Evidence for a role of endogenous nesfatin-1 in the control of water drinking.

Nesfatin-1, a post-translational product of the nucleobindin-2 (NucB2) gene, is produced in several brain areas known to be important in neuroendocrine, autonomic and metabolic function, including the hypothalamus and medulla. The hallmark action of the peptide is its ability at picomole doses to inhibit food and water intake in rodents and, indeed, the effect on water intake is more pronounced than that on food intake. In preliminary studies, we observed a decrease in hypothalamic NucB2 expression in response to overnight water deprivation even when food was present, which reversed when water was returned to the animals. We therefore hypothesised that the effect of nesfatin-1 on water drinking was independent of its anorexigenic action. Indeed, rats administered nesfatin-1 i.c.v. consumed significantly less water than controls in response to a subsequent, dipsogenic dose of angiotensin II, or upon return of water bottles after 18 h of fluid restriction (food present), or in response to a hypertonic challenge. Pretreatment with an antisense oligonucleotide against nesfatin-1 significantly reduced levels of immunoreactive nesfatin-1 in the hypothalamic paraventricular nucleus and resulted in exaggerated drinking responses to angiotensin II. The results obtained in the present study suggest that locally produced nesfatin-1 may be an important component of the hypothalamic mechanisms controlling fluid and electrolyte homeostasis.

Adrenomedullin and the control of fluid and electrolyte homeostasis.

Two potent hypotensive peptides, adrenomedullin (AM) and proadrenomedullin N-terminal 20 peptide (PAMP), are encoded by the adrenomedullin gene. AM stimulates nitric oxide production by endothelial cells, whereas PAMP acts presynaptically to inhibit adrenergic nerves that innervate blood vessels. Complementary, but mechanistically unique, actions also occur in the anterior pituitary gland where both peptides inhibit adrenocorticotropin release. In the adrenal gland both AM and PAMP inhibit potassium and angiotensin II-stimulated aldosterone secretion. Natriuretic and diuretic actions of AM reflect unique actions of the peptide on renal blood flow and tubular function. In the brain AM inhibits water intake and, in a physiologically relevant manner, salt appetite. Both AM and PAMP act in the brain to elevate sympathetic tone, effects that mirror the positive inotropic action of AM in the heart. Cardioprotective actions in the brain and heart may be important counter-regulatory actions that buffer the extreme hypotensive actions of the peptides when released in sepsis. Thus the biologic actions of the proadrenomedullin-derived peptides seem well coordinated to contribute to the physiologic regulation of volume and electrolyte homeostasis.

Proadrenomedullin-derived peptides.

Posttranslational processing of the adrenomedullin gene product results in the formation of at least two biologically active peptides, adrenomedullin (AM) and proadrenomedullin N-20 terminal peptide (PAMP). Produced predominantly in the vasculature, both peptides are potent hypotensive agents, albeit via unique mechanisms of action. The gene is transcribed in a variety of other tissues including brain, pituitary, and kidney. Numerous actions have been reported most related to the physiologic control of fluid and electrolyte homeostasis. In the kidney, AM is diuretic and natriuretic, and both AM and PAMP inhibit aldosterone secretion by direct adrenal actions. In pituitary gland, both peptides at physiologically relevant doses inhibit basal ACTH secretion, again by apparently differing mechanisms. Additionally, AM antagonizes CRH-stimulated ACTH release. The peptides are produced in numerous brain sites, including hypothalamus and brainstem. Inhibition of AVP release has been reported and the physiologic significance of AM's ability to inhibit water drinking and salt appetite has been established. Thus the peptides appear to act in brain and pituitary gland to facilitate the loss of plasma volume, actions which complement their hypotensive effects in the blood vessel. Interestingly, direct cardiac effects (positive inotropism and chronotropism) and CNS actions (sympathostimulation) have been reported, leading to the hypothesis that these peptides also can exert important cardioprotective effects, helping to prevent vascular collapse during states of high AM secretion such as sepsis.

