Rapid augmentation of prolactin cell number and secretory capacity by an estrogen-induced factor released from the neurointermediate lobe

17 beta-Estradiol (E2) has been shown to exert an acute stimulatory effect on PRL secretion via an indirect action involving the neurointermediate lobe (NIL). In the present study we used a reverse hemolytic plaque assay to determine whether this effect was manifested as an augmentation of the number of PRL secretors and/or an increase in the amount of hormone released per PRL cell. Cultures of anterior pituitary (AP) and NIL cells from ovariectomized rats were cultured overnight, exposed to the treatment (E2 or vehicle) for 3 h, and then subjected to a reverse hemolytic plaque assay that was carried out in the presence or absence of TRH. Concurrent exposure of AP cells to E2 and NIL cells evoked an 11-12% increase in the overall proportion of PRL-secreting cells. This was true when the AP and NIL cells were incubated as a mixed culture and when the two cell types were maintained in the same petri dish but on separate plastic supports, and TRH did not significantly influence this response. The effect of E2 on the number of PRL secretors was negated when NIL cells were not present throughout the experiment or when they were removed from the cultures just before commencement of E2 treatment. Simultaneous treatment with E2 and NIL cells also significantly augmented the sizes of PRL plaques produced under basal conditions by AP cells. Taken together, these results demonstrate that E2 stimulates NIL cells to release an activity that enhances PRL secretion in two ways: 1) by recruiting additional PRL cells into the secretory pool, and 2) by augmenting the secretory capacity of individual PRL cells.     

Neurointermediate lobe peptides recruit prolactin-secreting cells exclusively within the central region of the adenohypophysis.

There is strong evidence that the hypophyseal neurointermediate lobe (NIL) mediates 17 beta-estradiol (E2)-induced PRL secretion in rats. Our laboratory has previously demonstrated that E2 stimulates NIL cells to release an activity that acutely increases the relative abundance of PRL-releasing cells in anterior pituitary (AP) cell cultures. We later found that secretory products of the NIL melanotropes, specifically the acetylated forms of alpha MSH and beta-endorphin (beta END), can account for this activity. Given that blood from the NIL initially perfuses the region of the AP proximal to the NIL, we tested the hypothesis that this specific area was preferentially responsive to the lactotrope recruitment activities. AP glands from ovariectomized rats were dissected into an inner zone, proximal to the NIL, and the remaining outer zone of the gland, then dispersed with trypsin. The resulting cells were cultured for 16 h, either alone or in coculture with NIL cells, and subsequently treated with medium alone (control) or with alpha MSH, beta END, or E2 (all at 1 x 10(-7) M) for 3 h and then subjected to reverse hemolytic plaque assays for PRL release. Under control conditions, the proportion of PRL-secreting cells was significantly greater in cultures from the outer zone of the AP than in those from the corresponding inner zone of the gland. Treatment of AP cells from the inner zone with alpha MSH, beta END, or the E2-induced NIL activity significantly increased the percentage of PRL secretors by about 8% of all AP cells. In contrast, the fraction of PRL-secreting cells in cultures from the outer zone was not affected by these treatments. We conclude that the recruitment of PRL-secreting cells in response to products of the NIL occurs only in that region of the AP proximal to the NIL.     

Prolactin release after 5-hydroxytryptophan treatment requires an intact neurointermediate pituitary lobe

The present study was designed to evaluate the role of the neurointermediate pituitary lobe (NIL) in the 5-hydroxytryptophan (5-HTP)-induced increase in plasma PRL levels. The neurochemical mechanisms involved in this neuroendocrine regulation were also analyzed by examining the concentrations of serotonin (5-HT), norepinephrine, and dopamine as well as their primary metabolites in the median eminence (ME), NIL, and anterior pituitary (AP) after different treatments. Removal of the NIL (NIL-X) did not significantly affect basal plasma PRL concentrations or amine metabolism in the ME or AP. 5-HTP administration resulted in a 5-fold increase in plasma PRL in sham-operated (SHAM) animals, but NIL-X completely abolished this PRL response. 5-HTP injection elicited large increases in 5-HT and 5-hydroxyindole-3-acetic acid concentrations in ME, NIL, and AP in SHAM animals, and similar changes within the ME and AP in NIL-X animals, but did not significantly affect norepinephrine or dopamine metabolism in the ME, NIL, or AP of NIL-X or SHAM animals. Moreover, tissue concentrations of 5-HTP after 5-HTP injection increased similarly in SHAM and NIL-X animals. Inhibition of peripheral decarboxylase activity with MK486 prevented the 5-HTP-induced increase in PRL in SHAM animals and the increase in 5-HT metabolism in both SHAM and NIL-X groups. These data indicate that an intact NIL is required for the 5-HTP-induced increase in plasma PRL, but does not seem to be essential for the regulation of basal PRL release. They also demonstrate that the 5-HTP-induced activation of 5-HT metabolism in both ME and AP is not sufficient, by itself, to enhance PRL release.     

