Serotonergic terminals in the anterior hypothalamic nucleus involved in the prolactin release during suckling

The present studies were designed to localize within the hypothalamus and neighboring areas the serotonergic terminals which are implicated in suckling-induced PRL release. The initial experiments were performed to characterize the circulating hormone profile induced by suckling in lactating rats, previously separated from their pups. Five minutes of suckling induced an increase in serum PRL only. During these 5 min, 5-hydroxytryptamine (5-HT) and 5-hydroxyindole-3-acetic acid concentrations were determined in the pars nervosa of the pituitary gland, hypothalamic nuclei, dorsal, and median raphe nuclei. An increase by 80% (P less than 0.01) in 5-HT concentration was found only in the rostral part of the anterior hypothalamic nucleus (rNHA). In order to investigate causal effect between the altered 5-HT neuronal activity in the rNHA and the suckling-induced PRL release, serotonergic neurotoxin was bilaterally injected in the rNHA on day 1 of lactation. Litters were adjusted to eight pups each and weighed daily to determine litter growth rates. On day 8 of lactation, litters were separated from their mothers for 4 h and allowed to suckle for 5 or 15 min after which the mothers were decapitated. Litters from lesioned animals grew at a lower rate (P less than 0.0001) than control and sham-operated animals. Serum PRL increased with suckling in animals bearing the correct rNHA lesions, but the values were lower than in control and sham-operated animals after 5 (P less than 0.05) and 15 (P less than 0.01) min. Therefore we postulate that the rNHA is the site of termination of a stimulatory serotonergic pathway on PRL release induced by suckling.     

Prolactin modulates hypothalamic preproenkephalin,but not proopiomelanocortin,gene expression during lactation

The aim of this study was to examine prolactin (PRL) regulation of preproenkephalin and proopiomelanocortin (POMC) gene expression in the hypothalamus during lactation. In the first experiment, lactating rats were deprived of pups for 3, 6, 12, or 24 h. Preproenkephalin mRNA levels were decreased in the arcuate nucleus (ARC) to 60 or 53% of suckled levels and in the ventromedial nucleus to 70% of suckled levels after 12 or 24 h but were unchanged in the striatum. POMC mRNA levels in the ARC and periarcuate area were increased to 165% of suckled levels within 3 h and remained elevated two- to threefold for 24 h. Subcutaneous administration of bromocriptine to suckled dams markedly suppressed circulating PRL levels and decreased preproenkephalin mRNA signal levels to 38 and 50% of control levels in the arcuate and ventromedial nuclei, respectively. Intravenous administration of oPRL completely reversed this effect. By contrast, bromocriptine with or without administration of ovine PRL (oPRL) did not alter POMC mRNA signal levels in the ARC. Administration of oPRL to pup-deprived dams increased preproenkephalin mRNA levels in the arcuate and ventromedial nuclei and reduced POMC mRNA levels in the ARC to levels similar to suckled control levels. In conclusion, POMC neurons in the ARC appear to be refractory to PRL regulation in the presence of a suckling stimulus, and other components of the suckling stimulus may contribute to the suppression of POMC mRNA levels during lactation. By contrast, PRL provides a regulatory influence for the suckling-induced increase in preproenkephalin mRNA signal levels in arcuate and ventromedial nuclei.     

Lactation alters gamma-aminobutyric acid neuronal activity in the hypothalamus and cerebral cortex in the rat

Gamma-aminobutyric acid (GABA) neurons terminating in the hypothalamus have been implicated in the neuroendocrine regulation of reproductive hormones, particularly luteinizing hormone (LH) and prolactin. The aim of this study was to examine whether GABAergic neuronal activity in the hypothalamus was modified during lactation, and whether any observed changes correlated with changes in secretion of these hormones. Animals were divided into three experimental groups: diestrous controls, lactating with pups present (with pups), and lactating with pups removed for 4 h (without pups). Animals were decapitated either without treatment, or 60 min after inhibition of GABA degradation by aminooxyacetic acid (AOAA) (100 mg/kg, i.p.). The rate of GABA accumulation in the tissue after AOAA is a measure of GABA turnover. GABA turnover was estimated in 13 microdissected brain regions, and serum prolactin and LH measured by radioimmunoassay. Suckling was associated with significantly increased prolactin and significantly decreased LH compared with diestrous rats. In lactating rats with pups, GABA turnover was significantly increased in the cingulate cortex compared with diestrous rats. GABA turnover was significantly increased in the ventrolateral preoptic nucleus of lactating rats with pups compared with diestrous rats or lactating rats without pups. There was significantly lower GABA turnover in the anterior hypothalamic area, ventromedial and dorsomedial hypothalamic nuclei in lactating rats without pups compared with diestrous rats. There were no significant changes in other brain regions examined. The results demonstrate that activity of GABAergic neurons in specific parts of the hypothalamus and cerebral cortex is altered during lactation.     