Opposing neuroendocrine actions of the natriuretic peptides: C-type and A-type natriuretic peptides do not interact with the same hypothalamic cells controlling prolactin secretion.

The two major members of the family of natriuretic peptides (NPs) in brain, A-type natriuretic peptide (ANP) and C-type natriuretic peptide (CNP) exert opposing actions on the neuroendocrine regulation of prolactin (PRL) secretion. We have targeted for compromise and destruction cells within the diencephalon which bear receptors for ANP (NRP-A receptors), CNP (NRP-B receptors), or both peptides (NPR-C receptors) using novel cytotoxin cell targeting methodology in order to determine if the neuroendocrine effects of these two peptides are exerted on similar cell systems. In animals pretreated with ANP conjugated to the cytotoxic A chain of ricin, central administration of a dose of ANP which is known to inhibit PRL secretion did not alter PRL levels in plasma; however, subsequent administration of CNP elicited the stimulation of PRL secretion. In rats pretreated with CNP-ricin A chain conjugate, a treatment we hypothesize targets for destruction CNP responsive cells, ANP injection did inhibit PRL secretion, while the stimulatory effect of CNP was absent. These results suggest that the neuroendocrine effects of these two natriuretic peptides on PRL secretion are expressed on different cellular elements of the hypothalamo-pituitary axis. Furthermore, they reveal that neither peptide acts directly on the tuberoinfundibular dopamine system since pretreatment with either cytotoxin conjugate failed to alter basal PRL levels. Thus ANP and CNP do not appear to express opposing actions on the same cell systems, suggesting the recruitment of each peptide individually by differing, unique stimuli for PRL release.

C-type natriuretic peptide mediates the hypothalamic actions of the natriuretic peptides to inhibit luteinizing hormone secretion.

Both A- and C-type natriuretic peptides (ANP and CNP, respectively) significantly reduce LH secretion when injected into the third cerebral ventricle of conscious rats. To establish which natriuretic peptide receptor subtype transduces these inhibitory messages, we have employed novel cytotoxin cell targeting techniques to selectively destroy cells in the hypothalamus that respond to ANP or CNP. Rats pretreated with ANP conjugated to the toxic A-chain of the plant cytotoxin ricin failed 1 week later to respond to central injection of ANP with the normal inhibition of LH secretion. These rats did, however, respond with significant inhibition of LH secretion to central injection of CNP. In fact, the LH inhibition observed after CNP injection was significantly greater than that expressed after similar injection of CNP in rats pretreated with unconjugated ricin A-chain (toxin control). Those control rats displayed significant reduction of LH levels in response to ANP injection as well. Plasma LH levels were not significantly affected by central administration of either ANP or CNP in rats pretreated with ricin A-chain conjugated to CNP. These results further demonstrate the power of this novel technology and provide positive evidence supporting our hypothesis that ANP exerts its LH-inhibiting effect by displacing endogenous CNP from clearance receptors within the brain. This endogenous CNP, then, like exogenously applied CNP, activates the guanyl cyclase-B receptors on cells, which are part of the network controlling the release of LHRH.

Hypothalamic endothelin: presence and effects related to fluid and electrolyte homeostasis.

Endothelin-3-like immunoreactivity (ET-3-ir) was detected in extracts of rat hypothalamic median eminence, and in the anterior and neurointermediate lobes of the pituitary at levels (ng ET-3/mg protein) exceeding those present in extracts of abdominal aorta. This ET-3-ir appeared authentic because radioimmunoassay (RIA) dose-response curves parallel to those of synthetic ET-3 could be constructed and this ET-3-ir comigrated on C-8 high-pressure liquid chromatography (HPLC) with synthetic ET-3. Endothelin-1-like immunoreactivity, on the other hand, was abundant in extracts of abdominal aorta and cerebral cortex and only minimally present in hypothalamus and anterior pituitary gland. Central administration of 11 and 23 pmol ET-3 resulted in significant (4.2- and 5.7-fold, respectively) elevations of plasma levels of vasopressin. Oxytocin levels were transiently, yet significantly, elevated (1.8-fold) by the higher dose of ET-3. These results, and our findings that central administration of ET-3 inhibits stimulated water drinking, suggest a physiologically important role for endogenously produced endothelin in the central mechanisms regulating fluid and electrolyte homeostasis.