Alpha-melanocyte-stimulating hormone is a mammotrophic factor released by neurointermediate lobe cells after estrogen treatment.

When neurointermediate lobe (NIL) cells from ovariectomized rats are exposed to 17 beta-estradiol (E2) in vitro, they release a substance that rapidly induces the recruitment of additional PRL cells into the secretory pool. In the present study we tested the hypothesis that this mammotrophic factor is alpha MSH. Cocultures of anterior pituitary and NIL cells were incubated for 18 h, exposed to various treatments for 3 h, and then subjected to a reverse hemolytic plaque assay to quantify the percentage of all pituitary cells that released PRL. Combined exposure to E2 and NIL cells caused a significant increase in the fraction of anterior pituitary cells that released PRL, and the presence of TRH during the reverse hemolytic plaque assay did not affect the magnitude of the response. Treatment with dopamine (which inhibits alpha MSH release) reversed the recruitment of PRL secretors induced by E2 stimulation of NIL cells. Likewise, immunoneutralization with an antiserum directed against alpha MSH abolished the response. Furthermore, alpha MSH alone could substitute for E2 and NIL cells in evoking the recruitment response, whereas none of several other POMC-derived peptides had any consistent effect. Taken together, these results demonstrate that alpha MSH is a mammotrophic factor released by NIL cells in response to E2.     

Estrogen lowers immunoreactive beta-endorphin in the neurointermediate lobe of the rat pituitary

The effects of ovariectomy and sex steroids on tissue levels of immunoreactive beta-endorphin (ir-beta EP) were examined. Adult female Sprague-Dawley rats were sham operated, ovariectomized (OVX), adrenalectomized (ADRX), or ADRX-OVX. Animals were given estradiol (E2) or vehicle (oil) by six daily im injections, and tissue levels of immunoreactive beta-endorphin (ir-beta EP) determined. In OVX animals, neurointermediate lobe (NIL) content of ir-beta EP was double that in controls; plasma ir-beta EP was modestly but significantly raised, but levels in the anterior pituitary (AP) remained unaltered. The effects of ovariectomy on NIL and plasma ir-beta EP were reversed by E2 in a dose-related manner. ADRX-OVX animals showed elevations of AP and NIL ir-beta EP to levels double those in SHAM, and plasma levels 5 times higher. E2 administration to ADRX-OVX rats normalized ir-beta EP in NIL, but not that in AP nor plasma. These findings suggest that the ovary may exert a specific tonic influence on NIL ir-beta EP in the rat, and that this inhibition appears to be mediated, at least in part, through ovarian estrogen.     

Opioid peptides of the pituitary and hypothalamus: changes in pregnant and lactating rats

