The distribution of septal projections to the hippocampus of the rat

Hippocampal potentials evoked by stimulation of olfactory basal forebrain and lateral septum in the rat

Electrophysiological characteristics of olfactory-hippocampal relations were examined because recent anatomical studies have described a substantial olfactory input to the hippocampus via the entorhinal cortex. Potentials evoked in the dorsal hippocampus of anesthetized rats by stimulation of the prepyriform cortex, pyriform cortex, diagonal band, lateral olfactory tract, anterior commissure, olfactory tubercle and anterior olfactory nucleus had similar characteristics, although latencies differed. For example, latencies were twice as long after stimulation of the obliquely oriented portion of the diagonal band than after stimulation of the prepyriform cortex. A relatively low-amplitude, initially negative wave was recorded in the subiculum, CA1 and CA2, and a relatively high-amplitude, initially positive wave was recorded in CA4 and the dentate gyrus. In CA3 negative potentials were observed at dorsal recording sites and positive potentials were recorded at more ventral sites. Peak latencies were usually two to four msec shorter for the negative than for the positive wave. Laminar distributions of responses evoked in the hippocampus by stimulation of the prepyriform cortex and diagonal band were evaluated by driving eight electrodes mounted on one carrier through the brain and were found to be strikingly similar. Maximal amplitudes of the negative wave were recorded at the level of stratum moleculare of CA1 and the subiculum, and peak amplitudes of the positive wave were associated with the hilus of the dentae gyrus. Transition from negative to positive waveforms occurred approximately at the hippocampal fissure. Although the negative and positive waves were usually elicited together, they also were separable in that only negative waves were recorded along some tracks and only positive waves along others. Also, various stimulation sites in the prepyriform cortex elicited stable high-amplitude positive waves accompanied by negative waves of varying amplitude. It is suggested that branches of the perforant path are involved in generation of the two waves and that activity in a number of olfactory structures may influence the hippocampus, probably via the perforant pathway. Thus, hippocampal potentials following prepyriform or diagnonal band stimulation were not abolished by transection of the fornix-fimbria. Dorsolateral septal stimulation evoked hippocampal responses with characteristics and distribution distinctly different from those evoked by stimulation of olfactory areas. The findings suggest that lateral septal stimulation may activate the hippocampus antidromically.

Subcortical afferents to the hippocampal formation in the monkey

The distribution of neurons in the basal telencephalon, the diencephalon, and the brainstem that project to the hippocampal formation has been analyzed in mature cynomolgus monkeys (Macaca fascicularis) by the injection of horseradish peroxidase into different rostro-caudal levels of the hippocampal formation. After injections which involve Ammon's horn, the dentate gyrus, and the subicular complex, retrogradely labeled neurons are found in the following regions: in the amygdala (specifically in the anterior amygdaloid area, the basolateral nucleus, and the periamygdaloid cortex); in the medial septal nucleus and the nucleus of the diagonal band; in the ventral part of the claustrum; in the substantia innominata and the basal nucleus of Meynert; in the rostral thalamus (specifically in the anterior nuclear complex, the laterodorsal nucleus, the paraventricular and parataenial nuclei, the nucleus reuniens, and the nucleus centralis medialis); in the lateral preoptic and lateral hypothalamic areas, and especially in the supramammillary and retromammillary regions; in the ventral tegmental area, the tegmental reticular fields, the raphe nuclei (specifically in nucleus centralis superior and the dorsal raphe nucleus), in the nucleus reticularis tegmenti pontis, the central gray, the dorsal tegmental nucleus, and in the locus coeruleus.

Pharmacological identification of acetylcholine and glutamate excitatory systems in the dentate gyrus of the rat

The responses of dentate granule cells to medial septum (MS) and perforant path (PP) stimulation were examined in urethane anaesthetized rats. MS and PP stimulation evoked an orthodromic activation of granule cells which was correlated with the negative transient of the characteristic field potential elicited from each site. The effects of electrophoretic application of acetylcholine (ACh) and glutamate (Glu) were examined on granule cells identified in this manner. The excitatory action of ACh but not that of Glu was antagonized by atropine. Glutamate diethylester (GDEE) blocked the excitation produced by Glu but not ACh. The synaptically evoked excitation elicited by MS was blocked by atropine but unaltered by GDEE whereas the PP excitatory response was blocked by GDEE and unaltered by atropine. The results of this study indicate that two discrete excitatory systems are present in the dentate gyrus of the rat: a cholinergic system originating in the medial septum and a glutamate mediated system originating in the entorhinal cortex.