A nonoxytocinergic prolactin releasing factor and a nondopaminergic prolactin inhibiting factor in bovine neurointermediate lobe extracts: in vitro and in vivo studies.

Several peptidergic PRL-releasing factors (PRFs) have been described; however, none have been proven to be of primary physiological importance in the control of hormone release. Similarly dopamine withdrawal alone cannot completely explain the profiles of PRL secretion observed under a variety of conditions. We describe here the isolation in semipurified form of both a PRF and a PRL-inhibiting factor (PIF) from bovine neurointermediate lobe (NIL) extracts. Acid extracts of bovine NILs stimulated, in a dose-related manner, PRL release from cultured anterior pituitary cells, even after immunoabsorption of endogenous oxytocin from the extract. PIF and PRF activities were semipurified from NIL extracts by Sephadex chromatography and detected by in vitro and in vitro bioassays. The PRF material could be separated from oxytocin by gel sieving and was active in the presence of dopamine in vitro unlike synthetic oxytocin and in cell preparations in which the oxytocin-responsive lactotrophs had been removed by selective cytotoxin cell targeting using an oxytocin-ricin A chain cytotoxic conjugate. The PRF material stimulated PRL secretion in a dose-dependent fashion in conscious male rats after iv injection. The PIF material comigrated on sizing gel chromatography with immunoreactive oxytocin and was active in vitro during dopamine blockade with domperidone and in vivo in the presence of endogenous dopaminergic tone. These data suggest that novel factors present in the NIL might exert physiologically relevant control over lactotroph function and add to the growing literature on the presence of a PRF in the NIL.

Interactions of dopaminergic and peptidergic factors in the control of prolactin release.

Oxytocin (OT) has been shown to play a role in the control of physiological PRL release and has been demonstrated to have a direct effect on the pituitary to stimulate PRL secretion. Administration of OT into the third ventricle, however, lowers PRL levels. This reduction could be mediated by either an inhibition of the release of endogenous OT into the hypohysial portal circulation or via an alteration in the release of some other PRL releasing (PRF) or PRL release-inhibiting (PIF) factor. In order to determine if centrally administered OT lowers PRL levels by increasing secretion of dopamine (DA) into the portal circulation, endogenous dopaminergic tone was blocked by injection of the DA antagonist domperidone (DOM). Subcutaneous administration of DOM resulted in elevated PRL levels which could be further augmented by iv infusion of OT (at 0.01 or 0.1 microgram OT/kg.min) or partially, but significantly, reduced by pretreatment with anti-OT antiserum (0.75 ml) indicating that under conditions of DA blockade, OT (which has little PRF activity during conditions of normal dopaminergic tone) can stimulate PRL secretion by a direct pituitary action. Treatment with DOM did not prevent, however, the reduction in PRL levels produced by central administration of OT (2 micrograms). This suggests that the effect of OT to alter PRL secretion when administered into the third ventricle was not mediated via an increase in DA release into the portal circulation. Furthermore, central administration of the OT antagonist CAV-259 (1-deamino-2-D-Trp-4-Val-8-Orn-OT) after DOM treatment resulted in a significant increase in PRL secretion indicating that endogenous levels of OT within the hypothalamus inhibit PRL secretion through a nondopaminergic mechanism. This stimulatory effect of the OT antagonist was not blocked by pretreatment with anti-OT antiserum (iv) which had been demonstrated previously to reduce the PRL surges in lactating mothers and steroid-primed ovariectomized rats, as well as to block the increase in PRL secretion seen after central administration of vasoactive intestinal peptide (VIP). Thus the central effect of OT to alter PRL secretion was probably not due to a change in the release of OT into the portal circulation. Intravenous administration of a VIP antagonist (D-4-Cl-6-Phe-17-Leu-VIP, previously demonstrated to be capable of reducing the PRL surge seen in lactating mothers) into DOM-treated rats does not alter PRL levels but blocks the ability of central administration of the OT antagonist CAV-259 to increase PRL levels under these conditions.(ABSTRACT TRUNCATED AT 400 WORDS)