Immunoreactive (Ir) beta-endorphin concentrations were determined in plasma, anterior pituitary (AP), neurointermediate pituitary lobe (NIL) and mediobasal hypothalamus (MBH) of pregnant (12-14 and 18-20 days) and fertile control rats, during labour and lactation. Immunoreactive Met-enkephalin concentrations were also evaluated in the MBH. Concentrations of Ir beta-endorphin in plasma, AP and NIL of rats during early and late pregnancy were significantly higher than in controls, the plasma and AP contents showing an increasing pattern in the second half of gestation. During labour, Ir beta-endorphin concentrations in plasma and AP reached the highest values, whereas those in NIl remained unchanged. Lactating rats showed Ir beta-endorphin concentrations in NIL and plasma in a range similar to that found in pregnant rats, resulting in concentrations in the AP not significantly different from those of nonpregnant controls. Immunoreactive beta-endorphin and Ir Met-enkephalin concentrations in MBH of pregnant rats were almost twice as high as in controls, rising markedly during labour; during lactation levels were in the same range as in non-pregnant controls. These results indicate that pregnancy and labour are characterized by high plasma, pituitary and hypothalamic concentrations of Ir-beta-endorphin as well as by high hypothalamic Ir Met-enkephalin levels, and that Ir beta-endorphin concentrations vary differently during pregnancy, lactation and labour in the two pituitary lobes, supporting the existence of different control mechanisms in the AP and NIL.     

Glucocorticoid regulation of proopiomelanocortin gene expression in the pituitary gland of hypothalamopituitary intact and hypothalamopituitary disconnected sheep

Proopiomelanocortin (POMC) gene expression in the anterior pituitary (AP) gland has previously been shown to be positively regulated by CRF and AVP and negatively regulated by glucocorticoids. In the neurointermediate lobe (NIL) of the pituitary, however, POMC gene expression is under tonic inhibitory dopaminergic control. In the present study we have used hypothalamopituitary intact (HPI), ovariectomized (OVX), and OVX/hypothalamopituitary disconnected (OVX/HPD) ewes to examine direct (i.e. nonhypothalamic) effects of glucocorticoids on POMC gene expression in both the AP and the NIL. There was no difference between POMC mRNA levels in intact and OVX sheep. In intact animals treated with dexamethasone, AP POMC mRNA levels were half those of controls. POMC mRNA levels were increased 3-fold in OVX/HPD sheep, compared with OVX, and lowered by dexamethasone to half OVX/HPD levels. In the NIL, hypothalamopituitary disconnection resulted in slightly higher mean POMC mRNA levels than in intact animals but the large intragroup variation did not allow a significant change. Dexamethasone administration had no effect on NIL levels of POMC mRNA in intact or OVX/HPD sheep.     

Concomitant dopaminergic and glucocorticoid control of pituitary proopiomelanocortin messenger ribonucleic acid and beta-endorphin levels

Synthesis and secretion of POMC-derived peptides appear to be differentially regulated in the anterior pituitary (AP) and neurointermediate lobe (NIL). In the AP, glucocorticoids inhibit, and CRF and arginine vasopressin stimulate, synthesis of POMC and release of immunoreactive (ir)-beta-endorphin (beta EP); in the NIL, synthesis and release of POMC and its derivatives are under tonic inhibitory dopaminergic control. There is, however, evidence for some overlap of these control mechanisms under certain circumstances. In the present study we have used specific RIA and Northern blot analysis to examine the effects of chronic treatment with dopaminergic agents and dexamethasone (DM) (both alone and in combination) on AP and NIL content of ir-beta EP and POMC messenger RNA (mRNA), and/or hypothalamic ir-arginine vasopressin and ir-CRF content. In the NIL, the dopamine agonist bromocriptine reduced and the antagonist haloperidol raised both POMC mRNA and ir-beta EP content. Long term DM treatment did not alter NIL ir-beta EP content in the intact rat, but increased levels of POMC mRNA. DM abolished the haloperidol-induced increase in NIL ir-beta EP content but further increased the haloperidol-induced rise in POMC mRNA. DM treatment lowered both ir-beta EP and POMC mRNA in the AP as well as lowering levels of hypothalamic ir-CRF. In DM-treated rats, haloperidol partially restored AP ir-beta EP and POMC mRNA to control untreated levels. These findings further support the proposition that both dopaminergic agents and glucocorticoids can modulate POMC mRNA levels and/or tissue content of ir-beta EP in both the NIL and AP of the rat. The effects of DM on the NIL, both alone or with haloperidol, suggest that glucocorticoids may have both direct and indirect effects on POMC gene expression in this tissue.     

