Disruption of 5-hydroxytryptaminergic neuronal function blocks the action of morphine on tuberoinfundibular dopaminergic neurons

Subcutaneous injections of morphine to male rats reduced dopamine(DA) turnover (α-methyltyrosine-induced decline of DA concentrations) in the median eminence, and increased DA turnover in the striatum. Selective destruction of central 5-hydroxytryptamine(5HT)-neurons with intracerebroventricular injections of 5,7-dihydroxytryptamine, or the administration of metergoline, a putative 5HT antagonist, blocked the inhibitory effects of morphine on DA turnover in the median eminence. In the same experiments disruption of 5HT neurotransmission processes caused a similar but less dramatic antagonism of the stimulatory actions of morphine on DA turnover in the striatum. Thus, 5HT neurons play a role in mediating the effects of morphine on tuberoinfundibular and possibly on nigrostriatal DA neurons.     

Mechanism of prolactin release by 5-hydroxytryptophan

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

Human urogastrone and mouse epidermal growth factor share a common receptor site in cultured human fibroblasts.

d-Amphetamine, methylphenidate and cocaine, which are postulated to release or block the reuptake of released dopamine at nerve terminals in the brain, produced only slight reductions in the serum concentrations of prolactin in normal male rats or in rats in which the prolactin concentrations were elevated by pretreatment with α-methyltyrosine. These results suggest that indirect dopaminergic drugs, such as d-amphetamine, do not facilitate the release of dopamine from the terminals of tuberoinfundibular neurons in the same way as they do at the terminals of other dopaminergic neurons in the brain.     

Increased ability of apomorphine to reduce serum concentrations of prolactin in rats treated chronically with alpha-methyltyrosine

Serum concentrations of prolactin were significantly increased in rats for up to 9 hours after a single i.p. injection of α-methyltyrosine (50 mg/kg); apomorphine caused a dose-dependent reduction of the elevated prolactin concentrations. Doses of apomorphine required to reduce serum prolactin concentrations.were lower in animals previously injected with α-methyltyrosine three times a day for 10 days than in animals which received a single injection of α-methyltyrosine. These results suggest that chronic disruption of the normal release of dopamine from tuberoinfundibular neurons leads to the development of increased sensitivity of dopamine receptors involved with the inhibition of prolactin release from the anterior pituitary.     

Regulation of prolactin in mice with altered hypothalamic melanocortin activity

This study used two mouse models with genetic manipulation of the melanocortin system to investigate prolactin regulation. Mice with overexpression of the melanocortin receptor (MC-R) agonist, α-melanocyte-stimulating hormone (Tg-MSH) or deletion of the MC-R antagonist agouti-related protein (AgRP KO) were studied. Male Tg-MSH mice had lower blood prolactin levels at baseline (2.9±0.3 vs. 4.7±0.7ng/ml) and after restraint stress (68±6.5 vs. 117±22ng/ml) vs. WT (p<0.05); however, pituitary prolactin content was not different. Blood prolactin was also decreased in male AgRP KO mice at baseline (4.2±0.5 vs. 7.6±1.3ng/ml) and after stress (60±4.5 vs. 86.1±5.7ng/ml) vs. WT (p<0.001). Pituitary prolactin content was lower in male AgRP KO mice (4.3±0.3 vs. 6.7±0.5μg/pituitary, p<0.001) vs. WT. No differences in blood or pituitary prolactin levels were observed in female AgRP KO mice vs. WT. Hypothalamic dopamine activity was assessed as the potential mechanism responsible for changes in prolactin levels. Hypothalamic tyrosine hydroxylase mRNA was measured in both genetic models vs. WT mice and hypothalamic dopamine and 3,4-dihydroxyphenylacetic acid (DOPAC) content were measured in male AgRP KO and WT mice but neither were significantly different. However, these results do not preclude changes in dopamine activity as dopamine turnover was not directly investigated. This is the first study to show that baseline and stress-induced prolactin release and pituitary prolactin content are reduced in mice with genetic alterations of the melanocortin system and suggests that changes in hypothalamic melanocortin activity may be reflected in measurements of serum prolactin levels.     

