Complexity of sensory environment drives the expression of candidate-plasticity gene, nerve growth factor induced-A.

Exposure of animals to an enriched environment triggers widespread modifications in brain circuitry and function. While this paradigm leads to marked plasticity in animals chronically or acutely exposed to the enriched environment, the molecular mechanisms that enable or regulate such modifications require further characterization. To this end, we have investigated the expression profiles of both mRNA and protein products of a candidate-plasticity gene, nerve growth factor induced-A (NGFI-A), in the brains of rats exposed to increased environmental complexity. We found that NGFI-A mRNA is markedly up-regulated throughout the brains of animals exposed to the enriched environment, but not in the brains of either handled-only or undisturbed control groups. The most pronounced effects were observed in the somatosensory and visual cortices, in layers III and V, while more modest increases were observed in all other cortical layers, with the exception of layer I. A striking NGFI-A mRNA up-regulation was also observed in the striatum and hippocampal formation, notably in the CA1 subfield, of animals exposed to the enriched environment paradigm. Immunocytochemistry was also used to investigate the distribution of NGFI-A protein in response to the environmental enrichment protocol. A marked increase in the number of NGFI-A positive nuclei was identified in the enriched environment condition, as compared to undisturbed and handled-only controls, throughout the rat brain. While the greatest number of NGFI-A immunolabeled neurons was found in cortical layers III and V, up-regulation of NGFI-A protein was also detectable in layers II, IV and VI, in both the somatosensory and visual cortices. NGFI-A immunopositive neurons were also more numerous in the CA1 subfield of the hippocampal formation of animals exposed to the enriched environment, but remained at basal levels in both control groups. Our results implicate NGFI-A as one of the possible early genetic signals that ultimately lead to plastic changes in the CNS.

Upregulation of the immediate early gene arc in the brains of rats exposed to environmental enrichment: implications for molecular plasticity.

Exposure to an enriched environment, a procedure that induces plasticity in the cerebral cortex, is associated with pronounced morphological changes, including higher density of dendritic spines, enlargement of synaptic boutons, and other putative correlates of altered neurotransmission. Recently, it has been demonstrated that animals reared in an enriched environment setting for 3 weeks have less neuronal damage as a result of seizures and have decreased rates of spontaneous apoptosis. Even though clear morphological modifications are observed in the cerebral cortex of animals exposed to heightened environmental complexity, the molecular mechanisms that underlie such modifications are yet to be described. In the present work, we investigated the expression of the immediate early gene arc in the cortex of animals exposed to an enriched environment. Animals were exposed daily, for 1 h, to an enriched environment, for a total period of 3 weeks. Brains were processed for in-situ hybridization against arc mRNA. We found a marked upregulation of arc mRNA in the cerebral cortex of animals exposed to the enriched environment, when compared to undisturbed controls, an effect that was most pronounced in cortical layers III and V. Animals in an additional control group that were handled for 5 min daily, displayed intermediate levels of arc mRNA. Furthermore, arc expression was upregulated in the CA1, CA2 and CA3 hippocampal subfields and in the striatum, but to a lesser extent in the dentate gyrus of animals exposed to an enriched environment, as compared to the two control groups. Our results support the association between the upregulation of the immediate early gene arc and plasticity-associated anatomical changes in the cerebral cortex of the adult mammal.

Rapid kindling of the hippocampus protects against neural damage resulting from status epilepticus.

It has previously been reported that rats kindled via the standard kindling procedure do not exhibit the typical profile of neuropathology following status epilepticus. We wished to determine whether a 1-day rapid kindling procedure is also neuroprotective against cell damage resulting from prolonged seizure activity. We found that rats rapidly kindled from the dorsal hippocampus were more resistant to a kainic acid challenge 21-25 days after kindling than were unkindled control rats. Kindling prior to a kainic acid challenge also provided substantial protection against status epilepticus-induced damage in the CA3 region of the hippocampus and piriform cortex in most animals. Thus, despite the short kindling time period, rapid kindling is neuroprotective against status epilepticus-induced cell damage.

Light-induced zif268 expression is dependent on noradrenergic input in rat visual cortex.

