Catecholaminergic, GABAergic, and hippocamposeptal innervation of GABAergic "somatospiny" neurons in the rat lateral septal area

Intraseptal connections redefined: lack of a lateral septum to medial septum path

The integrity of the septohippocampal system is essential for memory formation and spatial behavior as well as for the electrical stability of the hippocampus. For many years it has been tacitly assumed or explicitly stated that the reciprocal septohippocampal loop is closed by a massive lateral septum-medial septum path. In the present study we reexamined the intraseptal connectivity with Phaseolus vulgaris leucoagglutinin tracing combined with choline acetyltransferase and parvalbumin immunohistochemistry at both the light and electron microscopic levels. We found that the previously hypothesized lateral septum to medial septum projection is extremely sparse and that the major medial septum to lateral septum path is parvalbumin-immunoreactive (likely GABAergic). The redefined circuitry has important implications for the understanding of the septal regulation of hippocampal electrical activity and the operations of the septo-hippocampal system.

Antagonism of GABAergic transmission within the septum disrupts working/episodic memory in the rat

Male Sprague-Dawley rats, trained to perform a standard or delayed-non-match-to-sample radial arm maze task, were implanted with a single cannula aimed at the medial septal nucleus. A within-subjects design was utilized to examine the effects of intraseptal administration of the GABAergic antagonist bicuculline on performance of these tasks. Bicuculline (0-0.5 microgram/0.5 microliter) infusion produced dose-dependent impairments when administered prior to performance of a standard radial arm maze task. Post-training infusion of bicuculline (0.-0.25 microgram/0.5 microliter) also induced dose-dependent impairments in the delayed version (4 h) of the task. Further testing indicated that post-training administration of a low dose of bicuculline (0.05 microgram) in the delayed version of the task induced a deficit at a 4-h, but not a 1-h, retention interval. The latter indicates that the impairment varied as a function of bicuculline dose and increasing task difficulty (longer retention intervals). Previous observations indicated that post-training administration of the GABAergic agonist muscimol and the antagonist bicuculline could induce deficits in the performance of the delayed task. The present findings demonstrate that intraseptal bicuculline treatment can disrupt ongoing radial maze performance, as well as the maintenance and/or retrieval of memories necessary for performance of the delayed version of the task. These findings suggest that either activation or blockade of intraseptal GABA receptors is sufficient to disrupt working/episodic memory processes. The role of septum and septohippocampal pathway in working/episodic memory is discussed.

Synaptology and origin of somatostatin fibers in the rat lateral septal area: convergent somatostatinergic and hippocampal inputs of somatospiny neurons

This study deals with the synaptology, morphologically identified postsynaptic targets, and origin of somatostatin (SOM) fibers in the rat lateral septal area (LSA) with special reference to those forming pericellular baskets. Septal vibratome sections were immunostained for SOM-14 in 3 experimental groups: control animals, rats subjected to a chronic transection of the ascending afferents to the septum, and animals with acute fimbria-fornix lesion. Light microscopy revealed that the SOM-immunoreactive fibers form pericellular baskets predominantly in the intermediate and ventral parts of the caudal half of the LSA. Electron microscopic analysis showed that the somatospiny neurons are postsynaptic targets of these pericellular baskets. Eight days after a unilateral cut placed at the ventral border of the septum, virtually all SOM-immunoreactive axon terminals disappeared from the ipsilateral intermediate and ventral LSA, and they were substantially reduced in the dorsal LSA. However, in these rats SOM-positive neurons could be observed in the LSA on the lesioned, but not on the contralateral side. Furthermore, on the lesion side of the anterior periventricular hypothalamus an increase was detected both in the number and the intensity of immunostaining of SOM-positive neurons. Thirty-six h following a unilateral transection of the fimbria-fornix, the SOM-immunoreactive axon terminals in the LSA remained intact; only immunonegative degenerated hippocamposeptal boutons were detected forming synaptic contacts with somatospiny neurons. Axosomatic synapses of SOM-positive boutons regularly appeared at the neck of somatic spines which were postsynaptic to degenerated hippocamposeptal fibers. The results indicate that the septal SOM fibers are of multiple origin. Those forming pericellular baskets in the LSA originate in ventral extraseptal, probably periventricular hypothalamic areas. SOM fibers scattered in the dorsal LSA are most likely processes of local SOM neurons. The accumulation of immunoreactive SOM in some cells of the undercut septum is a sign of axonal lesion, indicating that these neurons project outside the septum. The SOM innervation of somatospiny neurons which also receive hippocampal input and have been reported to contain gamma-aminobutyric acid (GABA) may be a morphological substrate of the SOM-related disinhibition in the LSA.

Convergent vasopressinergic and hippocampal input onto somatospiny neurons of the rat lateral septal area

Electron microscopic immunocytochemistry, was combined with acute anterograde axon degeneration, following transection of the fimbria-fornix, to describe the innervation of somatospiny neurons by vasopressin-immunoreactive and degenerated hippocamposeptal axon terminals in the rat lateral septal area. Vasopressin-immunopositive boutons characterized by symmetric synaptic membrane specializations, and the degenerated hippocamposeptal axon terminals which form asymmetric synaptic contacts, frequently terminate on the same dendritic and somatic profiles, and particularly on the somata of somatospiny neurons. Although hippocamposeptal fibers predominantly form axospinous synapses in the lateral septal area, they terminate mainly on the dendritic shafts and soma of the vasopressin-receptive neurons. Of 720 vasopressin-immunoreactive terminals in the mediolateral part of the lateral septal area, 80% form synaptic contacts with dendritic shafts; 50% on small (distal) dendritic profiles and 30% on large (proximal) dendrites. Synaptic contacts between vasopressin-immunoreactive terminals and dendritic spines were not observed. The remaining 20% of immunoreactive boutons formed axosomatic synaptic contacts with a total of 58 neurons; 31% of these neurons exhibited somatic spines in the plane of the section analysed. Previous studies have demonstrated that in the lateral septal area vasopressin modulates the action of the excitatory amino acid-containing hypocamposeptal fibers, and also plays a role in the maintenance of long term potentiation evoked by fimbria-fornix stimulation. The convergent vasopressinergic and hippocampal input onto the same somatospiny neurons of the lateral septal area suggests that these neurons are targets of these physiological actions.