Suckling-induced change in oxytocin but not in alpha-MSH concentrations of the median eminence, the neural-, intermediate- and anterior lobes of the pituitary gland

Previous reports have implicated that pituitary-derived prolactin (PRL) is secreted from two distinct zones of mammotropes within the anterior lobe (AL). The inner zone (AL-IZ), located adjacent to the neuro-intermediate lobe (NIL), is supposed to be involved in the rapid and massive discharge of PRL from the pituitary gland due to suckling stimulus. Whereas the outer-zone (AL-OZ) gives the basal secretion and it does not play a role in the acute secretory response during nursing. Anatomically, the AL-IZ has an intimate contact with the NIL because the blood passing through the short portal vessels (SPV) bathes it first. Based on this fact it would be hypothesized that locally released and/or produced compounds, like OXY and alpha-MSH, can be delivered to the AL-IZ. In conjunction, OXY and alpha-MSH have already been implicated to play a role in the regulation of PRL release during suckling. Therefore, the purpose of this study was to examine the possible local transportation of these hormones into the median eminence and various regions of the pituitary gland of lactating rats. We have measured the concentrations of OXY and alpha-MSH from tissue samples of nonsuckled (NS) and 10 or 30 min after suckling (S) was initiated using specific RIAs. It has been shown that there are no changes in the concentration of OXY and alpha-MSH in theAL-IZ and AL-OZ due to suckling stimulus. In contrast, our data provide compelling evidence that OXY is transported into the IL, which can be further increased by suckling stimulus. These data suggest that blood transfusing NL passes through the IL before it is drained into the cavernous sinus, which opens the road for OXY into the general circulation. In addition, our data have unequivocally shown a lack of local delivery of either alpha MSH or OXY into the AL that raises serious doubt about their possible role in PRL secretion during suckling stimulus.     

N-acetylation is required for the lactotrope recruitment activity of alpha-melanocyte-stimulating hormone and beta-endorphin.

Pituitary neurointermediate lobe (NIL) cells obtained from ovariectomized rats and exposed to 17 beta-estradiol in vitro have been shown to release an activity that induces acute recruitment of additional PRL-secreting cells. We have recently reported that alpha MSH, a major secretory product of the NIL, can substitute for this lactotrope-recruiting factor released by NIL cells in response to 17 beta-estradiol. beta-Endorphin (beta END) was not effective in this regard. Inasmuch as the degree of acetylation is critical to the activities of both of these molecules in other systems, we decided to assess its importance to lactotrope-recruiting activity in the present study. Anterior pituitary cells from ovariectomized rats were cultured overnight, exposed to various treatments for 3 h, and then subjected to a reverse hemolytic plaque assay for PRL. Exposure to mono- and diacetylated alpha MSH (N-ac-alpha MSH and di-ac-alpha MSH, respectively) or N-acetylated beta END (N-ac-beta END) caused a significant increase in the fraction of anterior pituitary cells that released PRL. In contrast, the Des-acetylated variants of both molecules had no lactotrope-recruiting activity. In a dose-response study, maximally effective doses of di-ac-alpha MSH and N-ac-beta END were equally effective with respect to their function as lactotrope-recruiting factors. Furthermore, the two peptides acted cooperatively when simultaneously applied in submaximal concentrations. Taken together, these results demonstrate that 1) N-acetylation is an essential requirement for the lactotrope-recruiting activity of alpha MSH and beta END in vitro; and 2) di-ac-alpha MSH and N-ac-beta END can act in a cooperative fashion to recruit additional cells into the PRL-secreting population.     

Aromatic L-amino acid decarboxylase activity in the rat median eminence, neurointermediate lobe and anterior lobe of the pituitary. Physiological and pharmacological implications for pituitary regulation