Evidence that serotonin neurons stimulate secretion of prolaction releasing factor.

The purpose of the present study was to determine if serotonin was stimulatory to prolactin release by inhibition of the dopaminergic system or by stimulating release of a prolactin releasing factor (PRF). We measured the amount of prolactin secreted after administration of 30 mg/kg of 5-hydroxytryptophan (5-HTP) to male rats pretreated with fluoxetine (10 mg/kg) and compared it with the amount of prolactin released in male rats treated with αmethyl-p-tyrosine methyl ester (αMT) or various dopamine receptor blocking agents. In every experiment the serotonergic stimulus provided by 5-HTP in fluoxetine-pretreated rats released considerably more prolactin than did treatment with αMT or dopaminergic blockers. We conclude that serotonin releases prolactin not by inhibiting dopaminergic neurons but rather by stimulating the release of PRF.     

Influence of adrenergic antagonists and apomorphine on prolactin release induced by serotonergic antagonists in the monkey.

The influence of adrenergic receptor blockers on the prolactin releasing effect of methysergide and cyproheptadine was examined in sexually mature female monkeys under ketamine anesthesia. Propranolol, a β-adrenergic blocker, at a dose of 1 mg/kg did not alter the prolactin releasing action of 0.1 mg/kg of methysergide but significantly potentiated (P < 0.025) the prolactin releasing action of 0.5 mg/kg of cyproheptadine. Phentolamine and phenoxybenzamine, both α-adrenergic blockers, at 1 mg/kg blunted the prolactin releasing effect of methysergide and cyproheptadine, but the pattern of prolactin blockade was different between the two putative antiserotonergic drugs. The prior administration of apomorphine, 4 mg/kg, a dopamine receptor stimulator, blocked the prolactin releasing effect of methysergide and cyproheptadine. Evidence presented here and from the literature indicate that the prolactin releasing action of methysergide and cyproheptadine is mediated by an antidopaminergic action directly on the pituitary.     

The effects of estradiol on pituitary responsiveness to dopamine in vitro: a comparison of ovariectomized Fischer 344 and Holtzman rats.

The objective of this study was to determine if the effectiveness of dopamine as an inhibitor of prolactin is altered by estradiol in strains of rats which show marked differences in estrogen-induced pituitary hyperplasia. Groups of Fischer 344 and Holtzman Sprague-Dawley rats were ovariectomized and implanted with Silastic capsules of estradiol. Rats were sacrificed by rapid decapitation following a brief period of ether anesthesia at 2, 4, 6, 8 weeks (F-344) or at 2 and 8 weeks (Holtzman) of estradiol treatment. The pituitary was removed and cut into fragments which were either snap frozen for initial prolactin content measurements or incubated for 60 min in the presence or absence of dopamine (1 x 10(-6) M). Prolactin was measured in the plasma, in sonicates of the pituitary and in the incubation medium by double antibody radioimmunoassay. Pituitary weight and plasma levels of prolactin were significantly less in Holtzman rats compared to Fischer 344 females at 2 or 8 weeks of estradiol treatment but pituitary concentrations of prolactin were not different between the two strains. Pituitary fragments from Fischer 344 rats studied at 2 and 4 weeks of estradiol treatment did not respond to the removal of dopamine in vitro whereas pituitary fragments from Holtzman rats obtained at 2 weeks of estradiol treatment did release significantly more prolactin in the absence than in the presence of dopamine. Pituitary fragments taken from Fischer 344 rats at 6 and 8 weeks were responsive to dopamine whereas pituitary tissue from Holtzman rats was not responsive at 8 weeks. The data indicate that temporal differences in responsiveness to the inhibitory effects of dopamine occur in strains which are susceptible or resistant to the formation of pituitary tumors following prolonged estradiol treatment.     

