Dopamine depletion in nucleus accumbens reduces ACTH1-24-induced excessive grooming

Therapeutic and pathogenetic animal models for Dolichos pruriens

The therapeutic and pathogenetic effects of Dolichos pruriens were evaluated using experimental models in rats. In the therapeutic experiment Wistar rats were housed in a heated environment (25+/-3 degrees C) to induce itch, and treated with ascending potencies D. pruriens (6 cH, 9 cH, 12 cH and 30 cH), each for 10 days. The positive control group received vehicle (ethanol 30% in water). The negative control group received no treatment and were kept at a standard temperature. In the pathogenetic experiment, all animals were kept at a temperature of 20+/-3 degrees C and treated for 30 consecutive days with D. pruriens 6 or 30 cH, or ethanol vehicle, or no treatment. The experiments were performed blind. The statistical analysis used Bartlett's test, followed by ANOVA/Tuckey-Krammer or Kruskal-Wallis/Dunn. The results point to the existence of therapeutic effects, with inhibition of the itching, skin lesions and fur thinning produced by heat, more evident in later observations, with the 9 12, and 30 cH potencies (Kruskal-Wallis/Dunn; P=0.001). No changes were observed in the other parameters, such as open field activity and laterality of the itching. In the pathogenetic experiment, no changes were observed in any parameters examined. We conclude that the proposed experimental model demonstrates the therapeutic effect of D. pruriens, but not its pathogenetic effects.

Long-term effects of developmental exposure to zidovudine on exploratory behavior and novelty discrimination in CD-1 mice

Long-term changes in exploratory, social and agonistic behavior have been reported in rodents following developmental exposure to zidovudine (AZT), an agent commonly administered to pregnant seropositive women and their neonates to prevent HIV-1 transmission. The present study evaluates the effects of either prenatal or prolonged AZT treatment on spatial and nonspatial novelty discrimination in mice, using an open-field test with four objects, in which responses to both spatial rearrangement of familiar objects and object novelty are assessed. AZT (160 mg/kg) or Saline was given orally twice daily to pregnant mice from gestational days (GD) 10 to 19 (Experiment 1) or from GD 10 to lactation day 10 (Experiment 2). Offspring of both sexes were tested on postnatal day (PND) 28, 45 or 70. Depending on treatment schedule, AZT altered different behavioral responses, males being more affected than females. The prenatal treatment (Experiment 1) reduced exploration of the objects at all ages considered and increased wall and top rearing at ages 45 and 70. Following prolonged treatment (Experiment 2), AZT offspring were markedly more active than controls and displayed more wall rearing at age 70 while showing lower grooming frequency at all ages. Both AZT and control mice failed to respond to object rearrangement at adulthood, a discrepancy from previous data, which is discussed in relation to perinatal stress effects.

Effects of prenatal AZT+3TC treatment on open field behavior and responsiveness to scopolamine in adult mice

Treatment of pregnant seropositive women and their neonates with the nucleoside analogs (reverse transcriptase inhibitors) zidovudine (AZT), lamivudine (3TC) and their combination has become a standard of care in industrialized countries to prevent transmission of the HIV-1 virus. Animal studies indicated limited but significant behavioral changes in AZT or 3TC-prenatally exposed offspring, whereas data on the potential neurobehavioral outcomes of AZT+3TC combination are still lacking. The aim of the present study was to assess in mice prenatally exposed to AZT+3TC the functional state of cholinergic muscarinic neuroregulation at adulthood. Pregnant CD-1 mice received per orem twice daily AZT+3TC (160 and 500 mg/kg, respectively) or vehicle solution (NaCl 0.9%) from gestational day (GD) 10 to delivery (GD 19). Locomotor activity, exploratory behavior and responsiveness to the muscarinic cholinergic blocker scopolamine (2 mg/kg) were analyzed at adulthood (PND 70) in offspring of both sexes in an open field test. Results indicated that prenatal AZT+3TC exposure does not influence responsiveness to the muscarinic cholinergic antagonist as measured by analysis of the drug's effects on locomotor and exploratory activity and different behavioral items. However, AZT+3TC-treated mice displayed higher frequency of rearing, and lower frequency and duration of self-grooming behavior, consistent with an effect on dopaminergic neurotransmission. However, this would need confirmatory experiments.