Selective reinnervation of hippocampal area CA1 and the fascia dentata after destruction of CA3-CA4 afferents with kainic acid

Intraventricular injections of kainic acid were used to destroy the hippocampal CA3-CA4 cells, thus denervating the inner third of the molecular layer of the fascia dentata and stratum radiatum and stratum oriens of area CA1. The responses of intact afferents to such lesions were then examined histologically. The hippocampal mossy fibers densely reinnervated the inner portion of the dentate molecular layer after bilateral destruction of CA4 neurons and to a lesser extent after unilateral destruction. Septohippocampal fibers replaced CA4-derived fibers in the dentate molecular layer only after particularly extensive bilateral CA4 lesions. Medial perforant path fibers showed no anatomical response to any of these lesions. Neither septohippocampal, temporoammonic nor mossy fibers proliferated in or grew into the denervated laminae of area CA1. These results show a preferential ordering in the reinnervation of dentate granule cells which is not readily explained by proximity to the degenerating fibers and also that removal of CA3-CA4-derived innervation more readily elicits translaminar growth in the fascia dentata than in area CA1. These results may be relevant to clinical situations in which neurons of the hippocampal end-blade are lost.

The effect of collateral sprouting on the density of innervation of normal target sites: implications for theories on the regulation of the size of developing synaptic domains

The 'commissural' innervation of the dentate gyrus molecular layer has been analyzed in normal adult rats and in those in which the ipsilateral entorhinal cortex had been removed by aspiration at 14 days post-natal. This ablation severely deafferents the distal two-thirds of the molecular layer and induces 'sprouting' by the commissural afferents which are normally restricted to the more proximal dendritic zone. It was the objective of the present study to employ quantitative electron microscopy to determine (1) the extent of synaptic recovery in the deafferented field; (2) the magnitude of the contribution by the commissural fibers to the reinnervation of the deafferented field; and (3) if sprouting by the commissural projections causes a reduction in the density of the terminal field they generate in their normal target region. The synaptic density of the neonatally deafferented middle molecular layer was found to have returned to near control levels by adulthood. Degeneration studies performed in the adult revealed that commissural endings were located in equivalent numbers in the inner and middle molecular layers of rats in which the entorhinal cortex had been removed at 14 days post-natal; in normal rats (i.e. no neonatal surgery) the commissural terminals were found only in the inner molecular layer. Furthermore, and most importantly, the density of commissural terminals in the inner molecular layer was virtually identical in the 'sprouted' and control rats. Thus the tremendous areal expansion of the commissural terminal field which occurs after early deafferentation of the distal parts of the granule cell dendrites was not accompanied by any loss of input to the normal target of this afferent. Therefore, sprouting in this system represents an exaggeration of normal growth rather than a redistribution of a fixed population of endings. The relevance of these findings to theories concerned with the regulation of axonal growth and terminal proliferation during development is discussed.

Hippocampal theta in rats under urethane: generators and phase relations

Recordings were made from the directly visualized dorsal hippocampus of urethane-anesthetized rats with silver ball and tungsten microelectrodes. Theta of about 5 c/sec was elicited by reticular stimulation and was located in two broad strata in and subjacent to CA1. A superficial generator yielded 200-250 microV theta from the alveus, stratum oriens and stratum pyramidale; a null-theta and phase-reversal point was located in stratum radiatum; a deep generator yielded 300-500 microV theta in stratum lacunosum-moleculare of the hippocampus and distal stratum moleculare of the dentate gyrus, with maximum amplitude near the fissure. No theta was found in CA3. Cross-correlation analyses between generators yielded coefficients on the order of -0.80 while within a generator--especially the deep one--coefficients could reach +0.95. Phase analyses showed the two generators were about 180 degrees out of phase, with the deep generator leading. Septotemporal movement along the upper generator yielded no phase shifts; similar movement along the deep generator showed slight lead ing in septal portions. Subiculofimbrial movement in both generators showed a complex pattern of phase shifts: generally, subicular sites led fimbrial sites, but an inversion of 10 degrees-20 degrees occurred in the millimeter anterior to the center of the hippocampus. Anatomical, phase and other datal led to consideration of a possible retrohippocampal role in supplementing the well-known pacemaker in the medial septum.