Recent evidence demonstrating a direct effect of 5-hydroxytryptamine (5-HT) upon anterior pituitary (AP) hormone secretion has made the question of determining the location of possible sites that could supply 5-HT to the AP an important one. It has been assumed, based on indirect evidence, that aromatic L-amino acid decarboxylase (L-AAD), the enzyme responsible for the conversion of L-5-hydroxytryptophan (5-HTP) to 5-HT as well as L-3,4-dihydroxyphenylalanine (L-dopa) to dopamine (DA), is ubiquitously distributed in most tissues of the body including the AP. The present study examined the ability of the AP and two neural areas anatomically connected to the AP, the neurointermediate lobe (NIL) of the pituitary and the median eminence (ME), to decarboxylate 5-HTP to 5-HT or L-dopa to DA following either the in vitro incubation of the various tissues with 5-HTP or L-dopa or the in vivo administration of 5-HTP to rats treated previously with saline or a peripheral decarboxylase inhibitor, MK 486. The in vivo effects of 5-HTP, alone, or following MK 486 pretreatment were also examined on 5-HT synthesis and metabolism in AP tissues which were transplanted 5 days previously under the renal capsule and were, thus, isolated from central influences that might be regulating 5-HT and 5-hydroxyindole-3-acetic acid (5-HIAA) concentrations in the animal's own AP. In addition, the direct radioisotopic measurement of L-AAD activity in the ME, NIL, and AP was also analyzed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Coculture of anterior and posterior pituitary cells: selective stimulation of lactotrophs

There is extensive evidence that the posterior pituitary (PP) participates in the regulation of PRL secretion. We recently reported that a putative PRL-releasing factor is localized, and possibly produced, in the intermediate lobe of the PP. The aim of the present investigation was to determine whether cultured PP cells affect anterior pituitary (AP) function in terms of cell content and cumulative release of PRL. Anterior and posterior pituitaries from adult male rats were dispersed with trypsin and cultured either alone or together for 4 and 8 days in serum-free medium. The concentrations of PRL, GH, and LH in cell extracts and culture media were measured by RIA. Coculturing of AP and PP cells at different plating densities resulted in a 2-fold rise in PRL cell content after 4 days. The cumulative release of PRL in the cocultures was significantly increased only after 8 days. LH and GH were affected slightly, or not at all. Medium conditioned by PP cells mimicked the effects of coculture on the cumulative release of PRL, but not on the cell content. Short-term incubation with TRH induced a much larger release of PRL from AP + PP cocultures than from AP cells cultured alone. In conclusion, these data suggest that 1) PP cells stimulate the production and release of PRL in a hormone-specific manner, and 2) coculturing of AP + PP cells augments the responsiveness of lactotrophs to secretagogues such as TRH. We propose that at least two factors, one of which might be PRL-releasing factor, are involved in these effects.     

gamma-Aminobutyric acid inhibits beta-endorphin secretion from the anterior pituitary but not the neurointermediate lobe in the rat

We have evaluated the role of gamma-aminobutyric acid (GABA) in the neuroendocrine control of beta-endorphin (beta-EP) secretion in the rat. Plasma beta-EP and beta-lipotropin (beta-LPH) levels and beta-EP-like immunoreactivity (beta-EPLI) in the anterior pituitary (AP) and neurointermediate lobe (NIL) were determined after administration of GABA antagonist or agonist drugs in male rats under resting conditions or after potent physical stresses. Bicuculline (0.1-0.8 mg/kg BW ip), a GABA receptor antagonist, induced a dose-related rise in plasma beta-EP and beta-LPH levels and a concomitant decrease in beta-EPLI concentrations in the AP but not in the NIL. Muscimol, a potent GABA-mimetic drug, did not alter baseline plasma beta-EP and beta-LPH levels, whether given systemically (1.0-2.0 mg/kg BW ip) or intracerebroventricularly (500 ng/kg BW), but prevented the effect of bicuculline on plasma and AP-beta-EP and beta-LPH concentrations. Administration of foot shock or restraint stress induced a clear-cut activation of the AP-related beta-EP secretion, an effect that was prevented by pretreatment with muscimol. Together, these data show that GABA-ergic mechanisms, probably operating at a central nervous system level, exert an inhibitory action on resting and stimulated beta-EP and beta-LPH secretion. Since no alterations in beta-EP concentrations in the NIL occurred after manipulations with GABA-ergic drugs or stress, and these were detected only in the AP, an interaction between GABA-ergic neurons and CRF neurons is the most likely explanation for the reported findings.     

