infected Acremonium coenophialum tall fescue (KY-31) seed (80% infected) on lactation in CD-1 dams and suckling performance of pups as measured by pup survival and growth rates. Twenty-four pairs of mature CD-1 mice were randomly allocated to four dietary treatments: 1) 100% mouse chow ad libitum; 2) 40% endophyte-infected tall fescue seed and 60% mouse chow (w/w); 3) reduced intake (100% chow), adjusted daily to the intake level of Treatment 2; and 4) 60% infected tall fescue seed and 40% chow. The mice were preconditioned on their respective diets for 100 d prior to 96 h of cohabitation between pairs of males and females. At parturition the litters were removed, and each dam was given a litter of six pups of equal weight, size and sex ratio to suckle for 15 days. All pups given to all the dams were born to other mice that were not part of the study and had not been exposed to endophyte-containing diets. Dams and litter weights were measured daily for 15 consecutive days. The combined body weight measurements of litters from dams fed the tall fescue containing diets (Treatments 2 and 4) were significantly lower (2.07 +/- 0.41 g/d) than that of litters from dams fed the chow containing diets (Treatments 1 and 3) during the suckling trial (P<0.05). Similarly, nine of ten (90%) dams fed the chow containing diets maintained five or more pups (5.5 +/- 0.2) throughout the study as compared to five of nine (55.6%) dams fed the tall fescue containing diets that maintained less than five pups (4.5 +/- 0.2).     

The administration of oleoyl-estrone to lactating dams induces selective changes in the normal growth pattern of their pups.

To determine the effects of oleoyl-estrone treatment on the lactating dams and on the growth pattern of developing rats, female Wistar rats were randomly divided into two groups after delivery. One group received a daily gavage of 0.2 mL sunflower oil containing 10 micromol oleoyl-estrone/kg (treated group) and the other received a daily intragastric gavage of 0.2 mL sunflower oil (control group). Treatment was carried out during the first 15 days of lactation. Dams were killed on days 1, 15 or 20 after delivery and pups were sacrificed on days 1, 15, 20 or 30. Treated dams showed a transient decrease in food intake, significant lower lipid content than control dams, with a parallel maintenance of protein content and no appreciative changes in plasmatic parameters. However, a significant increase in brown adipose tissue mass was detected in treated group. Pups from treated dams showed a decrease in their growth rate that was reflected in the lower adipose tissue mass in different locations, except in the case of brown adipose tissue and, that continued after cessation of treatment. Thus, treatment affects dams in a selective way that does not coincide with a simple food restriction model.     

3,5,3'-Triiodothyronine administered to rat dams during lactation increases milk yield and triglyceride concentration and hastens pups growth

It is known that lactation induces a mild hypothyroid state in rats and other mammals while thyroid hormone administration increases milk secretion in ruminants. The aim of this study was to investigate the effects of a moderate dose of 3,5,3'-triiodothyronine (T3), administered to rat dams during lactation on pups' growth and milk yield and composition. Primiparous Wistar rats with litters adjusted to 10 pups per dam received either tap water or T3 (75 microg/kg x day) in their drinking water from parturition till weaning. Food and water intake of dams and body weight of dams and pups were measured daily. In other groups of rats with similar treatments, milk yield of dams, macronutrient milk composition, and mammary arteriovenous differences for triglycerides (TG) and glucose were also determined. Dams treated with T3 ingested more food and their pups gained more weight than controls. Milk yield, milk TG concentration and glucose extraction by mammary glands were also higher in T3 treated dams. The results show that compensation of the mild hypothyroidism of the lactating rat may contribute to an increase in milk production and lipid levels, leading to an increase in growth of pups.     