Muscarinic receptors in the central nervous system of the rat. I. Technique for autoradiographic localization of the binding of [3H]propylbenzilylcholine mustard and its distribution in the forebrain

[3H]Propylbenzilylcholine mustard ([3H]PrBCM) is a synthetic, potent muscarinic antagonist, which binds specifically and irreversibly by means of a covalent linkage to muscarinic receptors. Ten micrometer coronal cryostat sections taken through unfixed rat brain at the level of the maximum extent of the caudate nucleus were mounted on glass slides and incubated with 2.4 nM [3H]PrBCM at 30 degrees C for 25 min. They showed a total binding of 3250 pmol/g protein, of which 2130 pmol/g protein was sensitive to pretreatment with 10-6 M atropine. The specific (atropine-sensitive) binding was saturable. Saturation was reached at 15 min, with a rate constant of 1.3 x 106 M-1 sec-1. Binding was unaffected by drugs acting at nicotinic receptors (D-tubocurarine, hexamethonium), or by physostigmine, but was inhibited by muscarinic drugs (pilocarpine, oxotremorine, 3-quinuclidinylbenzilate). Postfixation for 15 min in Carnoy's fixative reduced the specific binding by 10% and the non-specific by 50%. Prefixation (i.e. before incubation with [3H]PrBCM) with any fixatives containing formaldehyde largely prevented specific binding, but a range of concentrations of glutaraldehyde (2% to 0.05%) caused only small reductions in specific binding (e.g. 0.1% glutaraldehyde caused only a 6% reduction). Clear, regionally specific patterns of localization of specific label in light microscope autoradiographs could be obtained from cryostat sections prefixed with 0.1% glutaraldehyde, incubated with 2.4 nM [3H]PrBCM for 15 min at 30 degrees C, and postfixed for 15 min in Carnoy's solution. Of the 105 forebrain areas studied 12 had grain counts between 6 and 9 times the non-specific level and a further 30 had counts 4 to 6 times non-specific. The higher grain counts were in the external plexiform layer of the olfactory bulb, anterior olfactory nucleus, olfactory tubercle, pyriform cortex, stratum radiatum of the hippocampus, stratum moleculare of the dentate gyrus, lateral amygdaloid nucleus, cortico-amygdaloid transition zone, anteroventral thalamic nucleus, hypothalamic supraoptic nucleus, caudate-putamen, nucleus accumbens, and in laminae 3 and 6 of the neocortex (parietal region). There were high grain densities over the choroid plexus the lateral but not the third or fourth ventricles.

Seizures and related epileptiform activity in hippocampus transplanted to the anterior chamber of the eye: modulation by cholinergic and adrenergic input

Transplants of rat hippocampus into the anterior chamber of the eye of a host animal were used to assess the effects of cholinergic and adrenergic neuronal inputs on the generation and duration of seizure activity. Cholinomimetics initiated both seizures and hypersynchronous neuronal activity in the transplants. Cyclic guanosine monophosphate (GMP) derivatives and isobutyl methylxanthine elicited similar changes. Reflex activation of the cholinergic parasympathetic input to the iris and transplant by illumination of the ipsilateral retina also induced seizures or increased the rate of penicillin-induced interictal spike discharge. Application of beta-adrenergic agonists inhibited interictal spikes and paroxysmal depolarizing shifts induced by penicillin. Fluorescence histochemical studies showed that host sympathetic adrenergic fibers derived from the ground plexus of the iris invaded the transplant to form fine varicose nerve terminals. Activation of these adrenergic afferents to the transplant diminished both the amplitude and frequency of penicillin-induced epileptiform activity. Epileptiform activity in hippocampal occular transplants is strongly modulated by cholinergic and adrenergic neuronal inputs, with the former exerting a facilatory influence and the latter, an inhibitory effect.