Ultrastructural Characterization of Adrenocorticotrope Hormone (ACTH) Immunoreactive Fibres in the Mesencephalic Central Grey Substance of the Rat

The fine structural localization of fibres immunoreactive for the adrenocorticotrope hormone (ACTH) was studied in the mesencephalic central grey substance (MCG) of the male Wistar rat. Light microscopically, varicose ACTH-immunoreactive fibres were found throughout the MCG in a dorsal, lateral and ventral, periventricular position. Electron microscopically, the immunoreactivity was most prominent in the direct vicinity of electron-dense secretory granules in axonal varicosities, and, although to a lower degree, around other cytoplasmic organelles such as electron-lucent synaptic vesicles, mitochondria and microtubules. With serial section analysis two types of ACTH-immunoreactive varicosity were discerned. The first type is large, contains many, small electron-lucent synaptic vesicles, that are located in the vicinity of a morphologically well-defined synaptic contact. In this type of varicosity, large dense-core secretory granules are scarce. Immunoreactivity is low or absent, particularly near the active zone. The second type is strongly immunoreactive. It always contains many large, dense-core secretory granules; electron-lucent vesicles are rare. The smaller varicosities of this type never make synaptic contacts, but a few of the larger varicosities have synaptic contacts with dendrites of MCG cells.

The response of apomorphine administered into the accumbens in rats with bilateral lesions of the nucleus accumbens, induced with 6-hydroxydopamine

Bilateral lesions of the nucleus accumbens, induced with 6-hydroxydopamine, reduced motor activity and produced a 20-35% depletion of the concentrations of dopamine (DA) and its main metabolites 3,4-dihydroxyphenylacetic acid (DOPAC) and homovanillic acid (HVA). Small doses of apomorphine (1-10 ng), injected into the nucleus accumbens of sham-lesioned rats, decreased motor activity, while larger doses (1-10 micrograms) produced hyperactivity. In rats lesioned with 6-hydroxydopamine, apomorphine caused hyperactivity only, and this apomorphine-induced response was more pronounced than in sham-lesioned rats. Large doses of apomorphine decreased, only in sham-lesioned animals, the levels of DOPAC and HVA. These data suggest that the apomorphine-induced hypomotility is mediated by presynaptically located DA receptor systems in the nucleus accumbens, whereas the apomorphine-induced hypermotility is likely to be mediated by postsynaptically located DA receptor systems.

Anatomical evidence for interactions between catecholamine- and adrenocorticotropin-containing neurons

Recent studies suggest that neurons containing adrenocorticotropin and catecholamines are localized to similar areas of the brain. In this immunocytochemical study, the distributions of neurons and terminals containing adrenocorticotropin and tyrosine hydroxylase, the first enzyme in the catecholamine biosynthetic pathway, were compared using the peroxidase-antiperoxidase technique. Neurons containing adrenocorticotropin and tyrosine hydroxylase formed overlapping hyperbolic lamina in the mediobasal hypothalamus. Although adrenocorticotropin and tyrosine hydroxylase containing neurons often formed small clusters, no double labeled cells were observed. Overlap also occurred between adrenocorticotropin and tyrosine hydroxylase terminal fields in several diencephalic nuclei including the periventricular hypothalamic gray and paraventricular thalamus. In contrast, other regions displayed striking compartmentalization of terminal fields; for example, in both the paraventricular hypothalamus and central nucleus of the amygdala, adrenocorticotropin was located in ventral and tyrosine hydroxylase in more dorsal aspects of the nuclei. Adjacent sections also showed a close correspondence between adrenocorticotropin terminals and tyrosine hydroxylase cell bodies in paraventricular, periventricular, dorsomedial and ventral hypothalamic nuclei. These data provide anatomical substrates for potential functional interactions between catecholamine and adrenocorticotropin systems in forebrain.