Modulation of pituitary gonadotropin-releasing hormone receptors during lactation in the rat

Lactation is associated with a suppression of pituitary GnRH receptors (GnRH-R), and removal of the suckling stimulus for 24 h causes a 4- to 5-fold increase in GnRH-R. These studies were designed to examine the time course of recovery of GnRH-R after pup removal and to determine the roles that GnRH and PRL may play in modulating GnRH-R during lactation and after pup removal. All studies were performed on day 10 postpartum using ovariectomized rats suckling eight or zero pups. GnRH-R had more than doubled by 8 h after pup removal and had increased 4-5 times 16 h after pup removal to reach levels observed in nonsuckled controls. The increase in GnRH-R after pup removal resulted in a significant increase in pituitary responsiveness to GnRH. Maintenance of hyperprolactinemia after pup removal, by injecting ovine PRL, reduced the increase in GnRH-R by about 50%. Simultaneous administration of GnRH with ovine PRL restored GnRH-R to control levels. Administration of a potent antiserum to GnRH at the time of pup removal completely blocked the up-regulation of GnRH-R 24 h later. In the presence of the suckling stimulus and hyperprolactinemia, administration of pharmacological doses of GnRH caused a complete restoration of GnRH-R to levels observed in nonsuckled controls. Inhibition of suckling-induced PRL secretion with CB-154 caused a 2-fold increase in GnRH-R, and this effect could be completely reversed by simultaneous treatment with ovine PRL. These studies show that the suppression of pituitary GnRH-R during lactation appears to be due primarily to inhibition of GnRH secretion. After pup removal, recovery of GnRH-R occurs very rapidly, with recovery (4- to 5-fold increase) being completed by 16 h. Endogenous GnRH secretion is absolutely necessary for the up-regulation of GnRH-R to occur. The decrease in PRL levels after pup removal contributes to this process, most likely by causing an increase in GnRH secretion.     

Regulation of hypothalamic neuropeptide Y messenger ribonucleic acid expression during lactation: role of prolactin

In the present study, we investigated the role of prolactin (PRL) in the suckling-induced increase in hypothalamic neuropeptide Y (NPY) gene expression in the dorsomedial nucleus of the hypothalamus (DMH) and the caudal portion of the arcuate nucleus of the hypothalamus (ARH-C). Lactating rats were deprived of their eight-pup litters on d 9 postpartum. After 48 h, the animals were randomly divided into two groups: nonsuckled controls and eight pups suckling for 24 h. In addition, some of the suckled animals received two injections of bromocriptine (0.5 mg/rat per injection) to inhibit suckling-induced PRL secretion. Some bromocriptine-treated rats also received ovine PRL (1 mg/rat per injection). In situ hybridization was performed to measure NPY mRNA levels. Suckling for 24 h induced a significant increase in NPY mRNA levels in the DMH and ARH-C. Bromocriptine treatment greatly attenuated the increase of NPY mRNA in the DMH but not in the ARH. Injections of ovine PRL in bromocriptine-treated rats greatly restored DMH NPY mRNA levels but had no additional effects on the ARH NPY expression. Double-label in situ hybridization for NPY and PRL receptor (PRL-R) in the lactating rat brains showed that NPY-positive neurons in the DMH also express PRL-R mRNA. On the contrary, few ARH NPY neurons expressed PRL-R. These data suggest that PRL could act directly on DMH NPY neurons to modulate NPY gene expression during lactation. Thus, the results from the present study demonstrate that NPY neurons in the DMH and ARH are differentially regulated by PRL during lactation.     

