Centrally mediated effects of neurohypophyseal hormones

Effects of peripherally injected vasopressin and des-glycinamide vasopressin on the extinction of a spatial learning task in rats

An elevated eight-arm radial maze was employed to study the effects of neuropeptide administration on the spatial learning abilities of food-deprived rats. Following 18 days of reinforced training, each animal was briefly exposed to the maze with no food available in any of the eight food-cups. Immediately after this preliminary trial, animals were injected with a single subcutaneous dose of either saline, arginine vasopressin (AVP: 1.0 or 5.0 micrograms/kg), or an AVP analog with only weak endocrinological activity, des-gly-arginine vasopressin (DG-AVP: 1.0, 5.0 or 10.0 micrograms/kg). Additional extinction trials were conducted at 2, 4, 6 and 8 h post-injection. These tests consisted of individually placing an animal on the empty maze and recording the number of arms chosen in a 5-min period. In this situation, animals learn that food is no longer present in the maze and, consequently, extinguish responding. Vasopressin potentiated this radial maze extinction behavior while DG-AVP produced behavioral results directionally opposite to those predicted by a memory facilitation hypothesis. In a subsequent experiment, vasopressin had no effects on unconditioned locomotor activity measured 2 and 4 h post-injection. These results suggest that: vasopressin improved the learning that occurred during extinction of conditioned appetitive behaviors, these vasopressin effects on conditioned behavior were independent of any unconditioned, sedative or non-specific actions of the peptide, and peripheral endocrinological responses may be necessary to demonstrate memory-enhancing effects following peripherally administered AVP.

Oxytocin affects utilization of noradrenaline in distinct limbic-forebrain regions of the rat brain

The effects of oxytocin, administered intracerebroventricularly in doses of 1, 10, 100 and 1000 pmol, were studied on the disappearance of catecholamines induced by alpha-methyl-p-tyrosine in microdissected nuclei of the rat brain. Oxytocin dose-dependently decreased the utilization of noradrenaline in the lateral and medial septal nuclei and anterior hypothalamic area, whereas an enhanced utilization was observed in the nucleus supraopticus. Tendency towards a change in utilization of noradrenaline was found in the dorsal septal nucleus and the lateral amygdala. Utilization of dopamine was not significantly affected in any of the nuclei of the brain studied. Tendency towards a decrease in utilization of dopamine was observed in the nucleus caudatus, globus pallidus and medial septal nucleus. It thus appears that oxytocin elicited changes in only a restricted number of brain nuclei. Interestingly, these nuclei contain cell bodies (nucleus supraopticus) and terminals (other nuclei) of the oxytocin system in the brain. Though the effects of oxytocin were not as widespread as those previously seen after administration of vasopressin, it is worthy of note that, in general, the effects of oxytocin were opposite to those seen after vasopressin. The opposite effects of vasopressin and oxytocin on catecholamine metabolism could be related to the opposite effects of the two peptides on behaviour, neuroendocrine and autonomic regulation.

Intracerebroventricular application of a vasopressin antagonist peptide prevents the behavioral actions of vasopressin

Three experiments were conducted to test the hypothesis that the memory-improving properties of peripherally-applied vasopressin (AVP) were related to its aversive (i.e. arousing) actions. The memory effects of AVP were observed in a one-trial food-finding task where non-deprived rats were briefly exposed to a large open field that contained an alcove in which a high-incentive familiar food reward (sweetened milk) was freely available. AVP injections immediately upon removal from the open-field produced faster latencies to refind the alcove (compared to vehicle controls) when tested 48 h later. The aversive actions of AVP were demonstrated in two behavioral assays: (1) a conditioned taste aversion test in which rats learned to avoid a preferred saccharin solution after it had been paired with injections of AVP; and (2) a conditioned place test in which rats learned to avoid a distinctive environment associated with AVP administration. Both the memory and aversive responses to AVP were prevented, in a dose-dependent manner, by immediate pretreatment with intracerebroventricular infusions of the pressor antagonist analog 1-deaminopenicillamine-2-(O-methyl)-tyrosine AVP. The large antagonist doses required to block AVP's behavioral effects suggest that the critical site of action may be far removed from the lateral ventricles. The possibility that AVP-induced improvements in memory result from peripheral arousing actions is discussed.