Dopaminergic modulation of ACTH-induced grooming

ACTH-(1-24)-induced grooming was studied after administration of the peptide into the substantia nigra or intracerebroventricularly (i.c.v.). The modulation of dopamine receptors in neostriatum (with haloperidol and apomorphine) and nucleus accumbens (with 3,4-dihydroxyphenylamino-2-imidazoline hydrochloride; DPI and ergometrine) was investigated. In the nucleus accumbens, the modulatory effects of ergometrine and DPI on ACTH-(1-24)-induced grooming were based on their affinity for dopamine receptors and not on their affinity for adrenoceptors. Intrastriatal application of dopaminergic agents inhibited i.c.v. ACTH-(1-24)-induced excessive grooming, whereas the grooming score was enhanced if ACTH-(1-24) was administered into the substantia nigra. The finding of differential effects of dopaminergic agents on ACTH-induced excessive grooming depending on the route of administration indicate that i.c.v. ACTH-induced excessive grooming is not mediated solely through the substantia nigra. The increase in grooming behavior seen after the intrastriatal administration of dopaminergic agents - when ACTH was injected into the substantia nigra - suggests the involvement of the striato-nigral GABAergic pathway. Local injections of ACTH-(1-24) into the periaqueductal gray also induced excessive grooming. Since a second injection of ACTH-(1-24) into the periaqueductal gray did not lead to a grooming response, irrespective of where the first injection of ACTH-(1-24) was given (i.c.v. into the nigra or via the periaqueductal gray) it is suggested that this structure seems to play a primary role in the induction of excessive grooming. Therefore the modulatory effects of the dopaminergic influence on ACTH-(1-24)-induced grooming may be exerted via the striato-nigro-collicular pathway.

The effects of Org 2766 on the performance of sham, neocortical, and hippocampal-lesioned rats in a food search task

The behavioral effects of an ACTH4-9 variant, Org 2766, given for one week postoperatively at a dose of 1 microgram/rat daily, were evaluated in animals given hippocampal, neocortical, or "sham" lesions. After the week during which the injections were given, the animals were tested for 5 days in a food-search task in which food was hidden in two recessed holes in the floor. On the next day the ability of the rats to find food in these same two baited holes was tested in the presence of 14 additional holes that were not baited. On the following day, the animals were tested again, this time with all 16 holes baited. To assess the long-term effects of Org 2766 treatment, the animals were tested once again 2-3 months later in the same apparatus with 16 empty holes. In general, rats with lesions restricted to the neocortex were severely impaired in the task and were unaffected by prior treatment with Org 2766. Animals with hippocampal damage quickly learned the task and were hyperactive. During the test session with 16 baited holes they showed differential behavioral changes suggesting attentional deficits not seen in "sham" operated rats. These deficits were attenuated by prior Org 2766 treatment, whereas the lesion-induced hyperactivity was not. Treatment with Org 2766 impaired all aspects of performance of "sham" operated animals.

Neuropeptides in dopamine-containing regions of the brain

This paper reviews evidence of direct interactions occurring in the central nervous system between peptide- and dopamine-containing neural networks. While it seems fairly clear that neuropeptides are involved in the process of interneuronal communication, their specific role appears to be different from that of classic transmitters (which include dopamine). Neuropeptides coexist with dopamine in specific dopamine-containing neurons; in addition they interact abundantly with the dopaminergic neurons, by acting either on the perikarya or on the dopaminergic nerve terminals. Such interactions are reciprocal and account for some behavioral correlates of neuropeptide and dopamine alterations in the brain. They also shed new light on the pathophysiology of neurological and psychiatric diseases associated with depletion or abundance of brain peptides.

ACTH1-24 effects on d-amphetamine self-administration and the dynamics of brain dopamine in rats

Experiments aimed at determining the neural basis of reward have previously focused on the role of neurotransmitters and have only recently begun to investigate the role of peptides. The present experiment investigated the effect of ACTH1-24 on d-amphetamine self-administration in rats. Animals were trained daily (8 hour sessions) to press a lever which activated a system that administered 0.125 mg/kg of intravenous amphetamine. After achievement of a stable self-injection frequency, subjects were injected SC with 10, 20 or 40 micrograms/80 microliters ACTH1-24 immediately prior to placement in the apparatus. The 20 micrograms and 40 micrograms doses of the peptide fragment induced a statistically significant attenuation of d-amphetamine self-injection which lasted for 2 days. Control rates of responding were achieved by 5 to 10 days after the peptide treatment. An experiment was conducted to evaluate possible neuromodulatory effects of the peptide fragment. Twenty-four hr after ACTH1-24, HVA was elevated in the caudate. When both apomorphine and ACTH1-24 were administered, the combination lowered HVA in the caudate to a greater degree than apomorphine alone. The peptide fragment, when combined with haloperidol, attenuated the haloperidol-induced increases of DOPAC and HVA in both the caudate and nucleus accumbens. It was tentatively concluded that the neuromodulatory action of ACTH1-24 on dopaminergic neurons may result in an increase in the rewarding quality of d-amphetamine, thus rendering control level self-infusions superfluous.(ABSTRACT TRUNCATED AT 250 WORDS)