Oxytocin mediates the hypothalamic action of vasoactive intestinal peptide to stimulate prolactin secretion.

The ability of centrally administered vasoactive intestinal peptide (VIP) to stimulate PRL secretion when injected intracerebroventricularly could be due to leakage to the pituitary, where it is known to exert direct PRL-releasing activity, or to a hypothalamic action on its own release or that of another possible PRL-releasing factor. When 3 micrograms VIP were injected into the third ventricle of conscious ovariectomized rats, a significant (P less than 0.005) and transient elevation of plasma oxytocin (OT) levels was observed. When OVX rats were injected iv with 1 ml anti-OT serum 30 min before the central administration of 3 micrograms VIP, the PRL surge seen after VIP injection in normal rabbit serum-treated controls was completely absent. The PRL surge seen after central VIP administration was not significantly altered by iv saline infusion (1 ml over 30 min) or by infusion of a VIP antagonist [D-4-Cl-Phe6,Leu17]VIP at a dose of 0.5 microgram/kg.min in 1 ml saline for 30 min before the VIP injection. This was not due to the inability of the VIP antagonist to block the PRL-releasing factor activity of VIP, since it significantly antagonized that action both in vitro and in vivo in the suckling stimulation paradigm. However, the PRL surge was completely absent in ovariectomized rats pretreated by iv infusion of an OT antagonist, [deamino Cys1,D-Trp2,Val4,Orn8]OT, at a similar dose. This recruitment of OT by VIP indicates that it may act at more than one locus within the hypothalamo-pituitary axis to insure the coordinated control of PRL secretion.

Atrial natriuretic factor inhibits luteinizing hormone secretion in the rat: evidence for a hypothalamic site of action.

The presence of atrial natriuretic factor (ANF) immunoreactivity and receptors for ANF in the median eminence, hypothalamus, and anterior pituitary gland suggests a role for the peptide in the hypothalamic control of anterior pituitary function. In conscious ovariectomized female rats, transient elevation of plasma levels of ANF by volume loading, a stimulus known to release endogenous ANF from the heart, or by bolus iv injection of 0.1, 1.0, or 10 micrograms synthetic ANF failed to result in altered circulating levels of LH or GH. Constant iv infusion of ANF for 30 min, such that 2- to 3-fold elevations in plasma ANF were detected by RIA resulted, however, in significant inhibition of LH release in ovariectomized female rats (0.05 and 0.1 micrograms ANF/kg.min) and orchidectomized male rats (0.1 microgram ANF/kg.min). It was unlikely that this effect was exerted at the level of the anterior pituitary, since ANF failed to alter basal or LHRH-stimulated LH release from cultured anterior pituitary cells in vitro and since iv infusion of 0.1 microgram ANF/kg.min failed to alter pituitary responsiveness in vivo to a 10-ng bolus injection of LHRH. Significant inhibition of LH secretion was also observed after third cerebroventricular injection of 1.0 or 2.0 nmol ANF. As with iv infusion, central administration of ANF failed to significantly alter GH secretion. LHRH release from median eminence explants incubated in vitro in the presence of dopamine (60 or 120 microM) was inhibited by 10(-7) M ANF, suggesting a median eminence site of action of the peptide. Finally, an opiate involvement in the mechanism of ANF's action was suggested, since naloxone (0.5 mg, iv, followed by a 60-min infusion of an additional 1 mg) completely blocked the ability of ANF (0.1 or 0.5 microgram/kg.min, infused over the last 30 min of naloxone administration) to inhibit LH release. These data suggest that ANF can act centrally to alter the hypothalamic control of gonadotropin secretion, possibly by interacting with central dopaminergic and peptidergic systems. They further suggest actions of ANF within the brain unrelated to its previously described effects on fluid and electrolyte homeostasis.