Evidence that suckling pups, through an exteroceptive mechanism, inhibit the milk stimulatory effects of prolactin in the rat during late lactation

Lactating rats were removed from the animal room on postpartum Day 20 and placed in a room where there were no other rats. On postpartum Day 21, these rats released prolactin either in response to exteroceptive signals from their own pups which were placed underneath or in response to those from 25 to 30 other lactating rats which along with their litters were placed in a rack 3 ft in front of the mothers' cage. Milk secretion was stimulated in the isolated rats on Day 21 by the prolactin released in response to exposure to the rack of lactators, but paradoxically was not stimulated by that released in response to exposure of the mother to her own pups. In fact, the stimulatory effects upon milk secretion, resulting from exposure to the rack of lactators was totally prevented if the mother was exposed to her pups 3–4 min before exposure to the rack of lactators. The blocking effect of the pups, however, did not occur when the pups were placed in cages alongside the mothers' cage. From subsequent experiments, it was concluded that sensory cues, from the pups, appeared to activate the sympathetico-adrenal system of the mother to release catecholamines which then blocked the milk stimulatory effects of prolactin which already had been discharged into the circulation. The pups did not inhibit milk secretion on Day 14 which indicates that the inhibiting mechanism becomes established sometime between Days 14 and 21 of lactation. These data suggest that a peripheral mechanism may operate to reduce milk secretion in the rat during late lactation, and thus, may be involved in the normal weaning process.     

Lactational performance, consummatory behavior, and suppression of estrous cyclicity in rats suckling underfed pups

The role of pups' appetite in the regulation of maternal consummatory behavior (food intake of nursing mothers), lactational performance and postpartum diestrus was studied over a period of 45 days postpartum in rats chronically exposed to either underfed or normally fed pups. Experimental rats (n = 10) daily received 5 pups, 4-10-days-old, that had been deprived of food for the preceding 24 h while under the care of nonlactating foster mothers. Control rats (n = 10) received normally fed pups obtained daily from lactating foster mothers. Throughout the experimental period, the daily milk yield (estimated by litter weight gain), the intake of food and water by the mother, as well as the ratio of litter weight gain to mother's intake of food and water were all markedly higher in rats nursing underfed pups than in rats nursing normally fed pups. After a peak in lactation around Day 15 postpartum, experimental rats produced the same amount of milk during extended lactation as they did in the beginning of lactation, while control rats produced only half the amount of milk during extended lactation as they did in early lactation. Regardless of the nutritional state of the suckling pups, maternal body weight increased progressively over the first four weeks of lactation and remained unchanged during the time of extended lactation. The postpartum diestrus and the subsequent diestrous phase in the time of extended lactation were considerably longer in duration in rats that nursed underfed pups. On Day 45 of lactation, prolactin levels were higher and the adrenal glands were larger in experimental rats than in controls.(ABSTRACT TRUNCATED AT 250 WORDS)     

Prolactin does not mediate the suppressive effect of the suckling stimulus on luteinizing hormone secretion in ovariectomized lactating rats

The plasma LH concentration in ovariectomized lactating rats is low for 14 days postpartum, while the prolactin concentration is high during this period. We examined the effect of the inhibition of increased prolactin secretion with bromocriptine (CB-154) on the LH secretion in lactating rats ovariectomized on day 2 (day 0 = day of parturition). Blood samples were collected through an indwelling atrial cannula every day. LH levels were kept low until day 9 in lactating rats injected daily with CB-154 (0.6 mg/day, s.c.). The duration of the period during which LH secretion was suppressed was shorter in lactating rats treated with CB-154 than in saline-injected controls. The replacement with ovine prolactin by means of a mini-osmotic pump (0.3 mg/day, s.c.) in CB-154-treated lactating rats restored the duration of LH suppression. In rats deprived of their pups on day 2, the LH concentration rose immediately after removal of the pups and the LH level was not significantly different between rats treated with CB-154, ovine prolactin and saline, indicating that neither the CB-154 treatment nor the high level of prolactin alone has any effect on LH secretion in rats deprived of their pups. The present results clearly demonstrate that prolactin does not mediate the suppressing effect of the suckling stimulus on LH secretion in early lactation and support our theory that the suckling stimulus controls the LH and prolactin secretion independently at the hypothalamic level.