Effect of dopamine agonists or antagonists, TRH, stress and piglet removal on plasma prolactin concentrations in lactating gilts

The effect of dopamine agonists (ergocryptine), antagonists (chlorpromazine, haloperidol, reserpine, pimozide), thyrotropin releasing hormone or stress (restraint, piglet removal) on prolactin release was studied in primiparous lactating gilts. All animals were fitted with surgically implanted jugular catheters before farrowing. The only drug treatments which resulted in a significant change in PRL concentrations in blood were thyrotropin releasing hormone (increase) and ergocryptine (decrease). The results suggest that dopamine may not be the only regulator of prolactin in lactating pigs. Further studies are needed to identify drugs which would be useful in clinical situations for treatment of lactation failure due to low prolactin secretion. In the two stress-exposed groups, there was a gradual, steady decline in the plasma concentration of prolactin which resulted from loss of suckling contact with the piglets. Thus, snare restraint does not increase prolactin secretion in lactating sows confirming the results of other studies on pigs in different physiologic states.     

Receptors and neurotransmitters involved in the dual modulation of prolactin release by the serotoninergic system in pregnant and lactating rats

The receptors and neurotransmitter pathways that may participate in the inhibitory action of 5-hydroxytryptamine (5HT) on prolactin release during late pregnancy and lactation in rats were studied. Administration of the 5HT synthesis inhibitor, p-chlorophenylalanine, to late pregnant rats induced a significant increase in serum prolactin concentrations at 17:00 h on day 19 of pregnancy that was partially blocked by injections of the 5HT precursor, 5-hydroxytryptophan, or the 5HT agonists, 8-hydroxy-2-(di-n-propylamino)-tetralin hydrobromide (S1a), 1-(2,5-dimethoxy-4-iodophenyl)-2-aminopropane (S2) and N-(3-chlorophenyl)imidodicarbonimide diamide HCl (S3), but not by RU 24969 (S1b) or 1-meta-(chlorophenyl)-piperazine-2-HCl (S1a-2c). The 5HT neurotoxins, fenfluramine and p-chloroamphetamine, which selectively destroy fine axon serotoninergic fibres but not coarse ones, prevented the increase in circulating prolactin observed at 18:00 h on pro-oestrus and on day 21 of pregnancy, but did not modify serum prolactin concentrations at 17:00 h on day 19 of pregnancy. Administration of the adrenergic antagonists, metoprolol or prazosin, also prevented the stimulatory effects of p-chlorophenylalanine or ketanserin in pregnant rats on day 19 (17:00 h) or on days 10-12 (16:30 h) in lactating rats separated from their litters. Administration of p-chlorophenylalanine to pregnant rats on day 19 reduced dopamine concentrations in the arcuate nucleus and in the anterior hypothalamus and noradrenaline concentrations in the anterior hypothalamus and the suprachiasmatic nucleus. These results indicate that the inhibitory actions of 5HT on prolactin release in pregnant and lactating rats are mediated by S1a, S2a and S3 receptors and by the coarse axon serotoninergic fibres. In addition, the inhibitory actions of 5HT may modulate the action of a stimulatory adrenergic pathway, as well as the concentrations of noradrenaline and dopamine in different hypothalamic areas, which, in turn, particularly arcuate nucleus dopamine, regulate prolactin release.     

Fetal role in the control of parturition in the tammar, Macropus eugenii

When female tammars carrying dormant blastocysts were injected with progesterone at the time of removal of their pouch young the development of the fetus was advanced and parturition occurred 5 days earlier than in the control tammars. In these tammars the prolactin pulse was also advanced by 5 days but the usually concomitant fall in progesterone was not. In non-pregnant tammars similar injections of progesterone did not advance the subsequent fall in progesterone, oestrus, or the LH pulse. In non-pregnant tammars injected with ovine prolactin on Day 26, to mimic the prolactin pulse, plasma progesterone was reduced to basal levels within 12 h, significantly earlier than in controls. Conversely, in 5 pregnant and 1 non-pregnant tammar injected with ovine prolactin on Day 23, to mimic the condition induced by advancing the time of parturition with progesterone, the decline in plasma progesterone was not advanced and the endogenous prolactin pulse, parturition, post-partum ovulation and the LH pulse all occurred after intervals similar to those of controls. The results support the view that the fetus is associated with the pre-partum prolactin pulse in maternal plasma and that a prolactin pulse at this stage is luteolytic in non-pregnant tammars.     