The role of the suckling stimulus in regulating pituitary prolactin mRNA in the rat

Prolactin (PRL) gene expression and the synthesis and secretion of PRL were examined in ovarian-intact lactating rats suckling eight pups on 10 days postpartum. Plasma samples were assayed for PRL concentrations, and pituitary glands were analyzed for total PRL content and PRL mRNA levels. We found that suckling-induced hyperprolactinemia was associated with very high levels of plasma PRL and a doubling in pituitary PRL mRNA levels, whereas pituitary PRL content was not changed. Removal of the suckling pups decreased plasma PRL concentrations 15-fold within 24 h. This decrease in PRL secretion was not accompanied by any significant change in pituitary PRL content. Evidently, both synthesis and secretion of PRL were decreased in the pituitary gland within 24 h following cessation of suckling, as pituitary PRL mRNA content had returned to diestrous levels at this time. To determine whether or not ovarian steroids might have contributed to the changes in PRL synthesis and secretion during lactation and after withdrawal of the suckling stimulus, the experiments were repeated in lactating rats ovariectomized (OVX) on day 2 postpartum. The results in these OVX rats were qualitatively similar to those described in ovarian-intact rats. We concluded from these findings that the stimulus of suckling induces increases in PRL mRNA levels in the pituitary which provides for the increased PRL synthesis accompanying increased PRL secretion. The cessation of suckling led to prompt decreases in PRL synthesis and secretion within 24 h.     

Pup removal suppresses estrogen-induced surges of LH secretion and activation of GnRH neurons in lactating rats

During lactation, the suckling stimulus exerts profound influences on neuroendocrine regulation in nursing rats. We examined the acute effect of pup removal on the estrogen-induced surge of LH secretion in ovariectomized lactating rats. Lactating and nonlactating cyclic female rats were given an estradiol-containing capsule after ovariectomy, and blood samples were collected through an indwelling catheter for serum LH determinations. In lactating, freely suckled ovariectomized rats, estrogen treatment induced an afternoon LH surge with a magnitude and timing comparable to those seen in nonlactating rats. Removal of pups from the lactating rats at 0900, 1100, or 1300 h, but not at 1500 h, suppressed the estrogen-induced surge that normally occurs in the afternoon of the same day. The suppressive effect of pup removal at 0900 h was completely abolished when the pups were returned by 1400 h. In contrast, pup removal was ineffective in abolishing the stimulatory effect of progesterone on LH surges. Double immunohistochemical staining for gonadotropin-releasing hormone (GnRH) and c-Fos, a marker for neuronal activation, revealed a decrease, concomitantly with the suppression of LH surges, in the number of c-Fos-immunoreactive GnRH neurons in the preoptic regions of nonsuckled rats. An LH surge was restored in nonsuckled rats when 0.1 microg oxytocin was injected into the third ventricle three times at 1-h intervals during pup removal. These results suggest that the GnRH surge generator of lactating rats requires the suckling stimulus that is not involved in nonlactating cyclic female rats.     

Stimulation of anterior pituitary galanin and prolactin gene expression in suckling rats

Recent evidence suggests that galanin, may regulate prolactin (PRL) secretion during lactation. In this article, we describe the regulation of anterior pituitary galanin and PRL gene expression during pregnancy and after parturition in the rat. Expression of galanin and PRL in the anterior pituitary were significantly higher at d 20 of pregnancy compared to diestrus. One day after parturition, galanin mRNA levels increased a further 4.5-fold. This post partum increase in gene expression was not observed for PRL. The increase in galanin gene expression was maintained above the diestrous level for at least 10 d after parturition. PRL mRNA expression, on the other hand, was largely unchanged after parturition. Although the increase in galanin gene expression 1 d after parturition was independent of suckling, subsequently, galanin, gene expression was significantly higher in nursing mothers. Anterior pituitary galanin gene expression was 12-fold higher in nursing mothers compared with those that were not, 3 d after parturition. Similarly, PRL gene expression was significantly lower in mothers who were not suckling their pups 3 d after parturition. Initiation of suckling alone was insufficient to stimulate galanin and PRL expression. Despite suckling for 2 d, removal of the suckling stimulus subsequently resulted in a rapid decrease in galanin gene expression. Hence, the stimulatory effect of suckling on galanin expression requires a sustained suckling stimulus. In conclusion, the data support the hypothesis that anterior pituitary galanin plays an important role during lactation, likely acting to amplify lactotroph stimulation through paracrine and autocrine mechanisms.     