The connections of the septal region in the rat

The efferent, afferent and intrinsic connections of the septal region have been analyzed in the rat with the autoradiographic method. The lateral septal nucleus, which can be divided into dorsal, intermediate and ventral parts, receives its major input from the hippocampal formation and projects to the medial septal-diagonal band complex. The ventral part of the nucleus also sends fibers through the medial forebrain bundle to the medial preoptic and anterior hypothalamic areas, to the lateral hypothalamic area and the dorsomedial nucleus, to the mammillary body (including the supramammillary region), and to the ventral tegmental area. The medial septal nucleus/diagonal band complex projects back to the hippocampal formation by way of the dorsal fornix, fimbria, and possibly the cingulum. Both nuclei also project through the medial forebrain bundle to the medial and lateral preoptic areas, to the lateral hypothalamic area, and to the mammillary complex. The medial septal nucleus also sends fibers to the midbrain (the ventral tegmental area and raphe nuclei) and to the parataenial nucleus of the thalamus, while the nucleus of the diagonal band has an additional projection to the anterior limbic area. Ascending inputs to the medial septal nucleus/diagonal band complex arise in several hypothalamic nuclei and in the brainstem aminergic cell groups. The posterior septal nuclei (the septofimbrial and triangular nuclei) receive their major input from the hippocampal formation, and project in a topographically ordered manner upon the habenular nuclei and the interpeduncular nuclear complex. The bed nucleus of the stria terminalis receives its major input from the amygdala (Krettek and Price, '78); but other afferents arise from the ventral subiculum, the ventromedial nucleus, and the brainstem aminergic cell groups. The principal output of the bed nucleus is through the medial forebrain bundle to the substantia innominata, the nucleus accumbens, most parts of the hypothalamus and the preoptic area, the central tegmental fields of the midbrain, the ventral tegmental area, the dorsal and median nuclei of the raphe, and the locus coeruleus. The bed nucleus also projects to the anterior nuclei of the thalamus, the parataenial and paraventricular nuclei, and the medial habenular nucleus, and through the stria terminalis to the medial and central nuclei of the amygdala, and to the amygdalo-hippocampal transition area.

The specificity of reactive synaptogenesis: a comparative study in the adult rat hippocampal formation

The CA1 region of the hippocampus in the mature rat is shown to possess the capacity to form new synapses following a lesion of either the commissural afferents, which removes 41% of the synaptic input to stratum radiatum, or commissural and associational afferents, which destroys 74% of the synaptic input. With both types of lesion, extensive reinnervation occurs without obvious changes in lamination of afferent fibers and without accompanying changes in the acetylcholinesterase-(AChE) staining pattern. This is in contrast to what is known to occur in the hippocampal dentate gyrus following an ipsilateral entorhinal lesion where afferent lamination is reordered and where AChE-staining intensifies. A comparison between the disparate patterns of reinnervation in these closely related structures affords the opportunity to examine some of the specific factors that may regulate synaptic readjustments in brain.

Activity of dentate granule cells during learning: differentiation of perforant path input

Experiments were conducted which extended previous findings regarding the activity of the perforant path and its synaptic relationship to the granule cells of the dentate gyrus during conditioning. A differential conditioning paradigm was utilized in which rats were trained to respond to one of two different tone frequencies. Results demonstrated that (1) tone elicited averaged evoked potentials recorded from the perforant path terminal zone in the outer molecular layer of the dentate gyrus were similar for both the positive and negative tones regardless of frequency or reversal of the reinforcement condition; (2) extracellular unit discharge patterns of dentate granule cells were differentially associated with the positive and negative tones as demonstrated by post stimulus histograms (PSHs); (3) this differential pattern of unit discharges could be reversed following establishment of criterion differential behavioral responding after reversal of the reinforcement contingency between the two tone stimuli and (4) the differential unit discharge pattern was not present when behavioral responding was not differentiated to the two tone stimuli, e.g., immediately following reversal of the reinforcement contingency. The results are discussed within the context of other anatomically defined functional circuits within the hippocampus which could serve as the basis for alteration of the non differentiated excitatory perforant path input into a differential dentate granule cell discharge pattern for behaviorally relevant sensory stimuli.