Further evidence for a hypothalamic site of action of atrial natriuretic factor: inhibition of prolactin secretion in the conscious rat.

The presence of atrial natriuretic factor (ANF) in the hypothalamus and pituitary gland suggests a possible neuroendocrine action of the peptide. Because ANF has been shown to alter the activity of hypothalamic neurons and to interact with brain dopamine systems, we examined the possibility that it might be involved in the hypothalamic control of prolactin (PRL) and thyroid-stimulating hormone (TSH) secretion. Neither basal not stimulated release of PRL or TSH from cultured dispersed anterior pituitary cells was altered by doses of ANF ranging from 10(-11) to 10(-6) M. Similarly, the in vitro inhibition of PRL release by dopamine was not affected by the presence of ANF (10(-7) M). Plasma levels of PRL and TSH in conscious male rats infused for 30 min with 0.01 or 0.1 microgram ANF-kg-1.min-1 did not differ significantly from those present in saline infused controls. Third-cerebroventricular injection of saline (2 microL) or saline plus ANF (0.02, 0.1, 1.0, or 2.0 nmol) did not significantly alter TSH secretion; however, injection of the two highest doses of ANF resulted in significant inhibition of PRL release. Levels of PRL remained significantly reduced for 90 min after injection of 2 nmol ANF. The results indicate that ANF can act centrally to alter the release of neural factors responsible for the hypothalamic control of lactotroph function.

Hypothalamic action of atrial natriuretic factor to inhibit vasopressin secretion.

The ability of synthetic atrial natriuretic factor (ANF) to inhibit vasopressin (AVP) release, as well as its action to inhibit water intake and salt preference in the rat, suggest a role for the peptide in the hypothalamic control of fluid volume in addition to its established actions in the kidney. We report here evidence for a direct, hypothalamic site of action of ANF to inhibit, specifically, AVP secretion. Third cerebroventricular infusion of 1.0 (p less than 0.05) and 2.0 (p less than 0.025) nmoles ANF significantly inhibited AVP release in euvolemic, normally hydrated rats while IV doses of ANF failed to significantly alter AVP release except when 5 nmoles (p less than 0.05) were infused. No significant effects on oxytocin (OT) release were observed. Vasopressin release from median eminence or pituitary, neural lobe explants during static, in vitro incubations was not significantly altered by doses of ANF ranging from 10(-12) to 10(-7) molar. Release of AVP during perifusion of neural lobe explants in the presence of ANF was similarly unaffected. However, AVP and not OT release from hypothalamo-neurohypophysial system explants was significantly inhibited in the presence of 10(-8) and 10(-7) M ANF, suggesting an action of the peptide at the levels of the AVP-producing cell bodies in the included supraoptic nucleus either directly or via an action on an interneuron, and not at the AVP-containing terminal fields in the median eminence or neural lobe.

Arginine vasopressin as a thyrotropin-releasing hormone.

Although hypothyroidism (with concomitant increased levels of thyroid-stimulating hormone) has been associated with elevated plasma vasopressin, the role that vasopressin plays in controlling thyroid-stimulating hormone secretion from the adenohypophysis is not understood. In two in vitro pituitary cell systems, vasopressin caused a specific and dose-related release of thyroid-stimulating hormone from cells that was equal in potency to that elicited by thyrotropin-releasing hormone, the primary acknowledged regulator of thyroid-stimulating hormone release. When injected into the hypothalamus, however, vasopressin specifically inhibited the release of thyroid-stimulating hormone. Thus, vasopressin may exert differential regulatory effects on thyroid-stimulating hormone secretion in the hypothalamus and pituitary gland.

