Influence of gender and behavioural lateralisation on two exploratory models of anxiety in C3H mice.

Behavioural lateralisation, which has been postulated to be an individual personality trait, is related to the activity of various physiological systems including the immune system. As lateralisation has been related to anxiety, which is known to influence immune reactivity, it can be hypothesized that the relation between lateralisation and immune reactivity involves individual behavioural patterns as they appear in exploratory-based anxiety models. In order to answer this question, a behavioural investigation focussing on exploratory activity was undertaken in male and female C3H mice previously selected for their paw preference. The observations were performed using two generic paradigms: elevated plus-maze and open field. Exploratory behaviour in the open field, but not in the plus-maze, was influenced by the interactive effect of gender and behavioural lateralisation. A significant difference between male and female mice was found in left-pawed but not in right-pawed nor ambidextrous animals, left-pawed female mice displaying the less exploratory behaviours. These results provide a first evidence of inter-individual variations in exploratory behaviours involving interaction between gender and lateralisation.

Effects of intracerebral dopaminergic grafts on behavioural deficits induced by neonatal 6-hydroxydopamine lesions of the mesotelencephalic dopaminergic pathway.

The functional capabilities of dopamine neuron-rich grafts implanted into the accumbens and striatal regions in neonatal rats were evaluated in a series of behavioural tests. The ascending mesotelencephalic dopaminergic system of three-day-old rat pups was bilaterally lesioned by injecting 6-hydroxydopamine at the level of the lateral hypothalamus. Five days later a suspension containing dopaminergic neurons obtained from embryonic day 14 mesencephali was injected bilaterally into the striatal complex. The functional effects of such grafts were evaluated using behavioural tests for which it was known that the performance of the animals is changed following the lesion of the mesotelencephalic pathway and for which the influence of dopaminergic grafts implanted into adult hosts have previously been described. The dopamine-rich grafts compensated for the modifications of the locomotor responsiveness to amphetamine and apomorphine induced by neonatal dopamine depletion. However, the grafts were unable to restore more complex behaviours such as hoarding for food pellets, schedule-induced polydipsia and learning behaviours. Moreover, the neonatal transplants induced additional deficits such as catalepsia, nocturnal hyperactivity and day-time hyperactivity during food deprivation. It was concluded that, at least in the present paradigm, the implantation into neonatal brain does not lead to any greater functional recovery than that observed after implantation during adulthood.

Effects of intra-accumbens dopaminergic grafts on behavioral deficits induced by 6-OHDA lesions of the nucleus accumbens or A10 dopaminergic neurons: a comparison.

Local lesion of the dopaminergic (DA) terminals of the nucleus accumbens have been described to reproduce part of the behavioral deficits evoked by the lesion of the whole mesocorticolimbic DA system. The most straightforward interpretation of these results would be that the DA innervation of the nucleus accumbens is necessary for and critically involved in the normal performance of the given behaviors. However, while giving some indication as to the necessity of the integrity of this DA innervation for normal behaviors, such an approach cannot reveal whether the presence of the DA innervation of other mesocorticolimbic areas (e.g. amygdala, septum, etc.) is also required. In order to approach this question, the behavioral effects of DA grafts implanted into the nucleus accumbens of rats were evaluated following two different 6-hydroxydopamine-induced lesions: a lesion restricted to the anterior DA field (DA terminals of the nucleus accumbens and to a lesser degree the frontal cortex and anteromedial striatum) or a lesion of the whole mesocorticolimbic DA system. The latter lesion induces a disappearance of the DA innervation of the nucleus accumbens as well as the amygdala, septum, etc. Both kinds of lesions led to locomotor hypoactivity, loss of locomotor activation by amphetamine, increased locomotor stimulation to apomorphine, decrease of exploratory activity and loss of hoarding behavior. These deficits were not seen in grafted animals bearing a local lesion of the DA innervation of this structure. For some of these recoveries, however, a pharmacological stimulation of the grafted neurons was required to reveal the effect of the graft. In the case of the total lesion of the mesocorticolimbic DA system, only locomotor dysfunctions were compensated by the intra-accumbens DA implants, while the other deficits remained intact, irrespective of a stimulation of the graft. These results indicate that the re-establishment of the DA innervation of the nucleus accumbens is a sufficient condition for the compensation of locomotor deficits, irrespective of the presence of the DA terminals in more posterior limbic structures, while for deficits of more complex behaviors the simultaneous presence of posterior DA innervations is also required. This latter requirement suggests the existence of some cooperativity between the different central DA terminal areas for the normal performance of behaviors.