Changes during lactation in the renin-like enzyme concentration in rat luteal tissue

The activity of a renin-like enzyme (RLE) previously found in rat copora lutea was studied during lactation. Luteal RLE concentration significantly increased after delivery and reached a maximum on day 5 of lactation. Plasmatic levels of PRL and progesterone also increased through lactation. Treatment with 2 bromo-alpha-ergocryptine, which diminished plasma PRL and progesterone levels, enhanced luteal RLE activity. Therefore, the increase in luteal RLE during lactation seems to be independent of PRL and progesterone levels, but dopamine could be involved in its regulation. The increase in luteal RLE is not related to the intensity of the suckling stimulus, since RLE values were not modified in mothers suckling 2 to 10 pups. In conclusion, RLE activity in rat corpora lutea changes during lactation with a pattern similar to that of plasmatic PRL and progesterone, but seems not to be regulated by these hormones, nor by the intensity of suckling. On the contrary, luteal RLE may be regulated by dopamine.     

Suppression of leptin during lactation: contribution of the suckling stimulus versus milk production.

Lactation in the rat is characterized by the suppression of pulsatile LH secretion, a large increase in food intake, and changes in energy balance due to the metabolic drain of milk production. The change in energy balance may be a major component in altering reproductive function. A number of factors may contribute to changing energy balance of a lactating animal; one is leptin, the product of adipose tissue, which is known to act partly as a satiety factor to decrease food intake. The aims of the present study were to determine whether there are changes in leptin levels during lactation, a state of high energy demand, and during periods of acute suckling in the presence or absence of changes in energy demand. Our goals were to determine whether lactation and the suckling stimulus influenced serum leptin levels and whether there was a potential role for leptin in the suppression of LH secretion during lactation. The first experiment was performed during diestrus of the estrous cycle, and chronic lactation, (day 9 post partum) in animals suckling 8 pups. The results showed that leptin levels were significantly decreased in both ovarian intact or ovariectomized lactators; this decrease parallels the suppression of pulsatile LH secretion. Serum insulin levels were not altered in the lactating animals. The second experiment was performed in ovariectomized lactators whose 8 pup litters were removed for 48 h, starting on day 9. On day 11, mothers received no pups or pups that were either nonfostered (resulting in no milk production) or fostered (resulting in milk production). The pups were allowed to suckle for 24 h. Following 24 h of acute suckling, serum leptin, and insulin levels correlated with the energy drain on the mother. The levels of leptin were normal and of insulin were elevated in mothers producing no milk. Conversely, leptin levels were suppressed and insulin levels normal in mothers producing milk. The third experiment used the same groups as described for the second experiment except that serial blood samples were collected for measurement of pulsatile LH secretion following 24 h of acute suckling. The results showed that regardless of whether leptin levels remained normal or were suppressed in response to acute suckling, pulsatile LH secretion was significantly inhibited compared with the nonsuckled control animals. In summary, these data suggest that the metabolic drain of milk production, and not the suckling stimulus itself, is the most likely factor responsible for the suppression of leptin secretion during lactation. Furthermore, although the decreased levels of leptin may be causally related to the inhibition of pulsatile LH secretion during chronic lactation, changes in leptin are not a prerequisite for the suppression of LH secretion in response to suckling.     

Suckling unmasks the stimulatory effect of dopamine on prolactin release: possible role for alpha-melanocyte-stimulating hormone as a mammotrope responsiveness factor.

Mounting evidence indicates that dopamine (DA) can stimulate as well as inhibit PRL release when given in appropriately low doses. In the present study, we investigated whether the suckling stimulus could influence this response. Pituitary cultures from suckled or nonsuckled rats were exposed to DA (10(-16) - 10(-6) M) during a reverse hemolytic plaque assay for PRL. Pituitary cells from nonsuckled rats exhibited only the inhibitory response to DA; exposure to high-dose DA (10(-6) M) reduced plaque area to 42.3 +/- 7.2% (mean +/- SEM) of control. A low dose of DA (10(-12) M) had no effect on PRL secretion (79.3 +/- 13.3% of control). In striking contrast, a brief suckling stimulus (10 min) rendered the mammotropes responsive to stimulation by low-dose DA (to 152.7 +/- 12.5% of control). Thus, suckling appears to be a requirement for expression of the stimulatory effect of DA in lactators. In a subsequent series of experiments we explored the possibility that a hypophysial factor, released during nursing, might mimic the effects of suckling on mammotrope responsiveness. Accordingly, we tested the effects of alpha-melanocyte-stimulating hormone (10(-7) M) and low-dose DA, alone or in combination, on pituitary cells from nonsuckled rats. Although neither agent alone had a dramatic effect on PRL secretion, concurrent administration of both of these significantly stimulated PRL release to 130.0 +/- 4.2% of control. Taken together, these results demonstrate that suckling renders mammotropes responsive to the stimulatory effects of DA. Moreover, our data indicate that alpha-melanocyte-stimulating hormone could function as a responsiveness factor in this phenomenon.     

