Some pharmacological effects of p-chlorophenylalanine unrelated to tryptophan hydroxylase inhibition.
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1 Experiments were performed on a variety of tissues from different species to establish whether or not the properties of p-chlorophenylalanine methyl ester (PCPA) included a 5-hydroxytryptamine (5-HT)-like action which might explain the soporific action of PCPA in chicks. 2 PCPA, like 5-HT, contracted the rat fundal preparation (as did PCPA base), and in cats enhanced twitch tension of a lower limb flexor reflex, evoked adrenal medullary secretion and attenuated histamine-induced gastric secretion; the effects on the rat fundal strip and the adrenal medulla were prevented by methysergide. 3 Like 5-HT, PCPA elicited bronchoconstriction of guinea-pig lungs, isolated or in vivo; this was not prevented by methysergide but reduced by polyphloretin and by indomethacin. Perfusate collected from the lungs during PCPA-induced bronchoconstriction and applied to superfused isolated tissues contained a substance with prostaglandin-like activity. 4 In contrast, the effect of PCPA on the guinea-pig isolated ileum differed from that of 5-HT, since it relaxed the ileum when contracted by transmural excitation, by acetylcholine, histamine of 5-HT and contracted the ileum on wash-out. (+info)
Cholinergic and serotonergic neural links and the inhibitory effects of hippocampus, lateral amygdala and central gray matter on gonadotropin release.
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Effects of electrical stimulation of the hippocampus (HPC), lateral amygdala (1-AMYG) and midbrain central gray matter (CG) on the release of ovulatory gonadotropin were examined using proestrous Wistar rats with or without pretreatment with reserpine, atropine or p-chlorophenylalanine (PCPA) at such dosage that had been confirmed not to block ovulation. Electrical stimulation of the HPC, 1-AMYG or CG under light ether anesthesia just before the critical period prevented a rise in serum LH, FSH and prolactin levels at 18:00. Pretreatment with atropine (200 mg/kg body wt, sc) was effective to abolish this inhibitory effect of the HPC stimulation on the release of LH and FSH, whereas reserpine treatment (1mg/kg body wt, ip) did not affect the effect. The inhibitory effect of the 1-AMYG or CG stimulation on LH and FSH release was abolished by treatment with PCPA (150 mg/kg body wt, ip), while neither atropine nor reserpine had any effect. The inhibitory effect of the HPC stimulation on the release of these hormones was also blocked by PCPA treatment. In regard to the prolactin release, it was inhibited by the stimulation of the HPC, 1-AMYG or CG in both the non-treated rat and in the atropine or PCPA-treated one, while in the reserpine-treated rat it was not inhibited but rather was facilitated by these stimulations. It was assumed that the normal maintenance of both cholinergic and serotonergic neural links for the expression of the HPC inhibition on ovulatory LH, FSH and prolactin secretion and that of serotonergic link for the expression of the 1-AMYG or CG inhibition are needed. The inhibitory action on prolactin release changed into facilitation under the depletion of monoamines, but the mechanism is unknown. (+info)
An inhibitory role for brain serotonin-containing systems in the locomotor effects of d-amphetamine.
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Locomotor activity induced by d-amphetamine was found to be potentiated by food deprivation, a tryptophan-free diet, p-chlorophenylalanine and drugs proposed to antagonize serotonin receptors in brain. Administration of L-tryptophan 1 hour prior to d-amphetamine injection was found to antagonize the enhanced response to d-amphetamine in starved rats and in rats which had tryptophan removed from their diet. However, tryptophan did not block the potentiated response to d-amphetamine in animals pretreated with p-chlorophenylalanine. These findings suggested that the antagonism of d-amphetamine-induced activity by tryptophan in starved rats and rats fed a tryptophan-free diet was not due to a nonspecific depressant effect of the amino acid. Since accumulation of d-amphetamine and its metabolites was not affected by any of the treatments which enhanced its activity, it seems unlikely that an alteration in the metabolism of d-amphetamine can explain these findings. The present work provides additional support for the view that serotonergic fibers play an important role in the actions of d-amphetamine. (+info)
The regulation of phenylalanine hydroxylase in rat tissues in vivo. The maintenance of high plasma phenylalanine concentrations in suckling rats: a model for phenylketonuria.
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Maximum inhibition of phenylalanine hydroxylase activity in the liver (85%) and in the kidney (50%) of suckling rats required the administration of over 9 mumol of p-chlorophenylalanine/10g body weight. Despite the decrease in the total activity from 184 to 34 units per 10g body weight, the injection of as much as 26 mumol of phenylalanine was required for its concentration in plasma to be still considerably elevated 12h later. In rats injected with p-chlorophenylalanine every 48h and with phenylalanine every 24h from 3 to 18 days of age, the hepatic and renal phenylalanine hydroxylase remained inhibited, whereas the activities of three other hepatic enzymes were unchanged. There was about 20% inhibition of brain and body growth, but no interference with the developmental formation of several cerebral enzymes (four dehydrogenases, hexokinase and glutaminase) was detected. In the course of this prolonged treatment, the phenylalanine concentrations in plasma increased gradually; on day 2 and day 8 (measured 12h after the last injection) they were 800 and 1395 nmol/ml respectively; on day 15, 12 and 18h after the usual injection, the values were 2030 and 1030 respectively as opposed to the 96 nmol in untreated rats. This degree of hyperphenylalaninaemia, persisting for 18h per day throughout a critical period of development, fulfils the primary criterion of a suitable animal model for phenylketonuria. (+info)
The regulation of phenylalanine hydroxylase in rat tissues in vivo. Substrate- and cortisol-induced elevations in phenylalanine hydroxylase activity.