Dopaminergic regulation of glandular kallikrein in the intermediate lobe of the rat pituitary

The intermediate lobe of the rat pituitary contains a trypsin-like protease closely related or identical to glandular kallikrein. This study examined whether glandular kallikrein in the intermediate lobe is under inhibitory control by dopaminergic systems. Male rats were treated for 4-6 days with various doses of the following drugs, alone or in combination: haloperidol (a dopamine receptor blocker), reserpine (a catecholamine depleting agent), and bromocriptine (a dopamine receptor agonist). Neurointermediate lobe (NIL) homogenates were prepared. Following activation of latent enzymes with trypsin, glandular kallikrein was measured using two chromogenic peptide substrates. Haloperidol doubled NIL glandular kallikrein activity. Dissection of the NIL revealed that haloperidol specifically increased glandular kallikrein in the intermediate lobe and had no effect on the small amount of activity in the neural lobe. Reserpine also doubled NIL glandular kallikrein and haloperidol did not produce further increases. The reserpine-induced increase in NIL glandular kallikrein was completely blocked by concurrent administration of bromocriptine: this effect was blocked by haloperidol. The results demonstrate that intermediate lobe glandular kallikrein is under inhibitory control by dopaminergic systems. This parallels the regulation of proopiomelanocortin (POMC) synthesis in the intermediate lobe and suggests that glandular kallikrein should be evaluated as a POMC-processing enzyme.     

The effects of short photoperiod, pinealectomy, and melatonin treatment on oxytocin synthesis and release in the male syrian hamster

The pineal gland has been shown to affect plasma oxytocin (OT) levels, but the mechanism of this action is not apparent. In the present study, the ability of the photoperiod to affect plasma OT levels, neurointermediate lobe (NIL) OT content, and hypothalamic OT mRNA levels was studied in male Syrian hamsters. In addition, the ability of pinealectomy to prevent and melatonin (MEL) to mimic the short photoperiod-induced changes were also determined. Exposure to short days (SD) led to the expected decrease in testes weight and plasma PRL levels, but plasma OT levels were unchanged. However, NIL OT content was increased in the SD-exposed animals. Hypothalamic OT mRNA levels were not significantly altered by SD exposure. Pinealectomy blocked the effects of SD on testes weight, whereas afternoon MEL injections mimicked the effects of SD. In long day (LD)-exposed hamsters, pinealectomy induced a decrease in NIL OT content without altering hypothalamic OT mRNA levels. In SD-exposed animals, NIL OT content was not affected by pinealectomy. Melatonin injections had no significant effect on NIL OT content or hypothalamic OT mRNA levels. The data from the present study suggest that exposure of male Syrian hamsters to short photoperiods influences some aspects of OT synthesis and/or transport to produce its increased accumulation in the NIL, but does not affect OT release. These changes are apparently not the result of SD-induced changes in MEL secretion, but conceivably could be related to the previously documented effects of SD on hypothalamic catecholamine turnover.     

In vitro regulation of ACTH release from neurointermediate lobe of rat hypophysis. I. Effect of crude hypothalamic extracts.

Using incubated glands, we showed that cerebral cortex and liver extracts (CCE and LE) stimulated ACTH release from neurointermediate lobe (NIL) of hypophysis as well as hypothalmus extract (HE) did. Moreover, the HE-induced ACTH release was much smaller for the NIL (1.9 X basal level) than for the anterior lobe (AL; 13.7 x basal level). Thus, under these conditions, HE seemed to have no specific effect on NIL ACTH release. Using superfused glands, we showed: (a) that both spontaneous and HE-induced ACTH release decreased during superfusion; (b) that using this system, a specific stimulatory effect on HE on NIL was observed. In contrast to HE, CCE and LE had only a small effect on NIL ACTH release (always less than 20% of that caused by HE) which could be considered as a nonspecific response; (c) that trypsin suppressed the stimulating effect on HE as well on NIL as on AL; and (d) that arginine antidiuretic hormone (ADH) was not responsible for the stimulating effect of HE on NIL ACTH release, because synthetic ADH had no effect and HE containing ADH (from normal rats) or HE containing no ADH (from Brattleboro rats or from immunoneutralization of ADH in normal HE) had the same effect. From these results, we can conclude that HE contain a peptidic factor different from ADH which is able to stimulate in vitro release of ACTH from the NIL.     