Stimulation of prolactin secretion in the rat by alpha-neo-endorphin, beta-neo-endorphin and dynorphin

Intraventricular injections of α-neo-endorphin, β-neo-endorphin and dynorphins (dynorphin[1–13], dynorphin[1–17], dynorphin[1–8]) resulted in an increase in plasma prolactin levels in urethane-anesthetized rats. Dynorphin [1–13] was the most potent to stimulate prolactin release among these opioid peptides. Plasma prolactin responses to these stimuli were blunted by naloxone, an opiate antagonist. In $\text{in}\text{vitro}$ studies, prolactin release from perfused pituitary cells was stimulated by α-neo-endorphin, and the effect was blunted by naloxone, whereas neither β-neo-endorphin nor dynorphin[1–13] affected prolactin release. These results suggest that newly identified “big” Leu-enkephalins in the brain stimulate prolactin secretion in the rat and that α-neo-endorphin has a possible direct action on the pituitary.     

The effects of dopamine on prolactin mRNA levels in rat pituitary cells in culture.

Dopamine is known to be the prolactin-release inhibiting factor, but the effects of dopamine itself on regulation of prolactin messenger RNA have been little studied because of the instability of dopamine. We have compared the effects of dopamine and bromocriptine on the levels of prolactin mRNA and on the rates of synthesis, storage, and release of prolactin in primary cultured rat pituitary cells. The cells were incubated for 72 h with no secretagogue (control group) or in the presence of either dopamine (10 mumol/L) plus ascorbic acid (100 mumol/L) or bromocriptine (0.1 mumol/L). Prolactin mRNA was measured in cell extracts by means of slot blots, and newly synthesized prolactin was measured in similar incubations by the addition of [3H]leucine, followed by gel electrophoresis. The levels of total prolactin were measured by radioimmunoassay. Prolactin mRNA was reduced to 78 +/- 9% (mean +/- SEM) of control levels in bromocriptine-treated cells and to 59 +/- 7% in dopamine-treated cells, demonstrating that dopamine stabilized by ascorbic acid was able to reduce the levels of prolactin mRNA in rat pituitary cells in culture. Dopamine may act at sites in addition to the dopaminergic D2 receptor, since the level of prolactin mRNA was reduced more by a supramaximal dose of dopamine than by a supramaximal dose of bromocriptine. The results of the [3H]prolactin and prolactin measurements suggested that availability of mRNA was not a major factor in controlling the rate of prolactin synthesis.     

Neuroendocrine responses to cocaine do not exhibit sensitization following repeated cocaine exposure.

Cocaine-induced enhancement of motor activity and extracellular dopamine concentrations exhibits sensitization upon repeated exposure. In this study, the neuroendocrine responses to cocaine were examined following cocaine pretreatment regimens which have been shown to produce behavioral sensitization. Adult male rats were injected with cocaine (15 mg/kg, IP) once daily for 14 days, followed by a dose-response challenge with cocaine (1-15 mg/kg, IP) either 18 hours or 7 days after the final pretreatment injection. Blood was collected 15 minutes following injections for radioimmunoassay of ACTH, corticosterone, prolactin, and renin. Cocaine increased plasma ACTH and corticosterone, while it decreased prolactin and renin concentrations. Pretreatment with cocaine for 2 weeks did not alter any of these endocrine responses after either the 18 hour or 7 day interval between pretreatment and challenge injections. In contrast, sensitization to the locomotor stimulant effects of cocaine was observed on the final day of pretreatment injections, and 7 days later. These data suggest that these endocrine effects of cocaine do not exhibit sensitization following repeated cocaine exposure.     