Inhibition of suckling-induced prolactin release by dexamethasone.

The effect of dexamethasone (DEX) treatment (400 and 200 micrograms/kg BW 21 and 2 h before suckling stimulus, respectively) on suckling- and domperidone (DOMP)-induced PRL release was investigated in freely moving, primiparous lactating rats. DEX completely blocked suckling-induced plasma PRL release without affecting DOMP-induced release of the hormone suggesting a central action of DEX. The effect was transient because it could not be detected on the second day of testing. The effect of DEX implanted in three different brain areas on suckling- and DOMP-induced PRL release was also tested. Implants surrounding the hypothalamic paraventricular nuclei and dorsal hippocampus failed to affect PRL release induced by suckling stimulus. Surprisingly, DEX suppressed PRL release induced by suckling stimulus when it was implanted into the medial basal hypothalamus. These findings demonstrate that DEX is a potent inhibitor of the suckling-induced PRL release. They also indicate that the site of action of DEX is not at the anterior pituitary gland or the paraventricular nuclei and hippocampus because DEX treatment and DEX implants had no effect on plasma PRL levels induced by DOMP and suckling stimulus, respectively. Our data suggest that the effect of DEX is mediated through a region of the medial basal hypothalamus. The observed transient block in suckling-induced PRL release may be physiologically relevant during stress in lactating mothers for conserving pituitary stores of the hormone needed for milk production or being able to adapt to a rapid change in osmoregulation.     

The effect of exteroceptive pup stimuli on the responsiveness of prolactin release mechanisms to suckling stimuli in the lactating rat

In the lactating rat, the neural stimulus of suckling not only acutely releases PRL but also maintains the responsiveness of PRL regulatory mechanisms to subsequent nursing stimuli. Beginning near midlactation exteroceptive pup stimuli (ECS) can acutely release PRL. We have examined the capacity of this signal also to maintain the responsiveness of PRL release mechanisms to subsequent suckling stimuli. On day 14 postpartum lactating rats were either isolated from their young or exposed to ECS (without suckling) for approximately 24 h. When both groups were later nursed, plasma PRL of mothers earlier exposed to ECS rose significantly higher than that of subjects previously isolated from their young. Suckling produced a significant depletion in pituitary PRL and GH concentrations of ECS-exposed mothers; it did not produce a similar depletion in the pituitaries of the previously isolated group. When the pups were returned for suckling, ECS-exposed mothers began to nurse their pups substantially faster than did females of the isolated group. During the 6 h after nursing, the mammary glands of ECS-exposed mothers secreted milk at twice the rate of mammary glands of the isolated females. We conclude that ECS can maintain the capacity of neuroendocrine mechanisms to respond to galactopoetic hormone-releasing stimuli (consequently enhancing milk secretion) and support the maternal behavior pattern necessary for suckling to occur. As a result, ECS may become an important factor during later stages of lactation, compensating for the decline in suckling stimuli known to occur at that time.     

Changes in the pulsatile secretion of LH after the removal of and subsequent resuckling by pups in ovariectomized lactating rats

Changes in the pulsatile secretion of LH after removal of pups and subsequent resuckling were examined in ovariectomized lactating rats, and the change after removal of pups was compared with that after the removal of ovaries in cyclic female rats. The day of parturition was designated day 0 of lactation. All lactating rats were ovariectomized on day 2 of lactation. They were deprived of their pups for 6, 12, 18, 24 or 45 h before blood sampling on day 8 of lactation, or were resuckled by their pups for 1, 4, 7 or 12 h before blood collection after separation from pups for 24 h. Cyclic female rats were ovariectomized on the day of dioestrus and blood samples were taken 12, 18, 24 or 48 h or 6 days after ovariectomy. Typical LH pulses appeared in some animals from 12 h after the removal of pups. The mean LH level and the frequency and amplitude of LH pulses gradually increased after removal of pups, until after 45 h of separation the frequency reached the high level observed 6 days after ovariectomy in cyclic rats. The subsequent resuckling by pups after a 24-h separation decreased these three parameters of LH pulses rapidly. In contrast, the frequency of LH pulses was unchanged after ovariectomy in cyclic rats, although the mean LH level and the amplitude of LH pulses increased. These results suggest that the suckling stimulus suppresses pulsatile LH secretion in a different manner from that of ovarian steroids.     