Evidence for an input to the molecular layer and the stratum granulosum of the dentate gyrus from the supramammillary region of the hypothalamus

Injections of a mixture of tritiated amino acids were made into the posterior hypothalamus in a series of rats and cats. In every case in which the injection involved a significant proportion of the cells in the supramammillary region, labeled fibers could be followed to the dentate gyrus, the anterior hippocampal rudiment and the induseum griseum of both sides. In the dentate gyrus the hypothalamic afferents terminate in a narrow band in the outer half of the stratum gramulosum and the inner 20 micron or so, of the stratum moleculare, immediately deep to the zone of termination of the associational and commissural afferents. As judged by silver grain counts across the width of the zone of labeled terminals, the projection to the ipsilateral side is several times as heavy as that to the contralateral side, and although it involves the entire septo-temporal (=rostro-caudal) extent of the gyrus on both sides, the projection to the suprapyramidal (inner) blade of the dentate gyrus is approximately twice as heavy as that to the infrapyramidal (outer) blade.

Commissural and intrinsic connections of the rat hippocampus

The commissural and intrinsic connections of the hippocampus were studied using the Fink-Heimer method and the horseradish peroxidase (HRP) uptake technique. A conspicuous septo-termporal gradient was found of the density of the commissural projection that passes through the psalterium ventrale to the Ammon's horn. The degeneration resulting from transection of the psalterium ventrale was most dense in the septal tip and decreased towards the temporal tip. The commissural and ipsilateral connections from the hilus fasciae dentatae (CA4) and regio inferior (CA3/CA2) were found to terminate in different parts of the hippocampus. The hilus fasciae dentatae gave rise to ipsilateral and commissural projections to the dentate area only. The regio inferior has ipsilateral and commissural projections to the Ammon's horn. A specific termination pattern was found of the projection from regio inferior to stratum radiatum of both the ipsilateral and contralateral regio superior (CA1) and regio inferior (CA2/CA3). At levels temporal to the lesion, the projection is primarily to the superficial part of stratum radiatum, while at levels septal to the lesion the terminal zone occupies the deep part of the layer. This pattern was not related to the position of the cells of origin, along the septo-temporal or subiculo-dentate axes. In general, the commissural projections showed the same degree of septo-temporal divergence as the ipsilateral projections. The only major difference in the terminal fields of the two sets projections to the Ammon's horn was that the terminal zone of the commissural projection to stratum oriens was always more dense than that of the ipsilateral projection to this layer, while an inverse gradient was seen in stratum radiatum. The projections from the septal and middle dorso-ventral parts of regio inferior differed. The temporal spread of the projections from the septal part was large while that from the projections arising at middle dorso-ventral levels was more restricted. Moreover, a longitudinal association path interconnecting different parts of the regio inferior along the septo-temporal axis was seen to arise only from the cells in the septal parts of the regio inferior. Each part of the regio inferior projected to all parts of stratum radiatum and oriens of the contralateral Ammon's horn. However, the projection to the contralateral regio inferior was most dense at the site homotopic to that lesioned. The ventricular part of regio inferior projected primarily to the contralateral stratum oriens of the Ammon's horn, while the part adjacent to the dentate area mostly supplied stratum radiatum.

Septo-hippocampal pathway necessary for dentate theta production

In acute experiments in urethane-anaesthetized rabbits a small lesion at the septo-hippocampal border, from 0.8 to 1.5 mm from the midline, abolished theta activity ipsilaterally. This lesion severed fibres from the lateral part of the medial septal nucleus. Lesions of the main body of the fimbria or the dorsal fornix, alvear bundle and perforant path or the hippocampal commissures failed to change the dentate theta activity. Theta activity also survived the establishment of a 2 mm wide 'gate' near the rostral pole of the hippocampus; the gate was produced by cutting the main body of the fimbria and medially adjoining tissue and the dorsal fornix and laterally adjoining tissue. Cuts behind the 'gate' showed successive reduction of the dentate theta when the lesion passed beyond a threshold depth of about 1.5 mm. The degree of theta reduction appeared dependent upon the amount of the hippocampal tissue destroyed below this level. Thus, the fibres of importance for theta production seem to run through a bottleneck just behind the medial septum. Their further course is found in the basal part of the fimbria on its medial aspect and the adjoining parts of CA3 (lower blade) and hilus of the dentate fascia. Because the whole of this area had to be destroyed to block all theta activity, it is suggested that the fibres of importance for theta production are relatively dispersed within this region.

