Subcortical projections to the lateral geniculate body in the rat.

The subcortical projections to the lateral geniculate body (LGB) in the rat were studied by means of discrete HRP iontophoretic deposits in the dorsal or the ventral LGB; the labelling was compared to that resulting from HRP deposits in neighboring nuclei. After injecting HRP in the dorsal LGB, labelled cells appeared bilaterally in the ventral LGB, pretectum, superior colliculus, lateral groups of the dorsal raphe nucleus and locus coeruleus. Ipsilaterally, labelled cells were found in the lateral posterior thalamus, nucleus of the posterior commissure and deep mesencephalic reticular nucleus. After injecting HRP into the ventral LGB, labelled cells were observed bilaterally in the pretectum, superior colliculus and dorsal raphe nucleus (lateral groups). Contralateral labelling appeared in the ventral LGB and parabigeminal nucleus. Ipsilateral labelling was found in the zona incerta, lateral posterior thalamus, lateral and medial mesencephalic reticular formation, vestibular and dorsal tegmental nuclei. These findings provide evidence of subcortical projections to the LGB arising in visually-related areas as well as extravisual areas, which might be related to the LGB boutons that survive complete cortical and retinal ablations.

Central connections of the toad neural lobe as shown by retrograde neuronal labeling: classical and new connections.

Iontophoretic deposit of horseradish peroxidase (HRP) in the hypophysial neural lobe (NL) of the toad labeled neurons in the classical neurosecretory preoptic magnocellular nucleus. Further, a number of labeled neurons appeared in the whole extension of the periventricular and medial preoptic nuclei. The latter were continuous dorsally with two other labeled areas known as the bed nucleus of the hippocampal commissure (which appears to be homologous to the subfornical organ in mammals) and the ventromedial thalamic area of Frontera. The possible functional role of many of these afferents to the neural lobe is unknown because all types of neurons were labeled in the projecting zones and, in addition, many are outside of the generally recognized neurosecretory groups.

Afferent connections of the hypothalamic retrochiasmatic area in the rat.

The afferent projections to the retrochiasmatic area (RCA) of the rat hypothalamus have been studied by means of retrograde axonal transport of horseradish peroxidase. Iontophoretic deposit of the marker was used in most animals, and consistent projections from the hypothalamic ventromedial nucleus, the lateral part of the substantia nigra and the parabigeminal nucleus (NPB) were observed. A comparison between NPB projections and projections from the neighboring tegmentum suggests that some neurons of the NPB project to both the RCA and the superior colliculus. Consequently, these NPB neurons might link visual information on its way toward the retrochiasmatic area which, in view of its strategic position, could play a role in neuroendocrine processes.

Effect of a low protein diet on the anatomical development of subcortical formations.

The effects of a low protein diet during gestation, lactation, and after weaning on the anatomical development of a subcortical nucleate formation, the neostriatum, and a reticulate formation, the diagonal band of Broca, were studied. At 10, 30, and 90 days the volume of the neostriatum was decreased in the experimental rats. However, the percent of the brain volume that was neostriatum was unaffected at each of these ages. In a rapid Golgi study of individual neurons at 90 days of age there was no significant effect of the low protein diet on the dendritic length of three different types of neurons within the neostriatum. However, its heavily spined dominant neuron showed a significant decrease in synaptic spine density. In the reticular formation, there was also no significant effect on dendritic length. A minute, apparently axonless cell corresponding to the neurogliaform cell of Ramón y Cajal, showed a decrease in extent of its cell processes only in the neostriatum. When compared to cortical formations, these phylogenetically more conservative neuronal substrates appear to be more resistant to the effects of undernutrition.

The topographic organization of hypothalamic and brain stem projections to the hippocampus.

Direct projections primarily ipsilateral to hippocampus from medial septal, diagonal band, supramammillary, submammillothalamic, locus coeruleus, and dorsal and medianus raphe nuclei were demonstrated. The locus coeruleus projects primarily through the cingulum and fornix superior to the dorsal posterior hippocampus, with its terminal fields in the stratum lacunosum moleculare of the subiculum and areas CA 1-CA 2 of the dorsal posterior hippocampus. LC projections to the granular layer of the dentate hilus were not found. Raphe nuclei project through the cingulum, fornix superior, and primarily the fimbria, to the dorsal and ventral posterior hippocampus, with their terminal fields in the stratum lacunosum moleculare of the dorsal posterior subicular region, stratum radiatum of CA 1-CA 3 in the dorsal hippocampus, and the stratum polymorph of the dentate gyrus, primarily in its superficial part. Raphe projections to the anterior hippocampal rudiment were found. However, no projection was found to the subiculum of the ventral posterior hippocampus, nor to stratum oriens. Hypothalamic nuclei project through the fornix superior and the fimbria, mainly to the dorsal posterior hippocampus with abundant terminal fibers in the depth of the dentate hilus. Smaller cells in these hypothalamic nuclei appear projecting to the ventral hippocampus. The number of neurons in the entorhinal area, the diagonal band, and the hypothalamic nuclei projecting to the hippocampus suggests these groups as the main sources of the extrinsic hippocampal afferents. In addition, they may also serve as relay stations for inputs from more caudal nuclei, and the topographic organization of their terminal fields as described herein may have important functional implications.