In the present paper we investigated the role of the noradrenergic projection from the locus coeruleus on the expression of the immediate early gene zif268 in the visual cortex of rats exposed to ambient light stimulation. Local administrations of 6-hydroxydopamine (6-OHDA), a specific toxin directed against the catecholaminergic system, were performed in the locus coeruleus prior to visual stimulation. Animals were stimulated for 2 h by ambient light, after a 2-week dark adaptation period. Sham-operated controls displayed a massive increase in the number of zif268 positive cells after light stimulation. To the contrary, lesioned animals demonstrated a dramatic reduction in the number of zif268 positive nuclei across all cortical layers. A few scattered immunopositive nuclei were identified in cortical layer IV, however, this region also underwent a significant reduction in the number of zif268 immunopositive nuclei. Our results indicate that the noradrenergic system plays an important role in the expression of zif268 in the visual cortex of rats exposed to ambient light after dark isolation.

Antibody for human p75 LNTR identifies cholinergic basal forebrain of non-primate species.

192-IgG is an antibody directed against the p75 low affinity nerve growth factor receptor in rats, whereas ME 20.4 was raised against the analogous protein in humans. Coupled to saporin, 192-IgG and ME 20.4 have been used to lesion basal forebrain neurons in rats and primates, respectively. We compared the cross-reactivity of 192-IgG and ME 20.4 in the basal forebrain of rat, human, dog, cat, raccoon, pig, and rabbit. We found excellent species cross-reactivity of ME 20.4 in dog, raccoon, cat, pig and rabbit. In contrast, 192-IgG did not label neurons in any species other than rat. Our findings suggest that ME 20.4-saporin could be used to produce cholinergic basal forebrain lesions in several non-primate species.

Noradrenergic system of the zebra finch brain: immunocytochemical study of dopamine-beta-hydroxylase.

Oscine birds are among the few animal groups that have vocal learning, and their brains contain a specialized system for song learning and production. We describe here the immunocytochemical distribution of dopamine-beta-hydroxylase (DBH), a noradrenergic marker, in the brain of an oscine, the zebra finch (Taeniopygia guttata). DBH-positive cells were seen in the locus coeruleus, the nucleus subcoeruleus ventralis, the nucleus of the solitary tract, and the caudolateral medulla. Immunoreactive fibers and varicosities had a much wider brain distribution. They were particularly abundant in the hippocampus, septum, hypothalamus, area ventralis of Tsai, and substantia nigra, where they formed dense pericellular arrangements. Significant immunoreactivity was observed in auditory nuclei, including the nucleus mesencephalicus lateralis pars dorsalis, the thalamic nucleus ovoidalis, field L, the shelf of the high vocal center (HVC), and the cup of the nucleus robustus archistriatalis (RA), as well as in song control nuclei, including the HVC, RA, the lateral magnocellular nucleus of the anterior neostriatum, and the dorsomedial nucleus (DM) of the intercollicular complex. Except for the DM, DBH immunoreactivity within song nuclei was comparable to that of surrounding tissues. Conspicuously negative were the lobus paraolfactorius, including song nucleus area X, and the paleostriatum. Our results are in agreement with previous studies of the noradrenergic system performed in nonoscines. More importantly, they provide direct evidence for a noradrenergic innervation of auditory and song control nuclei involved in song perception and production, supporting the notion that noradrenaline is involved in vocal communication and learning in oscines.

GABAergic retinocollicular projection in the New World monkey Cebus apella.

GABA immunoreactivity was examined in the retina of the New World monkey Cebus apella. Labeled cell bodies were identified as horizontal, bipolar, interplexiform, amacrine and a population of putative ganglion cells. To determine whether ganglion cells were immunoreactive to GABA, double-labeling experiments were performed using Fast Blue as retrograde neuronal tracer injected into the superior colliculus. Retinas containing FB-labeled ganglion cells were subsequently incubated with antiserum against GABA. Although retinocollicular ganglion cells were found in three different layers (ganglion cell layer, inner nuclear layer and inner plexiform layer), our experiments revealed GABA-positive ganglion cells only in the outer half of the ganglion cell layer.