Synaptically identified hippocampal slow potentials during behavior

Averaged evoked slow-wave potentials (AEPs) were recorded from various locations within the dentate gyrus and CA1 field of the hippocampus of 16 rats during the performance of an operant tone discrimination task. Consistent time-locked tone averaged evoked potentials (AEPs) were recorded from the perforant path zone in the outer molecular layer of the dentate gyrus. Tone AEPs were never present in this region (1) prior to development of the discrimination, (2) during behavioral extinction, or (3) during the performance of other operant behaviors. Results are discussed in terms of the functions of the perforant path in neural and behavioral plasticity.

Neuronal plasticity in the limbic system during classical conditioning of the rabbit nictitating membrane response. II: Septum and mammillary bodies

Neuronal unit activity was recorded from several limbic system structures during classical conditioning of the rabbit nictiating membrane response to a tone CS. Air puff to cornea was used as a UCS. The present and past investigations of hippocampal activity using this paradigm show a neuronal plasticity which develops early in training, increases rapidly and shifts forward in time as behavioral conditioning develops. Recordings from the lateral septal region demonstrate the same within-trial pattern of unit discharge seen in hippocampus, indicating a projection of hippocampal plasticity over precommissural fornix pathways. Medial septal neurons, on the other hand, respond in an excitatory manner to the onsets of tone and air puff stimulation. While unit discharges seen in hippocampus and lateral septum occur only during the paired (learning) paradigm, medial septal activity is identical under both paired and unpaired (control) conditions. The latter fact lends support for a sensory interpretation of medial septal responses, and is consistent with anatomical evidence of a major septohippocampal projection originating from this region. In contrast to results for lateral septum, recordings from medial and lateral mammillary nuclei indicate only small, diffuse excitation that exhibits no consistent changes over training, and is not related to activity seen in hippocampal or septal regions. The apparent lack of correspondence between learning dependent unit measures obtained from pre- and postcommissural fornix structures is entirely consistent with current modified descriptions of limbic system anatomy.

Hippocampal activation and incorporation of macromolecule precursors

The effect of rhythmic slow wave activity (theta rhythm) on the incorporation of 3H-leucine and 3H-fucose into the total proteins of different hippocampus areas was studied. The theta rhythm was elicited by electrical stimulation of medial septum nuclei. An increase in 3H-leucine incorporation into the total proteins of CA 3 and CA 1 sectors of the hippocampus was observed, whereas the stimulation had no influence on precursor incorporation into the complex CA 4/area dentata. In contrast to these findings 3H-fucose incorporation into hippocampal proteins was not influenced by electrical stimulation of the medial septum. These findings are discussed in comparison to the results obtained in a learning experiment, which revealed an increased incorporation of both leucine and focuse into hippocampal proteins.

Development of potentiation in the dentate gyrus of rat: physiology and anatomy

The physiological development of potentiating processes in the rat dentate gyrus were compared to morphological development. Rapid Golgi techniques were coupled with in vitro studies of dentate granule cell frequency potentiation, post-tetanic potentiation and long-term potentiation. Frequency potentiation and long-term potentiation exhibited a developmental progression between 7 and 210 days postnatal. Posttetanic potentiation remained constant across this period. The relation of these findings to synaptogenesis and dendritic spine formation are discussed.

Loss of hippocampal theta rhythm results in spatial memory deficit in the rat

Rats learned, using distal room cues, to run to a goal on an elevated, circular track starting from any position on the track. The goal was one of eight equidistant, recessed cups set around the track, the goal cup being distinguished from the others solely by its position in the room. After learning, electrolytic lesions were made in the medial septal nucleus eliminating hippocampal theta rhythm in some animals but not in others. Rats without theta rhythm were no longer able to perform the spatial task, whereas rats with undisturbed theta rhythm retrained normal performance. Although rats without theta rhythm could not find their way directly to the goal, they recognized its location when they came upon it by chance. This type of spatial deficit appears similar to that shown by hippocampally lesioned patient H.M. Subsequent tests demonstrated that rats deprived of theta rhythm before training could nevertheless learn the task.

Development of habituation in the dentate gyrus of rat: physiology and anatomy

The physiological development of monosynaptic response habituation in the rat dentate gyrus was compared to morphological development. Rapid Golgi techniques were coupled with in vitro studies of dentate granule cell habituation to several frequencies and intensities of monosynaptic excitation. Except for the youngest group, the degree of habituation increased as a function of age, paralleling the morphological development.