The role of domperidone in the regulation of prolactin release in rats

Effects of domperidone, a dopamine antagonist, on prolactin release in female rats were studied. Oral administration of domperidone for 14 days caused a significant increase in serum prolactin levels in mature female rats. The routes by which domperidone exerted its effects on prolactin release were studied by a in vitro incubation system using rat pituitary tissues. Pituitary halves were incubated with (1) domperidone, (2) dopamine, (3) dopamine plus domperidone, (4) hypothalamic extracts from rats which had been treated with control meal (control hypothalamic extract), (5) control hypothalamic extract plus domperidone, and with (6) hypothalamic extract from rats which had been treated with domperidone for 14 days (domperidone-treated hypothalamic extract). Pituitary halves, when incubated alone, released a significant amount of prolactin into the incubation medium after 24 hours incubation, which was completely inhibited by dopamine or control hypothalamic extract. The addition of domperidone could not reverse the inhibitory effect of dopamine or control hypothalamic extract. On the other hand, domperidone-treated hypothalamic extract showed no inhibitory effects on prolactin release. These results indicated that domperidone could increase serum prolactin levels in female rats by acting primarily at the hypothalamus.     

Evidence for a rapid in vivo effect on estradiol-17 beta on prolactin secretion in ovariectomized rats.

Repeated intraarterial injections of synthetic thryrotropin releasing hormone (TRH, 1 microgram/rat) increased plasma prolactin levels 4 hours after a single subcutaneous injection of 10 micrograms estradiol-17 beta (E2-17 beta) in rats ovariectomized 1, 2 or 4 weeks and at 2 hours after E2-17 beta injection in rats ovariectomized for 6 weeks. The effect of TRH was still present at 24 but not 48 hours after estradiol treatment. TRH-induced increases in plasma prolactin were similar in groups of rats treated with 10 micrograms E2-17 beta (s.c.) or implanted with 0.5 cm Silastic capsules of crystalline E2-17 beta (s.c.) whereas smaller, yet significant, TRH-induced increases in plasma prolactin were observed in rats injected s.c. with 1.0 microgram E2-17 beta. Single intraarterial injections of TRH at 4 or 8 hours after E2-17 beta treatment induced increases in plasma prolactin similar in magnitude to those observed at the same times after E2-17 beta in rats given repeated TRH injections. No effect of TRH was observed in ovariectomized rats given sesame oil and E2-17 beta treatment did not influence plasma prolactin in rats given saline instead of TRH. Intraarterial administration of serotonin creatinine sulfate (5-HT, 10 mg/kg body weight) induced marked increases in plasma prolactin in rats ovariectomized for 4 weeks which were potentiated at 2 and 6 hours after E2-17 beta (10 micrograms) treatment. The data show that estradiol has a fairly rapid stimulatory effect on plasma levels of prolactin induced by two different secretagogues but the exact site and mechanism of action remain unresolved.     

Potential role of prolactin in antipsychotic-mediated association of schizophrenia and type 2 diabetes

It remains unclear why atypical antipsychotics confer a risk for hyperglycemia compared to typical antipsychotics. Atypical antipsychotics antagonize dopamine receptors-2 (D(2)) and serotonin (5-HT) receptors-2, while typical antipsychotics antagonize only D(2) receptors. We aimed at elucidating the mechanistic differences between the role of typical and atypical antipsychotics on prolactin levels and glucose regulation. A Medline search was conducted during 2010 using the search terms type 2 diabetes (T2D), typical/atypical antipsychotics, schizophrenia, prolactin, and serotonin. We discuss the effect of typical and atypical antipsychotics on prolactin levels and glucose regulation. Given that prolactin is under negative control by dopamine and positive control by serotonin, typical antipsychotics induce elevations in prolactin, while atypical antipsychotics do not. Research studies show protective effects of prolactin on T2D. We hypothesize that the difference in induction of T2D between typical and atypical antipsychotics is due to the antipsychotic receptor binding mediated effect in changes in prolactin levels.     