Inhibition of estrogen-induced anterior pituitary enlargement and arteriogenesis by bromocriptine in Fischer 344 rats

The interrelationship between dopamine (DA) regulation and changes in the blood supply of the anterior pituitary lobe (AP) in the etiology of estradiol (E2)-induced proliferation of pituitary cells was studied in Fischer 344 rats. Rats were implanted with E2-filled or empty Silastic capsules for 21 days alone or in conjunction with pellets of the potent DA agonist bromocriptine (CB-154). Changes in vascularization of the AP, median eminence DA content, and responsiveness to DA of cultured AP cells were measured. Development of a direct arterial blood supply was assessed by the injection of 15-microns microspheres that can only reach the AP by newly formed arteries (arteriogenesis). APs were enzymatically dispersed and cultured for 3 days before challenges with increasing concentrations of DA for 3 h. DA content was measured by radioenzymatic assay, and serum PRL was determined by RIA. E2 treatment increased the weight of the pituitary gland, serum PRL levels, and the number of microspheres in the AP 4.5-, 173-, and 142-fold, respectively, over control values. Median eminence DA content was decreased 71% by E2 treatment, while the ability of DA to suppress PRL secretion in vitro decreased from a maximum of 70% to 40% with no change in the ED50. Simultaneous treatment with CB-154 dramatically decreased the effect of E2 on arteriogenesis, pituitary weight, serum PRL levels, and median eminence DA content. Blockade of E2-induced AP enlargement by increased dopaminergic stimulation was closely correlated with inhibition of arteriogenesis, which further suggests an important role for vascular changes in lactotroph proliferation.     

Effects of stimulus frequency and potassium channel blockade on the secretion of vasopressin and oxytocin from the neurohypophysis

The facilitation of peptide secretion from the neurohypophysis induced by increasing stimulation frequency is accompanied by action potential (AP) prolongation. One hypothesis argues that inactivation of potassium channels in the neural lobe terminal membranes, under these conditions, is the underlying mechanism which leads to AP prolongation, and, therefore, increased calcium entry and secretion per AP. Therefore, factors which are known to cause AP prolongation, such as stimulus frequency and potassium channel blocking agents, were studied and compared with regard to their ability to augment electrically evoked release of oxytocin (OT) and vasopressin (VP) from isolated rat neurointermediate lobes (NILs). OT release (to a constant applied stimulus of 600 spikes) was maximally facilitated by increasing frequency up to a rate of 30 Hz, whereas VP release in the same stimulus paradigm was maximal between 12 and 20 Hz. Tetraethylammonium (TEA), 4-aminopyridine (4AP) and barium each caused a significant augmentation of AP-dependent, electrically stimulated hormone release, without affecting basal levels. The magnitude of the effect of the K channel blocking agents was inversely related to the frequency of the applied stimulus. Application of either 4AP or TEA caused a shift in the range of frequency dependence for OT such that maximal release was seen at a stimulus frequency of 12 Hz, but there was no comparable change in the pattern of VP release. The maximal effects of TEA and 4AP were additive indicating that the NIL terminals have two types of K channels which appear to be involved in the regulation of secretion. Addition of the three agents together produced maximal release at a stimulus frequency of 4 Hz, which was not facilitated further by the increase of stimulus frequency to 20 Hz. These data demonstrate the importance of potassium channels in the regulation of VP and OT secretion, and provide indirect support for the spike prolongation hypothesis of frequency facilitated secretion in the neural lobe.     

The distribution of some proopiomelanocortin-related peptides in the pituitary gland of the rainbow trout, Salmo gairdneri

Acid extracts of neurointermediate lobe (NIL) and pars distalis (PD) of the pituitary gland of the rainbow trout were radioimmunoassayed for alpha-melanocyte-stimulating hormone (alpha-MSH), beta-melanocyte-stimulating hormone (beta-MSH), adrenocorticotrophin (ACTH), and endorphin. The majority of the alpha-MSH, beta-MSH, and endorphin was present in the NIL; the small amount of these peptides present in the PD may be native to this lobe, or may be due to slight contamination with NIL material--it is not possible to distinguish between these possibilities at present. All the ACTH was present in the PD. These results support the hypothesis that throughout the vertebrates proopiomelanocortin is cleaved to smaller peptides in the NIL than it is in the PD.