Distribution of an alpha-bungarotoxin-binding cholinergic nicotinic receptor in rat brain

Cholinergic nicotinic receptors in rat brain were demonstrated by the use of the potent nicotinic antagonist [125I]alpha-bungarotoxin [125I]alpha-Btx). Biochemical studies on binding of [125I]alpha-Btx to rat hippocampal homogenates revealed saturable binding sites which are protected by nicotine, D-tuborcurarine and acetylcholine but not by atropine or oxotremorine. The hippocampus and hypothalamus displayed relatively high [125I]alpha-Btx specific binding whereas the cerebellum was devoid of specific binding. Other regions displayed intermediate binding levels. Analysis of the regional distribution of [125I]alpha-Btx binding by autoradiography of frontal brain sections revealed high labeling in the hippocampus, hypothalamic supraoptic, suprachiasmatic and periventricular nuclei, ventral lateral geniculate and the mesencephalic dorsal tegmental nucleus. It is suggested that the limbic forebrain and midbrain structures as well as sensory nuclei are the main nicotinic cholinoceptive structures in the brain.

A monosynaptic fiber track studied in vitro: evidence of a hippocampal CA1 associational system?

An excitatory afferent system previously undescribed in the in vitro slice was found to be present in the hippocampal CA1 stratum oriens. Evidence was provided that the system makes monosynaptic, en passage contact with CA1 pyramidal cells in the region of their basal dendrites. Slices from partially deafferented hippocampai were used in evaluating the possibility that the s. oriens pathway originated in the contralateral hippocampus. This possibility was not confirmed and the results were discussed in terms of an ipsilateral associational system in CA1 s. oriens.

Diminished axonal transport of glycoproteins in the senescent rat brain

At various time intervals (10, 15, 20, 25, 30 min) after injection of 3H-fucose into the medial septal nucleus of young adult (3 months old) and senescent (25 months old) Fischer-344 rats, the specific activities of trichloroacetic acid-phosphotungstic acid (TCA-PTA) soluble and insoluble fractions were determined in the medial area of the septum and in three successive rostro-caudal sections of the hippocampal formation containing mainly the dentate gyrus, but also its hilus with fields CA4 and CA3c of the hippocampus. The rate of 3H-fucose incorporation into glycoproteins of the septum did not differ in young adult and senescent rats. Part of the TCA-PTA soluble and insoluble radioactive material was transported through the septo-hippocampal pathway to the dentate gyrus. This transport was inhibited by the injection of colchicine into the septum prior to 3H-fucose injection and was completely blocked by electrolytic lesion of the medial septal nucleus. The arrival time and the amount of the TCA-PTA soluble radioactive material transported to the dentate gyrus did not differ in young adult and senescent rats. However, the TCA-PTA insoluble labelled glycoprotein was transported to the dentate gyrus in a significantly smaller amount and during a longer period of time in the senescent animals. This age-related change may reflect a reduction in amount and/or in rate of axonal transport of glycoproteins in the septo-hippocampal pathway of senescent rats.

Commissural connections of the dentate area in the rat

The commissural connections of the area dentata were investigated with the Fink-Heimer silver impregnation method and the commissural terminals in the hilus of the fascia dentata further studied by electron microscopy of anterograde degeneration. The commissural endings in the molecular layer were found to terminate as previously reported by others. In addition it was shown that the hilus also receives a significant commissural input. The commissural afferents to both the molecular layer and the hilus terminate along the full rostro-caudal extent of the area dentata, but with varying densities. The degeneration in the molecular layer is maximal dorso-rostrally and declines in the caudo-ventral direction, whereas the degeneration in the hilus varies inversely. The commissural terminals in the hilus make asymmetrical contacts with dendritic spines and to a lesser extent with dendritic stems. Dark, but otherwise apparently normal terminals with the features of mossy fiber boutons, were encountered in low numbers in both decommissurated and control animals. The commissural projection to the dentate area originates in the opposite hilus and possibly the adjacent part of CA3 (CA3c). Fibers from middle dorso-basal levels of the hilus to the opposite molecular layer are distributed more rostrally than ventrally relative to the level of the source of the fibers.