Spontaneous and graft-induced behavioral recovery after 6-hydroxydopamine lesion of the nucleus accumbens in the rat.

In the present study the long-term evolution of behavioral deficits following a local lesion of the dopaminergic innervation of the nucleus accumbens with 6-hydroxydopamine (6-OHDA) was compared in two groups of rats: lesioned animals and animals bearing a dopaminergic implant in the nucleus accumbens. Lesioned animals gradually recovered on various behavioral tests (amphetamine-induced locomotion, exploration, hoarding) and were indistinguishable from the control group on most parameters by 10 months postlesion. The deficits were, however, reinstated by a second intra-accumbens 6-OHDA lesion, a finding which suggests a role for dopaminergic reinnervation in the observed recovery. Conversely, grafted animals still displayed marked deficits even 10 months after grafting, although the lesioned areas were well reinnervated by the graft. These results indicate that the graft, while being unable on its own to compensate for part of the deficits, can nevertheless impair and compete with endogenous processes leading to behavioral recovery following a local lesion.

Reinnervation of the nucleus accumbens and frontal cortex of the rat by dopaminergic grafts and effects on hoarding behavior.

Embryonic dopaminergic neurons were implanted in the form of a cellular suspension in the nucleus accumbens previously deprived of its dopaminergic innervation by a local injection of 6-hydroxydopamine. The graft provided a dopaminergic reinnervation to the nucleus accumbens, the anteromedial striatum, the anteromedial frontal cortex and also, in some cases, of the septum. The pattern of reinnervation was specific for each structure and similar to the innervation provided by mesocorticolimbic dopaminergic neurons to these same structures in the normal animal. The graft restored the locomotor stimulatory action of amphetamine which was abolished in the lesioned controls. Hoarding behavior, which was disrupted following the lesion, was not reinstated by the graft alone. However, if the grafted neurons were stimulated by a small dose (0.2 mg/kg, i.p.) of (+)-amphetamine, hoarding reappeared in the grafted animals, while the same dose of amphetamine had no effect in the lesioned controls.

Activation of striatal dopaminergic grafts by haloperidol.

The effect of haloperidol (0.5 mg/kg, 60 min) on striatal dopamine metabolism of intact rats and of rats bearing a dopaminergic graft implanted into the previously denervated striatum was investigated. The dopaminergic grafts increased dopamine and dihydroxyphenylacetic acetic acid (DOPAC) contents to 6.2 and 9.6% of their respective control levels (lesioned striatum: 0.5 and 0.7% respectively). Haloperidol increased both the DOPAC content and the DOPAC:DA ratio in the grafted striatum, and the magnitude of these increases were similar to those seen in intact controls. Furthermore a tendency for the high striatal DOPAC:DA ratio seen in lesioned striata to revert toward control values could also be observed in grafted animals. The significance of these results is discussed in terms of the in vivo regulation of graft activity.

Hyper-reactivity to amphetamine in rats with dopaminergic grafts.

Rats with dopaminergic lesions were subsequently given grafts of dopaminergic (DA) neurons in various brain regions, and later tested for behavioral reactivity to amphetamine. Two experimental situations were used. Amphetamine-induced circling behavior was measured in animals with unilateral lesion of the nigrostriatal pathway implanted with intrastriatal grafts, locomotor activation by amphetamine was measured in animals with bilateral lesions and grafts in the nucleus accumbens. In both situations, behavioral overcompensation was observed after grafting. Ipsilateral circling, which is caracteristic of a unilateral lesion of the nigrostriatal pathway, gave way to contralateral circling, and locomotor activity was restored to levels above those observed for control animals. This behavioral overcompensation is a reflection of hyper-reactivity of grafted animals to amphetamine: they were found to respond to much lower doses than controls and the effect of the drug lasted longer. This enhanced response does not seem to be due to postsynaptic hypersensitivity, but rather to hyper-reactivity of the grafted neurons themselves to amphetamine. The mechanism of this phenomenon, which seems to be a general property of grafted DA neurons is discussed.