Alpha-MSH injected into the substantia nigra or intraventricularly alters behavior and the striatal dopaminergic activity

Rats were injected with 1 μg of alpha-melanocyte stimulating hormone (α-MSH) into the third ventricle and locally in the ventral tegmental area and in different regions of the substantia nigra. The modifications produced on grooming behavior and locomotion as well as on the dopamine content of the nucleus accumbens and the caudate putamen, were studied. Both intraventricular peptide administration and microinjections into the ventral tegmental area induced excessive grooming and a significant increase of the locomotor activity. The dopamine content of the nucleus accumbens and caudate putamen was markedly reduced. Injections of the peptide into the substantia nigra pars compacta failed to induce excessive grooming but did provoke a slight increase in locomotor activity and a smaller change in caudate dopamine content than that observed by injections in the ventral tegmental area or in the third ventricle. Dopamine levels in the nucleus accumbens were not changed. Finally, the injections of α-MSH into the lateral substantia nigra did not produce either biochemical or behavioral changes.The results suggests that α-MSH can modify, directly or indirectly, the striatal dopaminergic activity and that the behavioral alterations observed such as excessive grooming, could be mediated by the activation of the dopamine cells from the ventral tegmental area, that in turn may provoke a significative release of dopamine at the caudate putamen nucleus as well as in nucleus accumbens.     

Prolactin regulation of dopaminergic neurons in the infundibulum pituitary stalk of bull calves

The effects of elevated circulating concentrations of prolactin were examined on neurochemical estimates of activity of dopaminergic neurons in the infundibulum/pituitary stalk of Holstein bull calves (8-10 weeks of age). Activity of these neurons was estimated by measuring the accumulation of dihydroxyphenylalanine, the immediate precursor of dopamine, 15 min after an intravenous injection of the aromatic L-amino acid decarboxylase inhibitor, 3-hydroxybenzylhydrazine. Subcutaneous injections of the dopamine antagonist haloperidol every 6 hr for 1 day increased serum concentrations of prolactin and accumulation of dihydroxyphenylalanine in the infundibulum/stalk. Intravenous infusions of prolactin for 1 or 9 days increased accumulation of dihydroxyphenylalanine in the infundibulum/stalk, indicating that these neurons remain responsive to elevated prolactin for at least 9 days. It is concluded that elevated concentrations of prolactin in blood stimulate dopaminergic neurons in the infundibulum/pituitary stalk of bull calves. We speculate that these neurons may be analogous to the tuberoinfundibular dopaminergic neurons that regulate prolactin in rats.     

Reexamination of dopamine as the prolactin-release inhibiting factor (PIF): supplementary agent may be required for dopamine to function as the physiological PIF

A large number of studies have been performed concerning dopamine's inhibitory effect on prolactin release, but many of these studies have examined the effect of dopamine dissolved in a solution containing ascorbic acid. Ascorbic acid, routinely used to protect dopamine from oxidation, alone does not stimulate or inhibit prolactin release, but it can potentiate the inhibitory effect of dopamine in a static monolayer culture system by approximately 100 times. We have closely examined the inhibitory effect of dopamine on prolactin release in the absence of ascorbic acid using a perifusion system. Male rat adenohypophyses were dispersed with trypsin and cultured in a Petri dish to form cell clusters. Inhibition of prolactin release by dopamine (1 mumol/L) in the absence of ascorbic acid was sustained for only 63 min during the 2-h perifusion period. Following a 2-h period of incubation of dopamine in the same experimental solution, the dopamine concentration was reduced from 1 to 0.18 mumol/L, yet this "2-h-old dopamine" was still effective in inhibiting prolactin release (approximately 30 min). This result suggests that the lactotrophs may be desensitized by chronic exposure to a high concentration of dopamine in the absence of ascorbic acid. In contrast, when a low concentration of dopamine (3 nmol/L) containing ascorbic acid (0.1 mmol/L) was perifused, inhibition of prolactin release was sustained for the entire 2-h perifusion period. Although there may be a large number of explanations for dopamine's transient inhibitory effect on prolactin release, the present results suggest that dopamine may require supplementary agent(s) to effectively inhibit prolactin release and thus function as the prolactin release inhibitory factor (PIF).(ABSTRACT TRUNCATED AT 250 WORDS)