Central administration of atrial natriuretic factor inhibits saline preference in the rat.

Atrial natriuretic factors (ANFs), produced in myocytes of mammalian atria, exert potent natriuretic and diuretic actions in the kidney as well as a variety of other actions coordinated to normalize extracellular fluid volume. Recently, ANF-like immunoreactivity has been detected in the hypothalamus of the rat, and central administration of ANF has been shown to block dehydration-induced water intake. We describe here the ability of 0.2 and 2.0 nmol atriopeptin III to inhibit saline intake when infused into the third ventricle of conscious, salt-depleted rats; an effect that was dose-related and long-lasting (24 h). These studies provide further evidence for a central nervous system action of ANF, which, together with its established renal and adrenal actions, might be an important feature of the coordinated physiological control of fluid volume.

Naloxone-induced dissociation of oxytocin and prolactin releases.

Immobilization of adult male rats resulted in concomitant, significant releases of prolactin (PRL) and oxytocin (OT). Naloxone (0.2 mg/kg, i.p.) administration 30 min prior to initiation of restraint resulted in a significant diminution of the PRL response to stress. On the other hand, a significant augmentation of OT release was observed. These results demonstrate that concomitant releases of OT and PRL in response to a given physiologic stimulus (stress) can be dissociated and suggest that the hypothalamic events which are responsible for the release of these hormones during stress are different.

Neuropeptide Y affects secretion of luteinizing hormone and growth hormone in ovariectomized rats.

Neuropeptide Y (NPY) has recently been localized in the rat hypothalamus. We have evaluated the effects of NPY on hypothalamic and pituitary function by injecting NPY into the third ventricle in vivo and by examining its action on perifused pituitary cells in vitro. Injections of NPY into the third ventricle of conscious ovariectomized rats led to a dramatic and highly significant reduction in plasma luteinizing hormone (LH) relative to pretreatment levels in these animals or to those of controls injected with physiological saline. Significant inhibition was obtained with doses ranging from 0.02 to 5.0 micrograms (4.7-1175 pmol) of NPY. These inhibitory effects on LH release were dose dependent and lasted for at least 120 min after injection of 5.0 micrograms of NPY. Intraventricular injection of NPY also significantly decreased plasma growth hormone; however, the threshold dose was 2.0 micrograms (470 pmol), a dose 100-fold greater than the lowest dose that inhibited LH release. Plasma follicle-stimulating hormone was unaffected by injection of NPY. NPY (10(-6) and 10(-7) M) stimulated secretion of LH, growth hormone, and follicle-stimulating hormone from perifused anterior pituitary cells loaded in a Bio-Gel P-2 column. These results indicate that NPY acts on structures adjacent to the third ventricle to inhibit the secretion of LH and growth hormone but not follicle-stimulating hormone, whereas it can directly stimulate the secretion of all three hormones from the cells of the anterior pituitary in vitro. Since NPY has been found in the hypothalamus and median eminence, it is quite likely that it plays a physiologically significant role at both hypothalamic and pituitary sites: influencing secretion of pituitary hormones.

A possible role of prostacyclin to stimulate prolactin and growth hormone release by hypothalamic and pituitary actions, respectively.