Pattern and Duration of the Inhibitory Effect of Alcohol Administered Acutely on Suckling-Induced Prolactin in Lactating Rats

We have characterized the pattern and duration of the inhibitory effect of acute alcohol administration on suckling-induced prolactin (PRL) release in the lactating rat. On day 2 of lactation, litters were adjusted to eight pups. On day 6, dams were implanted with an atrial catheter and experiments were conducted on day 10 of lactation. Pups were removed from the dams at 0800 hr. An extension tube filled with heparinized saline was attached to the catheter at 1300 hr. At 1400 hr, a preinfusion (PRE 0) blood sample was removed and was followed by infusion of saline (control) or alcohol in saline (0.5, 1.0, 2.0, 2.5 g/kg body weight doses) solutions. Following the removal of a postinfusion (POST 0) blood sample, pups were returned to the mother. Subsequent blood samples were obtained 10, 30, 60, 120, and 180 min after initiation of suckling. In separate groups, the effects of alcohol on basal PRL were studied by collecting blood samples PRE 0, POST 0 and 20, 40, 60, 80, 100, and 120 min following infusion of saline or alcohol in saline to lactating rats also separated from their pups for 6 hr. Alcohol infusion did not alter basal PRL. However, suckling-induced PRL was inhibited at 10, 30, 60, and 120 min of suckling by alcohol administered at doses greater than or equal to 1.0 g/kg body weight. After 180 min of suckling, plasma PRL levels were comparable among groups. The suckling latency for the 2.5 g/kg body weight alcohol group was greater than for other groups, but the quantities of milk consumed during the 3-hr suckling period were comparable.(ABSTRACT TRUNCATED AT 250 WORDS)     

The suppression of pulsatile luteinizing hormone secretion during lactation in the rat

The inhibition of LH secretion during lactation may be the consequence of a pituitary insensitivity to GnRH stimulation and/or an inhibition of GnRH release from the hypothalamus. To assess the contribution that these mechanisms may make to the suppression of LH secretion during lactation, we described the pattern of LH secretion in lactating rats and the magnitude of LH secretion in response to a GnRH stimulus. We assessed the effect of the strength of the suckling stimulus (two and eight pups), the length of lactation (5 and 10 days), and the presence of the ovaries on the pattern of LH secretion. We also examined the pattern of LH secretion after removal of a large suckling stimulus. In the intact rat, the pattern of LH secretion during lactation was uniformly nonpulsatile, despite significant differences between animals suckling two and eight pups in pituitary responsiveness to GnRH. In intact rats suckling two pups during day 10 of lactation, significant LH secretion was stimulated by 0.4-ng pulses of GnRH every 50 min, while animals with eight pups secreted little LH in response to the same stimulus. It was concluded that a two-pup suckling stimulus was sufficient to completely suppress pulsatile GnRH release without affecting pituitary function, whereas an eight-pup suckling stimulus also depressed pituitary sensitivity to GnRH. In ovariectomized (ovx) rats suckling two pups, seven of nine animals showed no postcastration rise in LH secretion or evidence of pulsatile LH secretion during day 5 of lactation. In the remaining two animals, a castrate pattern of pulsatile LH secretion was observed, with a LH interpulse interval of 31 +/- 6 min. By day 10 of lactation, all animals suckling two pups had castration patterns of LH secretion, with a LH interpulse interval of 35 +/- 2 min, which was significantly different from the LH interpulse interval of 26 +/- 1 min observed in ovx animals without pups. Therefore, a two-pup suckling stimulus is capable of retarding the increase in LH pulse frequency characteristically seen in the rat after castration. In ovx rats suckling eight pups, the postcastration rise in LH secretion was completely inhibited in all animals examined on days 5 and 10 of lactation, and the pattern of LH secretion was uniformly nonpulsatile. A consistent pattern of pulsatile LH secretion was not reinitiated until 72 h after removal of the suckling stimulus (LH interpulse interval, 31 +/- 2 min).(ABSTRACT TRUNCATED AT 400 WORDS)     