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Injections of phenylalanine increased a 2.5-fold in 9 h the hepatic phenylalanine hydroxylase activity of 6-day-old or adult rats that had been pretreated (24h earlier) with p-chlorophenylalanine; without such pretreatment, phenylalanine did not raise the enzyme concentration. This difference is paralleled by the much greater extent to which the injected phenylalanine accumulated in livers of the pretreated compared with the normal animals. The hormonal induction of hepatic phenylalanine hydroxylase activity obeyed different rules: an injection of cortisol was without effect on adult livers but caused a threefold rise in phenylalanine hydroxylase activity of immature ones, both without and after pretreatment with p-chlorophenylalanine. In the latter instance, the effects of cortisol, and of phenylalanine were additive. Actinomycin inhibited the cortisol- but not the substrate-induced increase of phenylalanine hydroxylase, whereas puromycin inhibited both. The results indicate that substrate and hormone, two potential positive regulators of the amount of the hepatic (but not the renal) phenylalanine hydroxylase, act independently by two different mechanisms. The negative effector, p-chlorophenylalanine, also appears to interact with the synthetic (or degradative) machinery rather than with the existing phenylalanine hydroxylase molecules: 24h were required in vivo for an 85% decrease to ensue, and no inhibition occurred in vitro when incubating the enzyme with p-chlorophenylalanine or with liver extracts from p-chlorophenylalanine-treated rats. (+info)
Stereospecific actions of 2,5-dimethoxy-4-methylamphetamine (DOM) on colonic temperature in the rat at various ambient temperatures.
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The R(-) and S(+)-isomers of 2,5-dimethoxy-4-methylamphetamine (DOM) produce a dose-dependent hypothermia in rats kept in the cold (6 degrees C). 2 This hypothermia was linearly dependent upon ambient temperature and the R(-)-isomer was considerably more potent than the S(+)-isomer. 3 A statistically significant tachyphylaxis was observed when R(-)-DOM was administered on two successive days. The response seven days after the second injection was similar to that on the first day of injection. 4 The hypothermia induced by R(-) and S(+)-DOM was antagonized by methysergide but not by p-chlorophenylalanine (PCPA) or pimozide. Methysergide, PCPA or pimozide alone did not elicit hypothermia at the doses used. The results indicate that R(-) and S(+)-DOM act at post-synaptic 5-hydroxytryptamine receptors. (+info)
Effect of humoral modulators of morphine-induced increase in locomotor activity of mice.
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The effect of humoral modulators on the morphine-induced increase in locomotor activity of mice was studied. The subcutaneous administration of 10 mg/kg of morphine-HC1 produced a marked increase in locomotor activity in mice. The morphine-induced hyperactivity was potentiated by scopolamine and attenuated by physostigmine. In contrast, both methscopolamine and neostigmine, which do not penetrate the blood-brain barrier, had no effect on the hyperactivity produced by morphine. Pretreatment of mice with alpha-methyltyrosine (20 mg/kg i.p., one hour), an inhibitor of tyrosine hydroxylase, significantly decreased the activity-increasing effects of morphine. On the other hand, pretreatment with p-chlorophenylalamine (3 X 320 mg/kg i.p., 24 hr), a serotonin depletor, caused no significant change in the hyperactivity. The study suggests that the activity-increasing effects of morphine are mediated by the release of catecholamines from adrenergic neurons in the brain. And the results are consistent with the hypothesis that morphine acts by retarding the release of acetylcholine at some central cholinergic synapses. It is also suggested from collected evidence that the activity-increasing effects of morphine in mice are mediated by mechanisms different from those which mediate the activity-increasing effects of morphine in rats. (+info)
Evidence for postsynaptic mediation of the hypothermic effect of 5-HT1A receptor activation.
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1. The 5-HT1A ligand BMY 7378 (8-[2[4-(2-methoxyphenyl)-1-piperazinyl]ethyl]8-azaspirol [4,5]-decane-7,9-dione dihydrochloride, 0.032-2 mg kg-1, s.c.) caused hyperphagia, a response to the activation of presynaptic 5-HT1A receptors. 2. BMY 7378 (8 mg kg-1, s.c.) and the 5-HT1A agonist (8-hydroxy-2-(di-n-propylamino) tetralin (8-OH-DPAT), 0.10 and 0.25 mg kg-1 s.c.) also caused hypothermia. This was inhibited by (-)-pindolol (1-mg kg-1, i.p.) and not prevented by pretreatments with p-chlorophenylalanine which grossly depleted 5-hydroxytryptamine (5-HT) from terminal regions. The hypothermic effects are explicable by activation of postsynaptic 5-HT1A receptors. Infusion of BMY 7378 (8-64 micrograms) into the dorsal raphe was without convincing hypothermic effect. 3. BMY 7378 (8 mg kg-1, s.c.) inhibited another effect of activation of postsynaptic 5-HT1A receptors, i.e., the induction of components of the 5-HT syndrome by 8-OH-DPAT (0.5, 1.0 mg kg-1, s.c.) which suggests that BMY 7378 has antagonistic as well as agonistic effects at these sites. 4. Partial agonist properties of BMY 7378 at postsynaptic sites were also indicated by doses for hypothermia being much greater than those for hyperphagia i.e., ED50 (hypothermia) greater than 2 mg kg-1, ED50 (hyperphagia) = 0.010 mg kg-1. This contrasts with the similar ED50 values for both the hypothermic (ED50 = 0.08-0.10 mg kg-1) and hyperphagic (ED50 = 0.06-0.10 mg kg-1) effects of 8-OH-DPAT.5. The evidence obtained for mediation of the hypothermic response to 5-HTIA agonists by postsynaptic sites is relevant to the interpretation of the effects on it of antidepressant treatments and depressive illness. (+info)