Prostacyclin (PGI2) (1-5 micrograms in 3 microliters 0.05 M Tris/HCl buffer, pH 7.5) and its stable metabolite, 6-oxo-PGF1 alpha, were microinjected into the third ventricle of ovariectomized rats, and plasma FSH, GH, PRL, and TSH levels were measured by RIA. Control animals received 3 microliters buffer. Injection of 5 micrograms PGI2 dramatically elevated plasma PRL values (4- to 5-fold) at 5 and 15 min, whereas the same dose of 6-oxo-PGF1 alpha produced a significant but smaller (2-fold) stimulatory effect. A delayed increase (1.5-fold) in plasma GH occurred after intraventricular PGI2 at 30 and 60 min. 6-Oxo-PGF1 alpha failed to alter GH levels. There were no alterations in plasma FSH and TSH after intraventricular injection of PGI2. Dispersed, overnight cultured cells from anterior pituitaries of ovariectomized rats were tested with 10(-4)-10(-7) M PGI2 and its metabolite. After 15 min of incubation, 3 X 10(-5) PGI2 produced a highly significant elevation in GH release (P less than 0.001), whereas there was no alteration in PRL levels. Only pharmacological doses of 6-oxo-PGF1 alpha (10(-4) M) stimulated GH release. There was no alteration in PRL release by the cultured cells even in the presence of 10(-4) PGI2. These results suggest that PGI2 stimulates PRL release by a hypothalamic action either to increase the release of PRL-releasing factor, or to decrease release of PRL-inhibiting factor, or by both mechanisms. The delayed stimulatory effect of PGI2 on the release of GH may be exerted via an effect on the anterior lobe itself, since PGI2 was effective in stimulating GH release by the incubated pituitary cells.

Presence and possible site of action of secretin in the rat pituitary and hypothalamus.

Secretin-like immunoreactivity was detected in extracts of several rat brain structures by radioimmunoassay, most notably in the pituitary, hypothalamus, pineal and septum. Its localization to these structures suggested that it might play a role in neuroendocrine events similar to its structural homolog vasoactive intestinal peptide. Dose-related stimulations (MED, 10(-7) M) of prolactin (PRL) release were observed after incubation of synthetic secretin with dispersed, cultured pituitary cells from male and ovariectomized (OVX) female rats. In OVX females, i.v. infusion of a high dose of secretin (10 micrograms) resulted in a significant elevation of PRL levels. Doses of secretin as low as 0.1 micrograms when administered into the third cerebroventricle were capable of significantly inhibiting PRL release in both males and OVX females, suggesting an ultrashort-loop, negative feedback of secretin. Secretin can now be added to the growing list of putative PRL-releasing agents.

Recent studies on the role of brain peptides in control of anterior pituitary hormone secretion.

Recent work in our laboratory on the role of peptides to influence release of pituitary hormones by direct action on the gland and also some of the interactions of these peptides at the hypothalamic level to alter release of pituitary hormones will be reviewed. Considerable evidence from hypothalamic stimulation and lesion studies suggests the existence of a separate FSH-releasing factor (FSHRF). We have been able to purify a bioactive FSHRF which appears to be distinct from LHRH. Consequently, we believe that a distinct FSHRF will ultimately be isolated. With regard to prolactin, it is now clear that it is under dual control by both prolactin-inhibiting (PI) and prolactin-releasing factors (PRF). Although dopamine acts as a PIF, our recent fractionation studies indicate the existence of a peptidic PIF in hypothalamic extracts which can be separated from dopamine and GABA. The peptidic PIF is eluted from Sephadex in the same position originally described by us a number of years ago. Thus, inhibitory control is probably mediated by a combination of factors which would include dopamine, possibly GABA and a peptidic PIF. A number of peptides have been shown to have PRF activity which include TRF and also VIP. In recent studies, we have shown a prolactin-releasing action of oxytocin on male hemipituitaries or dispersed pituitary cells. Furthermore, high doses of oxytocin given intravenously released prolactin in male rats. There is a correlation between estrogen-induced prolactin release and an increase in plasma oxytocin and a correlation between suckling-induced oxytocin and prolactin release. These results suggest that oxytocin may be an important PRF.(ABSTRACT TRUNCATED AT 250 WORDS)