Dorsal raphe, substantia nigra and locus coeruleus: interconnections with each other and the neostriatum.

Using a retrograde axonal transport method, direct projections to the neostriatum were demonstrated from the dorsal raphe nucleus, a large area of the ventral midbrain tegmentum (including the ventral tegmental area of Tsai, the substantia nigra pars compacta, reticulata and suboculomotoria), and the tegmentum ventral to the caudal red nucleus. A direct projection was also found from the mediodorsal part of the substantia nigra to the rostral part of the dorsal raphe nucleus. Projections from the entopeduncular nucleus (pallidum) and the lateral hypothalamic area to the lateral habenular nucleus, and from the latter to the dorsal raphe nucleus were also found. This habenular projection arises primarily from large neurons in the medial part of the lateral habenula and also from another group of small cells immediately adjacent to the medial habenular nucleus. A non-reciprocal connection of the dorsal raphe nucleus to the locus coernuleus was also found. On the basis of these results and the data available in the literature on the possible neurotransmitters used by these various structures, it is suggested that the dorsal raphe nucleus may play an important role in brain stem modulation of neostriatal function.

Locus coeruleus-to-dorsal raphe input examined by electrophysiological and morphological methods.

In order to examine the hypothesis that the locus coeruleus (LC) projects directly to the nucleus raphe dorsalis (DR), electrical stimulation was applied to the LC of rats while recording from single neurons in the region of the DR. Slow firing units of the DR were not influenced by the stimulation, although faster firing units in the nearby substantia grisea centralis (SGC) were. These latter cells become oscillatory in their firing rates during LC stimulation. In parallel studies a retrograde transport technique was imployed to obtain morphological evidence regarding projections to DR. Placements of horseradish peroxidase precisely in the DR resulted in very sparse labeling in the LC, although positive transport occurred to other areas. The results indicate that the LC does not project directly to slow firing DR neurons, but does influence faster firing celles in the region of the SGC, probably by complex routes. Suggestions are made for the integration of these findings with earlier fluorescence studies.

Horseradish peroxidase tracing of the lateral habenular-midbrain raphe nuclei connections in the rat.

Connections of the habenular complex to the nuclei of the midline in the midbrain (interpeduncularis, medianus raphe, and dorsalis raphe) have been studied classically by anterograde degeneration in the monkey, the cat, and marsupials. Passing fibers from the medial septal nucleus and lateral preoptic area, however, have also been demonstrated which can complicate interpretation of these results. In this paper the habenular projections were studied in the rat by the retrograde axonal transport of horseradish peroxidase (HRP). After HRP injections in the medianus raphe nucleus labelled neurons appeared in the lateral habenular nucleus and parafascicular nucleus. Labelled neurons were also found in the lateral habenular nucleus after injections in either the dorsalis raphe nucleus or the caudal central gray substance. The habenular projections were always bilateral. There were no labelled neurons in the medial habenular nucleus after HRP injections in the medianus raphe especially on the dorsalis raphe neurons which have usually been thought of as functionally related to other brainstem structures. The present results suggest also that in the rat the lateral habenular nucleus might be the link between basal forbrain inputs and the limbic midbrain area. Thus, the raphe nuclei of the midbrain appear to be crucial regions for integrating two descending circuits: first, a limbic (through septum) circuit, and, second, a basal forebrain (through lateral habenular-preoptic area) circuit.

Regional distribution of 5-hydroxytryptamine in cat brain.

The regional distribution of serotonin (5-HT) in the brain of the cat is poorly understood. In this work, serotonin was analyzed fluorometrically along the brain stem and prosencephalon of the cat. The hypothalamus had the highest concentration of serotonin. Serotonin decreased gradually at the mesencephalon, preoptic area, medulla oblongata, hippocampus, pons, visual cortex, spinal cord and frontal cortex. Significant differences were found between the raphe (3 mm thick) and the lateral blocks of the brain stem. The concentration of serotonin is higher in the raphe blocks, though it decreases caudally. There is no significant difference between the raphe (4 mm thick) and the lateral block of the brain stem. The results demonstrate the regional concentration of serotonin in the CNS of a normal cat, the relationships between serotoninergic neuron groups and serotonin concentration,and the probable significance of nerve terminals and varicosities in storing serotonin.