Pro-Leu-GlyNH2 affects dopamine and noradrenaline utilization in rat limbic-forebrain nuclei

The effects of Pro-Leu-GlyNH2 (PLG), administered i.c.v. in doses of 3.5, 35, 350 and 3500 pmol, were studied on the alpha-MPT-induced disappearance of catecholamines in microdissected rat brain nuclei. PLG, dose-dependently, increased dopamine disappearance in the nucleus caudatus and globus pallidus, whereas a decrease in dopamine disappearance was observed in the nucleus dorsomedialis. Noradrenaline disappearance was decreased in the medial septal nucleus, anterior hypothalamic area and lateral amygdala. A tendency towards an increase in noradrenaline disappearance was observed in the nucl. supraopticus. These data show that PLG has a central site of action. The effects of PLG on dopamine disappearance are comparable to those previously found with vasopressin, while the effects of PLG on noradrenaline utilization show a striking similarity with those previously obtained with oxytocin.

Amastatin potentiates the behavioral effects of vasopressin and oxytocin in mice

Vasopressin and oxytocin cause behavioral excitation after intracerebroventricular injection in mice. This effect is short-lasting, suggesting that the peptides are rapidly inactivated in the brain. Co-injection of microgram amounts of amastatin, an aminopeptidase inhibitor, prolonged the effect of both vasopressin and oxytocin. Amastatin did not induce large vasopressin-like behavioral effects by itself, nor did it significantly potentiate the action of 1-deamino[1,6-dicarba, 8-arginine] vasopressin (Asu-AVP), an analog that lacks the N-terminal amino group. The effect of Asu-AVP, but not that of vasopressin, was potentiated by phosphoramidon, an inhibitor of neutral metalloendopeptidase ("enkephalinase A"). These results support previous suggestions that vasopressin and oxytocin are inactivated mainly by aminopeptidase action following intracerebroventricular injection.

Factors involved in the inactivation of vasopressin after intracerebroventricular injection in mice

Behavioral excitation induced by intracerebroventricularly administered vasopressin in mice is very short-lasting, suggesting a half-life of the injected peptide of only a few minutes. The results of the present study suggest that vasopressin and related peptides are too hydrophilic to penetrate lipid membranes readily by passive diffusion and that passive diffusion from the extracellular space into cells or the bloodstream is an unlikely mechanism of inactivation. Pharmacological desensitization (tachyphylaxis) occurs after higher doses, but does not seem to be the major factor responsible for the short duration of action. Some deaminoanalogs of vasopressin, however, show a prolonged action, suggesting that degradation by (an) aminopeptidase(s) is a major route of inactivation. These results also suggest that vasopressin-degrading aminopeptidases are accessible from the extracellular space.

Microinjection of vasopressin and two related peptides into the amygdala: enhancing effect on local dopamine neurotransmission

The effects of local microinjection of Arg8-vasopressin, cyclo[Lys-Gly] and L-Pro-L-Leu-GlyNH2 (PLG) were studied on the alpha-MPT-induced disappearance of dopamine and noradrenaline in the amygdala and in a number of other brain regions. A dose-dependent increase in dopamine utilization was found in the amygdala after local microinjection of Arg8-vasopressin, cyclo[Lys-Gly] and PLG at doses of 0.1, 2.7 and 18 pmol respectively. No effects were found on noradrenaline utilization in this brain region. Using a microdissection method, it was found that cyclo[Lys-Gly] enhanced dopamine utilization in the nucl. amygdaloideus centralis, whereas the effect of PLG was mainly located in the nucl. amygdaloideus corticalis. These effects of Arg8-vasopressin, cyclo[Lys-Gly] and PLG on dopamine utilization in the amygdala are correlated with those on avoidance behavior and can be interpreted as in support of the role of dopamine as neurotransmitter involved in retrieval processes.