PreproTRH(178-199) and two novel peptides (pFQ7 and pSE14) derived from its processing, which are produced in the paraventricular nucleus of the rat hypothalamus, are regulated during suckling

Suckling increases preproTRH messenger RNA in hypothalamic paraventricular neurons (PVN) and also markedly increases TRH release during the first period of lactation. Whether lactation alters preproTRH processing resulting in the generation of novel proTRH-derived peptides that may be involved in the regulation of PRL secretion lactation is not known. Therefore, in the present study we determine whether some other peptides derived from proTRH potentially contribute to lactation-induced PRL secretion. We have recently demonstrated that two members of the family of prohormone convertases PC1 and PC2 play a significant role in proTRH processing. PC1 is the major contributor in proTRH processing, whereas PC2 may have a specific role in cleaving TRH from its extended forms. In this study, we used a recombinant vaccinia virus system to coexpress rat preproTRH complementary DNA with PC1, PC2, and the neuropeptide 7B2 in GH4C1 cells (somatomammothophs, rat). We found that two novel peptides, preproTRH(178-184) (pFQ(7)), and preproTRH(186-199) (pSE(14)), were formed after the cleavage of their precursor preproTRH(178-199) (pFE(22)) by only PC2. Their formation was confirmed by microsequence analysis. Anatomical analyses revealed that these peptides are also found in the rat PVN. In addition, we found that pFE(22), pSE(14) and pFQ(7) produced a dose-dependent release of PRL from primary cultures of pituitary cells compared with one of the well studied secretagogues of PRL, TRH. To establish whether these peptides might play a role in vivo in the regulation of PRL release, we took rat litters on postnatal day 4, separated the pups from their mothers for 6 h, and then reunited the pups and mothers for 45 min. At the end of this period, the mothers were killed, acidic extracts of microdissected PVN were prepared and subjected to SDS-PAGE, followed by slicing and analysis by pFE(22) RIA. Forty-five minutes of suckling induced a marked 6-fold increase in serum levels of PRL. In addition, PVN levels of pFE(22) and pSE(14) increased approximately 5-fold during the same period in the acutely suckling females. Lactating animals that were separated from their litters and never reunited with their pups had low levels of PRL, and pFE(22) and pSE(14). These data provide the first evidence for alterations in proTRH processing in the PVN during lactation and suggest that the products of this altered processing may play a physiological role in the regulation of PRL secretion.     

Suckling increases the proportions of mammotropes responsive to various prolactin-releasing stimuli

It is well established that the suckling stimulus sensitizes or primes the anterior pituitary to PRL-releasing stimuli. It is also recognized that PRL-secreting cells from a given animal are not all alike but instead exhibit a considerable degree of functional heterogeneity. The goal of the present study was to determine whether the suckling-induced priming phenomenon is manifest at the cellular level by shifts in the relative abundance of various mammotrope subpopulations. This was accomplished by using reverse hemolytic plaque assays to evaluate the secretory characteristics of individual PRL secretors derived from lactating rats either before or after the transient application of a suckling stimulus. Groups of day 10 lactating rats separated from their litters for 4 h were either killed immediately or were reunited briefly (10 min) with their pups before death. Adenohypophyseal cells obtained after trypsin dispersion were then subjected to plaque assays for PRL. Mammotropes derived from suckled rats were, on average, considerably more responsive to the stimulatory actions of TRH and angiotensin II and less susceptible to inhibition by dopamine. Mammotropes from nonsuckled rats exhibited a bimodal frequency distribution in which plaques from the second mode were roughly 6-8 times larger (released considerably more PRL) than those from the first. Superimposition of suckling (or in vitro treatment with dopamine) caused the second mode to disappear. Suckling also enhanced greatly the fraction of PRL cells that shifted from the first to the second mode (i.e. released more hormone) after treatment with TRH or angiotensin II. Taken together, our results demonstrate that the suckling-induced sensitization of pituitary tissue to PRL-releasing stimuli is manifest at the cellular level as proportional shifts toward those cells most responsive to stimulatory secretagogues and away from those most susceptible to inhibition by dopamine.