Dopamine denervation of frontal cortex or nucleus accumbens does not affect ACTH-induced grooming behaviour

Studies with dopamine (DA) receptor antagonists have implicated brain DA systems in the increased grooming behaviour elicited by intracerebroventricular (i.c.v.) administration of ACTH or exposure to a novel environment. To evaluate the potential contributions of DA terminals innervating frontal cortex and nucleus accumbens, stereotaxically guided injections of 6-hydroxydopamine (6-OHDA) were made into these regions of rat brain following peripheral administration of desmethylimipramine and pargyline. Despite an 88% mean reduction of DA, and 68% mean reduction of noradrenaline in frontal cortex, the amount of grooming behaviour observed either in a novel cage, or after i.c.v. injection of ACTH1-24 was not detectably altered. The lesions also did not affect locomotor activity measured during the scoring of grooming, in an open field, in photocell cages, or in a running wheel, even in the animals most severely depleted of DA. Following nucleus accumbens 6-OHDA infusions, depletions of DA as great as 99% were obtained. Animals with accumbens depletions greater than 90% showed the expected attenuation of amphetamine-stimulated locomotor activity. Nevertheless, they exhibited normal grooming scores in a novel cage, and in response to i.c.v. ACTH1-24. It is concluded that dopaminergic terminals in nucleus accumbens and probably those in frontal cortex are not necessary for the expression of novelty- or ACTH-induced grooming.

Hippocampal damage: effects on dopaminergic systems of the basal ganglia

Although the research topics discussed in this chapter cover a substantial range of areas, methods, and behaviors, there is a consistent central issue: the alterations of brain and behavior subsequent to hippocampal lesions. The initial hypothesis that important secondary changes occur in the basal ganglia after hippocampal lesions has been sustained, at least in part, but other and unexpected results have been obtained that both clarify and mystify at the same time. The restoration of normal locomotion to animals with hippocampal damage by the application of a DAi agonist, DPI, to n. accumbens certainly supports our general idea, but the fact that membrane and transmitter changes in accumbens are transitory needs to be explained and perhaps related to alterations in DA receptor populations. The fact that intra-accumbens DPI can restore ACTH-induced excessive grooming at 28 days after hippocampal damage supports the idea that progressive changes are occurring in DA receptors in n. accumbens, but we need to know their nature more precisely. To do this, however, will probably require advances in our general knowledge of central DA receptors. One of the more interesting aspects of our observations is that the intra-accumbens administration of DPI restores normal behavioral patterns in several types of behaviors, especially locomotion and the excessive grooming response. These two behaviors are not closely linked in nature because large changes can occur in them independently, given appropriate conditions for testing. On the basis of available evidence both of these behaviors seem linked to activities in forebrain DA systems. This would further support the idea that the hippocampus modulates DA activities in basal ganglia systems. The results that suggest the presence of multiple sites for the central induction of grooming were also unexpected. As evidence mounts in support of this idea, it is likely that the one located in n. accumbens is more influenced by hippocampal destruction than the region(s) affected by icv neuropeptide administration. The interactions that take place in the basal ganglia can be extensive. Afferents from the entirety of the neocortical surface, the limbic system, and the projections from the brainstem DA cell groups meet in the striatum and ventral striatum. The efferents from this region not only reach motor cortical and subcortical sites but also project back onto diffusely projecting monoaminergic cells of the brainstem.(ABSTRACT TRUNCATED AT 400 WORDS)

The time course of excessive grooming after neuropeptide administration

In this paper we review the temporal pattern of excessive grooming in the hour or so following the central injection of ACTH1-24 in the rat. Changes in the grooming pattern after specific neuropharmacological manipulations of dopaminergic and opiate-related systems are presented which indicate a differential sensitivity of the grooming responses at different times after injection. The grooming affected by dopaminergic antagonists and opiate agonists and antagonists occurs in the last 30 min of the observation period while that found earlier is unaffected. It is also the grooming in this last 30 min of the observation period term tolerance to central administration of ACTH1-24. In contrast lesions of the central nervous system that affect excessive grooming, i.e., the substantia nigra and the hippocampus, reduce grooming throughout the observation period. The present analysis has provided evidence for dopamine/opiate insensitive and sensitive systems in excessive grooming, and thus temporal aspects are of extreme importance to the understanding of central neuropeptide influences on behavior.